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OpenGPTs

This is an open source effort to create a similar experience to OpenAI's GPTs and Assistants API. It is powered by LangGraph - a framework for creating agent runtimes. It also builds upon LangChain, LangServe and LangSmith. OpenGPTs gives you more control, allowing you to configure:

  • The LLM you use (choose between the 60+ that LangChain offers)
  • The prompts you use (use LangSmith to debug those)
  • The tools you give it (choose from LangChain's 100+ tools, or easily write your own)
  • The vector database you use (choose from LangChain's 60+ vector database integrations)
  • The retrieval algorithm you use
  • The chat history database you use

Most importantly, it gives you full control over the cognitive architecture of your application. Currently, there are three different architectures implemented:

  • Assistant
  • RAG
  • Chatbot

See below for more details on those. Because this is open source, if you do not like those architectures or want to modify them, you can easily do that!

Configure Chat

Key Links

Quickstart

Start the backend

Install requirements

cd backend
pip install -r requirements.txt

Set up persistence layer

The backend by default uses Redis for saving agent configurations and chat message history. In order to you use this, you need to a REDIS_URL variable.

export REDIS_URL=...

Set up vector database

The backend by default also uses Redis as a vector database, although you can easily switch this out to use any of the 50+ vector databases in LangChain. If you are using Redis as a vectorstore, the above environment variable should work (assuming you've enabled redissearch)

Set up language models

By default, this uses OpenAI, but there are also options for Azure OpenAI and Anthropic. If you are using those, you may need to set different environment variables.

export OPENAI_API_KEY="sk-..."

Other language models can be used, and in order to use them you will need to set more environment variables. See the section below on LLMs for how to configure Azure OpenAI, Anthropic, and Amazon Bedrock.

Set up tools

By default this uses a lot of tools. Some of these require additional environment variables. You do not need to use any of these tools, and the environment variables are not required to spin up the app (they are only required if that tool is called).

For a full list of environment variables to enable, see the Tools section below.

Set up monitoring

Set up LangSmith. This is optional, but it will help with debugging, logging, monitoring. Sign up at the link above and then set the relevant environment variables

export LANGCHAIN_TRACING_V2="true"
export LANGCHAIN_API_KEY=...

Start the backend server

langchain serve --port=8100

2. Start the frontend

cd frontend
yarn
yarn dev

Navigate to http://localhost:5173/ and enjoy!

Installation and Running with Docker

This project supports a Docker-based setup, streamlining installation and execution. It automatically builds images for the frontend and backend and sets up Redis using docker-compose.

Quick Start

  1. Clone the Repository:
    Obtain the project files by cloning the repository.

    git clone https://github.com/langchain-ai/opengpts.git
    cd opengpts
    
  2. Run with Docker Compose:
    In the root directory of the project, execute:

    docker compose up
    

    This command builds the Docker images for the frontend and backend from their respective Dockerfiles and starts all necessary services, including Redis.

  3. Access the Application:
    With the services running, access the frontend at http://localhost:5173, substituting 5173 with the designated port number.

  4. Rebuilding After Changes:
    If you make changes to either the frontend or backend, rebuild the Docker images to reflect these changes. Run:

    docker-compose up --build
    

    This command rebuilds the images with your latest changes and restarts the services.

Note

  • Ensure Docker and docker-compose are installed on your system.
  • Adjust the .env file as required for specific environment configurations.

Features

As much as possible, we are striving for feature parity with OpenAI.

  • Sandbox - Provides an environment to import, test, and modify existing chatbots.
    • The chatbots used are all in code, so are easily editable
  • Custom Actions - Define additional functionality for your chatbot using OpenAPI specifications
    • Supported by adding tools
  • Knowledge Files - attach additional files that your chatbot can reference
    • Upload files from the UI or API, used by Retrieval tool
  • Tools - Provides basic tools for web browsing, image creation, etc.
    • Basic DuckDuckGo and PythonREPL tools enabled by default
    • Image creation coming soon
  • Analytics - View and analyze chatbot usage data
    • Use LangSmith for this
  • Drafts - Save and share drafts of chatbots you're creating
    • Supports saving of configurations
  • Publishing - publicly distribute your completed chatbot
    • Can do by deploying via LangServe
  • Sharing - Set up and manage chatbot sharing
    • Can do by deploying via LangServe
  • Marketplace - Search and deploy chatbots created by other users
    • Coming soon

Repo Structure

  • frontend: Code for the frontend
  • backend: Code for the backend
    • app: LangServe code (for exposing APIs)
    • packages: Core logic
      • agent-executor: Runtime for the agent
      • gizmo-agent: Configuration for the agent

Customization

The big appeal of OpenGPTs as compared to using OpenAI directly is that it is more customizable. Specifically, you can choose which language models to use as well as more easily add custom tools. You can also use the underlying APIs directly and build a custom UI yourself should you choose.

Cognitive Architecture

This refers to the logic of how the GPT works. There are currently three different architectures supported, but because they are all written in LangGraph, it is very easy to modify them or add your own.

The three different architectures supported are assistants, RAG, and chatbots.

Assistants

Assistants can be equipped with arbitrary amount of tools and use an LLM to decide when to use them. This makes them the most flexible choice, but they work well with fewer models and can be less reliable.

When creating an assistant, you specify a few things.

First, you choose the language model to use. Only a few language models can be used reliably well: GPT-3.5, GPT-4, Claude, and Gemini.

Second, you choose the tools to use. These can be predefined tools OR a retriever constructed from uploaded files. You can choose however many you want.

The cognitive architecture can then be thought of as a loop. First, the LLM is called to determine what (if any) actions to take. If it decides to take actions, then those actions are executed and it loops back. If no actions are decided to take, then the response of the LLM is the final response, and it finishes the loop.

This can be a really powerful and flexible architecture. This is probably closest to how us humans operate. However, these also can be not super reliable, and generally only work with the more performant models (and even then they can mess up). Therefore, we introduced a few simpler architecures.

RAGBot

One of the big use cases of the GPT store is uploading files and giving the bot knowledge of those files. What would it mean to make an architecture more focused on that use case?

We added RAGBot - a retrieval-focused GPT with a straightforward architecture. First, a set of documents are retrieved. Then, those documents are passed in the system message to a separate call to the language model so it can respond.

Compared to assistants, it is more structured (but less powerful). It ALWAYS looks up something - which is good if you know you want to look things up, but potentially wasteful if the user is just trying to have a normal conversation. Also importantly, this only looks up things once - so if it doesn’t find the right results then it will yield a bad result (compared to an assistant, which could decide to look things up again).

Despite this being a more simple architecture, it is good for a few reasons. First, because it is simpler it can work pretty well with a wider variety of models (including lots of open source models). Second, if you have a use case where you don’t NEED the flexibility of an assistant (eg you know users will be looking up information every time) then it can be more focused. And third, compared to the final architecture below it can use external knowledge.

ChatBot

The final architecture is dead simple - just a call to a language model, parameterized by a system message. This allows the GPT to take on different personas and characters. This is clearly far less powerful than Assistants or RAGBots (which have access to external sources of data/computation) - but it’s still valuable! A lot of popular GPTs are just system messages at the end of the day, and CharacterAI is crushing it despite largely just being system messages as well.

LLMs

You can choose between different LLMs to use. This takes advantage of LangChain's many integrations. It is important to note that depending on which LLM you use, you may need to change how you are prompting it.

We have exposed four agent types by default:

  • "GPT 3.5 Turbo"
  • "GPT 4"
  • "Azure OpenAI"
  • "Claude 2"

We will work to add more when we have confidence they can work well.

If you want to add your own LLM or agent configuration, or want to edit the existing ones, you can find them in backend/packages/gizmo-agent/gizmo_agent/agent_types

Claude 2

If using Claude 2, you will need to set the following environment variable:

export ANTHROPIC_API_KEY=sk-...

Azure OpenAI

If using Azure OpenAI, you will need to set the following environment variables:

export AZURE_OPENAI_API_BASE=...
export AZURE_OPENAI_API_VERSION=...
export AZURE_OPENAI_API_KEY=...
export AZURE_OPENAI_DEPLOYMENT_NAME=...

Amazon Bedrock

If using Amazon Bedrock, you either have valid credentials in ~/.aws/credentials or set the following environment variables:

export AWS_ACCESS_KEY_ID=...
export AWS_SECRET_ACCESS_KEY=...

Tools

One of the big benefits of having this be open source is that you can more easily add tools (directly in Python).

In practice, most teams we see define their own tools. This is easy to do within LangChain. See this guide for details on how to best do this.

If you want to use some preconfigured tools, these include:

Robocorp Action Server

Run AI Python based actions with Robocorp Action Server. Does not require a service API key, but it requires the credentials for a running Action Server instance to be defined:

ROBOCORP_ACTION_SERVER_URL=https://dummy-action-server.robocorp.link
ROBOCORP_ACTION_SERVER_KEY=dummy-api-key

Connery Actions

Connect OpenGPTs to the real world with Connery.

Requires setting an environment variable, which you get during the Connery Runner setup:

CONNERY_RUNNER_URL=https://your-personal-connery-runner-url
CONNERY_RUNNER_API_KEY=...

DuckDuckGo Search

Search the web with DuckDuckGo. Does not require any API keys.

Tavily Search

Uses the Tavily search engine. Requires setting an environment variable:

export TAVILY_API_KEY=tvly-...

Sign up for an API key here.

Tavily Search (Answer Only)

Uses the Tavily search engine. This returns only the answer, no supporting evidence. Good when you need a short response (small context windows). Requires setting an environment variable:

export TAVILY_API_KEY=tvly-...

Sign up for an API key here.

You.com Search

Uses You.com search, optimized responses for LLMs. Requires setting an environment variable:

export YDC_API_KEY=...

Sign up for an API key here

SEC Filings (Kay.ai)

Searches through SEC filings using Kay.ai. Requires setting an environment variable:

export KAY_API_KEY=...

Sign up for an API key here

Press Releases (Kay.ai)

Searches through press releases using Kay.ai. Requires setting an environment variable:

export KAY_API_KEY=...

Sign up for an API key here

Arxiv

Searches Arxiv. Does not require any API keys.

PubMed

Searches PubMed. Does not require any API keys.

Wikipedia

Searches Wikipedia. Does not require any API keys.

Deployment

Deploy via Cloud Run

1. Build the frontend

cd frontend
yarn
yarn build

2. Deploy to Google Cloud Run

You can deploy to GCP Cloud Run using the following command:

First create a .env.gcp.yaml file with the contents from .env.gcp.yaml.example and fill in the values. Then run:

gcloud run deploy opengpts --source . --port 8000 --env-vars-file .env.gcp.yaml --allow-unauthenticated --region us-central1 --min-instances 1

Deploy in Kubernetes

We have a Helm chart for deploying the backend to Kubernetes. You can find more information here: README.md

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