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denoland-deno/cli/ops/dispatch_minimal.rs
Ryan Dahl 161cf7cdfd
refactor: Use Tokio's single-threaded runtime (#3844)
This change simplifies how we execute V8. Previously V8 Isolates jumped
around threads every time they were woken up. This was overly complex and
potentially hurting performance in a myriad ways. Now isolates run on
their own dedicated thread and never move.

- blocking_json spawns a thread and does not use a thread pool
- op_host_poll_worker and op_host_resume_worker are non-operational
- removes Worker::get_message and Worker::post_message
- ThreadSafeState::workers table contains WorkerChannel entries instead
  of actual Worker instances.
- MainWorker and CompilerWorker are no longer Futures.
- The multi-threaded version of deno_core_http_bench was removed.
- AyncOps no longer need to be Send + Sync

This PR is very large and several tests were disabled to speed
integration:
- installer_test_local_module_run
- installer_test_remote_module_run
- _015_duplicate_parallel_import
- _026_workers
2020-02-03 18:08:44 -05:00

170 lines
4.6 KiB
Rust

// Copyright 2018-2020 the Deno authors. All rights reserved. MIT license.
// Do not add flatbuffer dependencies to this module.
//! Connects to js/dispatch_minimal.ts sendAsyncMinimal This acts as a faster
//! alternative to flatbuffers using a very simple list of int32s to lay out
//! messages. The first i32 is used to determine if a message a flatbuffer
//! message or a "minimal" message.
use crate::deno_error::GetErrorKind;
use crate::msg::ErrorKind;
use byteorder::{LittleEndian, WriteBytesExt};
use deno_core::Buf;
use deno_core::CoreOp;
use deno_core::ErrBox;
use deno_core::Op;
use deno_core::ZeroCopyBuf;
use futures::future::FutureExt;
use std::future::Future;
use std::pin::Pin;
pub type MinimalOp = dyn Future<Output = Result<i32, ErrBox>>;
#[derive(Copy, Clone, Debug, PartialEq)]
// This corresponds to RecordMinimal on the TS side.
pub struct Record {
pub promise_id: i32,
pub arg: i32,
pub result: i32,
}
impl Into<Buf> for Record {
fn into(self) -> Buf {
let vec = vec![self.promise_id, self.arg, self.result];
let buf32 = vec.into_boxed_slice();
let ptr = Box::into_raw(buf32) as *mut [u8; 3 * 4];
unsafe { Box::from_raw(ptr) }
}
}
pub struct ErrorRecord {
pub promise_id: i32,
pub arg: i32,
pub error_code: i32,
pub error_message: Vec<u8>,
}
impl Into<Buf> for ErrorRecord {
fn into(self) -> Buf {
let v32: Vec<i32> = vec![self.promise_id, self.arg, self.error_code];
let mut v8: Vec<u8> = Vec::new();
for n in v32 {
v8.write_i32::<LittleEndian>(n).unwrap();
}
let mut message = self.error_message;
// Align to 32bit word, padding with the space character.
message.resize((message.len() + 3usize) & !3usize, b' ');
v8.append(&mut message);
v8.into_boxed_slice()
}
}
#[test]
fn test_error_record() {
let expected = vec![
1, 0, 0, 0, 255, 255, 255, 255, 10, 0, 0, 0, 69, 114, 114, 111, 114, 32,
32, 32,
];
let err_record = ErrorRecord {
promise_id: 1,
arg: -1,
error_code: 10,
error_message: "Error".to_string().as_bytes().to_owned(),
};
let buf: Buf = err_record.into();
assert_eq!(buf, expected.into_boxed_slice());
}
pub fn parse_min_record(bytes: &[u8]) -> Option<Record> {
if bytes.len() % std::mem::size_of::<i32>() != 0 {
return None;
}
let p = bytes.as_ptr();
#[allow(clippy::cast_ptr_alignment)]
let p32 = p as *const i32;
let s = unsafe { std::slice::from_raw_parts(p32, bytes.len() / 4) };
if s.len() != 3 {
return None;
}
let ptr = s.as_ptr();
let ints = unsafe { std::slice::from_raw_parts(ptr, 3) };
Some(Record {
promise_id: ints[0],
arg: ints[1],
result: ints[2],
})
}
#[test]
fn test_parse_min_record() {
let buf = vec![1, 0, 0, 0, 3, 0, 0, 0, 4, 0, 0, 0];
assert_eq!(
parse_min_record(&buf),
Some(Record {
promise_id: 1,
arg: 3,
result: 4,
})
);
let buf = vec![];
assert_eq!(parse_min_record(&buf), None);
let buf = vec![5];
assert_eq!(parse_min_record(&buf), None);
}
pub fn minimal_op<D>(d: D) -> impl Fn(&[u8], Option<ZeroCopyBuf>) -> CoreOp
where
D: Fn(i32, Option<ZeroCopyBuf>) -> Pin<Box<MinimalOp>>,
{
move |control: &[u8], zero_copy: Option<ZeroCopyBuf>| {
let mut record = match parse_min_record(control) {
Some(r) => r,
None => {
let error_record = ErrorRecord {
promise_id: 0,
arg: -1,
error_code: ErrorKind::InvalidInput as i32,
error_message: "Unparsable control buffer"
.to_string()
.as_bytes()
.to_owned(),
};
return Op::Sync(error_record.into());
}
};
let is_sync = record.promise_id == 0;
let rid = record.arg;
let min_op = d(rid, zero_copy);
// Convert to CoreOp
let fut = async move {
match min_op.await {
Ok(r) => {
record.result = r;
Ok(record.into())
}
Err(err) => {
let error_record = ErrorRecord {
promise_id: record.promise_id,
arg: -1,
error_code: err.kind() as i32,
error_message: err.to_string().as_bytes().to_owned(),
};
Ok(error_record.into())
}
}
};
if is_sync {
// Warning! Possible deadlocks can occur if we try to wait for a future
// while in a future. The safe but expensive alternative is to use
// tokio_util::block_on.
// This block is only exercised for readSync and writeSync, which I think
// works since they're simple polling futures.
Op::Sync(futures::executor::block_on(fut).unwrap())
} else {
Op::Async(fut.boxed_local())
}
}
}