LangGraph-MAS4SE is designed as a collaborative ecosystem of intelligent agents, each specialized in distinct software engineering phases. At its core, a graph-based message bus orchestrates workflows, allowing agents to publish and subscribe to task-specific data nodes. For example, a code synthesis agent generates initial code drafts, which are then passed to a static analysis agent for quality checks. A documentation agent produces user guides based on analyzed modules, while a testing agent auto-generates unit tests. The system supports plugin interfaces for custom agent development, enabling teams to integrate domain-specific logic. By abstracting complex dependency management and leveraging LLM-driven reasoning, LangGraph-MAS4SE accelerates development cycles, reduces manual overhead, and ensures consistent code quality across large projects.

LangServe Assistant UI is a modular front-end application built with React and TypeScript that interfaces seamlessly with the LangServe backend to deliver a full-featured conversational AI experience. It provides customizable chat windows, real-time message streaming, context-aware prompts, multi-agent orchestration, and plugin hooks for external API calls. The UI supports theming, localization, session management, and event hooks for capturing user interactions. It can be embedded into existing web applications or deployed as a standalone SPA, enabling rapid rollout of customer service bots, content generation assistants, and interactive knowledge agents. Its extensible architecture ensures easy customization and maintenance.

Layra is designed to simplify developing LLM-powered agents by providing a modular architecture that integrates with various tools and memory stores. It features a planner that breaks down tasks into subgoals, a memory module for storing conversation and context, and a plugin system to connect external APIs or custom functions. Layra also supports orchestrating multiple agent instances to collaborate on complex workflows, enabling parallel execution and task delegation. With clear abstractions for tools, memory, and policy definitions, developers can rapidly prototype and deploy intelligent agents for customer support, data analysis, RAG, and more. It is framework-agnostic toward modeling backends, supporting OpenAI, Hugging Face, and local LLMs.

Legal MultiAgent System is a Python-based open-source platform that orchestrates multiple AI agents specialized for legal workflows. Each agent handles discrete tasks like document parsing, contract drafting, citation retrieval, compliance verification, and Q&A. Agents communicate via a central orchestrator, enabling parallel processing and collaborative analysis. By integrating with popular LLM APIs and allowing custom module development, it streamlines legal research, automates repetitive tasks, and ensures consistent output. The system’s modular architecture supports easy extension, so organizations can tailor agents to specific jurisdictions, practice areas, or compliance frameworks, achieving scalable and accurate legal automation.

In practice, LlamaSim allows you to define multiple AI-powered agents using the Llama model, set up interaction scenarios, and run controlled simulations. You can customize agent personalities, decision-making logic, and communication channels using simple Python APIs. The framework automatically handles prompt construction, response parsing, and conversation state tracking. It logs all interactions and provides built-in evaluation metrics such as response coherence, task completion rate, and latency. With its plugin architecture, you can integrate external data sources, add custom evaluation functions, or extend agent capabilities. LlamaSim’s lightweight core makes it suitable for local development, CI pipelines, or cloud deployments, enabling replicable research and prototype validation.

LM-Kit is a comprehensive suite of C# toolkits designed to integrate advanced AI agent solutions into .NET applications. It enables developers to create customized AI agents, develop new agents, and orchestrate multi-agent systems. With capabilities including text analysis, translation, text generation, model optimization, and more, LM-Kit supports efficient on-device inference, data security, and reduced latency. Furthermore, it is designed to enhance AI model performance while ensuring seamless integration across different platforms and hardware configurations.

ManasAI is a Python-based framework that enables the creation of autonomous AI agents with built-in state and modular components. It offers core abstractions for agent reasoning, short-term and long-term memory, external tool and API integrations, message-driven event handling, and multi-agent orchestration. Agents can be configured to manage context, execute tasks, handle retries, and gather feedback. Its pluggable architecture allows developers to tailor memory backends, tools, and orchestrators to specific workflows, making it ideal for prototyping chatbots, digital workers, and automated pipelines that require persistent context and complex interactions.

Intelligence empowers developers to assemble AI agents by composing components that manage stateful memory, integrate language models like OpenAI GPT, and connect to external tools (APIs, databases, and knowledge bases). It features a plugin system for custom functionalities, observability modules to trace decisions and metrics, and orchestration utilities to coordinate multiple agents. Developers install via pip, define agents in Python with simple classes, and configure memory backends (in-memory, Redis, or vector stores). Its REST API server enables easy deployment, while CLI tools assist in debugging. Intelligence streamlines agent testing, versioning, and scaling, making it suitable for chatbots, customer support, data retrieval, document processing, and automated workflows.

MARFT is a Python-based LLMs, enabling reproducible experiments and rapid prototyping of collaborative AI systems.

MASlite provides a clear API to create agent classes, register behaviors, and handle event-driven messaging between agents. It includes a scheduler to manage agent tasks, environment modeling to simulate interactions, and a plugin system to extend core capabilities. Developers can rapidly prototype multi-agent scenarios in Python by defining agent lifecycle methods, connecting agents via channels, and running simulations in a headless mode or integrating with visualization tools.

Maxun.dev is a no-code/low-code AI agent framework that allows developers and businesses to create intelligent agents tailored to specific tasks. Users can define agent workflows via a visual interface, integrate data sources and external APIs, and configure memory modules for contextual understanding. The platform supports multi-agent orchestration, real-time monitoring, and performance analytics to optimize agent behaviors. With built-in collaboration tools, version control, and one-click deployment options, Maxun.dev simplifies the entire lifecycle from prototype to production, accelerating AI-driven automation across customer support, document management, and business processes.

MCP Crew AI is a developer-focused framework that simplifies the creation and coordination of GPT-based AI agents in collaborative teams. By defining manager, worker, and monitor agent roles, it automates task delegation, execution, and oversight. The package offers built-in support for OpenAI’s API, a modular architecture for custom agent plugins, and a CLI for running and monitoring your Crew. MCP Crew AI accelerates multi-agent system development, making it easier to build scalable, transparent, and maintainable AI-driven workflows.

mini-AlphaStar demystifies the complex AlphaStar architecture by offering an accessible, open-source PyTorch framework for StarCraft II AI development. It features spatial feature encoders for screen and minimap inputs, non-spatial feature processing, LSTM memory modules, and separate policy and value networks for action selection and state evaluation. Using imitation learning to bootstrap and reinforcement learning with self-play for fine-tuning, it supports environment wrappers compatible with StarCraft II via pysc2, logging through TensorBoard, and configurable hyperparameters. Researchers and students can generate datasets from human gameplay, train models on custom scenarios, evaluate agent performance, and visualize learning curves. The modular codebase enables easy experimentation with network variants, training schedules, and multi-agent setups. Designed for education and prototyping rather than production deployment.

Multi-Agent SEO Blog Generator is a Python-based framework that coordinates specialized AI agents to produce SEO-optimized blog posts. It begins with keyword analysis, using an SEO agent to discover high-impact terms. Next, an outline agent structures the post, crafting headings and subtopics. A content agent then writes engaging, natural-sounding paragraphs. Finally, an optimization agent fine-tunes keywords, meta descriptions, and internal linking suggestions. Developers can customize prompt templates, adjust agent roles, and integrate with OpenAI’s API keys. This modular architecture enables automated, end-to-end blog development, ensuring consistent, SEO-friendly, and high-quality content at scale.

Multi Agent Simulation offers a flexible API to define Agent classes with custom sensors, actuators, and decision logic. Users configure environments with obstacles, resources, and communication protocols, then run step-based or real-time simulation loops. Built-in logging, event scheduling, and Matplotlib integration help track agent states and visualize results. The modular design allows easy extension with new behaviors, environments, and performance optimizations, making it ideal for academic research, educational purposes, and prototyping multi-agent scenarios.

Multi-Agent Stock Analysis is an open-source framework that deploys multiple specialized AI agents—DataCollector, SentimentAnalyst, Predictor, and Reporter—to streamline end-to-end stock research. The DataCollector agent fetches real-time prices and financial news. The SentimentAnalyst processes news articles to gauge market sentiment. The Predictor leverages machine learning models to forecast future stock movements. Finally, the Reporter crafts detailed summaries and visualizations. Its modular architecture supports easy customization for different assets, models, and reporting formats.

The Multi-Agent System Framework offers a modular structure for building and orchestrating multiple AI agents within Python applications. It includes an agent manager to spawn and supervise agents, a communication backbone supporting various protocols (e.g., message passing, event broadcasting), and customizable memory stores for long-term knowledge retention. Developers can define distinct agent roles, assign specialized tasks, and configure cooperative strategies such as consensus-building or voting. The framework integrates seamlessly with external AI models and knowledge bases, enabling agents to reason, learn, and adapt. Ideal for distributed simulations, conversational agent clusters, and automated decision-making pipelines, the system accelerates complex problem solving by leveraging parallel autonomy.

The project uses the JADE (Java Agent DEvelopment) framework to build a multi-agent environment. It defines agents that register with the platform’s AMS and DF, exchange ACL messages, and execute behaviors like cyclic, one-shot, and FSM. Example scenarios include buyer-seller negotiations, contract net protocols, and task allocation. A GUI agent container helps monitor runtime agent states and message flows.

Multi-Agent Systems provides a comprehensive toolkit for creating, controlling, and observing interactions among autonomous agents. Developers can define agent classes with custom decision-making logic, set up complex environments with configurable resources and rules, and implement communication channels for information exchange. The framework supports synchronous and asynchronous scheduling, event-driven behaviors, and integrates logging for performance metrics. Users can extend core modules or integrate external AI models to enhance agent intelligence. Visualization tools render simulations in real-time or post-process, helping analyze emergent behaviors and optimize system parameters. From academic research to prototype distributed applications, Multi-Agent Systems simplifies end-to-end multi-agent simulations.

Multi-Agent Drone Environment is a Python package offering a customizable multi-agent simulation for UAV swarms, built on OpenAI Gym and PyBullet. Users define multiple drone agents with kinematic and dynamic models to explore cooperative tasks such as formation flying, target tracking, and obstacle avoidance. The environment supports modular task configuration, realistic collision detection, and sensor emulation, while allowing custom reward functions and decentralized policies. Developers can integrate their own reinforcement learning algorithms, evaluate performance under varied scenarios, and visualize agent trajectories and metrics in real time. Its open-source design encourages community contributions, making it ideal for research, teaching, and prototyping advanced multi-agent control solutions.