libstdc++-v3/src/c++17/uint128_t.h - gcc - Git at Google

 // A relatively minimal unsigned 128-bit integer class type, used by the
 // floating-point std::to_chars implementation on targets that lack __int128.

 // Copyright (C) 2021-2022 Free Software Foundation, Inc.
 //
 // This file is part of the GNU ISO C++ Library.  This library is free
 // software; you can redistribute it and/or modify it under the
 // terms of the GNU General Public License as published by the
 // Free Software Foundation; either version 3, or (at your option)
 // any later version.

 // This library is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.

 // Under Section 7 of GPL version 3, you are granted additional
 // permissions described in the GCC Runtime Library Exception, version
 // 3.1, as published by the Free Software Foundation.

 // You should have received a copy of the GNU General Public License and
 // a copy of the GCC Runtime Library Exception along with this program;
 // see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
 // <http://www.gnu.org/licenses/>.

 struct uint128_t
 {
 #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
   uint64_t lo, hi;
 #else
   uint64_t hi, lo;
 #endif

   uint128_t() = default;

   constexpr
   uint128_t(uint64_t lo, uint64_t hi = 0)
 #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
     : lo(lo), hi(hi)
 #else
     : hi(hi), lo(lo)
 #endif
   { }

   constexpr explicit
   operator bool() const
   { return *this != 0; }

   template<typename T, typename = std::enable_if_t<std::is_integral_v<T>>>
     constexpr explicit
     operator T() const
     {
       static_assert(sizeof(T) <= sizeof(uint64_t));
       return static_cast<T>(lo);
     }

   friend constexpr uint128_t
   operator&(uint128_t x, const uint128_t y)
   {
     x.lo &= y.lo;
     x.hi &= y.hi;
     return x;
   }

   friend constexpr uint128_t
   operator|(uint128_t x, const uint128_t y)
   {
     x.lo |= y.lo;
     x.hi |= y.hi;
     return x;
   }

   friend constexpr uint128_t
   operator<<(uint128_t x, const uint128_t y)
   {
     __glibcxx_assert(y < 128);
     // TODO: Convince GCC to use shldq on x86 here.
     if (y.lo >= 64)
       {
 	x.hi = x.lo << (y.lo - 64);
 	x.lo = 0;
       }
     else if (y.lo != 0)
       {
 	x.hi <<= y.lo;
 	x.hi |= x.lo >> (64 - y.lo);
 	x.lo <<= y.lo;
       }
     return x;
   }

   friend constexpr uint128_t
   operator>>(uint128_t x, const uint128_t y)
   {
     __glibcxx_assert(y < 128);
     // TODO: Convince GCC to use shrdq on x86 here.
     if (y.lo >= 64)
       {
 	x.lo = x.hi >> (y.lo - 64);
 	x.hi = 0;
       }
     else if (y.lo != 0)
       {
 	x.lo >>= y.lo;
 	x.lo |= x.hi << (64 - y.lo);
 	x.hi >>= y.lo;
       }
     return x;
   }

   constexpr uint128_t
   operator~() const
   { return {~lo, ~hi}; }

   constexpr uint128_t
   operator-() const
   { return operator~() + 1; }

   friend constexpr uint128_t
   operator+(uint128_t x, const uint128_t y)
   {
     x.hi += __builtin_add_overflow(x.lo, y.lo, &x.lo);
     x.hi += y.hi;
     return x;
   }

   friend constexpr uint128_t
   operator-(uint128_t x, const uint128_t y)
   {
     x.hi -= __builtin_sub_overflow(x.lo, y.lo, &x.lo);
     x.hi -= y.hi;
     return x;
   }

   static constexpr uint128_t
   umul64_64_128(const uint64_t x, const uint64_t y)
   {
     const uint64_t xl = x & 0xffffffff;
     const uint64_t xh = x >> 32;
     const uint64_t yl = y & 0xffffffff;
     const uint64_t yh = y >> 32;
     const uint64_t ll = xl * yl;
     const uint64_t lh = xl * yh;
     const uint64_t hl = xh * yl;
     const uint64_t hh = xh * yh;
     const uint64_t m = (ll >> 32) + lh + (hl & 0xffffffff);
     const uint64_t l = (ll & 0xffffffff ) | (m << 32);
     const uint64_t h = (m >> 32) + (hl >> 32) + hh;
     return {l, h};
   }

   friend constexpr uint128_t
   operator*(const uint128_t x, const uint128_t y)
   {
     uint128_t z = umul64_64_128(x.lo, y.lo);
     z.hi += x.lo * y.hi + x.hi * y.lo;
     return z;
   }

   friend constexpr uint128_t
   operator/(const uint128_t x, const uint128_t y)
   {
     // Ryu performs 128-bit division only by 5 and 10, so that's what we
     // implement.  The strategy here is to relate division of x with that of
     // x.hi and x.lo separately.
     __glibcxx_assert(y == 5 || y == 10);
     // The following implements division by 5 and 10.  In either case, we
     // first compute division by 5:
     //   x/5 = (x.hi*2^64 + x.lo)/5
     //       = (x.hi*(2^64-1) + x.hi + x.lo)/5
     //       = x.hi*((2^64-1)/5) + (x.hi + x.lo)/5 since CST=(2^64-1)/5 is exact
     //       = x.hi*CST + x.hi/5 + x.lo/5 + ((x.lo%5) + (x.hi%5) >= 5)
     // We go a step further and replace the last adjustment term with a
     // lookup table, which we encode as a binary literal.  This seems to
     // yield smaller code on x86 at least.
     constexpr auto cst = ~uint64_t(0) / 5;
     uint128_t q = uint128_t{x.hi}*cst + uint128_t{x.hi/5 + x.lo/5};
     constexpr auto lookup = 0b111100000u;
     q += (lookup >> ((x.hi % 5) + (x.lo % 5))) & 1;
     if (y == 10)
       q >>= 1;
     return q;
   }

   friend constexpr uint128_t
   operator%(const uint128_t x, const uint128_t y)
   {
     // Ryu performs 128-bit modulus only by 2, 5 and 10, so that's what we
     // implement.  The strategy here is to relate modulus of x with that of
     // x.hi and x.lo separately.
     if (y == 2)
       return x & 1;
     __glibcxx_assert(y == 5 || y == 10);
     // The following implements modulus by 5 and 10.  In either case,
     // we first compute modulus by 5:
     //   x (mod 5) = x.hi*2^64 + x.lo (mod 5)
     //             = x.hi + x.lo (mod 5) since 2^64 ≡ 1 (mod 5)
     // So the straightforward implementation would be
     //   ((x.hi % 5) + (x.lo % 5)) % 5
     // But we go a step further and replace the outermost % with a
     // lookup table:
     //             = {0,1,2,3,4,0,1,2,3}[(x.hi % 5) + (x.lo % 5)] (mod 5)
     // which we encode as an octal literal.
     constexpr auto lookup = 0321043210u;
     auto r = (lookup >> 3*((x.hi % 5) + (x.lo % 5))) & 7;
     if (y == 10)
       // x % 10 = (x % 5)      if x / 5 is even
       //          (x % 5) + 5  if x / 5 is odd
       // The compiler should be able to CSE the below computation of x/5 and
       // the above modulus operations with a nearby inlined computation of x/10.
       r += 5 * ((x/5).lo & 1);
     return r;
   }

   friend constexpr bool
   operator==(const uint128_t x, const uint128_t y)
   { return x.hi == y.hi && x.lo == y.lo; }

   friend constexpr bool
   operator<(const uint128_t x, const uint128_t y)
   { return x.hi < y.hi || (x.hi == y.hi && x.lo < y.lo); }

   friend constexpr auto
   __bit_width(const uint128_t x)
   {
     if (auto w = std::__bit_width(x.hi))
       return w + 64;
     else
       return std::__bit_width(x.lo);
   }

   friend constexpr auto
   __countr_zero(const uint128_t x)
   {
     auto c = std::__countr_zero(x.lo);
     if (c == 64)
       return 64 + std::__countr_zero(x.hi);
     else
       return c;
   }

   constexpr uint128_t&
   operator--()
   { return *this -= 1; }

   constexpr uint128_t&
   operator++()
   { return *this += 1; }

   constexpr uint128_t&
   operator+=(const uint128_t y)
   { return *this = *this + y; }

   constexpr uint128_t&
   operator-=(const uint128_t y)
   { return *this = *this - y; }

   constexpr uint128_t&
   operator*=(const uint128_t y)
   { return *this = *this * y; }

   constexpr uint128_t&
   operator<<=(const uint128_t y)
   { return *this = *this << y; }

   constexpr uint128_t&
   operator>>=(const uint128_t y)
   { return *this = *this >> y; }

   constexpr uint128_t&
   operator|=(const uint128_t y)
   { return *this = *this | y; }

   constexpr uint128_t&
   operator&=(const uint128_t y)
   { return *this = *this & y; }

   constexpr uint128_t&
   operator%=(const uint128_t y)
   { return *this = *this % y; }

   constexpr uint128_t&
   operator/=(const uint128_t y)
   { return *this = *this / y; }

   friend constexpr bool
   operator!=(const uint128_t x, const uint128_t y)
   { return !(x == y); }

   friend constexpr bool
   operator>(const uint128_t x, const uint128_t y)
   { return y < x; }

   friend constexpr bool
   operator>=(const uint128_t x, const uint128_t y)
   { return !(x < y); }
 };
	// A relatively minimal unsigned 128-bit integer class type, used by the
	// floating-point std::to_chars implementation on targets that lack __int128.

	// Copyright (C) 2021-2022 Free Software Foundation, Inc.
	//
	// This file is part of the GNU ISO C++ Library. This library is free
	// software; you can redistribute it and/or modify it under the
	// terms of the GNU General Public License as published by the
	// Free Software Foundation; either version 3, or (at your option)
	// any later version.

	// This library is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.

	// Under Section 7 of GPL version 3, you are granted additional
	// permissions described in the GCC Runtime Library Exception, version
	// 3.1, as published by the Free Software Foundation.

	// You should have received a copy of the GNU General Public License and
	// a copy of the GCC Runtime Library Exception along with this program;
	// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
	// <http://www.gnu.org/licenses/>.

	struct uint128_t
	{
	#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
	uint64_t lo, hi;
	#else
	uint64_t hi, lo;
	#endif

	uint128_t() = default;

	constexpr
	uint128_t(uint64_t lo, uint64_t hi = 0)
	#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
	: lo(lo), hi(hi)
	#else
	: hi(hi), lo(lo)
	#endif
	{ }

	constexpr explicit
	operator bool() const
	{ return *this != 0; }

	template<typename T, typename = std::enable_if_t<std::is_integral_v<T>>>
	constexpr explicit
	operator T() const
	{
	static_assert(sizeof(T) <= sizeof(uint64_t));
	return static_cast<T>(lo);
	}

	friend constexpr uint128_t
	operator&(uint128_t x, const uint128_t y)
	{
	x.lo &= y.lo;
	x.hi &= y.hi;
	return x;
	}

	friend constexpr uint128_t
	operator\|(uint128_t x, const uint128_t y)
	{
	x.lo \|= y.lo;
	x.hi \|= y.hi;
	return x;
	}

	friend constexpr uint128_t
	operator<<(uint128_t x, const uint128_t y)
	{
	__glibcxx_assert(y < 128);
	// TODO: Convince GCC to use shldq on x86 here.
	if (y.lo >= 64)
	{
	x.hi = x.lo << (y.lo - 64);
	x.lo = 0;
	}
	else if (y.lo != 0)
	{
	x.hi <<= y.lo;
	x.hi \|= x.lo >> (64 - y.lo);
	x.lo <<= y.lo;
	}
	return x;
	}

	friend constexpr uint128_t
	operator>>(uint128_t x, const uint128_t y)
	{
	__glibcxx_assert(y < 128);
	// TODO: Convince GCC to use shrdq on x86 here.
	if (y.lo >= 64)
	{
	x.lo = x.hi >> (y.lo - 64);
	x.hi = 0;
	}
	else if (y.lo != 0)
	{
	x.lo >>= y.lo;
	x.lo \|= x.hi << (64 - y.lo);
	x.hi >>= y.lo;
	}
	return x;
	}

	constexpr uint128_t
	operator~() const
	{ return {~lo, ~hi}; }

	constexpr uint128_t
	operator-() const
	{ return operator~() + 1; }

	friend constexpr uint128_t
	operator+(uint128_t x, const uint128_t y)
	{
	x.hi += __builtin_add_overflow(x.lo, y.lo, &x.lo);
	x.hi += y.hi;
	return x;
	}

	friend constexpr uint128_t
	operator-(uint128_t x, const uint128_t y)
	{
	x.hi -= __builtin_sub_overflow(x.lo, y.lo, &x.lo);
	x.hi -= y.hi;
	return x;
	}

	static constexpr uint128_t
	umul64_64_128(const uint64_t x, const uint64_t y)
	{
	const uint64_t xl = x & 0xffffffff;
	const uint64_t xh = x >> 32;
	const uint64_t yl = y & 0xffffffff;
	const uint64_t yh = y >> 32;
	const uint64_t ll = xl * yl;
	const uint64_t lh = xl * yh;
	const uint64_t hl = xh * yl;
	const uint64_t hh = xh * yh;
	const uint64_t m = (ll >> 32) + lh + (hl & 0xffffffff);
	const uint64_t l = (ll & 0xffffffff ) \| (m << 32);
	const uint64_t h = (m >> 32) + (hl >> 32) + hh;
	return {l, h};
	}

	friend constexpr uint128_t
	operator*(const uint128_t x, const uint128_t y)
	{
	uint128_t z = umul64_64_128(x.lo, y.lo);
	z.hi += x.lo * y.hi + x.hi * y.lo;
	return z;
	}

	friend constexpr uint128_t
	operator/(const uint128_t x, const uint128_t y)
	{
	// Ryu performs 128-bit division only by 5 and 10, so that's what we
	// implement. The strategy here is to relate division of x with that of
	// x.hi and x.lo separately.
	__glibcxx_assert(y == 5 \|\| y == 10);
	// The following implements division by 5 and 10. In either case, we
	// first compute division by 5:
	// x/5 = (x.hi*2^64 + x.lo)/5
	// = (x.hi*(2^64-1) + x.hi + x.lo)/5
	// = x.hi*((2^64-1)/5) + (x.hi + x.lo)/5 since CST=(2^64-1)/5 is exact
	// = x.hi*CST + x.hi/5 + x.lo/5 + ((x.lo%5) + (x.hi%5) >= 5)
	// We go a step further and replace the last adjustment term with a
	// lookup table, which we encode as a binary literal. This seems to
	// yield smaller code on x86 at least.
	constexpr auto cst = ~uint64_t(0) / 5;
	uint128_t q = uint128_t{x.hi}*cst + uint128_t{x.hi/5 + x.lo/5};
	constexpr auto lookup = 0b111100000u;
	q += (lookup >> ((x.hi % 5) + (x.lo % 5))) & 1;
	if (y == 10)
	q >>= 1;
	return q;
	}

	friend constexpr uint128_t
	operator%(const uint128_t x, const uint128_t y)
	{
	// Ryu performs 128-bit modulus only by 2, 5 and 10, so that's what we
	// implement. The strategy here is to relate modulus of x with that of
	// x.hi and x.lo separately.
	if (y == 2)
	return x & 1;
	__glibcxx_assert(y == 5 \|\| y == 10);
	// The following implements modulus by 5 and 10. In either case,
	// we first compute modulus by 5:
	// x (mod 5) = x.hi*2^64 + x.lo (mod 5)
	// = x.hi + x.lo (mod 5) since 2^64 ≡ 1 (mod 5)
	// So the straightforward implementation would be
	// ((x.hi % 5) + (x.lo % 5)) % 5
	// But we go a step further and replace the outermost % with a
	// lookup table:
	// = {0,1,2,3,4,0,1,2,3}[(x.hi % 5) + (x.lo % 5)] (mod 5)
	// which we encode as an octal literal.
	constexpr auto lookup = 0321043210u;
	auto r = (lookup >> 3*((x.hi % 5) + (x.lo % 5))) & 7;
	if (y == 10)
	// x % 10 = (x % 5) if x / 5 is even
	// (x % 5) + 5 if x / 5 is odd
	// The compiler should be able to CSE the below computation of x/5 and
	// the above modulus operations with a nearby inlined computation of x/10.
	r += 5 * ((x/5).lo & 1);
	return r;
	}

	friend constexpr bool
	operator==(const uint128_t x, const uint128_t y)
	{ return x.hi == y.hi && x.lo == y.lo; }

	friend constexpr bool
	operator<(const uint128_t x, const uint128_t y)
	{ return x.hi < y.hi \|\| (x.hi == y.hi && x.lo < y.lo); }

	friend constexpr auto
	__bit_width(const uint128_t x)
	{
	if (auto w = std::__bit_width(x.hi))
	return w + 64;
	else
	return std::__bit_width(x.lo);
	}

	friend constexpr auto
	__countr_zero(const uint128_t x)
	{
	auto c = std::__countr_zero(x.lo);
	if (c == 64)
	return 64 + std::__countr_zero(x.hi);
	else
	return c;
	}

	constexpr uint128_t&
	operator--()
	{ return *this -= 1; }

	constexpr uint128_t&
	operator++()
	{ return *this += 1; }

	constexpr uint128_t&
	operator+=(const uint128_t y)
	{ return this = this + y; }

	constexpr uint128_t&
	operator-=(const uint128_t y)
	{ return this = this - y; }

	constexpr uint128_t&
	operator*=(const uint128_t y)
	{ return this = this * y; }

	constexpr uint128_t&
	operator<<=(const uint128_t y)
	{ return this = this << y; }

	constexpr uint128_t&
	operator>>=(const uint128_t y)
	{ return this = this >> y; }

	constexpr uint128_t&
	operator\|=(const uint128_t y)
	{ return this = this \| y; }

	constexpr uint128_t&
	operator&=(const uint128_t y)
	{ return this = this & y; }

	constexpr uint128_t&
	operator%=(const uint128_t y)
	{ return this = this % y; }

	constexpr uint128_t&
	operator/=(const uint128_t y)
	{ return this = this / y; }

	friend constexpr bool
	operator!=(const uint128_t x, const uint128_t y)
	{ return !(x == y); }

	friend constexpr bool
	operator>(const uint128_t x, const uint128_t y)
	{ return y < x; }

	friend constexpr bool
	operator>=(const uint128_t x, const uint128_t y)
	{ return !(x < y); }
	};