/*====================================================================*
 -  Copyright (C) 2001 Leptonica.  All rights reserved.
 -  This software is distributed in the hope that it will be
 -  useful, but with NO WARRANTY OF ANY KIND.
 -  No author or distributor accepts responsibility to anyone for the
 -  consequences of using this software, or for whether it serves any
 -  particular purpose or works at all, unless he or she says so in
 -  writing.  Everyone is granted permission to copy, modify and
 -  redistribute this source code, for commercial or non-commercial
 -  purposes, with the following restrictions: (1) the origin of this
 -  source code must not be misrepresented; (2) modified versions must
 -  be plainly marked as such; and (3) this notice may not be removed
 -  or altered from any source or modified source distribution.
 *====================================================================*/

/*
 * dwamorph3_reg.c
 *
 *     Compare the timings of various binary morphological implementations.
 */

#include <stdio.h>
#include <stdlib.h>
#include "allheaders.h"

#define  HALFWIDTH   3

    /* Complete set of linear brick dwa operations */
PIX *pixMorphDwa_3(PIX *pixd, PIX *pixs, l_int32 operation, char *selname);

static const l_int32  NTIMES = 20;

main(int    argc,
     char **argv)
{
char        *filein, *selname;
l_int32      i, j, nsels, sx, sy;
l_float32    fact, time;
GPLOT       *gplot;
NUMA        *na1, *na2, *na3, *na4, *nac1, *nac2, *nac3, *nac4, *nax;
PIX         *pixs, *pixt;
SEL         *sel;
SELA        *selalinear;
static char  mainName[] = "dwamorph3_reg";

    if (argc != 2)
	exit(ERROR_INT(" Syntax:  dwamorph3_reg filein", mainName, 1));

    filein = argv[1];
    if ((pixs = pixRead(filein)) == NULL)
	exit(ERROR_INT("pix not made", mainName, 1));
    pixt = pixCreateTemplate(pixs);

    selalinear = selaAddDwaLinear(NULL);
    nsels = selaGetCount(selalinear);

    fact = 1000. / (l_float32)NTIMES;  /* converts to time in msec */
    na1 = numaCreate(64);
    na2 = numaCreate(64);
    na3 = numaCreate(64);
    na4 = numaCreate(64);

        /*  ---------  dilation  ----------*/

    for (i = 0; i < nsels / 2; i++)
    {
        sel = selaGetSel(selalinear, i);
        selGetParameters(sel, &sy, &sx, NULL, NULL);
        selname = selGetName(sel);
	fprintf(stderr, " %d .", i);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixDilate(pixt, pixs, sel);
        time = fact * stopTimer();
        numaAddNumber(na1, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixDilateCompBrick(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na2, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixMorphDwa_3(pixt, pixs, L_MORPH_DILATE, selname);
        time = fact * stopTimer();
        numaAddNumber(na3, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixDilateCompBrickDwa(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na4, time);
    }

    nax = numaMakeSequence(2, 1, nsels / 2);
    nac1 = numaConvolve(na1, HALFWIDTH);
    nac2 = numaConvolve(na2, HALFWIDTH);
    nac3 = numaConvolve(na3, HALFWIDTH);
    nac4 = numaConvolve(na4, HALFWIDTH);
    gplot = gplotCreate("junkdilate", GPLOT_PNG, "Dilation time vs sel size",
                        "size", "time (ms)");
    gplotAddPlot(gplot, nax, nac1, GPLOT_LINES, "linear rasterop");
    gplotAddPlot(gplot, nax, nac2, GPLOT_LINES, "composite rasterop");
    gplotAddPlot(gplot, nax, nac3, GPLOT_LINES, "linear dwa");
    gplotAddPlot(gplot, nax, nac4, GPLOT_LINES, "composite dwa");
    gplotMakeOutput(gplot);
    gplotDestroy(&gplot);
    numaDestroy(&nac1);
    numaDestroy(&nac2);
    numaDestroy(&nac3);
    numaDestroy(&nac4);

        /*  ---------  erosion  ----------*/

    numaEmpty(na1);
    numaEmpty(na2);
    numaEmpty(na3);
    numaEmpty(na4);
    for (i = 0; i < nsels / 2; i++)
    {
        sel = selaGetSel(selalinear, i);
        selGetParameters(sel, &sy, &sx, NULL, NULL);
        selname = selGetName(sel);
	fprintf(stderr, " %d .", i);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixErode(pixt, pixs, sel);
        time = fact * stopTimer();
        numaAddNumber(na1, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixErodeCompBrick(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na2, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixMorphDwa_3(pixt, pixs, L_MORPH_ERODE, selname);
        time = fact * stopTimer();
        numaAddNumber(na3, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixErodeCompBrickDwa(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na4, time);
    }

    nac1 = numaConvolve(na1, HALFWIDTH);
    nac2 = numaConvolve(na2, HALFWIDTH);
    nac3 = numaConvolve(na3, HALFWIDTH);
    nac4 = numaConvolve(na4, HALFWIDTH);
    gplot = gplotCreate("junkerode", GPLOT_PNG, "Erosion time vs sel size",
                        "size", "time (ms)");
    gplotAddPlot(gplot, nax, nac1, GPLOT_LINES, "linear rasterop");
    gplotAddPlot(gplot, nax, nac2, GPLOT_LINES, "composite rasterop");
    gplotAddPlot(gplot, nax, nac3, GPLOT_LINES, "linear dwa");
    gplotAddPlot(gplot, nax, nac4, GPLOT_LINES, "composite dwa");
    gplotMakeOutput(gplot);
    gplotDestroy(&gplot);
    numaDestroy(&nac1);
    numaDestroy(&nac2);
    numaDestroy(&nac3);
    numaDestroy(&nac4);

        /*  ---------  opening  ----------*/

    numaEmpty(na1);
    numaEmpty(na2);
    numaEmpty(na3);
    numaEmpty(na4);
    for (i = 0; i < nsels / 2; i++)
    {
        sel = selaGetSel(selalinear, i);
        selGetParameters(sel, &sy, &sx, NULL, NULL);
        selname = selGetName(sel);
	fprintf(stderr, " %d .", i);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixOpen(pixt, pixs, sel);
        time = fact * stopTimer();
        numaAddNumber(na1, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixOpenCompBrick(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na2, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixMorphDwa_3(pixt, pixs, L_MORPH_OPEN, selname);
        time = fact * stopTimer();
        numaAddNumber(na3, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixOpenCompBrickDwa(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na4, time);
    }

    nac1 = numaConvolve(na1, HALFWIDTH);
    nac2 = numaConvolve(na2, HALFWIDTH);
    nac3 = numaConvolve(na3, HALFWIDTH);
    nac4 = numaConvolve(na4, HALFWIDTH);
    gplot = gplotCreate("junkopen", GPLOT_PNG, "Opening time vs sel size",
                        "size", "time (ms)");
    gplotAddPlot(gplot, nax, nac1, GPLOT_LINES, "linear rasterop");
    gplotAddPlot(gplot, nax, nac2, GPLOT_LINES, "composite rasterop");
    gplotAddPlot(gplot, nax, nac3, GPLOT_LINES, "linear dwa");
    gplotAddPlot(gplot, nax, nac4, GPLOT_LINES, "composite dwa");
    gplotMakeOutput(gplot);
    gplotDestroy(&gplot);
    numaDestroy(&nac1);
    numaDestroy(&nac2);
    numaDestroy(&nac3);
    numaDestroy(&nac4);

        /*  ---------  closing  ----------*/

    numaEmpty(na1);
    numaEmpty(na2);
    numaEmpty(na3);
    numaEmpty(na4);
    for (i = 0; i < nsels / 2; i++)
    {
        sel = selaGetSel(selalinear, i);
        selGetParameters(sel, &sy, &sx, NULL, NULL);
        selname = selGetName(sel);
	fprintf(stderr, " %d .", i);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixClose(pixt, pixs, sel);
        time = fact * stopTimer();
        numaAddNumber(na1, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixCloseCompBrick(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na2, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixMorphDwa_3(pixt, pixs, L_MORPH_CLOSE, selname);
        time = fact * stopTimer();
        numaAddNumber(na3, time);

        startTimer();
        for (j = 0; j < NTIMES; j++)
            pixCloseCompBrickDwa(pixt, pixs, sx, sy);
        time = fact * stopTimer();
        numaAddNumber(na4, time);
    }

    nac1 = numaConvolve(na1, HALFWIDTH);
    nac2 = numaConvolve(na2, HALFWIDTH);
    nac3 = numaConvolve(na3, HALFWIDTH);
    nac4 = numaConvolve(na4, HALFWIDTH);
    gplot = gplotCreate("junkclose", GPLOT_PNG, "Closing time vs sel size",
                        "size", "time (ms)");
    gplotAddPlot(gplot, nax, nac1, GPLOT_LINES, "linear rasterop");
    gplotAddPlot(gplot, nax, nac2, GPLOT_LINES, "composite rasterop");
    gplotAddPlot(gplot, nax, nac3, GPLOT_LINES, "linear dwa");
    gplotAddPlot(gplot, nax, nac4, GPLOT_LINES, "composite dwa");
    gplotMakeOutput(gplot);
    gplotDestroy(&gplot);
    numaDestroy(&nac1);
    numaDestroy(&nac2);
    numaDestroy(&nac3);
    numaDestroy(&nac4);


    numaDestroy(&na1);
    numaDestroy(&na2);
    numaDestroy(&na3);
    numaDestroy(&na4);
    numaDestroy(&nax);
    selaDestroy(&selalinear);
    pixDestroy(&pixt);
    pixDestroy(&pixs);
    return 0;
}

#if 0
    resetMorphBoundaryCondition(ASYMMETRIC_MORPH_BC);
    fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

    pixt1 = pixErode(NULL, pixs, sel);
    pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_ERODE, selname);
    pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "erosions are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "erosions differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);

	    /*  ---------  erosion with symmetric b.c  ----------*/

        resetMorphBoundaryCondition(SYMMETRIC_MORPH_BC);
        fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

	pixt1 = pixErode(NULL, pixs, sel);
        pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_ERODE, selname);
        pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "erosions are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "erosions differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);

	    /*  ---------  opening with asymmetric b.c  ----------*/

        resetMorphBoundaryCondition(ASYMMETRIC_MORPH_BC);
        fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

	pixt1 = pixOpen(NULL, pixs, sel);
        pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_OPEN, selname);
        pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "openings are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "openings differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);

	    /*  ---------  opening with symmetric b.c  ----------*/

        resetMorphBoundaryCondition(SYMMETRIC_MORPH_BC);
        fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

	pixt1 = pixOpen(NULL, pixs, sel);
        pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_OPEN, selname);
        pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "openings are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "openings differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);

	    /*  ---------  safe closing with asymmetric b.c  ----------*/

        resetMorphBoundaryCondition(ASYMMETRIC_MORPH_BC);
        fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

	pixt1 = pixCloseSafe(NULL, pixs, sel);  /* must use safe version */
        pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_CLOSE, selname);
        pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "closings are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "closings differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);

	    /*  ---------  safe closing with symmetric b.c  ----------*/

        resetMorphBoundaryCondition(SYMMETRIC_MORPH_BC);
        fprintf(stderr, "MORPH_BC = %d ... ", MORPH_BC);

	pixt1 = pixClose(NULL, pixs, sel);  /* safe version not required */
        pixt2 = pixMorphDwa_3(NULL, pixs, L_MORPH_CLOSE, selname);
        pixEqual(pixt1, pixt2, &same);

	if (same == 1) {
	    fprintf(stderr, "closings are identical for sel %d (%s)\n",
	            i, selname);
	}
	else {
	    fprintf(stderr, "closings differ for sel %d (%s)\n", i, selname);
	    pixt3 = pixXor(NULL, pixt1, pixt2);
	    pixCountPixels(pixt3, &xorcount, NULL);
	    fprintf(stderr, "Number of pixels in XOR: %d\n", xorcount);
            pixDestroy(&pixt3);
	}
	pixDestroy(&pixt1);
	pixDestroy(&pixt2);
    }
#endif