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Java example source code file (vis_ByteGray.c)
The vis_ByteGray.c Java example source code/* * Copyright (c) 2003, 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. */ #if !defined(JAVA2D_NO_MLIB) || defined(MLIB_ADD_SUFF) #include <vis_proto.h> #include "java2d_Mlib.h" #include "vis_AlphaMacros.h" /***************************************************************/ #define RGB2GRAY(r, g, b) \ (((77 * (r)) + (150 * (g)) + (29 * (b)) + 128) >> 8) /***************************************************************/ #define Gray2Argb(x) \ 0xff000000 | (x << 16) | (x << 8) | x /***************************************************************/ #define LUT(x) \ ((mlib_u8*)LutU8)[4 * (x)] #define LUT12(x) \ ((mlib_u8*)LutU8)[4 * ((x) & 0xfff)] /***************************************************************/ void ADD_SUFF(UshortGrayToByteGrayConvert)(BLIT_PARAMS) { mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_u8 *dst_end; mlib_d64 s0, s1, ss; mlib_s32 i, j; if (width <= 8) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { dst[i] = src[2*i]; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (srcScan == 2*width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_d64 *sp; dst_end = dst + width; while (((mlib_s32)dst & 3) && dst < dst_end) { *dst++ = *src; src += 2; } if ((mlib_s32)src & 7) { sp = vis_alignaddr(src, 0); s1 = *sp++; #pragma pipeloop(0) for (; dst <= (dst_end - 4); dst += 4) { s0 = s1; s1 = *sp++; ss = vis_faligndata(s0, s1); ss = vis_fpmerge(vis_read_hi(ss), vis_read_lo(ss)); ss = vis_fpmerge(vis_read_hi(ss), vis_read_lo(ss)); *(mlib_f32*)dst = vis_read_hi(ss); src += 2*4; } } else { #pragma pipeloop(0) for (; dst <= (dst_end - 4); dst += 4) { ss = *(mlib_d64*)src; ss = vis_fpmerge(vis_read_hi(ss), vis_read_lo(ss)); ss = vis_fpmerge(vis_read_hi(ss), vis_read_lo(ss)); *(mlib_f32*)dst = vis_read_hi(ss); src += 2*4; } } while (dst < dst_end) { *dst++ = *src; src += 2; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(ByteGrayToIntArgbConvert)(BLIT_PARAMS) { mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_d64 d0, d1, d2, d3; mlib_f32 ff, aa = vis_fones(); mlib_s32 i, j, x; if (width < 8) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_s32 *dst = dstBase; for (i = 0; i < width; i++) { x = src[i]; dst[i] = Gray2Argb(x); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (srcScan == width && dstScan == 4*width) { width *= height; height = 1; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_s32 *dst = dstBase; mlib_s32 *dst_end; dst_end = dst + width; while (((mlib_s32)src & 3) && dst < dst_end) { x = *src++; *dst++ = Gray2Argb(x); } #pragma pipeloop(0) for (; dst <= (dst_end - 4); dst += 4) { ff = *(mlib_f32*)src; d0 = vis_fpmerge(aa, ff); d1 = vis_fpmerge(ff, ff); d2 = vis_fpmerge(vis_read_hi(d0), vis_read_hi(d1)); d3 = vis_fpmerge(vis_read_lo(d0), vis_read_lo(d1)); ((mlib_f32*)dst)[0] = vis_read_hi(d2); ((mlib_f32*)dst)[1] = vis_read_lo(d2); ((mlib_f32*)dst)[2] = vis_read_hi(d3); ((mlib_f32*)dst)[3] = vis_read_lo(d3); src += 4; } while (dst < dst_end) { x = *src++; *dst++ = Gray2Argb(x); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(ByteGrayToIntArgbScaleConvert)(SCALE_PARAMS) { mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_d64 d0, d1, d2, d3, dd; mlib_f32 ff, aa = vis_fones(); mlib_s32 i, j, x; if (width < 16) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_s32 *dst = dstBase; mlib_s32 tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); for (i = 0; i < width; i++) { x = src[tmpsxloc >> shift]; tmpsxloc += sxinc; dst[i] = Gray2Argb(x); } PTR_ADD(dstBase, dstScan); syloc += syinc; } return; } vis_alignaddr(NULL, 7); for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_s32 *dst = dstBase; mlib_s32 *dst_end; mlib_s32 tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); dst_end = dst + width; #pragma pipeloop(0) for (; dst <= (dst_end - 4); dst += 4) { LOAD_NEXT_U8(dd, src + ((tmpsxloc + 3*sxinc) >> shift)); LOAD_NEXT_U8(dd, src + ((tmpsxloc + 2*sxinc) >> shift)); LOAD_NEXT_U8(dd, src + ((tmpsxloc + sxinc) >> shift)); LOAD_NEXT_U8(dd, src + ((tmpsxloc ) >> shift)); tmpsxloc += 4*sxinc; ff = vis_read_hi(dd); d0 = vis_fpmerge(aa, ff); d1 = vis_fpmerge(ff, ff); d2 = vis_fpmerge(vis_read_hi(d0), vis_read_hi(d1)); d3 = vis_fpmerge(vis_read_lo(d0), vis_read_lo(d1)); ((mlib_f32*)dst)[0] = vis_read_hi(d2); ((mlib_f32*)dst)[1] = vis_read_lo(d2); ((mlib_f32*)dst)[2] = vis_read_hi(d3); ((mlib_f32*)dst)[3] = vis_read_lo(d3); } while (dst < dst_end) { x = src[tmpsxloc >> shift]; tmpsxloc += sxinc; *dst++ = Gray2Argb(x); } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ #if 1 #ifdef MLIB_ADD_SUFF #pragma weak ByteGrayToIntArgbPreConvert_F = ByteGrayToIntArgbConvert_F #else #pragma weak ByteGrayToIntArgbPreConvert = ByteGrayToIntArgbConvert #endif #ifdef MLIB_ADD_SUFF #pragma weak ByteGrayToIntArgbPreScaleConvert_F = \ ByteGrayToIntArgbScaleConvert_F #else #pragma weak ByteGrayToIntArgbPreScaleConvert = \ ByteGrayToIntArgbScaleConvert #endif #else void ADD_SUFF(ByteGrayToIntArgbPreConvert)(BLIT_PARAMS) { ADD_SUFF(ByteGrayToIntArgbConvert)(BLIT_CALL_PARAMS); } void ADD_SUFF(ByteGrayToIntArgbPreScaleConvert)(SCALE_PARAMS) { ADD_SUFF(ByteGrayToIntArgbScaleConvert)(SCALE_CALL_PARAMS); } #endif /***************************************************************/ void ADD_SUFF(UshortGrayToByteGrayScaleConvert)(SCALE_PARAMS) { mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 i, j, w, tmpsxloc; for (j = 0; j < height; j++) { mlib_u8 *pSrc = srcBase; mlib_u8 *pDst = dstBase; tmpsxloc = sxloc; w = width; PTR_ADD(pSrc, (syloc >> shift) * srcScan); if ((mlib_s32)pDst & 1) { *pDst++ = pSrc[2*(tmpsxloc >> shift)]; tmpsxloc += sxinc; w--; } #pragma pipeloop(0) for (i = 0; i <= (w - 2); i += 2) { mlib_s32 x0, x1; x0 = pSrc[2*(tmpsxloc >> shift)]; x1 = pSrc[2*((tmpsxloc + sxinc) >> shift)]; *(mlib_u16*)pDst = (x0 << 8) | x1; pDst += 2; tmpsxloc += 2*sxinc; } if (i < w) { *pDst = pSrc[2*(tmpsxloc >> shift)]; } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ void ADD_SUFF(Index8GrayToByteGrayConvert)(BLIT_PARAMS) { jint *SrcReadLut = pSrcInfo->lutBase; mlib_u8 *LutU8 = (mlib_u8*)SrcReadLut + 3; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { Index8GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { dst[i] = LUT(src[i]); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (srcScan == width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { Index8GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; if ((mlib_s32)dst & 1) { *dst++ = LUT(*src); src++; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LUT(src[0]) << 8) | LUT(src[1]); src += 2; } if (dst < dst_end) { *dst++ = LUT(*src); src++; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(Index12GrayToByteGrayConvert)(BLIT_PARAMS) { jint *SrcReadLut = pSrcInfo->lutBase; mlib_u8 *LutU8 = (mlib_u8*)SrcReadLut + 3; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { Index12GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { dst[i] = LUT12(src[i]); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (srcScan == 2*width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { Index12GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; if ((mlib_s32)dst & 1) { *dst++ = LUT12(*src); src++; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LUT12(src[0]) << 8) | LUT12(src[1]); src += 2; } if (dst < dst_end) { *dst++ = LUT12(*src); src++; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(Index8GrayToByteGrayScaleConvert)(SCALE_PARAMS) { jint *SrcReadLut = pSrcInfo->lutBase; mlib_u8 *LutU8 = (mlib_u8*)SrcReadLut + 3; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { Index8GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); for (i = 0; i < width; i++) { dst[i] = LUT(src[tmpsxloc >> shift]); tmpsxloc += sxinc; } PTR_ADD(dstBase, dstScan); syloc += syinc; } return; } for (j = 0; j < height; j++) { Index8GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); if ((mlib_s32)dst & 1) { *dst++ = LUT(src[tmpsxloc >> shift]); tmpsxloc += sxinc; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LUT(src[tmpsxloc >> shift]) << 8) | LUT(src[(tmpsxloc + sxinc) >> shift]); tmpsxloc += 2*sxinc; } if (dst < dst_end) { *dst = LUT(src[tmpsxloc >> shift]); } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ void ADD_SUFF(Index12GrayToByteGrayScaleConvert)(SCALE_PARAMS) { jint *SrcReadLut = pSrcInfo->lutBase; mlib_u8 *LutU8 = (mlib_u8*)SrcReadLut + 3; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { Index12GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); for (i = 0; i < width; i++) { dst[i] = LUT12(src[tmpsxloc >> shift]); tmpsxloc += sxinc; } PTR_ADD(dstBase, dstScan); syloc += syinc; } return; } for (j = 0; j < height; j++) { Index12GrayDataType *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); if ((mlib_s32)dst & 1) { *dst++ = LUT12(src[tmpsxloc >> shift]); tmpsxloc += sxinc; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LUT12(src[tmpsxloc >> shift]) << 8) | LUT12(src[(tmpsxloc + sxinc) >> shift]); tmpsxloc += 2*sxinc; } if (dst < dst_end) { *dst = LUT12(src[tmpsxloc >> shift]); } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ void ADD_SUFF(ByteIndexedToByteGrayConvert)(BLIT_PARAMS) { jint *srcLut = pSrcInfo->lutBase; juint lutSize = pSrcInfo->lutSize; mlib_u8 LutU8[256]; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { jint argb = srcLut[src[i]]; int r, g, b; b = (argb) & 0xff; g = (argb >> 8) & 0xff; r = (argb >> 16) & 0xff; dst[i] = RGB2GRAY(r, g, b); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (lutSize >= 256) lutSize = 256; ADD_SUFF(IntArgbToByteGrayConvert)(srcLut, LutU8, lutSize, 1, pSrcInfo, pDstInfo, pPrim, pCompInfo); for (i = lutSize; i < 256; i++) { LutU8[i] = 0; } if (srcScan == width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; if ((mlib_s32)dst & 1) { *dst++ = LutU8[*src]; src++; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LutU8[src[0]] << 8) | LutU8[src[1]]; src += 2; } if (dst < dst_end) { *dst++ = LutU8[*src]; src++; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(ByteIndexedToByteGrayScaleConvert)(SCALE_PARAMS) { jint *srcLut = pSrcInfo->lutBase; juint lutSize = pSrcInfo->lutSize; mlib_u8 LutU8[256]; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 8) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); for (i = 0; i < width; i++) { jint argb = srcLut[src[tmpsxloc >> shift]]; int r, g, b; b = (argb) & 0xff; g = (argb >> 8) & 0xff; r = (argb >> 16) & 0xff; dst[i] = RGB2GRAY(r, g, b); tmpsxloc += sxinc; } PTR_ADD(dstBase, dstScan); syloc += syinc; } return; } if (lutSize >= 256) lutSize = 256; ADD_SUFF(IntArgbToByteGrayConvert)(srcLut, LutU8, lutSize, 1, pSrcInfo, pDstInfo, pPrim, pCompInfo); for (i = lutSize; i < 256; i++) { LutU8[i] = 0; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); if ((mlib_s32)dst & 1) { *dst++ = LutU8[src[tmpsxloc >> shift]]; tmpsxloc += sxinc; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LutU8[src[tmpsxloc >> shift]] << 8) | LutU8[src[(tmpsxloc + sxinc) >> shift]]; tmpsxloc += 2*sxinc; } if (dst < dst_end) { *dst = LutU8[src[tmpsxloc >> shift]]; } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ void ADD_SUFF(ByteIndexedBmToByteGrayXparOver)(BLIT_PARAMS) { jint *srcLut = pSrcInfo->lutBase; juint lutSize = pSrcInfo->lutSize; mlib_u8 LutU8[256]; mlib_u32 LutU32[256]; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j, x0, x1, mask, res; if (width < 16) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { mlib_s32 argb = srcLut[src[i]]; if (argb < 0) { int r, g, b; b = (argb) & 0xff; g = (argb >> 8) & 0xff; r = (argb >> 16) & 0xff; dst[i] = RGB2GRAY(r, g, b); } } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (lutSize >= 256) lutSize = 256; ADD_SUFF(IntArgbToByteGrayConvert)(srcLut, LutU8, lutSize, 1, pSrcInfo, pDstInfo, pPrim, pCompInfo); for (i = lutSize; i < 256; i++) { LutU8[i] = 0; } #pragma pipeloop(0) for (i = 0; i < 256; i++) { LutU32[i] = ((srcLut[i] >> 31) & 0xFF0000) | LutU8[i]; } if (srcScan == width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; if ((mlib_s32)dst & 1) { x0 = *src; res = LutU32[x0]; mask = res >> 16; *dst++ = (res & mask) | (*dst &~ mask); src++; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { x0 = src[0]; x1 = src[1]; res = (LutU32[x0] << 8) | LutU32[x1]; mask = res >> 16; ((mlib_u16*)dst)[0] = (res & mask) | (((mlib_u16*)dst)[0] &~ mask); src += 2; } if (dst < dst_end) { x0 = *src; res = LutU32[x0]; mask = res >> 16; *dst = (res & mask) | (*dst &~ mask); } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(ByteIndexedBmToByteGrayXparBgCopy)(BCOPY_PARAMS) { jint *srcLut = pSrcInfo->lutBase; juint lutSize = pSrcInfo->lutSize; mlib_u8 LutU8[256]; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j; if (width < 16) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; for (i = 0; i < width; i++) { mlib_s32 argb = srcLut[src[i]]; if (argb < 0) { int r, g, b; b = (argb) & 0xff; g = (argb >> 8) & 0xff; r = (argb >> 16) & 0xff; dst[i] = RGB2GRAY(r, g, b); } else { dst[i] = bgpixel; } } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } return; } if (lutSize >= 256) lutSize = 256; ADD_SUFF(IntArgbToByteGrayConvert)(srcLut, LutU8, lutSize, 1, pSrcInfo, pDstInfo, pPrim, pCompInfo); for (i = lutSize; i < 256; i++) { LutU8[i] = 0; } #pragma pipeloop(0) for (i = 0; i < 256; i++) { if (srcLut[i] >= 0) LutU8[i] = bgpixel; } if (srcScan == width && dstScan == width) { width *= height; height = 1; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; if ((mlib_s32)dst & 1) { *dst++ = LutU8[*src]; src++; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { ((mlib_u16*)dst)[0] = (LutU8[src[0]] << 8) | LutU8[src[1]]; src += 2; } if (dst < dst_end) { *dst++ = LutU8[*src]; src++; } PTR_ADD(dstBase, dstScan); PTR_ADD(srcBase, srcScan); } } /***************************************************************/ void ADD_SUFF(ByteIndexedBmToByteGrayScaleXparOver)(SCALE_PARAMS) { jint *srcLut = pSrcInfo->lutBase; juint lutSize = pSrcInfo->lutSize; mlib_u8 LutU8[256]; mlib_u32 LutU32[256]; mlib_s32 dstScan = pDstInfo->scanStride; mlib_s32 srcScan = pSrcInfo->scanStride; mlib_s32 i, j, x0, x1, mask, res; if (width < 16) { for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); for (i = 0; i < width; i++) { mlib_s32 argb = srcLut[src[tmpsxloc >> shift]]; if (argb < 0) { int r, g, b; b = (argb) & 0xff; g = (argb >> 8) & 0xff; r = (argb >> 16) & 0xff; dst[i] = RGB2GRAY(r, g, b); } tmpsxloc += sxinc; } PTR_ADD(dstBase, dstScan); syloc += syinc; } return; } if (lutSize >= 256) lutSize = 256; ADD_SUFF(IntArgbToByteGrayConvert)(srcLut, LutU8, lutSize, 1, pSrcInfo, pDstInfo, pPrim, pCompInfo); for (i = lutSize; i < 256; i++) { LutU8[i] = 0; } #pragma pipeloop(0) for (i = 0; i < 256; i++) { LutU32[i] = ((srcLut[i] >> 31) & 0xFF0000) | LutU8[i]; } for (j = 0; j < height; j++) { mlib_u8 *src = srcBase; mlib_u8 *dst = dstBase; mlib_u8 *dst_end = dst + width; jint tmpsxloc = sxloc; PTR_ADD(src, (syloc >> shift) * srcScan); if ((mlib_s32)dst & 1) { x0 = src[tmpsxloc >> shift]; res = LutU32[x0]; mask = res >> 16; *dst++ = (res & mask) | (*dst &~ mask); tmpsxloc += sxinc; } #pragma pipeloop(0) for (; dst <= (dst_end - 2); dst += 2) { x0 = src[tmpsxloc >> shift]; x1 = src[(tmpsxloc + sxinc) >> shift]; res = (LutU32[x0] << 8) | LutU32[x1]; mask = res >> 16; ((mlib_u16*)dst)[0] = (res & mask) | (((mlib_u16*)dst)[0] &~ mask); tmpsxloc += 2*sxinc; } if (dst < dst_end) { x0 = src[tmpsxloc >> shift]; res = LutU32[x0]; mask = res >> 16; *dst = (res & mask) | (*dst &~ mask); } PTR_ADD(dstBase, dstScan); syloc += syinc; } } /***************************************************************/ #endif Other Java examples (source code examples)Here is a short list of links related to this Java vis_ByteGray.c source code file: |
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