ParkanPlayground/X86Disassembler/X86/Handlers/FloatingPoint/Float32OperationHandler.cs

using X86Disassembler.X86.Operands;

namespace X86Disassembler.X86.Handlers.FloatingPoint;

/// <summary>
/// Handler for floating-point operations on float32 (D8 opcode)
/// </summary>
public class Float32OperationHandler : InstructionHandler
{
    // D8 opcode - operations on float32
    private static readonly string[] Mnemonics =
    [
        "fadd",
        "fmul",
        "fcom",
        "fcomp",
        "fsub",
        "fsubr",
        "fdiv",
        "fdivr"
    ];

    // Corresponding instruction types for each mnemonic
    private static readonly InstructionType[] InstructionTypes =
    [
        InstructionType.Fadd,
        InstructionType.Fmul,
        InstructionType.Fcom,
        InstructionType.Fcomp,
        InstructionType.Fsub,
        InstructionType.Fsubr,
        InstructionType.Fdiv,
        InstructionType.Fdivr
    ];

    /// <summary>
    /// Initializes a new instance of the Float32OperationHandler class
    /// </summary>
    /// <param name="decoder">The instruction decoder that owns this handler</param>
    public Float32OperationHandler(InstructionDecoder decoder)
        : base(decoder)
    {
    }

    /// <summary>
    /// Checks if this handler can decode the given opcode
    /// </summary>
    /// <param name="opcode">The opcode to check</param>
    /// <returns>True if this handler can decode the opcode</returns>
    public override bool CanHandle(byte opcode)
    {
        return opcode == 0xD8;
    }

    /// <summary>
    /// Decodes a floating-point instruction for float32 operations
    /// </summary>
    /// <param name="opcode">The opcode of the instruction</param>
    /// <param name="instruction">The instruction object to populate</param>
    /// <returns>True if the instruction was successfully decoded</returns>
    public override bool Decode(byte opcode, Instruction instruction)
    {
        if (!Decoder.CanReadByte())
        {
            return false;
        }

        // Read the ModR/M byte
        var (mod, reg, rm, rawOperand) = ModRMDecoder.ReadModRM();

        // Set the instruction type based on the reg field
        instruction.Type = InstructionTypes[(int)reg];

        // For memory operands, set the operand
        if (mod != 3) // Memory operand
        {
            // Create a new memory operand with 32-bit size using the appropriate factory method
            Operand operand;
            
            if (rawOperand is DirectMemoryOperand directMemory)
            {
                operand = OperandFactory.CreateDirectMemoryOperand(directMemory.Address, 32);
            }
            else if (rawOperand is BaseRegisterMemoryOperand baseRegMemory)
            {
                operand = OperandFactory.CreateBaseRegisterMemoryOperand(baseRegMemory.BaseRegister, 32);
            }
            else if (rawOperand is DisplacementMemoryOperand dispMemory)
            {
                operand = OperandFactory.CreateDisplacementMemoryOperand(dispMemory.BaseRegister, dispMemory.Displacement, 32);
            }
            else if (rawOperand is ScaledIndexMemoryOperand scaledMemory)
            {
                operand = OperandFactory.CreateScaledIndexMemoryOperand(scaledMemory.IndexRegister, scaledMemory.Scale, scaledMemory.BaseRegister, scaledMemory.Displacement, 32);
            }
            else
            {
                operand = rawOperand;
            }
            
            // Set the structured operands
            instruction.StructuredOperands = 
            [
                operand
            ];
        }
        else // Register operand (ST(i))
        {
            // For register operands, we need to handle the stack registers
            var st0Operand = OperandFactory.CreateFPURegisterOperand(FpuRegisterIndex.ST0); // ST(0)
            var stiOperand = OperandFactory.CreateFPURegisterOperand((FpuRegisterIndex)rm); // ST(i)
            
            // Set the structured operands
            instruction.StructuredOperands = 
            [
                st0Operand,
                stiOperand
            ];
        }

        return true;
    }
}
Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00			`using X86Disassembler.X86.Operands;`

split float handlers 2025-04-12 23:24:42 +03:00			`namespace X86Disassembler.X86.Handlers.FloatingPoint;`

			`/// <summary>`
			`/// Handler for floating-point operations on float32 (D8 opcode)`
			`/// </summary>`
nice big refactor 2025-04-13 23:06:52 +03:00			`public class Float32OperationHandler : InstructionHandler`
split float handlers 2025-04-12 23:24:42 +03:00			`{`
			`// D8 opcode - operations on float32`
			`private static readonly string[] Mnemonics =`
			`[`
			`"fadd",`
			`"fmul",`
			`"fcom",`
			`"fcomp",`
			`"fsub",`
			`"fsubr",`
			`"fdiv",`
			`"fdivr"`
			`];`

Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00			`// Corresponding instruction types for each mnemonic`
			`private static readonly InstructionType[] InstructionTypes =`
			`[`
			`InstructionType.Fadd,`
			`InstructionType.Fmul,`
			`InstructionType.Fcom,`
			`InstructionType.Fcomp,`
			`InstructionType.Fsub,`
			`InstructionType.Fsubr,`
			`InstructionType.Fdiv,`
			`InstructionType.Fdivr`
			`];`

split float handlers 2025-04-12 23:24:42 +03:00			`/// <summary>`
			`/// Initializes a new instance of the Float32OperationHandler class`
			`/// </summary>`
			`/// <param name="decoder">The instruction decoder that owns this handler</param>`
Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00			`public Float32OperationHandler(InstructionDecoder decoder)`
			`: base(decoder)`
split float handlers 2025-04-12 23:24:42 +03:00			`{`
			`}`

			`/// <summary>`
			`/// Checks if this handler can decode the given opcode`
			`/// </summary>`
			`/// <param name="opcode">The opcode to check</param>`
			`/// <returns>True if this handler can decode the opcode</returns>`
			`public override bool CanHandle(byte opcode)`
			`{`
			`return opcode == 0xD8;`
			`}`

			`/// <summary>`
			`/// Decodes a floating-point instruction for float32 operations`
			`/// </summary>`
			`/// <param name="opcode">The opcode of the instruction</param>`
			`/// <param name="instruction">The instruction object to populate</param>`
			`/// <returns>True if the instruction was successfully decoded</returns>`
			`public override bool Decode(byte opcode, Instruction instruction)`
			`{`
more refactoring 2025-04-14 01:08:14 +03:00			`if (!Decoder.CanReadByte())`
split float handlers 2025-04-12 23:24:42 +03:00			`{`
			`return false;`
			`}`

			`// Read the ModR/M byte`
Test fixes 2025-04-16 18:30:17 +03:00			`var (mod, reg, rm, rawOperand) = ModRMDecoder.ReadModRM();`
split float handlers 2025-04-12 23:24:42 +03:00
Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00			`// Set the instruction type based on the reg field`
			`instruction.Type = InstructionTypes[(int)reg];`
split float handlers 2025-04-12 23:24:42 +03:00
			`// For memory operands, set the operand`
			`if (mod != 3) // Memory operand`
			`{`
Test fixes 2025-04-16 18:30:17 +03:00			`// Create a new memory operand with 32-bit size using the appropriate factory method`
			`Operand operand;`

			`if (rawOperand is DirectMemoryOperand directMemory)`
			`{`
			`operand = OperandFactory.CreateDirectMemoryOperand(directMemory.Address, 32);`
			`}`
			`else if (rawOperand is BaseRegisterMemoryOperand baseRegMemory)`
			`{`
			`operand = OperandFactory.CreateBaseRegisterMemoryOperand(baseRegMemory.BaseRegister, 32);`
			`}`
			`else if (rawOperand is DisplacementMemoryOperand dispMemory)`
			`{`
			`operand = OperandFactory.CreateDisplacementMemoryOperand(dispMemory.BaseRegister, dispMemory.Displacement, 32);`
			`}`
			`else if (rawOperand is ScaledIndexMemoryOperand scaledMemory)`
			`{`
			`operand = OperandFactory.CreateScaledIndexMemoryOperand(scaledMemory.IndexRegister, scaledMemory.Scale, scaledMemory.BaseRegister, scaledMemory.Displacement, 32);`
			`}`
			`else`
			`{`
			`operand = rawOperand;`
			`}`
Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00
			`// Set the structured operands`
			`instruction.StructuredOperands =`
			`[`
			`operand`
			`];`
split float handlers 2025-04-12 23:24:42 +03:00			`}`
			`else // Register operand (ST(i))`
			`{`
			`// For register operands, we need to handle the stack registers`
Updated instruction handlers to use Type and StructuredOperands instead of Mnemonic and Operands 2025-04-14 22:08:50 +03:00			`var st0Operand = OperandFactory.CreateFPURegisterOperand(FpuRegisterIndex.ST0); // ST(0)`
			`var stiOperand = OperandFactory.CreateFPURegisterOperand((FpuRegisterIndex)rm); // ST(i)`

			`// Set the structured operands`
			`instruction.StructuredOperands =`
			`[`
			`st0Operand,`
			`stiOperand`
			`];`
split float handlers 2025-04-12 23:24:42 +03:00			`}`

			`return true;`
			`}`
			`}`