pcsx2/pcsx2/SPR.cpp

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/* Pcsx2 - Pc Ps2 Emulator
* Copyright (C) 2002-2009 Pcsx2 Team
*
* 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include "PrecompiledHeader.h"
#include "Common.h"
#include "SPR.h"
#include "iR5900.h"
#include "VUmicro.h"
#define spr0 ((DMACh*)&PS2MEM_HW[0xD000])
#define spr1 ((DMACh*)&PS2MEM_HW[0xD400])
int spr0finished = 0;
int spr1finished = 0;
u32 mfifotransferred = 0;
void sprInit() {
}
//__forceinline static void SPR0transfer(u32 *data, int size) {
///* while (size > 0) {
// SPR_LOG("SPR1transfer: %x\n", *data);
// data++; size--;
// }*/
// size <<= 2;
// if ((psHu32(DMAC_CTRL) & 0xC) == 0xC || // GIF MFIFO
// (psHu32(DMAC_CTRL) & 0xC) == 0x8) { // VIF1 MFIFO
// hwMFIFOWrite(spr0->madr, (u8*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff], size);
// } else {
// u32 * p = (u32*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff];
// //WriteCodeSSE2(p,data,size >> 4);
// memcpy_fast((u8*)data, &PS2MEM_SCRATCH[spr0->sadr & 0x3fff], size);
// }
// spr0->sadr+= size;
//}
static void TestClearVUs(u32 madr, u32 size)
{
if( madr >= 0x11000000 ) {
if( madr < 0x11004000 ) {
DbgCon::Notice("scratch pad clearing vu0\n");
CpuVU0.Clear(madr&0xfff, size);
}
else if( madr >= 0x11008000 && madr < 0x1100c000 ) {
DbgCon::Notice("scratch pad clearing vu1\n");
CpuVU1.Clear(madr&0x3fff, size);
}
}
}
int _SPR0chain() {
u32 *pMem;
if (spr0->qwc == 0) return 0;
pMem = (u32*)dmaGetAddr(spr0->madr);
if (pMem == NULL) return -1;
//SPR0transfer(pMem, qwc << 2);
if ((psHu32(DMAC_CTRL) & 0xC) >= 0x8) { // 0x8 VIF1 MFIFO, 0xC GIF MFIFO
if((spr0->madr & ~psHu32(DMAC_RBSR)) != psHu32(DMAC_RBOR)) SysPrintf("SPR MFIFO Write outside MFIFO area\n");
hwMFIFOWrite(spr0->madr, (u8*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff], spr0->qwc << 4);
spr0->madr += spr0->qwc << 4;
spr0->madr = psHu32(DMAC_RBOR) + (spr0->madr & psHu32(DMAC_RBSR));
mfifotransferred += spr0->qwc;
} else {
memcpy_fast((u8*)pMem, &PS2MEM_SCRATCH[spr0->sadr & 0x3fff], spr0->qwc << 4);
Cpu->Clear(spr0->madr, spr0->qwc<<2);
// clear VU mem also!
TestClearVUs(spr0->madr, spr0->qwc << 2); // Wtf is going on here? AFAIK, only VIF should affect VU micromem (cottonvibes)
spr0->madr += spr0->qwc << 4;
}
spr0->sadr += spr0->qwc << 4;
return (spr0->qwc) * BIAS; // bus is 1/2 the ee speed
}
#define SPR0chain() \
cycles += _SPR0chain(); \
spr0->qwc = 0;
void _SPR0interleave() {
int qwc = spr0->qwc;
int sqwc = psHu32(DMAC_SQWC) & 0xff;
int tqwc = (psHu32(DMAC_SQWC) >> 16) & 0xff;
int cycles = 0;
u32 *pMem;
if(tqwc == 0) tqwc = qwc;
//SysPrintf("dmaSPR0 interleave\n");
SPR_LOG("SPR0 interleave size=%d, tqwc=%d, sqwc=%d, addr=%lx sadr=%lx\n",
spr0->qwc, tqwc, sqwc, spr0->madr, spr0->sadr);
while (qwc > 0) {
spr0->qwc = std::min(tqwc, qwc); qwc-= spr0->qwc;
pMem = (u32*)dmaGetAddr(spr0->madr);
if ((psHu32(DMAC_CTRL) & 0xC) == 0xC || // GIF MFIFO
(psHu32(DMAC_CTRL) & 0xC) == 0x8) { // VIF1 MFIFO
hwMFIFOWrite(spr0->madr, (u8*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff], spr0->qwc<<4);
mfifotransferred += spr0->qwc;
} else {
Cpu->Clear(spr0->madr, spr0->qwc<<2);
// clear VU mem also!
TestClearVUs(spr0->madr, spr0->qwc<<2);
memcpy_fast((u8*)pMem, &PS2MEM_SCRATCH[spr0->sadr & 0x3fff], spr0->qwc<<4);
}
cycles += tqwc * BIAS;
spr0->sadr+= spr0->qwc * 16;
spr0->madr+= (sqwc+spr0->qwc)*16; //qwc-= sqwc;
}
spr0->qwc = 0;
spr0finished = 1;
//CPU_INT(8, cycles);
}
static __forceinline void _dmaSPR0() {
if ((psHu32(DMAC_CTRL) & 0x30) == 0x20) { // STS == fromSPR
SysPrintf("SPR0 stall %d\n", (psHu32(DMAC_CTRL)>>6)&3);
}
// Transfer Dn_QWC from SPR to Dn_MADR
if ((spr0->chcr & 0xc) == 0x0) { // Normal Mode
int cycles = 0;
SPR0chain();
//CPU_INT(8, cycles);
spr0finished = 1;
return;
} else if ((spr0->chcr & 0xc) == 0x4) {
int cycles = 0;
u32 *ptag;
int id;
int done = 0;
if(spr0->qwc > 0){
SPR0chain();
//CPU_INT(8, cycles);
spr0finished = 1;
return;
}
// Destination Chain Mode
//while (done == 0) { // Loop while Dn_CHCR.STR is 1
ptag = (u32*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff];
spr0->sadr+= 16;
// Transfer dma tag if tte is set
// if (spr0->chcr & 0x40) SPR0transfer(ptag, 4);
spr0->chcr = ( spr0->chcr & 0xFFFF ) | ( (*ptag) & 0xFFFF0000 ); //Transfer upper part of tag to CHCR bits 31-15
id = (ptag[0] >> 28) & 0x7; //ID for DmaChain copied from bit 28 of the tag
spr0->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
spr0->madr = ptag[1]; //MADR = ADDR field
SPR_LOG("spr0 dmaChain %8.8x_%8.8x size=%d, id=%d, addr=%lx spr=%lx\n",
ptag[1], ptag[0], spr0->qwc, id, spr0->madr, spr0->sadr);
if ((psHu32(DMAC_CTRL) & 0x30) == 0x20) { // STS == fromSPR
SysPrintf("SPR stall control\n");
}
switch (id) {
case 0: // CNTS - Transfer QWC following the tag (Stall Control)
if ((psHu32(DMAC_CTRL) & 0x30) == 0x20 ) psHu32(DMAC_STADR) = spr0->madr + (spr0->qwc * 16); //Copy MADR to DMAC_STADR stall addr register
break;
case 1: // CNT - Transfer QWC following the tag.
done = 0;
break;
case 7: // End - Transfer QWC following the tag
done = 1; //End Transfer
break;
}
SPR0chain();
if (spr0->chcr & 0x80 && ptag[0] >> 31) { //Check TIE bit of CHCR and IRQ bit of tag
//SysPrintf("SPR0 TIE\n");
done = 1;
spr0->qwc = 0;
//break;
}
/* if (spr0->chcr & 0x80 && ptag[0] >> 31) {
SPR_LOG("dmaIrq Set\n");
spr0->chcr&= ~0x100;
hwDmacIrq(8);
return;
}*/
//}
spr0finished = done;
if(done == 0) {
ptag = (u32*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff]; //Set memory pointer to SADR
spr0->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
CPU_INT(8, spr0->qwc / BIAS);
spr0->qwc = 0;
return;
}
SPR_LOG("spr0 dmaChain complete %8.8x_%8.8x size=%d, id=%d, addr=%lx spr=%lx\n",
ptag[1], ptag[0], spr0->qwc, id, spr0->madr);
//CPU_INT(8, cycles);
} else { // Interleave Mode
_SPR0interleave();
}
}
extern void mfifoGIFtransfer(int);
#define gif ((DMACh*)&PS2MEM_HW[0xA000])
void SPRFROMinterrupt()
{
//int qwc = spr0->qwc;
_dmaSPR0();
if ((psHu32(DMAC_CTRL) & 0xC) == 0xC) { // GIF MFIFO
if((spr0->madr & ~psHu32(DMAC_RBSR)) != psHu32(DMAC_RBOR)) SysPrintf("GIF MFIFO Write outside MFIFO area\n");
spr0->madr = psHu32(DMAC_RBOR) + (spr0->madr & psHu32(DMAC_RBSR));
//SysPrintf("mfifoGIFtransfer %x madr %x, tadr %x\n", gif->chcr, gif->madr, gif->tadr);
mfifoGIFtransfer(mfifotransferred);
mfifotransferred = 0;
} else
if ((psHu32(DMAC_CTRL) & 0xC) == 0x8) { // VIF1 MFIFO
if((spr0->madr & ~psHu32(DMAC_RBSR)) != psHu32(DMAC_RBOR)) SysPrintf("VIF MFIFO Write outside MFIFO area\n");
spr0->madr = psHu32(DMAC_RBOR) + (spr0->madr & psHu32(DMAC_RBSR));
//SysPrintf("mfifoVIF1transfer %x madr %x, tadr %x\n", vif1ch->chcr, vif1ch->madr, vif1ch->tadr);
//vifqwc+= qwc;
mfifoVIF1transfer(mfifotransferred);
mfifotransferred = 0;
}
if(spr0finished == 0) return;
spr0->chcr&= ~0x100;
hwDmacIrq(8);
}
void dmaSPR0() { // fromSPR
SPR_LOG("dmaSPR0 chcr = %lx, madr = %lx, qwc = %lx, sadr = %lx\n",
spr0->chcr, spr0->madr, spr0->qwc, spr0->sadr);
if ((spr0->chcr & 0xc) == 0x4){
u32 *ptag;
ptag = (u32*)&PS2MEM_SCRATCH[spr0->sadr & 0x3fff]; //Set memory pointer to SADR
spr0->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
CPU_INT(8, spr0->qwc / BIAS);
spr0->qwc = 0;
return;
}
// COMPLETE HACK!!! For now at least.. FFX Videos dont rely on interrupts or reading DMA values
// It merely assumes that the last one has finished then starts another one (broke with the DMA fix)
// This "shouldn't" cause any problems as SPR is generally faster than the other DMAS anyway. (Refraction)
CPU_INT(8, spr0->qwc / BIAS);
}
__forceinline static void SPR1transfer(u32 *data, int size) {
/* {
int i;
for (i=0; i<size; i++) {
SPR_LOG( "SPR1transfer[0x%x]: 0x%x\n", (spr1->sadr+i*4) & 0x3fff, data[i] );
}
}*/
//Cpu->Clear(spr1->sadr, size); // why?
memcpy_fast(&PS2MEM_SCRATCH[spr1->sadr & 0x3fff], (u8*)data, size << 2);
spr1->sadr+= size << 2;
}
int _SPR1chain() {
u32 *pMem;
if (spr1->qwc == 0) return 0;
pMem = (u32*)dmaGetAddr(spr1->madr);
if (pMem == NULL) return -1;
SPR1transfer(pMem, spr1->qwc << 2);
spr1->madr+= spr1->qwc << 4;
return (spr1->qwc) * BIAS;
}
#define SPR1chain() \
cycles += _SPR1chain(); \
spr1->qwc = 0;
void _SPR1interleave() {
int qwc = spr1->qwc;
int sqwc = psHu32(DMAC_SQWC) & 0xff;
int tqwc = (psHu32(DMAC_SQWC) >> 16) & 0xff;
int cycles = 0;
u32 *pMem;
if(tqwc == 0) tqwc = qwc;
SPR_LOG("SPR1 interleave size=%d, tqwc=%d, sqwc=%d, addr=%lx sadr=%lx\n",
spr1->qwc, tqwc, sqwc, spr1->madr, spr1->sadr);
while (qwc > 0) {
spr1->qwc = std::min(tqwc, qwc); qwc-= spr1->qwc;
pMem = (u32*)dmaGetAddr(spr1->madr);
memcpy_fast(&PS2MEM_SCRATCH[spr1->sadr & 0x3fff], (u8*)pMem, spr1->qwc <<4);
spr1->sadr += spr1->qwc * 16;
cycles += spr1->qwc * BIAS;
spr1->madr+= (sqwc + spr1->qwc) * 16; //qwc-= sqwc;
}
spr1->qwc = 0;
spr1finished = 1;
//CPU_INT(9, cycles);
}
void _dmaSPR1() { // toSPR work function
if ((spr1->chcr & 0xc) == 0) { // Normal Mode
int cycles = 0;
//if(spr1->qwc == 0 && (spr1->chcr & 0xc) == 1) spr1->qwc = 0xffff;
// Transfer Dn_QWC from Dn_MADR to SPR1
SPR1chain();
spr1finished = 1;
//CPU_INT(9, cycles);
return;
} else
if ((spr1->chcr & 0xc) == 0x4){
int cycles = 0;
u32 *ptag;
int id, done=0;
if(spr1->qwc > 0){
//if(spr1->qwc == 0 && (spr1->chcr & 0xc) == 1) spr1->qwc = 0xffff;
// Transfer Dn_QWC from Dn_MADR to SPR1
SPR1chain();
spr1finished = 1;
//CPU_INT(9, cycles);
return;
}
// Chain Mode
// while (done == 0) { // Loop while Dn_CHCR.STR is 1
ptag = (u32*)dmaGetAddr(spr1->tadr); //Set memory pointer to TADR
if (ptag == NULL) { //Is ptag empty?
SysPrintf("SPR1 Tag BUSERR\n");
spr1->chcr = ( spr1->chcr & 0xFFFF ) | ( (*ptag) & 0xFFFF0000 ); //Transfer upper part of tag to CHCR bits 31-15
psHu32(DMAC_STAT)|= 1<<15; //If yes, set BEIS (BUSERR) in DMAC_STAT register
done = 1;
spr1finished = done;
return;
}
spr1->chcr = ( spr1->chcr & 0xFFFF ) | ( (*ptag) & 0xFFFF0000 ); //Transfer upper part of tag to CHCR bits 31-15
id = (ptag[0] >> 28) & 0x7; //ID for DmaChain copied from bit 28 of the tag
spr1->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
spr1->madr = ptag[1]; //MADR = ADDR field
// Transfer dma tag if tte is set
if (spr1->chcr & 0x40) {
SPR_LOG("SPR TTE: %x_%x\n", ptag[3], ptag[2]);
SPR1transfer(ptag, 4); //Transfer Tag
}
SPR_LOG("spr1 dmaChain %8.8x_%8.8x size=%d, id=%d, addr=%lx\n",
ptag[1], ptag[0], spr1->qwc, id, spr1->madr);
done = hwDmacSrcChain(spr1, id);
SPR1chain(); //Transfers the data set by the switch
if (spr1->chcr & 0x80 && ptag[0] >> 31) { //Check TIE bit of CHCR and IRQ bit of tag
SPR_LOG("dmaIrq Set\n");
//SysPrintf("SPR1 TIE\n");
spr1->qwc = 0;
done = 1;
// break;
}
//}
spr1finished = done;
if(done == 0) {
ptag = (u32*)dmaGetAddr(spr1->tadr); //Set memory pointer to TADR
spr1->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
CPU_INT(9, spr1->qwc / BIAS);
spr1->qwc = 0;
}
} else { // Interleave Mode
_SPR1interleave();
}
}
void dmaSPR1() { // toSPR
#ifdef SPR_LOG
SPR_LOG("dmaSPR1 chcr = 0x%x, madr = 0x%x, qwc = 0x%x\n"
" tadr = 0x%x, sadr = 0x%x\n",
spr1->chcr, spr1->madr, spr1->qwc,
spr1->tadr, spr1->sadr);
#endif
if ((spr1->chcr & 0xc) == 0x4){
u32 *ptag;
ptag = (u32*)dmaGetAddr(spr1->tadr); //Set memory pointer to TADR
spr1->qwc = (u16)ptag[0]; //QWC set to lower 16bits of the tag
CPU_INT(9, spr1->qwc / BIAS);
spr1->qwc = 0;
return;
}
// COMPLETE HACK!!! For now at least.. FFX Videos dont rely on interrupts or reading DMA values
// It merely assumes that the last one has finished then starts another one (broke with the DMA fix)
// This "shouldn't" cause any problems as SPR is generally faster than the other DMAS anyway. (Refraction)
CPU_INT(9, spr1->qwc / BIAS);
}
void SPRTOinterrupt()
{
_dmaSPR1();
if( spr1finished == 0 ) return;
spr1->chcr &= ~0x100;
hwDmacIrq(9);
}