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180 lines
5.9 KiB
C++
180 lines
5.9 KiB
C++
// Copyright (c) 2009-2010 Satoshi Nakamoto
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// Copyright (c) 2009-2019 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 <chain.h>
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#include <tinyformat.h>
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std::string CBlockIndex::ToString() const
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{
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return strprintf("CBlockIndex(pprev=%p, nHeight=%d, merkle=%s, hashBlock=%s)",
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pprev, nHeight, hashMerkleRoot.ToString(), GetBlockHash().ToString());
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}
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/**
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* CChain implementation
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*/
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void CChain::SetTip(CBlockIndex *pindex) {
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if (pindex == nullptr) {
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vChain.clear();
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return;
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}
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vChain.resize(pindex->nHeight + 1);
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while (pindex && vChain[pindex->nHeight] != pindex) {
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vChain[pindex->nHeight] = pindex;
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pindex = pindex->pprev;
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}
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}
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CBlockLocator CChain::GetLocator(const CBlockIndex *pindex) const {
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int nStep = 1;
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std::vector<uint256> vHave;
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vHave.reserve(32);
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if (!pindex)
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pindex = Tip();
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while (pindex) {
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vHave.push_back(pindex->GetBlockHash());
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// Stop when we have added the genesis block.
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if (pindex->nHeight == 0)
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break;
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// Exponentially larger steps back, plus the genesis block.
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int nHeight = std::max(pindex->nHeight - nStep, 0);
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if (Contains(pindex)) {
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// Use O(1) CChain index if possible.
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pindex = (*this)[nHeight];
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} else {
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// Otherwise, use O(log n) skiplist.
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pindex = pindex->GetAncestor(nHeight);
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}
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if (vHave.size() > 10)
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nStep *= 2;
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}
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return CBlockLocator(vHave);
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}
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const CBlockIndex *CChain::FindFork(const CBlockIndex *pindex) const {
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if (pindex == nullptr) {
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return nullptr;
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}
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if (pindex->nHeight > Height())
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pindex = pindex->GetAncestor(Height());
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while (pindex && !Contains(pindex))
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pindex = pindex->pprev;
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return pindex;
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}
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CBlockIndex* CChain::FindEarliestAtLeast(int64_t nTime, int height) const
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{
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std::pair<int64_t, int> blockparams = std::make_pair(nTime, height);
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std::vector<CBlockIndex*>::const_iterator lower = std::lower_bound(vChain.begin(), vChain.end(), blockparams,
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[](CBlockIndex* pBlock, const std::pair<int64_t, int>& blockparams) -> bool { return pBlock->GetBlockTimeMax() < blockparams.first || pBlock->nHeight < blockparams.second; });
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return (lower == vChain.end() ? nullptr : *lower);
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}
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/** Turn the lowest '1' bit in the binary representation of a number into a '0'. */
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int static inline InvertLowestOne(int n) { return n & (n - 1); }
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/** Compute what height to jump back to with the CBlockIndex::pskip pointer. */
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int static inline GetSkipHeight(int height) {
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if (height < 2)
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return 0;
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// Determine which height to jump back to. Any number strictly lower than height is acceptable,
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// but the following expression seems to perform well in simulations (max 110 steps to go back
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// up to 2**18 blocks).
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return (height & 1) ? InvertLowestOne(InvertLowestOne(height - 1)) + 1 : InvertLowestOne(height);
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}
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const CBlockIndex* CBlockIndex::GetAncestor(int height) const
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{
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if (height > nHeight || height < 0) {
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return nullptr;
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}
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const CBlockIndex* pindexWalk = this;
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int heightWalk = nHeight;
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while (heightWalk > height) {
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int heightSkip = GetSkipHeight(heightWalk);
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int heightSkipPrev = GetSkipHeight(heightWalk - 1);
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if (pindexWalk->pskip != nullptr &&
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(heightSkip == height ||
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(heightSkip > height && !(heightSkipPrev < heightSkip - 2 &&
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heightSkipPrev >= height)))) {
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// Only follow pskip if pprev->pskip isn't better than pskip->pprev.
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pindexWalk = pindexWalk->pskip;
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heightWalk = heightSkip;
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} else {
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assert(pindexWalk->pprev);
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pindexWalk = pindexWalk->pprev;
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heightWalk--;
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}
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}
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return pindexWalk;
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}
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CBlockIndex* CBlockIndex::GetAncestor(int height)
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{
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return const_cast<CBlockIndex*>(static_cast<const CBlockIndex*>(this)->GetAncestor(height));
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}
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void CBlockIndex::BuildSkip()
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{
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if (pprev)
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pskip = pprev->GetAncestor(GetSkipHeight(nHeight));
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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 an 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 / (bnTarget+1) + 1.
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return (~bnTarget / (bnTarget + 1)) + 1;
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}
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int64_t GetBlockProofEquivalentTime(const CBlockIndex& to, const CBlockIndex& from, const CBlockIndex& tip, const Consensus::Params& params)
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{
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arith_uint256 r;
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int sign = 1;
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if (to.nChainWork > from.nChainWork) {
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r = to.nChainWork - from.nChainWork;
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} else {
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r = from.nChainWork - to.nChainWork;
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sign = -1;
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}
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r = r * arith_uint256(params.nPowTargetSpacing) / GetBlockProof(tip);
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if (r.bits() > 63) {
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return sign * std::numeric_limits<int64_t>::max();
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}
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return sign * r.GetLow64();
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}
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/** Find the last common ancestor two blocks have.
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* Both pa and pb must be non-nullptr. */
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const CBlockIndex* LastCommonAncestor(const CBlockIndex* pa, const CBlockIndex* pb) {
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if (pa->nHeight > pb->nHeight) {
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pa = pa->GetAncestor(pb->nHeight);
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} else if (pb->nHeight > pa->nHeight) {
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pb = pb->GetAncestor(pa->nHeight);
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}
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while (pa != pb && pa && pb) {
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pa = pa->pprev;
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pb = pb->pprev;
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}
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// Eventually all chain branches meet at the genesis block.
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assert(pa == pb);
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return pa;
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}
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