Pixel dependency modeling from tampered images is pivotal for image forgery localization. Current approaches predominantly rely on convolutional neural network (CNN) or Transformer-based models, which often either lack sufficient receptive fields or entail significant computational overheads. In this paper, we propose LoMa, a novel image forgery localization method that leverages the Selective State Space (S6) model for global pixel dependency modeling and inverted residual CNN for local pixel dependency modeling. Our method introduces the Mixed-SSM Block, which initially employs atrous selective scan to traverse the spatial domain and convert the tampered image into order patch sequences, and subsequently applies multidirectional S6 modeling. In addition, an auxiliary convolutional branch is introduced to enhance local feature extraction. This design facilitates the efficient extraction of global dependencies while upholding linear complexity. Upon modeling the pixel dependency with the SSM and CNN blocks, the pixel-wise forgery localization results are obtained by a simple MLP decoder. Extensive experimental results validate the superiority of LoMa over CNN-based and Transformer-based state-of-the-arts.