TranslateArm: Implement CLREX, LDREX, LDREXB, LDREXD, LDREXH, STREX, STREXB, STREXD, STREXH, SWP, SWPB

This commit is contained in:
MerryMage 2016-08-09 22:48:20 +01:00
parent d921390928
commit df39308e03
12 changed files with 446 additions and 98 deletions

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@ -27,6 +27,7 @@ set(SRCS
frontend/translate/translate_arm/multiply.cpp
frontend/translate/translate_arm/parallel.cpp
frontend/translate/translate_arm/reversal.cpp
frontend/translate/translate_arm/synchronization.cpp
frontend/translate/translate_arm/vfp2.cpp
frontend/translate/translate_thumb.cpp
ir_opt/dead_code_elimination_pass.cpp

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@ -1293,6 +1293,18 @@ void EmitX64::EmitFPSub64(IR::Block& block, IR::Inst* inst) {
FPThreeOp64(code, reg_alloc, block, inst, &XEmitter::SUBSD);
}
void EmitX64::EmitClearExclusive(IR::Block&, IR::Inst*) {
code->MOV(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(0));
}
void EmitX64::EmitSetExclusive(IR::Block&, IR::Inst* inst) {
ASSERT(inst->GetArg(1).IsImmediate());
X64Reg address = reg_alloc.UseRegister(inst->GetArg(0), any_gpr);
code->MOV(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(1));
code->MOV(32, MDisp(R15, offsetof(JitState, exclusive_address)), R(address));
}
void EmitX64::EmitReadMemory8(IR::Block&, IR::Inst* inst) {
reg_alloc.HostCall(inst, inst->GetArg(0));
@ -1341,6 +1353,60 @@ void EmitX64::EmitWriteMemory64(IR::Block&, IR::Inst* inst) {
code->ABI_CallFunction(reinterpret_cast<void*>(cb.MemoryWrite64));
}
static void ExclusiveWrite(BlockOfCode* code, RegAlloc& reg_alloc, IR::Inst* inst, void* fn) {
reg_alloc.HostCall(nullptr, inst->GetArg(0), inst->GetArg(1));
X64Reg passed = reg_alloc.DefRegister(inst, any_gpr);
X64Reg tmp = ABI_RETURN; // Use one of the unusued HostCall registers.
code->MOV(32, R(passed), Imm32(1));
code->CMP(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(0));
auto fail1_fixup = code->J_CC(CC_E);
code->MOV(32, R(tmp), R(ABI_PARAM1));
code->XOR(32, R(tmp), MDisp(R15, offsetof(JitState, exclusive_address)));
code->TEST(32, R(tmp), Imm32(JitState::RESERVATION_GRANULE_MASK));
auto fail2_fixup = code->J_CC(CC_NE);
code->MOV(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(0));
code->ABI_CallFunction(fn);
code->XOR(32, R(passed), R(passed));
code->SetJumpTarget(fail1_fixup);
code->SetJumpTarget(fail2_fixup);
}
void EmitX64::EmitExclusiveWriteMemory8(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, reinterpret_cast<void*>(cb.MemoryWrite8));
}
void EmitX64::EmitExclusiveWriteMemory16(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, reinterpret_cast<void*>(cb.MemoryWrite16));
}
void EmitX64::EmitExclusiveWriteMemory32(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, reinterpret_cast<void*>(cb.MemoryWrite32));
}
void EmitX64::EmitExclusiveWriteMemory64(IR::Block&, IR::Inst* inst) {
reg_alloc.HostCall(nullptr, inst->GetArg(0), inst->GetArg(1));
X64Reg passed = reg_alloc.DefRegister(inst, any_gpr);
X64Reg value_hi = reg_alloc.UseScratchRegister(inst->GetArg(2), any_gpr);
X64Reg value = ABI_PARAM2;
X64Reg tmp = ABI_RETURN; // Use one of the unusued HostCall registers.
code->MOV(32, R(passed), Imm32(1));
code->CMP(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(0));
auto fail1_fixup = code->J_CC(CC_E);
code->MOV(32, R(tmp), R(ABI_PARAM1));
code->XOR(32, R(tmp), MDisp(R15, offsetof(JitState, exclusive_address)));
code->TEST(32, R(tmp), Imm32(JitState::RESERVATION_GRANULE_MASK));
auto fail2_fixup = code->J_CC(CC_NE);
code->MOV(8, MDisp(R15, offsetof(JitState, exclusive_state)), Imm8(0));
code->MOVZX(64, 32, value, R(value));
code->SHL(64, R(value_hi), Imm8(32));
code->OR(64, R(value), R(value_hi));
code->ABI_CallFunction(reinterpret_cast<void*>(cb.MemoryWrite64));
code->XOR(32, R(passed), R(passed));
code->SetJumpTarget(fail1_fixup);
code->SetJumpTarget(fail2_fixup);
}
void EmitX64::EmitAddCycles(size_t cycles) {
ASSERT(cycles < std::numeric_limits<u32>::max());

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@ -29,6 +29,11 @@ struct JitState {
u32 save_host_MXCSR = 0;
s64 cycles_remaining = 0;
// Exclusive state
static constexpr u32 RESERVATION_GRANULE_MASK = 0xFFFFFFF8;
u32 exclusive_state = 0;
u32 exclusive_address = 0;
u32 FPSCR_IDC = 0;
u32 FPSCR_UFC = 0;
u32 guest_FPSCR_flags = 0;

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@ -181,8 +181,8 @@ std::vector<ArmMatcher<V>> GetArmDecodeTable() {
INST(&V::arm_STREXB, "STREXB", "cccc00011100nnnndddd11111001mmmm"), // v6K
INST(&V::arm_STREXD, "STREXD", "cccc00011010nnnndddd11111001mmmm"), // v6K
INST(&V::arm_STREXH, "STREXH", "cccc00011110nnnndddd11111001mmmm"), // v6K
INST(&V::arm_SWP, "SWP", "cccc00010000nnnndddd00001001mmmm"), // v2S (v6: Deprecated)
INST(&V::arm_SWPB, "SWPB", "cccc00010100nnnndddd00001001mmmm"), // v2S (v6: Deprecated)
INST(&V::arm_SWP, "SWP", "cccc00010000nnnntttt00001001uuuu"), // v2S (v6: Deprecated)
INST(&V::arm_SWPB, "SWPB", "cccc00010100nnnntttt00001001uuuu"), // v2S (v6: Deprecated)
// Load/Store instructions
INST(&V::arm_LDR_imm, "LDR (imm)", "cccc010pu0w1nnnnddddvvvvvvvvvvvv"),

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@ -697,17 +697,39 @@ public:
std::string arm_QDSUB(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
// Synchronization Primitive instructions
std::string arm_CLREX() { return "ice"; }
std::string arm_LDREX(Cond cond, Reg n, Reg d) { return "ice"; }
std::string arm_LDREXB(Cond cond, Reg n, Reg d) { return "ice"; }
std::string arm_LDREXD(Cond cond, Reg n, Reg d) { return "ice"; }
std::string arm_LDREXH(Cond cond, Reg n, Reg d) { return "ice"; }
std::string arm_STREX(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_STREXB(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_STREXD(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_STREXH(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_SWP(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_SWPB(Cond cond, Reg n, Reg d, Reg m) { return "ice"; }
std::string arm_CLREX() {
return "clrex";
}
std::string arm_LDREX(Cond cond, Reg n, Reg d) {
return Common::StringFromFormat("ldrex%s %s, [%s]", CondToString(cond), RegToString(d), RegToString(n));
}
std::string arm_LDREXB(Cond cond, Reg n, Reg d) {
return Common::StringFromFormat("ldrexb%s %s, [%s]", CondToString(cond), RegToString(d), RegToString(n));
}
std::string arm_LDREXD(Cond cond, Reg n, Reg d) {
return Common::StringFromFormat("ldrexd%s %s, %s, [%s]", CondToString(cond), RegToString(d), RegToString(d+1), RegToString(n));
}
std::string arm_LDREXH(Cond cond, Reg n, Reg d) {
return Common::StringFromFormat("ldrexh%s %s, [%s]", CondToString(cond), RegToString(d), RegToString(n));
}
std::string arm_STREX(Cond cond, Reg n, Reg d, Reg m) {
return Common::StringFromFormat("strex%s %s, %s, [%s]", CondToString(cond), RegToString(d), RegToString(m), RegToString(n));
}
std::string arm_STREXB(Cond cond, Reg n, Reg d, Reg m) {
return Common::StringFromFormat("strexb%s %s, %s, [%s]", CondToString(cond), RegToString(d), RegToString(m), RegToString(n));
}
std::string arm_STREXD(Cond cond, Reg n, Reg d, Reg m) {
return Common::StringFromFormat("strexd%s %s, %s, %s, [%s]", CondToString(cond), RegToString(d), RegToString(m), RegToString(m+1), RegToString(n));
}
std::string arm_STREXH(Cond cond, Reg n, Reg d, Reg m) {
return Common::StringFromFormat("strexh%s %s, %s, [%s]", CondToString(cond), RegToString(d), RegToString(m), RegToString(n));
}
std::string arm_SWP(Cond cond, Reg n, Reg t, Reg t2) {
return Common::StringFromFormat("swp%s %s, %s, [%s]", CondToString(cond), RegToString(t), RegToString(t2), RegToString(n));
}
std::string arm_SWPB(Cond cond, Reg n, Reg t, Reg t2) {
return Common::StringFromFormat("swpb%s %s, %s, [%s]", CondToString(cond), RegToString(t), RegToString(t2), RegToString(n));
}
// Status register access instructions
std::string arm_CPS() { return "ice"; }

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@ -362,6 +362,15 @@ IR::Value IREmitter::FPSub64(const IR::Value& a, const IR::Value& b, bool fpscr_
return Inst(IR::Opcode::FPSub64, {a, b});
}
void IREmitter::ClearExlcusive() {
Inst(IR::Opcode::ClearExclusive, {});
}
void IREmitter::SetExclusive(const IR::Value& vaddr, size_t byte_size) {
ASSERT(byte_size == 1 || byte_size == 2 || byte_size == 4 || byte_size == 8 || byte_size == 16);
Inst(IR::Opcode::SetExclusive, {vaddr, Imm8(u8(byte_size))});
}
IR::Value IREmitter::ReadMemory8(const IR::Value& vaddr) {
return Inst(IR::Opcode::ReadMemory8, {vaddr});
}
@ -412,6 +421,38 @@ void IREmitter::WriteMemory64(const IR::Value& vaddr, const IR::Value& value) {
}
}
IR::Value IREmitter::ExclusiveWriteMemory8(const IR::Value& vaddr, const IR::Value& value) {
return Inst(IR::Opcode::ExclusiveWriteMemory8, {vaddr, value});
}
IR::Value IREmitter::ExclusiveWriteMemory16(const IR::Value& vaddr, const IR::Value& value) {
if (current_location.EFlag()) {
auto v = ByteReverseHalf(value);
return Inst(IR::Opcode::ExclusiveWriteMemory16, {vaddr, v});
} else {
return Inst(IR::Opcode::ExclusiveWriteMemory16, {vaddr, value});
}
}
IR::Value IREmitter::ExclusiveWriteMemory32(const IR::Value& vaddr, const IR::Value& value) {
if (current_location.EFlag()) {
auto v = ByteReverseWord(value);
return Inst(IR::Opcode::ExclusiveWriteMemory32, {vaddr, v});
} else {
return Inst(IR::Opcode::ExclusiveWriteMemory32, {vaddr, value});
}
}
IR::Value IREmitter::ExclusiveWriteMemory64(const IR::Value& vaddr, const IR::Value& value_lo, const IR::Value& value_hi) {
if (current_location.EFlag()) {
auto vlo = ByteReverseWord(value_lo);
auto vhi = ByteReverseWord(value_hi);
return Inst(IR::Opcode::ExclusiveWriteMemory64, {vaddr, vlo, vhi});
} else {
return Inst(IR::Opcode::ExclusiveWriteMemory64, {vaddr, value_lo, value_hi});
}
}
void IREmitter::Breakpoint() {
Inst(IR::Opcode::Breakpoint, {});
}

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@ -113,6 +113,8 @@ public:
IR::Value FPSub32(const IR::Value& a, const IR::Value& b, bool fpscr_controlled);
IR::Value FPSub64(const IR::Value& a, const IR::Value& b, bool fpscr_controlled);
void ClearExlcusive();
void SetExclusive(const IR::Value& vaddr, size_t byte_size);
IR::Value ReadMemory8(const IR::Value& vaddr);
IR::Value ReadMemory16(const IR::Value& vaddr);
IR::Value ReadMemory32(const IR::Value& vaddr);
@ -121,6 +123,10 @@ public:
void WriteMemory16(const IR::Value& vaddr, const IR::Value& value);
void WriteMemory32(const IR::Value& vaddr, const IR::Value& value);
void WriteMemory64(const IR::Value& vaddr, const IR::Value& value);
IR::Value ExclusiveWriteMemory8(const IR::Value& vaddr, const IR::Value& value);
IR::Value ExclusiveWriteMemory16(const IR::Value& vaddr, const IR::Value& value);
IR::Value ExclusiveWriteMemory32(const IR::Value& vaddr, const IR::Value& value);
IR::Value ExclusiveWriteMemory64(const IR::Value& vaddr, const IR::Value& value_lo, const IR::Value& value_hi);
void Breakpoint();

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@ -82,6 +82,8 @@ OPCODE(FPSub32, T::F32, T::F32, T::F32
OPCODE(FPSub64, T::F64, T::F64, T::F64 )
// Memory access
OPCODE(ClearExclusive, T::Void, )
OPCODE(SetExclusive, T::Void, T::U32, T::U8 )
OPCODE(ReadMemory8, T::U8, T::U32 )
OPCODE(ReadMemory16, T::U16, T::U32 )
OPCODE(ReadMemory32, T::U32, T::U32 )
@ -90,3 +92,7 @@ OPCODE(WriteMemory8, T::Void, T::U32, T::U8
OPCODE(WriteMemory16, T::Void, T::U32, T::U16 )
OPCODE(WriteMemory32, T::Void, T::U32, T::U32 )
OPCODE(WriteMemory64, T::Void, T::U32, T::U64 )
OPCODE(ExclusiveWriteMemory8, T::U32, T::U32, T::U8 )
OPCODE(ExclusiveWriteMemory16, T::U32, T::U32, T::U16 )
OPCODE(ExclusiveWriteMemory32, T::U32, T::U32, T::U32 )
OPCODE(ExclusiveWriteMemory64, T::U32, T::U32, T::U32, T::U32 )

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@ -0,0 +1,162 @@
/* This file is part of the dynarmic project.
* Copyright (c) 2016 MerryMage
* This software may be used and distributed according to the terms of the GNU
* General Public License version 2 or any later version.
*/
#include "translate_arm.h"
namespace Dynarmic {
namespace Arm {
bool ArmTranslatorVisitor::arm_CLREX() {
// CLREX
ir.ClearExlcusive();
return true;
}
bool ArmTranslatorVisitor::arm_LDREX(Cond cond, Reg n, Reg d) {
if (d == Reg::PC || n == Reg::PC)
return UnpredictableInstruction();
// LDREX <Rd>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
ir.SetExclusive(address, 4);
ir.SetRegister(d, ir.ReadMemory32(address));
}
return true;
}
bool ArmTranslatorVisitor::arm_LDREXB(Cond cond, Reg n, Reg d) {
if (d == Reg::PC || n == Reg::PC)
return UnpredictableInstruction();
// LDREXB <Rd>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
ir.SetExclusive(address, 1);
ir.SetRegister(d, ir.ZeroExtendByteToWord(ir.ReadMemory8(address)));
}
return true;
}
bool ArmTranslatorVisitor::arm_LDREXD(Cond cond, Reg n, Reg d) {
if (d == Reg::LR || d == Reg::PC || n == Reg::PC)
return UnpredictableInstruction();
// LDREXD <Rd>, <Rd1>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
ir.SetExclusive(address, 8);
// DO NOT SWAP hi AND lo IN BIG ENDIAN MODE, THIS IS CORRECT BEHAVIOUR
auto lo = ir.ReadMemory32(address);
ir.SetRegister(d, lo);
auto hi = ir.ReadMemory32(ir.Add(address, ir.Imm32(4)));
ir.SetRegister(d+1, hi);
}
return true;
}
bool ArmTranslatorVisitor::arm_LDREXH(Cond cond, Reg n, Reg d) {
if (d == Reg::PC || n == Reg::PC)
return UnpredictableInstruction();
// LDREXH <Rd>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
ir.SetExclusive(address, 2);
ir.SetRegister(d, ir.ZeroExtendHalfToWord(ir.ReadMemory16(address)));
}
return true;
}
bool ArmTranslatorVisitor::arm_STREX(Cond cond, Reg n, Reg d, Reg m) {
if (n == Reg::PC || d == Reg::PC || m == Reg::PC)
return UnpredictableInstruction();
if (d == n || d == m)
return UnpredictableInstruction();
// STREX <Rd>, <Rm>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
auto value = ir.GetRegister(m);
auto passed = ir.ExclusiveWriteMemory32(address, value);
ir.SetRegister(d, passed);
}
return true;
}
bool ArmTranslatorVisitor::arm_STREXB(Cond cond, Reg n, Reg d, Reg m) {
if (n == Reg::PC || d == Reg::PC || m == Reg::PC)
return UnpredictableInstruction();
if (d == n || d == m)
return UnpredictableInstruction();
// STREXB <Rd>, <Rm>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
auto value = ir.LeastSignificantByte(ir.GetRegister(m));
auto passed = ir.ExclusiveWriteMemory8(address, value);
ir.SetRegister(d, passed);
}
return true;
}
bool ArmTranslatorVisitor::arm_STREXD(Cond cond, Reg n, Reg d, Reg m) {
if (n == Reg::PC || d == Reg::PC || m == Reg::LR || static_cast<size_t>(m) % 2 == 1)
return UnpredictableInstruction();
if (d == n || d == m || d == m+1)
return UnpredictableInstruction();
Reg m2 = m + 1;
// STREXD <Rd>, <Rm>, <Rm2>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
auto value_lo = ir.GetRegister(m);
auto value_hi = ir.GetRegister(m2);
auto passed = ir.ExclusiveWriteMemory64(address, value_lo, value_hi);
ir.SetRegister(d, passed);
}
return true;
}
bool ArmTranslatorVisitor::arm_STREXH(Cond cond, Reg n, Reg d, Reg m) {
if (n == Reg::PC || d == Reg::PC || m == Reg::PC)
return UnpredictableInstruction();
if (d == n || d == m)
return UnpredictableInstruction();
// STREXH <Rd>, <Rm>, [<Rn>]
if (ConditionPassed(cond)) {
auto address = ir.GetRegister(n);
auto value = ir.LeastSignificantHalf(ir.GetRegister(m));
auto passed = ir.ExclusiveWriteMemory16(address, value);
ir.SetRegister(d, passed);
}
return true;
}
bool ArmTranslatorVisitor::arm_SWP(Cond cond, Reg n, Reg t, Reg t2) {
if (t == Reg::PC || t2 == Reg::PC || n == Reg::PC || n == t || n == t2)
return UnpredictableInstruction();
// TODO: UNDEFINED if current mode is Hypervisor
// SWP <Rt>, <Rt2>, [<Rn>]
if (ConditionPassed(cond)) {
auto data = ir.ReadMemory32(ir.GetRegister(n));
ir.WriteMemory32(ir.GetRegister(n), ir.GetRegister(t2));
// TODO: Alignment check
ir.SetRegister(t, data);
}
return true;
}
bool ArmTranslatorVisitor::arm_SWPB(Cond cond, Reg n, Reg t, Reg t2) {
if (t == Reg::PC || t2 == Reg::PC || n == Reg::PC || n == t || n == t2)
return UnpredictableInstruction();
// TODO: UNDEFINED if current mode is Hypervisor
// SWPB <Rt>, <Rt2>, [<Rn>]
if (ConditionPassed(cond)) {
auto data = ir.ReadMemory8(ir.GetRegister(n));
ir.WriteMemory8(ir.GetRegister(n), ir.LeastSignificantByte(ir.GetRegister(t2)));
// TODO: Alignment check
ir.SetRegister(t, ir.ZeroExtendByteToWord(data));
}
return true;
}
} // namespace Arm
} // namespace Dynarmic

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@ -304,17 +304,17 @@ struct ArmTranslatorVisitor final {
bool arm_QDSUB(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
// Synchronization Primitive instructions
bool arm_CLREX() { return InterpretThisInstruction(); }
bool arm_LDREX(Cond cond, Reg n, Reg d) { return InterpretThisInstruction(); }
bool arm_LDREXB(Cond cond, Reg n, Reg d) { return InterpretThisInstruction(); }
bool arm_LDREXD(Cond cond, Reg n, Reg d) { return InterpretThisInstruction(); }
bool arm_LDREXH(Cond cond, Reg n, Reg d) { return InterpretThisInstruction(); }
bool arm_STREX(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_STREXB(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_STREXD(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_STREXH(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_SWP(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_SWPB(Cond cond, Reg n, Reg d, Reg m) { return InterpretThisInstruction(); }
bool arm_CLREX();
bool arm_LDREX(Cond cond, Reg n, Reg d);
bool arm_LDREXB(Cond cond, Reg n, Reg d);
bool arm_LDREXD(Cond cond, Reg n, Reg d);
bool arm_LDREXH(Cond cond, Reg n, Reg d);
bool arm_STREX(Cond cond, Reg n, Reg d, Reg m);
bool arm_STREXB(Cond cond, Reg n, Reg d, Reg m);
bool arm_STREXD(Cond cond, Reg n, Reg d, Reg m);
bool arm_STREXH(Cond cond, Reg n, Reg d, Reg m);
bool arm_SWP(Cond cond, Reg n, Reg d, Reg m);
bool arm_SWPB(Cond cond, Reg n, Reg d, Reg m);
// Status register access instructions
bool arm_CPS() { return InterpretThisInstruction(); }

View file

@ -13,7 +13,47 @@ namespace Optimization {
void DeadCodeElimination(IR::Block& block) {
const auto is_side_effect_free = [](IR::Opcode op) -> bool {
return IR::GetTypeOf(op) != IR::Type::Void;
switch (op) {
case IR::Opcode::Breakpoint:
case IR::Opcode::SetRegister:
case IR::Opcode::SetExtendedRegister32:
case IR::Opcode::SetExtendedRegister64:
case IR::Opcode::SetNFlag:
case IR::Opcode::SetZFlag:
case IR::Opcode::SetCFlag:
case IR::Opcode::SetVFlag:
case IR::Opcode::OrQFlag:
case IR::Opcode::BXWritePC:
case IR::Opcode::CallSupervisor:
case IR::Opcode::FPAbs32:
case IR::Opcode::FPAbs64:
case IR::Opcode::FPAdd32:
case IR::Opcode::FPAdd64:
case IR::Opcode::FPDiv32:
case IR::Opcode::FPDiv64:
case IR::Opcode::FPMul32:
case IR::Opcode::FPMul64:
case IR::Opcode::FPNeg32:
case IR::Opcode::FPNeg64:
case IR::Opcode::FPSqrt32:
case IR::Opcode::FPSqrt64:
case IR::Opcode::FPSub32:
case IR::Opcode::FPSub64:
case IR::Opcode::ClearExclusive:
case IR::Opcode::SetExclusive:
case IR::Opcode::WriteMemory8:
case IR::Opcode::WriteMemory16:
case IR::Opcode::WriteMemory32:
case IR::Opcode::WriteMemory64:
case IR::Opcode::ExclusiveWriteMemory8:
case IR::Opcode::ExclusiveWriteMemory16:
case IR::Opcode::ExclusiveWriteMemory32:
case IR::Opcode::ExclusiveWriteMemory64:
return false;
default:
ASSERT(IR::GetTypeOf(op) != IR::Type::Void);
return true;
}
};
// We iterate over the instructions in reverse order.

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@ -70,7 +70,7 @@ static u32 MemoryRead32(u32 vaddr) {
return vaddr;
}
static u64 MemoryRead64(u32 vaddr) {
return vaddr;
return MemoryRead32(vaddr) | (u64(MemoryRead32(vaddr+4)) << 32);
}
static void MemoryWrite8(u32 vaddr, u8 value){
@ -133,7 +133,7 @@ public:
REQUIRE(strlen(format) == 32);
for (int i = 0; i < 32; i++) {
const u32 bit = 1 << (31 - i);
const u32 bit = 1u << (31 - i);
switch (format[i]) {
case '0':
mask |= bit;
@ -169,6 +169,7 @@ public:
}
u32 Bits() const { return bits; }
u32 Mask() const { return mask; }
bool IsValid(u32 inst) const { return is_valid(inst); }
private:
u32 bits = 0;
u32 mask = 0;
@ -210,10 +211,12 @@ void FuzzJitArm(const size_t instruction_count, const size_t instructions_to_exe
u32 initial_fpscr = RandInt<u32>(0x0, 0x1) << 24;
interp.UnsetExclusiveMemoryAddress();
interp.Cpsr = initial_cpsr;
interp.Reg = initial_regs;
interp.ExtReg = initial_extregs;
interp.VFP[VFP_FPSCR] = initial_fpscr;
jit.Reset();
jit.Cpsr() = initial_cpsr;
jit.Regs() = initial_regs;
jit.ExtRegs() = initial_extregs;
@ -242,7 +245,7 @@ void FuzzJitArm(const size_t instruction_count, const size_t instructions_to_exe
printf("\nInstruction Listing: \n");
for (size_t i = 0; i < instruction_count; i++) {
printf("%s\n", Dynarmic::Arm::DisassembleArm(code_mem[i]).c_str());
printf("%x: %s\n", code_mem[i], Dynarmic::Arm::DisassembleArm(code_mem[i]).c_str());
}
printf("\nInitial Register Listing: \n");
@ -555,15 +558,42 @@ TEST_CASE("Fuzz ARM data processing instructions", "[JitX64]") {
}
TEST_CASE("Fuzz ARM load/store instructions (byte, half-word, word)", "[JitX64]") {
const std::array<InstructionGenerator, 17> instructions = {{
auto EXD_valid = [](u32 inst) -> bool {
return Bits<0, 3>(inst) % 2 == 0 && Bits<0, 3>(inst) != 14 && Bits<12, 15>(inst) != (Bits<0, 3>(inst) + 1);
};
auto STREX_valid = [](u32 inst) -> bool {
return Bits<12, 15>(inst) != Bits<16, 19>(inst) && Bits<12, 15>(inst) != Bits<0, 3>(inst);
};
auto SWP_valid = [](u32 inst) -> bool {
return Bits<12, 15>(inst) != Bits<16, 19>(inst) && Bits<16, 19>(inst) != Bits<0, 3>(inst);
};
auto LDREXD_valid = [](u32 inst) -> bool {
return Bits<12, 15>(inst) != 14;
};
auto D_valid = [](u32 inst) -> bool {
u32 Rn = Bits<16, 19>(inst);
u32 Rd = Bits<12, 15>(inst);
u32 Rm = Bits<0, 3>(inst);
return Rn % 2 == 0 && Rd % 2 == 0 && Rm != Rd && Rm != Rd + 1 && Rd != 14;
};
const std::array<InstructionGenerator, 32> instructions = {{
InstructionGenerator("cccc010pu0w1nnnnddddvvvvvvvvvvvv"), // LDR_imm
InstructionGenerator("cccc011pu0w1nnnnddddvvvvvrr0mmmm"), // LDR_reg
InstructionGenerator("cccc010pu1w1nnnnddddvvvvvvvvvvvv"), // LDRB_imm
InstructionGenerator("cccc011pu1w1nnnnddddvvvvvrr0mmmm"), // LDRB_reg
InstructionGenerator("cccc000pu1w0nnnnddddvvvv1101vvvv", D_valid), // LDRD_imm
InstructionGenerator("cccc000pu0w0nnnndddd00001101mmmm", D_valid), // LDRD_reg
InstructionGenerator("cccc010pu0w0nnnnddddvvvvvvvvvvvv"), // STR_imm
InstructionGenerator("cccc011pu0w0nnnnddddvvvvvrr0mmmm"), // STR_reg
InstructionGenerator("cccc010pu1w0nnnnddddvvvvvvvvvvvv"), // STRB_imm
InstructionGenerator("cccc011pu1w0nnnnddddvvvvvrr0mmmm"), // STRB_reg
InstructionGenerator("cccc000pu1w0nnnnddddvvvv1111vvvv", D_valid), // STRD_imm
InstructionGenerator("cccc000pu0w0nnnndddd00001111mmmm", D_valid), // STRD_reg
InstructionGenerator("cccc000pu1w1nnnnddddvvvv1011vvvv"), // LDRH_imm
InstructionGenerator("cccc000pu0w1nnnndddd00001011mmmm"), // LDRH_reg
InstructionGenerator("cccc000pu1w1nnnnddddvvvv1101vvvv"), // LDRSB_imm
@ -573,87 +603,56 @@ TEST_CASE("Fuzz ARM load/store instructions (byte, half-word, word)", "[JitX64]"
InstructionGenerator("cccc000pu1w0nnnnddddvvvv1011vvvv"), // STRH_imm
InstructionGenerator("cccc000pu0w0nnnndddd00001011mmmm"), // STRH_reg
InstructionGenerator("1111000100000001000000e000000000"), // SETEND
InstructionGenerator("11110101011111111111000000011111"), // CLREX
InstructionGenerator("cccc00011001nnnndddd111110011111"), // LDREX
InstructionGenerator("cccc00011101nnnndddd111110011111"), // LDREXB
InstructionGenerator("cccc00011011nnnndddd111110011111", LDREXD_valid), // LDREXD
InstructionGenerator("cccc00011111nnnndddd111110011111"), // LDREXH
InstructionGenerator("cccc00011000nnnndddd11111001mmmm", STREX_valid), // STREX
InstructionGenerator("cccc00011100nnnndddd11111001mmmm", STREX_valid), // STREXB
InstructionGenerator("cccc00011010nnnndddd11111001mmmm",
[=](u32 inst) { return EXD_valid(inst) && STREX_valid(inst); }), // STREXD
InstructionGenerator("cccc00011110nnnndddd11111001mmmm", STREX_valid), // STREXH
InstructionGenerator("cccc00010000nnnntttt00001001uuuu", SWP_valid), // SWP
InstructionGenerator("cccc00010100nnnntttt00001001uuuu", SWP_valid), // SWPB
}};
auto instruction_select = [&]() -> u32 {
size_t inst_index = RandInt<size_t>(0, instructions.size() - 1);
u32 cond = 0xE;
// Have a one-in-twenty-five chance of actually having a cond.
if (RandInt(1, 25) == 1) {
cond = RandInt<u32>(0x0, 0xD);
}
while (true) {
u32 cond = 0xE;
// Have a one-in-twenty-five chance of actually having a cond.
if (RandInt(1, 25) == 1) {
cond = RandInt<u32>(0x0, 0xD);
}
u32 Rn = RandInt<u32>(0, 14);
u32 Rd = RandInt<u32>(0, 14);
u32 W = 0;
u32 P = RandInt<u32>(0, 1);
if (P) W = RandInt<u32>(0, 1);
u32 U = RandInt<u32>(0, 1);
u32 rand = RandInt<u32>(0, 0xFF);
u32 Rm = RandInt<u32>(0, 14);
u32 Rn = RandInt<u32>(0, 14);
u32 Rd = RandInt<u32>(0, 14);
u32 W = 0;
u32 P = RandInt<u32>(0, 1);
if (P) W = RandInt<u32>(0, 1);
u32 U = RandInt<u32>(0, 1);
u32 rand = RandInt<u32>(0, 0xFF);
u32 Rm = RandInt<u32>(0, 14);
if (W) {
while (Rn == Rd) {
Rn = RandInt<u32>(0, 14);
Rd = RandInt<u32>(0, 14);
if (W) {
while (Rn == Rd) {
Rn = RandInt<u32>(0, 14);
Rd = RandInt<u32>(0, 14);
}
}
u32 assemble_randoms = (Rm << 0) | (rand << 4) | (Rd << 12) | (Rn << 16) | (W << 21) | (U << 23) | (P << 24) | (cond << 28);
u32 inst = instructions[inst_index].Bits() | (assemble_randoms & (~instructions[inst_index].Mask()));
if (instructions[inst_index].IsValid(inst)) {
return inst;
}
}
u32 assemble_randoms = (Rm << 0) | (rand << 4) | (Rd << 12) | (Rn << 16) | (W << 21) | (U << 23) | (P << 24) | (cond << 28);
return instructions[inst_index].Bits() | (assemble_randoms & (~instructions[inst_index].Mask()));
};
SECTION("short blocks") {
FuzzJitArm(5, 6, 10000, instruction_select);
}
}
TEST_CASE("Fuzz ARM load/store instructions (double-word)", "[JitX64]") {
const std::array<InstructionGenerator, 4> instructions = {{
InstructionGenerator("cccc000pu1w0nnnnddddvvvv1101vvvv"), // LDRD_imm
InstructionGenerator("cccc000pu0w0nnnndddd00001101mmmm"), // LDRD_reg
InstructionGenerator("cccc000pu1w0nnnnddddvvvv1111vvvv"), // STRD_imm
InstructionGenerator("cccc000pu0w0nnnndddd00001111mmmm"), // STRD_reg
}};
auto instruction_select = [&]() -> u32 {
size_t inst_index = RandInt<size_t>(0, instructions.size() - 1);
u32 cond = 0xE;
// Have a one-in-twenty-five chance of actually having a cond.
if (RandInt(1, 25) == 1) {
cond = RandInt<u32>(0x0, 0xD);
}
u32 Rn = RandInt<u32>(0, 6) * 2;
u32 Rd = RandInt<u32>(0, 6) * 2;
u32 W = 0;
u32 P = RandInt<u32>(0, 1);
if (P) W = RandInt<u32>(0, 1);
u32 U = RandInt<u32>(0, 1);
u32 rand = RandInt<u32>(0, 0xF);
u32 Rm = RandInt<u32>(0, 14);
if (W) {
while (Rn == Rd) {
Rn = RandInt<u32>(0, 6) * 2;
Rd = RandInt<u32>(0, 6) * 2;
}
}
while (Rm == Rd || Rm == Rd + 1) {
Rm = RandInt<u32>(0, 14);
}
u32 assemble_randoms = (Rm << 0) | (rand << 4) | (Rd << 12) | (Rn << 16) | (W << 21) | (U << 23) | (P << 24) | (cond << 28);
return instructions[inst_index].Bits() | (assemble_randoms & (~instructions[inst_index].Mask()));
};
SECTION("short blocks") {
FuzzJitArm(5, 6, 10000, instruction_select);
FuzzJitArm(5, 6, 30000, instruction_select);
}
}