test_pie/external/MRF/ICM.cpp

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "ICM.h"

#define m_D(pix,l)  m_D[(pix)*m_nLabels+(l)]
#define m_V(l1,l2)  m_V[(l1)*m_nLabels+(l2)]


ICM::ICM(int width, int height, int nLabels,EnergyFunction *eng):MRF(width,height,nLabels,eng)
{
    m_needToFreeV = 0;
    initializeAlg();
}
ICM::ICM(int nPixels, int nLabels,EnergyFunction *eng):MRF(nPixels,nLabels,eng)
{
    m_needToFreeV = 0;
    initializeAlg();
}

ICM::~ICM()
{ 
    delete[] m_answer;
    if (!m_grid_graph) delete[] m_neighbors;
    if ( m_needToFreeV ) delete[] m_V;
}


void ICM::initializeAlg()
{
    m_answer = (Label *) new Label[m_nPixels];
    if ( !m_answer ){printf("\nNot enough memory, exiting");exit(0);}

    if (!m_grid_graph)
    {
        m_neighbors = (LinkedBlockList *) new LinkedBlockList[m_nPixels];
        if (!m_neighbors) {printf("Not enough memory,exiting");exit(0);};
    }
}

void ICM::clearAnswer()
{
    memset(m_answer, 0, m_nPixels*sizeof(Label));
}

void ICM::setNeighbors(int pixel1, int pixel2, CostVal weight)
{
    assert(!m_grid_graph);
    assert(pixel1 < m_nPixels && pixel1 >= 0 && pixel2 < m_nPixels && pixel2 >= 0);


    Neighbor *temp1 = (Neighbor *) new Neighbor;
    Neighbor *temp2 = (Neighbor *) new Neighbor;

    if ( !temp1 || ! temp2 ) {printf("\nNot enough memory, exiting");exit(0);}

    temp1->weight  = weight;
    temp1->to_node = pixel2;

    temp2->weight  = weight;
    temp2->to_node = pixel1;

    m_neighbors[pixel1].addFront(temp1);
    m_neighbors[pixel2].addFront(temp2);
}


MRF::EnergyVal ICM::smoothnessEnergy()
{
    EnergyVal eng = (EnergyVal) 0;
    EnergyVal weight;
    int x,y,pix,i;

    if ( m_grid_graph )
    {
        if ( m_smoothType != FUNCTION  )
        {
            for ( y = 0; y < m_height; y++ )
                for ( x = 1; x < m_width; x++ )
                {
                    pix    = x+y*m_width;
                    weight = m_varWeights ? m_horizWeights[pix-1] :  1;
                    eng = eng + m_V(m_answer[pix],m_answer[pix-1])*weight;
                }

            for ( y = 1; y < m_height; y++ )
                for ( x = 0; x < m_width; x++ )
                {
                    pix = x+y*m_width;
                    weight = m_varWeights ? m_vertWeights[pix-m_width] :  1;
                    eng = eng + m_V(m_answer[pix],m_answer[pix-m_width])*weight;
                }
        }
        else
        {
            for ( y = 0; y < m_height; y++ )
                for ( x = 1; x < m_width; x++ )
                {
                    pix = x+y*m_width;
                    eng = eng + m_smoothFn(pix,pix-1,m_answer[pix],m_answer[pix-1]);
                }

            for ( y = 1; y < m_height; y++ )
                for ( x = 0; x < m_width; x++ )
                {
                    pix = x+y*m_width;
                    eng = eng + m_smoothFn(pix,pix-m_width,m_answer[pix],m_answer[pix-m_width]);
                }
        }
    }
    else
    {
        
        Neighbor *temp; 

        if ( m_smoothType != FUNCTION  )
        {
            for ( i = 0; i < m_nPixels; i++ )
                if ( !m_neighbors[i].isEmpty() )
                {
                    m_neighbors[i].setCursorFront();
                    while ( m_neighbors[i].hasNext() )
                    {
                        temp = (Neighbor *) m_neighbors[i].next();

                        if ( i < temp->to_node )
                            eng = eng + m_V(m_answer[i],m_answer[temp->to_node])*(temp->weight);
                    }
                }
        }
        else
        {
            for ( i = 0; i < m_nPixels; i++ )
                if ( !m_neighbors[i].isEmpty() )
                {
                    m_neighbors[i].setCursorFront();
                    while ( m_neighbors[i].hasNext() )
                    {
                        temp = (Neighbor *) m_neighbors[i].next();
                        if ( i < temp->to_node )
                            eng = eng + m_smoothFn(i,temp->to_node, m_answer[i],m_answer[temp->to_node]);
                }
            }
        }
        
    }

    return(eng);
}


MRF::EnergyVal ICM::dataEnergy()
{
    EnergyVal eng = (EnergyVal) 0;

    
    if ( m_dataType == ARRAY) 
    {
        for ( int i = 0; i < m_nPixels; i++ )
            eng = eng + m_D(i,m_answer[i]);
    }
    else
    {
        for ( int i = 0; i < m_nPixels; i++ )
            eng = eng + m_dataFn(i,m_answer[i]);
    }
    return(eng);

}


void ICM::setData(DataCostFn dcost)
{
    m_dataFn = dcost;
}

void ICM::setData(CostVal* data)
{
    m_D = data;
}


void ICM::setSmoothness(SmoothCostGeneralFn cost)
{
    m_smoothFn = cost;
}
void ICM::setSmoothness(CostVal* V)
{
    m_V = V;
}


void ICM::setSmoothness(int smoothExp,CostVal smoothMax, CostVal lambda)
{
    int i, j;
    CostVal cost;


    m_needToFreeV = 1;

    m_V = (CostVal *) new CostVal[m_nLabels*m_nLabels*sizeof(CostVal)];
    if (!m_V) { fprintf(stderr, "Not enough memory!\n"); exit(1); }


    for (i=0; i<m_nLabels; i++)
        for (j=i; j<m_nLabels; j++)
        {
            cost = (CostVal) ((smoothExp == 1) ? j - i : (j - i)*(j - i));
            if (cost > smoothMax) cost = smoothMax;
            m_V[i*m_nLabels + j] = m_V[j*m_nLabels + i] = cost*lambda;
        }

}


void ICM::setCues(CostVal* hCue, CostVal* vCue)
{
    m_horizWeights = hCue;
    m_vertWeights  = vCue;
}


void ICM::optimizeAlg(int nIterations)
{
    int x, y, i, j, n;
    Label* l;
    CostVal* dataPtr;
    CostVal *D = (CostVal *) new CostVal[m_nLabels];
    if ( !D ) {printf("\nNot enough memory, exiting");exit(0);}

    if ( !m_grid_graph) {printf("\nICM is not implemented for nongrids yet!");exit(1);}

    for ( ; nIterations > 0; nIterations --)
    {
        n = 0;
        l = m_answer;
        dataPtr = m_D;

        for (y=0; y<m_height; y++)
        for (x=0; x<m_width; x++, l++, dataPtr+=m_nLabels, n++)
        {
            // set array D
            if (m_dataType == FUNCTION)
            {
                for (i=0; i<m_nLabels; i++)
                {
                    D[i] = m_dataFn(x+y*m_width, i);
                }
            }
            else memcpy(D, dataPtr, m_nLabels*sizeof(CostVal));
            

            // add smoothness costs
            if (m_smoothType == FUNCTION)
            {
                if (x > 0)
                {
                    j = *(l-1);
                    for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+y*m_width-1, x+y*m_width, j, i);
                }
                if (y > 0)
                {
                    j = *(l-m_width);
                    for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+y*m_width-m_width,x+y*m_width , j, i);
                }
                if (x < m_width-1)
                {
                    j = *(l+1);
                    for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+y*m_width+1, x+y*m_width, i, j);
                }
                if (y < m_height-1)
                {
                    j = *(l+m_width);
                    for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+y*m_width+m_width, x+y*m_width, i, j);
                }
            }
            else
            {
                if (x > 0)
                {
                    j = *(l-1);
                    CostVal lambda = (m_varWeights) ? m_horizWeights[n-1] : 1;
                    for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];
                }
                if (y > 0)
                {
                    j = *(l-m_width);
                    CostVal lambda = (m_varWeights) ? m_vertWeights[n-m_width] : 1;
                    for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];
                }
                if (x < m_width-1)
                {
                    j = *(l+1);
                    CostVal lambda = (m_varWeights) ? m_horizWeights[n] : 1;
                    for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];
                }
                if (y < m_height-1)
                {
                    j = *(l+m_width);
                    CostVal lambda = (m_varWeights) ? m_vertWeights[n] : 1;
                    for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];
                }
            }

            // compute minimum of D, set new label for (x,y)
            CostVal D_min = D[0];
            *l = 0;
            for (i=1; i<m_nLabels; i++)
            {
                if (D_min > D[i])
                {
                    D_min = D[i];
                    *l = i;
                }
            }
        }
    }

    delete[] D;
}
Add texturemerge code. 2023-09-14 11:12:02 +02:00			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <assert.h>`
			`#include "ICM.h"`

			`#define m_D(pix,l) m_D[(pix)*m_nLabels+(l)]`
			`#define m_V(l1,l2) m_V[(l1)*m_nLabels+(l2)]`





			`ICM::ICM(int width, int height, int nLabels,EnergyFunction *eng):MRF(width,height,nLabels,eng)`
			`{`
			`m_needToFreeV = 0;`
			`initializeAlg();`
			`}`
			`ICM::ICM(int nPixels, int nLabels,EnergyFunction *eng):MRF(nPixels,nLabels,eng)`
			`{`
			`m_needToFreeV = 0;`
			`initializeAlg();`
			`}`

			`ICM::~ICM()`
			`{`
			`delete[] m_answer;`
			`if (!m_grid_graph) delete[] m_neighbors;`
			`if ( m_needToFreeV ) delete[] m_V;`
			`}`


			`void ICM::initializeAlg()`
			`{`
			`m_answer = (Label *) new Label[m_nPixels];`
			`if ( !m_answer ){printf("\nNot enough memory, exiting");exit(0);}`

			`if (!m_grid_graph)`
			`{`
			`m_neighbors = (LinkedBlockList *) new LinkedBlockList[m_nPixels];`
			`if (!m_neighbors) {printf("Not enough memory,exiting");exit(0);};`
			`}`
			`}`

			`void ICM::clearAnswer()`
			`{`
			`memset(m_answer, 0, m_nPixels*sizeof(Label));`
			`}`

			`void ICM::setNeighbors(int pixel1, int pixel2, CostVal weight)`
			`{`
			`assert(!m_grid_graph);`
			`assert(pixel1 < m_nPixels && pixel1 >= 0 && pixel2 < m_nPixels && pixel2 >= 0);`


			`Neighbor temp1 = (Neighbor ) new Neighbor;`
			`Neighbor temp2 = (Neighbor ) new Neighbor;`

			`if ( !temp1 \|\| ! temp2 ) {printf("\nNot enough memory, exiting");exit(0);}`

			`temp1->weight = weight;`
			`temp1->to_node = pixel2;`

			`temp2->weight = weight;`
			`temp2->to_node = pixel1;`

			`m_neighbors[pixel1].addFront(temp1);`
			`m_neighbors[pixel2].addFront(temp2);`
			`}`


			`MRF::EnergyVal ICM::smoothnessEnergy()`
			`{`
			`EnergyVal eng = (EnergyVal) 0;`
			`EnergyVal weight;`
			`int x,y,pix,i;`

			`if ( m_grid_graph )`
			`{`
			`if ( m_smoothType != FUNCTION )`
			`{`
			`for ( y = 0; y < m_height; y++ )`
			`for ( x = 1; x < m_width; x++ )`
			`{`
			`pix = x+y*m_width;`
			`weight = m_varWeights ? m_horizWeights[pix-1] : 1;`
			`eng = eng + m_V(m_answer[pix],m_answer[pix-1])*weight;`
			`}`

			`for ( y = 1; y < m_height; y++ )`
			`for ( x = 0; x < m_width; x++ )`
			`{`
			`pix = x+y*m_width;`
			`weight = m_varWeights ? m_vertWeights[pix-m_width] : 1;`
			`eng = eng + m_V(m_answer[pix],m_answer[pix-m_width])*weight;`
			`}`
			`}`
			`else`
			`{`
			`for ( y = 0; y < m_height; y++ )`
			`for ( x = 1; x < m_width; x++ )`
			`{`
			`pix = x+y*m_width;`
			`eng = eng + m_smoothFn(pix,pix-1,m_answer[pix],m_answer[pix-1]);`
			`}`

			`for ( y = 1; y < m_height; y++ )`
			`for ( x = 0; x < m_width; x++ )`
			`{`
			`pix = x+y*m_width;`
			`eng = eng + m_smoothFn(pix,pix-m_width,m_answer[pix],m_answer[pix-m_width]);`
			`}`
			`}`
			`}`
			`else`
			`{`

			`Neighbor *temp;`

			`if ( m_smoothType != FUNCTION )`
			`{`
			`for ( i = 0; i < m_nPixels; i++ )`
			`if ( !m_neighbors[i].isEmpty() )`
			`{`
			`m_neighbors[i].setCursorFront();`
			`while ( m_neighbors[i].hasNext() )`
			`{`
			`temp = (Neighbor *) m_neighbors[i].next();`

			`if ( i < temp->to_node )`
			`eng = eng + m_V(m_answer[i],m_answer[temp->to_node])*(temp->weight);`
			`}`
			`}`
			`}`
			`else`
			`{`
			`for ( i = 0; i < m_nPixels; i++ )`
			`if ( !m_neighbors[i].isEmpty() )`
			`{`
			`m_neighbors[i].setCursorFront();`
			`while ( m_neighbors[i].hasNext() )`
			`{`
			`temp = (Neighbor *) m_neighbors[i].next();`
			`if ( i < temp->to_node )`
			`eng = eng + m_smoothFn(i,temp->to_node, m_answer[i],m_answer[temp->to_node]);`
			`}`
			`}`
			`}`

			`}`

			`return(eng);`
			`}`



			`MRF::EnergyVal ICM::dataEnergy()`
			`{`
			`EnergyVal eng = (EnergyVal) 0;`


			`if ( m_dataType == ARRAY)`
			`{`
			`for ( int i = 0; i < m_nPixels; i++ )`
			`eng = eng + m_D(i,m_answer[i]);`
			`}`
			`else`
			`{`
			`for ( int i = 0; i < m_nPixels; i++ )`
			`eng = eng + m_dataFn(i,m_answer[i]);`
			`}`
			`return(eng);`

			`}`


			`void ICM::setData(DataCostFn dcost)`
			`{`
			`m_dataFn = dcost;`
			`}`

			`void ICM::setData(CostVal* data)`
			`{`
			`m_D = data;`
			`}`


			`void ICM::setSmoothness(SmoothCostGeneralFn cost)`
			`{`
			`m_smoothFn = cost;`
			`}`
			`void ICM::setSmoothness(CostVal* V)`
			`{`
			`m_V = V;`
			`}`


			`void ICM::setSmoothness(int smoothExp,CostVal smoothMax, CostVal lambda)`
			`{`
			`int i, j;`
			`CostVal cost;`


			`m_needToFreeV = 1;`

			`m_V = (CostVal ) new CostVal[m_nLabelsm_nLabels*sizeof(CostVal)];`
			`if (!m_V) { fprintf(stderr, "Not enough memory!\n"); exit(1); }`


			`for (i=0; i<m_nLabels; i++)`
			`for (j=i; j<m_nLabels; j++)`
			`{`
			`cost = (CostVal) ((smoothExp == 1) ? j - i : (j - i)*(j - i));`
			`if (cost > smoothMax) cost = smoothMax;`
			`m_V[im_nLabels + j] = m_V[jm_nLabels + i] = cost*lambda;`
			`}`

			`}`


			`void ICM::setCues(CostVal* hCue, CostVal* vCue)`
			`{`
			`m_horizWeights = hCue;`
			`m_vertWeights = vCue;`
			`}`


			`void ICM::optimizeAlg(int nIterations)`
			`{`
			`int x, y, i, j, n;`
			`Label* l;`
			`CostVal* dataPtr;`
			`CostVal D = (CostVal ) new CostVal[m_nLabels];`
			`if ( !D ) {printf("\nNot enough memory, exiting");exit(0);}`

			`if ( !m_grid_graph) {printf("\nICM is not implemented for nongrids yet!");exit(1);}`

			`for ( ; nIterations > 0; nIterations --)`
			`{`
			`n = 0;`
			`l = m_answer;`
			`dataPtr = m_D;`

			`for (y=0; y<m_height; y++)`
			`for (x=0; x<m_width; x++, l++, dataPtr+=m_nLabels, n++)`
			`{`
			`// set array D`
			`if (m_dataType == FUNCTION)`
			`{`
			`for (i=0; i<m_nLabels; i++)`
			`{`
			`D[i] = m_dataFn(x+y*m_width, i);`
			`}`
			`}`
			`else memcpy(D, dataPtr, m_nLabels*sizeof(CostVal));`


			`// add smoothness costs`
			`if (m_smoothType == FUNCTION)`
			`{`
			`if (x > 0)`
			`{`
			`j = *(l-1);`
			`for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+ym_width-1, x+ym_width, j, i);`
			`}`
			`if (y > 0)`
			`{`
			`j = *(l-m_width);`
			`for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+ym_width-m_width,x+ym_width , j, i);`
			`}`
			`if (x < m_width-1)`
			`{`
			`j = *(l+1);`
			`for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+ym_width+1, x+ym_width, i, j);`
			`}`
			`if (y < m_height-1)`
			`{`
			`j = *(l+m_width);`
			`for (i=0; i<m_nLabels; i++) D[i] += m_smoothFn(x+ym_width+m_width, x+ym_width, i, j);`
			`}`
			`}`
			`else`
			`{`
			`if (x > 0)`
			`{`
			`j = *(l-1);`
			`CostVal lambda = (m_varWeights) ? m_horizWeights[n-1] : 1;`
			`for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];`
			`}`
			`if (y > 0)`
			`{`
			`j = *(l-m_width);`
			`CostVal lambda = (m_varWeights) ? m_vertWeights[n-m_width] : 1;`
			`for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];`
			`}`
			`if (x < m_width-1)`
			`{`
			`j = *(l+1);`
			`CostVal lambda = (m_varWeights) ? m_horizWeights[n] : 1;`
			`for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];`
			`}`
			`if (y < m_height-1)`
			`{`
			`j = *(l+m_width);`
			`CostVal lambda = (m_varWeights) ? m_vertWeights[n] : 1;`
			`for (i=0; i<m_nLabels; i++) D[i] += lambda * m_V[j*m_nLabels + i];`
			`}`
			`}`

			`// compute minimum of D, set new label for (x,y)`
			`CostVal D_min = D[0];`
			`*l = 0;`
			`for (i=1; i<m_nLabels; i++)`
			`{`
			`if (D_min > D[i])`
			`{`
			`D_min = D[i];`
			`*l = i;`
			`}`
			`}`
			`}`
			`}`

			`delete[] D;`
			`}`