mirror of https://github.com/davisking/dlib.git
325 lines
11 KiB
C++
325 lines
11 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 dlib machine learning tools for
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learning to solve the assignment problem.
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Many tasks in computer vision or natural language processing can be thought of
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as assignment problems. For example, in a computer vision application where
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you are trying to track objects moving around in video, you likely need to solve
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an association problem every time you get a new video frame. That is, each new
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frame will contain objects (e.g. people, cars, etc.) and you will want to
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determine which of these objects are actually things you have seen in previous
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frames.
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The assignment problem can be optimally solved using the well known Hungarian
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algorithm. However, this algorithm requires the user to supply some function
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which measures the "goodness" of an individual association. In many cases the
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best way to measure this goodness isn't obvious and therefore machine learning
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methods are used.
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The remainder of this example program will show you how to learn a goodness
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function which is optimal, in a certain sense, for use with the Hungarian
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algorithm. To do this, we will make a simple dataset of example associations
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and use them to train a supervised machine learning method.
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Finally, note that there is a whole example program dedicated to assignment learning
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problems where you are trying to make an object tracker. So if that is what you are
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interested in then read the learning_to_track_ex.cpp example program.
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*/
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#include <iostream>
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#include <dlib/svm_threaded.h>
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using namespace std;
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using namespace dlib;
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// ----------------------------------------------------------------------------------------
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/*
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In an association problem, we will talk about the "Left Hand Set" (LHS) and the
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"Right Hand Set" (RHS). The task will be to learn to map all elements of LHS to
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unique elements of RHS. If an element of LHS can't be mapped to a unique element of
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RHS for some reason (e.g. LHS is bigger than RHS) then it can also be mapped to the
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special -1 output, indicating no mapping to RHS.
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So the first step is to define the type of elements in each of these sets. In the
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code below we will use column vectors in both LHS and RHS. However, in general,
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they can each contain any type you like. LHS can even contain a different type
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than RHS.
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*/
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typedef dlib::matrix<double,0,1> column_vector;
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// This type represents a pair of LHS and RHS. That is, sample_type::first
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// contains a left hand set and sample_type::second contains a right hand set.
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typedef std::pair<std::vector<column_vector>, std::vector<column_vector> > sample_type;
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// This type will contain the association information between LHS and RHS. That is,
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// it will determine which elements of LHS map to which elements of RHS.
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typedef std::vector<long> label_type;
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// In this example, all our LHS and RHS elements will be 3-dimensional vectors.
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const unsigned long num_dims = 3;
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void make_data (
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std::vector<sample_type>& samples,
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std::vector<label_type>& labels
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);
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/*!
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ensures
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- This function creates a training dataset of 5 example associations.
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- #samples.size() == 5
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- #labels.size() == 5
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- for all valid i:
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- #samples[i].first == a left hand set
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- #samples[i].second == a right hand set
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- #labels[i] == a set of integers indicating how to map LHS to RHS. To be
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precise:
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- #samples[i].first.size() == #labels[i].size()
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- for all valid j:
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-1 <= #labels[i][j] < #samples[i].second.size()
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(A value of -1 indicates that #samples[i].first[j] isn't associated with anything.
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All other values indicate the associating element of #samples[i].second)
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- All elements of #labels[i] which are not equal to -1 are unique. That is,
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multiple elements of #samples[i].first can't associate to the same element
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in #samples[i].second.
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!*/
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// ----------------------------------------------------------------------------------------
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struct feature_extractor
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{
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/*!
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Recall that our task is to learn the "goodness of assignment" function for
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use with the Hungarian algorithm. The dlib tools assume this function
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can be written as:
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match_score(l,r) == dot(w, PSI(l,r))
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where l is an element of LHS, r is an element of RHS, w is a parameter vector,
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and PSI() is a user supplied feature extractor.
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This feature_extractor is where we implement PSI(). How you implement this
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is highly problem dependent.
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!*/
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// The type of feature vector returned from get_features(). This must be either
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// a dlib::matrix or a sparse vector.
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typedef column_vector feature_vector_type;
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// The types of elements in the LHS and RHS sets
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typedef column_vector lhs_element;
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typedef column_vector rhs_element;
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unsigned long num_features() const
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{
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// Return the dimensionality of feature vectors produced by get_features()
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return num_dims;
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}
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void get_features (
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const lhs_element& left,
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const rhs_element& right,
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feature_vector_type& feats
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) const
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/*!
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ensures
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- #feats == PSI(left,right)
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(i.e. This function computes a feature vector which, in some sense,
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captures information useful for deciding if matching left to right
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is "good").
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!*/
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{
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// Lets just use the squared difference between each vector as our features.
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// However, it should be emphasized that how to compute the features here is very
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// problem dependent.
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feats = squared(left - right);
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}
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};
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// We need to define serialize() and deserialize() for our feature extractor if we want
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// to be able to serialize and deserialize our learned models. In this case the
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// implementation is empty since our feature_extractor doesn't have any state. But you
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// might define more complex feature extractors which have state that needs to be saved.
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void serialize (const feature_extractor& , std::ostream& ) {}
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void deserialize (feature_extractor& , std::istream& ) {}
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// ----------------------------------------------------------------------------------------
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int main()
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{
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try
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{
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// Get a small bit of training data.
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std::vector<sample_type> samples;
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std::vector<label_type> labels;
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make_data(samples, labels);
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structural_assignment_trainer<feature_extractor> trainer;
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// This is the common SVM C parameter. Larger values encourage the
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// trainer to attempt to fit the data exactly but might overfit.
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// In general, you determine this parameter by cross-validation.
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trainer.set_c(10);
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// This trainer can use multiple CPU cores to speed up the training.
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// So set this to the number of available CPU cores.
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trainer.set_num_threads(4);
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// Do the training and save the results in assigner.
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assignment_function<feature_extractor> assigner = trainer.train(samples, labels);
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// Test the assigner on our data. The output will indicate that it makes the
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// correct associations on all samples.
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cout << "Test the learned assignment function: " << endl;
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for (unsigned long i = 0; i < samples.size(); ++i)
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{
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// Predict the assignments for the LHS and RHS in samples[i].
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std::vector<long> predicted_assignments = assigner(samples[i]);
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cout << "true labels: " << trans(mat(labels[i]));
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cout << "predicted labels: " << trans(mat(predicted_assignments)) << endl;
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}
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// We can also use this tool to compute the percentage of assignments predicted correctly.
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cout << "training accuracy: " << test_assignment_function(assigner, samples, labels) << endl;
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// Since testing on your training data is a really bad idea, we can also do 5-fold cross validation.
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// Happily, this also indicates that all associations were made correctly.
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randomize_samples(samples, labels);
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cout << "cv accuracy: " << cross_validate_assignment_trainer(trainer, samples, labels, 5) << endl;
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// Finally, the assigner can be serialized to disk just like most dlib objects.
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serialize("assigner.dat") << assigner;
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// recall from disk
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deserialize("assigner.dat") >> assigner;
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}
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catch (std::exception& e)
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{
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cout << "EXCEPTION THROWN" << endl;
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cout << e.what() << endl;
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}
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}
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// ----------------------------------------------------------------------------------------
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void make_data (
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std::vector<sample_type>& samples,
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std::vector<label_type>& labels
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)
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{
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// Make four different vectors. We will use them to make example assignments.
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column_vector A(num_dims), B(num_dims), C(num_dims), D(num_dims);
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A = 1,0,0;
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B = 0,1,0;
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C = 0,0,1;
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D = 0,1,1;
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std::vector<column_vector> lhs;
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std::vector<column_vector> rhs;
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label_type mapping;
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// In all the assignments to follow, we will only say an element of the LHS
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// matches an element of the RHS if the two are equal. So A matches with A,
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// B with B, etc. But never A with C, for example.
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// ------------------------
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lhs.resize(3);
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lhs[0] = A;
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lhs[1] = B;
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lhs[2] = C;
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rhs.resize(3);
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rhs[0] = B;
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rhs[1] = A;
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rhs[2] = C;
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mapping.resize(3);
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mapping[0] = 1; // lhs[0] matches rhs[1]
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mapping[1] = 0; // lhs[1] matches rhs[0]
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mapping[2] = 2; // lhs[2] matches rhs[2]
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samples.push_back(make_pair(lhs,rhs));
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labels.push_back(mapping);
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// ------------------------
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lhs[0] = C;
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lhs[1] = A;
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lhs[2] = B;
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rhs[0] = A;
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rhs[1] = B;
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rhs[2] = D;
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mapping[0] = -1; // The -1 indicates that lhs[0] doesn't match anything in rhs.
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mapping[1] = 0; // lhs[1] matches rhs[0]
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mapping[2] = 1; // lhs[2] matches rhs[1]
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samples.push_back(make_pair(lhs,rhs));
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labels.push_back(mapping);
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// ------------------------
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lhs[0] = A;
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lhs[1] = B;
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lhs[2] = C;
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rhs.resize(4);
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rhs[0] = C;
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rhs[1] = B;
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rhs[2] = A;
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rhs[3] = D;
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mapping[0] = 2;
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mapping[1] = 1;
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mapping[2] = 0;
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samples.push_back(make_pair(lhs,rhs));
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labels.push_back(mapping);
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// ------------------------
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lhs.resize(2);
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lhs[0] = B;
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lhs[1] = C;
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rhs.resize(3);
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rhs[0] = C;
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rhs[1] = A;
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rhs[2] = D;
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mapping.resize(2);
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mapping[0] = -1;
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mapping[1] = 0;
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samples.push_back(make_pair(lhs,rhs));
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labels.push_back(mapping);
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// ------------------------
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lhs.resize(3);
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lhs[0] = D;
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lhs[1] = B;
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lhs[2] = C;
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// rhs will be empty. So none of the items in lhs can match anything.
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rhs.resize(0);
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mapping.resize(3);
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mapping[0] = -1;
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mapping[1] = -1;
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mapping[2] = -1;
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samples.push_back(make_pair(lhs,rhs));
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labels.push_back(mapping);
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}
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