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This is a bit complicated; I'd welcome any comments on how to improve the clarity of the question.

Ok, say I have an array:

real, allocatable :: A(:,:,:)

and I want to allocate it before I use it. Is it possible for the size of third dimension to depend on the size of the second dimension?

E.g.

do i=1,n
allocate(A(3,i,i**2))
end do

Obviously the above doesn't work. I'd like to end up with an array (or a set of arrays) with the shape(s)

(3,1,1), (3,2,4), (3,3,9), ... (3, n, n^2)

where the size of the third dimension is the square of the size of the second dimension.

My rule for the size of the dependent dimension is a bit more complicated, but if squaring is possible I can do the rest.

Is this possible? If so, how might I implement it in Fortran?

What would shape(A) return? That would be interesting.

My other alternative is to allocate to the maximum size required, and be careful to only use certain elements in calculations, i.e.

allocate(A(3,n,n**2))

Even though I'm not hard up on memory at the moment, I'd like to have good programming practices. This is an interesting problem anyway.

Thank you.

EDIT:

What about having the size of a dimension depend on the value of an element in another dimension?

In the answer below the size of array in both dimensions depended on the index of B. I'd like something along the lines of

type myarray
    real :: coord(3)
    integer,allocatable :: lev(:)
    integer, allocatable :: cell(:)
endtype myarray

type(myarray), allocatable :: data

allocate(data(m))
allocate(data%lev(n))

forall (j=1:n) !simple now, for argument's sake
    lev(j)=j
endforall

! I was thinking of using a FORALL loop here, but the errors returned 
! suggested that the compiler (gfortran) didn't expect IF blocks and ALLOCATE 
! statements in a FORALL block
do i=1,m
    do j=1,n
        allocate(data(i)%cell(lev(j)**2))
    enddo
enddo

You get what I mean? But the program falls over as it tries to allocate already allocated variables, e.g. when i=1 it allocates data(1)%cell(1), and then tries to allocate data(1)%cell(2)...uh oh. What I want is something like:

Each data(i) has an array lev(j) of values, with j running from 1 to n, and for each lev(j) value we have a cell of size lev^2. Note that these cell's are unique for each data(i) and each lev, and that the size of that particular cell depends on the corresponding lev value, and possibly the corresponding data(i) too.

Would I have to use a derived type within a derived type?

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1  
Just so you know, the type of array you're looking for is called a "jagged" array, as vs. "rectangular" array. IRO-bot below has the correct answer; in Fortran arrays by themselves are always rectangular but you can use defined types to make your own structure. –  Jonathan Dursi Dec 19 '11 at 13:54
    
"Jagged"...hey, that makes sense, pictorially. "...you can use defined types to make your own structure." Really? So if I want an array whose shape increases until halfway then decreases, or follows the Fibonacci sequence, or is completely random--that's all possible for not too much effort...cool! –  Samuel Tan Dec 20 '11 at 0:17
    
@SamuelTan I further edited my answer with updated code to solve your new problem. Compare the two codes to see what you were doing wrong. –  IRO-bot Dec 20 '11 at 4:53
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1 Answer

up vote 7 down vote accepted

Yes, you can use a derived type to accomplish this:

TYPE array
  REAL,DIMENSION(:,:,:),ALLOCATABLE :: A
ENDTYPE array

INTEGER :: i
INTEGER,PARAMETER :: n=10

TYPE(array),DIMENSION(:),ALLOCATABLE :: B

ALLOCATE(B(n))

DO i=1,n
  ALLOCATE(B(i)%A(3,i,i*i))
  WRITE(*,*)SHAPE(B(i)%A)
ENDDO

END

This approach allows each element of array B to be a multi-dimensional array of a different shape.

The output of the program is as expected:

        3            1            1
        3            2            4
        3            3            9
        3            4           16
        3            5           25
        3            6           36
        3            7           49
        3            8           64
        3            9           81
        3           10          100

EDIT: To further answer OP's edited question. Yes, it seems like you would need to do something like this, use nested derived type (compare to your code example to figure out what you did wrong):

integer,parameter :: m=3,n=5

type cellarray
  integer,dimension(:),allocatable :: c
endtype cellarray

type myarray
  integer,allocatable :: lev(:)
  type(cellarray),dimension(:),allocatable :: cell
endtype myarray

type(myarray),dimension(:),allocatable :: B

allocate(B(m))

! Allocate and assign lev and cell:
do i=1,m
  allocate(B(i)%lev(n))
  allocate(B(i)%cell(n))
  do j=1,n
    B(i)%lev(j)=j
  enddo
enddo

! Based on value of lev, allocate B%cell%c:    
do i=1,m
  do j=1,n
    allocate(B(i)%cell(j)%c(B(i)%lev(j)**2))
  enddo
enddo

! Print out to check that it works:
do j=1,n
  write(*,*)j,B(1)%lev(j),SIZE(B(1)%cell(j)%c)
enddo

end

Tried this with gfortran 4.6.2. It produces expected output:

       1           1           1
       2           2           4
       3           3           9
       4           4          16
       5           5          25
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5  
It works with any recent gfortran I have encountered (4.1.2 is totally obsolete). –  Vladimir F Dec 19 '11 at 10:12
    
@VladimirF Thanks for the comment - I editted my answer. I was not aware of this since I barely ever use gfortran, and this is what we have on our compute cluster. I assume our sysadmin didn't bother updating it. :) –  IRO-bot Dec 19 '11 at 16:35
    
That's a consolation. I use gfortran, and I was afraid I might have to get another compiler. –  Samuel Tan Dec 20 '11 at 0:22
    
What happens if we have B allocatable as well? Would the allocation still take one loop? –  Samuel Tan Dec 20 '11 at 0:28
1  
@SamuelTan I have no experience with derived types in HPC - you will have to figure out this yourself. I assume it should not be significantly slower, remember that derived types are just an abstraction of data, and it is all stored in 1-D arrays in memory. As an exercise, you can implement your problem both ways, and see if you get difference in performance. However, what I would worry about is to first implement the program in the simplest and most obvious way that works for you, and worry about optimizing later. –  IRO-bot Dec 20 '11 at 15:40
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