/* Copyright 2013-2014 Pierre Ossman for Cendio AB * * This is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This software 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 for more details. * * You should have received a copy of the GNU General Public License * along with this software; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, * USA. */ #include #include #include #include static const rdr::U8 pixelRed = 0xf1; static const rdr::U8 pixelGreen = 0xc3; static const rdr::U8 pixelBlue = 0x97; static const int fbWidth = 40; static const int fbHeight = 30; static const int fbArea = fbWidth * fbHeight; // Maximum bpp, plus some room for unaligned fudging static const int fbMalloc = (fbArea * 4) + 4; typedef bool (*testfn) (const rfb::PixelFormat&, const rfb::PixelFormat&); struct TestEntry { const char *label; testfn fn; }; #define min(a,b) (((a) < (b)) ? (a) : (b)) namespace rfb { void makePixel(const rfb::PixelFormat &pf, rdr::U8 *buffer) { rfb::Pixel p; p = 0; p |= (pixelRed >> (8 - pf.redBits)) << pf.redShift; p |= (pixelGreen >> (8 - pf.greenBits)) << pf.greenShift; p |= (pixelBlue >> (8 - pf.blueBits)) << pf.blueShift; // FIXME: Should we reimplement this as well? pf.bufferFromPixel(buffer, p); } bool verifyPixel(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf, const rdr::U8 *buffer) { rfb::Pixel p; int r, g, b; int re, ge, be; // FIXME: Should we reimplement this as well? p = dstpf.pixelFromBuffer(buffer); r = (p >> dstpf.redShift) & dstpf.redMax; g = (p >> dstpf.greenShift) & dstpf.greenMax; b = (p >> dstpf.blueShift) & dstpf.blueMax; r <<= 8 - dstpf.redBits; g <<= 8 - dstpf.greenBits; b <<= 8 - dstpf.blueBits; // The allowed error depends on: // // a) The number of bits the format can hold // b) The number of bits the source format could hold re = (1 << (8 - min(dstpf.redBits, srcpf.redBits))) - 1; ge = (1 << (8 - min(dstpf.greenBits, srcpf.greenBits))) - 1; be = (1 << (8 - min(dstpf.blueBits, srcpf.blueBits))) - 1; if (abs(r - pixelRed) > re) return false; if (abs(g - pixelGreen) > ge) return false; if (abs(b - pixelBlue) > be) return false; return true; } } using rfb::makePixel; using rfb::verifyPixel; static bool testPixel(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf) { rfb::Pixel p; rdr::U8 buffer[4]; makePixel(srcpf, buffer); p = srcpf.pixelFromBuffer(buffer); p = dstpf.pixelFromPixel(srcpf, p); memset(buffer, 0, sizeof(buffer)); dstpf.bufferFromPixel(buffer, p); if (!verifyPixel(dstpf, srcpf, buffer)) return false; return true; } static bool testBuffer(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf) { int i, x, y, unaligned; rdr::U8 bufIn[fbMalloc], bufOut[fbMalloc]; // Once aligned, and once unaligned for (unaligned = 0;unaligned < 2;unaligned++) { for (i = 0;i < fbArea;i++) makePixel(srcpf, bufIn + unaligned + i*srcpf.bpp/8); memset(bufOut, 0, sizeof(bufOut)); dstpf.bufferFromBuffer(bufOut + unaligned, srcpf, bufIn + unaligned, fbArea); for (i = 0;i < fbArea;i++) { if (!verifyPixel(dstpf, srcpf, bufOut + unaligned + i*dstpf.bpp/8)) return false; } memset(bufIn, 0, sizeof(bufIn)); for (y = 0;y < fbHeight;y++) { for (x = 0;x < fbWidth/2;x++) makePixel(srcpf, bufIn + unaligned + (x + y*fbWidth)*srcpf.bpp/8); } memset(bufOut, 0, sizeof(bufOut)); dstpf.bufferFromBuffer(bufOut + unaligned, srcpf, bufIn + unaligned, fbWidth/2, fbHeight, fbWidth, fbWidth); for (y = 0;y < fbHeight;y++) { for (x = 0;x < fbWidth;x++) { if (x < fbWidth/2) { if (!verifyPixel(dstpf, srcpf, bufOut + unaligned + (x + y*fbWidth)*dstpf.bpp/8)) return false; } else { const rdr::U8 zero[4] = { 0, 0, 0, 0 }; if (memcmp(bufOut + unaligned + (x + y*fbWidth)*dstpf.bpp/8, zero, dstpf.bpp/8) != 0) return false; } } } } return true; } static bool testRGB(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf) { int i, x, y, unaligned; rdr::U8 bufIn[fbMalloc], bufRGB[fbMalloc], bufOut[fbMalloc]; // Once aligned, and once unaligned for (unaligned = 0;unaligned < 2;unaligned++) { for (i = 0;i < fbArea;i++) makePixel(srcpf, bufIn + unaligned + i*srcpf.bpp/8); memset(bufRGB, 0, sizeof(bufRGB)); srcpf.rgbFromBuffer(bufRGB + unaligned, bufIn + unaligned, fbArea); memset(bufOut, 0, sizeof(bufOut)); dstpf.bufferFromRGB(bufOut + unaligned, bufRGB + unaligned, fbArea); for (i = 0;i < fbArea;i++) { if (!verifyPixel(dstpf, srcpf, bufOut + unaligned + i*dstpf.bpp/8)) return false; } memset(bufIn, 0, sizeof(bufIn)); for (y = 0;y < fbHeight;y++) { for (x = 0;x < fbWidth/2;x++) makePixel(srcpf, bufIn + unaligned + (x + y*fbWidth)*srcpf.bpp/8); } memset(bufRGB, 0, sizeof(bufRGB)); srcpf.rgbFromBuffer(bufRGB + unaligned, bufIn + unaligned, fbWidth/2, fbWidth, fbHeight); memset(bufOut, 0, sizeof(bufOut)); dstpf.bufferFromRGB(bufOut + unaligned, bufRGB + unaligned, fbWidth/2, fbWidth, fbHeight); for (y = 0;y < fbHeight;y++) { for (x = 0;x < fbWidth;x++) { if (x < fbWidth/2) { if (!verifyPixel(dstpf, srcpf, bufOut + unaligned + (x + y*fbWidth)*dstpf.bpp/8)) return false; } else { const rdr::U8 zero[4] = { 0, 0, 0, 0 }; if (memcmp(bufOut + unaligned + (x + y*fbWidth)*dstpf.bpp/8, zero, dstpf.bpp/8) != 0) return false; } } } } return true; } static bool testPixelRGB(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf) { rfb::Pixel p; rdr::U16 r16, g16, b16; rdr::U8 r8, g8, b8; rdr::U8 buffer[4]; makePixel(srcpf, buffer); p = srcpf.pixelFromBuffer(buffer); srcpf.rgbFromPixel(p, &r16, &g16, &b16); p = dstpf.pixelFromRGB(r16, g16, b16); memset(buffer, 0, sizeof(buffer)); dstpf.bufferFromPixel(buffer, p); if (!verifyPixel(dstpf, srcpf, buffer)) return false; makePixel(srcpf, buffer); p = srcpf.pixelFromBuffer(buffer); srcpf.rgbFromPixel(p, &r8, &g8, &b8); p = dstpf.pixelFromRGB(r8, g8, b8); memset(buffer, 0, sizeof(buffer)); dstpf.bufferFromPixel(buffer, p); if (!verifyPixel(dstpf, srcpf, buffer)) return false; return true; } struct TestEntry tests[] = { {"Pixel from pixel", testPixel}, {"Buffer from buffer", testBuffer}, {"Buffer to/from RGB", testRGB}, {"Pixel to/from RGB", testPixelRGB}, }; static void doTests(const rfb::PixelFormat &dstpf, const rfb::PixelFormat &srcpf) { int i; char dstb[256], srcb[256]; dstpf.print(dstb, sizeof(dstb)); srcpf.print(srcb, sizeof(srcb)); printf("\n"); printf("%s to %s\n", srcb, dstb); printf("\n"); for (i = 0;i < sizeof(tests)/sizeof(tests[0]);i++) { printf(" %s: ", tests[i].label); fflush(stdout); if (tests[i].fn(dstpf, srcpf)) printf("OK"); else printf("FAILED"); printf("\n"); } } int main(int argc, char **argv) { rfb::PixelFormat dstpf, srcpf; printf("Pixel Conversion Correctness Test\n"); /* rgb888 targets */ dstpf.parse("rgb888"); srcpf.parse("rgb888"); doTests(dstpf, srcpf); srcpf.parse("bgr888"); doTests(dstpf, srcpf); srcpf.parse("rgb565"); doTests(dstpf, srcpf); srcpf.parse("rgb232"); doTests(dstpf, srcpf); /* rgb565 targets */ dstpf.parse("rgb565"); srcpf.parse("rgb888"); doTests(dstpf, srcpf); srcpf.parse("bgr565"); doTests(dstpf, srcpf); srcpf.parse("rgb232"); doTests(dstpf, srcpf); /* rgb232 targets */ dstpf.parse("rgb232"); srcpf.parse("rgb888"); doTests(dstpf, srcpf); srcpf.parse("rgb565"); doTests(dstpf, srcpf); srcpf.parse("bgr232"); doTests(dstpf, srcpf); /* endian conversion (both ways) */ dstpf = rfb::PixelFormat(32, 24, false, true, 255, 255, 255, 0, 8, 16); srcpf = rfb::PixelFormat(32, 24, true, true, 255, 255, 255, 0, 8, 16); doTests(dstpf, srcpf); doTests(srcpf, dstpf); dstpf = rfb::PixelFormat(16, 16, false, true, 31, 63, 31, 0, 5, 11); srcpf = rfb::PixelFormat(16, 16, true, true, 31, 63, 31, 0, 5, 11); doTests(dstpf, srcpf); doTests(srcpf, dstpf); // Pesky case that is very asymetrical dstpf = rfb::PixelFormat(32, 24, false, true, 255, 255, 255, 0, 8, 16); srcpf = rfb::PixelFormat(32, 24, true, true, 255, 255, 255, 0, 24, 8); doTests(dstpf, srcpf); doTests(srcpf, dstpf); }