How to avoid for loops when generating index arrays?

1 Ansicht (letzte 30 Tage)
Oliver
Oliver am 30 Apr. 2013
I often find myself coding nested for loops to generate vectors of integer indices. For example:
n = 4;
i = 1;
for L = 0:n
for M = -L:L
l(i) = L;
m(i) = M;
i = i+1;
end
end
All I need are the vectors "l" and "m". I can preallocate to save some speed, but my real problem is having to use the for loops as sometimes the index vectors I need to create have many more nested for loops whose (note that the inner loop index depends on the outer loop index).
Is there a simple way to avoid using loops to generate index vectors like these?

Melden Sie sich an, um diese Frage zu beantworten.

Akzeptierte Antwort

Matt J
Matt J am 30 Apr. 2013
Here's another method, less memory consuming than NDGRID
mm=sparse(-n:n);
ll=sparse(0:n);
map=bsxfun(@le,abs(mm.'),ll);
idx=nonzeros(bsxfun(@times,map,1:length(ll) ));
l=full(ll(idx));
idx=nonzeros(bsxfun(@times,map,(1:length(mm)).')) ;
m=full(mm(idx));

Weitere Antworten (5)

Roger Stafford
Roger Stafford am 30 Apr. 2013
Bearbeitet: Matt J am 30 Apr. 2013
For your particular problem you can do this:
M = (0:n*(n+2))';
L = floor(sqrt(M));
M = M-L.*(L+1);
(I've used uppercase letters, 'L' and 'M', in place of your lowercase 'l' and 'm'.)
As with Matt Kindig, I am not sure this will be any faster than your for-loops. Time it with a large value for n and see.
Matt J
Matt J am 30 Apr. 2013
Bearbeitet: Matt J am 30 Apr. 2013
Here's a way to do it using NDGRID. It's not apriori obvious whether for loops would or would not be faster. It depends what you plan to reuse.
[mg,lg]=ndgrid(-n:n,0:n);
idx=abs(mg)<=lg;
l=lg(idx).',
m=mg(idx).',
  6 Kommentare
4 ältere Kommentare anzeigen
Oliver
Oliver am 1 Mai 2013
The reason that I care is that I have only given you a simplified example. In practice I have things like:
for N = 0:2:30
for L = 0:N
for M = -L:L
for P = 0:M
for Q = -P:P
...
end
end
end
end
end
So making the intermediate arrays in this case would require a 5-dimensional array that takes up a lot of space.
Matt J
Matt J am 1 Mai 2013
Bearbeitet: Matt J am 2 Mai 2013
I'm starting to think Sean's advice about sticking with for-loops is the best one. There can definitely be ways to cut down on the loop nesting (see my newest Answer based on cell arrays), but the required form would depend on the body of the original set of for-loops.

Melden Sie sich an, um zu kommentieren.

Sean de Wolski
Sean de Wolski am 30 Apr. 2013
Bearbeitet: Sean de Wolski am 30 Apr. 2013
doc meshgrid
doc ndgrid %?
:)
And of course, depending on your application, two nested for-loops or bsxfun() might be better.
  2 Kommentare
Oliver
Oliver am 30 Apr. 2013
I can't use ndgrid or meshgrid because the inner loop depends on the outer loop. If i had something like
i = 1;
for L = 3:6
for M = 1:5
l(i) = L;
m(i) = M;
i = i+1;
end
end
then I could use:
[l,m] = meshgrid(3:6,1:5);
But, this won't work with the dependency.
Sean de Wolski
Sean de Wolski am 30 Apr. 2013
Just use the for-loops, they'll be the fastest by far. If you want to disguise it, write a function that takes L and M and returns l and m.
cellfun and arrayfun are slow and converting between cells and numeric types is slow. The above with preallocation will be pretty quick.

Melden Sie sich an, um zu kommentieren.

Matt Kindig
Matt Kindig am 30 Apr. 2013
It's kind of hack-y, but it gives the same output as your original posting:
n=4;
l = cell2mat(arrayfun(@(x) x*ones(1,2*x+1), 0:n, 'uni', false));
m= cell2mat( arrayfun(@(x) (-x:1:x), 0:n, 'uni', false));
Keep in mind that this may very well be slower than for-loops--I haven't done any timing comparisons.
Matt J
Matt J am 1 Mai 2013
Bearbeitet: Matt J am 1 Mai 2013
Here's a way to eliminate one nested loop
l=cell(1,n+1);
m=l;
for L=0:n
i=L+1;
m{i}=-L:L;
l{i}=m{i};
l{i}(:)=L;
end
l=[l{:}],
m=[m{:}],
  2 Kommentare
Sean de Wolski
Sean de Wolski am 1 Mai 2013
I'd be surprised if this is faster due to the cell array conversions. I guess one of us will have to run a timing test.
Matt J
Matt J am 1 Mai 2013
Bearbeitet: Matt J am 2 Mai 2013
For n=1000 I get this,
Original Approach:
Elapsed time is 0.093130 seconds.
Cell-Based Approach
Elapsed time is 0.027393 seconds.
I think the vectorization inherent in
m{i}=-L:L;
l{i}=m{i};
l{i}(:)=L;
trumps the overhead from the cell conversion.

Melden Sie sich an, um zu kommentieren.

Kategorien

Mehr zu Loops and Conditional Statements finden Sie in Help Center und File Exchange

Tags

Produkte

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by