Datasets:

ArtifactAI

/

arxiv_python_research_code

like 16

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/prior/__init__.py

from typing import Tuple import numpy as np class Prior: def __init__( self, # todo is may be better to pass tensor as arguments and unify whether we use tensor/np array X_train: np.array, y_train: np.array, ): super(Prior, self).__init__() assert len(X_train) == len(y_train) assert X_train.ndim == 2 assert y_train.ndim == 2 self.dim = X_train.shape[1] def predict(self, X: np.array) -> Tuple[np.array, np.array]: """ :param X: features with shape (n, dim) :return: two arrays with shape (n,) """ pass

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/optimizer_styles.py

from matplotlib import cm from experiments.optimizer_names import names def _method_dict(): cmap = cm.Set1 def style(prior: bool = False, copula: bool = False): ms = 's' if prior else "" ls = '--' if copula else '-' return ls, ms rs_copula_color = cmap(0) rs_color = cmap(0) gcp_color = cmap(1) gp_color = cmap(1) styles = { names.GCP_prior: (style(prior=True, copula=True), gcp_color), names.GCP_prior_mo: (style(prior=True, copula=True), gcp_color), names.GCP: (style(prior=False, copula=True), gcp_color), names.GP_prior: (style(prior=True, copula=False), gp_color), names.GP_prior_mo: (style(prior=True, copula=False), gp_color), names.GP: (style(prior=False, copula=False), gp_color), names.CTS_prior: (style(prior=True, copula=True), rs_copula_color), names.CTS_prior_mo: (style(prior=True, copula=True), rs_copula_color), names.TS_prior: (style(prior=True), rs_color), names.TS_prior_mo: (style(prior=True), rs_color), names.RS: (style(prior=False), rs_color), names.AUTORANGE_GP: (style(), cmap(2)), names.WS_BEST: (style(), cmap(3)), names.AUTORANGE_GP: (style(), cmap(4)), names.ABLR: (style(), cmap(2)), names.ABLR_COPULA: (style(copula=True), cmap(2)), names.BOHB: (style(), cmap(6)), names.REA: (style(), cmap(7)), names.REINFORCE: (style(), cmap(8)), names.GCP_ho_prior: (style(), "black"), names.CTS_ho_prior: (style(), "black"), names.EHI: (style(), cmap(2)), names.SMS: (style(), cmap(3)), names.SUR: (style(), cmap(4)), names.EMI: (style(), cmap(5)), names.SGPT: (style(), cmap(9)), names.SGPT_COPULA: (style(copula=True), cmap(9)), } return styles def optimizer_style(method: str): styles = _method_dict() #method = method.strip(names.MO_suffix) assert method in styles, f"method {method} is missing a style" return styles[method] if __name__ == '__main__': import matplotlib.pyplot as plt m = list(_method_dict().items()) plt.figure(figsize=(5, 5)) for i, (method, ((ls, ms), color)) in enumerate(m): plt.plot(range(10), [i] * 10, ls=ls, marker=ms, color=color, label=method) plt.legend() plt.show()

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/evaluate_optimizer_task.py

import argparse import logging import os from functools import partial from pathlib import Path import pandas as pd import numpy as np from blackbox import BlackboxOffline from blackbox.load_utils import evaluation_split_from_task, blackbox_from_task from optimizer.benchmark import benchmark from optimizer.gaussian_process import GP from optimizer.gaussian_process_functional_prior import G3P from optimizer.random_search import RS from optimizer.thompson_sampling_functional_prior import TS def evaluate( task: str, optimizer: str, prior: str, num_seeds: int, num_evaluations: int, output_folder: str, ): optimizers = { "GP": partial(GP, normalization="standard"), "GCP": partial(GP, normalization="gaussian"), "RS": RS, "GP+prior": partial(G3P, normalization="standard", prior=prior), "GCP+prior": partial(G3P, normalization="gaussian", prior=prior), "TS": partial(TS, normalization="standard", prior=prior), "CTS": partial(TS, normalization="gaussian", prior=prior), } logging.info(f"Evaluating {optimizer} on {task} with {num_seeds} seeds and {num_evaluations} evaluations.") Xys_train, (X_test, y_test) = evaluation_split_from_task(test_task=task) candidates = X_test blackbox = BlackboxOffline( X=X_test, y=y_test, ) X = np.vstack([X for X, _ in Xys_train] + [X_test]) bounds = np.vstack([X.min(axis=0), X.max(axis=0)]) optimizer_factory = partial( optimizers[optimizer], bounds=bounds, input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, evaluations_other_tasks=Xys_train, ) # (num_seeds, num_evaluations, dim) X, y = benchmark( optimizer_factory=optimizer_factory, blackbox=blackbox, candidates=candidates, num_seeds=num_seeds, num_evaluations=num_evaluations, verbose=False, ) # (num_seeds, num_evaluations,) y = y.squeeze(axis=-1) df = pd.DataFrame([ {"seed": seed, "iteration": iteration, "value": y[seed, iteration]} for seed in range(num_seeds) for iteration in range(num_evaluations) ]) df["blackbox"] = blackbox_from_task(task) df["task"] = task df["optimizer"] = optimizer df.to_csv(Path(output_folder) / "result.csv.zip", index=False) if __name__ == '__main__': logging.basicConfig(level=logging.INFO) parser = argparse.ArgumentParser() parser.add_argument('--task', type=str, required=True) parser.add_argument('--optimizer', type=str, required=True) parser.add_argument('--prior', type=str, default="sklearn") parser.add_argument('--num_seeds', type=int, default=30) parser.add_argument('--num_evaluations', type=int, default=100) parser.add_argument('--output_folder', type=str) args = parser.parse_args() if args.output_folder is not None: output_folder = args.output_folder else: output_folder = os.getenv("SLURMAKER_JOBPATH") assert output_folder is not None, \ "if you dont pass an output folder as argument, " \ "you must set it with SLURMAKER_JOBPATH environment variable" logging.info(f"evaluating: {args}") for key, val in args.__dict__.items(): logging.info(f"[{key}]:{val}") evaluate( task=args.task, optimizer=args.optimizer, num_seeds=args.num_seeds, num_evaluations=args.num_evaluations, output_folder=output_folder, prior=args.prior, )

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/figure_illustration.py

import seaborn as sns import matplotlib.pyplot as plt from pathlib import Path import pandas as pd import numpy as np from optimizer.normalization_transforms import GaussianTransform from blackbox.offline import evaluations_df, deepar df = evaluations_df(deepar) df = df[df.task.isin(["traffic", "electricity", "solar"])] df["hp_learning_rate"] = df.hp_learning_rate_log.apply(np.exp) df["hp_context_length_ratio"] = df.hp_context_length_ratio_log.apply(np.exp) df["hp_num_batches_per_epoch"] = df.hp_num_batches_per_epoch_log.apply(np.exp) #fig, axes = plt.subplots(1, 3) # plot learning rate vs CRPS #ax = sns.lmplot(x="hp_learning_rate", y="metric_CRPS", hue="task", data=df,) #ax = sns.scatterplot(data=df, x='hp_learning_rate', y='metric_CRPS', hue='task') #ax.set(xscale="log") #ax.set_xlabel("x (learning rate)") #ax.set_ylabel("y") height = 4 aspect = 1.2 ax = sns.lmplot( x="hp_learning_rate", y="metric_CRPS", hue="task", ci=None, data=df, height=height, aspect=aspect, legend_out=False, fit_reg=False ) ax.set(xscale="log", yscale="log") ax.ax.set_ylim(0.02,) ax.ax.set_xlabel("x (learning rate)") ax.ax.set_ylabel("y") plt.tight_layout() plt.savefig("y_plot.jpg") plt.show() # plot learning rate vs CRPS mapped through psi = Phi^{-1} o F for task in df.task.unique(): y = df.loc[df.loc[:, "task"] == task, "metric_CRPS"].values.reshape(-1, 1) z = GaussianTransform(y).transform(y) df.loc[df.loc[:, "task"] == task, "z"] = z.reshape(-1) #ax = sns.scatterplot(data=df, x='hp_learning_rate', y='z', hue='task') #ax.set_ylabel("z = Psi(y)") ax = sns.lmplot( x="hp_learning_rate", y="z", hue="task", legend=False, data=df, ci=None, height=height, aspect=aspect ) ax.set(xscale="log") ax.ax.set_xlabel("x (learning rate)") ax.ax.set_ylabel("z") plt.tight_layout() plt.savefig("z_plot.jpg") plt.show() ax = sns.lmplot( x="hp_learning_rate", y="z", hue="task", legend=False, data=df, ci=None, height=height, aspect=aspect, fit_reg=False, ) ax.set(xscale="log") ax.ax.set_xlabel("x (learning rate)") ax.ax.set_ylabel("z") plt.tight_layout() plt.savefig("z_scatter.jpg") plt.show()

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/load_results.py

from typing import Optional import pandas as pd from pathlib import Path from blackbox.offline import evaluations_df from blackbox.load_utils import error_metric path = Path(__file__).parent def postprocess_results(df): # keeps only 70 iteration for NAS and 100 for other blackboxes as described in the paper # in case where optimizer fails, we put their evaluation value to the maximum of the task (note that when computing # the rolling best, this is equivalent of forward filling with the best value observed) task_max = df.groupby('task').max()['value'] missing_mask = df.loc[:, "value"].isna() if sum(missing_mask) > 0: df.loc[missing_mask, 'value'] = df.loc[missing_mask, 'task'].apply(lambda task: task_max[task]) # only keep 100 iteration df = df[(df.iteration < 100) & (df.seed < 30)] # for NAS, not more than 70 iteration as explained in the paper df = df[(df.blackbox != "nas_bench102") | (df.iteration < 70)] return df def min_max_tasks(): """ :return: two series mapping task name to min and max respectively. """ res = [] for bb, metric in error_metric.items(): offline_evals = evaluations_df(bb) res.append(offline_evals.groupby('task').agg(['min', 'max'])[metric]) y_min = pd.concat([x['min'] for x in res]) y_max = pd.concat([x['max'] for x in res]) return y_min, y_max def add_adtm(df): """ :param df: :return: dataframe with a column ADTM added measuring (best - min_task) / (max_task - min_task) """ df.loc[:, 'best'] = df.groupby(['task', 'optimizer', 'seed']).cummin().loc[:, 'value'] y_min, y_max = min_max_tasks() df = df.join(other=y_min, on='task', lsuffix='dataset_') df = df.join(other=y_max, on='task', lsuffix='dataset_') df.loc[:, "ADTM"] = (df.loc[:, "best"] - df.loc[:, "min"]) / (df.loc[:, "max"] - df.loc[:, "min"]) return df def load_results(file): df = pd.read_csv(file) df = postprocess_results(df) return df def load_results_paper(do_add_adtm: bool = True): df = load_results(path / "results_paper.csv.zip") if do_add_adtm: df = add_adtm(df) return df def load_results_reimplem(filename: str = "results_reimplem.csv.zip"): return load_results(path / filename)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/figure2.py

from pathlib import Path from typing import List import pandas as pd import matplotlib.pyplot as plt import os import numpy as np from experiments.load_results import load_results_paper from experiments.optimizer_names import names from experiments.optimizer_styles import optimizer_style from experiments.table2 import adtm_scores path = Path(__file__).parent def plot_per_task(scores_per_task: pd.DataFrame, optimizers_to_plot: List[str]): import seaborn as sns from matplotlib.patches import Patch sns.set() sns.set_style("white") # load RMSEs from csv rmses = pd.read_csv( Path(__file__).parent / 'rmse.csv', header=None, names=['task', 'rmse'] ).set_index('task')['rmse'] # show task in x, ADTM improvement over RS on the y-axis cols = {'rmse': rmses} for method in optimizers_to_plot: cols[method] = scores_per_task[method].reset_index()[['task', method]].set_index('task')[method] dd = pd.DataFrame(cols).sort_values(by='rmse').reset_index().rename(columns={'index': 'task'}) dd['task_and_rmse'] = dd.apply(lambda x: f"{x.task} (%.2f)" % x.rmse, axis=1) styles, colors = zip(*[optimizer_style(method) for method in optimizers_to_plot]) hatches = tuple(['///' if 'Copula' in m else None for m in optimizers_to_plot]) fig, axes = plt.subplots(3, 9, figsize=(20, 5), sharex=True, sharey='row') axes = np.ravel(axes) for i, row in dd.iterrows(): y = [row[m] for m in optimizers_to_plot] bars = axes[i].bar(x=range(len(colors)), height=y, color=colors, label=optimizers_to_plot) for bar, h in zip(bars, hatches): bar.set_hatch(h) axes[i].set_xlabel(row['task_and_rmse'], fontsize=14) axes[i].set_ylim([-1, 1]) # plot legend on the last subplots custom_lines = [] for c, h in zip(colors, hatches): p = Patch(facecolor=c, hatch=h) custom_lines.append(p) axes[-1].spines['right'].set_visible(False) axes[-1].spines['top'].set_visible(False) axes[-1].spines['left'].set_visible(False) axes[-1].spines['bottom'].set_visible(False) axes[-1].legend(custom_lines, optimizers_to_plot, fontsize=10, loc='center') plt.subplots_adjust(wspace=0.0) plt.xticks([], []) plt.tight_layout(h_pad=0, w_pad=0) filename = Path(__file__).parent / f'hpo/figures/ADTM_per_task.pdf' os.makedirs(filename.parent, exist_ok=True) print(filename) plt.savefig(str(filename)) plt.show() if __name__ == '__main__': df_paper = load_results_paper() optimizers_to_plot = [ names.GCP_prior, names.CTS_prior, names.WS_BEST, names.AUTORANGE_GP, names.ABLR, names.ABLR_COPULA, names.SGPT, names.SGPT_COPULA, ] scores_per_blackbox, scores_per_task = adtm_scores(df_paper, optimizers_to_plot) plot_per_task(scores_per_task=scores_per_task, optimizers_to_plot=optimizers_to_plot)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/optimizer_names.py

class names: # put names into a class to add structure and avoid having lots of imports RS = "RS" # ablation GP = "GP" GCP_ho_prior = "GCP + homosk. prior" GCP = "GCP" GCP_prior = "GCP + prior (ours)" GP_prior = "GP + prior" CTS_ho_prior = "CTS + homosk. prior" CTS_prior = "CTS (ours)" TS_prior = "TS" GP_prior = "GP + prior" # multi-objectives MO_suffix = " + MO" GP_prior_mo = GP_prior + MO_suffix GP_mo = GP + MO_suffix GCP_prior_mo = "GCP + prior" + MO_suffix + " (ours)" GCP_mo = GCP + MO_suffix CTS_prior_mo = "CTS + prior" + MO_suffix + " (ours)" TS_prior_mo = TS_prior + MO_suffix # baselines WS_BEST = 'WS GP' AUTORANGE_GP = "AutoGP" AUTORANGE_RS = "AutoRS" BOHB = 'BOHB' REA = 'R-EA' REINFORCE = 'REINFORCE' ABLR = "ABLR" ABLR_COPULA = 'ABLR Copula' SGPT = "SGPT" SGPT_COPULA = "SGPT Copula" EHI = "EHI" SMS = "SMS" SUR = "SUR" EMI = "EMI" def method_name(dataset_name): for prefix in ["fcnet", "xgboost"]: if prefix in dataset_name: return prefix if 'nas102' in dataset_name: return 'NAS' return "DeepAR" def rename_results(df): rename_dict = { 'ablr_norm_fixed_set_tr': names.ABLR, 'ablr_copula': names.ABLR_COPULA, 'copula_gp_1_5_random_fix_sigma_5_tr': names.GCP_ho_prior, 'copula_gp_1_5_random_pred_sigma_5_tr': names.GCP_prior, 'copula_gp_1_5_random_pred_sigma_std_5_tr': names.GP_prior, 'copula_rs_1_fix_sigma_tr': names.CTS_ho_prior, 'copula_rs_1_pred_sigma_std_tr': names.TS_prior, 'copula_rs_1_pred_sigma_tr': names.CTS_prior, 'gp_fixed_set_tr': names.GP, 'random_fixed_set_tr': names.RS, 'warm-start-gp-top1-1init': names.WS_BEST, 'auto-range-gp': names.AUTORANGE_GP, 'copula_gp_no_proir': names.GCP, 'sgpt_0.01': names.SGPT, #'sgpt_0.10': names.SGPT_010, #'sgpt_1.00': names.SGPT_100, 'sgpt_0.01_copula': names.SGPT_COPULA } df.method = df.method.apply(lambda name: rename_dict[name] if name in rename_dict else "") df = df.loc[df.method != "", :] df.dataset = df.dataset.apply( lambda name: name.replace("xgboost_", "") .replace("_max_resource", "") .replace("fcnet_", "") .replace("nas102_", "") .replace("_lookup", "") ) df = df[df.dataset != 'skin_nonskin'] return df

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/table2.py

from typing import List, Optional import pandas as pd import numpy as np from pathlib import Path from blackbox.offline import deepar, fcnet, xgboost, nas102 from experiments.load_results import load_results_paper from experiments.optimizer_names import names path = Path(__file__).parent def adtm_scores(df, optimizers_to_plot = None, baseline: Optional[str] = "RS"): # return adtm table per blackbox and per dataset scores_df = df.groupby(["blackbox", "task", "optimizer", "iteration"])[ "ADTM" ].mean().reset_index().pivot_table( values='ADTM', columns=['optimizer'], index=['blackbox', 'task', 'iteration'], ) rel_scores = (scores_df[[baseline]].values - scores_df.values) / scores_df[[baseline]].values rel_scores_df = pd.DataFrame(rel_scores, index=scores_df.index, columns=scores_df.columns).reset_index( level=2).drop( columns='iteration') scores_per_task = rel_scores_df.groupby(['blackbox', 'task']).mean() avg_scores_per_blackbox = rel_scores_df.groupby(['blackbox']).mean() if optimizers_to_plot is not None: avg_scores_per_blackbox = avg_scores_per_blackbox[optimizers_to_plot] scores_per_task = scores_per_task[optimizers_to_plot] scores_per_blackbox = avg_scores_per_blackbox.T[["DeepAR", "FCNET", "XGBoost", "nas_bench102"]] return scores_per_blackbox, scores_per_task def rank(scores_per_task: pd.DataFrame, blackboxes: List[str]): ranks = {} for b in blackboxes: ranks[b] = scores_per_task.transpose()[b].rank(ascending=False).mean(axis=1) return pd.DataFrame(ranks) if __name__ == '__main__': df_paper = load_results_paper() print(df_paper.head()) baseline = names.RS renamed_baseline = f"{names.RS} (baseline)" df_paper.optimizer = df_paper.optimizer.apply(lambda name: renamed_baseline if name == baseline else name) optimizers_to_plot = [ renamed_baseline, names.TS_prior, names.CTS_prior, names.GP_prior, names.GCP, names.GCP_prior, names.GP, names.AUTORANGE_GP, names.WS_BEST, names.ABLR, names.ABLR_COPULA, names.SGPT, names.SGPT_COPULA, names.BOHB, names.REA, names.REINFORCE, ] scores_per_blackbox, scores_per_task = adtm_scores( df_paper, optimizers_to_plot, baseline=renamed_baseline, ) print(scores_per_blackbox.to_string()) print(scores_per_blackbox.to_latex(float_format='%.2f', na_rep='-')) rank_df = rank(scores_per_task=scores_per_task, blackboxes=[deepar, fcnet, xgboost, nas102]) print(rank_df.to_string()) print(rank_df.to_latex(float_format='%.1f', na_rep='-')) # generates "dtm (rank)" numbers dataframe so that it can be exported easily in latex dtm_and_rank_values = [] for x, y in zip(scores_per_blackbox.values.reshape(-1), rank_df.values.reshape(-1)): dtm_and_rank_values.append("{:.2f}".format(x) + " (" + "{:.1f}".format(y) + ")") dtm_and_rank = pd.DataFrame( np.array(dtm_and_rank_values).reshape(rank_df.shape), index=rank_df.index, columns=rank_df.columns ) print(dtm_and_rank.to_latex())

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/__init__.py

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/table2-new-implem.py

import os import pandas as pd from pathlib import Path from experiments.load_results import load_results_paper, load_results_reimplem, add_adtm from experiments.optimizer_names import names from experiments.table2 import adtm_scores, rank path = Path(__file__).parent if __name__ == '__main__': df_paper = load_results_paper(do_add_adtm=False) df_reimplem = load_results_reimplem() df = pd.concat([df_paper, df_reimplem], sort=False) print(df.optimizer.unique()) optimizers_to_plot = [ "RS", names.CTS_prior, "CTS (sklearn)", "CTS (pytorch)", names.GCP_prior, "GCP+prior (sklearn)", "GCP+prior (pytorch)", ] df = add_adtm(df) scores_per_blackbox, scores_per_task = adtm_scores(df, optimizers_to_plot) print(scores_per_blackbox.to_string()) print(scores_per_blackbox.to_latex(float_format='%.2f', na_rep='-'))

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/experiments/figure1.py

from pathlib import Path import matplotlib.pyplot as plt from blackbox.offline import deepar, fcnet, xgboost, nas102 from experiments.load_results import load_results_paper from experiments.optimizer_names import names from experiments.optimizer_styles import optimizer_style path = Path(__file__).parent def plot_optimizers(df, ax, blackbox, optimizers, legend: bool = False): df_plot = df.loc[df.optimizer.isin(optimizers), :] pivot_df = df_plot.loc[df_plot.blackbox == blackbox, :].groupby( ['blackbox', 'optimizer', 'iteration'] )['ADTM'].mean().reset_index().pivot_table( index='iteration', columns='optimizer', values='ADTM' ).dropna() # reorder optimizers to original list order optimizers = [m for m in optimizers if m in pivot_df] style, color = zip(*[optimizer_style(optimizer) for optimizer in optimizers]) pivot_df[optimizers].plot( ax=ax, title=blackbox, color=list(color), style=[a + b for a, b in style], # marker=list(marker), markevery=20, alpha=0.8, lw=2.5, ) ax.grid() if blackbox == 'DeepAR': ax.set_ylim([None, 1e-2]) if blackbox == 'fcnet': ax.set_ylim([None, 0.3]) if blackbox == 'xgboost': ax.set_ylim([1e-2, 0.3]) if blackbox == 'NAS': ax.set_xlim([None, 65]) # ax.set_ylim([0.001, None]) ax.set_yscale('log') ax.set_ylabel('ADTM') if not legend: ax.get_legend().remove() else: ax.legend(loc="upper right") if __name__ == '__main__': df = load_results_paper() blackboxes = [deepar, fcnet, xgboost, nas102] optimizers_to_plot = [ [ names.RS, names.GP, names.AUTORANGE_GP, names.WS_BEST, names.ABLR, names.CTS_prior, names.GCP_prior, # 'BOHB', 'R-EA', 'REINFORCE', ], [ names.GP, names.GP_prior, names.GCP, names.GCP_prior, names.TS_prior, names.CTS_prior, ] ] fig, axes = plt.subplots(4, 2, figsize=(10, 12), sharex='row', sharey='row') for i, blackbox in enumerate(blackboxes): for j, optimizers in enumerate(optimizers_to_plot): plot_optimizers(df, blackbox=blackbox, ax=axes[i, j], optimizers=optimizers, legend=(i == 0)) plt.savefig("adtm.pdf") plt.show()

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/benchmark.py

import gc import logging import sys import traceback from typing import Tuple, Callable import numpy as np from tqdm import tqdm from blackbox import Blackbox from misc import set_seed from optimizer import Optimizer def benchmark( num_evaluations: int, optimizer_factory: Callable[[], Optimizer], blackbox: Blackbox, candidates: np.array, num_seeds: int, verbose: bool = False, ) -> Tuple[np.array]: """ For each seed, the optimizer is run 'num_evaluations'. :param num_evaluations: :param optimizer_factory: :param blackbox: :param candidates: :param num_seeds: :param verbose: :return: two tensors of shape (num_seeds, num_evaluations, X) where X = [input_dim, output_dim] """ seeds = range(num_seeds) #if verbose: # seeds = tqdm(seeds) seeds = tqdm(seeds) Xs = np.empty((num_seeds, num_evaluations, blackbox.input_dim)) Xs[:] = np.nan ys = np.empty((num_seeds, num_evaluations, blackbox.output_dim)) ys[:] = np.nan for seed in seeds: try: set_seed(seed) optimizer = optimizer_factory() for i in range(num_evaluations): x = optimizer.sample(candidates) y = blackbox(x) if verbose: logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y) Xs[seed, i] = x ys[seed, i] = y # memory leaks without gc, not sure why, perhaps a reference cycle gc.collect() del optimizer except Exception: print("seed evaluation failed") traceback.print_exc(file=sys.stdout) pass return Xs, ys

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/gaussian_process_functional_prior.py

from typing import Optional, Tuple, Callable, Union, List import logging import numpy as np import torch from gpytorch import ExactMarginalLogLikelihood from gpytorch.constraints import GreaterThan from gpytorch.likelihoods import GaussianLikelihood from torch import Tensor from torch.distributions import Normal from botorch import fit_gpytorch_model from botorch.acquisition import ExpectedImprovement, ScalarizedObjective from botorch.models import SingleTaskGP from botorch.models.model import Model from botorch.optim import optimize_acqf from botorch.utils.transforms import t_batch_mode_transform from blackbox import Blackbox from constants import num_gradient_updates from misc.artificial_data import artificial_task1 from optimizer.gaussian_process import GP from optimizer.thompson_sampling_functional_prior import TS def residual_transform(y, mu_pred, sigma_pred): return (y - mu_pred) / sigma_pred def residual_transform_inv(z, mu_pred, sigma_pred): return z * sigma_pred + mu_pred def scale_posterior(mu_posterior, sigma_posterior, mu_est, sigma_est): mean = mu_posterior * sigma_est + mu_est sigma = (sigma_posterior * sigma_est) return mean, sigma class ShiftedExpectedImprovement(ExpectedImprovement): """ Applies ExpectedImprovement taking care to shift residual posterior with the predicted prior mean and variance :param model: :param best_f: best value observed (not residual but actual value) :param mean_std_predictor: :param objective: :param maximize: """ def __init__( self, model: Model, best_f: Union[float, Tensor], mean_std_predictor: Callable[[np.array], Tuple[np.array, np.array]], objective: Optional[ScalarizedObjective] = None, maximize: bool = True, ) -> None: super(ShiftedExpectedImprovement, self).__init__(model=model, best_f=best_f, objective=objective, maximize=maximize) self.mean_std_predictor = mean_std_predictor @t_batch_mode_transform(expected_q=1) def forward(self, X: Tensor) -> Tensor: """ :param X: A (..., 1, input_dim) batched tensor of input_dim design points. Expected Improvement is computed for each point individually, i.e., what is considered are the marginal posteriors, not the joint. :return: A (...) tensor of Expected Improvement values at the given design points `X`. """ with torch.no_grad(): # both (..., 1,) # (..., input_dim) X_features = X.detach().numpy().squeeze(1) mu_est, sigma_est = self.mean_std_predictor(X_features) # both (..., 1, 1) mu_est = torch.Tensor(mu_est).unsqueeze(1) sigma_est = torch.Tensor(sigma_est).unsqueeze(1) posterior = self._get_posterior(X=X) mean, sigma = scale_posterior( mu_posterior=posterior.mean, sigma_posterior=posterior.variance.clamp_min(1e-6).sqrt(), mu_est=mu_est, sigma_est=sigma_est, ) u = (mean - self.best_f.expand_as(mean)) / sigma if not self.maximize: u = -u normal = Normal(torch.zeros_like(u), torch.ones_like(u)) ucdf = normal.cdf(u) updf = torch.exp(normal.log_prob(u)) ei = sigma * (updf + u * ucdf) return ei.squeeze(dim=-1).squeeze(dim=-1) class ShiftedThompsonSampling(ExpectedImprovement): """ Applies Thompson sampling taking care to shift residual posterior with the predicted prior mean and variance :param model: :param best_f: :param mean_std_predictor: :param objective: :param maximize: """ def __init__( self, model: Model, best_f: Union[float, Tensor], mean_std_predictor: Callable[[np.array], Tuple[np.array, np.array]], objective: Optional[ScalarizedObjective] = None, maximize: bool = True, ) -> None: super(ShiftedThompsonSampling, self).__init__(model=model, best_f=best_f, objective=objective, maximize=maximize) self.mean_std_predictor = mean_std_predictor @t_batch_mode_transform(expected_q=1) def forward(self, X: Tensor) -> Tensor: """ :param X: A `... x 1 x d`-dim batched tensor of `d`-dim design points. Expected Improvement is computed for each point individually, i.e., what is considered are the marginal posteriors, not the joint. :return: A `...` tensor of Expected Improvement values at the given design points `X`. """ with torch.no_grad(): # both (..., 1,) mu_est, sigma_est = self.mean_std_predictor(X) posterior = self._get_posterior(X=X) mean, sigma = scale_posterior( mu_posterior=posterior.mean, sigma_posterior=posterior.variance.clamp_min(1e-9).sqrt(), mu_est=mu_est, sigma_est=sigma_est, ) normal = Normal(torch.zeros_like(mean), torch.ones_like(mean)) u = normal.sample() * sigma + mean if not self.maximize: u = -u return u.squeeze(dim=-1).squeeze(dim=-1) class G3P(GP): def __init__( self, input_dim: int, output_dim: int, bounds: Optional[np.array] = None, evaluations_other_tasks: Optional[List[Tuple[np.array, np.array]]] = None, num_gradient_updates: int = num_gradient_updates, normalization: str = "standard", prior: str = "pytorch", ): super(G3P, self).__init__( input_dim=input_dim, output_dim=output_dim, bounds=bounds, normalization=normalization, ) self.initial_sampler = TS( input_dim=input_dim, output_dim=output_dim, evaluations_other_tasks=evaluations_other_tasks, num_gradient_updates=num_gradient_updates, normalization=normalization, prior=prior, ) def _sample(self, candidates: Optional[np.array] = None) -> np.array: if len(self.X_observed) < self.num_initial_random_draws: return self.initial_sampler.sample(candidates=candidates) else: z_observed = torch.Tensor(self.transform_outputs(self.y_observed.numpy())) with torch.no_grad(): # both (n, 1) #mu_pred, sigma_pred = self.thompson_sampling.prior(self.X_observed) mu_pred, sigma_pred = self.initial_sampler.prior.predict(self.X_observed) mu_pred = torch.Tensor(mu_pred) sigma_pred = torch.Tensor(sigma_pred) # (n, 1) r_observed = residual_transform(z_observed, mu_pred, sigma_pred) # build and fit GP on residuals gp = SingleTaskGP( train_X=self.X_observed, train_Y=r_observed, likelihood=GaussianLikelihood(noise_constraint=GreaterThan(1e-3)), ) mll = ExactMarginalLogLikelihood(gp.likelihood, gp) fit_gpytorch_model(mll) acq = ShiftedExpectedImprovement( model=gp, best_f=z_observed.min(dim=0).values, mean_std_predictor=self.initial_sampler.prior.predict, maximize=False, ) if candidates is None: candidate, acq_value = optimize_acqf( acq, bounds=self.bounds_tensor, q=1, num_restarts=5, raw_samples=100, ) # import matplotlib.pyplot as plt # x = torch.linspace(-1, 1).unsqueeze(dim=-1) # x = torch.cat((x, x * 0), dim=1) # plt.plot(x[:, 0].flatten().tolist(), acq(x.unsqueeze(dim=1)).tolist()) # plt.show() return candidate[0] else: # (N,) ei = acq(torch.Tensor(candidates).unsqueeze(dim=-2)) return torch.Tensor(candidates[ei.argmax()]) if __name__ == '__main__': logging.basicConfig(level=logging.INFO) num_evaluations = 10 Xy_train, X_test, y_test = artificial_task1() blackbox = Blackbox( input_dim=2, output_dim=1, eval_fun=lambda x: x.sum(axis=-1, keepdims=True), ) optimizer = G3P( input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, evaluations_other_tasks=Xy_train, num_gradient_updates=2, ) candidates = X_test for i in range(num_evaluations): x = optimizer.sample(candidates) #x = optimizer.sample() y = blackbox(x) logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/thompson_sampling_functional_prior.py

import logging from typing import Optional, List, Tuple import numpy as np from constants import num_gradient_updates from optimizer import Optimizer from optimizer.normalization_transforms import from_string from optimizer.random_search import RS from prior.mlp_pytorch import ParametricPrior from prior.mlp_sklearn import ParametricPriorSklearn class TS(Optimizer): def __init__( self, input_dim: int, output_dim: int, bounds: Optional[np.array] = None, evaluations_other_tasks: Optional[List[Tuple[np.array, np.array]]] = None, num_gradient_updates: int = num_gradient_updates, normalization: str = "standard", prior: str = "pytorch", ): super(TS, self).__init__( input_dim=input_dim, output_dim=output_dim, evaluations_other_tasks=evaluations_other_tasks, bounds=bounds, ) # todo add option for data transform assert evaluations_other_tasks is not None X_train = np.concatenate([X for X, y in evaluations_other_tasks], axis=0) normalizer = from_string(normalization) z_train = np.concatenate([normalizer(y).transform(y) for X, y in evaluations_other_tasks], axis=0) prior_dict = { "sklearn": ParametricPriorSklearn, "pytorch": ParametricPrior, } logging.info(f"fit prior {prior}") self.prior = prior_dict[prior]( X_train=X_train, y_train=z_train, num_gradient_updates=num_gradient_updates, ) logging.info("prior fitted") def _sample(self, candidates: Optional[np.array] = None) -> np.array: if candidates is None: num_random_candidates = 10000 # since Thompson Sampling selects from discrete set of options, # when no candidates are given we draw random candidates candidates = self.draw_random_candidates(num_random_candidates) mu_pred, sigma_pred = self.prior.predict(candidates) samples = np.random.normal(loc=mu_pred, scale=sigma_pred) return candidates[np.argmin(samples)] def draw_random_candidates(self, num_random_candidates: int): random_sampler = RS( input_dim=self.input_dim, output_dim=self.output_dim, bounds=self.bounds, ) candidates = np.stack([random_sampler.sample() for _ in range(num_random_candidates)]) return candidates

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/gaussian_process.py

import logging from typing import Optional import numpy as np import torch from botorch import fit_gpytorch_model from botorch.acquisition import ExpectedImprovement from botorch.models import SingleTaskGP from botorch.optim import optimize_acqf from botorch.utils.transforms import normalize from gpytorch import ExactMarginalLogLikelihood from gpytorch.constraints import GreaterThan from gpytorch.likelihoods import GaussianLikelihood from blackbox import Blackbox, BlackboxOffline from constants import num_initial_random_draws from misc import set_seed from misc.artificial_data import artificial_task1 from optimizer import Optimizer from optimizer.normalization_transforms import from_string from optimizer.random_search import RS class GP(Optimizer): def __init__( self, input_dim: int, output_dim: int, bounds: Optional[np.array] = None, normalization: str = "standard", evaluations_other_tasks=None, ): super(GP, self).__init__( input_dim=input_dim, output_dim=output_dim, evaluations_other_tasks=evaluations_other_tasks, bounds=bounds, ) # maintains observations # (num_observations, input_dim) self.X_observed = torch.empty(size=(0, input_dim)) # (num_observations, output_dim) self.y_observed = torch.empty(size=(0, output_dim)) self.num_initial_random_draws = num_initial_random_draws self.normalizer = from_string(normalization) self.initial_sampler = RS( input_dim=input_dim, output_dim=output_dim, bounds=bounds, ) self.bounds_tensor = torch.Tensor(self.bounds) def expected_improvement(self, model, best_f): return ExpectedImprovement( model=model, best_f=best_f, maximize=False, ) def transform_outputs(self, y: np.array): psi = self.normalizer(y) z = psi.transform(y) return z def _sample(self, candidates: Optional[np.array] = None) -> np.array: if len(self.X_observed) < self.num_initial_random_draws: return self.initial_sampler.sample(candidates=candidates) else: z_observed = torch.Tensor(self.transform_outputs(self.y_observed.numpy())) # build and fit GP gp = SingleTaskGP( train_X=self.X_observed, train_Y=z_observed, # special likelihood for numerical Cholesky errors, following advice from # https://www.gitmemory.com/issue/pytorch/botorch/179/506276521 likelihood=GaussianLikelihood(noise_constraint=GreaterThan(1e-3)), ) mll = ExactMarginalLogLikelihood(gp.likelihood, gp) fit_gpytorch_model(mll) acq = self.expected_improvement( model=gp, best_f=z_observed.min(dim=0).values, ) if candidates is None: candidate, acq_value = optimize_acqf( acq, bounds=self.bounds_tensor, q=1, num_restarts=5, raw_samples=100, ) return candidate[0] else: # (N,) ei = acq(torch.Tensor(candidates).unsqueeze(dim=-2)) return torch.Tensor(candidates[ei.argmax()]) def _observe(self, x: np.array, y: np.array): # remark, we could fit the GP there so that sampling several times avoid the cost of refitting the GP self.X_observed = torch.cat((self.X_observed, torch.Tensor(x).unsqueeze(dim=0)), dim=0) self.y_observed = torch.cat((self.y_observed, torch.Tensor(y).unsqueeze(dim=0)), dim=0) if __name__ == '__main__': logging.basicConfig(level=logging.INFO) num_evaluations = 10 Xy_train, X_test, y_test = artificial_task1(seed=0) print(y_test[0]) set_seed(0) blackbox = BlackboxOffline( X=X_test, y=y_test, ) optimizer = GP( input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, ) candidates = X_test for i in range(num_evaluations): #x = optimizer.sample(candidates) x = optimizer.sample() y = blackbox(x) logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/__init__.py

from typing import Optional, Tuple, List import numpy as np class Optimizer: def __init__( self, input_dim: int, output_dim: int, bounds: Optional[np.array] = None, evaluations_other_tasks: Optional[List[Tuple[np.array, np.array]]] = None, ): """ :param input_dim: input dimensions of blackbox arguments :param output_dim: output dimensions of blackbox output :param bounds: bounds on the space to sample with shape (2, input_dim), if not specified all coordinates are constrained to [-1, 1] :param evaluations_other_tasks: List of tuple X, y with shape (num_evaluations, input_dim) and (num_evaluations, output_dim). We pass as a separate list as the optimizer may need to group evaluations, for instance for normalizing the data. :param candidates: """ self.input_dim = input_dim self.output_dim = output_dim if bounds is None: self.bounds = np.stack([ np.ones(input_dim) * -1, np.ones(input_dim) ]) else: self.bounds = bounds assert self.bounds.shape == (2, input_dim) if evaluations_other_tasks is not None: self.num_tasks = len(evaluations_other_tasks) for X, y in evaluations_other_tasks: assert len(X) == len(y) assert X.shape[1] == input_dim assert y.shape[1] == output_dim def sample(self, candidates: Optional[np.array] = None) -> np.array: """ :param candidates: optionally a list of candidates when performing constrained search todo ensure that sampling happens inside this range :return: sample point with shape (input_dim,) """ if candidates is not None: assert candidates.shape[1] == self.input_dim x = self._sample(candidates) assert x.shape == (self.input_dim,) return x def _sample(self, candidates: Optional[np.array] = None) -> np.array: return "override me" def observe(self, x: np.array, y: np.array): """ Update the state after seeing an observation :param x: shape (input_dim,) :param y: shape (output_dim,) """ assert x.shape == (self.input_dim,) assert y.shape == (self.output_dim,) self._observe(x, y) def _observe(self, x: np.array, y: np.array): pass

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/normalization_transforms.py

import numpy as np from scipy import stats class GaussianTransform: """ Transform data into Gaussian by applying psi = Phi^{-1} o F where F is the truncated ECDF. :param y: shape (n, dim) """ def __init__(self, y: np.array): assert y.ndim == 2 self.dim = y.shape[1] self.sorted = y.copy() self.sorted.sort(axis=0) @staticmethod def z_transform(series, values_sorted=None): # applies truncated ECDF then inverse Gaussian CDF. if values_sorted is None: values_sorted = sorted(series) def winsorized_delta(n): return 1.0 / (4.0 * n ** 0.25 * np.sqrt(np.pi * np.log(n))) delta = winsorized_delta(len(series)) def quantile(values_sorted, values_to_insert, delta): res = np.searchsorted(values_sorted, values_to_insert) / len(values_sorted) return np.clip(res, a_min=delta, a_max=1 - delta) quantiles = quantile( values_sorted, series, delta ) quantiles = np.clip(quantiles, a_min=delta, a_max=1 - delta) return stats.norm.ppf(quantiles) def transform(self, y: np.array): """ :param y: shape (n, dim) :return: shape (n, dim), distributed along a normal """ assert y.shape[1] == self.dim # compute truncated quantile, apply gaussian inv cdf return np.stack([ self.z_transform(y[:, i], self.sorted[:, i]) for i in range(self.dim) ]).T class StandardTransform: def __init__(self, y: np.array): assert y.ndim == 2 self.dim = y.shape[1] self.mean = y.mean(axis=0, keepdims=True) self.std = y.std(axis=0, keepdims=True) def transform(self, y: np.array): z = (y - self.mean) / np.clip(self.std, a_min=0.001, a_max=None) return z def from_string(name: str): assert name in ["standard", "gaussian"] mapping = { "standard": StandardTransform, "gaussian": GaussianTransform, } return mapping[name]

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/optimizer/random_search.py

from typing import Optional, List, Tuple import numpy as np from optimizer import Optimizer class RS(Optimizer): def __init__( self, input_dim: int, output_dim: int, bounds: Optional[np.array] = None, evaluations_other_tasks: Optional[List[Tuple[np.array, np.array]]] = None, ): super(RS, self).__init__( input_dim=input_dim, output_dim=output_dim, bounds=bounds, evaluations_other_tasks=evaluations_other_tasks, ) def _sample(self, candidates: Optional[np.array] = None) -> np.array: # if candidates are given, then pick a random one, else draw uniformly from domain if candidates is not None: return candidates[np.random.randint(low=0, high=len(candidates))] else: a, b = self.bounds random_draw = (b - a) * np.random.random(self.input_dim, ) + a return random_draw

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/blackbox/offline.py

from pathlib import Path import pandas as pd import numpy as np deepar = 'DeepAR' fcnet = 'FCNET' xgboost = 'XGBoost' nas102 = 'nas_bench102' metric_error = 'metric_error' metric_time = 'metric_time' def evaluations_df(blackbox: str) -> pd.DataFrame: """ :returns a dataframe where each row corresponds to one hyperparameter evaluated for one task. The hyperparamers columns are all prefixed by 'hp_', the metric columns (error, time, etc) are prefixed by 'metric_' and dataset information are prefixed by 'dataset_' (only available for DeepAR). Two columns 'task' and 'blackbox' contains the name of the task and of the blackbox. ## DeepAR Hyperparameters: * num_layers * num_cells * context_length_ratio, context_length_ratio = context_length / prediction_length * dropout_rate * learning_rate * num_batches_per_epoch Constants: * epochs = 100 * early_stopping_patience = 5 Dataset specific: * time_freq * prediction_length Metrics: * CRPS * train_loss * throughput * RMSE ## FCNET """ assert blackbox in [deepar, fcnet, xgboost, nas102] df = pd.read_csv(Path(__file__).parent / f"offline_evaluations/{blackbox}.csv.zip") return df if __name__ == '__main__': df = evaluations_df(deepar) import seaborn as sns import matplotlib.pyplot as plt df["hp_learning_rate"] = df.hp_learning_rate_log.apply(np.exp) df["hp_context_length_ratio"] = df.hp_context_length_ratio_log.apply(np.exp) df["hp_num_batches_per_epoch"] = df.hp_num_batches_per_epoch_log.apply(np.exp) ax = sns.scatterplot(data=df, x='hp_learning_rate', y='metric_CRPS', hue='task') plt.show() ax = sns.scatterplot(data=df, x='hp_learning_rate', y='metric_CRPS', hue='task') ax.set(xscale="log", yscale="log") plt.show() ax = sns.scatterplot(data=df, x='hp_context_length_ratio', y='metric_CRPS', hue='task') ax.set(yscale="log") plt.show() ax = sns.scatterplot(data=df, x='hp_num_batches_per_epoch', y='metric_time', hue='task') ax.set(xscale="log", yscale="log") plt.show()

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/blackbox/load_utils.py

import logging from typing import Tuple, List import numpy as np from blackbox.offline import evaluations_df, deepar, fcnet, nas102, xgboost blackbox_tasks = { nas102: [ 'cifar10', 'cifar100', 'ImageNet16-120' ], fcnet: [ 'naval', 'parkinsons', 'protein', 'slice', ], deepar: [ 'm4-Hourly', 'm4-Daily', 'm4-Weekly', 'm4-Monthly', 'm4-Quarterly', 'm4-Yearly', 'electricity', 'exchange-rate', 'solar', 'traffic', ], xgboost: [ 'a6a', 'australian', 'german.numer', 'heart', 'ijcnn1', 'madelon', 'skin_nonskin', 'spambase', 'svmguide1', 'w6a' ], } error_metric = { deepar: 'metric_CRPS', fcnet: 'metric_error', nas102: 'metric_error', xgboost: 'metric_error', } tasks = [task for bb, tasks in blackbox_tasks.items() for task in tasks] def evaluations_np( blackbox: str, test_task: str, metric_cols: List[str], min_max_features: bool = False ) -> Tuple[List[Tuple[np.array, np.array]], Tuple[np.array, np.array]] : """ :param blackbox: :param test_task: :param metric_cols: :param min_max_features: whether to apply min-max scaling on input features :return: list of features/evaluations on train task and features/evaluations of the test task. """ logging.info(f"retrieving metrics {metric_cols} of blackbox {blackbox} for test-task {test_task}") df = evaluations_df(blackbox=blackbox) assert test_task in df.task.unique() for c in metric_cols: assert c in df.columns Xy_dict = {} for task in sorted(df.task.unique()): mask = df.loc[:, 'task'] == task hp_cols = [c for c in sorted(df.columns) if c.startswith("hp_")] X = df.loc[mask, hp_cols].values y = df.loc[mask, metric_cols].values Xy_dict[task] = X, y # todo it would be better done as a post-processing step if blackbox in [fcnet, nas102]: # applies onehot encoding to *all* hp columns as all hps are categories for those two blackboxes # it would be nice to detect column types or pass it as an argument from sklearn.preprocessing import OneHotEncoder enc = OneHotEncoder(handle_unknown='ignore', sparse=False) hp_cols = [c for c in sorted(df.columns) if c.startswith("hp_")] enc.fit(df.loc[:, hp_cols]) for task, (X, y) in Xy_dict.items(): X_features = enc.transform(X) Xy_dict[task] = X_features, y if min_max_features: # min-max scaling of input features from sklearn.preprocessing import MinMaxScaler X = np.vstack([X for (X, y) in Xy_dict.values()]) scaler = MinMaxScaler().fit(X) Xy_dict = {t: (scaler.transform(X), y) for (t, (X, y)) in Xy_dict.items()} Xys_train = [Xy_dict[t] for t in df.task.unique() if t != test_task] Xy_test = Xy_dict[test_task] return Xys_train, Xy_test def blackbox_from_task(task: str) -> str: for bb, tasks in blackbox_tasks.items(): if task in tasks: return bb assert f"unknown task {task}" def evaluation_split_from_task(test_task: str, min_max_features: bool = True) -> Tuple[np.array, np.array]: """ :param test_task: :param min_max_features: whether inputs are maped to [0, 1] with min-max scaling :return: list of features/evaluations on train task and features/evaluations of the test task. """ blackbox = blackbox_from_task(test_task) Xys_train, Xy_test = evaluations_np( blackbox=blackbox, test_task=test_task, metric_cols=[error_metric[blackbox]], min_max_features=min_max_features ) return Xys_train, Xy_test if __name__ == '__main__': Xys_train, (X_test, y_test) = evaluation_split_from_task("a6a") for task in [ 'electricity', 'cifar10', 'australian', 'parkinsons', ]: Xys_train, (X_test, y_test) = evaluation_split_from_task(task) print(len(Xys_train), X_test.shape)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/src/blackbox/__init__.py

from typing import Callable import numpy as np class Blackbox: def __init__( self, input_dim: int, output_dim: int, eval_fun: Callable[[np.array], np.array], ): self.input_dim = input_dim self.output_dim = output_dim self.eval_fun = eval_fun def __call__(self, x: np.array) -> np.array: """ :param x: shape (input_dim,) :return: shape (output_dim,) """ assert x.shape == (self.input_dim,) y = self.eval_fun(x) assert y.shape == (self.output_dim,) return y class BlackboxOffline(Blackbox): def __init__( self, X: np.array, y: np.array, ): """ A blackbox whose evaluations are already known. To evaluate a new point, we return the value of the closest known point. :param input_dim: :param output_dim: :param X: list of arguments evaluated, shape (n, input_dim) :param y: list of outputs evaluated, shape (n, output_dim) """ assert len(X) == len(y) n, input_dim = X.shape n, output_dim = y.shape from sklearn.neighbors import KNeighborsRegressor proj = KNeighborsRegressor(n_neighbors=1).fit(X, y) super(BlackboxOffline, self).__init__( input_dim=input_dim, output_dim=output_dim, eval_fun=lambda x: proj.predict(x.reshape(1, -1))[0] )

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_normalization.py

import numpy as np import pytest from optimizer.normalization_transforms import GaussianTransform, StandardTransform @pytest.mark.parametrize("psi_cls", [GaussianTransform, StandardTransform]) def test_gaussian_transform(psi_cls): n = 1000 tol = 0.05 dim = 2 y = np.random.uniform(size=(n, dim)) psi = psi_cls(y) z = psi.transform(y) assert np.allclose(z.mean(axis=0), np.zeros((dim,)), rtol=tol, atol=tol) assert np.allclose(z.std(axis=0), np.ones((dim,)), rtol=tol)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_prior.py

import numpy as np from prior.mlp_pytorch import ParametricPrior num_train_examples = 10000 num_test_examples = num_train_examples dim = 2 num_gradient_updates = 200 lr = 1e-2 def make_random_X_y(num_examples: int, dim: int, noise_std: float): X = np.random.rand(num_examples, dim) noise = np.random.normal(scale=noise_std, size=(num_examples, 1)) y = X.sum(axis=-1, keepdims=True) + noise return X, y def test_mu_fit(): # test that parametric prior can recover a simple linear function for the mean noise_std = 0.01 X_train, y_train = make_random_X_y(num_examples=num_train_examples, dim=dim, noise_std=noise_std) prior = ParametricPrior( X_train=X_train, y_train=y_train, num_gradient_updates=num_gradient_updates, num_decays=1, # smaller network for UT speed num_layers=2, num_hidden=20, dropout=0.0, lr=lr ) X_test, y_test = make_random_X_y(num_examples=num_test_examples, dim=dim, noise_std=noise_std) mu_pred, sigma_pred = prior.predict(X_test) mu_l1_error = np.abs(mu_pred - y_test).mean() print(mu_l1_error) assert mu_l1_error < 0.3 def test_sigma_fit(): # test that parametric prior can recover a simple constant function for the variance noise_std = 0.5 X_train, y_train = make_random_X_y(num_examples=num_train_examples, dim=dim, noise_std=noise_std) prior = ParametricPrior( X_train=X_train, y_train=y_train, num_gradient_updates=num_gradient_updates, num_decays=1, num_layers=2, num_hidden=20, dropout=0.0, lr=lr ) X_test, y_test = make_random_X_y(num_examples=num_test_examples, dim=dim, noise_std=noise_std) mu_pred, sigma_pred = prior.predict(X_test) sigma_l1_error = (sigma_pred.mean() - noise_std) assert sigma_l1_error < 0.05

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_optimization.py

import logging import random from functools import partial import numpy as np import pytest import torch from blackbox import Blackbox, BlackboxOffline from misc import set_seed from misc.artificial_data import artificial_task1 from optimizer.gaussian_process import GP from optimizer.gaussian_process_functional_prior import G3P from optimizer.normalization_transforms import StandardTransform, GaussianTransform from optimizer.thompson_sampling_functional_prior import TS from optimizer.random_search import RS Xy_train, X_test, y_test = artificial_task1() @pytest.mark.parametrize("blackbox", [ Blackbox( input_dim=2, output_dim=1, eval_fun=lambda x: x.sum(axis=-1, keepdims=True), ), BlackboxOffline( X=X_test, y=y_test, ) ]) def test_blackbox_works_with_optimization(blackbox: Blackbox): logging.basicConfig(level=logging.INFO) seed = 3 num_evaluations = 5 optimizer_cls = RS set_seed(seed) optimizer = optimizer_cls( input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, evaluations_other_tasks=Xy_train, ) candidates = X_test for i in range(num_evaluations): x = optimizer.sample(candidates) y = blackbox(x) logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y) @pytest.mark.parametrize("optimizer_cls", [ RS, # 5 gradient updates to makes it faster as we are only smoke-checking partial(TS, num_gradient_updates=5, normalization="standard"), partial(TS, num_gradient_updates=5, normalization="gaussian"), partial(GP, normalization="standard"), partial(GP, normalization="gaussian"), partial(G3P, num_gradient_updates=5, normalization="standard"), ]) @pytest.mark.parametrize("constrained_search", [False, True]) def test_smoke_optimizers(optimizer_cls, constrained_search: bool): logging.basicConfig(level=logging.INFO) num_evaluations = 10 blackbox = Blackbox( input_dim=2, output_dim=1, eval_fun=lambda x: x.sum(axis=-1, keepdims=True), ) optimizer = optimizer_cls( input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, evaluations_other_tasks=Xy_train, ) candidates = X_test for i in range(num_evaluations): if constrained_search: x = optimizer.sample(candidates) else: x = optimizer.sample() y = blackbox(x) logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_evaluate.py

import pytest from experiments.evaluate_optimizer_task import evaluate @pytest.mark.parametrize("optimizer", [ "RS", "GP", "GCP", # slow: # "TS", "CTS", # "GP+prior", "GCP+prior", ]) def test_evaluate(optimizer: str): evaluate( optimizer=optimizer, task="electricity", num_seeds=2, num_evaluations=10, output_folder="/tmp/", prior="sklearn", )

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_gp.py

import logging import pytest from blackbox import Blackbox from misc.artificial_data import artificial_task1 from optimizer.gaussian_process import GP @pytest.mark.parametrize("constrained_search", [False, True]) @pytest.mark.parametrize("normalization", ["standard", "gaussian"]) def test_gp(constrained_search: bool, normalization: str): logging.basicConfig(level=logging.INFO) num_evaluations = 8 Xy_train, X_test, y_test = artificial_task1() blackbox = Blackbox( input_dim=2, output_dim=1, eval_fun=lambda x: x.sum(axis=-1, keepdims=True), ) optimizer = GP( input_dim=blackbox.input_dim, output_dim=blackbox.output_dim, normalization=normalization, ) candidates = X_test for i in range(num_evaluations): x = optimizer.sample(candidates) if constrained_search else optimizer.sample() y = blackbox(x) logging.info(f"criterion {y} for arguments {x}") optimizer.observe(x=x, y=y)

py

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning

A-Quantile-based-Approach-for-Hyperparameter-Transfer-Learning-master/tst/test_blackbox.py

import numpy as np from blackbox import BlackboxOffline def test_blackbox(): n = 20 dim = 2 X_test = np.random.rand(n, dim) y_test = np.random.rand(n, 1) blackbox = BlackboxOffline( X=X_test, y=y_test, ) for x, y in zip(X_test, y_test): assert np.allclose(blackbox(x), y)

py

optisplit

optisplit-main/mean.py

import pandas as pd import os import numpy as np from pdb import set_trace as bp import sys from pathlib import Path """Calculate means of result files.""" def sort_dfs(dfs): res = [] for df in dfs: start = df.iloc[:4,:].sort_values(by=[' method'], ascending=False) end = df.iloc[4:,:].sort_values(by=[' method'], ascending=False) df_new = pd.concat([start, end]) df_new.set_index(np.arange(len(df)), inplace=True) res.append(df_new) return res if __name__ == '__main__': name = sys.argv[1] output_dir = sys.argv[2] if name not in ['small', 'go', 'xml']: print('invalid dataset name') sys.exit(1) dfs = [pd.read_csv(Path(output_dir, fname), index_col=False) for fname in os.listdir(output_dir) if 'csv' in fname and name in fname and 'mean' not in fname] print(len(dfs)) if name == 'xml': dfs = sort_dfs(dfs) df = pd.concat(dfs).groupby(level=0).mean() df.insert(0, 'method', dfs[0].values[:,1]) df.insert(0, 'dataset', dfs[0].values[:,0]) df.to_csv(Path(output_dir, f'mean_scores_{name}.csv'), index=False, float_format='%.4f') # df.to_csv(Path(path, f'mean_scores_{name}.csv'), index=False)

py

optisplit

optisplit-main/evaluation_metric_experiment.py

import numpy as np import joblib import matplotlib.pyplot as plt import scipy.sparse as sp import warnings from copy import deepcopy from pdb import set_trace as bp from textwrap import wrap import cv_balance np.set_printoptions(formatter={'float': lambda x: "{0:0.5f}".format(x)}) warnings.filterwarnings('ignore', message='Comparing a sparse matrix with 0 using == is inefficient') def equal(y, ones, n_folds): """Equally distributed folds""" for j, yy in enumerate(y): for i in range(yy.shape[1]): yy[:ones[i]//n_folds, i] = 1 targets = np.row_stack(y) return sp.csr_matrix(targets) def classes_missing_from_1_fold(y, ones, n_folds): for j, yy in enumerate(y): if j == 0: continue else: for i in range(yy.shape[1]): yy[:ones[i]//(n_folds-1), i] = 1 targets = np.row_stack(y).astype(np.int) return sp.csr_matrix(targets) def difference(y, ones, n_folds): """Small difference between folds""" diff = 0.2 for j, yy in enumerate(y): if j == 0: for i in range(yy.shape[1]): yy[:ones[i]//n_folds+(diff*(ones[i]//n_folds)).astype(np.int), i] = 1 elif j== 1: for i in range(yy.shape[1]): yy[:ones[i]//n_folds-(diff*(ones[i]//n_folds)).astype(np.int), i] = 1 else: for i in range(yy.shape[1]): yy[:ones[i]//n_folds, i] = 1 targets = sp.csr_matrix(np.row_stack(y)) return targets def mk_y(size, n_folds): """Generate the synthetic data""" y = np.split(np.zeros(size), n_folds) folds = np.split(np.arange(size[0]), n_folds) folds = [(np.setdiff1d(np.arange(size[0]), f), f) for f in folds] ones = np.linspace(start=2*n_folds, stop=size[0]//2, num=100).astype(np.int) res = {} res['Equal'] = folds, equal(deepcopy(y), ones, n_folds) res['Difference'] = folds, difference(deepcopy(y), ones, n_folds) res['One missing'] = folds, classes_missing_from_1_fold(deepcopy(y), ones, n_folds) joblib.dump(res, 'results/res.joblib') def calculate_scores(target_fold_ratio, actual_fold_ratio): """Return LD and rLD scores for the given ratios""" #Notation like in Section 3. D = 1 # data size Di = np.linspace(0.01*D, 0.99*D, 100) # number of positives in each class Sj = D*actual_fold_ratio Sij = Di*target_fold_ratio d = Di / D p = Sij / Sj rld = np.abs((d-p)/d) ld = np.abs(p/(1-p) - d/(1-d)) return ld, rld def plot_measures(): """Plot LD and rLD scores of folds with given error""" # get scores ratios = [(0.2, 0.25), (0.2, 0.3), (0.2, 0.4), (0.2, 0.5)][::-1] scores = [calculate_scores(*r) for r in ratios] ld_scores = [s[0] for s in scores] rld_scores = [s[1] for s in scores] # plot results # Score comparison plt.figure(figsize=(11, 3.8)) plt.subplots_adjust(wspace=0.3, top=0.90, bottom=0.15, right=0.82, left=0.10) Di = np.linspace(0.01, 0.99, 100) plt.subplot(1,2,1,) plt.yscale('log') plt.plot(Di, np.array(ld_scores).T) plt.xlabel('$D_i$', fontsize=13) plt.title('A', fontsize=16) plt.ylabel('LD', fontsize=13, rotation=0, labelpad=15) plt.xticks(fontsize=13) plt.yticks(fontsize=13) plt.subplot(1,2,2,) plt.plot(Di, np.array(rld_scores).T) plt.title('B', fontsize=16) plt.ylabel('rLD', fontsize=13, rotation=0, labelpad=15) plt.xlabel('$D_i$', fontsize=13) plt.xticks(fontsize=13) plt.yticks(fontsize=13) title = 'Ratio of positive data points in the fold' title = '\n'.join(wrap(title, 20)) lg = plt.legend([r[1] for r in ratios], bbox_to_anchor=(1.03, 0.8), loc="upper left", fontsize=13, title=title) title = lg.get_title() title.set_fontsize(13) plt.savefig(f'results/ld_vs_rld.pdf') # Difference comparison # calculate pairwise differences between scores ld_differences = np.array([x - y for i,x in enumerate(ld_scores[::-1]) for j,y in enumerate(ld_scores[::-1]) if i > j]).T rld_differences = np.array([x - y for i,x in enumerate(rld_scores[::-1]) for j,y in enumerate(rld_scores[::-1]) if i > j]).T labels = np.array([f'{ratios[i][1]}-{ratios[j][1]}' for i,x in enumerate(ld_scores[::-1]) for j,y in enumerate(ld_scores[::-1]) if i > j]).T plt.clf() plt.figure(figsize=(11, 3.8)) plt.subplots_adjust(wspace=0.3, top=0.90, bottom=0.15, right=0.82, left=0.10) Di = np.linspace(0.01, 0.99, 100) plt.subplot(1,2,1,) plt.yscale('log') plt.plot(Di, ld_differences) plt.xlabel('$D_i$', fontsize=13) plt.title('C', fontsize=16) plt.ylabel('$\Delta LD$', fontsize=13, rotation=0, labelpad=15) plt.xticks(fontsize=13) plt.yticks(fontsize=13) plt.subplot(1,2,2,) plt.plot(Di, rld_differences) plt.title('D', fontsize=16) plt.xlabel('$D_i$', fontsize=13) plt.ylabel('$\Delta rLD$', fontsize=13, rotation=0, labelpad=15) plt.xticks(fontsize=13) plt.yticks(fontsize=13) plt.legend(labels, bbox_to_anchor=(1.02, 0.8), loc="upper left", fontsize=13) plt.savefig(f'results/ld_vs_rld_differences.pdf') def synthetic_data_experiment(): datas = joblib.load('results/res.joblib') methods = ['rld', 'ld', 'dcp'] for i, name in enumerate(datas): plt.clf() data = datas[name] rld = np.array(cv_balance.rld(data[0], data[1])).ravel() ld = cv_balance.ld(data[0], data[1]) dcp = cv_balance.cv_evaluate(data[0], data[1], np.array(data[1].sum(axis=0)).ravel(), method='dcp') res_all = np.column_stack((ld, rld, dcp)) sizes = np.array(data[1].sum(axis=0)).ravel() if i == 2: plt.figure(figsize=(6.6, 3.8)) else: plt.figure(figsize=(5.4, 3.8)) for j, m in enumerate(['.', '+', '2']): plt.plot(sizes, res_all[:,j], ms=11, marker=m, markevery=0.04, alpha=0.9, linestyle='None') plt.xscale('symlog', linthreshx=0.000001) plt.yscale('symlog', linthreshy=0.000001) plt.ylim(-0.000001, np.max(res_all)+3) plt.xlabel('Class size', fontsize=16) plt.ylabel('Score', fontsize=16) plt.xticks(fontsize=15) plt.yticks(fontsize=15) plt.title(name, x=0.5, y=0.89, fontsize=16) if i == 2: lg = plt.legend(['LD', 'rLD', 'DCP'], bbox_to_anchor=(1.05, 0.5), loc="upper left", fontsize=14, title='Measure') title = lg.get_title() title.set_fontsize(14) plt.tight_layout() plt.savefig(f'results/{name}.pdf') if __name__ == '__main__': mk_y((100000,100), 10) synthetic_data_experiment() plot_measures()

py

optisplit

optisplit-main/cv_comparison_experiment.py

import argparse import sys import time import arff import joblib import numpy as np import scipy.sparse as sp from copy import deepcopy from datetime import timedelta from joblib import Parallel, delayed from pdb import set_trace as bp from skmultilearn.model_selection import IterativeStratification from cv_balance import optisplit, random_cv, cv_evaluate, check_folds, rld, ld sys.path.append('stratified_sampling_for_XML/stratify_function/') from stratify import stratified_train_test_split import warnings warnings.filterwarnings('ignore', message='Comparing a sparse matrix with 0 using == is inefficient') def load_datasets(dataset_type): datasets = {} if dataset_type == 'small': for dataset in [('mediamill', 101), ('bibtex', 159), ('delicious', 983)]: print(f'loading {dataset[0]}') with open(f'data/{dataset[0]}.arff') as f: data = arff.load(f) data = np.array(data['data']) datasets[dataset[0]] = sp.csr_matrix(data[:,-dataset[1]:].astype(np.int)) elif dataset_type == 'go': for dataset in ['CC', 'MF']: print(f'loading {dataset}') data =sp.load_npz(f'data/{dataset}_targets.npz') class_sizes = data.sum(axis=0) if np.any(class_sizes == data.shape[0]): data = data[:, np.array(class_sizes) < data.shape[0]] datasets[dataset] = data elif dataset_type == 'xml': for dataset in ['BP_targets.npz', 'wiki10_31k.npz']: print(f'loading {dataset}') data =sp.load_npz(f'data/{dataset}') class_sizes = data.sum(axis=0) if np.any(class_sizes == 0): data = data[:, (np.array(class_sizes) > 0).ravel()] if np.any(class_sizes == data.shape[0]): data = data[:, np.array(class_sizes) < data.shape[0]] datasets[dataset] = data else: raise NotImplementedError('unknown datasets') return datasets def iterstrat(n_folds, targets, random_state=42): """Iterative stratification""" X = np.zeros((targets.shape[0], 1)) k_fold = IterativeStratification(n_splits=n_folds, random_state=random_state).split(X,targets) return list(k_fold) def sois(n_folds, targets, random_state=42): """Second order iterative stratification""" X = np.zeros((targets.shape[0], 1)) k_fold = IterativeStratification(n_splits=n_folds, random_state=random_state, order=2).split(X,targets) return list(k_fold) def stratified(n_folds, targets, random_state=42): """Stratified sampling""" res = [] remaining = np.arange(targets.shape[0]) m = targets.shape[0]//n_folds for i in range(n_folds): if len(remaining) > m and i < n_folds-1: s = m/len(remaining) else: s = len(remaining) tt = list(targets[remaining,:].tolil().rows) X = list(np.zeros((targets.shape[0], 1))[remaining]) split = stratified_train_test_split(X, tt, target_test_size=s, random_state=random_state) remaining2 = remove(remaining, split[1]) res.append((None, remaining[split[1]])) remaining = remaining2 res = [(np.setdiff1d(np.arange(targets.shape[0]), f[1]), f[1]) for f in res] return res def partitioning_cv(n_folds, targets, random_state=42): """Partitioning method based on stratified random sampling""" np.random.seed(random_state) frequencies = np.array(np.mean(targets, axis=0)).ravel() index = list(targets.tolil().rows) tt = [frequencies[index[i]] for i in range(len(index))] D = np.array([np.product(t) for t in tt]) index = np.argsort(D) stratas = np.array_split(index, n_folds) for i in range(len(stratas)): np.random.shuffle(stratas[i]) substratas = [np.array_split(s, n_folds) for s in stratas] folds = [] for j in range(n_folds): res = [] for i in range(n_folds): res.append(substratas[i][j]) folds.append((None, np.concatenate(res).ravel())) folds = [(np.setdiff1d(np.arange(targets.shape[0]), f[1]), f[1]) for f in folds] return folds def remove(remaining, split): remaining2 = np.setdiff1d(remaining, remaining[split]) return remaining2 def improve_split(dataset_type, random_state=42, output_dir='results'): """Use optisplit to improve an existing split""" np.random.seed(random_state) folds = joblib.load(f'{output_dir}/folds_{dataset_type}_{random_state}.joblib') res = {} for dataset in folds.keys(): res[dataset] = {} for method in folds[dataset].keys(): data = folds[dataset][method] folds0 = [(np.setdiff1d(np.arange(data[1].shape[0]), f[1]), f[1]) for f in data[0]] if not check_folds(folds0, data[1]): bp() check_folds(folds0, data[1]) print(f'{method}') start = time.time() result = optisplit(n_splits=len(data[0]), targets=data[1], seed=random_state,initial_folds=folds0) elapsed = time.time()-start runtime = f'Time: {str(timedelta(seconds=elapsed))}' res[dataset][method] = result, data[1], elapsed print(runtime) joblib.dump(res, f'{output_dir}/folds_{dataset_type}_{random_state}_IMPROVED.joblib') def create_folds(dataset_type, n_folds=5, random_state=42, output_dir='results'): own_dcp = lambda n_splits, targets, random_seed: optisplit(n_splits, targets, method='dcp', seed=random_seed) own_rld = lambda n_splits, targets, random_seed: optisplit(n_splits, targets, method='rld', seed=random_seed) own_ld = lambda n_splits, targets, random_seed: optisplit(n_splits, targets, method='ld', seed=random_seed) datasets = load_datasets(dataset_type) if dataset_type in ['small', 'go']: methods = {'SS':stratified, 'PMBSRS':partitioning_cv, 'IS':iterstrat, 'SOIS':sois, 'own_ld':own_ld, 'own_dcp':own_dcp, 'own_rld':own_rld, 'random':random_cv} else: methods = {'own_ld':own_ld, 'own_dcp':own_dcp, 'own_rld':own_rld, 'PMBSRS':partitioning_cv, 'random':random_cv, 'SS':stratified} res = {} for dataset in datasets.keys(): print(f'{dataset}') res[dataset] = {} for method in methods.keys(): print(f'{method}') start = time.time() targets = datasets[dataset] try: result = methods[method](n_folds, deepcopy(targets), random_state) elapsed = time.time()-start runtime = f'Time: {str(timedelta(seconds=elapsed))}' res[dataset][method] = result, targets, elapsed print(runtime) except: print(f'Error in {method} on {dataset} - skipped') joblib.dump(res, f'{output_dir}/folds_{dataset_type}_{random_state}.joblib') def example_distribution(folds, targets): k = len(folds) res = 0 for j in range(k): Sj = len(folds[j][1]) cj = targets.shape[0]*(1/k) res += np.abs(Sj - cj) return (1/k)*res def evaluate_folds(dataset_type, random_state, output_dir): folds = joblib.load(f'{output_dir}/folds_{dataset_type}_{random_state}.joblib') res = {} for dataset in folds.keys(): res[dataset] = {} for method in folds[dataset].keys(): data = folds[dataset][method] targets = data[1] class_sizes = np.array(targets.sum(axis=0)).ravel() # remove empty classes if they exists targets = targets[:, np.where(class_sizes > 0)[0]] class_sizes = np.array(targets.sum(axis=0)).ravel() dcp = cv_evaluate(data[0], targets, class_sizes, method='dcp') ED = example_distribution(data[0], targets) LD = np.mean(ld(data[0], targets)) rld_score = np.mean(rld(data[0], targets)) dcp_score = np.mean(dcp) runtime = data[2] res[dataset][method] = {'ED':ED, 'LD':LD, 'dcp':dcp_score, 'rld':rld_score, 'runtime':runtime} tostr = lambda x: str(x).replace('[','').replace(']','').replace('\'', '') with open(f'{output_dir}/scores_{dataset_type}_{random_state}.csv', 'w') as f: fields = 'dataset, method, ED, LD, dcp, rld, runtime\n' f.write(fields) for dataset, results in res.items(): for method, scores in results.items(): score_str = tostr([v for v in list(scores.values())]) f.write(f'{dataset},{method},{score_str}\n') if __name__ == '__main__': parser = argparse.ArgumentParser() parser.add_argument('dataset_type', type=str, help='small, go or xml') parser.add_argument('random_state', type=int) parser.add_argument('output_dir', type=str) parser.add_argument('-e', '--evaluation', action='store_true', help='run evaluations') parser.add_argument('-i', '--improve', action='store_true', help='improve existing folds') parser.add_argument('-c', '--create', action='store_true', help='create folds') args = parser.parse_args() if args.create: create_folds(dataset_type=args.dataset_type, random_state=args.random_state, output_dir=args.output_dir) if args.evaluation: evaluate_folds(dataset_type=args.dataset_type, random_state=args.random_state, output_dir=args.output_dir) if args.improve: improve_split(dataset_type=args.dataset_type, random_state=args.random_state, output_dir=args.output_dir)

py

optisplit

optisplit-main/cv_balance.py

import time import numpy as np import scipy.sparse as sp from copy import deepcopy from datetime import timedelta from pdb import set_trace as bp def rld(folds, targets): tt = deepcopy(targets) res = [] di = np.array(tt.sum(axis=0)).ravel() / tt.shape[0] for f in folds: pij = np.array(tt[f[1]].sum(axis=0)).ravel() / len(f[1]) res.append((abs((di - pij)/di))) res = np.stack(res) return res.mean(axis=0) def dcp(folds, targets): tt = deepcopy(targets) res = [] Si = np.array(tt.sum(axis=0)).ravel() for f in folds: Sji = np.array(tt[f[1]].sum(axis=0)).ravel() res.append(Sji) res = np.stack(res) return (res / Si).max(axis=0) - 1/len(folds) def ld(folds, targets): tt = deepcopy(targets) res = [] di = np.array(tt.sum(axis=0)).ravel() / tt.shape[0] di = np.where(di == 1, (tt.shape[0]-1)/tt.shape[0], di) # avoid division by zero for f in folds: pij = np.array(tt[f[1]].sum(axis=0)).ravel() / len(f[1]) pij = np.where(pij == 1, (len(f[1])-1)/len(f[1]), pij) res.append(abs((pij/(1-pij) - di/(1-di)))) res = np.stack(res) return res.mean(axis=0) def cv_evaluate(folds, targets, method='original'): """Return X, Y evaluation metrics for a cv""" if method == 'dcp': res = np.array(dcp(folds, targets)).ravel() elif method == 'rld': res = np.array(rld(folds, targets)).ravel() elif method == 'ld': res = np.array(ld(folds, targets)).ravel() else: raise NotImplementedError('invalid method') return np.array(res).ravel() def transfer_sequences(class_index, arr0, arr1, n_transfer, A, targets, sequences=None): """Transfer contents of class_index array from arr0 to arr1""" arr0_index = np.intersect1d(class_index, arr0).astype(np.int) # select sequences with smallest number of other features tt = np.array(targets[arr0_index, :].sum(axis=1)).ravel() if sequences is not None: # use precomputed transfer index transfer_index = sequences else: # select sequences with fewest other classes to be transferred transfer_index = arr0_index[tt.argsort()[:n_transfer]] # move arr0 to arr1 arr1 = np.concatenate((arr1, transfer_index)).astype(np.int) arr0 = np.setdiff1d(arr0, transfer_index).astype(np.int) return arr0, arr1, transfer_index def balance(targets, A, folds, n_splits): n_transfer = calc_transfer(targets, A, folds, n_splits) class_index = np.where(targets[:,A].toarray().ravel() > 0)[0] excess = np.array([]) # process folds with too many test cases for i, n in enumerate(n_transfer): if n_transfer[i] < 0: tr_index = folds[i][0] test_index = folds[i][1] test_index, tr_index, transfer_index = transfer_sequences(class_index, test_index, tr_index, abs(n_transfer[i]), A, targets) excess = np.concatenate((excess, transfer_index)) folds[i] = tr_index, test_index #? else: continue # process folds with too few test cases for i, n in enumerate(n_transfer): if n_transfer[i] > 0: tr_index = folds[i][0] test_index = folds[i][1] sequences = excess[:abs(n_transfer[i])] excess = np.setdiff1d(excess, sequences) tr_index, test_index, transfer_index = transfer_sequences(class_index, tr_index, test_index, n_transfer[i], A, targets, sequences=sequences) folds[i] = tr_index, test_index #? else: continue assert len(excess) == 0,'Failed to distribute all sequences' return folds, n_transfer def check_folds(folds, targets): all_sequences_in_test = sum([len(np.unique(f[1])) for f in folds]) == targets.shape[0] separate_training_test = all([len(np.intersect1d(f[0], f[1])) == 0 for f in folds]) data_shape = all([len(f[0]) + len(f[1]) == targets.shape[0] for f in folds]) no_overlapping_test_sets = len(np.unique(np.concatenate([np.unique(f[1]) for f in folds]))) == len(np.concatenate([f[1] for f in folds])) return all_sequences_in_test and no_overlapping_test_sets and separate_training_test and data_shape def random_cv(n_splits, targets, seed=42): np.random.seed(seed) t = np.arange(targets.shape[0]) np.random.shuffle(t) folds = np.array_split(t, n_splits) folds = [(np.setdiff1d(t,f), f) for f in folds] return folds def calc_transfer(targets, A, folds, n_splits): # calculate the amount of balancing needed tt = np.array([targets[f[1], A].sum() for f in folds]) n_transfer = np.array([tt.sum()//n_splits - t for t in tt]) if sum(n_transfer) < 0: aa = np.zeros(len(n_transfer)).astype(np.int) aa[:abs(sum(n_transfer))] = 1 n_transfer = n_transfer + aa assert sum(n_transfer) == 0, 'Balancing failed' return n_transfer def optisplit(n_splits, targets, method='rld', max_epochs=3, seed=42, initial_folds=None): """Run Optisplit. Parameters ---------- n_splits : int Number of cross validation folds targets : scipy csr matrix Target matrix method : str (rld or dcp), default=rld Optimisation method max_epochs: int, defauld=3 Number of times to run optisplit over the data seed: int, default=42 Random seed initial_folds: list, default=None List of numpy arrays containing cross validation fold indices. These are used as the initial folds. Returns ------- list list of n_split tuples containing numpy arrays containing training and test fold indices. """ np.random.seed(seed) targets = sp.csr_matrix(targets) class_sizes = targets.sum(axis=0) # if > 50% of the examples are positive, optimize the negative distribution pos_index = np.where(class_sizes > 0.5*targets.shape[0])[0] targets[:,pos_index] = (targets[:,pos_index] == 0).astype(np.int) class_sizes = targets.sum(axis=0) if initial_folds is None: folds0 = random_cv(n_splits, targets) else: folds0 = initial_folds res0 = cv_evaluate(folds0, targets, method=method) score0 = np.sum(res0) start = time.time() for jjj in range(max_epochs): max_offset = 0 print(f'round {jjj}') if jjj == 0: print(score0) for iii in range(targets.shape[1]): folds = deepcopy(folds0) A = np.argsort(np.array(res0).ravel())[::-1][max_offset] folds, n_transfer = balance(targets, A, folds, n_splits) res1 = cv_evaluate(folds, targets, method=method) if np.sum(res0) <= np.sum(res1) or np.all(n_transfer == 0): #balancing unbalanced some other classes max_offset += 1 continue score1 = np.sum(res1) folds0 = folds res0 = res1 print(score1) if np.isclose(score0, score1, atol=0.1): break assert check_folds(folds, targets), 'Invalid CV folds created' print(f'Time: {str(timedelta(seconds=time.time()-start))}') print(f'Ignored {max_offset} classes') return folds0 def main(): pass if __name__ == '__main__': main()

py

optisplit

optisplit-main/stratified_sampling_for_XML/stratify_function/stratify.py

import random import numpy as np from datetime import datetime import helper_funcs def stratified_train_test_split(X, y, target_test_size, random_state=None, epochs=50, swap_probability=0.1, threshold_proportion=0.1, decay=0.1): if random_state != None: random.seed(random_state) # To keep track of how long the initialization takes start_time = datetime.now() # Keep track how how many instances have been swapped to train or test swap_counter = { 'to_train': 0, 'to_test': 0, } # 1. Create instances_dict to keep track of instance information: # labels: array of labels, [] # train_or_test: string, 'train' or 'test' # instance_score: float, adjusted sum of label scores instances_dict = helper_funcs.create_instances_dict(X, y, target_test_size) # 1.5 Get average number of labels per instance labels_per_instance = [] for instance_id, instance_dict in instances_dict.items(): labels_count = len(instance_dict['labels']) labels_per_instance.append(labels_count) average_labels_per_instance = sum(labels_per_instance) / len(labels_per_instance) # 2. Create labels_dict to keep track of label information: # train: int, number of times label appears in train set # test: int, number of times label appears in test set # label_score: float, label score labels_dict = helper_funcs.create_labels_dict(instances_dict) # 3. Calculate the label score for each label in labels_dict # Positive score if too much of the label is in the test set # Negative score if too much of the label is in the train set helper_funcs.score_labels(labels_dict, target_test_size, average_labels_per_instance) # 4. Calculate the instance score for each instance in instances_dict # A high score means the instance is a good candidate for swapping helper_funcs.score_instances(instances_dict, labels_dict) # 5. Calculate the total score # The higher the score, the more 'imbalanced' the distribution of labels between train and test sets total_score = helper_funcs.calculate_total_score(instances_dict) print(f'Starting score: {round(total_score)}. Calculated in {str(datetime.now() - start_time).split(".")[0]}') # Main loop to create stratified train-test split for epoch in range(epochs): # To keep track of how long each itteration takes itteration_start_time = datetime.now() # 6. Calculate the threshold score for swapping threshold_score = helper_funcs.calculte_threshold_score(instances_dict, average_labels_per_instance, epoch, threshold_proportion, decay) # 7. Swap the instances with instance_score that is greater than the threshold score # Probability of swapping an instance is swap_probability helper_funcs.swap_instances(instances_dict, threshold_score, swap_counter, average_labels_per_instance, epoch, swap_probability, decay) # 2. Recreate labels_dict with updated train-test split labels_dict = helper_funcs.create_labels_dict(instances_dict) # from pdb import set_trace as bp # bp() # 3. Recalculate the label score for each label in labels_dict helper_funcs.score_labels(labels_dict, target_test_size, average_labels_per_instance) # 4. Recalculate the instance score for each instance in instances_dict helper_funcs.score_instances(instances_dict, labels_dict) # 5. Recalculate the total score total_score = helper_funcs.calculate_total_score(instances_dict) print(f'Epoch {epoch + 1}/{epochs} score: {round(total_score)}. Calculated in {str(datetime.now() - itteration_start_time).split(".")[0]}') # Prepare X_train, X_test, y_train, y_test X_train = [] X_test = [] y_train = [] y_test = [] train_index = [] test_index = [] for instance_id, instance_dict in instances_dict.items(): if instance_dict['train_or_test'] == 'train': X_train.append(X[instance_id]) y_train.append(y[instance_id]) train_index.append(instance_id) elif instance_dict['train_or_test'] == 'test': X_test.append(X[instance_id]) y_test.append(y[instance_id]) test_index.append(instance_id) else: print(f'Something went wrong: {instance_id}') # # Print some statistics # actual_test_size = len(X_test) / (len(X_train) + len(X_test)) # print(f'To train: {swap_counter["to_train"]}') # print(f'To test: {swap_counter["to_test"]}') # print(f'Target test size: {target_test_size}') # print(f'Actual test size: {actual_test_size}') return np.array(train_index), np.array(test_index)

py

optisplit

optisplit-main/stratified_sampling_for_XML/stratify_function/helper_funcs.py

import random import numpy as np # 1. Create instances_dict to keep track of instance information: # labels: array of labels, [] # train_or_test: string, 'train' or 'test' # instance_score: float, adjusted sum of label scores def create_instances_dict(X, y, target_test_size): instances_dict = {} instance_id = 0 for _ in X: train_or_test = 'train' if random.uniform(0, 1) <= target_test_size: train_or_test = 'test' instances_dict[instance_id] = { 'labels': y[instance_id], 'train_or_test': train_or_test, 'instance_score': 0, } instance_id += 1 return instances_dict # 2. Create labels_dict to keep track of label information: # train: int, number of times label appears in train set # test: int, number of times label appears in test set # label_score: float, label score def create_labels_dict(instances_dict): labels_dict = {} for _, instance_dict in instances_dict.items(): train_or_test = instance_dict['train_or_test'] for label in instance_dict['labels']: try: if train_or_test == 'train': labels_dict[label]['train'] += 1 else: labels_dict[label]['test'] += 1 except: if train_or_test == 'train': labels_dict[label] = { 'train': 1, 'test': 0, 'label_score': 0 } else: labels_dict[label] = { 'train': 0, 'test': 1, 'label_score': 0 } return labels_dict # 3. Calculate the label score for each label in labels_dict # Positive score if too much of the label is in the test set # Negative score if too much of the label is in the train set def score_labels( labels_dict, target_test_size, average_labels_per_instance): for label, label_dict in labels_dict.items(): label_score = 0 label_count = label_dict['train'] + label_dict['test'] if label_count > 1: actual_test_proportion = label_dict['test'] / label_count if actual_test_proportion >= target_test_size: # Too much of the label is in the test set label_score = (actual_test_proportion - target_test_size) / (1 - target_test_size) if actual_test_proportion > 0.999: label_score += average_labels_per_instance else: # Too much of the label is in the train set label_score = (actual_test_proportion - target_test_size) / target_test_size if actual_test_proportion < 0.001: label_score -= average_labels_per_instance labels_dict[label]['label_score'] = label_score # 4. Calculate the instance score for each instance in instances_dict # A high score means the instance is a good candidate for swapping def score_instances(instances_dict, labels_dict): for instance_id, instance_dict in instances_dict.items(): instance_score = 0 train_or_test = instance_dict['train_or_test'] for label in instance_dict['labels']: label_score = labels_dict[label]['label_score'] if label_score > 0: # If too much of the label is in the test set if train_or_test == 'test': instance_score += label_score # If instance in test, increase score elif train_or_test == 'train': instance_score -= label_score # If instance in train, decrease score else: print(f'Something went wrong: {instance_id}') elif label_score < 0: # If too much of the label is in the train set if train_or_test == 'train': instance_score -= label_score # If instance in train, increase score elif train_or_test == 'test': instance_score += label_score # If instance in test, decrease score else: print(f'Something went wrong: {instance_id}') instances_dict[instance_id]['instance_score'] = instance_score # 5. Calculate the total score # The higher the score, the more 'imbalanced' the distribution of labels between train and test sets def calculate_total_score(instances_dict): total_score = 0 for _, instance_dict in instances_dict.items(): total_score += instance_dict['instance_score'] return total_score # 6. Calculate the threshold score for swapping def calculte_threshold_score(instances_dict, average_labels_per_instance, epoch, threshold_proportion, decay): instance_scores = [] for _, instance_dict in instances_dict.items(): if instance_dict['instance_score'] < average_labels_per_instance: instance_scores.append(instance_dict['instance_score']) threshold_score = np.quantile(instance_scores, (1 - (threshold_proportion / ((1 + decay) ** epoch)))) if threshold_score < 0: threshold_score = 0 return threshold_score # 7. Swap the instances with instance_score that is greater than the threshold score # Probability of swapping an instance is swap_probability def swap_instances(instances_dict, threshold_score, swap_counter, average_labels_per_instance, epoch, swap_probability, decay): for instance_id, instance_dict in instances_dict.items(): instance_score = instance_dict['instance_score'] if instance_score >= average_labels_per_instance: if random.uniform(0, 1) <= 0.25 / (1.05 ** epoch): current_group = instance_dict['train_or_test'] if current_group == 'train': instances_dict[instance_id]['train_or_test'] = 'test' swap_counter['to_test'] += 1 elif current_group == 'test': instances_dict[instance_id]['train_or_test'] = 'train' swap_counter['to_train'] += 1 elif instance_score > threshold_score and random.uniform(0, 1) <= swap_probability / ((1 + decay) ** epoch): current_group = instance_dict['train_or_test'] if current_group == 'train': instances_dict[instance_id]['train_or_test'] = 'test' swap_counter['to_test'] += 1 elif current_group == 'test': instances_dict[instance_id]['train_or_test'] = 'train' swap_counter['to_train'] += 1

py

PC-JeDi

PC-JeDi-main/src/plotting.py

from copy import deepcopy from functools import partial from pathlib import Path from typing import Optional, Union import matplotlib.pyplot as plt import numpy as np import PIL import wandb from jetnet.utils import efps def plot_multi_hists( data_list: Union[list, np.ndarray], data_labels: Union[list, str], col_labels: Union[list, str], path: Optional[Union[Path, str]] = None, scale_factors: Optional[list] = None, do_err: bool = False, do_norm: bool = False, bins: Union[list, str, partial] = "auto", logy: bool = False, y_label: Optional[str] = None, ylim: Optional[list] = None, rat_ylim: tuple = (0, 2), rat_label: Optional[str] = None, scale: int = 5, do_legend: bool = True, hist_kwargs: Optional[list] = None, err_kwargs: Optional[list] = None, legend_kwargs: Optional[dict] = None, incl_overflow: bool = True, incl_underflow: bool = True, do_ratio_to_first: bool = False, return_fig: bool = False, return_img: bool = False, ) -> Union[plt.Figure, None]: """Plot multiple histograms given a list of 2D tensors/arrays. - Performs the histogramming here - Each column the arrays will be a seperate axis - Matching columns in each array will be superimposed on the same axis - If the tensor being passed is 3D it will average them and combine the uncertainty args: data_list: A list of tensors or numpy arrays, each col will be a seperate axis data_labels: A list of labels for each tensor in data_list col_labels: A list of labels for each column/axis path: The save location of the plots (include img type) scale_factors: List of scalars to be applied to each histogram do_err: If the statistical errors should be included as shaded regions do_norm: If the histograms are to be a density plot bins: List of bins to use for each axis, can use numpy's strings logy: If we should use the log in the y-axis y_label: Label for the y axis of the plots ylim: The y limits for all plots rat_ylim: The y limits of the ratio plots rat_label: The label for the ratio plot scale: The size in inches for each subplot do_legend: If the legend should be plotted hist_kwargs: Additional keyword arguments for the line for each histogram legend_kwargs: Extra keyword arguments to pass to the legend constructor incl_overflow: Have the final bin include the overflow incl_underflow: Have the first bin include the underflow do_ratio_to_first: Include a ratio plot to the first histogram in the list as_pdf: Also save an additional image in pdf format return_fig: Return the figure (DOES NOT CLOSE IT!) return_img: Return a PIL image (will close the figure) """ # Make the arguments lists for generality if not isinstance(data_list, list): data_list = [data_list] if isinstance(data_labels, str): data_labels = [data_labels] if isinstance(col_labels, str): col_labels = [col_labels] if not isinstance(bins, list): bins = data_list[0].shape[-1] * [bins] if not isinstance(scale_factors, list): scale_factors = len(data_list) * [scale_factors] if not isinstance(hist_kwargs, list): hist_kwargs = len(data_list) * [hist_kwargs] if not isinstance(err_kwargs, list): err_kwargs = len(data_list) * [err_kwargs] # Cycle through the datalist and ensure that they are 2D, as each column is an axis for data_idx in range(len(data_list)): if data_list[data_idx].ndim < 2: data_list[data_idx] = data_list[data_idx].unsqueeze(-1) # Check the number of histograms to plot n_data = len(data_list) n_axis = data_list[0].shape[-1] # Make sure that all the list lengths are consistant assert len(data_labels) == n_data assert len(col_labels) == n_axis assert len(bins) == n_axis # Make sure the there are not too many subplots if n_axis > 20: raise RuntimeError("You are asking to create more than 20 subplots!") # Create the figure and axes lists dims = np.array([1, n_axis]) # Subplot is (n_rows, n_columns) size = np.array([n_axis, 1.0]) # Size is (width, height) if do_ratio_to_first: dims *= np.array([2, 1]) # Double the number of rows size *= np.array([1, 1.2]) # Increase the height fig, axes = plt.subplots( *dims, figsize=tuple(scale * size), gridspec_kw={"height_ratios": [3, 1] if do_ratio_to_first else {1}}, squeeze=False, ) # Cycle through each axis and determine the bins that should be used # Automatic/Interger bins are replaced using the first item in the data list for ax_idx in range(n_axis): ax_bins = bins[ax_idx] if isinstance(ax_bins, partial): ax_bins = ax_bins() # If the axis bins was specified to be 'auto' or another numpy string if isinstance(ax_bins, str): unq = np.unique(data_list[0][:, ax_idx]) n_unique = len(unq) # If the number of datapoints is less than 10 then use even spacing if 1 < n_unique < 10: ax_bins = (unq[1:] + unq[:-1]) / 2 # Use midpoints, add final, initial ax_bins = np.append(ax_bins, unq.max() + unq.max() - ax_bins[-1]) ax_bins = np.insert(ax_bins, 0, unq.min() + unq.min() - ax_bins[0]) # Numpy function to get the bin edges, catches all other cases (int, etc) ax_bins = np.histogram_bin_edges(data_list[0][:, ax_idx], bins=ax_bins) # Replace the element in the array with the edges bins[ax_idx] = ax_bins # Cycle through each of the axes for ax_idx in range(n_axis): # Get the bins for this axis ax_bins = bins[ax_idx] # Cycle through each of the data arrays for data_idx in range(n_data): # Apply overflow and underflow (make a copy) data = np.copy(data_list[data_idx][..., ax_idx]).squeeze() if incl_overflow: data = np.minimum(data, ax_bins[-1]) if incl_underflow: data = np.maximum(data, ax_bins[0]) # If the data is still a 2D tensor treat it as a collection of histograms if data.ndim > 1: h = [] for dim in range(data.shape[-1]): h.append(np.histogram(data[:, dim], ax_bins, density=do_norm)[0]) # Nominal and err is based on chi2 of same value, mult measurements hist = 1 / np.mean(1 / np.array(h), axis=0) hist_err = np.sqrt(1 / np.sum(1 / np.array(h), axis=0)) # Otherwise just calculate a single histogram else: hist, _ = np.histogram(data, ax_bins, density=do_norm) hist_err = np.sqrt(hist) # Apply the scale factors if scale_factors[data_idx] is not None: hist *= scale_factors hist_err *= scale_factors # Save the first histogram for the ratio plots if data_idx == 0: denom_hist = hist denom_err = hist_err # Get the additional keyword arguments for the histograms and errors if hist_kwargs[data_idx] is not None and bool(hist_kwargs[data_idx]): h_kwargs = deepcopy(hist_kwargs[data_idx]) else: h_kwargs = {} # Use the stair function to plot the histograms line = axes[0, ax_idx].stairs( hist, ax_bins, label=data_labels[data_idx], **h_kwargs ) if err_kwargs[data_idx] is not None and bool(err_kwargs[data_idx]): e_kwargs = deepcopy(err_kwargs[data_idx]) else: e_kwargs = {"color": line._edgecolor, "alpha": 0.2, "fill": True} # Include the uncertainty in the plots as a shaded region if do_err: axes[0, ax_idx].stairs( hist + hist_err, ax_bins, baseline=hist - hist_err, **e_kwargs, ) # Add a ratio plot if do_ratio_to_first: if hist_kwargs[data_idx] is not None and bool(hist_kwargs[data_idx]): ratio_kwargs = deepcopy(hist_kwargs[data_idx]) else: ratio_kwargs = { "color": line._edgecolor, "linestyle": line._linestyle, } ratio_kwargs["fill"] = False # Never fill a ratio plot # Calculate the new ratio values with their errors rat_hist = hist / denom_hist rat_err = rat_hist * np.sqrt( (hist_err / hist) ** 2 + (denom_err / denom_hist) ** 2 ) # Plot the ratios axes[1, ax_idx].stairs( rat_hist, ax_bins, **ratio_kwargs, ) # Use a standard shaded region for the errors if do_err: axes[1, ax_idx].stairs( rat_hist + rat_err, ax_bins, baseline=rat_hist - rat_err, **e_kwargs, ) # Cycle again through each axis and apply editing for ax_idx in range(n_axis): ax_bins = bins[ax_idx] # X axis axes[0, ax_idx].set_xlim(ax_bins[0], ax_bins[-1]) if do_ratio_to_first: axes[0, ax_idx].set_xticklabels([]) axes[1, ax_idx].set_xlabel(col_labels[ax_idx]) axes[1, ax_idx].set_xlim(ax_bins[0], ax_bins[-1]) else: axes[0, ax_idx].set_xlabel(col_labels[ax_idx]) # Y axis if logy: axes[0, ax_idx].set_yscale("log") if ylim is not None: axes[0, ax_idx].set_ylim(*ylim) else: _, ylim2 = axes[0, ax_idx].get_ylim() if logy: axes[0, ax_idx].set_ylim(top=10 ** (np.log10(ylim2) * 1.40)) else: axes[0, ax_idx].set_ylim(top=ylim2 * 1.35) if y_label is not None: axes[0, ax_idx].set_ylabel(y_label) elif do_norm: axes[0, ax_idx].set_ylabel("Normalised Entries") else: axes[0, ax_idx].set_ylabel("Entries") # Ratio Y axis if do_ratio_to_first: axes[1, ax_idx].set_ylim(rat_ylim) if rat_label is not None: axes[1, ax_idx].set_ylabel(rat_label) else: axes[1, ax_idx].set_ylabel(f"Ratio to {data_labels[0]}") # Legend if do_legend: legend_kwargs = legend_kwargs or {} axes[0, ax_idx].legend(**legend_kwargs) # Final figure layout fig.tight_layout() if do_ratio_to_first: fig.subplots_adjust(hspace=0.08) # For ratio plots minimise the h_space # Save the file if path is not None: fig.savefig(path) # Return a rendered image, or the matplotlib figure, or close if return_img: img = PIL.Image.frombytes( "RGB", fig.canvas.get_width_height(), fig.canvas.tostring_rgb() ) plt.close(fig) return img if return_fig: return fig plt.close(fig) def locals_to_rel_mass_and_efp(csts: np.ndarray, mask: np.ndarray) -> np.ndarray: """Convert the values of a set of constituents to the relative mass and EFP values of the jet they belong to. Args: csts: A numpy array of shape (batch_size, n_csts, 3) containing the (eta, phi, pt) values of the constituents. mask: A numpy array of shape (batch_size, n_csts) containing a mask for the constituents, used to sum only over the valid constituents. Returns: A numpy array of shape (batch_size, 2) containing the relative mass and EFP values of the jet. """ # Calculate the constituent pt, eta and phi eta = csts[..., 0] phi = csts[..., 1] pt = csts[..., 2] # Calculate the total jet values in cartensian coordinates, include mask for sum jet_px = (pt * np.cos(phi) * mask).sum(axis=-1) jet_py = (pt * np.sin(phi) * mask).sum(axis=-1) jet_pz = (pt * np.sinh(eta) * mask).sum(axis=-1) jet_e = (pt * np.cosh(eta) * mask).sum(axis=-1) # Get the derived jet values, the clamps ensure NaNs dont occur jet_m = np.sqrt( np.clip(jet_e**2 - jet_px**2 - jet_py**2 - jet_pz**2, 0, None) ) # Get the efp values jet_efps = efps(csts, efp_jobs=1).mean(axis=-1) return np.vstack([jet_m, jet_efps]).T def plot_mpgan_marginals( outputs: np.ndarray, nodes: np.ndarray, mask: np.ndarray, current_epoch: int, ) -> None: # Clip the outputs for the marginals to match expected jet spread outputs[..., 0] = np.clip(outputs[..., 0], -0.5, 0.5) outputs[..., 1] = np.clip(outputs[..., 1], -0.5, 0.5) outputs[..., 2] = np.clip(outputs[..., 2], 0, 1) # Plot histograms for the constituent marginals Path("./plots/").mkdir(parents=False, exist_ok=True) cst_img = plot_multi_hists( data_list=[nodes[mask], outputs[mask]], data_labels=["Original", "Generated"], col_labels=[r"$\Delta \eta$", r"$\Delta \phi$", r"$\frac{p_T}{Jet_{p_T}}$"], do_norm=True, return_img=True, path=f"./plots/csts_{current_epoch}", logy=True, ) # Convert to total jet mass and pt, do some clamping to make everyone happy pred_jets = locals_to_rel_mass_and_efp(outputs, mask) pred_jets[:, 0] = np.clip(pred_jets[:, 0], 0, 0.4) pred_jets[:, 1] = np.clip(pred_jets[:, 1], 0, 4e-3) pred_jets = np.nan_to_num(pred_jets) real_jets = locals_to_rel_mass_and_efp(nodes, mask) real_jets[:, 0] = np.clip(real_jets[:, 0], 0, 0.4) real_jets[:, 1] = np.clip(real_jets[:, 1], 0, 4e-3) real_jets = np.nan_to_num(real_jets) # Image for the total jet variables jet_img = plot_multi_hists( data_list=[real_jets, pred_jets], data_labels=["Original", "Generated"], col_labels=["Relative Jet Mass", "Jet EFP"], do_norm=True, return_img=True, path=f"./plots/jets_{current_epoch}", ) # Create the wandb table and add the data if wandb.run is not None: gen_table = wandb.Table(columns=["constituents", "jets"]) gen_table.add_data(wandb.Image(cst_img), wandb.Image(jet_img)) wandb.run.log({"generated": gen_table}, commit=False)

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PC-JeDi

PC-JeDi-main/src/physics.py

# import jetnet import numpy as np import pytorch_lightning as pl import torch as T # FIX RANDOM SEED FOR REPRODUCIBILITY pl.seed_everything(0, workers=True) def locals_to_mass_and_pt(csts: T.Tensor, mask: T.BoolTensor) -> T.Tensor: """Calculate the overall jet pt and mass from the constituents. The constituents are expected to be expressed as: - del_eta - del_phi - log_pt """ # Calculate the constituent pt, eta and phi eta = csts[..., 0] phi = csts[..., 1] pt = csts[..., 2].exp() # Calculate the total jet values in cartensian coordinates, include mask for sum jet_px = (pt * T.cos(phi) * mask).sum(axis=-1) jet_py = (pt * T.sin(phi) * mask).sum(axis=-1) jet_pz = (pt * T.sinh(eta) * mask).sum(axis=-1) jet_e = (pt * T.cosh(eta) * mask).sum(axis=-1) # Get the derived jet values, the clamps ensure NaNs dont occur jet_pt = T.clamp_min(jet_px**2 + jet_py**2, 0).sqrt() jet_m = T.clamp_min(jet_e**2 - jet_px**2 - jet_py**2 - jet_pz**2, 0).sqrt() return T.vstack([jet_pt, jet_m]).T def numpy_locals_to_mass_and_pt( csts: np.ndarray, mask: np.ndarray, pt_logged=False, ) -> np.ndarray: """Calculate the overall jet pt and mass from the constituents. The constituents are expected to be expressed as: - del_eta - del_phi - log_pt or just pt depending on pt_logged """ # Calculate the constituent pt, eta and phi eta = csts[..., 0] phi = csts[..., 1] pt = np.exp(csts[..., 2]) * mask if pt_logged else csts[..., 2] # Calculate the total jet values in cartensian coordinates, include mask for sum jet_px = (pt * np.cos(phi) * mask).sum(axis=-1) jet_py = (pt * np.sin(phi) * mask).sum(axis=-1) jet_pz = (pt * np.sinh(eta) * mask).sum(axis=-1) jet_e = (pt * np.cosh(eta) * mask).sum(axis=-1) # Get the derived jet values, the clamps ensure NaNs dont occur jet_pt = np.sqrt(np.clip(jet_px**2 + jet_py**2, 0, None)) jet_m = np.sqrt( np.clip(jet_e**2 - jet_px**2 - jet_py**2 - jet_pz**2, 0, None) ) return np.vstack([jet_pt, jet_m]).T

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PC-JeDi

PC-JeDi-main/src/utils.py

py

PC-JeDi

PC-JeDi-main/src/numpy_utils.py

import numpy as np def undo_log_squash(data: np.ndarray) -> np.ndarray: """Undo the log squash function above.""" return np.sign(data) * (np.exp(np.abs(data)) - 1) def log_squash(data: np.ndarray) -> np.ndarray: """Apply a log squashing function for distributions with high tails.""" return np.sign(data) * np.log(np.abs(data) + 1)

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PC-JeDi

PC-JeDi-main/src/torch_utils.py

from typing import Union import numpy as np import torch as T import torch.nn as nn def get_loss_fn(name: str, **kwargs) -> nn.Module: """Return a pytorch loss function given a name.""" if name == "none": return None # Regression losses if name == "huber": return nn.HuberLoss(reduction="none") if name == "mse": return nn.MSELoss(reduction="none") if name == "mae": return nn.L1Loss(reduction="none") def to_np(inpt: Union[T.Tensor, tuple]) -> np.ndarray: """More consicse way of doing all the necc steps to convert a pytorch tensor to numpy array. - Includes gradient deletion, and device migration """ if isinstance(inpt, (tuple, list)): return type(inpt)(to_np(x) for x in inpt) if inpt.dtype == T.bfloat16: # Numpy conversions don't support bfloat16s inpt = inpt.half() return inpt.detach().cpu().numpy()

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PC-JeDi

PC-JeDi-main/src/hydra_utils.py

"""A collection of misculaneous functions usefull for the lighting/hydra template.""" import logging import os from pathlib import Path from typing import Any, List, Sequence import hydra import rich import rich.syntax import rich.tree import wandb from omegaconf import DictConfig, OmegaConf from pytorch_lightning import LightningModule, Trainer from pytorch_lightning.utilities.rank_zero import rank_zero_only log = logging.getLogger(__name__) @rank_zero_only def reload_original_config(cfg: OmegaConf, get_best: bool = False) -> OmegaConf: """Replaces the cfg with the one stored at the checkpoint location. Will also set the chkpt_dir to the latest version of the last or best checkpoint """ # Load the original config found in the the file directory orig_cfg = OmegaConf.load(Path("full_config.yaml")) # Get the latest updated checkpoint with the prefix last or best flag = "best" if get_best else "last" orig_cfg.ckpt_path = str( sorted(Path.cwd().glob(f"checkpoints/{flag}*.ckpt"), key=os.path.getmtime)[-1] ) # Set the wandb logger to attempt to resume the job if hasattr(orig_cfg, "loggers"): if hasattr(orig_cfg.loggers, "wandb"): orig_cfg.loggers.wandb.resume = True return orig_cfg @rank_zero_only def print_config( cfg: DictConfig, print_order: Sequence[str] = ( "datamodule", "model", "callbacks", "loggers", "trainer", "paths", ), resolve: bool = True, ) -> None: """Prints content of DictConfig using Rich library and its tree structure. Args: cfg: Configuration composed by Hydra. print_order: Determines in what order config components are printed. resolve: Whether to resolve reference fields of DictConfig. save_to_file: Whether to export config to the hydra output folder. """ style = "dim" tree = rich.tree.Tree("CONFIG", style=style, guide_style=style) queue = [] # add fields from `print_order` to queue for field in print_order: queue.append(field) if field in cfg else log.warning( f"Field '{field}' not found in config. Skipping '{field}' printing..." ) # add all the other fields to queue (not specified in `print_order`) for field in cfg: if field not in queue: queue.insert(0, field) # generate config tree from queue for field in queue: branch = tree.add(field, style=style, guide_style=style) config_group = cfg[field] if isinstance(config_group, DictConfig): branch_content = OmegaConf.to_yaml(config_group, resolve=resolve) else: branch_content = str(config_group) branch.add(rich.syntax.Syntax(branch_content, "yaml")) # print config tree rich.print(tree) def save_config(cfg: OmegaConf) -> None: """Saves the config to the output directory. This is necc ontop of hydra's default conf.yaml as it will resolve the entries allowing one to resume jobs identically with elements such as ${now:%H-%M-%S}. Furthermore, hydra does not allow resuming a previous job from the same dir. The work around is reload_original_config but that will fail as hydra overwites the default config.yaml file on startup, so this backup is needed for resuming. """ # In order to be able to resume the wandb logger session, save the run id if hasattr(cfg, "loggers"): if hasattr(cfg.loggers, "wandb"): if wandb.run is not None: cfg.loggers.wandb.id = wandb.run.id # save config tree to file OmegaConf.save(cfg, Path(cfg.paths.full_path, "full_config.yaml"), resolve=True) @rank_zero_only def log_hyperparameters( cfg: DictConfig, model: LightningModule, trainer: Trainer ) -> None: """Passes the config dict to the trainer's logger, also calculates # params.""" # Convert the config object to a hyperparameter dict hparams = OmegaConf.to_container(cfg, resolve=True) # calculate the number of trainable parameters in the model and add it hparams["model/params/total"] = sum(p.numel() for p in model.parameters()) hparams["model/params/trainable"] = sum( p.numel() for p in model.parameters() if p.requires_grad ) hparams["model/params/non_trainable"] = sum( p.numel() for p in model.parameters() if not p.requires_grad ) trainer.logger.log_hyperparams(hparams) def instantiate_collection(cfg_coll: DictConfig) -> List[Any]: """Uses hydra to instantiate a collection of classes and return a list.""" objs = [] if not cfg_coll: log.warning("List of configs is empty") return objs if not isinstance(cfg_coll, DictConfig): raise TypeError("List of configs must be a DictConfig!") for _, cb_conf in cfg_coll.items(): if isinstance(cb_conf, DictConfig) and "_target_" in cb_conf: log.info(f"Instantiating <{cb_conf._target_}>") objs.append(hydra.utils.instantiate(cb_conf)) return objs

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PC-JeDi

PC-JeDi-main/src/__init__.py

py

PC-JeDi

PC-JeDi-main/src/datamodules/__init__.py

py

PC-JeDi

PC-JeDi-main/src/datamodules/jetnet.py

from copy import deepcopy from typing import Mapping import numpy as np from jetnet.datasets import JetNet from pytorch_lightning import LightningDataModule from torch.utils.data import DataLoader, Dataset from src.numpy_utils import log_squash from src.physics import numpy_locals_to_mass_and_pt class JetNetData(Dataset): """Wrapper for the JetNet dataset so it works with our models with different inputs.""" def __init__(self, **kwargs) -> None: # Extra arguments used here self.log_squash_pt = kwargs.pop("log_squash_pt", False) self.high_as_context = kwargs.pop("high_as_context", True) self.recalc_high = kwargs.pop("recalculate_jet_from_pc", True) self.n_jets = kwargs.pop("n_jets", None) # All other arguments passed to the jetnet dataset constructor self.csts, self.high = JetNet.getData(**kwargs) self.csts = self.csts.astype(np.float32) self.high = self.high.astype(np.float32) # Trim the data based on the requested number of jets (None does nothing) self.csts = self.csts[: self.n_jets].astype(np.float32) self.high = self.high[: self.n_jets].astype(np.float32) # Manually calculate the mask by looking for zero padding self.mask = ~np.all(self.csts == 0, axis=-1) # Change the constituent information from pt-fraction to pure pt csts = self.csts.copy() csts[..., -1] = csts[..., -1] * self.high[..., 0:1] # Recalculate the jet mass and pt using the point cloud if self.recalc_high: self.high = numpy_locals_to_mass_and_pt(csts, self.mask) # Change the pt fraction to log_squash(pt) if self.log_squash_pt: self.csts[..., -1] = log_squash(csts[..., -1]) * self.mask def __getitem__(self, idx) -> tuple: csts = self.csts[idx] high = self.high[idx] if self.high_as_context else np.empty(0, dtype="f") mask = self.mask[idx] return csts, mask, high def __len__(self) -> int: return len(self.high) class JetNetDataModule(LightningDataModule): def __init__( self, *, data_conf: Mapping, loader_kwargs: Mapping, ) -> None: super().__init__() self.save_hyperparameters(logger=False) # Get the dimensions of the data from the config file self.dim = len(data_conf["particle_features"]) self.n_nodes = data_conf["num_particles"] if data_conf["high_as_context"]: self.ctxt_dim = len(data_conf["jet_features"]) else: self.ctxt_dim = 0 def setup(self, stage: str) -> None: """Sets up the relevant datasets.""" if stage == "fit": self.train_set = JetNetData(**self.hparams.data_conf, split="train") self.valid_set = JetNetData(**self.hparams.data_conf, split="test") if stage == "test": self.test_set = JetNetData(**self.hparams.data_conf, split="test") def train_dataloader(self) -> DataLoader: return DataLoader(self.train_set, **self.hparams.loader_kwargs, shuffle=True) def val_dataloader(self) -> DataLoader: return DataLoader(self.valid_set, **self.hparams.loader_kwargs, shuffle=False) def test_dataloader(self) -> DataLoader: test_kwargs = deepcopy(self.hparams.loader_kwargs) test_kwargs["drop_last"] = False return DataLoader(self.test_set, **test_kwargs, shuffle=False)

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PC-JeDi

PC-JeDi-main/src/models/diffusion.py

import math from typing import Optional, Tuple import torch as T from tqdm import tqdm class VPDiffusionSchedule: def __init__(self, max_sr: float = 1, min_sr: float = 1e-2) -> None: self.max_sr = max_sr self.min_sr = min_sr def __call__(self, time: T.Tensor) -> T.Tensor: return cosine_diffusion_shedule(time, self.max_sr, self.min_sr) def get_betas(self, time: T.Tensor) -> T.Tensor: return cosine_beta_shedule(time, self.max_sr, self.min_sr) def cosine_diffusion_shedule( diff_time: T.Tensor, max_sr: float = 1, min_sr: float = 1e-2 ) -> Tuple[T.Tensor, T.Tensor]: """Calculates the signal and noise rate for any point in the diffusion processes. Using continuous diffusion times between 0 and 1 which make switching between different numbers of diffusion steps between training and testing much easier. Returns only the values needed for the jump forward diffusion step and the reverse DDIM step. These are sqrt(alpha_bar) and sqrt(1-alphabar) which are called the signal_rate and noise_rate respectively. The jump forward diffusion process is simply a weighted sum of: input * signal_rate + eps * noise_rate Uses a cosine annealing schedule as proposed in Proposed in https://arxiv.org/abs/2102.09672 Args: diff_time: The time used to sample the diffusion scheduler Output will match the shape Must be between 0 and 1 max_sr: The initial rate at the first step min_sr: How much signal is preserved at end of diffusion (can't be zero due to log) """ # Use cosine annealing, which requires switching from times -> angles start_angle = math.acos(max_sr) end_angle = math.acos(min_sr) diffusion_angles = start_angle + diff_time * (end_angle - start_angle) signal_rates = T.cos(diffusion_angles) noise_rates = T.sin(diffusion_angles) return signal_rates, noise_rates def cosine_beta_shedule( diff_time: T.Tensor, max_sr: float = 1, min_sr: float = 1e-2 ) -> T.Tensor: """Returns the beta values for the continuous flows using the above cosine scheduler.""" start_angle = math.acos(max_sr) end_angle = math.acos(min_sr) diffusion_angles = start_angle + diff_time * (end_angle - start_angle) return 2 * (end_angle - start_angle) * T.tan(diffusion_angles) def ddim_predict( noisy_data: T.Tensor, pred_noises: T.Tensor, signal_rates: T.Tensor, noise_rates: T.Tensor, ) -> T.Tensor: """Use a single ddim step to predict the final image from anywhere in the diffusion process.""" return (noisy_data - noise_rates * pred_noises) / signal_rates @T.no_grad() def ddim_sampler( model, diff_sched: VPDiffusionSchedule, initial_noise: T.Tensor, n_steps: int = 50, keep_all: bool = False, mask: Optional[T.Tensor] = None, ctxt: Optional[T.BoolTensor] = None, clip_predictions: Optional[tuple] = None, ) -> Tuple[T.Tensor, list]: """Apply the DDIM sampling process to generate a batch of samples from noise. Args: model: A denoising diffusion model Requires: inpt_dim, device, forward() method that outputs pred noise diif_sched: A diffusion schedule object to calculate signal and noise rates initial_noise: The initial noise to pass through the process If none it will be generated here n_steps: The number of iterations to generate the samples keep_all: Return all stages of diffusion process Can be memory heavy for large batches num_samples: How many samples to generate Ignored if initial_noise is provided mask: The mask for the output point clouds ctxt: The context tensor for the output point clouds clip_predictions: Can stabalise generation by clipping the outputs """ # Get the initial noise for generation and the number of sammples num_samples = initial_noise.shape[0] # The shape needed for expanding the time encodings expanded_shape = [-1] + [1] * (initial_noise.dim() - 1) # Check the input argument for the n_steps, must be less than what was trained all_stages = [] step_size = 1 / n_steps # The initial variables needed for the loop noisy_data = initial_noise diff_times = T.ones(num_samples, device=model.device) next_signal_rates, next_noise_rates = diff_sched(diff_times.view(expanded_shape)) for step in tqdm(range(n_steps), "DDIM-sampling", leave=False): # Update with the previous 'next' step signal_rates = next_signal_rates noise_rates = next_noise_rates # Keep track of the diffusion evolution if keep_all: all_stages.append(noisy_data) # Apply the denoise step to get X_0 and expected noise pred_noises = model(noisy_data, diff_times, mask, ctxt) pred_data = ddim_predict(noisy_data, pred_noises, signal_rates, noise_rates) # Get the next predicted components using the next signal and noise rates diff_times = diff_times - step_size next_signal_rates, next_noise_rates = diff_sched( diff_times.view(expanded_shape) ) # Clamp the predicted X_0 for stability if clip_predictions is not None: pred_data.clamp_(*clip_predictions) # Remix the predicted components to go from estimated X_0 -> X_{t-1} noisy_data = next_signal_rates * pred_data + next_noise_rates * pred_noises return pred_data, all_stages @T.no_grad() def euler_maruyama_sampler( model, diff_sched: VPDiffusionSchedule, initial_noise: T.Tensor, n_steps: int = 50, keep_all: bool = False, mask: Optional[T.Tensor] = None, ctxt: Optional[T.BoolTensor] = None, clip_predictions: Optional[tuple] = None, ) -> Tuple[T.Tensor, list]: """Apply the full reverse process to noise to generate a batch of samples.""" # Get the initial noise for generation and the number of sammples num_samples = initial_noise.shape[0] # The shape needed for expanding the time encodings expanded_shape = [-1] + [1] * (initial_noise.dim() - 1) # Check the input argument for the n_steps, must be less than what was trained all_stages = [] delta_t = 1 / n_steps # The initial variables needed for the loop x_t = initial_noise t = T.ones(num_samples, device=model.device) for step in tqdm(range(n_steps), "Euler-Maruyama-sampling", leave=False): # Use the model to get the expected noise pred_noises = model(x_t, t, mask, ctxt) # Use to get s_theta _, noise_rates = diff_sched(t.view(expanded_shape)) s = -pred_noises / noise_rates # Take one step using the em method betas = diff_sched.get_betas(t.view(expanded_shape)) x_t += 0.5 * betas * (x_t + 2 * s) * delta_t x_t += (betas * delta_t).sqrt() * T.randn_like(x_t) t -= delta_t # Keep track of the diffusion evolution if keep_all: all_stages.append(x_t) # Clamp the denoised data for stability if clip_predictions is not None: x_t.clamp_(*clip_predictions) return x_t, all_stages @T.no_grad() def euler_sampler( model, diff_sched: VPDiffusionSchedule, initial_noise: T.Tensor, n_steps: int = 50, keep_all: bool = False, mask: Optional[T.Tensor] = None, ctxt: Optional[T.BoolTensor] = None, clip_predictions: Optional[tuple] = None, ) -> Tuple[T.Tensor, list]: """Apply the full reverse process to noise to generate a batch of samples.""" # Get the initial noise for generation and the number of sammples num_samples = initial_noise.shape[0] # The shape needed for expanding the time encodings expanded_shape = [-1] + [1] * (initial_noise.dim() - 1) # Check the input argument for the n_steps, must be less than what was trained all_stages = [] delta_t = 1 / n_steps # The initial variables needed for the loop t = T.ones(num_samples, device=model.device) signal_rates, noise_rates = diff_sched(t.view(expanded_shape)) x_t = initial_noise * (signal_rates + noise_rates) for step in tqdm(range(n_steps), "Euler-sampling", leave=False): # Take a step using the euler method and the gradient calculated by the ode x_t += get_ode_gradient(model, diff_sched, x_t, t, mask, ctxt) * delta_t t -= delta_t # Keep track of the diffusion evolution if keep_all: all_stages.append(x_t) # Clamp the denoised data for stability if clip_predictions is not None: x_t.clamp_(*clip_predictions) return x_t, all_stages @T.no_grad() def runge_kutta_sampler( model, diff_sched: VPDiffusionSchedule, initial_noise: T.Tensor, n_steps: int = 50, keep_all: bool = False, mask: Optional[T.Tensor] = None, ctxt: Optional[T.BoolTensor] = None, clip_predictions: Optional[tuple] = None, ) -> Tuple[T.Tensor, list]: """Apply the full reverse process to noise to generate a batch of samples.""" # Get the initial noise for generation and the number of sammples num_samples = initial_noise.shape[0] # Check the input argument for the n_steps, must be less than what was trained all_stages = [] delta_t = 1 / n_steps # Wrap the ode gradient in a lambda function depending only on xt and t ode_grad = lambda t, x_t: get_ode_gradient(model, diff_sched, x_t, t, mask, ctxt) # The initial variables needed for the loop x_t = initial_noise t = T.ones(num_samples, device=model.device) for step in tqdm(range(n_steps), "Runge-Kutta-sampling", leave=False): k1 = delta_t * (ode_grad(t, x_t)) k2 = delta_t * (ode_grad((t - delta_t / 2), (x_t + k1 / 2))) k3 = delta_t * (ode_grad((t - delta_t / 2), (x_t + k2 / 2))) k4 = delta_t * (ode_grad((T.clamp_min(t - delta_t, 0)), (x_t + k3))) k = (k1 + 2 * k2 + 2 * k3 + k4) / 6 x_t += k t -= delta_t # Keep track of the diffusion evolution if keep_all: all_stages.append(x_t) # Clamp the denoised data for stability if clip_predictions is not None: x_t.clamp_(*clip_predictions) return x_t, all_stages def get_ode_gradient( model, diff_sched: VPDiffusionSchedule, x_t: T.Tensor, t: T.Tensor, mask: Optional[T.BoolTensor] = None, ctxt: Optional[T.Tensor] = None, ) -> T.Tensor: expanded_shape = [-1] + [1] * (x_t.dim() - 1) _, noise_rates = diff_sched(t.view(expanded_shape)) betas = diff_sched.get_betas(t.view(expanded_shape)) return 0.5 * betas * (x_t - model(x_t, t, mask, ctxt) / noise_rates) def run_sampler(sampler: str, *args, **kwargs) -> Tuple[T.Tensor, list]: if sampler == "em": return euler_maruyama_sampler(*args, **kwargs) if sampler == "euler": return euler_sampler(*args, **kwargs) if sampler == "rk": return runge_kutta_sampler(*args, **kwargs) if sampler == "ddim": return ddim_sampler(*args, **kwargs) raise RuntimeError(f"Unknown sampler: {sampler}")

py

PC-JeDi

PC-JeDi-main/src/models/transformers.py

"""Some classes to describe transformer architectures.""" import math from typing import Mapping, Optional, Union import torch as T import torch.nn as nn from torch.nn.functional import dropout, softmax from .modules import DenseNetwork def merge_masks( q_mask: Union[T.BoolTensor, None], kv_mask: Union[T.BoolTensor, None], attn_mask: Union[T.BoolTensor, None], q_shape: T.Size, k_shape: T.Size, device: T.device, ) -> Union[None, T.BoolTensor]: """Create a full attention mask which incoporates the padding information.""" # Create the full mask which combines the attention and padding masks merged_mask = None # If either pad mask exists, create if q_mask is not None or kv_mask is not None: if q_mask is None: q_mask = T.full(q_shape[:-1], True, device=device) if kv_mask is None: kv_mask = T.full(k_shape[:-1], True, device=device) merged_mask = q_mask.unsqueeze(-1) & kv_mask.unsqueeze(-2) # If attention mask exists, create if attn_mask is not None: merged_mask = attn_mask if merged_mask is None else attn_mask & merged_mask return merged_mask def attention( query: T.Tensor, key: T.Tensor, value: T.Tensor, dim_key: int, attn_mask: Optional[T.BoolTensor] = None, attn_bias: Optional[T.Tensor] = None, drp: float = 0.0, training: bool = True, ) -> T.Tensor: """Apply the attention using the scaled dot product between the key query and key tensors, then matrix multiplied by the value. Note that the attention scores are ordered in recv x send, which is the opposite to how I usually do it for the graph network, which is send x recv We use masked fill -T.inf as this kills the padded key/values elements but introduces nans for padded query elements. We could used a very small number like -1e9 but this would need to scale with if we are using half precision. Args: query: Batched query sequence of tensors (b, h, s, f) key: Batched key sequence of tensors (b, h, s, f) value: Batched value sequence of tensors (b, h, s, f) dim_key: The dimension of the key features, used to scale the dot product attn_mask: The attention mask, used to blind certain combinations of k,q pairs attn_bias: Extra weights to combine with attention weights drp: Dropout probability training: If the model is in training mode, effects the dropout applied """ # Perform the matrix multiplication scores = T.matmul(query, key.transpose(-2, -1)) / math.sqrt(dim_key) # Add the bias terms if present if attn_bias is not None: # Move the head dimension to the first scores = scores + attn_bias.permute(0, 3, 1, 2) # Mask away the scores between invalid elements in sequence if attn_mask is not None: scores = scores.masked_fill(~attn_mask.unsqueeze(-3), -T.inf) # Apply the softmax function per head feature scores = softmax(scores, dim=-1) # Kill the nans introduced by the padded query elements scores = T.nan_to_num(scores, 0) # Apply dropout to the attention scores scores = dropout(scores, p=drp, training=training) # Finally multiply these scores by the output scores = T.matmul(scores, value) return scores class MultiHeadedAttentionBlock(nn.Module): """Generic Multiheaded Attention. Takes in three sequences with dim: (batch, sqeuence, features) - q: The primary sequence queries (determines output sequence length) - k: The attending sequence keys (determines incoming information) - v: The attending sequence values In a message passing sense you can think of q as your receiver nodes, v and k are the information coming from the sender nodes. When q == k(and v) this is a SELF attention operation When q != k(and v) this is a CROSS attention operation === Block operations: 1) Uses three linear layers to project the sequences. - q = q_linear * q - k = k_linear * k - v = v_linear * v 2) Outputs are reshaped to add a head dimension, and transposed for matmul. - features = model_dim = head_dim * num_heads - dim becomes: batch, num_heads, sequence, head_dim 3) Passes these through to the attention module (message passing) - In standard transformers this is the scaled dot product attention - Also takes additional dropout layer to mask the attention 4) Flatten out the head dimension and pass through final linear layer - results are same as if attention was done seperately for each head and concat - dim: batch, q_seq, head_dim * num_heads """ def __init__( self, model_dim: int, num_heads: int = 1, drp: float = 0, ) -> None: """ Args: model_dim: The dimension of the model num_heads: The number of different attention heads to process in parallel - Must allow interger division into model_dim drp: The dropout probability used in the MHA operation """ super().__init__() # Define model base attributes self.model_dim = model_dim self.num_heads = num_heads self.head_dim = model_dim // num_heads # Check that the dimension of each head makes internal sense if self.head_dim * num_heads != model_dim: raise ValueError("Model dimension must be divisible by number of heads!") # Initialise the weight matrices self.q_linear = nn.Linear(model_dim, model_dim) self.k_linear = nn.Linear(model_dim, model_dim) self.v_linear = nn.Linear(model_dim, model_dim) self.out_linear = nn.Linear(model_dim, model_dim) self.drp = drp def forward( self, q: T.Tensor, k: Optional[T.Tensor] = None, v: Optional[T.Tensor] = None, q_mask: Optional[T.BoolTensor] = None, kv_mask: Optional[T.BoolTensor] = None, attn_mask: Optional[T.BoolTensor] = None, attn_bias: Optional[T.Tensor] = None, ) -> T.Tensor: """ Args: q: The main sequence queries (determines the output length) k: The incoming information keys v: The incoming information values q_mask: Shows which elements of the main sequence are real kv_mask: Shows which elements of the attn sequence are real attn_mask: Extra mask for the attention matrix (eg: look ahead) attn_bias: Extra bias term for the attention matrix (eg: edge features) """ # If only q and q_mask are provided then we automatically apply self attention if k is None: k = q if kv_mask is None: kv_mask = q_mask v = v if v is not None else k # Store the batch size, useful for reshaping b_size, seq, feat = q.shape # Work out the masking situation, with padding, no peaking etc attn_mask = merge_masks(q_mask, kv_mask, attn_mask, q.shape, k.shape, q.device) # Generate the q, k, v projections, break final head dimension in 2 shape = (b_size, -1, self.num_heads, self.head_dim) q = self.q_linear(q).view(shape) k = self.k_linear(k).view(shape) v = self.v_linear(v).view(shape) # Transpose to get dimensions: B,H,Seq,HD (required for matmul) q = q.transpose(1, 2) k = k.transpose(1, 2) v = v.transpose(1, 2) # Calculate the new sequence values, for memory reasons overwrite q q = attention( q, k, v, self.head_dim, attn_mask=attn_mask, attn_bias=attn_bias, drp=self.drp, training=self.training, ) # Returned shape is B,H,Q_seq,HD # Concatenate the all of the heads together to get shape: B,Seq,F q = q.transpose(1, 2).contiguous().view(b_size, -1, self.model_dim) # Pass through final linear layer q = self.out_linear(q) return q class TransformerEncoderLayer(nn.Module): """A transformer encoder layer based on the GPT-2+Normformer style arcitecture. We choose Normformer as it has often proved to be the most stable to train https://arxiv.org/abs/2210.06423 https://arxiv.org/abs/2110.09456 It contains: - Multihead(self)Attention block - A dense network Layernorm is applied before each operation Residual connections are used to bypass each operation """ def __init__( self, model_dim: int, mha_config: Optional[Mapping] = None, dense_config: Optional[Mapping] = None, ctxt_dim: int = 0, ) -> None: """ Args: model_dim: The embedding dimensio of the transformer block mha_config: Keyword arguments for multiheaded-attention block dense_config: Keyword arguments for feed forward network ctxt_dim: Context dimension, """ super().__init__() mha_config = mha_config or {} dense_config = dense_config or {} self.model_dim = model_dim self.ctxt_dim = ctxt_dim # The basic blocks self.self_attn = MultiHeadedAttentionBlock(model_dim, **mha_config) self.dense = DenseNetwork( model_dim, outp_dim=model_dim, ctxt_dim=ctxt_dim, **dense_config ) # The normalisation layers (lots from NormFormer) self.norm1 = nn.LayerNorm(model_dim) self.norm2 = nn.LayerNorm(model_dim) self.norm3 = nn.LayerNorm(model_dim) def forward( self, x: T.Tensor, mask: Optional[T.BoolTensor] = None, ctxt: Optional[T.Tensor] = None, attn_bias: Optional[T.Tensor] = None, attn_mask: Optional[T.BoolTensor] = None, ) -> T.Tensor: "Pass through the layer using residual connections and layer normalisation" x = x + self.norm2( self.self_attn( self.norm1(x), q_mask=mask, attn_mask=attn_mask, attn_bias=attn_bias ) ) x = x + self.dense(self.norm3(x), ctxt) return x class TransformerEncoder(nn.Module): """A stack of N transformer encoder layers followed by a final normalisation step. Sequence -> Sequence """ def __init__( self, model_dim: int = 64, num_layers: int = 3, mha_config: Optional[Mapping] = None, dense_config: Optional[Mapping] = None, ctxt_dim: int = 0, ) -> None: """ Args: model_dim: Feature sieze for input, output, and all intermediate layers num_layers: Number of encoder layers used mha_config: Keyword arguments for the mha block dense_config: Keyword arguments for the dense network in each layer ctxt_dim: Dimension of the context inputs """ super().__init__() self.model_dim = model_dim self.num_layers = num_layers self.layers = nn.ModuleList( [ TransformerEncoderLayer(model_dim, mha_config, dense_config, ctxt_dim) for _ in range(num_layers) ] ) self.final_norm = nn.LayerNorm(model_dim) def forward(self, x: T.Tensor, **kwargs) -> T.Tensor: """Pass the input through all layers sequentially.""" for layer in self.layers: x = layer(x, **kwargs) return self.final_norm(x) class FullTransformerEncoder(nn.Module): """A transformer encoder with added input and output embedding networks. Sequence -> Sequence """ def __init__( self, inpt_dim: int, outp_dim: int, edge_dim: int = 0, ctxt_dim: int = 0, te_config: Optional[Mapping] = None, node_embd_config: Optional[Mapping] = None, outp_embd_config: Optional[Mapping] = None, edge_embd_config: Optional[Mapping] = None, ctxt_embd_config: Optional[Mapping] = None, ) -> None: """ Args: inpt_dim: Dim. of each element of the sequence outp_dim: Dim. of of the final output vector edge_dim: Dim. of the input edge features ctxt_dim: Dim. of the context vector to pass to the embedding nets te_config: Keyword arguments to pass to the TVE constructor node_embd_config: Keyword arguments for node dense embedder outp_embd_config: Keyword arguments for output dense embedder edge_embd_config: Keyword arguments for edge dense embedder ctxt_embd_config: Keyword arguments for context dense embedder """ super().__init__() self.inpt_dim = inpt_dim self.outp_dim = outp_dim self.ctxt_dim = ctxt_dim self.edge_dim = edge_dim te_config = te_config or {} node_embd_config = node_embd_config or {} outp_embd_config = outp_embd_config or {} edge_embd_config = edge_embd_config or {} # Initialise the context embedding network (optional) if self.ctxt_dim: self.ctxt_emdb = DenseNetwork( inpt_dim=self.ctxt_dim, **ctxt_embd_config, ) self.ctxt_out = self.ctxt_emdb.outp_dim else: self.ctxt_out = 0 # Initialise the TVE, the main part of this network self.te = TransformerEncoder(**te_config, ctxt_dim=self.ctxt_out) self.model_dim = self.te.model_dim # Initialise all embedding networks self.node_embd = DenseNetwork( inpt_dim=self.inpt_dim, outp_dim=self.model_dim, ctxt_dim=self.ctxt_out, **node_embd_config, ) self.outp_embd = DenseNetwork( inpt_dim=self.model_dim, outp_dim=self.outp_dim, ctxt_dim=self.ctxt_out, **outp_embd_config, ) # Initialise the edge embedding network (optional) if self.edge_dim: self.edge_embd = DenseNetwork( inpt_dim=self.edge_dim, outp_dim=self.te.layers[0].self_attn.num_heads, ctxt_dim=self.ctxt_out, **edge_embd_config, ) def forward( self, x: T.Tensor, mask: Optional[T.BoolTensor] = None, ctxt: Optional[T.Tensor] = None, attn_bias: Optional[T.Tensor] = None, attn_mask: Optional[T.BoolTensor] = None, ) -> T.Tensor: """Pass the input through all layers sequentially.""" if self.ctxt_dim: ctxt = self.ctxt_emdb(ctxt) if self.edge_dim: attn_bias = self.edge_embd(attn_bias, ctxt) x = self.node_embd(x, ctxt) x = self.te(x, mask=mask, ctxt=ctxt, attn_bias=attn_bias, attn_mask=attn_mask) x = self.outp_embd(x, ctxt) return x

py

PC-JeDi

PC-JeDi-main/src/models/schedulers.py

from torch.optim import Optimizer from torch.optim.lr_scheduler import _LRScheduler class WarmupToConstant(_LRScheduler): """Gradually warm-up learning rate in optimizer to a constant value.""" def __init__(self, optimizer: Optimizer, num_steps: int = 100) -> None: """ args: optimizer (Optimizer): Wrapped optimizer. num_steps: target learning rate is reached at num_steps. """ self.num_steps = num_steps self.finished = False super().__init__(optimizer) def get_lr(self) -> list[float]: if self.last_epoch > self.num_steps: return [base_lr for base_lr in self.base_lrs] return [ (base_lr / self.num_steps) * self.last_epoch for base_lr in self.base_lrs ]

py

PC-JeDi

PC-JeDi-main/src/models/modules.py

"""Collection of pytorch modules that make up the networks.""" import math from typing import Optional, Union import torch as T import torch.nn as nn def get_act(name: str) -> nn.Module: """Return a pytorch activation function given a name.""" if name == "relu": return nn.ReLU() if name == "lrlu": return nn.LeakyReLU(0.1) if name == "silu" or name == "swish": return nn.SiLU() if name == "selu": return nn.SELU() if name == "softmax": return nn.Softmax() if name == "gelu": return nn.GELU() if name == "tanh": return nn.Tanh() if name == "softmax": return nn.Softmax() if name == "sigmoid": return nn.Sigmoid() raise ValueError("No activation function with name: ", name) def get_nrm(name: str, outp_dim: int) -> nn.Module: """Return a 1D pytorch normalisation layer given a name and a output size Returns None object if name is none.""" if name == "batch": return nn.BatchNorm1d(outp_dim) if name == "layer": return nn.LayerNorm(outp_dim) if name == "none": return None else: raise ValueError("No normalistation with name: ", name) class MLPBlock(nn.Module): """A simple MLP block that makes up a dense network. Made up of several layers containing: - linear map - activation function [Optional] - layer normalisation [Optional] - dropout [Optional] Only the input of the block is concatentated with context information. For residual blocks, the input is added to the output of the final layer. """ def __init__( self, inpt_dim: int, outp_dim: int, ctxt_dim: int = 0, n_layers: int = 1, act: str = "lrlu", nrm: str = "none", drp: float = 0, do_res: bool = False, ) -> None: """Init method for MLPBlock. Parameters ---------- inpt_dim : int The number of features for the input layer outp_dim : int The number of output features ctxt_dim : int, optional The number of contextual features to concat to the inputs, by default 0 n_layers : int, optional1 A string indicating the name of the activation function, by default 1 act : str, optional A string indicating the name of the normalisation, by default "lrlu" nrm : str, optional The dropout probability, 0 implies no dropout, by default "none" drp : float, optional Add to previous output, only if dim does not change, by default 0 do_res : bool, optional The number of transform layers in this block, by default False """ super().__init__() # Save the input and output dimensions of the module self.inpt_dim = inpt_dim self.outp_dim = outp_dim self.ctxt_dim = ctxt_dim # If this layer includes an additive residual connection self.do_res = do_res and (inpt_dim == outp_dim) # Initialise the block layers as a module list self.block = nn.ModuleList() for n in range(n_layers): # Increase the input dimension of the first layer to include context lyr_in = inpt_dim + ctxt_dim if n == 0 else outp_dim # Linear transform, activation, normalisation, dropout self.block.append(nn.Linear(lyr_in, outp_dim)) if act != "none": self.block.append(get_act(act)) if nrm != "none": self.block.append(get_nrm(nrm, outp_dim)) if drp > 0: self.block.append(nn.Dropout(drp)) def forward(self, inpt: T.Tensor, ctxt: Optional[T.Tensor] = None) -> T.Tensor: """ args: tensor: Pytorch tensor to pass through the network ctxt: The conditioning tensor, can be ignored """ # Concatenate the context information to the input of the block if self.ctxt_dim and ctxt is None: raise ValueError( "Was expecting contextual information but none has been provided!" ) temp = T.cat([inpt, ctxt], dim=-1) if self.ctxt_dim else inpt # Pass through each transform in the block for layer in self.block: temp = layer(temp) # Add the original inputs again for the residual connection if self.do_res: temp = temp + inpt return temp def __repr__(self) -> str: """Generate a one line string summing up the components of the block.""" string = str(self.inpt_dim) if self.ctxt_dim: string += f"({self.ctxt_dim})" string += "->" string += "->".join([str(b).split("(", 1)[0] for b in self.block]) string += "->" + str(self.outp_dim) if self.do_res: string += "(add)" return string class DenseNetwork(nn.Module): """A dense neural network made from a series of consecutive MLP blocks and context injection layers.""" def __init__( self, inpt_dim: int, outp_dim: int = 0, ctxt_dim: int = 0, hddn_dim: Union[int, list] = 32, num_blocks: int = 1, n_lyr_pbk: int = 1, act_h: str = "lrlu", act_o: str = "none", do_out: bool = True, nrm: str = "none", drp: float = 0, do_res: bool = False, ctxt_in_inpt: bool = True, ctxt_in_hddn: bool = False, ) -> None: """Initialise the DenseNetwork. Parameters ---------- inpt_dim : int The number of input neurons outp_dim : int, optional The number of output neurons. If none it will take from inpt or hddn, by default 0 ctxt_dim : int, optional The number of context features. The context feature use is determined by ctxt_type, by default 0 hddn_dim : Union[int, list], optional The width of each hidden block. If a list it overides depth, by default 32 num_blocks : int, optional The number of hidden blocks, can be overwritten by hddn_dim, by default 1 n_lyr_pbk : int, optional The number of transform layers per hidden block, by default 1 act_h : str, optional The name of the activation function to apply in the hidden blocks, by default "lrlu" act_o : str, optional The name of the activation function to apply to the outputs, by default "none" do_out : bool, optional If the network has a dedicated output block, by default True nrm : str, optional Type of normalisation (layer or batch) in each hidden block, by default "none" drp : float, optional Dropout probability for hidden layers (0 means no dropout), by default 0 do_res : bool, optional Use resisdual-connections between hidden blocks (only if same size), by default False ctxt_in_inpt : bool, optional Include the ctxt tensor in the input block, by default True ctxt_in_hddn : bool, optional Include the ctxt tensor in the hidden blocks, by default False Raises ------ ValueError If the network was given a context input but both ctxt_in_inpt and ctxt_in_hddn were False """ super().__init__() # Check that the context is used somewhere if ctxt_dim: if not ctxt_in_hddn and not ctxt_in_inpt: raise ValueError("Network has context inputs but nowhere to use them!") # We store the input, hddn (list), output, and ctxt dims to query them later self.inpt_dim = inpt_dim if not isinstance(hddn_dim, int): self.hddn_dim = hddn_dim else: self.hddn_dim = num_blocks * [hddn_dim] self.outp_dim = outp_dim or inpt_dim if do_out else self.hddn_dim[-1] self.num_blocks = len(self.hddn_dim) self.ctxt_dim = ctxt_dim self.do_out = do_out # Necc for this module to work with the nflows package self.hidden_features = self.hddn_dim[-1] # Input MLP block self.input_block = MLPBlock( inpt_dim=self.inpt_dim, outp_dim=self.hddn_dim[0], ctxt_dim=self.ctxt_dim if ctxt_in_inpt else 0, act=act_h, nrm=nrm, drp=drp, ) # All hidden blocks as a single module list self.hidden_blocks = [] if self.num_blocks > 1: self.hidden_blocks = nn.ModuleList() for h_1, h_2 in zip(self.hddn_dim[:-1], self.hddn_dim[1:]): self.hidden_blocks.append( MLPBlock( inpt_dim=h_1, outp_dim=h_2, ctxt_dim=self.ctxt_dim if ctxt_in_hddn else 0, n_layers=n_lyr_pbk, act=act_h, nrm=nrm, drp=drp, do_res=do_res, ) ) # Output block (optional and there is no normalisation, dropout or context) if do_out: self.output_block = MLPBlock( inpt_dim=self.hddn_dim[-1], outp_dim=self.outp_dim, act=act_o, ) def forward(self, inputs: T.Tensor, ctxt: Optional[T.Tensor] = None) -> T.Tensor: """Pass through all layers of the dense network.""" # Reshape the context if it is available if ctxt is not None: dim_diff = inputs.dim() - ctxt.dim() if dim_diff > 0: ctxt = ctxt.view(ctxt.shape[0], *dim_diff * (1,), *ctxt.shape[1:]) ctxt = ctxt.expand(*inputs.shape[:-1], -1) # Pass through the input block inputs = self.input_block(inputs, ctxt) # Pass through each hidden block for h_block in self.hidden_blocks: # Context tensor will only be used if inputs = h_block(inputs, ctxt) # block was initialised with a ctxt dim # Pass through the output block if self.do_out: inputs = self.output_block(inputs) return inputs def __repr__(self): string = "" string += "\n (inp): " + repr(self.input_block) + "\n" for i, h_block in enumerate(self.hidden_blocks): string += f" (h-{i+1}): " + repr(h_block) + "\n" if self.do_out: string += " (out): " + repr(self.output_block) return string def one_line_string(self): """Return a one line string that sums up the network structure.""" string = str(self.inpt_dim) if self.ctxt_dim: string += f"({self.ctxt_dim})" string += ">" string += str(self.input_block.outp_dim) + ">" if self.num_blocks > 1: string += ">".join( [ str(layer.out_features) for hidden in self.hidden_blocks for layer in hidden.block if isinstance(layer, nn.Linear) ] ) string += ">" if self.do_out: string += str(self.outp_dim) return string class IterativeNormLayer(nn.Module): """A basic normalisation layer so it can be part of the model. Note! If a mask is provided in the forward pass, then this must be the dimension to apply over the masked inputs! For example: Graph nodes are usually batch x n_nodes x features so to normalise over the features one would typically give extra_dims as (0,) But nodes are always passed with the mask which flattens it to batch x features. Batch dimension is done automatically, so we dont pass any extra_dims!!! """ def __init__( self, inpt_dim: Union[T.Tensor, tuple, int], means: Optional[T.Tensor] = None, vars: Optional[T.Tensor] = None, n: int = 0, max_n: int = 5_00_000, extra_dims: Union[tuple, int] = (), ) -> None: """Init method for Normalisatiion module. Args: inpt_dim: Shape of the input tensor, required for reloading means: Calculated means for the mapping. Defaults to None. vars: Calculated variances for the mapping. Defaults to None. n: Number of samples used to make the mapping. Defaults to None. max_n: Maximum number of iterations before the means and vars are frozen extra_dims: The extra dimension(s) over which to calculate the stats Will always calculate over the batch dimension """ super().__init__() # Fail if only one of means or vars is provided if (means is None) ^ (vars is None): # XOR raise ValueError( """Only one of 'means' and 'vars' is defined. Either both or neither must be defined""" ) # Allow interger inpt_dim and n arguments if isinstance(inpt_dim, int): inpt_dim = (inpt_dim,) if isinstance(n, int): n = T.tensor(n) # The dimensions over which to apply the normalisation, make positive! if isinstance(extra_dims, int): # Ensure it is a list extra_dims = [extra_dims] else: extra_dims = list(extra_dims) if any([abs(e) > len(inpt_dim) for e in extra_dims]): # Check size raise ValueError("extra_dims argument lists dimensions outside input range") for d in range(len(extra_dims)): if extra_dims[d] < 0: # make positive extra_dims[d] = len(inpt_dim) + extra_dims[d] extra_dims[d] += 1 # Add one because we are inserting a batch dimension self.extra_dims = extra_dims # Calculate the input and output shapes self.max_n = max_n self.inpt_dim = list(inpt_dim) self.stat_dim = [1] + list(inpt_dim) # Add batch dimension for d in range(len(self.stat_dim)): if d in self.extra_dims: self.stat_dim[d] = 1 # Buffers arenneeded for saving/loading the layer self.register_buffer( "means", T.zeros(self.stat_dim) if means is None else means ) self.register_buffer("vars", T.ones(self.stat_dim) if vars is None else vars) self.register_buffer("n", n) # For the welford algorithm it is useful to have another variable m2 self.register_buffer("m2", T.ones(self.stat_dim) if vars is None else vars) # If the means are set here then the model is "frozen" and not updated self.frozen = means is not None def _mask(self, inpt: T.Tensor, mask: Optional[T.BoolTensor] = None) -> T.Tensor: if mask is None: return inpt return inpt[mask] def _check_attributes(self) -> None: if self.means is None or self.vars is None: raise ValueError( "Stats for have not been initialised or fit() has not been run!" ) def fit( self, inpt: T.Tensor, mask: Optional[T.BoolTensor] = None, freeze: bool = True ) -> None: """Set the stats given a population of data.""" inpt = self._mask(inpt, mask) self.vars, self.means = T.var_mean( inpt, dim=(0, *self.extra_dims), keepdim=True ) self.n = T.tensor(len(inpt), device=self.means.device) self.m2 = self.vars * self.n self.frozen = freeze def forward(self, inpt: T.Tensor, mask: Optional[T.BoolTensor] = None) -> T.Tensor: """Applies the standardisation to a batch of inputs, also uses the inputs to update the running stats if in training mode.""" with T.no_grad(): sel_inpt = self._mask(inpt, mask) if not self.frozen and self.training: self.update(sel_inpt) # Apply the mapping normed_inpt = (sel_inpt - self.means) / (self.vars.sqrt() + 1e-8) # Undo the masking if mask is not None: inpt = inpt.clone() # prevents inplace operation, bad for autograd inpt[mask] = normed_inpt return inpt return normed_inpt def reverse(self, inpt: T.Tensor, mask: Optional[T.BoolTensor] = None) -> T.Tensor: """Unnormalises the inputs given the recorded stats.""" sel_inpt = self._mask(inpt, mask) unnormed_inpt = sel_inpt * self.vars.sqrt() + self.means # Undo the masking if mask is not None: inpt = inpt.clone() # prevents inplace operation, bad for autograd inpt[mask] = unnormed_inpt return inpt return unnormed_inpt def update(self, inpt: T.Tensor, mask: Optional[T.BoolTensor] = None) -> None: """Update the running stats using a batch of data.""" inpt = self._mask(inpt, mask) # For first iteration if self.n == 0: self.fit(inpt, freeze=False) return # later iterations based on batched welford algorithm with T.no_grad(): self.n += len(inpt) delta = inpt - self.means self.means += (delta / self.n).mean( dim=(0, *self.extra_dims), keepdim=True ) * len(inpt) delta2 = inpt - self.means self.m2 += (delta * delta2).mean( dim=(0, *self.extra_dims), keepdim=True ) * len(inpt) self.vars = self.m2 / self.n # Freeze the model if we exceed the requested stats self.frozen = self.n >= self.max_n class CosineEncoding: def __init__( self, outp_dim: int = 32, min_value: float = 0.0, max_value: float = 1.0, frequency_scaling: str = "exponential", ) -> None: self.outp_dim = outp_dim self.min_value = min_value self.max_value = max_value self.frequency_scaling = frequency_scaling def __call__(self, inpt: T.Tensor) -> T.Tensor: return cosine_encoding( inpt, self.outp_dim, self.min_value, self.max_value, self.frequency_scaling ) def cosine_encoding( x: T.Tensor, outp_dim: int = 32, min_value: float = 0.0, max_value: float = 1.0, frequency_scaling: str = "exponential", ) -> T.Tensor: """Computes a positional cosine encodings with an increasing series of frequencies. The frequencies either increase linearly or exponentially (default). The latter is good for when max_value is large and extremely high sensitivity to the input is required. If inputs greater than the max value are provided, the outputs become degenerate. If inputs smaller than the min value are provided, the inputs the the cosine will be both positive and negative, which may lead degenerate outputs. Always make sure that the min and max bounds are not exceeded! Args: x: The input, the final dimension is encoded. If 1D then it will be unqueezed out_dim: The dimension of the output encoding min_value: Added to x (and max) as cosine embedding works with positive inputs max_value: The maximum expected value, sets the scale of the lowest frequency frequency_scaling: Either 'linear' or 'exponential' Returns: The cosine embeddings of the input using (out_dim) many frequencies """ # Unsqueeze if final dimension is flat if x.shape[-1] != 1 or x.dim() == 1: x = x.unsqueeze(-1) # Check the the bounds are obeyed if T.any(x > max_value): print("Warning! Passing values to cosine_encoding encoding that exceed max!") if T.any(x < min_value): print("Warning! Passing values to cosine_encoding encoding below min!") # Calculate the various frequencies if frequency_scaling == "exponential": freqs = T.arange(outp_dim, device=x.device).exp() elif frequency_scaling == "linear": freqs = T.arange(1, outp_dim + 1, device=x.device) else: raise RuntimeError(f"Unrecognised frequency scaling: {frequency_scaling}") return T.cos((x + min_value) * freqs * math.pi / (max_value + min_value))

py

PC-JeDi

PC-JeDi-main/src/models/pc_jedi.py

import copy from functools import partial from typing import Mapping, Optional, Tuple import numpy as np import pytorch_lightning as pl import torch as T import wandb from jetnet.evaluation import w1efp, w1m, w1p from src.models.diffusion import VPDiffusionSchedule, run_sampler from src.models.modules import CosineEncoding, IterativeNormLayer from src.models.schedulers import WarmupToConstant from src.models.transformers import FullTransformerEncoder from src.numpy_utils import undo_log_squash from src.plotting import plot_mpgan_marginals from src.torch_utils import get_loss_fn, to_np class TransformerDiffusionGenerator(pl.LightningModule): """A generative model which uses the diffusion process on a point cloud.""" def __init__( self, *, pc_dim: list, ctxt_dim: int, n_nodes: int, cosine_config: Mapping, diff_config: Mapping, normaliser_config: Mapping, trans_enc_config: Mapping, optimizer: partial, loss_name: str = "mse", mle_loss_weight: float = 0.0, ema_sync: float = 0.999, sampler_name: str = "em", sampler_steps: int = 100, ) -> None: """ Args: pc_dim: The dimension of the point cloud ctxt_dim: The size of the context vector for the point cloud n_nodes: Max number of nodes used to train this model cosine_config: For defining the cosine embedding arguments normaliser_config: For defining the iterative normalisation layer diff_shedule: The diffusion scheduler, defines the signal and noise rates trans_enc_config: Keyword arguments for the TransformerEncoder network optimizer: Partially initialised optimizer sched_config: The config for how to apply the scheduler ema_sync: How fast the ema network syncs with the given one loss_name: Name of the loss function to use for noise estimation mle_loss_weight: Relative weight of the Maximum-Liklihood loss term sampler_name: Name of O/SDE solver, does not effect training. sampler_steps: Steps used in generation, does not effect training. """ super().__init__() self.save_hyperparameters(logger=False) # Class attributes self.pc_dim = pc_dim self.ctxt_dim = ctxt_dim self.n_nodes = n_nodes self.loss_fn = get_loss_fn(loss_name) self.mle_loss_weight = mle_loss_weight self.ema_sync = ema_sync # The encoder and scheduler needed for diffusion self.diff_sched = VPDiffusionSchedule(**diff_config) self.time_encoder = CosineEncoding(**cosine_config) # The layer which normalises the input point cloud data self.normaliser = IterativeNormLayer((pc_dim,), **normaliser_config) if self.ctxt_dim: self.ctxt_normaliser = IterativeNormLayer((ctxt_dim,), **normaliser_config) # The denoising transformer self.net = FullTransformerEncoder( inpt_dim=pc_dim, outp_dim=pc_dim, ctxt_dim=ctxt_dim + self.time_encoder.outp_dim, **trans_enc_config, ) # A copy of the network which will sync with an exponential moving average self.ema_net = copy.deepcopy(self.net) # Sampler to run in the validation/testing loop self.sampler_name = sampler_name self.sampler_steps = sampler_steps # Record of the outputs of the validation step self.val_outs = [] def forward( self, noisy_data: T.Tensor, diffusion_times: T.Tensor, mask: T.BoolTensor, ctxt: Optional[T.Tensor] = None, ) -> T.Tensor: """Pass through the model and get an estimate of the noise added to the input.""" # Use the appropriate network for training or validation if self.training: network = self.net else: network = self.ema_net # Encode the times and combine with existing context info context = self.time_encoder(diffusion_times) if self.ctxt_dim: context = T.cat([context, ctxt], dim=-1) # Use the selected network to esitmate the noise present in the data return network(noisy_data, mask=mask, ctxt=context) def _shared_step(self, sample: tuple) -> Tuple[T.Tensor, T.Tensor]: """Shared step used in both training and validaiton.""" # Unpack the sample tuple nodes, mask, ctxt = sample # Pass through the normalisers nodes = self.normaliser(nodes, mask) if self.ctxt_dim: ctxt = self.ctxt_normaliser(ctxt) # Sample from the gaussian latent space to perturb the point clouds noises = T.randn_like(nodes) * mask.unsqueeze(-1) # Sample uniform random diffusion times and get the rates diffusion_times = T.rand(size=(len(nodes), 1), device=self.device) signal_rates, noise_rates = self.diff_sched(diffusion_times.view(-1, 1, 1)) # Mix the signal and noise according to the diffusion equation noisy_nodes = signal_rates * nodes + noise_rates * noises # Predict the noise using the network pred_noises = self.forward(noisy_nodes, diffusion_times, mask, ctxt) # Simple noise loss is for "perceptual quality" simple_loss = self.loss_fn(noises[mask], pred_noises[mask]) # MLE loss is for maximum liklihood training if self.mle_loss_weight: betas = self.diff_sched.get_betas(diffusion_times.view(-1, 1, 1)) mle_weights = betas / noise_rates mle_loss = mle_weights * simple_loss else: mle_loss = T.zeros_like(simple_loss) return simple_loss.mean(), mle_loss.mean() def training_step(self, sample: tuple, _batch_idx: int) -> T.Tensor: simple_loss, mle_loss = self._shared_step(sample) total_loss = simple_loss + self.mle_loss_weight * mle_loss self.log("train/simple_loss", simple_loss) self.log("train/mle_loss", mle_loss) self.log("train/total_loss", total_loss) self._sync_ema_network() return total_loss def validation_step(self, sample: tuple, batch_idx: int) -> None: simple_loss, mle_loss = self._shared_step(sample) total_loss = simple_loss + self.mle_loss_weight * mle_loss self.log("valid/simple_loss", simple_loss) self.log("valid/mle_loss", mle_loss) self.log("valid/total_loss", total_loss) # Run the full generation of the sample during a validation step outputs = self.full_generation( self.sampler_name, self.sampler_steps, mask=sample[1], ctxt=sample[2], ) # Add to the collection of the validaiton outputs self.val_outs.append((to_np(outputs), to_np(sample))) def on_validation_epoch_end(self) -> None: """At the end of the validation epoch, calculate and log the metrics and plot the histograms. This function right now only works with MPGAN configs """ # Combine all outputs gen_nodes = np.vstack([v[0] for v in self.val_outs]) real_nodes = np.vstack([v[1][0] for v in self.val_outs]) mask = np.vstack([v[1][1] for v in self.val_outs]) high = np.vstack([v[1][2] for v in self.val_outs]) # Change the data from log(pt+1) into pt fraction (needed for metrics) if self.trainer.datamodule.hparams.data_conf.log_squash_pt: gen_nodes[..., -1] = undo_log_squash(gen_nodes[..., -1]) / high[..., 0:1] real_nodes[..., -1] = undo_log_squash(real_nodes[..., -1]) / high[..., 0:1] # Apply clipping gen_nodes = np.nan_to_num(gen_nodes) gen_nodes[..., 0] = np.clip(gen_nodes[..., 0], -0.5, 0.5) gen_nodes[..., 1] = np.clip(gen_nodes[..., 1], -0.5, 0.5) gen_nodes[..., 2] = np.clip(gen_nodes[..., 2], 0, 1) real_nodes = np.nan_to_num(real_nodes) real_nodes[..., 0] = np.clip(real_nodes[..., 0], -0.5, 0.5) real_nodes[..., 1] = np.clip(real_nodes[..., 1], -0.5, 0.5) real_nodes[..., 2] = np.clip(real_nodes[..., 2], 0, 1) # Calculate and log the Wasserstein discriminants bootstrap = { "num_eval_samples": 10000, "num_batches": 10, } w1m_val, w1m_err = w1m(real_nodes, gen_nodes, **bootstrap) w1p_val, w1p_err = w1p(real_nodes, gen_nodes, **bootstrap) w1efp_val, w1efp_err = w1efp(real_nodes, gen_nodes, efp_jobs=1, **bootstrap) self.log("valid/w1m", w1m_val) self.log("valid/w1m_err", w1m_err) self.log("valid/w1p", w1p_val.mean()) self.log("valid/w1p_err", w1p_err.mean()) self.log("valid/w1efp", w1efp_val.mean()) self.log("valid/w1efp_err", w1efp_err.mean()) # Plot the MPGAN-like marginals plot_mpgan_marginals(gen_nodes, real_nodes, mask, self.trainer.current_epoch) self.val_outs.clear() def _sync_ema_network(self) -> None: """Updates the Exponential Moving Average Network.""" with T.no_grad(): for params, ema_params in zip( self.net.parameters(), self.ema_net.parameters() ): ema_params.data.copy_( self.ema_sync * ema_params.data + (1.0 - self.ema_sync) * params.data ) def on_fit_start(self, *_args) -> None: """Function to run at the start of training.""" # Define the metrics for wandb (otherwise the min wont be stored!) if wandb.run is not None: wandb.define_metric("train/simple_loss", summary="min") wandb.define_metric("train/mle_loss", summary="min") wandb.define_metric("train/total_loss", summary="min") wandb.define_metric("valid/simple_loss", summary="min") wandb.define_metric("valid/mle_loss", summary="min") wandb.define_metric("valid/total_loss", summary="min") wandb.define_metric("valid/w1m", summary="min") wandb.define_metric("valid/w1p", summary="min") wandb.define_metric("valid/w1efp", summary="min") def set_sampler( self, sampler_name: Optional[str] = None, sampler_steps: Optional[int] = None ) -> None: """Replaces the sampler list with a new one.""" if sampler_name is not None: self.sampler_name = sampler_name if sampler_steps is not None: self.sampler_steps = sampler_steps def full_generation( self, sampler: str, steps: int, mask: Optional[T.BoolTensor] = None, ctxt: Optional[T.Tensor] = None, initial_noise: Optional[T.Tensor] = None, ) -> T.Tensor: """Fully generate a batch of data from noise, given context information and a mask.""" # Either a mask or initial noise must be defined or we dont know how # many samples to generate and with what cardinality if mask is None and initial_noise is None: raise ValueError("Please provide either a mask or noise to generate from") if mask is None: mask = T.full(initial_noise.shape[:-1], True, device=self.device) if initial_noise is None: initial_noise = T.randn((*mask.shape, self.pc_dim), device=self.device) # Normalise the context if self.ctxt_dim: ctxt = self.ctxt_normaliser(ctxt) assert len(ctxt) == len(initial_noise) # Run the sampling method outputs, _ = run_sampler( sampler, self, self.diff_sched, initial_noise=initial_noise * mask.unsqueeze(-1), n_steps=steps, mask=mask, ctxt=ctxt, clip_predictions=(-25, 25), ) # Ensure that the output adheres to the mask outputs[~mask] = 0 # Return the normalisation of the generated point cloud return self.normaliser.reverse(outputs, mask=mask) def configure_optimizers(self) -> dict: """Configure the optimisers and learning rate sheduler for this model.""" # Finish initialising the optimiser and create the scheduler opt = self.hparams.optimizer(params=self.parameters()) sched = WarmupToConstant(opt, num_steps=10_000) # Return the dict for the lightning trainer return { "optimizer": opt, "lr_scheduler": { "scheduler": sched, "interval": "step", "frequency": 1, }, }

py

PC-JeDi

PC-JeDi-main/src/models/__init__.py

py

PC-JeDi

PC-JeDi-main/scripts/train.py

import pyrootutils root = pyrootutils.setup_root(search_from=__file__, pythonpath=True) import logging import hydra import pytorch_lightning as pl from omegaconf import DictConfig from src.hydra_utils import ( instantiate_collection, log_hyperparameters, print_config, reload_original_config, save_config, ) log = logging.getLogger(__name__) @hydra.main( version_base=None, config_path=str(root / "configs"), config_name="train.yaml" ) def main(cfg: DictConfig) -> None: log.info("Setting up full job config") if cfg.full_resume: cfg = reload_original_config(cfg) print_config(cfg) if cfg.seed: log.info(f"Setting seed to: {cfg.seed}") pl.seed_everything(cfg.seed, workers=True) log.info("Instantiating the data module") datamodule = hydra.utils.instantiate(cfg.datamodule) log.info("Instantiating the model") model = hydra.utils.instantiate( cfg.model, pc_dim=datamodule.dim, n_nodes=datamodule.n_nodes, ctxt_dim=datamodule.ctxt_dim, ) log.info(model) log.info("Instantiating all callbacks") callbacks = instantiate_collection(cfg.callbacks) log.info("Instantiating the loggers") loggers = instantiate_collection(cfg.loggers) log.info("Instantiating the trainer") trainer = hydra.utils.instantiate(cfg.trainer, callbacks=callbacks, logger=loggers) if loggers: log.info("Logging all hyperparameters") log_hyperparameters(cfg, model, trainer) log.info("Saving config so job can be resumed") save_config(cfg) log.info("Starting training!") trainer.fit(model, datamodule, ckpt_path=cfg.ckpt_path) if __name__ == "__main__": main()

py

trees_from_transformers

trees_from_transformers-master/run.py

import argparse import datetime import logging import os import pickle from tqdm import tqdm import torch from transformers import * from data.dataset import Dataset from utils.measure import Measure from utils.parser import not_coo_parser, parser from utils.tools import set_seed, select_indices, group_indices from utils.yk import get_actions, get_nonbinary_spans MODELS = [(BertModel, BertTokenizer, BertConfig, 'bert-base-cased'), (BertModel, BertTokenizer, BertConfig, 'bert-large-cased'), (GPT2Model, GPT2Tokenizer, GPT2Config, 'gpt2'), (GPT2Model, GPT2Tokenizer, GPT2Config, 'gpt2-medium'), (RobertaModel, RobertaTokenizer, RobertaConfig, 'roberta-base'), (RobertaModel, RobertaTokenizer, RobertaConfig, 'roberta-large'), (XLNetModel, XLNetTokenizer, XLNetConfig, 'xlnet-base-cased'), (XLNetModel, XLNetTokenizer, XLNetConfig, 'xlnet-large-cased')] def evaluate(args): scores = dict() for model_class, tokenizer_class, model_config, pretrained_weights in MODELS: tokenizer = tokenizer_class.from_pretrained( pretrained_weights, cache_dir=args.lm_cache_path) if args.from_scratch: config = model_config.from_pretrained(pretrained_weights) config.output_hidden_states = True config.output_attentions = True model = model_class(config).to(args.device) else: model = model_class.from_pretrained( pretrained_weights, cache_dir=args.lm_cache_path, output_hidden_states=True, output_attentions=True).to(args.device) with torch.no_grad(): test_sent = tokenizer.encode('test', add_special_tokens=False) token_ids = torch.tensor([test_sent]).to(args.device) all_hidden, all_att = model(token_ids)[-2:] n_layers = len(all_att) n_att = all_att[0].size(1) n_hidden = all_hidden[0].size(-1) measure = Measure(n_layers, n_att) data = Dataset(path=args.data_path, tokenizer=tokenizer) for idx, s in tqdm(enumerate(data.sents), total=len(data.sents), desc=pretrained_weights, ncols=70): raw_tokens = data.raw_tokens[idx] tokens = data.tokens[idx] if len(raw_tokens) < 2: data.cnt -= 1 continue token_ids = tokenizer.encode(s, add_special_tokens=False) token_ids_tensor = torch.tensor([token_ids]).to(args.device) with torch.no_grad(): all_hidden, all_att = model(token_ids_tensor)[-2:] all_hidden, all_att = list(all_hidden[1:]), list(all_att) # (n_layers, seq_len, hidden_dim) all_hidden = torch.cat([all_hidden[n] for n in range(n_layers)], dim=0) # (n_layers, n_att, seq_len, seq_len) all_att = torch.cat([all_att[n] for n in range(n_layers)], dim=0) if len(tokens) > len(raw_tokens): th = args.token_heuristic if th == 'first' or th == 'last': mask = select_indices(tokens, raw_tokens, pretrained_weights, th) assert len(mask) == len(raw_tokens) all_hidden = all_hidden[:, mask] all_att = all_att[:, :, mask, :] all_att = all_att[:, :, :, mask] else: # mask = torch.tensor(data.masks[idx]) mask = group_indices(tokens, raw_tokens, pretrained_weights) raw_seq_len = len(raw_tokens) all_hidden = torch.stack( [all_hidden[:, mask == i].mean(dim=1) for i in range(raw_seq_len)], dim=1) all_att = torch.stack( [all_att[:, :, :, mask == i].sum(dim=3) for i in range(raw_seq_len)], dim=3) all_att = torch.stack( [all_att[:, :, mask == i].mean(dim=2) for i in range(raw_seq_len)], dim=2) l_hidden, r_hidden = all_hidden[:, :-1], all_hidden[:, 1:] l_att, r_att = all_att[:, :, :-1], all_att[:, :, 1:] syn_dists = measure.derive_dists(l_hidden, r_hidden, l_att, r_att) gold_spans = data.gold_spans[idx] gold_tags = data.gold_tags[idx] assert len(gold_spans) == len(gold_tags) for m, d in syn_dists.items(): pred_spans = [] for i in range(measure.scores[m].n): dist = syn_dists[m][i].tolist() if len(dist) > 1: bias_base = (sum(dist) / len(dist)) * args.bias bias = [bias_base * (1 - (1 / (len(dist) - 1)) * x) for x in range(len(dist))] dist = [dist[i] + bias[i] for i in range(len(dist))] if args.use_not_coo_parser: pred_tree = not_coo_parser(dist, raw_tokens) else: pred_tree = parser(dist, raw_tokens) ps = get_nonbinary_spans(get_actions(pred_tree))[0] pred_spans.append(ps) measure.scores[m].update(pred_spans, gold_spans, gold_tags) measure.derive_final_score() scores[pretrained_weights] = measure.scores if not os.path.exists(args.result_path): os.makedirs(args.result_path) with open(f'{args.result_path}/{pretrained_weights}.txt', 'w') as f: print('Model name:', pretrained_weights, file=f) print('Experiment time:', args.time, file=f) print('# of layers:', n_layers, file=f) print('# of attentions:', n_att, file=f) print('# of hidden dimensions:', n_hidden, file=f) print('# of processed sents:', data.cnt, file=f) max_corpus_f1, max_sent_f1 = 0, 0 for n in range(n_layers): print(f'[Layer {n + 1}]', file=f) print('-' * (119 + measure.max_m_len), file=f) for m, s in measure.scores.items(): if m in measure.h_measures + measure.a_avg_measures: print( f'| {m.upper()} {" " * (measure.max_m_len - len(m))} ' f'| Corpus F1: {s.corpus_f1[n] * 100:.2f} ' f'| Sent F1: {s.sent_f1[n] * 100:.2f} ', end='', file=f) for z in range(len(s.label_recalls[0])): print( f'| {s.labels[z]}: ' f'{s.label_recalls[n][z] * 100:.2f} ', end='', file=f) print('|', file=f) if s.sent_f1[n] > max_sent_f1: max_corpus_f1 = s.corpus_f1[n] max_sent_f1 = s.sent_f1[n] max_measure = m max_layer = n + 1 else: for i in range(n_att): m_att = str(i) if i > 9 else '0' + str(i) m_att = m + m_att + " " * ( measure.max_m_len - len(m)) i_att = n_att * n + i print( f'| {m_att.upper()}' f'| Corpus F1: {s.corpus_f1[i_att] * 100:.2f} ' f'| Sent F1: {s.sent_f1[i_att] * 100:.2f} ', end='', file=f) for z in range(len(s.label_recalls[0])): print(f'| {s.labels[z]}: ' f'{s.label_recalls[i_att][z] * 100:.2f} ', end='', file=f) print('|', file=f) if s.sent_f1[i_att] > max_sent_f1: max_corpus_f1 = s.corpus_f1[i_att] max_sent_f1 = s.sent_f1[i_att] max_measure = m_att max_layer = n + 1 print('-' * (119 + measure.max_m_len), file=f) print(f'[MAX]: | Layer: {max_layer} ' f'| {max_measure.upper()} ' f'| Corpus F1: {max_corpus_f1 * 100:.2f} ' f'| Sent F1: {max_sent_f1 * 100:.2f} |') print(f'[MAX]: | Layer: {max_layer} ' f'| {max_measure.upper()} ' f'| Corpus F1: {max_corpus_f1 * 100:.2f} ' f'| Sent F1: {max_sent_f1 * 100:.2f} |', file=f) return scores def main(): parser = argparse.ArgumentParser() parser.add_argument('--data-path', default='.data/PTB/ptb-test.txt', type=str) parser.add_argument('--result-path', default='outputs', type=str) parser.add_argument('--lm-cache-path', default='/data/transformers', type=str) parser.add_argument('--from-scratch', default=False, action='store_true') parser.add_argument('--gpu', default=0, type=int) parser.add_argument('--bias', default=0.0, type=float, help='the right-branching bias hyperparameter lambda') parser.add_argument('--seed', default=1234, type=int) parser.add_argument('--token-heuristic', default='mean', type=str, help='Available options: mean, first, last') parser.add_argument('--use-not-coo-parser', default=False, action='store_true', help='Turning on this option will allow you to exploit ' 'the NOT-COO parser (named by Dyer et al. 2019), ' 'which has been broadly adopted by recent methods ' 'for unsupervised parsing. As this parser utilizes' ' the right-branching bias in its inner workings, ' 'it may give rise to some unexpected gains or ' 'latent issues for the resulting trees. For more ' 'details, see https://arxiv.org/abs/1909.09428.') args = parser.parse_args() setattr(args, 'device', f'cuda:{args.gpu}' if torch.cuda.is_available() and args.gpu >= 0 else 'cpu') setattr(args, 'time', datetime.datetime.now().strftime('%Y%m%d-%H:%M:%S')) dataset_name = args.data_path.split('/')[-1].split('.')[0] parser = '-w-not-coo-parser' if args.use_not_coo_parser else '' pretrained = 'scratch' if args.from_scratch else 'pretrained' result_path = f'{args.result_path}/{dataset_name}-{args.token_heuristic}' result_path += f'-{pretrained}-{args.bias}{parser}' setattr(args, 'result_path', result_path) set_seed(args.seed) logging.disable(logging.WARNING) print('[List of arguments]') for a in args.__dict__: print(f'{a}: {args.__dict__[a]}') scores = evaluate(args) with open(f'{args.result_path}/scores.pickle', 'wb') as f: pickle.dump(scores, f) if __name__ == '__main__': main()

py

trees_from_transformers

trees_from_transformers-master/utils/yk.py

""" The functions in this file are originated from the code for Compound Probabilistic Context-Free Grammars for Grammar Induction, Y. Kim et al., ACL 2019. For more details, visit https://github.com/harvardnlp/compound-pcfg. """ import re def clean_number(w): new_w = re.sub('[0-9]{1,}([,.]?[0-9]*)*', 'N', w) return new_w def get_stats(span1, span2): tp = 0 fp = 0 fn = 0 for span in span1: if span in span2: tp += 1 else: fp += 1 for span in span2: if span not in span1: fn += 1 return tp, fp, fn def get_nonbinary_spans(actions, SHIFT=0, REDUCE=1): spans = [] tags = [] stack = [] pointer = 0 binary_actions = [] nonbinary_actions = [] num_shift = 0 num_reduce = 0 for action in actions: # print(action, stack) if action == "SHIFT": nonbinary_actions.append(SHIFT) stack.append((pointer, pointer)) pointer += 1 binary_actions.append(SHIFT) num_shift += 1 elif action[:3] == 'NT(': # stack.append('(') stack.append(action[3:-1].split('-')[0]) elif action == "REDUCE": nonbinary_actions.append(REDUCE) right = stack.pop() left = right n = 1 # while stack[-1] is not '(': while type(stack[-1]) is tuple: left = stack.pop() n += 1 span = (left[0], right[1]) tag = stack.pop() if left[0] != right[1]: spans.append(span) tags.append(tag) stack.append(span) while n > 1: n -= 1 binary_actions.append(REDUCE) num_reduce += 1 else: assert False assert (len(stack) == 1) assert (num_shift == num_reduce + 1) return spans, tags, binary_actions, nonbinary_actions def get_actions(line): output_actions = [] line_strip = line.rstrip() i = 0 max_idx = (len(line_strip) - 1) while i <= max_idx: assert line_strip[i] == '(' or line_strip[i] == ')' if line_strip[i] == '(': if is_next_open_bracket(line_strip, i): # open non-terminal curr_NT = get_nonterminal(line_strip, i) output_actions.append('NT(' + curr_NT + ')') i += 1 # get the next open bracket, # which may be a terminal or another non-terminal while line_strip[i] != '(': i += 1 else: # it's a terminal symbol output_actions.append('SHIFT') while line_strip[i] != ')': i += 1 i += 1 while line_strip[i] != ')' and line_strip[i] != '(': i += 1 else: output_actions.append('REDUCE') if i == max_idx: break i += 1 while line_strip[i] != ')' and line_strip[i] != '(': i += 1 assert i == max_idx return output_actions def is_next_open_bracket(line, start_idx): for char in line[(start_idx + 1):]: if char == '(': return True elif char == ')': return False raise IndexError('Bracket possibly not balanced, ' 'open bracket not followed by closed bracket') def get_nonterminal(line, start_idx): assert line[start_idx] == '(' # make sure it's an open bracket output = [] for char in line[(start_idx + 1):]: if char == ' ': break assert not (char == '(') and not (char == ')') output.append(char) return ''.join(output) def get_tags_tokens_lowercase(line): output = [] line_strip = line.rstrip() for i in range(len(line_strip)): if i == 0: assert line_strip[i] == '(' # fulfilling this condition means this is a terminal symbol if line_strip[i] == '(' and not (is_next_open_bracket(line_strip, i)): output.append(get_between_brackets(line_strip, i)) # print 'output:',output output_tags = [] output_tokens = [] output_lowercase = [] for terminal in output: terminal_split = terminal.split() # print(terminal, terminal_split) assert len( terminal_split) == 2 # each terminal contains a POS tag and word output_tags.append(terminal_split[0]) output_tokens.append(terminal_split[1]) output_lowercase.append(terminal_split[1].lower()) return [output_tags, output_tokens, output_lowercase] def get_between_brackets(line, start_idx): output = [] for char in line[(start_idx + 1):]: if char == ')': break assert not (char == '(') output.append(char) return ''.join(output)

py

trees_from_transformers

trees_from_transformers-master/utils/parser.py

import numpy as np def not_coo_parser(score, sent): assert len(score) == len(sent) - 1 if len(score) == 0: parse_tree = f'(T {sent[0]} )' elif len(score) == 1: parse_tree = f'(T (T {sent[0]} ) (T {sent[1]} ) )' else: idx_max = np.argmax(score) l_len = len(sent[:idx_max + 1]) r_len = len(sent[idx_max + 2:]) if l_len > 0 and r_len > 0: l_tree = not_coo_parser(score[:idx_max], sent[:idx_max + 1]) r_tree = not_coo_parser(score[idx_max + 2:], sent[idx_max + 2:]) r_tree = f'(T (T {sent[idx_max +1]} ) {r_tree} )' parse_tree = f'(T {l_tree} {r_tree} )' else: if l_len == 0: r_tree = not_coo_parser(score[idx_max + 2:], sent[idx_max + 2:]) r_tree = f'(T (T {sent[idx_max +1]} ) {r_tree} )' parse_tree = r_tree else: l_tree = not_coo_parser(score[:idx_max], sent[:idx_max + 1]) parse_tree = f'(T {l_tree} (T {sent[idx_max + 1]} ) )' return parse_tree def parser(score, sent): assert len(score) == len(sent) - 1 if len(score) == 0: parse_tree = f'(T {sent[0]} )' elif len(score) == 1: parse_tree = f'(T (T {sent[0]} ) (T {sent[1]} ) )' else: idx_max = np.argmax(score) l_len = len(sent[:idx_max + 1]) r_len = len(sent[idx_max + 1:]) if l_len > 0 and r_len > 0: l_tree = parser(score[:idx_max], sent[:idx_max + 1]) r_tree = parser(score[idx_max + 1:], sent[idx_max + 1:]) parse_tree = f'(T {l_tree} {r_tree} )' else: if l_len == 0: r_tree = parser(score[idx_max + 1:], sent[idx_max + 1:]) parse_tree = r_tree else: l_tree = parser(score[:idx_max], sent[:idx_max + 1]) parse_tree = l_tree return parse_tree

py

trees_from_transformers

trees_from_transformers-master/utils/score.py

import numpy as np import torch from utils.yk import get_stats class Score(object): def __init__(self, n): self.corpus_f1 = torch.zeros(n, 3, dtype=torch.float) self.sent_f1 = torch.zeros(n, dtype=torch.float) self.n = n self.cnt = 0 self.labels = ['SBAR', 'NP', 'VP', 'PP', 'ADJP', 'ADVP'] self.label_recalls = np.zeros((n, 6), dtype=float) self.label_cnts = np.zeros(6, dtype=float) def update(self, pred_spans, gold_spans, gold_tags): pred_sets = [set(ps[:-1]) for ps in pred_spans] gold_set = set(gold_spans[:-1]) self.update_corpus_f1(pred_sets, gold_set) self.update_sentence_f1(pred_sets, gold_set) self.update_label_recalls(pred_spans, gold_spans, gold_tags) self.cnt += 1 def update_label_recalls(self, pred, gold, tags): for i, tag in enumerate(tags): if tag not in self.labels: continue tag_idx = self.labels.index(tag) self.label_cnts[tag_idx] += 1 for z in range(len(pred)): if gold[i] in pred[z]: self.label_recalls[z][tag_idx] += 1 def update_corpus_f1(self, pred, gold): stats = torch.tensor([get_stats(pred[i], gold) for i in range(self.n)], dtype=torch.float) self.corpus_f1 += stats def update_sentence_f1(self, pred, gold): # sent-level F1 is based on L83-89 from # https://github.com/yikangshen/PRPN/test_phrase_grammar.py for i in range(self.n): model_out, std_out = pred[i], gold overlap = model_out.intersection(std_out) prec = float(len(overlap)) / (len(model_out) + 1e-8) reca = float(len(overlap)) / (len(std_out) + 1e-8) if len(std_out) == 0: reca = 1. if len(model_out) == 0: prec = 1. f1 = 2 * prec * reca / (prec + reca + 1e-8) self.sent_f1[i] += f1 def derive_final_score(self): tp = self.corpus_f1[:, 0] fp = self.corpus_f1[:, 1] fn = self.corpus_f1[:, 2] prec = tp / (tp + fp) recall = tp / (tp + fn) epsilon = 1e-8 self.corpus_f1 = 2 * prec * recall / (prec + recall + epsilon) self.sent_f1 /= self.cnt for i in range(len(self.label_recalls)): for j in range(len(self.label_recalls[0])): self.label_recalls[i][j] /= self.label_cnts[j]

py

trees_from_transformers

trees_from_transformers-master/utils/tools.py

import logging import random import torch specials = {'bert': '#', 'gpt2': 'Ġ', 'xlnet': '▁', 'roberta': 'Ġ'} def set_seed(seed): torch.manual_seed(seed) torch.cuda.manual_seed(seed) random.seed(seed) def select_indices(tokens, raw_tokens, model, mode): mask = [] raw_i = 0 collapsed = '' model = model.split('-')[0] special = specials[model] for i in range(len(tokens)): token = tokens[i] while len(token) > 0 and token[0] == special: token = token[1:] if collapsed == '' and len(token) > 0: start_idx = i collapsed += token if collapsed == raw_tokens[raw_i]: if mode == 'first': mask.append(start_idx) elif mode == 'last': mask.append(i) else: raise NotImplementedError raw_i += 1 collapsed = '' if raw_i != len(raw_tokens): raise Exception(f'Token mismatch: \n{tokens}\n{raw_tokens}') return mask def group_indices(tokens, raw_tokens, model): mask = [] raw_i = 0 collapsed = '' model = model.split('-')[0] special = specials[model] for i in range(len(tokens)): token = tokens[i] while len(token) > 0 and token[0] == special: token = token[1:] collapsed += token mask.append(raw_i) if collapsed == raw_tokens[raw_i]: raw_i += 1 collapsed = '' if raw_i != len(raw_tokens): raise Exception(f'Token mismatch: \n{tokens}\n{raw_tokens}') return torch.tensor(mask)

py

trees_from_transformers

trees_from_transformers-master/utils/extractor.py

import torch import torch.nn as nn import torch.nn.functional as F class Extractor(nn.Module): def __init__(self, n_hidden): super(Extractor, self).__init__() self.linear = nn.Linear(n_hidden * 2, 1) nn.init.uniform_(self.linear.weight, -0.01, 0.01) nn.init.uniform_(self.linear.bias, 0) def forward(self, l, r): h = torch.cat([l, r], dim=-1) o = self.linear(h) # (seq_len-1) return o.squeeze(-1) def loss(self, d, gold): assert len(d) == len(gold) gold = d.new_tensor(gold) l = 0 for i in range(len(d)): for j in range(i+1, len(d)): l += F.relu(1 - torch.sign(gold[i]- gold[j]) * (d[i] - d[j])) return l

py

trees_from_transformers

trees_from_transformers-master/utils/measure.py

import math import torch import torch.nn.functional as F from utils.score import Score class Measure(object): def __init__(self, n_layers, n_att): self.h_measures = ['cos', 'l1', 'l2'] self.a_measures = ['hellinger', 'jsd'] self.a_avg_measures = ['avg_hellinger', 'avg_jsd'] self.measures = self.h_measures + self.a_measures + self.a_avg_measures self.max_m_len = max([len(m) for m in self.measures]) + 2 self.scores = {m: Score(n_layers) for m in self.h_measures} for m in self.a_measures: self.scores[m] = Score(n_layers * n_att) for m in self.a_avg_measures: self.scores[m] = Score(n_layers) def derive_dists(self, l_hidden, r_hidden, l_att, r_att): syn_dists = {} for m in self.h_measures: syn_dists[m] = getattr(self, m)(l_hidden, r_hidden) for m in self.a_measures: syn_dists[m] = getattr(self, m)(l_att, r_att) syn_dists[m] = syn_dists[m].view(-1, syn_dists[m].size(-1)) for m in self.a_avg_measures: syn_dists[m] = getattr(self, m)(l_att, r_att) return syn_dists def derive_final_score(self): for m in self.scores.keys(): self.scores[m].derive_final_score() @staticmethod def cos(l_hidden, r_hidden): # (n_layers, seq_len-1, hidden_dim) * 2 -> (n_layers, seq_len-1) return (F.cosine_similarity(l_hidden, r_hidden, dim=-1) + 1) / 2 @staticmethod def l1(l_hidden, r_hidden): # (n_layers, seq_len-1, hidden_dim) * 2 -> (n_layers, seq_len-1) return torch.norm(l_hidden - r_hidden, p=1, dim=-1) @staticmethod def l2(l_hidden, r_hidden): # (n_layers, seq_len-1, hidden_dim) * 2 -> (n_layers, seq_len-1) return torch.norm(l_hidden - r_hidden, p=2, dim=-1) @staticmethod def kl(p, q): eps = 1e-30 p, q = p + eps, q + eps p, q = p / p.sum(dim=-1, keepdim=True), q / q.sum(dim=-1, keepdim=True) kl = F.kl_div(torch.log(q), p, reduction='none').sum(dim=-1) # kl = (p * (torch.log(p) - torch.log(q))).sum(dim=-1) # To deal with the numerical instability of the KL-div function in PyTorch if (kl < 0).sum() > 0: kl = kl * (1 - (kl < 0).float()) assert torch.isinf(kl).sum() == 0 assert torch.isnan(kl).sum() == 0 return kl @staticmethod def jsd(l_att, r_att): m = (l_att + r_att) / 2 l_kl = Measure.kl(l_att, m) r_kl = Measure.kl(r_att, m) d = torch.sqrt((l_kl + r_kl) / 2) assert (d < 0).sum() == 0 assert torch.isnan(d).sum() == 0 return d @staticmethod def hellinger(l_att, r_att): d = (((l_att.sqrt() - r_att.sqrt()) ** 2).sum(dim=-1)).sqrt() d /= math.sqrt(2) return d @staticmethod def avg_hellinger(l_att, r_att): d = Measure.hellinger(l_att, r_att) return d.mean(dim=1) @staticmethod def avg_jsd(l_att, r_att): d = Measure.jsd(l_att, r_att) return d.mean(dim=1)

py

trees_from_transformers

trees_from_transformers-master/data/dataset.py

from utils.yk import get_actions, get_nonbinary_spans, get_tags_tokens_lowercase class Dataset(object): def __init__(self, path, tokenizer): self.path = path self.tokenizer = tokenizer self.cnt = 0 self.sents = [] self.raw_tokens = [] self.tokens = [] self.masks = [] self.gold_spans = [] self.gold_tags = [] self.gold_trees = [] flatten = lambda l: [item for sublist in l for item in sublist] with open(path, 'r') as f: lines = f.readlines() for line in lines: raw_tokens = get_tags_tokens_lowercase(line)[1] sent = ' '.join(raw_tokens) actions = get_actions(line) self.cnt += 1 self.sents.append(sent) self.raw_tokens.append(raw_tokens) self.tokens.append(self.tokenizer.tokenize(sent)) mask = [len(self.tokenizer.tokenize(w)) * [i] for i, w in enumerate(sent.split())] self.masks.append(flatten(mask)) gold_spans, gold_tags, _, _ = get_nonbinary_spans(actions) self.gold_spans.append(gold_spans) self.gold_tags.append(gold_tags) self.gold_trees.append(line.strip())

py

pi-peps

pi-peps-master/docs/source/conf.py

# -*- coding: utf-8 -*- # # Configuration file for the Sphinx documentation builder. # # This file does only contain a selection of the most common options. For a # full list see the documentation: # http://www.sphinx-doc.org/en/master/config # -- Path setup -------------------------------------------------------------- # If extensions (or modules to document with autodoc) are in another directory, # add these directories to sys.path here. If the directory is relative to the # documentation root, use os.path.abspath to make it absolute, like shown here. # # import os # import sys # sys.path.insert(0, os.path.abspath('.')) # -- Project information ----------------------------------------------------- project = 'pi-peps' copyright = '2019, Juraj Hasik, Alberto Sartori' author = 'Juraj Hasik, Alberto Sartori' # The short X.Y version version = '' # The full version, including alpha/beta/rc tags release = '' # -- General configuration --------------------------------------------------- # If your documentation needs a minimal Sphinx version, state it here. # # needs_sphinx = '1.0' # Add any Sphinx extension module names here, as strings. They can be # extensions coming with Sphinx (named 'sphinx.ext.*') or your custom # ones. extensions = [ 'sphinx.ext.todo', 'sphinx.ext.coverage', 'sphinx.ext.mathjax', 'sphinx.ext.ifconfig', 'sphinx.ext.githubpages', ] # Add any paths that contain templates here, relative to this directory. templates_path = ['_templates'] # The suffix(es) of source filenames. # You can specify multiple suffix as a list of string: # # source_suffix = ['.rst', '.md'] source_suffix = '.rst' # The master toctree document. master_doc = 'index' # The language for content autogenerated by Sphinx. Refer to documentation # for a list of supported languages. # # This is also used if you do content translation via gettext catalogs. # Usually you set "language" from the command line for these cases. language = None # List of patterns, relative to source directory, that match files and # directories to ignore when looking for source files. # This pattern also affects html_static_path and html_extra_path . exclude_patterns = [] # The name of the Pygments (syntax highlighting) style to use. pygments_style = 'sphinx' # -- Options for HTML output ------------------------------------------------- # The theme to use for HTML and HTML Help pages. See the documentation for # a list of builtin themes. # html_theme = 'sphinx_rtd_theme' # Theme options are theme-specific and customize the look and feel of a theme # further. For a list of options available for each theme, see the # documentation. # # html_theme_options = {} # Add any paths that contain custom static files (such as style sheets) here, # relative to this directory. They are copied after the builtin static files, # so a file named "default.css" will overwrite the builtin "default.css". html_static_path = [] # Custom sidebar templates, must be a dictionary that maps document names # to template names. # # The default sidebars (for documents that don't match any pattern) are # defined by theme itself. Builtin themes are using these templates by # default: ``['localtoc.html', 'relations.html', 'sourcelink.html', # 'searchbox.html']``. # # html_sidebars = {} # -- Options for HTMLHelp output --------------------------------------------- # Output file base name for HTML help builder. htmlhelp_basename = 'pi-pepsdoc' # -- Options for LaTeX output ------------------------------------------------ latex_elements = { # The paper size ('letterpaper' or 'a4paper'). # # 'papersize': 'letterpaper', # The font size ('10pt', '11pt' or '12pt'). # # 'pointsize': '10pt', # Additional stuff for the LaTeX preamble. # # 'preamble': '', # Latex figure (float) alignment # # 'figure_align': 'htbp', } # Grouping the document tree into LaTeX files. List of tuples # (source start file, target name, title, # author, documentclass [howto, manual, or own class]). latex_documents = [ (master_doc, 'pi-peps.tex', 'pi-peps Documentation', 'Juraj Hasik, Alberto Sartori', 'manual'), ] # -- Options for manual page output ------------------------------------------ # One entry per manual page. List of tuples # (source start file, name, description, authors, manual section). man_pages = [ (master_doc, 'pi-peps', 'pi-peps Documentation', [author], 1) ] # -- Options for Texinfo output ---------------------------------------------- # Grouping the document tree into Texinfo files. List of tuples # (source start file, target name, title, author, # dir menu entry, description, category) texinfo_documents = [ (master_doc, 'pi-peps', 'pi-peps Documentation', author, 'pi-peps', 'One line description of project.', 'Miscellaneous'), ] # -- Options for Epub output ------------------------------------------------- # Bibliographic Dublin Core info. epub_title = project epub_author = author epub_publisher = author epub_copyright = copyright # The unique identifier of the text. This can be a ISBN number # or the project homepage. # # epub_identifier = '' # A unique identification for the text. # # epub_uid = '' # A list of files that should not be packed into the epub file. epub_exclude_files = ['search.html'] # -- Extension configuration ------------------------------------------------- # -- Options for todo extension ---------------------------------------------- # If true, `todo` and `todoList` produce output, else they produce nothing. todo_include_todos = True

py

SSTAP

SSTAP-main/post_processing.py

# -*- coding: utf-8 -*- import numpy as np import pandas as pd import json import multiprocessing as mp from utils import iou_with_anchors def load_json(file): with open(file) as json_file: data = json.load(json_file) return data def getDatasetDict(opt): df = pd.read_csv(opt["video_info"]) json_data = load_json(opt["video_anno"]) database = json_data video_dict = {} for i in range(len(df)): video_name = df.video.values[i] video_info = database[video_name] video_new_info = {} video_new_info['duration_frame'] = video_info['duration_frame'] video_new_info['duration_second'] = video_info['duration_second'] video_new_info["feature_frame"] = video_info['feature_frame'] video_subset = df.subset.values[i] video_new_info['annotations'] = video_info['annotations'] if video_subset == 'validation': video_dict[video_name] = video_new_info return video_dict def soft_nms(df, alpha, t1, t2): ''' df: proposals generated by network; alpha: alpha value of Gaussian decaying function; t1, t2: threshold for soft nms. ''' df = df.sort_values(by="score", ascending=False) tstart = list(df.xmin.values[:]) tend = list(df.xmax.values[:]) tscore = list(df.score.values[:]) rstart = [] rend = [] rscore = [] while len(tscore) > 1 and len(rscore) < 101: max_index = tscore.index(max(tscore)) tmp_iou_list = iou_with_anchors( np.array(tstart), np.array(tend), tstart[max_index], tend[max_index]) for idx in range(0, len(tscore)): if idx != max_index: tmp_iou = tmp_iou_list[idx] tmp_width = tend[max_index] - tstart[max_index] if tmp_iou > t1 + (t2 - t1) * tmp_width: tscore[idx] = tscore[idx] * np.exp(-np.square(tmp_iou) / alpha) rstart.append(tstart[max_index]) rend.append(tend[max_index]) rscore.append(tscore[max_index]) tstart.pop(max_index) tend.pop(max_index) tscore.pop(max_index) newDf = pd.DataFrame() newDf['score'] = rscore newDf['xmin'] = rstart newDf['xmax'] = rend return newDf def video_post_process(opt, video_list, video_dict): for video_name in video_list: df = pd.read_csv("./output/BMN_results/" + video_name + ".csv") if len(df) > 1: snms_alpha = opt["soft_nms_alpha"] # 0.4 snms_t1 = opt["soft_nms_low_thres"] # 0.5 snms_t2 = opt["soft_nms_high_thres"] # 0.9 df = soft_nms(df, snms_alpha, snms_t1, snms_t2) df = df.sort_values(by="score", ascending=False) video_info = video_dict[video_name] video_duration = float(video_info["duration_frame"] // 16 * 16) / video_info["duration_frame"] * video_info[ "duration_second"] proposal_list = [] for j in range(min(100, len(df))): tmp_proposal = {} tmp_proposal["score"] = df.score.values[j] tmp_proposal["segment"] = [max(0, df.xmin.values[j]) * video_duration, min(1, df.xmax.values[j]) * video_duration] proposal_list.append(tmp_proposal) result_dict[video_name[2:]] = proposal_list def BMN_post_processing(opt): video_dict = getDatasetDict(opt) video_list = list(video_dict.keys()) # [:100] global result_dict result_dict = mp.Manager().dict() num_videos = len(video_list) num_videos_per_thread = num_videos // opt["post_process_thread"] processes = [] for tid in range(opt["post_process_thread"] - 1): tmp_video_list = video_list[tid * num_videos_per_thread:(tid + 1) * num_videos_per_thread] p = mp.Process(target=video_post_process, args=(opt, tmp_video_list, video_dict)) p.start() processes.append(p) tmp_video_list = video_list[(opt["post_process_thread"] - 1) * num_videos_per_thread:] p = mp.Process(target=video_post_process, args=(opt, tmp_video_list, video_dict)) p.start() processes.append(p) for p in processes: p.join() result_dict = dict(result_dict) output_dict = {"version": "VERSION 1.3", "results": result_dict, "external_data": {}} outfile = open(opt["result_file"], "w") json.dump(output_dict, outfile) outfile.close() # opt = opts.parse_opt() # opt = vars(opt) # BSN_post_processing(opt)

py

SSTAP

SSTAP-main/main.py

import sys from dataset import VideoDataSet, VideoDataSet_unlabel from loss_function import bmn_loss_func, get_mask import os import json import torch import torch.nn.parallel import torch.nn.functional as F import torch.nn as nn import torch.optim as optim import numpy as np import opts from ipdb import set_trace from models import BMN, TemporalShift, TemporalShift_random import pandas as pd import random from post_processing import BMN_post_processing from eval import evaluation_proposal from ipdb import set_trace seed = 400 torch.manual_seed(seed) torch.cuda.manual_seed(seed) torch.cuda.manual_seed_all(seed) np.random.seed(seed) # Numpy module. random.seed(seed) # Python random module. torch.manual_seed(seed) torch.backends.cudnn.benchmark = False torch.backends.cudnn.deterministic = True os.environ["CUDA_VISIBLE_DEVICES"] = '0,1,2,3' blue = lambda x: '\033[94m' + x + '\033[0m' sys.dont_write_bytecode = True global_step = 0 eval_loss = [] consistency_rampup = 5 consistency = 6 # 30 # 3 # None def update_ema_variables(model, ema_model, alpha, global_step): # Use the true average until the exponential average is more correct alpha = min(1 - 1 / (global_step + 1), alpha) for ema_param, param in zip(ema_model.parameters(), model.parameters()): ema_param.data.mul_(alpha).add_(1 - alpha, param.data) def softmax_mse_loss(input_logits, target_logits): """Takes softmax on both sides and returns MSE loss Note: - Returns the sum over all examples. Divide by the batch size afterwards if you want the mean. - Sends gradients to inputs but not the targets. """ assert input_logits.size() == target_logits.size() # input_softmax = F.softmax(input_logits, dim=1) # target_softmax = F.softmax(target_logits, dim=1) # num_classes = input_logits.size()[1] # return F.mse_loss(input_softmax, target_softmax, reduction='sum') / num_classes # size_average=False return F.mse_loss(input_logits, target_logits, reduction='mean') def softmax_kl_loss(input_logits, target_logits): """Takes softmax on both sides and returns KL divergence Note: - Returns the sum over all examples. Divide by the batch size afterwards if you want the mean. - Sends gradients to inputs but not the targets. """ assert input_logits.size() == target_logits.size() # input_log_softmax = F.log_softmax(input_logits, dim=1) # target_softmax = F.softmax(target_logits, dim=1) # return F.kl_div(input_log_softmax, target_softmax, reduction='sum') return F.kl_div(input_logits, target_logits, reduction='mean') def Motion_MSEloss(output,clip_label,motion_mask=torch.ones(100).cuda()): z = torch.pow((output-clip_label),2) loss = torch.mean(motion_mask*z) return loss def sigmoid_rampup(current, rampup_length): """Exponential rampup from https://arxiv.org/abs/1610.02242""" if rampup_length == 0: return 1.0 else: current = np.clip(current, 0.0, rampup_length) phase = 1.0 - current / rampup_length return float(np.exp(-5.0 * phase * phase)) def linear_rampup(current, rampup_length): """Linear rampup""" assert current >= 0 and rampup_length >= 0 if current >= rampup_length: return 1.0 else: return current / rampup_length def cosine_rampdown(current, rampdown_length): """Cosine rampdown from https://arxiv.org/abs/1608.03983""" assert 0 <= current <= rampdown_length return float(.5 * (np.cos(np.pi * current / rampdown_length) + 1)) def get_current_consistency_weight(epoch): # Consistency ramp-up from https://arxiv.org/abs/1610.02242 return consistency * sigmoid_rampup(epoch, consistency_rampup) def train_BMN(data_loader, model, optimizer, epoch, bm_mask): model.train() epoch_pemreg_loss = 0 epoch_pemclr_loss = 0 epoch_tem_loss = 0 epoch_loss = 0 for n_iter, (input_data, label_confidence, label_start, label_end) in enumerate(data_loader): input_data = input_data.cuda() label_start = label_start.cuda() label_end = label_end.cuda() label_confidence = label_confidence.cuda() confidence_map, start, end = model(input_data) # [B, 2, 100, 100], [B,100],[B,100] loss = bmn_loss_func(confidence_map, start, end, label_confidence, label_start, label_end, bm_mask.cuda()) # loss = tem_loss + 10 * pem_reg_loss + pem_cls_loss # return loss, tem_loss, pem_reg_loss, pem_cls_loss optimizer.zero_grad() loss[0].backward() optimizer.step() epoch_pemreg_loss += loss[2].cpu().detach().numpy() epoch_pemclr_loss += loss[3].cpu().detach().numpy() epoch_tem_loss += loss[1].cpu().detach().numpy() epoch_loss += loss[0].cpu().detach().numpy() print( "BMN training loss(epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, total_loss: %.03f" % ( epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), epoch_loss / (n_iter + 1))) def train_BMN_Semi(data_loader, train_loader_unlabel, model, model_ema, optimizer, epoch, bm_mask): global global_step model.train() epoch_pemreg_loss = 0 epoch_pemclr_loss = 0 epoch_tem_loss = 0 epoch_loss = 0 consistency_loss_all = 0 consistency_loss_ema_all = 0 consistency_criterion = softmax_mse_loss # softmax_kl_loss temporal_perb = TemporalShift_random(400, 64) order_clip_criterion = nn.CrossEntropyLoss() consistency = True clip_order = True dropout2d = True temporal_re = True unlabeled_train_iter = iter(train_loader_unlabel) for n_iter, (input_data, label_confidence, label_start, label_end) in enumerate(data_loader): input_data = input_data.cuda() label_start = label_start.cuda() label_end = label_end.cuda() label_confidence = label_confidence.cuda() input_data_student = temporal_perb(input_data) if dropout2d: input_data_student = F.dropout2d(input_data_student, 0.2) else: input_data_student = F.dropout(input_data_student, 0.2) confidence_map, start, end = model(input_data_student) # [B, 2, 100, 100], [B,100],[B,100] loss = bmn_loss_func(confidence_map, start, end, label_confidence, label_start, label_end, bm_mask.cuda()) confidence_map = confidence_map * bm_mask.cuda() if temporal_re: input_recons = F.dropout2d(input_data.permute(0,2,1), 0.2).permute(0,2,1) else: input_recons = F.dropout2d(input_data, 0.2) recons_feature = model(input_recons, recons=True) try: input_data_unlabel= unlabeled_train_iter.next() input_data_unlabel = input_data_unlabel.cuda() except: unlabeled_train_iter = iter(train_loader_unlabel) input_data_unlabel = unlabeled_train_iter.next() input_data_unlabel = input_data_unlabel.cuda() input_data_unlabel_student = temporal_perb(input_data_unlabel) if dropout2d: input_data_unlabel_student = F.dropout2d(input_data_unlabel_student, 0.2) else: input_data_unlabel_student = F.dropout(input_data_unlabel_student, 0.2) confidence_map_unlabel_student, start_unlabel_student, end_unlabel_student = model(input_data_unlabel_student) confidence_map_unlabel_student = confidence_map_unlabel_student * bm_mask.cuda() # label input_data_label_student_flip = F.dropout2d(input_data.flip(2).contiguous(), 0.1) confidence_map_label_student_flip, start_label_student_flip, end_label_student_flip = model( input_data_label_student_flip) confidence_map_label_student_flip = confidence_map_label_student_flip * bm_mask.cuda() # unlabel input_data_unlabel_student_flip = F.dropout2d(input_data_unlabel.flip(2).contiguous(), 0.1) confidence_map_unlabel_student_flip, start_unlabel_student_flip, end_unlabel_student_flip = model( input_data_unlabel_student_flip) confidence_map_unlabel_student_flip = confidence_map_unlabel_student_flip * bm_mask.cuda() if temporal_re: recons_input_student = F.dropout2d(input_data_unlabel.permute(0,2,1), 0.2).permute(0,2,1) else: recons_input_student = F.dropout2d(input_data_unlabel, 0.2) recons_feature_unlabel_student = model(recons_input_student, recons=True) loss_recons = 0.0005 * ( Motion_MSEloss(recons_feature, input_data) + Motion_MSEloss(recons_feature_unlabel_student, input_data_unlabel)) # 0.0001 with torch.no_grad(): # input_data_unlabel = input_data_unlabel.cuda() input_data_ema = F.dropout(input_data, 0.05) # 0.3 confidence_map_teacher, start_teacher, end_teacher = model_ema(input_data_ema) confidence_map_teacher = confidence_map_teacher * bm_mask.cuda() input_data_unlabel_teacher = F.dropout(input_data_unlabel, 0.05) # 0.3 confidence_map_unlabel_teacher, start_unlabel_teacher, end_unlabel_teacher = model_ema( input_data_unlabel_teacher) confidence_map_unlabel_teacher = confidence_map_unlabel_teacher * bm_mask.cuda() # flip (label) out = torch.zeros_like(confidence_map_unlabel_teacher) out_m = confidence_map_unlabel_teacher.flip(3).contiguous() for i in range(100): out[:, :, i, :100 - i] = out_m[:, :, i, i:] confidence_map_unlabel_teacher_flip = out # flip (unlabel) out = torch.zeros_like(confidence_map_teacher) out_m = confidence_map_teacher.flip(3).contiguous() for i in range(100): out[:, :, i, :100 - i] = out_m[:, :, i, i:] confidence_map_label_teacher_flip = out # start_unlabel_teacher_flip = start_unlabel_teacher.flip(1).contiguous() # end_unlabel_teacher_flip = end_unlabel_teacher.flip(1).contiguous() # add mask start_unlabel_teacher[start_unlabel_teacher >= 0.9] = 1.0 start_unlabel_teacher[start_unlabel_teacher <= 0.1] = 0.0 # 2_add end_unlabel_teacher[end_unlabel_teacher >= 0.9] = 1.0 end_unlabel_teacher[end_unlabel_teacher <= 0.1] = 0.0 # flip (label) start_label_teacher_flip = start_teacher.flip(1).contiguous() end_label_teacher_flip = end_teacher.flip(1).contiguous() # flip (unlabel) start_unlabel_teacher_flip = start_unlabel_teacher.flip(1).contiguous() end_unlabel_teacher_flip = end_unlabel_teacher.flip(1).contiguous() mask = torch.eq( (start_unlabel_teacher.max(1)[0] > 0.6).float() + (end_unlabel_teacher.max(1)[0] > 0.6).float(), 2.) confidence_map_unlabel_teacher = confidence_map_unlabel_teacher[mask] start_unlabel_teacher = start_unlabel_teacher[mask] end_unlabel_teacher = end_unlabel_teacher[mask] # flip confidence_map_unlabel_teacher_flip = confidence_map_unlabel_teacher_flip[mask] start_unlabel_teacher_flip = start_unlabel_teacher_flip[mask] end_unlabel_teacher_flip = end_unlabel_teacher_flip[mask] # add mask confidence_map_unlabel_student = confidence_map_unlabel_student[mask] start_unlabel_student = start_unlabel_student[mask] end_unlabel_student = end_unlabel_student[mask] # flip add mask confidence_map_unlabel_student_flip = confidence_map_unlabel_student_flip[mask] start_unlabel_student_flip = start_unlabel_student_flip[mask] end_unlabel_student_flip = end_unlabel_student_flip[mask] if consistency: consistency_weight = get_current_consistency_weight(epoch) # meters.update('cons_weight', consistency_weight) # set_trace() consistency_loss = consistency_weight * (consistency_criterion(confidence_map, confidence_map_teacher) + consistency_criterion(start, start_teacher) + consistency_criterion(end, end_teacher)) consistency_loss_ema = consistency_weight * ( consistency_criterion(confidence_map_unlabel_teacher, confidence_map_unlabel_student) + consistency_criterion(start_unlabel_teacher, start_unlabel_student) + consistency_criterion(end_unlabel_teacher, end_unlabel_student)) # set_trace() if torch.isnan(consistency_loss_ema): consistency_loss_ema = torch.tensor(0.).cuda() consistency_loss_ema_flip = 0.1 * consistency_weight * ( consistency_criterion(confidence_map_unlabel_teacher_flip, confidence_map_unlabel_student_flip) + consistency_criterion(start_unlabel_teacher_flip, start_unlabel_student_flip) + consistency_criterion(end_unlabel_teacher_flip, end_unlabel_student_flip)) + 0.1 * consistency_weight * ( consistency_criterion(confidence_map_label_teacher_flip, confidence_map_label_student_flip) + consistency_criterion(start_label_teacher_flip, start_label_student_flip) + consistency_criterion(end_label_teacher_flip, end_label_student_flip)) # meters.update('cons_loss', consistency_loss.item()) else: consistency_loss = torch.tensor(0).cuda() consistency_loss_ema = torch.tensor(0).cuda() consistency_loss_ema_flip = torch.tensor(0).cuda() # meters.update('cons_loss', 0) if clip_order: input_data_all = torch.cat([input_data, input_data_unlabel], 0) batch_size, C, T = input_data_all.size() idx = torch.randperm(batch_size) input_data_all_new = input_data_all[idx] forw_input = torch.cat( [input_data_all_new[:batch_size // 2, :, T // 2:], input_data_all_new[:batch_size // 2, :, :T // 2]], 2) back_input = input_data_all_new[batch_size // 2:, :, :] input_all = torch.cat([forw_input, back_input], 0) label_order = [0] * (batch_size // 2) + [1] * (batch_size - batch_size // 2) label_order = torch.tensor(label_order).long().cuda() out = model(input_all, clip_order=True) loss_clip_order = order_clip_criterion(out, label_order) loss_all = loss[0] + consistency_loss + consistency_loss_ema + loss_recons + 0.01 * loss_clip_order + consistency_loss_ema_flip optimizer.zero_grad() loss_all.backward() optimizer.step() global_step += 1 update_ema_variables(model, model_ema, 0.999, float(global_step/20)) # //5 //25 epoch_pemreg_loss += loss[2].cpu().detach().numpy() epoch_pemclr_loss += loss[3].cpu().detach().numpy() epoch_tem_loss += loss[1].cpu().detach().numpy() epoch_loss += loss[0].cpu().detach().numpy() consistency_loss_all += consistency_loss.cpu().detach().numpy() consistency_loss_ema_all += consistency_loss_ema.cpu().detach().numpy() if n_iter % 10 == 0: print( "training %d (epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, consistency_loss: %.05f, consistency_loss_ema: %.05f, total_loss: %.03f" % (global_step, epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), consistency_loss_all / (n_iter + 1), consistency_loss_ema_all / (n_iter + 1), epoch_loss / (n_iter + 1))) print( blue("BMN training loss(epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, total_loss: %.03f" % ( epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), epoch_loss / (n_iter + 1)))) def train_BMN_Semi_Full(data_loader, model, model_ema, optimizer, epoch, bm_mask): global global_step model.train() epoch_pemreg_loss = 0 epoch_pemclr_loss = 0 epoch_tem_loss = 0 epoch_loss = 0 consistency_loss_all = 0 consistency_loss_ema_all = 0 consistency_criterion = softmax_mse_loss # softmax_kl_loss # perturbance = nn.dropout(0.3) temporal_perb = TemporalShift_random(400, 64) # TemporalShift(400, 8) 16 order_clip_criterion = nn.CrossEntropyLoss() consistency = True clip_order = True dropout2d = True temporal_re = True # unlabeled_train_iter = iter(train_loader_unlabel) for n_iter, (input_data, label_confidence, label_start, label_end) in enumerate(data_loader): input_data = input_data.cuda() label_start = label_start.cuda() label_end = label_end.cuda() label_confidence = label_confidence.cuda() input_data_student = temporal_perb(input_data) if dropout2d: input_data_student = F.dropout2d(input_data_student, 0.2) else: input_data_student = F.dropout(input_data_student, 0.2) confidence_map, start, end = model(input_data_student) # [B, 2, 100, 100], [B,100],[B,100] loss = bmn_loss_func(confidence_map, start, end, label_confidence, label_start, label_end, bm_mask.cuda()) confidence_map = confidence_map * bm_mask.cuda() if temporal_re: input_recons = F.dropout2d(input_data.permute(0, 2, 1), 0.2).permute(0, 2, 1) else: input_recons = F.dropout2d(input_data, 0.2) recons_feature = model(input_recons, recons=True) # try: # input_data_unlabel= unlabeled_train_iter.next() # input_data_unlabel = input_data_unlabel.cuda() # except: # unlabeled_train_iter = iter(train_loader_unlabel) # input_data_unlabel = unlabeled_train_iter.next() # input_data_unlabel = input_data_unlabel.cuda() # input_data_unlabel = F.dropout2d(input_data_unlabel.cuda(), 0.2) # input_data_unlabel_student = temporal_perb(input_data_unlabel) # if dropout2d: # input_data_unlabel_student = F.dropout2d(input_data_unlabel_student, 0.2) # else: # input_data_unlabel_student = F.dropout(input_data_unlabel_student, 0.2) # confidence_map_unlabel_student, start_unlabel_student, end_unlabel_student = model(input_data_unlabel_student) # confidence_map_unlabel_student = confidence_map_unlabel_student * bm_mask.cuda() input_data_label_student_flip = F.dropout2d(input_data.flip(2).contiguous(), 0.1) confidence_map_label_student_flip, start_label_student_flip, end_label_student_flip = model( input_data_label_student_flip) confidence_map_label_student_flip = confidence_map_label_student_flip * bm_mask.cuda() # recons_input_student = F.dropout2d(input_data_unlabel.cuda(), 0.2) # recons_feature_unlabel_student = model(recons_input_student, recons=True) # set_trace() loss_recons = 0.0005 * ( Motion_MSEloss(recons_feature, input_data)) # 0.0001 with torch.no_grad(): # input_data_unlabel = input_data_unlabel.cuda() input_data_ema = F.dropout(input_data, 0.05) # 0.3 confidence_map_teacher, start_teacher, end_teacher = model_ema(input_data_ema) confidence_map_teacher = confidence_map_teacher * bm_mask.cuda() # input_data_unlabel_teacher = F.dropout(input_data_unlabel, 0.05) # 0.3 # confidence_map_unlabel_teacher, start_unlabel_teacher, end_unlabel_teacher = model_ema( # input_data_unlabel_teacher) # confidence_map_unlabel_teacher = confidence_map_unlabel_teacher * bm_mask.cuda() # flip out = torch.zeros_like(confidence_map_teacher) out_m = confidence_map_teacher.flip(3).contiguous() for i in range(100): out[:, :, i, :100 - i] = out_m[:, :, i, i:] confidence_map_label_teacher = out # start_unlabel_teacher_flip = start_unlabel_teacher.flip(1).contiguous() # end_unlabel_teacher_flip = end_unlabel_teacher.flip(1).contiguous() # add mask # start_label_teacher[start_label_teacher >= 0.9] = 1.0 # start_label_teacher[start_label_teacher <= 0.1] = 0.0 # 2_add # end_unlabel_teacher[end_unlabel_teacher >= 0.9] = 1.0 # end_unlabel_teacher[end_unlabel_teacher <= 0.1] = 0.0 # flip start_label_teacher_flip = label_start.flip(1).contiguous() end_label_teacher_flip = label_end.flip(1).contiguous() # mask = torch.eq( # (start_unlabel_teacher.max(1)[0] > 0.6).float() + (end_unlabel_teacher.max(1)[0] > 0.6).float(), 2.) # confidence_map_unlabel_teacher = confidence_map_unlabel_teacher[mask] # start_unlabel_teacher = start_unlabel_teacher[mask] # end_unlabel_teacher = end_unlabel_teacher[mask] # flip # confidence_map_unlabel_teacher_flip = confidence_map_unlabel_teacher_flip[mask] # start_unlabel_teacher_flip = start_unlabel_teacher_flip[mask] # end_unlabel_teacher_flip = end_unlabel_teacher_flip[mask] # add mask # confidence_map_unlabel_student = confidence_map_unlabel_student[mask] # start_unlabel_student = start_unlabel_student[mask] # end_unlabel_student = end_unlabel_student[mask] # flip add mask # confidence_map_unlabel_student_flip = confidence_map_label_student_flip[mask] # start_unlabel_student_flip = start_label_student_flip[mask] # end_unlabel_student_flip = end_label_student_flip[mask] if consistency: consistency_weight = get_current_consistency_weight(epoch) # meters.update('cons_weight', consistency_weight) # set_trace() consistency_loss = consistency_weight * (consistency_criterion(confidence_map, confidence_map_teacher) + consistency_criterion(start, start_teacher) + consistency_criterion(end, end_teacher)) consistency_loss_ema_flip = 0.1 * consistency_weight * ( consistency_criterion(confidence_map_label_student_flip, confidence_map_label_teacher) + consistency_criterion(start_label_student_flip, start_label_teacher_flip) + consistency_criterion(end_label_student_flip, end_label_teacher_flip)) # consistency_loss_ema_flip = 0.1 * consistency_weight * ( # consistency_criterion(confidence_map_label_teacher, confidence_map_label_student_flip) + # consistency_criterion(start_label_teacher_flip, start_label_student_flip) + # consistency_criterion(end_label_teacher_flip, end_label_student_flip)) # meters.update('cons_loss', consistency_loss.item()) else: consistency_loss = torch.tensor(0).cuda() consistency_loss_ema = torch.tensor(0).cuda() consistency_loss_ema_flip = torch.tensor(0).cuda() # meters.update('cons_loss', 0) if clip_order: input_data_all = input_data # torch.cat([input_data, input_data_unlabel], 0) batch_size, C, T = input_data_all.size() idx = torch.randperm(batch_size) input_data_all_new = input_data_all[idx] forw_input = torch.cat( [input_data_all_new[:batch_size // 2, :, T // 2:], input_data_all_new[:batch_size // 2, :, :T // 2]], 2) back_input = input_data_all_new[batch_size // 2:, :, :] input_all = torch.cat([forw_input, back_input], 0) label_order = [0] * (batch_size // 2) + [1] * (batch_size - batch_size // 2) label_order = torch.tensor(label_order).long().cuda() out = model(input_all, clip_order=True) loss_clip_order = order_clip_criterion(out, label_order) loss_all = loss[0] + consistency_loss + loss_recons + 0.01 * loss_clip_order + consistency_loss_ema_flip optimizer.zero_grad() loss_all.backward() optimizer.step() global_step += 1 update_ema_variables(model, model_ema, 0.999, float(global_step/20)) # //5 //25 epoch_pemreg_loss += loss[2].cpu().detach().numpy() epoch_pemclr_loss += loss[3].cpu().detach().numpy() epoch_tem_loss += loss[1].cpu().detach().numpy() epoch_loss += loss[0].cpu().detach().numpy() consistency_loss_all += consistency_loss.cpu().detach().numpy() # consistency_loss_ema_all += consistency_loss_ema.cpu().detach().numpy() if n_iter % 10 == 0: print( "training %d (epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, consistency_loss: %.05f, total_loss: %.03f" % (global_step, epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), consistency_loss_all / (n_iter + 1), # consistency_loss_ema_all / (n_iter + 1), epoch_loss / (n_iter + 1))) print( blue("BMN training loss(epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, total_loss: %.03f" % ( epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), epoch_loss / (n_iter + 1)))) def test_BMN(data_loader, model, epoch, bm_mask): global eval_loss model.eval() best_loss = 1e10 epoch_pemreg_loss = 0 epoch_pemclr_loss = 0 epoch_tem_loss = 0 epoch_loss = 0 for n_iter, (input_data, label_confidence, label_start, label_end) in enumerate(data_loader): input_data = input_data.cuda() label_start = label_start.cuda() label_end = label_end.cuda() label_confidence = label_confidence.cuda() confidence_map, start, end = model(input_data) loss = bmn_loss_func(confidence_map, start, end, label_confidence, label_start, label_end, bm_mask.cuda()) epoch_pemreg_loss += loss[2].cpu().detach().numpy() epoch_pemclr_loss += loss[3].cpu().detach().numpy() epoch_tem_loss += loss[1].cpu().detach().numpy() epoch_loss += loss[0].cpu().detach().numpy() print( blue("BMN val loss(epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, total_loss: %.03f" % ( epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), epoch_loss / (n_iter + 1)))) eval_loss.append(epoch_loss / (n_iter + 1)) state = {'epoch': epoch + 1, 'state_dict': model.state_dict()} torch.save(state, opt["checkpoint_path"] + "/BMN_checkpoint.pth.tar") # ./checkpoint if epoch_loss < model.module.tem_best_loss: model.module.tem_best_loss = epoch_loss torch.save(state, opt["checkpoint_path"] + "/BMN_best.pth.tar") # eval_loss.append(epoch_loss / (n_iter + 1)) opt_file = open(opt["checkpoint_path"] + "/output_eval_loss.json", "w") json.dump(eval_loss, opt_file) opt_file.close() def test_BMN_ema(data_loader, model, epoch, bm_mask): model.eval() best_loss = 1e10 epoch_pemreg_loss = 0 epoch_pemclr_loss = 0 epoch_tem_loss = 0 epoch_loss = 0 for n_iter, (input_data, label_confidence, label_start, label_end) in enumerate(data_loader): input_data = input_data.cuda() label_start = label_start.cuda() label_end = label_end.cuda() label_confidence = label_confidence.cuda() confidence_map, start, end = model(input_data) loss = bmn_loss_func(confidence_map, start, end, label_confidence, label_start, label_end, bm_mask.cuda()) epoch_pemreg_loss += loss[2].cpu().detach().numpy() epoch_pemclr_loss += loss[3].cpu().detach().numpy() epoch_tem_loss += loss[1].cpu().detach().numpy() epoch_loss += loss[0].cpu().detach().numpy() print( blue("BMN val_ema loss(epoch %d): tem_loss: %.03f, pem class_loss: %.03f, pem reg_loss: %.03f, total_loss: %.03f" % ( epoch, epoch_tem_loss / (n_iter + 1), epoch_pemclr_loss / (n_iter + 1), epoch_pemreg_loss / (n_iter + 1), epoch_loss / (n_iter + 1)))) state = {'epoch': epoch + 1, 'state_dict': model.state_dict()} torch.save(state, opt["checkpoint_path"] + "/BMN_checkpoint_ema.pth.tar") # ./checkpoint if epoch_loss < model.module.tem_best_loss: model.module.tem_best_loss = epoch_loss torch.save(state, opt["checkpoint_path"] + "/BMN_best_ema.pth.tar") def BMN_Train(opt): model = BMN(opt) model = torch.nn.DataParallel(model, device_ids=[0, 1, 2, 3]).cuda() model_ema = BMN(opt) model_ema = torch.nn.DataParallel(model_ema, device_ids=[0, 1, 2, 3]).cuda() for param in model_ema.parameters(): param.detach_() optimizer = optim.Adam(filter(lambda p: p.requires_grad, model.parameters()), lr=opt["training_lr"], weight_decay=opt["weight_decay"]) # 1e-4 train_loader = torch.utils.data.DataLoader(VideoDataSet(opt, subset="train"), # [16,400,100] batch_size=opt["batch_size"], shuffle=True, drop_last=True, num_workers=8, pin_memory=True) if opt['use_semi'] and opt['unlabel_percent'] > 0.: train_loader_unlabel = torch.utils.data.DataLoader(VideoDataSet_unlabel(opt, subset="unlabel"), # [16,400,100] batch_size=min(max(round(opt["batch_size"]*opt['unlabel_percent']/(4*(1.-opt['unlabel_percent'])))*4, 4), 24), shuffle=True,drop_last=True, num_workers=8, pin_memory=True) test_loader = torch.utils.data.DataLoader(VideoDataSet(opt, subset="validation"), batch_size=opt["batch_size"], shuffle=False, num_workers=8, pin_memory=True) scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=opt["step_size"], gamma=opt["step_gamma"]) # 7 0.1 bm_mask = get_mask(opt["temporal_scale"]) use_semi = opt['use_semi'] print('use {} label for training!!!'.format(1-opt['unlabel_percent'])) print('training batchsize : {}'.format(opt["batch_size"])) print('unlabel_training batchsize : {}'.format(min(max(round(opt["batch_size"]*opt['unlabel_percent']/(4*(1.-opt['unlabel_percent'])))*4, 4), 24))) for epoch in range(opt["train_epochs"]): # 9 # scheduler.step() if use_semi: if opt['unlabel_percent'] == 0.: print('use Semi !!! use all label !!!') train_BMN_Semi_Full(train_loader, model, model_ema, optimizer, epoch, bm_mask) test_BMN(test_loader, model, epoch, bm_mask) test_BMN_ema(test_loader, model_ema, epoch, bm_mask) else: print('use Semi !!!') train_BMN_Semi(train_loader, train_loader_unlabel, model, model_ema, optimizer, epoch, bm_mask) test_BMN(test_loader, model, epoch, bm_mask) test_BMN_ema(test_loader, model_ema, epoch, bm_mask) else: print('use Fewer label !!!') train_BMN(train_loader, model, optimizer, epoch, bm_mask) test_BMN(test_loader, model, epoch, bm_mask) scheduler.step() def BMN_inference(opt, eval_name): model = BMN(opt) model = torch.nn.DataParallel(model, device_ids=[0, 1, 2, 3]).cuda() model_checkpoint_dir = opt["checkpoint_path"] + eval_name # BMN_checkpoint.pth.tar BMN_best.pth.tar checkpoint = torch.load(model_checkpoint_dir) # BMN_best.pth.tar print('load :', model_checkpoint_dir, ' OK !') model.load_state_dict(checkpoint['state_dict']) model.eval() test_loader = torch.utils.data.DataLoader(VideoDataSet(opt, subset="validation"), batch_size=8, shuffle=False, num_workers=8, pin_memory=True, drop_last=False) tscale = opt["temporal_scale"] with torch.no_grad(): for idx, input_data in test_loader: # set_trace() length = idx.shape[0] # for ii in range(length): video_name = [] for ii in range(length): video_name_video = test_loader.dataset.video_list[idx[ii]] video_name.append(video_name_video) input_data = input_data.cuda() confidence_map, start, end = model(input_data) # set_trace() for ii in range(length): start_scores = start[ii].detach().cpu().numpy() end_scores = end[ii].detach().cpu().numpy() clr_confidence = (confidence_map[ii][1]).detach().cpu().numpy() reg_confidence = (confidence_map[ii][0]).detach().cpu().numpy() max_start = max(start_scores) max_end = max(end_scores) #################################################################################################### # generate the set of start points and end points start_bins = np.zeros(len(start_scores)) start_bins[0] = 1 # [1,0,0...,0,1] for idx in range(1, tscale - 1): if start_scores[idx] > start_scores[idx + 1] and start_scores[idx] > start_scores[idx - 1]: start_bins[idx] = 1 elif start_scores[idx] > (0.5 * max_start): start_bins[idx] = 1 end_bins = np.zeros(len(end_scores)) end_bins[-1] = 1 for idx in range(1, tscale - 1): if end_scores[idx] > end_scores[idx + 1] and end_scores[idx] > end_scores[idx - 1]: end_bins[idx] = 1 elif end_scores[idx] > (0.5 * max_end): end_bins[idx] = 1 ######################################################################################################## ######################################################################### # new_props = [] for idx in range(tscale): for jdx in range(tscale): start_index = jdx end_index = start_index + idx+1 if end_index < tscale and start_bins[start_index] == 1 and end_bins[end_index] == 1: xmin = start_index/tscale xmax = end_index/tscale xmin_score = start_scores[start_index] xmax_score = end_scores[end_index] clr_score = clr_confidence[idx, jdx] reg_score = reg_confidence[idx, jdx] score = xmin_score * xmax_score * clr_score*reg_score new_props.append([xmin, xmax, xmin_score, xmax_score, clr_score, reg_score, score]) new_props = np.stack(new_props) ######################################################################### col_name = ["xmin", "xmax", "xmin_score", "xmax_score", "clr_score", "reg_socre", "score"] new_df = pd.DataFrame(new_props, columns=col_name) new_df.to_csv("./output/BMN_results/" + video_name[ii] + ".csv", index=False) def BMN_inference_ema(opt, eval_name): model = BMN(opt) model = torch.nn.DataParallel(model, device_ids=[0, 1, 2, 3]).cuda() model_checkpoint_dir = opt["checkpoint_path"] + eval_name # BMN_checkpoint.pth.tar BMN_best.pth.tar checkpoint = torch.load(model_checkpoint_dir) # BMN_best.pth.tar print('load :', model_checkpoint_dir, ' OK !') model.load_state_dict(checkpoint['state_dict']) model.eval() test_loader = torch.utils.data.DataLoader(VideoDataSet(opt, subset="validation"), batch_size=8, shuffle=False, num_workers=8, pin_memory=True, drop_last=False) tscale = opt["temporal_scale"] with torch.no_grad(): for idx, input_data in test_loader: # set_trace() length = idx.shape[0] # for ii in range(length): video_name = [] for ii in range(length): video_name_video = test_loader.dataset.video_list[idx[ii]] video_name.append(video_name_video) input_data = input_data.cuda() confidence_map, start, end = model(input_data) # set_trace() for ii in range(length): start_scores = start[ii].detach().cpu().numpy() end_scores = end[ii].detach().cpu().numpy() clr_confidence = (confidence_map[ii][1]).detach().cpu().numpy() reg_confidence = (confidence_map[ii][0]).detach().cpu().numpy() max_start = max(start_scores) max_end = max(end_scores) #################################################################################################### # generate the set of start points and end points start_bins = np.zeros(len(start_scores)) start_bins[0] = 1 # [1,0,0...,0,1] for idx in range(1, tscale - 1): if start_scores[idx] > start_scores[idx + 1] and start_scores[idx] > start_scores[idx - 1]: start_bins[idx] = 1 elif start_scores[idx] > (0.5 * max_start): start_bins[idx] = 1 end_bins = np.zeros(len(end_scores)) end_bins[-1] = 1 for idx in range(1, tscale - 1): if end_scores[idx] > end_scores[idx + 1] and end_scores[idx] > end_scores[idx - 1]: end_bins[idx] = 1 elif end_scores[idx] > (0.5 * max_end): end_bins[idx] = 1 ######################################################################################################## ######################################################################### new_props = [] for idx in range(tscale): for jdx in range(tscale): start_index = jdx end_index = start_index + idx+1 if end_index < tscale and start_bins[start_index] == 1 and end_bins[end_index] == 1: xmin = start_index/tscale xmax = end_index/tscale xmin_score = start_scores[start_index] xmax_score = end_scores[end_index] clr_score = clr_confidence[idx, jdx] reg_score = reg_confidence[idx, jdx] score = xmin_score * xmax_score * clr_score*reg_score new_props.append([xmin, xmax, xmin_score, xmax_score, clr_score, reg_score, score]) new_props = np.stack(new_props) ######################################################################### col_name = ["xmin", "xmax", "xmin_score", "xmax_score", "clr_score", "reg_socre", "score"] new_df = pd.DataFrame(new_props, columns=col_name) new_df.to_csv("./output/BMN_results/" + video_name[ii] + ".csv", index=False) def main(opt): if opt["mode"] == "train": BMN_Train(opt) elif opt["mode"] == "inference": if not os.path.exists("output/BMN_results"): os.makedirs("output/BMN_results") print('unlabel percent: ', opt['unlabel_percent']) print('eval student model !!') for eval_name in ['/BMN_checkpoint.pth.tar', '/BMN_best.pth.tar']: BMN_inference(opt, eval_name) print("Post processing start") BMN_post_processing(opt) print("Post processing finished") evaluation_proposal(opt) print('eval teacher model !!') for eval_name in ['/BMN_checkpoint_ema.pth.tar', '/BMN_best_ema.pth.tar']: BMN_inference_ema(opt, eval_name) print("Post processing start") BMN_post_processing(opt) print("Post processing finished") evaluation_proposal(opt) if __name__ == '__main__': opt = opts.parse_opt() opt = vars(opt) if not os.path.exists(opt["checkpoint_path"]): os.makedirs(opt["checkpoint_path"]) if not os.path.exists('./output'): os.makedirs('./output') opt_file = open(opt["checkpoint_path"] + "/opts.json", "w") json.dump(opt, opt_file) opt_file.close() main(opt)

py

SSTAP

SSTAP-main/gen_unlabel_videos.py

import numpy as np import pandas as pd import json import random def load_json(file): with open(file) as json_file: json_data = json.load(json_file) return json_data anno_df = pd.read_csv("./data/activitynet_annotations/video_info_new.csv") anno_database = load_json("./data/activitynet_annotations/anet_anno_action.json") subset = 'training' training_video = [] action_dict = {} action_dict_num = {} # get all training video names for i in range(len(anno_df)): video_name = anno_df.video.values[i] video_info = anno_database[video_name] video_subset = anno_df.subset.values[i] if subset in video_subset: training_video.append(video_name) label = video_info["annotations"][0]['label'] if label not in action_dict: action_dict[label] = [video_name] else: action_dict[label].append(video_name) for label_name in action_dict: action_dict_num[label_name] = len(action_dict[label_name]) opt_file = open("./data/activitynet_annotations/per_label_num.json", "w") json.dump(action_dict_num, opt_file) opt_file.close() # unlabel percents label_percent = np.linspace(0.1, 0.9, 9) # unlabeled_video = [] for percent in label_percent: unlabeled_video = [] new_props = [] for label_name in action_dict: unlabeled_video.extend(random.sample(action_dict[label_name], round(percent*len(action_dict[label_name])))) for i in range(len(anno_df)): video_name = anno_df.video.values[i] numFrame = anno_df.numFrame.values[i] seconds = anno_df.seconds.values[i] fps = anno_df.fps.values[i] rfps = anno_df.rfps.values[i] featureFrame = anno_df.featureFrame.values[i] video_info = anno_database[video_name] video_subset = anno_df.subset.values[i] if video_name in unlabeled_video: new_props.append([video_name, numFrame, seconds, fps, rfps, 'training_unlabel', featureFrame]) else: new_props.append([video_name, numFrame, seconds, fps, rfps, video_subset, featureFrame]) new_props = np.stack(new_props) col_name = ["video", "numFrame", "seconds", "fps", "rfps", "subset", "featureFrame"] new_df = pd.DataFrame(new_props, columns=col_name) new_df.to_csv("./data/activitynet_annotations/video_info_new_{}.csv".format(round(percent, 1)), index=False)

py

SSTAP

SSTAP-main/opts.py

import argparse def parse_opt(): parser = argparse.ArgumentParser() # Overall settings parser.add_argument( '--mode', type=str, default='train') parser.add_argument( '--checkpoint_path', type=str, default='./checkpoint') parser.add_argument( '--use_semi', type=bool, default=True) parser.add_argument( '--training_lr', type=float, default=0.001) parser.add_argument( '--unlabel_percent', type=float, default=0.5) # 0.5 parser.add_argument( '--weight_decay', type=float, default=1e-4) parser.add_argument( '--train_epochs', type=int, default=10) parser.add_argument( '--batch_size', type=int, default=16) # 16 parser.add_argument( '--step_size', type=int, default=7) parser.add_argument( '--step_gamma', type=float, default=0.1) # Overall Dataset settings parser.add_argument( '--video_info', type=str, default="./data/activitynet_annotations/video_info_new.csv") parser.add_argument( '--video_anno', type=str, default="./data/activitynet_annotations/anet_anno_action.json") parser.add_argument( '--temporal_scale', type=int, default=100) parser.add_argument( '--feature_path', type=str, default="../BSN/data/activitynet_feature_cuhk/") parser.add_argument( '--num_sample', type=int, default=32) parser.add_argument( '--num_sample_perbin', type=int, default=3) parser.add_argument( '--prop_boundary_ratio', type=int, default=0.5) parser.add_argument( '--feat_dim', type=int, default=400) # Post processing parser.add_argument( '--post_process_thread', type=int, default=8) parser.add_argument( '--soft_nms_alpha', type=float, default=0.4) parser.add_argument( '--soft_nms_low_thres', type=float, default=0.5) parser.add_argument( '--soft_nms_high_thres', type=float, default=0.9) parser.add_argument( '--result_file', type=str, default="./output/result_proposal.json") parser.add_argument( '--save_fig_path', type=str, default="./output/evaluation_result.jpg") args = parser.parse_args() return args

py

SSTAP

SSTAP-main/utils.py

import numpy as np def ioa_with_anchors(anchors_min, anchors_max, box_min, box_max): # calculate the overlap proportion between the anchor and all bbox for supervise signal, # the length of the anchor is 0.01 len_anchors = anchors_max - anchors_min int_xmin = np.maximum(anchors_min, box_min) int_xmax = np.minimum(anchors_max, box_max) inter_len = np.maximum(int_xmax - int_xmin, 0.) scores = np.divide(inter_len, len_anchors) return scores def iou_with_anchors(anchors_min, anchors_max, box_min, box_max): """Compute jaccard score between a box and the anchors. """ len_anchors = anchors_max - anchors_min int_xmin = np.maximum(anchors_min, box_min) int_xmax = np.minimum(anchors_max, box_max) inter_len = np.maximum(int_xmax - int_xmin, 0.) union_len = len_anchors - inter_len + box_max - box_min # print inter_len,union_len jaccard = np.divide(inter_len, union_len) return jaccard

py

SSTAP

SSTAP-main/dataset.py

# -*- coding: utf-8 -*- import numpy as np import pandas as pd import json import torch.utils.data as data import torch from utils import ioa_with_anchors, iou_with_anchors from ipdb import set_trace def load_json(file): with open(file) as json_file: json_data = json.load(json_file) return json_data class VideoDataSet(data.Dataset): def __init__(self, opt, subset="train"): self.temporal_scale = opt["temporal_scale"] # 100 self.temporal_gap = 1. / self.temporal_scale self.subset = subset self.mode = opt["mode"] self.feature_path = opt["feature_path"] self.video_info_path = "./data/activitynet_annotations/video_info_new_{}.csv".format(opt['unlabel_percent']) self.video_anno_path = opt["video_anno"] self._getDatasetDict() self._get_match_map() # set_trace() def _getDatasetDict(self): anno_df = pd.read_csv(self.video_info_path) anno_database = load_json(self.video_anno_path) self.video_dict = {} for i in range(len(anno_df)): video_name = anno_df.video.values[i] video_info = anno_database[video_name] video_subset = anno_df.subset.values[i] if self.subset in video_subset: if 'unlabel' not in video_subset: self.video_dict[video_name] = video_info self.video_list = list(self.video_dict.keys()) print("%s subset video numbers: %d" % (self.subset, len(self.video_list))) def __getitem__(self, index): video_data = self._load_file(index) if self.mode == "train": match_score_start, match_score_end, confidence_score = self._get_train_label(index, self.anchor_xmin, self.anchor_xmax) return video_data,confidence_score, match_score_start, match_score_end # [400,100],[100,100],[100] else: return index, video_data def _get_match_map(self): match_map = [] for idx in range(self.temporal_scale): tmp_match_window = [] xmin = self.temporal_gap * idx for jdx in range(1, self.temporal_scale + 1): xmax = xmin + self.temporal_gap * jdx tmp_match_window.append([xmin, xmax]) match_map.append(tmp_match_window) match_map = np.array(match_map) # 100x100x2 match_map = np.transpose(match_map, [1, 0, 2]) # [0,1] [1,2] [2,3].....[99,100] match_map = np.reshape(match_map, [-1, 2]) # [0,2] [1,3] [2,4].....[99,101] # duration x start self.match_map = match_map # duration is same in row, start is same in col [10000,2] self.anchor_xmin = [self.temporal_gap * (i-0.5) for i in range(self.temporal_scale)] # [-0.5/100,0.5/100,...98.5/100] self.anchor_xmax = [self.temporal_gap * (i+0.5) for i in range(1, self.temporal_scale + 1)] # [1.5/100,...,100.5/100] def _load_file(self, index): video_name = self.video_list[index] video_df = pd.read_csv(self.feature_path + "csv_mean_" + str(self.temporal_scale) + "/" + video_name + ".csv") video_data = video_df.values[:, :] video_data = torch.Tensor(video_data) video_data = torch.transpose(video_data, 0, 1) video_data.float() return video_data def _get_train_label(self, index, anchor_xmin, anchor_xmax): video_name = self.video_list[index] # video_name video_info = self.video_dict[video_name] video_frame = video_info['duration_frame'] video_second = video_info['duration_second'] feature_frame = video_info['feature_frame'] corrected_second = float(feature_frame) / video_frame * video_second # there are some frames not used video_labels = video_info['annotations'] # the measurement is second, not frame ############################################################################################## # change the measurement from second to percentage gt_bbox = [] gt_iou_map = [] for j in range(len(video_labels)): tmp_info = video_labels[j] tmp_start = max(min(1, tmp_info['segment'][0] / corrected_second), 0) tmp_end = max(min(1, tmp_info['segment'][1] / corrected_second), 0) gt_bbox.append([tmp_start, tmp_end]) # gt_bbox [0~1] tmp_gt_iou_map = iou_with_anchors( self.match_map[:, 0], self.match_map[:, 1], tmp_start, tmp_end) # [100*100] tmp_gt_iou_map = np.reshape(tmp_gt_iou_map, [self.temporal_scale, self.temporal_scale]) gt_iou_map.append(tmp_gt_iou_map) gt_iou_map = np.array(gt_iou_map) # gt [100*100] gt_iou_map = np.max(gt_iou_map, axis=0) gt_iou_map = torch.Tensor(gt_iou_map) # [100,100] ############################################################################################## #################################################################################################### # generate R_s and R_e gt_bbox = np.array(gt_bbox) # gt [start,end] gt_xmins = gt_bbox[:, 0] gt_xmaxs = gt_bbox[:, 1] gt_lens = gt_xmaxs - gt_xmins gt_len_small = 3 * self.temporal_gap # np.maximum(self.temporal_gap, self.boundary_ratio * gt_lens) gt_start_bboxs = np.stack((gt_xmins - gt_len_small / 2, gt_xmins + gt_len_small / 2), axis=1) gt_end_bboxs = np.stack((gt_xmaxs - gt_len_small / 2, gt_xmaxs + gt_len_small / 2), axis=1) ##################################################################################################### ########################################################################################################## # calculate the ioa for all timestamp match_score_start = [] for jdx in range(len(anchor_xmin)): match_score_start.append(np.max( ioa_with_anchors(anchor_xmin[jdx], anchor_xmax[jdx], gt_start_bboxs[:, 0], gt_start_bboxs[:, 1]))) match_score_end = [] for jdx in range(len(anchor_xmin)): match_score_end.append(np.max( ioa_with_anchors(anchor_xmin[jdx], anchor_xmax[jdx], gt_end_bboxs[:, 0], gt_end_bboxs[:, 1]))) match_score_start = torch.Tensor(match_score_start) match_score_end = torch.Tensor(match_score_end) ############################################################################################################ return match_score_start, match_score_end, gt_iou_map def __len__(self): return len(self.video_list) class VideoDataSet_unlabel(data.Dataset): def __init__(self, opt, subset="unlabel"): self.temporal_scale = opt["temporal_scale"] # 100 self.temporal_gap = 1. / self.temporal_scale self.subset = subset self.mode = opt["mode"] self.feature_path = opt["feature_path"] self.video_info_path = "./data/activitynet_annotations/video_info_new_{}.csv".format(opt['unlabel_percent']) self.video_anno_path = opt["video_anno"] self._getDatasetDict() self.unlabel_percent = opt['unlabel_percent'] self._get_match_map() def _getDatasetDict(self): anno_df = pd.read_csv(self.video_info_path) anno_database = load_json(self.video_anno_path) self.video_dict = {} for i in range(len(anno_df)): video_name = anno_df.video.values[i] video_info = anno_database[video_name] video_subset = anno_df.subset.values[i] if self.subset in video_subset: self.video_dict[video_name] = 'unseen' self.video_list = list(self.video_dict.keys()) print("%s unlabeled subset video numbers: %d" % (self.subset, len(self.video_list))) def __getitem__(self, index): video_data = self._load_file(index) if self.mode == "train": # match_score_start, match_score_end, confidence_score = self._get_train_label(index, self.anchor_xmin, # self.anchor_xmax) return video_data # ,confidence_score, match_score_start, match_score_end # [400,100],[100,100],[100] else: return index, video_data def _get_match_map(self): match_map = [] for idx in range(self.temporal_scale): tmp_match_window = [] xmin = self.temporal_gap * idx for jdx in range(1, self.temporal_scale + 1): xmax = xmin + self.temporal_gap * jdx tmp_match_window.append([xmin, xmax]) match_map.append(tmp_match_window) match_map = np.array(match_map) # 100x100x2 match_map = np.transpose(match_map, [1, 0, 2]) # [0,1] [1,2] [2,3].....[99,100] match_map = np.reshape(match_map, [-1, 2]) # [0,2] [1,3] [2,4].....[99,101] # duration x start self.match_map = match_map # duration is same in row, start is same in col [10000,2] self.anchor_xmin = [self.temporal_gap * (i-0.5) for i in range(self.temporal_scale)] # [-0.5/100,0.5/100,...98.5/100] self.anchor_xmax = [self.temporal_gap * (i+0.5) for i in range(1, self.temporal_scale + 1)] # [1.5/100,...,100.5/100] def _load_file(self, index): video_name = self.video_list[index] video_df = pd.read_csv(self.feature_path + "csv_mean_" + str(self.temporal_scale) + "/" + video_name + ".csv") video_data = video_df.values[:, :] video_data = torch.Tensor(video_data) video_data = torch.transpose(video_data, 0, 1) video_data.float() return video_data def _get_train_label(self, index, anchor_xmin, anchor_xmax): video_name = self.video_list[index] # video_name video_info = self.video_dict[video_name] video_frame = video_info['duration_frame'] video_second = video_info['duration_second'] feature_frame = video_info['feature_frame'] corrected_second = float(feature_frame) / video_frame * video_second # there are some frames not used video_labels = video_info['annotations'] # the measurement is second, not frame ############################################################################################## # change the measurement from second to percentage gt_bbox = [] gt_iou_map = [] for j in range(len(video_labels)): tmp_info = video_labels[j] tmp_start = max(min(1, tmp_info['segment'][0] / corrected_second), 0) tmp_end = max(min(1, tmp_info['segment'][1] / corrected_second), 0) gt_bbox.append([tmp_start, tmp_end]) # gt_bbox [0~1] tmp_gt_iou_map = iou_with_anchors( self.match_map[:, 0], self.match_map[:, 1], tmp_start, tmp_end) # [100*100] tmp_gt_iou_map = np.reshape(tmp_gt_iou_map, [self.temporal_scale, self.temporal_scale]) gt_iou_map.append(tmp_gt_iou_map) gt_iou_map = np.array(gt_iou_map) # gt个[100*100] gt_iou_map = np.max(gt_iou_map, axis=0) gt_iou_map = torch.Tensor(gt_iou_map) # [100,100] ############################################################################################## #################################################################################################### # generate R_s and R_e gt_bbox = np.array(gt_bbox) # gt个[start,end] gt_xmins = gt_bbox[:, 0] gt_xmaxs = gt_bbox[:, 1] gt_lens = gt_xmaxs - gt_xmins gt_len_small = 3 * self.temporal_gap # np.maximum(self.temporal_gap, self.boundary_ratio * gt_lens) gt_start_bboxs = np.stack((gt_xmins - gt_len_small / 2, gt_xmins + gt_len_small / 2), axis=1) gt_end_bboxs = np.stack((gt_xmaxs - gt_len_small / 2, gt_xmaxs + gt_len_small / 2), axis=1) ##################################################################################################### ########################################################################################################## # calculate the ioa for all timestamp match_score_start = [] for jdx in range(len(anchor_xmin)): match_score_start.append(np.max( ioa_with_anchors(anchor_xmin[jdx], anchor_xmax[jdx], gt_start_bboxs[:, 0], gt_start_bboxs[:, 1]))) match_score_end = [] for jdx in range(len(anchor_xmin)): match_score_end.append(np.max( ioa_with_anchors(anchor_xmin[jdx], anchor_xmax[jdx], gt_end_bboxs[:, 0], gt_end_bboxs[:, 1]))) match_score_start = torch.Tensor(match_score_start) match_score_end = torch.Tensor(match_score_end) ############################################################################################################ return match_score_start, match_score_end, gt_iou_map def __len__(self): return len(self.video_list) if __name__ == '__main__': import opts opt = opts.parse_opt() opt = vars(opt) train_loader = torch.utils.data.DataLoader(VideoDataSet(opt, subset="train"), batch_size=opt["batch_size"], shuffle=True, num_workers=8, pin_memory=True) for aaa,bbb,ccc,ddd in train_loader: # len(train_loader)=604 set_trace() print(aaa.shape,bbb.shape,ccc.shape,ddd.shape) # torch.Size([16, 400, 100]) torch.Size([16, 100, 100]) torch.Size([16, 100]) torch.Size([16, 100]) # set_trace() break

py

SSTAP

SSTAP-main/loss_function.py

# -*- coding: utf-8 -*- import torch import numpy as np import torch.nn.functional as F def get_mask(tscale): bm_mask = [] for idx in range(tscale): mask_vector = [1 for i in range(tscale - idx) ] + [0 for i in range(idx)] bm_mask.append(mask_vector) bm_mask = np.array(bm_mask, dtype=np.float32) return torch.Tensor(bm_mask) ''' [1, 1, 1, 1, 1] [1, 1, 1, 1, 0] [1, 1, 1, 0, 0] [1, 1, 0, 0, 0] [1, 0, 0, 0, 0]''' def bmn_loss_func(pred_bm, pred_start, pred_end, gt_iou_map, gt_start, gt_end, bm_mask): pred_bm_reg = pred_bm[:, 0].contiguous() pred_bm_cls = pred_bm[:, 1].contiguous() gt_iou_map = gt_iou_map * bm_mask # [b,100,100]*[100,100] ->[B,100,100] pem_reg_loss = pem_reg_loss_func(pred_bm_reg, gt_iou_map, bm_mask) pem_cls_loss = pem_cls_loss_func(pred_bm_cls, gt_iou_map, bm_mask) tem_loss = tem_loss_func(pred_start, pred_end, gt_start, gt_end) loss = tem_loss + 10 * pem_reg_loss + pem_cls_loss return loss, tem_loss, pem_reg_loss, pem_cls_loss def tem_loss_func(pred_start, pred_end, gt_start, gt_end): def bi_loss(pred_score, gt_label): pred_score = pred_score.view(-1) gt_label = gt_label.view(-1) pmask = (gt_label > 0.5).float() num_entries = len(pmask) num_positive = torch.sum(pmask) ratio = num_entries / num_positive coef_0 = 0.5 * ratio / (ratio - 1) coef_1 = 0.5 * ratio epsilon = 0.000001 loss_pos = coef_1 * torch.log(pred_score + epsilon) * pmask loss_neg = coef_0 * torch.log(1.0 - pred_score + epsilon)*(1.0 - pmask) loss = -1 * torch.mean(loss_pos + loss_neg) return loss loss_start = bi_loss(pred_start, gt_start) loss_end = bi_loss(pred_end, gt_end) loss = loss_start + loss_end return loss def pem_reg_loss_func(pred_score, gt_iou_map, mask): u_hmask = (gt_iou_map > 0.7).float() u_mmask = ((gt_iou_map <= 0.7) & (gt_iou_map > 0.3)).float() u_lmask = ((gt_iou_map <= 0.3) & (gt_iou_map > 0.)).float() u_lmask = u_lmask * mask num_h = torch.sum(u_hmask) num_m = torch.sum(u_mmask) num_l = torch.sum(u_lmask) r_m = num_h / num_m u_smmask = torch.Tensor(np.random.rand(*gt_iou_map.shape)).cuda() u_smmask = u_mmask * u_smmask u_smmask = (u_smmask > (1. - r_m)).float() r_l = num_h / num_l u_slmask = torch.Tensor(np.random.rand(*gt_iou_map.shape)).cuda() u_slmask = u_lmask * u_slmask u_slmask = (u_slmask > (1. - r_l)).float() weights = u_hmask + u_smmask + u_slmask loss = F.mse_loss(pred_score* weights, gt_iou_map* weights) loss = 0.5 * torch.sum(loss*torch.ones(*weights.shape).cuda()) / torch.sum(weights) return loss def pem_cls_loss_func(pred_score, gt_iou_map, mask): pmask = (gt_iou_map > 0.9).float() nmask = (gt_iou_map <= 0.9).float() nmask = nmask * mask num_positive = torch.sum(pmask) num_entries = num_positive + torch.sum(nmask) ratio = num_entries / num_positive coef_0 = 0.5 * ratio / (ratio - 1) coef_1 = 0.5 * ratio epsilon = 0.000001 loss_pos = coef_1 * torch.log(pred_score + epsilon) * pmask loss_neg = coef_0 * torch.log(1.0 - pred_score + epsilon) * nmask loss = -1 * torch.sum(loss_pos + loss_neg) / num_entries return loss

py

SSTAP

SSTAP-main/eval.py

# -*- coding: utf-8 -*- import sys import warnings warnings.filterwarnings('ignore') sys.path.append('./Evaluation') from eval_proposal import ANETproposal import matplotlib.pyplot as plt import numpy as np def run_evaluation(ground_truth_filename, proposal_filename, max_avg_nr_proposals=100, tiou_thresholds=np.linspace(0.5, 0.95, 10), subset='validation'): anet_proposal = ANETproposal(ground_truth_filename, proposal_filename, tiou_thresholds=tiou_thresholds, max_avg_nr_proposals=max_avg_nr_proposals, subset=subset, verbose=True, check_status=False) anet_proposal.evaluate() recall = anet_proposal.recall average_recall = anet_proposal.avg_recall average_nr_proposals = anet_proposal.proposals_per_video return (average_nr_proposals, average_recall, recall) def plot_metric(opt,average_nr_proposals, average_recall, recall, tiou_thresholds=np.linspace(0.5, 0.95, 10)): fn_size = 14 plt.figure(num=None, figsize=(12, 8)) ax = plt.subplot(1,1,1) colors = ['k', 'r', 'yellow', 'b', 'c', 'm', 'b', 'pink', 'lawngreen', 'indigo'] area_under_curve = np.zeros_like(tiou_thresholds) for i in range(recall.shape[0]): area_under_curve[i] = np.trapz(recall[i], average_nr_proposals) for idx, tiou in enumerate(tiou_thresholds[::2]): ax.plot(average_nr_proposals, recall[2*idx,:], color=colors[idx+1], label="tiou=[" + str(tiou) + "], area=" + str(int(area_under_curve[2*idx]*100)/100.), linewidth=4, linestyle='--', marker=None) # Plots Average Recall vs Average number of proposals. ax.plot(average_nr_proposals, average_recall, color=colors[0], label="tiou = 0.5:0.05:0.95," + " area=" + str(int(np.trapz(average_recall, average_nr_proposals)*100)/100.), linewidth=4, linestyle='-', marker=None) handles, labels = ax.get_legend_handles_labels() ax.legend([handles[-1]] + handles[:-1], [labels[-1]] + labels[:-1], loc='best') plt.ylabel('Average Recall', fontsize=fn_size) plt.xlabel('Average Number of Proposals per Video', fontsize=fn_size) plt.grid(b=True, which="both") plt.ylim([0, 1.0]) plt.setp(plt.axes().get_xticklabels(), fontsize=fn_size) plt.setp(plt.axes().get_yticklabels(), fontsize=fn_size) #plt.show() plt.savefig(opt["save_fig_path"]) def evaluation_proposal(opt): uniform_average_nr_proposals_valid, uniform_average_recall_valid, uniform_recall_valid = run_evaluation( "./Evaluation/data/activity_net_1_3_new.json", # filter_activity_net_1_3_new.json opt["result_file"], max_avg_nr_proposals=100, tiou_thresholds=np.linspace(0.5, 0.95, 10), subset='validation') plot_metric(opt,uniform_average_nr_proposals_valid, uniform_average_recall_valid, uniform_recall_valid) print( "AR@1 is \t",np.mean(uniform_recall_valid[:,0])) print( "AR@5 is \t",np.mean(uniform_recall_valid[:,4])) print( "AR@10 is \t",np.mean(uniform_recall_valid[:,9])) print( "AR@100 is \t",np.mean(uniform_recall_valid[:,-1]))

py

SSTAP

SSTAP-main/models.py

# -*- coding: utf-8 -*- import math import numpy as np import torch import torch.nn as nn from ipdb import set_trace import random import torch.nn.functional as F class TemporalShift(nn.Module): def __init__(self, n_segment=3, n_div=8, inplace=False): super(TemporalShift, self).__init__() # self.net = net self.n_segment = n_segment self.fold_div = n_div self.inplace = inplace self.channels_range = list(range(400)) # feature_channels if inplace: print('=> Using in-place shift...') # print('=> Using fold div: {}'.format(self.fold_div)) def forward(self, x): # self.fold_div = n_div x = self.shift(x, self.n_segment, fold_div=self.fold_div, inplace=self.inplace, channels_range =self.channels_range) return x @staticmethod def shift(x, n_segment, fold_div=8, inplace=False, channels_range=[1,2]): x = x.permute(0, 2, 1) # [B,C,T] --> [B, T, C] # set_trace() n_batch, T, c = x.size() # nt, c, h, w = x.size() # n_batch = nt // n_segment # x = x.view(n_batch, n_segment, c, h, w) # x = x.view(n_batch, T, c, h, w) fold = c // 2*fold_div # all = random.sample(channels_range, fold*2) # forward = sorted(all[:fold]) # backward = sorted(all[fold:]) # fixed = list(set(channels_range) - set(all)) # fold = c // fold_div if inplace: # Due to some out of order error when performing parallel computing. # May need to write a CUDA kernel. raise NotImplementedError # out = InplaceShift.apply(x, fold) else: out = torch.zeros_like(x) out[:, :-1, :fold] = x[:, 1:, :fold] # shift left out[:, 1:, fold: 2 * fold] = x[:, :-1, fold: 2 * fold] # shift right out[:, :, 2 * fold:200] = x[:, :, 2 * fold:200] # not shift out[:, :-1, 200:200+fold] = x[:, 1:, 200:200+fold] # shift left out[:, 1:, 200+fold: 200+2 * fold] = x[:, :-1, 200+fold: 200+2 * fold] # shift right out[:, :, 200+2 * fold:] = x[:, :, 200 + 2 * fold:] # not shift # out = torch.zeros_like(x) # out[:, :-1, forward] = x[:, 1:, forward] # shift left # out[:, 1:, backward] = x[:, :-1, backward] # shift right # out[:, :, fixed] = x[:, :, fixed] # not shift # return out.view(nt, c, h, w) return out.permute(0, 2, 1) class TemporalShift_random(nn.Module): def __init__(self, n_segment=3, n_div=8, inplace=False): super(TemporalShift_random, self).__init__() # self.net = net self.n_segment = n_segment self.fold_div = n_div self.inplace = inplace self.channels_range = list(range(400)) # feature_channels if inplace: print('=> Using in-place shift...') # print('=> Using fold div: {}'.format(self.fold_div)) def forward(self, x): # self.fold_div = n_div x = self.shift(x, self.n_segment, fold_div=self.fold_div, inplace=self.inplace, channels_range =self.channels_range) return x @staticmethod def shift(x, n_segment, fold_div=8, inplace=False, channels_range=[1,2]): x = x.permute(0, 2, 1) # [B,C,T] --> [B, T, C] # set_trace() n_batch, T, c = x.size() # nt, c, h, w = x.size() # n_batch = nt // n_segment # x = x.view(n_batch, n_segment, c, h, w) # x = x.view(n_batch, T, c, h, w) fold = c // fold_div all = random.sample(channels_range, fold*2) forward = sorted(all[:fold]) backward = sorted(all[fold:]) fixed = list(set(channels_range) - set(all)) # fold = c // fold_div if inplace: # Due to some out of order error when performing parallel computing. # May need to write a CUDA kernel. raise NotImplementedError # out = InplaceShift.apply(x, fold) else: # out = torch.zeros_like(x) # out[:, :-1, :fold] = x[:, 1:, :fold] # shift left # out[:, 1:, fold: 2 * fold] = x[:, :-1, fold: 2 * fold] # shift right # out[:, :, 2 * fold:] = x[:, :, 2 * fold:] # not shift out = torch.zeros_like(x) out[:, :-1, forward] = x[:, 1:, forward] # shift left out[:, 1:, backward] = x[:, :-1, backward] # shift right out[:, :, fixed] = x[:, :, fixed] # not shift # return out.view(nt, c, h, w) return out.permute(0, 2, 1) class InplaceShift(torch.autograd.Function): # Special thanks to @raoyongming for the help to this function @staticmethod def forward(ctx, input, fold): # not support higher order gradient # input = input.detach_() ctx.fold_ = fold n, t, c, h, w = input.size() buffer = input.data.new(n, t, fold, h, w).zero_() buffer[:, :-1] = input.data[:, 1:, :fold] input.data[:, :, :fold] = buffer buffer.zero_() buffer[:, 1:] = input.data[:, :-1, fold: 2 * fold] input.data[:, :, fold: 2 * fold] = buffer return input @staticmethod def backward(ctx, grad_output): # grad_output = grad_output.detach_() fold = ctx.fold_ n, t, c, h, w = grad_output.size() buffer = grad_output.data.new(n, t, fold, h, w).zero_() buffer[:, 1:] = grad_output.data[:, :-1, :fold] grad_output.data[:, :, :fold] = buffer buffer.zero_() buffer[:, :-1] = grad_output.data[:, 1:, fold: 2 * fold] grad_output.data[:, :, fold: 2 * fold] = buffer return grad_output, None class BMN(nn.Module): def __init__(self, opt): super(BMN, self).__init__() self.tscale = opt["temporal_scale"] # 100 self.prop_boundary_ratio = opt["prop_boundary_ratio"] # 0.5 self.num_sample = opt["num_sample"] # 32 self.num_sample_perbin = opt["num_sample_perbin"] # 3 self.feat_dim=opt["feat_dim"] # 400 self.tem_best_loss = 10000000 self.hidden_dim_1d = 256 self.hidden_dim_2d = 128 self.hidden_dim_3d = 512 self._get_interp1d_mask() # Base Module self.x_1d_b = nn.Sequential( nn.Conv1d(self.feat_dim, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), nn.ReLU(inplace=True), nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), # 256 nn.ReLU(inplace=True) ) self.recons = nn.Sequential( nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), nn.ReLU(inplace=True), nn.Conv1d(self.hidden_dim_1d, self.feat_dim, kernel_size=3, padding=1, groups=4), # 256 # nn.ReLU(inplace=True) ) self.clip_order = nn.Sequential( # nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), # nn.ReLU(inplace=True), nn.Conv1d(self.hidden_dim_1d, 1, kernel_size=3, padding=1), # 256 nn.ReLU(inplace=True) ) self.clip_order_drop = nn.Dropout(0.5) self.clip_order_linear = nn.Linear(100, 2) # Temporal Evaluation Module self.x_1d_s = nn.Sequential( nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), nn.ReLU(inplace=True), nn.Conv1d(self.hidden_dim_1d, 1, kernel_size=1), nn.Sigmoid() ) self.x_1d_e = nn.Sequential( nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1, groups=4), nn.ReLU(inplace=True), nn.Conv1d(self.hidden_dim_1d, 1, kernel_size=1), nn.Sigmoid() ) # Proposal Evaluation Module self.x_1d_p = nn.Sequential( nn.Conv1d(self.hidden_dim_1d, self.hidden_dim_1d, kernel_size=3, padding=1), nn.ReLU(inplace=True) ) self.x_3d_p = nn.Sequential( nn.Conv3d(self.hidden_dim_1d, self.hidden_dim_3d, kernel_size=(self.num_sample, 1, 1), stride=(self.num_sample, 1, 1)), # 512 nn.ReLU(inplace=True) ) self.x_2d_p = nn.Sequential( nn.Conv2d(self.hidden_dim_3d, self.hidden_dim_2d, kernel_size=1), nn.ReLU(inplace=True), nn.Conv2d(self.hidden_dim_2d, self.hidden_dim_2d, kernel_size=3, padding=1), nn.ReLU(inplace=True), nn.Conv2d(self.hidden_dim_2d, self.hidden_dim_2d, kernel_size=3, padding=1), nn.ReLU(inplace=True), nn.Conv2d(self.hidden_dim_2d, 2, kernel_size=1), nn.Sigmoid() ) def forward(self, x, recons=False, clip_order=False): # [B,400,100] base_feature = self.x_1d_b(x) # [B,256,100] recons_feature = self.recons(base_feature) if recons: return recons_feature batch_size, C, T = base_feature.size() if clip_order: return self.clip_order_linear(self.clip_order_drop(self.clip_order(base_feature).view(batch_size, T))) start = self.x_1d_s(base_feature).squeeze(1) # [B,1,100]->[B,100] sigmoid() end = self.x_1d_e(base_feature).squeeze(1) confidence_map = self.x_1d_p(base_feature) # [B,256,100]———>[B,256,100]+relu() confidence_map = self._boundary_matching_layer(confidence_map) # [B, 256, 32, 100, 100] # set_trace() confidence_map = self.x_3d_p(confidence_map).squeeze(2) confidence_map = self.x_2d_p(confidence_map) # [B, 2, 100, 100] return confidence_map, start, end # [B, 2, 100, 100], [B,100],[B,100] def _boundary_matching_layer(self, x): input_size = x.size() # [B,256,100] out = torch.matmul(x, self.sample_mask).reshape(input_size[0],input_size[1],self.num_sample,self.tscale,self.tscale) return out # sample_mask= [100, 320000] def _get_interp1d_bin_mask(self, seg_xmin, seg_xmax, tscale, num_sample, num_sample_perbin): # generate sample mask for a boundary-matching pair plen = float(seg_xmax - seg_xmin) # during plen_sample = plen / (num_sample * num_sample_perbin - 1.0) total_samples = [ seg_xmin + plen_sample * ii for ii in range(num_sample * num_sample_perbin) ] # num_sample * num_sample_perbin p_mask = [] for idx in range(num_sample): # 32 bin_samples = total_samples[idx * num_sample_perbin:(idx + 1) * num_sample_perbin] bin_vector = np.zeros([tscale]) for sample in bin_samples: sample_upper = math.ceil(sample) sample_decimal, sample_down = math.modf(sample) if int(sample_down) <= (tscale - 1) and int(sample_down) >= 0: bin_vector[int(sample_down)] += 1 - sample_decimal # down if int(sample_upper) <= (tscale - 1) and int(sample_upper) >= 0: bin_vector[int(sample_upper)] += sample_decimal # upper bin_vector = 1.0 / num_sample_perbin * bin_vector p_mask.append(bin_vector) p_mask = np.stack(p_mask, axis=1) # 100*32 return p_mask def _get_interp1d_mask(self): # generate sample mask for each point in Boundary-Matching Map mask_mat = [] for start_index in range(self.tscale): # 100 mask_mat_vector = [] for duration_index in range(self.tscale): # 100 if start_index + duration_index < self.tscale: # p_xmin = start_index # start p_xmax = start_index + duration_index # end center_len = float(p_xmax - p_xmin) + 1 # during sample_xmin = p_xmin - center_len * self.prop_boundary_ratio # sample_start sample_xmax = p_xmax + center_len * self.prop_boundary_ratio # sample_end p_mask = self._get_interp1d_bin_mask( sample_xmin, sample_xmax, self.tscale, self.num_sample, # 32 self.num_sample_perbin) else: p_mask = np.zeros([self.tscale, self.num_sample]) # [100,32] mask_mat_vector.append(p_mask) # mask_mat_vector = np.stack(mask_mat_vector, axis=2) # [100,32,100] mask_mat.append(mask_mat_vector) mask_mat = np.stack(mask_mat, axis=3) # [100,32,100,100] mask_mat = mask_mat.astype(np.float32) self.sample_mask = nn.Parameter(torch.Tensor(mask_mat).view(self.tscale, -1), requires_grad=False) # [100,32*100*100] if __name__ == '__main__': import opts opt = opts.parse_opt() opt = vars(opt) model=BMN(opt).cuda() input=torch.randn(2,400,100).cuda() a,b,c=model(input) print(a.shape,b.shape,c.shape)

py

SSTAP

SSTAP-main/data/activitynet_feature_cuhk/data_process.py

# -*- coding: utf-8 -*- import random import numpy as np import scipy import pandas as pd import pandas import numpy import json def resizeFeature(inputData,newSize): # inputX: (temporal_length,feature_dimension) # originalSize=len(inputData) #print originalSize if originalSize==1: inputData=np.reshape(inputData,[-1]) return np.stack([inputData]*newSize) x=numpy.array(range(originalSize)) f=scipy.interpolate.interp1d(x,inputData,axis=0) x_new=[i*float(originalSize-1)/(newSize-1) for i in range(newSize)] y_new=f(x_new) return y_new def readData(video_name,data_type=["spatial","temporal"]): spatial_dir="./spatial/csv_action/" temporal_dir="./temporal/csv_action/" data=[] for dtype in data_type: if dtype=="spatial": df=pandas.read_csv(spatial_dir+video_name+".csv") elif dtype=="temporal": df=pandas.read_csv(temporal_dir+video_name+".csv") data.append(df.values[:,:]) lens=[len(d) for d in data] #print lens min_len=min(lens) new_data=[d[:min_len] for d in data] new_data=numpy.concatenate(new_data,axis=1) return new_data def load_json(file): with open(file) as json_file: data = json.load(json_file) return data def getDatasetDict(): df=pd.read_csv("./info/video_info.csv") json_data= load_json("./info/activity_net.v1-3.min.json") database=json_data['database'] out_dict={} for i in range(len(df)): video_name=df.video.values[i] video_info=database[video_name[2:]] video_new_info={} video_new_info['duration_frame']=df.numFrame.values[i] video_new_info['duration_second']=df.seconds.values[i] video_new_info['annotations']=video_info['annotations'] out_dict[video_name]=video_new_info return out_dict def poolData(data,videoAnno,num_prop=100,num_bin=1,num_sample_bin=3,pool_type="mean"): feature_frame=len(data)*16 video_frame=videoAnno['duration_frame'] video_second=videoAnno['duration_second'] corrected_second=float(feature_frame)/video_frame*video_second fps=float(video_frame)/video_second st=16/fps if len(data)==1: video_feature=np.stack([data]*num_prop) video_feature=np.reshape(video_feature,[num_prop,400]) return video_feature x=[st/2+ii*st for ii in range(len(data))] f=scipy.interpolate.interp1d(x,data,axis=0) video_feature=[] zero_sample=np.zeros(num_bin*400) tmp_anchor_xmin=[1.0/num_prop*i for i in range(num_prop)] tmp_anchor_xmax=[1.0/num_prop*i for i in range(1,num_prop+1)] num_sample=num_bin*num_sample_bin for idx in range(num_prop): xmin=max(x[0]+0.0001,tmp_anchor_xmin[idx]*corrected_second) xmax=min(x[-1]-0.0001,tmp_anchor_xmax[idx]*corrected_second) if xmax<x[0]: #print "fuck" video_feature.append(zero_sample) continue if xmin>x[-1]: video_feature.append(zero_sample) continue plen=(xmax-xmin)/(num_sample-1) x_new=[xmin+plen*ii for ii in range(num_sample)] y_new=f(x_new) y_new_pool=[] for b in range(num_bin): tmp_y_new=y_new[num_sample_bin*b:num_sample_bin*(b+1)] if pool_type=="mean": tmp_y_new=np.mean(y_new,axis=0) elif pool_type=="max": tmp_y_new=np.max(y_new,axis=0) y_new_pool.append(tmp_y_new) y_new_pool=np.stack(y_new_pool) y_new_pool=np.reshape(y_new_pool,[-1]) video_feature.append(y_new_pool) video_feature=np.stack(video_feature) return video_feature videoDict=getDatasetDict() videoNameList=videoDict.keys() random.shuffle(videoNameList) col_names=[] for i in range(400): col_names.append("f"+str(i)) for videoName in videoNameList: videoAnno=videoDict[videoName] data=readData(videoName) numFrame=videoAnno['duration_frame'] featureFrame=len(data)*16 videoAnno["feature_frame"]=featureFrame videoDict[videoName]=videoAnno print numFrame,featureFrame videoFeature_mean=poolData(data,videoAnno,num_prop=100,num_bin=1,num_sample_bin=3,pool_type="mean") outDf=pd.DataFrame(videoFeature_mean,columns=col_names) outDf.to_csv("./csv_mean_100/"+videoName+".csv",index=False) outfile=open("./anet_anno_anet.json","w") json.dump(videoDict,outfile) outfile.close()

py

SSTAP

SSTAP-main/data/activitynet_feature_cuhk/ldb_process.py

# -*- coding: utf-8 -*- """ Created on Mon May 15 22:31:31 2017 @author: wzmsltw """ import caffe import leveldb import numpy as np from caffe.proto import caffe_pb2 import pandas as pd col_names=[] for i in range(200): col_names.append("f"+str(i)) df=pd.read_table("./input_spatial_list.txt",names=['image','frame','label'],sep=" ") db = leveldb.LevelDB('./LDB') datum = caffe_pb2.Datum() i=0 video_name="init" videoData=np.reshape([],[-1,200]) for key, value in db.RangeIter(): tmp_video_name=df.image.values[i].split('/')[-1] if tmp_video_name !=video_name: outDf=pd.DataFrame(videoData,columns=col_names) outDf.to_csv("./csv_raw/"+video_name+".csv",index=False) videoData=np.reshape([],[-1,200]) video_name=tmp_video_name i+=1 datum.ParseFromString(value) label = datum.label data = caffe.io.datum_to_array(datum) data=np.reshape(data,[1,200]) videoData=np.concatenate((videoData,data)) del db

py

SSTAP

SSTAP-main/Evaluation/eval_proposal.py

import json import numpy as np import pandas as pd def interpolated_prec_rec(prec, rec): """Interpolated AP - VOCdevkit from VOC 2011. """ mprec = np.hstack([[0], prec, [0]]) mrec = np.hstack([[0], rec, [1]]) for i in range(len(mprec) - 1)[::-1]: mprec[i] = max(mprec[i], mprec[i + 1]) idx = np.where(mrec[1::] != mrec[0:-1])[0] + 1 ap = np.sum((mrec[idx] - mrec[idx - 1]) * mprec[idx]) return ap def segment_iou(target_segment, candidate_segments): """Compute the temporal intersection over union between a target segment and all the test segments. Parameters ---------- target_segment : 1d array Temporal target segment containing [starting, ending] times. candidate_segments : 2d array Temporal candidate segments containing N x [starting, ending] times. Outputs ------- tiou : 1d array Temporal intersection over union score of the N's candidate segments. """ tt1 = np.maximum(target_segment[0], candidate_segments[:, 0]) tt2 = np.minimum(target_segment[1], candidate_segments[:, 1]) # Intersection including Non-negative overlap score. segments_intersection = (tt2 - tt1).clip(0) # Segment union. segments_union = (candidate_segments[:, 1] - candidate_segments[:, 0]) \ + (target_segment[1] - target_segment[0]) - segments_intersection # Compute overlap as the ratio of the intersection # over union of two segments. tIoU = segments_intersection.astype(float) / segments_union return tIoU def wrapper_segment_iou(target_segments, candidate_segments): """Compute intersection over union btw segments Parameters ---------- target_segments : ndarray 2-dim array in format [m x 2:=[init, end]] candidate_segments : ndarray 2-dim array in format [n x 2:=[init, end]] Outputs ------- tiou : ndarray 2-dim array [n x m] with IOU ratio. Note: It assumes that candidate-segments are more scarce that target-segments """ if candidate_segments.ndim != 2 or target_segments.ndim != 2: raise ValueError('Dimension of arguments is incorrect') n, m = candidate_segments.shape[0], target_segments.shape[0] tiou = np.empty((n, m)) for i in range(m): tiou[:, i] = segment_iou(target_segments[i,:], candidate_segments) return tiou class ANETproposal(object): GROUND_TRUTH_FIELDS = ['database', 'taxonomy', 'version'] PROPOSAL_FIELDS = ['results', 'version', 'external_data'] def __init__(self, ground_truth_filename=None, proposal_filename=None, ground_truth_fields=GROUND_TRUTH_FIELDS, proposal_fields=PROPOSAL_FIELDS, tiou_thresholds=np.linspace(0.5, 0.95, 10), max_avg_nr_proposals=None, subset='validation', verbose=False, check_status=False): if not ground_truth_filename: raise IOError('Please input a valid ground truth file.') if not proposal_filename: raise IOError('Please input a valid proposal file.') self.subset = subset self.tiou_thresholds = tiou_thresholds self.max_avg_nr_proposals = max_avg_nr_proposals self.verbose = verbose self.gt_fields = ground_truth_fields self.pred_fields = proposal_fields self.recall = None self.avg_recall = None self.proposals_per_video = None self.check_status = check_status # Retrieve blocked videos from server. if self.check_status: self.blocked_videos = get_blocked_videos() else: self.blocked_videos = list() # Import ground truth and proposals. self.ground_truth, self.activity_index = self._import_ground_truth( ground_truth_filename) self.proposal = self._import_proposal(proposal_filename) if self.verbose: print ('[INIT] Loaded annotations from {} subset.'.format(subset)) nr_gt = len(self.ground_truth) print ('\tNumber of ground truth instances: {}'.format(nr_gt)) nr_pred = len(self.proposal) print ('\tNumber of proposals: {}'.format(nr_pred)) print ('\tFixed threshold for tiou score: {}'.format(self.tiou_thresholds)) def _import_ground_truth(self, ground_truth_filename): """Reads ground truth file, checks if it is well formatted, and returns the ground truth instances and the activity classes. Parameters ---------- ground_truth_filename : str Full path to the ground truth json file. Outputs ------- ground_truth : df Data frame containing the ground truth instances. activity_index : dict Dictionary containing class index. """ with open(ground_truth_filename, 'r') as fobj: data = json.load(fobj) # Checking format if not all([field in data.keys() for field in self.gt_fields]): raise IOError('Please input a valid ground truth file.') # Read ground truth data. activity_index, cidx = {}, 0 video_lst, t_start_lst, t_end_lst, label_lst = [], [], [], [] for videoid, v in data['database'].items(): if self.subset != v['subset']: continue if videoid in self.blocked_videos: continue for ann in v['annotations']: if ann['label'] not in activity_index: activity_index[ann['label']] = cidx cidx += 1 video_lst.append(videoid) t_start_lst.append(ann['segment'][0]) t_end_lst.append(ann['segment'][1]) label_lst.append(activity_index[ann['label']]) ground_truth = pd.DataFrame({'video-id': video_lst, 't-start': t_start_lst, 't-end': t_end_lst, 'label': label_lst}) return ground_truth, activity_index def _import_proposal(self, proposal_filename): """Reads proposal file, checks if it is well formatted, and returns the proposal instances. Parameters ---------- proposal_filename : str Full path to the proposal json file. Outputs ------- proposal : df Data frame containing the proposal instances. """ with open(proposal_filename, 'r') as fobj: data = json.load(fobj) # Checking format... if not all([field in data.keys() for field in self.pred_fields]): raise IOError('Please input a valid proposal file.') # Read predictions. video_lst, t_start_lst, t_end_lst = [], [], [] score_lst = [] for videoid, v in data['results'].items(): if videoid in self.blocked_videos: continue for result in v: video_lst.append(videoid) t_start_lst.append(result['segment'][0]) t_end_lst.append(result['segment'][1]) score_lst.append(result['score']) proposal = pd.DataFrame({'video-id': video_lst, 't-start': t_start_lst, 't-end': t_end_lst, 'score': score_lst}) return proposal def evaluate(self): """Evaluates a proposal file. To measure the performance of a method for the proposal task, we computes the area under the average recall vs average number of proposals per video curve. """ recall, avg_recall, proposals_per_video = average_recall_vs_avg_nr_proposals( self.ground_truth, self.proposal, max_avg_nr_proposals=self.max_avg_nr_proposals, tiou_thresholds=self.tiou_thresholds) area_under_curve = np.trapz(avg_recall, proposals_per_video) if self.verbose: print('[RESULTS] Performance on ActivityNet proposal task.') print('\tArea Under the AR vs AN curve: {}%'.format(100.*float(area_under_curve)/proposals_per_video[-1])) self.recall = recall self.avg_recall = avg_recall self.proposals_per_video = proposals_per_video def average_recall_vs_avg_nr_proposals(ground_truth, proposals, max_avg_nr_proposals=None, tiou_thresholds=np.linspace(0.5, 0.95, 10)): """ Computes the average recall given an average number of proposals per video. Parameters ---------- ground_truth : df Data frame containing the ground truth instances. Required fields: ['video-id', 't-start', 't-end'] proposal : df Data frame containing the proposal instances. Required fields: ['video-id, 't-start', 't-end', 'score'] tiou_thresholds : 1darray, optional array with tiou thresholds. Outputs ------- recall : 2darray recall[i,j] is recall at ith tiou threshold at the jth average number of average number of proposals per video. average_recall : 1darray recall averaged over a list of tiou threshold. This is equivalent to recall.mean(axis=0). proposals_per_video : 1darray average number of proposals per video. """ # Get list of videos. video_lst = ground_truth['video-id'].unique() if not max_avg_nr_proposals: max_avg_nr_proposals = float(proposals.shape[0])/video_lst.shape[0] ratio = max_avg_nr_proposals*float(video_lst.shape[0])/proposals.shape[0] # Adaptation to query faster ground_truth_gbvn = ground_truth.groupby('video-id') proposals_gbvn = proposals.groupby('video-id') # For each video, computes tiou scores among the retrieved proposals. score_lst = [] total_nr_proposals = 0 for videoid in video_lst: # Get proposals for this video. # try: proposals_videoid = proposals_gbvn.get_group(videoid) # except: # continue this_video_proposals = proposals_videoid.loc[:, ['t-start', 't-end']].values # Sort proposals by score. sort_idx = proposals_videoid['score'].argsort()[::-1] this_video_proposals = this_video_proposals[sort_idx, :] # Get ground-truth instances associated to this video. ground_truth_videoid = ground_truth_gbvn.get_group(videoid) this_video_ground_truth = ground_truth_videoid.loc[:,['t-start', 't-end']].values if this_video_proposals.shape[0] == 0: n = this_video_ground_truth.shape[0] score_lst.append(np.zeros((n, 1))) continue if this_video_proposals.ndim != 2: this_video_proposals = np.expand_dims(this_video_proposals, axis=0) if this_video_ground_truth.ndim != 2: this_video_ground_truth = np.expand_dims(this_video_ground_truth, axis=0) nr_proposals = np.minimum(int(this_video_proposals.shape[0] * ratio), this_video_proposals.shape[0]) total_nr_proposals += nr_proposals this_video_proposals = this_video_proposals[:nr_proposals, :] # Compute tiou scores. tiou = wrapper_segment_iou(this_video_proposals, this_video_ground_truth) score_lst.append(tiou) # Given that the length of the videos is really varied, we # compute the number of proposals in terms of a ratio of the total # proposals retrieved, i.e. average recall at a percentage of proposals # retrieved per video. # Computes average recall. pcn_lst = np.arange(1, 101) / 100.0 *(max_avg_nr_proposals*float(video_lst.shape[0])/total_nr_proposals) matches = np.empty((video_lst.shape[0], pcn_lst.shape[0])) positives = np.empty(video_lst.shape[0]) recall = np.empty((tiou_thresholds.shape[0], pcn_lst.shape[0])) # Iterates over each tiou threshold. for ridx, tiou in enumerate(tiou_thresholds): # Inspect positives retrieved per video at different # number of proposals (percentage of the total retrieved). for i, score in enumerate(score_lst): # Total positives per video. positives[i] = score.shape[0] # Find proposals that satisfies minimum tiou threshold. true_positives_tiou = score >= tiou # Get number of proposals as a percentage of total retrieved. pcn_proposals = np.minimum((score.shape[1] * pcn_lst).astype(np.int), score.shape[1]) for j, nr_proposals in enumerate(pcn_proposals): # Compute the number of matches for each percentage of the proposals matches[i, j] = np.count_nonzero((true_positives_tiou[:, :nr_proposals]).sum(axis=1)) # Computes recall given the set of matches per video. recall[ridx, :] = matches.sum(axis=0) / positives.sum() # Recall is averaged. avg_recall = recall.mean(axis=0) # Get the average number of proposals per video. proposals_per_video = pcn_lst * (float(total_nr_proposals) / video_lst.shape[0]) return recall, avg_recall, proposals_per_video

py

SSTAP

SSTAP-main/Evaluation/utils.py

import json import urllib2 import numpy as np API = 'http://ec2-52-11-11-89.us-west-2.compute.amazonaws.com/challenge16/api.py' def get_blocked_videos(api=API): api_url = '{}?action=get_blocked'.format(api) req = urllib2.Request(api_url) response = urllib2.urlopen(req) return json.loads(response.read()) def interpolated_prec_rec(prec, rec): """Interpolated AP - VOCdevkit from VOC 2011. """ mprec = np.hstack([[0], prec, [0]]) mrec = np.hstack([[0], rec, [1]]) for i in range(len(mprec) - 1)[::-1]: mprec[i] = max(mprec[i], mprec[i + 1]) idx = np.where(mrec[1::] != mrec[0:-1])[0] + 1 ap = np.sum((mrec[idx] - mrec[idx - 1]) * mprec[idx]) return ap def segment_iou(target_segment, candidate_segments): """Compute the temporal intersection over union between a target segment and all the test segments. Parameters ---------- target_segment : 1d array Temporal target segment containing [starting, ending] times. candidate_segments : 2d array Temporal candidate segments containing N x [starting, ending] times. Outputs ------- tiou : 1d array Temporal intersection over union score of the N's candidate segments. """ tt1 = np.maximum(target_segment[0], candidate_segments[:, 0]) tt2 = np.minimum(target_segment[1], candidate_segments[:, 1]) # Intersection including Non-negative overlap score. segments_intersection = (tt2 - tt1).clip(0) # Segment union. segments_union = (candidate_segments[:, 1] - candidate_segments[:, 0]) \ + (target_segment[1] - target_segment[0]) - segments_intersection # Compute overlap as the ratio of the intersection # over union of two segments. tIoU = segments_intersection.astype(float) / segments_union return tIoU def wrapper_segment_iou(target_segments, candidate_segments): """Compute intersection over union btw segments Parameters ---------- target_segments : ndarray 2-dim array in format [m x 2:=[init, end]] candidate_segments : ndarray 2-dim array in format [n x 2:=[init, end]] Outputs ------- tiou : ndarray 2-dim array [n x m] with IOU ratio. Note: It assumes that candidate-segments are more scarce that target-segments """ if candidate_segments.ndim != 2 or target_segments.ndim != 2: raise ValueError('Dimension of arguments is incorrect') n, m = candidate_segments.shape[0], target_segments.shape[0] tiou = np.empty((n, m)) for i in xrange(m): tiou[:, i] = segment_iou(target_segments[i,:], candidate_segments) return tiou

py

xSLHA

xSLHA-master/setup.py

import setuptools with open("README.md", "r") as fh: long_description = fh.read() setuptools.setup( name="xslha", version="1.0.2", author="Florian Staub", author_email="florian.staub@gmail.com", description="A python package to read (big/many) SLHA files", long_description=long_description, long_description_content_type="text/markdown", url="https://github.com/fstaub/xSLHA", packages=setuptools.find_packages(), classifiers=[ "Programming Language :: Python :: 3", "Programming Language :: Python :: 2", "License :: OSI Approved :: MIT License", "Operating System :: POSIX :: Linux", "Operating System :: MacOS" ], )

py

xSLHA

xSLHA-master/xslha/main.py

import subprocess import os from six import string_types # SLHA parser # by Florian Staub (florian.staub@gmail.com) # ---------------------------------------------------------- # SLHA Class # ---------------------------------------------------------- class SLHA(): def __init__(self): self.blocks = {} self.br = {} self.widths = {} self.br1L = {} self.widths1L = {} self.xsections = {} self.block_name = None self.entries = {} self.reading_block = False self.reading_decay = False self.reading_xsection = False self.reading_hb_fermion = False self.reading_hb_boson = False self.decay1L = False self.decay_part = 0 # return wdith and BR def BR(self, init, final): # frozenset: make sure that the final states are order-less return self.br[init][tuple(sorted(final))] def Width(self, pdg): return self.widths[pdg] def Value(self, block, number): '''return value of a parameter defined by block and entry or the width or an BR''' if block == 'WIDTH': return self.widths[number] elif block == 'BR': return self.br[number[0]][tuple(sorted(number[1]))] elif block == 'WIDTH1L': return self.widths1L[number] elif block == 'BR1L': return self.br1L[number[0]][tuple(sorted(number[1]))] elif block == 'XSECTION': xs = self.xsections[tuple(number)] return [[x, xs[x]] for x in xs.keys()] else: return self.blocks[block.upper()][ str(number)[1:-1].replace(" ", "")] def start_decay(self, li): parsed = list(filter(None, li.split(' '))) self.decay1L = li.upper().startswith("DECAY1L") self.decay_part = int(parsed[1]) if self.decay1L: self.widths1L[self.decay_part] = float(parsed[2]) else: self.widths[self.decay_part] = float(parsed[2]) self.entries = {} self.reading_block, self.reading_decay, self.reading_xsection \ = False, True, False def start_block(self, li): self.block_name = (list(filter(None, li.split(' ')))[1]).upper() self.entries = {} self.reading_block, self.reading_decay, self.reading_xsection \ = True, False, False self.reading_hb_boson = \ self.block_name in ["HIGGSBOUNDSINPUTHIGGSCOUPLINGSBOSONS", "HIGGSCOUPLINGSBOSONS"] self.reading_hb_fermion = \ self.block_name in ["HIGGSBOUNDSINPUTHIGGSCOUPLINGSFERMIONS", "HIGGSCOUPLINGSFERMIONS"] def start_xsection(self, li): parsed = list(filter(None, li.split(' '))) if "#" in parsed: parsed = parsed[:parsed.index("#")] # remove comments self.xs_head = tuple( [float(parsed[1]), tuple([int(parsed[2]), int(parsed[3])]), tuple([int(parsed[-2]), int(parsed[-1])]) ]) self.entries = {} self.reading_block, self.reading_decay, self.reading_xsection \ = False, False, True def flush(self): '''store the information once a block is completely parsed''' if len(self.entries) > 0: if self.reading_block: self.blocks[self.block_name] = self.entries if self.reading_decay: if self.decay1L: self.br1L[self.decay_part] = self.entries else: self.br[self.decay_part] = self.entries if self.reading_xsection: self.xsections[self.xs_head] = self.entries # ---------------------------------------------------------- # Reading # ---------------------------------------------------------- # now the main function to read the SLHA file def read(file, separator=None, verbose=False): spc = SLHA() if separator is not None: all_files = [] count = 1 with open(file) as infile: for line in infile: li = line.strip().upper() if li.startswith("#") or len(li) < 1: continue if separator is not None: if li.startswith(separator): spc.flush() if max(len(spc.blocks.keys()),len(spc.widths.keys())) > 0: all_files.append(spc) # start next point spc = SLHA() count = count + 1 if verbose: print("Read spc file:", count) continue # New block started if li.startswith("BLOCK"): spc.flush() # store information which was read spc.start_block(li) elif li.startswith("DECAY"): spc.flush() # store information which was read spc.start_decay(li) elif li.startswith("XSECTION"): spc.flush() # store information which was read spc.start_xsection(li) # Reading and parsing values else: parsed = list(filter(None, li.split(' '))) if "#" in parsed: parsed = parsed[:parsed.index("#")] # remove comments if spc.reading_block: if spc.reading_hb_fermion: spc.entries[",".join(parsed[3:])] = \ [float(parsed[0]), float(parsed[1])] elif spc.reading_hb_boson: spc.entries[",".join(parsed[2:])] = \ float(parsed[0]) else: # Value might be a string like in SPINFO block try: value = float(parsed[-1]) except: value = parsed[-2] spc.entries[",".join(parsed[0:-1])] = value if spc.reading_decay: spc.entries[ tuple(sorted(eval("[" + ",".join(parsed[2:]) + "]"))) ] = float(parsed[0]) if spc.reading_xsection: spc.entries[ tuple(eval("[" + ",".join(parsed[0:-2]) + "]")) ] = float(parsed[-2]) spc.flush() # save the very last block in the file if verbose: print("Read %i blocks and %i decays" % (len(spc.blocks), len(spc.br))) if separator is None: return spc else: if len(spc.entries) > 0: all_files.append(spc) return all_files # wrapper for faster read-in of multiple files # squeeze the file (just keeping the necessary entries) to make the reading more efficient # example: read_small_spc(filename,["# m0","# m12","# relic"],separator="ENDOF") def read_small(file, entries, sep): if entries is None: out = read(file, separator=sep) else: string = "--regexp=\"" + sep + "\" --regexp=\"Block\" " for i in entries: string = string + "--regexp=\"" + i + "\" " if os.path.isfile("temp.spc"): subprocess.call("rm temp.spc", shell=True) subprocess.call("cat " + file + " | grep -i " + string + " > temp_read_small.spc", shell=True) out = read("temp_read_small.spc", separator=sep) subprocess.call("rm temp_read_small.spc", shell=True) return out def read_dir(dir, entries=None): if os.path.isfile("temp_read_dir.spc"): subprocess.call("rm temp_read_dir.spc", shell=True) # subprocess.check_call("cat "+dir+"/* > temp_read_dir.spc",shell=True) subprocess.check_call("tail -n+1 " + dir + "/* > temp_read_dir.spc", shell=True) out = read_small("temp_read_dir.spc", entries, "==>") subprocess.call("rm temp_read_dir.spc", shell=True) return out #def read_dir(dir,entries=None): #subprocess.call("rm temp_read_dir.spc",shell=True) #subprocess.check_call("cat "+dir+"/* > temp_read_dir.spc",shell=True) #with open("temp_read_dir.spc") as infile: #for line in infile: #li=line.strip().upper() #if li.startswith("#") or len(li)<1: #continue #else: #file_sep=li[:li.index("#")] #break #out=read_small("temp_read_dir.spc",entries,file_sep) #subprocess.call("rm temp_read_dir.spc",shell=True) #return out # ---------------------------------------------------------- # Writing # ---------------------------------------------------------- def write(blocks, file): with open(file, 'w+') as f: for b in blocks: write_block_head(b, f) write_block_entries(blocks[b], f) def write_block_entries(values, file): for v in values.keys(): file.write(' %s %10.4e # \n' % (v, float(values[v]))) def write_les_houches(block, values, point, file): write_block_head(block, file) write_block_numbers(block, values, point, file) def write_block_head(name, file): file.write("Block " + name.upper() + " # \n") def write_block_numbers(name, values, Variable, file): for v in values.keys(): # if type(values[v]) is string_types: if isinstance(values[v], string_types): # to be 2 and 3 compatible if str(eval(values[v]))==values[v]: file.write(' %s %s # %s \n' % (v, values[v], name.upper() + "[" + str(v) + "]")) else: file.write(' %s %10.4e # %s \n' % (v, float(eval(values[v])), name.upper() + "[" + str(v) + "]")) elif isinstance(values[v], int): file.write(' %s %i # %s \n' % (v, (values[v]), name.upper() + "[" + str(v) + "]")) else: file.write(' %s %10.4e # %s \n' % (v, float(values[v]), name.upper() + "[" + str(v) + "]"))

py

xSLHA

xSLHA-master/xslha/__init__.py

from .main import * name = "xslha"

py

enterprise_extensions

enterprise_extensions-master/setup.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """The setup script.""" from setuptools import setup with open("README.rst") as readme_file: readme = readme_file.read() with open("HISTORY.rst") as history_file: history = history_file.read() requirements = [ "numpy>=1.16.3", "scipy>=1.2.0", "ephem>=3.7.6.0", "healpy>=1.14.0", "scikit-sparse>=0.4.5", "pint-pulsar>=0.8.2", "libstempo>=2.4.0", "enterprise-pulsar>=3.3.0", "scikit-learn>=0.24", "emcee", "ptmcmcsampler", ] test_requirements = [] # Extract version def get_version(): with open("enterprise_extensions/__init__.py") as f: for line in f.readlines(): if "__version__" in line: return line.split('"')[1] setup( name="enterprise_extensions", version=get_version(), description="Extensions, model shortcuts, and utilities for the enterprise PTA analysis framework.", long_description=readme + "\n\n" + history, long_description_content_type='text/x-rst', classifiers=[ "Topic :: Scientific/Engineering :: Astronomy", "Topic :: Scientific/Engineering :: Physics", "Topic :: Scientific/Engineering :: Mathematics", "Intended Audience :: Science/Research", "Programming Language :: Python :: 3", "Topic :: Software Development :: Libraries :: Python Modules", ], keywords="gravitational-wave, black-hole binary, pulsar-timing arrays", url="https://github.com/stevertaylor/enterprise_extensions", author="Stephen R. Taylor, Paul T. Baker, Jeffrey S. Hazboun, Sarah Vigeland", author_email="jeffrey.hazboun@gmail.com", license="MIT", packages=[ "enterprise_extensions", "enterprise_extensions.frequentist", "enterprise_extensions.chromatic", ], package_data={ "enterprise_extensions.chromatic": [ "ACE_SWEPAM_daily_proton_density_1998_2018_MJD_cm-3.txt" ] }, test_suite="tests", tests_require=test_requirements, install_requires=requirements, zip_safe=False, )

py

enterprise_extensions

enterprise_extensions-master/tests/test_hypermodel.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import json import logging import os import pickle import pytest from enterprise_extensions import models, hypermodel testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') outdir = os.path.join(testdir, 'test_out') psr_names = ['J0613-0200', 'J1713+0747', 'J1909-3744'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def dmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_dmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_hypermodel(dmx_psrs, caplog): m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) m3a = models.model_3a(dmx_psrs, noisedict=noise_dict) ptas = {0: m2a, 1: m3a} hm = hypermodel.HyperModel(ptas) assert hasattr(hm, 'get_lnlikelihood') assert 'gw_log10_A' in hm.param_names assert 'nmodel' in hm.param_names @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_hyper_sampler(dmx_psrs, caplog): m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) m3a = models.model_3a(dmx_psrs, noisedict=noise_dict) ptas = {0: m2a, 1: m3a} hm = hypermodel.HyperModel(ptas) samp = hm.setup_sampler(outdir=outdir, human='tester') assert hasattr(samp, "sample") paramfile = os.path.join(outdir, "pars.txt") assert os.path.isfile(paramfile) with open(paramfile, "r") as f: params = [line.rstrip('\n') for line in f] for ptapar, filepar in zip(hm.param_names, params): assert ptapar == filepar x0 = hm.initial_sample() assert len(x0) == len(hm.param_names)

py

enterprise_extensions

enterprise_extensions-master/tests/test_chromatic.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions.chromatic` submodule.""" import logging import os import pickle import numpy as np import pytest from enterprise_extensions.chromatic import solar_wind as sw testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') psr_names = ['J0613-0200', 'J1944+0907'] @pytest.fixture def nodmx_psrs(caplog): caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng11yr_nodmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_sw_r_to_p(nodmx_psrs): p0 = nodmx_psrs[0] dt_sw1 = sw.solar_wind_r_to_p(p0.toas, p0.freqs, p0.planetssb, p0.sunssb, p0.pos_t, n_earth=5, power=2, log10_ne=False) dt_sw2 = sw.solar_wind(p0.toas, p0.freqs, p0.planetssb, p0.sunssb, p0.pos_t, n_earth=5) assert all(np.isclose(dt_sw1, dt_sw2, atol=1e-8))

py

enterprise_extensions

enterprise_extensions-master/tests/test_models.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import json import logging import os import pickle import pytest from enterprise import constants as const from enterprise_extensions import model_utils, models testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') psr_names = ['J0613-0200', 'J1713+0747', 'J1909-3744'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def dmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_dmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.fixture def nodmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_nodmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs def test_model_singlepsr_noise(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m=models.model_singlepsr_noise(nodmx_psrs[1]) assert hasattr(m, 'get_lnlikelihood') def test_model_singlepsr_noise_faclike(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) # default behaviour m=models.model_singlepsr_noise(nodmx_psrs[1], factorized_like=True, Tspan=10*const.yr) m.get_basis() assert 'gw_log10_A' in m.param_names assert 'J1713+0747_red_noise_log10_A' in m.param_names assert m.signals["J1713+0747_gw"]._labels[''][-1] == const.fyr # gw but no RN m=models.model_singlepsr_noise(nodmx_psrs[1], red_var=False, factorized_like=True, Tspan=10*const.yr) assert hasattr(m, 'get_lnlikelihood') assert 'gw_log10_A' in m.param_names assert 'J1713+0747_red_noise_log10_A' not in m.param_names def test_model_singlepsr_noise_sw(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_sw_deter=True, dm_sw_gp=True, swgp_basis='powerlaw') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_sw_deter=True, dm_sw_gp=True, swgp_basis='periodic') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_sw_deter=True, dm_sw_gp=True, swgp_basis='sq_exp') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) def test_model_singlepsr_noise_dip_cusp(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) dip_kwargs = {'dm_expdip': True, 'dmexp_sign': 'negative', 'num_dmdips': 2, 'dm_expdip_tmin': [54700, 57450], 'dm_expdip_tmax': [54850, 57560], 'dmdip_seqname': ['1st_ism', '2nd_ism'], 'dm_cusp': False, 'dm_cusp_sign': 'negative', 'dm_cusp_idx': [2, 4], 'dm_cusp_sym': False, 'dm_cusp_tmin': None, 'dm_cusp_tmax': None, 'num_dm_cusps': 2, 'dm_dual_cusp': True, 'dm_dual_cusp_tmin': [54700, 57450], 'dm_dual_cusp_tmax': [54850, 57560], } m=models.model_singlepsr_noise(nodmx_psrs[1], dm_sw_deter=True, dm_sw_gp=True, **dip_kwargs) assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) def test_model_singlepsr_noise_chrom_nondiag(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m=models.model_singlepsr_noise(nodmx_psrs[0], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag') assert 'J0613-0200_chrom_gp_log10_sigma' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell2' not in m.param_names assert 'J0613-0200_chrom_gp_log10_alpha_wgt' not in m.param_names assert 'J0613-0200_chrom_gp_log10_p' in m.param_names assert 'J0613-0200_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag') assert 'J1713+0747_chrom_gp_log10_sigma' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell2' not in m.param_names assert 'J1713+0747_chrom_gp_log10_alpha_wgt' not in m.param_names assert 'J1713+0747_chrom_gp_log10_p' in m.param_names assert 'J1713+0747_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[2], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag') assert 'J1909-3744_chrom_gp_log10_sigma' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell2' not in m.param_names assert 'J1909-3744_chrom_gp_log10_alpha_wgt' not in m.param_names assert 'J1909-3744_chrom_gp_log10_p' in m.param_names assert 'J1909-3744_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[0], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='periodic_rfband') assert 'J0613-0200_chrom_gp_log10_sigma' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell2' in m.param_names assert 'J0613-0200_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J0613-0200_chrom_gp_log10_p' in m.param_names assert 'J0613-0200_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='periodic_rfband') assert 'J1713+0747_chrom_gp_log10_sigma' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell2' in m.param_names assert 'J1713+0747_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J1713+0747_chrom_gp_log10_p' in m.param_names assert 'J1713+0747_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[2], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='periodic_rfband') assert 'J1909-3744_chrom_gp_log10_sigma' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell2' in m.param_names assert 'J1909-3744_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J1909-3744_chrom_gp_log10_p' in m.param_names assert 'J1909-3744_chrom_gp_log10_gam_p' in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[0], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp') assert 'J0613-0200_chrom_gp_log10_sigma' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell' in m.param_names assert 'J0613-0200_chrom_gp_log10_p' not in m.param_names assert 'J0613-0200_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp') assert 'J1713+0747_chrom_gp_log10_sigma' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell' in m.param_names assert 'J1713+0747_chrom_gp_log10_p' not in m.param_names assert 'J1713+0747_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[2], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp') assert 'J1909-3744_chrom_gp_log10_sigma' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell' in m.param_names assert 'J1909-3744_chrom_gp_log10_p' not in m.param_names assert 'J1909-3744_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[0], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp_rfband') assert 'J0613-0200_chrom_gp_log10_sigma' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell' in m.param_names assert 'J0613-0200_chrom_gp_log10_ell2' in m.param_names assert 'J0613-0200_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J0613-0200_chrom_gp_log10_p' not in m.param_names assert 'J0613-0200_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp_rfband') assert 'J1713+0747_chrom_gp_log10_sigma' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell' in m.param_names assert 'J1713+0747_chrom_gp_log10_ell2' in m.param_names assert 'J1713+0747_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J1713+0747_chrom_gp_log10_p' not in m.param_names assert 'J1713+0747_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[2], dm_var=True, dm_type=None, chrom_gp=True, chrom_gp_kernel='nondiag', chrom_kernel='sq_exp_rfband') assert 'J1909-3744_chrom_gp_log10_sigma' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell' in m.param_names assert 'J1909-3744_chrom_gp_log10_ell2' in m.param_names assert 'J1909-3744_chrom_gp_log10_alpha_wgt' in m.param_names assert 'J1909-3744_chrom_gp_log10_p' not in m.param_names assert 'J1909-3744_chrom_gp_log10_gam_p' not in m.param_names assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) def test_model_singlepsr_noise_chrom_diag(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m=models.model_singlepsr_noise(nodmx_psrs[1], chrom_gp=True, chrom_gp_kernel='diag') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], chrom_gp=True, chrom_gp_kernel='diag', chrom_psd='turnover') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) m=models.model_singlepsr_noise(nodmx_psrs[1], chrom_gp=True, chrom_gp_kernel='diag', chrom_psd='spectrum') assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) def test_model_singlepsr_fact_like(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) psr = nodmx_psrs[1] Tspan = model_utils.get_tspan([psr]) m=models.model_singlepsr_noise(psr, chrom_gp=True, chrom_gp_kernel='diag', factorized_like=False, Tspan=Tspan, fact_like_gamma=13./3, gw_components=5) assert hasattr(m, 'get_lnlikelihood') x0 = {pname: p.sample() for pname, p in zip(m.param_names, m.params)} m.get_lnlikelihood(x0) def test_modelbwmsglpsr(nodmx_psrs, caplog): nodmx_psr=nodmx_psrs[0] m=models.model_bwm_sglpsr(nodmx_psr) # should I be testing the Log and Lookup Likelihoods? # If this test belongs in enterprise/tests instead, do # I need to include the lookup table in tests/data? assert hasattr(m, 'get_lnlikelihood') assert "ramp_log10_A" in m.param_names assert "ramp_t0" in m.param_names def test_modelbwm(nodmx_psrs, caplog): m=models.model_bwm(nodmx_psrs) # should I be testing the Log and Lookup Likelihoods? # If this test belongs in enterprise/tests instead, do # I need to include the lookup table in tests/data? assert hasattr(m, 'get_lnlikelihood') assert "bwm_log10_A" in m.param_names assert "bwm_t0" in m.param_names assert "bwm_phi" in m.param_names assert "bwm_pol" in m.param_names assert "bwm_costheta" in m.param_names @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model1(dmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m1=models.model_1(dmx_psrs, noisedict=noise_dict) assert hasattr(m1, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2a(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2a=models.model_2a(dmx_psrs, noisedict=noise_dict) assert hasattr(m2a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2a_pshift(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2a=models.model_2a(dmx_psrs, noisedict=noise_dict, pshift=True, pseed=42) assert hasattr(m2a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2a_5gwb(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2a=models.model_2a(dmx_psrs, n_gwbfreqs=5, noisedict=noise_dict) assert hasattr(m2a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2a_broken_plaw(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2a=models.model_2a(dmx_psrs, psd='broken_powerlaw', delta_common=0, noisedict=noise_dict) assert hasattr(m2a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2b(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2b=models.model_2b(dmx_psrs, noisedict=noise_dict) assert hasattr(m2b, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2c(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2c=models.model_2c(dmx_psrs, noisedict=noise_dict) assert hasattr(m2c, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model2d(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m2d=models.model_2d(dmx_psrs, noisedict=noise_dict) assert hasattr(m2d, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3a(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3a=models.model_3a(dmx_psrs, noisedict=noise_dict) assert hasattr(m3a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3a_pshift(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3a=models.model_3a(dmx_psrs, noisedict=noise_dict, pshift=True, pseed=42) assert hasattr(m3a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3a_5rnfreqs(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3a=models.model_3a(dmx_psrs, n_rnfreqs=5, noisedict=noise_dict) assert hasattr(m3a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3a_broken_plaw(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3a=models.model_3a(dmx_psrs, psd='broken_powerlaw', delta_common=0, noisedict=noise_dict) assert hasattr(m3a, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3b(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3b=models.model_3b(dmx_psrs) assert hasattr(m3b, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3c(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3c=models.model_3c(dmx_psrs, noisedict=noise_dict) assert hasattr(m3c, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model3d(dmx_psrs, caplog): caplog.set_level(logging.CRITICAL) m3d=models.model_3d(dmx_psrs, noisedict=noise_dict) assert hasattr(m3d, 'get_lnlikelihood') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_model_fdm(dmx_psrs, caplog): fdm=models.model_fdm(dmx_psrs, noisedict=noise_dict) assert hasattr(fdm, 'get_lnlikelihood')

py

enterprise_extensions

enterprise_extensions-master/tests/test_sampler.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import json import logging import os import pickle import pytest from enterprise_extensions import models, sampler from enterprise_extensions.empirical_distr import ( make_empirical_distributions, make_empirical_distributions_KDE) testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') outdir = os.path.join(testdir, 'test_out') psr_names = ['J0613-0200', 'J1713+0747', 'J1909-3744'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def dmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_dmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.fixture def empirical_distribution_1d(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) with open(datadir+'/emp_dist_1d.pkl', 'rb') as fin: emp_dists = pickle.load(fin) return emp_dists @pytest.fixture def empirical_distribution_1d_kde(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) with open(datadir+'/emp_dist_samples.pkl', 'rb') as fin: emp_dists = pickle.load(fin) return emp_dists @pytest.fixture def empirical_distribution_2d(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) with open(datadir+'/emp_dist_2d.pkl', 'rb') as fin: emp_dists = pickle.load(fin) return emp_dists @pytest.fixture def empirical_distribution_2d_kde(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) with open(datadir+'/emp_dist_2d_kde.pkl', 'rb') as fin: emp_dists = pickle.load(fin) return emp_dists @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_jumpproposal(dmx_psrs, caplog): m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) jp = sampler.JumpProposal(m2a) assert jp.draw_from_prior.__name__ == 'draw_from_prior' assert jp.draw_from_signal_prior.__name__ == 'draw_from_signal_prior' assert (jp.draw_from_par_prior('J1713+0747').__name__ == 'draw_from_J1713+0747_prior') assert (jp.draw_from_par_log_uniform({'gw': (-20, -10)}).__name__ == 'draw_from_gw_log_uniform') assert (jp.draw_from_signal('red noise').__name__ == 'draw_from_red noise_signal') @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_setup_sampler(dmx_psrs, caplog): m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) samp = sampler.setup_sampler(m2a, outdir=outdir, human='tester') assert hasattr(samp, "sample") paramfile = os.path.join(outdir, "pars.txt") assert os.path.isfile(paramfile) with open(paramfile, "r") as f: params = [line.rstrip('\n') for line in f] for ptapar, filepar in zip(m2a.param_names, params): assert ptapar == filepar @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_extend_emp_dists_1d(dmx_psrs, caplog): with open(datadir+'/emp_dist_samples.pkl', 'rb') as fin: tmp_data = pickle.load(fin) m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) new_dist = make_empirical_distributions(m2a, tmp_data['names'], tmp_data['names'], tmp_data['samples'], save_dists=False) # run extend when edges match priors new_dist = sampler.extend_emp_dists(m2a, new_dist) # change priors so they don't match edges of # empirical distribution for ii in range(len(tmp_data['names'])): m2a.params[ii].prior._defaults['pmin'] -= 0.1 new_dist = sampler.extend_emp_dists(m2a, new_dist) assert len(new_dist) == 6 for i in range(6): assert new_dist[i]._edges[0] <= m2a.params[i].prior._defaults['pmin'] assert new_dist[i]._edges[-1] >= m2a.params[i].prior._defaults['pmax'] @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_extend_emp_dists_2d(dmx_psrs, caplog): with open(datadir+'/emp_dist_samples.pkl', 'rb') as fin: tmp_data = pickle.load(fin) m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) parnames = [[tmp_data['names'][0], tmp_data['names'][1]], [tmp_data['names'][2], tmp_data['names'][3]], [tmp_data['names'][4], tmp_data['names'][5]]] new_dist = make_empirical_distributions(m2a, parnames, tmp_data['names'], tmp_data['samples'], save_dists=False) # case 1, edges match priors new_dist = sampler.extend_emp_dists(m2a, new_dist) # case 2, edges don't match priors (set priors to be different) for ii in range(len(tmp_data['names'])): m2a.params[ii].prior._defaults['pmin'] -= 0.1 m2a.params[ii].prior._defaults['pmax'] += 0.1 new_dist = sampler.extend_emp_dists(m2a, new_dist) assert len(new_dist) == 3 for i in range(3): k = 2 * i assert new_dist[i]._edges[0][0] <= m2a.params[k].prior._defaults['pmin'] assert new_dist[i]._edges[0][-1] <= m2a.params[k].prior._defaults['pmax'] assert new_dist[i]._edges[1][0] <= m2a.params[k + 1].prior._defaults['pmin'] assert new_dist[i]._edges[1][-1] <= m2a.params[k + 1].prior._defaults['pmax'] @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_extend_emp_dists_1d_kde(dmx_psrs, caplog): with open(datadir+'/emp_dist_samples.pkl', 'rb') as fin: tmp_data = pickle.load(fin) m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) new_dist = make_empirical_distributions_KDE(m2a, tmp_data['names'], tmp_data['names'], tmp_data['samples'], save_dists=False) new_dist = sampler.extend_emp_dists(m2a, new_dist) for ii in range(len(tmp_data['names'])): m2a.params[ii].prior._defaults['pmin'] -= 0.1 new_dist = sampler.extend_emp_dists(m2a, new_dist) assert len(new_dist) == 6 for i in range(6): assert new_dist[i].minval <= m2a.params[i].prior._defaults['pmin'] assert new_dist[i].maxval >= m2a.params[i].prior._defaults['pmax'] @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_extend_emp_dists_2d_kde(dmx_psrs, caplog): with open(datadir+'/emp_dist_samples.pkl', 'rb') as fin: tmp_data = pickle.load(fin) m2a = models.model_2a(dmx_psrs, noisedict=noise_dict) parnames = [[tmp_data['names'][0], tmp_data['names'][1]], [tmp_data['names'][2], tmp_data['names'][3]], [tmp_data['names'][4], tmp_data['names'][5]]] new_dist = make_empirical_distributions_KDE(m2a, parnames, tmp_data['names'], tmp_data['samples'], save_dists=False) # case 1 new_dist = sampler.extend_emp_dists(m2a, new_dist) # case 2 for ii in range(len(tmp_data['names'])): m2a.params[ii].prior._defaults['pmin'] -= 0.1 m2a.params[ii].prior._defaults['pmax'] += 0.1 new_dist = sampler.extend_emp_dists(m2a, new_dist) assert len(new_dist) == 3 for i in range(3): k = 2 * i assert new_dist[i].minvals[0] <= m2a.params[k].prior._defaults['pmin'] assert new_dist[i].maxvals[0] <= m2a.params[k].prior._defaults['pmax'] assert new_dist[i].minvals[1] <= m2a.params[k + 1].prior._defaults['pmin'] assert new_dist[i].maxvals[1] <= m2a.params[k + 1].prior._defaults['pmax']

py

enterprise_extensions

enterprise_extensions-master/tests/__init__.py

py

enterprise_extensions

enterprise_extensions-master/tests/test_frequentist.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import json import logging import os import pickle import numpy as np import pytest from enterprise_extensions import models from enterprise_extensions.frequentist import chi_squared as chisqr testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') psr_names = ['J0613-0200', 'J1944+0907'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def dmx_psrs(caplog): caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng11yr_dmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.mark.filterwarnings('ignore::DeprecationWarning') @pytest.fixture def pta_model1(dmx_psrs, caplog): m2a=models.model_1(dmx_psrs, noisedict=noise_dict, tnequad=True) return m2a @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_chisqr(dmx_psrs, pta_model1): chi2 = chisqr.get_chi2(pta_model1, noise_dict) dof = 0 dof += np.sum([p.toas.size for p in dmx_psrs]) dof -= np.sum([len(p.fitpars) for p in dmx_psrs]) dof -= len(pta_model1.param_names) red_chi2 = chi2/dof print(red_chi2) rchi2 = chisqr.get_reduced_chi2(pta_model1, noise_dict) assert rchi2 == red_chi2 assert np.isclose(1.0, rchi2, atol=0.01)

py

enterprise_extensions

enterprise_extensions-master/tests/test_enterprise_extensions.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import pytest @pytest.fixture def response(): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ # import requests # return requests.get('https://github.com/audreyr/cookiecutter-pypackage') def test_content(response): """Sample pytest test function with the pytest fixture as an argument.""" # from bs4 import BeautifulSoup # assert 'GitHub' in BeautifulSoup(response.content).title.string

py

enterprise_extensions

enterprise_extensions-master/tests/test_os.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """Tests for `enterprise_extensions` package.""" import json import logging import os import pickle import numpy as np import pytest from enterprise.signals import signal_base, gp_signals, parameter, utils from enterprise_extensions import models, blocks, model_utils from enterprise_extensions.frequentist import optimal_statistic as optstat testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') psr_names = ['J0613-0200', 'J1713+0747', 'J1909-3744'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def dmx_psrs(caplog): caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_dmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.fixture def nodmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_nodmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs @pytest.mark.filterwarnings('ignore::DeprecationWarning') @pytest.fixture def pta_model2a(dmx_psrs, caplog): m2a=models.model_2a(dmx_psrs, noisedict=noise_dict, tnequad=True) return m2a @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_os(nodmx_psrs, pta_model2a): OS = optstat.OptimalStatistic(psrs=nodmx_psrs, pta=pta_model2a) OS.compute_os() chain = np.zeros((10, len(pta_model2a.params)+4)) for ii in range(10): entry = [par.sample() for par in pta_model2a.params] entry.extend([OS.pta.get_lnlikelihood(entry)-OS.pta.get_lnprior(entry), OS.pta.get_lnlikelihood(entry), 0.5, 1]) chain[ii, :] = np.array(entry) OS.compute_noise_marginalized_os(chain, param_names=OS.pta.param_names, N=10) OS.compute_noise_maximized_os(chain, param_names=OS.pta.param_names) @pytest.mark.filterwarnings('ignore::DeprecationWarning') @pytest.fixture def pta_pshift(dmx_psrs, caplog): Tspan = model_utils.get_tspan(dmx_psrs) tm = gp_signals.TimingModel() wn = blocks.white_noise_block(inc_ecorr=True, tnequad=True) rn = blocks.red_noise_block(Tspan=Tspan) pseed = parameter.Uniform(0, 10000)('gw_pseed') gw_log10_A = parameter.Uniform(-18, -14)('gw_log10_A') gw_gamma = parameter.Constant(13./3)('gw_gamma') gw_pl = utils.powerlaw(log10_A=gw_log10_A, gamma=gw_gamma) gw_pshift = gp_signals.FourierBasisGP(spectrum=gw_pl, components=5, Tspan=Tspan, name='gw', pshift=True, pseed=pseed) model = tm + wn + rn + gw_pshift pta_pshift = signal_base.PTA([model(p) for p in dmx_psrs]) pta_pshift.set_default_params(noise_dict) return pta_pshift @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_os_pseed(dmx_psrs, pta_pshift): OS = optstat.OptimalStatistic(psrs=dmx_psrs, pta=pta_pshift) params = {pnm: p.sample() for pnm, p in zip(pta_pshift.param_names, pta_pshift.params)} params.update({'gw_pseed': 1}) _, _, _, A1, rho1 = OS.compute_os(params=params) params.update({'gw_pseed': 2}) _, _, _, A2, rho2 = OS.compute_os(params=params) print(A1, A2) print(rho1, rho2) assert A1!=A2 assert rho1!=rho2

py

enterprise_extensions

enterprise_extensions-master/tests/altpol_tests.py

#!/usr/bin/env python # -*- coding: utf-8 -*- """ Tests for altpol functions in e_e Code. """ import json import logging import os import pickle import enterprise.signals.parameter as parameter import numpy as np import pytest from enterprise.signals import gp_signals, signal_base from enterprise_extensions import model_orfs, models from enterprise_extensions.frequentist import optimal_statistic as optstat testdir = os.path.dirname(os.path.abspath(__file__)) datadir = os.path.join(testdir, 'data') psr_names = ['J0613-0200', 'J1713+0747', 'J1909-3744'] with open(datadir+'/ng11yr_noise.json', 'r') as fin: noise_dict = json.load(fin) @pytest.fixture def nodmx_psrs(caplog): """Sample pytest fixture. See more at: http://doc.pytest.org/en/latest/fixture.html """ caplog.set_level(logging.CRITICAL) psrs = [] for p in psr_names: with open(datadir+'/{0}_ng9yr_nodmx_DE436_epsr.pkl'.format(p), 'rb') as fin: psrs.append(pickle.load(fin)) return psrs def test_model_general_alt_correlations(nodmx_psrs, caplog): # caplog.set_level(logging.CRITICAL) m=models.model_general(nodmx_psrs, noisedict=noise_dict, orf='hd,gw_monopole,gw_dipole,st,gt,dipole,monopole') assert hasattr(m, 'get_lnlikelihood') def test_model_2a_altpol_spectrum(nodmx_psrs, caplog): log10_A_tt = parameter.LinearExp(-18, -12)('log10_A_tt') log10_A_st = parameter.LinearExp(-18, -12)('log10_A_st') log10_A_vl = parameter.LinearExp(-18, -15)('log10_A_vl') log10_A_sl = parameter.LinearExp(-18, -16)('log10_A_sl') kappa = parameter.Uniform(0, 15)('kappa') p_dist = parameter.Normal(1.0, 0.2) pl = model_orfs.generalized_gwpol_psd(log10_A_tt=log10_A_tt, log10_A_st=log10_A_st, log10_A_vl=log10_A_vl, log10_A_sl=log10_A_sl, kappa=kappa, p_dist=p_dist, alpha_tt=-2/3, alpha_alt=-1) s = models.white_noise_block(vary=False, inc_ecorr=True) s += models.red_noise_block(prior='log-uniform') s += gp_signals.FourierBasisGP(spectrum=pl, name='gw') s += gp_signals.TimingModel() m = signal_base.PTA([s(psr) for psr in nodmx_psrs]) m.set_default_params(noise_dict) for param in m.params: if 'gw_p_dist' in str(param): # get pulsar name and distance psr_name = str(param).split('_')[0].strip('"') psr_dist = [p._pdist for p in nodmx_psrs if psr_name in p.name][0] # edit prior settings param._prior = parameter.Normal(mu=psr_dist[0], sigma=psr_dist[1]) param._mu = psr_dist[0] param._sigma = psr_dist[1] assert hasattr(m, 'get_lnlikelihood') """ Tests for altpol functions in OS Code. """ @pytest.mark.filterwarnings('ignore::DeprecationWarning') @pytest.fixture def pta_model2a(nodmx_psrs, caplog): m2a=models.model_2a(nodmx_psrs, noisedict=noise_dict) return m2a @pytest.mark.filterwarnings('ignore::DeprecationWarning') def test_os(nodmx_psrs, pta_model2a): orfs = ['hd', 'gw_monopole', 'gw_dipole', 'st', 'dipole', 'monopole'] for orf in orfs: OS = optstat.OptimalStatistic(psrs=nodmx_psrs, pta=pta_model2a, orf=orf) assert hasattr(OS, 'Fmats') OS.compute_os() chain = np.zeros((10, len(pta_model2a.params)+4)) for ii in range(10): entry = [par.sample() for par in pta_model2a.params] entry.extend([OS.pta.get_lnlikelihood(entry)-OS.pta.get_lnprior(entry), OS.pta.get_lnlikelihood(entry), 0.5, 1]) chain[ii, :] = np.array(entry) OS.compute_noise_marginalized_os(chain, param_names=OS.pta.param_names, N=10) OS.compute_noise_maximized_os(chain, param_names=OS.pta.param_names)

py

enterprise_extensions

enterprise_extensions-master/docs/conf.py

#!/usr/bin/env python # -*- coding: utf-8 -*- # # enterprise_extensions documentation build configuration file, created by # sphinx-quickstart on Fri Jun 9 13:47:02 2017. # # This file is execfile()d with the current directory set to its # containing dir. # # Note that not all possible configuration values are present in this # autogenerated file. # # All configuration values have a default; values that are commented out # serve to show the default. # If extensions (or modules to document with autodoc) are in another # directory, add these directories to sys.path here. If the directory is # relative to the documentation root, use os.path.abspath to make it # absolute, like shown here. # import os import sys # sys.path.insert(0, os.path.abspath('..')) # Get the project root dir, which is the parent dir of this cwd = os.getcwd() project_root = os.path.dirname(cwd) # Insert the project root dir as the first element in the PYTHONPATH. # This lets us ensure that the source package is imported, and that its # version is used. sys.path.insert(0, project_root) import enterprise_extensions # -- General configuration --------------------------------------------- # If your documentation needs a minimal Sphinx version, state it here. # # needs_sphinx = '1.0' # Add any Sphinx extension module names here, as strings. They can be # extensions coming with Sphinx (named 'sphinx.ext.*') or your custom ones. extensions = ['sphinx.ext.autodoc', 'sphinx.ext.viewcode'] # get doctrings for __init__ method autoclass_content = "both" # make order or docs 'groupwise' autodoc_member_order = "groupwise" # we won't even try installing these autodoc_mock_imports = ["enterprise","libstempo", "PINT", "astropy", "healpy", "sksparse", "ephem"] # Add any paths that contain templates here, relative to this directory. templates_path = ['_templates'] # The suffix(es) of source filenames. # You can specify multiple suffix as a list of string: # # source_suffix = ['.rst', '.md'] source_suffix = '.rst' # The master toctree document. master_doc = 'index' # General information about the project. project = u'enterprise_extensions' copyright = u"2019, Stephen R. Taylor, Jeffrey S. Hazboun, Paul T. Baker, Sarah J. Vigeland" author = u"Stephen R. Taylor, Jeffrey S. Hazboun, Paul T. Baker, Sarah J. Vigeland" # The version info for the project you're documenting, acts as replacement # for |version| and |release|, also used in various other places throughout # the built documents. # # The short X.Y version. version = enterprise_extensions.__version__ # The full version, including alpha/beta/rc tags. release = enterprise_extensions.__version__ # The language for content autogenerated by Sphinx. Refer to documentation # for a list of supported languages. # # This is also used if you do content translation via gettext catalogs. # Usually you set "language" from the command line for these cases. language = None # List of patterns, relative to source directory, that match files and # directories to ignore when looking for source files. # This patterns also effect to html_static_path and html_extra_path exclude_patterns = ['_build', 'Thumbs.db', '.DS_Store'] # The name of the Pygments (syntax highlighting) style to use. pygments_style = 'sphinx' # If true, `todo` and `todoList` produce output, else they produce nothing. todo_include_todos = False # -- Options for HTML output ------------------------------------------- # The theme to use for HTML and HTML Help pages. See the documentation for # a list of builtin themes. # html_theme = 'sphinx_rtd_theme'#'alabaster' # Theme options are theme-specific and customize the look and feel of a # theme further. For a list of options available for each theme, see the # documentation. # # html_theme_options = {} # Add any paths that contain custom static files (such as style sheets) here, # relative to this directory. They are copied after the builtin static files, # so a file named "default.css" will overwrite the builtin "default.css". html_static_path = ['_static'] # -- Options for HTMLHelp output --------------------------------------- # Output file base name for HTML help builder. htmlhelp_basename = 'enterprise_extensionsdoc' # -- Options for LaTeX output ------------------------------------------ latex_elements = { # The paper size ('letterpaper' or 'a4paper'). # # 'papersize': 'letterpaper', # The font size ('10pt', '11pt' or '12pt'). # # 'pointsize': '10pt', # Additional stuff for the LaTeX preamble. # # 'preamble': '', # Latex figure (float) alignment # # 'figure_align': 'htbp', } # Grouping the document tree into LaTeX files. List of tuples # (source start file, target name, title, author, documentclass # [howto, manual, or own class]). latex_documents = [ (master_doc, 'enterprise_extensions.tex', u'enterprise_extensions Documentation', u'Stephen R. Taylor', 'manual'), ] # -- Options for manual page output ------------------------------------ # One entry per manual page. List of tuples # (source start file, name, description, authors, manual section). man_pages = [ (master_doc, 'enterprise_extensions', u'enterprise_extensions Documentation', [author], 1) ] # -- Options for Texinfo output ---------------------------------------- # Grouping the document tree into Texinfo files. List of tuples # (source start file, target name, title, author, # dir menu entry, description, category) texinfo_documents = [ (master_doc, 'enterprise_extensions', u'enterprise_extensions Documentation', author, 'enterprise_extensions', 'One line description of project.', 'Miscellaneous'), ]

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/hypermodel.py

# -*- coding: utf-8 -*- import os import numpy as np import scipy.linalg as sl from enterprise import constants as const from PTMCMCSampler.PTMCMCSampler import PTSampler as ptmcmc from .sampler import JumpProposal, get_parameter_groups, save_runtime_info class HyperModel(object): """ Class to define hyper-model that is the concatenation of all models. """ def __init__(self, models, log_weights=None): self.models = models self.num_models = len(self.models) self.log_weights = log_weights ######### self.param_names, ind = np.unique(np.concatenate([p.param_names for p in self.models.values()]), return_index=True) self.param_names = self.param_names[np.argsort(ind)] self.param_names = np.append(self.param_names, 'nmodel').tolist() ######### self.pulsars = np.unique(np.concatenate([p.pulsars for p in self.models.values()])) self.pulsars = np.sort(self.pulsars) ######### self.params = [p for p in self.models[0].params] # start of param list uniq_params = [str(p) for p in self.models[0].params] # which params are unique for model in self.models.values(): # find differences between next model and concatenation of previous param_diffs = np.setdiff1d([str(p) for p in model.params], uniq_params) mask = np.array([str(p) in param_diffs for p in model.params]) # concatenate for next loop iteration uniq_params = np.union1d([str(p) for p in model.params], uniq_params) # extend list of unique parameters self.params.extend([pp for pp in np.array(model.params)[mask]]) ######### ######### # get signal collections self.snames = dict.fromkeys(np.unique(sum(sum([[[qq.signal_name for qq in pp._signals] for pp in self.models[mm]._signalcollections] for mm in self.models], []), []))) for key in self.snames: self.snames[key] = [] for mm in self.models: for sc in self.models[mm]._signalcollections: for signal in sc._signals: self.snames[signal.signal_name].extend(signal.params) for key in self.snames: self.snames[key] = list(set(self.snames[key])) for key in self.snames: uniq_params, ind = np.unique([p.name for p in self.snames[key]], return_index=True) uniq_params = uniq_params[np.argsort(ind)].tolist() all_params = [p.name for p in self.snames[key]] self.snames[key] = np.array(self.snames[key])[[all_params.index(q) for q in uniq_params]].tolist() ######### def get_lnlikelihood(self, x): # find model index variable idx = list(self.param_names).index('nmodel') nmodel = int(np.rint(x[idx])) # find parameters of active model q = [] for par in self.models[nmodel].param_names: idx = self.param_names.index(par) q.append(x[idx]) # only active parameters enter likelihood active_lnlike = self.models[nmodel].get_lnlikelihood(q) if self.log_weights is not None: active_lnlike += self.log_weights[nmodel] return active_lnlike def get_lnprior(self, x): # find model index variable idx = list(self.param_names).index('nmodel') nmodel = int(np.rint(x[idx])) if nmodel not in self.models.keys(): return -np.inf else: lnP = 0 for p in self.models.values(): q = [] for par in p.param_names: idx = self.param_names.index(par) q.append(x[idx]) lnP += p.get_lnprior(np.array(q)) return lnP def get_parameter_groups(self): unique_groups = [] for p in self.models.values(): groups = get_parameter_groups(p) # check for any duplicate groups # e.g. the GWB may have different indices in model 1 and model 2 for group in groups: check_group = [] for idx in group: param_name = p.param_names[idx] check_group.append(self.param_names.index(param_name)) if check_group not in unique_groups: unique_groups.append(check_group) unique_groups.extend([[len(self.param_names) - 1]]) return unique_groups def initial_sample(self): """ Draw an initial sample from within the hyper-model prior space. """ x0 = [np.array(p.sample()).ravel().tolist() for p in self.models[0].params] uniq_params = [str(p) for p in self.models[0].params] for model in self.models.values(): param_diffs = np.setdiff1d([str(p) for p in model.params], uniq_params) mask = np.array([str(p) in param_diffs for p in model.params]) x0.extend([np.array(pp.sample()).ravel().tolist() for pp in np.array(model.params)[mask]]) uniq_params = np.union1d([str(p) for p in model.params], uniq_params) x0.extend([[0.1]]) return np.array([p for sublist in x0 for p in sublist]) def draw_from_nmodel_prior(self, x, iter, beta): """ Model-index uniform distribution prior draw. """ q = x.copy() idx = list(self.param_names).index('nmodel') q[idx] = np.random.uniform(-0.5, self.num_models-0.5) lqxy = 0 return q, float(lqxy) def setup_sampler(self, outdir='chains', resume=False, sample_nmodel=True, empirical_distr=None, groups=None, human=None, loglkwargs={}, logpkwargs={}): """ Sets up an instance of PTMCMC sampler. We initialize the sampler the likelihood and prior function from the PTA object. We set up an initial jump covariance matrix with fairly small jumps as this will be adapted as the MCMC runs. We will setup an output directory in `outdir` that will contain the chain (first n columns are the samples for the n parameters and last 4 are log-posterior, log-likelihood, acceptance rate, and an indicator variable for parallel tempering but it doesn't matter because we aren't using parallel tempering). We then add several custom jump proposals to the mix based on whether or not certain parameters are in the model. These are all either draws from the prior distribution of parameters or draws from uniform distributions. """ # dimension of parameter space ndim = len(self.param_names) # initial jump covariance matrix if os.path.exists(outdir+'/cov.npy') and resume: cov = np.load(outdir+'/cov.npy') # check that the one we load is the same shape as our data cov_new = np.diag(np.ones(ndim) * 1.0**2) if cov.shape != cov_new.shape: msg = 'The covariance matrix (cov.npy) in the output folder is ' msg += 'the wrong shape for the parameters given. ' msg += 'Start with a different output directory or ' msg += 'change resume to False to overwrite the run that exists.' raise ValueError(msg) else: cov = np.diag(np.ones(ndim) * 1.0**2) # used to be 0.1 # parameter groupings if groups is None: groups = self.get_parameter_groups() sampler = ptmcmc(ndim, self.get_lnlikelihood, self.get_lnprior, cov, groups=groups, outDir=outdir, resume=resume, loglkwargs=loglkwargs, logpkwargs=logpkwargs) save_runtime_info(self, sampler.outDir, human) # additional jump proposals jp = JumpProposal(self, self.snames, empirical_distr=empirical_distr) sampler.jp = jp # always add draw from prior sampler.addProposalToCycle(jp.draw_from_prior, 5) # try adding empirical proposals if empirical_distr is not None: print('Adding empirical proposals...\n') sampler.addProposalToCycle(jp.draw_from_empirical_distr, 25) # Red noise prior draw if 'red noise' in self.snames: print('Adding red noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_red_prior, 10) # DM GP noise prior draw if 'dm_gp' in self.snames: print('Adding DM GP noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dm_gp_prior, 10) # DM annual prior draw if 'dm_s1yr' in jp.snames: print('Adding DM annual prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dm1yr_prior, 10) # DM dip prior draw if 'dmexp' in '\t'.join(jp.snames): print('Adding DM exponential dip prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmexpdip_prior, 10) # DM cusp prior draw if 'dm_cusp' in jp.snames: print('Adding DM exponential cusp prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmexpcusp_prior, 10) # DMX prior draw if 'dmx_signal' in jp.snames: print('Adding DMX prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmx_prior, 10) # Chromatic GP noise prior draw if 'chrom_gp' in self.snames: print('Adding Chromatic GP noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_chrom_gp_prior, 10) # SW prior draw if 'gp_sw' in jp.snames: print('Adding Solar Wind DM GP prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dm_sw_prior, 10) # Chromatic GP noise prior draw if 'chrom_gp' in self.snames: print('Adding Chromatic GP noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_chrom_gp_prior, 10) # Ephemeris prior draw if 'd_jupiter_mass' in self.param_names: print('Adding ephemeris model prior draws...\n') sampler.addProposalToCycle(jp.draw_from_ephem_prior, 10) # GWB uniform distribution draw if np.any([('gw' in par and 'log10_A' in par) for par in self.param_names]): print('Adding GWB uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_gwb_log_uniform_distribution, 10) # Dipole uniform distribution draw if 'dipole_log10_A' in self.param_names: print('Adding dipole uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_dipole_log_uniform_distribution, 10) # Monopole uniform distribution draw if 'monopole_log10_A' in self.param_names: print('Adding monopole uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_monopole_log_uniform_distribution, 10) # BWM prior draw if 'bwm_log10_A' in self.param_names: print('Adding BWM prior draws...\n') sampler.addProposalToCycle(jp.draw_from_bwm_prior, 10) # FDM prior draw if 'fdm_log10_A' in self.param_names: print('Adding FDM prior draws...\n') sampler.addProposalToCycle(jp.draw_from_fdm_prior, 10) # CW prior draw if 'cw_log10_h' in self.param_names: print('Adding CW prior draws...\n') sampler.addProposalToCycle(jp.draw_from_cw_log_uniform_distribution, 10) # free spectrum prior draw if np.any(['log10_rho' in par for par in self.param_names]): print('Adding free spectrum prior draws...\n') sampler.addProposalToCycle(jp.draw_from_gw_rho_prior, 25) # Prior distribution draw for parameters named GW if any([str(p).split(':')[0] for p in list(self.params) if 'gw' in str(p)]): print('Adding gw param prior draws...\n') sampler.addProposalToCycle(jp.draw_from_par_prior( par_names=[str(p).split(':')[0] for p in list(self.params) if 'gw' in str(p)]), 10) # Model index distribution draw if sample_nmodel: if 'nmodel' in self.param_names: print('Adding nmodel uniform distribution draws...\n') sampler.addProposalToCycle(self.draw_from_nmodel_prior, 25) return sampler def get_process_timeseries(self, psr, chain, burn, comp='DM', mle=False, model=0): """ Construct a time series realization of various constrained processes. :param psr: enterprise pulsar object :param chain: MCMC chain from sampling all models :param burn: desired number of initial samples to discard :param comp: which process to reconstruct? (red noise or DM) [default=DM] :param mle: create time series from ML of GP hyper-parameters? [default=False] :param model: which sub-model within the super-model to reconstruct from? [default=0] :return ret: time-series of the reconstructed process """ wave = 0 pta = self.models[model] model_chain = chain[np.rint(chain[:, -5])==model, :] # get parameter dictionary if mle: ind = np.argmax(model_chain[:, -4]) else: ind = np.random.randint(burn, model_chain.shape[0]) params = {par: model_chain[ind, ct] for ct, par in enumerate(self.param_names) if par in pta.param_names} # deterministic signal part wave += pta.get_delay(params=params)[0] # get linear parameters # Nvec = pta.get_ndiag(params)[0] # Not currently used in code phiinv = pta.get_phiinv(params, logdet=False)[0] T = pta.get_basis(params)[0] d = pta.get_TNr(params)[0] TNT = pta.get_TNT(params)[0] # Red noise piece Sigma = TNT + (np.diag(phiinv) if phiinv.ndim == 1 else phiinv) try: u, s, _ = sl.svd(Sigma) mn = np.dot(u, np.dot(u.T, d)/s) Li = u * np.sqrt(1/s) except np.linalg.LinAlgError: Q, R = sl.qr(Sigma) Sigi = sl.solve(R, Q.T) mn = np.dot(Sigi, d) u, s, _ = sl.svd(Sigi) Li = u * np.sqrt(1/s) b = mn + np.dot(Li, np.random.randn(Li.shape[0])) # find basis indices pardict = {} for sc in pta._signalcollections: ntot = 0 for sig in sc._signals: if sig.signal_type == 'basis': basis = sig.get_basis(params=params) nb = basis.shape[1] pardict[sig.signal_name] = np.arange(ntot, nb+ntot) ntot += nb # DM quadratic + GP if comp == 'DM': idx = pardict['dm_gp'] wave += np.dot(T[:, idx], b[idx]) ret = wave * (psr.freqs**2 * const.DM_K * 1e12) elif comp == 'scattering': idx = pardict['scattering_gp'] wave += np.dot(T[:, idx], b[idx]) ret = wave * (psr.freqs**4) # * const.DM_K * 1e12) elif comp == 'red': idx = pardict['red noise'] wave += np.dot(T[:, idx], b[idx]) ret = wave elif comp == 'FD': idx = pardict['FD'] wave += np.dot(T[:, idx], b[idx]) ret = wave elif comp == 'all': wave += np.dot(T, b) ret = wave else: ret = wave return ret def summary(self, to_stdout=False): """generate summary string for HyperModel, including all PTAs :param to_stdout: [bool] print summary to `stdout` instead of returning it :return: [string] """ summary = "" for ii, pta in self.models.items(): summary += "model " + str(ii) + "\n" summary += "=" * 9 + "\n\n" summary += pta.summary() summary += "=" * 90 + "\n\n" if to_stdout: print(summary) else: return summary

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/gp_kernels.py

# -*- coding: utf-8 -*- import numpy as np from enterprise.signals import signal_base, utils __all__ = ['linear_interp_basis_dm', 'linear_interp_basis_freq', 'dmx_ridge_prior', 'periodic_kernel', 'se_kernel', 'se_dm_kernel', 'get_tf_quantization_matrix', 'tf_kernel', 'sf_kernel', ] # linear interpolation basis in time with nu^-2 scaling @signal_base.function def linear_interp_basis_dm(toas, freqs, dt=30*86400): # get linear interpolation basis in time U, avetoas = utils.linear_interp_basis(toas, dt=dt) # scale with radio frequency Dm = (1400/freqs)**2 return U * Dm[:, None], avetoas @signal_base.function def linear_interp_basis_chromatic(toas, freqs, dt=30*86400, idx=4): """Linear interpolation basis in time with nu^-4 scaling""" # get linear interpolation basis in time U, avetoas = utils.linear_interp_basis(toas, dt=dt) # scale with radio frequency Dm = (1400/freqs)**idx return U * Dm[:, None], avetoas @signal_base.function def linear_interp_basis_freq(freqs, df=64): """Linear interpolation in radio frequency""" return utils.linear_interp_basis(freqs, dt=df) @signal_base.function def dmx_ridge_prior(avetoas, log10_sigma=-7): """DMX-like signal with Gaussian prior""" sigma = 10**log10_sigma return sigma**2 * np.ones_like(avetoas) @signal_base.function def periodic_kernel(avetoas, log10_sigma=-7, log10_ell=2, log10_gam_p=0, log10_p=0): """Quasi-periodic kernel for DM""" r = np.abs(avetoas[None, :] - avetoas[:, None]) # convert units to seconds sigma = 10**log10_sigma l = 10**log10_ell * 86400 p = 10**log10_p * 3.16e7 gam_p = 10**log10_gam_p d = np.eye(r.shape[0]) * (sigma/500)**2 K = sigma**2 * np.exp(-r**2/2/l**2 - gam_p*np.sin(np.pi*r/p)**2) + d return K @signal_base.function def se_kernel(avefreqs, log10_sigma=-7, log10_lam=3): """Squared-exponential kernel for FD""" tm = np.abs(avefreqs[None, :] - avefreqs[:, None]) lam = 10**log10_lam sigma = 10**log10_sigma d = np.eye(tm.shape[0]) * (sigma/500)**2 return sigma**2 * np.exp(-tm**2/2/lam) + d @signal_base.function def se_dm_kernel(avetoas, log10_sigma=-7, log10_ell=2): """Squared-exponential kernel for DM""" r = np.abs(avetoas[None, :] - avetoas[:, None]) # Convert everything into seconds l = 10**log10_ell * 86400 sigma = 10**log10_sigma d = np.eye(r.shape[0]) * (sigma/500)**2 K = sigma**2 * np.exp(-r**2/2/l**2) + d return K @signal_base.function def get_tf_quantization_matrix(toas, freqs, dt=30*86400, df=None, dm=False, dm_idx=2): """ Quantization matrix in time and radio frequency to cut down on the kernel size. """ if df is None: dfs = [(600, 1000), (1000, 1900), (1900, 3000), (3000, 5000)] else: fmin = freqs.min() fmax = freqs.max() fs = np.arange(fmin, fmax+df, df) dfs = [(fs[ii], fs[ii+1]) for ii in range(len(fs)-1)] Us, avetoas, avefreqs, masks = [], [], [], [] for rng in dfs: mask = np.logical_and(freqs>=rng[0], freqs<rng[1]) if any(mask): masks.append(mask) U, _ = utils.create_quantization_matrix(toas[mask], dt=dt, nmin=1) avetoa = np.array([toas[mask][idx.astype(bool)].mean() for idx in U.T]) avefreq = np.array([freqs[mask][idx.astype(bool)].mean() for idx in U.T]) Us.append(U) avetoas.append(avetoa) avefreqs.append(avefreq) nc = np.sum(U.shape[1] for U in Us) U = np.zeros((len(toas), nc)) avetoas = np.concatenate(avetoas) idx = np.argsort(avetoas) avefreqs = np.concatenate(avefreqs) nctot = 0 for ct, mask in enumerate(masks): Umat = Us[ct] nn = Umat.shape[1] U[mask, nctot:nn+nctot] = Umat nctot += nn if dm: weights = (1400/freqs)**dm_idx else: weights = np.ones_like(freqs) return U[:, idx] * weights[:, None], {'avetoas': avetoas[idx], 'avefreqs': avefreqs[idx]} @signal_base.function def tf_kernel(labels, log10_sigma=-7, log10_ell=2, log10_gam_p=0, log10_p=0, log10_ell2=4, log10_alpha_wgt=0): """ The product of a quasi-periodic time kernel and a rational-quadratic frequency kernel. """ avetoas = labels['avetoas'] avefreqs = labels['avefreqs'] r = np.abs(avetoas[None, :] - avetoas[:, None]) r2 = np.abs(avefreqs[None, :] - avefreqs[:, None]) # convert units to seconds sigma = 10**log10_sigma l = 10**log10_ell * 86400 l2 = 10**log10_ell2 p = 10**log10_p * 3.16e7 gam_p = 10**log10_gam_p alpha_wgt = 10**log10_alpha_wgt d = np.eye(r.shape[0]) * (sigma/500)**2 Kt = sigma**2 * np.exp(-r**2/2/l**2 - gam_p*np.sin(np.pi*r/p)**2) Kv = (1+r2**2/2/alpha_wgt/l2**2)**(-alpha_wgt) return Kt * Kv + d @signal_base.function def sf_kernel(labels, log10_sigma=-7, log10_ell=2, log10_ell2=4, log10_alpha_wgt=0): """ The product of a squared-exponential time kernel and a rational-quadratic frequency kernel. """ avetoas = labels['avetoas'] avefreqs = labels['avefreqs'] r = np.abs(avetoas[None, :] - avetoas[:, None]) r2 = np.abs(avefreqs[None, :] - avefreqs[:, None]) # Convert everything into seconds l = 10**log10_ell * 86400 sigma = 10**log10_sigma l2 = 10**log10_ell2 alpha_wgt = 10**log10_alpha_wgt d = np.eye(r.shape[0]) * (sigma/500)**2 Kt = sigma**2 * np.exp(-r**2/2/l**2) Kv = (1+r2**2/2/alpha_wgt/l2**2)**(-alpha_wgt) return Kt * Kv + d

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/deterministic.py

# -*- coding: utf-8 -*- import numpy as np from enterprise import constants as const from enterprise.signals import (deterministic_signals, parameter, signal_base, utils) def fdm_block(Tmin, Tmax, amp_prior='log-uniform', name='fdm', amp_lower=-18, amp_upper=-11, freq_lower=-9, freq_upper=-7, use_fixed_freq=False, fixed_freq=-8): """ Returns deterministic fuzzy dark matter model: 1. FDM parameterized by frequency, phase, and amplitude (mass and DM energy density). :param Tmin: Min time to search, probably first TOA (MJD). :param Tmax: Max time to search, probably last TOA (MJD). :param amp_prior: Prior on log10_A. :param logmin: log of minimum FDM amplitude for prior (log10) :param logmax: log of maximum FDM amplitude for prior (log10) :param name: Name of FDM signal. :param amp_upper, amp_lower, freq_upper, freq_lower: The log-space bounds on the amplitude and frequency priors. :param use_fixed_freq: Whether to do a fixed-frequency run and not search over the frequency. :param fixed_freq: The frequency value to do a fixed-frequency run with. """ # BWM parameters amp_name = '{}_log10_A'.format(name) log10_A_fdm = parameter.Uniform(amp_lower, amp_upper)(amp_name) if use_fixed_freq is True: log10_f_fdm = fixed_freq if use_fixed_freq is False: freq_name = '{}_log10_f'.format(name) log10_f_fdm = parameter.Uniform(freq_lower, freq_upper)(freq_name) phase_e_name = '{}_phase_e'.format(name) phase_e_fdm = parameter.Uniform(0, 2*np.pi)(phase_e_name) phase_p = parameter.Uniform(0, 2*np.pi) fdm_wf = fdm_delay(log10_A=log10_A_fdm, log10_f=log10_f_fdm, phase_e=phase_e_fdm, phase_p=phase_p) fdm = deterministic_signals.Deterministic(fdm_wf, name=name) return fdm def cw_block_circ(amp_prior='log-uniform', dist_prior=None, skyloc=None, log10_fgw=None, psrTerm=False, tref=0, name='cw'): """ Returns deterministic, cirular orbit continuous GW model: :param amp_prior: Prior on log10_h. Default is "log-uniform." Use "uniform" for upper limits, or "None" to search over log10_dist instead. :param dist_prior: Prior on log10_dist. Default is "None," meaning that the search is over log10_h instead of log10_dist. Use "log-uniform" to search over log10_h with a log-uniform prior. :param skyloc: Fixed sky location of CW signal search as [cos(theta), phi]. Search over sky location if ``None`` given. :param log10_fgw: Fixed log10 GW frequency of CW signal search. Search over GW frequency if ``None`` given. :param ecc: Fixed log10 distance to SMBHB search. Search over distance or strain if ``None`` given. :param psrTerm: Boolean for whether to include the pulsar term. Default is False. :param name: Name of CW signal. """ if dist_prior is None: log10_dist = None if amp_prior == 'uniform': log10_h = parameter.LinearExp(-18.0, -11.0)('{}_log10_h'.format(name)) elif amp_prior == 'log-uniform': log10_h = parameter.Uniform(-18.0, -11.0)('{}_log10_h'.format(name)) elif dist_prior == 'log-uniform': log10_dist = parameter.Uniform(-2.0, 4.0)('{}_log10_dL'.format(name)) log10_h = None # chirp mass [Msol] log10_Mc = parameter.Uniform(6.0, 10.0)('{}_log10_Mc'.format(name)) # GW frequency [Hz] if log10_fgw is None: log10_fgw = parameter.Uniform(-9.0, -7.0)('{}_log10_fgw'.format(name)) else: log10_fgw = parameter.Constant(log10_fgw)('{}_log10_fgw'.format(name)) # orbital inclination angle [radians] cosinc = parameter.Uniform(-1.0, 1.0)('{}_cosinc'.format(name)) # initial GW phase [radians] phase0 = parameter.Uniform(0.0, 2*np.pi)('{}_phase0'.format(name)) # polarization psi_name = '{}_psi'.format(name) psi = parameter.Uniform(0, np.pi)(psi_name) # sky location costh_name = '{}_costheta'.format(name) phi_name = '{}_phi'.format(name) if skyloc is None: costh = parameter.Uniform(-1, 1)(costh_name) phi = parameter.Uniform(0, 2*np.pi)(phi_name) else: costh = parameter.Constant(skyloc[0])(costh_name) phi = parameter.Constant(skyloc[1])(phi_name) if psrTerm: # orbital phase p_phase = parameter.Uniform(0, np.pi) p_dist = parameter.Normal(0, 1) else: p_phase = None p_dist = 0 # continuous wave signal wf = cw_delay(cos_gwtheta=costh, gwphi=phi, cos_inc=cosinc, log10_mc=log10_Mc, log10_fgw=log10_fgw, log10_h=log10_h, log10_dist=log10_dist, phase0=phase0, psi=psi, psrTerm=True, p_dist=p_dist, p_phase=p_phase, phase_approx=True, check=False, tref=tref) cw = CWSignal(wf, ecc=False, psrTerm=psrTerm) return cw def cw_block_ecc(amp_prior='log-uniform', skyloc=None, log10_F=None, ecc=None, psrTerm=False, tref=0, name='cw'): """ Returns deterministic, eccentric orbit continuous GW model: :param amp_prior: Prior on log10_h and log10_Mc/log10_dL. Default is "log-uniform" with log10_Mc and log10_dL searched over. Use "uniform" for upper limits, log10_h searched over. :param skyloc: Fixed sky location of CW signal search as [cos(theta), phi]. Search over sky location if ``None`` given. :param log10_F: Fixed log-10 orbital frequency of CW signal search. Search over orbital frequency if ``None`` given. :param ecc: Fixed eccentricity of SMBHB search. Search over eccentricity if ``None`` given. :param psrTerm: Boolean for whether to include the pulsar term. Default is False. :param name: Name of CW signal. """ if amp_prior == 'uniform': log10_h = parameter.LinearExp(-18.0, -11.0)('{}_log10_h'.format(name)) elif amp_prior == 'log-uniform': log10_h = None # chirp mass [Msol] log10_Mc = parameter.Uniform(6.0, 10.0)('{}_log10_Mc'.format(name)) # luminosity distance [Mpc] log10_dL = parameter.Uniform(-2.0, 4.0)('{}_log10_dL'.format(name)) # orbital frequency [Hz] if log10_F is None: log10_Forb = parameter.Uniform(-9.0, -7.0)('{}_log10_Forb'.format(name)) else: log10_Forb = parameter.Constant(log10_F)('{}_log10_Forb'.format(name)) # orbital inclination angle [radians] cosinc = parameter.Uniform(-1.0, 1.0)('{}_cosinc'.format(name)) # periapsis position angle [radians] gamma_0 = parameter.Uniform(0.0, np.pi)('{}_gamma0'.format(name)) # Earth-term eccentricity if ecc is None: e_0 = parameter.Uniform(0.0, 0.99)('{}_e0'.format(name)) else: e_0 = parameter.Constant(ecc)('{}_e0'.format(name)) # initial mean anomaly [radians] l_0 = parameter.Uniform(0.0, 2.0*np.pi)('{}_l0'.format(name)) # mass ratio = M_2/M_1 q = parameter.Constant(1.0)('{}_q'.format(name)) # polarization pol_name = '{}_pol'.format(name) pol = parameter.Uniform(0, np.pi)(pol_name) # sky location costh_name = '{}_costheta'.format(name) phi_name = '{}_phi'.format(name) if skyloc is None: costh = parameter.Uniform(-1, 1)(costh_name) phi = parameter.Uniform(0, 2*np.pi)(phi_name) else: costh = parameter.Constant(skyloc[0])(costh_name) phi = parameter.Constant(skyloc[1])(phi_name) # continuous wave signal wf = compute_eccentric_residuals(cos_gwtheta=costh, gwphi=phi, log10_mc=log10_Mc, log10_dist=log10_dL, log10_h=log10_h, log10_F=log10_Forb, cos_inc=cosinc, psi=pol, gamma0=gamma_0, e0=e_0, l0=l_0, q=q, nmax=400, pdist=None, pphase=None, pgam=None, tref=tref, check=False) cw = CWSignal(wf, ecc=True, psrTerm=psrTerm) return cw @signal_base.function def cw_delay(toas, pos, pdist, cos_gwtheta=0, gwphi=0, cos_inc=0, log10_mc=9, log10_fgw=-8, log10_dist=None, log10_h=None, phase0=0, psi=0, psrTerm=False, p_dist=1, p_phase=None, evolve=False, phase_approx=False, check=False, tref=0): """ Function to create GW incuced residuals from a SMBMB as defined in Ellis et. al 2012,2013. :param toas: Pular toas in seconds :param pos: Unit vector from the Earth to the pulsar :param pdist: Pulsar distance (mean and uncertainty) [kpc] :param cos_gwtheta: Cosine of Polar angle of GW source in celestial coords [radians] :param gwphi: Azimuthal angle of GW source in celestial coords [radians] :param cos_inc: cosine of Inclination of GW source [radians] :param log10_mc: log10 of Chirp mass of SMBMB [solar masses] :param log10_fgw: log10 of Frequency of GW (twice the orbital frequency) [Hz] :param log10_dist: log10 of Luminosity distance to SMBMB [Mpc], used to compute strain, if not None :param log10_h: log10 of GW strain, used to compute distance, if not None :param phase0: Initial GW phase of source [radians] :param psi: Polarization angle of GW source [radians] :param psrTerm: Option to include pulsar term [boolean] :param p_dist: Pulsar distance parameter :param p_phase: Use pulsar phase to determine distance [radian] :param evolve: Option to include/exclude full evolution [boolean] :param phase_approx: Option to include/exclude phase evolution across observation time [boolean] :param check: Check if frequency evolves significantly over obs. time [boolean] :param tref: Reference time for phase and frequency [s] :return: Vector of induced residuals """ # convert units to time mc = 10**log10_mc * const.Tsun fgw = 10**log10_fgw gwtheta = np.arccos(cos_gwtheta) inc = np.arccos(cos_inc) p_dist = (pdist[0] + pdist[1]*p_dist)*const.kpc/const.c if log10_h is None and log10_dist is None: raise ValueError("one of log10_dist or log10_h must be non-None") elif log10_h is not None and log10_dist is not None: raise ValueError("only one of log10_dist or log10_h can be non-None") elif log10_h is None: dist = 10**log10_dist * const.Mpc / const.c else: dist = 2 * mc**(5/3) * (np.pi*fgw)**(2/3) / 10**log10_h if check: # check that frequency is not evolving significantly over obs. time fstart = fgw * (1 - 256/5 * mc**(5/3) * fgw**(8/3) * toas[0])**(-3/8) fend = fgw * (1 - 256/5 * mc**(5/3) * fgw**(8/3) * toas[-1])**(-3/8) df = fend - fstart # observation time Tobs = toas.max()-toas.min() fbin = 1/Tobs if np.abs(df) > fbin: print('WARNING: Frequency is evolving over more than one ' 'frequency bin.') print('f0 = {0}, f1 = {1}, df = {2}, fbin = {3}'.format(fstart, fend, df, fbin)) return np.ones(len(toas)) * np.nan # get antenna pattern funcs and cosMu # write function to get pos from theta,phi fplus, fcross, cosMu = utils.create_gw_antenna_pattern(pos, gwtheta, gwphi) # get pulsar time toas -= tref if p_dist > 0: tp = toas-p_dist*(1-cosMu) else: tp = toas # orbital frequency w0 = np.pi * fgw phase0 /= 2 # convert GW to orbital phase # omegadot = 96/5 * mc**(5/3) * w0**(11/3) # Not currently used in code # evolution if evolve: # calculate time dependent frequency at earth and pulsar omega = w0 * (1 - 256/5 * mc**(5/3) * w0**(8/3) * toas)**(-3/8) omega_p = w0 * (1 - 256/5 * mc**(5/3) * w0**(8/3) * tp)**(-3/8) if p_dist > 0: omega_p0 = w0 * (1 + 256/5 * mc**(5/3) * w0**(8/3) * p_dist*(1-cosMu))**(-3/8) else: omega_p0 = w0 # calculate time dependent phase phase = phase0 + 1/32/mc**(5/3) * (w0**(-5/3) - omega**(-5/3)) if p_phase is None: phase_p = phase0 + 1/32/mc**(5/3) * (w0**(-5/3) - omega_p**(-5/3)) else: phase_p = (phase0 + p_phase + 1/32*mc**(-5/3) * (omega_p0**(-5/3) - omega_p**(-5/3))) elif phase_approx: # monochromatic omega = w0 if p_dist > 0: omega_p = w0 * (1 + 256/5 * mc**(5/3) * w0**(8/3) * p_dist*(1-cosMu))**(-3/8) else: omega_p = w0 # phases phase = phase0 + omega * toas if p_phase is not None: phase_p = phase0 + p_phase + omega_p*toas else: phase_p = (phase0 + omega_p*toas + 1/32/mc**(5/3) * (w0**(-5/3) - omega_p**(-5/3))) # no evolution else: # monochromatic omega = np.pi*fgw omega_p = omega # phases phase = phase0 + omega * toas phase_p = phase0 + omega * tp # define time dependent coefficients At = -0.5*np.sin(2*phase)*(3+np.cos(2*inc)) Bt = 2*np.cos(2*phase)*np.cos(inc) At_p = -0.5*np.sin(2*phase_p)*(3+np.cos(2*inc)) Bt_p = 2*np.cos(2*phase_p)*np.cos(inc) # now define time dependent amplitudes alpha = mc**(5./3.)/(dist*omega**(1./3.)) alpha_p = mc**(5./3.)/(dist*omega_p**(1./3.)) # define rplus and rcross rplus = alpha*(-At*np.cos(2*psi)+Bt*np.sin(2*psi)) rcross = alpha*(At*np.sin(2*psi)+Bt*np.cos(2*psi)) rplus_p = alpha_p*(-At_p*np.cos(2*psi)+Bt_p*np.sin(2*psi)) rcross_p = alpha_p*(At_p*np.sin(2*psi)+Bt_p*np.cos(2*psi)) # residuals if psrTerm: res = fplus*(rplus_p-rplus)+fcross*(rcross_p-rcross) else: res = -fplus*rplus - fcross*rcross return res @signal_base.function def bwm_delay(toas, pos, log10_h=-14.0, cos_gwtheta=0.0, gwphi=0.0, gwpol=0.0, t0=55000, antenna_pattern_fn=None): """ Function that calculates the earth-term gravitational-wave burst-with-memory signal, as described in: Seto et al, van haasteren and Levin, phsirkov et al, Cordes and Jenet. This version uses the F+/Fx polarization modes, as verified with the Continuous Wave and Anisotropy papers. :param toas: Time-of-arrival measurements [s] :param pos: Unit vector from Earth to pulsar :param log10_h: log10 of GW strain :param cos_gwtheta: Cosine of GW polar angle :param gwphi: GW azimuthal polar angle [rad] :param gwpol: GW polarization angle :param t0: Burst central time [day] :param antenna_pattern_fn: User defined function that takes `pos`, `gwtheta`, `gwphi` as arguments and returns (fplus, fcross) :return: the waveform as induced timing residuals (seconds) """ # convert h = 10 ** log10_h gwtheta = np.arccos(cos_gwtheta) t0 *= const.day # antenna patterns if antenna_pattern_fn is None: apc = utils.create_gw_antenna_pattern(pos, gwtheta, gwphi) else: apc = antenna_pattern_fn(pos, gwtheta, gwphi) # grab fplus, fcross fp, fc = apc[0], apc[1] # combined polarization pol = np.cos(2 * gwpol) * fp + np.sin(2 * gwpol) * fc # Return the time-series for the pulsar return pol * h * np.heaviside(toas - t0, 0.5) * (toas - t0) @signal_base.function def bwm_sglpsr_delay(toas, sign, log10_A=-15, t0=55000): """ Function that calculates the earth-term gravitational-wave burst-with-memory signal for an optimally oriented source in a single pulsar :param toas: Time-of-arrival measurements [s] :param log10_A: log10 of the amplitude of the ramp (delta_f/f) :param t0: Burst central time [day] :return: the waveform as induced timing residuals (seconds) """ A = 10 ** log10_A t0 *= const.day # Return the time-series for the pulsar def heaviside(x): return 0.5 * (np.sign(x) + 1) # return 0 #Fix the return to 0 in order to test what the heck is wrong with red noise detection in bwm return A * np.sign(sign) * heaviside(toas - t0) * (toas - t0) @signal_base.function def compute_eccentric_residuals(toas, theta, phi, cos_gwtheta, gwphi, log10_mc, log10_dist, log10_h, log10_F, cos_inc, psi, gamma0, e0, l0, q, nmax=400, pdist=1.0, pphase=None, pgam=None, psrTerm=False, tref=0, check=False): """ Simulate GW from eccentric SMBHB. Waveform models from Taylor et al. (2015) and Barack and Cutler (2004). WARNING: This residual waveform is only accurate if the GW frequency is not significantly evolving over the observation time of the pulsar. :param toa: pulsar observation times :param theta: polar coordinate of pulsar :param phi: azimuthal coordinate of pulsar :param gwtheta: Polar angle of GW source in celestial coords [radians] :param gwphi: Azimuthal angle of GW source in celestial coords [radians] :param log10_mc: Base-10 lof of chirp mass of SMBMB [solar masses] :param log10_dist: Base-10 uminosity distance to SMBMB [Mpc] :param log10_F: base-10 orbital frequency of SMBHB [Hz] :param inc: Inclination of GW source [radians] :param psi: Polarization of GW source [radians] :param gamma0: Initial angle of periastron [radians] :param e0: Initial eccentricity of SMBHB :param l0: Initial mean anomoly [radians] :param q: Mass ratio of SMBHB :param nmax: Number of harmonics to use in waveform decomposition :param pdist: Pulsar distance [kpc] :param pphase: Pulsar phase [rad] :param pgam: Pulsar angle of periastron [rad] :param psrTerm: Option to include pulsar term [boolean] :param tref: Fidicuial time at which initial parameters are referenced [s] :param check: Check if frequency evolves significantly over obs. time :returns: Vector of induced residuals """ # convert from sampling F = 10.0**log10_F mc = 10.0**log10_mc dist = 10.0**log10_dist if log10_h is not None: h0 = 10.0**log10_h else: h0 = None inc = np.arccos(cos_inc) gwtheta = np.arccos(cos_gwtheta) # define variable for later use cosgwtheta, cosgwphi = np.cos(gwtheta), np.cos(gwphi) singwtheta, singwphi = np.sin(gwtheta), np.sin(gwphi) sin2psi, cos2psi = np.sin(2*psi), np.cos(2*psi) # unit vectors to GW source m = np.array([singwphi, -cosgwphi, 0.0]) n = np.array([-cosgwtheta*cosgwphi, -cosgwtheta*singwphi, singwtheta]) omhat = np.array([-singwtheta*cosgwphi, -singwtheta*singwphi, -cosgwtheta]) # pulsar position vector phat = np.array([np.sin(theta)*np.cos(phi), np.sin(theta)*np.sin(phi), np.cos(theta)]) fplus = 0.5 * (np.dot(m, phat)**2 - np.dot(n, phat)**2) / (1+np.dot(omhat, phat)) fcross = (np.dot(m, phat)*np.dot(n, phat)) / (1 + np.dot(omhat, phat)) cosMu = -np.dot(omhat, phat) # get values from pulsar object toas = toas.copy() - tref if check: # check that frequency is not evolving significantly over obs. time y = utils.solve_coupled_ecc_solution(F, e0, gamma0, l0, mc, q, np.array([0.0, toas.max()])) # initial and final values over observation time Fc0, ec0, gc0, phic0 = y[0, :] Fc1, ec1, gc1, phic1 = y[-1, :] # observation time Tobs = 1/(toas.max()-toas.min()) if np.abs(Fc0-Fc1) > 1/Tobs: print('WARNING: Frequency is evolving over more than one frequency bin.') print('F0 = {0}, F1 = {1}, delta f = {2}'.format(Fc0, Fc1, 1/Tobs)) return np.ones(len(toas)) * np.nan # get gammadot for earth term gammadot = utils.get_gammadot(F, mc, q, e0) # get number of harmonics to use if not isinstance(nmax, int): if e0 < 0.999 and e0 > 0.001: nharm = int(nmax(e0)) elif e0 < 0.001: nharm = 2 else: nharm = int(nmax(0.999)) else: nharm = nmax # no more than 100 harmonics nharm = min(nharm, 100) ##### earth term ##### splus, scross = utils.calculate_splus_scross(nmax=nharm, mc=mc, dl=dist, h0=h0, F=F, e=e0, t=toas.copy(), l0=l0, gamma=gamma0, gammadot=gammadot, inc=inc) ##### pulsar term ##### if psrTerm: # pulsar distance pd = pdist # convert units pd *= const.kpc / const.c # get pulsar time tp = toas.copy() - pd * (1-cosMu) # solve coupled system of equations to get pulsar term values y = utils.solve_coupled_ecc_solution(F, e0, gamma0, l0, mc, q, np.array([0.0, tp.min()])) # get pulsar term values if np.any(y): Fp, ep, gp, phip = y[-1, :] # get gammadot at pulsar term gammadotp = utils.get_gammadot(Fp, mc, q, ep) # get phase at pulsar if pphase is None: lp = phip else: lp = pphase # get angle of periastron at pulsar if pgam is None: gp = gp else: gp = pgam # get number of harmonics to use if not isinstance(nmax, int): if e0 < 0.999 and e0 > 0.001: nharm = int(nmax(e0)) elif e0 < 0.001: nharm = 2 else: nharm = int(nmax(0.999)) else: nharm = nmax # no more than 1000 harmonics nharm = min(nharm, 100) splusp, scrossp = utils.calculate_splus_scross(nmax=nharm, mc=mc, dl=dist, h0=h0, F=Fp, e=ep, t=toas.copy(), l0=lp, gamma=gp, gammadot=gammadotp, inc=inc) rr = (fplus*cos2psi - fcross*sin2psi) * (splusp - splus) + \ (fplus*sin2psi + fcross*cos2psi) * (scrossp - scross) else: rr = np.ones(len(toas)) * np.nan else: rr = - (fplus*cos2psi - fcross*sin2psi) * splus - \ (fplus*sin2psi + fcross*cos2psi) * scross return rr def CWSignal(cw_wf, ecc=False, psrTerm=False, name='cw'): BaseClass = deterministic_signals.Deterministic(cw_wf, name=name) class CWSignal(BaseClass): def __init__(self, psr): super(CWSignal, self).__init__(psr) self._wf[''].add_kwarg(psrTerm=psrTerm) if ecc: pgam = parameter.Uniform(0, 2*np.pi)('_'.join([psr.name, 'pgam', name])) self._params['pgam'] = pgam self._wf['']._params['pgam'] = pgam return CWSignal @signal_base.function def generalized_gwpol_psd(f, log10_A_tt=-15, log10_A_st=-15, log10_A_vl=-15, log10_A_sl=-15, kappa=10/3, p_dist=1.0): """ PSD for a generalized mixture of scalar+vector dipole radiation and tensorial quadrupole radiation from SMBHBs. """ df = np.diff(np.concatenate((np.array([0]), f[::2]))) euler_e = 0.5772156649 pdist = p_dist * const.kpc / const.c orf_aa_tt = (2/3) * np.ones(len(f)) orf_aa_st = (2/3) * np.ones(len(f)) orf_aa_vl = 2*np.log(4*np.pi*f*pdist) - 14/3 + 2*euler_e orf_aa_sl = np.pi**2*f*pdist/4 - \ np.log(4*np.pi*f*pdist) + 37/24 - euler_e prefactor = (1 + kappa**2) / (1 + kappa**2 * (f / const.fyr)**(-2/3)) gwpol_amps = 10**(2*np.array([log10_A_tt, log10_A_st, log10_A_vl, log10_A_sl])) gwpol_factors = np.array([orf_aa_tt*gwpol_amps[0], orf_aa_st*gwpol_amps[1], orf_aa_vl*gwpol_amps[2], orf_aa_sl*gwpol_amps[3]]) S_psd = prefactor * (gwpol_factors[0, :] * (f / const.fyr)**(-4/3) + np.sum(gwpol_factors[1:, :], axis=0) * (f / const.fyr)**(-2)) / \ (8*np.pi**2*f**3) return S_psd * np.repeat(df, 2) @signal_base.function def fdm_delay(toas, log10_A, log10_f, phase_e, phase_p): """ Function that calculates the earth-term gravitational-wave fuzzy dark matter signal, as described in: Kato et al. (2020). :param toas: Time-of-arrival measurements [s] :param log10_A: log10 of GW strain :param log10_f: log10 of GW frequency :param phase_e: The Earth-term phase of the GW :param phase_p: The Pulsar-term phase of the GW :return: the waveform as induced timing residuals (seconds) """ # convert A = 10 ** log10_A f = 10 ** log10_f # Return the time-series for the pulsar return - A / (2 * np.pi * f) * (np.sin(2 * np.pi * f * toas + phase_e) - np.sin(2 * np.pi * f * toas + phase_p))

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/sampler.py

# -*- coding: utf-8 -*- import glob import os import pickle import platform import healpy as hp import numpy as np from PTMCMCSampler import __version__ as __vPTMCMC__ from PTMCMCSampler.PTMCMCSampler import PTSampler as ptmcmc from enterprise_extensions import __version__ from enterprise_extensions.empirical_distr import (EmpiricalDistribution1D, EmpiricalDistribution1DKDE, EmpiricalDistribution2D, EmpiricalDistribution2DKDE) def extend_emp_dists(pta, emp_dists, npoints=100_000, save_ext_dists=False, outdir='./chains'): new_emp_dists = [] modified = False # check if anything was changed for emp_dist in emp_dists: if isinstance(emp_dist, EmpiricalDistribution2D) or isinstance(emp_dist, EmpiricalDistribution2DKDE): # check if we need to extend the distribution prior_ok=True for ii, (param, nbins) in enumerate(zip(emp_dist.param_names, emp_dist._Nbins)): param_names = [par.name for par in pta.params] if param not in param_names: # skip if one of the parameters isn't in our PTA object short_par = '_'.join(param.split('_')[:-1]) # make sure we aren't skipping priors with size!=None if short_par in param_names: param = short_par else: continue # check 2 conditions on both params to make sure that they cover their priors # skip if emp dist already covers the prior param_idx = param_names.index(param) if pta.params[param_idx].type not in ['uniform', 'normal']: msg = '{} cannot be covered automatically by the empirical distribution\n'.format(pta.params[param_idx].prior) msg += 'Please check that your prior is covered by the empirical distribution.\n' print(msg) continue elif pta.params[param_idx].type == 'uniform': prior_min = pta.params[param_idx].prior._defaults['pmin'] prior_max = pta.params[param_idx].prior._defaults['pmax'] elif pta.params[param_idx].type == 'normal': prior_min = pta.params[param_idx].prior._defaults['mu'] - 10 * pta.params[param_idx].prior._defaults['sigma'] prior_max = pta.params[param_idx].prior._defaults['mu'] + 10 * pta.params[param_idx].prior._defaults['sigma'] # no need to extend if histogram edges are already prior min/max if isinstance(emp_dist, EmpiricalDistribution2D): if not (emp_dist._edges[ii][0] == prior_min and emp_dist._edges[ii][-1] == prior_max): prior_ok = False continue elif isinstance(emp_dist, EmpiricalDistribution2DKDE): if not (emp_dist.minvals[ii] == prior_min and emp_dist.maxvals[ii] == prior_max): prior_ok=False continue if prior_ok: new_emp_dists.append(emp_dist) continue modified = True samples = np.zeros((npoints, emp_dist.draw().shape[0])) for ii in range(npoints): # generate samples from old emp dist samples[ii] = emp_dist.draw() new_bins = [] minvals = [] maxvals = [] idxs_to_remove = [] for ii, (param, nbins) in enumerate(zip(emp_dist.param_names, emp_dist._Nbins)): param_idx = param_names.index(param) if pta.params[param_idx].type == 'uniform': prior_min = pta.params[param_idx].prior._defaults['pmin'] prior_max = pta.params[param_idx].prior._defaults['pmax'] elif pta.params[param_idx].type == 'normal': prior_min = pta.params[param_idx].prior._defaults['mu'] - 10 * pta.params[param_idx].prior._defaults['sigma'] prior_max = pta.params[param_idx].prior._defaults['mu'] + 10 * pta.params[param_idx].prior._defaults['sigma'] # drop samples that are outside the prior range (in case prior is smaller than samples) if isinstance(emp_dist, EmpiricalDistribution2D): samples[(samples[:, ii] < prior_min) | (samples[:, ii] > prior_max), ii] = -np.inf elif isinstance(emp_dist, EmpiricalDistribution2DKDE): idxs_to_remove.extend(np.arange(npoints)[(samples[:, ii] < prior_min) | (samples[:, ii] > prior_max)]) minvals.append(prior_min) maxvals.append(prior_max) # new distribution with more bins this time to extend it all the way out in same style as above. new_bins.append(np.linspace(prior_min, prior_max, nbins + 40)) samples = np.delete(samples, idxs_to_remove, axis=0) if isinstance(emp_dist, EmpiricalDistribution2D): new_emp = EmpiricalDistribution2D(emp_dist.param_names, samples.T, new_bins) elif isinstance(emp_dist, EmpiricalDistribution2DKDE): # new distribution with more bins this time to extend it all the way out in same style as above. new_emp = EmpiricalDistribution2DKDE(emp_dist.param_names, samples.T, minvals=minvals, maxvals=maxvals, nbins=nbins+40, bandwidth=emp_dist.bandwidth) new_emp_dists.append(new_emp) elif isinstance(emp_dist, EmpiricalDistribution1D) or isinstance(emp_dist, EmpiricalDistribution1DKDE): param_names = [par.name for par in pta.params] if emp_dist.param_name not in param_names: # skip if one of the parameters isn't in our PTA object short_par = '_'.join(emp_dist.param_name.split('_')[:-1]) # make sure we aren't skipping priors with size!=None if short_par in param_names: param = short_par else: continue else: param = emp_dist.param_name param_idx = param_names.index(param) if pta.params[param_idx].type not in ['uniform', 'normal']: msg = 'This prior cannot be covered automatically by the empirical distribution\n' msg += 'Please check that your prior is covered by the empirical distribution.\n' print(msg) continue if pta.params[param_idx].type == 'uniform': prior_min = pta.params[param_idx].prior._defaults['pmin'] prior_max = pta.params[param_idx].prior._defaults['pmax'] elif pta.params[param_idx].type == 'uniform': prior_min = pta.params[param_idx].prior._defaults['mu'] - 10 * pta.params[param_idx].prior._defaults['sigma'] prior_max = pta.params[param_idx].prior._defaults['mu'] + 10 * pta.params[param_idx].prior._defaults['sigma'] # check 2 conditions on param to make sure that it covers the prior # skip if emp dist already covers the prior if isinstance(emp_dist, EmpiricalDistribution1D): if emp_dist._edges[0] == prior_min and emp_dist._edges[-1] == prior_max: new_emp_dists.append(emp_dist) continue elif isinstance(emp_dist, EmpiricalDistribution1DKDE): if emp_dist.minval == prior_min and emp_dist.maxval == prior_max: new_emp_dists.append(emp_dist) continue modified = True samples = np.zeros((npoints, 1)) for ii in range(npoints): # generate samples from old emp dist samples[ii] = emp_dist.draw() new_bins = [] idxs_to_remove = [] # drop samples that are outside the prior range (in case prior is smaller than samples) if isinstance(emp_dist, EmpiricalDistribution1D): samples[(samples < prior_min) | (samples > prior_max)] = -np.inf elif isinstance(emp_dist, EmpiricalDistribution1DKDE): idxs_to_remove.extend(np.arange(npoints)[(samples.squeeze() < prior_min) | (samples.squeeze() > prior_max)]) samples = np.delete(samples, idxs_to_remove, axis=0) new_bins = np.linspace(prior_min, prior_max, emp_dist._Nbins + 40) if isinstance(emp_dist, EmpiricalDistribution1D): new_emp = EmpiricalDistribution1D(emp_dist.param_name, samples, new_bins) elif isinstance(emp_dist, EmpiricalDistribution1DKDE): new_emp = EmpiricalDistribution1DKDE(emp_dist.param_name, samples, minval=prior_min, maxval=prior_max, bandwidth=emp_dist.bandwidth) new_emp_dists.append(new_emp) else: print('Unable to extend class of unknown type to the edges of the priors.') new_emp_dists.append(emp_dist) continue if save_ext_dists and modified: # if user wants to save them, and they have been modified... with open(outdir + '/new_emp_dists.pkl', 'wb') as f: pickle.dump(new_emp_dists, f) return new_emp_dists class JumpProposal(object): def __init__(self, pta, snames=None, empirical_distr=None, f_stat_file=None, save_ext_dists=False, outdir='./chains'): """Set up some custom jump proposals""" self.params = pta.params self.pnames = pta.param_names self.psrnames = pta.pulsars self.ndim = sum(p.size or 1 for p in pta.params) self.plist = [p.name for p in pta.params] # parameter map self.pmap = {} ct = 0 for p in pta.params: size = p.size or 1 self.pmap[str(p)] = slice(ct, ct+size) ct += size # parameter indices map self.pimap = {} for ct, p in enumerate(pta.param_names): self.pimap[p] = ct # collecting signal parameters across pta if snames is None: allsigs = np.hstack([[qq.signal_name for qq in pp._signals] for pp in pta._signalcollections]) self.snames = dict.fromkeys(np.unique(allsigs)) for key in self.snames: self.snames[key] = [] for sc in pta._signalcollections: for signal in sc._signals: self.snames[signal.signal_name].extend(signal.params) for key in self.snames: self.snames[key] = list(set(self.snames[key])) else: self.snames = snames # empirical distributions if isinstance(empirical_distr, list): # check if a list of emp dists is provided self.empirical_distr = empirical_distr # check if a directory of empirical dist pkl files are provided elif empirical_distr is not None and os.path.isdir(empirical_distr): dir_files = glob.glob(empirical_distr+'*.pkl') # search for pkls pickled_distr = np.array([]) for idx, emp_file in enumerate(dir_files): try: with open(emp_file, 'rb') as f: pickled_distr = np.append(pickled_distr, pickle.load(f)) except: try: with open(emp_file, 'rb') as f: pickled_distr = np.append(pickled_distr, pickle.load(f)) except: print(f'\nI can\'t open the empirical distribution pickle file at location {idx} in list!') print("Empirical distributions set to 'None'") pickled_distr = None break self.empirical_distr = pickled_distr # check if single pkl file provided elif empirical_distr is not None and os.path.isfile(empirical_distr): # checking for single file try: # try opening the file with open(empirical_distr, 'rb') as f: pickled_distr = pickle.load(f) except: # second attempt at opening the file try: with open(empirical_distr, 'rb') as f: pickled_distr = pickle.load(f) # if the second attempt fails... except: print('\nI can\'t open the empirical distribution pickle file!') pickled_distr = None self.empirical_distr = pickled_distr # all other cases - emp dists set to None else: self.empirical_distr = None if self.empirical_distr is not None: # only save the empirical distributions for parameters that are in the model mask = [] for idx, d in enumerate(self.empirical_distr): if d.ndim == 1: if d.param_name in pta.param_names: mask.append(idx) else: if d.param_names[0] in pta.param_names and d.param_names[1] in pta.param_names: mask.append(idx) if len(mask) >= 1: self.empirical_distr = [self.empirical_distr[m] for m in mask] # extend empirical_distr here: print('Extending empirical distributions to priors...\n') self.empirical_distr = extend_emp_dists(pta, self.empirical_distr, npoints=100_000, save_ext_dists=save_ext_dists, outdir=outdir) else: self.empirical_distr = None if empirical_distr is not None and self.empirical_distr is None: # if an emp dist path is provided, but fails the code, this helpful msg is provided print("Adding empirical distributions failed!! Empirical distributions set to 'None'\n") # F-statistic map if f_stat_file is not None and os.path.isfile(f_stat_file): npzfile = np.load(f_stat_file) self.fe_freqs = npzfile['freqs'] self.fe = npzfile['fe'] def draw_from_prior(self, x, iter, beta): """Prior draw. The function signature is specific to PTMCMCSampler. """ q = x.copy() lqxy = 0 # randomly choose parameter param = np.random.choice(self.params) # if vector parameter jump in random component if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_red_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'red noise' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_empirical_distr(self, x, iter, beta): q = x.copy() lqxy = 0 if self.empirical_distr is not None: # randomly choose one of the empirical distributions distr_idx = np.random.randint(0, len(self.empirical_distr)) if self.empirical_distr[distr_idx].ndim == 1: idx = self.pnames.index(self.empirical_distr[distr_idx].param_name) q[idx] = self.empirical_distr[distr_idx].draw() lqxy = (self.empirical_distr[distr_idx].logprob(x[idx]) - self.empirical_distr[distr_idx].logprob(q[idx])) dist = self.empirical_distr[distr_idx] # if we fall outside the emp distr support, pull from prior instead if x[idx] < dist._edges[0] or x[idx] > dist._edges[-1]: q, lqxy = self.draw_from_prior(x, iter, beta) else: dist = self.empirical_distr[distr_idx] oldsample = [x[self.pnames.index(p)] for p in dist.param_names] newsample = dist.draw() lqxy = (dist.logprob(oldsample) - dist.logprob(newsample)) for p, n in zip(dist.param_names, newsample): q[self.pnames.index(p)] = n # if we fall outside the emp distr support, pull from prior instead for ii in range(len(oldsample)): if oldsample[ii] < dist._edges[ii][0] or oldsample[ii] > dist._edges[ii][-1]: q, lqxy = self.draw_from_prior(x, iter, beta) return q, float(lqxy) def draw_from_psr_empirical_distr(self, x, iter, beta): q = x.copy() lqxy = 0 if self.empirical_distr is not None: # make list of empirical distributions with psr name psr = np.random.choice(self.psrnames) pnames = [ed.param_name if ed.ndim==1 else ed.param_names for ed in self.empirical_distr] # Retrieve indices of emp dists with pulsar pars. idxs = [] for par in pnames: if isinstance(par, str): if psr in par: idxs.append(pnames.index(par)) elif isinstance(par, list): if any([psr in p for p in par]): idxs.append(pnames.index(par)) for idx in idxs: if self.empirical_distr[idx].ndim == 1: pidx = self.pimap[self.empirical_distr[idx].param_name] q[pidx] = self.empirical_distr[idx].draw() lqxy += (self.empirical_distr[idx].logprob(x[pidx]) - self.empirical_distr[idx].logprob(q[pidx])) else: oldsample = [x[self.pnames.index(p)] for p in self.empirical_distr[idx].param_names] newsample = self.empirical_distr[idx].draw() for p, n in zip(self.empirical_distr[idx].param_names, newsample): q[self.pnames.index(p)] = n lqxy += (self.empirical_distr[idx].logprob(oldsample) - self.empirical_distr[idx].logprob(newsample)) return q, float(lqxy) def draw_from_dm_gp_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'dm_gp' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_dm1yr_prior(self, x, iter, beta): q = x.copy() dm1yr_names = [dmname for dmname in self.pnames if 'dm_s1yr' in dmname] dmname = np.random.choice(dm1yr_names) idx = self.pnames.index(dmname) if 'log10_Amp' in dmname: q[idx] = np.random.uniform(-10, -2) elif 'phase' in dmname: q[idx] = np.random.uniform(0, 2*np.pi) return q, 0 def draw_from_dmexpdip_prior(self, x, iter, beta): q = x.copy() dmexp_names = [dmname for dmname in self.pnames if 'dmexp' in dmname] dmname = np.random.choice(dmexp_names) idx = self.pnames.index(dmname) if 'log10_Amp' in dmname: q[idx] = np.random.uniform(-10, -2) elif 'log10_tau' in dmname: q[idx] = np.random.uniform(0, 2.5) elif 'sign_param' in dmname: q[idx] = np.random.uniform(-1.0, 1.0) return q, 0 def draw_from_dmexpcusp_prior(self, x, iter, beta): q = x.copy() dmexp_names = [dmname for dmname in self.pnames if 'dm_cusp' in dmname] dmname = np.random.choice(dmexp_names) idx = self.pnames.index(dmname) if 'log10_Amp' in dmname: q[idx] = np.random.uniform(-10, -2) elif 'log10_tau' in dmname: q[idx] = np.random.uniform(0, 2.5) # elif 't0' in dmname: # q[idx] = np.random.uniform(53393.0, 57388.0) elif 'sign_param' in dmname: q[idx] = np.random.uniform(-1.0, 1.0) return q, 0 def draw_from_dmx_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'dmx_signal' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_chrom_gp_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'chrom_gp' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_gwb_log_uniform_distribution(self, x, iter, beta): q = x.copy() lqxy = 0 # draw parameter from signal model signal_name = [par for par in self.pnames if ('gw' in par and 'log10_A' in par)][0] idx = list(self.pnames).index(signal_name) param = self.params[idx] q[self.pmap[str(param)]] = np.random.uniform(param.prior._defaults['pmin'], param.prior._defaults['pmax']) # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_dipole_log_uniform_distribution(self, x, iter, beta): q = x.copy() # draw parameter from signal model idx = self.pnames.index('dipole_log10_A') q[idx] = np.random.uniform(-18, -11) return q, 0 def draw_from_monopole_log_uniform_distribution(self, x, iter, beta): q = x.copy() # draw parameter from signal model idx = self.pnames.index('monopole_log10_A') q[idx] = np.random.uniform(-18, -11) return q, 0 def draw_from_altpol_log_uniform_distribution(self, x, iter, beta): q = x.copy() # draw parameter from signal model polnames = [pol for pol in self.pnames if 'log10Apol' in pol] if 'kappa' in self.pnames: polnames.append('kappa') pol = np.random.choice(polnames) idx = self.pnames.index(pol) if pol == 'log10Apol_tt': q[idx] = np.random.uniform(-18, -12) elif pol == 'log10Apol_st': q[idx] = np.random.uniform(-18, -12) elif pol == 'log10Apol_vl': q[idx] = np.random.uniform(-18, -15) elif pol == 'log10Apol_sl': q[idx] = np.random.uniform(-18, -16) elif pol == 'kappa': q[idx] = np.random.uniform(0, 10) return q, 0 def draw_from_ephem_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'phys_ephem' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_bwm_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'bwm' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_fdm_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'fdm' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_cw_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'cw' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_cw_log_uniform_distribution(self, x, iter, beta): q = x.copy() # draw parameter from signal model idx = self.pnames.index('log10_h') q[idx] = np.random.uniform(-18, -11) return q, 0 def draw_from_dm_sw_prior(self, x, iter, beta): q = x.copy() lqxy = 0 signal_name = 'gp_sw' # draw parameter from signal model param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_gw_rho_prior(self, x, iter, beta): """ Jump proposals on free spec """ q = x.copy() lqxy = 0 # draw parameter from signal model parnames = [par.name for par in self.params] pname = [pnm for pnm in parnames if ('gw' in pnm and 'rho' in pnm)][0] idx = parnames.index(pname) param = self.params[idx] if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_signal_prior(self, x, iter, beta): q = x.copy() lqxy = 0 std = ['linear timing model', 'red noise', 'phys_ephem', 'gw', 'cw', 'bwm', 'fdm', 'gp_sw', 'ecorr_sherman-morrison', 'ecorr', 'efac', 'equad', ] non_std = [nm for nm in self.snames.keys() if nm not in std] # draw parameter from signal model signal_name = np.random.choice(non_std) param = np.random.choice(self.snames[signal_name]) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) def draw_from_par_prior(self, par_names): # Preparing and comparing par_names with PTA parameters par_names = np.atleast_1d(par_names) par_list = [] name_list = [] for par_name in par_names: pn_list = [n for n in self.plist if par_name in n] if pn_list: par_list.append(pn_list) name_list.append(par_name) if not par_list: raise UserWarning("No parameter prior match found between {} and PTA.object." .format(par_names)) par_list = np.concatenate(par_list, axis=None) def draw(x, iter, beta): """Prior draw function generator for custom par_names. par_names: list of strings The function signature is specific to PTMCMCSampler. """ q = x.copy() lqxy = 0 # randomly choose parameter idx_name = np.random.choice(par_list) idx = self.plist.index(idx_name) # if vector parameter jump in random component param = self.params[idx] if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) name_string = '_'.join(name_list) draw.__name__ = 'draw_from_{}_prior'.format(name_string) return draw def draw_from_par_log_uniform(self, par_dict): # Preparing and comparing par_dict.keys() with PTA parameters par_list = [] name_list = [] for par_name in par_dict.keys(): pn_list = [n for n in self.plist if par_name in n and 'log' in n] if pn_list: par_list.append(pn_list) name_list.append(par_name) if not par_list: raise UserWarning("No parameter dictionary match found between {} and PTA.object." .format(par_dict.keys())) par_list = np.concatenate(par_list, axis=None) def draw(x, iter, beta): """log uniform prior draw function generator for custom par_names. par_dict: dictionary with {"par_names":(lower bound,upper bound)} { "string":(float,float)} The function signature is specific to PTMCMCSampler. """ q = x.copy() # draw parameter from signal model idx_name = np.random.choice(par_list) idx = self.plist.index(idx_name) q[idx] = np.random.uniform(par_dict[par_name][0], par_dict[par_name][1]) return q, 0 name_string = '_'.join(name_list) draw.__name__ = 'draw_from_{}_log_uniform'.format(name_string) return draw def draw_from_psr_prior(self, x, iter, beta): q = x.copy() lqxy = 0 # draw parameter from pulsar names psr = np.random.choice(self.psrnames) idxs = [self.pimap[par] for par in self.pnames if psr in par] for idx in idxs: q[idx] = self.params[idx].sample() # forward-backward jump probability first = np.sum([self.params[idx].get_logpdf(x[idx]) for idx in idxs]) last = np.sum([self.params[idx].get_logpdf(q[idx]) for idx in idxs]) lqxy = first - last return q, float(lqxy) def draw_from_signal(self, signal_names): # Preparing and comparing signal_names with PTA signals signal_names = np.atleast_1d(signal_names) signal_list = [] name_list = [] for signal_name in signal_names: try: param_list = self.snames[signal_name] signal_list.append(param_list) name_list.append(signal_name) except: pass if not signal_list: raise UserWarning("No signal match found between {} and PTA.object!" .format(signal_names)) signal_list = np.concatenate(signal_list, axis=None) def draw(x, iter, beta): """Signal draw function generator for custom signal_names. signal_names: list of strings The function signature is specific to PTMCMCSampler. """ q = x.copy() lqxy = 0 # draw parameter from signal model param = np.random.choice(signal_list) if param.size: idx2 = np.random.randint(0, param.size) q[self.pmap[str(param)]][idx2] = param.sample()[idx2] # scalar parameter else: q[self.pmap[str(param)]] = param.sample() # forward-backward jump probability lqxy = (param.get_logpdf(x[self.pmap[str(param)]]) - param.get_logpdf(q[self.pmap[str(param)]])) return q, float(lqxy) name_string = '_'.join(name_list) draw.__name__ = 'draw_from_{}_signal'.format(name_string) return draw def fe_jump(self, x, iter, beta): q = x.copy() lqxy = 0 fe_limit = np.max(self.fe) # draw skylocation and frequency from f-stat map accepted = False while accepted is False: log_f_new = self.params[self.pimap['log10_fgw']].sample() f_idx = (np.abs(np.log10(self.fe_freqs) - log_f_new)).argmin() gw_theta = np.arccos(self.params[self.pimap['cos_gwtheta']].sample()) gw_phi = self.params[self.pimap['gwphi']].sample() hp_idx = hp.ang2pix(hp.get_nside(self.fe), gw_theta, gw_phi) fe_new_point = self.fe[f_idx, hp_idx] if np.random.uniform()<(fe_new_point/fe_limit): accepted = True # draw other parameters from prior cos_inc = self.params[self.pimap['cos_inc']].sample() psi = self.params[self.pimap['psi']].sample() phase0 = self.params[self.pimap['phase0']].sample() log10_h = self.params[self.pimap['log10_h']].sample() # put new parameters into q for param_name, new_param in zip(['log10_fgw', 'gwphi', 'cos_gwtheta', 'cos_inc', 'psi', 'phase0', 'log10_h'], [log_f_new, gw_phi, np.cos(gw_theta), cos_inc, psi, phase0, log10_h]): q[self.pimap[param_name]] = new_param # calculate Hastings ratio log_f_old = x[self.pimap['log10_fgw']] f_idx_old = (np.abs(np.log10(self.fe_freqs) - log_f_old)).argmin() gw_theta_old = np.arccos(x[self.pimap['cos_gwtheta']]) gw_phi_old = x[self.pimap['gwphi']] hp_idx_old = hp.ang2pix(hp.get_nside(self.fe), gw_theta_old, gw_phi_old) fe_old_point = self.fe[f_idx_old, hp_idx_old] if fe_old_point>fe_limit: fe_old_point = fe_limit log10_h_old = x[self.pimap['log10_h']] phase0_old = x[self.pimap['phase0']] psi_old = x[self.pimap['psi']] cos_inc_old = x[self.pimap['cos_inc']] hastings_extra_factor = self.params[self.pimap['log10_h']].get_pdf(log10_h_old) hastings_extra_factor *= 1/self.params[self.pimap['log10_h']].get_pdf(log10_h) hastings_extra_factor = self.params[self.pimap['phase0']].get_pdf(phase0_old) hastings_extra_factor *= 1/self.params[self.pimap['phase0']].get_pdf(phase0) hastings_extra_factor = self.params[self.pimap['psi']].get_pdf(psi_old) hastings_extra_factor *= 1/self.params[self.pimap['psi']].get_pdf(psi) hastings_extra_factor = self.params[self.pimap['cos_inc']].get_pdf(cos_inc_old) hastings_extra_factor *= 1/self.params[self.pimap['cos_inc']].get_pdf(cos_inc) lqxy = np.log(fe_old_point/fe_new_point * hastings_extra_factor) return q, float(lqxy) def get_global_parameters(pta): """Utility function for finding global parameters.""" pars = [] for sc in pta._signalcollections: pars.extend(sc.param_names) gpars = list(set(par for par in pars if pars.count(par) > 1)) ipars = [par for par in pars if par not in gpars] # gpars = np.unique(list(filter(lambda x: pars.count(x)>1, pars))) # ipars = np.array([p for p in pars if p not in gpars]) return np.array(gpars), np.array(ipars) def get_parameter_groups(pta): """Utility function to get parameter groupings for sampling.""" params = pta.param_names ndim = len(params) groups = [list(np.arange(0, ndim))] # get global and individual parameters gpars, ipars = get_global_parameters(pta) if gpars.size: # add a group of all global parameters groups.append([params.index(gp) for gp in gpars]) # make a group for each signal, with all non-global parameters for sc in pta._signalcollections: for signal in sc._signals: ind = [params.index(p) for p in signal.param_names if not gpars.size or p not in gpars] if ind: groups.append(ind) return groups def get_psr_groups(pta): groups = [] for psr in pta.pulsars: grp = [pta.param_names.index(par) for par in pta.param_names if psr in par] groups.append(grp) return groups def get_cw_groups(pta): """Utility function to get parameter groups for CW sampling. These groups should be appended to the usual get_parameter_groups() output. """ ang_pars = ['costheta', 'phi', 'cosinc', 'phase0', 'psi'] mfdh_pars = ['log10_Mc', 'log10_fgw', 'log10_dL', 'log10_h'] freq_pars = ['log10_Mc', 'log10_fgw', 'pdist', 'pphase'] groups = [] for pars in [ang_pars, mfdh_pars, freq_pars]: groups.append(group_from_params(pta, pars)) return groups def group_from_params(pta, params): gr = [] for p in params: for q in pta.param_names: if p in q: gr.append(pta.param_names.index(q)) return gr def save_runtime_info(pta, outdir='chains', human=None): """save system info, enterprise PTA.summary, and other metadata to file """ # save system info and enterprise PTA.summary to single file sysinfo = {} if human is not None: sysinfo.update({"human": human}) sysinfo.update(platform.uname()._asdict()) with open(os.path.join(outdir, "runtime_info.txt"), "w") as fout: for field, data in sysinfo.items(): fout.write(field + " : " + data + "\n") fout.write("\n") fout.write("enterprise_extensions v" + __version__ +"\n") fout.write("PTMCMCSampler v" + __vPTMCMC__ +"\n") fout.write(pta.summary()) # save paramter list with open(os.path.join(outdir, "pars.txt"), "w") as fout: for pname in pta.param_names: fout.write(pname + "\n") # save list of priors with open(os.path.join(outdir, "priors.txt"), "w") as fout: for pp in pta.params: fout.write(pp.__repr__() + "\n") def setup_sampler(pta, outdir='chains', resume=False, empirical_distr=None, groups=None, human=None, save_ext_dists=False, loglkwargs={}, logpkwargs={}): """ Sets up an instance of PTMCMC sampler. We initialize the sampler the likelihood and prior function from the PTA object. We set up an initial jump covariance matrix with fairly small jumps as this will be adapted as the MCMC runs. We will setup an output directory in `outdir` that will contain the chain (first n columns are the samples for the n parameters and last 4 are log-posterior, log-likelihood, acceptance rate, and an indicator variable for parallel tempering but it doesn't matter because we aren't using parallel tempering). We then add several custom jump proposals to the mix based on whether or not certain parameters are in the model. These are all either draws from the prior distribution of parameters or draws from uniform distributions. save_ext_dists: saves distributions that have been extended to cover priors as a pickle to the outdir folder. These can then be loaded later as distributions to save a minute at the start of the run. """ # dimension of parameter space params = pta.param_names ndim = len(params) # initial jump covariance matrix if os.path.exists(outdir+'/cov.npy') and resume: cov = np.load(outdir+'/cov.npy') # check that the one we load is the same shape as our data cov_new = np.diag(np.ones(ndim) * 0.1**2) if cov.shape != cov_new.shape: msg = 'The covariance matrix (cov.npy) in the output folder is ' msg += 'the wrong shape for the parameters given. ' msg += 'Start with a different output directory or ' msg += 'change resume to False to overwrite the run that exists.' raise ValueError(msg) else: cov = np.diag(np.ones(ndim) * 0.1**2) # parameter groupings if groups is None: groups = get_parameter_groups(pta) sampler = ptmcmc(ndim, pta.get_lnlikelihood, pta.get_lnprior, cov, groups=groups, outDir=outdir, resume=resume, loglkwargs=loglkwargs, logpkwargs=logpkwargs) save_runtime_info(pta, sampler.outDir, human) # additional jump proposals jp = JumpProposal(pta, empirical_distr=empirical_distr, save_ext_dists=save_ext_dists, outdir=outdir) sampler.jp = jp # always add draw from prior sampler.addProposalToCycle(jp.draw_from_prior, 5) # try adding empirical proposals if empirical_distr is not None: print('Attempting to add empirical proposals...\n') sampler.addProposalToCycle(jp.draw_from_empirical_distr, 10) # Red noise prior draw if 'red noise' in jp.snames: print('Adding red noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_red_prior, 10) # DM GP noise prior draw if 'dm_gp' in jp.snames: print('Adding DM GP noise prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dm_gp_prior, 10) # DM annual prior draw if 'dm_s1yr' in jp.snames: print('Adding DM annual prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dm1yr_prior, 10) # DM dip prior draw if 'dmexp' in jp.snames: print('Adding DM exponential dip prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmexpdip_prior, 10) # DM cusp prior draw if 'dm_cusp' in jp.snames: print('Adding DM exponential cusp prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmexpcusp_prior, 10) # DMX prior draw if 'dmx_signal' in jp.snames: print('Adding DMX prior draws...\n') sampler.addProposalToCycle(jp.draw_from_dmx_prior, 10) # Ephemeris prior draw if 'd_jupiter_mass' in pta.param_names: print('Adding ephemeris model prior draws...\n') sampler.addProposalToCycle(jp.draw_from_ephem_prior, 10) # GWB uniform distribution draw if np.any([('gw' in par and 'log10_A' in par) for par in pta.param_names]): print('Adding GWB uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_gwb_log_uniform_distribution, 10) # Dipole uniform distribution draw if 'dipole_log10_A' in pta.param_names: print('Adding dipole uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_dipole_log_uniform_distribution, 10) # Monopole uniform distribution draw if 'monopole_log10_A' in pta.param_names: print('Adding monopole uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_monopole_log_uniform_distribution, 10) # Altpol uniform distribution draw if 'log10Apol_tt' in pta.param_names: print('Adding alternative GW-polarization uniform distribution draws...\n') sampler.addProposalToCycle(jp.draw_from_altpol_log_uniform_distribution, 10) # BWM prior draw if 'bwm_log10_A' in pta.param_names: print('Adding BWM prior draws...\n') sampler.addProposalToCycle(jp.draw_from_bwm_prior, 10) # FDM prior draw if 'fdm_log10_A' in pta.param_names: print('Adding FDM prior draws...\n') sampler.addProposalToCycle(jp.draw_from_fdm_prior, 10) # CW prior draw if 'cw_log10_h' in pta.param_names: print('Adding CW strain prior draws...\n') sampler.addProposalToCycle(jp.draw_from_cw_log_uniform_distribution, 10) if 'cw_log10_Mc' in pta.param_names: print('Adding CW prior draws...\n') sampler.addProposalToCycle(jp.draw_from_cw_distribution, 10) # free spectrum prior draw if np.any(['log10_rho' in par for par in pta.param_names]): print('Adding free spectrum prior draws...\n') sampler.addProposalToCycle(jp.draw_from_gw_rho_prior, 25) return sampler

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/model_utils.py

# -*- coding: utf-8 -*- import time import matplotlib.pyplot as plt import numpy as np import scipy.stats as scistats try: import acor except ImportError: from emcee.autocorr import integrated_time as acor from enterprise_extensions import models # Log-spaced frequncies def linBinning(T, logmode, f_min, nlin, nlog): """ Get the frequency binning for the low-rank approximations, including log-spaced low-frequency coverage. Credit: van Haasteren & Vallisneri, MNRAS, Vol. 446, Iss. 2 (2015) :param T: Duration experiment :param logmode: From which linear mode to switch to log :param f_min: Down to which frequency we'll sample :param nlin: How many linear frequencies we'll use :param nlog: How many log frequencies we'll use """ if logmode < 0: raise ValueError("Cannot do log-spacing when all frequencies are" "linearly sampled") # First the linear spacing and weights df_lin = 1.0 / T f_min_lin = (1.0 + logmode) / T f_lin = np.linspace(f_min_lin, f_min_lin + (nlin-1)*df_lin, nlin) w_lin = np.sqrt(df_lin * np.ones(nlin)) if nlog > 0: # Now the log-spacing, and weights f_min_log = np.log(f_min) f_max_log = np.log((logmode+0.5)/T) df_log = (f_max_log - f_min_log) / (nlog) f_log = np.exp(np.linspace(f_min_log+0.5*df_log, f_max_log-0.5*df_log, nlog)) w_log = np.sqrt(df_log * f_log) return np.append(f_log, f_lin), np.append(w_log, w_lin) else: return f_lin, w_lin # New filter for different cadences def cadence_filter(psr, start_time=None, end_time=None, cadence=None): """ Filter data for coarser cadences. """ if start_time is None and end_time is None and cadence is None: mask = np.ones(psr._toas.shape, dtype=bool) else: # find start and end indices of cadence filtering start_idx = (np.abs((psr._toas / 86400) - start_time)).argmin() end_idx = (np.abs((psr._toas / 86400) - end_time)).argmin() # make a safe copy of sliced toas tmp_toas = psr._toas[start_idx:end_idx+1].copy() # cumulative sum of time differences cumsum = np.cumsum(np.diff(tmp_toas / 86400)) tspan = (tmp_toas.max() - tmp_toas.min()) / 86400 # find closest indices of sliced toas to desired cadence mask = [] for ii in np.arange(1.0, tspan, cadence): idx = (np.abs(cumsum - ii)).argmin() mask.append(idx) # append start and end segements with cadence-sliced toas mask = np.append(np.arange(start_idx), np.array(mask) + start_idx) mask = np.append(mask, np.arange(end_idx, len(psr._toas))) psr._toas = psr._toas[mask] psr._toaerrs = psr._toaerrs[mask] psr._residuals = psr._residuals[mask] psr._ssbfreqs = psr._ssbfreqs[mask] psr._designmatrix = psr._designmatrix[mask, :] dmx_mask = np.sum(psr._designmatrix, axis=0) != 0.0 psr._designmatrix = psr._designmatrix[:, dmx_mask] for key in psr._flags: psr._flags[key] = psr._flags[key][mask] if psr._planetssb is not None: psr._planetssb = psr.planetssb[mask, :, :] psr.sort_data() def get_tspan(psrs): """ Returns maximum time span for all pulsars. :param psrs: List of pulsar objects """ tmin = np.min([p.toas.min() for p in psrs]) tmax = np.max([p.toas.max() for p in psrs]) return tmax - tmin class PostProcessing(object): def __init__(self, chain, pars, burn_percentage=0.25): burn = int(burn_percentage*chain.shape[0]) self.chain = chain[burn:] self.pars = pars def plot_trace(self, plot_kwargs={}): ndim = len(self.pars) if ndim > 1: ncols = 4 nrows = int(np.ceil(ndim/ncols)) else: ncols, nrows = 1, 1 plt.figure(figsize=(15, 2*nrows)) for ii in range(ndim): plt.subplot(nrows, ncols, ii+1) plt.plot(self.chain[:, ii], **plot_kwargs) plt.title(self.pars[ii], fontsize=8) plt.tight_layout() def plot_hist(self, hist_kwargs={'bins': 50, 'normed': True}): ndim = len(self.pars) if ndim > 1: ncols = 4 nrows = int(np.ceil(ndim/ncols)) else: ncols, nrows = 1, 1 plt.figure(figsize=(15, 2*nrows)) for ii in range(ndim): plt.subplot(nrows, ncols, ii+1) plt.hist(self.chain[:, ii], **hist_kwargs) plt.title(self.pars[ii], fontsize=8) plt.tight_layout() def ul(chain, q=95.0): """ Computes upper limit and associated uncertainty. :param chain: MCMC samples of GWB (or common red noise) amplitude :param q: desired percentile of upper-limit value [out of 100, default=95] :returns: (upper limit, uncertainty on upper limit) """ hist = np.histogram(10.0**chain, bins=100) hist_dist = scistats.rv_histogram(hist) A_ul = 10**np.percentile(chain, q=q) p_ul = hist_dist.pdf(A_ul) Aul_error = np.sqrt((q/100.) * (1.0 - (q/100.0)) / (chain.shape[0]/acor.acor(chain)[0])) / p_ul return A_ul, Aul_error def bayes_fac(samples, ntol=200, logAmin=-18, logAmax=-14): """ Computes the Savage Dickey Bayes Factor and uncertainty. :param samples: MCMCF samples of GWB (or common red noise) amplitude :param ntol: Tolerance on number of samples in bin :returns: (bayes factor, 1-sigma bayes factor uncertainty) """ prior = 1 / (logAmax - logAmin) dA = np.linspace(0.01, 0.1, 100) bf = [] bf_err = [] mask = [] # selecting bins with more than 200 samples for ii, delta in enumerate(dA): n = np.sum(samples <= (logAmin + delta)) N = len(samples) post = n / N / delta bf.append(prior/post) bf_err.append(bf[ii]/np.sqrt(n)) if n > ntol: mask.append(ii) return np.mean(np.array(bf)[mask]), np.std(np.array(bf)[mask]) def odds_ratio(chain, models=[0, 1], uncertainty=True, thin=False): if thin: indep_samples = np.rint(chain.shape[0] / acor.acor(chain)[0]) samples = np.random.choice(chain.copy(), int(indep_samples)) else: samples = chain.copy() mask_top = np.rint(samples) == max(models) mask_bot = np.rint(samples) == min(models) top = float(np.sum(mask_top)) bot = float(np.sum(mask_bot)) if top == 0.0 and bot != 0.0: bf = 1.0 / bot elif bot == 0.0 and top != 0.0: bf = top else: bf = top / bot if uncertainty: if bot == 0. or top == 0.: sigma = 0.0 else: # Counting transitions from model 1 model 2 ct_tb = 0 for ii in range(len(mask_top)-1): if mask_top[ii]: if not mask_top[ii+1]: ct_tb += 1 # Counting transitions from model 2 to model 1 ct_bt = 0 for ii in range(len(mask_bot)-1): if mask_bot[ii]: if not mask_bot[ii+1]: ct_bt += 1 try: sigma = bf * np.sqrt((float(top) - float(ct_tb))/(float(top)*float(ct_tb)) + (float(bot) - float(ct_bt))/(float(bot)*float(ct_bt))) except ZeroDivisionError: sigma = 0.0 return bf, sigma elif not uncertainty: return bf def bic(chain, nobs, log_evidence=False): """ Computes the Bayesian Information Criterion. :param chain: MCMC samples of all parameters, plus meta-data :param nobs: Number of observations in data :param evidence: return evidence estimate too? :returns: (bic, evidence) """ nparams = chain.shape[1] - 4 # removing 4 aux columns maxlnlike = chain[:, -4].max() bic = np.log(nobs)*nparams - 2.0*maxlnlike if log_evidence: return (bic, -0.5*bic) else: return bic def mask_filter(psr, mask): """filter given pulsar data by user defined mask""" psr._toas = psr._toas[mask] psr._toaerrs = psr._toaerrs[mask] psr._residuals = psr._residuals[mask] psr._ssbfreqs = psr._ssbfreqs[mask] psr._designmatrix = psr._designmatrix[mask, :] dmx_mask = np.sum(psr._designmatrix, axis=0) != 0.0 psr._designmatrix = psr._designmatrix[:, dmx_mask] for key in psr._flags: psr._flags[key] = psr._flags[key][mask] if psr._planetssb is not None: psr._planetssb = psr.planetssb[mask, :, :] psr.sort_data() class CompareTimingModels(): """ Compare difference between the usual and marginalized timing models. After instantiating, the __call__() method can be used for sampling for any number of points. To see the results, use the results() method. :param psrs: Pulsar object containing pulsars from model :param model_name: String name of model to test. Model must be defined in enterprise_extensions.models. :param abs_tol: absolute tolerance for error between timing models (default 1e-3), set to None to bypass errors :param rel_tol: relative tolerance for error between timing models (default 1e-6), set to None to bypass errors :param dense: use the dense cholesky algorithm over sparse """ def __init__(self, psrs, model_name='model_1', abs_tol=1e-3, rel_tol=1e-6, dense=True, **kwargs): model = getattr(models, model_name) self.abs_tol = abs_tol self.rel_tol = rel_tol if dense: self.pta_marg = model(psrs, tm_marg=True, dense_like=True, **kwargs) # marginalized model else: self.pta_marg = model(psrs, tm_marg=True, **kwargs) # marginalized model self.pta_norm = model(psrs, **kwargs) # normal model self.tm_correction = 0 for psr in psrs: self.tm_correction -= 0.5 * np.log(1e40) * psr.Mmat.shape[1] self.abs_err = [] self.rel_err = [] self.count = 0 def check_timing(self, number=10_000): print('Timing sample creation...') start = time.time() for __ in range(number): x0 = np.hstack([p.sample() for p in self.pta_marg.params]) end = time.time() sample_time = end - start print('Sampling {0} points took {1} seconds.'.format(number, sample_time)) print('Timing MarginalizedTimingModel...') start = time.time() for __ in range(number): x0 = np.hstack([p.sample() for p in self.pta_marg.params]) self.pta_marg.get_lnlikelihood(x0) end = time.time() time_marg = end - start - sample_time # remove sampling time from total time taken print('Sampling {0} points took {1} seconds.'.format(number, time_marg)) print('Timing TimingModel...') start = time.time() for __ in range(number): x0 = np.hstack([p.sample() for p in self.pta_marg.params]) self.pta_norm.get_lnlikelihood(x0) end = time.time() time_norm = end - start - sample_time # remove sampling time from total time taken print('Sampling {0} points took {1} seconds.'.format(number, time_norm)) res = time_norm / time_marg print('MarginalizedTimingModel is {0} times faster than TimingModel after {1} points.'.format(res, number)) return res def get_sample_point(self): x0 = np.hstack([p.sample() for p in self.pta_marg.params]) return x0 def __call__(self, x0): res_norm = self.pta_norm.get_lnlikelihood(x0) res_marg = self.pta_marg.get_lnlikelihood(x0) abs_err = np.abs(res_marg - res_norm) rel_err = abs_err / res_norm self.abs_err.append(abs_err) self.rel_err.append(rel_err) self.count += 1 if self.abs_tol is not None and abs_err > self.abs_tol: abs_raise = 'Absolute error is {0} at {1} which is larger than abs_tol of {2}.'.format( abs_err, x0, self.abs_tol) raise ValueError(abs_raise) elif self.rel_tol is not None and rel_err > self.rel_tol: rel_raise = 'Relative error is {0} at {1} which is larger than rel_tol of {2}.'.format( rel_err, x0, self.rel_tol) raise ValueError(rel_raise) return res_norm def results(self): print('Number of points evaluated:', self.count) print('Maximum absolute error:', np.max(self.abs_err)) print('Maximum relative error:', np.max(self.rel_err)) return self.abs_err, self.rel_err

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/empirical_distr.py

# -*- coding: utf-8 -*- import logging import pickle import numpy as np try: from sklearn.neighbors import KernelDensity sklearn_available=True except ModuleNotFoundError: sklearn_available=False from scipy.interpolate import interp1d, interp2d logger = logging.getLogger(__name__) class EmpiricalDistribution1D(object): """ Class used to define a 1D empirical distribution based on posterior from another MCMC. :param samples: samples for hist :param bins: edges to use for hist (left and right) make sure bins cover whole prior! """ def __init__(self, param_name, samples, bins): self.ndim = 1 self.param_name = param_name self._Nbins = len(bins)-1 hist, x_bins = np.histogram(samples, bins=bins) self._edges = x_bins self._wids = np.diff(x_bins) hist += 1 # add a sample to every bin counts = np.sum(hist) self._pdf = hist / float(counts) / self._wids self._cdf = np.cumsum((self._pdf*self._wids).ravel()) self._logpdf = np.log(self._pdf) def draw(self): draw = np.random.rand() draw_bin = np.searchsorted(self._cdf, draw, side='right') idx = np.unravel_index(draw_bin, self._Nbins)[0] samp = self._edges[idx] + self._wids[idx]*np.random.rand() return np.array(samp) def prob(self, params): ix = np.searchsorted(self._edges, params) - 1 return self._pdf[ix] def logprob(self, params): ix = np.searchsorted(self._edges, params) - 1 return self._logpdf[ix] class EmpiricalDistribution1DKDE(object): def __init__(self, param_name, samples, minval=None, maxval=None, bandwidth=0.1, nbins=40): """ Minvals and maxvals should specify priors for these. Should make these required. """ self.ndim = 1 self.param_name = param_name self.bandwidth = bandwidth # code below relies on samples axes being swapped. but we # want to keep inputs the same # create a 2D KDE from which to evaluate self.kde = KernelDensity(kernel='gaussian', bandwidth=bandwidth).fit(samples.reshape((samples.size, 1))) if minval is None: # msg = "minvals for KDE empirical distribution were not supplied. Resulting distribution may not have support over full prior" # logger.warning(msg) # widen these to add support minval = min(samples) maxval = max(samples) # significantly faster probability estimation using interpolation # instead of evaluating KDE every time self.minval = minval self.maxval = maxval xvals = np.linspace(minval, maxval, num=nbins) self._Nbins = nbins scores = np.array([self.kde.score(np.atleast_2d(xval)) for xval in xvals]) # interpolate within prior self._logpdf = interp1d(xvals, scores, kind='linear', fill_value=-1000) def draw(self): params = self.kde.sample(1).T return params.squeeze() # class used to define a 2D empirical distribution # based on posteriors from another MCMC class EmpiricalDistribution2D(object): """ Class used to define a 1D empirical distribution based on posterior from another MCMC. :param samples: samples for hist :param bins: edges to use for hist (left and right) make sure bins cover whole prior! """ def __init__(self, param_names, samples, bins): self.ndim = 2 self.param_names = param_names self._Nbins = [len(b)-1 for b in bins] hist, x_bins, y_bins = np.histogram2d(*samples, bins=bins) self._edges = np.array([x_bins, y_bins]) self._wids = np.diff([x_bins, y_bins]) area = np.outer(*self._wids) hist += 1 # add a sample to every bin counts = np.sum(hist) self._pdf = hist / counts / area self._cdf = np.cumsum((self._pdf*area).ravel()) self._logpdf = np.log(self._pdf) def draw(self): draw = np.random.rand() draw_bin = np.searchsorted(self._cdf, draw) idx = np.unravel_index(draw_bin, self._Nbins) samp = [self._edges[ii, idx[ii]] + self._wids[ii, idx[ii]]*np.random.rand() for ii in range(2)] return np.array(samp) def prob(self, params): ix, iy = [np.searchsorted(self._edges[ii], params[ii]) - 1 for ii in range(2)] return self._pdf[ix, iy] def logprob(self, params): ix, iy = [np.searchsorted(self._edges[ii], params[ii]) - 1 for ii in range(2)] return self._logpdf[ix, iy] class EmpiricalDistribution2DKDE(object): def __init__(self, param_names, samples, minvals=None, maxvals=None, bandwidth=0.1, nbins=40): """ Minvals and maxvals should specify priors for these. Should make these required. :param param_names: 2-element list of parameter names :param samples: samples, with dimension (2 x Nsamples) :return distr: list of empirical distributions """ self.ndim = 2 self.param_names = param_names self.bandwidth = bandwidth # code below relies on samples axes being swapped. but we # want to keep inputs the same # create a 2D KDE from which to evaluate self.kde = KernelDensity(kernel='gaussian', bandwidth=bandwidth).fit(samples.T) if minvals is None: msg = "minvals for KDE empirical distribution were not supplied. Resulting distribution may not have support over full prior" logger.warning(msg) # widen these to add support minvals = (min(samples[0, :]), min(samples[1, :])) maxvals = (max(samples[0, :]), max(samples[1, :])) # significantly faster probability estimation using interpolation # instead of evaluating KDE every time self.minvals = minvals self.maxvals = maxvals xvals = np.linspace(minvals[0], maxvals[0], num=nbins) yvals = np.linspace(minvals[1], maxvals[1], num=nbins) self._Nbins = [yvals.size for ii in range(xvals.size)] scores = np.array([self.kde.score(np.array([xvals[ii], yvals[jj]]).reshape((1, 2))) for ii in range(xvals.size) for jj in range(yvals.size)]) # interpolate within prior self._logpdf = interp2d(xvals, yvals, scores, kind='linear', fill_value=-1000) def draw(self): params = self.kde.sample(1).T return params.squeeze() def prob(self, params): # just in case...make sure to make this zero outside of our prior ranges param1_out = params[0] < self.minvals[0] or params[0] > self.maxvals[0] param2_out = params[1] < self.minvals[1] or params[1] > self.maxvals[1] if param1_out or param2_out: # essentially zero return -1000 else: return np.exp(self._logpdf(*params))[0] def logprob(self, params): return self._logpdf(*params)[0] def make_empirical_distributions(pta, paramlist, params, chain, burn=0, nbins=81, filename='distr.pkl', return_distribution=True, save_dists=True): """ Utility function to construct empirical distributions. :param pta: the pta object used to generate the posteriors :param paramlist: a list of parameter names, either single parameters or pairs of parameters :param chain: MCMC chain from a previous run :param burn: desired number of initial samples to discard :param nbins: number of bins to use for the empirical distributions :return distr: list of empirical distributions """ distr = [] if not save_dists and not return_distribution: msg = "no distribution returned or saved, are you sure??" logger.info(msg) for pl in paramlist: if type(pl) is not list: pl = [pl] if len(pl) == 1: idx = pta.param_names.index(pl[0]) prior_min = pta.params[idx].prior._defaults['pmin'] prior_max = pta.params[idx].prior._defaults['pmax'] # get the bins for the histogram bins = np.linspace(prior_min, prior_max, nbins) new_distr = EmpiricalDistribution1D(pl[0], chain[burn:, idx], bins) distr.append(new_distr) elif len(pl) == 2: # get the parameter indices idx = [pta.param_names.index(pl1) for pl1 in pl] # get the bins for the histogram bins = [np.linspace(pta.params[i].prior._defaults['pmin'], pta.params[i].prior._defaults['pmax'], nbins) for i in idx] new_distr = EmpiricalDistribution2D(pl, chain[burn:, idx].T, bins) distr.append(new_distr) else: msg = 'WARNING: only 1D and 2D empirical distributions are currently allowed.' logger.warning(msg) # save the list of empirical distributions as a pickle file if save_dists: if len(distr) > 0: with open(filename, 'wb') as f: pickle.dump(distr, f) msg = 'The empirical distributions have been pickled to {0}.'.format(filename) logger.info(msg) else: msg = 'WARNING: No empirical distributions were made!' logger.warning(msg) if return_distribution: return distr def make_empirical_distributions_KDE(pta, paramlist, params, chain, burn=0, nbins=41, filename='distr.pkl', bandwidth=0.1, return_distribution=True, save_dists=True): """ Utility function to construct empirical distributions. :param paramlist: a list of parameter names, either single parameters or pairs of parameters :param params: list of all parameter names for the MCMC chain :param chain: MCMC chain from a previous run, has dimensions Nsamples x Nparams :param burn: desired number of initial samples to discard :param nbins: number of bins to use for the empirical distributions :return distr: list of empirical distributions """ distr = [] if not save_dists and not return_distribution: msg = "no distribution returned or saved, are you sure??" logger.info(msg) for pl in paramlist: if type(pl) is not list: pl = [pl] if len(pl) == 1: # get the parameter index idx = pta.param_names.index(pl[0]) prior_min = pta.params[idx].prior._defaults['pmin'] prior_max = pta.params[idx].prior._defaults['pmax'] # get the bins for the histogram new_distr = EmpiricalDistribution1DKDE(pl[0], chain[burn:, idx], bandwidth=bandwidth, minval=prior_min, maxval=prior_max) distr.append(new_distr) elif len(pl) == 2: # get the parameter indices idx = [pta.param_names.index(pl1) for pl1 in pl] # get the bins for the histogram bins = [np.linspace(pta.params[i].prior._defaults['pmin'], pta.params[i].prior._defaults['pmax'], nbins) for i in idx] minvals = [pta.params[0].prior._defaults['pmin'], pta.params[1].prior._defaults['pmin']] maxvals = [pta.params[0].prior._defaults['pmax'], pta.params[1].prior._defaults['pmax']] # get the bins for the histogram if sklearn_available: new_distr = EmpiricalDistribution2DKDE(pl, chain[burn:, idx].T, bandwidth=bandwidth, minvals=minvals, maxvals=maxvals) else: logger.warn('`sklearn` package not available. Fall back to using histgrams for empirical distribution') new_distr = EmpiricalDistribution2D(pl, chain[burn:, idx].T, bins) distr.append(new_distr) else: msg = 'WARNING: only 1D and 2D empirical distributions are currently allowed.' logger.warning(msg) # save the list of empirical distributions as a pickle file if save_dists: if len(distr) > 0: with open(filename, 'wb') as f: pickle.dump(distr, f) msg = 'The empirical distributions have been pickled to {0}.'.format(filename) logger.info(msg) else: msg = 'WARNING: No empirical distributions were made!' logger.warning(msg) if return_distribution: return distr

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/sky_scrambles.py

# -*- coding: utf-8 -*- import pickle import sys import time import numpy as np from enterprise.signals import utils def compute_match(orf1, orf1_mag, orf2, orf2_mag): """Computes the match between two different ORFs.""" match = np.abs(np.dot(orf1, orf2))/(orf1_mag*orf2_mag) return match def make_true_orf(psrs): """Computes the ORF by looping over pulsar pairs""" npsr = len(psrs) orf = np.zeros(int(npsr*(npsr-1)/2)) idx = 0 for i in range(npsr): for j in range(i+1, npsr): orf[idx] = utils.hd_orf(psrs[i].pos, psrs[j].pos) idx += 1 return orf def compute_orf(ptheta, pphi): """ Computes the ORF coefficient. Takes different input than utils.hd_orf(). :param ptheta: Array of values of pulsar positions theta :param pphi: Array of values of pulsar positions phi :returns: orf: ORF for the given positions orf_mag: Magnitude of the ORF """ npsr = len(ptheta) pos = [np.array([np.cos(phi)*np.sin(theta), np.sin(phi)*np.sin(theta), np.cos(theta)]) for phi, theta in zip(pphi, ptheta)] x = [] for i in range(npsr): for j in range(i+1, npsr): x.append(np.dot(pos[i], pos[j])) x = np.array(x) orf = 1.5*(1./3. + (1.-x)/2.*(np.log((1.-x)/2.)-1./6.)) return orf, np.sqrt(np.dot(orf, orf)) def get_scrambles(psrs, N=500, Nmax=10000, thresh=0.1, filename='sky_scrambles.npz', resume=False): """ Get sky scramble ORFs and matches. :param psrs: List of pulsar objects :param N: Number of desired sky scrambles :param Nmax: Maximum number of tries to get independent scrambles :param thresh: Threshold value for match statistic. :param filename: Name of the file where the sky scrambles should be saved. Sky scrambles should be saved in `npz` file. :param resume: Whether to resume from an earlier run. """ # compute the unscrambled ORF orf_true = make_true_orf(psrs) orf_true_mag = np.sqrt(np.dot(orf_true, orf_true)) npsr = len(psrs) print('Generating {0} sky scrambles from {1} attempts with threshold {2}...'.format(N, Nmax, thresh)) orf_mags = [] if resume: print('Resuming from earlier run... loading sky scrambles from file {0}'.format(filename)) npzfile = np.load(filename) matches, orfs = npzfile['matches'], npzfile['orfs'] thetas, phis = npzfile['thetas'], npzfile['phis'] print('{0} sky scrambles have already been generated.'.format(len(matches))) for o in orfs: orf_mags.append(np.sqrt(np.dot(o, o))) else: matches, orfs, thetas, phis = [], [], [], [] ct = 0 tstart = time.time() while ct <= Nmax and len(matches) <= N: ptheta = np.arccos(np.random.uniform(-1, 1, npsr)) pphi = np.random.uniform(0, 2*np.pi, npsr) orf_s, orf_s_mag = compute_orf(ptheta, pphi) match = compute_match(orf_true, orf_true_mag, orf_s, orf_s_mag) if thresh == 1.0: if ct == 0: print('There is no threshold! Keep all the sky scrambles') if len(orfs) == 0: orfs.append(orf_s) matches.append(match) orfs = np.array(orfs) matches = np.array(matches) thetas = ptheta[np.newaxis, ...] phis = pphi[np.newaxis, ...] orf_mags.append(np.sqrt(np.dot(orf_s, orf_s))) else: matches = np.append(matches, match) orf_reshape = np.vstack(orf_s).T orfs = np.append(orfs, orf_reshape, axis=0) orf_mags.append(orf_s_mag) thetas = np.concatenate((thetas, [ptheta])) phis = np.concatenate((phis, [pphi])) elif thresh < 1.0 and match <= thresh: if len(orfs) == 0: orfs.append(orf_s) matches.append(match) orfs = np.array(orfs) matches = np.array(matches) thetas = ptheta[np.newaxis, ...] phis = pphi[np.newaxis, ...] orf_mags.append(np.sqrt(np.dot(orf_s, orf_s))) else: check = np.all(map(lambda x, y: compute_match(orf_s, orf_s_mag, x, y)<=thresh, orfs, orf_mags)) if check: matches = np.append(matches, match) orf_reshape = np.vstack(orf_s).T orfs = np.append(orfs, orf_reshape, axis=0) orf_mags.append(orf_s_mag) thetas = np.concatenate((thetas, [ptheta])) phis = np.concatenate((phis, [pphi])) ct += 1 if ct % 1000 == 0: sys.stdout.write('\r') sys.stdout.write('Finished %2.1f percent in %f min' % (float(ct)/N*100, (time.time() - tstart)/60.)) sys.stdout.flush() if len(matches) < N: print('\nGenerated {0} matches rather than the desired {1} matches'.format(len(matches), N)) else: print('\nGenerated the desired {0} matches in {1} attempts'.format(len(matches), ct)) print('Total runtime: {0:.1f} min'.format((time.time()-tstart)/60.)) np.savez(filename, matches=matches, orfs=orfs, thetas=thetas, phis=phis) return (matches, orfs, thetas, phis) if __name__ == '__main__': import argparse parser = argparse.ArgumentParser(description='') parser.add_argument('--picklefile', help='pickle file for the pulsars') parser.add_argument('--threshold', default=0.1, help='threshold for sky scrambles (DEFAULT 0.1)') parser.add_argument('--nscrambles', default=1000, help='number of sky scrambles to generate (DEFAULT 1000)') parser.add_argument('--nmax', default=1000, help='maximum number of attempts (DEFAULT 1000)') parser.add_argument('--savefile', default='../data/scrambles_nano.npz', help='outputfile name') parser.add_argument('--resume', action='store_true', help='resume from existing savefile?') args = parser.parse_args() with open(args.picklefile, 'rb') as f: psrs = pickle.load(f) get_scrambles(psrs, N=int(args.nscrambles), Nmax=int(args.nmax), thresh=float(args.threshold), filename=args.savefile, resume=args.resume)

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/timing.py

# -*- coding: utf-8 -*- from collections import OrderedDict import numpy as np from enterprise.signals import deterministic_signals, parameter, signal_base # timing model delay @signal_base.function def tm_delay(residuals, t2pulsar, tmparams_orig, tmparams, which='all'): """ Compute difference in residuals due to perturbed timing model. :param residuals: original pulsar residuals from Pulsar object :param t2pulsar: libstempo pulsar object :param tmparams_orig: dictionary of TM parameter tuples, (val, err) :param tmparams: new timing model parameters, rescaled to be in sigmas :param which: option to have all or only named TM parameters varied :return: difference between new and old residuals in seconds """ if which == 'all': keys = tmparams_orig.keys() else: keys = which # grab original timing model parameters and errors in dictionary orig_params = np.array([tmparams_orig[key] for key in keys]) # put varying parameters into dictionary tmparams_rescaled = np.atleast_1d(np.double(orig_params[:, 0] + tmparams * orig_params[:, 1])) tmparams_vary = OrderedDict(zip(keys, tmparams_rescaled)) # set to new values t2pulsar.vals(tmparams_vary) new_res = np.double(t2pulsar.residuals().copy()) # remember to set values back to originals t2pulsar.vals(OrderedDict(zip(keys, np.atleast_1d(np.double(orig_params[:, 0]))))) # Sort the residuals isort = np.argsort(t2pulsar.toas(), kind='mergesort') return residuals[isort] - new_res[isort] # Model component building blocks # def timing_block(tmparam_list=['RAJ', 'DECJ', 'F0', 'F1', 'PMRA', 'PMDEC', 'PX']): """ Returns the timing model block of the model :param tmparam_list: a list of parameters to vary in the model """ # default 5-sigma prior above and below the parfile mean tm_params = parameter.Uniform(-5.0, 5.0, size=len(tmparam_list)) # timing model tm_func = tm_delay(tmparams=tm_params, which=tmparam_list) tm = deterministic_signals.Deterministic(tm_func, name='timing model') return tm

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/dropout.py

# -*- coding: utf-8 -*- import enterprise import numpy as np from enterprise import constants as const from enterprise.signals import (deterministic_signals, parameter, signal_base, utils) @signal_base.function def dropout_powerlaw(f, name, log10_A=-16, gamma=5, dropout_psr='B1855+09', k_drop=0.5, k_threshold=0.5): """ Dropout powerlaw for a stochastic process. Switches a stochastic process on or off in a single pulsar depending on whether k_drop exceeds k_threshold. :param dropout_psr: Which pulsar to use a dropout switch on. The value 'all' will use the method on all pulsars. """ df = np.diff(np.concatenate((np.array([0]), f[::2]))) if name == 'all': if k_drop >= k_threshold: k_switch = 1.0 elif k_drop < k_threshold: k_switch = 0.0 return k_switch * ((10**log10_A)**2 / 12.0 / np.pi**2 * const.fyr**(gamma-3) * f**(-gamma) * np.repeat(df, 2)) elif name == dropout_psr: if k_drop >= k_threshold: k_switch = 1.0 elif k_drop < k_threshold: k_switch = 0.0 return k_switch * ((10**log10_A)**2 / 12.0 / np.pi**2 * const.fyr**(gamma-3) * f**(-gamma) * np.repeat(df, 2)) else: return ((10**log10_A)**2 / 12.0 / np.pi**2 * const.fyr**(gamma-3) * f**(-gamma) * np.repeat(df, 2)) @signal_base.function def dropout_physical_ephem_delay(toas, planetssb, pos_t, frame_drift_rate=0, d_jupiter_mass=0, d_saturn_mass=0, d_uranus_mass=0, d_neptune_mass=0, jup_orb_elements=np.zeros(6), sat_orb_elements=np.zeros(6), inc_jupiter_orb=False, jup_orbelxyz=None, jup_mjd=None, inc_saturn_orb=False, sat_orbelxyz=None, sat_mjd=None, equatorial=True, k_drop=0.5, k_threshold=0.5): """ Dropout BayesEphem model. Switches BayesEphem on or off depending on whether k_drop exceeds k_threshold. """ # get dropout switch if k_drop >= k_threshold: k_switch = 1.0 elif k_drop < k_threshold: k_switch = 0.0 # convert toas to MJD mjd = toas / 86400 # grab planet-to-SSB vectors earth = planetssb[:, 2, :3] jupiter = planetssb[:, 4, :3] saturn = planetssb[:, 5, :3] uranus = planetssb[:, 6, :3] neptune = planetssb[:, 7, :3] # do frame rotation earth = utils.ss_framerotate(mjd, earth, 0.0, 0.0, 0.0, frame_drift_rate, offset=None, equatorial=equatorial) # mass perturbations mpert = [(jupiter, d_jupiter_mass), (saturn, d_saturn_mass), (uranus, d_uranus_mass), (neptune, d_neptune_mass)] for planet, dm in mpert: earth += utils.dmass(planet, dm) # jupter orbital element perturbations if inc_jupiter_orb: jup_perturb_tmp = 0.0009547918983127075 * np.einsum( 'i,ijk->jk', jup_orb_elements, jup_orbelxyz) earth += np.array([np.interp(mjd, jup_mjd, jup_perturb_tmp[:, aa]) for aa in range(3)]).T # saturn orbital element perturbations if inc_saturn_orb: sat_perturb_tmp = 0.00028588567008942334 * np.einsum( 'i,ijk->jk', sat_orb_elements, sat_orbelxyz) earth += np.array([np.interp(mjd, sat_mjd, sat_perturb_tmp[:, aa]) for aa in range(3)]).T # construct the true geocenter to barycenter roemer tmp_roemer = np.einsum('ij,ij->i', planetssb[:, 2, :3], pos_t) # create the delay delay = tmp_roemer - np.einsum('ij,ij->i', earth, pos_t) return k_switch * delay def Dropout_PhysicalEphemerisSignal( frame_drift_rate=parameter.Uniform(-1e-9, 1e-9)('frame_drift_rate'), d_jupiter_mass=parameter.Normal(0, 1.54976690e-11)('d_jupiter_mass'), d_saturn_mass=parameter.Normal(0, 8.17306184e-12)('d_saturn_mass'), d_uranus_mass=parameter.Normal(0, 5.71923361e-11)('d_uranus_mass'), d_neptune_mass=parameter.Normal(0, 7.96103855e-11)('d_neptune_mass'), jup_orb_elements=parameter.Uniform(-0.05, 0.05, size=6)('jup_orb_elements'), sat_orb_elements=parameter.Uniform(-0.5, 0.5, size=6)('sat_orb_elements'), inc_jupiter_orb=True, inc_saturn_orb=False, use_epoch_toas=True, k_drop=parameter.Uniform(0.0, 1.0), k_threshold=0.5, name=''): """ Class factory for dropout physical ephemeris model signal.""" # turn off saturn orbital element parameters if not including in signal if not inc_saturn_orb: sat_orb_elements = np.zeros(6) # define waveform jup_mjd, jup_orbelxyz, sat_mjd, sat_orbelxyz = ( utils.get_planet_orbital_elements()) wf = dropout_physical_ephem_delay(frame_drift_rate=frame_drift_rate, d_jupiter_mass=d_jupiter_mass, d_saturn_mass=d_saturn_mass, d_uranus_mass=d_uranus_mass, d_neptune_mass=d_neptune_mass, jup_orb_elements=jup_orb_elements, sat_orb_elements=sat_orb_elements, inc_jupiter_orb=inc_jupiter_orb, jup_orbelxyz=jup_orbelxyz, jup_mjd=jup_mjd, inc_saturn_orb=inc_saturn_orb, sat_orbelxyz=sat_orbelxyz, sat_mjd=sat_mjd, k_drop=k_drop, k_threshold=k_threshold) BaseClass = deterministic_signals.Deterministic(wf, name=name) class Dropout_PhysicalEphemerisSignal(BaseClass): signal_name = 'phys_ephem' signal_id = 'phys_ephem_' + name if name else 'phys_ephem' def __init__(self, psr): # not available for PINT yet if isinstance(psr, enterprise.pulsar.PintPulsar): msg = 'Physical Ephemeris model is not compatible with PINT ' msg += 'at this time.' raise NotImplementedError(msg) super(Dropout_PhysicalEphemerisSignal, self).__init__(psr) if use_epoch_toas: # get quantization matrix and calculate daily average TOAs U, _ = utils.create_quantization_matrix(psr.toas, nmin=1) self.uinds = utils.quant2ind(U) avetoas = np.array([psr.toas[sc].mean() for sc in self.uinds]) self._wf[''].add_kwarg(toas=avetoas) # interpolate ssb planet position vectors to avetoas planetssb = np.zeros((len(avetoas), 9, 3)) for jj in range(9): planetssb[:, jj, :] = np.array([ np.interp(avetoas, psr.toas, psr.planetssb[:, jj, aa]) for aa in range(3)]).T self._wf[''].add_kwarg(planetssb=planetssb) # Inteprolating the pulsar position vectors onto epoch TOAs pos_t = np.array([np.interp(avetoas, psr.toas, psr.pos_t[:, aa]) for aa in range(3)]).T self._wf[''].add_kwarg(pos_t=pos_t) # initialize delay self._delay = np.zeros(len(psr.toas)) @signal_base.cache_call('delay_params') def get_delay(self, params): delay = self._wf[''](params=params) if use_epoch_toas: for slc, val in zip(self.uinds, delay): self._delay[slc] = val return self._delay else: return delay return Dropout_PhysicalEphemerisSignal

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/model_orfs.py

# -*- coding: utf-8 -*- import numpy as np import scipy.interpolate as interp from enterprise import constants as const from enterprise.signals import signal_base @signal_base.function def param_hd_orf(pos1, pos2, a=1.5, b=-0.25, c=0.5): ''' Pre-factor parametrized Hellings & Downs spatial correlation function. :param: a, b, c: coefficients of H&D-like curve [default=1.5,-0.25,0.5]. Reference: Taylor, Gair, Lentati (2013), https://arxiv.org/abs/1210.6014 Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1 else: omc2 = (1 - np.dot(pos1, pos2)) / 2 params = [a, b, c] return params[0] * omc2 * np.log(omc2) + params[1] * omc2 + params[2] @signal_base.function def spline_orf(pos1, pos2, params): ''' Agnostic spline-interpolated spatial correlation function. Spline knots are placed at edges, zeros, and minimum of H&D curve. Changing locations will require manual intervention to create new function. :param: params spline knot amplitudes. Reference: Taylor, Gair, Lentati (2013), https://arxiv.org/abs/1210.6014 Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1 else: # spline knots placed at edges, zeros, and minimum of H&D spl_knts = np.array([1e-3, 25.0, 49.3, 82.5, 121.8, 150.0, 180.0]) * np.pi/180.0 omc2_knts = (1 - np.cos(spl_knts)) / 2 finterp = interp.interp1d(omc2_knts, params, kind='cubic') omc2 = (1 - np.dot(pos1, pos2)) / 2 return finterp(omc2) @signal_base.function def bin_orf(pos1, pos2, params): ''' Agnostic binned spatial correlation function. Bin edges are placed at edges and across angular separation space. Changing bin edges will require manual intervention to create new function. :param: params inter-pulsar correlation bin amplitudes. Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1 else: # bins in angsep space bins = np.array([1e-3, 30.0, 50.0, 80.0, 100.0, 120.0, 150.0, 180.0]) * np.pi/180.0 angsep = np.arccos(np.dot(pos1, pos2)) idx = np.digitize(angsep, bins) return params[idx-1] @signal_base.function def zero_diag_bin_orf(pos1, pos2, params): ''' Agnostic binned spatial correlation function. To be used in a "split likelihood" model with an additional common uncorrelated red process. The latter is necessary to regularize the overall Phi covariance matrix. :param: params inter-pulsar correlation bin amplitudes. Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1e-20 else: # bins in angsep space bins = np.array([1e-3, 30.0, 50.0, 80.0, 100.0, 120.0, 150.0, 180.0]) * np.pi/180.0 angsep = np.arccos(np.dot(pos1, pos2)) idx = np.digitize(angsep, bins) return params[idx-1] @signal_base.function def zero_diag_hd(pos1, pos2): ''' Off-diagonal Hellings & Downs spatial correlation function. To be used in a "split likelihood" model with an additional common uncorrelated red process. The latter is necessary to regularize the overall Phi covariance matrix. Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1e-20 else: omc2 = (1 - np.dot(pos1, pos2)) / 2 return 1.5 * omc2 * np.log(omc2) - 0.25 * omc2 + 0.5 @signal_base.function def freq_hd(pos1, pos2, params): ''' Frequency-dependent Hellings & Downs spatial correlation function. Implemented as a model that only enforces H&D inter-pulsar correlations after a certain number of frequencies in the spectrum. The first set of frequencies are uncorrelated. :param: params params[0] is the number of components in the stochastic process. params[1] is the frequency at which to start the H&D inter-pulsar correlations (indexing from 0). Reference: Taylor et al. (2017), https://arxiv.org/abs/1606.09180 Author: S. R. Taylor (2020) ''' nfreq = params[0] orf_ifreq = params[1] if np.all(pos1 == pos2): return np.ones(2*nfreq) else: omc2 = (1 - np.dot(pos1, pos2)) / 2 hd_coeff = 1.5 * omc2 * np.log(omc2) - 0.25 * omc2 + 0.5 hd_coeff *= np.ones(2*nfreq) hd_coeff[:2*orf_ifreq] = 0.0 return hd_coeff @signal_base.function def legendre_orf(pos1, pos2, params): ''' Legendre polynomial spatial correlation function. Assumes process normalization such that autocorrelation signature is 1. A separate function is needed to use a "split likelihood" model with this Legendre process decoupled from the autocorrelation signature ("zero_diag_legendre_orf"). :param: params Legendre polynomial amplitudes describing the Legendre series approximation to the inter-pulsar correlation signature. H&D coefficients are a_0=0, a_1=0, a_2=0.3125, a_3=0.0875, ... Reference: Gair et al. (2014), https://arxiv.org/abs/1406.4664 Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1 else: costheta = np.dot(pos1, pos2) orf = np.polynomial.legendre.legval(costheta, params) return orf @signal_base.function def zero_diag_legendre_orf(pos1, pos2, params): ''' Legendre polynomial spatial correlation function. To be used in a "split likelihood" model with an additional common uncorrelated red process. The latter is necessary to regularize the overall Phi covariance matrix. :param: params Legendre polynomial amplitudes describing the Legendre series approximation to the inter-pulsar correlation signature. H&D coefficients are a_0=0, a_1=0, a_2=0.3125, a_3=0.0875, ... Reference: Gair et al. (2014), https://arxiv.org/abs/1406.4664 Author: S. R. Taylor (2020) ''' if np.all(pos1 == pos2): return 1e-20 else: costheta = np.dot(pos1, pos2) orf = np.polynomial.legendre.legval(costheta, params) return orf @signal_base.function def hd_orf(pos1, pos2): """Hellings & Downs spatial correlation function.""" if np.all(pos1 == pos2): return 1 else: omc2 = (1 - np.dot(pos1, pos2)) / 2 return 1.5 * omc2 * np.log(omc2) - 0.25 * omc2 + 0.5 @signal_base.function def dipole_orf(pos1, pos2): """Dipole spatial correlation function.""" if np.all(pos1 == pos2): return 1 + 1e-5 else: return np.dot(pos1, pos2) @signal_base.function def monopole_orf(pos1, pos2): """Monopole spatial correlation function.""" if np.all(pos1 == pos2): return 1.0 + 1e-5 else: return 1.0 @signal_base.function def anis_orf(pos1, pos2, params, **kwargs): """Anisotropic GWB spatial correlation function.""" anis_basis = kwargs["anis_basis"] psrs_pos = kwargs["psrs_pos"] lmax = kwargs["lmax"] psr1_index = [ii for ii in range(len(psrs_pos)) if np.all(psrs_pos[ii] == pos1)][0] psr2_index = [ii for ii in range(len(psrs_pos)) if np.all(psrs_pos[ii] == pos2)][0] clm = np.zeros((lmax + 1) ** 2) clm[0] = 2.0 * np.sqrt(np.pi) if lmax > 0: clm[1:] = params return sum(clm[ii] * basis for ii, basis in enumerate(anis_basis[: (lmax + 1) ** 2, psr1_index, psr2_index])) @signal_base.function def gw_monopole_orf(pos1, pos2): """ GW-monopole Correlations. This phenomenological correlation pattern can be used in Bayesian runs as the simplest type of correlations. Author: N. Laal (2020) """ if np.all(pos1 == pos2): return 1 else: return 1/2 @signal_base.function def gw_dipole_orf(pos1, pos2): """ GW-dipole Correlations. Author: N. Laal (2020) """ if np.all(pos1 == pos2): return 1 else: return 1/2*np.dot(pos1, pos2) @signal_base.function def st_orf(pos1, pos2): """ Scalar tensor correlations as induced by the breathing polarization mode of gravity. Author: N. Laal (2020) """ if np.all(pos1 == pos2): return 1 else: return 1/8 * (3.0 + np.dot(pos1, pos2)) @signal_base.function def gt_orf(pos1, pos2, tau): """ General Transverse (GT) Correlations. This ORF is used to detect the relative significance of all possible correlation patterns induced by the most general family of transverse gravitational waves. :param: tau tau = 1 results in ST correlations while tau = -1 results in HD correlations. Author: N. Laal (2020) """ if np.all(pos1 == pos2): return 1 else: k = 1/2*(1-np.dot(pos1, pos2)) return 1/8 * (3+np.dot(pos1, pos2)) + (1-tau)*3/4*k*np.log(k) @signal_base.function def generalized_gwpol_psd(f, log10_A_tt=-15, log10_A_st=-15, alpha_tt=-2/3, alpha_alt=-1, log10_A_vl=-15, log10_A_sl=-15, kappa=0, p_dist=1.0): ''' General powerlaw spectrum allowing for existence of all possible modes of gravity as predicted by a general metric spacetime theory and generated by a binary system. The SL and VL modes' powerlaw relations are not normalized. :param: f A list of considered frequencies :param: log10_A_tt Amplitude of the tensor transverse mode :param: log10_A_st Amplitude of the scalar transverse mode :param: log10_A_vl Amplitude of the vector longitudinal mode :param: log10_A_sl Amplitude of the scalar longitudinal mode :param: kappa Relative amplitude of dipole radiation over quadrupolar radiation :param: p_dist Pulsar distance in kpc :param: alpha_tt spectral index of the TT mode. :param: alpha_alt spectral index of the non-Einsteinian modes. Reference: Cornish et al. (2017), https://arxiv.org/abs/1712.07132 Author: S. R. Taylor, N. Laal (2020) ''' df = np.diff(np.concatenate((np.array([0]), f[::2]))) euler_e = 0.5772156649 pdist = p_dist * const.kpc / const.c orf_aa_tt = (2/3) * np.ones(len(f)) orf_aa_st = (2/3) * np.ones(len(f)) orf_aa_vl = 2*np.log(4*np.pi*f*pdist) - 14/3 + 2*euler_e orf_aa_sl = np.pi**2*f*pdist/4 - \ np.log(4*np.pi*f*pdist) + 37/24 - euler_e prefactor = (1 + kappa**2) / (1 + kappa**2 * (f / const.fyr)**(-2/3)) gwpol_amps = 10**(2*np.array([log10_A_tt, log10_A_st, log10_A_vl, log10_A_sl])) gwpol_factors = np.array([orf_aa_tt*gwpol_amps[0], orf_aa_st*gwpol_amps[1], orf_aa_vl*gwpol_amps[2], orf_aa_sl*gwpol_amps[3]]) S_psd = prefactor * (gwpol_factors[0, :] * (f / const.fyr)**(2 * alpha_tt) + np.sum(gwpol_factors[1:, :], axis=0) * (f / const.fyr)**(2 * alpha_alt)) / \ (8*np.pi**2*f**3) return S_psd * np.repeat(df, 2)

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/models.py

# -*- coding: utf-8 -*- import functools from collections import OrderedDict import numpy as np from enterprise import constants as const from enterprise.signals import (deterministic_signals, gp_signals, parameter, selections, signal_base, white_signals) from enterprise.signals.signal_base import LogLikelihood from enterprise_extensions import chromatic as chrom from enterprise_extensions import deterministic from enterprise_extensions import dropout as do from enterprise_extensions import model_utils from enterprise_extensions.blocks import (bwm_block, bwm_sglpsr_block, chromatic_noise_block, common_red_noise_block, dm_noise_block, red_noise_block, white_noise_block) from enterprise_extensions.chromatic.solar_wind import solar_wind_block from enterprise_extensions.timing import timing_block # from enterprise.signals.signal_base import LookupLikelihood def model_singlepsr_noise(psr, tm_var=False, tm_linear=False, tmparam_list=None, red_var=True, psd='powerlaw', red_select=None, noisedict=None, tm_svd=False, tm_norm=True, white_vary=True, components=30, upper_limit=False, is_wideband=False, use_dmdata=False, tnequad=False, dmjump_var=False, gamma_val=None, dm_var=False, dm_type='gp', dmgp_kernel='diag', dm_psd='powerlaw', dm_nondiag_kernel='periodic', dmx_data=None, dm_annual=False, gamma_dm_val=None, dm_dt=15, dm_df=200, chrom_gp=False, chrom_gp_kernel='nondiag', chrom_psd='powerlaw', chrom_idx=4, chrom_quad=False, chrom_kernel='periodic', chrom_dt=15, chrom_df=200, dm_expdip=False, dmexp_sign='negative', dm_expdip_idx=2, dm_expdip_tmin=None, dm_expdip_tmax=None, num_dmdips=1, dmdip_seqname=None, dm_cusp=False, dm_cusp_sign='negative', dm_cusp_idx=2, dm_cusp_sym=False, dm_cusp_tmin=None, dm_cusp_tmax=None, num_dm_cusps=1, dm_cusp_seqname=None, dm_dual_cusp=False, dm_dual_cusp_tmin=None, dm_dual_cusp_tmax=None, dm_dual_cusp_sym=False, dm_dual_cusp_idx1=2, dm_dual_cusp_idx2=4, dm_dual_cusp_sign='negative', num_dm_dual_cusps=1, dm_dual_cusp_seqname=None, dm_sw_deter=False, dm_sw_gp=False, swgp_prior=None, swgp_basis=None, coefficients=False, extra_sigs=None, psr_model=False, factorized_like=False, Tspan=None, fact_like_gamma=13./3, gw_components=10, fact_like_logmin=None, fact_like_logmax=None, select='backend', tm_marg=False, dense_like=False, ng_twg_setup=False, wb_efac_sigma=0.25): """ Single pulsar noise model. :param psr: enterprise pulsar object :param tm_var: explicitly vary the timing model parameters :param tm_linear: vary the timing model in the linear approximation :param tmparam_list: an explicit list of timing model parameters to vary :param red_var: include red noise in the model :param psd: red noise psd model :param noisedict: dictionary of noise parameters :param tm_svd: boolean for svd-stabilised timing model design matrix :param tm_norm: normalize the timing model, or provide custom normalization :param white_vary: boolean for varying white noise or keeping fixed :param components: number of modes in Fourier domain processes :param dm_components: number of modes in Fourier domain DM processes :param upper_limit: whether to do an upper-limit analysis :param is_wideband: whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband :param gamma_val: red noise spectral index to fix :param dm_var: whether to explicitly model DM-variations :param dm_type: gaussian process ('gp') or dmx ('dmx') :param dmgp_kernel: diagonal in frequency or non-diagonal :param dm_psd: power-spectral density of DM variations :param dm_nondiag_kernel: type of time-domain DM GP kernel :param dmx_data: supply the DMX data from par files :param dm_annual: include an annual DM signal :param gamma_dm_val: spectral index of power-law DM variations :param dm_dt: time-scale for DM linear interpolation basis (days) :param dm_df: frequency-scale for DM linear interpolation basis (MHz) :param chrom_gp: include general chromatic noise :param chrom_gp_kernel: GP kernel type to use in chrom ['diag','nondiag'] :param chrom_psd: power-spectral density of chromatic noise ['powerlaw','tprocess','free_spectrum'] :param chrom_idx: frequency scaling of chromatic noise :param chrom_kernel: Type of 'nondiag' time-domain chrom GP kernel to use ['periodic', 'sq_exp','periodic_rfband', 'sq_exp_rfband'] :param chrom_quad: Whether to add a quadratic chromatic term. Boolean :param chrom_dt: time-scale for chromatic linear interpolation basis (days) :param chrom_df: frequency-scale for chromatic linear interpolation basis (MHz) :param dm_expdip: inclue a DM exponential dip :param dmexp_sign: set the sign parameter for dip :param dm_expdip_idx: chromatic index of exponential dip :param dm_expdip_tmin: sampling minimum of DM dip epoch :param dm_expdip_tmax: sampling maximum of DM dip epoch :param num_dmdips: number of dm exponential dips :param dmdip_seqname: name of dip sequence :param dm_cusp: include a DM exponential cusp :param dm_cusp_sign: set the sign parameter for cusp :param dm_cusp_idx: chromatic index of exponential cusp :param dm_cusp_tmin: sampling minimum of DM cusp epoch :param dm_cusp_tmax: sampling maximum of DM cusp epoch :param dm_cusp_sym: make exponential cusp symmetric :param num_dm_cusps: number of dm exponential cusps :param dm_cusp_seqname: name of cusp sequence :param dm_dual_cusp: include a DM cusp with two chromatic indices :param dm_dual_cusp_tmin: sampling minimum of DM dual cusp epoch :param dm_dual_cusp_tmax: sampling maximum of DM dual cusp epoch :param dm_dual_cusp_idx1: first chromatic index of DM dual cusp :param dm_dual_cusp_idx2: second chromatic index of DM dual cusp :param dm_dual_cusp_sym: make dual cusp symmetric :param dm_dual_cusp_sign: set the sign parameter for dual cusp :param num_dm_dual_cusps: number of DM dual cusps :param dm_dual_cusp_seqname: name of dual cusp sequence :param dm_scattering: whether to explicitly model DM scattering variations :param dm_sw_deter: use the deterministic solar wind model :param dm_sw_gp: add a Gaussian process perturbation to the deterministic solar wind model. :param swgp_prior: prior is currently set automatically :param swgp_basis: ['powerlaw', 'periodic', 'sq_exp'] :param coefficients: explicitly include latent coefficients in model :param psr_model: Return the enterprise model instantiated on the pulsar rather than an instantiated PTA object, i.e. model(psr) rather than PTA(model(psr)). :param factorized_like: Whether to run a factorized likelihood analyis Boolean :param gw_components: number of modes in Fourier domain for a common process in a factorized likelihood calculation. :param fact_like_gamma: fixed common process spectral index :param fact_like_logmin: specify lower prior for common psd. This is a prior on log10_rho if common_psd is 'spectrum', else it is a prior on log10 amplitude :param fact_like_logmax: specify upper prior for common psd. This is a prior on log10_rho if common_psd is 'spectrum', else it is a prior on log10 amplitude :param Tspan: time baseline used to determine Fourier GP frequencies :param extra_sigs: Any additional `enterprise` signals to be added to the model. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :return s: single pulsar noise model """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # timing model if not tm_var: if (is_wideband and use_dmdata): if dmjump_var: dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmjump = parameter.Constant() if white_vary: if ng_twg_setup: dmefac = parameter.Normal(1.0, wb_efac_sigma) else: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection( selections.by_backend), dmjump_selection=selections.Selection( selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd, normed=tm_norm, coefficients=coefficients) else: # create new attribute for enterprise pulsar object psr.tmparams_orig = OrderedDict.fromkeys(psr.t2pulsar.pars()) for key in psr.tmparams_orig: psr.tmparams_orig[key] = (psr.t2pulsar[key].val, psr.t2pulsar[key].err) if not tm_linear: s = timing_block(tmparam_list=tmparam_list) else: pass # red noise and common process if factorized_like: if Tspan is None: msg = 'Must Timespan to match amongst all pulsars when doing ' msg += 'a factorized likelihood analysis.' raise ValueError(msg) s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=gw_components, gamma_val=fact_like_gamma, delta_val=None, orf=None, name='gw', coefficients=coefficients, pshift=False, pseed=None, logmin=fact_like_logmin, logmax=fact_like_logmax) if red_var: s += red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_val, coefficients=coefficients, select=red_select) # DM variations if dm_var: if dm_type == 'gp': if dmgp_kernel == 'diag': s += dm_noise_block(gp_kernel=dmgp_kernel, psd=dm_psd, prior=amp_prior, components=components, gamma_val=gamma_dm_val, coefficients=coefficients) elif dmgp_kernel == 'nondiag': s += dm_noise_block(gp_kernel=dmgp_kernel, nondiag_kernel=dm_nondiag_kernel, dt=dm_dt, df=dm_df, coefficients=coefficients) elif dm_type == 'dmx': s += chrom.dmx_signal(dmx_data=dmx_data[psr.name]) if dm_annual: s += chrom.dm_annual_signal() if chrom_gp: s += chromatic_noise_block(gp_kernel=chrom_gp_kernel, psd=chrom_psd, idx=chrom_idx, components=components, nondiag_kernel=chrom_kernel, dt=chrom_dt, df=chrom_df, include_quadratic=chrom_quad, coefficients=coefficients) if dm_expdip: if dm_expdip_tmin is None and dm_expdip_tmax is None: tmin = [psr.toas.min() / const.day for ii in range(num_dmdips)] tmax = [psr.toas.max() / const.day for ii in range(num_dmdips)] else: tmin = (dm_expdip_tmin if isinstance(dm_expdip_tmin, list) else [dm_expdip_tmin]) tmax = (dm_expdip_tmax if isinstance(dm_expdip_tmax, list) else [dm_expdip_tmax]) if dmdip_seqname is not None: dmdipname_base = (['dmexp_' + nm for nm in dmdip_seqname] if isinstance(dmdip_seqname, list) else ['dmexp_' + dmdip_seqname]) else: dmdipname_base = ['dmexp_{0}'.format(ii+1) for ii in range(num_dmdips)] dm_expdip_idx = (dm_expdip_idx if isinstance(dm_expdip_idx, list) else [dm_expdip_idx]) for dd in range(num_dmdips): s += chrom.dm_exponential_dip(tmin=tmin[dd], tmax=tmax[dd], idx=dm_expdip_idx[dd], sign=dmexp_sign, name=dmdipname_base[dd]) if dm_cusp: if dm_cusp_tmin is None and dm_cusp_tmax is None: tmin = [psr.toas.min() / const.day for ii in range(num_dm_cusps)] tmax = [psr.toas.max() / const.day for ii in range(num_dm_cusps)] else: tmin = (dm_cusp_tmin if isinstance(dm_cusp_tmin, list) else [dm_cusp_tmin]) tmax = (dm_cusp_tmax if isinstance(dm_cusp_tmax, list) else [dm_cusp_tmax]) if dm_cusp_seqname is not None: cusp_name_base = 'dm_cusp_'+dm_cusp_seqname+'_' else: cusp_name_base = 'dm_cusp_' dm_cusp_idx = (dm_cusp_idx if isinstance(dm_cusp_idx, list) else [dm_cusp_idx]) dm_cusp_sign = (dm_cusp_sign if isinstance(dm_cusp_sign, list) else [dm_cusp_sign]) for dd in range(1, num_dm_cusps+1): s += chrom.dm_exponential_cusp(tmin=tmin[dd-1], tmax=tmax[dd-1], idx=dm_cusp_idx[dd-1], sign=dm_cusp_sign[dd-1], symmetric=dm_cusp_sym, name=cusp_name_base+str(dd)) if dm_dual_cusp: if dm_dual_cusp_tmin is None and dm_cusp_tmax is None: tmin = psr.toas.min() / const.day tmax = psr.toas.max() / const.day else: tmin = dm_dual_cusp_tmin tmax = dm_dual_cusp_tmax if dm_dual_cusp_seqname is not None: dual_cusp_name_base = 'dm_dual_cusp_'+dm_cusp_seqname+'_' else: dual_cusp_name_base = 'dm_dual_cusp_' for dd in range(1, num_dm_dual_cusps+1): s += chrom.dm_dual_exp_cusp(tmin=tmin, tmax=tmax, idx1=dm_dual_cusp_idx1, idx2=dm_dual_cusp_idx2, sign=dm_dual_cusp_sign, symmetric=dm_dual_cusp_sym, name=dual_cusp_name_base+str(dd)) if dm_sw_deter: Tspan = psr.toas.max() - psr.toas.min() s += solar_wind_block(ACE_prior=True, include_swgp=dm_sw_gp, swgp_prior=swgp_prior, swgp_basis=swgp_basis, Tspan=Tspan) if extra_sigs is not None: s += extra_sigs # adding white-noise, and acting on psr objects if ('NANOGrav' in psr.flags['pta'] or 'CHIME' in psr.flags['f']) and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) model = s2(psr) if psr_model: Model = s2 else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select, ng_twg_setup=ng_twg_setup, wb_efac_sigma=wb_efac_sigma) model = s3(psr) if psr_model: Model = s3 if psr_model: return Model else: # set up PTA if dense_like: pta = signal_base.PTA([model], lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA([model]) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_1(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, upper_limit=False, bayesephem=False, tnequad=False, be_type='orbel', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with only white and red noise: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. Optional physical ephemeris modeling. :param psd: Choice of PSD function [e.g. powerlaw (default), turnover, tprocess] :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2a(psrs, psd='powerlaw', noisedict=None, components=30, n_rnfreqs=None, n_gwbfreqs=None, gamma_common=None, delta_common=None, upper_limit=False, bayesephem=False, be_type='setIII', white_vary=False, is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tnequad=False, pshift=False, pseed=None, psr_models=False, tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2A from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1.Common red noise modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param psr_models: Return list of psr models rather than signal_base.PTA object. :param n_rnfreqs: Number of frequencies to use in achromatic rednoise model. :param n_gwbfreqs: Number of frequencies to use in the GWB model. :param pshift: Option to use a random phase shift in design matrix. For testing the null hypothesis. :param pseed: Option to provide a seed for the random phase shift. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) if n_gwbfreqs is None: n_gwbfreqs = components if n_rnfreqs is None: n_rnfreqs = components # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=n_rnfreqs) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=n_gwbfreqs, gamma_val=gamma_common, delta_val=delta_common, name='gw', pshift=pshift, pseed=pseed) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) if psr_models: return models else: # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_general(psrs, tm_var=False, tm_linear=False, tmparam_list=None, tm_svd=False, tm_norm=True, noisedict=None, white_vary=False, Tspan=None, modes=None, wgts=None, logfreq=False, nmodes_log=10, common_psd='powerlaw', common_components=30, tnequad=False, log10_A_common=None, gamma_common=None, common_logmin=None, common_logmax=None, orf='crn', orf_names=None, orf_ifreq=0, leg_lmax=5, upper_limit_common=None, upper_limit=False, red_var=True, red_psd='powerlaw', red_components=30, upper_limit_red=None, red_select=None, red_breakflat=False, red_breakflat_fq=None, bayesephem=False, be_type='setIII_1980', is_wideband=False, use_dmdata=False, dm_var=False, dm_type='gp', dm_psd='powerlaw', dm_components=30, upper_limit_dm=None, dm_annual=False, dm_chrom=False, dmchrom_psd='powerlaw', dmchrom_idx=4, gequad=False, coefficients=False, pshift=False, select='backend', tm_marg=False, dense_like=False, delta_common=None): """ Reads in list of enterprise Pulsar instances and returns a PTA object instantiated with user-supplied options. :param tm_var: boolean to vary timing model coefficients. [default = False] :param tm_linear: boolean to vary timing model under linear approximation. [default = False] :param tmparam_list: list of timing model parameters to vary. [default = None] :param tm_svd: stabilize timing model designmatrix with SVD. [default = False] :param tm_norm: normalize the timing model design matrix, or provide custom normalization. Alternative to 'tm_svd'. [default = True] :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. [default = None] :param white_vary: boolean for varying white noise or keeping fixed. [default = False] :param Tspan: timespan assumed for describing stochastic processes, in units of seconds. If None provided will find span of pulsars. [default = None] :param modes: list of frequencies on which to describe red processes. [default = None] :param wgts: sqrt summation weights for each frequency bin, i.e. sqrt(delta f). [default = None] :param logfreq: boolean for including log-spaced bins. [default = False] :param nmodes_log: number of log-spaced bins below 1/T. [default = 10] :param common_psd: psd of common process. ['powerlaw', 'spectrum', 'turnover', 'turnover_knee,', 'broken_powerlaw'] [default = 'powerlaw'] :param common_components: number of frequencies starting at 1/T for common process. [default = 30] :param log10_A_common: value of fixed log10_A_common parameter for fixed amplitude analyses. [default = None] :param gamma_common: fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. [default = None] :param common_logmin: specify lower prior for common psd. This is a prior on log10_rho if common_psd is 'spectrum', else it is a prior on log amplitude :param common_logmax: specify upper prior for common psd. This is a prior on log10_rho if common_psd is 'spectrum', else it is a prior on log amplitude :param orf: comma de-limited string of multiple common processes with different orfs. [default = crn] :param orf_names: comma de-limited string of process names for different orfs. Manual control of these names is useful for embedding model_general within a hypermodel analysis for a process with and without hd correlations where we want to avoid parameter duplication. [default = None] :param orf_ifreq: Frequency bin at which to start the Hellings & Downs function with numbering beginning at 0. Currently only works with freq_hd orf. [default = 0] :param leg_lmax: Maximum multipole of a Legendre polynomial series representation of the overlap reduction function. [default = 5] :param upper_limit_common: perform upper limit on common red noise amplitude. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. [default = False] :param upper_limit: apply upper limit priors to all red processes. [default = False] :param red_var: boolean to switch on/off intrinsic red noise. [default = True] :param red_psd: psd of intrinsic red process. ['powerlaw', 'spectrum', 'turnover', 'tprocess', 'tprocess_adapt'] [default = 'powerlaw'] :param red_components: number of frequencies starting at 1/T for intrinsic red process. [default = 30] :param upper_limit_red: perform upper limit on intrinsic red noise amplitude. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. [default = False] :param red_select: selection properties for intrinsic red noise. ['backend', 'band', 'band+', None] [default = None] :param red_breakflat: break red noise spectrum and make flat above certain frequency. [default = False] :param red_breakflat_fq: break frequency for 'red_breakflat'. [default = None] :param bayesephem: boolean to include BayesEphem model. [default = False] :param be_type: flavor of bayesephem model based on how partials are computed. ['orbel', 'orbel-v2', 'setIII', 'setIII_1980'] [default = 'setIII_1980'] :param is_wideband: boolean for whether input TOAs are wideband TOAs. Will exclude ecorr from the white noise model. [default = False] :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. [default = False] :param dm_var: boolean for explicitly searching for DM variations. [default = False] :param dm_type: type of DM variations. ['gp', other choices selected with additional options; see below] [default = 'gp'] :param dm_psd: psd of DM GP. ['powerlaw', 'spectrum', 'turnover', 'tprocess', 'tprocess_adapt'] [default = 'powerlaw'] :param dm_components: number of frequencies starting at 1/T for DM GP. [default = 30] :param upper_limit_dm: perform upper limit on DM GP. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. [default = False] :param dm_annual: boolean to search for an annual DM trend. [default = False] :param dm_chrom: boolean to search for a generic chromatic GP. [default = False] :param dmchrom_psd: psd of generic chromatic GP. ['powerlaw', 'spectrum', 'turnover'] [default = 'powerlaw'] :param dmchrom_idx: spectral index of generic chromatic GP. [default = 4] :param gequad: boolean to search for a global EQUAD. [default = False] :param coefficients: boolean to form full hierarchical PTA object; (no analytic latent-coefficient marginalization) [default = False] :param pshift: boolean to add random phase shift to red noise Fourier design matrices for false alarm rate studies. [default = False] :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood Default PTA object composition: 1. fixed EFAC per backend/receiver system (per pulsar) 2. fixed EQUAD per backend/receiver system (per pulsar) 3. fixed ECORR per backend/receiver system (per pulsar) 4. Red noise modeled as a power-law with 30 sampling frequencies (per pulsar) 5. Linear timing model (per pulsar) 6. Common-spectrum uncorrelated process modeled as a power-law with 30 sampling frequencies. (global) """ amp_prior = 'uniform' if upper_limit else 'log-uniform' gp_priors = [upper_limit_red, upper_limit_dm, upper_limit_common] if all(ii is None for ii in gp_priors): amp_prior_red = amp_prior amp_prior_dm = amp_prior amp_prior_common = amp_prior else: amp_prior_red = 'uniform' if upper_limit_red else 'log-uniform' amp_prior_dm = 'uniform' if upper_limit_dm else 'log-uniform' amp_prior_common = 'uniform' if upper_limit_common else 'log-uniform' # timing model if not tm_var and not use_dmdata: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd, normed=tm_norm, coefficients=coefficients) elif not tm_var and use_dmdata: dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: # create new attribute for enterprise pulsar object for p in psrs: p.tmparams_orig = OrderedDict.fromkeys(p.t2pulsar.pars()) for key in p.tmparams_orig: p.tmparams_orig[key] = (p.t2pulsar[key].val, p.t2pulsar[key].err) if not tm_linear: s = timing_block(tmparam_list=tmparam_list) else: pass # find the maximum time span to set GW frequency sampling if Tspan is not None: Tspan = Tspan else: Tspan = model_utils.get_tspan(psrs) if logfreq: fmin = 10.0 modes, wgts = model_utils.linBinning(Tspan, nmodes_log, 1.0 / fmin / Tspan, common_components, nmodes_log) wgts = wgts**2.0 # red noise if red_var: s += red_noise_block(psd=red_psd, prior=amp_prior_red, Tspan=Tspan, components=red_components, modes=modes, wgts=wgts, coefficients=coefficients, select=red_select, break_flat=red_breakflat, break_flat_fq=red_breakflat_fq) # common red noise block crn = [] if orf_names is None: orf_names = orf for elem, elem_name in zip(orf.split(','), orf_names.split(',')): if elem == 'zero_diag_bin_orf' or elem == 'zero_diag_legendre_orf': log10_A_val = log10_A_common else: log10_A_val = None crn.append(common_red_noise_block(psd=common_psd, prior=amp_prior_common, Tspan=Tspan, components=common_components, log10_A_val=log10_A_val, gamma_val=gamma_common, delta_val=None, orf=elem, name='gw_{}'.format(elem_name), orf_ifreq=orf_ifreq, leg_lmax=leg_lmax, coefficients=coefficients, pshift=pshift, pseed=None, logmin=common_logmin, logmax=common_logmax)) # orf_ifreq only affects freq_hd model. # leg_lmax only affects (zero_diag_)legendre_orf model. crn = functools.reduce((lambda x, y: x+y), crn) s += crn # DM variations if dm_var: if dm_type == 'gp': s += dm_noise_block(gp_kernel='diag', psd=dm_psd, prior=amp_prior_dm, components=dm_components, gamma_val=None, coefficients=coefficients) if dm_annual: s += chrom.dm_annual_signal() if dm_chrom: s += chromatic_noise_block(psd=dmchrom_psd, idx=dmchrom_idx, name='chromatic', components=dm_components, coefficients=coefficients) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) if gequad: s2 += white_signals.EquadNoise(log10_equad=parameter.Uniform(-8.5, -5), selection=selections.Selection(selections.no_selection), name='gequad') if '1713' in p.name and dm_var: tmin = p.toas.min() / const.day tmax = p.toas.max() / const.day s3 = s2 + chrom.dm_exponential_dip(tmin=tmin, tmax=tmax, idx=2, sign=False, name='dmexp') models.append(s3(p)) else: models.append(s2(p)) else: s4 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) if gequad: s4 += white_signals.TNEquadNoise(log10_tnequad=parameter.Uniform(-8.5, -5), selection=selections.Selection(selections.no_selection), name='gequad') if '1713' in p.name and dm_var: tmin = p.toas.min() / const.day tmax = p.toas.max() / const.day s5 = s4 + chrom.dm_exponential_dip(tmin=tmin, tmax=tmax, idx=2, sign=False, name='dmexp') models.append(s5(p)) else: models.append(s4(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2b(psrs, psd='powerlaw', noisedict=None, white_vary=False, bayesephem=False, be_type='orbel', is_wideband=False, components=30, use_dmdata=False, Tspan=None, select='backend', pshift=False, tnequad=False, tm_marg=False, dense_like=False, tm_svd=False, upper_limit=False, gamma_common=None): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2B from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. Dipole spatially correlated signal modeled with PSD. Default PSD is powerlaw. Available options ['powerlaw', 'turnover', 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # dipole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='dipole', name='dipole', pshift=pshift) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2c(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, tnequad=False, bayesephem=False, be_type='orbel', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2C from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. Dipole spatially correlated signal modeled with PSD. Default PSD is powerlaw. Available options ['powerlaw', 'turnover', 'spectrum'] 2. Monopole spatially correlated signal modeled with PSD. Default PSD is powerlaw. Available options ['powerlaw', 'turnover', 'spectrum'] 3. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # dipole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='dipole', name='dipole') # monopole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='monopole', name='monopole') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2d(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, n_rnfreqs=None, n_gwbfreqs=None, gamma_common=None, upper_limit=False, tnequad=False, bayesephem=False, be_type='orbel', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', pshift=False, tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2D from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. Monopole spatially correlated signal modeled with PSD. Default PSD is powerlaw. Available options ['powerlaw', 'turnover', 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) if n_gwbfreqs is None: n_gwbfreqs = components if n_rnfreqs is None: n_rnfreqs = components # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=n_rnfreqs) # monopole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=n_gwbfreqs, gamma_val=gamma_common, orf='monopole', name='monopole', pshift=pshift) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_3a(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, n_rnfreqs=None, n_gwbfreqs=None, gamma_common=None, delta_common=None, upper_limit=False, bayesephem=False, be_type='setIII', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tnequad=False, pshift=False, pseed=None, psr_models=False, tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 3A from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. GWB with HD correlations modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum'] 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param delta_common: Fixed common red process spectral index value for higher frequencies in broken power law model. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param pshift: Option to use a random phase shift in design matrix. For testing the null hypothesis. :param pseed: Option to provide a seed for the random phase shift. :param psr_models: Return list of psr models rather than signal_base.PTA object. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) if n_gwbfreqs is None: n_gwbfreqs = components if n_rnfreqs is None: n_rnfreqs = components # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(psd='powerlaw', prior=amp_prior, Tspan=Tspan, components=n_rnfreqs) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=n_gwbfreqs, gamma_val=gamma_common, delta_val=delta_common, orf='hd', name='gw', pshift=pshift, pseed=pseed) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) if psr_models: return models else: # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_3b(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, tnequad=False, bayesephem=False, be_type='setIII', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 3B from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. GWB with HD correlations modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Dipole signal modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 3. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum'] 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='hd', name='gw') # dipole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='dipole', name='dipole') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_3c(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, tnequad=False, bayesephem=False, be_type='orbel', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 3C from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. GWB with HD correlations modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Dipole signal modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 3. Monopole signal modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 4. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum'] 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if is_wideband and use_dmdata: dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='hd', name='gw') # dipole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='dipole', name='dipole') # monopole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='monopole', name='monopole') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_3d(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, tnequad=False, bayesephem=False, be_type='orbel', is_wideband=False, use_dmdata=False, Tspan=None, select='backend', tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 3D from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. GWB with HD correlations modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Monopole signal modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 3. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum'] 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param be_type: orbel, orbel-v2, setIII :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param Tspan: time baseline used to determine Fourier GP frequencies; derived from data if not specified :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling if Tspan is None: Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='hd', name='gw') # monopole s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, orf='monopole', name='monopole') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True, model=be_type) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad, select=select) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad, select=select) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2a_drop_be(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, is_wideband=False, use_dmdata=False, k_threshold=0.5, pshift=False, tm_marg=False, dense_like=False, tm_svd=False, tnequad=False,): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2A from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1.Common red noise modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param k_threshold: Define threshold for dropout parameter 'k'. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, name='gw', pshift=pshift) # ephemeris model s += do.Dropout_PhysicalEphemerisSignal(use_epoch_toas=True, k_threshold=k_threshold) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_2a_drop_crn(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, bayesephem=False, is_wideband=False, use_dmdata=False, k_threshold=0.5, pshift=False, tm_marg=False, dense_like=False, tm_svd=False, tnequad=False,): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2A from the analysis paper: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1.Common red noise modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block amp_name = '{}_log10_A'.format('gw') if amp_prior == 'uniform': log10_Agw = parameter.LinearExp(-18, -11)(amp_name) elif amp_prior == 'log-uniform' and gamma_common is not None: if np.abs(gamma_common - 4.33) < 0.1: log10_Agw = parameter.Uniform(-18, -14)(amp_name) else: log10_Agw = parameter.Uniform(-18, -11)(amp_name) else: log10_Agw = parameter.Uniform(-18, -11)(amp_name) gam_name = '{}_gamma'.format('gw') if gamma_common is not None: gamma_gw = parameter.Constant(gamma_common)(gam_name) else: gamma_gw = parameter.Uniform(0, 7)(gam_name) k_drop = parameter.Uniform(0.0, 1.0) # per-pulsar drop_pl = do.dropout_powerlaw(log10_A=log10_Agw, gamma=gamma_gw, k_drop=k_drop, k_threshold=k_threshold) crn = gp_signals.FourierBasisGP(drop_pl, components=components, Tspan=Tspan, name='gw', pshift=pshift) s += crn # ephemeris model s += do.Dropout_PhysicalEphemerisSignal(use_epoch_toas=True) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta # Does not yet work with IPTA datasets due to white-noise modeling issues. def model_chromatic(psrs, psd='powerlaw', noisedict=None, white_vary=False, components=30, gamma_common=None, upper_limit=False, bayesephem=False, is_wideband=False, use_dmdata=False, pshift=False, idx=4, chromatic_psd='powerlaw', c_psrs=['J1713+0747'], tm_marg=False, dense_like=False, tm_svd=False, tnequad=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with model 2A from the analysis paper + additional chromatic noise for given pulsars per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. 6. Chromatic noise for given pulsar list global: 1.Common red noise modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] 2. Optional physical ephemeris modeling. :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param bayesephem: Include BayesEphem model. Set to False by default :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param idx: Index of chromatic process (i.e DM is 2, scattering would be 4). If set to `vary` then will vary from 0 - 6 (This will be VERY slow!) :param chromatic_psd: PSD to use for chromatic noise. Available options are ['powerlaw', 'turnover' 'spectrum']. 'powerlaw' is default value. :param c_psrs: List of pulsars to use chromatic noise. 'all' will use all pulsars :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling Tspan = model_utils.get_tspan(psrs) # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # white noise s += white_noise_block(vary=white_vary, inc_ecorr=not is_wideband, tnequad=tnequad) # red noise s += red_noise_block(prior=amp_prior, Tspan=Tspan, components=components) # common red noise block s += common_red_noise_block(psd=psd, prior=amp_prior, Tspan=Tspan, components=components, gamma_val=gamma_common, name='gw', pshift=pshift) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True) # chromatic noise sc = chromatic_noise_block(psd=chromatic_psd, idx=idx) if c_psrs == 'all': s += sc models = [s(psr) for psr in psrs] elif len(c_psrs) > 0: models = [] for psr in psrs: if psr.name in c_psrs: print('Adding chromatic model to PSR {}'.format(psr.name)) snew = s + sc models.append(snew(psr)) else: models.append(s(psr)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_bwm(psrs, likelihood=LogLikelihood, lookupdir=None, noisedict=None, tm_svd=False, Tmin_bwm=None, Tmax_bwm=None, skyloc=None, logmin=None, logmax=None, burst_logmin=-17, burst_logmax=-12, red_psd='powerlaw', components=30, dm_var=False, dm_psd='powerlaw', dm_annual=False, tnequad=False, upper_limit=False, bayesephem=False, wideband=False, tm_marg=False, dense_like=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with BWM model: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system (if NG channelized) 4. Red noise modeled by a specified psd 5. Linear timing model. 6. Optional DM-variation modeling global: 1. Deterministic GW burst with memory signal. 2. Optional physical ephemeris modeling. :param psrs: list of enterprise.Pulsar objects for PTA :param noisedict: Dictionary of pulsar noise properties for fixed white noise. Can provide manually, or the code will attempt to find it. :param tm_svd: boolean for svd-stabilised timing model design matrix :param Tmin_bwm: Min time to search for BWM (MJD). If omitted, uses first TOA. :param Tmax_bwm: Max time to search for BWM (MJD). If omitted, uses last TOA. :param skyloc: Fixed sky location of BWM signal search as [cos(theta), phi]. Search over sky location if ``None`` given. :param logmin: Lower bound on log10_A of the red noise process in each pulsar` :param logmax: Upper bound on log10_A of the red noise process in each pulsar :param burst_logmin: Lower bound on the log10_A of the burst amplitude in each pulsar :param burst_logmax: Upper boudn on the log10_A of the burst amplitude in each pulsar :param red_psd: PSD to use for per pulsar red noise. Available options are ['powerlaw', 'turnover', tprocess, 'spectrum']. :param components: number of modes in Fourier domain processes (red noise, DM variations, etc) :param dm_var: include gaussian process DM variations :param dm_psd: power-spectral density for gp DM variations :param dm_annual: include a yearly period DM variation :param upper_limit: Perform upper limit on BWM amplitude. By default this is set to False for a 'detection' run. :param bayesephem: Include BayesEphem model. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :return: instantiated enterprise.PTA object """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set frequency sampling tmin = np.min([p.toas.min() for p in psrs]) tmax = np.max([p.toas.max() for p in psrs]) Tspan = tmax - tmin if Tmin_bwm is None: Tmin_bwm = tmin/const.day if Tmax_bwm is None: Tmax_bwm = tmax/const.day if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, psd=red_psd, Tspan=Tspan, components=components, logmin=logmin, logmax=logmax) # DM variations if dm_var: s += dm_noise_block(psd=dm_psd, prior=amp_prior, components=components, gamma_val=None) if dm_annual: s += chrom.dm_annual_signal() # DM exponential dip for J1713's DM event dmexp = chrom.dm_exponential_dip(tmin=54500, tmax=54900) # GW BWM signal block s += bwm_block(Tmin_bwm, Tmax_bwm, logmin=burst_logmin, logmax=burst_logmax, amp_prior=amp_prior, skyloc=skyloc, name='bwm') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not wideband: s2 = s + white_noise_block(vary=False, inc_ecorr=True, tnequad=tnequad) if dm_var and 'J1713+0747' == p.name: s2 += dmexp models.append(s2(p)) else: s3 = s + white_noise_block(vary=False, inc_ecorr=False, tnequad=tnequad) if dm_var and 'J1713+0747' == p.name: s3 += dmexp models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_bwm_sglpsr(psr, likelihood=LogLikelihood, lookupdir=None, noisedict=None, tm_svd=False, tnequad=False, Tmin_bwm=None, Tmax_bwm=None, burst_logmin=-17, burst_logmax=-12, fixed_sign=None, red_psd='powerlaw', logmin=None, logmax=None, components=30, dm_var=False, dm_psd='powerlaw', dm_annual=False, upper_limit=False, bayesephem=False, wideband=False, tm_marg=False, dense_like=False): """ Burst-With-Memory model for single pulsar runs Because all of the geometric parameters (pulsar_position, source_position, gw_pol) are all degenerate with each other in a single pulsar BWM search, this model can only search over burst epoch and residual-space ramp amplitude (t0, ramp_amplitude) Reads in list of enterprise Pulsar instance and returns a PTA instantiated with single-pulsar BWM model (called a ramp): per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system (if NG channelized) 4. Red noise modeled by a specified psd 5. Linear timing model. 6. Optional DM-variation modeling 7. Deterministic GW burst with memory signal for this pulsar :param psr: enterprise.Pulsar objects for PTA. This model is only for one pulsar at a time. :param likelihood: The likelihood function to use. The options are [enterprise.signals.signal_base.LogLikelihood, enterprise.signals.signal_base.LookupLikelihood] :param noisedict: Dictionary of pulsar noise properties for fixed white noise. Can provide manually, or the code will attempt to find it. :param tm_svd: boolean for svd-stabilised timing model design matrix :param Tmin_bwm: Min time to search for BWM (MJD). If omitted, uses first TOA. :param Tmax_bwm: Max time to search for BWM (MJD). If omitted, uses last TOA. :param red_psd: PSD to use for per pulsar red noise. Available options are ['powerlaw', 'turnover', tprocess, 'spectrum']. :param components: number of modes in Fourier domain processes (red noise, DM variations, etc) :param dm_var: include gaussian process DM variations :param dm_psd: power-spectral density for gp DM variations :param dm_annual: include a yearly period DM variation :param upper_limit: Perform upper limit on BWM amplitude. By default this is set to False for a 'detection' run. :param bayesephem: Include BayesEphem model. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :return: instantiated enterprise.PTA object """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set frequency sampling tmin = psr.toas.min() tmax = psr.toas.max() Tspan = tmax - tmin if Tmin_bwm is None: Tmin_bwm = tmin/const.day if Tmax_bwm is None: Tmax_bwm = tmax/const.day if tm_marg: s = gp_signals.MarginalizingTimingModel() else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, psd=red_psd, Tspan=Tspan, components=components, logmin=logmin, logmax=logmax) # DM variations if dm_var: s += dm_noise_block(psd=dm_psd, prior=amp_prior, components=components, gamma_val=None) if dm_annual: s += chrom.dm_annual_signal() # DM exponential dip for J1713's DM event dmexp = chrom.dm_exponential_dip(tmin=54500, tmax=54900) # GW BWM signal block s += bwm_sglpsr_block(Tmin_bwm, Tmax_bwm, amp_prior=amp_prior, name='ramp', logmin=burst_logmin, logmax=burst_logmax, fixed_sign=fixed_sign) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True) # adding white-noise, and acting on psr objects models = [] if 'NANOGrav' in psr.flags['pta'] and not wideband: s2 = s + white_noise_block(vary=False, inc_ecorr=True, tnequad=tnequad) if dm_var and 'J1713+0747' == psr.name: s2 += dmexp models.append(s2(psr)) else: s3 = s + white_noise_block(vary=False, inc_ecorr=False, tnequad=tnequad) if dm_var and 'J1713+0747' == psr.name: s3 += dmexp models.append(s3(psr)) # set up PTA # TODO: decide on a way to handle likelihood if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_fdm(psrs, noisedict=None, white_vary=False, tm_svd=False, Tmin_fdm=None, Tmax_fdm=None, gw_psd='powerlaw', red_psd='powerlaw', components=30, n_rnfreqs=None, n_gwbfreqs=None, gamma_common=None, delta_common=None, dm_var=False, dm_psd='powerlaw', dm_annual=False, upper_limit=False, bayesephem=False, wideband=False, pshift=False, pseed=None, model_CRN=False, amp_upper=-11, amp_lower=-18, tnequad=False, freq_upper=-7, freq_lower=-9, use_fixed_freq=False, fixed_freq=-8, tm_marg=False, dense_like=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with FDM model: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system (if NG channelized) 4. Red noise modeled by a specified psd 5. Linear timing model. 6. Optional DM-variation modeling 7. The pulsar phase term. global: 1. Deterministic GW FDM signal. 2. Optional physical ephemeris modeling. :param psrs: list of enterprise.Pulsar objects for PTA :param noisedict: Dictionary of pulsar noise properties for fixed white noise. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param tm_svd: boolean for svd-stabilised timing model design matrix :param Tmin_fdm: Min time to search for FDM (MJD). If omitted, uses first TOA. :param Tmax_fdm: Max time to search for FDM (MJD). If omitted, uses last TOA. :param gw_psd: PSD to use for the per pulsar GWB. :param red_psd: PSD to use for per pulsar red noise. Available options are ['powerlaw', 'turnover', tprocess, 'spectrum']. :param components: number of modes in Fourier domain processes (red noise, DM variations, etc) :param n_rnfreqs: Number of frequencies to use in achromatic rednoise model. :param n_gwbfreqs: Number of frequencies to use in the GWB model. :param gamma_common: Fixed common red process spectral index value. By default we vary the spectral index over the range [0, 7]. :param dm_var: include gaussian process DM variations :param dm_psd: power-spectral density for gp DM variations :param dm_annual: include a yearly period DM variation :param upper_limit: Perform upper limit on FDM amplitude. By default this is set to False for a 'detection' run. :param bayesephem: Include BayesEphem model. :param wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param pshift: Option to use a random phase shift in design matrix. For testing the null hypothesis. :param pseed: Option to provide a seed for the random phase shift. :param model_CRN: Option to model the common red process in addition to the FDM signal. :param amp_upper, amp_lower, freq_upper, freq_lower: The log-space bounds on the amplitude and frequency priors. :param use_fixed_freq: Whether to do a fixed-frequency run and not search over the frequency. :param fixed_freq: The frequency value to do a fixed-frequency run with. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :return: instantiated enterprise.PTA object """ amp_prior = 'uniform' if upper_limit else 'log-uniform' if n_gwbfreqs is None: n_gwbfreqs = components if n_rnfreqs is None: n_rnfreqs = components # find the maximum time span to set frequency sampling tmin = np.min([p.toas.min() for p in psrs]) tmax = np.max([p.toas.max() for p in psrs]) Tspan = tmax - tmin if Tmin_fdm is None: Tmin_fdm = tmin/const.day if Tmax_fdm is None: Tmax_fdm = tmax/const.day # timing model if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, psd=red_psd, Tspan=Tspan, components=n_rnfreqs) # DM variations if dm_var: s += dm_noise_block(psd=dm_psd, prior=amp_prior, components=components, gamma_val=None) if dm_annual: s += chrom.dm_annual_signal() # DM exponential dip for J1713's DM event dmexp = chrom.dm_exponential_dip(tmin=54500, tmax=54900) if model_CRN is True: # common red noise block s += common_red_noise_block(psd=gw_psd, prior=amp_prior, Tspan=Tspan, components=n_gwbfreqs, gamma_val=gamma_common, delta_val=delta_common, name='gw', pshift=pshift, pseed=pseed) # GW FDM signal block s += deterministic.fdm_block(Tmin_fdm, Tmax_fdm, amp_prior=amp_prior, name='fdm', amp_lower=amp_lower, amp_upper=amp_upper, freq_lower=freq_lower, freq_upper=freq_upper, use_fixed_freq=use_fixed_freq, fixed_freq=fixed_freq) # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not wideband: s2 = s + white_noise_block(vary=False, inc_ecorr=True, tnequad=tnequad) if dm_var and 'J1713+0747' == p.name: s2 += dmexp models.append(s2(p)) else: s3 = s + white_noise_block(vary=False, inc_ecorr=False, tnequad=tnequad) if dm_var and 'J1713+0747' == p.name: s3 += dmexp models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta def model_cw(psrs, upper_limit=False, rn_psd='powerlaw', noisedict=None, white_vary=False, components=30, bayesephem=False, skyloc=None, log10_F=None, ecc=False, psrTerm=False, is_wideband=False, use_dmdata=False, gp_ecorr='basis_ecorr', tnequad=False, tm_marg=False, dense_like=False, tm_svd=False): """ Reads in list of enterprise Pulsar instance and returns a PTA instantiated with CW model: per pulsar: 1. fixed EFAC per backend/receiver system 2. fixed EQUAD per backend/receiver system 3. fixed ECORR per backend/receiver system 4. Red noise modeled as a power-law with 30 sampling frequencies 5. Linear timing model. global: 1. Deterministic CW signal. 2. Optional physical ephemeris modeling. :param upper_limit: Perform upper limit on common red noise amplitude. By default this is set to False. Note that when perfoming upper limits it is recommended that the spectral index also be fixed to a specific value. :param rn_psd: psd to use in red_noise_block() :param noisedict: Dictionary of pulsar noise properties. Can provide manually, or the code will attempt to find it. :param white_vary: boolean for varying white noise or keeping fixed. :param bayesephem: Include BayesEphem model. Set to False by default :param skyloc: Fixed sky location of CW signal search as [cos(theta), phi]. Search over sky location if ``None`` given. :param log10_F: Fixed frequency of CW signal search. Search over frequency if ``None`` given. :param ecc: boolean or float if boolean: include/exclude eccentricity in search if float: use fixed eccentricity with eccentric model :psrTerm: boolean, include/exclude pulsar term in search :param is_wideband: Whether input TOAs are wideband TOAs; will exclude ecorr from the white noise model. :param use_dmdata: whether to use DM data (WidebandTimingModel) if is_wideband. :param tm_marg: Use marginalized timing model. In many cases this will speed up the likelihood calculation significantly. :param dense_like: Use dense or sparse functions to evalute lnlikelihood :param tm_svd: boolean for svd-stabilised timing model design matrix """ amp_prior = 'uniform' if upper_limit else 'log-uniform' # find the maximum time span to set GW frequency sampling tmin = np.min([p.toas.min() for p in psrs]) tmax = np.max([p.toas.max() for p in psrs]) Tspan = tmax - tmin # timing model if (is_wideband and use_dmdata): dmjump = parameter.Constant() if white_vary: dmefac = parameter.Uniform(pmin=0.1, pmax=10.0) log10_dmequad = parameter.Uniform(pmin=-7.0, pmax=0.0) # dmjump = parameter.Uniform(pmin=-0.005, pmax=0.005) else: dmefac = parameter.Constant() log10_dmequad = parameter.Constant() # dmjump = parameter.Constant() s = gp_signals.WidebandTimingModel(dmefac=dmefac, log10_dmequad=log10_dmequad, dmjump=dmjump, selection=selections.Selection(selections.by_backend), dmjump_selection=selections.Selection(selections.by_frontend)) else: if tm_marg: s = gp_signals.MarginalizingTimingModel(use_svd=tm_svd) else: s = gp_signals.TimingModel(use_svd=tm_svd) # red noise s += red_noise_block(prior=amp_prior, psd=rn_psd, Tspan=Tspan, components=components) # GW CW signal block if not ecc: s += deterministic.cw_block_circ(amp_prior=amp_prior, skyloc=skyloc, log10_fgw=log10_F, psrTerm=psrTerm, tref=tmin, name='cw') else: if type(ecc) is not float: ecc = None s += deterministic.cw_block_ecc(amp_prior=amp_prior, skyloc=skyloc, log10_F=log10_F, ecc=ecc, psrTerm=psrTerm, tref=tmin, name='cw') # ephemeris model if bayesephem: s += deterministic_signals.PhysicalEphemerisSignal(use_epoch_toas=True) # adding white-noise, and acting on psr objects models = [] for p in psrs: if 'NANOGrav' in p.flags['pta'] and not is_wideband: if gp_ecorr: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, gp_ecorr=True, name=gp_ecorr, tnequad=tnequad) else: s2 = s + white_noise_block(vary=white_vary, inc_ecorr=True, tnequad=tnequad) models.append(s2(p)) else: s3 = s + white_noise_block(vary=white_vary, inc_ecorr=False, tnequad=tnequad) models.append(s3(p)) # set up PTA if dense_like: pta = signal_base.PTA(models, lnlikelihood=signal_base.LogLikelihoodDenseCholesky) else: pta = signal_base.PTA(models) # set white noise parameters if not white_vary or (is_wideband and use_dmdata): if noisedict is None: print('No noise dictionary provided!...') else: noisedict = noisedict pta.set_default_params(noisedict) return pta

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/__init__.py

__version__ = "2.4.3"

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/blocks.py

# -*- coding: utf-8 -*- import types import numpy as np from enterprise import constants as const from enterprise.signals import deterministic_signals from enterprise.signals import gp_bases as gpb from enterprise.signals import gp_priors as gpp from enterprise.signals import (gp_signals, parameter, selections, utils, white_signals) from enterprise_extensions import deterministic as ee_deterministic from . import chromatic as chrom from . import dropout as drop from . import gp_kernels as gpk from . import model_orfs __all__ = ['white_noise_block', 'red_noise_block', 'bwm_block', 'bwm_sglpsr_block', 'dm_noise_block', 'chromatic_noise_block', 'common_red_noise_block', ] def channelized_backends(backend_flags): """Selection function to split by channelized backend flags only. For ECORR""" flagvals = np.unique(backend_flags) ch_b = ['ASP', 'GASP', 'GUPPI', 'PUPPI', 'YUPPI', 'CHIME'] flagvals = filter(lambda x: any(map(lambda y: y in x, ch_b)), flagvals) return {flagval: backend_flags == flagval for flagval in flagvals} def white_noise_block(vary=False, inc_ecorr=False, gp_ecorr=False, efac1=False, select='backend', tnequad=False, name=None, ng_twg_setup=False, wb_efac_sigma=0.25): """ Returns the white noise block of the model: 1. EFAC per backend/receiver system 2. EQUAD per backend/receiver system 3. ECORR per backend/receiver system :param vary: If set to true we vary these parameters with uniform priors. Otherwise they are set to constants with values to be set later. :param inc_ecorr: include ECORR, needed for NANOGrav channelized TOAs :param gp_ecorr: whether to use the Gaussian process model for ECORR :param efac1: use a strong prior on EFAC = Normal(mu=1, stdev=0.1) :param tnequad: Whether to use the TempoNest definition of EQUAD. Defaults to False to follow Tempo, Tempo2 and Pint definition. """ if select == 'backend': # define selection by observing backend backend = selections.Selection(selections.by_backend) # define selection by nanograv backends backend_ng = selections.Selection(selections.nanograv_backends) # backend_ch = selections.Selection(channelized_backends) else: # define no selection backend = selections.Selection(selections.no_selection) # white noise parameters if vary: if efac1: efac = parameter.Normal(1.0, 0.1) elif ng_twg_setup: efac = parameter.Normal(1.0, wb_efac_sigma) else: efac = parameter.Uniform(0.01, 10.0) equad = parameter.Uniform(-8.5, -5) if inc_ecorr: ecorr = parameter.Uniform(-8.5, -5) else: efac = parameter.Constant() equad = parameter.Constant() if inc_ecorr: ecorr = parameter.Constant() # white noise signals if tnequad: efeq = white_signals.MeasurementNoise(efac=efac, selection=backend, name=name) efeq += white_signals.TNEquadNoise(log10_tnequad=equad, selection=backend, name=name) else: efeq = white_signals.MeasurementNoise(efac=efac, log10_t2equad=equad, selection=backend, name=name) if inc_ecorr: if gp_ecorr: if name is None: ec = gp_signals.EcorrBasisModel(log10_ecorr=ecorr, selection=backend_ng) else: ec = gp_signals.EcorrBasisModel(log10_ecorr=ecorr, selection=backend_ng, name=name) else: ec = white_signals.EcorrKernelNoise(log10_ecorr=ecorr, selection=backend_ng, name=name) # combine signals if inc_ecorr: s = efeq + ec elif not inc_ecorr: s = efeq return s def red_noise_block(psd='powerlaw', prior='log-uniform', Tspan=None, components=30, gamma_val=None, coefficients=False, select=None, modes=None, wgts=None, combine=True, break_flat=False, break_flat_fq=None, logmin=None, logmax=None, dropout=False, k_threshold=0.5): """ Returns red noise model: Red noise modeled as a power-law with 30 sampling frequencies :param psd: PSD function [e.g. powerlaw (default), turnover, spectrum, tprocess] :param prior: Prior on log10_A. Default if "log-uniform". Use "uniform" for upper limits. :param Tspan: Sets frequency sampling f_i = i / Tspan. Default will use overall time span for indivicual pulsar. :param components: Number of frequencies in sampling of red noise :param gamma_val: If given, this is the fixed slope of the power-law for powerlaw, turnover, or tprocess red noise :param coefficients: include latent coefficients in GP model? :param dropout: Use a dropout analysis for intrinsic red noise models. Currently only supports power law option. :param k_threshold: Threshold for dropout analysis. """ # red noise parameters that are common if psd in ['powerlaw', 'powerlaw_genmodes', 'turnover', 'tprocess', 'tprocess_adapt']: # parameters shared by PSD functions if logmin is not None and logmax is not None: if prior == 'uniform': log10_A = parameter.LinearExp(logmin, logmax) elif prior == 'log-uniform': log10_A = parameter.Uniform(logmin, logmax) else: if prior == 'uniform': log10_A = parameter.LinearExp(-20, -11) elif prior == 'log-uniform' and gamma_val is not None: if np.abs(gamma_val - 4.33) < 0.1: log10_A = parameter.Uniform(-20, -11) else: log10_A = parameter.Uniform(-20, -11) else: log10_A = parameter.Uniform(-20, -11) if gamma_val is not None: gamma = parameter.Constant(gamma_val) else: gamma = parameter.Uniform(0, 7) # different PSD function parameters if psd == 'powerlaw' and dropout: k_drop = parameter.Uniform(0, 1) pl = drop.dropout_powerlaw(log10_A=log10_A, gamma=gamma, dropout_psr='all', k_drop=k_drop, k_threshold=k_threshold) elif psd == 'powerlaw': pl = utils.powerlaw(log10_A=log10_A, gamma=gamma) elif psd == 'powerlaw_genmodes': pl = gpp.powerlaw_genmodes(log10_A=log10_A, gamma=gamma, wgts=wgts) elif psd == 'turnover': kappa = parameter.Uniform(0, 7) lf0 = parameter.Uniform(-9, -7) pl = utils.turnover(log10_A=log10_A, gamma=gamma, lf0=lf0, kappa=kappa) elif psd == 'tprocess': df = 2 alphas = gpp.InvGamma(df/2, df/2, size=components) pl = gpp.t_process(log10_A=log10_A, gamma=gamma, alphas=alphas) elif psd == 'tprocess_adapt': df = 2 alpha_adapt = gpp.InvGamma(df/2, df/2, size=1) nfreq = parameter.Uniform(-0.5, 10-0.5) pl = gpp.t_process_adapt(log10_A=log10_A, gamma=gamma, alphas_adapt=alpha_adapt, nfreq=nfreq) if psd == 'spectrum': if prior == 'uniform': log10_rho = parameter.LinearExp(-10, -4, size=components) elif prior == 'log-uniform': log10_rho = parameter.Uniform(-10, -4, size=components) pl = gpp.free_spectrum(log10_rho=log10_rho) if select == 'backend': # define selection by observing backend selection = selections.Selection(selections.by_backend) elif select == 'band' or select == 'band+': # define selection by observing band selection = selections.Selection(selections.by_band) else: # define no selection selection = selections.Selection(selections.no_selection) if break_flat: log10_A_flat = parameter.Uniform(-20, -11) gamma_flat = parameter.Constant(0) pl_flat = utils.powerlaw(log10_A=log10_A_flat, gamma=gamma_flat) freqs = 1.0 * np.arange(1, components+1) / Tspan components_low = sum(f < break_flat_fq for f in freqs) if components_low < 1.5: components_low = 2 rn = gp_signals.FourierBasisGP(pl, components=components_low, Tspan=Tspan, coefficients=coefficients, combine=combine, selection=selection) rn_flat = gp_signals.FourierBasisGP(pl_flat, modes=freqs[components_low:], coefficients=coefficients, selection=selection, combine=combine, name='red_noise_hf') rn = rn + rn_flat else: rn = gp_signals.FourierBasisGP(pl, components=components, Tspan=Tspan, combine=combine, coefficients=coefficients, selection=selection, modes=modes) if select == 'band+': # Add the common component as well rn = rn + gp_signals.FourierBasisGP(pl, components=components, Tspan=Tspan, combine=combine, coefficients=coefficients) return rn def bwm_block(Tmin, Tmax, amp_prior='log-uniform', skyloc=None, logmin=-18, logmax=-11, name='bwm'): """ Returns deterministic GW burst with memory model: 1. Burst event parameterized by time, sky location, polarization angle, and amplitude :param Tmin: Min time to search, probably first TOA (MJD). :param Tmax: Max time to search, probably last TOA (MJD). :param amp_prior: Prior on log10_A. Default if "log-uniform". Use "uniform" for upper limits. :param skyloc: Fixed sky location of BWM signal search as [cos(theta), phi]. Search over sky location if ``None`` given. :param logmin: log of minimum BWM amplitude for prior (log10) :param logmax: log of maximum BWM amplitude for prior (log10) :param name: Name of BWM signal. """ # BWM parameters amp_name = '{}_log10_A'.format(name) if amp_prior == 'uniform': log10_A_bwm = parameter.LinearExp(logmin, logmax)(amp_name) elif amp_prior == 'log-uniform': log10_A_bwm = parameter.Uniform(logmin, logmax)(amp_name) pol_name = '{}_pol'.format(name) pol = parameter.Uniform(0, np.pi)(pol_name) t0_name = '{}_t0'.format(name) t0 = parameter.Uniform(Tmin, Tmax)(t0_name) costh_name = '{}_costheta'.format(name) phi_name = '{}_phi'.format(name) if skyloc is None: costh = parameter.Uniform(-1, 1)(costh_name) phi = parameter.Uniform(0, 2*np.pi)(phi_name) else: costh = parameter.Constant(skyloc[0])(costh_name) phi = parameter.Constant(skyloc[1])(phi_name) # BWM signal bwm_wf = ee_deterministic.bwm_delay(log10_h=log10_A_bwm, t0=t0, cos_gwtheta=costh, gwphi=phi, gwpol=pol) bwm = deterministic_signals.Deterministic(bwm_wf, name=name) return bwm def bwm_sglpsr_block(Tmin, Tmax, amp_prior='log-uniform', logmin=-17, logmax=-12, name='ramp', fixed_sign=None): if fixed_sign is None: sign = parameter.Uniform(-1, 1)("sign") else: sign = np.sign(fixed_sign) amp_name = '{}_log10_A'.format(name) if amp_prior == 'uniform': log10_A_ramp = parameter.LinearExp(logmin, logmax)(amp_name) elif amp_prior == 'log-uniform': log10_A_ramp = parameter.Uniform(logmin, logmax)(amp_name) t0_name = '{}_t0'.format(name) t0 = parameter.Uniform(Tmin, Tmax)(t0_name) ramp_wf = ee_deterministic.bwm_sglpsr_delay(log10_A=log10_A_ramp, t0=t0, sign=sign) ramp = deterministic_signals.Deterministic(ramp_wf, name=name) return ramp def dm_noise_block(gp_kernel='diag', psd='powerlaw', nondiag_kernel='periodic', prior='log-uniform', dt=15, df=200, Tspan=None, components=30, gamma_val=None, coefficients=False): """ Returns DM noise model: 1. DM noise modeled as a power-law with 30 sampling frequencies :param psd: PSD function [e.g. powerlaw (default), spectrum, tprocess] :param prior: Prior on log10_A. Default if "log-uniform". Use "uniform" for upper limits. :param dt: time-scale for linear interpolation basis (days) :param df: frequency-scale for linear interpolation basis (MHz) :param Tspan: Sets frequency sampling f_i = i / Tspan. Default will use overall time span for indivicual pulsar. :param components: Number of frequencies in sampling of DM-variations. :param gamma_val: If given, this is the fixed slope of the power-law for powerlaw, turnover, or tprocess DM-variations """ # dm noise parameters that are common if gp_kernel == 'diag': if psd in ['powerlaw', 'turnover', 'tprocess', 'tprocess_adapt']: # parameters shared by PSD functions if prior == 'uniform': log10_A_dm = parameter.LinearExp(-20, -11) elif prior == 'log-uniform' and gamma_val is not None: if np.abs(gamma_val - 4.33) < 0.1: log10_A_dm = parameter.Uniform(-20, -11) else: log10_A_dm = parameter.Uniform(-20, -11) else: log10_A_dm = parameter.Uniform(-20, -11) if gamma_val is not None: gamma_dm = parameter.Constant(gamma_val) else: gamma_dm = parameter.Uniform(0, 7) # different PSD function parameters if psd == 'powerlaw': dm_prior = utils.powerlaw(log10_A=log10_A_dm, gamma=gamma_dm) elif psd == 'turnover': kappa_dm = parameter.Uniform(0, 7) lf0_dm = parameter.Uniform(-9, -7) dm_prior = utils.turnover(log10_A=log10_A_dm, gamma=gamma_dm, lf0=lf0_dm, kappa=kappa_dm) elif psd == 'tprocess': df = 2 alphas_dm = gpp.InvGamma(df/2, df/2, size=components) dm_prior = gpp.t_process(log10_A=log10_A_dm, gamma=gamma_dm, alphas=alphas_dm) elif psd == 'tprocess_adapt': df = 2 alpha_adapt_dm = gpp.InvGamma(df/2, df/2, size=1) nfreq_dm = parameter.Uniform(-0.5, 10-0.5) dm_prior = gpp.t_process_adapt(log10_A=log10_A_dm, gamma=gamma_dm, alphas_adapt=alpha_adapt_dm, nfreq=nfreq_dm) if psd == 'spectrum': if prior == 'uniform': log10_rho_dm = parameter.LinearExp(-10, -4, size=components) elif prior == 'log-uniform': log10_rho_dm = parameter.Uniform(-10, -4, size=components) dm_prior = gpp.free_spectrum(log10_rho=log10_rho_dm) dm_basis = utils.createfourierdesignmatrix_dm(nmodes=components, Tspan=Tspan) elif gp_kernel == 'nondiag': if nondiag_kernel == 'periodic': # Periodic GP kernel for DM log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_p = parameter.Uniform(-4, 1) log10_gam_p = parameter.Uniform(-3, 2) dm_basis = gpk.linear_interp_basis_dm(dt=dt*const.day) dm_prior = gpk.periodic_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_gam_p=log10_gam_p, log10_p=log10_p) elif nondiag_kernel == 'periodic_rfband': # Periodic GP kernel for DM with RQ radio-frequency dependence log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_ell2 = parameter.Uniform(2, 7) log10_alpha_wgt = parameter.Uniform(-4, 1) log10_p = parameter.Uniform(-4, 1) log10_gam_p = parameter.Uniform(-3, 2) dm_basis = gpk.get_tf_quantization_matrix(df=df, dt=dt*const.day, dm=True) dm_prior = gpk.tf_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_gam_p=log10_gam_p, log10_p=log10_p, log10_alpha_wgt=log10_alpha_wgt, log10_ell2=log10_ell2) elif nondiag_kernel == 'sq_exp': # squared-exponential GP kernel for DM log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) dm_basis = gpk.linear_interp_basis_dm(dt=dt*const.day) dm_prior = gpk.se_dm_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell) elif nondiag_kernel == 'sq_exp_rfband': # Sq-Exp GP kernel for DM with RQ radio-frequency dependence log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_ell2 = parameter.Uniform(2, 7) log10_alpha_wgt = parameter.Uniform(-4, 1) dm_basis = gpk.get_tf_quantization_matrix(df=df, dt=dt*const.day, dm=True) dm_prior = gpk.sf_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_alpha_wgt=log10_alpha_wgt, log10_ell2=log10_ell2) elif nondiag_kernel == 'dmx_like': # DMX-like signal log10_sigma = parameter.Uniform(-10, -4) dm_basis = gpk.linear_interp_basis_dm(dt=dt*const.day) dm_prior = gpk.dmx_ridge_prior(log10_sigma=log10_sigma) dmgp = gp_signals.BasisGP(dm_prior, dm_basis, name='dm_gp', coefficients=coefficients) return dmgp def chromatic_noise_block(gp_kernel='nondiag', psd='powerlaw', nondiag_kernel='periodic', prior='log-uniform', dt=15, df=200, idx=4, include_quadratic=False, Tspan=None, name='chrom', components=30, coefficients=False): """ Returns GP chromatic noise model : 1. Chromatic modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] :param gp_kernel: Whether to use a diagonal kernel for the GP. ['diag','nondiag'] :param nondiag_kernel: Which nondiagonal kernel to use for the GP. ['periodic','sq_exp','periodic_rfband','sq_exp_rfband'] :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum'] :param prior: What type of prior to use for amplitudes. ['log-uniform','uniform'] :param dt: time-scale for linear interpolation basis (days) :param df: frequency-scale for linear interpolation basis (MHz) :param idx: Index of radio frequency dependence (i.e. DM is 2). Any float will work. :param include_quadratic: Whether to include a quadratic fit. :param name: Name of signal :param Tspan: Tspan from which to calculate frequencies for PSD-based GPs. :param components: Number of frequencies to use in 'diag' GPs. :param coefficients: Whether to keep coefficients of the GP. """ if gp_kernel == 'diag': chm_basis = gpb.createfourierdesignmatrix_chromatic(nmodes=components, Tspan=Tspan) if psd in ['powerlaw', 'turnover']: if prior == 'uniform': log10_A = parameter.LinearExp(-18, -11) elif prior == 'log-uniform': log10_A = parameter.Uniform(-18, -11) gamma = parameter.Uniform(0, 7) # PSD if psd == 'powerlaw': chm_prior = utils.powerlaw(log10_A=log10_A, gamma=gamma) elif psd == 'turnover': kappa = parameter.Uniform(0, 7) lf0 = parameter.Uniform(-9, -7) chm_prior = utils.turnover(log10_A=log10_A, gamma=gamma, lf0=lf0, kappa=kappa) if psd == 'spectrum': if prior == 'uniform': log10_rho = parameter.LinearExp(-10, -4, size=components) elif prior == 'log-uniform': log10_rho = parameter.Uniform(-10, -4, size=components) chm_prior = gpp.free_spectrum(log10_rho=log10_rho) elif gp_kernel == 'nondiag': if nondiag_kernel == 'periodic': # Periodic GP kernel for DM log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_p = parameter.Uniform(-4, 1) log10_gam_p = parameter.Uniform(-3, 2) chm_basis = gpk.linear_interp_basis_chromatic(dt=dt*const.day) chm_prior = gpk.periodic_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_gam_p=log10_gam_p, log10_p=log10_p) elif nondiag_kernel == 'periodic_rfband': # Periodic GP kernel for DM with RQ radio-frequency dependence log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_ell2 = parameter.Uniform(2, 7) log10_alpha_wgt = parameter.Uniform(-4, 1) log10_p = parameter.Uniform(-4, 1) log10_gam_p = parameter.Uniform(-3, 2) chm_basis = gpk.get_tf_quantization_matrix(df=df, dt=dt*const.day, dm=True, dm_idx=idx) chm_prior = gpk.tf_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_gam_p=log10_gam_p, log10_p=log10_p, log10_alpha_wgt=log10_alpha_wgt, log10_ell2=log10_ell2) elif nondiag_kernel == 'sq_exp': # squared-exponential kernel for DM log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) chm_basis = gpk.linear_interp_basis_chromatic(dt=dt*const.day, idx=idx) chm_prior = gpk.se_dm_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell) elif nondiag_kernel == 'sq_exp_rfband': # Sq-Exp GP kernel for Chrom with RQ radio-frequency dependence log10_sigma = parameter.Uniform(-10, -4) log10_ell = parameter.Uniform(1, 4) log10_ell2 = parameter.Uniform(2, 7) log10_alpha_wgt = parameter.Uniform(-4, 1) chm_basis = gpk.get_tf_quantization_matrix(df=df, dt=dt*const.day, dm=True, dm_idx=idx) chm_prior = gpk.sf_kernel(log10_sigma=log10_sigma, log10_ell=log10_ell, log10_alpha_wgt=log10_alpha_wgt, log10_ell2=log10_ell2) cgp = gp_signals.BasisGP(chm_prior, chm_basis, name=name+'_gp', coefficients=coefficients) if include_quadratic: # quadratic piece basis_quad = chrom.chromatic_quad_basis(idx=idx) prior_quad = chrom.chromatic_quad_prior() cquad = gp_signals.BasisGP(prior_quad, basis_quad, name=name+'_quad') cgp += cquad return cgp def common_red_noise_block(psd='powerlaw', prior='log-uniform', Tspan=None, components=30, combine=True, log10_A_val=None, gamma_val=None, delta_val=None, logmin=None, logmax=None, orf=None, orf_ifreq=0, leg_lmax=5, name='gw', coefficients=False, pshift=False, pseed=None): """ Returns common red noise model: 1. Red noise modeled with user defined PSD with 30 sampling frequencies. Available PSDs are ['powerlaw', 'turnover' 'spectrum'] :param psd: PSD to use for common red noise signal. Available options are ['powerlaw', 'turnover' 'spectrum', 'broken_powerlaw'] :param prior: Prior on log10_A. Default if "log-uniform". Use "uniform" for upper limits. :param Tspan: Sets frequency sampling f_i = i / Tspan. Default will use overall time span for individual pulsar. :param log10_A_val: Value of log10_A parameter for fixed amplitude analyses. :param gamma_val: Value of spectral index for power-law and turnover models. By default spectral index is varied of range [0,7] :param delta_val: Value of spectral index for high frequencies in broken power-law and turnover models. By default spectral index is varied in range [0,7].\ :param logmin: Specify the lower bound of the prior on the amplitude for all psd but 'spectrum'. If psd=='spectrum', then this specifies the lower prior on log10_rho_gw :param logmax: Specify the lower bound of the prior on the amplitude for all psd but 'spectrum'. If psd=='spectrum', then this specifies the lower prior on log10_rho_gw :param orf: String representing which overlap reduction function to use. By default we do not use any spatial correlations. Permitted values are ['hd', 'dipole', 'monopole']. :param orf_ifreq: Frequency bin at which to start the Hellings & Downs function with numbering beginning at 0. Currently only works with freq_hd orf. :param leg_lmax: Maximum multipole of a Legendre polynomial series representation of the overlap reduction function [default=5] :param pshift: Option to use a random phase shift in design matrix. For testing the null hypothesis. :param pseed: Option to provide a seed for the random phase shift. :param name: Name of common red process """ orfs = {'crn': None, 'hd': model_orfs.hd_orf(), 'gw_monopole': model_orfs.gw_monopole_orf(), 'gw_dipole': model_orfs.gw_dipole_orf(), 'st': model_orfs.st_orf(), 'gt': model_orfs.gt_orf(tau=parameter.Uniform(-1.5, 1.5)('tau')), 'dipole': model_orfs.dipole_orf(), 'monopole': model_orfs.monopole_orf(), 'param_hd': model_orfs.param_hd_orf(a=parameter.Uniform(-1.5, 3.0)('gw_orf_param0'), b=parameter.Uniform(-1.0, 0.5)('gw_orf_param1'), c=parameter.Uniform(-1.0, 1.0)('gw_orf_param2')), 'spline_orf': model_orfs.spline_orf(params=parameter.Uniform(-0.9, 0.9, size=7)('gw_orf_spline')), 'bin_orf': model_orfs.bin_orf(params=parameter.Uniform(-1.0, 1.0, size=7)('gw_orf_bin')), 'zero_diag_hd': model_orfs.zero_diag_hd(), 'zero_diag_bin_orf': model_orfs.zero_diag_bin_orf(params=parameter.Uniform( -1.0, 1.0, size=7)('gw_orf_bin_zero_diag')), 'freq_hd': model_orfs.freq_hd(params=[components, orf_ifreq]), 'legendre_orf': model_orfs.legendre_orf(params=parameter.Uniform( -1.0, 1.0, size=leg_lmax+1)('gw_orf_legendre')), 'zero_diag_legendre_orf': model_orfs.zero_diag_legendre_orf(params=parameter.Uniform( -1.0, 1.0, size=leg_lmax+1)('gw_orf_legendre_zero_diag'))} # common red noise parameters if psd in ['powerlaw', 'turnover', 'turnover_knee', 'broken_powerlaw']: amp_name = '{}_log10_A'.format(name) if log10_A_val is not None: log10_Agw = parameter.Constant(log10_A_val)(amp_name) if logmin is not None and logmax is not None: if prior == 'uniform': log10_Agw = parameter.LinearExp(logmin, logmax)(amp_name) elif prior == 'log-uniform' and gamma_val is not None: if np.abs(gamma_val - 4.33) < 0.1: log10_Agw = parameter.Uniform(logmin, logmax)(amp_name) else: log10_Agw = parameter.Uniform(logmin, logmax)(amp_name) else: log10_Agw = parameter.Uniform(logmin, logmax)(amp_name) else: if prior == 'uniform': log10_Agw = parameter.LinearExp(-18, -11)(amp_name) elif prior == 'log-uniform' and gamma_val is not None: if np.abs(gamma_val - 4.33) < 0.1: log10_Agw = parameter.Uniform(-18, -14)(amp_name) else: log10_Agw = parameter.Uniform(-18, -11)(amp_name) else: log10_Agw = parameter.Uniform(-18, -11)(amp_name) gam_name = '{}_gamma'.format(name) if gamma_val is not None: gamma_gw = parameter.Constant(gamma_val)(gam_name) else: gamma_gw = parameter.Uniform(0, 7)(gam_name) # common red noise PSD if psd == 'powerlaw': cpl = utils.powerlaw(log10_A=log10_Agw, gamma=gamma_gw) elif psd == 'broken_powerlaw': delta_name = '{}_delta'.format(name) kappa_name = '{}_kappa'.format(name) log10_fb_name = '{}_log10_fb'.format(name) kappa_gw = parameter.Uniform(0.01, 0.5)(kappa_name) log10_fb_gw = parameter.Uniform(-10, -7)(log10_fb_name) if delta_val is not None: delta_gw = parameter.Constant(delta_val)(delta_name) else: delta_gw = parameter.Uniform(0, 7)(delta_name) cpl = gpp.broken_powerlaw(log10_A=log10_Agw, gamma=gamma_gw, delta=delta_gw, log10_fb=log10_fb_gw, kappa=kappa_gw) elif psd == 'turnover': kappa_name = '{}_kappa'.format(name) lf0_name = '{}_log10_fbend'.format(name) kappa_gw = parameter.Uniform(0, 7)(kappa_name) lf0_gw = parameter.Uniform(-9, -7)(lf0_name) cpl = utils.turnover(log10_A=log10_Agw, gamma=gamma_gw, lf0=lf0_gw, kappa=kappa_gw) elif psd == 'turnover_knee': kappa_name = '{}_kappa'.format(name) lfb_name = '{}_log10_fbend'.format(name) delta_name = '{}_delta'.format(name) lfk_name = '{}_log10_fknee'.format(name) kappa_gw = parameter.Uniform(0, 7)(kappa_name) lfb_gw = parameter.Uniform(-9.3, -8)(lfb_name) delta_gw = parameter.Uniform(-2, 0)(delta_name) lfk_gw = parameter.Uniform(-8, -7)(lfk_name) cpl = gpp.turnover_knee(log10_A=log10_Agw, gamma=gamma_gw, lfb=lfb_gw, lfk=lfk_gw, kappa=kappa_gw, delta=delta_gw) if psd == 'spectrum': rho_name = '{}_log10_rho'.format(name) # checking if priors specified, otherwise give default values if logmin is None: logmin = -9 if logmax is None: logmax = -4 if prior == 'uniform': log10_rho_gw = parameter.LinearExp(logmin, logmax, size=components)(rho_name) elif prior == 'log-uniform': log10_rho_gw = parameter.Uniform(logmin, logmax, size=components)(rho_name) cpl = gpp.free_spectrum(log10_rho=log10_rho_gw) if orf is None: crn = gp_signals.FourierBasisGP(cpl, coefficients=coefficients, combine=combine, components=components, Tspan=Tspan, name=name, pshift=pshift, pseed=pseed) elif orf in orfs.keys(): if orf == 'crn': crn = gp_signals.FourierBasisGP(cpl, coefficients=coefficients, combine=combine, components=components, Tspan=Tspan, name=name, pshift=pshift, pseed=pseed) else: crn = gp_signals.FourierBasisCommonGP(cpl, orfs[orf], components=components, combine=combine, Tspan=Tspan, name=name, pshift=pshift, pseed=pseed) elif isinstance(orf, types.FunctionType): crn = gp_signals.FourierBasisCommonGP(cpl, orf, components=components, combine=combine, Tspan=Tspan, name=name, pshift=pshift, pseed=pseed) else: raise ValueError('ORF {} not recognized'.format(orf)) return crn

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/chromatic/chromatic.py

# -*- coding: utf-8 -*- import numpy as np from enterprise import constants as const from enterprise.signals import deterministic_signals, parameter, signal_base __all__ = ['chrom_exp_decay', 'chrom_exp_cusp', 'chrom_dual_exp_cusp', 'chrom_yearly_sinusoid', 'chromatic_quad_basis', 'chromatic_quad_prior', 'dmx_delay', 'dm_exponential_dip', 'dm_exponential_cusp', 'dm_dual_exp_cusp', 'dmx_signal', 'dm_annual_signal', ] @signal_base.function def chrom_exp_decay(toas, freqs, log10_Amp=-7, sign_param=-1.0, t0=54000, log10_tau=1.7, idx=2): """ Chromatic exponential-dip delay term in TOAs. :param t0: time of exponential minimum [MJD] :param tau: 1/e time of exponential [s] :param log10_Amp: amplitude of dip :param sign_param: sign of waveform :param idx: index of chromatic dependence :return wf: delay time-series [s] """ t0 *= const.day tau = 10**log10_tau * const.day ind = np.where(toas > t0)[0] wf = 10**log10_Amp * np.heaviside(toas - t0, 1) wf[ind] *= np.exp(- (toas[ind] - t0) / tau) return np.sign(sign_param) * wf * (1400 / freqs) ** idx @signal_base.function def chrom_exp_cusp(toas, freqs, log10_Amp=-7, sign_param=-1.0, t0=54000, log10_tau_pre=1.7, log10_tau_post=1.7, symmetric=False, idx=2): """ Chromatic exponential-cusp delay term in TOAs. :param t0: time of exponential minimum [MJD] :param tau_pre: 1/e time of exponential before peak [s] :param tau_post: 1/e time of exponential after peak[s] :param symmetric: whether or not tau_pre = tau_post :param log10_Amp: amplitude of cusp :param sign_param: sign of waveform :param idx: index of chromatic dependence :return wf: delay time-series [s] """ t0 *= const.day if symmetric: tau = 10**log10_tau_pre * const.day ind_pre = np.where(toas < t0)[0] ind_post = np.where(toas > t0)[0] wf_pre = 10**log10_Amp * (1 - np.heaviside(toas - t0, 1)) wf_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau) wf_post = 10**log10_Amp * np.heaviside(toas - t0, 1) wf_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau) wf = wf_pre + wf_post else: tau_pre = 10**log10_tau_pre * const.day tau_post = 10**log10_tau_post * const.day ind_pre = np.where(toas < t0)[0] ind_post = np.where(toas > t0)[0] wf_pre = 10**log10_Amp * (1 - np.heaviside(toas - t0, 1)) wf_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau_pre) wf_post = 10**log10_Amp * np.heaviside(toas - t0, 1) wf_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau_post) wf = wf_pre + wf_post return np.sign(sign_param) * wf * (1400 / freqs) ** idx @signal_base.function def chrom_dual_exp_cusp(toas, freqs, t0=54000, sign_param=-1.0, log10_Amp_1=-7, log10_tau_pre_1=1.7, log10_tau_post_1=1.7, log10_Amp_2=-7, log10_tau_pre_2=1.7, log10_tau_post_2=1.7, symmetric=False, idx1=2, idx2=4): """ Chromatic exponential-cusp delay term in TOAs. :param t0: time of exponential minimum [MJD] :param tau_pre: 1/e time of exponential before peak [s] :param tau_post: 1/e time of exponential after peak[s] :param symmetric: whether or not tau_pre = tau_post :param log10_Amp: amplitude of cusp :param sign_param: sign of waveform :param idx: index of chromatic dependence :return wf: delay time-series [s] """ t0 *= const.day ind_pre = np.where(toas < t0)[0] ind_post = np.where(toas > t0)[0] if symmetric: tau_1 = 10**log10_tau_pre_1 * const.day wf_1_pre = 10**log10_Amp_1 * (1 - np.heaviside(toas - t0, 1)) wf_1_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau_1) wf_1_post = 10**log10_Amp_1 * np.heaviside(toas - t0, 1) wf_1_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau_1) wf_1 = wf_1_pre + wf_1_post tau_2 = 10**log10_tau_pre_2 * const.day wf_2_pre = 10**log10_Amp_2 * (1 - np.heaviside(toas - t0, 1)) wf_2_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau_2) wf_2_post = 10**log10_Amp_2 * np.heaviside(toas - t0, 1) wf_2_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau_2) wf_2 = wf_2_pre + wf_2_post else: tau_1_pre = 10**log10_tau_pre_1 * const.day tau_1_post = 10**log10_tau_post_1 * const.day wf_1_pre = 10**log10_Amp_1 * (1 - np.heaviside(toas - t0, 1)) wf_1_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau_1_pre) wf_1_post = 10**log10_Amp_1 * np.heaviside(toas - t0, 1) wf_1_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau_1_post) wf_1 = wf_1_pre + wf_1_post tau_2_pre = 10**log10_tau_pre_2 * const.day tau_2_post = 10**log10_tau_post_2 * const.day wf_2_pre = 10**log10_Amp_2 * (1 - np.heaviside(toas - t0, 1)) wf_2_pre[ind_pre] *= np.exp(- (t0 - toas[ind_pre]) / tau_2_pre) wf_2_post = 10**log10_Amp_2 * np.heaviside(toas - t0, 1) wf_2_post[ind_post] *= np.exp(- (toas[ind_post] - t0) / tau_2_post) wf_2 = wf_2_pre + wf_2_post return np.sign(sign_param) * (wf_1 * (1400 / freqs) ** idx1 + wf_2 * (1400 / freqs) ** idx2) @signal_base.function def chrom_yearly_sinusoid(toas, freqs, log10_Amp=-7, phase=0, idx=2): """ Chromatic annual sinusoid. :param log10_Amp: amplitude of sinusoid :param phase: initial phase of sinusoid :param idx: index of chromatic dependence :return wf: delay time-series [s] """ wf = 10**log10_Amp * np.sin(2 * np.pi * const.fyr * toas + phase) return wf * (1400 / freqs) ** idx @signal_base.function def chromatic_quad_basis(toas, freqs, idx=4): """ Basis for chromatic quadratic function. :param idx: index of chromatic dependence :return ret: normalized quadratic basis matrix [Ntoa, 3] """ ret = np.zeros((len(toas), 3)) t0 = (toas.max() + toas.min()) / 2 for ii in range(3): ret[:, ii] = (toas-t0) ** (ii) * (1400/freqs) ** idx norm = np.sqrt(np.sum(ret**2, axis=0)) return ret/norm, np.ones(3) @signal_base.function def chromatic_quad_prior(toas): """ Prior for chromatic quadratic function. :return prior: prior-range for quadratic coefficients """ return np.ones(3) * 1e80 @signal_base.function def dmx_delay(toas, freqs, dmx_ids, **kwargs): """ Delay in DMX model of DM variations. :param dmx_ids: dictionary of DMX data for each pulsar from parfile :param kwargs: dictionary of enterprise DMX parameters :return wf: DMX signal """ wf = np.zeros(len(toas)) dmx = kwargs for dmx_id in dmx_ids: mask = np.logical_and(toas >= (dmx_ids[dmx_id]['DMX_R1'] - 0.01) * 86400., toas <= (dmx_ids[dmx_id]['DMX_R2'] + 0.01) * 86400.) wf[mask] += dmx[dmx_id] / freqs[mask]**2 / const.DM_K / 1e12 return wf def dm_exponential_dip(tmin, tmax, idx=2, sign='negative', name='dmexp'): """ Returns chromatic exponential dip (i.e. TOA advance): :param tmin, tmax: search window for exponential dip time. :param idx: index of radio frequency dependence (i.e. DM is 2). If this is set to 'vary' then the index will vary from 1 - 6 :param sign: set sign of dip: 'positive', 'negative', or 'vary' :param name: Name of signal :return dmexp: chromatic exponential dip waveform. """ t0_dmexp = parameter.Uniform(tmin, tmax) log10_Amp_dmexp = parameter.Uniform(-10, -2) log10_tau_dmexp = parameter.Uniform(0, 2.5) if sign == 'vary': sign_param = parameter.Uniform(-1.0, 1.0) elif sign == 'positive': sign_param = 1.0 else: sign_param = -1.0 wf = chrom_exp_decay(log10_Amp=log10_Amp_dmexp, t0=t0_dmexp, log10_tau=log10_tau_dmexp, sign_param=sign_param, idx=idx) dmexp = deterministic_signals.Deterministic(wf, name=name) return dmexp def dm_exponential_cusp(tmin, tmax, idx=2, sign='negative', symmetric=False, name='dm_cusp'): """ Returns chromatic exponential cusp (i.e. TOA advance): :param tmin, tmax: search window for exponential cusp time. :param idx: index of radio frequency dependence (i.e. DM is 2). If this is set to 'vary' then the index will vary from 1 - 6 :param sign: set sign of dip: 'positive', 'negative', or 'vary' :param name: Name of signal :return dmexp: chromatic exponential dip waveform. """ t0_dm_cusp = parameter.Uniform(tmin, tmax) log10_Amp_dm_cusp = parameter.Uniform(-10, -2) log10_tau_dm_cusp_pre = parameter.Uniform(0, 2.5) if sign == 'vary': sign_param = parameter.Uniform(-1.0, 1.0) elif sign == 'positive': sign_param = 1.0 else: sign_param = -1.0 if symmetric: log10_tau_dm_cusp_post = 1 else: log10_tau_dm_cusp_post = parameter.Uniform(0, 2.5) wf = chrom_exp_cusp(log10_Amp=log10_Amp_dm_cusp, sign_param=sign_param, t0=t0_dm_cusp, log10_tau_pre=log10_tau_dm_cusp_pre, log10_tau_post=log10_tau_dm_cusp_post, symmetric=symmetric, idx=idx) dm_cusp = deterministic_signals.Deterministic(wf, name=name) return dm_cusp def dm_dual_exp_cusp(tmin, tmax, idx1=2, idx2=4, sign='negative', symmetric=False, name='dual_dm_cusp'): """ Returns chromatic exponential cusp (i.e. TOA advance): :param tmin, tmax: search window for exponential cusp time. :param idx: index of radio frequency dependence (i.e. DM is 2). If this is set to 'vary' then the index will vary from 1 - 6 :param sign: set sign of dip: 'positive', 'negative', or 'vary' :param name: Name of signal :return dmexp: chromatic exponential dip waveform. """ t0_dual_cusp = parameter.Uniform(tmin, tmax) log10_Amp_dual_cusp_1 = parameter.Uniform(-10, -2) log10_Amp_dual_cusp_2 = parameter.Uniform(-10, -2) log10_tau_dual_cusp_pre_1 = parameter.Uniform(0, 2.5) log10_tau_dual_cusp_pre_2 = parameter.Uniform(0, 2.5) if sign == 'vary': sign_param = parameter.Uniform(-1.0, 1.0) elif sign == 'positive': sign_param = 1.0 else: sign_param = -1.0 if symmetric: log10_tau_dual_cusp_post_1 = 1 log10_tau_dual_cusp_post_2 = 1 else: log10_tau_dual_cusp_post_1 = parameter.Uniform(0, 2.5) log10_tau_dual_cusp_post_2 = parameter.Uniform(0, 2.5) wf = chrom_dual_exp_cusp(t0=t0_dual_cusp, sign_param=sign_param, symmetric=symmetric, log10_Amp_1=log10_Amp_dual_cusp_1, log10_tau_pre_1=log10_tau_dual_cusp_pre_1, log10_tau_post_1=log10_tau_dual_cusp_post_1, log10_Amp_2=log10_Amp_dual_cusp_2, log10_tau_pre_2=log10_tau_dual_cusp_pre_2, log10_tau_post_2=log10_tau_dual_cusp_post_2, idx1=idx1, idx2=idx2) dm_cusp = deterministic_signals.Deterministic(wf, name=name) return dm_cusp def dmx_signal(dmx_data, name='dmx_signal'): """ Returns DMX signal: :param dmx_data: dictionary of DMX data for each pulsar from parfile. :param name: Name of signal. :return dmx_sig: dmx signal waveform. """ dmx = {} for dmx_id in sorted(dmx_data): dmx_data_tmp = dmx_data[dmx_id] dmx.update({dmx_id: parameter.Normal(mu=dmx_data_tmp['DMX_VAL'], sigma=dmx_data_tmp['DMX_ERR'])}) wf = dmx_delay(dmx_ids=dmx_data, **dmx) dmx_sig = deterministic_signals.Deterministic(wf, name=name) return dmx_sig def dm_annual_signal(idx=2, name='dm_s1yr'): """ Returns chromatic annual signal (i.e. TOA advance): :param idx: index of radio frequency dependence (i.e. DM is 2). If this is set to 'vary' then the index will vary from 1 - 6 :param name: Name of signal :return dm1yr: chromatic annual waveform. """ log10_Amp_dm1yr = parameter.Uniform(-10, -2) phase_dm1yr = parameter.Uniform(0, 2*np.pi) wf = chrom_yearly_sinusoid(log10_Amp=log10_Amp_dm1yr, phase=phase_dm1yr, idx=idx) dm1yr = deterministic_signals.Deterministic(wf, name=name) return dm1yr

py

enterprise_extensions

enterprise_extensions-master/enterprise_extensions/chromatic/__init__.py

# -*- coding: utf-8 -*- from .chromatic import * # noqa: F401, F403

py