diff options
Diffstat (limited to '')
3 files changed, 894 insertions, 0 deletions
diff --git a/ml/dlib/tools/convert_dlib_nets_to_caffe/CMakeLists.txt b/ml/dlib/tools/convert_dlib_nets_to_caffe/CMakeLists.txt new file mode 100644 index 000000000..f9518df21 --- /dev/null +++ b/ml/dlib/tools/convert_dlib_nets_to_caffe/CMakeLists.txt @@ -0,0 +1,25 @@ +# +# This is a CMake makefile. You can find the cmake utility and +# information about it at http://www.cmake.org +# + +cmake_minimum_required(VERSION 2.8.12) + +set (target_name dtoc) + +PROJECT(${target_name}) + +add_subdirectory(../../dlib dlib_build) + +add_executable(${target_name} + main.cpp + ) + +target_link_libraries(${target_name} dlib::dlib ) + + +INSTALL(TARGETS ${target_name} + RUNTIME DESTINATION bin + ) + + diff --git a/ml/dlib/tools/convert_dlib_nets_to_caffe/main.cpp b/ml/dlib/tools/convert_dlib_nets_to_caffe/main.cpp new file mode 100644 index 000000000..f5cc19748 --- /dev/null +++ b/ml/dlib/tools/convert_dlib_nets_to_caffe/main.cpp @@ -0,0 +1,792 @@ + +#include <dlib/xml_parser.h> +#include <dlib/matrix.h> +#include <fstream> +#include <vector> +#include <stack> +#include <set> +#include <dlib/string.h> + +using namespace std; +using namespace dlib; + + +// ---------------------------------------------------------------------------------------- + +// Only these computational layers have parameters +const std::set<string> comp_tags_with_params = {"fc", "fc_no_bias", "con", "affine_con", "affine_fc", "affine", "prelu"}; + +struct layer +{ + string type; // comp, loss, or input + int idx; + + matrix<long,4,1> output_tensor_shape; // (N,K,NR,NC) + + string detail_name; // The name of the tag inside the layer tag. e.g. fc, con, max_pool, input_rgb_image. + std::map<string,double> attributes; + matrix<float> params; + long tag_id = -1; // If this isn't -1 then it means this layer was tagged, e.g. wrapped with tag2<> giving tag_id==2 + long skip_id = -1; // If this isn't -1 then it means this layer draws its inputs from + // the most recent layer with tag_id==skip_id rather than its immediate predecessor. + + double attribute (const string& key) const + { + auto i = attributes.find(key); + if (i != attributes.end()) + return i->second; + else + throw dlib::error("Layer doesn't have the requested attribute '" + key + "'."); + } + + string caffe_layer_name() const + { + if (type == "input") + return "data"; + else + return detail_name+to_string(idx); + } +}; + +// ---------------------------------------------------------------------------------------- + +std::vector<layer> parse_dlib_xml( + const matrix<long,4,1>& input_tensor_shape, + const string& xml_filename +); + +// ---------------------------------------------------------------------------------------- + +template <typename iterator> +const layer& find_layer ( + iterator i, + long tag_id +) +/*! + requires + - i is a reverse iterator pointing to a layer in the list of layers produced by parse_dlib_xml(). + - i is not an input layer. + ensures + - if (tag_id == -1) then + - returns the previous layer (i.e. closer to the input) to layer i. + - else + - returns the previous layer (i.e. closer to the input) to layer i with the + given tag_id. +!*/ +{ + if (tag_id == -1) + { + return *(i-1); + } + else + { + while(true) + { + i--; + // if we hit the end of the network before we found what we were looking for + if (i->tag_id == tag_id) + return *i; + if (i->type == "input") + throw dlib::error("Network definition is bad, a layer wanted to skip back to a non-existing layer."); + } + } +} + +template <typename iterator> +const layer& find_input_layer (iterator i) { return find_layer(i, i->skip_id); } + +template <typename iterator> +string find_layer_caffe_name ( + iterator i, + long tag_id +) +{ + return find_layer(i,tag_id).caffe_layer_name(); +} + +template <typename iterator> +string find_input_layer_caffe_name (iterator i) { return find_input_layer(i).caffe_layer_name(); } + +// ---------------------------------------------------------------------------------------- + +template <typename iterator> +void compute_caffe_padding_size_for_pooling_layer( + const iterator& i, + long& pad_x, + long& pad_y +) +/*! + requires + - i is a reverse iterator pointing to a layer in the list of layers produced by parse_dlib_xml(). + - i is not an input layer. + ensures + - Caffe is funny about how it computes the output sizes from pooling layers. + Rather than using the normal formula for output row/column sizes used by all the + other layers (and what dlib uses everywhere), + floor((bottom_size + 2*pad - kernel_size) / stride) + 1 + it instead uses: + ceil((bottom_size + 2*pad - kernel_size) / stride) + 1 + + These are the same except when the stride!=1. In that case we need to figure out + how to change the padding value so that the output size of the caffe padding + layer will match the output size of the dlib padding layer. That is what this + function does. +!*/ +{ + const long dlib_output_nr = i->output_tensor_shape(2); + const long dlib_output_nc = i->output_tensor_shape(3); + const long bottom_nr = find_input_layer(i).output_tensor_shape(2); + const long bottom_nc = find_input_layer(i).output_tensor_shape(3); + const long padding_x = (long)i->attribute("padding_x"); + const long padding_y = (long)i->attribute("padding_y"); + const long stride_x = (long)i->attribute("stride_x"); + const long stride_y = (long)i->attribute("stride_y"); + long kernel_w = i->attribute("nc"); + long kernel_h = i->attribute("nr"); + + if (kernel_w == 0) + kernel_w = bottom_nc; + if (kernel_h == 0) + kernel_h = bottom_nr; + + + // The correct padding for caffe could be anything in the range [0,padding_x]. So + // check what gives the correct output size and use that. + for (pad_x = 0; pad_x <= padding_x; ++pad_x) + { + long caffe_out_size = ceil((bottom_nc + 2.0*pad_x - kernel_w)/(double)stride_x) + 1; + if (caffe_out_size == dlib_output_nc) + break; + } + if (pad_x == padding_x+1) + { + std::ostringstream sout; + sout << "No conversion between dlib pooling layer parameters and caffe pooling layer parameters found for layer " << to_string(i->idx) << endl; + sout << "dlib_output_nc: " << dlib_output_nc << endl; + sout << "bottom_nc: " << bottom_nc << endl; + sout << "padding_x: " << padding_x << endl; + sout << "stride_x: " << stride_x << endl; + sout << "kernel_w: " << kernel_w << endl; + sout << "pad_x: " << pad_x << endl; + throw dlib::error(sout.str()); + } + + for (pad_y = 0; pad_y <= padding_y; ++pad_y) + { + long caffe_out_size = ceil((bottom_nr + 2.0*pad_y - kernel_h)/(double)stride_y) + 1; + if (caffe_out_size == dlib_output_nr) + break; + } + if (pad_y == padding_y+1) + { + std::ostringstream sout; + sout << "No conversion between dlib pooling layer parameters and caffe pooling layer parameters found for layer " << to_string(i->idx) << endl; + sout << "dlib_output_nr: " << dlib_output_nr << endl; + sout << "bottom_nr: " << bottom_nr << endl; + sout << "padding_y: " << padding_y << endl; + sout << "stride_y: " << stride_y << endl; + sout << "kernel_h: " << kernel_h << endl; + sout << "pad_y: " << pad_y << endl; + throw dlib::error(sout.str()); + } +} + +// ---------------------------------------------------------------------------------------- + +void convert_dlib_xml_to_caffe_python_code( + const string& xml_filename, + const long N, + const long K, + const long NR, + const long NC +) +{ + const string out_filename = left_substr(xml_filename,".") + "_dlib_to_caffe_model.py"; + const string out_weights_filename = left_substr(xml_filename,".") + "_dlib_to_caffe_model.weights"; + cout << "Writing python part of model to " << out_filename << endl; + cout << "Writing weights part of model to " << out_weights_filename << endl; + ofstream fout(out_filename); + fout.precision(9); + const auto layers = parse_dlib_xml({N,K,NR,NC}, xml_filename); + + + fout << "#\n"; + fout << "# !!! This file was automatically generated by dlib's tools/convert_dlib_nets_to_caffe utility. !!!\n"; + fout << "# !!! It contains all the information from a dlib DNN network and lets you save it as a cafe model. !!!\n"; + fout << "#\n"; + fout << "import caffe " << endl; + fout << "from caffe import layers as L, params as P" << endl; + fout << "import numpy as np" << endl; + + // dlib nets don't commit to a batch size, so just use 1 as the default + fout << "\n# Input tensor dimensions" << endl; + fout << "input_batch_size = " << N << ";" << endl; + if (layers.back().detail_name == "input_rgb_image") + { + fout << "input_num_channels = 3;" << endl; + fout << "input_num_rows = "<<NR<<";" << endl; + fout << "input_num_cols = "<<NC<<";" << endl; + if (K != 3) + throw dlib::error("The dlib model requires input tensors with NUM_CHANNELS==3, but the dtoc command line specified NUM_CHANNELS=="+to_string(K)); + } + else if (layers.back().detail_name == "input_rgb_image_sized") + { + fout << "input_num_channels = 3;" << endl; + fout << "input_num_rows = " << layers.back().attribute("nr") << ";" << endl; + fout << "input_num_cols = " << layers.back().attribute("nc") << ";" << endl; + if (NR != layers.back().attribute("nr")) + throw dlib::error("The dlib model requires input tensors with NUM_ROWS=="+to_string((long)layers.back().attribute("nr"))+", but the dtoc command line specified NUM_ROWS=="+to_string(NR)); + if (NC != layers.back().attribute("nc")) + throw dlib::error("The dlib model requires input tensors with NUM_COLUMNS=="+to_string((long)layers.back().attribute("nc"))+", but the dtoc command line specified NUM_COLUMNS=="+to_string(NC)); + if (K != 3) + throw dlib::error("The dlib model requires input tensors with NUM_CHANNELS==3, but the dtoc command line specified NUM_CHANNELS=="+to_string(K)); + } + else if (layers.back().detail_name == "input") + { + fout << "input_num_channels = 1;" << endl; + fout << "input_num_rows = "<<NR<<";" << endl; + fout << "input_num_cols = "<<NC<<";" << endl; + if (K != 1) + throw dlib::error("The dlib model requires input tensors with NUM_CHANNELS==1, but the dtoc command line specified NUM_CHANNELS=="+to_string(K)); + } + else + { + throw dlib::error("No known transformation from dlib's " + layers.back().detail_name + " layer to caffe."); + } + fout << endl; + fout << "# Call this function to write the dlib DNN model out to file as a pair of caffe\n"; + fout << "# definition and weight files. You can then use the network by loading it with\n"; + fout << "# this statement: \n"; + fout << "# net = caffe.Net(def_file, weights_file, caffe.TEST);\n"; + fout << "#\n"; + fout << "def save_as_caffe_model(def_file, weights_file):\n"; + fout << " with open(def_file, 'w') as f: f.write(str(make_netspec()));\n"; + fout << " net = caffe.Net(def_file, caffe.TEST);\n"; + fout << " set_network_weights(net);\n"; + fout << " net.save(weights_file);\n\n"; + fout << "###############################################################################\n"; + fout << "# EVERYTHING BELOW HERE DEFINES THE DLIB MODEL PARAMETERS #\n"; + fout << "###############################################################################\n\n\n"; + + + // ----------------------------------------------------------------------------------- + // The next block of code outputs python code that defines the network architecture. + // ----------------------------------------------------------------------------------- + + fout << "def make_netspec():" << endl; + fout << " # For reference, the only \"documentation\" about caffe layer parameters seems to be this page:\n"; + fout << " # https://github.com/BVLC/caffe/blob/master/src/caffe/proto/caffe.proto\n" << endl; + fout << " n = caffe.NetSpec(); " << endl; + fout << " n.data,n.label = L.MemoryData(batch_size=input_batch_size, channels=input_num_channels, height=input_num_rows, width=input_num_cols, ntop=2)" << endl; + // iterate the layers starting with the input layer + for (auto i = layers.rbegin(); i != layers.rend(); ++i) + { + // skip input and loss layers + if (i->type == "loss" || i->type == "input") + continue; + + + if (i->detail_name == "con") + { + fout << " n." << i->caffe_layer_name() << " = L.Convolution(n." << find_input_layer_caffe_name(i); + fout << ", num_output=" << i->attribute("num_filters"); + fout << ", kernel_w=" << i->attribute("nc"); + fout << ", kernel_h=" << i->attribute("nr"); + fout << ", stride_w=" << i->attribute("stride_x"); + fout << ", stride_h=" << i->attribute("stride_y"); + fout << ", pad_w=" << i->attribute("padding_x"); + fout << ", pad_h=" << i->attribute("padding_y"); + fout << ");\n"; + } + else if (i->detail_name == "relu") + { + fout << " n." << i->caffe_layer_name() << " = L.ReLU(n." << find_input_layer_caffe_name(i); + fout << ");\n"; + } + else if (i->detail_name == "sig") + { + fout << " n." << i->caffe_layer_name() << " = L.Sigmoid(n." << find_input_layer_caffe_name(i); + fout << ");\n"; + } + else if (i->detail_name == "prelu") + { + fout << " n." << i->caffe_layer_name() << " = L.PReLU(n." << find_input_layer_caffe_name(i); + fout << ", channel_shared=True"; + fout << ");\n"; + } + else if (i->detail_name == "max_pool") + { + fout << " n." << i->caffe_layer_name() << " = L.Pooling(n." << find_input_layer_caffe_name(i); + fout << ", pool=P.Pooling.MAX"; + if (i->attribute("nc")==0) + { + fout << ", global_pooling=True"; + } + else + { + fout << ", kernel_w=" << i->attribute("nc"); + fout << ", kernel_h=" << i->attribute("nr"); + } + + fout << ", stride_w=" << i->attribute("stride_x"); + fout << ", stride_h=" << i->attribute("stride_y"); + long pad_x, pad_y; + compute_caffe_padding_size_for_pooling_layer(i, pad_x, pad_y); + fout << ", pad_w=" << pad_x; + fout << ", pad_h=" << pad_y; + fout << ");\n"; + } + else if (i->detail_name == "avg_pool") + { + fout << " n." << i->caffe_layer_name() << " = L.Pooling(n." << find_input_layer_caffe_name(i); + fout << ", pool=P.Pooling.AVE"; + if (i->attribute("nc")==0) + { + fout << ", global_pooling=True"; + } + else + { + fout << ", kernel_w=" << i->attribute("nc"); + fout << ", kernel_h=" << i->attribute("nr"); + } + if (i->attribute("padding_x") != 0 || i->attribute("padding_y") != 0) + { + throw dlib::error("dlib and caffe implement pooling with non-zero padding differently, so you can't convert a " + "network with such pooling layers."); + } + + fout << ", stride_w=" << i->attribute("stride_x"); + fout << ", stride_h=" << i->attribute("stride_y"); + long pad_x, pad_y; + compute_caffe_padding_size_for_pooling_layer(i, pad_x, pad_y); + fout << ", pad_w=" << pad_x; + fout << ", pad_h=" << pad_y; + fout << ");\n"; + } + else if (i->detail_name == "fc") + { + fout << " n." << i->caffe_layer_name() << " = L.InnerProduct(n." << find_input_layer_caffe_name(i); + fout << ", num_output=" << i->attribute("num_outputs"); + fout << ", bias_term=True"; + fout << ");\n"; + } + else if (i->detail_name == "fc_no_bias") + { + fout << " n." << i->caffe_layer_name() << " = L.InnerProduct(n." << find_input_layer_caffe_name(i); + fout << ", num_output=" << i->attribute("num_outputs"); + fout << ", bias_term=False"; + fout << ");\n"; + } + else if (i->detail_name == "bn_con" || i->detail_name == "bn_fc") + { + throw dlib::error("Conversion from dlib's batch norm layers to caffe's isn't supported. Instead, " + "you should put your dlib network into 'test mode' by switching batch norm layers to affine layers. " + "Then you can convert that 'test mode' network to caffe."); + } + else if (i->detail_name == "affine_con") + { + fout << " n." << i->caffe_layer_name() << " = L.Scale(n." << find_input_layer_caffe_name(i); + fout << ", bias_term=True"; + fout << ");\n"; + } + else if (i->detail_name == "affine_fc") + { + fout << " n." << i->caffe_layer_name() << " = L.Scale(n." << find_input_layer_caffe_name(i); + fout << ", bias_term=True"; + fout << ");\n"; + } + else if (i->detail_name == "add_prev") + { + auto in_shape1 = find_input_layer(i).output_tensor_shape; + auto in_shape2 = find_layer(i,i->attribute("tag")).output_tensor_shape; + if (in_shape1 != in_shape2) + { + // if only the number of channels differs then we will use a dummy layer to + // pad with zeros. But otherwise we will throw an error. + if (in_shape1(0) == in_shape2(0) && + in_shape1(2) == in_shape2(2) && + in_shape1(3) == in_shape2(3)) + { + fout << " n." << i->caffe_layer_name() << "_zeropad = L.DummyData(num=" << in_shape1(0); + fout << ", channels="<<std::abs(in_shape1(1)-in_shape2(1)); + fout << ", height="<<in_shape1(2); + fout << ", width="<<in_shape1(3); + fout << ");\n"; + + string smaller_layer = find_input_layer_caffe_name(i); + string bigger_layer = find_layer_caffe_name(i, i->attribute("tag")); + if (in_shape1(1) > in_shape2(1)) + swap(smaller_layer, bigger_layer); + + fout << " n." << i->caffe_layer_name() << "_concat = L.Concat(n." << smaller_layer; + fout << ", n." << i->caffe_layer_name() << "_zeropad"; + fout << ");\n"; + + fout << " n." << i->caffe_layer_name() << " = L.Eltwise(n." << i->caffe_layer_name() << "_concat"; + fout << ", n." << bigger_layer; + fout << ", operation=P.Eltwise.SUM"; + fout << ");\n"; + } + else + { + std::ostringstream sout; + sout << "The dlib network contained an add_prev layer (layer idx " << i->idx << ") that adds two previous "; + sout << "layers with different output tensor dimensions. Caffe's equivalent layer, Eltwise, doesn't support "; + sout << "adding layers together with different dimensions. In the special case where the only difference is "; + sout << "in the number of channels, this converter program will add a dummy layer that outputs a tensor full of zeros "; + sout << "and concat it appropriately so this will work. However, this network you are converting has tensor dimensions "; + sout << "different in values other than the number of channels. In particular, here are the two tensor shapes (batch size, channels, rows, cols): "; + std::ostringstream sout2; + sout2 << wrap_string(sout.str()) << endl; + sout2 << trans(in_shape1); + sout2 << trans(in_shape2); + throw dlib::error(sout2.str()); + } + } + else + { + fout << " n." << i->caffe_layer_name() << " = L.Eltwise(n." << find_input_layer_caffe_name(i); + fout << ", n." << find_layer_caffe_name(i, i->attribute("tag")); + fout << ", operation=P.Eltwise.SUM"; + fout << ");\n"; + } + } + else + { + throw dlib::error("No known transformation from dlib's " + i->detail_name + " layer to caffe."); + } + } + fout << " return n.to_proto();\n\n" << endl; + + + // ----------------------------------------------------------------------------------- + // The next block of code outputs python code that populates all the filter weights. + // ----------------------------------------------------------------------------------- + + ofstream fweights(out_weights_filename, ios::binary); + fout << "def set_network_weights(net):\n"; + fout << " # populate network parameters\n"; + fout << " f = open('"<<out_weights_filename<<"', 'rb');\n"; + // iterate the layers starting with the input layer + for (auto i = layers.rbegin(); i != layers.rend(); ++i) + { + // skip input and loss layers + if (i->type == "loss" || i->type == "input") + continue; + + + if (i->detail_name == "con") + { + const long num_filters = i->attribute("num_filters"); + matrix<float> weights = trans(rowm(i->params,range(0,i->params.size()-num_filters-1))); + matrix<float> biases = trans(rowm(i->params,range(i->params.size()-num_filters, i->params.size()-1))); + fweights.write((char*)&weights(0,0), weights.size()*sizeof(float)); + fweights.write((char*)&biases(0,0), biases.size()*sizeof(float)); + + // main filter weights + fout << " p = np.fromfile(f, dtype='float32', count="<<weights.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][0].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][0].data[:] = p;\n"; + + // biases + fout << " p = np.fromfile(f, dtype='float32', count="<<biases.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][1].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][1].data[:] = p;\n"; + } + else if (i->detail_name == "fc") + { + matrix<float> weights = trans(rowm(i->params, range(0,i->params.nr()-2))); + matrix<float> biases = rowm(i->params, i->params.nr()-1); + fweights.write((char*)&weights(0,0), weights.size()*sizeof(float)); + fweights.write((char*)&biases(0,0), biases.size()*sizeof(float)); + + // main filter weights + fout << " p = np.fromfile(f, dtype='float32', count="<<weights.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][0].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][0].data[:] = p;\n"; + + // biases + fout << " p = np.fromfile(f, dtype='float32', count="<<biases.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][1].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][1].data[:] = p;\n"; + } + else if (i->detail_name == "fc_no_bias") + { + matrix<float> weights = trans(i->params); + fweights.write((char*)&weights(0,0), weights.size()*sizeof(float)); + + // main filter weights + fout << " p = np.fromfile(f, dtype='float32', count="<<weights.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][0].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][0].data[:] = p;\n"; + } + else if (i->detail_name == "affine_con" || i->detail_name == "affine_fc") + { + const long dims = i->params.size()/2; + matrix<float> gamma = trans(rowm(i->params,range(0,dims-1))); + matrix<float> beta = trans(rowm(i->params,range(dims, 2*dims-1))); + fweights.write((char*)&gamma(0,0), gamma.size()*sizeof(float)); + fweights.write((char*)&beta(0,0), beta.size()*sizeof(float)); + + // set gamma weights + fout << " p = np.fromfile(f, dtype='float32', count="<<gamma.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][0].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][0].data[:] = p;\n"; + + // set beta weights + fout << " p = np.fromfile(f, dtype='float32', count="<<beta.size()<<");\n"; + fout << " p.shape = net.params['"<<i->caffe_layer_name()<<"'][1].data.shape;\n"; + fout << " net.params['"<<i->caffe_layer_name()<<"'][1].data[:] = p;\n"; + } + else if (i->detail_name == "prelu") + { + const double param = i->params(0); + + // main filter weights + fout << " tmp = net.params['"<<i->caffe_layer_name()<<"'][0].data.view();\n"; + fout << " tmp.shape = 1;\n"; + fout << " tmp[0] = "<<param<<";\n"; + } + } + +} + +// ---------------------------------------------------------------------------------------- + +int main(int argc, char** argv) try +{ + if (argc != 6) + { + cout << "To use this program, give it an xml file generated by dlib::net_to_xml() " << endl; + cout << "and then 4 numbers that indicate the input tensor size. It will convert " << endl; + cout << "the xml file into a python file that outputs a caffe model containing the dlib model." << endl; + cout << "For example, you might run this program like this: " << endl; + cout << " ./dtoc lenet.xml 1 1 28 28" << endl; + cout << "would convert the lenet.xml model into a caffe model with an input tensor of shape(1,1,28,28)" << endl; + cout << "where the shape values are (num samples in batch, num channels, num rows, num columns)." << endl; + return 0; + } + + const long N = sa = argv[2]; + const long K = sa = argv[3]; + const long NR = sa = argv[4]; + const long NC = sa = argv[5]; + + convert_dlib_xml_to_caffe_python_code(argv[1], N, K, NR, NC); + + return 0; +} +catch(std::exception& e) +{ + cout << "\n\n*************** ERROR CONVERTING TO CAFFE ***************\n" << e.what() << endl; + return 1; +} + +// ---------------------------------------------------------------------------------------- +// ---------------------------------------------------------------------------------------- +// ---------------------------------------------------------------------------------------- +// ---------------------------------------------------------------------------------------- + +class doc_handler : public document_handler +{ +public: + std::vector<layer> layers; + bool seen_first_tag = false; + + layer next_layer; + std::stack<string> current_tag; + long tag_id = -1; + + + virtual void start_document ( + ) + { + layers.clear(); + seen_first_tag = false; + tag_id = -1; + } + + virtual void end_document ( + ) { } + + virtual void start_element ( + const unsigned long /*line_number*/, + const std::string& name, + const dlib::attribute_list& atts + ) + { + if (!seen_first_tag) + { + if (name != "net") + throw dlib::error("The top level XML tag must be a 'net' tag."); + seen_first_tag = true; + } + + if (name == "layer") + { + next_layer = layer(); + if (atts["type"] == "skip") + { + // Don't make a new layer, just apply the tag id to the previous layer + if (layers.size() == 0) + throw dlib::error("A skip layer was found as the first layer, but the first layer should be an input layer."); + layers.back().skip_id = sa = atts["id"]; + + // We intentionally leave next_layer empty so the end_element() callback + // don't add it as another layer when called. + } + else if (atts["type"] == "tag") + { + // Don't make a new layer, just remember the tag id so we can apply it on + // the next layer. + tag_id = sa = atts["id"]; + + // We intentionally leave next_layer empty so the end_element() callback + // don't add it as another layer when called. + } + else + { + next_layer.idx = sa = atts["idx"]; + next_layer.type = atts["type"]; + if (tag_id != -1) + { + next_layer.tag_id = tag_id; + tag_id = -1; + } + } + } + else if (current_tag.size() != 0 && current_tag.top() == "layer") + { + next_layer.detail_name = name; + // copy all the XML tag's attributes into the layer struct + atts.reset(); + while (atts.move_next()) + next_layer.attributes[atts.element().key()] = sa = atts.element().value(); + } + + current_tag.push(name); + } + + virtual void end_element ( + const unsigned long /*line_number*/, + const std::string& name + ) + { + current_tag.pop(); + if (name == "layer" && next_layer.type.size() != 0) + layers.push_back(next_layer); + } + + virtual void characters ( + const std::string& data + ) + { + if (current_tag.size() == 0) + return; + + if (comp_tags_with_params.count(current_tag.top()) != 0) + { + istringstream sin(data); + sin >> next_layer.params; + } + + } + + virtual void processing_instruction ( + const unsigned long /*line_number*/, + const std::string& /*target*/, + const std::string& /*data*/ + ) + { + } +}; + +// ---------------------------------------------------------------------------------------- + +void compute_output_tensor_shapes(const matrix<long,4,1>& input_tensor_shape, std::vector<layer>& layers) +{ + DLIB_CASSERT(layers.back().type == "input"); + layers.back().output_tensor_shape = input_tensor_shape; + for (auto i = ++layers.rbegin(); i != layers.rend(); ++i) + { + const auto input_shape = find_input_layer(i).output_tensor_shape; + if (i->type == "comp") + { + if (i->detail_name == "fc" || i->detail_name == "fc_no_bias") + { + long num_outputs = i->attribute("num_outputs"); + i->output_tensor_shape = {input_shape(0), num_outputs, 1, 1}; + } + else if (i->detail_name == "con") + { + long num_filters = i->attribute("num_filters"); + long filter_nc = i->attribute("nc"); + long filter_nr = i->attribute("nr"); + long stride_x = i->attribute("stride_x"); + long stride_y = i->attribute("stride_y"); + long padding_x = i->attribute("padding_x"); + long padding_y = i->attribute("padding_y"); + long nr = 1+(input_shape(2) + 2*padding_y - filter_nr)/stride_y; + long nc = 1+(input_shape(3) + 2*padding_x - filter_nc)/stride_x; + i->output_tensor_shape = {input_shape(0), num_filters, nr, nc}; + } + else if (i->detail_name == "max_pool" || i->detail_name == "avg_pool") + { + long filter_nc = i->attribute("nc"); + long filter_nr = i->attribute("nr"); + long stride_x = i->attribute("stride_x"); + long stride_y = i->attribute("stride_y"); + long padding_x = i->attribute("padding_x"); + long padding_y = i->attribute("padding_y"); + if (filter_nc != 0) + { + long nr = 1+(input_shape(2) + 2*padding_y - filter_nr)/stride_y; + long nc = 1+(input_shape(3) + 2*padding_x - filter_nc)/stride_x; + i->output_tensor_shape = {input_shape(0), input_shape(1), nr, nc}; + } + else // if we are filtering the whole input down to one thing + { + i->output_tensor_shape = {input_shape(0), input_shape(1), 1, 1}; + } + } + else if (i->detail_name == "add_prev") + { + auto aux_shape = find_layer(i, i->attribute("tag")).output_tensor_shape; + for (long j = 0; j < input_shape.size(); ++j) + i->output_tensor_shape(j) = std::max(input_shape(j), aux_shape(j)); + } + else + { + i->output_tensor_shape = input_shape; + } + } + else + { + i->output_tensor_shape = input_shape; + } + + } +} + +// ---------------------------------------------------------------------------------------- + +std::vector<layer> parse_dlib_xml( + const matrix<long,4,1>& input_tensor_shape, + const string& xml_filename +) +{ + doc_handler dh; + parse_xml(xml_filename, dh); + if (dh.layers.size() == 0) + throw dlib::error("No layers found in XML file!"); + + if (dh.layers.back().type != "input") + throw dlib::error("The network in the XML file is missing an input layer!"); + + compute_output_tensor_shapes(input_tensor_shape, dh.layers); + + return dh.layers; +} + +// ---------------------------------------------------------------------------------------- + diff --git a/ml/dlib/tools/convert_dlib_nets_to_caffe/running_a_dlib_model_with_caffe_example.py b/ml/dlib/tools/convert_dlib_nets_to_caffe/running_a_dlib_model_with_caffe_example.py new file mode 100755 index 000000000..c03a7bf5c --- /dev/null +++ b/ml/dlib/tools/convert_dlib_nets_to_caffe/running_a_dlib_model_with_caffe_example.py @@ -0,0 +1,77 @@ +#!/usr/bin/env python + +# This script takes the dlib lenet model trained by the +# examples/dnn_introduction_ex.cpp example program and runs it using caffe. + +import caffe +import numpy as np + +# Before you run this program, you need to run dnn_introduction_ex.cpp to get a +# dlib lenet model. Then you need to convert that model into a "dlib to caffe +# model" python script. You can do this using the command line program +# included with dlib: tools/convert_dlib_nets_to_caffe. That program will +# output a lenet_dlib_to_caffe_model.py file. You run that program like this: +# ./dtoc lenet.xml 1 1 28 28 +# and it will create the lenet_dlib_to_caffe_model.py file, which we import +# with the next line: +import lenet_dlib_to_caffe_model as dlib_model + +# lenet_dlib_to_caffe_model defines a function, save_as_caffe_model() that does +# the work of converting dlib's DNN model to a caffe model and saves it to disk +# in two files. These files are all you need to run the model with caffe. +dlib_model.save_as_caffe_model('dlib_model_def.prototxt', 'dlib_model.proto') + +# Now that we created the caffe model files, we can load them into a caffe Net object. +net = caffe.Net('dlib_model_def.prototxt', 'dlib_model.proto', caffe.TEST); + + +# Now lets do a test, we will run one of the MNIST images through the network. + +# An MNIST image of a 7, it is the very first testing image in MNIST (i.e. wrt dnn_introduction_ex.cpp, it is testing_images[0]) +data = np.array([0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0,84,185,159,151,60,36, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0,222,254,254,254,254,241,198,198,198,198,198,198,198,198,170,52, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0,67,114,72,114,163,227,254,225,254,254,254,250,229,254,254,140, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,17,66,14,67,67,67,59,21,236,254,106, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,83,253,209,18, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,22,233,255,83, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,129,254,238,44, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,59,249,254,62, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,133,254,187,5, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,9,205,248,58, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,126,254,182, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,75,251,240,57, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,19,221,254,166, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,3,203,254,219,35, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,38,254,254,77, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,31,224,254,115,1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,133,254,254,52, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,61,242,254,254,52, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,121,254,254,219,40, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,121,254,207,18, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], dtype='float32'); +data.shape = (dlib_model.input_batch_size, dlib_model.input_num_channels, dlib_model.input_num_rows, dlib_model.input_num_cols); + +# labels isn't logically needed but there doesn't seem to be a way to use +# caffe's Net interface without providing a superfluous input array. So we do +# that here. +labels = np.ones((dlib_model.input_batch_size), dtype='float32') +# Give the image to caffe +net.set_input_arrays(data/256, labels) +# Run the data through the network and get the results. +out = net.forward() + +# Print outputs, looping over minibatch. You should see that the network +# correctly classifies the image (it's the number 7). +for i in xrange(dlib_model.input_batch_size): + print i, 'net final layer = ', out['fc1'][i] + print i, 'predicted number =', np.argmax(out['fc1'][i]) + + + |