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actix-web/actix-multipart/src/server.rs
Matt Gathu 37c76a39ab
Fix Multipart consuming payload before header checks (#1704) 
* Fix Multipart consuming payload before header checks

What
--
Split up logic in the constructor into two functions:

- **from_boundary:** build Multipart from boundary and stream
- **from_error:** build Multipart for MultipartError

Also we make the `boundary`, `from_boundary`, `from_error`  methods public within the crate so that we can use them in the extractor.

The extractor is then able to perform header checks and only consume the
payload if the checks pass.

* Add tests

* Add payload consumption test

Co-authored-by: Rob Ede <robjtede@icloud.com>
2020-09-25 14:50:37 +01:00

1204 lines
38 KiB
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//! Multipart payload support
use std::cell::{Cell, RefCell, RefMut};
use std::convert::TryFrom;
use std::marker::PhantomData;
use std::pin::Pin;
use std::rc::Rc;
use std::task::{Context, Poll};
use std::{cmp, fmt};
use bytes::{Bytes, BytesMut};
use futures_util::stream::{LocalBoxStream, Stream, StreamExt};
use actix_utils::task::LocalWaker;
use actix_web::error::{ParseError, PayloadError};
use actix_web::http::header::{
self, ContentDisposition, HeaderMap, HeaderName, HeaderValue,
};
use crate::error::MultipartError;
const MAX_HEADERS: usize = 32;
/// The server-side implementation of `multipart/form-data` requests.
///
/// This will parse the incoming stream into `MultipartItem` instances via its
/// Stream implementation.
/// `MultipartItem::Field` contains multipart field. `MultipartItem::Multipart`
/// is used for nested multipart streams.
pub struct Multipart {
safety: Safety,
error: Option<MultipartError>,
inner: Option<Rc<RefCell<InnerMultipart>>>,
}
enum InnerMultipartItem {
None,
Field(Rc<RefCell<InnerField>>),
}
#[derive(PartialEq, Debug)]
enum InnerState {
/// Stream eof
Eof,
/// Skip data until first boundary
FirstBoundary,
/// Reading boundary
Boundary,
/// Reading Headers,
Headers,
}
struct InnerMultipart {
payload: PayloadRef,
boundary: String,
state: InnerState,
item: InnerMultipartItem,
}
impl Multipart {
/// Create multipart instance for boundary.
pub fn new<S>(headers: &HeaderMap, stream: S) -> Multipart
where
S: Stream<Item = Result<Bytes, PayloadError>> + Unpin + 'static,
{
match Self::boundary(headers) {
Ok(boundary) => Multipart::from_boundary(boundary, stream),
Err(err) => Multipart::from_error(err),
}
}
/// Extract boundary info from headers.
pub(crate) fn boundary(headers: &HeaderMap) -> Result<String, MultipartError> {
if let Some(content_type) = headers.get(&header::CONTENT_TYPE) {
if let Ok(content_type) = content_type.to_str() {
if let Ok(ct) = content_type.parse::<mime::Mime>() {
if let Some(boundary) = ct.get_param(mime::BOUNDARY) {
Ok(boundary.as_str().to_owned())
} else {
Err(MultipartError::Boundary)
}
} else {
Err(MultipartError::ParseContentType)
}
} else {
Err(MultipartError::ParseContentType)
}
} else {
Err(MultipartError::NoContentType)
}
}
/// Create multipart instance for given boundary and stream
pub(crate) fn from_boundary<S>(boundary: String, stream: S) -> Multipart
where
S: Stream<Item = Result<Bytes, PayloadError>> + Unpin + 'static,
{
Multipart {
error: None,
safety: Safety::new(),
inner: Some(Rc::new(RefCell::new(InnerMultipart {
boundary,
payload: PayloadRef::new(PayloadBuffer::new(Box::new(stream))),
state: InnerState::FirstBoundary,
item: InnerMultipartItem::None,
}))),
}
}
/// Create Multipart instance from MultipartError
pub(crate) fn from_error(err: MultipartError) -> Multipart {
Multipart {
error: Some(err),
safety: Safety::new(),
inner: None,
}
}
}
impl Stream for Multipart {
type Item = Result<Field, MultipartError>;
fn poll_next(
mut self: Pin<&mut Self>,
cx: &mut Context<'_>,
) -> Poll<Option<Self::Item>> {
if let Some(err) = self.error.take() {
Poll::Ready(Some(Err(err)))
} else if self.safety.current() {
let this = self.get_mut();
let mut inner = this.inner.as_mut().unwrap().borrow_mut();
if let Some(mut payload) = inner.payload.get_mut(&this.safety) {
payload.poll_stream(cx)?;
}
inner.poll(&this.safety, cx)
} else if !self.safety.is_clean() {
Poll::Ready(Some(Err(MultipartError::NotConsumed)))
} else {
Poll::Pending
}
}
}
impl InnerMultipart {
fn read_headers(
payload: &mut PayloadBuffer,
) -> Result<Option<HeaderMap>, MultipartError> {
match payload.read_until(b"\r\n\r\n")? {
None => {
if payload.eof {
Err(MultipartError::Incomplete)
} else {
Ok(None)
}
}
Some(bytes) => {
let mut hdrs = [httparse::EMPTY_HEADER; MAX_HEADERS];
match httparse::parse_headers(&bytes, &mut hdrs) {
Ok(httparse::Status::Complete((_, hdrs))) => {
// convert headers
let mut headers = HeaderMap::with_capacity(hdrs.len());
for h in hdrs {
if let Ok(name) = HeaderName::try_from(h.name) {
if let Ok(value) = HeaderValue::try_from(h.value) {
headers.append(name, value);
} else {
return Err(ParseError::Header.into());
}
} else {
return Err(ParseError::Header.into());
}
}
Ok(Some(headers))
}
Ok(httparse::Status::Partial) => Err(ParseError::Header.into()),
Err(err) => Err(ParseError::from(err).into()),
}
}
}
}
fn read_boundary(
payload: &mut PayloadBuffer,
boundary: &str,
) -> Result<Option<bool>, MultipartError> {
// TODO: need to read epilogue
match payload.readline_or_eof()? {
None => {
if payload.eof {
Ok(Some(true))
} else {
Ok(None)
}
}
Some(chunk) => {
if chunk.len() < boundary.len() + 4
|| &chunk[..2] != b"--"
|| &chunk[2..boundary.len() + 2] != boundary.as_bytes()
{
Err(MultipartError::Boundary)
} else if &chunk[boundary.len() + 2..] == b"\r\n" {
Ok(Some(false))
} else if &chunk[boundary.len() + 2..boundary.len() + 4] == b"--"
&& (chunk.len() == boundary.len() + 4
|| &chunk[boundary.len() + 4..] == b"\r\n")
{
Ok(Some(true))
} else {
Err(MultipartError::Boundary)
}
}
}
}
fn skip_until_boundary(
payload: &mut PayloadBuffer,
boundary: &str,
) -> Result<Option<bool>, MultipartError> {
let mut eof = false;
loop {
match payload.readline()? {
Some(chunk) => {
if chunk.is_empty() {
return Err(MultipartError::Boundary);
}
if chunk.len() < boundary.len() {
continue;
}
if &chunk[..2] == b"--"
&& &chunk[2..chunk.len() - 2] == boundary.as_bytes()
{
break;
} else {
if chunk.len() < boundary.len() + 2 {
continue;
}
let b: &[u8] = boundary.as_ref();
if &chunk[..boundary.len()] == b
&& &chunk[boundary.len()..boundary.len() + 2] == b"--"
{
eof = true;
break;
}
}
}
None => {
return if payload.eof {
Err(MultipartError::Incomplete)
} else {
Ok(None)
};
}
}
}
Ok(Some(eof))
}
fn poll(
&mut self,
safety: &Safety,
cx: &mut Context<'_>,
) -> Poll<Option<Result<Field, MultipartError>>> {
if self.state == InnerState::Eof {
Poll::Ready(None)
} else {
// release field
loop {
// Nested multipart streams of fields has to be consumed
// before switching to next
if safety.current() {
let stop = match self.item {
InnerMultipartItem::Field(ref mut field) => {
match field.borrow_mut().poll(safety) {
Poll::Pending => return Poll::Pending,
Poll::Ready(Some(Ok(_))) => continue,
Poll::Ready(Some(Err(e))) => {
return Poll::Ready(Some(Err(e)))
}
Poll::Ready(None) => true,
}
}
InnerMultipartItem::None => false,
};
if stop {
self.item = InnerMultipartItem::None;
}
if let InnerMultipartItem::None = self.item {
break;
}
}
}
let headers = if let Some(mut payload) = self.payload.get_mut(safety) {
match self.state {
// read until first boundary
InnerState::FirstBoundary => {
match InnerMultipart::skip_until_boundary(
&mut *payload,
&self.boundary,
)? {
Some(eof) => {
if eof {
self.state = InnerState::Eof;
return Poll::Ready(None);
} else {
self.state = InnerState::Headers;
}
}
None => return Poll::Pending,
}
}
// read boundary
InnerState::Boundary => {
match InnerMultipart::read_boundary(
&mut *payload,
&self.boundary,
)? {
None => return Poll::Pending,
Some(eof) => {
if eof {
self.state = InnerState::Eof;
return Poll::Ready(None);
} else {
self.state = InnerState::Headers;
}
}
}
}
_ => (),
}
// read field headers for next field
if self.state == InnerState::Headers {
if let Some(headers) = InnerMultipart::read_headers(&mut *payload)? {
self.state = InnerState::Boundary;
headers
} else {
return Poll::Pending;
}
} else {
unreachable!()
}
} else {
log::debug!("NotReady: field is in flight");
return Poll::Pending;
};
// content type
let mut mt = mime::APPLICATION_OCTET_STREAM;
if let Some(content_type) = headers.get(&header::CONTENT_TYPE) {
if let Ok(content_type) = content_type.to_str() {
if let Ok(ct) = content_type.parse::<mime::Mime>() {
mt = ct;
}
}
}
self.state = InnerState::Boundary;
// nested multipart stream
if mt.type_() == mime::MULTIPART {
Poll::Ready(Some(Err(MultipartError::Nested)))
} else {
let field = Rc::new(RefCell::new(InnerField::new(
self.payload.clone(),
self.boundary.clone(),
&headers,
)?));
self.item = InnerMultipartItem::Field(Rc::clone(&field));
Poll::Ready(Some(Ok(Field::new(safety.clone(cx), headers, mt, field))))
}
}
}
}
impl Drop for InnerMultipart {
fn drop(&mut self) {
// InnerMultipartItem::Field has to be dropped first because of Safety.
self.item = InnerMultipartItem::None;
}
}
/// A single field in a multipart stream
pub struct Field {
ct: mime::Mime,
headers: HeaderMap,
inner: Rc<RefCell<InnerField>>,
safety: Safety,
}
impl Field {
fn new(
safety: Safety,
headers: HeaderMap,
ct: mime::Mime,
inner: Rc<RefCell<InnerField>>,
) -> Self {
Field {
ct,
headers,
inner,
safety,
}
}
/// Get a map of headers
pub fn headers(&self) -> &HeaderMap {
&self.headers
}
/// Get the content type of the field
pub fn content_type(&self) -> &mime::Mime {
&self.ct
}
/// Get the content disposition of the field, if it exists
pub fn content_disposition(&self) -> Option<ContentDisposition> {
// RFC 7578: 'Each part MUST contain a Content-Disposition header field
// where the disposition type is "form-data".'
if let Some(content_disposition) = self.headers.get(&header::CONTENT_DISPOSITION)
{
ContentDisposition::from_raw(content_disposition).ok()
} else {
None
}
}
}
impl Stream for Field {
type Item = Result<Bytes, MultipartError>;
fn poll_next(
self: Pin<&mut Self>,
cx: &mut Context<'_>,
) -> Poll<Option<Self::Item>> {
if self.safety.current() {
let mut inner = self.inner.borrow_mut();
if let Some(mut payload) =
inner.payload.as_ref().unwrap().get_mut(&self.safety)
{
payload.poll_stream(cx)?;
}
inner.poll(&self.safety)
} else if !self.safety.is_clean() {
Poll::Ready(Some(Err(MultipartError::NotConsumed)))
} else {
Poll::Pending
}
}
}
impl fmt::Debug for Field {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
writeln!(f, "\nField: {}", self.ct)?;
writeln!(f, " boundary: {}", self.inner.borrow().boundary)?;
writeln!(f, " headers:")?;
for (key, val) in self.headers.iter() {
writeln!(f, " {:?}: {:?}", key, val)?;
}
Ok(())
}
}
struct InnerField {
payload: Option<PayloadRef>,
boundary: String,
eof: bool,
length: Option<u64>,
}
impl InnerField {
fn new(
payload: PayloadRef,
boundary: String,
headers: &HeaderMap,
) -> Result<InnerField, PayloadError> {
let len = if let Some(len) = headers.get(&header::CONTENT_LENGTH) {
if let Ok(s) = len.to_str() {
if let Ok(len) = s.parse::<u64>() {
Some(len)
} else {
return Err(PayloadError::Incomplete(None));
}
} else {
return Err(PayloadError::Incomplete(None));
}
} else {
None
};
Ok(InnerField {
boundary,
payload: Some(payload),
eof: false,
length: len,
})
}
/// Reads body part content chunk of the specified size.
/// The body part must has `Content-Length` header with proper value.
fn read_len(
payload: &mut PayloadBuffer,
size: &mut u64,
) -> Poll<Option<Result<Bytes, MultipartError>>> {
if *size == 0 {
Poll::Ready(None)
} else {
match payload.read_max(*size)? {
Some(mut chunk) => {
let len = cmp::min(chunk.len() as u64, *size);
*size -= len;
let ch = chunk.split_to(len as usize);
if !chunk.is_empty() {
payload.unprocessed(chunk);
}
Poll::Ready(Some(Ok(ch)))
}
None => {
if payload.eof && (*size != 0) {
Poll::Ready(Some(Err(MultipartError::Incomplete)))
} else {
Poll::Pending
}
}
}
}
}
/// Reads content chunk of body part with unknown length.
/// The `Content-Length` header for body part is not necessary.
fn read_stream(
payload: &mut PayloadBuffer,
boundary: &str,
) -> Poll<Option<Result<Bytes, MultipartError>>> {
let mut pos = 0;
let len = payload.buf.len();
if len == 0 {
return if payload.eof {
Poll::Ready(Some(Err(MultipartError::Incomplete)))
} else {
Poll::Pending
};
}
// check boundary
if len > 4 && payload.buf[0] == b'\r' {
let b_len = if &payload.buf[..2] == b"\r\n" && &payload.buf[2..4] == b"--" {
Some(4)
} else if &payload.buf[1..3] == b"--" {
Some(3)
} else {
None
};
if let Some(b_len) = b_len {
let b_size = boundary.len() + b_len;
if len < b_size {
return Poll::Pending;
} else if &payload.buf[b_len..b_size] == boundary.as_bytes() {
// found boundary
return Poll::Ready(None);
}
}
}
loop {
return if let Some(idx) = twoway::find_bytes(&payload.buf[pos..], b"\r") {
let cur = pos + idx;
// check if we have enough data for boundary detection
if cur + 4 > len {
if cur > 0 {
Poll::Ready(Some(Ok(payload.buf.split_to(cur).freeze())))
} else {
Poll::Pending
}
} else {
// check boundary
if (&payload.buf[cur..cur + 2] == b"\r\n"
&& &payload.buf[cur + 2..cur + 4] == b"--")
|| (&payload.buf[cur..=cur] == b"\r"
&& &payload.buf[cur + 1..cur + 3] == b"--")
{
if cur != 0 {
// return buffer
Poll::Ready(Some(Ok(payload.buf.split_to(cur).freeze())))
} else {
pos = cur + 1;
continue;
}
} else {
// not boundary
pos = cur + 1;
continue;
}
}
} else {
Poll::Ready(Some(Ok(payload.buf.split().freeze())))
};
}
}
fn poll(&mut self, s: &Safety) -> Poll<Option<Result<Bytes, MultipartError>>> {
if self.payload.is_none() {
return Poll::Ready(None);
}
let result = if let Some(mut payload) = self.payload.as_ref().unwrap().get_mut(s)
{
if !self.eof {
let res = if let Some(ref mut len) = self.length {
InnerField::read_len(&mut *payload, len)
} else {
InnerField::read_stream(&mut *payload, &self.boundary)
};
match res {
Poll::Pending => return Poll::Pending,
Poll::Ready(Some(Ok(bytes))) => return Poll::Ready(Some(Ok(bytes))),
Poll::Ready(Some(Err(e))) => return Poll::Ready(Some(Err(e))),
Poll::Ready(None) => self.eof = true,
}
}
match payload.readline() {
Ok(None) => Poll::Pending,
Ok(Some(line)) => {
if line.as_ref() != b"\r\n" {
log::warn!("multipart field did not read all the data or it is malformed");
}
Poll::Ready(None)
}
Err(e) => Poll::Ready(Some(Err(e))),
}
} else {
Poll::Pending
};
if let Poll::Ready(None) = result {
self.payload.take();
}
result
}
}
struct PayloadRef {
payload: Rc<RefCell<PayloadBuffer>>,
}
impl PayloadRef {
fn new(payload: PayloadBuffer) -> PayloadRef {
PayloadRef {
payload: Rc::new(payload.into()),
}
}
fn get_mut<'a, 'b>(&'a self, s: &'b Safety) -> Option<RefMut<'a, PayloadBuffer>>
where
'a: 'b,
{
if s.current() {
Some(self.payload.borrow_mut())
} else {
None
}
}
}
impl Clone for PayloadRef {
fn clone(&self) -> PayloadRef {
PayloadRef {
payload: Rc::clone(&self.payload),
}
}
}
/// Counter. It tracks of number of clones of payloads and give access to
/// payload only to top most task panics if Safety get destroyed and it not top
/// most task.
#[derive(Debug)]
struct Safety {
task: LocalWaker,
level: usize,
payload: Rc<PhantomData<bool>>,
clean: Rc<Cell<bool>>,
}
impl Safety {
fn new() -> Safety {
let payload = Rc::new(PhantomData);
Safety {
task: LocalWaker::new(),
level: Rc::strong_count(&payload),
clean: Rc::new(Cell::new(true)),
payload,
}
}
fn current(&self) -> bool {
Rc::strong_count(&self.payload) == self.level && self.clean.get()
}
fn is_clean(&self) -> bool {
self.clean.get()
}
fn clone(&self, cx: &mut Context<'_>) -> Safety {
let payload = Rc::clone(&self.payload);
let s = Safety {
task: LocalWaker::new(),
level: Rc::strong_count(&payload),
clean: self.clean.clone(),
payload,
};
s.task.register(cx.waker());
s
}
}
impl Drop for Safety {
fn drop(&mut self) {
// parent task is dead
if Rc::strong_count(&self.payload) != self.level {
self.clean.set(true);
}
if let Some(task) = self.task.take() {
task.wake()
}
}
}
/// Payload buffer
struct PayloadBuffer {
eof: bool,
buf: BytesMut,
stream: LocalBoxStream<'static, Result<Bytes, PayloadError>>,
}
impl PayloadBuffer {
/// Create new `PayloadBuffer` instance
fn new<S>(stream: S) -> Self
where
S: Stream<Item = Result<Bytes, PayloadError>> + 'static,
{
PayloadBuffer {
eof: false,
buf: BytesMut::new(),
stream: stream.boxed_local(),
}
}
fn poll_stream(&mut self, cx: &mut Context<'_>) -> Result<(), PayloadError> {
loop {
match Pin::new(&mut self.stream).poll_next(cx) {
Poll::Ready(Some(Ok(data))) => self.buf.extend_from_slice(&data),
Poll::Ready(Some(Err(e))) => return Err(e),
Poll::Ready(None) => {
self.eof = true;
return Ok(());
}
Poll::Pending => return Ok(()),
}
}
}
/// Read exact number of bytes
#[cfg(test)]
fn read_exact(&mut self, size: usize) -> Option<Bytes> {
if size <= self.buf.len() {
Some(self.buf.split_to(size).freeze())
} else {
None
}
}
fn read_max(&mut self, size: u64) -> Result<Option<Bytes>, MultipartError> {
if !self.buf.is_empty() {
let size = std::cmp::min(self.buf.len() as u64, size) as usize;
Ok(Some(self.buf.split_to(size).freeze()))
} else if self.eof {
Err(MultipartError::Incomplete)
} else {
Ok(None)
}
}
/// Read until specified ending
pub fn read_until(&mut self, line: &[u8]) -> Result<Option<Bytes>, MultipartError> {
let res = twoway::find_bytes(&self.buf, line)
.map(|idx| self.buf.split_to(idx + line.len()).freeze());
if res.is_none() && self.eof {
Err(MultipartError::Incomplete)
} else {
Ok(res)
}
}
/// Read bytes until new line delimiter
pub fn readline(&mut self) -> Result<Option<Bytes>, MultipartError> {
self.read_until(b"\n")
}
/// Read bytes until new line delimiter or eof
pub fn readline_or_eof(&mut self) -> Result<Option<Bytes>, MultipartError> {
match self.readline() {
Err(MultipartError::Incomplete) if self.eof => {
Ok(Some(self.buf.split().freeze()))
}
line => line,
}
}
/// Put unprocessed data back to the buffer
pub fn unprocessed(&mut self, data: Bytes) {
let buf = BytesMut::from(data.as_ref());
let buf = std::mem::replace(&mut self.buf, buf);
self.buf.extend_from_slice(&buf);
}
}
#[cfg(test)]
mod tests {
use super::*;
use actix_http::h1::Payload;
use actix_utils::mpsc;
use actix_web::http::header::{DispositionParam, DispositionType};
use actix_web::test::TestRequest;
use actix_web::FromRequest;
use bytes::Bytes;
use futures_util::future::lazy;
#[actix_rt::test]
async fn test_boundary() {
let headers = HeaderMap::new();
match Multipart::boundary(&headers) {
Err(MultipartError::NoContentType) => (),
_ => unreachable!("should not happen"),
}
let mut headers = HeaderMap::new();
headers.insert(
header::CONTENT_TYPE,
header::HeaderValue::from_static("test"),
);
match Multipart::boundary(&headers) {
Err(MultipartError::ParseContentType) => (),
_ => unreachable!("should not happen"),
}
let mut headers = HeaderMap::new();
headers.insert(
header::CONTENT_TYPE,
header::HeaderValue::from_static("multipart/mixed"),
);
match Multipart::boundary(&headers) {
Err(MultipartError::Boundary) => (),
_ => unreachable!("should not happen"),
}
let mut headers = HeaderMap::new();
headers.insert(
header::CONTENT_TYPE,
header::HeaderValue::from_static(
"multipart/mixed; boundary=\"5c02368e880e436dab70ed54e1c58209\"",
),
);
assert_eq!(
Multipart::boundary(&headers).unwrap(),
"5c02368e880e436dab70ed54e1c58209"
);
}
fn create_stream() -> (
mpsc::Sender<Result<Bytes, PayloadError>>,
impl Stream<Item = Result<Bytes, PayloadError>>,
) {
let (tx, rx) = mpsc::channel();
(tx, rx.map(|res| res.map_err(|_| panic!())))
}
// Stream that returns from a Bytes, one char at a time and Pending every other poll()
struct SlowStream {
bytes: Bytes,
pos: usize,
ready: bool,
}
impl SlowStream {
fn new(bytes: Bytes) -> SlowStream {
SlowStream {
bytes,
pos: 0,
ready: false,
}
}
}
impl Stream for SlowStream {
type Item = Result<Bytes, PayloadError>;
fn poll_next(
self: Pin<&mut Self>,
cx: &mut Context<'_>,
) -> Poll<Option<Self::Item>> {
let this = self.get_mut();
if !this.ready {
this.ready = true;
cx.waker().wake_by_ref();
return Poll::Pending;
}
if this.pos == this.bytes.len() {
return Poll::Ready(None);
}
let res = Poll::Ready(Some(Ok(this.bytes.slice(this.pos..(this.pos + 1)))));
this.pos += 1;
this.ready = false;
res
}
}
fn create_simple_request_with_header() -> (Bytes, HeaderMap) {
let bytes = Bytes::from(
"testasdadsad\r\n\
--abbc761f78ff4d7cb7573b5a23f96ef0\r\n\
Content-Disposition: form-data; name=\"file\"; filename=\"fn.txt\"\r\n\
Content-Type: text/plain; charset=utf-8\r\nContent-Length: 4\r\n\r\n\
test\r\n\
--abbc761f78ff4d7cb7573b5a23f96ef0\r\n\
Content-Type: text/plain; charset=utf-8\r\nContent-Length: 4\r\n\r\n\
data\r\n\
--abbc761f78ff4d7cb7573b5a23f96ef0--\r\n",
);
let mut headers = HeaderMap::new();
headers.insert(
header::CONTENT_TYPE,
header::HeaderValue::from_static(
"multipart/mixed; boundary=\"abbc761f78ff4d7cb7573b5a23f96ef0\"",
),
);
(bytes, headers)
}
#[actix_rt::test]
async fn test_multipart_no_end_crlf() {
let (sender, payload) = create_stream();
let (mut bytes, headers) = create_simple_request_with_header();
let bytes_stripped = bytes.split_to(bytes.len()); // strip crlf
sender.send(Ok(bytes_stripped)).unwrap();
drop(sender); // eof
let mut multipart = Multipart::new(&headers, payload);
match multipart.next().await.unwrap() {
Ok(_) => (),
_ => unreachable!(),
}
match multipart.next().await.unwrap() {
Ok(_) => (),
_ => unreachable!(),
}
match multipart.next().await {
None => (),
_ => unreachable!(),
}
}
#[actix_rt::test]
async fn test_multipart() {
let (sender, payload) = create_stream();
let (bytes, headers) = create_simple_request_with_header();
sender.send(Ok(bytes)).unwrap();
let mut multipart = Multipart::new(&headers, payload);
match multipart.next().await {
Some(Ok(mut field)) => {
let cd = field.content_disposition().unwrap();
assert_eq!(cd.disposition, DispositionType::FormData);
assert_eq!(cd.parameters[0], DispositionParam::Name("file".into()));
assert_eq!(field.content_type().type_(), mime::TEXT);
assert_eq!(field.content_type().subtype(), mime::PLAIN);
match field.next().await.unwrap() {
Ok(chunk) => assert_eq!(chunk, "test"),
_ => unreachable!(),
}
match field.next().await {
None => (),
_ => unreachable!(),
}
}
_ => unreachable!(),
}
match multipart.next().await.unwrap() {
Ok(mut field) => {
assert_eq!(field.content_type().type_(), mime::TEXT);
assert_eq!(field.content_type().subtype(), mime::PLAIN);
match field.next().await {
Some(Ok(chunk)) => assert_eq!(chunk, "data"),
_ => unreachable!(),
}
match field.next().await {
None => (),
_ => unreachable!(),
}
}
_ => unreachable!(),
}
match multipart.next().await {
None => (),
_ => unreachable!(),
}
}
// Loops, collecting all bytes until end-of-field
async fn get_whole_field(field: &mut Field) -> BytesMut {
let mut b = BytesMut::new();
loop {
match field.next().await {
Some(Ok(chunk)) => b.extend_from_slice(&chunk),
None => return b,
_ => unreachable!(),
}
}
}
#[actix_rt::test]
async fn test_stream() {
let (bytes, headers) = create_simple_request_with_header();
let payload = SlowStream::new(bytes);
let mut multipart = Multipart::new(&headers, payload);
match multipart.next().await.unwrap() {
Ok(mut field) => {
let cd = field.content_disposition().unwrap();
assert_eq!(cd.disposition, DispositionType::FormData);
assert_eq!(cd.parameters[0], DispositionParam::Name("file".into()));
assert_eq!(field.content_type().type_(), mime::TEXT);
assert_eq!(field.content_type().subtype(), mime::PLAIN);
assert_eq!(get_whole_field(&mut field).await, "test");
}
_ => unreachable!(),
}
match multipart.next().await {
Some(Ok(mut field)) => {
assert_eq!(field.content_type().type_(), mime::TEXT);
assert_eq!(field.content_type().subtype(), mime::PLAIN);
assert_eq!(get_whole_field(&mut field).await, "data");
}
_ => unreachable!(),
}
match multipart.next().await {
None => (),
_ => unreachable!(),
}
}
#[actix_rt::test]
async fn test_basic() {
let (_, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
assert_eq!(payload.buf.len(), 0);
lazy(|cx| payload.poll_stream(cx)).await.unwrap();
assert_eq!(None, payload.read_max(1).unwrap());
}
#[actix_rt::test]
async fn test_eof() {
let (mut sender, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
assert_eq!(None, payload.read_max(4).unwrap());
sender.feed_data(Bytes::from("data"));
sender.feed_eof();
lazy(|cx| payload.poll_stream(cx)).await.unwrap();
assert_eq!(Some(Bytes::from("data")), payload.read_max(4).unwrap());
assert_eq!(payload.buf.len(), 0);
assert!(payload.read_max(1).is_err());
assert!(payload.eof);
}
#[actix_rt::test]
async fn test_err() {
let (mut sender, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
assert_eq!(None, payload.read_max(1).unwrap());
sender.set_error(PayloadError::Incomplete(None));
lazy(|cx| payload.poll_stream(cx)).await.err().unwrap();
}
#[actix_rt::test]
async fn test_readmax() {
let (mut sender, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
sender.feed_data(Bytes::from("line1"));
sender.feed_data(Bytes::from("line2"));
lazy(|cx| payload.poll_stream(cx)).await.unwrap();
assert_eq!(payload.buf.len(), 10);
assert_eq!(Some(Bytes::from("line1")), payload.read_max(5).unwrap());
assert_eq!(payload.buf.len(), 5);
assert_eq!(Some(Bytes::from("line2")), payload.read_max(5).unwrap());
assert_eq!(payload.buf.len(), 0);
}
#[actix_rt::test]
async fn test_readexactly() {
let (mut sender, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
assert_eq!(None, payload.read_exact(2));
sender.feed_data(Bytes::from("line1"));
sender.feed_data(Bytes::from("line2"));
lazy(|cx| payload.poll_stream(cx)).await.unwrap();
assert_eq!(Some(Bytes::from_static(b"li")), payload.read_exact(2));
assert_eq!(payload.buf.len(), 8);
assert_eq!(Some(Bytes::from_static(b"ne1l")), payload.read_exact(4));
assert_eq!(payload.buf.len(), 4);
}
#[actix_rt::test]
async fn test_readuntil() {
let (mut sender, payload) = Payload::create(false);
let mut payload = PayloadBuffer::new(payload);
assert_eq!(None, payload.read_until(b"ne").unwrap());
sender.feed_data(Bytes::from("line1"));
sender.feed_data(Bytes::from("line2"));
lazy(|cx| payload.poll_stream(cx)).await.unwrap();
assert_eq!(
Some(Bytes::from("line")),
payload.read_until(b"ne").unwrap()
);
assert_eq!(payload.buf.len(), 6);
assert_eq!(
Some(Bytes::from("1line2")),
payload.read_until(b"2").unwrap()
);
assert_eq!(payload.buf.len(), 0);
}
#[actix_rt::test]
async fn test_multipart_from_error() {
let err = MultipartError::NoContentType;
let mut multipart = Multipart::from_error(err);
assert!(multipart.next().await.unwrap().is_err())
}
#[actix_rt::test]
async fn test_multipart_from_boundary() {
let (_, payload) = create_stream();
let (_, headers) = create_simple_request_with_header();
let boundary = Multipart::boundary(&headers);
assert!(boundary.is_ok());
let _ = Multipart::from_boundary(boundary.unwrap(), payload);
}
#[actix_rt::test]
async fn test_multipart_payload_consumption() {
// with sample payload and HttpRequest with no headers
let (_, inner_payload) = Payload::create(false);
let mut payload = actix_web::dev::Payload::from(inner_payload);
let req = TestRequest::default().to_http_request();
// multipart should generate an error
let mut mp = Multipart::from_request(&req, &mut payload).await.unwrap();
assert!(mp.next().await.unwrap().is_err());
// and should not consume the payload
match payload {
actix_web::dev::Payload::H1(_) => {} //expected
_ => unreachable!(),
}
}
}
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