Instead of the traditional spare row/column redundancy architectures, block-based redundancy architectures are proposed in this paper. The redundant rows/columns are divided into row/column blocks. Therefore, the repair of faulty memory cells can be performed at the row/column block level. Moreover, the redundant row/column blocks can be used to replace faulty cells anywhere in the memory array. This global characteristic is helpful for repairing cluster faults. The proposed redundancy architecture can be easily integrated with the embedded memory cores. Based on the proposed global redundancy architecture, a heuristic MESP (modified essential spare pivoting) algorithm suitable for built-in implementation is also proposed. According to experimental results, the area overhead for implementing the MESP algorithm is almost negligible. Due to the efficient usage of the redundancy, the manufacturing yield, repair rate, and reliability can all be improved significantly.