本文整理汇总了C++中InvMod函数的典型用法代码示例。如果您正苦于以下问题:C++ InvMod函数的具体用法?C++ InvMod怎么用?C++ InvMod使用的例子?那么恭喜您, 这里精选的函数代码示例或许可以为您提供帮助。
在下文中一共展示了InvMod函数的20个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于我们的系统推荐出更棒的C++代码示例。
示例1: rem
// Create a tensor product of c1,c2. It is assumed that *this,c1,c2
// are defined relative to the same set of primes and plaintext space,
// and that *this DOES NOT point to the same object as c1,c2
void Ctxt::tensorProduct(const Ctxt& c1, const Ctxt& c2)
{
// c1,c2 may be scaled, so multiply by the inverse scalar if needed
long f = 1;
if (c1.ptxtSpace>2)
f = rem(context.productOfPrimes(c1.primeSet),c1.ptxtSpace);
if (f!=1) f = InvMod(f,c1.ptxtSpace);
clear(); // clear *this, before we start adding things to it
primeSet = c1.primeSet; // set the correct prime-set before we begin
// The actual tensoring
CtxtPart tmpPart(context, IndexSet::emptySet()); // a scratch CtxtPart
for (size_t i=0; i<c1.parts.size(); i++) {
CtxtPart thisPart = c1.parts[i];
if (f!=1) thisPart *= f;
for (size_t j=0; j<c2.parts.size(); j++) {
tmpPart = c2.parts[j];
// What secret key will the product point to?
if (!tmpPart.skHandle.mul(thisPart.skHandle, tmpPart.skHandle))
Error("Ctxt::tensorProduct: cannot multiply secret-key handles");
tmpPart *= thisPart; // The element of the tensor product
// Check if we already have a part relative to this secret-key handle
long k = getPartIndexByHandle(tmpPart.skHandle);
if (k >= 0) // found a matching part
parts[k] += tmpPart;
else
parts.push_back(tmpPart);
}
}
/* Compute the noise estimate as c1.noiseVar * c2.noiseVar * factor
* where the factor depends on the handles of c1,c2. Specifically,
* if the largest powerOfS in c1,c2 are n1,n2, respectively, then we
* have factor = ((n1+n2) choose n2).
*/
long n1=0, n2=0;
for (size_t i=0; i<c1.parts.size(); i++) // get largest powerOfS in c1
if (c1.parts[i].skHandle.getPowerOfS() > n1)
n1 = c1.parts[i].skHandle.getPowerOfS();
for (size_t i=0; i<c2.parts.size(); i++) // get largest powerOfS in c2
if (c2.parts[i].skHandle.getPowerOfS() > n2)
n2 = c2.parts[i].skHandle.getPowerOfS();
// compute ((n1+n2) choose n2)
long factor = 1;
for (long i=n1+1; i<=n1+n2; i++) factor *= i;
for (long i=n2 ; i>1 ; i--) factor /= i;
noiseVar = c1.noiseVar * c2.noiseVar * factor * context.zMStar.get_cM();
if (f!=1) {
// WARNING: the following line is written just so to prevent overflow
noiseVar = (noiseVar*f)*f; // because every product was scaled by f
}
}
开发者ID:Kverma517,项目名称:HElib,代码行数:60,代码来源:Ctxt.cpp
示例2: MulMod
// Sets the prime defining the field for the curve and stores certain values
void Icart::setPrime(ZZ* p)
{
//ZZ_p::init(*p);
// Icart hash function uses 1/3 root, which is equivalent to (2p-1)/3
exp = MulMod( SubMod( MulMod(ZZ(2), *p, *p), ZZ(1), *p), InvMod(ZZ(3),*p), *p);
// Store inverse values to be used later
ts = inv(ZZ_p(27));
th = inv(ZZ_p(3));
}
开发者ID:tomsimmons,项目名称:ecurves,代码行数:10,代码来源:icart.cpp
示例3: InitFFTPrimeInfo
void InitFFTPrimeInfo(FFTPrimeInfo& info, long q, long w, long bigtab)
{
double qinv = 1/((double) q);
long mr = CalcMaxRoot(q);
info.q = q;
info.qinv = qinv;
info.zz_p_context = 0;
info.RootTable.SetLength(mr+1);
info.RootInvTable.SetLength(mr+1);
info.TwoInvTable.SetLength(mr+1);
info.TwoInvPreconTable.SetLength(mr+1);
long *rt = &info.RootTable[0];
long *rit = &info.RootInvTable[0];
long *tit = &info.TwoInvTable[0];
mulmod_precon_t *tipt = &info.TwoInvPreconTable[0];
long j;
long t;
rt[mr] = w;
for (j = mr-1; j >= 0; j--)
rt[j] = MulMod(rt[j+1], rt[j+1], q);
rit[mr] = InvMod(w, q);
for (j = mr-1; j >= 0; j--)
rit[j] = MulMod(rit[j+1], rit[j+1], q);
t = InvMod(2, q);
tit[0] = 1;
for (j = 1; j <= mr; j++)
tit[j] = MulMod(tit[j-1], t, q);
for (j = 0; j <= mr; j++)
tipt[j] = PrepMulModPrecon(tit[j], q, qinv);
info.bigtab = bigtab;
}
开发者ID:ddemarco5,项目名称:CRYPTO_chat,代码行数:42,代码来源:FFT.cpp
示例4: count
NTL_CLIENT
#include <algorithm> // defines count(...), min(...)
#include <iostream>
#include "NumbTh.h"
#include "PAlgebra.h"
// Generate the representation of Z[X]/(Phi_m(X),2) for the odd integer m
void PAlgebraModTwo::init(unsigned m)
{
if (m == zmStar.M()) return; // nothign to do
((PAlgebra&)zmStar).init(m); // initialize the structure of (Z/mZ)*, if needed
if (zmStar.M()==0 || zmStar.NSlots()==0) return; // error in zmStar
unsigned nSlots = zmStar.NSlots();
// Next compute the factors Ft of Phi_m(X) mod 2, for all t \in T
// GF2X PhimXmod = to_GF2X(zmStar.PhimX()); // Phi_m(X) mod 2
PhimXmod = to_GF2X(zmStar.PhimX()); // Phi_m(X) mod 2
EDF(factors, PhimXmod, zmStar.OrdTwo()); // equal-degree factorization
// It is left to order the factors according to their representatives
GF2XModulus F1(factors[0]); // We arbitrarily choose factors[0] as F1
for (unsigned i=1; i<nSlots; i++) {
unsigned t = zmStar.ith_rep(i); // Ft is minimal polynomial of x^{1/t} mod F1
unsigned tInv = rep(inv(to_zz_p(t))); // tInv = t^{-1} mod m
GF2X X2tInv = PowerXMod(tInv,F1); // X2tInv = X^{1/t} mod F1
IrredPolyMod(factors[i], X2tInv, F1);
}
/* Debugging sanity-check #1: we should have Ft= GCD(F1(X^t),Phi_m(X))
GF2XModulus Pm2(PhimXmod);
for (i=1; i<nSlots; i++) {
unsigned t = T[i];
GF2X X2t = PowerXMod(t,PhimXmod); // X2t = X^t mod Phi_m(X)
GF2X Ft = GCD(CompMod(F1,X2t,Pm2),Pm2);
if (Ft != factors[i]) {
cout << "Ft != F1(X^t) mod Phi_m(X), t=" << t << endl;
exit(0);
}
}*******************************************************************/
// Compute the CRT coefficients for the Ft's
crtCoeffs.SetLength(nSlots);
for (unsigned i=0; i<nSlots; i++) {
GF2X te = PhimXmod / factors[i]; // \prod_{j\ne i} Fj
te %= factors[i]; // \prod_{j\ne i} Fj mod Fi
InvMod(crtCoeffs[i], te, factors[i]);// \prod_{j\ne i} Fj^{-1} mod Fi
}
}
开发者ID:dwu4,项目名称:fhe-si,代码行数:54,代码来源:PAlgebraMod.cpp
示例5: computeInvVec
// divVec[d] = m/p_d^{e_d}, powVec[d] = p^{e_d}
// computes invVec[d] = divVec[d]^{-1} mod powVec[d]
void computeInvVec(Vec<long>& invVec,
const Vec<long>& divVec, const Vec<long>& powVec)
{
long k = divVec.length();
invVec.SetLength(k);
for (long d = 0; d < k; d++) {
long t1 = divVec[d] % powVec[d];
long t2 = InvMod(t1, powVec[d]);
invVec[d] = t2;
}
}
开发者ID:2080,项目名称:HElib,代码行数:14,代码来源:powerful.cpp
示例6: getTypes
ZZ ASTDiv::eval(Environment &env) {
pair<VarInfo,VarInfo> p = getTypes(env);
VarInfo leftInfo = p.first;
VarInfo rightInfo = p.second;
// XXX: this will cause a problem if we ever try to use
// it during constant propagation/substitution
const Group* lGroup = env.groups.at(leftInfo.group);
const Group* rGroup = env.groups.at(rightInfo.group);
const Group* retGroup = (lGroup != 0 ? lGroup : rGroup);
// integers can just be divided
if ((lGroup == 0 && rGroup == 0)
|| (leftInfo.type == VarInfo::MODULUS
|| rightInfo.type == VarInfo::MODULUS)) {
return lhs->eval(env) / rhs->eval(env);
} else if (leftInfo.type == VarInfo::EXPONENT ||
rightInfo.type == VarInfo::EXPONENT) {
// want to get LHS * inv(RHS)
// this only works if we are in a group with known order
if (retGroup->getType() == Group::TYPE_PRIME) {
ZZ ord = retGroup->getOrder();
ZZ right = InvMod(rhs->eval(env), ord);
return lhs->eval(env) * right;
// in an RSA group, only permit computing 1/x if the caller
// knows the order of the group
} else if(retGroup->getType() == Group::TYPE_RSA &&
(retGroup->getOrder() != 0)) {
ZZ ord = retGroup->getOrder();
ZZ right = InvMod(rhs->eval(env), ord);
return lhs->eval(env) * right;
} else {
throw CashException(CashException::CE_PARSE_ERROR,
"That operation is not permitted in an RSA group");
}
} else {
assert(retGroup);
ZZ mod = retGroup->getModulus();
return MulMod(lhs->eval(env), InvMod(rhs->eval(env), mod), mod);
}
}
开发者ID:brownie,项目名称:cashlib,代码行数:39,代码来源:ASTNode.cpp
示例7: InvMod
ZZ BankTool::identifyDoubleSpender(const Coin& coin1, const ZZ &tPrime2,
const ZZ& rValue2) const {
// Should probably check that the R values are different
ZZ mod = coin1.getCashGroup()->getModulus();
ZZ order = coin1.getCashGroup()->getOrder();
ZZ t1 = coin1.getTPrime();
ZZ t2 = tPrime2;
ZZ r1 = coin1.getR();
ZZ r2 = rValue2;
if (r2 > r1) {
NTL::swap(r2, r1);
NTL::swap(t2, t1);
}
ZZ exp = InvMod(r1 - r2, order);
ZZ num = PowerMod(t2, r1, mod);
ZZ denom = InvMod(PowerMod(t1, r2, mod), mod);
ZZ base = MulMod(num, denom, mod);
ZZ publicKeyUser = PowerMod(base, exp, mod);
return publicKeyUser;
}
开发者ID:brownie,项目名称:cashlib,代码行数:23,代码来源:BankTool.cpp
示例8: solve
long solve(int *S, int *R) { // start = S, each = R
for (int i = 0; i < m; ++i) {
visited[i] = false;
inv[S[i]] = i;
}
long ret = 0, MOD = 1;
for (int i = 0; i < m; ++i) {
if (visited[i]) continue;
// print("--- loop ---\n");
int loop = 0;
for (int j = i; !visited[j]; j = R[j]) {
// print("{} ", j);
visited[j] = true;
vs[loop] = S[j] % 2;
vr[loop] = j % 2;
++loop;
}
// print("\n");
TIME += loop;
int mod, rem;
tie(mod, rem) = match(loop);
// for (int i = 0; i < loop; ++i) {
// print("{} {}\n", vs[i], vr[i]);
// }
// print("mod = {}, rem = {}\n", mod, rem);
if (mod == 0) {
return 1e18;
}
long g = GCD(MOD, mod);
if (ret % g != rem % g) {
return 1e18;
}
// print("mod = {}, rem = {}\n", mod, rem);
MOD /= g, mod /= g;
long t = InvMod(MOD, mod) * ((rem - ret) / g % mod + mod) % mod;
// print("t = {}\n", t);
assert((t * MOD * g + ret) % (mod * g) == rem);
ret = t * MOD * g + ret;
MOD = MOD * mod * g;
// print("MOD = {}, REM = {}\n", MOD, ret);
// print("loop: {}\n", n);
}
return ret;
}
开发者ID:roosephu,项目名称:project-euler,代码行数:48,代码来源:566.cpp
示例9: to_ZZ
// Division by constant
// FIXME: this is not alias friendly
SingleCRT& SingleCRT::operator/=(const ZZ &num)
{
const IndexSet& s = map.getIndexSet();
ZZ pi, n;
for (long i = s.first(); i <= s.last(); i = s.next(i)) {
pi = to_ZZ(context.ithPrime(i));
rem(n,num,pi);
InvMod(n,n,pi); // n = num^{-1} mod pi
vec_ZZ& vp = map[i].rep;
for (long j=0; j<vp.length(); j++) MulMod(vp[j], vp[j], n, pi);
map[i].normalize();
}
return *this;
}
开发者ID:dwu4,项目名称:fhe-si,代码行数:18,代码来源:SingleCRT.cpp
示例10: verifysign
// Процедура проверки подписи
void verifysign (ZZ &R, ZZ &r, ZZ &s, ZZ &e, Qxy &Q, Qxy &P, ZZ &q )
{
ZZ v, z1, z2;
Qxy C;
ZZ e1;
if (InvModStatus( v, e, q ))
{
cout << "\nError in signature\n";
goto end;
}
v = InvMod(e,q);
z1 = (s*v)%q;
z2 = (-r*v)%q;
C = P*z1 + Q*z2;
R = (conv<ZZ>(C.putx()))%q;
cout << "\nv (dec) = \n" << v << endl;
cout << "\nv (hex) = \n";
show_dec_in_hex (v, L);
cout << endl;
cout << "\nz1 (dec) = \n" << z1 << endl;
cout << "\nz1 (hex) = \n";
show_dec_in_hex (z1, L);
cout << endl;
cout << "\nz2 (dec) = \n" << z2 << endl;
cout << "\nz2 (hex) = \n";
show_dec_in_hex (z2, L);
cout << endl;
cout << "\nPoint C:\n";
C.putQxy();
cout << "\nR (dec) = \n" << R << endl;
cout << "\nR (hex) = \n";
show_dec_in_hex (R, L);
cout << endl;
end:
if ( r == R )
cout << "\nr = R\nSignature is OK";
else
cout << "\nSignature is FAILD";
cout << endl;
}
开发者ID:vster,项目名称:GOST-R-3410,代码行数:47,代码来源:G3410-2012.cpp
示例11: exit
// mod-switch down to primeSet \intersect s, after this call we have
// primeSet<=s. s must contain either all special primes or none of them.
void Ctxt::modDownToSet(const IndexSet &s)
{
IndexSet intersection = primeSet & s;
// assert(!empty(intersection)); // some primes must be left
if (empty(intersection)) {
cerr << "modDownToSet called from "<<primeSet<<" to "<<s<<endl;
exit(1);
}
if (intersection==primeSet) return; // nothing to do, removing no primes
FHE_TIMER_START;
IndexSet setDiff = primeSet / intersection; // set-minus
// Scale down all the parts: use either a simple "drop down" (just removing
// primes, i.e., reducing the ctxt modulo the samaller modulus), or a "real
// modulus switching" with rounding, basically whichever yeilds smaller
// noise. Recall that we keep the invariant that a ciphertext mod Q is
// decrypted to Q*m (mod p), so if we just "drop down" we still need to
// multiply by (Q^{-1} mod p).
// Get an estimate for the added noise term for modulus switching
xdouble addedNoiseVar = modSwitchAddedNoiseVar();
if (noiseVar*ptxtSpace*ptxtSpace < addedNoiseVar) { // just "drop down"
long prodInv = InvMod(rem(context.productOfPrimes(setDiff),ptxtSpace), ptxtSpace);
for (size_t i=0; i<parts.size(); i++) {
parts[i].removePrimes(setDiff); // remove the primes not in s
parts[i] *= prodInv;
// WARNING: the following line is written just so to prevent overflow
noiseVar = noiseVar*prodInv*prodInv;
}
// cerr << "DEGENERATE DROP\n";
}
else { // do real mod switching
for (size_t i=0; i<parts.size(); i++)
parts[i].scaleDownToSet(intersection, ptxtSpace);
// update the noise estimate
double f = context.logOfProduct(setDiff);
noiseVar /= xexp(2*f);
noiseVar += addedNoiseVar;
}
primeSet.remove(setDiff); // remove the primes not in s
assert(verifyPrimeSet()); // sanity-check: ensure primeSet is still valid
FHE_TIMER_STOP;
}
开发者ID:Kverma517,项目名称:HElib,代码行数:47,代码来源:Ctxt.cpp
示例12: getContext
// Divide a cipehrtext by p, for plaintext space p^r, r>1. It is assumed
// that the ciphertext encrypts a polynomial which is zero mod p. If this
// is not the case then the result will not be a valid ciphertext anymore.
// As a side-effect, the plaintext space is reduced from p^r to p^{r-1}.
void Ctxt::divideByP()
{
// Special case: if *this is empty then do nothing
if (this->isEmpty()) return;
long p = getContext().zMStar.getP();
assert (ptxtSpace>p);
// multiply all the parts by p^{-1} mod Q (Q=productOfPrimes)
ZZ pInverse, Q;
getContext().productOfPrimes(Q, getPrimeSet());
InvMod(pInverse, conv<ZZ>(p), Q);
for (size_t i=0; i<parts.size(); i++)
parts[i] *= pInverse;
noiseVar /= (p * (double)p); // noise is reduced by a p factor
ptxtSpace /= p; // and so is the plaintext space
}
开发者ID:Kverma517,项目名称:HElib,代码行数:22,代码来源:Ctxt.cpp
示例13: add1DMatrices
// generate all matrices of the form s(X^{g^i})->s(X) for generators g of
// Zm* /<2> and i<ord(g). If g has different orders in Zm* and Zm* /<2>
// then generate also matrices of the form s(X^{g^{-i}})->s(X)
void add1DMatrices(FHESecKey& sKey, long keyID)
{
const FHEcontext &context = sKey.getContext();
long m = context.zMStar.getM();
// key-switching matrices for the automorphisms
for (long i = 0; i < (long)context.zMStar.numOfGens(); i++) {
for (long j = 1; j < (long)context.zMStar.OrderOf(i); j++) {
long val = PowerMod(context.zMStar.ZmStarGen(i), j, m); // val = g^j
// From s(X^val) to s(X)
sKey.GenKeySWmatrix(1, val, keyID, keyID);
if (!context.zMStar.SameOrd(i))
// also from s(X^{1/val}) to s(X)
sKey.GenKeySWmatrix(1, InvMod(val,m), keyID, keyID);
}
}
sKey.setKeySwitchMap(); // re-compute the key-switching map
}
开发者ID:2080,项目名称:HElib,代码行数:21,代码来源:KeySwitching.cpp
示例14: recordAutomorphVal
// Apply F(X)->F(X^k) followed by re-liearization. The automorphism is possibly
// evaluated via a sequence of steps, to ensure that we can re-linearize the
// result of every step.
void Ctxt::smartAutomorph(long k)
{
FHE_TIMER_START;
// A hack: record this automorphism rather than actually performing it
if (isSetAutomorphVals()) { // defined in NumbTh.h
recordAutomorphVal(k);
return;
}
// Special case: if *this is empty then do nothing
if (this->isEmpty()) return;
// Sanity check: verify that k \in Zm*
long m = context.zMStar.getM();
k = mcMod(k, m);
assert (context.zMStar.inZmStar(k));
long keyID=getKeyID();
if (!pubKey.isReachable(k,keyID)) {// must have key-switching matrices for it
throw std::logic_error("no key-switching matrices for k="+std::to_string(k)
+ ", keyID="+std::to_string(keyID));
}
if (!inCanonicalForm(keyID)) { // Re-linearize the input, if needed
reLinearize(keyID);
assert (inCanonicalForm(keyID)); // ensure that re-linearization succeeded
}
while (k != 1) {
const KeySwitch& matrix = pubKey.getNextKSWmatrix(k,keyID);
long amt = matrix.fromKey.getPowerOfX();
// A hack: record this automorphism rather than actually performing it
if (isSetAutomorphVals2()) { // defined in NumbTh.h
recordAutomorphVal2(amt);
return;
}
//cerr << "********* automorph " << amt << "\n";
automorph(amt);
reLinearize(keyID);
k = MulMod(k, InvMod(amt,m), m);
}
FHE_TIMER_STOP;
}
开发者ID:fionser,项目名称:HElib,代码行数:47,代码来源:Ctxt.cpp
示例15: InvModpr
// Assumes current zz_p modulus is p^r
// computes S = F^{-1} mod G via Hensel lifting
void InvModpr(zz_pX& S, const zz_pX& F, const zz_pX& G, long p, long r)
{
ZZX ff, gg, ss, tt;
ff = to_ZZX(F);
gg = to_ZZX(G);
zz_pBak bak;
bak.save();
zz_p::init(p);
zz_pX f, g, s, t;
f = to_zz_pX(ff);
g = to_zz_pX(gg);
s = InvMod(f, g);
t = (1-s*f)/g;
assert(s*f + t*g == 1);
ss = to_ZZX(s);
tt = to_ZZX(t);
ZZ pk = to_ZZ(1);
for (long k = 1; k < r; k++) {
// lift from p^k to p^{k+1}
pk = pk * p;
assert(divide(ss*ff + tt*gg - 1, pk));
zz_pX d = to_zz_pX( (1 - (ss*ff + tt*gg))/pk );
zz_pX s1, t1;
s1 = (s * d) % g;
t1 = (d-s1*f)/g;
ss = ss + pk*to_ZZX(s1);
tt = tt + pk*to_ZZX(t1);
}
bak.restore();
S = to_zz_pX(ss);
assert((S*F) % G == 1);
}
开发者ID:Kverma517,项目名称:HElib,代码行数:44,代码来源:PAlgebra.cpp
示例16: sum
ZZ PaillierParty::decrypt(const std::map<uint32_t,ZZ> &partialCiphers,
const std::vector<ZZ> &pubKeys) {
ZZ sum(0);
for (auto &pubKey : pubKeys) {
sum = AddMod(sum,pubKey,m_n);
}
ZZ phi = MulMod(m_a,sum,m_n);
ZZ prod(1);
for (auto &partialCipher: partialCiphers) {
uint32_t partyId = partialCipher.first;
prod = MulMod(prod,PowerMod(partialCipher.second, 2*m_lagrangeBasis[partyId],m_field),m_field);
}
ZZ LResult = L_function(prod);
ZZ combinedShare = InvMod(MulMod(4*m_delta*m_delta,phi,m_n),m_n);
return MulMod(LResult, combinedShare, m_n);
}
开发者ID:cryptobiu,项目名称:MultiPartyPSI,代码行数:20,代码来源:PaillierParty.cpp
示例17: init_representatives
static void
init_representatives(Vec<long>& representatives, long dim,
const Vec<long>& mvec, const PAlgebra& zMStar)
{
assert(dim >= 0 && dim < mvec.length());
// special case
if (dim >= LONG(zMStar.numOfGens())) {
representatives.SetLength(1);
representatives[0] = 1;
return;
}
long m = mvec[dim];
long D = zMStar.OrderOf(dim);
long g = InvMod(zMStar.ZmStarGen(dim) % m, m);
representatives.SetLength(D);
for (long i = 0; i < D; i++)
representatives[i] = PowerMod(g, i, m);
}
开发者ID:deepinit-arek,项目名称:HElib,代码行数:21,代码来源:EvalMap.cpp
示例18: init_representatives
static void
init_representatives(Vec<long>& representatives, long dim,
const Vec<long>& mvec, const PAlgebra& zMStar)
{
//OLD: assert(dim >= 0 && dim < mvec.length());
helib::assertInRange(dim, 0l, mvec.length(), "Invalid argument: dim must be between 0 and mvec.length()");
// special case
if (dim >= LONG(zMStar.numOfGens())) {
representatives.SetLength(1);
representatives[0] = 1;
return;
}
long m = mvec[dim];
long D = zMStar.OrderOf(dim);
long g = InvMod(zMStar.ZmStarGen(dim) % m, m);
representatives.SetLength(D);
for (long i = 0; i < D; i++)
representatives[i] = PowerMod(g, i, m);
}
开发者ID:shaih,项目名称:HElib,代码行数:22,代码来源:EvalMap.cpp
示例19: get_PowerMod
ZZ get_PowerMod(const ZZ& numar, const ZZ& exponent, const ZZ& baza)
{
if (exponent == 0)
return to_ZZ(1);
long k = NumBits(exponent);
ZZ res;
res = 1;
for (long i = k-1; i >= 0; i--)
{
res = (res*res) % baza;
if (bit(exponent, i) == 1)
res = (res*numar) % n;
}
if (exponent < 0)
return InvMod(res, baza);
else
return res;
}
开发者ID:RobertAlexandroaie,项目名称:C_CPP,代码行数:22,代码来源:Source.cpp
示例20: compute_a_vals
static
void compute_a_vals(Vec<ZZ>& a, long p, long e)
// computes a[m] = a(m)/m! for m = p..(e-1)(p-1)+1,
// as defined by Chen and Han.
// a.length() is set to (e-1)(p-1)+2
{
ZZ p_to_e = power_ZZ(p, e);
ZZ p_to_2e = power_ZZ(p, 2*e);
long len = (e-1)*(p-1)+2;
ZZ_pPush push(p_to_2e);
ZZ_pX x_plus_1_to_p = power(ZZ_pX(INIT_MONO, 1) + 1, p);
ZZ_pX denom = InvTrunc(x_plus_1_to_p - ZZ_pX(INIT_MONO, p), len);
ZZ_pX poly = MulTrunc(x_plus_1_to_p, denom, len);
poly *= p;
a.SetLength(len);
ZZ m_fac(1);
for (long m = 2; m < p; m++) {
m_fac = MulMod(m_fac, m, p_to_2e);
}
for (long m = p; m < len; m++) {
m_fac = MulMod(m_fac, m, p_to_2e);
ZZ c = rep(coeff(poly, m));
ZZ d = GCD(m_fac, p_to_2e);
if (d == 0 || d > p_to_e || c % d != 0) Error("cannot divide");
ZZ m_fac_deflated = (m_fac / d) % p_to_e;
ZZ c_deflated = (c / d) % p_to_e;
a[m] = MulMod(c_deflated, InvMod(m_fac_deflated, p_to_e), p_to_e);
}
}
开发者ID:bbreck3,项目名称:HElib,代码行数:37,代码来源:extractDigits.cpp
注:本文中的InvMod函数示例由纯净天空整理自Github/MSDocs等源码及文档管理平台,相关代码片段筛选自各路编程大神贡献的开源项目,源码版权归原作者所有,传播和使用请参考对应项目的License;未经允许,请勿转载。 |
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