library/compiler-builtins/libm/src/math/support/env.rs - rust - Git at Google

 //! Support for rounding directions and status flags as specified by IEEE 754.
 //!
 //! Rust does not support the floating point environment so rounding mode is passed as an argument
 //! and status flags are returned as part of the result. There is currently not much support for
 //! this; most existing ports from musl use a form of `force_eval!` to raise exceptions, but this
 //! has no side effects in Rust. Further, correct behavior relies on elementary operations making
 //! use of the correct rounding and raising relevant exceptions, which is not the case for Rust.
 //!
 //! This module exists so no functionality is lost when porting algorithms that respect floating
 //! point environment, and so that some functionality may be tested (that which does not rely on
 //! side effects from elementary operations). Full support would require wrappers around basic
 //! operations, but there is no plan to add this at the current time.

 /// A value combined with a floating point status.
 pub struct FpResult<T> {
     pub val: T,
     #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
     pub status: Status,
 }

 impl<T> FpResult<T> {
     pub fn new(val: T, status: Status) -> Self {
         Self { val, status }
     }

     /// Return `val` with `Status::OK`.
     pub fn ok(val: T) -> Self {
         Self {
             val,
             status: Status::OK,
         }
     }
 }

 /// IEEE 754 rounding mode, excluding the optional `roundTiesToAway` version of nearest.
 ///
 /// Integer representation comes from what CORE-MATH uses for indexing.
 #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
 #[derive(Clone, Copy, Debug, PartialEq)]
 pub enum Round {
     /// IEEE 754 nearest, `roundTiesToEven`.
     Nearest = 0,
     /// IEEE 754 `roundTowardNegative`.
     Negative = 1,
     /// IEEE 754 `roundTowardPositive`.
     Positive = 2,
     /// IEEE 754 `roundTowardZero`.
     Zero = 3,
 }

 /// IEEE 754 exception status flags.
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]
 pub struct Status(u8);

 impl Status {
     /// Default status indicating no errors.
     pub const OK: Self = Self(0);

     /// No definable result.
     ///
     /// Includes:
     /// - Any ops on sNaN, with a few exceptions.
     /// - `0 * inf`, `inf * 0`.
     /// - `fma(0, inf, c)` or `fma(inf, 0, c)`, possibly excluding `c = qNaN`.
     /// - `+inf + -inf` and similar (includes subtraction and fma).
     /// - `0.0 / 0.0`, `inf / inf`
     /// - `remainder(x, y)` if `y == 0.0` or `x == inf`, and neither is NaN.
     /// - `sqrt(x)` with `x < 0.0`.
     pub const INVALID: Self = Self(1);

     /// Division by zero.
     ///
     /// The default result for division is +/-inf based on operand sign. For `logB`, the default
     /// result is -inf.
     /// `x / y` when `x != 0.0` and `y == 0.0`,
     #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
     pub const DIVIDE_BY_ZERO: Self = Self(1 << 2);

     /// The result exceeds the maximum finite value.
     ///
     /// The default result depends on rounding mode. `Nearest*` rounds to +/- infinity, sign based
     /// on the intermediate result. `Zero` rounds to the signed maximum finite. `Positive` and
     /// `Negative` round to signed maximum finite in one direction, signed infinity in the other.
     #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
     pub const OVERFLOW: Self = Self(1 << 3);

     /// The result is subnormal and lost precision.
     pub const UNDERFLOW: Self = Self(1 << 4);

     /// The finite-precision result does not match that of infinite precision, and the reason
     /// is not represented by one of the other flags.
     pub const INEXACT: Self = Self(1 << 5);

     /// True if `UNDERFLOW` is set.
     #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
     pub const fn underflow(self) -> bool {
         self.0 & Self::UNDERFLOW.0 != 0
     }

     /// True if `OVERFLOW` is set.
     #[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
     pub const fn overflow(self) -> bool {
         self.0 & Self::OVERFLOW.0 != 0
     }

     pub fn set_underflow(&mut self, val: bool) {
         self.set_flag(val, Self::UNDERFLOW);
     }

     /// True if `INEXACT` is set.
     pub const fn inexact(self) -> bool {
         self.0 & Self::INEXACT.0 != 0
     }

     pub fn set_inexact(&mut self, val: bool) {
         self.set_flag(val, Self::INEXACT);
     }

     fn set_flag(&mut self, val: bool, mask: Self) {
         if val {
             self.0 |= mask.0;
         } else {
             self.0 &= !mask.0;
         }
     }

     pub(crate) const fn with(self, rhs: Self) -> Self {
         Self(self.0 | rhs.0)
     }
 }
	//! Support for rounding directions and status flags as specified by IEEE 754.
	//!
	//! Rust does not support the floating point environment so rounding mode is passed as an argument
	//! and status flags are returned as part of the result. There is currently not much support for
	//! this; most existing ports from musl use a form of `force_eval!` to raise exceptions, but this
	//! has no side effects in Rust. Further, correct behavior relies on elementary operations making
	//! use of the correct rounding and raising relevant exceptions, which is not the case for Rust.
	//!
	//! This module exists so no functionality is lost when porting algorithms that respect floating
	//! point environment, and so that some functionality may be tested (that which does not rely on
	//! side effects from elementary operations). Full support would require wrappers around basic
	//! operations, but there is no plan to add this at the current time.

	/// A value combined with a floating point status.
	pub struct FpResult<T> {
	pub val: T,
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	pub status: Status,
	}

	impl<T> FpResult<T> {
	pub fn new(val: T, status: Status) -> Self {
	Self { val, status }
	}

	/// Return `val` with `Status::OK`.
	pub fn ok(val: T) -> Self {
	Self {
	val,
	status: Status::OK,
	}
	}
	}

	/// IEEE 754 rounding mode, excluding the optional `roundTiesToAway` version of nearest.
	///
	/// Integer representation comes from what CORE-MATH uses for indexing.
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	#[derive(Clone, Copy, Debug, PartialEq)]
	pub enum Round {
	/// IEEE 754 nearest, `roundTiesToEven`.
	Nearest = 0,
	/// IEEE 754 `roundTowardNegative`.
	Negative = 1,
	/// IEEE 754 `roundTowardPositive`.
	Positive = 2,
	/// IEEE 754 `roundTowardZero`.
	Zero = 3,
	}

	/// IEEE 754 exception status flags.
	#[derive(Clone, Copy, Debug, PartialEq, Eq)]
	pub struct Status(u8);

	impl Status {
	/// Default status indicating no errors.
	pub const OK: Self = Self(0);

	/// No definable result.
	///
	/// Includes:
	/// - Any ops on sNaN, with a few exceptions.
	/// - `0 * inf`, `inf * 0`.
	/// - `fma(0, inf, c)` or `fma(inf, 0, c)`, possibly excluding `c = qNaN`.
	/// - `+inf + -inf` and similar (includes subtraction and fma).
	/// - `0.0 / 0.0`, `inf / inf`
	/// - `remainder(x, y)` if `y == 0.0` or `x == inf`, and neither is NaN.
	/// - `sqrt(x)` with `x < 0.0`.
	pub const INVALID: Self = Self(1);

	/// Division by zero.
	///
	/// The default result for division is +/-inf based on operand sign. For `logB`, the default
	/// result is -inf.
	/// `x / y` when `x != 0.0` and `y == 0.0`,
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	pub const DIVIDE_BY_ZERO: Self = Self(1 << 2);

	/// The result exceeds the maximum finite value.
	///
	/// The default result depends on rounding mode. `Nearest*` rounds to +/- infinity, sign based
	/// on the intermediate result. `Zero` rounds to the signed maximum finite. `Positive` and
	/// `Negative` round to signed maximum finite in one direction, signed infinity in the other.
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	pub const OVERFLOW: Self = Self(1 << 3);

	/// The result is subnormal and lost precision.
	pub const UNDERFLOW: Self = Self(1 << 4);

	/// The finite-precision result does not match that of infinite precision, and the reason
	/// is not represented by one of the other flags.
	pub const INEXACT: Self = Self(1 << 5);

	/// True if `UNDERFLOW` is set.
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	pub const fn underflow(self) -> bool {
	self.0 & Self::UNDERFLOW.0 != 0
	}

	/// True if `OVERFLOW` is set.
	#[cfg_attr(not(feature = "unstable-public-internals"), allow(dead_code))]
	pub const fn overflow(self) -> bool {
	self.0 & Self::OVERFLOW.0 != 0
	}

	pub fn set_underflow(&mut self, val: bool) {
	self.set_flag(val, Self::UNDERFLOW);
	}

	/// True if `INEXACT` is set.
	pub const fn inexact(self) -> bool {
	self.0 & Self::INEXACT.0 != 0
	}

	pub fn set_inexact(&mut self, val: bool) {
	self.set_flag(val, Self::INEXACT);
	}

	fn set_flag(&mut self, val: bool, mask: Self) {
	if val {
	self.0 \|= mask.0;
	} else {
	self.0 &= !mask.0;
	}
	}

	pub(crate) const fn with(self, rhs: Self) -> Self {
	Self(self.0 \| rhs.0)
	}
	}