# How to do logical tests for all list elements in mathematica

I have a list and I want to apply a logical test to each element, and if any one of them does not satisfy this condition, then return false. I want to write this in Mathematica or find a built-in function, but seems ForAll does not actually do that.

My question is: how to do this most efficiently?

Bonus: how about similarly for Exists function: i.e. if there is any element in the list satisfy the condition, return true.

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Would you perhaps be looking for And and/or Or? (I like the way that sounds. But it might look better as (&&)^2 (||)^2 ) ForAll and Exists really are not meant for this although they can be adapted. Example: Resolve[ForAll[x, x == 1 || x == 2 || x == 3, x > 2.5]] will return False. – Daniel Lichtblau Dec 14 '11 at 22:44
This question has been asked before here, in fact more than once. See here: stackoverflow.com/questions/4181470/…, and here: stackoverflow.com/questions/4911827/… – Leonid Shifrin Dec 15 '11 at 9:11

The answer to the first portion of your question might be something along these lines:

forAll[list_, cond_] := Select[list, ! cond@# &, 1] === {};

which is used like this:

forAll[{1, 2, 3, 3.5}, IntegerQ]

The "exists" function is already natively implemented as MemberQ. It could be reimplemented as:

exists[list_,cond_] := Select[list, cond, 1] =!= {};

Use it like

exists[Range@100, (10 == # &)]

which returns true as 10 is an element causing the Select to return {10} which is not equal to {}.

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Damn. I was about to post an answer when I realized it was the same exact thing you posted. – Mike Bailey Dec 14 '11 at 22:43
This is a really fast accept, perhaps you should uncheck my answer for a bit and see if others manage to do any better :). Plus I've only really answered the second part of your question, though with a bit of (correct) tweaking you can answer the first part of the question as well. – nixeagle Dec 14 '11 at 22:49
Yeah which is why I removed it once I realized it was not answering the question properly. And using Length after collecting up the full list of elements is not really efficient at all. – nixeagle Dec 14 '11 at 22:51
Length should be O(1) for lists in Mathematica, IIRC. It is inefficient in use of memory though, since you're creating the list then getting it's length. Most functional solutions in Mathematica seem to suffer from memory issues. – Mike Bailey Dec 14 '11 at 22:53
@MikeBantegui Right, I've edited this to do something a little less wasteful of memory :) – nixeagle Dec 14 '11 at 22:57

This answer is not intended to show the most efficient method, but rather an alternative method that serves the pedagogical purpose of showing some important core functionality in Mathematica.

nixeagle's answer avoids explicitly testing every element of the list. If the test doesn't lend itself to inclusion in the third argument of Select, then the below might be useful.

To do this, you need to learn about the standard Or and And functions, as well as the Map (/@) and Apply (@@) commands which are extremely important for any Mathematica user to learn. (see this tutorial)

Here is a simple example.

In[2]:= data = RandomInteger[{0, 10}, {10}]

Out[2]= {10, 1, 0, 10, 1, 5, 2, 2, 4, 1}

In[4]:= # > 5 & /@ data

Out[4]= {True, False, False, True, False, False, False, False, False, \
False}

In[6]:= And @@ (# > 5 & /@ data)

Out[6]= False

What is going on here is that you are mapping the function ("greater than 5") to each element of the list using Map, to get a list of True/False values. You are then applying the standard logical function And to the whole list to get the single Boolean value.

These are all very much core functionality in Mathematica and I recommend you read the documentation for these functions carefully and practice using them.

This is not the most efficient method, but for small problems you will not notice the difference.

In[11]:= Do[Select[data, ! # > 5 &, 1] === {}, {10000}] // Timing

Out[11]= {0.031, Null}

In[12]:= Do[And @@ (# > 5 & /@ data);, {10000}] // Timing

Out[12]= {0.11, Null}

For Exists, the alternative to Select would be MatchQ for patterns or MemberQ for explicit values. The documentation has some useful examples.

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+1 for showing an alternate way to do this :). – nixeagle Dec 15 '11 at 0:09
This is not good. All elements are tested even if the first one fails. – Mr.Wizard Dec 15 '11 at 9:28
@Mr.Wizard This problem has been addressed in full in the previous incarnations of this question (which is a duplicate. A pity I only saw it now) - here: stackoverflow.com/questions/4181470/…, and here: stackoverflow.com/questions/4911827/… – Leonid Shifrin Dec 15 '11 at 9:35
@Leonid vote to close? – Mr.Wizard Dec 15 '11 at 9:49
@Mr.Wizard I had forgotten that. I will amend my answer to make it clear that I am not purporting to demonstrate the most efficient approach. – Verbeia Dec 15 '11 at 11:23

Not to be taken too seriously, but this

ClearAll[existsC];
existsC[cond_] := With[
{c = cond},
Compile[
{{l, _Integer, 1}},
Module[
{flag = False, len = Length@l},
Do[
If[cond[l[[i]]],
flag = True; Break[];
];,
{i, 1, len}];
flag
],
CompilationTarget -> "C"
]
]

appears to be around 300 times faster than nixeagle's solutions on my machine. What this does is to emit a compiled function which takes a list and compares its elements to the given condition (fixed at compile-time), returning True if any of them matches.

It is used as follows: Compile with the appropriate cond, eg

t = existsC[# == 99999 &];

and then

t[Range@100000] // timeIt

returns 2.33376*10^-6 (a worst-case scenario, as I am just searching linearly and the matching element is at the end) while

exists[Range@100000, (99999 == # &)] // timeIt

returns 0.000237162 (here, timeIt is this).

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+1 for showing a really cool way to make use of Compile and making me think of (defmacro ...) in Common Lisp! This is probably my first interesting encounter with what some folks call Mathematica "meta" programming. And yes I'd love to know why "WVM" is faster. Finally not to dampen the pure awesomeness of this answer... but I strongly suspect that this is only valid for numbers, not symbols or anything else Compile won't work with (though I wish it did work with more stuff!). – nixeagle Dec 15 '11 at 0:03
@nixeagle thanks! you're right, it won't work with lists of objects not supported by Compile, or with inhomogeneous lists etc. – acl Dec 15 '11 at 0:20
+1. You don't need the outer With - the rules (parameter-passing) have (almost) the same semantics and can also be used to inject stuff. As for the timings, on my machine C-compiled code is much faster than WVM - compiled (as we would expect), which contradicts your observation. – Leonid Shifrin Dec 15 '11 at 9:08
By the way, here is a shorter version of your code: existsC[cond_] := Compile[{{l, _Integer, 1}}, Do[If[cond[el], Return[True]], {el, l}] == True, CompilationTarget -> "C"]. It might also be a tiny bit faster. – Leonid Shifrin Dec 15 '11 at 9:44
@Leonid thanks. Using Null==True to return False is clever, even if it forces me to have to think when I read the code. – acl Dec 15 '11 at 11:04

A pattern based approach:

forAll[list_, test_] := MatchQ[ list, _[__?test] ]

Mathematica 10 has a new function for this: AllTrue. When all elements pass the test my function appears to be a bit faster:

a = Range[2, 1*^7, 2];

AllTrue[a, EvenQ] // Timing // First
forAll[a, EvenQ]  // Timing // First
1.014007

0.936006

However with an early exit the benefit of the new function becomes apparent:

a[[123456]] = 1;

AllTrue[a, EvenQ] // Timing // First
forAll[a, EvenQ]  // Timing // First
0.031200

0.265202
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Even though && and || perform short-circuit evaluation, i.e., don't evaluate their arguments unnecessarily, I suspect that solutions based on Select[] or Map[] won't benefit much from this. That's because they apply the logical test to every element, building a list of Boolean truth-values before performing the conjunction/disjunction among them. If the test you've specified is slow, it can be a real bottleneck.

So here is a variant that does short-circuit evaluation of the condition as well:

allSatisfy[list_, cond_] :=
Catch[Fold[If[cond[#2], True, Throw[False]] &, True, list]]

Testing if any element in the list satisfies the condition is nicely symmetric:

anySatisfy[list_, cond_] :=
Catch[Fold[If[cond[#2], Throw[True], False] &, False, list]]

Of course this could equally have been done (and candidly speaking, more easily) using procedural loops such as While[], but I have a soft spot for functional programming!

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I would use tagged exceptions which are safer. For an implementation which uses that but otherwise is similar to your suggestion, see the second part of my answer here: stackoverflow.com/questions/4911827/… – Leonid Shifrin Dec 15 '11 at 9:13
The third argument of Select allows it to "short-circuit" the test after the first match. – Mr.Wizard Dec 15 '11 at 9:48
@Mr.Wizard That's a good point. – Leonid Shifrin Dec 15 '11 at 10:08

nixeagle got the bonus part, but the way I would've done the first part is as follows:

AllSatisfy[expr_, cond_] := Length@Select[expr, cond] == Length@expr
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There's a simple solution:

In[1401]:= a = {1, 2, 3}

Out[1401]= {1, 2, 3}

Out[1398]= {0, 1, 0}

Out[1400]= {1, 1, 0}

Out[1402]= {1, 0, 1}

Success!

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