LLM Caching integrations
This notebook covers how to cache results of individual LLM calls using different caches.
from langchain.globals import set_llm_cache
from langchain.llms import OpenAI
# To make the caching really obvious, lets use a slower model.
llm = OpenAI(model_name="gpt-3.5-turbo-instruct", n=2, best_of=2)
In Memory Cache
from langchain.cache import InMemoryCache
set_llm_cache(InMemoryCache())
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 52.2 ms, sys: 15.2 ms, total: 67.4 ms
Wall time: 1.19 s
"\n\nWhy couldn't the bicycle stand up by itself? Because it was...two tired!"
%%time
# The second time it is, so it goes faster
llm("Tell me a joke")
CPU times: user 191 µs, sys: 11 µs, total: 202 µs
Wall time: 205 µs
"\n\nWhy couldn't the bicycle stand up by itself? Because it was...two tired!"
SQLite Cache
!rm .langchain.db
# We can do the same thing with a SQLite cache
from langchain.cache import SQLiteCache
set_llm_cache(SQLiteCache(database_path=".langchain.db"))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 33.2 ms, sys: 18.1 ms, total: 51.2 ms
Wall time: 667 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side.'
%%time
# The second time it is, so it goes faster
llm("Tell me a joke")
CPU times: user 4.86 ms, sys: 1.97 ms, total: 6.83 ms
Wall time: 5.79 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side.'
Upstash Redis Cache
Standard Cache
Use Upstash Redis to cache prompts and responses with a serverless HTTP API.
import langchain
from langchain.cache import UpstashRedisCache
from upstash_redis import Redis
URL = "<UPSTASH_REDIS_REST_URL>"
TOKEN = "<UPSTASH_REDIS_REST_TOKEN>"
langchain.llm_cache = UpstashRedisCache(redis_=Redis(url=URL, token=TOKEN))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 7.56 ms, sys: 2.98 ms, total: 10.5 ms
Wall time: 1.14 s
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
%%time
# The second time it is, so it goes faster
llm("Tell me a joke")
CPU times: user 2.78 ms, sys: 1.95 ms, total: 4.73 ms
Wall time: 82.9 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
Redis Cache
Standard Cache
Use Redis to cache prompts and responses.
# We can do the same thing with a Redis cache
# (make sure your local Redis instance is running first before running this example)
from langchain.cache import RedisCache
from redis import Redis
set_llm_cache(RedisCache(redis_=Redis()))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 6.88 ms, sys: 8.75 ms, total: 15.6 ms
Wall time: 1.04 s
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
%%time
# The second time it is, so it goes faster
llm("Tell me a joke")
CPU times: user 1.59 ms, sys: 610 µs, total: 2.2 ms
Wall time: 5.58 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
Semantic Cache
Use Redis to cache prompts and responses and evaluate hits based on semantic similarity.
from langchain.cache import RedisSemanticCache
from langchain.embeddings import OpenAIEmbeddings
set_llm_cache(
RedisSemanticCache(redis_url="redis://localhost:6379", embedding=OpenAIEmbeddings())
)
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 351 ms, sys: 156 ms, total: 507 ms
Wall time: 3.37 s
"\n\nWhy don't scientists trust atoms?\nBecause they make up everything."
%%time
# The second time, while not a direct hit, the question is semantically similar to the original question,
# so it uses the cached result!
llm("Tell me one joke")
CPU times: user 6.25 ms, sys: 2.72 ms, total: 8.97 ms
Wall time: 262 ms
"\n\nWhy don't scientists trust atoms?\nBecause they make up everything."
GPTCache
We can use GPTCache for exact match caching OR to cache results based on semantic similarity
Let’s first start with an example of exact match
import hashlib
from gptcache import Cache
from gptcache.manager.factory import manager_factory
from gptcache.processor.pre import get_prompt
from langchain.cache import GPTCache
def get_hashed_name(name):
return hashlib.sha256(name.encode()).hexdigest()
def init_gptcache(cache_obj: Cache, llm: str):
hashed_llm = get_hashed_name(llm)
cache_obj.init(
pre_embedding_func=get_prompt,
data_manager=manager_factory(manager="map", data_dir=f"map_cache_{hashed_llm}"),
)
set_llm_cache(GPTCache(init_gptcache))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 21.5 ms, sys: 21.3 ms, total: 42.8 ms
Wall time: 6.2 s
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
%%time
# The second time it is, so it goes faster
llm("Tell me a joke")
CPU times: user 571 µs, sys: 43 µs, total: 614 µs
Wall time: 635 µs
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
Let’s now show an example of similarity caching
import hashlib
from gptcache import Cache
from gptcache.adapter.api import init_similar_cache
from langchain.cache import GPTCache
def get_hashed_name(name):
return hashlib.sha256(name.encode()).hexdigest()
def init_gptcache(cache_obj: Cache, llm: str):
hashed_llm = get_hashed_name(llm)
init_similar_cache(cache_obj=cache_obj, data_dir=f"similar_cache_{hashed_llm}")
set_llm_cache(GPTCache(init_gptcache))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 1.42 s, sys: 279 ms, total: 1.7 s
Wall time: 8.44 s
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side.'
%%time
# This is an exact match, so it finds it in the cache
llm("Tell me a joke")
CPU times: user 866 ms, sys: 20 ms, total: 886 ms
Wall time: 226 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side.'
%%time
# This is not an exact match, but semantically within distance so it hits!
llm("Tell me joke")
CPU times: user 853 ms, sys: 14.8 ms, total: 868 ms
Wall time: 224 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side.'
Momento Cache
Use Momento to cache prompts and responses.
Requires momento to use, uncomment below to install:
# !pip install momento
You’ll need to get a Momento auth token to use this class. This can
either be passed in to a momento.CacheClient if you’d like to
instantiate that directly, as a named parameter auth_token to
MomentoChatMessageHistory.from_client_params, or can just be set as an
environment variable MOMENTO_AUTH_TOKEN.
from datetime import timedelta
from langchain.cache import MomentoCache
cache_name = "langchain"
ttl = timedelta(days=1)
set_llm_cache(MomentoCache.from_client_params(cache_name, ttl))
%%time
# The first time, it is not yet in cache, so it should take longer
llm("Tell me a joke")
CPU times: user 40.7 ms, sys: 16.5 ms, total: 57.2 ms
Wall time: 1.73 s
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
%%time
# The second time it is, so it goes faster
# When run in the same region as the cache, latencies are single digit ms
llm("Tell me a joke")
CPU times: user 3.16 ms, sys: 2.98 ms, total: 6.14 ms
Wall time: 57.9 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
SQLAlchemy Cache
You can use SQLAlchemyCache to cache with any SQL database supported
by SQLAlchemy.
# from langchain.cache import SQLAlchemyCache
# from sqlalchemy import create_engine
# engine = create_engine("postgresql://postgres:postgres@localhost:5432/postgres")
# set_llm_cache(SQLAlchemyCache(engine))
Custom SQLAlchemy Schemas
# You can define your own declarative SQLAlchemyCache child class to customize the schema used for caching. For example, to support high-speed fulltext prompt indexing with Postgres, use:
from langchain.cache import SQLAlchemyCache
from sqlalchemy import Column, Computed, Index, Integer, Sequence, String, create_engine
from sqlalchemy.ext.declarative import declarative_base
from sqlalchemy_utils import TSVectorType
Base = declarative_base()
class FulltextLLMCache(Base): # type: ignore
"""Postgres table for fulltext-indexed LLM Cache"""
__tablename__ = "llm_cache_fulltext"
id = Column(Integer, Sequence("cache_id"), primary_key=True)
prompt = Column(String, nullable=False)
llm = Column(String, nullable=False)
idx = Column(Integer)
response = Column(String)
prompt_tsv = Column(
TSVectorType(),
Computed("to_tsvector('english', llm || ' ' || prompt)", persisted=True),
)
__table_args__ = (
Index("idx_fulltext_prompt_tsv", prompt_tsv, postgresql_using="gin"),
)
engine = create_engine("postgresql://postgres:postgres@localhost:5432/postgres")
set_llm_cache(SQLAlchemyCache(engine, FulltextLLMCache))
Cassandra caches
You can use Cassandra / Astra DB through CQL for caching LLM responses,
choosing from the exact-match CassandraCache or the
(vector-similarity-based) CassandraSemanticCache.
Let’s see both in action in the following cells.
Connect to the DB
First you need to establish a Session to the DB and to specify a
keyspace for the cache table(s). The following gets you connected to
Astra DB through CQL (see
e.g. here for more
backends and connection options).
import getpass
keyspace = input("\nKeyspace name? ")
ASTRA_DB_APPLICATION_TOKEN = getpass.getpass('\nAstra DB Token ("AstraCS:...") ')
ASTRA_DB_SECURE_BUNDLE_PATH = input("Full path to your Secure Connect Bundle? ")
Keyspace name? my_keyspace
Astra DB Token ("AstraCS:...") ········
Full path to your Secure Connect Bundle? /path/to/secure-connect-databasename.zip
from cassandra.auth import PlainTextAuthProvider
from cassandra.cluster import Cluster
cluster = Cluster(
cloud={
"secure_connect_bundle": ASTRA_DB_SECURE_BUNDLE_PATH,
},
auth_provider=PlainTextAuthProvider("token", ASTRA_DB_APPLICATION_TOKEN),
)
session = cluster.connect()
Exact cache
This will avoid invoking the LLM when the supplied prompt is exactly the same as one encountered already:
from langchain.cache import CassandraCache
from langchain.globals import set_llm_cache
set_llm_cache(CassandraCache(session=session, keyspace=keyspace))
%%time
print(llm("Why is the Moon always showing the same side?"))
The Moon always shows the same side because it is tidally locked to Earth.
CPU times: user 41.7 ms, sys: 153 µs, total: 41.8 ms
Wall time: 1.96 s
%%time
print(llm("Why is the Moon always showing the same side?"))
The Moon always shows the same side because it is tidally locked to Earth.
CPU times: user 4.09 ms, sys: 0 ns, total: 4.09 ms
Wall time: 119 ms
Semantic cache
This cache will do a semantic similarity search and return a hit if it
finds a cached entry that is similar enough, For this, you need to
provide an Embeddings instance of your choice.
from langchain.embeddings import OpenAIEmbeddings
embedding = OpenAIEmbeddings()
from langchain.cache import CassandraSemanticCache
set_llm_cache(
CassandraSemanticCache(
session=session,
keyspace=keyspace,
embedding=embedding,
table_name="cass_sem_cache",
)
)
%%time
print(llm("Why is the Moon always showing the same side?"))
The Moon always shows the same side because it is tidally locked with Earth. This means that the same side of the Moon always faces Earth.
CPU times: user 21.3 ms, sys: 177 µs, total: 21.4 ms
Wall time: 3.09 s
%%time
print(llm("How come we always see one face of the moon?"))
The Moon always shows the same side because it is tidally locked with Earth. This means that the same side of the Moon always faces Earth.
CPU times: user 10.9 ms, sys: 17 µs, total: 10.9 ms
Wall time: 461 ms
Astra DB Caches
You can easily use Astra DB as an LLM cache, with either the “exact” or the “semantic-based” cache.
Make sure you have a running database (it must be a Vector-enabled database to use the Semantic cache) and get the required credentials on your Astra dashboard:
- the API Endpoint looks like
https://01234567-89ab-cdef-0123-456789abcdef-us-east1.apps.astra.datastax.com - the Token looks like
AstraCS:6gBhNmsk135....
import getpass
ASTRA_DB_API_ENDPOINT = input("ASTRA_DB_API_ENDPOINT = ")
ASTRA_DB_APPLICATION_TOKEN = getpass.getpass("ASTRA_DB_APPLICATION_TOKEN = ")
ASTRA_DB_API_ENDPOINT = https://01234567-89ab-cdef-0123-456789abcdef-us-east1.apps.astra.datastax.com
ASTRA_DB_APPLICATION_TOKEN = ········
Astra DB exact LLM cache
This will avoid invoking the LLM when the supplied prompt is exactly the same as one encountered already:
from langchain.cache import AstraDBCache
from langchain.globals import set_llm_cache
set_llm_cache(
AstraDBCache(
api_endpoint=ASTRA_DB_API_ENDPOINT,
token=ASTRA_DB_APPLICATION_TOKEN,
)
)
%%time
print(llm("Is a true fakery the same as a fake truth?"))
There is no definitive answer to this question as it depends on the interpretation of the terms "true fakery" and "fake truth". However, one possible interpretation is that a true fakery is a counterfeit or imitation that is intended to deceive, whereas a fake truth is a false statement that is presented as if it were true.
CPU times: user 70.8 ms, sys: 4.13 ms, total: 74.9 ms
Wall time: 2.06 s
%%time
print(llm("Is a true fakery the same as a fake truth?"))
There is no definitive answer to this question as it depends on the interpretation of the terms "true fakery" and "fake truth". However, one possible interpretation is that a true fakery is a counterfeit or imitation that is intended to deceive, whereas a fake truth is a false statement that is presented as if it were true.
CPU times: user 15.1 ms, sys: 3.7 ms, total: 18.8 ms
Wall time: 531 ms
Astra DB Semantic cache
This cache will do a semantic similarity search and return a hit if it
finds a cached entry that is similar enough, For this, you need to
provide an Embeddings instance of your choice.
from langchain.embeddings import OpenAIEmbeddings
embedding = OpenAIEmbeddings()
from langchain.cache import AstraDBSemanticCache
set_llm_cache(
AstraDBSemanticCache(
api_endpoint=ASTRA_DB_API_ENDPOINT,
token=ASTRA_DB_APPLICATION_TOKEN,
embedding=embedding,
collection_name="demo_semantic_cache",
)
)
%%time
print(llm("Are there truths that are false?"))
There is no definitive answer to this question since it presupposes a great deal about the nature of truth itself, which is a matter of considerable philosophical debate. It is possible, however, to construct scenarios in which something could be considered true despite being false, such as if someone sincerely believes something to be true even though it is not.
CPU times: user 65.6 ms, sys: 15.3 ms, total: 80.9 ms
Wall time: 2.72 s
%%time
print(llm("Is is possible that something false can be also true?"))
There is no definitive answer to this question since it presupposes a great deal about the nature of truth itself, which is a matter of considerable philosophical debate. It is possible, however, to construct scenarios in which something could be considered true despite being false, such as if someone sincerely believes something to be true even though it is not.
CPU times: user 29.3 ms, sys: 6.21 ms, total: 35.5 ms
Wall time: 1.03 s
Optional Caching
You can also turn off caching for specific LLMs should you choose. In the example below, even though global caching is enabled, we turn it off for a specific LLM
llm = OpenAI(model_name="gpt-3.5-turbo-instruct", n=2, best_of=2, cache=False)
%%time
llm("Tell me a joke")
CPU times: user 5.8 ms, sys: 2.71 ms, total: 8.51 ms
Wall time: 745 ms
'\n\nWhy did the chicken cross the road?\n\nTo get to the other side!'
%%time
llm("Tell me a joke")
CPU times: user 4.91 ms, sys: 2.64 ms, total: 7.55 ms
Wall time: 623 ms
'\n\nTwo guys stole a calendar. They got six months each.'
Optional Caching in Chains
You can also turn off caching for particular nodes in chains. Note that because of certain interfaces, its often easier to construct the chain first, and then edit the LLM afterwards.
As an example, we will load a summarizer map-reduce chain. We will cache results for the map-step, but then not freeze it for the combine step.
llm = OpenAI(model_name="gpt-3.5-turbo-instruct")
no_cache_llm = OpenAI(model_name="gpt-3.5-turbo-instruct", cache=False)
from langchain.text_splitter import CharacterTextSplitter
text_splitter = CharacterTextSplitter()
with open("../../modules/state_of_the_union.txt") as f:
state_of_the_union = f.read()
texts = text_splitter.split_text(state_of_the_union)
from langchain.docstore.document import Document
docs = [Document(page_content=t) for t in texts[:3]]
from langchain.chains.summarize import load_summarize_chain
chain = load_summarize_chain(llm, chain_type="map_reduce", reduce_llm=no_cache_llm)
%%time
chain.run(docs)
CPU times: user 452 ms, sys: 60.3 ms, total: 512 ms
Wall time: 5.09 s
'\n\nPresident Biden is discussing the American Rescue Plan and the Bipartisan Infrastructure Law, which will create jobs and help Americans. He also talks about his vision for America, which includes investing in education and infrastructure. In response to Russian aggression in Ukraine, the United States is joining with European allies to impose sanctions and isolate Russia. American forces are being mobilized to protect NATO countries in the event that Putin decides to keep moving west. The Ukrainians are bravely fighting back, but the next few weeks will be hard for them. Putin will pay a high price for his actions in the long run. Americans should not be alarmed, as the United States is taking action to protect its interests and allies.'
When we run it again, we see that it runs substantially faster but the final answer is different. This is due to caching at the map steps, but not at the reduce step.
%%time
chain.run(docs)
CPU times: user 11.5 ms, sys: 4.33 ms, total: 15.8 ms
Wall time: 1.04 s
'\n\nPresident Biden is discussing the American Rescue Plan and the Bipartisan Infrastructure Law, which will create jobs and help Americans. He also talks about his vision for America, which includes investing in education and infrastructure.'
!rm .langchain.db sqlite.db