/* 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 "bladerunner/slice_renderer.h" #include "bladerunner/bladerunner.h" #include "bladerunner/lights.h" #include "bladerunner/screen_effects.h" #include "bladerunner/set_effects.h" #include "bladerunner/slice_animations.h" #include "common/memstream.h" #include "common/rect.h" #include "common/util.h" namespace BladeRunner { SliceRenderer::SliceRenderer(BladeRunnerEngine *vm) { _vm = vm; _pixelFormat = screenPixelFormat(); for (int i = 0; i < 942; i++) { // yes, its going just to 942 and not 997 _animationsShadowEnabled[i] = true; } _animation = -1; _frame = -1; _facing = 0.0f; _scale = 0.0f; _screenEffects = nullptr; _view = nullptr; _lights = nullptr; _setEffects = nullptr; _sliceFramePtr = nullptr; _frameBottomZ = 0.0f; _frameSliceHeight = 0.0f; _framePaletteIndex = 0; _frameSliceCount = 0; _startSlice = 0.0f; _endSlice = 0.0f; _m13 = 0; _m23 = 0; _shadowPolygonDefault[ 0] = Vector3( 16.0f, 96.0f, 0.0f); _shadowPolygonDefault[ 1] = Vector3( 16.0f, 160.0f, 0.0f); _shadowPolygonDefault[ 2] = Vector3( 64.0f, 192.0f, 0.0f); _shadowPolygonDefault[ 3] = Vector3( 80.0f, 240.0f, 0.0f); _shadowPolygonDefault[ 4] = Vector3(160.0f, 240.0f, 0.0f); _shadowPolygonDefault[ 5] = Vector3(192.0f, 192.0f, 0.0f); _shadowPolygonDefault[ 6] = Vector3(240.0f, 160.0f, 0.0f); _shadowPolygonDefault[ 7] = Vector3(240.0f, 96.0f, 0.0f); _shadowPolygonDefault[ 8] = Vector3(192.0f, 64.0f, 0.0f); _shadowPolygonDefault[ 9] = Vector3(160.0f, 16.0f, 0.0f); _shadowPolygonDefault[10] = Vector3( 96.0f, 16.0f, 0.0f); _shadowPolygonDefault[11] = Vector3( 64.0f, 64.0f, 0.0f); for (int i = 0; i < 12; ++i) { _shadowPolygonCurrent[i] = Vector3(0.0f, 0.0f, 0.0f); } } SliceRenderer::~SliceRenderer() { } void SliceRenderer::setScreenEffects(ScreenEffects *screenEffects) { _screenEffects = screenEffects; } void SliceRenderer::setView(View *view) { _view = view; } void SliceRenderer::setLights(Lights *lights) { _lights = lights; } void SliceRenderer::setSetEffects(SetEffects *setEffects) { _setEffects = setEffects; } void SliceRenderer::setupFrameInWorld(int animationId, int animationFrame, Vector3 position, float facing, float scale) { _position = position; _facing = facing; _scale = scale; loadFrame(animationId, animationFrame); calculateBoundingRect(); } void SliceRenderer::getScreenRectangle(Common::Rect *screenRectangle, int animationId, int animationFrame, Vector3 position, float facing, float scale) { assert(screenRectangle); setupFrameInWorld(animationId, animationFrame, position, facing, scale); *screenRectangle = _screenRectangle; } Matrix3x2 SliceRenderer::calculateFacingRotationMatrix() { assert(_sliceFramePtr); Vector3 viewPos = _view->_sliceViewMatrix * _position; float dir = atan2(viewPos.x, viewPos.z) + _facing; float s = sin(dir); float c = cos(dir); Matrix3x2 mRotation(c, -s, 0.0f, s, c, 0.0f); Matrix3x2 mView(_view->_sliceViewMatrix(0,0), _view->_sliceViewMatrix(0,1), 0.0f, _view->_sliceViewMatrix(2,0), _view->_sliceViewMatrix(2,1), 0.0f); return mView * mRotation; } void SliceRenderer::calculateBoundingRect() { assert(_sliceFramePtr); _screenRectangle.left = 0; _screenRectangle.right = 0; _screenRectangle.top = 0; _screenRectangle.bottom = 0; Matrix4x3 viewMatrix = _view->_sliceViewMatrix; Vector3 frameBottom = Vector3(0.0f, 0.0f, _frameBottomZ); Vector3 frameTop = Vector3(0.0f, 0.0f, _frameBottomZ + _frameSliceCount * _frameSliceHeight); Vector3 bottom = viewMatrix * (_position + frameBottom); Vector3 top = viewMatrix * (_position + frameTop); top = bottom + _scale * (top - bottom); if (bottom.z <= 0.0f || top.z <= 0.0f) { return; } Vector4 startScreenVector( _view->_viewportPosition.x + (top.x / top.z) * _view->_viewportPosition.z, _view->_viewportPosition.y + (top.y / top.z) * _view->_viewportPosition.z, 1.0f / top.z, _frameSliceCount * (1.0f / top.z)); Vector4 endScreenVector( _view->_viewportPosition.x + (bottom.x / bottom.z) * _view->_viewportPosition.z, _view->_viewportPosition.y + (bottom.y / bottom.z) * _view->_viewportPosition.z, 1.0f / bottom.z, 0.0f); Vector4 delta = endScreenVector - startScreenVector; if (delta.y == 0.0f) { return; } /* * Calculate min and max Y */ float screenTop = 0.0f; float screenBottom = 479.0f; if (startScreenVector.y < screenTop) { if (endScreenVector.y < screenTop) { return; } float f = (screenTop - startScreenVector.y) / delta.y; startScreenVector = startScreenVector + f * delta; } else if (startScreenVector.y > screenBottom) { if (endScreenVector.y >= screenBottom) { return; } float f = (screenBottom - startScreenVector.y) / delta.y; startScreenVector = startScreenVector + f * delta; } if (endScreenVector.y < screenTop) { float f = (screenTop - endScreenVector.y) / delta.y; endScreenVector = endScreenVector + f * delta; } else if (endScreenVector.y > screenBottom) { float f = (screenBottom - endScreenVector.y) / delta.y; endScreenVector = endScreenVector + f * delta; } _screenRectangle.top = (int)MIN(startScreenVector.y, endScreenVector.y); _screenRectangle.bottom = (int)MAX(startScreenVector.y, endScreenVector.y) + 1; /* * Calculate min and max X */ Matrix3x2 facingRotation = calculateFacingRotationMatrix(); Matrix3x2 mProjection(_view->_viewportPosition.z / bottom.z, 0.0f, 0.0f, 0.0f, 25.5f, 0.0f); Matrix3x2 mOffset(1.0f, 0.0f, _framePos.x, 0.0f, 1.0f, _framePos.y); Matrix3x2 mScale(_frameScale.x, 0.0f, 0.0f, 0.0f, _frameScale.y, 0.0f); _mvpMatrix = mProjection * (facingRotation * (mOffset * mScale)); Matrix3x2 mStart( 1.0f, 0.0f, startScreenVector.x, 0.0f, 1.0f, 25.5f / startScreenVector.z ); Matrix3x2 mEnd( 1.0f, 0.0f, endScreenVector.x, 0.0f, 1.0f, 25.5f / endScreenVector.z ); Matrix3x2 mStartMVP = mStart * _mvpMatrix; Matrix3x2 mEndMVP = mEnd * _mvpMatrix; float minX = 640.0f; float maxX = 0.0f; for (float i = 0.0f; i <= 255.0f; i += 255.0f) { for (float j = 0.0f; j <= 255.0f; j += 255.0f) { Vector2 v1 = mStartMVP * Vector2(i, j); minX = MIN(minX, v1.x); maxX = MAX(maxX, v1.x); Vector2 v2 = mEndMVP * Vector2(i, j); minX = MIN(minX, v2.x); maxX = MAX(maxX, v2.x); } } _screenRectangle.left = CLIP((int)minX, 0, 640); _screenRectangle.right = CLIP((int)maxX + 1, 0, 640); _startScreenVector.x = startScreenVector.x; _startScreenVector.y = startScreenVector.y; _startScreenVector.z = startScreenVector.z; _endScreenVector.x = endScreenVector.x; _endScreenVector.y = endScreenVector.y; _endScreenVector.z = endScreenVector.z; _startSlice = startScreenVector.w; _endSlice = endScreenVector.w; } void SliceRenderer::loadFrame(int animation, int frame) { _animation = animation; _frame = frame; _sliceFramePtr = _vm->_sliceAnimations->getFramePtr(_animation, _frame); Common::MemoryReadStream stream((byte *)_sliceFramePtr, _vm->_sliceAnimations->_animations[_animation].frameSize); _frameScale.x = stream.readFloatLE(); _frameScale.y = stream.readFloatLE(); _frameSliceHeight = stream.readFloatLE(); _framePos.x = stream.readFloatLE(); _framePos.y = stream.readFloatLE(); _frameBottomZ = stream.readFloatLE(); _framePaletteIndex = stream.readUint32LE(); _frameSliceCount = stream.readUint32LE(); } struct SliceLineIterator { Matrix3x2 _sliceMatrix; int _startY; int _endY; int _currentY; float _currentZ; float _stepZ; float _currentSlice; float _stepSlice; float _currentX; float _stepX; float _field_38; void setup(float endScreenX, float endScreenY, float endScreenZ, float startScreenX, float startScreenY, float startScreenZ, float endSlice, float startSlice, Matrix3x2 m); float line() const; void advance(); }; void SliceLineIterator::setup( float endScreenX, float endScreenY, float endScreenZ, float startScreenX, float startScreenY, float startScreenZ, float endSlice, float startSlice, Matrix3x2 m) { _startY = (int)startScreenY; _endY = (int)endScreenY; _currentY = _startY; float size = endScreenY - startScreenY; if (size <= 0.0f || startScreenZ <= 0.0f) { _currentY = _endY + 1; } _currentZ = startScreenZ; _stepZ = (endScreenZ - startScreenZ) / size; _stepSlice = (endSlice - startSlice) / size; _currentSlice = startSlice - (startScreenY - floor(startScreenY) - 1.0f) * _stepSlice; _currentX = startScreenX; _stepX = (endScreenX - startScreenX) / size; _field_38 = (25.5f / size) * (1.0f / endScreenZ - 1.0f / startScreenZ); float offsetX = _currentX; float offsetZ = 25.5f / _currentZ; Matrix3x2 mTranslate = Matrix3x2(1.0f, 0.0f, offsetX, 0.0f, 1.0f, offsetZ); Matrix3x2 mScale = Matrix3x2(65536.0f, 0.0f, 0.0f, // x position is using fixed-point precisson with 16 bits 0.0f, 64.0f, 0.0f); // z position is using fixed-point precisson with 6 bits _sliceMatrix = mScale * (mTranslate * m); } float SliceLineIterator::line() const { float var_0 = 0.0f; if (_currentZ != 0.0f) var_0 = _currentSlice / _currentZ; if (var_0 < 0.0) var_0 = 0.0f; return var_0; } void SliceLineIterator::advance() { _currentZ += _stepZ; _currentSlice += _stepSlice; _currentX += _stepX; _currentY += 1; _sliceMatrix._m[0][2] += _stepX * 65536.0f; _sliceMatrix._m[1][2] += _field_38 * 64.0f; } static void setupLookupTable(int t[256], int inc) { int v = 0; for (int i = 0; i != 256; ++i) { t[i] = v; v += inc; } } void SliceRenderer::drawInWorld(int animationId, int animationFrame, Vector3 position, float facing, float scale, Graphics::Surface &surface, uint16 *zbuffer) { assert(_lights); assert(_setEffects); //assert(_view); setupFrameInWorld(animationId, animationFrame, position, facing, scale); assert(_sliceFramePtr); if (_screenRectangle.isEmpty()) { return; } SliceLineIterator sliceLineIterator; sliceLineIterator.setup( _endScreenVector.x, _endScreenVector.y, _endScreenVector.z, _startScreenVector.x, _startScreenVector.y, _startScreenVector.z, _endSlice, _startSlice, _mvpMatrix ); SliceRendererLights sliceRendererLights = SliceRendererLights(_lights); _lights->setupFrame(_view->_frame); _setEffects->setupFrame(_view->_frame); float sliceLine = sliceLineIterator.line(); sliceRendererLights.calculateColorBase( Vector3(_position.x, _position.y, _position.z + _frameBottomZ + sliceLine * _frameSliceHeight), Vector3(_position.x, _position.y, _position.z + _frameBottomZ), sliceLineIterator._endY - sliceLineIterator._startY); float setEffectsColorCoeficient; Color setEffectColor; _setEffects->calculateColor( _view->_cameraPosition, Vector3(_position.x, _position.y, _position.z + _frameBottomZ + sliceLine * _frameSliceHeight), &setEffectsColorCoeficient, &setEffectColor); _lightsColor.r = setEffectsColorCoeficient * sliceRendererLights._finalColor.r * 65536.0f; _lightsColor.g = setEffectsColorCoeficient * sliceRendererLights._finalColor.g * 65536.0f; _lightsColor.b = setEffectsColorCoeficient * sliceRendererLights._finalColor.b * 65536.0f; _setEffectColor.r = setEffectColor.r * 31.0f * 65536.0f; _setEffectColor.g = setEffectColor.g * 31.0f * 65536.0f; _setEffectColor.b = setEffectColor.b * 31.0f * 65536.0f; setupLookupTable(_m12lookup, sliceLineIterator._sliceMatrix(0, 1)); setupLookupTable(_m11lookup, sliceLineIterator._sliceMatrix(0, 0)); _m13 = sliceLineIterator._sliceMatrix(0, 2); setupLookupTable(_m21lookup, sliceLineIterator._sliceMatrix(1, 0)); setupLookupTable(_m22lookup, sliceLineIterator._sliceMatrix(1, 1)); _m23 = sliceLineIterator._sliceMatrix(1, 2); if (_animationsShadowEnabled[_animation]) { float coeficientShadow; Color colorShadow; _setEffects->calculateColor( _view->_cameraPosition, _position, &coeficientShadow, &colorShadow); int transparency = 32.0f * sqrt(setEffectColor.r * setEffectColor.r + setEffectColor.g * setEffectColor.g + setEffectColor.b * setEffectColor.b); drawShadowInWorld(transparency, surface, zbuffer); } int frameY = sliceLineIterator._startY; uint16 *zBufferLinePtr = zbuffer + 640 * frameY; while (sliceLineIterator._currentY <= sliceLineIterator._endY) { _m13 = sliceLineIterator._sliceMatrix(0, 2); _m23 = sliceLineIterator._sliceMatrix(1, 2); sliceLine = sliceLineIterator.line(); sliceRendererLights.calculateColorSlice(Vector3(_position.x, _position.y, _position.z + _frameBottomZ + sliceLine * _frameSliceHeight)); if (sliceLineIterator._currentY & 1) { _setEffects->calculateColor( _view->_cameraPosition, Vector3(_position.x, _position.y, _position.z + _frameBottomZ + sliceLine * _frameSliceHeight), &setEffectsColorCoeficient, &setEffectColor); } _lightsColor.r = setEffectsColorCoeficient * sliceRendererLights._finalColor.r * 65536.0f; _lightsColor.g = setEffectsColorCoeficient * sliceRendererLights._finalColor.g * 65536.0f; _lightsColor.b = setEffectsColorCoeficient * sliceRendererLights._finalColor.b * 65536.0f; _setEffectColor.r = setEffectColor.r * 31.0f * 65536.0f; _setEffectColor.g = setEffectColor.g * 31.0f * 65536.0f; _setEffectColor.b = setEffectColor.b * 31.0f * 65536.0f; if (frameY >= 0 && frameY < surface.h) { drawSlice((int)sliceLine, true, frameY, surface, zBufferLinePtr); } sliceLineIterator.advance(); frameY += 1; zBufferLinePtr += 640; } } void SliceRenderer::drawOnScreen(int animationId, int animationFrame, int screenX, int screenY, float facing, float scale, Graphics::Surface &surface) { if (scale == 0.0f) { return; } _position.x = 0; _position.y = 0; _position.z = 0; _facing = facing; loadFrame(animationId, animationFrame); float frameHeight = _frameSliceHeight * _frameSliceCount; float frameSize = sqrt(_frameScale.x * 255.0f * _frameScale.x * 255.0f + _frameScale.y * 255.0f * _frameScale.y * 255.0f); float size = scale / MAX(frameSize, frameHeight); float s = sin(_facing); float c = cos(_facing); Matrix3x2 mRotation(c, -s, 0.0f, s, c, 0.0f); Matrix3x2 mFrame(_frameScale.x, 0.0f, _framePos.x, 0.0f, _frameScale.y, _framePos.y); Matrix3x2 mScale(size, 0.0f, 0.0f, 0.0f, 25.5f, 0.0f); Matrix3x2 mTranslate(1.0f, 0.0f, screenX, 0.0f, 1.0f, 32768.0f); Matrix3x2 mScaleFixed(65536.0f, 0.0f, 0.0f, // x position is using fixed-point precisson with 16 bits 0.0f, 64.0f, 0.0f); // z position is using fixed-point precisson with 6 bits Matrix3x2 m = mScaleFixed * (mTranslate * (mScale * (mRotation * mFrame))); setupLookupTable(_m11lookup, m(0, 0)); setupLookupTable(_m12lookup, m(0, 1)); _m13 = m(0, 2); setupLookupTable(_m21lookup, m(1, 0)); setupLookupTable(_m22lookup, m(1, 1)); _m23 = m(1, 2); int frameY = screenY + (size / 2.0f * frameHeight); int currentY = frameY; float currentSlice = 0; float sliceStep = 1.0f / size / _frameSliceHeight; uint16 lineZbuffer[640]; while (currentSlice < _frameSliceCount) { if (currentY >= 0 && currentY < surface.h) { memset(lineZbuffer, 0xFF, 640 * 2); drawSlice(currentSlice, false, currentY, surface, lineZbuffer); currentSlice += sliceStep; currentY--; } } } void SliceRenderer::drawSlice(int slice, bool advanced, int y, Graphics::Surface &surface, uint16 *zbufferLine) { if (slice < 0 || (uint32)slice >= _frameSliceCount) { return; } SliceAnimations::Palette &palette = _vm->_sliceAnimations->getPalette(_framePaletteIndex); byte *p = (byte *)_sliceFramePtr + 0x20 + 4 * slice; uint32 polyOffset = READ_LE_UINT32(p); p = (byte *)_sliceFramePtr + polyOffset; uint32 polyCount = READ_LE_UINT32(p); p += 4; while (polyCount--) { uint32 vertexCount = READ_LE_UINT32(p); p += 4; if (vertexCount == 0) continue; uint32 lastVertex = vertexCount - 1; int lastVertexX = MAX((_m11lookup[p[3 * lastVertex]] + _m12lookup[p[3 * lastVertex + 1]] + _m13) / 65536, 0); int previousVertexX = lastVertexX; while (vertexCount--) { int vertexX = CLIP((_m11lookup[p[0]] + _m12lookup[p[1]] + _m13) / 65536, 0, 640); if (vertexX > previousVertexX) { int vertexZ = (_m21lookup[p[0]] + _m22lookup[p[1]] + _m23) / 64; if (vertexZ >= 0 && vertexZ < 65536) { uint32 outColor = palette.value[p[2]]; if (advanced) { Color256 aescColor = { 0, 0, 0 }; _screenEffects->getColor(&aescColor, vertexX, y, vertexZ); Color256 color = palette.color[p[2]]; color.r = ((int)(_setEffectColor.r + _lightsColor.r * color.r) / 65536) + aescColor.r; color.g = ((int)(_setEffectColor.g + _lightsColor.g * color.g) / 65536) + aescColor.g; color.b = ((int)(_setEffectColor.b + _lightsColor.b * color.b) / 65536) + aescColor.b; int bladeToScummVmConstant = 256 / 32; outColor = _pixelFormat.RGBToColor(CLIP(color.r * bladeToScummVmConstant, 0, 255), CLIP(color.g * bladeToScummVmConstant, 0, 255), CLIP(color.b * bladeToScummVmConstant, 0, 255)); } for (int x = previousVertexX; x != vertexX; ++x) { if (vertexZ < zbufferLine[x]) { zbufferLine[x] = (uint16)vertexZ; void *dstPtr = surface.getBasePtr(CLIP(x, 0, surface.w - 1), CLIP(y, 0, surface.h - 1)); drawPixel(surface, dstPtr, outColor); } } } } p += 3; previousVertexX = vertexX; } } } void SliceRenderer::drawShadowInWorld(int transparency, Graphics::Surface &surface, uint16 *zbuffer) { Matrix4x3 mOffset( 1.0f, 0.0f, 0.0f, _framePos.x, 0.0f, 1.0f, 0.0f, _framePos.y, 0.0f, 0.0f, 1.0f, 0.0f); Matrix4x3 mTransition( 1.0f, 0.0f, 0.0f, _position.x, 0.0f, 1.0f, 0.0f, _position.y, 0.0f, 0.0f, 1.0f, _position.z); Matrix4x3 mRotation( cos(_facing), -sin(_facing), 0.0f, 0.0f, sin(_facing), cos(_facing), 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f); Matrix4x3 mScale( _frameScale.x, 0.0f, 0.0f, 0.0f, 0.0f, _frameScale.y, 0.0f, 0.0f, 0.0f, 0.0f, _frameSliceHeight, 0.0f); Matrix4x3 m = _view->_sliceViewMatrix * (mTransition * (mRotation * (mOffset * mScale))); for (int i = 0; i < 12; ++i) { Vector3 t = m * _shadowPolygonDefault[i]; if (t.z > 0.0f) { _shadowPolygonCurrent[i] = Vector3( _view->_viewportPosition.x + t.x / t.z * _view->_viewportPosition.z, _view->_viewportPosition.y + t.y / t.z * _view->_viewportPosition.z, t.z * 25.5f ); } else { _shadowPolygonCurrent[i] = Vector3(0.0f, 0.0f, 0.0f); } } drawShadowPolygon(transparency, surface, zbuffer); } void SliceRenderer::drawShadowPolygon(int transparency, Graphics::Surface &surface, uint16 *zbuffer) { // this simplified polygon drawing algo is in the game int yMax = 0; int yMin = 480; uint16 zMin = 65535; int polygonLeft[480] = {}; int polygonRight[480] = {}; int iNext = 11; for (int i = 0; i < 12; ++i) { int xCurrent = _shadowPolygonCurrent[i].x; int yCurrent = _shadowPolygonCurrent[i].y; int xNext = _shadowPolygonCurrent[iNext].x; int yNext = _shadowPolygonCurrent[iNext].y; if (yCurrent < yMin) { yMin = yCurrent; } if (yCurrent > yMax) { yMax = yCurrent; } if (_shadowPolygonCurrent[i].z < zMin) { zMin = _shadowPolygonCurrent[i].z; } int xDelta = abs(xNext - xCurrent); int yDelta = abs(yNext - yCurrent); int xDirection = -1; if (xCurrent < xNext) { xDirection = 1; } int xCounter = 0; int x = xCurrent; int y = yCurrent; if (yCurrent > yNext) { while (y >= yNext) { if (y >= 0 && y < 480) { polygonLeft[y] = x; } xCounter += xDelta; while (xCounter >= yDelta) { x += xDirection; xCounter -= yDelta; } --y; } } else if (yCurrent < yNext) { while (y <= yNext) { if (y >= 0 && y < 480) { polygonRight[y] = x; } xCounter += xDelta; while (xCounter >= yDelta) { x += xDirection; xCounter -= yDelta; } ++y; } } iNext = (iNext + 1) % 12; } yMax = CLIP(yMax, 0, 480); yMin = CLIP(yMin, 0, 480); int ditheringFactor[] = { 0, 8, 2, 10, 12, 4, 14, 6, 3, 11, 1, 9, 15, 7, 13, 5 }; for (int y = yMin; y < yMax; ++y) { int xMin = CLIP(polygonLeft[y], 0, 640); int xMax = CLIP(polygonRight[y], 0, 640); for (int x = MIN(xMin, xMax); x < MAX(xMin, xMax); ++x) { uint16 z = zbuffer[x + y * 640]; void *pixel = surface.getBasePtr(CLIP(x, 0, surface.w - 1), CLIP(y, 0, surface.h - 1)); if (z >= zMin) { int index = (x & 3) + ((y & 3) << 2); if (transparency - ditheringFactor[index] <= 0) { uint8 r, g, b; surface.format.colorToRGB(READ_UINT32(pixel), r, g, b); r *= 0.75f; g *= 0.75f; b *= 0.75f; drawPixel(surface, pixel, surface.format.RGBToColor(r, g, b)); } } } } } void SliceRenderer::preload(int animationId) { int frameCount = _vm->_sliceAnimations->getFrameCount(animationId); for (int i = 0; i < frameCount; ++i) { _vm->_sliceAnimations->getFramePtr(animationId, i); } } void SliceRenderer::disableShadows(int animationsIdsList[], int listSize) { for (int i = 0; i < listSize; ++i) { _animationsShadowEnabled[animationsIdsList[i]] = false; } } SliceRendererLights::SliceRendererLights(Lights *lights) { _finalColor.r = 0.0f; _finalColor.g = 0.0f; _finalColor.b = 0.0f; _lights = lights; for (int i = 0; i < 20; i++) { _cacheColor[i].r = 0.0f; _cacheColor[i].g = 0.0f; _cacheColor[i].b = 0.0f; } _cacheRecalculation = 0.0f; } void SliceRendererLights::calculateColorBase(Vector3 position1, Vector3 position2, float height) { _finalColor.r = 0.0f; _finalColor.g = 0.0f; _finalColor.b = 0.0f; _cacheRecalculation = 0; if (_lights) { for (uint i = 0; i < _lights->_lights.size(); i++) { Light *light = _lights->_lights[i]; if (i < 20) { float cacheCoeficient = light->calculate(position1, position2/*, height*/); _cacheStart[i] = cacheCoeficient; _cacheCounter[i] = cacheCoeficient; Color color; light->calculateColor(&color, position1); _cacheColor[i] = color; _finalColor.r += color.r; _finalColor.g += color.g; _finalColor.b += color.b; } else { Color color; light->calculateColor(&color, position1); _finalColor.r += color.r; _finalColor.g += color.g; _finalColor.b += color.b; } } _finalColor.r += _lights->_ambientLightColor.r; _finalColor.g += _lights->_ambientLightColor.g; _finalColor.b += _lights->_ambientLightColor.b; } } void SliceRendererLights::calculateColorSlice(Vector3 position) { _finalColor.r = 0.0f; _finalColor.g = 0.0f; _finalColor.b = 0.0f; if (_lights) { for (uint i = 0; i < _lights->_lights.size(); i++) { Light *light = _lights->_lights[i]; if (i < 20) { _cacheCounter[i] -= 1.0f; if (_cacheCounter[i] <= 0.0f) { do { _cacheCounter[i] = _cacheCounter[i] + _cacheStart[i]; } while (_cacheCounter[i] <= 0.0f); light->calculateColor(&_cacheColor[i], position); _cacheRecalculation++; } _finalColor.r += _cacheColor[i].r; _finalColor.g += _cacheColor[i].g; _finalColor.b += _cacheColor[i].b; } else { Color color; light->calculateColor(&color, position); _cacheRecalculation++; _finalColor.r += color.r; _finalColor.g += color.g; _finalColor.b += color.b; } } _finalColor.r += _lights->_ambientLightColor.r; _finalColor.g += _lights->_ambientLightColor.g; _finalColor.b += _lights->_ambientLightColor.b; } } } // End of namespace BladeRunner