void convertProtoToLua(void** handle, const char* lua_name, const char* cuda_package) { const caffe::NetParameter netparam = *(const caffe::NetParameter*)handle[1]; std::ofstream ofs (lua_name); ofs << "require '" << cuda_package << "'\n"; ofs << "require 'cunn'\n"; ofs << "model = {}\n"; if(std::string(cuda_package)=="ccn2") ofs<< "table.insert(model, {'torch_transpose_dwhb', nn.Transpose({1,4},{1,3},{1,2})})\n"; int num_output = netparam.input_dim_size(); for (int i=0; i<netparam.layers_size(); ++i) { std::vector<std::pair<std::string, std::string>> lines; auto& layer = netparam.layers(i); switch(layer.type()) { case caffe::LayerParameter::CONVOLUTION: { auto ¶m = layer.convolution_param(); int groups = param.group() == 0 ? 1 : param.group(); int nInputPlane = layer.blobs(0).channels()*groups; int nOutputPlane = param.num_output(); num_output = nOutputPlane; int kW = param.kernel_w(); int kH = param.kernel_h(); int dW = param.stride_w(); int dH = param.stride_h(); if(kW==0 || kH==0) { kW = param.kernel_size(); kH = kW; } if(dW==0 || dH==0) { dW = param.stride(); dH = dW; } int pad_w = param.pad_w(); int pad_h = param.pad_h(); if(pad_w==0 || pad_h==0) { pad_w = param.pad(); pad_h = pad_w; } if(std::string(cuda_package) == "ccn2") { if(kW != kH || dW != dH || pad_w != pad_h) { std::cout << "ccn2 only supports square images!\n"; break; } char buf[1024]; sprintf(buf, "ccn2.SpatialConvolution(%d, %d, %d, %d, %d, %d)", nInputPlane, nOutputPlane, kW, dW, pad_w, groups); lines.emplace_back(layer.name(), buf); } else { char buf[1024]; const char* mm_or_not = std::string(cuda_package)=="nn" ? "MM" : ""; sprintf(buf, "%s.SpatialConvolution%s(%d, %d, %d, %d, %d, %d, %d, %d)", cuda_package, mm_or_not, nInputPlane, nOutputPlane, kW, kH, dW, dH, pad_w, pad_h); lines.emplace_back(layer.name(), buf); } break; } case caffe::LayerParameter::POOLING: { auto ¶m = layer.pooling_param(); std::string ptype = param.pool() == caffe::PoolingParameter::MAX ? "Max" : "Avg"; int kW = param.kernel_w(); int kH = param.kernel_h(); int dW = param.stride_w(); int dH = param.stride_h(); if(kW==0 || kH==0) { kW = param.kernel_size(); kH = kW; } if(dW==0 || dH==0) { dW = param.stride(); dH = dW; } if(std::string(cuda_package) == "ccn2") { char buf[1024]; sprintf(buf, "ccn2.Spatial%sPooling(%d, %d)", ptype.c_str(), kW, dW); lines.emplace_back(layer.name(), buf); } else if(std::string(cuda_package) == "cudnn") { char buf[1024]; sprintf(buf, "%s.Spatial%sPooling(%d, %d, %d, %d):ceil()", cuda_package, ptype=="Avg" ? "Average" : "Max", kW, kH, dW, dH); lines.emplace_back(layer.name(), buf); } break; } case caffe::LayerParameter::RELU: { lines.emplace_back(layer.name(), "nn.ReLU()"); break; } case caffe::LayerParameter::LRN: { if(std::string(cuda_package) == "ccn2") { auto ¶m = layer.lrn_param(); int local_size = param.local_size(); float alpha = param.alpha(); float beta = param.beta(); char buf[1024]; sprintf(buf, "ccn2.SpatialCrossResponseNormalization(%d, %.6f, %.4f)", local_size, alpha, beta); lines.emplace_back(layer.name(), buf); } break; } case caffe::LayerParameter::INNER_PRODUCT: { auto ¶m = layer.inner_product_param(); int nInputPlane = layer.blobs(0).width(); int nOutputPlane = param.num_output(); char buf[1024]; sprintf(buf, "nn.Linear(%d, %d)", nInputPlane, nOutputPlane); if(num_output != nInputPlane) { if(std::string(cuda_package) == "ccn2") lines.emplace_back("torch_transpose_bdwh", "nn.Transpose({4,1},{4,2},{4,3})"); lines.emplace_back("torch_view", "nn.View(-1):setNumInputDims(3)"); } lines.emplace_back(layer.name(), buf); num_output = nOutputPlane; break; } case caffe::LayerParameter::DROPOUT: { char buf[1024]; sprintf(buf, "nn.Dropout(%f)", netparam.layers(i).dropout_param().dropout_ratio()); lines.emplace_back(layer.name(), buf); break; } case caffe::LayerParameter::SOFTMAX_LOSS: { lines.emplace_back(layer.name(), "nn.SoftMax()"); break; } case caffe::LayerParameter::SOFTMAX: { lines.emplace_back(layer.name(), "nn.SoftMax()"); break; } default: { std::cout << "MODULE " << netparam.layers(i).name() << " UNDEFINED\n"; break; } } if(!lines.empty()) for(auto& it: lines) ofs << "table.insert(model, {'" << it.first << "', " << it.second << "})\n"; else ofs << "-- module '" << layer.name() << "' not found\n"; } }
void convertProtoToLuaV1(const caffe::NetParameter &netparam, const char* lua_name, const char* cuda_package) { PACKAGE_TYPE cuda_package_type = CCN2; if(std::string(cuda_package) == "ccn2") cuda_package_type = CCN2; else if(std::string(cuda_package) == "nn") cuda_package_type = NN; else if(std::string(cuda_package) == "cudnn") cuda_package_type = CUDNN; std::ofstream ofs (lua_name); ofs << "require '" << cuda_package << "'\n"; ofs << "require 'cunn'\n"; ofs << "local model = {}\n"; if(std::string(cuda_package)=="ccn2") ofs<< "table.insert(model, {'torch_transpose_dwhb', nn.Transpose({1,4},{1,3},{1,2})})\n"; else if(std::string(cuda_package)=="nn" || std::string(cuda_package)=="cudnn") ofs<< "require 'inn'\n"; int num_output = netparam.input_dim_size(); for (int i=0; i<netparam.layers_size(); ++i) { std::vector<std::pair<std::string, std::string>> lines; auto& layer = netparam.layers(i); switch(layer.type()) { case caffe::V1LayerParameter::CONVOLUTION: { auto ¶m = layer.convolution_param(); int groups = param.group() == 0 ? 1 : param.group(); int nInputPlane = layer.blobs(0).channels()*groups; int nOutputPlane = layer.blobs(0).num(); //int nOutputPlane = param.num_output(); num_output = nOutputPlane; int kW = param.kernel_w(); int kH = param.kernel_h(); int dW = param.stride_w(); int dH = param.stride_h(); if(kW==0 || kH==0) { kW = param.kernel_size(); kH = kW; } if(dW==0 || dH==0) { dW = param.stride(); dH = dW; } int pad_w = param.pad_w(); int pad_h = param.pad_h(); if(pad_w==0 || pad_h==0) { pad_w = param.pad(); pad_h = pad_w; } if(cuda_package_type == CCN2) { if(kW != kH || dW != dH || pad_w != pad_h) { std::cout << "ccn2 only supports square images!\n"; break; } char buf[1024]; sprintf(buf, "ccn2.SpatialConvolution(%d, %d, %d, %d, %d, %d)", nInputPlane, nOutputPlane, kW, dW, pad_w, groups); lines.emplace_back(layer.name(), buf); } else if(cuda_package_type == NN) { if(groups != 1) { std::cout << "nn supports no groups!\n"; break; } char buf[1024]; sprintf(buf, "nn.SpatialConvolutionMM(%d, %d, %d, %d, %d, %d, %d, %d)", nInputPlane, nOutputPlane, kW, kH, dW, dH, pad_w, pad_h); lines.emplace_back(layer.name(), buf); } else { char buf[1024]; sprintf(buf, "cudnn.SpatialConvolution(%d, %d, %d, %d, %d, %d, %d, %d, %d)", nInputPlane, nOutputPlane, kW, kH, dW, dH, pad_w, pad_h, groups); lines.emplace_back(layer.name(), buf); } break; } case caffe::V1LayerParameter::POOLING: { auto ¶m = layer.pooling_param(); int kW = param.kernel_w(); int kH = param.kernel_h(); int dW = param.stride_w(); int dH = param.stride_h(); int padW = param.pad_w(); int padH = param.pad_h(); if(kW==0 || kH==0) { kW = param.kernel_size(); kH = kW; } if(dW==0 || dH==0) { dW = param.stride(); dH = dW; } char buf[1024]; switch(cuda_package_type) { case CCN2: // ceil mode by default if(param.pool() == caffe::PoolingParameter::MAX) sprintf(buf, "ccn2.SpatialMaxPooling(%d, %d)", kW, dW); else if(param.pool() == caffe::PoolingParameter::AVE) sprintf(buf, "ccn2.SpatialAvgPooling(%d, %d)", kW, dW); else if(param.pool() == caffe::PoolingParameter::STOCHASTIC) THError("Stochastic pooling is not implemented in DHWB format"); break; case CUDNN: if(param.pool() == caffe::PoolingParameter::MAX) sprintf(buf, "cudnn.SpatialMaxPooling(%d, %d, %d, %d, %d, %d):ceil()", kW, kH, dW, dH, padW, padH); else if(param.pool() == caffe::PoolingParameter::AVE) sprintf(buf, "cudnn.SpatialAveragePooling(%d, %d, %d, %d, %d, %d):ceil()", kW, kH, dW, dH, padW, padH); else if(param.pool() == caffe::PoolingParameter::STOCHASTIC) sprintf(buf, "inn.SpatialStochasticPooling(%d, %d, %d, %d)", kW, kH, dW, dH); break; case NN: if(param.pool() == caffe::PoolingParameter::MAX) //sprintf(buf, "nn.SpatialMaxPooling(%d, %d, %d, %d, %d, %d):ceil()", kW, kH, dW, dH, padW, padH); sprintf(buf, "nn.SpatialMaxPooling(%d, %d, %d, %d, %d, %d)", kW, kH, dW, dH, padW, padH); else if(param.pool() == caffe::PoolingParameter::AVE) sprintf(buf, "inn.SpatialAveragePooling(%d, %d, %d, %d)", kW, kH, dW, dH); // padding is not supported yet else if(param.pool() == caffe::PoolingParameter::STOCHASTIC) sprintf(buf, "inn.SpatialStochasticPooling(%d, %d, %d, %d)", kW, kH, dW, dH); break; } lines.emplace_back(layer.name(), buf); break; } case caffe::V1LayerParameter::RELU: { switch(cuda_package_type) { case CUDNN: lines.emplace_back(layer.name(), "cudnn.ReLU(true)"); break; default: lines.emplace_back(layer.name(), "nn.ReLU(true)"); break; } break; } case caffe::V1LayerParameter::TANH: { switch(cuda_package_type) { case CUDNN: lines.emplace_back(layer.name(), "cudnn.Tanh(true)"); break; default: lines.emplace_back(layer.name(), "nn.Tanh()"); break; } break; } case caffe::V1LayerParameter::SIGMOID: { switch(cuda_package_type) { case CUDNN: lines.emplace_back(layer.name(), "cudnn.Sigmoid(true)"); break; default: lines.emplace_back(layer.name(), "nn.Sigmoid()"); break; } break; } case caffe::V1LayerParameter::LRN: { auto ¶m = layer.lrn_param(); int local_size = param.local_size(); float alpha = param.alpha(); float beta = param.beta(); float k = param.k(); char buf[1024]; if(std::string(cuda_package) == "ccn2") sprintf(buf, "ccn2.SpatialCrossResponseNormalization(%d, %.6f, %.4f, %f)", local_size, alpha, beta, k); else sprintf(buf, "inn.SpatialCrossResponseNormalization(%d, %.6f, %.4f, %f)", local_size, alpha, beta, k); lines.emplace_back(layer.name(), buf); break; } case caffe::V1LayerParameter::INNER_PRODUCT: { auto ¶m = layer.inner_product_param(); int nInputPlane = layer.blobs(0).width(); int nOutputPlane = param.num_output(); char buf[1024]; sprintf(buf, "nn.Linear(%d, %d)", nInputPlane, nOutputPlane); if(num_output != nInputPlane) { if(std::string(cuda_package) == "ccn2") lines.emplace_back("torch_transpose_bdwh", "nn.Transpose({4,1},{4,2},{4,3})"); lines.emplace_back("torch_view", "nn.View(-1):setNumInputDims(3)"); } lines.emplace_back(layer.name(), buf); num_output = nOutputPlane; break; } case caffe::V1LayerParameter::DROPOUT: { char buf[1024]; sprintf(buf, "nn.Dropout(%f)", layer.dropout_param().dropout_ratio()); lines.emplace_back(layer.name(), buf); break; } case caffe::V1LayerParameter::SOFTMAX_LOSS: { lines.emplace_back(layer.name(), "nn.SoftMax()"); break; } case caffe::V1LayerParameter::SOFTMAX: { lines.emplace_back(layer.name(), "nn.SoftMax()"); break; } default: { std::cout << "MODULE " << layer.name() << " UNDEFINED\n"; break; } } if(!lines.empty()) for(auto& it: lines) ofs << "table.insert(model, {'" << it.first << "', " << it.second << "})\n"; else { ofs << "-- warning: module '" << layer.name() << "' not found\n"; std::cout << "warning: module '" << layer.name() << "' not found\n"; } } ofs << "return model"; }