thanks to Qwen ❤

e45b914 over 2 years ago

15 kB

	import base64
	import gzip
	from dataclasses import dataclass
	from typing import Dict, Iterable, Optional, List

	import numpy as np
	import torch
	import torch.nn.functional as F
	from torch import Tensor, nn
	from subprocess import CalledProcessError, run, Popen, PIPE

	import os
	from functools import lru_cache
	from typing import Optional, Union

	def exact_div(x, y):
	assert x % y == 0
	return x // y

	# hard-coded audio hyperparameters
	SAMPLE_RATE = 16000
	N_FFT = 400
	N_MELS = 80
	HOP_LENGTH = 160
	CHUNK_LENGTH = 30
	N_SAMPLES = CHUNK_LENGTH * SAMPLE_RATE # 480000 samples in a 30-second chunk
	N_FRAMES = exact_div(N_SAMPLES, HOP_LENGTH) # 3000 frames in a mel spectrogram input

	N_SAMPLES_PER_TOKEN = HOP_LENGTH * 2 # the initial convolutions has stride 2
	FRAMES_PER_SECOND = exact_div(SAMPLE_RATE, HOP_LENGTH) # 10ms per audio frame
	TOKENS_PER_SECOND = exact_div(SAMPLE_RATE, N_SAMPLES_PER_TOKEN) # 20ms per audio token



	def get_T_after_cnn(L_in, dilation=1):
	for (padding, kernel_size, stride) in eval("[(1,3,1)] + [(1,3,2)] "):
	L_out = L_in + 2 * padding - dilation * (kernel_size - 1) - 1
	L_out = 1 + L_out // stride
	L_in = L_out
	return L_out

	def load_bytesio_audio(content, sr: int = SAMPLE_RATE):
	cmd = [
	"ffmpeg",
	"-nostdin",
	"-threads", "0",
	"-i", "pipe:",
	"-f", "s16le",
	"-ac", "1",
	"-acodec", "pcm_s16le",
	"-ar", str(sr),
	"pipe:"
	]
	p = Popen(cmd, stdin=PIPE, stdout=PIPE, stderr=PIPE, bufsize=-1)
	out, _ = p.communicate(input=content)
	return np.frombuffer(out, np.int16).flatten().astype(np.float32) / 32768.0

	def load_audio(file: str, sr: int = SAMPLE_RATE):
	"""
	Open an audio file and read as mono waveform, resampling as necessary

	Parameters
	----------
	file: str
	The audio file to open

	sr: int
	The sample rate to resample the audio if necessary

	Returns
	-------
	A NumPy array containing the audio waveform, in float32 dtype.
	"""

	# This launches a subprocess to decode audio while down-mixing
	# and resampling as necessary. Requires the ffmpeg CLI in PATH.
	# fmt: off
	cmd = [
	"ffmpeg",
	"-nostdin",
	"-threads", "0",
	"-i", file,
	"-f", "s16le",
	"-ac", "1",
	"-acodec", "pcm_s16le",
	"-ar", str(sr),
	"-"
	]
	# fmt: on
	try:
	out = run(cmd, capture_output=True, check=True).stdout
	except CalledProcessError as e:
	raise RuntimeError(f"Failed to load audio: {e.stderr.decode()}") from e

	return np.frombuffer(out, np.int16).flatten().astype(np.float32) / 32768.0


	def pad_or_trim(array, length: int = N_SAMPLES, *, axis: int = -1):
	"""
	Pad or trim the audio array to N_SAMPLES, as expected by the encoder.
	"""
	if torch.is_tensor(array):
	if array.shape[axis] > length:
	array = array.index_select(
	dim=axis, index=torch.arange(length, device=array.device)
	)

	if array.shape[axis] < length:
	pad_widths = [(0, 0)] * array.ndim
	pad_widths[axis] = (0, length - array.shape[axis])
	array = F.pad(array, [pad for sizes in pad_widths[::-1] for pad in sizes])
	else:
	if array.shape[axis] > length:
	array = array.take(indices=range(length), axis=axis)

	if array.shape[axis] < length:
	pad_widths = [(0, 0)] * array.ndim
	pad_widths[axis] = (0, length - array.shape[axis])
	array = np.pad(array, pad_widths)

	return array

	def trim(array, length: int = N_SAMPLES, *, axis: int = -1):
	"""
	Pad or trim the audio array to N_SAMPLES, as expected by the encoder.
	"""
	if torch.is_tensor(array):
	if array.shape[axis] > length:
	array = array.index_select(
	dim=axis, index=torch.arange(length, device=array.device)
	)
	else:
	if array.shape[axis] > length:
	array = array.take(indices=range(length), axis=axis)
	return array


	@lru_cache(maxsize=None)
	def mel_filters(device, n_mels: int = N_MELS) -> torch.Tensor:
	"""
	load the mel filterbank matrix for projecting STFT into a Mel spectrogram.
	Allows decoupling librosa dependency; saved using:

	np.savez_compressed(
	"mel_filters.npz",
	mel_80=librosa.filters.mel(sr=16000, n_fft=400, n_mels=80),
	)
	"""
	assert n_mels == 80, f"Unsupported n_mels: {n_mels}"
	with np.load(
	os.path.join(os.path.dirname(__file__), "mel_filters.npz") # todo
	# os.path.join("assets", "mel_filters.npz")
	) as f:
	return torch.from_numpy(f[f"mel_{n_mels}"]).to(device)


	def log_mel_spectrogram(
	audio: Union[str, np.ndarray, torch.Tensor],
	n_mels: int = N_MELS,
	padding: int = 0,
	device: Optional[Union[str, torch.device]] = None,
	):
	"""
	Compute the log-Mel spectrogram of

	Parameters
	----------
	audio: Union[str, np.ndarray, torch.Tensor], shape = (*)
	The path to audio or either a NumPy array or Tensor containing the audio waveform in 16 kHz

	n_mels: int
	The number of Mel-frequency filters, only 80 is supported

	padding: int
	Number of zero samples to pad to the right

	device: Optional[Union[str, torch.device]]
	If given, the audio tensor is moved to this device before STFT

	Returns
	-------
	torch.Tensor, shape = (80, n_frames)
	A Tensor that contains the Mel spectrogram
	"""
	if not torch.is_tensor(audio):
	if isinstance(audio, str):
	audio = load_audio(audio)
	audio = torch.from_numpy(audio)

	if device is not None:
	audio = audio.to(device)
	if padding > 0:
	audio = F.pad(audio, (0, padding))
	window = torch.hann_window(N_FFT).to(audio.device)
	stft = torch.stft(audio, N_FFT, HOP_LENGTH, window=window, return_complex=True)
	magnitudes = stft[..., :-1].abs() ** 2

	filters = mel_filters(audio.device, n_mels)
	mel_spec = filters @ magnitudes

	log_spec = torch.clamp(mel_spec, min=1e-10).log10()
	log_spec = torch.maximum(log_spec, log_spec.max() - 8.0)
	log_spec = (log_spec + 4.0) / 4.0
	return log_spec


	@dataclass
	class ModelDimensions:
	n_mels: int
	n_audio_ctx: int
	n_audio_state: int
	n_audio_head: int
	n_audio_layer: int
	n_vocab: int
	n_text_ctx: int
	n_text_state: int
	n_text_head: int
	n_text_layer: int


	class LayerNorm(nn.LayerNorm):
	def forward(self, x: Tensor) -> Tensor:
	# return super().forward(x.float()).type(x.dtype)
	return super().forward(x).type(x.dtype)




	class Linear(nn.Linear):
	def forward(self, x: Tensor) -> Tensor:
	return F.linear(
	x,
	self.weight.to(x.dtype),
	None if self.bias is None else self.bias.to(x.dtype),
	)


	class Conv1d(nn.Conv1d):
	def _conv_forward(
	self, x: Tensor, weight: Tensor, bias: Optional[Tensor]
	) -> Tensor:
	return super()._conv_forward(
	x, weight.to(x.dtype), None if bias is None else bias.to(x.dtype)
	)


	def sinusoids(length, channels, max_timescale=10000):
	"""Returns sinusoids for positional embedding"""
	assert channels % 2 == 0
	log_timescale_increment = np.log(max_timescale) / (channels // 2 - 1)
	inv_timescales = torch.exp(-log_timescale_increment * torch.arange(channels // 2))
	scaled_time = torch.arange(length)[:, np.newaxis] * inv_timescales[np.newaxis, :]
	return torch.cat([torch.sin(scaled_time), torch.cos(scaled_time)], dim=1)


	class MultiHeadAttention(nn.Module):
	def __init__(self, n_state: int, n_head: int):
	super().__init__()
	self.n_head = n_head
	self.query = Linear(n_state, n_state)
	self.key = Linear(n_state, n_state, bias=False)
	self.value = Linear(n_state, n_state)
	self.out = Linear(n_state, n_state)

	def forward(
	self,
	x: Tensor,
	xa: Optional[Tensor] = None,
	mask: Optional[Tensor] = None,
	kv_cache: Optional[dict] = None,
	):
	q = self.query(x)

	if kv_cache is None or xa is None or self.key not in kv_cache:
	# hooks, if installed (i.e. kv_cache is not None), will prepend the cached kv tensors;
	# otherwise, perform key/value projections for self- or cross-attention as usual.
	k = self.key(x if xa is None else xa)
	v = self.value(x if xa is None else xa)
	else:
	# for cross-attention, calculate keys and values once and reuse in subsequent calls.
	k = kv_cache[self.key]
	v = kv_cache[self.value]

	wv, qk = self.qkv_attention(q, k, v, mask)
	return self.out(wv), qk

	def qkv_attention(
	self, q: Tensor, k: Tensor, v: Tensor, mask: Optional[Tensor] = None
	):
	n_batch, n_ctx, n_state = q.shape
	scale = (n_state // self.n_head) ** -0.25
	q = q.view(q.shape[:2], self.n_head, -1).permute(0, 2, 1, 3) scale
	k = k.view(k.shape[:2], self.n_head, -1).permute(0, 2, 3, 1) scale
	v = v.view(*v.shape[:2], self.n_head, -1).permute(0, 2, 1, 3)

	qk = q @ k
	if mask is not None:
	qk += mask

	w = F.softmax(qk, dim=-1).to(q.dtype)
	return (w @ v).permute(0, 2, 1, 3).flatten(start_dim=2), qk.detach()


	class ResidualAttentionBlock(nn.Module):
	def __init__(self, n_state: int, n_head: int, cross_attention: bool = False):
	super().__init__()

	self.attn = MultiHeadAttention(n_state, n_head)
	self.attn_ln = LayerNorm(n_state)

	self.cross_attn = (
	MultiHeadAttention(n_state, n_head) if cross_attention else None
	)
	self.cross_attn_ln = LayerNorm(n_state) if cross_attention else None

	n_mlp = n_state * 4
	self.mlp = nn.Sequential(
	Linear(n_state, n_mlp), nn.GELU(), Linear(n_mlp, n_state)
	)
	self.mlp_ln = LayerNorm(n_state)

	def forward(
	self,
	x: Tensor,
	xa: Optional[Tensor] = None,
	mask: Optional[Tensor] = None,
	kv_cache: Optional[dict] = None,
	):
	x = x + self.attn(self.attn_ln(x), mask=mask, kv_cache=kv_cache)[0]
	if self.cross_attn:
	x = x + self.cross_attn(self.cross_attn_ln(x), xa, kv_cache=kv_cache)[0]
	x = x + self.mlp(self.mlp_ln(x))
	return x


	class AudioEncoder(nn.Module):
	def __init__(
	self,
	n_mels: int,
	n_ctx: int,
	n_state: int,
	n_head: int,
	n_layer: int,
	output_dim: int = 512,
	avg_pool: bool = True,
	add_audio_bos_eos_token: bool = True,
	**kwargs
	):
	super().__init__()
	self.conv1 = Conv1d(n_mels, n_state, kernel_size=3, padding=1)
	self.conv2 = Conv1d(n_state, n_state, kernel_size=3, stride=2, padding=1)
	self.register_buffer("positional_embedding", sinusoids(n_ctx, n_state))

	self.blocks: Iterable[ResidualAttentionBlock] = nn.ModuleList(
	[ResidualAttentionBlock(n_state, n_head) for _ in range(n_layer)]
	)
	self.ln_post = LayerNorm(n_state)

	if avg_pool:
	self.avg_pooler = nn.AvgPool1d(2, stride=2)
	else:
	self.avg_pooler = None
	self.proj = nn.Linear(n_state, output_dim)
	if add_audio_bos_eos_token:
	self.audio_bos_eos_token = nn.Embedding(2, output_dim)
	else:
	self.audio_bos_eos_token = None
	self.output_dim = output_dim
	self.n_head = n_head

	def forward(self, x: Tensor, padding_mask: Tensor=None, audio_lengths: Tensor=None):
	"""
	x : torch.Tensor, shape = (batch_size, n_mels, n_ctx)
	the mel spectrogram of the audio
	"""
	x = x.to(dtype=self.conv1.weight.dtype,
	device=self.conv1.weight.device)
	if audio_lengths is not None:
	input_mel_len = audio_lengths[:,0] * 2
	max_mel_len_in_batch = input_mel_len.max()
	x = x[:, :, :max_mel_len_in_batch]
	x = F.gelu(self.conv1(x))
	x = F.gelu(self.conv2(x))
	x = x.permute(0, 2, 1) # B, L, D
	bsz = x.size(0)
	src_len = x.size(1)


	self.input_positional_embedding = self.positional_embedding[:src_len]
	assert x.shape[1:] == self.input_positional_embedding.shape, f"incorrect audio shape: {x.shape[1:], self.input_positional_embedding.shape}"
	x = (x + self.input_positional_embedding).to(x.dtype)
	if padding_mask is not None:
	padding_mask = padding_mask.to(dtype=self.conv1.weight.dtype,
	device=self.conv1.weight.device)
	batch_src_len = padding_mask.size(1)
	x = x[:, :batch_src_len, :]
	padding_mask = padding_mask.view(
	bsz, -1, batch_src_len
	)
	padding_mask_ = padding_mask.all(1)
	x[padding_mask_] = 0
	key_padding_mask = padding_mask_.view(bsz, 1, 1, batch_src_len). \
	expand(-1, self.n_head, -1, -1).reshape(bsz, self.n_head, 1, batch_src_len)
	new_padding_mask = torch.zeros_like(key_padding_mask, dtype=x.dtype)
	padding_mask = new_padding_mask.masked_fill(key_padding_mask, float("-inf"))

	for block in self.blocks:
	x = block(x, mask=padding_mask)


	if self.avg_pooler:
	x = x.permute(0, 2, 1)
	x = self.avg_pooler(x)
	x = x.permute(0, 2, 1)


	x = self.ln_post(x)
	x = self.proj(x)

	if self.audio_bos_eos_token is not None:
	bos = self.audio_bos_eos_token.weight[0][None, :]
	eos = self.audio_bos_eos_token.weight[1][None, :]
	else:
	bos, eos = None, None
	return x, bos, eos

	def encode(self, input_audios: Tensor, input_audio_lengths: Tensor, audio_span_tokens: List):
	real_input_audio_lens = input_audio_lengths[:, 0].tolist()
	max_len_in_batch = max(real_input_audio_lens)
	padding_mask = torch.ones([input_audios.size(0), max_len_in_batch]).to(dtype=self.conv1.weight.dtype,
	device=self.conv1.weight.device)
	for index in range(len(input_audios)):
	padding_mask[index, :input_audio_lengths[index][0].item()] = 0
	x, bos, eos = self(input_audios, padding_mask,input_audio_lengths)
	output_audios = []
	for i in range(len(audio_span_tokens)):
	audio_span = audio_span_tokens[i]
	audio = x[i][:audio_span-2]
	if bos is not None:
	audio = torch.concat([bos, audio, eos])
	assert len(audio) == audio_span
	output_audios.append(audio)
	return output_audios