void decryptAndPrint(ostream& s, const Ctxt& ctxt, const FHESecKey& sk,
const EncryptedArray& ea, long flags)
{
const FHEcontext& context = ctxt.getContext();
xdouble noiseEst = sqrt(ctxt.getNoiseVar());
xdouble modulus = xexp(context.logOfProduct(ctxt.getPrimeSet()));
vector<ZZX> ptxt;
ZZX p, pp;
sk.Decrypt(p, ctxt, pp);
s << "plaintext space mod "<<ctxt.getPtxtSpace()
<< ", level="<<ctxt.findBaseLevel()
<< ", \n |noise|=q*" << (coeffsL2Norm(pp)/modulus)
<< ", |noiseEst|=q*" << (noiseEst/modulus)
<<endl;
if (flags & FLAG_PRINT_ZZX) {
s << " before mod-p reduction=";
printZZX(s,pp) <<endl;
}
if (flags & FLAG_PRINT_POLY) {
s << " after mod-p reduction=";
printZZX(s,p) <<endl;
}
if (flags & FLAG_PRINT_VEC) {
ea.decode(ptxt, p);
if (ea.getAlMod().getTag() == PA_zz_p_tag
&& ctxt.getPtxtSpace() != ea.getAlMod().getPPowR()) {
long g = GCD(ctxt.getPtxtSpace(), ea.getAlMod().getPPowR());
for (long i=0; i<ea.size(); i++)
PolyRed(ptxt[i], g, true);
}
s << " decoded to ";
if (deg(p) < 40) // just pring the whole thing
s << ptxt << endl;
else if (ptxt.size()==1) // a single slot
printZZX(s, ptxt[0]) <<endl;
else { // print first and last slots
printZZX(s, ptxt[0],20) << "--";
printZZX(s, ptxt[ptxt.size()-1], 20) <<endl;
}
}
}
// bootstrap a ciphertext to reduce noise
void FHEPubKey::reCrypt(Ctxt &ctxt)
{
FHE_TIMER_START;
// Some sanity checks for dummy ciphertext
long ptxtSpace = ctxt.getPtxtSpace();
if (ctxt.isEmpty()) return;
if (ctxt.parts.size()==1 && ctxt.parts[0].skHandle.isOne()) {
// Dummy encryption, just ensure that it is reduced mod p
ZZX poly = to_ZZX(ctxt.parts[0]);
for (long i=0; i<poly.rep.length(); i++)
poly[i] = to_ZZ( rem(poly[i],ptxtSpace) );
poly.normalize();
ctxt.DummyEncrypt(poly);
return;
}
assert(recryptKeyID>=0); // check that we have bootstrapping data
long p = getContext().zMStar.getP();
long r = getContext().alMod.getR();
long p2r = getContext().alMod.getPPowR();
// the bootstrapping key is encrypted relative to plaintext space p^{e-e'+r}.
long e = getContext().rcData.e;
long ePrime = getContext().rcData.ePrime;
long p2ePrime = power_long(p,ePrime);
long q = power_long(p,e)+1;
assert(e>=r);
#ifdef DEBUG_PRINTOUT
cerr << "reCrypt: p="<<p<<", r="<<r<<", e="<<e<<" ePrime="<<ePrime
<< ", q="<<q<<endl;
#endif
// can only bootstrap ciphertext with plaintext-space dividing p^r
assert(p2r % ptxtSpace == 0);
FHE_NTIMER_START(preProcess);
// Make sure that this ciphertxt is in canonical form
if (!ctxt.inCanonicalForm()) ctxt.reLinearize();
// Mod-switch down if needed
IndexSet s = ctxt.getPrimeSet() / getContext().specialPrimes; // set minus
if (s.card()>2) { // leave only bottom two primes
long frst = s.first();
long scnd = s.next(frst);
IndexSet s2(frst,scnd);
s.retain(s2); // retain only first two primes
}
ctxt.modDownToSet(s);
// key-switch to the bootstrapping key
ctxt.reLinearize(recryptKeyID);
// "raw mod-switch" to the bootstrapping mosulus q=p^e+1.
vector<ZZX> zzParts; // the mod-switched parts, in ZZX format
double noise = ctxt.rawModSwitch(zzParts, q);
noise = sqrt(noise);
// Add multiples of p2r and q to make the zzParts divisible by p^{e'}
long maxU=0;
for (long i=0; i<(long)zzParts.size(); i++) {
// make divisible by p^{e'}
long newMax = makeDivisible(zzParts[i].rep, p2ePrime, p2r, q,
getContext().rcData.alpha);
zzParts[i].normalize(); // normalize after working directly on the rep
if (maxU < newMax) maxU = newMax;
}
// Check that the estimated noise is still low
if (noise + maxU*p2r*(skHwts[recryptKeyID]+1) > q/2)
cerr << " * noise/q after makeDivisible = "
<< ((noise + maxU*p2r*(skHwts[recryptKeyID]+1))/q) << endl;
for (long i=0; i<(long)zzParts.size(); i++)
zzParts[i] /= p2ePrime; // divide by p^{e'}
// Multiply the post-processed cipehrtext by the encrypted sKey
#ifdef DEBUG_PRINTOUT
cerr << "+ Before recryption ";
decryptAndPrint(cerr, recryptEkey, *dbgKey, *dbgEa, printFlag);
#endif
double p0size = to_double(coeffsL2Norm(zzParts[0]));
double p1size = to_double(coeffsL2Norm(zzParts[1]));
ctxt = recryptEkey;
ctxt.multByConstant(zzParts[1], p1size*p1size);
ctxt.addConstant(zzParts[0], p0size*p0size);
#ifdef DEBUG_PRINTOUT
cerr << "+ Before linearTrans1 ";
decryptAndPrint(cerr, ctxt, *dbgKey, *dbgEa, printFlag);
#endif
FHE_NTIMER_STOP(preProcess);
// Move the powerful-basis coefficients to the plaintext slots
FHE_NTIMER_START(LinearTransform1);
ctxt.getContext().rcData.firstMap->apply(ctxt);
FHE_NTIMER_STOP(LinearTransform1);
#ifdef DEBUG_PRINTOUT
cerr << "+ After linearTrans1 ";
decryptAndPrint(cerr, ctxt, *dbgKey, *dbgEa, printFlag);
#endif
// Extract the digits e-e'+r-1,...,e-e' (from fully packed slots)
extractDigitsPacked(ctxt, e-ePrime, r, ePrime,
context.rcData.unpackSlotEncoding);
#ifdef DEBUG_PRINTOUT
cerr << "+ Before linearTrans2 ";
decryptAndPrint(cerr, ctxt, *dbgKey, *dbgEa, printFlag);
#endif
// Move the slots back to powerful-basis coefficients
FHE_NTIMER_START(LinearTransform2);
ctxt.getContext().rcData.secondMap->apply(ctxt);
FHE_NTIMER_STOP(LinearTransform2);
}
