/* 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. * */ #include "audio/mixer.h" // for Audio::Mixer::kSFXSoundType #include "common/config-manager.h" // for ConfMan #include "common/textconsole.h" // for warning, error #ifndef USE_RGB_COLOR #include "common/translation.h" // for _ #endif #include "common/util.h" // for ARRAYSIZE #include "common/system.h" // for g_system #include "engine.h" // for Engine, g_engine #include "graphics/colormasks.h" // for createPixelFormat #include "graphics/palette.h" // for PaletteManager #include "graphics/transparent_surface.h" // for TransparentSurface #include "sci/console.h" // for Console #include "sci/engine/features.h" // for GameFeatures #include "sci/engine/state.h" // for EngineState #include "sci/engine/vm_types.h" // for reg_t #include "sci/event.h" // for SciEvent, EventManager, SCI_... #include "sci/graphics/celobj32.h" // for CelInfo32, ::kLowResX, ::kLo... #include "sci/graphics/cursor32.h" // for GfxCursor32 #include "sci/graphics/frameout.h" // for GfxFrameout #include "sci/graphics/helpers.h" // for Color, Palette #include "sci/graphics/palette32.h" // for GfxPalette32 #include "sci/graphics/plane32.h" // for Plane, PlanePictureCodes::kP... #include "sci/graphics/screen_item32.h" // for ScaleInfo, ScreenItem, Scale... #include "sci/resource.h" // for ResourceManager, ResourceId,... #include "sci/sci.h" // for SciEngine, g_sci, getSciVersion #include "sci/sound/audio32.h" // for Audio32 #include "sci/video/seq_decoder.h" // for SEQDecoder #include "video/avi_decoder.h" // for AVIDecoder #include "video/coktel_decoder.h" // for AdvancedVMDDecoder #include "sci/graphics/video32.h" namespace Graphics { struct Surface; } namespace Sci { bool VideoPlayer::open(const Common::String &fileName) { if (!_decoder->loadFile(fileName)) { warning("Failed to load %s", fileName.c_str()); return false; } #ifndef USE_RGB_COLOR // KQ7 2.00b videos are compressed in 24bpp Cinepak, so cannot play on // a system with no RGB support if (_decoder->getPixelFormat().bytesPerPixel != 1) { void showScummVMDialog(const Common::String &message); showScummVMDialog(Common::String::format(_("Cannot play back %dbpp video on a system with maximum color depth of 8bpp"), _decoder->getPixelFormat().bpp())); _decoder->close(); return false; } #endif return true; } bool VideoPlayer::startHQVideo() { #ifdef USE_RGB_COLOR // Optimize rendering performance for unscaled videos, and allow // better-than-NN interpolation for videos that are scaled if (shouldStartHQVideo()) { // TODO: Search for and use the best supported format (which may be // lower than 32bpp) once the scaling code in Graphics supports // 16bpp/24bpp, and once the SDL backend can correctly communicate // supported pixel formats above whatever format is currently used by // _hwsurface. Right now, this will either show an error dialog (OpenGL) // or just crash entirely (SDL) if the backend does not support this // 32bpp pixel format, which sucks since this code really ought to be // able to fall back to NN scaling for games with 256-color videos // without any error. const Graphics::PixelFormat format(4, 8, 8, 8, 8, 24, 16, 8, 0); g_sci->_gfxFrameout->setPixelFormat(format); _hqVideoMode = (g_system->getScreenFormat() == format); return _hqVideoMode; } else { _hqVideoMode = false; } #endif return false; } bool VideoPlayer::endHQVideo() { #ifdef USE_RGB_COLOR if (g_system->getScreenFormat().bytesPerPixel != 1) { const Graphics::PixelFormat format = Graphics::PixelFormat::createFormatCLUT8(); g_sci->_gfxFrameout->setPixelFormat(format); assert(g_system->getScreenFormat() == format); _hqVideoMode = false; return true; } #endif return false; } VideoPlayer::EventFlags VideoPlayer::playUntilEvent(const EventFlags flags, const uint32 maxSleepMs) { // Flushing all the keyboard and mouse events out of the event manager // keeps events queued from before the start of playback from accidentally // activating a video stop flag _eventMan->flushEvents(); _decoder->start(); EventFlags stopFlag = kEventFlagNone; for (;;) { g_sci->sleep(MIN(_decoder->getTimeToNextFrame(), maxSleepMs)); const Graphics::Surface *nextFrame = nullptr; // If a decoder needs more than one update per loop, this means we are // running behind and should skip rendering these frames (but must still // submit any palettes from skipped frames) while (_decoder->needsUpdate()) { nextFrame = _decoder->decodeNextFrame(); if (_decoder->hasDirtyPalette()) { submitPalette(_decoder->getPalette()); } } // Some frames may contain only audio and/or palette data; this occurs // with Duck videos and is not an error if (nextFrame) { renderFrame(*nextFrame); } // Event checks must only happen *after* the decoder is updated (1) and // frame rendered (2), otherwise (1) interval yields will get stuck // forever on the current frame, and (2) other events will end up // dropping the new frame entirely stopFlag = checkForEvent(flags); if (stopFlag != kEventFlagNone) { break; } // Only call to update the screen after the event check, otherwise // whatever the game scripts try to change when the player yields to // them will not make it into the hardware buffer until the next tick g_sci->_gfxFrameout->updateScreen(); } return stopFlag; } VideoPlayer::EventFlags VideoPlayer::checkForEvent(const EventFlags flags) { if (g_engine->shouldQuit() || _decoder->endOfVideo()) { return kEventFlagEnd; } SciEvent event = _eventMan->getSciEvent(kSciEventMousePress | kSciEventPeek); if ((flags & kEventFlagMouseDown) && event.type == kSciEventMousePress) { return kEventFlagMouseDown; } event = _eventMan->getSciEvent(kSciEventKeyDown | kSciEventPeek); if ((flags & kEventFlagEscapeKey) && event.type == kSciEventKeyDown) { if (getSciVersion() < SCI_VERSION_3) { while ((event = _eventMan->getSciEvent(kSciEventKeyDown)), event.type != kSciEventNone) { if (event.character == kSciKeyEsc) { return kEventFlagEscapeKey; } } } else if (event.character == kSciKeyEsc) { return kEventFlagEscapeKey; } } return kEventFlagNone; } void VideoPlayer::submitPalette(const uint8 palette[256 * 3]) const { #ifdef USE_RGB_COLOR if (g_system->getScreenFormat().bytesPerPixel != 1) { return; } #endif assert(palette); g_system->getPaletteManager()->setPalette(palette, 0, 256); // KQ7 1.x has videos encoded using Microsoft Video 1 where palette 0 is // white and 255 is black, which is basically the opposite of DOS/Win // SCI palettes. So, when drawing to an 8bpp hwscreen, whenever a new // palette is seen, the screen must be re-filled with the new black // entry to ensure areas outside the video are always black and not some // other color for (int color = 0; color < 256; ++color) { if (palette[0] == 0 && palette[1] == 0 && palette[2] == 0) { g_system->fillScreen(color); break; } palette += 3; } } void VideoPlayer::renderFrame(const Graphics::Surface &nextFrame) const { bool freeConvertedFrame; Graphics::Surface *convertedFrame; // Avoid creating a duplicate copy of the surface when it is not necessary if (_decoder->getPixelFormat() == g_system->getScreenFormat()) { freeConvertedFrame = false; convertedFrame = const_cast(&nextFrame); } else { freeConvertedFrame = true; convertedFrame = nextFrame.convertTo(g_system->getScreenFormat(), _decoder->getPalette()); } assert(convertedFrame); if (_decoder->getWidth() != _drawRect.width() || _decoder->getHeight() != _drawRect.height()) { Graphics::Surface *const unscaledFrame(convertedFrame); // TODO: The only reason TransparentSurface is used here because it is // where common scaler code is right now. const Graphics::TransparentSurface tsUnscaledFrame(*unscaledFrame); #ifdef USE_RGB_COLOR if (_hqVideoMode) { convertedFrame = tsUnscaledFrame.scaleT(_drawRect.width(), _drawRect.height()); } else { #elif 1 { #else } #endif convertedFrame = tsUnscaledFrame.scaleT(_drawRect.width(), _drawRect.height()); } assert(convertedFrame); if (freeConvertedFrame) { unscaledFrame->free(); delete unscaledFrame; } freeConvertedFrame = true; } g_system->copyRectToScreen(convertedFrame->getPixels(), convertedFrame->pitch, _drawRect.left, _drawRect.top, _drawRect.width(), _drawRect.height()); g_sci->_gfxFrameout->updateScreen(); if (freeConvertedFrame) { convertedFrame->free(); delete convertedFrame; } } template void VideoPlayer::renderLQToSurface(Graphics::Surface &out, const Graphics::Surface &nextFrame, const bool doublePixels, const bool blackLines) const { const int lineCount = blackLines ? 2 : 1; if (doublePixels) { for (int16 y = 0; y < nextFrame.h * 2; y += lineCount) { const PixelType *source = (const PixelType *)nextFrame.getBasePtr(0, y >> 1); PixelType *target = (PixelType *)out.getBasePtr(0, y); for (int16 x = 0; x < nextFrame.w; ++x) { *target++ = *source; *target++ = *source++; } } } else if (blackLines) { for (int16 y = 0; y < nextFrame.h; y += lineCount) { const PixelType *source = (const PixelType *)nextFrame.getBasePtr(0, y); PixelType *target = (PixelType *)out.getBasePtr(0, y); memcpy(target, source, out.w * sizeof(PixelType)); } } else { out.copyRectToSurface(nextFrame.getPixels(), nextFrame.pitch, 0, 0, nextFrame.w, nextFrame.h); } } void VideoPlayer::setDrawRect(const int16 x, const int16 y, const int16 width, const int16 height) { _drawRect = Common::Rect(x, y, x + width, y + height); if (_drawRect.right > g_system->getWidth() || _drawRect.bottom > g_system->getHeight()) { warning("Draw rect (%d, %d, %d, %d) is out of bounds of the screen; clipping it", PRINT_RECT(_drawRect)); _drawRect.clip(g_system->getWidth(), g_system->getHeight()); } } #pragma mark SEQPlayer SEQPlayer::SEQPlayer(EventManager *eventMan) : VideoPlayer(eventMan) {} void SEQPlayer::play(const Common::String &fileName, const int16 numTicks, const int16, const int16) { _decoder.reset(new SEQDecoder(numTicks)); if (!VideoPlayer::open(fileName)) { _decoder.reset(); return; } const int16 scriptWidth = g_sci->_gfxFrameout->getCurrentBuffer().scriptWidth; const int16 scriptHeight = g_sci->_gfxFrameout->getCurrentBuffer().scriptHeight; const int16 screenWidth = g_sci->_gfxFrameout->getCurrentBuffer().screenWidth; const int16 screenHeight = g_sci->_gfxFrameout->getCurrentBuffer().screenHeight; const int16 scaledWidth = (_decoder->getWidth() * Ratio(screenWidth, scriptWidth)).toInt(); const int16 scaledHeight = (_decoder->getHeight() * Ratio(screenHeight, scriptHeight)).toInt(); // Normally we would use the coordinates passed into the play function // to position the video, but since we are scaling the video (which SSCI // did not do), the coordinates are not correct. Since videos are always // intended to play in the center of the screen, we just recalculate the // origin here. _drawRect.left = (screenWidth - scaledWidth) / 2; _drawRect.top = (screenHeight - scaledHeight) / 2; _drawRect.setWidth(scaledWidth); _drawRect.setHeight(scaledHeight); startHQVideo(); playUntilEvent(kEventFlagMouseDown | kEventFlagEscapeKey); endHQVideo(); g_system->fillScreen(0); _decoder.reset(); } #pragma mark - #pragma mark AVIPlayer AVIPlayer::AVIPlayer(EventManager *eventMan) : VideoPlayer(eventMan, new Video::AVIDecoder()), _status(kAVINotOpen) { _decoder->setSoundType(Audio::Mixer::kSFXSoundType); } AVIPlayer::IOStatus AVIPlayer::open(const Common::String &fileName) { if (_status != kAVINotOpen) { close(); } if (!VideoPlayer::open(fileName)) { return kIOFileNotFound; } _status = kAVIOpen; return kIOSuccess; } AVIPlayer::IOStatus AVIPlayer::init(const bool doublePixels) { // Calls to initialize the AVI player in SCI can be made in a few ways: // // * kShowMovie(WinInit, x, y) to render the video at (x,y) using its // original resolution, or // * kShowMovie(WinInit, x, y, w, h) to render the video at (x,y) with // rescaling to the given width and height, or // * kShowMovie(WinInitDouble, x, y) to render the video at (x,y) with // rescaling to double the original resolution. // // Unfortunately, the values passed by game scripts are frequently wrong: // // * KQ7 passes origin coordinates that cause videos to be misaligned on the // Y-axis; // * GK1 passes width and height that change the aspect ratio of the videos, // even though they were rendered with square pixels (and in the case of // CREDITS.AVI, cause the video to be badly downscaled); // * The GK2 demo does all of these things at the same time. // // Fortunately, whenever all of these games play an AVI, they are just // trying to play a video at the center of the screen. So, we ignore the // values that the game sends, and instead calculate the correct dimensions // and origin based on the video data, only allowing games to specify // whether or not the videos should be scaled up 2x. if (_status == kAVINotOpen) { return kIOFileNotFound; } g_sci->_gfxCursor32->hide(); int16 width = _decoder->getWidth(); int16 height = _decoder->getHeight(); if (doublePixels) { width *= 2; height *= 2; } const int16 screenWidth = g_sci->_gfxFrameout->getCurrentBuffer().screenWidth; const int16 screenHeight = g_sci->_gfxFrameout->getCurrentBuffer().screenHeight; // When scaling videos, they must not grow larger than the hardware screen // or else the engine will crash. This is particularly important for the GK1 // CREDITS.AVI since the game sends extra width/height arguments, causing it // to be treated as needing upscaling even though it does not. width = MIN(width, screenWidth); height = MIN(height, screenHeight); _drawRect.left = (screenWidth - width) / 2; _drawRect.top = (screenHeight - height) / 2; _drawRect.setWidth(width); _drawRect.setHeight(height); if (!startHQVideo() && _decoder->getPixelFormat().bytesPerPixel != 1) { const Common::List outFormats = g_system->getSupportedFormats(); Graphics::PixelFormat inFormat = _decoder->getPixelFormat(); Graphics::PixelFormat bestFormat = outFormats.front(); Common::List::const_iterator it; for (it = outFormats.begin(); it != outFormats.end(); ++it) { if (*it == inFormat) { bestFormat = inFormat; break; } } if (bestFormat.bytesPerPixel != 2 && bestFormat.bytesPerPixel != 4) { error("Failed to find any valid output pixel format"); } g_sci->_gfxFrameout->setPixelFormat(bestFormat); } return kIOSuccess; } AVIPlayer::IOStatus AVIPlayer::play(const int16 from, const int16 to, const int16, const bool async) { if (_status == kAVINotOpen) { return kIOFileNotFound; } if (from >= 0 && to > 0 && from <= to) { _decoder->seekToFrame(from); _decoder->setEndFrame(to); } if (!async || getSciVersion() == SCI_VERSION_2_1_EARLY) { playUntilEvent(kEventFlagNone); } else { _status = kAVIPlaying; } return kIOSuccess; } AVIPlayer::EventFlags AVIPlayer::playUntilEvent(const EventFlags flags, const uint32 maxSleepMs) { // NOTE: In SSCI, whether or not a video could be skipped was controlled by // game scripts; here, we always allow skipping video with the mouse or // escape key, to improve the user experience return VideoPlayer::playUntilEvent(flags | kEventFlagMouseDown | kEventFlagEscapeKey, maxSleepMs); } AVIPlayer::IOStatus AVIPlayer::close() { if (_status == kAVINotOpen) { return kIOSuccess; } if (!endHQVideo()) { // This fixes a single-frame white flash after playback of the KQ7 1.x // videos, which replace palette entry 0 with white const uint8 black[3] = { 0, 0, 0 }; g_system->getPaletteManager()->setPalette(black, 0, 1); } g_system->fillScreen(0); g_sci->_gfxCursor32->unhide(); _decoder->close(); _status = kAVINotOpen; return kIOSuccess; } AVIPlayer::IOStatus AVIPlayer::cue(const uint16 frameNo) { if (!_decoder->seekToFrame(frameNo)) { return kIOSeekFailed; } _status = kAVIPaused; return kIOSuccess; } uint16 AVIPlayer::getDuration() const { if (_status == kAVINotOpen) { return 0; } return _decoder->getFrameCount(); } #pragma mark - #pragma mark VMDPlayer VMDPlayer::VMDPlayer(EventManager *eventMan, SegManager *segMan) : VideoPlayer(eventMan, new Video::AdvancedVMDDecoder(Audio::Mixer::kSFXSoundType)), _segMan(segMan), _isOpen(false), _isInitialized(false), _bundledVmd(nullptr), _yieldFrame(0), _yieldInterval(0), _lastYieldedFrameNo(0), _plane(nullptr), _screenItem(nullptr), _planeIsOwned(true), _priority(0), _doublePixels(false), _stretchVertical(false), _blackLines(false), _leaveScreenBlack(false), _leaveLastFrame(false), _ignorePalettes(false), _blackoutPlane(nullptr), _startColor(0), _endColor(255), #ifdef SCI_VMD_BLACK_PALETTE _blackPalette(false), #endif _boostPercent(100), _boostStartColor(0), _boostEndColor(255), _showCursor(false) {} VMDPlayer::~VMDPlayer() { close(); } #pragma mark - #pragma mark VMDPlayer - Playback VMDPlayer::IOStatus VMDPlayer::open(const Common::String &fileName, const OpenFlags flags) { if (_isOpen) { error("Attempted to play %s, but another VMD was loaded", fileName.c_str()); } if (g_sci->_features->VMDOpenStopsAudio()) { g_sci->_audio32->stop(kAllChannels); } Resource *bundledVmd = g_sci->getResMan()->findResource(ResourceId(kResourceTypeVMD, fileName.asUint64()), true); if (bundledVmd != nullptr) { Common::SeekableReadStream *stream = bundledVmd->makeStream(); if (_decoder->loadStream(stream)) { _bundledVmd = bundledVmd; _isOpen = true; } else { delete stream; g_sci->getResMan()->unlockResource(bundledVmd); } } else if (_decoder->loadFile(fileName)) { _isOpen = true; } if (_isOpen) { if (flags & kOpenFlagMute) { _decoder->setVolume(0); } return kIOSuccess; } return kIOError; } void VMDPlayer::init(int16 x, const int16 y, const PlayFlags flags, const int16 boostPercent, const int16 boostStartColor, const int16 boostEndColor) { if (getSciVersion() < SCI_VERSION_3) { x &= ~1; } _doublePixels = flags & kPlayFlagDoublePixels; _blackLines = ConfMan.getBool("enable_black_lined_video") && (flags & kPlayFlagBlackLines); // If ScummVM has been configured to disable black lines on video playback, // the boosts need to be ignored too or else the brightness of the video // will be too high _boostPercent = 100 + (_blackLines && (flags & kPlayFlagBoost) ? boostPercent : 0); _boostStartColor = CLIP(boostStartColor, 0, 255); _boostEndColor = CLIP(boostEndColor, 0, 255); _leaveScreenBlack = flags & kPlayFlagLeaveScreenBlack; _leaveLastFrame = flags & kPlayFlagLeaveLastFrame; #ifdef SCI_VMD_BLACK_PALETTE _blackPalette = flags & kPlayFlagBlackPalette; #endif _stretchVertical = flags & kPlayFlagStretchVertical; setDrawRect(x, y, (_decoder->getWidth() << _doublePixels), (_decoder->getHeight() << (_doublePixels || _stretchVertical))); } VMDPlayer::IOStatus VMDPlayer::close() { if (!_isOpen) { return kIOSuccess; } if (_isComposited) { closeComposited(); } else { closeOverlay(); } if (_blackoutPlane != nullptr) { g_sci->_gfxFrameout->deletePlane(*_blackoutPlane); _blackoutPlane = nullptr; } if (!_leaveLastFrame && !_leaveScreenBlack) { // This call *actually* deletes the blackout plane g_sci->_gfxFrameout->frameOut(true); } _decoder->close(); if (_bundledVmd) { g_sci->getResMan()->unlockResource(_bundledVmd); _bundledVmd = nullptr; } if (!_showCursor) { g_sci->_gfxCursor32->unhide(); } _isOpen = false; _isInitialized = false; _ignorePalettes = false; _lastYieldedFrameNo = 0; _planeIsOwned = true; _priority = 0; _drawRect = Common::Rect(); return kIOSuccess; } VMDPlayer::VMDStatus VMDPlayer::getStatus() const { if (!_isOpen) { return kVMDNotOpen; } if (_decoder->isPaused()) { return kVMDPaused; } if (_decoder->isPlaying()) { return kVMDPlaying; } if (_decoder->endOfVideo()) { return kVMDFinished; } return kVMDOpen; } VMDPlayer::EventFlags VMDPlayer::kernelPlayUntilEvent(const EventFlags flags, const int16 lastFrameNo, const int16 yieldInterval) { assert(lastFrameNo >= -1); const int32 maxFrameNo = _decoder->getFrameCount() - 1; if (flags & kEventFlagToFrame) { _yieldFrame = MIN(lastFrameNo, maxFrameNo); } else { _yieldFrame = maxFrameNo; } if (flags & kEventFlagYieldToVM) { _yieldInterval = 3; if (yieldInterval == -1 && !(flags & kEventFlagToFrame)) { _yieldInterval = lastFrameNo; } else if (yieldInterval != -1) { _yieldInterval = MIN(yieldInterval, maxFrameNo); } } else { _yieldInterval = maxFrameNo; } return playUntilEvent(flags); } VMDPlayer::EventFlags VMDPlayer::playUntilEvent(const EventFlags flags, const uint32) { if (flags & kEventFlagReverse) { // NOTE: This flag may not work properly since SSCI does not care // if a video has audio, but the VMD decoder does. warning("VMD reverse playback flag was set. Please report this event to the bug tracker"); const bool success = _decoder->setReverse(true); assert(success); _decoder->setVolume(0); } if (!_isInitialized) { _isInitialized = true; if (!_showCursor) { g_sci->_gfxCursor32->hide(); } if (!_blackoutRect.isEmpty() && _planeIsOwned) { _blackoutPlane = new Plane(_blackoutRect); g_sci->_gfxFrameout->addPlane(_blackoutPlane); } if (shouldUseCompositing()) { _isComposited = true; initComposited(); } else { _isComposited = false; initOverlay(); } } // Sleeping any more than 1/60th of a second will make the mouse feel // very sluggish during VMD action sequences because the frame rate of // VMDs is usually only 15fps return VideoPlayer::playUntilEvent(flags, 10); } VMDPlayer::EventFlags VMDPlayer::checkForEvent(const EventFlags flags) { const int currentFrameNo = _decoder->getCurFrame(); if (currentFrameNo == _yieldFrame) { return kEventFlagEnd; } if (_yieldInterval > 0 && currentFrameNo != _lastYieldedFrameNo && (currentFrameNo % _yieldInterval) == 0) { _lastYieldedFrameNo = currentFrameNo; return kEventFlagYieldToVM; } EventFlags stopFlag = VideoPlayer::checkForEvent(flags); if (stopFlag != kEventFlagNone) { return stopFlag; } const SciEvent event = _eventMan->getSciEvent(kSciEventHotRectangle | kSciEventPeek); if ((flags & kEventFlagHotRectangle) && event.type == kSciEventHotRectangle) { return kEventFlagHotRectangle; } return kEventFlagNone; } void VMDPlayer::initOverlay() { // Composited videos forced through the overlay renderer (due to HQ video // mode) still need to occlude whatever is behind them in the renderer (as // in composited mode) to prevent palette glitches caused by premature // submission of occluded screen items (e.g. leaving the lava room sphere in // the volcano in Lighthouse, the pic after the video finishes playing will // be rendered with the wrong palette) if (isNormallyComposited() && _planeIsOwned) { _plane = new Plane(_drawRect, kPlanePicColored); if (_priority) { _plane->_priority = _priority; } g_sci->_gfxFrameout->addPlane(_plane); } // Make sure that any pending graphics changes from the game are submitted // before starting playback, since if they aren't, and the video player // yields back to the VM in the middle of playback, there may be a flash of // content that draws over the video. (This happens when subtitles are // enabled in Shivers.) g_sci->_gfxFrameout->frameOut(true); #ifdef USE_RGB_COLOR // TODO: Allow interpolation for videos where the cursor is drawn, either by // writing to an intermediate 4bpp surface and using that surface during // cursor drawing, or by promoting the cursor code to use CursorMan, if // possible if (startHQVideo()) { redrawGameScreen(); } #endif } #ifdef USE_RGB_COLOR void VMDPlayer::redrawGameScreen() const { if (!_hqVideoMode) { return; } Graphics::Surface *game = g_sci->_gfxFrameout->getCurrentBuffer().convertTo(g_system->getScreenFormat(), g_sci->_gfxPalette32->getHardwarePalette()); assert(game); Common::Rect rects[4]; int splitCount = splitRects(Common::Rect(game->w, game->h), _drawRect, rects); if (splitCount != -1) { while (splitCount--) { const Common::Rect &drawRect = rects[splitCount]; g_system->copyRectToScreen(game->getBasePtr(drawRect.left, drawRect.top), game->pitch, drawRect.left, drawRect.top, drawRect.width(), drawRect.height()); } } game->free(); delete game; } #endif void VMDPlayer::renderOverlay(const Graphics::Surface &nextFrame) const { #ifdef USE_RGB_COLOR if (_hqVideoMode) { VideoPlayer::renderFrame(nextFrame); return; } #endif Graphics::Surface out = g_sci->_gfxFrameout->getCurrentBuffer().getSubArea(_drawRect); renderLQToSurface(out, nextFrame, _doublePixels, _blackLines); g_sci->_gfxFrameout->directFrameOut(_drawRect); } void VMDPlayer::submitPalette(const uint8 rawPalette[256 * 3]) const { if (_ignorePalettes) { return; } Palette palette; for (uint16 i = 0; i < _startColor; ++i) { palette.colors[i].used = false; } for (uint16 i = _endColor + 1; i < ARRAYSIZE(palette.colors); ++i) { palette.colors[i].used = false; } #if SCI_VMD_BLACK_PALETTE if (_blackPalette) { for (uint16 i = _startColor; i <= _endColor; ++i) { palette.colors[i].r = palette.colors[i].g = palette.colors[i].b = 0; palette.colors[i].used = true; } } else #endif fillPalette(rawPalette, palette); if (_isComposited) { SciBitmap *bitmap = _segMan->lookupBitmap(_bitmapId); bitmap->setPalette(palette); // NOTE: SSCI calls updateScreenItem and frameOut here, but this should // not be necessary in ScummVM since the new palette gets submitted // before the next frame is rendered, and the frame rendering call will // perform the same operations. } else { g_sci->_gfxPalette32->submit(palette); g_sci->_gfxPalette32->updateForFrame(); g_sci->_gfxPalette32->updateHardware(); } #if SCI_VMD_BLACK_PALETTE if (_blackPalette) { fillPalette(rawPalette, palette); if (_isComposited) { SciBitmap *bitmap = _segMan->lookupBitmap(_bitmapId); bitmap->setPalette(palette); } g_sci->_gfxPalette32->submit(palette); g_sci->_gfxPalette32->updateForFrame(); g_sci->_gfxPalette32->updateHardware(); } #endif #ifdef USE_RGB_COLOR // Changes to the palette may affect areas outside of the video; when the // engine is rendering video in high color, palette changes will only take // effect once the entire screen is redrawn to the high color surface redrawGameScreen(); #endif } void VMDPlayer::closeOverlay() { if (isNormallyComposited() && _planeIsOwned && _plane != nullptr) { g_sci->_gfxFrameout->deletePlane(*_plane); _plane = nullptr; } #ifdef USE_RGB_COLOR if (_hqVideoMode) { if (endHQVideo()) { g_sci->_gfxFrameout->resetHardware(); } return; } #endif g_sci->_gfxFrameout->frameOut(true, _drawRect); } void VMDPlayer::initComposited() { ScaleInfo vmdScaleInfo; if (_doublePixels) { vmdScaleInfo.x *= 2; vmdScaleInfo.y *= 2; vmdScaleInfo.signal = kScaleSignalManual; } else if (_stretchVertical) { vmdScaleInfo.y *= 2; vmdScaleInfo.signal = kScaleSignalManual; } const uint32 hunkPaletteSize = HunkPalette::calculateHunkPaletteSize(256, false); const int16 screenWidth = g_sci->_gfxFrameout->getCurrentBuffer().screenWidth; const int16 screenHeight = g_sci->_gfxFrameout->getCurrentBuffer().screenHeight; SciBitmap &vmdBitmap = *_segMan->allocateBitmap(&_bitmapId, _drawRect.width(), _drawRect.height(), 255, 0, 0, screenWidth, screenHeight, hunkPaletteSize, false, false); vmdBitmap.getBuffer().fillRect(Common::Rect(_drawRect.width(), _drawRect.height()), 0); CelInfo32 vmdCelInfo; vmdCelInfo.bitmap = _bitmapId; Video::AdvancedVMDDecoder *decoder = dynamic_cast(_decoder.get()); assert(decoder); decoder->setSurfaceMemory(vmdBitmap.getPixels(), vmdBitmap.getWidth(), vmdBitmap.getHeight(), 1); if (_planeIsOwned) { _plane = new Plane(_drawRect, kPlanePicColored); if (_priority) { _plane->_priority = _priority; } g_sci->_gfxFrameout->addPlane(_plane); _screenItem = new ScreenItem(_plane->_object, vmdCelInfo, Common::Point(), vmdScaleInfo); } else { _screenItem = new ScreenItem(_plane->_object, vmdCelInfo, Common::Point(_drawRect.left, _drawRect.top), vmdScaleInfo); if (_priority) { _screenItem->_priority = _priority; } } if (_blackLines) { _screenItem->_drawBlackLines = true; } // NOTE: There was code for positioning the screen item using insetRect // here, but none of the game scripts seem to use this functionality. g_sci->_gfxFrameout->addScreenItem(*_screenItem); // Composited VMDs periodically yield to game scripts which will often call // kFrameOut to make changes to other parts of the screen. Since VMDPlayer // is responsible for throttling output during these times, GfxFrameout // needs to stop throttling kFrameOut calls or else we will drop frames when // kFrameOut sleeps right through the next frame g_sci->_gfxFrameout->_throttleKernelFrameOut = false; } void VMDPlayer::renderComposited() const { g_sci->_gfxFrameout->updateScreenItem(*_screenItem); g_sci->_gfxFrameout->frameOut(true); } void VMDPlayer::closeComposited() { if (_bitmapId != NULL_REG) { _segMan->freeBitmap(_bitmapId); _bitmapId = NULL_REG; } if (!_planeIsOwned && _screenItem != nullptr) { g_sci->_gfxFrameout->deleteScreenItem(*_screenItem); _screenItem = nullptr; } else if (_plane != nullptr) { g_sci->_gfxFrameout->deletePlane(*_plane); _plane = nullptr; } if (!_leaveLastFrame && _leaveScreenBlack) { // This call *actually* deletes the plane/screen item g_sci->_gfxFrameout->frameOut(true); } g_sci->_gfxFrameout->_throttleKernelFrameOut = true; } #pragma mark - #pragma mark VMDPlayer - Rendering void VMDPlayer::renderFrame(const Graphics::Surface &nextFrame) const { if (_isComposited) { renderComposited(); } else { renderOverlay(nextFrame); } } void VMDPlayer::fillPalette(const uint8 rawPalette[256 * 3], Palette &outPalette) const { const byte *vmdPalette = rawPalette + _startColor * 3; for (uint16 i = _startColor; i <= _endColor; ++i) { uint8 r = *vmdPalette++; uint8 g = *vmdPalette++; uint8 b = *vmdPalette++; if (_boostPercent != 100 && i >= _boostStartColor && i <= _boostEndColor) { r = CLIP(r * _boostPercent / 100, 0, 255); g = CLIP(g * _boostPercent / 100, 0, 255); b = CLIP(b * _boostPercent / 100, 0, 255); } outPalette.colors[i].r = r; outPalette.colors[i].g = g; outPalette.colors[i].b = b; outPalette.colors[i].used = true; } } void VMDPlayer::setPlane(const int16 priority, const reg_t planeId) { _priority = priority; if (planeId != NULL_REG) { _plane = g_sci->_gfxFrameout->getPlanes().findByObject(planeId); assert(_plane != nullptr); _planeIsOwned = false; } } #pragma mark - #pragma mark VMDPlayer - Palette void VMDPlayer::restrictPalette(const uint8 startColor, const int16 endColor) { _startColor = startColor; // At least GK2 sends 256 as the end color, which is wrong, // but works in the original engine as the storage size is 4 bytes // and used values are clamped to 0-255 _endColor = MIN(255, endColor); } #pragma mark - #pragma mark DuckPlayer DuckPlayer::DuckPlayer(EventManager *eventMan, SegManager *segMan) : VideoPlayer(eventMan, new Video::AVIDecoder()), _plane(nullptr), _status(kDuckClosed), _volume(Audio::Mixer::kMaxChannelVolume), _doFrameOut(false) { _decoder->setSoundType(Audio::Mixer::kSFXSoundType); } void DuckPlayer::open(const GuiResourceId resourceId, const int displayMode, const int16 x, const int16 y) { if (_status != kDuckClosed) { error("Attempted to play %u.duk, but another video was loaded", resourceId); } const Common::String fileName = Common::String::format("%u.duk", resourceId); if (!VideoPlayer::open(fileName)) { return; } _decoder->setVolume(_volume); _doublePixels = displayMode != 0; _blackLines = ConfMan.getBool("enable_black_lined_video") && (displayMode == 1 || displayMode == 3); // SSCI seems to incorrectly calculate the draw rect by scaling the origin // in addition to the width/height for the BR point setDrawRect(x, y, (_decoder->getWidth() << _doublePixels), (_decoder->getHeight() << _doublePixels)); g_sci->_gfxCursor32->hide(); if (_doFrameOut) { _plane = new Plane(_drawRect, kPlanePicColored); g_sci->_gfxFrameout->addPlane(_plane); g_sci->_gfxFrameout->frameOut(true); } if (!startHQVideo() && _decoder->getPixelFormat().bytesPerPixel != 1) { g_sci->_gfxFrameout->setPixelFormat(_decoder->getPixelFormat()); } _status = kDuckOpen; } void DuckPlayer::play(const int lastFrameNo) { // This status check does not exist in the original interpreter, but is // necessary to avoid a crash if the engine cannot find or render the video // for playback. Game scripts receive no feedback from the kernel regarding // whether or not an attempt to open a Duck video actually succeeded, so // they can only assume it always succeeds (and so always call to `play` // even if they shouldn't). if (_status == kDuckClosed) { return; } if (_status != kDuckPlaying) { _status = kDuckPlaying; } if (lastFrameNo != -1) { _decoder->setEndFrame(lastFrameNo); } playUntilEvent(kEventFlagMouseDown | kEventFlagEscapeKey); } void DuckPlayer::close() { if (_status == kDuckClosed) { return; } _decoder->close(); endHQVideo(); g_sci->_gfxCursor32->unhide(); if (_doFrameOut) { g_sci->_gfxFrameout->deletePlane(*_plane); g_sci->_gfxFrameout->frameOut(true); _plane = nullptr; } _drawRect = Common::Rect(); _status = kDuckClosed; _volume = Audio::Mixer::kMaxChannelVolume; _doFrameOut = false; } void DuckPlayer::renderFrame(const Graphics::Surface &nextFrame) const { #ifdef USE_RGB_COLOR if (_hqVideoMode) { VideoPlayer::renderFrame(nextFrame); return; } #endif Graphics::Surface out; out.create(_drawRect.width(), _drawRect.height(), nextFrame.format); renderLQToSurface(out, nextFrame, _doublePixels, _blackLines); if (out.format != g_system->getScreenFormat()) { out.convertToInPlace(g_system->getScreenFormat()); } g_system->copyRectToScreen(out.getPixels(), out.pitch, _drawRect.left, _drawRect.top, out.w, out.h); out.free(); } } // End of namespace Sci