#ifndef MANDEL_FIXED128_H
#define MANDEL_FIXED128_H
#include <cinttypes>
#include <cmath>
#include <utility>
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));
/*int integerPart = ::floor(x);
double fractionalPart = x - integerPart;
upper = int64_t(integerPart) << 32;
upper |= uint64_t(fractionalPart * (1ULL << 32)) & 0xFFFFFFFFULL;
lower = 0;// uint64_t(fractionalPart * (1ULL << 32) * (1ULL << 63) * 2);*/
}
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<uint64_t, uint64_t> mul64(int64_t a, int64_t b) {
int32_t aa[2] = { a >> 32, a & 0xFFFFFFFF };
int32_t bb[2] = { b >> 32, 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<uint64_t, uint64_t> mulu64(uint64_t a, uint64_t b) {
uint32_t aa[2] = { a >> 32, a & 0xFFFFFFFF };
uint32_t bb[2] = { b >> 32, 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 (isNegative()) {
return -(other * this->operator-());
}
if (other.isNegative()) {
return -(*this * (-other));
}
auto [uuc, uu] = mulu64(upper, other.upper);
auto [ulc, ul] = mulu64(upper, other.lower);
auto [luc, lu] = mulu64(lower, other.upper);
auto [llc, ll] = 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<Fixed128, uint32_t> mul(uint32_t factor) const {
uint32_t quarters[4] = {
(upper >> 32) & 0xFFFFFFFF,
upper & 0xFFFFFFFF,
(lower >> 32) & 0xFFFFFFFF,
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);
}
/*
inline void arshift(int fac32) {
uint32_t temp = 0;
switch (fac32) {
case 0:
return;
case 1:
temp = upper & 0xFFFFFFFF;
upper = uint64_t(int64_t(upper) >> 32);
lower >>= 32;
lower |= uint64_t(temp) << 32;
case 2:
lower = upper;
upper = uint64_t(int64_t(upper) >> 63);
case 3:
lower = uint64_t(int64_t(upper) >> 32);
upper = uint64_t(int64_t(upper) >> 63);
default:
lower = uint64_t(int64_t(upper) >> 63);
upper = uint64_t(int64_t(upper) >> 63);
}
}*/
/*
inline Fixed128 operator * (const Fixed128& other) const {
int32_t quarters[4] = {
(upper >> 32) & 0xFFFFFFFF,
upper & 0xFFFFFFFF,
(lower >> 32) & 0xFFFFFFFF,
lower & 0xFFFFFFFF
};
int32_t otherQuarters[4] = {
(other.upper >> 32) & 0xFFFFFFFF,
other.upper & 0xFFFFFFFF,
(other.lower >> 32) & 0xFFFFFFFF,
other.lower & 0xFFFFFFFF
};
int64_t prods[4][4];
for (int i = 0; i < 4; i++) {
for (int j = 0; j < 4 && j + i < 5; j++) {
if (i == 0 || j == 0)
prods[i][j] = int64_t(quarters[i]) * int64_t(otherQuarters[j]);
else
prods[i][j] = uint64_t(uint32_t(quarters[i])) * uint64_t(uint32_t(otherQuarters[j]));
}
}
Fixed128 ret = { 0, 0 };
for (int i = 0; i < 4; i++) {
for (int j = 0; j < 4 && j + i < 5; j++) {
if (i == 0 || j == 0)
ret.addSigned(prods[i][j], i + j);
else
ret.add(prods[i][j], i + j);
}
}
return ret;
/*
int64_t x00 = int64_t(quarters[0]) * int64_t(otherQuarters[0]);
int64_t x01 = int64_t(quarters[0]) * int64_t(otherQuarters[1]);
int64_t x02 = int64_t(quarters[0]) * int64_t(otherQuarters[2]);
int64_t x03 = int64_t(quarters[0]) * int64_t(otherQuarters[3]);
int64_t x10 = int64_t(quarters[1]) * int64_t(otherQuarters[0]);
int64_t x11 = int64_t(quarters[1]) * int64_t(otherQuarters[1]);
int64_t x12 = int64_t(quarters[1]) * int64_t(otherQuarters[2]);
int64_t x13 = int64_t(quarters[1]) * int64_t(otherQuarters[3]);
int64_t x20 = int64_t(quarters[2]) * int64_t(otherQuarters[0]);
int64_t x21 = int64_t(quarters[2]) * int64_t(otherQuarters[1]);
int64_t x22 = int64_t(quarters[2]) * int64_t(otherQuarters[2]);
int64_t x30 = int64_t(quarters[3]) * int64_t(otherQuarters[0]);
int64_t x31 = int64_t(quarters[3]) * int64_t(otherQuarters[1]);
Fixed128 ret = { 0, 0 };
/*uint32_t newQuarters[4] = {
x00,
x01 + x10,
x02 + x11 + x20,
x03 + x12 + x21 + x30,
};*//*
ret.add(x00, 0);
ret.add(x01 + x10, 1);
ret.add(x02 + x11 + x20, 2);
ret.add(x03 + x12 + x21 + x30, 3);
ret.add(x13 + x22 + x31, 4);
return ret;*/
/*}*/
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:
bool isNegative(void) const {
return (upper & (uint64_t(1) << 63)) != 0;
}
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
{
bool sign;
uint64_t bits;
Fixed64(const Fixed64&) = default;
~Fixed64() = default;
inline Fixed64(uint64_t bits, bool dummy) :
bits{ bits }
{
}
inline Fixed64(double x)
{
if (x < 0) {
sign = true;
x *= -1;
}
else {
sign = false;
}
int integerPart = int(x);
double fractionalPart = x - integerPart;
bits = uint64_t(integerPart) << 32;
bits |= uint64_t(fractionalPart * (1ULL << 32)) & 0xFFFFFFFF;
}
inline Fixed64 operator + (const Fixed64& other) {
return Fixed64{ bits + other.bits, true };
}
inline Fixed64& operator +=(const Fixed64& other) {
bits += other.bits;
return *this;
}
inline Fixed64 operator - (const Fixed64& other) {
return Fixed64{ bits - other.bits, true };
}
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 * (other.sign != sign) ? -1 : 1;
//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 dummy) :
bits{ bits }
{
}
inline Fixed32(double x)
{
int integerPart = ::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