| .. | ||
| platform | ||
| .gitignore | ||
| Hello.roc | ||
| README.md | ||
Hello, World!
To run, cd into this directory and run:
$ cargo run Hello.roc
To run in release mode instead, do:
$ cargo run --release Hello.roc
Design Notes
This demonstrates the basic design of hosts: Roc code gets compiled into a pure
function (in this case, a thunk that always returns "Hello, World!") and
then the host calls that function. Fundamentally, that's the whole idea! The host
might not even have a main - it could be a library, a plugin, anything.
Everything else is built on this basic "hosts calling linked pure functions" design.
For example, things get more interesting when the compiled Roc function returns
a Task - that is, a tagged union data structure containing function pointers
to callback closures. This lets the Roc pure function describe arbitrary
chainable effects, which the host can interpret to perform I/O as requested by
the Roc program. (The tagged union Task would have a variant for each supported
I/O operation.)
In this trivial example, it's very easy to line up the API between the host and the Roc program. In a more involved host, this would be much trickier - especially if the API were changing frequently during development.
The idea there is to have a first-class concept of "glue code" which host authors
can write (it would be plain Roc code, but with some extra keywords that aren't
available in normal modules - kinda like port module in Elm), and which
describe both the Roc-host/C boundary as well as the Roc-host/Roc-app boundary.
Roc application authors only care about the Roc-host/Roc-app portion, and the
host author only cares about the Roc-host/C boundary when implementing the host.
Using this glue code, the Roc compiler can generate C header files describing the
boundary. This not only gets us host compatibility with C compilers, but also
Rust FFI for free, because rust-bindgen
generates correct Rust FFI bindings from C headers.