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flow_error.cpp
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861 lines (731 loc) · 29.4 KB
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#include <algorithm>
#include <vector>
#include <assert.h>
#include <stdio.h>
#include <cstdio>
#include <string>
#include <string.h>
#include "OSUFlow.h"
#include "system/cmd_arg_reader.h"
#include "system/path.h"
#include "macros.h"
#include "file/nrrd.h"
#include "statistics.h"
#include "cp_time.h"
#include "thread/ThreadClass.h"
#include "omp.h"
#include "online_quad_bezier_fit.h"
using namespace std;
using namespace JCLib; // https://github.com/chunmingchen/JCLib
vector<string> fileAry;
int W, H, D, Ts;
#define POS_ID(x,y,z) ((x)+W*((y)+H*(z)));
bool saveErrHist=false;
#if 0
///////////////////////
/// \brief The SINGLETON struct
/// Model for a scalar type
struct SINGLETON{
float v;
SINGLETON() {v=0;}
inline float &operator[](int i) { assert(i==0); return v; }
inline SINGLETON operator+(const SINGLETON &x) { SINGLETON y; y.v = v+x.v; return y; }
inline SINGLETON operator-(const SINGLETON &x) { SINGLETON y; y.v = v-x.v; return y; }
inline SINGLETON operator*(const SINGLETON &x) { SINGLETON y; y.v = v*x.v; return y; }
inline SINGLETON operator*(float f) { SINGLETON y; y.v = v*f; return y; }
inline SINGLETON operator*(double f) { SINGLETON y; y.v = v*f; return y; }
inline SINGLETON &operator+=(const SINGLETON &x) { v += x.v; return *this; }
};
inline VECTOR3 mult(const VECTOR3 & v0, const VECTOR3 & v1)
{
VECTOR3 y(v0[0]*v1[0], v0[1]*v1[1], v0[2]*v1[2]); return y;
}
inline SINGLETON mult(const SINGLETON & v0, const SINGLETON & v1)
{
SINGLETON y; y.v = v0.v * v1.v; return y;
}
inline SINGLETON sqrt(const SINGLETON x)
{
SINGLETON y; y.v = sqrt(x.v); return y;
}
#endif
inline VECTOR3 &operator +=(VECTOR3 & v0, const VECTOR3 & v1)
{
v0[0]+=v1[0]; v0[1]+=v1[1]; v0[2]+=v1[2];
return v0;
}
inline VECTOR3 operator*(const VECTOR3 & v0, const VECTOR3 & v1)
{
VECTOR3 y(v0[0]*v1[0], v0[1]*v1[1], v0[2]*v1[2]); return y;
}
inline VECTOR3 sqrt(const VECTOR3 &x)
{
VECTOR3 y(sqrt(x[0]), sqrt(x[1]), sqrt(x[2]));
}
////////////////////////////////////////////////////////
// global: fileAry, w,h,d,t
void load_list(string list_filename) {
int i, j;
string path = getPath(list_filename);
FILE *fp = fopen(list_filename.c_str(), "rt");
char str[1024];
fgets(str, 1024, fp);
i = sscanf(str, "%d %d %d %d", &W, &H, &D, &Ts);
assert(i==4);
fgets(str, 1024, fp); // dummy line
fileAry.clear();
for (i = 0; i < Ts; i++) {
fgets(str, 1024, fp);
char *p = strtok(str, " \r\n");
//printf("%s\n", p);
if (isFilenameOnly(p))
fileAry.push_back(path + p);
else
fileAry.push_back(p);
}
}
template<class T, int DIMS>
class ErrorModeling{
vector<vector<T> > quadFuncAry; // xyz, abc, dim
vector<T> rmsErrAry; // mean square error; xyz, dim
vector<T> stdErrAry; // std error; xyz, dim
vector<T> meanErrAry; // std error; xyz, dim
vector<vector<T> > errAry; // std error; xyz, dim
// online timing
AtomicLong totalAddTime, totalFitTime;
int addTimes, fitTimes;
void run_online(int sampling) {
fitTimes = 0; addTimes = 0;
int i, j, z;
OnlineCache online;
int size = W*H*D;
println("sampling=%d", sampling);
vector<T> flowfield(size);
initOnlineQuadBezier(online, size);
// output
this->quadBezierAry = vector<T>(size);
this->rmsErrAry = vector<T>(size);
string out_path = GET_ARG_STRING("out_path");
int count = 0;
int sample_base = 0;
#if 1
// the simulation loop
initOnlineQuadBezier(online, size);
for (i = 0; i < Ts; i ++)
{
// start file reading
{
println("Opening %s", fileAry[i].c_str());
FILE *fp = fopen(fileAry[i].c_str(), "rb");
if (!fp) {
perror("load flow field");
exit(1);
}
if (getFileExtension( fileAry[i] )=="vec") {
// skip first 3 integers
fseek(fp, 12, SEEK_SET);
}
printf("Reading data...");
fread(&flowfield[0], sizeof(T), W * H * D, fp);
printf("Done\n");
fclose(fp);
}
Timer timer;
timer.start();
addOnlineQuadBezier(online, flowfield, (i-sample_base)/(float)sampling);
totalAddTime+=timer.getElapsedUS();
addTimes++;
if (i%sampling==0) {
if (i>0) {
Timer timer;
timer.start();
fitOnlineQuadBezier(this->quadBezierAry, this->rmsErrAry , online, sampling);
timer.end();
totalFitTime+=timer.getElapsedUS();
fitTimes++;
vector<vector<T> > fittedAry; // dum
if (!out_path.empty())
saveFittedFlowfields(fittedAry, sample_base, sampling, out_path.c_str());
count ++;
}
initOnlineQuadBezier(online, size);
sample_base = i;
// start saving
if (!out_path.empty()) {
std::string cmd ;
if (DIMS==3)
cmd = strprintf("cp %s %s/sampling%d_%02d.vec", fileAry[i].c_str(), out_path.c_str(), sampling, i);
else
cmd = strprintf("cp %s %s/sampling%d_%02d.raw", fileAry[i].c_str(), out_path.c_str(), sampling, i);
println("%s", cmd.c_str());
system(cmd.c_str());
}
}
reportTime();
}
#else
for (i = 0; i < Ts; i += sampling)
{
if (i+sampling >= Ts) {
break;
}
count ++;
}
#endif
if (!out_path.empty()) {
FILE *fp = fopen(strprintf("%s/all_bezier_rms.list", out_path.c_str()).c_str(), "w");
fprintf(fp, "%d %d %d %d\n", W, H, D, count+1);
fprintf(fp, "%lg\n", 1.f/(double)sampling);
for (i=0; i< count ; i++)
{
fprintf(fp, "sampling%d_%02d.vec sampling%d_%02d_bctrl.raw sampling%d_%02d_rmserr.raw\n",
sampling, sampling*i, sampling, sampling*i, sampling, sampling*i);
int i1 = i+1;
if (i==count-1)
fprintf(fp, "sampling%d_%02d.vec sampling%d_%02d_bctrl.raw sampling%d_%02d_rmserr.raw\n",
sampling, sampling*i1, sampling, sampling*i, sampling, sampling*i);
}
fclose(fp);
}
}
// fitting with quad with connected end points
void fitQuadFuncEndPoints(vector<vector<T> > &flowfieldAry, int start, int sampling)
{
int n=sampling+1;
quadFuncAry = vector<vector<T> > (W*H*D, vector<T>(3));
stdErrAry = vector<T> (W*H*D);
rmsErrAry = vector<T> (W*H*D);
errAry = vector<vector<T> >(W*H*D, vector<T>(n));
meanErrAry = vector<T> (W*H*D);
println ("Fitting quadratic function");
int x, y, z, i;
for (z = 0; z < D; z++)
for (y = 0; y < H; y++)
for (x = 0; x < W; x++)
{
int id = POS_ID(x,y,z);
vector<T> y_ary(n);
for (i=0; i<n; i++)
y_ary[i] = flowfieldAry[i][id];
for (int d=0; d<DIMS; d++) //dim
{
float y1=y_ary[0][d];
float yn=y_ary[n-1][d];
float sum_y=0, sum_y2=0, sum_x2y=0, sum_xy=0;
//println("y=");
for (i=0; i<n; i++)
{
sum_y += y_ary[i][d];
sum_y2+= pow(y_ary[i][d], 2);
sum_xy += i* y_ary[i][d];
sum_x2y += i*i * y_ary[i][d];
//println("%f", y_ary[i][d]);
}
float sum_x = (n-1)*n/2;
float sum_x2 = (n-1)*(n)*(2*n-1)/6.f;
float sum_x3 = sum_x*sum_x;
float sum_x4 = (n-1)*n*(2*n-1)*(3*(n-1)*(n-1)+3*(n-1)-1)/30.f;
float par[3];
par[0] = (sum_x3*(yn-y1)/(n-1) - sum_x2y - yn*sum_x2 + 2*y1*sum_x2 + (n-1)*sum_xy - (n-1)*y1*sum_x)
/ (2*sum_x3*(n-1)-sum_x4-sum_x2*(n-1)*(n-1));
par[1] = ( (yn-y1)-par[0]*(n-1)*(n-1))/(n-1);
par[2] = y_ary[0][d];
quadFuncAry[id][0][d] = par[0];
quadFuncAry[id][1][d] = par[1];
quadFuncAry[id][2][d] = par[2];
//println("a=%f b=%f c=%f", par[0], par[1], par[2]);
//printf("d=%d, asserting...%f\n", d, abs(par[0][d]*(n-1)*(n-1)+par[1][d]*(n-1)+par[2][d]-yn));
//assert(abs(par[0][d]*(n-1)*(n-1)+par[1][d]*(n-1)+par[2][d]-y_ary[n-1][d])<1e-5);
// gen err std
//println("Err:");
vector<float> err_ary(n), err_ary2(n);
for (i=0; i<n; i++)
{
float truth = y_ary[i][d];
float fitted = par[0]*(i*i) + par[1]*i + par[2];
err_ary[i] = truth-fitted;
err_ary2[i] = err_ary[i]*err_ary[i];
//println("%f", err_ary[i]);
}
double mean = JCLib::getMean(err_ary.begin(), err_ary.end());
double std = JCLib::getDeviation(err_ary.begin(), err_ary.end());
double rms = sqrt(JCLib::getSum(err_ary2.begin(), err_ary2.end())/(n-1));
stdErrAry[id][d] = std;
rmsErrAry[id][d] = rms;
meanErrAry[id][d] = mean;
//println("std=%lf", std);
// errAry
for (i=0; i<n; i++)
errAry[id][i][d]=err_ary[i];
}
//VECTOR3 err_std;
//VECTOR3 sum_err(0,0,0);
//for (i=0; i<n; i++)
// sum_err = sum_err+(par[0]*i*i + par[1]*i + par[2] - y_ary[i]);
//getchar();
}
}
void fitQuadFunc(vector<vector<T> > &flowfieldAry, int start, int sampling)
{
int n=sampling+1;
quadFuncAry = vector<vector<T> > (W*H*D, vector<T>(3));
stdErrAry = vector<T> (W*H*D);
rmsErrAry = vector<T> (W*H*D);
println ("Fitting quadratic function");
int x, y, z, i;
for (z = 0; z < D; z++)
for (y = 0; y < H; y++)
for (x = 0; x < W; x++)
{
int id = POS_ID(x,y,z);
vector<T> y_ary(n);
for (i=0; i<n; i++)
y_ary[i] = flowfieldAry[i][id];
vector<VECTOR3> &par = quadFuncAry[id];
for (int d=0; d<DIMS; d++) //dim
{
float y1=y_ary[0][d];
float yn=y_ary[n-1][d];
float sum_y=0, sum_x2y=0, sum_xy=0;
//println("y=");
for (i=0; i<n; i++)
{
sum_y += y_ary[i][d];
sum_xy += i* y_ary[i][d];
sum_x2y += i*i * y_ary[i][d];
//println("%f", y_ary[i][d]);
}
float sum_x = (n-1)*n/2;
float sum_x2 = (n-1)*(n)*(2*n-1)/6.f;
float sum_x3 = sum_x*sum_x;
float sum_x4 = (n-1)*n*(2*n-1)*(3*(n-1)*(n-1)+3*(n-1)-1)/30.f;
MATRIX3 A(VECTOR3(sum_x4, sum_x3, sum_x2), VECTOR3(sum_x3, sum_x2, sum_x), VECTOR3(sum_x2, sum_x, n));
VECTOR3 b(sum_x2y, sum_xy, sum_y);
MATRIX3 invA;
A.inverse(invA); // invA = inv(A)
VECTOR3 par_ = invA*b;
par[0][d] = par_[0];
par[1][d] = par_[1];
par[2][d] = par_[2];
//println("a=%f b=%f c=%f", par[0][d], par[1][d], par[2][d]);
}
//getchar();
}
}
// fitting with quad bezier
vector<T> quadBezierAry; // control point
vector<T> y0Ary, ynAry;
// flowfieldAry: one layer of the original vector data
// z: the z of the layer
// start: file id
void fitQuadBezier(vector<vector<T> > &flowfieldAry, int z, int sampling)
{
int n=sampling+1;
if (z==0) {
quadBezierAry = vector<T> (W*H*D);
stdErrAry = vector<T> (W*H*D);
rmsErrAry = vector<T> (W*H*D);
//errAry = vector<vector<T> >(w*h*d, vector<T>(n));
meanErrAry = vector<T> (W*H*D);
y0Ary = vector<T> (W*H*D);
ynAry = vector<T> (W*H*D);
}
println ("Fitting quadratic function");
int x, y, i;
//for (z = 0; z < d; z++)
for (y = 0; y < H; y++)
for (x = 0; x < W; x++)
{
int id_in = POS_ID(x,y,0);
int id_out = POS_ID(x,y,z);
vector<T> y_ary(n);
for (i=0; i<n; i++)
y_ary[i] = flowfieldAry[i][id_in];
for (int d=0; d<DIMS; d++) //dim
{
float y1=y_ary[0][d];
float yn=y_ary[n-1][d];
y0Ary[id_out][d] = y1;
ynAry[id_out][d] = yn;
// t: x, u: 1-x
double sum_t1u1y=0, sum_t1u3=0, sum_t3u1=0, sum_t2u2=0;
//println("y=");
for (int t=0; t<n; t++)
{
int u = n-1-t;
int u2 = u*u;
int t2 = t*t;
sum_t1u1y += y_ary[t][d]*t*u;
sum_t1u3 += t*u*u2;
sum_t2u2 += t2*u2;
sum_t3u1 += t*t2*u;
//println("%f", y_ary[t][d]);
}
float ctrl = (sum_t1u1y * (n-1) * (n-1) - sum_t1u3 * y1 - sum_t3u1 * yn) / 2.f / sum_t2u2 ;
quadBezierAry[id_out][d] = ctrl;
//println("ctrl=%f, t1u1y=%lf, t1u3=%lf, t2u2=%lf, t3u1=%lf", ctrl, sum_t1u1y, sum_t1u3, sum_t2u2, sum_t3u1);
//printf("d=%d, asserting...%f\n", d, abs(par[0][d]*(n-1)*(n-1)+par[1][d]*(n-1)+par[2][d]-yn));
//assert(abs(par[0][d]*(n-1)*(n-1)+par[1][d]*(n-1)+par[2][d]-y_ary[n-1][d])<1e-5);
// gen err std
//println("Val, Err:");
vector<float> err_ary(n), err_ary2(n);
for (i=0; i<n; i++)
{
float truth = y_ary[i][d];
float t = (float)i/(n-1);
float u = (float)(n-1-i)/(n-1);
float fitted = u*u*y1 + 2*t*u*ctrl + t*t*yn;
err_ary[i] = truth-fitted;
err_ary2[i] = err_ary[i]*err_ary[i];
//println("%f %f", fitted, err_ary[i]);
}
double mean = JCLib::getMean(err_ary.begin(), err_ary.end());
double std = JCLib::getDeviation(err_ary.begin(), err_ary.end());
double rms = sqrt(JCLib::getSum(err_ary2.begin(), err_ary2.end())/(n-1));
stdErrAry[id_out][d] = std;
rmsErrAry[id_out][d] = rms;
meanErrAry[id_out][d] = mean;
//println("std=%lf mean=%lf rms=%f", std, mean, rms);
// errAry
//for (i=0; i<n; i++)
// errAry[id_out][i][d]=err_ary[i];
}
//VECTOR3 err_std;
//VECTOR3 sum_err(0,0,0);
//for (i=0; i<n; i++)
// sum_err = sum_err+(par[0]*i*i + par[1]*i + par[2] - y_ary[i]);
//getchar();
}
}
void saveFittedFlowfields(vector<vector<T> >& funcAry, int start, int sampling, const char *folder)
{
println("Saving fitted flow fields...");
int i;
FILE *fp;
#if 1 // store each timestep
int skip = 1;
vector<T> flowfield(W*H*D);
for (i=0; i<=sampling; i+=skip)
{
// gen field
#if 0 // normal polynomial
for (int id=0; id<W*H*D; id++)
{
flowfield[id] = funcAry[id][0]*(i*i) + funcAry[id][1]*i + funcAry[id][2];
}
#else // bezier
// gen err std
//println("Val, Err:");
int n = sampling+1;
for (int id=0; id<W*H*D; id++)
{
T y0 = y0Ary[id];
T yn = ynAry[id];
T ctrl = quadBezierAry[id];
float t = (float)i/(n-1);
float u = (float)(n-1-i)/(n-1);
T fitted = y0*(u*u) + ctrl*(2*t*u) + yn*(t*t);
flowfield[id] = fitted;
}
#endif
// save file
if (DIMS==3) {
fp = fopen(strprintf("%s/sampling%d_%02d.vec", folder, sampling, start+i).c_str(), "wb");
{
int dim[3];
dim[0] = W; dim[1] = H; dim[2] = D;
fwrite(dim, 4, 3, fp);
}
} else
fp = fopen(strprintf("%s/sampling%d_%02d.raw", folder, sampling, start+i).c_str(), "wb");
fwrite(&flowfield[0], sizeof(T), W*H*D, fp);
fclose(fp);
}
#endif
// save quad bezier control point
fp = fopen(strprintf("%s/sampling%d_%02d_bctrl.raw", folder, sampling, start).c_str(), "wb");
fwrite(&quadBezierAry[0], sizeof(T), W*H*D, fp);
fclose(fp);
#if 1
// save rms err
fp = fopen(strprintf("%s/sampling%d_%02d_rmserr.raw", folder, sampling, start).c_str(), "wb");
fwrite(&rmsErrAry[0], sizeof(T), W*H*D, fp);
fclose(fp);
// save errstd
//fp = fopen(strprintf("%s/sampling%d_%02d_stderr.raw", folder, sampling, start).c_str(), "wb");
//fwrite(&stdErrAry[0], 4, W*H*D*3, fp);
//fclose(fp);
// save err mean
//fp = fopen(strprintf("%s/sampling%d_%02d_meanerr.raw", folder, sampling, start).c_str(), "wb");
//fwrite(&meanErrAry[0], 4, W*H*D*3, fp);
//fclose(fp);
#endif
#if 0
// save a
fp = fopen(strprintf("%s/sampling%d_%02d_a.raw", folder, sampling, start).c_str(), "wb");
for (int id=0; id<w*h*d; id++)
fwrite(&funcAry[id][0], sizeof(T), 1, fp);
fclose(fp);
#endif
#if 0
// errAry
fp = fopen(strprintf("%s/sampling%d_%02d_err.raw", folder, sampling, start).c_str(), "wb");
for (int id=0; id<w*h*d; id++)
fwrite(&errAry[id][0], sizeof(T), (sampling+1), fp);
fclose(fp);
#endif
}
public:
void run_offline(int sampling) {
int i, j, z;
println("allocating size=%d", sampling);
vector<vector<T> > flowfieldAry(sampling+1, vector<T>(W * H * 1));
string out_path = GET_ARG_STRING("out_path").c_str();
int count = 0;
#if 1
for (i = 0; i < Ts; i += sampling)
{
vector<FILE *> fp_ary;
if (i+sampling >= Ts) {
break;
}
for (j=0; j <= sampling; j++)
{
int id = i + j;
if (id >= Ts) {
break;
}
println("Opening %s", fileAry[id].c_str());
FILE *fp = fopen(fileAry[id].c_str(), "rb");
if (!fp) {
perror("load flow field");
exit(1);
}
if (DIMS==3) { // for .vec format
fseek(fp, 12, SEEK_SET);
}
fp_ary.push_back(fp);
}
for (z = 0; z < D; z++ )
{
println("Reading files for z=%d", z);
for (j = 0; j <= sampling; j++) {
//println("Reading %s for z=%d", fileAry[id].c_str(), z);
fread(&flowfieldAry[j][0], sizeof(T), W * H * 1, fp_ary[j]);
//print_array(&flowfieldAry[j][0][0], 3);
}
//computeMaxError(flowfieldAry, i, sampling);
//computeMaxAngleMagError(flowfieldAry, i, sampling);
//genConvex4Error(flowfieldAry, i, sampling);
//fitQuadFunc(flowfieldAry, i, sampling);
//saveFittedFlowfields(quadFuncAry, i, sampling, "fitted_quad");
//fitQuadFuncEndPoints(flowfieldAry, i, sampling);
//saveFittedFlowfields(quadFuncAry, i, sampling, out_path.c_str());
fitQuadBezier(flowfieldAry, z, sampling);
}
for (j = 0; j <= sampling ; j++) {
fclose(fp_ary[j]);
}
if (i==0) {
std::string cmd ;
if (DIMS==3)
cmd = strprintf("cp %s %s/sampling%d_%02d.vec", fileAry[i].c_str(), out_path.c_str(), sampling, i);
else
cmd = strprintf("cp %s %s/sampling%d_%02d.raw", fileAry[i].c_str(), out_path.c_str(), sampling, i);
println("%s", cmd.c_str());
system(cmd.c_str());
}
{
std::string cmd ;
if (DIMS==3)
cmd = strprintf("cp %s %s/sampling%d_%02d.vec", fileAry[i+sampling].c_str(), out_path.c_str(), sampling, i+sampling);
else
cmd = strprintf("cp %s %s/sampling%d_%02d.raw", fileAry[i+sampling].c_str(), out_path.c_str(), sampling, i+sampling);
println("%s", cmd.c_str());
system(cmd.c_str());
}
saveFittedFlowfields(quadFuncAry, i, sampling, out_path.c_str());
count ++;
}
#else
for (i = 0; i < Ts; i += sampling)
{
if (i+sampling >= Ts) {
break;
}
count ++;
}
#endif
FILE *fp = fopen(strprintf("%s/all_bezier_rms.list", out_path.c_str()).c_str(), "w");
fprintf(fp, "%d %d %d %d\n", W, H, D, count);
fprintf(fp, "%lg\n", 1.f/(double)sampling);
for (i=0; i< count ; i++)
{
fprintf(fp, "sampling%d_%02d.vec sampling%d_%02d_bctrl.raw sampling%d_%02d_rmserr.raw\n",
sampling, sampling*i, sampling, sampling*i, sampling, sampling*i);
int i1 = i+1;
if (i==count-1)
fprintf(fp, "sampling%d_%02d.vec sampling%d_%02d_bctrl.raw sampling%d_%02d_rmserr.raw\n",
sampling, sampling*i1, sampling, sampling*i, sampling, sampling*i);
}
fclose(fp);
}
struct OnlineCache{
vector<T> ysum;
vector<T> ytsum;
vector<T> yt2sum;
vector<T> y2sum;
vector<T> y0;
vector<T> y1;
};
void addOnlineQuadBezier(OnlineCache &online, vector<T> flowfield, float t)
{
assert(flowfield.size() == online.ysum.size());
Timer timer;
timer.start();
#pragma omp parallel for
for (int i=0; i<online.ysum.size(); i++)
{
T y = flowfield[i];
T yt = y*t;
online.ysum[i] += y;
online.ytsum[i] += yt;
online.yt2sum[i] += yt*t;
online.y2sum[i] += mult(y,y); // element-wise multiplication for VECTOR3
}
timer.end();
if (t==0) {
memcpy(&online.y0[0], &flowfield[0], flowfield.size()*sizeof(T));
}
if (t==1.f) {
memcpy(&online.y1[0], &flowfield[0], flowfield.size()*sizeof(T));
}
totalAddTime+=timer.getElapsedUS();
addTimes++;
}
// output : ctrlAry, stderrAry
void fitOnlineQuadBezier(vector<T> &ctrlAry, vector<T> &stderrAry, OnlineCache &online, int sampling)
{
int n=sampling+1;
float sum_t1u1y=0, sum_t1u3=0, sum_t3u1=0, sum_t2u2=0;
float sum_u4=0, sum_t4=0;
int i;
// t: x, u: 1-x
for (i=0; i<=sampling; i++) {
float t = (float)i/sampling;
float u = 1-t;
float u2 = u*u;
float t2 = t*t;
sum_t1u3 += t*u*u2;
sum_t2u2 += t2*u2;
sum_t3u1 += t*t2*u;
sum_u4 += u2*u2;
sum_t4 += t2*t2;
}
Timer timer;
timer.start();
#pragma omp parallel for
for (i=0; i<online.ysum.size(); i++)
{
T &p0 = online.y0[i];
T &p2 = online.y1[i];
// control
T ctrl = (online.ytsum[i] - online.yt2sum[i] - p0*sum_t1u3 - p2*sum_t3u1 ) * (.5/sum_t2u2) ;
ctrlAry[i] = ctrl;
// sum est y
T sum_est_y2; // assume initialized
#if 0
for (int j=0; j<=sampling; j++)
{
float t = (float)j/sampling;
float u = 1-t;
T est_y = p0*(u*u) + ctrl*( u*t*2. ) + p2*(t*t);
sum_est_y2 += mult(est_y, est_y);
}
#else
sum_est_y2 = mult(p0,p0)*sum_u4 + mult(ctrl, ctrl)*(4.*sum_t2u2) + mult(p2, p2)*sum_t4 +
mult(p0, ctrl)*(4.*sum_t1u3) + mult(p0, p2)*(2.*sum_t2u2) + mult(ctrl, p2)*(4.*sum_t3u1);
#endif
T t1 = mult(p0, online.ysum[i]);
T t2 = mult((ctrl-p0), online.ytsum[i])*2.f;
T t3 = mult((p0-ctrl*2.f+p2), online.yt2sum[i]);
T sum_yiyest = mult(p0, online.ysum[i]) + mult((ctrl-p0), online.ytsum[i])*2.f + mult((p0-ctrl*2.f+p2), online.yt2sum[i]);
stderrAry[i] = sqrt(( online.y2sum[i] - sum_yiyest*2.f + sum_est_y2 ) * (1.f/(n-1)));
}
timer.end();
totalFitTime+=timer.getElapsedUS();
fitTimes++;
}
#if 0
void initOnlineQuadBezier(OnlineCache &online, int size) {
online.ysum = vector<T>(size); memset(&online.ysum[0], 0, size*sizeof(T));
online.ytsum = vector<T>(size); memset(&online.ytsum[0], 0, size*sizeof(T));
online.yt2sum = vector<T>(size); memset(&online.yt2sum[0], 0, size*sizeof(T));
online.y2sum = vector<T>(size); memset(&online.y2sum[0], 0, size*sizeof(T));
online.y0 = vector<T>(size); memset(&online.y0[0], 0, size*sizeof(T));
online.y1 = vector<T>(size); memset(&online.y1[0], 0, size*sizeof(T));
}
void test_online() {
//float seq[] = {1, 2, 3, 100, 5, 6, 7, 8, 9, 10};
float seq[] = {1, 4, 9, 100, 25, 36, 49, 64, 81, 100};
int sampling = 9, n = 10;
int i;
vector<vector<T> > fieldAry(n, vector<T>(1));
OnlineCache online;
vector<T> ctrlAry(1);
stdErrAry = vector<T> (1);
quadBezierAry = vector<T> (1);
rmsErrAry = vector<T> (1);
meanErrAry = vector<T> (1);
W=H=D=1;
initOnlineQuadBezier(online, 1);
for (i=0; i<=sampling; i++)
{
fieldAry[i][0][0] = seq[i];
addOnlineQuadBezier(online, fieldAry[i], (float)i/sampling);
}
// test online version
fitOnlineQuadBezier(quadBezierAry, rmsErrAry, online, sampling);
printf("online: Ctrl=%f, stderr=%f\n", quadBezierAry[0][0], rmsErrAry[0][0]);
// test offline version
fitQuadBezier(fieldAry, 0, sampling);
printf("offline: Ctrl=%f, stderr=%f\n", quadBezierAry[0][0], rmsErrAry[0][0]);
}
#endif
void reportTime() {
printf("sampling=%d, threads=%d, Fit times: %d\n", GET_ARG_INT("sampling"), GET_ARG_INT("threads"), fitTimes);
printf("Average online add time, fit time (ms): %.5lf, %.5lf\n", totalAddTime.getValue()*1e-3/addTimes, totalFitTime.getValue()*1e-3/fitTimes );
}
};
int main(int argc, const char **argv) {
CmdArgReader::init(argc, argv, "-sampling=4 -list=all.list -2d=0 -errhist=1 -scalar=0 -threads=4 -online=1 -out_path=");
omp_set_num_threads(GET_ARG_INT("threads"));
#if 0 // debug
{
ErrorModeling<SINGLETON, 1>em;
em.test_online();
return 0;
}
#endif
saveErrHist = GET_ARG_INT("errhist");
load_list(GET_ARG_STRING("list"));
int sampling = GET_ARG_INT("sampling");
int online = GET_ARG_INT("online");
//OSUFlow osuflow;
//osuflow.LoadData(GET_ARG_STRING("list").c_str(), false); // time-varying
if (GET_ARG_INT("scalar")) {
ErrorModeling<float, 1> em;
if (online) {
em.run_online(sampling);
em.reportTime();
} else
em.run_offline(sampling);
} else {
ErrorModeling<VECTOR3, 3> em;
if (online) {
em.run_online(sampling);
em.reportTime();
} else
em.run_offline(sampling);
}
}