mirror of https://github.com/davisking/dlib.git
158 lines
6.1 KiB
C++
158 lines
6.1 KiB
C++
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
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/*
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This is an example illustrating the use of the deep learning tools from the
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dlib C++ Library. I'm assuming you have already read the dnn_introduction_ex.cpp and
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the dnn_introduction2_ex.cpp examples. So in this example program I'm going to go
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over a transfer learning example, which includes:
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- Defining a layer visitor to modify the some network parameters for fine-tuning
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- Using pretrained layers of a network for another task
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*/
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#include <dlib/dnn.h>
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#include <iostream>
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// This header file includes a generic definition of the most common ResNet architectures
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#include "resnet.h"
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using namespace std;
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using namespace dlib;
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// In this simple example we will show how to load a pretrained network and use it for a
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// different task. In particular, we will load a ResNet50 trained on ImageNet, adjust
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// some of its parameters and use it as a pretrained backbone for some metric learning
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// task.
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// Let's start by defining a network that will use the ResNet50 backbone from resnet.h
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namespace model
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{
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template<template<typename> class BN>
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using net_type = loss_metric<
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fc_no_bias<128,
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avg_pool_everything<
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typename resnet::def<BN>::template backbone_50<
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input_rgb_image
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>>>>;
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using train = net_type<bn_con>;
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using infer = net_type<affine>;
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}
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// Next, we define a layer visitor that will modify the weight decay of a network. The
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// main interest of this class is to show how one can define custom visitors that modify
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// some network parameters.
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class visitor_weight_decay_multiplier
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{
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public:
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visitor_weight_decay_multiplier(double new_weight_decay_multiplier_) :
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new_weight_decay_multiplier(new_weight_decay_multiplier_) {}
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template <typename layer>
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void operator()(layer& l) const
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{
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set_weight_decay_multiplier(l, new_weight_decay_multiplier);
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}
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private:
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double new_weight_decay_multiplier;
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};
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int main() try
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{
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// Let's instantiate our network in train mode.
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model::train net;
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// We create a new scope so that resources from the loaded network are freed
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// automatically when leaving the scope.
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{
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// Now, let's define the classic ResNet50 network and load the pretrained model on
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// ImageNet.
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resnet::train_50 resnet50;
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std::vector<string> labels;
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deserialize("resnet50_1000_imagenet_classifier.dnn") >> resnet50 >> labels;
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// For transfer learning, we are only interested in the ResNet50's backbone, which
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// lays below the loss and the fc layers, so we can extract it as:
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auto backbone = std::move(resnet50.subnet().subnet());
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// We can now assign ResNet50's backbone to our network skipping the different
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// layers, in our case, the loss layer and the fc layer:
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net.subnet().subnet() = backbone;
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// An alternative way to use the pretrained network on a different
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// network is to extract the relevant part of the network (we remove
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// loss and fc layers), stack the new layers on top of it and assign
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// the network.
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using net_type = loss_metric<fc_no_bias<128, decltype(backbone)>>;
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net_type net2;
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net2.subnet().subnet() = backbone;
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}
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// We can use the visit_layers function to modify the weight decay of the entire
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// network:
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visit_computational_layers(net, visitor_weight_decay_multiplier(0.001));
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// We can also use predefined visitors to affect the learning rate of the whole
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// network.
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set_all_learning_rate_multipliers(net, 0.5);
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// Modifying the learning rates of a network is a common practice for fine tuning, for
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// this reason it is already provided. However, it is implemented internally using a
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// visitor that is very similar to the one defined in this example.
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// Usually, we want to freeze the network, except for the top layers:
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visit_computational_layers(net.subnet().subnet(), visitor_weight_decay_multiplier(0));
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set_all_learning_rate_multipliers(net.subnet().subnet(), 0);
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// Alternatively, we can use the visit_layers_range to modify only a specific set of
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// layers:
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visit_computational_layers_range<0, 2>(net, visitor_weight_decay_multiplier(1));
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// Sometimes we might want to set the learning rate differently throughout the network.
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// Here we show how to use adjust the learning rate at the different ResNet50's
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// convolutional blocks:
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set_learning_rate_multipliers_range< 0, 2>(net, 1);
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set_learning_rate_multipliers_range< 2, 38>(net, 0.1);
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set_learning_rate_multipliers_range< 38, 107>(net, 0.01);
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set_learning_rate_multipliers_range<107, 154>(net, 0.001);
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set_learning_rate_multipliers_range<154, 193>(net, 0.0001);
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// Finally, we can check the results by printing the network. But before, if we
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// forward an image through the network, we will see tensors shape at every layer.
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matrix<rgb_pixel> image(224, 224);
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assign_all_pixels(image, rgb_pixel(0, 0, 0));
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std::vector<matrix<rgb_pixel>> minibatch(1, image);
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resizable_tensor input;
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net.to_tensor(minibatch.begin(), minibatch.end(), input);
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net.forward(input);
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cout << net << endl;
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cout << "input size=(" <<
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"num:" << input.num_samples() << ", " <<
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"k:" << input.k() << ", " <<
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"nr:" << input.nr() << ", "
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"nc:" << input.nc() << ")" << endl;
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// We can also print the number of parameters of the network:
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cout << "number of network parameters: " << count_parameters(net) << endl;
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// From this point on, we can fine-tune the new network using this pretrained backbone
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// on another task, such as the one showed in dnn_metric_learning_on_images_ex.cpp.
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return EXIT_SUCCESS;
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}
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catch (const serialization_error& e)
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{
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cout << e.what() << endl;
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cout << "You need to download a copy of the file resnet50_1000_imagenet_classifier.dnn" << endl;
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cout << "available at http://dlib.net/files/resnet50_1000_imagenet_classifier.dnn.bz2" << endl;
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cout << endl;
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return EXIT_FAILURE;
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}
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catch (const exception& e)
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{
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cout << e.what() << endl;
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return EXIT_FAILURE;
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}
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