use std::{cell::Cell, cell::RefCell, marker, num, rc::Rc, task::Context};
use ntex_bytes::ByteString;
use ntex_io::DispatchItem;
use ntex_service::cfg::{Cfg, SharedCfg};
use ntex_service::{self as service, Pipeline, Service, ServiceCtx, ServiceFactory};
use ntex_util::services::inflight::InFlightService;
use ntex_util::services::{buffer::BufferService, buffer::BufferServiceError};
use ntex_util::{HashMap, HashSet, future::join};
use crate::error::{DecodeError, HandshakeError, MqttError, PayloadError, ProtocolError};
use crate::payload::{Payload, PayloadStatus, PlSender};
use crate::{MqttServiceConfig, types::QoS};
use super::Session;
use super::codec::{self, Decoded, DisconnectReasonCode, Encoded, Packet};
use super::control::{Control, ControlAck};
use super::publish::{Publish, PublishAck};
use super::shared::{Ack, MqttShared};
pub(super) fn factory<St, T, C, E>(
publish: T,
control: C,
) -> impl ServiceFactory<
DispatchItem<Rc<MqttShared>>,
(SharedCfg, Session<St>),
Response = Option<Encoded>,
Error = MqttError<E>,
InitError = MqttError<E>,
>
where
St: 'static,
E: From<T::Error> + From<T::InitError> + From<C::Error> + From<C::InitError> + 'static,
T: ServiceFactory<Publish, Session<St>, Response = PublishAck> + 'static,
C: ServiceFactory<Control<E>, Session<St>, Response = ControlAck> + 'static,
PublishAck: TryFrom<T::Error, Error = E>,
{
let factories = Rc::new((publish, control));
service::fn_factory_with_config(async move |(cfg, ses): (SharedCfg, Session<St>)| {
let cfg: Cfg<MqttServiceConfig> = cfg.get();
let sink = ses.sink().shared();
let (publish, control) =
join(factories.0.create(ses.clone()), factories.1.create(ses)).await;
let publish = publish.map_err(|e| MqttError::Service(e.into()))?;
let control = control.map_err(|e| MqttError::Service(e.into()))?;
let control = BufferService::new(
16,
InFlightService::new(1, control),
)
.map_err(|err| match err {
BufferServiceError::Service(e) => MqttError::Service(E::from(e)),
BufferServiceError::RequestCanceled => {
MqttError::Handshake(HandshakeError::Disconnected(None))
}
});
Ok(Dispatcher::<_, _, E>::new(sink, publish, control, cfg))
})
}
impl crate::inflight::SizedRequest for DispatchItem<Rc<MqttShared>> {
fn size(&self) -> u32 {
match self {
DispatchItem::Item(Decoded::Packet(_, size))
| DispatchItem::Item(Decoded::Publish(_, _, size)) => *size,
_ => 0,
}
}
fn is_publish(&self) -> bool {
matches!(self, DispatchItem::Item(Decoded::Publish(..)))
}
fn is_chunk(&self) -> bool {
matches!(self, DispatchItem::Item(Decoded::PayloadChunk(..)))
}
}
pub(crate) struct Dispatcher<T, C: Service<Control<E>>, E> {
publish: T,
inner: Rc<Inner<C>>,
cfg: Cfg<MqttServiceConfig>,
_t: marker::PhantomData<E>,
}
struct Inner<C> {
control: Pipeline<C>,
sink: Rc<MqttShared>,
info: RefCell<PublishInfo>,
payload: Cell<Option<PlSender>>,
}
struct PublishInfo {
inflight: HashSet<num::NonZeroU16>,
aliases: HashMap<num::NonZeroU16, ByteString>,
}
impl<T, C, E> Dispatcher<T, C, E>
where
E: From<T::Error>,
T: Service<Publish, Response = PublishAck>,
PublishAck: TryFrom<T::Error, Error = E>,
C: Service<Control<E>, Response = ControlAck, Error = MqttError<E>>,
{
fn new(sink: Rc<MqttShared>, publish: T, control: C, cfg: Cfg<MqttServiceConfig>) -> Self {
Self {
cfg,
publish,
inner: Rc::new(Inner {
sink,
payload: Cell::new(None),
control: Pipeline::new(control),
info: RefCell::new(PublishInfo {
aliases: HashMap::default(),
inflight: HashSet::default(),
}),
}),
_t: marker::PhantomData,
}
}
fn tag(&self) -> &'static str {
self.inner.sink.tag()
}
}
impl<C> Inner<C> {
fn drop_payload<PErr>(&self, err: &PErr)
where
PErr: Clone,
PayloadError: From<PErr>,
{
if let Some(pl) = self.payload.take() {
pl.set_error(err.clone().into());
}
}
}
impl<T, C, E> Service<DispatchItem<Rc<MqttShared>>> for Dispatcher<T, C, E>
where
E: From<T::Error> + 'static,
T: Service<Publish, Response = PublishAck> + 'static,
PublishAck: TryFrom<T::Error, Error = E>,
C: Service<Control<E>, Response = ControlAck, Error = MqttError<E>> + 'static,
{
type Response = Option<Encoded>;
type Error = MqttError<E>;
async fn ready(&self, ctx: ServiceCtx<'_, Self>) -> Result<(), Self::Error> {
let (res1, res2) = join(ctx.ready(&self.publish), self.inner.control.ready()).await;
let result = if let Err(e) = res1 {
if res2.is_err() {
Err(MqttError::Service(e.into()))
} else {
match self.inner.control.call(Control::error(e.into())).await {
Ok(res) => {
if res.disconnect {
self.inner.sink.drop_sink();
}
Ok(())
}
Err(err) => Err(err),
}
}
} else {
res2
};
if result.is_ok() {
if let Some(pl) = self.inner.payload.take() {
self.inner.payload.set(Some(pl.clone()));
if pl.ready().await != PayloadStatus::Ready {
self.inner.sink.force_close();
}
}
}
result
}
fn poll(&self, cx: &mut Context<'_>) -> Result<(), Self::Error> {
if let Err(e) = self.publish.poll(cx) {
let inner = self.inner.clone();
ntex_rt::spawn(async move {
if let Ok(res) = inner.control.call(Control::error(e.into())).await {
if res.disconnect {
inner.sink.drop_sink();
}
}
});
}
self.inner.control.poll(cx)
}
async fn shutdown(&self) {
log::trace!("{}: Shutdown v5 dispatcher", self.tag());
self.inner.drop_payload(&PayloadError::Disconnected);
self.inner.sink.drop_sink();
let _ = self.inner.control.call(Control::closed()).await;
self.publish.shutdown().await;
self.inner.control.shutdown().await;
}
#[allow(clippy::await_holding_refcell_ref)]
async fn call(
&self,
request: DispatchItem<Rc<MqttShared>>,
ctx: ServiceCtx<'_, Self>,
) -> Result<Self::Response, Self::Error> {
log::trace!("{}: Dispatch v5 packet: {:#?}", self.tag(), request);
match request {
DispatchItem::Item(Decoded::Publish(mut publish, payload, size)) => {
let info = self.inner.as_ref();
let packet_id = publish.packet_id;
if publish.topic.contains(['#', '+']) {
return control(
Control::proto_error(
ProtocolError::generic_violation(
"PUBLISH packet's topic name contains wildcard character [MQTT-3.3.2-2]"
)
),
&self.inner,
0,
).await;
}
{
let mut inner = info.info.borrow_mut();
let state = &self.inner.sink;
if let Some(pid) = packet_id {
let receive_max = state.receive_max();
if receive_max != 0 && inner.inflight.len() >= receive_max as usize {
log::trace!(
"{}: Receive maximum exceeded: max: {} in-flight: {}",
self.tag(),
receive_max,
inner.inflight.len()
);
drop(inner);
return control(
Control::proto_error(
ProtocolError::violation(
DisconnectReasonCode::ReceiveMaximumExceeded,
"Number of in-flight messages exceeds set maximum [MQTT-3.3.4-7]"
)
),
&self.inner,
0,
).await;
}
if publish.qos > state.max_qos() {
log::trace!(
"{}: Max allowed QoS is violated, max {:?} provided {:?}",
self.tag(),
state.max_qos(),
publish.qos
);
drop(inner);
return control(
Control::proto_error(ProtocolError::violation(
DisconnectReasonCode::QosNotSupported,
"PUBLISH QoS is higher than supported [MQTT-3.2.2-11]",
)),
&self.inner,
0,
)
.await;
}
if publish.retain && !state.codec.retain_available() {
log::trace!("{}: Retain is not available but is set", self.tag());
drop(inner);
return control(
Control::proto_error(ProtocolError::violation(
DisconnectReasonCode::RetainNotSupported,
"RETAIN is not supported [MQTT-3.2.2-14]",
)),
&self.inner,
0,
)
.await;
}
if !inner.inflight.insert(pid) {
let _ = self.inner.sink.encode_packet(codec::Packet::PublishAck(
codec::PublishAck {
packet_id: pid,
reason_code: codec::PublishAckReason::PacketIdentifierInUse,
..Default::default()
},
));
return Ok(None);
}
}
if let Some(alias) = publish.properties.topic_alias {
if publish.topic.is_empty() {
match inner.aliases.get(&alias) {
Some(aliased_topic) => publish.topic = aliased_topic.clone(),
None => {
drop(inner);
return control(
Control::proto_error(ProtocolError::violation(
DisconnectReasonCode::TopicAliasInvalid,
"Unknown topic alias",
)),
&self.inner,
0,
)
.await;
}
}
} else {
match inner.aliases.entry(alias) {
std::collections::hash_map::Entry::Occupied(mut entry) => {
if entry.get().as_str() != publish.topic.as_str() {
let mut topic = publish.topic.clone();
topic.trimdown();
entry.insert(topic);
}
}
std::collections::hash_map::Entry::Vacant(entry) => {
if alias.get() > state.topic_alias_max() {
drop(inner);
return control(
Control::proto_error(
ProtocolError::generic_violation(
"Topic alias is greater than max allowed [MQTT-3.2.2-17]",
)
),
&self.inner,
0,
).await;
}
let mut topic = publish.topic.clone();
topic.trimdown();
entry.insert(topic);
}
}
}
}
if state.is_closed()
&& !self
.cfg
.handle_qos_after_disconnect
.map(|max_qos| publish.qos <= max_qos)
.unwrap_or_default()
{
return Ok(None);
}
}
let payload = if publish.payload_size == payload.len() as u32 {
Payload::from_bytes(payload)
} else {
let (pl, sender) =
Payload::from_stream(payload, self.cfg.max_payload_buffer_size);
self.inner.payload.set(Some(sender));
pl
};
publish_fn(
&self.publish,
Publish::new(publish, payload, size),
packet_id.map(|v| v.get()).unwrap_or(0),
info,
ctx,
)
.await
}
DispatchItem::Item(Decoded::PayloadChunk(buf, eof)) => {
if let Some(pl) = self.inner.payload.take() {
pl.feed_data(buf);
if eof {
pl.feed_eof();
} else {
self.inner.payload.set(Some(pl));
}
Ok(None)
} else {
control(
Control::proto_error(ProtocolError::Decode(
DecodeError::UnexpectedPayload,
)),
&self.inner,
0,
)
.await
}
}
DispatchItem::Item(Decoded::Packet(Packet::PublishAck(packet), _)) => {
if let Err(err) = self.inner.sink.pkt_ack(Ack::Publish(packet)) {
control(Control::proto_error(err), &self.inner, 0).await
} else {
Ok(None)
}
}
DispatchItem::Item(Decoded::Packet(Packet::PublishReceived(pkt), _)) => {
if let Err(e) = self.inner.sink.pkt_ack(Ack::Receive(pkt)) {
control(Control::proto_error(e), &self.inner, 0).await
} else {
Ok(None)
}
}
DispatchItem::Item(Decoded::Packet(Packet::PublishRelease(ack), size)) => {
if self.inner.info.borrow().inflight.contains(&ack.packet_id) {
control(Control::pubrel(ack, size), &self.inner, 0).await
} else {
Ok(Some(Encoded::Packet(codec::Packet::PublishComplete(
codec::PublishAck2 {
packet_id: ack.packet_id,
reason_code: codec::PublishAck2Reason::PacketIdNotFound,
properties: codec::UserProperties::default(),
reason_string: None,
},
))))
}
}
DispatchItem::Item(Decoded::Packet(Packet::PublishComplete(pkt), _)) => {
if let Err(e) = self.inner.sink.pkt_ack(Ack::Complete(pkt)) {
control(Control::proto_error(e), &self.inner, 0).await
} else {
Ok(None)
}
}
DispatchItem::Item(Decoded::Packet(Packet::Auth(pkt), size)) => {
if self.inner.sink.is_closed() {
return Ok(None);
}
control(Control::auth(pkt, size), &self.inner, 0).await
}
DispatchItem::Item(Decoded::Packet(Packet::PingRequest, _)) => {
control(Control::ping(), &self.inner, 0).await
}
DispatchItem::Item(Decoded::Packet(Packet::Disconnect(pkt), size)) => {
control(Control::remote_disconnect(pkt, size), &self.inner, 0).await
}
DispatchItem::Item(Decoded::Packet(Packet::Subscribe(pkt), size)) => {
if self.inner.sink.is_closed() {
return Ok(None);
}
if pkt.topic_filters.iter().any(|(tf, _)| !crate::topic::is_valid(tf)) {
return control(
Control::proto_error(ProtocolError::generic_violation(
"Topic filter is malformed [MQTT-4.7.1-*]",
)),
&self.inner,
0,
)
.await;
}
if pkt.id.is_some() && !self.inner.sink.codec.sub_ids_available() {
log::trace!(
"{}: Subscription Identifiers are not supported but was set",
self.tag()
);
return control(
Control::proto_error(ProtocolError::violation(
DisconnectReasonCode::SubscriptionIdentifiersNotSupported,
"Subscription Identifiers are not supported",
)),
&self.inner,
0,
)
.await;
}
if !self.inner.info.borrow_mut().inflight.insert(pkt.packet_id) {
let _ = self.inner.sink.encode_packet(codec::Packet::SubscribeAck(
codec::SubscribeAck {
packet_id: pkt.packet_id,
status: pkt
.topic_filters
.iter()
.map(|_| codec::SubscribeAckReason::PacketIdentifierInUse)
.collect(),
properties: codec::UserProperties::new(),
reason_string: None,
},
));
return Ok(None);
}
let id = pkt.packet_id;
control(Control::subscribe(pkt, size), &self.inner, id.get()).await
}
DispatchItem::Item(Decoded::Packet(Packet::Unsubscribe(pkt), size)) => {
if self.inner.sink.is_closed() {
return Ok(None);
}
if pkt.topic_filters.iter().any(|tf| !crate::topic::is_valid(tf)) {
return control(
Control::proto_error(ProtocolError::generic_violation(
"Topic filter is malformed [MQTT-4.7.1-*]",
)),
&self.inner,
0,
)
.await;
}
if !self.inner.info.borrow_mut().inflight.insert(pkt.packet_id) {
let _ = self.inner.sink.encode_packet(codec::Packet::UnsubscribeAck(
codec::UnsubscribeAck {
packet_id: pkt.packet_id,
status: pkt
.topic_filters
.iter()
.map(|_| codec::UnsubscribeAckReason::PacketIdentifierInUse)
.collect(),
properties: codec::UserProperties::new(),
reason_string: None,
},
));
return Ok(None);
}
let id = pkt.packet_id;
control(Control::unsubscribe(pkt, size), &self.inner, id.get()).await
}
DispatchItem::Item(Decoded::Packet(_, _)) => Ok(None),
DispatchItem::EncoderError(err) => {
let err = ProtocolError::Encode(err);
self.inner.drop_payload(&err);
control(Control::proto_error(err), &self.inner, 0).await
}
DispatchItem::KeepAliveTimeout => {
self.inner.drop_payload(&ProtocolError::KeepAliveTimeout);
control(Control::proto_error(ProtocolError::KeepAliveTimeout), &self.inner, 0)
.await
}
DispatchItem::ReadTimeout => {
self.inner.drop_payload(&ProtocolError::ReadTimeout);
control(Control::proto_error(ProtocolError::ReadTimeout), &self.inner, 0).await
}
DispatchItem::DecoderError(err) => {
let err = ProtocolError::Decode(err);
self.inner.drop_payload(&err);
control(Control::proto_error(err), &self.inner, 0).await
}
DispatchItem::Disconnect(err) => {
self.inner.drop_payload(&PayloadError::Disconnected);
control(Control::peer_gone(err), &self.inner, 0).await
}
DispatchItem::WBackPressureEnabled => {
self.inner.sink.enable_wr_backpressure();
control(Control::wr_backpressure(true), &self.inner, 0).await
}
DispatchItem::WBackPressureDisabled => {
self.inner.sink.disable_wr_backpressure();
control(Control::wr_backpressure(false), &self.inner, 0).await
}
}
}
}
async fn publish_fn<'f, T, C, E>(
publish: &T,
pkt: Publish,
packet_id: u16,
inner: &'f Inner<C>,
ctx: ServiceCtx<'f, Dispatcher<T, C, E>>,
) -> Result<Option<Encoded>, MqttError<E>>
where
E: From<T::Error>,
T: Service<Publish, Response = PublishAck>,
PublishAck: TryFrom<T::Error, Error = E>,
C: Service<Control<E>, Response = ControlAck, Error = MqttError<E>>,
{
let qos2 = pkt.qos() == QoS::ExactlyOnce;
let ack = match ctx.call(publish, pkt).await {
Ok(ack) => ack,
Err(e) => {
if packet_id != 0 {
match PublishAck::try_from(e) {
Ok(ack) => ack,
Err(e) => return control(Control::error(e), inner, 0).await,
}
} else {
return control(Control::error(e.into()), inner, 0).await;
}
}
};
if let Some(id) = num::NonZeroU16::new(packet_id) {
let ack = if qos2 {
codec::Packet::PublishReceived(codec::PublishAck {
packet_id: id,
reason_code: ack.reason_code,
reason_string: ack.reason_string,
properties: ack.properties,
})
} else {
inner.info.borrow_mut().inflight.remove(&id);
codec::Packet::PublishAck(codec::PublishAck {
packet_id: id,
reason_code: ack.reason_code,
reason_string: ack.reason_string,
properties: ack.properties,
})
};
Ok(Some(Encoded::Packet(ack)))
} else {
Ok(None)
}
}
async fn control<C, E>(
pkt: Control<E>,
inner: &Inner<C>,
packet_id: u16,
) -> Result<Option<Encoded>, MqttError<E>>
where
C: Service<Control<E>, Response = ControlAck, Error = MqttError<E>>,
{
let mut error = matches!(pkt, Control::Error(_) | Control::ProtocolError(_));
let result = match inner.control.call(pkt).await {
Ok(result) => {
if let Some(id) = num::NonZeroU16::new(packet_id) {
inner.info.borrow_mut().inflight.remove(&id);
}
result
}
Err(err) => {
inner.drop_payload(&PayloadError::Service);
if error {
inner.sink.drop_sink();
return Err(err);
} else {
match err {
MqttError::Service(err) => {
error = true;
inner.control.call(Control::error(err)).await?
}
_ => return Err(err),
}
}
}
};
let response = if error {
if let Some(pkt) = result.packet {
let _ = inner.sink.encode_packet(pkt);
}
Ok(None)
} else {
Ok(result.packet.map(Encoded::Packet))
};
if result.disconnect {
inner.drop_payload(&PayloadError::Service);
inner.sink.drop_sink();
}
response
}
#[cfg(test)]
mod tests {
use ntex_io::{Io, testing::IoTest};
use ntex_service::{cfg::SharedCfg, fn_service};
use ntex_util::future::{Ready, lazy};
use super::*;
use crate::v5::MqttSink;
#[derive(Debug)]
struct TestError;
impl TryFrom<TestError> for PublishAck {
type Error = TestError;
fn try_from(err: TestError) -> Result<Self, Self::Error> {
Err(err)
}
}
#[ntex::test]
async fn test_wr_backpressure() {
let io = Io::new(IoTest::create().0, SharedCfg::new("DBG"));
let codec = codec::Codec::default();
let shared = Rc::new(MqttShared::new(io.get_ref(), codec, Default::default()));
let disp = Pipeline::new(Dispatcher::<_, _, _>::new(
shared.clone(),
fn_service(|p: Publish| Ready::Ok::<_, TestError>(p.ack())),
fn_service(|_| {
Ready::Ok::<_, MqttError<TestError>>(ControlAck {
packet: None,
disconnect: false,
})
}),
Default::default(),
));
let sink = MqttSink::new(shared.clone());
assert!(!sink.is_ready());
shared.set_cap(1);
assert!(sink.is_ready());
assert!(shared.wait_readiness().is_none());
disp.call(DispatchItem::WBackPressureEnabled).await.unwrap();
assert!(!sink.is_ready());
let rx = shared.wait_readiness();
let rx2 = shared.wait_readiness().unwrap();
assert!(rx.is_some());
let rx = rx.unwrap();
disp.call(DispatchItem::WBackPressureDisabled).await.unwrap();
assert!(lazy(|cx| rx.poll_recv(cx).is_ready()).await);
assert!(!lazy(|cx| rx2.poll_recv(cx).is_ready()).await);
}
}