namespace X86Disassembler.X86.Handlers.Add; ///

/// Handler for ADD r/m32, imm8 (sign-extended) instruction (0x83 /0) ///

public class AddImmToRm32SignExtendedHandler : InstructionHandler { ///

/// Initializes a new instance of the AddImmToRm32SignExtendedHandler class ///

/// The buffer containing the code to decode /// The instruction decoder that owns this handler /// The length of the buffer public AddImmToRm32SignExtendedHandler(byte[] codeBuffer, InstructionDecoder decoder, int length) : base(codeBuffer, decoder, length) { } ///

/// 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 != 0x83) return false; // Check if the reg field of the ModR/M byte is 0 (ADD) int position = Decoder.GetPosition(); if (!Decoder.CanReadByte()) return false; byte modRM = CodeBuffer[position]; byte reg = (byte) ((modRM & 0x38) >> 3); return reg == 0; // 0 = ADD } ///

/// Decodes an ADD r/m32, imm8 (sign-extended) 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 mnemonic instruction.Mnemonic = "add"; if (!Decoder.CanReadByte()) { return false; } // Read the ModR/M byte var (mod, reg, rm, destOperand) = ModRMDecoder.ReadModRM(); // Check if we have enough bytes for the immediate value if (!Decoder.CanReadByte()) { return false; } // Read the immediate value as a signed byte and automatically sign-extend it to int int imm = (sbyte) Decoder.ReadByte(); // Format the immediate value string immStr; if (imm < 0) { // For negative values, use the full 32-bit representation (0xFFFFFFxx) immStr = $"0x{(uint) imm:X8}"; } else { // For positive values, use the regular format with leading zeros immStr = $"0x{imm:X8}"; } // Set the operands instruction.Operands = $"{destOperand}, {immStr}"; return true; } }