#ifndef MANDEL_FIXED128_H #define MANDEL_FIXED128_H #ifdef _MSC_VER # include #endif #include #include #include #include #include #include #include #include namespace mnd { #if defined(_MSC_VER) && defined(_WIN64) static inline std::pair mul64(int64_t a, int64_t b) { int64_t higher; int64_t lower = _mul128(a, b, &higher); return { higher, lower }; } static inline std::pair mulu64(uint64_t a, uint64_t b) { uint64_t higher; uint64_t lower = _umul128(a, b, &higher); return { higher, lower }; } #elif defined(__SIZEOF_INT128__) static inline std::pair mul64(int64_t a, int64_t b) { __int128_t result = __int128_t(a) * __int128_t(b); return { result >> 64, uint64_t(result & 0xFFFFFFFFFFFFFFFFULL) }; } static inline std::pair mulu64(uint64_t a, uint64_t b) { __uint128_t result = __uint128_t(a) * __uint128_t(b); return { result >> 64, uint64_t(result & 0xFFFFFFFFFFFFFFFFULL) }; } #else static inline std::pair mul64(int64_t a, int64_t b) { uint32_t aa[2] = { uint32_t(a >> 32), uint32_t(a & 0xFFFFFFFF) }; uint32_t bb[2] = { uint32_t(b >> 32), uint32_t(b & 0xFFFFFFFF) }; uint32_t res[4]; int64_t temp = uint64_t(aa[1]) * uint64_t(bb[1]); res[3] = temp & 0xFFFFFFFF; temp >>= 32; temp += int64_t(int32_t(aa[0])) * int64_t(bb[1]) + int64_t(aa[1]) * int64_t(int32_t(bb[0])); res[2] = temp & 0xFFFFFFFF; temp >>= 32; temp += int64_t(int32_t(aa[0])) * int64_t(int32_t(bb[0])); res[1] = temp & 0xFFFFFFFF; res[0] = temp >> 32; return std::make_pair((int64_t(res[0]) << 32) | res[1], uint64_t((int64_t(res[2]) << 32) | res[3])); } static inline std::pair mulu64(uint64_t a, uint64_t b) { uint32_t aa[2] = { uint32_t(a >> 32), uint32_t(a & 0xFFFFFFFF) }; uint32_t bb[2] = { uint32_t(b >> 32), uint32_t(b & 0xFFFFFFFF) }; uint32_t res[4]; uint64_t temp = uint64_t(aa[1]) * bb[1]; res[3] = temp & 0xFFFFFFFF; uint32_t carry = temp >> 32; temp = uint64_t(aa[0]) * bb[1] + uint64_t(aa[1]) * bb[0] + carry; res[2] = temp & 0xFFFFFFFF; carry = temp >> 32; temp = uint64_t(aa[0]) * bb[0] + carry; res[1] = temp & 0xFFFFFFFF; res[0] = temp >> 32; return std::make_pair((uint64_t(res[0]) << 32) | res[1], (uint64_t(res[2]) << 32) | res[3] ); } #endif } struct Fixed512 { using Once = boost::multiprecision::int512_t; using Twice = boost::multiprecision::int1024_t; Once body; inline explicit Fixed512(const Once& body) : body{ body } {} using Float256 = boost::multiprecision::number< boost::multiprecision::backends::cpp_bin_float< 240, boost::multiprecision::backends::digit_base_2, void, boost::int16_t, -16382, 16383>, boost::multiprecision::et_off>; using Float512 = boost::multiprecision::number< boost::multiprecision::backends::cpp_bin_float< 496, boost::multiprecision::backends::digit_base_2, void, boost::int16_t, -16382, 16383>, boost::multiprecision::et_off>; inline Fixed512(const Float256& val) { body = Once{ val * boost::multiprecision::pow(Float256{ 2 }, 512 - 32) }; } inline Fixed512(const Float512& val) { body = Once{ val * boost::multiprecision::pow(Float512{ 2 }, 512 - 32) }; } inline Fixed512(double val) { body = Once{ boost::multiprecision::pow(Float512{ 2 }, 512 - 32) * val }; } inline operator Float256(void) const { return boost::multiprecision::pow(Float256{ 0.5 }, 512 - 32) * Float256{ body }; } inline operator Float512(void) const { return boost::multiprecision::pow(Float512{ 0.5 }, 512 - 32) * Float512{ body }; } inline Fixed512& operator += (const Fixed512& other) { body += other.body; return *this; } inline Fixed512 operator + (const Fixed512& other) const { return Fixed512{ body + other.body }; } inline Fixed512& operator -= (const Fixed512& other) { body -= other.body; return *this; } inline Fixed512 operator - (const Fixed512& other) const { return Fixed512{ body - other.body }; } inline Fixed512 operator * (const Fixed512& other) const { auto prod = Twice{ this->body } * other.body; return Fixed512{ Once{ prod >> (512 - 32) } }; } inline Fixed512& operator *= (const Fixed512& other) { auto prod = Twice{ this->body } * other.body; body = Once{ prod >> (512 - 64) }; return *this; } inline bool operator > (const Fixed512& other) { return this->body > other.body; } }; struct Fixed128 { uint64_t upper; uint64_t lower; Fixed128(const Fixed128&) = default; ~Fixed128() = default; inline Fixed128(uint64_t upper, uint64_t lower) : upper{ upper }, lower{ lower } { } inline Fixed128(uint32_t a, uint32_t b, uint32_t c, uint32_t d) : upper{ (uint64_t(a) << 32) | b }, lower{ (uint64_t(c) << 32) | d } { } inline Fixed128(double x) { const double twoToThe32 = double(0x100000000ULL); upper = uint64_t(int64_t(x * twoToThe32)); double remainder = x - double(upper) / twoToThe32; lower = uint64_t(int64_t(remainder * twoToThe32 * twoToThe32 * twoToThe32)); } inline Fixed128 operator + (const Fixed128& other) const { uint64_t lowerAdded = lower + other.lower; uint64_t upperAdded = upper + other.upper + (lowerAdded < lower); return Fixed128{ upperAdded, lowerAdded }; } inline Fixed128& operator +=(const Fixed128& other) { uint64_t lowerAdded = lower + other.lower; upper += other.upper + (lowerAdded < lower); lower = lowerAdded; return *this; } inline Fixed128 operator - (const Fixed128& other) const { uint64_t lowerSubbed = lower - other.lower; uint64_t upperSubbed = upper - other.upper - (lowerSubbed > lower); return Fixed128{ upperSubbed, lowerSubbed }; } inline Fixed128 operator - (void) const { return this->operator~() + Fixed128{ 0, 0, 0, 1 }; } /* //private: static inline std::pair mul64(int64_t a, int64_t b) { int32_t aa[2] = { int32_t(a >> 32), int32_t(a & 0xFFFFFFFF) }; int32_t bb[2] = { int32_t(b >> 32), int32_t(b & 0xFFFFFFFF) }; int32_t res[4]; int64_t temp = int64_t(aa[1]) * bb[1]; res[3] = temp & 0xFFFFFFFF; int32_t carry = temp >> 32; temp = int64_t(aa[0]) * bb[1] + int64_t(aa[1]) * bb[0] + carry; res[2] = temp & 0xFFFFFFFF; carry = temp >> 32; temp = int64_t(aa[0]) * bb[0] + carry; res[1] = temp & 0xFFFFFFFF; res[0] = temp >> 32; return std::make_pair(uint64_t((int64_t(res[0]) << 32) | res[1]), uint64_t((int64_t(res[2]) << 32) | res[3])); } static inline std::pair mulu64(uint64_t a, uint64_t b) { uint32_t aa[2] = { uint32_t(a >> 32), uint32_t(a & 0xFFFFFFFF) }; uint32_t bb[2] = { uint32_t(b >> 32), uint32_t(b & 0xFFFFFFFF) }; uint32_t res[4]; uint64_t temp = uint64_t(aa[1]) * bb[1]; res[3] = temp & 0xFFFFFFFF; uint32_t carry = temp >> 32; temp = uint64_t(aa[0]) * bb[1] + uint64_t(aa[1]) * bb[0] + carry; res[2] = temp & 0xFFFFFFFF; carry = temp >> 32; temp = uint64_t(aa[0]) * bb[0] + carry; res[1] = temp & 0xFFFFFFFF; res[0] = temp >> 32; return std::make_pair((uint64_t(res[0]) << 32) | res[1], (uint64_t(res[2]) << 32) | res[3] ); } */ public: inline Fixed128 operator * (const Fixed128& other) const { if (this->operator!=(Fixed128{ 0xFFFFFFFFFFFFFFFF, 0xFFFFFFFFFFFFFFFF }) && isNegative()) { return -(other * this->operator-()); } if (other.isNegative()) { return -((-other) * (*this)); } auto [uuc, uu] = mnd::mulu64(upper, other.upper); auto [ulc, ul] = mnd::mulu64(upper, other.lower); auto [luc, lu] = mnd::mulu64(lower, other.upper); auto [llc, ll] = mnd::mulu64(lower, other.lower); uint64_t res[4] = { 0, 0, 0, 0 }; res[3] = ll; res[2] += lu; res[2] += ul; if (res[2] < ul) res[1]++; res[2] += llc; if (res[2] < llc) res[1]++; res[1] += uu; if (res[1] < uu) res[0]++; res[1] += ulc; if (res[1] < ulc) res[0]++; res[1] += luc; if (res[1] < luc) res[0]++; res[0] += uuc; return Fixed128{ uint32_t(res[0] & 0xFFFFFFFF), uint32_t(int64_t(res[1]) >> 32), uint32_t(res[1] & 0xFFFFFFFF), uint32_t(int64_t(res[2]) >> 32) }; /*if (isNegative()) { return -(this->operator-() * other); } if (other.isNegative()) { return -(*this * (-other)); } bool otherNegative = other.isNegative(); uint32_t quarters[4] = { (upper >> 32) & 0xFFFFFFFF, upper & 0xFFFFFFFF, (lower >> 32) & 0xFFFFFFFF, lower & 0xFFFFFFFF }; auto [a, ra] = other.mul(quarters[0]); auto [b, rb] = other.mul(quarters[1]); auto [c, rc] = other.mul(quarters[2]); auto [d, rd] = other.mul(quarters[3]); b.arshift(1); c.arshift(2); d.arshift(3); Fixed128 carries = { uint32_t(rb), uint32_t(rc), uint32_t(rd), 0 }; Fixed128 result = a + b + c + d + carries; return result;*/ } inline std::pair mul(uint32_t factor) const { uint32_t quarters[4] = { uint32_t(upper >> 32) & 0xFFFFFFFF, uint32_t(upper) & 0xFFFFFFFF, uint32_t(lower >> 32) & 0xFFFFFFFF, uint32_t(lower) & 0xFFFFFFFF }; uint32_t newQ[4]; uint32_t carry = 0; for (int i = 3; i >= 0; i--) { int64_t prod = int64_t(quarters[i]) * factor + carry; newQ[i] = prod & 0xFFFFFFFF; carry = prod >> 32; } /* newQ[i] = quarters[i] * factor; uint64_t tempLower = newQ[3]; uint64_t newLower = tempLower + (newQ[2] << 32); uint64_t newUpper = (newQ[2] >> 32) + newQ[1] + (newQ[0] << 32) + (newLower < tempLower ? 1 : 0);*/ return std::make_pair(Fixed128{ newQ[0], newQ[1], newQ[2], newQ[3] }, carry); } private: inline void add(uint64_t val, int b32offset) { switch (b32offset) { case 0: upper += val << 32; return; case 1: upper += val; return; case 2: upper += val >> 32; lower += val << 32; return; case 3: { uint64_t newLower = lower + val; if (newLower < lower) upper++; lower = newLower; return; } case 4: uint64_t newLower = lower + (val >> 32); if (lower > newLower) upper++; lower += newLower; return; } } inline void addSigned(int64_t val, int b32offset) { switch (b32offset) { case 0: upper += val << 32; return; case 1: upper += val; return; case 2: upper += val >> 32; lower += val << 32; return; case 3: lower += val; if (val < 0) upper--; return; case 4: { uint64_t newLower = lower + (val >> 32); if (lower > newLower) upper++; lower = newLower; return; } default: if (val < 0) { if (lower == 0) upper--; lower--; } return; } } public: inline Fixed128 operator / (const Fixed128& other) { if (this->operator!=(Fixed128{ 0xFFFFFFFFFFFFFFFF, 0xFFFFFFFFFFFFFFFF }) && isNegative()) { return -((-(*this)) / other); } if (other != Fixed128{ 0xFFFFFFFFFFFFFFFF, 0xFFFFFFFFFFFFFFFF } && other.isNegative()) { return -((*this) / (-other)); } using u256 = std::array; u256 bigDividend = { upper, lower, 0, 0 }; u256 bigDivisor = { 0, 0, other.upper, other.lower }; auto twice = [] (u256& x) { bool carry = false; for (int i = 3; i >= 0; i--) { bool oldCarry = carry; carry = x[i] & 0x1000000000000000ULL; x[i] <<= 1; if (oldCarry) x[i] ++; } }; auto geq = [] (const u256& a, const u256& b) -> bool { for (int i = 0; i < 4; i++) { if (a[i] > b[i]) return true; if (a[i] < b[i]) return false; } return true; }; auto sub = [] (u256& a, const u256& b) -> bool { bool carry = false; for (int i = 3; i >= 0; i--) { uint64_t oldA = a[i]; a[i] -= b[i]; carry = oldA < a[i]; } return carry; }; auto add = [] (u256& a, const u256& b) -> bool { bool carry = false; for (int i = 3; i >= 0; i--) { uint64_t oldA = a[i]; a[i] += b[i]; carry = oldA > a[i]; } return carry; }; u256 growingCount = { 0, 0, 0, 1 }; u256 quotient = { 0, 0, 0, 0 }; std::vector growingStack = { bigDivisor }; while (true) { u256 beforeSub = bigDividend; const u256& gr = growingStack[growingStack.size() - 1]; if (!sub(bigDividend, gr)) { add(quotient, growingCount); u256 tw = gr; twice(tw); growingStack.push_back(tw); } else if (geq(bigDivisor, bigDividend)) { break; } else { bigDividend = beforeSub; growingStack.pop_back(); } } return Fixed128{ quotient[2], quotient[3] }; } bool isNegative(void) const { return upper >> 63; } operator double(void) const { const int64_t twoToThe32 = 0x100000000ULL; return double(int64_t(upper)) / twoToThe32 + int64_t(lower) / twoToThe32 / twoToThe32 / twoToThe32; } inline Fixed128 operator ~ (void) const { return Fixed128{ ~upper, ~lower }; } inline bool operator == (const Fixed128& other) const { return upper == other.upper && lower == other.lower; } inline bool operator != (const Fixed128& other) const { return !operator==(other); } inline bool operator < (const Fixed128& other) const { return upper < other.upper || (upper == other.upper && lower < other.lower); } inline bool operator <= (const Fixed128& other) const { return operator<(other) || operator==(other); } inline bool operator > (const Fixed128& other) const { return upper > other.upper || (upper == other.upper && lower > other.lower); } inline bool operator >= (const Fixed128& other) const { return operator>(other) || operator==(other); } }; struct Fixed64 { int64_t bits; Fixed64(const Fixed64&) = default; ~Fixed64() = default; explicit inline Fixed64(int64_t bits, bool /* dummy */) : bits{ bits } { } inline Fixed64(double x) { bits = int64_t(x * (1LL << 48)); } inline operator float(void) const { return bits * (1.0f / (1ULL << 48)); } inline operator double(void) const { return bits * (1.0 / (1ULL << 48)); } inline Fixed64 operator + (const Fixed64& other) const { return Fixed64{ bits + other.bits, true }; } inline Fixed64& operator +=(const Fixed64& other) { bits += other.bits; return *this; } inline Fixed64 operator - (const Fixed64& other) const { return Fixed64{ bits - other.bits, true }; } inline Fixed64& operator -= (const Fixed64& other) { bits -= other.bits; return *this; } inline Fixed64 operator * (const Fixed64& other) { /*int32_t upper = bits >> 32; uint32_t lower = uint32_t(bits & 0xFFFFFFFF); int64_t upup = int64_t(upper) * int64_t(upper); int64_t loup = int64_t(upper) * int64_t(lower); int64_t lolo = int64_t(lower) * int64_t(lower); int32_t newUp = upup & 0xFFFFFFFF + (loup >> 32); int32_t newLo = loup & 0xFFFFFFFF + (lolo >> 32);*/ /*double d = int32_t(bits >> 32) + double(uint32_t(bits)) / (1ULL << 32); double od = int32_t(other.bits >> 32) + double(uint32_t(other.bits)) / (1ULL << 32); return d * od;*/ #if defined(__SIZEOF_INT128__) __int128_t m = __int128_t(bits) * __int128_t(other.bits); return Fixed64{ int64_t(m >> 48), true }; #else auto[hi, lo] = mnd::mul64(bits, other.bits); return Fixed64{ int64_t((hi << 16) | (lo >> 48)), true }; #endif /*uint32_t a[2] = { uint32_t(uint64_t(bits) >> 32), uint32_t(bits & 0xFFFFFFFF) }; uint32_t b[2] = { uint32_t(uint64_t(other.bits) >> 32), uint32_t(other.bits & 0xFFFFFFFF) }; uint64_t a1b1 = uint64_t(a[1]) * b[1]; int64_t a0b1 = int64_t(int32_t(a[0])) * uint64_t(b[1]); int64_t a1b0 = uint64_t(a[1]) * int64_t(int32_t(b[1])); int64_t a0b0 = int64_t(int32_t(a[1])) * int64_t(int32_t(b[1])); int64_t res = a1b1 >> 32; res += a0b1 + a1b0; res += a0b0 << 32; return Fixed64{ res, true };*/ /* uint32_t aa[2] = { uint32_t(uint64_t(bits) >> 32), uint32_t(bits & 0xFFFFFFFF) }; uint32_t bb[2] = { uint32_t(uint64_t(other.bits) >> 32), uint32_t(other.bits & 0xFFFFFFFF) }; uint64_t ab0[2] = { 0, 0 }; ab[1] = int64_t(int32_t(aa[1]) * int32_t(ab[0])); ab[0] = int64_t(int32_t(aa[0]) * int32_t(ab[0])); uint64_t ab1[2] = { 0, 0 }; ab[1] = aa[1] * ab[1]; ab[0] = int64_t(int32_t(aa[1]) * int32_t(ab[0])); */ /* boost::multiprecision::int128_t a(this->bits); boost::multiprecision::int128_t b(other.bits); return Fixed64{ int64_t((a * b) >> 32), true }; */ //return Fixed64{ (uint64_t(newUp) << 32) | newLo, true }; } inline bool operator == (const Fixed64& other) { return bits == other.bits; } inline bool operator != (const Fixed64& other) { return !operator==(other); } inline bool operator < (const Fixed64& other) { return bits < other.bits; } inline bool operator <= (const Fixed64& other) { return operator<(other) || operator==(other); } inline bool operator > (const Fixed64& other) { return bits > other.bits; } inline bool operator >= (const Fixed64& other) { return operator>(other) || operator==(other); } }; struct Fixed32 { int32_t bits; Fixed32(const Fixed32&) = default; ~Fixed32() = default; inline Fixed32(int32_t bits, bool) : bits{ bits } { } inline Fixed32(double x) { int integerPart = int(::floor(x)); double fractionalPart = x - integerPart; /*if (x < 0) { integerPart--; fractionalPart = 1.0 - fractionalPart; }*/ bits = int32_t(integerPart) << 16; bits |= uint32_t(fractionalPart * (1ULL << 16)) & 0xFFFF; } inline Fixed32 operator + (const Fixed32& other) { return Fixed32{ bits + other.bits, true }; } inline Fixed32& operator +=(const Fixed32& other) { bits += other.bits; return *this; } inline Fixed32 operator - (const Fixed32& other) { return Fixed32{ bits - other.bits, true }; } inline Fixed32 operator * (const Fixed32& other) { int64_t prod = int64_t(bits) * int64_t(other.bits); return Fixed32{ int32_t(prod >> 16), true }; //return Fixed32{ (uint64_t(newUp) << 32) | newLo, true }; } inline bool operator == (const Fixed32& other) { return bits == other.bits; } inline bool operator != (const Fixed32& other) { return !operator==(other); } inline bool operator < (const Fixed32& other) { return bits < other.bits; } inline bool operator <= (const Fixed32& other) { return operator<(other) || operator==(other); } inline bool operator > (const Fixed32& other) { return bits > other.bits; } inline bool operator >= (const Fixed32& other) { return operator>(other) || operator==(other); } }; #endif // MANDEL_FIXED128_H