forked from mrq/DL-Art-School
191 lines
8.9 KiB
Python
191 lines
8.9 KiB
Python
import json
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import torch
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import torch.nn as nn
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import torch.nn.functional as F
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from x_transformers import Encoder, XTransformer, TransformerWrapper
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from models.gpt_voice.unet_diffusion_tts6 import CheckpointedLayer
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from models.gpt_voice.unified_voice2 import ConditioningEncoder
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from models.tacotron2.text.cleaners import english_cleaners
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from trainer.networks import register_model
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from utils.util import opt_get
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def clustered_mask(probability, shape, dev, lateral_expansion_radius_max=3):
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"""
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Produces a masking vector of the specified shape where each element has probability to be zero.
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lateral_expansion_radius_max neighbors of any element that is zero also have a 50% chance to be zero.
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Effectively, this produces clusters of masks tending to be lateral_expansion_radius_max wide.
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Note: This means the algorithm has a far higher output probability for zeros then <probability>.
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"""
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mask = torch.rand(shape, device=dev)
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mask = (mask < probability).float()
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kernel = torch.tensor([.5 for _ in range(lateral_expansion_radius_max)] + [1] + [.5 for _ in range(lateral_expansion_radius_max)], device=dev)
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mask = F.conv1d(mask.unsqueeze(1), kernel.view(1,1,2*lateral_expansion_radius_max+1), padding=lateral_expansion_radius_max).squeeze(1)
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return torch.bernoulli(torch.clamp(mask, 0, 1)) == 0 # ==0 logically inverts the mask.
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class CheckpointedTransformerWrapper(nn.Module):
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"""
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Wraps a ContinuousTransformerWrapper and applies CheckpointedLayer to each layer and permutes from channels-mid
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to channels-last that XTransformer expects.
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"""
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def __init__(self, **xtransformer_kwargs):
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super().__init__()
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self.transformer = TransformerWrapper(**xtransformer_kwargs)
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for i in range(len(self.transformer.transformer.attn_layers.layers)):
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n, b, r = self.transformer.transformer.attn_layers.layers[i]
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self.transformer.transformer.attn_layers.layers[i] = nn.ModuleList([n, CheckpointedLayer(b), r])
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def forward(self, *args, **kwargs):
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return self.transformer(*args, **kwargs)
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class CtcCodeGenerator(nn.Module):
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def __init__(self, model_dim=512, layers=10, num_heads=8, dropout=.1, ctc_codes=36, max_pad=121, max_repeat=30, mask_probability=.1):
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super().__init__()
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self.max_pad = max_pad
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self.max_repeat = max_repeat
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self.mask_probability = mask_probability
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self.conditioning_encoder = ConditioningEncoder(80, model_dim, num_attn_heads=num_heads, mean=True)
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self.initial_embedding = nn.Embedding(ctc_codes, model_dim)
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self.combiner = nn.Linear(model_dim*2, model_dim)
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self.transformer = TransformerWrapper(
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num_tokens=max_pad*max_repeat+1,
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max_seq_len=-1, # Unneeded for rotary embeddings.
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attn_layers=Encoder(
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dim=model_dim,
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depth=layers,
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heads=num_heads,
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ff_dropout=dropout,
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attn_dropout=dropout,
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use_rmsnorm=True,
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ff_glu=True,
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rotary_pos_emb=True
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)
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)
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self.transformer.token_emb = nn.Identity() # This class handles the initial embeddings.
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self.transformer.to_logits = nn.Identity()
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self.ctc_head = nn.Linear(model_dim, max_pad*max_repeat+1)
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self.inp_head = nn.Linear(model_dim, ctc_codes)
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def forward(self, conditioning_input, codes, separators, repeats, unpadded_lengths):
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max_len = unpadded_lengths.max()
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codes = codes[:, :max_len]
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loss_mask = torch.ones_like(codes)
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for i, l in enumerate(unpadded_lengths):
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loss_mask[i, l:] = 0
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if self.training:
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codes = clustered_mask(self.mask_probability, codes.shape, codes.device) * codes
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if separators.max() > self.max_pad:
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print(f"Got unexpectedly long separators. Max: {separators.max()}, {separators}")
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separators = torch.clip(separators, 0, self.max_pad)
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separators = separators[:, :max_len]
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if repeats.max() > self.max_repeat:
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print(f"Got unexpectedly long repeats. Max: {repeats.max()}, {repeats}")
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repeats = torch.clip(repeats, 1, self.max_repeat)
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repeats = repeats[:, :max_len]
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repeats = repeats - 1 # min(repeats) is 1; make it 0 to avoid wasting a prediction slot.
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labels = separators + repeats * self.max_pad
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# Perform conditioning encoder in FP32, with the transformer in FP16
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cond = self.conditioning_encoder(conditioning_input).unsqueeze(1).repeat(1,codes.shape[1],1)
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h = torch.cat([cond, self.initial_embedding(codes)], dim=-1)
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h = self.combiner(h)
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with torch.autocast(codes.device.type):
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logits = self.transformer(h)
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ctc_pred = self.ctc_head(logits)
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code_pred = self.inp_head(logits)
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ctcloss = F.cross_entropy(ctc_pred.float().permute(0,2,1), labels, reduction='none')
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ctcloss = torch.mean(ctcloss * loss_mask)
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codeloss = F.cross_entropy(code_pred.float().permute(0,2,1), codes, reduction='none')
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codeloss = torch.mean(codeloss * loss_mask)
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return ctcloss, codeloss
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def generate(self, speech_conditioning_input, texts):
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codes = []
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max_seq = 50
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for text in texts:
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# First, generate CTC codes from the given texts.
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vocab = json.loads('{" ": 4, "E": 5, "T": 6, "A": 7, "O": 8, "N": 9, "I": 10, "H": 11, "S": 12, "R": 13, "D": 14, "L": 15, "U": 16, "M": 17, "W": 18, "C": 19, "F": 20, "G": 21, "Y": 22, "P": 23, "B": 24, "V": 25, "K": 26, "\'": 27, "X": 28, "J": 29, "Q": 30, "Z": 31}')
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text = english_cleaners(text)
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text = text.strip().upper()
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cd = []
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for c in text:
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if c not in vocab.keys():
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continue
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cd.append(vocab[c])
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codes.append(torch.tensor(cd, device=speech_conditioning_input.device))
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max_seq = max(max_seq, codes[-1].shape[-1])
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# Collate
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for i in range(len(codes)):
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if codes[i].shape[-1] < max_seq:
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codes[i] = F.pad(codes[i], (0, max_seq-codes[i].shape[-1]))
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codes = torch.stack(codes, dim=0)
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cond = self.conditioning_encoder(speech_conditioning_input).unsqueeze(1).repeat(1,codes.shape[1],1)
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h = torch.cat([cond, self.initial_embedding(codes)], dim=-1)
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h = self.combiner(h)
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with torch.autocast(codes.device.type):
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logits = self.transformer(h)
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ctc_pred = self.ctc_head(logits)
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generate = torch.argmax(ctc_pred, dim=-1)
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# De-compress the codes from the generated output
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pads = generate % self.max_pad
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repeats = (generate // self.max_pad) + 1
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ctc_batch = []
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max_seq = 0
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for bc, bp, br in zip(codes, pads, repeats):
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ctc = []
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for c, p, r in zip(bc, bp, br):
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for _ in range(p):
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ctc.append(0)
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for _ in range(r):
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ctc.append(c.item())
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ctc_batch.append(torch.tensor(ctc, device=speech_conditioning_input.device))
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max_seq = max(max_seq, ctc_batch[-1].shape[-1])
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# Collate the batch
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for i in range(len(ctc_batch)):
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if ctc_batch[i].shape[-1] < max_seq:
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ctc_batch[i] = F.pad(ctc_batch[i], (0, max_seq-ctc_batch[i].shape[-1]))
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return torch.stack(ctc_batch, dim=0)
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@register_model
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def register_ctc_code_generator(opt_net, opt):
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return CtcCodeGenerator(**opt_get(opt_net, ['kwargs'], {}))
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def inf():
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sd = torch.load('D:\\dlas\\experiments\\train_encoder_build_ctc_alignments_medium\\models\\24000_generator.pth', map_location='cpu')
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model = CtcCodeGenerator(model_dim=1024,layers=32).eval()
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model.load_state_dict(sd)
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with torch.no_grad():
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from data.audio.unsupervised_audio_dataset import load_audio
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from scripts.audio.gen.speech_synthesis_utils import wav_to_mel
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ref_mel = torch.cat([wav_to_mel(load_audio("D:\\tortoise-tts\\voices\\atkins\\1.wav", 22050))[:,:,:450],
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wav_to_mel(load_audio("D:\\tortoise-tts\\voices\\kennard\\1.wav", 22050))[:,:,:450],
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wav_to_mel(load_audio("D:\\tortoise-tts\\voices\\grace\\1.wav", 22050))[:,:,:450],
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wav_to_mel(load_audio("D:\\tortoise-tts\\voices\\atkins\\1.wav", 22050))[:,:,:450]], dim=0)
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ctc = model.generate(ref_mel, (["i suppose though it's too early for them"] * 3) + ["i suppose though it's too early for them, dear"])
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print("Break")
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if __name__ == '__main__':
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#inf()
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mask = clustered_mask(.1, (4,100), 'cpu')
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model = CtcCodeGenerator()
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inps = torch.randint(0,36, (4, 300))
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pads = torch.randint(0,100, (4,300))
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repeats = torch.randint(1,20, (4,300))
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conds = torch.randn(4,80,600)
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loss1, loss2 = model(conds, inps, pads, repeats, torch.tensor([250, 300, 280, 30]))
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print(loss1.shape, loss2.shape) |