import os import sys import numpy as np import argparse import h5py import time import pickle import matplotlib.pyplot as plt import csv from sklearn import metrics from utilities import (create_folder, get_filename, d_prime) import config def load_statistics(statistics_path): statistics_dict = pickle.load(open(statistics_path, 'rb')) bal_map = np.array([statistics['average_precision'] for statistics in statistics_dict['bal']]) # (N, classes_num) bal_map = np.mean(bal_map, axis=-1) test_map = np.array([statistics['average_precision'] for statistics in statistics_dict['test']]) # (N, classes_num) test_map = np.mean(test_map, axis=-1) return bal_map, test_map def crop_label(label): max_len = 16 if len(label) <= max_len: return label else: words = label.split(' ') cropped_label = '' for w in words: if len(cropped_label + ' ' + w) > max_len: break else: cropped_label += ' {}'.format(w) return cropped_label def add_comma(integer): """E.g., 1234567 -> 1,234,567 """ integer = int(integer) if integer >= 1000: return str(integer // 1000) + ',' + str(integer % 1000) else: return str(integer) def plot_classwise_iteration_map(args): # Paths save_out_path = 'results/classwise_iteration_map.pdf' create_folder(os.path.dirname(save_out_path)) # Load statistics statistics_dict = pickle.load(open('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_WavegramLogmelCnn_balanced_mixup_bs32.pkl', 'rb')) mAP_mat = np.array([e['average_precision'] for e in statistics_dict['test']]) mAP_mat = mAP_mat[0 : 300, :] # 300 * 2000 = 600k iterations sorted_indexes = np.argsort(config.full_samples_per_class)[::-1] fig, axs = plt.subplots(1, 3, figsize=(20, 5)) ranges = [np.arange(0, 10), np.arange(250, 260), np.arange(517, 527)] axs[0].set_ylabel('AP') for col in range(0, 3): axs[col].set_ylim(0, 1.) axs[col].set_xlim(0, 301) axs[col].set_xlabel('Iterations') axs[col].set_ylabel('AP') axs[col].xaxis.set_ticks(np.arange(0, 301, 100)) axs[col].xaxis.set_ticklabels(['0', '200k', '400k', '600k']) lines = [] for _ix in ranges[col]: _label = crop_label(config.labels[sorted_indexes[_ix]]) + \ ' ({})'.format(add_comma(config.full_samples_per_class[sorted_indexes[_ix]])) line, = axs[col].plot(mAP_mat[:, sorted_indexes[_ix]], label=_label) lines.append(line) box = axs[col].get_position() axs[col].set_position([box.x0, box.y0, box.width * 1., box.height]) axs[col].legend(handles=lines, bbox_to_anchor=(1., 1.)) axs[col].yaxis.grid(color='k', linestyle='solid', alpha=0.3, linewidth=0.3) plt.tight_layout(pad=4, w_pad=1, h_pad=1) plt.savefig(save_out_path) print(save_out_path) def plot_six_figures(args): # Arguments & parameters classes_num = config.classes_num labels = config.labels max_plot_iteration = 540000 iterations = np.arange(0, max_plot_iteration, 2000) # Paths class_labels_indices_path = os.path.join('metadata', 'class_labels_indices.csv') save_out_path = 'results/six_figures.pdf' create_folder(os.path.dirname(save_out_path)) # Plot fig, ax = plt.subplots(2, 3, figsize=(14, 7)) bal_alpha = 0.3 test_alpha = 1.0 linewidth = 1. # (a) Comparison of architectures if True: lines = [] # Wavegram-Logmel-CNN (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_WavegramLogmelCnn_balanced_mixup_bs32.pkl') line, = ax[0, 0].plot(bal_map, color='g', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 0].plot(test_map, label='Wavegram-Logmel-CNN', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Cnn14 (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[0, 0].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 0].plot(test_map, label='CNN14', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # MobileNetV1 (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_MobileNetV1_balanced_mixup_bs32.pkl') line, = ax[0, 0].plot(bal_map, color='b', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 0].plot(test_map, label='MobileNetV1', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[0, 0].legend(handles=lines, loc=2) ax[0, 0].set_title('(a) Comparison of architectures') # (b) Comparison of training data and augmentation' if True: lines = [] # Full data + balanced sampler + mixup (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,bal,mixup (1.9m)', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Full data + balanced sampler + mixup in time domain (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_timedomain_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='y', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,bal,mixup-wav (1.9m)', color='y', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Full data + balanced sampler + no mixup (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_nomixup_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='g', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,bal,no-mixup (1.9m)', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Full data + uniform sampler + no mixup (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_nobalanced_nomixup_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='b', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,no-bal,no-mixup (1.9m)', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Balanced data + balanced sampler + mixup (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_balanced_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='m', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,bal,mixup (20k)', color='m', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Balanced data + balanced sampler + no mixup (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_balanced_train_Cnn14_balanced_nomixup_bs32.pkl') line, = ax[0, 1].plot(bal_map, color='k', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 1].plot(test_map, label='CNN14,bal,no-mixup (20k)', color='k', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[0, 1].legend(handles=lines, loc=2, fontsize=8) ax[0, 1].set_title('(b) Comparison of training data and augmentation') # (c) Comparison of embedding size if True: lines = [] # Embedding size 2048 (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[0, 2].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 2].plot(test_map, label='CNN14,emb=2048', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Embedding size 128 (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_emb128_balanced_mixup_bs32.pkl') line, = ax[0, 2].plot(bal_map, color='g', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 2].plot(test_map, label='CNN14,emb=128', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Embedding size 32 (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_emb32_balanced_mixup_bs32.pkl') line, = ax[0, 2].plot(bal_map, color='b', alpha=bal_alpha, linewidth=linewidth) line, = ax[0, 2].plot(test_map, label='CNN14,emb=32', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[0, 2].legend(handles=lines, loc=2) ax[0, 2].set_title('(c) Comparison of embedding size') # (d) Comparison of amount of training data if True: lines = [] # 100% of full training data (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 0].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 0].plot(test_map, label='CNN14 (100% full)', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # 80% of full training data (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_0.8full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 0].plot(bal_map, color='b', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 0].plot(test_map, label='CNN14 (80% full)', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) # 50% of full training data (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_0.5full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 0].plot(bal_map, color='g', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 0].plot(test_map, label='cnn14 (50% full)', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[1, 0].legend(handles=lines, loc=2) ax[1, 0].set_title('(d) Comparison of amount of training data') # (e) Comparison of sampling rate if True: lines = [] # Cnn14 + 32 kHz (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 1].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 1].plot(test_map, label='CNN14,32kHz', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Cnn14 + 16 kHz (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_16k_balanced_mixup_bs32.pkl') line, = ax[1, 1].plot(bal_map, color='b', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 1].plot(test_map, label='CNN14,16kHz', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Cnn14 + 8 kHz (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_8k_balanced_mixup_bs32.pkl') line, = ax[1, 1].plot(bal_map, color='g', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 1].plot(test_map, label='CNN14,8kHz', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[1, 1].legend(handles=lines, loc=2) ax[1, 1].set_title('(e) Comparison of sampling rate') # (f) Comparison of mel bins number if True: lines = [] # Cnn14 + 128 mel bins (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel128_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 2].plot(bal_map, color='g', alpha=bal_alpha) line, = ax[1, 2].plot(test_map, label='CNN14,128-melbins', color='g', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Cnn14 + 64 mel bins (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel64_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 2].plot(bal_map, color='r', alpha=bal_alpha, linewidth=linewidth) line, = ax[1, 2].plot(test_map, label='CNN14,64-melbins', color='r', alpha=test_alpha, linewidth=linewidth) lines.append(line) # Cnn14 + 32 mel bins (bal_map, test_map) = load_statistics('paper_statistics/statistics_sr32000_window1024_hop320_mel32_fmin50_fmax14000_full_train_Cnn14_balanced_mixup_bs32.pkl') line, = ax[1, 2].plot(bal_map, color='b', alpha=bal_alpha) line, = ax[1, 2].plot(test_map, label='CNN14,32-melbins', color='b', alpha=test_alpha, linewidth=linewidth) lines.append(line) ax[1, 2].legend(handles=lines, loc=2) ax[1, 2].set_title('(f) Comparison of mel bins number') for i in range(2): for j in range(3): ax[i, j].set_ylim(0, 0.8) ax[i, j].set_xlim(0, len(iterations)) ax[i, j].set_xlabel('Iterations') ax[i, j].set_ylabel('mAP') ax[i, j].xaxis.set_ticks(np.arange(0, len(iterations), 50)) ax[i, j].xaxis.set_ticklabels(['0', '100k', '200k', '300k', '400k', '500k']) ax[i, j].yaxis.set_ticks(np.arange(0, 0.81, 0.05)) ax[i, j].yaxis.set_ticklabels(['0', '', '0.1', '', '0.2', '', '0.3', '', '0.4', '', '0.5', '', '0.6', '', '0.7', '', '0.8']) ax[i, j].yaxis.grid(color='k', linestyle='solid', alpha=0.3, linewidth=0.3) ax[i, j].xaxis.grid(color='k', linestyle='solid', alpha=0.3, linewidth=0.3) plt.tight_layout(0, 1, 0) plt.savefig(save_out_path) print('Save figure to {}'.format(save_out_path)) def plot_complexity_map(args): # Paths save_out_path = 'results/complexity_mAP.pdf' create_folder(os.path.dirname(save_out_path)) plt.figure(figsize=(5, 5)) fig, ax = plt.subplots(1, 1) model_types = np.array(['Cnn6', 'Cnn10', 'Cnn14', 'ResNet22', 'ResNet38', 'ResNet54', 'MobileNetV1', 'MobileNetV2', 'DaiNet', 'LeeNet', 'LeeNet18', 'Res1dNet30', 'Res1dNet44', 'Wavegram-CNN', 'Wavegram-\nLogmel-CNN']) flops = np.array([21.986, 28.166, 42.220, 30.081, 48.962, 54.563, 3.614, 2.810, 30.395, 4.741, 26.369, 32.688, 61.833, 44.234, 53.510]) mAPs = np.array([0.343, 0.380, 0.431, 0.430, 0.434, 0.429, 0.389, 0.383, 0.295, 0.266, 0.336, 0.365, 0.355, 0.389, 0.439]) sorted_indexes = np.sort(flops) ax.scatter(flops, mAPs) shift = [[-5.5, -0.004], [1, -0.004], [-1, -0.014], [-2, 0.006], [-7, 0.006], [1, -0.01], [0.5, 0.004], [-1, -0.014], [1, -0.007], [0.8, -0.008], [1, -0.007], [1, 0.002], [-6, -0.015], [1, -0.008], [0.8, 0]] for i, model_type in enumerate(model_types): ax.annotate(model_type, (flops[i] + shift[i][0], mAPs[i] + shift[i][1])) ax.plot(flops[[0, 1, 2]], mAPs[[0, 1, 2]]) ax.plot(flops[[3, 4, 5]], mAPs[[3, 4, 5]]) ax.plot(flops[[6, 7]], mAPs[[6, 7]]) ax.plot(flops[[9, 10]], mAPs[[9, 10]]) ax.plot(flops[[11, 12]], mAPs[[11, 12]]) ax.plot(flops[[13, 14]], mAPs[[13, 14]]) ax.set_xlim(0, 70) ax.set_ylim(0.2, 0.5) ax.set_xlabel('Multi-load_statisticss (million)', fontsize=15) ax.set_ylabel('mAP', fontsize=15) ax.tick_params(axis='x', labelsize=12) ax.tick_params(axis='y', labelsize=12) plt.tight_layout(0, 0, 0) plt.savefig(save_out_path) print('Write out figure to {}'.format(save_out_path)) def plot_long_fig(args): # Paths stats = pickle.load(open('paper_statistics/stats_for_long_fig.pkl', 'rb')) save_out_path = 'results/long_fig.pdf' create_folder(os.path.dirname(save_out_path)) # Load meta N = len(config.labels) sorted_indexes = stats['sorted_indexes_for_plot'] sorted_labels = np.array(config.labels)[sorted_indexes] audio_clips_per_class = stats['official_balanced_training_samples'] + stats['official_unbalanced_training_samples'] audio_clips_per_class = audio_clips_per_class[sorted_indexes] # Prepare axes for plot (ax1a, ax2a, ax3a, ax4a, ax1b, ax2b, ax3b, ax4b) = prepare_plot_long_4_rows(sorted_labels) # plot the number of training samples ax1a.bar(np.arange(N), audio_clips_per_class, alpha=0.3) ax2a.bar(np.arange(N), audio_clips_per_class, alpha=0.3) ax3a.bar(np.arange(N), audio_clips_per_class, alpha=0.3) ax4a.bar(np.arange(N), audio_clips_per_class, alpha=0.3) # Load mAP of different systems """Average instance system of [1] with an mAP of 0.317. [1] Kong, Qiuqiang, Changsong Yu, Yong Xu, Turab Iqbal, Wenwu Wang, and Mark D. Plumbley. "Weakly labelled audioset tagging with attention neural networks." IEEE/ACM Transactions on Audio, Speech, and Language Processing 27, no. 11 (2019): 1791-1802.""" maps_avg_instances = stats['averaging_instance_system_avg_9_probs_from_10000_to_50000_iterations']['eval']['average_precision'] maps_avg_instances = maps_avg_instances[sorted_indexes] # PANNs Cnn14 maps_panns_cnn14 = stats['panns_cnn14']['eval']['average_precision'] maps_panns_cnn14 = maps_panns_cnn14[sorted_indexes] # PANNs MobileNetV1 maps_panns_mobilenetv1 = stats['panns_mobilenetv1']['eval']['average_precision'] maps_panns_mobilenetv1 = maps_panns_mobilenetv1[sorted_indexes] # PANNs Wavegram-Logmel-Cnn14 maps_panns_wavegram_logmel_cnn14 = stats['panns_wavegram_logmel_cnn14']['eval']['average_precision'] maps_panns_wavegram_logmel_cnn14 = maps_panns_wavegram_logmel_cnn14[sorted_indexes] # Plot mAPs _scatter_4_rows(maps_panns_wavegram_logmel_cnn14, ax1b, ax2b, ax3b, ax4b, s=5, c='g') _scatter_4_rows(maps_panns_cnn14, ax1b, ax2b, ax3b, ax4b, s=5, c='r') _scatter_4_rows(maps_panns_mobilenetv1, ax1b, ax2b, ax3b, ax4b, s=5, c='b') _scatter_4_rows(maps_avg_instances, ax1b, ax2b, ax3b, ax4b, s=5, c='k') linewidth = 0.7 line0te = _plot_4_rows(maps_panns_wavegram_logmel_cnn14, ax1b, ax2b, ax3b, ax4b, c='g', linewidth=linewidth, label='AP with Wavegram-Logmel-CNN') line1te = _plot_4_rows(maps_panns_cnn14, ax1b, ax2b, ax3b, ax4b, c='r', linewidth=linewidth, label='AP with CNN14') line2te = _plot_4_rows(maps_panns_mobilenetv1, ax1b, ax2b, ax3b, ax4b, c='b', linewidth=linewidth, label='AP with MobileNetV1') line3te = _plot_4_rows(maps_avg_instances, ax1b, ax2b, ax3b, ax4b, c='k', linewidth=linewidth, label='AP with averaging instances (baseline)') # Plot label quality label_quality = stats['label_quality'] sorted_label_quality = np.array(label_quality)[sorted_indexes] for k in range(len(sorted_label_quality)): if sorted_label_quality[k] and sorted_label_quality[k] == 1: sorted_label_quality[k] = 0.99 ax1b.scatter(np.arange(N)[sorted_label_quality != None], sorted_label_quality[sorted_label_quality != None], s=12, c='r', linewidth=0.8, marker='+') ax2b.scatter(np.arange(N)[sorted_label_quality != None], sorted_label_quality[sorted_label_quality != None], s=12, c='r', linewidth=0.8, marker='+') ax3b.scatter(np.arange(N)[sorted_label_quality != None], sorted_label_quality[sorted_label_quality != None], s=12, c='r', linewidth=0.8, marker='+') line_label_quality = ax4b.scatter(np.arange(N)[sorted_label_quality != None], sorted_label_quality[sorted_label_quality != None], s=12, c='r', linewidth=0.8, marker='+', label='Label quality') ax1b.scatter(np.arange(N)[sorted_label_quality == None], 0.5 * np.ones(len(np.arange(N)[sorted_label_quality == None])), s=12, c='r', linewidth=0.8, marker='_') ax2b.scatter(np.arange(N)[sorted_label_quality == None], 0.5 * np.ones(len(np.arange(N)[sorted_label_quality == None])), s=12, c='r', linewidth=0.8, marker='_') ax3b.scatter(np.arange(N)[sorted_label_quality == None], 0.5 * np.ones(len(np.arange(N)[sorted_label_quality == None])), s=12, c='r', linewidth=0.8, marker='_') ax4b.scatter(np.arange(N)[sorted_label_quality == None], 0.5 * np.ones(len(np.arange(N)[sorted_label_quality == None])), s=12, c='r', linewidth=0.8, marker='_') plt.legend(handles=[line0te, line1te, line2te, line3te, line_label_quality], fontsize=6, loc=1) plt.tight_layout(0, 0, 0) plt.savefig(save_out_path) print('Save fig to {}'.format(save_out_path)) def prepare_plot_long_4_rows(sorted_lbs): N = len(sorted_lbs) f,(ax1a, ax2a, ax3a, ax4a) = plt.subplots(4, 1, sharey=False, facecolor='w', figsize=(10, 10.5)) fontsize = 5 K = 132 ax1a.set_xlim(0, K) ax2a.set_xlim(K, 2 * K) ax3a.set_xlim(2 * K, 3 * K) ax4a.set_xlim(3 * K, N) truncated_sorted_lbs = [] for lb in sorted_lbs: lb = lb[0 : 25] words = lb.split(' ') if len(words[-1]) < 3: lb = ' '.join(words[0:-1]) truncated_sorted_lbs.append(lb) ax1a.grid(which='major', axis='x', linestyle='-', alpha=0.3) ax2a.grid(which='major', axis='x', linestyle='-', alpha=0.3) ax3a.grid(which='major', axis='x', linestyle='-', alpha=0.3) ax4a.grid(which='major', axis='x', linestyle='-', alpha=0.3) ax1a.set_yscale('log') ax2a.set_yscale('log') ax3a.set_yscale('log') ax4a.set_yscale('log') ax1b = ax1a.twinx() ax2b = ax2a.twinx() ax3b = ax3a.twinx() ax4b = ax4a.twinx() ax1b.set_ylim(0., 1.) ax2b.set_ylim(0., 1.) ax3b.set_ylim(0., 1.) ax4b.set_ylim(0., 1.) ax1b.set_ylabel('Average precision') ax2b.set_ylabel('Average precision') ax3b.set_ylabel('Average precision') ax4b.set_ylabel('Average precision') ax1b.yaxis.grid(color='grey', linestyle='--', alpha=0.5) ax2b.yaxis.grid(color='grey', linestyle='--', alpha=0.5) ax3b.yaxis.grid(color='grey', linestyle='--', alpha=0.5) ax4b.yaxis.grid(color='grey', linestyle='--', alpha=0.5) ax1a.xaxis.set_ticks(np.arange(K)) ax1a.xaxis.set_ticklabels(truncated_sorted_lbs[0:K], rotation=90, fontsize=fontsize) ax1a.xaxis.tick_bottom() ax1a.set_ylabel("Number of audio clips") ax2a.xaxis.set_ticks(np.arange(K, 2*K)) ax2a.xaxis.set_ticklabels(truncated_sorted_lbs[K:2*K], rotation=90, fontsize=fontsize) ax2a.xaxis.tick_bottom() ax2a.set_ylabel("Number of audio clips") ax3a.xaxis.set_ticks(np.arange(2*K, 3*K)) ax3a.xaxis.set_ticklabels(truncated_sorted_lbs[2*K:3*K], rotation=90, fontsize=fontsize) ax3a.xaxis.tick_bottom() ax3a.set_ylabel("Number of audio clips") ax4a.xaxis.set_ticks(np.arange(3*K, N)) ax4a.xaxis.set_ticklabels(truncated_sorted_lbs[3*K:], rotation=90, fontsize=fontsize) ax4a.xaxis.tick_bottom() ax4a.set_ylabel("Number of audio clips") ax1a.spines['right'].set_visible(False) ax1b.spines['right'].set_visible(False) ax2a.spines['left'].set_visible(False) ax2b.spines['left'].set_visible(False) ax2a.spines['right'].set_visible(False) ax2b.spines['right'].set_visible(False) ax3a.spines['left'].set_visible(False) ax3b.spines['left'].set_visible(False) ax3a.spines['right'].set_visible(False) ax3b.spines['right'].set_visible(False) ax4a.spines['left'].set_visible(False) ax4b.spines['left'].set_visible(False) plt.subplots_adjust(hspace = 0.8) return ax1a, ax2a, ax3a, ax4a, ax1b, ax2b, ax3b, ax4b def _scatter_4_rows(x, ax, ax2, ax3, ax4, s, c, marker='.', alpha=1.): N = len(x) ax.scatter(np.arange(N), x, s=s, c=c, marker=marker, alpha=alpha) ax2.scatter(np.arange(N), x, s=s, c=c, marker=marker, alpha=alpha) ax3.scatter(np.arange(N), x, s=s, c=c, marker=marker, alpha=alpha) ax4.scatter(np.arange(N), x, s=s, c=c, marker=marker, alpha=alpha) def _plot_4_rows(x, ax, ax2, ax3, ax4, c, linewidth=1.0, alpha=1.0, label=""): N = len(x) ax.plot(x, c=c, linewidth=linewidth, alpha=alpha) ax2.plot(x, c=c, linewidth=linewidth, alpha=alpha) ax3.plot(x, c=c, linewidth=linewidth, alpha=alpha) line, = ax4.plot(x, c=c, linewidth=linewidth, alpha=alpha, label=label) return line if __name__ == '__main__': parser = argparse.ArgumentParser(description='') subparsers = parser.add_subparsers(dest='mode') parser_classwise_iteration_map = subparsers.add_parser('plot_classwise_iteration_map') parser_six_figures = subparsers.add_parser('plot_six_figures') parser_complexity_map = subparsers.add_parser('plot_complexity_map') parser_long_fig = subparsers.add_parser('plot_long_fig') args = parser.parse_args() if args.mode == 'plot_classwise_iteration_map': plot_classwise_iteration_map(args) elif args.mode == 'plot_six_figures': plot_six_figures(args) elif args.mode == 'plot_complexity_map': plot_complexity_map(args) elif args.mode == 'plot_long_fig': plot_long_fig(args) else: raise Exception('Incorrect argument!')