As you already know linux kernel provides many different libraries and functions which implement different data structures and algorithm. In this part we will consider one of these data structures - [Radix tree](http://en.wikipedia.org/wiki/Radix_tree). There are two files which are related to `radix tree` implementation and API in the linux kernel:
Lets talk about what is `radix tree`. Radix tree is a `compressed trie` where [trie](http://en.wikipedia.org/wiki/Trie) is a data structure which implements interface of an associative array and allows to store values as `key-value`. The keys are usually strings, but any other data type can be used as well. Trie is different from any `n-tree` in its nodes. Nodes of a trie do not store keys, instead, a node of a trie stores single character labels. The key which is related to a given node is derived by traversing from the root of the tree to this node. For example:
So in this example, we can see the `trie` with keys, `go` and `cat`. The compressed trie or `radix tree` differs from `trie`, such that all intermediates nodes which have only one child are removed.
Radix tree in linux kernel is the datastructure which maps values to the integer key. It is represented by the following structures from the file [include/linux/radix-tree.h](https://github.com/torvalds/linux/blob/master/include/linux/radix-tree.h):
Low-level kernel memory allocation functions take a set of flags as - `gfp_mask`, which describes how that allocation is to be performed. These `GFP_` flags which control the allocation process can have following values, (`GF_NOIO` flag) be sleep and wait for memory, (`__GFP_HIGHMEM` flag) is high memory can be used, (`GFP_ATOMIC` flag) is allocation process high-priority and can't sleep etc.
This structure contains information about the offset in a parent and height from the bottom, count of the child nodes and fields for accessing and freeing a node. The fields are described below:
The two last fields of the `radix_tree_node` - `tags` and `slots` are important and interesting. Every node can contains a set of slots which are store pointers to the data. Empty slots in the linux kernel radix tree implementation store `NULL`. Radix tree in the linux kernel also supports tags which are associated with the `tags` fields in the `radix_tree_node` structure. Tags allow to set individual bits on records which are stored in the radix tree.
As you can see we pass the `name` parameter, so with the `RADIX_TREE` macro we can define and initialize radix tree with the given name. Implementation of the `RADIX_TREE` is easy:
```C
#define RADIX_TREE(name, mask) \
struct radix_tree_root name = RADIX_TREE_INIT(mask)
At the beginning of the `RADIX_TREE` macro we define instance of the `radix_tree_root` structure with the given name and call `RADIX_TREE_INIT` macro with the given mask. The `RADIX_TREE_INIT` macro just initializes `radix_tree_root` structure with the default values and the given mask.
This function tries to find the given key in the tree and returns associated record with this key. The second `radix_tree_gang_lookup` function have the following signature
and returns number of records, sorted by the keys, starting from the first index. Number of the returned records will be not greater than `max_items` value.