I wanted to introduce a weak symbol into my code, however, I am unable to comprehend its behavior when *.a files are used.
This is my minimal example:
file a.h:
void foo() __attribute__((weak));
file a.c:
#include "a.h"
#include <stdio.h>
void foo() { printf("%s\n", __FILE__); }
file b.c:
#include <stdio.h>
void foo() { printf("%s\n", __FILE__); }
file main.cpp:
#include "a.h"
#include <stdio.h>
int main() { if (foo) foo(); else printf("no foo\n"); }
Now, depending if I use *.o files (make -c a.c and make -c b.c) or *.a files (ar cr a.o and ar cr b.o) the output is different:
1) g++ main.cpp a.o b.o prints b.c
2) g++ main.cpp b.o a.o prints b.c
3) g++ main.cpp a.a b.a prints no foo
4) g++ main.cpp b.a a.a prints no foo
1), 2) work just fine but the output for 3), 4) seems to be a little unexpected.
I was desperately trying to make this example work with archives so I made few changes:
file a.h:
void foo();
file a.c:
#include "a.h"
#include <stdio.h>
void __attribute__((weak)) foo() { printf("%s\n", __FILE__); }
After this modification:
1) g++ main.cpp a.a b.a prints a.c
2) g++ main.cpp b.a a.a prints b.c
So it works a bit better. After running nm a.a shows W _Z3foov so there is no violation of ODR. However, I don't know if this is a correct usage of weak attribute. According to gcc documentation:
The weak attribute causes the declaration to be emitted as a weak symbol rather than a global. This is primarily useful in defining library functions which can be overridden in user code, though it can also be used with non-function declarations. Weak symbols are supported for ELF targets, and also for a.out targets when using the GNU assembler and linker.
Yet I use weak attribute on the function definition not the declaration.
So the question is why weak doesn't work with *.a files? Is usage of weak attribute on a definition instead of a declaration correct?
UPDATE
It has dawned on me that weak attribute used with foo() method definition had no impact on the symbol resolution. Without the attribute final binary generates the same:
1) g++ main.cpp a.a b.a prints a.c
2) g++ main.cpp b.a a.a prints b.c
So simply the first definition of the symbol is used and this is consisten with default gcc behaviour. Even though nm a.a shows that a weak symbol was emitted, it doesn't seem to affect static linking.
Is it possible to use weak attribute with static linking at all?
DESCRIPTION OF THE PROBLEM I WANT TO SOLVE
I have a library that is used by >20 clients, let's call it library A. I also provide a library B which contains testing utils for A. Somehow I need to know that library A is used in testing mode, so the simplest solution seems to be replacing a symbol during linking with B (because clients are already linking with B).
I know there are cleaner solutions to this problem, however I absolutely can't impact clients' code or their build scripts (adding parameter that would indicate testing for A or some DEFINE for compilation is out of option).
To explain what's going on here, let's talk first about your original source files, with
a.h (1):
void foo() __attribute__((weak));
and:
a.c (1):
#include "a.h"
#include <stdio.h>
void foo() { printf("%s\n", __FILE__); }
The mixture of .c and .cpp files in your sample code is irrelevant to the
issues, and all the code is C, so we'll say that main.cpp is main.c and
do all compiling and linking with gcc:
$ gcc -Wall -c main.c a.c b.c
ar rcs a.a a.o
ar rcs b.a b.o
First let's review the differences between a weakly declared symbol, like
your:
void foo() __attribute__((weak));
and a strongly declared symbol, like
void foo();
which is the default:
When a weak reference to foo (i.e. a reference to weakly declared foo) is linked in a program, the
linker need not find a definition of foo anywhere in the linkage: it may remain
undefined. If a strong reference to foo is linked in a program,
the linker needs to find a definition of foo.
A linkage may contain at most one strong definition of foo (i.e. a definition
of foo that declares it strongly). Otherwise a multiple-definition error results.
But it may contain multiple weak definitions of foo without error.
If a linkage contains one or more weak definitions of foo and also a strong
definition, then the linker chooses the strong definition and ignores the weak
ones.
If a linkage contains just one weak definition of foo and no strong
definition, inevitably the linker uses the one weak definition.
If a linkage contains multiple weak definitions of foo and no strong
definition, then the linker chooses one of the weak definitions arbitrarily.
Next, let's review the differences between inputting an object file in a linkage
and inputting a static library.
A static library is merely an ar archive of object files that we may offer to
the linker from which to select the ones it needs to carry on the linkage.
When an object file is input to a linkage, the linker unconditionally links it
into the output file.
When static library is input to a linkage, the linker examines the archive to
find any object files within it that provide definitions it needs for unresolved symbol references
that have accrued from input files already linked. If it finds any such object files
in the archive, it extracts them and links them into the output file, exactly as
if they were individually named input files and the static library was not mentioned at all.
With these observations in mind, consider the compile-and-link command:
gcc main.c a.o b.o
Behind the scenes gcc breaks it down, as it must, into a compile-step and link
step, just as if you had run:
gcc -c main.c # compile
gcc main.o a.o b.o # link
All three object files are linked unconditionally into the (default) program ./a.out. a.o contains a
weak definition of foo, as we can see:
$ nm --defined a.o
0000000000000000 W foo
Whereas b.o contains a strong definition:
$ nm --defined b.o
0000000000000000 T foo
The linker will find both definitions and choose the strong one from b.o, as we can
also see:
$ gcc main.o a.o b.o -Wl,-trace-symbol=foo
main.o: reference to foo
a.o: definition of foo
b.o: definition of foo
$ ./a.out
b.c
Reversing the linkage order of a.o and b.o will make no difference: there's
still exactly one strong definition of foo, the one in b.o.
By contrast consider the compile-and-link command:
gcc main.cpp a.a b.a
which breaks down into:
gcc -c main.cpp # compile
gcc main.o a.a b.a # link
Here, only main.o is linked unconditionally. That puts an undefined weak reference
to foo into the linkage:
$ nm --undefined main.o
w foo
U _GLOBAL_OFFSET_TABLE_
U puts
That weak reference to foo does not need a definition. So the linker will
not attempt to find a definition that resolves it in any of the object files in either a.a or b.a and
will leave it undefined in the program, as we can see:
$ gcc main.o a.a b.a -Wl,-trace-symbol=foo
main.o: reference to foo
$ nm --undefined a.out
w __cxa_finalize##GLIBC_2.2.5
w foo
w __gmon_start__
w _ITM_deregisterTMCloneTable
w _ITM_registerTMCloneTable
U __libc_start_main##GLIBC_2.2.5
U puts##GLIBC_2.2.5
Hence:
$ ./a.out
no foo
Again, it doesn't matter if you reverse the linkage order of a.a and b.a,
but this time it is because neither of them contributes anything to the linkage.
Let's turn now to the different behavior you discovered by changing a.h and a.c
to:
a.h (2):
void foo();
a.c (2):
#include "a.h"
#include <stdio.h>
void __attribute__((weak)) foo() { printf("%s\n", __FILE__); }
Once again:
$ gcc -Wall -c main.c a.c b.c
main.c: In function ‘main’:
main.c:4:18: warning: the address of ‘foo’ will always evaluate as ‘true’ [-Waddress]
int main() { if (foo) foo(); else printf("no foo\n"); }
See that warning? main.o now contains a strongly declared reference to foo:
$ nm --undefined main.o
U foo
U _GLOBAL_OFFSET_TABLE_
so the code (when linked) must have a non-null address for foo. Proceeding:
$ ar rcs a.a a.o
$ ar rcs b.a b.o
Then try the linkage:
$ gcc main.o a.o b.o
$ ./a.out
b.c
And with the object files reversed:
$ gcc main.o b.o a.o
$ ./a.out
b.c
As before, the order makes no difference. All the object files are linked. b.o provides
a strong definition of foo, a.o provides a weak one, so b.o wins.
Next try the linkage:
$ gcc main.o a.a b.a
$ ./a.out
a.c
And with the order of the libraries reversed:
$ gcc main.o b.a a.a
$ ./a.out
b.c
That does make a difference. Why? Let's redo the linkages with diagnostics:
$ gcc main.o a.a b.a -Wl,-trace,-trace-symbol=foo
/usr/bin/x86_64-linux-gnu-ld: mode elf_x86_64
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/Scrt1.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crti.o
/usr/lib/gcc/x86_64-linux-gnu/7/crtbeginS.o
main.o
(a.a)a.o
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/lib/x86_64-linux-gnu/libc.so.6
(/usr/lib/x86_64-linux-gnu/libc_nonshared.a)elf-init.oS
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/usr/lib/gcc/x86_64-linux-gnu/7/crtendS.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crtn.o
main.o: reference to foo
a.a(a.o): definition of foo
Ignoring the default libraries, the only object files of ours that get
linked were:
main.o
(a.a)a.o
And the definition of foo was taken from the archive member a.o of a.a:
a.a(a.o): definition of foo
Reversing the library order:
$ gcc main.o b.a a.a -Wl,-trace,-trace-symbol=foo
/usr/bin/x86_64-linux-gnu-ld: mode elf_x86_64
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/Scrt1.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crti.o
/usr/lib/gcc/x86_64-linux-gnu/7/crtbeginS.o
main.o
(b.a)b.o
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/lib/x86_64-linux-gnu/libc.so.6
(/usr/lib/x86_64-linux-gnu/libc_nonshared.a)elf-init.oS
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/usr/lib/gcc/x86_64-linux-gnu/7/crtendS.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crtn.o
main.o: reference to foo
b.a(b.o): definition of foo
This time the object files linked were:
main.o
(b.a)b.o
And the definition of foo was taken from b.o in b.a:
b.a(b.o): definition of foo
In the first linkage, the linker had an unresolved strong reference to
foo for which it needed a definition when it reached a.a. So it
looked in the archive for an object file that provides a definition,
and found a.o. That definition was a weak one, but that didn't matter. No
strong definition had been seen. a.o was extracted from a.a and linked,
and the reference to foo was thus resolved. Next b.a was reached, where
a strong definition of foo would have been found in b.o, if the linker still needed one
and looked for it. But it didn't need one any more and didn't look. The linkage:
gcc main.o a.a b.a
is exactly the same as:
gcc main.o a.o
And likewise the linkage:
$ gcc main.o b.a a.a
is exactly the same as:
$ gcc main.o b.o
Your real problem...
... emerges in one of your comments to the post:
I want to override [the] original function implementation when linking with a testing framework.
You want to link a program inputting some static library lib1.a
which has some member file1.o that defines a symbol foo, and you want to knock out
that definition of foo and link a different one that is defined in some other object
file file2.o.
__attribute__((weak)) isn't applicable to that problem. The solution is more
elementary. You just make sure to input file2.o to the linkage before you input
lib1.a (and before any other input that provides a definition of foo).
Then the linker will resolve references to foo with the definition provided in file2.o and will not try to find any other
definition when it reaches lib1.a. The linker will not consume lib1.a(file1.o) at all. It might as well not exist.
And what if you have put file2.o in another static library lib2.a? Then inputting
lib2.a before lib1.a will do the job of linking lib2.a(file2.o) before
lib1.a is reached and resolving foo to the definition in file2.o.
Likewise, of course, every definition provided by members of lib2.a will be linked in
preference to a definition of the same symbol provided in lib1.a. If that's not what
you want, then don't like lib2.a: link file2.o itself.
Finally
Is it possible to use [the] weak attribute with static linking at all?
Certainly. Here is a first-principles use-case:
foo.h (1)
#ifndef FOO_H
#define FOO_H
int __attribute__((weak)) foo(int i)
{
return i != 0;
}
#endif
aa.c
#include "foo.h"
int a(void)
{
return foo(0);
}
bb.c
#include "foo.h"
int b(void)
{
return foo(42);
}
prog.c
#include <stdio.h>
extern int a(void);
extern int b(void);
int main(void)
{
puts(a() ? "true" : "false");
puts(b() ? "true" : "false");
return 0;
}
Compile all the source files, requesting a seperate ELF section for each function:
$ gcc -Wall -ffunction-sections -c prog.c aa.c bb.c
Note that the weak definition of foo is compiled via foo.h into both
aa.o and bb.o, as we can see:
$ nm --defined aa.o
0000000000000000 T a
0000000000000000 W foo
$ nm --defined bb.o
0000000000000000 T b
0000000000000000 W foo
Now link a program from all the object files, requesting the linker to
discard unused sections (and give us the map-file, and some diagnostics):
$ gcc prog.o aa.o bb.o -Wl,--gc-sections,-Map=mapfile,-trace,-trace-symbol=foo
/usr/bin/x86_64-linux-gnu-ld: mode elf_x86_64
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/Scrt1.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crti.o
/usr/lib/gcc/x86_64-linux-gnu/7/crtbeginS.o
prog.o
aa.o
bb.o
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/lib/x86_64-linux-gnu/libc.so.6
(/usr/lib/x86_64-linux-gnu/libc_nonshared.a)elf-init.oS
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
/lib/x86_64-linux-gnu/ld-linux-x86-64.so.2
libgcc_s.so.1 (/usr/lib/gcc/x86_64-linux-gnu/7/libgcc_s.so.1)
/usr/lib/gcc/x86_64-linux-gnu/7/crtendS.o
/usr/lib/gcc/x86_64-linux-gnu/7/../../../x86_64-linux-gnu/crtn.o
aa.o: definition of foo
This linkage is no different from:
$ ar rcs libaabb.a aa.o bb.o
$ gcc prog.o libaabb.a
Despite the fact that both aa.o and bb.o were loaded, and each contains
a definition of foo, no multiple-definition error results, because each definition
is weak. aa.o was loaded before bb.o and the definition of foo was linked from aa.o.
So what happened to the definition of foo in bb.o? The mapfile shows us:
mapfile (1)
...
...
Discarded input sections
...
...
.text.foo 0x0000000000000000 0x13 bb.o
...
...
The linker discarded the function section that contained the definition
in bb.o
Let's reverse the linkage order of aa.o and bb.o:
$ gcc prog.o bb.o aa.o -Wl,--gc-sections,-Map=mapfile,-trace,-trace-symbol=foo
...
prog.o
bb.o
aa.o
...
bb.o: definition of foo
And now the opposite thing happens. bb.o is loaded before aa.o. The
definition of foo is linked from bb.o and:
mapfile (2)
...
...
Discarded input sections
...
...
.text.foo 0x0000000000000000 0x13 aa.o
...
...
the definition from aa.o is chucked away.
There you see how the linker arbitrarily chooses one of multiple
weak definitions of a symbol, in the absence of a strong definition. It simply
picks the first one you give it and ignores the rest.
What we've just done here is effectively what the GCC C++ compiler does for us when we
define a global inline function. Rewrite:
foo.h (2)
#ifndef FOO_H
#define FOO_H
inline int foo(int i)
{
return i != 0;
}
#endif
Rename our source files *.c -> *.cpp; compile and link:
$ g++ -Wall -c prog.cpp aa.cpp bb.cpp
Now there is a weak definition of foo (C++ mangled) in each of aa.o and bb.o:
$ nm --defined aa.o bb.o
aa.o:
0000000000000000 T _Z1av
0000000000000000 W _Z3fooi
bb.o:
0000000000000000 T _Z1bv
0000000000000000 W _Z3fooi
The linkage uses the first definition it finds:
$ g++ prog.o aa.o bb.o -Wl,-Map=mapfile,-trace,-trace-symbol=_Z3fooi
...
prog.o
aa.o
bb.o
...
aa.o: definition of _Z3fooi
bb.o: reference to _Z3fooi
and throws away the other one:
mapfile (3)
...
...
Discarded input sections
...
...
.text._Z3fooi 0x0000000000000000 0x13 bb.o
...
...
And as you may know, every instantiation of the C++ function template in
global scope (or instantiation of a class template member function) is
an inline global function. Rewrite again:
#ifndef FOO_H
#define FOO_H
template<typename T>
T foo(T i)
{
return i != 0;
}
#endif
Recompile:
$ g++ -Wall -c prog.cpp aa.cpp bb.cpp
Again:
$ nm --defined aa.o bb.o
aa.o:
0000000000000000 T _Z1av
0000000000000000 W _Z3fooIiET_S0_
bb.o:
0000000000000000 T _Z1bv
0000000000000000 W _Z3fooIiET_S0_
each of aa.o and bb.o has a weak definition of:
$ c++filt _Z3fooIiET_S0_
int foo<int>(int)
and the linkage behaviour is now familiar. One way:
$ g++ prog.o aa.o bb.o -Wl,-Map=mapfile,-trace,-trace-symbol=_Z3fooIiET_S0_
...
prog.o
aa.o
bb.o
...
aa.o: definition of _Z3fooIiET_S0_
bb.o: reference to _Z3fooIiET_S0_
and the other way:
$ g++ prog.o bb.o aa.o -Wl,-Map=mapfile,-trace,-trace-symbol=_Z3fooIiET_S0_
...
prog.o
bb.o
aa.o
...
bb.o: definition of _Z3fooIiET_S0_
aa.o: reference to _Z3fooIiET_S0_
Our program's behavior is unchanged by the rewrites:
$ ./a.out
false
true
So the application of the weak attribute to symbols in the linkage of ELF objects -
whether static or dynamic - enables the GCC implementation of C++ templates
for the GNU linker. You could fairly say it enables the GCC implementation of modern C++.
I find that here is the best explanation:
The linker will only search through libraries to resolve a reference if it cannot resolve that reference after searching all input objects. If required, the libraries are searched from left to right according to their position on the linker command line. Objects within the library will be searched by the order in which they were archived. As soon as armlink finds a symbol match for the reference, the searching is finished, even if it matches a weak definition.
The ELF ABI section 4.6.1.2 says:
"A weak definition does not change the rules by which object files are selected from libraries. However, if a link set contains both a weak definition and a non-weak definition, the non-weak definition will always be used."
The "link set" is the set of objects that have been loaded by the linker. It does not include objects from libraries that are not required.
Therefore archiving two objects where one contains the weak definition of a given symbol and the other contains the non-weak definition of that symbol, into a library or separate libraries, is not recommended.
Observe the following. Basically renamed mv a.c definition.c mv b.c noweak.c and mv second_a.c declaration.c.
> for i in Makefile *.c; do echo "cat $i <<EOF"; cat $i; echo EOF; done
cat Makefile <<EOF
tgt=
tgt+=only_weak_1.out only_weak_2.out
tgt+=definition.out declaration.out noweak.out
tgt+=definition_static.out declaration_static.out noweak_static.out
tgt+=1.out 2.out 3.out 4.out
tgt+=5.out 6.out 7.out 8.out
tgt+=10.out 11.out 12.out
tgt+=13.out
tgt+=14.out
only_weak_1_obj= definition.o declaration.o
only_weak_2_obj= declaration.o definition.o
definition_obj= definition.o
declaration_obj= declaration.o
noweak_obj= noweak.o
definition_static_obj= definition.a
declaration_static_obj= declaration.a
noweak_static_obj= noweak.a
1_obj= declaration.o noweak.o
2_obj= noweak.o declaration.o
3_obj= declaration.a noweak.a
4_obj= noweak.a declaration.a
5_obj= definition.o noweak.o
6_obj= noweak.o definition.o
7_obj= definition.a noweak.a
8_obj= noweak.a definition.a
10_obj= noweak.a definition.a declaration.a
11_obj= definition.a declaration.a noweak.a
12_obj= declaration.a definition.a noweak.a
13_obj= all.a
14_obj= all.o
.PRECIOUS: % %.o %.c %.a
def: run
.PHONY: run
run: $(tgt)
{ $(foreach a,$^,echo "$($(a:.out=)_obj)#->#$(a)#:#$$(./$(a))";) } | { echo; column -t -s'#' -N 'objects, ,executable, ,output' -o' '; echo; }
.SECONDEXPANSION:
%.out: main.o $$(%_obj)
$(CC) -o $# $^
%.o: %.c
$(CC) -c -o $# $^
%.a: %.o
ar cr $# $^
all.a: declaration.o definition.o noweak.o
ar cr $# $^
all.o: declaration.o definition.o noweak.o
$(LD) -i -o $# $^
clean:
rm -fv *.o *.a *.out
EOF
cat declaration.c <<EOF
#include <stdio.h>
__attribute__((__weak__)) void foo();
void foo() { printf("%s\n", __FILE__); }
EOF
cat definition.c <<EOF
#include <stdio.h>
__attribute__((__weak__)) void foo() { printf("%s\n", __FILE__); }
EOF
cat main.c <<EOF
#include <stdio.h>
void foo();
int main() {
if (foo) foo(); else printf("no foo\n");
return 0;
}
EOF
cat noweak.c <<EOF
#include <stdio.h>
void foo() { printf("%s\n", __FILE__); }
EOF
> make
cc -c -o definition.o definition.c
cc -c -o declaration.o declaration.c
cc -c -o main.o main.c
cc -o only_weak_1.out main.o definition.o declaration.o
cc -o only_weak_2.out main.o declaration.o definition.o
cc -o definition.out main.o definition.o
cc -o declaration.out main.o declaration.o
cc -c -o noweak.o noweak.c
cc -o noweak.out main.o noweak.o
ar cr definition.a definition.o
cc -o definition_static.out main.o definition.a
ar cr declaration.a declaration.o
cc -o declaration_static.out main.o declaration.a
ar cr noweak.a noweak.o
cc -o noweak_static.out main.o noweak.a
cc -o 1.out main.o declaration.o noweak.o
cc -o 2.out main.o noweak.o declaration.o
cc -o 3.out main.o declaration.a noweak.a
cc -o 4.out main.o noweak.a declaration.a
cc -o 5.out main.o definition.o noweak.o
cc -o 6.out main.o noweak.o definition.o
cc -o 7.out main.o definition.a noweak.a
cc -o 8.out main.o noweak.a definition.a
cc -o 10.out main.o noweak.a definition.a declaration.a
cc -o 11.out main.o definition.a declaration.a noweak.a
cc -o 12.out main.o declaration.a definition.a noweak.a
ar cr all.a declaration.o definition.o noweak.o
cc -o 13.out main.o all.a
ld -i -o all.o declaration.o definition.o noweak.o
cc -o 14.out main.o all.o
{ echo "definition.o declaration.o#->#only_weak_1.out#:#$(./only_weak_1.out)"; echo "declaration.o definition.o#->#only_weak_2.out#:#$(./only_weak_2.out)"; echo "definition.o#->#definition.out#:#$(./definition.out)"; echo "declaration.o#->#declaration.out#:#$(./declaration.out)"; echo "noweak.o#->#noweak.out#:#$(./noweak.out)"; echo "definition.a#->#definition_static.out#:#$(./definition_static.out)"; echo "declaration.a#->#declaration_static.out#:#$(./declaration_static.out)"; echo "noweak.a#->#noweak_static.out#:#$(./noweak_static.out)"; echo "declaration.o noweak.o#->#1.out#:#$(./1.out)"; echo "noweak.o declaration.o#->#2.out#:#$(./2.out)"; echo "declaration.a noweak.a#->#3.out#:#$(./3.out)"; echo "noweak.a declaration.a#->#4.out#:#$(./4.out)"; echo "definition.o noweak.o#->#5.out#:#$(./5.out)"; echo "noweak.o definition.o#->#6.out#:#$(./6.out)"; echo "definition.a noweak.a#->#7.out#:#$(./7.out)"; echo "noweak.a definition.a#->#8.out#:#$(./8.out)"; echo "noweak.a definition.a declaration.a#->#10.out#:#$(./10.out)"; echo "definition.a declaration.a noweak.a#->#11.out#:#$(./11.out)"; echo "declaration.a definition.a noweak.a#->#12.out#:#$(./12.out)"; echo "all.a#->#13.out#:#$(./13.out)"; echo "all.o#->#14.out#:#$(./14.out)"; } | { echo; column -t -s'#' -N 'objects, ,executable, ,output' -o' '; echo; }
objects executable output
definition.o declaration.o -> only_weak_1.out : definition.c
declaration.o definition.o -> only_weak_2.out : declaration.c
definition.o -> definition.out : definition.c
declaration.o -> declaration.out : declaration.c
noweak.o -> noweak.out : noweak.c
definition.a -> definition_static.out : definition.c
declaration.a -> declaration_static.out : declaration.c
noweak.a -> noweak_static.out : noweak.c
declaration.o noweak.o -> 1.out : noweak.c
noweak.o declaration.o -> 2.out : noweak.c
declaration.a noweak.a -> 3.out : declaration.c
noweak.a declaration.a -> 4.out : noweak.c
definition.o noweak.o -> 5.out : noweak.c
noweak.o definition.o -> 6.out : noweak.c
definition.a noweak.a -> 7.out : definition.c
noweak.a definition.a -> 8.out : noweak.c
noweak.a definition.a declaration.a -> 10.out : noweak.c
definition.a declaration.a noweak.a -> 11.out : definition.c
declaration.a definition.a noweak.a -> 12.out : declaration.c
all.a -> 13.out : declaration.c
all.o -> 14.out : noweak.c
In case only weak symbols are used (case only_weak_1 and only_weak_2) the first definition is used.
In case of only static libraries (case 3, 4, 7, 8, 10, 11, 12, 13) the first definition is used.
In case only object files are used (cases 1, 2, 5, 6, 14) the weak symbols are omitted and only the symbol from noweak is used.
From the link I provided:
There are different ways to guarantee armlink selecting a non-weak version of a given symbol:
- Do not archive such objects
- Ensure that the weak and non-weak symbols are contained within the same object before archiving
- Use partial linking as an alternative.
I created a shared library "A" that use an other shared library "B".
I have a problem when I link my program with the shared library "A".
When I use some function from the other shared library ("B") inside cpp file of the shared library "A", all is fine.
But when I use these functions inside .h file (inside a templated method or an inlined method) of the shared library "A", the symbol is not loaded and I get an error "undefined reference to symbol".
I used g++ 7.2.
I think the option -l forget to load the symbols used in header file.
Do you have an idea to avoid this?
Update 2:
Here a full reproducible example:
A.cpp
#include "A.h"
A.h
#ifndef A_H
# define A_H
#include <type_traits>
#include "B.h"
class A
{
public:
template <typename Type>
std::enable_if_t<std::is_arithmetic<Type>::value,void> funcA(Type value);
};
template <typename Type>
std::enable_if_t<std::is_arithmetic<Type>::value,void> A::funcA(Type value)
{
B tmp;
tmp.funcB(value);
}
#endif
B.cpp
#include "B.h"
#include <iostream>
void B::example()
{
std::cout << "works" << std::endl;
}
B.h
#ifndef B_H
# define B_H
class B
{
public:
void funcB(int value);
private:
void example();
};
inline void B::funcB(int value)
{
value += 1;
example();
}
#endif
main.cpp
#include "A.h"
int main()
{
A tmp;
tmp.funcA(5);
return 1;
}
Compile
g++ -std=c++17 -m64 -O2 -DNDEBUG -Wall -Wextra -Werror -fPIC -o A.o -c A.cpp
g++ -std=c++17 -m64 -O2 -DNDEBUG -Wall -Wextra -Werror -fPIC -o B.o -c B.cpp
g++ -std=c++17 -m64 -O2 -DNDEBUG -Wall -Wextra -Werror -fPIC -o main.o -c main.cpp
g++ -o libB.so B.o -shared
g++ -o libA.so A.o -shared -L. -lB
g++ -o application main.o -L . -lA
Error
main.o: In function `main':
main.cpp:(.text.startup+0x1a): undefined reference to `B::example()'
collect2: error: ld returned 1 exit status
Thank you,
SOLVED:
Finally, I solved my problem with this thread:
GCC 4.5 vs 4.4 linking with dependencies
Thank you!
Consider the following setup consisting of two shared libraries which both use a static library:
static.cpp
#include "static.h"
static int a = 0;
int getA()
{
return a++;
}
static.h
#pragma once
int getA();
shareda.cpp
#include <iostream>
#include "shareda.h"
#include "static.h"
void printA()
{
std::cout << getA() << std::endl;
}
shareda.h
#pragma once
void printA();
sharedb.cpp
#include <iostream>
#include "sharedb.h"
#include "static.h"
void printB()
{
std::cout << getA() << std::endl;
}
sharedb.h
#pragma once
void printB();
main.cpp
#include "shareda.h"
#include "sharedb.h"
int main()
{
printA();
printA();
printB();
printA();
printB();
return 0;
}
I compiled and ran these files with the following commands (using Clang 3.8.0, compiled from source, and 64-bit Debian with GNU ld 2.25):
clang++ -c static.cpp -o static.o -fPIC
ar rcs libstatic.a static.o
clang++ -c shareda.cpp -o shareda.o -fPIC
clang++ -shared -o libshareda.so shareda.o libstatic.a
clang++ -c sharedb.cpp -o sharedb.o -fPIC
clang++ -shared -o libsharedb.so sharedb.o libstatic.a
clang++ -L. -lshareda -lsharedb -o main main.cpp
LD_LIBRARY_PATH=.:$LD_LIBRARY_PATH ./main
To my surprise, the output was the following:
0
1
2
3
4
My expectation was this:
0
1
0
2
1
Apparently, despite the static keyword in front of a in static.cpp, only one instance of a exists. Is there a way to have two instances of a, one for each of the shared libraries?
Apparently, despite the static keyword in front of a in static.cpp, only one instance of a exists.
That is incorrect: two instances of a exist, but only one is actually used.
And that is happening because (contrary to your expectations) printB calls the first getA available to it (the one from libshareda.so, not the one from libsharedb.so). That is one major difference between UNIX shared libraries and Windows DLLs. UNIX shared libraries emulate what would have happened if your link was:
clang++ -L. -o main main.cpp shareda.o sharedb.o libstatic.a
So what can you do to "fix" this?
You could link libsharedb.so to prefer its own getA, by using -Bsymbolic.
You could hide getA inside libsharedb.so completely (as if it's a private implementation detail):
clang++ -c -fvisibility=hidden -fPIC static.cpp
ar rcs libstatic.a static.o
clang++ -shared -o libsharedb.so sharedb.o libstatic.a
You could achieve similar result using linker version script.
P.S. Your link command:
clang++ -L. -lshareda -lsharedb -o main main.cpp
is completely backwards. It should be:
clang++ -L. -o main main.cpp -lshareda -lsharedb
The order of sources/object files and libraries on command line matters, and libraries should follow object files that reference them.
I write a C++ library and when linking against the library the symbols in it cannot be found. Here's what I've got:
a.cpp:
void zak()
{
}
test.cpp:
extern void zak();
int main(int argc, const char ** argv)
{
zak();
}
Makefile:
all:
g++ -c -o a.o a.cpp
ar r libzak.a a.o
g++ -L. -lzak test.cpp -o test
Here is what make says on my (Linux Mint 13) box:
g++ -c -o a.o a.cpp
ar r libzak.a a.o
g++ -L. -lzak test.cpp -o test
/tmp/ccC4cnLV.o: In function `main':
test.cpp:(.text+0x7): undefined reference to `zak()'
collect2: error: ld returned 1 exit status
make: *** [all] Error 1
I am sure I am missing something obvious, but what is it?
Link order matters. Put -lzak after test.cpp on the link line.
I think that -l is for shared libraries (.so). Try this: g++ libzak.a test.cpp -o test
I have a question about making static libraries that use other static libraries.
I set up an example with 3 files - main.cpp, slib1.cpp and slib2.cpp. slib1.cpp and slib2.cpp are both compiled as individual static libraries (e.g. I end up with slib1.a and slib2.a) main.cpp is compiled into a standard ELF executable linked against both libraries.
There also exists a header file named main.h which prototypes the functions in slib1 and slib2.
main.cpp calls a function called lib2func() from slib2. This function in turn calls lib1func() from slib1.
If I compile the code as is, g++ will return with a linker error stating that it could not find lib1func() in slib1. However, if I make a call to lib1func() BEFORE any calls to any functions in slib2, the code compiles and works correctly.
My question is simply as follows: is it possible to create a static library that depends on another static library? It would seem like a very severe limitation if this were not possible.
The source code for this problem is attached below:
main.h:
#ifndef MAIN_H
#define MAIN_H
int lib1func();
int lib2func();
#endif
slib1.cpp:
#include "main.h"
int lib1func() {
return 1;
}
slib2.cpp:
#include "main.h"
int lib2func() {
return lib1func();
}
main.cpp:
#include <iostream>
#include "main.h"
int main(int argc, char **argv) {
//lib1func(); // Uncomment and compile will succeed. WHY??
cout << "Ans: " << lib2func() << endl;
return 0;
}
gcc output (with line commented out):
g++ -o src/slib1.o -c src/slib1.cpp
ar rc libslib1.a src/slib1.o
ranlib libslib1.a
g++ -o src/slib2.o -c src/slib2.cpp
ar rc libslib2.a src/slib2.o
ranlib libslib2.a
g++ -o src/main.o -c src/main.cpp
g++ -o main src/main.o -L. -lslib1 -lslib2
./libslib2.a(slib2.o): In function `lib2func()':
slib2.cpp:(.text+0x5): undefined reference to `lib1func()'
collect2: ld returned 1 exit status
gcc output (with line uncommented)
g++ -o src/slib1.o -c src/slib1.cpp
ar rc libslib1.a src/slib1.o
ranlib libslib1.a
g++ -o src/slib2.o -c src/slib2.cpp
ar rc libslib2.a src/slib2.o
ranlib libslib2.a
g++ -o src/main.o -c src/main.cpp
g++ -o main src/main.o -L. -lslib1 -lslib2
$ ./main
Ans: 1
Please, try g++ -o main src/main.o -L. -Wl,--start-group -lslib1 -lslib2 -Wl,--end-group.
Group defined with --start-group, --end-group helps to resolve circular dependencies between libraries.
See also: GCC: what are the --start-group and --end-group command line options?
The order make the difference. Here's from gcc(1) manual page:
It makes a difference where in the command you write this option; the linker searches and processes libraries and object files in the order they are specified. Thus, foo.o -lz bar.o searches library z after file foo.o but before bar.o. If bar.o refers to functions in z, those functions may not be loaded.