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|
//! UDP for IOCP
//!
//! Note that most of this module is quite similar to the TCP module, so if
//! something seems odd you may also want to try the docs over there.
use std::fmt;
use std::io::prelude::*;
use std::io;
use std::mem;
use std::net::{self, Ipv4Addr, Ipv6Addr, SocketAddr};
use std::sync::{Mutex, MutexGuard};
#[allow(unused_imports)]
use net2::{UdpBuilder, UdpSocketExt};
use winapi::shared::winerror::WSAEMSGSIZE;
use winapi::um::minwinbase::OVERLAPPED_ENTRY;
use miow::iocp::CompletionStatus;
use miow::net::SocketAddrBuf;
use miow::net::UdpSocketExt as MiowUdpSocketExt;
use {poll, Ready, Poll, PollOpt, Token};
use event::Evented;
use sys::windows::from_raw_arc::FromRawArc;
use sys::windows::selector::{Overlapped, ReadyBinding};
pub struct UdpSocket {
imp: Imp,
registration: Mutex<Option<poll::Registration>>,
}
#[derive(Clone)]
struct Imp {
inner: FromRawArc<Io>,
}
struct Io {
read: Overlapped,
write: Overlapped,
socket: net::UdpSocket,
inner: Mutex<Inner>,
}
struct Inner {
iocp: ReadyBinding,
read: State<Vec<u8>, Vec<u8>>,
write: State<Vec<u8>, (Vec<u8>, usize)>,
read_buf: SocketAddrBuf,
}
enum State<T, U> {
Empty,
Pending(T),
Ready(U),
Error(io::Error),
}
impl UdpSocket {
pub fn new(socket: net::UdpSocket) -> io::Result<UdpSocket> {
Ok(UdpSocket {
registration: Mutex::new(None),
imp: Imp {
inner: FromRawArc::new(Io {
read: Overlapped::new(recv_done),
write: Overlapped::new(send_done),
socket: socket,
inner: Mutex::new(Inner {
iocp: ReadyBinding::new(),
read: State::Empty,
write: State::Empty,
read_buf: SocketAddrBuf::new(),
}),
}),
},
})
}
pub fn local_addr(&self) -> io::Result<SocketAddr> {
self.imp.inner.socket.local_addr()
}
pub fn try_clone(&self) -> io::Result<UdpSocket> {
self.imp.inner.socket.try_clone().and_then(UdpSocket::new)
}
/// Note that unlike `TcpStream::write` this function will not attempt to
/// continue writing `buf` until its entirely written.
///
/// TODO: This... may be wrong in the long run. We're reporting that we
/// successfully wrote all of the bytes in `buf` but it's possible
/// that we don't actually end up writing all of them!
pub fn send_to(&self, buf: &[u8], target: &SocketAddr)
-> io::Result<usize> {
let mut me = self.inner();
let me = &mut *me;
match me.write {
State::Empty => {}
_ => return Err(io::ErrorKind::WouldBlock.into()),
}
if !me.iocp.registered() {
return Err(io::ErrorKind::WouldBlock.into())
}
let interest = me.iocp.readiness();
me.iocp.set_readiness(interest - Ready::writable());
let mut owned_buf = me.iocp.get_buffer(64 * 1024);
let amt = owned_buf.write(buf)?;
unsafe {
trace!("scheduling a send");
self.imp.inner.socket.send_to_overlapped(&owned_buf, target,
self.imp.inner.write.as_mut_ptr())
}?;
me.write = State::Pending(owned_buf);
mem::forget(self.imp.clone());
Ok(amt)
}
/// Note that unlike `TcpStream::write` this function will not attempt to
/// continue writing `buf` until its entirely written.
///
/// TODO: This... may be wrong in the long run. We're reporting that we
/// successfully wrote all of the bytes in `buf` but it's possible
/// that we don't actually end up writing all of them!
pub fn send(&self, buf: &[u8]) -> io::Result<usize> {
let mut me = self.inner();
let me = &mut *me;
match me.write {
State::Empty => {}
_ => return Err(io::ErrorKind::WouldBlock.into()),
}
if !me.iocp.registered() {
return Err(io::ErrorKind::WouldBlock.into())
}
let interest = me.iocp.readiness();
me.iocp.set_readiness(interest - Ready::writable());
let mut owned_buf = me.iocp.get_buffer(64 * 1024);
let amt = owned_buf.write(buf)?;
unsafe {
trace!("scheduling a send");
self.imp.inner.socket.send_overlapped(&owned_buf, self.imp.inner.write.as_mut_ptr())
}?;
me.write = State::Pending(owned_buf);
mem::forget(self.imp.clone());
Ok(amt)
}
pub fn recv_from(&self, mut buf: &mut [u8]) -> io::Result<(usize, SocketAddr)> {
let mut me = self.inner();
match mem::replace(&mut me.read, State::Empty) {
State::Empty => Err(io::ErrorKind::WouldBlock.into()),
State::Pending(b) => { me.read = State::Pending(b); Err(io::ErrorKind::WouldBlock.into()) }
State::Ready(data) => {
// If we weren't provided enough space to receive the message
// then don't actually read any data, just return an error.
if buf.len() < data.len() {
me.read = State::Ready(data);
Err(io::Error::from_raw_os_error(WSAEMSGSIZE as i32))
} else {
let r = if let Some(addr) = me.read_buf.to_socket_addr() {
buf.write(&data).unwrap();
Ok((data.len(), addr))
} else {
Err(io::Error::new(io::ErrorKind::Other,
"failed to parse socket address"))
};
me.iocp.put_buffer(data);
self.imp.schedule_read_from(&mut me);
r
}
}
State::Error(e) => {
self.imp.schedule_read_from(&mut me);
Err(e)
}
}
}
pub fn recv(&self, buf: &mut [u8])
-> io::Result<usize> {
//Since recv_from can be used on connected sockets just call it and drop the address.
self.recv_from(buf).map(|(size,_)| size)
}
pub fn connect(&self, addr: SocketAddr) -> io::Result<()> {
self.imp.inner.socket.connect(addr)
}
pub fn broadcast(&self) -> io::Result<bool> {
self.imp.inner.socket.broadcast()
}
pub fn set_broadcast(&self, on: bool) -> io::Result<()> {
self.imp.inner.socket.set_broadcast(on)
}
pub fn multicast_loop_v4(&self) -> io::Result<bool> {
self.imp.inner.socket.multicast_loop_v4()
}
pub fn set_multicast_loop_v4(&self, on: bool) -> io::Result<()> {
self.imp.inner.socket.set_multicast_loop_v4(on)
}
pub fn multicast_ttl_v4(&self) -> io::Result<u32> {
self.imp.inner.socket.multicast_ttl_v4()
}
pub fn set_multicast_ttl_v4(&self, ttl: u32) -> io::Result<()> {
self.imp.inner.socket.set_multicast_ttl_v4(ttl)
}
pub fn multicast_loop_v6(&self) -> io::Result<bool> {
self.imp.inner.socket.multicast_loop_v6()
}
pub fn set_multicast_loop_v6(&self, on: bool) -> io::Result<()> {
self.imp.inner.socket.set_multicast_loop_v6(on)
}
pub fn ttl(&self) -> io::Result<u32> {
self.imp.inner.socket.ttl()
}
pub fn set_ttl(&self, ttl: u32) -> io::Result<()> {
self.imp.inner.socket.set_ttl(ttl)
}
pub fn join_multicast_v4(&self,
multiaddr: &Ipv4Addr,
interface: &Ipv4Addr) -> io::Result<()> {
self.imp.inner.socket.join_multicast_v4(multiaddr, interface)
}
pub fn join_multicast_v6(&self,
multiaddr: &Ipv6Addr,
interface: u32) -> io::Result<()> {
self.imp.inner.socket.join_multicast_v6(multiaddr, interface)
}
pub fn leave_multicast_v4(&self,
multiaddr: &Ipv4Addr,
interface: &Ipv4Addr) -> io::Result<()> {
self.imp.inner.socket.leave_multicast_v4(multiaddr, interface)
}
pub fn leave_multicast_v6(&self,
multiaddr: &Ipv6Addr,
interface: u32) -> io::Result<()> {
self.imp.inner.socket.leave_multicast_v6(multiaddr, interface)
}
pub fn set_only_v6(&self, only_v6: bool) -> io::Result<()> {
self.imp.inner.socket.set_only_v6(only_v6)
}
pub fn only_v6(&self) -> io::Result<bool> {
self.imp.inner.socket.only_v6()
}
pub fn take_error(&self) -> io::Result<Option<io::Error>> {
self.imp.inner.socket.take_error()
}
fn inner(&self) -> MutexGuard<Inner> {
self.imp.inner()
}
fn post_register(&self, interest: Ready, me: &mut Inner) {
if interest.is_readable() {
//We use recv_from here since it is well specified for both
//connected and non-connected sockets and we can discard the address
//when calling recv().
self.imp.schedule_read_from(me);
}
// See comments in TcpSocket::post_register for what's going on here
if interest.is_writable() {
if let State::Empty = me.write {
self.imp.add_readiness(me, Ready::writable());
}
}
}
}
impl Imp {
fn inner(&self) -> MutexGuard<Inner> {
self.inner.inner.lock().unwrap()
}
fn schedule_read_from(&self, me: &mut Inner) {
match me.read {
State::Empty => {}
_ => return,
}
let interest = me.iocp.readiness();
me.iocp.set_readiness(interest - Ready::readable());
let mut buf = me.iocp.get_buffer(64 * 1024);
let res = unsafe {
trace!("scheduling a read");
let cap = buf.capacity();
buf.set_len(cap);
self.inner.socket.recv_from_overlapped(&mut buf, &mut me.read_buf,
self.inner.read.as_mut_ptr())
};
match res {
Ok(_) => {
me.read = State::Pending(buf);
mem::forget(self.clone());
}
Err(e) => {
me.read = State::Error(e);
self.add_readiness(me, Ready::readable());
me.iocp.put_buffer(buf);
}
}
}
// See comments in tcp::StreamImp::push
fn add_readiness(&self, me: &Inner, set: Ready) {
me.iocp.set_readiness(set | me.iocp.readiness());
}
}
impl Evented for UdpSocket {
fn register(&self, poll: &Poll, token: Token,
interest: Ready, opts: PollOpt) -> io::Result<()> {
let mut me = self.inner();
me.iocp.register_socket(&self.imp.inner.socket,
poll, token, interest, opts,
&self.registration)?;
self.post_register(interest, &mut me);
Ok(())
}
fn reregister(&self, poll: &Poll, token: Token,
interest: Ready, opts: PollOpt) -> io::Result<()> {
let mut me = self.inner();
me.iocp.reregister_socket(&self.imp.inner.socket,
poll, token, interest,
opts, &self.registration)?;
self.post_register(interest, &mut me);
Ok(())
}
fn deregister(&self, poll: &Poll) -> io::Result<()> {
self.inner().iocp.deregister(&self.imp.inner.socket,
poll, &self.registration)
}
}
impl fmt::Debug for UdpSocket {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.debug_struct("UdpSocket")
.finish()
}
}
impl Drop for UdpSocket {
fn drop(&mut self) {
let inner = self.inner();
// If we're still internally reading, we're no longer interested. Note
// though that we don't cancel any writes which may have been issued to
// preserve the same semantics as Unix.
unsafe {
match inner.read {
State::Pending(_) => {
drop(super::cancel(&self.imp.inner.socket,
&self.imp.inner.read));
}
State::Empty |
State::Ready(_) |
State::Error(_) => {}
}
}
}
}
fn send_done(status: &OVERLAPPED_ENTRY) {
let status = CompletionStatus::from_entry(status);
trace!("finished a send {}", status.bytes_transferred());
let me2 = Imp {
inner: unsafe { overlapped2arc!(status.overlapped(), Io, write) },
};
let mut me = me2.inner();
me.write = State::Empty;
me2.add_readiness(&mut me, Ready::writable());
}
fn recv_done(status: &OVERLAPPED_ENTRY) {
let status = CompletionStatus::from_entry(status);
trace!("finished a recv {}", status.bytes_transferred());
let me2 = Imp {
inner: unsafe { overlapped2arc!(status.overlapped(), Io, read) },
};
let mut me = me2.inner();
let mut buf = match mem::replace(&mut me.read, State::Empty) {
State::Pending(buf) => buf,
_ => unreachable!(),
};
unsafe {
buf.set_len(status.bytes_transferred() as usize);
}
me.read = State::Ready(buf);
me2.add_readiness(&mut me, Ready::readable());
}
|
