Is it possible to divide an unsigned integer by 10 by using pure bit shifts, addition, subtraction and maybe multiply? Using a processor with very limited resources and slow divide.

Here's what the Microsoft compiler does when compiling divisions by small integral constants. Assume a 32bit machine (code can be adjusted accordingly):
What's going here is that we're multiplying by a close approximation of 1/10 * 2^32 and then removing the 2^32. This approach can be adapted to different divisors and different bit widths. This works great for the ia32 architecture, since its IMUL instruction will put the 64bit product into edx:eax, and the edx value will be the wanted value. Viz (assuming dividend is passed in eax and quotient returned in eax)
Even on a machine with a slow multiply instruction, this will be faster than a software divide. 


Though the answers given so far match the actual question, they do not match the title. So here's a solution heavily inspired by Hacker's Delight that really uses only bit shifts.
I think that this is the best solution for architectures that lack a multiply instruction. 


Of course you can if you can live with some loss in precision. If you know the value range of your input values you can come up with a bit shift and a multiplication which is exact. Some examples how you can divide by 10, 60, ... like it is described in this blog to format time the fastest way possible.
Yours, Alois Kraus 


Well division is subtraction, so yes. Shift right by 1 (divide by 2). Now subtract 5 from the result, counting the number of times you do the subtraction until the value is less than 5. The result is number of subtractions you did. Oh, and dividing is probably going to be faster. A hybrid strategy of shift right then divide by 5 using the normal division might get you a performance improvement if the logic in the divider doesn't already do this for you. 

