Seeing expanded C macros

Question

If I want to expand a C macro, what are some good ways to do that (besides tracing it manually)?

For instance, GTK_WIDGET_SET_FLAGS, it uses a macro that uses a macro that uses a macro (or two) ...

I want to just see it somehow expanded automagically, instead of searching for every macro, every step of the way.

UPDATE

I tried cpp, but it seemed to only do the first pass

on:

GTK_WIDGET_SET_FLAGS(obj, 13)

I got the include file expanded, and then:

G_STMT_START{ ((GTK_OBJECT_FLAGS (obj)) |= (13)); }G_STMT_END

This is explained by these error message I get this on stderr (when using -o filename)

gtk/gtkwidget.h:34:21: gdk/gdk.h: No such file or directory
gtk/gtkwidget.h:35:31: gtk/gtkaccelgroup.h: No such file or directory
gtk/gtkwidget.h:36:27: gtk/gtkobject.h: No such file or directory
gtk/gtkwidget.h:37:31: gtk/gtkadjustment.h: No such file or directory
gtk/gtkwidget.h:38:26: gtk/gtkstyle.h: No such file or directory
gtk/gtkwidget.h:39:29: gtk/gtksettings.h: No such file or directory
gtk/gtkwidget.h:40:21: atk/atk.h: No such file or directory

the gtk, atk, and gdk directories are all in the current working directory, so how do I let cpp search in it?

btw, gcc -E gives the exact same output as cpp

Update2:

The include path problem is solved by using gcc -E and passing the include directory with the -I option

Answer 1

Depending on which compiler you use, there should be a way to see the code after the preprocessor (which does the macro expansion, macros are not known by the compiler at all) is done.

With gcc, the option is -E. Here's a simplified example, using toy code and not the actual GTK+ macro:

~/tmp> cat cpptest.c
#define SET_FLAGS(w, f) ((w)->flags |= (f))

int main(void)
{
        SET_FLAGS(0, 4711);

        return 0;
}
~/tmp> gcc -E cpptest.c
# 1 "cpptest.c"
# 1 "<built-in>"
# 1 "<command line>"
# 1 "cpptest.c"


int main(void)
{
 ((0)->flags |= (4711));

 return 0;
}

Answer 2

You can dump the expansion of a macro at run time like this:

#include <stdio.h>

/*
 * generic helper macros
 */
#define CALL(macro, arguments) macro arguments
#define STR(...) STR_(__VA_ARGS__)
#define STR_(...) # __VA_ARGS__

/*
 * dumps a macro and its expansion to stdout
 * the second argument is optional and specifies the number of
 * arguments that macro takes: 0 means macro takes zero arguments
 * no second argument means macro is not function-like
 */
#define DUMP_MACRO(macro, ...) \
    do { \
        puts ( \
            "'" \
            # macro STR(DUMP_MACRO_ARGS_ ## __VA_ARGS__) \
            "' expands to '" \
            STR(CALL(macro, DUMP_MACRO_ARGS_ ## __VA_ARGS__)) \
            "'" \
        ); \
    } while (0)
/* helpers for DUMP_MACRO, add more if required */
#define DUMP_MACRO_ARGS_
#define DUMP_MACRO_ARGS_0 ()
#define DUMP_MACRO_ARGS_1 (<1>)
#define DUMP_MACRO_ARGS_2 (<1>, <2>)
#define DUMP_MACRO_ARGS_3 (<1>, <2>, <3>)

/*
 * macros to be used in examples for DUMP_MACRO
 */
#define EXAMPLE ( EXAMPLE0() << 9 )
#define EXAMPLE0() __GNUC__
#define EXAMPLE1(EXAMPLE1) EXAMPLE1
#define EXAMPLE3(EXAMPLE1, _, __) ( EXAMPLE1 ? _(__) : false )

int main() {
    /* examples */
    DUMP_MACRO(EXAMPLE);
    DUMP_MACRO(EXAMPLE0, 0);
    DUMP_MACRO(EXAMPLE1, 1);
    DUMP_MACRO(EXAMPLE3, 3);
    DUMP_MACRO(EXAMPLE3(EXAMPLE, EXAMPLE1, non_macro_symbol));
    /* does not work for DUMP_MACRO itself, because the
       preprocessor does not allow recursion */
    DUMP_MACRO(DUMP_MACRO, 1);
    DUMP_MACRO(DUMP_MACRO, 2);
    return 0;
}

The program prints:

'EXAMPLE' expands to '( 4 << 9 )'
'EXAMPLE0()' expands to '4'
'EXAMPLE1(<1>)' expands to '<1>'
'EXAMPLE3(<1>, <2>, <3>)' expands to '( <1> ? <2>(<3>) : false )'
'EXAMPLE3(EXAMPLE, EXAMPLE1, non_macro_symbol)' expands to '( ( 4 << 9 ) ? non_macro_symbol : false )'
'DUMP_MACRO(<1>)' expands to 'DUMP_MACRO (<1>)'
'DUMP_MACRO(<1>, <2>)' expands to 'DUMP_MACRO (<1>, <2>)'

However this yields only the full expansion. If you need single steps, Eclipse/CDT can help, but only if you teach it all the headers and compiler flags you use.

Answer 3

In Visual Studio, you can generate the preprocessor resulted translation unit file. You can go project options, C/C++/Preprocessor and put "Generate Preprocessed File" or "Preprocess to a File" on Yes (or use /P or /EP compiler switch to include line numbers or not).

Answer 4

gcc -E myfile.c

Answer 5

GCC -save-temps

The big advantage of this option over -E is that it is very easy to add it to any build script, without interfering much in the build itself.

When you do:

gcc -save-temps -c -o main.o main.c

main.c

#define INC 1

int myfunc(int i) {
    return i + INC;
}

and now, besides the normal output main.o, the current working directory also contains the following files:

• main.i is a contains the desired preprossessed file:

  # 1 "main.c"
  # 1 "<built-in>"
  # 1 "<command-line>"
  # 31 "<command-line>"
  # 1 "/usr/include/stdc-predef.h" 1 3 4
  # 32 "<command-line>" 2
  # 1 "main.c"
  
  
  int myfunc(int i) {
      return i + 1;
  }
  

• main.s is a bonus, and contains the desired generated assembly:

      .file   "main.c"
      .text
      .globl  myfunc
      .type   myfunc, @function
  myfunc:
  .LFB0:
      .cfi_startproc
      pushq   %rbp
      .cfi_def_cfa_offset 16
      .cfi_offset 6, -16
      movq    %rsp, %rbp
      .cfi_def_cfa_register 6
      movl    %edi, -4(%rbp)
      movl    -4(%rbp), %eax
      addl    $1, %eax
      popq    %rbp
      .cfi_def_cfa 7, 8
      ret
      .cfi_endproc
  .LFE0:
      .size   myfunc, .-myfunc
      .ident  "GCC: (Ubuntu 8.3.0-6ubuntu1) 8.3.0"
      .section    .note.GNU-stack,"",@progbits
  

If you want to do it for a large number of files, consider using instead:

 -save-temps=obj

which saves the intermediate files to the same directory as the -o object output instead of the current working directory, thus avoiding potential basename conflicts.

Another cool thing about this option is if you add -v:

gcc -save-temps -c -o main.o -v main.c

it actually shows the explicit files being used instead of ugly temporaries under /tmp, so it is easy to know exactly what is going on, which includes the preprocessing / compilation / assembly steps:

/usr/lib/gcc/x86_64-linux-gnu/8/cc1 -E -quiet -v -imultiarch x86_64-linux-gnu main.c -mtune=generic -march=x86-64 -fpch-preprocess -fstack-protector-strong -Wformat -Wformat-security -o main.i
/usr/lib/gcc/x86_64-linux-gnu/8/cc1 -fpreprocessed main.i -quiet -dumpbase main.c -mtune=generic -march=x86-64 -auxbase-strip main.o -version -fstack-protector-strong -Wformat -Wformat-security -o main.s
as -v --64 -o main.o main.s

Tested in Ubuntu 19.04 amd64, GCC 8.3.0.

Answer 6

gcc even with -E needs the path of the header files ... like -I _path_to_your_headers...

If you've a Makefile, generally, what you could do is over-riding CC with gcc -E

Generally, cpp is only a script adding some flags to gcc for the preprocessor, like traditional...

Answer 7

Many IDEs will show you the expanded version of the macro in the editor when the mouse pointer hovers over the identifier (or some other way). I know Eclipse/CDT does this, and Visual Studio does this (at least VS 2008 does).

Having the compiler generate preprocessed output can be useful if you're tracking down a tricky problem, but for day in/day out use where you just want to know what's going on with the code on your screen,using the IDE is the way to go.

Answer 8

If you use gcc you can also run

cpp myfile.c

Answer 9

Try running cpp on your source file

Answer 10

You want to run just the preprocessor stage of your compiler, responsible for expanding macros. For gcc, that's "gcc -E", but I'm not sure about other compilers.

Answer 11

Have you tried running gcc -E multiple times until there are no longer any macros?

Answer 12

Naive Approach

Basically here's my stringification macro:

#define stringify(exp) #exp

# is a preprocessor operator that makes strings in simple words, so stringify(foo) would give you "foo".

---

Problem

But if you used it on another macro like this #define FOO some_expression, it would just expand into "FOO" (the name of that macro) since it's not expanded yet.

---

Solution

This is why I have special macro that expands it first and then puts it through that special macro:

#define stringify_m(macro) stringify(macro)

---

Example

Now if we take this slightly more complex macro:

#define _padding_(size, id) char _padding##id##_ [((size) + sizeof(char) - 1) / sizeof(char)]

and put through stringify_m like this:

stringify_m(_padding_(8, 6502))

the result would be:

"char _padding6502_ [((8) + sizeof(char) - 1) / sizeof(char)]"

Answer 13

When trapped in a sketchy IDE, try something like

#define DISPLAY_VALUE2(x) #x
#define DISPLAY_VALUE(x) DISPLAY_VALUE2(x)
#pragma message("#DEFINE F_CPU " DISPLAY_VALUE(F_CPU))

to produce

…/sketch_may21a.ino: In function 'void loop()':
…/sketch_may21a.ino:10:54: note: #pragma message: #DEFINE F_CPU 16000000L
#pragma message("#DEFINE F_CPU " DISPLAY_VALUE(F_CPU))
                                                     ^

thanks to "mdematos" at http://MicroChip.com/forums/m724722.aspx

Answer 14

On macOS

gcc -E -dD source_file.c

-E Do nothing beyond preprocessing.

-dD Output the #define directives and the result of preprocessing.

Additional recommendations

Example code

#define max(A, B) ((A) > (B) ? (A) : (B))

int main(void) {
   int a = 1, b = 2;
   printf("Between %i and %i, %i is bigger\n", a, b, max(a, b));
   return 0;
}

Since we are only preprocessing we don’t need to #include <stdio.h> to have the printf() function or other libraries. In this example, including it will produce over 4,000 lines of output instead of less than 400 without.