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In our company, just until recently, we were not using namespaces because some compilers could not support them well.

This lead to numerous occurrences of the following mistake:


class Node {
    Data *ptr;
    Node() { ptr = new Data; }
    ~Node() { delete ptr; }


class Node {
    vector<int> v;
    Point *pt;
    Node(int x,int y) { pt = new Point(x,y); v.push_back(0); }
    ~Node() { delete pt; }

void foo() {
    Node n(10,10);
}    // calls file_B::~Node() !!!

Each author Node did not know the existence of the other Node, but since he expected that this class name might be reused, he refrained from creating a .hpp file with it.

The compiler silently removes one of the destructors, as their signature matches, and the bug is hard to find, since it may not replicate in different computers.

Once the error had been identified, people gradually became aware of it, and they try to seal the definitions in unnamed namespaces, or avoid inilining the member functions in the class' body [see below].

  • Question 1: Since you can't trust that the programmer will always remember to program defensively, is there a tool that can detect these "unintended weak link symbols" ?

    By unintended I mean, Node classes were not defined in .hpp files, and at least one class member doesn't match between the class definitions...

  • Question 2: If we don't use namespaces, but we do inline every function, is there a possibility that the auto-generated functions (copy-ctor, copy-assignment, destructor) will create the aforementioned "weak link bug" ?

Way 1: enclose in unnamed namespaces

namespace {
  class Node {
     Data *ptr;
     Node() { ptr = new Data; }
     ~Node() { delete ptr; }

Way 2: avoid inlining

class Node {
   Data *ptr;

Node::Node()  { ptr = new Data; }
Node::~Node() { delete ptr; }
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The sample code looks to me like it ought to call file_B::~Node() –  Mooing Duck Nov 29 '11 at 21:47
What compilers support namespaces badly? I'm just interested. –  Beginner Nov 29 '11 at 21:49
@MooingDuck: One of the 2 destructors whose signature match, will be kept. So, it might call the (file_B)::~Node() –  Grim Fandango Nov 29 '11 at 21:50
@AShelly at what rate do you perform code reviews? For every file that is committed? Or randomly? –  Grim Fandango Nov 29 '11 at 22:32
I believe the existing codebase actually violates the One Definition Rule, and thus the program is invalid C++. Your distinct types must have -- after qualification -- different names. So it's not just "bad form": it's wrong. Trying to hack around it is not recommended. –  Lightness Races in Orbit Nov 29 '11 at 23:34
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2 Answers

up vote 2 down vote accepted

If your code base is large enough to justify the effort, you could customize an existing compiler to tackle with your issue:

  1. The LLVM/Clang compiler is customizable (it is in C++, and I don't know it very well).
  2. The GCC compiler (recent versions like 4.6) is extensible, either thru plugins coded in C, or thru extensions coded in MELT. MELT is a (free, GPLv3 licensed) high level domain specific language to extend GCC.

In both cases, it is a effort of several days or weeks, and the most difficult is to understand partly the compiler internal representations (Gimple & Tree for GCC) and organizations (e.g. passes).

I am the main author of MELT and I will be delighted to help you with MELT, so feel free to contact me.

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We're ~5 million lines, currently growing by about 1 million each year. But the side-effects of such bug are really costly. –  Grim Fandango Nov 29 '11 at 21:58
I think it is an excellent use case for MELT... but again, you should be able to spend weeks on it, not only a few hours... –  Basile Starynkevitch Nov 29 '11 at 21:59
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"C++ and the linker" is a very interesting read regarding this issue. See specifically the section called 'Rules Without Enforcement Mean Nothing'.

One insight is that you can detect "Weak" Symbols by parsing the object files, and looking for "W"s:

$ nm -C foo.o | grep doSomething
00000000 W doSomething()

So you may be able to add a post-process step which automatically collects these and lists the duplicates. You can compare these to a master list of intended duplicates, and raise a flag if there are any new ones.

Another option might be gcc's -Fno-weak option. It's not clear from the docs what will happen on duplicates, but it might be interesting to find out.

The linked article also answers your second question (the "above phenomenon" refers to deleting all but one instance of a duplicated weak symbol):

In some cases the compiler has to create a symbol although it inlines the function. This can happen for example when a function pointer references the function. So, the above phenomenon does not always disappear when optimization is enabled.

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