test_pie/external/MRF/example.cpp

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2023-09-14 11:12:02 +02:00
// example.cpp -- illustrates calling the MRF code
static const char *usage = "usage: %s [energyType] (a number between 0 and 3)\n";
// uncomment "#define COUNT_TRUNCATIONS" in energy.h to enable counting of truncations
#include "mrf.h"
#include "ICM.h"
#include "GCoptimization.h"
#include "MaxProdBP.h"
#include "TRW-S.h"
#include "BP-S.h"
#include <stdio.h>
#include <stdlib.h>
#include <time.h>
#include <new>
const int sizeX = 50;
const int sizeY = 50;
const int numLabels = 20;
MRF::CostVal D[sizeX*sizeY*numLabels];
MRF::CostVal V[numLabels*numLabels];
MRF::CostVal hCue[sizeX*sizeY];
MRF::CostVal vCue[sizeX*sizeY];
#ifdef COUNT_TRUNCATIONS
int truncCnt, totalCnt;
#endif
EnergyFunction* generate_DataARRAY_SmoothFIXED_FUNCTION()
{
int i, j;
// generate function
for (i=0; i<numLabels; i++) {
for (j=i; j<numLabels; j++) {
V[i*numLabels+j] = V[j*numLabels+i] = (i == j) ? 0 : (MRF::CostVal)2.3;
}
}
MRF::CostVal* ptr;
for (ptr=&D[0]; ptr<&D[sizeX*sizeY*numLabels]; ptr++) *ptr = ((MRF::CostVal)(rand() % 100))/10 + 1;
for (ptr=&hCue[0]; ptr<&hCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3 + 1;
for (ptr=&vCue[0]; ptr<&vCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3 + 1;
// allocate energy
DataCost *data = new DataCost(D);
SmoothnessCost *smooth = new SmoothnessCost(V,hCue,vCue);
EnergyFunction *energy = new EnergyFunction(data,smooth);
return energy;
}
EnergyFunction* generate_DataARRAY_SmoothTRUNCATED_LINEAR()
{
// generate function
MRF::CostVal* ptr;
for (ptr=&D[0]; ptr<&D[sizeX*sizeY*numLabels]; ptr++) *ptr = ((MRF::CostVal)(rand() % 100))/10 + 1;
for (ptr=&hCue[0]; ptr<&hCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3;
for (ptr=&vCue[0]; ptr<&vCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3;
MRF::CostVal smoothMax = (MRF::CostVal)25.5, lambda = (MRF::CostVal)2.7;
// allocate energy
DataCost *data = new DataCost(D);
SmoothnessCost *smooth = new SmoothnessCost(1,smoothMax,lambda,hCue,vCue);
EnergyFunction *energy = new EnergyFunction(data,smooth);
return energy;
}
EnergyFunction* generate_DataARRAY_SmoothTRUNCATED_QUADRATIC()
{
// generate function
MRF::CostVal* ptr;
for (ptr=&D[0]; ptr<&D[sizeX*sizeY*numLabels]; ptr++) *ptr = ((MRF::CostVal)(rand() % 100))/10 + 1;
for (ptr=&hCue[0]; ptr<&hCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3;
for (ptr=&vCue[0]; ptr<&vCue[sizeX*sizeY]; ptr++) *ptr = rand() % 3;
MRF::CostVal smoothMax = (MRF::CostVal)5.5, lambda = (MRF::CostVal)2.7;
// allocate energy
DataCost *data = new DataCost(D);
SmoothnessCost *smooth = new SmoothnessCost(2,smoothMax,lambda,hCue,vCue);
EnergyFunction *energy = new EnergyFunction(data,smooth);
return energy;
}
MRF::CostVal dCost(int pix, int i)
{
return ((pix*i + i + pix) % 30) / ((MRF::CostVal) 3);
}
MRF::CostVal fnCost(int pix1, int pix2, int i, int j)
{
if (pix2 < pix1) { // ensure that fnCost(pix1, pix2, i, j) == fnCost(pix2, pix1, j, i)
int tmp;
tmp = pix1; pix1 = pix2; pix2 = tmp;
tmp = i; i = j; j = tmp;
}
MRF::CostVal answer = (pix1*(i+1)*(j+2) + pix2*i*j*pix1 - 2*i*j*pix1) % 100;
return answer / 10;
}
EnergyFunction* generate_DataFUNCTION_SmoothGENERAL_FUNCTION()
{
DataCost *data = new DataCost(dCost);
SmoothnessCost *smooth = new SmoothnessCost(fnCost);
EnergyFunction *energy = new EnergyFunction(data,smooth);
return energy;
}
int main(int argc, char **argv)
{
MRF* mrf;
EnergyFunction *energy;
MRF::EnergyVal E;
double lowerBound;
float t,tot_t;
int iter;
int seed = 1124285485;
srand(seed);
int Etype = 0;
if (argc != 2) {
fprintf(stderr, usage, argv[0]);
exit(1);
}
if (argc > 1)
Etype = atoi(argv[1]);
try {
switch(Etype) {
// Here are 4 sample energies to play with.
case 0:
energy = generate_DataARRAY_SmoothFIXED_FUNCTION();
fprintf(stderr, "using fixed (array) smoothness cost\n");
break;
case 1:
energy = generate_DataARRAY_SmoothTRUNCATED_LINEAR();
fprintf(stderr, "using truncated linear smoothness cost\n");
break;
case 2:
energy = generate_DataARRAY_SmoothTRUNCATED_QUADRATIC();
fprintf(stderr, "using truncated quadratic smoothness cost\n");
break;
case 3:
energy = generate_DataFUNCTION_SmoothGENERAL_FUNCTION();
fprintf(stderr, "using general smoothness functions\n");
break;
default:
fprintf(stderr, usage, argv[0]);
exit(1);
}
bool runICM = true;
bool runExpansion = true;
bool runSwap = true;
bool runMaxProdBP = true;
bool runTRWS = true;
bool runBPS = true;
////////////////////////////////////////////////
// ICM //
////////////////////////////////////////////////
if (runICM) {
printf("\n*******Started ICM *****\n");
mrf = new ICM(sizeX,sizeY,numLabels,energy);
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
tot_t = 0;
for (iter=0; iter<6; iter++) {
mrf->optimize(10, t);
E = mrf->totalEnergy();
tot_t = tot_t + t ;
printf("energy = %g (%f secs)\n", (float)E, tot_t);
}
delete mrf;
}
////////////////////////////////////////////////
// Graph-cuts expansion //
////////////////////////////////////////////////
if (runExpansion) {
printf("\n*******Started graph-cuts expansion *****\n");
mrf = new Expansion(sizeX,sizeY,numLabels,energy);
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
#ifdef COUNT_TRUNCATIONS
truncCnt = totalCnt = 0;
#endif
tot_t = 0;
for (iter=0; iter<6; iter++) {
mrf->optimize(1, t);
E = mrf->totalEnergy();
tot_t = tot_t + t ;
printf("energy = %g (%f secs)\n", (float)E, tot_t);
}
#ifdef COUNT_TRUNCATIONS
if (truncCnt > 0)
printf("***WARNING: %d terms (%.2f%%) were truncated to ensure regularity\n",
truncCnt, (float)(100.0 * truncCnt / totalCnt));
#endif
delete mrf;
}
////////////////////////////////////////////////
// Graph-cuts swap //
////////////////////////////////////////////////
if (runSwap) {
printf("\n*******Started graph-cuts swap *****\n");
mrf = new Swap(sizeX,sizeY,numLabels,energy);
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
#ifdef COUNT_TRUNCATIONS
truncCnt = totalCnt = 0;
#endif
tot_t = 0;
for (iter=0; iter<8; iter++) {
mrf->optimize(1, t);
E = mrf->totalEnergy();
tot_t = tot_t + t ;
printf("energy = %g (%f secs)\n", (float)E, tot_t);
}
#ifdef COUNT_TRUNCATIONS
if (truncCnt > 0)
printf("***WARNING: %d terms (%.2f%%) were truncated to ensure regularity\n",
truncCnt, (float)(100.0 * truncCnt / totalCnt));
#endif
delete mrf;
}
////////////////////////////////////////////////
// Belief Propagation //
////////////////////////////////////////////////
if (runMaxProdBP) {
printf("\n******* Started MaxProd Belief Propagation *****\n");
mrf = new MaxProdBP(sizeX,sizeY,numLabels,energy);
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
tot_t = 0;
for (iter=0; iter < 10; iter++) {
mrf->optimize(1, t);
E = mrf->totalEnergy();
tot_t = tot_t + t ;
printf("energy = %g (%f secs)\n", (float)E, tot_t);
}
delete mrf;
}
////////////////////////////////////////////////
// TRW-S //
////////////////////////////////////////////////
if (runTRWS) {
printf("\n*******Started TRW-S *****\n");
mrf = new TRWS(sizeX,sizeY,numLabels,energy);
// can disable caching of values of general smoothness function:
//mrf->dontCacheSmoothnessCosts();
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
tot_t = 0;
for (iter=0; iter<10; iter++) {
mrf->optimize(10, t);
E = mrf->totalEnergy();
lowerBound = mrf->lowerBound();
tot_t = tot_t + t ;
printf("energy = %g, lower bound = %f (%f secs)\n", (float)E, lowerBound, tot_t);
}
delete mrf;
}
////////////////////////////////////////////////
// BP-S //
////////////////////////////////////////////////
if (runBPS) {
printf("\n*******Started BP-S *****\n");
mrf = new BPS(sizeX,sizeY,numLabels,energy);
// can disable caching of values of general smoothness function:
//mrf->dontCacheSmoothnessCosts();
mrf->initialize();
mrf->clearAnswer();
E = mrf->totalEnergy();
printf("Energy at the Start= %g (%g,%g)\n", (float)E,
(float)mrf->smoothnessEnergy(), (float)mrf->dataEnergy());
tot_t = 0;
for (iter=0; iter<10; iter++) {
mrf->optimize(10, t);
E = mrf->totalEnergy();
tot_t = tot_t + t ;
printf("energy = %g (%f secs)\n", (float)E, tot_t);
}
delete mrf;
}
}
catch (std::bad_alloc) {
fprintf(stderr, "*** Error: not enough memory\n");
exit(1);
}
return 0;
}