Opentk/tests/OpenTK.Tests/Vector3Tests.fs
Jarl Gullberg 6ad8b92c84
Split FsCheck data generators into a helper library (#716)
* Move generators and assertions to helper library.

* Add example usage to bezier curve tests.

* Add FsCheck to OpenTK.Tests.Math via paket.

* Tweak fsharp msbuild settings for OpenTK.Tests.Generators.
2018-01-09 12:06:39 +01:00

765 lines
28 KiB
Forth

namespace OpenTK.Tests
open Xunit
open FsCheck
open FsCheck.Xunit
open System
open System.Runtime.InteropServices
open OpenTK
open OpenTK.Tests.Generators
module Vector3 =
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Constructors =
//
[<Property>]
let ``Triple value constructor sets all components to the correct values`` (a, b, c) =
let v = Vector3(a, b, c)
Assert.Equal(a, v.X)
Assert.Equal(b, v.Y)
Assert.Equal(c, v.Z)
[<Property>]
let ``Single value constructor sets all components to the correct values`` (a : float32) =
let v = Vector3(a)
Assert.Equal(a, v.X)
Assert.Equal(a, v.Y)
Assert.Equal(a, v.Z)
[<Property>]
let ``Vector2 value constructor sets all components to the correct values`` (a, b) =
let v1 = Vector2(a, b)
let v2 = Vector3(v1)
Assert.Equal(v1.X, v2.X)
Assert.Equal(v1.Y, v2.Y)
Assert.Equal(a, v2.X)
Assert.Equal(b, v2.Y)
Assert.Equal(0.0f, v2.Z)
[<Property>]
let ``Vector3 value constructor sets all components to the correct values`` (a, b, c) =
let v1 = Vector3(a, b, c)
let v2 = Vector3(v1)
Assert.Equal(v1.X, v2.X)
Assert.Equal(v1.Y, v2.Y)
Assert.Equal(v1.Z, v2.Z)
Assert.Equal(a, v2.X)
Assert.Equal(b, v2.Y)
Assert.Equal(c, v2.Z)
[<Property>]
let ``Vector4 value constructor sets all components to the correct values`` (a, b, c, d) =
let v1 = Vector4(a, b, c, d)
let v2 = Vector3(v1)
Assert.Equal(v1.X, v2.X)
Assert.Equal(v1.Y, v2.Y)
Assert.Equal(v1.Z, v2.Z)
Assert.Equal(a, v2.X)
Assert.Equal(b, v2.Y)
Assert.Equal(c, v2.Z)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Indexing =
//
[<Property>]
let ``Index operator accesses the correct components`` (x, y, z) =
let v = Vector3(x, y, z)
Assert.Equal(x, v.[0])
Assert.Equal(y, v.[1])
Assert.Equal(z, v.[2])
[<Property>]
let ``Indexed set operator throws exception for negative indices`` (x, y, z) =
let mutable v = Vector3(x, y, z)
(fun() -> v.[-1] <- x) |> Assert.ThrowsIndexExn
[<Property>]
let ``Indexed get operator throws exception for negative indices`` (x, y, z) =
let mutable v = Vector3(x, y, z)
(fun() -> v.[-1] |> ignore) |> Assert.ThrowsIndexExn
[<Property>]
let ``Indexed set operator throws exception for large indices`` (x, y, z) =
let mutable v = Vector3(x, y, z)
(fun() -> v.[4] <- x) |> Assert.ThrowsIndexExn
[<Property>]
let ``Indexed get operator throws exception for large indices`` (x, y, z) =
let mutable v = Vector3(x, y, z)
(fun() -> v.[4] |> ignore) |> Assert.ThrowsIndexExn
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Length =
//
[<Property>]
let ``Length method follows the pythagorean theorem`` (a, b, c) =
let v = Vector3(a, b, c)
let l = System.Math.Sqrt((float)(a * a + b * b + c * c))
Assert.Equal((float32)l, v.Length)
[<Property>]
let ``Fast length method is the same as one divided by the fast inverse square`` (a, b, c) =
let v = Vector3(a, b, c)
let l = 1.0f / MathHelper.InverseSqrtFast(a * a + b * b + c * c)
Assert.Equal(l, v.LengthFast)
[<Property>]
let ``Length squared method returns each component squared and summed`` (a, b, c) =
let v = Vector3(a, b, c)
let lsq = a * a + b * b + c * c
Assert.Equal(lsq, v.LengthSquared)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Distance =
[<Property>]
let ``Distance(a, b) = (b - a).Length`` (a : Vector3, b : Vector3) =
Assert.ApproximatelyEqual(Vector3.Distance(a, b), (b - a).Length)
[<Property>]
let ``DistanceSquared(a, b) = (b - a).LengthSquared`` (a : Vector3, b : Vector3) =
Assert.ApproximatelyEqual(Vector3.DistanceSquared(a, b), (b - a).LengthSquared)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Normalization =
//
[<Property>]
let ``Normalization creates a new unit length vector with the correct components`` (a, b, c) =
let v = Vector3(a, b, c)
let l = v.Length
// Dividing by zero is not supported
if not (approxEq l 0.0f) then
let norm = v.Normalized()
Assert.ApproximatelyEquivalent(v.X / l, norm.X)
Assert.ApproximatelyEquivalent(v.Y / l, norm.Y)
Assert.ApproximatelyEquivalent(v.Z / l, norm.Z)
[<Property>]
let ``Normalization of instance transforms the instance into a unit length vector with the correct components`` (a, b, c) =
let v = Vector3(a, b, c)
let l = v.Length
if not (approxEq l 0.0f) then
let norm = Vector3(a, b, c)
norm.Normalize()
Assert.ApproximatelyEquivalent(v.X / l, norm.X)
Assert.ApproximatelyEquivalent(v.Y / l, norm.Y)
Assert.ApproximatelyEquivalent(v.Z / l, norm.Z)
[<Property>]
let ``Fast approximate normalization of instance transforms the instance into a unit length vector with the correct components`` (a, b, c) =
let v = Vector3(a, b, c)
let norm = Vector3(a, b, c)
norm.NormalizeFast()
let scale = MathHelper.InverseSqrtFast(a * a + b * b + c * c)
Assert.ApproximatelyEquivalent(v.X * scale, norm.X)
Assert.ApproximatelyEquivalent(v.Y * scale, norm.Y)
Assert.ApproximatelyEquivalent(v.Z * scale, norm.Z)
[<Property>]
let ``Normalization by reference is the same as division by magnitude`` (a : Vector3) =
// Zero-length vectors can't be normalized
if not (approxEq a.Length 0.0f) then
let norm = a / a.Length
let vRes = Vector3.Normalize(ref a)
Assert.ApproximatelyEquivalent(norm, vRes)
[<Property>]
let ``Normalization is the same as division by magnitude`` (a : Vector3) =
// Zero-length vectors can't be normalized
if not (approxEq a.Length 0.0f) then
let norm = a / a.Length
Assert.ApproximatelyEquivalent(norm, Vector3.Normalize(a));
[<Property>]
let ``Fast approximate normalization by reference is the same as multiplication by the fast inverse square`` (a : Vector3) =
let scale = MathHelper.InverseSqrtFast(a.X * a.X + a.Y * a.Y + a.Z * a.Z)
let norm = a * scale
let vRes = Vector3.NormalizeFast(ref a)
Assert.ApproximatelyEquivalent(norm, vRes)
[<Property>]
let ``Fast approximate normalization is the same as multiplication by fast inverse square`` (a : Vector3) =
let scale = MathHelper.InverseSqrtFast(a.X * a.X + a.Y * a.Y + a.Z * a.Z)
let norm = a * scale
Assert.ApproximatelyEquivalent(norm, Vector3.NormalizeFast(a));
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Addition =
//
[<Property>]
let ``Vector3 addition is the same as component addition`` (a : Vector3, b : Vector3) =
let c = a + b
Assert.ApproximatelyEquivalent(a.X + b.X,c.X)
Assert.ApproximatelyEquivalent(a.Y + b.Y,c.Y)
Assert.ApproximatelyEquivalent(a.Z + b.Z,c.Z)
[<Property>]
let ``Vector3 addition is commutative`` (a : Vector3, b : Vector3) =
let c = a + b
let c2 = b + a
Assert.ApproximatelyEquivalent(c, c2)
[<Property>]
let ``Vector3 addition is associative`` (a : Vector3, b : Vector3, c : Vector3) =
let r1 = (a + b) + c
let r2 = a + (b + c)
Assert.ApproximatelyEquivalent(r1, r2)
[<Property>]
let ``Static Vector3 addition method is the same as component addition`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X + b.X, a.Y + b.Y, a.Z + b.Z)
let sum = Vector3.Add(a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3 addition method by reference is the same as component addition`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X + b.X, a.Y + b.Y, a.Z + b.Z)
let sum = Vector3.Add(ref a, ref b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Subtraction =
//
[<Property>]
let ``Vector3 subtraction is the same as component subtraction`` (a : Vector3, b : Vector3) =
let c = a - b
Assert.Equal(a.X - b.X,c.X)
Assert.Equal(a.Y - b.Y,c.Y)
Assert.Equal(a.Z - b.Z,c.Z)
[<Property>]
let ``Static Vector3 subtraction method is the same as component addition`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X - b.X, a.Y - b.Y, a.Z - b.Z)
let sum = Vector3.Subtract(a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3 subtraction method by reference is the same as component addition`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X - b.X, a.Y - b.Y, a.Z - b.Z)
let sum = Vector3.Subtract(ref a, ref b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Multiplication =
//
[<Property>]
let ``Vector3 multiplication is the same as component multiplication`` (a : Vector3, b : Vector3) =
let c = a * b
Assert.Equal(a.X * b.X,c.X)
Assert.Equal(a.Y * b.Y,c.Y)
Assert.Equal(a.Z * b.Z,c.Z)
[<Property>]
let ``Vector3 multiplication is commutative`` (a : Vector3, b : Vector3) =
let r1 = a * b
let r2 = b * a
Assert.Equal(r1, r2)
[<Property>]
let ``Left-handed Vector3-scalar multiplication is the same as component-scalar multiplication`` (a : Vector3, f : float32) =
let r = a * f
Assert.Equal(a.X * f,r.X)
Assert.Equal(a.Y * f,r.Y)
Assert.Equal(a.Z * f,r.Z)
[<Property>]
let ``Right-handed Vector3-scalar multiplication is the same as component-scalar multiplication`` (a : Vector3, f : float32) =
let r = f * a
Assert.Equal(a.X * f,r.X)
Assert.Equal(a.Y * f,r.Y)
Assert.Equal(a.Z * f,r.Z)
[<Property>]
let ``Static method Vector3-scalar multiplication is the same as component-scalar multiplication`` (a : Vector3, f : float32) =
let r = Vector3.Multiply(a, f)
Assert.Equal(a.X * f,r.X)
Assert.Equal(a.Y * f,r.Y)
Assert.Equal(a.Z * f,r.Z)
[<Property>]
let ``Vector3-Matrix3 multiplication using right-handed notation is the same as vector/row multiplication and summation`` (a : Matrix3, b : Vector3) =
let res = a*b
let c1 = b.X * a.M11 + b.Y * a.M12 + b.Z * a.M13
let c2 = b.X * a.M21 + b.Y * a.M22 + b.Z * a.M23
let c3 = b.X * a.M31 + b.Y * a.M32 + b.Z * a.M33
let exp = Vector3(c1, c2, c3)
Assert.Equal(exp, res)
[<Property>]
let ``Vector3-Matrix3 multiplication using left-handed notation is the same as vector/column multiplication and summation`` (a : Matrix3, b : Vector3) =
let res = b*a
let c1 = b.X * a.M11 + b.Y * a.M21 + b.Z * a.M31
let c2 = b.X * a.M12 + b.Y * a.M22 + b.Z * a.M32
let c3 = b.X * a.M13 + b.Y * a.M23 + b.Z * a.M33
let exp = Vector3(c1, c2, c3)
Assert.Equal(exp, res)
[<Property>]
let ``Static Vector3 multiplication method is the same as component multiplication`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X * b.X, a.Y * b.Y, a.Z * b.Z)
let sum = Vector3.Multiply(a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3 multiplication method by reference is the same as component multiplication`` (a : Vector3, b : Vector3) =
let v1 = Vector3(a.X * b.X, a.Y * b.Y, a.Z * b.Z)
let sum = Vector3.Multiply(ref a, ref b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Division =
//
[<Property>]
let ``Vector3-float division is the same as component-float division`` (a : Vector3, f : float32) =
if not (approxEq f 0.0f) then // we don't support diving by zero.
let r = a / f
Assert.ApproximatelyEquivalent(a.X / f,r.X)
Assert.ApproximatelyEquivalent(a.Y / f,r.Y)
Assert.ApproximatelyEquivalent(a.Z / f,r.Z)
[<Property>]
let ``Static Vector3-Vector3 division method is the same as component division`` (a : Vector3, b : Vector3) =
if not (anyZero3 a || anyZero3 b) then
let v1 = Vector3(a.X / b.X, a.Y / b.Y, a.Z / b.Z)
let sum = Vector3.Divide(a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3-Vector3 divison method by reference is the same as component division`` (a : Vector3, b : Vector3) =
if not (anyZero3 a || anyZero3 b) then
let v1 = Vector3(a.X / b.X, a.Y / b.Y, a.Z / b.Z)
let sum = Vector3.Divide(ref a, ref b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3-scalar division method is the same as component division`` (a : Vector3, b : float32) =
if not (approxEq b 0.0f) then // we don't support diving by zero.
let v1 = Vector3(a.X / b, a.Y / b, a.Z / b)
let sum = Vector3.Divide(a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Property>]
let ``Static Vector3-scalar divison method by reference is the same as component division`` (a : Vector3, b : float32) =
if not (approxEq b 0.0f) then // we don't support diving by zero.
let v1 = Vector3(a.X / b, a.Y / b, a.Z / b)
let sum = Vector3.Divide(ref a, b)
Assert.ApproximatelyEquivalent(v1, sum)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Negation =
//
[<Property>]
let ``Vector negation operator negates all components`` (x, y, z) =
let v = Vector3(x, y, z)
let vNeg = -v
Assert.Equal(-x, vNeg.X)
Assert.Equal(-y, vNeg.Y)
Assert.Equal(-z, vNeg.Z)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Equality =
//
[<Property>]
let ``Vector equality operator is by component`` (x, y, z) =
let v1 = Vector3(x, y, z)
let v2 = Vector3(x, y, z)
let equality = v1 = v2
Assert.True(equality)
[<Property>]
let ``Vector inequality operator is by component`` (x, y, z) =
let v1 = Vector3(x, y, z)
let v2 = Vector3(x + 1.0f , y + 1.0f, z + 1.0f)
let inequality = v1 <> v2
Assert.True(inequality)
[<Property>]
let ``Vector equality method is by component`` (x, y, z) =
let v1 = Vector3(x, y, z)
let v2 = Vector3(x, y, z)
let notVector = Matrix2()
let equality = v1.Equals(v2)
let inequalityByOtherType = v1.Equals(notVector)
Assert.True(equality)
Assert.False(inequalityByOtherType)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Swizzling =
//
[<Property>]
let ``Vector swizzling returns the correct composite for X-primary components`` (x, y, z) =
let v = Vector3(x, y, z)
let xyz = Vector3(x, y, z)
let xzy = Vector3(x, z, y)
let xy = Vector2(x, y)
let xz = Vector2(x, z)
Assert.Equal(xyz, v);
Assert.Equal(xzy, v.Xzy);
Assert.Equal(xy, v.Xy);
Assert.Equal(xz, v.Xz);
[<Property>]
let ``Vector swizzling returns the correct composite for Y-primary components`` (x, y, z) =
let v = Vector3(x, y, z)
let yxz = Vector3(y, x, z)
let yzx = Vector3(y, z, x)
let yx = Vector2(y, x)
let yz = Vector2(y, z)
Assert.Equal(yxz, v.Yxz);
Assert.Equal(yzx, v.Yzx);
Assert.Equal(yx, v.Yx);
Assert.Equal(yz, v.Yz);
[<Property>]
let ``Vector swizzling returns the correct composite for Z-primary components`` (x, y, z) =
let v = Vector3(x, y, z)
let zxy = Vector3(z, x, y)
let zyx = Vector3(z, y, x)
let zx = Vector2(z, x)
let zy = Vector2(z, y);
Assert.Equal(zxy, v.Zxy);
Assert.Equal(zyx, v.Zyx);
Assert.Equal(zx, v.Zx);
Assert.Equal(zy, v.Zy);
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Interpolation =
//
[<Property>]
let ``Linear interpolation is by component`` (a : Vector3, b : Vector3, q) =
let blend = q
let rX = blend * (b.X - a.X) + a.X
let rY = blend * (b.Y - a.Y) + a.Y
let rZ = blend * (b.Z - a.Z) + a.Z
let vExp = Vector3(rX, rY, rZ)
Assert.Equal(vExp, Vector3.Lerp(a, b, q))
let vRes = Vector3.Lerp(ref a, ref b, q)
Assert.Equal(vExp, vRes)
[<Property>]
let ``Barycentric interpolation follows the barycentric formula`` (a : Vector3, b : Vector3, c : Vector3, u, v) =
let r = a + u * (b - a) + v * (c - a)
Assert.Equal(r, Vector3.BaryCentric(a, b, c, u, v))
let vRes = Vector3.BaryCentric(ref a, ref b, ref c, u, v)
Assert.Equal(r, vRes)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module ``Vector products`` =
//
[<Property>]
let ``Dot product follows the dot product formula`` (a : Vector3, b : Vector3) =
let dot = a.X * b.X + a.Y * b.Y + a.Z * b.Z
Assert.Equal(dot, Vector3.Dot(a, b));
let vRes = Vector3.Dot(ref a, ref b)
Assert.Equal(dot, vRes)
[<Property>]
let ``Cross product follows the cross product formula`` (a : Vector3, b : Vector3) =
let crossX = a.Y * b.Z - a.Z * b.Y
let crossY = a.Z * b.X - a.X * b.Z
let crossZ = a.X * b.Y - a.Y * b.X
let cross = Vector3(crossX, crossY, crossZ)
Assert.Equal(cross, Vector3.Cross(a, b));
let vRes = Vector3.Cross(ref a, ref b)
Assert.Equal(cross, vRes)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module ``Magnitude min and max`` =
//
[<Property>]
let ``MagnitudeMin selects the vector with equal or lesser magnitude given two vectors`` (v1 : Vector3, v2: Vector3) =
// Results do not matter for equal vectors
if not (v1 = v2) then
let l1 = v1.LengthSquared
let l2 = v2.LengthSquared
let vMin = Vector3.MagnitudeMin(v1, v2)
if vMin = v1 then
let v1ShorterThanv2 = l1 < l2
Assert.True(v1ShorterThanv2)
else
let v2ShorterThanOrEqualTov1 = l2 <= l1
Assert.True(v2ShorterThanOrEqualTov1)
[<Property>]
let ``MagnitudeMax selects the vector with equal or greater magnitude given two vectors`` (v1 : Vector3, v2: Vector3) =
// Results do not matter for equal vectors
if not (v1 = v2) then
let l1 = v1.LengthSquared
let l2 = v2.LengthSquared
let vMin = Vector3.MagnitudeMax(v1, v2)
if vMin = v1 then
let v1LongerThanOrEqualTov2 = l1 >= l2
Assert.True(v1LongerThanOrEqualTov2)
else
let v2LongerThanv1 = l2 > l1
Assert.True(v2LongerThanv1)
[<Property>]
let ``MagnitudeMin by reference selects the vector with equal or lesser magnitude given two vectors`` (v1 : Vector3, v2: Vector3) =
// Results do not matter for equal vectors
if not (v1 = v2) then
let l1 = v1.LengthSquared
let l2 = v2.LengthSquared
let vMin = Vector3.MagnitudeMin(ref v1, ref v2)
if vMin = v1 then
let v1ShorterThanv2 = l1 < l2
Assert.True(v1ShorterThanv2)
else
let v2ShorterThanOrEqualTov1 = l2 <= l1
Assert.True(v2ShorterThanOrEqualTov1)
[<Property>]
let ``MagnitudeMax by reference selects the vector with equal or greater magnitude given two vectors`` (v1 : Vector3, v2: Vector3) =
// Results do not matter for equal vectors
if not (v1 = v2) then
let l1 = v1.LengthSquared
let l2 = v2.LengthSquared
let vMin = Vector3.MagnitudeMax(ref v1, ref v2)
if vMin = v1 then
let v1LongerThanOrEqualTov2 = l1 >= l2
Assert.True(v1LongerThanOrEqualTov2)
else
let v2LongerThanv1 = l2 > l1
Assert.True(v2LongerThanv1)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module ``Component min and max`` =
//
[<Property>]
let ``ComponentMin creates a new vector from the smallest components of given vectors`` (v1 : Vector3, v2: Vector3) =
let vMin = Vector3.ComponentMin(v1, v2)
let isComponentSmallest smallComp comp1 comp2 = smallComp <= comp1 && smallComp <= comp2
Assert.True(isComponentSmallest vMin.X v1.X v2.X)
Assert.True(isComponentSmallest vMin.Y v1.Y v2.Y)
Assert.True(isComponentSmallest vMin.Z v1.Z v2.Z)
[<Property>]
let ``ComponentMax creates a new vector from the greatest components of given vectors`` (v1 : Vector3, v2: Vector3) =
let vMax = Vector3.ComponentMax(v1, v2)
let isComponentLargest largeComp comp1 comp2 = largeComp >= comp1 && largeComp >= comp2
Assert.True(isComponentLargest vMax.X v1.X v2.X)
Assert.True(isComponentLargest vMax.Y v1.Y v2.Y)
Assert.True(isComponentLargest vMax.Z v1.Z v2.Z)
[<Property>]
let ``ComponentMin by reference creates a new vector from the smallest components of given vectors`` (v1 : Vector3, v2: Vector3) =
let vMin = Vector3.ComponentMin(ref v1, ref v2)
let isComponentSmallest smallComp comp1 comp2 = smallComp <= comp1 && smallComp <= comp2
Assert.True(isComponentSmallest vMin.X v1.X v2.X)
Assert.True(isComponentSmallest vMin.Y v1.Y v2.Y)
Assert.True(isComponentSmallest vMin.Z v1.Z v2.Z)
[<Property>]
let ``ComponentMax by reference creates a new vector from the greatest components of given vectors`` (v1 : Vector3, v2: Vector3) =
let vMax = Vector3.ComponentMax(ref v1, ref v2)
let isComponentLargest largeComp comp1 comp2 = largeComp >= comp1 && largeComp >= comp2
Assert.True(isComponentLargest vMax.X v1.X v2.X)
Assert.True(isComponentLargest vMax.Y v1.Y v2.Y)
Assert.True(isComponentLargest vMax.Z v1.Z v2.Z)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Clamping =
//
[<Property>]
let ``Clamping one vector between two other vectors clamps all components between corresponding components`` (a : Vector3, b : Vector3, w : Vector3) =
let res = Vector3.Clamp(w, a, b)
let expX = if w.X < a.X then a.X else if w.X > b.X then b.X else w.X
let expY = if w.Y < a.Y then a.Y else if w.Y > b.Y then b.Y else w.Y
let expZ = if w.Z < a.Z then a.Z else if w.Z > b.Z then b.Z else w.Z
Assert.Equal(expX, res.X)
Assert.Equal(expY, res.Y)
Assert.Equal(expZ, res.Z)
[<Property>]
let ``Clamping one vector between two other vectors by reference clamps all components between corresponding components`` (a : Vector3, b : Vector3, w : Vector3) =
let res = Vector3.Clamp(ref w, ref a, ref b)
let expX = if w.X < a.X then a.X else if w.X > b.X then b.X else w.X
let expY = if w.Y < a.Y then a.Y else if w.Y > b.Y then b.Y else w.Y
let expZ = if w.Z < a.Z then a.Z else if w.Z > b.Z then b.Z else w.Z
Assert.Equal(expX, res.X)
Assert.Equal(expY, res.Y)
Assert.Equal(expZ, res.Z)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module ``Unit vectors``=
//
[<Property>]
let ``Unit X is correct`` =
let unitX = Vector3(1.0f, 0.0f, 0.0f)
Assert.Equal(Vector3.UnitX, unitX)
[<Property>]
let ``Unit Y is correct`` =
let unitY = Vector3(0.0f, 1.0f, 0.0f)
Assert.Equal(Vector3.UnitY, unitY)
[<Property>]
let ``Unit Z is correct`` =
let unitZ = Vector3(0.0f, 0.0f, 1.0f)
Assert.Equal(Vector3.UnitZ, unitZ)
[<Property>]
let ``Unit zero is correct`` =
let unitZero = Vector3(0.0f, 0.0f, 0.0f)
Assert.Equal(Vector3.Zero, unitZero)
[<Property>]
let ``Unit one is correct`` =
let unitOne = Vector3(1.0f, 1.0f, 1.0f)
Assert.Equal(Vector3.One, unitOne)
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Serialization =
//
[<Property>]
let ``The absolute size of a Vector3 is always the size of its components`` (v : Vector3) =
let expectedSize = sizeof<float32> * 3
Assert.Equal(expectedSize, Vector3.SizeInBytes)
Assert.Equal(expectedSize, Marshal.SizeOf(Vector3()))
[<Properties(Arbitrary = [| typeof<OpenTKGen> |])>]
module Transformation =
//
[<Property>]
let ``Transformation by quaternion is the same as multiplication by quaternion and its conjugate`` (v : Vector3, q : Quaternion) =
let vectorQuat = Quaternion(v.X, v.Y, v.Z, 0.0f)
let inverse = Quaternion.Invert(q)
let transformedQuat = q * vectorQuat * inverse
let transformedVector = transformedQuat.Xyz
Assert.ApproximatelyEquivalent(transformedVector, Vector3.Transform(v, q))
[<Property>]
let ``Transformation by quaternion by reference is the same as multiplication by quaternion and its conjugate`` (v : Vector3, q : Quaternion) =
let vectorQuat = Quaternion(v.X, v.Y, v.Z, 0.0f)
let inverse = Quaternion.Invert(q)
let transformedQuat = q * vectorQuat * inverse
let transformedVector = transformedQuat.Xyz
Assert.ApproximatelyEquivalent(transformedVector, Vector3.Transform(ref v, ref q))
[<Property>]
let ``Transformation by quaternion by multiplication using right-handed notation is the same as multiplication by quaternion and its conjugate`` (v : Vector3, q : Quaternion) =
let vectorQuat = Quaternion(v.X, v.Y, v.Z, 0.0f)
let inverse = Quaternion.Invert(q)
let transformedQuat = q * vectorQuat * inverse
let transformedVector = transformedQuat.Xyz
Assert.ApproximatelyEquivalent(transformedVector, q * v)
[<Property>]
let ``Transformation by identity quaternion does not alter vector`` (v : Vector3) =
let q = Quaternion.Identity
let vectorQuat = Quaternion(v.X, v.Y, v.Z, 0.0f)
let inverse = Quaternion.Invert(q)
let transformedQuat = q * vectorQuat * inverse
let transformedVector = transformedQuat.Xyz
Assert.ApproximatelyEquivalent(v, transformedVector)
Assert.ApproximatelyEquivalent(v, Vector3.Transform(v, q))
Assert.ApproximatelyEquivalent(transformedVector, Vector3.Transform(v, q))