Presentation is loading. Please wait.

Presentation is loading. Please wait.

CS 44321 CS4432: Database Systems II Record and Page Formats Chapter 12.

Published byIris Young Modified over 8 years ago

Similar presentations

Presentation on theme: "CS 44321 CS4432: Database Systems II Record and Page Formats Chapter 12."— Presentation transcript:

1 CS 44321 CS4432: Database Systems II Record and Page Formats Chapter 12

2 CS 44322 Data Items Records Blocks Files Memory Overview

3 CS 44323 What are the data items we want to store? a salary a name a picture What we have available: Bytes 8 bits

4 CS 44324 To represent: Integer (short): 2 bytes e.g., 35 is 0000000000100011

5 CS 44325 Boolean e.g., TRUE FALSE 1111 0000 To represent: Enumeration types: e.g., RED  1 GREEN  3 BLUE  2 YELLOW  4 … Can we use less than 1 byte/code? Yes, but only if desperate...

6 CS 44326 Characters  Various coding schemes suggested (ASCII) To represent: Example: A: 1000001 a: 1100001 5: 0110101 LF: 0001010

7 CS 44327 –Null terminated e.g., –Length given e.g., -Fixed length e.g., In Oracle define the string length. e.g., name CHAR(20), ctacta3 To represent: String of characters

8 CS 44328 Key Points Fixed length items Variable length items - usually length given at beginning Type of an item : - tells us how to interpret (plus size if fixed)

9 CS 44329 Data Items Records Blocks Files Memory Overview

10 CS 443210 Record - Collection of related data items (called FIELDS) E.g.: Employee record: name CHAR (20), salary NUMBER, date-of-hire DATE,...

11 CS 443211 Types of records: Main choices: –FIXED vs VARIABLE FORMAT –FIXED vs VARIABLE LENGTH

12 CS 443212 A SCHEMA contains information such as: - # fields (attributes) - type of each field (length) - order of attributes in record - meaning of each field (domain) - constraints (primary key, etc). Fixed format Not associated with each record.

13 CS 443213 Example: fixed format & fixed length Employee record (1) E.id, 2 byte integer (2) E.name, 10 char. Schema (3) Dept, 2 byte code We can simply concatenate fields. 55 s m i t h 02 83 j o n e s 01 Records

14 CS 443214 What : –Not all fields are included in the record, –and/or, fields possibly in different orders. Then : –Record itself must contain format, i.e., it is “self-describing”: Variable format

15 CS 443215 Why Variable Format ? “sparse” records repeating fields evolving formats

16 CS 443216 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.

17 CS 443217 EXAMPLE: variable format record with repeating fields e.g., Employee has one or more children 3E_name: FredChild: SallyChild: Tom Do repeating fields always require variable format and length?

18 CS 443218 Example : a person and her hobbies. MarySailingChess-- Then allocate maximum number of repeating fields If not used, set to null Repeating fields with fixed format & length

19 CS 443219 Many variants between fixed - variable format: Example1: Include record type in record recordtype record length tells me what to expect (i.e., points to schema) 527....

20 CS 443220 Record header - data at beginning that describes record May contain: - pointer to schema (record type) - length of record - time stamp (create time, mod. time) - other stuff (e.g., ROW-ID in Oracle)

21 CS 443221 Example2: Variant btw FIXED/VAR format Hybrid format : one part is fixed, other is variable E.g.: All employees have E#, name, dept; and other fields vary. 25SmithToy2retiredHobby:chess # of var fields

22 CS 443222 Also, many variations in internal organization of record Just to show one: length of field 3F310F1 5 F212 * * * 33251520F1F2F3 total size offsets 0 1 2 3 4 5 15 20

23 CS 443223 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?

24 CS 443224 Data Items Records Blocks Files Memory Next:

25 CS 443225 Goal : placing records into blocks blocks... a file assume fixed length blocks assume a single file (for now) records

26 CS 443226 (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:

27 CS 443227 Block (a) no need to separate if fixed size records. (b) or, use special marker (c) or, give record lengths (or offsets) - within each record - in block header (1) Separating records R2R1R3

28 CS 443228 Unspanned: records within one block block 1 block 2... Spanned : records wrap across 2 blocks block 1 block 2... (2) Spanned vs. Unspanned R1R2 R1 R3R4R5 R2 R3 (a) R3 (b) R6R5R4 R7 (a)

29 CS 443229 Unspanned is much simpler, but may waste space… Spanned essential if record size > block size Spanned vs. unspanned:

30 CS 443230 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 Utiliz = 50% -> ½ of space is wasted

31 CS 443231 Mixed - records of different types (e.g., EMPLOYEE, DEPT) allowed in same block e.g., a block (3) Mixed versus uniform record types EMP e1 DEPT d1 DEPT d2

32 CS 443232 Why do we want to mix? Answer: CLUSTERING Records that are frequently accessed together should be placed into the same block Problems Creates variable length records in block Aim to avoid duplicates (how to cluster?) Insert/deletes are harder

33 CS 443233 Example Clustering Q1: select C_NAME, C_CITY, AMOUNT, … from DEPOSIT, CUSTOMER where DEPOSIT.C_NAME = CUSTOMER.C.NAME a block layout: CUSTOMER,NAME=SMITH DEPOSIT,NAME=SMITH CUSTOMER,NAME=JONES Question: Good idea or bad idea ?

34 CS 443234 If Q1 frequent with join on customer and deposit relations, then clustering good But if instead Q2 frequent with : Q2: SELECT * FROM CUSTOMER then clustering is counter-productive

35 CS 443235 Compromise: No mixing, but keep related records in same cylinder...

36 CS 443236 (1) Separating records (2) Spanned vs. Unspanned (3) Mixed record types - Clustering (4) Split records (5) Sequencing (6) Indirection So Far: Storing records in blocks

37 CS 443237 (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:

38 CS 443238 Fixed part in one block Typically for hybrid format Variable part in another block (4) Split records

39 CS 443239 Block with fixed recs. R1 (a) R1 (b) Block with variable recs. R2 (a) R2 (b) R2 (c)

40 CS 443240 Ordering records in file (and block) by some key value –Sequential file ( -  sequenced file) Why sequencing ? –Typically to make it possible to efficiently read records in order (5) Sequencing

41 CS 443241 Sequencing Options (a) Next record physically contiguous... (b) Linked What about INSERT/ DELETE ? Next (R1)R1 Next (R1)

42 CS 443242 (c)Overflow area Records in sequence R1 R2 R3 R4 R5 Sequencing Options header R2.1 R1.3 R4.7

43 CS 443243 How does one refer to records? Problem: Records can be on disk or in (virtual) memory. Need common address, but have different physical locations. (6) Indirection Addressing Rx Many options: PhysicalIndirect

44 CS 443244 Purely Physical Addressing Device ID E.g., RecordCylinder # Address=Track # ( ID ) Block # Offset in block Block ID

45 CS 443245 Fully Indirect Addressing Solution: Record ID (Oracle: ROWID) as global address, maintain a map table. Map Table rec ID raddress a Physical addr. Rec ID

46 CS 443246 Tradeoff Flexibility Cost to move recordsof indirection (for deletions, insertions) (lookup) What to do : Options inbetween ? Physical Indirect

47 CS 443247 Ex #1 : Indirection in block Block Header A block:Free space R3 R4 R1R2

48 CS 443248 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...

49 CS 443249 Ex. #2 Use logical block #’s understood by file system instead of direct disk access REC ID File ID Block # Record # or Offset File ID,Physical Block #Block ID File System Map

50 CS 443250 (1) Separating records (2) Spanned vs. Unspanned (3) Mixed record types - Clustering (4) Split records (5) Sequencing (6) Indirection Recap: Storing records in blocks

51 CS 443251 (1) Insertion/Deletion (2) Buffer Management (3) Comparison of Schemes Other Topics in Chapter 12

52 CS 443252 Block Deletion Rx

53 CS 443253 Options: (a)Deleted and 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

54 CS 443254 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,...

55 CS 443255 Dangling pointers Note: If pointers point to physical locations (rather than ROWIDs), storing new data in deleted block corrupts data. Concern with deletions R1?

56 CS 443256 Solution #1: Do not worry

57 CS 443257 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

58 CS 443258 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

59 CS 443259 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

60 CS 443260 Easy case: Records fixed length/not in sequence  Insert new record at end of file  or, in deleted slot A little harder:  If records are variable size, not as easy  may not be able to reuse space – fragmentation Hard case: records in sequence  If free space “close by”, not too bad...  Or, use overflow idea...  Or worst case, reorganize file... Insert

61 CS 443261 Interesting problems: How much free space to leave in each block, track, cylinder? How often do I reorganize file + overflow? Free space

62 CS 443262 DB features needed Why LRU may be bad Read Pinned blocks Textbook! Forced output Double buffering Swizzling Buffer Management

63 CS 443263 Pointer Swizzling Memory Disk Rec A block 1 Rec A block 2 block 1 Issue : If records (objects) contain pointers to other objects, translate locations when load objects into memory.

64 CS 443264 TranslationDB Addr Mem Addr Table Rec-A Rec-A-inMem One Option: Solution: Insert fields that represent pointers into map table. Translate pointers as needed.

65 CS 443265 In memory pointers - need “type” bit to disk to memory M Another Option:

66 CS 443266 Swizzling Issues Automatic On-demand No swizzling / program control Swizzling Options Must ‘unswizzle’ Updating/writing of records

67 CS 443267 There are 1,000,001 ways to organize my data on disk… Which is right for me? Comparison

68 CS 443268 Issues: FlexibilitySpace Utilization ComplexityPerformance

69 CS 443269 To evaluate a given strategy, compute following parameters: -> space used for expected data - on average -> expected time to : - fetch record given key - fetch record with next key - insert/delete/update record - read complete file - reorganize file (maybe sort) -> usage patterns / workload: - how many/which user queries/updates

70 CS 443270 Chapter 13 in book How to find a record quickly, given a key NEXT

Download ppt "CS 44321 CS4432: Database Systems II Record and Page Formats Chapter 12."

Similar presentations

Disk Storage, Basic File Structures, and Hashing

Disk Storage, Basic File Structures, and Hashing
CS 245Notes 31 (1) Insertion/Deletion (2) Buffer Management (3) Comparison of Schemes Other Topics.

CS 245Notes 31 (1) Insertion/Deletion (2) Buffer Management (3) Comparison of Schemes Other Topics.
Dr. Kalpakis CMSC 661, Principles of Database Systems Representing Data Elements [12]

Dr. Kalpakis CMSC 661, Principles of Database Systems Representing Data Elements [12]
CS4432: Database Systems II Hash Indexing 1. Hash-Based Indexes Adaptation of main memory hash tables Support equality searches No range searches 2.

CS4432: Database Systems II Hash Indexing 1. Hash-Based Indexes Adaptation of main memory hash tables Support equality searches No range searches 2.
1 Introduction to Database Systems CSE 444 Lectures 19: Data Storage and Indexes November 14, 2007.

1 Introduction to Database Systems CSE 444 Lectures 19: Data Storage and Indexes November 14, 2007.
Tuples vs. Records CREAT TABLE MovieStar ( Name CHAR (30), Address VARCHAR (255), Gender CHAR (1), DataOfBirth Date ); Tuples are similar to records or.

Tuples vs. Records CREAT TABLE MovieStar ( Name CHAR (30), Address VARCHAR (255), Gender CHAR (1), DataOfBirth Date ); Tuples are similar to records or.
Advance Database System

Advance Database System
Fall 2004 ECE569 Lecture 03-2.1 ECE 569 Database System Engineering Fall 2004 Yanyong Zhang www.ece.rutgers.edu/~yyzhangwww.ece.rutgers.edu/~yyzhang Course.

Fall 2004 ECE569 Lecture ECE 569 Database System Engineering Fall 2004 Yanyong Zhang Course.
CS 277 – Spring 2002Notes 31 CS 277: Database System Implementation Notes 03: Disk Organization Arthur Keller.

CS 277 – Spring 2002Notes 31 CS 277: Database System Implementation Notes 03: Disk Organization Arthur Keller.
Database Implementation Issues CPSC 315 – Programming Studio Spring 2008 Project 1, Lecture 5 Slides adapted from those used by Jennifer Welch.

Database Implementation Issues CPSC 315 – Programming Studio Spring 2008 Project 1, Lecture 5 Slides adapted from those used by Jennifer Welch.
CS 4432lecture #61 CS4432: Database Systems II Lecture #6 Professor Elke A. Rundensteiner.

CS 4432lecture #61 CS4432: Database Systems II Lecture #6 Professor Elke A. Rundensteiner.
Recap of Feb 27: Disk-Block Access and Buffer Management Major concepts in Disk-Block Access covered: –Disk-arm Scheduling –Non-volatile write buffers.

Recap of Feb 27: Disk-Block Access and Buffer Management Major concepts in Disk-Block Access covered: –Disk-arm Scheduling –Non-volatile write buffers.
CS 245Notes 31 CS 245: Database System Principles Notes 03: Disk Organization Hector Garcia-Molina.

CS 245Notes 31 CS 245: Database System Principles Notes 03: Disk Organization Hector Garcia-Molina.
METU Department of Computer Eng Ceng 302 Introduction to DBMS Disk Storage, Basic File Structures, and Hashing by Pinar Senkul resources: mostly froom.

METU Department of Computer Eng Ceng 302 Introduction to DBMS Disk Storage, Basic File Structures, and Hashing by Pinar Senkul resources: mostly froom.
CS 4432lecture #41 CS4432: Database Systems II Lecture #5 Professor Elke A. Rundensteiner.

CS 4432lecture #41 CS4432: Database Systems II Lecture #5 Professor Elke A. Rundensteiner.
Copyright © 2007 Ramez Elmasri and Shamkant B. Navathe Chapter 13 Disk Storage, Basic File Structures, and Hashing.

Copyright © 2007 Ramez Elmasri and Shamkant B. Navathe Chapter 13 Disk Storage, Basic File Structures, and Hashing.
CS 245Notes 51 CS 245: Database System Principles Hector Garcia-Molina Notes 5: Hashing and More.

CS 245Notes 51 CS 245: Database System Principles Hector Garcia-Molina Notes 5: Hashing and More.
CS 4432lecture #71 CS4432: Database Systems II Lecture #7 Professor Elke A. Rundensteiner.

CS 4432lecture #71 CS4432: Database Systems II Lecture #7 Professor Elke A. Rundensteiner.
File Management.

File Management.
1.1 CAS CS 460/660 Introduction to Database Systems File Organization Slides from UC Berkeley.

1.1 CAS CS 460/660 Introduction to Database Systems File Organization Slides from UC Berkeley.

Similar presentations

Ads by Google