// Copyright 2018-2019 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::state::ThreadSafeState; use deno::Buf; use deno::CoreOp; use deno::Op; use deno::PinnedBuf; use futures::Future; const DISPATCH_MINIMAL_TOKEN: i32 = 0xCAFE; const OP_READ: i32 = 1; const OP_WRITE: i32 = 2; #[derive(Copy, Clone, Debug, PartialEq)] // This corresponds to RecordMinimal on the TS side. pub struct Record { pub promise_id: i32, pub op_id: i32, pub arg: i32, pub result: i32, } impl Into for Record { fn into(self) -> Buf { let vec = vec![ DISPATCH_MINIMAL_TOKEN, self.promise_id, self.op_id, self.arg, self.result, ]; let buf32 = vec.into_boxed_slice(); let ptr = Box::into_raw(buf32) as *mut [u8; 5 * 4]; unsafe { Box::from_raw(ptr) } } } pub fn parse_min_record(bytes: &[u8]) -> Option { if bytes.len() % std::mem::size_of::() != 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() < 5 { return None; } let ptr = s.as_ptr(); let ints = unsafe { std::slice::from_raw_parts(ptr, 5) }; if ints[0] != DISPATCH_MINIMAL_TOKEN { return None; } Some(Record { promise_id: ints[1], op_id: ints[2], arg: ints[3], result: ints[4], }) } #[test] fn test_parse_min_record() { let buf = vec![ 0xFE, 0xCA, 0, 0, 1, 0, 0, 0, 2, 0, 0, 0, 3, 0, 0, 0, 4, 0, 0, 0, ]; assert_eq!( parse_min_record(&buf), Some(Record { promise_id: 1, op_id: 2, 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 dispatch_minimal( state: &ThreadSafeState, mut record: Record, zero_copy: Option, ) -> CoreOp { let is_sync = record.promise_id == 0; let min_op = match record.op_id { OP_READ => ops::read(record.arg, zero_copy), OP_WRITE => ops::write(record.arg, zero_copy), _ => unimplemented!(), }; let state = state.clone(); let fut = Box::new(min_op.then(move |result| -> Result { match result { Ok(r) => { record.result = r; } Err(err) => { // TODO(ry) The dispatch_minimal doesn't properly pipe errors back to // the caller. debug!("swallowed err {}", err); record.result = -1; } } let buf: Buf = record.into(); state.metrics_op_completed(buf.len()); Ok(buf) })); if is_sync { Op::Sync(fut.wait().unwrap()) } else { Op::Async(fut) } } mod ops { use crate::deno_error; use crate::resources; use crate::tokio_write; use deno::PinnedBuf; use futures::Future; type MinimalOp = dyn Future + Send; pub fn read(rid: i32, zero_copy: Option) -> Box { debug!("read rid={}", rid); let zero_copy = match zero_copy { None => { return Box::new(futures::future::err(deno_error::no_buffer_specified())) } Some(buf) => buf, }; match resources::lookup(rid as u32) { None => Box::new(futures::future::err(deno_error::bad_resource())), Some(resource) => Box::new( tokio::io::read(resource, zero_copy) .map_err(deno_error::DenoError::from) .and_then(move |(_resource, _buf, nread)| Ok(nread as i32)), ), } } pub fn write(rid: i32, zero_copy: Option) -> Box { debug!("write rid={}", rid); let zero_copy = match zero_copy { None => { return Box::new(futures::future::err(deno_error::no_buffer_specified())) } Some(buf) => buf, }; match resources::lookup(rid as u32) { None => Box::new(futures::future::err(deno_error::bad_resource())), Some(resource) => Box::new( tokio_write::write(resource, zero_copy) .map_err(deno_error::DenoError::from) .and_then(move |(_resource, _buf, nwritten)| Ok(nwritten as i32)), ), } } }