Variables#
Variables store information that can be manipulated by the program. Fortran is a strongly typed language, which means that each variable must have a type.
There are 5 built-in data types in Fortran:
integer
– for data that represent whole numbers, positive or negativereal
– for floating-point data (not a whole number)complex
– pair consisting of a real part and an imaginary partcharacter
– for text datalogical
– for data that represent boolean (true or false) values
Before we can use a variable, we must declare it; this tells the compiler the variable type and any other variable attributes.
Fortran is a statically typed language, which means the type of each variable is fixed when the program is compiled—variable types cannot change while the program is running.
Declaring variables#
The syntax for declaring variables is:
<variable_type> :: <variable_name>, <variable_name>, ...
where <variable_type>
is one of the built-in variable types listed above and
<variable_name>
is the name that you would like to call your variable.
Variable names must start with a letter and can consist of letters, numbers and underscores. In the following example we declare a variable for each of the built-in types.
Example: variable declaration
program variables
implicit none
integer :: amount
real :: pi, e ! two `real` variables declared
complex :: frequency
character :: initial
logical :: isOkay
end program variables
Fortran code is case-insensitive; you don’t have to worry about the capitalisation of your variable names, but it’s good practice to keep it consistent.
Note the additional statement at the beginning of the program: implicit none
.
This statement tells the compiler that all variables will be explicitly declared; without
this statement variables will be implicitly typed according to the letter they begin with.
Always use the
implicit none
statement at the beginning of each program and procedure. Implicit typing is considered bad practice in modern programming since it hides information leading to more program errors.
Once we have declared a variable, we can assign and reassign values to it using the assignment operator =
.
Example: variable assignment
amount = 10
pi = 3.1415927
frequency = (1.0, -0.5)
initial = 'A'
isOkay = .false.
Characters are surrounded by either single ('
) or double quotes ("
).
Logical or boolean values can be either .true.
or .false.
.
Importante
Watch out for assignment at declaration:
integer :: amount = 1
This is NOT a normal initialisation; it implies the save
attribute, which means that the variable retains
its value between procedure calls. Good practice is to initialise your variables separately to their declaration.
Standard input / output#
In our Hello World example, we printed text to the command window.
This is commonly referred to as writing to standard output
or stdout
.
We can use the print
statement introduced earlier to print variable values to stdout
:
print *, 'The value of amount (integer) is: ', amount
print *, 'The value of pi (real) is: ', pi
print *, 'The value of frequency (complex) is: ', frequency
print *, 'The value of initial (character) is: ', initial
print *, 'The value of isOkay (logical) is: ', isOkay
In a similar way, we can read values from the command window
using the read
statement:
program read_values
implicit none
real :: x, y
print *, 'Please enter two numbers. '
read(*,*) x, y
print *, 'The sum and product of the numbers are ', x+y, x*y
end program read_values
This input source is commonly referred to as standard input
or stdin
.
Expressions#
The usual set of arithmetic operators are available, listed in order of precedence:
Operator |
Descripción |
---|---|
|
Exponent |
|
Multiplication |
|
Division |
|
Addition |
|
Subtraction |
Example:
program arithmetic
implicit none
real :: pi, radius, height, area, volume
pi = 3.1415927
print *, 'Enter cylinder base radius:'
read(*,*) radius
print *, 'Enter cylinder height:'
read(*,*) height
area = pi * radius**2
volume = area * height
print *, 'Cylinder radius is: ', radius
print *, 'Cylinder height is: ', height
print *, 'Cylinder base area is: ', area
print *, 'Cylinder volume is: ', volume
end program arithmetic
Floating-point precision#
The desired floating-point precision can be explicitly declared using a kind
parameter.
The iso_fortran_env
intrinsic module provides kind
parameters for the common 32-bit and 64-bit floating-point types.
Example: explicit real kind
program float
use, intrinsic :: iso_fortran_env, only: sp=>real32, dp=>real64
implicit none
real(sp) :: float32
real(dp) :: float64
float32 = 1.0_sp ! Explicit suffix for literal constants
float64 = 1.0_dp
print*, float32, float64
end program float
Always use a
kind
suffix for floating-point literal constants.
Example: C-interoperable kind
program float
use, intrinsic :: iso_c_binding, only: sp=>c_float, dp=>c_double
implicit none
real(sp) :: float32
real(dp) :: float64
end program float
In the next part we will learn how to use arrays for storing more than one value in a variable.
Local scope variables with block
construct#
The 2008 Fortran standard introduced the notion of block
which enables using local scope variables within a program or procedure.
Example:
module your_module
implicit none
integer :: n = 2
end module
program main
implicit none
real :: x
block
use your_module, only: n ! you can import modules within blocks
real :: y ! local scope variable
y = 2.0
x = y ** n
print *, y
end block
! print *, y ! this is not allowed as y only exists during the block's scope
print *, x ! prints 4.00000000
end program