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// Copyright (c) 2009-2010 Satoshi Nakamoto
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// Copyright (c) 2009-2014 The Bitcoin Core developers
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// Distributed under the MIT software license, see the accompanying
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// file COPYING or http://www.opensource.org/licenses/mit-license.php.
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#include "pow.h"
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#include "arith_uint256.h"
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#include "chain.h"
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#include "primitives/block.h"
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#include "uint256.h"
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Split up util.cpp/h
Split up util.cpp/h into:
- string utilities (hex, base32, base64): no internal dependencies, no dependency on boost (apart from foreach)
- money utilities (parsesmoney, formatmoney)
- time utilities (gettime*, sleep, format date):
- and the rest (logging, argument parsing, config file parsing)
The latter is basically the environment and OS handling,
and is stripped of all utility functions, so we may want to
rename it to something else than util.cpp/h for clarity (Matt suggested
osinterface).
Breaks dependency of sha256.cpp on all the things pulled in by util.
10 years ago
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#include "util.h"
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unsigned int GetNextWorkRequired(const CBlockIndex* pindexLast, const CBlockHeader *pblock, const Consensus::Params& params)
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{
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unsigned int nProofOfWorkLimit = UintToArith256(params.powLimit).GetCompact();
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// Genesis block
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if (pindexLast == NULL)
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return nProofOfWorkLimit;
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// Only change once per difficulty adjustment interval
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if ((pindexLast->nHeight+1) % params.DifficultyAdjustmentInterval() != 0)
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{
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if (params.fPowAllowMinDifficultyBlocks)
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{
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// Special difficulty rule for testnet:
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// If the new block's timestamp is more than 2* 10 minutes
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// then allow mining of a min-difficulty block.
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if (pblock->GetBlockTime() > pindexLast->GetBlockTime() + params.nPowTargetSpacing*2)
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return nProofOfWorkLimit;
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else
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{
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// Return the last non-special-min-difficulty-rules-block
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const CBlockIndex* pindex = pindexLast;
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while (pindex->pprev && pindex->nHeight % params.DifficultyAdjustmentInterval() != 0 && pindex->nBits == nProofOfWorkLimit)
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pindex = pindex->pprev;
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return pindex->nBits;
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}
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}
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return pindexLast->nBits;
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}
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// Go back by what we want to be 14 days worth of blocks
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int nHeightFirst = pindexLast->nHeight - (params.DifficultyAdjustmentInterval()-1);
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assert(nHeightFirst >= 0);
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const CBlockIndex* pindexFirst = pindexLast->GetAncestor(nHeightFirst);
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assert(pindexFirst);
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return CalculateNextWorkRequired(pindexLast, pindexFirst->GetBlockTime(), params);
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}
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unsigned int CalculateNextWorkRequired(const CBlockIndex* pindexLast, int64_t nFirstBlockTime, const Consensus::Params& params)
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{
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// Limit adjustment step
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int64_t nActualTimespan = pindexLast->GetBlockTime() - nFirstBlockTime;
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LogPrintf(" nActualTimespan = %d before bounds\n", nActualTimespan);
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if (nActualTimespan < params.nPowTargetTimespan/4)
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nActualTimespan = params.nPowTargetTimespan/4;
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if (nActualTimespan > params.nPowTargetTimespan*4)
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nActualTimespan = params.nPowTargetTimespan*4;
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// Retarget
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const arith_uint256 bnPowLimit = UintToArith256(params.powLimit);
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arith_uint256 bnNew;
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arith_uint256 bnOld;
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bnNew.SetCompact(pindexLast->nBits);
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bnOld = bnNew;
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bnNew *= nActualTimespan;
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bnNew /= params.nPowTargetTimespan;
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if (bnNew > bnPowLimit)
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bnNew = bnPowLimit;
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/// debug print
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LogPrintf("GetNextWorkRequired RETARGET\n");
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LogPrintf("params.nPowTargetTimespan = %d nActualTimespan = %d\n", params.nPowTargetTimespan, nActualTimespan);
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LogPrintf("Before: %08x %s\n", pindexLast->nBits, bnOld.ToString());
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LogPrintf("After: %08x %s\n", bnNew.GetCompact(), bnNew.ToString());
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return bnNew.GetCompact();
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}
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bool CheckProofOfWork(uint256 hash, unsigned int nBits, const Consensus::Params& params)
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{
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bool fNegative;
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bool fOverflow;
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arith_uint256 bnTarget;
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bnTarget.SetCompact(nBits, &fNegative, &fOverflow);
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// Check range
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if (fNegative || bnTarget == 0 || fOverflow || bnTarget > UintToArith256(params.powLimit))
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return error("CheckProofOfWork(): nBits below minimum work");
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// Check proof of work matches claimed amount
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if (UintToArith256(hash) > bnTarget)
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return error("CheckProofOfWork(): hash doesn't match nBits");
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return true;
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}
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arith_uint256 GetBlockProof(const CBlockIndex& block)
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{
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arith_uint256 bnTarget;
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bool fNegative;
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bool fOverflow;
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bnTarget.SetCompact(block.nBits, &fNegative, &fOverflow);
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if (fNegative || fOverflow || bnTarget == 0)
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return 0;
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// We need to compute 2**256 / (bnTarget+1), but we can't represent 2**256
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// as it's too large for a arith_uint256. However, as 2**256 is at least as large
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// as bnTarget+1, it is equal to ((2**256 - bnTarget - 1) / (bnTarget+1)) + 1,
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// or ~bnTarget / (nTarget+1) + 1.
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return (~bnTarget / (bnTarget + 1)) + 1;
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}
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