source: LMDZ6/branches/cirrus/libf/phylmd/ecrad.v1.5.1/radiation_cloud_generator.F90 @ 5435

Last change on this file since 5435 was 4586, checked in by lguez, 18 months ago

Remove OpenMP directive in ECRad

With this directive, with gfortran 11, compilation of
radiation_cloud_generator.f90 fails with message:

`
554 | !$omp declare simd(sample_from_pdf_simd) uniform(this) &
Error: Symbol ‘sample_from_pdf_simd’ at (1) has already been
host associated fcm_internal compile failed (256)
`

With other compilers, removing this directive should have no effect:
the procedure which contains the directive is not called.

File size: 27.2 KB
Line 
1! radiation_cloud_generator.F90 - Generate water-content or optical-depth scalings for McICA
2!
3! (C) Copyright 2015- ECMWF.
4!
5! This software is licensed under the terms of the Apache Licence Version 2.0
6! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0.
7!
8! In applying this licence, ECMWF does not waive the privileges and immunities
9! granted to it by virtue of its status as an intergovernmental organisation
10! nor does it submit to any jurisdiction.
11!
12! Author:  Robin Hogan
13! Email:   r.j.hogan@ecmwf.int
14!
15! Generate clouds for McICA using a method modified from Raisanen et
16! al. (2002)
17!
18! Modifications
19!   2018-02-22  R. Hogan  Call masked version of PDF sampler for speed
20!   2020-03-31  R. Hogan  More vectorizable version of Exp-Ran
21
22module radiation_cloud_generator
23
24  public
25
26contains
27
28  !---------------------------------------------------------------------
29  ! Generate scaling factors for the cloud optical depth to represent
30  ! cloud overlap, the overlap of internal cloud inhomogeneities and
31  ! the fractional standard deviation of these inhomogeneities, for
32  ! use in a Monte Carlo Independent Column Approximation radiation
33  ! scheme. All returned profiles contain cloud, and the total cloud
34  ! cover is also returned, so the calling function can then do a
35  ! weighted average of clear and cloudy skies; this is a way to
36  ! reduce the Monte Carlo noise in profiles with low cloud cover.
37  subroutine cloud_generator(ng, nlev, i_overlap_scheme, &
38       &  iseed, frac_threshold, &
39       &  frac, overlap_param, decorrelation_scaling, &
40       &  fractional_std, pdf_sampler, &
41       &  od_scaling, total_cloud_cover, &
42       &  use_beta_overlap, use_vectorizable_generator)
43
44    use parkind1, only           : jprb
45    use yomhook,  only           : lhook, dr_hook
46    use radiation_io,   only     : nulerr, radiation_abort
47    use random_numbers_mix, only : randomnumberstream, &
48         initialize_random_numbers, uniform_distribution
49    use radiation_pdf_sampler, only : pdf_sampler_type
50    use radiation_cloud_cover, only : cum_cloud_cover_exp_ran, &
51         &       cum_cloud_cover_max_ran, cum_cloud_cover_exp_exp, &
52         &       IOverlapMaximumRandom, IOverlapExponentialRandom, &
53         &       IOverlapExponential
54
55    implicit none
56
57    ! Inputs
58    integer, intent(in)     :: ng    ! number of g points
59    integer, intent(in)     :: nlev  ! number of model levels
60    integer, intent(in)     :: i_overlap_scheme
61    integer, intent(in)     :: iseed ! seed for random number generator
62
63    ! Only cloud fractions above this threshold are considered to be
64    ! clouds
65    real(jprb), intent(in)  :: frac_threshold
66
67    ! Cloud fraction on full levels
68    real(jprb), intent(in)  :: frac(nlev)
69
70    ! Cloud overlap parameter for interfaces between model layers,
71    ! where 0 indicates random overlap and 1 indicates maximum-random
72    ! overlap
73    real(jprb), intent(in)  :: overlap_param(nlev-1)
74
75    ! Overlap parameter for internal inhomogeneities
76    real(jprb), intent(in)  :: decorrelation_scaling
77
78    ! Fractional standard deviation at each layer
79    real(jprb), intent(in)  :: fractional_std(nlev)
80
81    ! Object for sampling from a lognormal or gamma distribution
82    type(pdf_sampler_type), intent(in) :: pdf_sampler
83
84    ! This routine has been coded using the "alpha" overlap parameter
85    ! of Hogan and Illingworth (2000). If the following logical is
86    ! present and true then the input is interpretted to be the "beta"
87    ! overlap parameter of Shonk et al. (2010), and needs to be
88    ! converted to alpha.
89    logical, intent(in), optional :: use_beta_overlap
90
91    ! Do we use the more vectorizable cloud generator, at the expense
92    ! of more random numbers being needed?
93    logical, intent(in), optional :: use_vectorizable_generator
94
95    ! Outputs
96
97    ! Cloud optical depth scaling factor, with 0 indicating clear sky
98    real(jprb), intent(out) :: od_scaling(ng,nlev)
99
100    ! Total cloud cover using cloud fraction and overlap parameter
101    real(jprb), intent(out) :: total_cloud_cover
102
103    ! Local variables
104
105    ! Cumulative cloud cover from TOA to the base of each layer
106    real(jprb) :: cum_cloud_cover(nlev)
107
108    ! Scaled random number for finding cloud
109    real(jprb) :: trigger
110
111    ! Uniform deviates between 0 and 1
112    real(jprb) :: rand_top(ng)
113
114    ! Overlap parameter of inhomogeneities
115    real(jprb) :: overlap_param_inhom(nlev-1)
116
117    ! Seed for random number generator and stream for producing random
118    ! numbers
119    type(randomnumberstream) :: random_stream
120   
121    ! First and last cloudy layers
122    integer :: ibegin, iend
123
124    integer :: itrigger
125
126    ! Loop index for model level and g-point
127    integer :: jlev, jg
128
129    ! Cloud cover of a pair of layers, and amount by which cloud at
130    ! next level increases total cloud cover as seen from above
131    real(jprb), dimension(nlev-1) :: pair_cloud_cover, overhang
132
133    logical :: use_vec_gen
134
135    real(jprb) :: hook_handle
136
137    if (lhook) call dr_hook('radiation_cloud_generator:cloud_generator',0,hook_handle)
138
139    if (i_overlap_scheme == IOverlapExponentialRandom) then
140      call cum_cloud_cover_exp_ran(nlev, frac, overlap_param, &
141           &   cum_cloud_cover, pair_cloud_cover, use_beta_overlap)
142    else if (i_overlap_scheme == IOverlapMaximumRandom) then
143      call cum_cloud_cover_max_ran(nlev, frac, &
144           &   cum_cloud_cover, pair_cloud_cover)
145    else if (i_overlap_scheme == IOverlapExponential) then
146      call cum_cloud_cover_exp_exp(nlev, frac, overlap_param, &
147           &   cum_cloud_cover, pair_cloud_cover, use_beta_overlap)
148    else
149      write(nulerr,'(a)') '*** Error: cloud overlap scheme not recognised'
150      call radiation_abort()
151    end if
152
153    total_cloud_cover = cum_cloud_cover(nlev);
154    do jlev = 1,nlev-1
155      overhang(jlev) = cum_cloud_cover(jlev+1)-cum_cloud_cover(jlev)
156    end do
157
158    if (total_cloud_cover < frac_threshold) then
159      ! Treat column as clear sky: calling function therefore will not
160      ! use od_scaling so we don't need to calculate it
161      total_cloud_cover = 0.0_jprb
162
163    else
164      ! Cloud is present: need to calculate od_scaling
165
166      ! Find range of cloudy layers
167      jlev = 1
168      do while (frac(jlev) <= 0.0_jprb)
169        jlev = jlev + 1
170      end do
171      ibegin = jlev
172      iend = jlev
173      do jlev = jlev+1,nlev
174        if (frac(jlev) > 0.0_jprb) then
175          iend = jlev
176        end if
177      end do
178
179      ! Set overlap parameter of inhomogeneities
180      overlap_param_inhom = overlap_param
181
182      do jlev = ibegin,iend-1
183        if (overlap_param(jlev) > 0.0_jprb) then
184          overlap_param_inhom(jlev) &
185               &  = overlap_param(jlev)**(1.0_jprb/decorrelation_scaling)
186        end if
187      end do
188
189      ! Reset optical depth scaling to clear skies
190      od_scaling = 0.0_jprb
191
192      if (present(use_vectorizable_generator)) then
193        use_vec_gen = use_vectorizable_generator
194      else
195        use_vec_gen = .false.
196      end if
197
198      if (.not. use_vec_gen) then
199        ! Original generator that minimizes the number of random
200        ! numbers used, but is not vectorizable
201
202        ! Expensive operation: initialize random number generator for
203        ! this column
204        call initialize_random_numbers(iseed, random_stream)
205
206        ! Compute ng random numbers to use to locate cloud top
207        call uniform_distribution(rand_top, random_stream)
208       
209        ! Loop over ng columns
210        do jg = 1,ng
211          ! Find the cloud top height corresponding to the current
212          ! random number, and store in itrigger
213          trigger = rand_top(jg) * total_cloud_cover
214          jlev = ibegin
215          do while (trigger > cum_cloud_cover(jlev) .and. jlev < iend)
216            jlev = jlev + 1
217          end do
218          itrigger = jlev
219         
220          if (i_overlap_scheme /= IOverlapExponential) then
221            call generate_column_exp_ran(ng, nlev, jg, random_stream, pdf_sampler, &
222                 &  frac, pair_cloud_cover, &
223                 &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
224                 &  itrigger, iend, od_scaling)
225          else
226            call generate_column_exp_exp(ng, nlev, jg, random_stream, pdf_sampler, &
227                 &  frac, pair_cloud_cover, &
228                 &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
229                 &  itrigger, iend, od_scaling)
230          end if
231         
232        end do
233
234      else
235        ! Alternative generator (only for Exp-Ran overlap so far) that
236        ! should be vectorizable but generates more random numbers,
237        ! some of which are not used
238
239        if (i_overlap_scheme == IOverlapExponential) then
240          write(nulerr,'(a)') '*** Error: vectorizable cloud generator is not available with Exp-Exp overlap'
241          call radiation_abort()
242        end if
243
244        call generate_columns_exp_ran(ng, nlev, iseed, pdf_sampler, &
245             &  total_cloud_cover, frac_threshold, frac, pair_cloud_cover, &
246             &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
247             &  ibegin, iend, od_scaling)
248
249      end if
250
251    end if
252
253    if (lhook) call dr_hook('radiation_cloud_generator:cloud_generator',1,hook_handle)
254
255  end subroutine cloud_generator
256
257
258  !---------------------------------------------------------------------
259  ! Generate a column of optical depth scalings using
260  ! exponential-random overlap (which includes maximum-random overlap
261  ! as a limiting case)
262  subroutine generate_column_exp_ran(ng, nlev, ig, random_stream, pdf_sampler, &
263       &  frac, pair_cloud_cover, &
264       &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
265       &  itrigger, iend, od_scaling)
266
267    use parkind1,              only : jprb
268    use radiation_pdf_sampler, only : pdf_sampler_type
269    use random_numbers_mix,    only : randomnumberstream, &
270         initialize_random_numbers, uniform_distribution
271
272
273    implicit none
274
275    ! Number of g points / columns, and number of current column
276    integer, intent(in) :: ng, ig
277
278    ! Number of levels
279    integer, intent(in) :: nlev
280
281    ! Stream for producing random numbers
282    type(randomnumberstream), intent(inout) :: random_stream
283
284    ! Object for sampling from a lognormal or gamma distribution
285    type(pdf_sampler_type), intent(in) :: pdf_sampler
286
287    ! Cloud fraction, cumulative cloud cover and fractional standard
288    ! deviation in each layer
289    real(jprb), intent(in), dimension(nlev) :: frac, cum_cloud_cover, fractional_std
290
291    ! Cloud cover of a pair of layers, and amount by which cloud at
292    ! next level increases total cloud cover as seen from above
293    real(jprb), intent(in), dimension(nlev-1) :: pair_cloud_cover, overhang
294
295    ! Overlap parameter of inhomogeneities
296    real(jprb), intent(in), dimension(nlev-1) :: overlap_param_inhom
297
298    ! Top of highest cloudy layer (in this subcolumn) and base of
299    ! lowest
300    integer, intent(in) :: itrigger, iend
301
302    ! Optical depth scaling to output
303    real(jprb), intent(inout), dimension(ng,nlev) :: od_scaling
304
305    ! Height indices
306    integer :: jlev, jcloud
307
308    ! Number of contiguous cloudy layers for which to compute optical
309    ! depth scaling
310    integer :: n_layers_to_scale
311
312    integer :: iy
313
314    ! Is it time to fill the od_scaling variable?
315    logical :: do_fill_od_scaling
316
317    real(jprb) :: rand_cloud(nlev)
318    real(jprb) :: rand_inhom1(nlev), rand_inhom2(nlev)
319
320    ! So far our vertically contiguous cloud contains only one layer
321    n_layers_to_scale = 1
322    iy = 0
323
324    ! Locate the clouds below this layer: first generate some more
325    ! random numbers
326    call uniform_distribution(rand_cloud(1:(iend+1-itrigger)),random_stream)
327
328    ! Loop from the layer below the local cloud top down to the
329    ! bottom-most cloudy layer
330    do jlev = itrigger+1,iend+1
331      do_fill_od_scaling = .false.
332      if (jlev <= iend) then
333        iy = iy+1
334        if (n_layers_to_scale > 0) then
335          ! There is a cloud above, in which case the probability
336          ! of cloud in the layer below is as follows
337          if (rand_cloud(iy)*frac(jlev-1) &
338               &  < frac(jlev) + frac(jlev-1) - pair_cloud_cover(jlev-1)) then
339            ! Add another cloudy layer
340            n_layers_to_scale = n_layers_to_scale + 1
341          else
342            ! Reached the end of a contiguous set of cloudy layers and
343            ! will compute the optical depth scaling immediately.
344            do_fill_od_scaling = .true.
345          end if
346        else
347          ! There is clear-sky above, in which case the
348          ! probability of cloud in the layer below is as follows
349          if (rand_cloud(iy)*(cum_cloud_cover(jlev-1) - frac(jlev-1)) &
350               &  < pair_cloud_cover(jlev-1) - overhang(jlev-1) - frac(jlev-1)) then
351            ! A new cloud top
352            n_layers_to_scale = 1
353          end if
354        end if
355      else
356        ! We are at the bottom of the cloudy layers in the model,
357        ! so in a moment need to populate the od_scaling array
358        do_fill_od_scaling = .true.
359      end if
360
361      if (do_fill_od_scaling) then
362        ! We have a contiguous range of layers for which we
363        ! compute the od_scaling elements using some random
364        ! numbers
365        call uniform_distribution(rand_inhom1(1:n_layers_to_scale),random_stream)
366        call uniform_distribution(rand_inhom2(1:n_layers_to_scale),random_stream)
367
368        ! Loop through the sequence of cloudy layers
369        do jcloud = 2,n_layers_to_scale
370          ! Use second random number, and inhomogeneity overlap
371          ! parameter, to decide whether the first random number
372          ! should be repeated (corresponding to maximum overlap)
373          ! or not (corresponding to random overlap)
374          if (rand_inhom2(jcloud) &
375               &  < overlap_param_inhom(jlev-n_layers_to_scale+jcloud-2)) then
376            rand_inhom1(jcloud) = rand_inhom1(jcloud-1)
377          end if
378        end do
379       
380        ! Sample from a lognormal or gamma distribution to obtain
381        ! the optical depth scalings
382        call pdf_sampler%sample(fractional_std(jlev-n_layers_to_scale:jlev-1), &
383             & rand_inhom1(1:n_layers_to_scale), od_scaling(ig,jlev-n_layers_to_scale:jlev-1))
384
385        n_layers_to_scale = 0
386      end if
387         
388    end do
389
390  end subroutine generate_column_exp_ran
391
392
393
394  !---------------------------------------------------------------------
395  ! Generate a column of optical depth scalings using
396  ! exponential-exponential overlap
397  subroutine generate_column_exp_exp(ng, nlev, ig, random_stream, pdf_sampler, &
398       &  frac, pair_cloud_cover, &
399       &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
400       &  itrigger, iend, od_scaling)
401
402    use parkind1,              only : jprb
403    use radiation_pdf_sampler, only : pdf_sampler_type
404    use random_numbers_mix,    only : randomnumberstream, &
405         initialize_random_numbers, uniform_distribution
406
407    implicit none
408
409    ! Number of g points / columns, and number of current column
410    integer, intent(in) :: ng, ig
411
412    ! Number of levels
413    integer, intent(in) :: nlev
414
415    ! Stream for producing random numbers
416    type(randomnumberstream), intent(inout) :: random_stream
417
418    ! Object for sampling from a lognormal or gamma distribution
419    type(pdf_sampler_type), intent(in) :: pdf_sampler
420
421    ! Cloud fraction, cumulative cloud cover and fractional standard
422    ! deviation in each layer
423    real(jprb), intent(in), dimension(nlev) :: frac, cum_cloud_cover, fractional_std
424
425    ! Cloud cover of a pair of layers, and amount by which cloud at
426    ! next level increases total cloud cover as seen from above
427    real(jprb), intent(in), dimension(nlev-1) :: pair_cloud_cover, overhang
428
429    ! Overlap parameter of inhomogeneities
430    real(jprb), intent(in), dimension(nlev-1) :: overlap_param_inhom
431
432    ! Top of highest cloudy layer (in this subcolumn) and base of
433    ! lowest
434    integer, intent(in) :: itrigger, iend
435
436    ! Optical depth scaling to output
437    real(jprb), intent(inout), dimension(ng,nlev) :: od_scaling
438
439    ! Height indices
440    integer :: jlev, jcloud
441
442    integer :: iy
443
444    real(jprb) :: rand_cloud(nlev)
445    real(jprb) :: rand_inhom1(nlev), rand_inhom2(nlev)
446
447    ! For each column analysed, this vector locates the clouds. It is
448    ! only actually used for Exp-Exp overlap
449    logical :: is_cloudy(nlev)
450
451    ! Number of contiguous cloudy layers for which to compute optical
452    ! depth scaling
453    integer :: n_layers_to_scale
454
455    iy = 0
456
457    is_cloudy = .false.
458    is_cloudy(itrigger) = .true.
459
460    ! Locate the clouds below this layer: first generate some more
461    ! random numbers
462    call uniform_distribution(rand_cloud(1:(iend+1-itrigger)),random_stream)
463
464    ! Loop from the layer below the local cloud top down to the
465    ! bottom-most cloudy layer
466    do jlev = itrigger+1,iend
467      iy = iy+1
468      if (is_cloudy(jlev-1)) then
469        ! There is a cloud above, in which case the probability
470        ! of cloud in the layer below is as follows
471        if (rand_cloud(iy)*frac(jlev-1) &
472             &  < frac(jlev) + frac(jlev-1) - pair_cloud_cover(jlev-1)) then
473          ! Add another cloudy layer
474          is_cloudy(jlev) = .true.
475        end if
476      else
477        ! There is clear-sky above, in which case the
478        ! probability of cloud in the layer below is as follows
479        if (rand_cloud(iy)*(cum_cloud_cover(jlev-1) - frac(jlev-1)) &
480             &  < pair_cloud_cover(jlev-1) - overhang(jlev-1) - frac(jlev-1)) then
481            ! A new cloud top
482          is_cloudy(jlev) = .true.
483        end if
484      end if
485    end do
486
487    ! We have a contiguous range of layers for which we compute the
488    ! od_scaling elements using some random numbers
489
490    ! In the Exp-Exp overlap scheme we do all layers at once
491    n_layers_to_scale = iend+1 - itrigger
492       
493    call uniform_distribution(rand_inhom1(1:n_layers_to_scale),random_stream)
494    call uniform_distribution(rand_inhom2(1:n_layers_to_scale),random_stream)
495       
496    ! Loop through the sequence of cloudy layers
497    do jcloud = 2,n_layers_to_scale
498      ! Use second random number, and inhomogeneity overlap
499      ! parameter, to decide whether the first random number
500      ! should be repeated (corresponding to maximum overlap)
501      ! or not (corresponding to random overlap)
502      if (rand_inhom2(jcloud) &
503           &  < overlap_param_inhom(iend-n_layers_to_scale+jcloud-1)) then
504        rand_inhom1(jcloud) = rand_inhom1(jcloud-1)
505      end if
506    end do
507       
508    ! Sample from a lognormal or gamma distribution to obtain the
509    ! optical depth scalings
510
511    ! Masked version assuming values outside the range itrigger:iend
512    ! are already zero:
513    call pdf_sampler%masked_sample(n_layers_to_scale, &
514         &  fractional_std(itrigger:iend), &
515         &  rand_inhom1(1:n_layers_to_scale), od_scaling(ig,itrigger:iend), &
516         &  is_cloudy(itrigger:iend))
517       
518    ! ! IFS version:
519    ! !$omp simd
520    ! do jlev=itrigger,iend
521    !    if (.not. is_cloudy(jlev)) then
522    !       od_scaling(ig,jlev) = 0.0_jprb
523    !    else
524    !       call sample_from_pdf_simd(&
525    !            pdf_sampler,fractional_std(jlev),&
526    !            rand_inhom1(jlev-itrigger+1), &
527    !            od_scaling(ig,jlev))
528    !    end if
529    ! end do
530
531  end subroutine generate_column_exp_exp
532
533
534  !---------------------------------------------------------------------
535  ! Extract the value of a lognormal distribution with fractional
536  ! standard deviation "fsd" corresponding to the cumulative
537  ! distribution function value "cdf", and return it in x. Since this
538  ! is an elemental subroutine, fsd, cdf and x may be arrays. SIMD version.
539  subroutine sample_from_pdf_simd(this, fsd, cdf, x)
540    use parkind1,              only : jprb
541    use radiation_pdf_sampler, only : pdf_sampler_type
542    implicit none
543    type(pdf_sampler_type), intent(in)  :: this
544
545    ! Fractional standard deviation (0 to 4) and cumulative
546    ! distribution function (0 to 1)
547    real(jprb),              intent(in)  :: fsd, cdf
548
549    ! Sample from distribution
550    real(jprb),              intent(out) :: x
551
552    ! Index to look-up table
553    integer    :: ifsd, icdf
554
555    ! Weights in bilinear interpolation
556    real(jprb) :: wfsd, wcdf
557
558    ! Bilinear interpolation with bounds
559    wcdf = cdf * (this%ncdf-1) + 1.0_jprb
560    icdf = max(1, min(int(wcdf), this%ncdf-1))
561    wcdf = max(0.0_jprb, min(wcdf - icdf, 1.0_jprb))
562
563    wfsd = (fsd-this%fsd1) * this%inv_fsd_interval + 1.0_jprb
564    ifsd = max(1, min(int(wfsd), this%nfsd-1))
565    wfsd = max(0.0_jprb, min(wfsd - ifsd, 1.0_jprb))
566
567    x =      (1.0_jprb-wcdf)*(1.0_jprb-wfsd) * this%val(icdf  ,ifsd)   &
568         & + (1.0_jprb-wcdf)*          wfsd  * this%val(icdf  ,ifsd+1) &
569         & +           wcdf *(1.0_jprb-wfsd) * this%val(icdf+1,ifsd)   &
570         & +           wcdf *          wfsd  * this%val(icdf+1,ifsd+1)
571
572  end subroutine sample_from_pdf_simd
573
574
575  !---------------------------------------------------------------------
576  ! Generate columns of optical depth scalings using
577  ! exponential-random overlap (which includes maximum-random overlap
578  ! as a limiting case).  This version is intended to work better on
579  ! hardware with long vector lengths.  As with all calculations in
580  ! this file, we zoom into the fraction of the column with cloud at
581  ! any height, so that all spectral intervals see a cloud somewhere.
582  ! In the McICA solver, this is combined appropriately with the
583  ! clear-sky calculation.
584  subroutine generate_columns_exp_ran(ng, nlev, iseed, pdf_sampler, &
585       &  total_cloud_cover, frac_threshold, frac, pair_cloud_cover, &
586       &  cum_cloud_cover, overhang, fractional_std, overlap_param_inhom, &
587       &  ibegin, iend, od_scaling)
588
589    use parkind1,              only : jprb
590    use radiation_pdf_sampler, only : pdf_sampler_type
591    use radiation_random_numbers, only : rng_type, IRngMinstdVector, IRngNative
592
593    implicit none
594
595    ! Number of g points / columns
596    integer, intent(in) :: ng
597
598    ! Number of levels
599    integer, intent(in) :: nlev
600
601    integer, intent(in) :: iseed ! seed for random number generator
602
603    ! Stream for producing random numbers
604    !type(randomnumberstream) :: random_stream
605    type(rng_type) :: random_number_generator
606
607    ! Object for sampling from a lognormal or gamma distribution
608    type(pdf_sampler_type), intent(in) :: pdf_sampler
609
610    ! Total cloud cover using cloud fraction and overlap parameter
611    real(jprb), intent(in) :: total_cloud_cover
612
613    real(jprb), intent(in) :: frac_threshold
614
615    ! Cloud fraction, cumulative cloud cover and fractional standard
616    ! deviation in each layer
617    real(jprb), intent(in), dimension(nlev) :: frac, cum_cloud_cover, fractional_std
618
619    ! Cloud cover of a pair of layers, and amount by which cloud at
620    ! next level increases total cloud cover as seen from above
621    real(jprb), intent(in), dimension(nlev-1) :: pair_cloud_cover, overhang
622
623    ! Overlap parameter of inhomogeneities
624    real(jprb), intent(in), dimension(nlev-1) :: overlap_param_inhom
625
626    ! Top of highest cloudy layer and base of lowest
627    integer, intent(inout) :: ibegin, iend
628
629    ! Optical depth scaling to output
630    real(jprb), intent(inout), dimension(ng,nlev) :: od_scaling
631
632    ! Loop indices
633    integer :: jlev, jg
634
635    real(jprb) :: rand_cloud(ng,ibegin:iend)
636    real(jprb) :: rand_inhom(ng,ibegin-1:iend), rand_inhom2(ng,ibegin:iend)
637
638    ! Is the cloud fraction above the minimum threshold at each level
639    logical :: is_any_cloud(ibegin:iend)
640
641    ! Scaled random number for finding cloud
642    real(jprb) :: trigger(ng)
643
644    logical :: is_cloud(ng)    ! Is there cloud at this level and spectral interval?
645    logical :: prev_cloud(ng)  ! Was there cloud at level above?
646    logical :: first_cloud(ng) ! At level of first cloud counting down from top?
647    logical :: found_cloud(ng) ! Cloud found in this column counting down from top?
648
649    is_any_cloud = (frac(ibegin:iend) >= frac_threshold)
650
651    ! Initialize random number generator for this column, and state
652    ! that random numbers will be requested in blocks of length the
653    ! number of spectral intervals ng.
654    call random_number_generator%initialize(IRngMinstdVector, iseed=iseed, &
655         &                                  nmaxstreams=ng)
656
657    ! Random numbers to use to locate cloud top
658    call random_number_generator%uniform_distribution(trigger)
659
660    ! Random numbers to work out whether to transition vertically from
661    ! clear to cloudy, cloudy to clear, clear to clear or cloudy to
662    ! cloudy
663    call random_number_generator%uniform_distribution(rand_cloud, is_any_cloud)
664
665    ! Random numbers to generate sub-grid cloud structure
666    call random_number_generator%uniform_distribution(rand_inhom)
667    call random_number_generator%uniform_distribution(rand_inhom2, is_any_cloud)
668
669    trigger = trigger * total_cloud_cover
670
671    ! Initialize logicals for clear-sky above first cloudy layer
672    found_cloud = .false.
673    is_cloud    = .false.
674    first_cloud = .false.
675
676    ! Loop down through layers starting at the first cloudy layer
677    do jlev = ibegin,iend
678
679      if (is_any_cloud(jlev)) then
680
681! Added for DWD (2020)
682!NEC$ shortloop
683        do jg = 1,ng
684          ! The intention is that all these operations are vectorizable,
685          ! since all are vector operations on vectors of length ng...
686
687          ! Copy the cloud mask between levels
688          prev_cloud(jg) = is_cloud(jg)
689
690          ! For each spectral interval, has the first cloud appeared at this level?
691          first_cloud(jg) = (trigger(jg) <= cum_cloud_cover(jlev) .and. .not. found_cloud(jg))
692
693          ! ...if so, add to found_cloud
694          found_cloud(jg) = found_cloud(jg) .or. first_cloud(jg)
695
696          ! There is cloud at this level either if a first cloud has
697          ! appeared, or using separate probability calculations
698          ! depending on whether there is a cloud above (given by
699          ! prev_cloud)
700          is_cloud(jg) = first_cloud(jg) &
701               &  .or. found_cloud(jg) .and. merge(rand_cloud(jg,jlev)*frac(jlev-1) &
702               &               < frac(jlev)+frac(jlev-1)-pair_cloud_cover(jlev-1), &
703               &             rand_cloud(jg,jlev)*(cum_cloud_cover(jlev-1) - frac(jlev-1)) &
704               &               < pair_cloud_cover(jlev-1) - overhang(jlev-1) - frac(jlev-1), &
705               &             prev_cloud(jg))
706          ! The random number determining cloud structure decorrelates
707          ! with the one above it according to the overlap parameter,
708          ! but always decorrelates if there is clear-sky above.  If
709          ! there is clear-sky in the present level, the random number
710          ! is set to zero to ensure that the optical depth scaling is
711          ! also zero.
712          rand_inhom(jg,jlev) = merge(merge(rand_inhom(jg,jlev-1), rand_inhom(jg,jlev), &
713               &                           rand_inhom2(jg,jlev) < overlap_param_inhom(jlev-1) &
714               &                           .and. prev_cloud(jg)), &
715               &                     0.0_jprb, is_cloud(jg))
716        end do
717      else
718        ! No cloud at this level
719        is_cloud = .false.
720      end if
721    end do
722       
723    ! Sample from a lognormal or gamma distribution to obtain the
724    ! optical depth scalings, calling the faster masked version and
725    ! assuming values outside the range ibegin:iend are already zero
726    call pdf_sampler%masked_block_sample(iend-ibegin+1, ng, &
727         &  fractional_std(ibegin:iend), &
728         &  rand_inhom(:,ibegin:iend), od_scaling(:,ibegin:iend), &
729         &  is_any_cloud)
730
731  end subroutine generate_columns_exp_ran
732
733end module radiation_cloud_generator
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