As the integrated circuits (ICs) technology continues to scale, resolution enhancement techniques (RETs) are mandatory to obtain high manufacturing quality and yield. Among various RETs, subresolution assist feature (SRAF) generation is a key technique to improve the target pattern quality and lithographic process window. While model-based SRAF insertion techniques have demonstrated high accuracy, they usually suffer from high computational cost. Therefore, more efficient techniques that can achieve high accuracy while reducing runtime are in strong demand. In this article, we leverage the recent advancement in machine learning for image generation to tackle the SRAF insertion problem. In particular, we propose a new SRAF insertion framework, GAN-SRAF, which uses generative adversarial networks (GANs) to generate SRAFs directly for any given layout. Our proposed approach incorporates a novel layout to image encoding using multichannel heatmaps to preserve the layout information and facilitate layout reconstruction. Our experimental results demonstrate ${\sim }14.6\times$ reduction in runtime when compared to the previous best machine learning approach for SRAF generation, and ${\sim }144\times$ reduction compared to the model-based approach, while achieving comparable quality of results.