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Modular Blog

Qualcomm to Acquire Modular Modular 26.4: SOTA MoE Serving, Model Bringup via Agent Skills, Mojo 1.0 Beta 2 and More ModCon 2026: Modular’s Developer Conference Day Zero: MiniMax M3 Open Weights on Modular Cloud Modverse #55: Mojo 1.0 Beta, Community Mojo Libraries, and Real-Time Patient Conversations Powered by MAX What about OpenCL and CUDA C++ alternatives? (Democratizing AI Compute, Part 5) Why LLM Inference Needs a New Kind of Router - Part 3 Three trends from MLSys 2026 Why LLM Inference Needs a New Kind of Router - Part 2 How I built a pure Mojo app (and 10 libraries) with AI agents Hippocratic AI partners with Modular to power flexible, high-quality inference for real-time patient conversations Translating to Mojo via AI Agents Inkwell: Why Your Inference Platform Matters As Much As Your Model Why LLM Inference Needs a New Kind of Router - Part 1 Modular 26.3: Mojo 1.0 Beta, MAX Video Gen, and more Modverse #54: AMD AI DevDay, New Modular Offices, and a Community That Keeps Shipping How Frontier Coding Agents Built a Video Diffusion Pipeline on MAX TileTensor Part 1 - Safer, More Efficient GPU Kernels Modular Opens Edinburgh & San Francisco Offices Structured Mojo Kernels Part 4 - Portability and the Road Ahead Day Zero Launch: Fastest Performance for Gemma 4 on NVIDIA and AMD Modverse #54: From GTC to Edinburgh, a Community Building Momentum Software Pipelining for GPU Kernels: Part 1 - The Pipeline Problem Structured Mojo Kernels Part 3 - Composition in Practice Modular 26.2: State-of-the-Art Image Generation and Upgraded AI Coding with Mojo Modular at NVIDIA GTC 2026: MAX on Blackwell, Mojo Kernel Porting, and DeepSeek V3 on B200 Structured Mojo Kernels Part 2 - The Three Pillars Modverse #53: Community Builds, Research Milestones, and a Growing Ecosystem Structured Mojo Kernels Part 1 - Peak Performance, Half the Code The Claude C Compiler: What It Reveals About the Future of Software BentoML Joins Modular The Five Eras of KVCache Modular 26.1: A Big Step Towards More Programmable and Portable AI Infrastructure How to Beat Unsloth's CUDA Kernel Using Mojo—With Zero GPU Experience 🔥 Modular 2025 Year in Review The path to Mojo 1.0 Modverse #52: Advancing AI Together — Community Projects & Platform Milestones Modular 25.7: Faster Inference, Safer GPU Programming, and a More Unified Developer Experience "TTS 1 Max" (powered by Modular Platform) Ranked #1 Speech Model on Artificial Analysis PyTorch and LLVM in 2025 — Keeping up With AI Innovation Achieving State-of-the-Art Performance on AMD MI355 — in Just 14 Days Modular Raises $250M to scale AI's Unified Compute Layer Modular 25.6: Unifying the latest GPUs from NVIDIA, AMD, and Apple Matrix Multiplication on Blackwell: Part 4 - Breaking SOTA Modverse #51: Modular x Inworld x Oracle, Modular Meetup Recap and Community Projects Matrix Multiplication on Blackwell: Part 3 - The Optimizations Behind 85% of SOTA Performance Matrix Multiplication on Blackwell: Part 2 - Using Hardware Features to Optimize Matmul Matrix Multiplication on Blackwell: Part 1 - Introduction Modverse #50: Modular Platform 25.5, Community Meetups, and Mojo's Debut in the Stack Overflow Developer Survey Modular Platform 25.5: Introducing Large Scale Batch Inference SF Compute and Modular Partner to Revolutionize AI Inference Economics AI Agents for AWS Marketplace Modverse #49: Modular Platform 25.4, Modular 🤝 AMD, and Modular Hack Weekend Inside Modular Hack Weekend: Top Projects and Community Highlights How is Modular Democratizing AI Compute? 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(Democratizing AI Compute, Part 2) Modular Modular Hands-on with Mojo 24.6 Evaluating Llama Guard with MAX 24.6 and Hugging Face Modular Introducing MAX 24.6: A GPU Native Generative AI Platform MAX GPU: State of the Art Throughput on a New GenAI platform Understanding SIMD: Infinite Complexity of Trivial Problems Community Spotlight: Writing Mojo with Cursor Hands-on with Mojo 24.5 MAX 24.5 - With SOTA CPU Performance for Llama 3.1 Announcing stack-pr: an open source tool for managing stacked PRs on GitHub Debugging in Mojo🔥 Write hardware-agnostic custom ops for PyTorch | Modular Take control of your AI Develop locally, deploy globally A brief guide to the Mojo n-body example What's new in MAX 24.4? MAX on macOS, fast local Llama3, native quantization and GGUF support What’s new in Mojo 24.4? Improved collections, new traits, os module features and core language enhancements MAX 24.4 - Introducing quantization APIs and MAX on macOS Deep dive into ownership in Mojo What ownership is really about: a mental model approach Fast⚡k-means clustering in Mojo🔥: a guide to porting Python to Mojo🔥 for accelerated k-means clustering
DeepSeek's Impact on AI (Democratizing AI Compute, Part 1)
No items found. · 2025-01-30 · via Modular Blog

DeepSeek’s recent breakthrough has upended assumptions about AI’s compute demands, showing that better hardware utilization can dramatically reduce the need for expensive GPUs.

For years, leading AI companies have insisted that only those with vast compute resources can drive cutting-edge research, reinforcing the idea that it is “hopeless to catch up” unless you have billions of dollars to spend on infrastructure. But DeepSeek’s success tells a different story: novel ideas can unlock efficiency breakthroughs to accelerate AI, and smaller, highly focused teams to challenge industry giants–and even level the playing field.

We believe DeepSeek’s efficiency breakthrough signals a coming surge in demand for AI applications. If AI is to continue advancing, we must drive down the Total Cost of Ownership (TCO)–by expanding access to alternative hardware, maximizing efficiency on existing systems, and accelerating software innovation. Otherwise, we risk a future where AI’s benefits are bottlenecked–either by hardware shortages or by developers struggling to effectively utilize the diverse hardware that is available.

This isn’t just an abstract problem–it's a challenge I’ve spent my career working to solve.

My passion for compute + developer efficiency

I've spent the past 25 years working to unlock computing power for the world. I founded and led the development of LLVM, a compiler technology that opened CPUs to new applications of compiler technology. Today, LLVM is the foundation for performance-oriented programming languages like C++, Rust, Swift and more. It powers nearly all iOS and Android apps, as well as the infrastructure behind major internet services from Google and Meta.

This work paved the way for several key innovations I led at Apple, including the creation of OpenCL, an early accelerator framework now widely adopted across the industry, the rebuild of Apple’s CPU and GPU software stack using LLVM, and the development of the Swift programming language. These experiences reinforced my belief in the power of shared infrastructure, the importance of co-designing hardware and software, and how intuitive, developer-friendly tools unlock the full potential of advanced hardware.

Falling in love with AI

In 2017, I became fascinated by AI’s potential and joined Google to lead software development for the TPU platform. At the time, the hardware was ready, but the software wasn’t functional. Over the next two and a half years, through intense team effort, we launched TPUs in Google Cloud, scaled them to ExaFLOPS of compute, and built a research platform that enabled breakthroughs like Attention Is All You Need and BERT.

Yet, this journey revealed deeper troubles in AI software. Despite TPUs' success, they remain only semi-compatible with AI frameworks like PyTorch–an issue Google overcomes with vast economic and research resources. A common customer question was, “Can TPUs run arbitrary AI models out of the box?” The hard truth? No–because we didn’t have CUDA, the de facto standard for AI development.

I’m not one to shy away from tackling major industry problems: my recent work has been the creation of next-generation technologies to scale into this new era of hardware and accelerators. This includes the MLIR compiler framework (widely adopted now for AI compilers across the industry) and the Modular team has spent the last 3 years building something special–but we’ll share more about that later, when the time is right.

How do GPUs and next-generation compute move forward?

Because of my background and relationships across the industry, I’m often asked about the future of compute. Today, countless groups are innovating in hardware (fueled in part by NVIDIA’s soaring market cap), while many software teams are adopting MLIR to enable new architectures. At the same time, senior leaders are questioning why–despite massive investments–the AI software problem remains unsolved. The challenge isn’t a lack of motivation or resources. So why does the industry feel stuck?

I don’t believe we are stuck. But we do face difficult, foundational problems.

To move forward, we need to better understand the underlying industry dynamics. Compute is a deeply technical field, evolving rapidly, and filled with jargon, codenames, and press releases designed to make every new product sound revolutionary. Many people try to cut through the noise to see the forest for the trees, but to truly understand where we’re going, we need to examine the roots—the fundamental building blocks that hold everything together.

This post is the first in a multipart series where we’ll help answer these critical questions in a straightforward, accessible way:

  • 🧐 What exactly is CUDA?
  • 🎯 Why has CUDA been so successful?
  • ⚖️ Is CUDA any good?
  • ❓ Why do other hardware makers struggle to provide comparable AI software?
  • ⚡ Why haven’t existing technologies like Triton or OneAPI or OpenCL solved this?
  • 🚀 How can we as an industry move forward?

I hope this series sparks meaningful discussions and raises the level of understanding around these complex issues. The rapid advancements in AI —like DeepSeek’s recent breakthroughs–remind us that software and algorithmic innovation are still driving forces. A deep understanding of low-level hardware continues to unlock "10x" breakthroughs.

AI is advancing at an unprecedented pace–but there’s still so much left to unlock. Together we can break it down, challenge assumptions, and push the industry forward. Let’s dive in!

-Chris

What’s next?

Learn more about the MAX Platform and the Mojo programming language, and join us in building the next wave of AI innovation.