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Fleshed out example program.
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# The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
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#
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#
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# You need to compile the dlib python interface before you can use this
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# file. To do this, run compile_dlib_python_module.bat. You also need to
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# have the boost-python library installed. On Ubuntu, this can be done easily by running
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# the command: sudo apt-get install libboost-python-dev
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# This example program shows how to use the dlib sequence segmentation tools from within a
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# python program. In particular, we will create a simple training dataset, learn a
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# sequence segmentation model, and then test it on some sequences.
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#
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# COMPILING THE DLIB PYTHON INTERFACE
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# You need to compile the dlib python interface before you can use this file. To do
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# this, run compile_dlib_python_module.bat. This should work on any operating system so
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# long as you have CMake and boost-python installed. On Ubuntu, this can be done easily
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# by running the command: sudo apt-get install libboost-python-dev cmake
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# asfd
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import dlib
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# In a sequence segmentation task we are given a sequence of objects (e.g. words in a
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# sentence) and we are supposed to detect certain subsequences (e.g. named entities). In
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# the code below we create some very simple sequence/segmentation training pairs. In
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# particular, each element of a sequence is represented by a vector which describes
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# important properties of the element. The idea is to use vectors that contain information
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# useful for detecting whatever kind of subsequences you are interested in detecting.
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# To keep this example simple we will use very simple vectors. Specifically, each vector
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# is 2D and is either the vector [0 1] or [1 0]. Moreover, we will say that the
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# subsequences we want to detect are any runs of the [0 1] vector. Note that the code
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# works with both dense and sparse vectors. The following if statement constructs either
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# kind depending on the value in use_sparse_vects.
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use_sparse_vects = False
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if use_sparse_vects:
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samples = dlib.sparse_vectorss()
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else:
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samples = dlib.vectorss()
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segments = dlib.rangess()
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if use_sparse_vects:
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training_sequences = dlib.sparse_vectorss()
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inside = dlib.sparse_vector()
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outside = dlib.sparse_vector()
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# Add index/value pairs to each sparse vector. Any index not mentioned in a sparse
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# vector is implicitly associated with a value of zero.
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inside.append(dlib.pair(0,1))
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outside.append(dlib.pair(1,1))
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else:
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training_sequences = dlib.vectorss()
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inside = dlib.vector([0, 1])
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outside = dlib.vector([1, 0])
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samples.resize(2)
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# Here we make our training sequences and their annotated subsegments. We create two
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# training sequences.
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segments = dlib.rangess()
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training_sequences.resize(2)
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segments.resize(2)
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samples[0].append(outside)
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samples[0].append(outside)
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samples[0].append(inside)
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samples[0].append(inside)
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samples[0].append(inside)
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samples[0].append(outside)
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samples[0].append(outside)
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samples[0].append(outside)
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# training_sequences[0] starts out empty and we append vectors onto it. Note that we wish
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# to detect the subsequence of "inside" vectors within the sequence. So the output should
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# be the range (2,5). Note that this is a "half open" range meaning that it starts with
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# the element with index 2 and ends just before the element with index 5.
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training_sequences[0].append(outside) # index 0
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training_sequences[0].append(outside) # index 1
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training_sequences[0].append(inside) # index 2
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training_sequences[0].append(inside) # index 3
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training_sequences[0].append(inside) # index 4
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training_sequences[0].append(outside) # index 5
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training_sequences[0].append(outside) # index 6
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training_sequences[0].append(outside) # index 7
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segments[0].append(dlib.range(2,5))
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samples[1].append(outside)
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samples[1].append(outside)
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samples[1].append(inside)
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samples[1].append(inside)
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samples[1].append(inside)
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samples[1].append(inside)
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samples[1].append(outside)
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samples[1].append(outside)
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# Add another training sequence
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training_sequences[1].append(outside) # index 0
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training_sequences[1].append(outside) # index 1
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training_sequences[1].append(inside) # index 2
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training_sequences[1].append(inside) # index 3
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training_sequences[1].append(inside) # index 4
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training_sequences[1].append(inside) # index 5
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training_sequences[1].append(outside) # index 6
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training_sequences[1].append(outside) # index 7
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segments[1].append(dlib.range(2,6))
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# Now that we have a simple training set we can train a sequence segmenter. However, the
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# sequence segmentation trainer has some optional parameters we can set. These parameters
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# determine properties of the segmentation model we will learn. See the dlib documentation
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# for the sequence_segmenter object for a full discussion of their meanings.
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params = dlib.segmenter_params()
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#params.be_verbose = True
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params.window_size = 1
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params.use_high_order_features = False
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params.use_BIO_model = True
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params.C = 1
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print "params:", params
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df = dlib.train_sequence_segmenter(samples, segments, params)
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# Train a model
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model = dlib.train_sequence_segmenter(training_sequences, segments, params)
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print len(df.segment_sequence(samples[0]))
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print df.segment_sequence(samples[0])[0]
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# A segmenter model takes a sequence of vectors and returns an array of detected ranges.
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# So for example, we can give it the first training sequence and it will predict the
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# locations of the subsequences. This statement will correctly print 2,5.
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print model.segment_sequence(training_sequences[0])[0]
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# We can also measure the accuracy of a model relative to some labeled data. This
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# statement prints the precision, recall, and F1-score of the model relative to the data in
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# training_sequences/segments.
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print "Test on training data:", dlib.test_sequence_segmenter(model, training_sequences, segments)
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# We can also do n-fold cross-validation and print the resulting precision, recall, and
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# F1-score.
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num_folds = 2
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print "cross validation:", dlib.cross_validate_sequence_segmenter(training_sequences, segments, num_folds, params)
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print df.weights
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#res = dlib.test_sequence_segmenter(df, samples, segments)
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res = dlib.cross_validate_sequence_segmenter(samples, segments, 2, params)
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print res
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