aarch64/usr/lib/rustlib/src/rust/library/core/src/fmt/float.rs - manifest_repos/toolchain - Git at Google

 use crate::fmt::{Debug, Display, Formatter, LowerExp, Result, UpperExp};
 use crate::mem::MaybeUninit;
 use crate::num::flt2dec;
 use crate::num::fmt as numfmt;

 #[doc(hidden)]
 trait GeneralFormat: PartialOrd {
     /// Determines if a value should use exponential based on its magnitude, given the precondition
     /// that it will not be rounded any further before it is displayed.
     fn already_rounded_value_should_use_exponential(&self) -> bool;
 }

 macro_rules! impl_general_format {
     ($($t:ident)*) => {
         $(impl GeneralFormat for $t {
             fn already_rounded_value_should_use_exponential(&self) -> bool {
                 let abs = $t::abs_private(*self);
                 (abs != 0.0 && abs < 1e-4) || abs >= 1e+16
             }
         })*
     }
 }

 impl_general_format! { f32 f64 }

 // Don't inline this so callers don't use the stack space this function
 // requires unless they have to.
 #[inline(never)]
 fn float_to_decimal_common_exact<T>(
     fmt: &mut Formatter<'_>,
     num: &T,
     sign: flt2dec::Sign,
     precision: usize,
 ) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     let mut buf: [MaybeUninit<u8>; 1024] = MaybeUninit::uninit_array(); // enough for f32 and f64
     let mut parts: [MaybeUninit<numfmt::Part<'_>>; 4] = MaybeUninit::uninit_array();
     let formatted = flt2dec::to_exact_fixed_str(
         flt2dec::strategy::grisu::format_exact,
         *num,
         sign,
         precision,
         &mut buf,
         &mut parts,
     );
     fmt.pad_formatted_parts(&formatted)
 }

 // Don't inline this so callers that call both this and the above won't wind
 // up using the combined stack space of both functions in some cases.
 #[inline(never)]
 fn float_to_decimal_common_shortest<T>(
     fmt: &mut Formatter<'_>,
     num: &T,
     sign: flt2dec::Sign,
     precision: usize,
 ) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     // enough for f32 and f64
     let mut buf: [MaybeUninit<u8>; flt2dec::MAX_SIG_DIGITS] = MaybeUninit::uninit_array();
     let mut parts: [MaybeUninit<numfmt::Part<'_>>; 4] = MaybeUninit::uninit_array();
     let formatted = flt2dec::to_shortest_str(
         flt2dec::strategy::grisu::format_shortest,
         *num,
         sign,
         precision,
         &mut buf,
         &mut parts,
     );
     fmt.pad_formatted_parts(&formatted)
 }

 fn float_to_decimal_display<T>(fmt: &mut Formatter<'_>, num: &T) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     let force_sign = fmt.sign_plus();
     let sign = match force_sign {
         false => flt2dec::Sign::Minus,
         true => flt2dec::Sign::MinusPlus,
     };

     if let Some(precision) = fmt.precision {
         float_to_decimal_common_exact(fmt, num, sign, precision)
     } else {
         let min_precision = 0;
         float_to_decimal_common_shortest(fmt, num, sign, min_precision)
     }
 }

 // Don't inline this so callers don't use the stack space this function
 // requires unless they have to.
 #[inline(never)]
 fn float_to_exponential_common_exact<T>(
     fmt: &mut Formatter<'_>,
     num: &T,
     sign: flt2dec::Sign,
     precision: usize,
     upper: bool,
 ) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     let mut buf: [MaybeUninit<u8>; 1024] = MaybeUninit::uninit_array(); // enough for f32 and f64
     let mut parts: [MaybeUninit<numfmt::Part<'_>>; 6] = MaybeUninit::uninit_array();
     let formatted = flt2dec::to_exact_exp_str(
         flt2dec::strategy::grisu::format_exact,
         *num,
         sign,
         precision,
         upper,
         &mut buf,
         &mut parts,
     );
     fmt.pad_formatted_parts(&formatted)
 }

 // Don't inline this so callers that call both this and the above won't wind
 // up using the combined stack space of both functions in some cases.
 #[inline(never)]
 fn float_to_exponential_common_shortest<T>(
     fmt: &mut Formatter<'_>,
     num: &T,
     sign: flt2dec::Sign,
     upper: bool,
 ) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     // enough for f32 and f64
     let mut buf: [MaybeUninit<u8>; flt2dec::MAX_SIG_DIGITS] = MaybeUninit::uninit_array();
     let mut parts: [MaybeUninit<numfmt::Part<'_>>; 6] = MaybeUninit::uninit_array();
     let formatted = flt2dec::to_shortest_exp_str(
         flt2dec::strategy::grisu::format_shortest,
         *num,
         sign,
         (0, 0),
         upper,
         &mut buf,
         &mut parts,
     );
     fmt.pad_formatted_parts(&formatted)
 }

 // Common code of floating point LowerExp and UpperExp.
 fn float_to_exponential_common<T>(fmt: &mut Formatter<'_>, num: &T, upper: bool) -> Result
 where
     T: flt2dec::DecodableFloat,
 {
     let force_sign = fmt.sign_plus();
     let sign = match force_sign {
         false => flt2dec::Sign::Minus,
         true => flt2dec::Sign::MinusPlus,
     };

     if let Some(precision) = fmt.precision {
         // 1 integral digit + `precision` fractional digits = `precision + 1` total digits
         float_to_exponential_common_exact(fmt, num, sign, precision + 1, upper)
     } else {
         float_to_exponential_common_shortest(fmt, num, sign, upper)
     }
 }

 fn float_to_general_debug<T>(fmt: &mut Formatter<'_>, num: &T) -> Result
 where
     T: flt2dec::DecodableFloat + GeneralFormat,
 {
     let force_sign = fmt.sign_plus();
     let sign = match force_sign {
         false => flt2dec::Sign::Minus,
         true => flt2dec::Sign::MinusPlus,
     };

     if let Some(precision) = fmt.precision {
         // this behavior of {:.PREC?} predates exponential formatting for {:?}
         float_to_decimal_common_exact(fmt, num, sign, precision)
     } else {
         // since there is no precision, there will be no rounding
         if num.already_rounded_value_should_use_exponential() {
             let upper = false;
             float_to_exponential_common_shortest(fmt, num, sign, upper)
         } else {
             let min_precision = 1;
             float_to_decimal_common_shortest(fmt, num, sign, min_precision)
         }
     }
 }

 macro_rules! floating {
     ($ty:ident) => {
         #[stable(feature = "rust1", since = "1.0.0")]
         impl Debug for $ty {
             fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
                 float_to_general_debug(fmt, self)
             }
         }

         #[stable(feature = "rust1", since = "1.0.0")]
         impl Display for $ty {
             fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
                 float_to_decimal_display(fmt, self)
             }
         }

         #[stable(feature = "rust1", since = "1.0.0")]
         impl LowerExp for $ty {
             fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
                 float_to_exponential_common(fmt, self, false)
             }
         }

         #[stable(feature = "rust1", since = "1.0.0")]
         impl UpperExp for $ty {
             fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
                 float_to_exponential_common(fmt, self, true)
             }
         }
     };
 }

 floating! { f32 }
 floating! { f64 }
	use crate::fmt::{Debug, Display, Formatter, LowerExp, Result, UpperExp};
	use crate::mem::MaybeUninit;
	use crate::num::flt2dec;
	use crate::num::fmt as numfmt;

	#[doc(hidden)]
	trait GeneralFormat: PartialOrd {
	/// Determines if a value should use exponential based on its magnitude, given the precondition
	/// that it will not be rounded any further before it is displayed.
	fn already_rounded_value_should_use_exponential(&self) -> bool;
	}

	macro_rules! impl_general_format {
	($($t:ident)*) => {
	$(impl GeneralFormat for $t {
	fn already_rounded_value_should_use_exponential(&self) -> bool {
	let abs = $t::abs_private(*self);
	(abs != 0.0 && abs < 1e-4) \|\| abs >= 1e+16
	}
	})*
	}
	}

	impl_general_format! { f32 f64 }

	// Don't inline this so callers don't use the stack space this function
	// requires unless they have to.
	#[inline(never)]
	fn float_to_decimal_common_exact<T>(
	fmt: &mut Formatter<'_>,
	num: &T,
	sign: flt2dec::Sign,
	precision: usize,
	) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	let mut buf: [MaybeUninit<u8>; 1024] = MaybeUninit::uninit_array(); // enough for f32 and f64
	let mut parts: [MaybeUninit<numfmt::Part<'_>>; 4] = MaybeUninit::uninit_array();
	let formatted = flt2dec::to_exact_fixed_str(
	flt2dec::strategy::grisu::format_exact,
	*num,
	sign,
	precision,
	&mut buf,
	&mut parts,
	);
	fmt.pad_formatted_parts(&formatted)
	}

	// Don't inline this so callers that call both this and the above won't wind
	// up using the combined stack space of both functions in some cases.
	#[inline(never)]
	fn float_to_decimal_common_shortest<T>(
	fmt: &mut Formatter<'_>,
	num: &T,
	sign: flt2dec::Sign,
	precision: usize,
	) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	// enough for f32 and f64
	let mut buf: [MaybeUninit<u8>; flt2dec::MAX_SIG_DIGITS] = MaybeUninit::uninit_array();
	let mut parts: [MaybeUninit<numfmt::Part<'_>>; 4] = MaybeUninit::uninit_array();
	let formatted = flt2dec::to_shortest_str(
	flt2dec::strategy::grisu::format_shortest,
	*num,
	sign,
	precision,
	&mut buf,
	&mut parts,
	);
	fmt.pad_formatted_parts(&formatted)
	}

	fn float_to_decimal_display<T>(fmt: &mut Formatter<'_>, num: &T) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	let force_sign = fmt.sign_plus();
	let sign = match force_sign {
	false => flt2dec::Sign::Minus,
	true => flt2dec::Sign::MinusPlus,
	};

	if let Some(precision) = fmt.precision {
	float_to_decimal_common_exact(fmt, num, sign, precision)
	} else {
	let min_precision = 0;
	float_to_decimal_common_shortest(fmt, num, sign, min_precision)
	}
	}

	// Don't inline this so callers don't use the stack space this function
	// requires unless they have to.
	#[inline(never)]
	fn float_to_exponential_common_exact<T>(
	fmt: &mut Formatter<'_>,
	num: &T,
	sign: flt2dec::Sign,
	precision: usize,
	upper: bool,
	) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	let mut buf: [MaybeUninit<u8>; 1024] = MaybeUninit::uninit_array(); // enough for f32 and f64
	let mut parts: [MaybeUninit<numfmt::Part<'_>>; 6] = MaybeUninit::uninit_array();
	let formatted = flt2dec::to_exact_exp_str(
	flt2dec::strategy::grisu::format_exact,
	*num,
	sign,
	precision,
	upper,
	&mut buf,
	&mut parts,
	);
	fmt.pad_formatted_parts(&formatted)
	}

	// Don't inline this so callers that call both this and the above won't wind
	// up using the combined stack space of both functions in some cases.
	#[inline(never)]
	fn float_to_exponential_common_shortest<T>(
	fmt: &mut Formatter<'_>,
	num: &T,
	sign: flt2dec::Sign,
	upper: bool,
	) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	// enough for f32 and f64
	let mut buf: [MaybeUninit<u8>; flt2dec::MAX_SIG_DIGITS] = MaybeUninit::uninit_array();
	let mut parts: [MaybeUninit<numfmt::Part<'_>>; 6] = MaybeUninit::uninit_array();
	let formatted = flt2dec::to_shortest_exp_str(
	flt2dec::strategy::grisu::format_shortest,
	*num,
	sign,
	(0, 0),
	upper,
	&mut buf,
	&mut parts,
	);
	fmt.pad_formatted_parts(&formatted)
	}

	// Common code of floating point LowerExp and UpperExp.
	fn float_to_exponential_common<T>(fmt: &mut Formatter<'_>, num: &T, upper: bool) -> Result
	where
	T: flt2dec::DecodableFloat,
	{
	let force_sign = fmt.sign_plus();
	let sign = match force_sign {
	false => flt2dec::Sign::Minus,
	true => flt2dec::Sign::MinusPlus,
	};

	if let Some(precision) = fmt.precision {
	// 1 integral digit + `precision` fractional digits = `precision + 1` total digits
	float_to_exponential_common_exact(fmt, num, sign, precision + 1, upper)
	} else {
	float_to_exponential_common_shortest(fmt, num, sign, upper)
	}
	}

	fn float_to_general_debug<T>(fmt: &mut Formatter<'_>, num: &T) -> Result
	where
	T: flt2dec::DecodableFloat + GeneralFormat,
	{
	let force_sign = fmt.sign_plus();
	let sign = match force_sign {
	false => flt2dec::Sign::Minus,
	true => flt2dec::Sign::MinusPlus,
	};

	if let Some(precision) = fmt.precision {
	// this behavior of {:.PREC?} predates exponential formatting for {:?}
	float_to_decimal_common_exact(fmt, num, sign, precision)
	} else {
	// since there is no precision, there will be no rounding
	if num.already_rounded_value_should_use_exponential() {
	let upper = false;
	float_to_exponential_common_shortest(fmt, num, sign, upper)
	} else {
	let min_precision = 1;
	float_to_decimal_common_shortest(fmt, num, sign, min_precision)
	}
	}
	}

	macro_rules! floating {
	($ty:ident) => {
	#[stable(feature = "rust1", since = "1.0.0")]
	impl Debug for $ty {
	fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
	float_to_general_debug(fmt, self)
	}
	}

	#[stable(feature = "rust1", since = "1.0.0")]
	impl Display for $ty {
	fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
	float_to_decimal_display(fmt, self)
	}
	}

	#[stable(feature = "rust1", since = "1.0.0")]
	impl LowerExp for $ty {
	fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
	float_to_exponential_common(fmt, self, false)
	}
	}

	#[stable(feature = "rust1", since = "1.0.0")]
	impl UpperExp for $ty {
	fn fmt(&self, fmt: &mut Formatter<'_>) -> Result {
	float_to_exponential_common(fmt, self, true)
	}
	}
	};
	}

	floating! { f32 }
	floating! { f64 }