从头学pytorch(二十一):全连接网络dense net

调度算法

DenseNet

论文传送门,这篇论文是CVPR 2017的最佳论文.

resnet一文里说了,resnet是具有里程碑意义的.densenet就是受resnet的启发提出的模型.

resnet中是把不同层的feature map相应元素的值直接相加.而densenet是将channel维上的feature map直接concat在一起,从而实现了feature的复用.如下所示:
从头学pytorch(二十一):全连接网络dense net
从头学pytorch(二十一):全连接网络dense net
注意,是连接dense block内输出层前面所有层的输出,不是只有输出层的前一层

网络结构

从头学pytorch(二十一):全连接网络dense net
从头学pytorch(二十一):全连接网络dense net

首先实现DenseBlock
从头学pytorch(二十一):全连接网络dense net
先解释几个名词

  • bottleneck layer  
    即上图中红圈的1×1卷积核.主要目的是对输入在channel维度做降维.减少运算量.
    从头学pytorch(二十一):全连接网络dense net
    卷积核的数量为4k,k为该layer输出的feature map的数量(也就是3×3卷积核的数量)

  • growth rate
    即上图中黑圈处3×3卷积核的数量.假设3×3卷积核的数量为k,则每个这种3×3卷积后,都得到一个channel=k的输出.假如一个denseblock有m组这种结构,输入的channel为n的话,则做完一次连接操作后得到的输出的channel为n + k + k +…+k = n+m*k.所以又叫做growth rate.

  • conv  
    论文里的conv指的是BN-ReLU-Conv

实现DenseBlock

DenseLayer

class DenseLayer(nn.Module):
    def __init__(self,in_channels,bottleneck_size,growth_rate):
        super(DenseLayer,self).__init__()
        count_of_1x1 = bottleneck_size
        self.bn1 = nn.BatchNorm2d(in_channels)
        self.relu1 = nn.ReLU(inplace=True)
        self.conv1x1 = nn.Conv2d(in_channels,count_of_1x1,kernel_size=1)

        self.bn2 = nn.BatchNorm2d(count_of_1x1)
        self.relu2 = nn.ReLU(inplace=True)
        self.conv3x3 = nn.Conv2d(count_of_1x1,growth_rate,kernel_size=3,padding=1)
        
    def forward(self,*prev_features):
        # for f in prev_features:
        #     print(f.shape)

        input = torch.cat(prev_features,dim=1)
        # print(input.device,input.shape)
        # for param in self.bn1.parameters():
        #     print(param.device)
        # print(list())
        bottleneck_output = self.conv1x1(self.relu1(self.bn1(input)))
        out = self.conv3x3(self.relu2(self.bn2(bottleneck_output)))
        
        return out

首先是1×1卷积,然后是3×3卷积.3×3卷积核的数量即growth_rate,bottleneck_size即1×1卷积核数量.论文里是bottleneck_size=4xgrowth_rate的关系. 注意forward函数的实现

简单看看读写锁ReentantReadWriteLock

    def forward(self,*prev_features):
        # for f in prev_features:
        #     print(f.shape)

        input = torch.cat(prev_features,dim=1)
        # print(input.device,input.shape)
        # for param in self.bn1.parameters():
        #     print(param.device)
        # print(list())
        bottleneck_output = self.conv1x1(self.relu1(self.bn1(input)))
        out = self.conv3x3(self.relu2(self.bn2(bottleneck_output)))
        
        return out

我们传进来的是一个元祖,其含义是[block的输入,layer1输出,layer2输出,...].前面说过了,一个dense block内的每一个layer的输入是前面所有layer的输出和该block的输入在channel维度上的连接.这样就使得不同layer的feature map得到了充分的利用.

tips:
函数参数带*表示可以传入任意多的参数,这些参数被组织成元祖的形式,比如

## var-positional parameter
## 定义的时候,我们需要添加单个星号作为前缀
def func(arg1, arg2, *args):
    print arg1, arg2, args
 
## 调用的时候,前面两个必须在前面
## 前两个参数是位置或关键字参数的形式
## 所以你可以使用这种参数的任一合法的传递方法
func("hello", "Tuple, values is:", 2, 3, 3, 4)
 
## Output:
## hello Tuple, values is: (2, 3, 3, 4)
## 多余的参数将自动被放入元组中提供给函数使用
 
## 如果你需要传递元组给函数
## 你需要在传递的过程中添加*号
## 请看下面例子中的输出差异:
 
func("hello", "Tuple, values is:", (2, 3, 3, 4))
 
## Output:
## hello Tuple, values is: ((2, 3, 3, 4),)
 
func("hello", "Tuple, values is:", *(2, 3, 3, 4))
 
## Output:
## hello Tuple, values is: (2, 3, 3, 4)

DenseBlock

class DenseBlock(nn.Module):
    def __init__(self,in_channels,layer_counts,growth_rate):
        super(DenseBlock,self).__init__()
        self.layer_counts = layer_counts
        self.layers = []
        for i in range(layer_counts):
            curr_input_channel = in_channels + i*growth_rate
            bottleneck_size = 4*growth_rate #论文里设置的1x1卷积核是3x3卷积核的4倍.
            layer = DenseLayer(curr_input_channel,bottleneck_size,growth_rate).cuda()       
            self.layers.append(layer)

    def forward(self,init_features):
        features = [init_features]
        for layer in self.layers:
            layer_out = layer(*features) #注意参数是*features不是features
            features.append(layer_out)

        return torch.cat(features, 1)

一个Dense Block由多个Layer组成.这里注意forward的实现,init_features即该block的输入,然后每个layer都会得到一个输出.第n个layer的输入由输入和前n-1个layer的输出在channel维度上连接组成.

最后,该block的输出为各个layer的输出为输入以及各个layer的输出在channel维度上连接而成.

TransitionLayer

很显然,dense block的计算方式会使得channel维度过大,所以每一个dense block之后要通过1×1卷积在channel维度降维.

class TransitionLayer(nn.Sequential):
    def __init__(self, in_channels, out_channels):
        super(TransitionLayer, self).__init__()
        self.add_module('norm', nn.BatchNorm2d(in_channels))
        self.add_module('relu', nn.ReLU(inplace=True))
        self.add_module('conv', nn.Conv2d(in_channels, out_channels,kernel_size=1, stride=1, bias=False))
        self.add_module('pool', nn.AvgPool2d(kernel_size=2, stride=2))

Dense Net

dense net的基本组件我们已经实现了.下面就可以实现dense net了.

class DenseNet(nn.Module):
    def __init__(self,in_channels,num_classes,block_config):
        super(DenseNet,self).__init__()
        self.conv1 = nn.Sequential(
            nn.Conv2d(in_channels,64,kernel_size=7,stride=2,padding=3),
            nn.BatchNorm2d(64),
            nn.ReLU(inplace=True)
        )
        self.pool1 = nn.MaxPool2d(kernel_size=3,stride=2,padding=1)
        
        self.dense_block_layers = nn.Sequential()

        block_in_channels = in_channels
        growth_rate = 32
        for i,layers_counts in enumerate(block_config):
            block = DenseBlock(in_channels=block_in_channels,layer_counts=layers_counts,growth_rate=growth_rate)
            self.dense_block_layers.add_module('block%d' % (i+1),block)

            block_out_channels = block_in_channels + layers_counts*growth_rate
            transition = TransitionLayer(block_out_channels,block_out_channels//2)
            if i != len(block_config): #最后一个dense block后没有transition layer
                self.dense_block_layers.add_module('transition%d' % (i+1),transition)

            block_in_channels = block_out_channels // 2 #更新下一个dense block的in_channels
        
        self.avg_pool = nn.AdaptiveAvgPool2d(output_size=(1,1))

        self.fc = nn.Linear(block_in_channels,num_classes)


    def forward(self,x):
        out = self.conv1(x)
        out = self.pool1(x)
        for layer in self.dense_block_layers:
            out = layer(out) 
            # print(out.shape)
        out = self.avg_pool(out)
        out = torch.flatten(out,start_dim=1) #相当于out = out.view((x.shape[0],-1))
        out = self.fc(out)

        return out

首先和resnet一样,首先是7×7卷积接3×3,stride=2的最大池化,然后就是不断地dense block + tansition.得到feature map以后用全局平均池化得到n个feature.然后给全连接层做分类使用.

可以用

X=torch.randn(1,3,224,224).cuda()
block_config = [6,12,24,16]
net = DenseNet(3,10,block_config)
net = net.cuda()
out = net(X)
print(out.shape)

测试一下,输出如下,可以看出feature map的变化情况.最终得到508x7x7的feature map.全局平均池化后,得到508个特征,通过线性回归得到10个类别.

torch.Size([1, 195, 112, 112])
torch.Size([1, 97, 56, 56])
torch.Size([1, 481, 56, 56])
torch.Size([1, 240, 28, 28])
torch.Size([1, 1008, 28, 28])
torch.Size([1, 504, 14, 14])
torch.Size([1, 1016, 14, 14])
torch.Size([1, 508, 7, 7])
torch.Size([1, 10])

总结:
核心就是dense block内每一个layer都复用了之前的layer得到的feature map,因为底层细节的feature被复用,所以使得模型的特征提取能力更强. 当然坏处就是计算量大,显存消耗大.

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