// Copyright 2013 Dolphin Emulator Project // Licensed under GPLv2 // Refer to the license.txt file included. #include "Common.h" #include "VideoCommon.h" #include "VertexLoader.h" #include "VertexLoader_Normal.h" #include "VertexManagerBase.h" #include "CPUDetect.h" #include #include #if _M_SSE >= 0x401 #include #include #elif _M_SSE >= 0x301 && !(defined __GNUC__ && !defined __SSSE3__) #include #endif // warning: mapping buffer should be disabled to use this #define LOG_NORM() // PRIM_LOG("norm: %f %f %f, ", ((float*)VertexManager::s_pCurBufferPointer)[-3], ((float*)VertexManager::s_pCurBufferPointer)[-2], ((float*)VertexManager::s_pCurBufferPointer)[-1]); VertexLoader_Normal::Set VertexLoader_Normal::m_Table[NUM_NRM_TYPE][NUM_NRM_INDICES][NUM_NRM_ELEMENTS][NUM_NRM_FORMAT]; namespace { template __forceinline float FracAdjust(T val) { //auto const S8FRAC = 1.f / (1u << 6); //auto const U8FRAC = 1.f / (1u << 7); //auto const S16FRAC = 1.f / (1u << 14); //auto const U16FRAC = 1.f / (1u << 15); // TODO: is this right? return val / float(1u << (sizeof(T) * 8 - std::numeric_limits::is_signed - 1)); } template <> __forceinline float FracAdjust(float val) { return val; } template __forceinline void ReadIndirect(const T* data) { static_assert(3 == N || 9 == N, "N is only sane as 3 or 9!"); DataWriter dst; for (int i = 0; i != N; ++i) { dst.Write(FracAdjust(Common::FromBigEndian(data[i]))); } LOG_NORM(); } template struct Normal_Direct { static void LOADERDECL function() { auto const source = reinterpret_cast(DataGetPosition()); ReadIndirect(source); DataSkip(); } static const int size = sizeof(T) * N * 3; }; template __forceinline void Normal_Index_Offset() { static_assert(!std::numeric_limits::is_signed, "Only unsigned I is sane!"); auto const index = DataRead(); auto const data = reinterpret_cast(cached_arraybases[ARRAY_NORMAL] + (index * arraystrides[ARRAY_NORMAL]) + sizeof(T) * 3 * Offset); ReadIndirect(data); } template struct Normal_Index { static void LOADERDECL function() { Normal_Index_Offset(); } static const int size = sizeof(I); }; template struct Normal_Index_Indices3 { static void LOADERDECL function() { Normal_Index_Offset(); Normal_Index_Offset(); Normal_Index_Offset(); } static const int size = sizeof(I) * 3; }; } void VertexLoader_Normal::Init(void) { m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT] [FORMAT_UBYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT] [FORMAT_BYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT] [FORMAT_USHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT] [FORMAT_SHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT] [FORMAT_FLOAT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT3][FORMAT_UBYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT3][FORMAT_BYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT3][FORMAT_USHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT3][FORMAT_SHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES1][NRM_NBT3][FORMAT_FLOAT] = Normal_Direct(); // Same as above m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT] [FORMAT_UBYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT] [FORMAT_BYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT] [FORMAT_USHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT] [FORMAT_SHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT] [FORMAT_FLOAT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT3][FORMAT_UBYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT3][FORMAT_BYTE] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT3][FORMAT_USHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT3][FORMAT_SHORT] = Normal_Direct(); m_Table[NRM_DIRECT] [NRM_INDICES3][NRM_NBT3][FORMAT_FLOAT] = Normal_Direct(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT] [FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT] [FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT] [FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT] [FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT] [FORMAT_FLOAT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT3][FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT3][FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT3][FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT3][FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES1][NRM_NBT3][FORMAT_FLOAT] = Normal_Index(); // Same as above for NRM_NBT m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT] [FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT] [FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT] [FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT] [FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT] [FORMAT_FLOAT] = Normal_Index(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT3][FORMAT_UBYTE] = Normal_Index_Indices3(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT3][FORMAT_BYTE] = Normal_Index_Indices3(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT3][FORMAT_USHORT] = Normal_Index_Indices3(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT3][FORMAT_SHORT] = Normal_Index_Indices3(); m_Table[NRM_INDEX8] [NRM_INDICES3][NRM_NBT3][FORMAT_FLOAT] = Normal_Index_Indices3(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT] [FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT] [FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT] [FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT] [FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT] [FORMAT_FLOAT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT3][FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT3][FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT3][FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT3][FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES1][NRM_NBT3][FORMAT_FLOAT] = Normal_Index(); // Same as above for NRM_NBT m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT] [FORMAT_UBYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT] [FORMAT_BYTE] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT] [FORMAT_USHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT] [FORMAT_SHORT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT] [FORMAT_FLOAT] = Normal_Index(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT3][FORMAT_UBYTE] = Normal_Index_Indices3(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT3][FORMAT_BYTE] = Normal_Index_Indices3(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT3][FORMAT_USHORT] = Normal_Index_Indices3(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT3][FORMAT_SHORT] = Normal_Index_Indices3(); m_Table[NRM_INDEX16][NRM_INDICES3][NRM_NBT3][FORMAT_FLOAT] = Normal_Index_Indices3(); } unsigned int VertexLoader_Normal::GetSize(unsigned int _type, unsigned int _format, unsigned int _elements, unsigned int _index3) { return m_Table[_type][_index3][_elements][_format].gc_size; } TPipelineFunction VertexLoader_Normal::GetFunction(unsigned int _type, unsigned int _format, unsigned int _elements, unsigned int _index3) { TPipelineFunction pFunc = m_Table[_type][_index3][_elements][_format].function; return pFunc; }