I've been working on creating a subclass of db.Model that is automatically cached, i.e.:
- instance.put would store the entity in memcache before persisting it to the datastore
- class.get_by_key_name would first check the cache, and if missed, would go to the datastore to retrieve it and cache it after retrieval
I developed the approach below (which appears to work for me), but I have a few questions:
- I had read Nick Johnson's article on efficient model memcaching which suggests implementing the serialization for memcache through protocol buffers. Looking at the memcache API source code in the SDK, it looks like Google has already implemented protobuf serialization by default. Is my interpretation correct?
- Am I missing some important details (which could get me in the future) in the way I am subclassing db.Model or overriding the two methods?
- Is there a more efficient way of implementing what I've done below?
- Are there guidelines, benchmarks or best practices for when such entity caching would make sense from a performance perspective? Or would it always make sense to cache entities? On a related note, should I be reading anything into the fact that Google hasn't provided a cached model in the modeling API? Are there too many special cases to be thinking about?
Below is my current implementation. I would really appreciate any and all guidance/suggestions on caching entities (even if your response is not a direct answer to one of the 4 questions above, but relevant to the topic overall).
from google.appengine.ext import db from google.appengine.api import memcache import os import logging class CachedModel(db.Model): '''Subclass of db.Model that automatically caches entities for put and attempts to load from cache for get_by_key_name ''' @classmethod def get_by_key_name(cls, key_names, parent=None, **kwargs): cache = memcache.Client() # Ensure that every new deployment of the application results in a cache miss # by including the application version ID in the namespace of the cache entry namespace = os.environ['CURRENT_VERSION_ID'] + '_' + cls.__name__ if not isinstance(key_names, list): key_names = [key_names] entities = cache.get_multi(key_names, namespace=namespace) if entities: logging.info('%s (namespace=%s) retrieved from memcache' % (str(entities.keys()), namespace)) missing_key_names = list(set(key_names) - set(entities.keys())) # For keys missed in memcahce, attempt to retrieve entities from datastore if missing_key_names: missing_entities = super(CachedModel, cls).get_by_key_name(missing_key_names, parent, **kwargs) missing_mapping = zip(missing_key_names, missing_entities) # Determine entities that exist in datastore and store them to memcache entities_to_cache = dict() for key_name, entity in missing_mapping: if entity: entities_to_cache[key_name] = entity if entities_to_cache: logging.info('%s (namespace=%s) cached by get_by_key_name' % (str(entities_to_cache.keys()), namespace)) cache.set_multi(entities_to_cache, namespace=namespace) non_existent = set(missing_key_names) - set(entities_to_cache.keys()) if non_existent: logging.info('%s (namespace=%s) missing from cache and datastore' % (str(non_existent), namespace)) # Combine entities retrieved from cache and entities retrieved from datastore entities.update(missing_mapping) if len(key_names) == 1: return entities[key_names] else: return [entities[key_name] for key_name in key_names] def put(self, **kwargs): cache = memcache.Client() namespace = os.environ['CURRENT_VERSION_ID'] + '_' + self.__class__.__name__ cache.set(self.key().name(), self, namespace=namespace) logging.info('%s (namespace=%s) cached by put' % (self.key().name(), namespace)) return super(CachedModel, self).put(**kwargs)