深度学习---之blob,layer,net

本文地址：http://blog.csdn.net/mounty_fsc/article/details/51085654

Caffe中，Blob。Layer，Net，Solver是最为核心的类，下面介绍这几个类，Solver将在下一节介绍。

1 Blob

1.1 简单介绍

Blob是：

对待处理数据带一层封装，用于在Caffe中通信传递。也为CPU和GPU间提供同步能力数学上，是一个N维的C风格的存储数组 总的来说。Caffe使用Blob来交流数据，其是Caffe中标准的数组与统一的内存接口，它是多功能的。在不同的应用场景具有不同的含义，如能够是：batches of images, model parameters, and derivatives for optimization等。

1.2 源码

/** * @brief A wrapper around SyncedMemory holders serving as the basic * computational unit through which Layer%s, Net%s, and Solver%s * interact. * * TODO(dox): more thorough description. */ template <typename Dtype> class Blob { public: Blob() : data_(), diff_(), count_(0), capacity_(0) {} /// @brief Deprecated; use <code>Blob(const vector<int>& shape)</code>. explicit Blob(const int num, const int channels, const int height, const int width); explicit Blob(const vector<int>& shape); ..... protected: shared_ptr<SyncedMemory> data_; shared_ptr<SyncedMemory> diff_; shared_ptr<SyncedMemory> shape_data_; vector<int> shape_; int count_; int capacity_; DISABLE_COPY_AND_ASSIGN(Blob); }; // class Blob

注：此处仅仅保留了构造函数与成员变量。

说明：

Blob在实现上是对SyncedMemory（见1.5部分）进行了一层封装。shape_为blob维度，见1.3部分data_为原始数据diff_为梯度信息count_为该blob的总容量（即数据的size）。函数count(x,y)（或count(x)）返回某个切片[x,y]（[x,end]）内容量，本质上就是shape[x]shape[x+1]….*shape[y]的值

1.3 Blob的shape

由源码中能够注意到Blob有个成员变量：vector shape_ 其作用：

对于图像数据，shape能够定义为4维的数组(Num, Channels, Height, Width)或(n, k, h, w)。所以Blob数据维度为n*k*h*w。Blob是row-major保存的，因此在(n, k, h, w)位置的值物理位置为((n * K + k) * H + h) * W + w。当中Number是数据的batch size，对于256张图片为一个training batch的ImageNet来说n = 256;Channel是特征维度，如RGB图像k = 3对于全连接网络，使用2D blobs (shape (N, D))。然后调用InnerProductLayer对于參数，维度依据该层的类型和配置来确定。对于有3个输入96个输出的卷积层，Filter核 11 x 11，则blob为96 x 3 x 11 x 11. 对于全连接层，1000个输出。1024个输入。则blob为1000 x 1024.

1.4 Blob的行优先的存储方式

以Blob中二维矩阵为例（如全连接网络shape (N, D)）。如图所看到的。同样的存储方式能够推广到多维。

1.5 SyncedMemory

由1.2知。Blob本质是对SyncedMemory的再封装。

其核心代码例如以下：

/** * @brief Manages memory allocation and synchronization between the host (CPU) * and device (GPU). * * TODO(dox): more thorough description. */ class SyncedMemory { public: ... const void* cpu_data(); const void* gpu_data(); void* mutable_cpu_data(); void* mutable_gpu_data(); ... private: ... void* cpu_ptr_; void* gpu_ptr_; ... }; // class SyncedMemory

Blob同一时候保存了data_和diff_,其类型为SyncedMemory的指针。 对于data_(diff_同样),事实上际值要么存储在CPU(cpu_ptr_)要么存储在GPU(gpu_ptr_),有两种方式訪问CPU数据(GPU同样)：

常量方式,void* cpu_data()，其不改变cpu_ptr_指向存储区域的值。

可变方式，void* mutable_cpu_data()，其可改变cpu_ptr_指向存储区值。 以mutable_cpu_data()为例

void* SyncedMemory::mutable_cpu_data() { to_cpu(); head_ = HEAD_AT_CPU; return cpu_ptr_; } inline void SyncedMemory::to_cpu() { switch (head_) { case UNINITIALIZED: CaffeMallocHost(&cpu_ptr_, size_, &cpu_malloc_use_cuda_); caffe_memset(size_, 0, cpu_ptr_); head_ = HEAD_AT_CPU; own_cpu_data_ = true; break; case HEAD_AT_GPU: #ifndef CPU_ONLY if (cpu_ptr_ == NULL) { CaffeMallocHost(&cpu_ptr_, size_, &cpu_malloc_use_cuda_); own_cpu_data_ = true; } caffe_gpu_memcpy(size_, gpu_ptr_, cpu_ptr_); head_ = SYNCED; #else NO_GPU; #endif break; case HEAD_AT_CPU: case SYNCED: break; } }

说明：

经验上来说，假设不须要改变其值，则使用常量调用的方式，而且，不要在你对象中保存其指针。为何要这样设计呢。由于这样涉及能够隐藏CPU到GPU的同步细节，以及降低数据传递从而提高效率。当你调用它们的时候。SyncedMem会决定何时去复制数据，通常情况是仅当gnu或cpu改动后有复制操作，引用1官方文档中有一个样例说明何时进行复制操作。调用mutable_cpu_data()能够让head转移到cpu上第一次调用mutable_cpu_data()是UNINITIALIZED将运行9到14行。将为cpu_ptr_分配host内存若head从gpu转移到cpu。将把数据从gpu拷贝到cpu中

2 Layer

2.1 简单介绍

Layer是Caffe的基础以及基本计算单元。Caffe十分强调网络的层次性，能够说。一个网络的大部分功能都是以Layer的形式去展开的，如convolute,pooling,loss等等。 在创建一个Caffe模型的时候，也是以Layer为基础进行的，需依照src/caffe/proto/caffe.proto中定义的网络及參数格式定义网络 prototxt文件（需了解google protocol buffer）

2.2 Layer与Blob的关系

如图，名为conv1的Layer 的输入是名为data的bottom blob，其输出是名为conv1的top blob。

其protobuff定义例如以下，一个layer有一个到多个的top和bottom，其相应于blob

layer { name: "conv1" type: "Convolution" bottom: "data" top: "conv1" .... }

2.3 源码

/** * Layer%s must implement a Forward function, in which they take their input * (bottom) Blob%s (if any) and compute their output Blob%s (if any). * They may also implement a Backward function, in which they compute the error * gradients with respect to their input Blob%s, given the error gradients with * their output Blob%s. */ template <typename Dtype> class Layer { public: /** * You should not implement your own constructor. Any set up code should go * to SetUp(), where the dimensions of the bottom blobs are provided to the * layer. */ explicit Layer(const LayerParameter& param) : layer_param_(param), is_shared_(false) { ... } virtual ~Layer() {} /** * @brief Implements common layer setup functionality. * @param bottom the preshaped input blobs * @param top * the allocated but unshaped output blobs, to be shaped by Reshape */ void SetUp(const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) { ... } ... /** * @brief Given the bottom blobs, compute the top blobs and the loss. * \return The total loss from the layer. * * The Forward wrapper calls the relevant device wrapper function * (Forward_cpu or Forward_gpu) to compute the top blob values given the * bottom blobs. If the layer has any non-zero loss_weights, the wrapper * then computes and returns the loss. * * Your layer should implement Forward_cpu and (optionally) Forward_gpu. */ inline Dtype Forward(const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top); /** * @brief Given the top blob error gradients, compute the bottom blob error * gradients. * * @param top * the output blobs, whose diff fields store the gradient of the error * with respect to themselves * @param propagate_down * a vector with equal length to bottom, with each index indicating * whether to propagate the error gradients down to the bottom blob at * the corresponding index * @param bottom * the input blobs, whose diff fields will store the gradient of the error * with respect to themselves after Backward is run * * The Backward wrapper calls the relevant device wrapper function * (Backward_cpu or Backward_gpu) to compute the bottom blob diffs given the * top blob diffs. * * Your layer should implement Backward_cpu and (optionally) Backward_gpu. */ inline void Backward(const vector<Blob<Dtype>*>& top, const vector<bool>& propagate_down, const vector<Blob<Dtype>*>& bottom); ... protected: /** The protobuf that stores the layer parameters */ LayerParameter layer_param_; /** The phase: TRAIN or TEST */ Phase phase_; /** The vector that stores the learnable parameters as a set of blobs. */ vector<shared_ptr<Blob<Dtype> > > blobs_; /** Vector indicating whether to compute the diff of each param blob. */ vector<bool> param_propagate_down_; /** The vector that indicates whether each top blob has a non-zero weight in * the objective function. */ vector<Dtype> loss_; virtual void Forward_cpu(const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) = 0; virtual void Forward_gpu(const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) { // LOG(WARNING) << "Using CPU code as backup."; return Forward_cpu(bottom, top); } virtual void Backward_cpu(const vector<Blob<Dtype>*>& top, const vector<bool>& propagate_down, const vector<Blob<Dtype>*>& bottom) = 0; virtual void Backward_gpu(const vector<Blob<Dtype>*>& top, const vector<bool>& propagate_down, const vector<Blob<Dtype>*>& bottom) { // LOG(WARNING) << "Using CPU code as backup."; Backward_cpu(top, propagate_down, bottom); } ... }; // class Layer

说明：每一层定义了三种操作

Setup：Layer的初始化Forward：前向传导计算。依据bottom计算top，调用了Forward_cpu（必须实现）和Forward_gpu（可选，若未实现，则调用cpu的）Backward：反向传导计算。依据top计算bottom的梯度。其它同上

2.4 派生类分类

在Layer的派生类中，主要能够分为Vision Layers

Vision Layers Vison 层主要用于处理视觉图像相关的层。以图像作为输入，产生其它的图像。其主要特点是具有空间结构。 包括Convolution(conv_layer.hpp)、Pooling(pooling_layer.hpp)、Local Response Normalization(LRN)(lrn_layer.hpp)、im2col等。注：老版本号的Caffe有头文件include/caffe/vision_layers.hpp，新版本号中用include/caffe/layer/conv_layer.hpp等代替Loss Layers 这些层产生loss，如Softmax(SoftmaxWithLoss)、Sum-of-Squares / Euclidean(EuclideanLoss)、Hinge / Margin(HingeLoss)、Sigmoid Cross-Entropy(SigmoidCrossEntropyLoss)、Infogain(InfogainLoss)、Accuracy and Top-k等Activation / Neuron Layers 元素级别的运算，运算均为同址计算（in-place computation。返回值覆盖原值而占用新的内存）。如：ReLU / Rectified-Linear and Leaky-ReLU(ReLU)、Sigmoid(Sigmoid)、TanH / Hyperbolic Tangent(TanH)、Absolute Value(AbsVal)、Power(Power)、BNLL(BNLL)等Data Layers 网络的最底层，主要实现数据格式的转换，如：Database(Data)、In-Memory(MemoryData)、HDF5 Input(HDF5Data)、HDF5 Output(HDF5Output)、Images(ImageData)、Windows(WindowData)、Dummy(DummyData)等Common Layers Caffe提供了单个层与多个层的连接。

如：Inner Product(InnerProduct)、Splitting(Split)、Flattening(Flatten)、Reshape(Reshape)、Concatenation(Concat)、Slicing(Slice)、Elementwise(Eltwise)、Argmax(ArgMax)、Softmax(Softmax)、Mean-Variance Normalization(MVN)等

注，括号内为Layer Type,没有括号暂缺信息。具体咱见引用2

3 Net

3.1 简单介绍

一个Net由多个Layer组成。

一个典型的网络从data layer（从磁盘中加载数据）出发到loss layer结束。如图是一个简单的逻辑回归分类器。

例如以下定义：

name: "LogReg" layer { name: "mnist" type: "Data" top: "data" top: "label" data_param { source: "input_leveldb" batch_size: 64 } } layer { name: "ip" type: "InnerProduct" bottom: "data" top: "ip" inner_product_param { num_output: 2 } } layer { name: "loss" type: "SoftmaxWithLoss" bottom: "ip" bottom: "label" top: "loss" }

3.2 源码

/** * @brief Connects Layer%s together into a directed acyclic graph (DAG) * specified by a NetParameter. * * TODO(dox): more thorough description. */ template <typename Dtype> class Net { public: ... /// @brief Initialize a network with a NetParameter. void Init(const NetParameter& param); ... const vector<Blob<Dtype>*>& Forward(const vector<Blob<Dtype>* > & bottom, Dtype* loss = NULL); ... /** * The network backward should take no input and output, since it solely * computes the gradient w.r.t the parameters, and the data has already been * provided during the forward pass. */ void Backward(); ... Dtype ForwardBackward(const vector<Blob<Dtype>* > & bottom) { Dtype loss; Forward(bottom, &loss); Backward(); return loss; } ... protected: ... /// @brief The network name string name_; /// @brief The phase: TRAIN or TEST Phase phase_; /// @brief Individual layers in the net vector<shared_ptr<Layer<Dtype> > > layers_; /// @brief the blobs storing intermediate results between the layer. vector<shared_ptr<Blob<Dtype> > > blobs_; vector<vector<Blob<Dtype>*> > bottom_vecs_; vector<vector<Blob<Dtype>*> > top_vecs_; ... /// The root net that actually holds the shared layers in data parallelism const Net* const root_net_; }; } // namespace caffe

说明：

Init中，通过创建blob和layer搭建了整个网络框架，以及调用各层的SetUp函数。blobs_存放这每一层产生的blobls的中间结果。bottom_vecs_存放每一层的bottom blobs，top_vecs_存放每一层的top blobs