dynarmic/tests/arm/fuzz_arm.cpp

1249 lines
50 KiB
C++

/* 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 <algorithm>
#include <array>
#include <cinttypes>
#include <cstdio>
#include <cstring>
#include <functional>
#include <tuple>
#include <vector>
#include <catch.hpp>
#include <dynarmic/dynarmic.h>
#include "common/bit_util.h"
#include "common/common_types.h"
#include "frontend/disassembler/disassembler.h"
#include "frontend/ir/basic_block.h"
#include "frontend/ir/location_descriptor.h"
#include "frontend/translate/translate.h"
#include "ir_opt/passes.h"
#include "rand_int.h"
#include "skyeye_interpreter/dyncom/arm_dyncom_interpreter.h"
#include "skyeye_interpreter/skyeye_common/armstate.h"
#ifdef __unix__
#include <signal.h>
#endif
using Dynarmic::Common::Bits;
struct WriteRecord {
size_t size;
u32 address;
u64 data;
};
static bool operator==(const WriteRecord& a, const WriteRecord& b) {
return std::tie(a.size, a.address, a.data) == std::tie(b.size, b.address, b.data);
}
static std::array<u32, 3000> code_mem{};
static std::vector<WriteRecord> write_records;
static bool IsReadOnlyMemory(u32 vaddr);
static u8 MemoryRead8(u32 vaddr);
static u16 MemoryRead16(u32 vaddr);
static u32 MemoryRead32(u32 vaddr);
static u64 MemoryRead64(u32 vaddr);
static u32 MemoryReadCode(u32 vaddr);
static void MemoryWrite8(u32 vaddr, u8 value);
static void MemoryWrite16(u32 vaddr, u16 value);
static void MemoryWrite32(u32 vaddr, u32 value);
static void MemoryWrite64(u32 vaddr, u64 value);
static void InterpreterFallback(u32 pc, Dynarmic::Jit* jit, void*);
static Dynarmic::UserCallbacks GetUserCallbacks();
static bool IsReadOnlyMemory(u32 vaddr) {
return vaddr < code_mem.size();
}
static u8 MemoryRead8(u32 vaddr) {
return static_cast<u8>(vaddr);
}
static u16 MemoryRead16(u32 vaddr) {
return static_cast<u16>(vaddr);
}
static u32 MemoryRead32(u32 vaddr) {
return vaddr;
}
static u64 MemoryRead64(u32 vaddr) {
return MemoryRead32(vaddr) | (u64(MemoryRead32(vaddr+4)) << 32);
}
static u32 MemoryReadCode(u32 vaddr) {
if (vaddr < code_mem.size() * sizeof(u32)) {
size_t index = vaddr / sizeof(u32);
return code_mem[index];
}
return 0xeafffffe; // b +#0
}
static void MemoryWrite8(u32 vaddr, u8 value){
write_records.push_back({8, vaddr, value});
}
static void MemoryWrite16(u32 vaddr, u16 value){
write_records.push_back({16, vaddr, value});
}
static void MemoryWrite32(u32 vaddr, u32 value){
write_records.push_back({32, vaddr, value});
}
static void MemoryWrite64(u32 vaddr, u64 value){
write_records.push_back({64, vaddr, value});
}
static void InterpreterFallback(u32 pc, Dynarmic::Jit* jit, void*) {
ARMul_State interp_state{USER32MODE};
interp_state.user_callbacks = GetUserCallbacks();
interp_state.NumInstrsToExecute = 1;
interp_state.Reg = jit->Regs();
interp_state.ExtReg = jit->ExtRegs();
interp_state.Cpsr = jit->Cpsr();
interp_state.VFP[VFP_FPSCR] = jit->Fpscr();
interp_state.Reg[15] = pc;
InterpreterClearCache();
InterpreterMainLoop(&interp_state);
bool T = Dynarmic::Common::Bit<5>(interp_state.Cpsr);
interp_state.Reg[15] &= T ? 0xFFFFFFFE : 0xFFFFFFFC;
jit->Regs() = interp_state.Reg;
jit->ExtRegs() = interp_state.ExtReg;
jit->Cpsr() = interp_state.Cpsr;
jit->SetFpscr(interp_state.VFP[VFP_FPSCR]);
}
static void Fail() {
FAIL();
}
static Dynarmic::UserCallbacks GetUserCallbacks() {
Dynarmic::UserCallbacks user_callbacks{};
user_callbacks.InterpreterFallback = &InterpreterFallback;
user_callbacks.CallSVC = (void (*)(u32)) &Fail;
user_callbacks.memory.IsReadOnlyMemory = &IsReadOnlyMemory;
user_callbacks.memory.Read8 = &MemoryRead8;
user_callbacks.memory.Read16 = &MemoryRead16;
user_callbacks.memory.Read32 = &MemoryRead32;
user_callbacks.memory.Read64 = &MemoryRead64;
user_callbacks.memory.ReadCode = &MemoryReadCode;
user_callbacks.memory.Write8 = &MemoryWrite8;
user_callbacks.memory.Write16 = &MemoryWrite16;
user_callbacks.memory.Write32 = &MemoryWrite32;
user_callbacks.memory.Write64 = &MemoryWrite64;
return user_callbacks;
}
struct InstructionGenerator final {
public:
InstructionGenerator(const char* format, std::function<bool(u32)> is_valid = [](u32){ return true; }) : is_valid(is_valid) {
REQUIRE(strlen(format) == 32);
for (int i = 0; i < 32; i++) {
const u32 bit = 1u << (31 - i);
switch (format[i]) {
case '0':
mask |= bit;
break;
case '1':
bits |= bit;
mask |= bit;
break;
default:
// Do nothing
break;
}
}
}
u32 Generate(bool condition = true) const {
u32 inst;
do {
u32 random = RandInt<u32>(0, 0xFFFFFFFF);
if (condition)
random &= ~(0xF << 28);
inst = bits | (random & ~mask);
} while (!is_valid(inst));
if (condition) {
// Have a one-in-twenty-five chance of actually having a cond.
if (RandInt(1, 25) == 1)
inst |= RandInt(0x0, 0xD) << 28;
else
inst |= 0xE << 28;
}
return inst;
}
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;
std::function<bool(u32)> is_valid;
};
static bool DoesBehaviorMatch(const ARMul_State& interp, const Dynarmic::Jit& jit, const std::vector<WriteRecord>& interp_write_records, const std::vector<WriteRecord>& jit_write_records) {
return interp.Reg == jit.Regs()
&& interp.ExtReg == jit.ExtRegs()
&& interp.Cpsr == jit.Cpsr()
&& interp.VFP[VFP_FPSCR] == jit.Fpscr()
&& interp_write_records == jit_write_records;
}
void FuzzJitArm(const size_t instruction_count, const size_t instructions_to_execute_count, const size_t run_count, const std::function<u32()> instruction_generator) {
// Prepare memory
code_mem.fill(0xEAFFFFFE); // b +#0
// Prepare test subjects
ARMul_State interp{USER32MODE};
interp.user_callbacks = GetUserCallbacks();
Dynarmic::Jit jit{GetUserCallbacks()};
for (size_t run_number = 0; run_number < run_count; run_number++) {
interp.instruction_cache.clear();
InterpreterClearCache();
jit.ClearCache();
// Setup initial state
u32 initial_cpsr = 0x000001D0;
std::array<u32, 16> initial_regs;
std::generate_n(initial_regs.begin(), 15, []{ return RandInt<u32>(0, 0xFFFFFFFF); });
initial_regs[15] = 0;
std::array<u32, 64> initial_extregs;
std::generate_n(initial_extregs.begin(), 64, []{ return RandInt<u32>(0, 0xFFFFFFFF); });
u32 initial_fpscr = 0x01000000 | (RandInt<u32>(0, 3) << 22);
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;
jit.SetFpscr(initial_fpscr);
std::generate_n(code_mem.begin(), instruction_count, instruction_generator);
// Run interpreter
write_records.clear();
std::vector<WriteRecord> interp_write_records;
interp.NumInstrsToExecute = static_cast<unsigned>(instructions_to_execute_count);
InterpreterMainLoop(&interp);
interp_write_records = write_records;
{
bool T = Dynarmic::Common::Bit<5>(interp.Cpsr);
interp.Reg[15] &= T ? 0xFFFFFFFE : 0xFFFFFFFC;
}
// Run jit
write_records.clear();
std::vector<WriteRecord> jit_write_records;
try {
jit.Run(static_cast<unsigned>(instructions_to_execute_count));
jit_write_records = write_records;
} catch (...) {
printf("Caught something!\n");
goto dump_state;
}
// Compare
if (!DoesBehaviorMatch(interp, jit, interp_write_records, jit_write_records)) {
printf("Failed at execution number %zu\n", run_number);
dump_state:
printf("\nInstruction Listing: \n");
for (size_t i = 0; i < instruction_count; i++) {
printf("%x: %s\n", code_mem[i], Dynarmic::Arm::DisassembleArm(code_mem[i]).c_str());
}
printf("\nInitial Register Listing: \n");
for (int i = 0; i <= 15; i++) {
auto reg = Dynarmic::Arm::RegToString(static_cast<Dynarmic::Arm::Reg>(i));
printf("%4s: %08x\n", reg, initial_regs[i]);
}
printf("CPSR: %08x\n", initial_cpsr);
printf("FPSCR:%08x\n", initial_fpscr);
for (int i = 0; i <= 63; i++) {
printf("S%3i: %08x\n", i, initial_extregs[i]);
}
printf("\nFinal Register Listing: \n");
printf(" interp jit\n");
for (int i = 0; i <= 15; i++) {
auto reg = Dynarmic::Arm::RegToString(static_cast<Dynarmic::Arm::Reg>(i));
printf("%4s: %08x %08x %s\n", reg, interp.Reg[i], jit.Regs()[i], interp.Reg[i] != jit.Regs()[i] ? "*" : "");
}
printf("CPSR: %08x %08x %s\n", interp.Cpsr, jit.Cpsr(), interp.Cpsr != jit.Cpsr() ? "*" : "");
printf("FPSCR:%08x %08x %s\n", interp.VFP[VFP_FPSCR], jit.Fpscr(), interp.VFP[VFP_FPSCR] != jit.Fpscr() ? "*" : "");
for (int i = 0; i <= 63; i++) {
printf("S%3i: %08x %08x %s\n", i, interp.ExtReg[i], jit.ExtRegs()[i], interp.ExtReg[i] != jit.ExtRegs()[i] ? "*" : "");
}
printf("\nInterp Write Records:\n");
for (auto& record : interp_write_records) {
printf("%zu [%x] = %" PRIx64 "\n", record.size, record.address, record.data);
}
printf("\nJIT Write Records:\n");
for (auto& record : jit_write_records) {
printf("%zu [%x] = %" PRIx64 "\n", record.size, record.address, record.data);
}
size_t num_insts = 0;
while (num_insts < instructions_to_execute_count) {
Dynarmic::IR::LocationDescriptor descriptor = {u32(num_insts * 4), Dynarmic::Arm::PSR{}, Dynarmic::Arm::FPSCR{}};
Dynarmic::IR::Block ir_block = Dynarmic::Arm::Translate(descriptor, &MemoryReadCode);
Dynarmic::Optimization::GetSetElimination(ir_block);
Dynarmic::Optimization::DeadCodeElimination(ir_block);
Dynarmic::Optimization::VerificationPass(ir_block);
printf("\n\nIR:\n%s", Dynarmic::IR::DumpBlock(ir_block).c_str());
printf("\n\nx86_64:\n%s", jit.Disassemble(descriptor).c_str());
num_insts += ir_block.CycleCount();
}
fflush(stdout);
#ifdef _MSC_VER
__debugbreak();
#endif
#ifdef __unix__
raise(SIGTRAP);
#endif
FAIL();
}
if (run_number % 10 == 0) printf("%zu\r", run_number);
}
}
TEST_CASE( "arm: Optimization Failure (Randomized test case)", "[arm]" ) {
// This was a randomized test-case that was failing.
//
// IR produced for location {12, !T, !E} was:
// %0 = GetRegister r1
// %1 = SubWithCarry %0, #0x3e80000, #1
// %2 = GetCarryFromOp %1
// %3 = GetOverflowFromOp %1
// %4 = MostSignificantBit %1
// SetNFlag %4
// %6 = IsZero %1
// SetZFlag %6
// SetCFlag %2
// SetVFlag %3
// %10 = GetRegister r5
// %11 = AddWithCarry %10, #0x8a00, %2
// SetRegister r4, %11
//
// The reference to %2 in instruction %11 was the issue, because instruction %8
// told the register allocator it was a Use but then modified the value.
// Changing the EmitSet*Flag instruction to declare their arguments as UseScratch
// solved this bug.
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = 0xe35f0cd9; // cmp pc, #55552
code_mem[1] = 0xe11c0474; // tst r12, r4, ror r4
code_mem[2] = 0xe1a006a7; // mov r0, r7, lsr #13
code_mem[3] = 0xe35107fa; // cmp r1, #0x3E80000
code_mem[4] = 0xe2a54c8a; // adc r4, r5, #35328
code_mem[5] = 0xeafffffe; // b +#0
jit.Regs() = {
0x6973b6bb, 0x267ea626, 0x69debf49, 0x8f976895, 0x4ecd2d0d, 0xcf89b8c7, 0xb6713f85, 0x15e2aa5,
0xcd14336a, 0xafca0f3e, 0xace2efd9, 0x68fb82cd, 0x775447c0, 0xc9e1f8cd, 0xebe0e626, 0x0
};
jit.Cpsr() = 0x000001d0; // User-mode
jit.Run(6);
REQUIRE( jit.Regs()[0] == 0x00000af1 );
REQUIRE( jit.Regs()[1] == 0x267ea626 );
REQUIRE( jit.Regs()[2] == 0x69debf49 );
REQUIRE( jit.Regs()[3] == 0x8f976895 );
REQUIRE( jit.Regs()[4] == 0xcf8a42c8 );
REQUIRE( jit.Regs()[5] == 0xcf89b8c7 );
REQUIRE( jit.Regs()[6] == 0xb6713f85 );
REQUIRE( jit.Regs()[7] == 0x015e2aa5 );
REQUIRE( jit.Regs()[8] == 0xcd14336a );
REQUIRE( jit.Regs()[9] == 0xafca0f3e );
REQUIRE( jit.Regs()[10] == 0xace2efd9 );
REQUIRE( jit.Regs()[11] == 0x68fb82cd );
REQUIRE( jit.Regs()[12] == 0x775447c0 );
REQUIRE( jit.Regs()[13] == 0xc9e1f8cd );
REQUIRE( jit.Regs()[14] == 0xebe0e626 );
REQUIRE( jit.Regs()[15] == 0x00000014 );
REQUIRE( jit.Cpsr() == 0x200001d0 );
}
TEST_CASE( "arm: shsax r11, sp, r9 (Edge-case)", "[arm]" ) {
// This was a randomized test-case that was failing.
//
// The issue here was one of the words to be subtracted was 0x8000.
// When the 2s complement was calculated by (~a + 1), it was 0x8000.
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = 0xe63dbf59; // shsax r11, sp, r9
code_mem[1] = 0xeafffffe; // b +#0
jit.Regs() = {
0x3a3b8b18, 0x96156555, 0xffef039f, 0xafb946f2, 0x2030a69a, 0xafe09b2a, 0x896823c8, 0xabde0ded,
0x9825d6a6, 0x17498000, 0x999d2c95, 0x8b812a59, 0x209bdb58, 0x2f7fb1d4, 0x0f378107, 0x00000000
};
jit.Cpsr() = 0x000001d0; // User-mode
jit.Run(2);
REQUIRE( jit.Regs()[0] == 0x3a3b8b18 );
REQUIRE( jit.Regs()[1] == 0x96156555 );
REQUIRE( jit.Regs()[2] == 0xffef039f );
REQUIRE( jit.Regs()[3] == 0xafb946f2 );
REQUIRE( jit.Regs()[4] == 0x2030a69a );
REQUIRE( jit.Regs()[5] == 0xafe09b2a );
REQUIRE( jit.Regs()[6] == 0x896823c8 );
REQUIRE( jit.Regs()[7] == 0xabde0ded );
REQUIRE( jit.Regs()[8] == 0x9825d6a6 );
REQUIRE( jit.Regs()[9] == 0x17498000 );
REQUIRE( jit.Regs()[10] == 0x999d2c95 );
REQUIRE( jit.Regs()[11] == 0x57bfe48e );
REQUIRE( jit.Regs()[12] == 0x209bdb58 );
REQUIRE( jit.Regs()[13] == 0x2f7fb1d4 );
REQUIRE( jit.Regs()[14] == 0x0f378107 );
REQUIRE( jit.Regs()[15] == 0x00000004 );
REQUIRE( jit.Cpsr() == 0x000001d0 );
}
TEST_CASE( "arm: uasx (Edge-case)", "[arm]" ) {
// UASX's Rm<31:16> == 0x0000.
// An implementation that depends on addition overflow to detect
// if diff >= 0 will fail this testcase.
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = 0xe6549f35; // uasx r9, r4, r5
code_mem[1] = 0xeafffffe; // b +#0
jit.Regs()[4] = 0x8ed38f4c;
jit.Regs()[5] = 0x0000261d;
jit.Regs()[15] = 0x00000000;
jit.Cpsr() = 0x000001d0; // User-mode
jit.Run(2);
REQUIRE( jit.Regs()[4] == 0x8ed38f4c );
REQUIRE( jit.Regs()[5] == 0x0000261d );
REQUIRE( jit.Regs()[9] == 0xb4f08f4c );
REQUIRE( jit.Regs()[15] == 0x00000004 );
REQUIRE( jit.Cpsr() == 0x000301d0 );
}
struct VfpTest {
u32 initial_fpscr;
u32 a;
u32 b;
u32 result;
u32 final_fpscr;
};
static void RunVfpTests(u32 instr, std::vector<VfpTest> tests) {
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = instr;
code_mem[1] = 0xeafffffe; // b +#0
printf("vfp test 0x%08x\r", instr);
for (const auto& test : tests) {
jit.Regs()[15] = 0;
jit.Cpsr() = 0x000001d0;
jit.ExtRegs()[4] = test.a;
jit.ExtRegs()[6] = test.b;
jit.SetFpscr(test.initial_fpscr);
jit.Run(2);
const auto check = [&test, &jit](bool p) {
if (!p) {
printf("Failed test:\n");
printf("initial_fpscr: 0x%08x\n", test.initial_fpscr);
printf("a: 0x%08x (jit: 0x%08x)\n", test.a, jit.ExtRegs()[4]);
printf("b: 0x%08x (jit: 0x%08x)\n", test.b, jit.ExtRegs()[6]);
printf("result: 0x%08x (jit: 0x%08x)\n", test.result, jit.ExtRegs()[2]);
printf("final_fpscr: 0x%08x (jit: 0x%08x)\n", test.final_fpscr, jit.Fpscr());
FAIL();
}
};
REQUIRE( jit.Regs()[15] == 4 );
REQUIRE( jit.Cpsr() == 0x000001d0 );
check( jit.ExtRegs()[2] == test.result );
check( jit.ExtRegs()[4] == test.a );
check( jit.ExtRegs()[6] == test.b );
check( jit.Fpscr() == test.final_fpscr );
}
}
TEST_CASE("vfp: vadd", "[vfp]") {
// vadd.f32 s2, s4, s6
RunVfpTests(0xEE321A03, {
#include "vfp_vadd_f32.inc"
});
}
TEST_CASE("vfp: vsub", "[vfp]") {
// vsub.f32 s2, s4, s6
RunVfpTests(0xEE321A43, {
#include "vfp_vsub_f32.inc"
});
}
TEST_CASE("VFP: VMOV", "[JitX64][vfp]") {
const auto is_valid = [](u32 instr) -> bool {
return Bits<0, 6>(instr) != 0b111111
&& Bits<12, 15>(instr) != 0b1111
&& Bits<16, 19>(instr) != 0b1111
&& Bits<12, 15>(instr) != Bits<16, 19>(instr);
};
const std::array<InstructionGenerator, 8> instructions = {{
InstructionGenerator("cccc11100000ddddtttt1011D0010000", is_valid),
InstructionGenerator("cccc11100001nnnntttt1011N0010000", is_valid),
InstructionGenerator("cccc11100000nnnntttt1010N0010000", is_valid),
InstructionGenerator("cccc11100001nnnntttt1010N0010000", is_valid),
InstructionGenerator("cccc11000100uuuutttt101000M1mmmm", is_valid),
InstructionGenerator("cccc11000101uuuutttt101000M1mmmm", is_valid),
InstructionGenerator("cccc11000100uuuutttt101100M1mmmm", is_valid),
InstructionGenerator("cccc11000101uuuutttt101100M1mmmm", is_valid),
}};
FuzzJitArm(1, 1, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("VFP: VMOV (reg), VLDR, VSTR", "[JitX64][vfp]") {
const std::array<InstructionGenerator, 4> instructions = {{
InstructionGenerator("1111000100000001000000e000000000"), // SETEND
InstructionGenerator("cccc11101D110000dddd101z01M0mmmm"), // VMOV (reg)
InstructionGenerator("cccc1101UD01nnnndddd101zvvvvvvvv"), // VLDR
InstructionGenerator("cccc1101UD00nnnndddd101zvvvvvvvv"), // VSTR
}};
FuzzJitArm(5, 6, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("VFP: VCMP", "[JitX64][vfp]") {
const std::array<InstructionGenerator, 2> instructions = {{
InstructionGenerator("cccc11101D110100dddd101zE1M0mmmm"), // VCMP
InstructionGenerator("cccc11101D110101dddd101zE1000000"), // VCMP (zero)
}};
FuzzJitArm(5, 6, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("Fuzz ARM data processing instructions", "[JitX64]") {
const std::array<InstructionGenerator, 16> imm_instructions = {{
InstructionGenerator("cccc0010101Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010100Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010000Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0011110Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc00110111nnnn0000rrrrvvvvvvvv"),
InstructionGenerator("cccc00110101nnnn0000rrrrvvvvvvvv"),
InstructionGenerator("cccc0010001Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0011101S0000ddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0011111S0000ddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0011100Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010011Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010111Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010110Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc0010010Snnnnddddrrrrvvvvvvvv"),
InstructionGenerator("cccc00110011nnnn0000rrrrvvvvvvvv"),
InstructionGenerator("cccc00110001nnnn0000rrrrvvvvvvvv"),
}};
const std::array<InstructionGenerator, 16> reg_instructions = {{
InstructionGenerator("cccc0000101Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000100Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000000Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0001110Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc00010111nnnn0000vvvvvrr0mmmm"),
InstructionGenerator("cccc00010101nnnn0000vvvvvrr0mmmm"),
InstructionGenerator("cccc0000001Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0001101S0000ddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0001111S0000ddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0001100Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000011Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000111Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000110Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc0000010Snnnnddddvvvvvrr0mmmm"),
InstructionGenerator("cccc00010011nnnn0000vvvvvrr0mmmm"),
InstructionGenerator("cccc00010001nnnn0000vvvvvrr0mmmm"),
}};
const std::array<InstructionGenerator, 16> rsr_instructions = {{
InstructionGenerator("cccc0000101Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000100Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000000Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0001110Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc00010111nnnn0000ssss0rr1mmmm"),
InstructionGenerator("cccc00010101nnnn0000ssss0rr1mmmm"),
InstructionGenerator("cccc0000001Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0001101S0000ddddssss0rr1mmmm"),
InstructionGenerator("cccc0001111S0000ddddssss0rr1mmmm"),
InstructionGenerator("cccc0001100Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000011Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000111Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000110Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc0000010Snnnnddddssss0rr1mmmm"),
InstructionGenerator("cccc00010011nnnn0000ssss0rr1mmmm"),
InstructionGenerator("cccc00010001nnnn0000ssss0rr1mmmm"),
}};
auto instruction_select = [&](bool Rd_can_be_r15) -> auto {
return [&, Rd_can_be_r15]() -> u32 {
size_t instruction_set = RandInt<size_t>(0, 2);
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 S = RandInt<u32>(0, 1);
switch (instruction_set) {
case 0: {
InstructionGenerator instruction = imm_instructions[RandInt<size_t>(0, imm_instructions.size() - 1)];
u32 Rd = RandInt<u32>(0, Rd_can_be_r15 ? 15 : 14);
if (Rd == 15) S = false;
u32 Rn = RandInt<u32>(0, 15);
u32 shifter_operand = RandInt<u32>(0, 0xFFF);
u32 assemble_randoms = (shifter_operand << 0) | (Rd << 12) | (Rn << 16) | (S << 20) | (cond << 28);
return instruction.Bits() | (assemble_randoms & ~instruction.Mask());
}
case 1: {
InstructionGenerator instruction = reg_instructions[RandInt<size_t>(0, reg_instructions.size() - 1)];
u32 Rd = RandInt<u32>(0, Rd_can_be_r15 ? 15 : 14);
if (Rd == 15) S = false;
u32 Rn = RandInt<u32>(0, 15);
u32 shifter_operand = RandInt<u32>(0, 0xFFF);
u32 assemble_randoms =
(shifter_operand << 0) | (Rd << 12) | (Rn << 16) | (S << 20) | (cond << 28);
return instruction.Bits() | (assemble_randoms & ~instruction.Mask());
}
case 2: {
InstructionGenerator instruction = rsr_instructions[RandInt<size_t>(0, rsr_instructions.size() - 1)];
u32 Rd = RandInt<u32>(0, 14); // Rd can never be 15.
u32 Rn = RandInt<u32>(0, 14);
u32 Rs = RandInt<u32>(0, 14);
int rotate = RandInt<int>(0, 3);
u32 Rm = RandInt<u32>(0, 14);
u32 assemble_randoms =
(Rm << 0) | (rotate << 5) | (Rs << 8) | (Rd << 12) | (Rn << 16) | (S << 20) | (cond << 28);
return instruction.Bits() | (assemble_randoms & ~instruction.Mask());
}
}
return 0;
};
};
SECTION("single instructions") {
FuzzJitArm(1, 2, 10000, instruction_select(/*Rd_can_be_r15=*/false));
}
SECTION("short blocks") {
FuzzJitArm(5, 6, 10000, instruction_select(/*Rd_can_be_r15=*/false));
}
SECTION("long blocks") {
FuzzJitArm(1024, 1025, 200, instruction_select(/*Rd_can_be_r15=*/false));
}
SECTION("R15") {
FuzzJitArm(1, 1, 10000, instruction_select(/*Rd_can_be_r15=*/true));
}
}
TEST_CASE("Fuzz ARM load/store instructions (byte, half-word, word)", "[JitX64]") {
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
InstructionGenerator("cccc000pu0w1nnnndddd00001101mmmm"), // LDRSB_reg
InstructionGenerator("cccc000pu1w1nnnnddddvvvv1111vvvv"), // LDRSH_imm
InstructionGenerator("cccc000pu0w1nnnndddd00001111mmmm"), // LDRSH_reg
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);
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);
if (!P || 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;
}
}
};
SECTION("short blocks") {
FuzzJitArm(5, 6, 30000, instruction_select);
}
}
TEST_CASE("Fuzz ARM load/store multiple instructions", "[JitX64]") {
const std::array<InstructionGenerator, 2> instructions = {{
InstructionGenerator("cccc100pu0w1nnnnxxxxxxxxxxxxxxxx"), // LDM
InstructionGenerator("cccc100pu0w0nnnnxxxxxxxxxxxxxxxx"), // STM
}};
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 reg_list = RandInt<u32>(1, 0xFFFF);
u32 Rn = RandInt<u32>(0, 14);
u32 flags = RandInt<u32>(0, 0xF);
while (true) {
if (inst_index == 1 && (flags & 2)) {
if (reg_list & (1 << Rn))
reg_list &= ~((1 << Rn) - 1);
} else if (inst_index == 0 && (flags & 2)) {
reg_list &= ~(1 << Rn);
}
if (reg_list)
break;
reg_list = RandInt<u32>(1, 0xFFFF);
}
u32 assemble_randoms = (reg_list << 0) | (Rn << 16) | (flags << 24) | (cond << 28);
return instructions[inst_index].Bits() | (assemble_randoms & (~instructions[inst_index].Mask()));
};
FuzzJitArm(1, 1, 10000, instruction_select);
}
TEST_CASE("Fuzz ARM branch instructions", "[JitX64]") {
const std::array<InstructionGenerator, 6> instructions = {{
InstructionGenerator("1111101hvvvvvvvvvvvvvvvvvvvvvvvv"),
InstructionGenerator("cccc000100101111111111110011mmmm",
[](u32 instr) { return Bits<0, 3>(instr) != 0b1111; }), // R15 is UNPREDICTABLE
InstructionGenerator("cccc1010vvvvvvvvvvvvvvvvvvvvvvvv"),
InstructionGenerator("cccc1011vvvvvvvvvvvvvvvvvvvvvvvv"),
InstructionGenerator("cccc000100101111111111110001mmmm"),
InstructionGenerator("cccc000100101111111111110010mmmm"),
}};
FuzzJitArm(1, 1, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("Fuzz ARM reversal instructions", "[JitX64]") {
const auto is_valid = [](u32 instr) -> bool {
// R15 is UNPREDICTABLE
return Bits<0, 3>(instr) != 0b1111 && Bits<12, 15>(instr) != 0b1111;
};
const std::array<InstructionGenerator, 3> rev_instructions = {{
InstructionGenerator("cccc011010111111dddd11110011mmmm", is_valid),
InstructionGenerator("cccc011010111111dddd11111011mmmm", is_valid),
InstructionGenerator("cccc011011111111dddd11111011mmmm", is_valid),
}};
SECTION("Reverse tests") {
FuzzJitArm(1, 1, 10000, [&rev_instructions]() -> u32 {
return rev_instructions[RandInt<size_t>(0, rev_instructions.size() - 1)].Generate();
});
}
}
TEST_CASE("Fuzz ARM extension instructions", "[JitX64]") {
const auto is_valid = [](u32 instr) -> bool {
// R15 as Rd or Rm is UNPREDICTABLE
return Bits<0, 3>(instr) != 0b1111 && Bits<12, 15>(instr) != 0b1111;
};
const std::array<InstructionGenerator, 6> signed_instructions = {{
InstructionGenerator("cccc011010101111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc011010001111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc011010111111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc01101010nnnnddddrr000111mmmm", is_valid),
InstructionGenerator("cccc01101000nnnnddddrr000111mmmm", is_valid),
InstructionGenerator("cccc01101011nnnnddddrr000111mmmm", is_valid),
}};
const std::array<InstructionGenerator, 6> unsigned_instructions = {{
InstructionGenerator("cccc011011101111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc011011001111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc011011111111ddddrr000111mmmm", is_valid),
InstructionGenerator("cccc01101110nnnnddddrr000111mmmm", is_valid),
InstructionGenerator("cccc01101100nnnnddddrr000111mmmm", is_valid), //UXTAB16
InstructionGenerator("cccc01101111nnnnddddrr000111mmmm", is_valid),
}};
SECTION("Signed extension") {
FuzzJitArm(1, 1, 10000, [&signed_instructions]() -> u32 {
return signed_instructions[RandInt<size_t>(0, signed_instructions.size() - 1)].Generate();
});
}
SECTION("Unsigned extension") {
FuzzJitArm(1, 1, 10000, [&unsigned_instructions]() -> u32 {
return unsigned_instructions[RandInt<size_t>(0, unsigned_instructions.size() - 1)].Generate();
});
}
}
TEST_CASE("Fuzz ARM multiply instructions", "[JitX64]") {
auto validate_d_m_n = [](u32 inst) -> bool {
return Bits<16, 19>(inst) != 15 &&
Bits<8, 11>(inst) != 15 &&
Bits<0, 3>(inst) != 15;
};
auto validate_d_a_m_n = [&](u32 inst) -> bool {
return validate_d_m_n(inst) &&
Bits<12, 15>(inst) != 15;
};
auto validate_h_l_m_n = [&](u32 inst) -> bool {
return validate_d_a_m_n(inst) &&
Bits<12, 15>(inst) != Bits<16, 19>(inst);
};
const std::array<InstructionGenerator, 21> instructions = {{
InstructionGenerator("cccc0000001Sddddaaaammmm1001nnnn", validate_d_a_m_n), // MLA
InstructionGenerator("cccc0000000Sdddd0000mmmm1001nnnn", validate_d_m_n), // MUL
InstructionGenerator("cccc0000111Sddddaaaammmm1001nnnn", validate_h_l_m_n), // SMLAL
InstructionGenerator("cccc0000110Sddddaaaammmm1001nnnn", validate_h_l_m_n), // SMULL
InstructionGenerator("cccc00000100ddddaaaammmm1001nnnn", validate_h_l_m_n), // UMAAL
InstructionGenerator("cccc0000101Sddddaaaammmm1001nnnn", validate_h_l_m_n), // UMLAL
InstructionGenerator("cccc0000100Sddddaaaammmm1001nnnn", validate_h_l_m_n), // UMULL
InstructionGenerator("cccc00010100ddddaaaammmm1xy0nnnn", validate_h_l_m_n), // SMLALxy
InstructionGenerator("cccc00010000ddddaaaammmm1xy0nnnn", validate_d_a_m_n), // SMLAxy
InstructionGenerator("cccc00010110dddd0000mmmm1xy0nnnn", validate_d_m_n), // SMULxy
InstructionGenerator("cccc00010010ddddaaaammmm1y00nnnn", validate_d_a_m_n), // SMLAWy
InstructionGenerator("cccc00010010dddd0000mmmm1y10nnnn", validate_d_m_n), // SMULWy
InstructionGenerator("cccc01110101dddd1111mmmm00R1nnnn", validate_d_m_n), // SMMUL
InstructionGenerator("cccc01110101ddddaaaammmm00R1nnnn", validate_d_a_m_n), // SMMLA
InstructionGenerator("cccc01110101ddddaaaammmm11R1nnnn", validate_d_a_m_n), // SMMLS
InstructionGenerator("cccc01110000ddddaaaammmm00M1nnnn", validate_d_a_m_n), // SMLAD
InstructionGenerator("cccc01110100ddddaaaammmm00M1nnnn", validate_h_l_m_n), // SMLALD
InstructionGenerator("cccc01110000ddddaaaammmm01M1nnnn", validate_d_a_m_n), // SMLSD
InstructionGenerator("cccc01110100ddddaaaammmm01M1nnnn", validate_h_l_m_n), // SMLSLD
InstructionGenerator("cccc01110000dddd1111mmmm00M1nnnn", validate_d_m_n), // SMUAD
InstructionGenerator("cccc01110000dddd1111mmmm01M1nnnn", validate_d_m_n), // SMUSD
}};
SECTION("Multiply") {
FuzzJitArm(1, 1, 10000, [&]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
}
TEST_CASE("Fuzz ARM parallel instructions", "[JitX64][parallel]") {
const auto is_valid = [](u32 instr) -> bool {
// R15 as Rd, Rn, or Rm is UNPREDICTABLE
return Bits<0, 3>(instr) != 0b1111 && Bits<12, 15>(instr) != 0b1111 && Bits<16, 19>(instr) != 0b1111;
};
const auto is_sel_valid = [](u32 instr) -> bool {
// R15 as Rd, Rn, or Rm is UNPREDICTABLE
return Bits<0, 3>(instr) != 0b1111 && Bits<12, 15>(instr) != 0b1111 && Bits<16, 19>(instr) != 0b1111;
};
const auto is_msr_valid = [](u32 instr) -> bool {
// Mask can not be 0
return Bits<18, 19>(instr) != 0b00;
};
const InstructionGenerator cpsr_setter = InstructionGenerator("11100011001001001111rrrrvvvvvvvv", is_msr_valid); // MSR_Imm write GE
const InstructionGenerator sel_instr = InstructionGenerator("111001101000nnnndddd11111011mmmm", is_sel_valid); // SEL
const std::array<InstructionGenerator, 4> modulo_add_instructions = {{
InstructionGenerator("cccc01100001nnnndddd11111001mmmm", is_valid), // SADD8
InstructionGenerator("cccc01100001nnnndddd11110001mmmm", is_valid), // SADD16
InstructionGenerator("cccc01100101nnnndddd11111001mmmm", is_valid), // UADD8
InstructionGenerator("cccc01100101nnnndddd11110001mmmm", is_valid), // UADD16
}};
const std::array<InstructionGenerator, 4> modulo_sub_instructions = {{
InstructionGenerator("cccc01100001nnnndddd11111111mmmm", is_valid), // SSUB8
InstructionGenerator("cccc01100001nnnndddd11110111mmmm", is_valid), // SSUB16
InstructionGenerator("cccc01100101nnnndddd11111111mmmm", is_valid), // USUB8
InstructionGenerator("cccc01100101nnnndddd11110111mmmm", is_valid), // USUB16
}};
const std::array<InstructionGenerator, 4> modulo_exchange_instructions = {{
InstructionGenerator("cccc01100001nnnndddd11110011mmmm", is_valid), // SASX
InstructionGenerator("cccc01100001nnnndddd11110101mmmm", is_valid), // SSAX
InstructionGenerator("cccc01100101nnnndddd11110011mmmm", is_valid), // UASX
InstructionGenerator("cccc01100101nnnndddd11110101mmmm", is_valid), // USAX
}};
const std::array<InstructionGenerator, 12> saturating_instructions = {{
InstructionGenerator("cccc01100010nnnndddd11111001mmmm", is_valid), // QADD8
InstructionGenerator("cccc01100010nnnndddd11111111mmmm", is_valid), // QSUB8
InstructionGenerator("cccc01100110nnnndddd11111001mmmm", is_valid), // UQADD8
InstructionGenerator("cccc01100110nnnndddd11111111mmmm", is_valid), // UQSUB8
InstructionGenerator("cccc01100010nnnndddd11110001mmmm", is_valid), // QADD16
InstructionGenerator("cccc01100010nnnndddd11110111mmmm", is_valid), // QSUB16
InstructionGenerator("cccc01100110nnnndddd11110001mmmm", is_valid), // UQADD16
InstructionGenerator("cccc01100110nnnndddd11110111mmmm", is_valid), // UQSUB16
InstructionGenerator("cccc01100010nnnndddd11110011mmmm", is_valid), // QASX
InstructionGenerator("cccc01100010nnnndddd11110101mmmm", is_valid), // QSAX
InstructionGenerator("cccc01100110nnnndddd11110011mmmm", is_valid), // UQASX
InstructionGenerator("cccc01100110nnnndddd11110101mmmm", is_valid), // UQSAX
}};
const std::array<InstructionGenerator, 12> halving_instructions = {{
InstructionGenerator("cccc01100011nnnndddd11111001mmmm", is_valid), // SHADD8
InstructionGenerator("cccc01100011nnnndddd11110001mmmm", is_valid), // SHADD16
InstructionGenerator("cccc01100011nnnndddd11110011mmmm", is_valid), // SHASX
InstructionGenerator("cccc01100011nnnndddd11110101mmmm", is_valid), // SHSAX
InstructionGenerator("cccc01100011nnnndddd11111111mmmm", is_valid), // SHSUB8
InstructionGenerator("cccc01100011nnnndddd11110111mmmm", is_valid), // SHSUB16
InstructionGenerator("cccc01100111nnnndddd11111001mmmm", is_valid), // UHADD8
InstructionGenerator("cccc01100111nnnndddd11110001mmmm", is_valid), // UHADD16
InstructionGenerator("cccc01100111nnnndddd11110011mmmm", is_valid), // UHASX
InstructionGenerator("cccc01100111nnnndddd11110101mmmm", is_valid), // UHSAX
InstructionGenerator("cccc01100111nnnndddd11111111mmmm", is_valid), // UHSUB8
InstructionGenerator("cccc01100111nnnndddd11110111mmmm", is_valid), // UHSUB16
}};
size_t index = 0;
const auto also_test_sel = [&](u32 inst) -> u32 {
switch (index++ % 3) {
case 1:
return cpsr_setter.Generate(false);
case 2:
return sel_instr.Generate(false);
}
return inst;
};
SECTION("Parallel Add (Modulo)") {
FuzzJitArm(4, 5, 10000, [&]() -> u32 {
return also_test_sel(modulo_add_instructions[RandInt<size_t>(0, modulo_add_instructions.size() - 1)].Generate());
});
}
SECTION("Parallel Subtract (Modulo)") {
FuzzJitArm(4, 5, 10000, [&]() -> u32 {
return also_test_sel(modulo_sub_instructions[RandInt<size_t>(0, modulo_sub_instructions.size() - 1)].Generate());
});
}
SECTION("Parallel Exchange (Modulo)") {
FuzzJitArm(4, 5, 10000, [&]() -> u32 {
return also_test_sel(modulo_exchange_instructions[RandInt<size_t>(0, modulo_exchange_instructions.size() - 1)].Generate());
});
}
SECTION("Parallel Add/Subtract (Saturating)") {
FuzzJitArm(4, 5, 10000, [&]() -> u32 {
return also_test_sel(saturating_instructions[RandInt<size_t>(0, saturating_instructions.size() - 1)].Generate());
});
}
SECTION("Parallel Add/Subtract (Halving)") {
FuzzJitArm(4, 5, 10000, [&]() -> u32 {
return also_test_sel(halving_instructions[RandInt<size_t>(0, halving_instructions.size() - 1)].Generate());
});
}
SECTION("Fuzz SEL") {
// Alternate between a SEL and a MSR to change the CPSR, thus changing the expected result of the next SEL
bool set_cpsr = true;
FuzzJitArm(5, 6, 10000, [&sel_instr, &cpsr_setter, &set_cpsr]() -> u32 {
set_cpsr ^= true;
if (set_cpsr)
return cpsr_setter.Generate(false);
return sel_instr.Generate(false);
});
}
}
TEST_CASE("Fuzz ARM sum of absolute differences", "[JitX64]") {
auto validate_d_m_n = [](u32 inst) -> bool {
return Bits<16, 19>(inst) != 15 &&
Bits<8, 11>(inst) != 15 &&
Bits<0, 3>(inst) != 15;
};
auto validate_d_a_m_n = [&](u32 inst) -> bool {
return validate_d_m_n(inst) &&
Bits<12, 15>(inst) != 15;
};
const std::array<InstructionGenerator, 2> differences_instructions = {{
InstructionGenerator("cccc01111000dddd1111mmmm0001nnnn", validate_d_m_n), // USAD8
InstructionGenerator("cccc01111000ddddaaaammmm0001nnnn", validate_d_a_m_n), // USADA8
}};
SECTION("Sum of Absolute Differences (Differences)") {
FuzzJitArm(1, 1, 10000, [&differences_instructions]() -> u32 {
return differences_instructions[RandInt<size_t>(0, differences_instructions.size() - 1)].Generate();
});
}
}
TEST_CASE( "SMUAD", "[JitX64]" ) {
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = 0xE700F211; // smuad r0, r1, r2
jit.Regs() = {
0, // Rd
0x80008000, // Rn
0x80008000, // Rm
0,
0, 0, 0, 0,
0, 0, 0, 0,
0, 0, 0, 0,
};
jit.Cpsr() = 0x000001d0; // User-mode
jit.Run(6);
REQUIRE(jit.Regs()[0] == 0x80000000);
REQUIRE(jit.Regs()[1] == 0x80008000);
REQUIRE(jit.Regs()[2] == 0x80008000);
REQUIRE(jit.Cpsr() == 0x080001d0);
}
TEST_CASE("VFP: VPUSH, VPOP", "[JitX64][vfp]") {
const auto is_valid = [](u32 instr) -> bool {
auto regs = (instr & 0x100) ? (Bits<0, 7>(instr) >> 1) : Bits<0, 7>(instr);
auto base = Bits<12, 15>(instr);
unsigned d;
if (instr & 0x100) {
d = (base + ((instr & 0x400000) ? 16 : 0));
} else {
d = ((base << 1) + ((instr & 0x400000) ? 1 : 0));
}
// if regs == 0 || regs > 16 || (d+regs) > 32 then UNPREDICTABLE
return regs != 0 && regs <= 16 && (d + regs) <= 32;
};
const std::array<InstructionGenerator, 2> instructions = {{
InstructionGenerator("cccc11010D101101dddd101zvvvvvvvv", is_valid), // VPUSH
InstructionGenerator("cccc11001D111101dddd1010vvvvvvvv", is_valid), // VPOP
}};
FuzzJitArm(5, 6, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("Test ARM misc instructions", "[JitX64]") {
const auto is_clz_valid = [](u32 instr) -> bool {
// R15 as Rd, or Rm is UNPREDICTABLE
return Bits<0, 3>(instr) != 0b1111 && Bits<12, 15>(instr) != 0b1111;
};
const InstructionGenerator clz_instr = InstructionGenerator("cccc000101101111dddd11110001mmmm", is_clz_valid); // CLZ
SECTION("Fuzz CLZ") {
FuzzJitArm(1, 1, 1000, [&clz_instr]() -> u32 {
return clz_instr.Generate();
});
}
}
TEST_CASE("Fuzz ARM saturated add/sub instructions", "[JitX64]") {
auto is_valid = [](u32 inst) -> bool {
// R15 as Rd, Rn, or Rm is UNPREDICTABLE
return Bits<16, 19>(inst) != 0b1111 &&
Bits<12, 15>(inst) != 0b1111 &&
Bits<0, 3>(inst) != 0b1111;
};
const std::array<InstructionGenerator, 4> instructions = {{
InstructionGenerator("cccc00010000nnnndddd00000101mmmm", is_valid), // QADD
InstructionGenerator("cccc00010010nnnndddd00000101mmmm", is_valid), // QSUB
InstructionGenerator("cccc00010100nnnndddd00000101mmmm", is_valid), // QDADD
InstructionGenerator("cccc00010110nnnndddd00000101mmmm", is_valid), // QDSUB
}};
SECTION("Saturated") {
FuzzJitArm(4, 5, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
}
TEST_CASE("Fuzz ARM saturation instructions", "[JitX64]") {
auto is_valid = [](u32 inst) -> bool {
// R15 as Rd or Rn is UNPREDICTABLE
return Bits<12, 15>(inst) != 0b1111 &&
Bits<0, 3>(inst) != 0b1111;
};
const std::array<InstructionGenerator, 4> instructions = {{
InstructionGenerator("cccc0110101vvvvvddddvvvvvr01nnnn", is_valid), // SSAT
InstructionGenerator("cccc01101010vvvvdddd11110011nnnn", is_valid), // SSAT16
InstructionGenerator("cccc0110111vvvvvddddvvvvvr01nnnn", is_valid), // USAT
InstructionGenerator("cccc01101110vvvvdddd11110011nnnn", is_valid), // USAT16
}};
FuzzJitArm(4, 5, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
TEST_CASE("Fuzz ARM packing instructions", "[JitX64]") {
auto is_pkh_valid = [](u32 inst) -> bool {
// R15 as Rd, Rn, or Rm is UNPREDICTABLE
return Bits<16, 19>(inst) != 0b1111 &&
Bits<12, 15>(inst) != 0b1111 &&
Bits<0, 3>(inst) != 0b1111;
};
const std::array<InstructionGenerator, 2> instructions = {{
InstructionGenerator("cccc01101000nnnnddddvvvvv001mmmm", is_pkh_valid), // PKHBT
InstructionGenerator("cccc01101000nnnnddddvvvvv101mmmm", is_pkh_valid), // PKHTB
}};
SECTION("Packing") {
FuzzJitArm(1, 1, 10000, [&instructions]() -> u32 {
return instructions[RandInt<size_t>(0, instructions.size() - 1)].Generate();
});
}
}
TEST_CASE("arm: Test InvalidateCacheRange", "[arm]") {
Dynarmic::Jit jit{GetUserCallbacks()};
code_mem.fill({});
code_mem[0] = 0xe3a00005; // mov r0, #5
code_mem[1] = 0xe3a0100D; // mov r1, #13
code_mem[2] = 0xe0812000; // add r2, r1, r0
code_mem[3] = 0xeafffffe; // b +#0 (infinite loop)
jit.Regs() = {};
jit.Cpsr() = 0x000001d0; // User-mode
jit.Run(4);
REQUIRE(jit.Regs()[0] == 5);
REQUIRE(jit.Regs()[1] == 13);
REQUIRE(jit.Regs()[2] == 18);
REQUIRE(jit.Regs()[15] == 0x0000000c);
REQUIRE(jit.Cpsr() == 0x000001d0);
// Change the code
code_mem[1] = 0xe3a01007; // mov r1, #7
jit.InvalidateCacheRange(/*start_memory_location = */ 4, /* length_in_bytes = */ 4);
// Reset position of PC
jit.Regs()[15] = 0;
jit.Run(4);
REQUIRE(jit.Regs()[0] == 5);
REQUIRE(jit.Regs()[1] == 7);
REQUIRE(jit.Regs()[2] == 12);
REQUIRE(jit.Regs()[15] == 0x0000000c);
REQUIRE(jit.Cpsr() == 0x000001d0);
}