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dogecoin/src/chain.cpp
Gregory Maxwell 997a98a674 Replace FindLatestBefore used by importmuti with FindEarliestAtLeast. 
In spite of the name FindLatestBefore used std::lower_bound to try
 to find the earliest block with a nTime greater or equal to the
 the requested value.  But lower_bound uses bisection and requires
 the input to be ordered with respect to the comparison operation.
 Block times are not well ordered.

I don't know what lower_bound is permitted to do when the data
 is not sufficiently ordered, but it's probably not good.
 (I could construct an implementation which would infinite loop...)

To resolve the issue this commit introduces a maximum-so-far to the
 block indexes and searches that.

For clarity the function is renamed to reflect what it actually does.

An issue that remains is that there is no grace period in importmulti:
 If a address is created at time T and a send is immediately broadcast
 and included by a miner with a slow clock there may not yet have been
 any block with at least time T.

The normal rescan has a grace period of 7200 seconds, but importmulti
 does not.
2017-01-12 14:21:43 +00:00

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// Copyright (c) 2009-2010 Satoshi Nakamoto
// Copyright (c) 2009-2016 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include "chain.h"
using namespace std;
/**
* CChain implementation
*/
void CChain::SetTip(CBlockIndex *pindex) {
if (pindex == NULL) {
vChain.clear();
return;
}
vChain.resize(pindex->nHeight + 1);
while (pindex && vChain[pindex->nHeight] != pindex) {
vChain[pindex->nHeight] = pindex;
pindex = pindex->pprev;
}
}
CBlockLocator CChain::GetLocator(const CBlockIndex *pindex) const {
int nStep = 1;
std::vector<uint256> vHave;
vHave.reserve(32);
if (!pindex)
pindex = Tip();
while (pindex) {
vHave.push_back(pindex->GetBlockHash());
// Stop when we have added the genesis block.
if (pindex->nHeight == 0)
break;
// Exponentially larger steps back, plus the genesis block.
int nHeight = std::max(pindex->nHeight - nStep, 0);
if (Contains(pindex)) {
// Use O(1) CChain index if possible.
pindex = (*this)[nHeight];
} else {
// Otherwise, use O(log n) skiplist.
pindex = pindex->GetAncestor(nHeight);
}
if (vHave.size() > 10)
nStep *= 2;
}
return CBlockLocator(vHave);
}
const CBlockIndex *CChain::FindFork(const CBlockIndex *pindex) const {
if (pindex == NULL) {
return NULL;
}
if (pindex->nHeight > Height())
pindex = pindex->GetAncestor(Height());
while (pindex && !Contains(pindex))
pindex = pindex->pprev;
return pindex;
}
CBlockIndex* CChain::FindEarliestAtLeast(int64_t nTime) const
{
std::vector<CBlockIndex*>::const_iterator lower = std::lower_bound(vChain.begin(), vChain.end(), nTime,
[](CBlockIndex* pBlock, const int64_t& time) -> bool { return pBlock->GetBlockTimeMax() < time; });
return (lower == vChain.end() ? NULL : *lower);
}
/** Turn the lowest '1' bit in the binary representation of a number into a '0'. */
int static inline InvertLowestOne(int n) { return n & (n - 1); }
/** Compute what height to jump back to with the CBlockIndex::pskip pointer. */
int static inline GetSkipHeight(int height) {
if (height < 2)
return 0;
// Determine which height to jump back to. Any number strictly lower than height is acceptable,
// but the following expression seems to perform well in simulations (max 110 steps to go back
// up to 2**18 blocks).
return (height & 1) ? InvertLowestOne(InvertLowestOne(height - 1)) + 1 : InvertLowestOne(height);
}
CBlockIndex* CBlockIndex::GetAncestor(int height)
{
if (height > nHeight || height < 0)
return NULL;
CBlockIndex* pindexWalk = this;
int heightWalk = nHeight;
while (heightWalk > height) {
int heightSkip = GetSkipHeight(heightWalk);
int heightSkipPrev = GetSkipHeight(heightWalk - 1);
if (pindexWalk->pskip != NULL &&
(heightSkip == height ||
(heightSkip > height && !(heightSkipPrev < heightSkip - 2 &&
heightSkipPrev >= height)))) {
// Only follow pskip if pprev->pskip isn't better than pskip->pprev.
pindexWalk = pindexWalk->pskip;
heightWalk = heightSkip;
} else {
assert(pindexWalk->pprev);
pindexWalk = pindexWalk->pprev;
heightWalk--;
}
}
return pindexWalk;
}
const CBlockIndex* CBlockIndex::GetAncestor(int height) const
{
return const_cast<CBlockIndex*>(this)->GetAncestor(height);
}
void CBlockIndex::BuildSkip()
{
if (pprev)
pskip = pprev->GetAncestor(GetSkipHeight(nHeight));
}
arith_uint256 GetBlockProof(const CBlockIndex& block)
{
arith_uint256 bnTarget;
bool fNegative;
bool fOverflow;
bnTarget.SetCompact(block.nBits, &fNegative, &fOverflow);
if (fNegative || fOverflow || bnTarget == 0)
return 0;
// We need to compute 2**256 / (bnTarget+1), but we can't represent 2**256
// as it's too large for a arith_uint256. However, as 2**256 is at least as large
// as bnTarget+1, it is equal to ((2**256 - bnTarget - 1) / (bnTarget+1)) + 1,
// or ~bnTarget / (nTarget+1) + 1.
return (~bnTarget / (bnTarget + 1)) + 1;
}
int64_t GetBlockProofEquivalentTime(const CBlockIndex& to, const CBlockIndex& from, const CBlockIndex& tip, const Consensus::Params& params)
{
arith_uint256 r;
int sign = 1;
if (to.nChainWork > from.nChainWork) {
r = to.nChainWork - from.nChainWork;
} else {
r = from.nChainWork - to.nChainWork;
sign = -1;
}
r = r * arith_uint256(params.nPowTargetSpacing) / GetBlockProof(tip);
if (r.bits() > 63) {
return sign * std::numeric_limits<int64_t>::max();
}
return sign * r.GetLow64();
}
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