protobuf/rust/proxied.rs

// Protocol Buffers - Google's data interchange format
// Copyright 2023 Google Inc.  All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
//     * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
//     * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

// copybara:strip_begin
// See http://go/rust-proxy-reference-types for design discussion.
// copybara:strip_end

//! Operating on borrowed data owned by a message is a central concept in
//! Protobuf (and Rust in general). The way this is normally accomplished in
//! Rust is to pass around references and operate on those. Unfortunately,
//! references come with two major drawbacks:
//!
//! * We must store the value somewhere in the memory to create a reference to
//!   it. The value must be readable by a single load. However for Protobuf
//!   fields it happens that the actual memory representation of a value differs
//!   from what users expect and it is an implementation detail that can change
//!   as more optimizations are implemented. For example, rarely accessed
//!   `int64` fields can be represented in a packed format with 32 bits for the
//!   value in the common case. Or, a single logical value can be spread across
//!   multiple memory locations. For example, presence information for all the
//!   fields in a protobuf message is centralized in a bitset.
//! * We cannot store extra data on the reference that might be necessary for
//!   correctly manipulating it (and custom-metadata DSTs do not exist yet in
//!   Rust). Concretely, messages, string, bytes, and repeated fields in UPB
//!   need to carry around an arena parameter separate from the data pointer to
//!   enable mutation (for example adding an element to a repeated field) or
//!   potentially to enable optimizations (for example referencing a string
//!   value using a Cord-like type instead of copying it if the source and
//!   target messages are on the same arena already). Mutable references to
//!   messages have one additional drawback: Rust allows users to
//!   indiscriminately run a bytewise swap() on mutable references, which could
//!   result in pointers to the wrong arena winding up on a message. For
//!   example, imagine swapping a submessage across two root messages allocated
//!   on distinct arenas A and B; after the swap, the message allocated in A may
//!   contain pointers from B by way of the submessage, because the swap does
//!   not know to fix up those pointers as needed. The C++ API uses
//!   message-owned arenas, and this ends up resembling self-referential types,
//!   which need `Pin` in order to be sound. However, `Pin` has much stronger
//!   guarantees than we need to uphold.
//!
//! These drawbacks put the "idiomatic Rust" goal in conflict with the
//! "performance", "evolvability", and "safety" goals. Given the project design
//! priorities we decided to not use plain Rust references. Instead, we
//! implemented the concept of "proxy" types. Proxy types are a reference-like
//! indirection between the user and the internal memory representation.

use std::fmt::Debug;
use std::marker::{Send, Sync};

/// Represents a type that can be accessed through a reference-like proxy.
///
/// An instance of a `Proxied` can be accessed
/// immutably via `Proxied::View` and mutably via `Proxied::Mut`.
///
/// All Protobuf field types implement `Proxied`.
pub trait Proxied {
    /// Represents a shared accessor of a `T` through an `&'a T`-like proxy
    /// type.
    ///
    /// Most code should use the type alias [`View`].
    type View<'a>: ViewFor<'a, Self> + Copy + Send + Sync + Unpin + Sized + Debug
    where
        Self: 'a;

    /// Represents a unique mutator of a `T` through an `&'a mut T`-like proxy
    /// type.
    ///
    /// Most code should use the type alias [`Mut`].
    type Mut<'a>: MutFor<'a, Self> + Sync + Sized + Debug
    where
        Self: 'a;
}

/// Represents a shared accessor of a `T` through an `&'a T`-like proxy type.
///
/// This is more concise than fully spelling the associated type.
#[allow(dead_code)]
pub type View<'a, T> = <T as Proxied>::View<'a>;

/// Represents a unique mutator of a `T` through an `&'a mut T`-like proxy type.
///
/// This is more concise than fully spelling the associated type.
#[allow(dead_code)]
pub type Mut<'a, T> = <T as Proxied>::Mut<'a>;

/// Declares conversion operations common to all views.
///
/// This trait is intentionally made non-object-safe to prevent a potential
/// future incompatible change.
pub trait ViewFor<'a, T: 'a + Proxied + ?Sized>: 'a + Sized {
    /// Converts a borrow into a `View` with the lifetime of that borrow.
    ///
    /// In non-generic code we don't need to use `as_view` because the proxy
    /// types are covariant over `'a`. However, generic code conservatively
    /// treats `'a` as [invariant], therefore we need to call
    /// `as_view` to explicitly perform the operation that in concrete code
    /// coercion would perform implicitly.
    ///
    /// For example, the call to `.as_view()` in the following snippet
    /// wouldn't be necessary in concrete code:
    /// ```
    /// fn reborrow<'a, 'b, T>(x: &'b View<'a, T>) -> View<'b, T>
    /// where 'a: 'b, T: Proxied
    /// {
    ///   x.as_view()
    /// }
    /// ```
    ///
    /// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance
    fn as_view(&self) -> View<'_, T>;

    /// Converts into a `View` with a potentially shorter lifetime.
    ///
    /// In non-generic code we don't need to use `into_view` because the proxy
    /// types are covariant over `'a`. However, generic code conservatively
    /// treats `'a` as [invariant], therefore we need to call
    /// `into_view` to explicitly perform the operation that in concrete
    /// code coercion would perform implicitly.
    ///
    /// ```
    /// fn reborrow_generic_view_into_view<'a, 'b, T>(
    ///     x: View<'a, T>,
    ///     y: View<'b, T>,
    /// ) -> [View<'b, T>; 2]
    /// where
    ///     T: Proxied,
    ///     'a: 'b,
    /// {
    ///     // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
    ///     // lifetime parameter is (conservatively) invariant.
    ///     // `[x.as_view(), y]` fails because that borrow cannot outlive `'b`.
    ///     [x.into_view(), y]
    /// }
    /// ```
    ///
    /// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance
    fn into_view<'shorter>(self) -> View<'shorter, T>
    where
        'a: 'shorter;
}

/// Declares operations common to all mutators.
///
/// This trait is intentionally made non-object-safe to prevent a potential
/// future incompatible change.
pub trait MutFor<'a, T: 'a + Proxied + ?Sized>: ViewFor<'a, T> {
    /// Converts a borrow into a `Mut` with the lifetime of that borrow.
    ///
    /// This function enables calling multiple methods consuming `self`, for
    /// example:
    ///
    /// ```ignore
    ///   let mut sub: Mut<SubMsg> = msg.submsg_mut().or_default();
    ///   sub.as_mut().field_x_mut().set(10);  // field_x_mut is fn(self)
    ///   sub.field_y_mut().set(20);  // `sub` is now consumed
    /// ```
    ///
    /// `as_mut` is also useful in generic code to explicitly perform the
    /// operation that in concrete code coercion would perform implicitly.
    fn as_mut(&mut self) -> Mut<'_, T>;

    /// Converts into a `Mut` with a potentially shorter lifetime.
    ///
    /// In non-generic code we don't need to use `into_mut` because the proxy
    /// types are covariant over `'a`. However, generic code conservatively
    /// treats `'a` as [invariant], therefore we need to call
    /// `into_mut` to explicitly perform the operation that in concrete code
    /// coercion would perform implicitly.
    ///
    /// ```
    /// fn reborrow_generic_mut_into_mut<'a, 'b, T>(x: Mut<'a, T>, y: Mut<'b, T>) -> [Mut<'b, T>; 2]
    /// where
    ///     T: Proxied,
    ///     'a: 'b,
    /// {
    ///     // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `Mut`
    ///     // lifetime parameter is (conservatively) invariant.
    ///     // `[x.as_mut(), y]` fails because that borrow cannot outlive `'b`.
    ///     [x.into_mut(), y]
    /// }
    /// ```
    ///
    /// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance
    fn into_mut<'shorter>(self) -> Mut<'shorter, T>
    where
        'a: 'shorter;
}

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

    #[derive(Debug, PartialEq)]
    struct MyProxied {
        val: String,
    }

    impl MyProxied {
        fn as_view(&self) -> View<'_, Self> {
            MyProxiedView { my_proxied_ref: self }
        }

        fn as_mut(&mut self) -> Mut<'_, Self> {
            MyProxiedMut { my_proxied_ref: self }
        }
    }

    impl Proxied for MyProxied {
        type View<'a> = MyProxiedView<'a>;
        type Mut<'a> = MyProxiedMut<'a>;
    }

    #[derive(Debug, Clone, Copy)]
    struct MyProxiedView<'a> {
        my_proxied_ref: &'a MyProxied,
    }

    impl MyProxiedView<'_> {
        fn val(&self) -> &str {
            &self.my_proxied_ref.val
        }
    }

    impl<'a> ViewFor<'a, MyProxied> for MyProxiedView<'a> {
        fn as_view(&self) -> View<'a, MyProxied> {
            *self
        }

        fn into_view<'shorter>(self) -> View<'shorter, MyProxied>
        where
            'a: 'shorter,
        {
            self
        }
    }

    #[derive(Debug)]
    struct MyProxiedMut<'a> {
        my_proxied_ref: &'a mut MyProxied,
    }

    impl MyProxiedMut<'_> {
        fn set_val(&mut self, new_val: String) {
            self.my_proxied_ref.val = new_val;
        }
    }

    impl<'a> ViewFor<'a, MyProxied> for MyProxiedMut<'a> {
        fn as_view(&self) -> View<'_, MyProxied> {
            MyProxiedView { my_proxied_ref: self.my_proxied_ref }
        }
        fn into_view<'shorter>(self) -> View<'shorter, MyProxied>
        where
            'a: 'shorter,
        {
            MyProxiedView { my_proxied_ref: self.my_proxied_ref }
        }
    }

    impl<'a> MutFor<'a, MyProxied> for MyProxiedMut<'a> {
        fn as_mut(&mut self) -> Mut<'_, MyProxied> {
            MyProxiedMut { my_proxied_ref: self.my_proxied_ref }
        }

        fn into_mut<'shorter>(self) -> Mut<'shorter, MyProxied>
        where
            'a: 'shorter,
        {
            self
        }
    }

    #[test]
    fn test_as_view() {
        let my_proxied = MyProxied { val: "Hello World".to_string() };

        let my_view = my_proxied.as_view();

        assert_eq!(my_view.val(), my_proxied.val);
    }

    #[test]
    fn test_as_mut() {
        let mut my_proxied = MyProxied { val: "Hello World".to_string() };

        let mut my_mut = my_proxied.as_mut();
        my_mut.set_val("Hello indeed".to_string());

        let val_after_set = my_mut.as_view().val().to_string();
        assert_eq!(my_proxied.val, val_after_set);
        assert_eq!(my_proxied.val, "Hello indeed");
    }

    fn reborrow_mut_into_view<'a>(x: Mut<'a, MyProxied>) -> View<'a, MyProxied> {
        // x.as_view() fails to compile with:
        //   `ERROR: attempt to return function-local borrowed content`
        x.into_view() // OK: we return the same lifetime as we got in.
    }

    #[test]
    fn test_mut_into_view() {
        let mut my_proxied = MyProxied { val: "Hello World".to_string() };
        reborrow_mut_into_view(my_proxied.as_mut());
    }

    fn require_unified_lifetimes<'a>(_x: Mut<'a, MyProxied>, _y: View<'a, MyProxied>) {}

    #[test]
    fn test_require_unified_lifetimes() {
        let mut my_proxied = MyProxied { val: "Hello1".to_string() };
        let my_mut = my_proxied.as_mut();

        {
            let other_proxied = MyProxied { val: "Hello2".to_string() };
            let other_view = other_proxied.as_view();
            require_unified_lifetimes(my_mut, other_view);
        }
    }

    fn reborrow_generic_as_view<'a, 'b, T>(
        x: &'b mut Mut<'a, T>,
        y: &'b View<'a, T>,
    ) -> [View<'b, T>; 2]
    where
        T: Proxied,
        'a: 'b,
    {
        // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
        // lifetime parameter is (conservatively) invariant.
        [x.as_view(), y.as_view()]
    }

    #[test]
    fn test_reborrow_generic_as_view() {
        let mut my_proxied = MyProxied { val: "Hello1".to_string() };
        let mut my_mut = my_proxied.as_mut();
        let my_ref = &mut my_mut;

        {
            let other_proxied = MyProxied { val: "Hello2".to_string() };
            let other_view = other_proxied.as_view();
            reborrow_generic_as_view::<MyProxied>(my_ref, &other_view);
        }
    }

    fn reborrow_generic_view_into_view<'a, 'b, T>(
        x: View<'a, T>,
        y: View<'b, T>,
    ) -> [View<'b, T>; 2]
    where
        T: Proxied,
        'a: 'b,
    {
        // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
        // lifetime parameter is (conservatively) invariant.
        // `[x.as_view(), y]` fails because that borrow cannot outlive `'b`.
        [x.into_view(), y]
    }

    #[test]
    fn test_reborrow_generic_into_view() {
        let my_proxied = MyProxied { val: "Hello1".to_string() };
        let my_view = my_proxied.as_view();

        {
            let other_proxied = MyProxied { val: "Hello2".to_string() };
            let other_view = other_proxied.as_view();
            reborrow_generic_view_into_view::<MyProxied>(my_view, other_view);
        }
    }

    fn reborrow_generic_mut_into_view<'a, 'b, T>(x: Mut<'a, T>, y: View<'b, T>) -> [View<'b, T>; 2]
    where
        T: Proxied,
        'a: 'b,
    {
        [x.into_view(), y]
    }

    #[test]
    fn test_reborrow_generic_mut_into_view() {
        let mut my_proxied = MyProxied { val: "Hello1".to_string() };
        let my_mut = my_proxied.as_mut();

        {
            let other_proxied = MyProxied { val: "Hello2".to_string() };
            let other_view = other_proxied.as_view();
            reborrow_generic_mut_into_view::<MyProxied>(my_mut, other_view);
        }
    }

    fn reborrow_generic_mut_into_mut<'a, 'b, T>(x: Mut<'a, T>, y: Mut<'b, T>) -> [Mut<'b, T>; 2]
    where
        T: Proxied,
        'a: 'b,
    {
        // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `Mut`
        // lifetime parameter is (conservatively) invariant.
        // `[x.as_mut(), y]` fails because that borrow cannot outlive `'b`.
        [x.into_mut(), y]
    }

    #[test]
    fn test_reborrow_generic_mut_into_mut() {
        let mut my_proxied = MyProxied { val: "Hello1".to_string() };
        let my_mut = my_proxied.as_mut();

        {
            let mut other_proxied = MyProxied { val: "Hello2".to_string() };
            let other_mut = other_proxied.as_mut();
            // No need to reborrow, even though lifetime of &other_view is different
            // than the lifetiem of my_ref. Rust references are covariant over their
            // lifetime.
            reborrow_generic_mut_into_mut::<MyProxied>(my_mut, other_mut);
        }
    }
}
Implement Proxied for v0.6 PiperOrigin-RevId: 539600447 1 year ago			`// Protocol Buffers - Google's data interchange format`
			`// Copyright 2023 Google Inc. All rights reserved.`
			`// https://developers.google.com/protocol-buffers/`
			`//`
			`// Redistribution and use in source and binary forms, with or without`
			`// modification, are permitted provided that the following conditions are`
			`// met:`
			`//`
			`// * Redistributions of source code must retain the above copyright`
			`// notice, this list of conditions and the following disclaimer.`
			`// * Redistributions in binary form must reproduce the above`
			`// copyright notice, this list of conditions and the following disclaimer`
			`// in the documentation and/or other materials provided with the`
			`// distribution.`
			`// * Neither the name of Google Inc. nor the names of its`
			`// contributors may be used to endorse or promote products derived from`
			`// this software without specific prior written permission.`
			`//`
			`// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS`
			`// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT`
			`// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR`
			`// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT`
			`// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,`
			`// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT`
			`// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,`
			`// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY`
			`// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT`
			`// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE`
			`// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.`

			`// copybara:strip_begin`
			`// See http://go/rust-proxy-reference-types for design discussion.`
			`// copybara:strip_end`

			`//! Operating on borrowed data owned by a message is a central concept in`
			`//! Protobuf (and Rust in general). The way this is normally accomplished in`
			`//! Rust is to pass around references and operate on those. Unfortunately,`
			`//! references come with two major drawbacks:`
			`//!`
			`//! * We must store the value somewhere in the memory to create a reference to`
			`//! it. The value must be readable by a single load. However for Protobuf`
			`//! fields it happens that the actual memory representation of a value differs`
			`//! from what users expect and it is an implementation detail that can change`
			`//! as more optimizations are implemented. For example, rarely accessed`
			//! `int64` fields can be represented in a packed format with 32 bits for the
			`//! value in the common case. Or, a single logical value can be spread across`
			`//! multiple memory locations. For example, presence information for all the`
			`//! fields in a protobuf message is centralized in a bitset.`
			`//! * We cannot store extra data on the reference that might be necessary for`
			`//! correctly manipulating it (and custom-metadata DSTs do not exist yet in`
			`//! Rust). Concretely, messages, string, bytes, and repeated fields in UPB`
			`//! need to carry around an arena parameter separate from the data pointer to`
			`//! enable mutation (for example adding an element to a repeated field) or`
			`//! potentially to enable optimizations (for example referencing a string`
			`//! value using a Cord-like type instead of copying it if the source and`
			`//! target messages are on the same arena already). Mutable references to`
			`//! messages have one additional drawback: Rust allows users to`
			`//! indiscriminately run a bytewise swap() on mutable references, which could`
			`//! result in pointers to the wrong arena winding up on a message. For`
			`//! example, imagine swapping a submessage across two root messages allocated`
			`//! on distinct arenas A and B; after the swap, the message allocated in A may`
			`//! contain pointers from B by way of the submessage, because the swap does`
			`//! not know to fix up those pointers as needed. The C++ API uses`
			`//! message-owned arenas, and this ends up resembling self-referential types,`
			//! which need `Pin` in order to be sound. However, `Pin` has much stronger
			`//! guarantees than we need to uphold.`
			`//!`
			`//! These drawbacks put the "idiomatic Rust" goal in conflict with the`
			`//! "performance", "evolvability", and "safety" goals. Given the project design`
			`//! priorities we decided to not use plain Rust references. Instead, we`
			`//! implemented the concept of "proxy" types. Proxy types are a reference-like`
			`//! indirection between the user and the internal memory representation.`

			`use std::fmt::Debug;`
			`use std::marker::{Send, Sync};`

			`/// Represents a type that can be accessed through a reference-like proxy.`
			`///`
			/// An instance of a `Proxied` can be accessed
			/// immutably via `Proxied::View` and mutably via `Proxied::Mut`.
			`///`
			/// All Protobuf field types implement `Proxied`.
			`pub trait Proxied {`
			/// Represents a shared accessor of a `T` through an `&'a T`-like proxy
			`/// type.`
			`///`
			/// Most code should use the type alias [`View`].
			`type View<'a>: ViewFor<'a, Self> + Copy + Send + Sync + Unpin + Sized + Debug`
			`where`
			`Self: 'a;`

			/// Represents a unique mutator of a `T` through an `&'a mut T`-like proxy
			`/// type.`
			`///`
			/// Most code should use the type alias [`Mut`].
			`type Mut<'a>: MutFor<'a, Self> + Sync + Sized + Debug`
			`where`
			`Self: 'a;`
			`}`

			/// Represents a shared accessor of a `T` through an `&'a T`-like proxy type.
			`///`
			`/// This is more concise than fully spelling the associated type.`
			`#[allow(dead_code)]`
			`pub type View<'a, T> = <T as Proxied>::View<'a>;`

			/// Represents a unique mutator of a `T` through an `&'a mut T`-like proxy type.
			`///`
			`/// This is more concise than fully spelling the associated type.`
			`#[allow(dead_code)]`
			`pub type Mut<'a, T> = <T as Proxied>::Mut<'a>;`

			`/// Declares conversion operations common to all views.`
			`///`
			`/// This trait is intentionally made non-object-safe to prevent a potential`
			`/// future incompatible change.`
			`pub trait ViewFor<'a, T: 'a + Proxied + ?Sized>: 'a + Sized {`
			/// Converts a borrow into a `View` with the lifetime of that borrow.
			`///`
			/// In non-generic code we don't need to use `as_view` because the proxy
			/// types are covariant over `'a`. However, generic code conservatively
			/// treats `'a` as [invariant], therefore we need to call
			/// `as_view` to explicitly perform the operation that in concrete code
			`/// coercion would perform implicitly.`
			`///`
			/// For example, the call to `.as_view()` in the following snippet
			`/// wouldn't be necessary in concrete code:`
			/// ```
			`/// fn reborrow<'a, 'b, T>(x: &'b View<'a, T>) -> View<'b, T>`
			`/// where 'a: 'b, T: Proxied`
			`/// {`
			`/// x.as_view()`
			`/// }`
			/// ```
			`///`
			`/// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance`
			`fn as_view(&self) -> View<'_, T>;`

			/// Converts into a `View` with a potentially shorter lifetime.
			`///`
			/// In non-generic code we don't need to use `into_view` because the proxy
			/// types are covariant over `'a`. However, generic code conservatively
			/// treats `'a` as [invariant], therefore we need to call
			/// `into_view` to explicitly perform the operation that in concrete
			`/// code coercion would perform implicitly.`
			`///`
			/// ```
			`/// fn reborrow_generic_view_into_view<'a, 'b, T>(`
			`/// x: View<'a, T>,`
			`/// y: View<'b, T>,`
			`/// ) -> [View<'b, T>; 2]`
			`/// where`
			`/// T: Proxied,`
			`/// 'a: 'b,`
			`/// {`
			/// // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
			`/// // lifetime parameter is (conservatively) invariant.`
			/// // `[x.as_view(), y]` fails because that borrow cannot outlive `'b`.
			`/// [x.into_view(), y]`
			`/// }`
			/// ```
			`///`
			`/// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance`
			`fn into_view<'shorter>(self) -> View<'shorter, T>`
			`where`
			`'a: 'shorter;`
			`}`

			`/// Declares operations common to all mutators.`
			`///`
			`/// This trait is intentionally made non-object-safe to prevent a potential`
			`/// future incompatible change.`
			`pub trait MutFor<'a, T: 'a + Proxied + ?Sized>: ViewFor<'a, T> {`
			/// Converts a borrow into a `Mut` with the lifetime of that borrow.
			`///`
			/// This function enables calling multiple methods consuming `self`, for
			`/// example:`
			`///`
			/// ```ignore
			`/// let mut sub: Mut<SubMsg> = msg.submsg_mut().or_default();`
			`/// sub.as_mut().field_x_mut().set(10); // field_x_mut is fn(self)`
			/// sub.field_y_mut().set(20); // `sub` is now consumed
			/// ```
			`///`
			/// `as_mut` is also useful in generic code to explicitly perform the
			`/// operation that in concrete code coercion would perform implicitly.`
			`fn as_mut(&mut self) -> Mut<'_, T>;`

			/// Converts into a `Mut` with a potentially shorter lifetime.
			`///`
			/// In non-generic code we don't need to use `into_mut` because the proxy
			/// types are covariant over `'a`. However, generic code conservatively
			/// treats `'a` as [invariant], therefore we need to call
			/// `into_mut` to explicitly perform the operation that in concrete code
			`/// coercion would perform implicitly.`
			`///`
			/// ```
			`/// fn reborrow_generic_mut_into_mut<'a, 'b, T>(x: Mut<'a, T>, y: Mut<'b, T>) -> [Mut<'b, T>; 2]`
			`/// where`
			`/// T: Proxied,`
			`/// 'a: 'b,`
			`/// {`
			/// // `[x, y]` fails to compile because `'a` is not the same as `'b` and the `Mut`
			`/// // lifetime parameter is (conservatively) invariant.`
			/// // `[x.as_mut(), y]` fails because that borrow cannot outlive `'b`.
			`/// [x.into_mut(), y]`
			`/// }`
			/// ```
			`///`
			`/// [invariant]: https://doc.rust-lang.org/nomicon/subtyping.html#variance`
			`fn into_mut<'shorter>(self) -> Mut<'shorter, T>`
			`where`
			`'a: 'shorter;`
			`}`

			`#[cfg(test)]`
			`mod tests {`
			`use super::*;`

			`#[derive(Debug, PartialEq)]`
			`struct MyProxied {`
			`val: String,`
			`}`

			`impl MyProxied {`
			`fn as_view(&self) -> View<'_, Self> {`
			`MyProxiedView { my_proxied_ref: self }`
			`}`

			`fn as_mut(&mut self) -> Mut<'_, Self> {`
			`MyProxiedMut { my_proxied_ref: self }`
			`}`
			`}`

			`impl Proxied for MyProxied {`
			`type View<'a> = MyProxiedView<'a>;`
			`type Mut<'a> = MyProxiedMut<'a>;`
			`}`

			`#[derive(Debug, Clone, Copy)]`
			`struct MyProxiedView<'a> {`
			`my_proxied_ref: &'a MyProxied,`
			`}`

			`impl MyProxiedView<'_> {`
			`fn val(&self) -> &str {`
			`&self.my_proxied_ref.val`
			`}`
			`}`

			`impl<'a> ViewFor<'a, MyProxied> for MyProxiedView<'a> {`
			`fn as_view(&self) -> View<'a, MyProxied> {`
			`*self`
			`}`

			`fn into_view<'shorter>(self) -> View<'shorter, MyProxied>`
			`where`
			`'a: 'shorter,`
			`{`
			`self`
			`}`
			`}`

			`#[derive(Debug)]`
			`struct MyProxiedMut<'a> {`
			`my_proxied_ref: &'a mut MyProxied,`
			`}`

			`impl MyProxiedMut<'_> {`
			`fn set_val(&mut self, new_val: String) {`
			`self.my_proxied_ref.val = new_val;`
			`}`
			`}`

			`impl<'a> ViewFor<'a, MyProxied> for MyProxiedMut<'a> {`
			`fn as_view(&self) -> View<'_, MyProxied> {`
			`MyProxiedView { my_proxied_ref: self.my_proxied_ref }`
			`}`
			`fn into_view<'shorter>(self) -> View<'shorter, MyProxied>`
			`where`
			`'a: 'shorter,`
			`{`
			`MyProxiedView { my_proxied_ref: self.my_proxied_ref }`
			`}`
			`}`

			`impl<'a> MutFor<'a, MyProxied> for MyProxiedMut<'a> {`
			`fn as_mut(&mut self) -> Mut<'_, MyProxied> {`
			`MyProxiedMut { my_proxied_ref: self.my_proxied_ref }`
			`}`

			`fn into_mut<'shorter>(self) -> Mut<'shorter, MyProxied>`
			`where`
			`'a: 'shorter,`
			`{`
			`self`
			`}`
			`}`

			`#[test]`
			`fn test_as_view() {`
			`let my_proxied = MyProxied { val: "Hello World".to_string() };`

			`let my_view = my_proxied.as_view();`

			`assert_eq!(my_view.val(), my_proxied.val);`
			`}`

			`#[test]`
			`fn test_as_mut() {`
			`let mut my_proxied = MyProxied { val: "Hello World".to_string() };`

			`let mut my_mut = my_proxied.as_mut();`
			`my_mut.set_val("Hello indeed".to_string());`

			`let val_after_set = my_mut.as_view().val().to_string();`
			`assert_eq!(my_proxied.val, val_after_set);`
			`assert_eq!(my_proxied.val, "Hello indeed");`
			`}`

			`fn reborrow_mut_into_view<'a>(x: Mut<'a, MyProxied>) -> View<'a, MyProxied> {`
			`// x.as_view() fails to compile with:`
			// `ERROR: attempt to return function-local borrowed content`
			`x.into_view() // OK: we return the same lifetime as we got in.`
			`}`

			`#[test]`
			`fn test_mut_into_view() {`
			`let mut my_proxied = MyProxied { val: "Hello World".to_string() };`
			`reborrow_mut_into_view(my_proxied.as_mut());`
			`}`

			`fn require_unified_lifetimes<'a>(_x: Mut<'a, MyProxied>, _y: View<'a, MyProxied>) {}`

			`#[test]`
			`fn test_require_unified_lifetimes() {`
			`let mut my_proxied = MyProxied { val: "Hello1".to_string() };`
			`let my_mut = my_proxied.as_mut();`

			`{`
			`let other_proxied = MyProxied { val: "Hello2".to_string() };`
			`let other_view = other_proxied.as_view();`
			`require_unified_lifetimes(my_mut, other_view);`
			`}`
			`}`

			`fn reborrow_generic_as_view<'a, 'b, T>(`
			`x: &'b mut Mut<'a, T>,`
			`y: &'b View<'a, T>,`
			`) -> [View<'b, T>; 2]`
			`where`
			`T: Proxied,`
			`'a: 'b,`
			`{`
			// `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
			`// lifetime parameter is (conservatively) invariant.`
			`[x.as_view(), y.as_view()]`
			`}`

			`#[test]`
			`fn test_reborrow_generic_as_view() {`
			`let mut my_proxied = MyProxied { val: "Hello1".to_string() };`
			`let mut my_mut = my_proxied.as_mut();`
			`let my_ref = &mut my_mut;`

			`{`
			`let other_proxied = MyProxied { val: "Hello2".to_string() };`
			`let other_view = other_proxied.as_view();`
			`reborrow_generic_as_view::<MyProxied>(my_ref, &other_view);`
			`}`
			`}`

			`fn reborrow_generic_view_into_view<'a, 'b, T>(`
			`x: View<'a, T>,`
			`y: View<'b, T>,`
			`) -> [View<'b, T>; 2]`
			`where`
			`T: Proxied,`
			`'a: 'b,`
			`{`
			// `[x, y]` fails to compile because `'a` is not the same as `'b` and the `View`
			`// lifetime parameter is (conservatively) invariant.`
			// `[x.as_view(), y]` fails because that borrow cannot outlive `'b`.
			`[x.into_view(), y]`
			`}`

			`#[test]`
			`fn test_reborrow_generic_into_view() {`
			`let my_proxied = MyProxied { val: "Hello1".to_string() };`
			`let my_view = my_proxied.as_view();`

			`{`
			`let other_proxied = MyProxied { val: "Hello2".to_string() };`
			`let other_view = other_proxied.as_view();`
			`reborrow_generic_view_into_view::<MyProxied>(my_view, other_view);`
			`}`
			`}`

			`fn reborrow_generic_mut_into_view<'a, 'b, T>(x: Mut<'a, T>, y: View<'b, T>) -> [View<'b, T>; 2]`
			`where`
			`T: Proxied,`
			`'a: 'b,`
			`{`
			`[x.into_view(), y]`
			`}`

			`#[test]`
			`fn test_reborrow_generic_mut_into_view() {`
			`let mut my_proxied = MyProxied { val: "Hello1".to_string() };`
			`let my_mut = my_proxied.as_mut();`

			`{`
			`let other_proxied = MyProxied { val: "Hello2".to_string() };`
			`let other_view = other_proxied.as_view();`
			`reborrow_generic_mut_into_view::<MyProxied>(my_mut, other_view);`
			`}`
			`}`

			`fn reborrow_generic_mut_into_mut<'a, 'b, T>(x: Mut<'a, T>, y: Mut<'b, T>) -> [Mut<'b, T>; 2]`
			`where`
			`T: Proxied,`
			`'a: 'b,`
			`{`
			// `[x, y]` fails to compile because `'a` is not the same as `'b` and the `Mut`
			`// lifetime parameter is (conservatively) invariant.`
			// `[x.as_mut(), y]` fails because that borrow cannot outlive `'b`.
			`[x.into_mut(), y]`
			`}`

			`#[test]`
			`fn test_reborrow_generic_mut_into_mut() {`
			`let mut my_proxied = MyProxied { val: "Hello1".to_string() };`
			`let my_mut = my_proxied.as_mut();`

			`{`
			`let mut other_proxied = MyProxied { val: "Hello2".to_string() };`
			`let other_mut = other_proxied.as_mut();`
			`// No need to reborrow, even though lifetime of &other_view is different`
			`// than the lifetiem of my_ref. Rust references are covariant over their`
			`// lifetime.`
			`reborrow_generic_mut_into_mut::<MyProxied>(my_mut, other_mut);`
			`}`
			`}`
			`}`