Please explain the difference between a binary search tree and m-way tree?
A binary tree is a special case of an m-way tree with only one "value" per node (m = 1) and you either move down to the left or the right link.
An m-way tree can have more than one "value" per node but the theory is still the same: you choose which link to move down to and there's m+1 possible choices. An m-way tree (where m is 2) can look like this:
These m-way trees are often used in situations where you can fit more than one value in an efficient block (by efficient, I mean one that can be read and written efficiently, like a disk block, sector, cluster or cylinder depending on how your storage subsystem operates).
For example, if a disk block is 512 bytes, the values take up 122 bytes and the links take up 4 bytes, you can fit 4 values in a disk block, calculated as follows:
That gives you four values (4 x 122 = 488) and five links (5 x 4 = 20) for a total of 508 bytes. Although there's some wastage, this has the advantage of storing an integral number of values in each efficient block.
A binary search tree has only two fixed branches and is therefore a lot easier to implement. m-way trees such as B-trees are generally used when the tree has to be stored on disk rather than in memory. Examples include file systems and database indexes.
an m-way search tree is a m-way tree in which:
Each node has m children and m-1 key fields The keys in each node are in ascending order. The keys in the first i children are smaller than the ith key The keys in the last m-i children are larger than the ith key
An extension of a multiway search tree of order m is a B-tree of order m. This type of tree will be used when the data to be accessed/stored is located on secondary storage devices because they allow for large amounts of data to be stored in a node.
A B-tree of order m is a multiway search tree in which:
The root has at least two subtrees unless it is the only node in the tree. Each nonroot and each nonleaf node have at most m nonempty children and at least m/2 nonempty children. The number of keys in each nonroot and each nonleaf node is one less than the number of its nonempty children. All leaves are on the same level.