In this guide, we will discuss Fortran Arrays. Arrays can store a fixed-size sequential collection of elements of the same type. An array is used to store a collection of data, but it is often more useful to think of an array as a collection of variables of the same type.
All arrays consist of contiguous memory locations. The lowest address corresponds to the first element and the highest address to the last element.
| Numbers(1) | Numbers(2) | Numbers(3) | Numbers(4) | β¦ |
Arrays can be one- dimensional (like vectors), two-dimensional (like matrices) and Fortran allows you to create up to 7-dimensional arrays.
Declaring Arrays
Arrays are declared with the dimension attribute.
For example, to declare a one-dimensional array named number, of real numbers containing 5 elements, you write,
real, dimension(5) :: numbers
The individual elements of arrays are referenced by specifying their subscripts. The first element of an array has a subscript of one. The array numbers contains five real variables βnumbers(1), numbers(2), numbers(3), numbers(4), and numbers(5).
To create a 5 x 5 two-dimensional array of integers named matrix, you write β
integer, dimension (5,5) :: matrix
You can also declare an array with some explicit lower bound, for example β
real, dimension(2:6) :: numbers integer, dimension (-3:2,0:4) :: matrix
Assigning Values
You can either assign values to individual members, like,
numbers(1) = 2.0
or, you can use a loop,
do i =1,5 numbers(i) = i * 2.0 end do
One-dimensional array elements can be directly assigned values using a short hand symbol, called array constructor, like,
numbers = (/1.5, 3.2,4.5,0.9,7.2 /)
please note that there are no spaces allowed between the brackets β( βand the back slash β/β
Example
The following example demonstrates the concepts discussed above.
program arrayProg
real :: numbers(5) !one dimensional integer array
integer :: matrix(3,3), i , j !two dimensional real array
!assigning some values to the array numbers
do i=1,5
numbers(i) = i * 2.0
end do
!display the values
do i = 1, 5
Print *, numbers(i)
end do
!assigning some values to the array matrix
do i=1,3
do j = 1, 3
matrix(i, j) = i+j
end do
end do
!display the values
do i=1,3
do j = 1, 3
Print *, matrix(i,j)
end do
end do
!short hand assignment
numbers = (/1.5, 3.2,4.5,0.9,7.2 /)
!display the values
do i = 1, 5
Print *, numbers(i)
end do
end program arrayProg
When the above code is compiled and executed, it produces the following result β
2.00000000
4.00000000
6.00000000
8.00000000
10.0000000
2
3
4
3
4
5
4
5
6
1.50000000
3.20000005
4.50000000
0.899999976
7.19999981
Some Array Related Terms
The following table gives some array related terms β
| Term | Meaning |
|---|---|
| Rank | It is the number of dimensions an array has. For example, for the array named matrix, rank is 2, and for the array named numbers, rank is 1. |
| Extent | It is the number of elements along a dimension. For example, the array numbers has extent 5 and the array named matrix has extent 3 in both dimensions. |
| Shape | The shape of an array is a one-dimensional integer array, containing the number of elements (the extent) in each dimension. For example, for the array matrix, shape is (3, 3) and the array numbers it is (5). |
| Size | It is the number of elements an array contains. For the array matrix, it is 9, and for the array numbers, it is 5. |
Passing Arrays to Procedures
You can pass an array to a procedure as an argument. The following example demonstrates the concept β
program arrayToProcedure
implicit none
integer, dimension (5) :: myArray
integer :: i
call fillArray (myArray)
call printArray(myArray)
end program arrayToProcedure
subroutine fillArray (a)
implicit none
integer, dimension (5), intent (out) :: a
! local variables
integer :: i
do i = 1, 5
a(i) = i
end do
end subroutine fillArray
subroutine printArray(a)
integer, dimension (5) :: a
integer::i
do i = 1, 5
Print *, a(i)
end do
end subroutine printArray
When the above code is compiled and executed, it produces the following result β
1 2 3 4 5
In the above example, the subroutine fillArray and printArray can only be called with arrays with dimension 5. However, to write subroutines that can be used for arrays of any size, you can rewrite it using the following technique β
program arrayToProcedure
implicit none
integer, dimension (10) :: myArray
integer :: i
interface
subroutine fillArray (a)
integer, dimension(:), intent (out) :: a
integer :: i
end subroutine fillArray
subroutine printArray (a)
integer, dimension(:) :: a
integer :: i
end subroutine printArray
end interface
call fillArray (myArray)
call printArray(myArray)
end program arrayToProcedure
subroutine fillArray (a)
implicit none
integer,dimension (:), intent (out) :: a
! local variables
integer :: i, arraySize
arraySize = size(a)
do i = 1, arraySize
a(i) = i
end do
end subroutine fillArray
subroutine printArray(a)
implicit none
integer,dimension (:) :: a
integer::i, arraySize
arraySize = size(a)
do i = 1, arraySize
Print *, a(i)
end do
end subroutine printArray
Please note that the program is using the size function to get the size of the array.
When the above code is compiled and executed, it produces the following result β
1 2 3 4 5 6 7 8 9 10
Array Sections
So far we have referred to the whole array, Fortran provides an easy way to refer several elements, or a section of an array, using a single statement.
To access an array section, you need to provide the lower and the upper bound of the section, as well as a stride (increment), for all the dimensions. This notation is called a subscript triplet:
array ([lower]:[upper][:stride], ...)
When no lower and upper bounds are mentioned, it defaults to the extents you declared, and stride value defaults to 1.
The following example demonstrates the concept β
program arraySubsection
real, dimension(10) :: a, b
integer:: i, asize, bsize
a(1:7) = 5.0 ! a(1) to a(7) assigned 5.0
a(8:) = 0.0 ! rest are 0.0
b(2:10:2) = 3.9
b(1:9:2) = 2.5
!display
asize = size(a)
bsize = size(b)
do i = 1, asize
Print *, a(i)
end do
do i = 1, bsize
Print *, b(i)
end do
end program arraySubsection
When the above code is compiled and executed, it produces the following result β
5.00000000 5.00000000 5.00000000 5.00000000 5.00000000 5.00000000 5.00000000 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.50000000 3.90000010 2.50000000 3.90000010 2.50000000 3.90000010 2.50000000 3.90000010 2.50000000 3.90000010
Array Intrinsic Functions
Fortran 90/95 provides several intrinsic procedures. They can be divided into 7 categories.
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