x86_64/usr/lib/rustlib/src/rust/library/proc_macro/src/bridge/server.rs - manifest_repos/toolchain - Git at Google

 //! Server-side traits.

 use super::*;

 use std::cell::Cell;
 use std::marker::PhantomData;

 // FIXME(eddyb) generate the definition of `HandleStore` in `server.rs`.
 use super::client::HandleStore;

 pub trait Types {
     type FreeFunctions: 'static;
     type TokenStream: 'static + Clone;
     type SourceFile: 'static + Clone;
     type Span: 'static + Copy + Eq + Hash;
     type Symbol: 'static;
 }

 /// Declare an associated fn of one of the traits below, adding necessary
 /// default bodies.
 macro_rules! associated_fn {
     (fn drop(&mut self, $arg:ident: $arg_ty:ty)) =>
         (fn drop(&mut self, $arg: $arg_ty) { mem::drop($arg) });

     (fn clone(&mut self, $arg:ident: $arg_ty:ty) -> $ret_ty:ty) =>
         (fn clone(&mut self, $arg: $arg_ty) -> $ret_ty { $arg.clone() });

     ($($item:tt)*) => ($($item)*;)
 }

 macro_rules! declare_server_traits {
     ($($name:ident {
         $(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
     }),* $(,)?) => {
         $(pub trait $name: Types {
             $(associated_fn!(fn $method(&mut self, $($arg: $arg_ty),*) $(-> $ret_ty)?);)*
         })*

         pub trait Server: Types $(+ $name)* {
             fn globals(&mut self) -> ExpnGlobals<Self::Span>;

             /// Intern a symbol received from RPC
             fn intern_symbol(ident: &str) -> Self::Symbol;

             /// Recover the string value of a symbol, and invoke a callback with it.
             fn with_symbol_string(symbol: &Self::Symbol, f: impl FnOnce(&str));
         }
     }
 }
 with_api!(Self, self_, declare_server_traits);

 pub(super) struct MarkedTypes<S: Types>(S);

 impl<S: Server> Server for MarkedTypes<S> {
     fn globals(&mut self) -> ExpnGlobals<Self::Span> {
         <_>::mark(Server::globals(&mut self.0))
     }
     fn intern_symbol(ident: &str) -> Self::Symbol {
         <_>::mark(S::intern_symbol(ident))
     }
     fn with_symbol_string(symbol: &Self::Symbol, f: impl FnOnce(&str)) {
         S::with_symbol_string(symbol.unmark(), f)
     }
 }

 macro_rules! define_mark_types_impls {
     ($($name:ident {
         $(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
     }),* $(,)?) => {
         impl<S: Types> Types for MarkedTypes<S> {
             $(type $name = Marked<S::$name, client::$name>;)*
         }

         $(impl<S: $name> $name for MarkedTypes<S> {
             $(fn $method(&mut self, $($arg: $arg_ty),*) $(-> $ret_ty)? {
                 <_>::mark($name::$method(&mut self.0, $($arg.unmark()),*))
             })*
         })*
     }
 }
 with_api!(Self, self_, define_mark_types_impls);

 struct Dispatcher<S: Types> {
     handle_store: HandleStore<S>,
     server: S,
 }

 macro_rules! define_dispatcher_impl {
     ($($name:ident {
         $(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
     }),* $(,)?) => {
         // FIXME(eddyb) `pub` only for `ExecutionStrategy` below.
         pub trait DispatcherTrait {
             // HACK(eddyb) these are here to allow `Self::$name` to work below.
             $(type $name;)*

             fn dispatch(&mut self, buf: Buffer) -> Buffer;
         }

         impl<S: Server> DispatcherTrait for Dispatcher<MarkedTypes<S>> {
             $(type $name = <MarkedTypes<S> as Types>::$name;)*

             fn dispatch(&mut self, mut buf: Buffer) -> Buffer {
                 let Dispatcher { handle_store, server } = self;

                 let mut reader = &buf[..];
                 match api_tags::Method::decode(&mut reader, &mut ()) {
                     $(api_tags::Method::$name(m) => match m {
                         $(api_tags::$name::$method => {
                             let mut call_method = || {
                                 reverse_decode!(reader, handle_store; $($arg: $arg_ty),*);
                                 $name::$method(server, $($arg),*)
                             };
                             // HACK(eddyb) don't use `panic::catch_unwind` in a panic.
                             // If client and server happen to use the same `libstd`,
                             // `catch_unwind` asserts that the panic counter was 0,
                             // even when the closure passed to it didn't panic.
                             let r = if thread::panicking() {
                                 Ok(call_method())
                             } else {
                                 panic::catch_unwind(panic::AssertUnwindSafe(call_method))
                                     .map_err(PanicMessage::from)
                             };

                             buf.clear();
                             r.encode(&mut buf, handle_store);
                         })*
                     }),*
                 }
                 buf
             }
         }
     }
 }
 with_api!(Self, self_, define_dispatcher_impl);

 pub trait ExecutionStrategy {
     fn run_bridge_and_client(
         &self,
         dispatcher: &mut impl DispatcherTrait,
         input: Buffer,
         run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
         force_show_panics: bool,
     ) -> Buffer;
 }

 thread_local! {
     /// While running a proc-macro with the same-thread executor, this flag will
     /// be set, forcing nested proc-macro invocations (e.g. due to
     /// `TokenStream::expand_expr`) to be run using a cross-thread executor.
     ///
     /// This is required as the thread-local state in the proc_macro client does
     /// not handle being re-entered, and will invalidate all `Symbol`s when
     /// entering a nested macro.
     static ALREADY_RUNNING_SAME_THREAD: Cell<bool> = Cell::new(false);
 }

 /// Keep `ALREADY_RUNNING_SAME_THREAD` (see also its documentation)
 /// set to `true`, preventing same-thread reentrance.
 struct RunningSameThreadGuard(());

 impl RunningSameThreadGuard {
     fn new() -> Self {
         let already_running = ALREADY_RUNNING_SAME_THREAD.replace(true);
         assert!(
             !already_running,
             "same-thread nesting (\"reentrance\") of proc macro executions is not supported"
         );
         RunningSameThreadGuard(())
     }
 }

 impl Drop for RunningSameThreadGuard {
     fn drop(&mut self) {
         ALREADY_RUNNING_SAME_THREAD.set(false);
     }
 }

 pub struct MaybeCrossThread<P> {
     cross_thread: bool,
     marker: PhantomData<P>,
 }

 impl<P> MaybeCrossThread<P> {
     pub const fn new(cross_thread: bool) -> Self {
         MaybeCrossThread { cross_thread, marker: PhantomData }
     }
 }

 impl<P> ExecutionStrategy for MaybeCrossThread<P>
 where
     P: MessagePipe<Buffer> + Send + 'static,
 {
     fn run_bridge_and_client(
         &self,
         dispatcher: &mut impl DispatcherTrait,
         input: Buffer,
         run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
         force_show_panics: bool,
     ) -> Buffer {
         if self.cross_thread || ALREADY_RUNNING_SAME_THREAD.get() {
             <CrossThread<P>>::new().run_bridge_and_client(
                 dispatcher,
                 input,
                 run_client,
                 force_show_panics,
             )
         } else {
             SameThread.run_bridge_and_client(dispatcher, input, run_client, force_show_panics)
         }
     }
 }

 pub struct SameThread;

 impl ExecutionStrategy for SameThread {
     fn run_bridge_and_client(
         &self,
         dispatcher: &mut impl DispatcherTrait,
         input: Buffer,
         run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
         force_show_panics: bool,
     ) -> Buffer {
         let _guard = RunningSameThreadGuard::new();

         let mut dispatch = |buf| dispatcher.dispatch(buf);

         run_client(BridgeConfig {
             input,
             dispatch: (&mut dispatch).into(),
             force_show_panics,
             _marker: marker::PhantomData,
         })
     }
 }

 pub struct CrossThread<P>(PhantomData<P>);

 impl<P> CrossThread<P> {
     pub const fn new() -> Self {
         CrossThread(PhantomData)
     }
 }

 impl<P> ExecutionStrategy for CrossThread<P>
 where
     P: MessagePipe<Buffer> + Send + 'static,
 {
     fn run_bridge_and_client(
         &self,
         dispatcher: &mut impl DispatcherTrait,
         input: Buffer,
         run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
         force_show_panics: bool,
     ) -> Buffer {
         let (mut server, mut client) = P::new();

         let join_handle = thread::spawn(move || {
             let mut dispatch = |b: Buffer| -> Buffer {
                 client.send(b);
                 client.recv().expect("server died while client waiting for reply")
             };

             run_client(BridgeConfig {
                 input,
                 dispatch: (&mut dispatch).into(),
                 force_show_panics,
                 _marker: marker::PhantomData,
             })
         });

         while let Some(b) = server.recv() {
             server.send(dispatcher.dispatch(b));
         }

         join_handle.join().unwrap()
     }
 }

 /// A message pipe used for communicating between server and client threads.
 pub trait MessagePipe<T>: Sized {
     /// Create a new pair of endpoints for the message pipe.
     fn new() -> (Self, Self);

     /// Send a message to the other endpoint of this pipe.
     fn send(&mut self, value: T);

     /// Receive a message from the other endpoint of this pipe.
     ///
     /// Returns `None` if the other end of the pipe has been destroyed, and no
     /// message was received.
     fn recv(&mut self) -> Option<T>;
 }

 fn run_server<
     S: Server,
     I: Encode<HandleStore<MarkedTypes<S>>>,
     O: for<'a, 's> DecodeMut<'a, 's, HandleStore<MarkedTypes<S>>>,
 >(
     strategy: &impl ExecutionStrategy,
     handle_counters: &'static client::HandleCounters,
     server: S,
     input: I,
     run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
     force_show_panics: bool,
 ) -> Result<O, PanicMessage> {
     let mut dispatcher =
         Dispatcher { handle_store: HandleStore::new(handle_counters), server: MarkedTypes(server) };

     let globals = dispatcher.server.globals();

     let mut buf = Buffer::new();
     (globals, input).encode(&mut buf, &mut dispatcher.handle_store);

     buf = strategy.run_bridge_and_client(&mut dispatcher, buf, run_client, force_show_panics);

     Result::decode(&mut &buf[..], &mut dispatcher.handle_store)
 }

 impl client::Client<crate::TokenStream, crate::TokenStream> {
     pub fn run<S>(
         &self,
         strategy: &impl ExecutionStrategy,
         server: S,
         input: S::TokenStream,
         force_show_panics: bool,
     ) -> Result<S::TokenStream, PanicMessage>
     where
         S: Server,
         S::TokenStream: Default,
     {
         let client::Client { get_handle_counters, run, _marker } = *self;
         run_server(
             strategy,
             get_handle_counters(),
             server,
             <MarkedTypes<S> as Types>::TokenStream::mark(input),
             run,
             force_show_panics,
         )
         .map(|s| <Option<<MarkedTypes<S> as Types>::TokenStream>>::unmark(s).unwrap_or_default())
     }
 }

 impl client::Client<(crate::TokenStream, crate::TokenStream), crate::TokenStream> {
     pub fn run<S>(
         &self,
         strategy: &impl ExecutionStrategy,
         server: S,
         input: S::TokenStream,
         input2: S::TokenStream,
         force_show_panics: bool,
     ) -> Result<S::TokenStream, PanicMessage>
     where
         S: Server,
         S::TokenStream: Default,
     {
         let client::Client { get_handle_counters, run, _marker } = *self;
         run_server(
             strategy,
             get_handle_counters(),
             server,
             (
                 <MarkedTypes<S> as Types>::TokenStream::mark(input),
                 <MarkedTypes<S> as Types>::TokenStream::mark(input2),
             ),
             run,
             force_show_panics,
         )
         .map(|s| <Option<<MarkedTypes<S> as Types>::TokenStream>>::unmark(s).unwrap_or_default())
     }
 }
	//! Server-side traits.

	use super::*;

	use std::cell::Cell;
	use std::marker::PhantomData;

	// FIXME(eddyb) generate the definition of `HandleStore` in `server.rs`.
	use super::client::HandleStore;

	pub trait Types {
	type FreeFunctions: 'static;
	type TokenStream: 'static + Clone;
	type SourceFile: 'static + Clone;
	type Span: 'static + Copy + Eq + Hash;
	type Symbol: 'static;
	}

	/// Declare an associated fn of one of the traits below, adding necessary
	/// default bodies.
	macro_rules! associated_fn {
	(fn drop(&mut self, $arg:ident: $arg_ty:ty)) =>
	(fn drop(&mut self, $arg: $arg_ty) { mem::drop($arg) });

	(fn clone(&mut self, $arg:ident: $arg_ty:ty) -> $ret_ty:ty) =>
	(fn clone(&mut self, $arg: $arg_ty) -> $ret_ty { $arg.clone() });

	($($item:tt)) => ($($item);)
	}

	macro_rules! declare_server_traits {
	($($name:ident {
	$(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
	}),* $(,)?) => {
	$(pub trait $name: Types {
	$(associated_fn!(fn $method(&mut self, $($arg: $arg_ty),) $(-> $ret_ty)?);)
	})*

	pub trait Server: Types $(+ $name)* {
	fn globals(&mut self) -> ExpnGlobals<Self::Span>;

	/// Intern a symbol received from RPC
	fn intern_symbol(ident: &str) -> Self::Symbol;

	/// Recover the string value of a symbol, and invoke a callback with it.
	fn with_symbol_string(symbol: &Self::Symbol, f: impl FnOnce(&str));
	}
	}
	}
	with_api!(Self, self_, declare_server_traits);

	pub(super) struct MarkedTypes<S: Types>(S);

	impl<S: Server> Server for MarkedTypes<S> {
	fn globals(&mut self) -> ExpnGlobals<Self::Span> {
	<_>::mark(Server::globals(&mut self.0))
	}
	fn intern_symbol(ident: &str) -> Self::Symbol {
	<_>::mark(S::intern_symbol(ident))
	}
	fn with_symbol_string(symbol: &Self::Symbol, f: impl FnOnce(&str)) {
	S::with_symbol_string(symbol.unmark(), f)
	}
	}

	macro_rules! define_mark_types_impls {
	($($name:ident {
	$(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
	}),* $(,)?) => {
	impl<S: Types> Types for MarkedTypes<S> {
	$(type $name = Marked<S::$name, client::$name>;)*
	}

	$(impl<S: $name> $name for MarkedTypes<S> {
	$(fn $method(&mut self, $($arg: $arg_ty),*) $(-> $ret_ty)? {
	<_>::mark($name::$method(&mut self.0, $($arg.unmark()),*))
	})*
	})*
	}
	}
	with_api!(Self, self_, define_mark_types_impls);

	struct Dispatcher<S: Types> {
	handle_store: HandleStore<S>,
	server: S,
	}

	macro_rules! define_dispatcher_impl {
	($($name:ident {
	$(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)?;)*
	}),* $(,)?) => {
	// FIXME(eddyb) `pub` only for `ExecutionStrategy` below.
	pub trait DispatcherTrait {
	// HACK(eddyb) these are here to allow `Self::$name` to work below.
	$(type $name;)*

	fn dispatch(&mut self, buf: Buffer) -> Buffer;
	}

	impl<S: Server> DispatcherTrait for Dispatcher<MarkedTypes<S>> {
	$(type $name = <MarkedTypes<S> as Types>::$name;)*

	fn dispatch(&mut self, mut buf: Buffer) -> Buffer {
	let Dispatcher { handle_store, server } = self;

	let mut reader = &buf[..];
	match api_tags::Method::decode(&mut reader, &mut ()) {
	$(api_tags::Method::$name(m) => match m {
	$(api_tags::$name::$method => {
	let mut call_method = \|\| {
	reverse_decode!(reader, handle_store; $($arg: $arg_ty),*);
	$name::$method(server, $($arg),*)
	};
	// HACK(eddyb) don't use `panic::catch_unwind` in a panic.
	// If client and server happen to use the same `libstd`,
	// `catch_unwind` asserts that the panic counter was 0,
	// even when the closure passed to it didn't panic.
	let r = if thread::panicking() {
	Ok(call_method())
	} else {
	panic::catch_unwind(panic::AssertUnwindSafe(call_method))
	.map_err(PanicMessage::from)
	};

	buf.clear();
	r.encode(&mut buf, handle_store);
	})*
	}),*
	}
	buf
	}
	}
	}
	}
	with_api!(Self, self_, define_dispatcher_impl);

	pub trait ExecutionStrategy {
	fn run_bridge_and_client(
	&self,
	dispatcher: &mut impl DispatcherTrait,
	input: Buffer,
	run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
	force_show_panics: bool,
	) -> Buffer;
	}

	thread_local! {
	/// While running a proc-macro with the same-thread executor, this flag will
	/// be set, forcing nested proc-macro invocations (e.g. due to
	/// `TokenStream::expand_expr`) to be run using a cross-thread executor.
	///
	/// This is required as the thread-local state in the proc_macro client does
	/// not handle being re-entered, and will invalidate all `Symbol`s when
	/// entering a nested macro.
	static ALREADY_RUNNING_SAME_THREAD: Cell<bool> = Cell::new(false);
	}

	/// Keep `ALREADY_RUNNING_SAME_THREAD` (see also its documentation)
	/// set to `true`, preventing same-thread reentrance.
	struct RunningSameThreadGuard(());

	impl RunningSameThreadGuard {
	fn new() -> Self {
	let already_running = ALREADY_RUNNING_SAME_THREAD.replace(true);
	assert!(
	!already_running,
	"same-thread nesting (\"reentrance\") of proc macro executions is not supported"
	);
	RunningSameThreadGuard(())
	}
	}

	impl Drop for RunningSameThreadGuard {
	fn drop(&mut self) {
	ALREADY_RUNNING_SAME_THREAD.set(false);
	}
	}

	pub struct MaybeCrossThread<P> {
	cross_thread: bool,
	marker: PhantomData<P>,
	}

	impl<P> MaybeCrossThread<P> {
	pub const fn new(cross_thread: bool) -> Self {
	MaybeCrossThread { cross_thread, marker: PhantomData }
	}
	}

	impl<P> ExecutionStrategy for MaybeCrossThread<P>
	where
	P: MessagePipe<Buffer> + Send + 'static,
	{
	fn run_bridge_and_client(
	&self,
	dispatcher: &mut impl DispatcherTrait,
	input: Buffer,
	run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
	force_show_panics: bool,
	) -> Buffer {
	if self.cross_thread \|\| ALREADY_RUNNING_SAME_THREAD.get() {
	<CrossThread<P>>::new().run_bridge_and_client(
	dispatcher,
	input,
	run_client,
	force_show_panics,
	)
	} else {
	SameThread.run_bridge_and_client(dispatcher, input, run_client, force_show_panics)
	}
	}
	}

	pub struct SameThread;

	impl ExecutionStrategy for SameThread {
	fn run_bridge_and_client(
	&self,
	dispatcher: &mut impl DispatcherTrait,
	input: Buffer,
	run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
	force_show_panics: bool,
	) -> Buffer {
	let _guard = RunningSameThreadGuard::new();

	let mut dispatch = \|buf\| dispatcher.dispatch(buf);

	run_client(BridgeConfig {
	input,
	dispatch: (&mut dispatch).into(),
	force_show_panics,
	_marker: marker::PhantomData,
	})
	}
	}

	pub struct CrossThread<P>(PhantomData<P>);

	impl<P> CrossThread<P> {
	pub const fn new() -> Self {
	CrossThread(PhantomData)
	}
	}

	impl<P> ExecutionStrategy for CrossThread<P>
	where
	P: MessagePipe<Buffer> + Send + 'static,
	{
	fn run_bridge_and_client(
	&self,
	dispatcher: &mut impl DispatcherTrait,
	input: Buffer,
	run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
	force_show_panics: bool,
	) -> Buffer {
	let (mut server, mut client) = P::new();

	let join_handle = thread::spawn(move \|\| {
	let mut dispatch = \|b: Buffer\| -> Buffer {
	client.send(b);
	client.recv().expect("server died while client waiting for reply")
	};

	run_client(BridgeConfig {
	input,
	dispatch: (&mut dispatch).into(),
	force_show_panics,
	_marker: marker::PhantomData,
	})
	});

	while let Some(b) = server.recv() {
	server.send(dispatcher.dispatch(b));
	}

	join_handle.join().unwrap()
	}
	}

	/// A message pipe used for communicating between server and client threads.
	pub trait MessagePipe<T>: Sized {
	/// Create a new pair of endpoints for the message pipe.
	fn new() -> (Self, Self);

	/// Send a message to the other endpoint of this pipe.
	fn send(&mut self, value: T);

	/// Receive a message from the other endpoint of this pipe.
	///
	/// Returns `None` if the other end of the pipe has been destroyed, and no
	/// message was received.
	fn recv(&mut self) -> Option<T>;
	}

	fn run_server<
	S: Server,
	I: Encode<HandleStore<MarkedTypes<S>>>,
	O: for<'a, 's> DecodeMut<'a, 's, HandleStore<MarkedTypes<S>>>,
	>(
	strategy: &impl ExecutionStrategy,
	handle_counters: &'static client::HandleCounters,
	server: S,
	input: I,
	run_client: extern "C" fn(BridgeConfig<'_>) -> Buffer,
	force_show_panics: bool,
	) -> Result<O, PanicMessage> {
	let mut dispatcher =
	Dispatcher { handle_store: HandleStore::new(handle_counters), server: MarkedTypes(server) };

	let globals = dispatcher.server.globals();

	let mut buf = Buffer::new();
	(globals, input).encode(&mut buf, &mut dispatcher.handle_store);

	buf = strategy.run_bridge_and_client(&mut dispatcher, buf, run_client, force_show_panics);

	Result::decode(&mut &buf[..], &mut dispatcher.handle_store)
	}

	impl client::Client<crate::TokenStream, crate::TokenStream> {
	pub fn run<S>(
	&self,
	strategy: &impl ExecutionStrategy,
	server: S,
	input: S::TokenStream,
	force_show_panics: bool,
	) -> Result<S::TokenStream, PanicMessage>
	where
	S: Server,
	S::TokenStream: Default,
	{
	let client::Client { get_handle_counters, run, _marker } = *self;
	run_server(
	strategy,
	get_handle_counters(),
	server,
	<MarkedTypes<S> as Types>::TokenStream::mark(input),
	run,
	force_show_panics,
	)
	.map(\|s\| <Option<<MarkedTypes<S> as Types>::TokenStream>>::unmark(s).unwrap_or_default())
	}
	}

	impl client::Client<(crate::TokenStream, crate::TokenStream), crate::TokenStream> {
	pub fn run<S>(
	&self,
	strategy: &impl ExecutionStrategy,
	server: S,
	input: S::TokenStream,
	input2: S::TokenStream,
	force_show_panics: bool,
	) -> Result<S::TokenStream, PanicMessage>
	where
	S: Server,
	S::TokenStream: Default,
	{
	let client::Client { get_handle_counters, run, _marker } = *self;
	run_server(
	strategy,
	get_handle_counters(),
	server,
	(
	<MarkedTypes<S> as Types>::TokenStream::mark(input),
	<MarkedTypes<S> as Types>::TokenStream::mark(input2),
	),
	run,
	force_show_panics,
	)
	.map(\|s\| <Option<<MarkedTypes<S> as Types>::TokenStream>>::unmark(s).unwrap_or_default())
	}
	}