371 lines
13 KiB
Python
371 lines
13 KiB
Python
# Copyright (c) Facebook, Inc. and its affiliates.
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#
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# This source code is licensed under the MIT license found in the
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# LICENSE file in the root directory of this source tree.
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from typing import Optional, TypeVar, Union, overload
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import torch
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import torch.nn.functional as F
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from torch import Tensor, device, dtype, nn
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import bitsandbytes as bnb
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import bitsandbytes.functional
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from bitsandbytes.autograd._functions import get_inverse_transform_indices, undo_layout
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from bitsandbytes.optim import GlobalOptimManager
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from bitsandbytes.utils import OutlierTracer, find_outlier_dims
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T = TypeVar("T", bound="torch.nn.Module")
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class StableEmbedding(torch.nn.Embedding):
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def __init__(
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self,
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num_embeddings: int,
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embedding_dim: int,
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padding_idx: Optional[int] = None,
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max_norm: Optional[float] = None,
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norm_type: float = 2.0,
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scale_grad_by_freq: bool = False,
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sparse: bool = False,
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_weight: Optional[Tensor] = None,
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device=None,
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dtype=None,
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) -> None:
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super().__init__(
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num_embeddings,
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embedding_dim,
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padding_idx,
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max_norm,
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norm_type,
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scale_grad_by_freq,
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sparse,
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_weight,
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device,
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dtype,
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)
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self.norm = torch.nn.LayerNorm(embedding_dim, device=device)
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GlobalOptimManager.get_instance().register_module_override(
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self, "weight", {"optim_bits": 32}
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)
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def reset_parameters(self) -> None:
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torch.nn.init.xavier_uniform_(self.weight)
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self._fill_padding_idx_with_zero()
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""" !!! This is a redefinition of _fill_padding_idx_with_zero in torch.nn.Embedding
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to make the Layer compatible with Pytorch < 1.9.
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This means that if this changes in future PyTorch releases this need to change too
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which is cumbersome. However, with this we can ensure compatibility with previous
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PyTorch releases.
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"""
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def _fill_padding_idx_with_zero(self) -> None:
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if self.padding_idx is not None:
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with torch.no_grad():
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self.weight[self.padding_idx].fill_(0)
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def forward(self, input: Tensor) -> Tensor:
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emb = F.embedding(
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input,
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self.weight,
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self.padding_idx,
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self.max_norm,
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self.norm_type,
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self.scale_grad_by_freq,
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self.sparse,
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)
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# always apply layer norm in full precision
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emb = emb.to(torch.get_default_dtype())
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return self.norm(emb).to(self.weight.dtype)
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class Embedding(torch.nn.Embedding):
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def __init__(
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self,
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num_embeddings: int,
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embedding_dim: int,
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padding_idx: Optional[int] = None,
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max_norm: Optional[float] = None,
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norm_type: float = 2.0,
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scale_grad_by_freq: bool = False,
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sparse: bool = False,
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_weight: Optional[Tensor] = None,
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) -> None:
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super().__init__(
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num_embeddings,
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embedding_dim,
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padding_idx,
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max_norm,
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norm_type,
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scale_grad_by_freq,
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sparse,
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_weight,
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)
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GlobalOptimManager.get_instance().register_module_override(
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self, "weight", {"optim_bits": 32}
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)
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def reset_parameters(self) -> None:
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torch.nn.init.xavier_uniform_(self.weight)
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self._fill_padding_idx_with_zero()
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""" !!! This is a redefinition of _fill_padding_idx_with_zero in torch.nn.Embedding
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to make the Layer compatible with Pytorch < 1.9.
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This means that if this changes in future PyTorch releases this need to change too
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which is cumbersome. However, with this we can ensure compatibility with previous
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PyTorch releases.
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"""
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def _fill_padding_idx_with_zero(self) -> None:
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if self.padding_idx is not None:
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with torch.no_grad():
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self.weight[self.padding_idx].fill_(0)
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def forward(self, input: Tensor) -> Tensor:
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emb = F.embedding(
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input,
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self.weight,
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self.padding_idx,
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self.max_norm,
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self.norm_type,
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self.scale_grad_by_freq,
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self.sparse,
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)
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return emb
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class OutlierAwareLinear(nn.Linear):
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def __init__(self, input_features, output_features, bias=True):
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super().__init__(input_features, output_features, bias)
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self.outlier_dim = None
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self.is_quantized = False
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def forward_with_outliers(self, x, outlier_idx):
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raise NotImplementedError('Please override the `forward_with_outliers(self, x, outlier_idx)` function')
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def quantize_weight(self, w, outlier_idx):
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raise NotImplementedError('Please override the `quantize_weights(self, w, outlier_idx)` function')
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def forward(self, x):
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if self.outlier_dim is None:
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tracer = OutlierTracer.get_instance()
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if not tracer.is_initialized():
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print('Please use OutlierTracer.initialize(model) before using the OutlierAwareLinear layer')
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outlier_idx = tracer.get_outliers(self.weight)
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#print(outlier_idx, tracer.get_hvalue(self.weight))
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self.outlier_dim = outlier_idx
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if not self.is_quantized:
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w = self.quantize_weight(self.weight, self.outlier_dim)
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self.weight.data.copy_(w)
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self.is_quantized = True
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return self.forward_with_outliers(x, self.outlier_dim)
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class Int8Params(torch.nn.Parameter):
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def __new__(
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cls,
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data=None,
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requires_grad=True,
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has_fp16_weights=False,
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CB=None,
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SCB=None,
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):
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cls.has_fp16_weights = has_fp16_weights
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cls.CB = None
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cls.SCB = None
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if data is None:
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data = torch.empty(0)
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return torch.Tensor._make_subclass(cls, data, requires_grad)
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def cuda(self, device):
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if self.has_fp16_weights:
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return super().cuda(device)
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else:
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# we store the 8-bit rows-major weight
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# we convert this weight to the turning/ampere weight during the first inference pass
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B = self.data.contiguous().half().cuda(device)
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CB, CBt, SCB, SCBt, coo_tensorB = bnb.functional.double_quant(B)
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del CBt
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del SCBt
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self.data = CB
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setattr(self, "CB", CB)
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setattr(self, "SCB", SCB)
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return self
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@overload
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def to(
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self: T,
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device: Optional[Union[int, device]] = ...,
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dtype: Optional[Union[dtype, str]] = ...,
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non_blocking: bool = ...,
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) -> T:
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...
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@overload
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def to(self: T, dtype: Union[dtype, str], non_blocking: bool = ...) -> T:
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...
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@overload
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def to(self: T, tensor: Tensor, non_blocking: bool = ...) -> T:
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...
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def to(self, *args, **kwargs):
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device, dtype, non_blocking, convert_to_format = torch._C._nn._parse_to(
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*args, **kwargs
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)
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if (
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device is not None
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and device.type == "cuda"
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and self.data.device.type == "cpu"
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):
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return self.cuda(device)
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else:
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new_param = Int8Params(
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super().to(
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device=device, dtype=dtype, non_blocking=non_blocking
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),
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requires_grad=self.requires_grad,
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has_fp16_weights=self.has_fp16_weights,
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)
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new_param.CB = self.CB
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new_param.SCB = self.SCB
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return new_param
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class Linear8bitLt(nn.Linear):
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def __init__(self, input_features, output_features, bias=True, has_fp16_weights=True,
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memory_efficient_backward=False, threshold=0.0, index=None):
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super().__init__(input_features, output_features, bias)
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assert not memory_efficient_backward, "memory_efficient_backward is no longer required and the argument is deprecated in 0.37.0 and will be removed in 0.39.0"
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self.state = bnb.MatmulLtState()
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self.index = index
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self.state.threshold = threshold
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self.state.has_fp16_weights = has_fp16_weights
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self.state.memory_efficient_backward = memory_efficient_backward
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if threshold > 0.0 and not has_fp16_weights:
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self.state.use_pool = True
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self.weight = Int8Params(self.weight.data, has_fp16_weights=has_fp16_weights, requires_grad=has_fp16_weights)
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def _save_to_state_dict(self, destination, prefix, keep_vars):
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if not self.state.has_fp16_weights and self.state.CB is None and self.state.CxB is not None:
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# reorder weight layout back from ampere/turing to row
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reorder_layout = True
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weight_clone = self.weight.data.clone()
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else:
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reorder_layout = False
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try:
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if reorder_layout:
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self.weight.data = undo_layout(self.state.CxB, self.state.tile_indices)
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super()._save_to_state_dict(destination, prefix, keep_vars)
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# we only need to save SCB as extra data, because CB for quantized weights is already stored in weight.data
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weight_name = "SCB"
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# case 1: .cuda was called, SCB is in self.weight
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param_from_weight = getattr(self.weight, weight_name)
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# case 2: self.init_8bit_state was called, SCB is in self.state
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param_from_state = getattr(self.state, weight_name)
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key_name = prefix + f"{weight_name}"
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if param_from_weight is not None:
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destination[key_name] = param_from_weight if keep_vars else param_from_weight.detach()
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elif not self.state.has_fp16_weights and param_from_state is not None:
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destination[key_name] = param_from_state if keep_vars else param_from_state.detach()
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finally:
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if reorder_layout:
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self.weight.data = weight_clone
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def _load_from_state_dict(self, state_dict, prefix, local_metadata, strict,
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missing_keys, unexpected_keys, error_msgs):
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super()._load_from_state_dict(state_dict, prefix, local_metadata, strict, missing_keys, unexpected_keys,
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error_msgs)
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for key in unexpected_keys:
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input_name = key[len(prefix):]
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if input_name == "SCB":
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if self.weight.SCB is None:
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# buffers not yet initialized, can't call them directly without
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raise RuntimeError("Loading a quantized checkpoint into non-quantized Linear8bitLt is "
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"not supported. Please call module.cuda() before module.load_state_dict()")
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input_param = state_dict[key]
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self.weight.SCB.copy_(input_param)
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unexpected_keys.remove(key)
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def init_8bit_state(self):
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self.state.CB = self.weight.CB
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self.state.SCB = self.weight.SCB
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self.weight.CB = None
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self.weight.SCB = None
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def forward(self, x: torch.Tensor):
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self.state.is_training = self.training
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if self.weight.CB is not None:
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self.init_8bit_state()
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# weights are cast automatically as Int8Params, but the bias has to be cast manually
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if self.bias is not None and self.bias.dtype != x.dtype:
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self.bias.data = self.bias.data.to(x.dtype)
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out = bnb.matmul(x, self.weight, bias=self.bias, state=self.state)
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if not self.state.has_fp16_weights:
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if self.state.CB is not None and self.state.CxB is not None:
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# we converted 8-bit row major to turing/ampere format in the first inference pass
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# we no longer need the row-major weight
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del self.state.CB
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self.weight.data = self.state.CxB
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return out
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class SwitchBackLinearBnb(nn.Linear):
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def __init__(
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self,
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input_features,
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output_features,
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bias=True,
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has_fp16_weights=True,
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memory_efficient_backward=False,
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threshold=0.0,
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index=None,
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):
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super().__init__(
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input_features, output_features, bias
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)
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self.state = bnb.MatmulLtState()
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self.index = index
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self.state.threshold = threshold
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self.state.has_fp16_weights = has_fp16_weights
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self.state.memory_efficient_backward = memory_efficient_backward
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if threshold > 0.0 and not has_fp16_weights:
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self.state.use_pool = True
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self.weight = Int8Params(
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self.weight.data, has_fp16_weights=has_fp16_weights, requires_grad=has_fp16_weights
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)
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def init_8bit_state(self):
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self.state.CB = self.weight.CB
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self.state.SCB = self.weight.SCB
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self.weight.CB = None
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self.weight.SCB = None
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def forward(self, x):
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self.state.is_training = self.training
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if self.weight.CB is not None:
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self.init_8bit_state()
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out = bnb.matmul_mixed(x.half(), self.weight.half(), bias=None, state=self.state) + self.bias
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