linux-x86/1.39.0/src/stdlibs/src/libcore/num/flt2dec/decoder.rs - platform/prebuilts/rust - Git at Google

 //! Decodes a floating-point value into individual parts and error ranges.

 use crate::{f32, f64};
 use crate::num::FpCategory;
 use crate::num::dec2flt::rawfp::RawFloat;

 /// Decoded unsigned finite value, such that:
 ///
 /// - The original value equals to `mant * 2^exp`.
 ///
 /// - Any number from `(mant - minus) * 2^exp` to `(mant + plus) * 2^exp` will
 ///   round to the original value. The range is inclusive only when
 ///   `inclusive` is `true`.
 #[derive(Copy, Clone, Debug, PartialEq, Eq)]
 pub struct Decoded {
     /// The scaled mantissa.
     pub mant: u64,
     /// The lower error range.
     pub minus: u64,
     /// The upper error range.
     pub plus: u64,
     /// The shared exponent in base 2.
     pub exp: i16,
     /// True when the error range is inclusive.
     ///
     /// In IEEE 754, this is true when the original mantissa was even.
     pub inclusive: bool,
 }

 /// Decoded unsigned value.
 #[derive(Copy, Clone, Debug, PartialEq, Eq)]
 pub enum FullDecoded {
     /// Not-a-number.
     Nan,
     /// Infinities, either positive or negative.
     Infinite,
     /// Zero, either positive or negative.
     Zero,
     /// Finite numbers with further decoded fields.
     Finite(Decoded),
 }

 /// A floating point type which can be `decode`d.
 pub trait DecodableFloat: RawFloat + Copy {
     /// The minimum positive normalized value.
     fn min_pos_norm_value() -> Self;
 }

 impl DecodableFloat for f32 {
     fn min_pos_norm_value() -> Self { f32::MIN_POSITIVE }
 }

 impl DecodableFloat for f64 {
     fn min_pos_norm_value() -> Self { f64::MIN_POSITIVE }
 }

 /// Returns a sign (true when negative) and `FullDecoded` value
 /// from given floating point number.
 pub fn decode<T: DecodableFloat>(v: T) -> (/*negative?*/ bool, FullDecoded) {
     let (mant, exp, sign) = v.integer_decode();
     let even = (mant & 1) == 0;
     let decoded = match v.classify() {
         FpCategory::Nan => FullDecoded::Nan,
         FpCategory::Infinite => FullDecoded::Infinite,
         FpCategory::Zero => FullDecoded::Zero,
         FpCategory::Subnormal => {
             // neighbors: (mant - 2, exp) -- (mant, exp) -- (mant + 2, exp)
             // Float::integer_decode always preserves the exponent,
             // so the mantissa is scaled for subnormals.
             FullDecoded::Finite(Decoded { mant, minus: 1, plus: 1,
                                           exp, inclusive: even })
         }
         FpCategory::Normal => {
             let minnorm = <T as DecodableFloat>::min_pos_norm_value().integer_decode();
             if mant == minnorm.0 {
                 // neighbors: (maxmant, exp - 1) -- (minnormmant, exp) -- (minnormmant + 1, exp)
                 // where maxmant = minnormmant * 2 - 1
                 FullDecoded::Finite(Decoded { mant: mant << 2, minus: 1, plus: 2,
                                               exp: exp - 2, inclusive: even })
             } else {
                 // neighbors: (mant - 1, exp) -- (mant, exp) -- (mant + 1, exp)
                 FullDecoded::Finite(Decoded { mant: mant << 1, minus: 1, plus: 1,
                                               exp: exp - 1, inclusive: even })
             }
         }
     };
     (sign < 0, decoded)
 }
	//! Decodes a floating-point value into individual parts and error ranges.

	use crate::{f32, f64};
	use crate::num::FpCategory;
	use crate::num::dec2flt::rawfp::RawFloat;

	/// Decoded unsigned finite value, such that:
	///
	/// - The original value equals to `mant * 2^exp`.
	///
	/// - Any number from `(mant - minus) * 2^exp` to `(mant + plus) * 2^exp` will
	/// round to the original value. The range is inclusive only when
	/// `inclusive` is `true`.
	#[derive(Copy, Clone, Debug, PartialEq, Eq)]
	pub struct Decoded {
	/// The scaled mantissa.
	pub mant: u64,
	/// The lower error range.
	pub minus: u64,
	/// The upper error range.
	pub plus: u64,
	/// The shared exponent in base 2.
	pub exp: i16,
	/// True when the error range is inclusive.
	///
	/// In IEEE 754, this is true when the original mantissa was even.
	pub inclusive: bool,
	}

	/// Decoded unsigned value.
	#[derive(Copy, Clone, Debug, PartialEq, Eq)]
	pub enum FullDecoded {
	/// Not-a-number.
	Nan,
	/// Infinities, either positive or negative.
	Infinite,
	/// Zero, either positive or negative.
	Zero,
	/// Finite numbers with further decoded fields.
	Finite(Decoded),
	}

	/// A floating point type which can be `decode`d.
	pub trait DecodableFloat: RawFloat + Copy {
	/// The minimum positive normalized value.
	fn min_pos_norm_value() -> Self;
	}

	impl DecodableFloat for f32 {
	fn min_pos_norm_value() -> Self { f32::MIN_POSITIVE }
	}

	impl DecodableFloat for f64 {
	fn min_pos_norm_value() -> Self { f64::MIN_POSITIVE }
	}

	/// Returns a sign (true when negative) and `FullDecoded` value
	/// from given floating point number.
	pub fn decode<T: DecodableFloat>(v: T) -> (/negative?/ bool, FullDecoded) {
	let (mant, exp, sign) = v.integer_decode();
	let even = (mant & 1) == 0;
	let decoded = match v.classify() {
	FpCategory::Nan => FullDecoded::Nan,
	FpCategory::Infinite => FullDecoded::Infinite,
	FpCategory::Zero => FullDecoded::Zero,
	FpCategory::Subnormal => {
	// neighbors: (mant - 2, exp) -- (mant, exp) -- (mant + 2, exp)
	// Float::integer_decode always preserves the exponent,
	// so the mantissa is scaled for subnormals.
	FullDecoded::Finite(Decoded { mant, minus: 1, plus: 1,
	exp, inclusive: even })
	}
	FpCategory::Normal => {
	let minnorm = <T as DecodableFloat>::min_pos_norm_value().integer_decode();
	if mant == minnorm.0 {
	// neighbors: (maxmant, exp - 1) -- (minnormmant, exp) -- (minnormmant + 1, exp)
	// where maxmant = minnormmant * 2 - 1
	FullDecoded::Finite(Decoded { mant: mant << 2, minus: 1, plus: 2,
	exp: exp - 2, inclusive: even })
	} else {
	// neighbors: (mant - 1, exp) -- (mant, exp) -- (mant + 1, exp)
	FullDecoded::Finite(Decoded { mant: mant << 1, minus: 1, plus: 1,
	exp: exp - 1, inclusive: even })
	}
	}
	};
	(sign < 0, decoded)
	}