jp6/cu126/: nemo-toolkit-2.1.0rc0 metadata and description

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NeMo - a toolkit for Conversational AI

author NVIDIA
author_email NVIDIA <nemo-toolkit@nvidia.com>
classifiers
  • Development Status :: 5 - Production/Stable
  • Environment :: Console
  • Intended Audience :: Developers
  • Intended Audience :: Information Technology
  • Intended Audience :: Science/Research
  • License :: OSI Approved :: Apache Software License
  • Natural Language :: English
  • Operating System :: OS Independent
  • Programming Language :: Python :: 3
  • Programming Language :: Python :: 3.10
  • Topic :: Scientific/Engineering :: Artificial Intelligence
  • Topic :: Scientific/Engineering :: Image Recognition
  • Topic :: Scientific/Engineering :: Mathematics
  • Topic :: Scientific/Engineering
  • Topic :: Software Development :: Libraries :: Python Modules
  • Topic :: Software Development :: Libraries
  • Topic :: Utilities
description_content_type text/markdown
download_url https://github.com/NVIDIA/NeMo/releases
keywords NLP,NeMo,deep,gpu,language,learning,learning,machine,nvidia,pytorch,speech,torch,tts
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maintainer NVIDIA
maintainer_email NVIDIA <nemo-toolkit@nvidia.com>
project_urls
  • Download, https://github.com/NVIDIA/NeMo/releases
  • Homepage, https://github.com/nvidia/nemo
requires_dist
  • huggingface-hub >=0.24
  • numba
  • numpy >=1.22
  • onnx >=1.7.0
  • python-dateutil
  • ruamel.yaml
  • scikit-learn
  • setuptools >=70.0.0
  • tensorboard
  • text-unidecode
  • torch
  • tqdm >=4.41.0
  • wget
  • wrapt
  • black ~=24.3 ; extra == 'all'
  • click >=8.1 ; extra == 'all'
  • isort <6.0.0,>5.1.0 ; extra == 'all'
  • parameterized ; extra == 'all'
  • pytest ; extra == 'all'
  • pytest-mock ; extra == 'all'
  • pytest-runner ; extra == 'all'
  • ruamel.yaml ; extra == 'all'
  • sphinx ; extra == 'all'
  • sphinxcontrib-bibtex ; extra == 'all'
  • wandb ; extra == 'all'
  • wget ; extra == 'all'
  • wrapt ; extra == 'all'
  • cloudpickle ; extra == 'all'
  • fiddle ; extra == 'all'
  • hydra-core <=1.3.2,>1.3 ; extra == 'all'
  • omegaconf <=2.3 ; extra == 'all'
  • pytorch-lightning >2.2.1 ; extra == 'all'
  • torchmetrics >=0.11.0 ; extra == 'all'
  • transformers >=4.45.0 ; extra == 'all'
  • webdataset >=0.2.86 ; extra == 'all'
  • datasets ; extra == 'all'
  • einops ; extra == 'all'
  • inflect ; extra == 'all'
  • mediapy ==1.1.6 ; extra == 'all'
  • pandas ; extra == 'all'
  • sacremoses >=0.0.43 ; extra == 'all'
  • sentencepiece <1.0.0 ; extra == 'all'
  • braceexpand ; extra == 'all'
  • editdistance ; extra == 'all'
  • g2p-en ; extra == 'all'
  • jiwer ; extra == 'all'
  • kaldi-python-io ; extra == 'all'
  • kaldiio ; extra == 'all'
  • lhotse >=1.26.0 ; extra == 'all'
  • librosa >=0.10.2 ; extra == 'all'
  • marshmallow ; extra == 'all'
  • packaging ; extra == 'all'
  • pyannote.core ; extra == 'all'
  • pyannote.metrics ; extra == 'all'
  • pydub ; extra == 'all'
  • pyloudnorm ; extra == 'all'
  • resampy ; extra == 'all'
  • scipy >=0.14 ; extra == 'all'
  • soundfile ; extra == 'all'
  • sox ; extra == 'all'
  • texterrors ; extra == 'all'
  • accelerated-scan ; extra == 'all'
  • boto3 ; extra == 'all'
  • faiss-cpu ; extra == 'all'
  • fasttext ; extra == 'all'
  • flask-restful ; extra == 'all'
  • ftfy ; extra == 'all'
  • gdown ; extra == 'all'
  • h5py ; extra == 'all'
  • ijson ; extra == 'all'
  • jieba ; extra == 'all'
  • markdown2 ; extra == 'all'
  • matplotlib >=3.3.2 ; extra == 'all'
  • nltk >=3.6.5 ; extra == 'all'
  • numpy <2 ; extra == 'all'
  • opencc <1.1.7 ; extra == 'all'
  • pangu ; extra == 'all'
  • prettytable ; extra == 'all'
  • rapidfuzz ; extra == 'all'
  • rouge-score ; extra == 'all'
  • sacrebleu ; extra == 'all'
  • sentence-transformers ; extra == 'all'
  • tensorstore <0.1.46 ; extra == 'all'
  • tiktoken ==0.7.0 ; extra == 'all'
  • zarr ; extra == 'all'
  • attrdict ; extra == 'all'
  • janome ; extra == 'all'
  • kornia ; extra == 'all'
  • librosa ; extra == 'all'
  • matplotlib ; extra == 'all'
  • nltk ; extra == 'all'
  • pypinyin ; extra == 'all'
  • pypinyin-dict ; extra == 'all'
  • jiwer >=2.0.0 ; extra == 'all'
  • progress >=1.5 ; extra == 'all'
  • tabulate >=0.8.7 ; extra == 'all'
  • textdistance >=4.1.5 ; extra == 'all'
  • tqdm ; extra == 'all'
  • addict ; extra == 'all'
  • clip ; extra == 'all'
  • diffusers >=0.19.3 ; extra == 'all'
  • einops-exts ; extra == 'all'
  • imageio ; extra == 'all'
  • megatron-energon ; extra == 'all'
  • nerfacc >=0.5.3 ; extra == 'all'
  • open-clip-torch ==2.24.0 ; extra == 'all'
  • PyMCubes ; extra == 'all'
  • taming-transformers ; extra == 'all'
  • torchdiffeq ; extra == 'all'
  • torchsde ; extra == 'all'
  • trimesh ; extra == 'all'
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  • nemo-text-processing ; ("arm" not in platform_machine and "aarch" not in platform_machine) and extra == 'all'
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  • decord ; (sys_platform == "linux") and extra == 'all'
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  • g2p-en ; extra == 'asr'
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  • librosa >=0.10.2 ; extra == 'asr'
  • marshmallow ; extra == 'asr'
  • packaging ; extra == 'asr'
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  • pydub ; extra == 'asr'
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  • ruamel.yaml ; extra == 'asr'
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  • transformers >=4.45.0 ; extra == 'core'
  • wandb ; extra == 'core'
  • webdataset >=0.2.86 ; extra == 'core'
  • addict ; extra == 'multimodal'
  • clip ; extra == 'multimodal'
  • diffusers >=0.19.3 ; extra == 'multimodal'
  • einops-exts ; extra == 'multimodal'
  • imageio ; extra == 'multimodal'
  • kornia ; extra == 'multimodal'
  • megatron-energon ; extra == 'multimodal'
  • nerfacc >=0.5.3 ; extra == 'multimodal'
  • open-clip-torch ==2.24.0 ; extra == 'multimodal'
  • PyMCubes ; extra == 'multimodal'
  • taming-transformers ; extra == 'multimodal'
  • torchdiffeq ; extra == 'multimodal'
  • torchsde ; extra == 'multimodal'
  • trimesh ; extra == 'multimodal'
  • accelerated-scan ; extra == 'multimodal'
  • boto3 ; extra == 'multimodal'
  • faiss-cpu ; extra == 'multimodal'
  • fasttext ; extra == 'multimodal'
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  • mamba-ssm ==2.2.2 ; (sys_platform == "linux") and extra == 'multimodal'
  • accelerated-scan ; extra == 'nlp'
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  • datasets ; extra == 'slu'
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  • pandas ; extra == 'slu'
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  • attrdict ; extra == 'test'
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  • janome ; extra == 'test'
  • jieba ; extra == 'test'
  • kornia ; extra == 'test'
  • librosa ; extra == 'test'
  • matplotlib ; extra == 'test'
  • nltk ; extra == 'test'
  • pandas ; extra == 'test'
  • pypinyin ; extra == 'test'
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  • inflect ; extra == 'test'
  • mediapy ==1.1.6 ; extra == 'test'
  • sacremoses >=0.0.43 ; extra == 'test'
  • sentencepiece <1.0.0 ; extra == 'test'
  • nemo-text-processing ; ("arm" not in platform_machine and "aarch" not in platform_machine) and extra == 'test'
  • attrdict ; extra == 'tts'
  • einops ; extra == 'tts'
  • janome ; extra == 'tts'
  • jieba ; extra == 'tts'
  • kornia ; extra == 'tts'
  • librosa ; extra == 'tts'
  • matplotlib ; extra == 'tts'
  • nltk ; extra == 'tts'
  • pandas ; extra == 'tts'
  • pypinyin ; extra == 'tts'
  • pypinyin-dict ; extra == 'tts'
  • cloudpickle ; extra == 'tts'
  • fiddle ; extra == 'tts'
  • hydra-core <=1.3.2,>1.3 ; extra == 'tts'
  • omegaconf <=2.3 ; extra == 'tts'
  • pytorch-lightning >2.2.1 ; extra == 'tts'
  • torchmetrics >=0.11.0 ; extra == 'tts'
  • transformers >=4.45.0 ; extra == 'tts'
  • wandb ; extra == 'tts'
  • webdataset >=0.2.86 ; extra == 'tts'
  • datasets ; extra == 'tts'
  • inflect ; extra == 'tts'
  • mediapy ==1.1.6 ; extra == 'tts'
  • sacremoses >=0.0.43 ; extra == 'tts'
  • sentencepiece <1.0.0 ; extra == 'tts'
  • braceexpand ; extra == 'tts'
  • editdistance ; extra == 'tts'
  • g2p-en ; extra == 'tts'
  • jiwer ; extra == 'tts'
  • kaldi-python-io ; extra == 'tts'
  • kaldiio ; extra == 'tts'
  • lhotse >=1.26.0 ; extra == 'tts'
  • librosa >=0.10.2 ; extra == 'tts'
  • marshmallow ; extra == 'tts'
  • packaging ; extra == 'tts'
  • pyannote.core ; extra == 'tts'
  • pyannote.metrics ; extra == 'tts'
  • pydub ; extra == 'tts'
  • pyloudnorm ; extra == 'tts'
  • resampy ; extra == 'tts'
  • ruamel.yaml ; extra == 'tts'
  • scipy >=0.14 ; extra == 'tts'
  • soundfile ; extra == 'tts'
  • sox ; extra == 'tts'
  • texterrors ; extra == 'tts'
  • nemo-text-processing ; ("arm" not in platform_machine and "aarch" not in platform_machine) and extra == 'tts'
requires_python >=3.10

Because this project isn't in the mirror_whitelist, no releases from root/pypi are included.

File Tox results History
nemo_toolkit-2.1.0rc0-py3-none-any.whl
Size
5 MB
Type
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Python
3

Project Status: Active -- The project has reached a stable, usable state and is being actively developed. Documentation CodeQL NeMo core license and license for collections in this repo Release version Python version PyPi total downloads Code style: black

NVIDIA NeMo Framework

Latest News

NeMo 2.0 We've released NeMo 2.0, an update on the NeMo Framework which prioritizes modularity and ease-of-use. Please refer to the NeMo Framework User Guide to get started.
Large Language Models and Multimodal Models
New Llama 3.1 Support (2024-07-23) The NeMo Framework now supports training and customizing the Llama 3.1 collection of LLMs from Meta.

Accelerate your Generative AI Distributed Training Workloads with the NVIDIA NeMo Framework on Amazon EKS (2024-07-16) NVIDIA NeMo Framework now runs distributed training workloads on an Amazon Elastic Kubernetes Service (Amazon EKS) cluster. For step-by-step instructions on creating an EKS cluster and running distributed training workloads with NeMo, see the GitHub repository here.

NVIDIA NeMo Accelerates LLM Innovation with Hybrid State Space Model Support (2024/06/17) NVIDIA NeMo and Megatron Core now support pre-training and fine-tuning of state space models (SSMs). NeMo also supports training models based on the Griffin architecture as described by Google DeepMind.

NVIDIA releases 340B base, instruct, and reward models pretrained on a total of 9T tokens. (2024-06-18) See documentation and tutorials for SFT, PEFT, and PTQ with Nemotron 340B in the NeMo Framework User Guide.

NVIDIA sets new generative AI performance and scale records in MLPerf Training v4.0 (2024/06/12) Using NVIDIA NeMo Framework and NVIDIA Hopper GPUs NVIDIA was able to scale to 11,616 H100 GPUs and achieve near-linear performance scaling on LLM pretraining. NVIDIA also achieved the highest LLM fine-tuning performance and raised the bar for text-to-image training.

Accelerate your generative AI journey with NVIDIA NeMo Framework on GKE (2024/03/16) An end-to-end walkthrough to train generative AI models on the Google Kubernetes Engine (GKE) using the NVIDIA NeMo Framework is available at https://github.com/GoogleCloudPlatform/nvidia-nemo-on-gke. The walkthrough includes detailed instructions on how to set up a Google Cloud Project and pre-train a GPT model using the NeMo Framework.

Speech Recognition
Accelerating Leaderboard-Topping ASR Models 10x with NVIDIA NeMo (2024/09/24) NVIDIA NeMo team released a number of inference optimizations for CTC, RNN-T, and TDT models that resulted in up to 10x inference speed-up. These models now exceed an inverse real-time factor (RTFx) of 2,000, with some reaching RTFx of even 6,000.

New Standard for Speech Recognition and Translation from the NVIDIA NeMo Canary Model (2024/04/18) The NeMo team just released Canary, a multilingual model that transcribes speech in English, Spanish, German, and French with punctuation and capitalization. Canary also provides bi-directional translation, between English and the three other supported languages.

Pushing the Boundaries of Speech Recognition with NVIDIA NeMo Parakeet ASR Models (2024/04/18) NVIDIA NeMo, an end-to-end platform for the development of multimodal generative AI models at scale anywhere—on any cloud and on-premises—released the Parakeet family of automatic speech recognition (ASR) models. These state-of-the-art ASR models, developed in collaboration with Suno.ai, transcribe spoken English with exceptional accuracy.

Turbocharge ASR Accuracy and Speed with NVIDIA NeMo Parakeet-TDT (2024/04/18) NVIDIA NeMo, an end-to-end platform for developing multimodal generative AI models at scale anywhere—on any cloud and on-premises—recently released Parakeet-TDT. This new addition to the  NeMo ASR Parakeet model family boasts better accuracy and 64% greater speed over the previously best model, Parakeet-RNNT-1.1B.

Introduction

NVIDIA NeMo Framework is a scalable and cloud-native generative AI framework built for researchers and PyTorch developers working on Large Language Models (LLMs), Multimodal Models (MMs), Automatic Speech Recognition (ASR), Text to Speech (TTS), and Computer Vision (CV) domains. It is designed to help you efficiently create, customize, and deploy new generative AI models by leveraging existing code and pre-trained model checkpoints.

For technical documentation, please see the NeMo Framework User Guide.

What's New in NeMo 2.0

NVIDIA NeMo 2.0 introduces several significant improvements over its predecessor, NeMo 1.0, enhancing flexibility, performance, and scalability.

Overall, these enhancements make NeMo 2.0 a powerful, scalable, and user-friendly framework for AI model development.

[!IMPORTANT]
NeMo 2.0 is currently supported by the LLM (large language model) and VLM (vision language model) collections.

Get Started with NeMo 2.0

LLMs and MMs Training, Alignment, and Customization

All NeMo models are trained with Lightning. Training is automatically scalable to 1000s of GPUs.

When applicable, NeMo models leverage cutting-edge distributed training techniques, incorporating parallelism strategies to enable efficient training of very large models. These techniques include Tensor Parallelism (TP), Pipeline Parallelism (PP), Fully Sharded Data Parallelism (FSDP), Mixture-of-Experts (MoE), and Mixed Precision Training with BFloat16 and FP8, as well as others.

NeMo Transformer-based LLMs and MMs utilize NVIDIA Transformer Engine for FP8 training on NVIDIA Hopper GPUs, while leveraging NVIDIA Megatron Core for scaling Transformer model training.

NeMo LLMs can be aligned with state-of-the-art methods such as SteerLM, Direct Preference Optimization (DPO), and Reinforcement Learning from Human Feedback (RLHF). See NVIDIA NeMo Aligner for more information.

In addition to supervised fine-tuning (SFT), NeMo also supports the latest parameter efficient fine-tuning (PEFT) techniques such as LoRA, P-Tuning, Adapters, and IA3. Refer to the NeMo Framework User Guide for the full list of supported models and techniques.

LLMs and MMs Deployment and Optimization

NeMo LLMs and MMs can be deployed and optimized with NVIDIA NeMo Microservices.

Speech AI

NeMo ASR and TTS models can be optimized for inference and deployed for production use cases with NVIDIA Riva.

NeMo Framework Launcher

[!IMPORTANT]
NeMo Framework Launcher is compatible with NeMo version 1.0 only. NeMo-Run is recommended for launching experiments using NeMo 2.0.

NeMo Framework Launcher is a cloud-native tool that streamlines the NeMo Framework experience. It is used for launching end-to-end NeMo Framework training jobs on CSPs and Slurm clusters.

The NeMo Framework Launcher includes extensive recipes, scripts, utilities, and documentation for training NeMo LLMs. It also includes the NeMo Framework Autoconfigurator, which is designed to find the optimal model parallel configuration for training on a specific cluster.

To get started quickly with the NeMo Framework Launcher, please see the NeMo Framework Playbooks. The NeMo Framework Launcher does not currently support ASR and TTS training, but it will soon.

Get Started with NeMo Framework

Getting started with NeMo Framework is easy. State-of-the-art pretrained NeMo models are freely available on Hugging Face Hub and NVIDIA NGC. These models can be used to generate text or images, transcribe audio, and synthesize speech in just a few lines of code.

We have extensive tutorials that can be run on Google Colab or with our NGC NeMo Framework Container. We also have playbooks for users who want to train NeMo models with the NeMo Framework Launcher.

For advanced users who want to train NeMo models from scratch or fine-tune existing NeMo models, we have a full suite of example scripts that support multi-GPU/multi-node training.

Key Features

Requirements

Developer Documentation

Version Status Description
Latest Documentation Status Documentation of the latest (i.e. main) branch.
Stable Documentation Status Documentation of the stable (i.e. most recent release)

Install NeMo Framework

The NeMo Framework can be installed in a variety of ways, depending on your needs. Depending on the domain, you may find one of the following installation methods more suitable.

Important: We strongly recommended that you start with a base NVIDIA PyTorch container: nvcr.io/nvidia/pytorch:24.02-py3.

Conda

Install NeMo in a fresh Conda environment:

conda create --name nemo python==3.10.12
conda activate nemo

Install PyTorch using their configurator:

conda install pytorch torchvision torchaudio pytorch-cuda=11.8 -c pytorch -c nvidia

The command to install PyTorch may depend on your system. Use the configurator linked above to find the right command for your system.

Then, install NeMo via Pip or from Source. We do not provide NeMo on the conda-forge or any other Conda channel.

Pip

To install the nemo_toolkit, use the following installation method:

apt-get update && apt-get install -y libsndfile1 ffmpeg
pip install Cython packaging
pip install nemo_toolkit['all']

Depending on the shell used, you may need to use the "nemo_toolkit[all]" specifier instead in the above command.

Pip from a Specific Domain

To install a specific domain of NeMo, you must first install the nemo_toolkit using the instructions listed above. Then, you run the following domain-specific commands:

pip install nemo_toolkit['asr']
pip install nemo_toolkit['nlp']
pip install nemo_toolkit['tts']
pip install nemo_toolkit['vision']
pip install nemo_toolkit['multimodal']

Pip from a Source Branch

If you want to work with a specific version of NeMo from a particular GitHub branch (e.g main), use the following installation method:

apt-get update && apt-get install -y libsndfile1 ffmpeg
pip install Cython packaging
python -m pip install git+https://github.com/NVIDIA/NeMo.git@{BRANCH}#egg=nemo_toolkit[all]

Build from Source

If you want to clone the NeMo GitHub repository and contribute to NeMo open-source development work, use the following installation method:

apt-get update && apt-get install -y libsndfile1 ffmpeg
git clone https://github.com/NVIDIA/NeMo
cd NeMo
./reinstall.sh

If you only want the toolkit without the additional Conda-based dependencies, you can replace reinstall.sh with pip install -e . when your PWD is the root of the NeMo repository.

Mac Computers with Apple Silicon

To install NeMo on Mac computers with the Apple M-Series GPU, you need to create a new Conda environment, install PyTorch 2.0 or higher, and then install the nemo_toolkit.

Important: This method is only applicable to the ASR domain.

Run the following code:

# [optional] install mecab using Homebrew, to use sacrebleu for NLP collection
# you can install Homebrew here: https://brew.sh
brew install mecab

# [optional] install pynini using Conda, to use text normalization
conda install -c conda-forge pynini

# install Cython manually
pip install cython packaging

# clone the repo and install in development mode
git clone https://github.com/NVIDIA/NeMo
cd NeMo
pip install 'nemo_toolkit[all]'

# Note that only the ASR toolkit is guaranteed to work on MacBook - so for MacBook use pip install 'nemo_toolkit[asr]'

Windows Computers

To install the Windows Subsystem for Linux (WSL), run the following code in PowerShell:

wsl --install
# [note] If you run wsl --install and see the WSL help text, it means WSL is already installed.

To learn more about installing WSL, refer to Microsoft's official documentation.

After installing your Linux distribution with WSL, two options are available:

Option 1: Open the distribution (Ubuntu by default) from the Start menu and follow the instructions.

Option 2: Launch the Terminal application. Download it from Microsoft's Windows Terminal page if not installed.

Next, follow the instructions for Linux systems, as provided above. For example:

apt-get update && apt-get install -y libsndfile1 ffmpeg
git clone https://github.com/NVIDIA/NeMo
cd NeMo
./reinstall.sh

RNNT

For optimal performance of a Recurrent Neural Network Transducer (RNNT), install the Numba package from Conda.

Run the following code:

conda remove numba
pip uninstall numba
conda install -c conda-forge numba

Install LLMs and MMs Dependencies

If you work with the LLM and MM domains, three additional dependencies are required: NVIDIA Apex, NVIDIA Transformer Engine, and NVIDIA Megatron Core. When working with the [main]{.title-ref} branch, these dependencies may require a recent commit.

The most recent working versions of these dependencies are here:

export apex_commit=810ffae374a2b9cb4b5c5e28eaeca7d7998fca0c
export te_commit=bfe21c3d68b0a9951e5716fb520045db53419c5e
export mcore_commit=02871b4df8c69fac687ab6676c4246e936ce92d0
export nv_pytorch_tag=24.02-py3

When using a released version of NeMo, please refer to the Software Component Versions for the correct versions.

PyTorch Container

We recommended that you start with a base NVIDIA PyTorch container: nvcr.io/nvidia/pytorch:24.02-py3.

If starting with a base NVIDIA PyTorch container, you must first launch the container:

docker run \
  --gpus all \
  -it \
  --rm \
  --shm-size=16g \
  --ulimit memlock=-1 \
  --ulimit stack=67108864 \
  nvcr.io/nvidia/pytorch:$nv_pytorch_tag

Next, you need to install the dependencies.

Apex

NVIDIA Apex is required for LLM and MM domains. Although Apex is pre-installed in the NVIDIA PyTorch container, you may need to update it to a newer version.

To install Apex, run the following code:

git clone https://github.com/NVIDIA/apex.git
cd apex
git checkout $apex_commit
pip install . -v --no-build-isolation --disable-pip-version-check --no-cache-dir --config-settings "--build-option=--cpp_ext --cuda_ext --fast_layer_norm --distributed_adam --deprecated_fused_adam --group_norm"

When attempting to install Apex separately from the NVIDIA PyTorch container, you might encounter an error if the CUDA version on your system is different from the one used to compile PyTorch. To bypass this error, you can comment out the relevant line in the setup file located in the Apex repository on GitHub here: https://github.com/NVIDIA/apex/blob/master/setup.py#L32.

cuda-nvprof is needed to install Apex. The version should match the CUDA version that you are using.

To install cuda-nvprof, run the following code:

conda install -c nvidia cuda-nvprof=11.8

Finally, install the packaging:

pip install packaging

To install the most recent versions of Apex locally, it might be necessary to remove the [pyproject.toml]{.title-ref} file from the Apex directory.

Transformer Engine

NVIDIA Transformer Engine is required for LLM and MM domains. Although the Transformer Engine is pre-installed in the NVIDIA PyTorch container, you may need to update it to a newer version.

The Transformer Engine facilitates training with FP8 precision on NVIDIA Hopper GPUs and introduces many enhancements for the training of Transformer-based models. Refer to Transformer Engine for information.

To install Transformer Engine, run the following code:

git clone https://github.com/NVIDIA/TransformerEngine.git && \
cd TransformerEngine && \
git checkout $te_commit && \
git submodule init && git submodule update && \
NVTE_FRAMEWORK=pytorch NVTE_WITH_USERBUFFERS=1 MPI_HOME=/usr/local/mpi pip install .

Transformer Engine requires PyTorch to be built with at least CUDA 11.8.

Megatron Core

Megatron Core is required for LLM and MM domains. Megatron Core is a library for scaling large Transformer-based models. NeMo LLMs and MMs leverage Megatron Core for model parallelism, transformer architectures, and optimized PyTorch datasets.

To install Megatron Core, run the following code:

git clone https://github.com/NVIDIA/Megatron-LM.git && \
cd Megatron-LM && \
git checkout $mcore_commit && \
pip install . && \
cd megatron/core/datasets && \
make

NeMo Text Processing

NeMo Text Processing, specifically Inverse Text Normalization, is now a separate repository. It is located here: https://github.com/NVIDIA/NeMo-text-processing.

Docker Containers

NeMo containers are launched concurrently with NeMo version updates. NeMo Framework now supports LLMs, MMs, ASR, and TTS in a single consolidated Docker container. You can find additional information about released containers on the NeMo releases page.

To use a pre-built container, run the following code:

docker pull nvcr.io/nvidia/nemo:24.05

To build a nemo container with Dockerfile from a branch, run the following code:

DOCKER_BUILDKIT=1 docker build -f Dockerfile -t nemo:latest

If you choose to work with the main branch, we recommend using NVIDIA's PyTorch container version 23.10-py3 and then installing from GitHub.

docker run --gpus all -it --rm -v <nemo_github_folder>:/NeMo --shm-size=8g \
-p 8888:8888 -p 6006:6006 --ulimit memlock=-1 --ulimit \
stack=67108864 --device=/dev/snd nvcr.io/nvidia/pytorch:23.10-py3

Future Work

The NeMo Framework Launcher does not currently support ASR and TTS training, but it will soon.

Discussions Board

FAQ can be found on the NeMo Discussions board. You are welcome to ask questions or start discussions on the board.

Contribute to NeMo

We welcome community contributions! Please refer to CONTRIBUTING.md for the process.

Publications

We provide an ever-growing list of publications that utilize the NeMo Framework.

To contribute an article to the collection, please submit a pull request to the gh-pages-src branch of this repository. For detailed information, please consult the README located at the gh-pages-src branch.

Blogs

Large Language Models and Multimodal Models
Bria Builds Responsible Generative AI for Enterprises Using NVIDIA NeMo, Picasso (2024/03/06) Bria, a Tel Aviv startup at the forefront of visual generative AI for enterprises now leverages the NVIDIA NeMo Framework. The Bria.ai platform uses reference implementations from the NeMo Multimodal collection, trained on NVIDIA Tensor Core GPUs, to enable high-throughput and low-latency image generation. Bria has also adopted NVIDIA Picasso, a foundry for visual generative AI models, to run inference.

New NVIDIA NeMo Framework Features and NVIDIA H200 (2023/12/06) NVIDIA NeMo Framework now includes several optimizations and enhancements, including: 1) Fully Sharded Data Parallelism (FSDP) to improve the efficiency of training large-scale AI models, 2) Mix of Experts (MoE)-based LLM architectures with expert parallelism for efficient LLM training at scale, 3) Reinforcement Learning from Human Feedback (RLHF) with TensorRT-LLM for inference stage acceleration, and 4) up to 4.2x speedups for Llama 2 pre-training on NVIDIA H200 Tensor Core GPUs.

H200-NeMo-performance

NVIDIA now powers training for Amazon Titan Foundation models (2023/11/28) NVIDIA NeMo Framework now empowers the Amazon Titan foundation models (FM) with efficient training of large language models (LLMs). The Titan FMs form the basis of Amazon’s generative AI service, Amazon Bedrock. The NeMo Framework provides a versatile framework for building, customizing, and running LLMs.

Licenses