use std::{cmp, io}; use std::fmt::Write; use bytes::BytesMut; use futures::{Async, Poll}; use tokio_io::AsyncWrite; use http::{Version, StatusCode}; use http::header::{HeaderValue, CONNECTION, CONTENT_TYPE, CONTENT_LENGTH, TRANSFER_ENCODING, DATE}; use date; use body::Body; use httprequest::HttpRequest; use httpresponse::HttpResponse; const AVERAGE_HEADER_SIZE: usize = 30; // totally scientific const MAX_WRITE_BUFFER_SIZE: usize = 65_536; // max buffer size 64k pub(crate) enum WriterState { Done, Pause, } /// Send stream pub(crate) trait Writer { fn start(&mut self, req: &mut HttpRequest, resp: &mut HttpResponse) -> Result; fn write(&mut self, payload: &[u8]) -> Result; fn write_eof(&mut self) -> Result; fn poll_complete(&mut self) -> Poll<(), io::Error>; } pub(crate) struct H1Writer { stream: Option, buffer: BytesMut, started: bool, encoder: Encoder, upgrade: bool, keepalive: bool, disconnected: bool, } impl H1Writer { pub fn new(stream: T) -> H1Writer { H1Writer { stream: Some(stream), buffer: BytesMut::new(), started: false, encoder: Encoder::length(0), upgrade: false, keepalive: false, disconnected: false, } } pub fn get_mut(&mut self) -> &mut T { self.stream.as_mut().unwrap() } pub fn into_inner(&mut self) -> T { self.stream.take().unwrap() } pub fn disconnected(&mut self) { let len = self.buffer.len(); self.buffer.split_to(len); } pub fn keepalive(&self) -> bool { self.keepalive && !self.upgrade } fn write_to_stream(&mut self) -> Result { if let Some(ref mut stream) = self.stream { while !self.buffer.is_empty() { match stream.write(self.buffer.as_ref()) { Ok(n) => { self.buffer.split_to(n); }, Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { if self.buffer.len() > MAX_WRITE_BUFFER_SIZE { return Ok(WriterState::Pause) } else { return Ok(WriterState::Done) } } Err(err) => return Err(err), } } } return Ok(WriterState::Done) } } impl Writer for H1Writer { fn start(&mut self, req: &mut HttpRequest, msg: &mut HttpResponse) -> Result { trace!("Prepare message status={:?}", msg.status); // prepare task let mut extra = 0; let body = msg.replace_body(Body::Empty); let version = msg.version().unwrap_or_else(|| req.version()); self.started = true; self.keepalive = msg.keep_alive().unwrap_or_else(|| req.keep_alive()); match body { Body::Empty => { if msg.chunked() { error!("Chunked transfer is enabled but body is set to Empty"); } msg.headers.insert(CONTENT_LENGTH, HeaderValue::from_static("0")); msg.headers.remove(TRANSFER_ENCODING); self.encoder = Encoder::length(0); }, Body::Length(n) => { if msg.chunked() { error!("Chunked transfer is enabled but body with specific length is specified"); } msg.headers.insert( CONTENT_LENGTH, HeaderValue::from_str(format!("{}", n).as_str()).unwrap()); msg.headers.remove(TRANSFER_ENCODING); self.encoder = Encoder::length(n); }, Body::Binary(ref bytes) => { extra = bytes.len(); msg.headers.insert( CONTENT_LENGTH, HeaderValue::from_str(format!("{}", bytes.len()).as_str()).unwrap()); msg.headers.remove(TRANSFER_ENCODING); self.encoder = Encoder::length(0); } Body::Streaming => { if msg.chunked() { if version < Version::HTTP_11 { error!("Chunked transfer encoding is forbidden for {:?}", version); } msg.headers.remove(CONTENT_LENGTH); msg.headers.insert(TRANSFER_ENCODING, HeaderValue::from_static("chunked")); self.encoder = Encoder::chunked(); } else { self.encoder = Encoder::eof(); } } Body::Upgrade => { msg.headers.insert(CONNECTION, HeaderValue::from_static("upgrade")); self.encoder = Encoder::eof(); } } // Connection upgrade if msg.upgrade() { msg.headers.insert(CONNECTION, HeaderValue::from_static("upgrade")); } // keep-alive else if self.keepalive { if version < Version::HTTP_11 { msg.headers.insert(CONNECTION, HeaderValue::from_static("keep-alive")); } } else if version >= Version::HTTP_11 { msg.headers.insert(CONNECTION, HeaderValue::from_static("close")); } // render message let init_cap = 100 + msg.headers.len() * AVERAGE_HEADER_SIZE + extra; self.buffer.reserve(init_cap); if version == Version::HTTP_11 && msg.status == StatusCode::OK { self.buffer.extend(b"HTTP/1.1 200 OK\r\n"); } else { let _ = write!(self.buffer, "{:?} {}\r\n", version, msg.status); } for (key, value) in &msg.headers { let t: &[u8] = key.as_ref(); self.buffer.extend(t); self.buffer.extend(b": "); self.buffer.extend(value.as_ref()); self.buffer.extend(b"\r\n"); } // using http::h1::date is quite a lot faster than generating // a unique Date header each time like req/s goes up about 10% if !msg.headers.contains_key(DATE) { self.buffer.reserve(date::DATE_VALUE_LENGTH + 8); self.buffer.extend(b"Date: "); date::extend(&mut self.buffer); self.buffer.extend(b"\r\n"); } // default content-type if !msg.headers.contains_key(CONTENT_TYPE) { self.buffer.extend(b"ContentType: application/octet-stream\r\n".as_ref()); } self.buffer.extend(b"\r\n"); if let Body::Binary(ref bytes) = body { self.buffer.extend_from_slice(bytes.as_ref()); return Ok(WriterState::Done) } msg.replace_body(body); Ok(WriterState::Done) } fn write(&mut self, payload: &[u8]) -> Result { if !self.disconnected { if self.started { // TODO: add warning, write after EOF self.encoder.encode(&mut self.buffer, payload); } else { // might be response for EXCEPT self.buffer.extend_from_slice(payload) } } if self.buffer.len() > MAX_WRITE_BUFFER_SIZE { return Ok(WriterState::Pause) } else { return Ok(WriterState::Done) } } fn write_eof(&mut self) -> Result { if !self.encoder.encode_eof(&mut self.buffer) { //debug!("last payload item, but it is not EOF "); Err(io::Error::new(io::ErrorKind::Other, "Last payload item, but eof is not reached")) } else { if self.buffer.len() > MAX_WRITE_BUFFER_SIZE { return Ok(WriterState::Pause) } else { return Ok(WriterState::Done) } } } fn poll_complete(&mut self) -> Poll<(), io::Error> { match self.write_to_stream() { Ok(WriterState::Done) => Ok(Async::Ready(())), Ok(WriterState::Pause) => Ok(Async::NotReady), Err(err) => Err(err) } } } /// Encoders to handle different Transfer-Encodings. #[derive(Debug, Clone)] struct Encoder { kind: Kind, } #[derive(Debug, PartialEq, Clone)] enum Kind { /// An Encoder for when Transfer-Encoding includes `chunked`. Chunked(bool), /// An Encoder for when Content-Length is set. /// /// Enforces that the body is not longer than the Content-Length header. Length(u64), /// An Encoder for when Content-Length is not known. /// /// Appliction decides when to stop writing. Eof, } impl Encoder { pub fn eof() -> Encoder { Encoder { kind: Kind::Eof, } } pub fn chunked() -> Encoder { Encoder { kind: Kind::Chunked(false), } } pub fn length(len: u64) -> Encoder { Encoder { kind: Kind::Length(len), } } /// Encode message. Return `EOF` state of encoder pub fn encode(&mut self, dst: &mut BytesMut, msg: &[u8]) -> bool { match self.kind { Kind::Eof => { dst.extend(msg); msg.is_empty() }, Kind::Chunked(ref mut eof) => { if *eof { return true; } if msg.is_empty() { *eof = true; dst.extend(b"0\r\n\r\n"); } else { write!(dst, "{:X}\r\n", msg.len()).unwrap(); dst.extend(msg); dst.extend(b"\r\n"); } *eof }, Kind::Length(ref mut remaining) => { if msg.is_empty() { return *remaining == 0 } let max = cmp::min(*remaining, msg.len() as u64); trace!("sized write = {}", max); dst.extend(msg[..max as usize].as_ref()); *remaining -= max as u64; trace!("encoded {} bytes, remaining = {}", max, remaining); *remaining == 0 }, } } /// Encode eof. Return `EOF` state of encoder pub fn encode_eof(&mut self, dst: &mut BytesMut) -> bool { match self.kind { Kind::Eof => true, Kind::Chunked(ref mut eof) => { if *eof { return true; } *eof = true; dst.extend(b"0\r\n\r\n"); true }, Kind::Length(ref mut remaining) => { return *remaining == 0 }, } } }