// Copyright 2013 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. /*! Generic communication channels for things that can be represented as, or transformed to and from, byte vectors. The `FlatPort` and `FlatChan` types implement the generic channel and port interface for arbitrary types and transport strategies. It can particularly be used to send and receive serializable types over I/O streams. `FlatPort` and `FlatChan` implement the same comm traits as pipe-based ports and channels. # Example This example sends boxed integers across tasks using serialization. ~~~ let (port, chan) = serial::pipe_stream(); do task::spawn || { for int::range(0, 10) |i| { chan.send(@i) } } for int::range(0, 10) |i| { assert @i == port.recv() } ~~~ # Safety Note Flat pipes created from `io::Reader`s and `io::Writer`s share the same blocking properties as the underlying stream. Since some implementations block the scheduler thread, so will their pipes. */ // The basic send/recv interface FlatChan and PortChan will implement use core::io; use core::comm::GenericChan; use core::comm::GenericPort; use core::sys::size_of; use core::vec; /** A FlatPort, consisting of a `BytePort` that receives byte vectors, and an `Unflattener` that converts the bytes to a value. Create using the constructors in the `serial` and `pod` modules. */ pub struct FlatPort { unflattener: U, byte_port: P } /** A FlatChan, consisting of a `Flattener` that converts values to byte vectors, and a `ByteChan` that transmits the bytes. Create using the constructors in the `serial` and `pod` modules. */ pub struct FlatChan { flattener: F, byte_chan: C } /** Constructors for flat pipes that using serialization-based flattening. */ pub mod serial { pub use DefaultEncoder = ebml::writer::Encoder; pub use DefaultDecoder = ebml::reader::Decoder; use serialize::{Decodable, Encodable}; use flatpipes::flatteners::{DeserializingUnflattener, SerializingFlattener}; use flatpipes::flatteners::{deserialize_buffer, serialize_value}; use flatpipes::bytepipes::{ReaderBytePort, WriterByteChan}; use flatpipes::bytepipes::{PipeBytePort, PipeByteChan}; use flatpipes::{FlatPort, FlatChan}; use core::io::{Reader, Writer}; use core::comm::{Port, Chan}; use core::comm; pub type ReaderPort = FlatPort< T, DeserializingUnflattener, ReaderBytePort>; pub type WriterChan = FlatChan< T, SerializingFlattener, WriterByteChan>; pub type PipePort = FlatPort< T, DeserializingUnflattener, PipeBytePort>; pub type PipeChan = FlatChan< T, SerializingFlattener, PipeByteChan>; /// Create a `FlatPort` from a `Reader` pub fn reader_port, R: Reader>(reader: R) -> ReaderPort { let unflat: DeserializingUnflattener = DeserializingUnflattener::new( deserialize_buffer::); let byte_port = ReaderBytePort::new(reader); FlatPort::new(unflat, byte_port) } /// Create a `FlatChan` from a `Writer` pub fn writer_chan, W: Writer>(writer: W) -> WriterChan { let flat: SerializingFlattener = SerializingFlattener::new( serialize_value::); let byte_chan = WriterByteChan::new(writer); FlatChan::new(flat, byte_chan) } /// Create a `FlatPort` from a `Port<~[u8]>` pub fn pipe_port>( port: Port<~[u8]> ) -> PipePort { let unflat: DeserializingUnflattener = DeserializingUnflattener::new( deserialize_buffer::); let byte_port = PipeBytePort::new(port); FlatPort::new(unflat, byte_port) } /// Create a `FlatChan` from a `Chan<~[u8]>` pub fn pipe_chan>( chan: Chan<~[u8]> ) -> PipeChan { let flat: SerializingFlattener = SerializingFlattener::new( serialize_value::); let byte_chan = PipeByteChan::new(chan); FlatChan::new(flat, byte_chan) } /// Create a pair of `FlatChan` and `FlatPort`, backed by pipes pub fn pipe_stream + Decodable>( ) -> (PipePort, PipeChan) { let (port, chan) = comm::stream(); return (pipe_port(port), pipe_chan(chan)); } } // FIXME #4074 this doesn't correctly enforce POD bounds /** Constructors for flat pipes that send POD types using memcpy. # Safety Note This module is currently unsafe because it uses `Copy Owned` as a type parameter bounds meaning POD (plain old data), but `Copy Owned` and POD are not equivelant. */ pub mod pod { use flatpipes::flatteners::{PodUnflattener, PodFlattener}; use flatpipes::bytepipes::{ReaderBytePort, WriterByteChan}; use flatpipes::bytepipes::{PipeBytePort, PipeByteChan}; use flatpipes::{FlatPort, FlatChan}; use core::io::{Reader, Writer}; use core::comm::{Port, Chan}; use core::comm; pub type ReaderPort = FlatPort, ReaderBytePort>; pub type WriterChan = FlatChan, WriterByteChan>; pub type PipePort = FlatPort, PipeBytePort>; pub type PipeChan = FlatChan, PipeByteChan>; /// Create a `FlatPort` from a `Reader` pub fn reader_port( reader: R ) -> ReaderPort { let unflat: PodUnflattener = PodUnflattener::new(); let byte_port = ReaderBytePort::new(reader); FlatPort::new(unflat, byte_port) } /// Create a `FlatChan` from a `Writer` pub fn writer_chan( writer: W ) -> WriterChan { let flat: PodFlattener = PodFlattener::new(); let byte_chan = WriterByteChan::new(writer); FlatChan::new(flat, byte_chan) } /// Create a `FlatPort` from a `Port<~[u8]>` pub fn pipe_port(port: Port<~[u8]>) -> PipePort { let unflat: PodUnflattener = PodUnflattener::new(); let byte_port = PipeBytePort::new(port); FlatPort::new(unflat, byte_port) } /// Create a `FlatChan` from a `Chan<~[u8]>` pub fn pipe_chan(chan: Chan<~[u8]>) -> PipeChan { let flat: PodFlattener = PodFlattener::new(); let byte_chan = PipeByteChan::new(chan); FlatChan::new(flat, byte_chan) } /// Create a pair of `FlatChan` and `FlatPort`, backed by pipes pub fn pipe_stream() -> (PipePort, PipeChan) { let (port, chan) = comm::stream(); return (pipe_port(port), pipe_chan(chan)); } } /** Flatteners present a value as a byte vector */ pub trait Flattener { fn flatten(&self, val: T) -> ~[u8]; } /** Unflatteners convert a byte vector to a value */ pub trait Unflattener { fn unflatten(&self, buf: ~[u8]) -> T; } /** BytePorts are a simple interface for receiving a specified number */ pub trait BytePort { fn try_recv(&self, count: uint) -> Option<~[u8]>; } /** ByteChans are a simple interface for sending bytes */ pub trait ByteChan { fn send(&self, val: ~[u8]); } static CONTINUE: [u8, ..4] = [0xAA, 0xBB, 0xCC, 0xDD]; impl,P:BytePort> GenericPort for FlatPort { fn recv(&self) -> T { match self.try_recv() { Some(val) => val, None => fail!("port is closed") } } fn try_recv(&self) -> Option { let command = match self.byte_port.try_recv(CONTINUE.len()) { Some(c) => c, None => { warn!("flatpipe: broken pipe"); return None; } }; if vec::eq(command, CONTINUE) { let msg_len = match self.byte_port.try_recv(size_of::()) { Some(bytes) => { io::u64_from_be_bytes(bytes, 0, size_of::()) }, None => { warn!("flatpipe: broken pipe"); return None; } }; let msg_len = msg_len as uint; match self.byte_port.try_recv(msg_len) { Some(bytes) => { Some(self.unflattener.unflatten(bytes)) } None => { warn!("flatpipe: broken pipe"); return None; } } } else { fail!("flatpipe: unrecognized command"); } } } impl,C:ByteChan> GenericChan for FlatChan { fn send(&self, val: T) { self.byte_chan.send(CONTINUE.to_vec()); let bytes = self.flattener.flatten(val); let len = bytes.len() as u64; do io::u64_to_be_bytes(len, size_of::()) |len_bytes| { self.byte_chan.send(len_bytes.to_vec()); } self.byte_chan.send(bytes); } } pub impl,P:BytePort> FlatPort { fn new(u: U, p: P) -> FlatPort { FlatPort { unflattener: u, byte_port: p } } } pub impl,C:ByteChan> FlatChan { fn new(f: F, c: C) -> FlatChan { FlatChan { flattener: f, byte_chan: c } } } pub mod flatteners { use ebml; use flatpipes::{Flattener, Unflattener}; use io_util::BufReader; use json; use serialize::{Encoder, Decoder, Encodable, Decodable}; use core::cast; use core::io::{Writer, Reader, ReaderUtil}; use core::ptr; use core::sys::size_of; use core::vec; // FIXME #4074: Copy + Owned != POD pub struct PodUnflattener { bogus: () } pub struct PodFlattener { bogus: () } impl Unflattener for PodUnflattener { fn unflatten(&self, buf: ~[u8]) -> T { assert!(size_of::() != 0); assert!(size_of::() == buf.len()); let addr_of_init: &u8 = unsafe { &*vec::raw::to_ptr(buf) }; let addr_of_value: &T = unsafe { cast::transmute(addr_of_init) }; copy *addr_of_value } } impl Flattener for PodFlattener { fn flatten(&self, val: T) -> ~[u8] { assert!(size_of::() != 0); let val: *T = ptr::to_unsafe_ptr(&val); let byte_value = val as *u8; unsafe { vec::from_buf(byte_value, size_of::()) } } } pub impl PodUnflattener { fn new() -> PodUnflattener { PodUnflattener { bogus: () } } } pub impl PodFlattener { fn new() -> PodFlattener { PodFlattener { bogus: () } } } pub type DeserializeBuffer = ~fn(buf: &[u8]) -> T; pub struct DeserializingUnflattener { deserialize_buffer: DeserializeBuffer } pub type SerializeValue = ~fn(val: &T) -> ~[u8]; pub struct SerializingFlattener { serialize_value: SerializeValue } impl> Unflattener for DeserializingUnflattener { fn unflatten(&self, buf: ~[u8]) -> T { (self.deserialize_buffer)(buf) } } impl> Flattener for SerializingFlattener { fn flatten(&self, val: T) -> ~[u8] { (self.serialize_value)(&val) } } pub impl> DeserializingUnflattener { fn new(deserialize_buffer: DeserializeBuffer) -> DeserializingUnflattener { DeserializingUnflattener { deserialize_buffer: deserialize_buffer } } } pub impl> SerializingFlattener { fn new(serialize_value: SerializeValue) -> SerializingFlattener { SerializingFlattener { serialize_value: serialize_value } } } /* Implementations of the serialization functions required by SerializingFlattener */ pub fn deserialize_buffer>( buf: &[u8]) -> T { let buf = vec::to_owned(buf); let buf_reader = @BufReader::new(buf); let reader = buf_reader as @Reader; let mut deser: D = FromReader::from_reader(reader); Decodable::decode(&mut deser) } pub fn serialize_value>( val: &T) -> ~[u8] { do io::with_bytes_writer |writer| { let mut ser = FromWriter::from_writer(writer); val.encode(&mut ser); } } pub trait FromReader { fn from_reader(r: @Reader) -> Self; } pub trait FromWriter { fn from_writer(w: @Writer) -> Self; } impl FromReader for json::Decoder { fn from_reader(r: @Reader) -> json::Decoder { match json::from_reader(r) { Ok(json) => { json::Decoder(json) } Err(e) => fail!("flatpipe: can't parse json: %?", e) } } } impl FromWriter for json::Encoder { fn from_writer(w: @Writer) -> json::Encoder { json::Encoder(w) } } impl FromReader for ebml::reader::Decoder { fn from_reader(r: @Reader) -> ebml::reader::Decoder { let buf = @r.read_whole_stream(); let doc = ebml::reader::Doc(buf); ebml::reader::Decoder(doc) } } impl FromWriter for ebml::writer::Encoder { fn from_writer(w: @Writer) -> ebml::writer::Encoder { ebml::writer::Encoder(w) } } } pub mod bytepipes { use flatpipes::{ByteChan, BytePort}; use core::io::{Writer, Reader, ReaderUtil}; use core::comm::{Port, Chan}; pub struct ReaderBytePort { reader: R } pub struct WriterByteChan { writer: W } impl BytePort for ReaderBytePort { fn try_recv(&self, count: uint) -> Option<~[u8]> { let mut left = count; let mut bytes = ~[]; while !self.reader.eof() && left > 0 { assert!(left <= count); assert!(left > 0); let new_bytes = self.reader.read_bytes(left); bytes.push_all(new_bytes); assert!(new_bytes.len() <= left); left -= new_bytes.len(); } if left == 0 { return Some(bytes); } else { warn!("flatpipe: dropped %? broken bytes", left); return None; } } } impl ByteChan for WriterByteChan { fn send(&self, val: ~[u8]) { self.writer.write(val); } } pub impl ReaderBytePort { fn new(r: R) -> ReaderBytePort { ReaderBytePort { reader: r } } } pub impl WriterByteChan { fn new(w: W) -> WriterByteChan { WriterByteChan { writer: w } } } // XXX: Remove `@mut` when this module is ported to the new I/O traits, // which use `&mut self` properly. pub struct PipeBytePort { port: comm::Port<~[u8]>, buf: @mut ~[u8] } pub struct PipeByteChan { chan: comm::Chan<~[u8]> } impl BytePort for PipeBytePort { fn try_recv(&self, count: uint) -> Option<~[u8]> { if vec::uniq_len(&const *self.buf) >= count { let mut bytes = ::core::util::replace(&mut *self.buf, ~[]); *self.buf = bytes.slice(count, bytes.len()).to_owned(); bytes.truncate(count); return Some(bytes); } else if vec::uniq_len(&const *self.buf) > 0 { let mut bytes = ::core::util::replace(&mut *self.buf, ~[]); assert!(count > bytes.len()); match self.try_recv(count - bytes.len()) { Some(rest) => { bytes.push_all(rest); return Some(bytes); } None => return None } } else if vec::uniq_len(&const *self.buf) == 0 { match self.port.try_recv() { Some(buf) => { assert!(!buf.is_empty()); *self.buf = buf; return self.try_recv(count); } None => return None } } else { ::core::util::unreachable() } } } impl ByteChan for PipeByteChan { fn send(&self, val: ~[u8]) { self.chan.send(val) } } pub impl PipeBytePort { fn new(p: Port<~[u8]>) -> PipeBytePort { PipeBytePort { port: p, buf: @mut ~[] } } } pub impl PipeByteChan { fn new(c: Chan<~[u8]>) -> PipeByteChan { PipeByteChan { chan: c } } } } #[cfg(test)] mod test { use flatpipes::{Flattener, Unflattener}; use flatpipes::bytepipes::*; use flatpipes::pod; use flatpipes::serial; use io_util::BufReader; use flatpipes::{BytePort, FlatChan, FlatPort}; use net::tcp::TcpSocketBuf; use core::io::BytesWriter; #[test] fn test_serializing_memory_stream() { let writer = BytesWriter(); let chan = serial::writer_chan(writer); chan.send(10); let bytes = copy *chan.byte_chan.writer.bytes; let reader = BufReader::new(bytes); let port = serial::reader_port(reader); let res: int = port.recv(); assert!(res == 10i); } #[test] #[ignore(reason = "FIXME #6211 failing on linux snapshot machine")] fn test_serializing_pipes() { let (port, chan) = serial::pipe_stream(); do task::spawn || { for int::range(0, 10) |i| { chan.send(i) } } for int::range(0, 10) |i| { assert!(i == port.recv()) } } #[test] fn test_serializing_boxes() { let (port, chan) = serial::pipe_stream(); do task::spawn || { for int::range(0, 10) |i| { chan.send(@i) } } for int::range(0, 10) |i| { assert!(@i == port.recv()) } } #[test] fn test_pod_memory_stream() { let writer = BytesWriter(); let chan = pod::writer_chan(writer); chan.send(10); let bytes = copy *chan.byte_chan.writer.bytes; let reader = BufReader::new(bytes); let port = pod::reader_port(reader); let res: int = port.recv(); assert!(res == 10); } #[test] fn test_pod_pipes() { let (port, chan) = pod::pipe_stream(); do task::spawn || { for int::range(0, 10) |i| { chan.send(i) } } for int::range(0, 10) |i| { assert!(i == port.recv()) } } // FIXME #2064: Networking doesn't work on x86 #[test] #[cfg(target_arch = "x86_64")] fn test_pod_tcp_stream() { fn reader_port(buf: TcpSocketBuf ) -> pod::ReaderPort { pod::reader_port(buf) } fn writer_chan(buf: TcpSocketBuf ) -> pod::WriterChan { pod::writer_chan(buf) } test_some_tcp_stream(reader_port, writer_chan, 9666); } #[test] #[cfg(target_arch = "x86_64")] fn test_serializing_tcp_stream() { fn reader_port(buf: TcpSocketBuf ) -> serial::ReaderPort { serial::reader_port(buf) } fn writer_chan(buf: TcpSocketBuf ) -> serial::WriterChan { serial::writer_chan(buf) } test_some_tcp_stream(reader_port, writer_chan, 9667); } type ReaderPortFactory = ~fn(TcpSocketBuf) -> FlatPort>; type WriterChanFactory = ~fn(TcpSocketBuf) -> FlatChan>; fn test_some_tcp_stream,F:Flattener>( reader_port: ReaderPortFactory, writer_chan: WriterChanFactory, port: uint) { use core::cell::Cell; use net::ip; use net::tcp; use uv; // Indicate to the client task that the server is listening let (begin_connect_port, begin_connect_chan) = comm::stream(); // The connection is sent from the server task to the receiver task // to handle the connection let (accept_port, accept_chan) = comm::stream(); // The main task will wait until the test is over to proceed let (finish_port, finish_chan) = comm::stream(); let addr0 = ip::v4::parse_addr("127.0.0.1"); let begin_connect_chan = Cell(begin_connect_chan); let accept_chan = Cell(accept_chan); // The server task let addr = copy addr0; do task::spawn || { let iotask = &uv::global_loop::get(); let begin_connect_chan = begin_connect_chan.take(); let accept_chan = accept_chan.take(); let listen_res = do tcp::listen( copy addr, port, 128, iotask, |_kill_ch| { // Tell the sender to initiate the connection debug!("listening"); begin_connect_chan.send(()) }) |new_conn, kill_ch| { // Incoming connection. Send it to the receiver task to accept let (res_port, res_chan) = comm::stream(); accept_chan.send((new_conn, res_chan)); // Wait until the connection is accepted res_port.recv(); // Stop listening kill_ch.send(None) }; assert!(listen_res.is_ok()); } // Client task let addr = copy addr0; do task::spawn || { // Wait for the server to start listening begin_connect_port.recv(); debug!("connecting"); let iotask = &uv::global_loop::get(); let connect_result = tcp::connect(copy addr, port, iotask); assert!(connect_result.is_ok()); let sock = result::unwrap(connect_result); let socket_buf: tcp::TcpSocketBuf = tcp::socket_buf(sock); // TcpSocketBuf is a Writer! let chan = writer_chan(socket_buf); for int::range(0, 10) |i| { debug!("sending %?", i); chan.send(i) } } // Receiver task do task::spawn || { // Wait for a connection let (conn, res_chan) = accept_port.recv(); debug!("accepting connection"); let accept_result = tcp::accept(conn); debug!("accepted"); assert!(accept_result.is_ok()); let sock = result::unwrap(accept_result); res_chan.send(()); let socket_buf: tcp::TcpSocketBuf = tcp::socket_buf(sock); // TcpSocketBuf is a Reader! let port = reader_port(socket_buf); for int::range(0, 10) |i| { let j = port.recv(); debug!("received %?", j); assert!(i == j); } // The test is over! finish_chan.send(()); } finish_port.recv(); } // Tests that the different backends behave the same when the // binary streaming protocol is broken mod broken_protocol { use flatpipes::{BytePort, FlatPort}; use flatpipes::flatteners::PodUnflattener; use flatpipes::pod; use io_util::BufReader; type PortLoader

= ~fn(~[u8]) -> FlatPort, P>; fn reader_port_loader(bytes: ~[u8] ) -> pod::ReaderPort { let reader = BufReader::new(bytes); pod::reader_port(reader) } fn pipe_port_loader(bytes: ~[u8] ) -> pod::PipePort { let (port, chan) = comm::stream(); if !bytes.is_empty() { chan.send(bytes); } pod::pipe_port(port) } fn test_try_recv_none1(loader: PortLoader

) { let bytes = ~[]; let port = loader(bytes); let res: Option = port.try_recv(); assert!(res.is_none()); } #[test] fn test_try_recv_none1_reader() { test_try_recv_none1(reader_port_loader); } #[test] fn test_try_recv_none1_pipe() { test_try_recv_none1(pipe_port_loader); } fn test_try_recv_none2(loader: PortLoader

) { // The control word in the protocol is interrupted let bytes = ~[0]; let port = loader(bytes); let res: Option = port.try_recv(); assert!(res.is_none()); } #[test] fn test_try_recv_none2_reader() { test_try_recv_none2(reader_port_loader); } #[test] fn test_try_recv_none2_pipe() { test_try_recv_none2(pipe_port_loader); } fn test_try_recv_none3(loader: PortLoader

) { static CONTINUE: [u8, ..4] = [0xAA, 0xBB, 0xCC, 0xDD]; // The control word is followed by garbage let bytes = CONTINUE.to_vec() + ~[0]; let port = loader(bytes); let res: Option = port.try_recv(); assert!(res.is_none()); } #[test] fn test_try_recv_none3_reader() { test_try_recv_none3(reader_port_loader); } #[test] fn test_try_recv_none3_pipe() { test_try_recv_none3(pipe_port_loader); } fn test_try_recv_none4(loader: PortLoader

) { assert!(do task::try || { static CONTINUE: [u8, ..4] = [0xAA, 0xBB, 0xCC, 0xDD]; // The control word is followed by a valid length, // then undeserializable garbage let len_bytes = do io::u64_to_be_bytes( 1, sys::size_of::()) |len_bytes| { len_bytes.to_vec() }; let bytes = CONTINUE.to_vec() + len_bytes + ~[0, 0, 0, 0]; let port = loader(bytes); let _res: Option = port.try_recv(); }.is_err()); } #[test] #[ignore(cfg(windows))] fn test_try_recv_none4_reader() { test_try_recv_none4(reader_port_loader); } #[test] #[ignore(cfg(windows))] fn test_try_recv_none4_pipe() { test_try_recv_none4(pipe_port_loader); } } }