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Storage and File Organization

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Presentation on theme: "Storage and File Organization"— Presentation transcript:

1 Storage and File Organization

2 File Organization Basics Two important issues:
A database is a collection of files, A file is a collection of records A record (tuple) is a collection of fields (attributes) Files are stored on Disks (that use blocks to read and write) Two important issues: Representation of each record Grouping/Ordering of records and storage in blocks

3 File Organization Goal and considerations: Compactness
Overhead of insertion/deletion Retrieval speed sometimes we prefer to bring more tuples than necessary into MM and use CPU to filter out the unnecessary ones!

4 Record Representation
Fixed-Length Records Example Account( acc-number char(10), branch-name char(20), balance real) Each record is 38 bytes. Store them sequentially, one after the other Record1 at position 0, record2 at position 38, record3 at position 76 etc Compactness (350 bytes)

5 Fixed-Length Records Simple approach:
Store record i starting from byte n  (i – 1), where n is the size of each record. Record access is simple but records may cross blocks Modification: do not allow records to cross block boundaries Insertion of record i: Add at the end Deletion of record i: Two alternatives: move records: i + 1, . . ., n to i, , n – 1 Move record n to position i do not move records, but link all free records on a free list

6 Free Lists 2nd approach: FLR with Free Lists Better handling ins/del
Store the address of the first deleted record in the file header. Use this first record to store the address of the second deleted record, and so on Can think of these stored addresses as pointers since they “point” to the location of a record. Better handling ins/del Less compact

7 Variable-Length Records
3rd approach: Variable-length records arise in database systems in several ways: Storage of multiple record types in a file. Record types that allow variable lengths for one or more fields. Record types that allow repeating fields or multivalued attribute. Byte string representation Attach an end-of-record () control character to the end of each record Difficulty with deletion (leaves holes) Difficulty with growth 4 Field Count R1 R2 R3

8 Variable-Length Records: Slotted Page Structure
4th approach VLR-SP Slotted page header contains: number of record entries end of free space in the block location and size of each record Records stored at the bottom of the page External tuple pointers point to record ptrs: rec-id = <page-id, slot#>

9 N # slots Rid = (i,N) Page i Rid = (i,2) Rid = (i,1) 20 16 24
Pointer to start of free space N # slots SLOT DIRECTORY Insertion: 1) Use Free Space Pointer (FP) to find space and insert 2) Find available ptr in the directory (or create a new one) 3) adjust FP and number of records Deletion ?

10 Variable-Length Records (Cont.)
Fixed-length representation: reserved space pointers 5th approach: Fixed Limit Records (for VLR) Reserved space – can use fixed-length records of a known maximum length; unused space in shorter records filled with a null or end-of-record symbol.

11 Pointer Method 6th approach: Pointer method Pointer method
A variable-length record is represented by a list of fixed-length records, chained together via pointers. Can be used even if the maximum record length is not known

12 Pointer Method (Cont.) Disadvantage to pointer structure; space is wasted in all records except the first in a chain. Solution is to allow two kinds of block in file: Anchor block – contains the first records of chain Overflow block – contains records other than those that are the first records of chains.

13 Ordering and Grouping records
Issue #1: In what order we place records in a block? Heap technique: assign anywhere there is space Ordered technique: maintain an order on some attribute So, we can use binary search if selection on this attribute.

14 Sequential File Organization
Suitable for applications that require sequential processing of the entire file The records in the file are ordered by a search-key

15 Sequential File Organization (Cont.)
Deletion – use pointer chains Insertion –locate the position where the record is to be inserted if there is free space insert there if no free space, insert the record in an overflow block In either case, pointer chain must be updated Need to reorganize the file from time to time to restore sequential order

16 Clustering File Organization
Simple file structure stores each relation in a separate file Can instead store several relations in one file using a clustering file organization e.g., clustering organization of customer and depositor: SELECT account-number, customer-name FROM depositor d, account a WHERE d.customer-name = a.customer-name good for queries involving depositor account, and for queries involving one single customer and his accounts bad for queries involving only customer results in variable size records

17 File organization Issue #2: In which blocks should records be placed
Many alternatives exist, each ideal for some situation , and not so good in others: Heap files: Add at the end of the file.Suitable when typical access is a file scan retrieving all records. Sorted Files:Keep the pages ordered. Best if records must be retrieved in some order, or only a `range’ of records is needed. Hashed Files: Good for equality selections. Assign records to blocks according to their value for some attribute

18 Data Dictionary Storage
Data dictionary (also called system catalog) stores metadata: that is, data about data, such as Information about relations names of relations names and types of attributes of each relation names and definitions of views integrity constraints User and accounting information, including passwords Statistical and descriptive data number of tuples in each relation Physical file organization information How relation is stored (sequential/hash/…) Physical location of relation operating system file name or disk addresses of blocks containing records of the relation Information about indices

19 Data dictionary storage
Stored as tables!! E-R diagram? Relations, attributes, domains Each relation has name, some attributes Each attribute has name, length and domain Also, views, integrity constraints, indices User info (authorizations etc) statistics

20 A-name name position 1 N has relation attribute domain

21 Data Dictionary Storage (Cont.)
A possible catalog representation: Relation-metadata = (relation-name, number-of-attributes, storage-organization, location) Attribute-metadata = (attribute-name, relation-name, domain-type, position, length) User-metadata = (user-name, encrypted-password, group) Index-metadata = (index-name, relation-name, index-type, index-attributes) View-metadata = (view-name, definition)


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