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import torch |
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import torch.nn as nn |
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import torch.nn.functional as F |
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import math |
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from typing import Optional, List |
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class LoRALayer(): |
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def __init__( |
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self, |
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r: int, |
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lora_alpha: int, |
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lora_dropout: float, |
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merge_weights: bool, |
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): |
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self.r = r |
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self.lora_alpha = lora_alpha |
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if lora_dropout > 0.: |
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self.lora_dropout = nn.Dropout(p=lora_dropout) |
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else: |
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self.lora_dropout = lambda x: x |
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self.merged = False |
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self.merge_weights = merge_weights |
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class Embedding(nn.Embedding, LoRALayer): |
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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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r: int = 0, |
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lora_alpha: int = 1, |
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merge_weights: bool = True, |
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**kwargs |
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): |
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nn.Embedding.__init__(self, num_embeddings, embedding_dim, **kwargs) |
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LoRALayer.__init__(self, r=r, lora_alpha=lora_alpha, lora_dropout=0, |
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merge_weights=merge_weights) |
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if r > 0: |
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self.lora_A = nn.Parameter(self.weight.new_zeros((r, num_embeddings))) |
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self.lora_B = nn.Parameter(self.weight.new_zeros((embedding_dim, r))) |
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self.scaling = self.lora_alpha / self.r |
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self.weight.requires_grad = False |
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self.reset_parameters() |
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def reset_parameters(self): |
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nn.Embedding.reset_parameters(self) |
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if hasattr(self, 'lora_A'): |
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nn.init.zeros_(self.lora_A) |
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nn.init.normal_(self.lora_B) |
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def train(self, mode: bool = True): |
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nn.Embedding.train(self, mode) |
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if mode: |
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if self.merge_weights and self.merged: |
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if self.r > 0: |
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self.weight.data -= (self.lora_B @ self.lora_A).transpose(0, 1) * self.scaling |
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self.merged = False |
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else: |
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if self.merge_weights and not self.merged: |
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if self.r > 0: |
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self.weight.data += (self.lora_B @ self.lora_A).transpose(0, 1) * self.scaling |
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self.merged = True |
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def forward(self, x: torch.Tensor): |
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if self.r > 0 and not self.merged: |
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result = nn.Embedding.forward(self, x) |
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if self.r > 0: |
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after_A = F.embedding( |
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x, self.lora_A.transpose(0, 1), self.padding_idx, self.max_norm, |
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self.norm_type, self.scale_grad_by_freq, self.sparse |
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) |
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result += (after_A @ self.lora_B.transpose(0, 1)) * self.scaling |
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return result |
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else: |
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return nn.Embedding.forward(self, x) |
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class Linear(nn.Linear, LoRALayer): |
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def __init__( |
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self, |
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in_features: int, |
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out_features: int, |
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r: int = 0, |
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lora_alpha: int = 1, |
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lora_dropout: float = 0., |
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fan_in_fan_out: bool = False, |
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merge_weights: bool = True, |
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**kwargs |
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): |
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nn.Linear.__init__(self, in_features, out_features, **kwargs) |
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LoRALayer.__init__(self, r=r, lora_alpha=lora_alpha, lora_dropout=lora_dropout, |
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merge_weights=merge_weights) |
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self.fan_in_fan_out = fan_in_fan_out |
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if r > 0: |
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self.lora_A = nn.Parameter(self.weight.new_zeros((r, in_features))) |
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self.lora_B = nn.Parameter(self.weight.new_zeros((out_features, r))) |
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self.scaling = self.lora_alpha / self.r |
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self.weight.requires_grad = False |
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self.reset_parameters() |
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if fan_in_fan_out: |
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self.weight.data = self.weight.data.transpose(0, 1) |
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def reset_parameters(self): |
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nn.Linear.reset_parameters(self) |
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if hasattr(self, 'lora_A'): |
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nn.init.kaiming_uniform_(self.lora_A, a=math.sqrt(5)) |
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nn.init.zeros_(self.lora_B) |
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def train(self, mode: bool = True): |
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def T(w): |
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return w.transpose(0, 1) if self.fan_in_fan_out else w |
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nn.Linear.train(self, mode) |
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if mode: |
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if self.merge_weights and self.merged: |
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if self.r > 0: |
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self.weight.data -= T(self.lora_B @ self.lora_A) * self.scaling |
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self.merged = False |
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else: |
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if self.merge_weights and not self.merged: |
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if self.r > 0: |
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self.weight.data += T(self.lora_B @ self.lora_A) * self.scaling |
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self.merged = True |
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def forward(self, x: torch.Tensor): |
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def T(w): |
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return w.transpose(0, 1) if self.fan_in_fan_out else w |
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if self.r > 0 and not self.merged: |
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result = F.linear(x, T(self.weight), bias=self.bias) |
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if self.r > 0: |
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result += (self.lora_dropout(x) @ self.lora_A.transpose(0, 1) @ self.lora_B.transpose(0, 1)) * self.scaling |
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return result |
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else: |
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return F.linear(x, T(self.weight), bias=self.bias) |
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class MergedLinear(nn.Linear, LoRALayer): |
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def __init__( |
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self, |
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in_features: int, |
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out_features: int, |
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r: int = 0, |
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lora_alpha: int = 1, |
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lora_dropout: float = 0., |
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enable_lora: List[bool] = [False], |
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fan_in_fan_out: bool = False, |
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merge_weights: bool = True, |
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**kwargs |
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): |
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nn.Linear.__init__(self, in_features, out_features, **kwargs) |
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LoRALayer.__init__(self, r=r, lora_alpha=lora_alpha, lora_dropout=lora_dropout, |
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merge_weights=merge_weights) |
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assert out_features % len(enable_lora) == 0, \ |
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'The length of enable_lora must divide out_features' |
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self.enable_lora = enable_lora |
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self.fan_in_fan_out = fan_in_fan_out |
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if r > 0 and any(enable_lora): |
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self.lora_A = nn.Parameter( |
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self.weight.new_zeros((r * sum(enable_lora), in_features))) |
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self.lora_B = nn.Parameter( |
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self.weight.new_zeros((out_features // len(enable_lora) * sum(enable_lora), r)) |
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) |
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self.scaling = self.lora_alpha / self.r |
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self.weight.requires_grad = False |
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self.lora_ind = self.weight.new_zeros( |
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(out_features, ), dtype=torch.bool |
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).view(len(enable_lora), -1) |
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self.lora_ind[enable_lora, :] = True |
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self.lora_ind = self.lora_ind.view(-1) |
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self.reset_parameters() |
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if fan_in_fan_out: |
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self.weight.data = self.weight.data.transpose(0, 1) |
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def reset_parameters(self): |
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nn.Linear.reset_parameters(self) |
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if hasattr(self, 'lora_A'): |
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nn.init.kaiming_uniform_(self.lora_A, a=math.sqrt(5)) |
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nn.init.zeros_(self.lora_B) |
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def zero_pad(self, x): |
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result = x.new_zeros((*x.shape[:-1], self.out_features)) |
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result = result.view(-1, self.out_features) |
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result[:, self.lora_ind] = x.reshape( |
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-1, self.out_features // len(self.enable_lora) * sum(self.enable_lora) |
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) |
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return result.view((*x.shape[:-1], self.out_features)) |
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def train(self, mode: bool = True): |
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def T(w): |
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return w.transpose(0, 1) if self.fan_in_fan_out else w |
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nn.Linear.train(self, mode) |
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print(f"lora.train, scaling = {self.scaling}, mode = {mode}, merge_weights = {self.merge_weights}, merged = {self.merged}") |
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if mode: |
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if self.merge_weights and self.merged: |
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if self.r > 0 and any(self.enable_lora): |
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delta_w = F.conv1d( |
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self.lora_A.data.unsqueeze(0), |
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self.lora_B.data.unsqueeze(-1), |
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groups=sum(self.enable_lora) |
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).squeeze(0) |
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self.weight.data -= self.zero_pad(T(delta_w * self.scaling)) |
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self.merged = False |
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else: |
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if self.merge_weights and not self.merged: |
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if self.r > 0 and any(self.enable_lora): |
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delta_w = F.conv1d( |
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self.lora_A.data.unsqueeze(0), |
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self.lora_B.data.unsqueeze(-1), |
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groups=sum(self.enable_lora) |
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).squeeze(0) |
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self.weight.data += self.zero_pad(T(delta_w * self.scaling)) |
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self.merged = True |
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def forward(self, x: torch.Tensor): |
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def T(w): |
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return w.transpose(0, 1) if self.fan_in_fan_out else w |
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if self.merged: |
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return F.linear(x, T(self.weight), bias=self.bias) |
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else: |
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result = F.linear(x, T(self.weight), bias=self.bias) |
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if self.r > 0: |
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after_A = F.linear(self.lora_dropout(x), self.lora_A) |
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after_B = F.conv1d( |
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after_A.transpose(-2, -1), |
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self.lora_B.unsqueeze(-1), |
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groups=sum(self.enable_lora) |
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).transpose(-2, -1) |
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result += self.zero_pad(after_B) * self.scaling |
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return result |
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class ConvLoRA(nn.Module, LoRALayer): |
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def __init__(self, conv_module, in_channels, out_channels, kernel_size, r=0, lora_alpha=1, lora_dropout=0., merge_weights=True, **kwargs): |
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super(ConvLoRA, self).__init__() |
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self.conv = conv_module(in_channels, out_channels, kernel_size, **kwargs) |
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LoRALayer.__init__(self, r=r, lora_alpha=lora_alpha, lora_dropout=lora_dropout, merge_weights=merge_weights) |
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assert isinstance(kernel_size, int) |
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if r > 0: |
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self.lora_A = nn.Parameter( |
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self.conv.weight.new_zeros((r * kernel_size, in_channels * kernel_size)) |
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) |
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self.lora_B = nn.Parameter( |
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self.conv.weight.new_zeros((out_channels//self.conv.groups*kernel_size, r*kernel_size)) |
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) |
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self.scaling = self.lora_alpha / self.r |
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self.conv.weight.requires_grad = False |
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self.reset_parameters() |
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self.merged = False |
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def reset_parameters(self): |
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self.conv.reset_parameters() |
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if hasattr(self, 'lora_A'): |
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nn.init.kaiming_uniform_(self.lora_A, a=math.sqrt(5)) |
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nn.init.zeros_(self.lora_B) |
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def train(self, mode=True): |
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super(ConvLoRA, self).train(mode) |
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if mode: |
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if self.merge_weights and self.merged: |
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self.conv.weight.data -= (self.lora_B @ self.lora_A).view(self.conv.weight.shape) * self.scaling |
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self.merged = False |
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else: |
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if self.merge_weights and not self.merged: |
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self.conv.weight.data += (self.lora_B @ self.lora_A).view(self.conv.weight.shape) * self.scaling |
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self.merged = True |
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def forward(self, x): |
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if self.r > 0 and not self.merged: |
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return self.conv._conv_forward( |
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x, |
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self.conv.weight + (self.lora_B @ self.lora_A).view(self.conv.weight.shape) * self.scaling, |
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self.conv.bias |
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) |
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return self.conv(x) |
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class Conv2d(ConvLoRA): |
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def __init__(self, *args, **kwargs): |
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super(Conv2d, self).__init__(nn.Conv2d, *args, **kwargs) |
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class Conv1d(ConvLoRA): |
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def __init__(self, *args, **kwargs): |
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super(Conv1d, self).__init__(nn.Conv1d, *args, **kwargs) |
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class Conv3d(ConvLoRA): |
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def __init__(self, *args, **kwargs): |
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super(Conv3d, self).__init__(nn.Conv3d, *args, **kwargs) |
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