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Julia 1.0 Programming - Second Edition

By : Ivo Balbaert

3.5 (2)

Buy this Book

Julia 1.0 Programming

3.5 (2)

By: Ivo Balbaert

Buy this Book

Overview of this book

The release of Julia 1.0 is now ready to change the technical world by combining the high productivity and ease of use of Python and R with the lightning-fast speed of C++. Julia 1.0 programming gives you a head start in tackling your numerical and data problems. You will begin by learning how to set up a running Julia platform, before exploring its various built-in types. With the help of practical examples, this book walks you through two important collection types: arrays and matrices. In addition to this, you will be taken through how type conversions and promotions work. In the course of the book, you will be introduced to the homo-iconicity and metaprogramming concepts in Julia. You will understand how Julia provides different ways to interact with an operating system, as well as other languages, and then you'll discover what macros are. Once you have grasped the basics, you’ll study what makes Julia suitable for numerical and scientific computing, and learn about the features provided by Julia. By the end of this book, you will also have learned how to run external programs. This book covers all you need to know about Julia in order to leverage its high speed and efficiency for your applications.

Preface

Who this book is for

What this book covers

To get the most out of this book

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Free Chapter

Installing the Julia Platform

Installing Julia

Working with Julia's REPL

Startup options and Julia scripts

Packages

Installing and working with IJulia

Installing Juno

Installing julia-vscode

Installing Sublime-IJulia

Other editors and IDEs

How Julia works

Summary

Variables, Types, and Operations

Variables, naming conventions, and comments

Types

Integers

Floating point numbers

Elementary mathematical functions and operations

Rational and complex numbers

Characters

Strings

Regular expressions

Ranges and arrays

Dates and times

Scope and constants

Summary

Functions

Defining functions

Optional and keyword arguments

Anonymous functions

First-class functions and closures

functions

Broadcasting

Map, filter, and list comprehensions

Generic functions and multiple dispatch

Summary

Control Flow

Conditional evaluation

Repeated evaluation

Exception handling

Scope revisited

Tasks

Summary

Collection Types

Matrices

Tuples

Dictionaries

Sets

An example project – word frequency

Summary

More on Types, Methods, and Modules

Type annotations

The type hierarchy – subtypes and supertypes

Concrete and abstract types

User-defined and composite types

Types and collections – inner constructors

Type unions

Parametric types and methods

Standard modules and paths

Summary

Metaprogramming in Julia

Expressions and symbols

Evaluation and interpolation

Defining macros

Built-in macros

Reflection capabilities

Summary

I/O, Networking, and Parallel Computing

Basic input and output

Working with files

Using DataFrames

Working with TCP sockets and servers

Interacting with databases

Parallel operations and computing

Summary

Running External Programs

Running shell commands

Calling C and Fortran

Calling Python

Performance tips

Summary

The Standard Library and Packages

Digging deeper into the standard library

Julia's package manager

Graphics in Julia

Using Plots on data

Summary

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functions

Functions can be nested, as demonstrated in the following example:

function a(x) 
    z = x * 2 
    function b(z) 
        z += 1 
    end 
    b(z) 
end 
 
d = 5 
a(d) #=> 11

A function can also be recursive, that is, it can call itself. To show some examples, we need to be able to test a condition in code. The simplest way to do this in Julia is to use the ternary operator ? of the form expr ? b : c (ternary because it takes three arguments). Julia also has a normal if construct. (Refer to the Conditional evaluation section of Chapter 4, Control Flow.) expr is a condition and, if it is true, then b is evaluated and the value is returned, else c is evaluated. This is used in the following recursive definition to calculate the sum of all the integers up to and including a certain number: