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--- |
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license: apache-2.0 |
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tags: |
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- text-to-image |
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- safetensors |
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--- |
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# Lumina-Next-T2I |
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The `Lumina-Next-T2I` model that uses Next-DiT with a 2B parameters model as well as using [Gemma-2B](https://huggingface.co/google/gemma-2b) as a text encoder. Compared with `Lumina-T2I`, it has faster inference speed, richer generation style, and more multilingual support, etc. |
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Our generative model has `Next-DiT` as the backbone, the text encoder is the `Gemma` 2B model, and the VAE uses a version of `sdxl` fine-tuned by stabilityai. |
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- Generation Model: Next-DiT |
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- Text Encoder: [Gemma-2B](https://huggingface.co/google/gemma-2b) |
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- VAE: [stabilityai/sdxl-vae](https://huggingface.co/stabilityai/sdxl-vae) |
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[paper](https://arxiv.org/abs/2405.05945) |
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## ๐ฐ News |
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- [2024-5-28] ๐๐๐ We updated the `Lumina-Next-T2I` model for supporting 2K Resolution image generation. |
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- [2024-5-16] โโโ We have converted the `.pth` weights to `.safetensors` weights. Please pull the latest code to use `demo.py` for inference. |
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- [2024-5-12] ๐๐๐ We release the next version of `Lumina-T2I`, called `Lumina-Next-T2I` for faster and lower memory usage image generation model. |
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## ๐ฎ Model Zoo |
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More checkpoints of our model will be released soon~ |
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| Resolution | Next-DiT Parameter| Text Encoder | Prediction | Download URL | |
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| ---------- | ----------------------- | ------------ | -----------|-------------- | |
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| 1024 | 2B | [Gemma-2B](https://huggingface.co/google/gemma-2b) | Rectified Flow | [hugging face](https://huggingface.co/Alpha-VLLM/Lumina-Next-T2I) | |
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## Installation |
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Before installation, ensure that you have a working ``nvcc`` |
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```bash |
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# The command should work and show the same version number as in our case. (12.1 in our case). |
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nvcc --version |
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``` |
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On some outdated distros (e.g., CentOS 7), you may also want to check that a late enough version of |
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``gcc`` is available |
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```bash |
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# The command should work and show a version of at least 6.0. |
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# If not, consult distro-specific tutorials to obtain a newer version or build manually. |
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gcc --version |
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``` |
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Downloading Lumina-T2X repo from github: |
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```bash |
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git clone https://github.com/Alpha-VLLM/Lumina-T2X |
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``` |
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### 1. Create a conda environment and install PyTorch |
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Note: You may want to adjust the CUDA version [according to your driver version](https://docs.nvidia.com/deploy/cuda-compatibility/#default-to-minor-version). |
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```bash |
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conda create -n Lumina_T2X -y |
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conda activate Lumina_T2X |
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conda install python=3.11 pytorch==2.1.0 torchvision==0.16.0 torchaudio==2.1.0 pytorch-cuda=12.1 -c pytorch -c nvidia -y |
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``` |
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### 2. Install dependencies |
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```bash |
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pip install diffusers fairscale accelerate tensorboard transformers gradio torchdiffeq click |
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``` |
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or you can use |
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```bash |
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cd lumina_next_t2i |
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pip install -r requirements.txt |
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``` |
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### 3. Install ``flash-attn`` |
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```bash |
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pip install flash-attn --no-build-isolation |
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``` |
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### 4. Install [nvidia apex](https://github.com/nvidia/apex) (optional) |
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>[!Warning] |
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> While Apex can improve efficiency, it is *not* a must to make Lumina-T2X work. |
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> |
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> Note that Lumina-T2X works smoothly with either: |
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> + Apex not installed at all; OR |
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> + Apex successfully installed with CUDA and C++ extensions. |
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> |
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> However, it will fail when: |
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> + A Python-only build of Apex is installed. |
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> |
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> If the error `No module named 'fused_layer_norm_cuda'` appears, it typically means you are using a Python-only build of Apex. To resolve this, please run `pip uninstall apex`, and Lumina-T2X should then function correctly. |
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You can clone the repo and install following the official guidelines (note that we expect a full |
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build, i.e., with CUDA and C++ extensions) |
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```bash |
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pip install ninja |
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git clone https://github.com/NVIDIA/apex |
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cd apex |
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# if pip >= 23.1 (ref: https://pip.pypa.io/en/stable/news/#v23-1) which supports multiple `--config-settings` with the same key... |
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pip install -v --disable-pip-version-check --no-cache-dir --no-build-isolation --config-settings "--build-option=--cpp_ext" --config-settings "--build-option=--cuda_ext" ./ |
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# otherwise |
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pip install -v --disable-pip-version-check --no-cache-dir --no-build-isolation --global-option="--cpp_ext" --global-option="--cuda_ext" ./ |
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``` |
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## Inference |
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To ensure that our generative model is ready to use right out of the box, we provide a user-friendly CLI program and a locally deployable Web Demo site. |
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### CLI |
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1. Install Lumina-Next-T2I |
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```bash |
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pip install -e . |
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``` |
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2. Prepare the pretrained model |
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โญโญ (Recommanded) you can use huggingface_cli downloading our model: |
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```bash |
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huggingface-cli download --resume-download Alpha-VLLM/Lumina-Next-T2I --local-dir /path/to/ckpt |
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``` |
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or using git for cloning the model you want to use: |
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```bash |
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git clone https://huggingface.co/Alpha-VLLM/Lumina-Next-T2I |
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``` |
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1. Setting your personal inference configuration |
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Update your own personal inference settings to generate different styles of images, checking `config/infer/config.yaml` for detailed settings. Detailed config structure: |
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> `/path/to/ckpt` should be a directory containing `consolidated*.pth` and `model_args.pth` |
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```yaml |
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- settings: |
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model: |
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ckpt: "/path/to/ckpt" # if ckpt is "", you should use `--ckpt` for passing model path when using `lumina` cli. |
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ckpt_lm: "" # if ckpt is "", you should use `--ckpt_lm` for passing model path when using `lumina` cli. |
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token: "" # if LLM is a huggingface gated repo, you should input your access token from huggingface and when token is "", you should `--token` for accessing the model. |
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transport: |
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path_type: "Linear" # option: ["Linear", "GVP", "VP"] |
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prediction: "velocity" # option: ["velocity", "score", "noise"] |
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loss_weight: "velocity" # option: [None, "velocity", "likelihood"] |
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sample_eps: 0.1 |
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train_eps: 0.2 |
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ode: |
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atol: 1e-6 # Absolute tolerance |
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rtol: 1e-3 # Relative tolerance |
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reverse: false # option: true or false |
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likelihood: false # option: true or false |
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infer: |
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resolution: "1024x1024" # option: ["1024x1024", "512x2048", "2048x512", "(Extrapolation) 1664x1664", "(Extrapolation) 1024x2048", "(Extrapolation) 2048x1024"] |
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num_sampling_steps: 60 # range: 1-1000 |
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cfg_scale: 4. # range: 1-20 |
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solver: "euler" # option: ["euler", "dopri5", "dopri8"] |
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t_shift: 4 # range: 1-20 (int only) |
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ntk_scaling: true # option: true or false |
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proportional_attn: true # option: true or false |
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seed: 0 # rnage: any number |
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``` |
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- model: |
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- `ckpt`: lumina-next-t2i checkpoint path from [huggingface repo](https://huggingface.co/Alpha-VLLM/Lumina-Next-T2I) containing `consolidated*.pth` and `model_args.pth`. |
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- `ckpt_lm`: LLM checkpoint. |
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- `token`: huggingface access token for accessing gated repo. |
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- transport: |
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- `path_type`: the type of path for transport: 'Linear', 'GVP' (Geodesic Vector Pursuit), or 'VP' (Vector Pursuit). |
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- `prediction`: the prediction model for the transport dynamics. |
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- `loss_weight`: the weighting of different components in the loss function, can be 'velocity' for dynamic modeling, 'likelihood' for statistical consistency, or None for no weighting |
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- `sample_eps`: sampling in the transport model. |
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- `train_eps`: training to stabilize the learning process. |
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- ode: |
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- `atol`: Absolute tolerance for the ODE solver. (options: ["Linear", "GVP", "VP"]) |
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- `rtol`: Relative tolerance for the ODE solver. (option: ["velocity", "score", "noise"]) |
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- `reverse`: run the ODE solver in reverse. (option: [None, "velocity", "likelihood"]) |
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- `likelihood`: Enable calculation of likelihood during the ODE solving process. |
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- infer |
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- `resolution`: generated image resolution. |
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- `num_sampling_steps`: sampling step for generating image. |
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- `cfg_scale`: classifier-free guide scaling factor |
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- `solver`: solver for image generation. |
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- `t_shift`: time shift factor. |
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- `ntk_scaling`: ntk rope scaling factor. |
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- `proportional_attn`: Whether to use proportional attention. |
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- `seed`: random initialization seeds. |
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1. Run with CLI |
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inference command: |
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```bash |
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lumina_next infer -c <config_path> <caption_here> <output_dir> |
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``` |
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e.g. Demo command: |
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```bash |
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cd lumina_next_t2i |
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lumina_next infer -c "config/infer/settings.yaml" "a snow man of ..." "./outputs" |
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``` |
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### Web Demo |
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To host a local gradio demo for interactive inference, run the following command: |
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```bash |
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# `/path/to/ckpt` should be a directory containing `consolidated*.pth` and `model_args.pth` |
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# default |
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python -u demo.py --ckpt "/path/to/ckpt" |
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# the demo by default uses bf16 precision. to switch to fp32: |
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python -u demo.py --ckpt "/path/to/ckpt" --precision fp32 |
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# use ema model |
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python -u demo.py --ckpt "/path/to/ckpt" --ema |
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``` |