github.com/core-coin/go-core/v2@v2.1.9/core/forkid/forkid.go (about) 1 // Copyright 2019 by the Authors 2 // This file is part of the go-core library. 3 // 4 // The go-core library is free software: you can redistribute it and/or modify 5 // it under the terms of the GNU Lesser General Public License as published by 6 // the Free Software Foundation, either version 3 of the License, or 7 // (at your option) any later version. 8 // 9 // The go-core library is distributed in the hope that it will be useful, 10 // but WITHOUT ANY WARRANTY; without even the implied warranty of 11 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 12 // GNU Lesser General Public License for more details. 13 // 14 // You should have received a copy of the GNU Lesser General Public License 15 // along with the go-core library. If not, see <http://www.gnu.org/licenses/>. 16 17 // Package forkid implements CIP-2124 (https://cips.coreblockchain.cc/CIPS/cip-2124). 18 package forkid 19 20 import ( 21 "encoding/binary" 22 "errors" 23 "hash/crc32" 24 "math" 25 "math/big" 26 "reflect" 27 "strings" 28 29 "github.com/core-coin/go-core/v2/common" 30 "github.com/core-coin/go-core/v2/core/types" 31 "github.com/core-coin/go-core/v2/log" 32 "github.com/core-coin/go-core/v2/params" 33 ) 34 35 var ( 36 // ErrRemoteStale is returned by the validator if a remote fork checksum is a 37 // subset of our already applied forks, but the announced next fork block is 38 // not on our already passed chain. 39 ErrRemoteStale = errors.New("remote needs update") 40 41 // ErrLocalIncompatibleOrStale is returned by the validator if a remote fork 42 // checksum does not match any local checksum variation, signalling that the 43 // two chains have diverged in the past at some point (possibly at genesis). 44 ErrLocalIncompatibleOrStale = errors.New("local incompatible or needs update") 45 ) 46 47 // Blockchain defines all necessary method to build a forkID. 48 type Blockchain interface { 49 // Config retrieves the chain's fork configuration. 50 Config() *params.ChainConfig 51 52 // Genesis retrieves the chain's genesis block. 53 Genesis() *types.Block 54 55 // CurrentHeader retrieves the current head header of the canonical chain. 56 CurrentHeader() *types.Header 57 } 58 59 // ID is a fork identifier as defined by CIP-2124. 60 type ID struct { 61 Hash [4]byte // CRC32 checksum of the genesis block and passed fork block numbers 62 Next uint64 // Block number of the next upcoming fork, or 0 if no forks are known 63 } 64 65 // Filter is a fork id filter to validate a remotely advertised ID. 66 type Filter func(id ID) error 67 68 // NewID calculates the Core fork ID from the chain config, genesis hash, and head. 69 func NewID(config *params.ChainConfig, genesis common.Hash, head uint64) ID { 70 // Calculate the starting checksum from the genesis hash 71 hash := crc32.ChecksumIEEE(genesis[:]) 72 73 // Calculate the current fork checksum and the next fork block 74 var next uint64 75 for _, fork := range gatherForks(config) { 76 if fork <= head { 77 // Fork already passed, checksum the previous hash and the fork number 78 hash = checksumUpdate(hash, fork) 79 continue 80 } 81 next = fork 82 break 83 } 84 return ID{Hash: checksumToBytes(hash), Next: next} 85 } 86 87 // NewFilter creates a filter that returns if a fork ID should be rejected or not 88 // based on the local chain's status. 89 func NewFilter(chain Blockchain) Filter { 90 return newFilter( 91 chain.Config(), 92 chain.Genesis().Hash(), 93 func() uint64 { 94 return chain.CurrentHeader().Number.Uint64() 95 }, 96 ) 97 } 98 99 // NewStaticFilter creates a filter at block zero. 100 func NewStaticFilter(config *params.ChainConfig, genesis common.Hash) Filter { 101 head := func() uint64 { return 0 } 102 return newFilter(config, genesis, head) 103 } 104 105 // newFilter is the internal version of NewFilter, taking closures as its arguments 106 // instead of a chain. The reason is to allow testing it without having to simulate 107 // an entire blockchain. 108 func newFilter(config *params.ChainConfig, genesis common.Hash, headfn func() uint64) Filter { 109 // Calculate the all the valid fork hash and fork next combos 110 var ( 111 forks = gatherForks(config) 112 sums = make([][4]byte, len(forks)+1) // 0th is the genesis 113 ) 114 hash := crc32.ChecksumIEEE(genesis[:]) 115 sums[0] = checksumToBytes(hash) 116 for i, fork := range forks { 117 hash = checksumUpdate(hash, fork) 118 sums[i+1] = checksumToBytes(hash) 119 } 120 // Add two sentries to simplify the fork checks and don't require special 121 // casing the last one. 122 forks = append(forks, math.MaxUint64) // Last fork will never be passed 123 124 // Create a validator that will filter out incompatible chains 125 return func(id ID) error { 126 // Run the fork checksum validation ruleset: 127 // 1. If local and remote FORK_CSUM matches, compare local head to FORK_NEXT. 128 // The two nodes are in the same fork state currently. They might know 129 // of differing future forks, but that's not relevant until the fork 130 // triggers (might be postponed, nodes might be updated to match). 131 // 1a. A remotely announced but remotely not passed block is already passed 132 // locally, disconnect, since the chains are incompatible. 133 // 1b. No remotely announced fork; or not yet passed locally, connect. 134 // 2. If the remote FORK_CSUM is a subset of the local past forks and the 135 // remote FORK_NEXT matches with the locally following fork block number, 136 // connect. 137 // Remote node is currently syncing. It might eventually diverge from 138 // us, but at this current point in time we don't have enough information. 139 // 3. If the remote FORK_CSUM is a superset of the local past forks and can 140 // be completed with locally known future forks, connect. 141 // Local node is currently syncing. It might eventually diverge from 142 // the remote, but at this current point in time we don't have enough 143 // information. 144 // 4. Reject in all other cases. 145 head := headfn() 146 for i, fork := range forks { 147 // If our head is beyond this fork, continue to the next (we have a dummy 148 // fork of maxuint64 as the last item to always fail this check eventually). 149 if head > fork { 150 continue 151 } 152 // Found the first unpassed fork block, check if our current state matches 153 // the remote checksum (rule #1). 154 if sums[i] == id.Hash { 155 // Fork checksum matched, check if a remote future fork block already passed 156 // locally without the local node being aware of it (rule #1a). 157 if id.Next > 0 && head >= id.Next { 158 return ErrLocalIncompatibleOrStale 159 } 160 // Haven't passed locally a remote-only fork, accept the connection (rule #1b). 161 return nil 162 } 163 // The local and remote nodes are in different forks currently, check if the 164 // remote checksum is a subset of our local forks (rule #2). 165 for j := 0; j < i; j++ { 166 if sums[j] == id.Hash { 167 // Remote checksum is a subset, validate based on the announced next fork 168 if forks[j] != id.Next { 169 return ErrRemoteStale 170 } 171 return nil 172 } 173 } 174 // Remote chain is not a subset of our local one, check if it's a superset by 175 // any chance, signalling that we're simply out of sync (rule #3). 176 for j := i + 1; j < len(sums); j++ { 177 if sums[j] == id.Hash { 178 // Yay, remote checksum is a superset, ignore upcoming forks 179 return nil 180 } 181 } 182 // No exact, subset or superset match. We are on differing chains, reject. 183 return ErrLocalIncompatibleOrStale 184 } 185 log.Error("Impossible fork ID validation", "id", id) 186 return nil // Something's very wrong, accept rather than reject 187 } 188 } 189 190 // checksumUpdate calculates the next IEEE CRC32 checksum based on the previous 191 // one and a fork block number (equivalent to CRC32(original-blob || fork)). 192 func checksumUpdate(hash uint32, fork uint64) uint32 { 193 var blob [8]byte 194 binary.BigEndian.PutUint64(blob[:], fork) 195 return crc32.Update(hash, crc32.IEEETable, blob[:]) 196 } 197 198 // checksumToBytes converts a uint32 checksum into a [4]byte array. 199 func checksumToBytes(hash uint32) [4]byte { 200 var blob [4]byte 201 binary.BigEndian.PutUint32(blob[:], hash) 202 return blob 203 } 204 205 // gatherForks gathers all the known forks and creates a sorted list out of them. 206 func gatherForks(config *params.ChainConfig) []uint64 { 207 // Gather all the fork block numbers via reflection 208 kind := reflect.TypeOf(params.ChainConfig{}) 209 conf := reflect.ValueOf(config).Elem() 210 211 var forks []uint64 212 for i := 0; i < kind.NumField(); i++ { 213 // Fetch the next field and skip non-fork rules 214 field := kind.Field(i) 215 if !strings.HasSuffix(field.Name, "Block") { 216 continue 217 } 218 if field.Type != reflect.TypeOf(new(big.Int)) { 219 continue 220 } 221 // Extract the fork rule block number and aggregate it 222 rule := conf.Field(i).Interface().(*big.Int) 223 if rule != nil { 224 forks = append(forks, rule.Uint64()) 225 } 226 } 227 // Sort the fork block numbers to permit chronological XOR 228 for i := 0; i < len(forks); i++ { 229 for j := i + 1; j < len(forks); j++ { 230 if forks[i] > forks[j] { 231 forks[i], forks[j] = forks[j], forks[i] 232 } 233 } 234 } 235 // Deduplicate block numbers applying multiple forks 236 for i := 1; i < len(forks); i++ { 237 if forks[i] == forks[i-1] { 238 forks = append(forks[:i], forks[i+1:]...) 239 i-- 240 } 241 } 242 // Skip any forks in block 0, that's the genesis ruleset 243 if len(forks) > 0 && forks[0] == 0 { 244 forks = forks[1:] 245 } 246 return forks 247 }