The detection of shape accuracy of body-in-white (BIW) via coordinate measuring machines (CMM) is a critical process in automobile manufacturing quality management. Traditional CMM inspection for a whole BIW requires an exhaustive examination of over 2000 measuring points and takes up to eight hours. To improve the inspection efficiency, in this paper, a novel sampling strategy and detection path optimization method that leverages historical quality inspection data instead of computer-aided design (CAD) models is proposed. In the proposed method, three key attributes of measuring points are first defined based on quality data, and a sampling point optimization model is established. Next, genetic algorithm (GA) is used to determine the most efficient and effective sampling point subsets for reducing the number of measuring points. Based on the selected points, the detection path planning problem is then formulated as a traveling salesman problem (TSP) and solved via particle swarm optimization (PSO). Based on a real dataset, the proposed method is proved effective in reducing the number of sampling points while preserving the integrity of defect detections.