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https://github.com/libretro/scummvm.git
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348 lines
12 KiB
C++
348 lines
12 KiB
C++
/* ScummVM - Graphic Adventure Engine
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*
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* ScummVM is the legal property of its developers, whose names
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* are too numerous to list here. Please refer to the COPYRIGHT
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* file distributed with this source distribution.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*
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*/
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#include "cine/cine.h"
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#include "cine/various.h"
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#include "cine/pal.h"
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#include "common/system.h" // For g_system->getPaletteManager()->setPalette
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#include "common/textconsole.h"
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#include "graphics/palette.h"
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namespace Cine {
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static byte paletteBuffer1[16];
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static byte paletteBuffer2[16];
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void loadPal(const char *fileName) {
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char buffer[20];
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removeExtention(buffer, fileName);
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strcat(buffer, ".PAL");
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g_cine->_palArray.clear();
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Common::File palFileHandle;
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if (!palFileHandle.open(buffer))
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error("loadPal(): Cannot open file %s", fileName);
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uint16 palEntriesCount = palFileHandle.readUint16LE();
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palFileHandle.readUint16LE(); // entry size
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g_cine->_palArray.resize(palEntriesCount);
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for (uint i = 0; i < g_cine->_palArray.size(); ++i) {
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palFileHandle.read(g_cine->_palArray[i].name, 10);
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palFileHandle.read(g_cine->_palArray[i].pal1, 16);
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palFileHandle.read(g_cine->_palArray[i].pal2, 16);
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}
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palFileHandle.close();
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}
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int16 findPaletteFromName(const char *fileName) {
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char buffer[10];
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uint16 position = 0;
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uint16 i;
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strcpy(buffer, fileName);
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while (position < strlen(fileName)) {
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if (buffer[position] > 'a' && buffer[position] < 'z') {
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buffer[position] += 'A' - 'a';
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}
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position++;
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}
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for (i = 0; i < g_cine->_palArray.size(); i++) {
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if (!strcmp(buffer, g_cine->_palArray[i].name)) {
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return i;
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}
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}
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return -1;
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}
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void loadRelatedPalette(const char *fileName) {
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char localName[16];
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byte i;
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int16 paletteIndex;
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removeExtention(localName, fileName);
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paletteIndex = findPaletteFromName(localName);
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if (paletteIndex == -1) {
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for (i = 0; i < 16; i++) { // generate default palette
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paletteBuffer1[i] = paletteBuffer2[i] = (i << 4) + i;
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}
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} else {
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assert(paletteIndex < (int32)g_cine->_palArray.size());
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memcpy(paletteBuffer1, g_cine->_palArray[paletteIndex].pal1, 16);
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memcpy(paletteBuffer2, g_cine->_palArray[paletteIndex].pal2, 16);
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}
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}
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namespace {
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/** Is given endian type big endian? (Handles native endian type too, otherwise this would be trivial). */
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bool isBigEndian(const EndianType endian) {
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assert(endian == CINE_NATIVE_ENDIAN || endian == CINE_LITTLE_ENDIAN || endian == CINE_BIG_ENDIAN);
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// Handle explicit little and big endian types here
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if (endian != CINE_NATIVE_ENDIAN) {
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return (endian == CINE_BIG_ENDIAN);
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}
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// Handle native endian type here
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#if defined(SCUMM_BIG_ENDIAN)
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return true;
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#elif defined(SCUMM_LITTLE_ENDIAN)
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return false;
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#else
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#error No endianness defined
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#endif
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}
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/** Calculate byte position of given bit position in a multibyte variable using defined endianness. */
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int bytePos(const int bitPos, const int numBytes, const bool bigEndian) {
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if (bigEndian)
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return (numBytes - 1) - (bitPos / 8);
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else // little endian
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return bitPos / 8;
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}
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/** Calculate the value of "base" to the power of "power". */
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int power(int base, int power) {
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int result = 1;
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while (power--)
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result *= base;
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return result;
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}
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} // end of anonymous namespace
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// a.k.a. palRotate
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Palette &Palette::rotateRight(byte firstIndex, byte lastIndex, signed rotationAmount) {
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debug(1, "Palette::rotateRight(firstIndex: %d, lastIndex: %d, rotationAmount:%d)", firstIndex, lastIndex, rotationAmount);
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assert(rotationAmount >= 0);
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for (int j = 0; j < rotationAmount; j++) {
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const Color lastColor = _colors[lastIndex];
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for (int i = lastIndex; i > firstIndex; i--)
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_colors[i] = _colors[i - 1];
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_colors[firstIndex] = lastColor;
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}
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return *this;
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}
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bool Palette::empty() const {
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return _colors.empty();
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}
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uint Palette::colorCount() const {
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return _colors.size();
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}
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Palette &Palette::fillWithBlack() {
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for (uint i = 0; i < _colors.size(); i++) {
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_colors[i].r = 0;
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_colors[i].g = 0;
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_colors[i].b = 0;
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}
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return *this;
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}
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// TODO: Add better heuristic for checking whether the color format is valid
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bool Palette::isValid() const {
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// Check that the color format has been actually set and not just default constructed.
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// Also check that the alpha channel is discarded.
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return _format != Graphics::PixelFormat() && _format.aLoss == 8;
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}
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const Graphics::PixelFormat &Palette::colorFormat() const {
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return _format;
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}
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void Palette::setGlobalOSystemPalette() const {
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byte buf[256 * 3]; // Allocate space for the largest possible palette
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// The color format used by OSystem's setPalette-function:
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save(buf, sizeof(buf), Graphics::PixelFormat(3, 8, 8, 8, 0, 0, 8, 16, 0), CINE_LITTLE_ENDIAN);
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if (g_cine->getPlatform() == Common::kPlatformAmiga && colorCount() == 16) {
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// The Amiga version of Future Wars does use the upper 16 colors for a darkened
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// game palette to allow transparent dialog boxes. To support that in our code
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// we do calculate that palette over here and append it to the screen palette.
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for (uint i = 0; i < 16 * 3; ++i)
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buf[16 * 3 + i] = buf[i] >> 1;
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g_system->getPaletteManager()->setPalette(buf, 0, colorCount() * 2);
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} else {
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g_system->getPaletteManager()->setPalette(buf, 0, colorCount());
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}
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}
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Cine::Palette::Color Palette::getColor(byte index) const {
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return _colors[index];
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}
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uint8 Palette::getR(byte index) const {
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return _colors[index].r;
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}
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uint8 Palette::getG(byte index) const {
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return _colors[index].g;
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}
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uint8 Palette::getB(byte index) const {
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return _colors[index].b;
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}
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void Palette::setColorFormat(const Graphics::PixelFormat format) {
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_format = format;
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}
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// a.k.a. transformPaletteRange
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Palette &Palette::saturatedAddColor(Palette &output, byte firstIndex, byte lastIndex, signed r, signed g, signed b) const {
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assert(firstIndex < colorCount() && lastIndex < colorCount());
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assert(firstIndex < output.colorCount() && lastIndex < output.colorCount());
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assert(output.colorFormat() == colorFormat());
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for (uint i = firstIndex; i <= lastIndex; i++)
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saturatedAddColor(output._colors[i], _colors[i], r, g, b);
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return output;
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}
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Palette &Palette::saturatedAddColor(Palette &output, byte firstIndex, byte lastIndex, signed rSource, signed gSource, signed bSource, const Graphics::PixelFormat &sourceFormat) const {
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// Convert the source color to the internal color format ensuring that no divide by zero will happen
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const signed r = ((signed) _format.rMax()) * rSource / MAX<int>(sourceFormat.rMax(), 1);
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const signed g = ((signed) _format.gMax()) * gSource / MAX<int>(sourceFormat.gMax(), 1);
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const signed b = ((signed) _format.bMax()) * bSource / MAX<int>(sourceFormat.bMax(), 1);
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return saturatedAddColor(output, firstIndex, lastIndex, r, g, b);
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}
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Palette &Palette::saturatedAddNormalizedGray(Palette &output, byte firstIndex, byte lastIndex, int grayDividend, int grayDenominator) const {
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assert(grayDenominator != 0);
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const signed r = ((signed) _format.rMax()) * grayDividend / grayDenominator;
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const signed g = ((signed) _format.gMax()) * grayDividend / grayDenominator;
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const signed b = ((signed) _format.bMax()) * grayDividend / grayDenominator;
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return saturatedAddColor(output, firstIndex, lastIndex, r, g, b);
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}
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// a.k.a. transformColor
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void Palette::saturatedAddColor(Color &result, const Color &baseColor, signed r, signed g, signed b) const {
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result.r = CLIP<int>(baseColor.r + r, 0, _format.rMax());
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result.g = CLIP<int>(baseColor.g + g, 0, _format.gMax());
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result.b = CLIP<int>(baseColor.b + b, 0, _format.bMax());
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}
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Palette::Palette(const Graphics::PixelFormat format, const uint numColors) : _format(format), _colors() {
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_colors.resize(numColors);
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fillWithBlack();
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}
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Palette &Palette::clear() {
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_format = Graphics::PixelFormat();
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_colors.clear();
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return *this;
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}
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Palette &Palette::load(const byte *buf, const uint size, const Graphics::PixelFormat format, const uint numColors, const EndianType endian) {
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assert(format.bytesPerPixel * numColors <= size); // Make sure there's enough input space
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assert(format.aLoss == 8); // No alpha
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assert(format.rShift / 8 == (format.rShift + MAX<int>(0, format.rBits() - 1)) / 8); // R must be inside one byte
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assert(format.gShift / 8 == (format.gShift + MAX<int>(0, format.gBits() - 1)) / 8); // G must be inside one byte
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assert(format.bShift / 8 == (format.bShift + MAX<int>(0, format.bBits() - 1)) / 8); // B must be inside one byte
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setColorFormat(format);
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_colors.clear();
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_colors.resize(numColors);
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const int rBytePos = bytePos(format.rShift, format.bytesPerPixel, isBigEndian(endian));
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const int gBytePos = bytePos(format.gShift, format.bytesPerPixel, isBigEndian(endian));
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const int bBytePos = bytePos(format.bShift, format.bytesPerPixel, isBigEndian(endian));
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for (uint i = 0; i < numColors; i++) {
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// format.rMax(), format.gMax(), format.bMax() are also used as masks here
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_colors[i].r = (buf[i * format.bytesPerPixel + rBytePos] >> (format.rShift % 8)) & format.rMax();
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_colors[i].g = (buf[i * format.bytesPerPixel + gBytePos] >> (format.gShift % 8)) & format.gMax();
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_colors[i].b = (buf[i * format.bytesPerPixel + bBytePos] >> (format.bShift % 8)) & format.bMax();
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}
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return *this;
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}
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byte *Palette::save(byte *buf, const uint size, const EndianType endian) const {
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return save(buf, size, colorFormat(), colorCount(), endian);
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}
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byte *Palette::save(byte *buf, const uint size, const Graphics::PixelFormat format, const EndianType endian) const {
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return save(buf, size, format, colorCount(), endian);
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}
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byte *Palette::save(byte *buf, const uint size, const Graphics::PixelFormat format, const uint numColors, const EndianType endian, const byte firstIndex) const {
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assert(format.bytesPerPixel * numColors <= size); // Make sure there's enough output space
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assert(format.aLoss == 8); // No alpha
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assert(format.rShift / 8 == (format.rShift + MAX<int>(0, format.rBits() - 1)) / 8); // R must be inside one byte
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assert(format.gShift / 8 == (format.gShift + MAX<int>(0, format.gBits() - 1)) / 8); // G must be inside one byte
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assert(format.bShift / 8 == (format.bShift + MAX<int>(0, format.bBits() - 1)) / 8); // B must be inside one byte
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// Clear the part of the output palette we're going to be writing to with all black
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memset(buf, 0, format.bytesPerPixel * numColors);
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// Calculate original R/G/B max values
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const int rOrigMax = power(2, 8 - colorFormat().rLoss) - 1;
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const int gOrigMax = power(2, 8 - colorFormat().gLoss) - 1;
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const int bOrigMax = power(2, 8 - colorFormat().bLoss) - 1;
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// Calculate new R/G/B max values
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const int rNewMax = power(2, 8 - format.rLoss) - 1;
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const int gNewMax = power(2, 8 - format.gLoss) - 1;
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const int bNewMax = power(2, 8 - format.bLoss) - 1;
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// Calculate the byte position
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const int rBytePos = bytePos(format.rShift, format.bytesPerPixel, isBigEndian(endian));
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const int gBytePos = bytePos(format.gShift, format.bytesPerPixel, isBigEndian(endian));
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const int bBytePos = bytePos(format.bShift, format.bytesPerPixel, isBigEndian(endian));
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// Save the palette to the output in the specified format
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for (uint i = firstIndex; i < firstIndex + numColors; i++) {
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const uint r = (_colors[i].r * rNewMax) / rOrigMax;
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const uint g = (_colors[i].g * gNewMax) / gOrigMax;
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const uint b = (_colors[i].b * bNewMax) / bOrigMax;
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buf[i * format.bytesPerPixel + rBytePos] |= r << (format.rShift % 8);
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buf[i * format.bytesPerPixel + gBytePos] |= g << (format.gShift % 8);
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buf[i * format.bytesPerPixel + bBytePos] |= b << (format.bShift % 8);
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}
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// Return the pointer to the output palette
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return buf;
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}
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} // End of namespace Cine
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