/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program 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 program 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 program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * $URL$ * $Id$ * */ #include "common/stdafx.h" #include "common/endian.h" #include "kyra/kyra_v2.h" #include "kyra/screen_v2.h" namespace Kyra { Screen_v2::Screen_v2(KyraEngine_v2 *vm, OSystem *system) : Screen(vm, system) { _vm = vm; } Screen_v2::~Screen_v2() { } void Screen_v2::setScreenDim(int dim) { debugC(9, kDebugLevelScreen, "Screen_v2::setScreenDim(%d)", dim); if (_vm->game() == GI_KYRA2) { assert(dim < _screenDimTableCount); _curDim = &_screenDimTable[dim]; } else { assert(dim < _screenDimTableCountK3); _curDim = &_screenDimTableK3[dim]; } } const ScreenDim *Screen_v2::getScreenDim(int dim) { debugC(9, kDebugLevelScreen, "Screen_v2::getScreenDim(%d)", dim); if (_vm->game() == GI_KYRA2) { assert(dim < _screenDimTableCount); return &_screenDimTable[dim]; } else { assert(dim < _screenDimTableCountK3); return &_screenDimTableK3[dim]; } } void Screen_v2::k2IntroFadeToGrey(int delay) { debugC(9, kDebugLevelScreen, "Screen_v2::k2IntroFadeToGrey(%d)", delay); for (int i = 0; i <= 50; ++i) { if (i <= 8 || i >= 30) { _currentPalette[3 * i + 0] = (_currentPalette[3 * i + 0] + _currentPalette[3 * i + 1] + _currentPalette[3 * i + 2]) / 3; _currentPalette[3 * i + 1] = _currentPalette[3 * i + 0]; _currentPalette[3 * i + 2] = _currentPalette[3 * i + 0]; } } // color 71 is the same in both the overview and closeup scenes // Converting it to greyscale makes the trees in the closeup look dull for (int i = 71; i < 200; ++i) { _currentPalette[3 * i + 0] = (_currentPalette[3 * i + 0] + _currentPalette[3 * i + 1] + _currentPalette[3 * i + 2]) / 3; _currentPalette[3 * i + 1] = _currentPalette[3 * i + 0]; _currentPalette[3 * i + 2] = _currentPalette[3 * i + 0]; } fadePalette(_currentPalette, delay); // Make the font color white again setPaletteIndex(254, 254, 254, 254); } void Screen_v2::copyWsaRect(int x, int y, int w, int h, int dimState, int plotFunc, const uint8 *src, int unk1, const uint8 *unkPtr1, const uint8 *unkPtr2) { uint8 *dstPtr = getPagePtr(_curPage); uint8 *origDst = dstPtr; const ScreenDim *dim = getScreenDim(dimState); int dimX1 = dim->sx << 3; int dimX2 = dim->w << 3; dimX2 += dimX1; int dimY1 = dim->sy; int dimY2 = dim->h; dimY2 += dimY1; int temp = y - dimY1; if (temp < 0) { if ((temp += h) <= 0) return; else { SWAP(temp, h); y += temp - h; src += (temp - h) * w; } } temp = dimY2 - y; if (temp <= 0) return; if (temp < h) h = temp; int srcOffset = 0; temp = x - dimX1; if (temp < 0) { temp = -temp; srcOffset = temp; x += temp; w -= temp; } int srcAdd = 0; temp = dimX2 - x; if (temp <= 0) return; if (temp < w) { SWAP(w, temp); temp -= w; srcAdd = temp; } dstPtr += y * SCREEN_W + x; uint8 *dst = dstPtr; if (_curPage == 0 || _curPage == 1) addDirtyRect(x, y, w, h); clearOverlayRect(_curPage, x, y, w, h); temp = h; while (h--) { src += srcOffset; int cW = w; switch (plotFunc) { case 0: memcpy(dst, src, cW); dst += cW; src += cW; break; case 1: while (cW--) { uint8 d = *src++; uint8 t = unkPtr1[d]; if (t != 0xFF) d = unkPtr2[*dst + (t << 8)]; *dst++ = d; } break; case 4: while (cW--) { uint8 d = *src++; if (d) *dst = d; ++dst; } break; case 5: while (cW--) { uint8 d = *src++; if (d) { uint8 t = unkPtr1[d]; if (t != 0xFF) d = unkPtr2[*dst + (t << 8)]; *dst = d; } ++dst; } break; case 8: case 9: while (cW--) { uint8 d = *src++; uint8 t = _shapePages[0][dst - origDst] & 7; if (unk1 < t) d = _shapePages[1][dst - origDst]; *dst++ = d; } break; case 12: case 13: while (cW--) { uint8 d = *src++; if (d) { uint8 t = _shapePages[0][dst - origDst] & 7; if (unk1 < t) d = _shapePages[1][dst - origDst]; *dst++ = d; } else { d = _shapePages[1][dst - origDst]; *dst++ = d; } } break; default: break; } dst = (dstPtr += SCREEN_W); src += srcAdd; } } const uint8 *Screen_v2::getPtrToShape(const uint8 *shpFile, int shape) { debugC(9, kDebugLevelScreen, "Screen_v2::getPtrToShape(%p, %d)", (const void *)shpFile, shape); uint16 shapes = READ_LE_UINT16(shpFile); if (shapes <= shape) return 0; uint32 offset = READ_LE_UINT32(shpFile + (shape << 2) + 2); return shpFile + offset + 2; } uint8 *Screen_v2::getPtrToShape(uint8 *shpFile, int shape) { debugC(9, kDebugLevelScreen, "Screen_v2::getPtrToShape(%p, %d)", (void *)shpFile, shape); uint16 shapes = READ_LE_UINT16(shpFile); if (shapes <= shape) return 0; uint32 offset = READ_LE_UINT32(shpFile + (shape << 2) + 2); return shpFile + offset + 2; } int Screen_v2::getShapeScaledWidth(const uint8 *shpFile, int scale) { int width = READ_LE_UINT16(shpFile+3); return (width * scale) >> 8; } int Screen_v2::getShapeScaledHeight(const uint8 *shpFile, int scale) { int height = shpFile[2]; return (height * scale) >> 8; } uint16 Screen_v2::getShapeSize(const uint8 *shp) { debugC(9, kDebugLevelScreen, "Screen_v2::getShapeSize(%p)", (const void *)shp); return READ_LE_UINT16(shp+6); } uint8 *Screen_v2::makeShapeCopy(const uint8 *src, int index) { debugC(9, kDebugLevelScreen, "Screen_v2::makeShapeCopy(%p, %d)", (const void *)src, index); const uint8 *shape = getPtrToShape(src, index); int size = getShapeSize(shape); uint8 *copy = new uint8[size]; assert(copy); memcpy(copy, shape, size); return copy; } void Screen_v2::drawShape(uint8 page, const uint8 *shape, int x, int y, int sd, int flags, ...) { if (!shape) return; if (*shape & 1) flags |= 0x400; va_list args; va_start(args, flags); static int drawShapeVar1 = 0; static int drawShapeVar2[] = { 1, 3, 2, 5, 4, 3, 2, 1 }; static int drawShapeVar3 = 1; static int drawShapeVar4 = 0; static int drawShapeVar5 = 0; uint8 *table = 0; int tableLoopCount = 0; int drawLayer = 0; const uint8 *table2 = 0; uint8 *table3 = 0; uint8 *table4 = 0; if (flags & 0x8000) { table2 = va_arg(args, uint8*); } if (flags & 0x100) { table = va_arg(args, uint8*); tableLoopCount = va_arg(args, int); if (!tableLoopCount) flags &= 0xFFFFFEFF; } if (flags & 0x1000) { table3 = va_arg(args, uint8*); table4 = va_arg(args, uint8*); } if (flags & 0x200) { drawShapeVar1 += 1; drawShapeVar1 &= 7; drawShapeVar3 = drawShapeVar2[drawShapeVar1]; drawShapeVar4 = 0; drawShapeVar5 = 256; } if (flags & 0x4000) { drawShapeVar5 = va_arg(args, int); } if (flags & 0x800) { drawLayer = va_arg(args, int); } int scale_w, scale_h; if (flags & 0x04) { scale_w = va_arg(args, int); scale_h = va_arg(args, int); } else { scale_w = 0x100; scale_h = 0x100; } int ppc = (flags >> 8) & 0x3F; const uint8 *src = shape; uint16 shapeFlags = READ_LE_UINT16(src); src += 2; int shapeHeight = *src++; int scaledShapeHeight = (shapeHeight * scale_h) >> 8; if (scaledShapeHeight == 0) { va_end(args); return; } int shapeWidth = READ_LE_UINT16(src); src += 2; int scaledShapeWidth = (shapeWidth * scale_w) >> 8; if (scaledShapeWidth == 0) { va_end(args); return; } if (flags & 0x20) { x -= scaledShapeWidth >> 1; y -= scaledShapeHeight >> 1; } src += 3; uint16 frameSize = READ_LE_UINT16(src); src += 2; int colorTableColors = 0x10; if (shapeFlags & 4) colorTableColors = *src++; if (!(flags & 0x8000) && (shapeFlags & 1)) table2 = src; if ((shapeFlags & 1) || (flags & 0x400)) src += colorTableColors; if (!(shapeFlags & 2)) { decodeFrame4(src, _animBlockPtr, frameSize); src = _animBlockPtr; } int shapeSize = shapeWidth * shapeHeight; if (_decodeShapeBufferSize < shapeSize) { delete [] _decodeShapeBuffer; _decodeShapeBuffer = new uint8[shapeSize]; _decodeShapeBufferSize = shapeSize; } if (!_decodeShapeBuffer) { _decodeShapeBufferSize = 0; va_end(args); return; } memset(_decodeShapeBuffer, 0, _decodeShapeBufferSize); uint8 *decodedShapeFrame = _decodeShapeBuffer; for (int j = 0; j < shapeHeight; ++j) { uint8 *dsbNextLine = decodedShapeFrame + shapeWidth; int count = shapeWidth; while (count > 0) { uint8 code = *src++; if (code != 0) { *decodedShapeFrame++ = code; --count; } else { code = *src++; decodedShapeFrame += code; count -= code; } } decodedShapeFrame = dsbNextLine; } uint16 sx1 = getScreenDim(sd)->sx << 3; uint16 sy1 = getScreenDim(sd)->sy; uint16 sx2 = sx1 + (getScreenDim(sd)->w << 3); uint16 sy2 = sy1 + getScreenDim(sd)->h; if (flags & 0x10) { x += sx1; y += sy1; } int x1, x2; if (x >= 0) { x1 = 0; if (x + scaledShapeWidth < sx2) { x2 = scaledShapeWidth; } else { x2 = sx2 - x; } } else { x2 = scaledShapeWidth; x1 = -x; x = 0; if (x2 > sx2) { x2 = sx2; } } int y1, y2; if (y >= 0) { y1 = 0; if (y + scaledShapeHeight < sy2) { y2 = scaledShapeHeight; } else { y2 = sy2 - y; } } else { y2 = scaledShapeHeight; y1 = -y; y = 0; if (y2 > sy2) { y2 = sy2; } } uint8 *dst = getPagePtr(page) + y * 320 + x; uint8 *dstStart = getPagePtr(page); int scaleYTable[200]; for (y = y1; y < y2; ++y) { scaleYTable[y] = (y << 8) / scale_h; } int scaleXTable[320]; for (x = x1; x < x2; ++x) { scaleXTable[x] = (x << 8) / scale_w; } const uint8 *shapeBuffer = _decodeShapeBuffer; if (flags & 0x02) { shapeBuffer += shapeWidth * (shapeHeight - 1); } if (flags & 0x01) { shapeBuffer += shapeWidth - 1; } for (y = y1; y < y2; ++y) { uint8 *dstNextLine = dst + 320; int j = scaleYTable[y]; if (flags & 0x02) { j = -j; } for (x = x1; x < x2; ++x) { int xpos = scaleXTable[x]; if (flags & 0x01) xpos = -xpos; uint8 color = shapeBuffer[j * shapeWidth + xpos]; if (color != 0) { switch (ppc) { case 0: *dst = color; break; case 4: *dst = table2[color]; break; case 8: { int layer = _shapePages[0][dst - dstStart] & 7; if (drawLayer > layer) color = _shapePages[1][dst - dstStart]; *dst = color; } break; case 12: { int layer = _shapePages[0][dst - dstStart] & 7; if (drawLayer < layer) color = _shapePages[1][dst - dstStart]; else color = table2[color]; *dst = color; } break; default: warning("unhandled ppc: %d", ppc); break; } } ++dst; } dst = dstNextLine; } va_end(args); } int Screen_v2::getRectSize(int w, int h) { if (w > 320 || h > 200) return 0; return w*h; } int Screen_v2::getLayer(int x, int y) { if (x < 0) x = 0; else if (x >= 320) x = 319; if (y < 0) y = 0; else if (y >= 144) y = 143; uint8 pixel = *(getCPagePtr(5) + y * 320 + x); pixel &= 0x7F; pixel >>= 3; if (pixel < 1) pixel = 1; else if (pixel > 15) pixel = 15; return pixel; } bool Screen_v2::isMouseVisible() const { return _mouseLockCount == 0; } } // end of namespace Kyra