third_party/rust_crates/vendor/fuchsia-zircon/src/lib.rs - fuchsia - Git at Google

 // Copyright 2016 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 //! Type-safe bindings for Zircon kernel
 //! [syscalls](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls.md).

 #![deny(warnings)]

 #[macro_use]
 extern crate bitflags;

 pub extern crate fuchsia_zircon_sys as sys;

 #[deprecated(note="use fuchsia_zircon::sys::ZX_CPRNG_DRAW_MAX_LEN instead")]
 #[doc(hidden)]
 pub use sys::ZX_CPRNG_DRAW_MAX_LEN;

 // Implements the HandleBased traits for a Handle newtype struct
 macro_rules! impl_handle_based {
     ($type_name:path) => {
         impl AsHandleRef for $type_name {
             fn as_handle_ref(&self) -> HandleRef {
                 self.0.as_handle_ref()
             }
         }

         impl From<Handle> for $type_name {
             fn from(handle: Handle) -> Self {
                 $type_name(handle)
             }
         }

         impl From<$type_name> for Handle {
             fn from(x: $type_name) -> Handle {
                 x.0
             }
         }

         impl HandleBased for $type_name {}
     }
 }

 // Creates associated constants of TypeName of the form
 // `pub const NAME: TypeName = TypeName(value);`
 macro_rules! assoc_consts {
     ($typename:ident, [$($name:ident = $num:expr;)*]) => {
         #[allow(non_upper_case_globals)]
         impl $typename {
             $(
                 pub const $name: $typename = $typename($num);
             )*
         }
     }
 }

 mod channel;
 mod cprng;
 mod event;
 mod eventpair;
 mod fifo;
 mod handle;
 mod job;
 mod port;
 mod process;
 mod rights;
 mod socket;
 mod signals;
 mod status;
 mod time;
 mod thread;
 mod vmar;
 mod vmo;

 pub use channel::*;
 pub use cprng::*;
 pub use event::*;
 pub use eventpair::*;
 pub use fifo::*;
 pub use handle::*;
 pub use job::*;
 pub use port::*;
 pub use process::*;
 pub use rights::*;
 pub use socket::*;
 pub use signals::*;
 pub use status::*;
 pub use thread::*;
 pub use time::*;
 pub use vmar::*;
 pub use vmo::*;

 /// Prelude containing common utility traits.
 /// Designed for use like `use fuchsia_zircon::prelude::*;`
 pub mod prelude {
     pub use {
         AsHandleRef,
         Cookied,
         DurationNum,
         HandleBased,
         Peered,
     };
 }

 /// Convenience re-export of `Status::ok`.
 pub fn ok(raw: sys::zx_status_t) -> Result<(), Status> {
     Status::ok(raw)
 }

 /// A "wait item" containing a handle reference and information about what signals
 /// to wait on, and, on return from `object_wait_many`, which are pending.
 #[repr(C)]
 #[derive(Debug)]
 pub struct WaitItem<'a> {
     /// The handle to wait on.
     pub handle: HandleRef<'a>,
     /// A set of signals to wait for.
     pub waitfor: Signals,
     /// The set of signals pending, on return of `object_wait_many`.
     pub pending: Signals,
 }

 /// An identifier to select a particular clock. See
 /// [zx_time_get](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls/time_get.md)
 /// for more information about the possible values.
 #[repr(u32)]
 #[derive(Debug, Copy, Clone, Eq, PartialEq)]
 pub enum ClockId {
     /// The number of nanoseconds since the system was powered on. Corresponds to
     /// `ZX_CLOCK_MONOTONIC`.
     Monotonic = 0,
     /// The number of wall clock nanoseconds since the Unix epoch (midnight on January 1 1970) in
     /// UTC. Corresponds to ZX_CLOCK_UTC.
     UTC = 1,
     /// The number of nanoseconds the current thread has been running for. Corresponds to
     /// ZX_CLOCK_THREAD.
     Thread = 2,
 }

 /// Wait on multiple handles.
 /// The success return value is a bool indicating whether one or more of the
 /// provided handle references was closed during the wait.
 ///
 /// Wraps the
 /// [zx_object_wait_many](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls/object_wait_many.md)
 /// syscall.
 pub fn object_wait_many(items: &mut [WaitItem], deadline: Time) -> Result<bool, Status>
 {
     let len = try!(usize_into_u32(items.len()).map_err(|_| Status::OUT_OF_RANGE));
     let items_ptr = items.as_mut_ptr() as *mut sys::zx_wait_item_t;
     let status = unsafe { sys::zx_object_wait_many( items_ptr, len, deadline.nanos()) };
     if status == sys::ZX_ERR_CANCELED {
         return Ok(true)
     }
     ok(status).map(|()| false)
 }

 #[cfg(test)]
 mod tests {
     use super::*;
     #[allow(unused_imports)]
     use super::prelude::*;

     #[test]
     fn monotonic_time_increases() {
         let time1 = Time::get(ClockId::Monotonic);
         1_000.nanos().sleep();
         let time2 = Time::get(ClockId::Monotonic);
         assert!(time2 > time1);
     }

     #[test]
     fn utc_time_increases() {
         let time1 = Time::get(ClockId::UTC);
         1_000.nanos().sleep();
         let time2 = Time::get(ClockId::UTC);
         assert!(time2 > time1);
     }

     #[test]
     fn thread_time_increases() {
         let time1 = Time::get(ClockId::Thread);
         1_000.nanos().sleep();
         let time2 = Time::get(ClockId::Thread);
         assert!(time2 > time1);
     }

     #[test]
     fn ticks_increases() {
         let ticks1 = ticks_get();
         1_000.nanos().sleep();
         let ticks2 = ticks_get();
         assert!(ticks2 > ticks1);
     }

     #[test]
     fn tick_length() {
         let sleep_time = 1.milli();
         let ticks1 = ticks_get();
         sleep_time.sleep();
         let ticks2 = ticks_get();

         // The number of ticks should have increased by at least 1 ms worth
         let sleep_ticks = sleep_time.millis() * ticks_per_second() / 1000;
         assert!(ticks2 >= (ticks1 + sleep_ticks));
     }

     #[test]
     fn into_raw() {
         let vmo = Vmo::create(1).unwrap();
         let h = vmo.into_raw();
         let vmo2 = Vmo::from(unsafe { Handle::from_raw(h) });
         assert!(vmo2.write(b"1", 0).is_ok());
     }

     #[test]
     fn sleep() {
         let sleep_ns = 1.millis();
         let time1 = Time::get(ClockId::Monotonic);
         sleep_ns.sleep();
         let time2 = Time::get(ClockId::Monotonic);
         assert!(time2 > time1 + sleep_ns);
     }

     /// Test duplication by means of a VMO
     #[test]
     fn duplicate() {
         let hello_length: usize = 5;

         // Create a VMO and write some data to it.
         let vmo = Vmo::create(hello_length as u64).unwrap();
         assert!(vmo.write(b"hello", 0).is_ok());

         // Replace, reducing rights to read.
         let readonly_vmo = vmo.duplicate_handle(Rights::READ).unwrap();
         // Make sure we can read but not write.
         let mut read_vec = vec![0; hello_length];
         assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
         assert_eq!(read_vec, b"hello");
         assert_eq!(readonly_vmo.write(b"", 0), Err(Status::ACCESS_DENIED));

         // Write new data to the original handle, and read it from the new handle
         assert!(vmo.write(b"bye", 0).is_ok());
         assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
         assert_eq!(read_vec, b"byelo");
     }

     // Test replace by means of a VMO
     #[test]
     fn replace() {
         let hello_length: usize = 5;

         // Create a VMO and write some data to it.
         let vmo = Vmo::create(hello_length as u64).unwrap();
         assert!(vmo.write(b"hello", 0).is_ok());

         // Replace, reducing rights to read.
         let readonly_vmo = vmo.replace_handle(Rights::READ).unwrap();
         // Make sure we can read but not write.
         let mut read_vec = vec![0; hello_length];
         assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
         assert_eq!(read_vec, b"hello");
         assert_eq!(readonly_vmo.write(b"", 0), Err(Status::ACCESS_DENIED));
     }

     #[test]
     fn wait_and_signal() {
         let event = Event::create().unwrap();
         let ten_ms = 10.millis();

         // Waiting on it without setting any signal should time out.
         assert_eq!(event.wait_handle(
             Signals::USER_0, ten_ms.after_now()), Err(Status::TIMED_OUT));

         // If we set a signal, we should be able to wait for it.
         assert!(event.signal_handle(Signals::NONE, Signals::USER_0).is_ok());
         assert_eq!(event.wait_handle(Signals::USER_0, ten_ms.after_now()).unwrap(),
             Signals::USER_0);

         // Should still work, signals aren't automatically cleared.
         assert_eq!(event.wait_handle(Signals::USER_0, ten_ms.after_now()).unwrap(),
             Signals::USER_0);

         // Now clear it, and waiting should time out again.
         assert!(event.signal_handle(Signals::USER_0, Signals::NONE).is_ok());
         assert_eq!(event.wait_handle(
             Signals::USER_0, ten_ms.after_now()), Err(Status::TIMED_OUT));
     }

     #[test]
     fn wait_many_and_signal() {
         let ten_ms = 10.millis();
         let e1 = Event::create().unwrap();
         let e2 = Event::create().unwrap();

         // Waiting on them now should time out.
         let mut items = vec![
           WaitItem { handle: e1.as_handle_ref(), waitfor: Signals::USER_0, pending: Signals::NONE },
           WaitItem { handle: e2.as_handle_ref(), waitfor: Signals::USER_1, pending: Signals::NONE },
         ];
         assert_eq!(object_wait_many(&mut items, ten_ms.after_now()), Err(Status::TIMED_OUT));
         assert_eq!(items[0].pending, Signals::NONE);
         assert_eq!(items[1].pending, Signals::NONE);

         // Signal one object and it should return success.
         assert!(e1.signal_handle(Signals::NONE, Signals::USER_0).is_ok());
         assert!(object_wait_many(&mut items, ten_ms.after_now()).is_ok());
         assert_eq!(items[0].pending, Signals::USER_0);
         assert_eq!(items[1].pending, Signals::NONE);

         // Signal the other and it should return both.
         assert!(e2.signal_handle(Signals::NONE, Signals::USER_1).is_ok());
         assert!(object_wait_many(&mut items, ten_ms.after_now()).is_ok());
         assert_eq!(items[0].pending, Signals::USER_0);
         assert_eq!(items[1].pending, Signals::USER_1);

         // Clear signals on both; now it should time out again.
         assert!(e1.signal_handle(Signals::USER_0, Signals::NONE).is_ok());
         assert!(e2.signal_handle(Signals::USER_1, Signals::NONE).is_ok());
         assert_eq!(object_wait_many(&mut items, ten_ms.after_now()), Err(Status::TIMED_OUT));
         assert_eq!(items[0].pending, Signals::NONE);
         assert_eq!(items[1].pending, Signals::NONE);
     }

     #[test]
     fn cookies() {
         let event = Event::create().unwrap();
         let scope = Event::create().unwrap();

         // Getting a cookie when none has been set should fail.
         assert_eq!(event.get_cookie(&scope.as_handle_ref()), Err(Status::ACCESS_DENIED));

         // Set a cookie.
         assert_eq!(event.set_cookie(&scope.as_handle_ref(), 42), Ok(()));

         // Should get it back....
         assert_eq!(event.get_cookie(&scope.as_handle_ref()), Ok(42));

         // but not with the wrong scope!
         assert_eq!(event.get_cookie(&event.as_handle_ref()), Err(Status::ACCESS_DENIED));

         // Can change it, with the same scope...
         assert_eq!(event.set_cookie(&scope.as_handle_ref(), 123), Ok(()));

         // but not with a different scope.
         assert_eq!(event.set_cookie(&event.as_handle_ref(), 123), Err(Status::ACCESS_DENIED));
     }
 }

 pub fn usize_into_u32(n: usize) -> Result<u32, ()> {
     if n > ::std::u32::MAX as usize || n < ::std::u32::MIN as usize {
         return Err(())
     }
     Ok(n as u32)
 }

 pub fn size_to_u32_sat(n: usize) -> u32 {
     if n > ::std::u32::MAX as usize {
         return ::std::u32::MAX;
     }
     if n < ::std::u32::MIN as usize {
         return ::std::u32::MIN;
     }
     n as u32
 }
	// Copyright 2016 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	//! Type-safe bindings for Zircon kernel
	//! [syscalls](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls.md).

	#![deny(warnings)]

	#[macro_use]
	extern crate bitflags;

	pub extern crate fuchsia_zircon_sys as sys;

	#[deprecated(note="use fuchsia_zircon::sys::ZX_CPRNG_DRAW_MAX_LEN instead")]
	#[doc(hidden)]
	pub use sys::ZX_CPRNG_DRAW_MAX_LEN;

	// Implements the HandleBased traits for a Handle newtype struct
	macro_rules! impl_handle_based {
	($type_name:path) => {
	impl AsHandleRef for $type_name {
	fn as_handle_ref(&self) -> HandleRef {
	self.0.as_handle_ref()
	}
	}

	impl From<Handle> for $type_name {
	fn from(handle: Handle) -> Self {
	$type_name(handle)
	}
	}

	impl From<$type_name> for Handle {
	fn from(x: $type_name) -> Handle {
	x.0
	}
	}

	impl HandleBased for $type_name {}
	}
	}

	// Creates associated constants of TypeName of the form
	// `pub const NAME: TypeName = TypeName(value);`
	macro_rules! assoc_consts {
	($typename:ident, [$($name:ident = $num:expr;)*]) => {
	#[allow(non_upper_case_globals)]
	impl $typename {
	$(
	pub const $name: $typename = $typename($num);
	)*
	}
	}
	}

	mod channel;
	mod cprng;
	mod event;
	mod eventpair;
	mod fifo;
	mod handle;
	mod job;
	mod port;
	mod process;
	mod rights;
	mod socket;
	mod signals;
	mod status;
	mod time;
	mod thread;
	mod vmar;
	mod vmo;

	pub use channel::*;
	pub use cprng::*;
	pub use event::*;
	pub use eventpair::*;
	pub use fifo::*;
	pub use handle::*;
	pub use job::*;
	pub use port::*;
	pub use process::*;
	pub use rights::*;
	pub use socket::*;
	pub use signals::*;
	pub use status::*;
	pub use thread::*;
	pub use time::*;
	pub use vmar::*;
	pub use vmo::*;

	/// Prelude containing common utility traits.
	/// Designed for use like `use fuchsia_zircon::prelude::*;`
	pub mod prelude {
	pub use {
	AsHandleRef,
	Cookied,
	DurationNum,
	HandleBased,
	Peered,
	};
	}

	/// Convenience re-export of `Status::ok`.
	pub fn ok(raw: sys::zx_status_t) -> Result<(), Status> {
	Status::ok(raw)
	}

	/// A "wait item" containing a handle reference and information about what signals
	/// to wait on, and, on return from `object_wait_many`, which are pending.
	#[repr(C)]
	#[derive(Debug)]
	pub struct WaitItem<'a> {
	/// The handle to wait on.
	pub handle: HandleRef<'a>,
	/// A set of signals to wait for.
	pub waitfor: Signals,
	/// The set of signals pending, on return of `object_wait_many`.
	pub pending: Signals,
	}

	/// An identifier to select a particular clock. See
	/// [zx_time_get](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls/time_get.md)
	/// for more information about the possible values.
	#[repr(u32)]
	#[derive(Debug, Copy, Clone, Eq, PartialEq)]
	pub enum ClockId {
	/// The number of nanoseconds since the system was powered on. Corresponds to
	/// `ZX_CLOCK_MONOTONIC`.
	Monotonic = 0,
	/// The number of wall clock nanoseconds since the Unix epoch (midnight on January 1 1970) in
	/// UTC. Corresponds to ZX_CLOCK_UTC.
	UTC = 1,
	/// The number of nanoseconds the current thread has been running for. Corresponds to
	/// ZX_CLOCK_THREAD.
	Thread = 2,
	}

	/// Wait on multiple handles.
	/// The success return value is a bool indicating whether one or more of the
	/// provided handle references was closed during the wait.
	///
	/// Wraps the
	/// [zx_object_wait_many](https://fuchsia.googlesource.com/zircon/+/master/docs/syscalls/object_wait_many.md)
	/// syscall.
	pub fn object_wait_many(items: &mut [WaitItem], deadline: Time) -> Result<bool, Status>
	{
	let len = try!(usize_into_u32(items.len()).map_err(\|_\| Status::OUT_OF_RANGE));
	let items_ptr = items.as_mut_ptr() as *mut sys::zx_wait_item_t;
	let status = unsafe { sys::zx_object_wait_many( items_ptr, len, deadline.nanos()) };
	if status == sys::ZX_ERR_CANCELED {
	return Ok(true)
	}
	ok(status).map(\|()\| false)
	}

	#[cfg(test)]
	mod tests {
	use super::*;
	#[allow(unused_imports)]
	use super::prelude::*;

	#[test]
	fn monotonic_time_increases() {
	let time1 = Time::get(ClockId::Monotonic);
	1_000.nanos().sleep();
	let time2 = Time::get(ClockId::Monotonic);
	assert!(time2 > time1);
	}

	#[test]
	fn utc_time_increases() {
	let time1 = Time::get(ClockId::UTC);
	1_000.nanos().sleep();
	let time2 = Time::get(ClockId::UTC);
	assert!(time2 > time1);
	}

	#[test]
	fn thread_time_increases() {
	let time1 = Time::get(ClockId::Thread);
	1_000.nanos().sleep();
	let time2 = Time::get(ClockId::Thread);
	assert!(time2 > time1);
	}

	#[test]
	fn ticks_increases() {
	let ticks1 = ticks_get();
	1_000.nanos().sleep();
	let ticks2 = ticks_get();
	assert!(ticks2 > ticks1);
	}

	#[test]
	fn tick_length() {
	let sleep_time = 1.milli();
	let ticks1 = ticks_get();
	sleep_time.sleep();
	let ticks2 = ticks_get();

	// The number of ticks should have increased by at least 1 ms worth
	let sleep_ticks = sleep_time.millis() * ticks_per_second() / 1000;
	assert!(ticks2 >= (ticks1 + sleep_ticks));
	}

	#[test]
	fn into_raw() {
	let vmo = Vmo::create(1).unwrap();
	let h = vmo.into_raw();
	let vmo2 = Vmo::from(unsafe { Handle::from_raw(h) });
	assert!(vmo2.write(b"1", 0).is_ok());
	}

	#[test]
	fn sleep() {
	let sleep_ns = 1.millis();
	let time1 = Time::get(ClockId::Monotonic);
	sleep_ns.sleep();
	let time2 = Time::get(ClockId::Monotonic);
	assert!(time2 > time1 + sleep_ns);
	}

	/// Test duplication by means of a VMO
	#[test]
	fn duplicate() {
	let hello_length: usize = 5;

	// Create a VMO and write some data to it.
	let vmo = Vmo::create(hello_length as u64).unwrap();
	assert!(vmo.write(b"hello", 0).is_ok());

	// Replace, reducing rights to read.
	let readonly_vmo = vmo.duplicate_handle(Rights::READ).unwrap();
	// Make sure we can read but not write.
	let mut read_vec = vec![0; hello_length];
	assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
	assert_eq!(read_vec, b"hello");
	assert_eq!(readonly_vmo.write(b"", 0), Err(Status::ACCESS_DENIED));

	// Write new data to the original handle, and read it from the new handle
	assert!(vmo.write(b"bye", 0).is_ok());
	assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
	assert_eq!(read_vec, b"byelo");
	}

	// Test replace by means of a VMO
	#[test]
	fn replace() {
	let hello_length: usize = 5;

	// Create a VMO and write some data to it.
	let vmo = Vmo::create(hello_length as u64).unwrap();
	assert!(vmo.write(b"hello", 0).is_ok());

	// Replace, reducing rights to read.
	let readonly_vmo = vmo.replace_handle(Rights::READ).unwrap();
	// Make sure we can read but not write.
	let mut read_vec = vec![0; hello_length];
	assert_eq!(readonly_vmo.read(&mut read_vec, 0).unwrap(), hello_length);
	assert_eq!(read_vec, b"hello");
	assert_eq!(readonly_vmo.write(b"", 0), Err(Status::ACCESS_DENIED));
	}

	#[test]
	fn wait_and_signal() {
	let event = Event::create().unwrap();
	let ten_ms = 10.millis();

	// Waiting on it without setting any signal should time out.
	assert_eq!(event.wait_handle(
	Signals::USER_0, ten_ms.after_now()), Err(Status::TIMED_OUT));

	// If we set a signal, we should be able to wait for it.
	assert!(event.signal_handle(Signals::NONE, Signals::USER_0).is_ok());
	assert_eq!(event.wait_handle(Signals::USER_0, ten_ms.after_now()).unwrap(),
	Signals::USER_0);

	// Should still work, signals aren't automatically cleared.
	assert_eq!(event.wait_handle(Signals::USER_0, ten_ms.after_now()).unwrap(),
	Signals::USER_0);

	// Now clear it, and waiting should time out again.
	assert!(event.signal_handle(Signals::USER_0, Signals::NONE).is_ok());
	assert_eq!(event.wait_handle(
	Signals::USER_0, ten_ms.after_now()), Err(Status::TIMED_OUT));
	}

	#[test]
	fn wait_many_and_signal() {
	let ten_ms = 10.millis();
	let e1 = Event::create().unwrap();
	let e2 = Event::create().unwrap();

	// Waiting on them now should time out.
	let mut items = vec![
	WaitItem { handle: e1.as_handle_ref(), waitfor: Signals::USER_0, pending: Signals::NONE },
	WaitItem { handle: e2.as_handle_ref(), waitfor: Signals::USER_1, pending: Signals::NONE },
	];
	assert_eq!(object_wait_many(&mut items, ten_ms.after_now()), Err(Status::TIMED_OUT));
	assert_eq!(items[0].pending, Signals::NONE);
	assert_eq!(items[1].pending, Signals::NONE);

	// Signal one object and it should return success.
	assert!(e1.signal_handle(Signals::NONE, Signals::USER_0).is_ok());
	assert!(object_wait_many(&mut items, ten_ms.after_now()).is_ok());
	assert_eq!(items[0].pending, Signals::USER_0);
	assert_eq!(items[1].pending, Signals::NONE);

	// Signal the other and it should return both.
	assert!(e2.signal_handle(Signals::NONE, Signals::USER_1).is_ok());
	assert!(object_wait_many(&mut items, ten_ms.after_now()).is_ok());
	assert_eq!(items[0].pending, Signals::USER_0);
	assert_eq!(items[1].pending, Signals::USER_1);

	// Clear signals on both; now it should time out again.
	assert!(e1.signal_handle(Signals::USER_0, Signals::NONE).is_ok());
	assert!(e2.signal_handle(Signals::USER_1, Signals::NONE).is_ok());
	assert_eq!(object_wait_many(&mut items, ten_ms.after_now()), Err(Status::TIMED_OUT));
	assert_eq!(items[0].pending, Signals::NONE);
	assert_eq!(items[1].pending, Signals::NONE);
	}

	#[test]
	fn cookies() {
	let event = Event::create().unwrap();
	let scope = Event::create().unwrap();

	// Getting a cookie when none has been set should fail.
	assert_eq!(event.get_cookie(&scope.as_handle_ref()), Err(Status::ACCESS_DENIED));

	// Set a cookie.
	assert_eq!(event.set_cookie(&scope.as_handle_ref(), 42), Ok(()));

	// Should get it back....
	assert_eq!(event.get_cookie(&scope.as_handle_ref()), Ok(42));

	// but not with the wrong scope!
	assert_eq!(event.get_cookie(&event.as_handle_ref()), Err(Status::ACCESS_DENIED));

	// Can change it, with the same scope...
	assert_eq!(event.set_cookie(&scope.as_handle_ref(), 123), Ok(()));

	// but not with a different scope.
	assert_eq!(event.set_cookie(&event.as_handle_ref(), 123), Err(Status::ACCESS_DENIED));
	}
	}

	pub fn usize_into_u32(n: usize) -> Result<u32, ()> {
	if n > ::std::u32::MAX as usize \|\| n < ::std::u32::MIN as usize {
	return Err(())
	}
	Ok(n as u32)
	}

	pub fn size_to_u32_sat(n: usize) -> u32 {
	if n > ::std::u32::MAX as usize {
	return ::std::u32::MAX;
	}
	if n < ::std::u32::MIN as usize {
	return ::std::u32::MIN;
	}
	n as u32
	}