void getBlobsToVisualize(caffe::Net<float> & net, std::vector<std::string> & blobsToVisualize) { // find input blob const int nInputBlobs = net.input_blob_indices().size(); if (nInputBlobs == 0) { std::cerr << "there are no input blobs - where to start?" << std::endl; return; } blobsToVisualize.push_back(net.blob_names()[net.input_blob_indices()[0]]); std::set<std::string> layersWhoOutputVisualizableBlobs; layersWhoOutputVisualizableBlobs.insert("Convolution"); std::map<std::string,std::vector<int> > outputBlobsToVisualizeByLayerType; outputBlobsToVisualizeByLayerType["Convolution"] = std::vector<int>(1,0); outputBlobsToVisualizeByLayerType["InnerProduct"] = std::vector<int>(1,0); outputBlobsToVisualizeByLayerType["Pooling"] = std::vector<int>(1,0); const int nLayers = net.layers().size(); for (int i=0; i<nLayers; ++i) { boost::shared_ptr<caffe::Layer<float> > layer = net.layers()[i]; std::string layerType(layer->type()); if (outputBlobsToVisualizeByLayerType.find(layerType) != outputBlobsToVisualizeByLayerType.end()) { caffe::Blob<float> * outputBlob = net.top_vecs()[i][0]; int blobNum = getBlobNumber(net,outputBlob); assert(blobNum >= 0); blobsToVisualize.push_back(net.blob_names()[blobNum]); } } }
int getLayerNum() { return net->layers().size(); }
void getBlobStridesAndReceptiveFields(caffe::Net<float> & net, const std::vector<std::string> & blobsToVisualize, std::map<std::string,int> & strides, std::map<std::string,int2> & receptiveFields) { const int nInputBlobs = net.input_blob_indices().size(); if (nInputBlobs == 0) { std::cerr << "there are no input blobs - where to start?" << std::endl; return; } std::string inputBlobName(net.blob_names()[net.input_blob_indices()[0]]); strides[inputBlobName] = 1; receptiveFields[inputBlobName] = make_int2(1,1); boost::shared_ptr<caffe::Blob<float> > inputBlob = net.blob_by_name(inputBlobName); int2 inputSize = make_int2(inputBlob->width(),inputBlob->height()); const int nLayers = net.layers().size(); for (int i=0; i<nLayers; ++i) { boost::shared_ptr<caffe::Layer<float> > layer = net.layers()[i]; std::string layerType(layer->type()); bool isConv = layerType == std::string("Convolution"); bool isPool = layerType == std::string("Pooling"); if (isConv || isPool) { caffe::Blob<float> * inputBlob = net.bottom_vecs()[i][0]; int inputBlobNum = getBlobNumber(net,inputBlob); assert(inputBlobNum >= 0); std::string inputBlobName = net.blob_names()[inputBlobNum]; caffe::Blob<float> * outputBlob = net.top_vecs()[i][0]; int outputBlobNum = getBlobNumber(net,outputBlob); assert(outputBlobNum >= 0); std::string outputBlobName = net.blob_names()[outputBlobNum]; int2 kernelSize, stride; if (isConv) { caffe::ConvolutionParameter convParam = layer->layer_param().convolution_param(); kernelSize = convParam.has_kernel_size() ? make_int2(convParam.kernel_size()) : make_int2(convParam.kernel_w(),convParam.kernel_h()); stride = convParam.has_stride() ? make_int2(convParam.stride()) : make_int2(convParam.stride_w(),convParam.stride_h()); } else if (isPool) { caffe::PoolingParameter poolParam = layer->layer_param().pooling_param(); kernelSize = poolParam.has_kernel_size() ? make_int2(poolParam.kernel_size()) : make_int2(poolParam.kernel_w(),poolParam.kernel_h()); stride = poolParam.has_stride() ? make_int2(poolParam.stride()) : make_int2(poolParam.stride_w(),poolParam.stride_h()); } if (strides.find(inputBlobName) != strides.end()) { const int strideIn = strides[inputBlobName]; const int2 fieldIn = receptiveFields[inputBlobName]; strides[outputBlobName] = strideIn*stride.x; receptiveFields[outputBlobName] = strideIn*(kernelSize - make_int2(1)) + fieldIn; } } else if (layerType == std::string("InnerProduct")) { caffe::Blob<float> * inputBlob = net.bottom_vecs()[i][0]; int inputBlobNum = getBlobNumber(net,inputBlob); assert(inputBlobNum >= 0); std::string inputBlobName = net.blob_names()[inputBlobNum]; caffe::Blob<float> * outputBlob = net.top_vecs()[i][0]; int outputBlobNum = getBlobNumber(net,outputBlob); assert(outputBlobNum >= 0); std::string outputBlobName = net.blob_names()[outputBlobNum]; if (strides.find(inputBlobName) != strides.end()) { strides[outputBlobName] = strides[inputBlobName]; receptiveFields[outputBlobName] = inputSize; } } } }