# Copyright (c) Facebook, Inc. and its affiliates. # All rights reserved. # # This source code is licensed under the license found in the # LICENSE file in the root directory of this source tree. from collections import defaultdict from contextlib import contextmanager import math import os import tempfile import typing as tp import errno import functools import hashlib import inspect import io import os import random import socket import tempfile import warnings import zlib import tkinter as tk from diffq import UniformQuantizer, DiffQuantizer import torch as th import tqdm from torch import distributed from torch.nn import functional as F import torch def unfold(a, kernel_size, stride): """Given input of size [*OT, T], output Tensor of size [*OT, F, K] with K the kernel size, by extracting frames with the given stride. This will pad the input so that `F = ceil(T / K)`. see https://github.com/pytorch/pytorch/issues/60466 """ *shape, length = a.shape n_frames = math.ceil(length / stride) tgt_length = (n_frames - 1) * stride + kernel_size a = F.pad(a, (0, tgt_length - length)) strides = list(a.stride()) assert strides[-1] == 1, 'data should be contiguous' strides = strides[:-1] + [stride, 1] return a.as_strided([*shape, n_frames, kernel_size], strides) def center_trim(tensor: torch.Tensor, reference: tp.Union[torch.Tensor, int]): """ Center trim `tensor` with respect to `reference`, along the last dimension. `reference` can also be a number, representing the length to trim to. If the size difference != 0 mod 2, the extra sample is removed on the right side. """ ref_size: int if isinstance(reference, torch.Tensor): ref_size = reference.size(-1) else: ref_size = reference delta = tensor.size(-1) - ref_size if delta < 0: raise ValueError("tensor must be larger than reference. " f"Delta is {delta}.") if delta: tensor = tensor[..., delta // 2:-(delta - delta // 2)] return tensor def pull_metric(history: tp.List[dict], name: str): out = [] for metrics in history: metric = metrics for part in name.split("."): metric = metric[part] out.append(metric) return out def EMA(beta: float = 1): """ Exponential Moving Average callback. Returns a single function that can be called to repeatidly update the EMA with a dict of metrics. The callback will return the new averaged dict of metrics. Note that for `beta=1`, this is just plain averaging. """ fix: tp.Dict[str, float] = defaultdict(float) total: tp.Dict[str, float] = defaultdict(float) def _update(metrics: dict, weight: float = 1) -> dict: nonlocal total, fix for key, value in metrics.items(): total[key] = total[key] * beta + weight * float(value) fix[key] = fix[key] * beta + weight return {key: tot / fix[key] for key, tot in total.items()} return _update def sizeof_fmt(num: float, suffix: str = 'B'): """ Given `num` bytes, return human readable size. Taken from https://stackoverflow.com/a/1094933 """ for unit in ['', 'Ki', 'Mi', 'Gi', 'Ti', 'Pi', 'Ei', 'Zi']: if abs(num) < 1024.0: return "%3.1f%s%s" % (num, unit, suffix) num /= 1024.0 return "%.1f%s%s" % (num, 'Yi', suffix) @contextmanager def temp_filenames(count: int, delete=True): names = [] try: for _ in range(count): names.append(tempfile.NamedTemporaryFile(delete=False).name) yield names finally: if delete: for name in names: os.unlink(name) def average_metric(metric, count=1.): """ Average `metric` which should be a float across all hosts. `count` should be the weight for this particular host (i.e. number of examples). """ metric = th.tensor([count, count * metric], dtype=th.float32, device='cuda') distributed.all_reduce(metric, op=distributed.ReduceOp.SUM) return metric[1].item() / metric[0].item() def free_port(host='', low=20000, high=40000): """ Return a port number that is most likely free. This could suffer from a race condition although it should be quite rare. """ sock = socket.socket() while True: port = random.randint(low, high) try: sock.bind((host, port)) except OSError as error: if error.errno == errno.EADDRINUSE: continue raise return port def sizeof_fmt(num, suffix='B'): """ Given `num` bytes, return human readable size. Taken from https://stackoverflow.com/a/1094933 """ for unit in ['', 'Ki', 'Mi', 'Gi', 'Ti', 'Pi', 'Ei', 'Zi']: if abs(num) < 1024.0: return "%3.1f%s%s" % (num, unit, suffix) num /= 1024.0 return "%.1f%s%s" % (num, 'Yi', suffix) def human_seconds(seconds, display='.2f'): """ Given `seconds` seconds, return human readable duration. """ value = seconds * 1e6 ratios = [1e3, 1e3, 60, 60, 24] names = ['us', 'ms', 's', 'min', 'hrs', 'days'] last = names.pop(0) for name, ratio in zip(names, ratios): if value / ratio < 0.3: break value /= ratio last = name return f"{format(value, display)} {last}" class TensorChunk: def __init__(self, tensor, offset=0, length=None): total_length = tensor.shape[-1] assert offset >= 0 assert offset < total_length if length is None: length = total_length - offset else: length = min(total_length - offset, length) self.tensor = tensor self.offset = offset self.length = length self.device = tensor.device @property def shape(self): shape = list(self.tensor.shape) shape[-1] = self.length return shape def padded(self, target_length): delta = target_length - self.length total_length = self.tensor.shape[-1] assert delta >= 0 start = self.offset - delta // 2 end = start + target_length correct_start = max(0, start) correct_end = min(total_length, end) pad_left = correct_start - start pad_right = end - correct_end out = F.pad(self.tensor[..., correct_start:correct_end], (pad_left, pad_right)) assert out.shape[-1] == target_length return out def tensor_chunk(tensor_or_chunk): if isinstance(tensor_or_chunk, TensorChunk): return tensor_or_chunk else: assert isinstance(tensor_or_chunk, th.Tensor) return TensorChunk(tensor_or_chunk) def apply_model_v1(model, mix, shifts=None, split=False, progress=False, set_progress_bar=None): """ Apply model to a given mixture. Args: shifts (int): if > 0, will shift in time `mix` by a random amount between 0 and 0.5 sec and apply the oppositve shift to the output. This is repeated `shifts` time and all predictions are averaged. This effectively makes the model time equivariant and improves SDR by up to 0.2 points. split (bool): if True, the input will be broken down in 8 seconds extracts and predictions will be performed individually on each and concatenated. Useful for model with large memory footprint like Tasnet. progress (bool): if True, show a progress bar (requires split=True) """ channels, length = mix.size() device = mix.device progress_value = 0 if split: out = th.zeros(4, channels, length, device=device) shift = model.samplerate * 10 offsets = range(0, length, shift) scale = 10 if progress: offsets = tqdm.tqdm(offsets, unit_scale=scale, ncols=120, unit='seconds') for offset in offsets: chunk = mix[..., offset:offset + shift] if set_progress_bar: progress_value += 1 set_progress_bar(0.1, (0.8/len(offsets)*progress_value)) chunk_out = apply_model_v1(model, chunk, shifts=shifts, set_progress_bar=set_progress_bar) else: chunk_out = apply_model_v1(model, chunk, shifts=shifts) out[..., offset:offset + shift] = chunk_out offset += shift return out elif shifts: max_shift = int(model.samplerate / 2) mix = F.pad(mix, (max_shift, max_shift)) offsets = list(range(max_shift)) random.shuffle(offsets) out = 0 for offset in offsets[:shifts]: shifted = mix[..., offset:offset + length + max_shift] if set_progress_bar: shifted_out = apply_model_v1(model, shifted, set_progress_bar=set_progress_bar) else: shifted_out = apply_model_v1(model, shifted) out += shifted_out[..., max_shift - offset:max_shift - offset + length] out /= shifts return out else: valid_length = model.valid_length(length) delta = valid_length - length padded = F.pad(mix, (delta // 2, delta - delta // 2)) with th.no_grad(): out = model(padded.unsqueeze(0))[0] return center_trim(out, mix) def apply_model_v2(model, mix, shifts=None, split=False, overlap=0.25, transition_power=1., progress=False, set_progress_bar=None): """ Apply model to a given mixture. Args: shifts (int): if > 0, will shift in time `mix` by a random amount between 0 and 0.5 sec and apply the oppositve shift to the output. This is repeated `shifts` time and all predictions are averaged. This effectively makes the model time equivariant and improves SDR by up to 0.2 points. split (bool): if True, the input will be broken down in 8 seconds extracts and predictions will be performed individually on each and concatenated. Useful for model with large memory footprint like Tasnet. progress (bool): if True, show a progress bar (requires split=True) """ assert transition_power >= 1, "transition_power < 1 leads to weird behavior." device = mix.device channels, length = mix.shape progress_value = 0 if split: out = th.zeros(len(model.sources), channels, length, device=device) sum_weight = th.zeros(length, device=device) segment = model.segment_length stride = int((1 - overlap) * segment) offsets = range(0, length, stride) scale = stride / model.samplerate if progress: offsets = tqdm.tqdm(offsets, unit_scale=scale, ncols=120, unit='seconds') # We start from a triangle shaped weight, with maximal weight in the middle # of the segment. Then we normalize and take to the power `transition_power`. # Large values of transition power will lead to sharper transitions. weight = th.cat([th.arange(1, segment // 2 + 1), th.arange(segment - segment // 2, 0, -1)]).to(device) assert len(weight) == segment # If the overlap < 50%, this will translate to linear transition when # transition_power is 1. weight = (weight / weight.max())**transition_power for offset in offsets: chunk = TensorChunk(mix, offset, segment) if set_progress_bar: progress_value += 1 set_progress_bar(0.1, (0.8/len(offsets)*progress_value)) chunk_out = apply_model_v2(model, chunk, shifts=shifts, set_progress_bar=set_progress_bar) else: chunk_out = apply_model_v2(model, chunk, shifts=shifts) chunk_length = chunk_out.shape[-1] out[..., offset:offset + segment] += weight[:chunk_length] * chunk_out sum_weight[offset:offset + segment] += weight[:chunk_length] offset += segment assert sum_weight.min() > 0 out /= sum_weight return out elif shifts: max_shift = int(0.5 * model.samplerate) mix = tensor_chunk(mix) padded_mix = mix.padded(length + 2 * max_shift) out = 0 for _ in range(shifts): offset = random.randint(0, max_shift) shifted = TensorChunk(padded_mix, offset, length + max_shift - offset) if set_progress_bar: progress_value += 1 shifted_out = apply_model_v2(model, shifted, set_progress_bar=set_progress_bar) else: shifted_out = apply_model_v2(model, shifted) out += shifted_out[..., max_shift - offset:] out /= shifts return out else: valid_length = model.valid_length(length) mix = tensor_chunk(mix) padded_mix = mix.padded(valid_length) with th.no_grad(): out = model(padded_mix.unsqueeze(0))[0] return center_trim(out, length) @contextmanager def temp_filenames(count, delete=True): names = [] try: for _ in range(count): names.append(tempfile.NamedTemporaryFile(delete=False).name) yield names finally: if delete: for name in names: os.unlink(name) def get_quantizer(model, args, optimizer=None): quantizer = None if args.diffq: quantizer = DiffQuantizer( model, min_size=args.q_min_size, group_size=8) if optimizer is not None: quantizer.setup_optimizer(optimizer) elif args.qat: quantizer = UniformQuantizer( model, bits=args.qat, min_size=args.q_min_size) return quantizer def load_model(path, strict=False): with warnings.catch_warnings(): warnings.simplefilter("ignore") load_from = path package = th.load(load_from, 'cpu') klass = package["klass"] args = package["args"] kwargs = package["kwargs"] if strict: model = klass(*args, **kwargs) else: sig = inspect.signature(klass) for key in list(kwargs): if key not in sig.parameters: warnings.warn("Dropping inexistant parameter " + key) del kwargs[key] model = klass(*args, **kwargs) state = package["state"] training_args = package["training_args"] quantizer = get_quantizer(model, training_args) set_state(model, quantizer, state) return model def get_state(model, quantizer): if quantizer is None: state = {k: p.data.to('cpu') for k, p in model.state_dict().items()} else: state = quantizer.get_quantized_state() buf = io.BytesIO() th.save(state, buf) state = {'compressed': zlib.compress(buf.getvalue())} return state def set_state(model, quantizer, state): if quantizer is None: model.load_state_dict(state) else: buf = io.BytesIO(zlib.decompress(state["compressed"])) state = th.load(buf, "cpu") quantizer.restore_quantized_state(state) return state def save_state(state, path): buf = io.BytesIO() th.save(state, buf) sig = hashlib.sha256(buf.getvalue()).hexdigest()[:8] path = path.parent / (path.stem + "-" + sig + path.suffix) path.write_bytes(buf.getvalue()) def save_model(model, quantizer, training_args, path): args, kwargs = model._init_args_kwargs klass = model.__class__ state = get_state(model, quantizer) save_to = path package = { 'klass': klass, 'args': args, 'kwargs': kwargs, 'state': state, 'training_args': training_args, } th.save(package, save_to) def capture_init(init): @functools.wraps(init) def __init__(self, *args, **kwargs): self._init_args_kwargs = (args, kwargs) init(self, *args, **kwargs) return __init__ class DummyPoolExecutor: class DummyResult: def __init__(self, func, *args, **kwargs): self.func = func self.args = args self.kwargs = kwargs def result(self): return self.func(*self.args, **self.kwargs) def __init__(self, workers=0): pass def submit(self, func, *args, **kwargs): return DummyPoolExecutor.DummyResult(func, *args, **kwargs) def __enter__(self): return self def __exit__(self, exc_type, exc_value, exc_tb): return