I am trying to learn and understand name mangling in C++. Here are some questions:

(1) From devx

When a global function is overloaded, the generated mangled name for each overloaded version is unique. Name mangling is also applied to variables. Thus, a local variable and a global variable with the same user-given name still get distinct mangled names.

Are there other examples that are using name mangling, besides overloading functions and same-name global and local variables ?

(2) From Wiki

The need arises where the language allows different entities to be named with the same identifier as long as they occupy a different namespace (where a namespace is typically defined by a module, class, or explicit namespace directive).

I don't quite understand why name mangling is only applied to the cases when the identifiers belong to different namespaces, since overloading functions can be in the same namespace and same-name global and local variables can also be in the same space. How to understand this?

Do variables with same name but in different scopes also use name mangling?

(3) Does C have name mangling? If it does not, how can it deal with the case when some global and local variables have the same name? C does not have overloading functions, right?

Thanks and regards!

6 Answers 6


C does not do name mangling, though it does pre-pend an underscore to function names, so the printf(3) is actually _printf in the libc object.

In C++ the story is different. The history of it is that originally Stroustrup created "C with classes" or cfront, a compiler that would translate early C++ to C. Then rest of the tools - C compiler and linker would we used to produce object code. This implied that C++ names had to be translated to C names somehow. This is exactly what name mangling does. It provides a unique name for each class member and global/namespace function and variable, so namespace and class names (for resolution) and argument types (for overloading) are somehow included in the final linker names.

This is very easy to see with tools like nm(1) - compile your C++ source and look at the generated symbols. The following is on OSX with GCC:

namespace zoom
    void boom( const std::string& s )
        throw std::runtime_error( s );

~$ nm a.out | grep boom
0000000100001873 T __ZN4zoom4boomERKSs

In both C and C++ local (automatic) variables produce no symbols, but live in registers or on stack.


Local variables do not have names in resulting object file for mere reason that linker does not need to know about them. So no name, no mangling. Everything else (that linker has to look at) is name-mangled in C++.

  • 5
    This is even more fun if you have nested template instantiations :-) May 30, 2010 at 3:21
  • 13
    Yeh, I usually call it pain though ... :) May 30, 2010 at 3:25
  • Thanks Nikolai! As you said "In both C and C++ local (automatic) variables produce no symbols, but live in registers or on stack", are the names of local variables mangled or not in C++? If not, what kinds of variables' names are mangled?
    – Tim
    May 30, 2010 at 18:36
  • 1
    The leading underscore in C is only present on a few odd platforms, it is very far from a general rule. Apr 25, 2019 at 7:28

Mangling is simply how the compiler keeps the linker happy.

In C, you can't have two functions with the same name, no matter what. So that's what the linker was written to assume: unique names. (You can have static functions in different compilation units, because their names aren't of interest to the linker.)

In C++, you can have two functions with the same name as long as they have different parameter types. So C++ combines the function name with the types in some way. That way the linker sees them as having different names.

The exact manner of mangling is not significant to the programmer, only the compiler, and in fact every compiler does it differently. All that matters is that every function with the same base name is somehow made unique for the linker.

You can see now that adding namespaces and templates to the mix keeps extending the principle.

  • 3
    "Note that it doesn't matter how the name gets mangled". It DOES matter - for example when you link libraries compiled by different compilers. That's why many C++ libraries are shipped in many versions, one for MSVC, one for mingw/gcc etc. Mar 21, 2014 at 9:02
  • 2
    What I meant was: the exact manner of mangling is not significant to you, the programmer.
    – egrunin
    Mar 21, 2014 at 15:49
  • So important not to break backwards compatibility with a current API could be to add a default parameter to a function. The main question would be, does the new function have a different mangled name? From what I'm reading here, the answer is most likely YES :-(
    – jaques-sam
    Jul 9, 2021 at 7:18

Technically, it's "decorating". It sounds less crude but also mangling sort of implies that CreditInterest might get rearranged into IntCrederestit whereas what actually happens is more like _CreditInterest@4 which is, fair to say, "decorated" more than mangled. That said, I call it mangling too :-) but you'll find more technical info and examples if you search for "C++ name decoration".

  • It actually depends on the compiler. Some of them literally mangle the names into strings that are meaningless except to the compiler. Older versions of VC++ were particularly bad about this. :) But yes, both search terms are valid.
    – Donnie
    May 30, 2010 at 2:30
  • I agree; when I started we only ever said mangling, and at some point over the decades decorating became more common, and when I got around to looking at the mangled names, decorating did seem to fit the bill. My guess would be someone changed the way they were doing things and wanted to leave the old name behind as well. Only partly successful though :-) May 30, 2010 at 2:33
  • 1
    Well... most of the results of searching for "C++ name decoration" actually bring up titles with "mangling" in them :-). Looks like Google hashes "decoration" in that context into the same slot as "mangling". Feb 11, 2016 at 19:08

Are there other examples that are using name mangling, besides overloading functions and same-name global and local variables?

C++ mangles all symbols, always. It's just easier for the compiler. Typically the mangling encodes something about the parameter list or types as these are the most common causes of mangling being needed.

C does not mangle. Scoping is used to control access to local and global variables of the same name.

  • Thanks Donnie. Do you think name mangling is only applied to identities with same name but in different namespaces?
    – Tim
    May 30, 2010 at 2:38


Name mangling is the process used by C++ compilers give each function in your program a unique name. In C++, generally programs have at-least a few functions with the same name. Thus name mangling can be considered as an important aspect in C++.

Example: Commonly, member names are uniquely generated by concatenating the name of the member with that of the class e.g. given the declaration:

class Class1
            int val;

val becomes something like:

  // a possible member name mangling

agner has more information on what is a name mangling and how it is done in different compilers.

Name mangling (also called name decoration) is a method used by C++ compilers to add additional information to the names of functions and objects in object files. This information is used by linkers when a function or object defined in one module is referenced from another module. Name mangling serves the following purposes:

  1. Make it possible for linkers to distinguish between different versions of overloaded functions.
  2. Make it possible for linkers to check that objects and functions are declared in exactly the same way in all modules.
  3. Make it possible for linkers to give complete information about the type of unresolved references in error messages.

Name mangling was invented to fulfill purpose 1. The other purposes are secondary benefits not fully supported by all compilers. The minimum information that must be supplied for a function is the name of the function and the types of all its parameters as well as any class or namespace qualifiers. Possible additional information includes the return type, calling convention, etc. All this information is coded into a single ASCII text string which looks cryptic to the human observer. The linker does not have to know what this code means in order to fulfill purpose 1 and 2. It only needs to check if strings are identical.

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