l_int32 main(int argc, char **argv) { l_int32 i, n; l_float32 a, b, c, d, e; NUMA *nax, *nafit; PIX *pixs, *pixn, *pixg, *pixb, *pixt1, *pixt2; PIXA *pixa; PTA *pta, *ptad; PTAA *ptaa1, *ptaa2; pixs = pixRead("cat-35.jpg"); /* pixs = pixRead("zanotti-78.jpg"); */ /* Normalize for varying background and binarize */ pixn = pixBackgroundNormSimple(pixs, NULL, NULL); pixg = pixConvertRGBToGray(pixn, 0.5, 0.3, 0.2); pixb = pixThresholdToBinary(pixg, 130); pixDestroy(&pixn); pixDestroy(&pixg); /* Get the textline centers */ pixa = pixaCreate(6); ptaa1 = dewarpGetTextlineCenters(pixb, 0); pixt1 = pixCreateTemplate(pixs); pixSetAll(pixt1); pixt2 = pixDisplayPtaa(pixt1, ptaa1); pixWrite("/tmp/textline1.png", pixt2, IFF_PNG); pixDisplayWithTitle(pixt2, 0, 100, "textline centers 1", 1); pixaAddPix(pixa, pixt2, L_INSERT); pixDestroy(&pixt1); /* Remove short lines */ fprintf(stderr, "Num all lines = %d\n", ptaaGetCount(ptaa1)); ptaa2 = dewarpRemoveShortLines(pixb, ptaa1, 0.8, 0); pixt1 = pixCreateTemplate(pixs); pixSetAll(pixt1); pixt2 = pixDisplayPtaa(pixt1, ptaa2); pixWrite("/tmp/textline2.png", pixt2, IFF_PNG); pixDisplayWithTitle(pixt2, 300, 100, "textline centers 2", 1); pixaAddPix(pixa, pixt2, L_INSERT); pixDestroy(&pixt1); n = ptaaGetCount(ptaa2); fprintf(stderr, "Num long lines = %d\n", n); ptaaDestroy(&ptaa1); pixDestroy(&pixb); /* Long lines over input image */ pixt1 = pixCopy(NULL, pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa2); pixWrite("/tmp/textline3.png", pixt2, IFF_PNG); pixDisplayWithTitle(pixt2, 600, 100, "textline centers 3", 1); pixaAddPix(pixa, pixt2, L_INSERT); pixDestroy(&pixt1); /* Quadratic fit to curve */ pixt1 = pixCopy(NULL, pixs); for (i = 0; i < n; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); ptaGetQuadraticLSF(pta, &a, &b, &c, &nafit); fprintf(stderr, "Quadratic: a = %10.6f, b = %7.3f, c = %7.3f\n", a, b, c); ptad = ptaCreateFromNuma(nax, nafit); pixDisplayPta(pixt1, pixt1, ptad); ptaDestroy(&pta); ptaDestroy(&ptad); numaDestroy(&nax); numaDestroy(&nafit); } pixWrite("/tmp/textline4.png", pixt1, IFF_PNG); pixDisplayWithTitle(pixt1, 900, 100, "textline centers 4", 1); pixaAddPix(pixa, pixt1, L_INSERT); /* Cubic fit to curve */ pixt1 = pixCopy(NULL, pixs); for (i = 0; i < n; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); ptaGetCubicLSF(pta, &a, &b, &c, &d, &nafit); fprintf(stderr, "Cubic: a = %10.6f, b = %10.6f, c = %7.3f, d = %7.3f\n", a, b, c, d); ptad = ptaCreateFromNuma(nax, nafit); pixDisplayPta(pixt1, pixt1, ptad); ptaDestroy(&pta); ptaDestroy(&ptad); numaDestroy(&nax); numaDestroy(&nafit); } pixWrite("/tmp/textline5.png", pixt1, IFF_PNG); pixDisplayWithTitle(pixt1, 1200, 100, "textline centers 5", 1); pixaAddPix(pixa, pixt1, L_INSERT); /* Quartic fit to curve */ pixt1 = pixCopy(NULL, pixs); for (i = 0; i < n; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); ptaGetQuarticLSF(pta, &a, &b, &c, &d, &e, &nafit); fprintf(stderr, "Quartic: a = %7.3f, b = %7.3f, c = %9.5f, d = %7.3f, e = %7.3f\n", a, b, c, d, e); ptad = ptaCreateFromNuma(nax, nafit); pixDisplayPta(pixt1, pixt1, ptad); ptaDestroy(&pta); ptaDestroy(&ptad); numaDestroy(&nax); numaDestroy(&nafit); } pixWrite("/tmp/textline6.png", pixt1, IFF_PNG); pixDisplayWithTitle(pixt1, 1500, 100, "textline centers 6", 1); pixaAddPix(pixa, pixt1, L_INSERT); pixaConvertToPdf(pixa, 300, 0.5, L_JPEG_ENCODE, 75, "LS fittings to textlines", "/tmp/dewarp_fittings.pdf"); pixaDestroy(&pixa); pixDestroy(&pixs); ptaaDestroy(&ptaa2); return 0; }
l_int32 main(int argc, char **argv) { l_int32 i, n, ignore; l_float32 a, b, c, d, e; L_DEWARP *dew; FILE *fp; FPIX *fpix; NUMA *nax, *nay, *nafit; PIX *pixs, *pixn, *pixg, *pixb, *pixt1, *pixt2, *pixt3; PIX *pixs2, *pixn2, *pixg2, *pixb2, *pixv, *pixd; PTA *pta, *ptad; PTAA *ptaa1, *ptaa2; pixs = pixRead("1555-7.jpg"); /* Normalize for varying background and binarize */ pixn = pixBackgroundNormSimple(pixs, NULL, NULL); pixg = pixConvertRGBToGray(pixn, 0.5, 0.3, 0.2); pixb = pixThresholdToBinary(pixg, 130); /* Run the basic functions */ dew = dewarpCreate(pixb, 7, 30, 15, 1); dewarpBuildModel(dew, 1); dewarpApplyDisparity(dew, pixg, 1); /* Save the intermediate dewarped images */ pixv = pixRead("/tmp/pixv.png"); pixd = pixRead("/tmp/pixd.png"); /* Normalize another image, that doesn't have enough textlines * to build an accurate model */ pixs2 = pixRead("1555-3.jpg"); pixn2 = pixBackgroundNormSimple(pixs2, NULL, NULL); pixg2 = pixConvertRGBToGray(pixn2, 0.5, 0.3, 0.2); pixb2 = pixThresholdToBinary(pixg2, 130); /* Apply the previous disparity model to this image */ dewarpApplyDisparity(dew, pixg2, 1); dewarpDestroy(&dew); /* Get the textline centers */ const char* const morph2 = "c15.1 + o15.1 + c50.1"; ptaa1 = pixGetTextlineCenters(pixb,morph2, 0); pixt1 = pixCreateTemplate(pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa1); pixWrite("/tmp/textline1.png", pixt2, IFF_PNG); pixDisplayWithTitle(pixt2, 500, 100, "textline centers", 1); pixDestroy(&pixt1); /* Remove short lines */ fprintf(stderr, "Num all lines = %d\n", ptaaGetCount(ptaa1)); ptaa2 = ptaaRemoveShortLines(pixb, ptaa1, 0.8, 0); /* Fit to curve */ n = ptaaGetCount(ptaa2); fprintf(stderr, "Num long lines = %d\n", n); for (i = 0; i < n; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); #if DO_QUAD ptaGetQuadraticLSF(pta, &a, &b, &c, &nafit); /* fprintf(stderr, "a = %7.3f, b = %7.3f, c = %7.3f\n", a, b, c); */ #elif DO_CUBIC ptaGetCubicLSF(pta, &a, &b, &c, &d, &nafit); /* fprintf(stderr, "a = %7.3f, b = %7.3f, c = %7.3f, d = %7.3f\n", a, b, c, d); */ #elif DO_QUARTIC ptaGetQuarticLSF(pta, &a, &b, &c, &d, &e, &nafit); /* fprintf(stderr, "a = %7.3f, b = %7.3f, c = %7.3f, d = %7.3f, e = %7.3f\n", a, b, c, d, e); */ #endif ptad = ptaCreateFromNuma(nax, nafit); pixDisplayPta(pixt2, pixt2, ptad); ptaDestroy(&pta); ptaDestroy(&ptad); numaDestroy(&nax); numaDestroy(&nafit); } pixDisplayWithTitle(pixt2, 700, 100, "fitted lines superimposed", 1); pixWrite("/tmp/textline2.png", pixt2, IFF_PNG); ptaaDestroy(&ptaa1); ptaaDestroy(&ptaa2); pixDestroy(&pixt2); /* Write out the files to be imaged */ lept_mkdir("junkdir"); pixWrite("/tmp/junkdir/001.jpg", pixs, IFF_JFIF_JPEG); pixWrite("/tmp/junkdir/002.jpg", pixn, IFF_JFIF_JPEG); pixWrite("/tmp/junkdir/003.jpg", pixg, IFF_JFIF_JPEG); pixWrite("/tmp/junkdir/004.png", pixb, IFF_TIFF_G4); pixt1 = pixRead("/tmp/textline1.png"); pixWrite("/tmp/junkdir/005.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixt1 = pixRead("/tmp/textline2.png"); pixWrite("/tmp/junkdir/006.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixt1 = pixRead("/tmp/lines1.png"); pixWrite("/tmp/junkdir/007.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixt1 = pixRead("/tmp/lines2.png"); pixWrite("/tmp/junkdir/008.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixt1 = pixRead("/tmp/vert-contours.png"); pixWrite("/tmp/junkdir/009.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixWrite("/tmp/junkdir/010.png", pixv, IFF_PNG); pixt1 = pixThresholdToBinary(pixv, 130); pixWrite("/tmp/junkdir/011.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixt1 = pixRead("/tmp/horiz-contours.png"); pixWrite("/tmp/junkdir/012.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixWrite("/tmp/junkdir/013.png", pixd, IFF_PNG); pixt1 = pixThresholdToBinary(pixd, 130); pixWrite("/tmp/junkdir/014.png", pixt1, IFF_PNG); pixDestroy(&pixt1); pixWrite("/tmp/junkdir/015.png", pixb, IFF_TIFF_G4); /* (these are for the second image) */ pixWrite("/tmp/junkdir/016.jpg", pixs2, IFF_JFIF_JPEG); pixWrite("/tmp/junkdir/017.png", pixb2, IFF_TIFF_G4); pixt1 = pixRead("/tmp/pixv.png"); pixt2 = pixThresholdToBinary(pixt1, 130); pixWrite("/tmp/junkdir/018.png", pixt2, IFF_PNG); pixDestroy(&pixt1); pixDestroy(&pixt2); pixt1 = pixRead("/tmp/pixd.png"); pixt2 = pixThresholdToBinary(pixt1, 130); pixWrite("/tmp/junkdir/019.png", pixt2, IFF_PNG); pixDestroy(&pixt1); pixDestroy(&pixt2); /* Generate the 19 page ps and pdf files */ convertFilesToPS("/tmp/junkdir", NULL, 135, "/tmp/dewarp.ps"); fprintf(stderr, "ps file made: /tmp/dewarp.ps\n"); ignore = system("ps2pdf /tmp/dewarp.ps /tmp/dewarp.pdf"); fprintf(stderr, "pdf file made: /tmp/dewarp.pdf\n"); pixDestroy(&pixs); pixDestroy(&pixn); pixDestroy(&pixg); pixDestroy(&pixb); pixDestroy(&pixs2); pixDestroy(&pixn2); pixDestroy(&pixg2); pixDestroy(&pixb2); pixDestroy(&pixv); pixDestroy(&pixd); return 0; }
/*! * dewarpBuildModel() * * Input: dew * debugflag (1 for debugging output) * Return: 0 if OK, 1 on error * * Notes: * (1) This is the basic function that builds the vertical * disparity array, which allows determination of the * src pixel in the input image corresponding to each * dest pixel in the dewarped image. * (2) The method is as follows: * * Estimate the centers of all the long textlines and * fit a LS quadratic to each one. This smooths the curves. * * Sample each curve at a regular interval, find the y-value * of the flat point on each curve, and subtract the sampled * curve value from this value. This is the vertical * disparity. * * Fit a LS quadratic to each set of vertically aligned * disparity samples. This smooths the disparity values * in the vertical direction. Then resample at the same * regular interval, We now have a regular grid of smoothed * vertical disparity valuels. * * Interpolate this grid to get a full resolution disparity * map. This can be applied directly to the src image * pixels to dewarp the image in the vertical direction, * making all textlines horizontal. */ l_int32 dewarpBuildModel(L_DEWARP *dew, l_int32 debugflag) { char *tempname; l_int32 i, j, nlines, nx, ny, sampling; l_float32 c0, c1, c2, x, y, flaty, val; l_float32 *faflats; NUMA *nax, *nafit, *nacurve, *nacurves, *naflat, *naflats, *naflatsi; PIX *pixs, *pixt1, *pixt2; PTA *pta, *ptad; PTAA *ptaa1, *ptaa2, *ptaa3, *ptaa4, *ptaa5, *ptaa6, *ptaa7; FPIX *fpix1, *fpix2, *fpix3; PROCNAME("dewarpBuildModel"); if (!dew) return ERROR_INT("dew not defined", procName, 1); pixs = dew->pixs; if (debugflag) { pixDisplayWithTitle(pixs, 0, 0, "pixs", 1); pixWriteTempfile("/tmp", "pixs.png", pixs, IFF_PNG, NULL); } /* Make initial estimate of centers of textlines */ ptaa1 = pixGetTextlineCenters(pixs, DEBUG_TEXTLINE_CENTERS); if (debugflag) { pixt1 = pixConvertTo32(pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa1); pixWriteTempfile("/tmp", "lines1.png", pixt2, IFF_PNG, NULL); pixDestroy(&pixt1); pixDestroy(&pixt2); } /* Remove all lines that are not near the length * of the longest line. */ ptaa2 = ptaaRemoveShortLines(pixs, ptaa1, 0.8, DEBUG_SHORT_LINES); if (debugflag) { pixt1 = pixConvertTo32(pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa2); pixWriteTempfile("/tmp", "lines2.png", pixt2, IFF_PNG, NULL); pixDestroy(&pixt1); pixDestroy(&pixt2); } nlines = ptaaGetCount(ptaa2); if (nlines < dew->minlines) return ERROR_INT("insufficient lines to build model", procName, 1); /* Do quadratic fit to smooth each line. A single quadratic * over the entire width of the line appears to be sufficient. * Quartics tend to overfit to noise. Each line is thus * represented by three coefficients: c2 * x^2 + c1 * x + c0. * Using the coefficients, sample each fitted curve uniformly * across the full width of the image. */ sampling = dew->sampling; nx = dew->nx; ny = dew->ny; ptaa3 = ptaaCreate(nlines); nacurve = numaCreate(nlines); /* stores curvature coeff c2 */ for (i = 0; i < nlines; i++) { /* for each line */ pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetQuadraticLSF(pta, &c2, &c1, &c0, NULL); numaAddNumber(nacurve, c2); ptad = ptaCreate(nx); for (j = 0; j < nx; j++) { /* uniformly sampled in x */ x = j * sampling; applyQuadraticFit(c2, c1, c0, x, &y); ptaAddPt(ptad, x, y); } ptaaAddPta(ptaa3, ptad, L_INSERT); ptaDestroy(&pta); } if (debugflag) { ptaa4 = ptaaCreate(nlines); for (i = 0; i < nlines; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); ptaGetQuadraticLSF(pta, NULL, NULL, NULL, &nafit); ptad = ptaCreateFromNuma(nax, nafit); ptaaAddPta(ptaa4, ptad, L_INSERT); ptaDestroy(&pta); numaDestroy(&nax); numaDestroy(&nafit); } pixt1 = pixConvertTo32(pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa4); pixWriteTempfile("/tmp", "lines3.png", pixt2, IFF_PNG, NULL); pixDestroy(&pixt1); pixDestroy(&pixt2); ptaaDestroy(&ptaa4); } /* Find and save the flat points in each curve. */ naflat = numaCreate(nlines); for (i = 0; i < nlines; i++) { pta = ptaaGetPta(ptaa3, i, L_CLONE); numaGetFValue(nacurve, i, &c2); if (c2 <= 0) /* flat point at bottom; max value of y in curve */ ptaGetRange(pta, NULL, NULL, NULL, &flaty); else /* flat point at top; min value of y in curve */ ptaGetRange(pta, NULL, NULL, &flaty, NULL); numaAddNumber(naflat, flaty); ptaDestroy(&pta); } /* Sort the lines in ptaa3 by their position */ naflatsi = numaGetSortIndex(naflat, L_SORT_INCREASING); naflats = numaSortByIndex(naflat, naflatsi); nacurves = numaSortByIndex(nacurve, naflatsi); dew->naflats = naflats; dew->nacurves = nacurves; ptaa4 = ptaaSortByIndex(ptaa3, naflatsi); numaDestroy(&naflat); numaDestroy(&nacurve); numaDestroy(&naflatsi); if (debugflag) { tempname = genTempFilename("/tmp", "naflats.na", 0); numaWrite(tempname, naflats); FREE(tempname); } /* Convert the sampled points in ptaa3 to a sampled disparity with * with respect to the flat point in the curve. */ ptaa5 = ptaaCreate(nlines); for (i = 0; i < nlines; i++) { pta = ptaaGetPta(ptaa4, i, L_CLONE); numaGetFValue(naflats, i, &flaty); ptad = ptaCreate(nx); for (j = 0; j < nx; j++) { ptaGetPt(pta, j, &x, &y); ptaAddPt(ptad, x, flaty - y); } ptaaAddPta(ptaa5, ptad, L_INSERT); ptaDestroy(&pta); } if (debugflag) { tempname = genTempFilename("/tmp", "ptaa5.ptaa", 0); ptaaWrite(tempname, ptaa5, 0); FREE(tempname); } /* Generate a ptaa taking vertical 'columns' from ptaa5. * We want to fit the vertical disparity on the column to the * vertical position of the line, which we call 'y' here and * obtain from naflats. */ ptaa6 = ptaaCreate(nx); faflats = numaGetFArray(naflats, L_NOCOPY); for (j = 0; j < nx; j++) { pta = ptaCreate(nlines); for (i = 0; i < nlines; i++) { y = faflats[i]; ptaaGetPt(ptaa5, i, j, NULL, &val); /* disparity value */ ptaAddPt(pta, y, val); } ptaaAddPta(ptaa6, pta, L_INSERT); } if (debugflag) { tempname = genTempFilename("/tmp", "ptaa6.ptaa", 0); ptaaWrite(tempname, ptaa6, 0); FREE(tempname); } /* Do quadratic fit vertically on a subset of pixel columns * for the vertical displacement, which identifies the * src pixel(s) for each dest pixel. Sample the displacement * on a regular grid in the vertical direction. */ ptaa7 = ptaaCreate(nx); /* uniformly sampled across full height of image */ for (j = 0; j < nx; j++) { /* for each column */ pta = ptaaGetPta(ptaa6, j, L_CLONE); ptaGetQuadraticLSF(pta, &c2, &c1, &c0, NULL); ptad = ptaCreate(ny); for (i = 0; i < ny; i++) { /* uniformly sampled in y */ y = i * sampling; applyQuadraticFit(c2, c1, c0, y, &val); ptaAddPt(ptad, y, val); } ptaaAddPta(ptaa7, ptad, L_INSERT); ptaDestroy(&pta); } if (debugflag) { tempname = genTempFilename("/tmp", "ptaa7.ptaa", 0); ptaaWrite(tempname, ptaa7, 0); FREE(tempname); } /* Save the result in a fpix at the specified subsampling */ fpix1 = fpixCreate(nx, ny); for (i = 0; i < ny; i++) { for (j = 0; j < nx; j++) { ptaaGetPt(ptaa7, j, i, NULL, &val); fpixSetPixel(fpix1, j, i, val); } } dew->sampvdispar = fpix1; /* Generate a full res fpix for vertical dewarping. We require that * the size of this fpix is at least as big as the input image. */ fpix2 = fpixScaleByInteger(fpix1, sampling); dew->fullvdispar = fpix2; if (debugflag) { pixt1 = fpixRenderContours(fpix2, -2., 2.0, 0.2); pixWriteTempfile("/tmp", "vert-contours.png", pixt1, IFF_PNG, NULL); pixDisplay(pixt1, 1000, 0); pixDestroy(&pixt1); } /* Generate full res and sampled fpix for horizontal dewarping. This * works to the extent that the line curvature is due to bending * out of the plane normal to the camera, and not wide-angle * "fishbowl" distortion. Also generate the sampled horizontal * disparity array. */ if (dew->applyhoriz) { fpix3 = fpixBuildHorizontalDisparity(fpix2, 0, &dew->extraw); dew->fullhdispar = fpix3; dew->samphdispar = fpixSampledDisparity(fpix3, dew->sampling); if (debugflag) { pixt1 = fpixRenderContours(fpix3, -2., 2.0, 0.2); pixWriteTempfile("/tmp", "horiz-contours.png", pixt1, IFF_PNG, NULL); pixDisplay(pixt1, 1000, 0); pixDestroy(&pixt1); } } dew->success = 1; ptaaDestroy(&ptaa1); ptaaDestroy(&ptaa2); ptaaDestroy(&ptaa3); ptaaDestroy(&ptaa4); ptaaDestroy(&ptaa5); ptaaDestroy(&ptaa6); ptaaDestroy(&ptaa7); return 0; }
l_int32 main(int argc, char **argv) { l_int32 i, n; l_float32 a, b, c; L_DEWARP *dew, *dew2; DPIX *dpix1, *dpix2, *dpix3; FPIX *fpix1, *fpix2, *fpix3; NUMA *nax, *nafit; PIX *pixs, *pixn, *pixg, *pixb, *pixt1, *pixt2; PIX *pixs2, *pixn2, *pixg2, *pixb2; PTA *pta, *ptad; PTAA *ptaa1, *ptaa2; L_REGPARAMS *rp; if (regTestSetup(argc, argv, &rp)) return 1; pixs = pixRead("1555-7.jpg"); /* Normalize for varying background and binarize */ pixn = pixBackgroundNormSimple(pixs, NULL, NULL); pixg = pixConvertRGBToGray(pixn, 0.5, 0.3, 0.2); pixb = pixThresholdToBinary(pixg, 130); pixDestroy(&pixn); pixDestroy(&pixg); regTestWritePixAndCheck(rp, pixb, IFF_PNG); /* 0 */ pixDisplayWithTitle(pixb, 0, 0, "binarized input", rp->display); /* Get the textline centers */ ptaa1 = pixGetTextlineCenters(pixb, 0); pixt1 = pixCreateTemplate(pixs); pixt2 = pixDisplayPtaa(pixt1, ptaa1); regTestWritePixAndCheck(rp, pixt2, IFF_PNG); /* 1 */ pixDisplayWithTitle(pixt2, 0, 500, "textline centers", rp->display); pixDestroy(&pixt1); /* Remove short lines */ ptaa2 = ptaaRemoveShortLines(pixb, ptaa1, 0.8, 0); /* Fit to quadratic */ n = ptaaGetCount(ptaa2); for (i = 0; i < n; i++) { pta = ptaaGetPta(ptaa2, i, L_CLONE); ptaGetArrays(pta, &nax, NULL); ptaGetQuadraticLSF(pta, &a, &b, &c, &nafit); ptad = ptaCreateFromNuma(nax, nafit); pixDisplayPta(pixt2, pixt2, ptad); ptaDestroy(&pta); ptaDestroy(&ptad); numaDestroy(&nax); numaDestroy(&nafit); } regTestWritePixAndCheck(rp, pixt2, IFF_PNG); /* 2 */ pixDisplayWithTitle(pixt2, 300, 500, "fitted lines superimposed", rp->display); ptaaDestroy(&ptaa1); ptaaDestroy(&ptaa2); pixDestroy(&pixt2); /* Run with only vertical disparity correction */ if ((dew = dewarpCreate(pixb, 7, 30, 15, 0)) == NULL) return ERROR_INT("\n\n\n FAILURE !!! \n\n\n", rp->testname, 1); dewarpBuildModel(dew, 0); dewarpApplyDisparity(dew, pixb, 0); regTestWritePixAndCheck(rp, dew->pixd, IFF_PNG); /* 3 */ pixDisplayWithTitle(dew->pixd, 400, 0, "fixed for vert disparity", rp->display); dewarpDestroy(&dew); /* Run with both vertical and horizontal disparity correction */ if ((dew = dewarpCreate(pixb, 7, 30, 15, 1)) == NULL) return ERROR_INT("\n\n\n FAILURE !!! \n\n\n", rp->testname, 1); dewarpBuildModel(dew, 0); dewarpApplyDisparity(dew, pixb, 0); regTestWritePixAndCheck(rp, dew->pixd, IFF_PNG); /* 4 */ pixDisplayWithTitle(dew->pixd, 800, 0, "fixed for both disparities", rp->display); /* Read another image, normalize background and binarize */ pixs2 = pixRead("1555-3.jpg"); pixn2 = pixBackgroundNormSimple(pixs2, NULL, NULL); pixg2 = pixConvertRGBToGray(pixn2, 0.5, 0.3, 0.2); pixb2 = pixThresholdToBinary(pixg2, 130); pixDestroy(&pixn2); pixDestroy(&pixg2); regTestWritePixAndCheck(rp, pixb, IFF_PNG); /* 5 */ pixDisplayWithTitle(pixb, 0, 400, "binarized input (2)", rp->display); /* Minimize and re-apply previous disparity to this image */ dewarpMinimize(dew); dewarpApplyDisparity(dew, pixb2, 0); regTestWritePixAndCheck(rp, dew->pixd, IFF_PNG); /* 6 */ pixDisplayWithTitle(dew->pixd, 400, 400, "fixed (2) for both disparities", rp->display); /* Write and read back minimized dewarp struct */ dewarpWrite("/tmp/dewarp.7.dew", dew); regTestCheckFile(rp, "/tmp/dewarp.7.dew"); /* 7 */ dew2 = dewarpRead("/tmp/dewarp.7.dew"); dewarpWrite("/tmp/dewarp.8.dew", dew2); regTestCheckFile(rp, "/tmp/dewarp.8.dew"); /* 8 */ regTestCompareFiles(rp, 7, 8); /* 9 */ /* Apply dew2 to pixb2 */ dewarpApplyDisparity(dew2, pixb2, 0); regTestWritePixAndCheck(rp, dew2->pixd, IFF_PNG); /* 10 */ pixDisplayWithTitle(dew->pixd, 800, 400, "fixed (3) for both disparities", rp->display); /* Minimize, repopulate disparity arrays, and apply again */ dewarpMinimize(dew2); dewarpApplyDisparity(dew2, pixb2, 0); regTestWritePixAndCheck(rp, dew2->pixd, IFF_PNG); /* 11 */ regTestCompareFiles(rp, 10, 11); /* 12 */ pixDisplayWithTitle(dew->pixd, 900, 400, "fixed (4) for both disparities", rp->display); /* Test a few of the fpix functions */ fpix1 = fpixClone(dew->sampvdispar); fpixWrite("/tmp/sampv.13.fpix", fpix1); regTestCheckFile(rp, "/tmp/sampv.13.fpix"); /* 13 */ fpix2 = fpixRead("/tmp/sampv.13.fpix"); fpixWrite("/tmp/sampv.14.fpix", fpix2); regTestCheckFile(rp, "/tmp/sampv.14.fpix"); /* 14 */ regTestCompareFiles(rp, 13, 14); /* 15 */ fpix3 = fpixScaleByInteger(fpix2, 30); pixt1 = fpixRenderContours(fpix3, -2., 2.0, 0.2); regTestWritePixAndCheck(rp, pixt1, IFF_PNG); /* 16 */ pixDisplayWithTitle(pixt1, 0, 800, "v. disparity contours", rp->display); fpixDestroy(&fpix1); fpixDestroy(&fpix2); fpixDestroy(&fpix3); pixDestroy(&pixt1); /* Test a few of the dpix functions */ dpix1 = fpixConvertToDPix(dew->sampvdispar); dpixWrite("/tmp/sampv.17.dpix", dpix1); regTestCheckFile(rp, "/tmp/sampv.17.dpix"); /* 17 */ dpix2 = dpixRead("/tmp/sampv.17.dpix"); dpixWrite("/tmp/sampv.18.dpix", dpix2); regTestCheckFile(rp, "/tmp/sampv.18.dpix"); /* 18 */ regTestCompareFiles(rp, 17, 18); /* 19 */ dpix3 = dpixScaleByInteger(dpix2, 30); fpix3 = dpixConvertToFPix(dpix3); pixt1 = fpixRenderContours(fpix3, -2., 2.0, 0.2); regTestWritePixAndCheck(rp, pixt1, IFF_PNG); /* 20 */ pixDisplayWithTitle(pixt1, 400, 800, "v. disparity contours", rp->display); regTestCompareFiles(rp, 16, 20); /* 21 */ dpixDestroy(&dpix1); dpixDestroy(&dpix2); dpixDestroy(&dpix3); fpixDestroy(&fpix3); pixDestroy(&pixt1); dewarpDestroy(&dew); dewarpDestroy(&dew2); pixDestroy(&pixs); pixDestroy(&pixb); pixDestroy(&pixs2); pixDestroy(&pixb2); regTestCleanup(rp); return 0; }