📄 prob_calc.cpp
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/*
//
// INTEL CORPORATION PROPRIETARY INFORMATION
// This software is supplied under the terms of a license agreement or
// nondisclosure agreement with Intel Corporation and may not be copied
// or disclosed except in accordance with the terms of that agreement.
// Copyright(c) 1999-2006 Intel Corporation. All Rights Reserved.
//
// Intel(R) Integrated Performance Primitives Gaussian Mixture Sample for Windows*
//
// By downloading and installing this sample, you hereby agree that the
// accompanying Materials are being provided to you under the terms and
// conditions of the End User License Agreement for the Intel(R) Integrated
// Performance Primitives product previously accepted by you. Please refer
// to the file ippEULA.rtf located in the root directory of your Intel(R) IPP
// product installation for more information.
//
//
// Gaussian Mixture Calculation Class
//
*/
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <ipps.h>
#include <ippsr.h>
#include "prob_calc.h"
#include "feat_calc.h"
#include <windows.h>
struct Param_File_Header{
int vecSize; // feature vector size
unsigned short maxComp; // maximum component number in mixture
unsigned short fileType; // mixture parameter file type
int mixNum; // number of Gaussian mixtures
int wgtNum; // total number of weights
int gaussNum; // total number of Gaussians
int trpNum; // total number of transition values
};
struct File_Mixture{
int compNum; // component number
int wgtInd; // compInd of the first weight
int compInd; // compInd of the first component
};
/////////////////////////////////////////////////////////////
// //
// Mixture parameter file structure //
// //
// Param_File_Header header; //
// File_Mixture exstates[header.mixNum] //
// float weights[wgtNum] //
// float means[wgtNum*((vecSize+3)&(-3))] //
// float vars[wgtNum*((vecSize+3)&(-3))] //
// float dets[wgtNum] //
// float trpdets[trpNum] //
// //
/////////////////////////////////////////////////////////////
Prob_Calc::Prob_Calc(Calc_Hint hint) {
state_number = 0;
max_gauss = 0;
space_dim = 0;
gauss_num = 0;
max_len = 0;
min_len = 0;
space_dim4 = 0;
state_number4= 0;
gauss_num4 = 0;
curidx = 0;
lastidx = 0;
delta_delay = 0;
sen_end = false;
type = hint;
feat = NULL;
buffer = NULL;
features = NULL;
tmp_prob = NULL;
states = NULL;
weights = NULL;
dets = NULL;
means = NULL;
vars = NULL;
curfeat = NULL;
endfeat = NULL;
lastfeat = NULL;
flog = NULL;
ready = -2;
in_start = 0;
in_end = 0;
in = NULL;
length = NULL;
tmp_counter=-1;
running=true;
}
int Prob_Calc::Init_Arrays(void) {
int model_len=0;
if ((type!=calcNone)&&(type!=calcVect)&&(type!=calcVecM)&&(type!=calcMMix)&&(type!=calcMix))
return -1;
if (state_number<=0) return -1;
if (max_gauss<=0) return -1;
if (space_dim<=0) return -1;
if (max_len<=0) return -1;
if (min_len<=0) return -1;
if (max_len<100) max_len=100;
if (min_len<12) min_len=12;
if (min_len>(max_len>>3)) min_len=(max_len>>3);
space_dim4=(space_dim+3)&(~3);
state_number4=(state_number+3)&(~3);
gauss_num4=(gauss_num+3)&(~3);
model_len=sizeof(Mixture)*state_number4+sizeof(float)*(gauss_num4+gauss_num4+
gauss_num*space_dim4+gauss_num*space_dim4);
if (!(features = ippsMalloc_32f(space_dim4*max_len))) return -2;
int tmp_len=(max_gauss>max_len)?max_gauss:max_len;
if (!(tmp_prob = ippsMalloc_32f(tmp_len))) return -2;
if (!(buffer = (void*)ippsMalloc_8u(model_len))) return -2;
states = (Mixture*)buffer;
weights = (float*)(states+state_number4);
dets = weights+gauss_num4;
means = dets+gauss_num4;
vars = means+gauss_num*space_dim4;
if (!(in = (Prob_List*)ippsMalloc_8u(sizeof(Prob_List)*state_number))) return -2;
if (!(length = ippsMalloc_32s(state_number))) return -2;
for(int i=0;i<state_number;i++){
in[i].next=-1;
in[i].t=-1;
}
return 0;
}
int Prob_Calc::Init_LogFile(char *feat_log) {
if (ready!=-1) return -10;
if (!feat_log) {
flog=NULL;
} else if (!feat_log[0]) {
flog=NULL;
} else {
if (!(flog=fopen(feat_log, "wb"))) return -3;
}
return 0;
}
int Prob_Calc::Init_Calc(int N, int G, int L, int F, int M) {
if (ready!=-2) return -10;
state_number = N;
max_gauss = G;
space_dim = L;
max_len = F;
min_len = M;
gauss_num = state_number*max_gauss;
int ret=Init_Arrays();
if (ret<0) return ret;
for (int i=0; i<state_number; i++) {
states[i].compInd=i*max_gauss;
states[i].compNum=max_gauss;
}
ippsSet_32f(1.0f/(float)max_gauss,weights,state_number);
ippsSet_32f((float)space_dim,dets,state_number);
ippsSet_32f(0.0f,means,state_number*space_dim4);
ippsSet_32f(1.0f,vars,state_number*space_dim4);
ippsOutProbPreCalc_32f_I(Weight(0),Det(0),gauss_num);
ready=-1;
return 0;
}
static FILE* create_param_file(char *file, int stateNum, int maxComp, int vecSize, int trpNum) {
Param_File_Header header;
FILE *fptr=NULL;
int i;
if (!(fptr=fopen(file, "wb"))) return fptr;
header.vecSize=vecSize;
header.maxComp=3;
header.fileType=0;
header.mixNum=stateNum;
header.wgtNum=stateNum*maxComp;
header.gaussNum=stateNum*maxComp;
header.trpNum=trpNum;
if (fwrite((void*)(&header), sizeof(Param_File_Header), 1, fptr)<1) {
fclose(fptr); return fptr;
}
File_Mixture *states=(File_Mixture*)calloc(sizeof(File_Mixture),header.mixNum);
if (!states) {
fclose(fptr); return fptr;
}
for (i=0; i<header.mixNum; i++) {
states[i].compNum=maxComp;
states[i].wgtInd=maxComp*i;
states[i].compInd=maxComp*i;
}
if (fwrite((void*)(states), sizeof(File_Mixture), header.mixNum, fptr)<1) {
fclose(fptr); return fptr;
}
free(states);
float *weights=(float*)calloc(sizeof(float),header.wgtNum);
for (i=0; i<header.mixNum; i++) {
// weights[i]=(float)log(1.0/maxComp);
weights[i]=-1.0f-((float)(rand())/(float)RAND_MAX); // -2.0 ... -1.0
}
if (fwrite((void*)(weights), sizeof(float)*header.wgtNum, 1, fptr)<1) {
fclose(fptr); return fptr;
}
free(weights);
float *means=(float*)calloc(sizeof(float),header.gaussNum*((header.vecSize+3)&(-3)));
for (i=0; i<stateNum*((header.vecSize+3)&(-3)); i++) {
// means[i]=0.0f;
means[i]=-4.0f+((float)(rand())*8.0f/(float)RAND_MAX); // -4.0 ... 4.0
}
if (fwrite((void*)(means), sizeof(float)*header.gaussNum*((header.vecSize+3)&(-3)), 1, fptr)<1) {
fclose(fptr); return fptr;
}
free(means);
float *vars=(float*)calloc(sizeof(float),header.gaussNum*((header.vecSize+3)&(-3)));
for (i=0; i<stateNum*((header.vecSize+3)&(-3)); i++) {
// vars[i]=1.0f;
vars[i]=0.1f+((float)(rand())*0.4f/(float)RAND_MAX); // 0.1 ... 0.5
}
if (fwrite((void*)(vars), sizeof(float)*header.gaussNum*((header.vecSize+3)&(-3)), 1, fptr)<1) {
fclose(fptr); return fptr;
}
free(vars);
float *dets=(float*)calloc(sizeof(float),header.gaussNum);
for (i=0; i<header.mixNum; i++) {
// dets[i]=10.0f;
dets[i]=90.0f+((float)(rand())*40.0f/(float)RAND_MAX); // 90.0 ... 130.0
}
if (fwrite((void*)(dets), sizeof(float)*header.gaussNum, 1, fptr)<1) {
fclose(fptr); return fptr;
}
free(dets);
float *trans=(float*)calloc(sizeof(float),header.trpNum);
for (i=0; i<header.trpNum; i++) {
trans[i]=0.1f;
}
if (fwrite((void*)(trans), sizeof(float), header.trpNum, fptr)<1) {
fclose(fptr); return fptr;
}
free(trans);
fclose(fptr);
fptr=fopen(file, "rb");
return fptr;
}
int Prob_Calc::Init_Calc(char* file, int F, int M) {
int i;
FILE *fptr;
Param_File_Header header;
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