docs/source/en/model_doc/edgetam_video.md
This model was released on 2025-01-13 and added to Hugging Face Transformers on 2025-09-29.
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The EdgeTAM model was proposed in EdgeTAM: On-Device Track Anything Model Chong Zhou, Chenchen Zhu, Yunyang Xiong, Saksham Suri, Fanyi Xiao, Lemeng Wu, Raghuraman Krishnamoorthi, Bo Dai, Chen Change Loy, Vikas Chandra, Bilge Soran.
EdgeTAM is an efficient adaptation of SAM 2 that introduces a 2D Spatial Perceiver architecture to optimize memory attention mechanisms for real-time video segmentation on mobile devices.
The abstract from the paper is the following:
On top of Segment Anything Model (SAM), SAM 2 further extends its capability from image to video inputs through a memory bank mechanism and obtains a remarkable performance compared with previous methods, making it a foundation model for video segmentation task. In this paper, we aim at making SAM 2 much more efficient so that it even runs on mobile devices while maintaining a comparable performance. Despite several works optimizing SAM for better efficiency, we find they are not sufficient for SAM 2 because they all focus on compressing the image encoder, while our benchmark shows that the newly introduced memory attention blocks are also the latency bottleneck. Given this observation, we propose EdgeTAM, which leverages a novel 2D Spatial Perceiver to reduce the computational cost. In particular, the proposed 2D Spatial Perceiver encodes the densely stored frame-level memories with a lightweight Transformer that contains a fixed set of learnable queries. Given that video segmentation is a dense prediction task, we find preserving the spatial structure of the memories is essential so that the queries are split into global-level and patch-level groups. We also propose a distillation pipeline that further improves the performance without inference overhead. As a result, EdgeTAM achieves 87.7, 70.0, 72.3, and 71.7 J&F on DAVIS 2017, MOSE, SA-V val, and SA-V test, while running at 16 FPS on iPhone 15 Pro Max.
This model was contributed by yonigozlan. The original code can be found here.
EdgeTAM Video's key strength is its ability to track objects across video frames efficiently on mobile devices. Here's how to use it for video segmentation:
from transformers import EdgeTamVideoModel, Sam2VideoProcessor
import torch
model = EdgeTamVideoModel.from_pretrained("yonigozlan/edgetam-video-1", device_map="auto")
processor = Sam2VideoProcessor.from_pretrained("yonigozlan/edgetam-video-1")
# Load video frames (example assumes you have a list of PIL Images)
# video_frames = [Image.open(f"frame_{i:05d}.jpg") for i in range(num_frames)]
# For this example, we'll use the video loading utility
from transformers.video_utils import load_video
video_url = "https://huggingface.co/datasets/hf-internal-testing/sam2-fixtures/resolve/main/bedroom.mp4"
video_frames, _ = load_video(video_url)
# Initialize video inference session
inference_session = processor.init_video_session(
video=video_frames,
inference_device=device,
)
# Add click on first frame to select object
ann_frame_idx = 0
ann_obj_id = 1
points = [[[[210, 350]]]]
labels = [[[1]]]
processor.add_inputs_to_inference_session(
inference_session=inference_session,
frame_idx=ann_frame_idx,
obj_ids=ann_obj_id,
input_points=points,
input_labels=labels,
)
# Segment the object on the first frame
outputs = model(
inference_session=inference_session,
frame_idx=ann_frame_idx,
)
video_res_masks = processor.post_process_masks(
[outputs.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
print(f"Segmentation shape: {video_res_masks.shape}")
Segmentation shape: torch.Size([1, 1, 540, 960])
# Propagate through the entire video
video_segments = {}
for sam2_video_output in model.propagate_in_video_iterator(inference_session):
video_res_masks = processor.post_process_masks(
[sam2_video_output.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
video_segments[sam2_video_output.frame_idx] = video_res_masks
print(f"Tracked object through {len(video_segments)} frames")
Tracked object through 200 frames
Track multiple objects simultaneously across video frames:
# Reset for new tracking session
inference_session.reset_inference_session()
# Add multiple objects on the first frame
ann_frame_idx = 0
obj_ids = [2, 3]
input_points = [[[[200, 300]], [[400, 150]]]] # Points for two objects (batched)
input_labels = [[[1], [1]]]
processor.add_inputs_to_inference_session(
inference_session=inference_session,
frame_idx=ann_frame_idx,
obj_ids=obj_ids,
input_points=input_points,
input_labels=input_labels,
)
# Get masks for both objects on first frame
outputs = model(
inference_session=inference_session,
frame_idx=ann_frame_idx,
)
# Propagate both objects through video
video_segments = {}
for sam2_video_output in model.propagate_in_video_iterator(inference_session):
video_res_masks = processor.post_process_masks(
[sam2_video_output.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
video_segments[sam2_video_output.frame_idx] = {
obj_id: video_res_masks[i]
for i, obj_id in enumerate(inference_session.obj_ids)
}
print(f"Tracked {len(inference_session.obj_ids)} objects through {len(video_segments)} frames")
Tracked 2 objects through 200 frames
You can add additional clicks on any frame to refine the tracking:
# Add refinement click on a later frame
refine_frame_idx = 50
ann_obj_id = 2 # Refining first object
points = [[[[220, 280]]]] # Additional point
labels = [[[1]]] # Positive click
processor.add_inputs_to_inference_session(
inference_session=inference_session,
frame_idx=refine_frame_idx,
obj_ids=ann_obj_id,
input_points=points,
input_labels=labels,
)
# Re-propagate with the additional information
video_segments = {}
for sam2_video_output in model.propagate_in_video_iterator(inference_session):
video_res_masks = processor.post_process_masks(
[sam2_video_output.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
video_segments[sam2_video_output.frame_idx] = video_res_masks
For real-time applications, EdgeTAM Video supports processing video frames as they arrive:
# Initialize session for streaming
inference_session = processor.init_video_session(
inference_device=device,
)
# Process frames one by one
for frame_idx, frame in enumerate(video_frames[:10]): # Process first 10 frames
inputs = processor(images=frame, device=device, return_tensors="pt").to(model.device)
...
if frame_idx == 0:
# Add point input on first frame
processor.add_inputs_to_inference_session(
inference_session=inference_session,
frame_idx=0,
obj_ids=1,
input_points=[[[[210, 350], [250, 220]]]],
input_labels=[[[1, 1]]],
original_size=inputs.original_sizes[0], # need to be provided when using streaming video inference
)
...
# Process current frame
sam2_video_output = model(inference_session=inference_session, frame=inputs.pixel_values[0])
...
video_res_masks = processor.post_process_masks(
[sam2_video_output.pred_masks], original_sizes=inputs.original_sizes, binarize=False
)[0]
print(f"Frame {frame_idx}: mask shape {video_res_masks.shape}")
Frame 0: mask shape torch.Size([1, 1, 540, 960])
...
Track multiple objects simultaneously in video by adding them all at once:
# Initialize video session
inference_session = processor.init_video_session(
video=video_frames,
inference_device=device,
)
# Add multiple objects on the first frame using batch processing
ann_frame_idx = 0
obj_ids = [2, 3] # Track two different objects
input_points = [
[[[200, 300], [230, 250], [275, 175]], [[400, 150]]]
] # Object 2: 3 points (2 positive, 1 negative); Object 3: 1 point
input_labels = [
[[1, 1, 0], [1]]
] # Object 2: positive, positive, negative; Object 3: positive
processor.add_inputs_to_inference_session(
inference_session=inference_session,
frame_idx=ann_frame_idx,
obj_ids=obj_ids,
input_points=input_points,
input_labels=input_labels,
)
# Get masks for all objects on the first frame
outputs = model(
inference_session=inference_session,
frame_idx=ann_frame_idx,
)
video_res_masks = processor.post_process_masks(
[outputs.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
print(f"Generated masks for {video_res_masks.shape[0]} objects")
Generated masks for 2 objects
# Propagate all objects through the video
video_segments = {}
for sam2_video_output in model.propagate_in_video_iterator(inference_session):
video_res_masks = processor.post_process_masks(
[sam2_video_output.pred_masks], original_sizes=[[inference_session.video_height, inference_session.video_width]], binarize=False
)[0]
video_segments[sam2_video_output.frame_idx] = {
obj_id: video_res_masks[i]
for i, obj_id in enumerate(inference_session.obj_ids)
}
print(f"Tracked {len(inference_session.obj_ids)} objects through {len(video_segments)} frames")
Tracked 2 objects through 200 frames
[[autodoc]] EdgeTamVideoMaskDecoderConfig
[[autodoc]] EdgeTamVideoPromptEncoderConfig
[[autodoc]] EdgeTamVideoConfig
[[autodoc]] EdgeTamVideoInferenceSession
[[autodoc]] EdgeTamVideoModel - forward - get_image_features