Rev 59 | Rev 61 | Go to most recent revision | Details | Compare with Previous | Last modification | View Log | RSS feed
| Rev | Author | Line No. | Line |
|---|---|---|---|
| 52 | jermar | 1 | <?xml version="1.0" encoding="UTF-8"?> |
| 59 | jermar | 2 | <chapter id="ds"> |
| 3 | <?dbhtml filename="ds.html"?> |
||
| 52 | jermar | 4 | |
| 59 | jermar | 5 | <title>Data structures</title> |
| 52 | jermar | 6 | |
| 59 | jermar | 7 | <para>There is lots of data that either flows through various HelenOS |
| 8 | subsystems or is stored directly by them. Each subsystem uses its own data |
||
| 9 | structures to represent the data. These data structures need to be kept |
||
| 10 | somewhere. In order to work efficiently, HelenOS, and especially its kernel, |
||
| 11 | deploys several house keeping data types that are designed to faciliate |
||
| 12 | managing other data structures. Most of them serve like generic |
||
| 13 | containers.</para> |
||
| 52 | jermar | 14 | |
| 59 | jermar | 15 | <section> |
| 16 | <title>Lists</title> |
||
| 52 | jermar | 17 | |
| 59 | jermar | 18 | <para>HelenOS uses doubly-circularly-linked lists to bind related data |
| 19 | together. Lists are composed of an independent sentinel node called head |
||
| 20 | and links that are always part of the object that is to be put into the |
||
| 21 | list. Adding items to a list thus doesn't require any further memory |
||
| 22 | allocations. Head and each link then contains forward and backward |
||
| 23 | pointer. An empty list is composed of a sole head whose both pointers |
||
| 24 | reference the head itself. The expense of two times bigger memory |
||
| 25 | consumption as compared to memory consumption of singly linked lists is |
||
| 26 | justified by constant insertion and removal times at random positions |
||
| 27 | within the list.</para> |
||
| 52 | jermar | 28 | |
| 59 | jermar | 29 | <para>Lists are frequently used to implement FIFO behaviour (e.g. |
| 30 | scheduler run queues or synchronization wait queues). Contrary to the FIFO |
||
| 31 | type, which is also supported by HelenOS, they don't take up any unused |
||
| 32 | space and are more general. On the other hand, they are slower than |
||
| 33 | in-array FIFOs and can be hardly used to implement buffers.</para> |
||
| 34 | </section> |
||
| 35 | |||
| 36 | <section> |
||
| 37 | <title>FIFO queues</title> |
||
| 38 | |||
| 39 | <para>FIFO queues are implemented as either statically or dynamically |
||
| 40 | allocated arrays<footnote> |
||
| 41 | <para>Depending on the array size.</para> |
||
| 42 | </footnote> of some generic type with two indices. The first index |
||
| 43 | points to the head of the FIFO queue and the other points to the tail |
||
| 44 | thereof. There can be as many items in the FIFO as is the number of |
||
| 45 | elements in the array and no more. The indices are taken modulo size of |
||
| 46 | the queue because as a consequence of insertions and deletions, the tail |
||
| 47 | can have numericaly lower index than the head.</para> |
||
| 48 | |||
| 49 | <para>FIFO queues are used, for example, in ASID management code to store |
||
| 50 | inactive ASIDs or in userspace keyboard driver to buffer read |
||
| 51 | characters.</para> |
||
| 52 | </section> |
||
| 53 | |||
| 54 | <section> |
||
| 55 | <title>Hash tables</title> |
||
| 56 | |||
| 57 | <para>The kernel, as well as userspace, provides hash table data type |
||
| 58 | which uses separate chaining. The hash table type is very generic in that |
||
| 59 | it forces the user to supply methods for computing the hash index, |
||
| 60 | comparing items against a set of keys and the item removal callback |
||
| 61 | function. Besides these virtual operations, the hash table is composed of |
||
| 62 | a dynamically allocated array of list heads that represent each chain, |
||
| 63 | number of chains and the maximal number of keys.</para> |
||
| 64 | </section> |
||
| 65 | |||
| 66 | <section> |
||
| 67 | <title>Bitmaps</title> |
||
| 68 | |||
| 69 | <para>Several bitmap operations such as clearing or setting consecutive |
||
| 70 | bit sequences as well as copying portions of one bitmap into another one |
||
| 71 | are supported.</para> |
||
| 72 | </section> |
||
| 73 | |||
| 74 | <section> |
||
| 75 | <title>B+trees</title> |
||
| 76 | |||
| 77 | <para>HelenOS makes use of a variant of B-tree called B+tree. B+trees, in |
||
| 78 | HelenOS implementation, are 3-4-5 balanced trees. They are characteristic |
||
| 79 | by the fact that values are kept only in the leaf-level nodes and that |
||
| 80 | these nodes are linked together in a list. This data structure has |
||
| 81 | logaritmic search, insertion and deletion times and, thanks to the |
||
| 82 | leaf-level list, provides fantastic means of walking the nodes containing |
||
| 83 | data. Moreover, B+trees can be used for easy storing, resizing and merging |
||
| 84 | of disjunctive intervals.</para> |
||
| 60 | jermar | 85 | |
| 86 | <para> |
||
| 87 | <mediaobject id="btree" xreflabel=""> |
||
| 88 | <imageobject role="html"> |
||
| 89 | <imagedata fileref="images/btree.png" format="PNG" /> |
||
| 90 | </imageobject> |
||
| 91 | |||
| 92 | <imageobject role="fop"> |
||
| 93 | <imagedata fileref="images.vector/btree.svg" format="SVG" /> |
||
| 94 | </imageobject> |
||
| 95 | |||
| 96 | <caption>B+tree</caption> |
||
| 97 | </mediaobject> |
||
| 98 | </para> |
||
| 99 | |||
| 59 | jermar | 100 | </section> |
| 101 | </chapter> |