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IntMod.cpp
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IntMod.cpp
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/*
* This file is part of the VanitySearch distribution (https://github.com/JeanLucPons/VanitySearch).
* Copyright (c) 2019 Jean Luc PONS.
*
* This program 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, version 3.
*
* This program 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.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "Int.h"
#include <emmintrin.h>
#include <string.h>
#define MAX(x,y) (((x)>(y))?(x):(y))
#define MIN(x,y) (((x)<(y))?(x):(y))
static Int _P; // Field characteristic
static Int _R; // Montgomery multiplication R
static Int _R2; // Montgomery multiplication R2
static Int _R3; // Montgomery multiplication R3
static Int _R4; // Montgomery multiplication R4
static int32_t Msize; // Montgomery mult size
static uint32_t MM32; // 32bits lsb negative inverse of P
static uint64_t MM64; // 64bits lsb negative inverse of P
#define MSK62 0x3FFFFFFFFFFFFFFF
extern Int _ONE;
// ------------------------------------------------
void Int::ModAdd(Int *a) {
Int p;
Add(a);
p.Sub(this,&_P);
if(p.IsPositive())
Set(&p);
}
// ------------------------------------------------
void Int::ModAdd(Int *a, Int *b) {
Int p;
Add(a,b);
p.Sub(this,&_P);
if(p.IsPositive())
Set(&p);
}
// ------------------------------------------------
void Int::ModDouble() {
Int p;
Add(this);
p.Sub(this,&_P);
if(p.IsPositive())
Set(&p);
}
// ------------------------------------------------
void Int::ModAdd(uint64_t a) {
Int p;
Add(a);
p.Sub(this,&_P);
if(p.IsPositive())
Set(&p);
}
// ------------------------------------------------
void Int::ModSub(Int *a) {
Sub(a);
if (IsNegative())
Add(&_P);
}
// ------------------------------------------------
void Int::ModSub(uint64_t a) {
Sub(a);
if (IsNegative())
Add(&_P);
}
// ------------------------------------------------
void Int::ModSub(Int *a,Int *b) {
Sub(a,b);
if (IsNegative())
Add(&_P);
}
// ------------------------------------------------
void Int::ModNeg() {
Neg();
Add(&_P);
}
// ------------------------------------------------
void Int::ModInv() {
// Compute modular inverse of this mop _P
// 0 < this < P , P must be odd
// Return 0 if no inverse
// 256bit
//#define XCD 1 // ~62 kOps/s
//#define BXCD 1 // ~167 kOps/s
//#define MONTGOMERY 1 // ~200 kOps/s
//#define PENK 1 // ~179 kOps/s
#define DRS62 1 // ~365 kOps/s
Int u(&_P);
Int v(this);
Int r((int64_t)0);
Int s((int64_t)1);
#ifdef XCD
Int q, t1, t2, w;
// Classic XCD
bool bIterations = true; // Remember odd/even iterations
while (!u.IsZero()) {
// Step X3. Divide and "Subtract"
q.Set(&v);
q.Div(&u, &t2); // q = u / v, t2 = u % v
w.Mult(&q, &r); // w = q * r
t1.Add(&s, &w); // t1 = s + w
// Swap u,v & r,s
s.Set(&r);
r.Set(&t1);
v.Set(&u);
u.Set(&t2);
bIterations = !bIterations;
}
if (!v.IsOne()) {
CLEAR();
return;
}
if (!bIterations) {
Set(&_P);
Sub(&s); /* inv = n - u1 */
} else {
Set(&s); /* inv = u1 */
}
#endif
#ifdef BXCD
#define SWAP_SUB(x,y) x.Sub(&y);y.Add(&x)
// Binary XCD loop
while (!u.IsZero()) {
if (u.IsEven()) {
u.ShiftR(1);
if (r.IsOdd())
r.Add(&_P);
r.ShiftR(1);
} else {
SWAP_SUB(u, v);
SWAP_SUB(r, s);
}
}
// v ends with -1 ou 1
if (!v.IsOne()) {
// v = -1
s.Neg();
s.Add(&_P);
v.Neg();
}
if (!v.IsOne()) {
CLEAR();
return;
}
if (s.IsNegative())
s.Add(&_P);
if (s.IsGreaterOrEqual(&_P))
s.Sub(&_P);
Set(&s);
#endif
#ifdef PENK
Int x;
Int n2(&_P);
int k = 0;
int T;
int Q = _P.bits[0] & 3;
shiftL(1,n2.bits64);
// Penk's Algorithm (With DRS2 optimisation)
while (v.IsEven()) {
shiftR(1,v.bits64);
if (s.IsEven())
shiftR(1, s.bits64);
else if (s.IsGreater(&_P)) {
s.Sub(&_P);
shiftR(1, s.bits64);
} else {
s.Add(&_P);
shiftR(1, s.bits64);
}
}
while (true) {
if (u.IsGreater(&v)) {
if ((u.bits[0] & 2) == (v.bits[0] & 2)) {
u.Sub(&v);
r.Sub(&s);
} else {
u.Add(&v);
r.Add(&s);
}
shiftR(2,u.bits64);
T = r.bits[0] & 3;
if (T == 0) {
shiftR(2,r.bits64);
} else if (T == 2) {
r.Add(&n2);
shiftR(2, r.bits64);
} else if (T == Q) {
r.Sub(&_P);
shiftR(2, r.bits64);
} else {
r.Add(&_P);
shiftR(2, r.bits64);
}
while (u.IsEven()) {
shiftR(1,u.bits64);
if (r.IsEven()) {
shiftR(1, r.bits64);
} else if (r.IsGreater(&_P)) {
r.Sub(&_P);
shiftR(1, r.bits64);
} else {
r.Add(&_P);
shiftR(1, r.bits64);
}
}
} else {
if ((u.bits[0] & 2) == (v.bits[0] & 2)) {
v.Sub(&u);
s.Sub(&r);
} else {
v.Add(&u);
s.Add(&r);
}
if (v.IsZero())
break;
shiftR(2, v.bits64);
T = s.bits[0] & 3;
if (T == 0) {
shiftR(2,s.bits64);
} else if (T == 2) {
s.Add(&n2);
shiftR(2, s.bits64);
} else if (T == Q) {
s.Sub(&_P);
shiftR(2, s.bits64);
} else {
s.Add(&_P);
shiftR(2, s.bits64);
}
while (v.IsEven()) {
shiftR(1, v.bits64);
if (s.IsEven()) {
shiftR(1, s.bits64);
} else if (s.IsGreater(&_P)) {
s.Sub(&_P);
shiftR(1, s.bits64);
} else {
s.Add(&_P);
shiftR(1, s.bits64);
}
}
}
}
if (u.IsGreater(&_ONE)) {
CLEAR();
return;
}
if (r.IsNegative())
r.Add(&_P);
Set(&r);
#endif
#ifdef MONTGOMERY
Int x;
int k = 0;
// Montgomery method
while (v.IsStrictPositive()) {
if (u.IsEven()) {
shiftR(1, u.bits64);
shiftL(1, s.bits64);
} else if (v.IsEven()) {
shiftR(1, v.bits64);
shiftL(1, r.bits64);
} else {
x.Set(&u);
x.Sub(&v);
if (x.IsStrictPositive()) {
shiftR(1, x.bits64);
u.Set(&x);
r.Add(&s);
shiftL(1, s.bits64);
} else {
x.Neg();
shiftR(1, x.bits64);
v.Set(&x);
s.Add(&r);
shiftL(1, r.bits64);
}
}
k++;
}
if (r.IsGreater(&_P))
r.Sub(&_P);
r.Neg();
r.Add(&_P);
for (int i = 0; i < k; i++) {
if (r.IsEven()) {
shiftR(1, r.bits64);
} else {
r.Add(&_P);
shiftR(1, r.bits64);
}
}
Set(&r);
#endif
#ifdef DRS62
// Delayed right shift 62bits
#define SWAP_ADD(x,y) x+=y;y-=x;
#define SWAP_SUB(x,y) x-=y;y+=x;
#define IS_EVEN(x) ((x&1)==0)
Int r0_P;
Int s0_P;
Int uu_u;
Int uv_v;
Int vu_u;
Int vv_v;
Int uu_r;
Int uv_s;
Int vu_r;
Int vv_s;
int64_t bitCount;
int64_t uu, uv, vu, vv;
int64_t v0, u0;
int64_t nb0;
while (!u.IsZero()) {
// u' = (uu*u + uv*v) >> bitCount
// v' = (vu*u + vv*v) >> bitCount
// Do not maintain a matrix for r and s, the number of
// 'added P' can be easily calculated
uu = 1; uv = 0;
vu = 0; vv = 1;
u0 = (int64_t)u.bits64[0];
v0 = (int64_t)v.bits64[0];
bitCount = 0;
// Slightly optimized Binary XCD loop on native signed integers
// Stop at 62 bits to avoid uv matrix overfow and loss of sign bit
while (true) {
while (IS_EVEN(u0) && bitCount<62) {
bitCount++;
u0 >>= 1;
vu <<= 1;
vv <<= 1;
}
if (bitCount == 62)
break;
nb0 = (v0 + u0) & 0x3;
if (nb0 == 0) {
SWAP_ADD(uv, vv);
SWAP_ADD(uu, vu);
SWAP_ADD(u0, v0);
} else {
SWAP_SUB(uv, vv);
SWAP_SUB(uu, vu);
SWAP_SUB(u0, v0);
}
}
// Now update BigInt variables
uu_u.IMult(&u,uu);
uv_v.IMult(&v,uv);
vu_u.IMult(&u,vu);
vv_v.IMult(&v,vv);
uu_r.IMult(&r,uu);
uv_s.IMult(&s,uv);
vu_r.IMult(&r,vu);
vv_s.IMult(&s,vv);
// Compute multiple of P to add to s and r to make them multiple of 2^62
uint64_t r0 = ((uu_r.bits64[0] + uv_s.bits64[0]) * MM64) & MSK62;
uint64_t s0 = ((vu_r.bits64[0] + vv_s.bits64[0]) * MM64) & MSK62;
r0_P.Mult(&_P,r0);
s0_P.Mult(&_P,s0);
// u = (uu*u + uv*v)
u.Add(&uu_u,&uv_v);
// v = (vu*u + vv*v)
v.Add(&vu_u,&vv_v);
// r = (uu*r + uv*s + r0*P)
r.Add(&uu_r,&uv_s);
r.Add(&r0_P);
// s = (vu*r + vv*s + s0*P)
s.Add(&vu_r,&vv_s);
s.Add(&s0_P);
// Right shift all variables by 62bits
shiftR(62, u.bits64);
shiftR(62, v.bits64);
shiftR(62, r.bits64);
shiftR(62, s.bits64);
}
// v ends with -1 or 1
if (v.IsNegative()) {
// V = -1
v.Neg();
s.Neg();
s.Add(&_P);
}
if (!v.IsOne()) {
// No inverse
CLEAR();
return;
}
// In very rare case |s|>2P
while(s.IsNegative())
s.Add(&_P);
while(s.IsGreaterOrEqual(&_P))
s.Sub(&_P);
Set(&s);
#endif
}
// ------------------------------------------------
void Int::ModExp(Int *e) {
Int base(this);
SetInt32(1);
uint32_t i = 0;
uint32_t nbBit = e->GetBitLength();
for(int i=0;i<(int)nbBit;i++) {
if (e->GetBit(i))
ModMul(&base);
base.ModMul(&base);
}
}
// ------------------------------------------------
void Int::ModMul(Int *a) {
Int p;
p.MontgomeryMult(a, this);
MontgomeryMult(&_R2, &p);
}
// ------------------------------------------------
void Int::ModSquare(Int *a) {
Int p;
p.MontgomeryMult(a, a);
MontgomeryMult(&_R2, &p);
}
// ------------------------------------------------
void Int::ModCube(Int *a) {
Int p;
Int p2;
p.MontgomeryMult(a, a);
p2.MontgomeryMult(&p, a);
MontgomeryMult(&_R3, &p2);
}
// ------------------------------------------------
bool Int::HasSqrt() {
// Euler's criterion
Int e(&_P);
Int a(this);
e.SubOne();
e.ShiftR(1);
a.ModExp(&e);
return a.IsOne();
}
// ------------------------------------------------
void Int::ModSqrt() {
if (_P.IsEven()) {
CLEAR();
return;
}
if (!HasSqrt()) {
CLEAR();
return;
}
if ((_P.bits64[0] & 3) == 3) {
Int e(&_P);
e.AddOne();
e.ShiftR(2);
ModExp(&e);
} else if ((_P.bits64[0] & 3) == 1) {
int nbBit = _P.GetBitLength();
// Tonelli Shanks
uint64_t e=0;
Int S(&_P);
S.SubOne();
while (S.IsEven()) {
S.ShiftR(1);
e++;
}
// Search smalest non-qresidue of P
Int q(1);
do {
q.AddOne();
} while (q.HasSqrt());
Int c(&q);
c.ModExp(&S);
Int t(this);
t.ModExp(&S);
Int r(this);
Int ex(&S);
ex.AddOne();
ex.ShiftR(1);
r.ModExp(&ex);
uint64_t M = e;
while (!t.IsOne()) {
Int t2(&t);
uint64_t i=0;
while (!t2.IsOne()) {
t2.ModSquare(&t2);
i++;
}
Int b(&c);
for(uint64_t j=0;j<M-i-1;j++)
b.ModSquare(&b);
M=i;
c.ModSquare(&b);
t.ModMul(&t,&c);
r.ModMul(&r,&b);
}
Set(&r);
}
}
// ------------------------------------------------
void Int::ModMul(Int *a, Int *b) {
Int p;
p.MontgomeryMult(a,b);
MontgomeryMult(&_R2,&p);
}
// ------------------------------------------------
Int* Int::GetFieldCharacteristic() {
return &_P;
}
// ------------------------------------------------
Int* Int::GetR() {
return &_R;
}
Int* Int::GetR2() {
return &_R2;
}
Int* Int::GetR3() {
return &_R3;
}
Int* Int::GetR4() {
return &_R4;
}
// ------------------------------------------------
void Int::SetupField(Int *n, Int *R, Int *R2, Int *R3, Int *R4) {
// Size in number of 32bit word
int nSize = n->GetSize();
// Last digit inversions (Newton's iteration)
{
int64_t x, t;
x = t = (int64_t)n->bits64[0];
x = x * (2 - t * x);
x = x * (2 - t * x);
x = x * (2 - t * x);
x = x * (2 - t * x);
x = x * (2 - t * x);
MM64 = (uint64_t)(-x);
MM32 = (uint32_t)MM64;
}
_P.Set(n);
// Size of Montgomery mult (64bits digit)
Msize = nSize/2;
// Compute few power of R
// R = 2^(64*Msize) mod n
Int Ri;
Ri.MontgomeryMult(&_ONE, &_ONE); // Ri = R^-1
_R.Set(&Ri); // R = R^-1
_R2.MontgomeryMult(&Ri, &_ONE); // R2 = R^-2
_R3.MontgomeryMult(&Ri, &Ri); // R3 = R^-3
_R4.MontgomeryMult(&_R3, &_ONE); // R4 = R^-4
_R.ModInv(); // R = R
_R2.ModInv(); // R2 = R^2
_R3.ModInv(); // R3 = R^3
_R4.ModInv(); // R4 = R^4
if (R)
R->Set(&_R);
if (R2)
R2->Set(&_R2);
if (R3)
R3->Set(&_R3);
if (R4)
R4->Set(&_R4);
}
// ------------------------------------------------
uint64_t Int::AddC(Int *a) {
unsigned char c = 0;
c = _addcarry_u64(c, bits64[0], a->bits64[0], bits64 + 0);
c = _addcarry_u64(c, bits64[1], a->bits64[1], bits64 + 1);
c = _addcarry_u64(c, bits64[2], a->bits64[2], bits64 + 2);
c = _addcarry_u64(c, bits64[3], a->bits64[3], bits64 + 3);
c = _addcarry_u64(c, bits64[4], a->bits64[4], bits64 + 4);
#if NB64BLOCK > 5
c = _addcarry_u64(c, bits64[5], a->bits64[5], bits64 + 5);
c = _addcarry_u64(c, bits64[6], a->bits64[6], bits64 + 6);
c = _addcarry_u64(c, bits64[7], a->bits64[7], bits64 + 7);
c = _addcarry_u64(c, bits64[8], a->bits64[8], bits64 + 8);
#endif
return c;
}
// ------------------------------------------------
void Int::AddAndShift(Int *a, Int *b, uint64_t cH) {
unsigned char c = 0;
c = _addcarry_u64(c, b->bits64[0], a->bits64[0], bits64 + 0);
c = _addcarry_u64(c, b->bits64[1], a->bits64[1], bits64 + 0);
c = _addcarry_u64(c, b->bits64[2], a->bits64[2], bits64 + 1);
c = _addcarry_u64(c, b->bits64[3], a->bits64[3], bits64 + 2);
c = _addcarry_u64(c, b->bits64[4], a->bits64[4], bits64 + 3);
#if NB64BLOCK > 5
c = _addcarry_u64(c, b->bits64[5], a->bits64[5], bits64 + 4);
c = _addcarry_u64(c, b->bits64[6], a->bits64[6], bits64 + 5);
c = _addcarry_u64(c, b->bits64[7], a->bits64[7], bits64 + 6);
c = _addcarry_u64(c, b->bits64[8], a->bits64[8], bits64 + 7);
#endif
bits64[NB64BLOCK-1] = c + cH;
}
// ------------------------------------------------
void Int::MontgomeryMult(Int *a) {
// Compute a*b*R^-1 (mod n), R=2^k (mod n), k = Msize*64
// a and b must be lower than n
// See SetupField()
Int t;
Int pr;
Int p;
uint64_t ML;
uint64_t c;
// i = 0
imm_umul(a->bits64, bits64[0], pr.bits64);
ML = pr.bits64[0] * MM64;
imm_umul(_P.bits64, ML, p.bits64);
c = pr.AddC(&p);
memcpy(t.bits64, pr.bits64 + 1, 8 * (NB64BLOCK - 1));
t.bits64[NB64BLOCK - 1] = c;
for (int i = 1; i < Msize; i++) {
imm_umul(a->bits64, bits64[i], pr.bits64);
ML = (pr.bits64[0] + t.bits64[0]) * MM64;
imm_umul(_P.bits64, ML, p.bits64);
c = pr.AddC(&p);
t.AddAndShift(&t, &pr, c);
}
p.Sub(&t,&_P);
if (p.IsPositive())
Set(&p);
else
Set(&t);
}
void Int::MontgomeryMult(Int *a, Int *b) {
// Compute a*b*R^-1 (mod n), R=2^k (mod n), k = Msize*64
// a and b must be lower than n
// See SetupField()
Int pr;
Int p;
uint64_t ML;
uint64_t c;
// i = 0
imm_umul(a->bits64, b->bits64[0], pr.bits64);
ML = pr.bits64[0] * MM64;
imm_umul(_P.bits64, ML, p.bits64);
c = pr.AddC(&p);
memcpy(bits64,pr.bits64 + 1,8*(NB64BLOCK-1));
bits64[NB64BLOCK-1] = c;
for (int i = 1; i < Msize; i++) {
imm_umul(a->bits64, b->bits64[i], pr.bits64);
ML = (pr.bits64[0] + bits64[0]) * MM64;
imm_umul(_P.bits64, ML, p.bits64);
c = pr.AddC(&p);
AddAndShift(this, &pr, c);
}
p.Sub(this, &_P);
if (p.IsPositive())
Set(&p);
}
// SecpK1 specific section -----------------------------------------------------------------------------
void Int::ModMulK1(Int *a, Int *b) {
#ifndef WIN64
#if (__GNUC__ > 7) || (__GNUC__ == 7 && (__GNUC_MINOR__ > 2))
unsigned char c;
#else
#warning "GCC lass than 7.3 detected, upgrade gcc to get best perfromance"
volatile unsigned char c;
#endif
#else
unsigned char c;
#endif
uint64_t ah, al;
uint64_t t[5];
uint64_t r512[8];
r512[5] = 0;
r512[6] = 0;
r512[7] = 0;
// 256*256 multiplier
imm_umul(a->bits64, b->bits64[0], r512);
imm_umul(a->bits64, b->bits64[1], t);
c = _addcarry_u64(0, r512[1], t[0], r512 + 1);
c = _addcarry_u64(c, r512[2], t[1], r512 + 2);
c = _addcarry_u64(c, r512[3], t[2], r512 + 3);
c = _addcarry_u64(c, r512[4], t[3], r512 + 4);
c = _addcarry_u64(c, r512[5], t[4], r512 + 5);
imm_umul(a->bits64, b->bits64[2], t);
c = _addcarry_u64(0, r512[2], t[0], r512 + 2);
c = _addcarry_u64(c, r512[3], t[1], r512 + 3);
c = _addcarry_u64(c, r512[4], t[2], r512 + 4);
c = _addcarry_u64(c, r512[5], t[3], r512 + 5);
c = _addcarry_u64(c, r512[6], t[4], r512 + 6);
imm_umul(a->bits64, b->bits64[3], t);
c = _addcarry_u64(0, r512[3], t[0], r512 + 3);
c = _addcarry_u64(c, r512[4], t[1], r512 + 4);
c = _addcarry_u64(c, r512[5], t[2], r512 + 5);
c = _addcarry_u64(c, r512[6], t[3], r512 + 6);
c = _addcarry_u64(c, r512[7], t[4], r512 + 7);
// Reduce from 512 to 320
imm_umul(r512 + 4, 0x1000003D1ULL, t);
c = _addcarry_u64(0, r512[0], t[0], r512 + 0);
c = _addcarry_u64(c, r512[1], t[1], r512 + 1);
c = _addcarry_u64(c, r512[2], t[2], r512 + 2);
c = _addcarry_u64(c, r512[3], t[3], r512 + 3);
// Reduce from 320 to 256
// No overflow possible here t[4]+c<=0x1000003D1ULL
al = _umul128(t[4] + c, 0x1000003D1ULL, &ah);
c = _addcarry_u64(0, r512[0], al, bits64 + 0);
c = _addcarry_u64(c, r512[1], ah, bits64 + 1);
c = _addcarry_u64(c, r512[2], 0ULL, bits64 + 2);
c = _addcarry_u64(c, r512[3], 0ULL, bits64 + 3);
// Probability of carry here or that this>P is very very unlikely
bits64[4] = 0;
}
void Int::ModMulK1(Int *a) {
#ifndef WIN64
#if (__GNUC__ > 7) || (__GNUC__ == 7 && (__GNUC_MINOR__ > 2))
unsigned char c;
#else
#warning "GCC lass than 7.3 detected, upgrade gcc to get best perfromance"
volatile unsigned char c;
#endif
#else
unsigned char c;
#endif
uint64_t ah, al;
uint64_t t[5];
uint64_t r512[8];
r512[5] = 0;
r512[6] = 0;
r512[7] = 0;
// 256*256 multiplier
imm_umul(a->bits64, bits64[0], r512);
imm_umul(a->bits64, bits64[1], t);
c = _addcarry_u64(0, r512[1], t[0], r512 + 1);
c = _addcarry_u64(c, r512[2], t[1], r512 + 2);
c = _addcarry_u64(c, r512[3], t[2], r512 + 3);
c = _addcarry_u64(c, r512[4], t[3], r512 + 4);
c = _addcarry_u64(c, r512[5], t[4], r512 + 5);
imm_umul(a->bits64, bits64[2], t);
c = _addcarry_u64(0, r512[2], t[0], r512 + 2);
c = _addcarry_u64(c, r512[3], t[1], r512 + 3);
c = _addcarry_u64(c, r512[4], t[2], r512 + 4);
c = _addcarry_u64(c, r512[5], t[3], r512 + 5);
c = _addcarry_u64(c, r512[6], t[4], r512 + 6);
imm_umul(a->bits64, bits64[3], t);
c = _addcarry_u64(0, r512[3], t[0], r512 + 3);
c = _addcarry_u64(c, r512[4], t[1], r512 + 4);
c = _addcarry_u64(c, r512[5], t[2], r512 + 5);
c = _addcarry_u64(c, r512[6], t[3], r512 + 6);
c = _addcarry_u64(c, r512[7], t[4], r512 + 7);
// Reduce from 512 to 320
imm_umul(r512 + 4, 0x1000003D1ULL, t);
c = _addcarry_u64(0, r512[0], t[0], r512 + 0);
c = _addcarry_u64(c, r512[1], t[1], r512 + 1);
c = _addcarry_u64(c, r512[2], t[2], r512 + 2);
c = _addcarry_u64(c, r512[3], t[3], r512 + 3);
// Reduce from 320 to 256
// No overflow possible here t[4]+c<=0x1000003D1ULL
al = _umul128(t[4] + c, 0x1000003D1ULL, &ah);
c = _addcarry_u64(0, r512[0], al, bits64 + 0);
c = _addcarry_u64(c, r512[1], ah, bits64 + 1);
c = _addcarry_u64(c, r512[2], 0, bits64 + 2);
c = _addcarry_u64(c, r512[3], 0, bits64 + 3);
// Probability of carry here or that this>P is very very unlikely
bits64[4] = 0;
}
void Int::ModSquareK1(Int *a) {
#ifndef WIN64
#if (__GNUC__ > 7) || (__GNUC__ == 7 && (__GNUC_MINOR__ > 2))
unsigned char c;
#else
#warning "GCC lass than 7.3 detected, upgrade gcc to get best perfromance"
volatile unsigned char c;
#endif
#else
unsigned char c;
#endif
uint64_t r512[8];
uint64_t u10, u11;
uint64_t t1;
uint64_t t2;
uint64_t t[5];
//k=0
r512[0] = _umul128(a->bits64[0], a->bits64[0], &t[1]);