예제 #1
0
 def BNReLU(num_features, norm_type=None, **kwargs):
     if norm_type == 'batchnorm':
         return nn.Sequential(nn.BatchNorm2d(num_features, **kwargs),
                              nn.ReLU())
     elif norm_type == 'encsync_batchnorm':
         from encoding.nn import SyncBatchNorm
         return nn.Sequential(SyncBatchNorm(num_features, **kwargs),
                              nn.ReLU())
     elif norm_type == 'instancenorm':
         return nn.Sequential(nn.InstanceNorm2d(num_features, **kwargs),
                              nn.ReLU())
     else:
         Log.error('Not support BN type: {}.'.format(norm_type))
         exit(1)
예제 #2
0
    def __init__(self, block_args, global_params):
        super().__init__()
        self._block_args = block_args
        self._bn_mom = 1 - global_params.batch_norm_momentum
        self._bn_eps = global_params.batch_norm_epsilon
        self.has_se = (self._block_args.se_ratio
                       is not None) and (0 < self._block_args.se_ratio <= 1)
        self.id_skip = block_args.id_skip  # skip connection and drop connect

        # Get static or dynamic convolution depending on image size
        Conv2d = get_same_padding_conv2d(image_size=global_params.image_size)

        # Expansion phase
        inp = self._block_args.input_filters  # number of input channels
        oup = self._block_args.input_filters * self._block_args.expand_ratio  # number of output channels
        if self._block_args.expand_ratio != 1:
            self._expand_conv = Conv2d(in_channels=inp,
                                       out_channels=oup,
                                       kernel_size=1,
                                       bias=False)
            #             self._bn0 = nn.BatchNorm2d(num_features=oup, momentum=self._bn_mom, eps=self._bn_eps)
            self._bn0 = SyncBatchNorm(num_features=oup,
                                      momentum=self._bn_mom,
                                      eps=self._bn_eps)

        # Depthwise convolution phase
        k = self._block_args.kernel_size
        s = self._block_args.stride
        self._depthwise_conv = Conv2d(
            in_channels=oup,
            out_channels=oup,
            groups=oup,  # groups makes it depthwise
            kernel_size=k,
            stride=s,
            bias=False)
        #         self._bn1 = nn.BatchNorm2d(num_features=oup, momentum=self._bn_mom, eps=self._bn_eps)
        self._bn1 = SyncBatchNorm(num_features=oup,
                                  momentum=self._bn_mom,
                                  eps=self._bn_eps)

        # Squeeze and Excitation layer, if desired
        if self.has_se:
            num_squeezed_channels = max(
                1,
                int(self._block_args.input_filters *
                    self._block_args.se_ratio))
            self._se_reduce = Conv2d(in_channels=oup,
                                     out_channels=num_squeezed_channels,
                                     kernel_size=1)
            self._se_expand = Conv2d(in_channels=num_squeezed_channels,
                                     out_channels=oup,
                                     kernel_size=1)

        # Output phase
        final_oup = self._block_args.output_filters
        self._project_conv = Conv2d(in_channels=oup,
                                    out_channels=final_oup,
                                    kernel_size=1,
                                    bias=False)
        #         self._bn2 = nn.BatchNorm2d(num_features=final_oup, momentum=self._bn_mom, eps=self._bn_eps)
        self._bn2 = SyncBatchNorm(num_features=final_oup,
                                  momentum=self._bn_mom,
                                  eps=self._bn_eps)
예제 #3
0
    def __init__(self, blocks_args=None, global_params=None):
        super().__init__()
        assert isinstance(blocks_args, list), 'blocks_args should be a list'
        assert len(blocks_args) > 0, 'block args must be greater than 0'
        self._global_params = global_params
        self._blocks_args = blocks_args

        # Get static or dynamic convolution depending on image size
        Conv2d = get_same_padding_conv2d(image_size=global_params.image_size)

        # Batch norm parameters
        bn_mom = 1 - self._global_params.batch_norm_momentum
        bn_eps = self._global_params.batch_norm_epsilon

        # Stem
        in_channels = 3  # rgb
        out_channels = round_filters(
            32, self._global_params)  # number of output channels
        self._conv_stem = Conv2d(in_channels,
                                 out_channels,
                                 kernel_size=3,
                                 stride=2,
                                 bias=False)
        #         self._bn0 = nn.BatchNorm2d(num_features=out_channels, momentum=bn_mom, eps=bn_eps)
        self._bn0 = SyncBatchNorm(num_features=out_channels,
                                  momentum=bn_mom,
                                  eps=bn_eps)

        # Build blocks
        self._blocks = nn.ModuleList([])
        for block_args in self._blocks_args:

            # Update block input and output filters based on depth multiplier.
            block_args = block_args._replace(
                input_filters=round_filters(block_args.input_filters,
                                            self._global_params),
                output_filters=round_filters(block_args.output_filters,
                                             self._global_params),
                num_repeat=round_repeats(block_args.num_repeat,
                                         self._global_params))

            # The first block needs to take care of stride and filter size increase.
            self._blocks.append(MBConvBlock(block_args, self._global_params))
            if block_args.num_repeat > 1:
                block_args = block_args._replace(
                    input_filters=block_args.output_filters, stride=1)
            for _ in range(block_args.num_repeat - 1):
                self._blocks.append(
                    MBConvBlock(block_args, self._global_params))

        # Head
        in_channels = block_args.output_filters  # output of final block
        out_channels = round_filters(1280, self._global_params)
        self._conv_head = Conv2d(in_channels,
                                 out_channels,
                                 kernel_size=1,
                                 bias=False)
        #         self._bn1 = nn.BatchNorm2d(num_features=out_channels, momentum=bn_mom, eps=bn_eps)
        self._bn1 = SyncBatchNorm(num_features=out_channels,
                                  momentum=bn_mom,
                                  eps=bn_eps)

        # Final linear layer
        self._dropout = self._global_params.dropout_rate
        self._fc = nn.Linear(out_channels, self._global_params.num_classes)