| .. | ||
| src | ||
| Cargo.toml | ||
| curl.mers | ||
| fail.mers | ||
| mers.wasm | ||
| README.md | ||
| t.mers | ||
| try.mers | ||
mers
Mers is a high-level programming language. It is designed to be safe (it doesn't crash at runtime) and as simple as possible.
Install from crates.io:
cargo install mers
what makes it special
Simplicity
Mers is simple. There are only a few expressions:
- Values (
1,-2.4,"my string") - Blocks (
{ statement1, statement2 }- comma is optional, newline preferred) - Tuples (
(5, 2)) and Objects ({ x: 5, y: 2 }) - Variable initializations (
:=) - Assignments (
=) - Variables:
my_var,&my_var - If statements:
if <condition> <then> [else <else>] - Functions:
arg -> <do something> - Function calls:
arg.function- or
arg1.function(arg2, arg3)(nicer syntax for(arg1, arg2, arg3).function)
- or
- Type annotations:
[Int] (1, 2, 3).sum- Type definitions:
[[MyType] Int],[[TypeOfMyVar] := my_var]
- Type definitions:
Everything else is implemented as a function.
Types and Safety
Mers is built around a type-system where a value could be one of multiple types.
x := if condition { 12 } else { "something went wrong" }
In mers, the compiler tracks all the types in your program,
and it will catch every possible crash before the program even runs:
If we tried to use x as an int, the compiler would complain since it might be a string, so this does not compile:
list := (1, 2, if true 3 else "not an int")
list.sum.println
Type-safety for functions is different from what you might expect. You don't need to tell mers what type your function's argument has - you just use it however you want as if mers was a dynamically typed language:
sum_doubled := iter -> {
one := iter.sum
(one, one).sum
}
(1, 2, 3).sum_doubled.println
We could try to use the function improperly by passing a string instead of an int:
(1, 2, "3").sum_doubled.println
But mers will catch this and show an error, because the call to sum inside of sum_doubled would fail.
Type Annotations
Eventually, mers' type-checking will cause a situation where calling f1 causes an error,
because it calls f2, which calls f3,
which tries to call f4 or f5, but neither of these calls are type-safe,
because, within f4, ..., and within f5, ..., and so on.
Error like this are basically unreadable, but they can happen.
To prevent this, we should type-check our functions (at least the non-trivial ones) to make sure they do what we want them to do:
f1 := /* ... */
// Calling `f1` with an int should cause it to return a string.
// If `f1` can't be called with an int or it doesn't return a string, the compiler gives us an error here.
[(Int -> String)] f1
We can still try calling f1 with non-int arguments, and it may still be type-safe and work perfectly fine.
If you want to deny any non-int arguments, the type annotation has to be in f1's declaration or you have to redeclare f1:
f1 := [(Int -> String)] /* ... */
// or
f1 := /* ... */
f1 := [(Int -> String)] f1
This hard-limits the type of f1, similar to what you would expect from functions in statically typed programming languages.
However, even when using type annotations for functions, mers can be more dynamic than most other languages:
f1 := [(Int/Float -> String, String -> ()/Float)] /* ... */
Here, f1's return type depends on the argument's type: For numbers, f1 returns a string, and for strings, f1 returns an empty tuple or a float.
Of course, if f1's implementation doesn't satisfy these requirements, we get an error.
Error Handling
Errors in mers are normal values.
For example, ("ls", ("/")).run_command has the return type ({Int/Bool}, String, String)/RunCommandError.
This means it either returns the result of the command (exit code, stdout, stderr) or an error (a value of type RunCommandError).
So, if we want to print the programs stdout, we could try
(s, stdout, stderr) := ("ls", ("/")).run_command
stdout.println
But if we encountered a RunCommandError, mers wouldn't be able to assign the value to (s, stdout, stderr), so this doesn't compile.
Instead, we need to handle the error case, using the try function:
("ls", ("/")).run_command.try((
(s, stdout, stderr) -> stdout.println,
error -> error.println,
))
For your own errors, you could use an object: {err: { read_file_err: { path: /* ... */, reason: /* ... */ } } }.
This makes it clear that the value represents an error and it is convenient when pattern-matching:
{ err: _ }: all errors{ err: { read_file_err: _ } }: only read-file errors{ err: { parse_err: _ } }: only parse errors{ err: { read_file_err: { path: _, reason: { permission_denied: _ } } } }: only read-file: permission-denied errors- ...