/* * The Python Imaging Library * $Id$ * * imaging storage object * * This baseline implementation is designed to efficiently handle * large images, provided they fit into the available memory. * * history: * 1995-06-15 fl Created * 1995-09-12 fl Updated API, compiles silently under ANSI C++ * 1995-11-26 fl Compiles silently under Borland 4.5 as well * 1996-05-05 fl Correctly test status from Prologue * 1997-05-12 fl Increased THRESHOLD (to speed up Tk interface) * 1997-05-30 fl Added support for floating point images * 1997-11-17 fl Added support for "RGBX" images * 1998-01-11 fl Added support for integer images * 1998-03-05 fl Exported Prologue/Epilogue functions * 1998-07-01 fl Added basic "YCrCb" support * 1998-07-03 fl Attach palette in prologue for "P" images * 1998-07-09 hk Don't report MemoryError on zero-size images * 1998-07-12 fl Change "YCrCb" to "YCbCr" (!) * 1998-10-26 fl Added "I;16" and "I;16B" storage modes (experimental) * 1998-12-29 fl Fixed allocation bug caused by previous fix * 1999-02-03 fl Added "RGBa" and "BGR" modes (experimental) * 2001-04-22 fl Fixed potential memory leak in ImagingCopyInfo * 2003-09-26 fl Added "LA" and "PA" modes (experimental) * 2005-10-02 fl Added image counter * * Copyright (c) 1998-2005 by Secret Labs AB * Copyright (c) 1995-2005 by Fredrik Lundh * * See the README file for information on usage and redistribution. */ #include "Imaging.h" #include int ImagingNewCount = 0; /* -------------------------------------------------------------------- * Standard image object. */ Imaging ImagingNewPrologueSubtype(const char *mode, int xsize, int ysize, int size) { Imaging im; /* linesize overflow check, roughly the current largest space req'd */ if (xsize > (INT_MAX / 4) - 1) { return (Imaging) ImagingError_MemoryError(); } im = (Imaging) calloc(1, size); if (!im) { return (Imaging) ImagingError_MemoryError(); } /* Setup image descriptor */ im->xsize = xsize; im->ysize = ysize; im->type = IMAGING_TYPE_UINT8; if (strcmp(mode, "1") == 0) { /* 1-bit images */ im->bands = im->pixelsize = 1; im->linesize = xsize; } else if (strcmp(mode, "P") == 0) { /* 8-bit palette mapped images */ im->bands = im->pixelsize = 1; im->linesize = xsize; im->palette = ImagingPaletteNew("RGB"); } else if (strcmp(mode, "PA") == 0) { /* 8-bit palette with alpha */ im->bands = 2; im->pixelsize = 4; /* store in image32 memory */ im->linesize = xsize * 4; im->palette = ImagingPaletteNew("RGB"); } else if (strcmp(mode, "L") == 0) { /* 8-bit greyscale (luminance) images */ im->bands = im->pixelsize = 1; im->linesize = xsize; } else if (strcmp(mode, "LA") == 0) { /* 8-bit greyscale (luminance) with alpha */ im->bands = 2; im->pixelsize = 4; /* store in image32 memory */ im->linesize = xsize * 4; } else if (strcmp(mode, "La") == 0) { /* 8-bit greyscale (luminance) with premultiplied alpha */ im->bands = 2; im->pixelsize = 4; /* store in image32 memory */ im->linesize = xsize * 4; } else if (strcmp(mode, "F") == 0) { /* 32-bit floating point images */ im->bands = 1; im->pixelsize = 4; im->linesize = xsize * 4; im->type = IMAGING_TYPE_FLOAT32; } else if (strcmp(mode, "I") == 0) { /* 32-bit integer images */ im->bands = 1; im->pixelsize = 4; im->linesize = xsize * 4; im->type = IMAGING_TYPE_INT32; } else if (strcmp(mode, "I;16") == 0 || strcmp(mode, "I;16L") == 0 \ || strcmp(mode, "I;16B") == 0 || strcmp(mode, "I;16N") == 0) { /* EXPERIMENTAL */ /* 16-bit raw integer images */ im->bands = 1; im->pixelsize = 2; im->linesize = xsize * 2; im->type = IMAGING_TYPE_SPECIAL; } else if (strcmp(mode, "RGB") == 0) { /* 24-bit true colour images */ im->bands = 3; im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "BGR;15") == 0) { /* EXPERIMENTAL */ /* 15-bit true colour */ im->bands = 1; im->pixelsize = 2; im->linesize = (xsize*2 + 3) & -4; im->type = IMAGING_TYPE_SPECIAL; } else if (strcmp(mode, "BGR;16") == 0) { /* EXPERIMENTAL */ /* 16-bit reversed true colour */ im->bands = 1; im->pixelsize = 2; im->linesize = (xsize*2 + 3) & -4; im->type = IMAGING_TYPE_SPECIAL; } else if (strcmp(mode, "BGR;24") == 0) { /* EXPERIMENTAL */ /* 24-bit reversed true colour */ im->bands = 1; im->pixelsize = 3; im->linesize = (xsize*3 + 3) & -4; im->type = IMAGING_TYPE_SPECIAL; } else if (strcmp(mode, "BGR;32") == 0) { /* EXPERIMENTAL */ /* 32-bit reversed true colour */ im->bands = 1; im->pixelsize = 4; im->linesize = (xsize*4 + 3) & -4; im->type = IMAGING_TYPE_SPECIAL; } else if (strcmp(mode, "RGBX") == 0) { /* 32-bit true colour images with padding */ im->bands = im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "RGBA") == 0) { /* 32-bit true colour images with alpha */ im->bands = im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "RGBa") == 0) { /* EXPERIMENTAL */ /* 32-bit true colour images with premultiplied alpha */ im->bands = im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "CMYK") == 0) { /* 32-bit colour separation */ im->bands = im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "YCbCr") == 0) { /* 24-bit video format */ im->bands = 3; im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "LAB") == 0) { /* 24-bit color, luminance, + 2 color channels */ /* L is uint8, a,b are int8 */ im->bands = 3; im->pixelsize = 4; im->linesize = xsize * 4; } else if (strcmp(mode, "HSV") == 0) { /* 24-bit color, luminance, + 2 color channels */ /* L is uint8, a,b are int8 */ im->bands = 3; im->pixelsize = 4; im->linesize = xsize * 4; } else { free(im); return (Imaging) ImagingError_ValueError("unrecognized image mode"); } /* Setup image descriptor */ strcpy(im->mode, mode); /* Pointer array (allocate at least one line, to avoid MemoryError exceptions on platforms where calloc(0, x) returns NULL) */ im->image = (char **) calloc((ysize > 0) ? ysize : 1, sizeof(void *)); if ( ! im->image) { free(im); return (Imaging) ImagingError_MemoryError(); } /* Initialize alias pointers to pixel data. */ switch (im->pixelsize) { case 1: case 2: case 3: im->image8 = (UINT8 **) im->image; break; case 4: im->image32 = (INT32 **) im->image; break; } ImagingNewCount++; return im; } Imaging ImagingNewPrologue(const char *mode, int xsize, int ysize) { return ImagingNewPrologueSubtype( mode, xsize, ysize, sizeof(struct ImagingMemoryInstance)); } void ImagingDelete(Imaging im) { if (!im) return; if (im->palette) ImagingPaletteDelete(im->palette); if (im->destroy) im->destroy(im); if (im->image) free(im->image); free(im); } /* Array Storage Type */ /* ------------------ */ /* Allocate image as an array of line buffers. */ static void ImagingDestroyArray(Imaging im) { int y; if (im->image) for (y = 0; y < im->ysize; y++) if (im->image[y]) free(im->image[y]); } Imaging ImagingNewArray(const char *mode, int xsize, int ysize) { Imaging im; ImagingSectionCookie cookie; int y; char* p; im = ImagingNewPrologue(mode, xsize, ysize); if (!im) return NULL; ImagingSectionEnter(&cookie); /* Allocate image as an array of lines */ for (y = 0; y < im->ysize; y++) { /* malloc check linesize checked in prologue */ p = (char *) calloc(1, im->linesize); if (!p) { ImagingDestroyArray(im); break; } im->image[y] = p; } ImagingSectionLeave(&cookie); if (y != im->ysize) { ImagingDelete(im); return (Imaging) ImagingError_MemoryError(); } im->destroy = ImagingDestroyArray; return im; } /* Block Storage Type */ /* ------------------ */ /* Allocate image as a single block. */ static void ImagingDestroyBlock(Imaging im) { if (im->block) free(im->block); } Imaging ImagingNewBlock(const char *mode, int xsize, int ysize) { Imaging im; Py_ssize_t y, i; im = ImagingNewPrologue(mode, xsize, ysize); if ( ! im) { return NULL; } /* We shouldn't overflow, since the threshold defined below says that we're only going to allocate max 4M here before going to the array allocator. Check anyway. */ if (im->linesize && im->ysize > INT_MAX / im->linesize) { /* punt if we're going to overflow */ return NULL; } if (im->ysize * im->linesize <= 0) { /* some platforms return NULL for malloc(0); this fix prevents MemoryError on zero-sized images on such platforms */ im->block = (char *) malloc(1); } else { /* malloc check ok, overflow check above */ im->block = (char *) calloc(im->ysize, im->linesize); } if ( ! im->block) { ImagingDelete(im); return (Imaging) ImagingError_MemoryError(); } for (y = i = 0; y < im->ysize; y++) { im->image[y] = im->block + i; i += im->linesize; } im->destroy = ImagingDestroyBlock; return im; } /* -------------------------------------------------------------------- * Create a new, internally allocated, image. */ #if defined(IMAGING_SMALL_MODEL) #define THRESHOLD 16384L #else #define THRESHOLD (2048*2048*4L) #endif Imaging ImagingNew(const char* mode, int xsize, int ysize) { int bytes; Imaging im; if (strlen(mode) == 1) { if (mode[0] == 'F' || mode[0] == 'I') bytes = 4; else bytes = 1; } else bytes = strlen(mode) || 1; /* close enough */ if (xsize < 0 || ysize < 0) { return (Imaging) ImagingError_ValueError("bad image size"); } if ((int64_t) xsize * (int64_t) ysize <= THRESHOLD / bytes) { im = ImagingNewBlock(mode, xsize, ysize); if (im) return im; /* assume memory error; try allocating in array mode instead */ ImagingError_Clear(); } return ImagingNewArray(mode, xsize, ysize); } Imaging ImagingNew2(const char* mode, Imaging imOut, Imaging imIn) { /* allocate or validate output image */ if (imOut) { /* make sure images match */ if (strcmp(imOut->mode, mode) != 0 || imOut->xsize != imIn->xsize || imOut->ysize != imIn->ysize) { return ImagingError_Mismatch(); } } else { /* create new image */ imOut = ImagingNew(mode, imIn->xsize, imIn->ysize); if (!imOut) return NULL; } return imOut; } void ImagingCopyInfo(Imaging destination, Imaging source) { if (source->palette) { if (destination->palette) ImagingPaletteDelete(destination->palette); destination->palette = ImagingPaletteDuplicate(source->palette); } }