For my header-only C++ library (lots of templates etc) I use GCov to check test coverage. However, it reports 100% coverage for all headers because the unused functions aren't generated by the compiler in the first place. Manually spotting uncovered functions is easy but defeats the purpose of continuous integration…

How does one solve this automatically? Should I just use "lines hit / LOC" as my coverage metric and just never reach 100% again?

  • 1
    You can make unit tests that calls all public methods and functions. You will get coverage as well as test that it works at the same time. Mar 12, 2012 at 12:31
  • 4
    Yeah, but I want to easily spot if I missed a function, and it would be nice if I could just browse through my CDash and see a header with <100% coverage.
    – pascal
    Mar 12, 2012 at 12:57
  • I'm also after a good answer to this question. 1. I agree that it would be nice to see uncalled instantiations. 2. I've seen no results for member templates (in template classes), where I'm absolutely sure these are instantiated and called within my testing code (which is a bit weird). May 30, 2012 at 18:08
  • OK, as for my point 2 it was simply my fault. You need to instrument your test classes as well, as far THESE will instantiate the code. I'm using the Eclipse gcov (integration) plugin to inspect my test coverage results (lcov alternatively, didn't check results there), and not instantiated template code in the template will be easy to spot as having no annotations at all. I'll put this together in a comprehensive answer ... May 30, 2012 at 19:15

4 Answers 4


Apart from the usual flags to GCC controlling inlining;

--coverage -fno-inline -fno-inline-small-functions -fno-default-inline

You can instantiate your template classes at the top of your unit test files;

template class std::map<std::string, std::string>;

This will generate code for every method in that template class making the coverage tools work perfectly.

Also, make sure that you initialise your *.gcno files (so for lcov)

lcov -c -i -b ${ROOT} -d . -o Coverage.baseline
<run your tests here>
lcov -c -d . -b ${ROOT} -o Coverage.out
lcov -a Coverage.baseline -a Coverage.out -o Coverage.combined
genhtml Coverage.combined -o HTML
  • This is a very helpful answer, thank you! I would add that if you do not compile with optimizations (which you shouldn't if you want accurate line counting coverage, see gcc.gnu.org/onlinedocs/gcc/Gcov-and-Optimization.html), then the inlining flags should not be necessary as gcc does not compile with inlining for -O0 (see towards the bottom of gcc.gnu.org/onlinedocs/gcc/Inline.html)
    – Alex
    Sep 6, 2021 at 1:15
  • It seems to me that I have the opposite problem. My classes use a non-type parameter to specify the scale. As the result, I see a lot of copies of the same method (e.g. constructor) but only a few of them have executed counts. What should I do?
    – uuu777
    Nov 3, 2022 at 16:17

I'm also using GCov to check test coverage (Tests written with Google Test framework), additionally I use the Eclipse GCov integration plugin or the LCov tool to generate easy to inspect views of the test coverage results. The raw GCov output is too hard to use :-(.

If you have header only template libraries, you also need to instrument (using G++ flag --coverage) your testing classes that instantiate the template classes and template member functions to see reasonable GCov outputs for these.

With the mentioned tools it's easy to spot template code that wasn't instantiated with the test cases at all, since it has NO annotations.

I have setup a sample and copied the LCov output to a DropBox link you can inspect.

Sample code (TemplateSampleTest.cpp is instrumented using the g++ --coverage option):


template<typename T>
class TemplateSample

    enum CodePath
        Path1 ,
        Path2 ,
        Path3 ,

    TemplateSample(const T& value)
    : data(value)

    int doSomething(CodePath path)
        case Path1:
            return 1;
        case Path2:
            return 2;
        case Path3:
            return 3;
            return 0;

        return -1;

    template<typename U>
    U& returnRefParam(U& refParam)
        return refParam;

    template<typename U, typename R>
    R doSomethingElse(const U& param)
        return static_cast<R>(data);

    void instantiatedCode()
        int x = 5;
        x = x * 10;

    void neverInstantiatedCode()
        int x = 5;
        x = x * 10;
    T data;


#include <string>
#include "gtest/gtest.h"
#include "TemplateSample.hpp"

class TemplateSampleTest : public ::testing::Test

    : templateSample(5)

    TemplateSample<int> templateSample;




    std::string stringValue = "Hello";

    std::string stringValue = "Hello";
    long value = templateSample.doSomethingElse<std::string,long>(stringValue);

See the code coverage output generated from lcov here:

TemplateSample.hpp coverage

Caveat: 'Functions' statistics is reported as 100%, which is not really true regarding the not instantiated template functions.


I stumbled across this problem too and unfortunately didn't have much luck with the various flags mentioned, I did, however, discover two ways to generate more accurate coverage information when dealing with header-only functions.

The first is to add the flag -fkeep-inline-functions (https://gcc.gnu.org/onlinedocs/gcc/Optimize-Options.html#index-fkeep-inline-functions).

This did give me just the results I was after but came with some serious problems trying to integrate with other libraries (even the normal C++ standard library). I wound up getting link errors because certain functions that should have been removed by the linker were not (e.g. a function declaration with no definition).

The second approach (the one I opted for in the end) was to use __attribute(used)__ in GCC to annotate all my header API functions. The documentation (https://gcc.gnu.org/onlinedocs/gcc-4.3.0/gcc/Function-Attributes.html) states:


This attribute, attached to a function, means that code must be emitted for the function even if it appears that the function is not referenced.

I used a #define to wrap it so I only have it turned on when I'm using GCC and coverage is enabled:

#ifdef _MSC_VER
#define MY_API
#elif defined __GNUC__ && defined COVERAGE
#define MY_API __attribute__((__used__))
#endif // _MSC_VER ? __GNUC__ && COVERAGE

Usage then looks like this:

MY_API void some_inline_function() {}

I'm going to try and write up how I got everything working at some point which I'll link to from here in future if I ever get round to it 😁

(Note: I also used -coverage -g -O0 -fno-inline when compiling)


Since I found this question super useful in setting up test coverage for my header-only library, here are some additional things I learned in hopes they can help others:

Even with all of the flags mentioned in these answers, I was still having problems with unused class methods getting optimized out. After much experimenting, I found that clang source based coverage (these flags: -fprofile-instr-generate -fcoverage-mapping) includes all class methods and is in general the most reliable way of getting coverage data. I also use the flags: -O0 -fno-inline -fno-elide-constructors to further reduce the risk of code getting optimized out.

For a large library, the template instantiation thing is still a problem. Explicitly instantiating them is all well and good, but if anyone ever forgets to, you'll get inaccurate code coverage metrics. See my answer to this question for an approach to automatically adjusting code coverage data to account for this.

  • I was unable to get coverage info for headers from -fprofile-instr-generate -fcoverage-mapping at all for my header only lib. It only gave me coverage for the .cpp test files which tested the headers (with -O0)
    – David
    Jul 15, 2018 at 17:00

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