Say I have a large struct, which includes other struct, etc. Would gcc -os
or any other gcc optimisation switch change the way it's stored in memory? I.e. would it pack the structure so as to squeeze out some extra space?
thanks,
Say I have a large struct, which includes other struct, etc. Would gcc -os
or any other gcc optimisation switch change the way it's stored in memory? I.e. would it pack the structure so as to squeeze out some extra space?
thanks,
No, in order change the native platform alignment for a structure in gcc
you would have to explicitly use the __attribute__((packed))
or __attribute__((align X))
compiler directives, or other gcc
command-line switches that specifically direct the compiler to change the native-platform alignment for data-structures.
Also, packing a structure with mixed data-types so that all the data-members may not be aligned on a proper word-boundary in memory actually will be slower for accessing a data-member at runtime, not faster. This is because the compiler will have to unpack the structure back to the native alignment for the platform before accessing the data-member.
-malign=...
and you may get differences between e.g. -m32
and -m64
.
#pragma pack
over __attribute__
stuff. Mostly because i never liked the attribute syntax, but also partially because the pragma pack syntax is fairly similar between compilers that support it.
Oct 3, 2011 at 15:19
No, this should not happen - so long as you have the same alignment and packing options for all your code modules then they should work correctly together even if compiled with different optimisation levels,
‑O
settings for example, then code generated in one translation unit might not match the layout expected in another translation unit when structs / classes are published and the published declaration is used in another file. It would be a nightmare, so you see why this isn't an option, as the previous poster pointed out.
Aug 29, 2016 at 3:00
In fact, I can see how aligning structs (by padding them) could lead to shorter code (no cross-boundary word addressing -> fewer load/stores)
-Os
optimizes for binary size (i.e. most commonly referred to as code size) not memory compression