Best algorithm for determining the high and low in an array of numbers?

I am using pseudo-code here, but this is in JavaScript. With the most efficient algorithm possible I am trying to find the high and low given an array of positive whole numbers. This is what I came up with, but I don't think it is probably best, and was just wondering if anyone has any other suggestions.

``````var low = 1;
var high = 1;
for ( loop numbers ) {
if ( number > high ) {
high = number;
}
if ( low == 1 ) {
low = high;
}
if ( number < low ) {
low = number;
}
}
``````
-

initialise the high and low to be the first element. makes a lot more sense than picking an arbitrarily "high" or "low" number.

``````var myArray = [...],
low = myArray[0],
high = myArray[0]
;
// start looping at index 1
for (var i = 1, l = myArray.length; i < l; ++i) {
if (myArray[i] > high) {
high = myArray[i];
} else if (myArray[i] < low) {
low = myArray[i];
}
}
``````

or, avoiding the need to lookup the array multiple times:

``````for (var i = 1, val; (val = myArray[i]) !== undefined; ++i) {
if (val > high) {
high = val;
} else if (val < low) {
low = val;
}
}
``````
-
Initializing using the first element, you no longer care about the limits of your data type. –  Mnebuerquo Oct 20 '08 at 1:53
Initializing using the first element, you assume there is one. (sequence could be empty. –  Anders Eurenius Oct 20 '08 at 12:31
that's ok. In javascript, you'll get low = undefined, and high = undefined. ...makes a lot more sense than negative infinity... –  nickf Oct 20 '08 at 12:42
Since we're going for the "best", why not retrieve each element from the array only once, instead of 2 or 3 times? –  Dave L. Oct 20 '08 at 21:12
And its not a sorting solution. Why sort the who array when you are only interested in two items. This approach is O(n), a generic sort is O(nlogn). –  Sanjaya R Nov 11 '09 at 18:34

You have to do it in `O(n)` time because you need to loop through all (`n`) of the elements to check them because any one of the elements may be the min or max. (Unless they are already sorted.)

In other words you need to loop through all elements and do the max and min check like you have.

Sorting is usually at best `O(n*log(n))`. Thus it is slower than a single sweep through (`O(n)`).

-

Your example is pretty much the most efficient algorithm but obviously it won't work when all the numbers are less than 1 or greater than 1. This code will work in those cases:

``````var low = numbers[0]; // first number in array
var high = numbers[0]; // first number in array
for ( loop numbers ) {
if ( number > high ) {
high = number;
}
if ( number < low ) {
low = number;
}
}
``````
-
there's no way the number can be greater than high AND less than low, so you could combine the two if statements into an if/else. –  nickf Oct 20 '08 at 3:27
the wording could be clarified. he means if all the numbers are <1, or if all the numbers are > 1. in any case, the provided source is good. –  DarenW Jan 17 '09 at 1:25

If the list is small (where "small" is less than a few thousand elements) and you don't do it much (where "much" is less than a few thousand times) it doesn't matter. Profile your code first to find the real bottleneck before you worry about optimizing your max/min algorithms.

Because there is no way to avoid looking at every element of the list, a linear search is the most efficient algorithm. It takes N time, where N is the number of elements in the list. Doing it all in one loop is more efficient than calling max() then min() (which takes 2*N time). So your code is basically correct, though it fails to account for negative numbers. Here it is in Perl.

``````# Initialize max & min
my \$max = \$list[0];
my \$min = \$list[0];
for my \$num (@list) {
\$max = \$num if \$num > \$max;
\$min = \$num if \$num < \$min;
}
``````

Sorting and then grabbing the first and last element is the least efficient. It takes N * log(N) where N is the number of elements in the list.

The most efficient min/max algorithm is one where min/max is recalculated every time an element is added or taken away from the list. In effect, caching the result and avoiding a linear search each time. The time spent on this is then the number of times the list is changed. It takes, at most, M time, where M is the number of changes no matter how many times you call it.

To do that, you might consider a search tree which keeps its elements in order. Getting the min/max in that structure is O(1) or O(log[n]) depending what tree style you use.

-

Although it's still an O(n) algorithm, you can do it 25% faster (that is, the proportionality constant is 3/2 vs 2) by comparing adjacent elements pairwise first, then comparing the smaller to min and the larger to max. I don't know javascript, but here it is in C++:

``````std::pair<int, int> minmax(int* a, int n)
{
int low = std::numeric_limits<int>::max();
int high = std::numeric_limits<int>::min();

for (int i = 0; i < n-1; i += 2) {
if (a[i] < a[i+i]) {
if (a[i] < low) {
low = a[i];
}
if (a[i+1] > high) {
high = a[i+1];
}
}
else {
if (a[i] > high) {
high = a[i];
}
if (a[i+1] < low) {
low = a[i+1];
}
}
}

// Handle last element if we've got an odd array size
if (a[n-1] < low) {
low = a[n-1];
}
if (a[n-1] > high) {
high = a[n-1];
}

return std::make_pair(low, high);
}
``````
-
That's assuming that the extra code complexity (due to the extra branches) doesn't slow things down. Oh, and O(3n/2) == O(2n) == O(n) -- you have to use something other than big-O notation to measure a constant factor difference. –  TimB Oct 20 '08 at 4:19
Agreed that O(3n/2) == O(n), I was just pointing out that the constant factor is actually smaller than it is with the "obvious" implementation. This is the textbook CLR algorithm for simultaneous min/max, and is actually faster for really large n. Normally it makes no difference, however... :) –  Drew Hall Oct 20 '08 at 4:34
BTW, note that by doing pairwise comparison first, you do 3 branches for every two elements, vs. 2 for each one (i.e. 4 for each 2) as you do with the simple version. It looks like it branches more, but it doesn't because the stride is greater. –  Drew Hall Oct 20 '08 at 4:37
"Agreed that O(3n/2) == O(n), I was just pointing out...", if you agree, and you should, you really should edit your answer. –  Brian R. Bondy Dec 31 '09 at 18:46
@Brian: Edited per your suggestion. Hadn't thought about this answer in a long time, but I'm sorry to see that the "naive" answer (compare each element to min & max) was the accepted one. –  Drew Hall Jan 2 '10 at 9:38
``````var numbers = [1,2,5,9,16,4,6];

var maxNumber = Math.max.apply(null, numbers);
var minNumber = Math.min.apply(null, numbers);
``````
-
In fact this is not an algorithm, it's just a way to find min/max value in an array. It may be the most efficient way or not - depends on the actual Math.min()/Math.max() algorithm implemented by given JavaScript engine vendor. In Spidermonkey: mxr.mozilla.org/mozilla/source/js/src/jsmath.c –  pawel Oct 21 '08 at 12:12
This is brilliant. I wasn't aware those methods took n parameters. Well done. –  fearphage Nov 12 '09 at 5:27

nickf's algorithm is not the best way to do this. In the worst case, nickf's algorithm does 2 compares per number, for a total of 2n - 2.

We can do a fair bit better. When you compare two elements a and b, if a > b we know that a is not the min, and b is not the maximum. This way we use all of the available information to eliminate as many elements as we can. For simplicity, suppose we have an even number of elements.

Break them into pairs: (a1, a2), (a3, a4), etc.

Compare them, breaking them into a set of winners and losers - this takes n/2 compares, giving us two sets of size n/2. Now find the max of the winners, and the min of the losers.

From above, finding the min or the max of n elements takes n-1 compares. Thus the runtime is: n/2 (for the initial compares) + n/2 - 1 (max of the winners) + n/2 - 1 (min of the losers) = n/2 + n/2 + n/2 -2 = 3n/2 - 2. If n is odd, we have one more element in each of the sets, so the runtime will be 3n/2

In fact, we can prove that this is the fastest that this problem can be possibly be solved by any algorithm.

An example:

Suppose our array is 1, 5, 2, 3, 1, 8, 4 Divide into pairs: (1,5), (2,3) (1,8),(4,-). Compare. The winners are: (5, 3, 8, 4). The losers are (1, 2, 1, 4).

Scanning the winners gives 8. Scanning the losers gives 1.

-

Trying these snippets out for real on V8, Drew Hall's algorithm runs in 2/3 of the time of nickf's, as predicted. Making the loop count down instead of up cuts it to about 59% of the time (though that's more implementation-dependent). Only lightly tested:

``````var A = [ /* 100,000 random integers */];

function minmax() {
var low = A[A.length-1];
var high = A[A.length-1];
var i, x, y;
for (i = A.length - 3; 0 <= i; i -= 2) {
y = A[i+1];
x = A[i];
if (x < y) {
if (x < low) {
low = x;
}
if (high < y) {
high = y;
}
} else {
if (y < low) {
low = y;
}
if (high < x) {
high = x;
}
}
}
if (i === -1) {
x = A[0];
if (high < x) {
high = x;
} else if (x < low) {
low = x;
}
}
return [low, high];
}

for (var i = 0; i < 1000; ++i) { minmax(); }
``````

But man, it's pretty ugly.

-

Javascript arrays have a native sort function that accepts a function to use for the comparison. You can sort the numbers and just take the head and the tail to get the minimum and maximum.

``````var sorted = arrayOfNumbers.sort(function(a, b) { return a - b; }),
,min = sorted[0], max = sorted[sorted.length -1];
``````

By default, the sort method sorts lexicographically (dictionary order) so that's why you have to pass in a function for it to use to get numerical sorting. The function you pass in needs to return 1, -1, or 0 to determine the sort order.

``````// standard sort function
function sorter(a, b) {
if (/* some check */)
return -1; // a should be left of b
if (/*some other check*/)
return 1; // a should be to the right of b
return 0; // a is equal to b (no movement)
}
``````

In the case of numbers, you can merely subtract the second from the first param to determine the order.

``````var numbers = [5,8,123,1,7,77,3.14,-5];

// default lexicographical sort
numbers.sort() // -5,1,123,3.14,5,7,77,8

// numerical sort
numbers.sort(function(a, b) { return a - b; }) // -5,1,123,3.14,5,7,77,8
``````
-
+1: you seem to be the only one to treat this the right way (a sorting problem). –  KooiInc May 7 '09 at 5:48
@KooiInc Sorting the array does more work than is necessary. Sorting requires O(log n) comparisons while finding the largest and smallest numbers requires O(n) comparisons. –  Amuck Nov 11 '09 at 18:33

The only further optimization I would suggest is optimizing the loop itself. It's faster to count down than to count up in JavaScript.

-
That is a very surprising thing to learn... On some search this is confirmed by peachpit.com/articles/article.aspx?p=31567&seqNum=6 too... Why does this occur and does this carry over to any other languages? –  sundar Oct 20 '08 at 4:42
On second thoughts, I think I can guess the reason. In a count-up loop, we have to fetch the upper bound and compare with the iterator index, (mov reg1,value; cmp reg2,reg1; jne addr;) while in a count-down loop we can use an internal instruction for comparing with zero (jnz reg2, addr). Is this it? –  sundar Oct 20 '08 at 5:05
that's it as far as I know –  Gene Oct 20 '08 at 9:50
if you're concerned about the direction of your loop, maybe Javascript isn't the language for you...? –  nickf Oct 20 '08 at 12:45
Micro-optimizations like this are implementation specific and can even change between versions. –  Schwern Oct 20 '08 at 23:54

Assuming the list isn't already sorted, that's about the best you can do. You can save yourself a comparison by doing the following (in pseudocode):

``````low = +INFINITY
high = -INFINITY
for each n in numbers:
if n < low:
low = n
if n > high:
high = n
``````

This is an O(n) operation, which is basically the best you can do.

-
That's another way of doing it. But that hardly makes this algorithm wrong, since a "wrong" algorithm would either (a) return a wrong answer, or (b) have a higher complexity. –  mipadi Nov 11 '09 at 18:53
Yeah, you are right. My fault. I thought that the algorithm would return the wrong answer because I misunderstood your if conditions. Sorry. –  Daniel Rodriguez Nov 11 '09 at 21:07

this algorithm works for O(n) and no more extra memory needed to store elements...

``````enter code here
int l=0,h=1,index,i=3;
if(a[l]>a[h])
swap(&a[l],&a[h]);
for(i=2;i<9;i++)
{
if(a[i]<a[l])
{
swap(&a[i],&a[l]);
}
if(a[i]>a[h])
{
swap(&a[i],&a[h]);
}
}
printf("Low:  %d  High:  %d",a[0],a[1]);
``````
-

In python:

``````>>> seq = [1, 2, 3, 4, 5, 6, 7]
>>> max(seq)
7
>>> min(seq)
1
``````
-
His language is javascript –  jjnguy Oct 20 '08 at 1:48
well, it's not that he was interested in JS, it's that he was looking for an algorithm. This really isn't that useful an answer. –  nickf Oct 20 '08 at 1:50
You will notice that my answer is completely facetious. Collections.sort is not the answer to "Best sorting algorithm?" even if we're talking Java. –  Aaron Maenpaa Oct 20 '08 at 1:52
No, the answer to "best sorting algorithm?" is the ORDER BY clause in SQL. –  MusiGenesis Oct 20 '08 at 2:07
@MusiGenesis mad props –  Aaron Maenpaa Oct 20 '08 at 2:08