/* Copyright 2016-2021 Arisotura, RSDuck 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 "ARMJIT_Compiler.h" using namespace Arm64Gen; // hack const int kCodeCacheTiming = 3; namespace ARMJIT { template void JumpToTrampoline(T* cpu, u32 addr, bool changeCPSR) { cpu->JumpTo(addr, changeCPSR); } void Compiler::Comp_JumpTo(u32 addr, bool forceNonConstantCycles) { // we can simplify constant branches by a lot // it's not completely safe to assume stuff like, which instructions to preload // we'll see how it works out IrregularCycles = true; u32 newPC; u32 cycles = 0; bool setupRegion = false; if (addr & 0x1 && !Thumb) { CPSRDirty = true; ORRI2R(RCPSR, RCPSR, 0x20); } else if (!(addr & 0x1) && Thumb) { CPSRDirty = true; ANDI2R(RCPSR, RCPSR, ~0x20); } if (Num == 0) { ARMv5* cpu9 = (ARMv5*)CurCPU; u32 oldregion = R15 >> 24; u32 newregion = addr >> 24; u32 regionCodeCycles = cpu9->MemTimings[addr >> 12][0]; u32 compileTimeCodeCycles = cpu9->RegionCodeCycles; cpu9->RegionCodeCycles = regionCodeCycles; MOVI2R(W0, regionCodeCycles); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARMv5, RegionCodeCycles)); setupRegion = newregion != oldregion; if (setupRegion) cpu9->SetupCodeMem(addr); if (addr & 0x1) { addr &= ~0x1; newPC = addr+2; // two-opcodes-at-once fetch // doesn't matter if we put garbage in the MSbs there if (addr & 0x2) { cpu9->CodeRead32(addr-2, true) >> 16; cycles += cpu9->CodeCycles; cpu9->CodeRead32(addr+2, false); cycles += CurCPU->CodeCycles; } else { cpu9->CodeRead32(addr, true); cycles += cpu9->CodeCycles; } } else { addr &= ~0x3; newPC = addr+4; cpu9->CodeRead32(addr, true); cycles += cpu9->CodeCycles; cpu9->CodeRead32(addr+4, false); cycles += cpu9->CodeCycles; } cpu9->RegionCodeCycles = compileTimeCodeCycles; if (setupRegion) cpu9->SetupCodeMem(R15); } else { ARMv4* cpu7 = (ARMv4*)CurCPU; u32 codeRegion = addr >> 24; u32 codeCycles = addr >> 15; // cheato cpu7->CodeRegion = codeRegion; cpu7->CodeCycles = codeCycles; MOVI2R(W0, codeRegion); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARM, CodeRegion)); MOVI2R(W0, codeCycles); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARM, CodeCycles)); if (addr & 0x1) { addr &= ~0x1; newPC = addr+2; // this is necessary because ARM7 bios protection u32 compileTimePC = CurCPU->R[15]; CurCPU->R[15] = newPC; cycles += NDS::ARM7MemTimings[codeCycles][0] + NDS::ARM7MemTimings[codeCycles][1]; CurCPU->R[15] = compileTimePC; } else { addr &= ~0x3; newPC = addr+4; u32 compileTimePC = CurCPU->R[15]; CurCPU->R[15] = newPC; cycles += NDS::ARM7MemTimings[codeCycles][2] + NDS::ARM7MemTimings[codeCycles][3]; CurCPU->R[15] = compileTimePC; } cpu7->CodeRegion = R15 >> 24; cpu7->CodeCycles = addr >> 15; } if (Exit) { MOVI2R(W0, newPC); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARM, R[15])); } if ((Thumb || CurInstr.Cond() >= 0xE) && !forceNonConstantCycles) ConstantCycles += cycles; else ADD(RCycles, RCycles, cycles); } void* Compiler::Gen_JumpTo9(int kind) { AlignCode16(); void* res = GetRXPtr(); LSR(W1, W0, 12); ADDI2R(W1, W1, offsetof(ARMv5, MemTimings), W2); LDRB(W1, RCPU, W1); LDR(INDEX_UNSIGNED, W2, RCPU, offsetof(ARMv5, ITCMSize)); STR(INDEX_UNSIGNED, W1, RCPU, offsetof(ARMv5, RegionCodeCycles)); CMP(W1, 0xFF); MOVI2R(W3, kCodeCacheTiming); CSEL(W1, W3, W1, CC_EQ); CMP(W0, W2); CSINC(W1, W1, WZR, CC_HS); FixupBranch switchToThumb; if (kind == 0) switchToThumb = TBNZ(W0, 0); if (kind == 0 || kind == 1) { // ARM if (kind == 0) ANDI2R(RCPSR, RCPSR, ~0x20); ANDI2R(W0, W0, ~3); ADD(W0, W0, 4); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARMv5, R[15])); ADD(W1, W1, W1); ADD(RCycles, RCycles, W1); RET(); } if (kind == 0 || kind == 2) { // Thumb if (kind == 0) { SetJumpTarget(switchToThumb); ORRI2R(RCPSR, RCPSR, 0x20); } ANDI2R(W0, W0, ~1); ADD(W0, W0, 2); STR(INDEX_UNSIGNED, W0, RCPU, offsetof(ARMv5, R[15])); ADD(W2, W1, W1); TSTI2R(W0, 0x2); CSEL(W1, W1, W2, CC_EQ); ADD(RCycles, RCycles, W1); RET(); } return res; } void* Compiler::Gen_JumpTo7(int kind) { void* res = GetRXPtr(); LSR(W1, W0, 24); STR(INDEX_UNSIGNED, W1, RCPU, offsetof(ARM, CodeRegion)); LSR(W1, W0, 15); STR(INDEX_UNSIGNED, W1, RCPU, offsetof(ARM, CodeCycles)); MOVP2R(X2, NDS::ARM7MemTimings); LDR(W3, X2, ArithOption(W1, true)); FixupBranch switchToThumb; if (kind == 0) switchToThumb = TBNZ(W0, 0); if (kind == 0 || kind == 1) { UBFX(W2, W3, 0, 8); UBFX(W3, W3, 8, 8); ADD(W2, W3, W2); ADD(RCycles, RCycles, W2); ANDI2R(W0, W0, ~3); if (kind == 0) ANDI2R(RCPSR, RCPSR, ~0x20); ADD(W3, W0, 4); STR(INDEX_UNSIGNED, W3, RCPU, offsetof(ARM, R[15])); RET(); } if (kind == 0 || kind == 2) { if (kind == 0) { SetJumpTarget(switchToThumb); ORRI2R(RCPSR, RCPSR, 0x20); } UBFX(W2, W3, 16, 8); UBFX(W3, W3, 24, 8); ADD(W2, W3, W2); ADD(RCycles, RCycles, W2); ANDI2R(W0, W0, ~1); ADD(W3, W0, 2); STR(INDEX_UNSIGNED, W3, RCPU, offsetof(ARM, R[15])); RET(); } return res; } void Compiler::Comp_JumpTo(Arm64Gen::ARM64Reg addr, bool switchThumb, bool restoreCPSR) { IrregularCycles = true; if (!restoreCPSR) { if (switchThumb) CPSRDirty = true; MOV(W0, addr); BL((Num ? JumpToFuncs7 : JumpToFuncs9)[switchThumb ? 0 : (Thumb + 1)]); } else { bool cpsrDirty = CPSRDirty; SaveCPSR(); SaveCycles(); PushRegs(restoreCPSR, true); if (switchThumb) MOV(W1, addr); else { if (Thumb) ORRI2R(W1, addr, 1); else ANDI2R(W1, addr, ~1); } MOV(X0, RCPU); MOVI2R(W2, restoreCPSR); if (Num == 0) QuickCallFunction(X3, JumpToTrampoline); else QuickCallFunction(X3, JumpToTrampoline); PopRegs(restoreCPSR, true); LoadCycles(); LoadCPSR(); if (CurInstr.Cond() < 0xE) CPSRDirty = cpsrDirty; } } void Compiler::A_Comp_BranchImm() { int op = (CurInstr.Instr >> 24) & 1; s32 offset = (s32)(CurInstr.Instr << 8) >> 6; u32 target = R15 + offset; bool link = op; if (CurInstr.Cond() == 0xF) // BLX_imm { target += (op << 1) + 1; link = true; } if (link) MOVI2R(MapReg(14), R15 - 4); Comp_JumpTo(target); } void Compiler::A_Comp_BranchXchangeReg() { ARM64Reg rn = MapReg(CurInstr.A_Reg(0)); MOV(W0, rn); if ((CurInstr.Instr & 0xF0) == 0x30) // BLX_reg MOVI2R(MapReg(14), R15 - 4); Comp_JumpTo(W0, true); } void Compiler::T_Comp_BCOND() { u32 cond = (CurInstr.Instr >> 8) & 0xF; FixupBranch skipExecute = CheckCondition(cond); s32 offset = (s32)(CurInstr.Instr << 24) >> 23; Comp_JumpTo(R15 + offset + 1, true); Comp_BranchSpecialBehaviour(true); FixupBranch skipFailed = B(); SetJumpTarget(skipExecute); Comp_AddCycles_C(true); Comp_BranchSpecialBehaviour(false); SetJumpTarget(skipFailed); } void Compiler::T_Comp_B() { s32 offset = (s32)((CurInstr.Instr & 0x7FF) << 21) >> 20; Comp_JumpTo(R15 + offset + 1); } void Compiler::T_Comp_BranchXchangeReg() { bool link = CurInstr.Instr & (1 << 7); if (link) { if (Num == 1) { printf("BLX unsupported on ARM7!!!\n"); return; } MOV(W0, MapReg(CurInstr.A_Reg(3))); MOVI2R(MapReg(14), R15 - 1); Comp_JumpTo(W0, true); } else { ARM64Reg rn = MapReg(CurInstr.A_Reg(3)); Comp_JumpTo(rn, true); } } void Compiler::T_Comp_BL_LONG_1() { s32 offset = (s32)((CurInstr.Instr & 0x7FF) << 21) >> 9; MOVI2R(MapReg(14), R15 + offset); Comp_AddCycles_C(); } void Compiler::T_Comp_BL_LONG_2() { ARM64Reg lr = MapReg(14); s32 offset = (CurInstr.Instr & 0x7FF) << 1; ADD(W0, lr, offset); MOVI2R(lr, (R15 - 2) | 1); Comp_JumpTo(W0, Num == 0 && !(CurInstr.Instr & (1 << 12))); } void Compiler::T_Comp_BL_Merged() { Comp_AddCycles_C(); R15 += 2; u32 upperPart = CurInstr.Instr >> 16; u32 target = (R15 - 2) + ((s32)((CurInstr.Instr & 0x7FF) << 21) >> 9); target += (upperPart & 0x7FF) << 1; if (Num == 1 || upperPart & (1 << 12)) target |= 1; MOVI2R(MapReg(14), (R15 - 2) | 1); Comp_JumpTo(target); } }