Mercurial > hg > release > icedtea7-forest-2.2 > jdk
view src/share/native/sun/awt/medialib/awt_ImagingLib.c @ 5363:384c02152d67
8012597: Better image channel verification
Reviewed-by: ahgross, vadim, prr
| author | bae |
|---|---|
| date | Tue, 30 Apr 2013 04:20:46 +0400 |
| parents | d82a5acd535d |
| children | aa0194c5cec0 |
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/* * Copyright (c) 1997, 2010, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include "sun_awt_image_ImagingLib.h" #include "java_awt_Transparency.h" #include "java_awt_image_AffineTransformOp.h" #include "java_awt_image_BufferedImage.h" #include "java_awt_color_ColorSpace.h" #include "java_awt_image_ConvolveOp.h" #include "sun_awt_image_IntegerComponentRaster.h" #include "awt_ImagingLib.h" #include "awt_parseImage.h" #include "imageInitIDs.h" #include <jni.h> #include <jni_util.h> #include <assert.h> #include "awt_Mlib.h" #include "gdefs.h" #include "safe_alloc.h" #include "safe_math.h" /*************************************************************************** * Definitions * ***************************************************************************/ #define jio_fprintf fprintf #ifndef TRUE #define TRUE 1 #endif /* TRUE */ #ifndef FALSE #define FALSE 0 #endif /* FALSE */ #define TYPE_CUSTOM java_awt_image_BufferedImage_TYPE_CUSTOM #define TYPE_INT_RGB java_awt_image_BufferedImage_TYPE_INT_RGB #define TYPE_INT_ARGB java_awt_image_BufferedImage_TYPE_INT_ARGB #define TYPE_INT_ARGB_PRE java_awt_image_BufferedImage_TYPE_INT_ARGB_PRE #define TYPE_INT_BGR java_awt_image_BufferedImage_TYPE_INT_BGR #define TYPE_4BYTE_ABGR java_awt_image_BufferedImage_TYPE_4BYTE_ABGR #define TYPE_4BYTE_ABGR_PRE java_awt_image_BufferedImage_TYPE_4BYTE_ABGR_PRE /* (alpha*color)>>nbits + alpha>>(nbits-1) */ #define BLEND(color, alpha, alphaNbits) \ ((((alpha)*(color))>>(alphaNbits)) + ((alpha) >> ((alphaNbits)-1))) /* ((color - (alpha>>(nBits-1)))<<nBits)/alpha */ #define UNBLEND(color, alpha, alphaNbits) \ ((((color)-((alpha)>>((alphaNbits)-1)))<<(alphaNbits))/(alpha)) /* Enumeration of all of the mlib functions used */ typedef enum { MLIB_CONVMxN, MLIB_AFFINE, MLIB_LOOKUP, MLIB_CONVKERNCVT } mlibTypeE_t; typedef struct { int dataType; /* One of BYTE_DATA_TYPE, SHORT_DATA_TYPE, */ int needToCopy; int cvtSrcToDefault; /* If TRUE, convert the src to def CM (pre?) */ int allocDefaultDst; /* If TRUE, alloc def CM dst buffer */ int cvtToDst; /* If TRUE, convert dst buffer to Dst CM */ int addAlpha; } mlibHintS_t; /*************************************************************************** * Static Variables/Structures * ***************************************************************************/ static mlibSysFnS_t sMlibSysFns = { NULL, // placeholder for j2d_mlib_ImageCreate NULL, // placeholder for j2d_mlib_ImageCreateStruct NULL, // placeholder for j2d_mlib_ImageDelete }; static mlibFnS_t sMlibFns[] = { {NULL, "j2d_mlib_ImageConvMxN"}, {NULL, "j2d_mlib_ImageAffine"}, {NULL, "j2d_mlib_ImageLookUp"}, {NULL, "j2d_mlib_ImageConvKernelConvert"}, {NULL, NULL}, }; static int s_timeIt = 0; static int s_printIt = 0; static int s_startOff = 0; static int s_nomlib = 0; /*************************************************************************** * Static Function Prototypes * ***************************************************************************/ static int allocateArray(JNIEnv *env, BufImageS_t *imageP, mlib_image **mlibImagePP, void **dataPP, int isSrc, int cvtToDefault, int addAlpha); static int allocateRasterArray(JNIEnv *env, RasterS_t *rasterP, mlib_image **mlibImagePP, void **dataPP, int isSrc); static void freeArray(JNIEnv *env, BufImageS_t *srcimageP, mlib_image *srcmlibImP, void *srcdataP, BufImageS_t *dstimageP, mlib_image *dstmlibImP, void *dstdataP); static void freeDataArray(JNIEnv *env, jobject srcJdata, mlib_image *srcmlibImP, void *srcdataP, jobject dstJdata, mlib_image *dstmlibImP, void *dstdataP); static int storeImageArray(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, mlib_image *mlibImP); static int storeRasterArray(JNIEnv *env, RasterS_t *srcP, RasterS_t *dstP, mlib_image *mlibImP); static int storeICMarray(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, mlib_image *mlibImP); static int colorMatch(int r, int g, int b, int a, unsigned char *argb, int numColors); static int setImageHints(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, int expandICM, int useAlpha, int premultiply, mlibHintS_t *hintP); static int expandICM(JNIEnv *env, BufImageS_t *imageP, unsigned int *mDataP); static int expandPackedBCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int expandPackedSCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int expandPackedICR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int expandPackedBCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha); static int expandPackedSCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha); static int expandPackedICRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha); static int setPackedBCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int setPackedSCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int setPackedICR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP); static int setPackedBCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int supportsAlpha); static int setPackedSCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int supportsAlpha); static int setPackedICRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int supportsAlpha); mlib_start_timer start_timer = NULL; mlib_stop_timer stop_timer = NULL; /*************************************************************************** * Debugging Definitions * ***************************************************************************/ #ifdef DEBUG static void printMedialibError(int status) { switch(status) { case MLIB_FAILURE: jio_fprintf(stderr, "failure\n"); break; case MLIB_NULLPOINTER: jio_fprintf(stderr, "null pointer\n"); break; case MLIB_OUTOFRANGE: jio_fprintf (stderr, "out of range\n"); break; default: jio_fprintf (stderr, "medialib error\n"); break; } } #else /* ! DEBUG */ # define printMedialibError(x) #endif /* ! DEBUG */ static int getMlibEdgeHint(jint edgeHint) { switch (edgeHint) { case java_awt_image_ConvolveOp_EDGE_NO_OP: return MLIB_EDGE_DST_COPY_SRC; case java_awt_image_ConvolveOp_EDGE_ZERO_FILL: default: return MLIB_EDGE_DST_FILL_ZERO; } } /*************************************************************************** * External Functions * ***************************************************************************/ JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_convolveBI(JNIEnv *env, jobject this, jobject jsrc, jobject jdst, jobject jkernel, jint edgeHint) { void *sdata, *ddata; mlib_image *src; mlib_image *dst; int i, scale; mlib_d64 *dkern; mlib_s32 *kdata; int klen; float kmax; mlib_s32 cmask; mlib_status status; int retStatus = 1; float *kern; BufImageS_t *srcImageP, *dstImageP; jobject jdata; int kwidth; int kheight; int w, h; int x, y; mlibHintS_t hint; int nbands; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) (*start_timer)(3600); kwidth = (*env)->GetIntField(env, jkernel, g_KernelWidthID); kheight = (*env)->GetIntField(env, jkernel, g_KernelHeightID); jdata = (*env)->GetObjectField(env, jkernel, g_KernelDataID); klen = (*env)->GetArrayLength(env, jdata); kern = (float *) (*env)->GetPrimitiveArrayCritical(env, jdata, NULL); if (kern == NULL) { /* out of memory exception already thrown */ return 0; } if ((kwidth&0x1) == 0) { /* Kernel has even width */ w = kwidth+1; } else { w = kwidth; } if ((kheight&0x1) == 0) { /* Kernel has even height */ h = kheight+1; } else { h = kheight; } dkern = NULL; if (SAFE_TO_ALLOC_3(w, h, sizeof(mlib_d64))) { dkern = (mlib_d64 *)calloc(1, w * h * sizeof(mlib_d64)); } if (dkern == NULL) { (*env)->ReleasePrimitiveArrayCritical(env, jdata, kern, JNI_ABORT); return 0; } /* Need to flip and find max value of the kernel. * Also, save the kernel values as mlib_d64 values. * The flip is to operate correctly with medialib, * which doesn't do the mathemetically correct thing, * i.e. it doesn't rotate the kernel by 180 degrees. * REMIND: This should perhaps be done at the Java * level by ConvolveOp. * REMIND: Should the max test be looking at absolute * values? * REMIND: What if klen != kheight * kwidth? */ kmax = kern[klen-1]; i = klen-1; for (y=0; y < kheight; y++) { for (x=0; x < kwidth; x++, i--) { dkern[y*w+x] = (mlib_d64) kern[i]; if (kern[i] > kmax) { kmax = kern[i]; } } } (*env)->ReleasePrimitiveArrayCritical(env, jdata, kern, JNI_ABORT); if (kmax > 1<<16) { /* We can only handle 16 bit max */ free(dkern); return 0; } /* Parse the source image */ if ((status = awt_parseImage(env, jsrc, &srcImageP, FALSE)) <= 0) { /* Can't handle any custom images */ free(dkern); return 0; } /* Parse the destination image */ if ((status = awt_parseImage(env, jdst, &dstImageP, FALSE)) <= 0) { /* Can't handle any custom images */ awt_freeParsedImage(srcImageP, TRUE); free(dkern); return 0; } nbands = setImageHints(env, srcImageP, dstImageP, TRUE, TRUE, FALSE, &hint); if (nbands < 1) { /* Can't handle any custom images */ awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); return 0; } /* Allocate the arrays */ if (allocateArray(env, srcImageP, &src, &sdata, TRUE, hint.cvtSrcToDefault, hint.addAlpha) < 0) { /* Must be some problem */ awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); return 0; } if (allocateArray(env, dstImageP, &dst, &ddata, FALSE, hint.cvtToDst, FALSE) < 0) { /* Must be some problem */ freeArray(env, srcImageP, src, sdata, NULL, NULL, NULL); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); return 0; } kdata = NULL; if (SAFE_TO_ALLOC_3(w, h, sizeof(mlib_s32))) { kdata = (mlib_s32 *)malloc(w * h * sizeof(mlib_s32)); } if (kdata == NULL) { freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); return 0; } if ((*sMlibFns[MLIB_CONVKERNCVT].fptr)(kdata, &scale, dkern, w, h, mlib_ImageGetType(src)) != MLIB_SUCCESS) { freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); free(kdata); return 0; } if (s_printIt) { fprintf(stderr, "Orig Kernel(len=%d):\n",klen); for (y=kheight-1; y >= 0; y--) { for (x=kwidth-1; x >= 0; x--) { fprintf(stderr, "%g ", dkern[y*w+x]); } fprintf(stderr, "\n"); } fprintf(stderr, "New Kernel(scale=%d):\n", scale); for (y=kheight-1; y >= 0; y--) { for (x=kwidth-1; x >= 0; x--) { fprintf(stderr, "%d ", kdata[y*w+x]); } fprintf(stderr, "\n"); } } cmask = (1<<src->channels)-1; status = (*sMlibFns[MLIB_CONVMxN].fptr)(dst, src, kdata, w, h, (w-1)/2, (h-1)/2, scale, cmask, getMlibEdgeHint(edgeHint)); if (status != MLIB_SUCCESS) { printMedialibError(status); retStatus = 0; } if (s_printIt) { unsigned int *dP; if (s_startOff != 0) { printf("Starting at %d\n", s_startOff); } if (sdata == NULL) { dP = (unsigned int *) mlib_ImageGetData(src); } else { dP = (unsigned int *) sdata; } printf("src is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[s_startOff+i]); } printf("\n"); if (ddata == NULL) { dP = (unsigned int *)mlib_ImageGetData(dst); } else { dP = (unsigned int *) ddata; } printf("dst is \n"); for (i=0; i < 20; i++) { printf("%x ",dP[s_startOff+i]); } printf("\n"); } /* Means that we couldn't write directly into the destination buffer */ if (ddata == NULL) { /* Need to store it back into the array */ if (storeImageArray(env, srcImageP, dstImageP, dst) < 0) { /* Error */ retStatus = 0; } } /* Release the pinned memory */ freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); free(dkern); free(kdata); if (s_timeIt) (*stop_timer)(3600, 1); return retStatus; } JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_convolveRaster(JNIEnv *env, jobject this, jobject jsrc, jobject jdst, jobject jkernel, jint edgeHint) { mlib_image *src; mlib_image *dst; int i, scale; mlib_d64 *dkern; mlib_s32 *kdata; int klen; float kmax; int retStatus = 1; mlib_status status; mlib_s32 cmask; void *sdata; void *ddata; RasterS_t *srcRasterP; RasterS_t *dstRasterP; int kwidth; int kheight; int w, h; int x, y; jobject jdata; float *kern; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) (*start_timer)(3600); kwidth = (*env)->GetIntField(env, jkernel, g_KernelWidthID); kheight = (*env)->GetIntField(env, jkernel, g_KernelHeightID); jdata = (*env)->GetObjectField(env, jkernel, g_KernelDataID); klen = (*env)->GetArrayLength(env, jdata); kern = (float *) (*env)->GetPrimitiveArrayCritical(env, jdata, NULL); if (kern == NULL) { /* out of memory exception already thrown */ return 0; } if ((kwidth&0x1) == 0) { /* Kernel has even width */ w = kwidth+1; } else { w = kwidth; } if ((kheight&0x1) == 0) { /* Kernel has even height */ h = kheight+1; } else { h = kheight; } dkern = NULL; if (SAFE_TO_ALLOC_3(w, h, sizeof(mlib_d64))) { dkern = (mlib_d64 *)calloc(1, w * h * sizeof(mlib_d64)); } if (dkern == NULL) { (*env)->ReleasePrimitiveArrayCritical(env, jdata, kern, JNI_ABORT); return 0; } /* Need to flip and find max value of the kernel. * Also, save the kernel values as mlib_d64 values. * The flip is to operate correctly with medialib, * which doesn't do the mathemetically correct thing, * i.e. it doesn't rotate the kernel by 180 degrees. * REMIND: This should perhaps be done at the Java * level by ConvolveOp. * REMIND: Should the max test be looking at absolute * values? * REMIND: What if klen != kheight * kwidth? */ kmax = kern[klen-1]; i = klen-1; for (y=0; y < kheight; y++) { for (x=0; x < kwidth; x++, i--) { dkern[y*w+x] = (mlib_d64) kern[i]; if (kern[i] > kmax) { kmax = kern[i]; } } } (*env)->ReleasePrimitiveArrayCritical(env, jdata, kern, JNI_ABORT); if (kmax > 1<<16) { /* We can only handle 16 bit max */ free(dkern); return 0; } /* Parse the source image */ if ((srcRasterP = (RasterS_t *) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); free(dkern); return -1; } if ((dstRasterP = (RasterS_t *) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); free(srcRasterP); free(dkern); return -1; } /* Parse the source raster */ if ((status = awt_parseRaster(env, jsrc, srcRasterP)) <= 0) { /* Can't handle any custom rasters */ free(srcRasterP); free(dstRasterP); free(dkern); return 0; } /* Parse the destination raster */ if ((status = awt_parseRaster(env, jdst, dstRasterP)) <= 0) { /* Can't handle any custom images */ awt_freeParsedRaster(srcRasterP, TRUE); free(dstRasterP); free(dkern); return 0; } /* Allocate the arrays */ if (allocateRasterArray(env, srcRasterP, &src, &sdata, TRUE) < 0) { /* Must be some problem */ awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); free(dkern); return 0; } if (allocateRasterArray(env, dstRasterP, &dst, &ddata, FALSE) < 0) { /* Must be some problem */ freeDataArray(env, srcRasterP->jdata, src, sdata, NULL, NULL, NULL); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); free(dkern); return 0; } kdata = NULL; if (SAFE_TO_ALLOC_3(w, h, sizeof(mlib_s32))) { kdata = (mlib_s32 *)malloc(w * h * sizeof(mlib_s32)); } if (kdata == NULL) { freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); free(dkern); return 0; } if ((*sMlibFns[MLIB_CONVKERNCVT].fptr)(kdata, &scale, dkern, w, h, mlib_ImageGetType(src)) != MLIB_SUCCESS) { freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); free(dkern); free(kdata); return 0; } if (s_printIt) { fprintf(stderr, "Orig Kernel(len=%d):\n",klen); for (y=kheight-1; y >= 0; y--) { for (x=kwidth-1; x >= 0; x--) { fprintf(stderr, "%g ", dkern[y*w+x]); } fprintf(stderr, "\n"); } fprintf(stderr, "New Kernel(scale=%d):\n", scale); for (y=kheight-1; y >= 0; y--) { for (x=kwidth-1; x >= 0; x--) { fprintf(stderr, "%d ", kdata[y*w+x]); } fprintf(stderr, "\n"); } } cmask = (1<<src->channels)-1; status = (*sMlibFns[MLIB_CONVMxN].fptr)(dst, src, kdata, w, h, (w-1)/2, (h-1)/2, scale, cmask, getMlibEdgeHint(edgeHint)); if (status != MLIB_SUCCESS) { printMedialibError(status); retStatus = 0; } if (s_printIt) { unsigned int *dP; if (s_startOff != 0) { printf("Starting at %d\n", s_startOff); } if (sdata == NULL) { dP = (unsigned int *) mlib_ImageGetData(src); } else { dP = (unsigned int *) sdata; } printf("src is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[s_startOff+i]); } printf("\n"); if (ddata == NULL) { dP = (unsigned int *)mlib_ImageGetData(dst); } else { dP = (unsigned int *) ddata; } printf("dst is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[s_startOff+i]); } printf("\n"); } /* Means that we couldn't write directly into the destination buffer */ if (ddata == NULL) { unsigned char *bdataP; unsigned short *sdataP; /* Punt for now */ switch (dstRasterP->dataType) { case BYTE_DATA_TYPE: bdataP = (unsigned char *) mlib_ImageGetData(dst); retStatus = (awt_setPixelByte(env, -1, dstRasterP, bdataP) >= 0) ; break; case SHORT_DATA_TYPE: sdataP = (unsigned short *) mlib_ImageGetData(dst); retStatus = (awt_setPixelShort(env, -1, dstRasterP, sdataP) >= 0) ; break; default: retStatus = 0; } } /* Release the pinned memory */ freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); free(dkern); free(kdata); if (s_timeIt) (*stop_timer)(3600,1); return retStatus; } JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_transformBI(JNIEnv *env, jobject this, jobject jsrc, jobject jdst, jdoubleArray jmatrix, jint interpType) { mlib_image *src; mlib_image *dst; int i; int retStatus = 1; mlib_status status; double *matrix; mlib_d64 mtx[6]; void *sdata; void *ddata; BufImageS_t *srcImageP; BufImageS_t *dstImageP; mlib_filter filter; mlibHintS_t hint; unsigned int *dP; int useIndexed; int nbands; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) { (*start_timer)(3600); } switch(interpType) { case java_awt_image_AffineTransformOp_TYPE_BILINEAR: filter = MLIB_BILINEAR; break; case java_awt_image_AffineTransformOp_TYPE_NEAREST_NEIGHBOR: filter = MLIB_NEAREST; break; case java_awt_image_AffineTransformOp_TYPE_BICUBIC: filter = MLIB_BICUBIC; break; default: JNU_ThrowInternalError(env, "Unknown interpolation type"); return -1; } if ((*env)->GetArrayLength(env, jmatrix) < 6) { /* * Very unlikely, however we should check for this: * if given matrix array is too short, we can't handle it */ return 0; } matrix = (*env)->GetPrimitiveArrayCritical(env, jmatrix, NULL); if (matrix == NULL) { /* out of memory error already thrown */ return 0; } if (s_printIt) { printf("matrix is %g %g %g %g %g %g\n", matrix[0], matrix[1], matrix[2], matrix[3], matrix[4], matrix[5]); } mtx[0] = matrix[0]; mtx[1] = matrix[2]; mtx[2] = matrix[4]; mtx[3] = matrix[1]; mtx[4] = matrix[3]; mtx[5] = matrix[5]; (*env)->ReleasePrimitiveArrayCritical(env, jmatrix, matrix, JNI_ABORT); /* Parse the source image */ if ((status = awt_parseImage(env, jsrc, &srcImageP, FALSE)) <= 0) { /* Can't handle any custom images */ return 0; } /* Parse the destination image */ if ((status = awt_parseImage(env, jdst, &dstImageP, FALSE)) <= 0) { /* Can't handle any custom images */ awt_freeParsedImage(srcImageP, TRUE); return 0; } /* REMIND!! Can't assume that it is the same LUT!! */ /* Fix 4213160, 4184283 */ useIndexed = (srcImageP->cmodel.cmType == INDEX_CM_TYPE && dstImageP->cmodel.cmType == INDEX_CM_TYPE && srcImageP->raster.rasterType == dstImageP->raster.rasterType && srcImageP->raster.rasterType == COMPONENT_RASTER_TYPE); nbands = setImageHints(env, srcImageP, dstImageP, !useIndexed, TRUE, FALSE, &hint); if (nbands < 1) { /* Can't handle any custom images */ awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } /* Allocate the arrays */ if (allocateArray(env, srcImageP, &src, &sdata, TRUE, hint.cvtSrcToDefault, hint.addAlpha) < 0) { /* Must be some problem */ awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } if (allocateArray(env, dstImageP, &dst, &ddata, FALSE, hint.cvtToDst, FALSE) < 0) { /* Must be some problem */ freeArray(env, srcImageP, src, sdata, NULL, NULL, NULL); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } #if 0 fprintf(stderr,"Src----------------\n"); fprintf(stderr,"Type : %d\n",src->type); fprintf(stderr,"Channels: %d\n",src->channels); fprintf(stderr,"Width : %d\n",src->width); fprintf(stderr,"Height : %d\n",src->height); fprintf(stderr,"Stride : %d\n",src->stride); fprintf(stderr,"Flags : %d\n",src->flags); fprintf(stderr,"Dst----------------\n"); fprintf(stderr,"Type : %d\n",dst->type); fprintf(stderr,"Channels: %d\n",dst->channels); fprintf(stderr,"Width : %d\n",dst->width); fprintf(stderr,"Height : %d\n",dst->height); fprintf(stderr,"Stride : %d\n",dst->stride); fprintf(stderr,"Flags : %d\n",dst->flags); #endif if (dstImageP->cmodel.cmType == INDEX_CM_TYPE) { /* Need to clear the destination to the transparent pixel */ unsigned char *cP = (unsigned char *)mlib_ImageGetData(dst); memset(cP, dstImageP->cmodel.transIdx, mlib_ImageGetWidth(dst)*mlib_ImageGetHeight(dst)); } /* Perform the transformation */ if ((status = (*sMlibFns[MLIB_AFFINE].fptr)(dst, src, mtx, filter, MLIB_EDGE_SRC_EXTEND) != MLIB_SUCCESS)) { printMedialibError(status); freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } if (s_printIt) { if (sdata == NULL) { dP = (unsigned int *) mlib_ImageGetData(src); } else { dP = (unsigned int *) sdata; } printf("src is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[i]); } printf("\n"); if (ddata == NULL) { dP = (unsigned int *)mlib_ImageGetData(dst); } else { dP = (unsigned int *) ddata; } printf("dst is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[i]); } printf("\n"); } /* Means that we couldn't write directly into the destination buffer */ if (ddata == NULL) { freeDataArray(env, srcImageP->raster.jdata, src, sdata, NULL, NULL, NULL); /* Need to store it back into the array */ if (storeImageArray(env, srcImageP, dstImageP, dst) < 0) { /* Error */ retStatus = 0; } freeDataArray(env, NULL, NULL, NULL, dstImageP->raster.jdata, dst, ddata); } else { /* Release the pinned memory */ freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); } awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); if (s_timeIt) (*stop_timer)(3600,1); return retStatus; } JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_transformRaster(JNIEnv *env, jobject this, jobject jsrc, jobject jdst, jdoubleArray jmatrix, jint interpType) { mlib_image *src; mlib_image *dst; int i; int retStatus = 1; mlib_status status; double *matrix; mlib_d64 mtx[6]; void *sdata; void *ddata; RasterS_t *srcRasterP; RasterS_t *dstRasterP; mlib_filter filter; unsigned int *dP; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) { (*start_timer)(3600); } switch(interpType) { case java_awt_image_AffineTransformOp_TYPE_BILINEAR: filter = MLIB_BILINEAR; break; case java_awt_image_AffineTransformOp_TYPE_NEAREST_NEIGHBOR: filter = MLIB_NEAREST; break; case java_awt_image_AffineTransformOp_TYPE_BICUBIC: filter = MLIB_BICUBIC; break; default: JNU_ThrowInternalError(env, "Unknown interpolation type"); return -1; } if ((srcRasterP = (RasterS_t *) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); return -1; } if ((dstRasterP = (RasterS_t *) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); free(srcRasterP); return -1; } if ((*env)->GetArrayLength(env, jmatrix) < 6) { /* * Very unlikely, however we should check for this: * if given matrix array is too short, we can't handle it. */ free(srcRasterP); free(dstRasterP); return 0; } matrix = (*env)->GetPrimitiveArrayCritical(env, jmatrix, NULL); if (matrix == NULL) { /* out of memory error already thrown */ free(srcRasterP); free(dstRasterP); return 0; } if (s_printIt) { printf("matrix is %g %g %g %g %g %g\n", matrix[0], matrix[1], matrix[2], matrix[3], matrix[4], matrix[5]); } mtx[0] = matrix[0]; mtx[1] = matrix[2]; mtx[2] = matrix[4]; mtx[3] = matrix[1]; mtx[4] = matrix[3]; mtx[5] = matrix[5]; (*env)->ReleasePrimitiveArrayCritical(env, jmatrix, matrix, JNI_ABORT); /* Parse the source raster */ if ((status = awt_parseRaster(env, jsrc, srcRasterP)) <= 0) { /* Can't handle any custom rasters */ free(srcRasterP); free(dstRasterP); return 0; } /* Parse the destination raster */ if ((status = awt_parseRaster(env, jdst, dstRasterP)) <= 0) { /* Can't handle any custom images */ awt_freeParsedRaster(srcRasterP, TRUE); free(dstRasterP); return 0; } /* Allocate the arrays */ if (allocateRasterArray(env, srcRasterP, &src, &sdata, TRUE) < 0) { /* Must be some problem */ awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } if (allocateRasterArray(env, dstRasterP, &dst, &ddata, FALSE) < 0) { /* Must be some problem */ freeDataArray(env, srcRasterP->jdata, src, sdata, NULL, NULL, NULL); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } #if 0 fprintf(stderr,"Src----------------\n"); fprintf(stderr,"Type : %d\n",src->type); fprintf(stderr,"Channels: %d\n",src->channels); fprintf(stderr,"Width : %d\n",src->width); fprintf(stderr,"Height : %d\n",src->height); fprintf(stderr,"Stride : %d\n",src->stride); fprintf(stderr,"Flags : %d\n",src->flags); fprintf(stderr,"Dst----------------\n"); fprintf(stderr,"Type : %d\n",dst->type); fprintf(stderr,"Channels: %d\n",dst->channels); fprintf(stderr,"Width : %d\n",dst->width); fprintf(stderr,"Height : %d\n",dst->height); fprintf(stderr,"Stride : %d\n",dst->stride); fprintf(stderr,"Flags : %d\n",dst->flags); #endif { unsigned char *cP = (unsigned char *)mlib_ImageGetData(dst); memset(cP, 0, mlib_ImageGetWidth(dst)*mlib_ImageGetHeight(dst)); } /* Perform the transformation */ if ((status = (*sMlibFns[MLIB_AFFINE].fptr)(dst, src, mtx, filter, MLIB_EDGE_SRC_EXTEND) != MLIB_SUCCESS)) { printMedialibError(status); /* REMIND: Free the regions */ return 0; } if (s_printIt) { if (sdata == NULL) { dP = (unsigned int *) mlib_ImageGetData(src); } else { dP = (unsigned int *) sdata; } printf("src is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[i]); } printf("\n"); if (ddata == NULL) { dP = (unsigned int *)mlib_ImageGetData(dst); } else { dP = (unsigned int *) ddata; } printf("dst is\n"); for (i=0; i < 20; i++) { printf("%x ",dP[i]); } printf("\n"); } /* Means that we couldn't write directly into the destination buffer */ if (ddata == NULL) { unsigned char *bdataP; unsigned short *sdataP; /* Need to store it back into the array */ if (storeRasterArray(env, srcRasterP, dstRasterP, dst) < 0) { /* Punt for now */ switch (dst->type) { case MLIB_BYTE: bdataP = (unsigned char *) mlib_ImageGetData(dst); retStatus = (awt_setPixelByte(env, -1, dstRasterP, bdataP) >= 0) ; break; case MLIB_SHORT: sdataP = (unsigned short *) mlib_ImageGetData(dst); retStatus = (awt_setPixelShort(env, -1, dstRasterP, sdataP) >= 0) ; break; default: retStatus = 0; } } } /* Release the pinned memory */ freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); if (s_timeIt) (*stop_timer)(3600,1); return retStatus; } typedef struct { jobject jArray; jsize length; unsigned char *table; } LookupArrayInfo; #define NLUT 8 #ifdef _LITTLE_ENDIAN #define INDEXES { 3, 2, 1, 0, 7, 6, 5, 4 } #else #define INDEXES { 0, 1, 2, 3, 4, 5, 6, 7 } #endif static int lookupShortData(mlib_image* src, mlib_image* dst, LookupArrayInfo* lookup) { int x, y; unsigned int mask = NLUT-1; unsigned short* srcLine = (unsigned short*)src->data; unsigned char* dstLine = (unsigned char*)dst->data; static int indexes[NLUT] = INDEXES; if (src->width != dst->width || src->height != dst->height) { return 0; } for (y=0; y < src->height; y++) { int nloop, nx; int npix = src->width; unsigned short* srcPixel = srcLine; unsigned char* dstPixel = dstLine; #ifdef SIMPLE_LOOKUP_LOOP for (x=0; status && x < width; x++) { unsigned short s = *srcPixel++; if (s >= lookup->length) { /* we can not handle source image using * byte lookup table. Fall back to processing * images in java */ return 0; } *dstPixel++ = lookup->table[s]; } #else /* Get to 32 bit-aligned point */ while(((uintptr_t)dstPixel & 0x3) != 0 && npix>0) { unsigned short s = *srcPixel++; if (s >= lookup->length) { return 0; } *dstPixel++ = lookup->table[s]; npix--; } /* * Do NLUT pixels per loop iteration. * Pack into ints and write out 2 at a time. */ nloop = npix/NLUT; nx = npix%NLUT; for(x=nloop; x!=0; x--) { int i = 0; int* dstP = (int*)dstPixel; for (i = 0; i < NLUT; i++) { if (srcPixel[i] >= lookup->length) { return 0; } } dstP[0] = (int) ((lookup->table[srcPixel[indexes[0]]] << 24) | (lookup->table[srcPixel[indexes[1]]] << 16) | (lookup->table[srcPixel[indexes[2]]] << 8) | lookup->table[srcPixel[indexes[3]]]); dstP[1] = (int) ((lookup->table[srcPixel[indexes[4]]] << 24) | (lookup->table[srcPixel[indexes[5]]] << 16) | (lookup->table[srcPixel[indexes[6]]] << 8) | lookup->table[srcPixel[indexes[7]]]); dstPixel += NLUT; srcPixel += NLUT; } /* * Complete any remaining pixels */ for(x=nx; x!=0; x--) { unsigned short s = *srcPixel++; if (s >= lookup->length) { return 0; } *dstPixel++ = lookup->table[s]; } #endif dstLine += dst->stride; // array of bytes, scan stride in bytes srcLine += src->stride / 2; // array of shorts, scan stride in bytes } return 1; } JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_lookupByteBI(JNIEnv *env, jobject thisLib, jobject jsrc, jobject jdst, jobjectArray jtableArrays) { mlib_image *src; mlib_image *dst; void *sdata, *ddata; unsigned char **tbl; unsigned char lut[256]; int retStatus = 1; int i; mlib_status status; int lut_nbands; LookupArrayInfo *jtable; BufImageS_t *srcImageP, *dstImageP; int nbands; int ncomponents; mlibHintS_t hint; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) (*start_timer)(3600); /* Parse the source image */ if ((status = awt_parseImage(env, jsrc, &srcImageP, FALSE)) <= 0) { /* Can't handle any custom images */ return 0; } /* Parse the destination image */ if ((status = awt_parseImage(env, jdst, &dstImageP, FALSE)) <= 0) { /* Can't handle any custom images */ awt_freeParsedImage(srcImageP, TRUE); return 0; } lut_nbands = (*env)->GetArrayLength(env, jtableArrays); ncomponents = srcImageP->cmodel.isDefaultCompatCM ? 4 : srcImageP->cmodel.numComponents; if (lut_nbands > ncomponents) { lut_nbands = ncomponents; } /* Make sure that color order can be used for * re-ordering of lookup arrays. */ for (i = 0; i < ncomponents; i++) { int idx = srcImageP->hints.colorOrder[i]; if (idx < 0 || idx >= ncomponents) { awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } } tbl = NULL; if (SAFE_TO_ALLOC_2(ncomponents, sizeof(unsigned char *))) { tbl = (unsigned char **) calloc(1, ncomponents * sizeof(unsigned char *)); } jtable = NULL; if (SAFE_TO_ALLOC_2(lut_nbands, sizeof(LookupArrayInfo))) { jtable = (LookupArrayInfo *)malloc(lut_nbands * sizeof (LookupArrayInfo)); } if (tbl == NULL || jtable == NULL) { if (tbl != NULL) free(tbl); if (jtable != NULL) free(jtable); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); JNU_ThrowNullPointerException(env, "NULL LUT"); return 0; } /* Need to grab these pointers before we lock down arrays */ for (i=0; i < lut_nbands; i++) { jtable[i].jArray = (*env)->GetObjectArrayElement(env, jtableArrays, i); if (jtable[i].jArray != NULL) { jtable[i].length = (*env)->GetArrayLength(env, jtable[i].jArray); jtable[i].table = NULL; if (jtable[i].length < 256) { /* we may read outside the table during lookup */ jtable[i].jArray = NULL; jtable[i].length = 0; } } if (jtable[i].jArray == NULL) { free(tbl); free(jtable); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } } nbands = setImageHints(env, srcImageP, dstImageP, FALSE, TRUE, FALSE, &hint); if (nbands < 1) { /* Can't handle any custom images */ free(tbl); free(jtable); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } /* Allocate the arrays */ if (allocateArray(env, srcImageP, &src, &sdata, TRUE, FALSE, FALSE) < 0) { /* Must be some problem */ free(tbl); free(jtable); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } if (allocateArray(env, dstImageP, &dst, &ddata, FALSE, FALSE, FALSE) < 0) { /* Must be some problem */ free(tbl); free(jtable); freeArray(env, srcImageP, src, sdata, NULL, NULL, NULL); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } /* Set up a straight lut so we don't mess around with alpha */ /* * NB: medialib lookup routine expects lookup array for each * component of source image including alpha. * If lookup table we got form the java layer does not contain * sufficient number of lookup arrays we add references to identity * lookup array to make medialib happier. */ if (lut_nbands < ncomponents) { int j; /* REMIND: This should be the size of the input lut!! */ for (j=0; j < 256; j++) { lut[j] = j; } for (j=0; j < ncomponents; j++) { tbl[j] = lut; } } for (i=0; i < lut_nbands; i++) { jtable[i].table = (unsigned char *) (*env)->GetPrimitiveArrayCritical(env, jtable[i].jArray, NULL); if (jtable[i].table == NULL) { /* Free what we've got so far. */ int j; for (j = 0; j < i; j++) { (*env)->ReleasePrimitiveArrayCritical(env, jtable[j].jArray, (jbyte *) jtable[j].table, JNI_ABORT); } free(tbl); free(jtable); freeArray(env, srcImageP, src, sdata, NULL, NULL, NULL); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); return 0; } tbl[srcImageP->hints.colorOrder[i]] = jtable[i].table; } if (lut_nbands == 1) { for (i=1; i < nbands - srcImageP->cmodel.supportsAlpha; i++) { tbl[srcImageP->hints.colorOrder[i]] = jtable[0].table; } } /* Mlib needs 16bit lookuptable and must be signed! */ if (src->type == MLIB_SHORT) { if (dst->type == MLIB_BYTE) { if (nbands > 1) { retStatus = 0; } else { retStatus = lookupShortData(src, dst, &jtable[0]); } } /* How about ddata == null? */ } else if ((status = (*sMlibFns[MLIB_LOOKUP].fptr)(dst, src, (void **)tbl) != MLIB_SUCCESS)) { printMedialibError(status); retStatus = 0; } /* * Means that we couldn't write directly into * the destination buffer */ if (ddata == NULL) { /* Need to store it back into the array */ if (storeImageArray(env, srcImageP, dstImageP, dst) < 0) { /* Error */ retStatus = 0; } } /* Release the LUT */ for (i=0; i < lut_nbands; i++) { (*env)->ReleasePrimitiveArrayCritical(env, jtable[i].jArray, (jbyte *) jtable[i].table, JNI_ABORT); } free ((void *) jtable); free ((void *) tbl); /* Release the pinned memory */ freeArray(env, srcImageP, src, sdata, dstImageP, dst, ddata); awt_freeParsedImage(srcImageP, TRUE); awt_freeParsedImage(dstImageP, TRUE); if (s_timeIt) (*stop_timer)(3600, 1); return retStatus; } JNIEXPORT jint JNICALL Java_sun_awt_image_ImagingLib_lookupByteRaster(JNIEnv *env, jobject this, jobject jsrc, jobject jdst, jobjectArray jtableArrays) { RasterS_t* srcRasterP; RasterS_t* dstRasterP; mlib_image* src; mlib_image* dst; void* sdata; void* ddata; LookupArrayInfo jtable[4]; unsigned char* mlib_lookupTable[4]; int i; int retStatus = 1; mlib_status status; int jlen; int lut_nbands; int src_nbands; int dst_nbands; unsigned char ilut[256]; /* This function requires a lot of local refs ??? Is 64 enough ??? */ if ((*env)->EnsureLocalCapacity(env, 64) < 0) return 0; if (s_nomlib) return 0; if (s_timeIt) (*start_timer)(3600); if ((srcRasterP = (RasterS_t*) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); return -1; } if ((dstRasterP = (RasterS_t *) calloc(1, sizeof(RasterS_t))) == NULL) { JNU_ThrowOutOfMemoryError(env, "Out of memory"); free(srcRasterP); return -1; } /* Parse the source raster - reject custom images */ if ((status = awt_parseRaster(env, jsrc, srcRasterP)) <= 0) { free(srcRasterP); free(dstRasterP); return 0; } /* Parse the destination image - reject custom images */ if ((status = awt_parseRaster(env, jdst, dstRasterP)) <= 0) { awt_freeParsedRaster(srcRasterP, TRUE); free(dstRasterP); return 0; } jlen = (*env)->GetArrayLength(env, jtableArrays); lut_nbands = jlen; src_nbands = srcRasterP->numBands; dst_nbands = dstRasterP->numBands; /* adjust number of lookup bands */ if (lut_nbands > src_nbands) { lut_nbands = src_nbands; } /* MediaLib can't do more than 4 bands */ if (src_nbands <= 0 || src_nbands > 4 || dst_nbands <= 0 || dst_nbands > 4 || lut_nbands <= 0 || lut_nbands > 4 || src_nbands != dst_nbands || ((lut_nbands != 1) && (lut_nbands != src_nbands))) { // we should free parsed rasters here awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } /* Allocate the raster arrays */ if (allocateRasterArray(env, srcRasterP, &src, &sdata, TRUE) < 0) { /* Must be some problem */ awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } if (allocateRasterArray(env, dstRasterP, &dst, &ddata, FALSE) < 0) { /* Must be some problem */ freeDataArray(env, srcRasterP->jdata, src, sdata, NULL, NULL, NULL); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } /* * Well, until now we have analyzed number of bands in * src and dst rasters. * However, it is not enough because medialib lookup routine uses * number of channels of medialib image. Note that in certain * case number of channels may differs form the number of bands. * Good example is raster that is used in TYPE_INT_RGB buffered * image: it has 3 bands, but their medialib representation has * 4 channels. * * In order to avoid the lookup routine failure, we need: * * 1. verify that src and dst have same number of channels. * 2. provide lookup array for every channel. If we have "extra" * channel (like the raster described above) then we need to * provide identical lookup array. */ if (src->channels != dst->channels) { freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } if (src_nbands < src->channels) { for (i = 0; i < 256; i++) { ilut[i] = i; } } /* Get references to the lookup table arrays */ /* Need to grab these pointers before we lock down arrays */ for (i=0; i < lut_nbands; i++) { jtable[i].jArray = (*env)->GetObjectArrayElement(env, jtableArrays, i); jtable[i].table = NULL; if (jtable[i].jArray != NULL) { jtable[i].length = (*env)->GetArrayLength(env, jtable[i].jArray); if (jtable[i].length < 256) { /* we may read outside the table during lookup */ jtable[i].jArray = NULL; } } if (jtable[i].jArray == NULL) { freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } } for (i=0; i < lut_nbands; i++) { jtable[i].table = (unsigned char *) (*env)->GetPrimitiveArrayCritical(env, jtable[i].jArray, NULL); if (jtable[i].table == NULL) { /* Free what we've got so far. */ int j; for (j = 0; j < i; j++) { (*env)->ReleasePrimitiveArrayCritical(env, jtable[j].jArray, (jbyte *) jtable[j].table, JNI_ABORT); } freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); return 0; } mlib_lookupTable[i] = jtable[i].table; } /* * Medialib routine expects lookup array for each band of raster. * Setup the rest of lookup arrays if supplied lookup table * contains single lookup array. */ for (i = lut_nbands; i < src_nbands; i++) { mlib_lookupTable[i] = jtable[0].table; } /* * Setup lookup array for "extra" channels */ for ( ; i < src->channels; i++) { mlib_lookupTable[i] = ilut; } /* Mlib needs 16bit lookuptable and must be signed! */ if (src->type == MLIB_SHORT) { if (dst->type == MLIB_BYTE) { if (lut_nbands > 1) { retStatus = 0; } else { retStatus = lookupShortData(src, dst, &jtable[0]); } } /* How about ddata == null? */ } else if ((status = (*sMlibFns[MLIB_LOOKUP].fptr)(dst, src, (void **)mlib_lookupTable) != MLIB_SUCCESS)) { printMedialibError(status); retStatus = 0; } /* * Means that we couldn't write directly into * the destination buffer */ if (ddata == NULL) { unsigned char* bdataP; unsigned short* sdataP; switch (dstRasterP->dataType) { case BYTE_DATA_TYPE: bdataP = (unsigned char *) mlib_ImageGetData(dst); retStatus = (awt_setPixelByte(env, -1, dstRasterP, bdataP) >= 0) ; break; case SHORT_DATA_TYPE: sdataP = (unsigned short *) mlib_ImageGetData(dst); retStatus = (awt_setPixelShort(env, -1, dstRasterP, sdataP) >= 0) ; break; default: retStatus = 0; } } /* Release the LUT */ for (i=0; i < lut_nbands; i++) { (*env)->ReleasePrimitiveArrayCritical(env, jtable[i].jArray, (jbyte *) jtable[i].table, JNI_ABORT); } /* Release the pinned memory */ freeDataArray(env, srcRasterP->jdata, src, sdata, dstRasterP->jdata, dst, ddata); awt_freeParsedRaster(srcRasterP, TRUE); awt_freeParsedRaster(dstRasterP, TRUE); if (s_timeIt) (*stop_timer)(3600, 1); return retStatus; } JNIEXPORT jboolean JNICALL Java_sun_awt_image_ImagingLib_init(JNIEnv *env, jclass thisClass) { char *start; if (getenv("IMLIB_DEBUG")) { start_timer = awt_setMlibStartTimer(); stop_timer = awt_setMlibStopTimer(); if (start_timer && stop_timer) { s_timeIt = 1; } } if (getenv("IMLIB_PRINT")) { s_printIt = 1; } if ((start = getenv("IMLIB_START")) != NULL) { sscanf(start, "%d", &s_startOff); } if (getenv ("IMLIB_NOMLIB")) { s_nomlib = 1; return JNI_FALSE; } /* This function is platform-dependent and is in awt_mlib.c */ if (awt_getImagingLib(env, (mlibFnS_t *)&sMlibFns, &sMlibSysFns) != MLIB_SUCCESS) { s_nomlib = 1; return JNI_FALSE; } return JNI_TRUE; } /* REMIND: How to specify border? */ static void extendEdge(JNIEnv *env, BufImageS_t *imageP, int *widthP, int *heightP) { RasterS_t *rasterP = &imageP->raster; int width; int height; /* Useful for convolution? */ jobject jbaseraster = (*env)->GetObjectField(env, rasterP->jraster, g_RasterBaseRasterID); width = rasterP->width; height = rasterP->height; #ifdef WORKING if (! JNU_IsNull(env, jbaseraster) && !(*env)->IsSameObject(env, rasterP->jraster, jbaseraster)) { int xOff; int yOff; int baseWidth; int baseHeight; int baseXoff; int baseYoff; /* Not the same object so get the width and height */ xOff = (*env)->GetIntField(env, rasterP->jraster, g_RasterXOffsetID); yOff = (*env)->GetIntField(env, rasterP->jraster, g_RasterYOffsetID); baseWidth = (*env)->GetIntField(env, jbaseraster, g_RasterWidthID); baseHeight = (*env)->GetIntField(env, jbaseraster, g_RasterHeightID); baseXoff = (*env)->GetIntField(env, jbaseraster, g_RasterXOffsetID); baseYoff = (*env)->GetIntField(env, jbaseraster, g_RasterYOffsetID); if (xOff + rasterP->width < baseXoff + baseWidth) { /* Can use edge */ width++; } if (yOff + rasterP->height < baseYoff + baseHeight) { /* Can use edge */ height++; } } #endif } static int setImageHints(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, int expandICM, int useAlpha, int premultiply, mlibHintS_t *hintP) { ColorModelS_t *srcCMP = &srcP->cmodel; ColorModelS_t *dstCMP = &dstP->cmodel; int nbands = 0; int ncomponents; hintP->dataType = srcP->raster.dataType; hintP->addAlpha = FALSE; /* Are the color spaces the same? */ if (srcCMP->csType != dstCMP->csType) { /* If the src is GRAY and dst RGB, we can handle it */ if (!(srcCMP->csType == java_awt_color_ColorSpace_TYPE_GRAY && dstCMP->csType == java_awt_color_ColorSpace_TYPE_RGB)) { /* Nope, need to handle that in java for now */ return -1; } else { hintP->cvtSrcToDefault = TRUE; } } else { if (srcP->hints.needToExpand) { hintP->cvtSrcToDefault = TRUE; } else { /* Need to initialize this */ hintP->cvtSrcToDefault = FALSE; } } ncomponents = srcCMP->numComponents; if ((useAlpha == 0) && srcCMP->supportsAlpha) { ncomponents--; /* ?? */ /* Not really, more like shrink src to get rid of alpha */ hintP->cvtSrcToDefault = TRUE; } hintP->dataType = srcP->raster.dataType; if (hintP->cvtSrcToDefault == FALSE) { if (srcCMP->cmType == INDEX_CM_TYPE) { if (expandICM) { nbands = srcCMP->numComponents; hintP->cvtSrcToDefault = TRUE; if (dstCMP->isDefaultCompatCM) { hintP->allocDefaultDst = FALSE; hintP->cvtToDst = FALSE; } else if (dstCMP->isDefaultCompatCM) { hintP->allocDefaultDst = FALSE; hintP->cvtToDst = FALSE; } } else { nbands = 1; hintP->cvtSrcToDefault = FALSE; } } else { if (srcP->hints.packing & INTERLEAVED) { nbands = srcCMP->numComponents; } else { nbands = 1; } /* Look at the packing */ if ((srcP->hints.packing&BYTE_INTERLEAVED)==BYTE_INTERLEAVED || (srcP->hints.packing&SHORT_INTERLEAVED)==SHORT_INTERLEAVED|| (srcP->hints.packing&BYTE_SINGLE_BAND) == BYTE_SINGLE_BAND|| (srcP->hints.packing&SHORT_SINGLE_BAND)==SHORT_SINGLE_BAND|| (srcP->hints.packing&BYTE_BANDED) == BYTE_BANDED || (srcP->hints.packing&SHORT_BANDED) == SHORT_BANDED) { /* Can use src directly */ hintP->cvtSrcToDefault = FALSE; } else { /* Must be packed or custom */ hintP->cvtSrcToDefault = TRUE; } } } if (hintP->cvtSrcToDefault) { /* By definition */ nbands = 4; /* What about alpha? */ hintP->dataType = BYTE_DATA_TYPE; hintP->needToCopy = TRUE; if (srcP->imageType == dstP->imageType) { hintP->cvtToDst = TRUE; } else if (dstP->cmodel.isDefaultCM) { /* Not necessarily */ hintP->cvtToDst = FALSE; } else { hintP->cvtToDst = TRUE; } } else { int srcImageType = srcP->imageType; int dstImageType = dstP->imageType; /* Special case where we need to fill in alpha values */ if (srcCMP->isDefaultCompatCM && dstCMP->isDefaultCompatCM) { int i; if (!srcCMP->supportsAlpha &&dstCMP->supportsAlpha) { hintP->addAlpha = TRUE; } for (i=0; i < srcCMP->numComponents; i++) { if (srcP->hints.colorOrder[i] != dstP->hints.colorOrder[i]){ if (!srcCMP->isDefaultCM) { hintP->cvtSrcToDefault = TRUE; srcImageType = java_awt_image_BufferedImage_TYPE_INT_ARGB; } if (!dstCMP->isDefaultCM) { hintP->cvtToDst = TRUE; dstImageType = java_awt_image_BufferedImage_TYPE_INT_ARGB; } break; } } } else if (srcCMP->cmType != INDEX_CM_TYPE && !srcCMP->supportsAlpha && dstCMP->supportsAlpha) { /* We've already handled the index case. This is for the rest of the cases */ srcImageType = java_awt_image_BufferedImage_TYPE_INT_ARGB; hintP->cvtSrcToDefault = TRUE; } hintP->allocDefaultDst = FALSE; if (srcImageType == dstImageType) { /* Same image type so use it */ hintP->cvtToDst = FALSE; } else if (srcImageType == TYPE_INT_RGB && (dstImageType == TYPE_INT_ARGB || dstImageType == TYPE_INT_ARGB_PRE)) { hintP->cvtToDst = FALSE; } else if (srcImageType == TYPE_INT_BGR && (dstImageType == TYPE_4BYTE_ABGR || dstImageType == TYPE_4BYTE_ABGR_PRE)) { hintP->cvtToDst = FALSE; } else if (srcP->hints.packing == dstP->hints.packing) { /* Now what? */ /* Check color order */ /* Check if just need to scale the data */ hintP->cvtToDst = TRUE; } else { /* Don't know what it is so convert it */ hintP->allocDefaultDst = TRUE; hintP->cvtToDst = TRUE; } hintP->needToCopy = (ncomponents > nbands); } return nbands; } static int expandPacked(JNIEnv *env, BufImageS_t *img, ColorModelS_t *cmP, RasterS_t *rasterP, int component, unsigned char *bdataP) { if (rasterP->rasterType == COMPONENT_RASTER_TYPE) { switch (rasterP->dataType) { case BYTE_DATA_TYPE: if (expandPackedBCR(env, rasterP, component, bdataP) < 0) { /* Must have been an error */ return -1; } break; case SHORT_DATA_TYPE: if (expandPackedICR(env, rasterP, component, bdataP) < 0) { /* Must have been an error */ return -1; } break; case INT_DATA_TYPE: if (expandPackedICR(env, rasterP, component, bdataP) < 0) { /* Must have been an error */ return -1; } break; default: /* REMIND: Return some sort of error */ return -1; } } else { /* REMIND: Return some sort of error */ return -1; } return 0; } static int cvtCustomToDefault(JNIEnv *env, BufImageS_t *imageP, int component, unsigned char *dataP) { ColorModelS_t *cmP = &imageP->cmodel; RasterS_t *rasterP = &imageP->raster; int y; jobject jpixels = NULL; jint *pixels; unsigned char *dP = dataP; #define NUM_LINES 10 int numLines = NUM_LINES; /* it is safe to calculate the scan length, because width has been verified * on creation of the mlib image */ int scanLength = rasterP->width * 4; int nbytes = 0; if (!SAFE_TO_MULT(numLines, scanLength)) { return -1; } nbytes = numLines * scanLength; for (y=0; y < rasterP->height; y+=numLines) { /* getData, one scanline at a time */ if (y+numLines > rasterP->height) { numLines = rasterP->height - y; nbytes = numLines * scanLength; } jpixels = (*env)->CallObjectMethod(env, imageP->jimage, g_BImgGetRGBMID, 0, y, rasterP->width, numLines, jpixels,0, rasterP->width); if (jpixels == NULL) { JNU_ThrowInternalError(env, "Can't retrieve pixels."); return -1; } pixels = (*env)->GetPrimitiveArrayCritical(env, jpixels, NULL); memcpy(dP, pixels, nbytes); dP += nbytes; (*env)->ReleasePrimitiveArrayCritical(env, jpixels, pixels, JNI_ABORT); } return 0; } static int cvtDefaultToCustom(JNIEnv *env, BufImageS_t *imageP, int component, unsigned char *dataP) { ColorModelS_t *cmP = &imageP->cmodel; RasterS_t *rasterP = &imageP->raster; int y; jint *pixels; unsigned char *dP = dataP; #define NUM_LINES 10 int numLines = NUM_LINES; int nbytes = rasterP->width*4*NUM_LINES; jintArray jpixels; jpixels = (*env)->NewIntArray(env, nbytes); if (JNU_IsNull(env, jpixels)) { JNU_ThrowOutOfMemoryError(env, "Out of Memory"); return -1; } for (y=0; y < rasterP->height; y+=NUM_LINES) { if (y+numLines > rasterP->height) { numLines = rasterP->height - y; nbytes = rasterP->width*4*numLines; } pixels = (*env)->GetPrimitiveArrayCritical(env, jpixels, NULL); if (pixels == NULL) { /* JNI error */ return -1; } memcpy(pixels, dP, nbytes); dP += nbytes; (*env)->ReleasePrimitiveArrayCritical(env, jpixels, pixels, 0); /* setData, one scanline at a time */ /* Fix 4223648, 4184283 */ (*env)->CallVoidMethod(env, imageP->jimage, g_BImgSetRGBMID, 0, y, rasterP->width, numLines, jpixels, 0, rasterP->width); if ((*env)->ExceptionOccurred(env)) { return -1; } } /* Need to release the array */ (*env)->DeleteLocalRef(env, jpixels); return 0; } static int allocateArray(JNIEnv *env, BufImageS_t *imageP, mlib_image **mlibImagePP, void **dataPP, int isSrc, int cvtToDefault, int addAlpha) { void *dataP; unsigned char *cDataP; RasterS_t *rasterP = &imageP->raster; ColorModelS_t *cmP = &imageP->cmodel; int dataType = BYTE_DATA_TYPE; int width; int height; HintS_t *hintP = &imageP->hints; *dataPP = NULL; width = rasterP->width; height = rasterP->height; /* Useful for convolution? */ /* This code is zero'ed out so that it cannot be called */ /* To do this correctly, we need to expand src and dst in the */ /* same direction up/down/left/right only if both can be expanded */ /* in that direction. Expanding right and down is easy - */ /* increment width. Expanding top and left requires bumping */ /* around pointers and incrementing the width/height */ #if 0 if (0 && useEdges) { baseWidth = rasterP->baseRasterWidth; baseHeight = rasterP->baseRasterHeight; baseXoff = rasterP->baseOriginX; baseYoff = rasterP->baseOriginY; if (rasterP->minX + rasterP->width < baseXoff + baseWidth) { /* Can use edge */ width++; } if (rasterP->minY + rasterP->height < baseYoff + baseHeight) { /* Can use edge */ height++; } if (rasterP->minX > baseXoff ) { /* Can use edge */ width++; /* NEED TO BUMP POINTER BACK A PIXELSTRIDE */ } if (rasterP->minY > baseYoff) { /* Can use edge */ height++; /* NEED TO BUMP POINTER BACK A SCANLINE */ } } #endif if (cvtToDefault) { int status = 0; *mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, 4, width, height); if (*mlibImagePP == NULL) { return -1; } cDataP = (unsigned char *) mlib_ImageGetData(*mlibImagePP); /* Make sure the image is cleared. * NB: the image dimension is already verified, so we can * safely calculate the length of the buffer. */ memset(cDataP, 0, width*height*4); if (!isSrc) { return 0; } switch(imageP->cmodel.cmType) { case INDEX_CM_TYPE: /* REMIND: Need to rearrange according to dst cm */ /* Fix 4213160, 4184283 */ if (rasterP->rasterType == COMPONENT_RASTER_TYPE) { return expandICM(env, imageP, (unsigned int *)cDataP); } else { return cvtCustomToDefault(env, imageP, -1, cDataP); } case DIRECT_CM_TYPE: switch(imageP->raster.dataType) { case BYTE_DATA_TYPE: return expandPackedBCRdefault(env, rasterP, -1, cDataP, !imageP->cmodel.supportsAlpha); case SHORT_DATA_TYPE: return expandPackedSCRdefault(env, rasterP, -1, cDataP, !imageP->cmodel.supportsAlpha); case INT_DATA_TYPE: return expandPackedICRdefault(env, rasterP, -1, cDataP, !imageP->cmodel.supportsAlpha); } } /* switch(imageP->cmodel.cmType) */ return cvtCustomToDefault(env, imageP, -1, cDataP); } /* Interleaved with shared data */ dataP = (void *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) { return -1; } /* Means we need to fill in alpha */ if (!cvtToDefault && addAlpha) { *mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, 4, width, height); if (*mlibImagePP != NULL) { unsigned int *dstP = (unsigned int *) mlib_ImageGetData(*mlibImagePP); int dstride = (*mlibImagePP)->stride>>2; int sstride = hintP->sStride>>2; unsigned int *srcP = (unsigned int *) ((unsigned char *)dataP + hintP->dataOffset); unsigned int *dP, *sP; int x, y; for (y=0; y < height; y++, srcP += sstride, dstP += dstride){ sP = srcP; dP = dstP; for (x=0; x < width; x++) { dP[x] = sP[x] | 0xff000000; } } } (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); return 0; } else if ((hintP->packing & BYTE_INTERLEAVED) == BYTE_INTERLEAVED) { int nChans = (cmP->isDefaultCompatCM ? 4 : hintP->numChans); /* Easy case. It is or is similar to the default CM so use * the array. Must be byte data. */ /* Create the medialib image */ *mlibImagePP = (*sMlibSysFns.createStructFP)(MLIB_BYTE, nChans, width, height, hintP->sStride, (unsigned char *)dataP + hintP->dataOffset); } else if ((hintP->packing & SHORT_INTERLEAVED) == SHORT_INTERLEAVED) { *mlibImagePP = (*sMlibSysFns.createStructFP)(MLIB_SHORT, hintP->numChans, width, height, imageP->raster.scanlineStride*2, (unsigned short *)dataP + hintP->channelOffset); } else { /* Release the data array */ (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); return -1; } *dataPP = dataP; return 0; } static int allocateRasterArray(JNIEnv *env, RasterS_t *rasterP, mlib_image **mlibImagePP, void **dataPP, int isSrc) { void *dataP; unsigned char *cDataP; unsigned short *sdataP; int dataType = BYTE_DATA_TYPE; int width; int height; int dataSize; int offset; *dataPP = NULL; width = rasterP->width; height = rasterP->height; if (rasterP->numBands <= 0 || rasterP->numBands > 4) { /* REMIND: Fix this */ return -1; } /* Useful for convolution? */ /* This code is zero'ed out so that it cannot be called */ /* To do this correctly, we need to expand src and dst in the */ /* same direction up/down/left/right only if both can be expanded */ /* in that direction. Expanding right and down is easy - */ /* increment width. Expanding top and left requires bumping */ /* around pointers and incrementing the width/height */ #if 0 if (0 && useEdges) { baseWidth = rasterP->baseRasterWidth; baseHeight = rasterP->baseRasterHeight; baseXoff = rasterP->baseOriginX; baseYoff = rasterP->baseOriginY; if (rasterP->minX + rasterP->width < baseXoff + baseWidth) { /* Can use edge */ width++; } if (rasterP->minY + rasterP->height < baseYoff + baseHeight) { /* Can use edge */ height++; } if (rasterP->minX > baseXoff ) { /* Can use edge */ width++; /* NEED TO BUMP POINTER BACK A PIXELSTRIDE */ } if (rasterP->minY > baseYoff) { /* Can use edge */ height++; /* NEED TO BUMP POINTER BACK A SCANLINE */ } } #endif switch (rasterP->type) { case sun_awt_image_IntegerComponentRaster_TYPE_INT_8BIT_SAMPLES: if (!((rasterP->chanOffsets[0] == 0 || SAFE_TO_ALLOC_2(rasterP->chanOffsets[0], 4)) && SAFE_TO_ALLOC_2(width, 4) && SAFE_TO_ALLOC_3(height, rasterP->scanlineStride, 4))) { return -1; } offset = 4 * rasterP->chanOffsets[0]; dataSize = 4 * (*env)->GetArrayLength(env, rasterP->jdata); if (offset < 0 || offset >= dataSize || width > rasterP->scanlineStride || height * rasterP->scanlineStride * 4 > dataSize - offset) { // raster data buffer is too short return -1; } dataP = (void *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) { return -1; } *mlibImagePP = (*sMlibSysFns.createStructFP)(MLIB_BYTE, 4, width, height, rasterP->scanlineStride*4, (unsigned char *)dataP + offset); *dataPP = dataP; return 0; case sun_awt_image_IntegerComponentRaster_TYPE_BYTE_SAMPLES: if (!(SAFE_TO_ALLOC_2(width, rasterP->numBands) && SAFE_TO_ALLOC_2(height, rasterP->scanlineStride))) { return -1; } offset = rasterP->chanOffsets[0]; dataSize = (*env)->GetArrayLength(env, rasterP->jdata); if (offset < 0 || offset >= dataSize || width * rasterP->numBands > rasterP->scanlineStride || height * rasterP->scanlineStride > dataSize - offset) { // raster data buffer is too short return -1; } dataP = (void *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) { return -1; } *mlibImagePP = (*sMlibSysFns.createStructFP)(MLIB_BYTE, rasterP->numBands, width, height, rasterP->scanlineStride, (unsigned char *)dataP + offset); *dataPP = dataP; return 0; case sun_awt_image_IntegerComponentRaster_TYPE_USHORT_SAMPLES: if (!((rasterP->chanOffsets[0] == 0 || SAFE_TO_ALLOC_2(rasterP->chanOffsets[0], 2)) && SAFE_TO_ALLOC_3(width, rasterP->numBands, 2) && SAFE_TO_ALLOC_3(height, rasterP->scanlineStride, 2))) { return -1; } offset = rasterP->chanOffsets[0] * 2; dataSize = 2 * (*env)->GetArrayLength(env, rasterP->jdata); if (offset < 0 || offset >= dataSize || width * rasterP->numBands > rasterP->scanlineStride || height * rasterP->scanlineStride * 2 > dataSize - offset) { // raster data buffer is too short return -1; } dataP = (void *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) { return -1; } *mlibImagePP = (*sMlibSysFns.createStructFP)(MLIB_SHORT, rasterP->numBands, width, height, rasterP->scanlineStride*2, (unsigned char *)dataP + offset); *dataPP = dataP; return 0; case sun_awt_image_IntegerComponentRaster_TYPE_BYTE_PACKED_SAMPLES: *mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, rasterP->numBands, width, height); if (*mlibImagePP == NULL) { return -1; } if (!isSrc) return 0; cDataP = (unsigned char *) mlib_ImageGetData(*mlibImagePP); return expandPackedBCR(env, rasterP, -1, cDataP); case sun_awt_image_IntegerComponentRaster_TYPE_USHORT_PACKED_SAMPLES: if (rasterP->sppsm.maxBitSize <= 8) { *mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, rasterP->numBands, width, height); if (*mlibImagePP == NULL) { return -1; } if (!isSrc) return 0; cDataP = (unsigned char *) mlib_ImageGetData(*mlibImagePP); return expandPackedSCR(env, rasterP, -1, cDataP); } break; case sun_awt_image_IntegerComponentRaster_TYPE_INT_PACKED_SAMPLES: if (rasterP->sppsm.maxBitSize <= 8) { *mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, rasterP->numBands, width, height); if (*mlibImagePP == NULL) { return -1; } if (!isSrc) return 0; cDataP = (unsigned char *) mlib_ImageGetData(*mlibImagePP); return expandPackedICR(env, rasterP, -1, cDataP); } break; } /* Just expand it right now */ switch (rasterP->dataType) { case BYTE_DATA_TYPE: if ((*mlibImagePP = (*sMlibSysFns.createFP)(MLIB_BYTE, rasterP->numBands, width, height)) == NULL) { return -1; } if (isSrc) { cDataP = (unsigned char *) mlib_ImageGetData(*mlibImagePP); if (awt_getPixelByte(env, -1, rasterP, cDataP) < 0) { (*sMlibSysFns.deleteImageFP)(*mlibImagePP); return -1; } } break; case SHORT_DATA_TYPE: if ((*mlibImagePP = (*sMlibSysFns.createFP)(MLIB_SHORT, rasterP->numBands, width, height)) == NULL) { return -1; } if (isSrc) { sdataP = (unsigned short *) mlib_ImageGetData(*mlibImagePP); if (awt_getPixelShort(env, -1, rasterP, sdataP) < 0) { (*sMlibSysFns.deleteImageFP)(*mlibImagePP); return -1; } } break; default: return -1; } return 0; } static void freeArray(JNIEnv *env, BufImageS_t *srcimageP, mlib_image *srcmlibImP, void *srcdataP, BufImageS_t *dstimageP, mlib_image *dstmlibImP, void *dstdataP) { jobject srcJdata = (srcimageP != NULL ? srcimageP->raster.jdata : NULL); jobject dstJdata = (dstimageP != NULL ? dstimageP->raster.jdata : NULL); freeDataArray(env, srcJdata, srcmlibImP, srcdataP, dstJdata, dstmlibImP, dstdataP); } static void freeDataArray(JNIEnv *env, jobject srcJdata, mlib_image *srcmlibImP, void *srcdataP, jobject dstJdata, mlib_image *dstmlibImP, void *dstdataP) { /* Free the medialib image */ if (srcmlibImP) { (*sMlibSysFns.deleteImageFP)(srcmlibImP); } /* Release the array */ if (srcdataP) { (*env)->ReleasePrimitiveArrayCritical(env, srcJdata, srcdataP, JNI_ABORT); } /* Free the medialib image */ if (dstmlibImP) { (*sMlibSysFns.deleteImageFP)(dstmlibImP); } /* Release the array */ if (dstdataP) { (*env)->ReleasePrimitiveArrayCritical(env, dstJdata, dstdataP, 0); } } static int storeDstArray(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, mlibHintS_t *hintP, mlib_image *mlibImP, void *ddata) { RasterS_t *rasterP = &dstP->raster; /* Nothing to do since it is the same image type */ if (srcP->imageType == dstP->imageType && srcP->imageType != java_awt_image_BufferedImage_TYPE_CUSTOM && srcP->imageType != java_awt_image_BufferedImage_TYPE_BYTE_INDEXED && srcP->imageType != java_awt_image_BufferedImage_TYPE_BYTE_BINARY) { /* REMIND: Should check the ICM LUTS to see if it is the same */ return 0; } /* These types are compatible with TYPE_INT_RGB */ if (srcP->imageType == java_awt_image_BufferedImage_TYPE_INT_RGB && (dstP->imageType == java_awt_image_BufferedImage_TYPE_INT_ARGB || dstP->imageType == java_awt_image_BufferedImage_TYPE_INT_ARGB_PRE)){ return 0; } if (hintP->cvtSrcToDefault && (srcP->cmodel.isAlphaPre == dstP->cmodel.isAlphaPre)) { if (srcP->cmodel.isAlphaPre) { if (dstP->imageType == java_awt_image_BufferedImage_TYPE_INT_ARGB_PRE) { return 0; } if (!srcP->cmodel.supportsAlpha && dstP->imageType == java_awt_image_BufferedImage_TYPE_INT_RGB){ return 0; } } else { /* REMIND: */ } } if (dstP->cmodel.cmType == DIRECT_CM_TYPE) { /* Just need to move bits */ if (mlibImP->type == MLIB_BYTE) { return awt_setPixelByte(env, -1, &dstP->raster, (unsigned char *) mlibImP->data); } else if (mlibImP->type == MLIB_SHORT) { return awt_setPixelByte(env, -1, &dstP->raster, (unsigned char *) mlibImP->data); } } return 0; } #define ERR_BAD_IMAGE_LAYOUT (-2) #define CHECK_DST_ARRAY(start_offset, elements_per_pixel) \ do { \ int offset = (start_offset); \ int lastScanOffset; \ \ if (!SAFE_TO_MULT(rasterP->scanlineStride, \ (rasterP->height - 1))) \ { \ return ERR_BAD_IMAGE_LAYOUT; \ } \ lastScanOffset = rasterP->scanlineStride * \ (rasterP->height - 1); \ \ if (!SAFE_TO_ADD(offset, lastScanOffset)) { \ return ERR_BAD_IMAGE_LAYOUT; \ } \ lastScanOffset += offset; \ \ if (!SAFE_TO_MULT((elements_per_pixel), rasterP->width)) { \ return ERR_BAD_IMAGE_LAYOUT; \ } \ offset = (elements_per_pixel) * rasterP->width; \ \ if (!SAFE_TO_ADD(offset, lastScanOffset)) { \ return ERR_BAD_IMAGE_LAYOUT; \ } \ lastScanOffset += offset; \ \ if (dataArrayLength < lastScanOffset) { \ return ERR_BAD_IMAGE_LAYOUT; \ } \ } while(0); \ static int storeImageArray(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, mlib_image *mlibImP) { int mStride; unsigned char *cmDataP, *dataP, *cDataP; HintS_t *hintP = &dstP->hints; RasterS_t *rasterP = &dstP->raster; jsize dataArrayLength = (*env)->GetArrayLength(env, rasterP->jdata); int y; /* REMIND: Store mlib data type? */ /* Check if it is an IndexColorModel */ if (dstP->cmodel.cmType == INDEX_CM_TYPE) { if (dstP->raster.rasterType == COMPONENT_RASTER_TYPE) { return storeICMarray(env, srcP, dstP, mlibImP); } else { /* Packed or some other custom raster */ cmDataP = (unsigned char *) mlib_ImageGetData(mlibImP); return cvtDefaultToCustom(env, dstP, -1, cmDataP); } } if (hintP->packing == BYTE_INTERLEAVED) { /* Write it back to the destination */ CHECK_DST_ARRAY(hintP->channelOffset, hintP->numChans); cmDataP = (unsigned char *) mlib_ImageGetData(mlibImP); mStride = mlib_ImageGetStride(mlibImP); dataP = (unsigned char *)(*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) return 0; cDataP = dataP + hintP->channelOffset; for (y=0; y < rasterP->height; y++, cmDataP += mStride, cDataP += rasterP->scanlineStride) { memcpy(cDataP, cmDataP, rasterP->width*hintP->numChans); } (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); } else if (hintP->packing == SHORT_INTERLEAVED) { /* Write it back to the destination */ unsigned short *sdataP, *sDataP; unsigned short *smDataP = (unsigned short *)mlib_ImageGetData(mlibImP); CHECK_DST_ARRAY(hintP->channelOffset, hintP->numChans); mStride = mlib_ImageGetStride(mlibImP); sdataP = (unsigned short *)(*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (sdataP == NULL) return -1; sDataP = sdataP + hintP->channelOffset; for (y=0; y < rasterP->height; y++, smDataP += mStride, sDataP += rasterP->scanlineStride) { memcpy(sDataP, smDataP, rasterP->width*hintP->numChans); } (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, sdataP, JNI_ABORT); } else if (dstP->cmodel.cmType == DIRECT_CM_TYPE) { /* Just need to move bits */ if (mlibImP->type == MLIB_BYTE) { if (dstP->hints.packing == PACKED_BYTE_INTER) { return setPackedBCRdefault(env, rasterP, -1, (unsigned char *) mlibImP->data, dstP->cmodel.supportsAlpha); } else if (dstP->hints.packing == PACKED_SHORT_INTER) { return setPackedSCRdefault(env, rasterP, -1, (unsigned char *) mlibImP->data, dstP->cmodel.supportsAlpha); } else if (dstP->hints.packing == PACKED_INT_INTER) { return setPackedICRdefault(env, rasterP, -1, (unsigned char *) mlibImP->data, dstP->cmodel.supportsAlpha); } } else if (mlibImP->type == MLIB_SHORT) { return awt_setPixelShort(env, -1, rasterP, (unsigned short *) mlibImP->data); } } else { return cvtDefaultToCustom(env, dstP, -1, (unsigned char *)mlibImP->data); } return 0; } static int storeRasterArray(JNIEnv *env, RasterS_t *srcP, RasterS_t *dstP, mlib_image *mlibImP) { unsigned char *cDataP; switch(dstP->type) { case sun_awt_image_IntegerComponentRaster_TYPE_BYTE_PACKED_SAMPLES: cDataP = (unsigned char *) mlib_ImageGetData(mlibImP); return setPackedBCR(env, dstP, -1, cDataP); case sun_awt_image_IntegerComponentRaster_TYPE_USHORT_PACKED_SAMPLES: if (dstP->sppsm.maxBitSize <= 8) { cDataP = (unsigned char *) mlib_ImageGetData(mlibImP); return setPackedSCR(env, dstP, -1, cDataP); } break; case sun_awt_image_IntegerComponentRaster_TYPE_INT_PACKED_SAMPLES: if (dstP->sppsm.maxBitSize <= 8) { cDataP = (unsigned char *) mlib_ImageGetData(mlibImP); return setPackedICR(env, dstP, -1, cDataP); } } return -1; } static int storeICMarray(JNIEnv *env, BufImageS_t *srcP, BufImageS_t *dstP, mlib_image *mlibImP) { int *argb; int x, y; unsigned char *dataP, *cDataP, *cP; unsigned char *sP; int aIdx, rIdx, gIdx, bIdx; ColorModelS_t *cmodelP = &dstP->cmodel; RasterS_t *rasterP = &dstP->raster; /* REMIND: Only works for RGB */ if (cmodelP->csType != java_awt_color_ColorSpace_TYPE_RGB) { JNU_ThrowInternalError(env, "Writing to non-RGB images not implemented yet"); return -1; } if (srcP->imageType == java_awt_image_BufferedImage_TYPE_INT_ARGB || srcP->imageType == java_awt_image_BufferedImage_TYPE_INT_ARGB_PRE || srcP->imageType == java_awt_image_BufferedImage_TYPE_INT_RGB) { aIdx = 0; rIdx = 1; gIdx = 2; bIdx = 3; } else if (srcP->imageType ==java_awt_image_BufferedImage_TYPE_4BYTE_ABGR|| srcP->imageType == java_awt_image_BufferedImage_TYPE_4BYTE_ABGR_PRE) { aIdx = 0; rIdx = 3; gIdx = 2; bIdx = 1; } else if (srcP->imageType == java_awt_image_BufferedImage_TYPE_3BYTE_BGR){ rIdx = 2; gIdx = 1; bIdx = 0; aIdx = 0; /* Ignored */ } else if (srcP->cmodel.cmType == INDEX_CM_TYPE) { rIdx = 0; gIdx = 1; bIdx = 2; aIdx = 3; /* Use supportsAlpha to see if it is really there */ } else { return -1; } /* Lock down the destination raster */ dataP = (unsigned char *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (dataP == NULL) { return -1; } argb = (*env)->GetPrimitiveArrayCritical(env, cmodelP->jrgb, NULL); if (argb == NULL) { (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); return -1; } cDataP = dataP + dstP->hints.dataOffset; sP = (unsigned char *) mlib_ImageGetData(mlibImP); for (y=0; y < rasterP->height; y++, cDataP += rasterP->scanlineStride) { cP = cDataP; for (x=0; x < rasterP->width; x++, cP += rasterP->pixelStride) { *cP = colorMatch(sP[rIdx], sP[gIdx], sP[bIdx], sP[aIdx], (unsigned char *)argb, cmodelP->mapSize); sP += cmodelP->numComponents; } } (*env)->ReleasePrimitiveArrayCritical(env, cmodelP->jrgb, argb, JNI_ABORT); (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); return -1; } static int expandICM(JNIEnv *env, BufImageS_t *imageP, unsigned int *mDataP) { ColorModelS_t *cmP = &imageP->cmodel; RasterS_t *rasterP = &imageP->raster; HintS_t *hintP = &imageP->hints; int *rgb; int status = 0; unsigned char *dataP, *cP; unsigned int *mP; int width = rasterP->width; int height = rasterP->height; int x, y; /* Need to grab the lookup tables. Right now only bytes */ rgb = (int *) (*env)->GetPrimitiveArrayCritical(env, cmP->jrgb, NULL); /* Interleaved with shared data */ dataP = (void *) (*env)->GetPrimitiveArrayCritical(env, rasterP->jdata, NULL); if (rgb == NULL || dataP == NULL) { /* Release the lookup tables */ if (rgb) { (*env)->ReleasePrimitiveArrayCritical(env, cmP->jrgb, rgb, JNI_ABORT); } if (dataP) { (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); } return -1; } if (rasterP->dataType == BYTE_DATA_TYPE) { unsigned char *cDataP = ((unsigned char *)dataP) + hintP->dataOffset; for (y=0; y < height; y++) { mP = mDataP; cP = cDataP; for (x=0; x < width; x++, cP += rasterP->pixelStride) { *mP++ = rgb[*cP]; } mDataP += width; cDataP += rasterP->scanlineStride; } } else if (rasterP->dataType == SHORT_DATA_TYPE) { unsigned short *sDataP, *sP; sDataP = ((unsigned short *)dataP) + hintP->channelOffset; for (y=0; y < height; y++) { mP = mDataP; sP = sDataP; for (x=0; x < width; x++, sP+=rasterP->pixelStride) { *mP++ = rgb[*sP]; } mDataP += width; sDataP += rasterP->scanlineStride; } } else { /* Unknown type */ status = -1; } /* Release the lookup table data */ (*env)->ReleasePrimitiveArrayCritical(env, imageP->cmodel.jrgb, rgb, JNI_ABORT); /* Release the data array */ (*env)->ReleasePrimitiveArrayCritical(env, rasterP->jdata, dataP, JNI_ABORT); return status; } /* This routine is expecting a ByteComponentRaster with a PackedColorModel */ static int expandPackedBCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP) { int x, y, c; unsigned char *outP = outDataP; unsigned char *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_BCRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned char *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Convert the all bands */ if (rasterP->numBands < 4) { /* Need to put in alpha */ for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) ((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]; inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a ByteComponentRaster with a PackedColorModel */ static int expandPackedBCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha) { int x, y, c; unsigned char *outP = outDataP; unsigned char *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int numBands = rasterP->numBands - (forceAlpha ? 0 : 1); int a = numBands; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_BCRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned char *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Need to put in alpha */ if (forceAlpha) { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = 0xff; for (c=0; c < numBands; c++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[a]) >> roff[a]) <<loff[a]); for (c=0; c < numBands; c++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) ((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]; inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a ShortComponentRaster with a PackedColorModel */ static int expandPackedSCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP) { int x, y, c; unsigned char *outP = outDataP; unsigned short *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_SCRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned short *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Convert the all bands */ if (rasterP->numBands < 4) { /* Need to put in alpha */ for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { /* *Not correct. Might need to unpremult, * shift, etc */ *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { /* *Not correct. Might need to unpremult, * shift, etc */ *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) ((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]; inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a ShortComponentRaster with a PackedColorModel */ static int expandPackedSCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha) { int x, y, c; unsigned char *outP = outDataP; unsigned short *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int numBands = rasterP->numBands - (forceAlpha ? 0 : 1); int a = numBands; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_SCRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned short *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Need to put in alpha */ if (forceAlpha) { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = 0xff; for (c=0; c < numBands; c++) { /* * Not correct. Might need to unpremult, * shift, etc */ *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[a]) >> roff[a]) <<loff[a]); for (c=0; c < numBands; c++) { /* * Not correct. Might need to * unpremult, shift, etc */ *outP++ = (unsigned char) (((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char) ((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]; inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a IntegerComponentRaster with a PackedColorModel*/ static int expandPackedICR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP) { int x, y, c; unsigned char *outP = outDataP; unsigned int *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_ICRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned int *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Convert the all bands */ if (rasterP->numBands < 4) { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { /* * Not correct. Might need to unpremult, * shift, etc */ *outP++ = (unsigned char)(((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++) { /* * Not correct. Might need to * unpremult, shift, etc */ *outP++ = (unsigned char)(((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char)(((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]); inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a IntegerComponentRaster with a PackedColorModel*/ static int expandPackedICRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *outDataP, int forceAlpha) { int x, y, c; unsigned char *outP = outDataP; unsigned int *lineInP, *inP; jarray jInDataP; jint *inDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int numBands = rasterP->numBands - (forceAlpha ? 0 : 1); int a = numBands; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jInDataP = (*env)->GetObjectField(env, rasterP->jraster, g_ICRdataID); inDataP = (*env)->GetPrimitiveArrayCritical(env, jInDataP, 0); if (inDataP == NULL) { return -1; } lineInP = (unsigned int *)inDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { roff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[c] < 0) { loff[c] = -roff[c]; roff[c] = 0; } else loff[c] = 0; } /* Need to put in alpha */ if (forceAlpha) { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = 0xff; for (c=0; c < numBands; c++) { /* * Not correct. Might need to unpremult, * shift, etc */ *outP++ = (unsigned char)(((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char)(((*inP&rasterP->sppsm.maskArray[a]) >> roff[a]) <<loff[a]); for (c=0; c < numBands; c++) { /* * Not correct. Might need to * unpremult, shift, etc */ *outP++ = (unsigned char)(((*inP&rasterP->sppsm.maskArray[c]) >> roff[c]) <<loff[c]); } inP++; } lineInP += rasterP->scanlineStride; } } } else { c = component; roff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (roff[0] < 0) { loff[0] = -roff[0]; roff[0] = 0; } else loff[c] = 0; for (y=0; y < rasterP->height; y++) { inP = lineInP; for (x=0; x < rasterP->width; x++) { *outP++ = (unsigned char)(((*inP & rasterP->sppsm.maskArray[c])>>roff[0])<<loff[0]); inP++; } lineInP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jInDataP, inDataP, JNI_ABORT); return 0; } /* This routine is expecting a ByteComponentRaster with a PackedColorModel */ static int setPackedBCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP) { int x, y, c; unsigned char *inP = inDataP; unsigned char *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned char *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_BCRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ for (y=0; y < rasterP->height; y++) { outP = lineOutP; *outP = 0; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++, inP++) { *outP |= (*inP<<loff[c]>>roff[c])&rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This routine is expecting a ShortComponentRaster with a PackedColorModel */ static int setPackedSCR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP) { int x, y, c; unsigned char *inP = inDataP; unsigned short *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned short *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_SCRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])&rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This routine is expecting a IntegerComponentRaster with a PackedColorModel*/ static int setPackedICR(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP) { int x, y, c; unsigned char *inP = inDataP; unsigned int *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned int *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_ICRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { for (c=0; c < rasterP->numBands; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])&rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This routine is expecting a ByteComponentRaster with a PackedColorModel */ static int setPackedBCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP, int supportsAlpha) { int x, y, c; unsigned char *inP = inDataP; unsigned char *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned char *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int a = rasterP->numBands - 1; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_BCRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ if (supportsAlpha) { for (y=0; y < rasterP->height; y++) { outP = lineOutP; *outP = 0; for (x=0; x < rasterP->width; x++) { *outP |= (*inP<<loff[a]>>roff[a])& rasterP->sppsm.maskArray[a]; inP++; for (c=0; c < rasterP->numBands-1; c++, inP++) { *outP |= (*inP<<loff[c]>>roff[c])& rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { outP = lineOutP; *outP = 0; for (x=0; x < rasterP->width; x++) { inP++; for (c=0; c < rasterP->numBands; c++, inP++) { *outP |= (*inP<<loff[c]>>roff[c])&rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This routine is expecting a ShortComponentRaster with a PackedColorModel */ static int setPackedSCRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP, int supportsAlpha) { int x, y, c; unsigned char *inP = inDataP; unsigned short *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned short *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int a = rasterP->numBands - 1; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_SCRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ if (supportsAlpha) { for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { *outP |= (*inP<<loff[a]>>roff[a])& rasterP->sppsm.maskArray[a]; inP++; for (c=0; c < rasterP->numBands-1; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])& rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { inP++; for (c=0; c < rasterP->numBands; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])&rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This routine is expecting a IntegerComponentRaster with a PackedColorModel*/ static int setPackedICRdefault(JNIEnv *env, RasterS_t *rasterP, int component, unsigned char *inDataP, int supportsAlpha) { int x, y, c; unsigned char *inP = inDataP; unsigned int *lineOutP, *outP; jarray jOutDataP; jsize dataArrayLength; unsigned int *outDataP; int loff[MAX_NUMBANDS], roff[MAX_NUMBANDS]; int a = rasterP->numBands - 1; if (rasterP->numBands > MAX_NUMBANDS) { return -1; } /* Grab data ptr, strides, offsets from raster */ jOutDataP = (*env)->GetObjectField(env, rasterP->jraster, g_ICRdataID); if (JNU_IsNull(env, jOutDataP)) { return -1; } dataArrayLength = (*env)->GetArrayLength(env, jOutDataP); CHECK_DST_ARRAY(rasterP->chanOffsets[0], 1); outDataP = (*env)->GetPrimitiveArrayCritical(env, jOutDataP, 0); if (outDataP == NULL) { return -1; } lineOutP = outDataP + rasterP->chanOffsets[0]; if (component < 0) { for (c=0; c < rasterP->numBands; c++) { loff[c] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[c] < 0) { roff[c] = -loff[c]; loff[c] = 0; } else roff[c] = 0; } /* Convert the all bands */ if (supportsAlpha) { for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { *outP |= (*inP<<loff[a]>>roff[a])& rasterP->sppsm.maskArray[a]; inP++; for (c=0; c < rasterP->numBands-1; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])& rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } else { for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++) { inP++; for (c=0; c < rasterP->numBands; c++, inP++) { /* Not correct. Might need to unpremult, shift, etc */ *outP |= (*inP<<loff[c]>>roff[c])& rasterP->sppsm.maskArray[c]; } outP++; } lineOutP += rasterP->scanlineStride; } } } else { c = component; loff[0] = rasterP->sppsm.offsets[c] + (rasterP->sppsm.nBits[c]-8); if (loff[0] < 0) { roff[0] = -loff[0]; loff[0] = 0; } else roff[c] = 0; for (y=0; y < rasterP->height; y++) { outP = lineOutP; for (x=0; x < rasterP->width; x++, inP++) { *outP |= (*inP<<loff[0]>>roff[0])&rasterP->sppsm.maskArray[c]; outP++; } lineOutP += rasterP->scanlineStride; } } (*env)->ReleasePrimitiveArrayCritical(env, jOutDataP, outDataP, JNI_ABORT); return 0; } /* This is temporary code. Should go away when there is better color * conversion code available. * REMIND: Ignoring alpha */ /* returns the absolute value x */ #define ABS(x) ((x) < 0 ? -(x) : (x)) #define CLIP(val,min,max) ((val < min) ? min : ((val > max) ? max : val)) static int colorMatch(int r, int g, int b, int a, unsigned char *argb, int numColors) { int besti = 0; int mindist, i, t, d; unsigned char red, green, blue; r = CLIP(r, 0, 255); g = CLIP(g, 0, 255); b = CLIP(b, 0, 255); /* look for pure gray match */ if ((r == g) && (g == b)) { mindist = 256; for (i = 0 ; i < numColors ; i++, argb+=4) { red = argb[1]; green = argb[2]; blue = argb[3]; if (! ((red == green) && (green == blue)) ) { continue; } d = ABS(red - r); if (d == 0) return i; if (d < mindist) { besti = i; mindist = d; } } return besti; } /* look for non-pure gray match */ mindist = 256 * 256 * 256; for (i = 0 ; i < numColors ; i++, argb+=4) { red = argb[1]; green = argb[2]; blue = argb[3]; t = red - r; d = t * t; if (d >= mindist) { continue; } t = green - g; d += t * t; if (d >= mindist) { continue; } t = blue - b; d += t * t; if (d >= mindist) { continue; } if (d == 0) return i; if (d < mindist) { besti = i; mindist = d; } } return besti; }