bool LoadCheckpoints(const std::string& strNetwork)
{
UniValue v;
if (strNetwork == "main")
v = read_json(GetMainCheckpoints());
else if (strNetwork == "test")
v = read_json(GetTestCheckpoints());
else if (strNetwork == "regtest")
v = read_json(GetRegTestCheckpoints());
else
return false;
if (v.empty())
return false;
for (unsigned int idx = 0; idx < v.size(); idx++) {
const UniValue &val = v[idx];
const UniValue &o = val.get_obj();
const UniValue &vHeight = find_value(o, "height");
if (!vHeight.isNum())
return false;
int nHeight = vHeight.get_int();
if (nHeight < 0)
return false;
Checkpoint checkpoint;
for (auto denom : libzerocoin::zerocoinDenomList) {
const UniValue& vDenomValue = find_value(o, std::to_string(denom));
if (!vDenomValue.isStr()) {
return false;
}
CBigNum bn = 0;
bn.SetHex(vDenomValue.get_str());
checkpoint.insert(std::make_pair(denom, bn));
}
mapCheckpoints.insert(make_pair(nHeight, checkpoint));
}
return true;
}
bool BitcoinMiner2_mineProbableChain(primecoinBlock_t* block, mpz_class& mpzFixedMultiplier, bool& fNewBlock, unsigned int& nTriedMultiplier, unsigned int& nProbableChainLength,
unsigned int& nTests, unsigned int& nPrimesHit, sint32 threadIndex, mpz_class& mpzHash, unsigned int nPrimorialMultiplier)
{
mpz_class mpzChainOrigin;
mpz_class mpzFinalFixedMultiplier = mpzFixedMultiplier * mpzHash;
mpz_class mpzTemp;
uint32 nTime = GetTickCount();
cSieve_prepare(mpzFinalFixedMultiplier, block->nBits>>24);
nTime = GetTickCount()-nTime;
//printf("cSieve prep time: %d\n", nTime);
unsigned int nPrimorialSeq = 0;
while (vPrimes[nPrimorialSeq + 1] <= nPrimorialMultiplier)
nPrimorialSeq++;
// Allocate GMP variables for primality tests
CPrimalityTestParams testParams(block->nBits, nPrimorialSeq);
{
unsigned long lDivisor = 1;
unsigned int i;
testParams.vFastDivSeq.push_back(nPrimorialSeq);
for (i = 1; i <= nFastDivPrimes; i++)
{
// Multiply primes together until the result won't fit an unsigned long
if (lDivisor < ULONG_MAX / vPrimes[nPrimorialSeq + i])
lDivisor *= vPrimes[nPrimorialSeq + i];
else
{
testParams.vFastDivisors.push_back(lDivisor);
testParams.vFastDivSeq.push_back(nPrimorialSeq + i);
lDivisor = 1;
}
}
// Finish off by multiplying as many primes as possible
while (lDivisor < ULONG_MAX / vPrimes[nPrimorialSeq + i])
{
lDivisor *= vPrimes[nPrimorialSeq + i];
i++;
}
testParams.vFastDivisors.push_back(lDivisor);
testParams.vFastDivSeq.push_back(nPrimorialSeq + i);
testParams.nFastDivisorsSize = testParams.vFastDivisors.size();
}
// References to counters;
unsigned int& nChainLengthCunningham1 = testParams.nChainLengthCunningham1;
unsigned int& nChainLengthCunningham2 = testParams.nChainLengthCunningham2;
unsigned int& nChainLengthBiTwin = testParams.nChainLengthBiTwin;
uint32 debugStats_primes = 0;
uint32 debugStats_multipliersTested = 0;
while( block->serverData.blockHeight == jhMiner_getCurrentWorkBlockHeight(block->threadIndex) )
{
uint32 sieveFlags;
uint32 multiplier = cSieve_findNextMultiplier(&sieveFlags);
if( multiplier == 0 )
{
// mix in next layer
//printf("Layer finished [%d]\n", cSieve->currentSieveLayerIdx);
if( cSieve_sieveNextLayer() == false )
break;
mpzFinalFixedMultiplier = cSieve->mpzFixedMultiplier;
//printf("[%02d] debugStats_multipliersTested: %d\n", cSieve->currentSieveLayerIdx, debugStats_multipliersTested);
//printf("[%02d] debugStats_primes: %d\n", cSieve->currentSieveLayerIdx, debugStats_primes);
//double primality = (double)debugStats_primes / (double)debugStats_multipliersTested;
//printf("[%02d] debugStats_primality: %lf\n", cSieve->currentSieveLayerIdx, primality);
debugStats_primes = 0;
debugStats_multipliersTested = 0;
continue;
}
//// test for sieve bugs C1
//if( (sieveFlags&SIEVE_FLAG_C1_COMPOSITE)==0 && (rand()%10)==0 )
//{
// // test c1
// for(uint32 lt=0; lt<cSieve->chainLength; lt++)
// {
// uint32 aMult = 1<<lt;
// mpzChainOrigin = mpzFinalFixedMultiplier * multiplier * aMult - 1;
// for(uint32 f=0; f<cSieve->numPrimeFactors; f++)
// {
// uint32 mod = mpz_mod_ui(mpzTemp.get_mpz_t(), mpzChainOrigin.get_mpz_t(), vPrimes[f]);
// if( mod == 0 )
// printf("c1 div by %d possible\n", vPrimes[f]);//__debugbreak();
// }
// }
//}
//// test for sieve bugs C2
//if( (sieveFlags&SIEVE_FLAG_C2_COMPOSITE)==0 && (rand()%10)==0 )
//{
// // test c1
// for(uint32 lt=0; lt<cSieve->chainLength; lt++)
// {
// uint32 aMult = 1<<lt;
// mpzChainOrigin = mpzFinalFixedMultiplier * multiplier * aMult + 1;
// for(uint32 f=0; f<cSieve->numPrimeFactors; f++)
// {
// uint32 mod = mpz_mod_ui(mpzTemp.get_mpz_t(), mpzChainOrigin.get_mpz_t(), vPrimes[f]);
// if( mod == 0 )
// printf("c2 div by %d possible\n", vPrimes[f]);//__debugbreak();
// }
// }
//}
// test for sieve bugs BT
//if( (sieveFlags&SIEVE_FLAG_BT_COMPOSITE)==0 )
//{
// // test c1
// mpzChainOrigin = mpzFinalFixedMultiplier * multiplier + 1;
// for(uint32 f=0; f<cSieve->numPrimeFactors; f++)
// {
// uint32 mod = mpz_mod_ui(mpzTemp.get_mpz_t(), mpzChainOrigin.get_mpz_t(), vPrimes[f]);
// if( mod == 0 )
// printf("bt-c2 div by %d possible\n", vPrimes[f]);
// }
// // test c2
// mpzChainOrigin = mpzFinalFixedMultiplier * multiplier - 1;
// for(uint32 f=0; f<cSieve->numPrimeFactors; f++)
// {
// uint32 mod = mpz_mod_ui(mpzTemp.get_mpz_t(), mpzChainOrigin.get_mpz_t(), vPrimes[f]);
// if( mod == 0 )
// printf("bt-c2 div by %d possible\n", vPrimes[f]);
// }
//}
//mpzChainOrigin = mpzFinalFixedMultiplier * multiplier;
mpz_mul_ui(mpzChainOrigin.get_mpz_t(), mpzFinalFixedMultiplier.get_mpz_t(), multiplier);
nChainLengthCunningham1 = 0;
nChainLengthCunningham2 = 0;
nChainLengthBiTwin = 0;
bool canSubmitAsShare = ProbablePrimeChainTestFast2(mpzChainOrigin, testParams, sieveFlags, multiplier);
nProbableChainLength = max(max(nChainLengthCunningham1, nChainLengthCunningham2), nChainLengthBiTwin);
if( nProbableChainLength >= 0x01000000 )
debugStats_primes++;
debugStats_multipliersTested++;
//bool canSubmitAsShare = ProbablePrimeChainTestFast(mpzChainOrigin, testParams);
//CBigNum bnChainOrigin;
//bnChainOrigin.SetHex(mpzChainOrigin.get_str(16));
//bool canSubmitAsShare = ProbablePrimeChainTestBN(bnChainOrigin, block->serverData.nBitsForShare, false, nChainLengthCunningham1, nChainLengthCunningham2, nChainLengthBiTwin);
if( nProbableChainLength >= 0x04000000 )
{
sint32 chainDif = (nProbableChainLength>>24) - 7;
primeStats.nChainHit += pow(8, (float)chainDif);
//primeStats.nChainHit += pow(8, ((float)((double)nProbableChainLength / (double)0x1000000))-7.0);
//primeStats.nChainHit += pow(8, floor((float)((double)nProbableChainLength / (double)0x1000000)) - 7);
nTests = 0;
primeStats.fourChainCount ++;
if (nProbableChainLength >= 0x5000000)
{
primeStats.fiveChainCount ++;
if (nProbableChainLength >= 0x6000000)
{
primeStats.sixChainCount ++;
if (nProbableChainLength >= 0x7000000)
primeStats.sevenChainCount ++;
}
}
}
//if( nBitsGen >= 0x03000000 )
// printf("%08X\n", nBitsGen);
primeStats.primeChainsFound++;
//if( nProbableChainLength > 0x03000000 )
// primeStats.qualityPrimesFound++;
if( nProbableChainLength > primeStats.bestPrimeChainDifficulty )
primeStats.bestPrimeChainDifficulty = nProbableChainLength;
if(nProbableChainLength >= block->serverData.nBitsForShare)
{
// note: mpzPrimeChainMultiplier does not include the blockHash multiplier
mpz_div(block->mpzPrimeChainMultiplier.get_mpz_t(), mpzChainOrigin.get_mpz_t(), mpzHash.get_mpz_t());
//mpz_lsh(block->mpzPrimeChainMultiplier.get_mpz_t(), mpzFixedMultiplier.get_mpz_t(), multiplier);
// update server data
block->serverData.client_shareBits = nProbableChainLength;
// generate block raw data
uint8 blockRawData[256] = {0};
memcpy(blockRawData, block, 80);
uint32 writeIndex = 80;
sint32 lengthBN = 0;
CBigNum bnPrimeChainMultiplier;
bnPrimeChainMultiplier.SetHex(block->mpzPrimeChainMultiplier.get_str(16));
std::vector<unsigned char> bnSerializeData = bnPrimeChainMultiplier.getvch();
lengthBN = bnSerializeData.size();
*(uint8*)(blockRawData+writeIndex) = (uint8)lengthBN; // varInt (we assume it always has a size low enough for 1 byte)
writeIndex += 1;
memcpy(blockRawData+writeIndex, &bnSerializeData[0], lengthBN);
writeIndex += lengthBN;
// switch endianness
for(uint32 f=0; f<256/4; f++)
{
*(uint32*)(blockRawData+f*4) = _swapEndianessU32(*(uint32*)(blockRawData+f*4));
}
time_t now = time(0);
struct tm * timeinfo;
timeinfo = localtime (&now);
char sNow [80];
strftime (sNow, 80, "%x - %X",timeinfo);
printf("%s - SHARE FOUND !!! (Th#: %u Multiplier: %d Layer: %d) --- DIFF: %f %s %s\n",
sNow, threadIndex, multiplier, cSieve->currentSieveLayerIdx, (float)((double)nProbableChainLength / (double)0x1000000),
nProbableChainLength >= 0x6000000 ? ">6":"", nProbableChainLength >= 0x7000000 ? ">7":"");
// submit this share
if (jhMiner_pushShare_primecoin(blockRawData, block))
primeStats.foundShareCount ++;
//printf("Probable prime chain found for block=%s!!\n Target: %s\n Length: (%s %s %s)\n", block.GetHash().GetHex().c_str(),TargetToString(block.nBits).c_str(), TargetToString(nChainLengthCunningham1).c_str(), TargetToString(nChainLengthCunningham2).c_str(), TargetToString(nChainLengthBiTwin).c_str());
//nProbableChainLength = max(max(nChainLengthCunningham1, nChainLengthCunningham2), nChainLengthBiTwin);
// since we are using C structs here we have to make sure the memory for the CBigNum in the block is freed again
//delete *psieve;
//*psieve = NULL;
//block->bnPrimeChainMultiplier = NULL;
RtlZeroMemory(blockRawData, 256);
//delete *psieve;
//*psieve = NULL;
// dont quit if we find a share, there could be other shares in the remaining prime candidates
nTests = 0; // tehere is a good chance to find more shares so search a litle more.
//block->nonce++;
//return true;
//break;
//if (multipleShare)
}
}