using X86Disassembler.X86.Operands;
namespace X86Disassembler.X86.Handlers.Cmp;
///
/// Handler for CMP r/m8, imm8 instruction (0x80 /7)
///
public class CmpImmWithRm8Handler : InstructionHandler
{
///
/// Initializes a new instance of the CmpImmWithRm8Handler class
///
/// The instruction decoder that owns this handler
public CmpImmWithRm8Handler(InstructionDecoder decoder)
: base(decoder)
{
}
///
/// Checks if this handler can decode the given opcode
///
/// The opcode to check
/// True if this handler can decode the opcode
public override bool CanHandle(byte opcode)
{
if (opcode != 0x80)
return false;
// Check if the reg field of the ModR/M byte is 7 (CMP)
if (!Decoder.CanReadByte())
return false;
var reg = ModRMDecoder.PeakModRMReg();
return reg == 7; // 7 = CMP
}
///
/// Decodes a CMP r/m8, imm8 instruction
///
/// The opcode of the instruction
/// The instruction object to populate
/// True if the instruction was successfully decoded
public override bool Decode(byte opcode, Instruction instruction)
{
// Set the instruction type
instruction.Type = InstructionType.Cmp;
// Read the ModR/M byte, specifying that we're dealing with 8-bit operands
var (_, _, _, destinationOperand) = ModRMDecoder.ReadModRM8();
// Note: The operand size is already set to 8-bit by the ReadModRM8 method
// Check if we have enough bytes for the immediate value
if (!Decoder.CanReadByte())
{
return false; // Not enough bytes for the immediate value
}
// Read the immediate byte
byte imm8 = Decoder.ReadByte();
// Create the source immediate operand
var sourceOperand = OperandFactory.CreateImmediateOperand(imm8, 8);
// Set the structured operands
instruction.StructuredOperands =
[
destinationOperand,
sourceOperand
];
return true;
}
}