HorizonWeaver: Generalizable Multi-Level Semantic Editing for Driving Scenes
Abstract
Ensuring safety in autonomous driving requires scalable generation of realistic, controllable driving scenes beyond what real-world testing provides. Yet existing instruction guided image editors, trained on object-centric or artistic data, struggle with dense, safety-critical driving layouts. We propose HorizonWeaver, which tackles three fundamental challenges in driving scene editing: (1) multi-level granularity, requiring coherent object- and scene-level edits in dense environments; (2) rich high-level semantics, preserving diverse objects while following detailed instructions; and (3) ubiquitous domain shifts, handling changes in climate, layout, and traffic across unseen environments. The core of HorizonWeaver is a set of complementary contributions across data, model, and training: (1) Data: Large-scale dataset generation, where we build a paired real/synthetic dataset from Boreas, nuScenes, and Argoverse2 to improve generalization; (2) Model: Language-Guided Masks for fine-grained editing, where semantics-enriched masks and prompts enable precise, language-guided edits; and (3) Training: Content preservation and instruction alignment, where joint losses enforce scene consistency and instruction fidelity. Together, HorizonWeaver provides a scalable framework for photorealistic, instruction-driven editing of complex driving scenes, collecting 255K images across 13 editing categories and outperforming prior methods in L1, CLIP, and DINO metrics, achieving +46.4% user preference and improving BEV segmentation IoU by +33%. Project page: https://msoroco.github.io/horizonweaver/
Cite
@article{arxiv.2604.04887,
title = {HorizonWeaver: Generalizable Multi-Level Semantic Editing for Driving Scenes},
author = {Mauricio Soroco and Francesco Pittaluga and Zaid Tasneem and Abhishek Aich and Bingbing Zhuang and Wuyang Chen and Manmohan Chandraker and Ziyu Jiang},
journal= {arXiv preprint arXiv:2604.04887},
year = {2026}
}
Comments
CVPR Findings 2026