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#
# For licensing see accompanying LICENSE file.
# Copyright (C) 2024 Apple Inc. All Rights Reserved.
#
from typing import List, Optional, Tuple, Union
import torch
import torch.utils.checkpoint
from torch import Tensor, nn
from torch.nn import CrossEntropyLoss
from torch.nn import functional as F
from transformers import PreTrainedModel
from transformers.activations import ACT2FN
from transformers.cache_utils import Cache, DynamicCache, StaticCache
from transformers.modeling_outputs import (
BaseModelOutputWithPast,
CausalLMOutputWithPast,
)
from transformers.utils import logging
logger = logging.get_logger(__name__)
# this import has to be relative, otherwise, when setting trust_remote_code=True
# huggingface transformers won't be able to load the module correctly
from numbers import Number
from typing import List, Optional, Union
import numpy as np
from transformers import PretrainedConfig, AutoTokenizer
def make_divisible(
v: Union[float, int],
divisor: Optional[int] = 8,
min_value: Optional[Union[float, int]] = None,
) -> Union[float, int]:
"""
This function is taken from the original tf repo.
It ensures that all layers have a channel number that is divisible by the divisor
It can be seen at:
https://github.com/tensorflow/models/blob/2cfc99eff5e5eb729c6793d2f3d03aa1c9be2b15/research/slim/nets/mobilenet/mobilenet.py#L62
Args:
v: input value
divisor: default to 8
min_value: minimum divisor value
Returns:
new_v: new divisible value
"""
if min_value is None:
min_value = divisor
new_v = max(min_value, int(v + divisor / 2) // divisor * divisor)
# Make sure that round down does not go down by more than 10%.
if new_v < 0.9 * v:
new_v += divisor
return new_v
def compute_heads(model_dim: int, head_dim: int) -> int:
"""Compute the number of heads.
Args:
model_dim: Model dimension.
head_dim: Head dimension.
Returns:
An integer denoting number of heads in multi-head attention is returned.
Raises:
ValueError: if model dimension is not divisible by head dimension.
"""
if model_dim % head_dim == 0:
return model_dim // head_dim
else:
raise ValueError(
f"Model dimension should be divisible by head dimension. Got: {model_dim} and {head_dim}."
)
OpenELM_CONFIGS = {
"OpenELM-270M": dict(
num_transformer_layers=16,
model_dim=1280,
head_dim=64,
num_gqa_groups=4,
normalize_qk_projections=True,
share_input_output_layers=True,
# Vary the FFN and QKV multipliers to create variable FFN and attention layers respectively.
ffn_multipliers=(0.5, 4.0),
qkv_multipliers=(0.5, 1.0),
),
"OpenELM-450M": dict(
num_transformer_layers=20,
model_dim=1536,
head_dim=64,
num_gqa_groups=4,
normalize_qk_projections=True,
share_input_output_layers=True,
# Vary the FFN and QKV multipliers to create variable FFN and attention layers respectively.
ffn_multipliers=(0.5, 4.0),
qkv_multipliers=(0.5, 1.0),
),
"OpenELM-1_1B": dict(
num_transformer_layers=28,
model_dim=2048,
head_dim=64,
num_gqa_groups=4,
normalize_qk_projections=True,
share_input_output_layers=True,
# Vary the FFN and QKV multipliers to create variable FFN and attention layers respectively.
ffn_multipliers=(0.5, 4.0),
qkv_multipliers=(0.5, 1.0),
),
"OpenELM-3B": dict(
num_transformer_layers=36,
model_dim=3072,
head_dim=128,
num_gqa_groups=4,
normalize_qk_projections=True,
share_input_output_layers=True,
# Vary the FFN and QKV multipliers to create variable FFN and attention layers respectively.
ffn_multipliers=(0.5, 4.0),
qkv_multipliers=(0.5, 1.0),
),
}
class OpenELMConfig(PretrainedConfig):
r"""
This is the configuration class to store the configuration of a [`OpenELMModel`]. It is used to instantiate an OpenELM model according to the specified arguments, defining the model architecture.
Configuration objects inherit from [`PretrainedConfig`] and can be used to control the model outputs. Read the
documentation from [`PretrainedConfig`] for more information.
Args:
vocab_size (`int`, *optional*, defaults to 32000):
Vocabulary size of the OpenELM model.
max_context_length (`int`, *optional*, defaults to 2048):
Maximum number of input tokens.
num_transformer_layers (`int`, *optional*, defaults to 12):
Number of hidden layers in the Transformer decoder.
model_dim (`int`, *optional*, defaults to 2048):
Dimension of the hidden representations.
head_dim (`int`, *optional*, defaults to 128):
The attention head dimension.
qkv_multipliers (`Union[Number, List[Number]]`, *optional*, defaults to 1.0):
If the qkv_multipliers is a Number, then all attention layers have the same latent dimensions,
resulting in uniform allocation of parameters.
If the qkv_multipliers is a List of Number, then each attention layer have different latent dimensions
assuming qkv_multipliers[0] != qkv_multipliers[1]. This results in variable allocation of parameters in attention layer.
This scaling is known as layer-wise or block-wise scaling: https://arxiv.org/abs/2008.00623
num_query_heads (`Union[int, None]`, *optional*, defaults to None):
The number of query heads, computed from `compute_heads(model_dim=model_dim, head_dim=head_dim)`.
num_gqa_groups (`int`, *optional*, defaults to 1):
This variable allows to switch between multi-head attention, group query attention, and multi-query attention.
When num_gqa_groups == 1, then it is multi-head attention.
When 1 < num_gqa_groups < num_heads and num_heads is divisible by num_gqa_groups, then it is group query attention
When num_gqa_groups == num_heads, then it is multi-query attention
ffn_multipliers (`Union[Number, List[Number]]`, *optional*, defaults to 4.0):
Feed-forward network (FFN) multipliers.
If the ffn_multipliers is a Number, then all FFN layers have the same latent dimensions,
resulting in uniform allocation of parameters.
If the ffn_multipliers is a List of Number, then each FFN layer have different latent dimensions
assuming ffn_multipliers[0] != ffn_multipliers[1]. This results in variable allocation of parameters in FFN layer.
This scaling is known as layer-wise or block-wise scaling: https://arxiv.org/abs/2008.00623
ffn_with_glu (`bool`, *optional*, defaults to True):
Whether to use FFN with Gated Linear Unit (GLU)
ffn_dim_divisor (`int`, *optional*, defaults to 256):
The ffn layer dimension divisor.
activation_fn_name (`str` or `function`, *optional*, defaults to `"swish"`):
The non-linear activation function (function or string) in the decoder.
normalization_layer_name (`str` or `function`, *optional*, defaults to `"rms_norm"`):
Type of normalization layer.
normalize_qk_projections (`bool`, *optional*, defaults to False):
Whether to normalize queries and keys after projections
share_input_output_layers (`bool`, *optional*, defaults to False):
Whether to share the embedding between input and output linear layer
rope_freq_constant (`int`, *optional*, defaults to 10000):
The base period of the RoPE embeddings.
rope_max_length (`int`, *optional*, defaults to 4096):
That rope_max_length is set to twice of max_context_length.
This allows flexibility in token lengths during training or fine-tuning.
initializer_range (`float`, *optional*, defaults to 0.02):
The standard deviation of the truncated_normal_initializer for initializing all weight matrices.
use_cache (`bool`, *optional*, defaults to `True`):
Whether or not the model should return the last key/values attentions (not used by all models). Only
relevant if `config.is_decoder=True`.
bos_token_id (`int`, *optional*, defaults to 2):
Beginning of stream token id.
eos_token_id (`int`, *optional*, defaults to 1):
End of stream token id.
"""
model_type = "openelm"
def __init__(
self,
vocab_size: int = 32000,
max_context_length: int = 2048,
num_transformer_layers: int = 12,
model_dim: int = 2048,
head_dim: int = 128,
qkv_multipliers: Union[Number, List[Number]] = 1.0,
num_query_heads: Union[int, None] = None,
num_gqa_groups: int = 1,
ffn_multipliers: Union[Number, List[Number]] = 4.0,
ffn_with_glu: bool = True,
ffn_dim_divisor: int = 256,
activation_fn_name: str = "swish",
normalization_layer_name: str = "rms_norm",
normalize_qk_projections: bool = False,
share_input_output_layers: bool = False,
rope_freq_constant: int = 10000,
rope_max_length: int = 4096,
initializer_range: float = 0.02,
use_cache: bool = True,
bos_token_id: int = 1,
eos_token_id: int = 2,
**kwargs,
) -> None:
self.vocab_size = vocab_size
self.max_context_length = max_context_length
self.num_transformer_layers = num_transformer_layers
self.model_dim = model_dim
self.head_dim = head_dim
self.qkv_multipliers = qkv_multipliers
self.num_query_heads = num_query_heads
self.num_gqa_groups = num_gqa_groups
self.ffn_multipliers = ffn_multipliers
self.ffn_with_glu = ffn_with_glu
self.ffn_dim_divisor = ffn_dim_divisor
self.activation_fn_name = activation_fn_name
self.normalization_layer_name = normalization_layer_name
self.normalize_qk_projections = normalize_qk_projections
self.share_input_output_layers = share_input_output_layers
self.rope_freq_constant = rope_freq_constant
self.rope_max_length = rope_max_length
self.num_query_heads = (
compute_heads(model_dim=model_dim, head_dim=head_dim)
if num_query_heads is None
else num_query_heads
)
self.initializer_range = initializer_range
self.__post_init__()
super().__init__(
use_cache=use_cache,
bos_token_id=bos_token_id,
eos_token_id=eos_token_id,
**kwargs,
)
def __post_init__(self) -> None:
if self.num_gqa_groups is not None:
head_multiple_of = self.num_gqa_groups
else:
head_multiple_of = 2
if isinstance(self.qkv_multipliers, Number):
# All attention layers have the same latent dimensions, resulting in uniform allocation of parameters.
qkv_dim = make_divisible(
self.model_dim * self.qkv_multipliers,
divisor=self.head_dim * head_multiple_of,
)
query_dims = [int(qkv_dim)] * self.num_transformer_layers
elif (
isinstance(self.qkv_multipliers, (tuple, list))
and len(self.qkv_multipliers) == 2
):
# Each attention layer have different latent dimensions assuming qkv_multipliers[0] != qkv_multipliers[1].
# This results in variable allocation of parameters in attention layer.
# This scaling is known as layer-wise or block-wise scaling: https://arxiv.org/abs/2008.00623
qkv_multipliers = [
round(v, 2)
for v in np.linspace(
self.qkv_multipliers[0],
self.qkv_multipliers[1],
num=self.num_transformer_layers,
dtype=float,
)
]
# Make sure that scaled model dimension is divisible by scaled head dimension.
query_dims = [
int(
make_divisible(
self.model_dim * m, divisor=self.head_dim * head_multiple_of
)
)
for m in qkv_multipliers
]
else:
raise NotImplementedError(
f"QKV multipliers should be a single number or a list containing exactly two numbers. Got: {qkv_multipliers}."
)
# compute the number of query, key, and value heads
# For multi-head and multi-query attention, the number of heads for query, key, and value are the same.
# For group query attention, the number of key and value heads are the same.
self.num_query_heads = [
int(compute_heads(q_dim, self.head_dim)) for q_dim in query_dims
]
self.num_kv_heads = [
q_heads // self.num_gqa_groups for q_heads in self.num_query_heads
]
# Feed-forward network (FFN) multipliers
if isinstance(self.ffn_multipliers, Number):
# All FFN layers have the same latent dimensions, resulting in uniform allocation of parameters.
self.ffn_multipliers = [self.ffn_multipliers] * self.num_transformer_layers
elif isinstance(self.ffn_multipliers, (tuple, list)):
# Each FFN layer have different latent dimensions assuming ffn_multipliers[0] != ffn_multipliers[1].
# This results in variable allocation of parameters in FFN layer.
# This scaling is known as layer-wise or block-wise scaling: https://arxiv.org/abs/2008.00623
if len(self.ffn_multipliers) == 2:
self.ffn_multipliers = [
round(v, 2)
for v in np.linspace(
self.ffn_multipliers[0],
self.ffn_multipliers[1],
num=self.num_transformer_layers,
dtype=float,
)
]
else:
assert (
len(self.ffn_multipliers) == self.num_transformer_layers
), f"{len(self.ffn_multipliers)=}!={self.num_transformer_layers=}"
else:
raise NotImplementedError(
f"FFN multipliers should be a single number or a list containing exactly two numbers. Got: {qkv_multipliers}."
)
# check num_query_heads divisible by num_kv_heads for every layer
for layer_idx in range(len(query_dims)):
assert self.num_query_heads[layer_idx] % self.num_kv_heads[layer_idx] == 0
class OpenELMRMSNorm(nn.Module):
def __init__(self, num_features: int, eps: float = 1e-6):
"""
Initialize the OpenELMRMSNorm normalization layer.
Args:
dim (int): The dimension of the input tensor.
eps (float, optional): A small value added to the denominator for numerical stability. Default is 1e-6.
Attributes:
eps (float): A small value added to the denominator for numerical stability.
weight (nn.Parameter): Learnable scaling parameter.
"""
super().__init__()
self.eps = eps
self.weight = nn.Parameter(torch.ones(num_features))
self.num_features = num_features
def _norm(self, x: Tensor) -> Tensor:
"""
Apply the OpenELMRMSNorm normalization to the input tensor.
Args:
x (torch.Tensor): The input tensor.
Returns:
torch.Tensor: The normalized tensor.
"""
return x * torch.rsqrt(x.pow(2).mean(-1, keepdim=True) + self.eps)
def forward(self, x: Tensor) -> Tensor:
"""
Forward pass through the OpenELMRMSNorm layer.
Args:
x (torch.Tensor): The input tensor.
Returns:
torch.Tensor: The output tensor after applying OpenELMRMSNorm.
"""
output = self._norm(x.float()).type_as(x)
return output * self.weight
def extra_repr(self) -> str:
return (
super().extra_repr() + f"num_features={self.num_features}, eps={self.eps}"
)
class OpenELMPreTrainedModel(PreTrainedModel):
config_class = OpenELMConfig
base_model_prefix = "transformer"
supports_gradient_checkpointing = True
_no_split_modules = ["OpenELMDecoderLayer"]
_skip_keys_device_placement = "past_key_values"
def __init__(self, *inputs, **kwargs) -> None:
super().__init__(*inputs, **kwargs)
def _init_weights(self, module: nn.Module) -> None:
"""Initialize the weights."""
if isinstance(module, nn.Linear):
# Slightly different from the TF version which uses truncated_normal for initialization
# cf https://github.com/pytorch/pytorch/pull/5617
module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
if module.bias is not None:
module.bias.data.zero_()
elif isinstance(module, nn.Embedding):
module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
if module.padding_idx is not None:
module.weight.data[module.padding_idx].zero_()
elif isinstance(module, OpenELMRMSNorm):
module.weight.data.fill_(1.0)
def _rotate_half(x: Tensor) -> Tensor:
x1, x2 = x.chunk(2, dim=-1)
return torch.cat((-x2, x1), dim=-1)
def _apply_rotary_pos_emb(x: Tensor, pos_sin: Tensor, pos_cos: Tensor) -> Tensor:
return (x * pos_cos) + (_rotate_half(x) * pos_sin)
class OpenELMRotaryEmbedding(torch.nn.Module):
"""
The rotary position embeddings (aka RoPE) from `RoFormer <https://arxiv.org/abs/2104.09864>`_.
RoPE encodes the position information of tokens using a rotation matrix, and is able to capture
explicit relative positional dependencies.
Args:
model_dim: The dimensionality of the model's hidden state.
max_seq_length: Maximum sequence length.
freq_constant: A constant used for computing frequencies.
"""
def __init__(
self, model_dim: int, max_seq_length: int, freq_constant: int = 10000
) -> None:
inv_freq = 1.0 / (
freq_constant
** (torch.arange(0, model_dim, 2, dtype=torch.float32) / model_dim)
)
super().__init__()
self.model_dim = model_dim
self.freq_constant = freq_constant
self.max_seq_length = max_seq_length
self.register_buffer("inv_freq", inv_freq, persistent=False)
self._cached_cos = None
self._cached_sin = None
self._cached_seq_length = max_seq_length
self._compute_sin_cos_embeddings(max_seq_length)
def extra_repr(self) -> str:
return f"\tmodel_dim={self.model_dim}, max_seq_length={self.max_seq_length}, freq_constant={self.freq_constant}"
def _compute_sin_cos_embeddings(
self,
key_len: int,
key_device: torch.device = torch.device("cpu"),
key_dtype: torch.dtype = torch.float32,
) -> None:
"""
Compute sine and cos embeddings.
Args:
key_len: Number of tokens in the key embeddings in the transformer model.
device: Device where the key embeddings are stored.
key_dtype: Data type of the key embeddings.
Returns:
None
...note:
We recalculate the sine and cosine embeddings if any of the following conditions are met:
1. The number of tokens in key embeddings are greater than the cached sequence length.
2. Sine and cosine caches are empty.
3. The device and data type of sine and cosine embeddings does not match with the key embeddings.
"""
if (
key_len > self._cached_seq_length
or self._cached_cos is None
or (self._cached_cos is not None and self._cached_cos.device != key_device)
or (self._cached_cos is not None and self._cached_cos.dtype != key_dtype)
or self._cached_sin is None
or (self._cached_sin is not None and self._cached_sin.device != key_device)
or (self._cached_sin is not None and self._cached_sin.dtype != key_dtype)
):
self._cached_seq_length = max(key_len, self._cached_seq_length)
# The shape of 'pos_index' is [number of key tokens]
pos_index = torch.arange(
self._cached_seq_length,
dtype=torch.float32,
device=self.inv_freq.device,
)
# The shape of 'pos_index_theta' is [number of key tokens, model dimension]
pos_index_theta = torch.einsum("i,j->ij", pos_index, self.inv_freq)
# The shape of 'emb' is [number of key tokens, model dimension]
emb = torch.cat((pos_index_theta, pos_index_theta), dim=-1)
# the shape of cos and sin embeddings is [number of key tokens, model_dim]
cos_emb = emb.cos().to(dtype=key_dtype, device=key_device)
sin_emb = emb.sin().to(dtype=key_dtype, device=key_device)
# the shape of cached cos and sin embeddings is [1, 1, number of key tokens, model_dim]
self._cached_cos = cos_emb[None, None, :, :]
self._cached_sin = sin_emb[None, None, :, :]
def forward(
self,
query: torch.Tensor,
key: torch.Tensor,
) -> Tuple[torch.Tensor, torch.Tensor]:
"""
The forward function of RoPE embeddings.
Args:
query: Query embeddings in the transformer model. The shape of query embeddings is
[Batch, number of query heads, number of query tokens, model dimension].
key: Key embeddings in the transformer model. The shape of key embeddings is
[Batch, number of key heads, number of key tokens, model dimension].
Returns:
A tuple containing the query and key embeddings with positional information. The shape of the returned query
and key embeddings is the same as the input query and key embeddings respectively.
...note:
The RoPE embedding computation is done in full-precision. After the computation, input query and key tensors
are casted to original input datatype.
"""
dim = key.shape[-1]
key_len = key.shape[2]
query_len = query.shape[2]
assert dim == self.model_dim
assert key.device == query.device
assert key.dtype == query.dtype
# In the context of self-attention, the lengths of keys and queries are equal.
# However, in generation tasks, such as predicting the next token in a sequence, the lengths of keys and queries
# can differ. For instance, when employing key-value (KV) caching for sequence prediction, the keys
# represent embeddings of previous tokens and the current token, while the query corresponds
# to the embedding of the current token only.
assert (
key_len >= query_len
), "Number of keys has to be greater than or equal to number of queries."
query_float = query.float()
key_float = key.float()
self._compute_sin_cos_embeddings(
key_len, key_device=key_float.device, key_dtype=key_float.dtype
)
query_float = _apply_rotary_pos_emb(
x=query_float,
pos_sin=self._cached_sin[..., key_len - query_len : key_len, :],
pos_cos=self._cached_cos[..., key_len - query_len : key_len, :],
)
key_float = _apply_rotary_pos_emb(
x=key_float,
pos_sin=self._cached_sin[..., :key_len, :],
pos_cos=self._cached_cos[..., :key_len, :],
)
return query_float.type_as(query), key_float.type_as(key)
class OpenELMMultiHeadCausalAttention(nn.Module):
def __init__(self, config: OpenELMConfig, layer_idx: int) -> None:
super().__init__()
self.layer_idx = layer_idx
head_dim = config.head_dim
q_heads = config.num_query_heads[layer_idx]
k_heads = config.num_kv_heads[layer_idx]
v_heads = config.num_kv_heads[layer_idx]
self.qkv_proj = nn.Linear(
in_features=config.model_dim,
out_features=(q_heads + k_heads + v_heads) * head_dim,
bias=False,
)
self.pos_embedding = OpenELMRotaryEmbedding(
model_dim=config.head_dim,
max_seq_length=config.rope_max_length,
freq_constant=config.rope_freq_constant,
)
if config.normalize_qk_projections:
self.q_norm = OpenELMRMSNorm(
num_features=config.head_dim,
)
self.k_norm = OpenELMRMSNorm(
num_features=config.head_dim,
)
else:
self.q_norm = None
self.k_norm = None
self.out_proj = nn.Linear(
in_features=q_heads * head_dim,
out_features=config.model_dim,
bias=False,
)
self.head_dim = config.head_dim
self.num_q_heads = q_heads
self.num_k_heads = k_heads
self.num_v_heads = v_heads
self.transformer_dim = config.model_dim
self.num_groups = self.num_q_heads // self.num_k_heads
def extra_repr(self) -> str:
return (
super().extra_repr()
+ f"query_heads={self.num_q_heads}, key_heads={self.num_k_heads}, value_heads={self.num_v_heads}"
)
def forward(
self,
hidden_states: torch.Tensor,
attention_mask: Optional[torch.Tensor] = None,
past_key_value: Optional[Cache] = None,
output_attentions: bool = False,
use_cache: bool = False,
cache_position: Optional[torch.LongTensor] = None,
) -> Tuple[torch.Tensor, Optional[torch.Tensor], Optional[Tuple[torch.Tensor]]]:
"""
Forward pass of multi-head self-attention.
Args:
hidden_states: Input tensor of the shape [batch size, sequence length, model dimension].
past_key_value: Tensor storing the cached keys and values.
output_attentions: output attention weights.
use_cache: Specifies whether to use kv-cache for generation.
cache_position: used for updating the kv-cache.
Returns:
The output of the same shape as the input, optionally with a tensor containing cached keys and values.
"""
# scaled_dot_product_attention does not return attention weights, set output_attentions to False
output_attentions = False
batch_size, seq_length, d_model = hidden_states.size()
# [B, S, d] --> [B, S, (q_h + k_h + v_h) * h]
qkv = self.qkv_proj(hidden_states)
# [B, S, (q_h + k_h + v_h) * h] --> [B, S, (q_h + k_h + v_h), h]
qkv = qkv.reshape(
batch_size,
seq_length,
self.num_q_heads + self.num_k_heads + self.num_v_heads,
self.head_dim,
)
# [B, S, (q_h + k_h + v_h), h] --> [B, (q_h + k_h + v_h), S, h]
qkv = qkv.transpose(1, 2)
# [B, (q_h + k_h + v_h), S, h] --> [B, q_h, S h], [B, k_h, S, h], [B, v_h, S, h]
queries, keys, values = qkv.split(
[self.num_q_heads, self.num_k_heads, self.num_v_heads], dim=1
)
if self.q_norm is not None:
queries = self.q_norm(queries)
if self.k_norm is not None:
keys = self.k_norm(keys)
past_key_value = getattr(self, "past_key_value", past_key_value)
if past_key_value is not None:
# sin and cos are specific to RoPE models; position_ids needed for the static cache
# cache_kwargs = {"sin": sin, "cos": cos, "cache_position": cache_position}
cache_kwargs = {"cache_position": cache_position}
keys, values = past_key_value.update(
keys, values, self.layer_idx, cache_kwargs
)
# Add positional embedding
queries, keys = self.pos_embedding(queries, keys)
if self.num_groups != 1:
# GQA
# [B, k_h, S, h] --> [B, q_h, S, h]
keys = keys.repeat_interleave(self.num_groups, dim=1)
# [B, v_h, S, h] --> [B, q_h, S, h]
values = values.repeat_interleave(self.num_groups, dim=1)
causal_mask = attention_mask
if attention_mask is not None and cache_position is not None:
causal_mask = causal_mask[:, :, cache_position, : keys.shape[-2]]
attn_output = F.scaled_dot_product_attention(
queries,
keys,
values,
attn_mask=causal_mask,
dropout_p=0,
)
attn_output = attn_output.transpose(1, 2).contiguous()
attn_output = attn_output.reshape(
batch_size, seq_length, self.num_q_heads * self.head_dim
)
attn_output = self.out_proj(attn_output)
if not output_attentions:
attn_weights = None
return attn_output, attn_weights, past_key_value
class OpenELMFeedForwardNetwork(nn.Module):
def __init__(self, config: OpenELMConfig, layer_idx: int) -> None:
super().__init__()
ffn_multiplier = config.ffn_multipliers[layer_idx]
intermediate_dim = int(
make_divisible(
ffn_multiplier * config.model_dim,
divisor=config.ffn_dim_divisor,
)
)
if config.ffn_with_glu:
# FFN with Gated linear unit, as described in https://arxiv.org/abs/2002.05202v1.
self.proj_1 = nn.Linear(
in_features=config.model_dim,
out_features=2 * intermediate_dim,
bias=False,
)
self.proj_2 = nn.Linear(
in_features=intermediate_dim,
out_features=config.model_dim,
bias=False,
)
self.ffn_with_glu = True
else:
# Standard FFN, as described in https://arxiv.org/abs/1706.03762
self.proj_1 = nn.Linear(
in_features=config.model_dim,
out_features=intermediate_dim,
bias=False,
)
self.proj_2 = nn.Linear(
in_features=intermediate_dim,
out_features=config.model_dim,
bias=False,
)
self.ffn_with_glu = False
self.act = ACT2FN[config.activation_fn_name]
def extra_repr(self) -> str:
return super().extra_repr() + f"(ffn_with_glu) : {self.ffn_with_glu}"
def forward(self, x: Tensor) -> Tensor:
"""Forward function of FFN layer.
Args:
x: Input tensor of the shape [batch size, sequence length, model dimension].
Returns:
A tensor of the same shape as the input.
"""
if self.ffn_with_glu:
y_12 = self.proj_1(x)
y_1, y_2 = y_12.chunk(2, dim=-1)
y = self.act(y_1) * y_2
return self.proj_2(y)
else:
return self.proj_2(self.act(self.proj_1(x)))
class OpenELMDecoderLayer(nn.Module):
def __init__(self, config: OpenELMConfig, layer_idx: int) -> None:
super().__init__()
self.attn = OpenELMMultiHeadCausalAttention(config=config, layer_idx=layer_idx)
self.ffn = OpenELMFeedForwardNetwork(config=config, layer_idx=layer_idx)
self.ffn_norm = OpenELMRMSNorm(
num_features=config.model_dim,
)
self.attn_norm = OpenELMRMSNorm(
num_features=config.model_dim,
)
def forward(
self,
hidden_states: torch.Tensor,
attention_mask: Optional[torch.Tensor] = None,
position_ids: Optional[torch.LongTensor] = None,
past_key_value: Optional[Tuple[torch.Tensor]] = None,
output_attentions: Optional[bool] = False,
use_cache: Optional[bool] = False,
cache_position: Optional[torch.LongTensor] = None,
**kwargs,
) -> Tuple[
torch.FloatTensor, Optional[Tuple[torch.FloatTensor, torch.FloatTensor]]
]:
"""
Args:
hidden_states (`torch.FloatTensor`): input to the layer of shape `(batch, seq_len, embed_dim)`
attention_mask (`torch.FloatTensor`, *optional*):
attention mask of size `(batch_size, sequence_length)` if flash attention is used or `(batch_size, 1,
query_sequence_length, key_sequence_length)` if default attention is used.
output_attentions (`bool`, *optional*):
Whether or not to return the attentions tensors of all attention layers. See `attentions` under
returned tensors for more detail.
use_cache (`bool`, *optional*):
If set to `True`, `past_key_values` key value states are returned and can be used to speed up decoding
(see `past_key_values`).
past_key_value (`Tuple(torch.FloatTensor)`, *optional*): cached past key and value projection states
"""
residual = hidden_states
hidden_states = self.attn_norm(hidden_states)
# Self Attention
hidden_states, self_attn_weights, present_key_value = self.attn(
hidden_states=hidden_states,
attention_mask=attention_mask,
past_key_value=past_key_value,
output_attentions=output_attentions,
use_cache=use_cache,
cache_position=cache_position,
**kwargs,
)
hidden_states = residual + hidden_states
# Fully Connected
residual = hidden_states
hidden_states = self.ffn_norm(hidden_states)
hidden_states = self.ffn(hidden_states)
hidden_states = residual + hidden_states
outputs = (hidden_states,)
if output_attentions:
outputs += (self_attn_weights,)
if use_cache:
outputs += (present_key_value,)
return outputs
class OpenELMModel(OpenELMPreTrainedModel):
config_class = OpenELMConfig
def __init__(self, config: OpenELMConfig):
super().__init__(config)
self.config = config
self.token_embeddings = nn.Embedding(
embedding_dim=config.model_dim,
num_embeddings=config.vocab_size,
)
self.layers = nn.ModuleList(
OpenELMDecoderLayer(config=config, layer_idx=layer_idx)
for layer_idx in range(config.num_transformer_layers)
)
self.norm = OpenELMRMSNorm(num_features=config.model_dim)
if config.share_input_output_layers:
self.classifier = None
else:
self.classifier = nn.Linear(
in_features=config.model_dim,
out_features=config.vocab_size,
bias=False,
)
self.num_transformer_layers = config.num_transformer_layers
self.gradient_checkpointing = False
# Register a causal mask to separate causal and padding mask creation. Merging happens in the attention class.
# NOTE: This is not friendly with TorchScript, ONNX, ExportedProgram serialization for very large `max_context_length`.
causal_mask = torch.full(
(config.max_context_length, config.max_context_length),
fill_value=True,
dtype=torch.bool,
)
self.register_buffer(
"causal_mask", torch.triu(causal_mask, diagonal=1), persistent=False
)
# Initialize weights and apply final processing
self.post_init()
self.reset_parameters(config=config)
def get_input_embeddings(self):
return self.token_embeddings
def set_input_embeddings(self, new_embeddings: torch.Tensor):
self.token_embeddings = new_embeddings
def reset_parameters(self, config: OpenELMConfig) -> None:
"""Initialize the layers in Language Model
The initialization scheme is followed, following `OPT <https://arxiv.org/pdf/2205.01068.pdf>`_.
Args:
use_megatron_std: Use standard deviation as described in Megatron-LM.
Returns:
None
"""
for module in self.modules():
if isinstance(module, nn.Linear):
std = module.in_features**-0.5
torch.nn.init.normal_(module.weight, mean=0.0, std=std)
if module.bias is not None:
torch.nn.init.zeros_(module.bias)
elif isinstance(module, nn.Embedding):
std = module.embedding_dim**-0.5
torch.nn.init.normal_(module.weight, mean=0.0, std=std)
elif isinstance(module, OpenELMRMSNorm):
if module.weight is not None:
torch.nn.init.ones_(module.weight)
if hasattr(module, "bias") and module.bias is not None:
torch.nn.init.zeros_(module.bias)
model_dim = config.model_dim
n_layers = config.num_transformer_layers
std = (model_dim**-0.5) * ((2 * n_layers) ** -0.5)
for param_name, param in self.named_parameters():
if param_name.endswith("out_proj.weight") or param_name.endswith(
"ffn.proj_2.weight"
):
torch.nn.init.normal_(param, mean=0.0, std=std)
def forward(
self,
input_ids: torch.LongTensor = None,
attention_mask: Optional[torch.Tensor] = None,
position_ids: Optional[torch.LongTensor] = None,
past_key_values: Optional[List[torch.FloatTensor]] = None,
inputs_embeds: Optional[torch.FloatTensor] = None,
use_cache: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
cache_position: Optional[torch.LongTensor] = None,
) -> Union[Tuple, BaseModelOutputWithPast]:
output_attentions = (
output_attentions
if output_attentions is not None
else self.config.output_attentions
)
output_hidden_states = (
output_hidden_states
if output_hidden_states is not None
else self.config.output_hidden_states
)
use_cache = use_cache if use_cache is not None else self.config.use_cache
return_dict = (
return_dict if return_dict is not None else self.config.use_return_dict
)
if (input_ids is None) ^ (inputs_embeds is not None):
raise ValueError(
"You cannot specify both input_ids and inputs_embeds at the same time, and must specify either one"
)
if self.gradient_checkpointing and self.training and use_cache:
logger.warning_once(
"`use_cache=True` is incompatible with gradient checkpointing. Setting `use_cache=False`."
)
use_cache = False
if inputs_embeds is None:
inputs_embeds = self.token_embeddings(input_ids)
past_seen_tokens = 0
if use_cache: # kept for BC (cache positions)
if not isinstance(past_key_values, StaticCache):
past_key_values = DynamicCache.from_legacy_cache(past_key_values)
past_seen_tokens = past_key_values.get_seq_length()
if cache_position is None:
cache_position = torch.arange(
past_seen_tokens,
past_seen_tokens + inputs_embeds.shape[1],
device=inputs_embeds.device,
)
if position_ids is None:
position_ids = cache_position.unsqueeze(0)
causal_mask = self._update_causal_mask(attention_mask, inputs_embeds)
# embed positions
hidden_states = inputs_embeds
# decoder layers
all_hidden_states = () if output_hidden_states else None
all_self_attns = () if output_attentions else None
next_decoder_cache = None
for decoder_layer in self.layers:
if output_hidden_states:
all_hidden_states += (hidden_states,)
if self.gradient_checkpointing and self.training:
layer_outputs = self._gradient_checkpointing_func(
decoder_layer.__call__,
hidden_states,
causal_mask,
position_ids,
past_key_values,
output_attentions,
use_cache,
cache_position,
)
else:
layer_outputs = decoder_layer(
hidden_states,
attention_mask=causal_mask,
position_ids=position_ids,
past_key_value=past_key_values,
output_attentions=output_attentions,
use_cache=use_cache,
cache_position=cache_position,
)
hidden_states = layer_outputs[0]
if use_cache:
next_decoder_cache = layer_outputs[2 if output_attentions else 1]
if output_attentions:
all_self_attns += (layer_outputs[1],)
hidden_states = self.norm(hidden_states)
# add hidden states from the last decoder layer
if output_hidden_states:
all_hidden_states += (hidden_states,)
next_cache = None
if use_cache:
next_cache = (
next_decoder_cache.to_legacy_cache()
if isinstance(next_decoder_cache, Cache)
else next_decoder_cache
)
if not return_dict:
return tuple(
v
for v in [hidden_states, next_cache, all_hidden_states, all_self_attns]
if v is not None
)
return BaseModelOutputWithPast(
last_hidden_state=hidden_states,
past_key_values=next_cache,
hidden_states=all_hidden_states,
attentions=all_self_attns,
)
def _update_causal_mask(self, attention_mask, input_tensor):
if self.config._attn_implementation == "flash_attention_2":
if attention_mask is not None and 0.0 in attention_mask:
return attention_mask
return None
batch_size, seq_length = input_tensor.shape[:2]
dtype = input_tensor.dtype
device = input_tensor.device
# support going beyond cached `max_position_embedding`
if seq_length > self.causal_mask.shape[-1]:
causal_mask = torch.full(
(2 * self.causal_mask.shape[-1], 2 * self.causal_mask.shape[-1]),
fill_value=1,
)
self.register_buffer(
"causal_mask", torch.triu(causal_mask, diagonal=1), persistent=False
)
# We use the current dtype to avoid any overflows
min_dtype = torch.finfo(dtype).min
causal_mask = (
self.causal_mask[None, None, :, :].repeat(batch_size, 1, 1, 1).to(dtype)
* min_dtype
)
causal_mask = causal_mask.to(dtype=dtype, device=device)
if attention_mask is not None and attention_mask.dim() == 2:
mask_length = attention_mask.shape[-1]
padding_mask = causal_mask[..., :mask_length].eq(0.0) * attention_mask[
:, None, None, :
].eq(0.0)
causal_mask[..., :mask_length] = causal_mask[..., :mask_length].masked_fill(
padding_mask, min_dtype
)
if self.config._attn_implementation == "sdpa" and attention_mask is not None:
# For dynamo, rather use a check on fullgraph=True once this is possible (https://github.com/pytorch/pytorch/pull/120400).
is_tracing = (
torch.jit.is_tracing()
or isinstance(input_tensor, torch.fx.Proxy)
or (hasattr(torch, "_dynamo") and torch._dynamo.is_compiling())
)
if not is_tracing and torch.any(attention_mask != 1):
# Attend to all tokens in masked rows from the causal_mask, for example the relevant first rows when
# using left padding. This is required by F.scaled_dot_product_attention memory-efficient attention path.
# Details: https://github.com/pytorch/pytorch/issues/110213
causal_mask = causal_mask.mul(
~torch.all(causal_mask == min_dtype, dim=-1, keepdim=True)
).to(dtype)
return causal_mask
class OpenELMForCausalLM(OpenELMPreTrainedModel):
_tied_weights_keys = ["lm_head.weight"]
def __init__(self, config: OpenELMConfig):
super().__init__(config)
self.transformer = OpenELMModel(config)
self.vocab_size = config.vocab_size
if config.share_input_output_layers:
self.lm_head = None
else:
self.lm_head = nn.Linear(config.model_dim, config.vocab_size, bias=False)
# Initialize weights and apply final processing
self.post_init()
def get_input_embeddings(self):
return self.transformer.token_embeddings
def set_input_embeddings(self, value):
self.transformer.token_embeddings = value
def get_output_embeddings(self):
return self.lm_head
def set_output_embeddings(self, new_embeddings):
self.lm_head = new_embeddings
def set_decoder(self, decoder):
self.transformer = decoder
def get_decoder(self):
return self.transformer
def forward(
self,
input_ids: torch.LongTensor = None,
attention_mask: Optional[torch.Tensor] = None,
position_ids: Optional[torch.LongTensor] = None,
past_key_values: Optional[List[torch.FloatTensor]] = None,
inputs_embeds: Optional[torch.FloatTensor] = None,
labels: Optional[torch.LongTensor] = None,
use_cache: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
cache_position: Optional[torch.LongTensor] = None,
) -> Union[Tuple, CausalLMOutputWithPast]:
output_attentions = (
output_attentions
if output_attentions is not None
else self.config.output_attentions
)
output_hidden_states = (
output_hidden_states
if output_hidden_states is not None
else self.config.output_hidden_states
)
return_dict = (
return_dict if return_dict is not None else self.config.use_return_dict
)
# decoder outputs consists of (dec_features, layer_state, dec_hidden, dec_attn)
outputs = self.transformer(
input_ids=input_ids,
attention_mask=attention_mask,
position_ids=position_ids,
past_key_values=past_key_values,
inputs_embeds=inputs_embeds,
use_cache=use_cache,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
cache_position=cache_position,
)
hidden_states = outputs[0]
if self.lm_head is None:
# shared
logits = F.linear(
hidden_states, weight=self.transformer.token_embeddings.weight
)
else:
logits = self.lm_head(hidden_states)
logits = logits[:, : self.config.vocab_size]
loss = None
if labels is not None:
# Shift so that tokens < n predict n
shift_logits = logits[..., :-1, :].contiguous()
shift_labels = labels[..., 1:].contiguous()
# Flatten the tokens
loss_fct = CrossEntropyLoss()
shift_logits = shift_logits.view(-1, self.config.vocab_size)
shift_labels = shift_labels.view(-1)
# Enable model parallelism
shift_labels = shift_labels.to(shift_logits.device)
loss = loss_fct(shift_logits, shift_labels)
if not return_dict:
output = (logits,) + outputs[1:]
return (loss,) + output if loss is not None else output
return CausalLMOutputWithPast(
loss=loss,
logits=logits,
past_key_values=outputs.past_key_values,
hidden_states=outputs.hidden_states,
attentions=outputs.attentions,
)
def prepare_inputs_for_generation(
self,
input_ids,
past_key_values=None,
attention_mask=None,
inputs_embeds=None,
**kwargs,
):
past_length = 0
if past_key_values is not None:
if isinstance(past_key_values, Cache):
cache_length = past_key_values.get_seq_length()
past_length = past_key_values.seen_tokens
max_cache_length = past_key_values.get_max_length()
else:
cache_length = past_length = past_key_values[0][0].shape[2]
max_cache_length = None
# Keep only the unprocessed tokens:
# 1 - If the length of the attention_mask exceeds the length of input_ids, then we are in a setting where
# some of the inputs are exclusively passed as part of the cache (e.g. when passing input_embeds as
# input)
if (
attention_mask is not None
and attention_mask.shape[1] > input_ids.shape[1]
):
input_ids = input_ids[:, -(attention_mask.shape[1] - past_length) :]
# 2 - If the past_length is smaller than input_ids', then input_ids holds all input tokens. We can discard
# input_ids based on the past_length.
elif past_length < input_ids.shape[1]:
input_ids = input_ids[:, past_length:]
# 3 - Otherwise (past_length >= input_ids.shape[1]), let's assume input_ids only has unprocessed tokens.
# If we are about to go beyond the maximum cache length, we need to crop the input attention mask.
if (
max_cache_length is not None
and attention_mask is not None
and cache_length + input_ids.shape[1] > max_cache_length
):
attention_mask = attention_mask[:, -max_cache_length:]
position_ids = kwargs.get("position_ids", None)
if attention_mask is not None and position_ids is None:
# create position_ids on the fly for batch generation
position_ids = attention_mask.long().cumsum(-1) - 1
position_ids.masked_fill_(attention_mask == 0, 1)
if past_key_values:
position_ids = position_ids[:, -input_ids.shape[1] :]
if self.generation_config.cache_implementation == "static":
# generation with static cache
cache_position = kwargs.get("cache_position", None)
if cache_position is None:
past_length = 0
else:
past_length = cache_position[-1] + 1
input_ids = input_ids[:, past_length:]
position_ids = position_ids[:, past_length:]
# we should only keep a `cache_position` in generate, and do +=1.
# same goes for position ids. Could also help with continued generation.
cache_position = torch.arange(
past_length,
past_length + position_ids.shape[-1],
device=position_ids.device,
)
# if `inputs_embeds` are passed, we only want to use them in the 1st generation step
if inputs_embeds is not None and past_key_values is None:
model_inputs = {"inputs_embeds": inputs_embeds}
else:
# The `contiguous()` here is necessary to have a static stride during decoding. torchdynamo otherwise
# recompiles graphs as the stride of the inputs is a guard. Ref: https://github.com/huggingface/transformers/pull/29114
# We could use `next_tokens` directly instead.
model_inputs = {"input_ids": input_ids.contiguous()}
model_inputs.update(
{
"position_ids": position_ids.contiguous(),
"cache_position": cache_position,
"past_key_values": past_key_values,
"use_cache": kwargs.get("use_cache"),
"attention_mask": attention_mask,
}
)
return model_inputs
@staticmethod
def _reorder_cache(past_key_values, beam_idx):
reordered_past = ()
for layer_past in past_key_values:
reordered_past += (
tuple(
past_state.index_select(0, beam_idx.to(past_state.device))
for past_state in layer_past
),
)
return reordered_past