Pillow/libImaging/Chops.c

/* 
 * The Python Imaging Library
 * $Id$
 *
 * basic channel operations
 *
 * history:
 * 1996-03-28 fl   Created
 * 1996-08-13 fl   Added and/or/xor for "1" images
 * 1996-12-14 fl   Added add_modulo, sub_modulo
 * 2005-09-10 fl   Fixed output values from and/or/xor
 *
 * Copyright (c) 1996 by Fredrik Lundh.
 * Copyright (c) 1997 by Secret Labs AB.
 *
 * See the README file for details on usage and redistribution.
 */


#include "Imaging.h"

#define	CHOP(operation, mode)\
    int x, y;\
    Imaging imOut;\
    imOut = create(imIn1, imIn2, mode);\
    if (!imOut)\
	return NULL;\
    for (y = 0; y < imOut->ysize; y++) {\
	UINT8* out = (UINT8*) imOut->image[y];\
	UINT8* in1 = (UINT8*) imIn1->image[y];\
	UINT8* in2 = (UINT8*) imIn2->image[y];\
	for (x = 0; x < imOut->linesize; x++) {\
	    int temp = operation;\
	    if (temp <= 0)\
		out[x] = 0;\
	    else if (temp >= 255)\
		out[x] = 255;\
	    else\
		out[x] = temp;\
	}\
    }\
    return imOut;

#define	CHOP2(operation, mode)\
    int x, y;\
    Imaging imOut;\
    imOut = create(imIn1, imIn2, mode);\
    if (!imOut)\
	return NULL;\
    for (y = 0; y < imOut->ysize; y++) {\
	UINT8* out = (UINT8*) imOut->image[y];\
	UINT8* in1 = (UINT8*) imIn1->image[y];\
	UINT8* in2 = (UINT8*) imIn2->image[y];\
	for (x = 0; x < imOut->linesize; x++) {\
	    out[x] = operation;\
	}\
    }\
    return imOut;

static Imaging
create(Imaging im1, Imaging im2, char* mode)
{
    int xsize, ysize;

    if (!im1 || !im2 || im1->type != IMAGING_TYPE_UINT8 ||
        (mode != NULL && (strcmp(im1->mode, "1") || strcmp(im2->mode, "1"))))
	return (Imaging) ImagingError_ModeError();
    if (im1->type  != im2->type  ||
        im1->bands != im2->bands)
	return (Imaging) ImagingError_Mismatch();

    xsize = (im1->xsize < im2->xsize) ? im1->xsize : im2->xsize;
    ysize = (im1->ysize < im2->ysize) ? im1->ysize : im2->ysize;

    return ImagingNew(im1->mode, xsize, ysize);
}

Imaging
ImagingChopLighter(Imaging imIn1, Imaging imIn2)
{
    CHOP((in1[x] > in2[x]) ? in1[x] : in2[x], NULL);
}

Imaging
ImagingChopDarker(Imaging imIn1, Imaging imIn2)
{
    CHOP((in1[x] < in2[x]) ? in1[x] : in2[x], NULL);
}

Imaging
ImagingChopDifference(Imaging imIn1, Imaging imIn2)
{
    CHOP(abs((int) in1[x] - (int) in2[x]), NULL);
}

Imaging
ImagingChopMultiply(Imaging imIn1, Imaging imIn2)
{
    CHOP((int) in1[x] * (int) in2[x] / 255, NULL);
}

Imaging
ImagingChopScreen(Imaging imIn1, Imaging imIn2)
{
    CHOP(255 - ((int) (255 - in1[x]) * (int) (255 - in2[x])) / 255, NULL);
}

Imaging
ImagingChopAdd(Imaging imIn1, Imaging imIn2, float scale, int offset)
{
    CHOP(((int) in1[x] + (int) in2[x]) / scale + offset, NULL);
}

Imaging
ImagingChopSubtract(Imaging imIn1, Imaging imIn2, float scale, int offset)
{
    CHOP(((int) in1[x] - (int) in2[x]) / scale + offset, NULL);
}

Imaging
ImagingChopAnd(Imaging imIn1, Imaging imIn2)
{
    CHOP2((in1[x] && in2[x]) ? 255 : 0, "1");
}

Imaging
ImagingChopOr(Imaging imIn1, Imaging imIn2)
{
    CHOP2((in1[x] || in2[x]) ? 255 : 0, "1");
}

Imaging
ImagingChopXor(Imaging imIn1, Imaging imIn2)
{
    CHOP2(((in1[x] != 0) ^ (in2[x] != 0)) ? 255 : 0, "1");
}

Imaging
ImagingChopAddModulo(Imaging imIn1, Imaging imIn2)
{
    CHOP2(in1[x] + in2[x], NULL);
}

Imaging
ImagingChopSubtractModulo(Imaging imIn1, Imaging imIn2)
{
    CHOP2(in1[x] - in2[x], NULL);
}
Forking PIL 2010-07-31 06:52:47 +04:00			`/*`
			`* The Python Imaging Library`
			`* $Id$`
			`*`
			`* basic channel operations`
			`*`
			`* history:`
			`* 1996-03-28 fl Created`
			`* 1996-08-13 fl Added and/or/xor for "1" images`
			`* 1996-12-14 fl Added add_modulo, sub_modulo`
			`* 2005-09-10 fl Fixed output values from and/or/xor`
			`*`
			`* Copyright (c) 1996 by Fredrik Lundh.`
			`* Copyright (c) 1997 by Secret Labs AB.`
			`*`
			`* See the README file for details on usage and redistribution.`
			`*/`


			`#include "Imaging.h"`

			`#define CHOP(operation, mode)\`
			`int x, y;\`
			`Imaging imOut;\`
			`imOut = create(imIn1, imIn2, mode);\`
			`if (!imOut)\`
			`return NULL;\`
			`for (y = 0; y < imOut->ysize; y++) {\`
			`UINT8* out = (UINT8*) imOut->image[y];\`
			`UINT8* in1 = (UINT8*) imIn1->image[y];\`
			`UINT8* in2 = (UINT8*) imIn2->image[y];\`
			`for (x = 0; x < imOut->linesize; x++) {\`
			`int temp = operation;\`
			`if (temp <= 0)\`
			`out[x] = 0;\`
			`else if (temp >= 255)\`
			`out[x] = 255;\`
			`else\`
			`out[x] = temp;\`
			`}\`
			`}\`
			`return imOut;`

			`#define CHOP2(operation, mode)\`
			`int x, y;\`
			`Imaging imOut;\`
			`imOut = create(imIn1, imIn2, mode);\`
			`if (!imOut)\`
			`return NULL;\`
			`for (y = 0; y < imOut->ysize; y++) {\`
			`UINT8* out = (UINT8*) imOut->image[y];\`
			`UINT8* in1 = (UINT8*) imIn1->image[y];\`
			`UINT8* in2 = (UINT8*) imIn2->image[y];\`
			`for (x = 0; x < imOut->linesize; x++) {\`
			`out[x] = operation;\`
			`}\`
			`}\`
			`return imOut;`

			`static Imaging`
			`create(Imaging im1, Imaging im2, char* mode)`
			`{`
			`int xsize, ysize;`

			`if (!im1 \|\| !im2 \|\| im1->type != IMAGING_TYPE_UINT8 \|\|`
			`(mode != NULL && (strcmp(im1->mode, "1") \|\| strcmp(im2->mode, "1"))))`
			`return (Imaging) ImagingError_ModeError();`
			`if (im1->type != im2->type \|\|`
			`im1->bands != im2->bands)`
			`return (Imaging) ImagingError_Mismatch();`

			`xsize = (im1->xsize < im2->xsize) ? im1->xsize : im2->xsize;`
			`ysize = (im1->ysize < im2->ysize) ? im1->ysize : im2->ysize;`

			`return ImagingNew(im1->mode, xsize, ysize);`
			`}`

			`Imaging`
			`ImagingChopLighter(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP((in1[x] > in2[x]) ? in1[x] : in2[x], NULL);`
			`}`

			`Imaging`
			`ImagingChopDarker(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP((in1[x] < in2[x]) ? in1[x] : in2[x], NULL);`
			`}`

			`Imaging`
			`ImagingChopDifference(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP(abs((int) in1[x] - (int) in2[x]), NULL);`
			`}`

			`Imaging`
			`ImagingChopMultiply(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP((int) in1[x] * (int) in2[x] / 255, NULL);`
			`}`

			`Imaging`
			`ImagingChopScreen(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP(255 - ((int) (255 - in1[x]) * (int) (255 - in2[x])) / 255, NULL);`
			`}`

			`Imaging`
			`ImagingChopAdd(Imaging imIn1, Imaging imIn2, float scale, int offset)`
			`{`
			`CHOP(((int) in1[x] + (int) in2[x]) / scale + offset, NULL);`
			`}`

			`Imaging`
			`ImagingChopSubtract(Imaging imIn1, Imaging imIn2, float scale, int offset)`
			`{`
			`CHOP(((int) in1[x] - (int) in2[x]) / scale + offset, NULL);`
			`}`

			`Imaging`
			`ImagingChopAnd(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP2((in1[x] && in2[x]) ? 255 : 0, "1");`
			`}`

			`Imaging`
			`ImagingChopOr(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP2((in1[x] \|\| in2[x]) ? 255 : 0, "1");`
			`}`

			`Imaging`
			`ImagingChopXor(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP2(((in1[x] != 0) ^ (in2[x] != 0)) ? 255 : 0, "1");`
			`}`

			`Imaging`
			`ImagingChopAddModulo(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP2(in1[x] + in2[x], NULL);`
			`}`

			`Imaging`
			`ImagingChopSubtractModulo(Imaging imIn1, Imaging imIn2)`
			`{`
			`CHOP2(in1[x] - in2[x], NULL);`
			`}`