随着应用软件的不断积累,二进制代码兼容已经成为微处理器能否具有生命力的关键问题。
Accumulation of software has made binary code compatibility a critical issue for the success of a processor.
关于与其他选项的兼容性和与GCC 3.0以前的版本生成的二进制代码的调用兼容性,请参考GCC手册获得详细情况。
Refer to the GCC manual for details concerning the compatibility with other options and for call-compatibility with binary code generated by pre-3.0 versions of GCC.
例如,在SLES8系统中使用glibc版本2.2.5编译的二进制代码,将可以在SLES9系统中使用glibc版本2.3运行,因为2.3版本是向后兼容的。
For example, a binary that was compiled on a SLES8 system with a version of glibc at 2.2.5 will also run on a SLES9 system with a glibc version at 2.3 since the 2.3 version is backward compatible.
“二进制兼容性概述”中的最后一个示例涉及到了在不同的处理器类型中运行二进制代码——POWER 4处理器和POWER 5处理器。
The last example under "Overview of binary compatibility" involved running a binary on two different processor types — a POWER4 processor and a POWER5 processor.
本文评论了关于Linux onPOWER的二进制不兼容性的来源、为什么存在这些来源,以及开发人员如何将这些不兼容性对代码的影响降低到最小。
This paper reviews sources of binary incompatibility regarding Linux on POWER, why these sources exist, and how developers can minimize the impact these incompatibilities have on their code.
本文评论了关于Linux onPOWER的二进制不兼容性的来源、为什么存在这些来源,以及开发人员如何将这些不兼容性对代码的影响降低到最小。
This paper reviews sources of binary incompatibility regarding Linux on POWER, why these sources exist, and how developers can minimize the impact these incompatibilities have on their code.
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