Question

What is the worst real-world macros/pre-processor abuse you've ever come across (please no contrived IOCCC answers *haha*)?

Please add a short snippet or story if it is really entertaining. The goal is to teach something instead of always telling people "never use macros".

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p.s.: I've used macros before... but usually I get rid of them eventually when I have a "real" solution (even if the real solution is inlined so it becomes similar to a macro).

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Bonus: Give an example where the macro was really was better than a not-macro solution.

Related question: When are C++ macros beneficial?

Answer 1

From memory, it looked something like this:

#define RETURN(result) return (result);}

int myfunction1(args) {
    int x = 0;
    // do something
    RETURN(x)

int myfunction2(args) {
    int y = 0;
    // do something
    RETURN(z)

int myfunction3(args) {
    int z = 0;
    // do something
    RETURN(z)

Yes that's right, no closing braces in any of the functions. Syntax highlighting was a mess, so he used vi to edit (not vim, it has syntax coloring!)

He was a Russian programmer who had mostly worked in assembly language. He was fanatical about saving as many bytes as possible because he had previously worked on systems with very limited memory. "It was for satellite. Only very few byte, so we use each byte over for many things." (bit fiddling, reusing machine instruction bytes for their numeric values) When I tried to find out what kinds of satellites, I was only able to get "Orbiting satellite. For making to orbit."

He had two other quirks: A convex mirror mounted above his monitor "For knowing who is watching", and an occasional sudden exit from his chair to do a quick ten pushups. He explained this last one as "Compiler found error in code. This is punishment".

Answer 2

The worst I've seen is in my current project where there are a whole lot of cases of:

#if PROGRAMA
     .
     .
    if(...)
    {
     .
     .
     .
#else
    .
     .
    if(...)
    {
     .
     .
     .
#endif
     }

Yeah, he closes 2 opens with a single close.

Answer 3

#define begin {
#define end }

Answer 4

#define return if (std::random(1000) < 2) throw std::exception(); else return

this is just so evil. It's random, which means it fires in different places all the time, it changes return statement, which usually have some code on it that could fail all by itself, it changes innocent looking keyword that you won't ever get suspicious over and it uses exception from std space so you won't try to search through your sources to find it's source. Just brilliant.

Answer 5

#define "CR_LF" '\r'

That confused the hell out of me for a while!

Answer 6

Coroutines (AKA Stackless threads) in C. :) It's Evil trickery.

#define crBegin static int state=0; switch(state) { case 0:
#define crReturn(i,x) do { state=i; return x; case i:; } while (0)
#define crFinish }
int function(void) {
    static int i;
    crBegin;
    for (i = 0; i < 10; i++)
        crReturn(1, i);
    crFinish;
}

int decompressor(void) {
    static int c, len;
    crBegin;
    while (1) {
        c = getchar();
        if (c == EOF)
            break;
        if (c == 0xFF) {
            len = getchar();
            c = getchar();
            while (len--)
            crReturn(c);
        } else
        crReturn(c);
    }
    crReturn(EOF);
    crFinish;
}


void parser(int c) {
    crBegin;
    while (1) {
        /* first char already in c */
        if (c == EOF)
            break;
        if (isalpha(c)) {
            do {
                add_to_token(c);
    	crReturn( );
            } while (isalpha(c));
            got_token(WORD);
        }
        add_to_token(c);
        got_token(PUNCT);
    crReturn( );
    }
    crFinish;
}

Answer 7

I did the following myself, and I think I learned something from it.

In 1992 or so I wrote a small Lisp interpreter. It wasn't implemented in normal C, but in an interpreted C-like language. This C-like language used the standard C pre-processor, though.

The Lisp interpreter of course contained the functions car, which is used in Lisp to return the first element in a list, and cdr, which returns the rest of the list. They were implemented like this:

LISPID car(LISPID id) {
    CHECK_CONS("car", 1, id);
    return cons_cars[id - CONS_OFFSET];
} /* car */

LISPID cdr(LISPID id) {
    CHECK_CONS("cdr", 1, id);
    return cons_cdrs[id - CONS_OFFSET];
} /* cdr */

(Data were stored in arrays, since there were no structs. CONS_OFFSET is the constant 1000.)

car and cdr are used frequently in Lisp, and are short, and since function calls weren't very fast in the implementation language, I optimized my code by implementing those two Lisp functions as macros:

#define car(id) (CHECK_CONS("car", 1, (id)), cons_cars[(id) - CONS_OFFSET])
#define cdr(id) (CHECK_CONS("car", 1, (id)), cons_cdrs[(id) - CONS_OFFSET])

CHECK_CONS checks that its argument actually is a list, and since that one is also used frequently in the interpreter, and is short, I wrote that one too as a macro:

#define CHECK_CONS(fun, pos, arg)   \
    (!IS_CONS(arg) ?        \
        LISP_ERROR("Arg " + pos + " to " + fun +    \
                   " must be a list: " + lispid2string(arg)) : 0)

IS_CONS and LISP_ERROR were also used frequently, so I made them into macros too:

#define IS_CONS(id) \
    (   intp(id) && (id) >= CONS_OFFSET     \
     && ((id) - CONS_OFFSET) < sizeof(cons_cars))

#define LISP_ERROR(str)     (throw((str) + "\n"))

Seems reasonable?

But then, why did the entire system crash on this line:

id2 = car(car(car(car((id1))));

I worked a long time to find the problem, until I finally checked what that short line was expanded to by the pre-processor. It was expanded to a 31370-character line, which I have here split into lines (502 of them) for clarity:

id2 = ((!(intp( (((!(intp( (((!(intp( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
&& ( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) && ( (((!(intp( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) >= 1000 && (( (((!(intp(
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) - 1000) < sizeof(cons_cars))
? (throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 &&
(( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to
" + "car" + " must be a list: " + lispid2string( (id1))) + "\n"))
: 0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
>= 1000 && (( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && ((
(id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to "
+ "car" + " must be a list: " + lispid2string( (id1))) + "\n")) :
0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && ((
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])) - 1000]))) && ( (((!(intp(
(((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) && ( (((!(intp( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) >= 1000 && (( (((!(intp(
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) - 1000) < sizeof(cons_cars))
? (throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 &&
(( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to
" + "car" + " must be a list: " + lispid2string( (id1))) + "\n"))
: 0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
>= 1000 && (( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && ((
(id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to "
+ "car" + " must be a list: " + lispid2string( (id1))) + "\n")) :
0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && ((
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])) - 1000]))) >= 1000 && ((
(((!(intp( (((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && ((
(id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to "
+ "car" + " must be a list: " + lispid2string( (id1))) + "\n")) :
0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && ((
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) && ( (((!(intp( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) >= 1000 && (( (((!(intp(
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) - 1000) < sizeof(cons_cars))
? (throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 &&
(( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to
" + "car" + " must be a list: " + lispid2string( (id1))) + "\n"))
: 0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
>= 1000 && (( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && ((
(id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to "
+ "car" + " must be a list: " + lispid2string( (id1))) + "\n")) :
0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && ((
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])) - 1000]))) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (((!(intp( (((!(intp( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) && ( (((!(intp( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) >= 1000 && (( (((!(intp(
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && (( (((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000]))) - 1000) < sizeof(cons_cars))
? (throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 &&
(( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to
" + "car" + " must be a list: " + lispid2string( (id1))) + "\n"))
: 0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && (
(id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
>= 1000 && (( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (((!(intp( (id1)) && ( (id1)) >= 1000 && ((
(id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to "
+ "car" + " must be a list: " + lispid2string( (id1))) + "\n")) :
0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1)) && ( (id1))
>= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg "
+ 1 + " to " + "car" + " must be a list: " + lispid2string(
(id1))) + "\n")) : 0), cons_cars[(id1) - 1000]))) >= 1000 && ((
(((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1))
- 1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car"
+ " must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])))) + "\n")) : 0), cons_cars[(((!(intp(
(id1)) && ( (id1)) >= 1000 && (( (id1)) - 1000) <
sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" + " must
be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000])) - 1000])) - 1000])))) + "\n")) : 0),
cons_cars[(((!(intp( (((!(intp( (((!(intp( (id1)) && ( (id1)) >=
1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ? (throw(("Arg " +
1 + " to " + "car" + " must be a list: " + lispid2string( (id1)))
+ "\n")) : 0), cons_cars[(id1) - 1000]))) && ( (((!(intp( (id1))
&& ( (id1)) >= 1000 && (( (id1)) - 1000) < sizeof(cons_cars)) ?
(throw(("Arg " + 1 + " to " + "car" + " must be a list: " +
lispid2string( (id1))) + "\n")) : 0), cons_cars[(id1) - 1000])))
>= 1000 && (( (((!(intp( (id1)) && ( (id1)) >= 1000 && (( (id1)) -
1000) < sizeof(cons_cars)) ? (throw(("Arg " + 1 + " to " + "car" +
" must be a list: " + lispid2string( (id1))) + "\n")) : 0),
cons_cars[(id1) - 1000]))) - 1000) < sizeof(cons_cars))

Answer 8

I found it in libtidy,:

 /* Internal symbols are prefixed to avoid clashes with other libraries */
 #define TYDYAPPEND(str1,str2) str1##str2
 #define TY_(str) TYDYAPPEND(prvTidy,str)

 TY_(DocParseStream)(bar,foo);

The problem is that visual studio 2005 and maybe other ide go to definition and go to declaration features only find the #define TY_(...) and not the desired DocParseStream declaration.

Maybe it is safer this way.

I think they should put a prefix for each function and not call a macro to do the job.. it's cluttering the code.. but maybe I am wrong about that. What do you think..?

Ps: It seems that almost all the internal function const and others are prefixed using this.. My colleague just told me that it is usual.. wtf? Maybe I missed something.

Answer 9

It's not a C macro but...

Many years ago I had the fun task of porting the original Transport Tycoon from the PC to the Mac. The PC version was written entirely in assembler so we had to go through the whole source code and port it to 'PC' C code first and then port that to the Mac. Most of the code was OK, even object orientated in places. However, the world rendering system was unbelievable. For anyone who's not played the game, the world can be viewed at one of three zoom levels. The code for this was something along the lines of:

macro DrawMacro <list of arguments>
   a couple of thousand lines of assembler with loads of conditionals
   based on the macro arguments

DrawZoomLevel1:
   DrawMacro <list of magic numbers>

DrawZoomLevel2:
   DrawMacro <list of more magic numbers>

DrawZoomLevel3:
   DrawMacro <list of even more magic numbers>

We must have been using a slightly older version of MASM as the macro would crash the assembler when we tried to assemble it.

Skizz

Answer 10

I once had to port a C application from unix to windows, the specific nature of which shall remain unnamed to protect the guilty. The guy who wrote it was a professor unaccustomed to writing production code, and had clearly come to C from some other language. It also happens that English wasn't his first language, though the in country he came from from the majority of people speak it quite well.

His application made heavy use of the preprocessor to twist the C language into a format he could better understand. But the macros he used the most were defined in a header file named 'Thing.h' (seriously), which included the following:

#define I  Any void_me
#define thou  Any void_thee
#define iam(klas)  klas me = (klas) void_me
#define thouart(klas)  klas thee = (klas) void_thee
#define my  me ->
#define thy  thee ->
#define his  him ->
#define our  my methods ->
#define your  thy methods ->

...which he then used to write monstrosities like the following:

void Thing_setName (I, const char *name) {
iam (Thing);
if (name != my name) {
    Melder_free (my name);
    my name = Melder_wcsdup (name);
    }
    our nameChanged (me);
}

void Thing_overrideClass (I, void *klas) {
iam (Thing);
my methods = (Thing_Table)klas;
if (! ((Thing_Table) klas) -> destroy)
    ((Thing_Table) klas) -> _initialize (klas);
}

The entire project (~60,000 LOC) was written in a similar style -- marco hell, weird names, Olde-English jargon, etc. Fortunately we were able to throw the code out since I found an OSS library which performed the same algorithm dozens of times faster.

(I've copied and edited this answer which I originally made on this question).

Answer 11

#undef near
#undef far

When I was new to game programming I was writing a frustum for a camera class is a game that I wrote, I had really strange errors in my code.

It turns out that Microsoft had some #defines for near and far in windows.h which caused my _near and _far variables to error on the lines that contained them. It was very difficult to track the problem down because (I was a newbie at the time) and they only existed on four lines in the whole project so i didn't realise right away.

Answer 12

A "technical manager" who had formerly been a coder introduced the following wonderful macros into our C++ project because he thought that checking for NULL values in DOM parsing routines was just too much work:

TRYSEGV
CATCHSEGV

Under the covers, these used setjmp, longjmp, and a signal handler for SIGSEGV to emulate the ability to "catch" a segfault.

Of course, nothing in the code reset the jump pointed once the code had exited the scope of the original TRYSEGV macro invocation, so any segfault in the code would return to the (now invalid) jump_env pointer.

The code would immediately die there, but not before destroying the program stack and rendering debugging more or less pointless.

Answer 13

#define FLASE FALSE

The programmer was a bad typist, and this was his most common mistake.

Answer 14

#define TRUE 0 // dumbass

The person who did this explained himself some years later - most (if not all) C library functions return 0 as an indication that everything went well. So, he wanted to be able to write code like:

if (memcpy(buffer, packet, BUFFER_SIZE) == TRUE) {
; // rape that packet
}

Needless to say, nobody in our team (tester or developer) ever dared to glance at his code again.

Answer 15

#define unless(cond) if(!cond)
#define until(cond) while(!cond)

Used:

unless( ptr == NULL) 
    ptr->foo();

Answer 16

At the time it seemed like a good idea to "pass" a macro as an argument into another macro. (I just couldn't stand the thought of defining a list of values in multiple places.) The code here is contrived (and not very motivating), but gives you the idea:

#define ENUM_COLORS(CallbackMacro) \
    CallbackMacro(RED)   \
    CallbackMacro(GREEN) \
    CallbackMacro(BLUE)  \
    // ...

#define DEFINE_COLOR_TYPE_CALLBACK(Color) \
    Color,

enum MyColorType {
    ENUM_COLORS(DEFINE_COLOR_TYPE_CALLBACK)
};

void RegisterAllKnownColors(void)
{
#define REGISTER_COLOR_CALLBACK(Color) \
    RegisterColor(Color, #Color);

    ENUM_COLORS(REGISTER_COLOR_CALLBACK)
}

void RegisterColor(MyColorType Color, char *ColorName)
{
    // ...
}

Answer 17

I'm not fond of the Boost Preprocessor stuff. I attempted once to figure out how to use it (we had Boost in the project anyway...), but as near as I could tell, using it would make my error messages SO unreadable that it wasn't worth it.

I liked the idea of the equivalent of looping macros, but it was just too much.

Answer 18

I'm adding another one that has started to annoy me over time:

#define ARRAYSIZE(x) (sizeof(x)/sizeof((x)[0]))

And that's if they get it right; I've seen versions with all possible permutations of parenthesis present or not. I've seen it defined twice in the same header file.

Mainly my argument applies to Windows (though I assume other OS SDKs have something similar), where just about everyone seems to feel the need to define this macro in their project's header, and I don't understand why.

WinNT.h (which is included by Windows.h) defines a very nice version that does some template voodoo to cause compile time errors if you pass a pointer type instead of an array.

Of course it falls back to exactly what I wrote above if you are building a C program, but I would still not redefine something the SDK has by default for no reason.

Answer 19

Anything using sendmail and its magic configuration syntax

Answer 20

#define interface struct

in some of Optima++ headers (Optima++ is/was a Watcom/Powersoft IDE I had to work with).

Answer 21

I once put together this horrifying C++ code which used macros to help hook functions into the import table of DLLs.

#define ARGLIST(...) __VA_ARGS__

#define CPPTYPELESSARG(typelessParams) thisptr, typelessParams
#define CPPTYPEDARG(typedParams) void* thisptr, typedParams
#define CPPTYPELESSNOARG thisptr
#define CPPTYPEDNOARG void* thisptr

#define CPPHOOKBODY(hookName, params) void *thisptr; \
    __asm { mov thisptr, ecx } \
    return On##hookName ( params );


#define CHOOKBODY(hookName, typelessParams) return On##hookName( typelessParams );

#define CPPHOOK(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams) \
    HOOKIMPL(InjectHookRef, importLib, importFunc, hookName, returnType, CPPTYPEDARG(typedParams), typelessParams, \
    typedParams, __thiscall, __stdcall, CPPHOOKBODY(hookName, CPPTYPELESSARG(typelessParams)))

#define CPPHOOKNOARG(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams) \
    HOOKIMPL(InjectHookRef, importLib, importFunc, hookName, returnType, CPPTYPEDNOARG, typelessParams, \
    typedParams, __thiscall, __stdcall, CPPHOOKBODY(hookName, CPPTYPELESSNOARG))

#define CDECLHOOK(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams) \
    HOOKIMPL(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams, \
    typedParams, __cdecl, __cdecl, CHOOKBODY(hookName, typelessParams))

#define CDECLFUNC(name, address, returnType, args) \
    typedef returnType (__cdecl *name##Ptr)(args); \
    name##Ptr name = (name##Ptr) address;

#define CPPFUNC(name, address, returnType, args) \
    typedef returnType (__thiscall *name##Ptr)(void* thisptr, args); \
    name##Ptr name = (name##Ptr) address;

#define STDFUNC(name, address, returnType, args) \
    typedef returnType (__stdcall *name##Ptr)(args); \
    name##Ptr name = (name##Ptr) address;

#define STDHOOK(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams) \
    HOOKIMPL(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams, \
    typedParams, __stdcall, __stdcall, CHOOKBODY(hookName, ARGLIST(typelessParams)))

#define HOOKIMPL(InjectHookRef, importLib, importFunc, hookName, returnType, typedParams, typelessParams, hookParams, fnPtrCall, hookCall, hookBody) \
    	typedef returnType (fnPtrCall *##hookName##OrigPtr )( typedParams ); \
    	class hookName : public IHook \
    	{ \
    	public: \
    		typedef hookName##OrigPtr func_type; \
    	private: \
    		static void* m_origFunction; \
    		static bool m_bModifyImport; \
    		static std::string m_lib; \
    		static std::string m_importFunc; \
    		static std::string m_sHookName; \
    		static returnType hookCall hookName##FnHook ( hookParams ) \
    		{ \
    			hookBody \
    		} \
    		static bool	ImplIsModifyImport() { return hookName::m_bModifyImport; } \
    		static void ImplSetModifyImport(bool bModify) { hookName::m_bModifyImport = bModify; } \
    		static const std::string& ImplGetLibName() { return hookName::m_lib; } \
    		static const std::string& ImplGetImportFunctionName() { return hookName::m_importFunc; } \
    		static void ImplSetOriginalAddress(void* fn) { hookName::m_origFunction = fn; } \
    		static void* ImplGetOriginalAddress() { return hookName::m_origFunction; } \
    		static returnType On##hookName ( typedParams ); \
    		static void* ImplGetNewAddress() { return hookName::##hookName##FnHook; } \
    		static const std::string& ImplGetHookName() { return hookName::m_sHookName; } \
    	public: \
    		hookName() \
    		{ \
    			InjectHookRef.AddHook((IHook*)this); \
    			hookName::m_lib = importLib; \
    			hookName::m_importFunc = importFunc; \
    			hookName::m_sHookName = #hookName; \
    			hookName::m_origFunction = NULL; \
    			hookName::m_bModifyImport = true; \
    		} \
    		virtual bool IsModifyImport() const { return hookName::ImplIsModifyImport(); } \
    		virtual void SetModifyImport(bool bModify) { hookName::ImplSetModifyImport(bModify); } \
    		virtual const std::string& GetHookName() const { return hookName::ImplGetHookName(); } \
    		virtual const std::string& GetLibName() const { return hookName::ImplGetLibName(); } \
    		virtual const std::string& GetImportFunctionName() const { return hookName::ImplGetImportFunctionName(); } \
    		virtual void* GetOriginalAddress() const { return hookName::ImplGetOriginalAddress(); } \
    		virtual void* GetNewAddress() const { return hookName::ImplGetNewAddress(); } \
    		virtual void SetOriginalAddress(void* fn) { hookName::m_origFunction = fn; } \
    		static func_type GetTypedOriginalAddress() { return reinterpret_cast(hookName::m_origFunction); } \
    	}; \
    	void* hookName::m_origFunction = NULL; \
    	bool hookName::m_bModifyImport = false; \
    	std::string hookName::m_lib; \
    	std::string hookName::m_importFunc; \
    	std::string hookName::m_sHookName; \
    	static hookName g##hookName##Inst;

Which in turn allowed me to do this:

CPPHOOK(gIH, "SimEngine.dll", "?AddEntity@Player@@UAEXPAVEntity@@@Z", PlayerAddEntity, void, void* ent, ent);


/* Called when the engine calls Player::AddEntity(entity) */
void PlayerAddEntity::OnPlayerAddEntity(void *thisptr, void *ent)
{
    unsigned int id = getPlayerID(thisptr);

gIH.GetLog()->Info("Player %d adding entity %s.", 
	getPlayerID(thisptr), getEntityName(ent));

gPlayers[id] = thisptr;

/*if( id == 2 && gPlayers[1] && gPlayers[2] )
	EntitySetOwner::GetTypedOriginalAddress() (ent, gPlayers[1]);*/
//gEnts[ent] = Entity(ent, Vector3f());

PlayerAddEntity::GetTypedOriginalAddress() (thisptr, ent);


}

Answer 22

I agree that for the most part, macros are horrible to use, but i have found a few instances where they have been useful.

This one is actually brilliant IMHO, as you can only get something similar with sprintf, which then requires resource allocations and whatnot, plus, all work is done entirely by the preprocessor

// Macro: Stringize
//
//      Converts the parameter into a string
//
#define Stringize( L )  		#L


// Macro: MakeString
//
//      Converts the contents of a macro into a string
//
#define MakeString( L ) 	Stringize(L)


// Macro: $LINE
//
//      Gets the line number as a string
//
#define $LINE   				MakeString( __LINE__ )


// Macro: $FILE_POS
//
//      Gets the current file name and current line number in a format the Visual Studio
//  	can interpret and output goto
//
// NOTE: For VS to properly interpret this, it must be at the start of the line (can only have whitespace before)
//
#define $FILE_POS   			__FILE__ "(" $LINE ") : "

The other that I loathe to use, but find it extremely useful is doing something like this, which basically allows me to quickly generate templates that have a variable number of template parameters

#define TEMPLATE_DEFS    typename ReturnType
#define TEMPLATE_DECL   ReturnType
#define FUNCTION_PARAMS void
#define FUNCTION_PASS   
#define GENERIC_CALLBACK_DECL_NAME  	CallbackSafePointer0
#include "Callback.inl"

#define TEMPLATE_DEFS   typename ReturnType, typename P1
#define TEMPLATE_DECL   ReturnType, P1
#define FUNCTION_PARAMS P1 param1
#define FUNCTION_PASS   param1
#define GENERIC_CALLBACK_DECL_NAME  	CallbackSafePointer1
#include "Callback.inl"

#define TEMPLATE_DEFS   typename ReturnType, typename P1, typename P2
#define TEMPLATE_DECL   ReturnType, P1, P2
#define FUNCTION_PARAMS P1 param1, P2 param2
#define FUNCTION_PASS   param1, param2
#define GENERIC_CALLBACK_DECL_NAME  	CallbackSafePointer2
#include "Callback.inl"

#define TEMPLATE_DEFS   typename ReturnType, typename P1, typename P2, typename P3
#define TEMPLATE_DECL   ReturnType, P1, P2, P3
#define FUNCTION_PARAMS P1 param1, P2 param2, P3 param3
#define FUNCTION_PASS   param1, param2, param3
#define GENERIC_CALLBACK_DECL_NAME  	CallbackSafePointer3
#include "Callback.inl"

// and so on...

Although this makes it kind of horrible to read "Callback.inl", it does completely eliminate rewriting the same code with a different number of arguments. I should also mention that "Callback.inl" #undefs all of the macros at the end of the file, hence, the macros themselves won't interfere with any other code, it just makes "Callback.inl" a little harder to write (reading and debuging isn't too hard though)

Answer 23

I would like to submit for the contest a gem called chaos-pp, which implements a functional language by means of the preprocessor macros.

One of the examples is calculating the 500th fibonacci number entirely by the preprocessor:

The original code before preprocessor looks as this:

int main(void) {
   printf
     ("The 500th Fibonacci number is "
      ORDER_PP(8stringize(8to_lit(8fib(8nat(5,0,0)))))
      ".\n");
   return 0;
}

preprocessing the file we get the following result (after a rather long wait):

$ cpp -I../inc fibonacci.c 2>/dev/null | tail
  return fib_iter(n, 0, 1);
}
# 63 "fibonacci.c"
int main(void) {
   printf
     ("The 500th Fibonacci number is "
      "139423224561697880139724382870407283950070256587697307264108962948325571622863290691557658876222521294125"
      ".\n");
   return 0;
}

Answer 24

I have used header files as big macros:

// compile-time-caller.h
#define param1 ...
#define param2 ...
#include "killer-header.h"

// killer-header.h
// uses param1 and param2

I have also created recursive header files.

// compile-time-caller.h
#define param1 ...
#define param2 ...
#include "killer-header.h"

// killer-header.h"
#if ... // conditional taking param1 and param2 as parameters
#define temp1 param1
#define temp2 param2
#define param1 ... // expression taking temp1 and temp2 as parameters
#define param2 ... // expression taking temp1 and temp2 as parameters
#include "killer-header.h"
// some actual code
#else
// more actual code
#endif

Answer 25

At Lucent, I once took a look at the source code of Steve Bourne's original Unix shell, and found he'd used the C pre-processor to make C look like Pascal or Algol. The part dealing with if statements looked something like this:

#define IF if (
#define THEN ) {
#define ELSE } else {
#define FI }

A friend of mine told me he'd done some maintenance on it in the mid-1990s, and it was still the same. (There's a lesson here for us in the inherent conservatism of a code base.)

Of course Steve did this as an experiment in the early days, and I'm sure would have had second thoughts if he'd written it later.

Update: According to Wikipedia's Bourne Shell article, the macros gave it an Algol 68 flavor. And, the full set of macros is here! They apparently influenced the founders of the International Obfuscated C Code Contest.

Answer 26

In college somebody in my class did this:

#define CUNT const unsigned int

It makes sense, but I think he did it because he didn't like our teacher.

Answer 27

Any macro that uses the token concatenation operator ##.

I saw one that a colleague of mine had the pleasure of working with. They tried to make a custom-implementation of string interning, so they re-implemented strings using a massive number of macros that (of course) didn't work properly. Trying to figure out what it did made my eyes explode because of all the ##'s scattered about.

Answer 28

I maintain code that has gotos in macros. So a function will have a label at the end but no visible goto in the function code. To make matters worse the macro is at the end of other statements usually off the screen unless you scroll horizontally.

#define CHECK_ERROR if (!SomeCondition) goto Cleanup

void SomeFunction() 
{ 
    SomeLongFunctionName(ParamOne, ParamTwo, ParamThree, ParamFour); CHECK_ERROR  
    //SomeOtherCode  
    Cleanup:    
   //Cleanup code  
}

Answer 29

ASA - http://www.ingber.com/#ASA

You really have to download it to appreciate it. The entire work flow is determined by macros. It is completely unreadable. As an example -

 if (asa_open == FALSE) {
asa_open = TRUE;
++number_asa_open;
#if ASA_PRINT
if (number_asa_open == 1) {
  /* open the output file */
#if USER_ASA_OUT
  if (!strcmp (OPTIONS->Asa_Out_File, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
#if ASA_SAVE
    ptr_asa_out = fopen (OPTIONS->Asa_Out_File, "a");
#else
    ptr_asa_out = fopen (OPTIONS->Asa_Out_File, "w");
#endif
  }
#else /* USER_ASA_OUT */
  if (!strcmp (ASA_OUT, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
#if ASA_SAVE
    ptr_asa_out = fopen (ASA_OUT, "a");
#else
    ptr_asa_out = fopen (ASA_OUT, "w");
#endif
  }
#endif /* USER_ASA_OUT */
} else {
#if USER_ASA_OUT
  if (!strcmp (OPTIONS->Asa_Out_File, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
    ptr_asa_out = fopen (OPTIONS->Asa_Out_File, "a");
  }
#else
  if (!strcmp (ASA_OUT, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
    ptr_asa_out = fopen (ASA_OUT, "a");
  }
#endif
  fprintf (ptr_asa_out, "\n\n\t\t number_asa_open = %d\n",
           number_asa_open);
}
#endif /* ASA_PRINT */
} else {
++recursive_asa_open;
#if ASA_PRINT
if (recursive_asa_open == 1) {
  /* open the output file */
#if ASA_SAVE
#if USER_ASA_OUT
  if (!strcmp (OPTIONS->Asa_Out_File, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
    ptr_asa_out = fopen (OPTIONS->Asa_Out_File, "a");
  }
#else
  if (!strcmp (ASA_OUT, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {
    ptr_asa_out = fopen (ASA_OUT, "a");
  }
#endif
#else /* ASA_SAVE */
#if USER_ASA_OUT
  if (!strcmp (OPTIONS->Asa_Out_File, "STDOUT")) {
#if INCL_STDOUT
    ptr_asa_out = stdout;
#endif /* INCL_STDOUT */
  } else {

etc., etc.

And that is just setting up the options. the entire program is like that.

Answer 30

A coworker and I found these two gems in some of our code for object streaming. These macros were instantiated in EVERY SINGLE class file that did streaming. Not only is this hideous code spewed all over our code base, when we approached the original author about it, he wrote a 7 page article on our internal wiki defending this as the only possible way to accomplish what he was attempting to do here.

Needless to say, it has since been refactored out and is no longer used in our code base.

Don't be thrown off by the highlighted keywords. This is ALL a macro

#define DECLARE_MODIFICATION_REQUEST_PACKET( T )    											\
namespace NameSpace 																	\
{   																					\
    																					\
class T##ElementModificationRequestPacket;  														\
}   																					\
    																					\
DECLARE_STREAMING_TEMPLATES( IMPEXP_COMMON_TEMPLATE_DECLARE, NameSpace::ElementModificationRequestPacket<T>, OtherNameSpace::NetPacketBase )    \
DLLIMPEXP_COMMON_TEMPLATE_DECLARE( NameSpace::ElementModificationRequestPacket<T> ) 	\
DECLARE_AUTOGENERATION_TEMPLATES( DLLIMPEXP_COMMON_TEMPLATE_DECLARE, NameSpace::T##ModificationRequestPacket, NameSpace::ElementModificationRequestPacket<T> )  	\
    																					\
namespace NameSpace {   																\
class DLLIMPEXP_COMMON T##ModificationRequestPacket : public ElementModificationRequestPacket<T>\
{   																					\
public: 																				\
    T##ModificationRequestPacket( NetBase *	pParent )									\
    : ElementModificationRequestPacket<T>( pParent ), m_Gen() {}							\
    																					\
    T##ModificationRequestPacket( NetBase *	pParent,									\
    						Action			eAction,									\
    						const T &	rT )											\
    : ElementModificationRequestPacket<T>( pParent, eAction, rT ), m_Gen() {}				\
    																					\
    T##ModificationRequestPacket( const T##ModificationRequestPacket & rhs )						\
    : ElementModificationRequestPacket<T>( rhs ), m_Gen() {}								\
    																					\
    virtual						~T##ModificationRequestPacket( void ) {}						\
    																					\
    virtual Uint32			GetPacketTypeID( void ) const							\
    {																					\
    	return Net::T##_Modification_REQUEST_PACKET;										\
    }																					\
    																					\
    virtual	OtherNameSpace::ClassID	GetClassID ( void ) const							\
    {																					\
    	return OtherNameSpace::NetBase::GenerateHeader( OtherNameSpace::ID__LICENSING, 	\
    													 Net::T##_Modification_REQUEST_PACKET );	\
    }																					\
    																					\
    virtual T##ModificationRequestPacket * Create( void ) const								\
    { return new T##ModificationRequestPacket( m_pParent ); }									\
    																					\
    T##ModificationRequestPacket() {}															\
    																					\
protected:  																			\
    OtherNameSpace::ObjectAutogeneration<T##ModificationRequestPacket> m_Gen;						\
    																					\
    friend class OtherNameSpace::StreamingBase::StreamingClassInfoT<T##ModificationRequestPacket >;						\
    OtherNameSpace::StreamingBase::Streaming<T##ModificationRequestPacket, ElementModificationRequestPacket<T> >	m_Stream;	\
    																					\
};  																					\
}   																					\
DLLIMPEXP_COMMON_TEMPLATE_DECLARE( ThirdNameSpace::ListenerBase<const NameSpace::T##ModificationRequestPacket> )    		\
DLLIMPEXP_COMMON_TEMPLATE_DECLARE( ThirdNameSpace::BroadcasterT<const NameSpace::T##ModificationRequestPacket> )    		\
typedef  ThirdNameSpace::BroadcasterT<const T##ModificationRequestPacket>  T##ModifiedBroadcaster;



#define IMPLEMENT_MODIFICATION_REQUEST_PACKET( T )  																\
DLLIMPEXP_COMMON_TEMPLATE_INSTANTIATE( NameSpace::ElementModificationRequestPacket<T> ) 						\
DLLIMPEXP_COMMON_TEMPLATE_INSTANTIATE( ThirdNameSpace::ListenerBase<const NameSpace::T##ModificationRequestPacket> )    	\
DLLIMPEXP_COMMON_TEMPLATE_INSTANTIATE( ThirdNameSpace::BroadcasterT<const NameSpace::T##ModificationRequestPacket> )    	\
INSTANTIATE_STREAMING_TEMPLATES( DLLIMPEXP_COMMON_TEMPLATE_INSTANTIATE, NameSpace::ElementModificationRequestPacket<T>, OtherNameSpace::NetPacketBase ) \
INSTANTIATE_AUTOGENERATION_TEMPLATES( DLLIMPEXP_COMMON_TEMPLATE_INSTANTIATE, NameSpace::T##ModificationRequestPacket, NameSpace::ElementModificationRequestPacket<T> )