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tqchen 2014-05-16 19:51:33 -07:00
parent e872f488a5
commit 6a9438ac86
2 changed files with 0 additions and 159 deletions
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12
regrank/xgboost_regrank_obj.h
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@ -109,17 +109,6 @@ namespace xgboost{
namespace xgboost{ namespace xgboost{
namespace regrank{ namespace regrank{
inline IObjFunction* CreateObjFunction( const char *name ){ inline IObjFunction* CreateObjFunction( const char *name ){
<<<<<<< HEAD
if( !strcmp("reg", name ) ) return new RegressionObj();
if( !strcmp("rank:pairwise", name ) ) return new PairwiseRankObj();
if( !strcmp("rank:softmax", name ) ) return new SoftmaxRankObj();
if( !strcmp("softmax", name ) ) return new SoftmaxMultiClassObj();
if (!strcmp("rank:map", name)) return new LambdaRankObj_MAP();
if (!strcmp("rank:ndcg", name)) return new LambdaRankObj_NDCG();
utils::Error("unknown objective function type");
return NULL;
}
=======
if( !strcmp("reg:linear", name ) ) return new RegressionObj( LossType::kLinearSquare ); if( !strcmp("reg:linear", name ) ) return new RegressionObj( LossType::kLinearSquare );
if( !strcmp("reg:logistic", name ) ) return new RegressionObj( LossType::kLogisticNeglik ); if( !strcmp("reg:logistic", name ) ) return new RegressionObj( LossType::kLogisticNeglik );
if( !strcmp("binary:logistic", name ) ) return new RegressionObj( LossType::kLogisticClassify ); if( !strcmp("binary:logistic", name ) ) return new RegressionObj( LossType::kLogisticClassify );
@ -130,7 +119,6 @@ namespace xgboost{
utils::Error("unknown objective function type"); utils::Error("unknown objective function type");
return NULL; return NULL;
} }
>>>>>>> 9eabb5c7f912a326005aca53a76c2e53a1661842
}; };
}; };
#endif #endif

147
regrank/xgboost_regrank_obj.hpp
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@ -330,153 +330,6 @@ namespace xgboost{
virtual ~PairwiseRankObj(void){} virtual ~PairwiseRankObj(void){}
virtual void GetLambdaWeight( const std::vector<ListEntry> &sorted_list, std::vector<LambdaPair> &pairs ){} virtual void GetLambdaWeight( const std::vector<ListEntry> &sorted_list, std::vector<LambdaPair> &pairs ){}
}; };
class LambdaRankObj_NDCG : public LambdaRankObj{
public:
virtual ~LambdaRankObj_NDCG(void){}
inline float CalcDCG( const std::vector<float> &labels ){
double sumdcg = 0.0;
for( size_t i = 0; i < labels.size(); i ++ ){
const unsigned rel = labels[i];
if( rel != 0 ){
sumdcg += logf(2.0f) * ((1<<rel)-1) / logf( i + 2 );
}
}
return static_cast<float>(sumdcg);
}
inline float GetIDCG(const std::vector<ListEntry> &sorted_list){
std::vector<float> labels;
for (size_t i = 0; i < sorted_list.size(); i++){
labels.push_back(sorted_list[i].label);
}
std::sort(labels.begin(), labels.end(), std::greater<float>());
return CalcDCG(labels);
}
/*
* \brief Obtain the delta NDCG if trying to switch the positions of instances in index1 or index2
* in sorted triples. Here DCG is calculated as sigma_i 2^rel_i/log(i + 1)
* \param sorted_list the list containing entry information
* \param index1,index2 the instances switched
* \param the IDCG of the list
*/
inline float GetLambdaNDCG(const std::vector<ListEntry> &sorted_list,
int index1,
int index2, float IDCG){
double original = (1 << static_cast<int>(sorted_list[index1].label)) / log(index1 + 2)
+ (1 << static_cast<int>(sorted_list[index2].label)) / log(index2 + 2);
double changed = (1 << static_cast<int>(sorted_list[index2].label)) / log(index1 + 2)
+ (1 << static_cast<int>(sorted_list[index1].label)) / log(index2 + 2);
double ans = (original - changed) / IDCG;
if (ans < 0) ans = -ans;
return static_cast<float>(ans);
}
virtual void GetLambdaWeight(const std::vector<ListEntry> &sorted_list, std::vector<LambdaPair> &pairs){
float IDCG = GetIDCG(sorted_list);
for (size_t i = 0; i < pairs.size(); i++){
pairs[i].weight = GetLambdaNDCG(sorted_list,
pairs[i].pos_index, pairs[i].neg_index, IDCG);
}
}
};
class LambdaRankObj_MAP : public LambdaRankObj{
class Quadruple{
public:
/* \brief the accumulated precision */
float ap_acc_;
/* \brief the accumulated precision assuming a positive instance is missing*/
float ap_acc_miss_;
/* \brief the accumulated precision assuming that one more positive instance is inserted ahead*/
float ap_acc_add_;
/* \brief the accumulated positive instance count */
float hits_;
Quadruple(){}
Quadruple(const Quadruple& q){
ap_acc_ = q.ap_acc_;
ap_acc_miss_ = q.ap_acc_miss_;
ap_acc_add_ = q.ap_acc_add_;
hits_ = q.hits_;
}
Quadruple(float ap_acc, float ap_acc_miss, float ap_acc_add, float hits
) :ap_acc_(ap_acc), ap_acc_miss_(ap_acc_miss), ap_acc_add_(ap_acc_add), hits_(hits){
}
};
public:
virtual ~LambdaRankObj_MAP(void){}
/*
* \brief Obtain the delta MAP if trying to switch the positions of instances in index1 or index2
* in sorted triples
* \param sorted_list the list containing entry information
* \param index1,index2 the instances switched
* \param map_acc a vector containing the accumulated precisions for each position in a list
*/
inline float GetLambdaMAP(const std::vector<ListEntry> &sorted_list,
int index1, int index2,
std::vector< Quadruple > &map_acc){
if (index1 == index2 || sorted_list[index1].label == sorted_list[index2].label) return 0.0;
if (index1 > index2) std::swap(index1, index2);
float original = map_acc[index2].ap_acc_; // The accumulated precision in the interval [index1,index2]
if (index1 != 0) original -= map_acc[index1 - 1].ap_acc_;
float changed = 0;
if (sorted_list[index1].label < sorted_list[index2].label){
changed += map_acc[index2 - 1].ap_acc_add_ - map_acc[index1].ap_acc_add_;
changed += (map_acc[index1].hits_ + 1.0f) / (index1 + 1);
}
else{
changed += map_acc[index2 - 1].ap_acc_miss_ - map_acc[index1].ap_acc_miss_;
changed += map_acc[index2].hits_ / (index2 + 1);
}
float ans = (changed - original) / (map_acc[map_acc.size() - 1].hits_);
if (ans < 0) ans = -ans;
return ans;
}
/*
* \brief preprocessing results for calculating delta MAP
* \return The first field is the accumulated precision, the second field is the
* accumulated precision assuming a positive instance is missing,
* the third field is the accumulated precision assuming that one more positive
* instance is inserted, the fourth field is the accumulated positive instance count
*/
inline void GetMAPAcc(const std::vector<ListEntry> &sorted_list,
std::vector< Quadruple > &map_acc){
map_acc.resize(sorted_list.size());
float hit = 0, acc1 = 0, acc2 = 0, acc3 = 0;
for (size_t i = 1; i <= sorted_list.size(); i++){
if ((int)sorted_list[i - 1].label == 1) {
hit++;
acc1 += hit / i;
acc2 += (hit - 1) / i;
acc3 += (hit + 1) / i;
}
map_acc[i - 1] = Quadruple(acc1, acc2, acc3, hit);
}
}
virtual void GetLambdaWeight(const std::vector<ListEntry> &sorted_list, std::vector<LambdaPair> &pairs){
std::vector< Quadruple > map_acc;
GetMAPAcc(sorted_list, map_acc);
for (size_t i = 0; i < pairs.size(); i++){
pairs[i].weight = GetLambdaMAP(sorted_list, pairs[i].pos_index, pairs[i].neg_index, map_acc);
}
}
};
}; };
}; };
#endif #endif