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temperton_fft.f90 @ 1207

Last change on this file since 1207 was 392, checked in by raasch, 15 years ago

New:
---

Adapted for machine lck
(mrun, mbuild, subjob)

bc_lr/bc_ns in most subroutines replaced by LOGICAL variables bc_lr_cyc,
bc_ns_cyc for speed optimization
(check_parameters, diffusion_u, diffusion_v, diffusion_w, modules)

Additional timestep criterion in case of simulations with plant canopy (timestep)

Check for illegal entries in section_xy|xz|yz that exceed nz+1|ny+1|nx+1
(check_parameters)

Clipping of dvrp output implemented. Default colourtable for particles
implemented, particle attributes (color, dvrp_size) can be set with new
parameters particle_color, particle_dvrpsize, color_interval,
dvrpsize_interval (init_dvrp, data_output_dvrp, modules, user_data_output_dvrp).
Slicer attributes (dvrp) are set with new routine set_slicer_attributes_dvrp
and are controlled with existing parameters slicer_range_limits.
(set_slicer_attributes_dvrp)

Ocean atmosphere coupling allows to use independent precursor runs in order
to account for different spin-up times. The time when coupling has to be
started is given by new inipar parameter coupling_start_time. The precursor
ocean run has to be started using new mrun option "-y" in order to add
appendix "_O" to all output files.
(check_for_restart, check_parameters, data_output_2d, data_output_3d,
data_output_profiles, data_output_ptseries, data_output_spectra,
data_output_tseries, header, init_coupling, modules, mrun,
parin, read_var_list, surface_coupler, time_integration, write_var_list)

Polygon reduction for topography and ground plate isosurface. Reduction level
for buildings can be chosen with parameter cluster_size. (init_dvrp)

External pressure gradient (check_parameters, header, init_3d_model, modules,
parin, prognostic_equations, read_var_list, write_var_list)

New topography case 'single_street_canyon' (header, init_grid, modules, parin,
read_var_list, user_check_parameters, user_header, user_init_grid, write_var_list)

Option to predefine a target bulk velocity for conserve_volume_flow
(check_parameters, header, init_3d_model, modules, parin, read_var_list,
write_var_list)

Option for user defined 2D data output in xy cross sections at z=nzb+1
(data_output_2d, user_data_output_2d)

xy cross section output of surface heatfluxes (latent, sensible)
(average_3d_data, check_parameters, data_output_2d, modules, read_3d_binary,
sum_up_3d_data, write_3d_binary)

average_3d_data, check_for_restart, check_parameters, data_output_2d, data_output_3d, data_output_dvrp, data_output_profiles, data_output_ptseries, data_output_spectra, data_output_tseries, init_coupling, init_dvrp, init_grid, init_3d_model, header, mbuild, modules, mrun, package_parin, parin, prognostic_equations, read_3d_binary, read_var_list, subjob, surface_coupler, timestep, time_integration, user_check_parameters, user_data_output_2d, user_data_output_dvrp, user_header, user_init_grid, write_3d_binary, write_var_list

New: set_particle_attributes, set_slicer_attributes_dvrp

Changed:

lcmuk changed to lc to avoid problems with Intel compiler on sgi-ice
(poisfft)

For extended NetCDF files, the updated title attribute includes an update of
time_average_text where appropriate. (netcdf)

In case of restart runs without extension, initial profiles are not written
to NetCDF-file anymore. (data_output_profiles, modules, read_var_list, write_var_list)

Small change in formatting of the message handling routine concering the output in the
job protocoll. (message)

initializing_actions='read_data_for_recycling' renamed to 'cyclic_fill', now
independent of turbulent_inflow (check_parameters, header, init_3d_model)

2 NetCDF error numbers changed. (data_output_3d)

A Link to the website appendix_a.html is printed for further information
about the possible errors. (message)

Temperature gradient criterion for estimating the boundary layer height
replaced by the gradient criterion of Sullivan et al. (1998). (flow_statistics)

NetCDF unit attribute in timeseries output in case of statistic regions added
(netcdf)

Output of NetCDF messages with aid of message handling routine.
(check_open, close_file, data_output_2d, data_output_3d,
data_output_profiles, data_output_ptseries, data_output_spectra,
data_output_tseries, netcdf, output_particles_netcdf)

Output of messages replaced by message handling routine.
(advec_particles, advec_s_bc, buoyancy, calc_spectra, check_for_restart,
check_open, coriolis, cpu_log, data_output_2d, data_output_3d, data_output_dvrp,
data_output_profiles, data_output_spectra, fft_xy, flow_statistics, header,
init_1d_model, init_3d_model, init_dvrp, init_grid, init_particles, init_pegrid,
netcdf, parin, plant_canopy_model, poisfft_hybrid, poismg, read_3d_binary,
read_var_list, surface_coupler, temperton_fft, timestep, user_actions,
user_data_output_dvrp, user_dvrp_coltab, user_init_grid, user_init_plant_canopy,
user_parin, user_read_restart_data, user_spectra )

Maximum number of tails is calculated from maximum number of particles and
skip_particles_for_tail (init_particles)

Value of vertical_particle_advection may differ for each particle group
(advec_particles, header, modules)

First constant in array den also defined as type double. (eqn_state_seawater)

Parameter dvrp_psize moved from particles_par to dvrp_graphics_par. (package_parin)

topography_grid_convention moved from userpar to inipar (check_parameters,
header, parin, read_var_list, user_check_parameters, user_header,
user_init_grid, user_parin, write_var_list)

Default value of grid_matching changed to strict.

Adjustments for runs on lcxt4 (necessary due to an software update on CRAY) and
for coupled runs on ibmy (mrun, subjob)

advec_particles, advec_s_bc, buoyancy, calc_spectra, check_for_restart, check_open, check_parameters, close_file, coriolis, cpu_log, data_output_2d, data_output_3d, data_output_dvrp, data_output_profiles, data_output_ptseries, data_output_spectra, data_output_tseries, eqn_state_seawater, fft_xy, flow_statistics, header, init_1d_model, init_3d_model, init_dvrp, init_grid, init_particles, init_pegrid, message, mrun, netcdf, output_particles_netcdf, package_parin, parin, plant_canopy_model, poisfft, poisfft_hybrid, poismg, read_3d_binary, read_var_list, sort_particles, subjob, user_check_parameters, user_header, user_init_grid, user_parin, surface_coupler, temperton_fft, timestep, user_actions, user_data_output_dvrp, user_dvrp_coltab, user_init_grid, user_init_plant_canopy, user_parin, user_read_restart_data, user_spectra, write_var_list

Errors:

Bugfix: Initial hydrostatic pressure profile in case of ocean runs is now
calculated in 5 iteration steps. (init_ocean)

Bugfix: wrong sign in buoyancy production of ocean part in case of not using
the reference density (only in 3D routine production_e) (production_e)

Bugfix: output of averaged 2d/3d quantities requires that an avaraging
interval has been set, respective error message is included (check_parameters)

Bugfix: Output on unit 14 only if requested by write_binary.
(user_last_actions)

Bugfix to avoid zero division by km_neutral (production_e)

Bugfix for extended NetCDF files: In order to avoid 'data mode' errors if
updated attributes are larger than their original size, NF90_PUT_ATT is called
in 'define mode' enclosed by NF90_REDEF and NF90_ENDDEF calls. This implies a
possible performance loss; an alternative strategy would be to ensure equal
attribute size in a job chain. (netcdf)

Bugfix: correction of initial volume flow for non-flat topography (init_3d_model)
Bugfix: zero initialization of arrays within buildings for 'cyclic_fill' (init_3d_model)

Bugfix: to_be_resorted => s_av for time-averaged scalars (data_output_2d, data_output_3d)

Bugfix: error in formatting the output (message)

Bugfix: avoid that ngp_2dh_s_inner becomes zero (init_3_model)

Typographical error: unit of wpt in dots_unit (modules)

Bugfix: error in check, if particles moved further than one subdomain length.
This check must not be applied for newly released particles. (advec_particles)

Bugfix: several tail counters are initialized, particle_tail_coordinates is
only written to file if its third index is > 0, arrays for tails are allocated
with a minimum size of 10 tails if there is no tail initially (init_particles,
advec_particles)

Bugfix: pressure included for profile output (check_parameters)

Bugfix: Type of count and count_rate changed to default INTEGER on NEC machines
(cpu_log)

Bugfix: output if particle time series only if particle advection is switched
on. (time_integration)

Bugfix: qsws was calculated in case of constant heatflux = .FALSE. (prandtl_fluxes)

Bugfix: averaging along z is not allowed for 2d quantities (e.g. u* and z0) (data_output_2d)

Typographical errors (netcdf)

If the inversion height calculated by the prerun is zero, inflow_damping_height
must be explicitly specified (init_3d_model)

Small bugfix concerning 3d 64bit netcdf output format (header)

Bugfix: dt_fixed removed from the restart file, because otherwise, no change
from a fixed to a variable timestep would be possible in restart runs.
(read_var_list, write_var_list)

Bugfix: initial setting of time_coupling in coupled restart runs (time_integration)

advec_particles, check_parameters, cpu_log, data_output_2d, data_output_3d, header, init_3d_model, init_particles, init_ocean, modules, netcdf, prandtl_fluxes, production_e, read_var_list, time_integration, user_last_actions, write_var_list

Property svn:keywords set to Id

File size: 51.3 KB

Line
1	MODULE temperton_fft
2
3	!------------------------------------------------------------------------------!
4	! Current revisions:
5	! -----------------
6	!
7	!
8	! Former revisions:
9	! -----------------
10	! $Id: temperton_fft.f90 392 2009-09-24 10:39:14Z witha $
11	!
12	! 258 2009-03-13 12:36:03Z heinze
13	! Output of messages replaced by message handling routine.
14	!
15	! Feb. 2007
16	! RCS Log replace by Id keyword, revision history cleaned up
17	!
18	! Revision 1.2 2003/04/16 12:49:25 raasch
19	! Abort in case of illegal factors
20	!
21	! Revision 1.1 2003/03/12 16:41:59 raasch
22	! Initial revision
23	!
24	!
25	! Description:
26	! ------------
27	! Fast Fourier transformation developed by Clive Temperton, ECMWF.
28	!------------------------------------------------------------------------------!
29
30	IMPLICIT NONE
31
32	PRIVATE
33
34	PUBLIC set99, fft991cy
35
36
37	INTEGER :: nfax(10) ! array used by fft991.
38	REAL, ALLOCATABLE :: trig(:) ! array used by fft991.
39
40	!
41	!-- nfft: maximum length of calls to *fft.
42	#if defined( __nec )
43	INTEGER, PARAMETER :: nfft = 256
44	#else
45	INTEGER, PARAMETER :: nfft = 32
46	#endif
47
48	INTEGER, PARAMETER :: nout = 6 ! standard output stream
49
50	CONTAINS
51
52	SUBROUTINE fft991cy(a,work,trigs,ifax,inc,jump,n,lot,isign)
53
54	! Description:
55	!
56	! Calls fortran-versions of fft's.
57	!
58	! Method:
59	!
60	! Subroutine 'fft991cy' - multiple fast real periodic transform
61	! supersedes previous routine 'fft991cy'.
62	!
63	! Real transform of length n performed by removing redundant
64	! operations from complex transform of length n.
65	!
66	! a is the array containing input & output data.
67	! work is an area of size (n+1)*min(lot,nfft).
68	! trigs is a previously prepared list of trig function values.
69	! ifax is a previously prepared list of factors of n.
70	! inc is the increment within each data 'vector'
71	! (e.g. inc=1 for consecutively stored data).
72	! jump is the increment between the start of each data vector.
73	! n is the length of the data vectors.
74	! lot is the number of data vectors.
75	! isign = +1 for transform from spectral to gridpoint
76	! = -1 for transform from gridpoint to spectral.
77	!
78	! ordering of coefficients:
79	! a(0),b(0),a(1),b(1),a(2),b(2),.,a(n/2),b(n/2)
80	! where b(0)=b(n/2)=0; (n+2) locations required.
81	!
82	! ordering of data:
83	! x(0),x(1),x(2),.,x(n-1), 0 , 0 ; (n+2) locations required.
84	!
85	! Vectorization is achieved on cray by doing the transforms
86	! in parallel.
87	!
88	! n must be composed of factors 2,3 & 5 but does not have to be even.
89	!
90	! definition of transforms:
91	!
92	! isign=+1: x(j)=sum(k=0,.,n-1)(c(k)exp(2ijk*pi/n))
93	! where c(k)=a(k)+ib(k) and c(n-k)=a(k)-ib(k)
94
95	! isign=-1: a(k)=(1/n)sum(j=0,.,n-1)(x(j)cos(2jk*pi/n))
96	! b(k)=-(1/n)sum(j=0,.,n-1)(x(j)sin(2jk*pi/n))
97
98	! calls fortran-versions of fft's !!!
99	! dimension a(n),work(n),trigs(n),ifax(1)
100
101
102	IMPLICIT NONE
103
104	! Scalar arguments
105	INTEGER :: inc, isign, jump, lot, n
106
107	! Array arguments
108	REAL :: a(), trigs(), work(*)
109	INTEGER :: ifax(*)
110
111	! Local scalars:
112	INTEGER :: i, ia, ibase, ierr, ifac, igo, ii, istart, ix, iz, j, jbase, jj, &
113	& k, la, nb, nblox, nfax, nvex, nx
114
115	! Intrinsic functions
116	INTRINSIC MOD
117
118
119	! Executable statements
120
121	IF (ifax(10)/=n) CALL set99(trigs,ifax,n)
122	nfax = ifax(1)
123	nx = n + 1
124	IF (MOD(n,2)==1) nx = n
125	nblox = 1 + (lot-1)/nfft
126	nvex = lot - (nblox-1)*nfft
127	IF (isign==-1) GO TO 50
128
129	! isign=+1, spectral to gridpoint transform
130
131	istart = 1
132	DO nb = 1, nblox
133	ia = istart
134	i = istart
135	!DIR$ IVDEP
136	!CDIR NODEP
137	!OCL NOVREC
138	DO j = 1, nvex
139	a(i+inc) = 0.5*a(i)
140	i = i + jump
141	END DO
142	IF (MOD(n,2)==1) GO TO 10
143	i = istart + n*inc
144	DO j = 1, nvex
145	a(i) = 0.5*a(i)
146	i = i + jump
147	END DO
148	10 CONTINUE
149	ia = istart + inc
150	la = 1
151	igo = + 1
152
153	DO k = 1, nfax
154	ifac = ifax(k+1)
155	ierr = -1
156	IF (igo==-1) GO TO 20
157	CALL rpassm(a(ia),a(ia+lainc),work(1),work(ifacla+1),trigs,inc,1, &
158	& jump,nx,nvex,n,ifac,la,ierr)
159	GO TO 30
160	20 CONTINUE
161	CALL rpassm(work(1),work(la+1),a(ia),a(ia+ifaclainc),trigs,1,inc,nx, &
162	& jump,nvex,n,ifac,la,ierr)
163	30 CONTINUE
164	IF (ierr/=0) GO TO 100
165	la = ifac*la
166	igo = -igo
167	ia = istart
168	END DO
169
170	! If necessary, copy results back to a
171
172	IF (MOD(nfax,2)==0) GO TO 40
173	ibase = 1
174	jbase = ia
175	DO jj = 1, nvex
176	i = ibase
177	j = jbase
178	DO ii = 1, n
179	a(j) = work(i)
180	i = i + 1
181	j = j + inc
182	END DO
183	ibase = ibase + nx
184	jbase = jbase + jump
185	END DO
186	40 CONTINUE
187
188	! Fill in zeros at end
189
190	ix = istart + n*inc
191	!DIR$ IVDEP
192	!CDIR NODEP
193	!OCL NOVREC
194	DO j = 1, nvex
195	a(ix) = 0.0
196	a(ix+inc) = 0.0
197	ix = ix + jump
198	END DO
199
200	istart = istart + nvex*jump
201	nvex = nfft
202	END DO
203	RETURN
204
205	! isign=-1, gridpoint to spectral transform
206
207	50 CONTINUE
208	istart = 1
209	DO nb = 1, nblox
210	ia = istart
211	la = n
212	igo = + 1
213
214	DO k = 1, nfax
215	ifac = ifax(nfax+2-k)
216	la = la/ifac
217	ierr = -1
218	IF (igo==-1) GO TO 60
219	CALL qpassm(a(ia),a(ia+ifaclainc),work(1),work(la+1),trigs,inc,1, &
220	& jump,nx,nvex,n,ifac,la,ierr)
221	GO TO 70
222	60 CONTINUE
223	CALL qpassm(work(1),work(ifacla+1),a(ia),a(ia+lainc),trigs,1,inc,nx, &
224	& jump,nvex,n,ifac,la,ierr)
225	70 CONTINUE
226	IF (ierr/=0) GO TO 100
227	igo = -igo
228	ia = istart + inc
229	END DO
230
231	! If necessary, copy results back to a
232
233	IF (MOD(nfax,2)==0) GO TO 80
234	ibase = 1
235	jbase = ia
236	DO jj = 1, nvex
237	i = ibase
238	j = jbase
239	DO ii = 1, n
240	a(j) = work(i)
241	i = i + 1
242	j = j + inc
243	END DO
244	ibase = ibase + nx
245	jbase = jbase + jump
246	END DO
247	80 CONTINUE
248
249	! Shift a(0) & fill in zero imag parts
250
251	ix = istart
252	!DIR$ IVDEP
253	!CDIR NODEP
254	!OCL NOVREC
255	DO j = 1, nvex
256	a(ix) = a(ix+inc)
257	a(ix+inc) = 0.0
258	ix = ix + jump
259	END DO
260	IF (MOD(n,2)==1) GO TO 90
261	iz = istart + (n+1)*inc
262	DO j = 1, nvex
263	a(iz) = 0.0
264	iz = iz + jump
265	END DO
266	90 CONTINUE
267
268	istart = istart + nvex*jump
269	nvex = nfft
270	END DO
271	RETURN
272
273	! Error messages
274
275	100 CONTINUE
276
277	SELECT CASE (ierr)
278	CASE (:-1)
279	WRITE (nout,'(A,I5,A)') ' Vector length =',nvex,', greater than nfft'
280	CASE (0)
281	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', not catered for'
282	CASE (1:)
283	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', only catered for if la*ifac=n'
284	END SELECT
285
286	RETURN
287	END SUBROUTINE fft991cy
288
289	SUBROUTINE qpassm(a,b,c,d,trigs,inc1,inc2,inc3,inc4,lot,n,ifac,la,ierr)
290
291	! Description:
292	!
293	! Performs one pass through data as part of
294	! multiple real fft (fourier analysis) routine.
295	!
296	! Method:
297	!
298	! a is first real input vector
299	! equivalence b(1) with a(ifaclainc1+1)
300	! c is first real output vector
301	! equivalence d(1) with c(la*inc2+1)
302	! trigs is a precalculated list of sines & cosines
303	! inc1 is the addressing increment for a
304	! inc2 is the addressing increment for c
305	! inc3 is the increment between input vectors a
306	! inc4 is the increment between output vectors c
307	! lot is the number of vectors
308	! n is the length of the vectors
309	! ifac is the current factor of n
310	! la = n/(product of factors used so far)
311	! ierr is an error indicator:
312	! 0 - pass completed without error
313	! 1 - lot greater than nfft
314	! 2 - ifac not catered for
315	! 3 - ifac only catered for if la=n/ifac
316	!
317
318	IMPLICIT NONE
319
320	! Scalar arguments
321	INTEGER :: ierr, ifac, inc1, inc2, inc3, inc4, la, lot, n
322
323	! Array arguments
324	! REAL :: a(n),b(n),c(n),d(n),trigs(n)
325	REAL :: a(), b(), c(), d(), trigs(*)
326
327	! Local scalars:
328	REAL :: a0, a1, a10, a11, a2, a20, a21, a3, a4, a5, a6, b0, b1, b10, b11, &
329	& b2, b20, b21, b3, b4, b5, b6, c1, c2, c3, c4, c5, qrt5, s1, s2, s3, s4, &
330	& s5, sin36, sin45, sin60, sin72, z, zqrt5, zsin36, zsin45, zsin60, &
331	& zsin72
332	INTEGER :: i, ia, ib, ibad, ibase, ic, id, ie, if, ig, igo, ih, iink, ijk, &
333	& ijump, j, ja, jb, jbase, jc, jd, je, jf, jink, k, kb, kc, kd, ke, kf, &
334	& kstop, l, m
335
336	! Intrinsic functions
337	INTRINSIC REAL, SQRT
338
339	! Data statements
340	DATA sin36/0.587785252292473/, sin72/0.951056516295154/, &
341	& qrt5/0.559016994374947/, sin60/0.866025403784437/
342
343
344	! Executable statements
345
346	m = n/ifac
347	iink = la*inc1
348	jink = la*inc2
349	ijump = (ifac-1)*iink
350	kstop = (n-ifac)/(2*ifac)
351
352	ibad = 1
353	IF (lot>nfft) GO TO 180
354	ibase = 0
355	jbase = 0
356	igo = ifac - 1
357	IF (igo==7) igo = 6
358	ibad = 2
359	IF (igo<1 .OR. igo>6) GO TO 180
360	GO TO (10,40,70,100,130,160) igo
361
362	! Coding for factor 2
363
364	10 CONTINUE
365	ia = 1
366	ib = ia + iink
367	ja = 1
368	jb = ja + (2m-la)inc2
369
370	IF (la==m) GO TO 30
371
372	DO l = 1, la
373	i = ibase
374	j = jbase
375	!DIR$ IVDEP
376	!CDIR NODEP
377	!OCL NOVREC
378	DO ijk = 1, lot
379	c(ja+j) = a(ia+i) + a(ib+i)
380	c(jb+j) = a(ia+i) - a(ib+i)
381	i = i + inc3
382	j = j + inc4
383	END DO
384	ibase = ibase + inc1
385	jbase = jbase + inc2
386	END DO
387	ja = ja + jink
388	jink = 2*jink
389	jb = jb - jink
390	ibase = ibase + ijump
391	ijump = 2*ijump + iink
392	IF (ja==jb) GO TO 20
393	DO k = la, kstop, la
394	kb = k + k
395	c1 = trigs(kb+1)
396	s1 = trigs(kb+2)
397	jbase = 0
398	DO l = 1, la
399	i = ibase
400	j = jbase
401	!DIR$ IVDEP
402	!CDIR NODEP
403	!OCL NOVREC
404	DO ijk = 1, lot
405	c(ja+j) = a(ia+i) + (c1a(ib+i)+s1b(ib+i))
406	c(jb+j) = a(ia+i) - (c1a(ib+i)+s1b(ib+i))
407	d(ja+j) = (c1b(ib+i)-s1a(ib+i)) + b(ia+i)
408	d(jb+j) = (c1b(ib+i)-s1a(ib+i)) - b(ia+i)
409	i = i + inc3
410	j = j + inc4
411	END DO
412	ibase = ibase + inc1
413	jbase = jbase + inc2
414	END DO
415	ibase = ibase + ijump
416	ja = ja + jink
417	jb = jb - jink
418	END DO
419	IF (ja>jb) GO TO 170
420	20 CONTINUE
421	jbase = 0
422	DO l = 1, la
423	i = ibase
424	j = jbase
425	!DIR$ IVDEP
426	!CDIR NODEP
427	!OCL NOVREC
428	DO ijk = 1, lot
429	c(ja+j) = a(ia+i)
430	d(ja+j) = -a(ib+i)
431	i = i + inc3
432	j = j + inc4
433	END DO
434	ibase = ibase + inc1
435	jbase = jbase + inc2
436	END DO
437
438	GO TO 170
439	30 CONTINUE
440	z = 1.0/REAL(n)
441	DO l = 1, la
442	i = ibase
443	j = jbase
444	!DIR$ IVDEP
445	!CDIR NODEP
446	!OCL NOVREC
447	DO ijk = 1, lot
448	c(ja+j) = z*(a(ia+i)+a(ib+i))
449	c(jb+j) = z*(a(ia+i)-a(ib+i))
450	i = i + inc3
451	j = j + inc4
452	END DO
453	ibase = ibase + inc1
454	jbase = jbase + inc2
455	END DO
456	GO TO 170
457
458	! Coding for factor 3
459
460	40 CONTINUE
461	ia = 1
462	ib = ia + iink
463	ic = ib + iink
464	ja = 1
465	jb = ja + (2m-la)inc2
466	jc = jb
467
468	IF (la==m) GO TO 60
469
470	DO l = 1, la
471	i = ibase
472	j = jbase
473	!DIR$ IVDEP
474	!CDIR NODEP
475	!OCL NOVREC
476	DO ijk = 1, lot
477	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
478	c(jb+j) = a(ia+i) - 0.5*(a(ib+i)+a(ic+i))
479	d(jb+j) = sin60*(a(ic+i)-a(ib+i))
480	i = i + inc3
481	j = j + inc4
482	END DO
483	ibase = ibase + inc1
484	jbase = jbase + inc2
485	END DO
486	ja = ja + jink
487	jink = 2*jink
488	jb = jb + jink
489	jc = jc - jink
490	ibase = ibase + ijump
491	ijump = 2*ijump + iink
492	IF (ja==jc) GO TO 50
493	DO k = la, kstop, la
494	kb = k + k
495	kc = kb + kb
496	c1 = trigs(kb+1)
497	s1 = trigs(kb+2)
498	c2 = trigs(kc+1)
499	s2 = trigs(kc+2)
500	jbase = 0
501	DO l = 1, la
502	i = ibase
503	j = jbase
504	!DIR$ IVDEP
505	!CDIR NODEP
506	!OCL NOVREC
507	DO ijk = 1, lot
508	a1 = (c1a(ib+i)+s1b(ib+i)) + (c2a(ic+i)+s2b(ic+i))
509	b1 = (c1b(ib+i)-s1a(ib+i)) + (c2b(ic+i)-s2a(ic+i))
510	a2 = a(ia+i) - 0.5*a1
511	b2 = b(ia+i) - 0.5*b1
512	a3 = sin60((c1a(ib+i)+s1b(ib+i))-(c2a(ic+i)+s2*b(ic+i)))
513	b3 = sin60((c1b(ib+i)-s1a(ib+i))-(c2b(ic+i)-s2*a(ic+i)))
514	c(ja+j) = a(ia+i) + a1
515	d(ja+j) = b(ia+i) + b1
516	c(jb+j) = a2 + b3
517	d(jb+j) = b2 - a3
518	c(jc+j) = a2 - b3
519	d(jc+j) = -(b2+a3)
520	i = i + inc3
521	j = j + inc4
522	END DO
523	ibase = ibase + inc1
524	jbase = jbase + inc2
525	END DO
526	ibase = ibase + ijump
527	ja = ja + jink
528	jb = jb + jink
529	jc = jc - jink
530	END DO
531	IF (ja>jc) GO TO 170
532	50 CONTINUE
533	jbase = 0
534	DO l = 1, la
535	i = ibase
536	j = jbase
537	!DIR$ IVDEP
538	!CDIR NODEP
539	!OCL NOVREC
540	DO ijk = 1, lot
541	c(ja+j) = a(ia+i) + 0.5*(a(ib+i)-a(ic+i))
542	d(ja+j) = -sin60*(a(ib+i)+a(ic+i))
543	c(jb+j) = a(ia+i) - (a(ib+i)-a(ic+i))
544	i = i + inc3
545	j = j + inc4
546	END DO
547	ibase = ibase + inc1
548	jbase = jbase + inc2
549	END DO
550
551	GO TO 170
552	60 CONTINUE
553	z = 1.0/REAL(n)
554	zsin60 = z*sin60
555	DO l = 1, la
556	i = ibase
557	j = jbase
558	!DIR$ IVDEP
559	!CDIR NODEP
560	!OCL NOVREC
561	DO ijk = 1, lot
562	c(ja+j) = z*(a(ia+i)+(a(ib+i)+a(ic+i)))
563	c(jb+j) = z(a(ia+i)-0.5(a(ib+i)+a(ic+i)))
564	d(jb+j) = zsin60*(a(ic+i)-a(ib+i))
565	i = i + inc3
566	j = j + inc4
567	END DO
568	ibase = ibase + inc1
569	jbase = jbase + inc2
570	END DO
571	GO TO 170
572
573	! Coding for factor 4
574
575	70 CONTINUE
576	ia = 1
577	ib = ia + iink
578	ic = ib + iink
579	id = ic + iink
580	ja = 1
581	jb = ja + (2m-la)inc2
582	jc = jb + 2minc2
583	jd = jb
584
585	IF (la==m) GO TO 90
586
587	DO l = 1, la
588	i = ibase
589	j = jbase
590	!DIR$ IVDEP
591	!CDIR NODEP
592	!OCL NOVREC
593	DO ijk = 1, lot
594	c(ja+j) = (a(ia+i)+a(ic+i)) + (a(ib+i)+a(id+i))
595	c(jc+j) = (a(ia+i)+a(ic+i)) - (a(ib+i)+a(id+i))
596	c(jb+j) = a(ia+i) - a(ic+i)
597	d(jb+j) = a(id+i) - a(ib+i)
598	i = i + inc3
599	j = j + inc4
600	END DO
601	ibase = ibase + inc1
602	jbase = jbase + inc2
603	END DO
604	ja = ja + jink
605	jink = 2*jink
606	jb = jb + jink
607	jc = jc - jink
608	jd = jd - jink
609	ibase = ibase + ijump
610	ijump = 2*ijump + iink
611	IF (jb==jc) GO TO 80
612	DO k = la, kstop, la
613	kb = k + k
614	kc = kb + kb
615	kd = kc + kb
616	c1 = trigs(kb+1)
617	s1 = trigs(kb+2)
618	c2 = trigs(kc+1)
619	s2 = trigs(kc+2)
620	c3 = trigs(kd+1)
621	s3 = trigs(kd+2)
622	jbase = 0
623	DO l = 1, la
624	i = ibase
625	j = jbase
626	!DIR$ IVDEP
627	!CDIR NODEP
628	!OCL NOVREC
629	DO ijk = 1, lot
630	a0 = a(ia+i) + (c2a(ic+i)+s2b(ic+i))
631	a2 = a(ia+i) - (c2a(ic+i)+s2b(ic+i))
632	a1 = (c1a(ib+i)+s1b(ib+i)) + (c3a(id+i)+s3b(id+i))
633	a3 = (c1a(ib+i)+s1b(ib+i)) - (c3a(id+i)+s3b(id+i))
634	b0 = b(ia+i) + (c2b(ic+i)-s2a(ic+i))
635	b2 = b(ia+i) - (c2b(ic+i)-s2a(ic+i))
636	b1 = (c1b(ib+i)-s1a(ib+i)) + (c3b(id+i)-s3a(id+i))
637	b3 = (c1b(ib+i)-s1a(ib+i)) - (c3b(id+i)-s3a(id+i))
638	c(ja+j) = a0 + a1
639	c(jc+j) = a0 - a1
640	d(ja+j) = b0 + b1
641	d(jc+j) = b1 - b0
642	c(jb+j) = a2 + b3
643	c(jd+j) = a2 - b3
644	d(jb+j) = b2 - a3
645	d(jd+j) = -(b2+a3)
646	i = i + inc3
647	j = j + inc4
648	END DO
649	ibase = ibase + inc1
650	jbase = jbase + inc2
651	END DO
652	ibase = ibase + ijump
653	ja = ja + jink
654	jb = jb + jink
655	jc = jc - jink
656	jd = jd - jink
657	END DO
658	IF (jb>jc) GO TO 170
659	80 CONTINUE
660	sin45 = SQRT(0.5)
661	jbase = 0
662	DO l = 1, la
663	i = ibase
664	j = jbase
665	!DIR$ IVDEP
666	!CDIR NODEP
667	!OCL NOVREC
668	DO ijk = 1, lot
669	c(ja+j) = a(ia+i) + sin45*(a(ib+i)-a(id+i))
670	c(jb+j) = a(ia+i) - sin45*(a(ib+i)-a(id+i))
671	d(ja+j) = -a(ic+i) - sin45*(a(ib+i)+a(id+i))
672	d(jb+j) = a(ic+i) - sin45*(a(ib+i)+a(id+i))
673	i = i + inc3
674	j = j + inc4
675	END DO
676	ibase = ibase + inc1
677	jbase = jbase + inc2
678	END DO
679
680	GO TO 170
681	90 CONTINUE
682	z = 1.0/REAL(n)
683	DO l = 1, la
684	i = ibase
685	j = jbase
686	!DIR$ IVDEP
687	!CDIR NODEP
688	!OCL NOVREC
689	DO ijk = 1, lot
690	c(ja+j) = z*((a(ia+i)+a(ic+i))+(a(ib+i)+a(id+i)))
691	c(jc+j) = z*((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i)))
692	c(jb+j) = z*(a(ia+i)-a(ic+i))
693	d(jb+j) = z*(a(id+i)-a(ib+i))
694	i = i + inc3
695	j = j + inc4
696	END DO
697	ibase = ibase + inc1
698	jbase = jbase + inc2
699	END DO
700	GO TO 170
701
702	! Coding for factor 5
703
704	100 CONTINUE
705	ia = 1
706	ib = ia + iink
707	ic = ib + iink
708	id = ic + iink
709	ie = id + iink
710	ja = 1
711	jb = ja + (2m-la)inc2
712	jc = jb + 2minc2
713	jd = jc
714	je = jb
715
716	IF (la==m) GO TO 120
717
718	DO l = 1, la
719	i = ibase
720	j = jbase
721	!DIR$ IVDEP
722	!CDIR NODEP
723	!OCL NOVREC
724	DO ijk = 1, lot
725	a1 = a(ib+i) + a(ie+i)
726	a3 = a(ib+i) - a(ie+i)
727	a2 = a(ic+i) + a(id+i)
728	a4 = a(ic+i) - a(id+i)
729	a5 = a(ia+i) - 0.25*(a1+a2)
730	a6 = qrt5*(a1-a2)
731	c(ja+j) = a(ia+i) + (a1+a2)
732	c(jb+j) = a5 + a6
733	c(jc+j) = a5 - a6
734	d(jb+j) = -sin72a3 - sin36a4
735	d(jc+j) = -sin36a3 + sin72a4
736	i = i + inc3
737	j = j + inc4
738	END DO
739	ibase = ibase + inc1
740	jbase = jbase + inc2
741	END DO
742	ja = ja + jink
743	jink = 2*jink
744	jb = jb + jink
745	jc = jc + jink
746	jd = jd - jink
747	je = je - jink
748	ibase = ibase + ijump
749	ijump = 2*ijump + iink
750	IF (jb==jd) GO TO 110
751	DO k = la, kstop, la
752	kb = k + k
753	kc = kb + kb
754	kd = kc + kb
755	ke = kd + kb
756	c1 = trigs(kb+1)
757	s1 = trigs(kb+2)
758	c2 = trigs(kc+1)
759	s2 = trigs(kc+2)
760	c3 = trigs(kd+1)
761	s3 = trigs(kd+2)
762	c4 = trigs(ke+1)
763	s4 = trigs(ke+2)
764	jbase = 0
765	DO l = 1, la
766	i = ibase
767	j = jbase
768	!DIR$ IVDEP
769	!CDIR NODEP
770	!OCL NOVREC
771	DO ijk = 1, lot
772	a1 = (c1a(ib+i)+s1b(ib+i)) + (c4a(ie+i)+s4b(ie+i))
773	a3 = (c1a(ib+i)+s1b(ib+i)) - (c4a(ie+i)+s4b(ie+i))
774	a2 = (c2a(ic+i)+s2b(ic+i)) + (c3a(id+i)+s3b(id+i))
775	a4 = (c2a(ic+i)+s2b(ic+i)) - (c3a(id+i)+s3b(id+i))
776	b1 = (c1b(ib+i)-s1a(ib+i)) + (c4b(ie+i)-s4a(ie+i))
777	b3 = (c1b(ib+i)-s1a(ib+i)) - (c4b(ie+i)-s4a(ie+i))
778	b2 = (c2b(ic+i)-s2a(ic+i)) + (c3b(id+i)-s3a(id+i))
779	b4 = (c2b(ic+i)-s2a(ic+i)) - (c3b(id+i)-s3a(id+i))
780	a5 = a(ia+i) - 0.25*(a1+a2)
781	a6 = qrt5*(a1-a2)
782	b5 = b(ia+i) - 0.25*(b1+b2)
783	b6 = qrt5*(b1-b2)
784	a10 = a5 + a6
785	a20 = a5 - a6
786	b10 = b5 + b6
787	b20 = b5 - b6
788	a11 = sin72b3 + sin36b4
789	a21 = sin36b3 - sin72b4
790	b11 = sin72a3 + sin36a4
791	b21 = sin36a3 - sin72a4
792	c(ja+j) = a(ia+i) + (a1+a2)
793	c(jb+j) = a10 + a11
794	c(je+j) = a10 - a11
795	c(jc+j) = a20 + a21
796	c(jd+j) = a20 - a21
797	d(ja+j) = b(ia+i) + (b1+b2)
798	d(jb+j) = b10 - b11
799	d(je+j) = -(b10+b11)
800	d(jc+j) = b20 - b21
801	d(jd+j) = -(b20+b21)
802	i = i + inc3
803	j = j + inc4
804	END DO
805	ibase = ibase + inc1
806	jbase = jbase + inc2
807	END DO
808	ibase = ibase + ijump
809	ja = ja + jink
810	jb = jb + jink
811	jc = jc + jink
812	jd = jd - jink
813	je = je - jink
814	END DO
815	IF (jb>jd) GO TO 170
816	110 CONTINUE
817	jbase = 0
818	DO l = 1, la
819	i = ibase
820	j = jbase
821	!DIR$ IVDEP
822	!CDIR NODEP
823	!OCL NOVREC
824	DO ijk = 1, lot
825	a1 = a(ib+i) + a(ie+i)
826	a3 = a(ib+i) - a(ie+i)
827	a2 = a(ic+i) + a(id+i)
828	a4 = a(ic+i) - a(id+i)
829	a5 = a(ia+i) + 0.25*(a3-a4)
830	a6 = qrt5*(a3+a4)
831	c(ja+j) = a5 + a6
832	c(jb+j) = a5 - a6
833	c(jc+j) = a(ia+i) - (a3-a4)
834	d(ja+j) = -sin36a1 - sin72a2
835	d(jb+j) = -sin72a1 + sin36a2
836	i = i + inc3
837	j = j + inc4
838	END DO
839	ibase = ibase + inc1
840	jbase = jbase + inc2
841	END DO
842
843	GO TO 170
844	120 CONTINUE
845	z = 1.0/REAL(n)
846	zqrt5 = z*qrt5
847	zsin36 = z*sin36
848	zsin72 = z*sin72
849	DO l = 1, la
850	i = ibase
851	j = jbase
852	!DIR$ IVDEP
853	!CDIR NODEP
854	!OCL NOVREC
855	DO ijk = 1, lot
856	a1 = a(ib+i) + a(ie+i)
857	a3 = a(ib+i) - a(ie+i)
858	a2 = a(ic+i) + a(id+i)
859	a4 = a(ic+i) - a(id+i)
860	a5 = z(a(ia+i)-0.25(a1+a2))
861	a6 = zqrt5*(a1-a2)
862	c(ja+j) = z*(a(ia+i)+(a1+a2))
863	c(jb+j) = a5 + a6
864	c(jc+j) = a5 - a6
865	d(jb+j) = -zsin72a3 - zsin36a4
866	d(jc+j) = -zsin36a3 + zsin72a4
867	i = i + inc3
868	j = j + inc4
869	END DO
870	ibase = ibase + inc1
871	jbase = jbase + inc2
872	END DO
873	GO TO 170
874
875	! Coding for factor 6
876
877	130 CONTINUE
878	ia = 1
879	ib = ia + iink
880	ic = ib + iink
881	id = ic + iink
882	ie = id + iink
883	if = ie + iink
884	ja = 1
885	jb = ja + (2m-la)inc2
886	jc = jb + 2minc2
887	jd = jc + 2minc2
888	je = jc
889	jf = jb
890
891	IF (la==m) GO TO 150
892
893	DO l = 1, la
894	i = ibase
895	j = jbase
896	!DIR$ IVDEP
897	!CDIR NODEP
898	!OCL NOVREC
899	DO ijk = 1, lot
900	a11 = (a(ic+i)+a(if+i)) + (a(ib+i)+a(ie+i))
901	c(ja+j) = (a(ia+i)+a(id+i)) + a11
902	c(jc+j) = (a(ia+i)+a(id+i)-0.5*a11)
903	d(jc+j) = sin60*((a(ic+i)+a(if+i))-(a(ib+i)+a(ie+i)))
904	a11 = (a(ic+i)-a(if+i)) + (a(ie+i)-a(ib+i))
905	c(jb+j) = (a(ia+i)-a(id+i)) - 0.5*a11
906	d(jb+j) = sin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
907	c(jd+j) = (a(ia+i)-a(id+i)) + a11
908	i = i + inc3
909	j = j + inc4
910	END DO
911	ibase = ibase + inc1
912	jbase = jbase + inc2
913	END DO
914	ja = ja + jink
915	jink = 2*jink
916	jb = jb + jink
917	jc = jc + jink
918	jd = jd - jink
919	je = je - jink
920	jf = jf - jink
921	ibase = ibase + ijump
922	ijump = 2*ijump + iink
923	IF (jc==jd) GO TO 140
924	DO k = la, kstop, la
925	kb = k + k
926	kc = kb + kb
927	kd = kc + kb
928	ke = kd + kb
929	kf = ke + kb
930	c1 = trigs(kb+1)
931	s1 = trigs(kb+2)
932	c2 = trigs(kc+1)
933	s2 = trigs(kc+2)
934	c3 = trigs(kd+1)
935	s3 = trigs(kd+2)
936	c4 = trigs(ke+1)
937	s4 = trigs(ke+2)
938	c5 = trigs(kf+1)
939	s5 = trigs(kf+2)
940	jbase = 0
941	DO l = 1, la
942	i = ibase
943	j = jbase
944	!DIR$ IVDEP
945	!CDIR NODEP
946	!OCL NOVREC
947	DO ijk = 1, lot
948	a1 = c1a(ib+i) + s1b(ib+i)
949	b1 = c1b(ib+i) - s1a(ib+i)
950	a2 = c2a(ic+i) + s2b(ic+i)
951	b2 = c2b(ic+i) - s2a(ic+i)
952	a3 = c3a(id+i) + s3b(id+i)
953	b3 = c3b(id+i) - s3a(id+i)
954	a4 = c4a(ie+i) + s4b(ie+i)
955	b4 = c4b(ie+i) - s4a(ie+i)
956	a5 = c5a(if+i) + s5b(if+i)
957	b5 = c5b(if+i) - s5a(if+i)
958	a11 = (a2+a5) + (a1+a4)
959	a20 = (a(ia+i)+a3) - 0.5*a11
960	a21 = sin60*((a2+a5)-(a1+a4))
961	b11 = (b2+b5) + (b1+b4)
962	b20 = (b(ia+i)+b3) - 0.5*b11
963	b21 = sin60*((b2+b5)-(b1+b4))
964	c(ja+j) = (a(ia+i)+a3) + a11
965	d(ja+j) = (b(ia+i)+b3) + b11
966	c(jc+j) = a20 - b21
967	d(jc+j) = a21 + b20
968	c(je+j) = a20 + b21
969	d(je+j) = a21 - b20
970	a11 = (a2-a5) + (a4-a1)
971	a20 = (a(ia+i)-a3) - 0.5*a11
972	a21 = sin60*((a4-a1)-(a2-a5))
973	b11 = (b5-b2) - (b4-b1)
974	b20 = (b3-b(ia+i)) - 0.5*b11
975	b21 = sin60*((b5-b2)+(b4-b1))
976	c(jb+j) = a20 - b21
977	d(jb+j) = a21 - b20
978	c(jd+j) = a11 + (a(ia+i)-a3)
979	d(jd+j) = b11 + (b3-b(ia+i))
980	c(jf+j) = a20 + b21
981	d(jf+j) = a21 + b20
982	i = i + inc3
983	j = j + inc4
984	END DO
985	ibase = ibase + inc1
986	jbase = jbase + inc2
987	END DO
988	ibase = ibase + ijump
989	ja = ja + jink
990	jb = jb + jink
991	jc = jc + jink
992	jd = jd - jink
993	je = je - jink
994	jf = jf - jink
995	END DO
996	IF (jc>jd) GO TO 170
997	140 CONTINUE
998	jbase = 0
999	DO l = 1, la
1000	i = ibase
1001	j = jbase
1002	!DIR$ IVDEP
1003	!CDIR NODEP
1004	!OCL NOVREC
1005	DO ijk = 1, lot
1006	c(ja+j) = (a(ia+i)+0.5(a(ic+i)-a(ie+i))) + sin60(a(ib+i)-a(if+i))
1007	d(ja+j) = -(a(id+i)+0.5(a(ib+i)+a(if+i))) - sin60(a(ic+i)+a(ie+i))
1008	c(jb+j) = a(ia+i) - (a(ic+i)-a(ie+i))
1009	d(jb+j) = a(id+i) - (a(ib+i)+a(if+i))
1010	c(jc+j) = (a(ia+i)+0.5(a(ic+i)-a(ie+i))) - sin60(a(ib+i)-a(if+i))
1011	d(jc+j) = -(a(id+i)+0.5(a(ib+i)+a(if+i))) + sin60(a(ic+i)+a(ie+i))
1012	i = i + inc3
1013	j = j + inc4
1014	END DO
1015	ibase = ibase + inc1
1016	jbase = jbase + inc2
1017	END DO
1018
1019	GO TO 170
1020	150 CONTINUE
1021	z = 1.0/REAL(n)
1022	zsin60 = z*sin60
1023	DO l = 1, la
1024	i = ibase
1025	j = jbase
1026	!DIR$ IVDEP
1027	!CDIR NODEP
1028	!OCL NOVREC
1029	DO ijk = 1, lot
1030	a11 = (a(ic+i)+a(if+i)) + (a(ib+i)+a(ie+i))
1031	c(ja+j) = z*((a(ia+i)+a(id+i))+a11)
1032	c(jc+j) = z((a(ia+i)+a(id+i))-0.5a11)
1033	d(jc+j) = zsin60*((a(ic+i)+a(if+i))-(a(ib+i)+a(ie+i)))
1034	a11 = (a(ic+i)-a(if+i)) + (a(ie+i)-a(ib+i))
1035	c(jb+j) = z((a(ia+i)-a(id+i))-0.5a11)
1036	d(jb+j) = zsin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
1037	c(jd+j) = z*((a(ia+i)-a(id+i))+a11)
1038	i = i + inc3
1039	j = j + inc4
1040	END DO
1041	ibase = ibase + inc1
1042	jbase = jbase + inc2
1043	END DO
1044	GO TO 170
1045
1046	! Coding for factor 8
1047
1048	160 CONTINUE
1049	ibad = 3
1050	IF (la/=m) GO TO 180
1051	ia = 1
1052	ib = ia + iink
1053	ic = ib + iink
1054	id = ic + iink
1055	ie = id + iink
1056	if = ie + iink
1057	ig = if + iink
1058	ih = ig + iink
1059	ja = 1
1060	jb = ja + la*inc2
1061	jc = jb + 2minc2
1062	jd = jc + 2minc2
1063	je = jd + 2minc2
1064	z = 1.0/REAL(n)
1065	zsin45 = z*SQRT(0.5)
1066
1067	DO l = 1, la
1068	i = ibase
1069	j = jbase
1070	!DIR$ IVDEP
1071	!CDIR NODEP
1072	!OCL NOVREC
1073	DO ijk = 1, lot
1074	c(ja+j) = z*(((a(ia+i)+a(ie+i))+(a(ic+i)+a(ig+i)))+((a(id+i)+ &
1075	& a(ih+i))+(a(ib+i)+a(if+i))))
1076	c(je+j) = z*(((a(ia+i)+a(ie+i))+(a(ic+i)+a(ig+i)))-((a(id+i)+ &
1077	& a(ih+i))+(a(ib+i)+a(if+i))))
1078	c(jc+j) = z*((a(ia+i)+a(ie+i))-(a(ic+i)+a(ig+i)))
1079	d(jc+j) = z*((a(id+i)+a(ih+i))-(a(ib+i)+a(if+i)))
1080	c(jb+j) = z(a(ia+i)-a(ie+i)) + zsin45((a(ih+i)-a(id+i))-(a(if+ &
1081	& i)-a(ib+i)))
1082	c(jd+j) = z(a(ia+i)-a(ie+i)) - zsin45((a(ih+i)-a(id+i))-(a(if+ &
1083	& i)-a(ib+i)))
1084	d(jb+j) = zsin45*((a(ih+i)-a(id+i))+(a(if+i)-a(ib+i))) + &
1085	& z*(a(ig+i)-a(ic+i))
1086	d(jd+j) = zsin45*((a(ih+i)-a(id+i))+(a(if+i)-a(ib+i))) - &
1087	& z*(a(ig+i)-a(ic+i))
1088	i = i + inc3
1089	j = j + inc4
1090	END DO
1091	ibase = ibase + inc1
1092	jbase = jbase + inc2
1093	END DO
1094
1095	! Return
1096
1097	170 CONTINUE
1098	ibad = 0
1099	180 CONTINUE
1100	ierr = ibad
1101	RETURN
1102	END SUBROUTINE qpassm
1103
1104	SUBROUTINE rpassm(a,b,c,d,trigs,inc1,inc2,inc3,inc4,lot,n,ifac,la,ierr)
1105	! Dimension a(n),b(n),c(n),d(n),trigs(n)
1106
1107	IMPLICIT NONE
1108
1109	! Scalar arguments
1110	INTEGER :: ierr, ifac, inc1, inc2, inc3, inc4, la, lot, n
1111
1112	! Array arguments
1113	REAL :: a(), b(), c(), d(), trigs(*)
1114
1115	! Local scalars:
1116	REAL :: c1, c2, c3, c4, c5, qqrt5, qrt5, s1, s2, s3, s4, s5, sin36, sin45, &
1117	& sin60, sin72, ssin36, ssin45, ssin60, ssin72
1118	INTEGER :: i, ia, ib, ibad, ibase, ic, id, ie, if, igo, iink, ijk, j, ja, &
1119	& jb, jbase, jc, jd, je, jf, jg, jh, jink, jump, k, kb, kc, kd, ke, kf, &
1120	& kstop, l, m
1121
1122	! Local arrays:
1123	REAL :: a10(nfft), a11(nfft), a20(nfft), a21(nfft), b10(nfft), b11(nfft), b20(nfft), &
1124	& b21(nfft)
1125
1126	! Intrinsic functions
1127	INTRINSIC SQRT
1128
1129	! Data statements
1130	DATA sin36/0.587785252292473/, sin72/0.951056516295154/, &
1131	& qrt5/0.559016994374947/, sin60/0.866025403784437/
1132
1133
1134	! Executable statements
1135
1136	m = n/ifac
1137	iink = la*inc1
1138	jink = la*inc2
1139	jump = (ifac-1)*jink
1140	kstop = (n-ifac)/(2*ifac)
1141
1142	ibad = 1
1143	IF (lot>nfft) GO TO 180
1144	ibase = 0
1145	jbase = 0
1146	igo = ifac - 1
1147	IF (igo==7) igo = 6
1148	ibad = 2
1149	IF (igo<1 .OR. igo>6) GO TO 180
1150	GO TO (10,40,70,100,130,160) igo
1151
1152	! Coding for factor 2
1153
1154	10 CONTINUE
1155	ia = 1
1156	ib = ia + (2m-la)inc1
1157	ja = 1
1158	jb = ja + jink
1159
1160	IF (la==m) GO TO 30
1161
1162	DO l = 1, la
1163	i = ibase
1164	j = jbase
1165	!DIR$ IVDEP
1166	!CDIR NODEP
1167	!OCL NOVREC
1168	DO ijk = 1, lot
1169	c(ja+j) = a(ia+i) + a(ib+i)
1170	c(jb+j) = a(ia+i) - a(ib+i)
1171	i = i + inc3
1172	j = j + inc4
1173	END DO
1174	ibase = ibase + inc1
1175	jbase = jbase + inc2
1176	END DO
1177	ia = ia + iink
1178	iink = 2*iink
1179	ib = ib - iink
1180	ibase = 0
1181	jbase = jbase + jump
1182	jump = 2*jump + jink
1183	IF (ia==ib) GO TO 20
1184	DO k = la, kstop, la
1185	kb = k + k
1186	c1 = trigs(kb+1)
1187	s1 = trigs(kb+2)
1188	ibase = 0
1189	DO l = 1, la
1190	i = ibase
1191	j = jbase
1192	!DIR$ IVDEP
1193	!CDIR NODEP
1194	!OCL NOVREC
1195	DO ijk = 1, lot
1196	c(ja+j) = a(ia+i) + a(ib+i)
1197	d(ja+j) = b(ia+i) - b(ib+i)
1198	c(jb+j) = c1(a(ia+i)-a(ib+i)) - s1(b(ia+i)+b(ib+i))
1199	d(jb+j) = s1(a(ia+i)-a(ib+i)) + c1(b(ia+i)+b(ib+i))
1200	i = i + inc3
1201	j = j + inc4
1202	END DO
1203	ibase = ibase + inc1
1204	jbase = jbase + inc2
1205	END DO
1206	ia = ia + iink
1207	ib = ib - iink
1208	jbase = jbase + jump
1209	END DO
1210	IF (ia>ib) GO TO 170
1211	20 CONTINUE
1212	ibase = 0
1213	DO l = 1, la
1214	i = ibase
1215	j = jbase
1216	!DIR$ IVDEP
1217	!CDIR NODEP
1218	!OCL NOVREC
1219	DO ijk = 1, lot
1220	c(ja+j) = a(ia+i)
1221	c(jb+j) = -b(ia+i)
1222	i = i + inc3
1223	j = j + inc4
1224	END DO
1225	ibase = ibase + inc1
1226	jbase = jbase + inc2
1227	END DO
1228
1229	GO TO 170
1230	30 CONTINUE
1231	DO l = 1, la
1232	i = ibase
1233	j = jbase
1234	!DIR$ IVDEP
1235	!CDIR NODEP
1236	!OCL NOVREC
1237	DO ijk = 1, lot
1238	c(ja+j) = 2.0*(a(ia+i)+a(ib+i))
1239	c(jb+j) = 2.0*(a(ia+i)-a(ib+i))
1240	i = i + inc3
1241	j = j + inc4
1242	END DO
1243	ibase = ibase + inc1
1244	jbase = jbase + inc2
1245	END DO
1246	GO TO 170
1247
1248	! Coding for factor 3
1249
1250	40 CONTINUE
1251	ia = 1
1252	ib = ia + (2m-la)inc1
1253	ic = ib
1254	ja = 1
1255	jb = ja + jink
1256	jc = jb + jink
1257
1258	IF (la==m) GO TO 60
1259
1260	DO l = 1, la
1261	i = ibase
1262	j = jbase
1263	!DIR$ IVDEP
1264	!CDIR NODEP
1265	!OCL NOVREC
1266	DO ijk = 1, lot
1267	c(ja+j) = a(ia+i) + a(ib+i)
1268	c(jb+j) = (a(ia+i)-0.5a(ib+i)) - (sin60(b(ib+i)))
1269	c(jc+j) = (a(ia+i)-0.5a(ib+i)) + (sin60(b(ib+i)))
1270	i = i + inc3
1271	j = j + inc4
1272	END DO
1273	ibase = ibase + inc1
1274	jbase = jbase + inc2
1275	END DO
1276	ia = ia + iink
1277	iink = 2*iink
1278	ib = ib + iink
1279	ic = ic - iink
1280	jbase = jbase + jump
1281	jump = 2*jump + jink
1282	IF (ia==ic) GO TO 50
1283	DO k = la, kstop, la
1284	kb = k + k
1285	kc = kb + kb
1286	c1 = trigs(kb+1)
1287	s1 = trigs(kb+2)
1288	c2 = trigs(kc+1)
1289	s2 = trigs(kc+2)
1290	ibase = 0
1291	DO l = 1, la
1292	i = ibase
1293	j = jbase
1294	!DIR$ IVDEP
1295	!CDIR NODEP
1296	!OCL NOVREC
1297	DO ijk = 1, lot
1298	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
1299	d(ja+j) = b(ia+i) + (b(ib+i)-b(ic+i))
1300	c(jb+j) = c1((a(ia+i)-0.5(a(ib+i)+a(ic+i)))-(sin60*(b(ib+i)+ &
1301	& b(ic+i)))) - s1((b(ia+i)-0.5(b(ib+i)-b(ic+i)))+(sin60*(a(ib+i)- &
1302	& a(ic+i))))
1303	d(jb+j) = s1((a(ia+i)-0.5(a(ib+i)+a(ic+i)))-(sin60*(b(ib+i)+ &
1304	& b(ic+i)))) + c1((b(ia+i)-0.5(b(ib+i)-b(ic+i)))+(sin60*(a(ib+i)- &
1305	& a(ic+i))))
1306	c(jc+j) = c2((a(ia+i)-0.5(a(ib+i)+a(ic+i)))+(sin60*(b(ib+i)+ &
1307	& b(ic+i)))) - s2((b(ia+i)-0.5(b(ib+i)-b(ic+i)))-(sin60*(a(ib+i)- &
1308	& a(ic+i))))
1309	d(jc+j) = s2((a(ia+i)-0.5(a(ib+i)+a(ic+i)))+(sin60*(b(ib+i)+ &
1310	& b(ic+i)))) + c2((b(ia+i)-0.5(b(ib+i)-b(ic+i)))-(sin60*(a(ib+i)- &
1311	& a(ic+i))))
1312	i = i + inc3
1313	j = j + inc4
1314	END DO
1315	ibase = ibase + inc1
1316	jbase = jbase + inc2
1317	END DO
1318	ia = ia + iink
1319	ib = ib + iink
1320	ic = ic - iink
1321	jbase = jbase + jump
1322	END DO
1323	IF (ia>ic) GO TO 170
1324	50 CONTINUE
1325	ibase = 0
1326	DO l = 1, la
1327	i = ibase
1328	j = jbase
1329	!DIR$ IVDEP
1330	!CDIR NODEP
1331	!OCL NOVREC
1332	DO ijk = 1, lot
1333	c(ja+j) = a(ia+i) + a(ib+i)
1334	c(jb+j) = (0.5a(ia+i)-a(ib+i)) - (sin60b(ia+i))
1335	c(jc+j) = -(0.5a(ia+i)-a(ib+i)) - (sin60b(ia+i))
1336	i = i + inc3
1337	j = j + inc4
1338	END DO
1339	ibase = ibase + inc1
1340	jbase = jbase + inc2
1341	END DO
1342
1343	GO TO 170
1344	60 CONTINUE
1345	ssin60 = 2.0*sin60
1346	DO l = 1, la
1347	i = ibase
1348	j = jbase
1349	!DIR$ IVDEP
1350	!CDIR NODEP
1351	!OCL NOVREC
1352	DO ijk = 1, lot
1353	c(ja+j) = 2.0*(a(ia+i)+a(ib+i))
1354	c(jb+j) = (2.0a(ia+i)-a(ib+i)) - (ssin60b(ib+i))
1355	c(jc+j) = (2.0a(ia+i)-a(ib+i)) + (ssin60b(ib+i))
1356	i = i + inc3
1357	j = j + inc4
1358	END DO
1359	ibase = ibase + inc1
1360	jbase = jbase + inc2
1361	END DO
1362	GO TO 170
1363
1364	! Coding for factor 4
1365
1366	70 CONTINUE
1367	ia = 1
1368	ib = ia + (2m-la)inc1
1369	ic = ib + 2minc1
1370	id = ib
1371	ja = 1
1372	jb = ja + jink
1373	jc = jb + jink
1374	jd = jc + jink
1375
1376	IF (la==m) GO TO 90
1377
1378	DO l = 1, la
1379	i = ibase
1380	j = jbase
1381	!DIR$ IVDEP
1382	!CDIR NODEP
1383	!OCL NOVREC
1384	DO ijk = 1, lot
1385	c(ja+j) = (a(ia+i)+a(ic+i)) + a(ib+i)
1386	c(jb+j) = (a(ia+i)-a(ic+i)) - b(ib+i)
1387	c(jc+j) = (a(ia+i)+a(ic+i)) - a(ib+i)
1388	c(jd+j) = (a(ia+i)-a(ic+i)) + b(ib+i)
1389	i = i + inc3
1390	j = j + inc4
1391	END DO
1392	ibase = ibase + inc1
1393	jbase = jbase + inc2
1394	END DO
1395	ia = ia + iink
1396	iink = 2*iink
1397	ib = ib + iink
1398	ic = ic - iink
1399	id = id - iink
1400	jbase = jbase + jump
1401	jump = 2*jump + jink
1402	IF (ib==ic) GO TO 80
1403	DO k = la, kstop, la
1404	kb = k + k
1405	kc = kb + kb
1406	kd = kc + kb
1407	c1 = trigs(kb+1)
1408	s1 = trigs(kb+2)
1409	c2 = trigs(kc+1)
1410	s2 = trigs(kc+2)
1411	c3 = trigs(kd+1)
1412	s3 = trigs(kd+2)
1413	ibase = 0
1414	DO l = 1, la
1415	i = ibase
1416	j = jbase
1417	!DIR$ IVDEP
1418	!CDIR NODEP
1419	!OCL NOVREC
1420	DO ijk = 1, lot
1421	c(ja+j) = (a(ia+i)+a(ic+i)) + (a(ib+i)+a(id+i))
1422	d(ja+j) = (b(ia+i)-b(ic+i)) + (b(ib+i)-b(id+i))
1423	c(jc+j) = c2((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i))) - s2((b(ia+ &
1424	& i)-b(ic+i))-(b(ib+i)-b(id+i)))
1425	d(jc+j) = s2((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i))) + c2((b(ia+ &
1426	& i)-b(ic+i))-(b(ib+i)-b(id+i)))
1427	c(jb+j) = c1((a(ia+i)-a(ic+i))-(b(ib+i)+b(id+i))) - s1((b(ia+ &
1428	& i)+b(ic+i))+(a(ib+i)-a(id+i)))
1429	d(jb+j) = s1((a(ia+i)-a(ic+i))-(b(ib+i)+b(id+i))) + c1((b(ia+ &
1430	& i)+b(ic+i))+(a(ib+i)-a(id+i)))
1431	c(jd+j) = c3((a(ia+i)-a(ic+i))+(b(ib+i)+b(id+i))) - s3((b(ia+ &
1432	& i)+b(ic+i))-(a(ib+i)-a(id+i)))
1433	d(jd+j) = s3((a(ia+i)-a(ic+i))+(b(ib+i)+b(id+i))) + c3((b(ia+ &
1434	& i)+b(ic+i))-(a(ib+i)-a(id+i)))
1435	i = i + inc3
1436	j = j + inc4
1437	END DO
1438	ibase = ibase + inc1
1439	jbase = jbase + inc2
1440	END DO
1441	ia = ia + iink
1442	ib = ib + iink
1443	ic = ic - iink
1444	id = id - iink
1445	jbase = jbase + jump
1446	END DO
1447	IF (ib>ic) GO TO 170
1448	80 CONTINUE
1449	ibase = 0
1450	sin45 = SQRT(0.5)
1451	DO l = 1, la
1452	i = ibase
1453	j = jbase
1454	!DIR$ IVDEP
1455	!CDIR NODEP
1456	!OCL NOVREC
1457	DO ijk = 1, lot
1458	c(ja+j) = a(ia+i) + a(ib+i)
1459	c(jb+j) = sin45*((a(ia+i)-a(ib+i))-(b(ia+i)+b(ib+i)))
1460	c(jc+j) = b(ib+i) - b(ia+i)
1461	c(jd+j) = -sin45*((a(ia+i)-a(ib+i))+(b(ia+i)+b(ib+i)))
1462	i = i + inc3
1463	j = j + inc4
1464	END DO
1465	ibase = ibase + inc1
1466	jbase = jbase + inc2
1467	END DO
1468
1469	GO TO 170
1470	90 CONTINUE
1471	DO l = 1, la
1472	i = ibase
1473	j = jbase
1474	!DIR$ IVDEP
1475	!CDIR NODEP
1476	!OCL NOVREC
1477	DO ijk = 1, lot
1478	c(ja+j) = 2.0*((a(ia+i)+a(ic+i))+a(ib+i))
1479	c(jb+j) = 2.0*((a(ia+i)-a(ic+i))-b(ib+i))
1480	c(jc+j) = 2.0*((a(ia+i)+a(ic+i))-a(ib+i))
1481	c(jd+j) = 2.0*((a(ia+i)-a(ic+i))+b(ib+i))
1482	i = i + inc3
1483	j = j + inc4
1484	END DO
1485	ibase = ibase + inc1
1486	jbase = jbase + inc2
1487	END DO
1488
1489	! Coding for factor 5
1490
1491	GO TO 170
1492	100 CONTINUE
1493	ia = 1
1494	ib = ia + (2m-la)inc1
1495	ic = ib + 2minc1
1496	id = ic
1497	ie = ib
1498	ja = 1
1499	jb = ja + jink
1500	jc = jb + jink
1501	jd = jc + jink
1502	je = jd + jink
1503
1504	IF (la==m) GO TO 120
1505
1506	DO l = 1, la
1507	i = ibase
1508	j = jbase
1509	!DIR$ IVDEP
1510	!CDIR NODEP
1511	!OCL NOVREC
1512	DO ijk = 1, lot
1513	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
1514	c(jb+j) = ((a(ia+i)-0.25(a(ib+i)+a(ic+i)))+qrt5(a(ib+i)-a(ic+i))) - &
1515	& (sin72b(ib+i)+sin36b(ic+i))
1516	c(jc+j) = ((a(ia+i)-0.25(a(ib+i)+a(ic+i)))-qrt5(a(ib+i)-a(ic+i))) - &
1517	& (sin36b(ib+i)-sin72b(ic+i))
1518	c(jd+j) = ((a(ia+i)-0.25(a(ib+i)+a(ic+i)))-qrt5(a(ib+i)-a(ic+i))) + &
1519	& (sin36b(ib+i)-sin72b(ic+i))
1520	c(je+j) = ((a(ia+i)-0.25(a(ib+i)+a(ic+i)))+qrt5(a(ib+i)-a(ic+i))) + &
1521	& (sin72b(ib+i)+sin36b(ic+i))
1522	i = i + inc3
1523	j = j + inc4
1524	END DO
1525	ibase = ibase + inc1
1526	jbase = jbase + inc2
1527	END DO
1528	ia = ia + iink
1529	iink = 2*iink
1530	ib = ib + iink
1531	ic = ic + iink
1532	id = id - iink
1533	ie = ie - iink
1534	jbase = jbase + jump
1535	jump = 2*jump + jink
1536	IF (ib==id) GO TO 110
1537	DO k = la, kstop, la
1538	kb = k + k
1539	kc = kb + kb
1540	kd = kc + kb
1541	ke = kd + kb
1542	c1 = trigs(kb+1)
1543	s1 = trigs(kb+2)
1544	c2 = trigs(kc+1)
1545	s2 = trigs(kc+2)
1546	c3 = trigs(kd+1)
1547	s3 = trigs(kd+2)
1548	c4 = trigs(ke+1)
1549	s4 = trigs(ke+2)
1550	ibase = 0
1551	DO l = 1, la
1552	i = ibase
1553	j = jbase
1554	!DIR$ IVDEP
1555	!CDIR NODEP
1556	!OCL NOVREC
1557	DO ijk = 1, lot
1558
1559	a10(ijk) = (a(ia+i)-0.25*((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))) + &
1560	& qrt5*((a(ib+i)+a(ie+i))-(a(ic+i)+a(id+i)))
1561	a20(ijk) = (a(ia+i)-0.25*((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))) - &
1562	& qrt5*((a(ib+i)+a(ie+i))-(a(ic+i)+a(id+i)))
1563	b10(ijk) = (b(ia+i)-0.25*((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))) + &
1564	& qrt5*((b(ib+i)-b(ie+i))-(b(ic+i)-b(id+i)))
1565	b20(ijk) = (b(ia+i)-0.25*((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))) - &
1566	& qrt5*((b(ib+i)-b(ie+i))-(b(ic+i)-b(id+i)))
1567	a11(ijk) = sin72(b(ib+i)+b(ie+i)) + sin36(b(ic+i)+b(id+i))
1568	a21(ijk) = sin36(b(ib+i)+b(ie+i)) - sin72(b(ic+i)+b(id+i))
1569	b11(ijk) = sin72(a(ib+i)-a(ie+i)) + sin36(a(ic+i)-a(id+i))
1570	b21(ijk) = sin36(a(ib+i)-a(ie+i)) - sin72(a(ic+i)-a(id+i))
1571
1572	c(ja+j) = a(ia+i) + ((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))
1573	d(ja+j) = b(ia+i) + ((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))
1574	c(jb+j) = c1(a10(ijk)-a11(ijk)) - s1(b10(ijk)+b11(ijk))
1575	d(jb+j) = s1(a10(ijk)-a11(ijk)) + c1(b10(ijk)+b11(ijk))
1576	c(je+j) = c4(a10(ijk)+a11(ijk)) - s4(b10(ijk)-b11(ijk))
1577	d(je+j) = s4(a10(ijk)+a11(ijk)) + c4(b10(ijk)-b11(ijk))
1578	c(jc+j) = c2(a20(ijk)-a21(ijk)) - s2(b20(ijk)+b21(ijk))
1579	d(jc+j) = s2(a20(ijk)-a21(ijk)) + c2(b20(ijk)+b21(ijk))
1580	c(jd+j) = c3(a20(ijk)+a21(ijk)) - s3(b20(ijk)-b21(ijk))
1581	d(jd+j) = s3(a20(ijk)+a21(ijk)) + c3(b20(ijk)-b21(ijk))
1582
1583	i = i + inc3
1584	j = j + inc4
1585	END DO
1586	ibase = ibase + inc1
1587	jbase = jbase + inc2
1588	END DO
1589	ia = ia + iink
1590	ib = ib + iink
1591	ic = ic + iink
1592	id = id - iink
1593	ie = ie - iink
1594	jbase = jbase + jump
1595	END DO
1596	IF (ib>id) GO TO 170
1597	110 CONTINUE
1598	ibase = 0
1599	DO l = 1, la
1600	i = ibase
1601	j = jbase
1602	!DIR$ IVDEP
1603	!CDIR NODEP
1604	!OCL NOVREC
1605	DO ijk = 1, lot
1606	c(ja+j) = (a(ia+i)+a(ib+i)) + a(ic+i)
1607	c(jb+j) = (qrt5(a(ia+i)-a(ib+i))+(0.25(a(ia+i)+a(ib+i))-a(ic+i))) - &
1608	& (sin36b(ia+i)+sin72b(ib+i))
1609	c(je+j) = -(qrt5(a(ia+i)-a(ib+i))+(0.25(a(ia+i)+a(ib+i))-a(ic+i))) - &
1610	& (sin36b(ia+i)+sin72b(ib+i))
1611	c(jc+j) = (qrt5(a(ia+i)-a(ib+i))-(0.25(a(ia+i)+a(ib+i))-a(ic+i))) - &
1612	& (sin72b(ia+i)-sin36b(ib+i))
1613	c(jd+j) = -(qrt5(a(ia+i)-a(ib+i))-(0.25(a(ia+i)+a(ib+i))-a(ic+i))) - &
1614	& (sin72b(ia+i)-sin36b(ib+i))
1615	i = i + inc3
1616	j = j + inc4
1617	END DO
1618	ibase = ibase + inc1
1619	jbase = jbase + inc2
1620	END DO
1621
1622	GO TO 170
1623	120 CONTINUE
1624	qqrt5 = 2.0*qrt5
1625	ssin36 = 2.0*sin36
1626	ssin72 = 2.0*sin72
1627	DO l = 1, la
1628	i = ibase
1629	j = jbase
1630	!DIR$ IVDEP
1631	!CDIR NODEP
1632	!OCL NOVREC
1633	DO ijk = 1, lot
1634	c(ja+j) = 2.0*(a(ia+i)+(a(ib+i)+a(ic+i)))
1635	c(jb+j) = (2.0(a(ia+i)-0.25(a(ib+i)+a(ic+i)))+qqrt5*(a(ib+i)-a(ic+ &
1636	& i))) - (ssin72b(ib+i)+ssin36b(ic+i))
1637	c(jc+j) = (2.0(a(ia+i)-0.25(a(ib+i)+a(ic+i)))-qqrt5*(a(ib+i)-a(ic+ &
1638	& i))) - (ssin36b(ib+i)-ssin72b(ic+i))
1639	c(jd+j) = (2.0(a(ia+i)-0.25(a(ib+i)+a(ic+i)))-qqrt5*(a(ib+i)-a(ic+ &
1640	& i))) + (ssin36b(ib+i)-ssin72b(ic+i))
1641	c(je+j) = (2.0(a(ia+i)-0.25(a(ib+i)+a(ic+i)))+qqrt5*(a(ib+i)-a(ic+ &
1642	& i))) + (ssin72b(ib+i)+ssin36b(ic+i))
1643	i = i + inc3
1644	j = j + inc4
1645	END DO
1646	ibase = ibase + inc1
1647	jbase = jbase + inc2
1648	END DO
1649	GO TO 170
1650
1651	! Coding for factor 6
1652
1653	130 CONTINUE
1654	ia = 1
1655	ib = ia + (2m-la)inc1
1656	ic = ib + 2minc1
1657	id = ic + 2minc1
1658	ie = ic
1659	if = ib
1660	ja = 1
1661	jb = ja + jink
1662	jc = jb + jink
1663	jd = jc + jink
1664	je = jd + jink
1665	jf = je + jink
1666
1667	IF (la==m) GO TO 150
1668
1669	DO l = 1, la
1670	i = ibase
1671	j = jbase
1672	!DIR$ IVDEP
1673	!CDIR NODEP
1674	!OCL NOVREC
1675	DO ijk = 1, lot
1676	c(ja+j) = (a(ia+i)+a(id+i)) + (a(ib+i)+a(ic+i))
1677	c(jd+j) = (a(ia+i)-a(id+i)) - (a(ib+i)-a(ic+i))
1678	c(jb+j) = ((a(ia+i)-a(id+i))+0.5(a(ib+i)-a(ic+i))) - (sin60(b(ib+ &
1679	& i)+b(ic+i)))
1680	c(jf+j) = ((a(ia+i)-a(id+i))+0.5(a(ib+i)-a(ic+i))) + (sin60(b(ib+ &
1681	& i)+b(ic+i)))
1682	c(jc+j) = ((a(ia+i)+a(id+i))-0.5(a(ib+i)+a(ic+i))) - (sin60(b(ib+ &
1683	& i)-b(ic+i)))
1684	c(je+j) = ((a(ia+i)+a(id+i))-0.5(a(ib+i)+a(ic+i))) + (sin60(b(ib+ &
1685	& i)-b(ic+i)))
1686	i = i + inc3
1687	j = j + inc4
1688	END DO
1689	ibase = ibase + inc1
1690	jbase = jbase + inc2
1691	END DO
1692	ia = ia + iink
1693	iink = 2*iink
1694	ib = ib + iink
1695	ic = ic + iink
1696	id = id - iink
1697	ie = ie - iink
1698	if = if - iink
1699	jbase = jbase + jump
1700	jump = 2*jump + jink
1701	IF (ic==id) GO TO 140
1702	DO k = la, kstop, la
1703	kb = k + k
1704	kc = kb + kb
1705	kd = kc + kb
1706	ke = kd + kb
1707	kf = ke + kb
1708	c1 = trigs(kb+1)
1709	s1 = trigs(kb+2)
1710	c2 = trigs(kc+1)
1711	s2 = trigs(kc+2)
1712	c3 = trigs(kd+1)
1713	s3 = trigs(kd+2)
1714	c4 = trigs(ke+1)
1715	s4 = trigs(ke+2)
1716	c5 = trigs(kf+1)
1717	s5 = trigs(kf+2)
1718	ibase = 0
1719	DO l = 1, la
1720	i = ibase
1721	j = jbase
1722	!DIR$ IVDEP
1723	!CDIR NODEP
1724	!OCL NOVREC
1725	DO ijk = 1, lot
1726
1727	a11(ijk) = (a(ie+i)+a(ib+i)) + (a(ic+i)+a(if+i))
1728	a20(ijk) = (a(ia+i)+a(id+i)) - 0.5*a11(ijk)
1729	a21(ijk) = sin60*((a(ie+i)+a(ib+i))-(a(ic+i)+a(if+i)))
1730	b11(ijk) = (b(ib+i)-b(ie+i)) + (b(ic+i)-b(if+i))
1731	b20(ijk) = (b(ia+i)-b(id+i)) - 0.5*b11(ijk)
1732	b21(ijk) = sin60*((b(ib+i)-b(ie+i))-(b(ic+i)-b(if+i)))
1733
1734	c(ja+j) = (a(ia+i)+a(id+i)) + a11(ijk)
1735	d(ja+j) = (b(ia+i)-b(id+i)) + b11(ijk)
1736	c(jc+j) = c2(a20(ijk)-b21(ijk)) - s2(b20(ijk)+a21(ijk))
1737	d(jc+j) = s2(a20(ijk)-b21(ijk)) + c2(b20(ijk)+a21(ijk))
1738	c(je+j) = c4(a20(ijk)+b21(ijk)) - s4(b20(ijk)-a21(ijk))
1739	d(je+j) = s4(a20(ijk)+b21(ijk)) + c4(b20(ijk)-a21(ijk))
1740
1741	a11(ijk) = (a(ie+i)-a(ib+i)) + (a(ic+i)-a(if+i))
1742	b11(ijk) = (b(ie+i)+b(ib+i)) - (b(ic+i)+b(if+i))
1743	a20(ijk) = (a(ia+i)-a(id+i)) - 0.5*a11(ijk)
1744	a21(ijk) = sin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
1745	b20(ijk) = (b(ia+i)+b(id+i)) + 0.5*b11(ijk)
1746	b21(ijk) = sin60*((b(ie+i)+b(ib+i))+(b(ic+i)+b(if+i)))
1747
1748	c(jd+j) = c3((a(ia+i)-a(id+i))+a11(ijk)) - s3((b(ia+i)+b(id+ &
1749	& i))-b11(ijk))
1750	d(jd+j) = s3((a(ia+i)-a(id+i))+a11(ijk)) + c3((b(ia+i)+b(id+ &
1751	& i))-b11(ijk))
1752	c(jb+j) = c1(a20(ijk)-b21(ijk)) - s1(b20(ijk)-a21(ijk))
1753	d(jb+j) = s1(a20(ijk)-b21(ijk)) + c1(b20(ijk)-a21(ijk))
1754	c(jf+j) = c5(a20(ijk)+b21(ijk)) - s5(b20(ijk)+a21(ijk))
1755	d(jf+j) = s5(a20(ijk)+b21(ijk)) + c5(b20(ijk)+a21(ijk))
1756
1757	i = i + inc3
1758	j = j + inc4
1759	END DO
1760	ibase = ibase + inc1
1761	jbase = jbase + inc2
1762	END DO
1763	ia = ia + iink
1764	ib = ib + iink
1765	ic = ic + iink
1766	id = id - iink
1767	ie = ie - iink
1768	if = if - iink
1769	jbase = jbase + jump
1770	END DO
1771	IF (ic>id) GO TO 170
1772	140 CONTINUE
1773	ibase = 0
1774	DO l = 1, la
1775	i = ibase
1776	j = jbase
1777	!DIR$ IVDEP
1778	!CDIR NODEP
1779	!OCL NOVREC
1780	DO ijk = 1, lot
1781	c(ja+j) = a(ib+i) + (a(ia+i)+a(ic+i))
1782	c(jd+j) = b(ib+i) - (b(ia+i)+b(ic+i))
1783	c(jb+j) = (sin60(a(ia+i)-a(ic+i))) - (0.5(b(ia+i)+b(ic+i))+b(ib+i))
1784	c(jf+j) = -(sin60(a(ia+i)-a(ic+i))) - (0.5(b(ia+i)+b(ic+i))+b(ib+i))
1785	c(jc+j) = sin60(b(ic+i)-b(ia+i)) + (0.5(a(ia+i)+a(ic+i))-a(ib+i))
1786	c(je+j) = sin60(b(ic+i)-b(ia+i)) - (0.5(a(ia+i)+a(ic+i))-a(ib+i))
1787	i = i + inc3
1788	j = j + inc4
1789	END DO
1790	ibase = ibase + inc1
1791	jbase = jbase + inc2
1792	END DO
1793
1794	GO TO 170
1795	150 CONTINUE
1796	ssin60 = 2.0*sin60
1797	DO l = 1, la
1798	i = ibase
1799	j = jbase
1800	!DIR$ IVDEP
1801	!CDIR NODEP
1802	!OCL NOVREC
1803	DO ijk = 1, lot
1804	c(ja+j) = (2.0(a(ia+i)+a(id+i))) + (2.0(a(ib+i)+a(ic+i)))
1805	c(jd+j) = (2.0(a(ia+i)-a(id+i))) - (2.0(a(ib+i)-a(ic+i)))
1806	c(jb+j) = (2.0(a(ia+i)-a(id+i))+(a(ib+i)-a(ic+i))) - (ssin60(b(ib+ &
1807	& i)+b(ic+i)))
1808	c(jf+j) = (2.0(a(ia+i)-a(id+i))+(a(ib+i)-a(ic+i))) + (ssin60(b(ib+ &
1809	& i)+b(ic+i)))
1810	c(jc+j) = (2.0(a(ia+i)+a(id+i))-(a(ib+i)+a(ic+i))) - (ssin60(b(ib+ &
1811	& i)-b(ic+i)))
1812	c(je+j) = (2.0(a(ia+i)+a(id+i))-(a(ib+i)+a(ic+i))) + (ssin60(b(ib+ &
1813	& i)-b(ic+i)))
1814	i = i + inc3
1815	j = j + inc4
1816	END DO
1817	ibase = ibase + inc1
1818	jbase = jbase + inc2
1819	END DO
1820	GO TO 170
1821
1822	! Coding for factor 8
1823
1824	160 CONTINUE
1825	ibad = 3
1826	IF (la/=m) GO TO 180
1827	ia = 1
1828	ib = ia + la*inc1
1829	ic = ib + 2lainc1
1830	id = ic + 2lainc1
1831	ie = id + 2lainc1
1832	ja = 1
1833	jb = ja + jink
1834	jc = jb + jink
1835	jd = jc + jink
1836	je = jd + jink
1837	jf = je + jink
1838	jg = jf + jink
1839	jh = jg + jink
1840	ssin45 = SQRT(2.0)
1841
1842	DO l = 1, la
1843	i = ibase
1844	j = jbase
1845	!DIR$ IVDEP
1846	!CDIR NODEP
1847	!OCL NOVREC
1848	DO ijk = 1, lot
1849	c(ja+j) = 2.0*(((a(ia+i)+a(ie+i))+a(ic+i))+(a(ib+i)+a(id+i)))
1850	c(je+j) = 2.0*(((a(ia+i)+a(ie+i))+a(ic+i))-(a(ib+i)+a(id+i)))
1851	c(jc+j) = 2.0*(((a(ia+i)+a(ie+i))-a(ic+i))-(b(ib+i)-b(id+i)))
1852	c(jg+j) = 2.0*(((a(ia+i)+a(ie+i))-a(ic+i))+(b(ib+i)-b(id+i)))
1853	c(jb+j) = 2.0((a(ia+i)-a(ie+i))-b(ic+i)) + ssin45((a(ib+i)-a(id+ &
1854	& i))-(b(ib+i)+b(id+i)))
1855	c(jf+j) = 2.0((a(ia+i)-a(ie+i))-b(ic+i)) - ssin45((a(ib+i)-a(id+ &
1856	& i))-(b(ib+i)+b(id+i)))
1857	c(jd+j) = 2.0((a(ia+i)-a(ie+i))+b(ic+i)) - ssin45((a(ib+i)-a(id+ &
1858	& i))+(b(ib+i)+b(id+i)))
1859	c(jh+j) = 2.0((a(ia+i)-a(ie+i))+b(ic+i)) + ssin45((a(ib+i)-a(id+ &
1860	& i))+(b(ib+i)+b(id+i)))
1861	i = i + inc3
1862	j = j + inc4
1863	END DO
1864	ibase = ibase + inc1
1865	jbase = jbase + inc2
1866	END DO
1867
1868	! Return
1869
1870	170 CONTINUE
1871	ibad = 0
1872	180 CONTINUE
1873	ierr = ibad
1874	RETURN
1875	END SUBROUTINE rpassm
1876
1877	SUBROUTINE set99(trigs,ifax,n)
1878
1879	! Description:
1880	!
1881	! Computes factors of n & trigonometric functins required by fft99 & fft991cy
1882	!
1883	! Method:
1884	!
1885	! Dimension trigs(n),ifax(1),jfax(10),lfax(7)
1886	!
1887	! subroutine 'set99' - computes factors of n & trigonometric
1888	! functins required by fft99 & fft991cy
1889
1890
1891	USE control_parameters
1892	USE pegrid
1893
1894	IMPLICIT NONE
1895
1896	! Scalar arguments
1897	INTEGER :: n
1898
1899	! Array arguments
1900	REAL :: trigs(*)
1901	INTEGER :: ifax(*)
1902
1903	! Local scalars:
1904	REAL :: angle, del
1905	INTEGER :: i, ifac, ixxx, k, l, nfax, nhl, nil, nu
1906
1907	! Local arrays:
1908	INTEGER :: jfax(10), lfax(7)
1909
1910	! Intrinsic functions
1911	INTRINSIC ASIN, COS, MOD, REAL, SIN
1912
1913	! Data statements
1914	DATA lfax/6, 8, 5, 4, 3, 2, 1/
1915
1916
1917	! Executable statements
1918	ixxx = 1
1919
1920	del = 4.0*ASIN(1.0)/REAL(n)
1921	nil = 0
1922	nhl = (n/2) - 1
1923	DO k = nil, nhl
1924	angle = REAL(k)*del
1925	trigs(2*k+1) = COS(angle)
1926	trigs(2*k+2) = SIN(angle)
1927	END DO
1928
1929	! Find factors of n (8,6,5,4,3,2; only one 8 allowed)
1930	! Look for sixes first, store factors in descending order
1931	nu = n
1932	ifac = 6
1933	k = 0
1934	l = 1
1935	10 CONTINUE
1936	IF (MOD(nu,ifac)/=0) GO TO 30
1937	k = k + 1
1938	jfax(k) = ifac
1939	IF (ifac/=8) GO TO 20
1940	IF (k==1) GO TO 20
1941	jfax(1) = 8
1942	jfax(k) = 6
1943	20 CONTINUE
1944	nu = nu/ifac
1945	IF (nu==1) GO TO 40
1946	IF (ifac/=8) GO TO 10
1947	30 CONTINUE
1948	l = l + 1
1949	ifac = lfax(l)
1950	IF (ifac>1) GO TO 10
1951
1952	! WRITE (nout,'(A,I4,A)') ' n =',n,' - Contains illegal factors'
1953	message_string = 'number of gridpoints along x or/and y ' // &
1954	'contain illegal factors' // &
1955	'&only factors 8,6,5,4,3,2 are allowed'
1956	CALL message( 'temperton_fft', 'PA0311', 1, 2, 0, 6, 0 )
1957
1958	RETURN
1959
1960	! Now reverse order of factors
1961	40 CONTINUE
1962	nfax = k
1963	ifax(1) = nfax
1964	DO i = 1, nfax
1965	ifax(nfax+2-i) = jfax(i)
1966	END DO
1967	ifax(10) = n
1968	RETURN
1969	END SUBROUTINE set99
1970
1971	END MODULE temperton_fft

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