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₊˚ Elle ♡︎

A procedural programming language built in Rust and QBE

‎ ‎ ╱|、
(˚ˎ 。7
|、˜〵
じしˍ,)ノ

How is this better than C?

  • It's not. It never will be. As it stands, this is a project developed by a single person, me. I am neither smart enough nor efficient enough to mimic an enterprise programming language compiler such as clang.
  • Elle does, however, provide deferring, generic types, methods on structs (allowing for OOP-like semantics), pseudo-namespaces, and function call metadata. There are still many issues with the parser, compiler, and there is a huge lack of optimisations, but you may view these features as an improvement to C.

If you like this project, consider giving it a star!

Hello, World!

Writing a hello world program in Elle is super easy:

use std/io;

fn main() {
    io::println("Hello world!");
}

Let's dissect the code:

  • The fn keyword declares the identifier as a function

  • The word main defines the function as the entry point of our program.

  • The function call io::println is a function which prints all of its arguments.

  • Simple enough! ♡


If statements

  • An if statement is an expression that evaluates a block if the condition is non-zero, with an optional else block which is evaluated if the condition is zero.

  • You can define an if statement and then an optional else statement

  • If statement expressions can be wrapped in () but this is not mandatory

  • There is currently no else if or similar. A workaround is to just define another if statement with your new condition.

  • Example:

i32 a = 0;

if expression {
    a += 1;
} else {
    a -= 1;
}

While loops

  • A while loop is an expression that evaluates the block specified only if the condition is non-zero, otherwise breaks and continues execution on the primary branch.

  • Even though you can loop via recursion, the while loop primitive may be simpler to understand and use in many cases, therefore it is provided in Elle.

  • While loop expressions can be wrapped in () but this is not mandatory

  • There is no do while or finally functionality at the time of writing this.

  • Example:

while expression {
    // do code
}
  • You also have access to block scoped variables inside of this loop. This means you can create a pseudo for loop with the following code:
i32 i = 0;

while i < 10 {
    io::println(i);
    i += 1;
}

Please keep in mind that you also have access to the break and continue keywords while inside of a loop, which break execution early or continue to the next iteration respectively.


For loops

  • A for loop is an expression that has 3 main parts:
  1. Variable declaration - Declaring an iterator to be used in the loop
  2. Condition - The condition to break out of the loop
  3. Variable step - The amount that the variable should increase on each iteration.

Essentially, the loop creates the variable defined in (1), and evaluates the block (code) specified, aswell as (3), until the condition defined in (2) is false (zero), when it returns to the main branch and continues execution.

  • For loop expressions can be wrapped in () but this is not mandatory
  • Basic example of a for loop that prints the digits 0-9 to the stdout:
for i32 i = 0; i < 10; i += 1 {
    io::println(i);
}
  • More advanced example:
use std/io;

fn fact(i64 n) -> i64 {
    if n <= 1 {
        return 1;
    }

    return n * fact(n - 1);
}

fn get_e() {
    f64 res = 0.0;

    for i64 i = 0; i < 50; i += 1 {
        res += 1.0 / fact(i);
    }

    return res;
}

fn main() {
    f64 e = get_e();
    io::dbg(e);
}

Please keep in mind that you also have access to the break and continue keywords while inside of a loop, which break exeuction early or continue to the next iteration respectively.


Standalone blocks

  • A standalone block is somewhat equivalent to an if true statement, although they are not implemented exactly the same internally. It creates a block of code that is executed on a seperate "branch" to the main code in the function. This means that if you run something like defer inside of a standalone block it would call that when the standalone block leaves scope, not the function itself.

Here's a simple example:

fn main() {
    i32 a = 0;

    {
        a += 1;
        // If we do *something* here like calling defer then
        // the defer would run when this block leaves its scope
    }
}

And it is relatively clear how this code is essentially equal to:

fn main() {
    i32 a = 0;

    if true {
        a += 1;
        // If we do *something* here like calling defer then
        // the defer would run when this block leaves its scope
    }
}

Function Metadata

  • Elle can provide you with extra metadata using the ElleMeta struct.

This is done by ensuring the 0th argument of your function is typed to use the ElleMeta struct.
The compiler will automatically supply the struct to you when the function is called, you do not need to manually call it.

This struct is not defined in Elle code, however its equivalent structure may look like:

struct ElleMeta {
    string *exprs; // An array of every argument's expression passed to the function as a string
    string *types; // An array of the type of every argument supplied to the function
    i32 arity;     // The number of arguments. This does NOT include the ElleMeta argument.
    string caller; // The caller of the function as a string
    string file;   // The file where the function was called from
    i32 line;      // The line number of the function call + 1
    i32 column;    // The column number of the function call + 1
};

Important

You do not need to supply the structure yourself. This is automatically managed by the compiler.

This means that here:

fn square(i32 a) {
    return a * 2;
}

fn main() {
    i32 res = square(5);
}

square will not be passed ElleMeta.

However, here:

fn square(ElleMeta meta, i32 a) {
    return a * 2 + meta.arity;
}

fn main() {
    i32 res = square(5);
}

square will be passed ElleMeta. Please notice how it is NOT passed by the caller. It is automatically passed by the compiler if it is required.


Variadic Functions

  • A variadic function is a function that can take in a variable amount of arguments. This works similar to C except that there are macros which allow you to get the argument size.

Here's a basic example of a variadic function which takes in any amount of arguments and returns their sum:

fn add(ElleMeta meta, ...) {
    // Note: `i32` should be the same as the type
    // you are yielding from later.
    variadic args[meta.arity];
    i32 res = 0;

    for i32 i = 0; i < meta.arity; i += 1 {
        res += args.yield(i32);
    }

    return res;
}

Let's go through an explanation for how this works:

  • L1: Declare the function signature.
  • L2: Declare the args variable as a pointer to the start of the variadic arguments. This is denoted by variadic name[length]. This call internally stack allocates memory of the size specified and then calls vastart on the returned pointer.
  • L3: Initialize the result at 0.
  • L5: Declare a for loop with an unused iterator from 0 to the length. This will allow you to loop through all of the arguments that will be provided by the user. This is necessary because you can yield arguments forever, however if you don't know how many there are then you will enter uninitialized memory.
  • L6: Yield the next argument from the args pointer as an i32 type, and add it to the result value
  • L9: Return the summed value. Right before this point, the free call that we deferred earlier would be called.

At the call-site, using this function is easy. It can be done like this:

fn main() {
    i32 res = add(1, 2, 3, 4);
    io::println(res);
}

Examples that contain variadic functions include concat.le and variadic.le.


Lambda functions

Elle allows you to create single line lambda functions.

Here is a basic example of how you can use them:

use std/collections/array;
use std/io;

fn main() {
    Array<i32> *arr = Array::new(1, 2, 3);
    Array<i32> *arr_doubled = arr.map(fn(i32 x) -> x * 2);

    io::println(arr_doubled.to_string()); // [2, 4, 6]
}

Please note the following:

  • These lambdas do not capture surrounding variables
  • They are not automatically passed ElleMeta by the compiler (because there is not enough context to do so)
  • You cannot create multi-line lambdas
  • You cannot declare the interface for a lambda on the type level

This means that these examples won't work:

use std/collections/array;
use std/io;

fn main() {
    Array<i32> *arr = Array::new(1, 2, 3);
    i32 a = 5;

    // The compiler will throw an error here
    Array<i32> *arr_doubled = arr.map(fn(i32 x) -> x * a);
    io::println(arr_doubled.to_string());
}
use std/collections/array;
use std/io;

fn main() {
    Array<i32> *arr = Array::new(1, 2, 3);
    i32 a = 5;

    // The program will segfault here (for now)
    // due to not being passed ElleMeta
    Array<i32> *arr_doubled = arr.map(io::println);
    io::println(arr_doubled.to_string());
}

Exact literals

Note

You will probably never use exact literals when writing pure Elle code. Their only realistic use is to implement language features that don't exist yet.

  • An exact literal is Elle's way of implementing inline IR into the language. This basically means that you can write intermediate language code directly in Elle which compiles without any type, size, scope, or name context.

You can create an "exact literal" by wrapping the inline IR with $$ on both sides of the expression, and ensuring you include a semicolon at the end.

You can also use the manual return directive, which states that Elle should NOT include an automatic return if the function does not return anything by default. You can do this by writing $$__MANUAL_RETURN__$$ at any point in the top level of your function declaration (not in an inner block like an if statement or loop).

Here is a basic example that dereferences an i32 * to the underlying i32:

use std/io;

fn deref(i32 *$$ptr$$) -> i32 {
    $$__MANUAL_RETURN__$$;
    $$%deref.val =w loadsw %ptr$$;
    $$ret %deref.val$$;
}

fn main() {
    i32 some_buffer[1];
    some_buffer[0] = 123;

    // Print the value at the 0th index (pointer start + 0)
    // This is identical to `some_buffer[0]`
    io::println(deref(some_buffer + 0));
}
  • These expressions will expand into the exact characters you type into the intermediate language code.
  • Typing $$storeb 0, %tmp_12$$ will write exactly storeb 0, %tmp_12 into the intermediate language, completely ignoring types, sigils, etc.
  • Only use this for basic operations, it is not intended as a replacement for writing Elle code as block-scoped variables are written with a temporary counter and cannot be referenced directly from exact literals.

Static buffers

  • A static buffer is a basic allocation of stack memory with a specified, static size.

  • You can allocate a buffer with the type buf[size]; syntax.

  • Assuming you wrote the above code, you would now have a variable in scope, defined with the name buf. This variable is a pointer to the type specified.

  • Example:

char out[128];
out[0] = 'a'; // Keep in mind that `out` is a `char *`
io::println(out[0]);

Defer statements

  • A defer statement is commonly used to group together memory allocation and deallocation. A simple explanation is that it stores whatever operation is defined inside and does not run it until the function is about to go out of scope, ie during a return, a block being left, or an implicit return due to the function scope being left.

A very simple example of this is declaring a variable and deferring printing its value, like this:

use std/io;

fn main() {
    i32 i = 0;

    // If this were not in a defer statement, then this would print 0
    // However, it will print 25 instead.
    // Realistically this code only runs right before `return 0`.
    defer io::print(i);

    i += 5;
    i *= i;
}

You can see how this only calls io::print right before it returns 0, which is indeed after the i variable has had changes made to it. This also works if you return in other scopes, such as if statements, while loops, standalone blocks, etc, as stated above. Any defer statements in inner blocks will not be called on any return, rather will only be called when the inner block is about to leave scope.

This also means that if you, hypothetically, design a program like this

use std/io;

fn main() {
    i32 i = 0;
    defer io::print(i);

    {
        defer io::print(i);
        i += 2;
    }

    i *= i;
}

The expected output is 2, then 4. This is because it will call io::print once when the standalone block will leave scope, at which point i is 2, then it will call print_int again when the function itself (main) will leave scope, at which point it will be 4 because i was squared (i *= i).

You can also write something like this:

fn main() {
    i32 i = 0;
    defer io::print(i);

    {
        defer io::print(i);
        i += 2;

        {
            return 0;
        }
    }

    i *= i;
}

Here we expect i (2) to be printed to the console twice. Why? When the function returns, the scope created by the standalone block is also inherently about to be left. Hence, we also need to call all non-root deferrers here.

The most useful application of deferring is for memory management, however.

Consider this code:

use std/io;

fn main() {
    i64 size = 10;
    i64 *numbers = malloc(size * #size(i64));
    defer free(numbers);

    for i64 i = 0; i < size - 1; i += 1 {
        numbers[i] = i * 2;
        i64 res = numbers[i];
        io::printf("numbers[{}] = {}", i, res);
    }

    if numbers[2] + 1 * 5 == 10 {
        // Calls `free` here
        return 1;
    }

    // Calls `free` here
}

Without deferring, you would have to call free at every single place where you return. Not only is this inefficient, but also very easy to forget.

Of course for a function like the above, you are able to determine what path the code will take at compile time, however if you use something like rand() you no longer have the ability to do this, so you need to call free manually at all points where the function leaves its scope. This is an elegant way to prevent that.


Type definitions

  • A type definition is used to differentiate between the scope and size of different variables. You must define a type when declaring variables, taking variables as arguments in a function, and yielding the next value from a variadic argument pointer.

Elle's types are quite similar to C in terms of their definition. They can be a recursive pointer type too such as char ** (An array of strings). Although C has a limit on the number of pointers that a type can have (it is 2 in the C spec), Elle does not.

These are the mappings of types in Elle:

  • void - A mapping to word, usually used for void * or function return signatures
  • bool - A mapping to i8, and works purely as a semantic for boolean literals like true or false that expand to 1 or 0 respectively.
  • char - A mapping to a byte representing a character in ASCII.
  • i8 - A "byte", also known as an 8-bit integer.
  • i16 - A "short", also known as a 16-bit signed integer, or half the size of an i32.
  • i32 - A "word", also known as a 32-bit signed integer.
  • i64 - A signed integer of the size specified by your computer's architecture, up to 64-bit.
  • f32 - A 32-bit signed floating point number.
  • f64 - A 64-bit signed floating point number, providing double the precision of f32.
  • fn - A type that maps to a byte. This is intended to be used as a pointer to the first byte of a function definition.
  • pointer - Denoted by <type> * -> As pointers are just a number, an address in memory, a pointer in Elle is just an i64 that holds extra context by holding another type so that it can use its size to calculate an offset when indexing its memory.
  • string - A mapping to a char *, which is essentially an array of characters, or a "c-string".

Type Conversion / Casting

  • A type conversion consists of converting a variable from one type to another, usually compromising precision if converting to a type with a lower size (f64 -> f32) or having more precision if promoting a type (i32 -> i64).

You can cast a type in a similar manner to C.

Here is an example that casts a float to an integer to add it to another integer:

fn main() {
    f32 a = 1.5;
    i32 b = (i32)a + 2;
}

Casting is not necessary here, because the Elle compiler is smart enough to automatically cast the f32 to an i32 when compiling the arithmetic operation, based on a weight that each type is assigned.


You can also cast to pointer types, however note that, unlike C, casting to a pointer type when using malloc is not necessary because the Elle compiler automatically casts the void * into the type of the variable.

This means you can write:

fn main() {
    f64 *a = malloc(1024 * #size(f64));
}

and Elle will not complain.

Important

Strings are different to regular pointers. Even though they are just char*, the compiler will not allow you to implicitly cast a void* to a string. You will need to explicitly cast it.


Unary operators

  • A unary operator is a token used as a prefix to a literal or identifer to apply some operation to it, like negating it.

There are 5 unary operators in Elle:

  • ! - Logical NOT
  • ~ - Bitwise NOT
  • & - Stack address
  • - - Negative number
  • + - Positive number
  • * - Pointer dereference

Any identifier or literal can be prefixed by one of these operators.

Example of using logical NOT:

use std/io;

fn main() {
    bool myBool = false;

    if !myBool {
        io::println("Hello world!");
    }
}

Example of using bitwise NOT:

use std/io;

fn main() {
    i32 a = 1;

    if ~a == -2 {
        io::println("Hello world!");
    }
}

This can also be used for negative or positive values:

const i64 MAX_SIGNED_LONG = 9_223_372_036_854_775_807;
const i64 MIN_SIGNED_LONG = -MAX_SIGNED_LONG - 1;

Using unary - will multiply the expression by -1 while unary + will multiply the expression by 1.

The unary & operator is used to get the memory address of a local variable in a function. Here is an example:

use std/io;

fn other(i32 *something) {
    io::println(*something);
}

pub fn main() {
    i32 a = 39;
    other(&a);
    return 0;
}

Here we declare a as 39, then we pass the "address" of a to other as a pointer to an i32, then this pointer is dereferenced.


The unary * operator is used to dereference a pointer to a value:

use std/io;

fn other(i32 *a, string *str) {
    io::printf("(fn other)\n\ta = {}\n\tstr = {}", *a, *str);
    *a = 542;
}

fn main() {
    i32 a = 39;
    string str = "Hello world!";

    other(&a, &str);
    io::printf("(fn main)\n\ta = {}", a);
}

The example also implies that you can store values at those dereferenced addresses. You can put as many tokens as you want after the operator. It will yield until:

  • it matches a semicolon (;)
  • it matches an arithmetic operator
  • it reaches the end of the token vector

This means that if you want to manipulate the address before it is dereferenced, you can wrap it in ().

This code:

io::println(*a + 1);

will dereference a and then add 1 to the result.

This code, however:

io::println(*(a + 1));

will first add 1 to the address of a, and then will dereference that address.


Arithmetic operations

  • All arithmetic operations are declared with an expression on the left and right of an operator. This means you can call functions, do other arithmetic operations inside of operations, etc.

This is the mapping defined by Elle:

  • ^ - Xor
  • * - Multiply
  • / - Divide
  • + - Add
  • - - Subtract
  • % - Modulus
  • & - Bitwise And
  • | - Bitwise Or
  • << - Shift Left
  • >> - Shift Right
  • <> - Concatenation (only works on strings)
  • && - Logical And (Not usable when declaring a variable)
  • || - Logical Or (Not usable when declaring a variable)

Keep in mind that you can also use these operators when doing a variable declaration. This means the following code is valid:

use std/io;

fn main() {
    i32 a = 1;
    a ^= 1; // a is now 0
    io::println(a);
}

And of course, this works for every arithmetic operator, not just ^.

Elle follows the standard order of operations described by mathematics (typically defined as BIDMAS or PEMDAS), which means you can also wrap expressions in () to evaluate them before other expressions that may have a higher precedence.

Example of a program that calculates the xor (^) and sum (+) of some values:

use std/io;

fn main() {
    i32 a = 1 + (5 ^ 2); // Xor has a lower precedence than addition

    // We're expecting this to be 8 because
    //  5 ^ 2 = 7 and 7 + 1 = 8, however
    // without the brackets it would be 4
    // because it would evaluate to 6 ^ 2 = 4
    io::println(a);
}

Here's another example, using the string concatenation operator:

use std/io; // std/io contains std/string so we don't need to import it

fn main() {
    string a = "a" <> "b";
    a <>= "c"; // Concatenation can be done declaratively
    io::dbg(a); // Expected: (string) a = "abc"
}

Array literals

  • An array literal is a simple and intuitive syntax to automatically allocate stack memory for a buffer and assign values at each offset based on the literal definition. Essentially, an expression like this:
i32 *some_arr = [512, 1, -3];

would first allocate memory to a buffer and store that in a variable called some_arr with the size of 3 * 4 = 12 (because there are 3 items and the size of an i32 is 4 bytes) and then it would offset the pointer returned and store each value specified at that address.

So it would first store 512 at some_arr + 0, then it would store 1 at some_arr + 4 (offset accounting the size of the array type), then finally would store -3 at some_arr + 8.


You can view a more detailed example of array usage at array.le. Array literals are not required to be assigned to a variable. Please look at this example:

use std/io;

fn other(i64 *arr, i32 val) {
    io::printf("\narr[0] = {}\nval = {}", arr[0], val);
}

fn main() {
    other([MAX_SIGNED_LONG], [123][0]);
}

where we pass an array literal directly to another function or operation. An array literal, internally, will simply return the memory address of the start of the array. As these arrays has no variable declaration linked to them, there is no way to get their type, however we can infer this type based on the type of the values inside, so it can still be indexed correctly.

You can also get the size and length of these arrays. Simply wrap them in #size or #len just like if you wanted to get the size of an array that was declared to a variable. For more information, please read the size directives chapter.


Size directives

  • A "size directive" is similar to a sizeof builtin in C. It returns the size of various definitions verbatim.

There are currently 2 size directives in Elle: #size() and #len()

You can put both types and expressions inside of the #size() directive and it returns the size of the statement provided.

You can only place expressions inside of the #len() directive as it returns the size of the buffer divided by the size of each type. This is exactly equivalent to #size(arr) / #size(arr_type). It will crash if you try to use it on a buffer that wasn't defined in the function that the directive is called from.

For example, take this snippet:

use std/io;

fn other(i32 *buf) {
    io::printf(
        "(fn other)\n\t#size(buf) = {}\n\t#len(buf) = {}",
        #size(buf),
        #len(buf)
    );
}

fn main() {
    i32 buf[100];
    buf[0] = 123;

    io::printf(
        "(fn main)\n\t#size(buf) = {}\n\t#len(buf) = {}",
        #size(buf),
        #len(buf)
    );

    other(buf);
}

At this part:

io::printf(
    "(fn other)\n\t#size(buf) = {}\n\t#len(buf) = {}",
    #size(buf),
    #len(buf)
);

Elle will throw a compilation error. The buf buffer was not defined in the function called other, so therefore the compiler does not have enough context to get its length, as arguments in Elle are not fat (they don't contain extra metadata).

Essentially, contextually this means that the buf variable is just an i32 * to the compiler. As it no longer has context to the size of the buf allocation, it cannot evaluate the #len directive, and throws an error.

In this example:

use std/io;

fn other(i32 *buf) {
    io::printf("(fn other)\n\t#size(buf) = {}", #size(buf));
}

fn main() {
    i32 buf[100];
    buf[0] = 123;

    io::printf(
        "(fn main)\n\t#size(buf) = {}\n\t#len(buf) = {}",
        #size(buf),
        #len(buf)
    );

    other(buf);
}

The code will compile successfully, because #len is no longer used on a buffer that isn't defined in the function where the directive was called.


Finally, here is a basic example of using #len to loop through an array of strings and print their values:

use std/io;

fn main() {
    string *some_array = ["abc", "meow", "test"]";

    for i32 i = 0; i < #len(some_array); i += 1 {
        io::printf("some_array[{}] = {}", i, some_array[i]);
    }
}

Constants

  • A constant is a value that cannot be redeclared. In Elle, constants can only be defined at the top level of files, and vice versa too, where the top level of files can only be constants and functions. You cannot define normal variables at the top level.
  • Constants can be public, declared using the pub keyword.
  • Constants that create pointers (such as string literals) are referenced as the first statement of each function to bring them in scope.

Consider this example that uses constants:

use std/io;

const i32 WIDTH = 100;
const i32 HEIGHT = 24;
const i32 SIZE = WIDTH * HEIGHT;

pub fn main() {
    io::println(SIZE);
    return 0;
}

In the above code, all of the constants are technically function definitions that return the value after the = sign. However, when they're referenced, the function is automatically called. Therefore, you dont need to type SIZE() or similar, you can just directly reference SIZE as if it was a constant.

It is labelled as a "constant", because although it can return a different value (it can call any function), it cannot be redeclared.


Non-base-10 literals

  • These are literal numbers which are not declared in base 10.

These may include:

  • Hex - 0xFFFFFF
  • Octal - 0o777777
  • Binary - 0b111111
  • Scientific - 2.1e3

Basic example:

use std/io;

fn main() {
    i64 a = 0xDEADBEEF;
    i32 b = 0o273451456;
    i32 c = 0b111010011011111010010100101;
    i64 d = 1.2e9;
    f64 e = 2.7182818e2;

    io::dbg(a, b, c, d, e);
}

Imports/modules

Elle's module system works in the following way:

  • Elle will look in the /usr/local/include/elle folder for modules
  • Elle will look in the current working directory for modules

The syntax for importing is as follows:

use path/to/module;

where, in your current directory, there is a ./path/to/module.elle or a ./path/to/module.le file.

The syntax to export a symbol from your current file is as follows:

// ./module.le
pub const i32 myFavouriteNumber = 7;

pub fn foo() {
    return 1;
}

which you can then import

use std/io;
use module;

fn main() {
    io::println(foo() + myFavouriteNumber);
}

You can also add global pub; to your module to automatically make every symbol public in the module. If you want to make a symbol private after declaring them all public, use the local keyword.

Example:

global pub;

const i32 a = 100; // Public
const i32 b = 10; // Public
local const i32 c = 5; // Private

// Private
local fn increment(i32 a) {
    return a + 1;
}

Structs

Structs are allocations in memory with a defined layout. In Elle, these are defined using the struct keyword.

Example:

struct Bar {
    f32 myFloat;
};

struct Foo {
    i32 a;
    Bar bar;
    f64 baz;
};

You can then create these structures like this:

fn main() {
    Foo foo = Foo {
        a = 12,
        bar = Bar {
            myFloat = 10.2
        },
        baz = 3.141592
    };

    io::println(foo.bar.myFloat);
}

If taking a pointer to them from another function, you can do so like this:

use std/io;

fn other(Foo *foo) {
    foo.baz = 17.98;
    io::println(foo.a);
}

fn main() {
    Foo foo = ; // create Foo
    other(&foo);
}

Note

There is no equivalent of the a->b operator in Elle. Any pointer to a struct will automatically be dereferenced before processing any fields in the struct. You can still manually dereference the struct pointer manually if you like, but it will have no difference compared to directly using dot notation. This means that the following code will accurately update the value inside the struct Foo:

use std/io;

struct Foo {
    i32 a;
};

fn other(Foo *foo) {
    foo.a = 5;
}

fn main() {
    Foo foo = Foo { a = 100 };
    other(&foo);
    io::println(foo.a); // foo.a is now 5 not 100
}

You can also define methods on structs (and primitive types):

use std/io;

struct Foo {
    i32 a;
};

fn Foo::add(Foo self, Foo other) {
    return Foo { a = self.a + other.a };
}

fn main() {
    Foo foo1 = Foo { a = 10 };
    Foo foo2 = Foo { a = 30 };

    Foo res1 = foo1.add(foo2);
    Foo res2 = Foo::add(foo1, foo2);

    io::dbg(res1.a, res2.a);
}

You can define fn <Struct name>::<method name>(<Struct name> self, <args>) to create instance methods.
You can then either call them through instance.<method name>() or <Struct name>::<method name>(instance).
In this case, foo1.add(foo2) is an identical expression to Foo::add(foo1, foo2)
For more examples, please view vectors.le

You may also specify that self is a <ty> * instead of a <ty> if you require editing it in-place:

use std/io;

struct Foo {
    i32 a;
};

fn Foo::divideBy(Foo *self, i32 num) {
    self.a /= num;
}

fn main() {
    Foo foo = Foo { a = 10 };
    foo.divideBy(2);

    io::dbg(foo.a); // foo.a = 5
}

The compiler will automatically pass the address of foo instead of foo itself to the function.
In the case of a method that takes in a self pointer, the identical expression to foo1.divideBy(2) is Foo::divideBy(&foo1, 2).


Generics

  • Elle allows you to create generic structs and functions which may hold any inner type.

For example, here's a generic function which allows you to pass both integers and floats:

fn add<T>(T x, T y) {
    return x + y;
}

fn main() {
    add(1, 2);
    add(1.2, 1.3);
}

Notice how seamless using the generic was? Elle was able to infer 2 things here: T is whatever type x and y are, and the return type is also T. This means, even though you can, you usually don't need to explicitly specify all the generics. This is a more verbose but still correct way to do it:

fn add<T>(T x, T y) -> T {
    return x + y;
}

fn main() {
    add<i32>(1, 2);
    add<f32>(1.2, 1.3);
}

Generic structs are created as follows:

struct Foo<T> {
    T a;
};

fn main() {
    Foo<i32> x = Foo { a = 1 };
    Foo<string> y = Foo { a = "hello world!" };
}

In this struct, the a field can be of any type. Note that for structs, you cannot explicitly declare their inner type. You must do so via inference. Elle will infer the inner type based on the struct's variable declaration most of the time. Take the example above, where we declare Foo<i32> x = Foo { a = 1 };. The Elle compiler sees that the type of the left hand side and right hand side are both of Foo, however it sees that the right hand side is a struct declaration of a generic struct, so it uses the left hand side to infer the inner types of the right hand side.

This allows for almost rust-like declarations of generic structs and their methods:

use std/io;

struct Foo<T, U> {
    T a;
    U b;
};

fn Foo::new<T, U>(T a, U b) -> Foo<T, U> {
    return Foo { a = a, b = b };
}

fn Foo::double_all<T, U>(Foo<T, U> *self) {
    self.a *= 2;
    self.b *= 2;
}

fn Foo::get_a<T, U>(Foo<T, U> self) -> T {
    return self.a;
}

fn Foo::get_b<T, U>(Foo<T, U> self) -> U {
    return self.a;
}

fn main() {
    Foo<i32, f32> foo = Foo::new(10, 1.2);
    foo.double_all();
    io::dbg(foo.get_a());
    io::dbg(foo.get_b(), foo.b);
}

From this you can get a quick grasp of how to use generics effectively. The struct uses 2 generics, and as all methods require to define the self argument's type, this means that you need to type <T, U> on every function that takes a Foo<T, U>. This is slightly verbose, and in the future I may allow for syntax to simplify it in the future.


Argc and argv

  • These are variables that can be taken as arguments from the main function that allow you to pass extra data to the executable. Conventionally, the first argument, argc, is the number of arguments, and the second argument, argv, is an array of the arguments, or rather a pointer to them.

Due to Elle's compilation to QBE which implements the C ABI, getting input from argc and argv is actually exactly the same as C. There is practically no difference.

Consider this function which accepts argv and prints them all to the console:

use std/io;

fn main(i32 argc, string *argv) {
    for i32 i = 0; i < argc; i += 1 {
        io::printf("argv[{}] = {}", i, argv[i]);
    }
}

It accepts argc as a signed 32-bit integer and argv as an array of string (denoted by string *, basically an array of strings). These arguments are optional, as you may have noticed from code examples above, where some main functions did not take an argc or argv.

You can also accept string *envp (and string *apple on MacOS/Darwin platforms, which provides arbitrary OS information, such as the path to the executing binary).


Attributes

  • These are tags you can put on functions to specify extra functionality

The current existing attributes are:

  • Alias - Allows you to specify an alias for external functions
  • Volatile - Allows you to specify that Elle should not discard this function if it is unused.

Example:

// Attributes go BEFORE the return type
// The alias attribute will be purposefully ignored
// because this function is not external
fn add(i32 x, i32 y) @alias("foo") @volatile -> i32 {
    return x + y;
}

// The volatile attribute will be purposefully ignored
// because external functions do not generate IR
external fn printf(string formatter, ...) @alias("formatted_print") @volatile;

If you specify an alias attribute on a non-external function, you will only be warned, an error will not be thrown. Keep in mind that external functions do not generate IR, so the @volatile attribute will have no effect on them.


External symbols

  • An external symbol is a definition for a function or constant that was defined elsewhere (such as in C) and is implicitly defined in Elle. This is used to give definition and context to functions that were not defined in Elle but you wish to use in when writing Elle code.

You can do this with the following example:

external fn printf(string formatter, ...);

It essentially tells Elle where it should put the variadic argument starter. You could exclude this, if you like, but you will have to explicitly declare where the variadic arguments begin, because Elle no longer has this context.

You can also make these statements public:

pub external fn fprintf(FILE *fd, string formatter, ...);

In fact the order of prefixes before fn is not enforced, you can write external pub fn and achieve the same result.

You may also alias exported functions, and allow them to be accessible through a pseudo-namespace:

pub external fn InitWindow(i32 width, i32 height, string title) @alias("raylib::init_window");
struct raylib {};

// You can now call raylib::init_window() and it will internally reference the InitWindow symbol

Technical note: This declaration does not emit any IR code. This means that all these definitions do is provide more information and context to the compiler. They do not change the output of the program directly.


♡ If you have any questions, please raise an issue :3

All contributions to this project are welcome and I love talking about this stuff!


How to run

  • Ensure you have Rust, Cargo and the QBE compiler backend.

      $ git clone https://github.com/acquitelol/elle
    
      $ cd elle
    
      $ sudo make

    to install the compiler and standard library (requires root)

    OR

      $ make compile-release

    to get only a compiler executable and not install anything (does not require root)

    • You're done!

♡ You can now run ellec to get a help message of how to use the compiler!

Try compiling a simple example!

  $ ellec ./examples/donut.le && ./donut

Try compiling an example with libraries!

  $ ellec ./examples/ball.le -Dtime -Clink-flags -lraylib && ./ball

Licensing


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