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chore: import upstream snapshot with attribution
2026-07-13 13:24:42 +08:00

241 lines
9.0 KiB
Python

# Copyright 2026-present the HuggingFace Inc. team.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from copy import deepcopy
import pytest
import torch
from peft import LoraConfig, get_peft_model
from peft.tuners.lora.config import BdLoraConfig
from peft.tuners.lora.variants import BlockDiagonalLinear
def _fill_deterministic_weight(weight: torch.Tensor) -> None:
values = torch.arange(weight.numel(), dtype=weight.dtype, device=weight.device).reshape_as(weight)
weight.data.copy_(values)
def _dense_weight(module: torch.nn.Module) -> torch.Tensor:
if isinstance(module, BlockDiagonalLinear):
return module.weight_as_blockdiagonal_matrix()
return module.weight
def _copy_adapter_weights(dst_layer, src_layer) -> None:
dst_layer.lora_A["default"].weight.data.copy_(src_layer.lora_A["default"].weight.data)
dst_layer.lora_B["default"].weight.data.copy_(src_layer.lora_B["default"].weight.data)
class TinyMLP(torch.nn.Module):
def __init__(self):
super().__init__()
self.lin0 = torch.nn.Linear(10, 20)
self.relu = torch.nn.ReLU()
self.lin1 = torch.nn.Linear(20, 2)
def forward(self, x):
x = self.lin0(x)
x = self.relu(x)
return self.lin1(x)
class TestBdLora:
@pytest.mark.parametrize(
"nblocks,in_features,out_features,input_shape",
[
(2, 8, 8, (3, 8)),
(2, 8, 8, (2, 5, 8)),
(4, 12, 8, (3, 12)),
(4, 12, 8, (2, 5, 12)),
],
)
def test_block_diagonal_linear_forward_matches_dense_equivalent(
self, nblocks, in_features, out_features, input_shape
):
torch.manual_seed(0)
layer = BlockDiagonalLinear(in_features=in_features, out_features=out_features, nblocks=nblocks)
_fill_deterministic_weight(layer.weight)
x = torch.randn(*input_shape)
# Compare the packed implementation against the explicit dense reconstruction
dense_weight = layer.weight_as_blockdiagonal_matrix()
expected = x @ dense_weight.T
actual = layer(x)
assert torch.allclose(
actual,
expected,
atol=1e-5,
rtol=1e-4,
), f"BlockDiagonalLinear forward mismatch for input_shape={input_shape}, nblocks={nblocks}"
@pytest.mark.parametrize(
"bdlora_config",
[
BdLoraConfig(target_modules_bd_a=["lin0"], nblocks=2, match_strict=True),
BdLoraConfig(target_modules_bd_b=["lin0"], nblocks=2, match_strict=True),
],
)
def test_bdlora_merge_delta_matches_manual_dense_equivalent(self, bdlora_config):
torch.manual_seed(0)
model = TinyMLP()
base_weight = model.lin0.weight.detach().clone()
config = LoraConfig(
r=4,
lora_alpha=8,
lora_dropout=0.0,
target_modules=["lin0"],
use_bdlora=bdlora_config,
)
peft_model = get_peft_model(deepcopy(model), config).eval()
lora_layer = peft_model.base_model.model.lin0
_fill_deterministic_weight(lora_layer.lora_A["default"].weight)
_fill_deterministic_weight(lora_layer.lora_B["default"].weight)
# Convert any block-diagonal factor back to its dense view before multiplying
dense_a = _dense_weight(lora_layer.lora_A["default"])
dense_b = _dense_weight(lora_layer.lora_B["default"])
expected_delta = (dense_b @ dense_a) * lora_layer.scaling["default"]
peft_model.merge_adapter()
merged_weight = peft_model.base_model.model.lin0.base_layer.weight.data
assert torch.allclose(
merged_weight,
base_weight + expected_delta,
atol=1e-5,
rtol=1e-4,
), f"Merged weight mismatch for BD-LoRA config={bdlora_config}"
def test_bdlora_nblocks_one_matches_vanilla_lora(self):
# With nblocks=1, there is no block split: out_features // 1 = out_features and r // 1 = r
# So the BD-LoRA packing reduces to the same shapes as vanilla LoRA, and the outputs should match
torch.manual_seed(0)
base_model = TinyMLP()
x = torch.randn(5, 10)
lora_rank = 4
lora_alpha = 8
lora_dropout = 0.0
target_modules = ["lin0"]
bd_config = LoraConfig(
r=lora_rank,
lora_alpha=lora_alpha,
lora_dropout=lora_dropout,
target_modules=target_modules,
use_bdlora=BdLoraConfig(target_modules_bd_a=target_modules, nblocks=1, match_strict=True),
)
vanilla_config = LoraConfig(
r=lora_rank, lora_alpha=lora_alpha, lora_dropout=lora_dropout, target_modules=target_modules
)
bd_model = get_peft_model(deepcopy(base_model), bd_config).eval()
vanilla_model = get_peft_model(deepcopy(base_model), vanilla_config).eval()
# Copy adapter tensors so the only remaining difference is the block packing path
_copy_adapter_weights(vanilla_model.base_model.model.lin0, bd_model.base_model.model.lin0)
bd_output = bd_model(x)
vanilla_output = vanilla_model(x)
assert torch.allclose(
bd_output,
vanilla_output,
atol=1e-5,
rtol=1e-4,
), "nblocks=1 BD-LoRA forward output should match vanilla LoRA"
bd_model.merge_adapter()
vanilla_model.merge_adapter()
assert torch.allclose(
bd_model.base_model.model.lin0.base_layer.weight.data,
vanilla_model.base_model.model.lin0.base_layer.weight.data,
atol=1e-5,
rtol=1e-4,
), "nblocks=1 merged weights should match vanilla LoRA"
@pytest.mark.parametrize(
"bdlora_config,expected_a_shape,expected_b_shape,expected_adapter_params",
[
# A-block: only LoRA-A is block-diagonal. With in_features=10, nblocks=2, and r=4,
# A stores (4, 10 // 2) = (4, 5) parameters, while B stays unchanged as dense at (20, 4)
# Total trainable adapter params: 4 * 5 + 20 * 4 = 100
(BdLoraConfig(target_modules_bd_a=["lin0"], nblocks=2, match_strict=True), (4, 5), (20, 4), 100),
# B-block: only LoRA-B is block-diagonal. The packed parameter stores (out_features, r // nblocks),
# so B keeps 20 rows but only 4 // 2 = 2 columns per block. That is 2 blocks of shape (10, 2),
# for 2 * 10 * 2 = 40 B parameters. A stays unchanged as dense at (4, 10), so the total is 40 + 40 = 80
(BdLoraConfig(target_modules_bd_b=["lin0"], nblocks=2, match_strict=True), (4, 10), (20, 2), 80),
],
)
def test_bdlora_packed_shapes_and_adapter_param_counts_vs_vanilla(
self, bdlora_config, expected_a_shape, expected_b_shape, expected_adapter_params
):
torch.manual_seed(0)
base_model = TinyMLP()
lora_rank = 4
lora_alpha = 8
lora_dropout = 0.0
target_modules = ["lin0"]
bd_config = LoraConfig(
r=lora_rank,
lora_alpha=lora_alpha,
lora_dropout=lora_dropout,
target_modules=target_modules,
use_bdlora=bdlora_config,
)
vanilla_config = LoraConfig(
r=lora_rank, lora_alpha=lora_alpha, lora_dropout=lora_dropout, target_modules=target_modules
)
bd_model = get_peft_model(deepcopy(base_model), bd_config).eval()
vanilla_model = get_peft_model(deepcopy(base_model), vanilla_config).eval()
bd_layer = bd_model.base_model.model.lin0
vanilla_layer = vanilla_model.base_model.model.lin0
bd_a = bd_layer.lora_A["default"]
bd_b = bd_layer.lora_B["default"]
vanilla_a = vanilla_layer.lora_A["default"]
vanilla_b = vanilla_layer.lora_B["default"]
assert tuple(bd_a.weight.shape) == expected_a_shape
assert tuple(bd_b.weight.shape) == expected_b_shape
assert tuple(vanilla_a.weight.shape) == (4, 10)
assert tuple(vanilla_b.weight.shape) == (20, 4)
vanilla_adapter_params = sum(
p.numel() for module in (vanilla_a, vanilla_b) for p in module.parameters() if p.requires_grad
)
bd_adapter_params = sum(p.numel() for module in (bd_a, bd_b) for p in module.parameters() if p.requires_grad)
# For vanilla LoRA on lin0: A has shape (r, in)=(4,10) and B has shape (out, r)=(20,4),
# so trainable adapter params are 4*10 + 20*4 = 120
assert vanilla_adapter_params == 120
assert bd_adapter_params == expected_adapter_params
# BD-LoRA must reduce trainable adapter parameters vs vanilla LoRA
assert bd_adapter_params < vanilla_adapter_params