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How do I create a function of a list, such that if any member of the list is negative it is zero, otherwise it follows a recursion relation.

Mathematically this is what I have to do, but I'm not sure how to do it in Mathematica.


Edit: To be completely precise, I am trying to implement the recursion relation on page 6 of this paper (eq 18): http://arxiv.org/PS_cache/nlin/pdf/0003/0003069v1.pdf

However, it's quite complicated and requires a fair amount of reading to understand, so I didn't want to bring it into the question!

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What recursion relation? Could you add it to the question? –  rcollyer Nov 18 '11 at 19:58
There you go. Equation 18 on page 6 of the given paper. –  VolatileStorm Nov 18 '11 at 20:32
I think that's a different proposition than what your question implies, so I'm glad you posted it. Complex, of course; doable, probably. –  rcollyer Nov 18 '11 at 20:36
@Volatile you're right, it is hard to understand what is to be done by looking at eq 18. For instance, there is a sum over vectors mu and theta, constrained such that mu+theta=nu. I assume this means \sum_{\nu_1}\sum_{\nu_2} etc; but what is the range? from 1 to what? and what does nu(i) mean in the subscript to the U in the last sum? the ith component? –  acl Nov 18 '11 at 21:08
I think implementing the recursion relation is another question –  Verbeia Nov 18 '11 at 23:30

3 Answers 3

up vote 3 down vote accepted

Testing if any member of a list satisfies some condition can be done using MemberQ. To test if the list lst contains any element less than zero,

lst = {1, 2, 0, -4};
MemberQ[lst, x_ /; x < 0]

The second argument here is a conditional pattern.

But yes, knowing what it is you want to do would help.

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The conditional patters were what I was looking for, thankyou! –  VolatileStorm Nov 20 '11 at 19:40

Here's another approach:

g[l_List /; Min[g] >= 0] := (* recursion relation *)
g[l_List] := 0
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Strangely, this version is faster than the pattern-matching case in my original answer, but not the version with a conditional. –  Verbeia Nov 18 '11 at 23:29

You can define the function using a conditional test so that if all the elements are non-negative, the recursion relation is used.

 f[l_List] /; And @@ NonNegative[l] := (* recursion relation *)

Then the more general case only applies if not all the elements are non-negative, i.e. some are negative or zero.

 f[l_List] := 0

An even easier method using pattern-matching

 fff[l:{__?NonNegative}]:= (* recursion relation *)

 fff[l_List]:= 0


It turns out that the method I first proposed is the most efficient.

ff[l_list] /; And @@ NonNegative[l] := True

ff[l_List] := 0

Brett's version

gg[l_List] /; Min[l] > 0 := True

gg[l_List] := False

My second proposal

hh[l : {__?NonNegative}] := True

hh[l_List] := False

A variant on my second proposal that focussed on finding the negatives rather than not finding them, if that makese sense.

jj[l : {___, _?Negative, ___}] := False

jj[l_List] := True

There should only be a few negatives in this case

testfg = RandomInteger[{-1, 1000}, 10000];

A case with lots of negatives: some pattern matchers shouldn't need to scan the whole list

testfg1 = RandomInteger[{-1, 4}, 10000];

This one should return True

testfg2 = RandomInteger[{0, 4}, 10000];

Now to test:

ff[testfg] // Timing

{0.000016, 0}

ff[testfg1] // Timing

{0.000015, 0}

ff[testfg2] // Timing

{0.000024, 0}

Brett's version is a little slower, but second-fastest overall

gg[testfg] // Timing

{0.000049, True}

gg[testfg1] // Timing

{0.000049, True}

gg[testfg2] // Timing

{0.00005, True}

hh[testfg] // Timing

{0.000271, False}

hh[testfg1] // Timing

{0.000234, False}

hh[testfg2] // Timing

{0.003809, True}

jj[testfg] // Timing

{0.002482, False}

Sure enough, this version is fast if there are a lot of negative numbers and it doesn't have to check the whole list.

jj[testfg1] // Timing

{0.0005, False}

But it is extremely inefficient if there are no negative numbers because of the expansiveness of the pattern

jj[testfg2] // Timing

{0.678945, True}
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+1 for fff[l:{__?NonNegative}] –  acl Nov 18 '11 at 21:40
@acl I always forget that it is available (and has been since version 1), even though I use ?Positive patterns all the time. I did it the first way because I momentarily forgot NonNegative would work and was trying some compound (0|Positive) pattern using Alternative. But I always have trouble getting those kinds of patterns to work. –  Verbeia Nov 18 '11 at 21:44
Timing results! –  Verbeia Nov 18 '11 at 23:30
@Verbeia on version 7 Brett's method tests about 20X faster than your first with this data: SeedRandom[1]; lst = RandomInteger[{-1, 1*^6}, {3*^6}]; how does it compare on your system? –  Mr.Wizard Feb 7 '12 at 21:31

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