//: operating directly on a register
:(before "End Initialize Op Names")
put_new(Name, "01", "add r32 to rm32 (add)");
:(code)
void test_add_r32_to_r32() {
Reg[EAX].i = 0x10;
Reg[EBX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 01 d8 \n" // add EBX to EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: add EBX to r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x00000011\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x01: { // add r32 to r/m32
uint8_t modrm = next();
uint8_t arg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "add " << rname(arg2) << " to r/m32" << end();
int32_t* signed_arg1 = effective_address(modrm);
int32_t signed_result = *signed_arg1 + Reg[arg2].i;
SF = (signed_result < 0);
ZF = (signed_result == 0);
int64_t signed_full_result = static_cast<int64_t>(*signed_arg1) + Reg[arg2].i;
OF = (signed_result != signed_full_result);
// set CF
uint32_t unsigned_arg1 = static_cast<uint32_t>(*signed_arg1);
uint32_t unsigned_result = unsigned_arg1 + Reg[arg2].u;
uint64_t unsigned_full_result = static_cast<uint64_t>(unsigned_arg1) + Reg[arg2].u;
CF = (unsigned_result != unsigned_full_result);
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
*signed_arg1 = signed_result;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *signed_arg1 << end();
break;
}
:(code)
void test_add_r32_to_r32_signed_overflow() {
Reg[EAX].i = 0x7fffffff; // largest positive signed integer
Reg[EBX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 01 d8 \n" // add EBX to EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: add EBX to r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=0; OF=1\n"
"run: storing 0x80000000\n"
);
}
void test_add_r32_to_r32_unsigned_overflow() {
Reg[EAX].u = 0xffffffff; // largest unsigned number
Reg[EBX].u = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 01 d8 \n" // add EBX to EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: add EBX to r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=1; CF=1; OF=0\n"
"run: storing 0x00000000\n"
);
}
void test_add_r32_to_r32_unsigned_and_signed_overflow() {
Reg[EAX].u = Reg[EBX].u = 0x80000000; // smallest negative signed integer
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 01 d8 \n" // add EBX to EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: add EBX to r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=1; CF=1; OF=1\n"
"run: storing 0x00000000\n"
);
}
:(code)
// Implement tables 2-2 and 2-3 in the Intel manual, Volume 2.
// We return a pointer so that instructions can write to multiple bytes in
// 'Mem' at once.
// beware: will eventually have side-effects
int32_t* effective_address(uint8_t modrm) {
const uint8_t mod = (modrm>>6);
// ignore middle 3 'reg opcode' bits
const uint8_t rm = modrm & 0x7;
if (mod == 3) {
// mod 3 is just register direct addressing
trace(Callstack_depth+1, "run") << "r/m32 is " << rname(rm) << end();
return &Reg[rm].i;
}
uint32_t addr = effective_address_number(modrm);
trace(Callstack_depth+1, "run") << "effective address contains 0x" << HEXWORD << read_mem_i32(addr) << end();
return mem_addr_i32(addr);
}
// beware: will eventually have side-effects
uint32_t effective_address_number(uint8_t modrm) {
const uint8_t mod = (modrm>>6);
// ignore middle 3 'reg opcode' bits
const uint8_t rm = modrm & 0x7;
uint32_t addr = 0;
switch (mod) {
case 3:
// mod 3 is just register direct addressing
raise << "unexpected direct addressing mode\n" << end();
return 0;
// End Mod Special-cases(addr)
default:
cerr << "unrecognized mod bits: " << NUM(mod) << '\n';
exit(1);
}
//: other mods are indirect, and they'll set addr appropriately
// Found effective_address(addr)
return addr;
}
string rname(uint8_t r) {
switch (r) {
case 0: return "EAX";
case 1: return "ECX";
case 2: return "EDX";
case 3: return "EBX";
case 4: return "ESP";
case 5: return "EBP";
case 6: return "ESI";
case 7: return "EDI";
default: raise << "invalid register " << r << '\n' << end(); return "";
}
}
//:: subtract
:(before "End Initialize Op Names")
put_new(Name, "29", "subtract r32 from rm32 (sub)");
:(code)
void test_subtract_r32_from_r32() {
Reg[EAX].i = 10;
Reg[EBX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 29 d8 \n" // subtract EBX from EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: subtract EBX from r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x00000009\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x29: { // subtract r32 from r/m32
const uint8_t modrm = next();
const uint8_t arg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "subtract " << rname(arg2) << " from r/m32" << end();
int32_t* signed_arg1 = effective_address(modrm);
int32_t signed_result = *signed_arg1 - Reg[arg2].i;
SF = (signed_result < 0);
ZF = (signed_result == 0);
int64_t signed_full_result = static_cast<int64_t>(*signed_arg1) - Reg[arg2].i;
OF = (signed_result != signed_full_result);
// set CF
uint32_t unsigned_arg1 = static_cast<uint32_t>(*signed_arg1);
uint32_t unsigned_result = unsigned_arg1 - Reg[arg2].u;
uint64_t unsigned_full_result = static_cast<uint64_t>(unsigned_arg1) - Reg[arg2].u;
CF = (unsigned_result != unsigned_full_result);
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
*signed_arg1 = signed_result;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *signed_arg1 << end();
break;
}
:(code)
void test_subtract_r32_from_r32_signed_overflow() {
Reg[EAX].i = 0x80000000; // smallest negative signed integer
Reg[EBX].i = 0x7fffffff; // largest positive signed integer
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 29 d8 \n" // subtract EBX from EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: subtract EBX from r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=0; CF=0; OF=1\n"
"run: storing 0x00000001\n"
);
}
void test_subtract_r32_from_r32_unsigned_overflow() {
Reg[EAX].i = 0;
Reg[EBX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 29 d8 \n" // subtract EBX from EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: subtract EBX from r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=1; OF=0\n"
"run: storing 0xffffffff\n"
);
}
void test_subtract_r32_from_r32_signed_and_unsigned_overflow() {
Reg[EAX].i = 0;
Reg[EBX].i = 0x80000000; // smallest negative signed integer
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 29 d8 \n" // subtract EBX from EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: subtract EBX from r/m32\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=1; OF=1\n"
"run: storing 0x80000000\n"
);
}
//:: multiply
:(before "End Initialize Op Names")
put_new(Name, "f7", "negate/multiply/divide rm32 (with EAX and EDX if necessary) depending on subop (neg/mul/idiv)");
:(code)
void test_multiply_EAX_by_r32() {
Reg[EAX].i = 4;
Reg[ECX].i = 3;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 e1 \n" // multiply EAX by ECX
// ModR/M in binary: 11 (direct mode) 100 (subop mul) 001 (src ECX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is ECX\n"
"run: subop: multiply EAX by r/m32\n"
"run: storing 0x0000000c\n"
);
}
:(before "End Single-Byte Opcodes")
case 0xf7: {
const uint8_t modrm = next();
trace(Callstack_depth+1, "run") << "operate on r/m32" << end();
int32_t* arg1 = effective_address(modrm);
const uint8_t subop = (modrm>>3)&0x7; // middle 3 'reg opcode' bits
switch (subop) {
case 4: { // mul unsigned EAX by r/m32
trace(Callstack_depth+1, "run") << "subop: multiply EAX by r/m32" << end();
const uint64_t result = static_cast<uint64_t>(Reg[EAX].u) * static_cast<uint32_t>(*arg1);
Reg[EAX].u = result & 0xffffffff;
Reg[EDX].u = result >> 32;
OF = (Reg[EDX].u != 0);
CF = OF;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << Reg[EAX].u << end();
break;
}
// End Op f7 Subops
default:
cerr << "unrecognized subop for opcode f7: " << NUM(subop) << '\n';
exit(1);
}
break;
}
//:
:(before "End Initialize Op Names")
put_new(Name_0f, "af", "multiply rm32 into r32 (imul)");
:(code)
void test_multiply_r32_into_r32() {
Reg[EAX].i = 4;
Reg[EBX].i = 2;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 0f af d8 \n" // subtract EBX into EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: multiply EBX by r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x00000008\n"
);
}
:(before "End Two-Byte Opcodes Starting With 0f")
case 0xaf: { // multiply r32 by r/m32
const uint8_t modrm = next();
const uint8_t arg1 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "multiply " << rname(arg1) << " by r/m32" << end();
const int32_t* arg2 = effective_address(modrm);
int32_t result = Reg[arg1].i * (*arg2);
int64_t full_result = static_cast<int64_t>(Reg[arg1].i) * (*arg2);
OF = (result != full_result);
CF = OF;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
Reg[arg1].i = result;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << Reg[arg1].i << end();
break;
}
//:: negate
:(code)
void test_negate_r32() {
Reg[EBX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 db \n" // negate EBX
// ModR/M in binary: 11 (direct mode) 011 (subop negate) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: negate\n"
"run: storing 0xffffffff\n"
);
}
:(before "End Op f7 Subops")
case 3: { // negate r/m32
trace(Callstack_depth+1, "run") << "subop: negate" << end();
// one case that can overflow
if (static_cast<uint32_t>(*arg1) == 0x80000000) {
trace(Callstack_depth+1, "run") << "overflow" << end();
SF = true;
ZF = false;
OF = true;
break;
}
int32_t result = -(*arg1);
SF = (result >> 31);
ZF = (result == 0);
OF = false;
CF = (*arg1 != 0);
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
*arg1 = result;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << end();
break;
}
:(code)
// negate can overflow in exactly one situation
void test_negate_can_overflow() {
Reg[EBX].i = 0x80000000; // INT_MIN
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 db \n" // negate EBX
// ModR/M in binary: 11 (direct mode) 011 (subop negate) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: negate\n"
"run: overflow\n"
);
}
//:: divide with remainder
void test_divide_EAX_by_rm32() {
Reg[EAX].u = 7;
Reg[EDX].u = 0;
Reg[ECX].i = 3;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 f9 \n" // multiply EAX by ECX
// ModR/M in binary: 11 (direct mode) 111 (subop idiv) 001 (divisor ECX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is ECX\n"
"run: subop: divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX\n"
"run: quotient: 0x00000002\n"
"run: remainder: 0x00000001\n"
);
}
:(before "End Op f7 Subops")
case 7: { // divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX
trace(Callstack_depth+1, "run") << "subop: divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX" << end();
int64_t dividend = static_cast<int64_t>((static_cast<uint64_t>(Reg[EDX].u) << 32) | Reg[EAX].u);
int32_t divisor = *arg1;
assert(divisor != 0);
Reg[EAX].i = dividend/divisor; // quotient
Reg[EDX].i = dividend%divisor; // remainder
// flag state undefined
trace(Callstack_depth+1, "run") << "quotient: 0x" << HEXWORD << Reg[EAX].i << end();
trace(Callstack_depth+1, "run") << "remainder: 0x" << HEXWORD << Reg[EDX].i << end();
break;
}
:(code)
void test_divide_EAX_by_negative_rm32() {
Reg[EAX].u = 7;
Reg[EDX].u = 0;
Reg[ECX].i = -3;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 f9 \n" // multiply EAX by ECX
// ModR/M in binary: 11 (direct mode) 111 (subop idiv) 001 (divisor ECX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is ECX\n"
"run: subop: divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX\n"
"run: quotient: 0xfffffffe\n" // -2
"run: remainder: 0x00000001\n"
);
}
void test_divide_negative_EAX_by_rm32() {
Reg[EAX].i = -7;
Reg[EDX].i = -1; // sign extend
Reg[ECX].i = 3;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 f9 \n" // multiply EAX by ECX
// ModR/M in binary: 11 (direct mode) 111 (subop idiv) 001 (divisor ECX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is ECX\n"
"run: subop: divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX\n"
"run: quotient: 0xfffffffe\n" // -2
"run: remainder: 0xffffffff\n" // -1, same sign as divident (EDX:EAX)
);
}
void test_divide_negative_EDX_EAX_by_rm32() {
Reg[EAX].i = 0; // lower 32 bits are clear
Reg[EDX].i = -7;
Reg[ECX].i = 0x40000000; // 2^30 (largest positive power of 2)
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 f9 \n" // multiply EAX by ECX
// ModR/M in binary: 11 (direct mode) 111 (subop idiv) 001 (divisor ECX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is ECX\n"
"run: subop: divide EDX:EAX by r/m32, storing quotient in EAX and remainder in EDX\n"
"run: quotient: 0xffffffe4\n" // (-7 << 32) / (1 << 30) = -7 << 2 = -28
"run: remainder: 0x00000000\n"
);
}
//:: shift left
:(before "End Initialize Op Names")
put_new(Name, "d3", "shift rm32 by CL bits depending on subop (sal/sar/shl/shr)");
:(code)
void test_shift_left_r32_with_cl() {
Reg[EBX].i = 13;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 e3 \n" // shift EBX left by CL bits
// ModR/M in binary: 11 (direct mode) 100 (subop shift left) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift left by CL bits\n"
"run: storing 0x0000001a\n"
);
}
:(before "End Single-Byte Opcodes")
case 0xd3: {
const uint8_t modrm = next();
trace(Callstack_depth+1, "run") << "operate on r/m32" << end();
int32_t* arg1 = effective_address(modrm);
const uint8_t subop = (modrm>>3)&0x7; // middle 3 'reg opcode' bits
switch (subop) {
case 4: { // shift left r/m32 by CL
trace(Callstack_depth+1, "run") << "subop: shift left by CL bits" << end();
uint8_t count = Reg[ECX].u & 0x1f;
// OF is only defined if count is 1
if (count == 1) {
bool msb = (*arg1 & 0x80000000) >> 1;
bool pnsb = (*arg1 & 0x40000000);
OF = (msb != pnsb);
}
int32_t result = (*arg1 << count);
ZF = (result == 0);
SF = (result < 0);
CF = (*arg1 << (count-1)) & 0x80000000;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
*arg1 = result;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << end();
break;
}
// End Op d3 Subops
default:
cerr << "unrecognized subop for opcode d3: " << NUM(subop) << '\n';
exit(1);
}
break;
}
//:: shift right arithmetic
:(code)
void test_shift_right_arithmetic_r32_with_cl() {
Reg[EBX].i = 26;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 fb \n" // shift EBX right by CL bits, while preserving sign
// ModR/M in binary: 11 (direct mode) 111 (subop shift right arithmetic) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while preserving sign\n"
"run: storing 0x0000000d\n"
);
}
:(before "End Op d3 Subops")
case 7: { // shift right r/m32 by CL, preserving sign
trace(Callstack_depth+1, "run") << "subop: shift right by CL bits, while preserving sign" << end();
uint8_t count = Reg[ECX].u & 0x1f;
*arg1 = (*arg1 >> count);
ZF = (*arg1 == 0);
SF = (*arg1 < 0);
// OF is only defined if count is 1
if (count == 1) OF = false;
// CF undefined
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << end();
break;
}
:(code)
void test_shift_right_arithmetic_odd_r32_with_cl() {
Reg[EBX].i = 27;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 fb \n" // shift EBX right by CL bits, while preserving sign
// ModR/M in binary: 11 (direct mode) 111 (subop shift right arithmetic) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while preserving sign\n"
// result: 13
"run: storing 0x0000000d\n"
);
}
void test_shift_right_arithmetic_negative_r32_with_cl() {
Reg[EBX].i = 0xfffffffd; // -3
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 fb \n" // shift EBX right by CL bits, while preserving sign
// ModR/M in binary: 11 (direct mode) 111 (subop shift right arithmetic) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while preserving sign\n"
// result: -2
"run: storing 0xfffffffe\n"
);
}
//:: shift right logical
:(code)
void test_shift_right_logical_r32_with_cl() {
Reg[EBX].i = 26;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 eb \n" // shift EBX right by CL bits, while padding zeroes
// ModR/M in binary: 11 (direct mode) 101 (subop shift right logical) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while padding zeroes\n"
// result: 13
"run: storing 0x0000000d\n"
);
}
:(before "End Op d3 Subops")
case 5: { // shift right r/m32 by CL, padding zeroes
trace(Callstack_depth+1, "run") << "subop: shift right by CL bits, while padding zeroes" << end();
uint8_t count = Reg[ECX].u & 0x1f;
// OF is only defined if count is 1
if (count == 1) {
bool msb = (*arg1 & 0x80000000) >> 1;
bool pnsb = (*arg1 & 0x40000000);
OF = (msb != pnsb);
}
uint32_t* uarg1 = reinterpret_cast<uint32_t*>(arg1);
*uarg1 = (*uarg1 >> count);
ZF = (*uarg1 == 0);
// result is always positive by definition
SF = false;
// CF undefined
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << end();
break;
}
:(code)
void test_shift_right_logical_odd_r32_with_cl() {
Reg[EBX].i = 27;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 eb \n" // shift EBX right by CL bits, while padding zeroes
// ModR/M in binary: 11 (direct mode) 101 (subop shift right logical) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while padding zeroes\n"
// result: 13
"run: storing 0x0000000d\n"
);
}
void test_shift_right_logical_negative_r32_with_cl() {
Reg[EBX].i = 0xfffffffd;
Reg[ECX].i = 1;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" d3 eb \n" // shift EBX right by CL bits, while padding zeroes
// ModR/M in binary: 11 (direct mode) 101 (subop shift right logical) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: shift right by CL bits, while padding zeroes\n"
"run: storing 0x7ffffffe\n"
);
}
//:: and
:(before "End Initialize Op Names")
put_new(Name, "21", "rm32 = bitwise AND of r32 with rm32 (and)");
:(code)
void test_and_r32_with_r32() {
Reg[EAX].i = 0x0a0b0c0d;
Reg[EBX].i = 0x000000ff;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 21 d8 \n" // and EBX with destination EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: and EBX with r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x0000000d\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x21: { // and r32 with r/m32
const uint8_t modrm = next();
const uint8_t arg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "and " << rname(arg2) << " with r/m32" << end();
// bitwise ops technically operate on unsigned numbers, but it makes no
// difference
int32_t* signed_arg1 = effective_address(modrm);
*signed_arg1 &= Reg[arg2].i;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *signed_arg1 << end();
SF = (*signed_arg1 >> 31);
ZF = (*signed_arg1 == 0);
CF = false;
OF = false;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
break;
}
//:: or
:(before "End Initialize Op Names")
put_new(Name, "09", "rm32 = bitwise OR of r32 with rm32 (or)");
:(code)
void test_or_r32_with_r32() {
Reg[EAX].i = 0x0a0b0c0d;
Reg[EBX].i = 0xa0b0c0d0;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 09 d8 \n" // or EBX with destination EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: or EBX with r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0xaabbccdd\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x09: { // or r32 with r/m32
const uint8_t modrm = next();
const uint8_t arg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "or " << rname(arg2) << " with r/m32" << end();
// bitwise ops technically operate on unsigned numbers, but it makes no
// difference
int32_t* signed_arg1 = effective_address(modrm);
*signed_arg1 |= Reg[arg2].i;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *signed_arg1 << end();
SF = (*signed_arg1 >> 31);
ZF = (*signed_arg1 == 0);
CF = false;
OF = false;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
break;
}
//:: xor
:(before "End Initialize Op Names")
put_new(Name, "31", "rm32 = bitwise XOR of r32 with rm32 (xor)");
:(code)
void test_xor_r32_with_r32() {
Reg[EAX].i = 0x0a0b0c0d;
Reg[EBX].i = 0xaabbc0d0;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 31 d8 \n" // xor EBX with destination EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: xor EBX with r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0xa0b0ccdd\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x31: { // xor r32 with r/m32
const uint8_t modrm = next();
const uint8_t arg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "xor " << rname(arg2) << " with r/m32" << end();
// bitwise ops technically operate on unsigned numbers, but it makes no
// difference
int32_t* signed_arg1 = effective_address(modrm);
*signed_arg1 ^= Reg[arg2].i;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *signed_arg1 << end();
SF = (*signed_arg1 >> 31);
ZF = (*signed_arg1 == 0);
CF = false;
OF = false;
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
break;
}
//:: not
:(code)
void test_not_r32() {
Reg[EBX].i = 0x0f0f00ff;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" f7 d3 \n" // not EBX
// ModR/M in binary: 11 (direct mode) 010 (subop not) 011 (dest EBX)
);
CHECK_TRACE_CONTENTS(
"run: operate on r/m32\n"
"run: r/m32 is EBX\n"
"run: subop: not\n"
"run: storing 0xf0f0ff00\n"
);
}
:(before "End Op f7 Subops")
case 2: { // not r/m32
trace(Callstack_depth+1, "run") << "subop: not" << end();
*arg1 = ~(*arg1);
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << end();
// no flags affected
break;
}
//:: compare (cmp)
:(before "End Initialize Op Names")
put_new(Name, "39", "compare: set SF if rm32 < r32 (cmp)");
:(code)
void test_compare_r32_with_r32_greater() {
Reg[EAX].i = 0x0a0b0c0d;
Reg[EBX].i = 0x0a0b0c07;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX with EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=0; CF=0; OF=0\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x39: { // set SF if r/m32 < r32
const uint8_t modrm = next();
const uint8_t reg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "compare r/m32 with " << rname(reg2) << end();
const int32_t* signed_arg1 = effective_address(modrm);
const int32_t signed_difference = *signed_arg1 - Reg[reg2].i;
SF = (signed_difference < 0);
ZF = (signed_difference == 0);
const int64_t signed_full_difference = static_cast<int64_t>(*signed_arg1) - Reg[reg2].i;
OF = (signed_difference != signed_full_difference);
// set CF
const uint32_t unsigned_arg1 = static_cast<uint32_t>(*signed_arg1);
const uint32_t unsigned_difference = unsigned_arg1 - Reg[reg2].u;
const uint64_t unsigned_full_difference = static_cast<uint64_t>(unsigned_arg1) - Reg[reg2].u;
CF = (unsigned_difference != unsigned_full_difference);
trace(Callstack_depth+1, "run") << "SF=" << SF << "; ZF=" << ZF << "; CF=" << CF << "; OF=" << OF << end();
break;
}
:(code)
void test_compare_r32_with_r32_lesser_unsigned_and_signed() {
Reg[EAX].i = 0x0a0b0c07;
Reg[EBX].i = 0x0a0b0c0d;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX with EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=1; OF=0\n"
);
}
void test_compare_r32_with_r32_lesser_unsigned_and_signed_due_to_overflow() {
Reg[EAX].i = 0x7fffffff; // largest positive signed integer
Reg[EBX].i = 0x80000000; // smallest negative signed integer
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX with EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=1; OF=1\n"
);
}
void test_compare_r32_with_r32_lesser_signed() {
Reg[EAX].i = 0xffffffff; // -1
Reg[EBX].i = 0x00000001; // 1
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX with EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=1; ZF=0; CF=0; OF=0\n"
);
}
void test_compare_r32_with_r32_lesser_unsigned() {
Reg[EAX].i = 0x00000001; // 1
Reg[EBX].i = 0xffffffff; // -1
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX with EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=0; CF=1; OF=0\n"
);
}
void test_compare_r32_with_r32_equal() {
Reg[EAX].i = 0x0a0b0c0d;
Reg[EBX].i = 0x0a0b0c0d;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 39 d8 \n" // compare EAX and EBX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: compare r/m32 with EBX\n"
"run: r/m32 is EAX\n"
"run: SF=0; ZF=1; CF=0; OF=0\n"
);
}
//:: copy (mov)
:(before "End Initialize Op Names")
put_new(Name, "89", "copy r32 to rm32 (mov)");
:(code)
void test_copy_r32_to_r32() {
Reg[EBX].i = 0xaf;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 89 d8 \n" // copy EBX to EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: copy EBX to r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x000000af\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x89: { // copy r32 to r/m32
const uint8_t modrm = next();
const uint8_t rsrc = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "copy " << rname(rsrc) << " to r/m32" << end();
int32_t* dest = effective_address(modrm);
*dest = Reg[rsrc].i; // Write multiple elements of vector<uint8_t> at once. Assumes sizeof(int) == 4 on the host as well.
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *dest << end();
break;
}
//:: xchg
:(before "End Initialize Op Names")
put_new(Name, "87", "swap the contents of r32 and rm32 (xchg)");
:(code)
void test_xchg_r32_with_r32() {
Reg[EBX].i = 0xaf;
Reg[EAX].i = 0x2e;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 87 d8 \n" // exchange EBX with EAX
// ModR/M in binary: 11 (direct mode) 011 (src EBX) 000 (dest EAX)
);
CHECK_TRACE_CONTENTS(
"run: exchange EBX with r/m32\n"
"run: r/m32 is EAX\n"
"run: storing 0x000000af in r/m32\n"
"run: storing 0x0000002e in EBX\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x87: { // exchange r32 with r/m32
const uint8_t modrm = next();
const uint8_t reg2 = (modrm>>3)&0x7;
trace(Callstack_depth+1, "run") << "exchange " << rname(reg2) << " with r/m32" << end();
int32_t* arg1 = effective_address(modrm);
const int32_t tmp = *arg1;
*arg1 = Reg[reg2].i;
Reg[reg2].i = tmp;
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << *arg1 << " in r/m32" << end();
trace(Callstack_depth+1, "run") << "storing 0x" << HEXWORD << Reg[reg2].i << " in " << rname(reg2) << end();
break;
}
//:: increment
:(before "End Initialize Op Names")
put_new(Name, "40", "increment EAX (inc)");
put_new(Name, "41", "increment ECX (inc)");
put_new(Name, "42", "increment EDX (inc)");
put_new(Name, "43", "increment EBX (inc)");
put_new(Name, "44", "increment ESP (inc)");
put_new(Name, "45", "increment EBP (inc)");
put_new(Name, "46", "increment ESI (inc)");
put_new(Name, "47", "increment EDI (inc)");
:(code)
void test_increment_r32() {
Reg[ECX].u = 0x1f;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 41 \n" // increment ECX
);
CHECK_TRACE_CONTENTS(
"run: increment ECX\n"
"run: storing value 0x00000020\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x40:
case 0x41:
case 0x42:
case 0x43:
case 0x44:
case 0x45:
case 0x46:
case 0x47: { // increment r32
const uint8_t reg = op & 0x7;
trace(Callstack_depth+1, "run") << "increment " << rname(reg) << end();
++Reg[reg].u;
trace(Callstack_depth+1, "run") << "storing value 0x" << HEXWORD << Reg[reg].u << end();
break;
}
:(before "End Initialize Op Names")
put_new(Name, "ff", "increment/decrement/jump/push/call rm32 based on subop (inc/dec/jmp/push/call)");
:(code)
void test_increment_rm32() {
Reg[EAX].u = 0x20;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" ff c0 \n" // increment EAX
// ModR/M in binary: 11 (direct mode) 000 (subop inc) 000 (EAX)
);
CHECK_TRACE_CONTENTS(
"run: increment r/m32\n"
"run: r/m32 is EAX\n"
"run: storing value 0x00000021\n"
);
}
:(before "End Single-Byte Opcodes")
case 0xff: {
const uint8_t modrm = next();
const uint8_t subop = (modrm>>3)&0x7; // middle 3 'reg opcode' bits
switch (subop) {
case 0: { // increment r/m32
trace(Callstack_depth+1, "run") << "increment r/m32" << end();
int32_t* arg = effective_address(modrm);
++*arg;
trace(Callstack_depth+1, "run") << "storing value 0x" << HEXWORD << *arg << end();
break;
}
default:
cerr << "unrecognized subop for ff: " << HEXBYTE << NUM(subop) << '\n';
exit(1);
// End Op ff Subops
}
break;
}
//:: decrement
:(before "End Initialize Op Names")
put_new(Name, "48", "decrement EAX (dec)");
put_new(Name, "49", "decrement ECX (dec)");
put_new(Name, "4a", "decrement EDX (dec)");
put_new(Name, "4b", "decrement EBX (dec)");
put_new(Name, "4c", "decrement ESP (dec)");
put_new(Name, "4d", "decrement EBP (dec)");
put_new(Name, "4e", "decrement ESI (dec)");
put_new(Name, "4f", "decrement EDI (dec)");
:(code)
void test_decrement_r32() {
Reg[ECX].u = 0x1f;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 49 \n" // decrement ECX
);
CHECK_TRACE_CONTENTS(
"run: decrement ECX\n"
"run: storing value 0x0000001e\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x48:
case 0x49:
case 0x4a:
case 0x4b:
case 0x4c:
case 0x4d:
case 0x4e:
case 0x4f: { // decrement r32
const uint8_t reg = op & 0x7;
trace(Callstack_depth+1, "run") << "decrement " << rname(reg) << end();
--Reg[reg].u;
trace(Callstack_depth+1, "run") << "storing value 0x" << HEXWORD << Reg[reg].u << end();
break;
}
:(code)
void test_decrement_rm32() {
Reg[EAX].u = 0x20;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" ff c8 \n" // decrement EAX
// ModR/M in binary: 11 (direct mode) 001 (subop inc) 000 (EAX)
);
CHECK_TRACE_CONTENTS(
"run: decrement r/m32\n"
"run: r/m32 is EAX\n"
"run: storing value 0x0000001f\n"
);
}
:(before "End Op ff Subops")
case 1: { // decrement r/m32
trace(Callstack_depth+1, "run") << "decrement r/m32" << end();
int32_t* arg = effective_address(modrm);
--*arg;
trace(Callstack_depth+1, "run") << "storing value 0x" << HEXWORD << *arg << end();
break;
}
//:: push
:(before "End Initialize Op Names")
put_new(Name, "50", "push EAX to stack (push)");
put_new(Name, "51", "push ECX to stack (push)");
put_new(Name, "52", "push EDX to stack (push)");
put_new(Name, "53", "push EBX to stack (push)");
put_new(Name, "54", "push ESP to stack (push)");
put_new(Name, "55", "push EBP to stack (push)");
put_new(Name, "56", "push ESI to stack (push)");
put_new(Name, "57", "push EDI to stack (push)");
:(code)
void test_push_r32() {
Mem.push_back(vma(0xbd000000)); // manually allocate memory
Reg[ESP].u = 0xbd000008;
Reg[EBX].i = 0x0000000a;
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 53 \n" // push EBX to stack
);
CHECK_TRACE_CONTENTS(
"run: push EBX\n"
"run: decrementing ESP to 0xbd000004\n"
"run: pushing value 0x0000000a\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x50:
case 0x51:
case 0x52:
case 0x53:
case 0x54:
case 0x55:
case 0x56:
case 0x57: { // push r32 to stack
uint8_t reg = op & 0x7;
trace(Callstack_depth+1, "run") << "push " << rname(reg) << end();
//? cerr << "push: " << NUM(reg) << ": " << Reg[reg].u << " => " << Reg[ESP].u << '\n';
push(Reg[reg].u);
break;
}
//:: pop
:(before "End Initialize Op Names")
put_new(Name, "58", "pop top of stack to EAX (pop)");
put_new(Name, "59", "pop top of stack to ECX (pop)");
put_new(Name, "5a", "pop top of stack to EDX (pop)");
put_new(Name, "5b", "pop top of stack to EBX (pop)");
put_new(Name, "5c", "pop top of stack to ESP (pop)");
put_new(Name, "5d", "pop top of stack to EBP (pop)");
put_new(Name, "5e", "pop top of stack to ESI (pop)");
put_new(Name, "5f", "pop top of stack to EDI (pop)");
:(code)
void test_pop_r32() {
Mem.push_back(vma(0xbd000000)); // manually allocate memory
Reg[ESP].u = 0xbd000008;
write_mem_i32(0xbd000008, 0x0000000a); // ..before this write
run(
"== code 0x1\n" // code segment
// op ModR/M SIB displacement immediate
" 5b \n" // pop stack to EBX
"== data 0x2000\n" // data segment
"0a 00 00 00\n" // 0x0000000a
);
CHECK_TRACE_CONTENTS(
"run: pop into EBX\n"
"run: popping value 0x0000000a\n"
"run: incrementing ESP to 0xbd00000c\n"
);
}
:(before "End Single-Byte Opcodes")
case 0x58:
case 0x59:
case 0x5a:
case 0x5b:
case 0x5c:
case 0x5d:
case 0x5e:
case 0x5f: { // pop stack into r32
const uint8_t reg = op & 0x7;
trace(Callstack_depth+1, "run") << "pop into " << rname(reg) << end();
//? cerr << "pop from " << Reg[ESP].u << '\n';
Reg[reg].u = pop();
//? cerr << "=> " << NUM(reg) << ": " << Reg[reg].u << '\n';
break;
}
:(code)
uint32_t pop() {
const uint32_t result = read_mem_u32(Reg[ESP].u);
trace(Callstack_depth+1, "run") << "popping value 0x" << HEXWORD << result << end();
Reg[ESP].u += 4;
trace(Callstack_depth+1, "run") << "incrementing ESP to 0x" << HEXWORD << Reg[ESP].u << end();
assert(Reg[ESP].u < AFTER_STACK);
return result;
}