NVlabs / edm2

Analyzing and Improving the Training Dynamics of Diffusion Models
Tero Karras, Miika Aittala, Jaakko Lehtinen, Janne Hellsten, Timo Aila, Samuli Laine
https://arxiv.org/abs/2312.02696

Abstract: Diffusion models currently dominate the field of data-driven image synthesis with their unparalleled scaling to large datasets. In this paper, we identify and rectify several causes for uneven and ineffective training in the popular ADM diffusion model architecture, without altering its high-level structure. Observing uncontrolled magnitude changes and imbalances in both the network activations and weights over the course of training, we redesign the network layers to preserve activation, weight, and update magnitudes on expectation. We find that systematic application of this philosophy eliminates the observed drifts and imbalances, resulting in considerably better networks at equal computational complexity. Our modifications improve the previous record FID of 2.41 in ImageNet-512 synthesis to 1.81, achieved using fast deterministic sampling.
As an independent contribution, we present a method for setting the exponential moving average (EMA) parameters post-hoc, i.e., after completing the training run. This allows precise tuning of EMA length without the cost of performing several training runs, and reveals its surprising interactions with network architecture, training time, and guidance.

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• Linux and Windows are supported, but we recommend Linux for performance and compatibility reasons.
• 1+ high-end NVIDIA GPU for sampling and 8+ GPUs for training. We have done all testing and development using V100 and A100 GPUs.
• 64-bit Python 3.9 and PyTorch 2.1 (or later). See https://pytorch.org for PyTorch install instructions.
• Other Python libraries: pip install click Pillow psutil requests scipy tqdm diffusers==0.26.3 accelerate==0.27.2
• For downloading the raw snapshots needed for post-hoc EMA reconstruction, we recommend using Rclone.

Docker

For convenience, we provide a Dockerfile with the required dependencies. You can use it as follows:

# Build Docker image
docker build --tag edm2:latest .

# Run generate_images.py using Docker
docker run --gpus all -it --rm --user $(id -u):$(id -g) \
    -v `pwd`:/scratch --workdir /scratch -e HOME=/scratch \
    edm2:latest \
    python generate_images.py --preset=edm2-img512-s-guid-dino --outdir=out

If you hit an error, please ensure you have correctly installed the NVIDIA container runtime. See NVIDIA PyTorch container release notes for driver compatibility details.

Breakdown of the docker run command line:

• --gpus all -it --rm --user $(id -u):$(id -g): With all GPUs enabled, run an interactive session with current user's UID/GID to avoid Docker writing files as root.
• -v `pwd`:/scratch --workdir /scratch: Mount current running dir (e.g., the top of this git repo on your host machine) to /scratch in the container and use that as the current working dir.
• -e HOME=/scratch: Specify where to cache temporary files. If you want more fine-grained control, you can instead set DNNLIB_CACHE_DIR (for pre-trained model download cache). You want these cache dirs to reside on persistent volumes so that their contents are retained across multiple docker run invocations.

We provide pre-trained models for our proposed EDM2 configuration (config G) for different model sizes trained with ImageNet-512 and ImageNet-64. To generate images using a given model, run:

# Generate a couple of images and save them as out/*.png
python generate_images.py --preset=edm2-img512-s-guid-dino --outdir=out

The above command automatically downloads the necessary models and caches them under $HOME/.cache/dnnlib, which can be overridden by setting the DNNLIB_CACHE_DIR environment variable. The --preset=edm2-img512-s-guid-dino option indicates that we will be using the S-sized EDM2 model, trained with ImageNet-512 and sampled using guidance, with EMA length and guidance strength chosen to minimize FD_DINOv2. The following presets are supported:

edm2-img512-{xs|s|m|l|xl|xxl}-fid        # Table 2, no CFG
edm2-img512-{xs|s|m|l|xl|xxl}-guid-fid   # Table 2, w/CFG
edm2-img512-{xs|s|m|l|xl|xxl}-dino       # Table 5, no CFG
edm2-img512-{xs|s|m|l|xl|xxl}-guid-dino  # Table 5, w/CFG
edm2-img64-{s|m|l|xl}-fid                # Table 3

Each of these maps to a specific set of options that point to the models in https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/. For example, --preset=edm2-img512-xxl-guid-dino is equivalent to:

# Expanded command line for --preset=edm2-img512-xxl-guid-dino
python generate_images.py \
    --net=https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/edm2-img512-xxl-0939524-0.015.pkl \
    --gnet=https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/edm2-img512-xs-uncond-2147483-0.015.pkl \
    --guidance=1.7 \
    --outdir=out

In other words, we will use the XXL-sized conditional model at 939524 kimg and EMA length 0.015, and guide it with respect to the XS-sized unconditional model at 2147483 kimg with guidance strength 1.7. For further details, see config_presets in generate_images.py.

The computational cost of a given model can be estimated using count_flops.py:

# Calculate FLOPs for a given model
python count_flops.py \
    https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/edm2-img512-s-2147483-0.130.pkl

To calculate FID and FD_DINOv2, we first need to generate 50,000 random images. This can be quite time-consuming in practice, so it makes sense to distribute the workload across multiple GPUs. This can be done by launching generate_images.py through torchrun:

# Generate 50000 images using 8 GPUs and save them as out/*/*.png
torchrun --standalone --nproc_per_node=8 generate_images.py \
    --preset=edm2-img512-s-guid-fid --outdir=out --subdirs --seeds=0-49999

Alternatively, generate_images.py can be launched as a multi-GPU or multi-node job in a compute cluster. This should work out-of-the-box as long as the cluster environment spawns a separate process for each GPU and populates the necessary environment variables. For further details, please refer to the torchrun documetation.

Having generated 50,000 images, FID and FD_DINOv2 can then be calculated using calculate_metrics.py:

# Calculate metrics for a random subset of 50000 images in out/
python calculate_metrics.py calc --images=out \
    --ref=https://nvlabs-fi-cdn.nvidia.com/edm2/dataset-refs/img512.pkl

Here, the --ref option points to pre-computed reference statistics for the dataset that the model was originally trained with. The necessary reference statistics for our pre-trained models are available at https://nvlabs-fi-cdn.nvidia.com/edm2/dataset-refs/.

Note that the numerical values of the metrics vary across different random seeds and are highly sensitive to the number of images. By default, calculate_metrics.py uses 50,000 generated images, in line with established best practices. Providing fewer images will result in an error, whereas providing more will use a random subset. To reduce the effect of random variation, we recommend repeating the calculation multiple times with different random seeds, e.g., --seeds=0-49999, --seeds=50000-99999, and --seeds=100000-149999. In our paper, we calculated each metric multiple times and reported the minimum.

When performing larger sweeps over, say, EMA lengths or training snapshots, it may be impractical to use generate_images.py as outlined above. As an alternative, the metrics can also be calculated directly for a given network pickle, generating the necessary images on the fly:

# Calculate metrics directly for a given model without saving any images
torchrun --standalone --nproc_per_node=8 calculate_metrics.py gen \
    --net=https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/edm2-img512-s-2147483-0.130.pkl \
    --ref=https://nvlabs-fi-cdn.nvidia.com/edm2/dataset-refs/img512.pkl \
    --seed=123456789

We also provide the necessary APIs to do these kinds of operations programmatically from external Python scripts. For further details, see gen() in calculate_metrics.py.

The models in https://nvlabs-fi-cdn.nvidia.com/edm2/posthoc-reconstructions/ correspond to specific choices for the EMA length. In addition, we also provide the raw snapshots for each training run in https://nvlabs-fi-cdn.nvidia.com/edm2/raw-snapshots/ that can be used to reconstruct arbitrary EMA profiles.

Note that the raw snapshots can take up a considerable amount of disk space. In the paper, we saved snapshots every 8Mi (= 8 mebi = 8×2²⁰) training images, corresponding to 118–635 GB of data per training run depending on model size. In https://nvlabs-fi-cdn.nvidia.com/edm2/raw-snapshots/, we provide the snapshots at 64Mi intervals instead, corresponding to 15–79 GB per training run. We have done extensive testing to verify that this is sufficient for accurate reconstruction.

To reconstruct new EMA profiles, the first step is to download the raw snapshots corresponding to a given training run. We recommend using Rclone for this:

# Download raw snapshots for the pre-trained edm2-img512-xs model
rclone copy --progress --http-url https://nvlabs-fi-cdn.nvidia.com/edm2 \
    :http:raw-snapshots/edm2-img512-xs/ raw-snapshots/edm2-img512-xs/

The above command downloads 64 network pickles, 238 MB each, yielding 14.8 GB in total. Once the download is complete, new EMA profiles can be reconstructed using reconstruct_phema.py:

# Reconstruct a new EMA profile with std=0.150
python reconstruct_phema.py --indir=raw-snapshots/edm2-img512-xs \
    --outdir=out --outstd=0.150

This reads each of the input pickles once and saves the reconstructed model at out/phema-2147483-0.150.pkl, to be used with, e.g., generate_images.py. To perform a sweep over EMA length, it is also possible reconstruct multiple EMA profiles simultaneously:

# Reconstruct a set of 31 EMA profiles, streaming over the input data 4 times
python reconstruct_phema.py --indir=raw-snapshots/edm2-img512-xs \
    --outdir=out --outstd=0.010,0.015,...,0.250 --batch=8

See python reconstruct_phema.py --help for the full list of options.

Note that our post-hoc EMA approach is not specific to diffusion models in any way — it can be applied to other kinds of deep learning models as well. To try it out in your own training runs, you can (1) include training/phema.py in your codebase, (2) modify your training loop to use phema.PowerFunctionEMA, and (3) take a copy of reconstruct_phema.py and modify it to suit your needs.

Datasets are stored as uncompressed ZIP archives containing uncompressed PNG or NPY files, along with a metadata file dataset.json for labels. When using latent diffusion, it is necessary to create two different versions of a given dataset: the original RGB version, used for evaluation, and a VAE-encoded latent version, used for training.

To set up ImageNet-512:

1. Download the ILSVRC2012 data archive from Kaggle and extract it somewhere, e.g., downloads/imagenet.

2. Crop and resize the images to create the original RGB dataset:

# Convert raw ImageNet data to a ZIP archive at 512x512 resolution
python dataset_tool.py convert --source=downloads/imagenet/ILSVRC/Data/CLS-LOC/train \
    --dest=datasets/img512.zip --resolution=512x512 --transform=center-crop-dhariwal

3. Run the images through a pre-trained VAE encoder to create the corresponding latent dataset:

# Convert the pixel data to VAE latents
python dataset_tool.py encode --source=datasets/img512.zip \
    --dest=datasets/img512-sd.zip

4. Calculate reference statistics for the original RGB dataset, to be used with calculate_metrics.py:

# Compute dataset reference statistics for calculating metrics
python calculate_metrics.py ref --data=datasets/img512.zip \
    --dest=dataset-refs/img512.pkl

New models can be trained using train_edm2.py. For example, to train an XS-sized conditional model for ImageNet-512 using the same hyperparameters as in our paper, run:

# Train XS-sized model for ImageNet-512 using 8 GPUs
torchrun --standalone --nproc_per_node=8 train_edm2.py \
    --outdir=training-runs/00000-edm2-img512-xs \
    --data=datasets/img512-sd.zip \
    --preset=edm2-img512-xs \
    --batch-gpu=32

This example performs single-node training using 8 GPUs, but in practice, we recommend using at least 32 A100 GPUs, i.e., 4 DGX nodes. Note that training large models may easily run out of GPU memory, depending on the number of GPUs and the available VRAM. The best way to avoid this is to limit the per-GPU batch size using gradient accumulation. In the above example, the total batch size is 2048 images, i.e., 256 per GPU, but we limit it to 32 per GPU by specifying --batch-gpu=32. Modifying --batch-gpu is safe in the sense that it has no interaction with the other hyperparameters, whereas modifying the total batch size would also necessitate adjusting, e.g., the learning rate.

By default, the training script prints status every 128Ki (= 128 kibi = 128×2¹⁰) training images (controlled by --status), saves network snapshots every 8Mi (= 8×2²⁰) training images (controlled by --snapshot), and dumps training checkpoints every 128Mi training images (controlled by --checkpoint). The status is saved in log.txt (one-line summary) and stats.json (comprehensive set of statistics). The network snapshots are saved in network-snapshot-*.pkl, and they can be used directly with, e.g., generate_images.py and reconstruct_phema.py.

The training checkpoints, saved in training-state-*.pt, can be used to resume the training at a later time. When the training script starts, it will automatically look for the highest-numbered checkpoint and load it if available. To resume training, simply run the same train_edm2.py command line again — it is important to use the same set of options to avoid accidentally changing the hyperparameters mid-training. If you wish to have the ability to suspend the training at any time so that no progress is lost, you can modify the should_suspend() function in torch_utils/distributed.py to implement the desired signaling protocol.

See python train_edm2.py --help for the full list of options.

Copyright © 2024, NVIDIA CORPORATION & AFFILIATES. All rights reserved.

All material, including source code and pre-trained models, is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

@inproceedings{Karras2024edm2,
  title     = {Analyzing and Improving the Training Dynamics of Diffusion Models},
  author    = {Tero Karras and Miika Aittala and Jaakko Lehtinen and
               Janne Hellsten and Timo Aila and Samuli Laine},
  booktitle = {Proc. CVPR},
  year      = {2024},
}

This is a research reference implementation and is treated as a one-time code drop. As such, we do not accept outside code contributions in the form of pull requests.

We thank Eric Chan, Qinsheng Zhang, Erik Härkönen, Tuomas Kynkäänniemi, Arash Vahdat, Ming-Yu Liu, and David Luebke for discussions and comments, and Tero Kuosmanen and Samuel Klenberg for maintaining our compute infrastructure.