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

 // SPDX-License-Identifier: GPL-2.0

 //! Bitflag type generator.

 /// Common helper for declaring bitflag and bitmask types.
 ///
 /// This macro takes as input:
 /// - A struct declaration representing a bitmask type
 ///   (e.g., `pub struct Permissions(u32)`).
 /// - An enumeration declaration representing individual bit flags
 ///   (e.g., `pub enum Permission { ... }`).
 ///
 /// And generates:
 /// - The struct and enum types with appropriate `#[repr]` attributes.
 /// - Implementations of common bitflag operators
 ///   ([`::core::ops::BitOr`], [`::core::ops::BitAnd`], etc.).
 /// - Utility methods such as `.contains()` to check flags.
 ///
 /// # Examples
 ///
 /// ```
 /// use kernel::impl_flags;
 ///
 /// impl_flags!(
 ///     /// Represents multiple permissions.
 ///     #[derive(Debug, Clone, Default, Copy, PartialEq, Eq)]
 ///     pub struct Permissions(u32);
 ///
 ///     /// Represents a single permission.
 ///     #[derive(Debug, Clone, Copy, PartialEq, Eq)]
 ///     pub enum Permission {
 ///         /// Read permission.
 ///         Read = 1 << 0,
 ///
 ///         /// Write permission.
 ///         Write = 1 << 1,
 ///
 ///         /// Execute permission.
 ///         Execute = 1 << 2,
 ///     }
 /// );
 ///
 /// // Combine multiple permissions using the bitwise OR (`|`) operator.
 /// let mut read_write: Permissions = Permission::Read | Permission::Write;
 /// assert!(read_write.contains(Permission::Read));
 /// assert!(read_write.contains(Permission::Write));
 /// assert!(!read_write.contains(Permission::Execute));
 /// assert!(read_write.contains_any(Permission::Read | Permission::Execute));
 /// assert!(read_write.contains_all(Permission::Read | Permission::Write));
 ///
 /// // Using the bitwise OR assignment (`|=`) operator.
 /// read_write |= Permission::Execute;
 /// assert!(read_write.contains(Permission::Execute));
 ///
 /// // Masking a permission with the bitwise AND (`&`) operator.
 /// let read_only: Permissions = read_write & Permission::Read;
 /// assert!(read_only.contains(Permission::Read));
 /// assert!(!read_only.contains(Permission::Write));
 ///
 /// // Toggling permissions with the bitwise XOR (`^`) operator.
 /// let toggled: Permissions = read_only ^ Permission::Read;
 /// assert!(!toggled.contains(Permission::Read));
 ///
 /// // Inverting permissions with the bitwise NOT (`!`) operator.
 /// let negated = !read_only;
 /// assert!(negated.contains(Permission::Write));
 /// assert!(!negated.contains(Permission::Read));
 /// ```
 #[macro_export]
 macro_rules! impl_flags {
     (
         $(#[$outer_flags:meta])*
         $vis_flags:vis struct $flags:ident($ty:ty);

         $(#[$outer_flag:meta])*
         $vis_flag:vis enum $flag:ident {
             $(
                 $(#[$inner_flag:meta])*
                 $name:ident = $value:expr
             ),+ $( , )?
         }
     ) => {
         $(#[$outer_flags])*
         #[repr(transparent)]
         $vis_flags struct $flags($ty);

         $(#[$outer_flag])*
         #[repr($ty)]
         $vis_flag enum $flag {
             $(
                 $(#[$inner_flag])*
                 $name = $value
             ),+
         }

         impl ::core::convert::From<$flag> for $flags {
             #[inline]
             fn from(value: $flag) -> Self {
                 Self(value as $ty)
             }
         }

         impl ::core::convert::From<$flags> for $ty {
             #[inline]
             fn from(value: $flags) -> Self {
                 value.0
             }
         }

         impl ::core::ops::BitOr for $flags {
             type Output = Self;
             #[inline]
             fn bitor(self, rhs: Self) -> Self::Output {
                 Self(self.0 | rhs.0)
             }
         }

         impl ::core::ops::BitOrAssign for $flags {
             #[inline]
             fn bitor_assign(&mut self, rhs: Self) {
                 *self = *self | rhs;
             }
         }

         impl ::core::ops::BitOr<$flag> for $flags {
             type Output = Self;
             #[inline]
             fn bitor(self, rhs: $flag) -> Self::Output {
                 self | Self::from(rhs)
             }
         }

         impl ::core::ops::BitOrAssign<$flag> for $flags {
             #[inline]
             fn bitor_assign(&mut self, rhs: $flag) {
                 *self = *self | rhs;
             }
         }

         impl ::core::ops::BitAnd for $flags {
             type Output = Self;
             #[inline]
             fn bitand(self, rhs: Self) -> Self::Output {
                 Self(self.0 & rhs.0)
             }
         }

         impl ::core::ops::BitAndAssign for $flags {
             #[inline]
             fn bitand_assign(&mut self, rhs: Self) {
                 *self = *self & rhs;
             }
         }

         impl ::core::ops::BitAnd<$flag> for $flags {
             type Output = Self;
             #[inline]
             fn bitand(self, rhs: $flag) -> Self::Output {
                 self & Self::from(rhs)
             }
         }

         impl ::core::ops::BitAndAssign<$flag> for $flags {
             #[inline]
             fn bitand_assign(&mut self, rhs: $flag) {
                 *self = *self & rhs;
             }
         }

         impl ::core::ops::BitXor for $flags {
             type Output = Self;
             #[inline]
             fn bitxor(self, rhs: Self) -> Self::Output {
                 Self((self.0 ^ rhs.0) & Self::all_bits())
             }
         }

         impl ::core::ops::BitXorAssign for $flags {
             #[inline]
             fn bitxor_assign(&mut self, rhs: Self) {
                 *self = *self ^ rhs;
             }
         }

         impl ::core::ops::BitXor<$flag> for $flags {
             type Output = Self;
             #[inline]
             fn bitxor(self, rhs: $flag) -> Self::Output {
                 self ^ Self::from(rhs)
             }
         }

         impl ::core::ops::BitXorAssign<$flag> for $flags {
             #[inline]
             fn bitxor_assign(&mut self, rhs: $flag) {
                 *self = *self ^ rhs;
             }
         }

         impl ::core::ops::Not for $flags {
             type Output = Self;
             #[inline]
             fn not(self) -> Self::Output {
                 Self((!self.0) & Self::all_bits())
             }
         }

         impl ::core::ops::BitOr for $flag {
             type Output = $flags;
             #[inline]
             fn bitor(self, rhs: Self) -> Self::Output {
                 $flags(self as $ty | rhs as $ty)
             }
         }

         impl ::core::ops::BitAnd for $flag {
             type Output = $flags;
             #[inline]
             fn bitand(self, rhs: Self) -> Self::Output {
                 $flags(self as $ty & rhs as $ty)
             }
         }

         impl ::core::ops::BitXor for $flag {
             type Output = $flags;
             #[inline]
             fn bitxor(self, rhs: Self) -> Self::Output {
                 $flags((self as $ty ^ rhs as $ty) & $flags::all_bits())
             }
         }

         impl ::core::ops::Not for $flag {
             type Output = $flags;
             #[inline]
             fn not(self) -> Self::Output {
                 $flags((!(self as $ty)) & $flags::all_bits())
             }
         }

         impl $flags {
             /// Returns an empty instance where no flags are set.
             #[inline]
             pub const fn empty() -> Self {
                 Self(0)
             }

             /// Returns a mask containing all valid flag bits.
             #[inline]
             pub const fn all_bits() -> $ty {
                 0 $( | $value )+
             }

             /// Checks if a specific flag is set.
             #[inline]
             pub fn contains(self, flag: $flag) -> bool {
                 (self.0 & flag as $ty) == flag as $ty
             }

             /// Checks if at least one of the provided flags is set.
             #[inline]
             pub fn contains_any(self, flags: $flags) -> bool {
                 (self.0 & flags.0) != 0
             }

             /// Checks if all of the provided flags are set.
             #[inline]
             pub fn contains_all(self, flags: $flags) -> bool {
                 (self.0 & flags.0) == flags.0
             }
         }
     };
 }
	// SPDX-License-Identifier: GPL-2.0

	//! Bitflag type generator.

	/// Common helper for declaring bitflag and bitmask types.
	///
	/// This macro takes as input:
	/// - A struct declaration representing a bitmask type
	/// (e.g., `pub struct Permissions(u32)`).
	/// - An enumeration declaration representing individual bit flags
	/// (e.g., `pub enum Permission { ... }`).
	///
	/// And generates:
	/// - The struct and enum types with appropriate `#[repr]` attributes.
	/// - Implementations of common bitflag operators
	/// ([`::core::ops::BitOr`], [`::core::ops::BitAnd`], etc.).
	/// - Utility methods such as `.contains()` to check flags.
	///
	/// # Examples
	///
	/// ```
	/// use kernel::impl_flags;
	///
	/// impl_flags!(
	/// /// Represents multiple permissions.
	/// #[derive(Debug, Clone, Default, Copy, PartialEq, Eq)]
	/// pub struct Permissions(u32);
	///
	/// /// Represents a single permission.
	/// #[derive(Debug, Clone, Copy, PartialEq, Eq)]
	/// pub enum Permission {
	/// /// Read permission.
	/// Read = 1 << 0,
	///
	/// /// Write permission.
	/// Write = 1 << 1,
	///
	/// /// Execute permission.
	/// Execute = 1 << 2,
	/// }
	/// );
	///
	/// // Combine multiple permissions using the bitwise OR (`\|`) operator.
	/// let mut read_write: Permissions = Permission::Read \| Permission::Write;
	/// assert!(read_write.contains(Permission::Read));
	/// assert!(read_write.contains(Permission::Write));
	/// assert!(!read_write.contains(Permission::Execute));
	/// assert!(read_write.contains_any(Permission::Read \| Permission::Execute));
	/// assert!(read_write.contains_all(Permission::Read \| Permission::Write));
	///
	/// // Using the bitwise OR assignment (`\|=`) operator.
	/// read_write \|= Permission::Execute;
	/// assert!(read_write.contains(Permission::Execute));
	///
	/// // Masking a permission with the bitwise AND (`&`) operator.
	/// let read_only: Permissions = read_write & Permission::Read;
	/// assert!(read_only.contains(Permission::Read));
	/// assert!(!read_only.contains(Permission::Write));
	///
	/// // Toggling permissions with the bitwise XOR (`^`) operator.
	/// let toggled: Permissions = read_only ^ Permission::Read;
	/// assert!(!toggled.contains(Permission::Read));
	///
	/// // Inverting permissions with the bitwise NOT (`!`) operator.
	/// let negated = !read_only;
	/// assert!(negated.contains(Permission::Write));
	/// assert!(!negated.contains(Permission::Read));
	/// ```
	#[macro_export]
	macro_rules! impl_flags {
	(
	$(#[$outer_flags:meta])*
	$vis_flags:vis struct $flags:ident($ty:ty);

	$(#[$outer_flag:meta])*
	$vis_flag:vis enum $flag:ident {
	$(
	$(#[$inner_flag:meta])*
	$name:ident = $value:expr
	),+ $( , )?
	}
	) => {
	$(#[$outer_flags])*
	#[repr(transparent)]
	$vis_flags struct $flags($ty);

	$(#[$outer_flag])*
	#[repr($ty)]
	$vis_flag enum $flag {
	$(
	$(#[$inner_flag])*
	$name = $value
	),+
	}

	impl ::core::convert::From<$flag> for $flags {
	#[inline]
	fn from(value: $flag) -> Self {
	Self(value as $ty)
	}
	}

	impl ::core::convert::From<$flags> for $ty {
	#[inline]
	fn from(value: $flags) -> Self {
	value.0
	}
	}

	impl ::core::ops::BitOr for $flags {
	type Output = Self;
	#[inline]
	fn bitor(self, rhs: Self) -> Self::Output {
	Self(self.0 \| rhs.0)
	}
	}

	impl ::core::ops::BitOrAssign for $flags {
	#[inline]
	fn bitor_assign(&mut self, rhs: Self) {
	self = self \| rhs;
	}
	}

	impl ::core::ops::BitOr<$flag> for $flags {
	type Output = Self;
	#[inline]
	fn bitor(self, rhs: $flag) -> Self::Output {
	self \| Self::from(rhs)
	}
	}

	impl ::core::ops::BitOrAssign<$flag> for $flags {
	#[inline]
	fn bitor_assign(&mut self, rhs: $flag) {
	self = self \| rhs;
	}
	}

	impl ::core::ops::BitAnd for $flags {
	type Output = Self;
	#[inline]
	fn bitand(self, rhs: Self) -> Self::Output {
	Self(self.0 & rhs.0)
	}
	}

	impl ::core::ops::BitAndAssign for $flags {
	#[inline]
	fn bitand_assign(&mut self, rhs: Self) {
	self = self & rhs;
	}
	}

	impl ::core::ops::BitAnd<$flag> for $flags {
	type Output = Self;
	#[inline]
	fn bitand(self, rhs: $flag) -> Self::Output {
	self & Self::from(rhs)
	}
	}

	impl ::core::ops::BitAndAssign<$flag> for $flags {
	#[inline]
	fn bitand_assign(&mut self, rhs: $flag) {
	self = self & rhs;
	}
	}

	impl ::core::ops::BitXor for $flags {
	type Output = Self;
	#[inline]
	fn bitxor(self, rhs: Self) -> Self::Output {
	Self((self.0 ^ rhs.0) & Self::all_bits())
	}
	}

	impl ::core::ops::BitXorAssign for $flags {
	#[inline]
	fn bitxor_assign(&mut self, rhs: Self) {
	self = self ^ rhs;
	}
	}

	impl ::core::ops::BitXor<$flag> for $flags {
	type Output = Self;
	#[inline]
	fn bitxor(self, rhs: $flag) -> Self::Output {
	self ^ Self::from(rhs)
	}
	}

	impl ::core::ops::BitXorAssign<$flag> for $flags {
	#[inline]
	fn bitxor_assign(&mut self, rhs: $flag) {
	self = self ^ rhs;
	}
	}

	impl ::core::ops::Not for $flags {
	type Output = Self;
	#[inline]
	fn not(self) -> Self::Output {
	Self((!self.0) & Self::all_bits())
	}
	}

	impl ::core::ops::BitOr for $flag {
	type Output = $flags;
	#[inline]
	fn bitor(self, rhs: Self) -> Self::Output {
	$flags(self as $ty \| rhs as $ty)
	}
	}

	impl ::core::ops::BitAnd for $flag {
	type Output = $flags;
	#[inline]
	fn bitand(self, rhs: Self) -> Self::Output {
	$flags(self as $ty & rhs as $ty)
	}
	}

	impl ::core::ops::BitXor for $flag {
	type Output = $flags;
	#[inline]
	fn bitxor(self, rhs: Self) -> Self::Output {
	$flags((self as $ty ^ rhs as $ty) & $flags::all_bits())
	}
	}

	impl ::core::ops::Not for $flag {
	type Output = $flags;
	#[inline]
	fn not(self) -> Self::Output {
	$flags((!(self as $ty)) & $flags::all_bits())
	}
	}

	impl $flags {
	/// Returns an empty instance where no flags are set.
	#[inline]
	pub const fn empty() -> Self {
	Self(0)
	}

	/// Returns a mask containing all valid flag bits.
	#[inline]
	pub const fn all_bits() -> $ty {
	0 $( \| $value )+
	}

	/// Checks if a specific flag is set.
	#[inline]
	pub fn contains(self, flag: $flag) -> bool {
	(self.0 & flag as $ty) == flag as $ty
	}

	/// Checks if at least one of the provided flags is set.
	#[inline]
	pub fn contains_any(self, flags: $flags) -> bool {
	(self.0 & flags.0) != 0
	}

	/// Checks if all of the provided flags are set.
	#[inline]
	pub fn contains_all(self, flags: $flags) -> bool {
	(self.0 & flags.0) == flags.0
	}
	}
	};
	}