# Copyright (c) OpenMMLab. All rights reserved. import pytest import torch from torch.nn.modules import AvgPool2d from torch.nn.modules.batchnorm import _BatchNorm from mmpose.models.backbones import SEResNet from mmpose.models.backbones.resnet import ResLayer from mmpose.models.backbones.seresnet import SEBottleneck, SELayer def all_zeros(modules): """Check if the weight(and bias) is all zero.""" weight_zero = torch.equal(modules.weight.data, torch.zeros_like(modules.weight.data)) if hasattr(modules, 'bias'): bias_zero = torch.equal(modules.bias.data, torch.zeros_like(modules.bias.data)) else: bias_zero = True return weight_zero and bias_zero def check_norm_state(modules, train_state): """Check if norm layer is in correct train state.""" for mod in modules: if isinstance(mod, _BatchNorm): if mod.training != train_state: return False return True def test_selayer(): # Test selayer forward layer = SELayer(64) x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 64, 56, 56]) # Test selayer forward with different ratio layer = SELayer(64, ratio=8) x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 64, 56, 56]) def test_bottleneck(): with pytest.raises(AssertionError): # Style must be in ['pytorch', 'caffe'] SEBottleneck(64, 64, style='tensorflow') # Test SEBottleneck with checkpoint forward block = SEBottleneck(64, 64, with_cp=True) assert block.with_cp x = torch.randn(1, 64, 56, 56) x_out = block(x) assert x_out.shape == torch.Size([1, 64, 56, 56]) # Test Bottleneck style block = SEBottleneck(64, 256, stride=2, style='pytorch') assert block.conv1.stride == (1, 1) assert block.conv2.stride == (2, 2) block = SEBottleneck(64, 256, stride=2, style='caffe') assert block.conv1.stride == (2, 2) assert block.conv2.stride == (1, 1) # Test Bottleneck forward block = SEBottleneck(64, 64) x = torch.randn(1, 64, 56, 56) x_out = block(x) assert x_out.shape == torch.Size([1, 64, 56, 56]) def test_res_layer(): # Test ResLayer of 3 Bottleneck w\o downsample layer = ResLayer(SEBottleneck, 3, 64, 64, se_ratio=16) assert len(layer) == 3 assert layer[0].conv1.in_channels == 64 assert layer[0].conv1.out_channels == 16 for i in range(1, len(layer)): assert layer[i].conv1.in_channels == 64 assert layer[i].conv1.out_channels == 16 for i in range(len(layer)): assert layer[i].downsample is None x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 64, 56, 56]) # Test ResLayer of 3 SEBottleneck with downsample layer = ResLayer(SEBottleneck, 3, 64, 256, se_ratio=16) assert layer[0].downsample[0].out_channels == 256 for i in range(1, len(layer)): assert layer[i].downsample is None x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 256, 56, 56]) # Test ResLayer of 3 SEBottleneck with stride=2 layer = ResLayer(SEBottleneck, 3, 64, 256, stride=2, se_ratio=8) assert layer[0].downsample[0].out_channels == 256 assert layer[0].downsample[0].stride == (2, 2) for i in range(1, len(layer)): assert layer[i].downsample is None x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 256, 28, 28]) # Test ResLayer of 3 SEBottleneck with stride=2 and average downsample layer = ResLayer( SEBottleneck, 3, 64, 256, stride=2, avg_down=True, se_ratio=8) assert isinstance(layer[0].downsample[0], AvgPool2d) assert layer[0].downsample[1].out_channels == 256 assert layer[0].downsample[1].stride == (1, 1) for i in range(1, len(layer)): assert layer[i].downsample is None x = torch.randn(1, 64, 56, 56) x_out = layer(x) assert x_out.shape == torch.Size([1, 256, 28, 28]) def test_seresnet(): """Test resnet backbone.""" with pytest.raises(KeyError): # SEResNet depth should be in [50, 101, 152] SEResNet(20) with pytest.raises(AssertionError): # In SEResNet: 1 <= num_stages <= 4 SEResNet(50, num_stages=0) with pytest.raises(AssertionError): # In SEResNet: 1 <= num_stages <= 4 SEResNet(50, num_stages=5) with pytest.raises(AssertionError): # len(strides) == len(dilations) == num_stages SEResNet(50, strides=(1, ), dilations=(1, 1), num_stages=3) with pytest.raises(TypeError): # pretrained must be a string path model = SEResNet(50) model.init_weights(pretrained=0) with pytest.raises(AssertionError): # Style must be in ['pytorch', 'caffe'] SEResNet(50, style='tensorflow') # Test SEResNet50 norm_eval=True model = SEResNet(50, norm_eval=True) model.init_weights() model.train() assert check_norm_state(model.modules(), False) # Test SEResNet50 with torchvision pretrained weight model = SEResNet(depth=50, norm_eval=True) model.init_weights('torchvision://resnet50') model.train() assert check_norm_state(model.modules(), False) # Test SEResNet50 with first stage frozen frozen_stages = 1 model = SEResNet(50, frozen_stages=frozen_stages) model.init_weights() model.train() assert model.norm1.training is False for layer in [model.conv1, model.norm1]: for param in layer.parameters(): assert param.requires_grad is False for i in range(1, frozen_stages + 1): layer = getattr(model, f'layer{i}') for mod in layer.modules(): if isinstance(mod, _BatchNorm): assert mod.training is False for param in layer.parameters(): assert param.requires_grad is False # Test SEResNet50 with BatchNorm forward model = SEResNet(50, out_indices=(0, 1, 2, 3)) model.init_weights() model.train() imgs = torch.randn(1, 3, 224, 224) feat = model(imgs) assert len(feat) == 4 assert feat[0].shape == torch.Size([1, 256, 56, 56]) assert feat[1].shape == torch.Size([1, 512, 28, 28]) assert feat[2].shape == torch.Size([1, 1024, 14, 14]) assert feat[3].shape == torch.Size([1, 2048, 7, 7]) # Test SEResNet50 with layers 1, 2, 3 out forward model = SEResNet(50, out_indices=(0, 1, 2)) model.init_weights() model.train() imgs = torch.randn(1, 3, 224, 224) feat = model(imgs) assert len(feat) == 3 assert feat[0].shape == torch.Size([1, 256, 56, 56]) assert feat[1].shape == torch.Size([1, 512, 28, 28]) assert feat[2].shape == torch.Size([1, 1024, 14, 14]) # Test SEResNet50 with layers 3 (top feature maps) out forward model = SEResNet(50, out_indices=(3, )) model.init_weights() model.train() imgs = torch.randn(1, 3, 224, 224) feat = model(imgs) assert feat.shape == torch.Size([1, 2048, 7, 7]) # Test SEResNet50 with checkpoint forward model = SEResNet(50, out_indices=(0, 1, 2, 3), with_cp=True) for m in model.modules(): if isinstance(m, SEBottleneck): assert m.with_cp model.init_weights() model.train() imgs = torch.randn(1, 3, 224, 224) feat = model(imgs) assert len(feat) == 4 assert feat[0].shape == torch.Size([1, 256, 56, 56]) assert feat[1].shape == torch.Size([1, 512, 28, 28]) assert feat[2].shape == torch.Size([1, 1024, 14, 14]) assert feat[3].shape == torch.Size([1, 2048, 7, 7]) # Test SEResNet50 zero initialization of residual model = SEResNet(50, out_indices=(0, 1, 2, 3), zero_init_residual=True) model.init_weights() for m in model.modules(): if isinstance(m, SEBottleneck): assert all_zeros(m.norm3) model.train() imgs = torch.randn(1, 3, 224, 224) feat = model(imgs) assert len(feat) == 4 assert feat[0].shape == torch.Size([1, 256, 56, 56]) assert feat[1].shape == torch.Size([1, 512, 28, 28]) assert feat[2].shape == torch.Size([1, 1024, 14, 14]) assert feat[3].shape == torch.Size([1, 2048, 7, 7])