MockingBird/vocoder/hifigan/train.py

import warnings
warnings.simplefilter(action='ignore', category=FutureWarning)
import itertools
import os
import time
import argparse
import json
import torch
import torch.nn.functional as F
from torch.utils.tensorboard import SummaryWriter
from torch.utils.data import DistributedSampler, DataLoader
import torch.multiprocessing as mp
from torch.distributed import init_process_group
from torch.nn.parallel import DistributedDataParallel
from vocoder.hifigan.env import AttrDict, build_env
from vocoder.hifigan.meldataset import MelDataset, mel_spectrogram, get_dataset_filelist
from vocoder.hifigan.models import Generator, MultiPeriodDiscriminator, MultiScaleDiscriminator, feature_loss, generator_loss,\
    discriminator_loss
from vocoder.hifigan.utils import plot_spectrogram, scan_checkpoint, load_checkpoint, save_checkpoint

torch.backends.cudnn.benchmark = True


def train(rank, a, h):

    a.checkpoint_path = a.models_dir.joinpath(a.run_id+'_hifigan')
    a.checkpoint_path.mkdir(exist_ok=True)
    a.training_epochs = 3100
    a.stdout_interval = 5
    a.checkpoint_interval = 25000
    a.summary_interval = 5000
    a.validation_interval = 1000
    a.fine_tuning = True

    a.input_wavs_dir = a.syn_dir.joinpath("audio")
    a.input_mels_dir = a.syn_dir.joinpath("mels")

    if h.num_gpus > 1:
        init_process_group(backend=h.dist_config['dist_backend'], init_method=h.dist_config['dist_url'],
                           world_size=h.dist_config['world_size'] * h.num_gpus, rank=rank)

    torch.cuda.manual_seed(h.seed)
    device = torch.device('cuda:{:d}'.format(rank))

    generator = Generator(h).to(device)
    mpd = MultiPeriodDiscriminator().to(device)
    msd = MultiScaleDiscriminator().to(device)

    if rank == 0:
        print(generator)
        os.makedirs(a.checkpoint_path, exist_ok=True)
        print("checkpoints directory : ", a.checkpoint_path)

    if os.path.isdir(a.checkpoint_path):
        cp_g = scan_checkpoint(a.checkpoint_path, 'g_')
        cp_do = scan_checkpoint(a.checkpoint_path, 'do_')

    steps = 0
    if cp_g is None or cp_do is None:
        state_dict_do = None
        last_epoch = -1
    else:
        state_dict_g = load_checkpoint(cp_g, device)
        state_dict_do = load_checkpoint(cp_do, device)
        generator.load_state_dict(state_dict_g['generator'])
        mpd.load_state_dict(state_dict_do['mpd'])
        msd.load_state_dict(state_dict_do['msd'])
        steps = state_dict_do['steps'] + 1
        last_epoch = state_dict_do['epoch']

    if h.num_gpus > 1:
        generator = DistributedDataParallel(generator, device_ids=[rank]).to(device)
        mpd = DistributedDataParallel(mpd, device_ids=[rank]).to(device)
        msd = DistributedDataParallel(msd, device_ids=[rank]).to(device)

    optim_g = torch.optim.AdamW(generator.parameters(), h.learning_rate, betas=[h.adam_b1, h.adam_b2])
    optim_d = torch.optim.AdamW(itertools.chain(msd.parameters(), mpd.parameters()),
                                h.learning_rate, betas=[h.adam_b1, h.adam_b2])

    if state_dict_do is not None:
        optim_g.load_state_dict(state_dict_do['optim_g'])
        optim_d.load_state_dict(state_dict_do['optim_d'])

    scheduler_g = torch.optim.lr_scheduler.ExponentialLR(optim_g, gamma=h.lr_decay, last_epoch=last_epoch)
    scheduler_d = torch.optim.lr_scheduler.ExponentialLR(optim_d, gamma=h.lr_decay, last_epoch=last_epoch)

    training_filelist, validation_filelist = get_dataset_filelist(a)

    # print(training_filelist)
    # exit()

    trainset = MelDataset(training_filelist, h.segment_size, h.n_fft, h.num_mels,
                          h.hop_size, h.win_size, h.sampling_rate, h.fmin, h.fmax, n_cache_reuse=0,
                          shuffle=False if h.num_gpus > 1 else True, fmax_loss=h.fmax_for_loss, device=device,
                          fine_tuning=a.fine_tuning, base_mels_path=a.input_mels_dir)

    train_sampler = DistributedSampler(trainset) if h.num_gpus > 1 else None

    train_loader = DataLoader(trainset, num_workers=h.num_workers, shuffle=False,
                              sampler=train_sampler,
                              batch_size=h.batch_size,
                              pin_memory=True,
                              drop_last=True)

    if rank == 0:
        validset = MelDataset(validation_filelist, h.segment_size, h.n_fft, h.num_mels,
                              h.hop_size, h.win_size, h.sampling_rate, h.fmin, h.fmax, False, False, n_cache_reuse=0,
                              fmax_loss=h.fmax_for_loss, device=device, fine_tuning=a.fine_tuning,
                              base_mels_path=a.input_mels_dir)
        validation_loader = DataLoader(validset, num_workers=1, shuffle=False,
                                       sampler=None,
                                       batch_size=1,
                                       pin_memory=True,
                                       drop_last=True)

        sw = SummaryWriter(os.path.join(a.checkpoint_path, 'logs'))

    generator.train()
    mpd.train()
    msd.train()
    for epoch in range(max(0, last_epoch), a.training_epochs):
        if rank == 0:
            start = time.time()
            print("Epoch: {}".format(epoch+1))

        if h.num_gpus > 1:
            train_sampler.set_epoch(epoch)

        for i, batch in enumerate(train_loader):
            if rank == 0:
                start_b = time.time()
            x, y, _, y_mel = batch
            x = torch.autograd.Variable(x.to(device, non_blocking=True))
            y = torch.autograd.Variable(y.to(device, non_blocking=True))
            y_mel = torch.autograd.Variable(y_mel.to(device, non_blocking=True))
            y = y.unsqueeze(1)

            y_g_hat = generator(x)
            y_g_hat_mel = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels, h.sampling_rate, h.hop_size, h.win_size,
                                          h.fmin, h.fmax_for_loss)

            optim_d.zero_grad()

            # MPD
            y_df_hat_r, y_df_hat_g, _, _ = mpd(y, y_g_hat.detach())
            loss_disc_f, losses_disc_f_r, losses_disc_f_g = discriminator_loss(y_df_hat_r, y_df_hat_g)

            # MSD
            y_ds_hat_r, y_ds_hat_g, _, _ = msd(y, y_g_hat.detach())
            loss_disc_s, losses_disc_s_r, losses_disc_s_g = discriminator_loss(y_ds_hat_r, y_ds_hat_g)

            loss_disc_all = loss_disc_s + loss_disc_f

            loss_disc_all.backward()
            optim_d.step()

            # Generator
            optim_g.zero_grad()

            # L1 Mel-Spectrogram Loss
            loss_mel = F.l1_loss(y_mel, y_g_hat_mel) * 45

            y_df_hat_r, y_df_hat_g, fmap_f_r, fmap_f_g = mpd(y, y_g_hat)
            y_ds_hat_r, y_ds_hat_g, fmap_s_r, fmap_s_g = msd(y, y_g_hat)
            loss_fm_f = feature_loss(fmap_f_r, fmap_f_g)
            loss_fm_s = feature_loss(fmap_s_r, fmap_s_g)
            loss_gen_f, losses_gen_f = generator_loss(y_df_hat_g)
            loss_gen_s, losses_gen_s = generator_loss(y_ds_hat_g)
            loss_gen_all = loss_gen_s + loss_gen_f + loss_fm_s + loss_fm_f + loss_mel

            loss_gen_all.backward()
            optim_g.step()

            if rank == 0:
                # STDOUT logging
                if steps % a.stdout_interval == 0:
                    with torch.no_grad():
                        mel_error = F.l1_loss(y_mel, y_g_hat_mel).item()

                    print('Steps : {:d}, Gen Loss Total : {:4.3f}, Mel-Spec. Error : {:4.3f}, s/b : {:4.3f}'.
                          format(steps, loss_gen_all, mel_error, time.time() - start_b))

                # checkpointing
                if steps % a.checkpoint_interval == 0 and steps != 0:
                    checkpoint_path = "{}/g_{:08d}.pt".format(a.checkpoint_path, steps)
                    save_checkpoint(checkpoint_path,
                                    {'generator': (generator.module if h.num_gpus > 1 else generator).state_dict()})
                    checkpoint_path = "{}/do_{:08d}".format(a.checkpoint_path, steps)
                    save_checkpoint(checkpoint_path, 
                                    {'mpd': (mpd.module if h.num_gpus > 1
                                                         else mpd).state_dict(),
                                     'msd': (msd.module if h.num_gpus > 1
                                                         else msd).state_dict(),
                                     'optim_g': optim_g.state_dict(), 'optim_d': optim_d.state_dict(), 'steps': steps,
                                     'epoch': epoch})

                # Tensorboard summary logging
                if steps % a.summary_interval == 0:
                    sw.add_scalar("training/gen_loss_total", loss_gen_all, steps)
                    sw.add_scalar("training/mel_spec_error", mel_error, steps)

                # Validation
                if steps % a.validation_interval == 0:  # and steps != 0:
                    generator.eval()
                    torch.cuda.empty_cache()
                    val_err_tot = 0
                    with torch.no_grad():
                        for j, batch in enumerate(validation_loader):
                            x, y, _, y_mel = batch
                            y_g_hat = generator(x.to(device))
                            y_mel = torch.autograd.Variable(y_mel.to(device, non_blocking=True))
                            y_g_hat_mel = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels, h.sampling_rate,
                                                          h.hop_size, h.win_size,
                                                          h.fmin, h.fmax_for_loss)
#                             val_err_tot += F.l1_loss(y_mel, y_g_hat_mel).item()

                            if j <= 4:
                                if steps == 0:
                                    sw.add_audio('gt/y_{}'.format(j), y[0], steps, h.sampling_rate)
                                    sw.add_figure('gt/y_spec_{}'.format(j), plot_spectrogram(x[0]), steps)

                                sw.add_audio('generated/y_hat_{}'.format(j), y_g_hat[0], steps, h.sampling_rate)
                                y_hat_spec = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels,
                                                             h.sampling_rate, h.hop_size, h.win_size,
                                                             h.fmin, h.fmax)
                                sw.add_figure('generated/y_hat_spec_{}'.format(j),
                                              plot_spectrogram(y_hat_spec.squeeze(0).cpu().numpy()), steps)

                        val_err = val_err_tot / (j+1)
                        sw.add_scalar("validation/mel_spec_error", val_err, steps)

                    generator.train()

            steps += 1

        scheduler_g.step()
        scheduler_d.step()
        
        if rank == 0:
            print('Time taken for epoch {} is {} sec\n'.format(epoch + 1, int(time.time() - start)))
Support train hifigan (#83) * support train hifigan 2021-09-14 13:31:53 +08:00			`import warnings`
			`warnings.simplefilter(action='ignore', category=FutureWarning)`
			`import itertools`
			`import os`
			`import time`
			`import argparse`
			`import json`
			`import torch`
			`import torch.nn.functional as F`
			`from torch.utils.tensorboard import SummaryWriter`
			`from torch.utils.data import DistributedSampler, DataLoader`
			`import torch.multiprocessing as mp`
			`from torch.distributed import init_process_group`
			`from torch.nn.parallel import DistributedDataParallel`
			`from vocoder.hifigan.env import AttrDict, build_env`
			`from vocoder.hifigan.meldataset import MelDataset, mel_spectrogram, get_dataset_filelist`
			`from vocoder.hifigan.models import Generator, MultiPeriodDiscriminator, MultiScaleDiscriminator, feature_loss, generator_loss,\`
			`discriminator_loss`
			`from vocoder.hifigan.utils import plot_spectrogram, scan_checkpoint, load_checkpoint, save_checkpoint`

			`torch.backends.cudnn.benchmark = True`


			`def train(rank, a, h):`

			`a.checkpoint_path = a.models_dir.joinpath(a.run_id+'_hifigan')`
			`a.checkpoint_path.mkdir(exist_ok=True)`
			`a.training_epochs = 3100`
			`a.stdout_interval = 5`
			`a.checkpoint_interval = 25000`
			`a.summary_interval = 5000`
			`a.validation_interval = 1000`
			`a.fine_tuning = True`

			`a.input_wavs_dir = a.syn_dir.joinpath("audio")`
			`a.input_mels_dir = a.syn_dir.joinpath("mels")`

			`if h.num_gpus > 1:`
			`init_process_group(backend=h.dist_config['dist_backend'], init_method=h.dist_config['dist_url'],`
			`world_size=h.dist_config['world_size'] * h.num_gpus, rank=rank)`

			`torch.cuda.manual_seed(h.seed)`
			`device = torch.device('cuda:{:d}'.format(rank))`

			`generator = Generator(h).to(device)`
			`mpd = MultiPeriodDiscriminator().to(device)`
			`msd = MultiScaleDiscriminator().to(device)`

			`if rank == 0:`
			`print(generator)`
			`os.makedirs(a.checkpoint_path, exist_ok=True)`
			`print("checkpoints directory : ", a.checkpoint_path)`

			`if os.path.isdir(a.checkpoint_path):`
			`cp_g = scan_checkpoint(a.checkpoint_path, 'g_')`
			`cp_do = scan_checkpoint(a.checkpoint_path, 'do_')`

			`steps = 0`
			`if cp_g is None or cp_do is None:`
			`state_dict_do = None`
			`last_epoch = -1`
			`else:`
			`state_dict_g = load_checkpoint(cp_g, device)`
			`state_dict_do = load_checkpoint(cp_do, device)`
			`generator.load_state_dict(state_dict_g['generator'])`
			`mpd.load_state_dict(state_dict_do['mpd'])`
			`msd.load_state_dict(state_dict_do['msd'])`
			`steps = state_dict_do['steps'] + 1`
			`last_epoch = state_dict_do['epoch']`

			`if h.num_gpus > 1:`
			`generator = DistributedDataParallel(generator, device_ids=[rank]).to(device)`
			`mpd = DistributedDataParallel(mpd, device_ids=[rank]).to(device)`
			`msd = DistributedDataParallel(msd, device_ids=[rank]).to(device)`

			`optim_g = torch.optim.AdamW(generator.parameters(), h.learning_rate, betas=[h.adam_b1, h.adam_b2])`
			`optim_d = torch.optim.AdamW(itertools.chain(msd.parameters(), mpd.parameters()),`
			`h.learning_rate, betas=[h.adam_b1, h.adam_b2])`

			`if state_dict_do is not None:`
			`optim_g.load_state_dict(state_dict_do['optim_g'])`
			`optim_d.load_state_dict(state_dict_do['optim_d'])`

			`scheduler_g = torch.optim.lr_scheduler.ExponentialLR(optim_g, gamma=h.lr_decay, last_epoch=last_epoch)`
			`scheduler_d = torch.optim.lr_scheduler.ExponentialLR(optim_d, gamma=h.lr_decay, last_epoch=last_epoch)`

			`training_filelist, validation_filelist = get_dataset_filelist(a)`

			`# print(training_filelist)`
			`# exit()`

			`trainset = MelDataset(training_filelist, h.segment_size, h.n_fft, h.num_mels,`
			`h.hop_size, h.win_size, h.sampling_rate, h.fmin, h.fmax, n_cache_reuse=0,`
			`shuffle=False if h.num_gpus > 1 else True, fmax_loss=h.fmax_for_loss, device=device,`
			`fine_tuning=a.fine_tuning, base_mels_path=a.input_mels_dir)`

			`train_sampler = DistributedSampler(trainset) if h.num_gpus > 1 else None`

			`train_loader = DataLoader(trainset, num_workers=h.num_workers, shuffle=False,`
			`sampler=train_sampler,`
			`batch_size=h.batch_size,`
			`pin_memory=True,`
			`drop_last=True)`

			`if rank == 0:`
			`validset = MelDataset(validation_filelist, h.segment_size, h.n_fft, h.num_mels,`
			`h.hop_size, h.win_size, h.sampling_rate, h.fmin, h.fmax, False, False, n_cache_reuse=0,`
			`fmax_loss=h.fmax_for_loss, device=device, fine_tuning=a.fine_tuning,`
			`base_mels_path=a.input_mels_dir)`
			`validation_loader = DataLoader(validset, num_workers=1, shuffle=False,`
			`sampler=None,`
			`batch_size=1,`
			`pin_memory=True,`
			`drop_last=True)`

			`sw = SummaryWriter(os.path.join(a.checkpoint_path, 'logs'))`

			`generator.train()`
			`mpd.train()`
			`msd.train()`
			`for epoch in range(max(0, last_epoch), a.training_epochs):`
			`if rank == 0:`
			`start = time.time()`
			`print("Epoch: {}".format(epoch+1))`

			`if h.num_gpus > 1:`
			`train_sampler.set_epoch(epoch)`

			`for i, batch in enumerate(train_loader):`
			`if rank == 0:`
			`start_b = time.time()`
			`x, y, _, y_mel = batch`
			`x = torch.autograd.Variable(x.to(device, non_blocking=True))`
			`y = torch.autograd.Variable(y.to(device, non_blocking=True))`
			`y_mel = torch.autograd.Variable(y_mel.to(device, non_blocking=True))`
			`y = y.unsqueeze(1)`

			`y_g_hat = generator(x)`
			`y_g_hat_mel = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels, h.sampling_rate, h.hop_size, h.win_size,`
			`h.fmin, h.fmax_for_loss)`

			`optim_d.zero_grad()`

			`# MPD`
			`y_df_hat_r, y_df_hat_g, _, _ = mpd(y, y_g_hat.detach())`
			`loss_disc_f, losses_disc_f_r, losses_disc_f_g = discriminator_loss(y_df_hat_r, y_df_hat_g)`

			`# MSD`
			`y_ds_hat_r, y_ds_hat_g, _, _ = msd(y, y_g_hat.detach())`
			`loss_disc_s, losses_disc_s_r, losses_disc_s_g = discriminator_loss(y_ds_hat_r, y_ds_hat_g)`

			`loss_disc_all = loss_disc_s + loss_disc_f`

			`loss_disc_all.backward()`
			`optim_d.step()`

			`# Generator`
			`optim_g.zero_grad()`

			`# L1 Mel-Spectrogram Loss`
			`loss_mel = F.l1_loss(y_mel, y_g_hat_mel) * 45`

			`y_df_hat_r, y_df_hat_g, fmap_f_r, fmap_f_g = mpd(y, y_g_hat)`
			`y_ds_hat_r, y_ds_hat_g, fmap_s_r, fmap_s_g = msd(y, y_g_hat)`
			`loss_fm_f = feature_loss(fmap_f_r, fmap_f_g)`
			`loss_fm_s = feature_loss(fmap_s_r, fmap_s_g)`
			`loss_gen_f, losses_gen_f = generator_loss(y_df_hat_g)`
			`loss_gen_s, losses_gen_s = generator_loss(y_ds_hat_g)`
			`loss_gen_all = loss_gen_s + loss_gen_f + loss_fm_s + loss_fm_f + loss_mel`

			`loss_gen_all.backward()`
			`optim_g.step()`

			`if rank == 0:`
			`# STDOUT logging`
			`if steps % a.stdout_interval == 0:`
			`with torch.no_grad():`
			`mel_error = F.l1_loss(y_mel, y_g_hat_mel).item()`

			`print('Steps : {:d}, Gen Loss Total : {:4.3f}, Mel-Spec. Error : {:4.3f}, s/b : {:4.3f}'.`
			`format(steps, loss_gen_all, mel_error, time.time() - start_b))`

			`# checkpointing`
			`if steps % a.checkpoint_interval == 0 and steps != 0:`
			`checkpoint_path = "{}/g_{:08d}.pt".format(a.checkpoint_path, steps)`
			`save_checkpoint(checkpoint_path,`
			`{'generator': (generator.module if h.num_gpus > 1 else generator).state_dict()})`
			`checkpoint_path = "{}/do_{:08d}".format(a.checkpoint_path, steps)`
			`save_checkpoint(checkpoint_path,`
			`{'mpd': (mpd.module if h.num_gpus > 1`
			`else mpd).state_dict(),`
			`'msd': (msd.module if h.num_gpus > 1`
			`else msd).state_dict(),`
			`'optim_g': optim_g.state_dict(), 'optim_d': optim_d.state_dict(), 'steps': steps,`
			`'epoch': epoch})`

			`# Tensorboard summary logging`
			`if steps % a.summary_interval == 0:`
			`sw.add_scalar("training/gen_loss_total", loss_gen_all, steps)`
			`sw.add_scalar("training/mel_spec_error", mel_error, steps)`

			`# Validation`
			`if steps % a.validation_interval == 0: # and steps != 0:`
			`generator.eval()`
			`torch.cuda.empty_cache()`
			`val_err_tot = 0`
			`with torch.no_grad():`
			`for j, batch in enumerate(validation_loader):`
			`x, y, _, y_mel = batch`
			`y_g_hat = generator(x.to(device))`
			`y_mel = torch.autograd.Variable(y_mel.to(device, non_blocking=True))`
			`y_g_hat_mel = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels, h.sampling_rate,`
			`h.hop_size, h.win_size,`
			`h.fmin, h.fmax_for_loss)`
			`# val_err_tot += F.l1_loss(y_mel, y_g_hat_mel).item()`

			`if j <= 4:`
			`if steps == 0:`
			`sw.add_audio('gt/y_{}'.format(j), y[0], steps, h.sampling_rate)`
			`sw.add_figure('gt/y_spec_{}'.format(j), plot_spectrogram(x[0]), steps)`

			`sw.add_audio('generated/y_hat_{}'.format(j), y_g_hat[0], steps, h.sampling_rate)`
			`y_hat_spec = mel_spectrogram(y_g_hat.squeeze(1), h.n_fft, h.num_mels,`
			`h.sampling_rate, h.hop_size, h.win_size,`
			`h.fmin, h.fmax)`
			`sw.add_figure('generated/y_hat_spec_{}'.format(j),`
			`plot_spectrogram(y_hat_spec.squeeze(0).cpu().numpy()), steps)`

			`val_err = val_err_tot / (j+1)`
			`sw.add_scalar("validation/mel_spec_error", val_err, steps)`

			`generator.train()`

			`steps += 1`

			`scheduler_g.step()`
			`scheduler_d.step()`

			`if rank == 0:`
			`print('Time taken for epoch {} is {} sec\n'.format(epoch + 1, int(time.time() - start)))`