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Файл:Документация по криптоалгоритмам / CRYPTO30 / integer
.cpp// integer.cpp - written and placed in the public domain by Wei Dai
#include "pch.h"
#include "integer.h"
#include "modarith.h"
#include "nbtheory.h"
#include "asn.h"
#include "words.h"
#include <iostream>
#include "algebra.cpp"
#include "eprecomp.cpp"
NAMESPACE_BEGIN(CryptoPP)
#define MAKE_DWORD(lowWord, highWord) ((dword(highWord)<<WORD_BITS) | (lowWord))
#if defined(_MSC_VER) && defined(_M_IX86) && (_M_IX86<=500)
// Add() and Subtract() are coded in Pentium assembly for a speed increase
// of about 10-20 percent for a RSA signature
static __declspec(naked) word __fastcall Add(word *C, const word *A, const word *B, unsigned int N)
{
__asm
{
push ebp
push ebx
push esi
push edi
mov esi, [esp+24]
mov ebx, [esp+20]
sub ecx, edx
xor eax, eax
sub eax, esi
lea ebx, [ebx+4*esi]
sar eax, 1 // clears the carry flag
jz loopend
loopstart:
mov esi,[edx]
mov ebp,[edx+4]
mov edi,[ebx+8*eax]
lea edx,[edx+8]
adc esi,edi
mov edi,[ebx+8*eax+4]
adc ebp,edi
inc eax
mov [edx+ecx-8],esi
mov [edx+ecx-4],ebp
jnz loopstart
loopend:
adc eax, 0
pop edi
pop esi
pop ebx
pop ebp
ret 8
}
}
static __declspec(naked) word __fastcall Subtract(word *C, const word *A, const word *B, unsigned int N)
{
__asm
{
push ebp
push ebx
push esi
push edi
mov esi, [esp+24]
mov ebx, [esp+20]
sub ecx, edx
xor eax, eax
sub eax, esi
lea ebx, [ebx+4*esi]
sar eax, 1 // clears the carry flag
jz loopend
loopstart:
mov esi,[edx]
mov ebp,[edx+4]
mov edi,[ebx+8*eax]
lea edx,[edx+8]
sbb esi,edi
mov edi,[ebx+8*eax+4]
sbb ebp,edi
inc eax
mov [edx+ecx-8],esi
mov [edx+ecx-4],ebp
jnz loopstart
loopend:
adc eax, 0
pop edi
pop esi
pop ebx
pop ebp
ret 8
}
}
#else // defined(_MSC_VER) && defined(_M_IX86) && (_M_IX86<=500)
static word Add(word *C, const word *A, const word *B, unsigned int N)
{
assert (N%2 == 0);
word carry=0;
for (unsigned i = 0; i < N; i+=2)
{
dword u = (dword) carry + A[i] + B[i];
C[i] = LOW_WORD(u);
u = (dword) HIGH_WORD(u) + A[i+1] + B[i+1];
C[i+1] = LOW_WORD(u);
carry = HIGH_WORD(u);
}
return carry;
}
static word Subtract(word *C, const word *A, const word *B, unsigned int N)
{
assert (N%2 == 0);
word borrow=0;
for (unsigned i = 0; i < N; i+=2)
{
dword u = (dword) A[i] - B[i] - borrow;
C[i] = LOW_WORD(u);
u = (dword) A[i+1] - B[i+1] - (word)(0-HIGH_WORD(u));
C[i+1] = LOW_WORD(u);
borrow = 0-HIGH_WORD(u);
}
return borrow;
}
#endif // defined(_MSC_VER) && defined(_M_IX86) && (_M_IX86<=500)
static int Compare(const word *A, const word *B, unsigned int N)
{
while (N--)
if (A[N] > B[N])
return 1;
else if (A[N] < B[N])
return -1;
return 0;
}
static word Increment(word *A, unsigned int N, word B=1)
{
assert(N);
word t = A[0];
A[0] = t+B;
if (A[0] >= t)
return 0;
for (unsigned i=1; i<N; i++)
if (++A[i])
return 0;
return 1;
}
static word Decrement(word *A, unsigned int N, word B=1)
{
assert(N);
word t = A[0];
A[0] = t-B;
if (A[0] <= t)
return 0;
for (unsigned i=1; i<N; i++)
if (A[i]--)
return 0;
return 1;
}
static void TwosComplement(word *A, unsigned int N)
{
Decrement(A, N);
for (unsigned i=0; i<N; i++)
A[i] = ~A[i];
}
static word LinearMultiply(word *C, const word *A, word B, unsigned int N)
{
word carry=0;
for(unsigned i=0; i<N; i++)
{
dword p = (dword)A[i] * B + carry;
C[i] = LOW_WORD(p);
carry = HIGH_WORD(p);
}
return carry;
}
static void AtomicMultiply(word *C, word A0, word A1, word B0, word B1)
{
word s;
dword d;
if (A1 >= A0)
if (B0 >= B1)
{
s = 0;
d = (dword)(A1-A0)*(B0-B1);
}
else
{
s = (A1-A0);
d = (dword)s*(word)(B0-B1);
}
else
if (B0 > B1)
{
s = (B0-B1);
d = (word)(A1-A0)*(dword)s;
}
else
{
s = 0;
d = (dword)(A0-A1)*(B1-B0);
}
dword A0B0 = (dword)A0*B0;
C[0] = LOW_WORD(A0B0);
dword A1B1 = (dword)A1*B1;
dword t = (dword) HIGH_WORD(A0B0) + LOW_WORD(A0B0) + LOW_WORD(d) + LOW_WORD(A1B1);
C[1] = LOW_WORD(t);
t = A1B1 + HIGH_WORD(t) + HIGH_WORD(A0B0) + HIGH_WORD(d) + HIGH_WORD(A1B1) - s;
C[2] = LOW_WORD(t);
C[3] = HIGH_WORD(t);
}
static word AtomicMultiplyAdd(word *C, word A0, word A1, word B0, word B1)
{
word s;
dword d;
if (A1 >= A0)
if (B0 >= B1)
{
s = 0;
d = (dword)(A1-A0)*(B0-B1);
}
else
{
s = (A1-A0);
d = (dword)s*(word)(B0-B1);
}
else
if (B0 > B1)
{
s = (B0-B1);
d = (word)(A1-A0)*(dword)s;
}
else
{
s = 0;
d = (dword)(A0-A1)*(B1-B0);
}
dword A0B0 = (dword)A0*B0;
dword t = A0B0 + C[0];
C[0] = LOW_WORD(t);
dword A1B1 = (dword)A1*B1;
t = (dword) HIGH_WORD(t) + LOW_WORD(A0B0) + LOW_WORD(d) + LOW_WORD(A1B1) + C[1];
C[1] = LOW_WORD(t);
t = (dword) HIGH_WORD(t) + LOW_WORD(A1B1) + HIGH_WORD(A0B0) + HIGH_WORD(d) + HIGH_WORD(A1B1) - s + C[2];
C[2] = LOW_WORD(t);
t = (dword) HIGH_WORD(t) + HIGH_WORD(A1B1) + C[3];
C[3] = LOW_WORD(t);
return HIGH_WORD(t);
}
static inline void AtomicSquare(word *C, word A, word B)
{
dword t1 = (dword) A*A;
C[0] = LOW_WORD(t1);
dword t2 = (dword) A*B;
t1 = (dword) HIGH_WORD(t1) + LOW_WORD(t2) + LOW_WORD(t2);
C[1] = LOW_WORD(t1);
t1 = (dword) B*B + HIGH_WORD(t1) + HIGH_WORD(t2) + HIGH_WORD(t2);
C[2] = LOW_WORD(t1);
C[3] = HIGH_WORD(t1);
}
static inline void AtomicMultiplyBottom(word *C, word A0, word A1, word B0, word B1)
{
dword t = (dword)A0*B0;
C[0] = LOW_WORD(t);
C[1] = HIGH_WORD(t) + A0*B1 + A1*B0;
}
static inline void AtomicMultiplyBottomAdd(word *C, word A0, word A1, word B0, word B1)
{
dword t = (dword)A0*B0 + C[0];
C[0] = LOW_WORD(t);
C[1] += HIGH_WORD(t) + A0*B1 + A1*B0;
}
static void CombaMultiply(word *R, const word *A, const word *B)
{
dword p;
word c=0, d=0, e=0;
#define MulAcc(x, y) \
p = (dword)A[x] * B[y] + c; \
c = LOW_WORD(p); \
p = (dword)d + HIGH_WORD(p); \
d = LOW_WORD(p); \
e += HIGH_WORD(p);
#define SaveMulAcc(s, x, y) \
R[s] = c; \
p = (dword)A[x] * B[y] + d; \
c = LOW_WORD(p); \
p = (dword)e + HIGH_WORD(p); \
d = LOW_WORD(p); \
e = HIGH_WORD(p);
p = (dword)A[0] * B[0];
R[0] = LOW_WORD(p);
c = HIGH_WORD(p);
d = e = 0;
MulAcc(0, 1);
MulAcc(1, 0);
SaveMulAcc(1, 2, 0);
MulAcc(1, 1);
MulAcc(0, 2);
SaveMulAcc(2, 0, 3);
MulAcc(1, 2);
MulAcc(2, 1);
MulAcc(3, 0);
SaveMulAcc(3, 3, 1);
MulAcc(2, 2);
MulAcc(1, 3);
SaveMulAcc(4, 2, 3);
MulAcc(3, 2);
R[5] = c;
p = (dword)A[3] * B[3] + d;
R[6] = LOW_WORD(p);
R[7] = e + HIGH_WORD(p);
#undef MulAcc
#undef SaveMulAcc
}
static void AtomicInverseModPower2(word *C, word A0, word A1)
{
assert(A0%2==1);
dword A=MAKE_DWORD(A0, A1), R=A0%8;
for (unsigned i=3; i<2*WORD_BITS; i*=2)
R = R*(2-R*A);
assert(R*A==1);
C[0] = LOW_WORD(R);
C[1] = HIGH_WORD(R);
}
// ********************************************************
#define A0 A
#define A1 (A+N2)
#define B0 B
#define B1 (B+N2)
#define T0 T
#define T1 (T+N2)
#define T2 (T+N)
#define T3 (T+N+N2)
#define R0 R
#define R1 (R+N2)
#define R2 (R+N)
#define R3 (R+N+N2)
// R[2*N] - result = A*B
// T[2*N] - temporary work space
// A[N] --- multiplier
// B[N] --- multiplicant
void RecursiveMultiply(word *R, word *T, const word *A, const word *B, unsigned int N)
{
assert(N>=2 && N%2==0);
if (N==2)
AtomicMultiply(R, A[0], A[1], B[0], B[1]);
else if (N==4)
CombaMultiply(R, A, B);
else
{
const unsigned int N2 = N/2;
int carry;
int aComp = Compare(A0, A1, N2);
int bComp = Compare(B0, B1, N2);
switch (2*aComp + aComp + bComp)
{
case -4:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
Subtract(T1, T1, R0, N2);
carry = -1;
break;
case -2:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
carry = 0;
break;
case 2:
Subtract(R0, A0, A1, N2);
Subtract(R1, B1, B0, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
carry = 0;
break;
case 4:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
Subtract(T1, T1, R1, N2);
carry = -1;
break;
default:
SetWords(T0, 0, N);
carry = 0;
}
RecursiveMultiply(R0, T2, A0, B0, N2);
RecursiveMultiply(R2, T2, A1, B1, N2);
// now T[01] holds (A1-A0)*(B0-B1), R[01] holds A0*B0, R[23] holds A1*B1
carry += Add(T0, T0, R0, N);
carry += Add(T0, T0, R2, N);
carry += Add(R1, R1, T0, N);
assert (carry >= 0 && carry <= 2);
Increment(R3, N2, carry);
}
}
// R[2*N] - result = A*A
// T[2*N] - temporary work space
// A[N] --- number to be squared
void RecursiveSquare(word *R, word *T, const word *A, unsigned int N)
{
assert(N && N%2==0);
if (N==2)
AtomicSquare(R, A[0], A[1]);
else if (N==4)
{
AtomicSquare(R, A[0], A[1]);
AtomicSquare(R+4, A[2], A[3]);
AtomicMultiply(T, A[0], A[1], A[2], A[3]);
word carry = Add(R+2, R+2, T, 4);
carry += Add(R+2, R+2, T, 4);
Increment(R+6, 2, carry);
}
else
{
const unsigned int N2 = N/2;
RecursiveSquare(R0, T2, A0, N2);
RecursiveSquare(R2, T2, A1, N2);
RecursiveMultiply(T0, T2, A0, A1, N2);
word carry = Add(R1, R1, T0, N);
carry += Add(R1, R1, T0, N);
Increment(R3, N2, carry);
}
}
// R[N] - bottom half of A*B
// T[N] - temporary work space
// A[N] - multiplier
// B[N] - multiplicant
void RecursiveMultiplyBottom(word *R, word *T, const word *A, const word *B, unsigned int N)
{
assert(N>=2 && N%2==0);
if (N==2)
AtomicMultiplyBottom(R, A[0], A[1], B[0], B[1]);
else if (N==4)
{
AtomicMultiply(R, A[0], A[1], B[0], B[1]);
AtomicMultiplyBottomAdd(R+2, A[0], A[1], B[2], B[3]);
AtomicMultiplyBottomAdd(R+2, A[2], A[3], B[0], B[1]);
}
else
{
const unsigned int N2 = N/2;
RecursiveMultiply(R, T, A0, B0, N2);
RecursiveMultiplyBottom(T0, T1, A1, B0, N2);
Add(R1, R1, T0, N2);
RecursiveMultiplyBottom(T0, T1, A0, B1, N2);
Add(R1, R1, T0, N2);
}
}
// R[N] --- upper half of A*B
// T[2*N] - temporary work space
// L[N] --- lower half of A*B
// A[N] --- multiplier
// B[N] --- multiplicant
void RecursiveMultiplyTop(word *R, word *T, const word *L, const word *A, const word *B, unsigned int N)
{
assert(N>=2 && N%2==0);
if (N==2)
{
AtomicMultiply(T, A[0], A[1], B[0], B[1]);
R[0] = T[2];
R[1] = T[3];
}
else
{
const unsigned int N2 = N/2;
int carry;
int aComp = Compare(A0, A1, N2);
int bComp = Compare(B0, B1, N2);
switch (2*aComp + aComp + bComp)
{
case -4:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
Subtract(T1, T1, R0, N2);
carry = -1;
break;
case -2:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
carry = 0;
break;
case 2:
Subtract(R0, A0, A1, N2);
Subtract(R1, B1, B0, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
carry = 0;
break;
case 4:
Subtract(R0, A1, A0, N2);
Subtract(R1, B0, B1, N2);
RecursiveMultiply(T0, T2, R0, R1, N2);
Subtract(T1, T1, R1, N2);
carry = -1;
break;
default:
SetWords(T0, 0, N);
carry = 0;
}
RecursiveMultiply(T2, R0, A1, B1, N2);
// now T[01] holds (A1-A0)*(B0-B1), T[23] holds A1*B1
CopyWords(R0, L+N2, N2);
word c2 = Subtract(R0, R0, L, N2);
c2 += Subtract(R0, R0, T0, N2);
word t = (Compare(R0, T2, N2) == -1);
carry += t;
carry += Increment(R0, N2, c2+t);
carry += Add(R0, R0, T1, N2);
carry += Add(R0, R0, T3, N2);
CopyWords(R1, T3, N2);
assert (carry >= 0 && carry <= 2);
Increment(R1, N2, carry);
}
}
// R[NA+NB] - result = A*B
// T[NA+NB] - temporary work space
// A[NA] ---- multiplier
// B[NB] ---- multiplicant
void AsymmetricMultiply(word *R, word *T, const word *A, unsigned int NA, const word *B, unsigned int NB)
{
if (NA == NB)
{
if (A == B)
RecursiveSquare(R, T, A, NA);
else
RecursiveMultiply(R, T, A, B, NA);
return;
}
if (NA > NB)
{
std::swap(A, B);
std::swap(NA, NB);
}
assert(NB % NA == 0);
assert((NB/NA)%2 == 0); // NB is an even multiple of NA
if (NA==2 && !A[1])
{
switch (A[0])
{
case 0:
SetWords(R, 0, NB+2);
return;
case 1:
CopyWords(R, B, NB);
R[NB] = R[NB+1] = 0;
return;
default:
R[NB] = LinearMultiply(R, B, A[0], NB);
R[NB+1] = 0;
return;
}
}
RecursiveMultiply(R, T, A, B, NA);
CopyWords(T+2*NA, R+NA, NA);
unsigned i;
for (i=2*NA; i<NB; i+=2*NA)
RecursiveMultiply(T+NA+i, T, A, B+i, NA);
for (i=NA; i<NB; i+=2*NA)
RecursiveMultiply(R+i, T, A, B+i, NA);
if (Add(R+NA, R+NA, T+2*NA, NB-NA))
Increment(R+NB, NA);
}
// R[N] ----- result = A inverse mod 2**(WORD_BITS*N)
// T[3*N/2] - temporary work space
// A[N] ----- an odd number as input
void RecursiveInverseModPower2(word *R, word *T, const word *A, unsigned int N)
{
if (N==2)
AtomicInverseModPower2(R, A[0], A[1]);
else
{
const unsigned int N2 = N/2;
RecursiveInverseModPower2(R0, T0, A0, N2);
T0[0] = 1;
SetWords(T0+1, 0, N2-1);
RecursiveMultiplyTop(R1, T1, T0, R0, A0, N2);
RecursiveMultiplyBottom(T0, T1, R0, A1, N2);
Add(T0, R1, T0, N2);
TwosComplement(T0, N2);
RecursiveMultiplyBottom(R1, T1, R0, T0, N2);
}
}
// R[N] --- result = X/(2**(WORD_BITS*N)) mod M
// T[3*N] - temporary work space
// X[2*N] - number to be reduced
// M[N] --- modulus
// U[N] --- multiplicative inverse of M mod 2**(WORD_BITS*N)
void MontgomeryReduce(word *R, word *T, const word *X, const word *M, const word *U, unsigned int N)
{
RecursiveMultiplyBottom(R, T, X, U, N);
RecursiveMultiplyTop(T, T+N, X, R, M, N);
if (Subtract(R, X+N, T, N))
{
word carry = Add(R, R, M, N);
assert(carry);
}
}
// R[N] --- result = X/(2**(WORD_BITS*N/2)) mod M
// T[2*N] - temporary work space
// X[2*N] - number to be reduced
// M[N] --- modulus
// U[N/2] - multiplicative inverse of M mod 2**(WORD_BITS*N/2)
// V[N] --- 2**(WORD_BITS*3*N/2) mod M
void HalfMontgomeryReduce(word *R, word *T, const word *X, const word *M, const word *U, const word *V, unsigned int N)
{
assert(N%2==0 && N>=4);
#define M0 M
#define M1 (M+N2)
#define V0 V
#define V1 (V+N2)
#define X0 X
#define X1 (X+N2)
#define X2 (X+N)
#define X3 (X+N+N2)
const unsigned int N2 = N/2;
RecursiveMultiply(T0, T2, V0, X3, N2);
int c2 = Add(T0, T0, X0, N);
RecursiveMultiplyBottom(T3, T2, T0, U, N2);
RecursiveMultiplyTop(T2, R, T0, T3, M0, N2);
c2 -= Subtract(T2, T1, T2, N2);
RecursiveMultiply(T0, R, T3, M1, N2);
c2 -= Subtract(T0, T2, T0, N2);
int c3 = -(int)Subtract(T1, X2, T1, N2);
RecursiveMultiply(R0, T2, V1, X3, N2);
c3 += Add(R, R, T, N);
if (c2>0)
c3 += Increment(R1, N2);
else if (c2<0)
c3 -= Decrement(R1, N2, -c2);
assert(c3>=-1 && c3<=1);
if (c3>0)
Subtract(R, R, M, N);
else if (c3<0)
Add(R, R, M, N);
#undef M0
#undef M1
#undef V0
#undef V1
#undef X0
#undef X1
#undef X2
#undef X3
}
#undef A0
#undef A1
#undef B0
#undef B1
#undef T0
#undef T1
#undef T2
#undef T3
#undef R0
#undef R1
#undef R2
#undef R3
// do a 3 word by 2 word divide, returns quotient and leaves remainder in A
static word SubatomicDivide(word *A, word B0, word B1)
{
// assert {A[2],A[1]} < {B1,B0}, so quotient can fit in a word
assert(A[2] < B1 || (A[2]==B1 && A[1] < B0));
dword p, u;
word Q;
// estimate the quotient: do a 2 word by 1 word divide
if (B1+1 == 0)
Q = A[2];
else
Q = word(MAKE_DWORD(A[1], A[2]) / (B1+1));
// now subtract Q*B from A
p = (dword) B0*Q;
u = (dword) A[0] - LOW_WORD(p);
A[0] = LOW_WORD(u);
u = (dword) A[1] - HIGH_WORD(p) - (word)(0-HIGH_WORD(u)) - (dword)B1*Q;
A[1] = LOW_WORD(u);
A[2] += HIGH_WORD(u);
// Q <= actual quotient, so fix it
while (A[2] || A[1] > B1 || (A[1]==B1 && A[0]>=B0))
{
u = (dword) A[0] - B0;
A[0] = LOW_WORD(u);
u = (dword) A[1] - B1 - (word)(0-HIGH_WORD(u));
A[1] = LOW_WORD(u);
A[2] += HIGH_WORD(u);
Q++;
assert(Q); // shouldn't overflow
}
return Q;
}
// do a 4 word by 2 word divide, returns 2 word quotient in Q0 and Q1
static inline void AtomicDivide(word &Q0, word &Q1, const word *A, word B0, word B1)
{
if (!B0 && !B1) // if divisor is 0, we assume divisor==2**(2*WORD_BITS)
{
Q0 = A[2];
Q1 = A[3];
}
else
{
word T[4];
T[0] = A[0]; T[1] = A[1]; T[2] = A[2]; T[3] = A[3];
Q1 = SubatomicDivide(T+1, B0, B1);
Q0 = SubatomicDivide(T, B0, B1);
#ifndef NDEBUG
// multiply quotient and divisor and add remainder, make sure it equals dividend
assert(!T[2] && !T[3] && (T[1] < B1 || (T[1]==B1 && T[0]<B0)));
word P[4];
AtomicMultiply(P, Q0, Q1, B0, B1);
Add(P, P, T, 4);
assert(memcmp(P, A, 4*WORD_SIZE)==0);
#endif
}
}
// for use by Divide(), corrects the underestimated quotient {Q1,Q0}
static void CorrectQuotientEstimate(word *R, word *T, word &Q0, word &Q1, const word *B, unsigned int N)
{
assert(N && N%2==0);
if (Q1)
{
T[N] = T[N+1] = 0;
unsigned i;
for (i=0; i<N; i+=4)
AtomicMultiply(T+i, Q0, Q1, B[i], B[i+1]);
for (i=2; i<N; i+=4)
if (AtomicMultiplyAdd(T+i, Q0, Q1, B[i], B[i+1]))
T[i+5] += (++T[i+4]==0);
}
else
{
T[N] = LinearMultiply(T, B, Q0, N);
T[N+1] = 0;
}
word borrow = Subtract(R, R, T, N+2);
assert(!borrow && !R[N+1]);
while (R[N] || Compare(R, B, N) >= 0)
{
R[N] -= Subtract(R, R, B, N);
Q1 += (++Q0==0);
assert(Q0 || Q1); // no overflow
}
}
// R[NB] -------- remainder = A%B
// Q[NA-NB+2] --- quotient = A/B
// T[NA+2*NB+4] - temp work space
// A[NA] -------- dividend
// B[NB] -------- divisor
void Divide(word *R, word *Q, word *T, const word *A, unsigned int NA, const word *B, unsigned int NB)
{
assert(NA && NB && NA%2==0 && NB%2==0);
assert(B[NB-1] || B[NB-2]);
assert(NB <= NA);
// set up temporary work space
word *const TA=T;
word *const TB=T+NA+2;
word *const TP=T+NA+2+NB;
// copy B into TB and normalize it so that TB has highest bit set to 1
unsigned shiftWords = (B[NB-1]==0);
TB[0] = TB[NB-1] = 0;
CopyWords(TB+shiftWords, B, NB-shiftWords);
unsigned shiftBits = WORD_BITS - BitPrecision(TB[NB-1]);
assert(shiftBits < WORD_BITS);
ShiftWordsLeftByBits(TB, NB, shiftBits);
// copy A into TA and normalize it
TA[0] = TA[NA] = TA[NA+1] = 0;
CopyWords(TA+shiftWords, A, NA);
ShiftWordsLeftByBits(TA, NA+2, shiftBits);
if (TA[NA+1]==0 && TA[NA] <= 1)
{
Q[NA-NB+1] = Q[NA-NB] = 0;
while (TA[NA] || Compare(TA+NA-NB, TB, NB) >= 0)
{
TA[NA] -= Subtract(TA+NA-NB, TA+NA-NB, TB, NB);
++Q[NA-NB];
}
}
else
{
NA+=2;
assert(Compare(TA+NA-NB, TB, NB) < 0);
}
word B0 = TB[NB-2] + 1;
word B1 = TB[NB-1] + (B0==0);
// start reducing TA mod TB, 2 words at a time
for (unsigned i=NA-2; i>=NB; i-=2)
{
AtomicDivide(Q[i-NB], Q[i-NB+1], TA+i-2, B0, B1);
CorrectQuotientEstimate(TA+i-NB, TP, Q[i-NB], Q[i-NB+1], TB, NB);
}
// copy TA into R, and denormalize it
CopyWords(R, TA+shiftWords, NB);
ShiftWordsRightByBits(R, NB, shiftBits);
}
static inline unsigned int EvenWordCount(const word *X, unsigned int N)
{
while (N && X[N-2]==0 && X[N-1]==0)
N-=2;
return N;
}
// return k
// R[N] --- result = A^(-1) * 2^k mod M
// T[4*N] - temporary work space
// A[NA] -- number to take inverse of
// M[N] --- modulus
unsigned int AlmostInverse(word *R, word *T, const word *A, unsigned int NA, const word *M, unsigned int N)
{
assert(NA<=N && N && N%2==0);
word *b = T;
word *c = T+N;
word *f = T+2*N;
word *g = T+3*N;
unsigned int bcLen=2, fgLen=EvenWordCount(M, N);
unsigned int k=0, s=0;
SetWords(T, 0, 3*N);
b[0]=1;
CopyWords(f, A, NA);
CopyWords(g, M, N);
while (1)
{
word t=f[0];
while (!t)
{
if (EvenWordCount(f, fgLen)==0)
{
SetWords(R, 0, N);
return 0;
}
ShiftWordsRightByWords(f, fgLen, 1);
if (c[bcLen-1]) bcLen+=2;
assert(bcLen <= N);
ShiftWordsLeftByWords(c, bcLen, 1);
k+=WORD_BITS;
t=f[0];
}
unsigned int i=0;
while (t%2 == 0)
{
t>>=1;
i++;
}
k+=i;
if (t==1 && f[1]==0 && EvenWordCount(f, fgLen)==2)
{
if (s%2==0)
CopyWords(R, b, N);
else
Subtract(R, M, b, N);
return k;
}
ShiftWordsRightByBits(f, fgLen, i);
t=ShiftWordsLeftByBits(c, bcLen, i);
if (t)
{
c[bcLen] = t;
bcLen+=2;
assert(bcLen <= N);
}
if (f[fgLen-2]==0 && g[fgLen-2]==0 && f[fgLen-1]==0 && g[fgLen-1]==0)
fgLen-=2;
if (Compare(f, g, fgLen)==-1)
{
std::swap(f, g);
std::swap(b, c);
s++;
}
Subtract(f, f, g, fgLen);
if (Add(b, b, c, bcLen))
{
b[bcLen] = 1;
bcLen+=2;
assert(bcLen <= N);
}
}
}
// R[N] - result = A/(2^k) mod M
// A[N] - input
// M[N] - modulus
void DivideByPower2Mod(word *R, const word *A, unsigned int k, const word *M, unsigned int N)
{
CopyWords(R, A, N);
while (k--)
{
if (R[0]%2==0)
ShiftWordsRightByBits(R, N, 1);
else
{
word carry = Add(R, R, M, N);
ShiftWordsRightByBits(R, N, 1);
R[N-1] += carry<<(WORD_BITS-1);
}
}
}
// R[N] - result = A*(2^k) mod M
// A[N] - input
// M[N] - modulus
void MultiplyByPower2Mod(word *R, const word *A, unsigned int k, const word *M, unsigned int N)
{
CopyWords(R, A, N);
while (k--)
if (ShiftWordsLeftByBits(R, N, 1) || Compare(R, M, N)>=0)
Subtract(R, R, M, N);
}
// ******************************************************************
static const unsigned int RoundupSizeTable[] = {2, 2, 2, 4, 4, 8, 8, 8, 8};
static inline unsigned int RoundupSize(unsigned int n)
{
if (n<=8)
return RoundupSizeTable[n];
else if (n<=16)
return 16;
else if (n<=32)
return 32;
else if (n<=64)
return 64;
else return 1U << BitPrecision(n-1);
}
Integer::Integer()
: reg(2), sign(POSITIVE)
{
reg[0] = reg[1] = 0;
}
Integer::Integer(const Integer& t)
: reg(RoundupSize(t.WordCount())), sign(t.sign)
{
CopyWords(reg, t.reg, reg.size);
}
Integer::Integer(signed long value)
: reg(2)
{
if (value >= 0)
sign = POSITIVE;
else
{
sign = NEGATIVE;
value = -value;
}
reg[0] = word(value);
reg[1] = sizeof(value)>WORD_SIZE ? word(value>>WORD_BITS) : 0;
}
signed long Integer::ConvertToLong() const
{
unsigned long value = reg[0];
value += sizeof(value)>WORD_SIZE ? ((unsigned long)reg[1]<<WORD_BITS) : 0;
return sign==POSITIVE ? value : -long(value);
}
Integer::Integer(const byte *encodedInteger, unsigned int byteCount, Signedness s)
{
Decode(encodedInteger, byteCount, s);
}
Integer::Integer(const byte *BEREncodedInteger)
{
BERDecode(BEREncodedInteger);
}
Integer::Integer(BufferedTransformation &bt)
{
BERDecode(bt);
}
Integer::Integer(RandomNumberGenerator &rng, unsigned int bitcount)
{
Randomize(rng, bitcount);
}
Integer::Integer(RandomNumberGenerator &rng, const Integer &min, const Integer &max, RandomNumberType rnType, const Integer &equiv, const Integer &mod)
{
if (!Randomize(rng, min, max, rnType, equiv, mod))
throw Integer::RandomNumberNotFound();
}
Integer Integer::Power2(unsigned int e)
{
Integer r((word)0, bitsToWords(e+1));
r.SetBit(e);
return r;
}
const Integer &Integer::Zero()
{
static const Integer zero;
return zero;
}
const Integer &Integer::One()
{
static const Integer one(1,2);
return one;
}
bool Integer::operator!() const
{
return IsNegative() ? false : (reg[0]==0 && WordCount()==0);
}
Integer& Integer::operator=(const Integer& t)
{
if (this != &t)
{
reg.New(RoundupSize(t.WordCount()));
CopyWords(reg, t.reg, reg.size);
sign = t.sign;
}
return *this;
}
bool Integer::GetBit(unsigned int n) const
{
if (n/WORD_BITS >= reg.size)
return 0;
else
return bool((reg[n/WORD_BITS] >> (n % WORD_BITS)) & 1);
}
void Integer::SetBit(unsigned int n, bool value)
{
if (value)
{
reg.CleanGrow(RoundupSize(bitsToWords(n+1)));
reg[n/WORD_BITS] |= (word(1) << (n%WORD_BITS));
}
else
{
if (n/WORD_BITS < reg.size)
reg[n/WORD_BITS] &= ~(word(1) << (n%WORD_BITS));
}
}
byte Integer::GetByte(unsigned int n) const
{
if (n/WORD_SIZE >= reg.size)
return 0;
else
return byte(reg[n/WORD_SIZE] >> ((n%WORD_SIZE)*8));
}
void Integer::SetByte(unsigned int n, byte value)
{
reg.CleanGrow(RoundupSize(bytesToWords(n+1)));
reg[n/WORD_SIZE] &= ~(word(0xff) << 8*(n%WORD_SIZE));
reg[n/WORD_SIZE] |= (word(value) << 8*(n%WORD_SIZE));
}
Integer Integer::operator-() const
{
Integer result(*this);
result.Negate();
return result;
}
Integer Integer::AbsoluteValue() const
{
Integer result(*this);
result.sign = POSITIVE;
return result;
}
void Integer::swap(Integer &a)
{
reg.swap(a.reg);
std::swap(sign, a.sign);
}
Integer::Integer(word value, unsigned int length)
: reg(RoundupSize(length)), sign(POSITIVE)
{
reg[0] = value;
SetWords(reg+1, 0, reg.size-1);
}
Integer::Integer(const char *str)
: reg(2), sign(POSITIVE)
{
word radix;
unsigned length = strlen(str);
SetWords(reg, 0, 2);
if (length == 0)
return;
switch (str[length-1])
{
case 'h':
case 'H':
radix=16;
break;
case 'o':
case 'O':
radix=8;
break;
case 'b':
case 'B':
radix=2;
break;
default:
radix=10;
}
for (unsigned i=0; i<length; i++)
{
word digit;
if (str[i] >= '0' && str[i] <= '9')
digit = str[i] - '0';
else if (str[i] >= 'A' && str[i] <= 'F')
digit = str[i] - 'A' + 10;
else if (str[i] >= 'a' && str[i] <= 'f')
digit = str[i] - 'a' + 10;
else
digit = radix;
if (digit < radix)
{
*this *= radix;
*this += digit;
}
}
if (str[0] == '-')
Negate();
}
unsigned int Integer::WordCount() const
{
return CountWords(reg, reg.size);
}
unsigned int Integer::ByteCount() const
{
unsigned wordCount = WordCount();
if (wordCount)
return (wordCount-1)*WORD_SIZE + BytePrecision(reg[wordCount-1]);
else
return 0;
}
unsigned int Integer::BitCount() const
{
unsigned wordCount = WordCount();
if (wordCount)
return (wordCount-1)*WORD_BITS + BitPrecision(reg[wordCount-1]);
else
return 0;
}
void Integer::Decode(const byte *input, unsigned int inputLen, Signedness s)
{
sign = ((s==SIGNED) && (input[0] & 0x80)) ? NEGATIVE : POSITIVE;
while (inputLen>0 && input[0]==0)
{
input++;
inputLen--;
}
reg.CleanNew(RoundupSize(bytesToWords(inputLen)));
for (unsigned i=0; i<inputLen; i++)
reg[i/WORD_SIZE] |= input[inputLen-1-i] << (i%WORD_SIZE)*8;
if (sign == NEGATIVE)
{
for (unsigned i=inputLen; i<reg.size*WORD_SIZE; i++)
reg[i/WORD_SIZE] |= 0xff << (i%WORD_SIZE)*8;
TwosComplement(reg, reg.size);
}
}
unsigned int Integer::MinEncodedSize(Signedness signedness) const
{
unsigned int outputLen = STDMAX(1U, ByteCount());
if (signedness == UNSIGNED)
return outputLen;
if (NotNegative() && (GetByte(outputLen-1) & 0x80))
outputLen++;
if (IsNegative() && *this < -Power2(outputLen*8-1))
outputLen++;
return outputLen;
}
unsigned int Integer::Encode(byte *output, unsigned int outputLen, Signedness signedness) const
{
if (signedness == UNSIGNED || NotNegative())
{
for (unsigned i=0; i<outputLen; i++)
output[i]=GetByte(outputLen-i-1);
}
else
{
// take two's complement of *this
Integer temp = Integer::Power2(8*STDMAX(ByteCount(), outputLen)) + *this;
for (unsigned i=0; i<outputLen; i++)
output[i]=temp.GetByte(outputLen-i-1);
}
return outputLen;
}
unsigned int Integer::DEREncode(byte *output) const
{
unsigned int i=0;
output[i++] = INTEGER;
unsigned int bc = MinEncodedSize(SIGNED);
SecByteBlock buf(bc);
Encode(buf, bc, SIGNED);
i += DERLengthEncode(bc, output+i);
memcpy(output+i, buf, bc);
return i+bc;
}
unsigned int Integer::DEREncode(BufferedTransformation &bt) const
{
bt.Put(INTEGER);
unsigned int bc = MinEncodedSize(SIGNED);
SecByteBlock buf(bc);
Encode(buf, bc, SIGNED);
unsigned int lengthBytes = DERLengthEncode(bc, bt);
bt.Put(buf, bc);
return 1+lengthBytes+bc;
}
void Integer::BERDecode(const byte *input)
{
if (*input++ != INTEGER)
BERDecodeError();
int bc;
if (!(*input & 0x80))
bc = *input++;
else
{
int lengthBytes = *input++ & 0x7f;
if (lengthBytes > 2)
BERDecodeError();
bc = *input++;
if (lengthBytes > 1)
bc = (bc << 8) | *input++;
}
Decode(input, bc, SIGNED);
}
void Integer::BERDecode(BufferedTransformation &bt)
{
byte b;
if (!bt.Get(b) || b != INTEGER)
BERDecodeError();
unsigned int bc;
BERLengthDecode(bt, bc);
SecByteBlock buf(bc);
if (bc != bt.Get(buf, bc))
BERDecodeError();
Decode(buf, bc, SIGNED);
}
void Integer::Randomize(RandomNumberGenerator &rng, unsigned int nbits)
{
const unsigned int nbytes = nbits/8 + 1;
SecByteBlock buf(nbytes);
rng.GetBlock(buf, nbytes);
if (nbytes)
buf[0] = (byte)Crop(buf[0], nbits % 8);
Decode(buf, nbytes, UNSIGNED);
}
void Integer::Randomize(RandomNumberGenerator &rng, const Integer &min, const Integer &max)
{
assert(max >= min);
Integer range = max - min;
const unsigned int nbits = range.BitCount();
do
{
Randomize(rng, nbits);
}
while (*this > range);
*this += min;
}
bool Integer::Randomize(RandomNumberGenerator &rng, const Integer &min, const Integer &max, RandomNumberType rnType, const Integer &equiv, const Integer &mod)
{
assert(!equiv.IsNegative() && equiv < mod);
switch (rnType)
{
case ANY:
if (mod == One())
Randomize(rng, min, max);
else
{
Integer min1 = min + (equiv-min)%mod;
if (max < min1)
return false;
Randomize(rng, Zero(), (max - min1) / mod);
*this *= mod;
*this += min1;
}
return true;
case PRIME:
int i;
i = 0;
while (1)
{
if (++i==16)
{
// check if there are any suitable primes in [min, max]
Integer first = min;
if (FirstPrime(first, max, equiv, mod))
{
// if there is only one suitable prime, we're done
*this = first;
if (!FirstPrime(first, max, equiv, mod))
return true;
}
else
return false;
}
Randomize(rng, min, max);
if (FirstPrime(*this, STDMIN(*this+mod*PrimeSearchInterval(max), max), equiv, mod))
return true;
}
default:
assert(false);
return false;
}
}
std::istream& operator>>(std::istream& in, Integer &a)
{
char c;
unsigned int length = 0;
SecBlock<char> str(length + 16);
std::ws(in);
do
{
in.read(&c, 1);
str[length++] = c;
if (length >= str.size)
str.Grow(length + 16);
}
while (in && (c=='-' || (c>='0' && c<='9') || (c>='a' && c<='f') || (c>='A' && c<='F') || c=='h' || c=='H' || c=='o' || c=='O' || c==',' || c=='.'));
if (in.gcount())
in.putback(c);
str[length-1] = '\0';
a = Integer(str);
return in;
}
std::ostream& operator<<(std::ostream& out, const Integer &a)
{
// Get relevant conversion specifications from ostream.
long f = out.flags() & std::ios::basefield; // Get base digits.
int base, block;
char suffix;
switch(f)
{
case std::ios::oct :
base = 8;
block = 8;
suffix = 'o';
break;
case std::ios::hex :
base = 16;
block = 4;
suffix = 'h';
break;
default :
base = 10;
block = 3;
suffix = '.';
}
SecBlock<char> s(a.BitCount() / (BitPrecision(base)-1) + 1);
Integer temp1=a, temp2;
unsigned i=0;
const char vec[]="0123456789ABCDEF";
if (a.IsNegative())
{
out << '-';
temp1.Negate();
}
if (!a)
out << '0';
while (!!temp1)
{
s[i++]=vec[Integer::ShortDivide(temp2, temp1, base)];
temp1=temp2;
}
while (i--)
{
out << s[i];
if (i && !(i%block))
out << ",";
}
return out << suffix;
}
Integer& Integer::operator++()
{
if (NotNegative())
{
if (Increment(reg, reg.size))
{
reg.CleanGrow(2*reg.size);
reg[reg.size/2]=1;
}
}
else
{
word borrow = Decrement(reg, reg.size);
assert(!borrow);
if (WordCount()==0)
*this = Zero();
}
return *this;
}
Integer& Integer::operator--()
{
if (IsNegative())
{
if (Increment(reg, reg.size))
{
reg.CleanGrow(2*reg.size);
reg[reg.size/2]=1;
}
}
else
{
if (Decrement(reg, reg.size))
*this = -One();
}
return *this;
}
void PositiveAdd(Integer &sum, const Integer &a, const Integer& b)
{
word carry;
if (a.reg.size == b.reg.size)
carry = Add(sum.reg, a.reg, b.reg, a.reg.size);
else if (a.reg.size > b.reg.size)
{
carry = Add(sum.reg, a.reg, b.reg, b.reg.size);
CopyWords(sum.reg+b.reg.size, a.reg+b.reg.size, a.reg.size-b.reg.size);
carry = Increment(sum.reg+b.reg.size, a.reg.size-b.reg.size, carry);
}
else
{
carry = Add(sum.reg, a.reg, b.reg, a.reg.size);
CopyWords(sum.reg+a.reg.size, b.reg+a.reg.size, b.reg.size-a.reg.size);
carry = Increment(sum.reg+a.reg.size, b.reg.size-a.reg.size, carry);
}
if (carry)
{
sum.reg.CleanGrow(2*sum.reg.size);
sum.reg[sum.reg.size/2] = 1;
}
sum.sign = Integer::POSITIVE;
}
void PositiveSubtract(Integer &diff, const Integer &a, const Integer& b)
{
unsigned aSize = a.WordCount();
aSize += aSize%2;
unsigned bSize = b.WordCount();
bSize += bSize%2;
if (aSize == bSize)
{
if (Compare(a.reg, b.reg, aSize) >= 0)
{
Subtract(diff.reg, a.reg, b.reg, aSize);
diff.sign = Integer::POSITIVE;
}
else
{
Subtract(diff.reg, b.reg, a.reg, aSize);
diff.sign = Integer::NEGATIVE;
}
}
else if (aSize > bSize)
{
word borrow = Subtract(diff.reg, a.reg, b.reg, bSize);
CopyWords(diff.reg+bSize, a.reg+bSize, aSize-bSize);
borrow = Decrement(diff.reg+bSize, aSize-bSize, borrow);
assert(!borrow);
diff.sign = Integer::POSITIVE;
}
else
{
word borrow = Subtract(diff.reg, b.reg, a.reg, aSize);
CopyWords(diff.reg+aSize, b.reg+aSize, bSize-aSize);
borrow = Decrement(diff.reg+aSize, bSize-aSize, borrow);
assert(!borrow);
diff.sign = Integer::NEGATIVE;
}
}
Integer operator+(const Integer &a, const Integer& b)
{
Integer sum((word)0, STDMAX(a.reg.size, b.reg.size));
if (a.NotNegative())
{
if (b.NotNegative())
PositiveAdd(sum, a, b);
else
PositiveSubtract(sum, a, b);
}
else
{
if (b.NotNegative())
PositiveSubtract(sum, b, a);
else
{
PositiveAdd(sum, a, b);
sum.sign = Integer::NEGATIVE;
}
}
return sum;
}
Integer& Integer::operator+=(const Integer& t)
{
reg.CleanGrow(t.reg.size);
if (NotNegative())
{
if (t.NotNegative())
PositiveAdd(*this, *this, t);
else
PositiveSubtract(*this, *this, t);
}
else
{
if (t.NotNegative())
PositiveSubtract(*this, t, *this);
else
{
PositiveAdd(*this, *this, t);
sign = Integer::NEGATIVE;
}
}
return *this;
}
Integer operator-(const Integer &a, const Integer& b)
{
Integer diff((word)0, STDMAX(a.reg.size, b.reg.size));
if (a.NotNegative())
{
if (b.NotNegative())
PositiveSubtract(diff, a, b);
else
PositiveAdd(diff, a, b);
}
else
{
if (b.NotNegative())
{
PositiveAdd(diff, a, b);
diff.sign = Integer::NEGATIVE;
}
else
PositiveSubtract(diff, b, a);
}
return diff;
}
Integer& Integer::operator-=(const Integer& t)
{
reg.CleanGrow(t.reg.size);
if (NotNegative())
{
if (t.NotNegative())
PositiveSubtract(*this, *this, t);
else
PositiveAdd(*this, *this, t);
}
else
{
if (t.NotNegative())
{
PositiveAdd(*this, *this, t);
sign = Integer::NEGATIVE;
}
else
PositiveSubtract(*this, t, *this);
}
return *this;
}
Integer& Integer::operator<<=(unsigned int n)
{
const unsigned int wordCount = WordCount();
const unsigned int shiftWords = n / WORD_BITS;
const unsigned int shiftBits = n % WORD_BITS;
reg.CleanGrow(RoundupSize(wordCount+bitsToWords(n)));
ShiftWordsLeftByWords(reg, wordCount + shiftWords, shiftWords);
ShiftWordsLeftByBits(reg+shiftWords, wordCount+bitsToWords(shiftBits), shiftBits);
return *this;
}
Integer& Integer::operator>>=(unsigned int n)
{
const unsigned int wordCount = WordCount();
const unsigned int shiftWords = n / WORD_BITS;
const unsigned int shiftBits = n % WORD_BITS;
ShiftWordsRightByWords(reg, wordCount, shiftWords);
if (wordCount > shiftWords)
ShiftWordsRightByBits(reg, wordCount-shiftWords, shiftBits);
if (IsNegative() && WordCount()==0) // avoid -0
*this = Zero();
return *this;
}
void PositiveMultiply(Integer &product, const Integer &a, const Integer &b)
{
unsigned aSize = RoundupSize(a.WordCount());
unsigned bSize = RoundupSize(b.WordCount());
product.reg.CleanNew(RoundupSize(aSize+bSize));
product.sign = Integer::POSITIVE;
SecWordBlock workspace(aSize + bSize);
AsymmetricMultiply(product.reg, workspace, a.reg, aSize, b.reg, bSize);
}
void Multiply(Integer &product, const Integer &a, const Integer &b)
{
PositiveMultiply(product, a, b);
if (a.NotNegative() != b.NotNegative())
product.Negate();
}
Integer operator*(const Integer &a, const Integer &b)
{
Integer product;
Multiply(product, a, b);
return product;
}
/*
void PositiveDivide(Integer &remainder, Integer "ient,
const Integer ÷nd, const Integer &divisor)
{
remainder.reg.CleanNew(divisor.reg.size);
remainder.sign = Integer::POSITIVE;
quotient.reg.New(0);
quotient.sign = Integer::POSITIVE;
unsigned i=dividend.BitCount();
while (i--)
{
word overflow = ShiftWordsLeftByBits(remainder.reg, remainder.reg.size, 1);
remainder.reg[0] |= dividend[i];
if (overflow || remainder >= divisor)
{
Subtract(remainder.reg, remainder.reg, divisor.reg, remainder.reg.size);
quotient.SetBit(i);
}
}
}
*/
void PositiveDivide(Integer &remainder, Integer "ient,
const Integer &a, const Integer &b)
{
unsigned aSize = a.WordCount();
unsigned bSize = b.WordCount();
if (!bSize)
throw Integer::DivideByZero();
if (a.PositiveCompare(b) == -1)
{
remainder = a;
remainder.sign = Integer::POSITIVE;
quotient = Integer::Zero();
return;
}
aSize += aSize%2; // round up to next even number
bSize += bSize%2;
remainder.reg.CleanNew(RoundupSize(bSize));
remainder.sign = Integer::POSITIVE;
quotient.reg.CleanNew(RoundupSize(aSize-bSize+2));
quotient.sign = Integer::POSITIVE;
SecWordBlock T(aSize+2*bSize+4);
Divide(remainder.reg, quotient.reg, T, a.reg, aSize, b.reg, bSize);
}
void Integer::Divide(Integer &remainder, Integer "ient, const Integer ÷nd, const Integer &divisor)
{
PositiveDivide(remainder, quotient, dividend, divisor);
if (dividend.IsNegative())
{
quotient.Negate();
if (!!remainder)
{
--quotient;
remainder = divisor.AbsoluteValue() - remainder;
}
}
if (divisor.IsNegative())
quotient.Negate();
}
Integer operator/(const Integer &a, const Integer &b)
{
Integer remainder, quotient;
Integer::Divide(remainder, quotient, a, b);
return quotient;
}
Integer operator%(const Integer &a, const Integer &b)
{
Integer remainder, quotient;
Integer::Divide(remainder, quotient, a, b);
return remainder;
}
word Integer::ShortDivide(Integer "ient, const Integer ÷nd, word divisor)
{
if (!divisor)
throw Integer::DivideByZero();
assert(divisor);
if ((divisor & (divisor-1)) == 0) // divisor is a power of 2
{
quotient = dividend >> (BitPrecision(divisor)-1);
return dividend.reg[0] & (divisor-1);
}
unsigned int i = dividend.WordCount();
quotient.reg.CleanNew(RoundupSize(i));
word remainder = 0;
while (i--)
{
quotient.reg[i] = word(MAKE_DWORD(dividend.reg[i], remainder) / divisor);
remainder = word(MAKE_DWORD(dividend.reg[i], remainder) % divisor);
}
if (dividend.NotNegative())
quotient.sign = POSITIVE;
else
{
quotient.sign = NEGATIVE;
if (remainder)
{
--quotient;
remainder = divisor - remainder;
}
}
return remainder;
}
Integer operator/(const Integer &a, word b)
{
Integer quotient;
Integer::ShortDivide(quotient, a, b);
return quotient;
}
word operator%(const Integer ÷nd, word divisor)
{
if (!divisor)
throw Integer::DivideByZero();
assert(divisor);
word remainder;
if ((divisor & (divisor-1)) == 0) // divisor is a power of 2
remainder = dividend.reg[0] & (divisor-1);
else
{
unsigned int i = dividend.WordCount();
if (divisor <= 5)
{
dword sum=0;
while (i--)
sum += dividend.reg[i];
remainder = word(sum%divisor);
}
else
{
remainder = 0;
while (i--)
remainder = word(MAKE_DWORD(dividend.reg[i], remainder) % divisor);
}
}
if (dividend.IsNegative() && remainder)
remainder = divisor - remainder;
return remainder;
}
void Integer::Negate()
{
if (!!(*this)) // don't flip sign if *this==0
sign = Sign(1-sign);
}
int Integer::PositiveCompare(const Integer& t) const
{
unsigned size = WordCount(), tSize = t.WordCount();
if (size == tSize)
return CryptoPP::Compare(reg, t.reg, size);
else
return size > tSize ? 1 : -1;
}
int Integer::Compare(const Integer& t) const
{
if (NotNegative())
{
if (t.NotNegative())
return PositiveCompare(t);
else
return 1;
}
else
{
if (t.NotNegative())
return -1;
else
return -PositiveCompare(t);
}
}
Integer Integer::SquareRoot() const
{
if (!IsPositive())
return Zero();
// overestimate square root
Integer x, y = Power2((BitCount()+1)/2);
assert(y*y >= *this);
do
{
x = y;
y = (x + *this/x) >> 1;
} while (y<x);
return x;
}
bool Integer::IsSquare() const
{
Integer r = SquareRoot();
return *this == r.Squared();
}
bool Integer::IsUnit() const
{
return (WordCount() == 1) && (reg[0] == 1);
}
Integer Integer::MultiplicativeInverse() const
{
return IsUnit() ? *this : Zero();
}
Integer a_times_b_mod_c(const Integer &x, const Integer& y, const Integer& m)
{
return x*y%m;
}
Integer a_exp_b_mod_c(const Integer &x, const Integer& e, const Integer& m)
{
if (m.IsEven())
{
ModularArithmetic mr(m);
return mr.ConvertOut(mr.Exponentiate(mr.ConvertIn(x), e));
}
else
{
MontgomeryRepresentation mr(m);
return mr.ConvertOut(mr.Exponentiate(mr.ConvertIn(x), e));
}
}
Integer Integer::Gcd(const Integer &a, const Integer &b)
{
return EuclideanDomainOf<Integer>().Gcd(a, b);
}
Integer Integer::InverseMod(const Integer &m) const
{
assert(m.NotNegative());
if (IsNegative() || *this>=m)
return (*this%m).InverseMod(m);
if (m.IsEven())
{
if (!m || IsEven())
return Zero(); // no inverse
if (*this == One())
return One();
Integer u = m.InverseMod(*this);
return !u ? Zero() : (m*(*this-u)+1)/(*this);
}
SecBlock<word> T(m.reg.size * 4);
Integer r((word)0, m.reg.size);
unsigned k = AlmostInverse(r.reg, T, reg, reg.size, m.reg, m.reg.size);
DivideByPower2Mod(r.reg, r.reg, k, m.reg, m.reg.size);
return r;
}
word Integer::InverseMod(const word mod) const
{
word g0 = mod, g1 = *this % mod;
word v0 = 0, v1 = 1;
word y;
while (g1)
{
if (g1 == 1)
return v1;
y = g0 / g1;
g0 = g0 % g1;
v0 += y * v1;
if (!g0)
break;
if (g0 == 1)
return mod-v0;
y = g1 / g0;
g1 = g1 % g0;
v1 += y * v0;
}
return 0;
}
// ********************************************************
Integer ModularArithmetic::Add(const Integer &a, const Integer &b) const
{
if (a.reg.size==modulus.reg.size && b.reg.size==modulus.reg.size)
{
if (CryptoPP::Add(result.reg.ptr, a.reg, b.reg, a.reg.size)
|| Compare(result.reg, modulus.reg, a.reg.size) >= 0)
{
CryptoPP::Subtract(result.reg.ptr, result.reg, modulus.reg, a.reg.size);
}
return result;
}
else
{Integer r=a+b; if (r>=modulus) r-=modulus; return r;}
}
Integer& ModularArithmetic::Accumulate(Integer &a, const Integer &b) const
{
if (a.reg.size==modulus.reg.size && b.reg.size==modulus.reg.size)
{
if (CryptoPP::Add(a.reg, a.reg, b.reg, a.reg.size)
|| Compare(a.reg, modulus.reg, a.reg.size) >= 0)
{
CryptoPP::Subtract(a.reg, a.reg, modulus.reg, a.reg.size);
}
}
else
{a+=b; if (a>=modulus) a-=modulus;}
return a;
}
Integer ModularArithmetic::Subtract(const Integer &a, const Integer &b) const
{
if (a.reg.size==modulus.reg.size && b.reg.size==modulus.reg.size)
{
if (CryptoPP::Subtract(result.reg.ptr, a.reg, b.reg, a.reg.size))
CryptoPP::Add(result.reg.ptr, result.reg, modulus.reg, a.reg.size);
return result;
}
else
return Add(a, Inverse(b));
}
Integer& ModularArithmetic::Reduce(Integer &a, const Integer &b) const
{
if (a.reg.size==modulus.reg.size && b.reg.size==modulus.reg.size)
{
if (CryptoPP::Subtract(a.reg, a.reg, b.reg, a.reg.size))
CryptoPP::Add(a.reg, a.reg, modulus.reg, a.reg.size);
}
else
Accumulate(a, Inverse(b));
return a;
}
Integer ModularArithmetic::Inverse(const Integer &a) const
{
if (!a)
return a;
CopyWords(result.reg.ptr, modulus.reg, modulus.reg.size);
if (CryptoPP::Subtract(result.reg.ptr, result.reg, a.reg, a.reg.size))
Decrement(result.reg.ptr+a.reg.size, 1, modulus.reg.size-a.reg.size);
return result;
}
Integer ModularArithmetic::MultiplicativeInverse(const Integer &a) const
{
return a.InverseMod(modulus);
}
Integer ModularArithmetic::Exponentiate(const Integer &a, const Integer &e) const
{
if (modulus.IsOdd())
{
MontgomeryRepresentation dr(modulus);
return dr.ConvertOut(dr.Exponentiate(dr.ConvertIn(a), e));
}
else
return AbstractRing<Integer>::Exponentiate(a, e);
}
Integer ModularArithmetic::CascadeExponentiate(const Integer &x, const Integer &e1, const Integer &y, const Integer &e2) const
{
if (modulus.IsOdd())
{
MontgomeryRepresentation dr(modulus);
return dr.ConvertOut(dr.CascadeExponentiate(dr.ConvertIn(x), e1, dr.ConvertIn(y), e2));
}
else
return AbstractRing<Integer>::CascadeExponentiate(x, e1, y, e2);
}
MontgomeryRepresentation::MontgomeryRepresentation(const Integer &m) // modulus must be odd
: ModularArithmetic(m),
u((word)0, modulus.reg.size),
workspace(5*modulus.reg.size)
{
assert(modulus.IsOdd());
RecursiveInverseModPower2(u.reg, workspace, modulus.reg, modulus.reg.size);
}
Integer MontgomeryRepresentation::Multiply(const Integer &a, const Integer &b) const
{
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N && b.reg.size<=N);
AsymmetricMultiply(T, T+2*N, a.reg, a.reg.size, b.reg, b.reg.size);
SetWords(T+a.reg.size+b.reg.size, 0, 2*N-a.reg.size-b.reg.size);
MontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, N);
return result;
}
Integer MontgomeryRepresentation::Square(const Integer &a) const
{
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N);
RecursiveSquare(T, T+2*N, a.reg, a.reg.size);
SetWords(T+2*a.reg.size, 0, 2*N-2*a.reg.size);
MontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, N);
return result;
}
Integer MontgomeryRepresentation::ConvertOut(const Integer &a) const
{
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N);
CopyWords(T, a.reg, a.reg.size);
SetWords(T+a.reg.size, 0, 2*N-a.reg.size);
MontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, N);
return result;
}
Integer MontgomeryRepresentation::MultiplicativeInverse(const Integer &a) const
{
// return (EuclideanMultiplicativeInverse(a, modulus)<<(2*WORD_BITS*modulus.reg.size))%modulus;
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N);
CopyWords(T, a.reg, a.reg.size);
SetWords(T+a.reg.size, 0, 2*N-a.reg.size);
MontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, N);
unsigned k = AlmostInverse(R, T, R, N, modulus.reg, N);
// cout << "k=" << k << " N*32=" << 32*N << endl;
if (k>N*WORD_BITS)
DivideByPower2Mod(R, R, k-N*WORD_BITS, modulus.reg, N);
else
MultiplyByPower2Mod(R, R, N*WORD_BITS-k, modulus.reg, N);
return result;
}
HalfMontgomeryRepresentation::HalfMontgomeryRepresentation(const Integer &m) // modulus must be odd
: ModularArithmetic(m),
v((modulus.reg.CleanGrow(4), Integer::Power2(3*WORD_BITS*modulus.reg.size/2)%modulus)),
u((word)0, modulus.reg.size/2),
workspace(4*modulus.reg.size)
{
assert(modulus.IsOdd());
result.reg.Grow(4);
v.reg.CleanGrow(modulus.reg.size);
RecursiveInverseModPower2(u.reg, workspace, modulus.reg, modulus.reg.size/2);
}
Integer HalfMontgomeryRepresentation::Multiply(const Integer &a, const Integer &b) const
{
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N && b.reg.size<=N);
AsymmetricMultiply(T, T+2*N, a.reg, a.reg.size, b.reg, b.reg.size);
SetWords(T+a.reg.size+b.reg.size, 0, 2*N-a.reg.size-b.reg.size);
HalfMontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, v.reg, N);
return result;
}
Integer HalfMontgomeryRepresentation::Square(const Integer &a) const
{
word *const T = workspace.ptr;
const unsigned int N = modulus.reg.size;
word *const R = result.reg.ptr;
assert(a.reg.size<=N);
RecursiveSquare(T, T+2*N, a.reg, a.reg.size);
SetWords(T+2*a.reg.size, 0, 2*N-2*a.reg.size);
HalfMontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, v.reg, N);
return result;
}
Integer HalfMontgomeryRepresentation::ConvertOut(const Integer &a) const
{
word *const T = workspace.ptr;
word *const R = result.reg.ptr;
const unsigned int N = modulus.reg.size;
assert(a.reg.size<=N);
CopyWords(T, a.reg, a.reg.size);
SetWords(T+a.reg.size, 0, 2*N-a.reg.size);
HalfMontgomeryReduce(R, T+2*N, T, modulus.reg, u.reg, v.reg, N);
return result;
}
Integer HalfMontgomeryRepresentation::MultiplicativeInverse(const Integer &a) const
{
return (a.InverseMod(modulus)<<(WORD_BITS*modulus.reg.size))%modulus;
}
NAMESPACE_END
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