vb6parse 1.0.0

//! # Sin Function
//!
//! Returns a Double specifying the sine of an angle.
//!
//! ## Syntax
//!
//! ```vb
//! Sin(number)
//! ```
//!
//! ## Parameters
//!
//! - `number` - Required. Double or any valid numeric expression that expresses an angle in radians.
//!
//! ## Return Value
//!
//! Returns a Double value representing the sine of the angle:
//! - Range: -1 to 1 (inclusive)
//! - Sin(0) = 0
//! - Sin(π/2) ≈ 1
//! - Sin(π) ≈ 0
//! - Sin(3π/2) ≈ -1
//!
//! ## Remarks
//!
//! The Sin function takes an angle in radians and returns the ratio of two sides of a right triangle. The ratio is the length of the side opposite the angle divided by the length of the hypotenuse.
//!
//! Key characteristics:
//! - Input is in radians, not degrees
//! - To convert degrees to radians: radians = degrees × (π / 180)
//! - To convert radians to degrees: degrees = radians × (180 / π)
//! - π (Pi) ≈ 3.14159265358979
//! - Use `Atn(1) * 4` to calculate π in VB6
//! - Periodic function: Sin(x) = Sin(x + 2π)
//! - Returns values between -1 and 1
//!
//! The sine function is one of the fundamental trigonometric functions:
//! - Sin(x): Sine (this function)
//! - Cos(x): Cosine (use Cos function)
//! - Tan(x): Tangent (use Tan function or Sin(x)/Cos(x))
//!
//! Common angles and their sines:
//! - Sin(0°) = Sin(0 rad) = 0
//! - Sin(30°) = Sin(π/6 rad) = 0.5
//! - Sin(45°) = Sin(π/4 rad) ≈ 0.707
//! - Sin(60°) = Sin(π/3 rad) ≈ 0.866
//! - Sin(90°) = Sin(π/2 rad) = 1
//! - Sin(180°) = Sin(π rad) = 0
//! - Sin(270°) = Sin(3π/2 rad) = -1
//! - Sin(360°) = Sin(2π rad) = 0
//!
//! ## Typical Uses
//!
//! 1. **Wave Generation**: Create sine waves for animations or signals
//! 2. **Circular Motion**: Calculate vertical position in circular paths
//! 3. **Oscillations**: Model periodic oscillating systems
//! 4. **Physics Simulations**: Projectile motion, pendulum swing
//! 5. **Graphics**: Rotation, transformation, curve drawing
//! 6. **Audio Processing**: Sine wave tone generation
//! 7. **Engineering Calculations**: Structural analysis, AC circuits
//! 8. **Game Development**: Movement patterns, trajectories
//!
//! ## Basic Examples
//!
//! ```vb
//! ' Example 1: Calculate sine of 45 degrees
//! Const PI As Double = 3.14159265358979
//! Dim angle45 As Double
//! Dim sineValue As Double
//!
//! angle45 = 45 * (PI / 180)  ' Convert to radians
//! sineValue = Sin(angle45)   ' Returns ≈ 0.707
//! ```
//!
//! ```vb
//! ' Example 2: Calculate sine of π/2 (90 degrees)
//! Const PI As Double = 3.14159265358979
//! Dim result As Double
//! result = Sin(PI / 2)  ' Returns 1
//! ```
//!
//! ```vb
//! ' Example 3: Use with Atn to calculate π
//! Dim pi As Double
//! Dim sineValue As Double
//! pi = Atn(1) * 4
//! sineValue = Sin(pi)  ' Returns ≈ 0 (very small number)
//! ```
//!
//! ```vb
//! ' Example 4: Sine wave generation
//! Dim i As Integer
//! Dim y As Double
//! For i = 0 To 360
//!     y = Sin(i * (Atn(1) * 4) / 180)
//!     Debug.Print i & " degrees: " & y
//! Next i
//! ```
//!
//! ## Common Patterns
//!
//! ### Pattern 1: `DegreesToRadians`
//! Convert degrees to radians for Sin function
//! ```vb
//! Function DegreesToRadians(degrees As Double) As Double
//!     Const PI As Double = 3.14159265358979
//!     DegreesToRadians = degrees * (PI / 180)
//! End Function
//!
//! ' Usage:
//! result = Sin(DegreesToRadians(45))
//! ```
//!
//! ### Pattern 2: `SinDegrees`
//! Sine function that accepts degrees
//! ```vb
//! Function SinDegrees(degrees As Double) As Double
//!     Const PI As Double = 3.14159265358979
//!     SinDegrees = Sin(degrees * (PI / 180))
//! End Function
//! ```
//!
//! ### Pattern 3: `GenerateSineWave`
//! Generate array of sine wave values
//! ```vb
//! Function GenerateSineWave(samples As Integer, amplitude As Double, _
//!                           frequency As Double) As Double()
//!     Dim result() As Double
//!     Dim i As Integer
//!     Dim angle As Double
//!     Const PI As Double = 3.14159265358979
//!     
//!     ReDim result(0 To samples - 1)
//!     
//!     For i = 0 To samples - 1
//!         angle = (i / samples) * 2 * PI * frequency
//!         result(i) = amplitude * Sin(angle)
//!     Next i
//!     
//!     GenerateSineWave = result
//! End Function
//! ```
//!
//! ### Pattern 4: `CircularMotionY`
//! Calculate vertical position in circular motion
//! ```vb
//! Function CircularMotionY(centerY As Double, radius As Double, _
//!                          angle As Double) As Double
//!     ' angle in radians
//!     CircularMotionY = centerY + radius * Sin(angle)
//! End Function
//! ```
//!
//! ### Pattern 5: `OscillatingValue`
//! Create oscillating value over time
//! ```vb
//! Function OscillatingValue(time As Double, amplitude As Double, _
//!                           frequency As Double, Optional phase As Double = 0) As Double
//!     Const PI As Double = 3.14159265358979
//!     OscillatingValue = amplitude * Sin(2 * PI * frequency * time + phase)
//! End Function
//! ```
//!
//! ### Pattern 6: `SineInterpolation`
//! Smooth interpolation using sine
//! ```vb
//! Function SineInterpolation(startValue As Double, endValue As Double, _
//!                            t As Double) As Double
//!     ' t ranges from 0 to 1
//!     Dim factor As Double
//!     Const PI As Double = 3.14159265358979
//!     
//!     factor = (1 - Cos(t * PI)) / 2
//!     SineInterpolation = startValue + (endValue - startValue) * factor
//! End Function
//! ```
//!
//! ### Pattern 7: `AngleFromSine`
//! Get angle from sine value (inverse sine approximation)
//! ```vb
//! Function ArcSineApprox(sineValue As Double) As Double
//!     ' For small angles, asin(x) ≈ x
//!     ' For better accuracy, use iterative methods or Atn
//!     ' Using Atn for proper arcsin:
//!     If Abs(sineValue) >= 1 Then
//!         ArcSineApprox = Sgn(sineValue) * Atn(1) * 2
//!     Else
//!         ArcSineApprox = Atn(sineValue / Sqr(1 - sineValue * sineValue))
//!     End If
//! End Function
//! ```
//!
//! ### Pattern 8: `SineWaveAnalysis`
//! Analyze sine wave properties
//! ```vb
//! Sub AnalyzeSineWave(amplitude As Double, frequency As Double, _
//!                     ByRef maxVal As Double, ByRef minVal As Double, _
//!                     ByRef period As Double)
//!     Const PI As Double = 3.14159265358979
//!     
//!     maxVal = amplitude
//!     minVal = -amplitude
//!     period = 1 / frequency  ' In seconds or time units
//! End Sub
//! ```
//!
//! ### Pattern 9: `ProjectileMotionY`
//! Calculate vertical position in projectile motion
//! ```vb
//! Function ProjectileY(initialY As Double, velocity As Double, _
//!                      angle As Double, time As Double, gravity As Double) As Double
//!     ' angle in radians
//!     Dim verticalVelocity As Double
//!     
//!     verticalVelocity = velocity * Sin(angle)
//!     ProjectileY = initialY + verticalVelocity * time - 0.5 * gravity * time * time
//! End Function
//! ```
//!
//! ### Pattern 10: `HarmonicMotion`
//! Simple harmonic motion displacement
//! ```vb
//! Function HarmonicDisplacement(amplitude As Double, angularFrequency As Double, _
//!                               time As Double, Optional phase As Double = 0) As Double
//!     HarmonicDisplacement = amplitude * Sin(angularFrequency * time + phase)
//! End Function
//! ```
//!
//! ## Advanced Usage
//!
//! ### Example 1: `WaveformGenerator` Class
//! Generate various waveforms using sine function
//! ```vb
//! ' Class: WaveformGenerator
//! Private Const PI As Double = 3.14159265358979
//! Private m_sampleRate As Long
//! Private m_duration As Double
//!
//! Public Sub Initialize(sampleRate As Long, duration As Double)
//!     m_sampleRate = sampleRate
//!     m_duration = duration
//! End Sub
//!
//! Public Function GenerateSineWave(frequency As Double, amplitude As Double) As Double()
//!     Dim samples As Long
//!     Dim result() As Double
//!     Dim i As Long
//!     Dim t As Double
//!     
//!     samples = CLng(m_sampleRate * m_duration)
//!     ReDim result(0 To samples - 1)
//!     
//!     For i = 0 To samples - 1
//!         t = i / m_sampleRate
//!         result(i) = amplitude * Sin(2 * PI * frequency * t)
//!     Next i
//!     
//!     GenerateSineWave = result
//! End Function
//!
//! Public Function GenerateAMWave(carrier As Double, modulator As Double, _
//!                                amplitude As Double, modDepth As Double) As Double()
//!     ' Amplitude Modulation
//!     Dim samples As Long
//!     Dim result() As Double
//!     Dim i As Long
//!     Dim t As Double
//!     Dim envelope As Double
//!     
//!     samples = CLng(m_sampleRate * m_duration)
//!     ReDim result(0 To samples - 1)
//!     
//!     For i = 0 To samples - 1
//!         t = i / m_sampleRate
//!         envelope = 1 + modDepth * Sin(2 * PI * modulator * t)
//!         result(i) = amplitude * envelope * Sin(2 * PI * carrier * t)
//!     Next i
//!     
//!     GenerateAMWave = result
//! End Function
//!
//! Public Function GenerateFMWave(carrier As Double, modulator As Double, _
//!                                amplitude As Double, modIndex As Double) As Double()
//!     ' Frequency Modulation
//!     Dim samples As Long
//!     Dim result() As Double
//!     Dim i As Long
//!     Dim t As Double
//!     Dim phase As Double
//!     
//!     samples = CLng(m_sampleRate * m_duration)
//!     ReDim result(0 To samples - 1)
//!     
//!     For i = 0 To samples - 1
//!         t = i / m_sampleRate
//!         phase = 2 * PI * carrier * t + modIndex * Sin(2 * PI * modulator * t)
//!         result(i) = amplitude * Sin(phase)
//!     Next i
//!     
//!     GenerateFMWave = result
//! End Function
//!
//! Public Function GenerateHarmonics(fundamental As Double, harmonics As Integer, _
//!                                   amplitude As Double) As Double()
//!     ' Generate complex tone with harmonics
//!     Dim samples As Long
//!     Dim result() As Double
//!     Dim i As Long
//!     Dim h As Integer
//!     Dim t As Double
//!     Dim value As Double
//!     
//!     samples = CLng(m_sampleRate * m_duration)
//!     ReDim result(0 To samples - 1)
//!     
//!     For i = 0 To samples - 1
//!         t = i / m_sampleRate
//!         value = 0
//!         
//!         For h = 1 To harmonics
//!             value = value + (amplitude / h) * Sin(2 * PI * fundamental * h * t)
//!         Next h
//!         
//!         result(i) = value
//!     Next i
//!     
//!     GenerateHarmonics = result
//! End Function
//! ```
//!
//! ### Example 2: `CircularMotion` Module
//! Calculate circular and elliptical motion using trigonometry
//! ```vb
//! ' Module: CircularMotion
//! Private Const PI As Double = 3.14159265358979
//!
//! Public Sub GetCircularPosition(centerX As Double, centerY As Double, _
//!                                radius As Double, angle As Double, _
//!                                ByRef x As Double, ByRef y As Double)
//!     ' angle in radians
//!     x = centerX + radius * Cos(angle)
//!     y = centerY + radius * Sin(angle)
//! End Sub
//!
//! Public Sub GetEllipticalPosition(centerX As Double, centerY As Double, _
//!                                  radiusX As Double, radiusY As Double, _
//!                                  angle As Double, ByRef x As Double, ByRef y As Double)
//!     ' angle in radians
//!     x = centerX + radiusX * Cos(angle)
//!     y = centerY + radiusY * Sin(angle)
//! End Sub
//!
//! Public Function CalculateAngularVelocity(rpm As Double) As Double
//!     ' Convert revolutions per minute to radians per second
//!     CalculateAngularVelocity = (rpm / 60) * 2 * PI
//! End Function
//!
//! Public Sub AnimateCircularMotion(centerX As Double, centerY As Double, _
//!                                  radius As Double, angularVelocity As Double, _
//!                                  time As Double, ByRef x As Double, ByRef y As Double)
//!     Dim angle As Double
//!     angle = angularVelocity * time
//!     
//!     x = centerX + radius * Cos(angle)
//!     y = centerY + radius * Sin(angle)
//! End Sub
//!
//! Public Function CalculateTangentialVelocity(radius As Double, _
//!                                             angularVelocity As Double) As Double
//!     ' v = r * ω
//!     CalculateTangentialVelocity = radius * angularVelocity
//! End Function
//!
//! Public Sub GetVelocityComponents(speed As Double, angle As Double, _
//!                                  ByRef vx As Double, ByRef vy As Double)
//!     ' angle in radians from horizontal
//!     vx = speed * Cos(angle)
//!     vy = speed * Sin(angle)
//! End Sub
//! ```
//!
//! ### Example 3: `PhysicsSimulator` Class
//! Simulate physics using trigonometric functions
//! ```vb
//! ' Class: PhysicsSimulator
//! Private Const PI As Double = 3.14159265358979
//! Private Const GRAVITY As Double = 9.81  ' m/s²
//!
//! Public Function CalculateRange(velocity As Double, angle As Double) As Double
//!     ' Projectile range formula: R = v² * sin(2θ) / g
//!     ' angle in radians
//!     CalculateRange = (velocity * velocity * Sin(2 * angle)) / GRAVITY
//! End Function
//!
//! Public Function CalculateMaxHeight(velocity As Double, angle As Double) As Double
//!     ' Max height: H = (v * sin(θ))² / (2g)
//!     Dim verticalVelocity As Double
//!     verticalVelocity = velocity * Sin(angle)
//!     CalculateMaxHeight = (verticalVelocity * verticalVelocity) / (2 * GRAVITY)
//! End Function
//!
//! Public Function CalculateTimeOfFlight(velocity As Double, angle As Double) As Double
//!     ' Time of flight: T = 2 * v * sin(θ) / g
//!     CalculateTimeOfFlight = (2 * velocity * Sin(angle)) / GRAVITY
//! End Function
//!
//! Public Sub GetProjectilePosition(velocity As Double, angle As Double, _
//!                                  time As Double, ByRef x As Double, ByRef y As Double)
//!     ' angle in radians
//!     Dim vx As Double, vy As Double
//!     
//!     vx = velocity * Cos(angle)
//!     vy = velocity * Sin(angle)
//!     
//!     x = vx * time
//!     y = vy * time - 0.5 * GRAVITY * time * time
//! End Sub
//!
//! Public Function CalculatePendulumDisplacement(length As Double, angle0 As Double, _
//!                                               time As Double) As Double
//!     ' Small angle approximation
//!     ' angle(t) = angle0 * cos(ωt) where ω = sqrt(g/L)
//!     Dim omega As Double
//!     omega = Sqr(GRAVITY / length)
//!     
//!     ' For small angles, displacement ≈ L * θ
//!     CalculatePendulumDisplacement = length * angle0 * Cos(omega * time)
//! End Function
//!
//! Public Function CalculateInclinedPlaneForce(mass As Double, angle As Double) As Double
//!     ' Force down incline: F = m * g * sin(θ)
//!     ' angle in radians
//!     CalculateInclinedPlaneForce = mass * GRAVITY * Sin(angle)
//! End Function
//! ```
//!
//! ### Example 4: `GraphicsHelper` Module
//! Graphics and animation helpers using trigonometry
//! ```vb
//! ' Module: GraphicsHelper
//! Private Const PI As Double = 3.14159265358979
//!
//! Public Function RotatePointX(x As Double, y As Double, angle As Double, _
//!                              centerX As Double, centerY As Double) As Double
//!     ' Rotate point around center, return new X
//!     ' angle in radians
//!     Dim dx As Double, dy As Double
//!     
//!     dx = x - centerX
//!     dy = y - centerY
//!     
//!     RotatePointX = centerX + dx * Cos(angle) - dy * Sin(angle)
//! End Function
//!
//! Public Function RotatePointY(x As Double, y As Double, angle As Double, _
//!                              centerX As Double, centerY As Double) As Double
//!     ' Rotate point around center, return new Y
//!     ' angle in radians
//!     Dim dx As Double, dy As Double
//!     
//!     dx = x - centerX
//!     dy = y - centerY
//!     
//!     RotatePointY = centerY + dx * Sin(angle) + dy * Cos(angle)
//! End Function
//!
//! Public Function CreatePulseEffect(time As Double, frequency As Double) As Double
//!     ' Create pulsing effect (0 to 1)
//!     CreatePulseEffect = (Sin(2 * PI * frequency * time) + 1) / 2
//! End Function
//!
//! Public Function CreateFadeInOut(time As Double, duration As Double) As Double
//!     ' Smooth fade in and out using sine
//!     Dim t As Double
//!     t = (time / duration) * PI
//!     CreateFadeInOut = Sin(t)
//! End Function
//!
//! Public Function EaseInOutSine(t As Double) As Double
//!     ' Easing function using sine (t from 0 to 1)
//!     EaseInOutSine = -(Cos(PI * t) - 1) / 2
//! End Function
//!
//! Public Sub DrawSineWave(picBox As Object, amplitude As Double, _
//!                         frequency As Double, Optional phase As Double = 0)
//!     Dim x As Integer
//!     Dim y As Double
//!     Dim prevX As Integer, prevY As Integer
//!     Dim width As Integer
//!     
//!     width = picBox.ScaleWidth
//!     
//!     For x = 0 To width
//!         y = amplitude * Sin(2 * PI * frequency * (x / width) + phase)
//!         y = picBox.ScaleHeight / 2 - y  ' Flip Y axis
//!         
//!         If x > 0 Then
//!             picBox.Line (prevX, prevY)-(x, y)
//!         End If
//!         
//!         prevX = x
//!         prevY = y
//!     Next x
//! End Sub
//! ```
//!
//! ## Error Handling
//!
//! The Sin function can generate the following errors:
//!
//! - **Error 13** (Type mismatch): Argument cannot be interpreted as numeric
//! - **Error 5** (Invalid procedure call): In rare cases with invalid input
//!
//! Error handling example:
//! ```vb
//! On Error Resume Next
//! result = Sin(angle)
//! If Err.Number <> 0 Then
//!     MsgBox "Error calculating sine: " & Err.Description
//! End If
//! ```
//!
//! ## Performance Considerations
//!
//! - Sin is a relatively fast mathematical function
//! - Uses hardware FPU for calculation when available
//! - For repeated calculations with same angles, consider caching results
//! - Lookup tables can be faster for real-time applications with limited angle sets
//! - Modern CPUs execute Sin very quickly (microseconds)
//!
//! ## Best Practices
//!
//! 1. **Use Radians**: Remember Sin takes radians, not degrees
//! 2. **Convert Carefully**: Use consistent conversion factor for degrees↔radians
//! 3. **Cache Pi**: Define PI as a constant rather than calculating repeatedly
//! 4. **Range Awareness**: Sin always returns -1 to 1
//! 5. **Precision**: Be aware of floating-point precision limits
//! 6. **Angle Normalization**: For large angles, consider normalizing to 0-2π
//! 7. **Avoid Division**: Use multiplication by inverse when possible
//! 8. **Test Edge Cases**: Test with 0, π/2, π, 3π/2, 2π
//! 9. **Document Units**: Always document whether angles are in degrees or radians
//! 10. **Combine Functions**: Use with Cos, Tan for complete trigonometric operations
//!
//! ## Comparison with Related Functions
//!
//! | Function | Input (radians) | Output Range | Description |
//! |----------|-----------------|--------------|-------------|
//! | Sin | angle | -1 to 1 | Sine of angle |
//! | Cos | angle | -1 to 1 | Cosine of angle |
//! | Tan | angle | -∞ to +∞ | Tangent of angle |
//! | Atn | ratio | -π/2 to π/2 | Arctangent (inverse tangent) |
//! | Sqr | number ≥ 0 | ≥ 0 | Square root |
//!
//! ## Platform Considerations
//!
//! - Available in VB6, VBA (all versions)
//! - Uses system math library
//! - Precision depends on Double data type (IEEE 754)
//! - Results consistent across Windows versions
//! - Very small return values near multiples of π due to floating-point precision
//!
//! ## Limitations
//!
//! - Input must be in radians (no built-in degree support)
//! - Floating-point precision limits (≈15-17 decimal digits)
//! - Sin(π) returns very small number, not exactly 0
//! - Large angle values may accumulate rounding errors
//! - No complex number support
//! - No automatic angle normalization
//!
//! ## Related Functions
//!
//! - `Cos`: Returns the cosine of an angle in radians
//! - `Tan`: Returns the tangent of an angle in radians
//! - `Atn`: Returns the arctangent of a number in radians
//! - `Sqr`: Returns the square root (used in inverse sine calculations)
//! - `Abs`: Returns absolute value (useful for angle normalization)
//!
#[cfg(test)]
mod tests {
    use crate::*;

    #[test]
    fn sin_basic() {
        let source = r"
Sub Test()
    Dim result As Double
    result = Sin(1.5708)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_with_pi() {
        let source = r"
Sub Test()
    Dim pi As Double
    Dim sineValue As Double
    pi = Atn(1) * 4
    sineValue = Sin(pi / 2)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_if_statement() {
        let source = r#"
Sub Test()
    If Sin(angle) > 0.5 Then
        MsgBox "Greater than 0.5"
    End If
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_function_return() {
        let source = r"
Function CalculateSine(angle As Double) As Double
    CalculateSine = Sin(angle)
End Function
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_variable_assignment() {
        let source = r"
Sub Test()
    Dim y As Double
    y = Sin(x)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_msgbox() {
        let source = r#"
Sub Test()
    MsgBox "Sine value: " & Sin(angle)
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_debug_print() {
        let source = r"
Sub Test()
    Debug.Print Sin(1.0472)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_select_case() {
        let source = r#"
Sub Test()
    Select Case Sin(angle)
        Case Is > 0
            MsgBox "Positive"
        Case Is < 0
            MsgBox "Negative"
        Case Else
            MsgBox "Zero"
    End Select
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_class_usage() {
        let source = r"
Class TrigCalculator
    Public Function GetSine(angle As Double) As Double
        GetSine = Sin(angle)
    End Function
End Class
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_with_statement() {
        let source = r"
Sub Test()
    With Calculator
        Dim s As Double
        s = Sin(angle)
    End With
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_elseif() {
        let source = r#"
Sub Test()
    If Sin(a) > 0.9 Then
        MsgBox "High"
    ElseIf Sin(a) > 0.5 Then
        MsgBox "Medium"
    Else
        MsgBox "Low"
    End If
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_for_loop() {
        let source = r"
Sub Test()
    Dim i As Integer
    For i = 0 To 360
        Debug.Print Sin(i)
    Next i
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_do_while() {
        let source = r"
Sub Test()
    Do While Sin(angle) < 1
        angle = angle + 0.1
    Loop
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_do_until() {
        let source = r"
Sub Test()
    Do Until Sin(x) > threshold
        x = x + step
    Loop
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_while_wend() {
        let source = r"
Sub Test()
    While Abs(Sin(angle)) > 0.01
        angle = angle - 0.1
    Wend
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_parentheses() {
        let source = r"
Sub Test()
    Dim value As Double
    value = (Sin(a) + Sin(b)) / 2
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_iif() {
        let source = r#"
Sub Test()
    Dim msg As String
    msg = IIf(Sin(angle) > 0, "Positive", "Non-positive")
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_array_assignment() {
        let source = r"
Sub Test()
    Dim waveform(100) As Double
    waveform(0) = Sin(angle)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_property_assignment() {
        let source = r"
Class Point
    Public Y As Double
End Class

Sub Test()
    Dim pt As New Point
    pt.Y = Sin(angle)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_function_argument() {
        let source = r"
Sub ProcessValue(v As Double)
End Sub

Sub Test()
    ProcessValue Sin(angle)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_concatenation() {
        let source = r#"
Sub Test()
    Dim output As String
    output = "Sine: " & Sin(angle)
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_comparison() {
        let source = r"
Sub Test()
    Dim isPositive As Boolean
    isPositive = (Sin(angle) > 0)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_arithmetic() {
        let source = r"
Sub Test()
    Dim amplitude As Double
    Dim wave As Double
    wave = amplitude * Sin(angle)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_degrees_conversion() {
        let source = r"
Sub Test()
    Const PI As Double = 3.14159265358979
    Dim degrees As Double
    Dim radians As Double
    Dim result As Double
    degrees = 45
    radians = degrees * (PI / 180)
    result = Sin(radians)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_error_handling() {
        let source = r#"
Sub Test()
    On Error Resume Next
    Dim s As Double
    s = Sin(inputValue)
    If Err.Number <> 0 Then
        MsgBox "Error"
    End If
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_on_error_goto() {
        let source = r#"
Sub Test()
    On Error GoTo ErrorHandler
    Dim sineVal As Double
    sineVal = Sin(angle)
    Exit Sub
ErrorHandler:
    MsgBox "Error calculating sine"
End Sub
"#;
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }

    #[test]
    fn sin_circular_motion() {
        let source = r"
Sub Test()
    Dim y As Double
    Dim radius As Double
    y = centerY + radius * Sin(angle)
End Sub
";
        let (cst_opt, _failures) = ConcreteSyntaxTree::from_text("test.bas", source).unpack();
        let cst = cst_opt.expect("CST should be parsed");

        let tree = cst.to_serializable();

        let mut settings = insta::Settings::clone_current();
        settings.set_snapshot_path("../../../../../snapshots/syntax/library/functions/math/sin");
        settings.set_prepend_module_to_snapshot(false);
        let _guard = settings.bind_to_scope();
        insta::assert_yaml_snapshot!(tree);
    }
}