First things first: The `0x`

prefix indicates that what follows is a hexadecimal (base 16) number. The hexadecimal system extends the set of digits in the decimal system (0 through 9) with a, b, c, d, e and f that stand for the decimal numbers 10, 11, 12, 13, 14 and 15, respectively. The reason that we prefer hexadecimal numbers to decimal ones (at least on a machine whose word length is a multiple of four) is that each hexadecimal digit conveniently corresponds to a group of 4 bits (binary digits). For example:

```
Hexadecimal: 3
Binary: 0 0 1 1
--------------------
Hexadecimal: F
Binary: 1 1 1 1
```

Usually when we speak of machines being "32-bit" or "64-bit", we're talking about the virtual address length - that is, the number of bits that constitute a memory address from the perspective of a user-mode process. (This will usually, but not necessarily, coincide with the word length.)

On an x86-32 machine, such as an old Pentium, the virtual address size is 32 bits. This means that an address can be written using eight hexadecimal digits. For example, `0x80000000`

represents the 2 GiB mark. The fact that the virtual address is 32 bits implies that any given process can only directly refer to 4 GiB of memory (and in practice, the amount of usable memory is even smaller!).

For many applications today, such as large in-memory databases, 4 GiB of virtual memory is too small to hold the data set. This prompted the introduction of 64-bit machines, such as those based on the x86-64 architecture. In theory, a 64-bit machine should be able to address 16 EiB. But, as others have noted, the x86-64 architecture currently limits the virtual address size to 48 bits by requiring them to be in a canonical form.

Incidentally, an address in the lower portion of the canonical address space can be written using 12 hexadecimal digits. As usual, we omit the leading zeros when printing.

It's unlikely that we'll be seeing a complete shift from 32-bit to 64-bit computing anytime soon, if ever. There are still many applications, particularly in embedded systems, where the amount of memory supported by a 64-bit address is simply not required; indeed, 16- and even 8-bit microcontrollers are still very common.

`printf("%p",&a);`

need not print all leading`0`

digits nor does`0x7fffe9ebf984`

imply a consecutive linear memory range 0 to`0x7fffFFFFFFFF`

exists. Curious, what does`printf("%p",NULL);`

?