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Build a RAG (Retrieval Augmented Generation) pipeline from scratch and have it all run locally.

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Simple Local RAG Tutorial

Local RAG pipeline we're going to build:

"This is a flowchart describing a simple local retrieval-augmented generation (RAG) workflow for document processing and embedding creation, followed by search and answer functionality. The process begins with a collection of documents, such as PDFs or a 1200-page nutrition textbook, which are preprocessed into smaller chunks, for example, groups of 10 sentences each. These chunks are used as context for the Large Language Model (LLM). A cool person (potentially the user) asks a query such as "What are the macronutrients? And what do they do?" This query is then transformed by an embedding model into a numerical representation using sentence transformers or other options from Hugging Face, which are stored in a torch.tensor format for efficiency, especially with large numbers of embeddings (around 100k+). For extremely large datasets, a vector database/index may be used. The numerical query and relevant document passages are processed on a local GPU, specifically an RTX 4090. The LLM generates output based on the context related to the query, which can be interacted with through an optional chat web app interface. All of this processing happens on a local GPU. The flowchart includes icons for documents, processing steps, and hardware, with arrows indicating the flow from document collection to user interaction with the generated text and resources."

All designed to run locally on a NVIDIA GPU.

All the way from PDF ingestion to "chat with PDF" style features.

All using open-source tools.

In our specific example, we'll build NutriChat, a RAG workflow that allows a person to query a 1200 page PDF version of a Nutrition Textbook and have an LLM generate responses back to the query based on passages of text from the textbook.

PDF source: https://pressbooks.oer.hawaii.edu/humannutrition2/

You can also run notebook 00-simple-local-rag.ipynb directly in Google Colab.

TODO:

  • Finish setup instructions
  • Make header image of workflow
  • Add intro to RAG info in README?
  • Add extensions to README
  • Record video of code writing/walkthrough - DONE, follow along with each line of code on YouTube: https://youtu.be/qN_2fnOPY-M

Getting Started

Two main options:

  1. If you have a local NVIDIA GPU with 5GB+ VRAM, follow the steps below to have this pipeline run locally on your machine.
  2. If you don’t have a local NVIDIA GPU, you can follow along in Google Colab and have it run on a NVIDIA GPU there.

Prerequisites

  • Comfortable writing Python code.
  • 1-2 beginner machine learning/deep learning courses.
  • Familiarity with PyTorch, see my beginner PyTorch video for more.

Setup

Note: Tested in Python 3.11, running on Windows 11 with a NVIDIA RTX 4090 with CUDA 12.1.

Clone repo

git clone https://github.com/mrdbourke/simple-local-rag.git
cd simple-local-rag

Create environment

python -m venv venv

Activate environment

Linux/macOS:

source venv/bin/activate

Windows:

.\venv\Scripts\activate

Install requirements

pip install -r requirements.txt

Note: I found I had to install torch manually (torch 2.1.1+ is required for newer versions of attention for faster inference) with CUDA, see: https://pytorch.org/get-started/locally/

On Windows I used:

pip3 install -U torch torchvision torchaudio --index-url https://download.pytorch.org/whl/cu121

Launch notebook

VS Code:

code .

Jupyter Notebook

jupyter notebook

Setup notes:

  • If you run into any install/setup troubles, please leave an issue.
  • To get access to the Gemma LLM models, you will have to agree to the terms & conditions on the Gemma model page on Hugging Face. You will then have to authorize your local machine via the Hugging Face CLI/Hugging Face Hub login() function. Once you've done this, you'll be able to download the models. If you're using Google Colab, you can add a Hugging Face token to the "Secrets" tab.
  • For speedups, installing and compiling Flash Attention 2 (faster attention implementation) can take ~5 minutes to 3 hours depending on your system setup. See the Flash Attention 2 GitHub for more. In particular, if you're running on Windows, see this GitHub issue thread. I've commented out flash-attn in the requirements.txt due to compile time, feel free to uncomment if you'd like use it or run pip install flash-attn.

What is RAG?

RAG stands for Retrieval Augmented Generation.

It was introduced in the paper Retrieval-Augmented Generation for Knowledge-Intensive NLP Tasks.

Each step can be roughly broken down to:

  • Retrieval - Seeking relevant information from a source given a query. For example, getting relevant passages of Wikipedia text from a database given a question.
  • Augmented - Using the relevant retrieved information to modify an input to a generative model (e.g. an LLM).
  • Generation - Generating an output given an input. For example, in the case of an LLM, generating a passage of text given an input prompt.

Why RAG?

The main goal of RAG is to improve the generation outptus of LLMs.

Two primary improvements can be seen as:

  1. Preventing hallucinations - LLMs are incredible but they are prone to potential hallucination, as in, generating something that looks correct but isn't. RAG pipelines can help LLMs generate more factual outputs by providing them with factual (retrieved) inputs. And even if the generated answer from a RAG pipeline doesn't seem correct, because of retrieval, you also have access to the sources where it came from.
  2. Work with custom data - Many base LLMs are trained with internet-scale text data. This means they have a great ability to model language, however, they often lack specific knowledge. RAG systems can provide LLMs with domain-specific data such as medical information or company documentation and thus customized their outputs to suit specific use cases.

The authors of the original RAG paper mentioned above outlined these two points in their discussion.

This work offers several positive societal benefits over previous work: the fact that it is more strongly grounded in real factual knowledge (in this case Wikipedia) makes it “hallucinate” less with generations that are more factual, and offers more control and interpretability. RAG could be employed in a wide variety of scenarios with direct benefit to society, for example by endowing it with a medical index and asking it open-domain questions on that topic, or by helping people be more effective at their jobs.

RAG can also be a much quicker solution to implement than fine-tuning an LLM on specific data.

What kind of problems can RAG be used for?

RAG can help anywhere there is a specific set of information that an LLM may not have in its training data (e.g. anything not publicly accessible on the internet).

For example you could use RAG for:

  • Customer support Q&A chat - By treating your existing customer support documentation as a resource, when a customer asks a question, you could have a system retrieve relevant documentation snippets and then have an LLM craft those snippets into an answer. Think of this as a "chatbot for your documentation". Klarna, a large financial company, uses a system like this to save $40M per year on customer support costs.
  • Email chain analysis - Let's say you're an insurance company with long threads of emails between customers and insurance agents. Instead of searching through each individual email, you could retrieve relevant passages and have an LLM create strucutred outputs of insurance claims.
  • Company internal documentation chat - If you've worked at a large company, you know how hard it can be to get an answer sometimes. Why not let a RAG system index your company information and have an LLM answer questions you may have? The benefit of RAG is that you will have references to resources to learn more if the LLM answer doesn't suffice.
  • Textbook Q&A - Let's say you're studying for your exams and constantly flicking through a large textbook looking for answers to your quesitons. RAG can help provide answers as well as references to learn more.

All of these have the common theme of retrieving relevant resources and then presenting them in an understandable way using an LLM.

From this angle, you can consider an LLM a calculator for words.

Why local?

Privacy, speed, cost.

Running locally means you use your own hardware.

From a privacy standpoint, this means you don't have send potentially sensitive data to an API.

From a speed standpoint, it means you won't necessarily have to wait for an API queue or downtime, if your hardware is running, the pipeline can run.

And from a cost standpoint, running on your own hardware often has a heavier starting cost but little to no costs after that.

Performance wise, LLM APIs may still perform better than an open-source model running locally on general tasks but there are more and more examples appearing of smaller, focused models outperforming larger models.

Key terms

Term Description
Token A sub-word piece of text. For example, "hello, world!" could be split into ["hello", ",", "world", "!"]. A token can be a whole word,
part of a word or group of punctuation characters. 1 token ~= 4 characters in English, 100 tokens ~= 75 words.
Text gets broken into tokens before being passed to an LLM.
Embedding A learned numerical representation of a piece of data. For example, a sentence of text could be represented by a vector with
768 values. Similar pieces of text (in meaning) will ideally have similar values.
Embedding model A model designed to accept input data and output a numerical representation. For example, a text embedding model may take in 384
tokens of text and turn it into a vector of size 768. An embedding model can and often is different to an LLM model.
Similarity search/vector search Similarity search/vector search aims to find two vectors which are close together in high-demensional space. For example,
two pieces of similar text passed through an embedding model should have a high similarity score, whereas two pieces of text about
different topics will have a lower similarity score. Common similarity score measures are dot product and cosine similarity.
Large Language Model (LLM) A model which has been trained to numerically represent the patterns in text. A generative LLM will continue a sequence when given a sequence.
For example, given a sequence of the text "hello, world!", a genertive LLM may produce "we're going to build a RAG pipeline today!".
This generation will be highly dependant on the training data and prompt.
LLM context window The number of tokens a LLM can accept as input. For example, as of March 2024, GPT-4 has a default context window of 32k tokens
(about 96 pages of text) but can go up to 128k if needed. A recent open-source LLM from Google, Gemma (March 2024) has a context
window of 8,192 tokens (about 24 pages of text). A higher context window means an LLM can accept more relevant information
to assist with a query. For example, in a RAG pipeline, if a model has a larger context window, it can accept more reference items
from the retrieval system to aid with its generation.
Prompt A common term for describing the input to a generative LLM. The idea of "prompt engineering" is to structure a text-based
(or potentially image-based as well) input to a generative LLM in a specific way so that the generated output is ideal. This technique is
possible because of a LLMs capacity for in-context learning, as in, it is able to use its representation of language to breakdown
the prompt and recognize what a suitable output may be (note: the output of LLMs is probable, so terms like "may output" are used).

TK - Extensions

Coming soon.

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