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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
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