mirror of
https://github.com/python-pillow/Pillow.git
synced 2024-11-11 04:07:21 +03:00
0e9beed76d
rearrange filters everywhere
567 lines
17 KiB
C
567 lines
17 KiB
C
#include "Imaging.h"
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#include <math.h>
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#define ROUND_UP(f) ((int) ((f) >= 0.0 ? (f) + 0.5F : (f) - 0.5F))
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struct filter {
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double (*filter)(double x);
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double support;
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};
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static inline double bilinear_filter(double x)
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{
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if (x < 0.0)
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x = -x;
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if (x < 1.0)
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return 1.0-x;
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return 0.0;
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}
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static inline double bicubic_filter(double x)
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{
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/* https://en.wikipedia.org/wiki/Bicubic_interpolation#Bicubic_convolution_algorithm */
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#define a -0.5
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if (x < 0.0)
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x = -x;
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if (x < 1.0)
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return ((a + 2.0) * x - (a + 3.0)) * x*x + 1;
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if (x < 2.0)
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return (((x - 5) * x + 8) * x - 4) * a;
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return 0.0;
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#undef a
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}
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static inline double sinc_filter(double x)
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{
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if (x == 0.0)
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return 1.0;
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x = x * M_PI;
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return sin(x) / x;
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}
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static inline double lanczos_filter(double x)
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{
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/* truncated sinc */
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if (-3.0 <= x && x < 3.0)
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return sinc_filter(x) * sinc_filter(x/3);
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return 0.0;
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}
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static struct filter BILINEAR = { bilinear_filter, 1.0 };
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static struct filter BICUBIC = { bicubic_filter, 2.0 };
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static struct filter LANCZOS = { lanczos_filter, 3.0 };
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/* 8 bits for result. Filter can have negative areas.
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In one cases the sum of the coefficients will be negative,
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in the other it will be more than 1.0. That is why we need
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two extra bits for overflow and int type. */
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#define PRECISION_BITS (32 - 8 - 2)
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static inline UINT8 clip8(int in)
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{
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if (in >= (1 << PRECISION_BITS << 8))
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return 255;
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if (in <= 0)
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return 0;
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return (UINT8) (in >> PRECISION_BITS);
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}
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int
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ImagingPrecompute(int inSize, int outSize, struct filter *filterp,
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int **xboundsp, double **kkp) {
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double support, scale, filterscale;
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double center, ww, ss;
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int xx, x, kmax, xmin, xmax;
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int *xbounds;
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double *kk, *k;
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/* prepare for horizontal stretch */
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filterscale = scale = (double) inSize / outSize;
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if (filterscale < 1.0) {
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filterscale = 1.0;
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}
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/* determine support size (length of resampling filter) */
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support = filterp->support * filterscale;
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/* maximum number of coeffs */
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kmax = (int) ceil(support) * 2 + 1;
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// check for overflow
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if (outSize > INT_MAX / (kmax * sizeof(double)))
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return 0;
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/* coefficient buffer */
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/* malloc check ok, overflow checked above */
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kk = malloc(outSize * kmax * sizeof(double));
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if ( ! kk)
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return 0;
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/* malloc check ok, kmax*sizeof(double) > 2*sizeof(int) */
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xbounds = malloc(outSize * 2 * sizeof(int));
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if ( ! xbounds) {
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free(kk);
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return 0;
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}
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for (xx = 0; xx < outSize; xx++) {
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center = (xx + 0.5) * scale;
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ww = 0.0;
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ss = 1.0 / filterscale;
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xmin = (int) floor(center - support);
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if (xmin < 0)
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xmin = 0;
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xmax = (int) ceil(center + support);
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if (xmax > inSize)
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xmax = inSize;
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xmax -= xmin;
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k = &kk[xx * kmax];
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for (x = 0; x < xmax; x++) {
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double w = filterp->filter((x + xmin - center + 0.5) * ss);
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k[x] = w;
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ww += w;
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}
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for (x = 0; x < xmax; x++) {
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if (ww != 0.0)
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k[x] /= ww;
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}
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// Remaining values should stay empty if they are used despite of xmax.
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for (; x < kmax; x++) {
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k[x] = 0;
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}
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xbounds[xx * 2 + 0] = xmin;
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xbounds[xx * 2 + 1] = xmax;
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}
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*xboundsp = xbounds;
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*kkp = kk;
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return kmax;
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}
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Imaging
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ImagingResampleHorizontal_8bpc(Imaging imIn, int xsize, struct filter *filterp)
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{
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ImagingSectionCookie cookie;
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Imaging imOut;
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int ss0, ss1, ss2, ss3;
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int xx, yy, x, kmax, xmin, xmax;
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int *xbounds;
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int *k, *kk;
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double *prekk;
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kmax = ImagingPrecompute(imIn->xsize, xsize, filterp, &xbounds, &prekk);
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if ( ! kmax) {
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return (Imaging) ImagingError_MemoryError();
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}
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kk = malloc(xsize * kmax * sizeof(int));
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if ( ! kk) {
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free(xbounds);
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free(prekk);
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return (Imaging) ImagingError_MemoryError();
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}
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for (x = 0; x < xsize * kmax; x++) {
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kk[x] = (int) (0.5 + prekk[x] * (1 << PRECISION_BITS));
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}
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free(prekk);
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imOut = ImagingNew(imIn->mode, xsize, imIn->ysize);
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if ( ! imOut) {
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free(kk);
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free(xbounds);
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return NULL;
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}
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ImagingSectionEnter(&cookie);
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if (imIn->image8) {
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss0 = 1 << (PRECISION_BITS -1);
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for (x = 0; x < xmax; x++)
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ss0 += ((UINT8) imIn->image8[yy][x + xmin]) * k[x];
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imOut->image8[yy][xx] = clip8(ss0);
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}
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}
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} else if (imIn->type == IMAGING_TYPE_UINT8) {
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if (imIn->bands == 2) {
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss0 = ss3 = 1 << (PRECISION_BITS -1);
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for (x = 0; x < xmax; x++) {
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ss0 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 0]) * k[x];
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ss3 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 3]) * k[x];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 3] = clip8(ss3);
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}
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}
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} else if (imIn->bands == 3) {
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss0 = ss1 = ss2 = 1 << (PRECISION_BITS -1);
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for (x = 0; x < xmax; x++) {
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ss0 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 0]) * k[x];
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ss1 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 1]) * k[x];
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ss2 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 2]) * k[x];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 1] = clip8(ss1);
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imOut->image[yy][xx*4 + 2] = clip8(ss2);
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}
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}
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} else {
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss0 = ss1 = ss2 = ss3 = 1 << (PRECISION_BITS -1);
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for (x = 0; x < xmax; x++) {
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ss0 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 0]) * k[x];
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ss1 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 1]) * k[x];
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ss2 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 2]) * k[x];
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ss3 += ((UINT8) imIn->image[yy][(x + xmin)*4 + 3]) * k[x];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 1] = clip8(ss1);
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imOut->image[yy][xx*4 + 2] = clip8(ss2);
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imOut->image[yy][xx*4 + 3] = clip8(ss3);
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}
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}
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}
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}
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ImagingSectionLeave(&cookie);
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free(kk);
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free(xbounds);
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return imOut;
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}
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Imaging
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ImagingResampleVertical_8bpc(Imaging imIn, int ysize, struct filter *filterp)
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{
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ImagingSectionCookie cookie;
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Imaging imOut;
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int ss0, ss1, ss2, ss3;
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int xx, yy, y, kmax, ymin, ymax;
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int *xbounds;
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int *k, *kk;
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double *prekk;
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kmax = ImagingPrecompute(imIn->ysize, ysize, filterp, &xbounds, &prekk);
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if ( ! kmax) {
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return (Imaging) ImagingError_MemoryError();
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}
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kk = malloc(ysize * kmax * sizeof(int));
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if ( ! kk) {
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free(xbounds);
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free(prekk);
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return (Imaging) ImagingError_MemoryError();
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}
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for (y = 0; y < ysize * kmax; y++) {
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kk[y] = (int) (0.5 + prekk[y] * (1 << PRECISION_BITS));
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}
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free(prekk);
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imOut = ImagingNew(imIn->mode, imIn->xsize, ysize);
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if ( ! imOut) {
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free(kk);
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free(xbounds);
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return NULL;
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}
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ImagingSectionEnter(&cookie);
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if (imIn->image8) {
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for (yy = 0; yy < ysize; yy++) {
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k = &kk[yy * kmax];
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss0 = 1 << (PRECISION_BITS -1);
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for (y = 0; y < ymax; y++)
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ss0 += ((UINT8) imIn->image8[y + ymin][xx]) * k[y];
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imOut->image8[yy][xx] = clip8(ss0);
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}
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}
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} else if (imIn->type == IMAGING_TYPE_UINT8) {
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if (imIn->bands == 2) {
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for (yy = 0; yy < ysize; yy++) {
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k = &kk[yy * kmax];
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss0 = ss3 = 1 << (PRECISION_BITS -1);
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for (y = 0; y < ymax; y++) {
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ss0 += ((UINT8) imIn->image[y + ymin][xx*4 + 0]) * k[y];
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ss3 += ((UINT8) imIn->image[y + ymin][xx*4 + 3]) * k[y];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 3] = clip8(ss3);
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}
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}
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} else if (imIn->bands == 3) {
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for (yy = 0; yy < ysize; yy++) {
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k = &kk[yy * kmax];
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss0 = ss1 = ss2 = 1 << (PRECISION_BITS -1);
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for (y = 0; y < ymax; y++) {
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ss0 += ((UINT8) imIn->image[y + ymin][xx*4 + 0]) * k[y];
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ss1 += ((UINT8) imIn->image[y + ymin][xx*4 + 1]) * k[y];
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ss2 += ((UINT8) imIn->image[y + ymin][xx*4 + 2]) * k[y];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 1] = clip8(ss1);
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imOut->image[yy][xx*4 + 2] = clip8(ss2);
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}
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}
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} else {
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for (yy = 0; yy < ysize; yy++) {
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k = &kk[yy * kmax];
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss0 = ss1 = ss2 = ss3 = 1 << (PRECISION_BITS -1);
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for (y = 0; y < ymax; y++) {
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ss0 += ((UINT8) imIn->image[y + ymin][xx*4 + 0]) * k[y];
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ss1 += ((UINT8) imIn->image[y + ymin][xx*4 + 1]) * k[y];
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ss2 += ((UINT8) imIn->image[y + ymin][xx*4 + 2]) * k[y];
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ss3 += ((UINT8) imIn->image[y + ymin][xx*4 + 3]) * k[y];
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}
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imOut->image[yy][xx*4 + 0] = clip8(ss0);
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imOut->image[yy][xx*4 + 1] = clip8(ss1);
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imOut->image[yy][xx*4 + 2] = clip8(ss2);
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imOut->image[yy][xx*4 + 3] = clip8(ss3);
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}
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}
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}
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}
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ImagingSectionLeave(&cookie);
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free(kk);
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free(xbounds);
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return imOut;
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}
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Imaging
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ImagingResampleHorizontal_32bpc(Imaging imIn, int xsize, struct filter *filterp)
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{
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ImagingSectionCookie cookie;
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Imaging imOut;
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double ss;
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int xx, yy, x, kmax, xmin, xmax;
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int *xbounds;
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double *k, *kk;
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kmax = ImagingPrecompute(imIn->xsize, xsize, filterp, &xbounds, &kk);
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if ( ! kmax) {
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return (Imaging) ImagingError_MemoryError();
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}
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imOut = ImagingNew(imIn->mode, xsize, imIn->ysize);
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if ( ! imOut) {
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free(kk);
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free(xbounds);
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return NULL;
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}
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ImagingSectionEnter(&cookie);
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switch(imIn->type) {
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case IMAGING_TYPE_INT32:
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss = 0.0;
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for (x = 0; x < xmax; x++)
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ss += IMAGING_PIXEL_I(imIn, x + xmin, yy) * k[x];
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IMAGING_PIXEL_I(imOut, xx, yy) = ROUND_UP(ss);
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}
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}
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break;
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case IMAGING_TYPE_FLOAT32:
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for (yy = 0; yy < imOut->ysize; yy++) {
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for (xx = 0; xx < xsize; xx++) {
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xmin = xbounds[xx * 2 + 0];
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xmax = xbounds[xx * 2 + 1];
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k = &kk[xx * kmax];
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ss = 0.0;
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for (x = 0; x < xmax; x++)
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ss += IMAGING_PIXEL_F(imIn, x + xmin, yy) * k[x];
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IMAGING_PIXEL_F(imOut, xx, yy) = ss;
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}
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}
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break;
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}
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ImagingSectionLeave(&cookie);
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free(kk);
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free(xbounds);
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return imOut;
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}
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Imaging
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ImagingResampleVertical_32bpc(Imaging imIn, int ysize, struct filter *filterp)
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{
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ImagingSectionCookie cookie;
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Imaging imOut;
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double ss;
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int xx, yy, y, kmax, ymin, ymax;
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int *xbounds;
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double *k, *kk;
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kmax = ImagingPrecompute(imIn->ysize, ysize, filterp, &xbounds, &kk);
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if ( ! kmax) {
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return (Imaging) ImagingError_MemoryError();
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}
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imOut = ImagingNew(imIn->mode, imIn->xsize, ysize);
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if ( ! imOut) {
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free(kk);
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free(xbounds);
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return NULL;
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}
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ImagingSectionEnter(&cookie);
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switch(imIn->type) {
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case IMAGING_TYPE_INT32:
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for (yy = 0; yy < ysize; yy++) {
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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k = &kk[yy * kmax];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss = 0.0;
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for (y = 0; y < ymax; y++)
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ss += IMAGING_PIXEL_I(imIn, xx, y + ymin) * k[y];
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IMAGING_PIXEL_I(imOut, xx, yy) = ROUND_UP(ss);
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}
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}
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break;
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case IMAGING_TYPE_FLOAT32:
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for (yy = 0; yy < ysize; yy++) {
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ymin = xbounds[yy * 2 + 0];
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ymax = xbounds[yy * 2 + 1];
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k = &kk[yy * kmax];
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for (xx = 0; xx < imOut->xsize; xx++) {
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ss = 0.0;
|
|
for (y = 0; y < ymax; y++)
|
|
ss += IMAGING_PIXEL_F(imIn, xx, y + ymin) * k[y];
|
|
IMAGING_PIXEL_F(imOut, xx, yy) = ss;
|
|
}
|
|
}
|
|
break;
|
|
}
|
|
|
|
ImagingSectionLeave(&cookie);
|
|
free(kk);
|
|
free(xbounds);
|
|
return imOut;
|
|
}
|
|
|
|
|
|
Imaging
|
|
ImagingResample(Imaging imIn, int xsize, int ysize, int filter)
|
|
{
|
|
Imaging imTemp = NULL;
|
|
Imaging imOut = NULL;
|
|
struct filter *filterp;
|
|
Imaging (*ResampleHorizontal)(Imaging imIn, int xsize, struct filter *filterp);
|
|
Imaging (*ResampleVertical)(Imaging imIn, int xsize, struct filter *filterp);
|
|
|
|
if (strcmp(imIn->mode, "P") == 0 || strcmp(imIn->mode, "1") == 0)
|
|
return (Imaging) ImagingError_ModeError();
|
|
|
|
if (imIn->type == IMAGING_TYPE_SPECIAL) {
|
|
return (Imaging) ImagingError_ModeError();
|
|
} else if (imIn->image8) {
|
|
ResampleHorizontal = ImagingResampleHorizontal_8bpc;
|
|
ResampleVertical = ImagingResampleVertical_8bpc;
|
|
} else {
|
|
switch(imIn->type) {
|
|
case IMAGING_TYPE_UINT8:
|
|
ResampleHorizontal = ImagingResampleHorizontal_8bpc;
|
|
ResampleVertical = ImagingResampleVertical_8bpc;
|
|
break;
|
|
case IMAGING_TYPE_INT32:
|
|
case IMAGING_TYPE_FLOAT32:
|
|
ResampleHorizontal = ImagingResampleHorizontal_32bpc;
|
|
ResampleVertical = ImagingResampleVertical_32bpc;
|
|
break;
|
|
default:
|
|
return (Imaging) ImagingError_ModeError();
|
|
}
|
|
}
|
|
|
|
/* check filter */
|
|
switch (filter) {
|
|
case IMAGING_TRANSFORM_BILINEAR:
|
|
filterp = &BILINEAR;
|
|
break;
|
|
case IMAGING_TRANSFORM_BICUBIC:
|
|
filterp = &BICUBIC;
|
|
break;
|
|
case IMAGING_TRANSFORM_LANCZOS:
|
|
filterp = &LANCZOS;
|
|
break;
|
|
default:
|
|
return (Imaging) ImagingError_ValueError(
|
|
"unsupported resampling filter"
|
|
);
|
|
}
|
|
|
|
/* two-pass resize, first pass */
|
|
if (imIn->xsize != xsize) {
|
|
imTemp = ResampleHorizontal(imIn, xsize, filterp);
|
|
if ( ! imTemp)
|
|
return NULL;
|
|
imOut = imIn = imTemp;
|
|
}
|
|
|
|
/* second pass */
|
|
if (imIn->ysize != ysize) {
|
|
/* imIn can be the original image or horizontally resampled one */
|
|
imOut = ResampleVertical(imIn, ysize, filterp);
|
|
/* it's safe to call ImagingDelete with empty value
|
|
if there was no previous step. */
|
|
ImagingDelete(imTemp);
|
|
if ( ! imOut)
|
|
return NULL;
|
|
}
|
|
|
|
/* none of the previous steps are performed, copying */
|
|
if ( ! imOut) {
|
|
imOut = ImagingCopy(imIn);
|
|
}
|
|
|
|
return imOut;
|
|
}
|