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When I use gcov to measure test coverage of C++ code it reports branches in destructors.

struct Foo
{
    virtual ~Foo()
    {
    }
};

int main (int argc, char* argv[])
{
    Foo f;
}

When I run gcov with branch probabilities enabled (-b) I get the following output.

$ gcov /home/epronk/src/lcov-1.9/example/example.gcda -o /home/epronk/src/lcov-1.9/example -b
File 'example.cpp'
Lines executed:100.00% of 6
Branches executed:100.00% of 2
Taken at least once:50.00% of 2
Calls executed:40.00% of 5
example.cpp:creating 'example.cpp.gcov'

The part that bothers me is the "Taken at least once:50.00% of 2".

The generated .gcov file gives more detail.

$ cat example.cpp.gcov | c++filt
        -:    0:Source:example.cpp
        -:    0:Graph:/home/epronk/src/lcov-1.9/example/example.gcno
        -:    0:Data:/home/epronk/src/lcov-1.9/example/example.gcda
        -:    0:Runs:1
        -:    0:Programs:1
        -:    1:struct Foo
function Foo::Foo() called 1 returned 100% blocks executed 100%
        1:    2:{
function Foo::~Foo() called 1 returned 100% blocks executed 75%
function Foo::~Foo() called 0 returned 0% blocks executed 0%
        1:    3:    virtual ~Foo()
        1:    4:    {
        1:    5:    }
branch  0 taken 0% (fallthrough)
branch  1 taken 100%
call    2 never executed
call    3 never executed
call    4 never executed
        -:    6:};
        -:    7:
function main called 1 returned 100% blocks executed 100%
        1:    8:int main (int argc, char* argv[])
        -:    9:{
        1:   10:    Foo f;
call    0 returned 100%
call    1 returned 100%
        -:   11:}

Notice the line "branch 0 taken 0% (fallthrough)".

What causes this branch and what do I need to do in the code to get a 100% here?

  • g++ (Ubuntu/Linaro 4.5.2-8ubuntu4) 4.5.2
  • gcov (Ubuntu/Linaro 4.5.2-8ubuntu4) 4.5.2
share|improve this question
    
How do I get a 100% here is still not answered. –  Eddy Pronk Aug 28 '11 at 23:05
    
See my updated answer for an exhaustive explanation of what is happening here. –  AndreyT Aug 31 '11 at 4:08

2 Answers 2

up vote 37 down vote accepted
+100

In a typical implementation the destructor usually has two branches: one for non-dynamic object destruction, another for dynamic object destruction. The selection of a specific branch is performed through a hidden boolean parameter passed to the destructor by the caller. It is usually passed through a register as either 0 or 1.

I would guess that, since in your case the destruction is for a non-dynamic object, the dynamic branch is not taken. Try adding a new-ed and then delete-ed object of class Foo and the second branch should become taken as well.

The reason this branching is necessary is rooted in the specification of C++ language. When some class defines its own operator delete, the selection of a specific operator delete to call is done as if it was looked up from inside the class destructor. Many compilers implement this requirement literally: the proper operator delete is called literally from inside the destructor implementation. Of course, operator delete should only be called when destroying dynamically allocated objects. To achieve this, the call to operator delete is placed into a branch controlled by that hidden parameter.

In your example things look pretty trivial. I'd expect the optimizer to remove all unnecessary branching. However, it appears that somehow it managed to survive optimization.


Here's a little bit of additional research. Consider this code

#include <stdio.h>

struct A {
  void operator delete(void *) { scanf("11"); }
  virtual ~A() { printf("22"); }
};

struct B : A {
  void operator delete(void *) { scanf("33"); }
  virtual ~B() { printf("44"); }
};

int main() {
  A *a = new B;
  delete a;
} 

This is how the code for the destructor of A will look like when compiler with GCC 4.3.4 under default optimization settings

__ZN1AD2Ev:                      ; destructor A::~A  
LFB8:
        pushl   %ebp
LCFI8:
        movl    %esp, %ebp
LCFI9:
        subl    $8, %esp
LCFI10:
        movl    8(%ebp), %eax
        movl    $__ZTV1A+8, (%eax)
        movl    $LC1, (%esp)     ; LC1 is "22"
        call    _printf
        movl    $0, %eax         ; <------ Note this
        testb   %al, %al         ; <------ 
        je      L10              ; <------ 
        movl    8(%ebp), %eax    ; <------ 
        movl    %eax, (%esp)     ; <------ 
        call    __ZN1AdlEPv      ; <------ calling `A::operator delete`
L10:
        leave
        ret

(The destructor of B will be a bit more complicated, which is why I use A here as an example. But as far as the branching in question is concerned, destructor of B does it in the same way).

However, right after this destructor the generated code will contain another version of the destructor for the very same class A, which looks exactly the same, except the movl $0, %eax instruction is replaced with movl $1, %eax instruction.

__ZN1AD0Ev:                      ; another destructor A::~A       
LFB10:
        pushl   %ebp
LCFI13:
        movl    %esp, %ebp
LCFI14:
        subl    $8, %esp
LCFI15:
        movl    8(%ebp), %eax
        movl    $__ZTV1A+8, (%eax)
        movl    $LC1, (%esp)     ; LC1 is "22"
        call    _printf
        movl    $1, %eax         ; <------ See the difference?
        testb   %al, %al         ; <------
        je      L14              ; <------
        movl    8(%ebp), %eax    ; <------
        movl    %eax, (%esp)     ; <------
        call    __ZN1AdlEPv      ; <------ calling `A::operator delete`
L14:
        leave
        ret

Note the code blocks I labeled with arrows. This is exactly what I was talking about. This "pseudo-branch" is supposed to either call or skip the call to operator delete in accordance with the value of al. However, in the first version of the destructor this parameter is hardcoded into the body as always 0, while in the second one it is hardcoded as always 1.

Class B also has two versions of the destructor generated for it. So we end up with 4 distinctive destructors in the compiled program: two destructors for each class.

So, what happens in this case is at the beginning the compiler internally thinks in terms of a single "parameterized" destructor (which works exactly as I described above the break). And then it decides to split the parameterized destructor into two independent non-parameterized versions: one for the hardcoded parameter value of 0 (non-dynamic destructor) and another for the hardcoded parameter value of 1 (dynamic destructor). In non-optimized mode it does that literally, by assigning the actual parameter value inside the body of the function and leaving all the branching totally intact. This is acceptable in non-optimized code, I guess. And that's exactly what you are dealing with.

In other words, the answer to your question is: It is impossible to make the compiler to take all the branches in this case. There's no way to achieve 100% coverage. Some of these branches are "dead". It is just that the approach to generating non-optimized code is rather "lazy" and "loose" in this version of GCC.

There might be a way to prevent the split in non-optimized mode, I think. I just haven't found it yet. Or, quite possibly, it can't be done. Older versions of GCC used true parameterized destructors. Maybe in this version of GCC they decided to switch to two-destructor approach and while doing it they "reused" the existing code-generator in such a quick-and-dirty way, expecting the optimizer to clean out the useless branches.

When you are compiling with optimization enabled GCC will not allow itself such luxuries as useless branching in the final code. You should probably try to analyze optimized code. Non-optimized GCC-generated code has lots of meaningless inaccessible branches like this one.

share|improve this answer
    
I tried the different optimization levels, but for this case it doesn't have any impact. –  Eddy Pronk Aug 26 '11 at 4:45
    
adding a new-ed and then delete-ed object of class Foo makes it touch both dtor symbols, but doesn't affect the branch. –  Eddy Pronk Aug 26 '11 at 4:56
2  
@Eddy: do not forget that if the new occurs in the same scope as the delete, then the compiler may be smart enough to deduce the true dynamic type of the object and devirtualize the call to the destructor. –  Matthieu M. Aug 26 '11 at 7:06
    
@Eddy Pronk: OK, that probably means that instead of "branched destructor" approach GCC uses "two non-branched destructors" approach. In that case I don't know what that branching is doing there. Could it be just some kind of placeholder for inserting something in the future? Or maybe just something added to improve pipelining/alignment/branch prediction? –  AndreyT Aug 26 '11 at 15:28
1  
@AndreyT Impressive answer and discussion. Thanks! –  Eddy Pronk Sep 4 '11 at 2:43

In the destructor, GCC generated a conditial jump for a condition which can never be true (%al is not zero, since it was just assigned a 1):

[...]
  29:   b8 01 00 00 00          mov    $0x1,%eax
  2e:   84 c0                   test   %al,%al
  30:   74 30                   je     62 <_ZN3FooD0Ev+0x62>
[...]
share|improve this answer
    
any idea why it's not optimized away ? It seems an inconditional jump would be better. –  Matthieu M. Aug 26 '11 at 7:04
    
In that particular case I didn't give GCC any -O options, but even with -O there are some "interesting" control flow patterns (like calling an address which is in the middle of the calling function). I guess you could also make a case that without -O it shouldn't generate such code -- but maybe they have their reasons? –  Adam Mitz Aug 26 '11 at 12:16
    
I don't know, assembler is still a mythologic beast to me as I never really dug in :) –  Matthieu M. Aug 26 '11 at 12:22
1  
Scratch that last bit about calling an address in the middle of the calling function: I was looking at the wrong disassembly output (before linking and resolving relocations). –  Adam Mitz Aug 30 '11 at 1:27
2  
Gosh! What the hell is being done here je 62 <_ZN3FooD0Ev+0x62>? Adding an offset to the function base address? :-/ –  Nawaz Sep 1 '11 at 6:20

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