I need to multiply an integer ranging from 01023 by 1023 and divide the result by a number ranging from 11023 in hardware (verilog/fpga implementation). The multiplication is straight forward since I can probably get away with just shifting 10 bits (and if needed I'll subtract an extra 1023). The division is a little interesting though. Area/power arent't really critical to me (I'm in an FPGA so the resources are already there). Latency (within reason) isn't a big deal so long as I can pipeline the deisgn. There are obviously several choices with different trade offs, but I'm wondering if there's an "obvious" or "no brainer" algorithm for a situation like this. Given the limited range of operands and the abundance of resources that I have (bram etc) I'm wondering if there isn't something obvious to do.

If you can work with fixed point precision rather than integers it may be possible to change :
to multiplication by a number ranging from 1  1/1023, ie precompute the divide and store that as the coefficient for the multiply. 


If you can precompute everything, and you've got a spare 20x20 multiplier, and some way to store your precomputed number, then go for Morgan's suggestion. You need to precompute a 20bit multiplicand (10b quotient, 10b remainder), and multiply by your first 10b number, and take the bottom 30b of the 40b result. Otherwise, the nobrainer is nonrestoring division, since you say that latency isn't important (lots of stuff on the web, most of it incomprehensible). you have a 20bit numerator (the result of your (1023 x) multiplication), and a 10bit denominator. This gives a 20b quotient, and a 10b remainder (ie. 20 bits for the integer part of the answer, and 10 bits for the fractional part, giving a 30b answer). The actual hardware is pretty trivial: an 11b adder/subtractor, a 31b shift register, and a 10b or 11b register to store the divisor. You also need a small FSM to control it (2b). You have to do a compare, add or subtract, and shift in every clock cycle, and you get the answer out in 21 cycles. I think. :) 

