needle
Needle Retriever
Needle makes it easy to create your RAG pipelines with minimal effort.
For more details, refer to our API documentation
Overview
The Needle Document Loader is a utility for integrating Needle collections with LangChain. It enables seamless storage, retrieval, and utilization of documents for Retrieval-Augmented Generation (RAG) workflows.
This example demonstrates:
- Storing documents into a Needle collection.
- Setting up a retriever to fetch documents.
- Building a Retrieval-Augmented Generation (RAG) pipeline.
Setup
Before starting, ensure you have the following environment variables set:
- NEEDLE_API_KEY: Your API key for authenticating with Needle.
- OPENAI_API_KEY: Your OpenAI API key for language model operations.
Initialization
To initialize the NeedleLoader, you need the following parameters:
- needle_api_key: Your Needle API key (or set it as an environment variable).
- collection_id: The ID of the Needle collection to work with.
import os
os.environ["NEEDLE_API_KEY"] = ""
os.environ["OPENAI_API_KEY"] = ""
Instantiation
from langchain_community.document_loaders.needle import NeedleLoader
collection_id = "clt_01J87M9T6B71DHZTHNXYZQRG5H"
# Initialize NeedleLoader to store documents to the collection
document_loader = NeedleLoader(
needle_api_key=os.getenv("NEEDLE_API_KEY"),
collection_id=collection_id,
)
API Reference:NeedleLoader
Load
To add files to the Needle collection:
files = {
"tech-radar-30.pdf": "https://www.thoughtworks.com/content/dam/thoughtworks/documents/radar/2024/04/tr_technology_radar_vol_30_en.pdf"
}
document_loader.add_files(files=files)
# Show the documents in the collection
# collections_documents = document_loader.load()
Usage
Use within a chain
Below is a complete example of setting up a RAG pipeline with Needle within a chain:
import os
from langchain.chains import create_retrieval_chain
from langchain.chains.combine_documents import create_stuff_documents_chain
from langchain_community.retrievers.needle import NeedleRetriever
from langchain_core.prompts import ChatPromptTemplate
from langchain_openai import ChatOpenAI
llm = ChatOpenAI(temperature=0)
# Initialize the Needle retriever (make sure your Needle API key is set as an environment variable)
retriever = NeedleRetriever(
needle_api_key=os.getenv("NEEDLE_API_KEY"),
collection_id="clt_01J87M9T6B71DHZTHNXYZQRG5H",
)
# Define system prompt for the assistant
system_prompt = """
You are an assistant for question-answering tasks.
Use the following pieces of retrieved context to answer the question.
If you don't know, say so concisely.\n\n{context}
"""
prompt = ChatPromptTemplate.from_messages(
[("system", system_prompt), ("human", "{input}")]
)
# Define the question-answering chain using a document chain (stuff chain) and the retriever
question_answer_chain = create_stuff_documents_chain(llm, prompt)
# Create the RAG (Retrieval-Augmented Generation) chain by combining the retriever and the question-answering chain
rag_chain = create_retrieval_chain(retriever, question_answer_chain)
# Define the input query
query = {"input": "Did RAG move to accepted?"}
response = rag_chain.invoke(query)
response
API Reference:create_retrieval_chain | create_stuff_documents_chain | NeedleRetriever | ChatPromptTemplate | ChatOpenAI
{'input': 'Did RAG move to accepted?',
'context': [Document(metadata={}, page_content='New Moved in/out No change\n\n© Thoughtworks, Inc. All Rights Reserved. 12\n\nTechniques\n\n1. Retrieval-augmented generation (RAG)\nAdopt\n\nRetrieval-augmented generation (RAG) is the preferred pattern for our teams to improve the quality of \nresponses generated by a large language model (LLM). We’ve successfully used it in several projects, \nincluding the popular Jugalbandi AI Platform. With RAG, information about relevant and trustworthy \ndocuments — in formats like HTML and PDF — are stored in databases that supports a vector data \ntype or efficient document search, such as pgvector, Qdrant or Elasticsearch Relevance Engine. For \na given prompt, the database is queried to retrieve relevant documents, which are then combined \nwith the prompt to provide richer context to the LLM. This results in higher quality output and greatly \nreduced hallucinations. The context window — which determines the maximum size of the LLM input \n— is limited, which means that selecting the most relevant documents is crucial. We improve the \nrelevancy of the content that is added to the prompt by reranking. Similarly, the documents are usually \ntoo large to calculate an embedding, which means they must be split into smaller chunks. This is often \na difficult problem, and one approach is to have the chunks overlap to a certain extent.'),
Document(metadata={}, page_content='New Moved in/out No change\n\n© Thoughtworks, Inc. All Rights Reserved. 12\n\nTechniques\n\n1. Retrieval-augmented generation (RAG)\nAdopt\n\nRetrieval-augmented generation (RAG) is the preferred pattern for our teams to improve the quality of \nresponses generated by a large language model (LLM). We’ve successfully used it in several projects, \nincluding the popular Jugalbandi AI Platform. With RAG, information about relevant and trustworthy \ndocuments — in formats like HTML and PDF — are stored in databases that supports a vector data \ntype or efficient document search, such as pgvector, Qdrant or Elasticsearch Relevance Engine. For \na given prompt, the database is queried to retrieve relevant documents, which are then combined \nwith the prompt to provide richer context to the LLM. This results in higher quality output and greatly \nreduced hallucinations. The context window — which determines the maximum size of the LLM input \n— is limited, which means that selecting the most relevant documents is crucial. We improve the \nrelevancy of the content that is added to the prompt by reranking. Similarly, the documents are usually \ntoo large to calculate an embedding, which means they must be split into smaller chunks. This is often \na difficult problem, and one approach is to have the chunks overlap to a certain extent.'),
Document(metadata={}, page_content='New Moved in/out No change\n\n© Thoughtworks, Inc. All Rights Reserved. 12\n\nTechniques\n\n1. Retrieval-augmented generation (RAG)\nAdopt\n\nRetrieval-augmented generation (RAG) is the preferred pattern for our teams to improve the quality of \nresponses generated by a large language model (LLM). We’ve successfully used it in several projects, \nincluding the popular Jugalbandi AI Platform. With RAG, information about relevant and trustworthy \ndocuments — in formats like HTML and PDF — are stored in databases that supports a vector data \ntype or efficient document search, such as pgvector, Qdrant or Elasticsearch Relevance Engine. For \na given prompt, the database is queried to retrieve relevant documents, which are then combined \nwith the prompt to provide richer context to the LLM. This results in higher quality output and greatly \nreduced hallucinations. The context window — which determines the maximum size of the LLM input \n— is limited, which means that selecting the most relevant documents is crucial. We improve the \nrelevancy of the content that is added to the prompt by reranking. Similarly, the documents are usually \ntoo large to calculate an embedding, which means they must be split into smaller chunks. This is often \na difficult problem, and one approach is to have the chunks overlap to a certain extent.'),
Document(metadata={}, page_content='New Moved in/out No change\n\n© Thoughtworks, Inc. All Rights Reserved. 12\n\nTechniques\n\n1. Retrieval-augmented generation (RAG)\nAdopt\n\nRetrieval-augmented generation (RAG) is the preferred pattern for our teams to improve the quality of \nresponses generated by a large language model (LLM). We’ve successfully used it in several projects, \nincluding the popular Jugalbandi AI Platform. With RAG, information about relevant and trustworthy \ndocuments — in formats like HTML and PDF — are stored in databases that supports a vector data \ntype or efficient document search, such as pgvector, Qdrant or Elasticsearch Relevance Engine. For \na given prompt, the database is queried to retrieve relevant documents, which are then combined \nwith the prompt to provide richer context to the LLM. This results in higher quality output and greatly \nreduced hallucinations. The context window — which determines the maximum size of the LLM input \n— is limited, which means that selecting the most relevant documents is crucial. We improve the \nrelevancy of the content that is added to the prompt by reranking. Similarly, the documents are usually \ntoo large to calculate an embedding, which means they must be split into smaller chunks. This is often \na difficult problem, and one approach is to have the chunks overlap to a certain extent.'),
Document(metadata={}, page_content='https://www.thoughtworks.com/radar/tools/nemo-guardrails\nhttps://www.thoughtworks.com/radar/platforms/langfuse\nhttps://www.thoughtworks.com/radar/techniques/retrieval-augmented-generation-rag\nhttps://cruisecontrol.sourceforge.net/\nhttps://martinfowler.com/articles/continuousIntegration.html\nhttps://www.thoughtworks.com/radar/techniques/peer-review-equals-pull-request\nhttps://martinfowler.com/bliki/ContinuousIntegrationCertification.html\nhttps://linearb.io/platform/gitstream\nhttps://www.thoughtworks.com/radar/tools/github-merge-queue\nhttps://stacking.dev/\n\n© Thoughtworks, Inc. All Rights Reserved. 8\n\nHold HoldAssess AssessTrial TrialAdopt Adopt\n\n18\n\n8\n\n24\n\n29\n\n30\n31\n\n32\n33\n\n34 35\n\n36\n37\n\n38 39\n\n40\n41\n\n42\n43\n\n26\n\n2\n\n3\n\n4\n\n5\n\n6 7\n\n9\n\n15\n\n16\n\n17\n\n10\n\n11\n\n12\n\n13 14\n\n44\n\n47\n49\n\n50\n\n65\n66\n\n67 68\n69\n\n70\n71\n\n72\n\n73 74\n\n75\n\n76 77\n\n78\n79\n\n80\n81\n\n82\n\n83\n\n51\n\n52 54\n\n59\n\n53\n56\n\n58\n\n61\n\n62\n63\n\n64\n\n85\n\n88 89\n\n90 91\n\n92\n93\n\n94\n95 96\n\n97\n\n98 99\n\n100\n\n101\n102\n\n103\n\n104\n\n86\n\n87\n1921\n\n22\n\n20\n28\n\n25\n\n27\n\n23\n\n84\n\n105\n\n1\n45\n\n46\n\n48\n\n55\n57')],
'answer': 'Yes, RAG has moved to the "Adopt" status.'}
API reference
For detailed documentation of all Needle
features and configurations head to the API reference: https://docs.needle-ai.com
Related
- Retriever conceptual guide
- Retriever how-to guides