ableos/hblang
2024-06-23 09:09:33 +02:00
..
examples adding more elaborate directive example 2024-06-15 09:37:19 +02:00
src tests pass again 2024-06-23 09:09:33 +02:00
tests tests pass again 2024-06-23 09:09:33 +02:00
text-prj making modules work 2024-06-01 20:30:15 +02:00
build.rs whew 2024-06-21 23:07:32 +02:00
Cargo.toml removing deendence on macros with a simple build script 2024-05-15 14:36:38 +02:00
README.md cleaning up the docs 2024-06-20 11:18:36 +02:00

HERE SHALL THE DOCUMENTATION RESIDE

Enforced Political Views

  • worse is better
  • less is more
  • embrace unsafe {}
  • adhere macro_rules!
  • pessimization == death (put in std::pin::Pin and left with hungry crabs)
  • importing external dependencies == death (fn(dependencies) -> ExecutionStrategy)
  • above sell not be disputed, discussed, or questioned

What hblang is

Holey-Bytes-Language (hblang for short) (*.hb) is the only true language targeting hbvm byte code. hblang is low level, manually managed, and procedural. Its rumored to be better then writing hbasm and you should probably use it for complex applications.

What hblang isnt't

hblang knows what it isn't, because it knows what it is, hblang computes this by sub...

Examples

Examples are also used in tests. To add an example that runs during testing add:

#### <name>
```hb
<example>
```

and also:

<name> => README;

to the run_tests macro at the bottom of the src/codegen.rs.

Tour Examples

Following examples incrementally introduce language features and syntax.

main_fn

main := fn(): int {
	return 1;
}

arithmetic

main := fn(): int {
	return 10 - 20 / 2 + 4 * (2 + 2) - 4 * 4 + 1;
}

functions

main := fn(): int {
	return add_one(10) + add_two(20);
}

add_two := fn(x: int): int {
	return x + 2;
}

add_one := fn(x: int): int {
	return x + 1;
}

if_statements

main := fn(): int {
	return fib(10);
}

fib := fn(x: int): int {
	if x <= 2 {
		return 1;
	} else {
		return fib(x - 1) + fib(x - 2);
	}
}

variables

main := fn(): int {
	a := 1;
	b := 2;
	a = a + 1;
	return a - b;
}

loops

main := fn(): int {
	return fib(10);
}

fib := fn(n: int): int {
	a := 0;
	b := 1;
	loop {
		if n == 0 break;
		c := a + b;
		a = b;
		b = c;
		n -= 1;

		stack_reclamation_edge_case := 0;

		continue;
	}
	return a;
}

pointers

main := fn(): int {
	a := 1;
	b := &a;
	modify(b);
	drop(a);
	stack_reclamation_edge_case := 0;
	return *b - 2;
}

modify := fn(a: ^int): void {
	*a = 2;
	return;
}

drop := fn(a: int): void {
	return;
}

structs

Ty := struct {
	a: int,
	b: int,
}

Ty2 := struct {
	ty: Ty,
	c: int,
}

main := fn(): int {
	finst := Ty2.{ ty: Ty.{ a: 4, b: 1 }, c: 3 };
	inst := odher_pass(finst);
	if inst.c == 3 {
		return pass(&inst.ty);
	}
	return 0;
}

pass := fn(t: ^Ty): int {
	return t.a - t.b;
}

odher_pass := fn(t: Ty2): Ty2 {
	return t;
}

struct_operators

Point := struct {
	x: int,
	y: int,
}

Rect := struct {
	a: Point,
	b: Point,
}

main := fn(): int {
	a := Point.(1, 2);
	b := Point.(3, 4);

	d := Rect.(a + b, b - a);
	d2 := Rect.(Point.(0, 0) - b, a);
	d2 = d2 + d;

	c := d2.a + d2.b;
	return c.x + c.y;
}

global_variables

global_var := 10;

complex_global_var := fib(global_var) - 5;

fib := fn(n: int): int {
	if 2 > n {
		return n;
	}
	return fib(n - 1) + fib(n - 2);
}

main := fn(): int {
	return complex_global_var;
}

note: values of global variables are evaluated at compile time

directives

Type := struct {
	brah: int,
	blah: int,
}

main := fn(): int {
	byte := @as(u8, 10);
	same_type_as_byte := @as(@TypeOf(byte), 30);
	wide_uint := @as(u32, 40);
	truncated_uint := @as(u8, @intcast(wide_uint));
	size_of_Type_in_bytes := @sizeof(Type);
	align_of_Type_in_bytes := @alignof(Type);
	hardcoded_pointer := @as(^u8, @bitcast(10));
	ecall_that_returns_int := @eca(int, 1, Type.(10, 20), 5, 6);
	return 0;
}
  • @TypeOf(<expr>): results into literal type of whatever the type of <expr> is, <expr> is not included in final binary
  • @as(<ty>, <expr>): hint to the compiler that @TypeOf(<expr>) == <ty>
  • @intcast(<expr>): needs to be used when conversion of @TypeOf(<expr>) would loose precision (widening of integers is implicit)
  • @sizeof(<ty>), @alignof(<ty>): I think explaining this would insult your intelligence
  • @bitcast(<expr>): tell compiler to assume @TypeOf(<expr>) is whatever is inferred, so long as size and alignment did not change
  • @eca(<ty>, <expr>...): invoke eca instruction, where <ty> is the type this will return and <expr>... are arguments passed to the call

Incomplete Examples

generic_types

Vec := fn($Elem: type): type {
	return struct {
		data: ^Elem,
		len: uint,
		cap: uint,
	};
}

main := fn(): int {
	i := 69;
	vec := Vec(int).{
		data: &i,
		len: 1,
		cap: 1,
	};
	return *vec.data;
}

fb_driver

arm_fb_ptr := fn(): int return 100;
x86_fb_ptr := fn(): int return 100;


check_platform := fn(): int {
    return x86_fb_ptr();
}

set_pixel := fn(x: int, y: int, width: int): int {
    pix_offset := y * width + x;

    return 0;
}

main := fn(): int {
    fb_ptr := check_platform();
    width := 100;
    height := 30;
    x:= 0;
    y:= 0;

    loop {
        if x <= height + 1 {
            set_pixel(x,y,width);
            x = x + 1;
        } else {
            set_pixel(x,y,width);
            x = 0;
            y = y + 1;
        }
        if y == width {
            break;
        }
    }
    return 0;
}

Purely Testing Examples

different_types


Color := struct {
	r: u8,
	g: u8,
	b: u8,
	a: u8,
}

Point := struct {
	x: u32,
	y: u32,
}

Pixel := struct {
	color: Color,
	point: Point,
}

main := fn(): int {
	pixel := Pixel.{
		color: Color.{
			r: 255,
			g: 0,
			b: 0,
			a: 255,
		},
		point: Point.{
			x: 0,
			y: 2,
		},
	};

	if *(&pixel.point.x + 1) != 2 {
		return 0;
	}

	if *(&pixel.point.y - 1) != 0 {
		return 64;
	}

	return pixel.point.x + pixel.point.y + pixel.color.r
		+ pixel.color.g + pixel.color.b + pixel.color.a;
}