x86_64/usr/lib/rustlib/src/rust/library/core/src/num/dec2flt/lemire.rs - manifest_repos/toolchain - Git at Google

 //! Implementation of the Eisel-Lemire algorithm.

 use crate::num::dec2flt::common::BiasedFp;
 use crate::num::dec2flt::float::RawFloat;
 use crate::num::dec2flt::table::{
     LARGEST_POWER_OF_FIVE, POWER_OF_FIVE_128, SMALLEST_POWER_OF_FIVE,
 };

 /// Compute w * 10^q using an extended-precision float representation.
 ///
 /// Fast conversion of a the significant digits and decimal exponent
 /// a float to an extended representation with a binary float. This
 /// algorithm will accurately parse the vast majority of cases,
 /// and uses a 128-bit representation (with a fallback 192-bit
 /// representation).
 ///
 /// This algorithm scales the exponent by the decimal exponent
 /// using pre-computed powers-of-5, and calculates if the
 /// representation can be unambiguously rounded to the nearest
 /// machine float. Near-halfway cases are not handled here,
 /// and are represented by a negative, biased binary exponent.
 ///
 /// The algorithm is described in detail in "Daniel Lemire, Number Parsing
 /// at a Gigabyte per Second" in section 5, "Fast Algorithm", and
 /// section 6, "Exact Numbers And Ties", available online:
 /// <https://arxiv.org/abs/2101.11408.pdf>.
 pub fn compute_float<F: RawFloat>(q: i64, mut w: u64) -> BiasedFp {
     let fp_zero = BiasedFp::zero_pow2(0);
     let fp_inf = BiasedFp::zero_pow2(F::INFINITE_POWER);
     let fp_error = BiasedFp::zero_pow2(-1);

     // Short-circuit if the value can only be a literal 0 or infinity.
     if w == 0 || q < F::SMALLEST_POWER_OF_TEN as i64 {
         return fp_zero;
     } else if q > F::LARGEST_POWER_OF_TEN as i64 {
         return fp_inf;
     }
     // Normalize our significant digits, so the most-significant bit is set.
     let lz = w.leading_zeros();
     w <<= lz;
     let (lo, hi) = compute_product_approx(q, w, F::MANTISSA_EXPLICIT_BITS + 3);
     if lo == 0xFFFF_FFFF_FFFF_FFFF {
         // If we have failed to approximate w x 5^-q with our 128-bit value.
         // Since the addition of 1 could lead to an overflow which could then
         // round up over the half-way point, this can lead to improper rounding
         // of a float.
         //
         // However, this can only occur if q ∈ [-27, 55]. The upper bound of q
         // is 55 because 5^55 < 2^128, however, this can only happen if 5^q > 2^64,
         // since otherwise the product can be represented in 64-bits, producing
         // an exact result. For negative exponents, rounding-to-even can
         // only occur if 5^-q < 2^64.
         //
         // For detailed explanations of rounding for negative exponents, see
         // <https://arxiv.org/pdf/2101.11408.pdf#section.9.1>. For detailed
         // explanations of rounding for positive exponents, see
         // <https://arxiv.org/pdf/2101.11408.pdf#section.8>.
         let inside_safe_exponent = (q >= -27) && (q <= 55);
         if !inside_safe_exponent {
             return fp_error;
         }
     }
     let upperbit = (hi >> 63) as i32;
     let mut mantissa = hi >> (upperbit + 64 - F::MANTISSA_EXPLICIT_BITS as i32 - 3);
     let mut power2 = power(q as i32) + upperbit - lz as i32 - F::MINIMUM_EXPONENT;
     if power2 <= 0 {
         if -power2 + 1 >= 64 {
             // Have more than 64 bits below the minimum exponent, must be 0.
             return fp_zero;
         }
         // Have a subnormal value.
         mantissa >>= -power2 + 1;
         mantissa += mantissa & 1;
         mantissa >>= 1;
         power2 = (mantissa >= (1_u64 << F::MANTISSA_EXPLICIT_BITS)) as i32;
         return BiasedFp { f: mantissa, e: power2 };
     }
     // Need to handle rounding ties. Normally, we need to round up,
     // but if we fall right in between and we have an even basis, we
     // need to round down.
     //
     // This will only occur if:
     //  1. The lower 64 bits of the 128-bit representation is 0.
     //      IE, 5^q fits in single 64-bit word.
     //  2. The least-significant bit prior to truncated mantissa is odd.
     //  3. All the bits truncated when shifting to mantissa bits + 1 are 0.
     //
     // Or, we may fall between two floats: we are exactly halfway.
     if lo <= 1
         && q >= F::MIN_EXPONENT_ROUND_TO_EVEN as i64
         && q <= F::MAX_EXPONENT_ROUND_TO_EVEN as i64
         && mantissa & 3 == 1
         && (mantissa << (upperbit + 64 - F::MANTISSA_EXPLICIT_BITS as i32 - 3)) == hi
     {
         // Zero the lowest bit, so we don't round up.
         mantissa &= !1_u64;
     }
     // Round-to-even, then shift the significant digits into place.
     mantissa += mantissa & 1;
     mantissa >>= 1;
     if mantissa >= (2_u64 << F::MANTISSA_EXPLICIT_BITS) {
         // Rounding up overflowed, so the carry bit is set. Set the
         // mantissa to 1 (only the implicit, hidden bit is set) and
         // increase the exponent.
         mantissa = 1_u64 << F::MANTISSA_EXPLICIT_BITS;
         power2 += 1;
     }
     // Zero out the hidden bit.
     mantissa &= !(1_u64 << F::MANTISSA_EXPLICIT_BITS);
     if power2 >= F::INFINITE_POWER {
         // Exponent is above largest normal value, must be infinite.
         return fp_inf;
     }
     BiasedFp { f: mantissa, e: power2 }
 }

 /// Calculate a base 2 exponent from a decimal exponent.
 /// This uses a pre-computed integer approximation for
 /// log2(10), where 217706 / 2^16 is accurate for the
 /// entire range of non-finite decimal exponents.
 fn power(q: i32) -> i32 {
     (q.wrapping_mul(152_170 + 65536) >> 16) + 63
 }

 fn full_multiplication(a: u64, b: u64) -> (u64, u64) {
     let r = (a as u128) * (b as u128);
     (r as u64, (r >> 64) as u64)
 }

 // This will compute or rather approximate w * 5**q and return a pair of 64-bit words
 // approximating the result, with the "high" part corresponding to the most significant
 // bits and the low part corresponding to the least significant bits.
 fn compute_product_approx(q: i64, w: u64, precision: usize) -> (u64, u64) {
     debug_assert!(q >= SMALLEST_POWER_OF_FIVE as i64);
     debug_assert!(q <= LARGEST_POWER_OF_FIVE as i64);
     debug_assert!(precision <= 64);

     let mask = if precision < 64 {
         0xFFFF_FFFF_FFFF_FFFF_u64 >> precision
     } else {
         0xFFFF_FFFF_FFFF_FFFF_u64
     };

     // 5^q < 2^64, then the multiplication always provides an exact value.
     // That means whenever we need to round ties to even, we always have
     // an exact value.
     let index = (q - SMALLEST_POWER_OF_FIVE as i64) as usize;
     let (lo5, hi5) = POWER_OF_FIVE_128[index];
     // Only need one multiplication as long as there is 1 zero but
     // in the explicit mantissa bits, +1 for the hidden bit, +1 to
     // determine the rounding direction, +1 for if the computed
     // product has a leading zero.
     let (mut first_lo, mut first_hi) = full_multiplication(w, lo5);
     if first_hi & mask == mask {
         // Need to do a second multiplication to get better precision
         // for the lower product. This will always be exact
         // where q is < 55, since 5^55 < 2^128. If this wraps,
         // then we need to need to round up the hi product.
         let (_, second_hi) = full_multiplication(w, hi5);
         first_lo = first_lo.wrapping_add(second_hi);
         if second_hi > first_lo {
             first_hi += 1;
         }
     }
     (first_lo, first_hi)
 }
	//! Implementation of the Eisel-Lemire algorithm.

	use crate::num::dec2flt::common::BiasedFp;
	use crate::num::dec2flt::float::RawFloat;
	use crate::num::dec2flt::table::{
	LARGEST_POWER_OF_FIVE, POWER_OF_FIVE_128, SMALLEST_POWER_OF_FIVE,
	};

	/// Compute w * 10^q using an extended-precision float representation.
	///
	/// Fast conversion of a the significant digits and decimal exponent
	/// a float to an extended representation with a binary float. This
	/// algorithm will accurately parse the vast majority of cases,
	/// and uses a 128-bit representation (with a fallback 192-bit
	/// representation).
	///
	/// This algorithm scales the exponent by the decimal exponent
	/// using pre-computed powers-of-5, and calculates if the
	/// representation can be unambiguously rounded to the nearest
	/// machine float. Near-halfway cases are not handled here,
	/// and are represented by a negative, biased binary exponent.
	///
	/// The algorithm is described in detail in "Daniel Lemire, Number Parsing
	/// at a Gigabyte per Second" in section 5, "Fast Algorithm", and
	/// section 6, "Exact Numbers And Ties", available online:
	/// <https://arxiv.org/abs/2101.11408.pdf>.
	pub fn compute_float<F: RawFloat>(q: i64, mut w: u64) -> BiasedFp {
	let fp_zero = BiasedFp::zero_pow2(0);
	let fp_inf = BiasedFp::zero_pow2(F::INFINITE_POWER);
	let fp_error = BiasedFp::zero_pow2(-1);

	// Short-circuit if the value can only be a literal 0 or infinity.
	if w == 0 \|\| q < F::SMALLEST_POWER_OF_TEN as i64 {
	return fp_zero;
	} else if q > F::LARGEST_POWER_OF_TEN as i64 {
	return fp_inf;
	}
	// Normalize our significant digits, so the most-significant bit is set.
	let lz = w.leading_zeros();
	w <<= lz;
	let (lo, hi) = compute_product_approx(q, w, F::MANTISSA_EXPLICIT_BITS + 3);
	if lo == 0xFFFF_FFFF_FFFF_FFFF {
	// If we have failed to approximate w x 5^-q with our 128-bit value.
	// Since the addition of 1 could lead to an overflow which could then
	// round up over the half-way point, this can lead to improper rounding
	// of a float.
	//
	// However, this can only occur if q ∈ [-27, 55]. The upper bound of q
	// is 55 because 5^55 < 2^128, however, this can only happen if 5^q > 2^64,
	// since otherwise the product can be represented in 64-bits, producing
	// an exact result. For negative exponents, rounding-to-even can
	// only occur if 5^-q < 2^64.
	//
	// For detailed explanations of rounding for negative exponents, see
	// <https://arxiv.org/pdf/2101.11408.pdf#section.9.1>. For detailed
	// explanations of rounding for positive exponents, see
	// <https://arxiv.org/pdf/2101.11408.pdf#section.8>.
	let inside_safe_exponent = (q >= -27) && (q <= 55);
	if !inside_safe_exponent {
	return fp_error;
	}
	}
	let upperbit = (hi >> 63) as i32;
	let mut mantissa = hi >> (upperbit + 64 - F::MANTISSA_EXPLICIT_BITS as i32 - 3);
	let mut power2 = power(q as i32) + upperbit - lz as i32 - F::MINIMUM_EXPONENT;
	if power2 <= 0 {
	if -power2 + 1 >= 64 {
	// Have more than 64 bits below the minimum exponent, must be 0.
	return fp_zero;
	}
	// Have a subnormal value.
	mantissa >>= -power2 + 1;
	mantissa += mantissa & 1;
	mantissa >>= 1;
	power2 = (mantissa >= (1_u64 << F::MANTISSA_EXPLICIT_BITS)) as i32;
	return BiasedFp { f: mantissa, e: power2 };
	}
	// Need to handle rounding ties. Normally, we need to round up,
	// but if we fall right in between and we have an even basis, we
	// need to round down.
	//
	// This will only occur if:
	// 1. The lower 64 bits of the 128-bit representation is 0.
	// IE, 5^q fits in single 64-bit word.
	// 2. The least-significant bit prior to truncated mantissa is odd.
	// 3. All the bits truncated when shifting to mantissa bits + 1 are 0.
	//
	// Or, we may fall between two floats: we are exactly halfway.
	if lo <= 1
	&& q >= F::MIN_EXPONENT_ROUND_TO_EVEN as i64
	&& q <= F::MAX_EXPONENT_ROUND_TO_EVEN as i64
	&& mantissa & 3 == 1
	&& (mantissa << (upperbit + 64 - F::MANTISSA_EXPLICIT_BITS as i32 - 3)) == hi
	{
	// Zero the lowest bit, so we don't round up.
	mantissa &= !1_u64;
	}
	// Round-to-even, then shift the significant digits into place.
	mantissa += mantissa & 1;
	mantissa >>= 1;
	if mantissa >= (2_u64 << F::MANTISSA_EXPLICIT_BITS) {
	// Rounding up overflowed, so the carry bit is set. Set the
	// mantissa to 1 (only the implicit, hidden bit is set) and
	// increase the exponent.
	mantissa = 1_u64 << F::MANTISSA_EXPLICIT_BITS;
	power2 += 1;
	}
	// Zero out the hidden bit.
	mantissa &= !(1_u64 << F::MANTISSA_EXPLICIT_BITS);
	if power2 >= F::INFINITE_POWER {
	// Exponent is above largest normal value, must be infinite.
	return fp_inf;
	}
	BiasedFp { f: mantissa, e: power2 }
	}

	/// Calculate a base 2 exponent from a decimal exponent.
	/// This uses a pre-computed integer approximation for
	/// log2(10), where 217706 / 2^16 is accurate for the
	/// entire range of non-finite decimal exponents.
	fn power(q: i32) -> i32 {
	(q.wrapping_mul(152_170 + 65536) >> 16) + 63
	}

	fn full_multiplication(a: u64, b: u64) -> (u64, u64) {
	let r = (a as u128) * (b as u128);
	(r as u64, (r >> 64) as u64)
	}

	// This will compute or rather approximate w * 5**q and return a pair of 64-bit words
	// approximating the result, with the "high" part corresponding to the most significant
	// bits and the low part corresponding to the least significant bits.
	fn compute_product_approx(q: i64, w: u64, precision: usize) -> (u64, u64) {
	debug_assert!(q >= SMALLEST_POWER_OF_FIVE as i64);
	debug_assert!(q <= LARGEST_POWER_OF_FIVE as i64);
	debug_assert!(precision <= 64);

	let mask = if precision < 64 {
	0xFFFF_FFFF_FFFF_FFFF_u64 >> precision
	} else {
	0xFFFF_FFFF_FFFF_FFFF_u64
	};

	// 5^q < 2^64, then the multiplication always provides an exact value.
	// That means whenever we need to round ties to even, we always have
	// an exact value.
	let index = (q - SMALLEST_POWER_OF_FIVE as i64) as usize;
	let (lo5, hi5) = POWER_OF_FIVE_128[index];
	// Only need one multiplication as long as there is 1 zero but
	// in the explicit mantissa bits, +1 for the hidden bit, +1 to
	// determine the rounding direction, +1 for if the computed
	// product has a leading zero.
	let (mut first_lo, mut first_hi) = full_multiplication(w, lo5);
	if first_hi & mask == mask {
	// Need to do a second multiplication to get better precision
	// for the lower product. This will always be exact
	// where q is < 55, since 5^55 < 2^128. If this wraps,
	// then we need to need to round up the hi product.
	let (_, second_hi) = full_multiplication(w, hi5);
	first_lo = first_lo.wrapping_add(second_hi);
	if second_hi > first_lo {
	first_hi += 1;
	}
	}
	(first_lo, first_hi)
	}