17 KiB
name | contributors | filename | |||
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Fortran |
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learnfortran.f90 |
Fortran is one of the oldest computer languages. It was developed in the 1950s by IBM for numeric calculations (Fortran is an abbreviation of "Formula Translation"). Despite its age, it is still used for high-performance computing such as weather prediction. However, the language has changed considerably over the years, although mostly maintaining backwards compatibility; well known versions are FORTRAN 77, Fortran 90, Fortran 95, Fortran 2003, Fortran 2008, Fortran 2018 and Fortran 2023.
This overview will discuss the features of Fortran 2008 since it is the most widely implemented of the more recent specifications and the later versions are largely similar (by comparison FORTRAN 77 is a very different language).
! This is a comment.
program example ! declare a program called example.
! Code can only exist inside programs, functions, subroutines or modules.
! Using indentation is not required but it is recommended.
! Declaring Variables
! ===================
! All declarations must come before statements and expressions.
implicit none ! prevents dynamic declaration of variables
! Recommended!
! Implicit none must be redeclared in every function/program/module...
! IMPORTANT - Fortran is case insensitive.
real z
REAL Z2
real :: v, x ! WARNING: default initial values are compiler dependent!
real :: a = 3, b = 2E12, c = 0.01
integer :: i, j, k = 1, m
real, parameter :: PI = 3.14159265 ! declare a constant.
logical :: y = .TRUE., n = .FALSE. ! boolean type.
complex :: w = (0, 1) ! sqrt(-1)
character(len=3) :: month ! string of 3 characters.
! declare an array of 6 reals.
real :: array(6)
! another way to declare an array.
real, dimension(4) :: arrayb
! an array with a custom index -10 to 10 (inclusive)
integer :: arrayc(-10:10)
! A multidimensional array.
real :: array2d(3, 2)
! The '::' separators are not always necessary but are recommended.
! many other variable attributes also exist:
real, pointer :: p ! declare a pointer.
integer, parameter :: LP = selected_real_kind(20)
real(kind=LP) :: d ! long precision variable.
! WARNING: initialising variables during declaration causes problems
! in functions since this automatically implies the 'save' attribute
! whereby values are saved between function calls. In general, separate
! declaration and initialisation code except for constants!
! Strings
! =======
character :: a_char = 'i'
character(len=6) :: a_str = "qwerty"
character(len=30) :: str_b
character(len=*), parameter :: a_long_str = "This is a long string."
!can have automatic counting of length using (len=*) but only for constants.
str_b = a_str//" keyboard" ! concatenate strings using // operator.
! Assignment & Arithmetic
! =======================
Z = 1 ! assign to variable z declared above
j = 10 + 2 - 3
a = 11.54/(2.3*3.1)
b = 2**3 ! exponentiation
! Control Flow Statements & Operators
! ===================================
! Single-line if statement
if (z == a) b = 4 ! conditions always need parentheses.
if (z /= a) then ! z not equal to a
! Other symbolic comparisons are < > <= >= == /=
b = 4
else if (z .GT. a) then ! z greater than a
! Text equivalents to symbol operators are .LT. .GT. .LE. .GE. .EQ. .NE.
b = 6
else if (z < a) then ! 'then' must be on this line.
b = 5 ! execution block must be on a new line.
else
b = 10
end if ! end statement needs the 'if'
if (.NOT. (x < c .AND. v >= a .OR. z == z)) then ! boolean operators.
inner: if (.TRUE.) then ! can name if-construct.
b = 1
end if inner ! then must name endif statement.
endif ! 'endif' is equivalent to 'end if'
i = 20
select case (i)
case (0, 1) ! cases i == 0 or i == 1
j = 0
case (2:10) ! cases i is 2 to 10 inclusive.
j = 1
case (11:) ! all cases where i>=11
j = 2
case default
j = 3
end select
month = 'jan'
! Condition can be integer, logical or character type.
! Select constructions can also be named.
monthly:select case(month)
case ("jan")
j = 0
case default
j = -1
end select monthly
do i = 2, 10, 2 ! loops from 2 to 10 (inclusive) in steps of 2.
innerloop: do j = 1, 3 ! loops can be named too.
exit ! quits the loop.
end do innerloop
cycle ! jump to next loop iteration.
end do
! Goto statement exists but it is heavily discouraged.
goto 10
stop 1 ! stops the program, returns condition code 1.
10 j = 201 ! this line is labeled as line 10
! Arrays
! ======
array = (/1, 2, 3, 4, 5, 6/)
array = [1, 2, 3, 4, 5, 6] ! using Fortran 2003 notation.
arrayb = [10.2, 3e3, 0.41, 4e-5]
array2d = reshape([1.0, 2.0, 3.0, 4.0, 5.0, 6.0], [3, 2])
! Fortran array indexing starts from 1.
! (by default but can be defined differently for specific arrays).
v = array(1) ! take first element of array.
v = array2d(2, 2)
print *, array(3:5) ! print all elements from 3rd to 5th (inclusive).
print *, array2d(1, :) ! print first column of 2d array.
array = array*3 + 2 ! can apply mathematical expressions to arrays.
array = array*array ! array operations occur element-wise.
! array = array*array2d ! these arrays would not be compatible.
! There are many built-in functions that operate on arrays.
c = dot_product(array, array) ! this is the dot product.
! Use matmul() for matrix maths.
c = sum(array)
c = maxval(array)
print *, minloc(array)
c = size(array)
print *, shape(array)
m = count(array > 0)
! Loop over an array (could have used Product() function normally).
v = 1
do i = 1, size(array)
v = v*array(i)
end do
! Conditionally execute element-wise assignments.
array = [1, 2, 3, 4, 5, 6]
where (array > 3)
array = array + 1
elsewhere(array == 2)
array = 1
elsewhere
array = 0
end where
! Implied-DO loops are a compact way to create arrays.
array = [(i, i=1, 6)] ! creates an array of [1,2,3,4,5,6]
array = [(i, i=1, 12, 2)] ! creates an array of [1,3,5,7,9,11]
array = [(i**2, i=1, 6)] ! creates an array of [1,4,9,16,25,36]
array = [(4, 5, i=1, 3)] ! creates an array of [4,5,4,5,4,5]
! Input/Output
! ============
print *, b ! print the variable 'b' to the command line
! We can format our printed output.
print "(I6)", 320 ! prints ' 320'
print "(I6.4)", 3 ! prints ' 0003'
print "(F6.3)", 4.32 ! prints ' 4.320'
! The letter indicates the expected type and the number afterwards gives
! the number of characters to use for printing the value.
! Letters can be I (integer), F (real), E (engineering format),
! L (logical), A (characters) ...
print "(I3)", 3200 ! print '***' since the number doesn't fit.
! we can have multiple format specifications.
print "(I5,F6.2,E6.2)", 120, 43.41, 43.41
! 3 repeats of integers (field width = 5).
print "(3I5)", 10, 20, 30
! repeated grouping of formats.
print "(2(I5,F6.2))", 120, 43.42, 340, 65.3
! We can also read input from the terminal.
read (*, *) v
read (*, "(2F6.2)") v, x ! read two numbers
! To write a file.
open (unit=12, file="records.txt", status="replace")
! The file is referred to by a 'unit number', an integer that you pick in
! the range 9:99. Status can be one of {'old','replace','new'}.
write (12, "(F10.2,F10.2,F10.2)") c, b, a
close (12)
! To read a file.
open (newunit=m, file="records.txt", status="old")
! The file is referred to by a 'new unit number',
! an integer that the compiler picks for you.
read (unit=m, fmt="(3F10.2)") a, b, c
close (m)
! There are more features available than discussed here and alternative
! variants due to backwards compatibility with older Fortran versions.
! Built-in Functions
! ==================
! Fortran has around 200 functions/subroutines intrinsic to the language.
! Examples -
call cpu_time(v) ! sets 'v' to a time in seconds.
k = ior(i, j) ! bitwise OR of 2 integers.
v = log10(x) ! log base 10.
i = floor(b) ! converts b to integer by rounding down.
v = aimag(w) ! imaginary part of a complex number.
! Functions & Subroutines
! =======================
! A subroutine runs some code on some input values and can cause
! side-effects or modify the input values.
call routine(a, c, v) ! subroutine call.
! A function takes several input parameters and returns a single value.
! However the input parameters may still be modified and side effects
! executed.
m = func(3, 2, k) ! function call.
! Function calls can also be evoked within expressions.
print *, func2(3, 2, k)
! A pure function is a function that doesn't modify its input
! parameters or cause any side-effects.
m = func3(3, 2, k)
contains ! Start defining the program's internal procedures:
! Fortran has a couple of slightly different ways to define functions.
integer function func(a, b, c) ! a function returning an integer value.
! implicit none ! - no longer used in subvariable fields
integer, intent(in) :: a, b, c ! type of input parameters
! the return variable defaults to the function name.
if (a >= 2) then
func = a + b + c
return ! returns the current value at 'func'
end if
func = a + c
! Don't need a return statement at the end of a function.
end function func
function func2(a, b, c) result(f) ! return variable declared to be 'f'.
integer, intent(in) :: a, b ! can declare and enforce that variables
!are not modified by the function.
integer, intent(inout) :: c
integer :: f
! function return type declared inside the function.
integer :: cnt = 0 ! GOTCHA -
! assigning a value at initalization
! implies that the variable is
! saved between function calls.
f = a + b - c
c = 4 ! changing value of input variable c.
cnt = cnt + 1 ! count number of function calls.
end function func2
pure function func3(a, b, c) ! a pure function has no side-effects.
integer, intent(in) :: a, b, c
integer :: func3
func3 = a*b*c
end function func3
! a subroutine does not return anything,
! but can change the value of arguments.
subroutine routine(d, e, f)
real, intent(inout) :: f
real, intent(in) :: d, e
f = 2*d + 3*e + f
end subroutine routine
end program example
! End of Program Definition -----------------------
! Functions and Subroutines declared externally to the program listing need
! to be declared to the program using an Interface declaration (even if they
! are in the same source file!) (see below). It is easier to define them within
! the 'contains' section of a module or program.
elemental real function func4(a) result(res)
! An elemental function is a Pure function that takes a scalar input variable
! but can also be used on an array where it will be separately applied to all
! of the elements of an array and return a new array.
real, intent(in) :: a
res = a**2 + 1.0
end function func4
! Modules
! =======
! A module is a useful way to collect related declarations, functions and
! subroutines together for reusability.
module fruit
real :: apple
real :: pear
real :: orange
end module fruit
module fruity
! Declarations must be in the order: modules, interfaces, variables.
! (can declare modules and interfaces in programs too).
use fruit, only: apple, pear ! use apple and pear from fruit module.
implicit none ! comes after module imports.
! By default all module data and functions will be public
private ! Instead set default to private
! Declare some variables/functions explicitly public.
public :: apple, mycar, create_mycar
! Declare some variables/functions private to the module (redundant here).
private :: func4
! Interfaces
! ==========
! Explicitly declare an external function/procedure within the module
! (better in general to put functions/procedures in the 'contains' section).
interface
elemental real function func4(a) result(res)
real, intent(in) :: a
end function func4
end interface
! Overloaded functions can be defined using named interfaces.
interface myabs
! Can use 'module procedure' keyword to include functions already
! defined within the module.
module procedure real_abs, complex_abs
end interface
! Derived Data Types
! ==================
! Can create custom structured data collections.
type car
character(len=100) :: model
real :: weight ! (kg)
real :: dimensions(3) ! i.e. length-width-height (metres).
character :: colour
contains
procedure :: info ! bind a procedure to a type.
end type car
type(car) :: mycar ! declare a variable of your custom type.
! See create_mycar() routine for usage.
! Note: There are no executable statements in modules.
contains
subroutine create_mycar(mycar)
! Demonstrates usage of a derived data type.
type(car), intent(out) :: mycar
! Access type elements using '%' operator.
mycar%model = "Ford Prefect"
mycar%colour = 'r'
mycar%weight = 1400
mycar%dimensions(1) = 5.0 ! default indexing starts from 1!
mycar%dimensions(2) = 3.0
mycar%dimensions(3) = 1.5
end subroutine create_mycar
subroutine info(self)
class(car), intent(in) :: self
! 'class' keyword used to bind a procedure to a type here.
print *, "Model : ", self%model
print *, "Colour : ", self%colour
print *, "Weight : ", self%weight
print *, "Dimensions: ", self%dimensions
end subroutine info
real pure function real_abs(x)
real, intent(in) :: x
if (x < 0) then
real_abs = -x
else
real_abs = x
end if
end function real_abs
real pure function complex_abs(z)
complex, intent(in) :: z
! long lines can be continued using the continuation character '&'
complex_abs = sqrt(real(z)**2 + &
aimag(z)**2)
end function complex_abs
end module fruity
! ISO Standard Fortran 2008 introduced the DO CONCURRENT construct to allow you
! to express loop-level parallelism
integer :: i
real :: array(10)
DO CONCURRENT (i = 1:size(array))
array(i) = sqrt(real(i)**i)
END DO
! Only calls to pure functions are allowed inside the loop and we can declare
! multiple indices:
integer :: x, y
real :: array(8, 16)
do concurrent (x = 1:size(array, 1), y = 1:size(array, 2))
array(x, y) = real(x)
end do
! loop indices can also declared inside the contruct:
real :: array(8, 16)
do concurrent (integer :: x = 1:size(array, 1), y = 1:size(array, 2))
array(x, y) = real(x)
end do
More Resources
For more information on Fortran: