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In a K&R ebook I've been reading I came across this code:


And my concern was in the line:

allocbuf + ALLOCSIZE - allocp >= n

The code takes the address of where the buffer begins and calculates, using the index of the pointer to itself as well as the maximum buffer length constant defined above, the total remaining allocations.

Now, I understand that if you were to define a character pointer, for example, then were to arithmetically increment it by one:

char *ptr = "array";

Then you would get the second position, 'r' above, in memory. The, in memory, actually increments by sizeof(char) units.

So, given that arrays operate under the guise of pointers:

allocbuf + 10000 

Is the final allocated slot in the array, correct? Since the pointer is of type char, 10000 'slots' later is actually 10,000*sizeof(char) slots later.

To clarify this concept in my mind, given a random memory address say 4210720, does 4210721 represent a bit, byte or some other metic past the address?

That is:

void *ptr = "sherrellbc";

Where is ptr now? Is it at some pointer between the 's' and 'h' since type void gives no information regarding step length (as in, a char pointer would increment by sizeof(char)).

In essence, what metric is memory stored using? Bits bytes, nibbles, etc?

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Wait a minute: void *ptr = "..."; does not compile in the first place. ptr++ increases the memory address, whatever it is represented in, by sizeof(*ptr). –  Djee Jul 13 '13 at 20:17
void *ptr = ".."; does compile for me. Incrementing the ptr also does not result in an error insofar as compiling is concerned. I have not done any experiments as to what is happening, however. I am not that concerned with it. –  sherrellbc Jul 14 '13 at 0:12

3 Answers 3

up vote 2 down vote accepted

Memory addresses are byte addresses on every computer you're likely to use, even ones that don't have byte-level memory operations. Some compilers define incrementing a void * as adding one to the pointer, but it's not portable.

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So, adding one byte. What makes the un-portable if many computers are byte addresses? Also, you say that every computer I am likely to use, what kind of computer would I be unlikely to use? I am ignorant to much of this information. –  sherrellbc Jul 13 '13 at 20:11
@sherrellbc Incrementing a void* is disallowed by the language standard because void has no size. For some reason, some compilers treat sizeof(void) as 1 but this fact is really of no interest and is only confusing you. –  Jim Balter Jul 13 '13 at 22:12
@sherrellbc: Jim explained why it's not portable. You're unlikely to use a computer that has, say, 9-bit bytes or nibble addressing. They could exist (they used to exist) and, who knows, one day you might write code for one, but it's not likely. –  David Schwartz Jul 13 '13 at 22:39
@ Jim Balter I am not confused, my true question was with respect to the metric of addressing memory. The rest of the questions seen in this post are merely a result of curiosity. –  sherrellbc Jul 14 '13 at 0:11

Dereferencing an void pointer is undefined in nature. In case the type is defined the increment will always

ptr+1 = next address of ptr type.
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Of course, that is why I did not include the * notation. I was simply incrementing the pointer to the next 'slot.' Or, is arithmetic on void pointers inherently undefined somehow? –  sherrellbc Jul 13 '13 at 20:10
Yes, but if the pointer type is void? –  sherrellbc Jul 13 '13 at 20:13
Thats what I told it will result in undefined behaviour.Once you try to print the value of *ptr in your code the code will not compile. –  pradipta Jul 13 '13 at 20:14
I am telling to print the value of ptr not *ptr. int main() { void *p = "ab"; printf("%d\n",p); p++; printf("%d\n",p); p++; printf("%d\n",p); } you will find the address are printing incremented by one.This point is already told by justin and David Schwartz. –  pradipta Jul 13 '13 at 20:32
I see, I apologize. Thank you for the suggestion. That also is another question I had above about which metrics are used for the 'next' address in memory. It has been answered that the addresses are byte-wise. –  sherrellbc Jul 13 '13 at 20:35

allocbuf + 10000 Is the final allocated slot in the array, correct?

It's one past the end.

To clarify this concept in my mind, given a random memory address say 4210720, does 4210721 represent a bit, byte or some other metic past the address?

A byte (3.6):

"addressable unit of data storage large enough to hold any member of the basic character set of the execution environment.

NOTE 1 It is possible to express the address of each individual byte of an object uniquely."


void *ptr = "sherrellbc"; \n ptr++; - Where is ptr now?

Arithmetic on void* is illegal. Don't use it ;) It's like asking the compiler to take the address held by the variable and adding sizeof(void) to it.

If it must come down to this, use char* instead.

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I figured arithmetic on void pointers was illegal, but I was just using it as illustrative purposes. And thank you for the catch, I now realize that adding the size of the array to the first index would of course be too far. Thanks for the reply. –  sherrellbc Jul 13 '13 at 20:20
@sherrellbc you're welcome. pointer arithmetic (including array accesses) depends on the size and alignment of the type. as i added to the post, just use char* where you would use pointer arithmetic on void*. that is 1. –  justin Jul 13 '13 at 20:26
Could you cast void pointers? For whatever reason. I am not sure of any application of void pointers aside from memory placeholders or something. –  sherrellbc Jul 13 '13 at 20:32
void *ptr = "array, then using (char *) *ptr, perhaps. –  sherrellbc Jul 13 '13 at 20:33
yes. although, the cast from void* to char* is not mandatory in C: void* vp = NULL; \n char* c = vp;. the cast syntax here is: char* c = (char*)vp;. –  justin Jul 13 '13 at 20:38

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