Let's take a little closer look at `memcpy`

and, while we're at it, at "big O" or Landau notation.

First, big-O. As i've talked about elsewhere, it's worth remembering the definition of big O, which is that some function *g(n)* is said to be *O(f(n))* when there exists a constant *k* for which *g(n)* ≤ *kf(n)*. What the constant does is lets you ignore the little details in favor of the important part. As everyone has noted, `memcpy`

of *n* bytes will be *O(n)* in most any normal architecture, because no matter what you have to move those *n* bytes, one chunk at a time. So, a first, naive implementation of `memcpy`

in C could be written

```
unsigned char *
memcpy(unsigned char * s1, unsigned char * s2, long size){
long ix;
for(ix=0; ix < size; ix++)
s1[ix] = s2[ix];
return s1;
}
```

This is in fact *O(n)*, and might make you wonder why we even bother with a library routine. however, the thing about the *libc* functions is that they are the place where platform-specific utilities get written; if you want to optimize for the architecture, this is one of the places you can do it. So, *depending on the architecture*, there may be a more efficient implementation options; for example, in the IBM 360 archiecture, there is a `MOVL`

instruction that moves data is big chunks using very highly optimized microcode. So in place of that loop, a 360 implementation of memcpy might instead look something like

```
LR 3,S1 LOAD S1 ADDR in Register 3
LR 4,S2
MOVL 3,4,SIZE
```

(No guarantees that's exactly right 360 code by the way, but it'll serve for an illustration.) This implementation *looks* like instead of doing *n* steps around the loop as the C code did, it just executes 3 instructions.

What *really* happens, though, is that it's executing *O(n) micro* instructions under the covers. What's *different* between the two is the constant *k*; because the microcode is much faster, and because there's only three decode steps on the instructions, it is *dramatically* faster than the naive version, but it's still *O(n)* -- it's just the constant is smaller.

And that's why you can make good use of `memcpy`

-- it's not asymptotically faster, but the implementation is as fast as someone could make it *on that particular architecture*.