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Program-based simulations contain organisms with a complex DNA language, usually Turing complete.  This language is more often in the form of a computer program than actual biological DNA.  Assembly derivatives are the most common languages used. An organism "lives" when its code is executed, and there are usually various methods allowing self-replication. Mutations are generally implemented as random changes to the code. Use of cellular automata is common but not required. Another example could be an artificial intelligence and multi-agent system/program.

Program-based simulations contain organisms with a complex DNA language, usually Turing complete.  This language is more often in the form of a computer program than actual biological DNA.  Assembly derivatives are the most common languages used. An organism "lives" when its code is executed, and there are usually various methods allowing self-replication. Mutations are generally implemented as random changes to the code. Use of cellular automata is common but not required. Another example could be an artificial intelligence and multi-agent system/program.

基于程序的模拟包含具有复杂 DNA 语言的生物体，通常是图灵完成。这种语言通常以计算机程序的形式出现，而不是真正的生物 DNA。汇编导数是最常用的语言。一个有机体在代码执行的时候是“活着”的，通常有各种各样的方法允许自我复制。变异通常是作为代码的随机变更来实现的。使用细胞自动机是常见的，但不是必需的。另一个例子可能是人工智能和多 agent 系统 / 程序。

基于程序的模拟包含具有复杂DNA语言（通常为图灵完整）的生物。这种语言通常是计算机程序的形式，而不是实际的生物DNA。汇编派生词是最常用的语言。生物体在执行其代码时会“存活”，通常有多种方法可以进行自我复制。变异通常是通过随机更改代码来实现的。元胞自动机是常见工具，但不是唯一的。也有人用人工智能和多线程系统/程序来进行研究。

 

 

 

 

====Module-based====

====Module-based====