(Please Read This Paragraph Before Reading the Post. I am asking anyone interested in reading this post should try to read it carefully, and of course don't downvote it until you understand it completely, thanks.)
It is now community wiki, as such if someone disagrees with any of the concepts, please modify it, with a clear and detailed explanation of what is wrong and why, and if possible please cite sources or provide proof that can be reproduced.
Here are a few other reasons that might be the underlying factors for NULL==0
- The fact that zero is false, so one can do directly
if(!my_ptr) instead of
- The fact that uninitiated global integers are initialized by default to all zeros, and as such a pointer of all zeros would be considered uninitialized.
Here I Would Like to Say A Word On Other Answers
Not Because Of Syntactic Sugar
Saying that NULL is zero because of syntactic sugar, does not make too much sense, if so why not use index 0 of an array to hold it's length?
In fact C is the language that most closely resembles the internal implementation, does it make sense to say that C picked zero just because of syntactic sugar? They would rather provide a keyword null (as many other languages do) rather than mapping zero to NULL!
As such while as of today it might just syntactic sugar, it is clear that the original intention of the C language developers was not for syntactic sugar, as I will show further.
1) The Specification
Yet while it is true that the C specification speak from the constant 0 as the null pointer (section 184.108.40.206), and also define NULL to be implementation defined (section 7.19 in the C11 specification, and 7.17 in the C99 specification), the fact remains that in the book "The C Programming Language" written by the inventors of C the following is stated in section 5.4:
C guarantees that zero is never a valid address for data, so a return value of zero can be used to signal an abnormal event, in this case, no space.
Pointer and integers are not interchangeable, Zero is the sole exception: the constant zero may be assigned to a pointer, and a pointer may be compared with the constant zero. The symbolic constant NULL is often used in place of zero, as a mnemonic to indicate more clearly that this is a special value for a pointer. NULL is defined in . We will use NULL henceforth.
As one can see (from the words "zero address") at least the original intention of the authors of C were of the address zero, and not the constant zero, moreover it appears from this excerpt that the reason why the specification speaks from the constant zero is probably not to exclude an expression that evaluates to zero, but instead to include the integer constant zero to be the only integer constant allowed for use in a pointer context without casting.
While the specification does not say explicitly that a zero address can be treated different than the zero constant, it does not say that not, and the fact the when dealing with the null-pointer constant it does not claim it to be implementation defined as it does by the NULL defined constant, instead claim it to be zero, shows that there might be a difference between the zero constant and the zero address.
(However if this is the case I just wonder why NULL is implementation defined, since in such a case NULL can also be the constant zero, as the compiler anyway has to convert all zero constants into the actual implementation defined NULL?)
However I don not see this in real action, and in the general platforms the address zero and the constant zero are treated the same, and throw the same error message.
Furthermore the fact is that today's operating systems are actually reserving the entire first page (range 0x0000 to 0xFFFF), just to prevent access to the zero address because of C's NULL pointer, (see http://en.wikipedia.org/wiki/Zero_page, as well as "Windows Via C/C++ by Jeffrey Richter and Christophe Nasarre (published by Microsoft Press)").
Thus I would ask from anyone claiming to actually have it seen in action, to please specify the platform, and compiler, and the exact code he actually did, (although due to the vague definition in the specification [as I have shown] any compiler and platform is free to do whatever he wants).
However it apparently seems that the authors of C didn't had this in mind, and they were speaking of the "zero address", and that "C guarantees that it is never a valid address", as well as "NULL is just a mnemonic", clearly showing that it's original intention was not for "syntactic sugar".
Not Because Of The Operating System
Also claiming that the operating system denies access to address zero, for a few reasons:
1) When C was written there was no such restriction, as one can see on this wikipage http://en.wikipedia.org/wiki/Zero_page.
2) The fact is that C compilers did accessed memory address zero.
This appears to be the fact from the following paper by BellLabs (http://www.cs.bell-labs.com/who/dmr/primevalC.html)
The two compilers differ in the details in how they cope with this. In the earlier one, the start is found by naming a function; in the later, the start is simply taken to be 0. This indicates that the first compiler was written before we had a machine with memory mapping, so the origin of the program was not at location 0, whereas by the time of the second, we had a PDP-11 that did provide mapping.
(In fact as of today (as I cited references above from wikipedia and microsoft press), the reason for restricting access to the zero address is because of C's NULL pointers! So at the end it turns out to be the other way around!)
3) Remember that C is also used to write operating systems, and even C compilers!
In fact C was developed for the purpose of writing the UNIX operating system with it, and as such it appears to be no reason why they should restrict themselves from address zero.
(Hardware) Explanation On How Computers Are (Physically) Able To Access Address Zero
There is another point I want to explain here, how is it possible to reference address zero at all?
Think of it for a second, the addresses are fetched by the processor, and then sent as voltages on the memory bus, which is then used by the memory system to get to the actual address, and yet a address of zero will mean no voltage, so how is the physical hardware of the memory system accessing address zero?
The answer appears to be, that address zero is the default, and in other words address zero is always accessible by the memory system when the memory bus is completly off, and as such any request to read or write without specifying an actual address (which is the case with address zero) is automatically accessing address zero.