=cut
*/
-#include "image.h"
-#include "imagei.h"
+#define IMAGER_NO_CONTEXT
+
+#include "imager.h"
+#include "imageri.h"
#define PALEXT(im) ((i_img_pal_ext*)((im)->ext_data))
-static int i_ppix_p(i_img *im, int x, int y, i_color *val);
-static int i_gpix_p(i_img *im, int x, int y, i_color *val);
-static int i_glin_p(i_img *im, int l, int r, int y, i_color *vals);
-static int i_plin_p(i_img *im, int l, int r, int y, i_color *vals);
-static int i_gsamp_p(i_img *im, int l, int r, int y, i_sample_t *samps, int const *chans, int chan_count);
-static int i_gpal_p(i_img *pm, int l, int r, int y, i_palidx *vals);
-static int i_ppal_p(i_img *pm, int l, int r, int y, i_palidx *vals);
-static int i_addcolors_p(i_img *im, i_color *color, int count);
+static int i_ppix_p(i_img *im, i_img_dim x, i_img_dim y, const i_color *val);
+static int i_gpix_p(i_img *im, i_img_dim x, i_img_dim y, i_color *val);
+static i_img_dim i_glin_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_color *vals);
+static i_img_dim i_plin_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_color *vals);
+static i_img_dim i_gsamp_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_sample_t *samps, int const *chans, int chan_count);
+static i_img_dim i_gpal_p(i_img *pm, i_img_dim l, i_img_dim r, i_img_dim y, i_palidx *vals);
+static i_img_dim i_ppal_p(i_img *pm, i_img_dim l, i_img_dim r, i_img_dim y, const i_palidx *vals);
+static int i_addcolors_p(i_img *im, const i_color *color, int count);
static int i_getcolors_p(i_img *im, int i, i_color *color, int count);
static int i_colorcount_p(i_img *im);
static int i_maxcolors_p(i_img *im);
-static int i_findcolor_p(i_img *im, i_color *color, i_palidx *entry);
-static int i_setcolors_p(i_img *im, int index, i_color *color, int count);
+static int i_findcolor_p(i_img *im, const i_color *color, i_palidx *entry);
+static int i_setcolors_p(i_img *im, int index, const i_color *color, int count);
static void i_destroy_p(i_img *im);
+static i_img_dim
+i_psamp_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_sample_t *samps, const int *chans, int chan_count);
+static i_img_dim
+i_psampf_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_fsample_t *samps, const int *chans, int chan_count);
static i_img IIM_base_8bit_pal =
{
i_setcolors_p, /* i_f_setcolors */
i_destroy_p, /* i_f_destroy */
+
+ i_gsamp_bits_fb,
+ NULL, /* i_f_psamp_bits */
+
+ i_psamp_p,
+ i_psampf_p
};
/*
-=item i_img_pal_new_low(i_img *im, int x, int y, int channels, int maxpal)
+=item im_img_pal_new(ctx, C<x>, C<y>, C<channels>, C<maxpal>)
+X<im_img_pal_new API>X<i_img_pal_new API>
+=category Image creation/destruction
+=synopsis i_img *img = im_img_pal_new(aIMCTX, width, height, channels, max_palette_size)
+=synopsis i_img *img = i_img_pal_new(width, height, channels, max_palette_size)
-Creates a new paletted image.
+Creates a new paletted image of the supplied dimensions.
-Currently 0 < maxpal <= 256
+C<maxpal> is the maximum palette size and should normally be 256.
+
+Returns a new image or NULL on failure.
+
+Also callable as C<i_img_pal_new(width, height, channels, max_palette_size)>.
=cut
*/
-i_img *i_img_pal_new_low(i_img *im, int x, int y, int channels, int maxpal) {
+i_img *
+im_img_pal_new(pIMCTX, i_img_dim x, i_img_dim y, int channels, int maxpal) {
+ i_img *im;
i_img_pal_ext *palext;
- int bytes;
+ size_t bytes, line_bytes;
i_clear_error();
- if (maxpal < 0 || maxpal > 256) {
+ if (maxpal < 1 || maxpal > 256) {
i_push_error(0, "Maximum of 256 palette entries");
return NULL;
}
return NULL;
}
if (channels < 1 || channels > MAXCHANNELS) {
- i_push_errorf(0, "Channels must be positive and <= %d", MAXCHANNELS);
+ im_push_errorf(aIMCTX, 0, "Channels must be positive and <= %d", MAXCHANNELS);
return NULL;
}
bytes = sizeof(i_palidx) * x * y;
if (bytes / y / sizeof(i_palidx) != x) {
- i_push_errorf(0, "integer overflow calculating image allocation");
+ i_push_error(0, "integer overflow calculating image allocation");
return NULL;
}
+ /* basic assumption: we can always allocate a buffer representing a
+ line from the image, otherwise we're going to have trouble
+ working with the image */
+ line_bytes = sizeof(i_color) * x;
+ if (line_bytes / x != sizeof(i_color)) {
+ i_push_error(0, "integer overflow calculating scanline allocation");
+ return NULL;
+ }
+
+ im = i_img_alloc();
memcpy(im, &IIM_base_8bit_pal, sizeof(i_img));
palext = mymalloc(sizeof(i_img_pal_ext));
palext->pal = mymalloc(sizeof(i_color) * maxpal);
memset(im->idata, 0, im->bytes);
im->xsize = x;
im->ysize = y;
-
- return im;
-}
-
-i_img *i_img_pal_new(int x, int y, int channels, int maxpal) {
- i_img *im;
- mm_log((1, "i_img_pal_new(x %d, y %d, channels %d, maxpal %d)\n", x, y, channels, maxpal));
- im = mymalloc(sizeof(i_img));
- if (!i_img_pal_new_low(im, x, y, channels, maxpal)) {
- myfree(im);
- im = NULL;
- }
+ i_img_init(im);
+
return im;
}
*/
static void i_img_rgb_convert(i_img *targ, i_img *src) {
i_color *row = mymalloc(sizeof(i_color) * targ->xsize);
- int y;
+ i_img_dim y;
for (y = 0; y < targ->ysize; ++y) {
i_glin(src, 0, src->xsize, y, row);
i_plin(targ, 0, src->xsize, y, row);
=cut
*/
-int i_img_to_rgb_inplace(i_img *im) {
+int
+i_img_to_rgb_inplace(i_img *im) {
i_img temp;
- i_color *pal;
- int palsize;
+ dIMCTXim(im);
if (im->virtual)
return 0;
i_img *i_img_to_pal(i_img *src, i_quantize *quant) {
i_palidx *result;
i_img *im;
+ dIMCTXim(src);
i_clear_error();
- quant_makemap(quant, &src, 1);
- result = quant_translate(quant, src);
+ i_quant_makemap(quant, &src, 1);
+ result = i_quant_translate(quant, src);
if (result) {
=cut
*/
-i_img *i_img_to_rgb(i_img *src) {
+i_img *
+i_img_to_rgb(i_img *src) {
+ dIMCTXim(src);
i_img *im = i_img_empty_ch(NULL, src->xsize, src->ysize, src->channels);
i_img_rgb_convert(im, src);
}
/*
-=item i_ppix_p(i_img *im, int x, int y, i_color *val)
+=item i_ppix_p(i_img *im, i_img_dim x, i_img_dim y, const i_color *val)
Write to a pixel in the image.
=cut
*/
-static int i_ppix_p(i_img *im, int x, int y, i_color *val) {
+static int
+i_ppix_p(i_img *im, i_img_dim x, i_img_dim y, const i_color *val) {
+ const i_color *work_val = val;
+ i_color workc;
i_palidx which;
+ const unsigned all_mask = ( 1 << im->channels ) - 1;
+
if (x < 0 || x >= im->xsize || y < 0 || y >= im->ysize)
return -1;
- if (i_findcolor(im, val, &which)) {
+
+ if ((im->ch_mask & all_mask) != all_mask) {
+ unsigned mask = 1;
+ int ch;
+ i_gpix(im, x, y, &workc);
+ for (ch = 0; ch < im->channels; ++ch) {
+ if (im->ch_mask & mask)
+ workc.channel[ch] = val->channel[ch];
+ mask <<= 1;
+ }
+ work_val = &workc;
+ }
+
+ if (i_findcolor(im, work_val, &which)) {
((i_palidx *)im->idata)[x + y * im->xsize] = which;
return 0;
}
else {
+ dIMCTXim(im);
+ im_log((aIMCTX, 1, "i_ppix: color(%d,%d,%d) not found, converting to rgb\n",
+ val->channel[0], val->channel[1], val->channel[2]));
if (i_img_to_rgb_inplace(im)) {
return i_ppix(im, x, y, val);
}
}
/*
-=item i_gpix(i_img *im, int x, int y, i_color *val)
+=item i_gpix_p(i_img *im, i_img_dim x, i_img_dim y, i_color *val)
Retrieve a pixel, converting from a palette index to a color.
=cut
*/
-static int i_gpix_p(i_img *im, int x, int y, i_color *val) {
+static int i_gpix_p(i_img *im, i_img_dim x, i_img_dim y, i_color *val) {
i_palidx which;
if (x < 0 || x >= im->xsize || y < 0 || y >= im->ysize) {
return -1;
}
/*
-=item i_glinp(i_img *im, int l, int r, int y, i_color *vals)
+=item i_glinp(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_color *vals)
Retrieve a row of pixels.
=cut
*/
-static int i_glin_p(i_img *im, int l, int r, int y, i_color *vals) {
+static i_img_dim i_glin_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_color *vals) {
if (y >= 0 && y < im->ysize && l < im->xsize && l >= 0) {
int palsize = PALEXT(im)->count;
i_color *pal = PALEXT(im)->pal;
i_palidx *data;
- int count, i;
+ i_img_dim count, i;
if (r > im->xsize)
r = im->xsize;
data = ((i_palidx *)im->idata) + l + y * im->xsize;
}
/*
-=item i_plin_p(i_img *im, int l, int r, int y, i_color *vals)
+=item i_plin_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_color *vals)
Write a line of color data to the image.
=cut
*/
-static int i_plin_p(i_img *im, int l, int r, int y, i_color *vals) {
- int ch, count, i;
+static i_img_dim
+i_plin_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_color *vals) {
+ i_img_dim count, i;
i_palidx *data;
i_palidx which;
if (y >=0 && y < im->ysize && l < im->xsize && l >= 0) {
}
/*
-=item i_gsamp_p(i_img *im, int l, int r, int y, i_sample_t *samps, int chans, int chan_count)
+=item i_gsamp_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_sample_t *samps, int chans, int chan_count)
=cut
*/
-static int i_gsamp_p(i_img *im, int l, int r, int y, i_sample_t *samps,
+static i_img_dim i_gsamp_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_sample_t *samps,
int const *chans, int chan_count) {
int ch;
if (y >= 0 && y < im->ysize && l < im->xsize && l >= 0) {
int palsize = PALEXT(im)->count;
i_color *pal = PALEXT(im)->pal;
i_palidx *data;
- int count, i, w;
+ i_img_dim count, i, w;
if (r > im->xsize)
r = im->xsize;
data = ((i_palidx *)im->idata) + l + y * im->xsize;
if (chans) {
for (ch = 0; ch < chan_count; ++ch) {
if (chans[ch] < 0 || chans[ch] >= im->channels) {
- i_push_errorf(0, "No channel %d in this image", chans[ch]);
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "No channel %d in this image", chans[ch]);
}
}
}
}
else {
+ if (chan_count <= 0 || chan_count > im->channels) {
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "chan_count %d out of range, must be >0, <= channels",
+ chan_count);
+ return 0;
+ }
for (i = 0; i < w; ++i) {
i_palidx which = *data++;
if (which < palsize) {
}
/*
-=item i_gpal_p(i_img *im, int l, int r, int y, i_palidx *vals)
+=item i_gpal_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_palidx *vals)
=cut
*/
-static int i_gpal_p(i_img *im, int l, int r, int y, i_palidx *vals) {
+static i_img_dim i_gpal_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, i_palidx *vals) {
if (y >= 0 && y < im->ysize && l < im->xsize && l >= 0) {
i_palidx *data;
- int i, w;
+ i_img_dim i, w;
if (r > im->xsize)
r = im->xsize;
data = ((i_palidx *)im->idata) + l + y * im->xsize;
}
/*
-=item i_ppal_p(i_img *im, int l, int r, int y, i_palidx *vals)
+=item i_ppal_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_palidx *vals)
=cut
*/
-static int i_ppal_p(i_img *im, int l, int r, int y, i_palidx *vals) {
+static i_img_dim i_ppal_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y, const i_palidx *vals) {
if (y >= 0 && y < im->ysize && l < im->xsize && l >= 0) {
i_palidx *data;
- int i, w;
+ i_img_dim i, w;
if (r > im->xsize)
r = im->xsize;
data = ((i_palidx *)im->idata) + l + y * im->xsize;
}
/*
-=item i_addcolors_p(i_img *im, i_color *color, int count)
+=item i_addcolors_p(i_img *im, const i_color *color, int count)
=cut
*/
-static int i_addcolors_p(i_img *im, i_color *color, int count) {
+static int i_addcolors_p(i_img *im, const i_color *color, int count) {
if (PALEXT(im)->count + count <= PALEXT(im)->alloc) {
int result = PALEXT(im)->count;
int index = result;
return 0;
}
-static int color_eq(i_img *im, i_color *c1, i_color *c2) {
+static int color_eq(i_img *im, const i_color *c1, const i_color *c2) {
int ch;
for (ch = 0; ch < im->channels; ++ch) {
if (c1->channel[ch] != c2->channel[ch])
}
/*
-=item i_setcolors_p(i_img *im, int index, i_color *colors, int count)
+=item i_setcolors_p(i_img *im, int index, const i_color *colors, int count)
=cut
*/
-static int i_setcolors_p(i_img *im, int index, i_color *colors, int count) {
- if (index >= 0 && count >= 1 && index + count < PALEXT(im)->count) {
+static int i_setcolors_p(i_img *im, int index, const i_color *colors, int count) {
+ if (index >= 0 && count >= 1 && index + count <= PALEXT(im)->count) {
while (count) {
PALEXT(im)->pal[index++] = *colors++;
--count;
=cut
*/
-static int i_findcolor_p(i_img *im, i_color *color, i_palidx *entry) {
+static int i_findcolor_p(i_img *im, const i_color *color, i_palidx *entry) {
if (PALEXT(im)->count) {
int i;
/* often the same color comes up several times in a row */
return 0;
}
+/*
+=item i_psamp_p(im, l, r, y, samps, chans, chan_count)
+
+Implement psamp() for paletted images.
+
+Since writing samples doesn't really work as a concept for paletted
+images, this is slow.
+
+Also, writing samples may convert the image to a direct image in the
+process, so use i_ppix/i_gpix instead of directly calling the paletted
+handlers.
+
+=cut
+*/
+
+static i_img_dim
+i_psamp_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y,
+ const i_sample_t *samps, const int *chans, int chan_count) {
+ if (y >=0 && y < im->ysize && l < im->xsize && l >= 0) {
+ i_img_dim count = 0;
+ int ch;
+
+ if (r > im->xsize)
+ r = im->xsize;
+
+ if (chans) {
+ /* make sure we have good channel numbers */
+ for (ch = 0; ch < chan_count; ++ch) {
+ if (chans[ch] < 0 || chans[ch] >= im->channels) {
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "No channel %d in this image", chans[ch]);
+ return -1;
+ }
+ }
+ while (l < r) {
+ i_color c;
+
+ i_gpix(im, l, y, &c);
+ for (ch = 0; ch < chan_count; ++ch)
+ c.channel[chans[ch]] = *samps++;
+ i_ppix(im, l, y, &c);
+ count += chan_count;
+ ++l;
+ }
+ }
+ else {
+ if (chan_count <= 0 || chan_count > im->channels) {
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "chan_count %d out of range, must be >0, <= channels",
+ chan_count);
+ return -1;
+ }
+
+ while (l < r) {
+ i_color c;
+
+ i_gpix(im, l, y, &c);
+ for (ch = 0; ch < chan_count; ++ch)
+ c.channel[ch] = *samps++;
+ i_ppix(im, l, y, &c);
+ count += chan_count;
+ ++l;
+ }
+ }
+
+ return count;
+ }
+ else {
+ dIMCTXim(im);
+ i_push_error(0, "Image position outside of image");
+ return -1;
+ }
+}
+
+/*
+=item i_psampf_p(im, l, r, y, samps, chans, chan_count)
+
+Implement psampf() for paletted images.
+
+Since writing samples doesn't really work as a concept for paletted
+images, this is slow.
+
+Also, writing samples may convert the image to a direct image in the
+process, so use i_ppixf/i_gpixf instead of directly calling the paletted
+handlers.
+
+=cut
+*/
+
+static i_img_dim
+i_psampf_p(i_img *im, i_img_dim l, i_img_dim r, i_img_dim y,
+ const i_fsample_t *samps, const int *chans, int chan_count) {
+ if (y >=0 && y < im->ysize && l < im->xsize && l >= 0) {
+ i_img_dim count = 0;
+ int ch;
+
+ if (r > im->xsize)
+ r = im->xsize;
+
+ if (chans) {
+ /* make sure we have good channel numbers */
+ for (ch = 0; ch < chan_count; ++ch) {
+ if (chans[ch] < 0 || chans[ch] >= im->channels) {
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "No channel %d in this image", chans[ch]);
+ return -1;
+ }
+ }
+ while (l < r) {
+ i_fcolor c;
+
+ i_gpixf(im, l, y, &c);
+ for (ch = 0; ch < chan_count; ++ch)
+ c.channel[chans[ch]] = *samps++;
+ i_ppixf(im, l, y, &c);
+ count += chan_count;
+ ++l;
+ }
+ }
+ else {
+ if (chan_count <= 0 || chan_count > im->channels) {
+ dIMCTXim(im);
+ im_push_errorf(aIMCTX, 0, "chan_count %d out of range, must be >0, <= channels",
+ chan_count);
+ return -1;
+ }
+
+ while (l < r) {
+ i_fcolor c;
+
+ i_gpixf(im, l, y, &c);
+ for (ch = 0; ch < chan_count; ++ch)
+ c.channel[ch] = *samps++;
+ i_ppixf(im, l, y, &c);
+ count += chan_count;
+ ++l;
+ }
+ }
+
+ return count;
+ }
+ else {
+ dIMCTXim(im);
+ i_push_error(0, "Image position outside of image");
+ return -1;
+ }
+}
+
/*
=back
projects / imager.git / blobdiff