from __future__ import annotations import inspect import threading import time import urllib.parse from collections.abc import Iterable from math import ceil, floor from types import ModuleType from limits.errors import ConfigurationError from limits.storage.base import ( SlidingWindowCounterSupport, Storage, TimestampedSlidingWindow, ) from limits.typing import ( Any, Callable, MemcachedClientP, P, R, cast, ) from limits.util import get_dependency class MemcachedStorage(Storage, SlidingWindowCounterSupport, TimestampedSlidingWindow): """ Rate limit storage with memcached as backend. Depends on :pypi:`pymemcache`. """ STORAGE_SCHEME = ["memcached"] """The storage scheme for memcached""" DEPENDENCIES = ["pymemcache"] def __init__( self, uri: str, wrap_exceptions: bool = False, **options: str | Callable[[], MemcachedClientP], ) -> None: """ :param uri: memcached location of the form ``memcached://host:port,host:port``, ``memcached:///var/tmp/path/to/sock`` :param wrap_exceptions: Whether to wrap storage exceptions in :exc:`limits.errors.StorageError` before raising it. :param options: all remaining keyword arguments are passed directly to the constructor of :class:`pymemcache.client.base.PooledClient` or :class:`pymemcache.client.hash.HashClient` (if there are more than one hosts specified) :raise ConfigurationError: when :pypi:`pymemcache` is not available """ parsed = urllib.parse.urlparse(uri) self.hosts = [] for loc in parsed.netloc.strip().split(","): if not loc: continue host, port = loc.split(":") self.hosts.append((host, int(port))) else: # filesystem path to UDS if parsed.path and not parsed.netloc and not parsed.port: self.hosts = [parsed.path] # type: ignore self.dependency = self.dependencies["pymemcache"].module self.library = str(options.pop("library", "pymemcache.client")) self.cluster_library = str( options.pop("cluster_library", "pymemcache.client.hash") ) self.client_getter = cast( Callable[[ModuleType, list[tuple[str, int]]], MemcachedClientP], options.pop("client_getter", self.get_client), ) self.options = options if not get_dependency(self.library): raise ConfigurationError( f"memcached prerequisite not available. please install {self.library}" ) # pragma: no cover self.local_storage = threading.local() self.local_storage.storage = None super().__init__(uri, wrap_exceptions=wrap_exceptions) @property def base_exceptions( self, ) -> type[Exception] | tuple[type[Exception], ...]: # pragma: no cover return self.dependency.MemcacheError # type: ignore[no-any-return] def get_client( self, module: ModuleType, hosts: list[tuple[str, int]], **kwargs: str ) -> MemcachedClientP: """ returns a memcached client. :param module: the memcached module :param hosts: list of memcached hosts """ return cast( MemcachedClientP, ( module.HashClient(hosts, **kwargs) if len(hosts) > 1 else module.PooledClient(*hosts, **kwargs) ), ) def call_memcached_func( self, func: Callable[P, R], *args: P.args, **kwargs: P.kwargs ) -> R: if "noreply" in kwargs: argspec = inspect.getfullargspec(func) if not ("noreply" in argspec.args or argspec.varkw): kwargs.pop("noreply") return func(*args, **kwargs) @property def storage(self) -> MemcachedClientP: """ lazily creates a memcached client instance using a thread local """ if not (hasattr(self.local_storage, "storage") and self.local_storage.storage): dependency = get_dependency( self.cluster_library if len(self.hosts) > 1 else self.library )[0] if not dependency: raise ConfigurationError(f"Unable to import {self.cluster_library}") self.local_storage.storage = self.client_getter( dependency, self.hosts, **self.options ) return cast(MemcachedClientP, self.local_storage.storage) def get(self, key: str) -> int: """ :param key: the key to get the counter value for """ return int(self.storage.get(key, "0")) def get_many(self, keys: Iterable[str]) -> dict[str, Any]: # type:ignore[explicit-any] """ Return multiple counters at once :param keys: the keys to get the counter values for """ return self.storage.get_many(keys) def clear(self, key: str) -> None: """ :param key: the key to clear rate limits for """ self.storage.delete(key) def incr( self, key: str, expiry: float, elastic_expiry: bool = False, amount: int = 1, set_expiration_key: bool = True, ) -> int: """ increments the counter for a given rate limit key :param key: the key to increment :param expiry: amount in seconds for the key to expire in :param elastic_expiry: whether to keep extending the rate limit window every hit. :param amount: the number to increment by :param set_expiration_key: set the expiration key with the expiration time if needed. If set to False, the key will still expire, but memcached cannot provide the expiration time. """ value = self.call_memcached_func(self.storage.incr, key, amount, noreply=False) if value is not None: if elastic_expiry: self.call_memcached_func(self.storage.touch, key, ceil(expiry)) if set_expiration_key: self.call_memcached_func( self.storage.set, self._expiration_key(key), expiry + time.time(), expire=ceil(expiry), noreply=False, ) return value else: if not self.call_memcached_func( self.storage.add, key, amount, ceil(expiry), noreply=False ): value = self.storage.incr(key, amount) or amount if elastic_expiry: self.call_memcached_func(self.storage.touch, key, ceil(expiry)) if set_expiration_key: self.call_memcached_func( self.storage.set, self._expiration_key(key), expiry + time.time(), expire=ceil(expiry), noreply=False, ) return value else: if set_expiration_key: self.call_memcached_func( self.storage.set, self._expiration_key(key), expiry + time.time(), expire=ceil(expiry), noreply=False, ) return amount def get_expiry(self, key: str) -> float: """ :param key: the key to get the expiry for """ return float(self.storage.get(self._expiration_key(key)) or time.time()) def _expiration_key(self, key: str) -> str: """ Return the expiration key for the given counter key. Memcached doesn't natively return the expiration time or TTL for a given key, so we implement the expiration time on a separate key. """ return key + "/expires" def check(self) -> bool: """ Check if storage is healthy by calling the ``get`` command on the key ``limiter-check`` """ try: self.call_memcached_func(self.storage.get, "limiter-check") return True except: # noqa return False def reset(self) -> int | None: raise NotImplementedError def acquire_sliding_window_entry( self, key: str, limit: int, expiry: int, amount: int = 1, ) -> bool: if amount > limit: return False now = time.time() previous_key, current_key = self.sliding_window_keys(key, expiry, now) previous_count, previous_ttl, current_count, _ = self._get_sliding_window_info( previous_key, current_key, expiry, now=now ) weighted_count = previous_count * previous_ttl / expiry + current_count if floor(weighted_count) + amount > limit: return False else: # Hit, increase the current counter. # If the counter doesn't exist yet, set twice the theorical expiry. # We don't need the expiration key as it is estimated with the timestamps directly. current_count = self.incr( current_key, 2 * expiry, amount=amount, set_expiration_key=False ) actualised_previous_ttl = min(0, previous_ttl - (time.time() - now)) weighted_count = ( previous_count * actualised_previous_ttl / expiry + current_count ) if floor(weighted_count) > limit: # Another hit won the race condition: revert the incrementation and refuse this hit # Limitation: during high concurrency at the end of the window, # the counter is shifted and cannot be decremented, so less requests than expected are allowed. self.call_memcached_func( self.storage.decr, current_key, amount, noreply=True, ) return False return True def get_sliding_window( self, key: str, expiry: int ) -> tuple[int, float, int, float]: now = time.time() previous_key, current_key = self.sliding_window_keys(key, expiry, now) return self._get_sliding_window_info(previous_key, current_key, expiry, now) def _get_sliding_window_info( self, previous_key: str, current_key: str, expiry: int, now: float ) -> tuple[int, float, int, float]: result = self.get_many([previous_key, current_key]) previous_count, current_count = ( int(result.get(previous_key, 0)), int(result.get(current_key, 0)), ) if previous_count == 0: previous_ttl = float(0) else: previous_ttl = (1 - (((now - expiry) / expiry) % 1)) * expiry current_ttl = (1 - ((now / expiry) % 1)) * expiry + expiry return previous_count, previous_ttl, current_count, current_ttl