# Comparing CPU Performance - continued

I already posted part c) here

but I am still stuck with parts d and e

(c) A subset of the instructions for a machine M can be accelerated by n times using a coprocessor C. Given that a program P is compiled into instructions of M such that a fraction k belongs to this subset, what is the overall speedup that can be achieved using C with M?

(d) Given that the coprocessor C in part (c) above costs j times as much as M, calcu- late the minimum fraction of instructions for a program that C has to accelerate so that the combined system of M and C is j times faster than M.

If I have `j = 1 / ((1-k)+k/j)` (i.e. `j` times faster) I end up with `j = 1` if I simplify the formula, which is clearly wrong

(e) Given that the performance of M is improving by m times per month, how many months will pass before M alone (without the coprocessor C) can execute the program P in part (c) as fast as the current combined system of M and C?

Is this just `m = (1-k) + k/n`?

Thanks!

-
Mixing "times faster than" vs "times as fast as" in the same problem? Bad teacher! One wonders which "improving by `m` times" actually means. – Ben Voigt Feb 17 '12 at 21:01

For part (c), you used `j` (cost difference) when you meant `n` (coprocessor advantage). It should be:
``````s = 1 / ((1-k) + k/n)
For part (d), you want to set `s = (1 + j)`. So solve `1 + j = 1 / ((1-k) + k/n)` for `k`.
For part (e), you need logarithms. Start with `s = pow(1+m, t)`, set this equal to the speedup formula from (c) (cancelling `j` in the process), and solve for `t`.