canvit-pytorch 0.1.7

CanViT (Canvas Vision Transformer) -- PyTorch

CanViT (Canvas Vision Transformer) -- PyTorch

Yohaï-Eliel Berreby, Sabrina Du, Audrey Durand, B. Suresh Krishna

Reference PyTorch implementation of CanViT (Canvas Vision Transformer).

For details, see our preprint: CanViT: Toward Active-Vision Foundation Models.

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CanViT is a scalable recurrent architecture for fine-grained vision, and the first Active-Vision Foundation Model (AVFM): a foundation model for active vision that is both task-agnostic and policy-agnostic.

CanViT processes scenes through sequences of localized glimpses, integrating observations over time into a persistent scene-wide latent workspace — the canvas — via Canvas Attention, an efficient asymmetric cross-attention mechanism which is based on Scene-Relative Rotary Position Embeddings and eliminates canvas-side QKVO projections.

CanViT-B is pretrained on 1 billion glimpses taken from 13.2 million ImageNet-21k scenes, via policy-agnostic passive-to-active dense distillation from a frozen high-resolution DINOv3 ViT-B teacher, without human annotations.

CanViT's scene-wide output features at each timestep are linearly decodable into dense predictions without post-hoc upscaling; a frozen-weights CanViT-B evaluated with linear probing outperforms all prior dense active vision models by a wide margin on ADE20K scene parsing, at a fraction of the cost, while offering significantly greater flexibility.

CanViT generalizes natively across policies, sequence length, glimpse size and canvas size, enabling high-resolution and long-horizon continual pretraining alongside task-specific policy learning.

CanViT enables low-latency high-resolution dense vision, running at hundreds of sequential frames per second on commodity hardware.

Checkpoints

We release checkpoints on HuggingFace under the canvit namespace.

Checkpoint	Description
canvitb16-add-vpe-pretrain-g128px-s512px-in21k-dv3b16-2026-02-02	Pretrained on IN21K via dense distillation from DINOv3
canvitb16-add-vpe-finetune-g128px-s512px-in1k-2026-04-06	Finetuned for ImageNet-1K classification (trained on TPU v6e via torch_xla)

Quickstart

We recommend uv for dependency management.

uv add canvit-pytorch

from canvit_pytorch import CanViTForPretrainingHFHub, Viewpoint, sample_at_viewpoint
from canvit_pytorch.preprocess import preprocess
from PIL import Image
import torch

# CanViT is integrated with the HuggingFace Hub.
model = CanViTForPretrainingHFHub.from_pretrained(
    "canvit/canvitb16-add-vpe-pretrain-g128px-s512px-in21k-dv3b16-2026-02-02"
).eval()

# Replace with the image of your choice
image = Image.open("test_data/Cat03.jpg").convert("RGB")
image = preprocess(512)(image)
image = image.unsqueeze(0)  # [1, 3, 512, 512]

# CanViT is a recurrent model.
state = model.init_state(batch_size=1, canvas_grid_size=32)

# Let's process a first glimpse: centered, zoomed-out.
# You can use any viewpoint you like, as long as it is within bounds.
# CanViT was trained on viewpoints covering 0.25% to 100%
# of a scene's surface area.
with torch.inference_mode():
    vp = Viewpoint.full_scene(batch_size=1, device=image.device)
    glimpse = sample_at_viewpoint(spatial=image, viewpoint=vp, glimpse_size_px=128)
    out = model(glimpse=glimpse, state=state, viewpoint=vp)

# Let's inspect the structure of what we get back.
# The canvas contains the model's working understanding of
# the scene at any given time, and is linearly decodable 
# into dense predictions upon token-wise LayerNorm.
# See `demos/basic.py` for how to visualize the canvas.
canvas_spatial = model.get_spatial(out.state.canvas)  # [1, 1024, 1024]
canvas_spatial = canvas_spatial.unflatten(1, (32, 32))  # [1, 32, 32, 1024] — spatial feature map
out.state.recurrent_cls  # [1, 1, 768] — global CLS token
out.local_patches        # [1, 64, 768] — glimpse patch features

# Now let's do a second glimpse: zoom into the top-left quadrant
# You can do this repeatedly: CanViT is recurrent with a large but constant-size canvas.
with torch.inference_mode():
    vp2 = Viewpoint(centers=torch.tensor([[-.5, -.5]]), scales=torch.tensor([.5]))
    glimpse2 = sample_at_viewpoint(spatial=image, viewpoint=vp2, glimpse_size_px=128)
    out2 = model(glimpse=glimpse2, state=out.state, viewpoint=vp2)
    
# You can use CanViT with frozen weights, fine-tune it, learn a policy on top...
# Or pretrain your own; it's fast.
# Start building!

ImageNet-1K Classification

CanViTForImageClassification provides a unified interface for classification. Two construction paths, same forward pass:

From a finetuned checkpoint (backbone + head trained on IN1K):

from canvit_pytorch import CanViTForImageClassification, Viewpoint, sample_at_viewpoint
from canvit_pytorch.preprocess import preprocess
from PIL import Image
import torch

clf = CanViTForImageClassification.from_pretrained(
    "canvit/canvitb16-add-vpe-finetune-g128px-s512px-in1k-2026-04-06"
).eval()

From the pretrained (frozen) backbone + a DINOv3 linear probe:

clf = CanViTForImageClassification.from_pretrained_with_probe(
    pretrained_repo="canvit/canvitb16-add-vpe-pretrain-g128px-s512px-in21k-dv3b16-2026-02-02",
    probe_repo="yberreby/dinov3-vitb16-lvd1689m-in1k-512x512-linear-clf-probe",
).eval()

Both have the same forward pass:

image = preprocess(512)(Image.open("test_data/Cat03.jpg").convert("RGB")).unsqueeze(0)
state = clf.init_state(batch_size=1, canvas_grid_size=32)

with torch.inference_mode():
    vp = Viewpoint.full_scene(batch_size=1, device=image.device)
    glimpse = sample_at_viewpoint(spatial=image, viewpoint=vp, glimpse_size_px=128)
    logits, state = clf(glimpse=glimpse, state=state, viewpoint=vp)

print(logits.argmax(dim=-1))  # ImageNet-1K class index

Demos

git clone https://github.com/m2b3/CanViT-PyTorch.git
cd CanViT-PyTorch

# Classification with sequential glimpses
uv run --extra demo python demos/classify.py                # finetuned backbone
uv run --extra demo python demos/classify.py --mode frozen  # frozen backbone + fused probe

# Canvas PCA visualization with two viewing strategies
uv run --extra demo python demos/basic.py

Supported platforms

• CPU
• CUDA (tested on RTX 4090, H100 SXM 80GB)
• TPU via torch_xla 2.9.0 (tested on TPU v6e)

Citation

If you use this work, please cite our preprint:

@article{berreby2026canvit,
  title={CanViT: Toward Active-Vision Foundation Models},
  author={Berreby, Yoha{\"i}-Eliel and Du, Sabrina and Durand, Audrey and Krishna, B. Suresh},
  year={2026},
  eprint={2603.22570},
  archivePrefix={arXiv},
  primaryClass={cs.CV},
  url={https://arxiv.org/abs/2603.22570}
}

Contact

Open an issue in this repository or email me@yberreby.com.

License

MIT. See LICENSE.md for details.