melonDS/DMA.cpp

270 lines
6.8 KiB
C++

/*
Copyright 2016-2017 StapleButter
This file is part of melonDS.
melonDS 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 3 of the License, or (at your option)
any later version.
melonDS 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 melonDS. If not, see http://www.gnu.org/licenses/.
*/
#include <stdio.h>
#include "NDS.h"
#include "DMA.h"
#include "NDSCart.h"
#include "GPU3D.h"
// NOTES ON DMA SHIT
//
// * could use optimized code paths for common types of DMA transfers. for example, VRAM
// * needs to eventually be made more accurate anyway. DMA isn't instant.
DMA::DMA(u32 cpu, u32 num)
{
CPU = cpu;
Num = num;
if (cpu == 0)
CountMask = 0x001FFFFF;
else
CountMask = (num==3 ? 0x0000FFFF : 0x00003FFF);
// TODO: merge with the one in ARM.cpp, somewhere
for (int i = 0; i < 16; i++)
{
Waitstates[0][i] = 1;
Waitstates[1][i] = 1;
}
if (!cpu)
{
// ARM9
// note: 33MHz cycles
Waitstates[0][0x2] = 1;
Waitstates[0][0x3] = 1;
Waitstates[0][0x4] = 1;
Waitstates[0][0x5] = 1;
Waitstates[0][0x6] = 1;
Waitstates[0][0x7] = 1;
Waitstates[0][0x8] = 6;
Waitstates[0][0x9] = 6;
Waitstates[0][0xA] = 10;
Waitstates[0][0xF] = 1;
Waitstates[1][0x2] = 2;
Waitstates[1][0x3] = 1;
Waitstates[1][0x4] = 1;
Waitstates[1][0x5] = 2;
Waitstates[1][0x6] = 2;
Waitstates[1][0x7] = 1;
Waitstates[1][0x8] = 12;
Waitstates[1][0x9] = 12;
Waitstates[1][0xA] = 10;
Waitstates[1][0xF] = 1;
}
else
{
// ARM7
Waitstates[0][0x0] = 1;
Waitstates[0][0x2] = 1;
Waitstates[0][0x3] = 1;
Waitstates[0][0x4] = 1;
Waitstates[0][0x6] = 1;
Waitstates[0][0x8] = 6;
Waitstates[0][0x9] = 6;
Waitstates[0][0xA] = 10;
Waitstates[1][0x0] = 1;
Waitstates[1][0x2] = 2;
Waitstates[1][0x3] = 1;
Waitstates[1][0x4] = 1;
Waitstates[1][0x6] = 2;
Waitstates[1][0x8] = 12;
Waitstates[1][0x9] = 12;
Waitstates[1][0xA] = 10;
}
Reset();
}
DMA::~DMA()
{
}
void DMA::Reset()
{
SrcAddr = 0;
DstAddr = 0;
Cnt = 0;
StartMode = 0;
CurSrcAddr = 0;
CurDstAddr = 0;
RemCount = 0;
IterCount = 0;
SrcAddrInc = 0;
DstAddrInc = 0;
Running = false;
}
void DMA::WriteCnt(u32 val)
{
u32 oldcnt = Cnt;
Cnt = val;
if ((!(oldcnt & 0x80000000)) && (val & 0x80000000))
{
CurSrcAddr = SrcAddr;
CurDstAddr = DstAddr;
switch (Cnt & 0x00600000)
{
case 0x00000000: DstAddrInc = 1; break;
case 0x00200000: DstAddrInc = -1; break;
case 0x00400000: DstAddrInc = 0; break;
case 0x00600000: DstAddrInc = 1; break;
}
switch (Cnt & 0x01800000)
{
case 0x00000000: SrcAddrInc = 1; break;
case 0x00800000: SrcAddrInc = -1; break;
case 0x01000000: SrcAddrInc = 0; break;
case 0x01800000: SrcAddrInc = 1; printf("BAD DMA SRC INC MODE 3\n"); break;
}
if (CPU == 0)
StartMode = (Cnt >> 27) & 0x7;
else
StartMode = ((Cnt >> 28) & 0x3) | 0x10;
if ((StartMode & 0x7) == 0)
Start();
else if (StartMode == 0x07)
GPU3D::CheckFIFODMA();
if ((StartMode&7)!=0x00 && (StartMode&7)!=0x1 && StartMode!=2 && StartMode!=0x05 && StartMode!=0x12 && StartMode!=0x07)
printf("UNIMPLEMENTED ARM%d DMA%d START MODE %02X\n", CPU?7:9, Num, StartMode);
}
}
void DMA::Start()
{
if (Running) return;
u32 countmask;
if (CPU == 0)
countmask = 0x001FFFFF;
else
countmask = (Num==3 ? 0x0000FFFF : 0x00003FFF);
RemCount = Cnt & countmask;
if (!RemCount)
RemCount = countmask+1;
if (StartMode == 0x07 && RemCount > 112)
IterCount = 112;
else
IterCount = RemCount;
if ((Cnt & 0x00600000) == 0x00600000)
CurDstAddr = DstAddr;
//printf("ARM%d DMA%d %08X %02X %08X->%08X %d bytes %dbit\n", CPU?7:9, Num, Cnt, StartMode, CurSrcAddr, CurDstAddr, RemCount*((Cnt&0x04000000)?4:2), (Cnt&0x04000000)?32:16);
// special path for cart DMA. this is a gross hack.
// emulating it properly requires emulating cart transfer delays, so uh... TODO
if (CurSrcAddr==0x04100010 && RemCount==1 && (Cnt & 0x07E00000)==0x07000000 &&
StartMode==0x05 || StartMode==0x12)
{
NDSCart::DMA(CurDstAddr);
Cnt &= ~0x80000000;
if (Cnt & 0x40000000)
NDS::SetIRQ(CPU, NDS::IRQ_DMA0 + Num);
return;
}
// TODO eventually: not stop if we're running code in ITCM
Running = true;
NDS::StopCPU(CPU, 1<<Num);
}
s32 DMA::Run(s32 cycles)
{
if (!Running)
return cycles;
if (!(Cnt & 0x04000000))
{
u16 (*readfn)(u32) = CPU ? NDS::ARM7Read16 : NDS::ARM9Read16;
void (*writefn)(u32,u16) = CPU ? NDS::ARM7Write16 : NDS::ARM9Write16;
while (IterCount > 0 && cycles > 0)
{
writefn(CurDstAddr, readfn(CurSrcAddr));
cycles -= (Waitstates[0][(CurSrcAddr >> 24) & 0xF] + Waitstates[0][(CurDstAddr >> 24) & 0xF]);
CurSrcAddr += SrcAddrInc<<1;
CurDstAddr += DstAddrInc<<1;
IterCount--;
RemCount--;
}
}
else
{
u32 (*readfn)(u32) = CPU ? NDS::ARM7Read32 : NDS::ARM9Read32;
void (*writefn)(u32,u32) = CPU ? NDS::ARM7Write32 : NDS::ARM9Write32;
while (IterCount > 0 && cycles > 0)
{
writefn(CurDstAddr, readfn(CurSrcAddr));
cycles -= (Waitstates[1][(CurSrcAddr >> 24) & 0xF] + Waitstates[1][(CurDstAddr >> 24) & 0xF]);
CurSrcAddr += SrcAddrInc<<2;
CurDstAddr += DstAddrInc<<2;
IterCount--;
RemCount--;
}
}
if (RemCount)
{
Cnt &= ~CountMask;
Cnt |= RemCount;
if (IterCount == 0)
{
Running = false;
NDS::ResumeCPU(CPU, 1<<Num);
if (StartMode == 0x07)
GPU3D::CheckFIFODMA();
}
return cycles;
}
if (!(Cnt & 0x02000000))
Cnt &= ~0x80000000;
if (Cnt & 0x40000000)
NDS::SetIRQ(CPU, NDS::IRQ_DMA0 + Num);
Running = false;
NDS::ResumeCPU(CPU, 1<<Num);
return cycles - 2;
}