This article discusses Functional Programming in C# through Algebra, Numbers, Euclidean Plane and Fractals. A wide range of topics are covered related to functional programming and set operations. Code examples and explanations are provided to help readers understand the concepts and how to implement them in C#.
Contents
- Introduction
- Representing Data Through Functions
- Sets
- Binary Operations
- Go Further
- Euclidean Plane
- Drawing a Disk
- Drawing Horizontal and Vertical Half-planes
- Functions
- Go Further
- Fractals
- Complex Numbers and Drawing
- Mandelbrot Fractal
- Newton Fractal
- Go Further
- Introduction to Laziness
- Running the Source Code
- References
- History
Functional programming is a programming paradigm based on functions, their compositions, and also on decomposition into functions.
There are two possible properties of functions:
- Purity: Functions have results that depend strictly on their arguments, with no other external effect. Purity leads to compartmentalization, localization, stability, and determinism.
- First-class citizenship: Functions have value status. Functions can be named, assigned, typed, created on demand, passed as an argument to a function, be the result of a function, and stored in a data structure. First-class citizenship leads to flexibility of use and compositionality.
Functional programming consists in exploiting one and/or the other of these two properties.
This article will not discuss the basics of functional programming, as you can find numerous resources on this topic on the Internet. Instead, it will talk about functional programming in C# applied to algebra, numbers, the Euclidean plane, and fractals. The examples provided in this article will start from simple to more complex but always illustrated in a simple, straightforward and easy-to-understand manner.
Let S
be any set of elements a
, b
, c
... (for instance, the books on the table, or the videos in YouTube, or the points of the Euclidean plane) and let S'
be any subset of these elements (for instance, the green books on the table, or the cultural videos in YouTube, or the points in the circle of radius 1 centered at the origin of the Euclidean plane).
The Characteristic Function S'(x)
of the set S'
is a function which associates either true
or false
with each element x
of S
.
S'(x) = true if x is in S'
S'(x) = false if x is not in S'
Let S
be the set of books on the table and let S'
be the set of green books on the table. Let a
and b
be two green books, and let c
and d
be two red books on the table. Then:
S'(a) = S'(b) = true
S'(c) = S'(d) = false
Let S
be the set of the videos in YouTube and let S'
be the set of cultural videos in YouTube. Let a
and b
be two cultural videos in YouTube, and c
and d
be two non-cultural videos in YouTube. Then:
S'(a) = S'(b) = true
S'(c) = S'(d) = false
Let S
be the set of the points in the Euclidean plane and let S'
be the set of the points in the circle of radius 1 centered at the origin of the Euclidean plane (0, 0) (unit circle). Let a
and b
be two points in the unit circle, and let c
and d
be two points in a circle of radius 2 centered at the origin of the Euclidean plane. Then:
S'(a) = S'(b) = true
S'(c) = S'(d) = false
Thus, any set S'
can always be represented by its Characteristic Function. A function that takes as argument an element and returns true
if this element is in S'
, false
otherwise. In other words, a set (abstract data type) can be represented through a Predicate
in C#.
Predicate<T> set;
In the next sections, we will see how to represent some fundamental sets in the algebra of sets through C# in a functional way, then we will define generic binary operations on sets. We will then apply these operations on numbers then on subsets of the Euclidean Plane. Sets are abstract data structures, the subsets of numbers and the subsets of the Euclidean plane are the representation of abstract data-structures, and finally the binary operations are the generic logics that works on any representation of the abstract data structures.
This section introduces the representation of some fundamental sets in the algebra of sets through C#.
Empty Set
Let E
be the empty set and Empty
its Characteristic function. In algebra of sets, E
is the unique set having no elements. Therefore, Empty
can be defined as follows:
Empty(x) = false if x is in E
Empty(x) = false if x is not in E
Thus, the representation of E
in C# can be defined as follows:
public static Predicate<T> Empty<T>() => _ => false;
In algebra of sets, Empty
is represented as follows:
Thus, running the code below:
Console.WriteLine("\nEmpty set:");
Console.WriteLine("Is 7 in {{}}? {0}", Empty<int>()(7));
gives the following results:
Set All
Let S
be a set and S'
be the subset of S
that contains all the elements and All
its Characteristic function. In algebra of sets, S'
is the full set that contains all the elements. Therefore, All
can be defined like this:
All(x) = true if x is in S
Thus, the representation of S'
in C# can be defined as follows:
public static Predicate<T> All<T>() => _ => true;
In algebra of sets, All
is represented as follows:
Thus, running the code below:
Console.WriteLine("Is 7 in the integers set? {0}", All<int>()(7));
gives the following results:
Singleton Set
Let E
be the Singleton set and Singleton
its Characteristic function. In algebra of sets, E
also known as unit set, or 1-tuple is a set with exactly one element e
. Therefore, Singleton
can be defined as follows:
Singleton(x) = true if x is e
Singleton(x) = false if x is not e
Thus, the representation of E
in C# can be defined as follows:
public static Predicate<T> Singleton<T>(T e) where T : notnull => x => e.Equals(x);
Thus, running the code below:
Console.WriteLine("Is 7 in the singleton {{0}}? {0}", Singleton(0)(7));
Console.WriteLine("Is 7 in the singleton {{7}}? {0}", Singleton(7)(7));
gives the following results:
Other Sets
This section presents subsets of the integers set.
Even numbers
Let E
be the set of even numbers and Even
its Characteristic function. In mathematics, an even number is a number which is a multiple of two. Therefore, Even
can be defined as follows:
Even(x) = true if x is a multiple of 2
Even(x) = false if x is not a multiple of 2
Thus, the representation of E
in C# can be defined as follows:
Predicate<int> even = i => i % 2 == 0;
Thus, running the code below:
Console.WriteLine("Is {0} even? {1}", 99, even(99));
Console.WriteLine("Is {0} even? {1}", 998, even(998));
gives the following results:
Odd Numbers
Let E
be the set of odd numbers and Odd
its Characteristic function. In mathematics, an odd number is a number which is not a multiple of two. Therefore, Odd
can be defined as follows:
Odd(x) = true if x is not a multiple of 2
Odd(x) = false if x is a multiple of 2
Thus, the representation of E
in C# can be defined as follows:
Predicate<int> odd = i => i % 2 == 1;
Thus, running the code below:
Console.WriteLine("Is {0} odd? {1}", 99, odd(99));
Console.WriteLine("Is {0} odd? {1}", 998, odd(998));
gives the following results:
Multiples of 3
Let E
be the set of multiples of 3 and MultipleOfThree
its Characteristic function. In mathematics, a multiple of 3 is a number divisible by 3. Therefore, MultipleOfThree
can be defined as follows:
MultipleOfThree(x) = true if x is divisible by 3
MultipleOfThree(x) = false if x is not divisible by 3
Thus, the representation of E
in C# can be defined as follows:
Predicate<int> multipleOfThree = i => i % 3 == 0;
Thus, running the code below:
Console.WriteLine("Is {0} a multiple of 3? {1}", 99, multipleOfThree(99));
Console.WriteLine("Is {0} a multiple of 3? {1}", 998, multipleOfThree(998));
gives the following results:
Multiples of 5
Let E
be the set of multiples of 5 and MultipleOfFive
its Characteristic function. In mathematics, a multiple of 5 is a number divisible by 5. Therefore, MultipleOfFive
can be defined as follows:
MultipleOfFive(x) = true if x is divisible by 5
MultipleOfFive(x) = false if x is not divisible by 5
Thus, the representation of E
in C# can be defined as follows:
Predicate<int> multipleOfFive = i => i % 5 == 0;
Thus, running the code below:
Console.WriteLine("Is {0} a multiple of 5? {1}", 15, multipleOfFive(15));
Console.WriteLine("Is {0} a multiple of 5? {1}", 998, multipleOfFive(998));
gives the following results:
Prime Numbers
A long time ago, when I was playing with Project Euler problems, I had to resolve the following one:
By listing the first six prime numbers: 2, 3, 5, 7, 11, and 13,
we can see that the 6th prime is 13.
What is the 10 001st prime number?
To resolve this problem, I first had to write a fast algorithm that checks whether a given number is prime or not. Once the algorithm was written, I wrote an iterative algorithm that iterates through primes until the 10 001st prime number was found. Nevertheless, is the next iterative algorithm really necessary? You will see.
The algorithm that checks whether a given number is prime or not is the Characteristical function of the primes set.
Let E
be the set of primes and Prime
its Characteristic function. In mathematics, a prime is a natural number greater than 1 that has no positive divisors other than 1 and itself. Therefore, Prime
can be defined as follows:
Prime(x) = true if x is prime
Prime(x) = false if x is not prime
Thus, the representation of E
in C# can be defined as follows:
Predicate<int> prime = IsPrime;
where IsPrime
is a method that checks whether a given number is prime or not.
static bool IsPrime(int i)
{
if (i == 1) return false;
if (i < 4) return true;
if ((i >> 1) * 2 == i) return false;
if (i < 9) return true;
if (i % 3 == 0) return false;
int sqrt = (int)Math.Sqrt(i);
for (int d = 5; d <= sqrt; d += 6)
{
if (i % d == 0) return false;
if (i % (d + 2) == 0) return false;
}
return true;
}
Thus, running the code below to resolve our problem:
int p = Primes(prime).Skip(10000).First();
Console.WriteLine("The 10 001st prime number is {0}", p);
where Primes
is defined below:
static IEnumerable <int> Primes(Predicate<int> prime)
{
yield return 2;
int p = 3;
while (true)
{
if (prime(p)) yield return p;
p += 2;
}
}
gives the following results:
This section presents several fundamental operations for constructing new sets from given sets and for manipulating sets. Below is the Venn diagram in the algebra of sets.
Union
Let E
and F
be two sets. The union of E
and F
, denoted by E U F
is the set of all elements which are members of either E
and F
.
Let Union
be the union operation. Thus, the Union
operation can be implemented as follows in C#:
public static Predicate<T> Union<T>(this Predicate<T> e, Predicate<T> f)
=> x => e(x) || f(x);
As you can see, Union
is an extension function on the Characteristic function of a set. All the operations will be defined as extension functions on the Characteristic function of a set. Thereby, running the code below:
Console.WriteLine("Is 7 in the union of Even and Odd Integers Set? {0}", Even.Union(Odd)(7));
gives the following results:
Intersection
Let E
and F
be two sets. The intersection of E
and F
, denoted by E n F
is the set of all elements which are members of both E
and F
.
Let Intersection
be the intersection operation. Thus, the Intersection
operation can be implemented as follows in C#:
public static Predicate<T> Intersection<T>(this Predicate<T> e, Predicate<T> f)
=> x => e(x) && f(x);
As you can see, Intersection
is an extension function on the Characteristic function of a set. Thereby, running the code below:
Predicate<int> multiplesOfThreeAndFive = multipleOfThree.Intersection(multipleOfFive);
Console.WriteLine("Is 15 a multiple of 3 and 5? {0}", multiplesOfThreeAndFive(15));
Console.WriteLine("Is 10 a multiple of 3 and 5? {0}", multiplesOfThreeAndFive(10));
gives the following results:
Cartesian Product
Let E
and F
be two sets. The cartesian product of E
and F
, denoted by E × F
is the set of all ordered pairs (e, f)
such that e
is a member of E
and f
is a member of F
.
Let CartesianProduct
be the cartesian product operation. Thus, the CartesianProduct
operation can be implemented as follows in C#:
public static Func<T1, T2, bool>
CartesianProduct<T1, T2>(this Predicate<T1> e, Predicate<T2> f) => (x, y)
=> e(x) && f(y);
As you can see, CartesianProduct
is an extension function on the Characteristic function of a set. Thereby, running the code below:
Func<int, int, bool> cartesianProduct = multipleOfThree.CartesianProduct(multipleOfFive);
Console.WriteLine("Is (9, 15) in MultipleOfThree x MultipleOfFive? {0}",
cartesianProduct(9, 15));
gives the following results:
Complements
Let E
and F
be two sets. The relative complement of F
in E
, denoted by E \ F
is the set of all elements which are members of E
but not members of F
.
Let Complement
be the relative complement operation. Thus, the Complement
operation can be implemented as follows in C#:
public static Predicate<T> Complement<T>(this Predicate<T> e, Predicate<T> f)
=> x => e(x) && !f(x);
As you can see, Complement
is an extension method on the Characteristic function of a set. Thereby, running the code below:
Console.WriteLine("Is 15 in MultipleOfThree \\ MultipleOfFive set? {0}",
multipleOfThree.Complement(multipleOfFive)(15));
Console.WriteLine("Is 9 in MultipleOfThree \\ MultipleOfFive set? {0}",
multipleOfThree.Complement(multipleOfFive)(9));
gives the following results:
Symmetric Difference
Let E
and F
be two sets. The symmetric difference of E
and F
, denoted by E Δ F
is the set of all elements which are members of either E
and F
but not in the intersection of E
and F
.
Let SymmetricDifference
be the symmetric difference operation. Thus, the SymmetricDifference
operation can be implemented in two ways in C#. A trivial way is to use the union and complement operations as follows:
public static Predicate<T> SymmetricDifferenceWithoutXor<T>
(this Predicate<T> e, Predicate<T> f)
=> Union(e.Complement(f), f.Complement(e));
Another way is to use the XOR
binary operation as follows:
public static Predicate<T> SymmetricDifferenceWithXor<T>
(this Predicate<T> e, Predicate<T> f)
=> x => e(x) ^ f(x);
As you can see, SymmetricDifferenceWithoutXor
and SymmetricDifferenceWithXor
are extension methods on the Characteristic function of a set. Thereby, running the code below:
Console.WriteLine("\nSymmetricDifference without XOR:");
Predicate<int> sdWithoutXor = prime.SymmetricDifferenceWithoutXor(even);
Console.WriteLine("Is 2 in the symmetric difference of prime and even Sets? {0}",
sdWithoutXor(2));
Console.WriteLine("Is 4 in the symmetric difference of prime and even Sets? {0}",
sdWithoutXor(4));
Console.WriteLine("Is 7 in the symmetric difference of prime and even Sets? {0}",
sdWithoutXor(7));
Console.WriteLine("\nSymmetricDifference with XOR:");
Predicate<int> sdWithXor = prime.SymmetricDifferenceWithXor(even);
Console.WriteLine("Is 2 in the symetric difference of prime and even Sets? {0}",
sdWithXor(2));
Console.WriteLine("Is 4 in the symmetric difference of prime and even Sets? {0}",
sdWithXor(4));
Console.WriteLine("Is 7 in the symmetric difference of prime and even Sets? {0}",
sdWithXor(7));
gives the following results:
Other Operations
This section presents other useful binary operations on sets.
Contains
Let Contains
be the operation that checks whether or not an element is in a set. This operation is an extension function on the Characteristic function of a set that takes as parameter an element and returns true
if the element is in the set, false
otherwise.
Thus, this operation is defined as follows in C#:
public static bool Contains<T>(this Predicate<T> e, T x) => e(x);
Therefore, running the code below:
Console.WriteLine("Is 7 in the singleton {{0}}? {0}", Singleton(0).Contains(7));
Console.WriteLine("Is 7 in the singleton {{7}}? {0}", Singleton(7).Contains(7));
gives the following result:
Add
Let Add
be the operation that adds an element to a set. This operation is an extension function on the Characteristic function of a set that takes as parameter an element and adds it to the set.
Thus, this operation is defined as follows in C#:
public static Predicate<T> Add<T>(this Predicate<T> s, T e) where T : notnull
=> x => x.Equals(e) || s(x);
Therefore, running the code below:
Console.WriteLine("Is 7 in {{0, 7}}? {0}", Singleton(0).Add(7)(7));
Console.WriteLine("Is 0 in {{1, 0}}? {0}", Singleton(1).Add(0)(0));
Console.WriteLine("Is 7 in {{19, 0}}? {0}", Singleton(19).Add(0)(7));
gives the following result:
Remove
Let Remove
be the operation that removes an element from a set. This operation is an extension function on the Characteristic function of a set that takes as parameter an element and removes it from the set.
Thus, this operation is defined as follows in C#:
public static Predicate<T> Remove<T>(this Predicate<T> s, T e) where T : notnull
=> x => !x.Equals(e) && s(x);
Therefore, running the code below:
Console.WriteLine("Is 7 in {{}}? {0}", Singleton(0).Remove(0)(7));
Console.WriteLine("Is 0 in {{}}? {0}", Singleton(7).Remove(7)(0));
gives the following result:
You can see how easily we can do some algebra of sets in C# through functional programming. In the previous sections was shown the most fundamental definitions. But, if you want to go further, you can think about:
- Relations over sets
- Abstract algebra, such as monoids, groups, fields, rings, K-vectorial spaces and so on
- Inclusion-exclusion principle
- Russell's paradox
- Cantor's paradox
- Dual vector space
- Theorems and Corollaries
In the previous section, the fundamental concepts on sets were implemented in C#. In this section, we will practice the concepts implemented on the set of plane points (Euclidean plane).
A disk is a subset of a plane bounded by a circle. There are two types of disks. Closed disks which are disks that contain the points of the circle that constitutes its boundary, and Open disks which are disks that do not contain the points of the circle that constitutes its boundary.
In this section, we will set up the Characterstic function of the Closed disk and draw it in WPF.
To set up the Characterstic function, we need first a function that calculates the Euclidean Distance between two points in the plane. This function is implemented as follows:
private static double EuclidianDistance(Point point1, Point point2)
=> Math.Sqrt(Math.Pow(point1.X - point2.X, 2) + Math.Pow(point1.Y - point2.Y, 2));
where Point
is a struct
defined in the System.Windows
namespace. This formula is based on Pythagoras' Theorem.
where c
is the Euclidean distance, a²
is (point1.X - point2.X)²
and b²
is (point1.Y - point2.Y)²
.
Let Disk
be the Characteristic function of a closed disk. In algebra of sets, the definition of a closed disk in the reals set is as follows:
where a
and b
are the coordinates of the center and R
the radius.
Thus, the implementation of Disk
in C# is as follows:
public static Predicate<Point> Disk(Point center, double radius)
=> p => EuclidianDistance(center, p) <= radius;
In order to view the set in a result, I decided to implement a function Draw
that draws a set in the Euclidean plane. I chose WPF and thus used the System.Windows.Controls.Image
as a canvas and a Bitmap
as the context.
Thus, I've built the Euclidean plane illustrated below through the method Draw
.
Below the implementation of the method.
public static void Draw(this Predicate<Point> set, Image plane)
{
var bitmap = new Bitmap((int)plane.Width, (int)plane.Height);
double semiWidth = plane.Width / 2;
double semiHeight = plane.Height / 2;
double xMin = -semiWidth;
double xMax = +semiWidth;
double yMin = -semiHeight;
double yMax = +semiHeight;
for (int x = 0; x < bitmap.Height; x++)
{
double xp = xMin + x * (xMax - xMin) / plane.Width;
for (int y = 0; y < bitmap.Width; y++)
{
double yp = yMax - y * (yMax - yMin) / plane.Height;
if (set(new Point(xp, yp)))
{
bitmap.SetPixel(x, y, Color.Black);
}
}
}
plane.Source = Imaging.CreateBitmapSourceFromHBitmap(
bitmap.GetHbitmap(),
IntPtr.Zero,
Int32Rect.Empty,
BitmapSizeOptions.FromWidthAndHeight(bitmap.Width, bitmap.Height));
}
In the Draw
method, a bitmap
having the same width and same height as the Euclidean plane container is created. Then each point in pixels (x,y)
of the bitmap
is replaced by a black point if it belongs to the set
. xMin
, xMax
, yMin
and yMax
are the bounding values illustrated in the figure of the Euclidean plane above.
As you can see, Draw
is an extension function on the Characteristic function of a set of points. Therefore, running the code below:
Plane.Disk(new Point(0, 0), 20).Draw(PlaneCanvas);
gives the following result:
A horizontal or a vertical half-plane is either of the two subsets into which a plane divides the Euclidean space. A horizontal half-plane is either of the two subsets into which a plane divides the Euclidean space through a line perpendicular with the Y axis like in the figure above. A vertical half-plane is either of the two subsets into which a plane divides the Euclidean space through a line perpendicular with the X axis.
In this section, we will set up the Characteristic functions of the horizontal and vertical half-planes, draw them in WPF and see what we can do if we combine them with the disk subset.
Let HorizontalHalfPlane
be the Characteristic function of a horizontal half-plane. The implementation of HorizontalHalfPlane
in C# is as follows:
public static Predicate<Point> HorizontalHalfPlane(double y, bool lowerThan)
=> p => lowerThan ? p.Y <= y : p.Y >= y;
Thus, running the code below:
Plane.HorizontalHalfPlane(0, true).Draw(PlaneCanvas);
gives the following result:
Let VerticalHalfPlane
be the Characteristic function of a vertical half-plane. The implementation of VerticalHalfPlane
in C# is as follows:
public static Predicate<Point> VerticalHalfPlane(double x, bool lowerThan)
=> p => lowerThan ? p.X <= x : p.X >= x;
Thus, running the code below:
Plane.VerticalHalfPlane(0, false).Draw(PlaneCanvas);
gives the following result:
In the first section of the article, we set up basic binary operations on sets. Thus, by combining the intersection of a disk
and a half-plane
for example, we can draw the half-disk subset.
Therefore, running the sample below:
Plane.VerticalHalfPlane(0, false).Intersection(Plane.Disk(new Point(0, 0), 20)).Draw(PlaneCanvas);
gives the following result:
This section presents functions on the sets in the Euclidean plane.
Translate
Let Translate
be the function that translates a point in the plane. In Euclidean geometry, Translate
is a function that moves a given point a constant distance in a specified direction. Thus the implementation in C# is as follows:
private static Func<Point, Point> Translate(double deltax, double deltay)
=> p => new Point(p.X + deltax, p.Y + deltay);
where (deltax, deltay)
is the constant vector of the translation.
Let TranslateSet
be the function that translates a set in the plane. This function is simply implemented as follows in C#:
public static Predicate<Point> TranslateSet
(this Predicate<Point> set, double deltax, double deltay)
=> x => set(Translate(-deltax, -deltay)(x));
TranslateSet
is an extension function on a set. It takes as parameters deltax
which is the delta distance in the first Euclidean dimension and deltay
which is the delta distance in the second Euclidean dimension. If a point P (x, y) is translated in a set S, then its coordinates will change to (x', y') = (x + delatx, y + deltay). Thus, the point (x' - delatx, y' - deltay) will always belong to the set S. In set algebra, TranslateSet
is called isomorph, in other words, the set of all translations forms the translation group T, which is isomorphic to the space itself. This explains the main logic of the function.
Thus, running the code below in our WPF application:
TranslateDiskAnimation();
where TranslateDiskAnimation
is described below:
private const double Delta = 50;
private double _diskDeltay;
private readonly Predicate<Point> _disk = Plane.Disk(new Point(0, -170), 80);
private void TranslateDiskAnimation()
{
DispatcherTimer diskTimer = new DispatcherTimer
{ Interval = new TimeSpan(0, 0, 0, 1, 0) };
diskTimer.Tick += TranslateTimer_Tick;
diskTimer.Start();
}
private void TranslateTimer_Tick(object? sender, EventArgs e)
{
_diskDeltay = _diskDeltay <= plan.Height ? _diskDeltay + Delta : Delta;
Predicate<Point> translatedDisk = _diskDeltay <= plan.Height ?
_disk.TranslateSet(0, _diskDeltay) : _disk;
translatedDisk.Draw(PlaneCanvas);
}
gives the following result:
Homothety
Let Scale
be the function that sends any point M to another point N such that the segment SN is on the same line as SM, but scaled by a factor λ. In algebra of sets, Scale
is formulated as follows:
Thus the implementation in C# is as follows:
private static Func<Point, Point> Scale
(double deltax, double deltay, double lambdax, double lambday)
=> p => new Point(lambdax * p.X + deltax, lambday * p.Y + deltay);
where (deltax, deltay)
is the constant vector of the translation and (lambdax, lambday)
is the λ vector.
Let ScaleSet
be the function that applies an homothety on a set in the plan. This function is simply implemented as follows in C#:
public static Predicate<Point> ScaleSet
(this Predicate<Point> set, double deltax, double deltay, double lambdax,
double lambday) =>
x => set(Scale(-deltax / lambdax, -deltay / lambday, 1 / lambdax, 1 / lambday)(x));
ScaleSet
is an extension function on a set. It takes as parameters deltax
which is the delta distance in the first Euclidean dimension, deltay
which is the delta distance in the second Euclidean dimension and (lambdax, lambday)
which is the constant factor vector λ. If a point P (x, y) is transformed through ScaleSet
in a set S, then its coordinates will change to (x', y') = (lambdax * x + delatx, lambday * y + deltay). Thus, the point ((x'- delatx)/lambdax, (y' - deltay)/lambday) will always belong to the set S, If λ is different from the vector 0, of course. In algebra of sets, ScaleSet
is called isomorph, in other words the set of all homotheties forms the Homothety group H, which is isomorphic to the space itself \ {0}. This explains the main logic of the function.
Thus, running the code below in our WPF application:
ScaleDiskAnimation();
where ScaleDiskAnimation
is described below:
private const double Delta = 50;
private double _lambdaFactor = 1;
private double _diskScaleDeltay;
private readonly Predicate<Point> _disk2 = Plane.Disk(new Point(0, -230), 20);
private void ScaleDiskAnimation()
{
DispatcherTimer scaleTimer = new DispatcherTimer
{ Interval = new TimeSpan(0, 0, 0, 1, 0) };
scaleTimer.Tick += ScaleTimer_Tick;
scaleTimer.Start();
}
private void ScaleTimer_Tick(object? sender, EventArgs e)
{
_diskScaleDeltay = _diskScaleDeltay <= plan.Height ?
_diskScaleDeltay + Delta : Delta;
_lambdaFactor = _diskScaleDeltay <= plan.Height ? _lambdaFactor + 0.5 : 1;
Predicate<Point> scaledDisk = _diskScaleDeltay <= plan.Height
? _disk2.ScaleSet(0, _diskScaleDeltay,
_lambdaFactor, 1)
: _disk2;
scaledDisk.Draw(PlaneCanvas);
}
gives the following result:
Rotate
Let Rotation
be the function that rotates a point with an angle θ. In matrix algebra, Rotation
is formulated as follows:
where (x', y') are the co-ordinates of the point after rotation, and the formula for x' and y' is as follows:
The demonstration of this formula is very simple. Have a look at this rotation.
Below the demonstration:
Thus the implementation in C# is as follows:
private static Func<Point, Point> Rotate(double theta)
=> p => new Point(p.X * Math.Cos(theta) - p.Y * Math.Sin(theta),
p.X * Math.Sin(theta) + p.Y * Math.Cos(theta));
Let RotateSet
be the function that applies a rotation on a set in the plane with the angle θ. This function is simply implemented as follow in C#.
public static Predicate<Point> RotateSet(this Predicate<Point> set, double theta)
=> p => set(Rotate(-theta)(p));
RotateSet
is an extension function on a set. It takes as parameter theta
which is the angle of the rotation. If a point P (x, y) is transformed through RotateSet
in a set S, then its coordinates will change to (x', y') = (x * cos(θ) - y * sin(θ), x * cos(θ) + y * sin(θ)). Thus, the point (x' * cos(θ) + y' * sin(θ), x' * cos(θ) - y' * sin(θ)) will always belong to the set S. In algebra of sets, RotateSet
is called isomorph, in other words, the set of all rotations forms the Rotation group R, which is isomorphic to the space itself. This explains the main logic of the function.
Thus, running the code below in our WPF application:
RotateHalfPlaneAnimation();
where RotateHalfPlaneAnimation
is described below:
private double _theta;
private const double TWO_PI = 2 * Math.PI;
private const double HALF_PI = Math.PI / 2;
private readonly Predicate<Point> _halfPlane = Plane.VerticalHalfPlane(220, false);
private void RotateHalfPlaneAnimation()
{
DispatcherTimer rotateTimer =
new DispatcherTimer { Interval = new TimeSpan(0, 0, 0, 1, 0) };
rotateTimer.Tick += RotateTimer_Tick;
rotateTimer.Start();
}
private void RotateTimer_Tick(object? sender, EventArgs e)
{
_halfPlane.RotateSet(_theta).Draw(PlaneCanvas);
_theta += HALF_PI;
_theta %= TWO_PI;
}
gives the following result:
Very simple, isn't it? For those who want to go further, you can explore these:
- Ellipse
- Three-dimensional Euclidean space
- Ellipsoid
- Paraboloid
- Hyperboloid
- Spherical harmonics
- Superellipsoid
- Haumea
- Homoeoid
- Focaloid
Fractals are sets that have a fractal dimension that usually exceeds their topological dimension and may fall between the integers. For example, the Mandelbrot set is a fractal defined by a family of complex quadratic polynomials:
Pc(z) = z^2 + c
where c
is a complex. The Mandelbrot fractal is defined as the set of all points c
such that the above sequence does not escape to infinity. In algebra of sets, this is formulated as follows:
A Mandelbrot set is illustrated above.
Fractals (abstract data type) can always be represented as follows in C#:
Func<Complex, Complex> fractal;
In order to be able to draw fractals, I needed to manipulate Complex numbers. Thus, I've used Meta.numerics
library. I also needed an utility to draw complex numbers in a Bitmap
, thus I used ColorMap
and ClorTriplet
classes that are available in this CodeProject article.
I've created a Mandelbrot (abstract data type representation) P(z) = z^2 + c
that is available below.
public static Func<Complex, Complex, Complex> MandelbrotFractal() => (c, z) => z * z + c;
In order to be able to draw Complex numbers, I needed to update the Draw
function. Thus, I created an overload of the Draw
function that uses ColorMap
and ClorTriplet
classes. Below is the implementation in C#.
public static void Draw(this Func<Complex, Complex> fractal, Image plane)
{
var bitmap = new Bitmap((int)plane.Width, (int)plane.Height);
const double reMin = -3.0;
const double reMax = +3.0;
const double imMin = -3.0;
const double imMax = +3.0;
for (int x = 0; x < plane.Width; x++)
{
double re = reMin + x * (reMax - reMin) / plane.Width;
for (int y = 0; y < plane.Height; y++)
{
double im = imMax - y * (imMax - imMin) / plane.Height;
var z = new Complex(re, im);
Complex fz = fractal(z);
if (Double.IsInfinity(fz.Re) || Double.IsNaN(fz.Re) ||
Double.IsInfinity(fz.Im) ||
Double.IsNaN(fz.Im))
{
continue;
}
ColorTriplet hsv = ColorMap.ComplexToHsv(fz);
ColorTriplet rgb = ColorMap.HsvToRgb(hsv);
var r = (int)Math.Truncate(255.0 * rgb.X);
var g = (int)Math.Truncate(255.0 * rgb.Y);
var b = (int)Math.Truncate(255.0 * rgb.Z);
Color color = Color.FromArgb(r, g, b);
bitmap.SetPixel(x, y, color);
}
}
plane.Source = Imaging.CreateBitmapSourceFromHBitmap(
bitmap.GetHbitmap(),
IntPtr.Zero,
Int32Rect.Empty,
BitmapSizeOptions.FromWidthAndHeight(bitmap.Width, bitmap.Height));
}
Thus, running the code below:
Plane.MandelbrotFractal().Draw(PlaneCanvas, 20, 1.5);
gives the following result:
I've also created a Newton Fractal (abstract data type representation) P(z) = z^3 - 2*z + 2
that is available below:
public static Func<Complex, Complex> NewtonFractal() => z => z * z * z - 2 * z + 2;
Thus, running the code below:
Plane.NewtonFractal().Draw(PlaneCanvas);
gives the following result:
For those who want to go further, you can explore these:
- Mandelbrot Fractals
- Julia Fractals
- Other Newton Fractals
- Other Fractals
In this section, we will see how to make a type Lazy.
Lazy evaluation is an evaluation strategy which delays the evaluation of an expression until its value is needed and which also avoids repeated evaluations. The sharing can reduce the running time of certain functions by an exponential factor over other non-strict evaluation strategies, such as call-by-name. Below the benefits of Lazy evaluation.
- Performance increases by avoiding needless calculations, and error conditions in evaluating compound expressions
- The ability to construct potentially infinite data structure: We can easily create an infinite set of integers, for example, through a function (see the example on prime numbers in the Sets section)
- The ability to define control flow (structures) as abstractions instead of primitives
Let's have a look at the code below:
public class MyLazy<T>
{
#region Fields
private readonly Func<T> _f;
private bool _hasValue;
private T? _value;
#endregion
#region Constructors
public MyLazy(Func<T> f)
{
_f = f;
}
#endregion
#region Operators
public static implicit operator T?(MyLazy<T?> lazy)
{
if (!lazy._hasValue)
{
lazy._value = lazy._f();
lazy._hasValue = true;
}
return lazy._value;
}
#endregion
}
MyLazy<T>
is a generic class that contains the following fields:
_f
: A function for lazy evaluation that returns a value of type T
_value
: A value of type T
(frozen value) _hasValue
: A boolean that indicates whether the value has been calculated or not
In order to use objects of type MyLazy<T>
as objects of type T
, the implicit
keyword is used. The evaluation is done at type casting time, this operation is called thaw.
Thus, running the code below:
var myLazyRandom = new MyLazy<double>(GetRandomNumber);
double myRandomX = myLazyRandom;
Console.WriteLine("\n Random with MyLazy<double>: {0}", myRandomX);
where GetRandomNumber
returns a random double
as follows:
static double GetRandomNumber() => new Random().NextDouble();
gives the following output:
The .NET Framework 4 introduced a class System.Lazy<T>
for lazy evaluation. This class returns the value through the property Value
. Running the code below:
var lazyRandom = new Lazy<double>(GetRandomNumber);
double randomX = lazyRandom;
gives a compilation error because the type Lazy<T>
is different from the type double
.
To work with the value of the class System.Lazy<T>
, the property Value
has to be used as follows:
var lazyRandom = new Lazy<double>(GetRandomNumber);
double randomX = lazyRandom.Value;
Console.WriteLine("\n Random with System.Lazy<double>.Value: {0}", randomX);
which gives the following output:
The .NET Framework 4 also introduced ThreadLocal
and LazyInitializer
for Lazy evaluation.
To run the source code, you will need Visual Studio 2022 and .NET 7.0 SDK.
Below are the projects available in the solution:
Functional.Core
is a class library that contains sets functions and helpers. Functional.Core.WPF
is a WPF class library that contains plane and fractals functions and helpers. Functional.EuclideanPlane
is a WPF application that contains Euclidean Plane and Fractals samples. Functional.Laziness
is a Console application that contains Laziness samples. Functional.Set
is a Console application that contains sets samples.
That's it! I hope you enjoyed reading.
- 19th October 2023: Initial release