The location of
int *k is
&k, like so:
// For this example, assume the variables start at 0x00 and are 32 bits each.
int A = 9; // 0x00 = 0x09
int * k = &A; // 0x04 = 0x00
int ** k_2 = &k; // 0x08 = 0x04
cout << "Value of A: " << A; // "Value of A: 9"
cout << "Address of A: " << k; // "Address of A: 0x00"
cout << "Address of k: " << k_2; // "Address of k: 0x04"
assert( A == *k);
assert(&A == k);
assert(&A == *k_2);
assert( A == **k_2);
assert( k == *k_2);
assert(&k == k_2);
A pointer is a variable, 32-bit on 32-bit binaries and 64 in 64, storing a memory address. Like any other variable, it has an address of its own, and the syntax is identical. For most intents and purposes, pointers act like unsigned ints of the same size.
Now, when you take
&k, you now have an
int **, with all the interesting complexities that go with that.
int ** k_2 = &k,
*k, so everything works about how you'd expect.
This can be a useful way to handle creating objects cross-library (pointers are rather fundamental and mostly safe to pass). Double pointers are commonly used in interfaces where you want to pass a pointer that will be filled with an object, but not expose how the object is being created (DirectX, for example).