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Model editing plays a crucial role in the cost-effective development of large language models, and the challenge of evolving knowledge facilitates its sequential extension, namely lifelong model editing. However, progress on standard and lifelong editing has historically followed separate tracks, overlooking the potential of generalizing standard methods to lifelong scenarios. By establishing this bridge, we can provide robust baselines in lifelong scenarios and ensure that lifelong editing benefits from the ongoing advancements in standard editing technologies. In response, this paper proposes a general framework, ***Sim**ulating **I**deal **E**ditor* (SimIE), which restores the strong performance of parameter-modifying methods from standard model editing in a lifelong context. SimIE formulates the ideal parameter shift as the minimum-norm solution to a linear system, constructed using the Moore-Penrose inverse, and subsequently enables recursive updates by truncating the limiting expression of the Moore-Penrose inverse under two mild assumptions. Theoretically, we demonstrate that if either assumption is not met, the solution provided by SimIE remains near-optimal in a statistical sense or stable against perturbations introduced by the sequential editing, but a trade-off between optimality and stability arises when both assumptions fail. Extensive experiments validate the effectiveness of SimIE, which allows standard algorithms to achieve performance comparable to specialized lifelong model editing methods. Our code is available at https://github.com/YamingGuo98/SimIE.