ParkanPlayground/X86DisassemblerTests/InstructionTests/XorInstructionTests.cs

using X86Disassembler.X86;
using X86Disassembler.X86.Operands;

namespace X86DisassemblerTests.InstructionTests;

/// <summary>
/// Tests for XOR instruction handlers
/// </summary>
public class XorInstructionTests
{
    /// <summary>
    /// Tests the XorRegMemHandler for decoding XOR r32, r/m32 instruction
    /// </summary>
    [Fact]
    public void XorRegMemHandler_DecodesXorR32Rm32_Correctly()
    {
        // Arrange
        // XOR EAX, ECX (33 C1) - ModR/M byte C1 = 11 000 001 (mod=3, reg=0, rm=1)
        // mod=3 means direct register addressing, reg=0 is EAX, rm=1 is ECX
        byte[] codeBuffer = new byte[] { 0x33, 0xC1 };
        var disassembler = new Disassembler(codeBuffer, 0);
        
        // Act
        var instructions = disassembler.Disassemble();
        
        // Assert
        Assert.Single(instructions);
        var instruction = instructions[0];
        Assert.NotNull(instruction);
        Assert.Equal(InstructionType.Xor, instruction.Type);
        
        // Check that we have two operands
        Assert.Equal(2, instruction.StructuredOperands.Count);
        
        // Check the first operand (EAX)
        var eaxOperand = instruction.StructuredOperands[0];
        Assert.IsType<RegisterOperand>(eaxOperand);
        var registerOperand1 = (RegisterOperand)eaxOperand;
        Assert.Equal(RegisterIndex.A, registerOperand1.Register);
        Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (EAX)
        
        // Check the second operand (ECX)
        var ecxOperand = instruction.StructuredOperands[1];
        Assert.IsType<RegisterOperand>(ecxOperand);
        var registerOperand2 = (RegisterOperand)ecxOperand;
        Assert.Equal(RegisterIndex.C, registerOperand2.Register);
        Assert.Equal(32, registerOperand2.Size); // Validate that it's a 32-bit register (ECX)
    }
    
    /// <summary>
    /// Tests the XorMemRegHandler for decoding XOR r/m32, r32 instruction
    /// </summary>
    [Fact]
    public void XorMemRegHandler_DecodesXorRm32R32_Correctly()
    {
        // Arrange
        // XOR ECX, EAX (31 C1) - ModR/M byte C1 = 11 000 001 (mod=3, reg=0, rm=1)
        // mod=3 means direct register addressing, reg=0 is EAX, rm=1 is ECX
        byte[] codeBuffer = new byte[] { 0x31, 0xC1 };
        var disassembler = new Disassembler(codeBuffer, 0);
        
        // Act
        var instructions = disassembler.Disassemble();
        
        // Assert
        Assert.Single(instructions);
        var instruction = instructions[0];
        Assert.NotNull(instruction);
        Assert.Equal(InstructionType.Xor, instruction.Type);
        
        // Check that we have two operands
        Assert.Equal(2, instruction.StructuredOperands.Count);
        
        // Check the first operand (ECX)
        var ecxOperand = instruction.StructuredOperands[0];
        Assert.IsType<RegisterOperand>(ecxOperand);
        var registerOperand1 = (RegisterOperand)ecxOperand;
        Assert.Equal(RegisterIndex.C, registerOperand1.Register);
        Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (ECX)
        
        // Check the second operand (EAX)
        var eaxOperand = instruction.StructuredOperands[1];
        Assert.IsType<RegisterOperand>(eaxOperand);
        var registerOperand2 = (RegisterOperand)eaxOperand;
        Assert.Equal(RegisterIndex.A, registerOperand2.Register);
        Assert.Equal(32, registerOperand2.Size); // Validate that it's a 32-bit register (EAX)
    }
    
    /// <summary>
    /// Tests the XorAlImmHandler for decoding XOR AL, imm8 instruction
    /// </summary>
    [Fact]
    public void XorAlImmHandler_DecodesXorAlImm8_Correctly()
    {
        // Arrange
        // XOR AL, 0x42 (34 42)
        byte[] codeBuffer = new byte[] { 0x34, 0x42 };
        var disassembler = new Disassembler(codeBuffer, 0);
        
        // Act
        var instructions = disassembler.Disassemble();
        
        // Assert
        Assert.Single(instructions);
        var instruction = instructions[0];
        Assert.NotNull(instruction);
        Assert.Equal(InstructionType.Xor, instruction.Type);
        
        // Check that we have two operands
        Assert.Equal(2, instruction.StructuredOperands.Count);
        
        // Check the first operand (AL)
        var alOperand = instruction.StructuredOperands[0];
        Assert.IsType<RegisterOperand>(alOperand);
        var registerOperand = (RegisterOperand)alOperand;
        Assert.Equal(RegisterIndex.A, registerOperand.Register);
        Assert.Equal(8, registerOperand.Size); // Validate that it's an 8-bit register (AL)
        
        // Check the second operand (immediate value)
        var immOperand = instruction.StructuredOperands[1];
        Assert.IsType<ImmediateOperand>(immOperand);
        var immediateOperand = (ImmediateOperand)immOperand;
        Assert.Equal(0x42U, immediateOperand.Value);
        Assert.Equal(8, immediateOperand.Size); // Validate that it's an 8-bit immediate
    }
    
    /// <summary>
    /// Tests the XorEaxImmHandler for decoding XOR EAX, imm32 instruction
    /// </summary>
    [Fact]
    public void XorEaxImmHandler_DecodesXorEaxImm32_Correctly()
    {
        // Arrange
        // XOR EAX, 0x12345678 (35 78 56 34 12)
        byte[] codeBuffer = new byte[] { 0x35, 0x78, 0x56, 0x34, 0x12 };
        var disassembler = new Disassembler(codeBuffer, 0);
        
        // Act
        var instructions = disassembler.Disassemble();
        
        // Assert
        Assert.Single(instructions);
        var instruction = instructions[0];
        Assert.NotNull(instruction);
        Assert.Equal(InstructionType.Xor, instruction.Type);
        
        // Check that we have two operands
        Assert.Equal(2, instruction.StructuredOperands.Count);
        
        // Check the first operand (EAX)
        var eaxOperand = instruction.StructuredOperands[0];
        Assert.IsType<RegisterOperand>(eaxOperand);
        var registerOperand1 = (RegisterOperand)eaxOperand;
        Assert.Equal(RegisterIndex.A, registerOperand1.Register);
        Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (EAX)
        
        // Check the second operand (0x12345678)
        var immOperand = instruction.StructuredOperands[1];
        Assert.IsType<ImmediateOperand>(immOperand);
        var immediateOperand = (ImmediateOperand)immOperand;
        Assert.Equal(0x12345678U, immediateOperand.Value);
        Assert.Equal(32, immediateOperand.Size); // Validate that it's a 32-bit immediate
    }
}
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`using X86Disassembler.X86;`
unbreak tests 2025-04-14 23:08:52 +03:00			`using X86Disassembler.X86.Operands;`
Fixed immediate value formatting in Group1 instruction handlers 2025-04-13 16:00:46 +03:00
			`namespace X86DisassemblerTests.InstructionTests;`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`/// <summary>`
			`/// Tests for XOR instruction handlers`
			`/// </summary>`
			`public class XorInstructionTests`
			`{`
			`/// <summary>`
			`/// Tests the XorRegMemHandler for decoding XOR r32, r/m32 instruction`
			`/// </summary>`
			`[Fact]`
			`public void XorRegMemHandler_DecodesXorR32Rm32_Correctly()`
			`{`
			`// Arrange`
			`// XOR EAX, ECX (33 C1) - ModR/M byte C1 = 11 000 001 (mod=3, reg=0, rm=1)`
			`// mod=3 means direct register addressing, reg=0 is EAX, rm=1 is ECX`
			`byte[] codeBuffer = new byte[] { 0x33, 0xC1 };`
unbreak tests 2025-04-14 23:08:52 +03:00			`var disassembler = new Disassembler(codeBuffer, 0);`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Act`
unbreak tests 2025-04-14 23:08:52 +03:00			`var instructions = disassembler.Disassemble();`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Assert`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Single(instructions);`
			`var instruction = instructions[0];`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`Assert.NotNull(instruction);`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Equal(InstructionType.Xor, instruction.Type);`

			`// Check that we have two operands`
			`Assert.Equal(2, instruction.StructuredOperands.Count);`

			`// Check the first operand (EAX)`
			`var eaxOperand = instruction.StructuredOperands[0];`
			`Assert.IsType<RegisterOperand>(eaxOperand);`
			`var registerOperand1 = (RegisterOperand)eaxOperand;`
			`Assert.Equal(RegisterIndex.A, registerOperand1.Register);`
			`Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (EAX)`

			`// Check the second operand (ECX)`
			`var ecxOperand = instruction.StructuredOperands[1];`
			`Assert.IsType<RegisterOperand>(ecxOperand);`
			`var registerOperand2 = (RegisterOperand)ecxOperand;`
			`Assert.Equal(RegisterIndex.C, registerOperand2.Register);`
			`Assert.Equal(32, registerOperand2.Size); // Validate that it's a 32-bit register (ECX)`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`}`

			`/// <summary>`
			`/// Tests the XorMemRegHandler for decoding XOR r/m32, r32 instruction`
			`/// </summary>`
			`[Fact]`
			`public void XorMemRegHandler_DecodesXorRm32R32_Correctly()`
			`{`
			`// Arrange`
			`// XOR ECX, EAX (31 C1) - ModR/M byte C1 = 11 000 001 (mod=3, reg=0, rm=1)`
			`// mod=3 means direct register addressing, reg=0 is EAX, rm=1 is ECX`
			`byte[] codeBuffer = new byte[] { 0x31, 0xC1 };`
unbreak tests 2025-04-14 23:08:52 +03:00			`var disassembler = new Disassembler(codeBuffer, 0);`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Act`
unbreak tests 2025-04-14 23:08:52 +03:00			`var instructions = disassembler.Disassemble();`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Assert`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Single(instructions);`
			`var instruction = instructions[0];`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`Assert.NotNull(instruction);`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Equal(InstructionType.Xor, instruction.Type);`

			`// Check that we have two operands`
			`Assert.Equal(2, instruction.StructuredOperands.Count);`

			`// Check the first operand (ECX)`
			`var ecxOperand = instruction.StructuredOperands[0];`
			`Assert.IsType<RegisterOperand>(ecxOperand);`
			`var registerOperand1 = (RegisterOperand)ecxOperand;`
			`Assert.Equal(RegisterIndex.C, registerOperand1.Register);`
			`Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (ECX)`

			`// Check the second operand (EAX)`
			`var eaxOperand = instruction.StructuredOperands[1];`
			`Assert.IsType<RegisterOperand>(eaxOperand);`
			`var registerOperand2 = (RegisterOperand)eaxOperand;`
			`Assert.Equal(RegisterIndex.A, registerOperand2.Register);`
			`Assert.Equal(32, registerOperand2.Size); // Validate that it's a 32-bit register (EAX)`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`}`

			`/// <summary>`
			`/// Tests the XorAlImmHandler for decoding XOR AL, imm8 instruction`
			`/// </summary>`
			`[Fact]`
			`public void XorAlImmHandler_DecodesXorAlImm8_Correctly()`
			`{`
			`// Arrange`
			`// XOR AL, 0x42 (34 42)`
			`byte[] codeBuffer = new byte[] { 0x34, 0x42 };`
unbreak tests 2025-04-14 23:08:52 +03:00			`var disassembler = new Disassembler(codeBuffer, 0);`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Act`
unbreak tests 2025-04-14 23:08:52 +03:00			`var instructions = disassembler.Disassemble();`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Assert`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Single(instructions);`
			`var instruction = instructions[0];`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`Assert.NotNull(instruction);`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Equal(InstructionType.Xor, instruction.Type);`

			`// Check that we have two operands`
			`Assert.Equal(2, instruction.StructuredOperands.Count);`

			`// Check the first operand (AL)`
			`var alOperand = instruction.StructuredOperands[0];`
			`Assert.IsType<RegisterOperand>(alOperand);`
			`var registerOperand = (RegisterOperand)alOperand;`
			`Assert.Equal(RegisterIndex.A, registerOperand.Register);`
			`Assert.Equal(8, registerOperand.Size); // Validate that it's an 8-bit register (AL)`

			`// Check the second operand (immediate value)`
			`var immOperand = instruction.StructuredOperands[1];`
			`Assert.IsType<ImmediateOperand>(immOperand);`
			`var immediateOperand = (ImmediateOperand)immOperand;`
			`Assert.Equal(0x42U, immediateOperand.Value);`
			`Assert.Equal(8, immediateOperand.Size); // Validate that it's an 8-bit immediate`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`}`

			`/// <summary>`
			`/// Tests the XorEaxImmHandler for decoding XOR EAX, imm32 instruction`
			`/// </summary>`
			`[Fact]`
			`public void XorEaxImmHandler_DecodesXorEaxImm32_Correctly()`
			`{`
			`// Arrange`
			`// XOR EAX, 0x12345678 (35 78 56 34 12)`
			`byte[] codeBuffer = new byte[] { 0x35, 0x78, 0x56, 0x34, 0x12 };`
unbreak tests 2025-04-14 23:08:52 +03:00			`var disassembler = new Disassembler(codeBuffer, 0);`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Act`
unbreak tests 2025-04-14 23:08:52 +03:00			`var instructions = disassembler.Disassemble();`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00
			`// Assert`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Single(instructions);`
			`var instruction = instructions[0];`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`Assert.NotNull(instruction);`
unbreak tests 2025-04-14 23:08:52 +03:00			`Assert.Equal(InstructionType.Xor, instruction.Type);`

			`// Check that we have two operands`
			`Assert.Equal(2, instruction.StructuredOperands.Count);`

			`// Check the first operand (EAX)`
			`var eaxOperand = instruction.StructuredOperands[0];`
			`Assert.IsType<RegisterOperand>(eaxOperand);`
			`var registerOperand1 = (RegisterOperand)eaxOperand;`
			`Assert.Equal(RegisterIndex.A, registerOperand1.Register);`
			`Assert.Equal(32, registerOperand1.Size); // Validate that it's a 32-bit register (EAX)`

			`// Check the second operand (0x12345678)`
			`var immOperand = instruction.StructuredOperands[1];`
			`Assert.IsType<ImmediateOperand>(immOperand);`
			`var immediateOperand = (ImmediateOperand)immOperand;`
			`Assert.Equal(0x12345678U, immediateOperand.Value);`
			`Assert.Equal(32, immediateOperand.Size); // Validate that it's a 32-bit immediate`
Added comprehensive tests for various instruction handlers. Created test files for Jump, Return, XOR, Group1, Group3, and Call instructions. Fixed ConditionalJumpHandler test to use 'jz' instead of 'je' since they are equivalent in x86. 2025-04-12 21:38:47 +03:00			`}`
			`}`