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I want to store mixed data types in an array. How could one do that?

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It's possible and there are use cases, but this is likely a flawed design. That's not what arrays are for. –  djechlin Oct 18 '13 at 15:20

6 Answers 6

up vote 190 down vote accepted

You can make the array elements in a discriminated union, aka tagged union.

struct {
    enum { is_int, is_float, is_char } type;
    union {
        int ival;
        float fval;
        char cval;
    } val;
} my_array[10];

The type member is used to hold the choice of which member of the union is should be used for each array element. So if you want to store an int in the first element, you would do:

my_array[0].type = is_int;
my_array[0].val.ival = 3;

When you want to access an element of the array,firstly you must check the type, then use the corresponding member of the union.For this A switch statement is useful:

switch (my_array[n].type) {
case is_int:
    // Do stuff for integer, using my_array[n].ival
case is_float:
    // Do stuff for float, using my_array[n].fval
case is_char:
    // Do stuff for char, using my_array[n].cvar
    // Report an error, this shouldn't happen

It is left up to the programmer to ensure that the type member always corresponds to the last value stored in the union.

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+1 This is the implentation of many interpreting languages written in C –  texasbruce Sep 2 '13 at 16:42
@texasbruce also called a "tagged union". I'm using this technique too in my own language. ;) –  user529758 Sep 2 '13 at 16:50
Wikipedia uses a disambiguation page for "discriminated union" - "disjoint union" in set theory and, as @H2CO3 mentioned, "tagged union" in computer science. –  Izkata Sep 2 '13 at 17:38
And the first line of the Wikipedia Tagged union page says: In computer science, a tagged union, also called a variant, variant record, discriminated union, disjoint union, or sum type, ... It's been reinvented so many times it has many names (kind of like dictionaries, hashes, associative arrays, etc.). –  Barmar Sep 2 '13 at 17:40
@Barmar I've re-written it as "tagged union" but then read your comment. Rolled back the edit, I didn't mean to vandalize your answer. –  user529758 Sep 2 '13 at 17:44

Use a union:

union {
    int ival;
    float fval;
    void *pval;
} array[10];

You will have to keep track of the type of each element, though.

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Array elements need to have the same size, that is why it's not possible. You could work around it by creating a variant type:

#include <stdio.h>
#define SIZE 3

typedef enum __VarType {
} VarType;

typedef struct __Var {
  VarType type;
  union {
    int i;
    char c;
    float f;
} Var;

void var_init_int(Var *v, int i) {
  v->type = V_INT;
  v->i = i;

void var_init_char(Var *v, char c) {
  v->type = V_CHAR;
  v->c = c;

void var_init_float(Var *v, float f) {
  v->type = V_FLOAT;
  v->f = f;

int main(int argc, char **argv) {

  Var v[SIZE];
  int i;

  var_init_int(&v[0], 10);
  var_init_char(&v[1], 'C');
  var_init_float(&v[2], 3.14);

  for( i = 0 ; i < SIZE ; i++ ) {
    switch( v[i].type ) {
      case V_INT  : printf("INT   %d\n", v[i].i); break;
      case V_CHAR : printf("CHAR  %c\n", v[i].c); break;
      case V_FLOAT: printf("FLOAT %f\n", v[i].f); break;

  return 0;

The size of the element of the union is the size of the largest element, 4.

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There's a different style of defining the tag-union (by whatever name) that IMO make it much nicer to use, by removing the internal union. This is the style used in the X Window System for things like Events.

The example in Barmar's answer gives the name val to the internal union. The example in Sp.'s answer uses an anonymous union to avoid having to specify the .val. every time you access the variant record. Unfortunately "anonymous" internal structs and unions is not available in C89 or C99. It's a compiler extension, and therefore inherently non-portable.

A better way IMO is to invert the whole definition. Make each data type its own struct, and put the tag (type specifier) into each struct.

typedef struct {
    int tag;
    int val;
} integer;

typedef struct {
    int tag;
    float val;
} real;

Then you wrap these in a top-level union.

typedef union {
    int tag;
    integer int_;
    real real_;
} record;

enum types { INVALID, INT, REAL };

Now it may appear that we're repeating ourselves, and we are. But consider that this definition is likely to be isolated to a single file. But we've eliminated the noise of specifiying the intermediate .val. before you get to the data.

record i;
i.tag = INT;
i.int_.val = 12;

record r;
r.tag = REAL;
r.real_.val = 57.0;

Instead, it goes at the end, where it's less obnoxious. :D

Another thing this allows is a form of inheritance. Edit: this part is not standard C, but uses a GNU extension.

if (r.tag == INT) {
    integer x = r;
    x.val = 36;
} else if (r.tag == REAL) {
    real x = r;
    x.val = 25.0;

integer g = { INT, 100 };
record rg = g;

Up-casting and down-casting.

Edit: One gotcha to be aware of is if you're constructing one of these with C99 designated initializers. All member initializers should be through the same union member.

record problem = { .tag = INT, .int_.val = 3 };

problem.tag; // may not be initialized

The .tag initializer can be ignored by an optimizing compiler, because the .int_ initializer that follows aliases the same data area. Even though we know the layout (!), and it should be ok. No, it ain't. Use the "internal" tag instead (it overlays the outer tag, just like we want, but doesn't confuse the compiler).

record not_a_problem = { .int_.tag = INT, .int_.val = 3 };

not_a_problem.tag; // == INT
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You can do a void * array, with a separated array of size_t. But you lose the information type.
If you need to keep information type in some way keep a third array of int (where the int is an enumerated value) Then code the function that casts depending on the enum value.

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Union is the standard way to go. But you have other solutions as well.

One is tagged pointer. That takes the advantage of aligned memory, where the low bits of addresses are always zero. For example in 32-bit systems, pointers to int must be multiples of 4 and the low 2 bits must be 0, hence you can use it to store the type of your values. Of course you need to clear the bits before dereferencing values.

void* tp; // tagged pointer
enum { is_int, is_double, is_char_p, is_char } type;
// ...
intptr_t addr = (intptr_t)tp & ~0x03; // clear the 2 low bits in the pointer
switch ((intptr_t)tp & 0x03) // check the 2 low bits for the type
case is_int:    // data is int
    printf("%d\n", *((int*)addr));
case is_double: // data is double
    printf("%f\n", *((double*)addr));
case is_char_p: // data is char*
    printf("%s\n", (char*)addr);
case is_char:   // data is char
    printf("%c\n", *((char*)addr));

If you can make sure that the data is 8-byte aligned, you'll have one more bit for the tag. On most current 64-bit systems the virtual address is still 48 bits, hence the high 16 bits can also be used as tags.

This has one disavantage that you'll need more memory if the data have not been stored anywhere. Therefore in case the type and range of your data is limited, you can store the values directly in the pointer. This has been used in Chrome's V8 engine, where it checks the least significant bit of the address to see if that's a pointer to double or a 31-bit signed value (called smi - small integer). If it's an int, Chrome simply does an arithmetic right shift 1 bit to get the value, otherwise the pointer is dereferenced.

In prior versions of Mozilla Firefox they also use small integer optimizations like V8, with the 3 low bits used to store the type (int, string, object... etc.). But since JaegerMonkey they took another path (Mozilla’s New JavaScript Value Representation). The value is now always stored in a 64-bit double precision variable. When the double is a normalized one, it can be used directly in calculations. However if the high 16 bits of it are all 1s, which denote an NaN, the low 32-bits will store the address (in a 32-bit computer) to the value or the value directly, the remaining 16-bits will be used to store the type. This technique is called NaN-boxing. If your main data type is floating-point, this is the best solution and delivers very good performance. In 64-bit machines it can also be used, as the address is often only 48 bits as stated above.

Read more about the above techniques:

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