mirror of https://github.com/PCSX2/pcsx2.git
601 lines
18 KiB
C++
601 lines
18 KiB
C++
/* PCSX2 - PS2 Emulator for PCs
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* Copyright (C) 2002-2010 PCSX2 Dev Team
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*
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* PCSX2 is free software: you can redistribute it and/or modify it under the terms
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* of the GNU Lesser General Public License as published by the Free Software Found-
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* ation, either version 3 of the License, or (at your option) any later version.
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*
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* PCSX2 is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
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* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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* PURPOSE. See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along with PCSX2.
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* If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "PrecompiledHeader.h"
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#include "IopCommon.h"
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#include "Sif.h"
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using namespace R3000A;
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// Dma0/1 in Mdec.c
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// Dma3 in CdRom.c
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// Dma8 in PsxSpd.c
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// Dma11/12 in PsxSio2.c
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#ifndef ENABLE_NEW_IOPDMA_SPU2
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static void __fastcall psxDmaGeneric(u32 madr, u32 bcr, u32 chcr, u32 spuCore, _SPU2writeDMA4Mem spu2WriteFunc, _SPU2readDMA4Mem spu2ReadFunc)
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{
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const char dmaNum = spuCore ? '7' : '4';
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/*if (chcr & 0x400) DevCon.Status("SPU 2 DMA %c linked list chain mode! chcr = %x madr = %x bcr = %x\n", dmaNum, chcr, madr, bcr);
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if (chcr & 0x40000000) DevCon.Warning("SPU 2 DMA %c Unusual bit set on 'to' direction chcr = %x madr = %x bcr = %x\n", dmaNum, chcr, madr, bcr);
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if ((chcr & 0x1) == 0) DevCon.Status("SPU 2 DMA %c loading from spu2 memory chcr = %x madr = %x bcr = %x\n", dmaNum, chcr, madr, bcr);*/
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const int size = (bcr >> 16) * (bcr & 0xFFFF);
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// Update the spu2 to the current cycle before initiating the DMA
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if (SPU2async)
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{
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SPU2async(psxRegs.cycle - psxCounters[6].sCycleT);
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//Console.Status("cycles sent to SPU2 %x\n", psxRegs.cycle - psxCounters[6].sCycleT);
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psxCounters[6].sCycleT = psxRegs.cycle;
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psxCounters[6].CycleT = size * 3;
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psxNextCounter -= (psxRegs.cycle - psxNextsCounter);
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psxNextsCounter = psxRegs.cycle;
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if (psxCounters[6].CycleT < psxNextCounter)
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psxNextCounter = psxCounters[6].CycleT;
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if((g_iopNextEventCycle - psxNextsCounter) > (u32)psxNextCounter)
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{
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//DevCon.Warning("SPU2async Setting new counter branch, old %x new %x ((%x - %x = %x) > %x delta)", g_iopNextEventCycle, psxNextsCounter + psxNextCounter, g_iopNextEventCycle, psxNextsCounter, (g_iopNextEventCycle - psxNextsCounter), psxNextCounter);
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g_iopNextEventCycle = psxNextsCounter + psxNextCounter;
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}
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}
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switch (chcr)
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{
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case 0x01000201: //cpu to spu2 transfer
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PSXDMA_LOG("*** DMA %c - mem2spu *** %x addr = %x size = %x", dmaNum, chcr, madr, bcr);
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spu2WriteFunc((u16 *)iopPhysMem(madr), size*2);
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break;
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case 0x01000200: //spu2 to cpu transfer
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PSXDMA_LOG("*** DMA %c - spu2mem *** %x addr = %x size = %x", dmaNum, chcr, madr, bcr);
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spu2ReadFunc((u16 *)iopPhysMem(madr), size*2);
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psxCpu->Clear(spuCore ? HW_DMA7_MADR : HW_DMA4_MADR, size);
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break;
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default:
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Console.Error("*** DMA %c - SPU unknown *** %x addr = %x size = %x", dmaNum, chcr, madr, bcr);
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break;
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}
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}
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void psxDma4(u32 madr, u32 bcr, u32 chcr) // SPU2's Core 0
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{
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psxDmaGeneric(madr, bcr, chcr, 0, SPU2writeDMA4Mem, SPU2readDMA4Mem);
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}
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int psxDma4Interrupt()
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{
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#ifdef SPU2IRQTEST
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Console.Warning("psxDma4Interrupt()");
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#endif
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HW_DMA4_CHCR &= ~0x01000000;
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psxDmaInterrupt(4);
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iopIntcIrq(9);
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return 1;
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}
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void spu2DMA4Irq()
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{
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#ifdef SPU2IRQTEST
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Console.Warning("spu2DMA4Irq()");
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#endif
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SPU2interruptDMA4();
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HW_DMA4_CHCR &= ~0x01000000;
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psxDmaInterrupt(4);
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}
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void psxDma7(u32 madr, u32 bcr, u32 chcr) // SPU2's Core 1
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{
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psxDmaGeneric(madr, bcr, chcr, 1, SPU2writeDMA7Mem, SPU2readDMA7Mem);
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}
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int psxDma7Interrupt()
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{
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#ifdef SPU2IRQTEST
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Console.Warning("psxDma7Interrupt()");
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#endif
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HW_DMA7_CHCR &= ~0x01000000;
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psxDmaInterrupt2(0);
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return 1;
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}
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void spu2DMA7Irq()
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{
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#ifdef SPU2IRQTEST
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Console.Warning("spu2DMA7Irq()");
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#endif
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SPU2interruptDMA7();
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HW_DMA7_CHCR &= ~0x01000000;
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psxDmaInterrupt2(0);
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}
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#endif
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#ifndef DISABLE_PSX_GPU_DMAS
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void psxDma2(u32 madr, u32 bcr, u32 chcr) // GPU
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{
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DevCon.Warning("SIF2 IOP CHCR = %x MADR = %x BCR = %x first 16bits %x", chcr, madr, bcr, iopMemRead16(madr));
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sif2.iop.busy = true;
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sif2.iop.end = false;
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//SIF2Dma();
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dmaSIF2();
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}
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void psxDma6(u32 madr, u32 bcr, u32 chcr)
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{
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u32 *mem = (u32 *)iopPhysMem(madr);
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PSXDMA_LOG("*** DMA 6 - OT *** %lx addr = %lx size = %lx", chcr, madr, bcr);
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if (chcr == 0x11000002)
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{
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while (bcr--)
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{
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*mem-- = (madr - 4) & 0xffffff;
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madr -= 4;
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}
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mem++;
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*mem = 0xffffff;
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}
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else
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{
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// Unknown option
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PSXDMA_LOG("*** DMA 6 - OT unknown *** %lx addr = %lx size = %lx", chcr, madr, bcr);
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}
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HW_DMA6_CHCR &= ~0x01000000;
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psxDmaInterrupt(6);
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}
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#endif
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#ifndef ENABLE_NEW_IOPDMA_DEV9
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void psxDma8(u32 madr, u32 bcr, u32 chcr)
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{
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const int size = (bcr >> 16) * (bcr & 0xFFFF) * 8;
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switch (chcr & 0x01000201)
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{
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case 0x01000201: //cpu to dev9 transfer
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PSXDMA_LOG("*** DMA 8 - DEV9 mem2dev9 *** %lx addr = %lx size = %lx", chcr, madr, bcr);
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DEV9writeDMA8Mem((u32*)iopPhysMem(madr), size);
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break;
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case 0x01000200: //dev9 to cpu transfer
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PSXDMA_LOG("*** DMA 8 - DEV9 dev9mem *** %lx addr = %lx size = %lx", chcr, madr, bcr);
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DEV9readDMA8Mem((u32*)iopPhysMem(madr), size);
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break;
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default:
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PSXDMA_LOG("*** DMA 8 - DEV9 unknown *** %lx addr = %lx size = %lx", chcr, madr, bcr);
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break;
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}
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HW_DMA8_CHCR &= ~0x01000000;
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psxDmaInterrupt2(1);
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}
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#endif
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void psxDma9(u32 madr, u32 bcr, u32 chcr)
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{
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SIF_LOG("IOP: dmaSIF0 chcr = %lx, madr = %lx, bcr = %lx, tadr = %lx", chcr, madr, bcr, HW_DMA9_TADR);
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sif0.iop.busy = true;
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sif0.iop.end = false;
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SIF0Dma();
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}
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void psxDma10(u32 madr, u32 bcr, u32 chcr)
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{
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SIF_LOG("IOP: dmaSIF1 chcr = %lx, madr = %lx, bcr = %lx", chcr, madr, bcr);
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sif1.iop.busy = true;
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sif1.iop.end = false;
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SIF1Dma();
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}
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/* psxDma11 & psxDma 12 are in IopSio2.cpp, along with the appropriate interrupt functions. */
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//////////////////////////////////////////////////////////////////////////////////////////////
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//
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// Gigaherz's "Improved DMA Handling" Engine WIP...
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//
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#ifdef ENABLE_NEW_IOPDMA
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//////////////////////////////////////////////////////////////////////////////////////////////
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// Local Declarations
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// in IopSio2.cpp
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extern s32 CALLBACK sio2DmaStart(s32 channel, u32 madr, u32 bcr, u32 chcr);
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extern s32 CALLBACK sio2DmaRead(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed);
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extern s32 CALLBACK sio2DmaWrite(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed);
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extern void CALLBACK sio2DmaInterrupt(s32 channel);
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// implemented below
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s32 CALLBACK errDmaWrite(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed);
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s32 CALLBACK errDmaRead(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed);
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// pointer types
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typedef s32 (CALLBACK * DmaHandler)(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed);
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typedef void (CALLBACK * DmaIHandler)(s32 channel);
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typedef s32 (CALLBACK * DmaSHandler)(s32 channel, u32 madr, u32 bcr, u32 chcr);
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// constants
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struct DmaHandlerInfo
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{
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const char* Name;
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// doubles as a "disable" flag
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u32 DirectionFlags;
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u32 DmacRegisterBase;
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DmaHandler Read;
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DmaHandler Write;
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DmaIHandler Interrupt;
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DmaSHandler Start;
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__fi u32& REG_MADR(void) const { return psxHu32(DmacRegisterBase + 0x0); }
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__fi u32& REG_BCR(void) const { return psxHu32(DmacRegisterBase + 0x4); }
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__fi u32& REG_CHCR(void) const { return psxHu32(DmacRegisterBase + 0x8); }
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__fi u32& REG_TADR(void) const { return psxHu32(DmacRegisterBase + 0xC); }
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};
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#define MEM_BASE1 0x1f801080
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#define MEM_BASE2 0x1f801500
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#define CHANNEL_BASE1(ch) (MEM_BASE1 + ((ch)<<4))
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#define CHANNEL_BASE2(ch) (MEM_BASE2 + ((ch)<<4))
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// channel disabled
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#define _D__ 0
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#define _D_W 1
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#define _DR_ 2
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#define _DRW 3
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// channel enabled
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#define _E__ 4
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#define _E_W 5
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#define _ER_ 6
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#define _ERW 7
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//////////////////////////////////////////////////////////////////////////////////////////////
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// Plugin interface accessors
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#ifdef ENABLE_NEW_IOPDMA_SPU2
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s32 CALLBACK spu2DmaRead (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { return SPU2dmaRead(channel,data,bytesLeft,bytesProcessed); }
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s32 CALLBACK spu2DmaWrite (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { return SPU2dmaWrite(channel,data,bytesLeft,bytesProcessed); }
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void CALLBACK spu2DmaInterrupt (s32 channel) { SPU2dmaInterrupt(channel); }
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#else
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s32 CALLBACK spu2DmaRead (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { *bytesProcessed=0; return 0; }
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s32 CALLBACK spu2DmaWrite (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { *bytesProcessed=0; return 0; }
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void CALLBACK spu2DmaInterrupt (s32 channel) { }
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#endif
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#ifdef ENABLE_NEW_IOPDMA_DEV9
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s32 CALLBACK dev9DmaRead (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { return DEV9dmaRead(channel,data,bytesLeft,bytesProcessed); }
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s32 CALLBACK dev9DmaWrite (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { return DEV9dmaWrite(channel,data,bytesLeft,bytesProcessed); }
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void CALLBACK dev9DmaInterrupt (s32 channel) { DEV9dmaInterrupt(channel); }
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#else
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s32 CALLBACK dev9DmaRead (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { *bytesProcessed=0; return 0; }
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s32 CALLBACK dev9DmaWrite (s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed) { *bytesProcessed=0; return 0; }
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void CALLBACK dev9DmaInterrupt (s32 channel) { }
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#endif
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//////////////////////////////////////////////////////////////////////////////////////////////
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// Dma channel definitions
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const DmaHandlerInfo IopDmaHandlers[DMA_CHANNEL_MAX] =
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{
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// First DMAC, same as PS1
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{"Ps1 Mdec in", _D__}, //0
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{"Ps1 Mdec out", _D__}, //1
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{"Ps1 Gpu", _D__}, //2
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#ifdef ENABLE_NEW_IOPDMA_CDVD
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{"CDVD", _ER_, CHANNEL_BASE1(3), cdvdDmaRead, errDmaWrite, cdvdDmaInterrupt}, //3: CDVD
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#else
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{"CDVD", _D__}, //3: CDVD
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#endif
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#ifdef ENABLE_NEW_IOPDMA_SPU2
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{"SPU2 Core0", _ERW, CHANNEL_BASE1(4), spu2DmaRead, spu2DmaWrite, spu2DmaInterrupt}, //4: Spu/Spu2 Core0
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#else
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{"SPU2 Core0", _D__}, //4: Spu/Spu2 Core0
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#endif
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{"Ps1 PIO", _D__}, //5: PIO
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{"Ps1 OTC", _D__}, //6: "reverse clear OT" - PSX GPU related
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// Second DMAC, new in PS2 IOP
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#ifdef ENABLE_NEW_IOPDMA_SPU2
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{"SPU2 Core1", _ERW, CHANNEL_BASE2(0), spu2DmaRead, spu2DmaWrite, spu2DmaInterrupt}, //7: Spu2 Core1
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#else
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{"SPU2 Core1", _D__}, //7: Spu2 Core1
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#endif
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#ifdef ENABLE_NEW_IOPDMA_DEV9
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{"Dev9", _ERW, CHANNEL_BASE2(1), dev9DmaRead, dev9DmaWrite, dev9DmaInterrupt}, //8: Dev9
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#else
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{"Dev9", _D__}, //8: Dev9
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#endif
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#ifdef ENABLE_NEW_IOPDMA_SIF
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{"Sif0", _ERW, CHANNEL_BASE2(2), sif0DmaRead, sif0DmaWrite, sif0DmaInterrupt}, //9: SIF0
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{"Sif1", _ERW, CHANNEL_BASE2(3), sif1DmaRead, sif1DmaWrite, sif1DmaInterrupt}, //10: SIF1
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#else
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{"Sif0", _D__}, //9: SIF0
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{"Sif1", _D__}, //10: SIF1
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#endif
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#ifdef ENABLE_NEW_IOPDMA_SIO
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{"Sio2 (writes)", _E_W, CHANNEL_BASE2(4), errDmaRead, sio2DmaWrite, sio2DmaInterrupt, sio2DmaStart}, //11: Sio2
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{"Sio2 (reads)", _ER_, CHANNEL_BASE2(5), sio2DmaRead, errDmaWrite, sio2DmaInterrupt, sio2DmaStart}, //12: Sio2
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#else
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{"Sio2 (writes)", _D__}, //11: Sio2
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{"Sio2 (reads)", _D__}, //12: Sio2
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#endif
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{"?", _D__}, //13
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// if each dmac has 7 channels, the list would end here, but I'm not sure :p
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};
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// runtime variables
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struct DmaChannelInfo
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{
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s32 ByteCount;
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s32 NextUpdate;
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} IopDmaChannels[DMA_CHANNEL_MAX] = {0};
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//////////////////////////////////////////////////////////////////////////////////////////////
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// Tool functions
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void SetDmaUpdateTarget(u32 delay)
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{
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psxCounters[8].CycleT = delay;
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if (delay < psxNextCounter)
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psxNextCounter = delay;
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}
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void RaiseDmaIrq(u32 channel)
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{
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if(channel<7)
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psxDmaInterrupt(channel);
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else
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psxDmaInterrupt2(channel-7);
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}
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//////////////////////////////////////////////////////////////////////////////////////////////
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// IopDmaStart: Called from IopHwWrite to test and possibly start a dma transfer
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void IopDmaStart(int channel)
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{
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if(!(IopDmaHandlers[channel].DirectionFlags&_E__))
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return;
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int chcr = IopDmaHandlers[channel].REG_CHCR();
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int pcr = (channel>=7)?(HW_DMA_PCR2 & (8 << ((channel-7) * 4))):(HW_DMA_PCR & (8 << (channel * 4)));
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if ( !(chcr & 0x01000000) || !pcr)
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return;
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// I dont' really understand this, but it's used above. Is this BYTES OR WHAT?
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int bcr = IopDmaHandlers[channel].REG_BCR();
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int bcr_size = (bcr & 0xFFFF);
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int bcr_count = (bcr >> 16);
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int size = 4* bcr_count * bcr_size;
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int dirf = IopDmaHandlers[channel].DirectionFlags&3;
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if(dirf != 3)
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{
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bool ok = (chcr & DMA_CTRL_DIRECTION)? (dirf==_D_W) : (dirf==_DR_);
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if(!ok)
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{
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// hack?!
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IopDmaHandlers[channel].REG_CHCR() &= ~DMA_CTRL_ACTIVE;
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return;
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}
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}
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if(IopDmaHandlers[channel].Start)
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{
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int ret = IopDmaHandlers[channel].Start(channel,
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IopDmaHandlers[channel].REG_MADR(),
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IopDmaHandlers[channel].REG_BCR(),
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IopDmaHandlers[channel].REG_CHCR());
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if(ret < 0)
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{
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IopDmaHandlers[channel].REG_CHCR() &= ~DMA_CTRL_ACTIVE;
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return;
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}
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}
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//Console.WriteLn(Color_StrongOrange,"Starting NewDMA ch=%d, size=%d(0x%08x), dir=%d", channel, size, bcr, chcr&DMA_CTRL_DIRECTION);
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IopDmaHandlers[channel].REG_CHCR() |= DMA_CTRL_ACTIVE;
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IopDmaChannels[channel].ByteCount = size;
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IopDmaChannels[channel].NextUpdate = 0;
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//SetDmaUpdateTarget(1);
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{
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const s32 difference = psxRegs.cycle - psxCounters[8].sCycleT;
|
|
|
|
psxCounters[8].sCycleT = psxRegs.cycle;
|
|
psxCounters[8].CycleT = psxCounters[8].rate;
|
|
IopDmaUpdate(difference);
|
|
|
|
s32 c = psxCounters[8].CycleT;
|
|
if (c < psxNextCounter) psxNextCounter = c;
|
|
}
|
|
}
|
|
|
|
//////////////////////////////////////////////////////////////////////////////////////////////
|
|
// IopDmaProcessChannel: Called from IopDmaUpdate (below) to process a dma channel
|
|
|
|
template<int channel>
|
|
static void __ri IopDmaProcessChannel(int elapsed, int& MinDelay)
|
|
{
|
|
// Hopefully the compiler would be able to optimize the whole function away if this doesn't pass.
|
|
if(!(IopDmaHandlers[channel].DirectionFlags&_E__))
|
|
return;
|
|
|
|
DmaChannelInfo *ch = IopDmaChannels + channel;
|
|
const DmaHandlerInfo *hh = IopDmaHandlers + channel;
|
|
|
|
if (hh->REG_CHCR()&DMA_CTRL_ACTIVE)
|
|
{
|
|
ch->NextUpdate -= elapsed;
|
|
if (ch->NextUpdate <= 0) // Refresh target passed
|
|
{
|
|
if (ch->ByteCount <= 0) // No more data left, finish dma
|
|
{
|
|
ch->NextUpdate = 0x7fffffff;
|
|
|
|
hh->REG_CHCR() &= ~DMA_CTRL_ACTIVE;
|
|
RaiseDmaIrq(channel);
|
|
hh->Interrupt(channel);
|
|
}
|
|
else // let the handlers transfer more data
|
|
{
|
|
int chcr = hh->REG_CHCR();
|
|
|
|
DmaHandler handler = (chcr & DMA_CTRL_DIRECTION) ? hh->Write : hh->Read;
|
|
|
|
u32 ProcessedBytes = 0;
|
|
s32 RequestedDelay = (handler) ? handler(channel, (u32*)iopPhysMem(hh->REG_MADR()), ch->ByteCount, &ProcessedBytes) : 0;
|
|
|
|
if(ProcessedBytes>0 && (!(chcr & DMA_CTRL_DIRECTION)))
|
|
{
|
|
psxCpu->Clear(hh->REG_MADR(), ProcessedBytes/4);
|
|
}
|
|
|
|
int NextUpdateDelay = 100;
|
|
if (RequestedDelay < 0) // error code
|
|
{
|
|
// TODO: ... What to do if the handler gives an error code? :P
|
|
DevCon.Warning("ERROR on channel %d",channel);
|
|
hh->REG_CHCR() &= ~DMA_CTRL_ACTIVE;
|
|
RaiseDmaIrq(channel);
|
|
hh->Interrupt(channel);
|
|
}
|
|
else if (ProcessedBytes > 0) // if not an error, continue transfer
|
|
{
|
|
//DevCon.WriteLn("Transfer channel %d, ProcessedBytes = %d",i,ProcessedBytes);
|
|
hh->REG_MADR()+= ProcessedBytes;
|
|
ch->ByteCount -= ProcessedBytes;
|
|
|
|
NextUpdateDelay = ProcessedBytes/2; // / ch->Width;
|
|
}
|
|
else if(RequestedDelay==0)
|
|
DevCon.Warning("What now? :p"); // its ok as long as there's a delay requeste, autodma requires this.
|
|
|
|
if (RequestedDelay != 0) NextUpdateDelay = RequestedDelay;
|
|
|
|
// SPU2 adma early interrupts. PCSX2 likes those better currently.
|
|
if((channel==4 || channel==7) && (ch->ByteCount<=0) && (ProcessedBytes <= 1024))
|
|
{
|
|
ch->NextUpdate = 0;
|
|
}
|
|
else
|
|
ch->NextUpdate += NextUpdateDelay;
|
|
|
|
//ch->NextUpdate += NextUpdateDelay;
|
|
}
|
|
}
|
|
|
|
int nTarget = ch->NextUpdate;
|
|
if(nTarget < 0) nTarget = 0;
|
|
|
|
if (nTarget<MinDelay)
|
|
MinDelay = nTarget;
|
|
}
|
|
}
|
|
|
|
//////////////////////////////////////////////////////////////////////////////////////////////
|
|
// IopDmaProcessChannel: Called regularly to update the active channels
|
|
|
|
void IopDmaUpdate(u32 elapsed)
|
|
{
|
|
s32 MinDelay=0;
|
|
|
|
do {
|
|
MinDelay = 0x7FFFFFFF; // max possible value
|
|
|
|
// Unrolled
|
|
//IopDmaProcessChannel<0>(elapsed, MinDelay);
|
|
//IopDmaProcessChannel<1>(elapsed, MinDelay);
|
|
//IopDmaProcessChannel<2>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<3>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<4>(elapsed, MinDelay);
|
|
//IopDmaProcessChannel<5>(elapsed, MinDelay);
|
|
//IopDmaProcessChannel<6>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<7>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<8>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<9>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<10>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<11>(elapsed, MinDelay);
|
|
IopDmaProcessChannel<12>(elapsed, MinDelay);
|
|
//IopDmaProcessChannel<13>(elapsed, MinDelay);
|
|
|
|
// reset elapsed time in case we loop
|
|
elapsed=0;
|
|
}
|
|
while(MinDelay <= 0);
|
|
|
|
if(MinDelay<0x7FFFFFFF)
|
|
{
|
|
// tell the iop when to call this function again
|
|
SetDmaUpdateTarget(MinDelay);
|
|
}
|
|
else
|
|
{
|
|
// bogus value so the function gets called again, not sure if it's necessary anymore
|
|
SetDmaUpdateTarget(10000);
|
|
}
|
|
}
|
|
|
|
//////////////////////////////////////////////////////////////////////////////////////////////
|
|
// Error functions: dummy functions for unsupported dma "directions"
|
|
|
|
s32 CALLBACK errDmaRead(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed)
|
|
{
|
|
Console.Error("ERROR: Tried to read using DMA %d (%s). Ignoring.", channel, IopDmaHandlers[channel]);
|
|
|
|
*bytesProcessed = bytesLeft;
|
|
return 0;
|
|
}
|
|
|
|
s32 CALLBACK errDmaWrite(s32 channel, u32* data, u32 bytesLeft, u32* bytesProcessed)
|
|
{
|
|
Console.Error("ERROR: Tried to write using DMA %d (%s). Ignoring.", channel, IopDmaHandlers[channel]);
|
|
|
|
*bytesProcessed = bytesLeft;
|
|
return 0;
|
|
}
|
|
|
|
void SaveStateBase::iopDmacFreeze()
|
|
{
|
|
FreezeTag("iopDmac");
|
|
|
|
Freeze(IopDmaChannels);
|
|
|
|
if( IsLoading() )
|
|
{
|
|
SetDmaUpdateTarget(10000); // Might be needed to kickstart the main updater :p
|
|
}
|
|
}
|
|
|
|
#endif
|