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Generally speaking you're making a decision between fast read times (e.g. nested set) or fast write times (adjacency list). Usually you end up with a combination of the options below that best fit your needs. The following provides some in depth reading:


Ones I am aware of and general features:

  1. Adjacency List:
    • Columns: ID, ParentID
    • Easy to implement.
    • Cheap node moves, inserts, and deletes.
    • Expensive to find level (can store as a computed column), ancestry & descendants (Bridge Table combined with level column can solve), path (Lineage Column can solve).
    • Use Common Table Expressions in those databases that support them to traverse.
  2. Nested Set (a.k.a Modified Preorder Tree Traversal)
    • Popularized by Joe Celko in numerous articles and his book Trees and Hierarchies in SQL for Smarties
    • Columns: Left, Right
    • Cheap level, ancestry, descendants
    • Compared to Adjacency List, moves, inserts, deletes more expensive.
    • Requires a specific sort order (e.g. created). So sorting all descendants in a different order requires additional work.
  3. Nested Intervals
    • Combination of Nested Sets and Materialized Path where left/right columns are floating point decimals instead of integers and encode the path information. In the later development of this idea nested intervals gave rise to matrix encoding.
  4. Bridge Table (a.k.a. Closure Table: some good ideas about how to use triggers for maintaining this approach)
    • Columns: ancestor, descendant
    • Stands apart from table it describes.
    • Can include some nodes in more than one hierarchy.
    • Cheap ancestry and descendants (albeit not in what order)
    • For complete knowledge of a hierarchy needs to be combined with another option.
  5. Flat Table
    • A modification of the Adjacency List that adds a Level and Rank (e.g. ordering) column to each record.
    • Expensive move and delete
    • Cheap ancestry and descendants
    • Good Use: threaded discussion - forums / blog comments
  6. Lineage Column (a.k.a. Materialized Path, Path Enumeration)
    • Column: lineage (e.g. /parent/child/grandchild/etc...)
    • Limit to how deep the hierarchy can be.
    • Descendants cheap (e.g. LEFT(lineage, #) = '/enumerated/path')
    • Ancestry tricky (database specific queries)
  7. Multiple lineage columns
    • Columns: one for each lineage level, refers to all the parents up to the root, levels down from the items level are set to NULL
    • Limit to how deep the hierarchy can be
    • Cheap ancestors, descendants, level
    • Cheap insert, delete, move of the leaves
    • Expensive insert, delete, move of the internal nodes

Database Specific Notes




SQL Server

  • General summary
  • 2008 offers HierarchyId data type appears to help with Lineage Column approach and expand the depth that can be represented.
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IMO Transitive Closure Table method missing from your list is more significant than #4-5. –  Tegiri Nenashi Oct 29 '10 at 17:00
@Tegiri Nenashi: Is this the same thing as a Closure Table as described here: slideshare.net/billkarwin/models-for-hierarchical-data? –  orangepips Oct 29 '10 at 19:13
Yes. "Maintaining Transitive Closure of Graphs in SQL" by Libkin et.al is classic paper on the subject. –  Tegiri Nenashi Oct 29 '10 at 19:33
@Tegiri Nenashi: +1 OK, I believe this is the same thing as - or very similar to - a Bridge Table. I've added a name and link in the question above. –  orangepips Oct 29 '10 at 19:59
According to slideshare.net/billkarwin/sql-antipatterns-strike-back page 77, Closure Tables are superior to Adjacency List, Path Enumeration and Nested Sets in terms of ease of use (and I'm guessing performance as well). –  Gili Nov 1 '12 at 0:36

9 Answers 9

up vote 65 down vote accepted

This is kind of a question that is still interesting even after all big 3 vendors implemented Recursive WITH clause. I'd suggest that different readers would be pleased with different answers.

  1. Comprehensive list of references by Troels Arvin.
  2. For the lack of competition, introductory textbook by Joe Celko "Trees and Hierarchies in SQL for Smarties" can indeed be considered a classics.
  3. Review of various tree encodings with emphasis to nested intervals.
share|improve this answer
I guess with the big 3 you mean Oracle, IBM and Microsoft. Don't forget that Firebird, PostgreSQL and H2 also support recursive common table expressions –  a_horse_with_no_name Oct 29 '10 at 16:48
+1 for the comprehensive list –  orangepips Oct 29 '10 at 19:04
+1 to @a_horse_with_no_name for the CTE knowledge with other DBs. –  orangepips Oct 29 '10 at 19:05
Accepting as the answer because the Troels Arvin link is by far the most comprehensive. –  orangepips Oct 31 '10 at 19:36
The question is better than the answer in the sense that it points out which operations are efficient/expensive for each algorithm. Wading through 30+ different articles to get the same answer is an exercise in futility. –  Gili Oct 31 '12 at 17:08

Some articles from my blog on the subject:

share|improve this answer
+1 forgot about MySQL session variables. Knew nothing about PostgreSQL, good to know it supports CTEs. –  orangepips Oct 29 '10 at 13:12
@Quassnoi Why do you have commments on your blog articles turned off? –  Jeff Moden Oct 4 '12 at 4:10
Links appear to be broken. –  Lane Jun 25 '13 at 14:43
@Lane: which exactly? –  Quassnoi Jun 25 '13 at 14:49
@buffer: nothing much –  Quassnoi Mar 2 '14 at 17:13

Joe Celko wrote the book on SQL Trees & Hiearichies

This is the first edition. Look at the second edition in Bob's comment.

share|improve this answer
+1 this is a classic book. –  orangepips Oct 29 '10 at 13:13
This book has a second edition. –  BobStein-VisiBone Aug 21 '13 at 2:15
I love this book. Master piece. –  kta Feb 16 '14 at 8:51
This by itself does not stand as an answer. Please summarize the main points. –  Pacerier Jan 25 at 17:56

This is a very partial answer to your question, but I hope still useful.

Microsoft SQL Server 2008 implements two features that are extremely useful for managing hierarchical data:

  • the HierarchyId data type.
  • common table expressions, using the with keyword.

Have a look at this article for starts. See also my own question here.

share|improve this answer
Interesting, the HierarchyId, didn't know about that one: msdn.microsoft.com/en-us/library/bb677290.aspx –  orangepips Oct 29 '10 at 0:38
Indeed. I work with a lot of recursively hierarchical data, and I find common table expressions extremely useful. See msdn.microsoft.com/en-us/library/ms186243.aspx for an intro. –  CesarGon Oct 29 '10 at 0:41
+1 Wow, hadn't seen HierarchyId before now. Goodbye computed and denormalized column maintenance. –  JeremyWeir Oct 29 '10 at 0:45

My favorite answer is as what the first sentence in this thread suggested. Use an Adjacency List to maintain the hierarchy and use Nested Sets to query the hierarchy.

The problem up until now has been that the coversion method from an Adjacecy List to Nested Sets has been frightfully slow because most people use the extreme RBAR method known as a "Push Stack" to do the conversion and has been considered to be way to expensive to reach the Nirvana of the simplicity of maintenance by the Adjacency List and the awesome performance of Nested Sets. As a result, most people end up having to settle for one or the other especially if there are more than, say, a lousy 100,000 nodes or so. Using the push stack method can take a whole day to do the conversion on what MLM'ers would consider to be a small million node hierarchy.

I thought I'd give Celko a bit of competition by coming up with a method to convert an Adjacency List to Nested sets at speeds that just seem impossible. Here's the performance of the push stack method on my i5 laptop.

Duration for     1,000 Nodes = 00:00:00:870 
Duration for    10,000 Nodes = 00:01:01:783 (70 times slower instead of just 10)
Duration for   100,000 Nodes = 00:49:59:730 (3,446 times slower instead of just 100) 
Duration for 1,000,000 Nodes = 'Didn't even try this'

And here's the duration for the new method (with the push stack method in parenthesis).

Duration for     1,000 Nodes = 00:00:00:053 (compared to 00:00:00:870)
Duration for    10,000 Nodes = 00:00:00:323 (compared to 00:01:01:783)
Duration for   100,000 Nodes = 00:00:03:867 (compared to 00:49:59:730)
Duration for 1,000,000 Nodes = 00:00:54:283 (compared to something like 2 days!!!)

Yes, that's correct. 1 million nodes converted in less than a minute and 100,000 nodes in under 4 seconds.

You can read about the new method and get a copy of the code at the following URL. http://www.sqlservercentral.com/articles/Hierarchy/94040/

I also developed a "pre-aggregated" hierarchy using similar methods. MLM'ers and people making bills of materials will be particularly interested in this article. http://www.sqlservercentral.com/articles/T-SQL/94570/

If you do stop by to take a look at either article, jump into the "Join the discussion" link and let me know what you think.

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Content behind the links is useful and should be recreated here. However, the neither preamble text here before the links nor the required registration to view the articles is useful. –  orangepips Mar 4 '13 at 2:56
The full content and meaning can't be posted here because of length limits. The required resistration won't kill anyone, either. Shoot, I had to register here to participate and the original post on this thread also had links that could have been "recreated here" so not sure what the big deal is. Like a bazillion other forums, they only ask for your email so that you can be alerted to answers to your post if you ask a question. They don't sell it nor do they spam you. –  Jeff Moden Apr 14 '13 at 19:18
@JeffModen: Registration is an unconditional showstopper for me and all other people I know (Why? It's too much hassle to go through, for an answer which might not even be worth a few seconds of your time). And while you have to register to contribute to SO, you don't have to if you only want to read others' contributions. –  Jo So Aug 13 '14 at 3:59
And Like a bazillion other forums, they only ask for your email so that you can be alerted to answers to your post if you ask a question. They don't sell it nor do they spam you.. Come on. Seriously? –  Jo So Aug 13 '14 at 4:00

If your database supports arrays, you can also implement a lineage column or materialized path as an array of parent ids.

Specifically with Postgres you can then use the set operators to query the hierarchy, and get excellent performance with GIN indices. This makes finding parents, children, and depth pretty trivial in a single query. Updates are pretty manageable as well.

I have a full write up of using arrays for materialized paths if you're curious.

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This design was not mentioned yet:

Multiple lineage columns

Though it has limitations, if you can bear them, it's very simple and very efficient. Features:

  • Columns: one for each lineage level, refers to all the parents up to the root, levels down from the items level are set to NULL
  • Limit to how deep the hierarchy can be
  • Cheap ancestors, descendants, level
  • Cheap insert, delete, move of the leaves
  • Expensive insert, delete, move of the internal nodes

Here follows an example - taxonomic tree of birds so the hierarchy is Class/Order/Family/Genus/Species - species is the lowest level, 1 row = 1 species:

CREATE TABLE `taxons` (
  `TaxonId` smallint(6) NOT NULL default '0',
  `ClassId` smallint(6) default NULL,
  `OrderId` smallint(6) default NULL,
  `FamilyId` smallint(6) default NULL,
  `GenusId` smallint(6) default NULL,
  `Name` varchar(150) NOT NULL default ''

and the example of the data:

| TaxonId | ClassId | OrderId | FamilyId | GenusId | Name                          |
|     254 |       0 |       0 |        0 |       0 | Aves                          |
|     255 |     254 |       0 |        0 |       0 | Gaviiformes                   |
|     256 |     254 |     255 |        0 |       0 | Gaviidae                      |
|     257 |     254 |     255 |      256 |       0 | Gavia                         |
|     258 |     254 |     255 |      256 |     257 | Gavia stellata                |
|     259 |     254 |     255 |      256 |     257 | Gavia arctica                 |
|     260 |     254 |     255 |      256 |     257 | Gavia immer                   |
|     261 |     254 |     255 |      256 |     257 | Gavia adamsii                 |
|     262 |     254 |       0 |        0 |       0 | Podicipediformes              |
|     263 |     254 |     262 |        0 |       0 | Podicipedidae                 |
|     264 |     254 |     262 |      263 |       0 | Tachybaptus                   |

This is great because this way you accomplish all the needed operations in a very easy way, as long as the internal categories don't change their level in the tree.

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For more complex hierarchies, like an LDAP tree, the OpenLDAP-MySQL Cluster architecture was presented at the MySQL User Conference back in 2009.


It's quite similar to the "Multiple lineage columns" scheme shown above.

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This is really a square peg, round hole question.

If relational databases and SQL are the only hammer you have or are willing to use, then the answers that have been posted thus far are adequate. However, why not use a tool designed to handle hierarchical data? Graph database are ideal for complex hierarchical data.

The inefficiencies of the relational model along with the complexities of any code/query solution to map a graph/hierarchical model onto a relational model is just not worth the effort when compared to the ease with which a graph database solution can solve the same problem.

Consider a Bill of Materials as a common hierarchical data structure.

class Component extends Vertex {
    long assetId;
    long partNumber;
    long material;
    long amount;

class PartOf extends Edge {

class AdjacentTo extends Edge {

Shortest path between two sub-assemblies: Simple graph traversal algorithm. Acceptable paths can be qualified based on criteria.

Similarity: What is the degree of similarity between two assemblies? Perform a traversal on both sub-trees computing the intersection and union of the two sub-trees. The percent similar is the intersection divided by the union.

Transitive Closure: Walk the sub-tree and sum up the field(s) of interest, e.g. "How much aluminum is in a sub-assembly?"

Yes, you can solve the problem with SQL and a relational database. However, there are much better approaches if you are willing to use the right tool for the job.

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This answer would be immensely more useful if the use cases demonstrated, or better yet contrasted, how to query a graph database with SPARQL for instance instead of SQL in an RDBMS. –  orangepips Jan 6 at 13:58
SPARQL is relevant to RDF databases which are a subclass of the larger domain of graph databases. I work with InfiniteGraph which is not an RDF database and does not currently support SPARQL. InfiniteGraph supports several different query mechanisms: (1) a graph navigation API for setting up views, filters, path qualifiers and result handlers, (2) a complex graph path pattern matching language, and (3) Gremlin. –  djhallx Jan 7 at 16:05

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