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Int.h
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Int.h
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/*
* This file is part of the BSGS distribution (https://github.com/JeanLucPons/VanitySearch).
* Copyright (c) 2020 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/>.
*/
// Big integer class (Fixed size)
#ifndef BIGINTH
#define BIGINTH
#include "Random.h"
#include <string>
#include <inttypes.h>
// We need 1 extra block for Knuth div algorithm , Montgomery multiplication and ModInv
#define BISIZE 256
#if BISIZE==256
#define NB64BLOCK 5
#define NB32BLOCK 10
#elif BISIZE==512
#define NB64BLOCK 9
#define NB32BLOCK 18
#else
#error Unsuported size
#endif
class Int {
public:
Int();
Int(int64_t i64);
Int(uint64_t u64);
Int(Int *a);
// Op
void Add(uint64_t a);
void Add(Int *a);
void Add(Int *a,Int *b);
void AddOne();
void Sub(uint64_t a);
void Sub(Int *a);
void Sub(Int *a, Int *b);
void SubOne();
void Mult(Int *a);
uint64_t Mult(uint64_t a);
uint64_t IMult(int64_t a);
uint64_t Mult(Int *a,uint64_t b);
uint64_t IMult(Int *a, int64_t b);
void Mult(Int *a,Int *b);
void Div(Int *a,Int *mod = NULL);
void MultModN(Int *a, Int *b, Int *n);
void Neg();
void Abs();
// Right shift (signed)
void ShiftR(uint32_t n);
void ShiftR32Bit();
void ShiftR64Bit();
// Left shift
void ShiftL(uint32_t n);
void ShiftL32Bit();
void ShiftL64Bit();
// Bit swap
void SwapBit(int bitNumber);
// Comp
bool IsGreater(Int *a);
bool IsGreaterOrEqual(Int *a);
bool IsLowerOrEqual(Int *a);
bool IsLower(Int *a);
bool IsEqual(Int *a);
bool IsZero();
bool IsOne();
bool IsStrictPositive();
bool IsPositive();
bool IsNegative();
bool IsEven();
bool IsOdd();
bool IsProbablePrime();
double ToDouble();
// Modular arithmetic
// Setup field
// n is the field characteristic
// R used in Montgomery mult (R = 2^size(n))
// R2 = R^2, R3 = R^3, R4 = R^4
static void SetupField(Int *n, Int *R = NULL, Int *R2 = NULL, Int *R3 = NULL, Int *R4 = NULL);
static Int *GetR(); // Return R
static Int *GetR2(); // Return R2
static Int *GetR3(); // Return R3
static Int *GetR4(); // Return R4
static Int* GetFieldCharacteristic(); // Return field characteristic
void GCD(Int *a); // this <- GCD(this,a)
void Mod(Int *n); // this <- this (mod n)
void ModInv(); // this <- this^-1 (mod n)
void MontgomeryMult(Int *a,Int *b); // this <- a*b*R^-1 (mod n)
void MontgomeryMult(Int *a); // this <- this*a*R^-1 (mod n)
void ModAdd(Int *a); // this <- this+a (mod n) [0<a<P]
void ModAdd(Int *a,Int *b); // this <- a+b (mod n) [0<a,b<P]
void ModAdd(uint64_t a); // this <- this+a (mod n) [0<a<P]
void ModSub(Int *a); // this <- this-a (mod n) [0<a<P]
void ModSub(Int *a, Int *b); // this <- a-b (mod n) [0<a,b<P]
void ModSub(uint64_t a); // this <- this-a (mod n) [0<a<P]
void ModMul(Int *a,Int *b); // this <- a*b (mod n)
void ModMul(Int *a); // this <- this*b (mod n)
void ModSquare(Int *a); // this <- a^2 (mod n)
void ModCube(Int *a); // this <- a^3 (mod n)
void ModDouble(); // this <- 2*this (mod n)
void ModExp(Int *e); // this <- this^e (mod n)
void ModNeg(); // this <- -this (mod n)
void ModSqrt(); // this <- +/-sqrt(this) (mod n)
bool HasSqrt(); // true if this admit a square root
// Specific SecpK1
static void InitK1(Int *order);
void ModMulK1(Int *a, Int *b);
void ModMulK1(Int *a);
void ModSquareK1(Int *a);
void ModMulK1order(Int *a);
void ModAddK1order(Int *a,Int *b);
void ModAddK1order(Int *a);
void ModSubK1order(Int *a);
void ModNegK1order();
uint32_t ModPositiveK1();
// Size
int GetSize(); // Number of significant 32bit limbs
int GetSize64(); // Number of significant 64bit limbs
int GetBitLength(); // Number of significant bits
// Setter
void SetInt32(uint32_t value);
void Set(Int *a);
void SetBase10(char *value);
void SetBase16(char *value);
void SetBaseN(int n,char *charset,char *value);
void SetByte(int n,unsigned char byte);
void SetDWord(int n, uint32_t b);
void SetQWord(int n,uint64_t b);
void Rand(int nbit);
void Rand(Int *randMax);
void Set32Bytes(unsigned char *bytes);
void MaskByte(int n);
// Getter
uint32_t GetInt32();
int GetBit(uint32_t n);
unsigned char GetByte(int n);
void Get32Bytes(unsigned char *buff);
// To String
std::string GetBase2();
std::string GetBase10();
std::string GetBase16();
std::string GetBaseN(int n,char *charset);
std::string GetBlockStr();
std::string GetC64Str(int nbDigit);
// Check functions
static void Check();
static bool CheckInv(Int *a);
/*
// Align to 16 bytes boundary
union {
__declspec(align(16)) uint32_t bits[NB32BLOCK];
__declspec(align(16)) uint64_t bits64[NB64BLOCK];
};
*/
union {
uint32_t bits[NB32BLOCK];
uint64_t bits64[NB64BLOCK];
};
private:
void MatrixVecMul(Int *u,Int *v,int64_t _11,int64_t _12,int64_t _21,int64_t _22,uint64_t *cu,uint64_t* cv);
void MatrixVecMul(Int* u,Int* v,int64_t _11,int64_t _12,int64_t _21,int64_t _22);
uint64_t AddCh(Int *a,uint64_t ca,Int* b,uint64_t cb);
uint64_t AddCh(Int* a,uint64_t ca);
uint64_t AddC(Int* a);
void AddAndShift(Int* a,Int* b,uint64_t cH);
void ShiftL64BitAndSub(Int *a,int n);
uint64_t Mult(Int *a, uint32_t b);
int GetLowestBit();
void CLEAR();
void CLEARFF();
void DivStep62(Int* u,Int* v,int64_t* eta,int *pos,int64_t* uu,int64_t* uv,int64_t* vu,int64_t* vv);
};
// Inline routines
#ifndef WIN64
// Missing intrinsics
static uint64_t inline _umul128(uint64_t a, uint64_t b, uint64_t *h) {
uint64_t rhi;
uint64_t rlo;
__asm__( "mulq %[b];" :"=d"(rhi),"=a"(rlo) :"1"(a),[b]"rm"(b));
*h = rhi;
return rlo;
}
static int64_t inline _mul128(int64_t a, int64_t b, int64_t *h) {
uint64_t rhi;
uint64_t rlo;
__asm__( "imulq %[b];" :"=d"(rhi),"=a"(rlo) :"1"(a),[b]"rm"(b));
*h = rhi;
return rlo;
}
static uint64_t inline _udiv128(uint64_t hi, uint64_t lo, uint64_t d,uint64_t *r) {
uint64_t q;
uint64_t _r;
__asm__( "divq %[d];" :"=d"(_r),"=a"(q) :"d"(hi),"a"(lo),[d]"rm"(d));
*r = _r;
return q;
}
static uint64_t inline __rdtsc() {
uint32_t h;
uint32_t l;
__asm__( "rdtsc;" :"=d"(h),"=a"(l));
return (uint64_t)h << 32 | (uint64_t)l;
}
#define __shiftright128(a,b,n) ((a)>>(n))|((b)<<(64-(n)))
#define __shiftleft128(a,b,n) ((b)<<(n))|((a)>>(64-(n)))
#define _subborrow_u64(a,b,c,d) __builtin_ia32_sbb_u64(a,b,c,(long long unsigned int*)d);
#define _addcarry_u64(a,b,c,d) __builtin_ia32_addcarryx_u64(a,b,c,(long long unsigned int*)d);
#define _byteswap_uint64 __builtin_bswap64
#define LZC(x) __builtin_clzll(x)
#define TZC(x) __builtin_ctzll(x)
#else
#include <intrin.h>
#define TZC(x) _tzcnt_u64(x)
#define LZC(x) _lzcnt_u64(x)
#endif
#define LoadI64(i,i64) \
i.bits64[0] = i64; \
i.bits64[1] = i64 >> 63; \
i.bits64[2] = i.bits64[1];\
i.bits64[3] = i.bits64[1];\
i.bits64[4] = i.bits64[1];
static void inline imm_mul(uint64_t *x, uint64_t y, uint64_t *dst,uint64_t *carryH) {
unsigned char c = 0;
uint64_t h, carry;
dst[0] = _umul128(x[0], y, &h); carry = h;
c = _addcarry_u64(c, _umul128(x[1], y, &h), carry, dst + 1); carry = h;
c = _addcarry_u64(c, _umul128(x[2], y, &h), carry, dst + 2); carry = h;
c = _addcarry_u64(c, _umul128(x[3], y, &h), carry, dst + 3); carry = h;
c = _addcarry_u64(c, _umul128(x[4], y, &h), carry, dst + 4); carry = h;
#if NB64BLOCK > 5
c = _addcarry_u64(c, _umul128(x[5], y, &h), carry, dst + 5); carry = h;
c = _addcarry_u64(c, _umul128(x[6], y, &h), carry, dst + 6); carry = h;
c = _addcarry_u64(c, _umul128(x[7], y, &h), carry, dst + 7); carry = h;
c = _addcarry_u64(c, _umul128(x[8], y, &h), carry, dst + 8); carry = h;
#endif
*carryH = carry;
}
static void inline imm_imul(uint64_t* x,uint64_t y,uint64_t* dst,uint64_t* carryH) {
unsigned char c = 0;
uint64_t h,carry;
dst[0] = _umul128(x[0],y,&h); carry = h;
c = _addcarry_u64(c,_umul128(x[1],y,&h),carry,dst + 1); carry = h;
c = _addcarry_u64(c,_umul128(x[2],y,&h),carry,dst + 2); carry = h;
c = _addcarry_u64(c,_umul128(x[3],y,&h),carry,dst + 3); carry = h;
#if NB64BLOCK > 5
c = _addcarry_u64(c,_umul128(x[4],y,&h),carry,dst + 4); carry = h;
c = _addcarry_u64(c,_umul128(x[5],y,&h),carry,dst + 5); carry = h;
c = _addcarry_u64(c,_umul128(x[6],y,&h),carry,dst + 6); carry = h;
c = _addcarry_u64(c,_umul128(x[7],y,&h),carry,dst + 7); carry = h;
#endif
c = _addcarry_u64(c,_mul128(x[NB64BLOCK - 1],y,(int64_t*)&h),carry,dst + NB64BLOCK - 1); carry = h;
* carryH = carry;
}
static void inline imm_umul(uint64_t *x, uint64_t y, uint64_t *dst) {
// Assume that x[NB64BLOCK-1] is 0
unsigned char c = 0;
uint64_t h, carry;
dst[0] = _umul128(x[0], y, &h); carry = h;
c = _addcarry_u64(c, _umul128(x[1], y, &h), carry, dst + 1); carry = h;
c = _addcarry_u64(c, _umul128(x[2], y, &h), carry, dst + 2); carry = h;
c = _addcarry_u64(c, _umul128(x[3], y, &h), carry, dst + 3); carry = h;
#if NB64BLOCK > 5
c = _addcarry_u64(c, _umul128(x[4], y, &h), carry, dst + 4); carry = h;
c = _addcarry_u64(c, _umul128(x[5], y, &h), carry, dst + 5); carry = h;
c = _addcarry_u64(c, _umul128(x[6], y, &h), carry, dst + 6); carry = h;
c = _addcarry_u64(c, _umul128(x[7], y, &h), carry, dst + 7); carry = h;
#endif
_addcarry_u64(c, 0ULL, carry, dst + (NB64BLOCK - 1));
}
static void inline shiftR(unsigned char n, uint64_t *d) {
d[0] = __shiftright128(d[0], d[1], n);
d[1] = __shiftright128(d[1], d[2], n);
d[2] = __shiftright128(d[2], d[3], n);
d[3] = __shiftright128(d[3], d[4], n);
#if NB64BLOCK > 5
d[4] = __shiftright128(d[4], d[5], n);
d[5] = __shiftright128(d[5], d[6], n);
d[6] = __shiftright128(d[6], d[7], n);
d[7] = __shiftright128(d[7], d[8], n);
#endif
d[NB64BLOCK-1] = ((int64_t)d[NB64BLOCK-1]) >> n;
}
static void inline shiftR(unsigned char n,uint64_t* d,uint64_t h) {
d[0] = __shiftright128(d[0],d[1],n);
d[1] = __shiftright128(d[1],d[2],n);
d[2] = __shiftright128(d[2],d[3],n);
d[3] = __shiftright128(d[3],d[4],n);
#if NB64BLOCK > 5
d[4] = __shiftright128(d[4],d[5],n);
d[5] = __shiftright128(d[5],d[6],n);
d[6] = __shiftright128(d[6],d[7],n);
d[7] = __shiftright128(d[7],d[8],n);
#endif
d[NB64BLOCK-1] = __shiftright128(d[NB64BLOCK-1],h,n);
}
static void inline shiftL(unsigned char n, uint64_t *d) {
#if NB64BLOCK > 5
d[8] = __shiftleft128(d[7], d[8], n);
d[7] = __shiftleft128(d[6], d[7], n);
d[6] = __shiftleft128(d[5], d[6], n);
d[5] = __shiftleft128(d[4], d[5], n);
#endif
d[4] = __shiftleft128(d[3], d[4], n);
d[3] = __shiftleft128(d[2], d[3], n);
d[2] = __shiftleft128(d[1], d[2], n);
d[1] = __shiftleft128(d[0], d[1], n);
d[0] = d[0] << n;
}
static inline int isStrictGreater128(uint64_t h1,uint64_t l1,uint64_t h2,uint64_t l2) {
if(h1>h2) return 1;
if(h1==h2) return l1>l2;
return 0;
}
#endif // BIGINTH