mirror of
https://github.com/ggerganov/whisper.cpp.git
synced 2024-12-18 20:27:53 +00:00
319 lines
12 KiB
Python
319 lines
12 KiB
Python
import argparse
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import torch
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import torch.nn.functional as F
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import coremltools as ct
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from torch import Tensor
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from torch import nn
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from typing import Dict
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from typing import Optional
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from ane_transformers.reference.layer_norm import LayerNormANE as LayerNormANEBase
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from coremltools.models.neural_network.quantization_utils import quantize_weights
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from whisper.model import Whisper, AudioEncoder, TextDecoder, ResidualAttentionBlock, MultiHeadAttention, ModelDimensions
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from whisper import load_model
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# Use for changing dim of input in encoder and decoder embeddings
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def linear_to_conv2d_map(state_dict, prefix, local_metadata, strict,
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missing_keys, unexpected_keys, error_msgs):
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"""
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Unsqueeze twice to map nn.Linear weights to nn.Conv2d weights
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"""
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for k in state_dict:
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is_attention = all(substr in k for substr in ['attn', '.weight'])
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is_mlp = any(k.endswith(s) for s in ['mlp.0.weight', 'mlp.2.weight'])
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if (is_attention or is_mlp) and len(state_dict[k].shape) == 2:
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state_dict[k] = state_dict[k][:, :, None, None]
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def correct_for_bias_scale_order_inversion(state_dict, prefix, local_metadata,
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strict, missing_keys,
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unexpected_keys, error_msgs):
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state_dict[prefix + 'bias'] = state_dict[prefix + 'bias'] / state_dict[prefix + 'weight']
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return state_dict
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class LayerNormANE(LayerNormANEBase):
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def __init__(self, *args, **kwargs):
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super().__init__(*args, **kwargs)
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self._register_load_state_dict_pre_hook(
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correct_for_bias_scale_order_inversion)
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class MultiHeadAttentionANE(MultiHeadAttention):
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def __init__(self, n_state: int, n_head: int):
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super().__init__(n_state, n_head)
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self.query = nn.Conv2d(n_state, n_state, kernel_size=1)
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self.key = nn.Conv2d(n_state, n_state, kernel_size=1, bias=False)
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self.value = nn.Conv2d(n_state, n_state, kernel_size=1)
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self.out = nn.Conv2d(n_state, n_state, kernel_size=1)
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def forward(self,
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x: Tensor,
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xa: Optional[Tensor] = None,
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mask: Optional[Tensor] = None,
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kv_cache: Optional[dict] = None):
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q = self.query(x)
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if kv_cache is None or xa is None or self.key not in kv_cache:
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# hooks, if installed (i.e. kv_cache is not None), will prepend the cached kv tensors;
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# otherwise, perform key/value projections for self- or cross-attention as usual.
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k = self.key(x if xa is None else xa)
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v = self.value(x if xa is None else xa)
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else:
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# for cross-attention, calculate keys and values once and reuse in subsequent calls.
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k = kv_cache[self.key]
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v = kv_cache[self.value]
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wv, qk = self.qkv_attention_ane(q, k, v, mask)
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return self.out(wv), qk
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def qkv_attention_ane(self, q: Tensor, k: Tensor, v: Tensor, mask: Optional[Tensor] = None):
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_, dim, _, seqlen = q.size()
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dim_per_head = dim // self.n_head
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scale = float(dim_per_head)**-0.5
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q = q * scale
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mh_q = q.split(dim_per_head, dim=1)
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mh_k = k.transpose(1,3).split(dim_per_head, dim=3)
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mh_v = v.split(dim_per_head, dim=1)
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mh_qk = [
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torch.einsum('bchq,bkhc->bkhq', [qi, ki])
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for qi, ki in zip(mh_q, mh_k)
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] # (batch_size, max_seq_length, 1, max_seq_length) * n_heads
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if mask is not None:
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for head_idx in range(self.n_head):
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mh_qk[head_idx] = mh_qk[head_idx] + mask[:, :seqlen, :, :seqlen]
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attn_weights = [aw.softmax(dim=1) for aw in mh_qk] # (batch_size, max_seq_length, 1, max_seq_length) * n_heads
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attn = [torch.einsum('bkhq,bchk->bchq', wi, vi) for wi, vi in zip(attn_weights, mh_v)] # (batch_size, dim_per_head, 1, max_seq_length) * n_heads
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attn = torch.cat(attn, dim=1) # (batch_size, dim, 1, max_seq_length)
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return attn, torch.cat(mh_qk, dim=1).float().detach()
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class ResidualAttentionBlockANE(ResidualAttentionBlock):
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def __init__(self, n_state: int, n_head: int, cross_attention: bool = False):
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super().__init__(n_state, n_head, cross_attention)
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self.attn = MultiHeadAttentionANE(n_state, n_head)
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self.attn_ln = LayerNormANE(n_state)
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self.cross_attn = MultiHeadAttentionANE(n_state, n_head) if cross_attention else None
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self.cross_attn_ln = LayerNormANE(n_state) if cross_attention else None
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n_mlp = n_state * 4
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self.mlp = nn.Sequential(
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nn.Conv2d(n_state, n_mlp, kernel_size=1),
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nn.GELU(),
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nn.Conv2d(n_mlp, n_state, kernel_size=1)
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)
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self.mlp_ln = LayerNormANE(n_state)
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class AudioEncoderANE(AudioEncoder):
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def __init__(self, n_mels: int, n_ctx: int, n_state: int, n_head: int, n_layer: int):
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super().__init__(n_mels, n_ctx, n_state, n_head, n_layer)
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self.blocks = nn.ModuleList(
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[ResidualAttentionBlockANE(n_state, n_head) for _ in range(n_layer)]
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)
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self.ln_post = LayerNormANE(n_state)
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def forward(self, x: Tensor):
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"""
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x : torch.Tensor, shape = (batch_size, n_mels, n_ctx)
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the mel spectrogram of the audio
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"""
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x = F.gelu(self.conv1(x))
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x = F.gelu(self.conv2(x))
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assert x.shape[1:] == self.positional_embedding.shape[::-1], "incorrect audio shape"
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# Add positional embedding and add dummy dim for ANE
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x = (x + self.positional_embedding.transpose(0,1)).to(x.dtype).unsqueeze(2)
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for block in self.blocks:
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x = block(x)
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x = self.ln_post(x)
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x = x.squeeze(2).transpose(1, 2)
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return x
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class TextDecoderANE(TextDecoder):
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def __init__(self, n_vocab: int, n_ctx: int, n_state: int, n_head: int, n_layer: int):
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super().__init__(n_vocab, n_ctx, n_state, n_head, n_layer)
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self.blocks= nn.ModuleList(
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[ResidualAttentionBlockANE(n_state, n_head, cross_attention=True) for _ in range(n_layer)]
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)
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self.ln= LayerNormANE(n_state)
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def forward(self, x: Tensor, xa: Tensor, kv_cache: Optional[dict] = None):
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"""
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x : torch.LongTensor, shape = (batch_size, <= n_ctx)
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the text tokens
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xa : torch.Tensor, shape = (batch_size, n_mels, n_audio_ctx)
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the encoded audio features to be attended on
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"""
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offset = next(iter(kv_cache.values())).shape[3] if kv_cache else 0
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x = self.token_embedding(x) + self.positional_embedding[offset : offset + x.shape[-1]]
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x = x.to(xa.dtype)
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# Reformat for ANE
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mask = self.mask[None, None, :, :].permute(0,3,1,2)
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x = x.transpose(1,2).unsqueeze(2)
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for block in self.blocks:
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x = block(x, xa, mask=mask, kv_cache=kv_cache)
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x = self.ln(x)
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# Reformat back from ANE
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x = x.permute(0,2,3,1).squeeze(0)
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# ANE can only load tensors with dim size of at most 16,384 - whisper uses 51,864 (en) or 51,865 (multi-lang) tokens so we need to compute in chunks
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if self.token_embedding.weight.shape[0] >= 51865:
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# split in 11 chunks - 4715 each
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splits = self.token_embedding.weight.split(self.token_embedding.weight.shape[0]//11, dim=0)
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logits = torch.cat([torch.einsum('bid,jd->bij', x, split) for split in splits]).view(*x.shape[:2], -1)
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else:
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# split in 12 chunks - 4322 each
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assert(self.token_embedding.weight.shape[0] == 51864)
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splits = self.token_embedding.weight.split(self.token_embedding.weight.shape[0]//12, dim=0)
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logits = torch.cat([torch.einsum('bid,jd->bij', x, split) for split in splits]).view(*x.shape[:2], -1)
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return logits
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class WhisperANE(Whisper):
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def __init__(self, dims: ModelDimensions):
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super().__init__(dims)
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self.encoder = AudioEncoderANE(
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self.dims.n_mels,
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self.dims.n_audio_ctx,
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self.dims.n_audio_state,
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self.dims.n_audio_head,
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self.dims.n_audio_layer,
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)
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self.decoder = TextDecoderANE(
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self.dims.n_vocab,
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self.dims.n_text_ctx,
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self.dims.n_text_state,
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self.dims.n_text_head,
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self.dims.n_text_layer,
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)
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self._register_load_state_dict_pre_hook(linear_to_conv2d_map)
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def forward(self, mel: torch.Tensor, tokens: torch.Tensor) -> Dict[str, torch.Tensor]:
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return self.decoder(tokens, self.encoder(mel))
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def install_kv_cache_hooks(self, cache: Optional[dict] = None):
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cache = {**cache} if cache is not None else {}
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hooks = []
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def save_to_cache(module, _, output):
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if module not in cache or output.shape[3] > self.decoder.positional_embedding.shape[0]:
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cache[module] = output # save as-is, for the first token or cross attention
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else:
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cache[module] = torch.cat([cache[module], output], dim=3).detach()
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return cache[module]
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def install_hooks(layer: nn.Module):
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if isinstance(layer, MultiHeadAttentionANE):
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hooks.append(layer.key.register_forward_hook(save_to_cache))
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hooks.append(layer.value.register_forward_hook(save_to_cache))
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self.decoder.apply(install_hooks)
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return cache, hooks
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def convert_encoder(hparams, model, quantize=False):
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model.eval()
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input_shape = (1, hparams.n_mels, 3000)
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input_data = torch.randn(input_shape)
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traced_model = torch.jit.trace(model, input_data)
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model = ct.convert(
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traced_model,
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convert_to=None if quantize else "mlprogram", # convert will fail if weights are quantized, not sure why
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inputs=[ct.TensorType(name="logmel_data", shape=input_shape)],
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outputs=[ct.TensorType(name="output")],
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compute_units=ct.ComputeUnit.ALL
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)
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if quantize:
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model = quantize_weights(model, nbits=16)
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return model
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def convert_decoder(hparams, model, quantize=False):
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model.eval()
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tokens_shape = (1, 1)
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audio_shape = (1, hparams.n_audio_state, 1, 1500)
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audio_data = torch.randn(audio_shape)
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token_data = torch.randint(50257, tokens_shape).long()
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traced_model = torch.jit.trace(model, (token_data, audio_data))
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model = ct.convert(
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traced_model,
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convert_to=None if quantize else "mlprogram", # convert will fail if weights are quantized, not sure why
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inputs=[
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ct.TensorType(name="token_data", shape=tokens_shape, dtype=int),
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ct.TensorType(name="audio_data", shape=audio_shape)
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]
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)
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if quantize:
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model = quantize_weights(model, nbits=16)
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return model
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if __name__ == "__main__":
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parser = argparse.ArgumentParser()
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parser.add_argument("--model", type=str, help="model to convert (e.g. tiny, tiny.en, base, base.en, small, small.en, medium, medium.en, large-v1, large-v2, large-v3)", required=True)
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parser.add_argument("--encoder-only", type=bool, help="only convert encoder", default=False)
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parser.add_argument("--quantize", type=bool, help="quantize weights to F16", default=False)
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parser.add_argument("--optimize-ane", type=bool, help="optimize for ANE execution (currently broken)", default=False)
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args = parser.parse_args()
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if args.model not in ["tiny", "tiny.en", "base", "base.en", "small", "small.en", "small.en-tdrz", "medium", "medium.en", "large-v1", "large-v2", "large-v3"]:
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raise ValueError("Invalid model name")
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whisper = load_model(args.model).cpu()
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hparams = whisper.dims
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print(hparams)
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if args.optimize_ane:
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whisperANE = WhisperANE(hparams).eval()
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whisperANE.load_state_dict(whisper.state_dict())
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encoder = whisperANE.encoder
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decoder = whisperANE.decoder
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else:
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encoder = whisper.encoder
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decoder = whisper.decoder
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# Convert encoder
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encoder = convert_encoder(hparams, encoder, quantize=args.quantize)
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encoder.save(f"models/coreml-encoder-{args.model}.mlpackage")
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if args.encoder_only is False:
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# Convert decoder
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decoder = convert_decoder(hparams, decoder, quantize=args.quantize)
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decoder.save(f"models/coreml-decoder-{args.model}.mlpackage")
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print("done converting")
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