之前学习了SVM的原理(见http://www.cnblogs.com/bentu*ng/p/6444249.html),以及SMO算法的理论基础(见http://www.cnblogs.com/bentu*ng/p/6444516.html)。最近又学习了SVM的实现:LibSVM(版本为3.22),在这里总结一下。
1. LibSVM整体框架
Training: parse_command_line
从命令行读入需要设置的参数,并初始化各参数
read_problem
读入训练数据
svm_check_parameter
检查参数和训练数据是否符合规定的格式
do_cross_validation
svm_cross_validation
对训练数据进行均匀划分,使得同一个类别的数据均匀分布在各个fold中
最终得到的数组中,相同fold的数据的索引放在连续内存空间数组中
Cross Validation(k fold)
svm_train(使用k-1个fold的数据做训练)
svm_predict(使用剩下的1个fold的数据做预测)
得到每个样本在Cross Validation中的预测类别
得出Cross Validation的准确率
svm_train
classification
svm_group_classes
对训练数据按类别进行分组重排,相同类别的数据的索引放在连续内存空间数组中
得到类别总数:nr_class,每个类别的标识:label,每个类别的样本数:count,每个类别在重排数组中的起始位置:start,重排后的索引数组:perm(每个元素的值代表其在原始数组中的索引)
train k*(k-1)/2 models
新建1个训练数据子集sub_prob,并使用两个类别的训练数据进行填充
svm_train_one //根据svm_type的不同,使用不同的方式进行单次模型训练
solve_c_svc //针对C-SVC这一类型进行模型训练
新建1个Solver类对象s
s.Solve //使用SMO算法求解对偶问题(二次优化问题)
初始化拉格朗日乘子状态向量(是否在边界上)
初始化需要参与迭代优化计算的拉格朗日乘子集合
初始化梯度G,以及为了重建梯度时候节省计算开销而维护的中间变量G_bar
迭代优化
do_shrinking(每间隔若干次迭代进行一次shrinking)
找出m(a)和M(a)
reconstruct_gradient(如果满足停止条件,进行梯度重建)
因为有时候shrinking策略太过aggressive,所以当对shrinking之后的部分变量的优化问题迭代优化到第一次满足停止条件时,便可以对梯度进行重建
接下来的shrinking过程便可以建立在更精确的梯度值上
be_shrunk
判断该alpha是否被shrinking(不再参与后续迭代优化)
swap_index
交换两个变量的位置,从而使得参与迭代优化的变量(即没有被shrinking的变量)始终保持在变量数组的最前面的连续位置上
select_working_set(选择工作集)
对工作集的alpha进行更新
更新梯度G,拉格朗日乘子状态向量,及中间变量G_bar
计算b
填充alpha数组和SolutionInfo对象si并返回
返回alpha数组和SolutionInfo对象si
输出decision_function对象(包含alpha数组和b)
修改nonzero数组,将alpha大于0的对应位置改为true
填充svm_model对象model(包含nr_class,label数组,b数组,probA&probB数组,nSV数组,l,SV二维数组,sv_indices数组,sv_coef二维数组)并返回 //sv_coef二维数组内元素的放置方式很特别
svm_save_model
保存模型到制定文件中 Prediction: svm_predict
svm_predict_values
Kernel.k_function //计算预测样本与Support Vectors的Kernel值
用k(k-1)/2个分类器对预测样本进行预测,得出k(k-1)/2个预测类别
使用投票策略,选择预测数最多的那个类别作为最终的预测类别
返回预测类别
2. 各参数文件
public class svm_node implements java.io.Serializable
{
public int index;
public double value;
}
用于存储单个向量中的单个特征。index是该特征的索引,value是该特征的值。这样设计的好处是,可以节省存储空间,提高计算速度。
public class svm_problem implements java.io.Serializable
{
public int l;
public double[] y;
public svm_node[][] x;
}
用于存储本次运算的所有样本(数据集),及其所属类别。
public class svm_parameter implements Cloneable,java.io.Serializable
{
/* svm_type */
public static final int C_SVC = 0;
public static final int NU_SVC = 1;
public static final int ONE_CLASS = 2;
public static final int EPSILON_SVR = 3;
public static final int NU_SVR = 4; /* kernel_type */
public static final int LINEAR = 0;
public static final int POLY = 1;
public static final int RBF = 2;
public static final int SIGMOID = 3;
public static final int PRECOMPUTED = 4; public int svm_type;
public int kernel_type;
public int degree; // for poly
public double gamma; // for poly/rbf/sigmoid
public double coef0; // for poly/sigmoid // these are for training only
public double cache_size; // in MB
public double eps; // stopping criteria
public double C; // for C_SVC, EPSILON_SVR and NU_SVR
public int nr_weight; // for C_SVC
public int[] weight_label; // for C_SVC
public double[] weight; // for C_SVC
public double nu; // for NU_SVC, ONE_CLASS, and NU_SVR
public double p; // for EPSILON_SVR
public int shrinking; // use the shrinking heuristics
public int probability; // do probability estimates public Object clone()
{
try
{
return super.clone();
} catch (CloneNotSupportedException e)
{
return null;
}
} }
用于存储模型训练所需设置的参数。
public class svm_model implements java.io.Serializable
{
public svm_parameter param; // parameter
public int nr_class; // number of classes, = 2 in regression/one class svm
public int l; // total #SV
public svm_node[][] SV; // SVs (SV[l])
public double[][] sv_coef; // coefficients for SVs in decision functions (sv_coef[k-1][l])
public double[] rho; // constants in decision functions (rho[k*(k-1)/2])
public double[] probA; // pariwise probability information
public double[] probB;
public int[] sv_indices; // sv_indices[0,...,nSV-1] are values in [1,...,num_traning_data] to indicate SVs in the training set // for classification only public int[] label; // label of each class (label[k])
public int[] nSV; // number of SVs for each class (nSV[k])
// nSV[0] + nSV[1] + ... + nSV[k-1] = l
};
用于存储训练得到的模型,当然原来的训练参数也必须保留。
3. Cache类
Cache类主要负责运算所涉及的内存的管理,包括申请和释放等。
private final int l;
private long size;
private final class head_t
{
head_t prev, next; // a cicular list
float[] data;
int len; // data[0,len) is cached in this entry
}
private final head_t[] head;
private head_t lru_head;
类成员变量。包括:
l:样本总数。
size:指定的全部内存总量。
head_t:单块申请到的内存用class head_t来记录所申请内存,并记录长度。而且通过双向的指针,形成链表,增加寻址的速度。记录所有申请到的内存,一方面便于释放内存,另外方便在内存不够时适当释放一部分已经申请到的内存。
head:类似于变量指针,该指针用来记录程序所申请的内存。
lru_head:双向链表的头。
Cache(int l_, long size_)
{
l = l_;
size = size_;
head = new head_t[l];
for(int i=0;i<l;i++) head[i] = new head_t();
size /= 4;
size -= l * (16/4); // sizeof(head_t) == 16
size = Math.max(size, 2* (long) l); // cache must be large enough for two columns
lru_head = new head_t();
lru_head.next = lru_head.prev = lru_head;
}
构造函数。该函数根据样本数L,申请L 个head_t 的空间。Lru_head 因为尚没有head_t 中申请到内存,故双向链表指向自己。至于size 的处理,先将原来的byte 数目转化为float 的数目,然后扣除L 个head_t 的内存数目。
private void lru_delete(head_t h)
{
// delete from current location
h.prev.next = h.next;
h.next.prev = h.prev;
}
从双向链表中删除某个元素的链接,不删除、不释放该元素所涉及的内存。一般是删除当前所指向的元素。
private void lru_insert(head_t h)
{
// insert to last position
h.next = lru_head;
h.prev = lru_head.prev;
h.prev.next = h;
h.next.prev = h;
}
在链表后面插入一个新的节点。
// request data [0,len)
// return some position p where [p,len) need to be filled
// (p >= len if nothing needs to be filled)
// java: simulate pointer using single-element array
int get_data(int index, float[][] data, int len)
{
head_t h = head[index];
if(h.len > 0) lru_delete(h);
int more = len - h.len; if(more > 0)
{
// free old space
while(size < more)
{
head_t old = lru_head.next;
lru_delete(old);
size += old.len;
old.data = null;
old.len = 0;
} // allocate new space
float[] new_data = new float[len];
if(h.data != null) System.arraycopy(h.data,0,new_data,0,h.len);
h.data = new_data;
size -= more;
do {int tmp=h.len; h.len=len; len=tmp;} while(false);
} lru_insert(h);
data[0] = h.data;
return len;
}
该函数保证head_t[index]中至少有len 个float 的内存,并且将可以使用的内存块的指针放在 data 指针中。返回值为申请到的内存。函数首先将head_t[index]从链表中断开,如果head_t[index]原来没有分配内存,则跳过断开这步。计算当前head_t[index]已经申请到的内存,如果不够,释放部分内存,等内存足够后,重新分配内存。重新使head_t[index]进入双向链表。返回值不为申请到的内存的长度,为head_t[index]原来的数据长度h.len。
调用该函数后,程序会计算![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl5TlRFMU5qWTJOaTB4TmpVeE9USTNOVEU0TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
的值,并将其填入 data 所指向的内存区域,如果下次index 不变,正常情况下,不用重新计算该区域的值。若index 不变,则get_data()返回值len 与本次传入的len 一致,从get_Q( )中可以看到,程序不会重新计算。从而提高运算速度。
void swap_index(int i, int j)
{
if(i==j) return; if(head[i].len > 0) lru_delete(head[i]);
if(head[j].len > 0) lru_delete(head[j]);
do {float[] tmp=head[i].data; head[i].data=head[j].data; head[j].data=tmp;} while(false);
do {int tmp=head[i].len; head[i].len=head[j].len; head[j].len=tmp;} while(false);
if(head[i].len > 0) lru_insert(head[i]);
if(head[j].len > 0) lru_insert(head[j]); if(i>j) do {int tmp=i; i=j; j=tmp;} while(false);
for(head_t h = lru_head.next; h!=lru_head; h=h.next)
{
if(h.len > i)
{
if(h.len > j)
do {float tmp=h.data[i]; h.data[i]=h.data[j]; h.data[j]=tmp;} while(false);
else
{
// give up
lru_delete(h);
size += h.len;
h.data = null;
h.len = 0;
}
}
}
}
交换head_t[i] 和head_t[j]的内容,先从双向链表中断开,交换后重新进入双向链表中。然后对于每个head_t[index]中的值,交换其第 i 位和第 j 位的值。这两步是为了在Kernel 矩阵中在两个维度上都进行一次交换。
4. Kernel类
Kernel类是用来进行计算Kernel evaluation矩阵的。
//
// Kernel evaluation
//
// the static method k_function is for doing single kernel evaluation
// the constructor of Kernel prepares to calculate the l*l kernel matrix
// the member function get_Q is for getting one column from the Q Matrix
//
abstract class QMatrix {
abstract float[] get_Q(int column, int len);
abstract double[] get_QD();
abstract void swap_index(int i, int j);
};
Kernel的父类,抽象类。
abstract class Kernel extends QMatrix {
private svm_node[][] x;
private final double[] x_square;
// svm_parameter
private final int kernel_type;
private final int degree;
private final double gamma;
private final double coef0;
abstract float[] get_Q(int column, int len);
abstract double[] get_QD();
Kernel类的成员变量。
Kernel(int l, svm_node[][] x_, svm_parameter param)
{
this.kernel_type = param.kernel_type;
this.degree = param.degree;
this.gamma = param.gamma;
this.coef0 = param.coef0; x = (svm_node[][])x_.clone(); if(kernel_type == svm_parameter.RBF)
{
x_square = new double[l];
for(int i=0;i<l;i++)
x_square[i] = dot(x[i],x[i]);
}
else x_square = null;
}
构造函数。初始化类中的部分常量、指定核函数、克隆样本数据(每次数据传入时通过克隆函数来实现,完全重新分配内存)。如果使用RBF 核函数,则计算x_sqare[i]。
double kernel_function(int i, int j)
{
switch(kernel_type)
{
case svm_parameter.LINEAR:
return dot(x[i],x[j]);
case svm_parameter.POLY:
return powi(gamma*dot(x[i],x[j])+coef0,degree);
case svm_parameter.RBF:
return Math.exp(-gamma*(x_square[i]+x_square[j]-2*dot(x[i],x[j])));
case svm_parameter.SIGMOID:
return Math.tanh(gamma*dot(x[i],x[j])+coef0);
case svm_parameter.PRECOMPUTED:
return x[i][(int)(x[j][0].value)].value;
default:
return 0; // java
}
}
对Kernel类的对象中包含的任意2个样本求kernel evaluation。
static double k_function(svm_node[] x, svm_node[] y,
svm_parameter param)
{
switch(param.kernel_type)
{
case svm_parameter.LINEAR:
return dot(x,y);
case svm_parameter.POLY:
return powi(param.gamma*dot(x,y)+param.coef0,param.degree);
case svm_parameter.RBF:
{
double sum = 0;
int xlen = x.length;
int ylen = y.length;
int i = 0;
int j = 0;
while(i < xlen && j < ylen)
{
if(x[i].index == y[j].index)
{
double d = x[i++].value - y[j++].value;
sum += d*d;
}
else if(x[i].index > y[j].index)
{
sum += y[j].value * y[j].value;
++j;
}
else
{
sum += x[i].value * x[i].value;
++i;
}
} while(i < xlen)
{
sum += x[i].value * x[i].value;
++i;
} while(j < ylen)
{
sum += y[j].value * y[j].value;
++j;
} return Math.exp(-param.gamma*sum);
}
case svm_parameter.SIGMOID:
return Math.tanh(param.gamma*dot(x,y)+param.coef0);
case svm_parameter.PRECOMPUTED:
return x[(int)(y[0].value)].value;
default:
return 0; // java
}
}
静态方法,对参数传入的任意2个样本求kernel evaluation。主要应用在predict过程中。
//
// Q matrices for various formulations
//
class SVC_Q extends Kernel
{
private final byte[] y;
private final Cache cache;
private final double[] QD; SVC_Q(svm_problem prob, svm_parameter param, byte[] y_)
{
super(prob.l, prob.x, param);
y = (byte[])y_.clone();
cache = new Cache(prob.l,(long)(param.cache_size*(1<<20)));
QD = new double[prob.l];
for(int i=0;i<prob.l;i++)
QD[i] = kernel_function(i,i);
} float[] get_Q(int i, int len)
{
float[][] data = new float[1][];
int start, j;
if((start = cache.get_data(i,data,len)) < len)
{
for(j=start;j<len;j++)
data[0][j] = (float)(y[i]*y[j]*kernel_function(i,j));
}
return data[0];
} double[] get_QD()
{
return QD;
} void swap_index(int i, int j)
{
cache.swap_index(i,j);
super.swap_index(i,j);
do {byte tmp=y[i]; y[i]=y[j]; y[j]=tmp;} while(false);
do {double tmp=QD[i]; QD[i]=QD[j]; QD[j]=tmp;} while(false);
}
}
Kernel类的子类,用于对C-SVC进行定制的Kernel类。其中构造函数中会调用父类Kernel类的构造函数,并且初始化自身独有的成员变量。
在get_Q函数中,调用了Cache类的get_data函数。想要得到第 i 个变量与其它 len 个变量的Kernel函数值。但是如果取出的缓存中没有全部的值,只有部分的值的话,就需要重新计算一下剩下的那部分的Kernel值,这部分新计算的值会保存到缓存中去。只要不删除掉,以后可以继续使用,不用再重复计算了。
5. Solver类
LibSVM中的Solver类主要是SVM中SMO算法求解拉格朗日乘子的实现。SMO算法的原理可以参考之前的一篇博客:http://www.cnblogs.com/bentu*ng/p/6444516.html。
// An SMO algorithm in Fan et al., JMLR 6(2005), p. 1889--1918
// Solves:
//
// min 0.5(\alpha^T Q \alpha) + p^T \alpha
//
// y^T \alpha = \delta
// y_i = +1 or -1
// 0 <= alpha_i <= Cp for y_i = 1
// 0 <= alpha_i <= Cn for y_i = -1
//
// Given:
//
// Q, p, y, Cp, Cn, and an initial feasible point \alpha
// l is the size of vectors and matrices
// eps is the stopping tolerance
//
// solution will be put in \alpha, objective value will be put in obj
//
class Solver {
5.1 Solver类的成员变量
int active_size;
byte[] y;
double[] G; // gradient of objective function
static final byte LOWER_BOUND = 0;
static final byte UPPER_BOUND = 1;
static final byte FREE = 2;
byte[] alpha_status; // LOWER_BOUND, UPPER_BOUND, FREE
double[] alpha;
QMatrix Q;
double[] QD;
double eps;
double Cp,Cn;
double[] p;
int[] active_set;
double[] G_bar; // gradient, if we treat free variables as 0
int l;
boolean unshrink; // XXX static final double INF = java.lang.Double.POSITIVE_INFINITY;
Solver类的成员变量。包括:
active_size:计算时实际参加运算的样本数目,经过shrinking处理后,该数目会小于全部样本总数。
y:样本所属类别,+1/-1。
G:梯度,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUyTWpRek9URTJOaTB6TVRZNU1qTXpOell1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
。
alpha_status:拉格朗日乘子的状态,分别是![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUyTWpjMU5EZzROUzAzTWpRME5qZ3dOQzV3Ym1jPS5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,代表内部点(非SV,LOWER_BOUND),错分点(BSV,UPPER_BOUND),和支持向量(SV,FREE)。
alpha:拉格朗日乘子。
Q:核函数矩阵。
QD:核函数矩阵中的对角线部分。
eps:误差极限。
Cp,Cn:正负样本各自的惩罚系数。
p:目标函数中的系数。
active_set:计算时实际参加运算的样本索引。
G_bar:在重建梯度时的中间变量,可以降低重建的计算开销。
l:样本数目。
5.2 Solver类的简单辅助成员函数
double get_C(int i)
{
return (y[i] > 0)? Cp : Cn;
}
double get_c(int i):返回对应样本的C值(惩罚系数)。这里对正负样本设置了不同的惩罚系数Cp,Cn。
void update_alpha_status(int i)
{
if(alpha[i] >= get_C(i))
alpha_status[i] = UPPER_BOUND;
else if(alpha[i] <= 0)
alpha_status[i] = LOWER_BOUND;
else alpha_status[i] = FREE;
}
void update_alpha_status(int i):更新拉格朗日乘子的状态。
boolean is_upper_bound(int i) { return alpha_status[i] == UPPER_BOUND; }
boolean is_lower_bound(int i) { return alpha_status[i] == LOWER_BOUND; }
boolean is_free(int i) { return alpha_status[i] == FREE; }
boolean is_upper_bound(int i),boolean is_lower_bound(int i),boolean is_free(int i):返回拉格朗日是否在界上。
// java: information about solution except alpha,
// because we cannot return multiple values otherwise...
static class SolutionInfo {
double obj;
double rho;
double upper_bound_p;
double upper_bound_n;
double r; // for Solver_NU
}
static class Solutioninfo:SMO算法求得的解(除了alpha)。
void swap_index(int i, int j)
{
Q.swap_index(i,j);
do {byte tmp=y[i]; y[i]=y[j]; y[j]=tmp;} while(false);
do {double tmp=G[i]; G[i]=G[j]; G[j]=tmp;} while(false);
do {byte tmp=alpha_status[i]; alpha_status[i]=alpha_status[j]; alpha_status[j]=tmp;} while(false);
do {double tmp=alpha[i]; alpha[i]=alpha[j]; alpha[j]=tmp;} while(false);
do {double tmp=p[i]; p[i]=p[j]; p[j]=tmp;} while(false);
do {int tmp=active_set[i]; active_set[i]=active_set[j]; active_set[j]=tmp;} while(false);
do {double tmp=G_bar[i]; G_bar[i]=G_bar[j]; G_bar[j]=tmp;} while(false);
}
void swap_index(int i, int j):完全交换样本 i 和样本 j 的内容,包括申请的内存的地址。
5.3 Solving the Quadratic Problems
我们可以用一个通用的表达式来表示SMO算法要解决的二次优化问题:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTWpReU9UVTRPQzB4T0RFd016a3dOekF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
对于这个二次优化问题,最困难的地方在于Q是一个很大的稠密矩阵,难以存储,所以需要采用分解的方式解决,SMO算法就是采用每次选取拉格朗日乘子中的2个来更新,直到收敛到最优解。
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTWprek1UY3hNeTA0TkRnMU1qZzVPRGd1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpBd01EVTNNeTB4T1RZek5ESTROVFUzTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
5.4 Stopping Criteria
假设存在向量![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpZeU5qVTBNUzB4T0RJd09EZzBOamM1TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
是(11)式的解,则必然存在实数![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpjeE16Y3lPUzAzTlRjME1USXdNall1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
和两个非负向量![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpjek9EVTNNeTAyTURJNU1EazVPVFF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
使得下式成立:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpnd05UUXpNaTB4T1RZME5USXlORFE0TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
其中,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpneU56UXhOaTB4TnpJM056SXlPREk1TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
是目标函数的梯度。
上面的条件可以被重写为:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXpnMU9EazJNeTB4TVRJNU16RTRPRFF4TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
进一步,存在b使得![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTXprMU9ESXhNeTB4TkRJNE1ERXpPVFEzTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
其中,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRBeU5EWTRNaTB4TVRZMU16STJNVFU0TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRBME5UZ3dOeTB4TVRjMk16RTFPVFUxTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
则目标函数存在最优解![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF5THprNU5UWXhNUzB5TURFM01ESXlOakUyTXpVd05qTXdOQzB4TXpNMk5EVXlNREl5TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
的条件是:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRFeE1UWTJOaTAxTlRVek1EWTNOall1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
而实际实现过程中,优化迭代的停止条件为:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRFME9UWXpOUzB4T0RRMU5qVXpNekF5TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
其中,epsilon是误差极限,tolerance。
5.5 Working Set Selection
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRNMU1qZ3pPQzAyTnpjek16VXhOaTV3Ym1jPS5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
// return 1 if already optimal, return 0 otherwise
int select_working_set(int[] working_set)
{
// return i,j such that
// i: maximizes -y_i * grad(f)_i, i in I_up(\alpha)
// j: mimimizes the decrease of obj value
// (if quadratic coefficeint <= 0, replace it with tau)
// -y_j*grad(f)_j < -y_i*grad(f)_i, j in I_low(\alpha) double Gmax = -INF;
double Gmax2 = -INF;
int Gmax_idx = -1;
int Gmin_idx = -1;
double obj_diff_min = INF; for(int t=0;t<active_size;t++)
if(y[t]==+1)
{
if(!is_upper_bound(t))
if(-G[t] >= Gmax)
{
Gmax = -G[t];
Gmax_idx = t;
}
}
else
{
if(!is_lower_bound(t))
if(G[t] >= Gmax)
{
Gmax = G[t];
Gmax_idx = t;
}
} int i = Gmax_idx;
float[] Q_i = null;
if(i != -1) // null Q_i not accessed: Gmax=-INF if i=-1
Q_i = Q.get_Q(i,active_size); for(int j=0;j<active_size;j++)
{
if(y[j]==+1)
{
if (!is_lower_bound(j))
{
double grad_diff=Gmax+G[j];
if (G[j] >= Gmax2)
Gmax2 = G[j];
if (grad_diff > 0)
{
double obj_diff;
double quad_coef = QD[i]+QD[j]-2.0*y[i]*Q_i[j];
if (quad_coef > 0)
obj_diff = -(grad_diff*grad_diff)/quad_coef;
else
obj_diff = -(grad_diff*grad_diff)/1e-12; if (obj_diff <= obj_diff_min)
{
Gmin_idx=j;
obj_diff_min = obj_diff;
}
}
}
}
else
{
if (!is_upper_bound(j))
{
double grad_diff= Gmax-G[j];
if (-G[j] >= Gmax2)
Gmax2 = -G[j];
if (grad_diff > 0)
{
double obj_diff;
double quad_coef = QD[i]+QD[j]+2.0*y[i]*Q_i[j];
if (quad_coef > 0)
obj_diff = -(grad_diff*grad_diff)/quad_coef;
else
obj_diff = -(grad_diff*grad_diff)/1e-12; if (obj_diff <= obj_diff_min)
{
Gmin_idx=j;
obj_diff_min = obj_diff;
}
}
}
}
} if(Gmax+Gmax2 < eps || Gmin_idx == -1)
return 1; working_set[0] = Gmax_idx;
working_set[1] = Gmin_idx;
return 0;
}
其中,第1个 for 循环是在确定工作集的第1个变量 i 。在确定了 i 之后,第2个 for 循环即是为了确定第2个变量 j 的选取。当两者都确定了之后,通过看停止条件来确定是否当前变量已经处在最优解上了,如果是则返回1,如果不是对working_set数组赋值并返回0。
5.6 Maintaining the Gradient
我们可以看到,在每次迭代中,主要操作是找到![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRVeE56SXhNeTA0T1RVeE1ETXhORFF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
((12)式目标函数中会用到),以及![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRZd01qTXdOeTB4TVRNNE9EZzRNamt4TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
(在working set selection和stopping condition中会用到)。这两个主要操作可以合起来一起看待,因为:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRjek9UQTBNUzB4TmpRNU9USTJNRFF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRjMU5qRTRNaTB4TkRBNU5qSXdNVFF6TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
在第k次迭代中,我们已经得到了![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTkRnMU1UYzVNUzB4TlRFMk56RTBOemt4TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,于是便可以得到,用来计算(12)式的目标函数。当第k次迭代的目标函数得到解决后,我们又可以得到 k+1 次的![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREUzTlRBeE9UZ3lNeTB4TlRZek1UYzJOVEk1TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
。所以,LibSVM在整个迭代优化过程中都一直维护着梯度数组。
5.7 The Calculation of b
令![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRVeU1URTVPQzB4T1RBd05qVTJNRGt6TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
(1)当存在![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRRek56STBOUzA1TVRZNU1UUTBOREl1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,有![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRVd01qWXpOUzAzTURZMU5UUTFOREF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
。为了数值的稳定性,做一个平均处理,
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRVMU5USTNOaTB4TWpZME1qUTJOemt1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
(2)当![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRZeE5qazVOUzAwTlRFMU5ESXhPREl1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,有
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRZek56TXlNeTAwT0RZMk1qQTFNakV1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
则取中值。
double calculate_rho()
{
double r;
int nr_free = 0;
double ub = INF, lb = -INF, sum_free = 0;
for(int i=0;i<active_size;i++)
{
double yG = y[i]*G[i]; if(is_lower_bound(i))
{
if(y[i] > 0)
ub = Math.min(ub,yG);
else
lb = Math.max(lb,yG);
}
else if(is_upper_bound(i))
{
if(y[i] < 0)
ub = Math.min(ub,yG);
else
lb = Math.max(lb,yG);
}
else
{
++nr_free;
sum_free += yG;
}
} if(nr_free>0)
r = sum_free/nr_free;
else
r = (ub+lb)/2; return r;
}
5.8 Shrinking
对于(11)式目标函数的最优解中会包含一些边界值![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TURrek1UWTJOaTB6TWpNME1qVXhNakl1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,这些值在迭代优化的过程中可能就已经成为了边界值了,之后便不再变化。为了节省训练时间,使用shrinking方法去除这些个边界值,从而可以进一步解决一个更小的子优化问题。下面的这2个定理显示,在迭代的最后,只有一小部分变量还在改变。
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TVRNeE5Ea3pNaTAwTWpjMU5EVXlPVFF1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TVRReE56Z3dOeTB4TXpNME5qVTRNell1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
使用A来表示 k 轮迭代中没有被shrinking的元素集合,从而(11)式目标函数便可以缩减为一个子优化问题:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TVRZd09UazBPQzB4TXpVM056RXdPRGcyTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
其中,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TVRZeU9UYzJNQzB4TlRNek9UTTFNRGN5TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
是被shrinking的集合。在LibSVM中,通过元素的重排使得始终有![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU0TVRjeU56SXhNeTB4TlRNeU1qSXlPREU0TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
。
当(28)式解决了之后,我们会发现可能会有部分的元素被错误地shrinking了。如果有这种情况发生,那么需要对(11)式原优化问题进行重新求解最优值,而重新求解的起始点即是![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREU1TkRJeU16RTFNUzB6TXpJeU5EVXpPUzV3Ym1jPS5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
,其中![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TURFME1EY3lPUzB4TnpRM09ESXlNVGd1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
是(28)式子问题的最优解,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TURJd056WTJOaTAxTlRjNU56QTFNekl1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
是被shrinking的变量。
shrinking的步骤如下:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TURNek1qTTNNQzB6TmpFeE56YzBORFl1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TURRek16WXpOUzB4TVRZeU5qZ3dNVE0zTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
private boolean be_shrunk(int i, double Gmax1, double Gmax2)
{
if(is_upper_bound(i))
{
if(y[i]==+1)
return(-G[i] > Gmax1);
else
return(-G[i] > Gmax2);
}
else if(is_lower_bound(i))
{
if(y[i]==+1)
return(G[i] > Gmax2);
else
return(G[i] > Gmax1);
}
else
return(false);
}
通过上述shrinking条件来判断第 i 个变量是否被shrinking。
void do_shrinking()
{
int i;
double Gmax1 = -INF; // max { -y_i * grad(f)_i | i in I_up(\alpha) }
double Gmax2 = -INF; // max { y_i * grad(f)_i | i in I_low(\alpha) } // find maximal violating pair first
for(i=0;i<active_size;i++)
{
if(y[i]==+1)
{
if(!is_upper_bound(i))
{
if(-G[i] >= Gmax1)
Gmax1 = -G[i];
}
if(!is_lower_bound(i))
{
if(G[i] >= Gmax2)
Gmax2 = G[i];
}
}
else
{
if(!is_upper_bound(i))
{
if(-G[i] >= Gmax2)
Gmax2 = -G[i];
}
if(!is_lower_bound(i))
{
if(G[i] >= Gmax1)
Gmax1 = G[i];
}
}
} if(unshrink == false && Gmax1 + Gmax2 <= eps*10)
{
unshrink = true;
reconstruct_gradient();
active_size = l;
} for(i=0;i<active_size;i++)
if (be_shrunk(i, Gmax1, Gmax2))
{
active_size--;
while (active_size > i)
{
if (!be_shrunk(active_size, Gmax1, Gmax2))
{
swap_index(i,active_size);
break;
}
active_size--;
}
}
}
第1个 for 循环是为了找到![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TWpVd01UTTFOQzB4TmpJME5qSXhNRGszTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
这2个变量。
因为有时候shrinking策略太过aggressive,所以当对shrinking之后的部分变量的优化问题迭代优化到第一次满足条件![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TWpjeE9EQXlOaTAxTlRZME56VTNNRFV1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
时,便可以对梯度进行重建。于是,接下来的shrinking过程便可以建立在更精确的梯度值上。
最后的 for 循环是为了交换两个变量的位置,从而使得参与迭代优化的变量(即没有被shrinking的变量)始终保持在变量数组的最前面的连续位置上。进一步,为了减少交换操作的次数,从而优化计算开销,可以使用以下的trick:从左向右遍历找出需要被shrinking的变量位置 t1,从右向左遍历找出需要参与迭代优化计算的变量位置 t2,交换 t1 和 t2 的位置,然后继续遍历,直到两个遍历的指针相遇。
5.9 Reconstructing the Gradient
一旦(31)式和(32)式满足了,便需要重建梯度向量。因为在优化(28)子问题的时候,![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TXprMU56Y3lPUzB4TlRFek16RTJOamN1Y0c1bi5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
一直都在内存中的,所以在重建梯度时,我们只需要计算![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TkRFeE16Z3lNeTB4TlRjek16TXlOelExTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
即可。为了减少计算的开销,在迭代计算时,我们可以维护着另一个向量:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TkRJeE16a3pNaTB4TVRjM09EVXhOREkwTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
而对于任意不在 A 集合中的变量 i 而言,有:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TkRNd09UTXpPQzB4T1RreE5qRXpOVGd6TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
而对于上式的计算,包含了两层循环。是先对 i 循环还是先对 j 进行循环,意味着截然不同的Kernel evaluation次数。具体证明如下:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TkRVeE1qWXpOUzB4TmpnNU1EVXpOVGd5TG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
所以,我们具体选择method 1 还是method 2,是要看情况讨论的:
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TkRZd05UQXhNQzB4TlRVd09ESTBOVFUzTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
void reconstruct_gradient()
{
// reconstruct inactive elements of G from G_bar and free variables if(active_size == l) return; int i,j;
int nr_free = 0; for(j=active_size;j<l;j++)
G[j] = G_bar[j] + p[j]; for(j=0;j<active_size;j++)
if(is_free(j))
nr_free++; if(2*nr_free < active_size)
svm.info("\nWARNING: using -h 0 may be faster\n"); if (nr_free*l > 2*active_size*(l-active_size))
{
for(i=active_size;i<l;i++)
{
float[] Q_i = Q.get_Q(i,active_size);
for(j=0;j<active_size;j++)
if(is_free(j))
G[i] += alpha[j] * Q_i[j];
}
}
else
{
for(i=0;i<active_size;i++)
if(is_free(i))
{
float[] Q_i = Q.get_Q(i,l);
double alpha_i = alpha[i];
for(j=active_size;j<l;j++)
G[j] += alpha_i * Q_i[j];
}
}
}
5.10 迭代优化整体框架
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRFd05EUTVOUzB4TkRRM05qTTVPRFUzTG5CdVp3PT0uanBn.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
![[笔记]LibSVM源码剖析(java版)](https://image.shishitao.com:8440/aHR0cHM6Ly9iYnNtYXguaWthZmFuLmNvbS9zdGF0aWMvTDNCeWIzaDVMMmgwZEhCekwybHRZV2RsY3pJd01UVXVZMjVpYkc5bmN5NWpiMjB2WW14dlp5ODVPVFUyTVRFdk1qQXhOekF6THprNU5UWXhNUzB5TURFM01ETXhPREl3TlRFeU9UTTFOQzA1T1RnNE16ZzBOeTV3Ym1jPS5qcGc%3D.jpg?w=700&webp=1 "[笔记]LibSVM源码剖析(java版)")
void Solve(int l, QMatrix Q, double[] p_, byte[] y_,
double[] alpha_, double Cp, double Cn, double eps, SolutionInfo si, int shrinking)
Solver类中最重要的迭代优化函数 Solve 的接口格式。由于这个函数行数太多,下面分段进行剖析。
this.l = l;
this.Q = Q;
QD = Q.get_QD();
p = (double[])p_.clone();
y = (byte[])y_.clone();
alpha = (double[])alpha_.clone();
this.Cp = Cp;
this.Cn = Cn;
this.eps = eps;
this.unshrink = false;
对Solver类的一些成员变量进行初始化。
// initialize alpha_status
{
alpha_status = new byte[l];
for(int i=0;i<l;i++)
update_alpha_status(i);
}
初始化拉格朗日乘子状态向量值。
// initialize active set (for shrinking)
{
active_set = new int[l];
for(int i=0;i<l;i++)
active_set[i] = i;
active_size = l;
}
初始化需要参与迭代优化计算的拉格朗日乘子集合。
// initialize gradient
{
G = new double[l];
G_bar = new double[l];
int i;
for(i=0;i<l;i++)
{
G[i] = p[i];
G_bar[i] = 0;
}
for(i=0;i<l;i++)
if(!is_lower_bound(i))
{
float[] Q_i = Q.get_Q(i,l);
double alpha_i = alpha[i];
int j;
for(j=0;j<l;j++)
G[j] += alpha_i*Q_i[j];
if(is_upper_bound(i))
for(j=0;j<l;j++)
G_bar[j] += get_C(i) * Q_i[j];
}
}
初始化梯度G,以及为了重建梯度时候节省计算开销而维护的中间变量G_bar。
// optimization step
int iter = 0;
int max_iter = Math.max(10000000, l>Integer.MAX_VALUE/100 ? Integer.MAX_VALUE : 100*l);
int counter = Math.min(l,1000)+1;
int[] working_set = new int[2];
while(iter < max_iter)
{
// show progress and do shrinking
if(--counter == 0)
{
counter = Math.min(l,1000);
if(shrinking!=0) do_shrinking();
svm.info(".");
}
if(select_working_set(working_set)!=0)
{
// reconstruct the whole gradient
reconstruct_gradient();
// reset active set size and check
active_size = l;
svm.info("*");
if(select_working_set(working_set)!=0)
break;
else
counter = 1; // do shrinking next iteration
}
int i = working_set[0];
int j = working_set[1];
++iter;
// update alpha[i] and alpha[j], handle bounds carefully
float[] Q_i = Q.get_Q(i,active_size);
float[] Q_j = Q.get_Q(j,active_size);
double C_i = get_C(i);
double C_j = get_C(j);
double old_alpha_i = alpha[i];
double old_alpha_j = alpha[j];
if(y[i]!=y[j])
{
double quad_coef = QD[i]+QD[j]+2*Q_i[j];
if (quad_coef <= 0)
quad_coef = 1e-12;
double delta = (-G[i]-G[j])/quad_coef;
double diff = alpha[i] - alpha[j];
alpha[i] += delta;
alpha[j] += delta;
if(diff > 0)
{
if(alpha[j] < 0)
{
alpha[j] = 0;
alpha[i] = diff;
}
}
else
{
if(alpha[i] < 0)
{
alpha[i] = 0;
alpha[j] = -diff;
}
}
if(diff > C_i - C_j)
{
if(alpha[i] > C_i)
{
alpha[i] = C_i;
alpha[j] = C_i - diff;
}
}
else
{
if(alpha[j] > C_j)
{
alpha[j] = C_j;
alpha[i] = C_j + diff;
}
}
}
else
{
double quad_coef = QD[i]+QD[j]-2*Q_i[j];
if (quad_coef <= 0)
quad_coef = 1e-12;
double delta = (G[i]-G[j])/quad_coef;
double sum = alpha[i] + alpha[j];
alpha[i] -= delta;
alpha[j] += delta;
if(sum > C_i)
{
if(alpha[i] > C_i)
{
alpha[i] = C_i;
alpha[j] = sum - C_i;
}
}
else
{
if(alpha[j] < 0)
{
alpha[j] = 0;
alpha[i] = sum;
}
}
if(sum > C_j)
{
if(alpha[j] > C_j)
{
alpha[j] = C_j;
alpha[i] = sum - C_j;
}
}
else
{
if(alpha[i] < 0)
{
alpha[i] = 0;
alpha[j] = sum;
}
}
}
// update G
double delta_alpha_i = alpha[i] - old_alpha_i;
double delta_alpha_j = alpha[j] - old_alpha_j;
for(int k=0;k<active_size;k++)
{
G[k] += Q_i[k]*delta_alpha_i + Q_j[k]*delta_alpha_j;
}
// update alpha_status and G_bar
{
boolean ui = is_upper_bound(i);
boolean uj = is_upper_bound(j);
update_alpha_status(i);
update_alpha_status(j);
int k;
if(ui != is_upper_bound(i))
{
Q_i = Q.get_Q(i,l);
if(ui)
for(k=0;k<l;k++)
G_bar[k] -= C_i * Q_i[k];
else
for(k=0;k<l;k++)
G_bar[k] += C_i * Q_i[k];
}
if(uj != is_upper_bound(j))
{
Q_j = Q.get_Q(j,l);
if(uj)
for(k=0;k<l;k++)
G_bar[k] -= C_j * Q_j[k];
else
for(k=0;k<l;k++)
G_bar[k] += C_j * Q_j[k];
}
}
}
迭代优化最重要的循环部分。每间隔若干次迭代进行一次shrinking,使得部分变量不用参与迭代计算。选择工作集合(包含2个拉格朗日乘子),对工作集合进行更新计算操作。具体的更新原理可见paper:《Sequential Minimal Optimization: A Fast Algorithm for Training Support Vector Machines》。更新完工作集合后,再更新梯度G,拉格朗日乘子的状态向量,以及维护的中间变量G_bar。
// calculate rho
si.rho = calculate_rho();
// calculate objective value
{
double v = 0;
int i;
for(i=0;i<l;i++)
v += alpha[i] * (G[i] + p[i]);
si.obj = v/2;
}
// put back the solution
{
for(int i=0;i<l;i++)
alpha_[active_set[i]] = alpha[i];
}
si.upper_bound_p = Cp;
si.upper_bound_n = Cn;
svm.info("\noptimization finished, #iter = "+iter+"\n");
收尾工作。
6. Multi-class classification
LibSVM使用了“one-against-one”的方法实现了多分类。如果有 k 类样本,则需要建立 k(k-1)/2个分类器。
在预测时,用k(k-1)/2个分类器对预测样本进行预测,得出k(k-1)/2个预测类别,使用投票策略,选择预测数最多的那个类别作为最终的预测类别。
7. 参考文献
1. LIBSVM: A Library for Support Vector Machines
2. Sequential Minimal Optimization: A Fast Algorithm for Training Support Vector Machines
3. Working Set Selection Using Second Order Information
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