我应该如何在C中使用函数指针数组?
如何初始化它们?
答案 0 :(得分:177)
你有一个很好的例子here (Array of Function pointers)和syntax detailed。
int sum(int a, int b);
int subtract(int a, int b);
int mul(int a, int b);
int div(int a, int b);
int (*p[4]) (int x, int y);
int main(void)
{
int result;
int i, j, op;
p[0] = sum; /* address of sum() */
p[1] = subtract; /* address of subtract() */
p[2] = mul; /* address of mul() */
p[3] = div; /* address of div() */
[...]
调用其中一个函数指针:
result = (*p[op]) (i, j); // op being the index of one of the four functions
答案 1 :(得分:35)
上述答案可能对您有所帮助,但您可能也想知道如何使用函数指针数组。
void fun1()
{
}
void fun2()
{
}
void fun3()
{
}
void (*func_ptr[3]) = {fun1, fun2, fun3};
main()
{
int option;
printf("\nEnter function number you want");
printf("\nYou should not enter other than 0 , 1, 2"); /* because we have only 3 functions */
scanf("%d",&option);
if((option>=0)&&(option<=2))
{
(*func_ptr[option])();
}
return 0;
}
您只能将具有相同返回类型和相同参数类型且没有参数的函数的地址分配给单个函数指针数组。
如果所有上述函数具有相同数量的相同类型的参数,您也可以传递如下所示的参数。
(*func_ptr[option])(argu1);
注意:在数组中,函数指针的编号将从0开始,与一般数组相同。因此,在上面的示例中,如果option = 0,则可以调用fun1,如果option = 1,则可以调用fun2,如果option = 2,则可以调用fun3。
答案 2 :(得分:9)
以下是如何使用它:
#ifndef NEW_FUN_H_
#define NEW_FUN_H_
#include <stdio.h>
typedef int speed;
speed fun(int x);
enum fp {
f1, f2, f3, f4, f5
};
void F1();
void F2();
void F3();
void F4();
void F5();
#endif
#include "New_Fun.h"
speed fun(int x)
{
int Vel;
Vel = x;
return Vel;
}
void F1()
{
printf("From F1\n");
}
void F2()
{
printf("From F2\n");
}
void F3()
{
printf("From F3\n");
}
void F4()
{
printf("From F4\n");
}
void F5()
{
printf("From F5\n");
}
#include <stdio.h>
#include "New_Fun.h"
int main()
{
int (*F_P)(int y);
void (*F_A[5])() = { F1, F2, F3, F4, F5 }; // if it is int the pointer incompatible is bound to happen
int xyz, i;
printf("Hello Function Pointer!\n");
F_P = fun;
xyz = F_P(5);
printf("The Value is %d\n", xyz);
//(*F_A[5]) = { F1, F2, F3, F4, F5 };
for (i = 0; i < 5; i++)
{
F_A[i]();
}
printf("\n\n");
F_A[f1]();
F_A[f2]();
F_A[f3]();
F_A[f4]();
return 0;
}
我希望这有助于理解Function Pointer.
答案 3 :(得分:5)
这个“答案”更像是VonC答案的附录;只是注意到可以通过typedef简化语法,并且可以使用聚合初始化:
typedef int FUNC(int, int);
FUNC sum, subtract, mul, div;
FUNC *p[4] = { sum, subtract, mul, div };
int main(void)
{
int result;
int i = 2, j = 3, op = 2; // 2: mul
result = p[op](i, j); // = 6
}
// maybe even in another file
int sum(int a, int b) { return a+b; }
int subtract(int a, int b) { return a-b; }
int mul(int a, int b) { return a*b; }
int div(int a, int b) { return a/b; }
答案 4 :(得分:2)
哦,有很多例子。只要看看glib或gtk中的任何内容。 你可以在那里看到函数指针的工作。
这里例如gtk_button的初始化。
static void
gtk_button_class_init (GtkButtonClass *klass)
{
GObjectClass *gobject_class;
GtkObjectClass *object_class;
GtkWidgetClass *widget_class;
GtkContainerClass *container_class;
gobject_class = G_OBJECT_CLASS (klass);
object_class = (GtkObjectClass*) klass;
widget_class = (GtkWidgetClass*) klass;
container_class = (GtkContainerClass*) klass;
gobject_class->constructor = gtk_button_constructor;
gobject_class->set_property = gtk_button_set_property;
gobject_class->get_property = gtk_button_get_property;
在gtkobject.h中,您可以找到以下声明:
struct _GtkObjectClass
{
GInitiallyUnownedClass parent_class;
/* Non overridable class methods to set and get per class arguments */
void (*set_arg) (GtkObject *object,
GtkArg *arg,
guint arg_id);
void (*get_arg) (GtkObject *object,
GtkArg *arg,
guint arg_id);
/* Default signal handler for the ::destroy signal, which is
* invoked to request that references to the widget be dropped.
* If an object class overrides destroy() in order to perform class
* specific destruction then it must still invoke its superclass'
* implementation of the method after it is finished with its
* own cleanup. (See gtk_widget_real_destroy() for an example of
* how to do this).
*/
void (*destroy) (GtkObject *object);
};
(* set_arg)东西是指向函数的指针,这可以例如在某个派生类中指定另一个实现。
通常你会看到类似这样的东西
struct function_table {
char *name;
void (*some_fun)(int arg1, double arg2);
};
void function1(int arg1, double arg2)....
struct function_table my_table [] = {
{"function1", function1},
...
因此,您可以按名称进入表格并调用“关联”功能。
或许您可以使用哈希表来放置函数并“按名称”调用它。
此致
弗里德里希
答案 5 :(得分:1)
这应该是一个简短的&amp;简单的副本&amp;粘贴上述响应的代码示例。希望这会有所帮助。
#include <iostream>
using namespace std;
#define DBG_PRINT(x) do { std::printf("Line:%-4d" " %15s = %-10d\n", __LINE__, #x, x); } while(0);
void F0(){ printf("Print F%d\n", 0); }
void F1(){ printf("Print F%d\n", 1); }
void F2(){ printf("Print F%d\n", 2); }
void F3(){ printf("Print F%d\n", 3); }
void F4(){ printf("Print F%d\n", 4); }
void (*fArrVoid[N_FUNC])() = {F0, F1, F2, F3, F4};
int Sum(int a, int b){ return(a+b); }
int Sub(int a, int b){ return(a-b); }
int Mul(int a, int b){ return(a*b); }
int Div(int a, int b){ return(a/b); }
int (*fArrArgs[4])(int a, int b) = {Sum, Sub, Mul, Div};
int main(){
for(int i = 0; i < 5; i++) (*fArrVoid[i])();
printf("\n");
DBG_PRINT((*fArrArgs[0])(3,2))
DBG_PRINT((*fArrArgs[1])(3,2))
DBG_PRINT((*fArrArgs[2])(3,2))
DBG_PRINT((*fArrArgs[3])(3,2))
return(0);
}
答案 6 :(得分:1)
可以像这样使用它:
//! Define:
#define F_NUM 3
int (*pFunctions[F_NUM])(void * arg);
//! Initialise:
int someFunction(void * arg) {
int a= *((int*)arg);
return a*a;
}
pFunctions[0]= someFunction;
//! Use:
int someMethod(int idx, void * arg, int * result) {
int done= 0;
if (idx < F_NUM && pFunctions[idx] != NULL) {
*result= pFunctions[idx](arg);
done= 1;
}
return done;
}
int x= 2;
int z= 0;
someMethod(0, (void*)&x, &z);
assert(z == 4);
答案 7 :(得分:1)
这是一个更简单的例子:
jump_table.c
int func1(int arg) { return arg + 1; }
int func2(int arg) { return arg + 2; }
int func3(int arg) { return arg + 3; }
int func4(int arg) { return arg + 4; }
int func5(int arg) { return arg + 5; }
int func6(int arg) { return arg + 6; }
int func7(int arg) { return arg + 7; }
int func8(int arg) { return arg + 8; }
int func9(int arg) { return arg + 9; }
int func10(int arg) { return arg + 10; }
int (*jump_table[10])(int) = { func1, func2, func3, func4, func5,
func6, func7, func8, func9, func10 };
int main(void) {
int index = 2;
int argument = 42;
int result = (*jump_table[index])(argument);
// result is 45
}
存储在数组中的所有函数必须具有相同的签名。这只是意味着它们必须返回相同的类型(例如 int)并具有相同的参数(在上面的示例中为单个 int)。
在 C++ 中,您可以对 静态 类方法(但不是实例方法)执行相同的操作。例如,您可以在上面的数组中使用 MyClass::myStaticMethod,但不能使用 MyClass::myInstanceMethod 或 instance.myInstanceMethod:
class MyClass {
public:
static int myStaticMethod(int foo) { return foo + 17; }
int myInstanceMethod(int bar) { return bar + 17; }
}
MyClass instance;
答案 8 :(得分:0)
已经用很好的例子回答了这个问题。可能缺少的唯一示例是函数返回指针的示例。我用这个写了另一个例子,并添加了很多评论,以防有人发现它有用:
#include <stdio.h>
char * func1(char *a) {
*a = 'b';
return a;
}
char * func2(char *a) {
*a = 'c';
return a;
}
int main() {
char a = 'a';
/* declare array of function pointers
* the function pointer types are char * name(char *)
* A pointer to this type of function would be just
* put * before name, and parenthesis around *name:
* char * (*name)(char *)
* An array of these pointers is the same with [x]
*/
char * (*functions[2])(char *) = {func1, func2};
printf("%c, ", a);
/* the functions return a pointer, so I need to deference pointer
* Thats why the * in front of the parenthesis (in case it confused you)
*/
printf("%c, ", *(*functions[0])(&a));
printf("%c\n", *(*functions[1])(&a));
a = 'a';
/* creating 'name' for a function pointer type
* funcp is equivalent to type char *(*funcname)(char *)
*/
typedef char *(*funcp)(char *);
/* Now the declaration of the array of function pointers
* becomes easier
*/
funcp functions2[2] = {func1, func2};
printf("%c, ", a);
printf("%c, ", *(*functions2[0])(&a));
printf("%c\n", *(*functions2[1])(&a));
return 0;
}
答案 9 :(得分:0)
这个带有函数指针“:
的多维数组的简单例子void one( int a, int b){ printf(" \n[ ONE ] a = %d b = %d",a,b);}
void two( int a, int b){ printf(" \n[ TWO ] a = %d b = %d",a,b);}
void three( int a, int b){ printf("\n [ THREE ] a = %d b = %d",a,b);}
void four( int a, int b){ printf(" \n[ FOUR ] a = %d b = %d",a,b);}
void five( int a, int b){ printf(" \n [ FIVE ] a = %d b = %d",a,b);}
void(*p[2][2])(int,int) ;
int main()
{
int i,j;
printf("multidimensional array with function pointers\n");
p[0][0] = one; p[0][1] = two; p[1][0] = three; p[1][1] = four;
for ( i = 1 ; i >=0; i--)
for ( j = 0 ; j <2; j++)
(*p[i][j])( (i, i*j);
return 0;
}
答案 10 :(得分:0)
最简单的解决方案是给出你想要的最终矢量的地址,并在函数内修改它。
void calculation(double result[] ){ //do the calculation on result
result[0] = 10+5;
result[1] = 10 +6;
.....
}
int main(){
double result[10] = {0}; //this is the vector of the results
calculation(result); //this will modify result
}
答案 11 :(得分:0)
#include <iostream>
using namespace std;
int sum (int , int);
int prod (int , int);
int main()
{
int (*p[2])(int , int ) = {sum,prod};
cout << (*p[0])(2,3) << endl;
cout << (*p[1])(2,3) << endl;
}
int sum (int a , int b)
{
return a+b;
}
int prod (int a, int b)
{
return a*b;
}