# how to use erlang lists:map function

The following is a erlang function. I don't understand how lists:map function is used here. Could someone please explain?

``````% perform M runs with N calls to F in each run.
% For each of the M runs, determine the average time per call.
% Return, the average and standard deviation of these M results.

time_it(F, N, M) ->
G = fun() -> F(), ok end,
NN = lists:seq(1, N),
MM = lists:seq(1, M),
T = lists:map(
fun(_) ->
T0 = now(),				% start timer
[ G() || _ <- NN ], 			% make N calls to F
1.0e-6*timer:now_diff(now(), T0)/N	% average time per call
end,
MM
),
{ avg(T), std(T) }.
``````

Thanks.

also, I don't know the proper syntax when using this function. For example, I have a dummy() function take 1 parameter. I get an error while trying to time the dummy function.

``````moduleName:time_it(moduleName:dummy/1, 10, 100).
``````

the above would evaluate to illegal expression.

Actually, now with the correct syntax, the function can be invoked correctly with:

``````moduleName:time_it(fun moduleName:dummy/1, 10, 100).
``````

However, it will throw a exception saying invoking dummy function without passing any parameter. I think this line is the villain, `[ G() || _ <- NN ],` I have no idea how to fix it.

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What's the reason for `G = fun() -> F(), ok end` instead of directly calling `F()` NN times? – Zed Oct 11 '09 at 5:54
My initial guess was that this was a mistaken optimization to "throw away" the output of F() in case by accumulating it in the list comprehension it slowed things down. So I tried it and it does make a difference! If your F outputs something like a list of 255 integers, then running it enough times is slower inside a list comprehension than calling G(). Perhaps this is due to the overhead of building up the list. Using lists:foreach is a better solution - this is much faster than the list comprehension, and no need to nest the function. – Rob Charlton Oct 26 '09 at 18:54

`map` is used here to execute the function

``````T0 = now(),                           % start timer
[ G() || _ <- NN ],                   % make N calls to F
1.0e-6*timer:now_diff(now(), T0)/N    % average time per call
``````

for each element of `MM`. `map` will return a new list of the same size, where each element of the new list is the result of applying the above function to the corresponding element of `MM`.

You can invoke `time_it` like:

``````moduleName:time_it(fun moduleName:dummy/1, 10, 100).
``````
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If you have a function moduleName:dummy/1 you can do one of the following

1. If you can edit `time_it/3`, then make it call `F(constant_parameter)` instead of `F()`. I assume this is the case.
2. Otherwise, call `M1:time_it(fun() -> M2:dummy(constant_parameter) end, N, M)`. dummy will not be called directly, but only by F inside time_it.
-

The purpose of lists:map in the time_it function is just to run the inner function M times. When you see this pattern:

``````L = lists:seq(1,M),
lists:map(fun(_)-> Foo() end, L)
``````

It just means call Foo() again and again M times, and return the results of each call in a list. It actually makes a list of integers [1,2,3,...N] and then calls Foo() once for each member of the list. The author of time_it does this same trick again, because time_it needs to call the function you give it N*M times. So inside the outer loop that runs M times they use a different technique to run the inner loop N times:

``````L = lists:seq(1,N),
[Foo() || _ <- L]
``````

This has exactly the same result as the code above, but this time Foo is called N times.

The reason you are having trouble using time_it with your dummy function is that time_it takes a function with 0 parameters, not 1. So you need to make a dummy function and call it like this:

``````dummy() ->
%% do something here you want to measure
ok.

measure_dummy() ->
time_it(fun someModule:dummy/0, 10, 100).
``````
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``````results(N, F) when N >= 0 -> results(N, F, []).
results(0, _, Acc) -> lists:reverse(Acc);
results(N, F, Acc) -> results(N-1, F, [F() | Acc]).

repeat(0, F) -> ok;
repeat(N, F) when N > 0 ->
F(),
repeat(N-1, F).
``````

With these:

``````T = results(M, fun () ->
T0 = now(),
repeat(N, G),
1.0e-6 * timer:now_diff(now(), T0)/N
end)
``````

Make sense, now?

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