--- license: creativeml-openrail-m tags: - text-to-image --- # Karlo v1 alpha Karlo is a text-conditional image generation model based on OpenAI's unCLIP architecture with the improvement over the standard super-resolution model from 64px to 256px, recovering high-frequency details only in the small number of denoising steps. * [Original codebase](https://github.com/kakaobrain/karlo) ## Usage Karlo is available in diffusers! ```python pip install diffusers transformers accelerate safetensors ``` ### Text to image ```python from diffusers import UnCLIPPipeline import torch pipe = UnCLIPPipeline.from_pretrained("kakaobrain/karlo-v1-alpha", torch_dtype=torch.float16) pipe = pipe.to('cuda') prompt = "a high-resolution photograph of a big red frog on a green leaf." image = pipe([prompt]).images[0] image.save("./frog.png") ``` ![img](https://huggingface.co/datasets/patrickvonplaten/images/resolve/main/frog.png) ### Image variation ```python from diffusers import UnCLIPImageVariationPipeline import torch from PIL import Image pipe = UnCLIPImageVariationPipeline.from_pretrained("kakaobrain/karlo-v1-alpha-image-variations", torch_dtype=torch.float16) pipe = pipe.to('cuda') image = Image.open("./frog.png") image = pipe(image).images[0] image.save("./frog-variation.png") ``` ![img](https://huggingface.co/datasets/williamberman/images/resolve/main/frog-variation.png) ## Model Architecture ### Overview Karlo is a text-conditional diffusion model based on unCLIP, composed of prior, decoder, and super-resolution modules. In this repository, we include the improved version of the standard super-resolution module for upscaling 64px to 256px only in 7 reverse steps, as illustrated in the figure below:
In specific, the standard SR module trained by DDPM objective upscales 64px to 256px in the first 6 denoising steps based on the respacing technique. Then, the additional fine-tuned SR module trained by [VQ-GAN](https://compvis.github.io/taming-transformers/)-style loss performs the final reverse step to recover high-frequency details. We observe that this approach is very effective to upscale the low-resolution in a small number of reverse steps. ### Details We train all components from scratch on 115M image-text pairs including COYO-100M, CC3M, and CC12M. In the case of Prior and Decoder, we use ViT-L/14 provided by OpenAI’s [CLIP repository](https://github.com/openai/CLIP). Unlike the original implementation of unCLIP, we replace the trainable transformer in the decoder into the text encoder in ViT-L/14 for efficiency. In the case of the SR module, we first train the model using the DDPM objective in 1M steps, followed by additional 234K steps to fine-tune the additional component. The table below summarizes the important statistics of our components: | | Prior | Decoder | SR | |:------|----:|----:|----:| | CLIP | ViT-L/14 | ViT-L/14 | - | | #param | 1B | 900M | 700M + 700M | | #optimization steps | 1M | 1M | 1M + 0.2M | | #sampling steps | 25 | 50 (default), 25 (fast) | 7 | |Checkpoint links| [ViT-L-14](https://arena.kakaocdn.net/brainrepo/models/karlo-public/v1.0.0.alpha/096db1af569b284eb76b3881534822d9/ViT-L-14.pt), [ViT-L-14 stats](https://arena.kakaocdn.net/brainrepo/models/karlo-public/v1.0.0.alpha/0b62380a75e56f073e2844ab5199153d/ViT-L-14_stats.th), [model](https://arena.kakaocdn.net/brainrepo/models/karlo-public/v1.0.0.alpha/efdf6206d8ed593961593dc029a8affa/decoder-ckpt-step%3D01000000-of-01000000.ckpt) | [model](https://arena.kakaocdn.net/brainrepo/models/karlo-public/v1.0.0.alpha/85626483eaca9f581e2a78d31ff905ca/prior-ckpt-step%3D01000000-of-01000000.ckpt) | [model](https://arena.kakaocdn.net/brainrepo/models/karlo-public/v1.0.0.alpha/4226b831ae0279020d134281f3c31590/improved-sr-ckpt-step%3D1.2M.ckpt) | In the checkpoint links, ViT-L-14 is equivalent to the original version, but we include it for convenience. We also remark that ViT-L-14-stats is required to normalize the outputs of the prior module. ### Evaluation We quantitatively measure the performance of Karlo-v1.0.alpha in the validation split of CC3M and MS-COCO. The table below presents CLIP-score and FID. To measure FID, we resize the image of the shorter side to 256px, followed by cropping it at the center. We set classifier-free guidance scales for prior and decoder to 4 and 8 in all cases. We observe that our model achieves reasonable performance even with 25 sampling steps of decoder. CC3M | Sampling step | CLIP-s (ViT-B/16) | FID (13k from val)| |:------|----:|----:| | Prior (25) + Decoder (25) + SR (7) | 0.3081 | 14.37 | | Prior (25) + Decoder (50) + SR (7) | 0.3086 | 13.95 | MS-COCO | Sampling step | CLIP-s (ViT-B/16) | FID (30k from val)| |:------|----:|----:| | Prior (25) + Decoder (25) + SR (7) | 0.3192 | 15.24 | | Prior (25) + Decoder (50) + SR (7) | 0.3192 | 14.43 | For more information, please refer to the upcoming technical report. ### Training Details This alpha version of Karlo is trained on 115M image-text pairs, including [COYO](https://github.com/kakaobrain/coyo-dataset)-100M high-quality subset, CC3M, and CC12M. For those who are interested in a better version of Karlo trained on more large-scale high-quality datasets, please visit the landing page of our application [B^DISCOVER](https://bdiscover.kakaobrain.com/). ## BibTex If you find this repository useful in your research, please cite: ``` @misc{kakaobrain2022karlo-v1-alpha, title = {Karlo-v1.0.alpha on COYO-100M and CC15M}, author = {Donghoon Lee, Jiseob Kim, Jisu Choi, Jongmin Kim, Minwoo Byeon, Woonhyuk Baek and Saehoon Kim}, year = {2022}, howpublished = {\url{https://github.com/kakaobrain/karlo}}, } ```