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fuchsia / fuchsia / 6697568849879512cc8452e84c2db4c0da200466 / . / tools / fidl / fidlgen_rust / goldens / empty_struct.rs.golden
blob: afa21d173632bcd19581a260d050d9a173f8c99c [file] [log] [blame]
// WARNING: This file is machine generated by fidlgen.
#![allow(
unused_parens, // one-element-tuple-case is not a tuple
unused_mut, // not all args require mutation, but many do
nonstandard_style, // auto-caps does its best, but is not always successful
)]
#![recursion_limit = "512"]
#[cfg(target_os = "fuchsia")]
#[allow(unused_imports)]
use fuchsia_zircon as zx;
#[allow(unused_imports)]
use {
bitflags::bitflags,
fidl::{
client::{decode_transaction_body_fut, QueryResponseFut},
encoding::{Decodable as _, Encodable as _},
fidl_empty_struct, fidl_flexible_bits, fidl_flexible_enum, fidl_strict_bits,
fidl_strict_enum, fidl_struct, fidl_struct_copy, fidl_table, fidl_xunion,
wrap_handle_metadata,
},
fuchsia_zircon_status as zx_status,
futures::future::{self, MaybeDone, TryFutureExt},
};
const _FIDL_TRACE_BINDINGS_RUST: u32 = 6;
#[derive(Debug, Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Hash)]
pub struct Empty;
fidl_empty_struct!(Empty);
#[derive(Debug, Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Hash)]
pub struct EmptyProtocolMarker;
impl fidl::endpoints::ServiceMarker for EmptyProtocolMarker {
type Proxy = EmptyProtocolProxy;
type RequestStream = EmptyProtocolRequestStream;
const DEBUG_NAME: &'static str = "(anonymous) EmptyProtocol";
}
pub trait EmptyProtocolProxyInterface: Send + Sync {
fn r#send_(&self, e: &mut Empty) -> Result<(), fidl::Error>;
type ReceiveResponseFut: std::future::Future<Output = Result<(Empty), fidl::Error>> + Send;
type SendAndReceiveResponseFut: std::future::Future<Output = Result<(Empty), fidl::Error>>
+ Send;
fn r#send_and_receive(&self, e: &mut Empty) -> Self::SendAndReceiveResponseFut;
}
#[derive(Debug)]
#[cfg(target_os = "fuchsia")]
pub struct EmptyProtocolSynchronousProxy {
client: fidl::client::sync::Client,
}
#[cfg(target_os = "fuchsia")]
impl EmptyProtocolSynchronousProxy {
pub fn new(channel: fidl::Channel) -> Self {
let service_name = <EmptyProtocolMarker as fidl::endpoints::ServiceMarker>::DEBUG_NAME;
Self { client: fidl::client::sync::Client::new(channel, service_name) }
}
pub fn into_channel(self) -> fidl::Channel {
self.client.into_channel()
}
pub fn r#send_(&mut self, mut e: &mut Empty) -> Result<(), fidl::Error> {
self.client.send(&mut (e), 0x1e4e78d0556b6f28)
}
pub fn r#send_and_receive(
&mut self,
mut e: &mut Empty,
___deadline: zx::Time,
) -> Result<(Empty), fidl::Error> {
let _value: (Empty,) = self.client.send_query(&mut (e), 0x56ca6bd78bac3571, ___deadline)?;
Ok(_value.0)
}
}
#[derive(Debug, Clone)]
pub struct EmptyProtocolProxy {
client: fidl::client::Client,
}
impl fidl::endpoints::Proxy for EmptyProtocolProxy {
type Service = EmptyProtocolMarker;
fn from_channel(inner: fidl::AsyncChannel) -> Self {
Self::new(inner)
}
fn into_channel(self) -> Result<::fidl::AsyncChannel, Self> {
self.client.into_channel().map_err(|client| Self { client })
}
fn as_channel(&self) -> &::fidl::AsyncChannel {
self.client.as_channel()
}
}
impl EmptyProtocolProxy {
/// Create a new Proxy for EmptyProtocol
pub fn new(channel: fidl::AsyncChannel) -> Self {
let service_name = <EmptyProtocolMarker as fidl::endpoints::ServiceMarker>::DEBUG_NAME;
Self { client: fidl::client::Client::new(channel, service_name) }
}
/// Get a Stream of events from the remote end of the EmptyProtocol protocol
///
/// # Panics
///
/// Panics if the event stream was already taken.
pub fn take_event_stream(&self) -> EmptyProtocolEventStream {
EmptyProtocolEventStream { event_receiver: self.client.take_event_receiver() }
}
pub fn r#send_(&self, mut e: &mut Empty) -> Result<(), fidl::Error> {
EmptyProtocolProxyInterface::r#send_(self, e)
}
pub fn r#send_and_receive(&self, mut e: &mut Empty) -> fidl::client::QueryResponseFut<(Empty)> {
EmptyProtocolProxyInterface::r#send_and_receive(self, e)
}
}
impl EmptyProtocolProxyInterface for EmptyProtocolProxy {
fn r#send_(&self, mut e: &mut Empty) -> Result<(), fidl::Error> {
self.client.send(&mut (e), 0x1e4e78d0556b6f28)
}
type ReceiveResponseFut = fidl::client::QueryResponseFut<(Empty)>;
type SendAndReceiveResponseFut = fidl::client::QueryResponseFut<(Empty)>;
fn r#send_and_receive(&self, mut e: &mut Empty) -> Self::SendAndReceiveResponseFut {
fn transform(result: Result<(Empty,), fidl::Error>) -> Result<(Empty), fidl::Error> {
result.map(|_value| _value.0)
}
let send_result = self.client.call_send_raw_query(&mut (e), 0x56ca6bd78bac3571);
QueryResponseFut(match send_result {
Ok(res_fut) => future::maybe_done(
res_fut.and_then(|buf| decode_transaction_body_fut(buf, transform)),
),
Err(e) => MaybeDone::Done(Err(e)),
})
}
}
pub struct EmptyProtocolEventStream {
event_receiver: fidl::client::EventReceiver,
}
impl std::marker::Unpin for EmptyProtocolEventStream {}
impl futures::stream::FusedStream for EmptyProtocolEventStream {
fn is_terminated(&self) -> bool {
self.event_receiver.is_terminated()
}
}
impl futures::Stream for EmptyProtocolEventStream {
type Item = Result<EmptyProtocolEvent, fidl::Error>;
fn poll_next(
mut self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Option<Self::Item>> {
let mut buf = match futures::ready!(futures::stream::StreamExt::poll_next_unpin(
&mut self.event_receiver,
cx
)?) {
Some(buf) => buf,
None => return std::task::Poll::Ready(None),
};
let (bytes, _handles) = buf.split_mut();
let (tx_header, _body_bytes) = fidl::encoding::decode_transaction_header(bytes)?;
std::task::Poll::Ready(Some(match tx_header.ordinal() {
0x45bd261c537791e0 => {
let mut out_tuple: (Empty,) = fidl::encoding::Decodable::new_empty();
fidl::duration_begin!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolReceiveEvent");
fidl::trace_blob!("fidl:blob", "decode", bytes);
fidl::encoding::Decoder::decode_into(
&tx_header,
_body_bytes,
_handles,
&mut out_tuple,
)?;
fidl::duration_end!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => _handles.len() as u32);
Ok((EmptyProtocolEvent::Receive { e: out_tuple.0 }))
}
_ => Err(fidl::Error::UnknownOrdinal {
ordinal: tx_header.ordinal(),
service_name: <EmptyProtocolMarker as fidl::endpoints::ServiceMarker>::DEBUG_NAME,
}),
}))
}
}
#[derive(Debug)]
pub enum EmptyProtocolEvent {
Receive { e: Empty },
}
impl EmptyProtocolEvent {
#[allow(irrefutable_let_patterns)]
pub fn into_receive(self) -> Option<(Empty)> {
if let EmptyProtocolEvent::Receive { e } = self {
Some((e))
} else {
None
}
}
}
/// A type which can be used to send responses and events into a borrowed channel.
///
/// Note: this should only be used when the channel must be temporarily
/// borrowed. For a typical sending of events, use the send_ methods
/// on the ControlHandle types, which can be acquired through a
/// RequestStream or Responder type.
#[deprecated(note = "Use EmptyProtocolRequestStream / Responder instead")]
pub struct EmptyProtocolServerSender<'a> {
// Some protocols don't define events which would render this channel unused.
#[allow(dead_code)]
channel: &'a fidl::Channel,
}
#[allow(deprecated)]
impl<'a> EmptyProtocolServerSender<'a> {
pub fn new(channel: &'a fidl::Channel) -> Self {
Self { channel }
}
pub fn send_receive(&self, mut e: &mut Empty) -> Result<(), fidl::Error> {
fidl::encoding::with_tls_encode_buf(|bytes_, handles_| {
EmptyProtocolEncoder::encode_receive_response(bytes_, handles_, e)?;
self.channel
.write_etc(&*bytes_, &mut *handles_)
.map_err(fidl::Error::ServerResponseWrite)?;
Ok(())
})
}
pub fn send_send_and_receive_response(
&self,
txid: fidl::client::Txid,
mut e: &mut Empty,
) -> Result<(), fidl::Error> {
fidl::encoding::with_tls_encode_buf(|bytes_, handles_| {
EmptyProtocolEncoder::encode_send_and_receive_response(
bytes_,
handles_,
txid.as_raw_id(),
e,
)?;
self.channel
.write_etc(&*bytes_, &mut *handles_)
.map_err(fidl::Error::ServerResponseWrite)?;
Ok(())
})
}
}
/// A Stream of incoming requests for EmptyProtocol
pub struct EmptyProtocolRequestStream {
inner: std::sync::Arc<fidl::ServeInner>,
is_terminated: bool,
}
impl std::marker::Unpin for EmptyProtocolRequestStream {}
impl futures::stream::FusedStream for EmptyProtocolRequestStream {
fn is_terminated(&self) -> bool {
self.is_terminated
}
}
impl fidl::endpoints::RequestStream for EmptyProtocolRequestStream {
type Service = EmptyProtocolMarker;
/// Consume a channel to make a EmptyProtocolRequestStream
fn from_channel(channel: fidl::AsyncChannel) -> Self {
Self { inner: std::sync::Arc::new(fidl::ServeInner::new(channel)), is_terminated: false }
}
/// ControlHandle for the remote connection
type ControlHandle = EmptyProtocolControlHandle;
/// ControlHandle for the remote connection
fn control_handle(&self) -> Self::ControlHandle {
EmptyProtocolControlHandle { inner: self.inner.clone() }
}
fn into_inner(self) -> (::std::sync::Arc<fidl::ServeInner>, bool) {
(self.inner, self.is_terminated)
}
fn from_inner(inner: std::sync::Arc<fidl::ServeInner>, is_terminated: bool) -> Self {
Self { inner, is_terminated }
}
}
impl futures::Stream for EmptyProtocolRequestStream {
type Item = Result<EmptyProtocolRequest, fidl::Error>;
fn poll_next(
mut self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Option<Self::Item>> {
let this = &mut *self;
if this.inner.poll_shutdown(cx) {
this.is_terminated = true;
return std::task::Poll::Ready(None);
}
if this.is_terminated {
panic!("polled EmptyProtocolRequestStream after completion");
}
fidl::encoding::with_tls_decode_buf(|bytes, handles| {
match this.inner.channel().read_etc(cx, bytes, handles) {
std::task::Poll::Ready(Ok(())) => {}
std::task::Poll::Pending => return std::task::Poll::Pending,
std::task::Poll::Ready(Err(zx_status::Status::PEER_CLOSED)) => {
this.is_terminated = true;
return std::task::Poll::Ready(None);
}
std::task::Poll::Ready(Err(e)) => {
return std::task::Poll::Ready(Some(Err(fidl::Error::ServerRequestRead(e))))
}
}
// A message has been received from the channel
let (header, _body_bytes) = fidl::encoding::decode_transaction_header(bytes)?;
if !header.is_compatible() {
return std::task::Poll::Ready(Some(Err(fidl::Error::IncompatibleMagicNumber(
header.magic_number(),
))));
}
std::task::Poll::Ready(Some(match header.ordinal() {
0x1e4e78d0556b6f28 => {
let mut req: (Empty,) = fidl::encoding::Decodable::new_empty();
fidl::duration_begin!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSend_Request");
fidl::trace_blob!("fidl:blob", "decode", bytes);
fidl::encoding::Decoder::decode_into(&header, _body_bytes, handles, &mut req)?;
fidl::duration_end!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => handles.len() as u32);
let control_handle = EmptyProtocolControlHandle { inner: this.inner.clone() };
Ok(EmptyProtocolRequest::Send_ { e: req.0, control_handle })
}
0x56ca6bd78bac3571 => {
let mut req: (Empty,) = fidl::encoding::Decodable::new_empty();
fidl::duration_begin!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSendAndReceiveRequest");
fidl::trace_blob!("fidl:blob", "decode", bytes);
fidl::encoding::Decoder::decode_into(&header, _body_bytes, handles, &mut req)?;
fidl::duration_end!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => handles.len() as u32);
let control_handle = EmptyProtocolControlHandle { inner: this.inner.clone() };
Ok(EmptyProtocolRequest::SendAndReceive {
e: req.0,
responder: EmptyProtocolSendAndReceiveResponder {
control_handle: std::mem::ManuallyDrop::new(control_handle),
tx_id: header.tx_id(),
ordinal: header.ordinal(),
},
})
}
_ => Err(fidl::Error::UnknownOrdinal {
ordinal: header.ordinal(),
service_name:
<EmptyProtocolMarker as fidl::endpoints::ServiceMarker>::DEBUG_NAME,
}),
}))
})
}
}
/// Represents a single request.
/// RequestMessages should only be used for manual deserialization when higher level
/// structs such as RequestStream cannot be used. One usually would only encounter
/// such scenarios when working with legacy FIDL code (prior to FIDL generated client/server bindings).
#[derive(Debug)]
#[deprecated(note = "Use EmptyProtocolRequest instead")]
pub enum EmptyProtocolRequestMessage {
Send_ { e: Empty },
SendAndReceive { e: Empty, tx_id: fidl::client::Txid },
}
#[allow(deprecated)]
impl EmptyProtocolRequestMessage {
pub fn decode(
bytes: &[u8],
_handles: &mut [fidl::HandleInfo],
) -> Result<EmptyProtocolRequestMessage, fidl::Error> {
let (header, _body_bytes) = fidl::encoding::decode_transaction_header(bytes)?;
match header.ordinal() {
0x1e4e78d0556b6f28 => {
let mut out_tuple: (Empty,) = fidl::encoding::Decodable::new_empty();
fidl::duration_begin!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSend_Request");
fidl::trace_blob!("fidl:blob", "decode", bytes);
fidl::encoding::Decoder::decode_into(
&header,
_body_bytes,
_handles,
&mut out_tuple,
)?;
fidl::duration_end!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => _handles.len() as u32);
Ok(EmptyProtocolRequestMessage::Send_ { e: out_tuple.0 })
}
0x56ca6bd78bac3571 => {
let mut out_tuple: (Empty,) = fidl::encoding::Decodable::new_empty();
fidl::duration_begin!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSendAndReceiveRequest");
fidl::trace_blob!("fidl:blob", "decode", bytes);
fidl::encoding::Decoder::decode_into(
&header,
_body_bytes,
_handles,
&mut out_tuple,
)?;
fidl::duration_end!("fidl", "decode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => _handles.len() as u32);
Ok(EmptyProtocolRequestMessage::SendAndReceive {
e: out_tuple.0,
tx_id: header.tx_id().into(),
})
}
_ => Err(fidl::Error::UnknownOrdinal {
ordinal: header.ordinal(),
service_name: <EmptyProtocolMarker as fidl::endpoints::ServiceMarker>::DEBUG_NAME,
}),
}
}
}
#[derive(Debug)]
pub enum EmptyProtocolRequest {
Send_ { e: Empty, control_handle: EmptyProtocolControlHandle },
SendAndReceive { e: Empty, responder: EmptyProtocolSendAndReceiveResponder },
}
impl EmptyProtocolRequest {
#[allow(irrefutable_let_patterns)]
pub fn into_send_(self) -> Option<(Empty, EmptyProtocolControlHandle)> {
if let EmptyProtocolRequest::Send_ { e, control_handle } = self {
Some((e, control_handle))
} else {
None
}
}
#[allow(irrefutable_let_patterns)]
pub fn into_send_and_receive(self) -> Option<(Empty, EmptyProtocolSendAndReceiveResponder)> {
if let EmptyProtocolRequest::SendAndReceive { e, responder } = self {
Some((e, responder))
} else {
None
}
}
/// Name of the method defined in FIDL
pub fn method_name(&self) -> &'static str {
match *self {
EmptyProtocolRequest::Send_ { .. } => "send_",
EmptyProtocolRequest::SendAndReceive { .. } => "send_and_receive",
}
}
}
pub struct EmptyProtocolEncoder;
impl EmptyProtocolEncoder {
pub fn encode_send__request<'a>(
out_bytes: &'a mut Vec<u8>,
out_handles: &'a mut Vec<fidl::HandleDisposition<'static>>,
mut in_e: &mut Empty,
) -> Result<(), fidl::Error> {
let header = fidl::encoding::TransactionHeader::new(0, 0x1e4e78d0556b6f28);
let mut body = (in_e,);
let mut msg = fidl::encoding::TransactionMessage { header, body: &mut body };
fidl::duration_begin!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSend_Request");
fidl::encoding::Encoder::encode(out_bytes, out_handles, &mut msg)?;
fidl::trace_blob!("fidl:blob", "encode", out_bytes.as_slice());
fidl::duration_end!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => out_bytes.len() as u32, "handle_count" => out_handles.len() as u32);
Ok(())
}
pub fn encode_receive_response<'a>(
out_bytes: &'a mut Vec<u8>,
out_handles: &'a mut Vec<fidl::HandleDisposition<'static>>,
mut in_e: &mut Empty,
) -> Result<(), fidl::Error> {
let header = fidl::encoding::TransactionHeader::new(0, 0x45bd261c537791e0);
let mut body = (in_e,);
let mut msg = fidl::encoding::TransactionMessage { header, body: &mut body };
fidl::duration_begin!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolReceiveResponse");
fidl::encoding::Encoder::encode(out_bytes, out_handles, &mut msg)?;
fidl::trace_blob!("fidl:blob", "encode", out_bytes.as_slice());
fidl::duration_end!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => out_bytes.len() as u32, "handle_count" => out_handles.len() as u32);
Ok(())
}
pub fn encode_send_and_receive_request<'a>(
out_bytes: &'a mut Vec<u8>,
out_handles: &'a mut Vec<fidl::HandleDisposition<'static>>,
tx_id: u32,
mut in_e: &mut Empty,
) -> Result<(), fidl::Error> {
let header = fidl::encoding::TransactionHeader::new(tx_id, 0x56ca6bd78bac3571);
let mut body = (in_e,);
let mut msg = fidl::encoding::TransactionMessage { header, body: &mut body };
fidl::duration_begin!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSendAndReceiveRequest");
fidl::encoding::Encoder::encode(out_bytes, out_handles, &mut msg)?;
fidl::trace_blob!("fidl:blob", "encode", out_bytes.as_slice());
fidl::duration_end!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => out_bytes.len() as u32, "handle_count" => out_handles.len() as u32);
Ok(())
}
pub fn encode_send_and_receive_response<'a>(
out_bytes: &'a mut Vec<u8>,
out_handles: &'a mut Vec<fidl::HandleDisposition<'static>>,
tx_id: u32,
mut in_e: &mut Empty,
) -> Result<(), fidl::Error> {
let header = fidl::encoding::TransactionHeader::new(tx_id, 0x56ca6bd78bac3571);
let mut body = (in_e,);
let mut msg = fidl::encoding::TransactionMessage { header, body: &mut body };
fidl::duration_begin!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSendAndReceiveResponse");
fidl::encoding::Encoder::encode(out_bytes, out_handles, &mut msg)?;
fidl::trace_blob!("fidl:blob", "encode", out_bytes.as_slice());
fidl::duration_end!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => out_bytes.len() as u32, "handle_count" => out_handles.len() as u32);
Ok(())
}
}
#[derive(Debug, Clone)]
pub struct EmptyProtocolControlHandle {
inner: std::sync::Arc<fidl::ServeInner>,
}
impl EmptyProtocolControlHandle {
/// Set the server to shutdown. The underlying channel is only closed the
/// next time the stream is polled.
pub fn shutdown(&self) {
self.inner.shutdown()
}
pub fn shutdown_with_epitaph(&self, status: zx_status::Status) {
self.inner.shutdown_with_epitaph(status)
}
pub fn send_receive(&self, mut e: &mut Empty) -> Result<(), fidl::Error> {
let mut response = (e);
let mut msg = fidl::encoding::TransactionMessage {
header: fidl::encoding::TransactionHeader::new(0, 0x45bd261c537791e0),
body: &mut response,
};
fidl::encoding::with_tls_encoded(&mut msg, |bytes, handles| {
self.inner
.channel()
.write_etc(&*bytes, &mut *handles)
.map_err(fidl::Error::ServerResponseWrite)
})?;
Ok(())
}
}
#[must_use = "FIDL methods require a response to be sent"]
#[derive(Debug)]
pub struct EmptyProtocolSendAndReceiveResponder {
control_handle: std::mem::ManuallyDrop<EmptyProtocolControlHandle>,
tx_id: u32,
ordinal: u64,
}
/// Set the the channel to be shutdown (see [`EmptyProtocolControlHandle::shutdown`])
/// if the responder is dropped without sending a response, so that the client
/// doesn't hang. To prevent this behavior, call `drop_without_shutdown`.
impl std::ops::Drop for EmptyProtocolSendAndReceiveResponder {
fn drop(&mut self) {
self.control_handle.shutdown();
// Safety: drops once, never accessed again
unsafe { std::mem::ManuallyDrop::drop(&mut self.control_handle) };
}
}
impl EmptyProtocolSendAndReceiveResponder {
pub fn control_handle(&self) -> &EmptyProtocolControlHandle {
&self.control_handle
}
/// Drop the Responder without setting the channel to shutdown.
///
/// This method shouldn't normally be used-- instead, send a response
/// to prevent the channel from shutting down.
pub fn drop_without_shutdown(mut self) {
// Safety: drops once, never accessed again due to mem::forget
unsafe { std::mem::ManuallyDrop::drop(&mut self.control_handle) };
// Prevent Drop from running (which would shut down the channel)
std::mem::forget(self);
}
/// Sends a response to the FIDL transaction.
///
/// Sets the channel to shutdown if an error occurs.
pub fn send(self, mut e: &mut Empty) -> Result<(), fidl::Error> {
let r = self.send_raw(e);
if r.is_err() {
self.control_handle.shutdown();
}
self.drop_without_shutdown();
r
}
/// Similar to "send" but does not shutdown the channel if
/// an error occurs.
pub fn send_no_shutdown_on_err(self, mut e: &mut Empty) -> Result<(), fidl::Error> {
let r = self.send_raw(e);
self.drop_without_shutdown();
r
}
fn send_raw(&self, mut e: &mut Empty) -> Result<(), fidl::Error> {
let mut response = (e);
let mut msg = fidl::encoding::TransactionMessage {
header: fidl::encoding::TransactionHeader::new(self.tx_id, self.ordinal),
body: &mut response,
};
fidl::encoding::with_tls_encode_buf(|bytes, handles| {
fidl::duration_begin!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "name" => "fidl.test.emptystruct/EmptyProtocolSendAndReceiveResponse");
fidl::encoding::Encoder::encode(bytes, handles, &mut msg)?;
fidl::trace_blob!("fidl:blob", "encode", bytes.as_slice());
fidl::duration_end!("fidl", "encode", "bindings" => _FIDL_TRACE_BINDINGS_RUST, "size" => bytes.len() as u32, "handle_count" => handles.len() as u32);
self.control_handle
.inner
.channel()
.write_etc(&*bytes, &mut *handles)
.map_err(fidl::Error::ServerResponseWrite)?;
Ok(())
})
}
}