// Copyright 2016 The SwiftShader Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "Blitter.hpp" #include "Shader/ShaderCore.hpp" #include "Reactor/Reactor.hpp" #include "Common/Memory.hpp" #include "Common/Debug.hpp" namespace sw { using namespace rr; Blitter::Blitter() { blitCache = new RoutineCache(1024); } Blitter::~Blitter() { delete blitCache; } void Blitter::clear(void *pixel, sw::Format format, Surface *dest, const SliceRect &dRect, unsigned int rgbaMask) { if(fastClear(pixel, format, dest, dRect, rgbaMask)) { return; } sw::Surface *color = sw::Surface::create(1, 1, 1, format, pixel, sw::Surface::bytes(format), sw::Surface::bytes(format)); SliceRectF sRect(0.5f, 0.5f, 0.5f, 0.5f, 0); // Sample from the middle. blit(color, sRect, dest, dRect, {rgbaMask}); delete color; } bool Blitter::fastClear(void *pixel, sw::Format format, Surface *dest, const SliceRect &dRect, unsigned int rgbaMask) { if(format != FORMAT_A32B32G32R32F) { return false; } float *color = (float*)pixel; float r = color[0]; float g = color[1]; float b = color[2]; float a = color[3]; uint32_t packed; switch(dest->getFormat()) { case FORMAT_R5G6B5: if((rgbaMask & 0x7) != 0x7) return false; packed = ((uint16_t)(31 * b + 0.5f) << 0) | ((uint16_t)(63 * g + 0.5f) << 5) | ((uint16_t)(31 * r + 0.5f) << 11); break; case FORMAT_X8B8G8R8: if((rgbaMask & 0x7) != 0x7) return false; packed = ((uint32_t)(255) << 24) | ((uint32_t)(255 * b + 0.5f) << 16) | ((uint32_t)(255 * g + 0.5f) << 8) | ((uint32_t)(255 * r + 0.5f) << 0); break; case FORMAT_A8B8G8R8: if((rgbaMask & 0xF) != 0xF) return false; packed = ((uint32_t)(255 * a + 0.5f) << 24) | ((uint32_t)(255 * b + 0.5f) << 16) | ((uint32_t)(255 * g + 0.5f) << 8) | ((uint32_t)(255 * r + 0.5f) << 0); break; case FORMAT_X8R8G8B8: if((rgbaMask & 0x7) != 0x7) return false; packed = ((uint32_t)(255) << 24) | ((uint32_t)(255 * r + 0.5f) << 16) | ((uint32_t)(255 * g + 0.5f) << 8) | ((uint32_t)(255 * b + 0.5f) << 0); break; case FORMAT_A8R8G8B8: if((rgbaMask & 0xF) != 0xF) return false; packed = ((uint32_t)(255 * a + 0.5f) << 24) | ((uint32_t)(255 * r + 0.5f) << 16) | ((uint32_t)(255 * g + 0.5f) << 8) | ((uint32_t)(255 * b + 0.5f) << 0); break; default: return false; } bool useDestInternal = !dest->isExternalDirty(); uint8_t *slice = (uint8_t*)dest->lock(dRect.x0, dRect.y0, dRect.slice, sw::LOCK_WRITEONLY, sw::PUBLIC, useDestInternal); for(int j = 0; j < dest->getSamples(); j++) { uint8_t *d = slice; switch(Surface::bytes(dest->getFormat())) { case 2: for(int i = dRect.y0; i < dRect.y1; i++) { sw::clear((uint16_t*)d, packed, dRect.x1 - dRect.x0); d += dest->getPitchB(useDestInternal); } break; case 4: for(int i = dRect.y0; i < dRect.y1; i++) { sw::clear((uint32_t*)d, packed, dRect.x1 - dRect.x0); d += dest->getPitchB(useDestInternal); } break; default: assert(false); } slice += dest->getSliceB(useDestInternal); } dest->unlock(useDestInternal); return true; } void Blitter::blit(Surface *source, const SliceRectF &sourceRect, Surface *dest, const SliceRect &destRect, const Blitter::Options& options) { if(dest->getInternalFormat() == FORMAT_NULL) { return; } if(blitReactor(source, sourceRect, dest, destRect, options)) { return; } SliceRectF sRect = sourceRect; SliceRect dRect = destRect; bool flipX = destRect.x0 > destRect.x1; bool flipY = destRect.y0 > destRect.y1; if(flipX) { swap(dRect.x0, dRect.x1); swap(sRect.x0, sRect.x1); } if(flipY) { swap(dRect.y0, dRect.y1); swap(sRect.y0, sRect.y1); } source->lockInternal(0, 0, sRect.slice, sw::LOCK_READONLY, sw::PUBLIC); dest->lockInternal(0, 0, dRect.slice, sw::LOCK_WRITEONLY, sw::PUBLIC); float w = sRect.width() / dRect.width(); float h = sRect.height() / dRect.height(); float xStart = sRect.x0 + (0.5f - dRect.x0) * w; float yStart = sRect.y0 + (0.5f - dRect.y0) * h; for(int j = dRect.y0; j < dRect.y1; j++) { float y = yStart + j * h; for(int i = dRect.x0; i < dRect.x1; i++) { float x = xStart + i * w; // FIXME: Support RGBA mask dest->copyInternal(source, i, j, x, y, options.filter); } } source->unlockInternal(); dest->unlockInternal(); } void Blitter::blit3D(Surface *source, Surface *dest) { source->lockInternal(0, 0, 0, sw::LOCK_READONLY, sw::PUBLIC); dest->lockInternal(0, 0, 0, sw::LOCK_WRITEONLY, sw::PUBLIC); float w = static_cast(source->getWidth()) / static_cast(dest->getWidth()); float h = static_cast(source->getHeight()) / static_cast(dest->getHeight()); float d = static_cast(source->getDepth()) / static_cast(dest->getDepth()); for(int k = 0; k < dest->getDepth(); k++) { float z = (k + 0.5f) * d; for(int j = 0; j < dest->getHeight(); j++) { float y = (j + 0.5f) * h; for(int i = 0; i < dest->getWidth(); i++) { float x = (i + 0.5f) * w; dest->copyInternal(source, i, j, k, x, y, z, true); } } } source->unlockInternal(); dest->unlockInternal(); } bool Blitter::read(Float4 &c, Pointer element, const State &state) { c = Float4(0.0f, 0.0f, 0.0f, 1.0f); switch(state.sourceFormat) { case FORMAT_L8: c.xyz = Float(Int(*Pointer(element))); c.w = float(0xFF); break; case FORMAT_A8: c.w = Float(Int(*Pointer(element))); break; case FORMAT_R8I: case FORMAT_R8_SNORM: c.x = Float(Int(*Pointer(element))); c.w = float(0x7F); break; case FORMAT_R8: case FORMAT_R8UI: c.x = Float(Int(*Pointer(element))); c.w = float(0xFF); break; case FORMAT_R16I: c.x = Float(Int(*Pointer(element))); c.w = float(0x7FFF); break; case FORMAT_R16UI: c.x = Float(Int(*Pointer(element))); c.w = float(0xFFFF); break; case FORMAT_R32I: c.x = Float(*Pointer(element)); c.w = float(0x7FFFFFFF); break; case FORMAT_R32UI: c.x = Float(*Pointer(element)); c.w = float(0xFFFFFFFF); break; case FORMAT_A8R8G8B8: c = Float4(*Pointer(element)).zyxw; break; case FORMAT_A8B8G8R8I: case FORMAT_A8B8G8R8_SNORM: c = Float4(*Pointer(element)); break; case FORMAT_A8B8G8R8: case FORMAT_A8B8G8R8UI: case FORMAT_SRGB8_A8: c = Float4(*Pointer(element)); break; case FORMAT_X8R8G8B8: c = Float4(*Pointer(element)).zyxw; c.w = float(0xFF); break; case FORMAT_R8G8B8: c.z = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 1))); c.x = Float(Int(*Pointer(element + 2))); c.w = float(0xFF); break; case FORMAT_B8G8R8: c.x = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 1))); c.z = Float(Int(*Pointer(element + 2))); c.w = float(0xFF); break; case FORMAT_X8B8G8R8I: case FORMAT_X8B8G8R8_SNORM: c = Float4(*Pointer(element)); c.w = float(0x7F); break; case FORMAT_X8B8G8R8: case FORMAT_X8B8G8R8UI: case FORMAT_SRGB8_X8: c = Float4(*Pointer(element)); c.w = float(0xFF); break; case FORMAT_A16B16G16R16I: c = Float4(*Pointer(element)); break; case FORMAT_A16B16G16R16: case FORMAT_A16B16G16R16UI: c = Float4(*Pointer(element)); break; case FORMAT_X16B16G16R16I: c = Float4(*Pointer(element)); c.w = float(0x7FFF); break; case FORMAT_X16B16G16R16UI: c = Float4(*Pointer(element)); c.w = float(0xFFFF); break; case FORMAT_A32B32G32R32I: c = Float4(*Pointer(element)); break; case FORMAT_A32B32G32R32UI: c = Float4(*Pointer(element)); break; case FORMAT_X32B32G32R32I: c = Float4(*Pointer(element)); c.w = float(0x7FFFFFFF); break; case FORMAT_X32B32G32R32UI: c = Float4(*Pointer(element)); c.w = float(0xFFFFFFFF); break; case FORMAT_G8R8I: case FORMAT_G8R8_SNORM: c.x = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 1))); c.w = float(0x7F); break; case FORMAT_G8R8: case FORMAT_G8R8UI: c.x = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 1))); c.w = float(0xFF); break; case FORMAT_G16R16I: c.x = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 2))); c.w = float(0x7FFF); break; case FORMAT_G16R16: case FORMAT_G16R16UI: c.x = Float(Int(*Pointer(element + 0))); c.y = Float(Int(*Pointer(element + 2))); c.w = float(0xFFFF); break; case FORMAT_G32R32I: c.x = Float(*Pointer(element + 0)); c.y = Float(*Pointer(element + 4)); c.w = float(0x7FFFFFFF); break; case FORMAT_G32R32UI: c.x = Float(*Pointer(element + 0)); c.y = Float(*Pointer(element + 4)); c.w = float(0xFFFFFFFF); break; case FORMAT_A32B32G32R32F: c = *Pointer(element); break; case FORMAT_X32B32G32R32F: case FORMAT_X32B32G32R32F_UNSIGNED: case FORMAT_B32G32R32F: c.z = *Pointer(element + 8); case FORMAT_G32R32F: c.x = *Pointer(element + 0); c.y = *Pointer(element + 4); break; case FORMAT_R32F: c.x = *Pointer(element); break; case FORMAT_R5G6B5: c.x = Float(Int((*Pointer(element) & UShort(0xF800)) >> UShort(11))); c.y = Float(Int((*Pointer(element) & UShort(0x07E0)) >> UShort(5))); c.z = Float(Int(*Pointer(element) & UShort(0x001F))); break; case FORMAT_A2B10G10R10: case FORMAT_A2B10G10R10UI: c.x = Float(Int((*Pointer(element) & UInt(0x000003FF)))); c.y = Float(Int((*Pointer(element) & UInt(0x000FFC00)) >> 10)); c.z = Float(Int((*Pointer(element) & UInt(0x3FF00000)) >> 20)); c.w = Float(Int((*Pointer(element) & UInt(0xC0000000)) >> 30)); break; case FORMAT_D16: c.x = Float(Int((*Pointer(element)))); break; case FORMAT_D24S8: case FORMAT_D24X8: c.x = Float(Int((*Pointer(element) & UInt(0xFFFFFF00)) >> 8)); break; case FORMAT_D32: c.x = Float(Int((*Pointer(element)))); break; case FORMAT_D32F_COMPLEMENTARY: case FORMAT_D32FS8_COMPLEMENTARY: c.x = 1.0f - *Pointer(element); break; case FORMAT_D32F: case FORMAT_D32FS8: case FORMAT_D32F_LOCKABLE: case FORMAT_D32FS8_TEXTURE: case FORMAT_D32F_SHADOW: case FORMAT_D32FS8_SHADOW: c.x = *Pointer(element); break; case FORMAT_S8: c.x = Float(Int(*Pointer(element))); break; default: return false; } return true; } bool Blitter::write(Float4 &c, Pointer element, const State &state) { bool writeR = state.writeRed; bool writeG = state.writeGreen; bool writeB = state.writeBlue; bool writeA = state.writeAlpha; bool writeRGBA = writeR && writeG && writeB && writeA; switch(state.destFormat) { case FORMAT_L8: *Pointer(element) = Byte(RoundInt(Float(c.x))); break; case FORMAT_A8: if(writeA) { *Pointer(element) = Byte(RoundInt(Float(c.w))); } break; case FORMAT_A8R8G8B8: if(writeRGBA) { Short4 c0 = RoundShort4(c.zyxw); *Pointer(element) = Byte4(PackUnsigned(c0, c0)); } else { if(writeB) { *Pointer(element + 0) = Byte(RoundInt(Float(c.z))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeR) { *Pointer(element + 2) = Byte(RoundInt(Float(c.x))); } if(writeA) { *Pointer(element + 3) = Byte(RoundInt(Float(c.w))); } } break; case FORMAT_A8B8G8R8: case FORMAT_SRGB8_A8: if(writeRGBA) { Short4 c0 = RoundShort4(c); *Pointer(element) = Byte4(PackUnsigned(c0, c0)); } else { if(writeR) { *Pointer(element + 0) = Byte(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 2) = Byte(RoundInt(Float(c.z))); } if(writeA) { *Pointer(element + 3) = Byte(RoundInt(Float(c.w))); } } break; case FORMAT_X8R8G8B8: if(writeRGBA) { Short4 c0 = RoundShort4(c.zyxw) | Short4(0x0000, 0x0000, 0x0000, 0x00FF); *Pointer(element) = Byte4(PackUnsigned(c0, c0)); } else { if(writeB) { *Pointer(element + 0) = Byte(RoundInt(Float(c.z))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeR) { *Pointer(element + 2) = Byte(RoundInt(Float(c.x))); } if(writeA) { *Pointer(element + 3) = Byte(0xFF); } } break; case FORMAT_X8B8G8R8: case FORMAT_SRGB8_X8: if(writeRGBA) { Short4 c0 = RoundShort4(c) | Short4(0x0000, 0x0000, 0x0000, 0x00FF); *Pointer(element) = Byte4(PackUnsigned(c0, c0)); } else { if(writeR) { *Pointer(element + 0) = Byte(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 2) = Byte(RoundInt(Float(c.z))); } if(writeA) { *Pointer(element + 3) = Byte(0xFF); } } break; case FORMAT_R8G8B8: if(writeR) { *Pointer(element + 2) = Byte(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 0) = Byte(RoundInt(Float(c.z))); } break; case FORMAT_B8G8R8: if(writeR) { *Pointer(element + 0) = Byte(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 2) = Byte(RoundInt(Float(c.z))); } break; case FORMAT_A32B32G32R32F: if(writeRGBA) { *Pointer(element) = c; } else { if(writeR) { *Pointer(element) = c.x; } if(writeG) { *Pointer(element + 4) = c.y; } if(writeB) { *Pointer(element + 8) = c.z; } if(writeA) { *Pointer(element + 12) = c.w; } } break; case FORMAT_X32B32G32R32F: case FORMAT_X32B32G32R32F_UNSIGNED: if(writeA) { *Pointer(element + 12) = 1.0f; } case FORMAT_B32G32R32F: if(writeR) { *Pointer(element) = c.x; } if(writeG) { *Pointer(element + 4) = c.y; } if(writeB) { *Pointer(element + 8) = c.z; } break; case FORMAT_G32R32F: if(writeR && writeG) { *Pointer(element) = Float2(c); } else { if(writeR) { *Pointer(element) = c.x; } if(writeG) { *Pointer(element + 4) = c.y; } } break; case FORMAT_R32F: if(writeR) { *Pointer(element) = c.x; } break; case FORMAT_A8B8G8R8I: case FORMAT_A8B8G8R8_SNORM: if(writeA) { *Pointer(element + 3) = SByte(RoundInt(Float(c.w))); } case FORMAT_X8B8G8R8I: case FORMAT_X8B8G8R8_SNORM: if(writeA && (state.destFormat == FORMAT_X8B8G8R8I || state.destFormat == FORMAT_X8B8G8R8_SNORM)) { *Pointer(element + 3) = SByte(0x7F); } if(writeB) { *Pointer(element + 2) = SByte(RoundInt(Float(c.z))); } case FORMAT_G8R8I: case FORMAT_G8R8_SNORM: if(writeG) { *Pointer(element + 1) = SByte(RoundInt(Float(c.y))); } case FORMAT_R8I: case FORMAT_R8_SNORM: if(writeR) { *Pointer(element) = SByte(RoundInt(Float(c.x))); } break; case FORMAT_A8B8G8R8UI: if(writeA) { *Pointer(element + 3) = Byte(RoundInt(Float(c.w))); } case FORMAT_X8B8G8R8UI: if(writeA && (state.destFormat == FORMAT_X8B8G8R8UI)) { *Pointer(element + 3) = Byte(0xFF); } if(writeB) { *Pointer(element + 2) = Byte(RoundInt(Float(c.z))); } case FORMAT_G8R8UI: case FORMAT_G8R8: if(writeG) { *Pointer(element + 1) = Byte(RoundInt(Float(c.y))); } case FORMAT_R8UI: case FORMAT_R8: if(writeR) { *Pointer(element) = Byte(RoundInt(Float(c.x))); } break; case FORMAT_A16B16G16R16I: if(writeRGBA) { *Pointer(element) = Short4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = Short(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = Short(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 4) = Short(RoundInt(Float(c.z))); } if(writeA) { *Pointer(element + 6) = Short(RoundInt(Float(c.w))); } } break; case FORMAT_X16B16G16R16I: if(writeRGBA) { *Pointer(element) = Short4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = Short(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = Short(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 4) = Short(RoundInt(Float(c.z))); } } if(writeA) { *Pointer(element + 6) = Short(0x7F); } break; case FORMAT_G16R16I: if(writeR && writeG) { *Pointer(element) = Short2(Short4(RoundInt(c))); } else { if(writeR) { *Pointer(element) = Short(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = Short(RoundInt(Float(c.y))); } } break; case FORMAT_R16I: if(writeR) { *Pointer(element) = Short(RoundInt(Float(c.x))); } break; case FORMAT_A16B16G16R16UI: case FORMAT_A16B16G16R16: if(writeRGBA) { *Pointer(element) = UShort4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = UShort(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = UShort(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 4) = UShort(RoundInt(Float(c.z))); } if(writeA) { *Pointer(element + 6) = UShort(RoundInt(Float(c.w))); } } break; case FORMAT_X16B16G16R16UI: if(writeRGBA) { *Pointer(element) = UShort4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = UShort(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = UShort(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 4) = UShort(RoundInt(Float(c.z))); } } if(writeA) { *Pointer(element + 6) = UShort(0xFF); } break; case FORMAT_G16R16UI: case FORMAT_G16R16: if(writeR && writeG) { *Pointer(element) = UShort2(UShort4(RoundInt(c))); } else { if(writeR) { *Pointer(element) = UShort(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 2) = UShort(RoundInt(Float(c.y))); } } break; case FORMAT_R16UI: if(writeR) { *Pointer(element) = UShort(RoundInt(Float(c.x))); } break; case FORMAT_A32B32G32R32I: if(writeRGBA) { *Pointer(element) = RoundInt(c); } else { if(writeR) { *Pointer(element) = RoundInt(Float(c.x)); } if(writeG) { *Pointer(element + 4) = RoundInt(Float(c.y)); } if(writeB) { *Pointer(element + 8) = RoundInt(Float(c.z)); } if(writeA) { *Pointer(element + 12) = RoundInt(Float(c.w)); } } break; case FORMAT_X32B32G32R32I: if(writeRGBA) { *Pointer(element) = RoundInt(c); } else { if(writeR) { *Pointer(element) = RoundInt(Float(c.x)); } if(writeG) { *Pointer(element + 4) = RoundInt(Float(c.y)); } if(writeB) { *Pointer(element + 8) = RoundInt(Float(c.z)); } } if(writeA) { *Pointer(element + 12) = Int(0x7FFFFFFF); } break; case FORMAT_G32R32I: if(writeG) { *Pointer(element + 4) = RoundInt(Float(c.y)); } case FORMAT_R32I: if(writeR) { *Pointer(element) = RoundInt(Float(c.x)); } break; case FORMAT_A32B32G32R32UI: if(writeRGBA) { *Pointer(element) = UInt4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = As(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 4) = As(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 8) = As(RoundInt(Float(c.z))); } if(writeA) { *Pointer(element + 12) = As(RoundInt(Float(c.w))); } } break; case FORMAT_X32B32G32R32UI: if(writeRGBA) { *Pointer(element) = UInt4(RoundInt(c)); } else { if(writeR) { *Pointer(element) = As(RoundInt(Float(c.x))); } if(writeG) { *Pointer(element + 4) = As(RoundInt(Float(c.y))); } if(writeB) { *Pointer(element + 8) = As(RoundInt(Float(c.z))); } } if(writeA) { *Pointer(element + 12) = UInt4(0xFFFFFFFF); } break; case FORMAT_G32R32UI: if(writeG) { *Pointer(element + 4) = As(RoundInt(Float(c.y))); } case FORMAT_R32UI: if(writeR) { *Pointer(element) = As(RoundInt(Float(c.x))); } break; case FORMAT_R5G6B5: if(writeR && writeG && writeB) { *Pointer(element) = UShort(RoundInt(Float(c.z)) | (RoundInt(Float(c.y)) << Int(5)) | (RoundInt(Float(c.x)) << Int(11))); } else { unsigned short mask = (writeB ? 0x001F : 0x0000) | (writeG ? 0x07E0 : 0x0000) | (writeR ? 0xF800 : 0x0000); unsigned short unmask = ~mask; *Pointer(element) = (*Pointer(element) & UShort(unmask)) | (UShort(RoundInt(Float(c.z)) | (RoundInt(Float(c.y)) << Int(5)) | (RoundInt(Float(c.x)) << Int(11))) & UShort(mask)); } break; case FORMAT_A2B10G10R10: case FORMAT_A2B10G10R10UI: if(writeRGBA) { *Pointer(element) = UInt(RoundInt(Float(c.x)) | (RoundInt(Float(c.y)) << 10) | (RoundInt(Float(c.z)) << 20) | (RoundInt(Float(c.w)) << 30)); } else { unsigned int mask = (writeA ? 0xC0000000 : 0x0000) | (writeB ? 0x3FF00000 : 0x0000) | (writeG ? 0x000FFC00 : 0x0000) | (writeR ? 0x000003FF : 0x0000); unsigned int unmask = ~mask; *Pointer(element) = (*Pointer(element) & UInt(unmask)) | (UInt(RoundInt(Float(c.x)) | (RoundInt(Float(c.y)) << 10) | (RoundInt(Float(c.z)) << 20) | (RoundInt(Float(c.w)) << 30)) & UInt(mask)); } break; case FORMAT_D16: *Pointer(element) = UShort(RoundInt(Float(c.x))); break; case FORMAT_D24S8: case FORMAT_D24X8: *Pointer(element) = UInt(RoundInt(Float(c.x)) << 8); break; case FORMAT_D32: *Pointer(element) = UInt(RoundInt(Float(c.x))); break; case FORMAT_D32F_COMPLEMENTARY: case FORMAT_D32FS8_COMPLEMENTARY: *Pointer(element) = 1.0f - c.x; break; case FORMAT_D32F: case FORMAT_D32FS8: case FORMAT_D32F_LOCKABLE: case FORMAT_D32FS8_TEXTURE: case FORMAT_D32F_SHADOW: case FORMAT_D32FS8_SHADOW: *Pointer(element) = c.x; break; case FORMAT_S8: *Pointer(element) = Byte(RoundInt(Float(c.x))); break; default: return false; } return true; } bool Blitter::read(Int4 &c, Pointer element, const State &state) { c = Int4(0, 0, 0, 1); switch(state.sourceFormat) { case FORMAT_A8B8G8R8I: c = Insert(c, Int(*Pointer(element + 3)), 3); case FORMAT_X8B8G8R8I: c = Insert(c, Int(*Pointer(element + 2)), 2); case FORMAT_G8R8I: c = Insert(c, Int(*Pointer(element + 1)), 1); case FORMAT_R8I: c = Insert(c, Int(*Pointer(element)), 0); break; case FORMAT_A8B8G8R8UI: c = Insert(c, Int(*Pointer(element + 3)), 3); case FORMAT_X8B8G8R8UI: c = Insert(c, Int(*Pointer(element + 2)), 2); case FORMAT_G8R8UI: c = Insert(c, Int(*Pointer(element + 1)), 1); case FORMAT_R8UI: c = Insert(c, Int(*Pointer(element)), 0); break; case FORMAT_A16B16G16R16I: c = Insert(c, Int(*Pointer(element + 6)), 3); case FORMAT_X16B16G16R16I: c = Insert(c, Int(*Pointer(element + 4)), 2); case FORMAT_G16R16I: c = Insert(c, Int(*Pointer(element + 2)), 1); case FORMAT_R16I: c = Insert(c, Int(*Pointer(element)), 0); break; case FORMAT_A16B16G16R16UI: c = Insert(c, Int(*Pointer(element + 6)), 3); case FORMAT_X16B16G16R16UI: c = Insert(c, Int(*Pointer(element + 4)), 2); case FORMAT_G16R16UI: c = Insert(c, Int(*Pointer(element + 2)), 1); case FORMAT_R16UI: c = Insert(c, Int(*Pointer(element)), 0); break; case FORMAT_A32B32G32R32I: case FORMAT_A32B32G32R32UI: c = *Pointer(element); break; case FORMAT_X32B32G32R32I: case FORMAT_X32B32G32R32UI: c = Insert(c, *Pointer(element + 8), 2); case FORMAT_G32R32I: case FORMAT_G32R32UI: c = Insert(c, *Pointer(element + 4), 1); case FORMAT_R32I: case FORMAT_R32UI: c = Insert(c, *Pointer(element), 0); break; default: return false; } return true; } bool Blitter::write(Int4 &c, Pointer element, const State &state) { bool writeR = state.writeRed; bool writeG = state.writeGreen; bool writeB = state.writeBlue; bool writeA = state.writeAlpha; bool writeRGBA = writeR && writeG && writeB && writeA; switch(state.destFormat) { case FORMAT_A8B8G8R8I: if(writeA) { *Pointer(element + 3) = SByte(Extract(c, 3)); } case FORMAT_X8B8G8R8I: if(writeA && (state.destFormat != FORMAT_A8B8G8R8I)) { *Pointer(element + 3) = SByte(0x7F); } if(writeB) { *Pointer(element + 2) = SByte(Extract(c, 2)); } case FORMAT_G8R8I: if(writeG) { *Pointer(element + 1) = SByte(Extract(c, 1)); } case FORMAT_R8I: if(writeR) { *Pointer(element) = SByte(Extract(c, 0)); } break; case FORMAT_A8B8G8R8UI: if(writeA) { *Pointer(element + 3) = Byte(Extract(c, 3)); } case FORMAT_X8B8G8R8UI: if(writeA && (state.destFormat != FORMAT_A8B8G8R8UI)) { *Pointer(element + 3) = Byte(0xFF); } if(writeB) { *Pointer(element + 2) = Byte(Extract(c, 2)); } case FORMAT_G8R8UI: if(writeG) { *Pointer(element + 1) = Byte(Extract(c, 1)); } case FORMAT_R8UI: if(writeR) { *Pointer(element) = Byte(Extract(c, 0)); } break; case FORMAT_A16B16G16R16I: if(writeA) { *Pointer(element + 6) = Short(Extract(c, 3)); } case FORMAT_X16B16G16R16I: if(writeA && (state.destFormat != FORMAT_A16B16G16R16I)) { *Pointer(element + 6) = Short(0x7FFF); } if(writeB) { *Pointer(element + 4) = Short(Extract(c, 2)); } case FORMAT_G16R16I: if(writeG) { *Pointer(element + 2) = Short(Extract(c, 1)); } case FORMAT_R16I: if(writeR) { *Pointer(element) = Short(Extract(c, 0)); } break; case FORMAT_A16B16G16R16UI: if(writeA) { *Pointer(element + 6) = UShort(Extract(c, 3)); } case FORMAT_X16B16G16R16UI: if(writeA && (state.destFormat != FORMAT_A16B16G16R16UI)) { *Pointer(element + 6) = UShort(0xFFFF); } if(writeB) { *Pointer(element + 4) = UShort(Extract(c, 2)); } case FORMAT_G16R16UI: if(writeG) { *Pointer(element + 2) = UShort(Extract(c, 1)); } case FORMAT_R16UI: if(writeR) { *Pointer(element) = UShort(Extract(c, 0)); } break; case FORMAT_A32B32G32R32I: if(writeRGBA) { *Pointer(element) = c; } else { if(writeR) { *Pointer(element) = Extract(c, 0); } if(writeG) { *Pointer(element + 4) = Extract(c, 1); } if(writeB) { *Pointer(element + 8) = Extract(c, 2); } if(writeA) { *Pointer(element + 12) = Extract(c, 3); } } break; case FORMAT_X32B32G32R32I: if(writeRGBA) { *Pointer(element) = c; } else { if(writeR) { *Pointer(element) = Extract(c, 0); } if(writeG) { *Pointer(element + 4) = Extract(c, 1); } if(writeB) { *Pointer(element + 8) = Extract(c, 2); } } if(writeA) { *Pointer(element + 12) = Int(0x7FFFFFFF); } break; case FORMAT_G32R32I: if(writeR) { *Pointer(element) = Extract(c, 0); } if(writeG) { *Pointer(element + 4) = Extract(c, 1); } break; case FORMAT_R32I: if(writeR) { *Pointer(element) = Extract(c, 0); } break; case FORMAT_A32B32G32R32UI: if(writeRGBA) { *Pointer(element) = As(c); } else { if(writeR) { *Pointer(element) = As(Extract(c, 0)); } if(writeG) { *Pointer(element + 4) = As(Extract(c, 1)); } if(writeB) { *Pointer(element + 8) = As(Extract(c, 2)); } if(writeA) { *Pointer(element + 12) = As(Extract(c, 3)); } } break; case FORMAT_X32B32G32R32UI: if(writeRGBA) { *Pointer(element) = As(c); } else { if(writeR) { *Pointer(element) = As(Extract(c, 0)); } if(writeG) { *Pointer(element + 4) = As(Extract(c, 1)); } if(writeB) { *Pointer(element + 8) = As(Extract(c, 2)); } } if(writeA) { *Pointer(element + 3) = UInt(0xFFFFFFFF); } break; case FORMAT_G32R32UI: if(writeR) { *Pointer(element) = As(Extract(c, 0)); } if(writeG) { *Pointer(element + 4) = As(Extract(c, 1)); } break; case FORMAT_R32UI: if(writeR) { *Pointer(element) = As(Extract(c, 0)); } break; default: return false; } return true; } bool Blitter::GetScale(float4 &scale, Format format) { switch(format) { case FORMAT_L8: case FORMAT_A8: case FORMAT_A8R8G8B8: case FORMAT_X8R8G8B8: case FORMAT_R8: case FORMAT_G8R8: case FORMAT_R8G8B8: case FORMAT_B8G8R8: case FORMAT_X8B8G8R8: case FORMAT_A8B8G8R8: case FORMAT_SRGB8_X8: case FORMAT_SRGB8_A8: scale = vector(0xFF, 0xFF, 0xFF, 0xFF); break; case FORMAT_R8_SNORM: case FORMAT_G8R8_SNORM: case FORMAT_X8B8G8R8_SNORM: case FORMAT_A8B8G8R8_SNORM: scale = vector(0x7F, 0x7F, 0x7F, 0x7F); break; case FORMAT_A16B16G16R16: scale = vector(0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF); break; case FORMAT_R8I: case FORMAT_R8UI: case FORMAT_G8R8I: case FORMAT_G8R8UI: case FORMAT_X8B8G8R8I: case FORMAT_X8B8G8R8UI: case FORMAT_A8B8G8R8I: case FORMAT_A8B8G8R8UI: case FORMAT_R16I: case FORMAT_R16UI: case FORMAT_G16R16: case FORMAT_G16R16I: case FORMAT_G16R16UI: case FORMAT_X16B16G16R16I: case FORMAT_X16B16G16R16UI: case FORMAT_A16B16G16R16I: case FORMAT_A16B16G16R16UI: case FORMAT_R32I: case FORMAT_R32UI: case FORMAT_G32R32I: case FORMAT_G32R32UI: case FORMAT_X32B32G32R32I: case FORMAT_X32B32G32R32UI: case FORMAT_A32B32G32R32I: case FORMAT_A32B32G32R32UI: case FORMAT_A32B32G32R32F: case FORMAT_X32B32G32R32F: case FORMAT_X32B32G32R32F_UNSIGNED: case FORMAT_B32G32R32F: case FORMAT_G32R32F: case FORMAT_R32F: case FORMAT_A2B10G10R10UI: scale = vector(1.0f, 1.0f, 1.0f, 1.0f); break; case FORMAT_R5G6B5: scale = vector(0x1F, 0x3F, 0x1F, 1.0f); break; case FORMAT_A2B10G10R10: scale = vector(0x3FF, 0x3FF, 0x3FF, 0x03); break; case FORMAT_D16: scale = vector(0xFFFF, 0.0f, 0.0f, 0.0f); break; case FORMAT_D24S8: case FORMAT_D24X8: scale = vector(0xFFFFFF, 0.0f, 0.0f, 0.0f); break; case FORMAT_D32: scale = vector(static_cast(0xFFFFFFFF), 0.0f, 0.0f, 0.0f); break; case FORMAT_D32F: case FORMAT_D32FS8: case FORMAT_D32F_COMPLEMENTARY: case FORMAT_D32FS8_COMPLEMENTARY: case FORMAT_D32F_LOCKABLE: case FORMAT_D32FS8_TEXTURE: case FORMAT_D32F_SHADOW: case FORMAT_D32FS8_SHADOW: case FORMAT_S8: scale = vector(1.0f, 1.0f, 1.0f, 1.0f); break; default: return false; } return true; } bool Blitter::ApplyScaleAndClamp(Float4 &value, const State &state, bool preScaled) { float4 scale, unscale; if(state.clearOperation && Surface::isNonNormalizedInteger(state.sourceFormat) && !Surface::isNonNormalizedInteger(state.destFormat)) { // If we're clearing a buffer from an int or uint color into a normalized color, // then the whole range of the int or uint color must be scaled between 0 and 1. switch(state.sourceFormat) { case FORMAT_A32B32G32R32I: unscale = replicate(static_cast(0x7FFFFFFF)); break; case FORMAT_A32B32G32R32UI: unscale = replicate(static_cast(0xFFFFFFFF)); break; default: return false; } } else if(!GetScale(unscale, state.sourceFormat)) { return false; } if(!GetScale(scale, state.destFormat)) { return false; } bool srcSRGB = Surface::isSRGBformat(state.sourceFormat); bool dstSRGB = Surface::isSRGBformat(state.destFormat); if(state.convertSRGB && ((srcSRGB && !preScaled) || dstSRGB)) // One of the formats is sRGB encoded. { value *= preScaled ? Float4(1.0f / scale.x, 1.0f / scale.y, 1.0f / scale.z, 1.0f / scale.w) : // Unapply scale Float4(1.0f / unscale.x, 1.0f / unscale.y, 1.0f / unscale.z, 1.0f / unscale.w); // Apply unscale value = (srcSRGB && !preScaled) ? sRGBtoLinear(value) : LinearToSRGB(value); value *= Float4(scale.x, scale.y, scale.z, scale.w); // Apply scale } else if(unscale != scale) { value *= Float4(scale.x / unscale.x, scale.y / unscale.y, scale.z / unscale.z, scale.w / unscale.w); } if(state.destFormat == FORMAT_X32B32G32R32F_UNSIGNED) { value = Max(value, Float4(0.0f)); // TODO: Only necessary if source is signed. } else if(Surface::isFloatFormat(state.sourceFormat) && !Surface::isFloatFormat(state.destFormat)) { value = Min(value, Float4(scale.x, scale.y, scale.z, scale.w)); value = Max(value, Float4(Surface::isUnsignedComponent(state.destFormat, 0) ? 0.0f : -scale.x, Surface::isUnsignedComponent(state.destFormat, 1) ? 0.0f : -scale.y, Surface::isUnsignedComponent(state.destFormat, 2) ? 0.0f : -scale.z, Surface::isUnsignedComponent(state.destFormat, 3) ? 0.0f : -scale.w)); } return true; } Int Blitter::ComputeOffset(Int &x, Int &y, Int &pitchB, int bytes, bool quadLayout) { if(!quadLayout) { return y * pitchB + x * bytes; } else { // (x & ~1) * 2 + (x & 1) == (x - (x & 1)) * 2 + (x & 1) == x * 2 - (x & 1) * 2 + (x & 1) == x * 2 - (x & 1) return (y & Int(~1)) * pitchB + ((y & Int(1)) * 2 + x * 2 - (x & Int(1))) * bytes; } } Float4 Blitter::LinearToSRGB(Float4 &c) { Float4 lc = Min(c, Float4(0.0031308f)) * Float4(12.92f); Float4 ec = Float4(1.055f) * power(c, Float4(1.0f / 2.4f)) - Float4(0.055f); Float4 s = c; s.xyz = Max(lc, ec); return s; } Float4 Blitter::sRGBtoLinear(Float4 &c) { Float4 lc = c * Float4(1.0f / 12.92f); Float4 ec = power((c + Float4(0.055f)) * Float4(1.0f / 1.055f), Float4(2.4f)); Int4 linear = CmpLT(c, Float4(0.04045f)); Float4 s = c; s.xyz = As((linear & As(lc)) | (~linear & As(ec))); // TODO: IfThenElse() return s; } std::shared_ptr Blitter::generate(const State &state) { Function)> function; { Pointer blit(function.Arg<0>()); Pointer source = *Pointer>(blit + OFFSET(BlitData,source)); Pointer dest = *Pointer>(blit + OFFSET(BlitData,dest)); Int sPitchB = *Pointer(blit + OFFSET(BlitData,sPitchB)); Int dPitchB = *Pointer(blit + OFFSET(BlitData,dPitchB)); Float x0 = *Pointer(blit + OFFSET(BlitData,x0)); Float y0 = *Pointer(blit + OFFSET(BlitData,y0)); Float w = *Pointer(blit + OFFSET(BlitData,w)); Float h = *Pointer(blit + OFFSET(BlitData,h)); Int x0d = *Pointer(blit + OFFSET(BlitData,x0d)); Int x1d = *Pointer(blit + OFFSET(BlitData,x1d)); Int y0d = *Pointer(blit + OFFSET(BlitData,y0d)); Int y1d = *Pointer(blit + OFFSET(BlitData,y1d)); Int sWidth = *Pointer(blit + OFFSET(BlitData,sWidth)); Int sHeight = *Pointer(blit + OFFSET(BlitData,sHeight)); bool intSrc = Surface::isNonNormalizedInteger(state.sourceFormat); bool intDst = Surface::isNonNormalizedInteger(state.destFormat); bool intBoth = intSrc && intDst; bool srcQuadLayout = Surface::hasQuadLayout(state.sourceFormat); bool dstQuadLayout = Surface::hasQuadLayout(state.destFormat); int srcBytes = Surface::bytes(state.sourceFormat); int dstBytes = Surface::bytes(state.destFormat); bool hasConstantColorI = false; Int4 constantColorI; bool hasConstantColorF = false; Float4 constantColorF; if(state.clearOperation) { if(intBoth) // Integer types { if(!read(constantColorI, source, state)) { return nullptr; } hasConstantColorI = true; } else { if(!read(constantColorF, source, state)) { return nullptr; } hasConstantColorF = true; if(!ApplyScaleAndClamp(constantColorF, state)) { return nullptr; } } } For(Int j = y0d, j < y1d, j++) { Float y = state.clearOperation ? RValue(y0) : y0 + Float(j) * h; Pointer destLine = dest + (dstQuadLayout ? j & Int(~1) : RValue(j)) * dPitchB; For(Int i = x0d, i < x1d, i++) { Float x = state.clearOperation ? RValue(x0) : x0 + Float(i) * w; Pointer d = destLine + (dstQuadLayout ? (((j & Int(1)) << 1) + (i * 2) - (i & Int(1))) : RValue(i)) * dstBytes; if(hasConstantColorI) { if(!write(constantColorI, d, state)) { return nullptr; } } else if(hasConstantColorF) { for(int s = 0; s < state.destSamples; s++) { if(!write(constantColorF, d, state)) { return nullptr; } d += *Pointer(blit + OFFSET(BlitData, dSliceB)); } } else if(intBoth) // Integer types do not support filtering { Int4 color; // When both formats are true integer types, we don't go to float to avoid losing precision Int X = Int(x); Int Y = Int(y); if(state.clampToEdge) { X = Clamp(X, 0, sWidth - 1); Y = Clamp(Y, 0, sHeight - 1); } Pointer s = source + ComputeOffset(X, Y, sPitchB, srcBytes, srcQuadLayout); if(!read(color, s, state)) { return nullptr; } if(!write(color, d, state)) { return nullptr; } } else { Float4 color; bool preScaled = false; if(!state.filter || intSrc) { Int X = Int(x); Int Y = Int(y); if(state.clampToEdge) { X = Clamp(X, 0, sWidth - 1); Y = Clamp(Y, 0, sHeight - 1); } Pointer s = source + ComputeOffset(X, Y, sPitchB, srcBytes, srcQuadLayout); if(!read(color, s, state)) { return nullptr; } } else // Bilinear filtering { Float X = x; Float Y = y; if(state.clampToEdge) { X = Min(Max(x, 0.5f), Float(sWidth) - 0.5f); Y = Min(Max(y, 0.5f), Float(sHeight) - 0.5f); } Float x0 = X - 0.5f; Float y0 = Y - 0.5f; Int X0 = Max(Int(x0), 0); Int Y0 = Max(Int(y0), 0); Int X1 = X0 + 1; Int Y1 = Y0 + 1; X1 = IfThenElse(X1 >= sWidth, X0, X1); Y1 = IfThenElse(Y1 >= sHeight, Y0, Y1); Pointer s00 = source + ComputeOffset(X0, Y0, sPitchB, srcBytes, srcQuadLayout); Pointer s01 = source + ComputeOffset(X1, Y0, sPitchB, srcBytes, srcQuadLayout); Pointer s10 = source + ComputeOffset(X0, Y1, sPitchB, srcBytes, srcQuadLayout); Pointer s11 = source + ComputeOffset(X1, Y1, sPitchB, srcBytes, srcQuadLayout); Float4 c00; if(!read(c00, s00, state)) return nullptr; Float4 c01; if(!read(c01, s01, state)) return nullptr; Float4 c10; if(!read(c10, s10, state)) return nullptr; Float4 c11; if(!read(c11, s11, state)) return nullptr; if(state.convertSRGB && Surface::isSRGBformat(state.sourceFormat)) // sRGB -> RGB { if(!ApplyScaleAndClamp(c00, state)) return nullptr; if(!ApplyScaleAndClamp(c01, state)) return nullptr; if(!ApplyScaleAndClamp(c10, state)) return nullptr; if(!ApplyScaleAndClamp(c11, state)) return nullptr; preScaled = true; } Float4 fx = Float4(x0 - Float(X0)); Float4 fy = Float4(y0 - Float(Y0)); Float4 ix = Float4(1.0f) - fx; Float4 iy = Float4(1.0f) - fy; color = (c00 * ix + c01 * fx) * iy + (c10 * ix + c11 * fx) * fy; } if(!ApplyScaleAndClamp(color, state, preScaled)) { return nullptr; } for(int s = 0; s < state.destSamples; s++) { if(!write(color, d, state)) { return nullptr; } d += *Pointer(blit + OFFSET(BlitData,dSliceB)); } } } } } return function("BlitRoutine"); } bool Blitter::blitReactor(Surface *source, const SliceRectF &sourceRect, Surface *dest, const SliceRect &destRect, const Blitter::Options &options) { ASSERT(!options.clearOperation || ((source->getWidth() == 1) && (source->getHeight() == 1) && (source->getDepth() == 1))); Rect dRect = destRect; RectF sRect = sourceRect; if(destRect.x0 > destRect.x1) { swap(dRect.x0, dRect.x1); swap(sRect.x0, sRect.x1); } if(destRect.y0 > destRect.y1) { swap(dRect.y0, dRect.y1); swap(sRect.y0, sRect.y1); } State state(options); state.clampToEdge = (sourceRect.x0 < 0.0f) || (sourceRect.y0 < 0.0f) || (sourceRect.x1 > (float)source->getWidth()) || (sourceRect.y1 > (float)source->getHeight()); bool useSourceInternal = !source->isExternalDirty(); bool useDestInternal = !dest->isExternalDirty(); bool isStencil = options.useStencil; state.sourceFormat = isStencil ? source->getStencilFormat() : source->getFormat(useSourceInternal); state.destFormat = isStencil ? dest->getStencilFormat() : dest->getFormat(useDestInternal); state.destSamples = dest->getSamples(); criticalSection.lock(); auto blitRoutine = blitCache->query(state); if(!blitRoutine) { blitRoutine = generate(state); if(!blitRoutine) { criticalSection.unlock(); return false; } blitCache->add(state, blitRoutine); } criticalSection.unlock(); void (*blitFunction)(const BlitData *data) = (void(*)(const BlitData*))blitRoutine->getEntry(); BlitData data; bool isRGBA = options.writeMask == 0xF; bool isEntireDest = dest->isEntire(destRect); data.source = isStencil ? source->lockStencil(0, 0, 0, sw::PUBLIC) : source->lock(0, 0, sourceRect.slice, sw::LOCK_READONLY, sw::PUBLIC, useSourceInternal); data.dest = isStencil ? dest->lockStencil(0, 0, 0, sw::PUBLIC) : dest->lock(0, 0, destRect.slice, isRGBA ? (isEntireDest ? sw::LOCK_DISCARD : sw::LOCK_WRITEONLY) : sw::LOCK_READWRITE, sw::PUBLIC, useDestInternal); data.sPitchB = isStencil ? source->getStencilPitchB() : source->getPitchB(useSourceInternal); data.dPitchB = isStencil ? dest->getStencilPitchB() : dest->getPitchB(useDestInternal); data.dSliceB = isStencil ? dest->getStencilSliceB() : dest->getSliceB(useDestInternal); data.w = sRect.width() / dRect.width(); data.h = sRect.height() / dRect.height(); data.x0 = sRect.x0 + (0.5f - dRect.x0) * data.w; data.y0 = sRect.y0 + (0.5f - dRect.y0) * data.h; data.x0d = dRect.x0; data.x1d = dRect.x1; data.y0d = dRect.y0; data.y1d = dRect.y1; data.sWidth = source->getWidth(); data.sHeight = source->getHeight(); blitFunction(&data); if(isStencil) { source->unlockStencil(); dest->unlockStencil(); } else { source->unlock(useSourceInternal); dest->unlock(useDestInternal); } return true; } }