pcsx2/plugins/zzogl-pg/opengl/Mem.cpp

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/* ZeroGS KOSMOS
* Copyright (C) 2005-2006 zerofrog@gmail.com
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "GS.h"
#include "Mem.h"
#include "zerogs.h"
#include "targets.h"
#include "x86.h"
#include "Mem_Transmit.h"
#include "Mem_Swizzle.h"
BLOCK m_Blocks[0x40]; // do so blocks are indexable
PCSX2_ALIGNED16(u32 tempblock[64]);
// Add a bunch of local variables that used to be in the TransferHostLocal
// functions, in order to de-macro the TransmitHostLocal macros.
// May be in a class or namespace eventually.
int tempX, tempY;
int pitch, area, fracX;
int nSize;
u8* pstart;
// ------------------------
// | Y |
// ------------------------
// | block | |
// | aligned area | X |
// | | |
// ------------------------
// | Y |
// ------------------------
template <class T>
static __forceinline const T* AlignOnBlockBoundry(TransferData data, TransferFuncts fun, Point alignedPt, int& endY, const T* pbuf)
{
bool bCanAlign = ((MOD_POW2(gs.trxpos.dx, data.blockwidth) == 0) && (gs.imageX == gs.trxpos.dx) &&
(alignedPt.y > endY) && (alignedPt.x > gs.trxpos.dx));
if ((gs.imageEndX - gs.trxpos.dx) % data.widthlimit)
{
/* hack */
int testwidth = (int)nSize -
(gs.imageEndY - gs.imageY) * (gs.imageEndX - gs.trxpos.dx)
+ (gs.imageX - gs.trxpos.dx);
if ((testwidth <= data.widthlimit) && (testwidth >= -data.widthlimit))
{
/* don't transfer */
/*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/
//ERROR_LOG("bad texture: testwidth = %d; data.widthlimit = %d\n", testwidth, data.widthlimit);
gs.imageTransfer = -1;
}
bCanAlign = false;
}
/* first align on block boundary */
if ( MOD_POW2(gs.imageY, data.blockheight) || !bCanAlign )
{
u32 transwidth;
if( !bCanAlign )
endY = gs.imageEndY; /* transfer the whole image */
else
assert( endY < gs.imageEndY); /* part of alignment condition */
if (((gs.imageEndX - gs.trxpos.dx) % data.widthlimit) || ((gs.imageEndX - gs.imageX) % data.widthlimit))
{
/* transmit with a width of 1 */
transwidth = (1 + (DSTPSM == PSMT4));
}
else
{
transwidth = data.widthlimit;
}
pbuf = TransmitHostLocalY<T>(data, fun.wp, transwidth, endY, pbuf);
if (pbuf == NULL) return NULL;
if( nSize == 0 || tempY == gs.imageEndY ) return NULL;
}
return pbuf;
}
template <class T>
static __forceinline const T* TransferAligningToBlocks(TransferData data, TransferFuncts fun, Point alignedPt, const T* pbuf)
{
bool bAligned;
const u32 TSize = sizeof(T);
_SwizzleBlock swizzle;
/* can align! */
pitch = gs.imageEndX - gs.trxpos.dx;
area = pitch * data.blockheight;
fracX = gs.imageEndX - alignedPt.x;
/* on top of checking whether pbuf is aligned, make sure that the width is at least aligned to its limits (due to bugs in pcsx2) */
bAligned = !((uptr)pbuf & 0xf) && (TransPitch(pitch, data.transfersize) & 0xf) == 0;
if ( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)))
swizzle = (fun.Swizzle);
else
swizzle = (fun.Swizzle_u);
//Transfer aligning to blocks.
for(; tempY < alignedPt.y && nSize >= area; tempY += data.blockheight, nSize -= area)
{
for(int tempj = gs.trxpos.dx; tempj < alignedPt.x; tempj += data.blockwidth, pbuf += TransPitch(data.blockwidth, data.transfersize)/TSize)
{
u8 *temp = pstart + fun.gp(tempj, tempY, gs.dstbuf.bw) * data.blockbits/8;
swizzle(temp, (u8*)pbuf, TransPitch(pitch, data.transfersize), 0xffffffff);
}
/* transfer the rest */
if (alignedPt.x < gs.imageEndX)
{
pbuf = TransmitHostLocalX<T>(data, fun.wp, data.widthlimit, data.blockheight, alignedPt.x, pbuf);
if (pbuf == NULL) return NULL;
pbuf -= TransPitch((alignedPt.x - gs.trxpos.dx), data.transfersize)/TSize;
}
else
{
pbuf += (data.blockheight - 1)* TransPitch(pitch, data.transfersize)/TSize;
}
tempX = gs.trxpos.dx;
}
return pbuf;
}
static __forceinline int FinishTransfer(TransferData data, int nLeftOver)
{
if( tempY >= gs.imageEndY )
{
assert( gs.imageTransfer == -1 || tempY == gs.imageEndY );
gs.imageTransfer = -1;
/*int start, end;
ZeroGS::GetRectMemAddress(start, end, gs.dstbuf.psm, gs.trxpos.dx, gs.trxpos.dy, gs.imageWnew, gs.imageHnew, gs.dstbuf.bp, gs.dstbuf.bw);
ZeroGS::g_MemTargs.ClearRange(start, end);*/
}
else
{
/* update new params */
gs.imageY = tempY;
gs.imageX = tempX;
}
return (nSize * TransPitch(2, data.transfersize) + nLeftOver)/2;
}
template <class T>
static __forceinline int RealTransfer(TransferData data, TransferFuncts fun, const void* pbyMem, u32 nQWordSize)
{
assert( gs.imageTransfer == 0 );
pstart = g_pbyGSMemory + gs.dstbuf.bp*256;
const T* pbuf = (const T*)pbyMem;
const int tp2 = TransPitch(2, data.transfersize);
int nLeftOver = (nQWordSize*4*2)%tp2;
tempY = gs.imageY; tempX = gs.imageX;
Point alignedPt;
nSize = (nQWordSize*4*2)/tp2;
nSize = min(nSize, gs.imageWnew * gs.imageHnew);
int endY = ROUND_UPPOW2(gs.imageY, data.blockheight);
alignedPt.y = ROUND_DOWNPOW2(gs.imageEndY, data.blockheight);
alignedPt.x = ROUND_DOWNPOW2(gs.imageEndX, data.blockwidth);
pbuf = AlignOnBlockBoundry<T>(data, fun, alignedPt, endY, pbuf);
if (pbuf == NULL) return FinishTransfer(data, nLeftOver);
pbuf = TransferAligningToBlocks<T>(data, fun, alignedPt, pbuf);
if (pbuf == NULL) return FinishTransfer(data, nLeftOver);
if (TransPitch(nSize, data.transfersize)/4 > 0)
{
pbuf = TransmitHostLocalY<T>(data, fun.wp, data.widthlimit, gs.imageEndY, pbuf);
if (pbuf == NULL) return FinishTransfer(data, nLeftOver);
/* sometimes wrong sizes are sent (tekken tag) */
assert( gs.imageTransfer == -1 || TransPitch(nSize, data.transfersize)/4 <= 2 );
}
return FinishTransfer(data, nLeftOver);
}
//DEFINE_TRANSFERLOCAL(32, u32, 2, 32, 8, 8, _, SwizzleBlock32);
int TransferHostLocal32(const void* pbyMem, u32 nQWordSize)
{
TransferData data(2,32,8,8,32, PSM_);
TransferFuncts fun(writePixel32_0, getPixelAddress32_0, SwizzleBlock32, SwizzleBlock32u);
return RealTransfer<u32>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(32Z, u32, 2, 32, 8, 8, _, SwizzleBlock32);
int TransferHostLocal32Z(const void* pbyMem, u32 nQWordSize)
{
TransferData data(2,32,8,8,32, PSM_);
TransferFuncts fun(writePixel32Z_0, getPixelAddress32Z_0, SwizzleBlock32, SwizzleBlock32u);
return RealTransfer<u32>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(24, u8, 8, 32, 8, 8, _24, SwizzleBlock24);
int TransferHostLocal24(const void* pbyMem, u32 nQWordSize)
{
TransferData data(8,32,8,8,24, PSM_24_);
TransferFuncts fun(writePixel24_0, getPixelAddress24_0, SwizzleBlock24, SwizzleBlock24u);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(24Z, u8, 8, 32, 8, 8, _24, SwizzleBlock24);
int TransferHostLocal24Z(const void* pbyMem, u32 nQWordSize)
{
TransferData data(8,32,8,8,24, PSM_24_);
TransferFuncts fun(writePixel24Z_0, getPixelAddress24Z_0, SwizzleBlock24, SwizzleBlock24u);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(16, u16, 4, 16, 16, 8, _, SwizzleBlock16);
int TransferHostLocal16(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,16,16,8,16, PSM_);
TransferFuncts fun(writePixel16_0, getPixelAddress16_0, SwizzleBlock16, SwizzleBlock16u);
return RealTransfer<u16>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(16S, u16, 4, 16, 16, 8, _, SwizzleBlock16);
int TransferHostLocal16S(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,16,16,8,16, PSM_);
TransferFuncts fun(writePixel16S_0, getPixelAddress16S_0, SwizzleBlock16, SwizzleBlock16u);
return RealTransfer<u16>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(16Z, u16, 4, 16, 16, 8, _, SwizzleBlock16);
int TransferHostLocal16Z(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,16,16,8,16, PSM_);
TransferFuncts fun(writePixel16Z_0, getPixelAddress16Z_0, SwizzleBlock16, SwizzleBlock16u);
return RealTransfer<u16>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(16SZ, u16, 4, 16, 16, 8, _, SwizzleBlock16);
int TransferHostLocal16SZ(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,16,16,8,16, PSM_);
TransferFuncts fun(writePixel16SZ_0, getPixelAddress16SZ_0, SwizzleBlock16, SwizzleBlock16u);
return RealTransfer<u16>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(8, u8, 4, 8, 16, 16, _, SwizzleBlock8);
int TransferHostLocal8(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,8,16,16,8, PSM_);
TransferFuncts fun(writePixel8_0, getPixelAddress8_0, SwizzleBlock8, SwizzleBlock8u);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(4, u8, 8, 4, 32, 16, _4, SwizzleBlock4);
int TransferHostLocal4(const void* pbyMem, u32 nQWordSize)
{
TransferData data(8,4,32,16,4, PSM_4_);
TransferFuncts fun(writePixel4_0, getPixelAddress4_0, SwizzleBlock4, SwizzleBlock4u);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(8H, u8, 4, 32, 8, 8, _, SwizzleBlock8H);
int TransferHostLocal8H(const void* pbyMem, u32 nQWordSize)
{
TransferData data(4,32,8,8,8, PSM_);
TransferFuncts fun(writePixel8H_0, getPixelAddress8H_0, SwizzleBlock8H, SwizzleBlock8Hu);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(4HL, u8, 8, 32, 8, 8, _4, SwizzleBlock4HL);
int TransferHostLocal4HL(const void* pbyMem, u32 nQWordSize)
{
TransferData data(8,32,8,8,4, PSM_4_);
TransferFuncts fun(writePixel4HL_0, getPixelAddress4HL_0, SwizzleBlock4HL, SwizzleBlock4HLu);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
//DEFINE_TRANSFERLOCAL(4HH, u8, 8, 32, 8, 8, _4, SwizzleBlock4HH);
int TransferHostLocal4HH(const void* pbyMem, u32 nQWordSize)
{
TransferData data(8,32,8,8,4, PSM_4_);
TransferFuncts fun(writePixel4HH_0, getPixelAddress4HH_0, SwizzleBlock4HH, SwizzleBlock4HHu);
return RealTransfer<u8>(data, fun, pbyMem, nQWordSize);
}
void TransferLocalHost32(void* pbyMem, u32 nQWordSize) { FUNCLOG }
void TransferLocalHost24(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost16(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost16S(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost8(void* pbyMem, u32 nQWordSize) {}
void TransferLocalHost4(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost8H(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost4HL(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost4HH(void* pbyMem, u32 nQWordSize) {}
void TransferLocalHost32Z(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost24Z(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost16Z(void* pbyMem, u32 nQWordSize) {FUNCLOG}
void TransferLocalHost16SZ(void* pbyMem, u32 nQWordSize) {FUNCLOG}
#define FILL_BLOCK(bw, bh, ox, oy, mult, psm, psmcol) { \
b.vTexDims = Vector(BLOCK_TEXWIDTH/(float)(bw), BLOCK_TEXHEIGHT/(float)bh, 0, 0); \
b.vTexBlock = Vector((float)bw/BLOCK_TEXWIDTH, (float)bh/BLOCK_TEXHEIGHT, ((float)ox+0.2f)/BLOCK_TEXWIDTH, ((float)oy+0.05f)/BLOCK_TEXHEIGHT); \
b.width = bw; \
b.height = bh; \
b.colwidth = bh / 4; \
b.colheight = bw / 8; \
b.bpp = 32/mult; \
\
b.pageTable = &g_pageTable##psm[0][0]; \
b.blockTable = &g_blockTable##psm[0][0]; \
b.columnTable = &g_columnTable##psmcol[0][0]; \
assert( sizeof(g_pageTable##psm) == bw*bh*sizeof(g_pageTable##psm[0][0]) ); \
psrcf = (float*)&vBlockData[0] + ox + oy * BLOCK_TEXWIDTH; \
psrcw = (u16*)&vBlockData[0] + ox + oy * BLOCK_TEXWIDTH; \
for(i = 0; i < bh; ++i) { \
for(j = 0; j < bw; ++j) { \
/* fill the table */ \
u32 u = g_blockTable##psm[(i / b.colheight)][(j / b.colwidth)] * 64 * mult + g_columnTable##psmcol[i%b.colheight][j%b.colwidth]; \
b.pageTable[i*bw+j] = u; \
if( floatfmt ) { \
psrcf[i*BLOCK_TEXWIDTH+j] = (float)(u) / (float)(GPU_TEXWIDTH*mult); \
} \
else { \
psrcw[i*BLOCK_TEXWIDTH+j] = u; \
} \
} \
} \
\
if( floatfmt ) { \
assert( floatfmt ); \
psrcv = (Vector*)&vBilinearData[0] + ox + oy * BLOCK_TEXWIDTH; \
for(i = 0; i < bh; ++i) { \
for(j = 0; j < bw; ++j) { \
Vector* pv = &psrcv[i*BLOCK_TEXWIDTH+j]; \
pv->x = psrcf[i*BLOCK_TEXWIDTH+j]; \
pv->y = psrcf[i*BLOCK_TEXWIDTH+((j+1)%bw)]; \
pv->z = psrcf[((i+1)%bh)*BLOCK_TEXWIDTH+j]; \
pv->w = psrcf[((i+1)%bh)*BLOCK_TEXWIDTH+((j+1)%bw)]; \
} \
} \
} \
b.getPixelAddress = getPixelAddress##psm; \
b.getPixelAddress_0 = getPixelAddress##psm##_0; \
b.writePixel = writePixel##psm; \
b.writePixel_0 = writePixel##psm##_0; \
b.readPixel = readPixel##psm; \
b.readPixel_0 = readPixel##psm##_0; \
b.TransferHostLocal = TransferHostLocal##psm; \
b.TransferLocalHost = TransferLocalHost##psm; \
} \
void BLOCK::FillBlocks(vector<char>& vBlockData, vector<char>& vBilinearData, int floatfmt)
{
FUNCLOG
vBlockData.resize(BLOCK_TEXWIDTH * BLOCK_TEXHEIGHT * (floatfmt ? 4 : 2));
if( floatfmt )
vBilinearData.resize(BLOCK_TEXWIDTH * BLOCK_TEXHEIGHT * sizeof(Vector));
int i, j;
BLOCK b;
float* psrcf = NULL;
u16* psrcw = NULL;
Vector* psrcv = NULL;
memset(m_Blocks, 0, sizeof(m_Blocks));
// 32
FILL_BLOCK(64, 32, 0, 0, 1, 32, 32);
m_Blocks[PSMCT32] = b;
// 24 (same as 32 except write/readPixel are different)
m_Blocks[PSMCT24] = b;
m_Blocks[PSMCT24].writePixel = writePixel24;
m_Blocks[PSMCT24].writePixel_0 = writePixel24_0;
m_Blocks[PSMCT24].readPixel = readPixel24;
m_Blocks[PSMCT24].readPixel_0 = readPixel24_0;
m_Blocks[PSMCT24].TransferHostLocal = TransferHostLocal24;
m_Blocks[PSMCT24].TransferLocalHost = TransferLocalHost24;
// 8H (same as 32 except write/readPixel are different)
m_Blocks[PSMT8H] = b;
m_Blocks[PSMT8H].writePixel = writePixel8H;
m_Blocks[PSMT8H].writePixel_0 = writePixel8H_0;
m_Blocks[PSMT8H].readPixel = readPixel8H;
m_Blocks[PSMT8H].readPixel_0 = readPixel8H_0;
m_Blocks[PSMT8H].TransferHostLocal = TransferHostLocal8H;
m_Blocks[PSMT8H].TransferLocalHost = TransferLocalHost8H;
m_Blocks[PSMT4HL] = b;
m_Blocks[PSMT4HL].writePixel = writePixel4HL;
m_Blocks[PSMT4HL].writePixel_0 = writePixel4HL_0;
m_Blocks[PSMT4HL].readPixel = readPixel4HL;
m_Blocks[PSMT4HL].readPixel_0 = readPixel4HL_0;
m_Blocks[PSMT4HL].TransferHostLocal = TransferHostLocal4HL;
m_Blocks[PSMT4HL].TransferLocalHost = TransferLocalHost4HL;
m_Blocks[PSMT4HH] = b;
m_Blocks[PSMT4HH].writePixel = writePixel4HH;
m_Blocks[PSMT4HH].writePixel_0 = writePixel4HH_0;
m_Blocks[PSMT4HH].readPixel = readPixel4HH;
m_Blocks[PSMT4HH].readPixel_0 = readPixel4HH_0;
m_Blocks[PSMT4HH].TransferHostLocal = TransferHostLocal4HH;
m_Blocks[PSMT4HH].TransferLocalHost = TransferLocalHost4HH;
// 32z
FILL_BLOCK(64, 32, 64, 0, 1, 32Z, 32);
m_Blocks[PSMT32Z] = b;
// 24Z (same as 32Z except write/readPixel are different)
m_Blocks[PSMT24Z] = b;
m_Blocks[PSMT24Z].writePixel = writePixel24Z;
m_Blocks[PSMT24Z].writePixel_0 = writePixel24Z_0;
m_Blocks[PSMT24Z].readPixel = readPixel24Z;
m_Blocks[PSMT24Z].readPixel_0 = readPixel24Z_0;
m_Blocks[PSMT24Z].TransferHostLocal = TransferHostLocal24Z;
m_Blocks[PSMT24Z].TransferLocalHost = TransferLocalHost24Z;
// 16
FILL_BLOCK(64, 64, 0, 32, 2, 16, 16);
m_Blocks[PSMCT16] = b;
// 16s
FILL_BLOCK(64, 64, 64, 32, 2, 16S, 16);
m_Blocks[PSMCT16S] = b;
// 16z
FILL_BLOCK(64, 64, 0, 96, 2, 16Z, 16);
m_Blocks[PSMT16Z] = b;
// 16sz
FILL_BLOCK(64, 64, 64, 96, 2, 16SZ, 16);
m_Blocks[PSMT16SZ] = b;
// 8
FILL_BLOCK(128, 64, 0, 160, 4, 8, 8);
m_Blocks[PSMT8] = b;
// 4
FILL_BLOCK(128, 128, 0, 224, 8, 4, 4);
m_Blocks[PSMT4] = b;
}