I am working on a little project to understand the chain of compiler and linker better.
Suppose that i have the libraries libfoo.a and libbar.a. I want to create a library libmy.a, that acts like a wrapper or top level API to both libraries. The target is, that only libmy.a should be required to build an executable, that uses my defined wrapper functions. I created a cmake project and set up the library
cmake_minimum_required(VERSION 3.14)
project(Wrapper)
set(CMAKE_CXX_STANDARD 11)
add_library(my STATIC ${SOME_SRC_FILES})
#set up the lib/inc paths and libs to link
target_include_directories(my PUBLIC /path/to/Foo/inc/ /path/to/Bar/inc/)
target_link_directories(my PUBLIC /path/to/Foo/lib/ /path/to/Bar/lib)
target_link_libraries(my PUBLIC foo bar)
That works fine and there is no problem in compilation. However, if I try to reference the object from an external project, it tells me, that I have undefined references to the functions in libfoo.a and libbar.a. As far as I understand the problem, the linker only creates a declaration in the libmy.a, without including its definition from the external library. I checked this by opening libmy.a with the nm libmy.a command, where the used functions of the external libraries are declared, but undefined.
I came across one solution that used ar to combine multiple library files. However I would like to avoid such methods, because if it is not a single library, but a bunch of, say 10 libraries, it is not suitable to search each library for a definition and copy it into libmy.a. Just throwing all libraries together isn't a solution either, because the file will get too big.
Is it importand to note, that one of these library packages is CUDA?
I am sure there is a solution, but I was not able to find one. Any help would be appreciated
The target is, that only libmy.a should be required to build an executable
This is already an unconventional goal for static libraries.
Static libraries normally only contain the object code built from the source code for that library. Users of that library must also link to the libraries that your library requires, because the definitions have not been copied in to your library when it was built.
Tools like ar can be used to combine multiple static libraries together, since they are just archives of object code. The tool can not predict which object code the end-user will use though, so it will bundle entire libraries. Otherwise, the end user may be looking for a definition that you left out and then need to link in a 2nd copy of the dependency lib anyways.
If you want to provide a library that has everything the end-user needs, cut down to what your wrapper actually uses, you can build a shared library. Shared libraries are considered executable, so the compiler knows that any unreferenced object code is not going to be used, and it will not be included in the shared library.
You can force the entire static libraries to be included in shared libraries though.
On GCC you can use the linker argument: --whole-archive to ensure that all of the object code from the following libraries is included.
On MSVC, you can use the /WHOLEARCHIVE:<library file name> argument to do the same.
Related
I have a C++ project called testlib.pro (using Qtcreator) which will create a static library libtest.a.
The project is also included staticlib.a (example) and staticlib1.a. i.e using someother static libraries im creating one static library. After creating static library, Im creating C wrapper (testApi.c) to use the C++ code using the static library. I am compiling the testApi.c using the below option
gcc -o demo testApi.c -L ./testlib -ltest
But it is giving linker errors which stats that it requires the static libraries which i used to link the libtest.a. So i recompile the program with below comment and it works fine
gcc -o demo testApi.c -L ./testlib -ltest -lstatuclib -lstaticlib1
My understanding is If I ship the libtest.a to someother machine and try to compile testApi.c file it may requires staticlib.a and staticlib1.a in that machine. But I would like to use only newly created static library libtest.a. Am i missing any?
NOTE: I have included staticlib.a, staticlib1.a using -l option in my testlib.pro
If your library uses other static libraries then they will also need to be provided at link time.
There is an ugly way around it (on Linux). You can unpack existing static library (or several of them) and repack them into a new library. So you could, if you felt particularly frisky, unpack those libraries that yours depends on, then pack their contents along with your own stuff into a new library. Ugly, confusing, possibly causing all sorts of other problems, but if that is the way you want to go...
The static library concept is archaic in nature. When a program had a lot of modules, it was sometimes impossible to put them all in the command line for the linker to add them to the program. Also, for libraries, as the .o modules where all being included in the final executable, there had to be some mechanism to allow the linker select only the needed modules and not to include all of them in the final executable, or the executables will grow a lot including modules that the program will not use. Both things where solved with the introduction of dynamic shared objects, so using .a files is somewhat deprecated today and it is only used for statically linking programs.
Anyway, the algorithm to select the object modules in the linker is not recursive, so when it opens a .a library to search for dependent files to be included in the final executable, it searches only for .o (and probably .so, but I have not tested this), and it will ignore any .a file it finds in there. Many systems include an index file in the archive that has a mapping between provided identifiers, and the name of the module that provides them, so in one pass the compiler knows which archived objects need to be extracted. That index file should be appended (and rebuilt) in case a library (with its own index) where included in the file, so this justifies not using recursion at all in the library search.
The solution for this problem, is to link all those libraries you need to make the final executable, or as you have already been told, to extract the .o files in the library and put them in another library. There is still a third solution, that is: The linker allows you to specify a file that has options (and you can specify library names, and .o files you want it to scan) and it will read that file to check the set of libraries you want it to scan.
Another point is that the linker never includes a library as such. A library is just an archive (like a .tar or .zip file) in which the linker explores and extracts the files it needs, so there's no need to make the search algorithm recursive at all. And there's no difference between an archived file in a library and that same file out of the archive.
I need to provide an SDK with a static library. Let's call it "libsdk.a".
This library should hopefully be standalone, meaning a simple example "example.cpp" could link against it without any other library, except the system ones.
Here my configuration :
cmake for all my 10 dependencies libraries. There is a static library (.a) generated for each of my module. These libraries contain only object files .o of the given module. Dependency tree is not flat, some of them depends on others.
a simple example "example.cpp", with a cmake, which compiles and works. At this level, cmakes generates a very complex link command to deal with deps tree.
external dependencies such as boost (some static libraries too)
At the moment, I tried this :
make an archive of the different .a generated but it doesn't work because linking against this lib tells me the archive a no index (even after ranlib). Yet, I remembered I could add .a libraries inside .a files without problems.
extract all .o object (with ar -x) files from all *.a files and recreated a "libsdk.a" with all these object files. It doesn't work either (unresolved references). Moreover, it includes all objects even those which are not needed... My working example takes 3.7M. This library is around 35M.
make a .so shared library. It seems to work but I would prefer having a static library.
compile all statically but then linker complains it doesn't find -lgcc_s. Ok I want to compile in static but not that far, and just my own libs together !
So my final question : is there any way I can generate my static lib containing all my other libs, and not system ones ?
BTW, another interesting topic on that :
Combining static libraries
Thank you for any piece of advice to open my mind !
What you are trying to do by hand is the job of the linker. While it's feasible, you shouldn't bother with it.
When you compile libsdk.a, make sure that all of its dependencies are linked statically. If you do this, libsdk.a should be standalone. Static linking means copying the code to the right places in the final executable, so anything that is linked statically will not need to be provided in an external file.
See this post on CMake mailing list. libutils.cmake attached to the message has MERGE_STATIC_LIBS() macro that does the job. On Linux (and all other Unixes except OSX) it uses ar to pack and unpack objects files.
I have a software library and I used to create .a files, so that people can install them and link against them: g++ foo.o -L/path/to -llibrary
But now I often encounter third-party libraries where only .so files are available (instead of .a), and you just link against them without the -l switch, e.g. g++ foo.o /path/to/liblibrary.so.
What are the differences between these solutions? Should I prefer creating .so files for the users of my library?
Typically, libfoo.a is a static library, and libfoo.so is a shared library. You can use the same -L/-l linker options against either a static or shared. Or you can name the full path to the lib with static or shared. Often libraries are built both static and shared to provide application developers the choice of which they want.
All the code needed from a static lib is part of the final executable. This obviously makes it bigger, but it also means it's self-contained. Once it is compiled, you can run your app without the lib.
Code from a shared lib is not part of the executable. There are just some hooks in place to make the executable aware of the name of the lib it needs. In order to run your app, the shared lib has to be present in the lib search path (e.g. $LD_LIBRARY_PATH).
If you have two apps that share the same code, they can each link against a shared lib to keep the binary size down. If you want to upgrade parts of the app without rebuilding the whole thing, shared libs are good for that too.
Good overview of static, shared dynamic and loadable libraries at
http://www.yolinux.com/TUTORIALS/LibraryArchives-StaticAndDynamic.html
Some features that aren't really called out from comments I've seen so far.
Static linkage (.a/.lib)
Sharing memory between these compilation units is generally ok because they should(?will) all be using the same runtime.
Static linkage means you avoid 'dll hell' but the cost is recompilation to make use of any change at all. static linkage into Shared libraries (.so) can lead to strange results if you have more than 1 such shared library used by the final executable - global variables may exist multiple times and which one is used and when they are initialised can cause an entirely different hell.
The library will be part of the shipped product but obfuscated and not directly usable.
Shared/Dynamic libraries (.so/.dll)
Sharing memory between these compilation units can be hazardous as they may choose to use different runtime. This can mean you provide different Shared/Dynamic libraries based on the debug/release or single/multi threaded or...
Shared libraries (.so) are less prone to 'dll hell' then Dynamic libraries (.dll) as they include options for quite specific versioning.
Compiling against a .so will capture version information internal to the file (hard to fake) so that you get quite specific .so usage. Compiling against the .lib/.dll only gives a basic file name, any versioning is done managed by the developer (using naming or manually loading the library and checking version details by hand)
The library will have to ship with the final product (somebody else can pick it up and use it)
But now I often encounter third-party libraries where only .so files are available [...] and you just link against them without the -l switch, e.g. g++ foo.o /path/to/liblibrary.so.
JFYI, if you link to a shared library which does not have a SONAME set (compare with readelf -a liblibrary.so), you will end up putting the specified path of liblibrary.so into your target object (executable or another shared library), and which is usually undesired, for users have their own ideas of where to put a program and its associated files. The preferred way is to use -L/path/to -llibrary, perhaps together with -Wl,-rpath,/whatever/path/to if this is the final path (such pathing decisions are made by Linux distributions for example).
Should I prefer creating .so files for the users of my library?
If you distribute source code, the user will make the particular choice.
I have a bunch of projects that all could share a "common" static library of classes.
What confuses me is if I make a static library out of these classes and link against it in my projects that I still need the headers of the classes in the static library in my main projects.
What is the benefit of the static library then?
How do companies like Adobe deal with this?
Static libraries allow you to create a library and use that library in many projects.
The need for header files:
Since the project using the library is programmed and compiled independent of the library, that program needs to know the declaration of the things you're using. Otherwise how would your compiler know you're writing valid code?
A compiler only takes source code as input and produces output. It does not deal with compiled object files or static libraries on input.
The need for linking in the library:
So having the headers allows you to write valid code in your project, but when it comes to link time you'll need to provide the definition which is contained inside the static library.
The linker takes all object files (compiled code) and also all static libraries and produces an executable or binary.
More info about static libraries (benefits, comparing dynamic, etc...):
Amongst other things, it is nice to separate your project into libraries so that you don't end up with 1 huge monolithic project.
You do not need to distribute the source code (typically in the .cpp files) this way.
If you were to simply include all the .cpp files in every project that used the common library then you would have to compile the .cpp files each time.
An advantage of static libraries over dynamic libraries is that you can always be sure that your programs will be self contained and that they are using the correct version of the library (since they are compiled into the executable itself). You will also have a slight speed advantage over dynamic linking.
Disadvantages of static libraries over dynamic libraries include that your file sizes will be bigger because each executable needs their own copy, and that you can't swap out a different version of the library since it's not dynamically loaded.
Re your question: How do companies deal with this:
A typical company will make use of both static and dynamic libraries extensively.
The typical way you make use of a static library is to have a target in your Makefile (or whatever build system you use) that installs the headers into an appropriate location at the same time that it installs the library.
So, your static library ends up in /usr/local/lib, and the headers go into /usr/local/include or wherever.
Also, when compared with linking against object files, linking against static library may result is a smaller final executable. The reason for this is, if you don't call any of the functions from a particular object file (included in the static library), the linker will not include the code for those functions in you final executable. See Extraneous Library Linkage
In my quest to learn C++, I have come across dynamic and static libraries.
I generally get the gist of them: compiled code to include into other programs.
However, I would like to know a few things about them:
Is writing them any different than a normal C++ program, minus the main() function?
How does the compiled program get to be a library? It's obviously not an executable, so how do I turn, say 'test.cpp' into 'test.dll'?
Once I get it to its format, how do I include it in another program?
Is there a standard place to put them, so that whatever compilers/linkers need them can find them easily?
What is the difference (technically and practically) between a dynamic and static library?
How would I use third party libraries in my code (I'm staring at .dylib and .a files for the MySql C++ Connector)
Everything I have found relating to libraries seems to be targeting those who already know how to use them. I, however, don't. (But would like to!)
Thanks!
(I should also note I'm using Mac OS X, and although would prefer to remain IDE-neutral or command-line oriented, I use QtCreator/Netbeans)
Is writing them any different than a normal C++ program, minus the main() function?
No.
How does the compiled program get to be a library? It's obviously not an executable, so how do I turn, say 'test.cpp' into 'test.dll'?
Pass the -dynamiclib flag when you're compiling. (The name of the result is still by default a.out. On Mac OS X you should name your dynamic libraries as lib***.dylib, and on Linux, lib***.so (shared objects))
Once I get it to its format, how do I include it in another program?
First, make a header file so the the other program can #include to know what functions can be used in your dylib.
Second, link to your dylib. If your dylib is named as libblah.dylib, you pass the -lblah flag to gcc.
Is there a standard place to put them, so that whatever compilers/linkers need them can find them easily?
/usr/lib or /usr/local/lib.
What is the difference (technically and practically) between a dynamic and static library?
Basically, for a static lib, the whole library is embedded into the file it "links" to.
How would I use third party libraries in my code (I'm staring at .dylib and .a files for the MySql C++ Connector)
See the 3rd answer.
Is writing them any different than a normal C++ program, minus the main() function?
Except for the obvious difference that a library provides services for other programs to use, usually (*) there isn't a difference.
* in gcc classes/functions are exported by default - this isn't the case in VC++, there you have to explicitly export using __declspec(export).
How does the compiled program get to be a library? It's obviously not an executable, so how do I turn, say 'test.cpp' into 'test.dll'?
This depends on your compiler. In Visual Studio you specify this in your project configuration. In gcc to create a static library you compile your code normally and then package it in an archive using ar. To create a shared you compile first (with the -fpic flag to enable position independent code generation, a requirement for shared libraries), then use the -shared flag on the object files. More info can be found in the man pages.
Once I get it to its format, how do I include it in another program?
Again this is a little compiler-dependant. In VS, if it's a shared library, when including the class/function you wish to use it should be marked with a __declspec(import) (this is usually done with ifdefs) and you have to specify the .lib file of the shared library for linkage. For a static library you only have to specify the .lib file (no export/import needed since the code will end up in your executable).
In gcc you only need to specify the library which you link against using -llibrary_name.
In both cases you will need to provide your client some header files with the functions/classes that are intended for public use.
Is there a standard place to put them, so that whatever compilers/linkers need them can find them easily?
If it's your own library then it's up to you. Usually you can specify the linker additional folders to look in. We have a lib folder in our source tree where all .lib (or .a/.so) files end up and we add that folder to the additional folder to look in.
If you're shipping a library on UNIX the common place is usually /usr/lib (or /usr/local/lib), this is also where gcc searches in by default.
What is the difference (technically and practically) between a dynamic and static library?
When you link a program to static libraries the code of the libraries ends up in your executable. Practically this makes your executable larger and makes it harder to update/fix a static library for obvious reasons (requires a new version of your executable).
Shared libraries are separate from your executable and are referenced by your program and (usually) loaded at runtime when needed.
It's also possible to load shared libraries without linking to them. It requires more work since you have to manually load the shared library and any symbol you wish to use. On Windows this is done using LoadLibrary/GetProcAddress and on POSIX systems using dlsym/dlopen.
How would I use third party libraries in my code?
This is usually accomplished by including the necessary header files and linking with the appropriate library.
A simple example to link with a static library foo would look like this: gcc main.cpp -o main.o -L/folder/where/foo.a/is/at -lfoo.
Most open source projects have a readme that gives more detailed instructions, I'd suggest to take a look at it if there is one.
Is writing [libraries] any different than a normal C++ program, minus the main() function?
That depends on your definition of "different." From the language's point of view, you write a file or collection of files, don't put in a main() and you tell the compiler to generate a library instead of an executable.
However, designing libraries is much harder because you have no control over the code that calls you. Libraries need to be more robust against failure than normal code. You can't necessarily delete pointers somebody passes to your function. You can't tell what macros will mess with your code. You also can't accidentally pollute the global namespace (eg., don't put using namespace std at the beginning of your header files).
How does the compiled program get to be a library? It's obviously not an executable, so how do I turn, say 'test.cpp' into 'test.dll'?
That depends on the compiler. In Visual C++ this is a project config setting. In gcc (going from memory) it's something like gcc -c foo.c -shared.
Once I get it to its format, how do I include it in another program?
That depends on your compiler and linker. You make sure the header files are available via a project setting or environment variable, and you make sure the binaries are available via a different project setting or compiler variable.
Is there a standard place to put them, so that whatever compilers/linkers need them can find them easily?
That depends on the operating system. In UNIX you're going to put things in places like /usr/lib, /usr/local/lib. On Windows people used to put DLLs in places like C:\WINDOWS but that's no longer allowed. Instead you put it in your program directory.
What is the difference (technically and practically) between a dynamic and static library?
Static libraries are the easier, original model. At compile time the linker puts all the functions from the library into your executable. You can ship the executable without the library, because the library is baked in.
Dynamic libraries (also called shared libraries) involve the compiler putting enough information in the executable that at runtime the linker will be able to find the correct libraries and call the methods in there. The libraries are shared across the whole system among the programs that use them. Using dynamic linking (dlsym(), et. al.) adds a few details to the picture.
How would I use third party libraries in my code (I'm staring at .dylib and .a files for the MySql C++ Connector)
That's going to depend on your platform, and unfortunately I can't tell you much about .dylib files. .a files are static libraries, and you simply need to add them to your final call to gcc (gcc main.c foo.a -o main if you know where foo.a is, or gcc main.c -lfoo -o main if the system knows where foo.a, foo.la, or foo.so are). Generally you make sure the compiler can find the library and leave the linker to do the rest.
The difference between a static and dynamic library is that the linking is done at compile time for static libraries, embedding the executable code into your binary, while for dynamic libraries linking is done dynamically at program start. The advantages are that the libraris can be separately distributed, updated and the code (memory) can be shared among several programs.
To use a library you simply provide -l to g++ for a lib.a or lib.so
I'm writing this to be more pragmatic than technically correct. It's enough to give you the general idea of what you're after.
Is writing them any different than a normal C++ program, minus the main() function?
For a static library, there's really not much difference.
For a dynamic library, the most likely difference you'll need to be aware of is that you may need to export the symbols you want to be available outside your library. Basically everything you don't export is invisible to users of your library. Exactly how you export, and whether you even need to by default, depends on your compiler.
For a dynamic library you also need to have all symbols resolved, which means the library can't depend on a function or variable that comes from outside the library. If my library uses a function called foo(), I need to include foo() in my library by writing it myself or by linking to another library that supplies it. I can't use foo() and just assume the user of my library will supply it. The linker won't know how to call a foo() that doesn't yet exist.
How does the compiled program get to be a library? It's obviously not an executable, so how do I turn, say 'test.cpp' into 'test.dll'?
It's similar to how you turn test.cpp into test.exe - compile and link. You pass options to the compiler to tell it whether to create an executable, a static library, or a dynamic library.
Once I get it to its format, how do I include it in another program?
In your source code, you include header files necessary to use the library, much as you would include a header file for code that's not in a library. You'll also need to include the library on your link line, telling the linker where to find the library. For many systems, creating a dynamic library generates two files, the shared library and a link library. It's the link library that you include on the link line.
Is there a standard place to put them, so that whatever compilers/linkers need them can find them easily?
There is an environment variable that tells the linker where to look for libraries. The name of that variable is different from one system to another. You can also tell the linker about additional places to look.
What is the difference (technically and practically) between a dynamic and static library?
A static library gets copied into the thing it is linked to. An executable will include a copy of the static library and can be run on another machine without also copying the static library.
A dynamic library stays in a separate file. The executable loads that separate file when it runs. You have to distribute a copy of the dynamic library with your program or it won't run. You can also replace the dynamic library with a new version, and as long as the new library has the same interface it will still run with the old executable. It also may save space if several executables use the same dynamic library. In fact dynamic libraries are often called shared libraries.
How would I use third party libraries in my code
Same as you would use one you created yourself, as described above.