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I know there is a standard behind all C compiler implementations, so there should be no hidden features. Despite that, I am sure all C developers have hidden/secret tricks they use all the time.

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56 Answers

up vote 62 down vote accepted

Function pointers. You can use a table of function pointers to implement, e.g., fast indirect-threaded code interpreters (FORTH) or byte-code dispatchers, or to simulate OO-like virtual methods.

Then there are hidden gems in the standard library, such as qsort(),bsearch(), strpbrk(), strcspn() [the latter two being useful for implementing a strtok() replacement].

A misfeature of C is that signed arithmetic overflow is undefined behavior (UB). So whenever you see an expression such as x+y, both being signed ints, it might potentially overflow and cause UB.

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29  
But if they had specified behaviour on overflow, it would have made it very slow on architectures where that was not the normal behaviour. Very low runtime overhead has always been a design goal of C, and that has meant that a lot of things like this are undefined. –  Mark Baker Oct 17 '08 at 8:38
9  
I'm very well aware of why overflow is UB. It is still a misfeature, because the standard should have at least provided library routines that can test for arithmetic overflow (of all basic operations) w/o causing UB. –  zvrba Jan 20 '09 at 20:51
2  
@zvrba, "library routines that can test for arithmetic overflow (of all basic operations)" if you had added this then you would have incurred significant performance hit for any integer arithmetic operations. ===== Case study Matlab specifically ADDS the feature of controlling integer overflow behavior to wrapping or saturate. And it also throws an exception whenever overflow occurs ==> Performance of Matlab integer operations: VERY SLOW. My own conclusion: I think Matlab is a compelling case study that shows why you don't want integer overflow checking. –  Trevor Boyd Smith Jun 11 '09 at 13:35
15  
I said that the standard should have provided library support for checking for arithmetic overflow. Now, how can a library routine incur a performance hit if you never use it? –  zvrba Jun 12 '09 at 18:52
5  
A big negative is that GCC does not have a flag to catch signed integer overflows and throw a runtime exception. While there are x86 flags for detecting such cases, GCC does not utilize them. Having such a flag would allow non-performance-critical (especially legacy) applications the benefit of security with minimal to no code review and refactoring. –  Andrew Keeton Jun 22 '09 at 0:23
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More of a trick of the GCC compiler, but you can give branch indication hints to the compiler (common in the Linux kernel)

#define likely(x)       __builtin_expect((x),1)
#define unlikely(x)     __builtin_expect((x),0)

see: http://kerneltrap.org/node/4705

What I like about this is that it also adds some expressiveness to some functions.

void foo(int arg)
{
     if (unlikely(arg == 0)) {
           do_this();
           return;
     }
     do_that();
     ...
}
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2  
This trick is cool... :) Especially with the macros you define. :) –  sundar Oct 22 '08 at 15:23
add comment
int8_t
int16_t
int32_t
uint8_t
uint16_t
uint32_t

These are an optional item in the standard, but it must be a hidden feature, because people are constantly redefining them. One code base I've worked on (and still do, for now) has multiple redefinitions, all with different identifiers. Most of the time it's with preprocessor macros:

#define INT16 short
#define INT32  long

And so on. It makes me want to pull my hair out. Just use the freaking standard integer typedefs!

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3  
I think they are C99 or so. I haven't found a portable way to ensure these would be around. –  akauppi Sep 25 '08 at 19:25
3  
They are an optional part of C99, but I know of no compiler vendors that don't implement this. –  Ben Collins Sep 25 '08 at 21:07
10  
stdint.h isn't optional in C99, but following the C99 standard apparently is for some vendors (cough Microsoft). –  Ben Combee Oct 22 '08 at 17:54
5  
@Pete, if you want to be anal: (1) This thread has nothig to do with any Microsoft product. (2) This thread never had anything to do with C++ at all. (3) There is no such thing as C++ 97. –  Ben Collins Mar 1 '09 at 21:20
5  
Have a look at azillionmonkeys.com/qed/pstdint.h -- a close-to-portable stdint.h –  gnud Apr 16 '09 at 14:16
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The comma operator isn't widely used. It can certainly be abused, but it can also be very useful. This use is the most common one:

for (int i=0; i<10; i++, doSomethingElse())
{
  /* whatever */
}

But you can use this operator anywhere. Observe:

int j = (printf("Assigning variable j\n"), getValueFromSomewhere());

Each statement is evaluated, but the value of the expression will be that of the last statement evaluated.

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7  
In 20years of C I have NEVER seen that! –  Martin Beckett Jun 22 '09 at 14:55
11  
In C++ you can even overload it. –  Wouter Lievens Jul 1 '09 at 10:45
6  
can != should, of course. The danger with overloading it is that the built in applies to everything already, including void, so will never fail to compile for lack of available overload. Ie, gives programmer much rope. –  Aaron Jul 6 '09 at 17:45
3  
@Aif: the int inside the loop will work in C99. –  splicer Mar 11 '11 at 2:54
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initializing structure to zero

struct mystruct a = {0};

this will zero all stucture elements.

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2  
It doesn't zero the padding, if any, however. –  Mikeage Mar 1 '09 at 13:49
2  
@simonn, no it doesn't do undefined behavior if the structure contains non-integral types. memset with 0 on the memory of a float/double will still be zero when you interpret the float/double (float/double are designed like that on purpose). –  Trevor Boyd Smith Jun 11 '09 at 13:59
6  
@Andrew: memset/calloc do "all bytes zero" (i.e. physical zeroes), which is indeed not defined for all types. { 0 } is guaranteed to intilaize everything with proper logical zero values. Pointers, for example, are guranteed to get their proper null values, even if the null-value on the given platform is 0xBAADFOOD. –  AndreyT Oct 28 '09 at 10:12
1  
@nvl: You get physical zero when you just forcefully set all memory occupied by the object to all-bits-zero state. This is what memset does (with 0 as second argument). You get logical zero when you initialize/assign 0 ( or { 0 }) to the object in the source code. These two kinds of zeros do not necessarily produce the same result. As in the example with pointer. When you do memset on a pointer, you get a 0x0000 pointer. But when you assign 0 to a pointer, you get null pointer value, which at the physical level might be 0xBAADF00D or anything else. –  AndreyT Feb 26 '10 at 16:29
3  
@nvl: Well, in practice the difference is often only conceptual. But in theory, virtually any type can have it. For example, double. Usually it is implemented in accordance with IEEE-754 standard, in which the logical zero and physical zero are the same. But IEEE-754 is not required by the language. So it might happen that when you do double d = 0; (logical zero), physically some bits in memory occupied by d will not be zero. –  AndreyT Feb 26 '10 at 19:17
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Multi-character constants:

int x = 'ABCD';

This sets x to 0x41424344 (or 0x44434241, depending on architecture).

EDIT: This technique is not portable, especially if you serialize the int. However, it can be extremely useful to create self-documenting enums. e.g.

enum state {
    stopped = 'STOP',
    running = 'RUN!',
    waiting = 'WAIT',
};

This makes it much simpler if you're looking at a raw memory dump and need to determine the value of an enum without having to look it up.

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8  
The "not portable" comments miss the point entirely. It is like criticizing a program for using INT_MAX just because INT_MAX is "not portable" :) This feature is as portable as it needs to be. Multi-char constant is an extremely useful feature that provides readable way to for generating unique integer IDs. –  AndreyT Oct 28 '09 at 10:36
1  
@Chris Lutz - I'm pretty sure the trailing comma goes all the way back to K&R. It's described in the second edition (1988). –  Ferruccio Oct 28 '09 at 11:15
1  
@Ferruccio: You must be thinking about the trailing comma in the aggregate initailizer lists. As for the trailing comma in enum declarations - it's a recent addition, C99. –  AndreyT Oct 28 '09 at 17:59
3  
You forgot 'HANG' or 'BSOD' :-) –  JBRWilkinson Nov 2 '09 at 16:30
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I never used bit fields but they sound cool for ultra-low-level stuff.

struct cat {
    unsigned int legs:3;  // 3 bits for legs (0-4 fit in 3 bits)
    unsigned int lives:4; // 4 bits for lives (0-9 fit in 4 bits)
    // ...
};

cat make_cat()
{
    cat kitty;
    kitty.legs = 4;
    kitty.lives = 9;
    return kitty;
}

This means that sizeof(cat) can be as small as sizeof(char).


Incorporated comments by Aaron and leppie, thanks guys.

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5  
Bitfields are not portable -- the compiler can choose freely whether, in your example, legs will be allocated the most significant 3 bits, or the least significant 3 bits. –  zvrba Sep 25 '08 at 14:25
3  
Bitfields are an example of where the standard gives implementations so much freedom in how they're inplemented, that in practice, they're nearly useless. If you care how many bits a value takes up, and how it's stored, you're better off using bitmasks. –  Mark Bessey Oct 17 '08 at 4:13
26  
Bitfields are indeed portable as long as you treat them as the structure elements they are, and not "pieces of integers." Size, not location, matters in an embedded system with limited memory, as each bit is precious ... but most of today's coders are too young to remember that. :-) –  Adam Liss Oct 26 '08 at 0:41
5  
@Adam: location may well matter in an embedded system (or elsewhere), if you are depending on the position of the bitfield within its byte. Using masks removes any ambiguity. Similarly for unions. –  Steve Melnikoff Mar 1 '09 at 22:51
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C has a standard but not all C compilers are fully compliant (I've not seen any fully compliant C99 compiler yet!).

That said, the tricks I prefer are those that are non-obvious and portable across platforms as they rely on the C semantic. They usually are about macros or bit arithmetic.

For example: swapping two unsigned integer without using a temporary variable:

...
a ^= b ; b ^= a; a ^=b;
...

or "extending C" to represent finite state machines like:

FSM {
  STATE(x) {
    ...
    NEXTSTATE(y);
  }

  STATE(y) {
    ...
    if (x == 0) 
      NEXTSTATE(y);
    else 
      NEXTSTATE(x);
  }
}

that can be achieved with the following macros:

#define FSM
#define STATE(x)      s_##x :
#define NEXTSTATE(x)  goto s_##x

In general, though, I don't like the tricks that are clever but make the code unnecessarily complicated to read (as the swap example) and I love the ones that make the code clearer and directly conveying the intention (like the FSM example).

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18  
C supports chaining, so you can do a ^= b ^= a ^= b; –  OJ. Sep 25 '08 at 10:06
4  
Strictly speaking, the state example is a tick of the preprocessor, and not the C language - it is possible to use the former without the latter. –  Greg Whitfield Sep 25 '08 at 13:10
15  
OJ: actually what you suggest is undefined behavior because of sequence point rules. It may work on most compilers, but is not correct or portable. –  Evan Teran Sep 25 '08 at 14:14
5  
Xor swap could actually be less efficient in the case of a free register. Any decent optimizer would make the temp variable be a register. Depending on implementation (and need for parallelism support) the swap might actually use real memory instead of a register (which would be the same). –  Paul de Vrieze Oct 17 '08 at 9:49
27  
please don't ever actually do this: en.wikipedia.org/wiki/… –  Christian Oudard Jan 2 '09 at 18:55
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Interlacing structures like Duff's Device:

strncpy(to, from, count)
char *to, *from;
int count;
{
    int n = (count + 7) / 8;
    switch (count % 8) {
    case 0: do { *to = *from++;
    case 7:      *to = *from++;
    case 6:      *to = *from++;
    case 5:      *to = *from++;
    case 4:      *to = *from++;
    case 3:      *to = *from++;
    case 2:      *to = *from++;
    case 1:      *to = *from++;
               } while (--n > 0);
    }
}
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29  
@ComSubVie, anyone who uses Duff's Device is a script kiddy who saw Duff's Device and thought their code would look 1337 if they used Duff's Device. (1.) Duff's Device doesn't offer any performance increases on modern processor because modern processors have zero-overhead-looping. In other words it is an obsolete piece of code. (2.) Even if your processor doesn't offer zero-overhead-looping, it will probably have something like SSE/altivec/vector-processing which will put your Duff's Device to shame when you use memcpy(). (3.) Did I mention that other that doing memcpy() duff's is not useful? –  Trevor Boyd Smith Jun 11 '09 at 13:50
2  
@ComSubVie, please meet my Fist-of-death (en.wikipedia.org/wiki/…) –  Trevor Boyd Smith Jun 11 '09 at 13:52
12  
@Trevor: so only script kiddies program 8051 and PIC microcontrollers, right? –  SF. Feb 19 '10 at 11:13
6  
@Trevor Boyd Smith : While the Duff's Device appears outdated, it's still an historical curiosity, which validates ComSubVie's answer. Anyway, quoting Wikipedia : "When numerous instances of Duff's device were removed from the XFree86 Server in version 4.0, there was a notable improvement in performance."... –  paercebal May 8 '10 at 9:01
2  
On Symbian, we once evaluated various loops for fast pixel coding; the duff's device, in assembler, was the fastest. So it still had relevance on the mainstream ARM cores on your smartphones today. –  Will Oct 25 '10 at 8:37
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I'm very fond of designated initializers, added in C99 (and supported in gcc for a long time):

#define FOO 16
#define BAR 3

myStructType_t myStuff[] = {
    [FOO] = { foo1, foo2, foo3 },
    [BAR] = { bar1, bar2, bar3 },
    ...

The array initialization is no longer position dependent. If you change the values of FOO or BAR, the array initialization will automatically correspond to their new value.

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C99 has some awesome any-order structure initialization.

struct foo{
  int x;
  int y;
  char* name;
};

void main(){
  struct foo f = { .y = 23, .name = "awesome", .x = -38 };
}

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anonymous structures and arrays is my favourite one. (cf. http://www.run.montefiore.ulg.ac.be/~martin/resources/kung-f00.html)

setsockopt(yourSocket, SOL_SOCKET, SO_REUSEADDR, (int[]){1}, sizeof(int));

or

void myFunction(type* values) {
    while(*values) x=*values++;
}
myFunction((type[]){val1,val2,val3,val4,0});

it can even be used to instanciate linked lists...

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3  
This feature is usually called "compound literals". Anonymous (or unnamed) structures designate nested structures that have no member names. –  calandoa Jun 22 '09 at 11:47
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gcc has a number of extensions to the C language that I enjoy, which can be found here. Some of my favorites are function attributes. One extremely useful example is the format attribute. This can be used if you define a custom function that takes a printf format string. If you enable this function attribute, gcc will do checks on your arguments to ensure that your format string and arguments match up and will generate warnings or errors as appropriate.

int my_printf (void *my_object, const char *my_format, ...)
            __attribute__ ((format (printf, 2, 3)));
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the (hidden) feature that "shocked" me when I first saw is about printf. this feature allows you to use variables for formatting format specifiers themselves. look for the code, you will see better:

#include <stdio.h>

int main() {
    int a = 3;
    float b = 6.412355;
    printf("%.*f\n",a,b);
    return 0;
}

the * character achieves this effect.

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Well... I think that one of the strong points of C language is its portability and standardness, so whenever I find some "hidden trick" in the implementation I am currently using, I try not to use it because I try to keep my C code as standard and portable as possible.

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1  
And the code is more stable if you code like that ;) –  Johan Jun 22 '09 at 5:43
3  
@Joe D if its a cross platform project like Windows/OSX/Linux, probably a bit, and also there's different arch such as x86 vs x86_64 and etc... –  Pharaun Nov 11 '10 at 17:13
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Compile-time assertions, as already discussed here.

//--- size of static_assertion array is negative if condition is not met
#define STATIC_ASSERT(condition) \
    typedef struct { \
        char static_assertion[condition ? 1 : -1]; \
    } static_assertion_t

//--- ensure structure fits in 
STATIC_ASSERT(sizeof(mystruct_t) <= 4096);
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Constant string concatenation

I was quite surprised not seeing it allready in the answers, as all compilers I know of support it, but many programmers seems to ignore it. Sometimes it's really handy and not only when writing macros.

Use case I have in my current code: I have a #define PATH "/some/path/" in a configuration file (really it is setted by the makefile). Now I want to build the full path including filenames to open ressources. It just goes to:

fd = open(PATH "/file", flags);

Instead of the horrible, but very common:

char buffer[256];
snprintf(buffer, 256, "%s/file", PATH);
fd = open(buffer, flags);

Notice that the common horrible solution is:

  • three times as long
  • much less easy to read
  • much slower
  • less powerfull at it set to an arbitrary buffer size limit (but you would have to use even longer code to avoid that without constant strings contatenation).
  • use more stack space
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1  
It is also useful to split a string constant on multiple source lines without using dirty `\`. –  dolmen Mar 28 '11 at 21:35
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Well, I've never used it, and I'm not sure whether I'd ever recommend it to anyone, but I feel this question would be incomplete without a mention of Simon Tatham's co-routine trick.

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When initializing arrays or enums, you can put a comma after the last item in the initializer list. e.g:

int x[] = { 1, 2, 3, };

enum foo { bar, baz, boom, };

This was done so that if you're generating code automatically you don't need to worry about eliminating the last comma.

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Struct assignment is cool. Many people don't seem to realize that structs are values too, and can be assigned around, there is no need to use memcpy(), when a simple assignment does the trick.

For example, consider some imaginary 2D graphics library, it might define a type to represent an (integer) screen coordinate:

typedef struct {
   int x;
   int y;
} Point;

Now, you do things that might look "wrong", like write a function that creates a point initialized from function arguments, and returns it, like so:

Point point_new(int x, int y)
{
  Point p;
  p.x = x;
  p.y = y;
  return p;
}

This is safe, as long (of course) as the return value is copied by value using struct assignment:

Point origin;
origin = point_new(0, 0);

In this way you can write quite clean and object-oriented-ish code, all in plain standard C.

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4  
Of course, there are performance implications to passing round large structs in this way; it's often useful (and is indeed something a lot of people don't realise you can do) but you need to consider whether passing pointers is better. –  Mark Baker Oct 17 '08 at 8:47
1  
Of course, there might be. Ít's also quite possible for the compiler to detect the usage and optimize it. –  unwind Oct 17 '08 at 8:57
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Strange vector indexing:

int v[100]; int index = 10; 
/* v[index] it's the same thing as index[v] */
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4  
It's even better... char c = 2["Hello"]; (c == 'l' after this). –  yrp Sep 25 '08 at 10:20
5  
Not so strange when you consider that v[index] == *(v + index) and index[v] == *(index + v) –  Ferruccio Sep 25 '08 at 14:36
17  
Please tell me you don't actually use this "all the time", like the question asks! –  Tryke Sep 25 '08 at 20:52
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C compilers implement one of several standards. However, having a standard does not mean that all aspects of the language are defined. Duff's device, for example, is a favorite 'hidden' feature that has become so popular that modern compilers have special purpose recognition code to ensure that optimization techniques do not clobber the desired effect of this often used pattern.

In general hidden features or language tricks are discouraged as you are running on the razor edge of whichever C standard(s) your compiler uses. Many such tricks do not work from one compiler to another, and often these kinds of features will fail from one version of a compiler suite by a given manufacturer to another version.

Various tricks that have broken C code include:

  1. Relying on how the compiler lays out structs in memory.
  2. Assumptions on endianness of integers/floats.
  3. Assumptions on function ABIs.
  4. Assumptions on the direction that stack frames grow.
  5. Assumptions about order of execution within statements.
  6. Assumptions about order of execution of statements in function arguments.
  7. Assumptions on the bit size or precision of short, int, long, float and double types.

Other problems and issues that arise whenever programmers make assumptions about execution models that are all specified in most C standards as 'compiler dependent' behavior.

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2  
@Blaisorblade, Even better, use compile-time assertions to document your assumptions in a way that will make the compile fail on a platform where they are violated. –  RBerteig Aug 1 '10 at 0:06
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When using sscanf you can use %n to find out where you should continue to read:

sscanf ( string, "%d%n", &number, &length );
string += length;

Apparently, you can't add another answer, so I'll include a second one here, you can use "&&" and "||" as conditionals:

#include <stdio.h>
#include <stdlib.h>

int main()
{
   1 || puts("Hello\n");
   0 || puts("Hi\n");
   1 && puts("ROFL\n");
   0 && puts("LOL\n");

   exit( 0 );
}

This code will output:

Hi
ROFL
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using INT(3) to set break point at the code is my all time favorite

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3  
I don't think it's portable. It will work on x86, but what about other platforms? –  Cristian Ciupitu Sep 25 '08 at 19:25
1  
I have no idea - You should post a question about it –  Dror Helper Dec 8 '08 at 16:48
1  
@ Dror Helper No, this type of thing should be "you should try it yourself"... –  Ape-inago Mar 4 '09 at 15:53
2  
It's a good technique and it is X86 specific (although there are probably similar techniques on other platforms). However, this is not a feature of C. It depends on non-standard C extensions or library calls. –  Ferruccio Jun 22 '09 at 12:28
1  
In GCC there is __builtin_trap and for MSVC __debugbreak which will work on any supported architecture. –  Axel Gneiting Jun 7 '10 at 19:05
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My favorite "hidden" feature of C, is the usage of %n in printf to write back to the stack. Normally printf pops the parameter values from the stack based on the format string, but %n can write them back.

Check out section 3.4.2 here. Can lead to a lot of nasty vulnerabilities.

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Compile-time assumption-checking using enums: Stupid example, but can be really useful for libraries with compile-time configurable constants.

#define D 1
#define DD 2

enum CompileTimeCheck
{
    MAKE_SURE_DD_IS_TWICE_D = 1/(2*(D) == (DD)),
    MAKE_SURE_DD_IS_POW2    = 1/((((DD) - 1) & (DD)) == 0)
};
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2  
+1 Neat. I used to use the CompilerAssert macro from Microsoft, but yours is not bad either. (#define CompilerAssert(exp) extern char _CompilerAssert[(exp)?1:-1]) –  tristopia Nov 27 '10 at 12:52
1  
I like the enumeration method. The approach I'd used before took advantage of dead code elimination: "if (something_bad) {void BLORG_IS_WOOZLED(void); BLORG_IS_WOOZLED();}" which didn't error until link time, though it did offer the advantage of letting the programmer know via error message that the blorg was woozled. –  supercat Aug 25 '11 at 21:28
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Gcc (c) has some fun features you can enable, such as nested function declarations, and the a?:b form of the ?: operator, which returns a if a is not false.

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I discoverd recently 0 bitfields.

struct {
  int    a:3;
  int    b:2;
  int     :0;
  int    c:4;
  int    d:3;
};

which will give a layout of

000aaabb 0ccccddd

instead of without the :0;

0000aaab bccccddd

The 0 width field tells that the following bitfields should be set on the next atomic entity (char)

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C99-style variable argument macros, aka

#define ERR(name, fmt, ...)   fprintf(stderr, "ERROR " #name ": " fmt "\n", \
                                  __VAR_ARGS__)

which would be used like

ERR(errCantOpen, "File %s cannot be opened", filename);

Here I also use the stringize operator and string constant concatentation, other features I really like.

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Variable size automatic variables are also useful in some cases. These were added i nC99 and have been supported in gcc for a long time.

void foo(uint32_t extraPadding) {
    uint8_t commBuffer[sizeof(myProtocol_t) + extraPadding];

You end up with a buffer on the stack with room for the fixed-size protocol header plus variable size data. You can get the same effect with alloca(), but this syntax is more compact.

You have to make sure extraPadding is a reasonable value before calling this routine, or you end up blowing the stack. You'd have to sanity check the arguments before calling malloc or any other memory allocation technique, so this isn't really unusual.

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