I am trying to figure out how many clock cycles or total instructions it takes to access a pointer in C. I dont think I know how to figure out for example, p->x = d->a + f->b

i would assume two loads per pointer, just guessing that there would be a load for the pointer, and a load for the value. So in this operations, the pointer resolution would be a much larger factor than the actual addition, as far as trying to speed this code up, right?

This may depend on the compiler and architecture implemented, but am I on the right track?

I have seen some code where each value used in say, 3 additions, came from a

 f2->sum = p1->p2->p3->x + p1->p2->p3->a + p1->p2->p3->m

type of structure, and I am trying to define how bad this is

  • depends on address mode imho - near jump/long jump, address computation... – Gabriel Ščerbák Apr 30 '10 at 20:40
  • remember the compiler should move a lot of this to the stack after fetching it once. If it isn't, and you don't need to worry about multithreading, you can cache the pointer chases yourself. – Robert Fraser Apr 30 '10 at 20:44
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    @Robert: if multithreading is going to affect the pointer dereferencing in the example, then the code needs explicit serialization - an optimizing compiler will always be able to cache p3 into a register and use it for all 3 member accesses (assuming there's no volatile members being used). – Michael Burr Apr 30 '10 at 20:59
  • @Michael Burr - Yup; that's what I meant. +1 for the explanation. – Robert Fraser May 1 '10 at 0:11

This depends on the architecture at hand.

Some architectures can reference/dereference memory for an instruction without first loading it into a register, others don't. Some architectures don't have the notion of instructions that compute the offsets for you to dereference and will make you load the memory address, add your offset to it, and then allow you to dereference the memory location. I'm sure there are more variances chip-to-chip.

Once you get past these, each instruction takes varying amount of time depending on the architecture as well. To be honest though, it's an overhead that is very, very minimal.

For your immediate question of dereferencing a chain of items, the slowness will come in the fact that there is likely a poor locality of reference the farther you go in a dereferencing chain. This means more cache misses, which means more hits to main memory (or disk!) to get the data. Main memory is very slow compared to the CPU.

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    I dont think it is minimal. In optimizing code like the above, I have seen 3 - 8x speedups getting rid of the pointers and using normal array access. The problem is even worse if the pointers are actually structures. – Derek Apr 30 '10 at 20:45
  • @derek Well first of all, it's only a potentially bad overhead if the code is constantly executed, in which case, unless you are trashing the cache, continous memory lookups should be cached in the DTLB (in the case of x86). It's still nice to use registers when possible, which is what the compiler does. The example in my answer shows that there can be pointer access even when assigning local variables to each other. – L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Apr 30 '10 at 20:55
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    @Derek: That'll be from improving the cache locality. – Donal Fellows Apr 30 '10 at 20:55
  • @derek I don't buy it. On an even playing field, it's literally another instruction or two and are in fact usually very similar. Usually, you'll load the starting spot of the array (or the value of the pointer), and from there on you're simply computing offsets with something like an index register. This happens for both pointers and arrays through pointers. If you're talking about a linked-list or tree, then that's a locality problem. – San Jacinto Apr 30 '10 at 20:57
  • @San Jacinto I wrote a very simple program with 2 three structures. When compiled with no optimizations on the MIPS compiler -S option. The assembler for p.something->nextthing->value was calculated as three loads, every time it was accessed. The compiler did not store nextthing and just access the values from there. – Derek May 3 '10 at 15:26

Some IDEs like VisualStudio allow you to view the assembly generated along with the source code.

How to view the assembly behind the code using Visual C++?

Then you can see for your exact architecture and implementation what it looks like.

If you are using GDB (linux, mac) use disassemble

(gdb) disas 0x32c4 0x32e4
Dump of assembler code from 0x32c4 to 0x32e4:
0x32c4 <main+204>:      addil 0,dp
0x32c8 <main+208>:      ldw 0x22c(sr0,r1),r26
0x32cc <main+212>:      ldil 0x3000,r31
0x32d0 <main+216>:      ble 0x3f8(sr4,r31)
0x32d4 <main+220>:      ldo 0(r31),rp
0x32d8 <main+224>:      addil -0x800,dp
0x32dc <main+228>:      ldo 0x588(r1),r26
0x32e0 <main+232>:      ldil 0x3000,r31
End of assembler dump.
  • I compiled iwth the -S option, and I found something very similar to what others have talked about. – Derek May 3 '10 at 15:23

Depends what you are doing, a trivial pointer dereference y = *z; where

int x = 1;
int* z = &x;
int y;

might assemble to something like this on the x86:

mov eax, [z]
mov eax, [eax]
mov [y], eax

and y = x would still take a memory dereference:

mov eax, [x]
mov [y], eax

Mov instructions to memory take about 2-4 cycles IIRC.

Although, if you are loading memory from completely random locations, you will be causing a lot of page faults, resulting in hundreds of clock cycles being wasted.


Where it can, the compiler will remove that overhead for you by keeping repeatedly-used base locations in a register (eg. p1->p2->p3 in your example).

However, sometimes the compiler can't determine which pointers might alias other pointers used within your function - which means that it has to fall back to a very conservative position, and reload values from pointers frequently.

This is where C99's restrict keyword can help. It lets you inform the compiler when certain pointers are never aliased by other pointers in the scope of the function, which consquently can improve the optimisation.

For example, take this function:

struct xyz {
    int val1;
    int val2;
    int val3;

struct abc {
    struct xyz *p2;

int foo(struct abc *p1)
    int sum;

    sum = p1->p2->val1 + p1->p2->val2 + p1->p2->val3;

    return sum;

Under gcc 4.3.2 with optimisation level -O1, it compiles to this x86 code:

    pushl   %ebp
    movl    %esp, %ebp
    movl    8(%ebp), %eax
    movl    (%eax), %edx
    movl    4(%edx), %eax
    addl    (%edx), %eax
    addl    8(%edx), %eax
    popl    %ebp

As you can see, it only deferences p1 once - it keeps the value of p1->p2 in the %edx register and uses it three times to fetch the three values from that structure.

  • I actually wrote a test program, compiled with the -S option, and I found that even for a simple case such as p1.p2->p3->value or some such thing, it reloaded from p1 every time. Very conservative with no optimizations – Derek May 3 '10 at 15:22
  • @Derek: What optimisation level did you use? With -O1 or higher, it should optimise the simple cases quite well (see the example I've added to my answer). – caf May 4 '10 at 0:03
  • Yes, it will, but it loses some of that ability the more complex a program gets.This is kind of my point – Derek May 10 '10 at 18:52

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