libgomp/testsuite/libgomp.oacc-fortran/declare-allocatable-array_descriptor-1-runtime.f90 - gcc - Git at Google

 ! Test OpenACC 'declare create' with allocatable arrays.

 ! { dg-do run }

 ! Note that we're not testing OpenACC semantics here, but rather documenting
 ! current GCC behavior, specifically, behavior concerning updating of
 ! host/device array descriptors.
 ! { dg-skip-if n/a { *-*-* } { -DACC_MEM_SHARED=1 } }

 !TODO-OpenACC-declare-allocate
 ! Missing support for OpenACC "Changes from Version 2.0 to 2.5":
 ! "The 'declare create' directive with a Fortran 'allocatable' has new behavior".
 ! Thus, after 'allocate'/before 'deallocate', call 'acc_create'/'acc_delete'
 ! manually.


 !TODO { dg-additional-options -fno-inline } for stable results regarding OpenACC 'routine'.


 !TODO OpenACC 'serial' vs. GCC/nvptx:
 !TODO { dg-prune-output {using 'vector_length \(32\)', ignoring 1} }


 ! { dg-additional-options -fdump-tree-original }
 ! { dg-additional-options -fdump-tree-gimple }


 module vars
   implicit none
   integer, parameter :: n1_lb = -3
   integer, parameter :: n1_ub = 6
   integer, parameter :: n2_lb = -9999
   integer, parameter :: n2_ub = 22222

   integer, allocatable :: b(:)
   !$acc declare create (b)

 end module vars

 program test
   use vars
   use openacc
   implicit none
   integer :: i

   ! Identifiers for purposes of reliable '-fdump-tree-[...]' scanning.
   integer :: id1_1, id1_2

   interface

      subroutine verify_initial
        implicit none
        !$acc routine seq
      end subroutine verify_initial

      subroutine verify_n1_allocated
        implicit none
        !$acc routine seq
      end subroutine verify_n1_allocated

      subroutine verify_n1_values (addend)
        implicit none
        !$acc routine gang
        integer, value :: addend
      end subroutine verify_n1_values

      subroutine verify_n1_deallocated (expect_allocated)
        implicit none
        !$acc routine seq
        logical, value :: expect_allocated
      end subroutine verify_n1_deallocated

      subroutine verify_n2_allocated
        implicit none
        !$acc routine seq
      end subroutine verify_n2_allocated

      subroutine verify_n2_values (addend)
        implicit none
        !$acc routine gang
        integer, value :: addend
      end subroutine verify_n2_values

      subroutine verify_n2_deallocated (expect_allocated)
        implicit none
        !$acc routine seq
        logical, value :: expect_allocated
      end subroutine verify_n2_deallocated

   end interface

   call acc_create (id1_1)
   call acc_create (id1_2)

   call verify_initial
   ! It is important here (and similarly, following) that there is no data
   ! clause for 'b' (explicit or implicit): no 'GOMP_MAP_TO_PSET'.
   !$acc serial
   call verify_initial
   !$acc end serial

   allocate (b(n1_lb:n1_ub))
   call verify_n1_allocated
   if (acc_is_present (b)) error stop
   call acc_create (b)
   ! This is now OpenACC "present":
   if (.not.acc_is_present (b)) error stop
   ! This still has the initial array descriptor:
   !$acc serial
   call verify_initial
   !$acc end serial

   do i = n1_lb, n1_ub
      b(i) = i - 1
   end do

   ! Verify that host-to-device copy doesn't touch the device-side (still
   ! initial) array descriptor (but it does copy the array data).
   call acc_update_device (b)
   !$acc serial
   call verify_initial
   !$acc end serial

   b = 40

   ! Verify that device-to-host copy doesn't touch the host-side array
   ! descriptor, doesn't copy out the device-side (still initial) array
   ! descriptor (but it does copy the array data).
   call acc_update_self (b)
   call verify_n1_allocated

   do i = n1_lb, n1_ub
      if (b(i) /= i - 1) error stop
      b(i) = b(i) + 2
   end do

   ! The same using the OpenACC 'update' directive.

   !$acc update device (b) self (id1_1)
   ! We do have 'GOMP_MAP_TO_PSET' here:
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc update map\(force_to:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_1\);$} 1 original } }
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_update map\(force_to:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }
   ! ..., but it's silently skipped in 'GOACC_update'.
   !$acc serial
   call verify_initial
   !$acc end serial

   b = 41

   !$acc update self (b) self (id1_2)
   ! We do have 'GOMP_MAP_TO_PSET' here:
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc update map\(force_from:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_2\);$} 1 original } }
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_update map\(force_from:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }
   ! ..., but it's silently skipped in 'GOACC_update'.
   call verify_n1_allocated

   do i = n1_lb, n1_ub
      if (b(i) /= i + 1) error stop
      b(i) = b(i) + 2
   end do

   ! Now install the actual array descriptor, via a data clause for 'b'
   ! (explicit or implicit): must get a 'GOMP_MAP_TO_PSET', which then in
   ! 'gomp_map_vars_internal' is handled as 'declare target', and because of
   ! '*(void **) hostaddrs[i] != NULL', we've got 'has_always_ptrset == true',
   ! 'always_to_cnt == 1', and therefore 'gomp_map_vars_existing' does update
   ! the 'GOMP_MAP_TO_PSET'.
   !$acc serial present (b) copyin (id1_1)
   call verify_initial
   id1_1 = 0
   !$acc end serial
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc serial map\(force_present:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_1\)$} 1 original } }
   !TODO ..., but without an actual use of 'b', the gimplifier removes the
   !TODO 'GOMP_MAP_TO_PSET':
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }
   !$acc serial present (b) copyin (id1_2)
   call verify_n1_allocated
   !TODO Use of 'b':
   id1_2 = ubound (b, 1)
   !$acc end serial
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc serial map\(force_present:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2\)$} 1 original } }
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }

   !$acc parallel copyin (id1_1) ! No data clause for 'b' (explicit or implicit): no 'GOMP_MAP_TO_PSET'.
   call verify_n1_values (1)
   id1_1 = 0
   !$acc end parallel
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc parallel map\(to:id1_1\)$} 1 original } }
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_parallel map\(to:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }

   !$acc parallel copy (b) copyin (id1_2)
   ! As already present, 'copy (b)' doesn't copy; addend is still '1'.
   call verify_n1_values (1)
   id1_2 = 0
   !$acc end parallel
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc parallel map\(tofrom:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2\)$} 1 original } }
   !TODO ..., but without an actual use of 'b', the gimplifier removes the
   !TODO 'GOMP_MAP_TO_PSET':
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_parallel map\(tofrom:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }

   call verify_n1_allocated
   if (.not.acc_is_present (b)) error stop

   call acc_delete (b)
   if (.not.allocated (b)) error stop
   if (acc_is_present (b)) error stop
   ! The device-side array descriptor doesn't get updated, so 'b' still appears
   ! as "allocated":
   !$acc serial
   call verify_n1_allocated
   !$acc end serial

   deallocate (b)
   call verify_n1_deallocated (.false.)
   ! The device-side array descriptor doesn't get updated, so 'b' still appears
   ! as "allocated":
   !$acc serial
   call verify_n1_allocated
   !$acc end serial

   ! Now try to install the actual array descriptor, via a data clause for 'b'
   ! (explicit or implicit): must get a 'GOMP_MAP_TO_PSET', which then in
   ! 'gomp_map_vars_internal' is handled as 'declare target', but because of
   ! '*(void **) hostaddrs[i] == NULL', we've got 'has_always_ptrset == false',
   ! 'always_to_cnt == 0', and therefore 'gomp_map_vars_existing' doesn't update
   ! the 'GOMP_MAP_TO_PSET'.
   ! The device-side array descriptor doesn't get updated, so 'b' still appears
   ! as "allocated":
   !TODO Why does 'present (b)' still work here?
   !$acc serial present (b) copyout (id1_2)
   call verify_n1_deallocated (.true.)
   !TODO Use of 'b'.
   id1_2 = ubound (b, 1)
   !$acc end serial
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc serial map\(force_present:\*\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(from:id1_2\)$} 1 original } }
   ! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \*\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(from:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }


   ! Restart the procedure, with different array dimensions.

   allocate (b(n2_lb:n2_ub))
   call verify_n2_allocated
   if (acc_is_present (b)) error stop
   call acc_create (b)
   if (.not.acc_is_present (b)) error stop
   ! This still has the previous (n1) array descriptor:
   !$acc serial
   call verify_n1_deallocated (.true.)
   !$acc end serial

   do i = n2_lb, n2_ub
      b(i) = i + 20
   end do

   call acc_update_device (b)
   !$acc serial
   call verify_n1_deallocated (.true.)
   !$acc end serial

   b = -40

   call acc_update_self (b)
   call verify_n2_allocated

   do i = n2_lb, n2_ub
      if (b(i) /= i + 20) error stop
      b(i) = b(i) - 40
   end do

   !$acc update device (b)
   !$acc serial
   call verify_n1_deallocated (.true.)
   !$acc end serial

   b = -41

   !$acc update self (b)
   call verify_n2_allocated

   do i = n2_lb, n2_ub
      if (b(i) /= i - 20) error stop
      b(i) = b(i) + 10
   end do

   !$acc serial present (b) copy (id1_2)
   call verify_n2_allocated
   !TODO Use of 'b':
   id1_2 = ubound (b, 1)
   !$acc end serial

   !$acc parallel
   call verify_n2_values (-20)
   !$acc end parallel

   !$acc parallel copy (b)
   call verify_n2_values (-20)
   !$acc end parallel

   call verify_n2_allocated
   if (.not.acc_is_present (b)) error stop

   call acc_delete (b)
   if (.not.allocated (b)) error stop
   if (acc_is_present (b)) error stop
   !$acc serial
   call verify_n2_allocated
   !$acc end serial

   deallocate (b)
   call verify_n2_deallocated (.false.)
   !$acc serial
   call verify_n2_allocated
   !$acc end serial

   !$acc serial present (b) copy (id1_2)
   call verify_n2_deallocated (.true.)
   !TODO Use of 'b':
   id1_2 = ubound (b, 1)
   !$acc end serial

 end program test


 subroutine verify_initial
   use vars
   implicit none
   !$acc routine seq

   if (allocated (b)) error stop "verify_initial allocated"
   if (any (lbound (b) /= [0])) error stop "verify_initial lbound"
   if (any (ubound (b) /= [0])) error stop "verify_initial ubound"
 end subroutine verify_initial

 subroutine verify_n1_allocated
   use vars
   implicit none
   !$acc routine seq

   if (.not.allocated (b)) error stop "verify_n1_allocated allocated"
   if (any (lbound (b) /= [n1_lb])) error stop "verify_n1_allocated lbound"
   if (any (ubound (b) /= [n1_ub])) error stop "verify_n1_allocated ubound"
 end subroutine verify_n1_allocated

 subroutine verify_n1_values (addend)
   use vars
   implicit none
   !$acc routine gang
   integer, value :: addend
   integer :: i

   !$acc loop
   do i = n1_lb, n1_ub
      if (b(i) /= i + addend) error stop
   end do
 end subroutine verify_n1_values

 subroutine verify_n1_deallocated (expect_allocated)
   use vars
   implicit none
   !$acc routine seq
   logical, value :: expect_allocated

   if (allocated(b) .neqv. expect_allocated) error stop "verify_n1_deallocated allocated"
   ! Apparently 'deallocate'ing doesn't unset the bounds.
   if (any (lbound (b) /= [n1_lb])) error stop "verify_n1_deallocated lbound"
   if (any (ubound (b) /= [n1_ub])) error stop "verify_n1_deallocated ubound"
 end subroutine verify_n1_deallocated

 subroutine verify_n2_allocated
   use vars
   implicit none
   !$acc routine seq

   if (.not.allocated(b)) error stop "verify_n2_allocated allocated"
   if (any (lbound (b) /= [n2_lb])) error stop "verify_n2_allocated lbound"
   if (any (ubound (b) /= [n2_ub])) error stop "verify_n2_allocated ubound"
 end subroutine verify_n2_allocated

 subroutine verify_n2_values (addend)
   use vars
   implicit none
   !$acc routine gang
   integer, value :: addend
   integer :: i

   !$acc loop
   do i = n2_lb, n2_ub
      if (b(i) /= i + addend) error stop
   end do
 end subroutine verify_n2_values

 subroutine verify_n2_deallocated (expect_allocated)
   use vars
   implicit none
   !$acc routine seq
   logical, value :: expect_allocated

   if (allocated(b) .neqv. expect_allocated) error stop "verify_n2_deallocated allocated"
   ! Apparently 'deallocate'ing doesn't unset the bounds.
   if (any (lbound (b) /= [n2_lb])) error stop "verify_n2_deallocated lbound"
   if (any (ubound (b) /= [n2_ub])) error stop "verify_n2_deallocated ubound"
 end subroutine verify_n2_deallocated
	! Test OpenACC 'declare create' with allocatable arrays.

	! { dg-do run }

	! Note that we're not testing OpenACC semantics here, but rather documenting
	! current GCC behavior, specifically, behavior concerning updating of
	! host/device array descriptors.
	! { dg-skip-if n/a { --* } { -DACC_MEM_SHARED=1 } }

	!TODO-OpenACC-declare-allocate
	! Missing support for OpenACC "Changes from Version 2.0 to 2.5":
	! "The 'declare create' directive with a Fortran 'allocatable' has new behavior".
	! Thus, after 'allocate'/before 'deallocate', call 'acc_create'/'acc_delete'
	! manually.


	!TODO { dg-additional-options -fno-inline } for stable results regarding OpenACC 'routine'.


	!TODO OpenACC 'serial' vs. GCC/nvptx:
	!TODO { dg-prune-output {using 'vector_length \(32\)', ignoring 1} }


	! { dg-additional-options -fdump-tree-original }
	! { dg-additional-options -fdump-tree-gimple }


	module vars
	implicit none
	integer, parameter :: n1_lb = -3
	integer, parameter :: n1_ub = 6
	integer, parameter :: n2_lb = -9999
	integer, parameter :: n2_ub = 22222

	integer, allocatable :: b(:)
	!$acc declare create (b)

	end module vars

	program test
	use vars
	use openacc
	implicit none
	integer :: i

	! Identifiers for purposes of reliable '-fdump-tree-[...]' scanning.
	integer :: id1_1, id1_2

	interface

	subroutine verify_initial
	implicit none
	!$acc routine seq
	end subroutine verify_initial

	subroutine verify_n1_allocated
	implicit none
	!$acc routine seq
	end subroutine verify_n1_allocated

	subroutine verify_n1_values (addend)
	implicit none
	!$acc routine gang
	integer, value :: addend
	end subroutine verify_n1_values

	subroutine verify_n1_deallocated (expect_allocated)
	implicit none
	!$acc routine seq
	logical, value :: expect_allocated
	end subroutine verify_n1_deallocated

	subroutine verify_n2_allocated
	implicit none
	!$acc routine seq
	end subroutine verify_n2_allocated

	subroutine verify_n2_values (addend)
	implicit none
	!$acc routine gang
	integer, value :: addend
	end subroutine verify_n2_values

	subroutine verify_n2_deallocated (expect_allocated)
	implicit none
	!$acc routine seq
	logical, value :: expect_allocated
	end subroutine verify_n2_deallocated

	end interface

	call acc_create (id1_1)
	call acc_create (id1_2)

	call verify_initial
	! It is important here (and similarly, following) that there is no data
	! clause for 'b' (explicit or implicit): no 'GOMP_MAP_TO_PSET'.
	!$acc serial
	call verify_initial
	!$acc end serial

	allocate (b(n1_lb:n1_ub))
	call verify_n1_allocated
	if (acc_is_present (b)) error stop
	call acc_create (b)
	! This is now OpenACC "present":
	if (.not.acc_is_present (b)) error stop
	! This still has the initial array descriptor:
	!$acc serial
	call verify_initial
	!$acc end serial

	do i = n1_lb, n1_ub
	b(i) = i - 1
	end do

	! Verify that host-to-device copy doesn't touch the device-side (still
	! initial) array descriptor (but it does copy the array data).
	call acc_update_device (b)
	!$acc serial
	call verify_initial
	!$acc end serial

	b = 40

	! Verify that device-to-host copy doesn't touch the host-side array
	! descriptor, doesn't copy out the device-side (still initial) array
	! descriptor (but it does copy the array data).
	call acc_update_self (b)
	call verify_n1_allocated

	do i = n1_lb, n1_ub
	if (b(i) /= i - 1) error stop
	b(i) = b(i) + 2
	end do

	! The same using the OpenACC 'update' directive.

	!$acc update device (b) self (id1_1)
	! We do have 'GOMP_MAP_TO_PSET' here:
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc update map\(force_to:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_1\);$} 1 original } }
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_update map\(force_to:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }
	! ..., but it's silently skipped in 'GOACC_update'.
	!$acc serial
	call verify_initial
	!$acc end serial

	b = 41

	!$acc update self (b) self (id1_2)
	! We do have 'GOMP_MAP_TO_PSET' here:
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc update map\(force_from:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_2\);$} 1 original } }
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_update map\(force_from:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(force_from:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }
	! ..., but it's silently skipped in 'GOACC_update'.
	call verify_n1_allocated

	do i = n1_lb, n1_ub
	if (b(i) /= i + 1) error stop
	b(i) = b(i) + 2
	end do

	! Now install the actual array descriptor, via a data clause for 'b'
	! (explicit or implicit): must get a 'GOMP_MAP_TO_PSET', which then in
	! 'gomp_map_vars_internal' is handled as 'declare target', and because of
	! '(void *) hostaddrs[i] != NULL', we've got 'has_always_ptrset == true',
	! 'always_to_cnt == 1', and therefore 'gomp_map_vars_existing' does update
	! the 'GOMP_MAP_TO_PSET'.
	!$acc serial present (b) copyin (id1_1)
	call verify_initial
	id1_1 = 0
	!$acc end serial
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc serial map\(force_present:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_1\)$} 1 original } }
	!TODO ..., but without an actual use of 'b', the gimplifier removes the
	!TODO 'GOMP_MAP_TO_PSET':
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }
	!$acc serial present (b) copyin (id1_2)
	call verify_n1_allocated
	!TODO Use of 'b':
	id1_2 = ubound (b, 1)
	!$acc end serial
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc serial map\(force_present:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2\)$} 1 original } }
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }

	!$acc parallel copyin (id1_1) ! No data clause for 'b' (explicit or implicit): no 'GOMP_MAP_TO_PSET'.
	call verify_n1_values (1)
	id1_1 = 0
	!$acc end parallel
	! { dg-final { scan-tree-dump-times {(?n)^ *#pragma acc parallel map\(to:id1_1\)$} 1 original } }
	! { dg-final { scan-tree-dump-times {(?n)^ *#pragma omp target oacc_parallel map\(to:id1_1 \[len: [0-9]+\]\)$} 1 gimple } }

	!$acc parallel copy (b) copyin (id1_2)
	! As already present, 'copy (b)' doesn't copy; addend is still '1'.
	call verify_n1_values (1)
	id1_2 = 0
	!$acc end parallel
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc parallel map\(tofrom:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2\)$} 1 original } }
	!TODO ..., but without an actual use of 'b', the gimplifier removes the
	!TODO 'GOMP_MAP_TO_PSET':
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_parallel map\(tofrom:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(to:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }

	call verify_n1_allocated
	if (.not.acc_is_present (b)) error stop

	call acc_delete (b)
	if (.not.allocated (b)) error stop
	if (acc_is_present (b)) error stop
	! The device-side array descriptor doesn't get updated, so 'b' still appears
	! as "allocated":
	!$acc serial
	call verify_n1_allocated
	!$acc end serial

	deallocate (b)
	call verify_n1_deallocated (.false.)
	! The device-side array descriptor doesn't get updated, so 'b' still appears
	! as "allocated":
	!$acc serial
	call verify_n1_allocated
	!$acc end serial

	! Now try to install the actual array descriptor, via a data clause for 'b'
	! (explicit or implicit): must get a 'GOMP_MAP_TO_PSET', which then in
	! 'gomp_map_vars_internal' is handled as 'declare target', but because of
	! '(void *) hostaddrs[i] == NULL', we've got 'has_always_ptrset == false',
	! 'always_to_cnt == 0', and therefore 'gomp_map_vars_existing' doesn't update
	! the 'GOMP_MAP_TO_PSET'.
	! The device-side array descriptor doesn't get updated, so 'b' still appears
	! as "allocated":
	!TODO Why does 'present (b)' still work here?
	!$acc serial present (b) copyout (id1_2)
	call verify_n1_deallocated (.true.)
	!TODO Use of 'b'.
	id1_2 = ubound (b, 1)
	!$acc end serial
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma acc serial map\(force_present:\\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:\(integer\(kind=[0-9]+\)\[0:\] \* restrict\) b\.data \[pointer assign, bias: 0\]\) map\(from:id1_2\)$} 1 original } }
	! { dg-final { scan-tree-dump-times {(?n)^ #pragma omp target oacc_serial map\(force_present:MEM <integer\(kind=[0-9]+\)\[0:\]> \[\(integer\(kind=[0-9]+\)\[0:\] \\)[^\]]+\] \[len: [^\]]+\]\) map\(to:b \[pointer set, len: [0-9]+\]\) map\(alloc:b\.data \[pointer assign, bias: 0\]\) map\(from:id1_2 \[len: [0-9]+\]\)$} 1 gimple } }


	! Restart the procedure, with different array dimensions.

	allocate (b(n2_lb:n2_ub))
	call verify_n2_allocated
	if (acc_is_present (b)) error stop
	call acc_create (b)
	if (.not.acc_is_present (b)) error stop
	! This still has the previous (n1) array descriptor:
	!$acc serial
	call verify_n1_deallocated (.true.)
	!$acc end serial

	do i = n2_lb, n2_ub
	b(i) = i + 20
	end do

	call acc_update_device (b)
	!$acc serial
	call verify_n1_deallocated (.true.)
	!$acc end serial

	b = -40

	call acc_update_self (b)
	call verify_n2_allocated

	do i = n2_lb, n2_ub
	if (b(i) /= i + 20) error stop
	b(i) = b(i) - 40
	end do

	!$acc update device (b)
	!$acc serial
	call verify_n1_deallocated (.true.)
	!$acc end serial

	b = -41

	!$acc update self (b)
	call verify_n2_allocated

	do i = n2_lb, n2_ub
	if (b(i) /= i - 20) error stop
	b(i) = b(i) + 10
	end do

	!$acc serial present (b) copy (id1_2)
	call verify_n2_allocated
	!TODO Use of 'b':
	id1_2 = ubound (b, 1)
	!$acc end serial

	!$acc parallel
	call verify_n2_values (-20)
	!$acc end parallel

	!$acc parallel copy (b)
	call verify_n2_values (-20)
	!$acc end parallel

	call verify_n2_allocated
	if (.not.acc_is_present (b)) error stop

	call acc_delete (b)
	if (.not.allocated (b)) error stop
	if (acc_is_present (b)) error stop
	!$acc serial
	call verify_n2_allocated
	!$acc end serial

	deallocate (b)
	call verify_n2_deallocated (.false.)
	!$acc serial
	call verify_n2_allocated
	!$acc end serial

	!$acc serial present (b) copy (id1_2)
	call verify_n2_deallocated (.true.)
	!TODO Use of 'b':
	id1_2 = ubound (b, 1)
	!$acc end serial

	end program test


	subroutine verify_initial
	use vars
	implicit none
	!$acc routine seq

	if (allocated (b)) error stop "verify_initial allocated"
	if (any (lbound (b) /= [0])) error stop "verify_initial lbound"
	if (any (ubound (b) /= [0])) error stop "verify_initial ubound"
	end subroutine verify_initial

	subroutine verify_n1_allocated
	use vars
	implicit none
	!$acc routine seq

	if (.not.allocated (b)) error stop "verify_n1_allocated allocated"
	if (any (lbound (b) /= [n1_lb])) error stop "verify_n1_allocated lbound"
	if (any (ubound (b) /= [n1_ub])) error stop "verify_n1_allocated ubound"
	end subroutine verify_n1_allocated

	subroutine verify_n1_values (addend)
	use vars
	implicit none
	!$acc routine gang
	integer, value :: addend
	integer :: i

	!$acc loop
	do i = n1_lb, n1_ub
	if (b(i) /= i + addend) error stop
	end do
	end subroutine verify_n1_values

	subroutine verify_n1_deallocated (expect_allocated)
	use vars
	implicit none
	!$acc routine seq
	logical, value :: expect_allocated

	if (allocated(b) .neqv. expect_allocated) error stop "verify_n1_deallocated allocated"
	! Apparently 'deallocate'ing doesn't unset the bounds.
	if (any (lbound (b) /= [n1_lb])) error stop "verify_n1_deallocated lbound"
	if (any (ubound (b) /= [n1_ub])) error stop "verify_n1_deallocated ubound"
	end subroutine verify_n1_deallocated

	subroutine verify_n2_allocated
	use vars
	implicit none
	!$acc routine seq

	if (.not.allocated(b)) error stop "verify_n2_allocated allocated"
	if (any (lbound (b) /= [n2_lb])) error stop "verify_n2_allocated lbound"
	if (any (ubound (b) /= [n2_ub])) error stop "verify_n2_allocated ubound"
	end subroutine verify_n2_allocated

	subroutine verify_n2_values (addend)
	use vars
	implicit none
	!$acc routine gang
	integer, value :: addend
	integer :: i

	!$acc loop
	do i = n2_lb, n2_ub
	if (b(i) /= i + addend) error stop
	end do
	end subroutine verify_n2_values

	subroutine verify_n2_deallocated (expect_allocated)
	use vars
	implicit none
	!$acc routine seq
	logical, value :: expect_allocated

	if (allocated(b) .neqv. expect_allocated) error stop "verify_n2_deallocated allocated"
	! Apparently 'deallocate'ing doesn't unset the bounds.
	if (any (lbound (b) /= [n2_lb])) error stop "verify_n2_deallocated lbound"
	if (any (ubound (b) /= [n2_ub])) error stop "verify_n2_deallocated ubound"
	end subroutine verify_n2_deallocated