/* Copyright 2016-2019 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 #include #include "NDS.h" #include "ARM.h" // 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 // code cache timing can get as low as 3 const int kDataCacheTiming = 2; const int kCodeCacheTiming = 5; void ARMv5::CP15Reset() { CP15Control = 0x2078; // dunno DTCMSetting = 0; ITCMSetting = 0; memset(ITCM, 0, 0x8000); memset(DTCM, 0, 0x4000); ITCMSize = 0; DTCMBase = 0xFFFFFFFF; DTCMSize = 0; PU_CodeCacheable = 0; PU_DataCacheable = 0; PU_DataCacheWrite = 0; PU_CodeRW = 0; PU_DataRW = 0; memset(PU_Region, 0, 8*sizeof(u32)); UpdatePURegions(); } void ARMv5::CP15DoSavestate(Savestate* file) { file->Section("CP15"); file->Var32(&CP15Control); file->Var32(&DTCMSetting); file->Var32(&ITCMSetting); file->VarArray(ITCM, 0x8000); file->VarArray(DTCM, 0x4000); 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(); } } void ARMv5::UpdateDTCMSetting() { if (CP15Control & (1<<16)) { DTCMBase = DTCMSetting & 0xFFFFF000; DTCMSize = 0x200 << ((DTCMSetting >> 1) & 0x1F); //printf("DTCM [%08X] enabled at %08X, size %X\n", DTCMSetting, DTCMBase, DTCMSize); } else { DTCMBase = 0xFFFFFFFF; DTCMSize = 0; //printf("DTCM disabled\n"); } } void ARMv5::UpdateITCMSetting() { if (CP15Control & (1<<18)) { ITCMSize = 0x200 << ((ITCMSetting >> 1) & 0x1F); //printf("ITCM [%08X] enabled at %08X, size %X\n", ITCMSetting, 0, ITCMSize); } else { ITCMSize = 0; //printf("ITCM disabled\n"); } } void ARMv5::UpdatePURegions() { 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); return; } memset(PU_UserMap, 0, 0x100000); memset(PU_PrivMap, 0, 0x100000); u32 coderw = PU_CodeRW; u32 datarw = PU_DataRW; 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; else codecache = 0; if (CP15Control & (1<<2)) { datacache = PU_DataCacheable; datawrite = PU_DataCacheWrite; } else { datacache = 0; datawrite = 0; } for (int n = 0; n < 8; n++) { u32 rgn = PU_Region[n]; if (!(rgn & (1<<0))) continue; u32 start = rgn >> 12; u32 sz = 2 << ((rgn >> 1) & 0x1F); u32 end = start + (sz >> 12); // TODO: check alignment of start u8 usermask = 0; u8 privmask = 0; switch (datarw & 0xF) { 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: printf("!! BAD DATARW VALUE %d\n", datarw&0xF); } switch (coderw & 0xF) { 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: printf("!! 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; } printf("PU region %d: %08X-%08X, user=%02X priv=%02X\n", n, start<<12, end<<12, usermask, privmask); for (u32 i = start; i < end; i++) { PU_UserMap[i] = usermask; PU_PrivMap[i] = privmask; } coderw >>= 4; datarw >>= 4; codecache >>= 1; datacache >>= 1; datawrite >>= 1; // TODO: this will not be enough if they change their PU regions after the intial setup //UpdateRegionTimings(start<<12, end<<12); } // TODO: this is way unoptimized // should be okay unless the game keeps changing shit, tho UpdateRegionTimings(0x00000000, 0xFFFFFFFF); } void ARMv5::UpdateRegionTimings(u32 addrstart, u32 addrend) { addrstart >>= 12; addrend >>= 12; if (addrend == 0xFFFFF) 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] << ClockShift; } if (pu & 0x10) { MemTimings[i][1] = kDataCacheTiming; MemTimings[i][2] = kDataCacheTiming; MemTimings[i][3] = 1; } else { MemTimings[i][1] = bustimings[0] << ClockShift; MemTimings[i][2] = bustimings[2] << ClockShift; MemTimings[i][3] = bustimings[3] << ClockShift; } } } void ARMv5::CP15Write(u32 id, u32 val) { //printf("CP15 write op %03X %08X %08X\n", id, val, NDS::ARM9->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(); if (val & (1<<7)) printf("!!!! 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 PU_DataCacheable = val; printf("PU: DataCacheable=%08X\n", val); UpdatePURegions(); return; case 0x201: // code cacheable PU_CodeCacheable = val; printf("PU: CodeCacheable=%08X\n", val); UpdatePURegions(); return; case 0x300: // data cache write-buffer PU_DataCacheWrite = val; printf("PU: DataCacheWrite=%08X\n", val); UpdatePURegions(); return; case 0x500: // legacy data permissions 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); printf("PU: DataRW=%08X (legacy %08X)\n", PU_DataRW, val); UpdatePURegions(); return; case 0x501: // legacy code permissions 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); printf("PU: CodeRW=%08X (legacy %08X)\n", PU_CodeRW, val); UpdatePURegions(); return; case 0x502: // data permissions PU_DataRW = val; printf("PU: DataRW=%08X\n", PU_DataRW); UpdatePURegions(); return; case 0x503: // code permissions PU_CodeRW = val; printf("PU: CodeRW=%08X\n", PU_CodeRW); UpdatePURegions(); 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: PU_Region[(id >> 4) & 0xF] = val; printf("PU: region %d = %08X : ", (id>>4)&0xF, val); printf("%s, ", val&1 ? "enabled":"disabled"); printf("%08X-", val&0xFFFFF000); printf("%08X\n", (val&0xFFFFF000)+(2<<((val&0x3E)>>1))); UpdatePURegions(); return; case 0x704: case 0x782: Halt(1); 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; UpdateDTCMSetting(); return; case 0x911: ITCMSetting = val; UpdateITCMSetting(); return; } if ((id&0xF00)!=0x700) printf("unknown CP15 write op %03X %08X\n", id, val); } u32 ARMv5::CP15Read(u32 id) { //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; } printf("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) { if (addr < ITCMSize) { CodeCycles = 1; return *(u32*)&ITCM[addr & 0x7FFF]; } CodeCycles = RegionCodeCycles; if (CodeCycles == 0xFF) { // sort of code cache hit/miss average if (!(addr & 0x1F)) CodeCycles = kCodeCacheTiming; else CodeCycles = 1; } if (CodeMem.Mem) return *(u32*)&CodeMem.Mem[addr & CodeMem.Mask]; return NDS::ARM9Read32(addr); } void ARMv5::DataRead8(u32 addr, u32* val) { if (addr < ITCMSize) { DataCycles = 1; *val = *(u8*)&ITCM[addr & 0x7FFF]; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *val = *(u8*)&DTCM[(addr - DTCMBase) & 0x3FFF]; return; } *val = NDS::ARM9Read8(addr); DataCycles = MemTimings[addr >> 12][1]; } void ARMv5::DataRead16(u32 addr, u32* val) { addr &= ~1; if (addr < ITCMSize) { DataCycles = 1; *val = *(u16*)&ITCM[addr & 0x7FFF]; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *val = *(u16*)&DTCM[(addr - DTCMBase) & 0x3FFF]; return; } *val = NDS::ARM9Read16(addr); DataCycles = MemTimings[addr >> 12][1]; } void ARMv5::DataRead32(u32 addr, u32* val) { addr &= ~3; if (addr < ITCMSize) { DataCycles = 1; *val = *(u32*)&ITCM[addr & 0x7FFF]; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *val = *(u32*)&DTCM[(addr - DTCMBase) & 0x3FFF]; return; } *val = NDS::ARM9Read32(addr); DataCycles = MemTimings[addr >> 12][2]; } void ARMv5::DataRead32S(u32 addr, u32* val) { addr &= ~3; if (addr < ITCMSize) { DataCycles += 1; *val = *(u32*)&ITCM[addr & 0x7FFF]; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles += 1; *val = *(u32*)&DTCM[(addr - DTCMBase) & 0x3FFF]; return; } *val = NDS::ARM9Read32(addr); DataCycles += MemTimings[addr >> 12][3]; } void ARMv5::DataWrite8(u32 addr, u8 val) { if (addr < ITCMSize) { DataCycles = 1; *(u8*)&ITCM[addr & 0x7FFF] = val; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *(u8*)&DTCM[(addr - DTCMBase) & 0x3FFF] = val; return; } NDS::ARM9Write8(addr, val); DataCycles = MemTimings[addr >> 12][1]; } void ARMv5::DataWrite16(u32 addr, u16 val) { addr &= ~1; if (addr < ITCMSize) { DataCycles = 1; *(u16*)&ITCM[addr & 0x7FFF] = val; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *(u16*)&DTCM[(addr - DTCMBase) & 0x3FFF] = val; return; } NDS::ARM9Write16(addr, val); DataCycles = MemTimings[addr >> 12][1]; } void ARMv5::DataWrite32(u32 addr, u32 val) { addr &= ~3; if (addr < ITCMSize) { DataCycles = 1; *(u32*)&ITCM[addr & 0x7FFF] = val; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles = 1; *(u32*)&DTCM[(addr - DTCMBase) & 0x3FFF] = val; return; } NDS::ARM9Write32(addr, val); DataCycles = MemTimings[addr >> 12][2]; } void ARMv5::DataWrite32S(u32 addr, u32 val) { addr &= ~3; if (addr < ITCMSize) { DataCycles += 1; *(u32*)&ITCM[addr & 0x7FFF] = val; return; } if (addr >= DTCMBase && addr < (DTCMBase + DTCMSize)) { DataCycles += 1; *(u32*)&DTCM[(addr - DTCMBase) & 0x3FFF] = val; return; } NDS::ARM9Write32(addr, val); DataCycles += MemTimings[addr >> 12][3]; } void ARMv5::GetCodeMemRegion(u32 addr, NDS::MemRegion* region) { /*if (addr < ITCMSize) { region->Mem = ITCM; region->Mask = 0x7FFF; return; }*/ NDS::ARM9GetMemRegion(addr, false, &CodeMem); }