There are multiple problems:
The conditions in the two
for loops are odd and probably wrong. They are equivalent to:
for (i = 0; i < str1[i]; i++)
for (j = 0; j < str2[j]; j++)
You should probably specify the sizes of the input arrays in the function interface.
- In C, you must make sure you always know the sizes of the arrays.
- You should probably specify the output array in the function interface.
- Since you will need to know how many values were found in common, you'll need to return that number from the function.
- Your choice of the names
str2 is unusual. Not technically wrong, but probably not a good idea. Such names should be reserved for character strings, not arrays of integers.
- Your local array
c is barely used, and is not used safely.
- Your code returns when it finds the first pair of numbers that match, not all possible matches.
- The first two lines of the body of the
if statement elaborately copies the value in
str[i] back to itself via
- The third line of the body of the
if statement copies an uninitialized value from array
c into the variable
- The last line of the body of the
if then returns that uninitialized value.
This adds up to changes such as:
int func1(int *arr1, int num1, int *arr2, int num2, int *arr3)
int k = 0;
for (int i = 0; i < num1; i++)
for (int j = 0; j < num2; j++)
if (arr1[i] == arr2[j])
arr3[k++] = arr1[i];
Note that this code assumes that the size of
arr3 (the array, not the pointer itself) is as big as the product of
num2. If both arrays contain a list of the same value, then there will be one row in the output array,
arr3, for each pair so it could use
num1 * num2 rows. This points out that the code does not deal with suppressing duplicates; if you need that (you likely do), then the body of the
if statement needs to search through the current values in
arr3 to check that the new value is not present. It would be wise to add another parameter,
int siz3, to indicate the size of the third array; if you run out of space for values, you could then return -1 as an error indication.
The coded algorithm is quadratic (or, more accurately, proportional to the product
num1 * num2). If you know the arrays are sorted on entry, you can reduce it to a linear algorithm (proportional to
num1 + num2). With duplicate elimination, it is a little more expensive - it isn't quite as simple as 'cubic'. If you know the input arrays contain unique values (no duplicates), then duplicate elimination is obviously not necessary.