import heapq import time import operator import asyncio from collections import OrderedDict from .kademlia.utils import OrderedSet, sharedPrefix, bytesToBitString class KBucket: def __init__(self, rangeLower, rangeUpper, ksize): self.range = (rangeLower, rangeUpper) self.nodes = OrderedDict() self.replacementNodes = OrderedSet() self.touchLastUpdated() self.ksize = ksize def touchLastUpdated(self): self.lastUpdated = time.monotonic() def getNodes(self): return list(self.nodes.values()) def split(self): midpoint = (self.range[0] + self.range[1]) / 2 one = KBucket(self.range[0], midpoint, self.ksize) two = KBucket(midpoint + 1, self.range[1], self.ksize) for node in self.nodes.values(): bucket = one if node.long_id <= midpoint else two bucket.nodes[node.id] = node return (one, two) def removeNode(self, node): if node.id not in self.nodes: return # delete node, and see if we can add a replacement del self.nodes[node.id] if len(self.replacementNodes) > 0: newnode = self.replacementNodes.pop() self.nodes[newnode.id] = newnode def hasInRange(self, node): return self.range[0] <= node.long_id <= self.range[1] def isNewNode(self, node): return node.id not in self.nodes def addNode(self, node): """ Add a C{Node} to the C{KBucket}. Return True if successful, False if the bucket is full. If the bucket is full, keep track of node in a replacement list, per section 4.1 of the paper. """ if node.id in self.nodes: del self.nodes[node.id] self.nodes[node.id] = node elif len(self) < self.ksize: self.nodes[node.id] = node else: self.replacementNodes.push(node) return False return True def depth(self): vals = self.nodes.values() sp = sharedPrefix([bytesToBitString(n.id) for n in vals]) return len(sp) def head(self): return list(self.nodes.values())[0] def __getitem__(self, node_id): return self.nodes.get(node_id, None) def __len__(self): return len(self.nodes) class TableTraverser: def __init__(self, table, startNode): index = table.getBucketFor(startNode) table.buckets[index].touchLastUpdated() self.currentNodes = table.buckets[index].getNodes() self.leftBuckets = table.buckets[:index] self.rightBuckets = table.buckets[(index + 1):] self.left = True def __iter__(self): return self def __next__(self): """ Pop an item from the left subtree, then right, then left, etc. """ if len(self.currentNodes) > 0: return self.currentNodes.pop() if self.left and len(self.leftBuckets) > 0: self.currentNodes = self.leftBuckets.pop().getNodes() self.left = False return next(self) if len(self.rightBuckets) > 0: self.currentNodes = self.rightBuckets.pop(0).getNodes() self.left = True return next(self) raise StopIteration class RoutingTable: def __init__(self, protocol, ksize, node): """ @param node: The node that represents this server. It won't be added to the routing table, but will be needed later to determine which buckets to split or not. """ self.node = node self.protocol = protocol self.ksize = ksize self.flush() def flush(self): self.buckets = [KBucket(0, 2 ** 160, self.ksize)] def splitBucket(self, index): one, two = self.buckets[index].split() self.buckets[index] = one self.buckets.insert(index + 1, two) def getLonelyBuckets(self): """ Get all of the buckets that haven't been updated in over an hour. """ hrago = time.monotonic() - 3600 return [b for b in self.buckets if b.lastUpdated < hrago] def removeContact(self, node): index = self.getBucketFor(node) self.buckets[index].removeNode(node) def isNewNode(self, node): index = self.getBucketFor(node) return self.buckets[index].isNewNode(node) def addContact(self, node): index = self.getBucketFor(node) bucket = self.buckets[index] # this will succeed unless the bucket is full if bucket.addNode(node): return # Per section 4.2 of paper, split if the bucket has the node # in its range or if the depth is not congruent to 0 mod 5 if bucket.hasInRange(self.node) or bucket.depth() % 5 != 0: self.splitBucket(index) self.addContact(node) else: asyncio.ensure_future(self.protocol.callPing(bucket.head())) def getBucketFor(self, node): """ Get the index of the bucket that the given node would fall into. """ for index, bucket in enumerate(self.buckets): if node.long_id < bucket.range[1]: return index def findNeighbors(self, node, k=None, exclude=None): k = k or self.ksize nodes = [] for neighbor in TableTraverser(self, node): notexcluded = exclude is None or not neighbor.sameHomeAs(exclude) if neighbor.id != node.id and notexcluded: heapq.heappush(nodes, (node.distanceTo(neighbor), neighbor)) if len(nodes) == k: break return list(map(operator.itemgetter(1), heapq.nsmallest(k, nodes)))