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------------------------------------- --- Python interface of LIBLINEAR --- ------------------------------------- Table of Contents ================= - Introduction - Installation - Quick Start - Design Description - Data Structures - Utility Functions - Additional Information Introduction ============ Python (http://www.python.org/) is a programming language suitable for rapid development. This tool provides a simple Python interface to LIBLINEAR, a library for support vector machines (http://www.csie.ntu.edu.tw/~cjlin/liblinear). The interface is very easy to use as the usage is the same as that of LIBLINEAR. The interface is developed with the built-in Python library "ctypes." Installation ============ On Unix systems, type > make The interface needs only LIBLINEAR shared library, which is generated by the above command. We assume that the shared library is on the LIBLINEAR main directory or in the system path. For windows, the shared library liblinear.dll is ready in the directory `..\windows'. You can also copy it to the system directory (e.g., `C:\WINDOWS\system32\' for Windows XP). To regenerate the shared library, please follow the instruction of building windows binaries in LIBLINEAR README. Quick Start =========== There are two levels of usage. The high-level one uses utility functions in liblinearutil.py and the usage is the same as the LIBLINEAR MATLAB interface. >>> from liblinearutil import * # Read data in LIBSVM format >>> y, x = svm_read_problem('../heart_scale') >>> m = train(y[:200], x[:200], '-c 4') >>> p_label, p_acc, p_val = predict(y[200:], x[200:], m) # Construct problem in python format # Dense data >>> y, x = [1,-1], [[1,0,1], [-1,0,-1]] # Sparse data >>> y, x = [1,-1], [{1:1, 3:1}, {1:-1,3:-1}] >>> prob = problem(y, x) >>> param = parameter('-s 0 -c 4 -B 1') >>> m = train(prob, param) # Other utility functions >>> save_model('heart_scale.model', m) >>> m = load_model('heart_scale.model') >>> p_label, p_acc, p_val = predict(y, x, m, '-b 1') >>> ACC, MSE, SCC = evaluations(y, p_label) # Getting online help >>> help(train) The low-level use directly calls C interfaces imported by liblinear.py. Note that all arguments and return values are in ctypes format. You need to handle them carefully. >>> from liblinear import * >>> prob = problem([1,-1], [{1:1, 3:1}, {1:-1,3:-1}]) >>> param = parameter('-c 4') >>> m = liblinear.train(prob, param) # m is a ctype pointer to a model # Convert a Python-format instance to feature_nodearray, a ctypes structure >>> x0, max_idx = gen_feature_nodearray({1:1, 3:1}) >>> label = liblinear.predict(m, x0) Design Description ================== There are two files liblinear.py and liblinearutil.py, which respectively correspond to low-level and high-level use of the interface. In liblinear.py, we adopt the Python built-in library "ctypes," so that Python can directly access C structures and interface functions defined in linear.h. While advanced users can use structures/functions in liblinear.py, to avoid handling ctypes structures, in liblinearutil.py we provide some easy-to-use functions. The usage is similar to LIBLINEAR MATLAB interface. Data Structures =============== Three data structures derived from linear.h are node, problem, and parameter. They all contain fields with the same names in linear.h. Access these fields carefully because you directly use a C structure instead of a Python object. The following description introduces additional fields and methods. Before using the data structures, execute the following command to load the LIBLINEAR shared library: >>> from liblinear import * - class feature_node: Construct a feature_node. >>> node = feature_node(idx, val) idx: an integer indicates the feature index. val: a float indicates the feature value. Show the index and the value of a node. >>> print(node) - Function: gen_feature_nodearray(xi [,feature_max=None [,issparse=True]]) Generate a feature vector from a Python list/tuple or a dictionary: >>> xi, max_idx = gen_feature_nodearray({1:1, 3:1, 5:-2}) xi: the returned feature_nodearray (a ctypes structure) max_idx: the maximal feature index of xi issparse: if issparse == True, zero feature values are removed. The default value is True for the sparsity. feature_max: if feature_max is assigned, features with indices larger than feature_max are removed. - class problem: Construct a problem instance >>> prob = problem(y, x [,bias=-1]) y: a Python list/tuple of l labels (type must be int/double). x: a Python list/tuple of l data instances. Each element of x must be an instance of list/tuple/dictionary type. bias: if bias >= 0, instance x becomes [x; bias]; if < 0, no bias term added (default -1) You can also modify the bias value by >>> prob.set_bias(1) Note that if your x contains sparse data (i.e., dictionary), the internal ctypes data format is still sparse. - class parameter: Construct a parameter instance >>> param = parameter('training_options') If 'training_options' is empty, LIBLINEAR default values are applied. Set param to LIBLINEAR default values. >>> param.set_to_default_values() Parse a string of options. >>> param.parse_options('training_options') Show values of parameters. >>> print(param) - class model: There are two ways to obtain an instance of model: >>> model_ = train(y, x) >>> model_ = load_model('model_file_name') Note that the returned structure of interface functions liblinear.train and liblinear.load_model is a ctypes pointer of model, which is different from the model object returned by train and load_model in liblinearutil.py. We provide a function toPyModel for the conversion: >>> model_ptr = liblinear.train(prob, param) >>> model_ = toPyModel(model_ptr) If you obtain a model in a way other than the above approaches, handle it carefully to avoid memory leak or segmentation fault. Some interface functions to access LIBLINEAR models are wrapped as members of the class model: >>> nr_feature = model_.get_nr_feature() >>> nr_class = model_.get_nr_class() >>> class_labels = model_.get_labels() >>> is_prob_model = model_.is_probability_model() >>> is_regression_model = model_.is_regression_model() The decision function is W*x + b, where W is an nr_class-by-nr_feature matrix, and b is a vector of size nr_class. To access W_kj (i.e., coefficient for the k-th class and the j-th feature) and b_k (i.e., bias for the k-th class), use the following functions. >>> W_kj = model_.get_decfun_coef(feat_idx=j, label_idx=k) >>> b_k = model_.get_decfun_bias(label_idx=k) We also provide a function to extract w_k (i.e., the k-th row of W) and b_k directly as follows. >>> [w_k, b_k] = model_.get_decfun(label_idx=k) Note that w_k is a Python list of length nr_feature, which means that w_k[0] = W_k1. For regression models, W is just a vector of length nr_feature. Either set label_idx=0 or omit the label_idx parameter to access the coefficients. >>> W_j = model_.get_decfun_coef(feat_idx=j) >>> b = model_.get_decfun_bias() >>> [W, b] = model_.get_decfun() Note that in get_decfun_coef, get_decfun_bias, and get_decfun, feat_idx starts from 1, while label_idx starts from 0. If label_idx is not in the valid range (0 to nr_class-1), then a NaN will be returned; and if feat_idx is not in the valid range (1 to nr_feature), then a zero value will be returned. For regression models, label_idx is ignored. Utility Functions ================= To use utility functions, type >>> from liblinearutil import * The above command loads train() : train a linear model predict() : predict testing data svm_read_problem() : read the data from a LIBSVM-format file. load_model() : load a LIBLINEAR model. save_model() : save model to a file. evaluations() : evaluate prediction results. - Function: train There are three ways to call train() >>> model = train(y, x [, 'training_options']) >>> model = train(prob [, 'training_options']) >>> model = train(prob, param) y: a list/tuple of l training labels (type must be int/double). x: a list/tuple of l training instances. The feature vector of each training instance is an instance of list/tuple or dictionary. training_options: a string in the same form as that for LIBLINEAR command mode. prob: a problem instance generated by calling problem(y, x). param: a parameter instance generated by calling parameter('training_options') model: the returned model instance. See linear.h for details of this structure. If '-v' is specified, cross validation is conducted and the returned model is just a scalar: cross-validation accuracy for classification and mean-squared error for regression. If the '-C' option is specified, the best parameter C is found by cross validation. The returned model is a tuple of the best C and the corresponding cross-validation accuracy. The parameter selection utility is supported by only -s 0 and -s 2. To train the same data many times with different parameters, the second and the third ways should be faster.. Examples: >>> y, x = svm_read_problem('../heart_scale') >>> prob = problem(y, x) >>> param = parameter('-s 3 -c 5 -q') >>> m = train(y, x, '-c 5') >>> m = train(prob, '-w1 5 -c 5') >>> m = train(prob, param) >>> CV_ACC = train(y, x, '-v 3') >>> best_C, best_rate = train(y, x, '-C -s 0') >>> m = train(y, x, '-c {0} -s 0'.format(best_C)) # use the same solver: -s 0 - Function: predict To predict testing data with a model, use >>> p_labs, p_acc, p_vals = predict(y, x, model [,'predicting_options']) y: a list/tuple of l true labels (type must be int/double). It is used for calculating the accuracy. Use [] if true labels are unavailable. x: a list/tuple of l predicting instances. The feature vector of each predicting instance is an instance of list/tuple or dictionary. predicting_options: a string of predicting options in the same format as that of LIBLINEAR. model: a model instance. p_labels: a list of predicted labels p_acc: a tuple including accuracy (for classification), mean squared error, and squared correlation coefficient (for regression). p_vals: a list of decision values or probability estimates (if '-b 1' is specified). If k is the number of classes, for decision values, each element includes results of predicting k binary-class SVMs. If k = 2 and solver is not MCSVM_CS, only one decision value is returned. For probabilities, each element contains k values indicating the probability that the testing instance is in each class. Note that the order of classes here is the same as 'model.label' field in the model structure. Example: >>> m = train(y, x, '-c 5') >>> p_labels, p_acc, p_vals = predict(y, x, m) - Functions: svm_read_problem/load_model/save_model See the usage by examples: >>> y, x = svm_read_problem('data.txt') >>> m = load_model('model_file') >>> save_model('model_file', m) - Function: evaluations Calculate some evaluations using the true values (ty) and predicted values (pv): >>> (ACC, MSE, SCC) = evaluations(ty, pv) ty: a list of true values. pv: a list of predict values. ACC: accuracy. MSE: mean squared error. SCC: squared correlation coefficient. Additional Information ====================== This interface was written by Hsiang-Fu Yu from Department of Computer Science, National Taiwan University. If you find this tool useful, please cite LIBLINEAR as follows R.-E. Fan, K.-W. Chang, C.-J. Hsieh, X.-R. Wang, and C.-J. Lin. LIBLINEAR: A Library for Large Linear Classification, Journal of Machine Learning Research 9(2008), 1871-1874. Software available at http://www.csie.ntu.edu.tw/~cjlin/liblinear For any question, please contact Chih-Jen Lin <[email protected]>, or check the FAQ page: http://www.csie.ntu.edu.tw/~cjlin/liblinear/faq.html