/* ScummVM - Scumm Interpreter * Copyright (C) 2004-2005 The ScummVM project * * The ReInherit Engine is (C)2000-2003 by Daniel Balsom. * * 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * * $Header$ * */ // Background animation management module #include "saga/saga.h" #include "saga/gfx.h" #include "saga/console.h" #include "saga/events.h" #include "saga/interface.h" #include "saga/render.h" #include "saga/rscfile.h" #include "saga/scene.h" #include "saga/animation.h" namespace Saga { Anim::Anim(SagaEngine *vm) : _vm(vm) { uint16 i; _cutawayList = NULL; _cutawayListLength = 0; _cutawayActive = false; for (i = 0; i < MAX_ANIMATIONS; i++) _animations[i] = NULL; for (i = 0; i < ARRAYSIZE(_cutawayAnimations); i++) _cutawayAnimations[i] = NULL; } Anim::~Anim(void) { reset(); } void Anim::loadCutawayList(const byte *resourcePointer, size_t resourceLength) { free(_cutawayList); _cutawayListLength = resourceLength / 8; _cutawayList = (Cutaway *)malloc(_cutawayListLength * sizeof(Cutaway)); MemoryReadStream cutawayS(resourcePointer, resourceLength); for (int i = 0; i < _cutawayListLength; i++) { _cutawayList[i].backgroundResourceId = cutawayS.readUint16LE(); _cutawayList[i].animResourceId = cutawayS.readUint16LE(); _cutawayList[i].cycles = cutawayS.readSint16LE(); _cutawayList[i].frameRate = cutawayS.readSint16LE(); } } void Anim::freeCutawayList(void) { free(_cutawayList); _cutawayList = NULL; _cutawayListLength = 0; } void Anim::playCutaway(int cut, bool fade) { debug(0, "playCutaway(%d, %d)", cut, fade); if (fade) { // TODO: Fade down. Is this blocking or non-blocking? } if (!_cutawayActive) { _vm->_gfx->showCursor(false); _vm->_interface->setStatusText(""); _vm->_interface->setSaveReminderState(0); _vm->_interface->rememberMode(); _vm->_interface->setMode(kPanelCutaway); _cutawayActive = true; } // Set the initial background and palette for the cutaway ResourceContext *context = _vm->_resource->getContext(GAME_RESOURCEFILE); byte *resourceData; size_t resourceDataLength; _vm->_resource->loadResource(context, _cutawayList[cut].backgroundResourceId, resourceData, resourceDataLength); byte *buf; size_t buflen; int width; int height; _vm->decodeBGImage(resourceData, resourceDataLength, &buf, &buflen, &width, &height); const PalEntry *palette = (const PalEntry *)_vm->getImagePal(resourceData, resourceDataLength); Surface *bgSurface = _vm->_render->getBackGroundSurface(); const Rect rect(width, height); bgSurface->blit(rect, buf); _vm->_gfx->setPalette(palette); free(buf); free(resourceData); // Play the animation int cutawaySlot = -1; for (int i = 0; i < ARRAYSIZE(_cutawayAnimations); i++) { if (!_cutawayAnimations[i]) { cutawaySlot = i; } else if (_cutawayAnimations[i]->state == ANIM_PAUSE) { delete _cutawayAnimations[i]; _cutawayAnimations[i] = NULL; cutawaySlot = i; } else if (_cutawayAnimations[i]->state == ANIM_PLAYING) { _cutawayAnimations[i]->state = ANIM_PAUSE; } } if (cutawaySlot == -1) { warning("Could not allocate cutaway animation slot"); return; } _vm->_resource->loadResource(context, _cutawayList[cut].animResourceId, resourceData, resourceDataLength); load(MAX_ANIMATIONS + cutawaySlot, resourceData, resourceDataLength); free(resourceData); setCycles(MAX_ANIMATIONS + cutawaySlot, _cutawayList[cut].cycles); setFrameTime(MAX_ANIMATIONS + cutawaySlot, 1000 / _cutawayList[cut].frameRate); play(MAX_ANIMATIONS + cutawaySlot, 0); } void Anim::endCutaway(void) { // I believe this is called by scripts after running one cutaway. At // this time, nothing needs to be done here. debug(0, "endCutaway()"); } void Anim::returnFromCutaway(void) { // I believe this is called by scripts after running a cutaway to // ensure that we return to the scene as if nothing had happened. It's // not called by the IHNM intro, presumably because there is no old // scene to return to. debug(0, "returnFromCutaway()"); if (_cutawayActive) { // Note that clearCutaway() sets _cutawayActive to false. clearCutaway(); // TODO: Handle fade up, if we previously faded down // TODO: Restore the scene // TODO: Restore the animations for (int i = 0; i < MAX_ANIMATIONS; i++) { if (_animations[i] && _animations[i]->state == ANIM_PLAYING) { resume(i, 0); } } } } void Anim::clearCutaway(void) { debug(0, "clearCutaway()\n"); if (_cutawayActive) { _cutawayActive = false; for (int i = 0; i < ARRAYSIZE(_cutawayAnimations); i++) { delete _cutawayAnimations[i]; _cutawayAnimations[i] = NULL; } _vm->_interface->restoreMode(); _vm->_gfx->showCursor(true); } } void Anim::load(uint16 animId, const byte *animResourceData, size_t animResourceLength) { AnimationData *anim; uint16 temp; if (animId >= MAX_ANIMATIONS) { if (animId >= MAX_ANIMATIONS + ARRAYSIZE(_cutawayAnimations)) error("Anim::load could not find unused animation slot"); anim = _cutawayAnimations[animId - MAX_ANIMATIONS] = new AnimationData(animResourceData, animResourceLength); } else anim = _animations[animId] = new AnimationData(animResourceData, animResourceLength); MemoryReadStreamEndian headerReadS(anim->resourceData, anim->resourceLength, _vm->isBigEndian()); anim->magic = headerReadS.readUint16LE(); // cause ALWAYS LE anim->screenWidth = headerReadS.readUint16(); anim->screenHeight = headerReadS.readUint16(); anim->unknown06 = headerReadS.readByte(); anim->unknown07 = headerReadS.readByte(); anim->maxFrame = headerReadS.readByte() - 1; anim->loopFrame = headerReadS.readByte() - 1; temp = headerReadS.readUint16BE(); anim->start = headerReadS.pos(); if (temp == (uint16)(-1)) { temp = 0; } anim->start += temp; // Cache frame offsets anim->frameOffsets = (size_t *)malloc((anim->maxFrame + 1) * sizeof(*anim->frameOffsets)); if (anim->frameOffsets == NULL) { memoryError("Anim::load"); } fillFrameOffsets(anim); /* char s[200]; sprintf(s, "d:\\anim%i",animId); long flen=anim->resourceLength; char *buf=(char*)anim->resourceData; FILE*f; f=fopen(s,"wb"); for(long i=0;icurrentFrame = 0; anim->completed = 0; anim->cycles = anim->maxFrame; anim->frameTime = DEFAULT_FRAME_TIME; anim->flags = ANIM_FLAG_NONE; anim->linkId = -1; anim->state = ANIM_PAUSE; } void Anim::link(int16 animId1, int16 animId2) { AnimationData *anim1; AnimationData *anim2; anim1 = getAnimation(animId1); anim1->linkId = animId2; if (animId2 == -1) { return; } anim2 = getAnimation(animId2); anim2->frameTime = anim1->frameTime; } void Anim::setCycles(uint16 animId, int cycles) { AnimationData *anim; anim = getAnimation(animId); anim->cycles = cycles; } void Anim::play(uint16 animId, int vectorTime, bool playing) { Event event; Surface *backGroundSurface; byte *displayBuffer; uint16 frame; int frameTime; AnimationData *anim; AnimationData *linkAnim; if (animId > MAX_ANIMATIONS && !_cutawayActive) return; if (animId < MAX_ANIMATIONS && _cutawayActive) return; anim = getAnimation(animId); backGroundSurface = _vm->_render->getBackGroundSurface(); displayBuffer = (byte*)backGroundSurface->pixels; if (playing) { anim->state = ANIM_PLAYING; } if (anim->state == ANIM_PAUSE) { return; } if (anim->completed < anim->cycles) { frame = anim->currentFrame; // FIXME: if start > 0, then this works incorrectly decodeFrame(anim, anim->frameOffsets[frame], displayBuffer, _vm->getDisplayWidth() * _vm->getDisplayHeight()); anim->currentFrame++; if (anim->completed != 65535) { anim->completed++; } if (anim->currentFrame > anim->maxFrame) { anim->currentFrame = anim->loopFrame; if (anim->state == ANIM_STOPPING || anim->currentFrame == -1) { anim->state = ANIM_PAUSE; } } } else { // Animation done playing anim->state = ANIM_PAUSE; if (anim->linkId == -1) { if (anim->flags & ANIM_FLAG_ENDSCENE) { // This animation ends the scene event.type = kEvTOneshot; event.code = kSceneEvent; event.op = kEventEnd; event.time = anim->frameTime + vectorTime; _vm->_events->queue(&event); } return; } } if (anim->state == ANIM_PAUSE && anim->linkId != -1) { // If this animation has a link, follow it linkAnim = getAnimation(anim->linkId); debug(5, "Animation ended going to %d", anim->linkId); // linkAnim->cycles = anim->cycles; // linkAnim->currentFrame = 0; // linkAnim->completed = 0; linkAnim->state = ANIM_PLAYING; animId = anim->linkId; frameTime = 0; } else { frameTime = anim->frameTime + vectorTime; } event.type = kEvTOneshot; event.code = kAnimEvent; event.op = kEventFrame; event.param = animId; event.time = frameTime; _vm->_events->queue(&event); } void Anim::stop(uint16 animId) { AnimationData *anim; anim = getAnimation(animId); anim->state = ANIM_PAUSE; } void Anim::finish(uint16 animId) { AnimationData *anim; anim = getAnimation(animId); anim->state = ANIM_STOPPING; } void Anim::resume(uint16 animId, int cycles) { AnimationData *anim; anim = getAnimation(animId); anim->cycles += cycles; play(animId, 0, true); } void Anim::reset() { uint16 i; for (i = 0; i < MAX_ANIMATIONS; i++) { if (_animations[i] != NULL) { delete _animations[i]; _animations[i] = NULL; } } for (i = 0; i < ARRAYSIZE(_cutawayAnimations); i++) { if (_cutawayAnimations[i] != NULL) { delete _cutawayAnimations[i]; _cutawayAnimations[i] = NULL; } } } void Anim::setFlag(uint16 animId, uint16 flag) { AnimationData *anim; anim = getAnimation(animId); anim->flags |= flag; } void Anim::clearFlag(uint16 animId, uint16 flag) { AnimationData *anim; anim = getAnimation(animId); anim->flags &= ~flag; } void Anim::setFrameTime(uint16 animId, int time) { AnimationData *anim; anim = getAnimation(animId); anim->frameTime = time; } int16 Anim::getCurrentFrame(uint16 animId) { AnimationData *anim; anim = getAnimation(animId); return anim->currentFrame; } void Anim::decodeFrame(AnimationData *anim, size_t frameOffset, byte *buf, size_t bufLength) { byte *writePointer = NULL; uint16 xStart = 0; uint16 yStart = 0; uint32 screenWidth; uint32 screenHeight; int markByte; byte dataByte; int newRow; uint16 controlChar; uint16 paramChar; uint16 runcount; int xVector; uint16 i; bool longData = isLongData(); screenWidth = anim->screenWidth; screenHeight = anim->screenHeight; if ((screenWidth * screenHeight) > bufLength) { // Buffer argument is too small to hold decoded frame, abort. error("decodeFrame() Buffer size inadequate"); } MemoryReadStream readS(anim->resourceData + frameOffset, anim->resourceLength - frameOffset); #if 1 #define VALIDATE_WRITE_POINTER \ if ((writePointer < buf) || (writePointer >= (buf + screenWidth * screenHeight))) { \ error("VALIDATE_WRITE_POINTER: writePointer=%x buf=%x", writePointer, buf); \ } #else #define VALIDATE_WRITE_POINTER #endif // Begin RLE decompression to output buffer do { markByte = readS.readByte(); switch (markByte) { case SAGA_FRAME_START: xStart = readS.readUint16BE(); if (longData) yStart = readS.readUint16BE(); else yStart = readS.readByte(); readS.readByte(); /* Skip pad byte */ /*xPos = */readS.readUint16BE(); /*yPos = */readS.readUint16BE(); /*width = */readS.readUint16BE(); /*height = */readS.readUint16BE(); // Setup write pointer to the draw origin writePointer = (buf + (yStart * screenWidth) + xStart); VALIDATE_WRITE_POINTER; continue; break; case SAGA_FRAME_NOOP: // Does nothing readS.readByte(); readS.readByte(); readS.readByte(); continue; break; case SAGA_FRAME_LONG_UNCOMPRESSED_RUN: // Long Unencoded Run runcount = readS.readSint16BE(); for (i = 0; i < runcount; i++) { dataByte = readS.readByte(); if (dataByte != 0) { *writePointer = dataByte; } writePointer++; VALIDATE_WRITE_POINTER; } continue; break; case SAGA_FRAME_LONG_COMPRESSED_RUN: // Long encoded run runcount = readS.readSint16BE(); dataByte = readS.readByte(); for (i = 0; i < runcount; i++) { *writePointer++ = dataByte; VALIDATE_WRITE_POINTER; } continue; break; case SAGA_FRAME_ROW_END: // End of row xVector = readS.readSint16BE(); if (longData) newRow = readS.readSint16BE(); else newRow = readS.readByte(); // Set write pointer to the new draw origin writePointer = buf + ((yStart + newRow) * screenWidth) + xStart + xVector; VALIDATE_WRITE_POINTER; continue; break; case SAGA_FRAME_REPOSITION: // Reposition command xVector = readS.readSint16BE(); writePointer += xVector; VALIDATE_WRITE_POINTER; continue; break; case SAGA_FRAME_END: // End of frame marker return; break; default: break; } // Mask all but two high order control bits controlChar = markByte & 0xC0U; paramChar = markByte & 0x3FU; switch (controlChar) { case SAGA_FRAME_EMPTY_RUN: // 1100 0000 // Run of empty pixels runcount = paramChar + 1; writePointer += runcount; VALIDATE_WRITE_POINTER; continue; break; case SAGA_FRAME_COMPRESSED_RUN: // 1000 0000 // Run of compressed data runcount = paramChar + 1; dataByte = readS.readByte(); for (i = 0; i < runcount; i++) { *writePointer++ = dataByte; VALIDATE_WRITE_POINTER; } continue; break; case SAGA_FRAME_UNCOMPRESSED_RUN: // 0100 0000 // Uncompressed run runcount = paramChar + 1; for (i = 0; i < runcount; i++) { dataByte = readS.readByte(); if (dataByte != 0) { *writePointer = dataByte; } writePointer++; VALIDATE_WRITE_POINTER; } continue; break; default: // Unknown marker found - abort error("decodeFrame() Invalid RLE marker encountered"); break; } } while (1); } void Anim::fillFrameOffsets(AnimationData *anim) { uint16 currentFrame; byte markByte; uint16 control; uint16 runcount; int i; bool longData = isLongData(); MemoryReadStreamEndian readS(anim->resourceData, anim->resourceLength, _vm->isBigEndian()); readS.seek(12); readS._bigEndian = !_vm->isBigEndian(); // RLE has inversion BE<>LE for (currentFrame = 0; currentFrame <= anim->maxFrame; currentFrame++) { anim->frameOffsets[currentFrame] = readS.pos(); // For some strange reason, the animation header is in little // endian format, but the actual RLE encoded frame data, // including the frame header, is in big endian format. */ do { markByte = readS.readByte(); // debug(7, "_pos=%x currentFrame=%i markByte=%x", readS.pos(), currentFrame, markByte); switch (markByte) { case SAGA_FRAME_START: // Start of frame // skip header if (longData) { readS.seek(13, SEEK_CUR); } else { readS.seek(12, SEEK_CUR); } continue; break; case SAGA_FRAME_END: // End of frame marker continue; break; case SAGA_FRAME_REPOSITION: // Reposition command readS.readSint16BE(); continue; break; case SAGA_FRAME_ROW_END: // End of row marker readS.readSint16BE(); if (longData) readS.readSint16BE(); else readS.readByte(); continue; break; case SAGA_FRAME_LONG_COMPRESSED_RUN: // Long compressed run marker readS.readSint16BE(); readS.readByte(); continue; break; case SAGA_FRAME_LONG_UNCOMPRESSED_RUN: // (16) 0001 0000 // Long Uncompressed Run runcount = readS.readSint16BE(); for (i = 0; i < runcount; i++) readS.readByte(); continue; break; case SAGA_FRAME_NOOP: // Does nothing readS.readByte(); readS.readByte(); readS.readByte(); continue; break; default: break; } // Mask all but two high order (control) bits control = markByte & 0xC0; switch (control) { case SAGA_FRAME_EMPTY_RUN: // Run of empty pixels continue; break; case SAGA_FRAME_COMPRESSED_RUN: // Run of compressed data readS.readByte(); // Skip data byte continue; break; case SAGA_FRAME_UNCOMPRESSED_RUN: // Uncompressed run runcount = (markByte & 0x3f) + 1; for (i = 0; i < runcount; i++) readS.readByte(); continue; break; default: error("Encountered unknown RLE marker %i", markByte); break; } } while (markByte != SAGA_FRAME_END); } } void Anim::animInfo() { uint16 animCount; uint16 i; animCount = getAnimationCount(); _vm->_console->DebugPrintf("There are %d animations loaded:\n", animCount); for (i = 0; i < MAX_ANIMATIONS; i++) { if (_animations[i] == NULL) { continue; } _vm->_console->DebugPrintf("%02d: Frames: %u Flags: %u\n", i, _animations[i]->maxFrame, _animations[i]->flags); } } } // End of namespace Saga