IF by DeepFloyd Lab at StabilityAI
We introduce DeepFloyd IF, a novel state-of-the-art open-source text-to-image model with a high degree of photorealism and language understanding. DeepFloyd IF is a modular composed of a frozen text encoder and three cascaded pixel diffusion modules: a base model that generates 64x64 px image based on text prompt and two super-resolution models, each designed to generate images of increasing resolution: 256x256 px and 1024x1024 px. All stages of the model utilize a frozen text encoder based on the T5 transformer to extract text embeddings, which are then fed into a UNet architecture enhanced with cross-attention and attention pooling. The result is a highly efficient model that outperforms current state-of-the-art models, achieving a zero-shot FID score of 6.66 on the COCO dataset. Our work underscores the potential of larger UNet architectures in the first stage of cascaded diffusion models and depicts a promising future for text-to-image synthesis.
Inspired by Photorealistic Text-to-Image Diffusion Models with Deep Language Understanding
- 16GB vRAM for IF-I-XL (4.3B text to 64x64 base module) & IF-II-L (1.2B to 256x256 upscaler module)
- 24GB vRAM for IF-I-XL (4.3B text to 64x64 base module) & IF-II-L (1.2B to 256x256 upscaler module) & Stable x4 (to 1024x1024 upscaler)
xformersand set env variableFORCE_MEM_EFFICIENT_ATTN=1
pip install deepfloyd_if==1.0.2rc0
pip install xformers==0.0.16
pip install git+https://github.com/openai/CLIP.git --no-deps
The Dream, Style Transfer, Super Resolution or Inpainting modes are avaliable in a Jupyter Notebook here.
IF is also integrated with the π€ Hugging Face Diffusers library.
Diffusers runs each stage individually allowing the user to customize the image generation process as well as allowing to inspect intermediate results easily.
Before you can use IF, you need to accept its usage conditions. To do so:
- Make sure to have a Hugging Face account and be loggin in
- Accept the license on the model card of DeepFloyd/IF-I-XL-v1.0
- Make sure to login locally. Install
huggingface_hub
pip install huggingface_hub --upgraderun the login function in a Python shell
from huggingface_hub import login
login()and enter your Hugging Face Hub access token.
Next we install diffusers and dependencies:
pip install diffusers accelerate transformers safetensorsAnd we can now run the model locally.
By default diffusers makes use of model cpu offloading to run the whole IF pipeline with as little as 14 GB of VRAM.
If you are using torch>=2.0.0, make sure to delete all enable_xformers_memory_efficient_attention()
functions.
from diffusers import DiffusionPipeline
from diffusers.utils import pt_to_pil
import torch
# stage 1
stage_1 = DiffusionPipeline.from_pretrained("DeepFloyd/IF-I-XL-v1.0", variant="fp16", torch_dtype=torch.float16)
stage_1.enable_xformers_memory_efficient_attention() # remove line if torch.__version__ >= 2.0.0
stage_1.enable_model_cpu_offload()
# stage 2
stage_2 = DiffusionPipeline.from_pretrained(
"DeepFloyd/IF-II-L-v1.0", text_encoder=None, variant="fp16", torch_dtype=torch.float16
)
stage_2.enable_xformers_memory_efficient_attention() # remove line if torch.__version__ >= 2.0.0
stage_2.enable_model_cpu_offload()
# stage 3
safety_modules = {"feature_extractor": stage_1.feature_extractor, "safety_checker": stage_1.safety_checker, "watermarker": stage_1.watermarker}
stage_3 = DiffusionPipeline.from_pretrained("stabilityai/stable-diffusion-x4-upscaler", **safety_modules, torch_dtype=torch.float16)
stage_3.enable_xformers_memory_efficient_attention() # remove line if torch.__version__ >= 2.0.0
stage_3.enable_model_cpu_offload()
prompt = 'a photo of a kangaroo wearing an orange hoodie and blue sunglasses standing in front of the eiffel tower holding a sign that says "very deep learning"'
# text embeds
prompt_embeds, negative_embeds = stage_1.encode_prompt(prompt)
generator = torch.manual_seed(0)
# stage 1
image = stage_1(prompt_embeds=prompt_embeds, negative_prompt_embeds=negative_embeds, generator=generator, output_type="pt").images
pt_to_pil(image)[0].save("./if_stage_I.png")
# stage 2
image = stage_2(
image=image, prompt_embeds=prompt_embeds, negative_prompt_embeds=negative_embeds, generator=generator, output_type="pt"
).images
pt_to_pil(image)[0].save("./if_stage_II.png")
# stage 3
image = stage_3(prompt=prompt, image=image, generator=generator, noise_level=100).images
image[0].save("./if_stage_III.png")There are multiple ways to speed up the inference time and lower the memory consumption even more with diffusers. To do so, please have a look at the Diffusers docs:
For more in-detail information about how to use IF, please have a look at the IF blog post and the documentation π.
Diffusers dreambooth scripts also supports fine-tuning π¨ IF. With parameter efficient finetuning, you can add new concepts to IF with a single GPU and ~28 GB VRAM.
from deepfloyd_if.modules import IFStageI, IFStageII, StableStageIII
from deepfloyd_if.modules.t5 import T5Embedder
device = 'cuda:0'
if_I = IFStageI('IF-I-XL-v1.0', device=device)
if_II = IFStageII('IF-II-L-v1.0', device=device)
if_III = StableStageIII('stable-diffusion-x4-upscaler', device=device)
t5 = T5Embedder(device="cpu")Dream is the text-to-image mode of the IF model
from deepfloyd_if.pipelines import dream
prompt = 'ultra close-up color photo portrait of rainbow owl with deer horns in the woods'
count = 4
result = dream(
t5=t5, if_I=if_I, if_II=if_II, if_III=if_III,
prompt=[prompt]*count,
seed=42,
if_I_kwargs={
"guidance_scale": 7.0,
"sample_timestep_respacing": "smart100",
},
if_II_kwargs={
"guidance_scale": 4.0,
"sample_timestep_respacing": "smart50",
},
if_III_kwargs={
"guidance_scale": 9.0,
"noise_level": 20,
"sample_timestep_respacing": "75",
},
)
if_III.show(result['III'], size=14)
In Style Transfer mode, the output of your prompt comes out at the style of the support_pil_img
from deepfloyd_if.pipelines import style_transfer
result = style_transfer(
t5=t5, if_I=if_I, if_II=if_II,
support_pil_img=raw_pil_image,
style_prompt=[
'in style of professional origami',
'in style of oil art, Tate modern',
'in style of plastic building bricks',
'in style of classic anime from 1990',
],
seed=42,
if_I_kwargs={
"guidance_scale": 10.0,
"sample_timestep_respacing": "10,10,10,10,10,10,10,10,0,0",
'support_noise_less_qsample_steps': 5,
},
if_II_kwargs={
"guidance_scale": 4.0,
"sample_timestep_respacing": 'smart50',
"support_noise_less_qsample_steps": 5,
},
)
if_I.show(result['II'], 1, 20)
For super-resolution, users can run IF-II and IF-III or 'Stable x4' on an image that was not necessarely generated by IF (two cascades):
from deepfloyd_if.pipelines import super_resolution
middle_res = super_resolution(
t5,
if_III=if_II,
prompt=['woman with a blue headscarf and a blue sweaterp, detailed picture, 4k dslr, best quality'],
support_pil_img=raw_pil_image,
img_scale=4.,
img_size=64,
if_III_kwargs={
'sample_timestep_respacing': 'smart100',
'aug_level': 0.5,
'guidance_scale': 6.0,
},
)
high_res = super_resolution(
t5,
if_III=if_III,
prompt=[''],
support_pil_img=middle_res['III'][0],
img_scale=4.,
img_size=256,
if_III_kwargs={
"guidance_scale": 9.0,
"noise_level": 20,
"sample_timestep_respacing": "75",
},
)
show_superres(raw_pil_image, high_res['III'][0])
from deepfloyd_if.pipelines import inpainting
result = inpainting(
t5=t5, if_I=if_I,
if_II=if_II,
if_III=if_III,
support_pil_img=raw_pil_image,
inpainting_mask=inpainting_mask,
prompt=[
'oil art, a man in a hat',
],
seed=42,
if_I_kwargs={
"guidance_scale": 7.0,
"sample_timestep_respacing": "10,10,10,10,10,0,0,0,0,0",
'support_noise_less_qsample_steps': 0,
},
if_II_kwargs={
"guidance_scale": 4.0,
'aug_level': 0.0,
"sample_timestep_respacing": '100',
},
if_III_kwargs={
"guidance_scale": 9.0,
"noise_level": 20,
"sample_timestep_respacing": "75",
},
)
if_I.show(result['I'], 2, 3)
if_I.show(result['II'], 2, 6)
if_I.show(result['III'], 2, 14)
The link to download the weights as well as the model cards will be available soon on each model of the model zoo
| Name | Cascade | Params | FID | Batch size | Steps |
|---|---|---|---|---|---|
| IF-I-M | I | 400M | 8.86 | 3072 | 2.5M |
| IF-I-L | I | 900M | 8.06 | 3200 | 3.0M |
| IF-I-XL* | I | 4.3B | 6.66 | 3072 | 2.42M |
| IF-II-M | II | 450M | - | 1536 | 2.5M |
| IF-II-L* | II | 1.2B | - | 1536 | 2.5M |
| IF-III-L* (soon) | III | 700M | - | 3072 | 1.25M |
*best modules
FID = 6.66
The code in this repository is released under the bespoke license (see added point two).
The weights will be available soon via the DeepFloyd organization at Hugging Face and have their own LICENSE.
Disclaimer: The initial release of the IF model is under a restricted research-purposes-only license temporarily to gather feedback, and after that we intend to release a fully open-source model in line with other Stability AI models.
The models available in this codebase have known limitations and biases. Please refer to the model card for more information.
- Alex Shonenkov GitHub | Linktr
- Misha Konstantinov GitHub | Twitter
- Daria Bakshandaeva GitHub | Twitter
- Christoph Schuhmann GitHub | Twitter
- Ksenia Ivanova GitHub | Twitter
- Nadiia Klokova GitHub | Twitter
Special thanks to StabilityAI and its CEO Emad Mostaque for invaluable support, providing GPU compute and infrastructure to train the models (our gratitude goes to Richard Vencu); thanks to LAION and Christoph Schuhmann in particular for contribution to the project and well-prepared datasets; thanks to Huggingface teams for optimizing models' speed and memory consumption during inference, creating demos and giving cool advice!
- The Biggest Thanks @ApolinΓ‘rio, for ideas, consultations, help and support on all stages to make IF available in open-source; for writing a lot of documentation and instructions; for creating a friendly atmosphere in difficult moments π¦;
- Thanks, @patrickvonplaten, for improving loading time of unet models by 80%; for integration Stable-Diffusion-x4 as native pipeline πͺ;
- Thanks, @williamberman and @patrickvonplaten for diffusers integration π;
- Thanks, @hysts and @ApolinΓ‘rio for creating the best gradio demo with IF π;
- Thanks, @Dango233, for adapting IF with xformers memory efficient attention πͺ;