// Copyright (C) 2004 Id Software, Inc. // #ifndef __MATH_SIMD_ALTIVEC_H__ #define __MATH_SIMD_ALTIVEC_H__ /* =============================================================================== AltiVec implementation of idSIMDProcessor =============================================================================== */ // Defines for enabling parts of the library #if 0 //DAJ turn them all off // Turns on/off the simple math routines (add, sub, div, etc) #define ENABLE_SIMPLE_MATH // Turns on/off the dot routines #define ENABLE_DOT // Turns on/off the compare routines #define ENABLE_COMPARES // Turns on/off MinMax routines #define ENABLE_MINMAX // Turns on/off Clamp routines #define ENABLE_CLAMP // Turns on/off XXX16 routines #define ENABLE_16ROUTINES // Turns on/off LowerTriangularSolve, LowerTriangularSolveTranspose, and MatX_LDLT_Factor #define ENABLE_LOWER_TRIANGULAR // Turns on/off TracePointCull, DecalPointCull, and OverlayPoint #define ENABLE_CULL // Turns on/off DeriveTriPlanes, DeriveTangents, DeriveUnsmoothedTangents, NormalizeTangents #define ENABLE_DERIVE // Turns on/off CreateShadowCache #define ENABLE_CREATE // Turns on/off the sound routines #define ENABLE_SOUND_ROUTINES // Turns on/off the stuff that isn't on elsewhere // Currently: BlendJoints, TransformJoints, UntransformJoints, ConvertJointQuatsToJointMats, and ConvertJointMatsToJointQuats #define LIVE_VICARIOUSLY // This assumes that the dest (and mixBuffer) array to the sound functions is aligned. If this is not true, we take a large // performance hit from having to do unaligned stores //#define SOUND_DEST_ALIGNED // This assumes that the vertexCache array to CreateShadowCache and CreateShadowCache is aligned. If it's not, // then we take a big performance hit from unaligned stores. //#define VERTEXCACHE_ALIGNED // This turns on support for PPC intrinsics in the SIMD_AltiVec.cpp file. Right now it's only used for frsqrte. GCC // supports these intrinsics but XLC does not. #define PPC_INTRINSICS // This assumes that idDrawVert has been padded by 4 bytes so that xyz always starts at an aligned // address #define DRAWVERT_PADDED #endif //DAJ class idSIMD_AltiVec : public idSIMD_Generic { #if defined(MACOS_X) && defined(__ppc__) //DAJ public: virtual const char * VPCALL GetName( void ) const; #ifdef ENABLE_SIMPLE_MATH // Basic math, works for both aligned and unaligned data virtual void VPCALL Add( float *dst, const float constant, const float *src, const int count ); virtual void VPCALL Add( float *dst, const float *src0, const float *src1, const int count ); virtual void VPCALL Sub( float *dst, const float constant, const float *src, const int count ); virtual void VPCALL Sub( float *dst, const float *src0, const float *src1, const int count ); virtual void VPCALL Mul( float *dst, const float constant, const float *src, const int count); virtual void VPCALL Mul( float *dst, const float *src0, const float *src1, const int count ); virtual void VPCALL Div( float *dst, const float constant, const float *divisor, const int count ); virtual void VPCALL Div( float *dst, const float *src0, const float *src1, const int count ); virtual void VPCALL MulAdd( float *dst, const float constant, const float *src, const int count ); virtual void VPCALL MulAdd( float *dst, const float *src0, const float *src1, const int count ); virtual void VPCALL MulSub( float *dst, const float constant, const float *src, const int count ); virtual void VPCALL MulSub( float *dst, const float *src0, const float *src1, const int count ); #endif #ifdef ENABLE_DOT // Dot products, expects data structures in contiguous memory virtual void VPCALL Dot( float *dst, const idVec3 &constant, const idVec3 *src, const int count ); virtual void VPCALL Dot( float *dst, const idVec3 &constant, const idPlane *src, const int count ); virtual void VPCALL Dot( float *dst, const idVec3 &constant, const idDrawVert *src, const int count ); virtual void VPCALL Dot( float *dst, const idPlane &constant,const idVec3 *src, const int count ); virtual void VPCALL Dot( float *dst, const idPlane &constant,const idPlane *src, const int count ); virtual void VPCALL Dot( float *dst, const idPlane &constant,const idDrawVert *src, const int count ); virtual void VPCALL Dot( float *dst, const idVec3 *src0, const idVec3 *src1, const int count ); virtual void VPCALL Dot( float &dot, const float *src1, const float *src2, const int count ); #endif #ifdef ENABLE_COMPARES // Comparisons, works for both aligned and unaligned data virtual void VPCALL CmpGT( byte *dst, const float *src0, const float constant, const int count ); virtual void VPCALL CmpGT( byte *dst, const byte bitNum, const float *src0, const float constant, const int count ); virtual void VPCALL CmpGE( byte *dst, const float *src0, const float constant, const int count ); virtual void VPCALL CmpGE( byte *dst, const byte bitNum, const float *src0, const float constant, const int count ); virtual void VPCALL CmpLT( byte *dst, const float *src0, const float constant, const int count ); virtual void VPCALL CmpLT( byte *dst, const byte bitNum, const float *src0, const float constant, const int count ); virtual void VPCALL CmpLE( byte *dst, const float *src0, const float constant, const int count ); virtual void VPCALL CmpLE( byte *dst, const byte bitNum, const float *src0, const float constant, const int count ); #endif #ifdef ENABLE_MINMAX // Min/Max. Expects data structures in contiguous memory virtual void VPCALL MinMax( float &min, float &max, const float *src, const int count ); virtual void VPCALL MinMax( idVec2 &min, idVec2 &max, const idVec2 *src, const int count ); virtual void VPCALL MinMax( idVec3 &min, idVec3 &max, const idVec3 *src, const int count ); virtual void VPCALL MinMax( idVec3 &min, idVec3 &max, const idDrawVert *src, const int count ); virtual void VPCALL MinMax( idVec3 &min, idVec3 &max, const idDrawVert *src, const int *indexes, const int count ); #endif #ifdef ENABLE_CLAMP // Clamp operations. Works for both aligned and unaligned data virtual void VPCALL Clamp( float *dst, const float *src, const float min, const float max, const int count ); virtual void VPCALL ClampMin( float *dst, const float *src, const float min, const int count ); virtual void VPCALL ClampMax( float *dst, const float *src, const float max, const int count ); #endif // These are already using memcpy and memset functions. Leaving default implementation // virtual void VPCALL Memcpy( void *dst, const void *src, const int count ); // virtual void VPCALL Memset( void *dst, const int val, const int count ); #ifdef ENABLE_16ROUTINES // Operations that expect 16-byte aligned data and 16-byte padded memory (with zeros), generally faster virtual void VPCALL Zero16( float *dst, const int count ); virtual void VPCALL Negate16( float *dst, const int count ); virtual void VPCALL Copy16( float *dst, const float *src, const int count ); virtual void VPCALL Add16( float *dst, const float *src1, const float *src2, const int count ); virtual void VPCALL Sub16( float *dst, const float *src1, const float *src2, const int count ); virtual void VPCALL Mul16( float *dst, const float *src1, const float constant, const int count ); virtual void VPCALL AddAssign16( float *dst, const float *src, const int count ); virtual void VPCALL SubAssign16( float *dst, const float *src, const int count ); virtual void VPCALL MulAssign16( float *dst, const float constant, const int count ); #endif // Most of these deal with tiny matrices or vectors, generally not worth altivec'ing since // the scalar code is already really fast // virtual void VPCALL MatX_MultiplyVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_MultiplyAddVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_MultiplySubVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_TransposeMultiplyVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_TransposeMultiplyAddVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_TransposeMultiplySubVecX( idVecX &dst, const idMatX &mat, const idVecX &vec ); // virtual void VPCALL MatX_MultiplyMatX( idMatX &dst, const idMatX &m1, const idMatX &m2 ); // virtual void VPCALL MatX_TransposeMultiplyMatX( idMatX &dst, const idMatX &m1, const idMatX &m2 ); #ifdef ENABLE_LOWER_TRIANGULAR virtual void VPCALL MatX_LowerTriangularSolve( const idMatX &L, float *x, const float *b, const int n, int skip = 0 ); virtual void VPCALL MatX_LowerTriangularSolveTranspose( const idMatX &L, float *x, const float *b, const int n ); virtual unsigned char VPCALL MatX_LDLT_Factor( idMatX &mat, idVecX &invDiag, const int n ); #endif #ifdef LIVE_VICARIOUSLY virtual void VPCALL BlendJoints( idJointQuat *joints, const idJointQuat *blendJoints, const float lerp, const int *index, const int numJoints ); virtual void VPCALL ConvertJointQuatsToJointMats( idJointMat *jointMats, const idJointQuat *jointQuats, const int numJoints ); virtual void VPCALL ConvertJointMatsToJointQuats( idJointQuat *jointQuats, const idJointMat *jointMats, const int numJoints ); #endif #ifdef LIVE_VICARIOUSLY virtual void VPCALL TransformJoints( idJointMat *jointMats, const int *parents, const int firstJoint, const int lastJoint ); virtual void VPCALL UntransformJoints( idJointMat *jointMats, const int *parents, const int firstJoint, const int lastJoint ); #endif #ifdef ENABLE_CULL virtual void VPCALL TracePointCull( byte *cullBits, byte &totalOr, const float radius, const idPlane *planes, const idDrawVert *verts, const int numVerts ); virtual void VPCALL DecalPointCull( byte *cullBits, const idPlane *planes, const idDrawVert *verts, const int numVerts ); virtual void VPCALL OverlayPointCull( byte *cullBits, idVec2 *texCoords, const idPlane *planes, const idDrawVert *verts, const int numVerts ); #endif #ifdef ENABLE_DERIVE virtual void VPCALL DeriveTriPlanes( idPlane *planes, const idDrawVert *verts, const int numVerts, const int *indexes, const int numIndexes ); #endif #ifdef ENABLE_CREATE virtual int VPCALL CreateShadowCache( idVec4 *vertexCache, const idDrawVert *verts, const int numVerts ); #endif #ifdef ENABLE_SOUND_ROUTINES // Sound upsampling and mixing routines, works for aligned and unaligned data virtual void VPCALL UpSamplePCMTo44kHz( float *dest, const short *pcm, const int numSamples, const int kHz, const int numChannels ); virtual void VPCALL UpSampleOGGTo44kHz( float *dest, const float * const *ogg, const int numSamples, const int kHz, const int numChannels ); virtual void VPCALL MixSoundTwoSpeakerMono( float *mixBuffer, const float *samples, const int numSamples, const float lastV[2], const float currentV[2] ); virtual void VPCALL MixSoundTwoSpeakerStereo( float *mixBuffer, const float *samples, const int numSamples, const float lastV[2], const float currentV[2] ); virtual void VPCALL MixSoundSixSpeakerMono( float *mixBuffer, const float *samples, const int numSamples, const float lastV[6], const float currentV[6] ); virtual void VPCALL MixSoundSixSpeakerStereo( float *mixBuffer, const float *samples, const int numSamples, const float lastV[6], const float currentV[6] ); virtual void VPCALL MixedSoundToSamples( short *samples, const float *mixBuffer, const int numSamples ); #endif #endif }; #endif /* !__MATH_SIMD_ALTIVEC_H__ */