# What are the differences between segment trees, interval trees, binary indexed trees and range trees?

What are differences between segment trees, interval trees, binary indexed trees and range trees in terms of:

• Key idea/definition
• Applications
• Performance/order in higher dimensions/space consumption

Please do not just give definitions.

• It is not a duplicate, That question is if fenwick trees is generalization of interval tress, and my question is more specific and different. Commented Jul 4, 2013 at 9:08
• It has not been answered at stackoverflow.com/questions/2795989/…, the answer there just gives definition. Commented Jul 4, 2013 at 9:10
• How is it too broad? "What are some differences between x and y?" is as clear and focused as it gets. This is a very good question. Commented Jul 4, 2013 at 9:29
• And there is no good answer for this available anywhere. A good answer will be great for the community Commented Jul 4, 2013 at 9:30
• Most of these data structures (except Fenwick trees) are reviewed in this pdf: "Interval, Segment, Range, and Priority Search Trees" (by D. T. Lee). Or you can read it as a chapter from this book: "Handbook of Data Structures and Applications". Commented Jul 4, 2013 at 10:18

All these data structures are used for solving different problems:

• Segment tree stores intervals, and optimized for "which of these intervals contains a given point" queries.
• Interval tree stores intervals as well, but optimized for "which of these intervals overlap with a given interval" queries. It can also be used for point queries - similar to segment tree.
• Range tree stores points, and optimized for "which points fall within a given interval" queries.
• Binary indexed tree stores items-count per index, and optimized for "how many items are there between index m and n" queries.

Performance / Space consumption for one dimension:

• Segment tree - O(n logn) preprocessing time, O(k+logn) query time, O(n logn) space
• Interval tree - O(n logn) preprocessing time, O(k+logn) query time, O(n) space
• Range tree - O(n logn) preprocessing time, O(k+logn) query time, O(n) space
• Binary Indexed tree - O(n logn) preprocessing time, O(logn) query time, O(n) space

(k is the number of reported results).

All data structures can be dynamic, in the sense that the usage scenario includes both data changes and queries:

• Segment tree - interval can be added/deleted in O(logn) time (see here)
• Interval tree - interval can be added/deleted in O(logn) time
• Range tree - new points can be added/deleted in O(logn) time (see here)
• Binary Indexed tree - the items-count per index can be increased in O(logn) time

Higher dimensions (d>1):

• Segment tree - O(n(logn)^d) preprocessing time, O(k+(logn)^d) query time, O(n(logn)^(d-1)) space
• Interval tree - O(n logn) preprocessing time, O(k+(logn)^d) query time, O(n logn) space
• Range tree - O(n(logn)^d) preprocessing time, O(k+(logn)^d) query time, O(n(logn)^(d-1))) space
• Binary Indexed tree - O(n(logn)^d) preprocessing time, O((logn)^d) query time, O(n(logn)^d) space
• I really get the impression that segment trees < interval trees from this. Is there any reason to prefer a segment tree? E.g. implementation simplicity? Commented Jul 24, 2013 at 21:36
• @j_random_hacker: Segment trees based algorithms have advantages in certain more complex high-dimensional variants of the intervals query. For example, finding which non-axis-parallel line-segments intersect with a 2D window. Commented Jul 25, 2013 at 16:39
• Thanks, I'd be interested in any elaboration you could give on that. Commented Jul 25, 2013 at 23:17
• @j_random_hacker, segment trees have another interesting use: RMQs (range minimum queries) in O(log N) time where N is the overall interval size. Commented Feb 26, 2014 at 6:48
• Why are segment trees O(n log n) space? They store N leaves + N /2 + N/4 + ... + N/2^(log N), and this sum is O(N) if I am not mistaken. Also @icc97 answer also reports O(N) space.
– Ant
Commented Jun 19, 2018 at 8:32

Not that I can add anything to Lior's answer, but it seems like it could do with a good table.

### One Dimension

`k` is the number of reported results

Operation Segment Interval Range Indexed
Preprocessing n logn n logn n logn n logn
Query k+logn k+logn k+logn logn
Space n logn n n n
Insert/Delete logn logn logn logn

### Higher Dimensions

`d > 1`

Operation Segment Interval Range Indexed
Preprocessing n(logn)^d n logn n(logn)^d n(logn)^d
Query k+(logn)^d k+(logn)^d k+(logn)^d (logn)^d
Space n(logn)^(d-1) n logn n(logn)^(d-1)) n(logn)^d
• What do you mean by reported results ? Commented Feb 1, 2016 at 12:23
• @ps06756 search algorithms often have a runtime of log(n) where n is the inputsize but can yield results that are linear in n which can't be done in logarithmic time (outputting n numbers in log(n) time is not possible). Commented Aug 23, 2016 at 12:14
• Shouldn't Segment Tree have `O(n logn) space` in the first table? Commented Nov 23, 2018 at 15:48
• @Danny_ds - thanks I fixed that when you commented Commented Mar 10, 2023 at 9:11

The bounds for preprocessing and space for segment trees and binary indexed trees can be improved: