// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use deno_core::error::AnyError;
use deno_core::futures::channel::mpsc;
use deno_core::OpState;
use std::cell::RefCell;
use std::mem::size_of;
use std::os::raw::c_char;
use std::os::raw::c_short;
use std::path::Path;
use std::rc::Rc;
mod call;
mod callback;
mod dlfcn;
mod ir;
mod repr;
mod r#static;
mod symbol;
mod turbocall;
use call::op_ffi_call_nonblocking;
use call::op_ffi_call_ptr;
use call::op_ffi_call_ptr_nonblocking;
use callback::op_ffi_unsafe_callback_close;
use callback::op_ffi_unsafe_callback_create;
use callback::op_ffi_unsafe_callback_ref;
use dlfcn::op_ffi_load;
use dlfcn::ForeignFunction;
use r#static::op_ffi_get_static;
use repr::*;
use symbol::NativeType;
use symbol::Symbol;
#[cfg(not(target_pointer_width = "64"))]
compile_error!("platform not supported");
const _: () = {
assert!(size_of::<c_char>() == 1);
assert!(size_of::<c_short>() == 2);
assert!(size_of::<*const ()>() == 8);
};
pub(crate) const MAX_SAFE_INTEGER: isize = 9007199254740991;
pub(crate) const MIN_SAFE_INTEGER: isize = -9007199254740991;
pub const UNSTABLE_FEATURE_NAME: &str = "ffi";
fn check_unstable(state: &OpState, api_name: &str) {
// TODO(bartlomieju): replace with `state.feature_checker.check_or_exit`
// once we phase out `check_or_exit_with_legacy_fallback`
state
.feature_checker
.check_or_exit_with_legacy_fallback(UNSTABLE_FEATURE_NAME, api_name)
}
pub trait FfiPermissions {
fn check_partial(&mut self, path: Option<&Path>) -> Result<(), AnyError>;
}
pub(crate) type PendingFfiAsyncWork = Box<dyn FnOnce()>;
pub(crate) struct FfiState {
pub(crate) async_work_sender: mpsc::UnboundedSender<PendingFfiAsyncWork>,
pub(crate) async_work_receiver: mpsc::UnboundedReceiver<PendingFfiAsyncWork>,
}
deno_core::extension!(deno_ffi,
deps = [ deno_web ],
parameters = [P: FfiPermissions],
ops = [
op_ffi_load<P>,
op_ffi_get_static,
op_ffi_call_nonblocking,
op_ffi_call_ptr<P>,
op_ffi_call_ptr_nonblocking<P>,
op_ffi_ptr_create<P>,
op_ffi_ptr_equals<P>,
op_ffi_ptr_of<P>,
op_ffi_ptr_of_exact<P>,
op_ffi_ptr_offset<P>,
op_ffi_ptr_value<P>,
op_ffi_get_buf<P>,
op_ffi_buf_copy_into<P>,
op_ffi_cstr_read<P>,
op_ffi_read_bool<P>,
op_ffi_read_u8<P>,
op_ffi_read_i8<P>,
op_ffi_read_u16<P>,
op_ffi_read_i16<P>,
op_ffi_read_u32<P>,
op_ffi_read_i32<P>,
op_ffi_read_u64<P>,
op_ffi_read_i64<P>,
op_ffi_read_f32<P>,
op_ffi_read_f64<P>,
op_ffi_read_ptr<P>,
op_ffi_unsafe_callback_create<P>,
op_ffi_unsafe_callback_close,
op_ffi_unsafe_callback_ref,
],
esm = [ "00_ffi.js" ],
event_loop_middleware = event_loop_middleware,
);
fn event_loop_middleware(
op_state_rc: Rc<RefCell<OpState>>,
_cx: &mut std::task::Context,
) -> bool {
// FFI callbacks coming in from other threads will call in and get queued.
let mut maybe_scheduling = false;
let mut op_state = op_state_rc.borrow_mut();
if let Some(ffi_state) = op_state.try_borrow_mut::<FfiState>() {
// TODO(mmastrac): This should be a SmallVec to avoid allocations in most cases
let mut work_items = Vec::with_capacity(1);
while let Ok(Some(async_work_fut)) =
ffi_state.async_work_receiver.try_next()
{
// Move received items to a temporary vector so that we can drop the `op_state` borrow before we do the work.
work_items.push(async_work_fut);
maybe_scheduling = true;
}
// Drop the op_state and ffi_state borrows
drop(op_state);
for async_work_fut in work_items.into_iter() {
async_work_fut();
}
}
maybe_scheduling
}