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I know that performance never is black and white, often one implementation is faster in case X and slower in case Y, etc. but in general - are B-trees faster then AVL or RedBlack-Trees? They are considerably more complex to implement then AVL trees (and maybe even RedBlack-trees?), but are they faster (does their complexity pay off) ? Edit: I should also like to add that if they are faster then the equivalent AVL/RedBlack tree (in terms of nodes/content) - why are they faster?
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Sean's post (the currently accepted one) is full of nonsense. Sorry Sean, I don't mean to be rude; I hope I can convince you that my statement is based in fact.
They're both used for maintaining a set of totally ordered items with fast lookup, insertion and deletion. They have the same interface and the same intention.
always O(log n)
Nonsense. When you store search trees on disk, you typically use B-trees. That much is true. When you store data on disk, it's slower to access than data in memory. But a red-black tree stored on disk is also slower than a red-black tree stored in memory. You're comparing apples and oranges here. What is really interesting is a comparison of in-memory B-trees and in-memory red-black trees. [As an aside: B-trees, as opposed to red-black trees, are theoretically efficient in the I/O-model. I have experimentally tested (and validated) the I/O-model for sorting; I'd expect it to work for B-trees as well.]
To be clear, the size range of B-tree nodes is a parameter of the tree (in C++, you may want to use an integer value as a template parameter).
I remember them to be much simpler to understand (and implement) than red-black trees.
That much is true.
Got data?
Got data?
The size of each node is a fixed parameter, so even if you do a linear scan, it's O(1). If we big-oh over the size of each node, note that you typically keep the array sorted so it's O(log n).
You're comparing apples and oranges. The O(log n) is because the height of the tree is at most O(log n), just as it is for a B-tree. Also, unless you play nasty allocation tricks with the red-black trees, it seems reasonable to conjecture that B-trees have better caching behavior (it accesses an array, not pointers strewn about all over the place, and has less allocation overhead increasing memory locality even more), which might help it in the speed race. I can point to experimental evidence that B-trees (with size parameters 32 and 64, specifically) are very competitive with red-black trees for small sizes, and outperforms it hands down for even moderately large values of n. See http://idlebox.net/2007/stx-btree/stx-btree-0.8.3/doxygen-html/speedtest.html B-trees are faster. Why? I conjecture that it's due to memory locality, better caching behavior and less pointer chasing (which are, if not the same things, overlapping to some degree). |
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Actually Wikipedia has a great article that shows every RB-Tree can easily be expressed as a B-Tree. Take the following tree as sample:
now just convert it to a B-Tree (to make this more obvious, nodes are still colored R/B, what you usually don't have in a B-Tree): (cannot add the image here for some weird reason) Same is true for any other RB-Tree. It's taken from this article: http://en.wikipedia.org/wiki/Red-black_tree To quote from this article:
I found no data that one of both is significantly better than the other one. I guess one of both had already died out if that was the case. They are different regarding how much data they must store in memory and how complicated it is to add/remove nodes from the tree. Update:My personal tests suggest that B-Trees are better when searching for data, as they have better data locality and thus the CPU cache can do compares somewhat faster. The higher the order of a B-Tree (the order is the number of children a note can have), the faster the lookup will get. On the other hand, they have worse performance for adding and removing new entries the higher their order is. This is caused by the fact that adding a value within a node has linear complexity. As each node is a sorted array, you must move lots of elements around within that array when adding an element into the middle: all elements to the left of the new element must be moved one position to the left or all elements to the right of the new element must be moved one position to the right. If a value moves one node upwards during an insert (which happens frequently in a B-Tree), it leaves a hole which must be also be filled either by moving all elements from the left one position to the right or by moving all elements to the right one position to the left. These operations (in C usually performed by memmove) are in fact O(n). So the higher the order of the B-Tree, the faster the lookup but the slower the modification. On the other hand if you choose the order too low (e.g. 3), a B-Tree shows little advantages or disadvantages over other tree structures in practice (in such a case you can as well use something else). Thus I'd always create B-Trees with high orders (at least 4, 8 and up is fine). File systems, which often base on B-Trees, use much higher orders (order 200 and even a lot more) - this is because they usually choose the order high enough so that a note (when containing maximum number of allowed elements) equals either the size of a sector on harddrive or of a cluster of the filesystem. This gives optimal performance (since a HD can only write a full sector at a time, even when just one byte is changed, the full sector is rewritten anyway) and optimal space utilization (as each data entry on drive equals at least the size of one cluster or is a multiple of the cluster sizes, no matter how big the data really is). Caused by the fact that the hardware sees data as sectors and the file system groups sectors to clusters, B-Trees can yield much better performance and space utilization for file systems than any other tree structure can; that's why they are so popular for file systems. When your app is constantly updating the tree, adding or removing values from it, a RB-Tree or an AVL-Tree may show better performance on average compared to a B-Tree with high order. Somewhat worse for the lookups and they might also need more memory, but therefor modifications are usually fast. Actually RB-Trees are even faster for modifications than AVL-Trees, therefor AVL-Trees are a little bit faster for lookups as they are usually less deep. So as usual it depends a lot what your app is doing. My recommendations are:
An alternative to all these trees are AA-Trees. As this PDF paper suggests, AA-Trees (which are in fact a sub-group of RB-Trees) are almost equal in performance to normal RB-Trees, but they are much easier to implement than RB-Trees, AVL-Trees, or B-Trees. Here is a full implementation, look how tiny it is (the main-function is not part of the implementation and half of the implementation lines are actually comments). As the PDF paper shows, a Treap is also an interesting alternative to classic tree implementation. A Treap is also a binary tree, but one that doesn't try to enforce balancing. To avoid worst case scenarios that you may get in unbalanced binary trees (causing lookups to become O(n) instead of O(log n)), a Treap adds some randomness to the tree. Randomness cannot guarantee that the tree is well balanced, but it also makes it highly unlikely that the tree is extremely unbalanced. |
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They all have the same asymptotic behavior, so the performance depends more on the implementation than which type of tree you are using. Some combination of tree structures might actually be the fastest approach, where each node of a B-tree fits exactly into a cache-line and some sort of binary tree is used to search within each node. Managing the memory for the nodes yourself might also enable you to achieve even greater cache locality, but at a very high price. Personally, I just use whatever is in the standard library for the language I am using, since it's a lot of work for a very small performance gain (if any). On a theoretical note... RB-trees are actually very similar to B-trees, since they simulate the behavior of 2-3-4 trees. AA-trees are a similar structure, which simulates 2-3 trees instead. |
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Nothing prevents a B-Tree implementation that works only in memory. In fact, if key comparisons are cheap, in-memory B-Tree can be faster because its packing of multiple keys in one node will cause less cache misses during searches. See this link for performance comparisons. A quote: "The speed test results are interesting and show the B+ tree to be significantly faster for trees containing more than 16,000 items." (B+Tree is just a variation on B-Tree). |
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They're totally different in their use cases, so it's not possible to make a comparison. RB trees are typically in-memory structures used to provide fast access (ideally O(logN)) to data. A lot of C++ STL implementations uses them in the set class. RB are always binary trees. B-trees are typically disk-based structures, and so are inherently slower than in-memory data. Most database products use some form of B-tree (eg B*-tree) to manage their external data. B-trees are rarely binary trees, the number of children a node can have is typically a large number. The management of the B-tree structure can be quite complicated when the data changes. B-tree try to minimize the number of disk accesses so that data retrieval is reasonably deterministic. It's not uncommon to see something like 4 B-tree access necessary to lookup a bit of data in a very database. In most cases I'd say that in-memory RB trees are faster. Because the lookup is binary it's very easy to find something. B-tree can have multiple children per node, so on each node you have to scan the node to look for the appropriate child. This is an O(N) operation. On a RB-tree it'd be O(logN) since you're doing one comparison and then branching. |
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THey are sed in different circumstances - B-trees are used when the tree nodes need to be kept together in storage - typically because storage is a disk page and so re-balancing could be vey expensive. RB trees are used when you don't have this constraint. So B-trees will probably be faster if you want to implement (say) a relational database index, while RB trees will probably be fasterv for (say) an in memory search. |
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