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fuchsia / fuchsia / refs/heads/main / . / tools / fidl / fidlgen_rust / goldens / error_syntax.rs.golden
blob: ac1cbb911331b2a9d5540ee2169a65aab58bd0c5 [file] [log] [blame]
// WARNING: This file is machine generated by fidlgen.
// fidl_experiment = output_index_json
#![warn(clippy::all)]
#![allow(unused_parens, unused_mut, unused_imports, nonstandard_style)]
use {
bitflags::bitflags,
fidl::{
client::QueryResponseFut,
endpoints::{ControlHandle as _, Responder as _},
},
fuchsia_zircon_status as zx_status,
futures::future::{self, MaybeDone, TryFutureExt},
};
#[cfg(target_os = "fuchsia")]
use fuchsia_zircon as zx;
#[derive(Clone, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub struct ExampleUseOfErrorSyntaxCallWhichMayFailRequest {
pub s: String,
}
impl fidl::Persistable for ExampleUseOfErrorSyntaxCallWhichMayFailRequest {}
#[derive(Clone, Copy, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
#[repr(C)]
pub struct ExampleUseOfErrorSyntaxCallWhichMayFailResponse {
pub value: i64,
}
impl fidl::Persistable for ExampleUseOfErrorSyntaxCallWhichMayFailResponse {}
#[derive(Debug, Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Hash)]
pub struct ExampleUseOfErrorSyntaxMarker;
impl fidl::endpoints::ProtocolMarker for ExampleUseOfErrorSyntaxMarker {
type Proxy = ExampleUseOfErrorSyntaxProxy;
type RequestStream = ExampleUseOfErrorSyntaxRequestStream;
#[cfg(target_os = "fuchsia")]
type SynchronousProxy = ExampleUseOfErrorSyntaxSynchronousProxy;
const DEBUG_NAME: &'static str = "(anonymous) ExampleUseOfErrorSyntax";
}
pub type ExampleUseOfErrorSyntaxCallWhichMayFailResult = Result<i64, u32>;
pub trait ExampleUseOfErrorSyntaxProxyInterface: Send + Sync {
type ComposedCallWhichMayFailResponseFut: std::future::Future<
Output = Result<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
fidl::Error,
>,
> + Send;
fn r#composed_call_which_may_fail(&self, s: &str) -> Self::ComposedCallWhichMayFailResponseFut;
type CallWhichMayFailResponseFut: std::future::Future<
Output = Result<ExampleUseOfErrorSyntaxCallWhichMayFailResult, fidl::Error>,
> + Send;
fn r#call_which_may_fail(&self, s: &str) -> Self::CallWhichMayFailResponseFut;
}
#[derive(Debug)]
#[cfg(target_os = "fuchsia")]
pub struct ExampleUseOfErrorSyntaxSynchronousProxy {
client: fidl::client::sync::Client,
}
#[cfg(target_os = "fuchsia")]
impl fidl::endpoints::SynchronousProxy for ExampleUseOfErrorSyntaxSynchronousProxy {
type Proxy = ExampleUseOfErrorSyntaxProxy;
type Protocol = ExampleUseOfErrorSyntaxMarker;
fn from_channel(inner: fidl::Channel) -> Self {
Self::new(inner)
}
fn into_channel(self) -> fidl::Channel {
self.client.into_channel()
}
fn as_channel(&self) -> &fidl::Channel {
self.client.as_channel()
}
}
#[cfg(target_os = "fuchsia")]
impl ExampleUseOfErrorSyntaxSynchronousProxy {
pub fn new(channel: fidl::Channel) -> Self {
let protocol_name =
<ExampleUseOfErrorSyntaxMarker as fidl::endpoints::ProtocolMarker>::DEBUG_NAME;
Self { client: fidl::client::sync::Client::new(channel, protocol_name) }
}
pub fn into_channel(self) -> fidl::Channel {
self.client.into_channel()
}
/// Waits until an event arrives and returns it. It is safe for other
/// threads to make concurrent requests while waiting for an event.
pub fn wait_for_event(
&self,
deadline: zx::Time,
) -> Result<ExampleUseOfErrorSyntaxEvent, fidl::Error> {
ExampleUseOfErrorSyntaxEvent::decode(self.client.wait_for_event(deadline)?)
}
pub fn r#composed_call_which_may_fail(
&self,
mut s: &str,
___deadline: zx::Time,
) -> Result<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
fidl::Error,
> {
let _response = self.client.send_query::<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailRequest,
fidl::encoding::ResultType<fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResponse, u32>,
>(
(s,),
0x3179cf8f46814221,
fidl::encoding::DynamicFlags::empty(),
___deadline,
)?;
Ok(_response.map(|x| x.value))
}
pub fn r#call_which_may_fail(
&self,
mut s: &str,
___deadline: zx::Time,
) -> Result<ExampleUseOfErrorSyntaxCallWhichMayFailResult, fidl::Error> {
let _response = self.client.send_query::<
ExampleUseOfErrorSyntaxCallWhichMayFailRequest,
fidl::encoding::ResultType<ExampleUseOfErrorSyntaxCallWhichMayFailResponse, u32>,
>(
(s,),
0x3424ff83ce3004a2,
fidl::encoding::DynamicFlags::empty(),
___deadline,
)?;
Ok(_response.map(|x| x.value))
}
}
#[derive(Debug, Clone)]
pub struct ExampleUseOfErrorSyntaxProxy {
client: fidl::client::Client,
}
impl fidl::endpoints::Proxy for ExampleUseOfErrorSyntaxProxy {
type Protocol = ExampleUseOfErrorSyntaxMarker;
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 ExampleUseOfErrorSyntaxProxy {
/// Create a new Proxy for test.errorsyntax/ExampleUseOfErrorSyntax.
pub fn new(channel: fidl::AsyncChannel) -> Self {
let protocol_name =
<ExampleUseOfErrorSyntaxMarker as fidl::endpoints::ProtocolMarker>::DEBUG_NAME;
Self { client: fidl::client::Client::new(channel, protocol_name) }
}
/// Get a Stream of events from the remote end of the protocol.
///
/// # Panics
///
/// Panics if the event stream was already taken.
pub fn take_event_stream(&self) -> ExampleUseOfErrorSyntaxEventStream {
ExampleUseOfErrorSyntaxEventStream { event_receiver: self.client.take_event_receiver() }
}
pub fn r#composed_call_which_may_fail(
&self,
mut s: &str,
) -> fidl::client::QueryResponseFut<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
> {
ExampleUseOfErrorSyntaxProxyInterface::r#composed_call_which_may_fail(self, s)
}
pub fn r#call_which_may_fail(
&self,
mut s: &str,
) -> fidl::client::QueryResponseFut<ExampleUseOfErrorSyntaxCallWhichMayFailResult> {
ExampleUseOfErrorSyntaxProxyInterface::r#call_which_may_fail(self, s)
}
}
impl ExampleUseOfErrorSyntaxProxyInterface for ExampleUseOfErrorSyntaxProxy {
type ComposedCallWhichMayFailResponseFut = fidl::client::QueryResponseFut<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
>;
fn r#composed_call_which_may_fail(
&self,
mut s: &str,
) -> Self::ComposedCallWhichMayFailResponseFut {
fn _decode(
mut _buf: Result<fidl::MessageBufEtc, fidl::Error>,
) -> Result<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
fidl::Error,
> {
let _response = fidl::client::decode_transaction_body::<fidl::encoding::ResultType<fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResponse, u32>, 0x3179cf8f46814221>(_buf?)?;
Ok(_response.map(|x| x.value))
}
self.client.send_query_and_decode::<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailRequest,
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResult,
>(
(s,),
0x3179cf8f46814221,
fidl::encoding::DynamicFlags::empty(),
_decode,
)
}
type CallWhichMayFailResponseFut =
fidl::client::QueryResponseFut<ExampleUseOfErrorSyntaxCallWhichMayFailResult>;
fn r#call_which_may_fail(&self, mut s: &str) -> Self::CallWhichMayFailResponseFut {
fn _decode(
mut _buf: Result<fidl::MessageBufEtc, fidl::Error>,
) -> Result<ExampleUseOfErrorSyntaxCallWhichMayFailResult, fidl::Error> {
let _response = fidl::client::decode_transaction_body::<
fidl::encoding::ResultType<ExampleUseOfErrorSyntaxCallWhichMayFailResponse, u32>,
0x3424ff83ce3004a2,
>(_buf?)?;
Ok(_response.map(|x| x.value))
}
self.client.send_query_and_decode::<
ExampleUseOfErrorSyntaxCallWhichMayFailRequest,
ExampleUseOfErrorSyntaxCallWhichMayFailResult,
>(
(s,),
0x3424ff83ce3004a2,
fidl::encoding::DynamicFlags::empty(),
_decode,
)
}
}
pub struct ExampleUseOfErrorSyntaxEventStream {
event_receiver: fidl::client::EventReceiver,
}
impl std::marker::Unpin for ExampleUseOfErrorSyntaxEventStream {}
impl futures::stream::FusedStream for ExampleUseOfErrorSyntaxEventStream {
fn is_terminated(&self) -> bool {
self.event_receiver.is_terminated()
}
}
impl futures::Stream for ExampleUseOfErrorSyntaxEventStream {
type Item = Result<ExampleUseOfErrorSyntaxEvent, fidl::Error>;
fn poll_next(
mut self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Option<Self::Item>> {
match futures::ready!(futures::stream::StreamExt::poll_next_unpin(
&mut self.event_receiver,
cx
)?) {
Some(buf) => std::task::Poll::Ready(Some(ExampleUseOfErrorSyntaxEvent::decode(buf))),
None => std::task::Poll::Ready(None),
}
}
}
#[derive(Debug)]
pub enum ExampleUseOfErrorSyntaxEvent {}
impl ExampleUseOfErrorSyntaxEvent {
/// Decodes a message buffer as a [`ExampleUseOfErrorSyntaxEvent`].
fn decode(mut buf: fidl::MessageBufEtc) -> Result<ExampleUseOfErrorSyntaxEvent, fidl::Error> {
let (bytes, _handles) = buf.split_mut();
let (tx_header, _body_bytes) = fidl::encoding::decode_transaction_header(bytes)?;
debug_assert_eq!(tx_header.tx_id, 0);
match tx_header.ordinal {
_ => Err(fidl::Error::UnknownOrdinal {
ordinal: tx_header.ordinal,
protocol_name:
<ExampleUseOfErrorSyntaxMarker as fidl::endpoints::ProtocolMarker>::DEBUG_NAME,
}),
}
}
}
/// A Stream of incoming requests for test.errorsyntax/ExampleUseOfErrorSyntax.
pub struct ExampleUseOfErrorSyntaxRequestStream {
inner: std::sync::Arc<fidl::ServeInner>,
is_terminated: bool,
}
impl std::marker::Unpin for ExampleUseOfErrorSyntaxRequestStream {}
impl futures::stream::FusedStream for ExampleUseOfErrorSyntaxRequestStream {
fn is_terminated(&self) -> bool {
self.is_terminated
}
}
impl fidl::endpoints::RequestStream for ExampleUseOfErrorSyntaxRequestStream {
type Protocol = ExampleUseOfErrorSyntaxMarker;
type ControlHandle = ExampleUseOfErrorSyntaxControlHandle;
fn from_channel(channel: fidl::AsyncChannel) -> Self {
Self { inner: std::sync::Arc::new(fidl::ServeInner::new(channel)), is_terminated: false }
}
fn control_handle(&self) -> Self::ControlHandle {
ExampleUseOfErrorSyntaxControlHandle { 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 ExampleUseOfErrorSyntaxRequestStream {
type Item = Result<ExampleUseOfErrorSyntaxRequest, 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.check_shutdown(cx) {
this.is_terminated = true;
return std::task::Poll::Ready(None);
}
if this.is_terminated {
panic!("polled ExampleUseOfErrorSyntaxRequestStream 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)?;
std::task::Poll::Ready(Some(match header.ordinal {
0x3179cf8f46814221 => {
header.validate_request_tx_id(fidl::MethodType::TwoWay)?;
let mut req = fidl::new_empty!(fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailRequest);
fidl::encoding::Decoder::decode_into::<fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailRequest>(&header, _body_bytes, handles, &mut req)?;
let control_handle = ExampleUseOfErrorSyntaxControlHandle {
inner: this.inner.clone(),
};
Ok(ExampleUseOfErrorSyntaxRequest::ComposedCallWhichMayFail {s: req.s,
responder: ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder {
control_handle: std::mem::ManuallyDrop::new(control_handle),
tx_id: header.tx_id,
},
})
}
0x3424ff83ce3004a2 => {
header.validate_request_tx_id(fidl::MethodType::TwoWay)?;
let mut req = fidl::new_empty!(ExampleUseOfErrorSyntaxCallWhichMayFailRequest);
fidl::encoding::Decoder::decode_into::<ExampleUseOfErrorSyntaxCallWhichMayFailRequest>(&header, _body_bytes, handles, &mut req)?;
let control_handle = ExampleUseOfErrorSyntaxControlHandle {
inner: this.inner.clone(),
};
Ok(ExampleUseOfErrorSyntaxRequest::CallWhichMayFail {s: req.s,
responder: ExampleUseOfErrorSyntaxCallWhichMayFailResponder {
control_handle: std::mem::ManuallyDrop::new(control_handle),
tx_id: header.tx_id,
},
})
}
_ => Err(fidl::Error::UnknownOrdinal {
ordinal: header.ordinal,
protocol_name: <ExampleUseOfErrorSyntaxMarker as fidl::endpoints::ProtocolMarker>::DEBUG_NAME,
}),
}))
})
}
}
#[derive(Debug)]
pub enum ExampleUseOfErrorSyntaxRequest {
ComposedCallWhichMayFail {
s: String,
responder: ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder,
},
CallWhichMayFail {
s: String,
responder: ExampleUseOfErrorSyntaxCallWhichMayFailResponder,
},
}
impl ExampleUseOfErrorSyntaxRequest {
#[allow(irrefutable_let_patterns)]
pub fn into_composed_call_which_may_fail(
self,
) -> Option<(String, ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder)> {
if let ExampleUseOfErrorSyntaxRequest::ComposedCallWhichMayFail { s, responder } = self {
Some((s, responder))
} else {
None
}
}
#[allow(irrefutable_let_patterns)]
pub fn into_call_which_may_fail(
self,
) -> Option<(String, ExampleUseOfErrorSyntaxCallWhichMayFailResponder)> {
if let ExampleUseOfErrorSyntaxRequest::CallWhichMayFail { s, responder } = self {
Some((s, responder))
} else {
None
}
}
/// Name of the method defined in FIDL
pub fn method_name(&self) -> &'static str {
match *self {
ExampleUseOfErrorSyntaxRequest::ComposedCallWhichMayFail { .. } => {
"composed_call_which_may_fail"
}
ExampleUseOfErrorSyntaxRequest::CallWhichMayFail { .. } => "call_which_may_fail",
}
}
}
#[derive(Debug, Clone)]
pub struct ExampleUseOfErrorSyntaxControlHandle {
inner: std::sync::Arc<fidl::ServeInner>,
}
impl fidl::endpoints::ControlHandle for ExampleUseOfErrorSyntaxControlHandle {
fn shutdown(&self) {
self.inner.shutdown()
}
fn shutdown_with_epitaph(&self, status: zx_status::Status) {
self.inner.shutdown_with_epitaph(status)
}
fn is_closed(&self) -> bool {
self.inner.channel().is_closed()
}
fn on_closed(&self) -> fidl::OnSignalsRef<'_> {
self.inner.channel().on_closed()
}
}
impl ExampleUseOfErrorSyntaxControlHandle {}
#[must_use = "FIDL methods require a response to be sent"]
#[derive(Debug)]
pub struct ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder {
control_handle: std::mem::ManuallyDrop<ExampleUseOfErrorSyntaxControlHandle>,
tx_id: u32,
}
/// Set the the channel to be shutdown (see [`ExampleUseOfErrorSyntaxControlHandle::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 ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder {
fn drop(&mut self) {
self.control_handle.shutdown();
// Safety: drops once, never accessed again
unsafe { std::mem::ManuallyDrop::drop(&mut self.control_handle) };
}
}
impl fidl::endpoints::Responder for ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder {
type ControlHandle = ExampleUseOfErrorSyntaxControlHandle;
fn control_handle(&self) -> &ExampleUseOfErrorSyntaxControlHandle {
&self.control_handle
}
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);
}
}
impl ExampleUseOfErrorSyntaxComposedCallWhichMayFailResponder {
/// Sends a response to the FIDL transaction.
///
/// Sets the channel to shutdown if an error occurs.
pub fn send(self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
let _result = self.send_raw(result);
if _result.is_err() {
self.control_handle.shutdown();
}
self.drop_without_shutdown();
_result
}
/// Similar to "send" but does not shutdown the channel if an error occurs.
pub fn send_no_shutdown_on_err(self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
let _result = self.send_raw(result);
self.drop_without_shutdown();
_result
}
fn send_raw(&self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
self.control_handle.inner.send::<fidl::encoding::ResultType<
fidl_test_errorsyntax_parent::ParentUsesErrorSyntaxComposedCallWhichMayFailResponse,
u32,
>>(
result.map(|value| (value,)),
self.tx_id,
0x3179cf8f46814221,
fidl::encoding::DynamicFlags::empty(),
)
}
}
#[must_use = "FIDL methods require a response to be sent"]
#[derive(Debug)]
pub struct ExampleUseOfErrorSyntaxCallWhichMayFailResponder {
control_handle: std::mem::ManuallyDrop<ExampleUseOfErrorSyntaxControlHandle>,
tx_id: u32,
}
/// Set the the channel to be shutdown (see [`ExampleUseOfErrorSyntaxControlHandle::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 ExampleUseOfErrorSyntaxCallWhichMayFailResponder {
fn drop(&mut self) {
self.control_handle.shutdown();
// Safety: drops once, never accessed again
unsafe { std::mem::ManuallyDrop::drop(&mut self.control_handle) };
}
}
impl fidl::endpoints::Responder for ExampleUseOfErrorSyntaxCallWhichMayFailResponder {
type ControlHandle = ExampleUseOfErrorSyntaxControlHandle;
fn control_handle(&self) -> &ExampleUseOfErrorSyntaxControlHandle {
&self.control_handle
}
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);
}
}
impl ExampleUseOfErrorSyntaxCallWhichMayFailResponder {
/// Sends a response to the FIDL transaction.
///
/// Sets the channel to shutdown if an error occurs.
pub fn send(self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
let _result = self.send_raw(result);
if _result.is_err() {
self.control_handle.shutdown();
}
self.drop_without_shutdown();
_result
}
/// Similar to "send" but does not shutdown the channel if an error occurs.
pub fn send_no_shutdown_on_err(self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
let _result = self.send_raw(result);
self.drop_without_shutdown();
_result
}
fn send_raw(&self, mut result: Result<i64, u32>) -> Result<(), fidl::Error> {
self.control_handle.inner.send::<fidl::encoding::ResultType<
ExampleUseOfErrorSyntaxCallWhichMayFailResponse,
u32,
>>(
result.map(|value| (value,)),
self.tx_id,
0x3424ff83ce3004a2,
fidl::encoding::DynamicFlags::empty(),
)
}
}
mod internal {
use super::*;
unsafe impl fidl::encoding::TypeMarker for ExampleUseOfErrorSyntaxCallWhichMayFailRequest {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
16
}
}
impl fidl::encoding::ValueTypeMarker for ExampleUseOfErrorSyntaxCallWhichMayFailRequest {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<ExampleUseOfErrorSyntaxCallWhichMayFailRequest>
for &ExampleUseOfErrorSyntaxCallWhichMayFailRequest
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<ExampleUseOfErrorSyntaxCallWhichMayFailRequest>(offset);
// Delegate to tuple encoding.
fidl::encoding::Encode::<ExampleUseOfErrorSyntaxCallWhichMayFailRequest>::encode(
(<fidl::encoding::UnboundedString as fidl::encoding::ValueTypeMarker>::borrow(
&self.s,
),),
encoder,
offset,
_depth,
)
}
}
unsafe impl<T0: fidl::encoding::Encode<fidl::encoding::UnboundedString>>
fidl::encoding::Encode<ExampleUseOfErrorSyntaxCallWhichMayFailRequest> for (T0,)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<ExampleUseOfErrorSyntaxCallWhichMayFailRequest>(offset);
// Zero out padding regions. There's no need to apply masks
// because the unmasked parts will be overwritten by fields.
// Write the fields.
self.0.encode(encoder, offset + 0, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for ExampleUseOfErrorSyntaxCallWhichMayFailRequest {
#[inline(always)]
fn new_empty() -> Self {
Self { s: fidl::new_empty!(fidl::encoding::UnboundedString) }
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
// Verify that padding bytes are zero.
fidl::decode!(
fidl::encoding::UnboundedString,
&mut self.s,
decoder,
offset + 0,
_depth
)?;
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for ExampleUseOfErrorSyntaxCallWhichMayFailResponse {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn encode_is_copy() -> bool {
true
}
#[inline(always)]
fn decode_is_copy() -> bool {
true
}
}
impl fidl::encoding::ValueTypeMarker for ExampleUseOfErrorSyntaxCallWhichMayFailResponse {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<ExampleUseOfErrorSyntaxCallWhichMayFailResponse>
for &ExampleUseOfErrorSyntaxCallWhichMayFailResponse
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<ExampleUseOfErrorSyntaxCallWhichMayFailResponse>(offset);
unsafe {
// Copy the object into the buffer.
let buf_ptr = encoder.buf.as_mut_ptr().add(offset);
(buf_ptr as *mut ExampleUseOfErrorSyntaxCallWhichMayFailResponse).write_unaligned(
(self as *const ExampleUseOfErrorSyntaxCallWhichMayFailResponse).read(),
);
// Zero out padding regions. Unlike `fidl_struct_impl_noncopy!`, this must be
// done second because the memcpy will write garbage to these bytes.
}
Ok(())
}
}
unsafe impl<T0: fidl::encoding::Encode<i64>>
fidl::encoding::Encode<ExampleUseOfErrorSyntaxCallWhichMayFailResponse> for (T0,)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<ExampleUseOfErrorSyntaxCallWhichMayFailResponse>(offset);
// Zero out padding regions. There's no need to apply masks
// because the unmasked parts will be overwritten by fields.
// Write the fields.
self.0.encode(encoder, offset + 0, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for ExampleUseOfErrorSyntaxCallWhichMayFailResponse {
#[inline(always)]
fn new_empty() -> Self {
Self { value: fidl::new_empty!(i64) }
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let buf_ptr = unsafe { decoder.buf.as_ptr().add(offset) };
// Verify that padding bytes are zero.
// Copy from the buffer into the object.
unsafe {
std::ptr::copy_nonoverlapping(buf_ptr, self as *mut Self as *mut u8, 8);
}
Ok(())
}
}
}