Yes, I should not be thinking about optimizing unless I run into performance issues. But the nature of what I'm doing (where most non-trivial programs have very inefficient asymptotic runtimes) means that there will always be something to gain from optimizing. I want to do the best I can to get as many instructions per second as (reasonably) possible.
The solution is clear if I was programming in C++ for instance. Do some timing.
-O3 etc. I would be studying the architectures I expect the code to be run on, and probably also peek at the assembly being generated.
A turing machine is very simple. It is in fact the most simple formulation of computation that exists (!): It has a finite number of states, a bidirectionally infinite tape, a tape head that can move one unit in either direction, and can read and write a single character to the tape.
A program is encoded in a transition function which takes a state and a character that is read, and with that information provides the character to write, the direction to move the head, and the new state.
This is the logic each step:
// states is an array of arrays of triplets and is the transition func var trans = states[state][alph_index[tape[pos]]]; tape[cur_tape_pos] = trans; // write cur_tape_pos += trans; // move state = trans; // state update
Problem is, that would in the naive implementation insert a conditional statement in the inner loop. I'm not liking that. There must already be a conditional check anyway to check if the state is the halting state. So maybe it won't be so bad.
There is also one more potential optimization which could eliminate indexing into
alph_index by storing the index in the alphabet rather than the alphabet value itself on the tape.
Perhaps I am prematurely seeking advice. I will come back and edit with performance numbers as I make progress.
As a reward for reading my question I will provide a link to a live work-in-progress version of my project: http://stevenlu.net/tm.html
Its operation has so far been to manipulate a
div filled with
spans which represents the tape. It also performs a ton of operations on strings and also does a lot of copying around of elements that is entirely unnecessary where the actual computation of the turing machine is concerned. But even so it achieves decent performance. It took about a minute on my machine to calculate 600,000 or so steps (5^4 = 625), which is 10,000 steps per second. Which isn't so bad, but I know I can probably achieve more than a million per second with some lower level programming.
Looking at benchmark perf here for previous-gen CPU's I'm seeing about 10,000 MIPS per core. I estimate therefore that if I can get my inner loop running once in the time it takes to run 50 Dhrystone iterations (which seems very possible with a simple C implementation even though I have no idea what those synthetic benchmarks actually do), barring memory bandwidth limitations, I've got 200 million iterations per second on one thread. My 600k step calculation would be completed in 3ms!!
Well, if I can get my 5^4 computation to run without the browser reporting to me that it's hung up, I'll be pretty happy...
9^4 = 6561, taking 58202209 steps, took 6173 ms to compute. That's 9.4 million steps per second. Almost a 1,000 fold increase from my original DOM dependent method.
5^4 computation (which took about 30 seconds even without scrolling the tape) is now completed in 84 ms.