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I was reading a bit in Pointer Arithmetic, and I came upon 2 things I couldn't understand neither know it's use

address_expression - address_expression

and also

address_expression > address_expression

Can someone please explain them to me, how do they work and when they are used.

Edit:

What I meant to say is what do they produce if I just take two addresses and subtract them

And If I take two addresses and compare them what is the result or comparing based upon

Edit: I now understand the result of subtracting addresses, but comparing addresses I still don't get it.

I understand that 1<2, but how is an address greater than another one and what are they compared upon

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6 Answers

up vote 10 down vote accepted

Pointer substraction yields the number of array elements between two pointers of the same type.

For example,

int buf[10] = /* initializer here */;

&buf[10] - &buf[0];  // yields 10, the difference is 10 elements

Pointer comparison. For example, for the > relational operator: the > operation yields 1 if the pointed array element or structure member on the left hand side is after the pointed array element or structure member on the right hand side and it yields 0 otherwise. Remember arrays and structures are ordered sequences.

 &buf[10] > &buf[0];  // 1, &buf[10] element is after &buf[0] element
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Thank You. Although Other answers offered a lot more detail and explained to me a lot of things I didn't know. This is the most straight forward answer, answering my main question –  Mohamed Ahmed Nabil Jul 30 '12 at 0:23
    
@MohamedAhmedNabil You are welcome! –  ouah Jul 30 '12 at 0:24
    
- and > only work for pointers into the same array. It is undefined behavior to use them on anything else. –  FredOverflow Jul 30 '12 at 5:06
    
@FredOverflow Or one past the last element of the array (like in my two examples) and for the relational operators you can also use the operators for the same structure or union object. –  ouah Jul 30 '12 at 9:35
    
Interesting, I just verified the struct rule, and the standard indeed guarantees it. Is this a C++11 extension? Anyway, +1 from me. –  FredOverflow Jul 30 '12 at 11:50
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Several answers here have stated that pointers are numbers. This is not an accurate description of pointers as specified by the C standard.

In large part, you can think of pointers as numbers, and as addresses in memory, provided (a) you understand that pointer subtraction converts the difference from bytes to elements (of the type of the pointers being subtracted), and (b) you understand the limits where this model breaks.

The following uses the 1999 C standard (ISO/IEC 9899, Second edition, 1999-12-01). I expect the following is more detailed than the asker requested, but, given some of the misstatements here, I judge that precise and accurate information should be given.

Per 6.5.6 paragraph 9, you may subtract two pointers that point to elements of the same array or to one past the last element of the array. So, if you have int a[8], b[4];, you may subtract a pointer to a[5] from a pointer to a[2], because a[5] and a[2] are elements in the same array. You may also subtract a pointer to a[5] from a pointer to a[8], because a[8] is one past the last element of the array. (a[8] is not in the array; a[7] is the last element.) You may not subtract a pointer to a[5] from a pointer to b[2], because a[5] is not in the same array as b[2]. Or, more accurately, if you do such a subtraction, the behavior is undefined. Note that it is not merely the result that is unspecified; you cannot expect that you will get some possibly nonsensical number as a result: The behavior is undefined. According to the C standard, this means that the C standard does not say anything about what occurs as a consequence. Your program could give you a reasonable answer, or it could abort, or it could delete files, and all those consequences would be in conformance to the C standard.

If you do an allowed subtraction, then the result is the number of elements from the second pointed-to element to the first pointed-to element. Thus, a[5]-a[2] is 3, and a[2]-a[5] is -3. This is true regardless of what type a is. The C implementation is required to convert the distance from bytes (or whatever units it uses) into elements of the appropriate type. If a is an array of double of eight bytes each, then a[5]-a[2] is 3, for 3 elements. If a is an array of char of one byte each, then a[5]-a[2] is 3, for 3 elements.

Why would pointers ever not be just numbers? On some computers, especially older computers, addressing memory was more complicated. Early computers had small address spaces. When the manufacturers wanted to make bigger addresses spaces, they also wanted to maintain some compatibility with old software. They also had to implement various schemes for addressing memory, due to hardware limitations, and those schemes may have involved moving data between memory and disk or changing special registers in the processor that controlled how addresses were converted to physical memory locations. For pointers to work on machines like that, they have to contain more information than just a simple address. Because of this, the C standard does not just define pointers as addresses and let you do arithmetic with them. Only a reasonable amount of arithmetic is defined, and the C implementation is required to provide the necessary operations to make that arithmetic work, but no more.

Even on modern machines, there can be complications. On Digital’s Alpha processors, a pointer to a function does not contain the address of the function. It is the address of a descriptor of the function. That descriptor contains the address of the function, and it contains some additional information that is necessary to call the function correctly.

With regard to relational operators, such as >, the C standard says, in 6.5.8 paragraph 5, that you may compare the same pointers you may subtract, as described above, and you may also compare pointers to members of an aggregate object (a struct or union). Pointers to members of an array (or its end address) compare in the expected way: Pointers to higher-indexed elements are greater than pointers to lower-indexed elements. Pointers to two members of the same union compare equal. For pointers to two members of a struct, the pointer to the member declared later is greater than the pointer to the member declared earlier.

As long as you stay within the constraints above, then you can think of pointers as numbers which are memory addresses.

Usually, it is easy for a C implementation to provide the behavior required by the C standard. Even if a computer has a compound pointer scheme, such as a base address and offset, usually all elements of an array will use the same base address as each other, and all elements of a struct will use the same base address as each other. So the compiler can simply subtract or compare the offset parts of the pointer to get the desired difference or comparison.

However, if you subtract pointers to different arrays on such a computer, you can get strange results. It is possible for the bit pattern formed by a base address and offset to appear greater (when interpreted as a single integer) than another pointer even though it points to a lower address in memory. This is one reason you must stay within the rules set by the C standard.

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Subtracting two pointer addresses returns the number of elements of that type.

So if you have an array of integers and two pointers into it, subtracting those pointers will return the number of int values between, not the number of bytes. Same with char types. So you need to be careful with this, especially if you are working with a byte buffer or wide characters, that your expression is calculating the right value. If you need byte-based buffer offsets for something that does not use a single byte for storage (int, short, etc) you need to cast your pointers to char* first.

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Minor detail: with char types, subtracting always counts bytes because char is defined to be one byte by the C standard. –  Dietrich Epp Jul 30 '12 at 0:07
1  
Additionally, it is important to note that the result of p1 - p2 and p1 < p2 is undefined if the two pointers do not refer to subobjects inside the same superobject (elements inside the same array). –  David Rodríguez - dribeas Jul 30 '12 at 0:19
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Memory addresses are just numbers, so they can be compared and manipulated in the same way as integral data types.

The first expression subtracts one pointer from another. As a simple example of why this might be useful, consider a C string. The string is in contiguous memory, so if you had the address of the first character of the string, and the address of the last character, you could find the length of the string by doing:

int strLength = (last_char_address - first_char_address) + 1;

Such pointer arithmetic is type aware, meaning that the result of the arithmetic represents the number of elements - of the specific type - between two pointers. In the above example using char, the difference is the number of characters. This works similarly for e.g. pointers to two structs.

Similarly, your second expression is simply comparing pointers and the result will be 1 or 0. As a very simple example, the address of element 5 of an array is always > the address of element 4: &string[4] > &string[5] is true.

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What I meant to say is what do they produce if I just take two addresses and subtract them And If I take two addresses and compare them what is the result or comparing based upon –  Mohamed Ahmed Nabil Jul 29 '12 at 23:57
    
the subtraction produces a number. in my example the number means the distance between the address, or number of memory addresses between. The comparison is true or false based on the arguments –  pb2q Jul 29 '12 at 23:58
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Two things: strLength has an off-by-one error, and it would be nice to explain the difference between C pointer arithmetic and the equivalent arithmetic in assembly -- i.e., subtracting two int * pointers will give you a different result than if you cast them to char * first. –  Dietrich Epp Jul 30 '12 at 0:06
2  
Pointers are not necessarily simple memory addresses. The C standard allows room for more complicated forms of addressing that some platforms use. Furthermore, pointer subtraction in C does not merely subtract one address from another. It also divides the address difference by the size of the pointed-to objects. More accurately, the result of the subtraction operator in C, applied to pointers to two objects in the same array (or an end address for the array) is the number of elements from one object to the next. –  Eric Postpischil Jul 30 '12 at 0:08
2  
@MohamedAhmedNabil: If you compare pointers to two objects within an array (or an end address for the array, that is, the address of an element one beyond the last element actually in the array), then the pointer to the greater-indexed element in the array is greater than the pointer to the lesser-indexed element in the array. If you compare pointers to two members within a struct object, then the pointer to the later element is greater than the pointer to the earlier element. If you compare pointers to things other than the above, then the behavior is undefined. –  Eric Postpischil Jul 30 '12 at 0:10
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Pointers can often be thought of as just numbers that represents the memory address, like 0x0A31FCF20 (or 2736770848 in decimal), or 0xCAFEDEAD (sometimes systems use this to indicate an error, I don't remember the details.)

Pointer comparison is often used in sorting arrays of pointers. Sorted arrays of pointers are helpful when you need to check if a pointer is in a list of pointers; if the list is sorted, you don't have to look through every element of the list to figure out if the pointer is in that list. You need to use comparisons to sort a list.

Pointer arithmetic is often used when you have a pointer to a chunk of data, and you need to access something that is not at the beginning of the chunk of data. For example:

const char *string = "hello world!"
const char *substring = string+6;
std::cout << string << "\n";
std::cout << substring << std::endl;

This would output:

hello world!
world!

Here we got the string after the first 6 characters of "hello world!", or "world!". Keep in mind that you should use std::string where its available, instead, if possible. A concept very similar to pointer arithmetic is random access iterators.

Subtracting pointers can help you find the distance between those two pointers. If you have a pointer to the first element of an array, and a pointer to one element past the last element of the array, subtracting these two pointers helps you find the size of the array.

Another case where you might treat pointers as integers is in an optimized version of a linked list, called an XOR linked list. You can find more details about it here. I can expand on this if you'd like; let me know in the comments.

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Pointers are not just numbers. On some platforms, pointers are base addresses and offsets, and different combinations of base addresses and offsets can point to the same location. –  Eric Postpischil Jul 30 '12 at 0:16
    
I was editing this after you commented on the above post. Does that help at all? –  vedosity Jul 30 '12 at 0:23
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You can treat an address like an int in many ways. The only difference is that that int is representing the number of sizes in that address. For example, if we have int * p = 234;, it represents the address 234. If we do p += 1;, it's just adding, but in terms of 4. Now p is 238. You can compare and such just like an int.

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