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298 lines
9.7 KiB
Markdown
298 lines
9.7 KiB
Markdown
---
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language: neat
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contributors:
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- ["Feep", "https://github.com/FeepingCreature"]
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filename: LearnNeat.nt
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---
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Neat is basically a smaller version of D1 with some experimental syntax and a focus on terseness without losing the basic C-like syntax.
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[Read more here.](https://github.com/FeepingCreature/fcc/wiki)
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```c
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// single line comments start with //
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/*
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multiline comments look like this
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*/
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/+
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or this
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/+ these can be nested too, same as D +/
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+/
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// Module name. This has to match the filename/directory.
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module LearnNeat;
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// Make names from another module visible in this one.
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import std.file;
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// You can import multiple things at once.
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import std.math, std.util;
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// You can even group up imports!
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import std.(process, socket);
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// Global functions!
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void foo() { }
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// Main function, same as in C.
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// string[] == "array of strings".
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// "string" is just an alias for char[],
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void main(string[] args) {
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// Call functions with "function expression".
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writeln "Hello World";
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// You can do it like in C too... if you really want.
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writeln ("Hello World");
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// Declare a variable with "type identifier"
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string arg = ("Hello World");
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writeln arg;
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// (expression, expression) forms a tuple.
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// There are no one-value tuples though.
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// So you can always use () in the mathematical sense.
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// (string) arg; <- is an error
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/*
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byte: 8 bit signed integer
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char: 8 bit UTF-8 byte component.
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short: 16 bit signed integer
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int: 32 bit signed integer
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long: 64 bit signed integer
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float: 32 bit floating point
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double: 64 bit floating point
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real: biggest native size floating point (80 bit on x86).
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bool: true or false
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*/
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int a = 5;
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bool b = true;
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// as in C, && and || are short-circuit evaluating.
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b = b && false;
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assert(b == false);
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// "" are "format strings". So $variable will be substituted at runtime
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// with a formatted version of the variable.
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writeln "$a";
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// This will just print $a.
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writeln `$a`;
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// you can format expressions with $()
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writeln "$(2+2)";
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// Note: there is no special syntax for characters.
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char c = "a";
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// Cast values by using type: expression.
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// There are three kinds of casts:
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// casts that just specify conversions that would be happening automatically
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// (implicit casts)
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float f = float:5;
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float f2 = 5; // would also work
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// casts that require throwing away information or complicated computation -
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// those must always be done explicitly
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// (conversion casts)
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int i = int:f;
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// int i = f; // would not work!
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// and, as a last attempt, casts that just reinterpret the raw data.
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// Those only work if the types have the same size.
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string s = "Hello World";
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// Arrays are (length, pointer) pairs.
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// This is a tuple type. Tuple types are (type, type, type).
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// The type of a tuple expression is a tuple type. (duh)
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(int, char*) array = (int, char*): s;
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// You can index arrays and tuples using the expression[index] syntax.
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writeln "pointer is $(array[1]) and length is $(array[0])";
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// You can slice them using the expression[from .. to] syntax.
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// Slicing an array makes another array.
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writeln "$(s[0..5]) World";
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// Alias name = expression gives the expression a name.
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// As opposed to a variable, aliases do not have an address
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// and can not be assigned to. (Unless the expression is assignable)
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alias range = 0 .. 5;
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writeln "$(s[range]) World";
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// You can iterate over ranges.
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for int i <- range {
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write "$(s[i])";
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}
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writeln " World";
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// Note that if "range" had been a variable, it would be 'empty' now!
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// Range variables can only be iterated once.
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// The syntax for iteration is "expression <- iterable".
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// Lots of things are iterable.
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for char c <- "Hello" { write "$c"; }
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writeln " World";
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// For loops are "for test statement";
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alias test = char d <- "Hello";
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for test write "$d";
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writeln " World\t\x05"; // note: escapes work
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// Pointers: function the same as in C, btw. The usual.
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// Do note: the pointer star sticks with the TYPE, not the VARIABLE!
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string* p;
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assert(p == null); // default initializer
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p = &s;
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writeln "$(*p)";
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// Math operators are (almost) standard.
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int x = 2 + 3 * 4 << 5;
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// Note: XOR is "xor". ^ is reserved for exponentiation (once I implement that).
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int y = 3 xor 5;
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int z = 5;
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assert(z++ == 5);
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assert(++z == 7);
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writeln "x $x y $y z $z";
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// As in D, ~ concatenates.
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string hewo = "Hello " ~ "World";
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// == tests for equality, "is" tests for identity.
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assert (hewo == s);
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assert !(hewo is s);
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// same as
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assert (hewo !is s);
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// Allocate arrays using "new array length"
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int[] integers = new int[] 10;
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assert(integers.length == 10);
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assert(integers[0] == 0); // zero is default initializer
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integers = integers ~ 5; // This allocates a new array!
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assert(integers.length == 11);
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// This is an appender array.
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// Instead of (length, pointer), it tracks (capacity, length, pointer).
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// When you append to it, it will use the free capacity if it can.
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// If it runs out of space, it reallocates - but it will free the old array automatically.
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// This makes it convenient for building arrays.
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int[auto~] appender;
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appender ~= 2;
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appender ~= 3;
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appender.free(); // same as {mem.free(appender.ptr); appender = null;}
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// Scope variables are automatically freed at the end of the current scope.
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scope int[auto~] someOtherAppender;
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// This is the same as:
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int[auto~] someOtherAppender2;
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onExit { someOtherAppender2.free; }
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// You can do a C for loop too
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// - but why would you want to?
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for (int i = 0; i < 5; ++i) { }
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// Otherwise, for and while are the same.
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while int i <- 0..4 {
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assert(i == 0);
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break; // continue works too
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} then assert(false); // if we hadn't break'd, this would run at the end
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// This is the height of loopdom - the produce-test-consume loop.
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do {
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int i = 5;
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} while (i == 5) {
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assert(i == 5);
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break; // otherwise we'd go back up to do {
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}
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// This is a nested function.
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// Nested functions can access the surrounding function.
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string returnS() { return s; }
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writeln returnS();
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// Take the address of a function using &
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// The type of a global function is ReturnType function(ParameterTypeTuple).
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void function() foop = &foo;
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// Similarly, the type of a nested function is ReturnType delegate(ParameterTypeTuple).
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string delegate() returnSp = &returnS;
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writeln returnSp();
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// Class member functions and struct member functions also fit into delegate variables.
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// In general, delegates are functions that carry an additional context pointer.
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// ("fat pointers" in C)
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// Allocate a "snapshot" with "new delegate".
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// Snapshots are not closures! I used to call them closures too,
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// but then my Haskell-using friends yelled at me so I had to stop.
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// The difference is that snapshots "capture" their surrounding context
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// when "new" is used.
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// This allows things like this
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int delegate(int) add(int a) {
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int add_a(int b) { return a + b; }
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// This does not work - the context of add_a becomes invalid
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// when add returns.
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// return &add_a;
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// Instead:
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return new &add_a;
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}
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int delegate(int) dg = add 2;
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assert (dg(3) == 5);
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// or
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assert (((add 2) 3) == 5);
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// or
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assert (add 2 3 == 5);
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// add can also be written as
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int delegate(int) add2(int a) {
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// this is an implicit, nameless nested function.
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return new λ(int b) { return a + b; }
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}
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// or even
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auto add3(int a) { return new λ(int b) -> a + b; }
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// hahahaaa
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auto add4 = λ(int a) -> new λ(int b) -> a + b;
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assert(add4 2 3 == 5);
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// If your keyboard doesn't have a λ (you poor sod)
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// you can use \ too.
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auto add5 = \(int a) -> new \(int b) -> a + b;
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// Note!
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auto nestfun = λ() { } // There is NO semicolon needed here!
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// "}" can always substitute for "};".
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// This provides syntactic consistency with built-in statements.
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// This is a class.
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// Note: almost all elements of Neat can be used on the module level
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// or just as well inside a function.
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class C {
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int a;
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void writeA() { writeln "$a"; }
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// It's a nested class - it exists in the context of main().
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// so if you leave main(), any instances of C become invalid.
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void writeS() { writeln "$s"; }
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}
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C cc = new C;
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// cc is a *reference* to C. Classes are always references.
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cc.a = 5; // Always used for property access.
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auto ccp = &cc;
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(*ccp).a = 6;
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// or just
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ccp.a = 7;
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cc.writeA();
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cc.writeS(); // to prove I'm not making things up
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// Interfaces work same as in D, basically. Or Java.
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interface E { void doE(); }
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// Inheritance works same as in D, basically. Or Java.
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class D : C, E {
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override void writeA() { writeln "hahahahaha no"; }
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override void doE() { writeln "eeeee"; }
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// all classes inherit from Object. (toString is defined in Object)
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override string toString() { return "I am a D"; }
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}
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C cd = new D;
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// all methods are always virtual.
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cd.writeA();
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E e = E:cd; // dynamic class cast!
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e.doE();
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writeln "$e"; // all interfaces convert to Object implicitly.
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// Templates!
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// Templates are parameterized namespaces, taking a type as a parameter.
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template Templ(T) {
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alias hi = 5, hii = 8;
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// Templates always have to include something with the same name as the template
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// - this will become the template's _value_.
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// Static ifs are evaluated statically, at compile-time.
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// Because of this, the test has to be a constant expression,
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// or something that can be optimized to a constant.
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static if (types-equal (T, int)) {
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alias Templ = hi;
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} else {
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alias Templ = hii;
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}
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}
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assert(Templ!int == 5);
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assert(Templ!float == 8);
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}
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```
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## Topics Not Covered
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* Extended iterator types and expressions
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* Standard library
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* Conditions (error handling)
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* Macros
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