Building a Retrieval Augmented Generation Chatbot

With LangChain and Panel

Sophia Yang, Ph.D.
8 min readNov 29, 2023

By: Andrew Huang and Sophia Yang

Retrieval-augmented generation (RAG) has been empowering Conversational AI by allowing it to access and leverage external knowledge bases. In this post, we delve into how to build a RAG chatbot with LangChain and Panel. You will learn:

  • What is Retrieval-Augmented Generation (RAG)?
  • How to develop a Retrieval-Augmented Generation (RAG) application in LangChain?
  • How to use Panel’s chat interface for our RAG application?

By the end of this blog, you will be able to build a RAG chatbot like this:

What is Retrieval-Augmented Generation (RAG)?

Are you interested in making a chatbot that can make use of your own collections of data when answering questions? Retrieval-augmented generation (RAG) is an AI framework that combines the strengths of pre-trained language models and information retrieval systems to generate responses in a conversational AI system or to create content by leveraging external knowledge. It integrates the retrieval of relevant information from a knowledge source and the generation of responses based on that retrieved information.

In a typical RAG setup:

  • Retrieval: Given a user query or prompt, the system searches through a knowledge source (a vector store with text embeddings) to find relevant documents or text snippets. The retrieval component typically employs some form of similarity or relevance scoring to determine which portions of the knowledge source are most pertinent to the input query.
  • Generation: The retrieved documents or snippets are then provided to a large language model, which uses them as additional context for generating a more detailed, factual, and relevant response.

RAG can be particularly useful when the pre-trained language model alone may not have the necessary information to generate accurate or sufficiently detailed responses since standard language models like GPT-4 are not capable of accessing real-time or post-training external information directly.

Basic setup

Before we get started in building a RAG application, you will need to install panel1.3 and other packages you might need including jupyterlab, pypdf, chromadb, tiktoken, langchain, openai.

Developing a Retrieval-Augmented Generation (RAG) application in LangChain

There are actually multiple ways to do RAG in LangChain. Check out our previous blog post “​​4 Ways to Do Question Answering in LangChain” for details. In this example, we will use the RetrievalQA chain. There are several steps in this process:

Source: https://python.langchain.com/docs/modules/data_connection/
  • Load documents: LangChain provides multiple built-in document loaders, that work with PDF files, JSON files, or a Python file in your file directory. We can use LangChain’s PyPDFLoader to seamlessly import your PDF.
  • Split documents into chunks: When our document is long, it’s necessary to split up our document text into chunks. There are various ways to split your text. Let’s just use the simplest method CharacterTextSplitter here to split based on characters and measure chunk length by the number of characters.
  • Create text embeddings: The text chunks are then translated into numerical vectors through embeddings, allowing us to work with text data like semantic search in a computationally efficient manner. We can choose an embedding model provider like OpenAI for this task.
  • Create a vector store: We then need to store our embedding vectors in a vector store, which allows us to search and retrieve the relevant vectors at query time.
  • Create a retriever interface: We can expose the vector store in a retriever interface. To retrieve text, we can choose a search type like “similarity” to use similarity search in the retriever object where it selects text chunk vectors that are most similar to the question vector. k=2 lets us find the top 2 most relevant text chunk vectors.
  • Create a RetrievalQA chain to answer questions: A RetrievalQA chain chains a large language model with our retriever interface. You can also define the chain type as one of the four options: “stuff,” “map reduce,” “refine,” “map_rerank”:
  • The default chain_type=”stuff” incorporates ALL text from the documents into the prompt.
  • The “map_reduce” type breaks texts into groups, poses the question to the LLM for each batch separately, and derives the ultimate answer based on the replies from each batch.
  • The “refine” type partitions texts into batches, presents the first batch to the LLM, and then submits the answer along with the second batch to the LLM. It progressively refines the answer by processing through all the batches.
  • The “map-rerank” type divides texts into batches, submits each one to the LLM, returns a score indicating how comprehensively it answers the question, and determines the final answer based on the highest-scoring replies from each batch.
import os
from langchain.chains import RetrievalQA
from langchain.document_loaders import PyPDFLoader
from langchain.embeddings import OpenAIEmbeddings
from langchain.llms import OpenAI
from langchain.text_splitter import CharacterTextSplitter
from langchain.vectorstores import Chroma

os.environ["OPENAI_API_KEY"] = "Type your OpenAI API key here"
# load documents
loader = PyPDFLoader("example.pdf")
documents = loader.load()
# split the documents into chunks
text_splitter = CharacterTextSplitter(chunk_size=1000, chunk_overlap=0)
texts = text_splitter.split_documents(documents)
# select which embeddings we want to use
embeddings = OpenAIEmbeddings()
# create the vectorestore to use as the index
db = Chroma.from_documents(texts, embeddings)
# expose this index in a retriever interface
retriever = db.as_retriever(
search_type="similarity", search_kwargs={"k": 2}
)
# create a chain to answer questions
qa = RetrievalQA.from_chain_type(
llm=OpenAI(),
chain_type="map_reduce",
retriever=retriever,
return_source_documents=True,
verbose=True,
)

When we ask a question, we can see the result and two source documents:

Using Panel’s chat interface for our RAG application

In our previous blog post, we introduced Panel’s brand new chat interface and how to build basic AI chatbots in Panel. We recommend you check out that blog post if you are interested in learning more about the Panel and the chat interface. To make a Panel chatbot for our RAG application, here are four simple steps:

  • Define Panel widgets
  • Wrap LangChain logic into a function
  • Create a chat interface
  • Customize the look with a template

Step 1. Define Panel widgets

Panel widgets are interactive components that allow you to upload files or select values for your application.

For our RAG application chatbot, we define four Panel widgets:

  • pdf_input: To allow users to upload a PDF file.
  • key_input: To input the OpenAI API key.
  • k_slider: To select the number of relevant text chunks.
  • chain_select: To select the chain type for retrieval.
import panel as pn 
pn.extension()


pdf_input = pn.widgets.FileInput(accept=".pdf", value="", height=50)
key_input = pn.widgets.PasswordInput(
name="OpenAI Key",
placeholder="sk-...",
)
k_slider = pn.widgets.IntSlider(
name="Number of Relevant Chunks", start=1, end=5, step=1, value=2
)
chain_select = pn.widgets.RadioButtonGroup(
name="Chain Type", options=["stuff", "map_reduce", "refine", "map_rerank"]
)
chat_input = pn.widgets.TextInput(placeholder="First, upload a PDF!")

Here is what the widget looks like in a Jupyter Notebook:

Step 2: Wrap LangChain Logic into a Function

Next, let’s wrap up the LangChain code above into a function. This function should look very familiar to you. It’s worth pointing out that we have replaced some values with the widgets we just defined. Specifically:

  • We define OpenAI API key with the key_input widget
  • We load the file in the pdf_input widget
  • We replace search_kwargs={“k”: 2} with search_kwargs={“k”: k_slider.value} so that we can control how many relevant docs we’d like to retrieve
  • We replace chain_type=”map_reduce” with chain_type=chain_select.value to allow us to choose one of the four chain types.
def initialize_chain():
if key_input.value:
os.environ["OPENAI_API_KEY"] = key_input.value

selections = (pdf_input.value, k_slider.value, chain_select.value)
if selections in pn.state.cache:
return pn.state.cache[selections]

chat_input.placeholder = "Ask questions here!"

# load document
with tempfile.NamedTemporaryFile("wb", delete=False) as f:
f.write(pdf_input.value)
file_name = f.name
loader = PyPDFLoader(file_name)
documents = loader.load()
# split the documents into chunks
text_splitter = CharacterTextSplitter(chunk_size=1000, chunk_overlap=0)
texts = text_splitter.split_documents(documents)
# select which embeddings we want to use
embeddings = OpenAIEmbeddings()
# create the vectorestore to use as the index
db = Chroma.from_documents(texts, embeddings)
# expose this index in a retriever interface
retriever = db.as_retriever(
search_type="similarity", search_kwargs={"k": k_slider.value}
)
# create a chain to answer questions
qa = RetrievalQA.from_chain_type(
llm=OpenAI(),
chain_type=chain_select.value,
retriever=retriever,
return_source_documents=True,
verbose=True,
)
return qa

After we define the values in the widgets, we can call this function and ask questions about the document we uploaded in the pdf_input widget:

Step 3. Create a chat interface

How do we interact with our documents and ask questions in a chat interface? This is where Panel’s ChatInterface widget comes in!

We need to create a function respond to define how the chatbot responds. This function takes the response from Step 2 and formats it into a Panel object answers. We also append the relevant source documents in this Panel object. Then we can simply call the function in the pn.chat.ChatInterface callback.

async def respond(contents, user, chat_interface):
if not pdf_input.value:
chat_interface.send(
{"user": "System", "value": "Please first upload a PDF!"}, respond=False
)
return
elif chat_interface.active == 0:
chat_interface.active = 1
chat_interface.active_widget.placeholder = "Ask questions here!"
yield {"user": "OpenAI", "value": "Let's chat about the PDF!"}
return

qa = initialize_chain()
response = qa({"query": contents})
answers = pn.Column(response["result"])
answers.append(pn.layout.Divider())
for doc in response["source_documents"][::-1]:
answers.append(f"**Page {doc.metadata['page']}**:")
answers.append(f"```\n{doc.page_content}\n```")
yield {"user": "OpenAI", "value": answers}


chat_interface = pn.chat.ChatInterface(
callback=respond, sizing_mode="stretch_width", widgets=[pdf_input, chat_input]
)
chat_interface.send(
{"user": "System", "value": "Please first upload a PDF and click send!"},
respond=False,
)

Step 4. Customize the look with a template

The final step is to combine the widget and the chat interface together in an application. Panel comes with multiple templates that allow for us to quickly and easily create web apps with better aesthetics. Here we use the BootstrapTemplate to organize the widgets in the sidebar and display the chat interface in the center of the app.

template = pn.template.BootstrapTemplate(
sidebar=[key_input, k_slider, chain_select], main=[chat_interface]
)
template.servable()

To serve the app, run panel serve app.py or panel serve app.ipynb. You will get the app shown at the beginning of this blog post:

Conclusion

Retrieval-Augmented Generation (RAG) is a fascinating blend of information retrieval and generative techniques in the AI landscape. In this blog, we’ve broken down its essentials, walked through creating a RAG application using LangChain, and capped it off with integrating Panel’s user-friendly chat interface. This serves as a practical guide for anyone looking to understand or implement RAG in their projects. As we continue to navigate the evolving tech world, understanding and utilizing tools like RAG can be a beneficial step forward. We hope you found value in this introduction and guide. Happy coding!

Note:

image generated by the author using DALL-E

. . .

Originally published on anaconda.com.

By Andrew Huang and Sophia Yang

Sophia Yang is a Senior Data Scientist. Connect with me on LinkedIn, Twitter, and YouTube and join the DS/ML Book Club ❤️

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