Diffbot Graph Transformer
Open In Colab
Use case​
Text data often contain rich relationships and insights that can be useful for various analytics, recommendation engines, or knowledge management applications.
Diffbot’s NLP API allows for the extraction of entities, relationships, and semantic meaning from unstructured text data.
By coupling Diffbot’s NLP API with Neo4j, a graph database, you can create powerful, dynamic graph structures based on the information extracted from text. These graph structures are fully queryable and can be integrated into various applications.
This combination allows for use cases such as:
- Building knowledge graphs from textual documents, websites, or social media feeds.
- Generating recommendations based on semantic relationships in the data.
- Creating advanced search features that understand the relationships between entities.
- Building analytics dashboards that allow users to explore the hidden relationships in data.
Overview​
LangChain provides tools to interact with Graph Databases:
Construct knowledge graphs from text
using graph transformer and store integrationsQuery a graph database
using chains for query creation and executionInteract with a graph database
using agents for robust and flexible querying
Quickstart​
First, get required packages and set environment variables:
!pip install langchain langchain-experimental openai neo4j wikipedia
Diffbot NLP Service​
Diffbot’s NLP service is a tool for extracting entities, relationships, and semantic context from unstructured text data. This extracted information can be used to construct a knowledge graph. To use their service, you’ll need to obtain an API key from Diffbot.
from langchain_experimental.graph_transformers.diffbot import DiffbotGraphTransformer
diffbot_api_key = "DIFFBOT_API_KEY"
diffbot_nlp = DiffbotGraphTransformer(diffbot_api_key=diffbot_api_key)
This code fetches Wikipedia articles about “Warren Buffett” and then
uses DiffbotGraphTransformer
to extract entities and relationships.
The DiffbotGraphTransformer
outputs a structured data GraphDocument
,
which can be used to populate a graph database. Note that text chunking
is avoided due to Diffbot’s character limit per API
request.
from langchain.document_loaders import WikipediaLoader
query = "Warren Buffett"
raw_documents = WikipediaLoader(query=query).load()
graph_documents = diffbot_nlp.convert_to_graph_documents(raw_documents)
Loading the data into a knowledge graph​
You will need to have a running Neo4j instance. One option is to create a free Neo4j database instance in their Aura cloud service. You can also run the database locally using the Neo4j Desktop application, or running a docker container. You can run a local docker container by running the executing the following script:
docker run \
--name neo4j \
-p 7474:7474 -p 7687:7687 \
-d \
-e NEO4J_AUTH=neo4j/pleaseletmein \
-e NEO4J_PLUGINS=\[\"apoc\"\] \
neo4j:latest
If you are using the docker container, you need to wait a couple of second for the database to start.
from langchain.graphs import Neo4jGraph
url = "bolt://localhost:7687"
username = "neo4j"
password = "pleaseletmein"
graph = Neo4jGraph(url=url, username=username, password=password)
The GraphDocuments
can be loaded into a knowledge graph using the
add_graph_documents
method.
graph.add_graph_documents(graph_documents)
Refresh graph schema information​
If the schema of database changes, you can refresh the schema information needed to generate Cypher statements
graph.refresh_schema()
Querying the graph​
We can now use the graph cypher QA chain to ask question of the graph. It is advisable to use gpt-4 to construct Cypher queries to get the best experience.
from langchain.chains import GraphCypherQAChain
from langchain.chat_models import ChatOpenAI
chain = GraphCypherQAChain.from_llm(
cypher_llm=ChatOpenAI(temperature=0, model_name="gpt-4"),
qa_llm=ChatOpenAI(temperature=0, model_name="gpt-3.5-turbo"),
graph=graph,
verbose=True,
)
chain.run("Which university did Warren Buffett attend?")
> Entering new GraphCypherQAChain chain...
Generated Cypher:
MATCH (p:Person {name: "Warren Buffett"})-[:EDUCATED_AT]->(o:Organization)
RETURN o.name
Full Context:
[{'o.name': 'New York Institute of Finance'}, {'o.name': 'Alice Deal Junior High School'}, {'o.name': 'Woodrow Wilson High School'}, {'o.name': 'University of Nebraska'}]
> Finished chain.
'Warren Buffett attended the University of Nebraska.'
chain.run("Who is or was working at Berkshire Hathaway?")
> Entering new GraphCypherQAChain chain...
Generated Cypher:
MATCH (p:Person)-[r:EMPLOYEE_OR_MEMBER_OF]->(o:Organization) WHERE o.name = 'Berkshire Hathaway' RETURN p.name
Full Context:
[{'p.name': 'Charlie Munger'}, {'p.name': 'Oliver Chace'}, {'p.name': 'Howard Buffett'}, {'p.name': 'Howard'}, {'p.name': 'Susan Buffett'}, {'p.name': 'Warren Buffett'}]
> Finished chain.
'Charlie Munger, Oliver Chace, Howard Buffett, Susan Buffett, and Warren Buffett are or were working at Berkshire Hathaway.'