rust/kernel/alloc.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 //! Implementation of the kernel's memory allocation infrastructure.

 #[cfg(not(any(test, testlib)))]
 pub mod allocator;
 pub mod kbox;
 pub mod kvec;
 pub mod layout;

 #[cfg(any(test, testlib))]
 pub mod allocator_test;

 #[cfg(any(test, testlib))]
 pub use self::allocator_test as allocator;

 pub use self::kbox::Box;
 pub use self::kbox::KBox;
 pub use self::kbox::KVBox;
 pub use self::kbox::VBox;

 pub use self::kvec::IntoIter;
 pub use self::kvec::KVVec;
 pub use self::kvec::KVec;
 pub use self::kvec::VVec;
 pub use self::kvec::Vec;

 /// Indicates an allocation error.
 #[derive(Copy, Clone, PartialEq, Eq, Debug)]
 pub struct AllocError;
 use core::{alloc::Layout, ptr::NonNull};

 /// Flags to be used when allocating memory.
 ///
 /// They can be combined with the operators `|`, `&`, and `!`.
 ///
 /// Values can be used from the [`flags`] module.
 #[derive(Clone, Copy, PartialEq)]
 pub struct Flags(u32);

 impl Flags {
     /// Get the raw representation of this flag.
     pub(crate) fn as_raw(self) -> u32 {
         self.0
     }

     /// Check whether `flags` is contained in `self`.
     pub fn contains(self, flags: Flags) -> bool {
         (self & flags) == flags
     }
 }

 impl core::ops::BitOr for Flags {
     type Output = Self;
     fn bitor(self, rhs: Self) -> Self::Output {
         Self(self.0 | rhs.0)
     }
 }

 impl core::ops::BitAnd for Flags {
     type Output = Self;
     fn bitand(self, rhs: Self) -> Self::Output {
         Self(self.0 & rhs.0)
     }
 }

 impl core::ops::Not for Flags {
     type Output = Self;
     fn not(self) -> Self::Output {
         Self(!self.0)
     }
 }

 /// Allocation flags.
 ///
 /// These are meant to be used in functions that can allocate memory.
 pub mod flags {
     use super::Flags;

     /// Zeroes out the allocated memory.
     ///
     /// This is normally or'd with other flags.
     pub const __GFP_ZERO: Flags = Flags(bindings::__GFP_ZERO);

     /// Allow the allocation to be in high memory.
     ///
     /// Allocations in high memory may not be mapped into the kernel's address space, so this can't
     /// be used with `kmalloc` and other similar methods.
     ///
     /// This is normally or'd with other flags.
     pub const __GFP_HIGHMEM: Flags = Flags(bindings::__GFP_HIGHMEM);

     /// Users can not sleep and need the allocation to succeed.
     ///
     /// A lower watermark is applied to allow access to "atomic reserves". The current
     /// implementation doesn't support NMI and few other strict non-preemptive contexts (e.g.
     /// `raw_spin_lock`). The same applies to [`GFP_NOWAIT`].
     pub const GFP_ATOMIC: Flags = Flags(bindings::GFP_ATOMIC);

     /// Typical for kernel-internal allocations. The caller requires `ZONE_NORMAL` or a lower zone
     /// for direct access but can direct reclaim.
     pub const GFP_KERNEL: Flags = Flags(bindings::GFP_KERNEL);

     /// The same as [`GFP_KERNEL`], except the allocation is accounted to kmemcg.
     pub const GFP_KERNEL_ACCOUNT: Flags = Flags(bindings::GFP_KERNEL_ACCOUNT);

     /// For kernel allocations that should not stall for direct reclaim, start physical IO or
     /// use any filesystem callback.  It is very likely to fail to allocate memory, even for very
     /// small allocations.
     pub const GFP_NOWAIT: Flags = Flags(bindings::GFP_NOWAIT);

     /// Suppresses allocation failure reports.
     ///
     /// This is normally or'd with other flags.
     pub const __GFP_NOWARN: Flags = Flags(bindings::__GFP_NOWARN);
 }

 /// The kernel's [`Allocator`] trait.
 ///
 /// An implementation of [`Allocator`] can allocate, re-allocate and free memory buffers described
 /// via [`Layout`].
 ///
 /// [`Allocator`] is designed to be implemented as a ZST; [`Allocator`] functions do not operate on
 /// an object instance.
 ///
 /// In order to be able to support `#[derive(CoercePointee)]` later on, we need to avoid a design
 /// that requires an `Allocator` to be instantiated, hence its functions must not contain any kind
 /// of `self` parameter.
 ///
 /// # Safety
 ///
 /// - A memory allocation returned from an allocator must remain valid until it is explicitly freed.
 ///
 /// - Any pointer to a valid memory allocation must be valid to be passed to any other [`Allocator`]
 ///   function of the same type.
 ///
 /// - Implementers must ensure that all trait functions abide by the guarantees documented in the
 ///   `# Guarantees` sections.
 pub unsafe trait Allocator {
     /// Allocate memory based on `layout` and `flags`.
     ///
     /// On success, returns a buffer represented as `NonNull<[u8]>` that satisfies the layout
     /// constraints (i.e. minimum size and alignment as specified by `layout`).
     ///
     /// This function is equivalent to `realloc` when called with `None`.
     ///
     /// # Guarantees
     ///
     /// When the return value is `Ok(ptr)`, then `ptr` is
     /// - valid for reads and writes for `layout.size()` bytes, until it is passed to
     ///   [`Allocator::free`] or [`Allocator::realloc`],
     /// - aligned to `layout.align()`,
     ///
     /// Additionally, `Flags` are honored as documented in
     /// <https://docs.kernel.org/core-api/mm-api.html#mm-api-gfp-flags>.
     fn alloc(layout: Layout, flags: Flags) -> Result<NonNull<[u8]>, AllocError> {
         // SAFETY: Passing `None` to `realloc` is valid by its safety requirements and asks for a
         // new memory allocation.
         unsafe { Self::realloc(None, layout, Layout::new::<()>(), flags) }
     }

     /// Re-allocate an existing memory allocation to satisfy the requested `layout`.
     ///
     /// If the requested size is zero, `realloc` behaves equivalent to `free`.
     ///
     /// If the requested size is larger than the size of the existing allocation, a successful call
     /// to `realloc` guarantees that the new or grown buffer has at least `Layout::size` bytes, but
     /// may also be larger.
     ///
     /// If the requested size is smaller than the size of the existing allocation, `realloc` may or
     /// may not shrink the buffer; this is implementation specific to the allocator.
     ///
     /// On allocation failure, the existing buffer, if any, remains valid.
     ///
     /// The buffer is represented as `NonNull<[u8]>`.
     ///
     /// # Safety
     ///
     /// - If `ptr == Some(p)`, then `p` must point to an existing and valid memory allocation
     ///   created by this [`Allocator`]; if `old_layout` is zero-sized `p` does not need to be a
     ///   pointer returned by this [`Allocator`].
     /// - `ptr` is allowed to be `None`; in this case a new memory allocation is created and
     ///   `old_layout` is ignored.
     /// - `old_layout` must match the `Layout` the allocation has been created with.
     ///
     /// # Guarantees
     ///
     /// This function has the same guarantees as [`Allocator::alloc`]. When `ptr == Some(p)`, then
     /// it additionally guarantees that:
     /// - the contents of the memory pointed to by `p` are preserved up to the lesser of the new
     ///   and old size, i.e. `ret_ptr[0..min(layout.size(), old_layout.size())] ==
     ///   p[0..min(layout.size(), old_layout.size())]`.
     /// - when the return value is `Err(AllocError)`, then `ptr` is still valid.
     unsafe fn realloc(
         ptr: Option<NonNull<u8>>,
         layout: Layout,
         old_layout: Layout,
         flags: Flags,
     ) -> Result<NonNull<[u8]>, AllocError>;

     /// Free an existing memory allocation.
     ///
     /// # Safety
     ///
     /// - `ptr` must point to an existing and valid memory allocation created by this [`Allocator`];
     ///   if `old_layout` is zero-sized `p` does not need to be a pointer returned by this
     ///   [`Allocator`].
     /// - `layout` must match the `Layout` the allocation has been created with.
     /// - The memory allocation at `ptr` must never again be read from or written to.
     unsafe fn free(ptr: NonNull<u8>, layout: Layout) {
         // SAFETY: The caller guarantees that `ptr` points at a valid allocation created by this
         // allocator. We are passing a `Layout` with the smallest possible alignment, so it is
         // smaller than or equal to the alignment previously used with this allocation.
         let _ = unsafe { Self::realloc(Some(ptr), Layout::new::<()>(), layout, Flags(0)) };
     }
 }

 /// Returns a properly aligned dangling pointer from the given `layout`.
 pub(crate) fn dangling_from_layout(layout: Layout) -> NonNull<u8> {
     let ptr = layout.align() as *mut u8;

     // SAFETY: `layout.align()` (and hence `ptr`) is guaranteed to be non-zero.
     unsafe { NonNull::new_unchecked(ptr) }
 }
	// SPDX-License-Identifier: GPL-2.0

	//! Implementation of the kernel's memory allocation infrastructure.

	#[cfg(not(any(test, testlib)))]
	pub mod allocator;
	pub mod kbox;
	pub mod kvec;
	pub mod layout;

	#[cfg(any(test, testlib))]
	pub mod allocator_test;

	#[cfg(any(test, testlib))]
	pub use self::allocator_test as allocator;

	pub use self::kbox::Box;
	pub use self::kbox::KBox;
	pub use self::kbox::KVBox;
	pub use self::kbox::VBox;

	pub use self::kvec::IntoIter;
	pub use self::kvec::KVVec;
	pub use self::kvec::KVec;
	pub use self::kvec::VVec;
	pub use self::kvec::Vec;

	/// Indicates an allocation error.
	#[derive(Copy, Clone, PartialEq, Eq, Debug)]
	pub struct AllocError;
	use core::{alloc::Layout, ptr::NonNull};

	/// Flags to be used when allocating memory.
	///
	/// They can be combined with the operators `\|`, `&`, and `!`.
	///
	/// Values can be used from the [`flags`] module.
	#[derive(Clone, Copy, PartialEq)]
	pub struct Flags(u32);

	impl Flags {
	/// Get the raw representation of this flag.
	pub(crate) fn as_raw(self) -> u32 {
	self.0
	}

	/// Check whether `flags` is contained in `self`.
	pub fn contains(self, flags: Flags) -> bool {
	(self & flags) == flags
	}
	}

	impl core::ops::BitOr for Flags {
	type Output = Self;
	fn bitor(self, rhs: Self) -> Self::Output {
	Self(self.0 \| rhs.0)
	}
	}

	impl core::ops::BitAnd for Flags {
	type Output = Self;
	fn bitand(self, rhs: Self) -> Self::Output {
	Self(self.0 & rhs.0)
	}
	}

	impl core::ops::Not for Flags {
	type Output = Self;
	fn not(self) -> Self::Output {
	Self(!self.0)
	}
	}

	/// Allocation flags.
	///
	/// These are meant to be used in functions that can allocate memory.
	pub mod flags {
	use super::Flags;

	/// Zeroes out the allocated memory.
	///
	/// This is normally or'd with other flags.
	pub const __GFP_ZERO: Flags = Flags(bindings::__GFP_ZERO);

	/// Allow the allocation to be in high memory.
	///
	/// Allocations in high memory may not be mapped into the kernel's address space, so this can't
	/// be used with `kmalloc` and other similar methods.
	///
	/// This is normally or'd with other flags.
	pub const __GFP_HIGHMEM: Flags = Flags(bindings::__GFP_HIGHMEM);

	/// Users can not sleep and need the allocation to succeed.
	///
	/// A lower watermark is applied to allow access to "atomic reserves". The current
	/// implementation doesn't support NMI and few other strict non-preemptive contexts (e.g.
	/// `raw_spin_lock`). The same applies to [`GFP_NOWAIT`].
	pub const GFP_ATOMIC: Flags = Flags(bindings::GFP_ATOMIC);

	/// Typical for kernel-internal allocations. The caller requires `ZONE_NORMAL` or a lower zone
	/// for direct access but can direct reclaim.
	pub const GFP_KERNEL: Flags = Flags(bindings::GFP_KERNEL);

	/// The same as [`GFP_KERNEL`], except the allocation is accounted to kmemcg.
	pub const GFP_KERNEL_ACCOUNT: Flags = Flags(bindings::GFP_KERNEL_ACCOUNT);

	/// For kernel allocations that should not stall for direct reclaim, start physical IO or
	/// use any filesystem callback. It is very likely to fail to allocate memory, even for very
	/// small allocations.
	pub const GFP_NOWAIT: Flags = Flags(bindings::GFP_NOWAIT);

	/// Suppresses allocation failure reports.
	///
	/// This is normally or'd with other flags.
	pub const __GFP_NOWARN: Flags = Flags(bindings::__GFP_NOWARN);
	}

	/// The kernel's [`Allocator`] trait.
	///
	/// An implementation of [`Allocator`] can allocate, re-allocate and free memory buffers described
	/// via [`Layout`].
	///
	/// [`Allocator`] is designed to be implemented as a ZST; [`Allocator`] functions do not operate on
	/// an object instance.
	///
	/// In order to be able to support `#[derive(CoercePointee)]` later on, we need to avoid a design
	/// that requires an `Allocator` to be instantiated, hence its functions must not contain any kind
	/// of `self` parameter.
	///
	/// # Safety
	///
	/// - A memory allocation returned from an allocator must remain valid until it is explicitly freed.
	///
	/// - Any pointer to a valid memory allocation must be valid to be passed to any other [`Allocator`]
	/// function of the same type.
	///
	/// - Implementers must ensure that all trait functions abide by the guarantees documented in the
	/// `# Guarantees` sections.
	pub unsafe trait Allocator {
	/// Allocate memory based on `layout` and `flags`.
	///
	/// On success, returns a buffer represented as `NonNull<[u8]>` that satisfies the layout
	/// constraints (i.e. minimum size and alignment as specified by `layout`).
	///
	/// This function is equivalent to `realloc` when called with `None`.
	///
	/// # Guarantees
	///
	/// When the return value is `Ok(ptr)`, then `ptr` is
	/// - valid for reads and writes for `layout.size()` bytes, until it is passed to
	/// [`Allocator::free`] or [`Allocator::realloc`],
	/// - aligned to `layout.align()`,
	///
	/// Additionally, `Flags` are honored as documented in
	/// <https://docs.kernel.org/core-api/mm-api.html#mm-api-gfp-flags>.
	fn alloc(layout: Layout, flags: Flags) -> Result<NonNull<[u8]>, AllocError> {
	// SAFETY: Passing `None` to `realloc` is valid by its safety requirements and asks for a
	// new memory allocation.
	unsafe { Self::realloc(None, layout, Layout::new::<()>(), flags) }
	}

	/// Re-allocate an existing memory allocation to satisfy the requested `layout`.
	///
	/// If the requested size is zero, `realloc` behaves equivalent to `free`.
	///
	/// If the requested size is larger than the size of the existing allocation, a successful call
	/// to `realloc` guarantees that the new or grown buffer has at least `Layout::size` bytes, but
	/// may also be larger.
	///
	/// If the requested size is smaller than the size of the existing allocation, `realloc` may or
	/// may not shrink the buffer; this is implementation specific to the allocator.
	///
	/// On allocation failure, the existing buffer, if any, remains valid.
	///
	/// The buffer is represented as `NonNull<[u8]>`.
	///
	/// # Safety
	///
	/// - If `ptr == Some(p)`, then `p` must point to an existing and valid memory allocation
	/// created by this [`Allocator`]; if `old_layout` is zero-sized `p` does not need to be a
	/// pointer returned by this [`Allocator`].
	/// - `ptr` is allowed to be `None`; in this case a new memory allocation is created and
	/// `old_layout` is ignored.
	/// - `old_layout` must match the `Layout` the allocation has been created with.
	///
	/// # Guarantees
	///
	/// This function has the same guarantees as [`Allocator::alloc`]. When `ptr == Some(p)`, then
	/// it additionally guarantees that:
	/// - the contents of the memory pointed to by `p` are preserved up to the lesser of the new
	/// and old size, i.e. `ret_ptr[0..min(layout.size(), old_layout.size())] ==
	/// p[0..min(layout.size(), old_layout.size())]`.
	/// - when the return value is `Err(AllocError)`, then `ptr` is still valid.
	unsafe fn realloc(
	ptr: Option<NonNull<u8>>,
	layout: Layout,
	old_layout: Layout,
	flags: Flags,
	) -> Result<NonNull<[u8]>, AllocError>;

	/// Free an existing memory allocation.
	///
	/// # Safety
	///
	/// - `ptr` must point to an existing and valid memory allocation created by this [`Allocator`];
	/// if `old_layout` is zero-sized `p` does not need to be a pointer returned by this
	/// [`Allocator`].
	/// - `layout` must match the `Layout` the allocation has been created with.
	/// - The memory allocation at `ptr` must never again be read from or written to.
	unsafe fn free(ptr: NonNull<u8>, layout: Layout) {
	// SAFETY: The caller guarantees that `ptr` points at a valid allocation created by this
	// allocator. We are passing a `Layout` with the smallest possible alignment, so it is
	// smaller than or equal to the alignment previously used with this allocation.
	let _ = unsafe { Self::realloc(Some(ptr), Layout::new::<()>(), layout, Flags(0)) };
	}
	}

	/// Returns a properly aligned dangling pointer from the given `layout`.
	pub(crate) fn dangling_from_layout(layout: Layout) -> NonNull<u8> {
	let ptr = layout.align() as *mut u8;

	// SAFETY: `layout.align()` (and hence `ptr`) is guaranteed to be non-zero.
	unsafe { NonNull::new_unchecked(ptr) }
	}