/* Copyright 2016-2023 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 #include #include "NDS.h" #include "DSi.h" #include "ARM.h" #include "ARMInterpreter.h" #include "AREngine.h" #include "ARMJIT.h" #include "Platform.h" #include "GPU.h" #include "ARMJIT_Memory.h" using Platform::Log; using Platform::LogLevel; #ifdef GDBSTUB_ENABLED void ARM::GdbCheckA() { if (!IsSingleStep && !BreakReq) { // check if eg. break signal is incoming etc. Gdb::StubState st = GdbStub.Enter(false, Gdb::TgtStatus::NoEvent, ~(u32)0u, BreakOnStartup); BreakOnStartup = false; IsSingleStep = st == Gdb::StubState::Step; BreakReq = st == Gdb::StubState::Attach || st == Gdb::StubState::Break; } } void ARM::GdbCheckB() { if (IsSingleStep || BreakReq) { // use else here or we single-step the same insn twice in gdb u32 pc_real = R[15] - ((CPSR & 0x20) ? 2 : 4); Gdb::StubState st = GdbStub.Enter(true, Gdb::TgtStatus::SingleStep, pc_real); IsSingleStep = st == Gdb::StubState::Step; BreakReq = st == Gdb::StubState::Attach || st == Gdb::StubState::Break; } } void ARM::GdbCheckC() { u32 pc_real = R[15] - ((CPSR & 0x20) ? 2 : 4); Gdb::StubState st = GdbStub.CheckBkpt(pc_real, true, true); if (st != Gdb::StubState::CheckNoHit) { IsSingleStep = st == Gdb::StubState::Step; BreakReq = st == Gdb::StubState::Attach || st == Gdb::StubState::Break; } else GdbCheckB(); } #else void ARM::GdbCheckA() {} void ARM::GdbCheckB() {} void ARM::GdbCheckC() {} #endif // instruction timing notes // // * simple instruction: 1S (code) // * LDR: 1N+1N+1I (code/data/internal) // * STR: 1N+1N (code/data) // * LDM: 1N+1N+(n-1)S+1I // * STM: 1N+1N+(n-1)S // * MUL/etc: 1N+xI (code/internal) // * branch: 1N+1S (code/code) (pipeline refill) // // MUL/MLA seems to take 1I on ARM9 const u32 ARM::ConditionTable[16] = { 0xF0F0, // EQ 0x0F0F, // NE 0xCCCC, // CS 0x3333, // CC 0xFF00, // MI 0x00FF, // PL 0xAAAA, // VS 0x5555, // VC 0x0C0C, // HI 0xF3F3, // LS 0xAA55, // GE 0x55AA, // LT 0x0A05, // GT 0xF5FA, // LE 0xFFFF, // AL 0x0000 // NE }; ARM::ARM(u32 num, ARMJIT::ARMJIT& jit, Melon::GPU& gpu) : #ifdef GDBSTUB_ENABLED GdbStub(this, Platform::GetConfigInt(num ? Platform::GdbPortARM7 : Platform::GdbPortARM9)), #endif JIT(jit), Num(num), // well uh GPU(gpu) { #ifdef GDBSTUB_ENABLED if (Platform::GetConfigBool(Platform::GdbEnabled) #ifdef JIT_ENABLED && !Platform::GetConfigBool(Platform::JIT_Enable) #endif ) GdbStub.Init(); IsSingleStep = false; #endif } ARM::~ARM() { // dorp } ARMv5::ARMv5(ARMJIT::ARMJIT& jit, Melon::GPU& gpu) : ARM(0, jit, gpu) { DTCM = JIT.Memory.GetARM9DTCM(); PU_Map = PU_PrivMap; } ARMv4::ARMv4(ARMJIT::ARMJIT& jit, Melon::GPU& gpu) : ARM(1, jit, gpu) { // } ARMv5::~ARMv5() { // DTCM is owned by Memory, not going to delete it } void ARM::Reset() { Cycles = 0; Halted = 0; IRQ = 0; for (int i = 0; i < 16; i++) R[i] = 0; CPSR = 0x000000D3; for (int i = 0; i < 7; i++) R_FIQ[i] = 0; for (int i = 0; i < 2; i++) { R_SVC[i] = 0; R_ABT[i] = 0; R_IRQ[i] = 0; R_UND[i] = 0; } R_FIQ[7] = 0x00000010; R_SVC[2] = 0x00000010; R_ABT[2] = 0x00000010; R_IRQ[2] = 0x00000010; R_UND[2] = 0x00000010; ExceptionBase = Num ? 0x00000000 : 0xFFFF0000; CodeMem.Mem = NULL; #ifdef JIT_ENABLED FastBlockLookup = NULL; FastBlockLookupStart = 0; FastBlockLookupSize = 0; #endif #ifdef GDBSTUB_ENABLED IsSingleStep = false; BreakReq = false; BreakOnStartup = Platform::GetConfigBool( Num ? Platform::GdbARM7BreakOnStartup : Platform::GdbARM9BreakOnStartup); #endif // zorp JumpTo(ExceptionBase); } void ARMv5::Reset() { if (NDS::ConsoleType == 1) { BusRead8 = DSi::ARM9Read8; BusRead16 = DSi::ARM9Read16; BusRead32 = DSi::ARM9Read32; BusWrite8 = DSi::ARM9Write8; BusWrite16 = DSi::ARM9Write16; BusWrite32 = DSi::ARM9Write32; GetMemRegion = DSi::ARM9GetMemRegion; } else { BusRead8 = NDS::ARM9Read8; BusRead16 = NDS::ARM9Read16; BusRead32 = NDS::ARM9Read32; BusWrite8 = NDS::ARM9Write8; BusWrite16 = NDS::ARM9Write16; BusWrite32 = NDS::ARM9Write32; GetMemRegion = NDS::ARM9GetMemRegion; } PU_Map = PU_PrivMap; ARM::Reset(); } void ARMv4::Reset() { if (NDS::ConsoleType) { BusRead8 = DSi::ARM7Read8; BusRead16 = DSi::ARM7Read16; BusRead32 = DSi::ARM7Read32; BusWrite8 = DSi::ARM7Write8; BusWrite16 = DSi::ARM7Write16; BusWrite32 = DSi::ARM7Write32; } else { BusRead8 = NDS::ARM7Read8; BusRead16 = NDS::ARM7Read16; BusRead32 = NDS::ARM7Read32; BusWrite8 = NDS::ARM7Write8; BusWrite16 = NDS::ARM7Write16; BusWrite32 = NDS::ARM7Write32; } ARM::Reset(); } void ARM::DoSavestate(Savestate* file) { file->Section((char*)(Num ? "ARM7" : "ARM9")); file->Var32((u32*)&Cycles); //file->Var32((u32*)&CyclesToRun); // hack to make save states compatible u32 halted = Halted; file->Var32(&halted); Halted = halted; file->VarArray(R, 16*sizeof(u32)); file->Var32(&CPSR); file->VarArray(R_FIQ, 8*sizeof(u32)); file->VarArray(R_SVC, 3*sizeof(u32)); file->VarArray(R_ABT, 3*sizeof(u32)); file->VarArray(R_IRQ, 3*sizeof(u32)); file->VarArray(R_UND, 3*sizeof(u32)); file->Var32(&CurInstr); #ifdef JIT_ENABLED if (file->Saving && NDS::EnableJIT) { // hack, the JIT doesn't really pipeline // but we still want JIT save states to be // loaded while running the interpreter FillPipeline(); } #endif file->VarArray(NextInstr, 2*sizeof(u32)); file->Var32(&ExceptionBase); if (!file->Saving) { CPSR |= 0x00000010; R_FIQ[7] |= 0x00000010; R_SVC[2] |= 0x00000010; R_ABT[2] |= 0x00000010; R_IRQ[2] |= 0x00000010; R_UND[2] |= 0x00000010; if (!Num) { SetupCodeMem(R[15]); // should fix it ((ARMv5*)this)->RegionCodeCycles = ((ARMv5*)this)->MemTimings[R[15] >> 12][0]; if ((CPSR & 0x1F) == 0x10) ((ARMv5*)this)->PU_Map = ((ARMv5*)this)->PU_UserMap; else ((ARMv5*)this)->PU_Map = ((ARMv5*)this)->PU_PrivMap; } else { CodeRegion = R[15] >> 24; CodeCycles = R[15] >> 15; // cheato } } } void ARMv5::DoSavestate(Savestate* file) { ARM::DoSavestate(file); CP15DoSavestate(file); } void ARM::SetupCodeMem(u32 addr) { if (!Num) { ((ARMv5*)this)->GetCodeMemRegion(addr, &CodeMem); } else { // not sure it's worth it for the ARM7 // esp. as everything there generally runs on WRAM // and due to how it's mapped, we can't use this optimization //NDS::ARM7GetMemRegion(addr, false, &CodeMem); } } void ARMv5::JumpTo(u32 addr, bool restorecpsr) { if (restorecpsr) { RestoreCPSR(); if (CPSR & 0x20) addr |= 0x1; else addr &= ~0x1; } // aging cart debug crap //if (addr == 0x0201764C) printf("capture test %d: R1=%08X\n", R[6], R[1]); //if (addr == 0x020175D8) printf("capture test %d: res=%08X\n", R[6], R[0]); u32 oldregion = R[15] >> 24; u32 newregion = addr >> 24; RegionCodeCycles = MemTimings[addr >> 12][0]; if (addr & 0x1) { addr &= ~0x1; R[15] = addr+2; if (newregion != oldregion) SetupCodeMem(addr); // two-opcodes-at-once fetch // doesn't matter if we put garbage in the MSbs there if (addr & 0x2) { NextInstr[0] = CodeRead32(addr-2, true) >> 16; Cycles += CodeCycles; NextInstr[1] = CodeRead32(addr+2, false); Cycles += CodeCycles; } else { NextInstr[0] = CodeRead32(addr, true); NextInstr[1] = NextInstr[0] >> 16; Cycles += CodeCycles; } CPSR |= 0x20; } else { addr &= ~0x3; R[15] = addr+4; if (newregion != oldregion) SetupCodeMem(addr); NextInstr[0] = CodeRead32(addr, true); Cycles += CodeCycles; NextInstr[1] = CodeRead32(addr+4, false); Cycles += CodeCycles; CPSR &= ~0x20; } if (!(PU_Map[addr>>12] & 0x04)) { PrefetchAbort(); return; } NDS::MonitorARM9Jump(addr); } void ARMv4::JumpTo(u32 addr, bool restorecpsr) { if (restorecpsr) { RestoreCPSR(); if (CPSR & 0x20) addr |= 0x1; else addr &= ~0x1; } u32 oldregion = R[15] >> 23; u32 newregion = addr >> 23; CodeRegion = addr >> 24; CodeCycles = addr >> 15; // cheato if (addr & 0x1) { addr &= ~0x1; R[15] = addr+2; //if (newregion != oldregion) SetupCodeMem(addr); NextInstr[0] = CodeRead16(addr); NextInstr[1] = CodeRead16(addr+2); Cycles += NDS::ARM7MemTimings[CodeCycles][0] + NDS::ARM7MemTimings[CodeCycles][1]; CPSR |= 0x20; } else { addr &= ~0x3; R[15] = addr+4; //if (newregion != oldregion) SetupCodeMem(addr); NextInstr[0] = CodeRead32(addr); NextInstr[1] = CodeRead32(addr+4); Cycles += NDS::ARM7MemTimings[CodeCycles][2] + NDS::ARM7MemTimings[CodeCycles][3]; CPSR &= ~0x20; } } void ARM::RestoreCPSR() { u32 oldcpsr = CPSR; switch (CPSR & 0x1F) { case 0x11: CPSR = R_FIQ[7]; break; case 0x12: CPSR = R_IRQ[2]; break; case 0x13: CPSR = R_SVC[2]; break; case 0x14: case 0x15: case 0x16: case 0x17: CPSR = R_ABT[2]; break; case 0x18: case 0x19: case 0x1A: case 0x1B: CPSR = R_UND[2]; break; default: Log(LogLevel::Warn, "!! attempt to restore CPSR under bad mode %02X, %08X\n", CPSR&0x1F, R[15]); break; } CPSR |= 0x00000010; UpdateMode(oldcpsr, CPSR); } void ARM::UpdateMode(u32 oldmode, u32 newmode, bool phony) { if ((oldmode & 0x1F) == (newmode & 0x1F)) return; switch (oldmode & 0x1F) { case 0x11: std::swap(R[8], R_FIQ[0]); std::swap(R[9], R_FIQ[1]); std::swap(R[10], R_FIQ[2]); std::swap(R[11], R_FIQ[3]); std::swap(R[12], R_FIQ[4]); std::swap(R[13], R_FIQ[5]); std::swap(R[14], R_FIQ[6]); break; case 0x12: std::swap(R[13], R_IRQ[0]); std::swap(R[14], R_IRQ[1]); break; case 0x13: std::swap(R[13], R_SVC[0]); std::swap(R[14], R_SVC[1]); break; case 0x17: std::swap(R[13], R_ABT[0]); std::swap(R[14], R_ABT[1]); break; case 0x1B: std::swap(R[13], R_UND[0]); std::swap(R[14], R_UND[1]); break; } switch (newmode & 0x1F) { case 0x11: std::swap(R[8], R_FIQ[0]); std::swap(R[9], R_FIQ[1]); std::swap(R[10], R_FIQ[2]); std::swap(R[11], R_FIQ[3]); std::swap(R[12], R_FIQ[4]); std::swap(R[13], R_FIQ[5]); std::swap(R[14], R_FIQ[6]); break; case 0x12: std::swap(R[13], R_IRQ[0]); std::swap(R[14], R_IRQ[1]); break; case 0x13: std::swap(R[13], R_SVC[0]); std::swap(R[14], R_SVC[1]); break; case 0x17: std::swap(R[13], R_ABT[0]); std::swap(R[14], R_ABT[1]); break; case 0x1B: std::swap(R[13], R_UND[0]); std::swap(R[14], R_UND[1]); break; } if ((!phony) && (Num == 0)) { if ((newmode & 0x1F) == 0x10) ((ARMv5*)this)->PU_Map = ((ARMv5*)this)->PU_UserMap; else ((ARMv5*)this)->PU_Map = ((ARMv5*)this)->PU_PrivMap; } } void ARM::TriggerIRQ() { if (CPSR & 0x80) return; u32 oldcpsr = CPSR; CPSR &= ~0xFF; CPSR |= 0xD2; UpdateMode(oldcpsr, CPSR); R_IRQ[2] = oldcpsr; R[14] = R[15] + (oldcpsr & 0x20 ? 2 : 0); JumpTo(ExceptionBase + 0x18); // ARDS cheat support // normally, those work by hijacking the ARM7 VBlank handler if (Num == 1) { if ((NDS::IF[1] & NDS::IE[1]) & (1<RunCheats(); } } void ARMv5::PrefetchAbort() { Log(LogLevel::Warn, "ARM9: prefetch abort (%08X)\n", R[15]); u32 oldcpsr = CPSR; CPSR &= ~0xBF; CPSR |= 0x97; UpdateMode(oldcpsr, CPSR); // this shouldn't happen, but if it does, we're stuck in some nasty endless loop // so better take care of it if (!(PU_Map[ExceptionBase>>12] & 0x04)) { Log(LogLevel::Error, "!!!!! EXCEPTION REGION NOT EXECUTABLE. THIS IS VERY BAD!!\n"); NDS::Stop(Platform::StopReason::BadExceptionRegion); return; } R_ABT[2] = oldcpsr; R[14] = R[15] + (oldcpsr & 0x20 ? 2 : 0); JumpTo(ExceptionBase + 0x0C); } void ARMv5::DataAbort() { Log(LogLevel::Warn, "ARM9: data abort (%08X)\n", R[15]); u32 oldcpsr = CPSR; CPSR &= ~0xBF; CPSR |= 0x97; UpdateMode(oldcpsr, CPSR); R_ABT[2] = oldcpsr; R[14] = R[15] + (oldcpsr & 0x20 ? 4 : 0); JumpTo(ExceptionBase + 0x10); } void ARM::CheckGdbIncoming() { GdbCheckA(); } void ARMv5::Execute() { GdbCheckB(); if (Halted) { if (Halted == 2) { Halted = 0; } else if (NDS::HaltInterrupted(0)) { Halted = 0; if (NDS::IME[0] & 0x1) TriggerIRQ(); } else { NDS::ARM9Timestamp = NDS::ARM9Target; return; } } while (NDS::ARM9Timestamp < NDS::ARM9Target) { if (CPSR & 0x20) // THUMB { GdbCheckC(); // prefetch R[15] += 2; CurInstr = NextInstr[0]; NextInstr[0] = NextInstr[1]; if (R[15] & 0x2) { NextInstr[1] >>= 16; CodeCycles = 0; } else NextInstr[1] = CodeRead32(R[15], false); // actually execute u32 icode = (CurInstr >> 6) & 0x3FF; ARMInterpreter::THUMBInstrTable[icode](this); } else { GdbCheckC(); // prefetch R[15] += 4; CurInstr = NextInstr[0]; NextInstr[0] = NextInstr[1]; NextInstr[1] = CodeRead32(R[15], false); // actually execute if (CheckCondition(CurInstr >> 28)) { u32 icode = ((CurInstr >> 4) & 0xF) | ((CurInstr >> 16) & 0xFF0); ARMInterpreter::ARMInstrTable[icode](this); } else if ((CurInstr & 0xFE000000) == 0xFA000000) { ARMInterpreter::A_BLX_IMM(this); } else AddCycles_C(); } // TODO optimize this shit!!! if (Halted) { if (Halted == 1 && NDS::ARM9Timestamp < NDS::ARM9Target) { NDS::ARM9Timestamp = NDS::ARM9Target; } break; } /*if (NDS::IF[0] & NDS::IE[0]) { if (NDS::IME[0] & 0x1) TriggerIRQ(); }*/ if (IRQ) TriggerIRQ(); NDS::ARM9Timestamp += Cycles; Cycles = 0; } if (Halted == 2) Halted = 0; } #ifdef JIT_ENABLED void ARMv5::ExecuteJIT() { if (Halted) { if (Halted == 2) { Halted = 0; } else if (NDS::HaltInterrupted(0)) { Halted = 0; if (NDS::IME[0] & 0x1) TriggerIRQ(); } else { NDS::ARM9Timestamp = NDS::ARM9Target; return; } } while (NDS::ARM9Timestamp < NDS::ARM9Target) { u32 instrAddr = R[15] - ((CPSR&0x20)?2:4); if ((instrAddr < FastBlockLookupStart || instrAddr >= (FastBlockLookupStart + FastBlockLookupSize)) && !JIT.SetupExecutableRegion(0, instrAddr, FastBlockLookup, FastBlockLookupStart, FastBlockLookupSize)) { NDS::ARM9Timestamp = NDS::ARM9Target; Log(LogLevel::Error, "ARMv5 PC in non executable region %08X\n", R[15]); return; } ARMJIT::JitBlockEntry block = JIT.LookUpBlock(0, FastBlockLookup, instrAddr - FastBlockLookupStart, instrAddr); if (block) ARM_Dispatch(this, block); else JIT.CompileBlock(this); if (StopExecution) { // this order is crucial otherwise idle loops waiting for an IRQ won't function if (IRQ) TriggerIRQ(); if (Halted || IdleLoop) { if ((Halted == 1 || IdleLoop) && NDS::ARM9Timestamp < NDS::ARM9Target) { Cycles = 0; NDS::ARM9Timestamp = NDS::ARM9Target; } IdleLoop = 0; break; } } NDS::ARM9Timestamp += Cycles; Cycles = 0; } if (Halted == 2) Halted = 0; } #endif void ARMv4::Execute() { GdbCheckB(); if (Halted) { if (Halted == 2) { Halted = 0; } else if (NDS::HaltInterrupted(1)) { Halted = 0; if (NDS::IME[1] & 0x1) TriggerIRQ(); } else { NDS::ARM7Timestamp = NDS::ARM7Target; return; } } while (NDS::ARM7Timestamp < NDS::ARM7Target) { if (CPSR & 0x20) // THUMB { GdbCheckC(); // prefetch R[15] += 2; CurInstr = NextInstr[0]; NextInstr[0] = NextInstr[1]; NextInstr[1] = CodeRead16(R[15]); // actually execute u32 icode = (CurInstr >> 6); ARMInterpreter::THUMBInstrTable[icode](this); } else { GdbCheckC(); // prefetch R[15] += 4; CurInstr = NextInstr[0]; NextInstr[0] = NextInstr[1]; NextInstr[1] = CodeRead32(R[15]); // actually execute if (CheckCondition(CurInstr >> 28)) { u32 icode = ((CurInstr >> 4) & 0xF) | ((CurInstr >> 16) & 0xFF0); ARMInterpreter::ARMInstrTable[icode](this); } else AddCycles_C(); } // TODO optimize this shit!!! if (Halted) { if (Halted == 1 && NDS::ARM7Timestamp < NDS::ARM7Target) { NDS::ARM7Timestamp = NDS::ARM7Target; } break; } /*if (NDS::IF[1] & NDS::IE[1]) { if (NDS::IME[1] & 0x1) TriggerIRQ(); }*/ if (IRQ) TriggerIRQ(); NDS::ARM7Timestamp += Cycles; Cycles = 0; } if (Halted == 2) Halted = 0; if (Halted == 4) { DSi::SoftReset(); Halted = 2; } } #ifdef JIT_ENABLED void ARMv4::ExecuteJIT() { if (Halted) { if (Halted == 2) { Halted = 0; } else if (NDS::HaltInterrupted(1)) { Halted = 0; if (NDS::IME[1] & 0x1) TriggerIRQ(); } else { NDS::ARM7Timestamp = NDS::ARM7Target; return; } } while (NDS::ARM7Timestamp < NDS::ARM7Target) { u32 instrAddr = R[15] - ((CPSR&0x20)?2:4); if ((instrAddr < FastBlockLookupStart || instrAddr >= (FastBlockLookupStart + FastBlockLookupSize)) && !JIT.SetupExecutableRegion(1, instrAddr, FastBlockLookup, FastBlockLookupStart, FastBlockLookupSize)) { NDS::ARM7Timestamp = NDS::ARM7Target; Log(LogLevel::Error, "ARMv4 PC in non executable region %08X\n", R[15]); return; } ARMJIT::JitBlockEntry block = JIT.LookUpBlock(1, FastBlockLookup, instrAddr - FastBlockLookupStart, instrAddr); if (block) ARM_Dispatch(this, block); else JIT.CompileBlock(this); if (StopExecution) { if (IRQ) TriggerIRQ(); if (Halted || IdleLoop) { if ((Halted == 1 || IdleLoop) && NDS::ARM7Timestamp < NDS::ARM7Target) { Cycles = 0; NDS::ARM7Timestamp = NDS::ARM7Target; } IdleLoop = 0; break; } } NDS::ARM7Timestamp += Cycles; Cycles = 0; } if (Halted == 2) Halted = 0; if (Halted == 4) { DSi::SoftReset(); Halted = 2; } } #endif void ARMv5::FillPipeline() { SetupCodeMem(R[15]); if (CPSR & 0x20) { if ((R[15] - 2) & 0x2) { NextInstr[0] = CodeRead32(R[15] - 4, false) >> 16; NextInstr[1] = CodeRead32(R[15], false); } else { NextInstr[0] = CodeRead32(R[15] - 2, false); NextInstr[1] = NextInstr[0] >> 16; } } else { NextInstr[0] = CodeRead32(R[15] - 4, false); NextInstr[1] = CodeRead32(R[15], false); } } void ARMv4::FillPipeline() { SetupCodeMem(R[15]); if (CPSR & 0x20) { NextInstr[0] = CodeRead16(R[15] - 2); NextInstr[1] = CodeRead16(R[15]); } else { NextInstr[0] = CodeRead32(R[15] - 4); NextInstr[1] = CodeRead32(R[15]); } } #ifdef GDBSTUB_ENABLED u32 ARM::ReadReg(Gdb::Register reg) { using Gdb::Register; int r = static_cast(reg); if (reg < Register::pc) return R[r]; else if (reg == Register::pc) { return R[r] - ((CPSR & 0x20) ? 2 : 4); } else if (reg == Register::cpsr) return CPSR; else if (reg == Register::sp_usr || reg == Register::lr_usr) { r -= static_cast(Register::sp_usr); if (ModeIs(0x10) || ModeIs(0x1f)) { return R[13 + r]; } else switch (CPSR & 0x1f) { case 0x11: return R_FIQ[5 + r]; case 0x12: return R_IRQ[0 + r]; case 0x13: return R_SVC[0 + r]; case 0x17: return R_ABT[0 + r]; case 0x1b: return R_UND[0 + r]; } } else if (reg >= Register::r8_fiq && reg <= Register::lr_fiq) { r -= static_cast(Register::r8_fiq); return ModeIs(0x11) ? R[ 8 + r] : R_FIQ[r]; } else if (reg == Register::sp_irq || reg == Register::lr_irq) { r -= static_cast(Register::sp_irq); return ModeIs(0x12) ? R[13 + r] : R_IRQ[r]; } else if (reg == Register::sp_svc || reg == Register::lr_svc) { r -= static_cast(Register::sp_svc); return ModeIs(0x13) ? R[13 + r] : R_SVC[r]; } else if (reg == Register::sp_abt || reg == Register::lr_abt) { r -= static_cast(Register::sp_abt); return ModeIs(0x17) ? R[13 + r] : R_ABT[r]; } else if (reg == Register::sp_und || reg == Register::lr_und) { r -= static_cast(Register::sp_und); return ModeIs(0x1b) ? R[13 + r] : R_UND[r]; } else if (reg == Register::spsr_fiq) return ModeIs(0x11) ? CPSR : R_FIQ[7]; else if (reg == Register::spsr_irq) return ModeIs(0x12) ? CPSR : R_IRQ[2]; else if (reg == Register::spsr_svc) return ModeIs(0x13) ? CPSR : R_SVC[2]; else if (reg == Register::spsr_abt) return ModeIs(0x17) ? CPSR : R_ABT[2]; else if (reg == Register::spsr_und) return ModeIs(0x1b) ? CPSR : R_UND[2]; Log(LogLevel::Warn, "GDB reg read: unknown reg no %d\n", r); return 0xdeadbeef; } void ARM::WriteReg(Gdb::Register reg, u32 v) { using Gdb::Register; int r = static_cast(reg); if (reg < Register::pc) R[r] = v; else if (reg == Register::pc) JumpTo(v); else if (reg == Register::cpsr) CPSR = v; else if (reg == Register::sp_usr || reg == Register::lr_usr) { r -= static_cast(Register::sp_usr); if (ModeIs(0x10) || ModeIs(0x1f)) { R[13 + r] = v; } else switch (CPSR & 0x1f) { case 0x11: R_FIQ[5 + r] = v; break; case 0x12: R_IRQ[0 + r] = v; break; case 0x13: R_SVC[0 + r] = v; break; case 0x17: R_ABT[0 + r] = v; break; case 0x1b: R_UND[0 + r] = v; break; } } else if (reg >= Register::r8_fiq && reg <= Register::lr_fiq) { r -= static_cast(Register::r8_fiq); *(ModeIs(0x11) ? &R[ 8 + r] : &R_FIQ[r]) = v; } else if (reg == Register::sp_irq || reg == Register::lr_irq) { r -= static_cast(Register::sp_irq); *(ModeIs(0x12) ? &R[13 + r] : &R_IRQ[r]) = v; } else if (reg == Register::sp_svc || reg == Register::lr_svc) { r -= static_cast(Register::sp_svc); *(ModeIs(0x13) ? &R[13 + r] : &R_SVC[r]) = v; } else if (reg == Register::sp_abt || reg == Register::lr_abt) { r -= static_cast(Register::sp_abt); *(ModeIs(0x17) ? &R[13 + r] : &R_ABT[r]) = v; } else if (reg == Register::sp_und || reg == Register::lr_und) { r -= static_cast(Register::sp_und); *(ModeIs(0x1b) ? &R[13 + r] : &R_UND[r]) = v; } else if (reg == Register::spsr_fiq) { *(ModeIs(0x11) ? &CPSR : &R_FIQ[7]) = v; } else if (reg == Register::spsr_irq) { *(ModeIs(0x12) ? &CPSR : &R_IRQ[2]) = v; } else if (reg == Register::spsr_svc) { *(ModeIs(0x13) ? &CPSR : &R_SVC[2]) = v; } else if (reg == Register::spsr_abt) { *(ModeIs(0x17) ? &CPSR : &R_ABT[2]) = v; } else if (reg == Register::spsr_und) { *(ModeIs(0x1b) ? &CPSR : &R_UND[2]) = v; } else Log(LogLevel::Warn, "GDB reg write: unknown reg no %d (write 0x%08x)\n", r, v); } u32 ARM::ReadMem(u32 addr, int size) { if (size == 8) return BusRead8(addr); else if (size == 16) return BusRead16(addr); else if (size == 32) return BusRead32(addr); else return 0xfeedface; } void ARM::WriteMem(u32 addr, int size, u32 v) { if (size == 8) BusWrite8(addr, (u8)v); else if (size == 16) BusWrite16(addr, (u16)v); else if (size == 32) BusWrite32(addr, v); } void ARM::ResetGdb() { NDS::Reset(); GPU.StartFrame(); // need this to properly kick off the scheduler & frame output } int ARM::RemoteCmd(const u8* cmd, size_t len) { (void)len; Log(LogLevel::Info, "[ARMGDB] Rcmd: \"%s\"\n", cmd); if (!strcmp((const char*)cmd, "reset") || !strcmp((const char*)cmd, "r")) { Reset(); return 0; } return 1; // not implemented (yet) } void ARMv5::WriteMem(u32 addr, int size, u32 v) { if (addr < ITCMSize) { if (size == 8) *(u8*)&ITCM[addr & (ITCMPhysicalSize - 1)] = (u8)v; else if (size == 16) *(u16*)&ITCM[addr & (ITCMPhysicalSize - 1)] = (u16)v; else if (size == 32) *(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)] = (u32)v; else {} return; } else if ((addr & DTCMMask) == DTCMBase) { if (size == 8) *(u8*)&DTCM[addr & (DTCMPhysicalSize - 1)] = (u8)v; else if (size == 16) *(u16*)&DTCM[addr & (DTCMPhysicalSize - 1)] = (u16)v; else if (size == 32) *(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)] = (u32)v; else {} return; } ARM::WriteMem(addr, size, v); } u32 ARMv5::ReadMem(u32 addr, int size) { if (addr < ITCMSize) { if (size == 8) return *(u8*)&ITCM[addr & (ITCMPhysicalSize - 1)]; else if (size == 16) return *(u16*)&ITCM[addr & (ITCMPhysicalSize - 1)]; else if (size == 32) return *(u32*)&ITCM[addr & (ITCMPhysicalSize - 1)]; else return 0xfeedface; } else if ((addr & DTCMMask) == DTCMBase) { if (size == 8) return *(u8*)&DTCM[addr & (DTCMPhysicalSize - 1)]; else if (size == 16) return *(u16*)&DTCM[addr & (DTCMPhysicalSize - 1)]; else if (size == 32) return *(u32*)&DTCM[addr & (DTCMPhysicalSize - 1)]; else return 0xfeedface; } return ARM::ReadMem(addr, size); } #endif