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fft_fftw3.f90
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fft_fftw3.f90
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!=======================================================================
! This is part of the 2DECOMP&FFT library
!
! 2DECOMP&FFT is a software framework for general-purpose 2D (pencil)
! decomposition. It also implements a highly scalable distributed
! three-dimensional Fast Fourier Transform (FFT).
!
! Copyright (C) 2009-2011 Ning Li, the Numerical Algorithms Group (NAG)
!
!=======================================================================
! This is the FFTW (version 3.x) implementation of the FFT library
module decomp_2d_fft
use decomp_2d ! 2D decomposition module
implicit none
include "fftw3.f"
private ! Make everything private unless declared public
! engine-specific global variables
integer, save :: plan_type = FFTW_MEASURE
! FFTW plans
! j=1,2,3 corresponds to the 1D FFTs in X,Y,Z direction, respectively
! For c2c transforms:
! use plan(-1,j) for forward transform;
! use plan( 1,j) for backward transform;
! For r2c/c2r transforms:
! use plan(0,j) for r2c transforms;
! use plan(2,j) for c2r transforms;
integer*8, save :: plan(-1:2,3)
! common code used for all engines, including global variables,
! generic interface definitions and several subroutines
#include "fft_common.f90"
! Return a FFTW3 plan for multiple 1D c2c FFTs in X direction
subroutine c2c_1m_x_plan(plan1, decomp, isign)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp
integer, intent(IN) :: isign
complex(mytype), allocatable, dimension(:,:,:) :: a1
allocate(a1(decomp%xsz(1),decomp%xsz(2),decomp%xsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft(plan1, 1, decomp%xsz(1), &
decomp%xsz(2)*decomp%xsz(3), a1, decomp%xsz(1), 1, &
decomp%xsz(1), a1, decomp%xsz(1), 1, decomp%xsz(1), &
isign, plan_type)
#else
call sfftw_plan_many_dft(plan1, 1, decomp%xsz(1), &
decomp%xsz(2)*decomp%xsz(3), a1, decomp%xsz(1), 1, &
decomp%xsz(1), a1, decomp%xsz(1), 1, decomp%xsz(1), &
isign, plan_type)
#endif
deallocate(a1)
return
end subroutine c2c_1m_x_plan
! Return a FFTW3 plan for multiple 1D c2c FFTs in Y direction
subroutine c2c_1m_y_plan(plan1, decomp, isign)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp
integer, intent(IN) :: isign
complex(mytype), allocatable, dimension(:,:) :: a1
! Due to memory pattern of 3D arrays, 1D FFTs along Y have to be
! done one Z-plane at a time. So plan for 2D data sets here.
allocate(a1(decomp%ysz(1),decomp%ysz(2)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft(plan1, 1, decomp%ysz(2), decomp%ysz(1), &
a1, decomp%ysz(2), decomp%ysz(1), 1, a1, decomp%ysz(2), &
decomp%ysz(1), 1, isign, plan_type)
#else
call sfftw_plan_many_dft(plan1, 1, decomp%ysz(2), decomp%ysz(1), &
a1, decomp%ysz(2), decomp%ysz(1), 1, a1, decomp%ysz(2), &
decomp%ysz(1), 1, isign, plan_type)
#endif
deallocate(a1)
return
end subroutine c2c_1m_y_plan
! Return a FFTW3 plan for multiple 1D c2c FFTs in Z direction
subroutine c2c_1m_z_plan(plan1, decomp, isign)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp
integer, intent(IN) :: isign
complex(mytype), allocatable, dimension(:,:,:) :: a1
allocate(a1(decomp%zsz(1),decomp%zsz(2),decomp%zsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft(plan1, 1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), a1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), 1, a1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), 1, isign, plan_type)
#else
call sfftw_plan_many_dft(plan1, 1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), a1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), 1, a1, decomp%zsz(3), &
decomp%zsz(1)*decomp%zsz(2), 1, isign, plan_type)
#endif
deallocate(a1)
return
end subroutine c2c_1m_z_plan
! Return a FFTW3 plan for multiple 1D r2c FFTs in X direction
subroutine r2c_1m_x_plan(plan1, decomp_ph, decomp_sp)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp_ph
TYPE(DECOMP_INFO), intent(IN) :: decomp_sp
real(mytype), allocatable, dimension(:,:,:) :: a1
complex(mytype), allocatable, dimension(:,:,:) :: a2
allocate(a1(decomp_ph%xsz(1),decomp_ph%xsz(2),decomp_ph%xsz(3)))
allocate(a2(decomp_sp%xsz(1),decomp_sp%xsz(2),decomp_sp%xsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft_r2c(plan1, 1, decomp_ph%xsz(1), &
decomp_ph%xsz(2)*decomp_ph%xsz(3), a1, decomp_ph%xsz(1), 1, &
decomp_ph%xsz(1), a2, decomp_sp%xsz(1), 1, decomp_sp%xsz(1), &
plan_type)
#else
call sfftw_plan_many_dft_r2c(plan1, 1, decomp_ph%xsz(1), &
decomp_ph%xsz(2)*decomp_ph%xsz(3), a1, decomp_ph%xsz(1), 1, &
decomp_ph%xsz(1), a2, decomp_sp%xsz(1), 1, decomp_sp%xsz(1), &
plan_type)
#endif
deallocate(a1,a2)
return
end subroutine r2c_1m_x_plan
! Return a FFTW3 plan for multiple 1D c2r FFTs in X direction
subroutine c2r_1m_x_plan(plan1, decomp_sp, decomp_ph)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp_sp
TYPE(DECOMP_INFO), intent(IN) :: decomp_ph
complex(mytype), allocatable, dimension(:,:,:) :: a1
real(mytype), allocatable, dimension(:,:,:) :: a2
allocate(a1(decomp_sp%xsz(1),decomp_sp%xsz(2),decomp_sp%xsz(3)))
allocate(a2(decomp_ph%xsz(1),decomp_ph%xsz(2),decomp_ph%xsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft_c2r(plan1, 1, decomp_ph%xsz(1), &
decomp_ph%xsz(2)*decomp_ph%xsz(3), a1, decomp_sp%xsz(1), 1, &
decomp_sp%xsz(1), a2, decomp_ph%xsz(1), 1, decomp_ph%xsz(1), &
plan_type)
#else
call sfftw_plan_many_dft_c2r(plan1, 1, decomp_ph%xsz(1), &
decomp_ph%xsz(2)*decomp_ph%xsz(3), a1, decomp_sp%xsz(1), 1, &
decomp_sp%xsz(1), a2, decomp_ph%xsz(1), 1, decomp_ph%xsz(1), &
plan_type)
#endif
deallocate(a1,a2)
return
end subroutine c2r_1m_x_plan
! Return a FFTW3 plan for multiple 1D r2c FFTs in Z direction
subroutine r2c_1m_z_plan(plan1, decomp_ph, decomp_sp)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp_ph
TYPE(DECOMP_INFO), intent(IN) :: decomp_sp
real(mytype), allocatable, dimension(:,:,:) :: a1
complex(mytype), allocatable, dimension(:,:,:) :: a2
allocate(a1(decomp_ph%zsz(1),decomp_ph%zsz(2),decomp_ph%zsz(3)))
allocate(a2(decomp_sp%zsz(1),decomp_sp%zsz(2),decomp_sp%zsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft_r2c(plan1, 1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), a1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), 1, a2, decomp_sp%zsz(3), &
decomp_sp%zsz(1)*decomp_sp%zsz(2), 1, plan_type)
#else
call sfftw_plan_many_dft_r2c(plan1, 1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), a1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), 1, a2, decomp_sp%zsz(3), &
decomp_sp%zsz(1)*decomp_sp%zsz(2), 1, plan_type)
#endif
deallocate(a1,a2)
return
end subroutine r2c_1m_z_plan
! Return a FFTW3 plan for multiple 1D c2r FFTs in Z direction
subroutine c2r_1m_z_plan(plan1, decomp_sp, decomp_ph)
implicit none
integer*8, intent(OUT) :: plan1
TYPE(DECOMP_INFO), intent(IN) :: decomp_sp
TYPE(DECOMP_INFO), intent(IN) :: decomp_ph
complex(mytype), allocatable, dimension(:,:,:) :: a1
real(mytype), allocatable, dimension(:,:,:) :: a2
allocate(a1(decomp_sp%zsz(1),decomp_sp%zsz(2),decomp_sp%zsz(3)))
allocate(a2(decomp_ph%zsz(1),decomp_ph%zsz(2),decomp_ph%zsz(3)))
#ifdef DOUBLE_PREC
call dfftw_plan_many_dft_c2r(plan1, 1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), a1, decomp_sp%zsz(3), &
decomp_sp%zsz(1)*decomp_sp%zsz(2), 1, a2, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), 1, plan_type)
#else
call sfftw_plan_many_dft_c2r(plan1, 1, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), a1, decomp_sp%zsz(3), &
decomp_sp%zsz(1)*decomp_sp%zsz(2), 1, a2, decomp_ph%zsz(3), &
decomp_ph%zsz(1)*decomp_ph%zsz(2), 1, plan_type)
#endif
deallocate(a1,a2)
return
end subroutine c2r_1m_z_plan
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! This routine performs one-time initialisations for the FFT engine
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine init_fft_engine
implicit none
if (nrank==0) then
write(*,*) ' '
write(*,*) '***** Using the FFTW (version 3.x) engine *****'
write(*,*) ' '
end if
if (format == PHYSICAL_IN_X) then
! For C2C transforms
call c2c_1m_x_plan(plan(-1,1), ph, FFTW_FORWARD )
call c2c_1m_y_plan(plan(-1,2), ph, FFTW_FORWARD )
call c2c_1m_z_plan(plan(-1,3), ph, FFTW_FORWARD )
call c2c_1m_z_plan(plan( 1,3), ph, FFTW_BACKWARD)
call c2c_1m_y_plan(plan( 1,2), ph, FFTW_BACKWARD)
call c2c_1m_x_plan(plan( 1,1), ph, FFTW_BACKWARD)
! For R2C/C2R tranforms
call r2c_1m_x_plan(plan(0,1), ph, sp)
call c2c_1m_y_plan(plan(0,2), sp, FFTW_FORWARD )
call c2c_1m_z_plan(plan(0,3), sp, FFTW_FORWARD )
call c2c_1m_z_plan(plan(2,3), sp, FFTW_BACKWARD)
call c2c_1m_y_plan(plan(2,2), sp, FFTW_BACKWARD)
call c2r_1m_x_plan(plan(2,1), sp, ph)
else if (format == PHYSICAL_IN_Z) then
! For C2C transforms
call c2c_1m_z_plan(plan(-1,3), ph, FFTW_FORWARD )
call c2c_1m_y_plan(plan(-1,2), ph, FFTW_FORWARD )
call c2c_1m_x_plan(plan(-1,1), ph, FFTW_FORWARD )
call c2c_1m_x_plan(plan( 1,1), ph, FFTW_BACKWARD)
call c2c_1m_y_plan(plan( 1,2), ph, FFTW_BACKWARD)
call c2c_1m_z_plan(plan( 1,3), ph, FFTW_BACKWARD)
! For R2C/C2R tranforms
call r2c_1m_z_plan(plan(0,3), ph, sp)
call c2c_1m_y_plan(plan(0,2), sp, FFTW_FORWARD )
call c2c_1m_x_plan(plan(0,1), sp, FFTW_FORWARD )
call c2c_1m_x_plan(plan(2,1), sp, FFTW_BACKWARD)
call c2c_1m_y_plan(plan(2,2), sp, FFTW_BACKWARD)
call c2r_1m_z_plan(plan(2,3), sp, ph)
end if
return
end subroutine init_fft_engine
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! This routine performs one-time finalisations for the FFT engine
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine finalize_fft_engine
implicit none
integer :: i,j
do j=1,3
do i=-1,2
#ifdef DOUBLE_PREC
call dfftw_destroy_plan(plan(i,j))
#else
call sfftw_destroy_plan(plan(i,j))
#endif
end do
end do
return
end subroutine finalize_fft_engine
! Following routines calculate multiple one-dimensional FFTs to form
! the basis of three-dimensional FFTs.
! c2c transform, multiple 1D FFTs in x direction
subroutine c2c_1m_x(inout, isign, plan1)
implicit none
complex(mytype), dimension(:,:,:), intent(INOUT) :: inout
integer, intent(IN) :: isign
integer*8, intent(IN) :: plan1
#ifdef DOUBLE_PREC
call dfftw_execute_dft(plan1, inout, inout)
#else
call sfftw_execute_dft(plan1, inout, inout)
#endif
return
end subroutine c2c_1m_x
! c2c transform, multiple 1D FFTs in y direction
subroutine c2c_1m_y(inout, isign, plan1)
implicit none
complex(mytype), dimension(:,:,:), intent(INOUT) :: inout
integer, intent(IN) :: isign
integer*8, intent(IN) :: plan1
integer :: k, s3
! transform on one Z-plane at a time
s3 = size(inout,3)
do k=1,s3
#ifdef DOUBLE_PREC
call dfftw_execute_dft(plan1, inout(:,:,k), inout(:,:,k))
#else
call sfftw_execute_dft(plan1, inout(:,:,k), inout(:,:,k))
#endif
end do
return
end subroutine c2c_1m_y
! c2c transform, multiple 1D FFTs in z direction
subroutine c2c_1m_z(inout, isign, plan1)
implicit none
complex(mytype), dimension(:,:,:), intent(INOUT) :: inout
integer, intent(IN) :: isign
integer*8, intent(IN) :: plan1
#ifdef DOUBLE_PREC
call dfftw_execute_dft(plan1, inout, inout)
#else
call sfftw_execute_dft(plan1, inout, inout)
#endif
return
end subroutine c2c_1m_z
! r2c transform, multiple 1D FFTs in x direction
subroutine r2c_1m_x(input, output)
implicit none
real(mytype), dimension(:,:,:), intent(IN) :: input
complex(mytype), dimension(:,:,:), intent(OUT) :: output
#ifdef DOUBLE_PREC
call dfftw_execute_dft_r2c(plan(0,1), input, output)
#else
call sfftw_execute_dft_r2c(plan(0,1), input, output)
#endif
return
end subroutine r2c_1m_x
! r2c transform, multiple 1D FFTs in z direction
subroutine r2c_1m_z(input, output)
implicit none
real(mytype), dimension(:,:,:), intent(IN) :: input
complex(mytype), dimension(:,:,:), intent(OUT) :: output
#ifdef DOUBLE_PREC
call dfftw_execute_dft_r2c(plan(0,3), input, output)
#else
call sfftw_execute_dft_r2c(plan(0,3), input, output)
#endif
return
end subroutine r2c_1m_z
! c2r transform, multiple 1D FFTs in x direction
subroutine c2r_1m_x(input, output)
implicit none
complex(mytype), dimension(:,:,:), intent(IN) :: input
real(mytype), dimension(:,:,:), intent(OUT) :: output
#ifdef DOUBLE_PREC
call dfftw_execute_dft_c2r(plan(2,1), input, output)
#else
call sfftw_execute_dft_c2r(plan(2,1), input, output)
#endif
return
end subroutine c2r_1m_x
! c2r transform, multiple 1D FFTs in z direction
subroutine c2r_1m_z(input, output)
implicit none
complex(mytype), dimension(:,:,:), intent(IN) :: input
real(mytype), dimension(:,:,:), intent(OUT) :: output
#ifdef DOUBLE_PREC
call dfftw_execute_dft_c2r(plan(2,3), input, output)
#else
call sfftw_execute_dft_c2r(plan(2,3), input, output)
#endif
return
end subroutine c2r_1m_z
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! 3D FFT - complex to complex
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine fft_3d_c2c(in, out, isign)
implicit none
complex(mytype), dimension(:,:,:), intent(INOUT) :: in
complex(mytype), dimension(:,:,:), intent(OUT) :: out
integer, intent(IN) :: isign
#ifndef OVERWRITE
complex(mytype), allocatable, dimension(:,:,:) :: wk1
#endif
if (format==PHYSICAL_IN_X .AND. isign==DECOMP_2D_FFT_FORWARD .OR. &
format==PHYSICAL_IN_Z .AND. isign==DECOMP_2D_FFT_BACKWARD) then
! ===== 1D FFTs in X =====
#ifdef OVERWRITE
call c2c_1m_x(in,isign,plan(isign,1))
#else
allocate (wk1(ph%xsz(1),ph%xsz(2),ph%xsz(3)))
wk1 = in
call c2c_1m_x(wk1,isign,plan(isign,1))
#endif
! ===== Swap X --> Y; 1D FFTs in Y =====
if (dims(1)>1) then
#ifdef OVERWRITE
call transpose_x_to_y(in,wk2_c2c,ph)
#else
call transpose_x_to_y(wk1,wk2_c2c,ph)
#endif
call c2c_1m_y(wk2_c2c,isign,plan(isign,2))
else
#ifdef OVERWRITE
call c2c_1m_y(in,isign,plan(isign,2))
#else
call c2c_1m_y(wk1,isign,plan(isign,2))
#endif
end if
! ===== Swap Y --> Z; 1D FFTs in Z =====
if (dims(1)>1) then
call transpose_y_to_z(wk2_c2c,out,ph)
else
#ifdef OVERWRITE
call transpose_y_to_z(in,out,ph)
#else
call transpose_y_to_z(wk1,out,ph)
#endif
end if
call c2c_1m_z(out,isign,plan(isign,3))
else if (format==PHYSICAL_IN_X .AND. isign==DECOMP_2D_FFT_BACKWARD &
.OR. &
format==PHYSICAL_IN_Z .AND. isign==DECOMP_2D_FFT_FORWARD) then
! ===== 1D FFTs in Z =====
#ifdef OVERWRITE
call c2c_1m_z(in,isign,plan(isign,3))
#else
allocate (wk1(ph%zsz(1),ph%zsz(2),ph%zsz(3)))
wk1 = in
call c2c_1m_z(wk1,isign,plan(isign,3))
#endif
! ===== Swap Z --> Y; 1D FFTs in Y =====
if (dims(1)>1) then
#ifdef OVERWRITE
call transpose_z_to_y(in,wk2_c2c,ph)
#else
call transpose_z_to_y(wk1,wk2_c2c,ph)
#endif
call c2c_1m_y(wk2_c2c,isign,plan(isign,2))
else ! out==wk2_c2c if 1D decomposition
#ifdef OVERWRITE
call transpose_z_to_y(in,out,ph)
#else
call transpose_z_to_y(wk1,out,ph)
#endif
call c2c_1m_y(out,isign,plan(isign,2))
end if
! ===== Swap Y --> X; 1D FFTs in X =====
if (dims(1)>1) then
call transpose_y_to_x(wk2_c2c,out,ph)
end if
call c2c_1m_x(out,isign,plan(isign,1))
end if
#ifndef OVERWRITE
deallocate (wk1)
#endif
return
end subroutine fft_3d_c2c
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! 3D forward FFT - real to complex
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine fft_3d_r2c(in_r, out_c)
implicit none
real(mytype), dimension(:,:,:), intent(IN) :: in_r
complex(mytype), dimension(:,:,:), intent(OUT) :: out_c
if (format==PHYSICAL_IN_X) then
! ===== 1D FFTs in X =====
call r2c_1m_x(in_r,wk13)
! ===== Swap X --> Y; 1D FFTs in Y =====
if (dims(1)>1) then
call transpose_x_to_y(wk13,wk2_r2c,sp)
call c2c_1m_y(wk2_r2c,-1,plan(0,2))
else
call c2c_1m_y(wk13,-1,plan(0,2))
end if
! ===== Swap Y --> Z; 1D FFTs in Z =====
if (dims(1)>1) then
call transpose_y_to_z(wk2_r2c,out_c,sp)
else
call transpose_y_to_z(wk13,out_c,sp)
end if
call c2c_1m_z(out_c,-1,plan(0,3))
else if (format==PHYSICAL_IN_Z) then
! ===== 1D FFTs in Z =====
call r2c_1m_z(in_r,wk13)
! ===== Swap Z --> Y; 1D FFTs in Y =====
if (dims(1)>1) then
call transpose_z_to_y(wk13,wk2_r2c,sp)
call c2c_1m_y(wk2_r2c,-1,plan(0,2))
else ! out_c==wk2_r2c if 1D decomposition
call transpose_z_to_y(wk13,out_c,sp)
call c2c_1m_y(out_c,-1,plan(0,2))
end if
! ===== Swap Y --> X; 1D FFTs in X =====
if (dims(1)>1) then
call transpose_y_to_x(wk2_r2c,out_c,sp)
end if
call c2c_1m_x(out_c,-1,plan(0,1))
end if
return
end subroutine fft_3d_r2c
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! 3D inverse FFT - complex to real
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine fft_3d_c2r(in_c, out_r)
implicit none
complex(mytype), dimension(:,:,:), intent(INOUT) :: in_c
real(mytype), dimension(:,:,:), intent(OUT) :: out_r
#ifndef OVERWRITE
complex(mytype), allocatable, dimension(:,:,:) :: wk1
#endif
if (format==PHYSICAL_IN_X) then
! ===== 1D FFTs in Z =====
#ifdef OVERWRITE
call c2c_1m_z(in_c,1,plan(2,3))
#else
allocate (wk1(sp%zsz(1),sp%zsz(2),sp%zsz(3)))
wk1 = in_c
call c2c_1m_z(wk1,1,plan(2,3))
#endif
! ===== Swap Z --> Y; 1D FFTs in Y =====
#ifdef OVERWRITE
call transpose_z_to_y(in_c,wk2_r2c,sp)
#else
call transpose_z_to_y(wk1,wk2_r2c,sp)
#endif
call c2c_1m_y(wk2_r2c,1,plan(2,2))
! ===== Swap Y --> X; 1D FFTs in X =====
if (dims(1)>1) then
call transpose_y_to_x(wk2_r2c,wk13,sp)
call c2r_1m_x(wk13,out_r)
else
call c2r_1m_x(wk2_r2c,out_r)
end if
else if (format==PHYSICAL_IN_Z) then
! ===== 1D FFTs in X =====
#ifdef OVERWRITE
call c2c_1m_x(in_c,1,plan(2,1))
#else
allocate(wk1(sp%xsz(1),sp%xsz(2),sp%xsz(3)))
wk1 = in_c
call c2c_1m_x(wk1,1,plan(2,1))
#endif
! ===== Swap X --> Y; 1D FFTs in Y =====
if (dims(1)>1) then
#ifdef OVERWRITE
call transpose_x_to_y(in_c,wk2_r2c,sp)
#else
call transpose_x_to_y(wk1,wk2_r2c,sp)
#endif
call c2c_1m_y(wk2_r2c,1,plan(2,2))
else ! in_c==wk2_r2c if 1D decomposition
#ifdef OVERWRITE
call c2c_1m_y(in_c,1,plan(2,2))
#else
call c2c_1m_y(wk1,1,plan(2,2))
#endif
end if
! ===== Swap Y --> Z; 1D FFTs in Z =====
if (dims(1)>1) then
call transpose_y_to_z(wk2_r2c,wk13,sp)
else
#ifdef OVERWRITE
call transpose_y_to_z(in_c,wk13,sp)
#else
call transpose_y_to_z(wk1,wk13,sp)
#endif
end if
call c2r_1m_z(wk13,out_r)
end if
#ifndef OVERWRITE
deallocate (wk1)
#endif
return
end subroutine fft_3d_c2r
end module decomp_2d_fft