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source: palm/trunk/SOURCE/temperton_fft_mod.f90 @ 4297

Last change on this file since 4297 was 4182, checked in by scharf, 5 years ago
corrected "Former revisions" section minor formatting in "Former revisions" section added "Author" section
Property svn:keywords set to `Id`
File size: 70.3 KB

Rev	Line
[1850]	1	!> @file temperton_fft_mod.f90
[1]	2	!------------------------------------------------------------------------------!
[1682]	3	!
[258]	4	! Current revisions:
[1]	5	! -----------------
[1343]	6	!
[3049]	7	!
[1321]	8	! Former revisions:
	9	! -----------------
	10	! $Id: temperton_fft_mod.f90 4182 2019-08-22 15:20:23Z oliver.maas $
[4182]	11	! Corrected "Former revisions" section
	12	!
	13	! 3725 2019-02-07 10:11:02Z raasch
[3725]	14	! GOTO statements replaced, file re-formatted corresponding to coding standards
[1321]	15	!
[4182]	16	! Revision 1.1 2003/03/12 16:41:59 raasch
	17	! Initial revision
	18	!
	19	!
[1]	20	! Description:
	21	! ------------
[1682]	22	!> Fast Fourier transformation developed by Clive Temperton, ECMWF.
[1]	23	!------------------------------------------------------------------------------!
[1682]	24	MODULE temperton_fft
[1]	25
[1320]	26	USE kinds
	27
[1]	28	IMPLICIT NONE
	29
	30	PRIVATE
	31
	32	PUBLIC set99, fft991cy
	33
[2300]	34	INTEGER(iwp), PARAMETER :: nfft = 32 !< maximum length of calls to *fft
	35	INTEGER(iwp), PARAMETER :: nout = 6 !< standard output stream
	36
[1]	37	CONTAINS
	38
[1682]	39	!------------------------------------------------------------------------------!
	40	! Description:
	41	! ------------
[3725]	42	!> Calls Fortran-versions of fft's.
[1682]	43	!>
	44	!> Method:
	45	!>
	46	!> Subroutine 'fft991cy' - multiple fast real periodic transform
	47	!> supersedes previous routine 'fft991cy'.
	48	!>
	49	!> Real transform of length n performed by removing redundant
	50	!> operations from complex transform of length n.
	51	!>
	52	!> a is the array containing input & output data.
	53	!> work is an area of size (n+1)*min(lot,nfft).
	54	!> trigs is a previously prepared list of trig function values.
	55	!> ifax is a previously prepared list of factors of n.
	56	!> inc is the increment within each data 'vector'
	57	!> (e.g. inc=1 for consecutively stored data).
	58	!> jump is the increment between the start of each data vector.
	59	!> n is the length of the data vectors.
	60	!> lot is the number of data vectors.
	61	!> isign = +1 for transform from spectral to gridpoint
	62	!> = -1 for transform from gridpoint to spectral.
	63	!>
	64	!> ordering of coefficients:
	65	!> a(0),b(0),a(1),b(1),a(2),b(2),.,a(n/2),b(n/2)
	66	!> where b(0)=b(n/2)=0; (n+2) locations required.
	67	!>
	68	!> ordering of data:
	69	!> x(0),x(1),x(2),.,x(n-1), 0 , 0 ; (n+2) locations required.
	70	!>
	71	!> Vectorization is achieved on cray by doing the transforms
	72	!> in parallel.
	73	!>
	74	!> n must be composed of factors 2,3 & 5 but does not have to be even.
	75	!>
	76	!> definition of transforms:
	77	!>
	78	!> isign=+1: x(j)=sum(k=0,.,n-1)(c(k)exp(2ijk*pi/n))
	79	!> where c(k)=a(k)+ib(k) and c(n-k)=a(k)-ib(k)
	80	!>
	81	!> isign=-1: a(k)=(1/n)sum(j=0,.,n-1)(x(j)cos(2jk*pi/n))
	82	!> b(k)=-(1/n)sum(j=0,.,n-1)(x(j)sin(2jk*pi/n))
	83	!>
	84	!> calls fortran-versions of fft's !!!
	85	!> dimension a(n),work(n),trigs(n),ifax(1)
	86	!------------------------------------------------------------------------------!
[3725]	87	SUBROUTINE fft991cy( a, work, trigs, ifax, inc, jump, n, lot, isign )
[1]	88
[1320]	89	USE kinds
[1]	90
	91	IMPLICIT NONE
	92
[1682]	93	INTEGER(iwp) :: inc !<
	94	INTEGER(iwp) :: isign !<
	95	INTEGER(iwp) :: jump !<
	96	INTEGER(iwp) :: lot !<
	97	INTEGER(iwp) :: n !<
[1]	98
[1682]	99	REAL(wp) :: a(*) !<
	100	REAL(wp) :: trigs(*) !<
	101	REAL(wp) :: work(*) !<
	102	INTEGER(iwp) :: ifax(*) !<
[1]	103
[1682]	104	INTEGER(iwp) :: i !<
	105	INTEGER(iwp) :: ia !<
	106	INTEGER(iwp) :: ibase !<
	107	INTEGER(iwp) :: ierr !<
	108	INTEGER(iwp) :: ifac !<
	109	INTEGER(iwp) :: igo !<
	110	INTEGER(iwp) :: ii !<
	111	INTEGER(iwp) :: istart !<
	112	INTEGER(iwp) :: ix !<
	113	INTEGER(iwp) :: iz !<
	114	INTEGER(iwp) :: j !<
	115	INTEGER(iwp) :: jbase !<
	116	INTEGER(iwp) :: jj !<
	117	INTEGER(iwp) :: k !<
	118	INTEGER(iwp) :: la !<
	119	INTEGER(iwp) :: nb !<
	120	INTEGER(iwp) :: nblox !<
	121	INTEGER(iwp) :: nfax !<
	122	INTEGER(iwp) :: nvex !<
	123	INTEGER(iwp) :: nx !<
[1]	124
	125
[3725]	126	IF ( ifax(10) /= n ) CALL set99( trigs, ifax, n )
	127	nfax = ifax(1)
	128	nx = n + 1
	129	IF ( MOD(n,2) == 1 ) nx = n
	130	nblox = 1 + (lot-1) / nfft
	131	nvex = lot - (nblox-1) * nfft
[1]	132
	133
[3725]	134	IF ( isign == 1 ) THEN
	135	!
	136	!-- Backward fft: spectral to gridpoint transform
[1]	137
[3725]	138	istart = 1
	139	DO nb = 1, nblox
[1]	140
	141	ia = istart
[3725]	142	i = istart
	143	!DIR$ IVDEP
	144	!CDIR NODEP
	145	!OCL NOVREC
	146	DO j = 1, nvex
	147	a(i+inc) = 0.5_wp * a(i)
	148	i = i + jump
	149	ENDDO
	150	IF ( MOD(n,2) /= 1 ) THEN
	151	i = istart + n * inc
	152	DO j = 1, nvex
	153	a(i) = 0.5_wp * a(i)
	154	i = i + jump
	155	ENDDO
	156	ENDIF
	157	ia = istart + inc
	158	la = 1
	159	igo = + 1
[1]	160
[3725]	161	DO k = 1, nfax
[1]	162
[3725]	163	ifac = ifax(k+1)
	164	ierr = -1
	165	IF ( igo /= -1 ) THEN
	166	CALL rpassm( a(ia), a(ia+lainc), work(1), work(ifacla+1), trigs, inc, 1, jump, &
	167	nx, nvex, n, ifac, la, ierr )
	168	ELSE
	169	CALL rpassm( work(1), work(la+1), a(ia), a(ia+ifaclainc), trigs, 1, inc, nx, &
	170	jump, nvex, n, ifac, la, ierr )
	171	ENDIF
	172	!
	173	!-- Following messages shouldn't appear in PALM applications
	174	IF ( ierr /= 0 ) THEN
	175	SELECT CASE (ierr)
	176	CASE (:-1)
	177	WRITE (nout,'(A,I5,A)') ' Vector length =',nvex,', greater than nfft'
	178	CASE (0)
	179	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', not catered for'
	180	CASE (1:)
	181	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', only catered for if la*ifac=n'
	182	END SELECT
	183	RETURN
	184	ENDIF
[1]	185
[3725]	186	la = ifac * la
	187	igo = -igo
	188	ia = istart
[1]	189
[3725]	190	ENDDO
	191	!
	192	!-- If necessary, copy results back to a
	193	IF ( MOD(nfax,2) /= 0 ) THEN
	194	ibase = 1
	195	jbase = ia
	196	DO jj = 1, nvex
	197	i = ibase
	198	j = jbase
	199	DO ii = 1, n
	200	a(j) = work(i)
	201	i = i + 1
	202	j = j + inc
	203	ENDDO
	204	ibase = ibase + nx
	205	jbase = jbase + jump
	206	ENDDO
	207	ENDIF
	208	!
	209	!-- Fill in zeros at end
	210	ix = istart + n*inc
	211	!DIR$ IVDEP
	212	!CDIR NODEP
	213	!OCL NOVREC
	214	DO j = 1, nvex
	215	a(ix) = 0.0_wp
	216	a(ix+inc) = 0.0_wp
	217	ix = ix + jump
	218	ENDDO
	219	istart = istart + nvex*jump
	220	nvex = nfft
[1]	221
[3725]	222	ENDDO
[1]	223
[3725]	224	ELSEIF ( isign == -1 ) THEN
	225	!
	226	!-- Forward fft: gridpoint to spectral transform
	227	istart = 1
	228	DO nb = 1, nblox
	229	ia = istart
	230	la = n
	231	igo = + 1
[1]	232
[3725]	233	DO k = 1, nfax
[1]	234
[3725]	235	ifac = ifax(nfax+2-k)
	236	la = la / ifac
	237	ierr = -1
	238	IF ( igo /= -1 ) THEN
	239	CALL qpassm( a(ia), a(ia+ifaclainc), work(1), work(la+1), trigs, inc, 1, jump, &
	240	nx, nvex, n, ifac, la, ierr )
	241	ELSE
	242	CALL qpassm( work(1), work(ifacla+1), a(ia), a(ia+lainc), trigs, 1, inc, nx, &
	243	jump, nvex, n, ifac, la, ierr )
	244	ENDIF
	245	!
	246	!-- Following messages shouldn't appear in PALM applications
	247	IF ( ierr /= 0 ) THEN
	248	SELECT CASE (ierr)
	249	CASE (:-1)
	250	WRITE (nout,'(A,I5,A)') ' Vector length =',nvex,', greater than nfft'
	251	CASE (0)
	252	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', not catered for'
	253	CASE (1:)
	254	WRITE (nout,'(A,I3,A)') ' Factor =',ifac,', only catered for if la*ifac=n'
	255	END SELECT
	256	RETURN
	257	ENDIF
[1]	258
[3725]	259	igo = -igo
	260	ia = istart + inc
[1]	261
[3725]	262	ENDDO
	263	!
	264	!-- If necessary, copy results back to a
	265	IF ( MOD(nfax,2) /= 0 ) THEN
	266	ibase = 1
	267	jbase = ia
	268	DO jj = 1, nvex
	269	i = ibase
	270	j = jbase
	271	DO ii = 1, n
	272	a(j) = work(i)
	273	i = i + 1
	274	j = j + inc
	275	ENDDO
	276	ibase = ibase + nx
	277	jbase = jbase + jump
	278	ENDDO
	279	ENDIF
	280	!
	281	!-- Shift a(0) and fill in zero imag parts
	282	ix = istart
	283	!DIR$ IVDEP
	284	!CDIR NODEP
	285	!OCL NOVREC
	286	DO j = 1, nvex
	287	a(ix) = a(ix+inc)
	288	a(ix+inc) = 0.0_wp
	289	ix = ix + jump
	290	ENDDO
	291	IF ( MOD(n,2) /= 1 ) THEN
	292	iz = istart + (n+1) * inc
	293	DO j = 1, nvex
	294	a(iz) = 0.0_wp
	295	iz = iz + jump
	296	ENDDO
	297	ENDIF
	298	istart = istart + nvex * jump
	299	nvex = nfft
[1]	300
[3725]	301	ENDDO
[1]	302
[3725]	303	ENDIF
[1]	304
[3725]	305	END SUBROUTINE fft991cy
[1]	306
[1682]	307	!------------------------------------------------------------------------------!
	308	! Description:
	309	! ------------
	310	!> Performs one pass through data as part of
	311	!> multiple real fft (fourier analysis) routine.
	312	!>
	313	!> Method:
	314	!>
	315	!> a is first real input vector
	316	!> equivalence b(1) with a(ifaclainc1+1)
	317	!> c is first real output vector
	318	!> equivalence d(1) with c(la*inc2+1)
	319	!> trigs is a precalculated list of sines & cosines
	320	!> inc1 is the addressing increment for a
	321	!> inc2 is the addressing increment for c
	322	!> inc3 is the increment between input vectors a
	323	!> inc4 is the increment between output vectors c
	324	!> lot is the number of vectors
	325	!> n is the length of the vectors
	326	!> ifac is the current factor of n
	327	!> la = n/(product of factors used so far)
	328	!> ierr is an error indicator:
	329	!> 0 - pass completed without error
	330	!> 1 - lot greater than nfft
	331	!> 2 - ifac not catered for
	332	!> 3 - ifac only catered for if la=n/ifac
	333	!------------------------------------------------------------------------------!
[3725]	334	SUBROUTINE qpassm( a, b, c, d, trigs, inc1, inc2, inc3, inc4, lot, n, ifac, la, ierr )
[1]	335
[1320]	336	USE kinds
[1]	337
[1320]	338	IMPLICIT NONE
	339
[1682]	340	INTEGER(iwp) :: ierr !<
	341	INTEGER(iwp) :: ifac !<
	342	INTEGER(iwp) :: inc1 !<
	343	INTEGER(iwp) :: inc2 !<
	344	INTEGER(iwp) :: inc3 !<
	345	INTEGER(iwp) :: inc4 !<
	346	INTEGER(iwp) :: la !<
	347	INTEGER(iwp) :: lot !<
	348	INTEGER(iwp) :: n !<
[1]	349
[3725]	350	!
	351	!-- Arrays are dimensioned with n
[1682]	352	REAL(wp) :: a(*) !<
	353	REAL(wp) :: b(*) !<
	354	REAL(wp) :: c(*) !<
	355	REAL(wp) :: d(*) !<
	356	REAL(wp) :: trigs(*) !<
[1320]	357
[1682]	358	REAL(wp) :: a0 !<
	359	REAL(wp) :: a1 !<
	360	REAL(wp) :: a10 !<
	361	REAL(wp) :: a11 !<
	362	REAL(wp) :: a2 !<
	363	REAL(wp) :: a20 !<
	364	REAL(wp) :: a21 !<
	365	REAL(wp) :: a3 !<
	366	REAL(wp) :: a4 !<
	367	REAL(wp) :: a5 !<
	368	REAL(wp) :: a6 !<
	369	REAL(wp) :: b0 !<
	370	REAL(wp) :: b1 !<
	371	REAL(wp) :: b10 !<
	372	REAL(wp) :: b11 !<
	373	REAL(wp) :: b2 !<
	374	REAL(wp) :: b20 !<
	375	REAL(wp) :: b21 !<
	376	REAL(wp) :: b3 !<
	377	REAL(wp) :: b4 !<
	378	REAL(wp) :: b5 !<
	379	REAL(wp) :: b6 !<
	380	REAL(wp) :: c1 !<
	381	REAL(wp) :: c2 !<
	382	REAL(wp) :: c3 !<
	383	REAL(wp) :: c4 !<
	384	REAL(wp) :: c5 !<
	385	REAL(wp) :: qrt5 !<
	386	REAL(wp) :: s1 !<
	387	REAL(wp) :: s2 !<
	388	REAL(wp) :: s3 !<
	389	REAL(wp) :: s4 !<
	390	REAL(wp) :: s5 !<
	391	REAL(wp) :: sin36 !<
	392	REAL(wp) :: sin45 !<
	393	REAL(wp) :: sin60 !<
	394	REAL(wp) :: sin72 !<
	395	REAL(wp) :: z !<
	396	REAL(wp) :: zqrt5 !<
	397	REAL(wp) :: zsin36 !<
	398	REAL(wp) :: zsin45 !<
	399	REAL(wp) :: zsin60 !<
	400	REAL(wp) :: zsin72 !<
[1]	401
[1682]	402	INTEGER(iwp) :: i !<
	403	INTEGER(iwp) :: ia !<
	404	INTEGER(iwp) :: ib !<
	405	INTEGER(iwp) :: ibase !<
	406	INTEGER(iwp) :: ic !<
	407	INTEGER(iwp) :: id !<
	408	INTEGER(iwp) :: ie !<
	409	INTEGER(iwp) :: if !<
	410	INTEGER(iwp) :: ig !<
	411	INTEGER(iwp) :: igo !<
	412	INTEGER(iwp) :: ih !<
	413	INTEGER(iwp) :: iink !<
	414	INTEGER(iwp) :: ijk !<
	415	INTEGER(iwp) :: ijump !<
	416	INTEGER(iwp) :: j !<
	417	INTEGER(iwp) :: ja !<
	418	INTEGER(iwp) :: jb !<
	419	INTEGER(iwp) :: jbase !<
	420	INTEGER(iwp) :: jc !<
	421	INTEGER(iwp) :: jd !<
	422	INTEGER(iwp) :: je !<
	423	INTEGER(iwp) :: jf !<
	424	INTEGER(iwp) :: jink !<
	425	INTEGER(iwp) :: k !<
	426	INTEGER(iwp) :: kb !<
	427	INTEGER(iwp) :: kc !<
	428	INTEGER(iwp) :: kd !<
	429	INTEGER(iwp) :: ke !<
	430	INTEGER(iwp) :: kf !<
	431	INTEGER(iwp) :: kstop !<
	432	INTEGER(iwp) :: l !<
	433	INTEGER(iwp) :: m !<
[1320]	434
[1]	435
[3725]	436	DATA sin36/0.587785252292473_wp/, sin72/0.951056516295154_wp/, &
	437	qrt5/0.559016994374947_wp/, sin60/0.866025403784437_wp/
[1]	438
	439
[3725]	440	ierr = 0
[1]	441
[3725]	442	IF ( lot > nfft ) THEN
	443	ierr = 1
	444	RETURN
	445	ENDIF
[1]	446
[3725]	447	m = n / ifac
	448	iink = la * inc1
	449	jink = la * inc2
	450	ijump = (ifac-1) * iink
	451	kstop = ( n-ifac ) / ( 2*ifac )
	452
[1]	453	ibase = 0
	454	jbase = 0
	455	igo = ifac - 1
[3725]	456	IF ( igo == 7 ) igo = 6
[1]	457
[3725]	458	IF (igo < 1 .OR. igo > 6 ) THEN
	459	ierr = 2
	460	RETURN
	461	ENDIF
[1]	462
	463
[3725]	464	SELECT CASE ( igo )
[1]	465
[3725]	466	!
	467	!-- Coding for factor 2
	468	CASE ( 1 )
	469	ia = 1
	470	ib = ia + iink
	471	ja = 1
	472	jb = ja + (2m-la) inc2
[1]	473
[3725]	474	IF ( la /= m ) THEN
[1]	475
[3725]	476	DO l = 1, la
	477	i = ibase
	478	j = jbase
	479	!DIR$ IVDEP
	480	!CDIR NODEP
	481	!OCL NOVREC
	482	DO ijk = 1, lot
	483	c(ja+j) = a(ia+i) + a(ib+i)
	484	c(jb+j) = a(ia+i) - a(ib+i)
	485	i = i + inc3
	486	j = j + inc4
	487	ENDDO
	488	ibase = ibase + inc1
	489	jbase = jbase + inc2
	490	ENDDO
[1]	491
[3725]	492	ja = ja + jink
	493	jink = 2 * jink
	494	jb = jb - jink
	495	ibase = ibase + ijump
	496	ijump = 2 * ijump + iink
[1]	497
[3725]	498	IF ( ja /= jb ) THEN
[1]	499
[3725]	500	DO k = la, kstop, la
	501	kb = k + k
	502	c1 = trigs(kb+1)
	503	s1 = trigs(kb+2)
	504	jbase = 0
	505	DO l = 1, la
	506	i = ibase
	507	j = jbase
	508	!DIR$ IVDEP
	509	!CDIR NODEP
	510	!OCL NOVREC
	511	DO ijk = 1, lot
	512	c(ja+j) = a(ia+i) + (c1a(ib+i)+s1b(ib+i))
	513	c(jb+j) = a(ia+i) - (c1a(ib+i)+s1b(ib+i))
	514	d(ja+j) = (c1b(ib+i)-s1a(ib+i)) + b(ia+i)
	515	d(jb+j) = (c1b(ib+i)-s1a(ib+i)) - b(ia+i)
	516	i = i + inc3
	517	j = j + inc4
	518	ENDDO
	519	ibase = ibase + inc1
	520	jbase = jbase + inc2
	521	ENDDO
[1]	522
[3725]	523	ibase = ibase + ijump
	524	ja = ja + jink
	525	jb = jb - jink
	526	ENDDO
[1]	527
[3725]	528	IF ( ja > jb ) RETURN
[1]	529
[3725]	530	ENDIF
[1]	531
[3725]	532	jbase = 0
	533	DO l = 1, la
	534	i = ibase
	535	j = jbase
	536	!DIR$ IVDEP
	537	!CDIR NODEP
	538	!OCL NOVREC
	539	DO ijk = 1, lot
	540	c(ja+j) = a(ia+i)
	541	d(ja+j) = -a(ib+i)
	542	i = i + inc3
	543	j = j + inc4
[1]	544
[3725]	545	ENDDO
	546	ibase = ibase + inc1
	547	jbase = jbase + inc2
	548	ENDDO
[1]	549
[3725]	550	ELSE
[1]	551
[3725]	552	z = 1.0_wp/REAL(n,KIND=wp)
	553	DO l = 1, la
	554	i = ibase
	555	j = jbase
	556	!DIR$ IVDEP
	557	!CDIR NODEP
	558	!OCL NOVREC
	559	DO ijk = 1, lot
	560	c(ja+j) = z*(a(ia+i)+a(ib+i))
	561	c(jb+j) = z*(a(ia+i)-a(ib+i))
	562	i = i + inc3
	563	j = j + inc4
	564	ENDDO
	565	ibase = ibase + inc1
	566	jbase = jbase + inc2
	567	ENDDO
[1]	568
[3725]	569	ENDIF
[1]	570
[3725]	571	!
	572	!-- Coding for factor 3
	573	CASE ( 2 )
[1]	574
[3725]	575	ia = 1
	576	ib = ia + iink
	577	ic = ib + iink
	578	ja = 1
	579	jb = ja + (2m-la) inc2
	580	jc = jb
[1]	581
[3725]	582	IF ( la /= m ) THEN
[1]	583
[3725]	584	DO l = 1, la
	585	i = ibase
	586	j = jbase
	587	!DIR$ IVDEP
	588	!CDIR NODEP
	589	!OCL NOVREC
	590	DO ijk = 1, lot
	591	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
	592	c(jb+j) = a(ia+i) - 0.5_wp*(a(ib+i)+a(ic+i))
	593	d(jb+j) = sin60*(a(ic+i)-a(ib+i))
	594	i = i + inc3
	595	j = j + inc4
	596	ENDDO
	597	ibase = ibase + inc1
	598	jbase = jbase + inc2
	599	ENDDO
[1]	600
[3725]	601	ja = ja + jink
	602	jink = 2 * jink
	603	jb = jb + jink
	604	jc = jc - jink
	605	ibase = ibase + ijump
	606	ijump = 2 * ijump + iink
[1]	607
[3725]	608	IF ( ja /= jc ) THEN
[1]	609
[3725]	610	DO k = la, kstop, la
	611	kb = k + k
	612	kc = kb + kb
	613	c1 = trigs(kb+1)
	614	s1 = trigs(kb+2)
	615	c2 = trigs(kc+1)
	616	s2 = trigs(kc+2)
[1]	617
[3725]	618	jbase = 0
	619	DO l = 1, la
	620	i = ibase
	621	j = jbase
	622	!DIR$ IVDEP
	623	!CDIR NODEP
	624	!OCL NOVREC
	625	DO ijk = 1, lot
	626	a1 = (c1a(ib+i)+s1b(ib+i)) + (c2a(ic+i)+s2b(ic+i))
	627	b1 = (c1b(ib+i)-s1a(ib+i)) + (c2b(ic+i)-s2a(ic+i))
	628	a2 = a(ia+i) - 0.5_wp*a1
	629	b2 = b(ia+i) - 0.5_wp*b1
	630	a3 = sin60((c1a(ib+i)+s1b(ib+i))-(c2a(ic+i)+s2*b(ic+i)))
	631	b3 = sin60((c1b(ib+i)-s1a(ib+i))-(c2b(ic+i)-s2*a(ic+i)))
	632	c(ja+j) = a(ia+i) + a1
	633	d(ja+j) = b(ia+i) + b1
	634	c(jb+j) = a2 + b3
	635	d(jb+j) = b2 - a3
	636	c(jc+j) = a2 - b3
	637	d(jc+j) = -(b2+a3)
	638	i = i + inc3
	639	j = j + inc4
	640	ENDDO
	641	ibase = ibase + inc1
	642	jbase = jbase + inc2
	643	ENDDO
	644	ibase = ibase + ijump
	645	ja = ja + jink
	646	jb = jb + jink
	647	jc = jc - jink
	648	ENDDO
[1]	649
[3725]	650	IF ( ja > jc ) RETURN
[1]	651
[3725]	652	ENDIF
[1]	653
[3725]	654	jbase = 0
	655	DO l = 1, la
	656	i = ibase
	657	j = jbase
	658	!DIR$ IVDEP
	659	!CDIR NODEP
	660	!OCL NOVREC
	661	DO ijk = 1, lot
	662	c(ja+j) = a(ia+i) + 0.5_wp*(a(ib+i)-a(ic+i))
	663	d(ja+j) = -sin60*(a(ib+i)+a(ic+i))
	664	c(jb+j) = a(ia+i) - (a(ib+i)-a(ic+i))
	665	i = i + inc3
	666	j = j + inc4
	667	ENDDO
	668	ibase = ibase + inc1
	669	jbase = jbase + inc2
	670	ENDDO
[1]	671
[3725]	672	ELSE
[1]	673
[3725]	674	z = 1.0_wp / REAL( n, KIND=wp )
	675	zsin60 = z*sin60
	676	DO l = 1, la
	677	i = ibase
	678	j = jbase
	679	!DIR$ IVDEP
	680	!CDIR NODEP
	681	!OCL NOVREC
	682	DO ijk = 1, lot
	683	c(ja+j) = z*(a(ia+i)+(a(ib+i)+a(ic+i)))
	684	c(jb+j) = z(a(ia+i)-0.5_wp(a(ib+i)+a(ic+i)))
	685	d(jb+j) = zsin60*(a(ic+i)-a(ib+i))
	686	i = i + inc3
	687	j = j + inc4
	688	ENDDO
	689	ibase = ibase + inc1
	690	jbase = jbase + inc2
	691	ENDDO
[1]	692
[3725]	693	ENDIF
	694
	695	!
	696	!-- Coding for factor 4
	697	CASE ( 3 )
	698
	699	ia = 1
	700	ib = ia + iink
	701	ic = ib + iink
	702	id = ic + iink
	703	ja = 1
	704	jb = ja + (2m-la) inc2
	705	jc = jb + 2minc2
	706	jd = jb
	707
	708	IF ( la /= m ) THEN
	709
	710	DO l = 1, la
	711
	712	i = ibase
	713	j = jbase
	714	!DIR$ IVDEP
	715	!CDIR NODEP
	716	!OCL NOVREC
	717	DO ijk = 1, lot
	718	c(ja+j) = (a(ia+i)+a(ic+i)) + (a(ib+i)+a(id+i))
	719	c(jc+j) = (a(ia+i)+a(ic+i)) - (a(ib+i)+a(id+i))
	720	c(jb+j) = a(ia+i) - a(ic+i)
	721	d(jb+j) = a(id+i) - a(ib+i)
	722	i = i + inc3
	723	j = j + inc4
	724	ENDDO
	725	ibase = ibase + inc1
	726	jbase = jbase + inc2
	727	ENDDO
	728
	729	ja = ja + jink
	730	jink = 2 * jink
	731	jb = jb + jink
	732	jc = jc - jink
	733	jd = jd - jink
	734	ibase = ibase + ijump
	735	ijump = 2 * ijump + iink
	736
	737	IF ( jb /= jc ) THEN
	738
	739	DO k = la, kstop, la
	740	kb = k + k
	741	kc = kb + kb
	742	kd = kc + kb
	743	c1 = trigs(kb+1)
	744	s1 = trigs(kb+2)
	745	c2 = trigs(kc+1)
	746	s2 = trigs(kc+2)
	747	c3 = trigs(kd+1)
	748	s3 = trigs(kd+2)
	749	jbase = 0
	750	DO l = 1, la
	751	i = ibase
	752	j = jbase
	753	!DIR$ IVDEP
	754	!CDIR NODEP
	755	!OCL NOVREC
	756	DO ijk = 1, lot
	757	a0 = a(ia+i) + (c2a(ic+i)+s2b(ic+i))
	758	a2 = a(ia+i) - (c2a(ic+i)+s2b(ic+i))
	759	a1 = (c1a(ib+i)+s1b(ib+i)) + (c3a(id+i)+s3b(id+i))
	760	a3 = (c1a(ib+i)+s1b(ib+i)) - (c3a(id+i)+s3b(id+i))
	761	b0 = b(ia+i) + (c2b(ic+i)-s2a(ic+i))
	762	b2 = b(ia+i) - (c2b(ic+i)-s2a(ic+i))
	763	b1 = (c1b(ib+i)-s1a(ib+i)) + (c3b(id+i)-s3a(id+i))
	764	b3 = (c1b(ib+i)-s1a(ib+i)) - (c3b(id+i)-s3a(id+i))
	765	c(ja+j) = a0 + a1
	766	c(jc+j) = a0 - a1
	767	d(ja+j) = b0 + b1
	768	d(jc+j) = b1 - b0
	769	c(jb+j) = a2 + b3
	770	c(jd+j) = a2 - b3
	771	d(jb+j) = b2 - a3
	772	d(jd+j) = -(b2+a3)
	773	i = i + inc3
	774	j = j + inc4
	775	ENDDO
	776	ibase = ibase + inc1
	777	jbase = jbase + inc2
	778	ENDDO
	779	ibase = ibase + ijump
	780	ja = ja + jink
	781	jb = jb + jink
	782	jc = jc - jink
	783	jd = jd - jink
	784	ENDDO
	785
	786	IF ( jb > jc ) RETURN
	787
	788	ENDIF
	789
	790	sin45 = SQRT( 0.5_wp )
	791	jbase = 0
	792	DO l = 1, la
	793	i = ibase
	794	j = jbase
	795	!DIR$ IVDEP
	796	!CDIR NODEP
	797	!OCL NOVREC
	798	DO ijk = 1, lot
	799	c(ja+j) = a(ia+i) + sin45*(a(ib+i)-a(id+i))
	800	c(jb+j) = a(ia+i) - sin45*(a(ib+i)-a(id+i))
	801	d(ja+j) = -a(ic+i) - sin45*(a(ib+i)+a(id+i))
	802	d(jb+j) = a(ic+i) - sin45*(a(ib+i)+a(id+i))
	803	i = i + inc3
	804	j = j + inc4
	805	ENDDO
	806	ibase = ibase + inc1
	807	jbase = jbase + inc2
	808	ENDDO
	809
	810	ELSE
	811
	812	z = 1.0_wp / REAL( n, KIND=wp )
	813	DO l = 1, la
	814	i = ibase
	815	j = jbase
	816	!DIR$ IVDEP
	817	!CDIR NODEP
	818	!OCL NOVREC
	819	DO ijk = 1, lot
	820	c(ja+j) = z*((a(ia+i)+a(ic+i))+(a(ib+i)+a(id+i)))
	821	c(jc+j) = z*((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i)))
	822	c(jb+j) = z*(a(ia+i)-a(ic+i))
	823	d(jb+j) = z*(a(id+i)-a(ib+i))
	824	i = i + inc3
	825	j = j + inc4
	826	ENDDO
	827	ibase = ibase + inc1
	828	jbase = jbase + inc2
	829	ENDDO
	830
	831	ENDIF
	832
	833	!
	834	!-- Coding for factor 5
	835	CASE ( 4 )
	836
	837	ia = 1
	838	ib = ia + iink
	839	ic = ib + iink
	840	id = ic + iink
	841	ie = id + iink
	842	ja = 1
	843	jb = ja + (2m-la) inc2
	844	jc = jb + 2minc2
	845	jd = jc
	846	je = jb
	847
	848	IF ( la /= m ) THEN
	849
	850	DO l = 1, la
	851	i = ibase
	852	j = jbase
	853	!DIR$ IVDEP
	854	!CDIR NODEP
	855	!OCL NOVREC
	856	DO ijk = 1, lot
	857	a1 = a(ib+i) + a(ie+i)
	858	a3 = a(ib+i) - a(ie+i)
	859	a2 = a(ic+i) + a(id+i)
	860	a4 = a(ic+i) - a(id+i)
	861	a5 = a(ia+i) - 0.25_wp*(a1+a2)
	862	a6 = qrt5*(a1-a2)
	863	c(ja+j) = a(ia+i) + (a1+a2)
	864	c(jb+j) = a5 + a6
	865	c(jc+j) = a5 - a6
	866	d(jb+j) = -sin72a3 - sin36a4
	867	d(jc+j) = -sin36a3 + sin72a4
	868	i = i + inc3
	869	j = j + inc4
	870	ENDDO
	871	ibase = ibase + inc1
	872	jbase = jbase + inc2
	873	ENDDO
	874
	875	ja = ja + jink
	876	jink = 2 * jink
	877	jb = jb + jink
	878	jc = jc + jink
	879	jd = jd - jink
	880	je = je - jink
	881	ibase = ibase + ijump
	882	ijump = 2 * ijump + iink
	883
	884	IF ( jb /= jd ) THEN
	885
	886	DO k = la, kstop, la
	887	kb = k + k
	888	kc = kb + kb
	889	kd = kc + kb
	890	ke = kd + kb
	891	c1 = trigs(kb+1)
	892	s1 = trigs(kb+2)
	893	c2 = trigs(kc+1)
	894	s2 = trigs(kc+2)
	895	c3 = trigs(kd+1)
	896	s3 = trigs(kd+2)
	897	c4 = trigs(ke+1)
	898	s4 = trigs(ke+2)
	899	jbase = 0
	900	DO l = 1, la
	901	i = ibase
	902	j = jbase
	903	!DIR$ IVDEP
	904	!CDIR NODEP
	905	!OCL NOVREC
	906	DO ijk = 1, lot
	907	a1 = (c1a(ib+i)+s1b(ib+i)) + (c4a(ie+i)+s4b(ie+i))
	908	a3 = (c1a(ib+i)+s1b(ib+i)) - (c4a(ie+i)+s4b(ie+i))
	909	a2 = (c2a(ic+i)+s2b(ic+i)) + (c3a(id+i)+s3b(id+i))
	910	a4 = (c2a(ic+i)+s2b(ic+i)) - (c3a(id+i)+s3b(id+i))
	911	b1 = (c1b(ib+i)-s1a(ib+i)) + (c4b(ie+i)-s4a(ie+i))
	912	b3 = (c1b(ib+i)-s1a(ib+i)) - (c4b(ie+i)-s4a(ie+i))
	913	b2 = (c2b(ic+i)-s2a(ic+i)) + (c3b(id+i)-s3a(id+i))
	914	b4 = (c2b(ic+i)-s2a(ic+i)) - (c3b(id+i)-s3a(id+i))
	915	a5 = a(ia+i) - 0.25_wp*(a1+a2)
	916	a6 = qrt5*(a1-a2)
	917	b5 = b(ia+i) - 0.25_wp*(b1+b2)
	918	b6 = qrt5*(b1-b2)
	919	a10 = a5 + a6
	920	a20 = a5 - a6
	921	b10 = b5 + b6
	922	b20 = b5 - b6
	923	a11 = sin72b3 + sin36b4
	924	a21 = sin36b3 - sin72b4
	925	b11 = sin72a3 + sin36a4
	926	b21 = sin36a3 - sin72a4
	927	c(ja+j) = a(ia+i) + (a1+a2)
	928	c(jb+j) = a10 + a11
	929	c(je+j) = a10 - a11
	930	c(jc+j) = a20 + a21
	931	c(jd+j) = a20 - a21
	932	d(ja+j) = b(ia+i) + (b1+b2)
	933	d(jb+j) = b10 - b11
	934	d(je+j) = -(b10+b11)
	935	d(jc+j) = b20 - b21
	936	d(jd+j) = -(b20+b21)
	937	i = i + inc3
	938	j = j + inc4
	939	ENDDO
	940	ibase = ibase + inc1
	941	jbase = jbase + inc2
	942	ENDDO
	943	ibase = ibase + ijump
	944	ja = ja + jink
	945	jb = jb + jink
	946	jc = jc + jink
	947	jd = jd - jink
	948	je = je - jink
	949	ENDDO
	950
	951	IF ( jb > jd ) RETURN
	952
	953	ENDIF
	954
	955	jbase = 0
	956	DO l = 1, la
	957	i = ibase
	958	j = jbase
	959	!DIR$ IVDEP
	960	!CDIR NODEP
	961	!OCL NOVREC
	962	DO ijk = 1, lot
	963	a1 = a(ib+i) + a(ie+i)
	964	a3 = a(ib+i) - a(ie+i)
	965	a2 = a(ic+i) + a(id+i)
	966	a4 = a(ic+i) - a(id+i)
	967	a5 = a(ia+i) + 0.25_wp*(a3-a4)
	968	a6 = qrt5*(a3+a4)
	969	c(ja+j) = a5 + a6
	970	c(jb+j) = a5 - a6
	971	c(jc+j) = a(ia+i) - (a3-a4)
	972	d(ja+j) = -sin36a1 - sin72a2
	973	d(jb+j) = -sin72a1 + sin36a2
	974	i = i + inc3
	975	j = j + inc4
	976	ENDDO
	977	ibase = ibase + inc1
	978	jbase = jbase + inc2
	979	ENDDO
	980
	981	ELSE
	982
	983	z = 1.0_wp / REAL( n, KIND=wp )
	984	zqrt5 = z * qrt5
	985	zsin36 = z * sin36
	986	zsin72 = z * sin72
	987	DO l = 1, la
	988	i = ibase
	989	j = jbase
	990	!DIR$ IVDEP
	991	!CDIR NODEP
	992	!OCL NOVREC
	993	DO ijk = 1, lot
	994	a1 = a(ib+i) + a(ie+i)
	995	a3 = a(ib+i) - a(ie+i)
	996	a2 = a(ic+i) + a(id+i)
	997	a4 = a(ic+i) - a(id+i)
	998	a5 = z(a(ia+i)-0.25_wp(a1+a2))
	999	a6 = zqrt5*(a1-a2)
	1000	c(ja+j) = z*(a(ia+i)+(a1+a2))
	1001	c(jb+j) = a5 + a6
	1002	c(jc+j) = a5 - a6
	1003	d(jb+j) = -zsin72a3 - zsin36a4
	1004	d(jc+j) = -zsin36a3 + zsin72a4
	1005	i = i + inc3
	1006	j = j + inc4
	1007	ENDDO
	1008	ibase = ibase + inc1
	1009	jbase = jbase + inc2
	1010	ENDDO
	1011
	1012	ENDIF
	1013
	1014	!
	1015	!-- Coding for factor 6
	1016	CASE ( 5 )
	1017
	1018	ia = 1
	1019	ib = ia + iink
	1020	ic = ib + iink
	1021	id = ic + iink
	1022	ie = id + iink
	1023	if = ie + iink
	1024	ja = 1
	1025	jb = ja + (2m-la) inc2
	1026	jc = jb + 2minc2
	1027	jd = jc + 2minc2
	1028	je = jc
	1029	jf = jb
	1030
	1031	IF ( la /= m ) THEN
	1032
	1033	DO l = 1, la
	1034	i = ibase
	1035	j = jbase
	1036	!DIR$ IVDEP
	1037	!CDIR NODEP
	1038	!OCL NOVREC
	1039	DO ijk = 1, lot
	1040	a11 = (a(ic+i)+a(if+i)) + (a(ib+i)+a(ie+i))
	1041	c(ja+j) = (a(ia+i)+a(id+i)) + a11
	1042	c(jc+j) = (a(ia+i)+a(id+i)-0.5_wp*a11)
	1043	d(jc+j) = sin60*((a(ic+i)+a(if+i))-(a(ib+i)+a(ie+i)))
	1044	a11 = (a(ic+i)-a(if+i)) + (a(ie+i)-a(ib+i))
	1045	c(jb+j) = (a(ia+i)-a(id+i)) - 0.5_wp*a11
	1046	d(jb+j) = sin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
	1047	c(jd+j) = (a(ia+i)-a(id+i)) + a11
	1048	i = i + inc3
	1049	j = j + inc4
	1050	ENDDO
	1051	ibase = ibase + inc1
	1052	jbase = jbase + inc2
	1053	ENDDO
	1054	ja = ja + jink
	1055	jink = 2 * jink
	1056	jb = jb + jink
	1057	jc = jc + jink
	1058	jd = jd - jink
	1059	je = je - jink
	1060	jf = jf - jink
	1061	ibase = ibase + ijump
	1062	ijump = 2 * ijump + iink
	1063
	1064	IF ( jc /= jd ) THEN
	1065
	1066	DO k = la, kstop, la
	1067	kb = k + k
	1068	kc = kb + kb
	1069	kd = kc + kb
	1070	ke = kd + kb
	1071	kf = ke + kb
	1072	c1 = trigs(kb+1)
	1073	s1 = trigs(kb+2)
	1074	c2 = trigs(kc+1)
	1075	s2 = trigs(kc+2)
	1076	c3 = trigs(kd+1)
	1077	s3 = trigs(kd+2)
	1078	c4 = trigs(ke+1)
	1079	s4 = trigs(ke+2)
	1080	c5 = trigs(kf+1)
	1081	s5 = trigs(kf+2)
	1082	jbase = 0
	1083	DO l = 1, la
	1084	i = ibase
	1085	j = jbase
	1086	!DIR$ IVDEP
	1087	!CDIR NODEP
	1088	!OCL NOVREC
	1089	DO ijk = 1, lot
	1090	a1 = c1a(ib+i) + s1b(ib+i)
	1091	b1 = c1b(ib+i) - s1a(ib+i)
	1092	a2 = c2a(ic+i) + s2b(ic+i)
	1093	b2 = c2b(ic+i) - s2a(ic+i)
	1094	a3 = c3a(id+i) + s3b(id+i)
	1095	b3 = c3b(id+i) - s3a(id+i)
	1096	a4 = c4a(ie+i) + s4b(ie+i)
	1097	b4 = c4b(ie+i) - s4a(ie+i)
	1098	a5 = c5a(if+i) + s5b(if+i)
	1099	b5 = c5b(if+i) - s5a(if+i)
	1100	a11 = (a2+a5) + (a1+a4)
	1101	a20 = (a(ia+i)+a3) - 0.5_wp*a11
	1102	a21 = sin60*((a2+a5)-(a1+a4))
	1103	b11 = (b2+b5) + (b1+b4)
	1104	b20 = (b(ia+i)+b3) - 0.5_wp*b11
	1105	b21 = sin60*((b2+b5)-(b1+b4))
	1106	c(ja+j) = (a(ia+i)+a3) + a11
	1107	d(ja+j) = (b(ia+i)+b3) + b11
	1108	c(jc+j) = a20 - b21
	1109	d(jc+j) = a21 + b20
	1110	c(je+j) = a20 + b21
	1111	d(je+j) = a21 - b20
	1112	a11 = (a2-a5) + (a4-a1)
	1113	a20 = (a(ia+i)-a3) - 0.5_wp*a11
	1114	a21 = sin60*((a4-a1)-(a2-a5))
	1115	b11 = (b5-b2) - (b4-b1)
	1116	b20 = (b3-b(ia+i)) - 0.5_wp*b11
	1117	b21 = sin60*((b5-b2)+(b4-b1))
	1118	c(jb+j) = a20 - b21
	1119	d(jb+j) = a21 - b20
	1120	c(jd+j) = a11 + (a(ia+i)-a3)
	1121	d(jd+j) = b11 + (b3-b(ia+i))
	1122	c(jf+j) = a20 + b21
	1123	d(jf+j) = a21 + b20
	1124	i = i + inc3
	1125	j = j + inc4
	1126	ENDDO
	1127	ibase = ibase + inc1
	1128	jbase = jbase + inc2
	1129	ENDDO
	1130	ibase = ibase + ijump
	1131	ja = ja + jink
	1132	jb = jb + jink
	1133	jc = jc + jink
	1134	jd = jd - jink
	1135	je = je - jink
	1136	jf = jf - jink
	1137	ENDDO
	1138
	1139	IF ( jc > jd ) RETURN
	1140
	1141	ENDIF
	1142
	1143	jbase = 0
	1144	DO l = 1, la
	1145	i = ibase
	1146	j = jbase
	1147	!DIR$ IVDEP
	1148	!CDIR NODEP
	1149	!OCL NOVREC
	1150	DO ijk = 1, lot
	1151	c(ja+j) = (a(ia+i)+0.5_wp(a(ic+i)-a(ie+i))) + sin60(a(ib+i)-a(if+i))
	1152	d(ja+j) = -(a(id+i)+0.5_wp(a(ib+i)+a(if+i))) - sin60(a(ic+i)+a(ie+i))
	1153	c(jb+j) = a(ia+i) - (a(ic+i)-a(ie+i))
	1154	d(jb+j) = a(id+i) - (a(ib+i)+a(if+i))
	1155	c(jc+j) = (a(ia+i)+0.5_wp(a(ic+i)-a(ie+i))) - sin60(a(ib+i)-a(if+i))
	1156	d(jc+j) = -(a(id+i)+0.5_wp(a(ib+i)+a(if+i))) + sin60(a(ic+i)+a(ie+i))
	1157	i = i + inc3
	1158	j = j + inc4
	1159	ENDDO
	1160	ibase = ibase + inc1
	1161	jbase = jbase + inc2
	1162	ENDDO
	1163
	1164	ELSE
	1165
	1166	z = 1.0_wp/REAL(n,KIND=wp)
	1167	zsin60 = z*sin60
	1168	DO l = 1, la
	1169	i = ibase
	1170	j = jbase
	1171	!DIR$ IVDEP
	1172	!CDIR NODEP
	1173	!OCL NOVREC
	1174	DO ijk = 1, lot
	1175	a11 = (a(ic+i)+a(if+i)) + (a(ib+i)+a(ie+i))
	1176	c(ja+j) = z*((a(ia+i)+a(id+i))+a11)
	1177	c(jc+j) = z((a(ia+i)+a(id+i))-0.5_wpa11)
	1178	d(jc+j) = zsin60*((a(ic+i)+a(if+i))-(a(ib+i)+a(ie+i)))
	1179	a11 = (a(ic+i)-a(if+i)) + (a(ie+i)-a(ib+i))
	1180	c(jb+j) = z((a(ia+i)-a(id+i))-0.5_wpa11)
	1181	d(jb+j) = zsin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
	1182	c(jd+j) = z*((a(ia+i)-a(id+i))+a11)
	1183	i = i + inc3
	1184	j = j + inc4
	1185	ENDDO
	1186	ibase = ibase + inc1
	1187	jbase = jbase + inc2
	1188	ENDDO
	1189
	1190	ENDIF
	1191
	1192	!
	1193	!-- Coding for factor 8
	1194	CASE ( 6 )
	1195
	1196	IF ( la /= m ) THEN
	1197	ierr = 3
	1198	RETURN
	1199	ENDIF
	1200
	1201	ia = 1
	1202	ib = ia + iink
	1203	ic = ib + iink
	1204	id = ic + iink
	1205	ie = id + iink
	1206	if = ie + iink
	1207	ig = if + iink
	1208	ih = ig + iink
	1209	ja = 1
	1210	jb = ja + la * inc2
	1211	jc = jb + 2minc2
	1212	jd = jc + 2minc2
	1213	je = jd + 2minc2
	1214	z = 1.0_wp / REAL( n, KIND=wp )
	1215	zsin45 = z * SQRT( 0.5_wp )
	1216
	1217	DO l = 1, la
	1218	i = ibase
	1219	j = jbase
	1220
	1221	!DIR$ IVDEP
	1222	!CDIR NODEP
	1223	!OCL NOVREC
	1224	DO ijk = 1, lot
	1225	c(ja+j) = z*(((a(ia+i)+a(ie+i))+(a(ic+i)+a(ig+i)))+((a(id+i)+ a(ih+i))+(a(ib+i)+a(if+i))))
	1226	c(je+j) = z*(((a(ia+i)+a(ie+i))+(a(ic+i)+a(ig+i)))-((a(id+i)+ a(ih+i))+(a(ib+i)+a(if+i))))
	1227	c(jc+j) = z*((a(ia+i)+a(ie+i))-(a(ic+i)+a(ig+i)))
	1228	d(jc+j) = z*((a(id+i)+a(ih+i))-(a(ib+i)+a(if+i)))
	1229	c(jb+j) = z(a(ia+i)-a(ie+i)) + zsin45((a(ih+i)-a(id+i))-(a(if+i)-a(ib+i)))
	1230	c(jd+j) = z(a(ia+i)-a(ie+i)) - zsin45((a(ih+i)-a(id+i))-(a(if+i)-a(ib+i)))
	1231	d(jb+j) = zsin45((a(ih+i)-a(id+i))+(a(if+i)-a(ib+i))) + z(a(ig+i)-a(ic+i))
	1232	d(jd+j) = zsin45((a(ih+i)-a(id+i))+(a(if+i)-a(ib+i))) - z(a(ig+i)-a(ic+i))
	1233	i = i + inc3
	1234	j = j + inc4
	1235	ENDDO
	1236	ibase = ibase + inc1
	1237	jbase = jbase + inc2
	1238	ENDDO
	1239
	1240	END SELECT
	1241
	1242	END SUBROUTINE qpassm
	1243
[1682]	1244	!------------------------------------------------------------------------------!
	1245	! Description:
	1246	! ------------
[3725]	1247	!> Same as qpassm, but for backward fft
[1682]	1248	!------------------------------------------------------------------------------!
[3725]	1249	SUBROUTINE rpassm( a, b, c, d, trigs, inc1, inc2, inc3, inc4, lot, n, ifac, la, ierr )
[1]	1250
[1320]	1251	USE kinds
	1252
[1]	1253	IMPLICIT NONE
	1254
[1682]	1255	INTEGER(iwp) :: ierr !<
	1256	INTEGER(iwp) :: ifac !<
	1257	INTEGER(iwp) :: inc1 !<
	1258	INTEGER(iwp) :: inc2 !<
	1259	INTEGER(iwp) :: inc3 !<
	1260	INTEGER(iwp) :: inc4 !<
	1261	INTEGER(iwp) :: la !<
	1262	INTEGER(iwp) :: lot !<
	1263	INTEGER(iwp) :: n !<
[3725]	1264	!
	1265	!-- Arrays are dimensioned with n
[1682]	1266	REAL(wp) :: a(*) !<
	1267	REAL(wp) :: b(*) !<
	1268	REAL(wp) :: c(*) !<
	1269	REAL(wp) :: d(*) !<
	1270	REAL(wp) :: trigs(*) !<
[1]	1271
[1682]	1272	REAL(wp) :: c1 !<
	1273	REAL(wp) :: c2 !<
	1274	REAL(wp) :: c3 !<
	1275	REAL(wp) :: c4 !<
	1276	REAL(wp) :: c5 !<
	1277	REAL(wp) :: qqrt5 !<
	1278	REAL(wp) :: qrt5 !<
	1279	REAL(wp) :: s1 !<
	1280	REAL(wp) :: s2 !<
	1281	REAL(wp) :: s3 !<
	1282	REAL(wp) :: s4 !<
	1283	REAL(wp) :: s5 !<
	1284	REAL(wp) :: sin36 !<
	1285	REAL(wp) :: sin45 !<
	1286	REAL(wp) :: sin60 !<
	1287	REAL(wp) :: sin72 !<
	1288	REAL(wp) :: ssin36 !<
	1289	REAL(wp) :: ssin45 !<
	1290	REAL(wp) :: ssin60 !<
	1291	REAL(wp) :: ssin72 !<
[1]	1292
[1682]	1293	INTEGER(iwp) :: i !<
	1294	INTEGER(iwp) :: ia !<
	1295	INTEGER(iwp) :: ib !<
	1296	INTEGER(iwp) :: ibase !<
	1297	INTEGER(iwp) :: ic !<
	1298	INTEGER(iwp) :: id !<
	1299	INTEGER(iwp) :: ie !<
	1300	INTEGER(iwp) :: if !<
	1301	INTEGER(iwp) :: igo !<
	1302	INTEGER(iwp) :: iink !<
	1303	INTEGER(iwp) :: ijk !<
	1304	INTEGER(iwp) :: j !<
	1305	INTEGER(iwp) :: ja !<
	1306	INTEGER(iwp) :: jb !<
	1307	INTEGER(iwp) :: jbase !<
	1308	INTEGER(iwp) :: jc !<
	1309	INTEGER(iwp) :: jd !<
	1310	INTEGER(iwp) :: je !<
	1311	INTEGER(iwp) :: jf !<
	1312	INTEGER(iwp) :: jg !<
	1313	INTEGER(iwp) :: jh !<
	1314	INTEGER(iwp) :: jink !<
	1315	INTEGER(iwp) :: jump !<
	1316	INTEGER(iwp) :: k !<
	1317	INTEGER(iwp) :: kb !<
	1318	INTEGER(iwp) :: kc !<
	1319	INTEGER(iwp) :: kd !<
	1320	INTEGER(iwp) :: ke !<
	1321	INTEGER(iwp) :: kf !<
	1322	INTEGER(iwp) :: kstop !<
	1323	INTEGER(iwp) :: l !<
	1324	INTEGER(iwp) :: m !<
[1320]	1325
[1682]	1326	REAL(wp) :: a10(nfft) !<
	1327	REAL(wp) :: a11(nfft) !<
	1328	REAL(wp) :: a20(nfft) !<
	1329	REAL(wp) :: a21(nfft) !<
	1330	REAL(wp) :: b10(nfft) !<
	1331	REAL(wp) :: b11(nfft) !<
	1332	REAL(wp) :: b20(nfft) !<
	1333	REAL(wp) :: b21(nfft) !<
[1]	1334
	1335
[3725]	1336	DATA sin36/0.587785252292473_wp/, sin72/0.951056516295154_wp/, &
	1337	qrt5/0.559016994374947_wp/, sin60/0.866025403784437_wp/
[1]	1338
	1339
[3725]	1340	ierr = 0
[1]	1341
[3725]	1342	m = n / ifac
	1343	iink = la * inc1
	1344	jink = la * inc2
	1345	jump = (ifac-1) * jink
	1346	kstop = (n-ifac) / (2*ifac)
[1]	1347
[3725]	1348	IF ( lot > nfft ) THEN
	1349	ierr = 1
	1350	RETURN
	1351	ENDIF
[1]	1352	ibase = 0
	1353	jbase = 0
	1354	igo = ifac - 1
[3725]	1355	IF ( igo == 7 ) igo = 6
	1356	IF ( igo < 1 .OR. igo > 6 ) THEN
	1357	ierr = 2
	1358	RETURN
	1359	ENDIF
[1]	1360
	1361
[3725]	1362	SELECT CASE ( igo )
	1363	!
	1364	!-- Coding for factor 2
	1365	CASE ( 1 )
[1]	1366
[3725]	1367	ia = 1
	1368	ib = ia + (2m-la) inc1
	1369	ja = 1
	1370	jb = ja + jink
[1]	1371
[3725]	1372	IF ( la /= m ) THEN
[1]	1373
[3725]	1374	DO l = 1, la
	1375	i = ibase
	1376	j = jbase
	1377	!DIR$ IVDEP
	1378	!CDIR NODEP
	1379	!OCL NOVREC
	1380	DO ijk = 1, lot
	1381	c(ja+j) = a(ia+i) + a(ib+i)
	1382	c(jb+j) = a(ia+i) - a(ib+i)
	1383	i = i + inc3
	1384	j = j + inc4
	1385	ENDDO
	1386	ibase = ibase + inc1
	1387	jbase = jbase + inc2
	1388	ENDDO
[1]	1389
[3725]	1390	ia = ia + iink
	1391	iink = 2 * iink
	1392	ib = ib - iink
	1393	ibase = 0
	1394	jbase = jbase + jump
	1395	jump = 2 * jump + jink
[1]	1396
[3725]	1397	IF ( ia /= ib ) THEN
[1]	1398
[3725]	1399	DO k = la, kstop, la
	1400	kb = k + k
	1401	c1 = trigs(kb+1)
	1402	s1 = trigs(kb+2)
	1403	ibase = 0
	1404	DO l = 1, la
	1405	i = ibase
	1406	j = jbase
	1407	!DIR$ IVDEP
	1408	!CDIR NODEP
	1409	!OCL NOVREC
	1410	DO ijk = 1, lot
	1411	c(ja+j) = a(ia+i) + a(ib+i)
	1412	d(ja+j) = b(ia+i) - b(ib+i)
	1413	c(jb+j) = c1(a(ia+i)-a(ib+i)) - s1(b(ia+i)+b(ib+i))
	1414	d(jb+j) = s1(a(ia+i)-a(ib+i)) + c1(b(ia+i)+b(ib+i))
	1415	i = i + inc3
	1416	j = j + inc4
	1417	ENDDO
	1418	ibase = ibase + inc1
	1419	jbase = jbase + inc2
	1420	ENDDO
	1421	ia = ia + iink
	1422	ib = ib - iink
	1423	jbase = jbase + jump
	1424	ENDDO
[1]	1425
[3725]	1426	IF ( ia > ib ) RETURN
[1]	1427
[3725]	1428	ENDIF
[1]	1429
[3725]	1430	ibase = 0
	1431	DO l = 1, la
	1432	i = ibase
	1433	j = jbase
	1434	!DIR$ IVDEP
	1435	!CDIR NODEP
	1436	!OCL NOVREC
	1437	DO ijk = 1, lot
	1438	c(ja+j) = a(ia+i)
	1439	c(jb+j) = -b(ia+i)
	1440	i = i + inc3
	1441	j = j + inc4
	1442	ENDDO
	1443	ibase = ibase + inc1
	1444	jbase = jbase + inc2
	1445	ENDDO
[1]	1446
[3725]	1447	ELSE
[1]	1448
[3725]	1449	DO l = 1, la
	1450	i = ibase
	1451	j = jbase
	1452	!DIR$ IVDEP
	1453	!CDIR NODEP
	1454	!OCL NOVREC
	1455	DO ijk = 1, lot
	1456	c(ja+j) = 2.0_wp*(a(ia+i)+a(ib+i))
	1457	c(jb+j) = 2.0_wp*(a(ia+i)-a(ib+i))
	1458	i = i + inc3
	1459	j = j + inc4
	1460	ENDDO
	1461	ibase = ibase + inc1
	1462	jbase = jbase + inc2
	1463	ENDDO
[1]	1464
[3725]	1465	ENDIF
[1]	1466
[3725]	1467	!
	1468	!-- Coding for factor 3
	1469	CASE ( 2 )
[1]	1470
[3725]	1471	ia = 1
	1472	ib = ia + (2m-la) inc1
	1473	ic = ib
	1474	ja = 1
	1475	jb = ja + jink
	1476	jc = jb + jink
[1]	1477
[3725]	1478	IF ( la /= m ) THEN
[1]	1479
[3725]	1480	DO l = 1, la
	1481	i = ibase
	1482	j = jbase
	1483	!DIR$ IVDEP
	1484	!CDIR NODEP
	1485	!OCL NOVREC
	1486	DO ijk = 1, lot
	1487	c(ja+j) = a(ia+i) + a(ib+i)
	1488	c(jb+j) = (a(ia+i)-0.5_wpa(ib+i)) - (sin60(b(ib+i)))
	1489	c(jc+j) = (a(ia+i)-0.5_wpa(ib+i)) + (sin60(b(ib+i)))
	1490	i = i + inc3
	1491	j = j + inc4
	1492	ENDDO
	1493	ibase = ibase + inc1
	1494	jbase = jbase + inc2
	1495	ENDDO
	1496	ia = ia + iink
	1497	iink = 2 * iink
	1498	ib = ib + iink
	1499	ic = ic - iink
	1500	jbase = jbase + jump
	1501	jump = 2 * jump + jink
[1]	1502
[3725]	1503	IF ( ia /= ic ) THEN
[1]	1504
[3725]	1505	DO k = la, kstop, la
	1506	kb = k + k
	1507	kc = kb + kb
	1508	c1 = trigs(kb+1)
	1509	s1 = trigs(kb+2)
	1510	c2 = trigs(kc+1)
	1511	s2 = trigs(kc+2)
	1512	ibase = 0
	1513	DO l = 1, la
	1514	i = ibase
	1515	j = jbase
	1516	!DIR$ IVDEP
	1517	!CDIR NODEP
	1518	!OCL NOVREC
	1519	DO ijk = 1, lot
	1520	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
	1521	d(ja+j) = b(ia+i) + (b(ib+i)-b(ic+i))
	1522	c(jb+j) = c1((a(ia+i)-0.5_wp(a(ib+i)+a(ic+i)))-(sin60*(b(ib+i)+ b(ic+i)))) &
	1523	- s1((b(ia+i)-0.5_wp(b(ib+i)-b(ic+i)))+(sin60*(a(ib+i)- a(ic+i))))
	1524	d(jb+j) = s1((a(ia+i)-0.5_wp(a(ib+i)+a(ic+i)))-(sin60*(b(ib+i)+ b(ic+i)))) &
	1525	+ c1((b(ia+i)-0.5_wp(b(ib+i)-b(ic+i)))+(sin60*(a(ib+i)- a(ic+i))))
	1526	c(jc+j) = c2((a(ia+i)-0.5_wp(a(ib+i)+a(ic+i)))+(sin60*(b(ib+i)+ b(ic+i)))) &
	1527	- s2((b(ia+i)-0.5_wp(b(ib+i)-b(ic+i)))-(sin60*(a(ib+i)- a(ic+i))))
	1528	d(jc+j) = s2((a(ia+i)-0.5_wp(a(ib+i)+a(ic+i)))+(sin60*(b(ib+i)+ b(ic+i)))) &
	1529	+ c2((b(ia+i)-0.5_wp(b(ib+i)-b(ic+i)))-(sin60*(a(ib+i)- a(ic+i))))
	1530	i = i + inc3
	1531	j = j + inc4
	1532	ENDDO
	1533	ibase = ibase + inc1
	1534	jbase = jbase + inc2
	1535	ENDDO
	1536	ia = ia + iink
	1537	ib = ib + iink
	1538	ic = ic - iink
	1539	jbase = jbase + jump
	1540	ENDDO
[1]	1541
[3725]	1542	IF ( ia > ic ) RETURN
[1]	1543
[3725]	1544	ENDIF
[1]	1545
[3725]	1546	ibase = 0
	1547	DO l = 1, la
	1548	i = ibase
	1549	j = jbase
	1550	!DIR$ IVDEP
	1551	!CDIR NODEP
	1552	!OCL NOVREC
	1553	DO ijk = 1, lot
	1554	c(ja+j) = a(ia+i) + a(ib+i)
	1555	c(jb+j) = (0.5_wpa(ia+i)-a(ib+i)) - (sin60b(ia+i))
	1556	c(jc+j) = -(0.5_wpa(ia+i)-a(ib+i)) - (sin60b(ia+i))
	1557	i = i + inc3
	1558	j = j + inc4
	1559	ENDDO
	1560	ibase = ibase + inc1
	1561	jbase = jbase + inc2
	1562	ENDDO
[1]	1563
[3725]	1564	ELSE
[1]	1565
[3725]	1566	ssin60 = 2.0_wp * sin60
	1567	DO l = 1, la
	1568	i = ibase
	1569	j = jbase
	1570	!DIR$ IVDEP
	1571	!CDIR NODEP
	1572	!OCL NOVREC
	1573	DO ijk = 1, lot
	1574	c(ja+j) = 2.0_wp*(a(ia+i)+a(ib+i))
	1575	c(jb+j) = (2.0_wpa(ia+i)-a(ib+i)) - (ssin60b(ib+i))
	1576	c(jc+j) = (2.0_wpa(ia+i)-a(ib+i)) + (ssin60b(ib+i))
	1577	i = i + inc3
	1578	j = j + inc4
	1579	ENDDO
	1580	ibase = ibase + inc1
	1581	jbase = jbase + inc2
	1582	ENDDO
[1]	1583
[3725]	1584	ENDIF
[1]	1585
[3725]	1586	!
	1587	!-- Coding for factor 4
	1588	CASE ( 3 )
[1]	1589
[3725]	1590	ia = 1
	1591	ib = ia + (2m-la) inc1
	1592	ic = ib + 2minc1
	1593	id = ib
	1594	ja = 1
	1595	jb = ja + jink
	1596	jc = jb + jink
	1597	jd = jc + jink
[1]	1598
[3725]	1599	IF ( la /= m ) THEN
[1]	1600
[3725]	1601	DO l = 1, la
	1602	i = ibase
	1603	j = jbase
	1604	!DIR$ IVDEP
	1605	!CDIR NODEP
	1606	!OCL NOVREC
	1607	DO ijk = 1, lot
	1608	c(ja+j) = (a(ia+i)+a(ic+i)) + a(ib+i)
	1609	c(jb+j) = (a(ia+i)-a(ic+i)) - b(ib+i)
	1610	c(jc+j) = (a(ia+i)+a(ic+i)) - a(ib+i)
	1611	c(jd+j) = (a(ia+i)-a(ic+i)) + b(ib+i)
	1612	i = i + inc3
	1613	j = j + inc4
	1614	ENDDO
	1615	ibase = ibase + inc1
	1616	jbase = jbase + inc2
	1617	ENDDO
	1618	ia = ia + iink
	1619	iink = 2 * iink
	1620	ib = ib + iink
	1621	ic = ic - iink
	1622	id = id - iink
	1623	jbase = jbase + jump
	1624	jump = 2 * jump + jink
[1]	1625
[3725]	1626	IF ( ib /= ic ) THEN
[1]	1627
[3725]	1628	DO k = la, kstop, la
	1629	kb = k + k
	1630	kc = kb + kb
	1631	kd = kc + kb
	1632	c1 = trigs(kb+1)
	1633	s1 = trigs(kb+2)
	1634	c2 = trigs(kc+1)
	1635	s2 = trigs(kc+2)
	1636	c3 = trigs(kd+1)
	1637	s3 = trigs(kd+2)
	1638	ibase = 0
	1639	DO l = 1, la
	1640	i = ibase
	1641	j = jbase
	1642	!DIR$ IVDEP
	1643	!CDIR NODEP
	1644	!OCL NOVREC
	1645	DO ijk = 1, lot
	1646	c(ja+j) = (a(ia+i)+a(ic+i)) + (a(ib+i)+a(id+i))
	1647	d(ja+j) = (b(ia+i)-b(ic+i)) + (b(ib+i)-b(id+i))
	1648	c(jc+j) = c2((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i))) - s2((b(ia+i)-b(ic+i))&
	1649	-(b(ib+i)-b(id+i)))
	1650	d(jc+j) = s2((a(ia+i)+a(ic+i))-(a(ib+i)+a(id+i))) + c2((b(ia+i)-b(ic+i))&
	1651	-(b(ib+i)-b(id+i)))
	1652	c(jb+j) = c1((a(ia+i)-a(ic+i))-(b(ib+i)+b(id+i))) - s1((b(ia+i)+b(ic+i))&
	1653	+(a(ib+i)-a(id+i)))
	1654	d(jb+j) = s1((a(ia+i)-a(ic+i))-(b(ib+i)+b(id+i))) + c1((b(ia+i)+b(ic+i))&
	1655	+(a(ib+i)-a(id+i)))
	1656	c(jd+j) = c3((a(ia+i)-a(ic+i))+(b(ib+i)+b(id+i))) - s3((b(ia+i)+b(ic+i))&
	1657	-(a(ib+i)-a(id+i)))
	1658	d(jd+j) = s3((a(ia+i)-a(ic+i))+(b(ib+i)+b(id+i))) + c3((b(ia+i)+b(ic+i))&
	1659	-(a(ib+i)-a(id+i)))
	1660	i = i + inc3
	1661	j = j + inc4
	1662	ENDDO
	1663	ibase = ibase + inc1
	1664	jbase = jbase + inc2
	1665	ENDDO
	1666	ia = ia + iink
	1667	ib = ib + iink
	1668	ic = ic - iink
	1669	id = id - iink
	1670	jbase = jbase + jump
	1671	ENDDO
[1]	1672
[3725]	1673	IF ( ib > ic ) RETURN
[1]	1674
[3725]	1675	ENDIF
[1]	1676
[3725]	1677	ibase = 0
	1678	sin45 = SQRT( 0.5_wp )
	1679	DO l = 1, la
	1680	i = ibase
	1681	j = jbase
	1682	!DIR$ IVDEP
	1683	!CDIR NODEP
	1684	!OCL NOVREC
	1685	DO ijk = 1, lot
	1686	c(ja+j) = a(ia+i) + a(ib+i)
	1687	c(jb+j) = sin45*((a(ia+i)-a(ib+i))-(b(ia+i)+b(ib+i)))
	1688	c(jc+j) = b(ib+i) - b(ia+i)
	1689	c(jd+j) = -sin45*((a(ia+i)-a(ib+i))+(b(ia+i)+b(ib+i)))
	1690	i = i + inc3
	1691	j = j + inc4
	1692	ENDDO
	1693	ibase = ibase + inc1
	1694	jbase = jbase + inc2
	1695	ENDDO
[1]	1696
[3725]	1697	ELSE
[1]	1698
[3725]	1699	DO l = 1, la
	1700	i = ibase
	1701	j = jbase
	1702	!DIR$ IVDEP
	1703	!CDIR NODEP
	1704	!OCL NOVREC
	1705	DO ijk = 1, lot
	1706	c(ja+j) = 2.0_wp*((a(ia+i)+a(ic+i))+a(ib+i))
	1707	c(jb+j) = 2.0_wp*((a(ia+i)-a(ic+i))-b(ib+i))
	1708	c(jc+j) = 2.0_wp*((a(ia+i)+a(ic+i))-a(ib+i))
	1709	c(jd+j) = 2.0_wp*((a(ia+i)-a(ic+i))+b(ib+i))
	1710	i = i + inc3
	1711	j = j + inc4
	1712	ENDDO
	1713	ibase = ibase + inc1
	1714	jbase = jbase + inc2
	1715	ENDDO
[1]	1716
[3725]	1717	ENDIF
[1]	1718
[3725]	1719	!
	1720	!-- Coding for factor 5
	1721	CASE ( 4 )
	1722
	1723	ia = 1
	1724	ib = ia + (2m-la) inc1
	1725	ic = ib + 2minc1
	1726	id = ic
	1727	ie = ib
	1728	ja = 1
	1729	jb = ja + jink
	1730	jc = jb + jink
	1731	jd = jc + jink
	1732	je = jd + jink
	1733
	1734	IF ( la /= m ) THEN
	1735
	1736	DO l = 1, la
	1737	i = ibase
	1738	j = jbase
	1739	!DIR$ IVDEP
	1740	!CDIR NODEP
	1741	!OCL NOVREC
	1742	DO ijk = 1, lot
	1743	c(ja+j) = a(ia+i) + (a(ib+i)+a(ic+i))
	1744	c(jb+j) = ((a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))+qrt5(a(ib+i)-a(ic+i))) - &
	1745	(sin72b(ib+i)+sin36b(ic+i))
	1746	c(jc+j) = ((a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))-qrt5(a(ib+i)-a(ic+i))) - &
	1747	(sin36b(ib+i)-sin72b(ic+i))
	1748	c(jd+j) = ((a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))-qrt5(a(ib+i)-a(ic+i))) + &
	1749	(sin36b(ib+i)-sin72b(ic+i))
	1750	c(je+j) = ((a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))+qrt5(a(ib+i)-a(ic+i))) + &
	1751	(sin72b(ib+i)+sin36b(ic+i))
	1752	i = i + inc3
	1753	j = j + inc4
	1754	ENDDO
	1755	ibase = ibase + inc1
	1756	jbase = jbase + inc2
	1757	ENDDO
	1758	ia = ia + iink
	1759	iink = 2 * iink
	1760	ib = ib + iink
	1761	ic = ic + iink
	1762	id = id - iink
	1763	ie = ie - iink
	1764	jbase = jbase + jump
	1765	jump = 2 * jump + jink
	1766
	1767	IF ( ib /= id ) THEN
	1768
	1769	DO k = la, kstop, la
	1770	kb = k + k
	1771	kc = kb + kb
	1772	kd = kc + kb
	1773	ke = kd + kb
	1774	c1 = trigs(kb+1)
	1775	s1 = trigs(kb+2)
	1776	c2 = trigs(kc+1)
	1777	s2 = trigs(kc+2)
	1778	c3 = trigs(kd+1)
	1779	s3 = trigs(kd+2)
	1780	c4 = trigs(ke+1)
	1781	s4 = trigs(ke+2)
	1782	ibase = 0
	1783	DO l = 1, la
	1784	i = ibase
	1785	j = jbase
	1786	!DIR$ IVDEP
	1787	!CDIR NODEP
	1788	!OCL NOVREC
	1789	DO ijk = 1, lot
	1790	a10(ijk) = (a(ia+i)-0.25_wp*((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))) + &
	1791	qrt5*((a(ib+i)+a(ie+i))-(a(ic+i)+a(id+i)))
	1792	a20(ijk) = (a(ia+i)-0.25_wp*((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))) - &
	1793	qrt5*((a(ib+i)+a(ie+i))-(a(ic+i)+a(id+i)))
	1794	b10(ijk) = (b(ia+i)-0.25_wp*((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))) + &
	1795	qrt5*((b(ib+i)-b(ie+i))-(b(ic+i)-b(id+i)))
	1796	b20(ijk) = (b(ia+i)-0.25_wp*((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))) - &
	1797	qrt5*((b(ib+i)-b(ie+i))-(b(ic+i)-b(id+i)))
	1798	a11(ijk) = sin72(b(ib+i)+b(ie+i)) + sin36(b(ic+i)+b(id+i))
	1799	a21(ijk) = sin36(b(ib+i)+b(ie+i)) - sin72(b(ic+i)+b(id+i))
	1800	b11(ijk) = sin72(a(ib+i)-a(ie+i)) + sin36(a(ic+i)-a(id+i))
	1801	b21(ijk) = sin36(a(ib+i)-a(ie+i)) - sin72(a(ic+i)-a(id+i))
	1802	c(ja+j) = a(ia+i) + ((a(ib+i)+a(ie+i))+(a(ic+i)+a(id+i)))
	1803	d(ja+j) = b(ia+i) + ((b(ib+i)-b(ie+i))+(b(ic+i)-b(id+i)))
	1804	c(jb+j) = c1(a10(ijk)-a11(ijk)) - s1(b10(ijk)+b11(ijk))
	1805	d(jb+j) = s1(a10(ijk)-a11(ijk)) + c1(b10(ijk)+b11(ijk))
	1806	c(je+j) = c4(a10(ijk)+a11(ijk)) - s4(b10(ijk)-b11(ijk))
	1807	d(je+j) = s4(a10(ijk)+a11(ijk)) + c4(b10(ijk)-b11(ijk))
	1808	c(jc+j) = c2(a20(ijk)-a21(ijk)) - s2(b20(ijk)+b21(ijk))
	1809	d(jc+j) = s2(a20(ijk)-a21(ijk)) + c2(b20(ijk)+b21(ijk))
	1810	c(jd+j) = c3(a20(ijk)+a21(ijk)) - s3(b20(ijk)-b21(ijk))
	1811	d(jd+j) = s3(a20(ijk)+a21(ijk)) + c3(b20(ijk)-b21(ijk))
	1812
	1813	i = i + inc3
	1814	j = j + inc4
	1815	ENDDO
	1816	ibase = ibase + inc1
	1817	jbase = jbase + inc2
	1818	ENDDO
	1819	ia = ia + iink
	1820	ib = ib + iink
	1821	ic = ic + iink
	1822	id = id - iink
	1823	ie = ie - iink
	1824	jbase = jbase + jump
	1825	ENDDO
	1826
	1827	IF ( ib > id ) RETURN
	1828
	1829	ENDIF
	1830
	1831	ibase = 0
	1832	DO l = 1, la
	1833	i = ibase
	1834	j = jbase
	1835	!DIR$ IVDEP
	1836	!CDIR NODEP
	1837	!OCL NOVREC
	1838	DO ijk = 1, lot
	1839	c(ja+j) = (a(ia+i)+a(ib+i)) + a(ic+i)
	1840	c(jb+j) = (qrt5(a(ia+i)-a(ib+i))+(0.25_wp(a(ia+i)+a(ib+i))-a(ic+i))) - &
	1841	(sin36b(ia+i)+sin72b(ib+i))
	1842	c(je+j) = -(qrt5(a(ia+i)-a(ib+i))+(0.25_wp(a(ia+i)+a(ib+i))-a(ic+i))) - &
	1843	(sin36b(ia+i)+sin72b(ib+i))
	1844	c(jc+j) = (qrt5(a(ia+i)-a(ib+i))-(0.25_wp(a(ia+i)+a(ib+i))-a(ic+i))) - &
	1845	(sin72b(ia+i)-sin36b(ib+i))
	1846	c(jd+j) = -(qrt5(a(ia+i)-a(ib+i))-(0.25_wp(a(ia+i)+a(ib+i))-a(ic+i))) - &
	1847	(sin72b(ia+i)-sin36b(ib+i))
	1848	i = i + inc3
	1849	j = j + inc4
	1850	ENDDO
	1851	ibase = ibase + inc1
	1852	jbase = jbase + inc2
	1853	ENDDO
	1854
	1855	ELSE
	1856
	1857	qqrt5 = 2.0_wp * qrt5
	1858	ssin36 = 2.0_wp * sin36
	1859	ssin72 = 2.0_wp * sin72
	1860	DO l = 1, la
	1861	i = ibase
	1862	j = jbase
	1863	!DIR$ IVDEP
	1864	!CDIR NODEP
	1865	!OCL NOVREC
	1866	DO ijk = 1, lot
	1867	c(ja+j) = 2.0_wp*(a(ia+i)+(a(ib+i)+a(ic+i)))
	1868	c(jb+j) = (2.0_wp(a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))+qqrt5*(a(ib+i)-a(ic+i))) &
	1869	- (ssin72b(ib+i)+ssin36b(ic+i))
	1870	c(jc+j) = (2.0_wp(a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))-qqrt5*(a(ib+i)-a(ic+i))) &
	1871	- (ssin36b(ib+i)-ssin72b(ic+i))
	1872	c(jd+j) = (2.0_wp(a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))-qqrt5*(a(ib+i)-a(ic+i))) &
	1873	+ (ssin36b(ib+i)-ssin72b(ic+i))
	1874	c(je+j) = (2.0_wp(a(ia+i)-0.25_wp(a(ib+i)+a(ic+i)))+qqrt5*(a(ib+i)-a(ic+i))) &
	1875	+ (ssin72b(ib+i)+ssin36b(ic+i))
	1876	i = i + inc3
	1877	j = j + inc4
	1878	ENDDO
	1879	ibase = ibase + inc1
	1880	jbase = jbase + inc2
	1881	ENDDO
	1882
	1883	ENDIF
	1884
	1885	!
	1886	!-- Coding for factor 6
	1887	CASE ( 5 )
	1888
	1889	ia = 1
	1890	ib = ia + (2m-la) inc1
	1891	ic = ib + 2minc1
	1892	id = ic + 2minc1
	1893	ie = ic
	1894	if = ib
	1895	ja = 1
	1896	jb = ja + jink
	1897	jc = jb + jink
	1898	jd = jc + jink
	1899	je = jd + jink
	1900	jf = je + jink
	1901
	1902	IF ( la /= m ) THEN
	1903
	1904	DO l = 1, la
	1905	i = ibase
	1906	j = jbase
	1907	!DIR$ IVDEP
	1908	!CDIR NODEP
	1909	!OCL NOVREC
	1910	DO ijk = 1, lot
	1911	c(ja+j) = (a(ia+i)+a(id+i)) + (a(ib+i)+a(ic+i))
	1912	c(jd+j) = (a(ia+i)-a(id+i)) - (a(ib+i)-a(ic+i))
	1913	c(jb+j) = ((a(ia+i)-a(id+i))+0.5_wp(a(ib+i)-a(ic+i))) - (sin60(b(ib+i)+b(ic+i)))
	1914	c(jf+j) = ((a(ia+i)-a(id+i))+0.5_wp(a(ib+i)-a(ic+i))) + (sin60(b(ib+i)+b(ic+i)))
	1915	c(jc+j) = ((a(ia+i)+a(id+i))-0.5_wp(a(ib+i)+a(ic+i))) - (sin60(b(ib+i)-b(ic+i)))
	1916	c(je+j) = ((a(ia+i)+a(id+i))-0.5_wp(a(ib+i)+a(ic+i))) + (sin60(b(ib+i)-b(ic+i)))
	1917	i = i + inc3
	1918	j = j + inc4
	1919	ENDDO
	1920	ibase = ibase + inc1
	1921	jbase = jbase + inc2
	1922	ENDDO
	1923	ia = ia + iink
	1924	iink = 2 * iink
	1925	ib = ib + iink
	1926	ic = ic + iink
	1927	id = id - iink
	1928	ie = ie - iink
	1929	if = if - iink
	1930	jbase = jbase + jump
	1931	jump = 2 * jump + jink
	1932
	1933	IF ( ic /= id ) THEN
	1934
	1935	DO k = la, kstop, la
	1936	kb = k + k
	1937	kc = kb + kb
	1938	kd = kc + kb
	1939	ke = kd + kb
	1940	kf = ke + kb
	1941	c1 = trigs(kb+1)
	1942	s1 = trigs(kb+2)
	1943	c2 = trigs(kc+1)
	1944	s2 = trigs(kc+2)
	1945	c3 = trigs(kd+1)
	1946	s3 = trigs(kd+2)
	1947	c4 = trigs(ke+1)
	1948	s4 = trigs(ke+2)
	1949	c5 = trigs(kf+1)
	1950	s5 = trigs(kf+2)
	1951	ibase = 0
	1952	DO l = 1, la
	1953	i = ibase
	1954	j = jbase
	1955	!DIR$ IVDEP
	1956	!CDIR NODEP
	1957	!OCL NOVREC
	1958	DO ijk = 1, lot
	1959	a11(ijk) = (a(ie+i)+a(ib+i)) + (a(ic+i)+a(if+i))
	1960	a20(ijk) = (a(ia+i)+a(id+i)) - 0.5_wp*a11(ijk)
	1961	a21(ijk) = sin60*((a(ie+i)+a(ib+i))-(a(ic+i)+a(if+i)))
	1962	b11(ijk) = (b(ib+i)-b(ie+i)) + (b(ic+i)-b(if+i))
	1963	b20(ijk) = (b(ia+i)-b(id+i)) - 0.5_wp*b11(ijk)
	1964	b21(ijk) = sin60*((b(ib+i)-b(ie+i))-(b(ic+i)-b(if+i)))
	1965
	1966	c(ja+j) = (a(ia+i)+a(id+i)) + a11(ijk)
	1967	d(ja+j) = (b(ia+i)-b(id+i)) + b11(ijk)
	1968	c(jc+j) = c2(a20(ijk)-b21(ijk)) - s2(b20(ijk)+a21(ijk))
	1969	d(jc+j) = s2(a20(ijk)-b21(ijk)) + c2(b20(ijk)+a21(ijk))
	1970	c(je+j) = c4(a20(ijk)+b21(ijk)) - s4(b20(ijk)-a21(ijk))
	1971	d(je+j) = s4(a20(ijk)+b21(ijk)) + c4(b20(ijk)-a21(ijk))
	1972
	1973	a11(ijk) = (a(ie+i)-a(ib+i)) + (a(ic+i)-a(if+i))
	1974	b11(ijk) = (b(ie+i)+b(ib+i)) - (b(ic+i)+b(if+i))
	1975	a20(ijk) = (a(ia+i)-a(id+i)) - 0.5_wp*a11(ijk)
	1976	a21(ijk) = sin60*((a(ie+i)-a(ib+i))-(a(ic+i)-a(if+i)))
	1977	b20(ijk) = (b(ia+i)+b(id+i)) + 0.5_wp*b11(ijk)
	1978	b21(ijk) = sin60*((b(ie+i)+b(ib+i))+(b(ic+i)+b(if+i)))
	1979
	1980	c(jd+j) = c3((a(ia+i)-a(id+i))+a11(ijk)) - s3((b(ia+i)+b(id+i))-b11(ijk))
	1981	d(jd+j) = s3((a(ia+i)-a(id+i))+a11(ijk)) + c3((b(ia+i)+b(id+i))-b11(ijk))
	1982	c(jb+j) = c1(a20(ijk)-b21(ijk)) - s1(b20(ijk)-a21(ijk))
	1983	d(jb+j) = s1(a20(ijk)-b21(ijk)) + c1(b20(ijk)-a21(ijk))
	1984	c(jf+j) = c5(a20(ijk)+b21(ijk)) - s5(b20(ijk)+a21(ijk))
	1985	d(jf+j) = s5(a20(ijk)+b21(ijk)) + c5(b20(ijk)+a21(ijk))
	1986
	1987	i = i + inc3
	1988	j = j + inc4
	1989	ENDDO
	1990	ibase = ibase + inc1
	1991	jbase = jbase + inc2
	1992	ENDDO
	1993	ia = ia + iink
	1994	ib = ib + iink
	1995	ic = ic + iink
	1996	id = id - iink
	1997	ie = ie - iink
	1998	if = if - iink
	1999	jbase = jbase + jump
	2000	ENDDO
	2001
	2002	IF ( ic > id ) RETURN
	2003
	2004	ENDIF
	2005
	2006	ibase = 0
	2007	DO l = 1, la
	2008	i = ibase
	2009	j = jbase
	2010	!DIR$ IVDEP
	2011	!CDIR NODEP
	2012	!OCL NOVREC
	2013	DO ijk = 1, lot
	2014	c(ja+j) = a(ib+i) + (a(ia+i)+a(ic+i))
	2015	c(jd+j) = b(ib+i) - (b(ia+i)+b(ic+i))
	2016	c(jb+j) = (sin60(a(ia+i)-a(ic+i))) - (0.5_wp(b(ia+i)+b(ic+i))+b(ib+i))
	2017	c(jf+j) = -(sin60(a(ia+i)-a(ic+i))) - (0.5_wp(b(ia+i)+b(ic+i))+b(ib+i))
	2018	c(jc+j) = sin60(b(ic+i)-b(ia+i)) + (0.5_wp(a(ia+i)+a(ic+i))-a(ib+i))
	2019	c(je+j) = sin60(b(ic+i)-b(ia+i)) - (0.5_wp(a(ia+i)+a(ic+i))-a(ib+i))
	2020	i = i + inc3
	2021	j = j + inc4
	2022	ENDDO
	2023	ibase = ibase + inc1
	2024	jbase = jbase + inc2
	2025	ENDDO
	2026
	2027	ELSE
	2028
	2029	ssin60 = 2.0_wp * sin60
	2030	DO l = 1, la
	2031	i = ibase
	2032	j = jbase
	2033	!DIR$ IVDEP
	2034	!CDIR NODEP
	2035	!OCL NOVREC
	2036	DO ijk = 1, lot
	2037	c(ja+j) = (2.0_wp(a(ia+i)+a(id+i))) + (2.0_wp(a(ib+i)+a(ic+i)))
	2038	c(jd+j) = (2.0_wp(a(ia+i)-a(id+i))) - (2.0_wp(a(ib+i)-a(ic+i)))
	2039	c(jb+j) = (2.0_wp(a(ia+i)-a(id+i))+(a(ib+i)-a(ic+i))) - (ssin60(b(ib+i)+b(ic+i)))
	2040	c(jf+j) = (2.0_wp(a(ia+i)-a(id+i))+(a(ib+i)-a(ic+i))) + (ssin60(b(ib+i)+b(ic+i)))
	2041	c(jc+j) = (2.0_wp(a(ia+i)+a(id+i))-(a(ib+i)+a(ic+i))) - (ssin60(b(ib+i)-b(ic+i)))
	2042	c(je+j) = (2.0_wp(a(ia+i)+a(id+i))-(a(ib+i)+a(ic+i))) + (ssin60(b(ib+i)-b(ic+i)))
	2043	i = i + inc3
	2044	j = j + inc4
	2045	ENDDO
	2046	ibase = ibase + inc1
	2047	jbase = jbase + inc2
	2048	ENDDO
	2049
	2050	ENDIF
	2051
	2052	!
	2053	!-- Coding for factor 8
	2054	CASE ( 6 )
	2055
	2056	IF ( la /= m ) THEN
	2057	ierr = 3
	2058	RETURN
	2059	ENDIF
	2060
	2061	ia = 1
	2062	ib = ia + la*inc1
	2063	ic = ib + 2lainc1
	2064	id = ic + 2lainc1
	2065	ie = id + 2lainc1
	2066	ja = 1
	2067	jb = ja + jink
	2068	jc = jb + jink
	2069	jd = jc + jink
	2070	je = jd + jink
	2071	jf = je + jink
	2072	jg = jf + jink
	2073	jh = jg + jink
	2074	ssin45 = SQRT( 2.0_wp )
	2075
	2076	DO l = 1, la
	2077	i = ibase
	2078	j = jbase
	2079	!DIR$ IVDEP
	2080	!CDIR NODEP
	2081	!OCL NOVREC
	2082	DO ijk = 1, lot
	2083	c(ja+j) = 2.0_wp*(((a(ia+i)+a(ie+i))+a(ic+i))+(a(ib+i)+a(id+i)))
	2084	c(je+j) = 2.0_wp*(((a(ia+i)+a(ie+i))+a(ic+i))-(a(ib+i)+a(id+i)))
	2085	c(jc+j) = 2.0_wp*(((a(ia+i)+a(ie+i))-a(ic+i))-(b(ib+i)-b(id+i)))
	2086	c(jg+j) = 2.0_wp*(((a(ia+i)+a(ie+i))-a(ic+i))+(b(ib+i)-b(id+i)))
	2087	c(jb+j) = 2.0_wp((a(ia+i)-a(ie+i))-b(ic+i)) + ssin45((a(ib+i)-a(id+i))-(b(ib+i)+b(id+i)))
	2088	c(jf+j) = 2.0_wp((a(ia+i)-a(ie+i))-b(ic+i)) - ssin45((a(ib+i)-a(id+i))-(b(ib+i)+b(id+i)))
	2089	c(jd+j) = 2.0_wp((a(ia+i)-a(ie+i))+b(ic+i)) - ssin45((a(ib+i)-a(id+i))+(b(ib+i)+b(id+i)))
	2090	c(jh+j) = 2.0_wp((a(ia+i)-a(ie+i))+b(ic+i)) + ssin45((a(ib+i)-a(id+i))+(b(ib+i)+b(id+i)))
	2091	i = i + inc3
	2092	j = j + inc4
	2093	ENDDO
	2094	ibase = ibase + inc1
	2095	jbase = jbase + inc2
	2096	ENDDO
	2097
	2098	END SELECT
	2099
	2100	END SUBROUTINE rpassm
	2101
[1682]	2102	!------------------------------------------------------------------------------!
	2103	! Description:
	2104	! ------------
	2105	!> Computes factors of n & trigonometric functins required by fft99 & fft991cy
	2106	!> Method: Dimension trigs(n),ifax(1),jfax(10),lfax(7)
	2107	!> subroutine 'set99' - computes factors of n & trigonometric
	2108	!> functins required by fft99 & fft991cy
	2109	!------------------------------------------------------------------------------!
[3725]	2110	SUBROUTINE set99( trigs, ifax, n )
[1]	2111
	2112
[3725]	2113	USE control_parameters, &
[1320]	2114	ONLY: message_string
[1]	2115
[1320]	2116	USE kinds
	2117
[1]	2118	IMPLICIT NONE
	2119
[1682]	2120	INTEGER(iwp) :: n !<
[1]	2121
[1682]	2122	INTEGER(iwp) :: ifax(*) !<
	2123	REAL(wp) :: trigs(*) !<
[1]	2124
[1320]	2125
[1682]	2126	REAL(wp) :: angle !<
	2127	REAL(wp) :: del !<
	2128	INTEGER(iwp) :: i !<
	2129	INTEGER(iwp) :: ifac !<
	2130	INTEGER(iwp) :: ixxx !<
	2131	INTEGER(iwp) :: k !<
	2132	INTEGER(iwp) :: l !<
	2133	INTEGER(iwp) :: nfax !<
	2134	INTEGER(iwp) :: nhl !<
	2135	INTEGER(iwp) :: nil !<
	2136	INTEGER(iwp) :: nu !<
[1]	2137
[1682]	2138	INTEGER(iwp) :: jfax(10) !<
	2139	INTEGER(iwp) :: lfax(7) !<
[1]	2140
[3725]	2141	DATA lfax / 6, 8, 5, 4, 3, 2, 1 /
[1]	2142
	2143
	2144	ixxx = 1
	2145
[3725]	2146	del = 4.0_wp * ASIN( 1.0_wp ) / REAL( n, KIND=wp )
[1]	2147	nil = 0
	2148	nhl = (n/2) - 1
[3725]	2149	DO k = nil, nhl
	2150	angle = REAL( k, KIND=wp ) * del
	2151	trigs(2*k+1) = COS( angle )
	2152	trigs(2*k+2) = SIN( angle )
	2153	ENDDO
[1]	2154
[3725]	2155	!
	2156	!-- Find factors of n (8,6,5,4,3,2; only one 8 allowed).
	2157	!-- Look for sixes first, store factors in descending order.
	2158	nu = n
[1]	2159	ifac = 6
[3725]	2160	k = 0
	2161	l = 1
[1]	2162
[3725]	2163	DO
[1]	2164
[3725]	2165	IF ( MOD( nu, ifac ) == 0 ) THEN
	2166	k = k + 1
	2167	jfax(k) = ifac
	2168	IF ( ifac == 8 .AND. k /= 1 ) THEN
	2169	jfax(1) = 8
	2170	jfax(k) = 6
	2171	ENDIF
	2172	nu = nu/ifac
	2173	IF ( nu == 1 ) EXIT
	2174	IF ( ifac /= 8 ) CYCLE
	2175	ENDIF
[1]	2176
[3725]	2177	l = l + 1
	2178	ifac = lfax(l)
	2179	IF (ifac < 2 ) THEN
	2180	message_string = 'number of gridpoints along x or/and y ' // &
	2181	'contain illegal factors' // &
	2182	'&only factors 2, 3, 5 are allowed'
	2183	CALL message( 'temperton_fft', 'PA0311', 1, 2, 0, 6, 0 )
	2184	RETURN
	2185	ENDIF
	2186
	2187	ENDDO
	2188	!
	2189	!-- Now reverse order of factors
[1]	2190	nfax = k
	2191	ifax(1) = nfax
[3725]	2192	DO i = 1, nfax
[1]	2193	ifax(nfax+2-i) = jfax(i)
[3725]	2194	ENDDO
[1]	2195	ifax(10) = n
	2196
[3725]	2197	END SUBROUTINE set99
	2198
[1]	2199	END MODULE temperton_fft

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