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# from aria.tokenizer import AbsTokenizer
# aria_tokenizer = AbsTokenizer()
import copy
import json
from typing import Optional, Any, Union, Callable
import torch.multiprocessing as mp
from torch.nn import DataParallel
import jsonlines
import math
import time
import torch
import os
import warnings
from tqdm import tqdm
from torch import Tensor
# from aria.tokenizer import AbsTokenizer
import pickle
from torch.nn import Module, LayerNorm, Dropout, Linear
from torch.nn.modules.container import ModuleList
from torch.nn.modules.activation import MultiheadAttention
from torch.nn.init import xavier_uniform_
import torch.nn.functional as F
import torch.nn as nn
from st_moe_pytorch import MoE
from st_moe_pytorch import SparseMoEBlock
from einops import rearrange
from transformers import T5Tokenizer, T5EncoderModel
__all__ = ['Transformer', 'TransformerEncoder', 'TransformerDecoder', 'TransformerEncoderLayer', 'TransformerDecoderLayer']
def _generate_square_subsequent_mask(
sz: int,
device: Optional[torch.device] = None,
dtype: Optional[torch.dtype] = None,
) -> Tensor:
r"""Generate a square causal mask for the sequence.
The masked positions are filled with float('-inf'). Unmasked positions are filled with float(0.0).
"""
if device is None:
device = torch.device('cpu')
if dtype is None:
dtype = torch.float32
return torch.triu(
torch.full((sz, sz), float('-inf'), dtype=dtype, device=device),
diagonal=1,
)
def _get_seq_len(
src: Tensor,
batch_first: bool
) -> Optional[int]:
if src.is_nested:
return None
else:
src_size = src.size()
if len(src_size) == 2:
# unbatched: S, E
return src_size[0]
else:
# batched: B, S, E if batch_first else S, B, E
seq_len_pos = 1 if batch_first else 0
return src_size[seq_len_pos]
class PositionalEncoding(nn.Module):
r"""Inject some information about the relative or absolute position of the tokens in the sequence.
The positional encodings have the same dimension as the embeddings, so that the two can be summed.
Here, we use sine and cosine functions of different frequencies.
.. math:
\text{PosEncoder}(pos, 2i) = sin(pos/10000^(2i/d_model))
\text{PosEncoder}(pos, 2i+1) = cos(pos/10000^(2i/d_model))
\text{where pos is the word position and i is the embed idx)
Args:
d_model: the embed dim (required).
dropout: the dropout value (default=0.1).
max_len: the max. length of the incoming sequence (default=5000).
Examples:
>>> pos_encoder = PositionalEncoding(d_model)
"""
def __init__(self, d_model, dropout=0.1, max_len=5000):
super(PositionalEncoding, self).__init__()
self.dropout = nn.Dropout(p=dropout)
pe = torch.zeros(max_len, d_model)
position = torch.arange(0, max_len, dtype=torch.float).unsqueeze(1)
div_term = torch.exp(torch.arange(0, d_model, 2).float() * (-math.log(10000.0) / d_model))
pe[:, 0::2] = torch.sin(position * div_term)
pe[:, 1::2] = torch.cos(position * div_term)
pe = pe.unsqueeze(0).transpose(0, 1)
# self.register_buffer('pe', pe)
self.register_parameter('pe', nn.Parameter(pe, requires_grad=False))
def forward(self, x):
r"""Inputs of forward function
Args:
x: the sequence fed to the positional encoder model (required).
Shape:
x: [sequence length, batch size, embed dim]
output: [sequence length, batch size, embed dim]
Examples:
>>> output = pos_encoder(x)
"""
x = x + self.pe[:x.size(0), :]
return self.dropout(x)
def precompute_freqs_cis(
seq_len: int,
n_elem: int,
base: int = 10000,
dtype: torch.dtype = torch.bfloat16,
):
freqs = 1.0 / (
base ** (torch.arange(0, n_elem, 2)[: (n_elem // 2)].float() / n_elem)
)
t = torch.arange(seq_len, device=freqs.device)
freqs = torch.outer(t, freqs)
freqs_cis = torch.polar(torch.ones_like(freqs), freqs)
cache = torch.stack([freqs_cis.real, freqs_cis.imag], dim=-1)
return cache.to(dtype=dtype)
@torch.jit.script
def apply_rotary_emb(x: torch.Tensor, freqs_cis: torch.Tensor) -> torch.Tensor:
"""
In-place RoPE. Credits to Katherine Crowson:
x shape (b_sz, n_head, s_len, d_head).
cos, sin shape (s_len, d_head // 2).
"""
x = x.permute(0, 2, 1, 3)
d = x.shape[-1] // 2
cos = freqs_cis[..., 0][None, :, None]
sin = freqs_cis[..., 1][None, :, None]
x1, x2 = x[..., :d], x[..., d : d * 2]
tmp = x1.clone()
# x1.mul_(cos).addcmul_(x2, sin, value=-1)
# x2.mul_(cos).addcmul_(tmp, sin, value=1) ##was throwing some error: RuntimeError: Output 0 of SliceBackward0 is a view and is being modified inplace. This view is the output of a function that returns multiple views. Such functions do not allow the output views to be modified inplace. You should replace the inplace operation by an out-of-place one.
x1_new = x1.mul(cos) - x2.mul(sin)
x2_new = x2.mul(cos) + tmp.mul(sin)
x = torch.cat((x1_new, x2_new), dim=-1)
x = x.permute(0, 2, 1, 3)
return x
class MultiHeadSelfAttention(nn.Module):
r"""Multi-head self-attention module.
Args:
embed_dim (int): The input embedding dimension.
num_heads (int, optional): The number of attention heads (default: 4).
dropout (float, optional): The dropout probability (default: 0.1).
device (torch.device, optional): The device to use (default: None).
dtype (torch.dtype, optional): The data type to use (default: None).
Attributes:
dim_head (int): The dimension of each attention head.
scale (float): The scaling factor for attention scores.
heads (int): The number of attention heads.
to_qkv (nn.Linear): Linear layer for projecting input to query, key, and value.
to_out (nn.Linear): Linear layer for projecting attention output to the original embedding dimension.
dropout (nn.Dropout): Dropout layer.
"""
def __init__(
self,
embed_dim: int,
num_heads: int = 4,
dropout: float = 0.1,
batch_first: bool = True,
device: Optional[torch.device] = None,
dtype: Optional[torch.dtype] = None,
):
factory_kwargs = {'device': device, 'dtype': dtype}
super().__init__()
self.embed_dim = embed_dim
self.batch_first = batch_first
self.dim_head = embed_dim // num_heads
self.scale = self.dim_head ** -0.5
self.heads = num_heads
hidden_dim = self.dim_head * num_heads
self.to_qkv = nn.Linear(embed_dim, hidden_dim * 3, bias=False, **factory_kwargs)
self.to_out = nn.Linear(hidden_dim, embed_dim, bias=False, **factory_kwargs)
self.dropout = nn.Dropout(dropout)
def forward(self, x: torch.Tensor, is_causal: bool = True) -> torch.Tensor:
r"""Forward pass of the multi-head self-attention module.
Args:
x (torch.Tensor): The input tensor of shape (batch_size, sequence_length, embed_dim).
Returns:
torch.Tensor: The output tensor of shape (batch_size, sequence_length, embed_dim).
"""
if not self.batch_first:
x = x.transpose(0, 1)
b, n, _ = x.size()
q, k, v = torch.chunk(self.to_qkv(x), chunks=3, dim=-1)
q, k, v = map(lambda t: t.contiguous().view(b, self.heads, n, -1), (q, k, v))
self.freqs_cis = precompute_freqs_cis(
seq_len=n,
n_elem=self.embed_dim // self.heads,
base=10000,
dtype=x.dtype,
).to(x.device)
freqs_cis = self.freqs_cis[: x.shape[1]]
# q = apply_rotary_emb(q, freqs_cis)
# k = apply_rotary_emb(k, freqs_cis)
out = torch.nn.functional.scaled_dot_product_attention(q, k, v, is_causal=is_causal)
out = out.contiguous().view(b, n, -1)
out = self.dropout(out)
return self.to_out(out)
class Transformer(Module):
r"""A transformer model.
User is able to modify the attributes as needed. The architecture
is based on the paper "Attention Is All You Need". Ashish Vaswani, Noam Shazeer,
Niki Parmar, Jakob Uszkoreit, Llion Jones, Aidan N Gomez, Lukasz Kaiser, and
Illia Polosukhin. 2017. Attention is all you need. In Advances in Neural Information
Processing Systems, pages 6000-6010.
Args:
d_model: the number of expected features in the encoder/decoder inputs (default=512).
nhead: the number of heads in the multiheadattention models (default=8).
num_encoder_layers: the number of sub-encoder-layers in the encoder (default=6).
num_decoder_layers: the number of sub-decoder-layers in the decoder (default=6).
dim_feedforward: the dimension of the feedforward network model (default=2048).
use_moe: if True, use MoE instead of linear layer for feedforward network (default=False).
dropout: the dropout value (default=0.1).
activation: the activation function of encoder/decoder intermediate layer, can be a string
("relu" or "gelu") or a unary callable. Default: relu
custom_encoder: custom encoder (default=None).
custom_decoder: custom decoder (default=None).
layer_norm_eps: the eps value in layer normalization components (default=1e-5).
batch_first: If ``True``, then the input and output tensors are provided
as (batch, seq, feature). Default: ``False`` (seq, batch, feature).
norm_first: if ``True``, encoder and decoder layers will perform LayerNorms before
other attention and feedforward operations, otherwise after. Default: ``False`` (after).
bias: If set to ``False``, ``Linear`` and ``LayerNorm`` layers will not learn an additive
bias. Default: ``True``.
Examples::
>>> transformer_model = nn.Transformer(nhead=16, num_encoder_layers=12)
>>> src = torch.rand((32, 512))
>>> tgt = torch.rand((32, 512, 30000))
>>> out = transformer_model(src, tgt)
Note: A full example to apply nn.Transformer module for the word language model is available in
https://github.com/pytorch/examples/tree/master/word_language_model
"""
def __init__(self, n_vocab: int = 30000, d_model: int = 512, nhead: int = 8, max_len: int = 5000,
num_decoder_layers: int = 6, dim_feedforward: int = 2048, use_moe: bool = False,
num_experts: int = 16, dropout: float = 0.1,
activation: Union[str, Callable[[Tensor], Tensor]] = F.relu,
layer_norm_eps: float = 1e-5, batch_first: bool = True, norm_first: bool = False,
bias: bool = True, device=None, dtype=None) -> None:
factory_kwargs = {'device': device, 'dtype': dtype}
super().__init__()
torch._C._log_api_usage_once(f"torch.nn.modules.{self.__class__.__name__}")
self.use_moe = use_moe
self.input_emb = nn.Embedding(n_vocab, d_model, **factory_kwargs)
self.pos_encoder = PositionalEncoding(d_model, dropout, max_len).to(device)
# Load the FLAN-T5 encoder
self.encoder = T5EncoderModel.from_pretrained("google/flan-t5-base").to(device)
# Freeze the encoder
for param in self.encoder.parameters():
param.requires_grad = False
decoder_layer = TransformerDecoderLayer(d_model, nhead, dim_feedforward, use_moe, num_experts, dropout,
activation, layer_norm_eps, batch_first, norm_first,
bias, **factory_kwargs)
decoder_norm = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.decoder = TransformerDecoder(decoder_layer, num_decoder_layers, use_moe, decoder_norm)
self.projection = nn.Linear(d_model, n_vocab).to(device)
self._reset_parameters()
self.d_model = d_model
self.nhead = nhead
self.batch_first = batch_first
def forward(self, src: Tensor, src_mask: Tensor, tgt: Tensor, memory_mask: Optional[Tensor] = None,
memory_key_padding_mask: Optional[Tensor] = None, tgt_is_causal: bool = True,
memory_is_causal: bool = False) -> Tensor:
r"""Take in and process masked source/target sequences.
.. note::
If a boolean tensor is provided for any of the [src/tgt/memory]_mask arguments, positions with a ``True`` value are
not allowed to participate in the attention,
which is the opposite of the definition for :attr:`attn_mask`
in :func:`torch.nn.functional.scaled_dot_product_attention`.
Args:
src: the sequence to the encoder (required).
src_attn_mask: the attention mask for the src sequence (required).
tgt: the sequence to the decoder (required).
tgt_mask: the additive mask for the tgt sequence (optional).
memory_mask: the additive mask for the encoder output (optional).
tgt_key_padding_mask: the Tensor mask for tgt keys per batch (optional).
memory_key_padding_mask: the Tensor mask for memory keys per batch (optional).
tgt_is_causal: If specified, applies a causal mask as ``tgt_mask``.
Default: ``None``; try to detect a causal mask.
Warning:
``tgt_is_causal`` provides a hint that ``tgt_mask`` is
the causal mask. Providing incorrect hints can result in
incorrect execution, including forward and backward
compatibility.
memory_is_causal: If specified, applies a causal mask as
``memory_mask``.
Default: ``False``.
Warning:
``memory_is_causal`` provides a hint that
``memory_mask`` is the causal mask. Providing incorrect
hints can result in incorrect execution, including
forward and backward compatibility.
Shape:
- src: :math:`(S, S)` for unbatched input, :math:`(S, N)` if `batch_first=False` or
`(N, S)` if `batch_first=True`.
- src_mask: :math:`(S, S)` or :math:`(N\cdot\text{num\_heads}, S, S)`.
- tgt: :math:`(T, E)` for unbatched input, :math:`(T, N, E)` if `batch_first=False` or
`(N, T, E)` if `batch_first=True`.
- tgt_mask: :math:`(T, T)` or :math:`(N\cdot\text{num\_heads}, T, T)`.
- memory_mask: :math:`(T, S)`.
- src_key_padding_mask: :math:`(S)` for unbatched input otherwise :math:`(N, S)`.
- tgt_key_padding_mask: :math:`(T)` for unbatched input otherwise :math:`(N, T)`.
- memory_key_padding_mask: :math:`(S)` for unbatched input otherwise :math:`(N, S)`.
Note: [src/tgt/memory]_mask ensures that position :math:`i` is allowed to attend the unmasked
positions. If a BoolTensor is provided, positions with ``True``
are not allowed to attend while ``False`` values will be unchanged. If a FloatTensor
is provided, it will be added to the attention weight.
[src/tgt/memory]_key_padding_mask provides specified elements in the key to be ignored by
the attention. If a BoolTensor is provided, the positions with the
value of ``True`` will be ignored while the position with the value of ``False`` will be unchanged.
- output: :math:`(T, E)` for unbatched input, :math:`(T, N, E)` if `batch_first=False` or
`(N, T, E)` if `batch_first=True`.
Note: Due to the multi-head attention architecture in the transformer model,
the output sequence length of a transformer is same as the input sequence
(i.e. target) length of the decoder.
where :math:`S` is the source sequence length, :math:`T` is the target sequence length, :math:`N` is the
batch size, :math:`E` is the feature number
Examples:
>>> # xdoctest: +SKIP
>>> output = transformer_model(src, tgt, src_mask=src_mask)
"""
if src.dim() != tgt.dim():
raise RuntimeError("the number of dimensions in src and tgt must be equal")
memory = self.encoder(src, attention_mask=src_mask).last_hidden_state
tgt = self.input_emb(tgt) * math.sqrt(self.d_model)
tgt = self.pos_encoder(tgt)
# tgt = tgt + tgt_pos
if self.use_moe:
with torch.cuda.amp.autocast(enabled =False):
output, sum_total_aux_loss = self.decoder(tgt, memory, memory_mask=memory_mask,
memory_key_padding_mask=memory_key_padding_mask,
tgt_is_causal=tgt_is_causal, memory_is_causal=memory_is_causal)
else:
output = self.decoder(tgt, memory, memory_mask=memory_mask,
memory_key_padding_mask=memory_key_padding_mask,
tgt_is_causal=tgt_is_causal, memory_is_causal=memory_is_causal)
output = self.projection(output)
# output = F.log_softmax(output, dim=-1)
if self.use_moe:
return output, sum_total_aux_loss
else:
return output
def generate(self, src: Tensor, src_mask: Tensor, max_len: int = 100, temperature: float = 1.0):
## ADD A START OF SEQUENCE TOKEN <SS> token to the src tensor
r"""Generate a sequence of tokens from the given inputs.
Args:
src: the sequence to the encoder (required).
src_mask: the attention mask for the src sequence (required).
max_len: the maximum length of the sequence to generate (default=100).
temperature: the temperature for the softmax (default=1.0).
Returns:
torch.Tensor: The generated sequence of tokens.
"""
if src.dim() != 2:
raise RuntimeError("The src tensor should be 2-dimensional")
tgt_fin = torch.full((src.size(0), 1), 1, dtype=torch.long, device=src.device)
# values = [21631, 8, 10, 9, 6, 7, 17, 21632, 11474, 20626, 21151, 9426, 20627, 21143, 11476, 20640, 21143, 11477, 20655, 21145, 11476, 20669, 21145, 11477, 20683, 21145, 13527, 20697, 21146, 13529, 20712, 21145, 7013, 20769, 21143, 7006, 20769, 21143, 7006, 20769, 21141, 7009, 20769, 21143, 9426, 20797, 21144, 11474, 20797, 21173, 11476, 20812, 21144, 11477, 20826, 21145, 11476, 20840, 21145, 11477, 20855, 21145, 13527, 20869, 21144, 13529, 20883, 21143, 7006, 20940, 21139, 7013, 20940, 21140, 7006, 20940, 21147, 7009, 20940, 21147, 11474, 20969, 21144, 11474, 20969, 21170, 11476, 20983, 21144, 11477, 20997, 21145, 11476, 21012, 21144, 11477, 21026, 21144, 11479, 21040]
# values_tensor = torch.tensor(values, dtype=torch.long, device=src.device)
# tgt_fin = values_tensor.unsqueeze(0).repeat(src.size(0), 1)
for i in tqdm(range(max_len)):
max_index = tgt_fin.max()
# assert max_index < 21634, "tgt_fin contains index out of range. Adjust n_vocab or fix tgt_fin indices."
tgt = tgt_fin
if self.use_moe:
output, _ = self.froward(src, src_mask, tgt, memory_mask=None,
memory_key_padding_mask=None,
tgt_is_causal=True, memory_is_causal=False)
else:
output = self.forward(src, src_mask, tgt, memory_mask=None,
memory_key_padding_mask=None,
tgt_is_causal=True, memory_is_causal=False)
# logits = self.projection(output)
logits = output
output = F.log_softmax(logits/temperature, dim=-1)
output = output.view(-1, output.size(-1))
next_tokens = torch.multinomial(torch.exp(output), 1)[-1] # taking the last logit and adding to the sequence
tgt_fin = torch.cat((tgt_fin, next_tokens.unsqueeze(-1)), dim=1)
return tgt_fin[:, 1:]
@staticmethod
def generate_square_subsequent_mask(
sz: int,
device: Optional[torch.device] = None,
dtype: Optional[torch.dtype] = None,
) -> Tensor:
r"""Generate a square causal mask for the sequence.
The masked positions are filled with float('-inf'). Unmasked positions are filled with float(0.0).
"""
return _generate_square_subsequent_mask(sz, dtype=dtype, device=device)
def _reset_parameters(self):
r"""Initiate parameters in the transformer model."""
for p in self.parameters():
if p.dim() > 1:
xavier_uniform_(p)
class TransformerEncoder(Module):
r"""TransformerEncoder is a stack of N encoder layers.
Users can build the BERT(https://arxiv.org/abs/1810.04805) model with corresponding parameters.
Args:
encoder_layer: an instance of the TransformerEncoderLayer() class (required).
num_layers: the number of sub-encoder-layers in the encoder (required).
norm: the layer normalization component (optional).
enable_nested_tensor: if True, input will automatically convert to nested tensor
(and convert back on output). This will improve the overall performance of
TransformerEncoder when padding rate is high. Default: ``True`` (enabled).
Examples::
>>> encoder_layer = nn.TransformerEncoderLayer(d_model=512, nhead=8)
>>> transformer_encoder = nn.TransformerEncoder(encoder_layer, num_layers=6)
>>> src = torch.rand(10, 32, 512)
>>> out = transformer_encoder(src)
"""
__constants__ = ['norm']
def __init__(
self,
encoder_layer: "TransformerEncoderLayer",
num_layers: int,
norm: Optional[Module] = None,
enable_nested_tensor: bool = True,
mask_check: bool = True
) -> None:
super().__init__()
torch._C._log_api_usage_once(f"torch.nn.modules.{self.__class__.__name__}")
self.layers = _get_clones(encoder_layer, num_layers)
self.num_layers = num_layers
self.norm = norm
# this attribute saves the value providedat object construction
self.enable_nested_tensor = enable_nested_tensor
# this attribute controls whether nested tensors are used
self.use_nested_tensor = enable_nested_tensor
self.mask_check = mask_check
enc_layer = "encoder_layer"
why_not_sparsity_fast_path = ''
if not isinstance(encoder_layer, torch.nn.TransformerEncoderLayer):
why_not_sparsity_fast_path = f"{enc_layer} was not TransformerEncoderLayer"
elif encoder_layer.norm_first :
why_not_sparsity_fast_path = f"{enc_layer}.norm_first was True"
elif not encoder_layer.self_attn.batch_first:
why_not_sparsity_fast_path = (f"{enc_layer}.self_attn.batch_first was not True" +
"(use batch_first for better inference performance)")
elif not encoder_layer.self_attn._qkv_same_embed_dim:
why_not_sparsity_fast_path = f"{enc_layer}.self_attn._qkv_same_embed_dim was not True"
elif encoder_layer.self_attn.in_proj_bias is None:
why_not_sparsity_fast_path = f"{enc_layer}.self_attn was passed bias=False"
elif not encoder_layer.activation_relu_or_gelu:
why_not_sparsity_fast_path = f"{enc_layer}.activation_relu_or_gelu was not True"
elif not (encoder_layer.norm1.eps == encoder_layer.norm2.eps) :
why_not_sparsity_fast_path = f"{enc_layer}.norm1.eps was not equal to {enc_layer}.norm2.eps"
elif encoder_layer.self_attn.num_heads % 2 == 1:
why_not_sparsity_fast_path = f"{enc_layer}.self_attn.num_heads is odd"
if enable_nested_tensor and why_not_sparsity_fast_path:
warnings.warn(f"enable_nested_tensor is True, but self.use_nested_tensor is False because {why_not_sparsity_fast_path}")
self.use_nested_tensor = False
def forward(
self,
src: Tensor,
mask: Optional[Tensor] = None,
src_key_padding_mask: Optional[Tensor] = None,
is_causal: Optional[bool] = None) -> Tensor:
r"""Pass the input through the encoder layers in turn.
Args:
src: the sequence to the encoder (required).
mask: the mask for the src sequence (optional).
src_key_padding_mask: the mask for the src keys per batch (optional).
is_causal: If specified, applies a causal mask as ``mask``.
Default: ``None``; try to detect a causal mask.
Warning:
``is_causal`` provides a hint that ``mask`` is the
causal mask. Providing incorrect hints can result in
incorrect execution, including forward and backward
compatibility.
Shape:
see the docs in :class:`~torch.nn.Transformer`.
"""
src_key_padding_mask = F._canonical_mask(
mask=src_key_padding_mask,
mask_name="src_key_padding_mask",
other_type=F._none_or_dtype(mask),
other_name="mask",
target_type=src.dtype
)
mask = F._canonical_mask(
mask=mask,
mask_name="mask",
other_type=None,
other_name="",
target_type=src.dtype,
check_other=False,
)
output = src
convert_to_nested = False
first_layer = self.layers[0]
src_key_padding_mask_for_layers = src_key_padding_mask
why_not_sparsity_fast_path = ''
str_first_layer = "self.layers[0]"
batch_first = first_layer.self_attn.batch_first
# is_fastpath_enabled = torch.backends.mha.get_fastpath_enabled()
# if not is_fastpath_enabled:
# why_not_sparsity_fast_path = "torch.backends.mha.get_fastpath_enabled() was not True"
if not hasattr(self, "use_nested_tensor"):
why_not_sparsity_fast_path = "use_nested_tensor attribute not present"
elif not self.use_nested_tensor:
why_not_sparsity_fast_path = "self.use_nested_tensor (set in init) was not True"
elif first_layer.training:
why_not_sparsity_fast_path = f"{str_first_layer} was in training mode"
elif not src.dim() == 3:
why_not_sparsity_fast_path = f"input not batched; expected src.dim() of 3 but got {src.dim()}"
elif src_key_padding_mask is None:
why_not_sparsity_fast_path = "src_key_padding_mask was None"
elif (((not hasattr(self, "mask_check")) or self.mask_check)
and not torch._nested_tensor_from_mask_left_aligned(src, src_key_padding_mask.logical_not())):
why_not_sparsity_fast_path = "mask_check enabled, and src and src_key_padding_mask was not left aligned"
elif output.is_nested:
why_not_sparsity_fast_path = "NestedTensor input is not supported"
elif mask is not None:
why_not_sparsity_fast_path = "src_key_padding_mask and mask were both supplied"
elif torch.is_autocast_enabled():
why_not_sparsity_fast_path = "autocast is enabled"
if not why_not_sparsity_fast_path:
tensor_args = (
src,
first_layer.self_attn.in_proj_weight,
first_layer.self_attn.in_proj_bias,
first_layer.self_attn.out_proj.weight,
first_layer.self_attn.out_proj.bias,
first_layer.norm1.weight,
first_layer.norm1.bias,
first_layer.norm2.weight,
first_layer.norm2.bias,
first_layer.linear1.weight,
first_layer.linear1.bias,
first_layer.linear2.weight,
first_layer.linear2.bias,
)
_supported_device_type = ["cpu", "cuda", torch.utils.backend_registration._privateuse1_backend_name]
if torch.overrides.has_torch_function(tensor_args):
why_not_sparsity_fast_path = "some Tensor argument has_torch_function"
elif src.device.type not in _supported_device_type:
why_not_sparsity_fast_path = f"src device is neither one of {_supported_device_type}"
elif torch.is_grad_enabled() and any(x.requires_grad for x in tensor_args):
why_not_sparsity_fast_path = ("grad is enabled and at least one of query or the "
"input/output projection weights or biases requires_grad")
if (not why_not_sparsity_fast_path) and (src_key_padding_mask is not None):
convert_to_nested = True
output = torch._nested_tensor_from_mask(output, src_key_padding_mask.logical_not(), mask_check=False)
src_key_padding_mask_for_layers = None
seq_len = _get_seq_len(src, batch_first)
is_causal = _detect_is_causal_mask(mask, is_causal, seq_len)
for mod in self.layers:
output = mod(output, src_mask=mask, is_causal=is_causal, src_key_padding_mask=src_key_padding_mask_for_layers)
if convert_to_nested:
output = output.to_padded_tensor(0., src.size())
if self.norm is not None:
output = self.norm(output)
return output
class TransformerDecoder(Module):
r"""TransformerDecoder is a stack of N decoder layers.
Args:
decoder_layer: an instance of the TransformerDecoderLayer() class (required).
num_layers: the number of sub-decoder-layers in the decoder (required).
norm: the layer normalization component (optional).
Examples::
>>> decoder_layer = nn.TransformerDecoderLayer(d_model=512, nhead=8)
>>> transformer_decoder = nn.TransformerDecoder(decoder_layer, num_layers=6)
>>> memory = torch.rand(10, 32, 512)
>>> tgt = torch.rand(20, 32, 512)
>>> out = transformer_decoder(tgt, memory)
"""
__constants__ = ['norm']
def __init__(
self,
decoder_layer: "TransformerDecoderLayer",
num_layers: int,
use_moe: bool = False,
norm: Optional[Module] = None
) -> None:
super().__init__()
torch._C._log_api_usage_once(f"torch.nn.modules.{self.__class__.__name__}")
self.layers = _get_clones(decoder_layer, num_layers)
self.num_layers = num_layers
self.use_moe = use_moe
self.norm = norm
def forward(self, tgt: Tensor, memory: Tensor, tgt_mask: Optional[Tensor] = None,
memory_mask: Optional[Tensor] = None,
memory_key_padding_mask: Optional[Tensor] = None, tgt_is_causal: Optional[bool] = None,
memory_is_causal: bool = False) -> Tensor:
r"""Pass the inputs (and mask) through the decoder layer in turn.
Args:
tgt: the sequence to the decoder (required).
memory: the sequence from the last layer of the encoder (required).
tgt_mask: the mask for the tgt sequence (optional).
memory_mask: the mask for the memory sequence (optional).
memory_key_padding_mask: the mask for the memory keys per batch (optional).
tgt_is_causal: If specified, applies a causal mask as ``tgt mask``.
Default: ``None``; try to detect a causal mask.
Warning:
``tgt_is_causal`` provides a hint that ``tgt_mask`` is
the causal mask. Providing incorrect hints can result in
incorrect execution, including forward and backward
compatibility.
memory_is_causal: If specified, applies a causal mask as
``memory mask``.
Default: ``False``.
Warning:
``memory_is_causal`` provides a hint that
``memory_mask`` is the causal mask. Providing incorrect
hints can result in incorrect execution, including
forward and backward compatibility.
Shape:
see the docs in :class:`~torch.nn.Transformer`.
"""
output = tgt
seq_len = _get_seq_len(tgt, self.layers[0].self_attn.batch_first)
tgt_is_causal = _detect_is_causal_mask(tgt_mask, tgt_is_causal, seq_len)
# print(f'target is causal: {tgt_is_causal}')
if self.use_moe:
sum_total_aux_loss = 0
for mod in self.layers:
output, total_aux_loss, balance_loss, router_z_loss = mod(output, memory,
memory_mask=memory_mask,
memory_key_padding_mask=memory_key_padding_mask,
tgt_is_causal=tgt_is_causal,
memory_is_causal=memory_is_causal)
sum_total_aux_loss += total_aux_loss
else:
for mod in self.layers:
output = mod(output, memory,
memory_mask=memory_mask,
memory_key_padding_mask=memory_key_padding_mask,
tgt_is_causal=tgt_is_causal,
memory_is_causal=memory_is_causal)
if self.norm is not None:
output = self.norm(output)
if self.use_moe:
return output, sum_total_aux_loss
else:
return output
class TransformerEncoderLayer(Module):
r"""TransformerEncoderLayer is made up of self-attn and feedforward network.
This standard encoder layer is based on the paper "Attention Is All You Need".
Ashish Vaswani, Noam Shazeer, Niki Parmar, Jakob Uszkoreit, Llion Jones, Aidan N Gomez,
Lukasz Kaiser, and Illia Polosukhin. 2017. Attention is all you need. In Advances in
Neural Information Processing Systems, pages 6000-6010. Users may modify or implement
in a different way during application.
TransformerEncoderLayer can handle either traditional torch.tensor inputs,
or Nested Tensor inputs. Derived classes are expected to similarly accept
both input formats. (Not all combinations of inputs are currently
supported by TransformerEncoderLayer while Nested Tensor is in prototype
state.)
If you are implementing a custom layer, you may derive it either from
the Module or TransformerEncoderLayer class. If your custom layer
supports both torch.Tensors and Nested Tensors inputs, make its
implementation a derived class of TransformerEncoderLayer. If your custom
Layer supports only torch.Tensor inputs, derive its implementation from
Module.
Args:
d_model: the number of expected features in the input (required).
nhead: the number of heads in the multiheadattention models (required).
dim_feedforward: the dimension of the feedforward network model (default=2048).
dropout: the dropout value (default=0.1).
activation: the activation function of the intermediate layer, can be a string
("relu" or "gelu") or a unary callable. Default: relu
layer_norm_eps: the eps value in layer normalization components (default=1e-5).
batch_first: If ``True``, then the input and output tensors are provided
as (batch, seq, feature). Default: ``False`` (seq, batch, feature).
norm_first: if ``True``, layer norm is done prior to attention and feedforward
operations, respectively. Otherwise it's done after. Default: ``False`` (after).
bias: If set to ``False``, ``Linear`` and ``LayerNorm`` layers will not learn an additive
bias. Default: ``True``.
Examples::
>>> encoder_layer = nn.TransformerEncoderLayer(d_model=512, nhead=8)
>>> src = torch.rand(10, 32, 512)
>>> out = encoder_layer(src)
Alternatively, when ``batch_first`` is ``True``:
>>> encoder_layer = nn.TransformerEncoderLayer(d_model=512, nhead=8, batch_first=True)
>>> src = torch.rand(32, 10, 512)
>>> out = encoder_layer(src)
Fast path:
forward() will use a special optimized implementation described in
`FlashAttention: Fast and Memory-Efficient Exact Attention with IO-Awareness`_ if all of the following
conditions are met:
- Either autograd is disabled (using ``torch.inference_mode`` or ``torch.no_grad``) or no tensor
argument ``requires_grad``
- training is disabled (using ``.eval()``)
- batch_first is ``True`` and the input is batched (i.e., ``src.dim() == 3``)
- activation is one of: ``"relu"``, ``"gelu"``, ``torch.functional.relu``, or ``torch.functional.gelu``
- at most one of ``src_mask`` and ``src_key_padding_mask`` is passed
- if src is a `NestedTensor <https://pytorch.org/docs/stable/nested.html>`_, neither ``src_mask``
nor ``src_key_padding_mask`` is passed
- the two ``LayerNorm`` instances have a consistent ``eps`` value (this will naturally be the case
unless the caller has manually modified one without modifying the other)
If the optimized implementation is in use, a
`NestedTensor <https://pytorch.org/docs/stable/nested.html>`_ can be
passed for ``src`` to represent padding more efficiently than using a padding
mask. In this case, a `NestedTensor <https://pytorch.org/docs/stable/nested.html>`_ will be
returned, and an additional speedup proportional to the fraction of the input that
is padding can be expected.
.. _`FlashAttention: Fast and Memory-Efficient Exact Attention with IO-Awareness`:
https://arxiv.org/abs/2205.14135
"""
__constants__ = ['norm_first']
def __init__(self, d_model: int, nhead: int, dim_feedforward: int = 2048, dropout: float = 0.1,
activation: Union[str, Callable[[Tensor], Tensor]] = F.relu,
layer_norm_eps: float = 1e-5, batch_first: bool = False, norm_first: bool = False,
bias: bool = True, device=None, dtype=None) -> None:
factory_kwargs = {'device': device, 'dtype': dtype}
super().__init__()
self.self_attn = MultiheadAttention(d_model, nhead, dropout=dropout,
bias=bias, batch_first=batch_first,
**factory_kwargs)
# Implementation of Feedforward model
self.linear1 = Linear(d_model, dim_feedforward, bias=bias, **factory_kwargs)
self.dropout = Dropout(dropout)
self.linear2 = Linear(dim_feedforward, d_model, bias=bias, **factory_kwargs)
self.norm_first = norm_first
self.norm1 = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.norm2 = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.dropout1 = Dropout(dropout)
self.dropout2 = Dropout(dropout)
# Legacy string support for activation function.
if isinstance(activation, str):
activation = _get_activation_fn(activation)
# We can't test self.activation in forward() in TorchScript,
# so stash some information about it instead.
if activation is F.relu or isinstance(activation, torch.nn.ReLU):
self.activation_relu_or_gelu = 1
elif activation is F.gelu or isinstance(activation, torch.nn.GELU):
self.activation_relu_or_gelu = 2
else:
self.activation_relu_or_gelu = 0
self.activation = activation
def __setstate__(self, state):
super().__setstate__(state)
if not hasattr(self, 'activation'):
self.activation = F.relu
def forward(
self,
src: Tensor,
src_mask: Optional[Tensor] = None,
src_key_padding_mask: Optional[Tensor] = None,
is_causal: bool = False) -> Tensor:
r"""Pass the input through the encoder layer.
Args:
src: the sequence to the encoder layer (required).
src_mask: the mask for the src sequence (optional).
src_key_padding_mask: the mask for the src keys per batch (optional).
is_causal: If specified, applies a causal mask as ``src mask``.
Default: ``False``.
Warning:
``is_causal`` provides a hint that ``src_mask`` is the
causal mask. Providing incorrect hints can result in
incorrect execution, including forward and backward
compatibility.
Shape:
see the docs in :class:`~torch.nn.Transformer`.
"""
src_key_padding_mask = F._canonical_mask(
mask=src_key_padding_mask,
mask_name="src_key_padding_mask",
other_type=F._none_or_dtype(src_mask),
other_name="src_mask",
target_type=src.dtype
)
src_mask = F._canonical_mask(
mask=src_mask,
mask_name="src_mask",
other_type=None,
other_name="",
target_type=src.dtype,
check_other=False,
)
# is_fastpath_enabled = torch.backends.mha.get_fastpath_enabled()
# see Fig. 1 of https://arxiv.org/pdf/2002.04745v1.pdf
why_not_sparsity_fast_path = ''
# if not is_fastpath_enabled:
# why_not_sparsity_fast_path = "torch.backends.mha.get_fastpath_enabled() was not True"
if not src.dim() == 3:
why_not_sparsity_fast_path = f"input not batched; expected src.dim() of 3 but got {src.dim()}"
elif self.training:
why_not_sparsity_fast_path = "training is enabled"
elif not self.self_attn.batch_first:
why_not_sparsity_fast_path = "self_attn.batch_first was not True"
elif self.self_attn.in_proj_bias is None:
why_not_sparsity_fast_path = "self_attn was passed bias=False"
elif not self.self_attn._qkv_same_embed_dim:
why_not_sparsity_fast_path = "self_attn._qkv_same_embed_dim was not True"
elif not self.activation_relu_or_gelu:
why_not_sparsity_fast_path = "activation_relu_or_gelu was not True"
elif not (self.norm1.eps == self.norm2.eps):
why_not_sparsity_fast_path = "norm1.eps is not equal to norm2.eps"
elif src.is_nested and (src_key_padding_mask is not None or src_mask is not None):
why_not_sparsity_fast_path = "neither src_key_padding_mask nor src_mask are not supported with NestedTensor input"
elif self.self_attn.num_heads % 2 == 1:
why_not_sparsity_fast_path = "num_head is odd"
elif torch.is_autocast_enabled():
why_not_sparsity_fast_path = "autocast is enabled"
if not why_not_sparsity_fast_path:
tensor_args = (
src,
self.self_attn.in_proj_weight,
self.self_attn.in_proj_bias,
self.self_attn.out_proj.weight,
self.self_attn.out_proj.bias,
self.norm1.weight,
self.norm1.bias,
self.norm2.weight,
self.norm2.bias,
self.linear1.weight,
self.linear1.bias,
self.linear2.weight,
self.linear2.bias,
)
# We have to use list comprehensions below because TorchScript does not support
# generator expressions.
_supported_device_type = ["cpu", "cuda", torch.utils.backend_registration._privateuse1_backend_name]
if torch.overrides.has_torch_function(tensor_args):
why_not_sparsity_fast_path = "some Tensor argument has_torch_function"
elif not all((x.device.type in _supported_device_type) for x in tensor_args):
why_not_sparsity_fast_path = ("some Tensor argument's device is neither one of "
f"{_supported_device_type}")
elif torch.is_grad_enabled() and any(x.requires_grad for x in tensor_args):
why_not_sparsity_fast_path = ("grad is enabled and at least one of query or the "
"input/output projection weights or biases requires_grad")
if not why_not_sparsity_fast_path:
merged_mask, mask_type = self.self_attn.merge_masks(src_mask, src_key_padding_mask, src)
return torch._transformer_encoder_layer_fwd(
src,
self.self_attn.embed_dim,
self.self_attn.num_heads,
self.self_attn.in_proj_weight,
self.self_attn.in_proj_bias,
self.self_attn.out_proj.weight,
self.self_attn.out_proj.bias,
self.activation_relu_or_gelu == 2,
self.norm_first,
self.norm1.eps,
self.norm1.weight,
self.norm1.bias,
self.norm2.weight,
self.norm2.bias,
self.linear1.weight,
self.linear1.bias,
self.linear2.weight,
self.linear2.bias,
merged_mask,
mask_type,
)
x = src
if self.norm_first:
x = x + self._sa_block(self.norm1(x), src_mask, src_key_padding_mask, is_causal=is_causal)
x = x + self._ff_block(self.norm2(x))
else:
x = self.norm1(x + self._sa_block(x, src_mask, src_key_padding_mask, is_causal=is_causal))
x = self.norm2(x + self._ff_block(x))
return x
# self-attention block
def _sa_block(self, x: Tensor,
attn_mask: Optional[Tensor], key_padding_mask: Optional[Tensor], is_causal: bool = False) -> Tensor:
x = self.self_attn(x, x, x,
attn_mask=attn_mask,
key_padding_mask=key_padding_mask,
need_weights=False, is_causal=is_causal)[0]
return self.dropout1(x)
# feed forward block
def _ff_block(self, x: Tensor) -> Tensor:
x = self.linear2(self.dropout(self.activation(self.linear1(x))))
return self.dropout2(x)
class TransformerDecoderLayer(Module):
r"""TransformerDecoderLayer is made up of self-attn, multi-head-attn and feedforward network.
This standard decoder layer is based on the paper "Attention Is All You Need".
Ashish Vaswani, Noam Shazeer, Niki Parmar, Jakob Uszkoreit, Llion Jones, Aidan N Gomez,
Lukasz Kaiser, and Illia Polosukhin. 2017. Attention is all you need. In Advances in
Neural Information Processing Systems, pages 6000-6010. Users may modify or implement
in a different way during application.
Args:
d_model: the number of expected features in the input (required).
nhead: the number of heads in the multiheadattention models (required).
dim_feedforward: the dimension of the feedforward network model (default=2048).
dropout: the dropout value (default=0.1).
activation: the activation function of the intermediate layer, can be a string
("relu" or "gelu") or a unary callable. Default: relu
layer_norm_eps: the eps value in layer normalization components (default=1e-5).
batch_first: If ``True``, then the input and output tensors are provided
as (batch, seq, feature). Default: ``False`` (seq, batch, feature).
norm_first: if ``True``, layer norm is done prior to self attention, multihead
attention and feedforward operations, respectively. Otherwise it's done after.
Default: ``False`` (after).
bias: If set to ``False``, ``Linear`` and ``LayerNorm`` layers will not learn an additive
bias. Default: ``True``.
Examples::
>>> decoder_layer = nn.TransformerDecoderLayer(d_model=512, nhead=8)
>>> memory = torch.rand(10, 32, 512)
>>> tgt = torch.rand(20, 32, 512)
>>> out = decoder_layer(tgt, memory)
Alternatively, when ``batch_first`` is ``True``:
>>> decoder_layer = nn.TransformerDecoderLayer(d_model=512, nhead=8, batch_first=True)
>>> memory = torch.rand(32, 10, 512)
>>> tgt = torch.rand(32, 20, 512)
>>> out = decoder_layer(tgt, memory)
"""
__constants__ = ['norm_first']
def __init__(self, d_model: int, nhead: int, dim_feedforward: int = 2048, use_moe: bool = False, num_experts: int = 16,
dropout: float = 0.1, activation: Union[str, Callable[[Tensor], Tensor]] = F.relu,
layer_norm_eps: float = 1e-5, batch_first: bool = False, norm_first: bool = False,
bias: bool = True, device=None, dtype=None) -> None:
factory_kwargs = {'device': device, 'dtype': dtype}
super().__init__()
self.self_attn = MultiHeadSelfAttention(d_model, nhead, dropout=dropout, batch_first=batch_first, **factory_kwargs)
self.multihead_attn = MultiheadAttention(d_model, nhead, dropout=dropout, batch_first=batch_first,
bias=bias, **factory_kwargs)
self.use_moe = use_moe
if use_moe:
self.moe = MoE(
dim = d_model,
num_experts = num_experts, # increase the experts (# parameters) of your model without increasing computation
gating_top_n = 2, # default to top 2 gating, but can also be more (3 was tested in the paper with a lower threshold)
threshold_train = 0.2, # at what threshold to accept a token to be routed to second expert and beyond - 0.2 was optimal for 2 expert routing, and apparently should be lower for 3
threshold_eval = 0.2,
capacity_factor_train = 1.25, # experts have fixed capacity per batch. we need some extra capacity in case gating is not perfectly balanced.
capacity_factor_eval = 2., # capacity_factor_* should be set to a value >=1
balance_loss_coef = 1e-2, # multiplier on the auxiliary expert balancing auxiliary loss
router_z_loss_coef = 1e-3, # loss weight for router z-loss
).to(device)
self.moe_block = SparseMoEBlock(
self.moe,
add_ff_before = True,
add_ff_after = True
).to(device)
else:
# Implementation of Feedforward model
self.linear1 = Linear(d_model, dim_feedforward, bias=bias, **factory_kwargs)
self.dropout = Dropout(dropout)
self.linear2 = Linear(dim_feedforward, d_model, bias=bias, **factory_kwargs)
self.norm_first = norm_first
self.norm1 = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.norm2 = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.norm3 = LayerNorm(d_model, eps=layer_norm_eps, bias=bias, **factory_kwargs)
self.dropout1 = Dropout(dropout)
self.dropout2 = Dropout(dropout)
self.dropout3 = Dropout(dropout)
# Legacy string support for activation function.
if isinstance(activation, str):
self.activation = _get_activation_fn(activation)
else:
self.activation = activation
def __setstate__(self, state):
if 'activation' not in state:
state['activation'] = F.relu
super().__setstate__(state)
def forward(
self,
tgt: Tensor,
memory: Tensor,
memory_mask: Optional[Tensor] = None,
memory_key_padding_mask: Optional[Tensor] = None,
tgt_is_causal: bool = False,
memory_is_causal: bool = False,
) -> Tensor:
r"""Pass the inputs (and mask) through the decoder layer.
Args:
tgt: the sequence to the decoder layer (required).
memory: the sequence from the last layer of the encoder (required).
memory_mask: the mask for the memory sequence (optional).
memory_key_padding_mask: the mask for the memory keys per batch (optional).
tgt_is_causal: If specified, applies a causal mask as ``tgt mask``.
Default: ``False``.
Warning:
``tgt_is_causal`` provides a hint that ``tgt_mask`` is
the causal mask. Providing incorrect hints can result in
incorrect execution, including forward and backward
compatibility.
memory_is_causal: If specified, applies a causal mask as
``memory mask``.
Default: ``False``.
Warning:
``memory_is_causal`` provides a hint that
``memory_mask`` is the causal mask. Providing incorrect
hints can result in incorrect execution, including
forward and backward compatibility.
Shape:
see the docs in :class:`~torch.nn.Transformer`.
"""
# see Fig. 1 of https://arxiv.org/pdf/2002.04745v1.pdf
x = tgt
# print(f'target is causal: {tgt_is_causal}')
if self.norm_first:
x = x + self._sa_block(self.norm1(x), tgt_is_causal)
x = x + self._mha_block(self.norm2(x), memory, memory_mask, memory_key_padding_mask, memory_is_causal)
if self.use_moe:
m, total_aux_loss, balance_loss, router_z_loss = self.moe_block(x)
x = x + m
else:
x = x + self._ff_block(self.norm3(x))
else:
x = self.norm1(x + self._sa_block(x, tgt_is_causal))
x = self.norm2(x + self._mha_block(x, memory, memory_mask, memory_key_padding_mask, memory_is_causal))
if self.use_moe:
m, total_aux_loss, balance_loss, router_z_loss = self.moe_block(x)
x = x + m
else:
x = self.norm3(x + self._ff_block(x))
if self.use_moe:
return x, total_aux_loss, balance_loss, router_z_loss
else:
return x
# self-attention block
def _sa_block(self, x: Tensor,
is_causal: bool = False) -> Tensor:
x = self.self_attn(x, is_causal=is_causal)
return self.dropout1(x)
# multihead attention block
def _mha_block(self, x: Tensor, mem: Tensor,
attn_mask: Optional[Tensor], key_padding_mask: Optional[Tensor], is_causal: bool = False) -> Tensor:
x = self.multihead_attn(x, mem, mem,
attn_mask=attn_mask,
key_padding_mask=key_padding_mask,
is_causal=is_causal,
need_weights=False)[0]
return self.dropout2(x)
# feed forward block
def _ff_block(self, x: Tensor) -> Tensor:
x = self.linear2(self.dropout(self.activation(self.linear1(x))))
return self.dropout3(x)
def _get_clones(module, N):
# FIXME: copy.deepcopy() is not defined on nn.module
return ModuleList([copy.deepcopy(module) for i in range(N)])
def _get_activation_fn(activation: str) -> Callable[[Tensor], Tensor]:
if activation == "relu":
return F.relu
elif activation == "gelu":
return F.gelu
raise RuntimeError(f"activation should be relu/gelu, not {activation}")
def _detect_is_causal_mask(
mask: Optional[Tensor],
is_causal: Optional[bool] = None,
size: Optional[int] = None,
) -> bool:
"""Return whether the given attention mask is causal.
Warning:
If ``is_causal`` is not ``None``, its value will be returned as is. If a
user supplies an incorrect ``is_causal`` hint,
``is_causal=False`` when the mask is in fact a causal attention.mask
may lead to reduced performance relative to what would be achievable
with ``is_causal=True``;
``is_causal=True`` when the mask is in fact not a causal attention.mask
may lead to incorrect and unpredictable execution - in some scenarios,
a causal mask may be applied based on the hint, in other execution
scenarios the specified mask may be used. The choice may not appear
to be deterministic, in that a number of factors like alignment,
hardware SKU, etc influence the decision whether to use a mask or
rely on the hint.
``size`` if not None, check whether the mask is a causal mask of the provided size
Otherwise, checks for any causal mask.
"""
# Prevent type refinement
make_causal = (is_causal is True)
if is_causal is None and mask is not None:
sz = size if size is not None else mask.size(-2)
causal_comparison = _generate_square_subsequent_mask(
sz, device=mask.device, dtype=mask.dtype)
# Do not use `torch.equal` so we handle batched masks by
# broadcasting the comparison.
if mask.size() == causal_comparison.size():
make_causal = bool((mask == causal_comparison).all())
else:
make_causal = False
return make_causal
def check_instruments(genereated_seq):
ins_present = []
ins_count = 0
instrument_list = ["piano", "chromatic", "organ", "guitar", "bass", "strings", "ensemble", "brass", "reed", "drum", "pipe", "synth_lead", "synth_pad", "synth_effect", "ethnic", "percussive", "sfx"]
for token in genereated_seq:
try:
ins, pitch, vel = token
# print(str(ins))
except ValueError:
try:
ins, pitch = token
except ValueError:
ins = token
if str(ins) in instrument_list:
# print('coming here')
if ('prefix', 'instrument', str(ins)) not in ins_present and ins_count < 15:
ins_count += 1
print(f'adding instrument {ins}')
ins_present.append(('prefix', 'instrument', str(ins)))
if ins_present != []:
genereated_seq = ins_present + ['<S>']+ genereated_seq +['<E>']
else:
genereated_seq = genereated_seq +['<E>']
print(genereated_seq)
return genereated_seq
def process_caption(gpu_id, captions, model, tokenizer, r_tokenizer):
device = gpu_id
torch.cuda.set_device(gpu_id)
model.to(gpu_id)
model.eval()
for caption in captions:
src = caption['caption']
location = caption['location']
#src = "A cinematic electronic soundtrack that evokes an epic and dark atmosphere, featuring cello, contrabass, and drums. The song is set in A minor with a moderate tempo and a 4/4 time signature, creating an emotional and action-packed ambiance suitable for film."
'''
example 1: "A cheerful and melodic pop Christmas song featuring piano, acoustic guitar, vibraphone, bass, and drums, set in the key of Eb minor with a fast tempo of 123 bpm and a 4/4 time signature, creating a joyful and relaxing atmosphere."lmd_full/1/1b9f5f325c2080d345d877f590aa3dbe.mid
example 2: "A melodic electronic song with ambient elements, featuring piano, acoustic guitar, alto saxophone, string ensemble, and electric bass. Set in G minor with a 4/4 time signature, it moves at a lively Presto tempo. The composition evokes a blend of relaxation and darkness, with hints of happiness and a meditative quality."lmd_full/1/152891ac63017b234c33e75e4a4a28c5.mid
example 3: "This motivational electronic and pop song features a clean electric guitar, rock organ, synth voice, acoustic guitar, and vibraphone, creating a melodic and uplifting atmosphere. Set in the key of G# minor with a 4/4 time signature, the track moves at an energetic Allegro tempo of 120 beats per minute. The chord progression of Bbm7 and F# adds to the song's inspiring and corporate feel." lmd_full/1/14347e50e9e8149a9da09f49b188180b.mid
example 4: "This short electronic song in C minor features a brass section, string ensemble, tenor saxophone, clean electric guitar, and slap bass, creating a melodic and slightly dark atmosphere. With a tempo of 124 BPM (Allegro) and a 4/4 time signature, the track incorporates a chord progression of C7/E, Eb6, and Bbm6, adding a touch of corporate and motivational vibes to the overall composition." lmd_full/1/1dc4cd50a5509d8042d27d80bc7e668e.mid
example 5: "An energetic and melodic electronic trance track with a space and retro vibe, featuring drums, distortion guitar, flute, synth bass, and slap bass. Set in A minor with a fast tempo of 138 BPM, the song maintains a 4/4 time signature throughout its duration." lmd_full/3/3328b854ebe7a2fc9a746ede74c410ae.mid
example 6: "A short but energetic rock fragment in C minor, featuring overdriven guitars, electric bass, and drums, with a vivacious tempo of 155 BPM and a 4/4 time signature, evoking a blend of dark and melodic tones." lmd_full/4/4c2232688c5f869b8470a408d197f5e3.mid
example 7: "A classical piece with a cinematic flair, this composition is characterized by its fast tempo and 4/4 time signature. The soprano saxophone and flute take turns leading the melody, supported by the lush tones of the string ensemble, acoustic bass, and pan flute. Set in the key of F minor, the harmonic landscape is painted with the chords Gm7b5, Cm7b5, Fm7, Eaug, and Ab/Eb. The overall mood evokes images of film, with hints of Christmas, drama, documentary, and adventure." lmd_full/9/95bce1b489a11829b4fef39200291f60.mid
exmaple 8: "A slow, dark, and emotional classical piece featuring cello, violin, and viola, likely to be used in a dramatic film soundtrack. The composition is in the key of C minor with a 4/4 time signature, and the main chord progression consists of Cm, G, Cm, and Fm." lmd_full/a/a22aad98ecfe4b3d8a353c2a72132834.mid
example 9: "A slow and emotional classical piece, likely used in a film soundtrack, featuring a church organ as the sole instrument. Written in the key of Eb major with a 3/4 time signature, it evokes a sense of drama and romance. The chord progression of Bb7, Eb, and Ab contributes to the relaxing atmosphere throughout the song." lmd_full/a/af4302a036c9df71e0435df9b08f8c4b.mid
example 10: "A cinematic electronic soundtrack that evokes an epic and dark atmosphere, featuring cello, contrabass, and drums. The song is set in A minor with a moderate tempo and a 4/4 time signature, creating an emotional and action-packed ambiance suitable for film." lmd_full/d/d920b6f451d7a72ae06f154e7c06c4c1.mid
'''
inputs = tokenizer(src, return_tensors='pt', padding=True, truncation=True)
input_ids = nn.utils.rnn.pad_sequence(inputs.input_ids, batch_first=True, padding_value=0)
input_ids = input_ids.to(device)
attention_mask =nn.utils.rnn.pad_sequence(inputs.attention_mask, batch_first=True, padding_value=0)
attention_mask = attention_mask.to(device)
output = model.generate(input_ids, attention_mask,max_len=1000,temperature = 0.9)
output_list = output[0].tolist()
print(type(output_list))
# generated_sequences = [dict_tokenizer[token] for token in output_list[0]]
# generated_sequences = check_instruments(generated_sequences)
# # generated_sequences = [('prefix', 'instrument', 'bass'), ('prefix', 'instrument', 'guitar'), ('prefix', 'instrument', 'piano'), ('prefix', 'instrument', 'guitar'), '<S>' ]+ generated_sequences +['<E>']
# generated_sequences = [token for token in generated_sequences]# if token not in ["<SS>", "<S>", "<E>", "<SEP>"]]
# # print("Generated sequences:", generated_sequences)
# with open('../../generated_seq.pkl', 'wb') as f:
# pickle.dump(generated_sequences, f)
# mid_dict = aria_tokenizer.detokenize(generated_sequences)
# mid = mid_dict.to_midi()
generated_midi = r_tokenizer.decode(output_list)
# print(type(generated_midi))
generated_midi.dump_midi(f"../res/{location}")
def test_generate():
device = 'cuda'
artifact_folder = '../artifacts'
tokenizer_filepath = os.path.join(artifact_folder, "vocab_remi.pkl")
caption_dataset_path = '/root/captions/train.json'
print(f'caption_dataset_path: {caption_dataset_path}')
# Load the tokenizer dictionary
with open(tokenizer_filepath, "rb") as f:
r_tokenizer = pickle.load(f)
vocab_size = len(r_tokenizer)#+1
print("Vocab size: ", vocab_size)
# print(tokenizer[2171])
# d_model =
# model = Transformer(vocab_size, 768, 8, 8000, 8, 1024, False, 8, device=device)
model = Transformer(vocab_size, 768, 8, 2048, 18, 1024, False, 8, device=device)
# model = DataParallel(model)
model.load_state_dict(torch.load('/root/output_test_new/epoch_50/pytorch_model.bin', map_location=device))
model.eval()
tokenizer = T5Tokenizer.from_pretrained("google/flan-t5-base")
'''
# num_gpus = torch.cuda.device_count()
# captions_per_gpu = len(captions) // num_gpus
# processes = []
# for i in range(num_gpus):
# start_idx = i * captions_per_gpu
# end_idx = (i + 1) * captions_per_gpu if i != num_gpus - 1 else len(captions)
# p = mp.Process(target=process_caption, args=(i, captions[start_idx:end_idx], model, tokenizer, r_tokenizer))
# p.start()
# processes.append(p)
# for p in processes:
# p.join()
'''
# src = "This short electronic song in C minor features a brass section, string ensemble, tenor saxophone, clean electric guitar, and slap bass, creating a melodic and slightly dark atmosphere. With a tempo of 124 BPM (Allegro) and a 4/4 time signature, the track incorporates a chord progression of C7/E, Eb6, and Bbm6, adding a touch of corporate and motivational vibes to the overall composition."
src="This motivational electronic and pop song features a clean electric guitar, rock organ, synth voice, acoustic guitar, and vibraphone, creating a melodic and uplifting atmosphere. Set in the key of G# minor with a 4/4 time signature, the track moves at an energetic Allegro tempo of 120 beats per minute. The chord progression of Bbm7 and F# adds to the song's inspiring and corporate feel."
# src = "Played at 149 beats per minute in 2/4 time signature and the key of G major, classical piece with instruments: bassoon, clarinet, flute, horn, oboe, and trumpet."
# src= 'Played at 114 beats per minute in 1/4 time signature and the key of g# minor, classical piece with the following instruments: clarinet, english horn, flute, horn, piccolo, trombone, and trumpet.'
inputs = tokenizer(src, return_tensors='pt', padding=True, truncation=True)
input_ids = nn.utils.rnn.pad_sequence(inputs.input_ids, batch_first=True, padding_value=0)
input_ids = input_ids.to(device)
attention_mask =nn.utils.rnn.pad_sequence(inputs.attention_mask, batch_first=True, padding_value=0)
attention_mask = attention_mask.to(device)
output = model.generate(input_ids, attention_mask,max_len=5000,temperature = 0.9)
output_list = output[0].tolist()
generated_midi = r_tokenizer.decode(output_list)
generated_midi.dump_midi(f"../../output_e3_epoch_50_new.mid")
if __name__ == "__main__":
mp.set_start_method('spawn')
test_generate()
print("Done")