/* 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]); // ------------------------ // | Y | // ------------------------ // | block | | // | aligned area | X | // | | | // ------------------------ // | Y | // ------------------------ #define DEFINE_TRANSFERLOCAL(psm, transfersize, T, widthlimit, blockbits, blockwidth, blockheight, TransSfx, SwizzleBlock) \ int TransferHostLocal##psm(const void* pbyMem, u32 nQWordSize) \ { \ assert( gs.imageTransfer == 0 ); \ u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; \ \ /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ \ int i = gs.imageY, j = gs.imageX; \ const u32 TSize = sizeof(T); \ \ const T* pbuf = (const T*)pbyMem; \ const int tp = TransPitch(2, transfersize); \ int nLeftOver = (nQWordSize*4*2)%tp; \ int nSize = nQWordSize*4*2/tp; \ nSize = min(nSize, gs.imageWnew * gs.imageHnew); \ \ int pitch, area, fracX; \ int endY = ROUND_UPPOW2(i, blockheight); \ int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); \ int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); \ bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; \ \ if( (gs.imageEndX-gs.trxpos.dx)%widthlimit ) { \ /* hack */ \ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); \ if((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { \ /* don't transfer */ \ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ \ gs.imageTransfer = -1; \ } \ bCanAlign = false; \ } \ \ /* first align on block boundary */ \ if( MOD_POW2(i, blockheight) || !bCanAlign ) { \ \ if( !bCanAlign ) \ endY = gs.imageEndY; /* transfer the whole image */ \ else \ assert( endY < gs.imageEndY); /* part of alignment condition */ \ \ if( ((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit) ) { \ /* transmit with a width of 1 */ \ TRANSMIT_HOSTLOCAL_Y(TransSfx,psm, T, (1+(DSTPSM == 0x14)), endY); \ } \ else { \ TRANSMIT_HOSTLOCAL_Y(TransSfx,psm, T, widthlimit, endY); \ } \ \ if( nSize == 0 || i == gs.imageEndY ) \ goto End; \ } \ \ assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); \ \ /* can align! */ \ pitch = gs.imageEndX-gs.trxpos.dx; \ area = pitch*blockheight; \ fracX = gs.imageEndX-alignedX; \ \ /* 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, transfersize) & 0xf) == 0; \ \ /* transfer aligning to blocks */ \ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { \ \ if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { \ for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { \ SwizzleBlock(pstart + getPixelAddress_0(psm,tempj, i, gs.dstbuf.bw)*blockbits/8, \ (u8*)pbuf, TransPitch(pitch, transfersize)); \ } \ } \ else { \ for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { \ SwizzleBlock##u(pstart + getPixelAddress_0(psm,tempj, i, gs.dstbuf.bw)*blockbits/8, \ (u8*)pbuf, TransPitch(pitch, transfersize)); \ } \ } \ \ /* transfer the rest */ \ if( alignedX < gs.imageEndX ) { \ TRANSMIT_HOSTLOCAL_X(TransSfx,psm, T, widthlimit, blockheight, alignedX); \ pbuf -= TransPitch(alignedX-gs.trxpos.dx, transfersize)/TSize; \ } \ else pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; \ j = gs.trxpos.dx; \ } \ \ if( TransPitch(nSize, transfersize)/4 > 0 ) { \ TRANSMIT_HOSTLOCAL_Y(TransSfx,psm, T, widthlimit, gs.imageEndY); \ /* sometimes wrong sizes are sent (tekken tag) */ \ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); \ } \ \ End: \ if( i >= gs.imageEndY ) { \ assert( gs.imageTransfer == -1 || i == 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 = i; \ gs.imageX = j; \ } \ return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; \ } \ #define NEW_TRANSFER #ifdef NEW_TRANSFER //DEFINE_TRANSFERLOCAL(32, u32, 2, 32, 8, 8, _, SwizzleBlock32); int TransferHostLocal32(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 2; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u32); const u32 transfersize = 32; _SwizzleBlock swizzle; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u32* pbuf = (const u32*)pbyMem; const int tp2 = TransPitch(2, transfersize); int nLeftOver = (nQWordSize*4*2)%tp2; int nSize = (nQWordSize*4*2)/tp2; nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(gs.imageY, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned; bool bCanAlign = ((MOD_POW2(gs.trxpos.dx, blockwidth) == 0) && (gs.imageX == gs.trxpos.dx) && (alignedY > endY) && (alignedX > gs.trxpos.dx)); if ((gs.imageEndX - gs.trxpos.dx) % widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY - gs.imageY) * (gs.imageEndX - gs.trxpos.dx) + (gs.imageX - gs.trxpos.dx); if((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(gs.imageY, blockheight) || !bCanAlign ) { if( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX - gs.trxpos.dx) % widthlimit) || ((gs.imageEndX - gs.imageX) % widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(32, u32, (1 + (DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(32, u32, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } //assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX - gs.trxpos.dx; area = pitch * blockheight; fracX = gs.imageEndX - alignedX; /* 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, transfersize) & 0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if ( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL))) swizzle = SwizzleBlock32; else swizzle = SwizzleBlock32u; for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { u8 *temp = pstart + getPixelAddress_0(32, tempj, i, gs.dstbuf.bw)*blockbits/8; swizzle(temp, (u8*)pbuf, TransPitch(pitch, transfersize), 0xffffffff); } /* transfer the rest */ if( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(32, u32, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX - gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight - 1)* TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0) { TRANSMIT_HOSTLOCAL_Y_(32, u32, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(32Z, u32, 2, 32, 8, 8, _, SwizzleBlock32); int TransferHostLocal32Z(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 2; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u32); const u32 transfersize = 32; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u32* pbuf = (const u32*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(32Z, u32, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(32Z, u32, widthlimit, endY); } if ( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock32(pstart + getPixelAddress_0(32Z,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock32u(pstart + getPixelAddress_0(32Z,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_( 32Z, u32, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX - gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_( 32Z, u32, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(24, u8, 8, 32, 8, 8, _24, SwizzleBlock24); int TransferHostLocal24(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 8; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u8); const u32 transfersize = 24; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_24(24, T, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_24(24, T, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize) & 0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock24(pstart + getPixelAddress_0(24,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock24u(pstart + getPixelAddress_0(24,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_24(24, T, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_24(24, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(24Z, u8, 8, 32, 8, 8, _24, SwizzleBlock24); int TransferHostLocal24Z(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 8; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u8); const u32 transfersize = 24; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_24(16, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_24(16, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock24(pstart + getPixelAddress_0(16,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock24u(pstart + getPixelAddress_0(16,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_24(16, u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0) { TRANSMIT_HOSTLOCAL_Y_24(24, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(16, u16, 4, 16, 16, 8, _, SwizzleBlock16); int TransferHostLocal16(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 16; const u32 blockwidth = 16; const u32 blockheight = 8; const u32 TSize = sizeof(u16); const u32 transfersize = 16; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u16* pbuf = (const u16*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(16, u16, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(16, u16, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16(pstart + getPixelAddress_0(16,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16u(pstart + getPixelAddress_0(16,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(16, T, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)* TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(pitch, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(16, u16, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(pitch, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(16S, u16, 4, 16, 16, 8, _, SwizzleBlock16); int TransferHostLocal16S(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 16; const u32 blockwidth = 16; const u32 blockheight = 8; const u32 TSize = sizeof(u16); const u32 transfersize = 16; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u16* pbuf = (const u16*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(16S, u16, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(16S, u16, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16(pstart + getPixelAddress_0(16S,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16u(pstart + getPixelAddress_0(16S,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(16S, u16, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1) * TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(16S, u16, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(16Z, u16, 4, 16, 16, 8, _, SwizzleBlock16); int TransferHostLocal16Z(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 16; const u32 blockwidth = 16; const u32 blockheight = 8; const u32 TSize = sizeof(u16); const u32 transfersize = 16; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u16* pbuf = (const u16*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(16Z, u16, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(16Z, u16, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16(pstart + getPixelAddress_0(16Z,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16u(pstart + getPixelAddress_0(16Z,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(16Z, T, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(16Z, u16, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(16SZ, u16, 4, 16, 16, 8, _, SwizzleBlock16); int TransferHostLocal16SZ(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 16; const u32 blockwidth = 16; const u32 blockheight = 8; const u32 TSize = sizeof(u16); const u32 transfersize = 16; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u16* pbuf = (const u16*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(16SZ, u16, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(16SZ, u16, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16(pstart + getPixelAddress_0(16SZ,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock16u(pstart + getPixelAddress_0(16SZ,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(16SZ, u16, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(16SZ, u16, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(8, u8, 4, 8, 16, 16, _, SwizzleBlock8); int TransferHostLocal8(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 8; const u32 blockwidth = 16; const u32 blockheight = 16; const u32 TSize = sizeof(u8); const u32 transfersize = 8; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(8, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(8, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf +=TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock8(pstart + getPixelAddress_0(8,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock8u(pstart + getPixelAddress_0(8,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(8, u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch(alignedX-gs.trxpos.dx, transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(8, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(4, u8, 8, 4, 32, 16, _4, SwizzleBlock4); int TransferHostLocal4(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 8; const u32 blockbits = 4; const u32 blockwidth = 32; const u32 blockheight = 16; const u32 TSize = sizeof(u8); const u32 transfersize = 4; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_4(4, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_4(4, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4(pstart + getPixelAddress_0(4,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4u(pstart + getPixelAddress_0(4,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_4(4, u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_4(4, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(8H, u8, 4, 32, 8, 8, _, SwizzleBlock8H); int TransferHostLocal8H(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 4; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u8); const u32 transfersize = 8; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_(8H, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_(8H, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock8H(pstart + getPixelAddress_0(8H,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock8Hu(pstart + getPixelAddress_0(8H,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_(8H, u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_(8H, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(4HL, u8, 8, 32, 8, 8, _4, SwizzleBlock4HL); int TransferHostLocal4HL(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 8; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u8); const u32 transfersize = 4; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/ TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_4(4HL, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_4(4HL, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4HL(pstart + getPixelAddress_0(4HL,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4HLu(pstart + getPixelAddress_0(4HL,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_4(4HL, u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_4(4HL, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } //DEFINE_TRANSFERLOCAL(4HH, u8, 8, 32, 8, 8, _4, SwizzleBlock4HH); int TransferHostLocal4HH(const void* pbyMem, u32 nQWordSize) { const u32 widthlimit = 8; const u32 blockbits = 32; const u32 blockwidth = 8; const u32 blockheight = 8; const u32 TSize = sizeof(u8); const u32 transfersize = 4; assert( gs.imageTransfer == 0 ); u8* pstart = g_pbyGSMemory + gs.dstbuf.bp*256; /*const u8* pendbuf = (const u8*)pbyMem + nQWordSize*4;*/ int i = gs.imageY, j = gs.imageX; const u8* pbuf = (const u8*)pbyMem; int nLeftOver = (nQWordSize*4*2)%(TransPitch(2, transfersize)); int nSize = nQWordSize*4*2/TransPitch(2, transfersize); nSize = min(nSize, gs.imageWnew * gs.imageHnew); int pitch, area, fracX; int endY = ROUND_UPPOW2(i, blockheight); int alignedY = ROUND_DOWNPOW2(gs.imageEndY, blockheight); int alignedX = ROUND_DOWNPOW2(gs.imageEndX, blockwidth); bool bAligned, bCanAlign = MOD_POW2(gs.trxpos.dx, blockwidth) == 0 && (j == gs.trxpos.dx) && (alignedY > endY) && alignedX > gs.trxpos.dx; if ((gs.imageEndX-gs.trxpos.dx)%widthlimit) { /* hack */ int testwidth = (int)nSize - (gs.imageEndY-i)*(gs.imageEndX-gs.trxpos.dx)+(j-gs.trxpos.dx); if ((testwidth <= widthlimit) && (testwidth >= -widthlimit)) { /* don't transfer */ /*DEBUG_LOG("bad texture %s: %d %d %d\n", #psm, gs.trxpos.dx, gs.imageEndX, nQWordSize);*/ gs.imageTransfer = -1; } bCanAlign = false; } /* first align on block boundary */ if ( MOD_POW2(i, blockheight) || !bCanAlign ) { if ( !bCanAlign ) endY = gs.imageEndY; /* transfer the whole image */ else assert( endY < gs.imageEndY); /* part of alignment condition */ if (((gs.imageEndX-gs.trxpos.dx)%widthlimit) || ((gs.imageEndX-j)%widthlimit)) { /* transmit with a width of 1 */ TRANSMIT_HOSTLOCAL_Y_4(4HH, u8, (1+(DSTPSM == 0x14)), endY); } else { TRANSMIT_HOSTLOCAL_Y_4(4HH, u8, widthlimit, endY); } if( nSize == 0 || i == gs.imageEndY ) goto End; } assert( MOD_POW2(i, blockheight) == 0 && j == gs.trxpos.dx); /* can align! */ pitch = gs.imageEndX-gs.trxpos.dx; area = pitch*blockheight; fracX = gs.imageEndX-alignedX; /* 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, transfersize)&0xf) == 0; /* transfer aligning to blocks */ for(; i < alignedY && nSize >= area; i += blockheight, nSize -= area) { if( bAligned || ((DSTPSM==PSMCT24) || (DSTPSM==PSMT8H) || (DSTPSM==PSMT4HH) || (DSTPSM==PSMT4HL)) ) { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4HH(pstart + getPixelAddress_0(4HH,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } else { for(int tempj = gs.trxpos.dx; tempj < alignedX; tempj += blockwidth, pbuf += TransPitch(blockwidth, transfersize)/TSize) { SwizzleBlock4HHu(pstart + getPixelAddress_0(4HH,tempj, i, gs.dstbuf.bw)*blockbits/8, (u8*)pbuf, TransPitch(pitch, transfersize)); } } /* transfer the rest */ if ( alignedX < gs.imageEndX ) { TRANSMIT_HOSTLOCAL_X_4(4HH,u8, widthlimit, blockheight, alignedX); pbuf -= TransPitch((alignedX-gs.trxpos.dx), transfersize)/TSize; } else { pbuf += (blockheight-1)*TransPitch(pitch, transfersize)/TSize; } j = gs.trxpos.dx; } if (TransPitch(nSize, transfersize)/4 > 0 ) { TRANSMIT_HOSTLOCAL_Y_4(4HH, u8, widthlimit, gs.imageEndY); /* sometimes wrong sizes are sent (tekken tag) */ assert( gs.imageTransfer == -1 || TransPitch(nSize, transfersize)/4 <= 2 ); } End: if( i >= gs.imageEndY ) { assert( gs.imageTransfer == -1 || i == 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 = i; gs.imageX = j; } return (nSize * TransPitch(2, transfersize) + nLeftOver)/2; } #else DEFINE_TRANSFERLOCAL(32, 32, u32, 2, 32, 8, 8, _, SwizzleBlock32); DEFINE_TRANSFERLOCAL(32Z, 32, u32, 2, 32, 8, 8, _, SwizzleBlock32); DEFINE_TRANSFERLOCAL(24, 24, u8, 8, 32, 8, 8, _24, SwizzleBlock24); DEFINE_TRANSFERLOCAL(24Z, 24, u8, 8, 32, 8, 8, _24, SwizzleBlock24); DEFINE_TRANSFERLOCAL(16, 16, u16, 4, 16, 16, 8, _, SwizzleBlock16); DEFINE_TRANSFERLOCAL(16S, 16, u16, 4, 16, 16, 8, _, SwizzleBlock16); DEFINE_TRANSFERLOCAL(16Z, 16, u16, 4, 16, 16, 8, _, SwizzleBlock16); DEFINE_TRANSFERLOCAL(16SZ, 16, u16, 4, 16, 16, 8, _, SwizzleBlock16); DEFINE_TRANSFERLOCAL(8, 8, u8, 4, 8, 16, 16, _, SwizzleBlock8); DEFINE_TRANSFERLOCAL(4, 4, u8, 8, 4, 32, 16, _4, SwizzleBlock4); DEFINE_TRANSFERLOCAL(8H, 8, u8, 4, 32, 8, 8, _, SwizzleBlock8H); DEFINE_TRANSFERLOCAL(4HL, 4, u8, 8, 32, 8, 8, _4, SwizzleBlock4HL); DEFINE_TRANSFERLOCAL(4HH, 4, u8, 8, 32, 8, 8, _4, SwizzleBlock4HH); #endif 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& vBlockData, vector& 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; }