/* ScummVM - Scumm Interpreter * Copyright (C) 2001 Ludvig Strigeus * Copyright (C) 2001-2005 The ScummVM project * * 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. * * $Header$ * */ #include "common/stdafx.h" #include "scumm/intern.h" #include "scumm/resource.h" #include "scumm/scumm.h" #include "scumm/wiz_he.h" namespace Scumm { Wiz::Wiz(ScummEngine_v70he *vm) : _vm(vm) { _imagesNum = 0; memset(&_images, 0, sizeof(_images)); memset(&_polygons, 0, sizeof(_polygons)); _rectOverrideEnabled = false; } void Wiz::clearWizBuffer() { _imagesNum = 0; } void Wiz::polygonClear() { for (int i = 0; i < ARRAYSIZE(_polygons); i++) { if (_polygons[i].flag == 1) memset(&_polygons[i], 0, sizeof(WizPolygon)); } } void Wiz::polygonLoad(const uint8 *polData) { int slots = READ_LE_UINT32(polData); polData += 4; debug(1, "Loading %d polygon slots", slots); bool flag = 1; int id, points, vert1x, vert1y, vert2x, vert2y, vert3x, vert3y, vert4x, vert4y; while (slots--) { id = READ_LE_UINT32(polData); points = READ_LE_UINT32(polData + 4); if (points != 4) error("Illegal polygon with %d points", points); vert1x = READ_LE_UINT32(polData + 8); vert1y = READ_LE_UINT32(polData + 12); vert2x = READ_LE_UINT32(polData + 16); vert2y = READ_LE_UINT32(polData + 20); vert3x = READ_LE_UINT32(polData + 24); vert3y = READ_LE_UINT32(polData + 28); vert4x = READ_LE_UINT32(polData + 32); vert4y = READ_LE_UINT32(polData + 36); polData += 40; polygonStore(id, flag, vert1x, vert1y, vert2x, vert2y, vert3x, vert3y, vert4x, vert4y); } } void Wiz::polygonStore(int id, bool flag, int vert1x, int vert1y, int vert2x, int vert2y, int vert3x, int vert3y, int vert4x, int vert4y) { WizPolygon *wp = NULL; for (int i = 0; i < ARRAYSIZE(_polygons); ++i) { if (_polygons[i].id == 0) { wp = &_polygons[i]; break; } } if (!wp) { error("Wiz::polygonStore: out of polygon slot, max = %d", ARRAYSIZE(_polygons)); } wp->vert[0].x = vert1x; wp->vert[0].y = vert1y; wp->vert[1].x = vert2x; wp->vert[1].y = vert2y; wp->vert[2].x = vert3x; wp->vert[2].y = vert3y; wp->vert[3].x = vert4x; wp->vert[3].y = vert4y; wp->vert[4].x = vert1x; wp->vert[4].y = vert1y; wp->id = id; wp->numVerts = 5; wp->flag = flag; polygonCalcBoundBox(wp->vert, wp->numVerts, wp->bound); } void Wiz::polygonRotatePoints(Common::Point *pts, int num, int angle) { double alpha = angle * PI / 180.; double cos_alpha = cos(alpha); double sin_alpha = sin(alpha); for (int i = 0; i < num; ++i) { int16 x = pts[i].x; int16 y = pts[i].y; pts[i].x = (int16)(x * cos_alpha - y * sin_alpha); pts[i].y = (int16)(y * cos_alpha + x * sin_alpha); } } void Wiz::polygonCalcBoundBox(Common::Point *vert, int numVerts, Common::Rect &bound) { bound.left = 10000; bound.top = 10000; bound.right = -10000; bound.bottom = -10000; // compute bounding box for (int j = 0; j < numVerts; j++) { Common::Rect r(vert[j].x, vert[j].y, vert[j].x + 1, vert[j].y + 1); bound.extend(r); } } void Wiz::polygonErase(int fromId, int toId) { for (int i = 0; i < ARRAYSIZE(_polygons); i++) { if (_polygons[i].id >= fromId && _polygons[i].id <= toId) memset(&_polygons[i], 0, sizeof(WizPolygon)); } } int Wiz::polygonHit(int id, int x, int y) { for (int i = 0; i < ARRAYSIZE(_polygons); i++) { if ((id == 0 || _polygons[i].id == id) && _polygons[i].bound.contains(x, y)) { if (polygonContains(_polygons[i], x, y)) { return _polygons[i].id; } } } return 0; } bool Wiz::polygonDefined(int id) { for (int i = 0; i < ARRAYSIZE(_polygons); i++) if (_polygons[i].id == id) return true; return false; } bool Wiz::polygonContains(const WizPolygon &pol, int x, int y) { int pi = pol.numVerts - 1; bool diry = (y < pol.vert[pi].y); bool curdir; bool r = false; for (int i = 0; i < pol.numVerts; i++) { curdir = (y < pol.vert[i].y); if (curdir != diry) { if (((pol.vert[pi].y - pol.vert[i].y) * (pol.vert[i].x - x) < (pol.vert[pi].x - pol.vert[i].x) * (pol.vert[i].y - y)) == diry) r = !r; } pi = i; diry = curdir; } // HE80+ int a, b; pi = pol.numVerts - 1; if (r == 0) { for (int i = 0; i < pol.numVerts; i++) { if (pol.vert[i].y == y && pol.vert[i].y == pol.vert[pi].y) { a = pol.vert[i].x; b = pol.vert[pi].x; if (pol.vert[i].x >= pol.vert[pi].x) a = pol.vert[pi].x; if (pol.vert[i].x > pol.vert[pi].x) b = pol.vert[i].x; if (x >= a && x <= b) return 1; } else if (pol.vert[i].x == x && pol.vert[i].x == pol.vert[pi].x) { a = pol.vert[i].y; b = pol.vert[i].y; if (pol.vert[i].y >= pol.vert[pi].y) a = pol.vert[pi].y; if (pol.vert[i].y <= pol.vert[pi].y) b = pol.vert[pi].y; if (y >= a && y <= b) return 1; } pi = i; } } return r; } void Wiz::copyAuxImage(uint8 *dst1, uint8 *dst2, const uint8 *src, int dstw, int dsth, int srcx, int srcy, int srcw, int srch) { Common::Rect dstRect(srcx, srcy, srcx + srcw, srcy + srch); dstRect.clip(dstw, dsth); int rw = dstRect.width(); int rh = dstRect.height(); if (rh <= 0 || rw <= 0) return; uint8 *dst1Ptr = dst1 + dstRect.left + dstRect.top * dstw; uint8 *dst2Ptr = dst2 + dstRect.left + dstRect.top * dstw; const uint8 *dataPtr = src; while (rh--) { uint16 off = READ_LE_UINT16(dataPtr); dataPtr += 2; const uint8 *dataPtrNext = off + dataPtr; uint8 *dst1PtrNext = dst1Ptr + dstw; uint8 *dst2PtrNext = dst2Ptr + dstw; if (off != 0) { int w = rw; while (w > 0) { uint8 code = *dataPtr++; if (code & 1) { code >>= 1; dst1Ptr += code; dst2Ptr += code; w -= code; } else if (code & 2) { code = (code >> 2) + 1; w -= code; if (w >= 0) { memset(dst1Ptr, *dataPtr++, code); dst1Ptr += code; dst2Ptr += code; } else { code += w; memset(dst1Ptr, *dataPtr, code); } } else { code = (code >> 2) + 1; w -= code; if (w >= 0) { memcpy(dst1Ptr, dst2Ptr, code); dst1Ptr += code; dst2Ptr += code; } else { code += w; memcpy(dst1Ptr, dst2Ptr, code); } } } } dataPtr = dataPtrNext; dst1Ptr = dst1PtrNext; dst2Ptr = dst2PtrNext; } } static bool calcClipRects(int dst_w, int dst_h, int src_x, int src_y, int src_w, int src_h, const Common::Rect *rect, Common::Rect &srcRect, Common::Rect &dstRect) { srcRect = Common::Rect(src_w, src_h); dstRect = Common::Rect(src_x, src_y, src_x + src_w, src_y + src_h); Common::Rect r3; int diff; if (rect) { r3 = *rect; Common::Rect r4(dst_w, dst_h); if (r3.intersects(r4)) { r3.clip(r4); } else { return false; } } else { r3 = Common::Rect(dst_w, dst_h); } diff = dstRect.left - r3.left; if (diff < 0) { srcRect.left -= diff; dstRect.left -= diff; } diff = dstRect.right - r3.right; if (diff > 0) { srcRect.right -= diff; dstRect.right -= diff; } diff = dstRect.top - r3.top; if (diff < 0) { srcRect.top -= diff; dstRect.top -= diff; } diff = dstRect.bottom - r3.bottom; if (diff > 0) { srcRect.bottom -= diff; dstRect.bottom -= diff; } return srcRect.isValidRect() && dstRect.isValidRect(); } void Wiz::copyWizImage(uint8 *dst, const uint8 *src, int dstw, int dsth, int srcx, int srcy, int srcw, int srch, const Common::Rect *rect, const uint8 *palPtr) { Common::Rect r1, r2; if (calcClipRects(dstw, dsth, srcx, srcy, srcw, srch, rect, r1, r2)) { dst += r2.left + r2.top * dstw; decompressWizImage(dst, dstw, r2, src, r1, palPtr); } } void Wiz::copyRaw16BitWizImage(uint8 *dst, const uint8 *src, int dstw, int dsth, int srcx, int srcy, int srcw, int srch, const Common::Rect *rect, int flags, const uint8 *palPtr, int transColor) { // RAW 16 bits in 555 format // HACK: Skip every second bit for now Common::Rect r1, r2; if (calcClipRects(dstw, dsth, srcx, srcy, srcw, srch, rect, r1, r2)) { if (flags & kWIFFlipX) { int l = r1.left; int r = r1.right; r1.left = srcw - r; r1.right = srcw - l; } if (flags & kWIFFlipY) { int t = r1.top; int b = r1.bottom; r1.top = srch - b; r1.bottom = srch - t; } byte imagePal[256]; if (!palPtr) { for (int i = 0; i < 256; i++) { imagePal[i] = i; } palPtr = imagePal; } int h = r1.height(); int w = r1.width(); src += r1.left + r1.top * srcw * 2; dst += r2.left + r2.top * dstw; while (h--) { const uint8 *p = src; for (int i = 0; i < w; ++i) { uint8 col = *p; if (transColor == -1 || transColor != col) { dst[i] = palPtr[col]; } p += 2; } src += srcw * 2; dst += dstw; } } } void Wiz::copyRawWizImage(uint8 *dst, const uint8 *src, int dstw, int dsth, int srcx, int srcy, int srcw, int srch, const Common::Rect *rect, int flags, const uint8 *palPtr, int transColor) { Common::Rect r1, r2; if (calcClipRects(dstw, dsth, srcx, srcy, srcw, srch, rect, r1, r2)) { if (flags & kWIFFlipX) { int l = r1.left; int r = r1.right; r1.left = srcw - r; r1.right = srcw - l; } if (flags & kWIFFlipY) { int t = r1.top; int b = r1.bottom; r1.top = srch - b; r1.bottom = srch - t; } byte imagePal[256]; if (!palPtr) { for (int i = 0; i < 256; i++) { imagePal[i] = i; } palPtr = imagePal; } int h = r1.height(); int w = r1.width(); src += r1.left + r1.top * srcw; dst += r2.left + r2.top * dstw; while (h--) { const uint8 *p = src; for (int i = 0; i < w; ++i) { uint8 col = *p++; if (transColor == -1 || transColor != col) { dst[i] = palPtr[col]; } } src += srcw; dst += dstw; } } } void Wiz::decompressWizImage(uint8 *dst, int dstPitch, const Common::Rect &dstRect, const uint8 *src, const Common::Rect &srcRect, const uint8 *palPtr) { const uint8 *dataPtr, *dataPtrNext; uint8 *dstPtr, *dstPtrNext; uint32 code; uint8 databit; int h, w, xoff; uint16 off; byte imagePal[256]; if (!palPtr) { for (int i = 0; i < 256; i++) { imagePal[i] = i; } palPtr = imagePal; } dstPtr = dst; dataPtr = src; // Skip over the first 'srcRect->top' lines in the data h = srcRect.top; while (h--) { dataPtr += READ_LE_UINT16(dataPtr) + 2; } h = srcRect.height(); w = srcRect.width(); if (h <= 0 || w <= 0) return; while (h--) { xoff = srcRect.left; off = READ_LE_UINT16(dataPtr); w = srcRect.right - srcRect.left; dstPtrNext = dstPitch + dstPtr; dataPtrNext = off + 2 + dataPtr; dataPtr += 2; if (off == 0) goto dec_next; // Skip over the leftmost 'srcRect->left' pixels. // TODO: This code could be merged (at a loss of efficency) with the // loop below which does the actual drawing. while (xoff > 0) { code = *dataPtr++; databit = code & 1; code >>= 1; if (databit) { xoff -= code; if (xoff < 0) { code = -xoff; goto dec_sub1; } } else { databit = code & 1; code = (code >> 1) + 1; if (databit) { ++dataPtr; xoff -= code; if (xoff < 0) { code = -xoff; --dataPtr; goto dec_sub2; } } else { dataPtr += code; xoff -= code; if (xoff < 0) { dataPtr += xoff; code = -xoff; goto dec_sub3; } } } } while (w > 0) { code = *dataPtr++; databit = code & 1; code >>= 1; if (databit) { dec_sub1: dstPtr += code; w -= code; } else { databit = code & 1; code = (code >> 1) + 1; if (databit) { dec_sub2: w -= code; if (w < 0) { code += w; } uint8 color = palPtr[*dataPtr++]; memset(dstPtr, color, code); dstPtr += code; } else { dec_sub3: w -= code; if (w < 0) { code += w; } while (code--) { *dstPtr++ = palPtr[*dataPtr++]; } } } } dec_next: dataPtr = dataPtrNext; dstPtr = dstPtrNext; } } int Wiz::isWizPixelNonTransparent(const uint8 *data, int x, int y, int w, int h) { if (x < 0 || x >= w || y < 0 || y >= h) { return 0; } while (y != 0) { data += READ_LE_UINT16(data) + 2; --y; } uint16 off = READ_LE_UINT16(data); data += 2; if (off == 0) { return 0; } while (x > 0) { uint8 code = *data++; if (code & 1) { code >>= 1; if (code > x) { return 0; } x -= code; } else if (code & 2) { code = (code >> 2) + 1; if (code > x) { return 1; } x -= code; ++data; } else { code = (code >> 2) + 1; if (code > x) { return 1; } x -= code; data += code; } } return (~data[0]) & 1; } uint8 Wiz::getWizPixelColor(const uint8 *data, int x, int y, int w, int h, uint8 color) { if (x < 0 || x >= w || y < 0 || y >= h) { return color; } while (y != 0) { data += READ_LE_UINT16(data) + 2; --y; } uint16 off = READ_LE_UINT16(data); data += 2; if (off == 0) { return color; } while (x > 0) { uint8 code = *data++; if (code & 1) { code >>= 1; if (code > x) { return color; } x -= code; } else if (code & 2) { code = (code >> 2) + 1; if (code > x) { return data[0]; } x -= code; ++data; } else { code = (code >> 2) + 1; if (code > x) { return data[x]; } x -= code; data += code; } } return (data[0] & 1) ? color : data[1]; } uint8 Wiz::getRawWizPixelColor(const uint8 *data, int x, int y, int w, int h, uint8 color) { if (x < 0 || x >= w || y < 0 || y >= h) { return color; } return data[y * w + x]; } void Wiz::computeWizHistogram(uint32 *histogram, const uint8 *data, const Common::Rect &rCapt) { int y = rCapt.top; while (y != 0) { data += READ_LE_UINT16(data) + 2; --y; } int ih = rCapt.height(); while (ih--) { uint16 off = READ_LE_UINT16(data); data += 2; if (off != 0) { const uint8 *p = data; int x1 = rCapt.left; int x2 = rCapt.right; uint8 code; while (x1 > 0) { code = *p++; if (code & 1) { code >>= 1; if (code > x1) { code -= x1; x2 -= code; break; } x1 -= code; } else if (code & 2) { code = (code >> 2) + 1; if (code > x1) { code -= x1; goto dec_sub2; } x1 -= code; ++p; } else { code = (code >> 2) + 1; if (code > x1) { code -= x1; p += x1; goto dec_sub3; } x1 -= code; p += code; } } while (x2 > 0) { code = *p++; if (code & 1) { code >>= 1; x2 -= code; } else if (code & 2) { code = (code >> 2) + 1; dec_sub2: x2 -= code; if (x2 < 0) { code += x2; } histogram[*p++] += code; } else { code = (code >> 2) + 1; dec_sub3: x2 -= code; if (x2 < 0) { code += x2; } int n = code; while (n--) { ++histogram[*p++]; } } } data += off; } } } void Wiz::computeRawWizHistogram(uint32 *histogram, const uint8 *data, int srcPitch, const Common::Rect &rCapt) { data += rCapt.top * srcPitch + rCapt.left; int iw = rCapt.width(); int ih = rCapt.height(); while (ih--) { for (int i = 0; i < iw; ++i) { ++histogram[data[i]]; } data += srcPitch; } } static int wizPackType1(uint8 *dst, const uint8 *src, int srcPitch, const Common::Rect& rCapt, uint8 tColor) { debug(9, "wizPackType1(%d, [%d,%d,%d,%d])", tColor, rCapt.left, rCapt.top, rCapt.right, rCapt.bottom); src += rCapt.top * srcPitch + rCapt.left; int w = rCapt.width(); int h = rCapt.height(); int dataSize = 0; while (h--) { uint8 *dstLine = dst; if (dst) { dst += 2; } uint8 diffBuffer[0x40]; int runCountSame = 0; int runCountDiff = 0; uint8 prevColor = src[0]; for (int i = 1; i < w; ) { uint8 color = src[i++]; if (i == 2) { if (prevColor == color) { runCountSame = 1; } else { diffBuffer[0] = prevColor; runCountDiff = 1; } } if (prevColor == color) { if (runCountDiff != 0) { runCountSame = 1; if (runCountDiff > 1) { --runCountDiff; if (dst) { *dst++ = ((runCountDiff - 1) << 2) | 0; memcpy(dst, diffBuffer, runCountDiff); dst += runCountDiff; } dataSize += runCountDiff + 1; } runCountDiff = 0; } ++runCountSame; if (prevColor == tColor) { if (runCountSame == 0x7F) { if (dst) { *dst++ = (runCountSame << 1) | 1; } ++dataSize; runCountSame = 0; } } else { if (runCountSame == 0x40) { if (dst) { *dst++ = ((runCountSame - 1) << 2) | 2; *dst++ = prevColor; } dataSize += 2; runCountSame = 0; } } } else { if (runCountSame != 0) { if (prevColor == tColor) { if (dst) { *dst++ = (runCountSame << 1) | 1; } ++dataSize; } else { if (dst) { *dst++ = ((runCountSame - 1) << 2) | 2; *dst++ = prevColor; } dataSize += 2; } runCountSame = 0; } assert(runCountDiff < ARRAYSIZE(diffBuffer)); diffBuffer[runCountDiff++] = color; if (runCountDiff == 0x40) { if (dst) { *dst++ = ((runCountDiff - 1) << 2) | 0; memcpy(dst, diffBuffer, runCountDiff); dst += runCountDiff + 1; } dataSize += runCountDiff + 1; runCountDiff = 0; } } prevColor = color; } if (runCountSame != 0) { if (prevColor == tColor) { if (dst) { *dst++ = (runCountSame << 1) | 1; } ++dataSize; } else { if (dst) { *dst++ = ((runCountSame - 1) << 2) | 2; *dst++ = prevColor; } dataSize += 2; } } if (runCountDiff != 0) { if (dst) { *dst++ = ((runCountDiff - 1) << 2) | 0; memcpy(dst, diffBuffer, runCountDiff); dst += runCountDiff; } dataSize += runCountDiff + 1; } if (dst) { WRITE_LE_UINT16(dstLine, dst - dstLine - 2); } dataSize += 2; src += srcPitch; } return dataSize; } static int wizPackType0(uint8 *dst, const uint8 *src, int srcPitch, const Common::Rect& rCapt, uint8 tColor) { debug(9, "wizPackType0(%d, [%d,%d,%d,%d])", tColor, rCapt.left, rCapt.top, rCapt.right, rCapt.bottom); int w = rCapt.width(); int h = rCapt.height(); int size = w * h; if (dst) { src += rCapt.top * srcPitch + rCapt.left; while (h--) { memcpy(dst, src, w); dst += w; src += srcPitch; } } return size; } void Wiz::captureWizImage(int resNum, const Common::Rect& r, bool backBuffer, int compType) { debug(5, "ScummEngine_v72he::captureWizImage(%d, %d, [%d,%d,%d,%d])", resNum, compType, r.left, r.top, r.right, r.bottom); uint8 *src = NULL; VirtScreen *pvs = &_vm->virtscr[kMainVirtScreen]; if (backBuffer) { src = pvs->getBackPixels(0, 0); } else { src = pvs->getPixels(0, 0); } Common::Rect rCapt(pvs->w, pvs->h); if (rCapt.intersects(r)) { rCapt.clip(r); const uint8 *palPtr; if (_vm->_heversion >= 99) { palPtr = _vm->_hePalettes + 1024; } else { palPtr = _vm->_currentPalette; } int w = rCapt.width(); int h = rCapt.height(); int tColor = (_vm->VAR_WIZ_TCOLOR != 0xFF) ? _vm->VAR(_vm->VAR_WIZ_TCOLOR) : 5; // compute compressed size int dataSize = 0; int headerSize = palPtr ? 1080 : 36; switch (compType) { case 0: dataSize = wizPackType0(0, src, pvs->pitch, rCapt, tColor); break; case 1: dataSize = wizPackType1(0, src, pvs->pitch, rCapt, tColor); break; default: error("unhandled compression type %d", compType); break; } // alignment dataSize = (dataSize + 1) & ~1; int wizSize = headerSize + dataSize; // write header uint8 *wizImg = _vm->res.createResource(rtImage, resNum, dataSize + headerSize); WRITE_BE_UINT32(wizImg + 0x00, 'AWIZ'); WRITE_BE_UINT32(wizImg + 0x04, wizSize); WRITE_BE_UINT32(wizImg + 0x08, 'WIZH'); WRITE_BE_UINT32(wizImg + 0x0C, 0x14); WRITE_LE_UINT32(wizImg + 0x10, compType); WRITE_LE_UINT32(wizImg + 0x14, w); WRITE_LE_UINT32(wizImg + 0x18, h); int curSize = 0x1C; if (palPtr) { WRITE_BE_UINT32(wizImg + 0x1C, 'RGBS'); WRITE_BE_UINT32(wizImg + 0x20, 0x308); memcpy(wizImg + 0x24, palPtr, 0x300); WRITE_BE_UINT32(wizImg + 0x324, 'RMAP'); WRITE_BE_UINT32(wizImg + 0x328, 0x10C); WRITE_BE_UINT32(wizImg + 0x32C, 0); curSize = 0x330; for (int i = 0; i < 256; ++i) { wizImg[curSize] = i; ++curSize; } } WRITE_BE_UINT32(wizImg + curSize + 0x0, 'WIZD'); WRITE_BE_UINT32(wizImg + curSize + 0x4, dataSize + 8); curSize += 8; // write compressed data switch (compType) { case 0: wizPackType0(wizImg + headerSize, src, pvs->pitch, rCapt, tColor); break; case 1: wizPackType1(wizImg + headerSize, src, pvs->pitch, rCapt, tColor); break; default: break; } } } void Wiz::getWizImageDim(int resNum, int state, int32 &w, int32 &h) { uint8 *dataPtr = _vm->getResourceAddress(rtImage, resNum); assert(dataPtr); uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); w = READ_LE_UINT32(wizh + 0x4); h = READ_LE_UINT32(wizh + 0x8); } void Wiz::displayWizImage(WizImage *pwi) { if (_vm->_fullRedraw) { assert(_imagesNum < ARRAYSIZE(_images)); WizImage *wi = &_images[_imagesNum]; wi->resNum = pwi->resNum; wi->x1 = pwi->x1; wi->y1 = pwi->y1; wi->zorder = 0; wi->state = pwi->state; wi->flags = pwi->flags; wi->shadow = 0; wi->field_390 = 0; wi->palette = 0; ++_imagesNum; } else if (pwi->flags & kWIFIsPolygon) { drawWizPolygon(pwi->resNum, pwi->state, pwi->x1, pwi->flags, 0, 0, 0); } else { const Common::Rect *r = NULL; drawWizImage(pwi->resNum, pwi->state, pwi->x1, pwi->y1, 0, 0, 0, r, pwi->flags, 0, 0); } } uint8 *Wiz::drawWizImage(int resNum, int state, int x1, int y1, int zorder, int shadow, int field_390, const Common::Rect *clipBox, int flags, int dstResNum, int palette) { debug(2, "drawWizImage(resNum %d, x1 %d y1 %d flags 0x%X zorder %d shadow %d field_390 %d dstResNum %d palette %d)", resNum, x1, y1, flags, zorder, shadow, field_390, dstResNum, palette); uint8 *dst = NULL; const uint8 *palPtr = NULL; if (_vm->_heversion >= 99) { if (palette) { palPtr = _vm->_hePalettes + palette * 1024 + 768; } else { palPtr = _vm->_hePalettes + 1792; } } const uint8 *xmap = NULL; if (shadow) { // TODO: Handle 'XMAP' data for shadows } uint8 *dataPtr = _vm->getResourceAddress(rtImage, resNum); assert(dataPtr); uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); uint32 comp = READ_LE_UINT32(wizh + 0x0); uint32 width = READ_LE_UINT32(wizh + 0x4); uint32 height = READ_LE_UINT32(wizh + 0x8); debug(2, "wiz_header.comp = %d wiz_header.w = %d wiz_header.h = %d", comp, width, height); uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), dataPtr, state, 0); assert(wizd); if (flags & kWIFHasPalette) { uint8 *pal = _vm->findWrappedBlock(MKID('RGBS'), dataPtr, state, 0); assert(pal); _vm->setPaletteFromPtr(pal, 256); } uint8 *rmap = NULL; if (flags & kWIFRemapPalette) { rmap = _vm->findWrappedBlock(MKID('RMAP'), dataPtr, state, 0); assert(rmap); if (_vm->_heversion <= 80 || READ_BE_UINT32(rmap) != 0x01234567) { uint8 *rgbs = _vm->findWrappedBlock(MKID('RGBS'), dataPtr, state, 0); assert(rgbs); _vm->remapHEPalette(rgbs, rmap + 4); } } if (flags & kWIFPrint) { error("WizImage printing is unimplemented"); } int32 cw, ch; if (flags & kWIFBlitToMemBuffer) { dst = (uint8 *)malloc(width * height); int color = 255; // FIXME: should be (VAR_WIZ_TCOLOR != 0xFF) ? VAR(VAR_WIZ_TCOLOR) : 5; memset(dst, color, width * height); cw = width; ch = height; } else { if (dstResNum) { uint8 *dstPtr = _vm->getResourceAddress(rtImage, dstResNum); assert(dstPtr); _vm->res.lock(rtImage, dstResNum); dst = _vm->findWrappedBlock(MKID('WIZD'), dstPtr, 0, 0); assert(dst); getWizImageDim(dstResNum, 0, cw, ch); } else { VirtScreen *pvs = &_vm->virtscr[kMainVirtScreen]; if (flags & kWIFMarkBufferDirty) { dst = pvs->getPixels(0, pvs->topline); } else { dst = pvs->getBackPixels(0, pvs->topline); } cw = pvs->w; ch = pvs->h; } } Common::Rect rScreen(cw, ch); if (clipBox) { Common::Rect clip(clipBox->left, clipBox->top, clipBox->right, clipBox->bottom); if (rScreen.intersects(clip)) { rScreen.clip(clip); } else { return 0; } } else if (_rectOverrideEnabled) { if (rScreen.intersects(_rectOverride)) { rScreen.clip(_rectOverride); } else { return 0; } } if (xmap) { palPtr = xmap; } if (flags & kWIFRemapPalette) { palPtr = rmap + 4; } int color = -1; if (_vm->VAR_WIZ_TCOLOR != 0xFF) { uint8 *trns = _vm->findWrappedBlock(MKID('TRNS'), dataPtr, state, 0); color = (trns == NULL) ? _vm->VAR(_vm->VAR_WIZ_TCOLOR) : -1; } switch (comp) { case 0: copyRawWizImage(dst, wizd, cw, ch, x1, y1, width, height, &rScreen, flags, palPtr, color); break; case 1: // TODO Adding masking for flags 0x80 and 0x100 if (flags & 0x80) { // Used in maze debug(0, "drawWizImage: Unhandled flag 0x80"); } else if (flags & 0x100) { // Used in readdemo debug(0, "drawWizImage: Unhandled flag 0x100"); } copyWizImage(dst, wizd, cw, ch, x1, y1, width, height, &rScreen, palPtr); break; case 2: copyRaw16BitWizImage(dst, wizd, cw, ch, x1, y1, width, height, &rScreen, flags, palPtr, color); break; default: error("drawWizImage: Unhandled wiz compression type %d", comp); } if (!(flags & kWIFBlitToMemBuffer) && dstResNum == 0) { Common::Rect rImage(x1, y1, x1 + width, y1 + height); if (rImage.intersects(rScreen)) { rImage.clip(rScreen); if (!(flags & kWIFBlitToFrontVideoBuffer) && (flags & (kWIFBlitToFrontVideoBuffer | kWIFMarkBufferDirty))) { ++rImage.bottom; _vm->markRectAsDirty(kMainVirtScreen, rImage); } else { _vm->gdi.copyVirtScreenBuffers(rImage); } } } return dst; } struct PolygonDrawData { struct InterArea { bool valid; int32 xmin; int32 xmax; int32 x1; int32 y1; int32 x2; int32 y2; }; Common::Point pto; InterArea *ia; int areasNum; PolygonDrawData(int n) { areasNum = n; ia = new InterArea[areasNum]; memset(ia, 0, sizeof(InterArea) * areasNum); } ~PolygonDrawData() { delete[] ia; } void calcIntersection(const Common::Point *p1, const Common::Point *p2, const Common::Point *p3, const Common::Point *p4) { int32 x1_acc = p1->x << 0x10; int32 x3_acc = p3->x << 0x10; int32 y3_acc = p3->y << 0x10; uint16 dy = ABS(p2->y - p1->y) + 1; int32 x1_step = ((p2->x - p1->x) << 0x10) / dy; int32 x3_step = ((p4->x - p3->x) << 0x10) / dy; int32 y3_step = ((p4->y - p3->y) << 0x10) / dy; int iaidx = p1->y - pto.y; while (dy--) { assert(iaidx >= 0 && iaidx < areasNum); InterArea *pia = &ia[iaidx]; int32 tx1 = x1_acc >> 0x10; int32 tx3 = x3_acc >> 0x10; int32 ty3 = y3_acc >> 0x10; if (!pia->valid || pia->xmin > tx1) { pia->xmin = tx1; pia->x1 = tx3; pia->y1 = ty3; } if (!pia->valid || pia->xmax < tx1) { pia->xmax = tx1; pia->x2 = tx3; pia->y2 = ty3; } pia->valid = true; x1_acc += x1_step; x3_acc += x3_step; y3_acc += y3_step; if (p2->y <= p1->y) { --iaidx; } else { ++iaidx; } } } }; void Wiz::drawWizComplexPolygon(int resNum, int state, int po_x, int po_y, int shadow, int angle, int scale, const Common::Rect *r, int flags, int dstResNum, int palette) { Common::Point pts[4]; int32 w, h; getWizImageDim(resNum, state, w, h); pts[1].x = pts[2].x = w / 2 - 1; pts[0].x = pts[0].y = pts[1].y = pts[3].x = -w / 2; pts[2].y = pts[3].y = h / 2 - 1; // transform points if (scale != 256) { for (int i = 0; i < 4; ++i) { pts[i].x = pts[i].x * scale / 256; pts[i].y = pts[i].y * scale / 256; } } if (angle) polygonRotatePoints(pts, 4, angle); for (int i = 0; i < 4; ++i) { pts[i].x += po_x; pts[i].y += po_y; } if (scale != 256) { debug(1, "drawWizComplexPolygon() scale not implemented"); //drawWizPolygonTransform(resNum, state, pts, flags, VAR(VAR_WIZ_TCOLOR), r, dstPtr, palette, xmapPtr); } else { debug(1, "drawWizComplexPolygon() angle partially implemented"); angle %= 360; if (angle < 0) { angle += 360; } Common::Rect bounds; polygonCalcBoundBox(pts, 4, bounds); int x1 = bounds.left; int y1 = bounds.top; switch(angle) { case 270: flags |= kWIFFlipX | kWIFFlipY; //drawWizComplexPolygonHelper(resNum, state, x1, y1, r, flags, dstResNum, palette); break; case 180: flags |= kWIFFlipX | kWIFFlipY; drawWizImage(resNum, state, x1, y1, 0, shadow, 0, r, flags, dstResNum, palette); break; case 90: //drawWizComplexPolygonHelper(resNum, state, x1, y1, r, flags, dstResNum, palette); break; case 0: drawWizImage(resNum, state, x1, y1, 0, shadow, 0, r, flags, dstResNum, palette); break; default: //drawWizPolygonTransform(resNum, state, pts, flags, VAR(VAR_WIZ_TCOLOR), r, dstResNum, palette, xmapPtr); break; } } } void Wiz::drawWizPolygon(int resNum, int state, int id, int flags, int shadow, int dstResNum, int palette) { debug(1, "drawWizPolygon(resNum %d, id %d, flags 0x%X, shadow %d palette %d)", resNum, id, flags, shadow, palette); int i; WizPolygon *wp = NULL; for (i = 0; i < ARRAYSIZE(_polygons); ++i) { if (_polygons[i].id == id) { wp = &_polygons[i]; break; } } if (!wp) { error("Polygon %d is not defined", id); } if (wp->numVerts != 5) { error("Invalid point count %d for Polygon %d", wp->numVerts, id); } const Common::Rect *r = NULL; uint8 *srcWizBuf = drawWizImage(resNum, state, 0, 0, 0, shadow, 0, r, kWIFBlitToMemBuffer, 0, palette); if (srcWizBuf) { uint8 *dst; int32 wizW, wizH; VirtScreen *pvs = &_vm->virtscr[kMainVirtScreen]; if (dstResNum) { uint8 *dstPtr = _vm->getResourceAddress(rtImage, dstResNum); assert(dstPtr); _vm->res.lock(rtImage, dstResNum); dst = _vm->findWrappedBlock(MKID('WIZD'), dstPtr, 0, 0); assert(dst); getWizImageDim(dstResNum, 0, wizW, wizH); } else { if (flags & kWIFMarkBufferDirty) { dst = pvs->getPixels(0, 0); } else { dst = pvs->getBackPixels(0, 0); } getWizImageDim(resNum, state, wizW, wizH); } if (wp->bound.left < 0 || wp->bound.top < 0 || wp->bound.right >= pvs->w || wp->bound.bottom >= pvs->h) { error("Invalid coords polygon %d", wp->id); } Common::Point bbox[4]; bbox[0].x = 0; bbox[0].y = 0; bbox[1].x = wizW - 1; bbox[1].y = 0; bbox[2].x = wizW - 1; bbox[2].y = wizH - 1; bbox[3].x = 0; bbox[3].y = wizH - 1; int16 xmin_p, xmax_p, ymin_p, ymax_p; xmin_p = xmax_p = wp->vert[0].x; ymin_p = ymax_p = wp->vert[0].y; for (i = 1; i < 4; ++i) { xmin_p = MIN(wp->vert[i].x, xmin_p); xmax_p = MAX(wp->vert[i].x, xmax_p); ymin_p = MIN(wp->vert[i].y, ymin_p); ymax_p = MAX(wp->vert[i].y, ymax_p); } int16 xmin_b, xmax_b, ymin_b, ymax_b; xmin_b = 0; xmax_b = wizW - 1; ymin_b = 0; ymax_b = wizH - 1; PolygonDrawData pdd(ymax_p - ymin_p + 1); pdd.pto.x = xmin_p; pdd.pto.y = ymin_p; for (i = 0; i < 3; ++i) { pdd.calcIntersection(&wp->vert[i], &wp->vert[i + 1], &bbox[i], &bbox[i + 1]); } pdd.calcIntersection(&wp->vert[3], &wp->vert[0], &bbox[3], &bbox[0]); uint yoff = pdd.pto.y * pvs->w; for (i = 0; i < pdd.areasNum; ++i) { PolygonDrawData::InterArea *pia = &pdd.ia[i]; uint16 dx = pia->xmax - pia->xmin + 1; uint8 *dstPtr = dst + pia->xmin + yoff; int32 x_acc = pia->x1 << 0x10; int32 y_acc = pia->y1 << 0x10; int32 x_step = ((pia->x2 - pia->x1) << 0x10) / dx; int32 y_step = ((pia->y2 - pia->y1) << 0x10) / dx; while (dx--) { uint srcWizOff = (y_acc >> 0x10) * wizW + (x_acc >> 0x10); assert(srcWizOff < (uint32)(wizW * wizH)); x_acc += x_step; y_acc += y_step; *dstPtr++ = srcWizBuf[srcWizOff]; } yoff += pvs->pitch; } if (flags & kWIFMarkBufferDirty) { _vm->markRectAsDirty(kMainVirtScreen, wp->bound); } else { _vm->gdi.copyVirtScreenBuffers(wp->bound); } free(srcWizBuf); } } void Wiz::flushWizBuffer() { for (int i = 0; i < _imagesNum; ++i) { WizImage *pwi = &_images[i]; if (pwi->flags & kWIFIsPolygon) { drawWizPolygon(pwi->resNum, pwi->state, pwi->x1, pwi->flags, pwi->shadow, 0, pwi->palette); } else { const Common::Rect *r = NULL; drawWizImage(pwi->resNum, pwi->state, pwi->x1, pwi->y1, pwi->zorder, pwi->shadow, pwi->field_390, r, pwi->flags, 0, pwi->palette); } } _imagesNum = 0; } void Wiz::loadImgSpot(int resId, int state, int16 &x, int16 &y) { uint8 *dataPtr = _vm->getResourceAddress(rtImage, resId); assert(dataPtr); uint8 *spotPtr = _vm->findWrappedBlock(MKID('SPOT'), dataPtr, state, 0); if (spotPtr) { x = (int16)READ_LE_UINT32(spotPtr + 0); y = (int16)READ_LE_UINT32(spotPtr + 4); } else { x = 0; y = 0; } } void Wiz::loadWizCursor(int resId) { int16 x, y; loadImgSpot(resId, 0, x, y); if (x < 0) { x = 0; } else if (x > 32) { x = 32; } if (y < 0) { y = 0; } else if (y > 32) { y = 32; } const Common::Rect *r = NULL; uint8 *cursor = drawWizImage(resId, 0, 0, 0, 0, 0, 0, r, kWIFBlitToMemBuffer, 0, 0); int32 cw, ch; getWizImageDim(resId, 0, cw, ch); _vm->setCursorFromBuffer(cursor, cw, ch, cw); _vm->setCursorHotspot(x, y); free(cursor); } void Wiz::displayWizComplexImage(const WizParameters *params) { int sourceImage = 0; if (params->processFlags & kWPFMaskImg) { sourceImage = params->sourceImage; debug(0, "displayWizComplexImage() unhandled flag 0x80000"); } int palette = 0; if (params->processFlags & kWPFPaletteNum) { palette = params->img.palette; } int scale = 256; if (params->processFlags & kWPFScaled) { scale = params->scale; } int rotationAngle = 0; if (params->processFlags & kWPFRotate) { rotationAngle = params->angle; } int state = 0; if (params->processFlags & kWPFNewState) { state = params->img.state; } int flags = 0; if (params->processFlags & kWPFNewFlags) { flags = params->img.flags; } int po_x = 0; int po_y = 0; if (params->processFlags & kWPFSetPos) { po_x = params->img.x1; po_y = params->img.y1; } int shadow = 0; if (params->processFlags & kWPFShadow) { shadow = params->img.shadow; } int field_390 = 0; if (params->processFlags & 0x200000) { field_390 = params->img.field_390; debug(0, "displayWizComplexImage() unhandled flag 0x200000"); } const Common::Rect *r = NULL; if (params->processFlags & kWPFClipBox) { r = ¶ms->box; } int dstResNum = 0; if (params->processFlags & kWPFDstResNum) { dstResNum = params->dstResNum; } if (params->processFlags & kWPFRemapPalette) { int st = (params->processFlags & kWPFNewState) ? params->img.state : 0; int num = params->remapNum; const uint8 *index = params->remapIndex; uint8 *iwiz = _vm->getResourceAddress(rtImage, params->img.resNum); assert(iwiz); uint8 *rmap = _vm->findWrappedBlock(MKID('RMAP'), iwiz, st, 0) ; assert(rmap); WRITE_BE_UINT32(rmap, 0x01234567); while (num--) { uint8 idx = *index++; rmap[4 + idx] = params->remapColor[idx]; } flags |= kWIFRemapPalette; } if (_vm->_fullRedraw && dstResNum == 0) { if (sourceImage != 0 || (params->processFlags & (kWPFScaled | kWPFRotate))) error("Can't do this command in the enter script."); assert(_imagesNum < ARRAYSIZE(_images)); WizImage *pwi = &_images[_imagesNum]; pwi->resNum = params->img.resNum; pwi->x1 = po_x; pwi->y1 = po_y; pwi->zorder = params->img.zorder; pwi->state = state; pwi->flags = flags; pwi->shadow = shadow; pwi->field_390 = field_390; pwi->palette = palette; ++_imagesNum; } else { if (sourceImage != 0) { // TODO } else if (params->processFlags & (kWPFScaled | kWPFRotate)) { drawWizComplexPolygon(params->img.resNum, state, po_x, po_y, shadow, rotationAngle, scale, r, flags, dstResNum, palette); } else { if (flags & kWIFIsPolygon) { drawWizPolygon(params->img.resNum, state, po_x, flags, shadow, dstResNum, palette); // XXX , VAR(VAR_WIZ_TCOLOR)); } else { drawWizImage(params->img.resNum, state, po_x, po_y, params->img.zorder, shadow, field_390, r, flags, dstResNum, palette); } } } } void Wiz::createWizEmptyImage(const WizParameters *params) { debug(1, "ScummEngine_v90he::createWizEmptyImage(%d, %d, %d)", params->img.resNum, params->resDefImgW, params->resDefImgH); int img_w = 640; if (params->processFlags & kWPFUseDefImgWidth) { img_w = params->resDefImgW; } int img_h = 480; if (params->processFlags & kWPFUseDefImgHeight) { img_h = params->resDefImgH; } int img_x = 0; int img_y = 0; if (params->processFlags & 1) { img_x = params->img.x1; img_y = params->img.y1; } const uint16 flags = 0xB; int res_size = 0x1C; if (flags & 1) { res_size += 0x308; } if (flags & 2) { res_size += 0x10; } if (flags & 8) { res_size += 0x10C; } res_size += 8 + img_w * img_h; const uint8 *palPtr; if (_vm->_heversion >= 99) { palPtr = _vm->_hePalettes + 1024; } else { palPtr = _vm->_currentPalette; } uint8 *res_data = _vm->res.createResource(rtImage, params->img.resNum, res_size); if (!res_data) { _vm->VAR(119) = -1; } else { _vm->VAR(119) = 0; WRITE_BE_UINT32(res_data, 'AWIZ'); res_data += 4; WRITE_BE_UINT32(res_data, res_size); res_data += 4; WRITE_BE_UINT32(res_data, 'WIZH'); res_data += 4; WRITE_BE_UINT32(res_data, 0x14); res_data += 4; WRITE_LE_UINT32(res_data, 0); res_data += 4; WRITE_LE_UINT32(res_data, img_w); res_data += 4; WRITE_LE_UINT32(res_data, img_h); res_data += 4; if (flags & 1) { WRITE_BE_UINT32(res_data, 'RGBS'); res_data += 4; WRITE_BE_UINT32(res_data, 0x308); res_data += 4; memcpy(res_data, palPtr, 0x300); res_data += 0x300; } if (flags & 2) { WRITE_BE_UINT32(res_data, 'SPOT'); res_data += 4; WRITE_BE_UINT32(res_data, 0x10); res_data += 4; WRITE_BE_UINT32(res_data, img_x); res_data += 4; WRITE_BE_UINT32(res_data, img_y); res_data += 4; } if (flags & 8) { WRITE_BE_UINT32(res_data, 'RMAP'); res_data += 4; WRITE_BE_UINT32(res_data, 0x10C); res_data += 4; WRITE_BE_UINT32(res_data, 0); res_data += 4; for (int i = 0; i < 256; ++i) { *res_data++ = i; } } WRITE_BE_UINT32(res_data, 'WIZD'); res_data += 4; WRITE_BE_UINT32(res_data, 8 + img_w * img_h); res_data += 4; } } void Wiz::fillWizRect(const WizParameters *params) { int state = 0; if (params->processFlags & kWPFNewState) { state = params->img.state; } uint8 *dataPtr = _vm->getResourceAddress(rtImage, params->img.resNum); if (dataPtr) { uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); int w = READ_LE_UINT32(wizh + 0x4); int h = READ_LE_UINT32(wizh + 0x8); assert(c == 0); Common::Rect r1(w, h); if (params->processFlags & kWPFClipBox) { if (!r1.intersects(params->box)) { return; } r1.clip(params->box); } if (params->processFlags & kWPFClipBox2) { r1.clip(params->box2); } uint8 color = _vm->VAR(93); if (params->processFlags & kWPFFillColor) { color = params->fillColor; } uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), dataPtr, state, 0); assert(wizd); int dx = r1.width(); int dy = r1.height(); wizd += r1.top * w + r1.left; while (dy--) { memset(wizd, color, dx); wizd += w; } } } void Wiz::fillWizLine(const WizParameters *params) { if (params->processFlags & kWPFClipBox2) { int state = 0; if (params->processFlags & kWPFNewState) { state = params->img.state; } uint8 *dataPtr = _vm->getResourceAddress(rtImage, params->img.resNum); if (dataPtr) { uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); int w = READ_LE_UINT32(wizh + 0x4); int h = READ_LE_UINT32(wizh + 0x8); assert(c == 0); Common::Rect r1(w, h); if (params->processFlags & kWPFClipBox) { if (!r1.intersects(params->box)) { return; } r1.clip(params->box); } uint8 color = _vm->VAR(93); if (params->processFlags & kWPFFillColor) { color = params->fillColor; } uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), dataPtr, state, 0); assert(wizd); int x1 = params->box2.left; int y1 = params->box2.top; int x2 = params->box2.right; int y2 = params->box2.bottom; int dx = x2 - x1; int incx = 0; if (dx > 0) { incx = 1; } else if (dx < 0) { incx = -1; } int dy = y2 - y1; int incy = 0; if (dy > 0) { incy = 1; } else if (dy < 0) { incy = -1; } if (r1.contains(x1, y1)) { *(wizd + y1 * w + x1) = color; } if (dx >= dy) { int step1_y = (dy - dx) * 2; int step2_y = dy * 2; int accum_y = dy * 2 - dx; while (x1 != x2) { if (accum_y <= 0) { accum_y += step2_y; } else { accum_y += step1_y; y1 += incy; } x1 += incx; if (r1.contains(x1, y1)) { *(wizd + y1 * w + x1) = color; } } } else { int step1_x = (dx - dy) * 2; int step2_x = dx * 2; int accum_x = dx * 2 - dy; while (y1 != y2) { if (accum_x <= 0) { accum_x += step2_x; } else { accum_x += step1_x; x1 += incx; } y1 += incy; if (r1.contains(x1, y1)) { *(wizd + y1 * w + x1) = color; } } } } } } void Wiz::fillWizPixel(const WizParameters *params) { if (params->processFlags & kWPFClipBox2) { int px = params->box2.left; int py = params->box2.top; uint8 *dataPtr = _vm->getResourceAddress(rtImage, params->img.resNum); if (dataPtr) { int state = 0; if (params->processFlags & kWPFNewState) { state = params->img.state; } uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); int w = READ_LE_UINT32(wizh + 0x4); int h = READ_LE_UINT32(wizh + 0x8); assert(c == 0); Common::Rect imageRect(w, h); if (params->processFlags & kWPFClipBox) { if (!imageRect.intersects(params->box)) { return; } imageRect.clip(params->box); } uint8 color = _vm->VAR(93); if (params->processFlags & kWPFFillColor) { color = params->fillColor; } if (imageRect.contains(px, py)) { uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), dataPtr, state, 0); assert(wizd); *(wizd + py * w + px) = color; } } } } void Wiz::processWizImage(const WizParameters *params) { char buf[512]; unsigned int i; debug(1, "processWizImage: processMode %d", params->processMode); switch (params->processMode) { case 0: // Used in racedemo break; case 1: displayWizComplexImage(params); break; case 2: captureWizImage(params->img.resNum, params->box, (params->img.flags & kWIFBlitToFrontVideoBuffer) != 0, params->compType); break; case 3: if (params->processFlags & kWPFUseFile) { Common::File f; // Convert Windows path separators to something more portable strncpy(buf, (const char *)params->filename, 512); for (i = 0; i < strlen(buf); i++) { if (buf[i] == '\\') buf[i] = '/'; } if (f.open((const char *)buf, Common::File::kFileReadMode)) { uint32 id = f.readUint32LE(); if (id == TO_LE_32(MKID('AWIZ')) || id == TO_LE_32(MKID('MULT'))) { uint32 size = f.readUint32BE(); f.seek(0, SEEK_SET); byte *p = _vm->res.createResource(rtImage, params->img.resNum, size); if (f.read(p, size) != size) { _vm->res.nukeResource(rtImage, params->img.resNum); error("i/o error when reading '%s'", buf); _vm->VAR(_vm->VAR_GAME_LOADED) = -2; _vm->VAR(119) = -2; } else { _vm->res.lock(rtImage, params->img.resNum); _vm->VAR(_vm->VAR_GAME_LOADED) = 0; _vm->VAR(119) = 0; } } else { _vm->VAR(_vm->VAR_GAME_LOADED) = -1; _vm->VAR(119) = -1; } f.close(); } else { _vm->VAR(_vm->VAR_GAME_LOADED) = -3; _vm->VAR(119) = -3; debug(0, "Unable to open for read '%s'", buf); } } break; case 4: if (params->processFlags & kWPFUseFile) { Common::File f; switch(params->fileWriteMode) { case 2: _vm->VAR(119) = -1; break; case 1: // TODO Write image to file break; case 0: // Convert Windows path separators to something more portable strncpy(buf, (const char *)params->filename, 512); for (i = 0; i < strlen(buf); i++) { if (buf[i] == '\\') buf[i] = '/'; } if (!f.open((const char *)buf, Common::File::kFileWriteMode)) { debug(0, "Unable to open for write '%s'", buf); _vm->VAR(119) = -3; } else { byte *p = _vm->getResourceAddress(rtImage, params->img.resNum); uint32 size = READ_BE_UINT32(p + 4); if (f.write(p, size) != size) { error("i/o error when writing '%s'", params->filename); _vm->VAR(119) = -2; } else { _vm->VAR(119) = 0; } f.close(); } break; default: error("processWizImage: processMode 4 unhandled fileWriteMode %d", params->fileWriteMode); } } break; case 6: if (params->processFlags & kWPFRemapPalette) { int state = (params->processFlags & kWPFNewState) ? params->img.state : 0; int num = params->remapNum; const uint8 *index = params->remapIndex; uint8 *iwiz = _vm->getResourceAddress(rtImage, params->img.resNum); assert(iwiz); uint8 *rmap = _vm->findWrappedBlock(MKID('RMAP'), iwiz, state, 0) ; assert(rmap); WRITE_BE_UINT32(rmap, 0x01234567); while (num--) { uint8 idx = *index++; rmap[4 + idx] = params->remapColor[idx]; } } break; // HE 99+ case 7: // Used in PuttsFunShop/SamsFunShop/soccer2004 // TODO: Capture polygon break; case 8: createWizEmptyImage(params); break; case 9: fillWizRect(params); break; case 10: fillWizLine(params); break; case 11: fillWizPixel(params); break; case 12: // Used in PuttsFunShop/SamsFunShop // TODO: Flood Fill break; case 13: // Used in PuttsFunShop/SamsFunShop // TODO: Start Font break; case 14: // Used in PuttsFunShop/SamsFunShop // TODO: End Font break; case 15: // Used in PuttsFunShop/SamsFunShop // TODO: Create Font break; case 16: // TODO: Render Font String error("Render Font String"); break; case 17: // Used in PuttsFunShop/SamsFunShop // TODO: Ellipse break; default: error("Unhandled processWizImage mode %d", params->processMode); } } int Wiz::getWizImageData(int resNum, int state, int type) { uint8 *dataPtr, *wizh; dataPtr = _vm->getResourceAddress(rtImage, resNum); assert(dataPtr); switch (type) { case 0: wizh = _vm->findWrappedBlock(MKID('WIZH'), dataPtr, state, 0); assert(wizh); return READ_LE_UINT32(wizh + 0x0); case 1: return (_vm->findWrappedBlock(MKID('RGBS'), dataPtr, state, 0) != NULL) ? 1 : 0; case 2: return (_vm->findWrappedBlock(MKID('RMAP'), dataPtr, state, 0) != NULL) ? 1 : 0; case 3: return (_vm->findWrappedBlock(MKID('TRNS'), dataPtr, state, 0) != NULL) ? 1 : 0; case 4: return (_vm->findWrappedBlock(MKID('XMAP'), dataPtr, state, 0) != NULL) ? 1 : 0; default: error("getWizImageData: Unknown type %d", type); } } int Wiz::getWizImageStates(int resNum) { const uint8 *dataPtr = _vm->getResourceAddress(rtImage, resNum); assert(dataPtr); if (READ_UINT32(dataPtr) == MKID('MULT')) { const byte *offs, *wrap; wrap = _vm->findResource(MKID('WRAP'), dataPtr); if (wrap == NULL) return 1; offs = _vm->findResourceData(MKID('OFFS'), wrap); if (offs == NULL) return 1; return _vm->getResourceDataSize(offs) / 4; } else { return 1; } } int Wiz::isWizPixelNonTransparent(int resNum, int state, int x, int y, int flags) { int ret = 0; uint8 *data = _vm->getResourceAddress(rtImage, resNum); assert(data); uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), data, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); int w = READ_LE_UINT32(wizh + 0x4); int h = READ_LE_UINT32(wizh + 0x8); uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), data, state, 0); assert(wizd); if (x >= 0 && x < w && y >= 0 && y < h) { if (flags & kWIFFlipX) { x = w - x - 1; } if (flags & kWIFFlipY) { y = h - y - 1; } switch (c) { case 0: ret = getRawWizPixelColor(wizd, x, y, w, h, _vm->VAR(_vm->VAR_WIZ_TCOLOR)) != _vm->VAR(_vm->VAR_WIZ_TCOLOR) ? 1 : 0; break; case 1: ret = isWizPixelNonTransparent(wizd, x, y, w, h); break; case 2: // Used baseball2003 debug(0, "isWizPixelNonTransparent: Unhandled wiz compression type %d", c); break; default: error("isWizPixelNonTransparent: Unhandled wiz compression type %d", c); break; } } return ret; } uint8 Wiz::getWizPixelColor(int resNum, int state, int x, int y, int flags) { uint8 color; uint8 *data = _vm->getResourceAddress(rtImage, resNum); assert(data); uint8 *wizh = _vm->findWrappedBlock(MKID('WIZH'), data, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); int w = READ_LE_UINT32(wizh + 0x4); int h = READ_LE_UINT32(wizh + 0x8); uint8 *wizd = _vm->findWrappedBlock(MKID('WIZD'), data, state, 0); assert(wizd); switch (c) { case 0: color = getRawWizPixelColor(wizd, x, y, w, h, _vm->VAR(_vm->VAR_WIZ_TCOLOR)); break; case 1: color = getWizPixelColor(wizd, x, y, w, h, _vm->VAR(_vm->VAR_WIZ_TCOLOR)); break; default: error("getWizPixelColor: Unhandled wiz compression type %d", c); break; } return color; } int ScummEngine_v90he::computeWizHistogram(int resNum, int state, int x, int y, int w, int h) { writeVar(0, 0); defineArray(0, kDwordArray, 0, 0, 0, 255); if (readVar(0) != 0) { Common::Rect rCapt(x, y, w + 1, h + 1); uint8 *data = getResourceAddress(rtImage, resNum); assert(data); uint8 *wizh = findWrappedBlock(MKID('WIZH'), data, state, 0); assert(wizh); int c = READ_LE_UINT32(wizh + 0x0); w = READ_LE_UINT32(wizh + 0x4); h = READ_LE_UINT32(wizh + 0x8); Common::Rect rWiz(w, h); uint8 *wizd = findWrappedBlock(MKID('WIZD'), data, state, 0); assert(wizd); if (rCapt.intersects(rWiz)) { rCapt.clip(rWiz); uint32 histogram[256]; memset(histogram, 0, sizeof(histogram)); switch (c) { case 0: _wiz->computeRawWizHistogram(histogram, wizd, w, rCapt); break; case 1: _wiz->computeWizHistogram(histogram, wizd, rCapt); break; default: error("computeWizHistogram: Unhandled wiz compression type %d", c); break; } for (int i = 0; i < 256; ++i) { writeArray(0, 0, i, histogram[i]); } } } return readVar(0); } } // End of namespace Scumm