# What's the most efficient way to test if two ranges overlap?

Given two inclusive ranges [x1:x2] and [y1:y2], where `x1 ≤ x2` and `y1 ≤ y2`, what is the most efficient way to test whether there is any overlap of the two ranges?

A simple implementation is as follows:

``````bool testOverlap(int x1, int x2, int y1, int y2) {
return (x1 >= y1 && x1 <= y2) ||
(x2 >= y1 && x2 <= y2) ||
(y1 >= x1 && y1 <= x2) ||
(y2 >= x1 && y2 <= x2);
}
``````

But I expect there are more efficient ways to compute this.

What method would be the most efficient in terms of fewest operations?

What does it mean for the ranges to overlap? It means there exists some number C which is in both ranges, i.e.

``````x_start <= C <= x_end
``````

and

``````y_start <= C <= y_end
``````

To avoid confusion, considering the ranges are: `[x_start:x_end]` and `[y_start:y_end]`

Now, if we are allowed to assume that the ranges are well-formed (so that `x_start <= x_end` and `y_start <= y_end`) then it is sufficient to test

``````x_start <= y_end && y_start <= x_end
``````
• I believe it should be `x1 <= y2 && y1 >= x2`, no? Mar 27, 2013 at 22:40
• @DavidBeck: no, if y1 > x2 then the ranges definitely don't overlap (e.g. consider [1:2] and [3:4]: y1 = 3 and x2 = 2, so y1 > x2, but there's no overlap). Mar 28, 2013 at 9:14
• this would be a better answer if you explained the reasoning a bit more Mar 3, 2018 at 23:13
• @Vineet Deoraj - Why do you think it doesn't work? x1 = 1, y1 = 1, x2 = 1, y2 = 1, so x1 <= y2 && y1 <= x2 is true, thus, there is an overlap.
– dcp
Jun 19, 2018 at 13:34
• Explanation is here: stackoverflow.com/questions/325933/…
– Alex
Sep 5, 2018 at 19:16

Given two ranges [x1,x2], [y1,y2]

``````def is_overlapping(x1,x2,y1,y2):
return max(x1,y1) <= min(x2,y2)
``````
• @uyuyuy99 - only not so efficient, because when this check is being done many times per second, calling function is something you would like to avoid, and do as much math yourself, keep it to the basic Mar 30, 2016 at 14:02
• @vsync Modern browsers will inline & optimize functions like Math.max, there should be no noticeable impact on performance. Sep 15, 2016 at 1:35
• @AshtonWar - interesting. do you have an article explaining what gets inlined and what's not? Sep 15, 2016 at 8:07
• @vsync No, but I'm sure you can find the information yourself Sep 15, 2016 at 12:02
• In addition, note that `min(x2,y2) - max(x1,y1)` provides the amount of overlap in case you need that. Nov 7, 2018 at 13:14

This can easily warp a normal human brain, so I've found a visual approach to be easier to understand:

## le Explanation

If two ranges are "too fat" to fit in a slot that is exactly the sum of the width of both, then they overlap.

For ranges `[a1, a2]` and `[b1, b2]` this would be:

``````/**
* we are testing for:
*     max point - min point < w1 + w2
**/
if max(a2, b2) - min(a1, b1) < (a2 - a1) + (b2 - b1) {
// too fat -- they overlap!
}
``````
• There are more cases than depicted in your pictures. E.g., what if w2 starts before w1 and ends after w1? Aug 19, 2014 at 3:34
• @WilliamKF the logic stands true Sep 27, 2015 at 11:41
• Agreed, but I think it might help to provide a third picture. Sep 27, 2015 at 20:17
• @WilliamKF then you need a lot of more images there are 16 different combinations that 2 ranges can be placed in... Jan 21, 2016 at 15:13
• Be careful if you use this method, because the sum `a2 - a1 + b2 - b1` can overflow. To fix it, rearrange the formula to `max(a2, b2) - a2 - b2 < min(a1, b1) - a1 - b1`, which simplifies to `max(a1, b1) < min(a2, b2)`, saving some arithmetic and avoiding any possible overflows (this is AXE-Labs's answer below). In the special case where you know `b2-b1=a2-a1`, another useful rearrangement of FloatingRock's formula is `max(a2, b2) - min(a1, b1) - (b2 - b1) < a2-a1`, which becomes `abs(b1-a1) < a2 - a1`. Mar 1, 2018 at 12:23

Great answer from Simon, but for me it was easier to think about reverse case.

When do 2 ranges not overlap? They don't overlap when one of them starts after the other one ends:

``````dont_overlap = x2 < y1 || x1 > y2
``````

Now it easy to express when they do overlap:

``````overlap = !dont_overlap = !(x2 < y1 || x1 > y2) = (x2 >= y1 && x1 <= y2)
``````
• To me, easier to understand expression is : x2 < y1 || y2 < x1 // where I use 'less than' instead of "greater than". Oct 21, 2019 at 0:08

Subtracting the Minimum of the ends of the ranges from the Maximum of the beginning seems to do the trick. If the result is less than or equal to zero, we have an overlap.

Equation:

``````max(x1, x2) - min(y1, y2) <= 0

means ranges overlap
``````

This visualizes it well:

• This covers all cases Dec 24, 2016 at 11:00
• after wasting my time and life on other answers, this was the ONLY correct answer that covers all cases May 17 at 20:29
``````return x2 >= y1 && x1 <= y2;
``````

Why this works:
The only time the ranges DON'T overlap is when the end of one range is before the beginning of the other. So we want `!(x2 < y1 || x1 > y2)` which is equivalent to the above.

• this is not correct. Because `x1 <= y1 && x2 >= y2 || x1 >= y1 && x2 <= y2` should also return true. May 23, 2020 at 14:14
• @RahatZaman: It works in those cases as well. Try it out with some actual numbers. Dec 15, 2022 at 20:24
• Check for (x1 -> 10, x2 -> 40) (y1 -> 20, y2 -> 30) x2 >= y1 && x1 <= y2 = (40 >= 20) && (10 <= 30) = (true) && (true) = true But they clearly overlap. Jun 7, 2023 at 23:39
• @PRASANNASARAF Yes, `true` means they overlap. Jun 8, 2023 at 0:44

I suppose the question was about the fastest, not the shortest code. The fastest version have to avoid branches, so we can write something like this:

for simple case:

``````static inline bool check_ov1(int x1, int x2, int y1, int y2){
// insetead of x1 < y2 && y1 < x2
return (bool)(((unsigned int)((y1-x2)&(x1-y2))) >> (sizeof(int)*8-1));
};
``````

or, for this case:

``````static inline bool check_ov2(int x1, int x2, int y1, int y2){
// insetead of x1 <= y2 && y1 <= x2
return (bool)((((unsigned int)((x2-y1)|(y2-x1))) >> (sizeof(int)*8-1))^1);
};
``````
• Have faith in your compiler. The expression `x1 <= y2 && y1 <= x2` doesn't have any branches in it either, assuming a reasonably competent compiler and CPU architecture (even in 2010). In fact, on x86, the generated code is basically identical for the simple expression vs. the code in this answer. Nov 13, 2017 at 11:40

If you were dealing with, given two ranges `[x1:x2]` and `[y1:y2]`, natural / anti-natural order ranges at the same time where:

• natural order: `x1 <= x2 && y1 <= y2` or
• anti-natural order: `x1 >= x2 && y1 >= y2`

then you may want to use this to check:

they are overlapped <=> `(y2 - x1) * (x2 - y1) >= 0`

where only four operations are involved:

• two subtractions
• one multiplication
• one comparison

Given: `[x1,x2]` `[y1,y2]` then `x1 <= y2 || x2 >= y1` would work always. as

``````      x1 ... x2
y1 .... y2
``````

if `x1 > y2` then they do not overlap or

``````x1 ... x2
y1 ... y2
``````

if `x2 < y1` they do not overlap.

• this should be an AND, not an OR. Jul 3, 2022 at 0:47

If someone is looking for a one-liner which calculates the actual overlap:

``````int overlap = ( x2 > y1 || y2 < x1 ) ? 0 : (y2 >= y1 && x2 <= y1 ? y1 : y2) - ( x2 <= x1 && y2 >= x1 ? x1 : x2) + 1; //max 11 operations
``````

If you want a couple fewer operations, but a couple more variables:

``````bool b1 = x2 <= y1;
bool b2 = y2 >= x1;
int overlap = ( !b1 || !b2 ) ? 0 : (y2 >= y1 && b1 ? y1 : y2) - ( x2 <= x1 && b2 ? x1 : x2) + 1; // max 9 operations
``````

Think in the inverse way: how to make the 2 ranges not overlap? Given `[x1, x2]`, then `[y1, y2]` should be outside `[x1, x2]`, i.e., `y1 < y2 < x1 or x2 < y1 < y2` which is equivalent to `y2 < x1 or x2 < y1`.

Therefore, the condition to make the 2 ranges overlap: `not(y2 < x1 or x2 < y1)`, which is equivalent to `y2 >= x1 and x2 >= y1` (same with the accepted answer by Simon).

• Looks the same as what @damluar answered (Mar 2 '16 at 17:36) May 19, 2020 at 0:39

You have the most efficient representation already - it's the bare minimum that needs to be checked unless you know for sure that x1 < x2 etc, then use the solutions others have provided.

You should probably note that some compilers will actually optimise this for you - by returning as soon as any of those 4 expressions return true. If one returns true, so will the end result - so the other checks can just be skipped.

• All compilers will. All (to my knowledge) currently-used languages with C-style syntax (C, C++, C#, Java, etc.) employ short-circuited boolean operators and it is part of the various standards that govern those languages. If the result of the lefthand value is sufficient to determine the result of the operation, the righthand value is not evaluated. Jul 16, 2010 at 23:46
• Mark H -- the compiler will skip over the second clause if it can: so if you have a function that says: foo(int c) { int i=0; if (c < 3 || ++i == argc) printf("Inside\n"); printf("i is %d\n", i); Foo(2) will print: Inside i is 0 and Foo(4) will print: i is 1 (tested on gcc 4.4.3, but I've relied on this behavior for some ugly code in icc as well) Jul 17, 2010 at 0:02

``````def overlap(event_1, event_2):

start_time_1 = event_1[0]
end_time_1 = event_1[1]

start_time_2 = event_2[0]
end_time_2 = event_2[1]

start_late = max(start_time_1, start_time_2)
end_early = min(end_time_1, end_time_2)

# The event that starts late should only be after the event ending early.
if start_late > end_early:
print("Absoloutly No overlap!")
else:
print("Events do overlap!")
``````

I believe the min(upper(A),upper(B))>=max(lower(A),lower(B)) will be a great solution not only for its simplicity but also for its extendability beyond two ranges.

– Community Bot
Feb 3, 2023 at 16:14

I was recently tackling this question and made my own conclusion. Hope you'll find this helpful. I covered all possible test cases templates (I think) and when you switch the ranges. This is assuming that x1 <= y1 and x2 <= y2.

/ means it doesn't overlap and * otherwise

a b c d

0 2 3 5 / -> r1 & r2 do not touch and overlap

3 5 0 2 /

0 2 2 4 / -> r1 & r2 touch but do not overlap

2 4 0 2 /

0 3 2 4 * -> r1 & r2 overlap but each extends out

2 4 0 3 *

0 4 2 4 * -> r1 & r2 overlap but r1 extends out

2 4 0 4 *

0 2 0 4 * -> r1 & r2 overlap but r2 extends out

0 4 0 2 *

0 4 1 3 * -> r2 is inside r1

1 3 0 4 *

0 0 0 0 / -> r1 & r2 are same and empty

The formula is `( a < c ) ? ( b <= c ) : ( a >= d )`. If true then the ranges do not overlap.

Got confused about this problem as I thought that overlapping condition needs to have or operator, not and. So I decided to work through it to build some intuition. Hope someone will find it useful.

# Interval overlapping

## 1. A completely before B

Intuition: If interval A ends before B starts, they do not overlap.

``````A: |---|
B:      |---|
``````

Overlap? No, because A_end < B_start.

## 2. A starts before B and overlaps

Intuition: If A starts before B and ends after B starts, there is an overlap.

``````A: |-------|
B:    |-------|
``````

Overlap? Yes, because A_start < B_end and B_start < A_end.

## 3. A completely within B

Intuition: If A starts after B starts and ends before B ends, A is completely within B, thus they overlap.

``````A:   |---|
B: |-------|
``````

Overlap? Yes, since A is within B, clearly A_start < B_end and B_start < A_end.

## 4. A completely after B

Intuition: If A starts after B ends, they do not overlap.

``````A:       |---|
B: |---|
``````

Overlap? No, because B_end < A_start.

Overlap Determination From these cases, the main point for determining if two intervals overlap is to check if one interval starts before the other ends and vice versa. The formula, A_start < B_end and B_start < A_end, effectively covers the scenarios (cases 2 and 3) where the overlap occurs. Cases 1 and 4 show situations where the formula's conditions would not be met, indicating no overlap.

# Intervals are not overlapping

## 1. A Ends Before B Starts

Intuition: If the end point of interval A is before the start point of interval B, then there is a clear gap between A and B, ensuring no overlap.

``````A: |---|  B:      |---|
``````

Overlap? No, because the entire interval A occurs before B begins. This means A_end < B_start in terms of their positions.

## 2. A Starts After B Ends

Intuition: If A starts after B has already ended, then A occurs entirely outside of B's range, resulting in no overlap.

``````B: |---|  A:      |---|
``````

Overlap? No, because A does not begin until after B has concluded. This is expressed as A_start > B_end.

## Determining Non-overlap

To generalize, intervals do not overlap if one starts after the other ends. These conditions can be stated as either A_end < B_start or A_start > B_end. If either condition is true, there is no overlap between the intervals.

# Finding overlap value between intervals

To compare intervals for overlap using the min and max functions, we use these functions to find the latest start time and the earliest end time of the intervals. Intuition: The intervals overlap if the latest start time is earlier than the earliest end time. In formula terms, this is expressed as:

``````max(A_start, B_start) < min(A_end, B_end)  # note max on start, min on end
``````

This condition ensures there is a shared range between the intervals by confirming that the start of the overlapping segment (determined by the max of the start times) happens before the end of this segment (determined by the min of the end times).

## 1. Overlapping Intervals

``````Interval A: |----|
Interval B:   |----|
Overlap:      |--|
``````

Intervals: A = [1, 4], B = [3, 6] Overlap Check: max(1, 3) < min(4, 6) simplifies to 3 < 4. The intervals overlap.

## 2. Non-Overlapping Intervals

``````Interval A: |---|
Interval B:      |---|
Overlap:     (none)
``````

Intervals: A = [1, 3], B = [4, 6] Overlap Check: max(1, 4) < min(3, 6) simplifies to 4 < 3, which is false. Hence, the intervals do not overlap.

# Summary

It is easier to get intuition for non-overlapping intervals because there are only 2 clearly defined cases, and go from there.

``````is_overlapping = A_start <= B_end and B_start <= A_end  # note and, comparision inclusive (if overlapping is inclusive)
is_non_overlapping = A_end < B_start or A_start > B_end  # note or, comparision exclusive

def intervals_overlap(A_start, A_end, B_start, B_end):
return max(A_start, B_start) <= min(A_end, B_end) # assuming overlapping inclusive

def intervals_overlap_and_size(A_start, A_end, B_start, B_end):
overlap_size = min(A_end, B_end) - max(A_start, B_start)
if overlap_size >= 0: # assuming overlapping inclusive
return True, overlap_size  # Overlap exists with calculated size
else:
return False, 0  # No overlap
``````

My case is different. i want check two time ranges overlap. there should not be a unit time overlap. here is Go implementation.

``````    func CheckRange(as, ae, bs, be int) bool {
return (as >= be) != (ae > bs)
}
``````

Test cases

``````if CheckRange(2, 8, 2, 4) != true {
t.Error("Expected 2,8,2,4 to equal TRUE")
}

if CheckRange(2, 8, 2, 4) != true {
t.Error("Expected 2,8,2,4 to equal TRUE")
}

if CheckRange(2, 8, 6, 9) != true {
t.Error("Expected 2,8,6,9 to equal TRUE")
}

if CheckRange(2, 8, 8, 9) != false {
t.Error("Expected 2,8,8,9 to equal FALSE")
}

if CheckRange(2, 8, 4, 6) != true {
t.Error("Expected 2,8,4,6 to equal TRUE")
}

if CheckRange(2, 8, 1, 9) != true {
t.Error("Expected 2,8,1,9 to equal TRUE")
}

if CheckRange(4, 8, 1, 3) != false {
t.Error("Expected 4,8,1,3 to equal FALSE")
}

if CheckRange(4, 8, 1, 4) != false {
t.Error("Expected 4,8,1,4 to equal FALSE")
}

if CheckRange(2, 5, 6, 9) != false {
t.Error("Expected 2,5,6,9 to equal FALSE")
}

if CheckRange(2, 5, 5, 9) != false {
t.Error("Expected 2,5,5,9 to equal FALSE")
}
``````

you can see there is XOR pattern in boundary comparison

Overlap (X, Y) := if (X1 <= Y1) then (Y1 <= X2) else (X1 <= Y2).

PROOF:

Consider the case when X precedes, or is left aligned with, Y, i.e., X1 <= Y1. Then either Y starts inside, or at the end of, X, i.e. Y1 <= X2; or else Y is away from X. The first condition is overlap; the second, not.

In the complementary case when Y precedes X, the same logic applies to the swapped entities.

So,

Overlap (X, Y) := if (X1 <= Y1) then (Y1 <= X2) else Overlap (Y, X).

But this does not seem quite right. On the recursive call, the first test is redundant, as we already know the relative position of the entities from the first test on the first call. So, we really only need to test for the second condition, which, upon swapping, is (X1 <= Y2). So,

Overlap (X, Y) := if (X1 <= Y1) then (Y1 <= X2) else (X1 <= Y2).

QED.

``````   type Range_T is array (1 .. 2) of Integer;

function Overlap (X, Y: Range_T) return Boolean is
(if X(1) <= Y(1) then Y(1) <= X(2) else X(1) <= Y(2));
``````

Test program:

``````with Ada.Text_IO; use Ada.Text_IO;

procedure Main is

type Range_T is array (1 .. 2) of Integer;

function Overlap (X, Y: Range_T) return Boolean is
(if X(1) <= Y(1) then Y(1) <= X(2) else X(1) <= Y(2));

function Img (X: Range_T) return String is
(" [" & X(1)'Img & X(2)'Img & " ] ");

procedure Test (X, Y: Range_T; Expect: Boolean) is
B: Boolean := Overlap (X, Y);
begin
Put_Line
(Img (X) & " and " & Img (Y) &
(if B then " overlap .......... "
else " do not overlap ... ") &
(if B = Expect then "PASS" else "FAIL"));
end;

begin
Test ( (1, 2), (2, 3), True);  --  chained
Test ( (2, 3), (1, 2), True);

Test ( (4, 9), (5, 7), True);  --  inside
Test ( (5, 7), (4, 9), True);

Test ( (1, 5), (3, 7), True);  --  proper overlap
Test ( (3, 7), (1, 5), True);

Test ( (1, 2), (3, 4), False);  -- back to back
Test ( (3, 4), (1, 2), False);

Test ( (1, 2), (5, 7), False);  -- disjoint
Test ( (5, 7), (1, 2), False);
end;
``````

Output of above program:

`````` [ 1 2 ]  and  [ 2 3 ]  overlap .......... PASS
[ 2 3 ]  and  [ 1 2 ]  overlap .......... PASS
[ 4 9 ]  and  [ 5 7 ]  overlap .......... PASS
[ 5 7 ]  and  [ 4 9 ]  overlap .......... PASS
[ 1 5 ]  and  [ 3 7 ]  overlap .......... PASS
[ 3 7 ]  and  [ 1 5 ]  overlap .......... PASS
[ 1 2 ]  and  [ 3 4 ]  do not overlap ... PASS
[ 3 4 ]  and  [ 1 2 ]  do not overlap ... PASS
[ 1 2 ]  and  [ 5 7 ]  do not overlap ... PASS
[ 5 7 ]  and  [ 1 2 ]  do not overlap ... PASS
``````

Here's my version:

``````int xmin = min(x1,x2)
, xmax = max(x1,x2)
, ymin = min(y1,y2)
, ymax = max(y1,y2);

for (int i = xmin; i < xmax; ++i)
if (ymin <= i && i <= ymax)
return true;

return false;
``````

Unless you're running some high-performance range-checker on billions of widely-spaced integers, our versions should perform similarly. My point is, this is micro-optimization.

• I think you've gone over the specification here. It's assumed that x1 to x2 is ascending/decending (either way, it's sorted) - there's no need for a loop, you only need to check the head and tail elements. I do prefer the min/max solution though - simply because it's easier to read when you come back to the code later. Jul 16, 2010 at 23:42
• -1: this is not micro-optimisation; this is choosing an appropriate algorithm. Your algorithm is O(n) when there is a simple O(1) choice. Jul 18, 2010 at 17:51
• This is what happens when "premature optimization is the root of all evil" becomes an inviolable religious tenet for the inept instead of a half-serious remark on some occasional pattern of behaviour. Apr 9, 2019 at 9:50