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_imaging.c
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_imaging.c
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/*
* The Python Imaging Library.
*
* the imaging library bindings
*
* history:
* 1995-09-24 fl Created
* 1996-03-24 fl Ready for first public release (release 0.0)
* 1996-03-25 fl Added fromstring (for Jack's "img" library)
* 1996-03-28 fl Added channel operations
* 1996-03-31 fl Added point operation
* 1996-04-08 fl Added new/new_block/new_array factories
* 1996-04-13 fl Added decoders
* 1996-05-04 fl Added palette hack
* 1996-05-12 fl Compile cleanly as C++
* 1996-05-19 fl Added matrix conversions, gradient fills
* 1996-05-27 fl Added display_mode
* 1996-07-22 fl Added getbbox, offset
* 1996-07-23 fl Added sequence semantics
* 1996-08-13 fl Added logical operators, point mode
* 1996-08-16 fl Modified paste interface
* 1996-09-06 fl Added putdata methods, use abstract interface
* 1996-11-01 fl Added xbm encoder
* 1996-11-04 fl Added experimental path stuff, draw_lines, etc
* 1996-12-10 fl Added zip decoder, crc32 interface
* 1996-12-14 fl Added modulo arithmetics
* 1996-12-29 fl Added zip encoder
* 1997-01-03 fl Added fli and msp decoders
* 1997-01-04 fl Added experimental sun_rle and tga_rle decoders
* 1997-01-05 fl Added gif encoder, getpalette hack
* 1997-02-23 fl Added histogram mask
* 1997-05-12 fl Minor tweaks to match the IFUNC95 interface
* 1997-05-21 fl Added noise generator, spread effect
* 1997-06-05 fl Added mandelbrot generator
* 1997-08-02 fl Modified putpalette to coerce image mode if necessary
* 1998-01-11 fl Added INT32 support
* 1998-01-22 fl Fixed draw_points to draw the last point too
* 1998-06-28 fl Added getpixel, getink, draw_ink
* 1998-07-12 fl Added getextrema
* 1998-07-17 fl Added point conversion to arbitrary formats
* 1998-09-21 fl Added support for resampling filters
* 1998-09-22 fl Added support for quad transform
* 1998-12-29 fl Added support for arcs, chords, and pieslices
* 1999-01-10 fl Added some experimental arrow graphics stuff
* 1999-02-06 fl Added draw_bitmap, font acceleration stuff
* 2001-04-17 fl Fixed some egcs compiler nits
* 2001-09-17 fl Added screen grab primitives (win32)
* 2002-03-09 fl Added stretch primitive
* 2002-03-10 fl Fixed filter handling in rotate
* 2002-06-06 fl Added I, F, and RGB support to putdata
* 2002-06-08 fl Added rankfilter
* 2002-06-09 fl Added support for user-defined filter kernels
* 2002-11-19 fl Added clipboard grab primitives (win32)
* 2002-12-11 fl Added draw context
* 2003-04-26 fl Tweaks for Python 2.3 beta 1
* 2003-05-21 fl Added createwindow primitive (win32)
* 2003-09-13 fl Added thread section hooks
* 2003-09-15 fl Added expand helper
* 2003-09-26 fl Added experimental LA support
* 2004-02-21 fl Handle zero-size images in quantize
* 2004-06-05 fl Added ptr attribute (used to access Imaging objects)
* 2004-06-05 fl Don't crash when fetching pixels from zero-wide images
* 2004-09-17 fl Added getcolors
* 2004-10-04 fl Added modefilter
* 2005-10-02 fl Added access proxy
* 2006-06-18 fl Always draw last point in polyline
*
* Copyright (c) 1997-2006 by Secret Labs AB
* Copyright (c) 1995-2006 by Fredrik Lundh
*
* See the README file for information on usage and redistribution.
*/
#define PY_SSIZE_T_CLEAN
#include "Python.h"
#ifdef HAVE_LIBJPEG
#include "jconfig.h"
#endif
#ifdef HAVE_LIBZ
#include "zlib.h"
#endif
#ifdef HAVE_LIBTIFF
#ifndef _TIFFIO_
#include <tiffio.h>
#endif
#endif
#include "libImaging/Imaging.h"
#define _USE_MATH_DEFINES
#include <math.h>
/* Configuration stuff. Feel free to undef things you don't need. */
#define WITH_IMAGECHOPS /* ImageChops support */
#define WITH_IMAGEDRAW /* ImageDraw support */
#define WITH_MAPPING /* use memory mapping to read some file formats */
#define WITH_IMAGEPATH /* ImagePath stuff */
#define WITH_ARROW /* arrow graphics stuff (experimental) */
#define WITH_EFFECTS /* special effects */
#define WITH_QUANTIZE /* quantization support */
#define WITH_RANKFILTER /* rank filter */
#define WITH_MODEFILTER /* mode filter */
#define WITH_THREADING /* "friendly" threading support */
#define WITH_UNSHARPMASK /* Kevin Cazabon's unsharpmask module */
#undef VERBOSE
#define B16(p, i) ((((int)p[(i)]) << 8) + p[(i) + 1])
#define L16(p, i) ((((int)p[(i) + 1]) << 8) + p[(i)])
#define S16(v) ((v) < 32768 ? (v) : ((v)-65536))
/* -------------------------------------------------------------------- */
/* OBJECT ADMINISTRATION */
/* -------------------------------------------------------------------- */
typedef struct {
PyObject_HEAD Imaging image;
ImagingAccess access;
} ImagingObject;
static PyTypeObject Imaging_Type;
#ifdef WITH_IMAGEDRAW
typedef struct {
/* to write a character, cut out sxy from glyph data, place
at current position plus dxy, and advance by (dx, dy) */
int dx, dy;
int dx0, dy0, dx1, dy1;
int sx0, sy0, sx1, sy1;
} Glyph;
typedef struct {
PyObject_HEAD ImagingObject *ref;
Imaging bitmap;
int ysize;
int baseline;
Glyph glyphs[256];
} ImagingFontObject;
static PyTypeObject ImagingFont_Type;
typedef struct {
PyObject_HEAD ImagingObject *image;
UINT8 ink[4];
int blend;
} ImagingDrawObject;
static PyTypeObject ImagingDraw_Type;
#endif
typedef struct {
PyObject_HEAD ImagingObject *image;
int readonly;
} PixelAccessObject;
static PyTypeObject PixelAccess_Type;
PyObject *
PyImagingNew(Imaging imOut) {
ImagingObject *imagep;
if (!imOut) {
return NULL;
}
imagep = PyObject_New(ImagingObject, &Imaging_Type);
if (imagep == NULL) {
ImagingDelete(imOut);
return NULL;
}
#ifdef VERBOSE
printf("imaging %p allocated\n", imagep);
#endif
imagep->image = imOut;
imagep->access = ImagingAccessNew(imOut);
return (PyObject *)imagep;
}
static void
_dealloc(ImagingObject *imagep) {
#ifdef VERBOSE
printf("imaging %p deleted\n", imagep);
#endif
if (imagep->access) {
ImagingAccessDelete(imagep->image, imagep->access);
}
ImagingDelete(imagep->image);
PyObject_Del(imagep);
}
#define PyImaging_Check(op) (Py_TYPE(op) == &Imaging_Type)
Imaging
PyImaging_AsImaging(PyObject *op) {
if (!PyImaging_Check(op)) {
PyErr_BadInternalCall();
return NULL;
}
return ((ImagingObject *)op)->image;
}
/* -------------------------------------------------------------------- */
/* THREAD HANDLING */
/* -------------------------------------------------------------------- */
void
ImagingSectionEnter(ImagingSectionCookie *cookie) {
#ifdef WITH_THREADING
*cookie = (PyThreadState *)PyEval_SaveThread();
#endif
}
void
ImagingSectionLeave(ImagingSectionCookie *cookie) {
#ifdef WITH_THREADING
PyEval_RestoreThread((PyThreadState *)*cookie);
#endif
}
/* -------------------------------------------------------------------- */
/* BUFFER HANDLING */
/* -------------------------------------------------------------------- */
/* Python compatibility API */
int
PyImaging_CheckBuffer(PyObject *buffer) {
return PyObject_CheckBuffer(buffer);
}
int
PyImaging_GetBuffer(PyObject *buffer, Py_buffer *view) {
/* must call check_buffer first! */
return PyObject_GetBuffer(buffer, view, PyBUF_SIMPLE);
}
/* -------------------------------------------------------------------- */
/* EXCEPTION REROUTING */
/* -------------------------------------------------------------------- */
/* error messages */
static const char *must_be_sequence = "argument must be a sequence";
static const char *must_be_two_coordinates =
"coordinate list must contain exactly 2 coordinates";
static const char *incorrectly_ordered_x_coordinate =
"x1 must be greater than or equal to x0";
static const char *incorrectly_ordered_y_coordinate =
"y1 must be greater than or equal to y0";
static const char *wrong_mode = "unrecognized image mode";
static const char *wrong_raw_mode = "unrecognized raw mode";
static const char *outside_image = "image index out of range";
static const char *outside_palette = "palette index out of range";
static const char *wrong_palette_size = "invalid palette size";
static const char *no_palette = "image has no palette";
static const char *readonly = "image is readonly";
/* static const char* no_content = "image has no content"; */
void *
ImagingError_OSError(void) {
PyErr_SetString(PyExc_OSError, "error when accessing file");
return NULL;
}
void *
ImagingError_MemoryError(void) {
return PyErr_NoMemory();
}
void *
ImagingError_Mismatch(void) {
PyErr_SetString(PyExc_ValueError, "images do not match");
return NULL;
}
void *
ImagingError_ModeError(void) {
PyErr_SetString(PyExc_ValueError, "image has wrong mode");
return NULL;
}
void *
ImagingError_ValueError(const char *message) {
PyErr_SetString(
PyExc_ValueError, (message) ? (char *)message : "unrecognized argument value");
return NULL;
}
void
ImagingError_Clear(void) {
PyErr_Clear();
}
/* -------------------------------------------------------------------- */
/* HELPERS */
/* -------------------------------------------------------------------- */
static int
getbands(const char *mode) {
Imaging im;
int bands;
/* FIXME: add primitive to libImaging to avoid extra allocation */
im = ImagingNew(mode, 0, 0);
if (!im) {
return -1;
}
bands = im->bands;
ImagingDelete(im);
return bands;
}
#define TYPE_UINT8 (0x100 | sizeof(UINT8))
#define TYPE_INT32 (0x200 | sizeof(INT32))
#define TYPE_FLOAT16 (0x500 | sizeof(FLOAT16))
#define TYPE_FLOAT32 (0x300 | sizeof(FLOAT32))
#define TYPE_DOUBLE (0x400 | sizeof(double))
static void *
getlist(PyObject *arg, Py_ssize_t *length, const char *wrong_length, int type) {
/* - allocates and returns a c array of the items in the
python sequence arg.
- the size of the returned array is in length
- all of the arg items must be numeric items of the type
specified in type
- sequence length is checked against the length parameter IF
an error parameter is passed in wrong_length
- caller is responsible for freeing the memory
*/
Py_ssize_t i, n;
int itemp;
double dtemp;
FLOAT32 ftemp;
UINT8 *list;
PyObject *seq;
PyObject *op;
if (!PySequence_Check(arg)) {
PyErr_SetString(PyExc_TypeError, must_be_sequence);
return NULL;
}
n = PySequence_Size(arg);
if (length && wrong_length && n != *length) {
PyErr_SetString(PyExc_ValueError, wrong_length);
return NULL;
}
/* malloc check ok, type & ff is just a sizeof(something)
calloc checks for overflow */
list = calloc(n, type & 0xff);
if (!list) {
return ImagingError_MemoryError();
}
seq = PySequence_Fast(arg, must_be_sequence);
if (!seq) {
free(list);
return NULL;
}
for (i = 0; i < n; i++) {
op = PySequence_Fast_GET_ITEM(seq, i);
// DRY, branch prediction is going to work _really_ well
// on this switch. And 3 fewer loops to copy/paste.
switch (type) {
case TYPE_UINT8:
itemp = PyLong_AsLong(op);
list[i] = CLIP8(itemp);
break;
case TYPE_INT32:
itemp = PyLong_AsLong(op);
memcpy(list + i * sizeof(INT32), &itemp, sizeof(itemp));
break;
case TYPE_FLOAT32:
ftemp = (FLOAT32)PyFloat_AsDouble(op);
memcpy(list + i * sizeof(ftemp), &ftemp, sizeof(ftemp));
break;
case TYPE_DOUBLE:
dtemp = PyFloat_AsDouble(op);
memcpy(list + i * sizeof(dtemp), &dtemp, sizeof(dtemp));
break;
}
}
Py_DECREF(seq);
if (PyErr_Occurred()) {
free(list);
return NULL;
}
if (length) {
*length = n;
}
return list;
}
FLOAT32
float16tofloat32(const FLOAT16 in) {
UINT32 t1;
UINT32 t2;
UINT32 t3;
FLOAT32 out[1] = {0};
t1 = in & 0x7fff; // Non-sign bits
t2 = in & 0x8000; // Sign bit
t3 = in & 0x7c00; // Exponent
t1 <<= 13; // Align mantissa on MSB
t2 <<= 16; // Shift sign bit into position
t1 += 0x38000000; // Adjust bias
t1 = (t3 == 0 ? 0 : t1); // Denormals-as-zero
t1 |= t2; // Re-insert sign bit
memcpy(out, &t1, 4);
return out[0];
}
static inline PyObject *
getpixel(Imaging im, ImagingAccess access, int x, int y) {
union {
UINT8 b[4];
UINT16 h;
INT32 i;
FLOAT32 f;
} pixel;
if (x < 0) {
x = im->xsize + x;
}
if (y < 0) {
y = im->ysize + y;
}
if (x < 0 || x >= im->xsize || y < 0 || y >= im->ysize) {
PyErr_SetString(PyExc_IndexError, outside_image);
return NULL;
}
access->get_pixel(im, x, y, &pixel);
switch (im->type) {
case IMAGING_TYPE_UINT8:
switch (im->bands) {
case 1:
return PyLong_FromLong(pixel.b[0]);
case 2:
return Py_BuildValue("BB", pixel.b[0], pixel.b[1]);
case 3:
return Py_BuildValue("BBB", pixel.b[0], pixel.b[1], pixel.b[2]);
case 4:
return Py_BuildValue(
"BBBB", pixel.b[0], pixel.b[1], pixel.b[2], pixel.b[3]);
}
break;
case IMAGING_TYPE_INT32:
return PyLong_FromLong(pixel.i);
case IMAGING_TYPE_FLOAT32:
return PyFloat_FromDouble(pixel.f);
case IMAGING_TYPE_SPECIAL:
if (strncmp(im->mode, "I;16", 4) == 0) {
return PyLong_FromLong(pixel.h);
}
break;
}
/* unknown type */
Py_INCREF(Py_None);
return Py_None;
}
static char *
getink(PyObject *color, Imaging im, char *ink) {
int g = 0, b = 0, a = 0;
double f = 0;
/* Windows 64 bit longs are 32 bits, and 0xFFFFFFFF (white) is a
python long (not int) that raises an overflow error when trying
to return it into a 32 bit C long
*/
PY_LONG_LONG r = 0;
FLOAT32 ftmp;
INT32 itmp;
/* fill ink buffer (four bytes) with something that can
be cast to either UINT8 or INT32 */
int rIsInt = 0;
if (PyTuple_Check(color) && PyTuple_GET_SIZE(color) == 1) {
color = PyTuple_GetItem(color, 0);
}
if (im->type == IMAGING_TYPE_UINT8 || im->type == IMAGING_TYPE_INT32 ||
im->type == IMAGING_TYPE_SPECIAL) {
if (PyLong_Check(color)) {
r = PyLong_AsLongLong(color);
if (r == -1 && PyErr_Occurred()) {
return NULL;
}
rIsInt = 1;
} else if (im->type == IMAGING_TYPE_UINT8) {
if (!PyTuple_Check(color)) {
PyErr_SetString(PyExc_TypeError, "color must be int or tuple");
return NULL;
}
} else {
PyErr_SetString(
PyExc_TypeError, "color must be int or single-element tuple");
return NULL;
}
}
switch (im->type) {
case IMAGING_TYPE_UINT8:
/* unsigned integer */
if (im->bands == 1) {
/* unsigned integer, single layer */
if (rIsInt != 1) {
if (PyTuple_GET_SIZE(color) != 1) {
PyErr_SetString(PyExc_TypeError, "color must be int or single-element tuple");
return NULL;
} else if (!PyArg_ParseTuple(color, "L", &r)) {
return NULL;
}
}
ink[0] = (char)CLIP8(r);
ink[1] = ink[2] = ink[3] = 0;
} else {
a = 255;
if (rIsInt) {
/* compatibility: ABGR */
a = (UINT8)(r >> 24);
b = (UINT8)(r >> 16);
g = (UINT8)(r >> 8);
r = (UINT8)r;
} else {
int tupleSize = PyTuple_GET_SIZE(color);
if (im->bands == 2) {
if (tupleSize != 1 && tupleSize != 2) {
PyErr_SetString(PyExc_TypeError, "color must be int, or tuple of one or two elements");
return NULL;
} else if (!PyArg_ParseTuple(color, "L|i", &r, &a)) {
return NULL;
}
g = b = r;
} else {
if (tupleSize != 3 && tupleSize != 4) {
PyErr_SetString(PyExc_TypeError, "color must be int, or tuple of one, three or four elements");
return NULL;
} else if (!PyArg_ParseTuple(color, "Lii|i", &r, &g, &b, &a)) {
return NULL;
}
}
}
ink[0] = (char)CLIP8(r);
ink[1] = (char)CLIP8(g);
ink[2] = (char)CLIP8(b);
ink[3] = (char)CLIP8(a);
}
return ink;
case IMAGING_TYPE_INT32:
/* signed integer */
itmp = r;
memcpy(ink, &itmp, sizeof(itmp));
return ink;
case IMAGING_TYPE_FLOAT32:
/* floating point */
f = PyFloat_AsDouble(color);
if (f == -1.0 && PyErr_Occurred()) {
return NULL;
}
ftmp = f;
memcpy(ink, &ftmp, sizeof(ftmp));
return ink;
case IMAGING_TYPE_SPECIAL:
if (strncmp(im->mode, "I;16", 4) == 0) {
ink[0] = (UINT8)r;
ink[1] = (UINT8)(r >> 8);
ink[2] = ink[3] = 0;
return ink;
}
}
PyErr_SetString(PyExc_ValueError, wrong_mode);
return NULL;
}
/* -------------------------------------------------------------------- */
/* FACTORIES */
/* -------------------------------------------------------------------- */
static PyObject *
_fill(PyObject *self, PyObject *args) {
char *mode;
int xsize, ysize;
PyObject *color;
char buffer[4];
Imaging im;
xsize = ysize = 256;
color = NULL;
if (!PyArg_ParseTuple(args, "s|(ii)O", &mode, &xsize, &ysize, &color)) {
return NULL;
}
im = ImagingNewDirty(mode, xsize, ysize);
if (!im) {
return NULL;
}
buffer[0] = buffer[1] = buffer[2] = buffer[3] = 0;
if (color) {
if (!getink(color, im, buffer)) {
ImagingDelete(im);
return NULL;
}
}
(void)ImagingFill(im, buffer);
return PyImagingNew(im);
}
static PyObject *
_new(PyObject *self, PyObject *args) {
char *mode;
int xsize, ysize;
if (!PyArg_ParseTuple(args, "s(ii)", &mode, &xsize, &ysize)) {
return NULL;
}
return PyImagingNew(ImagingNew(mode, xsize, ysize));
}
static PyObject *
_new_block(PyObject *self, PyObject *args) {
char *mode;
int xsize, ysize;
if (!PyArg_ParseTuple(args, "s(ii)", &mode, &xsize, &ysize)) {
return NULL;
}
return PyImagingNew(ImagingNewBlock(mode, xsize, ysize));
}
static PyObject *
_linear_gradient(PyObject *self, PyObject *args) {
char *mode;
if (!PyArg_ParseTuple(args, "s", &mode)) {
return NULL;
}
return PyImagingNew(ImagingFillLinearGradient(mode));
}
static PyObject *
_radial_gradient(PyObject *self, PyObject *args) {
char *mode;
if (!PyArg_ParseTuple(args, "s", &mode)) {
return NULL;
}
return PyImagingNew(ImagingFillRadialGradient(mode));
}
static PyObject *
_alpha_composite(ImagingObject *self, PyObject *args) {
ImagingObject *imagep1;
ImagingObject *imagep2;
if (!PyArg_ParseTuple(
args, "O!O!", &Imaging_Type, &imagep1, &Imaging_Type, &imagep2)) {
return NULL;
}
return PyImagingNew(ImagingAlphaComposite(imagep1->image, imagep2->image));
}
static PyObject *
_blend(ImagingObject *self, PyObject *args) {
ImagingObject *imagep1;
ImagingObject *imagep2;
double alpha;
alpha = 0.5;
if (!PyArg_ParseTuple(
args, "O!O!|d", &Imaging_Type, &imagep1, &Imaging_Type, &imagep2, &alpha)) {
return NULL;
}
return PyImagingNew(ImagingBlend(imagep1->image, imagep2->image, (float)alpha));
}
/* -------------------------------------------------------------------- */
/* METHODS */
/* -------------------------------------------------------------------- */
static INT16 *
_prepare_lut_table(PyObject *table, Py_ssize_t table_size) {
int i;
Py_buffer buffer_info;
INT32 data_type = TYPE_FLOAT32;
float item = 0;
void *table_data = NULL;
int free_table_data = 0;
INT16 *prepared;
/* NOTE: This value should be the same as in ColorLUT.c */
#define PRECISION_BITS (16 - 8 - 2)
const char *wrong_size =
("The table should have table_channels * "
"size1D * size2D * size3D float items.");
if (PyObject_CheckBuffer(table)) {
if (!PyObject_GetBuffer(table, &buffer_info, PyBUF_CONTIG_RO | PyBUF_FORMAT)) {
if (buffer_info.ndim == 1 && buffer_info.shape[0] == table_size) {
if (strlen(buffer_info.format) == 1) {
switch (buffer_info.format[0]) {
case 'e':
data_type = TYPE_FLOAT16;
table_data = buffer_info.buf;
break;
case 'f':
data_type = TYPE_FLOAT32;
table_data = buffer_info.buf;
break;
case 'd':
data_type = TYPE_DOUBLE;
table_data = buffer_info.buf;
break;
}
}
}
PyBuffer_Release(&buffer_info);
}
}
if (!table_data) {
free_table_data = 1;
table_data = getlist(table, &table_size, wrong_size, TYPE_FLOAT32);
if (!table_data) {
return NULL;
}
}
/* malloc check ok, max is 2 * 4 * 65**3 = 2197000 */
prepared = (INT16 *)malloc(sizeof(INT16) * table_size);
if (!prepared) {
if (free_table_data) {
free(table_data);
}
return (INT16 *)ImagingError_MemoryError();
}
for (i = 0; i < table_size; i++) {
FLOAT16 htmp;
double dtmp;
switch (data_type) {
case TYPE_FLOAT16:
memcpy(&htmp, ((char *)table_data) + i * sizeof(htmp), sizeof(htmp));
item = float16tofloat32(htmp);
break;
case TYPE_FLOAT32:
memcpy(
&item, ((char *)table_data) + i * sizeof(FLOAT32), sizeof(FLOAT32));
break;
case TYPE_DOUBLE:
memcpy(&dtmp, ((char *)table_data) + i * sizeof(dtmp), sizeof(dtmp));
item = (FLOAT32)dtmp;
break;
}
/* Max value for INT16 */
if (item >= (0x7fff - 0.5) / (255 << PRECISION_BITS)) {
prepared[i] = 0x7fff;
continue;
}
/* Min value for INT16 */
if (item <= (-0x8000 + 0.5) / (255 << PRECISION_BITS)) {
prepared[i] = -0x8000;
continue;
}
if (item < 0) {
prepared[i] = item * (255 << PRECISION_BITS) - 0.5;
} else {
prepared[i] = item * (255 << PRECISION_BITS) + 0.5;
}
}
#undef PRECISION_BITS
if (free_table_data) {
free(table_data);
}
return prepared;
}
static PyObject *
_color_lut_3d(ImagingObject *self, PyObject *args) {
char *mode;
int filter;
int table_channels;
int size1D, size2D, size3D;
PyObject *table;
INT16 *prepared_table;
Imaging imOut;
if (!PyArg_ParseTuple(
args,
"siiiiiO:color_lut_3d",
&mode,
&filter,
&table_channels,
&size1D,
&size2D,
&size3D,
&table)) {
return NULL;
}
/* actually, it is trilinear */
if (filter != IMAGING_TRANSFORM_BILINEAR) {
PyErr_SetString(PyExc_ValueError, "Only LINEAR filter is supported.");
return NULL;
}
if (1 > table_channels || table_channels > 4) {
PyErr_SetString(PyExc_ValueError, "table_channels should be from 1 to 4");
return NULL;
}
if (2 > size1D || size1D > 65 || 2 > size2D || size2D > 65 || 2 > size3D ||
size3D > 65) {
PyErr_SetString(
PyExc_ValueError, "Table size in any dimension should be from 2 to 65");
return NULL;
}
prepared_table =
_prepare_lut_table(table, table_channels * size1D * size2D * size3D);
if (!prepared_table) {
return NULL;
}
imOut = ImagingNewDirty(mode, self->image->xsize, self->image->ysize);
if (!imOut) {
free(prepared_table);
return NULL;
}
if (!ImagingColorLUT3D_linear(
imOut,
self->image,
table_channels,
size1D,
size2D,
size3D,
prepared_table)) {
free(prepared_table);
ImagingDelete(imOut);
return NULL;
}
free(prepared_table);
return PyImagingNew(imOut);
}
static PyObject *
_convert(ImagingObject *self, PyObject *args) {
char *mode;
int dither = 0;
ImagingObject *paletteimage = NULL;
if (!PyArg_ParseTuple(args, "s|iO", &mode, &dither, &paletteimage)) {
return NULL;
}
if (paletteimage != NULL) {
if (!PyImaging_Check(paletteimage)) {
PyObject_Print((PyObject *)paletteimage, stderr, 0);
PyErr_SetString(
PyExc_ValueError, "palette argument must be image with mode 'P'");
return NULL;
}
if (paletteimage->image->palette == NULL) {
PyErr_SetString(PyExc_ValueError, "null palette");
return NULL;
}
}
return PyImagingNew(ImagingConvert(
self->image, mode, paletteimage ? paletteimage->image->palette : NULL, dither));
}
static PyObject *
_convert2(ImagingObject *self, PyObject *args) {
ImagingObject *imagep1;
ImagingObject *imagep2;
if (!PyArg_ParseTuple(
args, "O!O!", &Imaging_Type, &imagep1, &Imaging_Type, &imagep2)) {
return NULL;
}
if (!ImagingConvert2(imagep1->image, imagep2->image)) {
return NULL;
}
Py_INCREF(Py_None);
return Py_None;
}
static PyObject *
_convert_matrix(ImagingObject *self, PyObject *args) {
char *mode;
float m[12];
if (!PyArg_ParseTuple(args, "s(ffff)", &mode, m + 0, m + 1, m + 2, m + 3)) {
PyErr_Clear();
if (!PyArg_ParseTuple(
args,
"s(ffffffffffff)",
&mode,
m + 0,
m + 1,
m + 2,
m + 3,
m + 4,
m + 5,
m + 6,
m + 7,
m + 8,
m + 9,
m + 10,
m + 11)) {
return NULL;
}
}
return PyImagingNew(ImagingConvertMatrix(self->image, mode, m));
}
static PyObject *
_convert_transparent(ImagingObject *self, PyObject *args) {
char *mode;
int r, g, b;
if (PyArg_ParseTuple(args, "s(iii)", &mode, &r, &g, &b)) {
return PyImagingNew(ImagingConvertTransparent(self->image, mode, r, g, b));
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "si", &mode, &r)) {
return PyImagingNew(ImagingConvertTransparent(self->image, mode, r, 0, 0));
}
return NULL;
}
static PyObject *
_copy(ImagingObject *self, PyObject *args) {
if (!PyArg_ParseTuple(args, "")) {
return NULL;
}
return PyImagingNew(ImagingCopy(self->image));
}
static PyObject *
_crop(ImagingObject *self, PyObject *args) {
int x0, y0, x1, y1;
if (!PyArg_ParseTuple(args, "(iiii)", &x0, &y0, &x1, &y1)) {
return NULL;
}
return PyImagingNew(ImagingCrop(self->image, x0, y0, x1, y1));
}
static PyObject *
_expand_image(ImagingObject *self, PyObject *args) {
int x, y;
int mode = 0;
if (!PyArg_ParseTuple(args, "ii|i", &x, &y, &mode)) {
return NULL;
}