# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved. # # 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. import paddle.nn.functional as F from paddle import nn from paddleseg.cvlibs import manager from paddleseg.models.common import pyramid_pool from paddleseg.models.common.layer_libs import ConvBNReLU, SeparableConvBNReLU, AuxLayer from paddleseg.utils import utils @manager.MODELS.add_component class FastSCNN(nn.Layer): """ The FastSCNN implementation based on PaddlePaddle. As mentioned in the original paper, FastSCNN is a real-time segmentation algorithm (123.5fps) even for high resolution images (1024x2048). The original article refers to Poudel, Rudra PK, et al. "Fast-scnn: Fast semantic segmentation network." (https://arxiv.org/pdf/1902.04502.pdf) Args: num_classes (int): the unique number of target classes. Default to 2. enable_auxiliary_loss (bool): a bool values indicates whether adding auxiliary loss. if true, auxiliary loss will be added after LearningToDownsample module, where the weight is 0.4. Default to False. pretrained (str): the path of pretrained model. Default to None. """ def __init__(self, num_classes, enable_auxiliary_loss=True, pretrained=None): super(FastSCNN, self).__init__() self.learning_to_downsample = LearningToDownsample(32, 48, 64) self.global_feature_extractor = GlobalFeatureExtractor( 64, [64, 96, 128], 128, 6, [3, 3, 3]) self.feature_fusion = FeatureFusionModule(64, 128, 128) self.classifier = Classifier(128, num_classes) if enable_auxiliary_loss: self.auxlayer = AuxLayer(64, 32, num_classes) self.enable_auxiliary_loss = enable_auxiliary_loss self.init_weight() utils.load_entire_model(self, pretrained) def forward(self, input, label=None): logit_list = [] higher_res_features = self.learning_to_downsample(input) x = self.global_feature_extractor(higher_res_features) x = self.feature_fusion(higher_res_features, x) logit = self.classifier(x) logit = F.resize_bilinear(logit, input.shape[2:]) logit_list.append(logit) if self.enable_auxiliary_loss: auxiliary_logit = self.auxlayer(higher_res_features) auxiliary_logit = F.resize_bilinear(auxiliary_logit, input.shape[2:]) logit_list.append(auxiliary_logit) return logit_list def init_weight(self): """ Initialize the parameters of model parts. """ pass class LearningToDownsample(nn.Layer): """ Learning to downsample module. This module consists of three downsampling blocks (one Conv and two separable Conv) Args: dw_channels1 (int): the input channels of the first sep conv. Default to 32. dw_channels2 (int): the input channels of the second sep conv. Default to 48. out_channels (int): the output channels of LearningToDownsample module. Default to 64. """ def __init__(self, dw_channels1=32, dw_channels2=48, out_channels=64): super(LearningToDownsample, self).__init__() self.conv_bn_relu = ConvBNReLU( in_channels=3, out_channels=dw_channels1, kernel_size=3, stride=2) self.dsconv_bn_relu1 = SeparableConvBNReLU( in_channels=dw_channels1, out_channels=dw_channels2, kernel_size=3, stride=2, padding=1) self.dsconv_bn_relu2 = SeparableConvBNReLU( in_channels=dw_channels2, out_channels=out_channels, kernel_size=3, stride=2, padding=1) def forward(self, x): x = self.conv_bn_relu(x) x = self.dsconv_bn_relu1(x) x = self.dsconv_bn_relu2(x) return x class GlobalFeatureExtractor(nn.Layer): """ Global feature extractor module This module consists of three LinearBottleneck blocks (like inverted residual introduced by MobileNetV2) and a PPModule (introduced by PSPNet). Args: in_channels (int): the number of input channels to the module. Default to 64. block_channels (tuple): a tuple represents output channels of each bottleneck block. Default to (64, 96, 128). out_channels (int): the number of output channels of the module. Default to 128. expansion (int): the expansion factor in bottleneck. Default to 6. num_blocks (tuple): it indicates the repeat time of each bottleneck. Default to (3, 3, 3). """ def __init__(self, in_channels=64, block_channels=(64, 96, 128), out_channels=128, expansion=6, num_blocks=(3, 3, 3)): super(GlobalFeatureExtractor, self).__init__() self.bottleneck1 = self._make_layer(LinearBottleneck, in_channels, block_channels[0], num_blocks[0], expansion, 2) self.bottleneck2 = self._make_layer(LinearBottleneck, block_channels[0], block_channels[1], num_blocks[1], expansion, 2) self.bottleneck3 = self._make_layer(LinearBottleneck, block_channels[1], block_channels[2], num_blocks[2], expansion, 1) self.ppm = pyramid_pool.PPModule( block_channels[2], out_channels, dim_reduction=True) def _make_layer(self, block, in_channels, out_channels, blocks, expansion=6, stride=1): layers = [] layers.append(block(in_channels, out_channels, expansion, stride)) for i in range(1, blocks): layers.append(block(out_channels, out_channels, expansion, 1)) return nn.Sequential(*layers) def forward(self, x): x = self.bottleneck1(x) x = self.bottleneck2(x) x = self.bottleneck3(x) x = self.ppm(x) return x class LinearBottleneck(nn.Layer): """ Single bottleneck implementation. Args: in_channels (int): the number of input channels to bottleneck block. out_channels (int): the number of output channels of bottleneck block. expansion (int). the expansion factor in bottleneck. Default to 6. stride (int). the stride used in depth-wise conv. """ def __init__(self, in_channels, out_channels, expansion=6, stride=2, **kwargs): super(LinearBottleneck, self).__init__() self.use_shortcut = stride == 1 and in_channels == out_channels expand_channels = in_channels * expansion self.block = nn.Sequential( # pw ConvBNReLU( in_channels=in_channels, out_channels=expand_channels, kernel_size=1, bias_attr=False), # dw ConvBNReLU( in_channels=expand_channels, out_channels=expand_channels, kernel_size=3, stride=stride, padding=1, groups=expand_channels, bias_attr=False), # pw-linear nn.Conv2d( in_channels=expand_channels, out_channels=out_channels, kernel_size=1, bias_attr=False), nn.SyncBatchNorm(out_channels)) def forward(self, x): out = self.block(x) if self.use_shortcut: out = x + out return out class FeatureFusionModule(nn.Layer): """ Feature Fusion Module Implementation. This module fuses high-resolution feature and low-resolution feature. Args: high_in_channels (int): the channels of high-resolution feature (output of LearningToDownsample). low_in_channels (int). the channels of low-resolution feature (output of GlobalFeatureExtractor). out_channels (int). the output channels of this module. """ def __init__(self, high_in_channels, low_in_channels, out_channels): super(FeatureFusionModule, self).__init__() # There only depth-wise conv is used WITHOUT point-wise conv self.dwconv = ConvBNReLU( in_channels=low_in_channels, out_channels=out_channels, kernel_size=3, padding=1, groups=128, bias_attr=False) self.conv_low_res = nn.Sequential( nn.Conv2d( in_channels=out_channels, out_channels=out_channels, kernel_size=1), nn.SyncBatchNorm(out_channels)) self.conv_high_res = nn.Sequential( nn.Conv2d( in_channels=high_in_channels, out_channels=out_channels, kernel_size=1), nn.SyncBatchNorm(out_channels)) self.relu = nn.ReLU(True) def forward(self, high_res_input, low_res_input): low_res_input = F.resize_bilinear(input=low_res_input, scale=4) low_res_input = self.dwconv(low_res_input) low_res_input = self.conv_low_res(low_res_input) high_res_input = self.conv_high_res(high_res_input) x = high_res_input + low_res_input return self.relu(x) class Classifier(nn.Layer): """ The Classifier module implementation. This module consists of two depth-wise conv and one conv. Args: input_channels (int): the input channels to this module. num_classes (int). the unique number of target classes. """ def __init__(self, input_channels, num_classes): super(Classifier, self).__init__() self.dsconv1 = SeparableConvBNReLU( in_channels=input_channels, out_channels=input_channels, kernel_size=3, padding=1) self.dsconv2 = SeparableConvBNReLU( in_channels=input_channels, out_channels=input_channels, kernel_size=3, padding=1) self.conv = nn.Conv2d( in_channels=input_channels, out_channels=num_classes, kernel_size=1) def forward(self, x): x = self.dsconv1(x) x = self.dsconv2(x) x = F.dropout(x, p=0.1) # dropout_prob x = self.conv(x) return x