// Copyright (C) 2003 Dolphin Project. // 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, version 2.0. // 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 2.0 for more details. // A copy of the GPL 2.0 should have been included with the program. // If not, see http://www.gnu.org/licenses/ // Official SVN repository and contact information can be found at // http://code.google.com/p/dolphin-emu/ #include "ArmABI.h" #include "ArmRegCache.h" #include "ArmEmitter.h" using namespace ArmGen; #define CTXREG (R10) ArmRegCache::ArmRegCache(MIPSState *mips) : mips_(mips) { } void ArmRegCache::Init(ARMXEmitter *emitter) { emit = emitter; } void ArmRegCache::Start(MIPSAnalyst::AnalysisResults &stats) { for (int i = 0; i < 16; i++) { ar[i].mipsReg = -1; ar[i].isDirty = false; } for (int i = 0; i < NUM_MIPSREG; i++) { mr[i].loc = ML_MEM; mr[i].reg = INVALID_REG; mr[i].imm = -1; mr[i].spillLock = false; } } static const ARMReg *GetMIPSAllocationOrder(int &count) { // Note that R0 and R1 are reserved as scratch for now. We can probably free up R1 eventually. // R8 is used to preserve flags in nasty branches. // R9 and upwards are reserved for jit basics. // Six allocated registers should be enough... static const ARMReg allocationOrder[] = { R2, R3, R4, R5, R6, R7 }; count = sizeof(allocationOrder) / sizeof(const int); return allocationOrder; } ARMReg ArmRegCache::MapReg(MIPSReg mipsReg, int mapFlags) { // Let's see if it's already mapped. If so we just need to update the dirty flag. // We don't need to check for ML_NOINIT because we assume that anyone who maps // with that flag immediately writes a "known" value to the register. if (mr[mipsReg].loc == ML_ARMREG) { if (ar[mr[mipsReg].reg].mipsReg != mipsReg) { ERROR_LOG(HLE, "Register mapping out of sync! %i", mipsReg); } if (mapFlags & MAP_DIRTY) { ar[mr[mipsReg].reg].isDirty = true; } return mr[mipsReg].reg; } // Okay, not mapped, so we need to allocate an ARM register. int allocCount; const ARMReg *allocOrder = GetMIPSAllocationOrder(allocCount); allocate: for (int i = 0; i < allocCount; i++) { int reg = allocOrder[i]; if (ar[reg].mipsReg == -1) { // That means it's free. Grab it, and load the value into it (if requested). ar[reg].isDirty = (mapFlags & MAP_DIRTY) ? true : false; if (!(mapFlags & MAP_NOINIT)) { if (mr[mipsReg].loc == ML_MEM) { emit->LDR((ARMReg)reg, CTXREG, 4 * mipsReg); } else if (mr[mipsReg].loc == ML_IMM) { emit->ARMABI_MOVI2R((ARMReg)reg, mr[mipsReg].imm); ar[reg].isDirty = true; } } ar[reg].mipsReg = mipsReg; mr[mipsReg].loc = ML_ARMREG; mr[mipsReg].reg = (ARMReg)reg; return (ARMReg)reg; } } // Still nothing. Let's spill a reg and goto 10. // TODO: Use age or something to choose which register to spill? int bestToSpill = -1; for (int i = 0; i < allocCount; i++) { int reg = allocOrder[i]; if (ar[reg].mipsReg != -1 && mr[ar[reg].mipsReg].spillLock) continue; bestToSpill = reg; break; } if (bestToSpill != -1) { ERROR_LOG(JIT, "Out of registers at PC %08x - spills register %i.", mips_->pc, bestToSpill); FlushArmReg((ARMReg)bestToSpill); goto allocate; } // Uh oh, we have all them spilllocked.... ERROR_LOG(JIT, "Out of spillable registers at PC %08x!!!", mips_->pc); return INVALID_REG; } void ArmRegCache::FlushArmReg(ARMReg r) { if (ar[r].mipsReg == -1) { // Nothing to do, reg not mapped. return; } if (ar[r].mipsReg != -1) { if (ar[r].isDirty && mr[ar[r].mipsReg].loc == ML_ARMREG) emit->STR(CTXREG, r, 4 * ar[r].mipsReg); // IMMs won't be in an ARM reg. mr[ar[r].mipsReg].loc = ML_MEM; mr[ar[r].mipsReg].reg = INVALID_REG; mr[ar[r].mipsReg].imm = 0; } else { ERROR_LOG(HLE, "Dirty but no mipsreg?"); } ar[r].isDirty = false; ar[r].mipsReg = -1; } void ArmRegCache::FlushMipsReg(MIPSReg r) { switch (mr[r].loc) { case ML_IMM: // IMM is always "dirty". emit->ARMABI_MOVI2R(R0, mr[r].imm); emit->STR(CTXREG, R0, GetMipsRegOffset(r)); break; case ML_ARMREG: if (mr[r].reg == INVALID_REG) { ERROR_LOG(HLE, "FlushMipsReg: MipsReg had bad ArmReg"); } if (ar[mr[r].reg].isDirty) { emit->STR(CTXREG, mr[r].reg, GetMipsRegOffset(r)); ar[mr[r].reg].isDirty = false; } ar[mr[r].reg].mipsReg = -1; break; default: //BAD break; } mr[r].loc = ML_MEM; mr[r].reg = INVALID_REG; mr[r].imm = 0; } void ArmRegCache::FlushAll() { for (int i = 0; i < NUM_MIPSREG; i++) { FlushMipsReg(i); } // Sanity check for (int i = 0; i < NUM_ARMREG; i++) { if (ar[i].mipsReg != -1) { ERROR_LOG(JIT, "Flush fail: ar[%i].mipsReg=%i", i, ar[i].mipsReg); } } } void ArmRegCache::SetImm(MIPSReg r, u32 immVal) { // Zap existing value if cached in a reg if (mr[r].loc == ML_ARMREG) { ar[mr[r].reg].mipsReg = -1; ar[mr[r].reg].isDirty = false; } mr[r].loc = ML_IMM; mr[r].imm = immVal; mr[r].reg = INVALID_REG; } bool ArmRegCache::IsImm(MIPSReg r) const { return mr[r].loc == ML_IMM; } u32 ArmRegCache::GetImm(MIPSReg r) const { if (mr[r].loc != ML_IMM) { ERROR_LOG(JIT, "Trying to get imm from non-imm register %i", r); } return mr[r].imm; } int ArmRegCache::GetMipsRegOffset(MIPSReg r) { if (r < 32) return r * 4; switch (r) { case MIPSREG_HI: return offsetof(MIPSState, hi); case MIPSREG_LO: return offsetof(MIPSState, lo); } ERROR_LOG(JIT, "bad mips register %i", r); return 0; // or what? } void ArmRegCache::SpillLock(MIPSReg r1, MIPSReg r2, MIPSReg r3) { mr[r1].spillLock = true; if (r2 != -1) mr[r2].spillLock = true; if (r3 != -1) mr[r3].spillLock = true; } void ArmRegCache::ReleaseSpillLocks() { for (int i = 0; i < NUM_MIPSREG; i++) { mr[i].spillLock = false; } } ARMReg ArmRegCache::R(int mipsReg) { if (mr[mipsReg].loc == ML_ARMREG) { return mr[mipsReg].reg; } else { ERROR_LOG(JIT, "Reg %i not in arm reg. compilerPC = %08x", mipsReg, compilerPC_); return INVALID_REG; // BAAAD } }