I think that many static analysis tools may not give you what you need since they don't necessarily take into account things like template instantiations, header inclusions (including those pulled in by precompiled headers) and the code generation characteristics of the compiler.
I've faced a similar problem in the past, with a large executable whose size was dominated by a particular library. The way I got to the bottom of it was simply to look at the size of the object files for each .cpp. That won't give you the full story as the linker will optimise out unused portions (though it's worth checking you've got that option set -
/OPT:REF for Visual Studio). It will though allow you to focus your search. Find the two or three largest object files and then look at the corresponding .cpp files. You've then got two options - write a script that takes the output of
objdump (VisualStudio) or
nm -C (gcc) where you can extract the offsets of each function in the module, so you can diff each with the previous to get an idea of the size of each function.
Or the simplest method is just to use binary search on the cpp file. #ifdef out all the code after the end of the #includes and compile it. That will give you an idea of the overhead of the includes (if that itself is huge then you can drill down into the header inclusions to find which contributes the most). Next, disable each half the code with #ifdef and find which half is the larger. Using this method you can quickly find the functions that contribute most to the size of the library.
In the case of the library I had which had this same problem, the cause turned out to be a very large templated function that was instantiated every time a member variable was saved. The solution in that case was to make the function concrete so that all the code that didn't require type-specific behaviour is only instantiated once, and the template functions are localised for the bits of logic that are type-specific.