Remember that this
for (i = 0; i < sizeof(my_buffer); i++)
p[i] = 0;
can also be faster than
for (i = 0; i < sizeof(my_buffer); i++)
*p++ = 0;
As already answered, the compiler often has hand optimized routines for memset() memcpy() and other string functions. And we are talking significantly faster. now the amount of code, number of instructions, that a fast memcpy or memset from the compiler, is usually much larger than the loop solution you suggested. fewer lines of code, fewer instructions does not mean faster.
Anyway, my message is try both. diassemble the code, see the difference, try to understand, ask questions at stack overflow if you dont. and then use a timer and time the two solutions, call whichever memcpy function thousands or hundreds of thousands of times and time the whole thing (to elminate error in the timing). Make sure you do short copies like say 7 items or 5 items, and large copies like hundreds of bytes per memset and try some prime numbers while you are at it. On some processors on some systems, your loop can be faster for a few items like 3 or 5 or something like that, very quickly though it gets slow.
Here is one hint about performance. The DDR memory in your computer is likely 64 bits wide and needs to be written 64 bits at a time, maybe it has ecc and you have to compute across those bits and write 72 bits at a time. Not always that exact number but follow the thought here it will make sense for 32 bits or 64 or 128 or whatever. If you perform a single byte write instruction to ram, the hardware is going to need to do one of two things, if there are no caches along the way, the memory system has to perform a 64 bit read, modify the one byte, then write it back. Without some sort of hardware optimization, writing 8 bytes within that one dram row, is 16 memory cycles, and dram is very very slow, dont be fooled by the 1333mhz numbers.
Now if you have a cache, the first byte write is going to require a cache line read from dram, which is one or multiple of these 64 bit reads, the next 7 or 15 or whatever byte writes are probably going to be really fast as they only go to the cache and not to ddr, eventually that cache line goes out to dram, slow, so one or two or four, etc of these 64 bit or whatever ddr locations. So even though you are only doing writes you still have to read all of that ram then write it, so twice as many cycles as desired. If possible, and it is with some processors and memory systems, the memset or the write part of a memcpy, can be single instructions with a whole cache line or whole ddr location and there is no read required, instantly doubled speed. This is not how all the optimizations work but it hopefully gives you an idea of how to think about the problem. With your program being pulled into cache in cache lines, you can double or triple the number of instructions executed if in return you half or quarter or more cutbacks on the number of DDR cycles and you win overall.
At a minimum the compiler memset and memcpy routines are going to perform a byte operation if the start address is odd then a 16 bit if not aligned on 32 bits. Then a 32 bit if not aligned on 64 and on up until they hit the optimal transfer size for that instruction set/system. On arm they tend to aim for 128 bits. So worst case on the front end would be a single byte then single halfword then a few words, then get into the main set or copy loop. In the case of ARM 128 bit transfers, 128 bits written per instruction. Then on the back end if unaligned the same deal, a few words, one half word, one byte worst case. You will also see the libraries do things like, if number of bytes is less than X where X is a small number like 13 or so, then it goes into a loop like yours, just copy some bytes because the number of instructions and clock cycles to support that loop is smaller/faster. disassemble or find the gcc source code for ARM and probably mips and some other good processors and see what I am talking about.