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CpSc 862Note #31 CPSC 8620: Database Management System Design Data Format and Organization * From Database Systems – the complete book, authored by Dr.

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Presentation on theme: "CpSc 862Note #31 CPSC 8620: Database Management System Design Data Format and Organization * From Database Systems – the complete book, authored by Dr."— Presentation transcript:

1 CpSc 862Note #31 CPSC 8620: Database Management System Design Data Format and Organization * From Database Systems – the complete book, authored by Dr. Hector Garcia-Molina et al.

2 6/10/20162 Copyright notice Materials and lecture notes in this course are adapted from various sources, including the authors of the textbook and references, Internet, etc. The Copyright belong to the original authors. Thanks!

3 CpSc 862Note #33 How to lay out data on disk What are the data items we want to store? –a salary, a name, a date, a picture Topics for today What we have available: Bytes 8 bits

4 CpSc 862Note #34 To represent: Integer (short): 2 bytes e.g., 35 is 0000000000100011 Real, floating point n bits for significant, m for exponent….

5 CpSc 862Note #35 Characters  various coding schemes suggested, ascii, EBCDIC, Scan Code, Unicode… To represent: Example: A: 1000001 a: 1100001 5: 0110101 LF: 0001010

6 CpSc 862Note #36 Boolean e.g., TRUE FALSE 1111 0000 To represent: Application specific e.g., RED  1 GREEN  3 BLUE  2 YELLOW  4 … Can we use less than 1 byte/code? Yes, SQL Server uses bit for boolean.

7 CpSc 862Note #37 Dates e.g.: - Integer, # days since Jan 1, 1900 - 8 characters, YYYYMMDD - 7 characters, YYYYDDD Time e.g. - Integer, seconds since midnight - characters, HHMMSSFF Date & time: floating Point To represent:

8 CpSc 862Note #38 String of characters –Null terminated e.g., –Length given e.g., - Fixed length ctacta 3 To represent:

9 CpSc 862Note #39 Bag of bits LengthBits To represent:

10 CpSc 862Note #310 Key Point Fixed length items Variable length items  usually length given at beginning Type of an item:  Tells us how to interpret (plus size if fixed)

11 CpSc 862Note #311 Data Items Records Blocks Files Memory Overview

12 CpSc 862Note #312 Record - Collection of related data items (called FIELDS) E.g.: Employee record: name field, salary field, date-of-hire field,...

13 CpSc 862Note #313 Types of records: Main choices: –FIXED vs VARIABLE FORMAT –FIXED vs VARIABLE LENGTH

14 CpSc 862Note #314 A SCHEMA (not record) contains following information - # fields - type of each field - order in record - meaning of each field Fixed format

15 CpSc 862Note #315 Example: fixed format and length Employee record (1) E#, 2 byte integer (2) E.name, 10 char.Schema (3) Dept, 2 byte code 55 s m i t h 02 83 j o n e s 01 Records

16 CpSc 862Note #316 Record itself contains format “Self Describing” Variable format

17 CpSc 862Note #317 Example: variable format and length 4I524SDROF46 Field name codes could also be strings, i.e. TAGS # Fields Code identifying field as E# Integer type Code for Ename String type Length of str.

18 CpSc 862Note #318 Variable format useful for: “sparse” records repeating fields evolving formats But may waste space...

19 CpSc 862Note #319 EXAMPLE: var format record with repeating fields Employee  one or more  children 3E_name: FredChild: SallyChild: Tom

20 CpSc 862Note #320 Note: Repeating fields does not imply - variable format, nor - variable size JohnSailingChess-- Key is to allocate maximum number of repeating fields (if not used  null)

21 CpSc 862Note #321 Many variants between fixed - variable format: Ex. #1: Include record type in record recordtype record length tells me what to expect (i.e. points to schema) 527....

22 CpSc 862Note #322 Record header - data at beginning that describes record May contain: - record type - record length - time stamp - other stuff...

23 CpSc 862Note #323 Ex #2 of variant between FIXED/VAR format Hybrid format –one part is fixed, other variable E.g.: All employees have E#, name, dept other fields vary. 25SmithToy2retiredHobby:chess # of var fields

24 CpSc 862Note #324 Question: We have seen examples for * Fixed format and length records * Variable format and length records (a) Does fixed format and variable length make sense? (b) Does variable format and fixed length make sense?

25 CpSc 862Note #325 Other interesting issues: Compression –within record - e.g. code selection –collection of records - e.g. find common patterns Encryption

26 CpSc 862Note #326 Next: placing records into blocks blocks... a file assume fixed length blocks assume a single file (for now)

27 CpSc 862Note #327 (1) separating records (2) spanned vs. unspanned (3) mixed record types – clustering (4) split records (5) sequencing (6) indirection Options for storing records in blocks:

28 CpSc 862Note #328 Block (a) no need to separate - fixed size recs. (b) special marker (c) give record lengths (or offsets) - within each record - in block header (1) Separating records R2R1R3

29 CpSc 862Note #329 Unspanned: records must be within one block block 1 block 2... Spanned block 1 block 2... (2) Spanned vs. Unspanned R1R2 R1 R3R4R5 R2 R3 (a) R3 (b) R6R5R4 R7 (a)

30 CpSc 862Note #330 need indication of partial recordof continuation “pointer” to rest(+ from where?) R1R2 R3 (a) R3 (b) R6R5R4 R7 (a) With spanned records:

31 CpSc 862Note #331 Unspanned is much simpler, but may waste space… Spanned essential if record size > block size Spanned vs. unspanned:

32 CpSc 862Note #332 Example 10 6 records each of size 2,050 bytes (fixed) block size = 4096 bytes block 1 block 2 2050 bytes wasted 2046 2050 bytes wasted 2046 R1R2 Total wasted = 2 x 10 9 Utiliz = 50% Total space = 4 x 10 9

33 CpSc 862Note #333 Mixed - records of different types (e.g. EMPLOYEE, DEPT) allowed in same block e.g., a block (3) Mixed record types EMP e1 DEPT d1 DEPT d2

34 CpSc 862Note #334 Why do we want to mix? Answer: CLUSTERING Records that are frequently accessed together should be in the same block

35 CpSc 862Note #335 Compromise: No mixing, but keep related records in same cylinder...

36 CpSc 862Note #336 Example Q1: select A#, C_NAME, C_CITY, … from DEPOSIT, CUSTOMER where DEPOSIT.C_NAME = CUSTOMER.C.NAME a block CUSTOMER,NAME=SMITH DEPOSIT,NAME=SMITH

37 CpSc 862Note #337 If Q1 frequent, clustering good But if Q2 frequent Q2: SELECT * FROM CUSTOMER CLUSTERING IS COUNTER PRODUCTIVE

38 CpSc 862Note #338 Fixed part in one block Typically for hybrid format Variable part in another block (4) Split records

39 CpSc 862Note #339 Block with fixed recs. R1 (a) R1 (b) Block with variable recs. R2 (a) R2 (b) R2 (c) This block also has fixed recs.

40 CpSc 862Note #340 Question What is difference between - Split records - Simply using two different record types?

41 CpSc 862Note #341 Ordering records in file (and block) by some key value Sequential file (  sequenced) (5) Sequencing

42 CpSc 862Note #342 Why sequencing? Typically to make it possible to efficiently read records in order (e.g., to do a merge-join)

43 CpSc 862Note #343 Sequencing Options (a) Next record physically contiguous... (b) Linked Next (R1)R1 Next (R1)

44 CpSc 862Note #344 (c)Overflow area Records in sequence R1 R2 R3 R4 R5 Sequencing Options header R2.1 R1.3 R4.7

45 CpSc 862Note #345 How does one refer to records? (6) Indirection Rx Many options: PhysicalIndirect

46 CpSc 862Note #346 Purely Physical Device ID E.g., RecordCylinder # Address=Track # or IDBlock # Offset in block Block ID

47 CpSc 862Note #347 Fully Indirect E.g., Record ID is arbitrary bit string map rec ID raddress a Physical addr. Rec ID

48 CpSc 862Note #348 Tradeoff Flexibility Cost to move recordsof indirection (for deletions, insertions)

49 CpSc 862Note #349 Physical Indirect Many options in between …

50 CpSc 862Note #350 Ex #1 Indirection in block Header A block:Free space R3 R4 R1R2

51 CpSc 862Note #351 Block header - data at beginning that describes block May contain: - File ID (or RELATION or DB ID) - This block ID - Record directory - Pointer to free space - Type of block (e.g. contains recs type 4; is overflow, …) - Pointer to other blocks “like it” - Timestamp...

52 CpSc 862Note #352 Ex. #2 Use logical block #’s understood by file system REC ID File ID Block # Record # or Offset File ID,Physical Block #Block ID File Syst. Map

53 CpSc 862Note #353 File system map may be “Semi-physical”… File F1: physical address of block 1 table of bad blocks: B57  XXX B107  YYY Rest can be computed via formula...

54 CpSc 862Note #354 (1) Separating records (2) Spanned vs. Unspanned (3) Mixed record types - Clustering (4) Split records (5) Sequencing (6) Indirection Options for storing records in blocks

55 CpSc 862Note #355 (1) Insertion/Deletion (2) Buffer Management (3) Comparison of Schemes Other Topics

56 CpSc 862Note #356 Block Deletion Rx

57 CpSc 862Note #357 Options: (a)Immediately reclaim space (b)Mark deleted –May need chain of deleted records (for re-use) –Need a way to mark: special characters delete field in map

58 CpSc 862Note #358 As usual, many tradeoffs... How expensive is to move valid record to free space for immediate reclaim? How much space is wasted? –e.g., deleted records, delete fields, free space chains,...

59 CpSc 862Note #359 Dangling pointers Concern with deletions R1?

60 CpSc 862Note #360 Solution #1: Do not worry

61 CpSc 862Note #361 E.g., Leave “MARK” in map or old location Solution #2: Tombstones Physical IDs A block This spaceThis space can never re-usedbe re-used

62 CpSc 862Note #362 Logical IDs IDLOC 7788 map Never reuse ID 7788 nor space in map... E.g., Leave “MARK” in map or old location Solution #2: Tombstones

63 CpSc 862Note #363 Place record ID within every record When you follow a pointer, check if it leads to correct record Solution #3 (?): Does this work??? If space reused, won’t new record have same ID? to 3-77 rec-id: 3-77

64 CpSc 862Note #364 To point, use (pointer + hash) or (pointer + key)? Solution #4 (?): What if record modified??? ptr+ hash key

65 CpSc 862Note #365 Easy case: records not in sequence  Insert new record at end of file or in deleted slot  If records are variable size, not as easy... Insert

66 CpSc 862Note #366 Hard case: records in sequence  If free space “close by”, not too bad...  Or use overflow idea... Insert

67 CpSc 862Note #367 Interesting problems: How much free space to leave in each block, track, cylinder? How often do I reorganize file + overflow?

68 CpSc 862Note #368 Free space

69 CpSc 862Note #369 DB features needed Why LRU may be bad Pinned blocks Forced output Double buffering Swizzling Buffer Management

70 CpSc 862Note #370 Swizzling Memory Disk Rec A block 1 Rec A block 2 block 1

71 CpSc 862Note #371 TranslationDB Addr Mem Addr Table Rec-A Rec-A-inMem One Option:

72 CpSc 862Note #372 In memory pointers - need “type” bit to disk to memory M Another Option:

73 CpSc 862Note #373 Swizzling Automatic On-demand No swizzling / program control

74 CpSc 862Note #374 There are 10,000,000 ways to organize my data on disk… Which is right for me? Comparison

75 CpSc 862Note #375 Issues: FlexibilitySpace Utilization ComplexityPerformance

76 CpSc 862Note #376 To evaluate a given strategy, compute following parameters: -> space used for expected data -> expected time to - fetch record given key - fetch record with next key - insert record - append record - delete record - update record - read all file - reorganize file

77 CpSc 862Note #377 Example How would you design SuperGRES storage system? (for a relational DB, low end) –Variable length records? –Spanned? –What data types? –Fixed format? –Record IDs ? –Sequencing? –How to handle deletions?

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