| import numpy as np |
| import pytest |
| import torch |
|
|
| from mmdet.utils import AvoidOOM |
| from mmdet.utils.memory import cast_tensor_type |
|
|
|
|
| def test_avoidoom(): |
| tensor = torch.from_numpy(np.random.random((20, 20))) |
| if torch.cuda.is_available(): |
| tensor = tensor.cuda() |
| |
| default_result = torch.mm(tensor, tensor.transpose(1, 0)) |
|
|
| |
| AvoidCudaOOM = AvoidOOM() |
| result = AvoidCudaOOM.retry_if_cuda_oom(torch.mm)(tensor, |
| tensor.transpose( |
| 1, 0)) |
| assert default_result.device == result.device and \ |
| default_result.dtype == result.dtype and \ |
| torch.equal(default_result, result) |
|
|
| |
| AvoidCudaOOM = AvoidOOM(test=True) |
| result = AvoidCudaOOM.retry_if_cuda_oom(torch.mm)(tensor, |
| tensor.transpose( |
| 1, 0)) |
| assert default_result.device == result.device and \ |
| default_result.dtype == result.dtype and \ |
| torch.allclose(default_result, result, 1e-3) |
|
|
| |
| AvoidCudaOOM = AvoidOOM(test=True) |
| result = AvoidCudaOOM.retry_if_cuda_oom(torch.mm)(tensor, |
| tensor.transpose( |
| 1, 0)) |
| assert result.dtype == default_result.dtype and \ |
| result.device == default_result.device and \ |
| torch.allclose(default_result, result) |
|
|
| |
| AvoidCudaOOM = AvoidOOM(test=True, to_cpu=False) |
| result = AvoidCudaOOM.retry_if_cuda_oom(torch.mm)(tensor, |
| tensor.transpose( |
| 1, 0)) |
| assert result.dtype == default_result.dtype and \ |
| result.device == default_result.device |
|
|
| else: |
| default_result = torch.mm(tensor, tensor.transpose(1, 0)) |
| AvoidCudaOOM = AvoidOOM() |
| result = AvoidCudaOOM.retry_if_cuda_oom(torch.mm)(tensor, |
| tensor.transpose( |
| 1, 0)) |
| assert default_result.device == result.device and \ |
| default_result.dtype == result.dtype and \ |
| torch.equal(default_result, result) |
|
|
|
|
| def test_cast_tensor_type(): |
| inputs = torch.rand(10) |
| if torch.cuda.is_available(): |
| inputs = inputs.cuda() |
| with pytest.raises(AssertionError): |
| cast_tensor_type(inputs, src_type=None, dst_type=None) |
| |
| out = cast_tensor_type(10., dst_type=torch.half) |
| assert out == 10. and isinstance(out, float) |
| |
| fp16_out = cast_tensor_type(inputs, dst_type=torch.half) |
| assert fp16_out.dtype == torch.half |
| fp32_out = cast_tensor_type(fp16_out, dst_type=torch.float32) |
| assert fp32_out.dtype == torch.float32 |
|
|
| |
| list_input = [inputs, inputs] |
| list_outs = cast_tensor_type(list_input, dst_type=torch.half) |
| assert len(list_outs) == len(list_input) and \ |
| isinstance(list_outs, list) |
| for out in list_outs: |
| assert out.dtype == torch.half |
| |
| dict_input = {'test1': inputs, 'test2': inputs} |
| dict_outs = cast_tensor_type(dict_input, dst_type=torch.half) |
| assert len(dict_outs) == len(dict_input) and \ |
| isinstance(dict_outs, dict) |
|
|
| |
| if torch.cuda.is_available(): |
| cpu_device = torch.empty(0).device |
| gpu_device = inputs.device |
| cpu_out = cast_tensor_type(inputs, dst_type=cpu_device) |
| assert cpu_out.device == cpu_device |
|
|
| gpu_out = cast_tensor_type(inputs, dst_type=gpu_device) |
| assert gpu_out.device == gpu_device |
|
|
