/tmp/bitcoin/src/chain.cpp
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1 | | // Copyright (c) 2009-2010 Satoshi Nakamoto |
2 | | // Copyright (c) 2009-present The Bitcoin Core developers |
3 | | // Distributed under the MIT software license, see the accompanying |
4 | | // file COPYING or http://www.opensource.org/licenses/mit-license.php. |
5 | | |
6 | | #include <chain.h> |
7 | | #include <tinyformat.h> |
8 | | #include <util/check.h> |
9 | | |
10 | | std::string CBlockIndex::ToString() const |
11 | 0 | { |
12 | 0 | return strprintf("CBlockIndex(pprev=%p, nHeight=%d, merkle=%s, hashBlock=%s)", |
13 | 0 | pprev, nHeight, hashMerkleRoot.ToString(), GetBlockHash().ToString()); |
14 | 0 | } |
15 | | |
16 | | void CChain::SetTip(CBlockIndex& block) |
17 | 820k | { |
18 | 820k | CBlockIndex* pindex = █ |
19 | 820k | vChain.resize(pindex->nHeight + 1); |
20 | 125M | while (pindex && vChain[pindex->nHeight] != pindex) { |
21 | 124M | vChain[pindex->nHeight] = pindex; |
22 | 124M | pindex = pindex->pprev; |
23 | 124M | } |
24 | 820k | } |
25 | | |
26 | | std::vector<uint256> LocatorEntries(const CBlockIndex* index) |
27 | 21.0k | { |
28 | 21.0k | int step = 1; |
29 | 21.0k | std::vector<uint256> have; |
30 | 21.0k | if (index == nullptr) return have; |
31 | | |
32 | 21.0k | have.reserve(32); |
33 | 350k | while (index) { |
34 | 350k | have.emplace_back(index->GetBlockHash()); |
35 | 350k | if (index->nHeight == 0) break; |
36 | | // Exponentially larger steps back, plus the genesis block. |
37 | 329k | int height = std::max(index->nHeight - step, 0); |
38 | | // Use skiplist. |
39 | 329k | index = index->GetAncestor(height); |
40 | 329k | if (have.size() > 10) step *= 2; |
41 | 329k | } |
42 | 21.0k | return have; |
43 | 21.0k | } |
44 | | |
45 | | CBlockLocator GetLocator(const CBlockIndex* index) |
46 | 21.0k | { |
47 | 21.0k | return CBlockLocator{LocatorEntries(index)}; |
48 | 21.0k | } |
49 | | |
50 | | const CBlockIndex* CChain::FindFork(const CBlockIndex& index) const |
51 | 195k | { |
52 | 195k | const auto* pindex{&index}; |
53 | 195k | if (pindex->nHeight > Height()) |
54 | 97.7k | pindex = pindex->GetAncestor(Height()); |
55 | 219k | while (pindex && !Contains(*pindex)) |
56 | 24.2k | pindex = pindex->pprev; |
57 | 195k | return pindex; |
58 | 195k | } |
59 | | |
60 | | CBlockIndex* CChain::FindEarliestAtLeast(int64_t nTime, int height) const |
61 | 10.7k | { |
62 | 10.7k | std::pair<int64_t, int> blockparams = std::make_pair(nTime, height); |
63 | 10.7k | std::vector<CBlockIndex*>::const_iterator lower = std::lower_bound(vChain.begin(), vChain.end(), blockparams, |
64 | 171k | [](CBlockIndex* pBlock, const std::pair<int64_t, int>& blockparams) -> bool { return pBlock->GetBlockTimeMax() < blockparams.first || pBlock->nHeight < blockparams.second; }); |
65 | 10.7k | return (lower == vChain.end() ? nullptr : *lower); |
66 | 10.7k | } |
67 | | |
68 | | /** Turn the lowest '1' bit in the binary representation of a number into a '0'. */ |
69 | 210M | int static inline InvertLowestOne(int n) { return n & (n - 1); } |
70 | | |
71 | | /** Compute what height to jump back to with the CBlockIndex::pskip pointer. */ |
72 | 140M | int static inline GetSkipHeight(int height) { |
73 | 140M | if (height < 2) |
74 | 103k | return 0; |
75 | | |
76 | | // Determine which height to jump back to. Any number strictly lower than height is acceptable, |
77 | | // but the following expression seems to perform well in simulations (max 110 steps to go back |
78 | | // up to 2**18 blocks). |
79 | 140M | return (height & 1) ? InvertLowestOne(InvertLowestOne(height - 1)) + 1 : InvertLowestOne(height); |
80 | 140M | } |
81 | | |
82 | | const CBlockIndex* CBlockIndex::GetAncestor(int height) const |
83 | 23.5M | { |
84 | 23.5M | if (height > nHeight || height < 0) { |
85 | 12.4M | return nullptr; |
86 | 12.4M | } |
87 | | |
88 | 11.0M | const CBlockIndex* pindexWalk = this; |
89 | 11.0M | int heightWalk = nHeight; |
90 | 77.9M | while (heightWalk > height) { |
91 | 66.8M | int heightSkip = GetSkipHeight(heightWalk); |
92 | 66.8M | int heightSkipPrev = GetSkipHeight(heightWalk - 1); |
93 | 66.8M | if (pindexWalk->pskip != nullptr && |
94 | 66.8M | (heightSkip == height || |
95 | 66.8M | (heightSkip > height && !(heightSkipPrev < heightSkip - 2 && |
96 | 33.0M | heightSkipPrev >= height)))) { |
97 | | // Only follow pskip if pprev->pskip isn't better than pskip->pprev. |
98 | 33.0M | pindexWalk = pindexWalk->pskip; |
99 | 33.0M | heightWalk = heightSkip; |
100 | 33.8M | } else { |
101 | 33.8M | assert(pindexWalk->pprev); |
102 | 33.8M | pindexWalk = pindexWalk->pprev; |
103 | 33.8M | heightWalk--; |
104 | 33.8M | } |
105 | 66.8M | } |
106 | 11.0M | return pindexWalk; |
107 | 11.0M | } |
108 | | |
109 | | CBlockIndex* CBlockIndex::GetAncestor(int height) |
110 | 17.4M | { |
111 | 17.4M | return const_cast<CBlockIndex*>(static_cast<const CBlockIndex*>(this)->GetAncestor(height)); |
112 | 17.4M | } |
113 | | |
114 | | void CBlockIndex::BuildSkip() |
115 | 6.66M | { |
116 | 6.66M | if (pprev) |
117 | 6.66M | pskip = pprev->GetAncestor(GetSkipHeight(nHeight)); |
118 | 6.66M | } |
119 | | |
120 | | arith_uint256 GetBitsProof(uint32_t bits) |
121 | 997k | { |
122 | 997k | arith_uint256 bnTarget; |
123 | 997k | bool fNegative; |
124 | 997k | bool fOverflow; |
125 | 997k | bnTarget.SetCompact(bits, &fNegative, &fOverflow); |
126 | 997k | if (fNegative || fOverflow || bnTarget == 0) |
127 | 28 | return 0; |
128 | | // We need to compute 2**256 / (bnTarget+1), but we can't represent 2**256 |
129 | | // as it's too large for an arith_uint256. However, as 2**256 is at least as large |
130 | | // as bnTarget+1, it is equal to ((2**256 - bnTarget - 1) / (bnTarget+1)) + 1, |
131 | | // or ~bnTarget / (bnTarget+1) + 1. |
132 | 997k | return (~bnTarget / (bnTarget + 1)) + 1; |
133 | 997k | } |
134 | | |
135 | | int64_t GetBlockProofEquivalentTime(const CBlockIndex& to, const CBlockIndex& from, const CBlockIndex& tip, const Consensus::Params& params) |
136 | 1.37k | { |
137 | 1.37k | arith_uint256 r; |
138 | 1.37k | int sign = 1; |
139 | 1.37k | if (to.nChainWork > from.nChainWork) { |
140 | 862 | r = to.nChainWork - from.nChainWork; |
141 | 862 | } else { |
142 | 513 | r = from.nChainWork - to.nChainWork; |
143 | 513 | sign = -1; |
144 | 513 | } |
145 | 1.37k | r = r * arith_uint256(params.nPowTargetSpacing) / GetBlockProof(tip); |
146 | 1.37k | if (r.bits() > 63) { |
147 | 0 | return sign * std::numeric_limits<int64_t>::max(); |
148 | 0 | } |
149 | 1.37k | return sign * int64_t(r.GetLow64()); |
150 | 1.37k | } |
151 | | |
152 | | /** Find the last common ancestor two blocks have. |
153 | | * Both pa and pb must be non-nullptr. */ |
154 | 232k | const CBlockIndex* LastCommonAncestor(const CBlockIndex* pa, const CBlockIndex* pb) { |
155 | | // First rewind to the last common height (the forking point cannot be past one of the two). |
156 | 232k | if (pa->nHeight > pb->nHeight) { |
157 | 89.3k | pa = pa->GetAncestor(pb->nHeight); |
158 | 142k | } else if (pb->nHeight > pa->nHeight) { |
159 | 51.2k | pb = pb->GetAncestor(pa->nHeight); |
160 | 51.2k | } |
161 | 911k | while (pa != pb) { |
162 | | // Jump back until pa and pb have a common "skip" ancestor. |
163 | 1.22M | while (pa->pskip != pb->pskip) { |
164 | | // This logic relies on the property that equal-height blocks have equal-height skip |
165 | | // pointers. |
166 | 547k | Assume(pa->nHeight == pb->nHeight); |
167 | 547k | Assume(pa->pskip->nHeight == pb->pskip->nHeight); |
168 | 547k | pa = pa->pskip; |
169 | 547k | pb = pb->pskip; |
170 | 547k | } |
171 | | // At this point, pa and pb are different, but have equal pskip. The forking point lies in |
172 | | // between pa/pb on the one end, and pa->pskip/pb->pskip on the other end. |
173 | 678k | pa = pa->pprev; |
174 | 678k | pb = pb->pprev; |
175 | 678k | } |
176 | 232k | return pa; |
177 | 232k | } |