cvhmmobs.cpp.svn-base

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#include "_cv.h"

//*F///////////////////////////////////////////////////////////////////////////////////////
//    Name: icvImgToObs_DCT_8u32f_C1R
//    Purpose: The function takes as input an image and returns the sequnce of observations
//             to be used with an embedded HMM; Each observation is top-left block of DCT
//             coefficient matrix.
//    Context:
//    Parameters: img     - pointer to the original image ROI
//                imgStep - full row width of the image in bytes
//                roi     - width and height of ROI in pixels
//                obs     - pointer to resultant observation vectors
//                dctSize - size of the block for which DCT is calculated
//                obsSize - size of top-left block of DCT coeffs matrix, which is treated
//                          as observation. Each observation vector consists of
//                          obsSize.width * obsSize.height floats.
//                          The following conditions should be satisfied:
//                          0 < objSize.width <= dctSize.width,
//                          0 < objSize.height <= dctSize.height.
//                delta   - dctBlocks are overlapped and this parameter specifies horizontal
//                          and vertical shift.
//    Returns:
//      CV_NO_ERR or error code
//    Notes:
//      The algorithm is following:
//          1. First, number of observation vectors per row and per column are calculated:
//
//             Nx = floor((roi.width - dctSize.width + delta.width)/delta.width);
//             Ny = floor((roi.height - dctSize.height + delta.height)/delta.height);
//
//             So, total number of observation vectors is Nx*Ny, and total size of
//             array obs must be >= Nx*Ny*obsSize.width*obsSize.height*sizeof(float).
//          2. Observation vectors are calculated in the following loop
//               ( actual implementation may be different ), where 
//               I[x1:x2,y1:y2] means block of pixels from source image with
//               x1 <= x < x2, y1 <= y < y2,
//               D[x1:x2,y1:y2] means sub matrix of DCT matrix D.
//               O[x,y] means observation vector that corresponds to position
//               (x*delta.width,y*delta.height) in the source image
//               ( all indices are counted from 0 ).
//
//               for( y = 0; y < Ny; y++ )
//               {
//                   for( x = 0; x < Nx; x++ )
//                   {
//                       D = DCT(I[x*delta.width : x*delta.width + dctSize.width,
//                                  y*delta.height : y*delta.height + dctSize.height]);
//                       O[x,y] = D[0:obsSize.width, 0:obsSize.height];
//                   }
//               }
//F*/

/*comment out the following line to make DCT be calculated in floating-point arithmetics*/
//#define _CV_INT_DCT

/* for integer DCT only */
#define DCT_SCALE  15

#ifdef _CV_INT_DCT
typedef int work_t;

#define  DESCALE      CV_DESCALE
#define  SCALE(x)     CV_FLT_TO_FIX((x),DCT_SCALE)
#else
typedef float work_t;

#define  DESCALE(x,n) (float)(x)
#define  SCALE(x)     (float)(x)
#endif

/* calculate dct transform matrix */
static void icvCalcDCTMatrix( work_t * cfs, int n );

#define  MAX_DCT_SIZE  32

IPCVAPI( CvStatus, icvImgToObs_DCT_8u32f_C1R, ( uchar* img, int imgStep, CvSize roi,
                                                float* obs, CvSize dctSize,
                                                CvSize obsSize, CvSize delta ))

IPCVAPI_IMPL( CvStatus, icvImgToObs_DCT_8u32f_C1R, (uchar * img, int imgStep, CvSize roi,
                                                    float *obs, CvSize dctSize,
                                                    CvSize obsSize, CvSize delta) )
{
    /* dct transform matrices: horizontal and vertical */
    work_t tab_x[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];
    work_t tab_y[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];

    /* temporary buffers for dct */
    work_t temp0[MAX_DCT_SIZE * 4];
    work_t temp1[MAX_DCT_SIZE * 4];
    work_t *buffer = 0;
    work_t *buf_limit;

    double s;

    int y;
    int Nx, Ny;

    int n1 = dctSize.height, m1 = n1 / 2;
    int n2 = dctSize.width, m2 = n2 / 2;

    if( !img || !obs )
        return CV_NULLPTR_ERR;

    if( roi.width <= 0 || roi.height <= 0 )
        return CV_BADSIZE_ERR;

    if( delta.width <= 0 || delta.height <= 0 )
        return CV_BADRANGE_ERR;

    if( obsSize.width <= 0 || dctSize.width < obsSize.width ||
        obsSize.height <= 0 || dctSize.height < obsSize.height )
        return CV_BADRANGE_ERR;

    if( dctSize.width > MAX_DCT_SIZE || dctSize.height > MAX_DCT_SIZE )
        return CV_BADRANGE_ERR;

    Nx = (roi.width - dctSize.width + delta.width) / delta.width;
    Ny = (roi.height - dctSize.height + delta.height) / delta.height;

    if( Nx <= 0 || Ny <= 0 )
        return CV_BADRANGE_ERR;

    buffer = (work_t *) icvAlloc( roi.width * obsSize.height * sizeof( buffer[0] ));
    if( !buffer )
        return CV_OUTOFMEM_ERR;

    icvCalcDCTMatrix( tab_x, dctSize.width );
    icvCalcDCTMatrix( tab_y, dctSize.height );

    buf_limit = buffer + obsSize.height * roi.width;

    for( y = 0; y < Ny; y++, img += delta.height * imgStep )
    {
        int x, i, j, k;
        work_t k0 = 0;

        /* do transfroms for each column. Calc only first obsSize.height DCT coefficients */
        for( x = 0; x < roi.width; x++ )
        {
            float is = 0;
            work_t *buf = buffer + x;
            work_t *tab = tab_y + 2;

            if( n1 & 1 )
            {
                is = img[x + m1 * imgStep];
                k0 = ((work_t) is) * tab[-1];
            }

            /* first coefficient */
            for( j = 0; j < m1; j++ )
            {
                float t0 = img[x + j * imgStep];
                float t1 = img[x + (n1 - 1 - j) * imgStep];
                float t2 = t0 + t1;

                t0 -= t1;
                temp0[j] = (work_t) t2;
                is += t2;
                temp1[j] = (work_t) t0;
            }

            buf[0] = DESCALE( is * tab[-2], PASS1_SHIFT );
            if( (buf += roi.width) >= buf_limit )
                continue;

            /* other coefficients */
            for( ;; )
            {
                s = 0;

                for( k = 0; k < m1; k++ )
                    s += temp1[k] * tab[k];

                buf[0] = DESCALE( s, PASS1_SHIFT );
                if( (buf += roi.width) >= buf_limit )
                    break;

                tab += m1;
                s = 0;

                if( n1 & 1 )
                {
                    k0 = -k0;
                    s = k0;
                }
                for( k = 0; k < m1; k++ )
                    s += temp0[k] * tab[k];

                buf[0] = DESCALE( s, PASS1_SHIFT );
                tab += m1;

                if( (buf += roi.width) >= buf_limit )
                    break;
            }
        }

        k0 = 0;

        /* do transforms for rows. */
        for( x = 0; x + dctSize.width <= roi.width; x += delta.width )
        {
            for( i = 0; i < obsSize.height; i++ )
            {
                work_t *buf = buffer + x + roi.width * i;
                work_t *tab = tab_x + 2;
                float *obs_limit = obs + obsSize.width;

                s = 0;

                if( n2 & 1 )
                {
                    s = buf[m2];
                    k0 = (work_t) (s * tab[-1]);
                }

                /* first coefficient */
                for( j = 0; j < m2; j++ )
                {
                    work_t t0 = buf[j];
                    work_t t1 = buf[n2 - 1 - j];
                    work_t t2 = t0 + t1;

                    t0 -= t1;
                    temp0[j] = (work_t) t2;
                    s += t2;
                    temp1[j] = (work_t) t0;
                }

                *obs++ = (float) DESCALE( s * tab[-2], PASS2_SHIFT );

                if( obs == obs_limit )
                    continue;

                /* other coefficients */
                for( ;; )
                {
                    s = 0;

                    for( k = 0; k < m2; k++ )
                        s += temp1[k] * tab[k];

                    obs[0] = (float) DESCALE( s, PASS2_SHIFT );
                    if( ++obs == obs_limit )
                        break;

                    tab += m2;

                    s = 0;

                    if( n2 & 1 )
                    {
                        k0 = -k0;
                        s = k0;
                    }
                    for( k = 0; k < m2; k++ )
                        s += temp0[k] * tab[k];
                    obs[0] = (float) DESCALE( s, PASS2_SHIFT );

                    tab += m2;
                    if( ++obs == obs_limit )
                        break;
                }
            }
        }
    }

    icvFree( &buffer );
    return CV_NO_ERR;
}


IPCVAPI( CvStatus, icvImgToObs_DCT_32f_C1R, (float * img, int imgStep, CvSize roi,
                                             float *obs, CvSize dctSize,
                                             CvSize obsSize, CvSize delta) )

IPCVAPI_IMPL( CvStatus, icvImgToObs_DCT_32f_C1R, (float * img, int imgStep, CvSize roi,
                                                  float *obs, CvSize dctSize,
                                                  CvSize obsSize, CvSize delta) )
{