import torch

import utils
from .diff.diffusion import GaussianDiffusion
from .diff.net import DiffNet
from tasks.tts.fs2 import FastSpeech2Task
from utils.hparams import hparams


DIFF_DECODERS = {
    'wavenet': lambda hp: DiffNet(hp['audio_num_mel_bins']),
}


class DiffFsTask(FastSpeech2Task):
    def build_tts_model(self):
        mel_bins = hparams['audio_num_mel_bins']
        self.model = GaussianDiffusion(
            phone_encoder=self.phone_encoder,
            out_dims=mel_bins, denoise_fn=DIFF_DECODERS[hparams['diff_decoder_type']](hparams),
            timesteps=hparams['timesteps'],
            loss_type=hparams['diff_loss_type'],
            spec_min=hparams['spec_min'], spec_max=hparams['spec_max'],
        )

    def run_model(self, model, sample, return_output=False, infer=False):
        txt_tokens = sample['txt_tokens']  # [B, T_t]
        target = sample['mels']  # [B, T_s, 80]
        mel2ph = sample['mel2ph']  # [B, T_s]
        f0 = sample['f0']
        uv = sample['uv']
        energy = sample['energy']
        spk_embed = sample.get('spk_embed') if not hparams['use_spk_id'] else sample.get('spk_ids')
        if hparams['pitch_type'] == 'cwt':
            cwt_spec = sample[f'cwt_spec']
            f0_mean = sample['f0_mean']
            f0_std = sample['f0_std']
            sample['f0_cwt'] = f0 = model.cwt2f0_norm(cwt_spec, f0_mean, f0_std, mel2ph)

        output = model(txt_tokens, mel2ph=mel2ph, spk_embed=spk_embed,
                       ref_mels=target, f0=f0, uv=uv, energy=energy, infer=infer)

        losses = {}
        if 'diff_loss' in output:
            losses['mel'] = output['diff_loss']
        self.add_dur_loss(output['dur'], mel2ph, txt_tokens, losses=losses)
        if hparams['use_pitch_embed']:
            self.add_pitch_loss(output, sample, losses)
        if hparams['use_energy_embed']:
            self.add_energy_loss(output['energy_pred'], energy, losses)
        if not return_output:
            return losses
        else:
            return losses, output

    def _training_step(self, sample, batch_idx, _):
        log_outputs = self.run_model(self.model, sample)
        total_loss = sum([v for v in log_outputs.values() if isinstance(v, torch.Tensor) and v.requires_grad])
        log_outputs['batch_size'] = sample['txt_tokens'].size()[0]
        log_outputs['lr'] = self.scheduler.get_lr()[0]
        return total_loss, log_outputs

    def validation_step(self, sample, batch_idx):
        outputs = {}
        outputs['losses'] = {}
        outputs['losses'], model_out = self.run_model(self.model, sample, return_output=True, infer=False)
        outputs['total_loss'] = sum(outputs['losses'].values())
        outputs['nsamples'] = sample['nsamples']
        outputs = utils.tensors_to_scalars(outputs)
        if batch_idx < hparams['num_valid_plots']:
            _, model_out = self.run_model(self.model, sample, return_output=True, infer=True)
            self.plot_mel(batch_idx, sample['mels'], model_out['mel_out'])
        return outputs

    def build_scheduler(self, optimizer):
        return torch.optim.lr_scheduler.StepLR(optimizer, hparams['decay_steps'], gamma=0.5)

    def optimizer_step(self, epoch, batch_idx, optimizer, optimizer_idx):
        if optimizer is None:
            return
        optimizer.step()
        optimizer.zero_grad()
        if self.scheduler is not None:
            self.scheduler.step(self.global_step // hparams['accumulate_grad_batches'])