yangjun dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ
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README.md dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ
ms_deformable_attn_op.cc dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ
ms_deformable_attn_op.cu dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ
setup_ms_deformable_attn_op.py dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ
test_ms_deformable_attn_op.py dfa27afb39 提交PaddleDetection develop 分支 d56cf3f7c294a7138013dac21f87da4ea6bee829 1 gadu atpakaļ

README.md

Multi-scale deformable attention自定义OP编译

该自定义OP是参考自定义外部算子

1. 环境依赖

  • Paddle >= 2.3.2
  • gcc 8.2

2. 安装

请在当前路径下进行编译安装

cd PaddleDetection/ppdet/modeling/transformers/ext_op/
python setup_ms_deformable_attn_op.py install

编译完成后即可使用,以下为ms_deformable_attn的使用示例

# 引入自定义op
from deformable_detr_ops import ms_deformable_attn

# 构造fake input tensor
bs, n_heads, c = 2, 8, 8
query_length, n_levels, n_points = 2, 2, 2
spatial_shapes = paddle.to_tensor([(6, 4), (3, 2)], dtype=paddle.int64)
level_start_index = paddle.concat((paddle.to_tensor(
    [0], dtype=paddle.int64), spatial_shapes.prod(1).cumsum(0)[:-1]))
value_length = sum([(H * W).item() for H, W in spatial_shapes])

def get_test_tensors(channels):
    value = paddle.rand(
        [bs, value_length, n_heads, channels], dtype=paddle.float32) * 0.01
    sampling_locations = paddle.rand(
        [bs, query_length, n_heads, n_levels, n_points, 2],
        dtype=paddle.float32)
    attention_weights = paddle.rand(
        [bs, query_length, n_heads, n_levels, n_points],
        dtype=paddle.float32) + 1e-5
    attention_weights /= attention_weights.sum(-1, keepdim=True).sum(
        -2, keepdim=True)
    return [value, sampling_locations, attention_weights]

value, sampling_locations, attention_weights = get_test_tensors(c)

output = ms_deformable_attn(value,
                            spatial_shapes,
                            level_start_index,
                            sampling_locations,
                            attention_weights)

3. 单元测试

可以通过执行单元测试来确认自定义算子功能的正确性,执行单元测试的示例如下所示:

python test_ms_deformable_attn_op.py

运行成功后,打印如下:

*True check_forward_equal_with_paddle_float: max_abs_err 6.98e-10 max_rel_err 2.03e-07
*tensor1 True check_gradient_numerical(D=30)
*tensor2 True check_gradient_numerical(D=30)
*tensor3 True check_gradient_numerical(D=30)
*tensor1 True check_gradient_numerical(D=32)
*tensor2 True check_gradient_numerical(D=32)
*tensor3 True check_gradient_numerical(D=32)
*tensor1 True check_gradient_numerical(D=64)
*tensor2 True check_gradient_numerical(D=64)
*tensor3 True check_gradient_numerical(D=64)
*tensor1 True check_gradient_numerical(D=71)
*tensor2 True check_gradient_numerical(D=71)
*tensor3 True check_gradient_numerical(D=71)
*tensor1 True check_gradient_numerical(D=128)
*tensor2 True check_gradient_numerical(D=128)
*tensor3 True check_gradient_numerical(D=128)
*tensor1 True check_gradient_numerical(D=1024)
*tensor2 True check_gradient_numerical(D=1024)
*tensor3 True check_gradient_numerical(D=1024)
*tensor1 True check_gradient_numerical(D=1025)
*tensor2 True check_gradient_numerical(D=1025)
*tensor3 True check_gradient_numerical(D=1025)
*tensor1 True check_gradient_numerical(D=2048)
*tensor2 True check_gradient_numerical(D=2048)
*tensor3 True check_gradient_numerical(D=2048)
*tensor1 True check_gradient_numerical(D=3096)
*tensor2 True check_gradient_numerical(D=3096)
*tensor3 True check_gradient_numerical(D=3096)