// Copyright (c) 2013-2014 Conformal Systems LLC. // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package btcchain import ( "container/list" "errors" "fmt" "github.com/conformal/btcdb" "github.com/conformal/btcnet" "github.com/conformal/btcutil" "github.com/conformal/btcwire" "math/big" "sort" "sync" "time" ) const ( // maxOrphanBlocks is the maximum number of orphan blocks that can be // queued. maxOrphanBlocks = 100 // minMemoryNodes is the minimum number of consecutive nodes needed // in memory in order to perform all necessary validation. It is used // to determine when it's safe to prune nodes from memory without // causing constant dynamic reloading. minMemoryNodes = BlocksPerRetarget ) // ErrIndexAlreadyInitialized describes an error that indicates the block index // is already initialized. var ErrIndexAlreadyInitialized = errors.New("the block index can only be " + "initialized before it has been modified") // blockNode represents a block within the block chain and is primarily used to // aid in selecting the best chain to be the main chain. The main chain is // stored into the block database. type blockNode struct { // parent is the parent block for this node. parent *blockNode // children contains the child nodes for this node. Typically there // will only be one, but sometimes there can be more than one and that // is when the best chain selection algorithm is used. children []*blockNode // hash is the double sha 256 of the block. hash *btcwire.ShaHash // parentHash is the double sha 256 of the parent block. This is kept // here over simply relying on parent.hash directly since block nodes // are sparse and the parent node might not be in memory when its hash // is needed. parentHash *btcwire.ShaHash // height is the position in the block chain. height int64 // workSum is the total amount of work in the chain up to and including // this node. workSum *big.Int // inMainChain denotes whether the block node is currently on the // the main chain or not. This is used to help find the common // ancestor when switching chains. inMainChain bool // Some fields from block headers to aid in best chain selection. version uint32 bits uint32 timestamp time.Time } // newBlockNode returns a new block node for the given block header. It is // completely disconnected from the chain and the workSum value is just the work // for the passed block. The work sum is updated accordingly when the node is // inserted into a chain. func newBlockNode(blockHeader *btcwire.BlockHeader, blockSha *btcwire.ShaHash, height int64) *blockNode { // Make a copy of the hash so the node doesn't keep a reference to part // of the full block/block header preventing it from being garbage // collected. prevHash := blockHeader.PrevBlock node := blockNode{ hash: blockSha, parentHash: &prevHash, workSum: CalcWork(blockHeader.Bits), height: height, version: blockHeader.Version, bits: blockHeader.Bits, timestamp: blockHeader.Timestamp, } return &node } // orphanBlock represents a block that we don't yet have the parent for. It // is a normal block plus an expiration time to prevent caching the orphan // forever. type orphanBlock struct { block *btcutil.Block expiration time.Time } // addChildrenWork adds the passed work amount to all children all the way // down the chain. It is used primarily to allow a new node to be dynamically // inserted from the database into the memory chain prior to nodes we already // have and update their work values accordingly. func addChildrenWork(node *blockNode, work *big.Int) { for _, childNode := range node.children { childNode.workSum.Add(childNode.workSum, work) addChildrenWork(childNode, work) } } // removeChildNode deletes node from the provided slice of child block // nodes. It ensures the final pointer reference is set to nil to prevent // potential memory leaks. The original slice is returned unmodified if node // is invalid or not in the slice. func removeChildNode(children []*blockNode, node *blockNode) []*blockNode { if node == nil { return children } // An indexing for loop is intentionally used over a range here as range // does not reevaluate the slice on each iteration nor does it adjust // the index for the modified slice. for i := 0; i < len(children); i++ { if children[i].hash.IsEqual(node.hash) { copy(children[i:], children[i+1:]) children[len(children)-1] = nil return children[:len(children)-1] } } return children } // BlockChain provides functions for working with the bitcoin block chain. // It includes functionality such as rejecting duplicate blocks, ensuring blocks // follow all rules, orphan handling, checkpoint handling, and best chain // selection with reorganization. type BlockChain struct { db btcdb.Db netParams *btcnet.Params checkpointsByHeight map[int64]*btcnet.Checkpoint notifications NotificationCallback root *blockNode bestChain *blockNode index map[btcwire.ShaHash]*blockNode depNodes map[btcwire.ShaHash][]*blockNode orphans map[btcwire.ShaHash]*orphanBlock prevOrphans map[btcwire.ShaHash][]*orphanBlock oldestOrphan *orphanBlock orphanLock sync.RWMutex blockCache map[btcwire.ShaHash]*btcutil.Block noVerify bool noCheckpoints bool nextCheckpoint *btcnet.Checkpoint checkpointBlock *btcutil.Block } // DisableVerify provides a mechanism to disable transaction script validation // which you DO NOT want to do in production as it could allow double spends // and othe undesirable things. It is provided only for debug purposes since // script validation is extremely intensive and when debugging it is sometimes // nice to quickly get the chain. func (b *BlockChain) DisableVerify(disable bool) { b.noVerify = disable } // HaveBlock returns whether or not the chain instance has the block represented // by the passed hash. This includes checking the various places a block can // be like part of the main chain, on a side chain, or in the orphan pool. // // This function is NOT safe for concurrent access. func (b *BlockChain) HaveBlock(hash *btcwire.ShaHash) bool { return b.IsKnownOrphan(hash) || b.blockExists(hash) } // IsKnownOrphan returns whether the passed hash is currently a known orphan. // Keep in mind that only a limited number of orphans are held onto for a // limited amount of time, so this function must not be used as an absolute // way to test if a block is an orphan block. A full block (as opposed to just // its hash) must be passed to ProcessBlock for that purpose. However, calling // ProcessBlock with an orphan that already exists results in an error, so this // function provides a mechanism for a caller to intelligently detect *recent* // duplicate orphans and react accordingly. // // This function is safe for concurrent access. func (b *BlockChain) IsKnownOrphan(hash *btcwire.ShaHash) bool { // Protect concurrent access. Using a read lock only so multiple // readers can query without blocking each other. b.orphanLock.RLock() defer b.orphanLock.RUnlock() if _, exists := b.orphans[*hash]; exists { return true } return false } // GetOrphanRoot returns the head of the chain for the provided hash from the // map of orphan blocks. // // This function is safe for concurrent access. func (b *BlockChain) GetOrphanRoot(hash *btcwire.ShaHash) *btcwire.ShaHash { // Protect concurrent access. Using a read lock only so multiple // readers can query without blocking each other. b.orphanLock.RLock() defer b.orphanLock.RUnlock() // Keep looping while the parent of each orphaned block is // known and is an orphan itself. orphanRoot := hash prevHash := hash for { orphan, exists := b.orphans[*prevHash] if !exists { break } orphanRoot = prevHash prevHash = &orphan.block.MsgBlock().Header.PrevBlock } return orphanRoot } // removeOrphanBlock removes the passed orphan block from the orphan pool and // previous orphan index. func (b *BlockChain) removeOrphanBlock(orphan *orphanBlock) { // Protect concurrent access. b.orphanLock.Lock() defer b.orphanLock.Unlock() // Remove the orphan block from the orphan pool. It's safe to ignore // the error on Sha since it's cached. orphanHash, _ := orphan.block.Sha() delete(b.orphans, *orphanHash) // Remove the reference from the previous orphan index too. An indexing // for loop is intentionally used over a range here as range does not // reevaluate the slice on each iteration nor does it adjust the index // for the modified slice. prevHash := &orphan.block.MsgBlock().Header.PrevBlock orphans := b.prevOrphans[*prevHash] for i := 0; i < len(orphans); i++ { hash, _ := orphans[i].block.Sha() if hash.IsEqual(orphanHash) { copy(orphans[i:], orphans[i+1:]) orphans[len(orphans)-1] = nil orphans = orphans[:len(orphans)-1] i-- } } b.prevOrphans[*prevHash] = orphans // Remove the map entry altogether if there are no longer any orphans // which depend on the parent hash. if len(b.prevOrphans[*prevHash]) == 0 { delete(b.prevOrphans, *prevHash) } } // addOrphanBlock adds the passed block (which is already determined to be // an orphan prior calling this function) to the orphan pool. It lazily cleans // up any expired blocks so a separate cleanup poller doesn't need to be run. // It also imposes a maximum limit on the number of outstanding orphan // blocks and will remove the oldest received orphan block if the limit is // exceeded. func (b *BlockChain) addOrphanBlock(block *btcutil.Block) { // Remove expired orphan blocks. for _, oBlock := range b.orphans { if time.Now().After(oBlock.expiration) { b.removeOrphanBlock(oBlock) continue } // Update the oldest orphan block pointer so it can be discarded // in case the orphan pool fills up. if b.oldestOrphan == nil || oBlock.expiration.Before(b.oldestOrphan.expiration) { b.oldestOrphan = oBlock } } // Limit orphan blocks to prevent memory exhaustion. if len(b.orphans)+1 > maxOrphanBlocks { // Remove the oldest orphan to make room for the new one. b.removeOrphanBlock(b.oldestOrphan) b.oldestOrphan = nil } // Get the block sha. It is safe to ignore the error here since any // errors would've been caught prior to calling this function. blockSha, _ := block.Sha() // Protect concurrent access. This is intentionally done here instead // of near the top since removeOrphanBlock does its own locking and // the range iterator is not invalidated by removing map entries. b.orphanLock.Lock() defer b.orphanLock.Unlock() // Insert the block into the orphan map with an expiration time // 1 hour from now. expiration := time.Now().Add(time.Hour) oBlock := &orphanBlock{ block: block, expiration: expiration, } b.orphans[*blockSha] = oBlock // Add to previous hash lookup index for faster dependency lookups. prevHash := &block.MsgBlock().Header.PrevBlock b.prevOrphans[*prevHash] = append(b.prevOrphans[*prevHash], oBlock) return } // GenerateInitialIndex is an optional function which generates the required // number of initial block nodes in an optimized fashion. This is optional // because the memory block index is sparse and previous nodes are dynamically // loaded as needed. However, during initial startup (when there are no nodes // in memory yet), dynamically loading all of the required nodes on the fly in // the usual way is much slower than preloading them. // // This function can only be called once and it must be called before any nodes // are added to the block index. ErrIndexAlreadyInitialized is returned if // the former is not the case. In practice, this means the function should be // called directly after New. func (b *BlockChain) GenerateInitialIndex() error { // Return an error if the has already been modified. if b.root != nil { return ErrIndexAlreadyInitialized } // Grab the latest block height for the main chain from the database. _, endHeight, err := b.db.NewestSha() if err != nil { return err } // Calculate the starting height based on the minimum number of nodes // needed in memory. startHeight := endHeight - minMemoryNodes if startHeight < 0 { startHeight = 0 } // Loop forwards through each block loading the node into the index for // the block. // // Due to a bug in the SQLite btcdb driver, the FetchBlockBySha call is // limited to a maximum number of hashes per invocation. Since SQLite // is going to be nuked eventually, the bug isn't being fixed in the // driver. In the mean time, work around the issue by calling // FetchBlockBySha multiple times with the appropriate indices as needed. for start := startHeight; start <= endHeight; { hashList, err := b.db.FetchHeightRange(start, endHeight+1) if err != nil { return err } // The database did not return any further hashes. Break out of // the loop now. if len(hashList) == 0 { break } // Loop forwards through each block loading the node into the // index for the block. for _, hash := range hashList { // Make a copy of the hash to make sure there are no // references into the list so it can be freed. hashCopy := hash node, err := b.loadBlockNode(&hashCopy) if err != nil { return err } // This node is now the end of the best chain. b.bestChain = node } // Start at the next block after the latest one on the next loop // iteration. start += int64(len(hashList)) } return nil } // loadBlockNode loads the block identified by hash from the block database, // creates a block node from it, and updates the memory block chain accordingly. // It is used mainly to dynamically load previous blocks from database as they // are needed to avoid needing to put the entire block chain in memory. func (b *BlockChain) loadBlockNode(hash *btcwire.ShaHash) (*blockNode, error) { // Load the block header and height from the db. blockHeader, err := b.db.FetchBlockHeaderBySha(hash) if err != nil { return nil, err } blockHeight, err := b.db.FetchBlockHeightBySha(hash) if err != nil { return nil, err } // Create the new block node for the block and set the work. node := newBlockNode(blockHeader, hash, blockHeight) node.inMainChain = true // Add the node to the chain. // There are several possibilities here: // 1) This node is a child of an existing block node // 2) This node is the parent of one or more nodes // 3) Neither 1 or 2 is true, and this is not the first node being // added to the tree which implies it's an orphan block and // therefore is an error to insert into the chain // 4) Neither 1 or 2 is true, but this is the first node being added // to the tree, so it's the root. prevHash := &blockHeader.PrevBlock if parentNode, ok := b.index[*prevHash]; ok { // Case 1 -- This node is a child of an existing block node. // Update the node's work sum with the sum of the parent node's // work sum and this node's work, append the node as a child of // the parent node and set this node's parent to the parent // node. node.workSum = node.workSum.Add(parentNode.workSum, node.workSum) parentNode.children = append(parentNode.children, node) node.parent = parentNode } else if childNodes, ok := b.depNodes[*hash]; ok { // Case 2 -- This node is the parent of one or more nodes. // Connect this block node to all of its children and update // all of the children (and their children) with the new work // sums. for _, childNode := range childNodes { childNode.parent = node node.children = append(node.children, childNode) addChildrenWork(childNode, node.workSum) b.root = node } } else { // Case 3 -- The node does't have a parent and is not the parent // of another node. This is only acceptable for the first node // inserted into the chain. Otherwise it means an arbitrary // orphan block is trying to be loaded which is not allowed. if b.root != nil { str := "loadBlockNode: attempt to insert orphan block %v" return nil, fmt.Errorf(str, hash) } // Case 4 -- This is the root since it's the first and only node. b.root = node } // Add the new node to the indices for faster lookups. b.index[*hash] = node b.depNodes[*prevHash] = append(b.depNodes[*prevHash], node) return node, nil } // getPrevNodeFromBlock returns a block node for the block previous to the // passed block (the passed block's parent). When it is already in the memory // block chain, it simply returns it. Otherwise, it loads the previous block // from the block database, creates a new block node from it, and returns it. // The returned node will be nil if the genesis block is passed. func (b *BlockChain) getPrevNodeFromBlock(block *btcutil.Block) (*blockNode, error) { // Genesis block. prevHash := &block.MsgBlock().Header.PrevBlock if prevHash.IsEqual(zeroHash) { return nil, nil } // Return the existing previous block node if it's already there. if bn, ok := b.index[*prevHash]; ok { return bn, nil } // Dynamically load the previous block from the block database, create // a new block node for it, and update the memory chain accordingly. prevBlockNode, err := b.loadBlockNode(prevHash) if err != nil { return nil, err } return prevBlockNode, nil } // getPrevNodeFromNode returns a block node for the block previous to the // passed block node (the passed block node's parent). When the node is already // connected to a parent, it simply returns it. Otherwise, it loads the // associated block from the database to obtain the previous hash and uses that // to dynamically create a new block node and return it. The memory block // chain is updated accordingly. The returned node will be nil if the genesis // block is passed. func (b *BlockChain) getPrevNodeFromNode(node *blockNode) (*blockNode, error) { // Return the existing previous block node if it's already there. if node.parent != nil { return node.parent, nil } // Genesis block. if node.hash.IsEqual(b.netParams.GenesisHash) { return nil, nil } // Dynamically load the previous block from the block database, create // a new block node for it, and update the memory chain accordingly. prevBlockNode, err := b.loadBlockNode(node.parentHash) if err != nil { return nil, err } return prevBlockNode, nil } // removeBlockNode removes the passed block node from the memory chain by // unlinking all of its children and removing it from the the node and // dependency indices. func (b *BlockChain) removeBlockNode(node *blockNode) error { if node.parent != nil { return fmt.Errorf("removeBlockNode must be called with a "+ " node at the front of the chain - node %v", node.hash) } // Remove the node from the node index. delete(b.index, *node.hash) // Unlink all of the node's children. for _, child := range node.children { child.parent = nil } node.children = nil // Remove the reference from the dependency index. prevHash := node.parentHash if children, ok := b.depNodes[*prevHash]; ok { // Find the node amongst the children of the // dependencies for the parent hash and remove it. b.depNodes[*prevHash] = removeChildNode(children, node) // Remove the map entry altogether if there are no // longer any nodes which depend on the parent hash. if len(b.depNodes[*prevHash]) == 0 { delete(b.depNodes, *prevHash) } } return nil } // pruneBlockNodes removes references to old block nodes which are no longer // needed so they may be garbage collected. In order to validate block rules // and choose the best chain, only a portion of the nodes which form the block // chain are needed in memory. This function walks the chain backwards from the // current best chain to find any nodes before the first needed block node. func (b *BlockChain) pruneBlockNodes() error { // Nothing to do if there is not a best chain selected yet. if b.bestChain == nil { return nil } // Walk the chain backwards to find what should be the new root node. // Intentionally use node.parent instead of getPrevNodeFromNode since // the latter loads the node and the goal is to find nodes still in // memory that can be pruned. newRootNode := b.bestChain for i := int64(0); i < minMemoryNodes-1 && newRootNode != nil; i++ { newRootNode = newRootNode.parent } // Nothing to do if there are not enough nodes. if newRootNode == nil || newRootNode.parent == nil { return nil } // Push the nodes to delete on a list in reverse order since it's easier // to prune them going forwards than it is backwards. This will // typically end up being a single node since pruning is currently done // just before each new node is created. However, that might be tuned // later to only prune at intervals, so the code needs to account for // the possibility of multiple nodes. deleteNodes := list.New() for node := newRootNode.parent; node != nil; node = node.parent { deleteNodes.PushFront(node) } // Loop through each node to prune, unlink its children, remove it from // the dependency index, and remove it from the node index. for e := deleteNodes.Front(); e != nil; e = e.Next() { node := e.Value.(*blockNode) err := b.removeBlockNode(node) if err != nil { return err } } // Set the new root node. b.root = newRootNode return nil } // isMajorityVersion determines if a previous number of blocks in the chain // starting with startNode are at least the minimum passed version. func (b *BlockChain) isMajorityVersion(minVer uint32, startNode *blockNode, numRequired, numToCheck uint64) bool { numFound := uint64(0) iterNode := startNode for i := uint64(0); i < numToCheck && iterNode != nil; i++ { // This node has a version that is at least the minimum version. if iterNode.version >= minVer { numFound++ } // Get the previous block node. This function is used over // simply accessing iterNode.parent directly as it will // dynamically create previous block nodes as needed. This // helps allow only the pieces of the chain that are needed // to remain in memory. var err error iterNode, err = b.getPrevNodeFromNode(iterNode) if err != nil { break } } return numFound >= numRequired } // calcPastMedianTime calculates the median time of the previous few blocks // prior to, and including, the passed block node. It is primarily used to // validate new blocks have sane timestamps. func (b *BlockChain) calcPastMedianTime(startNode *blockNode) (time.Time, error) { // Genesis block. if startNode == nil { return b.netParams.GenesisBlock.Header.Timestamp, nil } // Create a slice of the previous few block timestamps used to calculate // the median per the number defined by the constant medianTimeBlocks. timestamps := make([]time.Time, medianTimeBlocks) numNodes := 0 iterNode := startNode for i := 0; i < medianTimeBlocks && iterNode != nil; i++ { timestamps[i] = iterNode.timestamp numNodes++ // Get the previous block node. This function is used over // simply accessing iterNode.parent directly as it will // dynamically create previous block nodes as needed. This // helps allow only the pieces of the chain that are needed // to remain in memory. var err error iterNode, err = b.getPrevNodeFromNode(iterNode) if err != nil { log.Errorf("getPrevNodeFromNode: %v", err) return time.Time{}, err } } // Prune the slice to the actual number of available timestamps which // will be fewer than desired near the beginning of the block chain // and sort them. timestamps = timestamps[:numNodes] sort.Sort(timeSorter(timestamps)) // NOTE: bitcoind incorrectly calculates the median for even numbers of // blocks. A true median averages the middle two elements for a set // with an even number of elements in it. Since the constant for the // previous number of blocks to be used is odd, this is only an issue // for a few blocks near the beginning of the chain. I suspect this is // an optimization even though the result is slightly wrong for a few // of the first blocks since after the first few blocks, there will // always be an odd number of blocks in the set per the constant. // // This code follows suit to ensure the same rules are used as bitcoind // however, be aware that should the medianTimeBlocks constant ever be // changed to an even number, this code will be wrong. medianTimestamp := timestamps[numNodes/2] return medianTimestamp, nil } // CalcPastMedianTime calculates the median time of the previous few blocks // prior to, and including, the end of the current best chain. It is primarily // used to ensure new blocks have sane timestamps. // // This function is NOT safe for concurrent access. func (b *BlockChain) CalcPastMedianTime() (time.Time, error) { return b.calcPastMedianTime(b.bestChain) } // getReorganizeNodes finds the fork point between the main chain and the passed // node and returns a list of block nodes that would need to be detached from // the main chain and a list of block nodes that would need to be attached to // the fork point (which will be the end of the main chain after detaching the // returned list of block nodes) in order to reorganize the chain such that the // passed node is the new end of the main chain. The lists will be empty if the // passed node is not on a side chain. func (b *BlockChain) getReorganizeNodes(node *blockNode) (*list.List, *list.List) { // Nothing to detach or attach if there is no node. attachNodes := list.New() detachNodes := list.New() if node == nil { return detachNodes, attachNodes } // Find the fork point (if any) adding each block to the list of nodes // to attach to the main tree. Push them onto the list in reverse order // so they are attached in the appropriate order when iterating the list // later. ancestor := node for ; ancestor.parent != nil; ancestor = ancestor.parent { if ancestor.inMainChain { break } attachNodes.PushFront(ancestor) } // TODO(davec): Use prevNodeFromNode function in case the requested // node is further back than the what is in memory. This shouldn't // happen in the normal course of operation, but the ability to fetch // input transactions of arbitrary blocks will likely to be exposed at // some point and that could lead to an issue here. // Start from the end of the main chain and work backwards until the // common ancestor adding each block to the list of nodes to detach from // the main chain. for n := b.bestChain; n != nil && n.parent != nil; n = n.parent { if n.hash.IsEqual(ancestor.hash) { break } detachNodes.PushBack(n) } return detachNodes, attachNodes } // connectBlock handles connecting the passed node/block to the end of the main // (best) chain. func (b *BlockChain) connectBlock(node *blockNode, block *btcutil.Block) error { // Make sure it's extending the end of the best chain. prevHash := &block.MsgBlock().Header.PrevBlock if b.bestChain != nil && !prevHash.IsEqual(b.bestChain.hash) { return fmt.Errorf("connectBlock must be called with a block " + "that extends the main chain") } // Insert the block into the database which houses the main chain. _, err := b.db.InsertBlock(block) if err != nil { return err } // Add the new node to the memory main chain indices for faster // lookups. node.inMainChain = true b.index[*node.hash] = node b.depNodes[*prevHash] = append(b.depNodes[*prevHash], node) // This node is now the end of the best chain. b.bestChain = node // Notify the caller that the block was connected to the main chain. // The caller would typically want to react with actions such as // updating wallets. b.sendNotification(NTBlockConnected, block) return nil } // disconnectBlock handles disconnecting the passed node/block from the end of // the main (best) chain. func (b *BlockChain) disconnectBlock(node *blockNode, block *btcutil.Block) error { // Make sure the node being disconnected is the end of the best chain. if b.bestChain == nil || !node.hash.IsEqual(b.bestChain.hash) { return fmt.Errorf("disconnectBlock must be called with the " + "block at the end of the main chain") } // Remove the block from the database which houses the main chain. prevNode, err := b.getPrevNodeFromNode(node) if err != nil { return err } err = b.db.DropAfterBlockBySha(prevNode.hash) if err != nil { return err } // Put block in the side chain cache. node.inMainChain = false b.blockCache[*node.hash] = block // This node's parent is now the end of the best chain. b.bestChain = node.parent // Notify the caller that the block was disconnected from the main // chain. The caller would typically want to react with actions such as // updating wallets. b.sendNotification(NTBlockDisconnected, block) return nil } // reorganizeChain reorganizes the block chain by disconnecting the nodes in the // detachNodes list and connecting the nodes in the attach list. It expects // that the lists are already in the correct order and are in sync with the // end of the current best chain. Specifically, nodes that are being // disconnected must be in reverse order (think of popping them off // the end of the chain) and nodes the are being attached must be in forwards // order (think pushing them onto the end of the chain). func (b *BlockChain) reorganizeChain(detachNodes, attachNodes *list.List) error { // Ensure all of the needed side chain blocks are in the cache. for e := attachNodes.Front(); e != nil; e = e.Next() { n := e.Value.(*blockNode) if _, exists := b.blockCache[*n.hash]; !exists { return fmt.Errorf("block %v is missing from the side "+ "chain block cache", n.hash) } } // Perform several checks to verify each block that needs to be attached // to the main chain can be connected without violating any rules and // without actually connecting the block. // // NOTE: bitcoind does these checks directly when it connects a block. // The downside to that approach is that if any of these checks fail // after disconnecting some blocks or attaching others, all of the // operations have to be rolled back to get the chain back into the // state it was before the rule violation (or other failure). There are // at least a couple of ways accomplish that rollback, but both involve // tweaking the chain. This approach catches these issues before ever // modifying the chain. for e := attachNodes.Front(); e != nil; e = e.Next() { n := e.Value.(*blockNode) block := b.blockCache[*n.hash] err := b.checkConnectBlock(n, block) if err != nil { return err } } // Disconnect blocks from the main chain. for e := detachNodes.Front(); e != nil; e = e.Next() { n := e.Value.(*blockNode) block, err := b.db.FetchBlockBySha(n.hash) if err != nil { return err } err = b.disconnectBlock(n, block) if err != nil { return err } } // Connect the new best chain blocks. for e := attachNodes.Front(); e != nil; e = e.Next() { n := e.Value.(*blockNode) block := b.blockCache[*n.hash] err := b.connectBlock(n, block) if err != nil { return err } delete(b.blockCache, *n.hash) } // Log the point where the chain forked. firstAttachNode := attachNodes.Front().Value.(*blockNode) forkNode, err := b.getPrevNodeFromNode(firstAttachNode) if err == nil { log.Infof("REORGANIZE: Chain forks at %v", forkNode.hash) } // Log the old and new best chain heads. firstDetachNode := detachNodes.Front().Value.(*blockNode) lastAttachNode := attachNodes.Back().Value.(*blockNode) log.Infof("REORGANIZE: Old best chain head was %v", firstDetachNode.hash) log.Infof("REORGANIZE: New best chain head is %v", lastAttachNode.hash) return nil } // connectBestChain handles connecting the passed block to the chain while // respecting proper chain selection according to the chain with the most // proof of work. In the typical case, the new block simply extends the main // chain. However, it may also be extending (or creating) a side chain (fork) // which may or may not end up becoming the main chain depending on which fork // cumulatively has the most proof of work. // The fastAdd argument avoids the call to checkConnectBlock which does // several expensive transaction validation operations. func (b *BlockChain) connectBestChain(node *blockNode, block *btcutil.Block, fastAdd bool) error { // We haven't selected a best chain yet or we are extending the main // (best) chain with a new block. This is the most common case. if b.bestChain == nil || node.parent.hash.IsEqual(b.bestChain.hash) { // Perform several checks to verify the block can be connected // to the main chain (including whatever reorganization might // be necessary to get this node to the main chain) without // violating any rules and without actually connecting the // block. if !fastAdd { err := b.checkConnectBlock(node, block) if err != nil { return err } } // Connect the block to the main chain. err := b.connectBlock(node, block) if err != nil { return err } // Connect the parent node to this node. if node.parent != nil { node.parent.children = append(node.parent.children, node) } return nil } if fastAdd { bsha, _ := block.Sha() log.Warnf("fastAdd set in the side chain case? %v\n", bsha) } // We're extending (or creating) a side chain which may or may not // become the main chain, but in either case we need the block stored // for future processing, so add the block to the side chain holding // cache. log.Debugf("Adding block %v to side chain cache", node.hash) b.blockCache[*node.hash] = block b.index[*node.hash] = node // Connect the parent node to this node. node.inMainChain = false node.parent.children = append(node.parent.children, node) // We're extending (or creating) a side chain, but the cumulative // work for this new side chain is not enough to make it the new chain. if node.workSum.Cmp(b.bestChain.workSum) <= 0 { // Find the fork point. fork := node for ; fork.parent != nil; fork = fork.parent { if fork.inMainChain { break } } // Log information about how the block is forking the chain. if fork.hash.IsEqual(node.parent.hash) { log.Infof("FORK: Block %v forks the chain at height %d"+ "/block %v, but does not cause a reorganize", node.hash, fork.height, fork.hash) } else { log.Infof("EXTEND FORK: Block %v extends a side chain "+ "which forks the chain at height %d/block %v", node.hash, fork.height, fork.hash) } return nil } // We're extending (or creating) a side chain and the cumulative work // for this new side chain is more than the old best chain, so this side // chain needs to become the main chain. In order to accomplish that, // find the common ancestor of both sides of the fork, disconnect the // blocks that form the (now) old fork from the main chain, and attach // the blocks that form the new chain to the main chain starting at the // common ancenstor (the point where the chain forked). detachNodes, attachNodes := b.getReorganizeNodes(node) // Reorganize the chain. log.Infof("REORGANIZE: Block %v is causing a reorganize.", node.hash) err := b.reorganizeChain(detachNodes, attachNodes) if err != nil { return err } return nil } // IsCurrent returns whether or not the chain believes it is current. Several // factors are used to guess, but the key factors that allow the chain to // believe it is current are: // - Latest block height is after the latest checkpoint (if enabled) // - Latest block has a timestamp newer than 24 hours ago // // This function is NOT safe for concurrent access. func (b *BlockChain) IsCurrent() bool { // Not current if there isn't a main (best) chain yet. if b.bestChain == nil { return false } // Not current if the latest main (best) chain height is before the // latest known good checkpoint (when checkpoints are enabled). checkpoint := b.LatestCheckpoint() if checkpoint != nil && b.bestChain.height < checkpoint.Height { return false } // Not current if the latest best block has a timestamp before 24 hours // ago. now := time.Now() if b.bestChain.timestamp.Before(now.Add(-24 * time.Hour)) { return false } // The chain appears to be current if the above checks did not report // otherwise. return true } // New returns a BlockChain instance for the passed bitcoin network using the // provided backing database. It accepts a callback on which notifications // will be sent when various events take place. See the documentation for // Notification and NotificationType for details on the types and contents of // notifications. The provided callback can be nil if the caller is not // interested in receiving notifications. func New(db btcdb.Db, params *btcnet.Params, c NotificationCallback) *BlockChain { // Generate a checkpoint by height map from the provided checkpoints. var checkpointsByHeight map[int64]*btcnet.Checkpoint if len(params.Checkpoints) > 0 { checkpointsByHeight = make(map[int64]*btcnet.Checkpoint) for i := range params.Checkpoints { checkpoint := ¶ms.Checkpoints[i] checkpointsByHeight[checkpoint.Height] = checkpoint } } b := BlockChain{ db: db, netParams: params, checkpointsByHeight: checkpointsByHeight, notifications: c, root: nil, bestChain: nil, index: make(map[btcwire.ShaHash]*blockNode), depNodes: make(map[btcwire.ShaHash][]*blockNode), orphans: make(map[btcwire.ShaHash]*orphanBlock), prevOrphans: make(map[btcwire.ShaHash][]*orphanBlock), blockCache: make(map[btcwire.ShaHash]*btcutil.Block), } return &b }