The address of
addr isn't "stored" anywhere explicitly, it just is. If you were to declare a second variable and use it to store that address, then sure it takes space:
int **addr2 = &addr;
You can think of the memory as a series of boxes. Assuming 4-byte
int and pointers, and little-endian byte order, your scenario might look like:
| Address |Data bytes |
The address is shown on the left, the bytes contained at that location on the right. You can see the value
100 stored in the first four bytes (100 decimal is 0x64 in hex). The second 4-byte location holds the value 0x00000000, which is the address of
x. The address 0x00000004 is not stored anywhere.
Now if we add a second pointer, we'd use more memory:
That would be the memory used to represent the
addr2 pointer, and you can see that it contains the address of
addr, i.e. 0x00000004.
addr2 with the expression
*addr2 would yield the value at address 0x00000004, i.e. 0x00000000 with the type
int *. De-referencing that once more yields the
int at that address, i.e. 0x00000064.
Since this memory layout is chosen by the compiler, it "knows" the addresses involved, and can just substitute so that when code references
addr2, it generates instructions that manipulate address 0x00000008, and so on. In real code this would probably all happen on the stack, but the principle is the same.
Final note: do heed @Phil Perry's advice; the above simplifies and makes ocncrete a lot of things that are meant to be somewhat abstract. This is how it really does work on many current-day architectures, but many of the things mentioned are not guaranteed by C so you cannot really depend on them to always hold true. I meant the above as an illustration to (hopefully) make the concepts slighly less vague.