import collections import threading import numpy as np class Fifo: def __init__(self): self.queue = collections.deque() def __call__(self): return self.queue[0] def __len__(self): return len(self.queue) def __setitem__(self, key, stepids): self.queue.append(key) def __delitem__(self, key): if self.queue[0] == key: self.queue.popleft() else: # This is very slow but typically not used. self.queue.remove(key) class Uniform: def __init__(self, seed=0): self.indices = {} self.keys = [] self.rng = np.random.default_rng(seed) self.lock = threading.Lock() def __len__(self): return len(self.keys) def __call__(self): with self.lock: index = self.rng.integers(0, len(self.keys)).item() return self.keys[index] def __setitem__(self, key, stepids): with self.lock: self.indices[key] = len(self.keys) self.keys.append(key) def __delitem__(self, key): with self.lock: assert 2 <= len(self), len(self) index = self.indices.pop(key) last = self.keys.pop() if index != len(self.keys): self.keys[index] = last self.indices[last] = index class Recency: def __init__(self, uprobs, seed=0): assert uprobs[0] >= uprobs[-1], uprobs self.uprobs = uprobs self.tree = self._build(uprobs) self.rng = np.random.default_rng(seed) self.step = 0 self.steps = {} self.items = {} def __len__(self): return len(self.items) def __call__(self): for retry in range(10): try: age = self._sample(self.tree, self.rng) if len(self.items) < len(self.uprobs): age = int(age / len(self.uprobs) * len(self.items)) return self.items[self.step - 1 - age] except KeyError: # Item might have been deleted very recently. if retry < 9: import time time.sleep(0.01) else: raise def __setitem__(self, key, stepids): self.steps[key] = self.step self.items[self.step] = key self.step += 1 def __delitem__(self, key): step = self.steps.pop(key) del self.items[step] def _sample(self, tree, rng, bfactor=16): path = [] for level, prob in enumerate(tree): p = prob for segment in path: p = p[segment] index = rng.choice(len(segment), p=p) path.append(index) index = sum( index * bfactor ** (len(tree) - level - 1) for level, index in enumerate(path)) return index def _build(self, uprobs, bfactor=16): assert np.isfinite(uprobs).all(), uprobs assert (uprobs >= 0).all(), uprobs depth = int(np.ceil(np.log(len(uprobs)) / np.log(bfactor))) size = bfactor ** depth uprobs = np.concatenate([uprobs, np.zeros(size - len(uprobs))]) tree = [uprobs] for level in reversed(range(depth - 1)): tree.insert(0, tree[0].reshape((-1, bfactor)).sum(-1)) for level, prob in enumerate(tree): prob = prob.reshape([bfactor] * (1 + level)) total = prob.sum(-1, keepdims=True) with np.errstate(divide='ignore', invalid='ignore'): tree[level] = np.where(total, prob / total, prob) return tree class Prioritized: def __init__( self, exponent=1.0, initial=1.0, zero_on_sample=False, maxfrac=0.0, branching=16, seed=0): assert 0 <= maxfrac <= 1, maxfrac self.exponent = float(exponent) self.initial = float(initial) self.zero_on_sample = zero_on_sample self.maxfrac = maxfrac self.tree = SampleTree(branching, seed) self.prios = collections.defaultdict(lambda: self.initial) self.stepitems = collections.defaultdict(list) self.items = {} def prioritize(self, stepids, priorities): if not isinstance(stepids[0], bytes): stepids = [x.tobytes() for x in stepids] for stepid, priority in zip(stepids, priorities): try: self.prios[stepid] = priority except KeyError: print('Ignoring priority update for removed time step.') items = [] for stepid in stepids: items += self.stepitems[stepid] for key in list(set(items)): try: self.tree.update(key, self._aggregate(key)) except KeyError: print('Ignoring tree update for removed time step.') def __len__(self): return len(self.items) def __call__(self): key = self.tree.sample() if self.zero_on_sample: zeros = [0.0] * len(self.items[key]) self.prioritize(self.items[key], zeros) return key def __setitem__(self, key, stepids): if not isinstance(stepids[0], bytes): stepids = [x.tobytes() for x in stepids] self.items[key] = stepids [self.stepitems[stepid].append(key) for stepid in stepids] self.tree.insert(key, self._aggregate(key)) def __delitem__(self, key): self.tree.remove(key) stepids = self.items.pop(key) for stepid in stepids: stepitems = self.stepitems[stepid] stepitems.remove(key) if not stepitems: del self.stepitems[stepid] del self.prios[stepid] def _aggregate(self, key): # Both list comprehensions in this function are a performance bottleneck # because they are called very often. prios = [self.prios[stepid] for stepid in self.items[key]] if self.exponent != 1.0: prios = [x ** self.exponent for x in prios] mean = sum(prios) / len(prios) if self.maxfrac: return self.maxfrac * max(prios) + (1 - self.maxfrac) * mean else: return mean class Mixture: def __init__(self, selectors, fractions, seed=0): assert set(selectors.keys()) == set(fractions.keys()) assert sum(fractions.values()) == 1, fractions for key, frac in list(fractions.items()): if not frac: selectors.pop(key) fractions.pop(key) keys = sorted(selectors.keys()) self.selectors = [selectors[key] for key in keys] self.fractions = np.array([fractions[key] for key in keys], np.float32) self.rng = np.random.default_rng(seed) def __call__(self): return self.rng.choice(self.selectors, p=self.fractions)() def __setitem__(self, key, stepids): for selector in self.selectors: selector[key] = stepids def __delitem__(self, key): for selector in self.selectors: del selector[key] def prioritize(self, stepids, priorities): for selector in self.selectors: if hasattr(selector, 'prioritize'): selector.prioritize(stepids, priorities) class SampleTree: def __init__(self, branching=16, seed=0): assert 2 <= branching self.branching = branching self.root = SampleTreeNode() self.last = None self.entries = {} self.rng = np.random.default_rng(seed) def __len__(self): return len(self.entries) def insert(self, key, uprob): if not self.last: node = self.root else: ups = 0 node = self.last.parent while node and len(node) >= self.branching: node = node.parent ups += 1 if not node: node = SampleTreeNode() node.append(self.root) self.root = node for _ in range(ups): below = SampleTreeNode() node.append(below) node = below entry = SampleTreeEntry(key, uprob) node.append(entry) self.entries[key] = entry self.last = entry def remove(self, key): entry = self.entries.pop(key) entry_parent = entry.parent last_parent = self.last.parent entry.parent.remove(entry) if entry is not self.last: entry_parent.append(self.last) node = last_parent ups = 0 while node.parent and not len(node): above = node.parent above.remove(node) node = above ups += 1 if not len(node): self.last = None return while isinstance(node, SampleTreeNode): node = node.children[-1] self.last = node def update(self, key, uprob): entry = self.entries[key] entry.uprob = uprob entry.parent.recompute() def sample(self): node = self.root while isinstance(node, SampleTreeNode): uprobs = np.array([x.uprob for x in node.children]) total = uprobs.sum() if not np.isfinite(total): finite = np.isinf(uprobs) probs = finite / finite.sum() elif total == 0: probs = np.ones(len(uprobs)) / len(uprobs) else: probs = uprobs / total choice = self.rng.choice(np.arange(len(uprobs)), p=probs) node = node.children[choice.item()] return node.key class SampleTreeNode: __slots__ = ('parent', 'children', 'uprob') def __init__(self, parent=None): self.parent = parent self.children = [] self.uprob = 0 def __repr__(self): return ( f'SampleTreeNode(uprob={self.uprob}, ' f'children={[x.uprob for x in self.children]})' ) def __len__(self): return len(self.children) def __bool__(self): return True def append(self, child): if child.parent: child.parent.remove(child) child.parent = self self.children.append(child) self.recompute() def remove(self, child): child.parent = None self.children.remove(child) self.recompute() def recompute(self): self.uprob = sum(x.uprob for x in self.children) self.parent and self.parent.recompute() class SampleTreeEntry: __slots__ = ('parent', 'key', 'uprob') def __init__(self, key=None, uprob=None): self.parent = None self.key = key self.uprob = uprob