/* * Copyright (C) 2002-2006 The DOSBox 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include #include "dosbox.h" #include "mem.h" #include "inout.h" #include "dma.h" #include "pic.h" #include "paging.h" #include "setup.h" DmaController *DmaControllers[2]; #define EMM_PAGEFRAME4K ((0xE000*16)/4096) Bit32u ems_board_mapping[LINK_START]; static void UpdateEMSMapping(void) { /* if EMS is not present, this will result in a 1:1 mapping */ Bitu i; for (i=0;i<0x10;i++) { ems_board_mapping[EMM_PAGEFRAME4K+i]=paging.firstmb[EMM_PAGEFRAME4K+i]; } } /* read a block from physical memory */ static void DMA_BlockRead(PhysPt pt,void * data,Bitu size) { Bit8u * write=(Bit8u *) data; for ( ; size ; size--, pt++) { Bitu page = pt >> 12; /* care for EMS pageframe etc. */ if (page < EMM_PAGEFRAME4K) page = paging.firstmb[page]; else if (page < EMM_PAGEFRAME4K+0x10) page = ems_board_mapping[page]; else if (page < LINK_START) page = paging.firstmb[page]; *write++=phys_readb(page*4096 + (pt & 4095)); } } /* write a block into physical memory */ static void DMA_BlockWrite(PhysPt pt,void * data,Bitu size) { Bit8u * read=(Bit8u *) data; for ( ; size ; size--, pt++) { Bitu page = pt >> 12; /* care for EMS pageframe etc. */ if (page < EMM_PAGEFRAME4K) page = paging.firstmb[page]; else if (page < EMM_PAGEFRAME4K+0x10) page = ems_board_mapping[page]; else if (page < LINK_START) page = paging.firstmb[page]; phys_writeb(page*4096 + (pt & 4095), *read++); } } DmaChannel * GetDMAChannel(Bit8u chan) { if (chan<4) { /* channel on first DMA controller */ if (DmaControllers[0]) return DmaControllers[0]->GetChannel(chan); } else if (chan<8) { /* channel on second DMA controller */ if (DmaControllers[1]) return DmaControllers[1]->GetChannel(chan-4); } return NULL; } /* remove the second DMA controller (ports are removed automatically) */ void CloseSecondDMAController(void) { if (DmaControllers[1]) { delete DmaControllers[1]; DmaControllers[1]=NULL; } } /* check availability of second DMA controller, needed for SB16 */ bool SecondDMAControllerAvailable(void) { if (DmaControllers[1]) return true; else return false; } static void DMA_Write_Port(Bitu port,Bitu val,Bitu iolen) { if (port<0x10) { /* write to the first DMA controller (channels 0-3) */ DmaControllers[0]->WriteControllerReg(port,val,1); } else if (port>=0xc0 && port <=0xdf) { /* write to the second DMA controller (channels 4-7) */ DmaControllers[1]->WriteControllerReg((port-0xc0) >> 1,val,1); } else { UpdateEMSMapping(); switch (port) { /* write DMA page register */ case 0x81:GetDMAChannel(2)->SetPage(val);break; case 0x82:GetDMAChannel(3)->SetPage(val);break; case 0x83:GetDMAChannel(1)->SetPage(val);break; case 0x89:GetDMAChannel(6)->SetPage(val);break; case 0x8a:GetDMAChannel(7)->SetPage(val);break; case 0x8b:GetDMAChannel(5)->SetPage(val);break; } } } static Bitu DMA_Read_Port(Bitu port,Bitu iolen) { if (port<0x10) { /* read from the first DMA controller (channels 0-3) */ return DmaControllers[0]->ReadControllerReg(port,iolen); } else if (port>=0xc0 && port <=0xdf) { /* read from the second DMA controller (channels 4-7) */ return DmaControllers[1]->ReadControllerReg((port-0xc0) >> 1,iolen); } else switch (port) { /* read DMA page register */ case 0x81:return GetDMAChannel(2)->pagenum; case 0x82:return GetDMAChannel(3)->pagenum; case 0x83:return GetDMAChannel(1)->pagenum; case 0x89:return GetDMAChannel(6)->pagenum; case 0x8a:return GetDMAChannel(7)->pagenum; case 0x8b:return GetDMAChannel(5)->pagenum; } return 0; } void DmaController::WriteControllerReg(Bitu reg,Bitu val,Bitu len) { DmaChannel * chan;Bitu i; switch (reg) { /* set base address of DMA transfer (1st byte low part, 2nd byte high part) */ case 0x0:case 0x2:case 0x4:case 0x6: UpdateEMSMapping(); chan=GetChannel(reg >> 1); flipflop=!flipflop; if (flipflop) { chan->baseaddr=(chan->baseaddr&0xff00)|val; chan->curraddr=(chan->curraddr&0xff00)|val; } else { chan->baseaddr=(chan->baseaddr&0x00ff)|(val << 8); chan->curraddr=(chan->curraddr&0x00ff)|(val << 8); } break; /* set DMA transfer count (1st byte low part, 2nd byte high part) */ case 0x1:case 0x3:case 0x5:case 0x7: UpdateEMSMapping(); chan=GetChannel(reg >> 1); flipflop=!flipflop; if (flipflop) { chan->basecnt=(chan->basecnt&0xff00)|val; chan->currcnt=(chan->currcnt&0xff00)|val; } else { chan->basecnt=(chan->basecnt&0x00ff)|(val << 8); chan->currcnt=(chan->currcnt&0x00ff)|(val << 8); } break; case 0x8: /* Comand reg not used */ break; case 0x9: /* Request registers, memory to memory */ //TODO Warning? break; case 0xa: /* Mask Register */ if ((val & 0x4)==0) UpdateEMSMapping(); chan=GetChannel(val & 3); chan->SetMask((val & 0x4)>0); break; case 0xb: /* Mode Register */ UpdateEMSMapping(); chan=GetChannel(val & 3); chan->autoinit=(val & 0x10) > 0; chan->increment=(val & 0x20) > 0; //TODO Maybe other bits? break; case 0xc: /* Clear Flip/Flip */ flipflop=false; break; case 0xd: /* Master Clear/Reset */ for (i=0;i<4;i++) { chan=GetChannel(i); chan->SetMask(true); chan->tcount=false; } flipflop=false; break; case 0xe: /* Clear Mask register */ UpdateEMSMapping(); for (i=0;i<4;i++) { chan=GetChannel(i); chan->SetMask(false); } break; case 0xf: /* Multiple Mask register */ UpdateEMSMapping(); for (i=0;i<4;i++) { chan=GetChannel(i); chan->SetMask(val & 1); val>>=1; } break; } } Bitu DmaController::ReadControllerReg(Bitu reg,Bitu len) { DmaChannel * chan;Bitu i,ret; switch (reg) { /* read base address of DMA transfer (1st byte low part, 2nd byte high part) */ case 0x0:case 0x2:case 0x4:case 0x6: chan=GetChannel(reg >> 1); flipflop=!flipflop; if (flipflop) { return chan->curraddr & 0xff; } else { return (chan->curraddr >> 8) & 0xff; } /* read DMA transfer count (1st byte low part, 2nd byte high part) */ case 0x1:case 0x3:case 0x5:case 0x7: chan=GetChannel(reg >> 1); flipflop=!flipflop; if (flipflop) { return chan->currcnt & 0xff; } else { return (chan->currcnt >> 8) & 0xff; } case 0x8: /* Status Register */ ret=0; for (i=0;i<4;i++) { chan=GetChannel(i); if (chan->tcount) ret|=1 << i; chan->tcount=false; if (chan->callback) ret|=1 << (i+4); } return ret; default: LOG(LOG_DMA,LOG_NORMAL)("Trying to read undefined DMA port %x",reg); break; } return 0xffffffff; } DmaChannel::DmaChannel(Bit8u num, bool dma16) { masked = true; callback = NULL; if(num == 4) return; channum = num; DMA16 = dma16 ? 0x1 : 0x0; pagenum = 0; pagebase = 0; baseaddr = 0; curraddr = 0; basecnt = 0; currcnt = 0; increment = true; autoinit = false; tcount = false; } Bitu DmaChannel::Read(Bitu want, Bit8u * buffer) { Bitu done=0; again: Bitu left=(currcnt+1); if (wantDMA_WriteHandler[i].Install(i,DMA_Write_Port,mask); DmaControllers[0]->DMA_ReadHandler[i].Install(i,DMA_Read_Port,mask); if (machine==MCH_VGA) { /* install handler for second DMA controller ports */ DmaControllers[1]->DMA_WriteHandler[i].Install(0xc0+i*2,DMA_Write_Port,mask); DmaControllers[1]->DMA_ReadHandler[i].Install(0xc0+i*2,DMA_Read_Port,mask); } } /* install handlers for ports 0x81-0x83 (on the first DMA controller) */ DmaControllers[0]->DMA_WriteHandler[0x10].Install(0x81,DMA_Write_Port,IO_MB,3); DmaControllers[0]->DMA_ReadHandler[0x10].Install(0x81,DMA_Read_Port,IO_MB,3); if (machine==MCH_VGA) { /* install handlers for ports 0x81-0x83 (on the second DMA controller) */ DmaControllers[1]->DMA_WriteHandler[0x10].Install(0x89,DMA_Write_Port,IO_MB,3); DmaControllers[1]->DMA_ReadHandler[0x10].Install(0x89,DMA_Read_Port,IO_MB,3); } } ~DMA(){ if (DmaControllers[0]) { delete DmaControllers[0]; DmaControllers[0]=NULL; } if (DmaControllers[1]) { delete DmaControllers[1]; DmaControllers[1]=NULL; } } }; static DMA* test; void DMA_Destroy(Section* sec){ delete test; } void DMA_Init(Section* sec) { test = new DMA(sec); sec->AddDestroyFunction(&DMA_Destroy); Bitu i; for (i=0;i