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//: operating directly on a register
:(scenario add_r32_to_r32)
% Reg[0].i = 0x10;
% Reg[3].i = 1;
# op ModR/M SIB displacement immediate
01 d8 # add EBX (reg 3) to EAX (reg 0)
+run: add reg 3 to effective address
+run: effective address is reg 0
+run: storing 0x00000011
:(before "End Single-Byte Opcodes")
case 0x01: { // add r32 to r/m32
uint8_t modrm = next();
uint8_t arg2 = (modrm>>3)&0x7;
trace(2, "run") << "add reg " << NUM(arg2) << " to effective address" << end();
int32_t* arg1 = effective_address(modrm);
BINARY_ARITHMETIC_OP(+, *arg1, Reg[arg2].i);
break;
}
:(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.
int32_t* effective_address(uint8_t modrm) {
uint8_t mod = (modrm>>6);
// ignore middle 3 'reg opcode' bits
uint8_t rm = modrm & 0x7;
int32_t* result = 0;
switch (mod) {
case 3:
// mod 3 is just register direct addressing
trace(2, "run") << "effective address is reg " << NUM(rm) << end();
result = &Reg[rm].i;
break;
// End Mod Special-cases
default:
cerr << "unrecognized mod bits: " << NUM(mod) << '\n';
exit(1);
}
return result;
}
//:: subtract
:(scenario subtract_r32_from_r32)
% Reg[0].i = 10;
% Reg[3].i = 1;
# op ModR/M SIB displacement immediate
29 d8 # subtract EBX (reg 3) from EAX (reg 0)
+run: subtract reg 3 from effective address
+run: effective address is reg 0
+run: storing 0x00000009
:(before "End Single-Byte Opcodes")
case 0x29: { // subtract r32 from r/m32
uint8_t modrm = next();
uint8_t arg2 = (modrm>>3)&0x7;
trace(2, "run") << "subtract reg " << NUM(arg2) << " from effective address" << end();
int32_t* arg1 = effective_address(modrm);
BINARY_ARITHMETIC_OP(-, *arg1, Reg[arg2].i);
break;
}
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