melonDS/src/CP15.cpp
2024-06-15 17:01:19 +02:00

1041 lines
23 KiB
C++

/*
Copyright 2016-2024 melonDS team
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 <string.h>
#include "NDS.h"
#include "DSi.h"
#include "ARM.h"
#include "Platform.h"
#include "ARMJIT_Memory.h"
#include "ARMJIT.h"
namespace melonDS
{
using Platform::Log;
using Platform::LogLevel;
// access timing for cached regions
// this would be an average between cache hits and cache misses
// this was measured to be close to hardware average
// a value of 1 would represent a perfect cache, but that causes
// games to run too fast, causing a number of issues
const int kDataCacheTiming = 3;//2;
const int kCodeCacheTiming = 3;//5;
void ARMv5::CP15Reset()
{
CP15Control = 0x2078; // dunno
RNGSeed = 44203;
DTCMSetting = 0;
ITCMSetting = 0;
memset(ITCM, 0, ITCMPhysicalSize);
memset(DTCM, 0, DTCMPhysicalSize);
ITCMSize = 0;
DTCMBase = 0xFFFFFFFF;
DTCMMask = 0;
memset(ICache, 0, 0x2000);
ICacheInvalidateAll();
memset(ICacheCount, 0, 64);
PU_CodeCacheable = 0;
PU_DataCacheable = 0;
PU_DataCacheWrite = 0;
PU_CodeRW = 0;
PU_DataRW = 0;
memset(PU_Region, 0, 8*sizeof(u32));
UpdatePURegions(true);
CurICacheLine = NULL;
}
void ARMv5::CP15DoSavestate(Savestate* file)
{
file->Section("CP15");
file->Var32(&CP15Control);
file->Var32(&DTCMSetting);
file->Var32(&ITCMSetting);
file->VarArray(ITCM, ITCMPhysicalSize);
file->VarArray(DTCM, DTCMPhysicalSize);
file->Var32(&PU_CodeCacheable);
file->Var32(&PU_DataCacheable);
file->Var32(&PU_DataCacheWrite);
file->Var32(&PU_CodeRW);
file->Var32(&PU_DataRW);
file->VarArray(PU_Region, 8*sizeof(u32));
if (!file->Saving)
{
UpdateDTCMSetting();
UpdateITCMSetting();
UpdatePURegions(true);
}
}
void ARMv5::UpdateDTCMSetting()
{
u32 newDTCMBase;
u32 newDTCMMask;
u32 newDTCMSize;
if (CP15Control & (1<<16))
{
newDTCMSize = 0x200 << ((DTCMSetting >> 1) & 0x1F);
if (newDTCMSize < 0x1000) newDTCMSize = 0x1000;
newDTCMMask = 0xFFFFF000 & ~(newDTCMSize-1);
newDTCMBase = DTCMSetting & newDTCMMask;
}
else
{
newDTCMSize = 0;
newDTCMBase = 0xFFFFFFFF;
newDTCMMask = 0;
}
if (newDTCMBase != DTCMBase || newDTCMMask != DTCMMask)
{
NDS.JIT.Memory.RemapDTCM(newDTCMBase, newDTCMSize);
DTCMBase = newDTCMBase;
DTCMMask = newDTCMMask;
}
}
void ARMv5::UpdateITCMSetting()
{
if (CP15Control & (1<<18))
{
ITCMSize = 0x200 << ((ITCMSetting >> 1) & 0x1F);
#ifdef JIT_ENABLED
FastBlockLookupSize = 0;
#endif
}
else
{
ITCMSize = 0;
}
}
// covers updates to a specific PU region's cache/etc settings
// (not to the region range/enabled status)
void ARMv5::UpdatePURegion(u32 n)
{
if (!(CP15Control & (1<<0)))
return;
u32 coderw = (PU_CodeRW >> (4*n)) & 0xF;
u32 datarw = (PU_DataRW >> (4*n)) & 0xF;
u32 codecache, datacache, datawrite;
// datacache/datawrite
// 0/0: goes to memory
// 0/1: goes to memory
// 1/0: goes to memory and cache
// 1/1: goes to cache
if (CP15Control & (1<<12))
codecache = (PU_CodeCacheable >> n) & 0x1;
else
codecache = 0;
if (CP15Control & (1<<2))
{
datacache = (PU_DataCacheable >> n) & 0x1;
datawrite = (PU_DataCacheWrite >> n) & 0x1;
}
else
{
datacache = 0;
datawrite = 0;
}
u32 rgn = PU_Region[n];
if (!(rgn & (1<<0)))
{
return;
}
// notes:
// * min size of a pu region is 4KiB (12 bits)
// * size is calculated as size + 1, but the 12 lsb of address space are ignored, therefore we need it as size + 1 - 12, or size - 11
// * pu regions are aligned based on their size
u32 size = std::max((int)((rgn>>1) & 0x1F) - 11, 0); // obtain the size, subtract 11 and clamp to a min of 0.
u32 start = ((rgn >> 12) >> size) << size; // determine the start offset, and use shifts to force alignment with a multiple of the size.
u32 end = start + (1<<size); // add 1 left shifted by size to start to determine end point
// dont need to bounds check the end point because the force alignment inherently prevents it from breaking
u8 usermask = 0;
u8 privmask = 0;
switch (datarw)
{
case 0: break;
case 1: privmask |= 0x03; break;
case 2: privmask |= 0x03; usermask |= 0x01; break;
case 3: privmask |= 0x03; usermask |= 0x03; break;
case 5: privmask |= 0x01; break;
case 6: privmask |= 0x01; usermask |= 0x01; break;
default: Log(LogLevel::Warn, "!! BAD DATARW VALUE %d\n", datarw&0xF);
}
switch (coderw)
{
case 0: break;
case 1: privmask |= 0x04; break;
case 2: privmask |= 0x04; usermask |= 0x04; break;
case 3: privmask |= 0x04; usermask |= 0x04; break;
case 5: privmask |= 0x04; break;
case 6: privmask |= 0x04; usermask |= 0x04; break;
default: Log(LogLevel::Warn, "!! BAD CODERW VALUE %d\n", datarw&0xF);
}
if (datacache & 0x1)
{
privmask |= 0x10;
usermask |= 0x10;
if (datawrite & 0x1)
{
privmask |= 0x20;
usermask |= 0x20;
}
}
if (codecache & 0x1)
{
privmask |= 0x40;
usermask |= 0x40;
}
Log(
LogLevel::Debug,
"PU region %d: %08X-%08X, user=%02X priv=%02X, %08X/%08X\n",
n,
start << 12,
(end << 12) - 1,
usermask,
privmask,
PU_DataRW,
PU_CodeRW
);
for (u32 i = start; i < end; i++)
{
PU_UserMap[i] = usermask;
PU_PrivMap[i] = privmask;
}
UpdateRegionTimings(start, end);
}
void ARMv5::UpdatePURegions(bool update_all)
{
if (!(CP15Control & (1<<0)))
{
// PU disabled
u8 mask = 0x07;
if (CP15Control & (1<<2)) mask |= 0x30;
if (CP15Control & (1<<12)) mask |= 0x40;
memset(PU_UserMap, mask, 0x100000);
memset(PU_PrivMap, mask, 0x100000);
UpdateRegionTimings(0x00000, 0x100000);
return;
}
if (update_all)
{
memset(PU_UserMap, 0, 0x100000);
memset(PU_PrivMap, 0, 0x100000);
}
for (int n = 0; n < 8; n++)
{
UpdatePURegion(n);
}
// TODO: this is way unoptimized
// should be okay unless the game keeps changing shit, tho
if (update_all) UpdateRegionTimings(0x00000, 0x100000);
// TODO: throw exception if the region we're running in has become non-executable, I guess
}
void ARMv5::UpdateRegionTimings(u32 addrstart, u32 addrend)
{
for (u32 i = addrstart; i < addrend; i++)
{
u8 pu = PU_Map[i];
u8* bustimings = NDS.ARM9MemTimings[i >> 2];
if (pu & 0x40)
{
MemTimings[i][0] = 0xFF;//kCodeCacheTiming;
}
else
{
MemTimings[i][0] = bustimings[2] << NDS.ARM9ClockShift;
}
if (pu & 0x10)
{
MemTimings[i][1] = kDataCacheTiming;
MemTimings[i][2] = kDataCacheTiming;
MemTimings[i][3] = 1;
}
else
{
MemTimings[i][1] = bustimings[0] << NDS.ARM9ClockShift;
MemTimings[i][2] = bustimings[2] << NDS.ARM9ClockShift;
MemTimings[i][3] = bustimings[3] << NDS.ARM9ClockShift;
}
}
}
u32 ARMv5::RandomLineIndex()
{
// lame RNG, but good enough for this purpose
u32 s = RNGSeed;
RNGSeed ^= (s*17);
RNGSeed ^= (s*7);
return (RNGSeed >> 17) & 0x3;
}
void ARMv5::ICacheLookup(u32 addr)
{
u32 tag = addr & 0xFFFFF800;
u32 id = (addr >> 5) & 0x3F;
id <<= 2;
if (ICacheTags[id+0] == tag)
{
CodeCycles = 1;
CurICacheLine = &ICache[(id+0) << 5];
return;
}
if (ICacheTags[id+1] == tag)
{
CodeCycles = 1;
CurICacheLine = &ICache[(id+1) << 5];
return;
}
if (ICacheTags[id+2] == tag)
{
CodeCycles = 1;
CurICacheLine = &ICache[(id+2) << 5];
return;
}
if (ICacheTags[id+3] == tag)
{
CodeCycles = 1;
CurICacheLine = &ICache[(id+3) << 5];
return;
}
// cache miss
u32 line;
if (CP15Control & (1<<14))
{
line = ICacheCount[id>>2];
ICacheCount[id>>2] = (line+1) & 0x3;
}
else
{
line = RandomLineIndex();
}
line += id;
addr &= ~0x1F;
u8* ptr = &ICache[line << 5];
if (CodeMem.Mem)
{
memcpy(ptr, &CodeMem.Mem[addr & CodeMem.Mask], 32);
}
else
{
for (int i = 0; i < 32; i+=4)
*(u32*)&ptr[i] = NDS.ARM9Read32(addr+i);
}
ICacheTags[line] = tag;
// ouch :/
//printf("cache miss %08X: %d/%d\n", addr, NDS::ARM9MemTimings[addr >> 14][2], NDS::ARM9MemTimings[addr >> 14][3]);
CodeCycles = (NDS.ARM9MemTimings[addr >> 14][2] + (NDS.ARM9MemTimings[addr >> 14][3] * 7)) << NDS.ARM9ClockShift;
CurICacheLine = ptr;
}
void ARMv5::ICacheInvalidateByAddr(u32 addr)
{
u32 tag = addr & 0xFFFFF800;
u32 id = (addr >> 5) & 0x3F;
id <<= 2;
if (ICacheTags[id+0] == tag)
{
ICacheTags[id+0] = 1;
return;
}
if (ICacheTags[id+1] == tag)
{
ICacheTags[id+1] = 1;
return;
}
if (ICacheTags[id+2] == tag)
{
ICacheTags[id+2] = 1;
return;
}
if (ICacheTags[id+3] == tag)
{
ICacheTags[id+3] = 1;
return;
}
}
void ARMv5::ICacheInvalidateAll()
{
for (int i = 0; i < 64*4; i++)
ICacheTags[i] = 1;
}
void ARMv5::CP15Write(u32 id, u32 val)
{
//if(id!=0x704)printf("CP15 write op %03X %08X %08X\n", id, val, R[15]);
switch (id)
{
case 0x100:
{
u32 old = CP15Control;
val &= 0x000FF085;
CP15Control &= ~0x000FF085;
CP15Control |= val;
//printf("CP15Control = %08X (%08X->%08X)\n", CP15Control, old, val);
UpdateDTCMSetting();
UpdateITCMSetting();
if ((old & 0x1005) != (val & 0x1005))
{
UpdatePURegions((old & 0x1) != (val & 0x1));
}
if (val & (1<<7)) Log(LogLevel::Warn, "!!!! ARM9 BIG ENDIAN MODE. VERY BAD. SHIT GONNA ASPLODE NOW\n");
if (val & (1<<13)) ExceptionBase = 0xFFFF0000;
else ExceptionBase = 0x00000000;
}
return;
case 0x200: // data cacheable
{
u32 diff = PU_DataCacheable ^ val;
PU_DataCacheable = val;
for (u32 i = 0; i < 8; i++)
{
if (diff & (1<<i)) UpdatePURegion(i);
}
}
return;
case 0x201: // code cacheable
{
u32 diff = PU_CodeCacheable ^ val;
PU_CodeCacheable = val;
for (u32 i = 0; i < 8; i++)
{
if (diff & (1<<i)) UpdatePURegion(i);
}
}
return;
case 0x300: // data cache write-buffer
{
u32 diff = PU_DataCacheWrite ^ val;
PU_DataCacheWrite = val;
for (u32 i = 0; i < 8; i++)
{
if (diff & (1<<i)) UpdatePURegion(i);
}
}
return;
case 0x500: // legacy data permissions
{
u32 old = PU_DataRW;
PU_DataRW = 0;
PU_DataRW |= (val & 0x0003);
PU_DataRW |= ((val & 0x000C) << 2);
PU_DataRW |= ((val & 0x0030) << 4);
PU_DataRW |= ((val & 0x00C0) << 6);
PU_DataRW |= ((val & 0x0300) << 8);
PU_DataRW |= ((val & 0x0C00) << 10);
PU_DataRW |= ((val & 0x3000) << 12);
PU_DataRW |= ((val & 0xC000) << 14);
u32 diff = old ^ PU_DataRW;
for (u32 i = 0; i < 8; i++)
{
if (diff & (0xF<<(i*4))) UpdatePURegion(i);
}
}
return;
case 0x501: // legacy code permissions
{
u32 old = PU_CodeRW;
PU_CodeRW = 0;
PU_CodeRW |= (val & 0x0003);
PU_CodeRW |= ((val & 0x000C) << 2);
PU_CodeRW |= ((val & 0x0030) << 4);
PU_CodeRW |= ((val & 0x00C0) << 6);
PU_CodeRW |= ((val & 0x0300) << 8);
PU_CodeRW |= ((val & 0x0C00) << 10);
PU_CodeRW |= ((val & 0x3000) << 12);
PU_CodeRW |= ((val & 0xC000) << 14);
u32 diff = old ^ PU_CodeRW;
for (u32 i = 0; i < 8; i++)
{
if (diff & (0xF<<(i*4))) UpdatePURegion(i);
}
}
return;
case 0x502: // data permissions
{
u32 diff = PU_DataRW ^ val;
PU_DataRW = val;
for (u32 i = 0; i < 8; i++)
{
if (diff & (0xF<<(i*4))) UpdatePURegion(i);
}
}
return;
case 0x503: // code permissions
{
u32 diff = PU_CodeRW ^ val;
PU_CodeRW = val;
for (u32 i = 0; i < 8; i++)
{
if (diff & (0xF<<(i*4))) UpdatePURegion(i);
}
}
return;
case 0x600:
case 0x601:
case 0x610:
case 0x611:
case 0x620:
case 0x621:
case 0x630:
case 0x631:
case 0x640:
case 0x641:
case 0x650:
case 0x651:
case 0x660:
case 0x661:
case 0x670:
case 0x671:
char log_output[1024];
PU_Region[(id >> 4) & 0xF] = val;
std::snprintf(log_output,
sizeof(log_output),
"PU: region %d = %08X : %s, start: %08X size: %02X\n",
(id >> 4) & 0xF,
val,
val & 1 ? "enabled" : "disabled",
val & 0xFFFFF000,
(val & 0x3E) >> 1
);
Log(LogLevel::Debug, "%s", log_output);
// Some implementations of Log imply a newline, so we build up the line before printing it
// TODO: smarter region update for this?
UpdatePURegions(true);
return;
case 0x704:
case 0x782:
Halt(1);
return;
case 0x750:
ICacheInvalidateAll();
//Halt(255);
return;
case 0x751:
ICacheInvalidateByAddr(val);
//Halt(255);
return;
case 0x752:
Log(LogLevel::Warn, "CP15: ICACHE INVALIDATE WEIRD. %08X\n", val);
//Halt(255);
return;
case 0x761:
//printf("inval data cache %08X\n", val);
return;
case 0x762:
//printf("inval data cache SI\n");
return;
case 0x7A1:
//printf("flush data cache %08X\n", val);
return;
case 0x7A2:
//printf("flush data cache SI\n");
return;
case 0x910:
DTCMSetting = val & 0xFFFFF03E;
UpdateDTCMSetting();
return;
case 0x911:
ITCMSetting = val & 0x0000003E;
UpdateITCMSetting();
return;
case 0xF00:
//printf("cache debug index register %08X\n", val);
return;
case 0xF10:
//printf("cache debug instruction tag %08X\n", val);
return;
case 0xF20:
//printf("cache debug data tag %08X\n", val);
return;
case 0xF30:
//printf("cache debug instruction cache %08X\n", val);
return;
case 0xF40:
//printf("cache debug data cache %08X\n", val);
return;
}
if ((id & 0xF00) == 0xF00) // test/debug shit?
return;
if ((id & 0xF00) != 0x700)
Log(LogLevel::Debug, "unknown CP15 write op %03X %08X\n", id, val);
}
u32 ARMv5::CP15Read(u32 id) const
{
//printf("CP15 read op %03X %08X\n", id, NDS::ARM9->R[15]);
switch (id)
{
case 0x000: // CPU ID
case 0x003:
case 0x004:
case 0x005:
case 0x006:
case 0x007:
return 0x41059461;
case 0x001: // cache type
return 0x0F0D2112;
case 0x002: // TCM size
return (6 << 6) | (5 << 18);
case 0x100: // control reg
return CP15Control;
case 0x200:
return PU_DataCacheable;
case 0x201:
return PU_CodeCacheable;
case 0x300:
return PU_DataCacheWrite;
case 0x500:
{
u32 ret = 0;
ret |= (PU_DataRW & 0x00000003);
ret |= ((PU_DataRW & 0x00000030) >> 2);
ret |= ((PU_DataRW & 0x00000300) >> 4);
ret |= ((PU_DataRW & 0x00003000) >> 6);
ret |= ((PU_DataRW & 0x00030000) >> 8);
ret |= ((PU_DataRW & 0x00300000) >> 10);
ret |= ((PU_DataRW & 0x03000000) >> 12);
ret |= ((PU_DataRW & 0x30000000) >> 14);
return ret;
}
case 0x501:
{
u32 ret = 0;
ret |= (PU_CodeRW & 0x00000003);
ret |= ((PU_CodeRW & 0x00000030) >> 2);
ret |= ((PU_CodeRW & 0x00000300) >> 4);
ret |= ((PU_CodeRW & 0x00003000) >> 6);
ret |= ((PU_CodeRW & 0x00030000) >> 8);
ret |= ((PU_CodeRW & 0x00300000) >> 10);
ret |= ((PU_CodeRW & 0x03000000) >> 12);
ret |= ((PU_CodeRW & 0x30000000) >> 14);
return ret;
}
case 0x502:
return PU_DataRW;
case 0x503:
return PU_CodeRW;
case 0x600:
case 0x601:
case 0x610:
case 0x611:
case 0x620:
case 0x621:
case 0x630:
case 0x631:
case 0x640:
case 0x641:
case 0x650:
case 0x651:
case 0x660:
case 0x661:
case 0x670:
case 0x671:
return PU_Region[(id >> 4) & 0xF];
case 0x910:
return DTCMSetting;
case 0x911:
return ITCMSetting;
}
if ((id & 0xF00) == 0xF00) // test/debug shit?
return 0;
Log(LogLevel::Debug, "unknown CP15 read op %03X\n", id);
return 0;
}
// TCM are handled here.
// TODO: later on, handle PU, and maybe caches
u32 ARMv5::CodeRead32(u32 addr, bool branch)
{
/*if (branch || (!(addr & 0xFFF)))
{
if (!(PU_Map[addr>>12] & 0x04))
{
PrefetchAbort();
return 0;
}
}*/
if (addr < ITCMSize)
{
CodeCycles = 1;
return *(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)];
}
CodeCycles = RegionCodeCycles;
if (CodeCycles == 0xFF) // cached memory. hax
{
if (branch || !(addr & 0x1F))
CodeCycles = kCodeCacheTiming;//ICacheLookup(addr);
else
CodeCycles = 1;
//return *(u32*)&CurICacheLine[addr & 0x1C];
}
if (CodeMem.Mem) return *(u32*)&CodeMem.Mem[addr & CodeMem.Mask];
return BusRead32(addr);
}
void ARMv5::DataRead8(u32 addr, u32* val)
{
if (!(PU_Map[addr>>12] & 0x01))
{
DataAbort();
return;
}
DataRegion = addr;
if (addr < ITCMSize)
{
DataCycles = 1;
*val = *(u8*)&ITCM[addr & (ITCMPhysicalSize - 1)];
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*val = *(u8*)&DTCM[addr & (DTCMPhysicalSize - 1)];
return;
}
*val = BusRead8(addr);
DataCycles = MemTimings[addr >> 12][1];
}
void ARMv5::DataRead16(u32 addr, u32* val)
{
if (!(PU_Map[addr>>12] & 0x01))
{
DataAbort();
return;
}
DataRegion = addr;
addr &= ~1;
if (addr < ITCMSize)
{
DataCycles = 1;
*val = *(u16*)&ITCM[addr & (ITCMPhysicalSize - 1)];
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*val = *(u16*)&DTCM[addr & (DTCMPhysicalSize - 1)];
return;
}
*val = BusRead16(addr);
DataCycles = MemTimings[addr >> 12][1];
}
void ARMv5::DataRead32(u32 addr, u32* val)
{
if (!(PU_Map[addr>>12] & 0x01))
{
DataAbort();
return;
}
DataRegion = addr;
addr &= ~3;
if (addr < ITCMSize)
{
DataCycles = 1;
*val = *(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)];
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*val = *(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)];
return;
}
*val = BusRead32(addr);
DataCycles = MemTimings[addr >> 12][2];
}
void ARMv5::DataRead32S(u32 addr, u32* val)
{
addr &= ~3;
if (addr < ITCMSize)
{
DataCycles += 1;
*val = *(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)];
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles += 1;
*val = *(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)];
return;
}
*val = BusRead32(addr);
DataCycles += MemTimings[addr >> 12][3];
}
void ARMv5::DataWrite8(u32 addr, u8 val)
{
if (!(PU_Map[addr>>12] & 0x02))
{
DataAbort();
return;
}
DataRegion = addr;
if (addr < ITCMSize)
{
DataCycles = 1;
*(u8*)&ITCM[addr & (ITCMPhysicalSize - 1)] = val;
NDS.JIT.CheckAndInvalidate<0, ARMJIT_Memory::memregion_ITCM>(addr);
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*(u8*)&DTCM[addr & (DTCMPhysicalSize - 1)] = val;
return;
}
BusWrite8(addr, val);
DataCycles = MemTimings[addr >> 12][1];
}
void ARMv5::DataWrite16(u32 addr, u16 val)
{
if (!(PU_Map[addr>>12] & 0x02))
{
DataAbort();
return;
}
DataRegion = addr;
addr &= ~1;
if (addr < ITCMSize)
{
DataCycles = 1;
*(u16*)&ITCM[addr & (ITCMPhysicalSize - 1)] = val;
NDS.JIT.CheckAndInvalidate<0, ARMJIT_Memory::memregion_ITCM>(addr);
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*(u16*)&DTCM[addr & (DTCMPhysicalSize - 1)] = val;
return;
}
BusWrite16(addr, val);
DataCycles = MemTimings[addr >> 12][1];
}
void ARMv5::DataWrite32(u32 addr, u32 val)
{
if (!(PU_Map[addr>>12] & 0x02))
{
DataAbort();
return;
}
DataRegion = addr;
addr &= ~3;
if (addr < ITCMSize)
{
DataCycles = 1;
*(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)] = val;
NDS.JIT.CheckAndInvalidate<0, ARMJIT_Memory::memregion_ITCM>(addr);
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles = 1;
*(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)] = val;
return;
}
BusWrite32(addr, val);
DataCycles = MemTimings[addr >> 12][2];
}
void ARMv5::DataWrite32S(u32 addr, u32 val)
{
addr &= ~3;
if (addr < ITCMSize)
{
DataCycles += 1;
*(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)] = val;
#ifdef JIT_ENABLED
NDS.JIT.CheckAndInvalidate<0, ARMJIT_Memory::memregion_ITCM>(addr);
#endif
return;
}
if ((addr & DTCMMask) == DTCMBase)
{
DataCycles += 1;
*(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)] = val;
return;
}
BusWrite32(addr, val);
DataCycles += MemTimings[addr >> 12][3];
}
void ARMv5::GetCodeMemRegion(u32 addr, MemRegion* region)
{
/*if (addr < ITCMSize)
{
region->Mem = ITCM;
region->Mask = 0x7FFF;
return;
}*/
NDS.ARM9GetMemRegion(addr, false, &CodeMem);
}
}