State-of-the-art (SOTA) adversarial attacks expose vulnerabilities in object detectors, often resulting in erroneous predictions. However, existing adversarial attacks neglect the stealth and flexibility of adversarial examples, which are crucial for conducting contextually consistent and inconspicuous attacks. To address these issues, leveraging the observed phenomenon of predicted box offsets in real-world object detection scenarios, this paper presents a novel adversarial attack framework called ShiftAttack. It leverages the concept of dense detection in prevalent object detectors, by boosting the confidence of low Intersection over Union (IoU) predictions within the positive samples (the set of predicted boxes responsible for localizing the same target), which leads to the erroneous exclusion of true positive predictions during the post-processing stage. Such a paradigm is highly stealthy as the shifted predictions seem like natural detector mistakes rather than obvious manipulations. To enhance the flexibility of ShiftAttack this paper proposes a generative approach called ShiftAttack Generator (SAG), which can not only shift predicted boxes for any target in arbitrary directions and distances but also facilitate adaptive feature exchange between pre- and post-shift regions to optimize the attack. Additionally, the proposed SAG incorporates the Dynamic Hinge Loss (DHL) to ensure the imperceptibility of perturbations, effectively mitigating the Patch-Pattern associated with the use of $\mathcal {L}_{2}$ norm. Extensive experiments confirm that SAG surpasses other SOTA adversarial attacks in effectiveness, speed and stealthiness.