3

I want to store some data, that can be of a different type that is only known in runtime. I do not want to waste any memory and I want to read all data as float values. In C++ I would have done something like this

struct IA {
  virtual float value(int index) = 0;
};

template<class T>
struct A : public IA {
  A(T* bytes, uint32_t size) { 
    values.resize(size);
    memcpy(values.data(), bytes, size*sizeof(T));
  }
  float value(int index) override {
      return static_cast<float>(values[index]);
  }
  std::vector<T> values;
};


int main() {
  uint16_t bytes[] = {1, 2, 3, 4, 5 }; 
  IA *a = new A<uint16_t>(bytes, 5);
  float value = a->value(0);
  delete a;
}

My question is how this would be done using C instead of C++. I could store the data in an uint8_t array and store nr of bits and a signed value. Then use a switch case and a cast every time I read a value from the array. But that would be expensive if the array is large and if there are many reads.

I also want to be able to pass the array around without having to do any special if cases?

closed as too broad by πάντα ῥεῖ, Sam Varshavchik, Brian Tompsett - 汤莱恩 Aug 19 at 21:19

Please edit the question to limit it to a specific problem with enough detail to identify an adequate answer. Avoid asking multiple distinct questions at once. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

  • 2
    You create a separate function for each case. read_as_uint16_t() read_as_uint32_t() read_as_uint64_t() etc. Using int or uint32_t for indexing arrays is strange, use size_t. – Kamil Cuk Aug 19 at 10:51
  • 2
    In C++, A(T* bytes, uint32_t size) : values(bytes, bytes + size){} would be better than memcpy. – Jarod42 Aug 19 at 10:53
  • Your code leaks memory. The a is never freed. – Kamil Cuk Aug 19 at 11:03
  • 2
    Would an union not work? – TUI lover Aug 19 at 11:21
  • When you say different types, do you mean different types of numerical values? (8 bit int, 16 bit int, 32 bit int, etc.?) – ttemple Aug 19 at 11:30
8

You can mimic virtual method with function pointer:

typedef struct
{
    void* userData;
    float (*value)(void*, int);
} IA;

float get_float_from_uint16(void* userData, int index)
{
    return ((uint16_t*) userData)[index];
}

int main()
{
    uint16_t bytes[] = {1, 2, 3, 4, 5 }; 
    IA a = {bytes, &get_float_from_uint16};

    int index = 0;
    float f = a.value(a.userData, index);
}

Demo

  • This solution is really nice, there is only one problem with it, the same problem as in c++ I would guess. If the array is large, there will be many function calls that cost a lot? – Samantha Aug 19 at 12:04
  • @Samantha The first parameter of the function pointed to by struct member value is a pointer, so the size of the array will have no impact on performance / memory usage at the time of calling the function pointer. – Jim Fell Aug 19 at 12:21
  • yeah, but if you do many lookups, there will always be a function call? – Samantha Aug 19 at 12:46
  • Neat solution! Just to nitpick, isn't the & redundant in IA a{bytes, &get_float_from_uint16};? – th33lf Aug 19 at 12:54
  • 1
    @ryyker: typo fixed and demo added. (used to code in C++). – Jarod42 Aug 19 at 13:31
0

Sure, that's plain and easy (spoiler alert: no, it's not easy, it's very hard). The following code I believe does the same as C++, but is written in C like.

So what happens:

  • At first I define struct IA_s that is an interface for accessing IA like objects. The structure holds only a virtual table for accessing the objects. The AI object has one accessor IA_value that does the same as IA::value in your code. I also added the objects destructor to the virtual table and IA_fini function that is a destructor. It's missing in your code and your code leaks memory.
  • Then I create two big macros A_C and A_H. A_H is intented to be used in header files. A_C is intended to be used inside sources files. They define a generic implementation of A object for any type. The first macro argument is the prefix to be used to prefix all exported symbols. The second is the type. The A object holds a dynamic array of some type elements.
  • Then I instantiate the generic macros on uint16_t type with uint16_ prefix.
  • Then in main function I allocate memory for A object, call it's constructor, cast it to IA object, get the value for the 2nd index and call all destructors.

Notes:

  • constructors are named *_init, destructors are named *_fini, all functions that touch an object are named object_*.
  • that was fun to do
  • I think I would never use such code in production
  • All heaps freed in valgrind

#include <assert.h>
#include <errno.h>
#include <limits.h>
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

/* IA object ---------------------------------------------- */

// forward definition for IA__vtable_s
struct IA_s;

// the virtual table of the object
struct IA__vtable_s {
    float (*value)(struct IA_s *ctx, size_t index);
    void (*fini)(struct IA_s *ctx);
};

// The structure, holds only the vtable
struct IA_s {
    const struct IA__vtable_s *vtable;
};

/**
 * Get the value holded in index index
 * @param t
 * @return the value
 */
float IA_value(struct IA_s *t, size_t index) {
    assert(t != NULL);
    assert(t->vtable != NULL);
    assert(t->vtable->value != NULL);
    return t->vtable->value(t, index);
}

/**
 * Call the destructor of IA object
 */
void IA_fini(struct IA_s *t) {
    assert(t != NULL);
    assert(t->vtable != NULL);
    assert(t->vtable->fini != NULL);
    t->vtable->fini(t);
}

/* A object ---------------------------------------------- */

/**
 * Header template of A object
 */
#define A_H(NAME, TYPE)  \
/* A object */ \
struct NAME##A_s { \
\
   /* pointer to allocated array */ \
   TYPE *arr; \
\
   /* elements in the array. */ \
   size_t cnt; \
\
   /* I think we have to have that. */ \
   struct IA_s ia; \
\
}; \
\
/* Initializes A object. The *bytes are copied into the object */ \
/* @param t */ \
/* @patam bytes pointer to size count of objects */ \
/* @param size */ \
/* @returns negative errno value on error, 0 on success */ \
int NAME##A_init(struct NAME##A_s *t, TYPE *bytes, size_t size); \
\
/* Deinitializes A object. */ \
void NAME##A_fini(struct NAME##A_s *t); \
\
/* Converts A object in IA object */ \
struct IA_s *NAME##A_to_IA(struct NAME##A_s *t);
// end of A_H

#define A_C(NAME, TYPE) \
\
/* A to IA interface ----------------------------------------------------- */ \
\
/* Convert pointer to IA_s to pointer to A_s */ \
static \
struct NAME##A_s *NAME##A__pnt_from_ia(struct IA_s *t) { \
    return (void*)( ((unsigned char*)(void *)t) - offsetof(struct NAME##A_s, ia) ); \
} \
\
/* this is our value function inside IA interface */ \
static \
float NAME##A__IA_value(struct IA_s *ia, size_t index) { \
    struct NAME##A_s *t = NAME##A__pnt_from_ia(ia); \
    assert(t != NULL); \
    /* UB happens, as in case of vector::operator[] */ \
    assert(index <= t->cnt); \
    return t->arr[index]; \
} \
\
/* this is our destructor inside IA interface */ \
static \
void NAME##A__IA_fini(struct IA_s *ia) { \
    struct NAME##A_s *t = NAME##A__pnt_from_ia(ia); \
    assert(t != NULL); \
    NAME##A_fini(t); \
} \
\
static const struct IA__vtable_s NAME##A__IA_vtable = { \
    .value = NAME##A__IA_value, \
    .fini = NAME##A__IA_fini, \
}; \
\
int NAME##A_init(struct NAME##A_s *t, TYPE *bytes, size_t cnt) { \
    assert(t != NULL); \
    assert(bytes != NULL); \
    if (cnt == 0) {  \
       /* malloc(0) happens to be nonportable */ \
       t->arr = NULL; \
       t->cnt = 0; \
       return 0; \
    } \
    if (SIZE_MAX / sizeof(*t->arr) < cnt) { \
    /* multiplication overflow */ \
    return -EOVERFLOW; \
    } \
    t->arr = malloc(cnt * sizeof(*t->arr)); \
    if (t->arr == NULL) { \
        return -ENOMEM; \
    } \
    t->cnt = cnt; \
    memcpy(t->arr, bytes, cnt * sizeof(*t->arr)); \
    t->ia.vtable = &NAME##A__IA_vtable; \
    return 0; \
} \
void NAME##A_fini(struct NAME##A_s *t) { \
    assert(t != NULL); \
    free(t->arr); \
    t->arr = NULL; \
    t->cnt = 0; \
} \
struct IA_s *NAME##A_to_IA(struct NAME##A_s *t) { \
     assert(t != NULL); \
     return &t->ia; \
}

// A<uint16_t>
A_H(uint16_, uint16_t)
A_C(uint16_, uint16_t)

int main() {
    uint16_t bytes[] = {1, 2, 3, 4, 5 };

    // new()
    struct uint16_A_s *temp = malloc(sizeof(*temp));
    if (temp == NULL) {
        // destructors
        abort();
    }

    // A::A(bytes, 5)
    int ret = uint16_A_init(temp, bytes, 5);
    if (ret != 0) {
        // destructors
        free(temp);
        abort();
    }

    // IA *ia = A;
    struct IA_s *ia = uint16_A_to_IA(temp);
    if (ia == NULL) {
        // destructors
        uint16_A_fini(temp);
        free(temp);
        abort();
    }

    // finally call IA::value(2)
    float value = IA_value(ia, 2);
    printf("%f\n", value);

    // destructors
    IA_fini(ia); // or uint16_A_fini(temp) depending on which you call delete on

    free(temp);
}
  • The testers will love you.... haha ;) – alk Aug 19 at 12:18
  • Somebody likes macros. – Jim Fell Aug 19 at 12:22

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