dhewm3-sdk/idlib/math/Simd_SSE3.cpp
dhewg 055b80e859 Always compile all SIMD code
Protect all SIMD implementations with the according defines and
let the compiler decide if it supports the intructions.

Linux will still use Simd_Generic because CPU feature runtime
detection is missing.
2018-08-20 01:46:26 +02:00

367 lines
11 KiB
C++

/*
===========================================================================
Doom 3 GPL Source Code
Copyright (C) 1999-2011 id Software LLC, a ZeniMax Media company.
This file is part of the Doom 3 GPL Source Code ("Doom 3 Source Code").
Doom 3 Source Code 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 3 of the License, or
(at your option) any later version.
Doom 3 Source Code 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 Doom 3 Source Code. If not, see <http://www.gnu.org/licenses/>.
In addition, the Doom 3 Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#include "../precompiled.h"
#pragma hdrstop
#include "Simd_Generic.h"
#include "Simd_MMX.h"
#include "Simd_SSE.h"
#include "Simd_SSE2.h"
#include "Simd_SSE3.h"
//===============================================================
//
// SSE3 implementation of idSIMDProcessor
//
//===============================================================
#if defined(__GNUC__) && defined(__SSE3__)
/*
============
idSIMD_SSE3::GetName
============
*/
const char * idSIMD_SSE3::GetName( void ) const {
return "MMX & SSE & SSE2 & SSE3";
}
#elif defined(_WIN32)
#include <xmmintrin.h>
#define SHUFFLEPS( x, y, z, w ) (( (x) & 3 ) << 6 | ( (y) & 3 ) << 4 | ( (z) & 3 ) << 2 | ( (w) & 3 ))
#define R_SHUFFLEPS( x, y, z, w ) (( (w) & 3 ) << 6 | ( (z) & 3 ) << 4 | ( (y) & 3 ) << 2 | ( (x) & 3 ))
#define SHUFFLEPD( x, y ) (( (x) & 1 ) << 1 | ( (y) & 1 ))
#define R_SHUFFLEPD( x, y ) (( (y) & 1 ) << 1 | ( (x) & 1 ))
/*
The first argument of an instruction macro is the destination
and the second argument is the source operand. The destination
operand can be _xmm0 to _xmm7 only. The source operand can be
any one of the registers _xmm0 to _xmm7 or _eax, _ecx, _edx, _esp,
_ebp, _ebx, _esi, or _edi that contains the effective address.
For instance: haddps xmm0, xmm1
becomes: haddps( _xmm0, _xmm1 )
and: haddps xmm0, [esi]
becomes: haddps( _xmm0, _esi )
The ADDRESS_ADDC macro can be used when the effective source address
is formed by adding a constant to a general purpose register.
For instance: haddps xmm0, [esi+48]
becomes: haddps( _xmm0, ADDRESS_ADDC( _esi, 48 ) )
The ADDRESS_ADDR macro can be used when the effective source address
is formed by adding two general purpose registers.
For instance: haddps xmm0, [esi+eax]
becomes: haddps( _xmm0, ADDRESS_ADDR( _esi, _eax ) )
The ADDRESS_ADDRC macro can be used when the effective source address
is formed by adding two general purpose registers and a constant.
The constant must be in the range [-128, 127].
For instance: haddps xmm0, [esi+eax+48]
becomes: haddps( _xmm0, ADDRESS_ADDRC( _esi, _eax, 48 ) )
The ADDRESS_SCALEADDR macro can be used when the effective source address is formed
by adding a scaled general purpose register to another general purpose register.
The scale must be either 1, 2, 4 or 8.
For instance: haddps xmm0, [esi+eax*4]
becomes: haddps( _xmm0, ADDRESS_SCALEADDR( _esi, _eax, 4 ) )
The ADDRESS_SCALEADDRC macro can be used when the effective source address is formed
by adding a scaled general purpose register to another general purpose register and
also adding a constant. The scale must be either 1, 2, 4 or 8. The constant must
be in the range [-128, 127].
For instance: haddps xmm0, [esi+eax*4+64]
becomes: haddps( _xmm0, ADDRESS_SCALEADDRC( _esi, _eax, 4, 64 ) )
*/
#define _eax 0x00
#define _ecx 0x01
#define _edx 0x02
#define _ebx 0x03
#define _esp 0x04
#define _ebp 0x05
#define _esi 0x06
#define _edi 0x07
#define _xmm0 0xC0
#define _xmm1 0xC1
#define _xmm2 0xC2
#define _xmm3 0xC3
#define _xmm4 0xC4
#define _xmm5 0xC5
#define _xmm6 0xC6
#define _xmm7 0xC7
#define RSCALE( s ) ( (s&2)<<5 ) | ( (s&4)<<5 ) | ( (s&8)<<3 ) | ( (s&8)<<4 )
#define ADDRESS_ADDC( reg0, constant ) 0x40 | ( reg0 & 7 ) \
_asm _emit constant
#define ADDRESS_ADDR( reg0, reg1 ) 0x04 \
_asm _emit ( ( reg1 & 7 ) << 3 ) | ( reg0 & 7 )
#define ADDRESS_ADDRC( reg0, reg1, constant ) 0x44 \
_asm _emit ( ( reg1 & 7 ) << 3 ) | ( reg0 & 7 ) \
_asm _emit constant
#define ADDRESS_SCALEADDR( reg0, reg1, scale ) 0x04 \
_asm _emit ( ( reg1 & 7 ) << 3 ) | ( reg0 & 7 ) | RSCALE( scale )
#define ADDRESS_SCALEADDRC( reg0, reg1, scale, constant ) 0x44 \
_asm _emit ( ( reg1 & 7 ) << 3 ) | ( reg0 & 7 ) | RSCALE( scale ) \
_asm _emit constant
// Packed Single-FP Add/Subtract ( dst[0]=dst[0]+src[0], dst[1]=dst[1]-src[1], dst[2]=dst[2]+src[2], dst[3]=dst[3]-src[3] )
#define addsubps( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0xD0 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Packed Double-FP Add/Subtract ( dst[0]=dst[0]+src[0], dst[1]=dst[1]-src[1] )
#define addsubpd( dst, src ) \
_asm _emit 0x66 \
_asm _emit 0x0F \
_asm _emit 0xD0 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Packed Single-FP Horizontal Add ( dst[0]=dst[0]+dst[1], dst[1]=dst[2]+dst[3], dst[2]=src[0]+src[1], dst[3]=src[2]+src[3] )
#define haddps( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0x7C \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Packed Double-FP Horizontal Add ( dst[0]=dst[0]+dst[1], dst[1]=src[0]+src[1] )
#define haddpd( dst, src ) \
_asm _emit 0x66 \
_asm _emit 0x0F \
_asm _emit 0x7C \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Packed Single-FP Horizontal Subtract ( dst[0]=dst[0]-dst[1], dst[1]=dst[2]-dst[3], dst[2]=src[0]-src[1], dst[3]=src[2]-src[3] )
#define hsubps( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0x7D \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Packed Double-FP Horizontal Subtract ( dst[0]=dst[0]-dst[1], dst[1]=src[0]-src[1] )
#define hsubpd( dst, src ) \
_asm _emit 0x66 \
_asm _emit 0x0F \
_asm _emit 0x7D \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Move Packed Single-FP Low and Duplicate ( dst[0]=src[0], dst[1]=src[0], dst[2]=src[2], dst[3]=src[2] )
#define movsldup( dst, src ) \
_asm _emit 0xF3 \
_asm _emit 0x0F \
_asm _emit 0x12 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Move One Double-FP Low and Duplicate ( dst[0]=src[0], dst[1]=src[0] )
#define movdldup( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0x12 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Move Packed Single-FP High and Duplicate ( dst[0]=src[1], dst[1]=src[1], dst[2]=src[3], dst[3]=src[3] )
#define movshdup( dst, src ) \
_asm _emit 0xF3 \
_asm _emit 0x0F \
_asm _emit 0x16 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Move One Double-FP High and Duplicate ( dst[0]=src[1], dst[1]=src[1] )
#define movdhdup( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0x16 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
// Load Unaligned Integer 128 bits
#define lddqu( dst, src ) \
_asm _emit 0xF2 \
_asm _emit 0x0F \
_asm _emit 0xF0 \
_asm _emit ( ( dst & 7 ) << 3 ) | src
#define DRAWVERT_SIZE 60
#define DRAWVERT_XYZ_OFFSET (0*4)
#define DRAWVERT_ST_OFFSET (3*4)
#define DRAWVERT_NORMAL_OFFSET (5*4)
#define DRAWVERT_TANGENT0_OFFSET (8*4)
#define DRAWVERT_TANGENT1_OFFSET (11*4)
#define DRAWVERT_COLOR_OFFSET (14*4)
#define JOINTQUAT_SIZE (7*4)
#define JOINTMAT_SIZE (4*3*4)
#define JOINTWEIGHT_SIZE (4*4)
/*
============
SSE3_Dot
============
*/
float SSE3_Dot( const idVec4 &v1, const idVec4 &v2 ) {
float d;
__asm {
mov esi, v1
mov edi, v2
movaps xmm0, [esi]
mulps xmm0, [edi]
haddps( _xmm0, _xmm0 )
haddps( _xmm0, _xmm0 )
movss d, xmm0
}
return d;
}
/*
============
idSIMD_SSE3::GetName
============
*/
const char * idSIMD_SSE3::GetName( void ) const {
return "MMX & SSE & SSE2 & SSE3";
}
/*
============
idSIMD_SSE3::TransformVerts
============
*/
void VPCALL idSIMD_SSE3::TransformVerts( idDrawVert *verts, const int numVerts, const idJointMat *joints, const idVec4 *weights, const int *index, const int numWeights ) {
#if 1
assert( sizeof( idDrawVert ) == DRAWVERT_SIZE );
assert( (int)&((idDrawVert *)0)->xyz == DRAWVERT_XYZ_OFFSET );
assert( sizeof( idVec4 ) == JOINTWEIGHT_SIZE );
assert( sizeof( idJointMat ) == JOINTMAT_SIZE );
__asm
{
mov eax, numVerts
test eax, eax
jz done
imul eax, DRAWVERT_SIZE
mov ecx, verts
mov edx, index
mov esi, weights
mov edi, joints
add ecx, eax
neg eax
loopVert:
mov ebx, [edx]
movaps xmm2, [esi]
add edx, 8
movaps xmm0, xmm2
add esi, JOINTWEIGHT_SIZE
movaps xmm1, xmm2
mulps xmm0, [edi+ebx+ 0] // xmm0 = m0, m1, m2, t0
mulps xmm1, [edi+ebx+16] // xmm1 = m3, m4, m5, t1
mulps xmm2, [edi+ebx+32] // xmm2 = m6, m7, m8, t2
cmp dword ptr [edx-4], 0
jne doneWeight
loopWeight:
mov ebx, [edx]
movaps xmm5, [esi]
add edx, 8
movaps xmm3, xmm5
add esi, JOINTWEIGHT_SIZE
movaps xmm4, xmm5
mulps xmm3, [edi+ebx+ 0] // xmm3 = m0, m1, m2, t0
mulps xmm4, [edi+ebx+16] // xmm4 = m3, m4, m5, t1
mulps xmm5, [edi+ebx+32] // xmm5 = m6, m7, m8, t2
cmp dword ptr [edx-4], 0
addps xmm0, xmm3
addps xmm1, xmm4
addps xmm2, xmm5
je loopWeight
doneWeight:
add eax, DRAWVERT_SIZE
haddps( _xmm0, _xmm1 )
haddps( _xmm2, _xmm0 )
movhps [ecx+eax-DRAWVERT_SIZE+0], xmm2
haddps( _xmm2, _xmm2 )
movss [ecx+eax-DRAWVERT_SIZE+8], xmm2
jl loopVert
done:
}
#else
int i, j;
const byte *jointsPtr = (byte *)joints;
for( j = i = 0; i < numVerts; i++ ) {
idVec3 v;
v = ( *(idJointMat *) ( jointsPtr + index[j*2+0] ) ) * weights[j];
while( index[j*2+1] == 0 ) {
j++;
v += ( *(idJointMat *) ( jointsPtr + index[j*2+0] ) ) * weights[j];
}
j++;
verts[i].xyz = v;
}
#endif
}
#endif /* _WIN32 */