learnxinyminutes-docs/d.html.markdown

---
language: D 
filename: learnd.d 
contributors:
    - ["Nick Papanastasiou", "www.nickpapanastasiou.github.io"]
lang: en
---

If you're like me and spend way too much time on the internet, odds are you've heard 
about [D](http://dlang.org/). The D programming language is a modern, general-purpose,
multi-paradigm language with fantastic support for OOP, functional programming, metaprogramming,
and easy concurrency and parallelism, and runs the gamut from low-level features such as
memory management, inline assembly, and pointer arithmetic, to high-level constructs 
such as higher-order functions and generic structures and functions via templates, all with
a pleasant syntax, and blazing fast performance! 

D is actively developed by Walter Bright and Andrei Alexandrescu, two super smart, really cool
dudes. With all that out of the way, let's look at some examples!

```d
// You know what's coming...
module hello;

import std.stdio;

// args is optional
void main(string[] args) {
    writeln("Hello, World!");
}

// Conditionals and loops work as expected.
import std.stdio;

void main() {
    for(int i = 0; i < 5; i++) {
        writeln(i);
    }

    auto n = 1; // use auto for type inferred variables

    while(n < 10_000) {
        n += n;
    }

    do {
        n -= (n / 2);
    } while(n > 0);

    // For and while are nice, but in D-land we prefer foreach
    foreach(i; 1..int.max) { // The .. creates a continuous range 
        if(n % 2 == 0)
            writeln(i);
    }

    foreach_reverse(i; 1..short.max) {
        if(n % 2 == 1) {
            writeln(i);
        } else {
            writeln("No!");
        }
    }
}
```

We can define new types and functions with `struct`, `class`, `union`, and `enum`. Structs and unions
are passed to functions by value (i.e. copied) and classes are passed by reference. Futhermore,
we can use templates to parameterize all of these on both types and values!

```d
// Here, T is a type parameter. Think <T> from C++/C#/Java
struct LinkedList(T) {
    T data = null;
    LinkedList!(T)* next; // The ! is used to instaniate a parameterized type. Again, think <T> 
}

class BinTree(T) {
    T data = null;

    BinTree!T left;
    BinTree!T right;
}

enum Day {
    Sunday,
    Monday,
    Tuesday,
    Wednesday,
    Thursday,
    Friday,
    Saturday,
}

// Use alias to create abbreviations for types

alias IntList = LinkedList!int;
alias NumTree = BinTree!double;

// We can create function templates as well!

T max(T)(T a, T b) {
    if(a < b) 
        return b;

    return a;
}

// Use the ref keyword to pass by referece
void swap(T)(ref T a, ref T b) {
    auto temp = a;

    a = b;
    b = a; 
}

// With templates, we can also parameterize on values, not just types
class Matrix(uint m, uint n, T = int) {
    T[m] rows;
    T[n] columns;
}

auto mat = new Matrix!(3, 3);

```

Speaking of classes, let's talk about properties for a second. A property
is roughly a function that may act like an lvalue, so we can
have the syntax of POD structures (`structure.x = 7`) with the semantics of
getter and setter methods (`object.setX(7)`)!

```d
// Consider a class parameterized on a types T, U

class MyClass(T, U) {
    T _data;
    U _other;

}

// We define "setter" methods as follows

class MyClass(T, U) {
    T _data;
    U _other;
    
    @property void data(T t) {
        _data = t;
    }

    @property void other(U u) {
        _other = u;
    }
}

// And "getter" methods like so
class MyClass(T, U) {
    T _data;
    U _other;
    
    // Constructors are always named `this`
    this(T t, U u) {
        data = t;
        other = u;
    }
    
    // getters
    @property T data() {
        return _data;
    }

    @property U other() {
        return _other;
    }

    // setters    
    @property void data(T t) {
        _data = t;
    }

    @property void other(U u) {
        _other = u;
    }
}
// And we use them in this manner

void main() {
    auto mc = MyClass!(int, string);

    mc.data = 7;
    mc.other = "seven";

    writeln(mc.data);
    writeln(mc.other);
}
```

With properties, we can add any amount of validation to
our getter and setter methods, and keep the clean syntax of
accessing members directly!
Prompt addition of D 2015-06-08 05:30:16 +03:00			`---`
fixed D syntax` 2015-06-08 05:39:01 +03:00			`language: D`
Prompt addition of D 2015-06-08 05:30:16 +03:00			`filename: learnd.d`
			`contributors:`
			`- ["Nick Papanastasiou", "www.nickpapanastasiou.github.io"]`
			`lang: en`
			`---`

So much D 2015-06-10 19:21:11 +03:00			`If you're like me and spend way too much time on the internet, odds are you've heard`
Prompt addition of D 2015-06-08 05:30:16 +03:00			`about [D](http://dlang.org/). The D programming language is a modern, general-purpose,`
			`multi-paradigm language with fantastic support for OOP, functional programming, metaprogramming,`
			`and easy concurrency and parallelism, and runs the gamut from low-level features such as`
			`memory management, inline assembly, and pointer arithmetic, to high-level constructs`
			`such as higher-order functions and generic structures and functions via templates, all with`
			`a pleasant syntax, and blazing fast performance!`

			`D is actively developed by Walter Bright and Andrei Alexandrescu, two super smart, really cool`
			`dudes. With all that out of the way, let's look at some examples!`

fixed D syntax` 2015-06-08 05:39:01 +03:00			```d
Prompt addition of D 2015-06-08 05:30:16 +03:00			`// You know what's coming...`
more D 2015-06-10 18:54:16 +03:00			`module hello;`

Prompt addition of D 2015-06-08 05:30:16 +03:00			`import std.stdio;`

			`// args is optional`
			`void main(string[] args) {`
			`writeln("Hello, World!");`
			`}`

			`// Conditionals and loops work as expected.`
			`import std.stdio;`

			`void main() {`
			`for(int i = 0; i < 5; i++) {`
			`writeln(i);`
			`}`

			`auto n = 1; // use auto for type inferred variables`

			`while(n < 10_000) {`
			`n += n;`
			`}`

			`do {`
			`n -= (n / 2);`
			`} while(n > 0);`

			`// For and while are nice, but in D-land we prefer foreach`
			`foreach(i; 1..int.max) { // The .. creates a continuous range`
			`if(n % 2 == 0)`
			`writeln(i);`
			`}`

D stuff 2015-06-08 05:50:05 +03:00			`foreach_reverse(i; 1..short.max) {`
So much D 2015-06-10 19:18:45 +03:00			`if(n % 2 == 1) {`
Prompt addition of D 2015-06-08 05:30:16 +03:00			`writeln(i);`
So much D 2015-06-10 19:18:45 +03:00			`} else {`
Prompt addition of D 2015-06-08 05:30:16 +03:00			`writeln("No!");`
So much D 2015-06-10 19:18:45 +03:00			`}`
Prompt addition of D 2015-06-08 05:30:16 +03:00			`}`
			`}`
D stuff 2015-06-08 05:50:05 +03:00			```

			We can define new types and functions with `struct`, `class`, `union`, and `enum`. Structs and unions
			`are passed to functions by value (i.e. copied) and classes are passed by reference. Futhermore,`
			`we can use templates to parameterize all of these on both types and values!`

fucking syntax highlighting 2015-06-08 05:52:34 +03:00			```d
D stuff 2015-06-08 05:50:05 +03:00			`// Here, T is a type parameter. Think <T> from C++/C#/Java`
more D 2015-06-10 18:54:16 +03:00			`struct LinkedList(T) {`
D stuff 2015-06-08 05:50:05 +03:00			`T data = null;`
			`LinkedList!(T)* next; // The ! is used to instaniate a parameterized type. Again, think <T>`
			`}`

			`class BinTree(T) {`
			`T data = null;`

			`BinTree!T left;`
			`BinTree!T right;`
			`}`

			`enum Day {`
			`Sunday,`
			`Monday,`
			`Tuesday,`
			`Wednesday,`
			`Thursday,`
			`Friday,`
			`Saturday,`
			`}`

			`// Use alias to create abbreviations for types`

			`alias IntList = LinkedList!int;`
			`alias NumTree = BinTree!double;`
Prompt addition of D 2015-06-08 05:30:16 +03:00
more D 2015-06-10 18:54:16 +03:00			`// We can create function templates as well!`

			`T max(T)(T a, T b) {`
			`if(a < b)`
			`return b;`

			`return a;`
			`}`

			`// Use the ref keyword to pass by referece`
			`void swap(T)(ref T a, ref T b) {`
			`auto temp = a;`

			`a = b;`
			`b = a;`
			`}`

			`// With templates, we can also parameterize on values, not just types`
So much D 2015-06-10 19:21:11 +03:00			`class Matrix(uint m, uint n, T = int) {`
more D 2015-06-10 18:54:16 +03:00			`T[m] rows;`
			`T[n] columns;`
			`}`
So much D 2015-06-10 19:21:11 +03:00
			`auto mat = new Matrix!(3, 3);`

fixed D syntax` 2015-06-08 05:39:01 +03:00			```
more D 2015-06-10 18:54:16 +03:00
			`Speaking of classes, let's talk about properties for a second. A property`
			`is roughly a function that may act like an lvalue, so we can`
			have the syntax of POD structures (`structure.x = 7`) with the semantics of
			getter and setter methods (`object.setX(7)`)!
So much D 2015-06-10 19:18:45 +03:00
			```d
			`// Consider a class parameterized on a types T, U`

			`class MyClass(T, U) {`
			`T _data;`
			`U _other;`

			`}`

			`// We define "setter" methods as follows`

			`class MyClass(T, U) {`
			`T _data;`
			`U _other;`

			`@property void data(T t) {`
			`_data = t;`
			`}`

			`@property void other(U u) {`
			`_other = u;`
			`}`
			`}`

			`// And "getter" methods like so`
			`class MyClass(T, U) {`
			`T _data;`
			`U _other;`

			// Constructors are always named `this`
			`this(T t, U u) {`
			`data = t;`
			`other = u;`
			`}`

			`// getters`
			`@property T data() {`
			`return _data;`
			`}`

			`@property U other() {`
			`return _other;`
			`}`

			`// setters`
			`@property void data(T t) {`
			`_data = t;`
			`}`

			`@property void other(U u) {`
			`_other = u;`
			`}`
			`}`
			`// And we use them in this manner`

			`void main() {`
			`auto mc = MyClass!(int, string);`

			`mc.data = 7;`
			`mc.other = "seven";`

			`writeln(mc.data);`
			`writeln(mc.other);`
			`}`
			```

			`With properties, we can add any amount of validation to`
			`our getter and setter methods, and keep the clean syntax of`
			`accessing members directly!`