Relational Databases and SQLite Charles Severance Python for

Relational Databases and SQLite Charles Severance Python for Everybody www.py4e.com/lectures3/

SQLite Browser http://sqlitebrowser.org/

OLD Sorted Sequential Master Update 1970s NEW Sorted Merg e Transactio ns Sorted https://en.wikipedia.org/wiki/IBM 729

Random Access When you can randomly access data. How can you layout data to be most efficient? Sorting might not be the best idea https://en.wikipedia.org/wiki/Hard disk drive platter

Relational Databases Relational databases model data by storing rows and columns in tables. The power of the relational database lies in its ability to efficiently retrieve data from those tables and in particular where there are multiple tables and the relationships between those tables involved in the query. http://en.wikipedia.org/wiki/Relational database

Terminology Database - contains many tables Relation (or table) - contains tuples and attributes Tuple (or row) - a set of fields that generally represents an “object” like a person or a music track Attribute (also column or field) - one of possibly many elements of data corresponding to the object represented by the row

A relation is defined as a set of tuples that have the same attributes. A tuple usually represents an object and information about that object. Objects are typically physical objects or concepts. A relation is usually described as a table, which is organized into rows and columns. All the data referenced by an attribute are in the same domain and conform to the same constraints. (Wikipedia)

Columns / Attributes Rows / Tuples Tables / Relations

SQL Structured Query Language is the language we use to issue commands to the database - Create data (a.k.a Insert) - Retrieve data - Update data - Delete data http://en.wikipedia.org/wiki/SQL

Input Files Python Programs R Excel Database File SQL Output Files You D3.js SQL SQLite Browser

Web Applications w/ Databases Application Developer - Builds the logic for the application, the look and feel of the application - monitors the application for problems Database Administrator - Monitors and adjusts the database as the program runs in production Often both people participate in the building of the “Data model”

End User Application Software SQL Database Data Server SQL Developer DBA Database Tools

Database Administrator A database administrator (DBA) is a person responsible for the design, implementation, maintenance, and repair of an organization’s database. The role includes the development and design of database strategies, monitoring and improving database performance and capacity, and planning for future expansion requirements. They may also plan, coordinate, and implement security measures to safeguard the database. http://en.wikipedia.org/wiki/Database administrator

Database Model A database model or database schema is the structure or format of a database, described in a formal language supported by the database management system. In other words, a “database model” is the application of a data model when used in conjunction with a database management system. http://en.wikipedia.org/wiki/Database model

Common Database Systems Three major Database Management Systems in wide use - Oracle - Large, commercial, enterprise-scale, very very tweakable - MySql - Simpler but very fast and scalable - commercial open source - SqlServer - Very nice - from Microsoft (also Access) Many other smaller projects, free and open source - HSQL, SQLite, Postgres, .

SQLite is in Lots of Software. http://www.sqlite.org/famous.html

SQLite Browser SQLite is a very popular database - it is free and fast and small SQLite Browser allows us to directly manipulate SQLite files http://sqlitebrowser.org/ SQLite is embedded in Python and a number of other languages

http://sqlitebrowser.org/

Lets Make a Database https://www.py4e.com/lectures3/Pythonlearn-15-Database-Handout.txt

Start Simple - A Single Table CREATE TABLE Users( name VARCHAR(128), email VARCHAR(128) )

Our table with four rows

SQL Structured Query Language is the language we use to issue commands to the database - Create data (a.k.a Insert) - Retrieve data - Update data - Delete data http://en.wikipedia.org/wiki/SQL

SQL: Insert The Insert statement inserts a row into a table INSERT INTO Users (name, email) VALUES ('Kristin', '[email protected]')

SQL: Delete Deletes a row in a table based on selection criteria DELETE FROM Users WHERE email '[email protected]'

SQL: Update Allows the updating of a field with a where clause UPDATE Users SET name 'Charles' WHERE email '[email protected]'

Retrieving Records: Select The select statement retrieves a group of records - you can either retrieve all the records or a subset of the records with a WHERE clause SELECT * FROM Users SELECT * FROM Users WHERE email '[email protected]'

Sorting with ORDER BY You can add an ORDER BY clause to SELECT statements to get the results sorted in ascending or descending order SELECT * FROM Users ORDER BY email SELECT * FROM Users ORDER BY name DESC

SQL Summary INSERT INTO Users (name, email) VALUES ('Kristin', '[email protected]') DELETE FROM Users WHERE email '[email protected]' UPDATE Users SET name "Charles" WHERE email '[email protected]' SELECT * FROM Users SELECT * FROM Users WHERE email '[email protected]' SELECT * FROM Users ORDER BY email

This is not too exciting (so far) Tables pretty much look like big fast programmable spreadsheets with rows, columns, and commands The power comes when we have more than one table and we can exploit the relationships between the tables

Complex Data Models and Relationships http://en.wikipedia.org/wiki/Relational model

Database Design Database design is an art form of its own with particular skills and experience Our goal is to avoid the really bad mistakes and design clean and easily understood databases Others may performance tune things later Database design starts with a picture.

Building a Data Model Drawing a picture of the data objects for our application and then figuring out how to represent the objects and their relationships Basic Rule: Don’t put the same string data in twice - use a relationship instead When there is one thing in the “real world” there should be one copy of that thing in the database

Track Len Artist Album Genre Rating Count

For each “piece of info”. Is the column an object or an attribute of another object? Once we define objects, we need to define the relationships between objects Len Album Genre Artist Track Rating Count

Track Album Artist Genre Rating Len Count

Track Album Artist Genre Track Artist belongs-to Album belongs-to Rating Len Count Rating Len Count Genre belongs-to

Track Artist belongs-to Album belongs-to Genre Rating Len Count belongs-to

Representing Relationships in a Database

Database Normalization (3NF) There is *tons* of database theory - way too much to understand without excessive predicate calculus Do not replicate data - reference data - point at data Use integers for keys and for references Add a special “key” column to each table which we will make references to. By convention, many programmers call this column “id” http://en.wikipedia.org/wiki/Database normalization

We want to keep track of which band is the “creator” of each music track. What album does this song “belong to”? Which album is this song related to?

Integer Reference Pattern Artist We use integers to reference rows in another table Album

Three Kinds of Keys Primary key - generally an integer autoincrement field Logical key - What the outside world uses for lookup Foreign key - generally an integer key pointing to a row in another table Album id title artist id .

Key Rules Best practices Never use your logical key as the primary key Logical keys can and do change, albeit slowly Relationships that are based on matching string fields are less efficient than integers User id login password name email created at modified at login at

Foreign Keys A foreign key is when a table has a column that contains a key which points to the primary key of another table. When all primary keys are integers, then all foreign keys are integers - this is good - very good Artist id name . Album id title artist id .

Relationship Building (in tables)

Track Rating Len Count Artist belongs-to Album belongs-to Genre belongs-to

belongs-to Album Album Table Primary key Logical key Foreign key id title Track Title Rating Len Count Track id title rating len count album id

Artist id name Table Primary key Logical key Foreign key Naming FK artist id is a convention Track Album id title artist id Genre id name id title rating len count album id genre id

CREATE TABLE Genre ( id INTEGER NOT NULL PRIMARY KEY AUTOINCREMENT UNIQUE, name TEXT )

CREATE TABLE Album ( id INTEGER NOT NULL PRIMARY KEY AUTOINCREMENT UNIQUE, artist id INTEGER, title TEXT ) CREATE TABLE Track ( id INTEGER NOT NULL PRIMARY KEY AUTOINCREMENT UNIQUE, title TEXT, album id INTEGER, genre id INTEGER, len INTEGER, rating INTEGER, count INTEGER )

insert into Artist (name) values ('Led Zepplin') insert into Artist (name) values ('AC/DC')

insert into Artist (name) values ('Led Zepplin') insert into Artist (name) values ('AC/DC')

insert into Genre (name) values ('Rock') insert into Genre (name) values ('Metal')

insert into Album (title, artist id) values ('Who Made Who', 2) insert into Album (title, artist id) values ('IV', 1)

insert into values insert into values insert into values insert into values Track (title, rating, len, count, album id, ('Black Dog', 5, 297, 0, 2, 1) Track (title, rating, len, count, album id, ('Stairway', 5, 482, 0, 2, 1) Track (title, rating, len, count, album id, ('About to Rock', 5, 313, 0, 1, 2) Track (title, rating, len, count, album id, ('Who Made Who', 5, 207, 0, 1, 2) genre id) genre id) genre id) genre id)

Track Album Genre Artist

Using Join Across Tables http://en.wikipedia.org/wiki/Join (SQL)

Relational Power By removing the replicated data and replacing it with references to a single copy of each bit of data we build a “web” of information that the relational database can read through very quickly - even for very large amounts of data Often when you want some data it comes from a number of tables linked by these foreign keys

The JOIN Operation The JOIN operation links across several tables as part of a select operation You must tell the JOIN how to use the keys that make the connection between the tables using an ON clause

Album Artist select Album.title, Artist.name from Album join Artist on Album.artist id Artist.id What we want to see The tables that hold the data How the tables are linked

select Album.title, Album.artist id, Artist.id,Artist.name from Album join Artist on Album.artist id Artist.id

SELECT Track.title, Track.genre id, Genre.id, Genre.name FROM Track JOIN Genre Joining two tables without an ON clause gives all possible combinations of rows.

select Track.title, Genre.name from Track join Genre on Track.genre id Genre.id What we want to see The tables that hold the data How the tables are linked

select Track.title, Artist.name, Album.title, Genre.name from Track join Genre join Album join Artist on Track.genre id Genre.id and Track.album id Album.id and Album.artist id Artist.id What we want to see The tables which hold the data How the tables are linked

Many-To-Many Relationships https://en.wikipedia.org/wiki/Many-to-many (data model)

belongs-to Track Title Rating Len Count Album One Table Primary key Logical key Foreign key Many Album id title Review: One to Many Track id title One https://en.wikipedia.org/wiki/One-to-many (data model) Many rating len count album id

One One Many https://en.wikipedia.org/wiki/One-to-many (data model) Many

Many to Many Sometimes we need to model a relationship that is many-to-many We need to add a "connection" table with two foreign keys There is usually no separate primary key https://en.wikipedia.org/wiki/Many-to-many (data model)

member-of Course title Course id title Many Many User name email User Member Many One user id course id Many https://en.wikipedia.org/wiki/Many-to-many (data model) One id name email

CREATE TABLE User ( id INTEGER PRIMARY KEY, name TEXT UNIQUE, email TEXT ) CREATE TABLE Course ( id INTEGER PRIMARY KEY, title TEXT UNIQUE ) CREATE TABLE Member ( user id INTEGER, course id INTEGER, role INTEGER, PRIMARY KEY (user id, course id) ) Start with a Fresh Database

Insert Users and Courses INSERT INTO User (name, email) VALUES ('Jane', '[email protected]'); INSERT INTO User (name, email) VALUES ('Ed', '[email protected]'); INSERT INTO User (name, email) VALUES ('Sue', '[email protected]'); INSERT INTO Course (title) VALUES ('Python'); INSERT INTO Course (title) VALUES ('SQL'); INSERT INTO Course (title) VALUES ('PHP');

INSERT INTO Member (user id, course id, role) VALUES (1, 1, 1); INSERT INTO Member (user id, course id, role) VALUES (2, 1, 0); INSERT INTO Member (user id, course id, role) VALUES (3, 1, 0); INSERT INTO Member (user id, course id, role) VALUES (1, 2, 0); INSERT INTO Member (user id, course id, role) VALUES (2, 2, 1); INSERT INTO Member (user id, course id, role) VALUES (2, 3, 1); INSERT INTO Member (user id, course id, role) VALUES (3, 3, 0);

SELECT User.name, Member.role, Course.title FROM User JOIN Member JOIN Course ON Member.user id User.id AND Member.course id Course.id ORDER BY Course.title, Member.role DESC, User.name

www.tsugi.org

Complexity Enables Speed Complexity makes speed possible and allows you to get very fast results as the data size grows By normalizing the data and linking it with integer keys, the overall amount of data which the relational database must scan is far lower than if the data were simply flattened out It might seem like a tradeoff - spend some time designing your database so it continues to be fast when your application is a success

Additional SQL Topics Indexes improve access performance for things like string fields Constraints on data - (cannot be NULL, etc.) Transactions - allow SQL operations to be grouped and done as a unit

Summary Relational databases allow us to scale to very large amounts of data The key is to have one copy of any data element and use relations and joins to link the data to multiple places This greatly reduces the amount of data which much be scanned when doing complex operations across large amounts of data Database and SQL design is a bit of an art form

Acknowledgements / Contributions These slides are Copyright 2010- Charles R. Severance ( www.dr-chuck.com) of the University of Michigan School of Information and open.umich.edu and made available under a Creative Commons Attribution 4.0 License. Please maintain this last slide in all copies of the document to comply with the attribution requirements of the license. If you make a change, feel free to add your name and organization to the list of contributors on this page as you republish the materials. Initial Development: Charles Severance, University of Michigan School of Information Insert new Contributors here .