llama.cpp + TurboQuant+

Production-grade KV-cache and weight quantization for llama.cpp, with cross-backend kernel support for Apple Silicon, NVIDIA CUDA, AMD ROCm, and Vulkan.

A fork of ggml-org/llama.cpp integrating the TurboQuant+ codec stack — Walsh-Hadamard rotated polar quantization, attention-gated sparse dequantization, and layer-aware V compression policies. The codec design, calibration, and validation papers live at TheTom/turboquant_plus; this repository is the llama.cpp runtime integration.

Lineage — why the +

TurboQuant+ is inspired by Google's original TurboQuant paper (ICLR 2026), which introduced Walsh-Hadamard-rotated polar codebook quantization for KV cache and demonstrated 4.6× compression at ~1% PPL loss. This project extends that foundation substantially — adding the asymmetric K/V policy (V is free, K is everything), layer-aware Boundary V protection, attention-gated sparse V dequantization, the TQ3_1S / TQ4_1S weight quantization formats, the turbo2 / turbo4 tier variants, the cross-backend kernel coverage (CUDA dp4a, HIP/ROCm RDNA/CDNA, Vulkan coopmat, Metal TurboFlash + V2.1 fused kernels), and a body of model-family-specific quality and operational fixes. The trailing + denotes that ongoing extension work; the original TurboQuant codec remains the foundation.

This fork is additive: every existing llama.cpp quantization, model, and backend continues to work unchanged. New types are opt-in via the standard --cache-type-k / --cache-type-v and llama-quantize interfaces.

Production deployments

This fork's TurboQuant integration is used in:

• LocalAI — drop-in OpenAI-compatible local inference server
• Chronara — quantum-safe fintech infrastructure with AI-driven networks
• AtomicChat — on-device chat application
• and other downstream projects

Status

Default branch	feature/turboquant-kv-cache
Commits ahead of upstream	~300
Upstream tracking	continuous sync from ggml-org/llama.cpp master
Upstream PR status	not yet upstreamed; running as a long-lived feature branch

---

What this fork adds

Quantization types

Type	Domain	Approx. bits	Notes	Paper
TQ3_1S	weights	~3.5	smaller VRAM than q8_0	weight-compression-tq4
TQ4_1S	weights	~4.5	V2.1 fused Metal kernels; CUDA dp4a 3.5× faster (240 t/s vs 68 baseline)	weight-compression-tq4
turbo2	KV cache	~2.0	aggressive; pair with Boundary V	block-size-experiment
turbo3	KV cache	~3.5	~4.6× compression at <1.5% PPL loss	attn-rotation-and-ppl-artifact
turbo4	KV cache	~4.5	rehabilitated to beat q4_0 on fidelity	turbo4-resurrection

All turbo formats use Walsh-Hadamard rotation followed by polar codebook quantization on 128-element blocks. Why this works where MSE-driven codecs fail: why-mse-fails-for-kv-quantization.

Compression policies

• Auto-asymmetric K/V compression — recognizes that V tolerates aggressive compression while K does not; default policy picks complementary codecs rather than symmetric. asymmetric-kv-compression
• Boundary V (experimental, layer-aware) — auto-enabled for turbo2-V. Protects layers where aggressive V quantization degrades quality, leaves the rest at full aggression. layer-aware-v-compression, moe-v-compression-frontier
• Sparse V dequantization — skip V dequantization for positions whose softmax attention weight falls below threshold. Enabled across all Metal targets. sparse-v-dequant

Backend coverage

Backend	Quant kernels	Flash Attention	Notes
Metal (Apple Silicon)	TQ V2.1 fused, TurboFlash	Yes — sparse V across the family; dk=512 FA kernels for Gemma 4	TurboFlash off by default on Apple10 (corruption regression under investigation). m5-max-stress-test
CUDA (NVIDIA)	dp4a for TQ4_1S, warp-cooperative dequant (16× less compute per block), multi-token / multi-GPU	Yes — turbo VEC FA (+9% decode); mixed f16/bf16 + q8_0 without GGML_CUDA_FA_ALL_QUANTS	Load-time TQ4_1S → q8_0 conversion path
HIP / ROCm (AMD)	Portable ggml_cuda_dp4a; scalar half path for TQ4_1S on AMD	Yes — VEC FA forced for quantized KV; pool bypass for FA f16 temp buffers	RDNA3 (gfx1100), RDNA4, CDNA3 (MI300X / gfx942), CDNA4 (MI355X / gfx950). cross-engine-mi300x
Vulkan	TQ4_1S weights, SET_ROWS for turbo2/turbo4	coopmat flash attention with turbo3 KV	Compute-shader path; nix-buildable

Model-family support

• Gemma 4 — dk=512 Metal FA kernels, MoE token routing, op-concurrency handling
• Large MoE — kernel instantiations for up to 256-expert routing
• Hybrid architectures (GDN, Mamba) — speculative decoding cherry-picked from upstream feature branches
• All existing llama.cpp model families remain fully supported

Operational fixes carried by this fork

• CPU vec_dot heap-allocation fix for turbo / TQ types at n > 4096
• Apple Silicon unified-memory explosion fix
• RPC GGML_OP_COUNT assertion fix
• Cross-vendor -Werror build fixes
• Defensive xxd.cmake handling for missing input files

---

Quick start

Standard llama.cpp build flags. TurboQuant types become available automatically once the matching backend is compiled in.

# Apple Silicon (Metal)
cmake -B build -DGGML_METAL=ON && cmake --build build -j

# NVIDIA CUDA
cmake -B build -DGGML_CUDA=ON && cmake --build build -j

# AMD HIP / ROCm (multi-arch fat binary)
cmake -B build -DGGML_HIP=ON -DCMAKE_HIP_ARCHITECTURES="gfx1100;gfx942;gfx950" && cmake --build build -j

# Vulkan
cmake -B build -DGGML_VULKAN=ON && cmake --build build -j

Usage

KV-cache quantization (runtime)

KV-cache types are selected per-side via the standard --cache-type-k / --cache-type-v flags.

Start light, then compress. Some model families — small models, certain MoE configurations, quant-sensitive instruction-tuned variants — are more delicate than others. Pick a light asymmetric configuration first, verify output quality (eyeball + PPL on a hold-out set) on your specific model, then ratchet up V aggression if you have memory headroom to gain. Do not start at maximum compression and work backwards.

The core finding from the asymmetric-kv-compression paper — Asymmetric K/V Cache Compression: Why V is Free and K is Everything — drives all the configs below: V tolerates aggressive compression, K does not. Always keep K at higher precision than V; never start symmetric. That paper documents the specific failure modes you'll hit if you ignore this and compress K aggressively (PPL blow-up on certain model families, attention-rotation interaction with low-bit K, etc.) — read it before considering step 6.

Higher turbo number = more bits per element = less aggressive compression. The V-side compression ladder is turbo4 (lightest) → turbo3 → turbo2 (heaviest). On the K side, prefer f16 or q8_0; never lead with a turbo K.

Recommendations, ordered from most conservative to most aggressive:

Step	--cache-type-k	--cache-type-v	When	Notes
1. Safest start	f16	turbo4	First contact with any new model	K untouched, V at the lightest turbo tier. If output isn't faithful at this step, the model is unusually quant-sensitive — stop and investigate before escalating.
2. Conservative	q8_0	turbo4	Verified safe at step 1, want a memory win without much risk	Light on both sides. Typically near-indistinguishable from f16/f16 outputs.
3. Recommended default	q8_0	turbo3	Most dense models, most production workloads	The "asymmetric turbo" sweet spot from the asymmetric-kv-compression paper. Near-lossless K, ~4.6× compressed V. Total KV ~3-4× smaller than f16/f16.
4. Aggressive V	q8_0	turbo2	Memory-bound long context, after validating quality at step 3	Boundary V auto-engages and protects sensitive layers. Expect <2% PPL loss on dense models outside the protected layers.
5. MoE-aware aggressive	q8_0	turbo2	Large MoE models (DeepSeek, Qwen3.6, Mixtral-style)	Same flags; Boundary V's per-expert-boundary protection is what makes this work on MoE. See moe-v-compression-frontier.
6. Discouraged: symmetric K compression	any turbo*	any turbo*	Only with model-specific quality validation in hand	Compressing K is where models break. The asymmetric paper documents the failure modes. Not a starting point.

Example invocations:

# Step 1 — safest start (first contact with a new model)
llama-cli -m model.gguf --cache-type-k f16 --cache-type-v turbo4 -p "..."

# Step 3 — recommended default (asymmetric turbo)
llama-cli -m model.gguf --cache-type-k q8_0 --cache-type-v turbo3 -p "..."

# Step 4 — aggressive V at long context
llama-cli -m model.gguf --cache-type-k q8_0 --cache-type-v turbo2 -c 131072 -p "..."

If output quality drops between steps, walk back to the previous step. The compression frontier is per-model — there is no global "best" setting.

Weight quantization (offline)

Weight quantization is selected at conversion time via llama-quantize:

# TQ4_1S — recommended for most CUDA / HIP deployments (dp4a 3.5× faster than baseline)
llama-quantize model.f16.gguf model.tq4_1s.gguf TQ4_1S

# TQ3_1S — smaller, accept ~1-2 PPL bump
llama-quantize model.f16.gguf model.tq3_1s.gguf TQ3_1S

Automatic behavior

The following activate based on the selected types — no flags required:

• Auto-asymmetric K/V — when both sides are turbo / TQ types, the policy picks complementary configurations rather than symmetric.
• Boundary V (layer-aware) — auto-enables for any turbo2-V selection.
• Sparse V dequantization — on Metal targets, sparse V activates for all turbo V types.
• Flash Attention — auto-enabled for turbo KV with the relevant backend kernel.

See the linked papers above for parameter selection guidance on a per-model basis.

Citation

If this fork or any of its quantization types is used in your work, please cite the corresponding paper from the TurboQuant+ paper corpus.

License

MIT, same as upstream llama.cpp.

---

Recent API changes

• Changelog for libllama API
• Changelog for llama-server REST API

Hot topics

• Hugging Face cache migration: models downloaded with -hf are now stored in the standard Hugging Face cache directory, enabling sharing with other HF tools.
• guide : using the new WebUI of llama.cpp
• guide : running gpt-oss with llama.cpp
• [FEEDBACK] Better packaging for llama.cpp to support downstream consumers 🤗
• Support for the gpt-oss model with native MXFP4 format has been added | PR | Collaboration with NVIDIA | Comment
• Multimodal support arrived in llama-server: #12898 | documentation
• VS Code extension for FIM completions: https://github.com/ggml-org/llama.vscode
• Vim/Neovim plugin for FIM completions: https://github.com/ggml-org/llama.vim
• Hugging Face Inference Endpoints now support GGUF out of the box! ggml-org#9669
• Hugging Face GGUF editor: discussion | tool

---

Quick start

Getting started with llama.cpp is straightforward. Here are several ways to install it on your machine:

• Install llama.cpp using brew, nix or winget
• Run with Docker - see our Docker documentation
• Download pre-built binaries from the releases page
• Build from source by cloning this repository - check out our build guide

Once installed, you'll need a model to work with. Head to the Obtaining and quantizing models section to learn more.

Example command:

# Use a local model file
llama-cli -m my_model.gguf

# Or download and run a model directly from Hugging Face
llama-cli -hf ggml-org/gemma-3-1b-it-GGUF

# Launch OpenAI-compatible API server
llama-server -hf ggml-org/gemma-3-1b-it-GGUF

Description

The main goal of llama.cpp is to enable LLM inference with minimal setup and state-of-the-art performance on a wide range of hardware - locally and in the cloud.

• Plain C/C++ implementation without any dependencies
• Apple silicon is a first-class citizen - optimized via ARM NEON, Accelerate and Metal frameworks
• AVX, AVX2, AVX512 and AMX support for x86 architectures
• RVV, ZVFH, ZFH, ZICBOP and ZIHINTPAUSE support for RISC-V architectures
• 1.5-bit, 2-bit, 3-bit, 4-bit, 5-bit, 6-bit, and 8-bit integer quantization for faster inference and reduced memory use
• Custom CUDA kernels for running LLMs on NVIDIA GPUs (support for AMD GPUs via HIP and Moore Threads GPUs via MUSA)
• Vulkan and SYCL backend support
• CPU+GPU hybrid inference to partially accelerate models larger than the total VRAM capacity

The llama.cpp project is the main playground for developing new features for the ggml library.

Models

Typically finetunes of the base models below are supported as well.

Instructions for adding support for new models: HOWTO-add-model.md

Text-only

• LLaMA 🦙
• LLaMA 2 🦙🦙
• LLaMA 3 🦙🦙🦙
• Mistral 7B
• Mixtral MoE
• DBRX
• Jamba
• Falcon
• Chinese LLaMA / Alpaca and Chinese LLaMA-2 / Alpaca-2
• Vigogne (French)
• BERT
• Koala
• Baichuan 1 & 2 + derivations
• Aquila 1 & 2
• Starcoder models
• Refact
• MPT
• Bloom
• Yi models
• StableLM models
• Deepseek models
• Qwen models
• PLaMo-13B
• Phi models
• PhiMoE
• GPT-2
• Orion 14B
• InternLM2
• CodeShell
• Gemma
• Mamba
• Grok-1
• Xverse
• Command-R models
• SEA-LION
• GritLM-7B + GritLM-8x7B
• OLMo
• OLMo 2
• OLMoE
• Granite models
• GPT-NeoX + Pythia
• Snowflake-Arctic MoE
• Smaug
• Poro 34B
• Bitnet b1.58 models
• Flan T5
• Open Elm models
• ChatGLM3-6b + ChatGLM4-9b + GLMEdge-1.5b + GLMEdge-4b
• GLM-4-0414
• SmolLM
• EXAONE-3.0-7.8B-Instruct
• FalconMamba Models
• Jais
• Bielik-11B-v2.3
• RWKV-7
• RWKV-6
• QRWKV-6
• GigaChat-20B-A3B
• Trillion-7B-preview
• Ling models
• LFM2 models
• Hunyuan models
• BailingMoeV2 (Ring/Ling 2.0) models

Multimodal

• LLaVA 1.5 models, LLaVA 1.6 models
• BakLLaVA
• Obsidian
• ShareGPT4V
• MobileVLM 1.7B/3B models
• Yi-VL
• Mini CPM
• Moondream
• Bunny
• GLM-EDGE
• Qwen2-VL
• LFM2-VL

Bindings

• Python: ddh0/easy-llama
• Python: abetlen/llama-cpp-python
• Go: go-skynet/go-llama.cpp
• Node.js: withcatai/node-llama-cpp
• JS/TS (llama.cpp server client): lgrammel/modelfusion
• JS/TS (Programmable Prompt Engine CLI): offline-ai/cli
• JavaScript/Wasm (works in browser): tangledgroup/llama-cpp-wasm
• Typescript/Wasm (nicer API, available on npm): ngxson/wllama
• Ruby: yoshoku/llama_cpp.rb
• Ruby: docusealco/rllama
• Rust (more features): edgenai/llama_cpp-rs
• Rust (nicer API): mdrokz/rust-llama.cpp
• Rust (more direct bindings): utilityai/llama-cpp-rs
• Rust (automated build from crates.io): ShelbyJenkins/llm_client
• C#/.NET: SciSharp/LLamaSharp
• C#/VB.NET (more features - community license): LM-Kit.NET
• Scala 3: donderom/llm4s
• Clojure: phronmophobic/llama.clj
• React Native: mybigday/llama.rn
• Java: kherud/java-llama.cpp
• Java: QuasarByte/llama-cpp-jna
• Zig: deins/llama.cpp.zig
• Flutter/Dart: netdur/llama_cpp_dart
• Flutter: xuegao-tzx/Fllama
• PHP (API bindings and features built on top of llama.cpp): distantmagic/resonance (more info)
• Guile Scheme: guile_llama_cpp
• Swift srgtuszy/llama-cpp-swift
• Swift ShenghaiWang/SwiftLlama
• Delphi Embarcadero/llama-cpp-delphi
• Go (no CGo needed): hybridgroup/yzma
• Android: llama.android

UIs

(to have a project listed here, it should clearly state that it depends on llama.cpp)

• AI Sublime Text plugin (MIT)
• BonzAI App (proprietary)
• cztomsik/ava (MIT)
• Dot (GPL)
• eva (MIT)
• iohub/collama (Apache-2.0)
• janhq/jan (AGPL)
• johnbean393/Sidekick (MIT)
• KanTV (Apache-2.0)
• KodiBot (GPL)
• llama.vim (MIT)
• LARS (AGPL)
• Llama Assistant (GPL)
• LlamaLib (Apache-2.0)
• LLMFarm (MIT)
• LLMUnity (MIT)
• LMStudio (proprietary)
• LocalAI (MIT)
• LostRuins/koboldcpp (AGPL)
• MindMac (proprietary)
• MindWorkAI/AI-Studio (FSL-1.1-MIT)
• Mobile-Artificial-Intelligence/maid (MIT)
• Mozilla-Ocho/llamafile (Apache-2.0)
• nat/openplayground (MIT)
• nomic-ai/gpt4all (MIT)
• ollama/ollama (MIT)
• oobabooga/text-generation-webui (AGPL)
• PocketPal AI (MIT)
• psugihara/FreeChat (MIT)
• ptsochantaris/emeltal (MIT)
• pythops/tenere (AGPL)
• ramalama (MIT)
• semperai/amica (MIT)
• withcatai/catai (MIT)
• Autopen (GPL)

Tools

• akx/ggify – download PyTorch models from Hugging Face Hub and convert them to GGML
• akx/ollama-dl – download models from the Ollama library to be used directly with llama.cpp
• crashr/gppm – launch llama.cpp instances utilizing NVIDIA Tesla P40 or P100 GPUs with reduced idle power consumption
• gpustack/gguf-parser - review/check the GGUF file and estimate the memory usage
• Styled Lines (proprietary licensed, async wrapper of inference part for game development in Unity3d with pre-built Mobile and Web platform wrappers and a model example)
• unslothai/unsloth – 🦥 exports/saves fine-tuned and trained models to GGUF (Apache-2.0)

Infrastructure

• Paddler - Open-source LLMOps platform for hosting and scaling AI in your own infrastructure
• GPUStack - Manage GPU clusters for running LLMs
• llama_cpp_canister - llama.cpp as a smart contract on the Internet Computer, using WebAssembly
• llama-swap - transparent proxy that adds automatic model switching with llama-server
• Kalavai - Crowdsource end to end LLM deployment at any scale
• llmaz - ☸️ Easy, advanced inference platform for large language models on Kubernetes.
• LLMKube - Kubernetes operator for llama.cpp with multi-GPU and Apple Silicon Metal support"

Games

• Lucy's Labyrinth - A simple maze game where agents controlled by an AI model will try to trick you.

Supported backends

Backend	Target devices
Metal	Apple Silicon
BLAS	All
BLIS	All
SYCL	Intel and Nvidia GPU
OpenVINO [In Progress]	Intel CPUs, GPUs, and NPUs
MUSA	Moore Threads GPU
CUDA	Nvidia GPU
HIP	AMD GPU
ZenDNN	AMD CPU
Vulkan	GPU
CANN	Ascend NPU
OpenCL	Adreno GPU
IBM zDNN	IBM Z & LinuxONE
WebGPU [In Progress]	All
RPC	All
Hexagon [In Progress]	Snapdragon
VirtGPU	VirtGPU APIR

Obtaining and quantizing models

The Hugging Face platform hosts a number of LLMs compatible with llama.cpp:

• Trending
• LLaMA

You can either manually download the GGUF file or directly use any llama.cpp-compatible models from Hugging Face or other model hosting sites, by using this CLI argument: -hf <user>/<model>[:quant]. For example:

llama-cli -hf ggml-org/gemma-3-1b-it-GGUF

By default, the CLI would download from Hugging Face, you can switch to other options with the environment variable MODEL_ENDPOINT. The MODEL_ENDPOINT must point to a Hugging Face compatible API endpoint.

After downloading a model, use the CLI tools to run it locally - see below.

llama.cpp requires the model to be stored in the GGUF file format. Models in other data formats can be converted to GGUF using the convert_*.py Python scripts in this repo.

The Hugging Face platform provides a variety of online tools for converting, quantizing and hosting models with llama.cpp:

• Use the GGUF-my-repo space to convert to GGUF format and quantize model weights to smaller sizes
• Use the GGUF-my-LoRA space to convert LoRA adapters to GGUF format (more info: ggml-org#10123)
• Use the GGUF-editor space to edit GGUF meta data in the browser (more info: ggml-org#9268)
• Use the Inference Endpoints to directly host llama.cpp in the cloud (more info: ggml-org#9669)

To learn more about model quantization, read this documentation

llama-cli

A CLI tool for accessing and experimenting with most of llama.cpp's functionality.

• Run in conversation mode

  Models with a built-in chat template will automatically activate conversation mode. If this doesn't occur, you can manually enable it by adding -cnv and specifying a suitable chat template with --chat-template NAME

  llama-cli -m model.gguf
  
  # > hi, who are you?
  # Hi there! I'm your helpful assistant! I'm an AI-powered chatbot designed to assist and provide information to users like you. I'm here to help answer your questions, provide guidance, and offer support on a wide range of topics. I'm a friendly and knowledgeable AI, and I'm always happy to help with anything you need. What's on your mind, and how can I assist you today?
  #
  # > what is 1+1?
  # Easy peasy! The answer to 1+1 is... 2!

• Run in conversation mode with custom chat template

  # use the "chatml" template (use -h to see the list of supported templates)
  llama-cli -m model.gguf -cnv --chat-template chatml
  
  # use a custom template
  llama-cli -m model.gguf -cnv --in-prefix 'User: ' --reverse-prompt 'User:'

• Constrain the output with a custom grammar

  llama-cli -m model.gguf -n 256 --grammar-file grammars/json.gbnf -p 'Request: schedule a call at 8pm; Command:'
  
  # {"appointmentTime": "8pm", "appointmentDetails": "schedule a a call"}

  The grammars/ folder contains a handful of sample grammars. To write your own, check out the GBNF Guide.

  For authoring more complex JSON grammars, check out https://grammar.intrinsiclabs.ai/

llama-server

A lightweight, OpenAI API compatible, HTTP server for serving LLMs.

• Start a local HTTP server with default configuration on port 8080

  llama-server -m model.gguf --port 8080
  
  # Basic web UI can be accessed via browser: http://localhost:8080
  # Chat completion endpoint: http://localhost:8080/v1/chat/completions

• Support multiple-users and parallel decoding

  # up to 4 concurrent requests, each with 4096 max context
  llama-server -m model.gguf -c 16384 -np 4

• Enable speculative decoding

  # the draft.gguf model should be a small variant of the target model.gguf
  llama-server -m model.gguf -md draft.gguf

• Serve an embedding model

  # use the /embedding endpoint
  llama-server -m model.gguf --embedding --pooling cls -ub 8192

• Serve a reranking model

  # use the /reranking endpoint
  llama-server -m model.gguf --reranking

• Constrain all outputs with a grammar

  # custom grammar
  llama-server -m model.gguf --grammar-file grammar.gbnf
  
  # JSON
  llama-server -m model.gguf --grammar-file grammars/json.gbnf

llama-perplexity

A tool for measuring the perplexity ¹ (and other quality metrics) of a model over a given text.

• Measure the perplexity over a text file

  llama-perplexity -m model.gguf -f file.txt
  
  # [1]15.2701,[2]5.4007,[3]5.3073,[4]6.2965,[5]5.8940,[6]5.6096,[7]5.7942,[8]4.9297, ...
  # Final estimate: PPL = 5.4007 +/- 0.67339

• Measure KL divergence

  # TODO

llama-bench

Benchmark the performance of the inference for various parameters.

• Run default benchmark

  llama-bench -m model.gguf
  
  # Output:
  # | model               |       size |     params | backend    | threads |          test |                  t/s |
  # | ------------------- | ---------: | ---------: | ---------- | ------: | ------------: | -------------------: |
  # | qwen2 1.5B Q4_0     | 885.97 MiB |     1.54 B | Metal,BLAS |      16 |         pp512 |      5765.41 ± 20.55 |
  # | qwen2 1.5B Q4_0     | 885.97 MiB |     1.54 B | Metal,BLAS |      16 |         tg128 |        197.71 ± 0.81 |
  #
  # build: 3e0ba0e60 (4229)

llama-simple

A minimal example for implementing apps with llama.cpp. Useful for developers.

• Basic text completion

  llama-simple -m model.gguf
  
  # Hello my name is Kaitlyn and I am a 16 year old girl. I am a junior in high school and I am currently taking a class called "The Art of

Contributing

• Contributors can open PRs
• Collaborators will be invited based on contributions
• Maintainers can push to branches in the llama.cpp repo and merge PRs into the master branch
• Any help with managing issues, PRs and projects is very appreciated!
• See good first issues for tasks suitable for first contributions
• Read the CONTRIBUTING.md for more information
• Make sure to read this: Inference at the edge
• A bit of backstory for those who are interested: Changelog podcast

Other documentation

• cli
• completion
• server
• GBNF grammars

Development documentation

• How to build
• Running on Docker
• Build on Android
• Multi-GPU usage
• Performance troubleshooting
• GGML tips & tricks

Seminal papers and background on the models

If your issue is with model generation quality, then please at least scan the following links and papers to understand the limitations of LLaMA models. This is especially important when choosing an appropriate model size and appreciating both the significant and subtle differences between LLaMA models and ChatGPT:

• LLaMA:
  • Introducing LLaMA: A foundational, 65-billion-parameter large language model
  • LLaMA: Open and Efficient Foundation Language Models
• GPT-3
  • Language Models are Few-Shot Learners
• GPT-3.5 / InstructGPT / ChatGPT:
  • Aligning language models to follow instructions
  • Training language models to follow instructions with human feedback

XCFramework

The XCFramework is a precompiled version of the library for iOS, visionOS, tvOS, and macOS. It can be used in Swift projects without the need to compile the library from source. For example:

// swift-tools-version: 5.10
// The swift-tools-version declares the minimum version of Swift required to build this package.

import PackageDescription

let package = Package(
    name: "MyLlamaPackage",
    targets: [
        .executableTarget(
            name: "MyLlamaPackage",
            dependencies: [
                "LlamaFramework"
            ]),
        .binaryTarget(
            name: "LlamaFramework",
            url: "https://github.com/ggml-org/llama.cpp/releases/download/b5046/llama-b5046-xcframework.zip",
            checksum: "c19be78b5f00d8d29a25da41042cb7afa094cbf6280a225abe614b03b20029ab"
        )
    ]
)

The above example is using an intermediate build b5046 of the library. This can be modified to use a different version by changing the URL and checksum.

Completions

Command-line completion is available for some environments.

Bash Completion

$ build/bin/llama-cli --completion-bash > ~/.llama-completion.bash
$ source ~/.llama-completion.bash

Optionally this can be added to your .bashrc or .bash_profile to load it automatically. For example:

$ echo "source ~/.llama-completion.bash" >> ~/.bashrc

Dependencies

• yhirose/cpp-httplib - Single-header HTTP server, used by llama-server - MIT license
• stb-image - Single-header image format decoder, used by multimodal subsystem - Public domain
• nlohmann/json - Single-header JSON library, used by various tools/examples - MIT License
• miniaudio.h - Single-header audio format decoder, used by multimodal subsystem - Public domain
• subprocess.h - Single-header process launching solution for C and C++ - Public domain

Footnotes

1. https://huggingface.co/docs/transformers/perplexity ↩