This is the Java version of LIBLINEAR.
The project site of the original C++
version is located at
http://www.csie.ntu.edu.tw/~cjlin/liblinear/
The upstream changelog can be found at http://www.csie.ntu.edu.tw/~cjlin/liblinear/log
The upstream GitHub project can be found at https://github.com/cjlin1/liblinear
Please be aware that the code would be written differently at various places, i.e.
- Java coding style,
- less static functions and state,
- smaller classes and methods,
if it would be a pure Java project.
However, I tried to stick as close as possible to the original C++ source code for the following reasons:
-
Maintainability: Patches for the original C++ version can often be applied easily
-
Probability of translation errors: Sticking to the original source code makes it less likely to introduce new bugs that are caused by porting to Java.
-
Code Reviews: It should be more easy to conduct code reviews since the sources can be compared to the original version.
Below follows a slightly modified version of the original README file. Please note that the README refers to the C++ version. As afore mentioned, the Java version is almost identical to use.
The three most important methods for programmatic usage that you might be interested in are:
Linear.train(…)
Linear.predict(…)
Linear.predictProbability(…)
LIBLINEAR is a simple package for solving large-scale regularized linear classification and regression. It currently supports
- L2-regularized logistic regression/L2-loss support vector classification/L1-loss support vector classification
- L1-regularized L2-loss support vector classification/L1-regularized logistic regression
- L2-regularized L2-loss support vector regression/L1-loss support vector regression. This document explains the usage of LIBLINEAR.
To get started, please read the Quick Start section first. For developers, please check the Library Usage section to learn how to integrate LIBLINEAR in your software.
- When to use LIBLINEAR but not LIBSVM
- Quick Start
train
Usagepredict
Usage- Examples
- Library Usage
- Additional Information
There are some large data for which with/without nonlinear mappings gives similar performances. Without using kernels, one can efficiently train a much larger set via linear classification/regression. These data usually have a large number of features. Document classification is an example.
Warning: While generally liblinear is very fast, its default solver may be slow under certain situations (e.g., data not scaled or C is large). See Appendix B of our SVM guide about how to handle such cases.
http://www.csie.ntu.edu.tw/~cjlin/papers/guide/guide.pdf
Warning: If you are a beginner and your data sets are not large, you should consider LIBSVM first.
LIBSVM page: http://www.csie.ntu.edu.tw/~cjlin/libsvm
See the section Installation for installing LIBLINEAR.
After installation, there are programs train
and predict
for
training and testing, respectively.
About the data format, please check the README file of LIBSVM. Note that feature index must start from 1 (but not 0).
A sample classification data included in this package is heart_scale
.
Type train heart_scale
, and the program will read the training
data and output the model file heart_scale.model
. If you have a test
set called heart_scale.t
, then type predict heart_scale.t heart_scale.model output
to see the prediction accuracy. The output
file contains the predicted class labels.
For more information about train
and predict
, see the sections
train
Usage and predict
Usage.
To obtain good performances, sometimes one needs to scale the
data. Please check the program svm-scale
of LIBSVM. For large and
sparse data, use -l 0
to keep the sparsity.
Usage: train [options] training_set_file [model_file]
options:
-s type : set type of solver (default 1)
for multi-class classification
0 -- L2-regularized logistic regression (primal)
1 -- L2-regularized L2-loss support vector classification (dual)
2 -- L2-regularized L2-loss support vector classification (primal)
3 -- L2-regularized L1-loss support vector classification (dual)
4 -- support vector classification by Crammer and Singer
5 -- L1-regularized L2-loss support vector classification
6 -- L1-regularized logistic regression
7 -- L2-regularized logistic regression (dual)
for regression
11 -- L2-regularized L2-loss support vector regression (primal)
12 -- L2-regularized L2-loss support vector regression (dual)
13 -- L2-regularized L1-loss support vector regression (dual)
-c cost : set the parameter C (default 1)
-p epsilon : set the epsilon in loss function of epsilon-SVR (default 0.1)
-e epsilon : set tolerance of termination criterion
-s 0 and 2
|f'(w)|_2 <= eps*min(pos,neg)/l*|f'(w0)|_2,
where f is the primal function and pos/neg are # of
positive/negative data (default 0.01)
-s 11
|f'(w)|_2 <= eps*|f'(w0)|_2 (default 0.001)
-s 1, 3, 4 and 7
Dual maximal violation <= eps; similar to libsvm (default 0.1)
-s 5 and 6
|f'(w)|_1 <= eps*min(pos,neg)/l*|f'(w0)|_1,
where f is the primal function (default 0.01)
-s 12 and 13\n"
|f'(alpha)|_1 <= eps |f'(alpha0)|,
where f is the dual function (default 0.1)
-B bias : if bias >= 0, instance x becomes [x; bias]; if < 0, no bias term added (default -1)
-wi weight: weights adjust the parameter C of different classes (see README for details)
-v n: n-fold cross validation mode
-C : find parameter C (only for -s 0 and 2)
-q : quiet mode (no outputs)
Option -v randomly splits the data into n parts and calculates cross validation accuracy on them.
Option -C conducts cross validation under different C values and finds the best one. This options is supported only by -s 0 and -s 2. If the solver is not specified, -s 2 is used.
Formulations:
For L2-regularized logistic regression (-s 0), we solve
min_w w^Tw/2 + C \sum log(1 + exp(-y_i w^Tx_i))
For L2-regularized L2-loss SVC dual (-s 1), we solve
min_alpha 0.5(alpha^T (Q + I/2/C) alpha) - e^T alpha
s.t. 0 <= alpha_i,
For L2-regularized L2-loss SVC (-s 2), we solve
min_w w^Tw/2 + C \sum max(0, 1- y_i w^Tx_i)^2
For L2-regularized L1-loss SVC dual (-s 3), we solve
min_alpha 0.5(alpha^T Q alpha) - e^T alpha
s.t. 0 <= alpha_i <= C,
For L1-regularized L2-loss SVC (-s 5), we solve
min_w \sum |w_j| + C \sum max(0, 1- y_i w^Tx_i)^2
For L1-regularized logistic regression (-s 6), we solve
min_w \sum |w_j| + C \sum log(1 + exp(-y_i w^Tx_i))
For L2-regularized logistic regression (-s 7), we solve
min_alpha 0.5(alpha^T Q alpha) + \sum alpha_i*log(alpha_i) + \sum (C-alpha_i)*log(C-alpha_i) - a constant
s.t. 0 <= alpha_i <= C,
where
Q is a matrix with Q_ij = y_i y_j x_i^T x_j.
For L2-regularized L2-loss SVR (-s 11), we solve
min_w w^Tw/2 + C \sum max(0, |y_i-w^Tx_i|-epsilon)^2
For L2-regularized L2-loss SVR dual (-s 12), we solve
min_beta 0.5(beta^T (Q + lambda I/2/C) beta) - y^T beta + \sum |beta_i|
For L2-regularized L1-loss SVR dual (-s 13), we solve
min_beta 0.5(beta^T Q beta) - y^T beta + \sum |beta_i|
s.t. -C <= beta_i <= C,
where
Q is a matrix with Q_ij = x_i^T x_j.
If bias >= 0
, w becomes [w; w_{n+1}]
and x becomes [x; bias]
.
The primal-dual relationship implies that -s 1 and -s 2 give the same model, -s 0 and -s 7 give the same, and -s 11 and -s 12 give the same.
We implement 1-vs-the rest multi-class strategy for classification.
In training i
vs. non_i
, their C parameters are (weight from -wi)*C
and C, respectively. If there are only two classes, we train only one
model. Thus weight1*C
vs. weight2*C
is used. See examples below.
We also implement multi-class SVM by Crammer and Singer (-s 4):
min_{w_m, \xi_i} 0.5 \sum_m ||w_m||^2 + C \sum_i \xi_i
s.t. w^T_{y_i} x_i - w^T_m x_i >= \e^m_i - \xi_i \forall m,i
where e^m_i = 0 if y_i = m,
e^m_i = 1 if y_i != m,
Here we solve the dual problem:
min_{\alpha} 0.5 \sum_m ||w_m(\alpha)||^2 + \sum_i \sum_m e^m_i alpha^m_i
s.t. \alpha^m_i <= C^m_i \forall m,i , \sum_m \alpha^m_i=0 \forall i
where w_m(\alpha) = \sum_i \alpha^m_i x_i,
and C^m_i = C if m = y_i,
C^m_i = 0 if m != y_i.
Usage: predict [options] test_file model_file output_file
options:
-b probability_estimates: whether to output probability estimates, 0 or 1 (default 0); currently for logistic regression only
-q : quiet mode (no outputs)
Note that -b is only needed in the prediction phase. This is different from the setting of LIBSVM.
> train data_file
Train linear SVM with L2-loss function.
> train -s 0 data_file
Train a logistic regression model.
> train -v 5 -e 0.001 data_file
Do five-fold cross-validation using L2-loss SVM. Use a smaller stopping tolerance 0.001 than the default 0.1 if you want more accurate solutions.
> train -C data_file
Conduct cross validation many times by L2-loss SVM and find the parameter C which achieves the best cross validation accuracy.
> train -C -s 0 -v 3 -c 0.5 -e 0.0001 data_file
For parameter selection by -C, users can specify other solvers (currently -s 0 and -s 2 are supported) and different number of CV folds. Further, users can use the -c option to specify the smallest C value of the search range. This setting is useful when users want to rerun the parameter selection procedure from a specified C under a different setting, such as a stricter stopping tolerance -e 0.0001 in the above example.
> train -c 10 -w1 2 -w2 5 -w3 2 four_class_data_file
Train four classifiers: positive negative Cp Cn class 1 class 2,3,4. 20 10 class 2 class 1,3,4. 50 10 class 3 class 1,2,4. 20 10 class 4 class 1,2,3. 10 10
> train -c 10 -w3 1 -w2 5 two_class_data_file
If there are only two classes, we train ONE model. The C values for the two classes are 10 and 50.
> predict -b 1 test_file data_file.model output_file
Output probability estimates (for logistic regression only).
These functions and structures are declared in the header file linear.h
.
You can see train.c
and predict.c
for examples showing how to use them.
We define LIBLINEAR_VERSION and declare extern int liblinear_version;
in linear.h, so you can check the version number.
-
Function:
model* train(const struct problem *prob, const struct parameter *param);
This function constructs and returns a linear classification or regression model according to the given training data and parameters.
struct problem
describes the problem:struct problem { int l, n; int *y; struct feature_node **x; double bias; };
where
l
is the number of training data. If bias >= 0, we assume that one additional feature is added to the end of each data instance.n
is the number of feature (including the bias feature if bias >= 0).y
is an array containing the target values. (integers in classification, real numbers in regression) Andx
is an array of pointers, each of which points to a sparse representation (array of feature_node) of one training vector.For example, if we have the following training data:
LABEL ATTR1 ATTR2 ATTR3 ATTR4 ATTR5 ----- ----- ----- ----- ----- ----- 1 0 0.1 0.2 0 0 2 0 0.1 0.3 -1.2 0 1 0.4 0 0 0 0 2 0 0.1 0 1.4 0.5 3 -0.1 -0.2 0.1 1.1 0.1
and bias = 1, then the components of problem are:
l = 5 n = 6 y -> 1 2 1 2 3 x -> [ ] -> (2,0.1) (3,0.2) (6,1) (-1,?) [ ] -> (2,0.1) (3,0.3) (4,-1.2) (6,1) (-1,?) [ ] -> (1,0.4) (6,1) (-1,?) [ ] -> (2,0.1) (4,1.4) (5,0.5) (6,1) (-1,?) [ ] -> (1,-0.1) (2,-0.2) (3,0.1) (4,1.1) (5,0.1) (6,1) (-1,?)
struct parameter
describes the parameters of a linear classification or regression model:struct parameter { int solver_type; /* these are for training only */ double eps; /* stopping criteria */ double C; int nr_weight; int *weight_label; double* weight; double p; };
solver_type can be one of L2R_LR, L2R_L2LOSS_SVC_DUAL, L2R_L2LOSS_SVC, L2R_L1LOSS_SVC_DUAL, MCSVM_CS, L1R_L2LOSS_SVC, L1R_LR, L2R_LR_DUAL, L2R_L2LOSS_SVR, L2R_L2LOSS_SVR_DUAL, L2R_L1LOSS_SVR_DUAL. for classification
L2R_LR
L2-regularized logistic regression (primal)L2R_L2LOSS_SVC_DUAL
L2-regularized L2-loss support vector classification (dual)L2R_L2LOSS_SVC
L2-regularized L2-loss support vector classification (primal)L2R_L1LOSS_SVC_DUAL
L2-regularized L1-loss support vector classification (dual)MCSVM_CS
support vector classification by Crammer and SingerL1R_L2LOSS_SVC
L1-regularized L2-loss support vector classificationL1R_LR
L1-regularized logistic regressionL2R_LR_DUAL
L2-regularized logistic regression (dual) for regressionL2R_L2LOSS_SVR
L2-regularized L2-loss support vector regression (primal)L2R_L2LOSS_SVR_DUAL
L2-regularized L2-loss support vector regression (dual)L2R_L1LOSS_SVR_DUAL
L2-regularized L1-loss support vector regression (dual)
C is the cost of constraints violation. p is the sensitiveness of loss of support vector regression. eps is the stopping criterion.
nr_weight, weight_label, and weight are used to change the penalty for some classes (If the weight for a class is not changed, it is set to 1). This is useful for training classifier using unbalanced input data or with asymmetric misclassification cost.
nr_weight is the number of elements in the array weight_label and weight. Each weight[i] corresponds to weight_label[i], meaning that the penalty of class weight_label[i] is scaled by a factor of weight[i].
If you do not want to change penalty for any of the classes, just set nr_weight to 0.
NOTE To avoid wrong parameters, check_parameter() should be called before train().
struct model stores the model obtained from the training procedure:
struct model { struct parameter param; int nr_class; /* number of classes */ int nr_feature; double *w; int *label; /* label of each class */ double bias; };
param describes the parameters used to obtain the model.
nr_class and nr_feature are the number of classes and features, respectively. nr_class = 2 for regression.
The array w gives feature weights; its size is nr_feature*nr_class but is nr_feature if nr_class = 2. We use one against the rest for multi-class classification, so each feature index corresponds to nr_class weight values. Weights are organized in the following way
+------------------+------------------+------------+ | nr_class weights | nr_class weights | ... | for 1st feature | for 2nd feature | +------------------+------------------+------------+
If bias >= 0, x becomes [x; bias]. The number of features is increased by one, so w is a (nr_feature+1)*nr_class array. The value of bias is stored in the variable bias.
The array label stores class labels.
-
Function:
void cross_validation(const problem *prob, const parameter *param, int nr_fold, double *target);
This function conducts cross validation. Data are separated to nr_fold folds. Under given parameters, sequentially each fold is validated using the model from training the remaining. Predicted labels in the validation process are stored in the array called target.
The format of prob is same as that for train().
-
Function:
void find_parameter_C(const struct problem *prob, const struct parameter *param, int nr_fold, double start_C, double max_C, double *best_C, double *best_rate);
This function is similar to cross_validation. However, instead of conducting cross validation under a specified parameter C, it conducts cross validation many times under parameters C = start_C, 2start_C, 4start_C, 8*start_C, ..., and finds the best one with the highest cross validation accuracy.
If start_C <= 0, then this procedure calculates a small enough C for prob as the start_C. The procedure stops when the models of all folds become stable or C reaches max_C. The best C and the corresponding accuracy are assigned to *best_C and *best_rate, respectively.
-
Function:
double predict(const model *model_, const feature_node *x);
For a classification model, the predicted class for x is returned. For a regression model, the function value of x calculated using the model is returned.
-
Function:
double predict_values(const struct model *model_, const struct feature_node *x, double* dec_values);
This function gives nr_w decision values in the array dec_values. nr_w=1 if regression is applied or the number of classes is two. An exception is multi-class SVM by Crammer and Singer (-s 4), where nr_w = 2 if there are two classes. For all other situations, nr_w is the number of classes.
We implement one-vs-the rest multi-class strategy (-s 0,1,2,3,5,6,7) and multi-class SVM by Crammer and Singer (-s 4) for multi-class SVM. The class with the highest decision value is returned.
-
Function:
double predict_probability(const struct model *model_, const struct feature_node *x, double* prob_estimates);
This function gives nr_class probability estimates in the array prob_estimates. nr_class can be obtained from the function get_nr_class. The class with the highest probability is returned. Currently, we support only the probability outputs of logistic regression.
-
Function:
int get_nr_feature(const model *model_);
The function gives the number of attributes of the model.
-
Function:
int get_nr_class(const model *model_);
The function gives the number of classes of the model. For a regression model, 2 is returned.
-
Function:
void get_labels(const model *model_, int* label);
This function outputs the name of labels into an array called label. For a regression model, label is unchanged.
-
Function:
double get_decfun_coef(const struct model *model_, int feat_idx, int label_idx);
This function gives the coefficient for the feature with feature index = feat_idx and the class with label index = label_idx. Note that feat_idx starts from 1, while label_idx starts from 0. If feat_idx is not in the valid range (1 to nr_feature), then a zero value will be returned. For classification models, if label_idx is not in the valid range (0 to nr_class-1), then a zero value will be returned; for regression models, label_idx is ignored.
-
Function:
double get_decfun_bias(const struct model *model_, int label_idx);
This function gives the bias term corresponding to the class with the label_idx. For classification models, if label_idx is not in a valid range (0 to nr_class-1), then a zero value will be returned; for regression models, label_idx is ignored.
-
Function:
const char *check_parameter(const struct problem *prob, const struct parameter *param);
This function checks whether the parameters are within the feasible range of the problem. This function should be called before calling train() and cross_validation(). It returns NULL if the parameters are feasible, otherwise an error message is returned.
-
Function:
int check_probability_model(const struct model *model);
This function returns 1 if the model supports probability output; otherwise, it returns 0.
-
Function:
int check_regression_model(const struct model *model);
This function returns 1 if the model is a regression model; otherwise it returns 0.
-
Function:
int save_model(const char *model_file_name, const struct model *model_);
This function saves a model to a file; returns 0 on success, or -1 if an error occurs.
-
Function:
struct model *load_model(const char *model_file_name);
This function returns a pointer to the model read from the file, or a null pointer if the model could not be loaded.
-
Function:
void free_model_content(struct model *model_ptr);
This function frees the memory used by the entries in a model structure.
-
Function:
void free_and_destroy_model(struct model **model_ptr_ptr);
This function frees the memory used by a model and destroys the model structure.
-
Function:
void destroy_param(struct parameter *param);
This function frees the memory used by a parameter set.
-
Function:
void set_print_string_function(void (*print_func)(const char *));
Users can specify their output format by a function. Use set_print_string_function(NULL); for default printing to stdout.
If you find LIBLINEAR helpful, please cite it as
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 questions and comments, please send your email to [email protected]