mptrac.c

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/*
  This file is part of MPTRAC.
  
  MPTRAC is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  
  MPTRAC is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  
  You should have received a copy of the GNU General Public License
  along with MPTRAC. If not, see <http://www.gnu.org/licenses/>.
  
  Copyright (C) 2013-2024 Forschungszentrum Juelich GmbH
*/
 
#include "mptrac.h"
 
#ifdef KPP
#include "kpp_chem.h"
#endif
 
static gsl_rng *rng[NTHREADS];
 
static uint64_t rng_ctr;
 
#ifdef CURAND
static curandGenerator_t rng_curand;
#endif
 
/*****************************************************************************/
 
#ifdef MPI
void broadcast_large_data(
  void *data,
  size_t N) {
 
#define CHUNK_SIZE 2147483647
 
  /* Broadcast the size of the data first... */
  MPI_Bcast(&N, 1, MPI_UINT64_T, 0, MPI_COMM_WORLD);
 
  /* Calculate the number of chunks... */
  size_t num_chunks = (N + CHUNK_SIZE - 1) / CHUNK_SIZE;
 
  /* Loop over chunks... */
  for (size_t i = 0; i < num_chunks; i++) {
 
    /* Determine the start and end indices for the current chunk... */
    size_t start = i * CHUNK_SIZE;
    size_t end = (start + CHUNK_SIZE > N) ? N : start + CHUNK_SIZE;
    size_t chunk_size = end - start;
 
    /* Broadcast the current chunk... */
    MPI_Bcast((char *) data + start, (int) chunk_size, MPI_BYTE, 0,
              MPI_COMM_WORLD);
  }
}
#endif
 
/*****************************************************************************/
 
void cart2geo(
  const double *x,
  double *z,
  double *lon,
  double *lat) {
 
  double radius = NORM(x);
  *lat = asin(x[2] / radius) * 180. / M_PI;
  *lon = atan2(x[1], x[0]) * 180. / M_PI;
  *z = radius - RE;
}
 
/*****************************************************************************/
 
double clim_oh(
  const ctl_t * ctl,
  const clim_t * clim,
  const double t,
  const double lon,
  const double lat,
  const double p) {
 
  /* Get OH data from climatology... */
  double oh = clim_zm(&clim->oh, t, lat, p);
 
  /* Apply diurnal correction... */
  if (ctl->oh_chem_beta > 0) {
    double sza = sza_calc(t, lon, lat);
    if (sza <= M_PI / 2. * 85. / 90.)
      return oh * exp(-ctl->oh_chem_beta / cos(sza));
    else
      return oh * exp(-ctl->oh_chem_beta / cos(M_PI / 2. * 85. / 90.));
  } else
    return oh;
}
 
/*****************************************************************************/
 
void clim_oh_diurnal_correction(
  ctl_t * ctl,
  clim_t * clim) {
 
  /* Loop over climatology data points... */
  for (int it = 0; it < clim->oh.ntime; it++)
    for (int iz = 0; iz < clim->oh.np; iz++)
      for (int iy = 0; iy < clim->oh.nlat; iy++) {
 
        /* Init... */
        int n = 0;
        double sum = 0;
 
        /* Integrate day/night correction factor over longitude... */
        for (double lon = -180; lon < 180; lon += 1.0) {
          double sza = sza_calc(clim->oh.time[it], lon, clim->oh.lat[iy]);
          if (sza <= M_PI / 2. * 85. / 90.)
            sum += exp(-ctl->oh_chem_beta / cos(sza));
          else
            sum += exp(-ctl->oh_chem_beta / cos(M_PI / 2. * 85. / 90.));
          n++;
        }
 
        /* Apply scaling factor to OH data... */
        clim->oh.vmr[it][iz][iy] /= (sum / (double) n);
      }
}
 
/*****************************************************************************/
 
double clim_photo(
  double rate[CP][CSZA][CO3],
  clim_photo_t * photo,
  double p,
  double sza,
  double o3c) {
 
  /* Check pressure range... */
  double p_help = p;
  if (p < photo->p[photo->np - 1])
    p_help = photo->p[photo->np - 1];
  else if (p > photo->p[0])
    p_help = photo->p[0];
 
  /* Check sza range... */
  double sza_help = sza;
  if (sza < photo->sza[0])
    sza_help = photo->sza[0];
  else if (sza > photo->sza[photo->nsza - 1])
    sza_help = photo->sza[photo->nsza - 1];
 
  /* Check ozone column range... */
  double o3c_help = o3c;
  if (o3c < photo->o3c[0])
    o3c_help = photo->o3c[0];
  else if (o3c > photo->o3c[photo->no3c - 1])
    o3c_help = photo->o3c[photo->no3c - 1];
 
  /* Get indices... */
  int ip = locate_irr(photo->p, photo->np, p_help);
  int isza = locate_reg(photo->sza, photo->nsza, sza_help);
  int io3c = locate_reg(photo->o3c, photo->no3c, o3c_help);
 
  /* Interpolate photolysis rate... */
  double aux00 = LIN(photo->p[ip], rate[ip][isza][io3c],
                     photo->p[ip + 1], rate[ip + 1][isza][io3c], p_help);
  double aux01 = LIN(photo->p[ip], rate[ip][isza][io3c + 1],
                     photo->p[ip + 1], rate[ip + 1][isza][io3c + 1], p_help);
  double aux10 = LIN(photo->p[ip], rate[ip][isza + 1][io3c],
                     photo->p[ip + 1], rate[ip + 1][isza + 1][io3c], p_help);
  double aux11 = LIN(photo->p[ip], rate[ip][isza + 1][io3c + 1],
                     photo->p[ip + 1], rate[ip + 1][isza + 1][io3c + 1],
                     p_help);
  aux00 = LIN(photo->o3c[io3c], aux00, photo->o3c[io3c + 1], aux01, o3c_help);
  aux11 = LIN(photo->o3c[io3c], aux10, photo->o3c[io3c + 1], aux11, o3c_help);
  aux00 = LIN(photo->sza[isza], aux00, photo->sza[isza + 1], aux11, sza_help);
  return MAX(aux00, 0.0);
}
 
/*****************************************************************************/
 
double clim_tropo(
  const clim_t * clim,
  const double t,
  const double lat) {
 
  /* Get seconds since begin of year... */
  double sec = FMOD(t, 365.25 * 86400.);
  while (sec < 0)
    sec += 365.25 * 86400.;
 
  /* Get indices... */
  int isec = locate_irr(clim->tropo_time, clim->tropo_ntime, sec);
  int ilat = locate_reg(clim->tropo_lat, clim->tropo_nlat, lat);
 
  /* Interpolate tropopause pressure... */
  double p0 = LIN(clim->tropo_lat[ilat],
                  clim->tropo[isec][ilat],
                  clim->tropo_lat[ilat + 1],
                  clim->tropo[isec][ilat + 1], lat);
  double p1 = LIN(clim->tropo_lat[ilat],
                  clim->tropo[isec + 1][ilat],
                  clim->tropo_lat[ilat + 1],
                  clim->tropo[isec + 1][ilat + 1], lat);
  return LIN(clim->tropo_time[isec], p0, clim->tropo_time[isec + 1], p1, sec);
}
 
/*****************************************************************************/
 
void clim_tropo_init(
  clim_t * clim) {
 
  /* Write info... */
  LOG(1, "Initialize tropopause data...");
 
  /* Set time [s]... */
  clim->tropo_ntime = 12;
  double tropo_time[12] = {
    1209600.00, 3888000.00, 6393600.00,
    9072000.00, 11664000.00, 14342400.00,
    16934400.00, 19612800.00, 22291200.00,
    24883200.00, 27561600.00, 30153600.00
  };
  memcpy(clim->tropo_time, tropo_time, sizeof(clim->tropo_time));
 
  /* Set latitudes [deg]... */
  clim->tropo_nlat = 73;
  double tropo_lat[73] = {
    -90, -87.5, -85, -82.5, -80, -77.5, -75, -72.5, -70, -67.5,
    -65, -62.5, -60, -57.5, -55, -52.5, -50, -47.5, -45, -42.5,
    -40, -37.5, -35, -32.5, -30, -27.5, -25, -22.5, -20, -17.5,
    -15, -12.5, -10, -7.5, -5, -2.5, 0, 2.5, 5, 7.5, 10, 12.5,
    15, 17.5, 20, 22.5, 25, 27.5, 30, 32.5, 35, 37.5, 40, 42.5,
    45, 47.5, 50, 52.5, 55, 57.5, 60, 62.5, 65, 67.5, 70, 72.5,
    75, 77.5, 80, 82.5, 85, 87.5, 90
  };
  memcpy(clim->tropo_lat, tropo_lat, sizeof(clim->tropo_lat));
 
  /* Set tropopause pressure [hPa] (NCEP/NCAR Reanalysis 1)... */
  double tropo[12][73] = {
    {324.1, 325.6, 325, 324.3, 322.5, 319.7, 314, 307.2, 301.8, 299.6,
     297.1, 292.2, 285.6, 276.1, 264, 248.9, 231.9, 213.5, 194.4,
     175.3, 157, 140.4, 126.7, 116.3, 109.5, 105.4, 103, 101.4, 100.4,
     99.69, 99.19, 98.84, 98.56, 98.39, 98.39, 98.42, 98.44, 98.54,
     98.68, 98.81, 98.89, 98.96, 99.12, 99.65, 101.4, 105.4, 113.5, 128,
     152.1, 184.7, 214, 234.1, 247.3, 255.8, 262.6, 267.7, 271.7, 275,
     277.2, 279, 280.1, 280.4, 280.6, 280.1, 279.3, 278.3, 276.8, 275.8,
     275.3, 275.6, 275.4, 274.1, 273.5},
    {337.3, 338.7, 337.8, 336.4, 333, 328.8, 321.1, 312.6, 306.6, 303.7,
     300.2, 293.8, 285.4, 273.8, 259.6, 242.7, 224.4, 205.2, 186, 167.5,
     150.3, 135, 122.8, 113.9, 108.2, 104.7, 102.5, 101.1, 100.2, 99.42,
     98.88, 98.52, 98.25, 98.09, 98.07, 98.1, 98.12, 98.2, 98.25, 98.27,
     98.26, 98.27, 98.36, 98.79, 100.2, 104.2, 113.7, 131.2, 159.5, 193,
     220.4, 238.1, 250.2, 258.1, 264.7, 269.7, 273.7, 277.3, 280.2, 282.8,
     284.9, 286.5, 288.1, 288.8, 289, 288.5, 287.2, 286.3, 286.1, 287.2,
     287.5, 286.2, 285.8},
    {335, 336, 335.7, 335.1, 332.3, 328.1, 320.6, 311.8, 305.1, 301.9,
     297.6, 290, 280.4, 268.3, 254.6, 239.6, 223.9, 207.9, 192.2, 176.9,
     161.7, 146.4, 132.2, 120.6, 112.3, 107.2, 104.3, 102.4, 101.3,
     100.4, 99.86, 99.47, 99.16, 98.97, 98.94, 98.97, 99, 99.09, 99.2,
     99.31, 99.35, 99.41, 99.51, 99.86, 101.1, 104.9, 114.3, 131, 156.8,
     186.3, 209.3, 224.6, 236.8, 246.3, 254.9, 262.3, 268.8, 274.8,
     279.9, 284.6, 288.6, 291.6, 294.9, 297.5, 299.8, 301.8, 303.1,
     304.3, 304.9, 306, 306.6, 306.2, 306},
    {306.2, 306.7, 305.7, 307.1, 307.3, 306.4, 301.8, 296.2, 292.4,
     290.3, 287.1, 280.9, 273.4, 264.3, 254.1, 242.8, 231, 219, 207.2,
     195.5, 183.3, 169.7, 154.7, 138.7, 124.1, 113.6, 107.8, 104.7,
     102.8, 101.7, 100.9, 100.4, 100, 99.79, 99.7, 99.66, 99.68, 99.79,
     99.94, 100.2, 100.5, 100.9, 101.4, 102.1, 103.4, 107, 115.2, 129.1,
     148.7, 171, 190.8, 205.6, 218.4, 229.4, 239.6, 248.6, 256.5,
     263.7, 270.3, 276.6, 282.6, 288.1, 294.5, 300.4, 306.3, 311.4,
     315.1, 318.3, 320.3, 322.2, 322.8, 321.5, 321.1},
    {266.5, 264.9, 260.8, 261, 262, 263, 261.3, 259.7, 259.2, 259.8,
     260.1, 258.6, 256.7, 253.6, 249.5, 243.9, 237.4, 230, 222.1, 213.9,
     205, 194.4, 180.4, 161.8, 140.7, 122.9, 112.1, 106.7, 104.1, 102.7,
     101.8, 101.4, 101.1, 101, 101, 101, 101.1, 101.2, 101.5, 101.9,
     102.4, 103, 103.8, 104.9, 106.8, 110.1, 115.6, 124, 135.2, 148.9,
     165.2, 181.3, 198, 211.8, 223.5, 233.8, 242.9, 251.5, 259, 266.2,
     273.1, 279.2, 286.2, 292.8, 299.6, 306, 311.1, 315.5, 318.8, 322.6,
     325.3, 325.8, 325.8},
    {220.1, 218.1, 210.8, 207.2, 207.6, 210.5, 211.4, 213.5, 217.3,
     222.4, 227.9, 232.8, 237.4, 240.8, 242.8, 243, 241.5, 238.6, 234.2,
     228.5, 221, 210.7, 195.1, 172.9, 147.8, 127.6, 115.6, 109.9, 107.1,
     105.7, 105, 104.8, 104.8, 104.9, 105, 105.1, 105.3, 105.5, 105.8,
     106.4, 107, 107.6, 108.1, 108.8, 110, 111.8, 114.2, 117.4, 121.6,
     127.9, 137.3, 151.2, 169.5, 189, 205.8, 218.9, 229.1, 237.8, 245,
     251.5, 257.1, 262.3, 268.2, 274, 280.4, 286.7, 292.4, 297.9, 302.9,
     308.5, 312.2, 313.1, 313.3},
    {187.4, 184.5, 173.3, 166.1, 165.4, 167.8, 169.6, 173.6, 179.6,
     187.9, 198.9, 210, 220.5, 229.2, 235.7, 239.9, 241.8, 241.6, 239.6,
     235.8, 229.4, 218.6, 200.9, 175.9, 149.4, 129.4, 118.3, 113.1,
     110.8, 109.7, 109.3, 109.4, 109.7, 110, 110.2, 110.4, 110.5, 110.7,
     111, 111.4, 111.8, 112.1, 112.3, 112.7, 113.2, 113.9, 115, 116.4,
     117.9, 120.4, 124.1, 130.9, 142.2, 159.6, 179.6, 198.5, 212.9,
     224.2, 232.7, 239.1, 243.8, 247.7, 252.4, 257.3, 263.2, 269.5,
     275.4, 281.1, 286.3, 292, 296.3, 298.2, 298.8},
    {166, 166.4, 155.7, 148.3, 147.1, 149, 152.1, 157, 163.6, 172.4,
     185.3, 199.2, 212.6, 224, 233.2, 239.6, 243.3, 244.6, 243.6, 240.3,
     233.9, 222.6, 203.7, 177, 149.5, 129.7, 119, 114, 111.7, 110.7,
     110.3, 110.3, 110.6, 110.9, 111.1, 111.3, 111.5, 111.6, 111.9,
     112.2, 112.5, 112.6, 112.8, 113, 113.4, 114, 115.1, 116.5, 118.3,
     120.9, 124.4, 130.2, 139.4, 154.6, 173.8, 193.1, 208.1, 220.4,
     230.1, 238.2, 244.7, 249.5, 254.5, 259.3, 264.5, 269.4, 273.7,
     278.2, 282.6, 287.4, 290.9, 292.5, 293},
    {171.9, 172.8, 166.2, 162.3, 161.4, 162.5, 165.2, 169.6, 175.3,
     183.1, 193.8, 205.9, 218.3, 229.6, 238.5, 244.3, 246.9, 246.7,
     243.8, 238.4, 230.2, 217.9, 199.6, 174.9, 148.9, 129.8, 119.5,
     114.8, 112.3, 110.9, 110.3, 110.1, 110.2, 110.3, 110.4, 110.5,
     110.6, 110.8, 111, 111.4, 111.8, 112, 112.2, 112.4, 112.9, 113.6,
     114.7, 116.3, 118.4, 121.9, 127.1, 136.1, 149.8, 168.4, 186.9,
     203.3, 217, 229.1, 238.7, 247, 254, 259.3, 264.3, 268.3, 272.5,
     276.6, 280.4, 284.4, 288.4, 293.3, 297.2, 298.7, 299.1},
    {191.6, 192.2, 189, 188.1, 190.2, 193.7, 197.8, 202.9, 208.5,
     215.6, 224.2, 233.1, 241.2, 247.3, 250.8, 251.3, 248.9, 244.2,
     237.3, 228.4, 217.2, 202.9, 184.5, 162.5, 140.7, 124.8, 116.2,
     111.8, 109.4, 107.9, 107, 106.7, 106.6, 106.6, 106.7, 106.7,
     106.8, 107, 107.4, 108, 108.7, 109.3, 109.8, 110.4, 111.2,
     112.4, 114.2, 116.9, 121.1, 127.9, 139.3, 155.2, 173.6, 190.7,
     206.1, 220.1, 232.3, 243, 251.8, 259.2, 265.7, 270.6, 275.3,
     279.3, 283.3, 286.9, 289.7, 292.8, 296.1, 300.5, 303.9, 304.8,
     305.1},
    {241.5, 239.6, 236.8, 237.4, 239.4, 242.3, 244.2, 246.4, 249.2,
     253.6, 258.6, 262.7, 264.8, 264.2, 260.6, 254.1, 245.5, 235.3,
     223.9, 211.7, 198.3, 183.1, 165.6, 147.1, 130.5, 118.7, 111.9,
     108.1, 105.8, 104.3, 103.4, 102.8, 102.5, 102.4, 102.5, 102.5,
     102.5, 102.7, 103.1, 103.8, 104.6, 105.4, 106.1, 107, 108.2,
     109.9, 112.8, 117.5, 126, 140.4, 161, 181.9, 201.2, 216.8, 230.4,
     241.8, 251.4, 259.9, 266.9, 272.8, 277.4, 280.4, 282.9, 284.6,
     286.1, 287.4, 288.3, 289.5, 290.9, 294.2, 296.9, 297.5, 297.6},
    {301.2, 300.3, 296.6, 295.4, 295, 294.3, 291.2, 287.4, 284.9, 284.7,
     284.1, 281.5, 277.1, 270.4, 261.7, 250.6, 237.6, 223.1, 207.9, 192,
     175.8, 158.8, 142.1, 127.6, 116.8, 109.9, 106, 103.6, 102.1, 101.1,
     100.4, 99.96, 99.6, 99.37, 99.32, 99.32, 99.31, 99.46, 99.77, 100.2,
     100.7, 101.3, 101.8, 102.7, 104.1, 106.8, 111.9, 121, 136.7, 160,
     186.9, 209.9, 228.1, 241.2, 251.5, 259.5, 265.7, 270.9, 274.8, 278,
     280.3, 281.8, 283, 283.3, 283.7, 283.8, 283, 282.2, 281.2, 281.4,
     281.7, 281.1, 281.2}
  };
  memcpy(clim->tropo, tropo, sizeof(clim->tropo));
 
  /* Get range... */
  double tropomin = 1e99, tropomax = -1e99;
  for (int it = 0; it < clim->tropo_ntime; it++)
    for (int iy = 0; iy < clim->tropo_nlat; iy++) {
      tropomin = MIN(tropomin, clim->tropo[it][iy]);
      tropomax = MAX(tropomax, clim->tropo[it][iy]);
    }
 
  /* Write info... */
  LOG(2, "Number of time steps: %d", clim->tropo_ntime);
  LOG(2, "Time steps: %.2f, %.2f ... %.2f s",
      clim->tropo_time[0], clim->tropo_time[1],
      clim->tropo_time[clim->tropo_ntime - 1]);
  LOG(2, "Number of latitudes: %d", clim->tropo_nlat);
  LOG(2, "Latitudes: %g, %g ... %g deg",
      clim->tropo_lat[0], clim->tropo_lat[1],
      clim->tropo_lat[clim->tropo_nlat - 1]);
  LOG(2, "Tropopause altitude range: %g ... %g hPa", Z(tropomax),
      Z(tropomin));
  LOG(2, "Tropopause pressure range: %g ... %g hPa", tropomin, tropomax);
}
 
/*****************************************************************************/
 
double clim_ts(
  const clim_ts_t * ts,
  const double t) {
 
  /* Interpolate... */
  if (t <= ts->time[0])
    return ts->vmr[0];
  else if (t >= ts->time[ts->ntime - 1])
    return ts->vmr[ts->ntime - 1];
  else {
    int idx = locate_irr(ts->time, ts->ntime, t);
    return LIN(ts->time[idx], ts->vmr[idx],
               ts->time[idx + 1], ts->vmr[idx + 1], t);
  }
}
 
/*****************************************************************************/
 
double clim_zm(
  const clim_zm_t * zm,
  const double t,
  const double lat,
  const double p) {
 
  /* Get seconds since begin of year... */
  double sec = FMOD(t, 365.25 * 86400.);
  while (sec < 0)
    sec += 365.25 * 86400.;
 
  /* Check pressure range... */
  double p_help = p;
  if (p < zm->p[zm->np - 1])
    p_help = zm->p[zm->np - 1];
  else if (p > zm->p[0])
    p_help = zm->p[0];
 
  /* Check latitude range... */
  double lat_help = lat;
  if (lat < zm->lat[0])
    lat_help = zm->lat[0];
  else if (lat > zm->lat[zm->nlat - 1])
    lat_help = zm->lat[zm->nlat - 1];
 
  /* Get indices... */
  int isec = locate_irr(zm->time, zm->ntime, sec);
  int ilat = locate_reg(zm->lat, zm->nlat, lat_help);
  int ip = locate_irr(zm->p, zm->np, p_help);
 
  /* Interpolate climatology data... */
  double aux00 = LIN(zm->p[ip], zm->vmr[isec][ip][ilat],
                     zm->p[ip + 1], zm->vmr[isec][ip + 1][ilat], p_help);
  double aux01 = LIN(zm->p[ip], zm->vmr[isec][ip][ilat + 1],
                     zm->p[ip + 1], zm->vmr[isec][ip + 1][ilat + 1], p_help);
  double aux10 = LIN(zm->p[ip], zm->vmr[isec + 1][ip][ilat],
                     zm->p[ip + 1], zm->vmr[isec + 1][ip + 1][ilat], p_help);
  double aux11 = LIN(zm->p[ip], zm->vmr[isec + 1][ip][ilat + 1],
                     zm->p[ip + 1], zm->vmr[isec + 1][ip + 1][ilat + 1],
                     p_help);
  aux00 = LIN(zm->lat[ilat], aux00, zm->lat[ilat + 1], aux01, lat_help);
  aux11 = LIN(zm->lat[ilat], aux10, zm->lat[ilat + 1], aux11, lat_help);
  aux00 = LIN(zm->time[isec], aux00, zm->time[isec + 1], aux11, sec);
 
  return MAX(aux00, 0.0);
}
 
/*****************************************************************************/
 
#ifdef CMS
void compress_cms(
  ctl_t * ctl,
  char *varname,
  float *array,
  size_t nx,
  size_t ny,
  size_t np,
  int decompress,
  FILE * inout) {
 
  /* Set lon-lat grid... */
  double lon[EX], lat[EY];
  for (size_t ix = 0; ix < nx; ix++)
    lon[ix] = 360. * (double) ix / ((double) nx - 1.);
  for (size_t iy = 0; iy < ny; iy++)
    lat[iy] = -(180. * (double) iy / ((double) ny - 1.) - 90);
 
  /* Set multiscale parameters... */
  const char domain[] = "[0.0, 360.0]x[-90.0, 90.0]";
  const int Nd0_x = 6;
  const int Nd0_y = 3;
  const int max_level_grid = 7;
  cms_param_t *cms_param
    = cms_set_parameters(nx, ny, max_level_grid, Nd0_x, Nd0_y, domain);
 
  /* Read compressed stream and decompress array... */
  if (decompress) {
 
    /* Loop over levels... */
    double cr = 0;
    for (size_t ip = 0; ip < np; ip++) {
 
      /* Initialize multiscale module... */
      cms_module_t *cms_ptr = cms_init(cms_param);
 
      /* Read binary data... */
      cms_sol_t *cms_sol = cms_read_sol(cms_ptr, inout);
 
      /* Evaluate... */
#pragma omp parallel for default(shared)
      for (size_t ix = 0; ix < nx; ix++)
        for (size_t iy = 0; iy < ny; iy++) {
          double val, x[] = { lon[ix], lat[iy] };
          cms_eval(cms_ptr, cms_sol, x, &val);
          array[ARRAY_3D(ix, iy, ny, ip, np)] = (float) val;
        }
 
      /* Calculate mean compression ratio... */
      cr += cms_compression_rate(cms_ptr, cms_sol) / (double) np;
 
      /* Free... */
      cms_delete_module(cms_ptr);
      cms_delete_sol(cms_sol);
    }
 
    /* Write info... */
    LOG(2, "Read 3-D variable: %s (cms, RATIO= %g)", varname, cr);
  }
 
  /* Compress array and output compressed stream... */
  else {
 
    /* Init... */
    cms_module_t *cms_ptr[EP];
    cms_sol_t *cms_sol[EP];
 
    /* Loop over levels... */
#pragma omp parallel for default(shared)
    for (size_t ip = 0; ip < np; ip++) {
 
      /* Copy level data... */
      float tmp_arr[nx * ny];
      for (size_t ix = 0; ix < nx; ++ix)
        for (size_t iy = 0; iy < ny; ++iy)
          tmp_arr[ARRAY_2D(ix, iy, ny)] = array[ARRAY_3D(ix, iy, ny, ip, np)];
 
      /* Initialize multiscale module... */
      cms_ptr[ip] = cms_init(cms_param);
 
      /* Create solution pointer... */
      cms_sol[ip] = cms_read_arr(cms_ptr[ip], tmp_arr, lon, lat, nx, ny);
 
      /* Set eps threshold value... */
      if (strcasecmp(varname, "Z") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_z);
      else if (strcasecmp(varname, "T") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_t);
      else if (strcasecmp(varname, "U") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_u);
      else if (strcasecmp(varname, "V") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_v);
      else if (strcasecmp(varname, "W") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_w);
      else if (strcasecmp(varname, "PV") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_pv);
      else if (strcasecmp(varname, "H2O") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_h2o);
      else if (strcasecmp(varname, "O3") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_o3);
      else if (strcasecmp(varname, "LWC") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_lwc);
      else if (strcasecmp(varname, "RWC") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_rwc);
      else if (strcasecmp(varname, "IWC") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_iwc);
      else if (strcasecmp(varname, "SWC") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_swc);
      else if (strcasecmp(varname, "CC") == 0)
        cms_set_eps(cms_ptr[ip], ctl->met_cms_eps_cc);
      else
        ERRMSG("Variable name unknown!");
 
      /* Coarsening... */
      cms_coarsening(cms_ptr[ip], cms_sol[ip],
                     (unsigned int) ctl->met_cms_heur);
    }
 
    /* Loop over levels... */
    double cr = 0;
    for (size_t ip = 0; ip < np; ip++) {
 
      /* Evaluate... */
      double tmp_cms[nx * ny], tmp_org[nx * ny], tmp_diff[nx * ny];
#pragma omp parallel for default(shared)
      for (size_t ix = 0; ix < nx; ix++)
        for (size_t iy = 0; iy < ny; iy++) {
          double val, x[] = { lon[ix], lat[iy] };
          cms_eval(cms_ptr[ip], cms_sol[ip], x, &val);
          tmp_cms[ARRAY_2D(ix, iy, ny)] = val;
          tmp_org[ARRAY_2D(ix, iy, ny)] = array[ARRAY_3D(ix, iy, ny, ip, np)];
          tmp_diff[ARRAY_2D(ix, iy, ny)] =
            tmp_cms[ARRAY_2D(ix, iy, ny)] - tmp_org[ARRAY_2D(ix, iy, ny)];
        }
 
      /* Write info... */
      LOG(2,
          "cmultiscale: var= %s / lev= %lu / ratio= %g / rho= %g / mean= %g / sd= %g / min= %g / max= %g",
          varname, ip, cms_compression_rate(cms_ptr[ip], cms_sol[ip]),
          gsl_stats_correlation(tmp_cms, 1, tmp_org, 1, nx * ny),
          gsl_stats_mean(tmp_diff, 1, nx * ny), gsl_stats_sd(tmp_diff, 1,
                                                             nx * ny),
          gsl_stats_min(tmp_diff, 1, nx * ny), gsl_stats_max(tmp_diff, 1,
                                                             nx * ny)
        );
 
      /* Calculate mean compression ratio... */
      cr += cms_compression_rate(cms_ptr[ip], cms_sol[ip]) / (double) np;
 
      /* Save binary data... */
      cms_save_sol(cms_sol[ip], cms_ptr[ip], inout);
 
      /* Free... */
      cms_delete_module(cms_ptr[ip]);
      cms_delete_sol(cms_sol[ip]);
    }
 
    /* Write info... */
    LOG(2, "Write 3-D variable: %s (cms, RATIO= %g)", varname, cr);
  }
 
  /* Free... */
  cms_delete_param(cms_param);
}
#endif
 
/*****************************************************************************/
 
void compress_pck(
  char *varname,
  float *array,
  size_t nxy,
  size_t nz,
  int decompress,
  FILE * inout) {
 
  double min[EP], max[EP], off[EP], scl[EP];
 
  unsigned short *sarray;
 
  /* Allocate... */
  ALLOC(sarray, unsigned short,
        nxy * nz);
 
  /* Read compressed stream and decompress array... */
  if (decompress) {
 
    /* Write info... */
    LOG(2, "Read 3-D variable: %s (pck, RATIO= %g)",
        varname, (double) sizeof(float) / (double) sizeof(unsigned short));
 
    /* Read data... */
    FREAD(&scl, double,
          nz,
          inout);
    FREAD(&off, double,
          nz,
          inout);
    FREAD(sarray, unsigned short,
          nxy * nz,
          inout);
 
    /* Convert to float... */
#pragma omp parallel for default(shared)
    for (size_t ixy = 0; ixy < nxy; ixy++)
      for (size_t iz = 0; iz < nz; iz++)
        array[ixy * nz + iz]
          = (float) (sarray[ixy * nz + iz] * scl[iz] + off[iz]);
  }
 
  /* Compress array and output compressed stream... */
  else {
 
    /* Write info... */
    LOG(2, "Write 3-D variable: %s (pck, RATIO= %g)",
        varname, (double) sizeof(float) / (double) sizeof(unsigned short));
 
    /* Get range... */
    for (size_t iz = 0; iz < nz; iz++) {
      min[iz] = array[iz];
      max[iz] = array[iz];
    }
    for (size_t ixy = 1; ixy < nxy; ixy++)
      for (size_t iz = 0; iz < nz; iz++) {
        if (array[ixy * nz + iz] < min[iz])
          min[iz] = array[ixy * nz + iz];
        if (array[ixy * nz + iz] > max[iz])
          max[iz] = array[ixy * nz + iz];
      }
 
    /* Get offset and scaling factor... */
    for (size_t iz = 0; iz < nz; iz++) {
      scl[iz] = (max[iz] - min[iz]) / 65533.;
      off[iz] = min[iz];
    }
 
    /* Convert to short... */
#pragma omp parallel for default(shared)
    for (size_t ixy = 0; ixy < nxy; ixy++)
      for (size_t iz = 0; iz < nz; iz++)
        if (scl[iz] != 0)
          sarray[ixy * nz + iz] = (unsigned short)
            ((array[ixy * nz + iz] - off[iz]) / scl[iz] + .5);
        else
          sarray[ixy * nz + iz] = 0;
 
    /* Write data... */
    FWRITE(&scl, double,
           nz,
           inout);
    FWRITE(&off, double,
           nz,
           inout);
    FWRITE(sarray, unsigned short,
           nxy * nz,
           inout);
  }
 
  /* Free... */
  free(sarray);
}
 
/*****************************************************************************/
 
#ifdef ZFP
void compress_zfp(
  char *varname,
  float *array,
  int nx,
  int ny,
  int nz,
  int precision,
  double tolerance,
  int decompress,
  FILE * inout) {
 
  zfp_type type;                /* array scalar type */
  zfp_field *field;             /* array meta data */
  zfp_stream *zfp;              /* compressed stream */
  void *buffer;                 /* storage for compressed stream */
  size_t bufsize;               /* byte size of compressed buffer */
  bitstream *stream;            /* bit stream to write to or read from */
  size_t zfpsize;               /* byte size of compressed stream */
 
  /* Allocate meta data for the 3D array a[nz][ny][nx]... */
  type = zfp_type_float;
  field = zfp_field_3d(array, type, (uint) nx, (uint) ny, (uint) nz);
 
  /* Allocate meta data for a compressed stream... */
  zfp = zfp_stream_open(NULL);
 
  /* Set compression mode... */
  int actual_prec = 0;
  double actual_tol = 0;
  if (precision > 0)
    actual_prec = (int) zfp_stream_set_precision(zfp, (uint) precision);
  else if (tolerance > 0)
    actual_tol = zfp_stream_set_accuracy(zfp, tolerance);
  else
    ERRMSG("Set precision or tolerance!");
 
  /* Allocate buffer for compressed data... */
  bufsize = zfp_stream_maximum_size(zfp, field);
  buffer = malloc(bufsize);
 
  /* Associate bit stream with allocated buffer... */
  stream = stream_open(buffer, bufsize);
  zfp_stream_set_bit_stream(zfp, stream);
  zfp_stream_rewind(zfp);
 
  /* Read compressed stream and decompress array... */
  if (decompress) {
    FREAD(&zfpsize, size_t,
          1,
          inout);
    if (fread(buffer, 1, zfpsize, inout) != zfpsize)
      ERRMSG("Error while reading zfp data!");
    if (!zfp_decompress(zfp, field)) {
      ERRMSG("Decompression failed!");
    }
    LOG(2, "Read 3-D variable: %s "
        "(zfp, PREC= %d, TOL= %g, RATIO= %g)",
        varname, actual_prec, actual_tol,
        ((double) (nx * ny * nz)) / (double) zfpsize);
  }
 
  /* Compress array and output compressed stream... */
  else {
    zfpsize = zfp_compress(zfp, field);
    if (!zfpsize) {
      ERRMSG("Compression failed!");
    } else {
      FWRITE(&zfpsize, size_t,
             1,
             inout);
      if (fwrite(buffer, 1, zfpsize, inout) != zfpsize)
        ERRMSG("Error while writing zfp data!");
    }
    LOG(2, "Write 3-D variable: %s "
        "(zfp, PREC= %d, TOL= %g, RATIO= %g)",
        varname, actual_prec, actual_tol,
        ((double) (nx * ny * nz)) / (double) zfpsize);
  }
 
  /* Free... */
  zfp_field_free(field);
  zfp_stream_close(zfp);
  stream_close(stream);
  free(buffer);
}
#endif
 
/*****************************************************************************/
 
#ifdef ZSTD
void compress_zstd(
  char *varname,
  float *array,
  size_t n,
  int decompress,
  FILE * inout) {
 
  /* Get buffer sizes... */
  size_t uncomprLen = n * sizeof(float);
  size_t comprLen = ZSTD_compressBound(uncomprLen);
  size_t compsize;
 
  /* Allocate... */
  char *compr = (char *) calloc((uint) comprLen, 1);
  char *uncompr = (char *) array;
 
  /* Read compressed stream and decompress array... */
  if (decompress) {
    FREAD(&comprLen, size_t,
          1,
          inout);
    if (fread(compr, 1, comprLen, inout) != comprLen)
      ERRMSG("Error while reading zstd data!");
    compsize = ZSTD_decompress(uncompr, uncomprLen, compr, comprLen);
    if (ZSTD_isError(compsize)) {
      ERRMSG("Decompression failed!");
    }
    LOG(2, "Read 3-D variable: %s (zstd, RATIO= %g)",
        varname, ((double) uncomprLen) / (double) comprLen);
  }
 
  /* Compress array and output compressed stream... */
  else {
    compsize = ZSTD_compress(compr, comprLen, uncompr, uncomprLen, 0);
    if (ZSTD_isError(compsize)) {
      ERRMSG("Compression failed!");
    } else {
      FWRITE(&compsize, size_t,
             1,
             inout);
      if (fwrite(compr, 1, compsize, inout) != compsize)
        ERRMSG("Error while writing zstd data!");
    }
    LOG(2, "Write 3-D variable: %s (zstd, RATIO= %g)",
        varname, ((double) uncomprLen) / (double) compsize);
  }
 
  /* Free... */
  free(compr);
}
#endif
 
/*****************************************************************************/
 
void day2doy(
  const int year,
  const int mon,
  const int day,
  int *doy) {
 
  const int
    d0[12] = { 1, 32, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335 },
    d0l[12] = { 1, 32, 61, 92, 122, 153, 183, 214, 245, 275, 306, 336 };
 
  /* Get day of year... */
  if (year % 400 == 0 || (year % 100 != 0 && year % 4 == 0))
    *doy = d0l[mon - 1] + day - 1;
  else
    *doy = d0[mon - 1] + day - 1;
}
 
/*****************************************************************************/
 
void doy2day(
  const int year,
  const int doy,
  int *mon,
  int *day) {
 
  const int
    d0[12] = { 1, 32, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335 },
    d0l[12] = { 1, 32, 61, 92, 122, 153, 183, 214, 245, 275, 306, 336 };
 
  int i;
 
  /* Get month and day... */
  if (year % 400 == 0 || (year % 100 != 0 && year % 4 == 0)) {
    for (i = 11; i > 0; i--)
      if (d0l[i] <= doy)
        break;
    *mon = i + 1;
    *day = doy - d0l[i] + 1;
  } else {
    for (i = 11; i > 0; i--)
      if (d0[i] <= doy)
        break;
    *mon = i + 1;
    *day = doy - d0[i] + 1;
  }
}
 
/*****************************************************************************/
 
void fft_help(
  double *fcReal,
  double *fcImag,
  int n) {
 
  gsl_fft_complex_wavetable *wavetable;
  gsl_fft_complex_workspace *workspace;
 
  double data[2 * EX];
 
  /* Check size... */
  if (n > EX)
    ERRMSG("Too many data points!");
 
  /* Allocate... */
  wavetable = gsl_fft_complex_wavetable_alloc((size_t) n);
  workspace = gsl_fft_complex_workspace_alloc((size_t) n);
 
  /* Set data (real, complex)... */
  for (int i = 0; i < n; i++) {
    data[2 * i] = fcReal[i];
    data[2 * i + 1] = fcImag[i];
  }
 
  /* Calculate FFT... */
  gsl_fft_complex_forward(data, 1, (size_t) n, wavetable, workspace);
 
  /* Copy data... */
  for (int i = 0; i < n; i++) {
    fcReal[i] = data[2 * i];
    fcImag[i] = data[2 * i + 1];
  }
 
  /* Free... */
  gsl_fft_complex_wavetable_free(wavetable);
  gsl_fft_complex_workspace_free(workspace);
}
 
/*****************************************************************************/
 
void geo2cart(
  const double z,
  const double lon,
  const double lat,
  double *x) {
 
  double radius = z + RE;
  x[0] = radius * cos(lat / 180. * M_PI) * cos(lon / 180. * M_PI);
  x[1] = radius * cos(lat / 180. * M_PI) * sin(lon / 180. * M_PI);
  x[2] = radius * sin(lat / 180. * M_PI);
}
 
/*****************************************************************************/
 
void get_met(
  ctl_t * ctl,
  clim_t * clim,
  double t,
  met_t ** met0,
  met_t ** met1) {
 
  static int init;
 
  met_t *mets;
 
  char cachefile[LEN], cmd[2 * LEN], filename[LEN];
 
  /* Set timer... */
  SELECT_TIMER("GET_MET", "INPUT", NVTX_READ);
 
  /* Init... */
  if (t == ctl->t_start || !init) {
    init = 1;
 
    /* Read meteo data... */
    get_met_help(ctl, t + (ctl->direction == -1 ? -1 : 0), -1,
                 ctl->metbase, ctl->dt_met, filename);
    if (!read_met(filename, ctl, clim, *met0))
      ERRMSG("Cannot open file!");
 
    get_met_help(ctl, t + (ctl->direction == 1 ? 1 : 0), 1,
                 ctl->metbase, ctl->dt_met, filename);
    if (!read_met(filename, ctl, clim, *met1))
      ERRMSG("Cannot open file!");
 
    /* Update GPU... */
#ifdef _OPENACC
    SELECT_TIMER("UPDATE_DEVICE", "MEMORY", NVTX_H2D);
    met_t *met0up = *met0;
    met_t *met1up = *met1;
#ifdef ASYNCIO
#pragma acc update device(met0up[:1],met1up[:1]) async(5)
#else
#pragma acc update device(met0up[:1],met1up[:1])
#endif
    SELECT_TIMER("GET_MET", "INPUT", NVTX_READ);
#endif
 
    /* Caching... */
    if (ctl->met_cache && t != ctl->t_stop) {
      get_met_help(ctl, t + 1.1 * ctl->dt_met * ctl->direction,
                   ctl->direction, ctl->metbase, ctl->dt_met, cachefile);
      sprintf(cmd, "cat %s > /dev/null &", cachefile);
      LOG(1, "Caching: %s", cachefile);
      if (system(cmd) != 0)
        WARN("Caching command failed!");
    }
  }
 
  /* Read new data for forward trajectories... */
  if (t > (*met1)->time) {
 
    /* Pointer swap... */
    mets = *met1;
    *met1 = *met0;
    *met0 = mets;
 
    /* Read new meteo data... */
    get_met_help(ctl, t, 1, ctl->metbase, ctl->dt_met, filename);
    if (!read_met(filename, ctl, clim, *met1))
      ERRMSG("Cannot open file!");
 
    /* Update GPU... */
#ifdef _OPENACC
    SELECT_TIMER("UPDATE_DEVICE", "MEMORY", NVTX_H2D);
    met_t *met1up = *met1;
#ifdef ASYNCIO
#pragma acc update device(met1up[:1]) async(5)
#else
#pragma acc update device(met1up[:1])
#endif
    SELECT_TIMER("GET_MET", "INPUT", NVTX_READ);
#endif
 
    /* Caching... */
    if (ctl->met_cache && t != ctl->t_stop) {
      get_met_help(ctl, t + ctl->dt_met, 1, ctl->metbase, ctl->dt_met,
                   cachefile);
      sprintf(cmd, "cat %s > /dev/null &", cachefile);
      LOG(1, "Caching: %s", cachefile);
      if (system(cmd) != 0)
        WARN("Caching command failed!");
    }
  }
 
  /* Read new data for backward trajectories... */
  if (t < (*met0)->time) {
 
    /* Pointer swap... */
    mets = *met1;
    *met1 = *met0;
    *met0 = mets;
 
    /* Read new meteo data... */
    get_met_help(ctl, t, -1, ctl->metbase, ctl->dt_met, filename);
    if (!read_met(filename, ctl, clim, *met0))
      ERRMSG("Cannot open file!");
 
    /* Update GPU... */
#ifdef _OPENACC
    SELECT_TIMER("UPDATE_DEVICE", "MEMORY", NVTX_H2D);
    met_t *met0up = *met0;
#ifdef ASYNCIO
#pragma acc update device(met0up[:1]) async(5)
#else
#pragma acc update device(met0up[:1])
#endif
    SELECT_TIMER("GET_MET", "INPUT", NVTX_READ);
#endif
 
    /* Caching... */
    if (ctl->met_cache && t != ctl->t_stop) {
      get_met_help(ctl, t - ctl->dt_met, -1, ctl->metbase, ctl->dt_met,
                   cachefile);
      sprintf(cmd, "cat %s > /dev/null &", cachefile);
      LOG(1, "Caching: %s", cachefile);
      if (system(cmd) != 0)
        WARN("Caching command failed!");
    }
  }
 
  /* Check that grids are consistent... */
  if ((*met0)->nx != 0 && (*met1)->nx != 0) {
    if ((*met0)->nx != (*met1)->nx
        || (*met0)->ny != (*met1)->ny || (*met0)->np != (*met1)->np)
      ERRMSG("Meteo grid dimensions do not match!");
    for (int ix = 0; ix < (*met0)->nx; ix++)
      if (fabs((*met0)->lon[ix] - (*met1)->lon[ix]) > 0.001)
        ERRMSG("Meteo grid longitudes do not match!");
    for (int iy = 0; iy < (*met0)->ny; iy++)
      if (fabs((*met0)->lat[iy] - (*met1)->lat[iy]) > 0.001)
        ERRMSG("Meteo grid latitudes do not match!");
    for (int ip = 0; ip < (*met0)->np; ip++)
      if (fabs((*met0)->p[ip] - (*met1)->p[ip]) > 0.001)
        ERRMSG("Meteo grid pressure levels do not match!");
  }
}
 
/*****************************************************************************/
 
void get_met_help(
  ctl_t * ctl,
  double t,
  int direct,
  char *metbase,
  double dt_met,
  char *filename) {
 
  char repl[LEN];
 
  double t6, r;
 
  int year, mon, day, hour, min, sec;
 
  /* Round time to fixed intervals... */
  if (direct == -1)
    t6 = floor(t / dt_met) * dt_met;
  else
    t6 = ceil(t / dt_met) * dt_met;
 
  /* Decode time... */
  jsec2time(t6, &year, &mon, &day, &hour, &min, &sec, &r);
 
  /* Set filename of MPTRAC meteo files... */
  if (ctl->met_clams == 0) {
    if (ctl->met_type == 0)
      sprintf(filename, "%s_YYYY_MM_DD_HH.nc", metbase);
    else if (ctl->met_type == 1)
      sprintf(filename, "%s_YYYY_MM_DD_HH.bin", metbase);
    else if (ctl->met_type == 2)
      sprintf(filename, "%s_YYYY_MM_DD_HH.pck", metbase);
    else if (ctl->met_type == 3)
      sprintf(filename, "%s_YYYY_MM_DD_HH.zfp", metbase);
    else if (ctl->met_type == 4)
      sprintf(filename, "%s_YYYY_MM_DD_HH.zstd", metbase);
    else if (ctl->met_type == 5)
      sprintf(filename, "%s_YYYY_MM_DD_HH.cms", metbase);
    sprintf(repl, "%d", year);
    get_met_replace(filename, "YYYY", repl);
    sprintf(repl, "%02d", mon);
    get_met_replace(filename, "MM", repl);
    sprintf(repl, "%02d", day);
    get_met_replace(filename, "DD", repl);
    sprintf(repl, "%02d", hour);
    get_met_replace(filename, "HH", repl);
  }
 
  /* Set filename of CLaMS meteo files... */
  else {
    sprintf(filename, "%s_YYMMDDHH.nc", metbase);
    sprintf(repl, "%d", year);
    get_met_replace(filename, "YYYY", repl);
    sprintf(repl, "%02d", year % 100);
    get_met_replace(filename, "YY", repl);
    sprintf(repl, "%02d", mon);
    get_met_replace(filename, "MM", repl);
    sprintf(repl, "%02d", day);
    get_met_replace(filename, "DD", repl);
    sprintf(repl, "%02d", hour);
    get_met_replace(filename, "HH", repl);
  }
}
 
/*****************************************************************************/
 
void get_met_replace(
  char *orig,
  char *search,
  char *repl) {
 
  char buffer[LEN];
 
  /* Iterate... */
  for (int i = 0; i < 3; i++) {
 
    /* Replace sub-string... */
    char *ch;
    if (!(ch = strstr(orig, search)))
      return;
    strncpy(buffer, orig, (size_t) (ch - orig));
    buffer[ch - orig] = 0;
    sprintf(buffer + (ch - orig), "%s%s", repl, ch + strlen(search));
    orig[0] = 0;
    strcpy(orig, buffer);
  }
}
 
/*****************************************************************************/
 
void get_tropo(
  int met_tropo,
  ctl_t * ctl,
  clim_t * clim,
  met_t * met,
  double *lons,
  int nx,
  double *lats,
  int ny,
  double *pt,
  double *zt,
  double *tt,
  double *qt,
  double *o3t,
  double *ps,
  double *zs) {
 
  INTPOL_INIT;
 
  ctl->met_tropo = met_tropo;
  read_met_tropo(ctl, clim, met);
#pragma omp parallel for default(shared) private(ci,cw)
  for (int ix = 0; ix < nx; ix++)
    for (int iy = 0; iy < ny; iy++) {
      intpol_met_space_2d(met, met->pt, lons[ix], lats[iy],
                          &pt[iy * nx + ix], ci, cw, 1);
      intpol_met_space_2d(met, met->ps, lons[ix], lats[iy],
                          &ps[iy * nx + ix], ci, cw, 0);
      intpol_met_space_2d(met, met->zs, lons[ix], lats[iy],
                          &zs[iy * nx + ix], ci, cw, 0);
      intpol_met_space_3d(met, met->z, pt[iy * nx + ix], lons[ix],
                          lats[iy], &zt[iy * nx + ix], ci, cw, 1);
      intpol_met_space_3d(met, met->t, pt[iy * nx + ix], lons[ix],
                          lats[iy], &tt[iy * nx + ix], ci, cw, 0);
      intpol_met_space_3d(met, met->h2o, pt[iy * nx + ix], lons[ix],
                          lats[iy], &qt[iy * nx + ix], ci, cw, 0);
      intpol_met_space_3d(met, met->o3, pt[iy * nx + ix], lons[ix],
                          lats[iy], &o3t[iy * nx + ix], ci, cw, 0);
    }
}
 
/*****************************************************************************/
 
void intpol_met_4d_coord(
  met_t * met0,
  float heights0[EX][EY][EP],
  float array0[EX][EY][EP],
  met_t * met1,
  float heights1[EX][EY][EP],
  float array1[EX][EY][EP],
  double ts,
  double height,
  double lon,
  double lat,
  double *var,
  int *ci,
  double *cw,
  int init) {
 
  if (init) {
 
    /* Restrict positions to coordinate range... */
    lon = FMOD(lon, 360.);
    if (met0->lon[met0->nx - 1] > 180 && lon < 0)
      lon += 360;
 
    /* Get horizontal indizes... */
    ci[0] = locate_irr(met0->lon, met0->nx, lon);
    ci[1] = locate_irr(met0->lat, met0->ny, lat);
 
    /* Locate the vertical indizes for each edge of the column... */
    int ind[2][4];
    locate_vert(heights0, met0->npl, ci[0], ci[1], height, ind[0]);
    locate_vert(heights1, met1->npl, ci[0], ci[1], height, ind[1]);
 
    /* Find minimum and maximum indizes... */
    ci[2] = ind[0][0];
    int k_max = ind[0][0];
    for (int i = 0; i < 2; i++)
      for (int j = 0; j < 4; j++) {
        if (ci[2] > ind[i][j])
          ci[2] = ind[i][j];
        if (k_max < ind[i][j])
          k_max = ind[i][j];
      }
 
    /* Get weighting factors for time, longitude and latitude... */
    cw[3] = (ts - met0->time) / (met1->time - met0->time);
    cw[0] = (lon - met0->lon[ci[0]]) /
      (met0->lon[ci[0] + 1] - met0->lon[ci[0]]);
    cw[1] = (lat - met0->lat[ci[1]]) /
      (met0->lat[ci[1] + 1] - met0->lat[ci[1]]);
 
    /* Start determiniation of the altitude weighting factor... */
    double height_top, height_bot;
    double height00, height01, height10, height11, height0, height1;
 
    /* Interpolate in time at the lowest level... */
    height00 = cw[3] * (heights1[ci[0]][ci[1]][ci[2]]
                        - heights0[ci[0]][ci[1]][ci[2]])
      + heights0[ci[0]][ci[1]][ci[2]];
    height01 = cw[3] * (heights1[ci[0]][ci[1] + 1][ci[2]]
                        - heights0[ci[0]][ci[1] + 1][ci[2]])
      + heights0[ci[0]][ci[1] + 1][ci[2]];
    height10 = cw[3] * (heights1[ci[0] + 1][ci[1]][ci[2]]
                        - heights0[ci[0] + 1][ci[1]][ci[2]])
      + heights0[ci[0] + 1][ci[1]][ci[2]];
    height11 = cw[3] * (heights1[ci[0] + 1][ci[1] + 1][ci[2]]
                        - heights0[ci[0] + 1][ci[1] + 1][ci[2]])
      + heights0[ci[0] + 1][ci[1] + 1][ci[2]];
 
    /* Interpolate in latitude direction... */
    height0 = cw[1] * (height01 - height00) + height00;
    height1 = cw[1] * (height11 - height10) + height10;
 
    /* Interpolate in longitude direction... */
    height_bot = cw[0] * (height1 - height0) + height0;
 
    /* Interpolate in time at the upper level... */
    height00 = cw[3] * (heights1[ci[0]][ci[1]][ci[2] + 1]
                        - heights0[ci[0]][ci[1]][ci[2] + 1])
      + heights0[ci[0]][ci[1]][ci[2] + 1];
    height01 = cw[3] * (heights1[ci[0]][ci[1] + 1][ci[2] + 1]
                        - heights0[ci[0]][ci[1] + 1][ci[2] + 1])
      + heights0[ci[0]][ci[1] + 1][ci[2] + 1];
    height10 = cw[3] * (heights1[ci[0] + 1][ci[1]][ci[2] + 1]
                        - heights0[ci[0] + 1][ci[1]][ci[2] + 1])
      + heights0[ci[0] + 1][ci[1]][ci[2] + 1];
    height11 = cw[3] * (heights1[ci[0] + 1][ci[1] + 1][ci[2] + 1]
                        - heights0[ci[0] + 1][ci[1] + 1][ci[2] + 1])
      + heights0[ci[0] + 1][ci[1] + 1][ci[2] + 1];
 
    /* Interpolate in latitude direction... */
    height0 = cw[1] * (height01 - height00) + height00;
    height1 = cw[1] * (height11 - height10) + height10;
 
    /* Interpolate in longitude direction... */
    height_top = cw[0] * (height1 - height0) + height0;
 
    /* Search at higher levels if height is not in box... */
    while (((heights0[0][0][0] > heights0[0][0][1]) &&
            ((height_bot <= height) || (height_top > height))
            && (height_bot >= height) && (ci[2] < k_max))
           ||
           ((heights0[0][0][0] < heights0[0][0][1]) &&
            ((height_bot >= height) || (height_top < height))
            && (height_bot <= height) && (ci[2] < k_max))
      ) {
 
      ci[2]++;
      height_bot = height_top;
 
      /* Interpolate in time at the next level... */
      height00 = cw[3] * (heights1[ci[0]][ci[1]][ci[2] + 1]
                          - heights0[ci[0]][ci[1]][ci[2] + 1])
        + heights0[ci[0]][ci[1]][ci[2] + 1];
      height01 = cw[3] * (heights1[ci[0]][ci[1] + 1][ci[2] + 1]
                          - heights0[ci[0]][ci[1] + 1][ci[2] + 1])
        + heights0[ci[0]][ci[1] + 1][ci[2] + 1];
      height10 = cw[3] * (heights1[ci[0] + 1][ci[1]][ci[2] + 1]
                          - heights0[ci[0] + 1][ci[1]][ci[2] + 1])
        + heights0[ci[0] + 1][ci[1]][ci[2] + 1];
      height11 = cw[3] * (heights1[ci[0] + 1][ci[1] + 1][ci[2] + 1]
                          - heights0[ci[0] + 1][ci[1] + 1][ci[2] + 1])
        + heights0[ci[0] + 1][ci[1] + 1][ci[2] + 1];
 
      /* Interpolate in latitude direction... */
      height0 = cw[1] * (height01 - height00) + height00;
      height1 = cw[1] * (height11 - height10) + height10;
 
      /* Interpolate in longitude direction... */
      height_top = cw[0] * (height1 - height0) + height0;
    }
 
    /* Get vertical weighting factors... */
    cw[2] = (height - height_bot)
      / (height_top - height_bot);
  }
 
  /* Calculate the needed array values... */
  double array000 = cw[3] * (array1[ci[0]][ci[1]][ci[2]]
                             - array0[ci[0]][ci[1]][ci[2]])
    + array0[ci[0]][ci[1]][ci[2]];
  double array100 = cw[3] * (array1[ci[0] + 1][ci[1]][ci[2]]
                             - array0[ci[0] + 1][ci[1]][ci[2]])
    + array0[ci[0] + 1][ci[1]][ci[2]];
  double array010 = cw[3] * (array1[ci[0]][ci[1] + 1][ci[2]]
                             - array0[ci[0]][ci[1] + 1][ci[2]])
    + array0[ci[0]][ci[1] + 1][ci[2]];
  double array110 = cw[3] * (array1[ci[0] + 1][ci[1] + 1][ci[2]]
                             - array0[ci[0] + 1][ci[1] + 1][ci[2]])
    + array0[ci[0] + 1][ci[1] + 1][ci[2]];
  double array001 = cw[3] * (array1[ci[0]][ci[1]][ci[2] + 1]
                             - array0[ci[0]][ci[1]][ci[2] + 1])
    + array0[ci[0]][ci[1]][ci[2] + 1];
  double array101 = cw[3] * (array1[ci[0] + 1][ci[1]][ci[2] + 1]
                             - array0[ci[0] + 1][ci[1]][ci[2] + 1])
    + array0[ci[0] + 1][ci[1]][ci[2] + 1];
  double array011 = cw[3] * (array1[ci[0]][ci[1] + 1][ci[2] + 1]
                             - array0[ci[0]][ci[1] + 1][ci[2] + 1])
    + array0[ci[0]][ci[1] + 1][ci[2] + 1];
  double array111 = cw[3] * (array1[ci[0] + 1][ci[1] + 1][ci[2] + 1]
                             - array0[ci[0] + 1][ci[1] + 1][ci[2] + 1])
    + array0[ci[0] + 1][ci[1] + 1][ci[2] + 1];
 
  double array00 = cw[0] * (array100 - array000) + array000;
  double array10 = cw[0] * (array110 - array010) + array010;
  double array01 = cw[0] * (array101 - array001) + array001;
  double array11 = cw[0] * (array111 - array011) + array011;
 
  double aux0 = cw[1] * (array10 - array00) + array00;
  double aux1 = cw[1] * (array11 - array01) + array01;
 
  /* Interpolate vertically... */
  *var = cw[2] * (aux1 - aux0) + aux0;
}
 
/*****************************************************************************/
 
void intpol_met_space_3d(
  met_t * met,
  float array[EX][EY][EP],
  double p,
  double lon,
  double lat,
  double *var,
  int *ci,
  double *cw,
  int init) {
 
  /* Initialize interpolation... */
  if (init) {
 
    /* Check longitude... */
    if (met->lon[met->nx - 1] > 180 && lon < 0)
      lon += 360;
 
    /* Get interpolation indices... */
    ci[0] = locate_irr(met->p, met->np, p);
    ci[1] = locate_reg(met->lon, met->nx, lon);
    ci[2] = locate_reg(met->lat, met->ny, lat);
 
    /* Get interpolation weights... */
    cw[0] = (met->p[ci[0] + 1] - p)
      / (met->p[ci[0] + 1] - met->p[ci[0]]);
    cw[1] = (met->lon[ci[1] + 1] - lon)
      / (met->lon[ci[1] + 1] - met->lon[ci[1]]);
    cw[2] = (met->lat[ci[2] + 1] - lat)
      / (met->lat[ci[2] + 1] - met->lat[ci[2]]);
  }
 
  /* Interpolate vertically... */
  double aux00 =
    cw[0] * (array[ci[1]][ci[2]][ci[0]] - array[ci[1]][ci[2]][ci[0] + 1])
    + array[ci[1]][ci[2]][ci[0] + 1];
  double aux01 =
    cw[0] * (array[ci[1]][ci[2] + 1][ci[0]] -
             array[ci[1]][ci[2] + 1][ci[0] + 1])
    + array[ci[1]][ci[2] + 1][ci[0] + 1];
  double aux10 =
    cw[0] * (array[ci[1] + 1][ci[2]][ci[0]] -
             array[ci[1] + 1][ci[2]][ci[0] + 1])
    + array[ci[1] + 1][ci[2]][ci[0] + 1];
  double aux11 =
    cw[0] * (array[ci[1] + 1][ci[2] + 1][ci[0]] -
             array[ci[1] + 1][ci[2] + 1][ci[0] + 1])
    + array[ci[1] + 1][ci[2] + 1][ci[0] + 1];
 
  /* Interpolate horizontally... */
  aux00 = cw[2] * (aux00 - aux01) + aux01;
  aux11 = cw[2] * (aux10 - aux11) + aux11;
  *var = cw[1] * (aux00 - aux11) + aux11;
}
 
/*****************************************************************************/
 
void intpol_met_space_3d_ml(
  met_t * met,
  float array[EX][EY][EP],
  double p,
  double lon,
  double lat,
  double *var) {
 
  /* Check longitude... */
  if (met->lon[met->nx - 1] > 180 && lon < 0)
    lon += 360;
 
  /* Get horizontal indices... */
  int ix = locate_reg(met->lon, met->nx, lon);
  int iy = locate_reg(met->lat, met->ny, lat);
 
  /* Interpolate vertically... */
  int iz = locate_irr_float(met->pl[ix][iy], met->npl, p, 0);
  double aux00;
  if (p >= met->pl[ix][iy][iz + 1])
    aux00 = array[ix][iy][iz + 1];
  else if (p <= met->pl[ix][iy][iz])
    aux00 = array[ix][iy][iz];
  else
    aux00 = LIN(met->pl[ix][iy][iz],
                array[ix][iy][iz],
                met->pl[ix][iy][iz + 1], array[ix][iy][iz + 1], p);
 
  iz = locate_irr_float(met->pl[ix][iy + 1], met->npl, p, iz);
  double aux01;
  if (p >= met->pl[ix][iy + 1][iz + 1])
    aux01 = array[ix][iy + 1][iz + 1];
  else if (p <= met->pl[ix][iy + 1][iz])
    aux01 = array[ix][iy + 1][iz];
  else
    aux01 = LIN(met->pl[ix][iy + 1][iz],
                array[ix][iy + 1][iz],
                met->pl[ix][iy + 1][iz + 1], array[ix][iy + 1][iz + 1], p);
 
  iz = locate_irr_float(met->pl[ix + 1][iy], met->npl, p, iz);
  double aux10;
  if (p >= met->pl[ix + 1][iy][iz + 1])
    aux10 = array[ix + 1][iy][iz + 1];
  else if (p <= met->pl[ix + 1][iy][iz])
    aux10 = array[ix + 1][iy][iz];
  else
    aux10 = LIN(met->pl[ix + 1][iy][iz],
                array[ix + 1][iy][iz],
                met->pl[ix + 1][iy][iz + 1], array[ix + 1][iy][iz + 1], p);
 
  iz = locate_irr_float(met->pl[ix + 1][iy + 1], met->npl, p, iz);
  double aux11;
  if (p >= met->pl[ix + 1][iy + 1][iz + 1])
    aux11 = array[ix + 1][iy + 1][iz + 1];
  else if (p <= met->pl[ix + 1][iy + 1][iz])
    aux11 = array[ix + 1][iy + 1][iz];
  else
    aux11 = LIN(met->pl[ix + 1][iy + 1][iz],
                array[ix + 1][iy + 1][iz],
                met->pl[ix + 1][iy + 1][iz + 1],
                array[ix + 1][iy + 1][iz + 1], p);
 
  /* Interpolate horizontally... */
  double aux0 = LIN(met->lat[iy], aux00, met->lat[iy + 1], aux01, lat);
  double aux1 = LIN(met->lat[iy], aux10, met->lat[iy + 1], aux11, lat);
  *var = LIN(met->lon[ix], aux0, met->lon[ix + 1], aux1, lon);
}
 
/*****************************************************************************/
 
void intpol_met_space_2d(
  met_t * met,
  float array[EX][EY],
  double lon,
  double lat,
  double *var,
  int *ci,
  double *cw,
  int init) {
 
  /* Initialize interpolation... */
  if (init) {
 
    /* Check longitude... */
    if (met->lon[met->nx - 1] > 180 && lon < 0)
      lon += 360;
 
    /* Get interpolation indices... */
    ci[1] = locate_reg(met->lon, met->nx, lon);
    ci[2] = locate_reg(met->lat, met->ny, lat);
 
    /* Get interpolation weights... */
    cw[1] = (met->lon[ci[1] + 1] - lon)
      / (met->lon[ci[1] + 1] - met->lon[ci[1]]);
    cw[2] = (met->lat[ci[2] + 1] - lat)
      / (met->lat[ci[2] + 1] - met->lat[ci[2]]);
  }
 
  /* Set variables... */
  double aux00 = array[ci[1]][ci[2]];
  double aux01 = array[ci[1]][ci[2] + 1];
  double aux10 = array[ci[1] + 1][ci[2]];
  double aux11 = array[ci[1] + 1][ci[2] + 1];
 
  /* Interpolate horizontally... */
  if (isfinite(aux00) && isfinite(aux01)
      && isfinite(aux10) && isfinite(aux11)) {
    aux00 = cw[2] * (aux00 - aux01) + aux01;
    aux11 = cw[2] * (aux10 - aux11) + aux11;
    *var = cw[1] * (aux00 - aux11) + aux11;
  } else {
    if (cw[2] < 0.5) {
      if (cw[1] < 0.5)
        *var = aux11;
      else
        *var = aux01;
    } else {
      if (cw[1] < 0.5)
        *var = aux10;
      else
        *var = aux00;
    }
  }
}
 
/*****************************************************************************/
 
void intpol_met_time_3d(
  met_t * met0,
  float array0[EX][EY][EP],
  met_t * met1,
  float array1[EX][EY][EP],
  double ts,
  double p,
  double lon,
  double lat,
  double *var,
  int *ci,
  double *cw,
  int init) {
 
  double var0, var1, wt;
 
  /* Spatial interpolation... */
  intpol_met_space_3d(met0, array0, p, lon, lat, &var0, ci, cw, init);
  intpol_met_space_3d(met1, array1, p, lon, lat, &var1, ci, cw, 0);
 
  /* Get weighting factor... */
  wt = (met1->time - ts) / (met1->time - met0->time);
 
  /* Interpolate... */
  *var = wt * (var0 - var1) + var1;
}
 
/*****************************************************************************/
 
void intpol_met_time_3d_ml(
  met_t * met0,
  float array0[EX][EY][EP],
  met_t * met1,
  float array1[EX][EY][EP],
  double ts,
  double p,
  double lon,
  double lat,
  double *var) {
 
  double var0, var1;
 
  /* Spatial interpolation... */
  intpol_met_space_3d_ml(met0, array0, p, lon, lat, &var0);
  intpol_met_space_3d_ml(met1, array1, p, lon, lat, &var1);
 
  /* Interpolate... */
  *var = LIN(met0->time, var0, met1->time, var1, ts);
}
 
/*****************************************************************************/
 
void intpol_met_time_2d(
  met_t * met0,
  float array0[EX][EY],
  met_t * met1,
  float array1[EX][EY],
  double ts,
  double lon,
  double lat,
  double *var,
  int *ci,
  double *cw,
  int init) {
 
  double var0, var1, wt;
 
  /* Spatial interpolation... */
  intpol_met_space_2d(met0, array0, lon, lat, &var0, ci, cw, init);
  intpol_met_space_2d(met1, array1, lon, lat, &var1, ci, cw, 0);
 
  /* Get weighting factor... */
  wt = (met1->time - ts) / (met1->time - met0->time);
 
  /* Interpolate... */
  if (isfinite(var0) && isfinite(var1))
    *var = wt * (var0 - var1) + var1;
  else if (wt < 0.5)
    *var = var1;
  else
    *var = var0;
}
 
/*****************************************************************************/
 
void intpol_tropo_3d(
  double time0,
  float array0[EX][EY],
  double time1,
  float array1[EX][EY],
  double lons[EX],
  double lats[EY],
  int nlon,
  int nlat,
  double time,
  double lon,
  double lat,
  int method,
  double *var,
  double *sigma) {
 
  double aux0, aux1, aux00, aux01, aux10, aux11, mean = 0;
 
  int n = 0;
 
  /* Adjust longitude... */
  if (lon < lons[0])
    lon += 360;
  else if (lon > lons[nlon - 1])
    lon -= 360;
 
  /* Get indices... */
  int ix = locate_reg(lons, (int) nlon, lon);
  int iy = locate_reg(lats, (int) nlat, lat);
 
  /* Calculate standard deviation... */
  *sigma = 0;
  for (int dx = 0; dx < 2; dx++)
    for (int dy = 0; dy < 2; dy++) {
      if (isfinite(array0[ix + dx][iy + dy])) {
        mean += array0[ix + dx][iy + dy];
        *sigma += SQR(array0[ix + dx][iy + dy]);
        n++;
      }
      if (isfinite(array1[ix + dx][iy + dy])) {
        mean += array1[ix + dx][iy + dy];
        *sigma += SQR(array1[ix + dx][iy + dy]);
        n++;
      }
    }
  if (n > 0)
    *sigma = sqrt(MAX(*sigma / n - SQR(mean / n), 0.0));
 
  /* Linear interpolation... */
  if (method == 1 && isfinite(array0[ix][iy])
      && isfinite(array0[ix][iy + 1])
      && isfinite(array0[ix + 1][iy])
      && isfinite(array0[ix + 1][iy + 1])
      && isfinite(array1[ix][iy])
      && isfinite(array1[ix][iy + 1])
      && isfinite(array1[ix + 1][iy])
      && isfinite(array1[ix + 1][iy + 1])) {
 
    aux00 = LIN(lons[ix], array0[ix][iy],
                lons[ix + 1], array0[ix + 1][iy], lon);
    aux01 = LIN(lons[ix], array0[ix][iy + 1],
                lons[ix + 1], array0[ix + 1][iy + 1], lon);
    aux0 = LIN(lats[iy], aux00, lats[iy + 1], aux01, lat);
 
    aux10 = LIN(lons[ix], array1[ix][iy],
                lons[ix + 1], array1[ix + 1][iy], lon);
    aux11 = LIN(lons[ix], array1[ix][iy + 1],
                lons[ix + 1], array1[ix + 1][iy + 1], lon);
    aux1 = LIN(lats[iy], aux10, lats[iy + 1], aux11, lat);
 
    *var = LIN(time0, aux0, time1, aux1, time);
  }
 
  /* Nearest neighbor interpolation... */
  else {
    aux00 = NN(lons[ix], array0[ix][iy],
               lons[ix + 1], array0[ix + 1][iy], lon);
    aux01 = NN(lons[ix], array0[ix][iy + 1],
               lons[ix + 1], array0[ix + 1][iy + 1], lon);
    aux0 = NN(lats[iy], aux00, lats[iy + 1], aux01, lat);
 
    aux10 = NN(lons[ix], array1[ix][iy],
               lons[ix + 1], array1[ix + 1][iy], lon);
    aux11 = NN(lons[ix], array1[ix][iy + 1],
               lons[ix + 1], array1[ix + 1][iy + 1], lon);
    aux1 = NN(lats[iy], aux10, lats[iy + 1], aux11, lat);
 
    *var = NN(time0, aux0, time1, aux1, time);
  }
}
 
/*****************************************************************************/
 
void jsec2time(
  const double jsec,
  int *year,
  int *mon,
  int *day,
  int *hour,
  int *min,
  int *sec,
  double *remain) {
 
  struct tm t0, *t1;
 
  t0.tm_year = 100;
  t0.tm_mon = 0;
  t0.tm_mday = 1;
  t0.tm_hour = 0;
  t0.tm_min = 0;
  t0.tm_sec = 0;
 
  time_t jsec0 = (time_t) jsec + timegm(&t0);
  t1 = gmtime(&jsec0);
 
  *year = t1->tm_year + 1900;
  *mon = t1->tm_mon + 1;
  *day = t1->tm_mday;
  *hour = t1->tm_hour;
  *min = t1->tm_min;
  *sec = t1->tm_sec;
  *remain = jsec - floor(jsec);
}
 
/*****************************************************************************/
 
double kernel_weight(
  const double kz[EP],
  const double kw[EP],
  const int nk,
  const double p) {
 
  /* Check number of data points... */
  if (nk < 2)
    return 1.0;
 
  /* Get altitude... */
  double z = Z(p);
 
  /* Get weighting factor... */
  if (z < kz[0])
    return kw[0];
  else if (z > kz[nk - 1])
    return kw[nk - 1];
  else {
    int idx = locate_irr(kz, nk, z);
    return LIN(kz[idx], kw[idx], kz[idx + 1], kw[idx + 1], z);
  }
}
 
/*****************************************************************************/
 
double lapse_rate(
  const double t,
  const double h2o) {
 
  /*
     Calculate moist adiabatic lapse rate [K/km] from temperature [K]
     and water vapor volume mixing ratio [1].
 
     Reference: https://en.wikipedia.org/wiki/Lapse_rate
   */
 
  const double a = RA * SQR(t), r = SH(h2o) / (1. - SH(h2o));
 
  return 1e3 * G0 * (a + LV * r * t) / (CPD * a + SQR(LV) * r * EPS);
}
 
/*****************************************************************************/
 
void level_definitions(
  ctl_t * ctl) {
 
 
  if (0 == ctl->met_press_level_def) {
 
    ctl->met_np = 138;
 
    const double press[138] = {
      0.0200, 0.0310, 0.0467, 0.0683, 0.0975, 0.1361, 0.1861, 0.2499,
      0.3299, 0.4288, 0.5496, 0.6952, 0.8690, 1.0742, 1.3143, 1.5928, 1.9134,
      2.2797, 2.6954, 3.1642, 3.6898, 4.2759, 4.9262, 5.6441, 6.4334, 7.2974,
      8.2397, 9.2634, 10.3720, 11.5685, 12.8561, 14.2377, 15.7162, 17.2945,
      18.9752, 20.7610, 22.6543, 24.6577, 26.7735, 29.0039, 31.3512, 33.8174,
      36.4047, 39.1149, 41.9493, 44.9082, 47.9915, 51.1990, 54.5299, 57.9834,
      61.5607, 65.2695, 69.1187, 73.1187, 77.2810, 81.6182, 86.1450, 90.8774,
      95.8280, 101.0047, 106.4153, 112.0681, 117.9714, 124.1337, 130.5637,
      137.2703, 144.2624, 151.5493, 159.1403, 167.0450, 175.2731, 183.8344,
      192.7389, 201.9969, 211.6186, 221.6146, 231.9954, 242.7719, 253.9549,
      265.5556, 277.5852, 290.0548, 302.9762, 316.3607, 330.2202, 344.5663,
      359.4111, 374.7666, 390.6450, 407.0583, 424.0190, 441.5395, 459.6321,
      478.3096, 497.5845, 517.4198, 537.7195, 558.3430, 579.1926, 600.1668,
      621.1624, 642.0764, 662.8084, 683.2620, 703.3467, 722.9795, 742.0855,
      760.5996, 778.4661, 795.6396, 812.0847, 827.7756, 842.6959, 856.8376,
      870.2004, 882.7910, 894.6222, 905.7116, 916.0815, 925.7571, 934.7666,
      943.1399, 950.9082, 958.1037, 964.7584, 970.9046, 976.5737, 981.7968,
      986.6036, 991.0230, 995.0824, 998.8081, 1002.2250, 1005.3562, 1008.2239,
      1010.8487, 1013.2500, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (1 == ctl->met_press_level_def) {
 
    ctl->met_np = 92;
 
    const double press[92] = {
      0.0200, 0.0398, 0.0739, 0.1291, 0.2141, 0.3395, 0.5175, 0.7617,
      1.0872, 1.5099, 2.0464, 2.7136, 3.5282, 4.5069, 5.6652, 7.0181,
      8.5795, 10.3617, 12.3759, 14.6316, 17.1371, 19.8987, 22.9216, 26.2090,
      29.7630, 33.5843, 37.6720, 42.0242, 46.6378, 51.5086, 56.6316, 61.9984,
      67.5973, 73.4150, 79.4434, 85.7016, 92.2162, 99.0182, 106.1445,
      113.6382,
      121.5502, 129.9403, 138.8558, 148.3260, 158.3816, 169.0545, 180.3786,
      192.3889, 205.1222, 218.6172, 232.9140, 248.0547, 264.0833, 281.0456,
      298.9895, 317.9651, 338.0245, 359.2221, 381.6144, 405.2606, 430.2069,
      456.4813, 483.8505, 512.0662, 540.8577, 569.9401, 599.0310, 627.9668,
      656.6129, 684.8491, 712.5573, 739.5739, 765.7697, 791.0376, 815.2774,
      838.3507, 860.1516, 880.6080, 899.6602, 917.2205, 933.2247, 947.6584,
      960.5245, 971.8169, 981.5301, 989.7322, 996.8732, 1002.8013,
      1007.4431, 1010.8487, 1013.2500, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (2 == ctl->met_press_level_def) {
 
    ctl->met_np = 60;
 
    const double press[60] = {
      0.01, 0.1361, 0.2499, 0.4288, 0.6952, 1.0742,
      2.2797, 3.1642, 4.2759, 7.2974, 9.2634, 11.5685, 14.2377, 20.761,
      24.6577, 33.8174, 39.1149, 51.199, 57.9834, 73.1187, 81.6182,
      90.8774, 101.005, 112.068, 124.134, 137.27, 151.549, 167.045, 183.834,
      201.997, 221.615, 242.772, 265.556, 290.055, 316.361, 344.566, 374.767,
      407.058, 441.539, 478.31, 517.42, 558.343, 600.167, 683.262, 722.979,
      760.6, 795.64, 827.776, 856.838, 882.791, 905.712, 925.757, 943.14,
      958.104, 972.495, 986.886, 1001.28, 1015.67, 1030.06, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (3 == ctl->met_press_level_def) {
 
    ctl->met_np = 147;
 
    const double press[147] = {
      0.0200, 0.0310, 0.0467, 0.0683, 0.0975, 0.1361, 0.1861, 0.2499,
      0.3299, 0.4288, 0.5496, 0.6952, 0.8690, 1.0742, 1.3143, 1.5928, 1.9134,
      2.2797, 2.6954, 3.1642, 3.6898, 4.2759, 4.9262, 5.6441, 6.4334, 7.2974,
      8.2397, 9.2634, 10.3720, 11.5685, 12.8561, 14.2377, 15.7162, 17.2945,
      18.9752, 20.7610, 22.6543, 24.6577, 26.7735, 29.0039, 31.3512, 33.8174,
      36.4047, 39.1149, 41.9493, 44.9082, 47.9915, 51.1990, 54.5299, 57.9834,
      61.5607, 65.2695, 69.1187, 73.1187, 77.2810, 81.6182, 86.1450, 90.8774,
      95.8280, 101.0047, 106.4153, 112.0681, 117.9714, 124.1337, 130.5637,
      137.2703, 144.2624, 151.5493, 159.1403, 167.0450, 175.2731, 183.8344,
      192.7389, 201.9969, 211.6186, 221.6146, 231.9954, 242.7719, 253.9549,
      265.5556, 277.5852, 290.0548, 302.9762, 316.3607, 330.2202, 344.5663,
      359.4111, 374.7666, 390.6450, 407.0583, 424.0190, 441.5395, 459.6321,
      478.3096, 497.5845, 517.4198, 537.7195, 558.3430, 579.1926, 600.1668,
      621.1624, 642.0764, 662.8084, 683.2620, 703.3467, 722.9795, 742.0855,
      760.5996, 778.4661, 795.6396, 812.0847, 827.7756, 842.6959, 856.8376,
      870.2004, 882.7910, 894.6222, 905.7116, 916.0815, 925.7571, 934.7666,
      943.1399, 950.9082, 958.1037, 964.7584, 970.9046, 976.5737, 981.7968,
      986.6036, 991.0230, 995.0824, 998.8081, 1002.2250, 1005.3562, 1008.2239,
      1010.8487, 1013.25, 1016.37, 1019.49, 1022.61, 1025.73, 1028.85,
      1031.97,
      1035.09, 1038.21, 1041.33, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (4 == ctl->met_press_level_def) {
 
    ctl->met_np = 101;
 
    const double press[101] = {
      0.0200, 0.0398, 0.0739, 0.1291, 0.2141, 0.3395, 0.5175, 0.7617,
      1.0872, 1.5099, 2.0464, 2.7136, 3.5282, 4.5069, 5.6652, 7.0181,
      8.5795, 10.3617, 12.3759, 14.6316, 17.1371, 19.8987, 22.9216, 26.2090,
      29.7630, 33.5843, 37.6720, 42.0242, 46.6378, 51.5086, 56.6316, 61.9984,
      67.5973, 73.4150, 79.4434, 85.7016, 92.2162, 99.0182, 106.1445,
      113.6382,
      121.5502, 129.9403, 138.8558, 148.3260, 158.3816, 169.0545, 180.3786,
      192.3889, 205.1222, 218.6172, 232.9140, 248.0547, 264.0833, 281.0456,
      298.9895, 317.9651, 338.0245, 359.2221, 381.6144, 405.2606, 430.2069,
      456.4813, 483.8505, 512.0662, 540.8577, 569.9401, 599.0310, 627.9668,
      656.6129, 684.8491, 712.5573, 739.5739, 765.7697, 791.0376, 815.2774,
      838.3507, 860.1516, 880.6080, 899.6602, 917.2205, 933.2247, 947.6584,
      960.5245, 971.8169, 981.5301, 989.7322, 996.8732, 1002.8013,
      1007.4431, 1010.8487, 1013.25, 1016.37, 1019.49, 1022.61, 1025.73,
      1028.85, 1031.97,
      1035.09, 1038.21, 1041.33, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (5 == ctl->met_press_level_def) {
 
    ctl->met_np = 62;
 
    const double press[62] = {
      0.01, 0.1361, 0.2499, 0.4288, 0.6952, 1.0742,
      2.2797, 3.1642, 4.2759, 7.2974, 9.2634, 11.5685, 14.2377, 20.761,
      24.6577, 33.8174, 39.1149, 51.199, 57.9834, 73.1187, 81.6182,
      90.8774, 101.005, 112.068, 124.134, 137.27, 151.549, 167.045, 183.834,
      201.997, 221.615, 242.772, 265.556, 290.055, 316.361, 344.566, 374.767,
      407.058, 441.539, 478.31, 517.42, 558.343, 600.167, 683.262, 722.979,
      760.6, 795.64, 827.776, 856.838, 882.791, 905.712, 925.757, 943.14,
      958.104, 972.495, 986.886, 1001.28, 1015.67, 1030.06, 1034.86, 1039.65,
      1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (6 == ctl->met_press_level_def) {
 
    ctl->met_np = 137;
 
    const double press[137] = {
      0.01, 0.02, 0.031, 0.0467, 0.0683, 0.0975, 0.1361, 0.1861,
      0.2499, 0.3299, 0.4288, 0.5496, 0.6952, 0.869, 1.0742,
      1.3143, 1.5928, 1.9134, 2.2797, 2.6954, 3.1642, 3.6898,
      4.2759, 4.9262, 5.6441, 6.4334, 7.2974, 8.2397, 9.2634,
      10.372, 11.5685, 12.8561, 14.2377, 15.7162, 17.2945, 18.9752,
      20.761, 22.6543, 24.6577, 26.7735, 29.0039, 31.3512, 33.8174,
      36.4047, 39.1149, 41.9493, 44.9082, 47.9915, 51.199, 54.5299,
      57.9834, 61.5607, 65.2695, 69.1187, 73.1187, 77.281, 81.6182,
      86.145, 90.8774, 95.828, 101.005, 106.415, 112.068, 117.971,
      124.134, 130.564, 137.27, 144.262, 151.549, 159.14, 167.045,
      175.273, 183.834, 192.739, 201.997, 211.619, 221.615, 231.995,
      242.772, 253.955, 265.556, 277.585, 290.055, 302.976, 316.361,
      330.22, 344.566, 359.411, 374.767, 390.645, 407.058, 424.019,
      441.539, 459.632, 478.31, 497.584, 517.42, 537.72, 558.343,
      579.193, 600.167, 621.162, 642.076, 662.808, 683.262, 703.347,
      722.979, 742.086, 760.6, 778.466, 795.64, 812.085, 827.776,
      842.696, 856.838, 870.2, 882.791, 894.622, 905.712, 916.081,
      925.757, 934.767, 943.14, 950.908, 958.104, 965.299, 972.495,
      979.69, 986.886, 994.081, 1001.28, 1008.47, 1015.67, 1022.86,
      1030.06, 1037.25, 1044.45
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else if (7 == ctl->met_press_level_def) {
 
    ctl->met_np = 59;
 
    const double press[59] = {
      0.1, 0.2, 0.3843, 0.6365, 0.9564, 1.3448, 1.8058, 2.3478,
      2.985, 3.7397, 4.6462, 5.7565, 7.1322, 8.8366, 10.9483,
      13.5647, 16.8064, 20.8227, 25.7989, 31.9642, 39.6029, 49.0671,
      60.1802, 73.0663, 87.7274, 104.229, 122.614, 142.902, 165.089,
      189.147, 215.025, 242.652, 272.059, 303.217, 336.044, 370.407,
      406.133, 443.009, 480.791, 519.209, 557.973, 596.777, 635.306,
      673.24, 710.263, 746.063, 780.346, 812.83, 843.263, 871.42,
      897.112, 920.189, 940.551, 958.148, 975.744, 993.341, 1010.94,
      1028.53, 1046.13
    };
 
    for (int ip = 0; ip < ctl->met_np; ip++)
      ctl->met_p[ctl->met_np - ip - 1] = press[ip];
 
  } else {
    ERRMSG("Use 0 for l137, 1 for l91, 2 for l60 or values between 3 and 7.")
  }
}
 
/*****************************************************************************/
 
int locate_irr(
  const double *xx,
  const int n,
  const double x) {
 
  int ilo = 0;
  int ihi = n - 1;
  int i = (ihi + ilo) >> 1;
 
  if (xx[i] < xx[i + 1])
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (xx[i] > x)
        ihi = i;
      else
        ilo = i;
  } else
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (xx[i] <= x)
        ihi = i;
      else
        ilo = i;
    }
 
  return ilo;
}
 
/*****************************************************************************/
 
int locate_irr_float(
  const float *xx,
  const int n,
  const double x,
  const int ig) {
 
  int ilo = 0;
  int ihi = n - 1;
  int i = (ihi + ilo) >> 1;
 
  if (x >= xx[ig] && x < xx[ig + 1])
    return ig;
 
  if (xx[i] < xx[i + 1])
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (xx[i] > x)
        ihi = i;
      else
        ilo = i;
  } else
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (xx[i] <= x)
        ihi = i;
      else
        ilo = i;
    }
 
  return ilo;
}
 
/*****************************************************************************/
 
int locate_irr_3d(
  float profiles[EX][EY][EP],
  int np,
  int ind_lon,
  int ind_lat,
  double x) {
 
  int ilo = 0;
  int ihi = np - 1;
  int i = (ihi + ilo) >> 1;
 
  if (profiles[ind_lon][ind_lat][i] < profiles[ind_lon][ind_lat][i + 1])
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (profiles[ind_lon][ind_lat][i] > x) {
        ihi = i;
      } else {
        ilo = i;
      }
  } else
    while (ihi > ilo + 1) {
      i = (ihi + ilo) >> 1;
      if (profiles[ind_lon][ind_lat][i] <= x) {
        ihi = i;
      } else {
        ilo = i;
      }
    }
 
  return ilo;
}
 
/*****************************************************************************/
 
int locate_reg(
  const double *xx,
  const int n,
  const double x) {
 
  /* Calculate index... */
  int i = (int) ((x - xx[0]) / (xx[1] - xx[0]));
 
  /* Check range... */
  if (i < 0)
    return 0;
  else if (i > n - 2)
    return n - 2;
  else
    return i;
}
 
/*****************************************************************************/
 
void locate_vert(
  float profiles[EX][EY][EP],
  int np,
  int lon_ap_ind,
  int lat_ap_ind,
  double height_ap,
  int *ind) {
 
  ind[0] = locate_irr_float(profiles[lon_ap_ind][lat_ap_ind],
                            np, height_ap, 0);
  ind[1] = locate_irr_float(profiles[lon_ap_ind + 1][lat_ap_ind],
                            np, height_ap, ind[0]);
  ind[2] = locate_irr_float(profiles[lon_ap_ind][lat_ap_ind + 1],
                            np, height_ap, ind[1]);
  ind[3] = locate_irr_float(profiles[lon_ap_ind + 1][lat_ap_ind + 1],
                            np, height_ap, ind[2]);
}
 
/*****************************************************************************/
 
void module_advect(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_ADVECTION", "PHYSICS", NVTX_GPU);
 
  /* Pressure coordinate... */
  if (ctl->advect_vert_coord == 0 || ctl->advect_vert_coord == 2) {
 
    /* Loop over particles... */
    PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
      /* Init... */
      INTPOL_INIT;
      double dts, u[4], um = 0, v[4], vm = 0, w[4], wm = 0,
        x[3] = { 0, 0, 0 };
 
      /* Loop over integration nodes... */
      for (int i = 0; i < ctl->advect; i++) {
 
        /* Set position... */
        if (i == 0) {
          dts = 0.0;
          x[0] = atm->lon[ip];
          x[1] = atm->lat[ip];
          x[2] = atm->p[ip];
        } else {
          dts = (i == 3 ? 1.0 : 0.5) * dt[ip];
          x[0] = atm->lon[ip] + DX2DEG(dts * u[i - 1] / 1000., atm->lat[ip]);
          x[1] = atm->lat[ip] + DY2DEG(dts * v[i - 1] / 1000.);
          x[2] = atm->p[ip] + dts * w[i - 1];
        }
        double tm = atm->time[ip] + dts;
 
        /* Interpolate meteo data on pressure levels... */
        if (ctl->advect_vert_coord == 0) {
          intpol_met_time_3d(met0, met0->u, met1, met1->u,
                             tm, x[2], x[0], x[1], &u[i], ci, cw, 1);
          intpol_met_time_3d(met0, met0->v, met1, met1->v,
                             tm, x[2], x[0], x[1], &v[i], ci, cw, 0);
          intpol_met_time_3d(met0, met0->w, met1, met1->w,
                             tm, x[2], x[0], x[1], &w[i], ci, cw, 0);
        }
 
        /* Interpolate meteo data on model levels... */
        else {
          intpol_met_time_3d_ml(met0, met0->ul, met1, met1->ul, tm, x[2],
                                x[0], x[1], &u[i]);
          intpol_met_time_3d_ml(met0, met0->vl, met1, met1->vl, tm, x[2],
                                x[0], x[1], &v[i]);
          intpol_met_time_3d_ml(met0, met0->wl, met1, met1->wl, tm, x[2],
                                x[0], x[1], &w[i]);
        }
 
        /* Get mean wind... */
        double k = 1.0;
        if (ctl->advect == 2)
          k = (i == 0 ? 0.0 : 1.0);
        else if (ctl->advect == 4)
          k = (i == 0 || i == 3 ? 1.0 / 6.0 : 2.0 / 6.0);
        um += k * u[i];
        vm += k * v[i];
        wm += k * w[i];
      }
 
      /* Set new position... */
      atm->time[ip] += dt[ip];
      atm->lon[ip] += DX2DEG(dt[ip] * um / 1000.,
                             (ctl->advect == 2 ? x[1] : atm->lat[ip]));
      atm->lat[ip] += DY2DEG(dt[ip] * vm / 1000.);
      atm->p[ip] += dt[ip] * wm;
    }
  }
 
  /* Zeta coordinate... */
  else if (ctl->advect_vert_coord == 1) {
 
    /* Loop over particles... */
    PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
      /* If other modules have changed p translate it into a zeta... */
      if (ctl->advect_cpl_zeta_and_press_modules > 0) {
        INTPOL_INIT;
        intpol_met_4d_coord(met0, met0->pl, met0->zetal, met1,
                            met1->pl, met1->zetal, atm->time[ip], atm->p[ip],
                            atm->lon[ip], atm->lat[ip],
                            &atm->q[ctl->qnt_zeta][ip], ci, cw, 1);
      }
 
      /* Init... */
      double dts, u[4], um = 0, v[4], vm = 0, zeta_dot[4], zeta_dotm = 0,
        x[3] = { 0, 0, 0 };
 
      /* Loop over integration nodes... */
      for (int i = 0; i < ctl->advect; i++) {
 
        /* Set position... */
        if (i == 0) {
          dts = 0.0;
          x[0] = atm->lon[ip];
          x[1] = atm->lat[ip];
          x[2] = atm->q[ctl->qnt_zeta][ip];
        } else {
          dts = (i == 3 ? 1.0 : 0.5) * dt[ip];
          x[0] = atm->lon[ip] + DX2DEG(dts * u[i - 1] / 1000., atm->lat[ip]);
          x[1] = atm->lat[ip] + DY2DEG(dts * v[i - 1] / 1000.);
          x[2] = atm->q[ctl->qnt_zeta][ip] + dts * zeta_dot[i - 1];
        }
        double tm = atm->time[ip] + dts;
 
        /* Interpolate meteo data... */
        INTPOL_INIT;
        intpol_met_4d_coord(met0, met0->zetal, met0->ul, met1, met1->zetal,
                            met1->ul, tm, x[2], x[0], x[1], &u[i], ci, cw, 1);
        intpol_met_4d_coord(met0, met0->zetal, met0->vl, met1, met0->zetal,
                            met1->vl, tm, x[2], x[0], x[1], &v[i], ci, cw, 0);
        intpol_met_4d_coord(met0, met0->zetal, met0->zeta_dotl, met1,
                            met1->zetal, met1->zeta_dotl, tm, x[2], x[0],
                            x[1], &zeta_dot[i], ci, cw, 0);
 
        /* Get mean wind... */
        double k = 1.0;
        if (ctl->advect == 2)
          k = (i == 0 ? 0.0 : 1.0);
        else if (ctl->advect == 4)
          k = (i == 0 || i == 3 ? 1.0 / 6.0 : 2.0 / 6.0);
        um += k * u[i];
        vm += k * v[i];
        zeta_dotm += k * zeta_dot[i];
      }
 
      /* Set new position... */
      atm->time[ip] += dt[ip];
      atm->lon[ip] += DX2DEG(dt[ip] * um / 1000.,
                             (ctl->advect == 2 ? x[1] : atm->lat[ip]));
      atm->lat[ip] += DY2DEG(dt[ip] * vm / 1000.);
      atm->q[ctl->qnt_zeta][ip] += dt[ip] * zeta_dotm;
 
      /* Check if zeta is below zero... */
      if (atm->q[ctl->qnt_zeta][ip] < 0) {
        atm->q[ctl->qnt_zeta][ip] = 0;
      }
 
      /* Set new position also in pressure coordinates... */
      INTPOL_INIT;
      intpol_met_4d_coord(met0, met0->zetal, met0->pl, met1, met1->zetal,
                          met1->pl, atm->time[ip], atm->q[ctl->qnt_zeta][ip],
                          atm->lon[ip], atm->lat[ip], &atm->p[ip], ci, cw, 1);
    }
  }
}
 
/*****************************************************************************/
 
void module_advect_init(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm) {
 
  /* Initialize pressure consistent with zeta... */
  if (ctl->advect_vert_coord == 1) {
#pragma omp parallel for default(shared)
    for (int ip = 0; ip < atm->np; ip++) {
      INTPOL_INIT;
      intpol_met_4d_coord(met0, met0->zetal, met0->pl, met1, met1->zetal,
                          met1->pl, atm->time[ip], atm->q[ctl->qnt_zeta][ip],
                          atm->lon[ip], atm->lat[ip], &atm->p[ip], ci, cw, 1);
    }
  }
}
 
/*****************************************************************************/
 
void module_bound_cond(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_BOUNDCOND", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0 && ctl->qnt_Cccl4
      && ctl->qnt_Cccl3f < 0 && ctl->qnt_Cccl2f2 < 0
      && ctl->qnt_Cn2o < 0 && ctl->qnt_Csf6 < 0 && ctl->qnt_aoa < 0)
    return;
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,met0,met1,atm,dt)") {
 
    /* Check latitude and pressure range... */
    if (atm->lat[ip] < ctl->bound_lat0 || atm->lat[ip] > ctl->bound_lat1
        || atm->p[ip] > ctl->bound_p0 || atm->p[ip] < ctl->bound_p1)
      continue;
 
    /* Check surface layer... */
    if (ctl->bound_dps > 0 || ctl->bound_dzs > 0
        || ctl->bound_zetas > 0 || ctl->bound_pbl) {
 
      /* Get surface pressure... */
      double ps;
      INTPOL_INIT;
      INTPOL_2D(ps, 1);
 
      /* Check pressure... */
      if (ctl->bound_dps > 0 && atm->p[ip] < ps - ctl->bound_dps)
        continue;
 
      /* Check height... */
      if (ctl->bound_dzs > 0 && Z(atm->p[ip]) > Z(ps) + ctl->bound_dzs)
        continue;
 
      /* Check zeta range... */
      if (ctl->bound_zetas > 0) {
        double t;
        INTPOL_3D(t, 1);
        if (ZETA(ps, atm->p[ip], t) > ctl->bound_zetas)
          continue;
      }
 
      /* Check planetary boundary layer... */
      if (ctl->bound_pbl) {
        double pbl;
        INTPOL_2D(pbl, 0);
        if (atm->p[ip] < pbl)
          continue;
      }
    }
 
    /* Set mass and volume mixing ratio... */
    if (ctl->qnt_m >= 0 && ctl->bound_mass >= 0)
      atm->q[ctl->qnt_m][ip] =
        ctl->bound_mass + ctl->bound_mass_trend * atm->time[ip];
    if (ctl->qnt_vmr >= 0 && ctl->bound_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] =
        ctl->bound_vmr + ctl->bound_vmr_trend * atm->time[ip];
 
    /* Set CFC-10 volume mixing ratio... */
    if (ctl->qnt_Cccl4 >= 0 && ctl->clim_ccl4_timeseries[0] != '-')
      atm->q[ctl->qnt_Cccl4][ip] = clim_ts(&clim->ccl4, atm->time[ip]);
 
    /* Set CFC-11 volume mixing ratio... */
    if (ctl->qnt_Cccl3f >= 0 && ctl->clim_ccl3f_timeseries[0] != '-')
      atm->q[ctl->qnt_Cccl3f][ip] = clim_ts(&clim->ccl3f, atm->time[ip]);
 
    /* Set CFC-12 volume mixing ratio... */
    if (ctl->qnt_Cccl2f2 >= 0 && ctl->clim_ccl2f2_timeseries[0] != '-')
      atm->q[ctl->qnt_Cccl2f2][ip] = clim_ts(&clim->ccl2f2, atm->time[ip]);
 
    /* Set N2O volume mixing ratio... */
    if (ctl->qnt_Cn2o >= 0 && ctl->clim_n2o_timeseries[0] != '-')
      atm->q[ctl->qnt_Cn2o][ip] = clim_ts(&clim->n2o, atm->time[ip]);
 
    /* Set SF6 volume mixing ratio... */
    if (ctl->qnt_Csf6 >= 0 && ctl->clim_sf6_timeseries[0] != '-')
      atm->q[ctl->qnt_Csf6][ip] = clim_ts(&clim->sf6, atm->time[ip]);
 
    /* Set age of air... */
    if (ctl->qnt_aoa >= 0)
      atm->q[ctl->qnt_aoa][ip] = atm->time[ip];
  }
}
 
/*****************************************************************************/
 
void module_chemgrid(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double tt) {
 
  /* Check quantities... */
  if (ctl->molmass <= 0)
    ERRMSG("Molar mass is not defined!");
  if (ctl->qnt_m < 0)
    ERRMSG("Module needs quantity mass!");
  if (ctl->qnt_Cx < 0)
    ERRMSG("Module needs quantity Cx!");
 
  /* Set timer... */
  SELECT_TIMER("MODULE_CHEMGRID", "PHYSICS", NVTX_GPU);
 
  /* Allocate... */
  const int np = atm->np;
  const int nz = ctl->chemgrid_nz;
  const int nx = ctl->chemgrid_nx;
  const int ny = ctl->chemgrid_ny;
  const int ngrid = nx * ny * nz;
 
  double *restrict const z = (double *) malloc((size_t) nz * sizeof(double));
  double *restrict const press =
    (double *) malloc((size_t) nz * sizeof(double));
  double *restrict const mass =
    (double *) calloc((size_t) ngrid, sizeof(double));
  double *restrict const area =
    (double *) malloc((size_t) ny * sizeof(double));
  double *restrict const lon =
    (double *) malloc((size_t) nx * sizeof(double));
  double *restrict const lat =
    (double *) malloc((size_t) ny * sizeof(double));
 
  int *restrict const ixs = (int *) malloc((size_t) np * sizeof(int));
  int *restrict const iys = (int *) malloc((size_t) np * sizeof(int));
  int *restrict const izs = (int *) malloc((size_t) np * sizeof(int));
 
  /* Set grid box size... */
  const double dz = (ctl->chemgrid_z1 - ctl->chemgrid_z0) / nz;
  const double dlon = (ctl->chemgrid_lon1 - ctl->chemgrid_lon0) / nx;
  const double dlat = (ctl->chemgrid_lat1 - ctl->chemgrid_lat0) / ny;
 
  /* Set vertical coordinates... */
#ifdef _OPENACC
#pragma acc enter data create(ixs[0:np],iys[0:np],izs[0:np],z[0:nz],press[0:nz],mass[0:ngrid],area[0:ny],lon[0:nx],lat[0:ny])
#pragma acc data present(ctl,met0,met1,atm,ixs,iys,izs,z,press,mass,area,lon,lat)
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int iz = 0; iz < nz; iz++) {
    z[iz] = ctl->chemgrid_z0 + dz * (iz + 0.5);
    press[iz] = P(z[iz]);
  }
 
  /* Set time interval for output... */
  const double t0 = tt - 0.5 * ctl->dt_mod;
  const double t1 = tt + 0.5 * ctl->dt_mod;
 
  /* Get indices... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++) {
    ixs[ip] = (int) ((atm->lon[ip] - ctl->chemgrid_lon0) / dlon);
    iys[ip] = (int) ((atm->lat[ip] - ctl->chemgrid_lat0) / dlat);
    izs[ip] = (int) ((Z(atm->p[ip]) - ctl->chemgrid_z0) / dz);
    if (atm->time[ip] < t0 || atm->time[ip] > t1
        || ixs[ip] < 0 || ixs[ip] >= nx
        || iys[ip] < 0 || iys[ip] >= ny || izs[ip] < 0 || izs[ip] >= nz)
      izs[ip] = -1;
  }
 
  /* Set horizontal coordinates... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ix = 0; ix < nx; ix++)
    lon[ix] = ctl->chemgrid_lon0 + dlon * (ix + 0.5);
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int iy = 0; iy < ny; iy++) {
    lat[iy] = ctl->chemgrid_lat0 + dlat * (iy + 0.5);
    area[iy] =
      dlat * dlon * SQR(RE * M_PI / 180.) * cos(lat[iy] * M_PI / 180.);
  }
 
  /* Get mass per grid box... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#endif
  for (int ip = 0; ip < np; ip++)
    if (izs[ip] >= 0)
#ifdef _OPENACC
#pragma acc atomic update
#endif
      mass[ARRAY_3D(ixs[ip], iys[ip], ny, izs[ip], nz)]
        += atm->q[ctl->qnt_m][ip];
 
  /* Assign grid data to air parcels ... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++)
    if (izs[ip] >= 0) {
 
      /* Interpolate temperature... */
      double temp;
      INTPOL_INIT;
      intpol_met_time_3d(met0, met0->t, met1, met1->t, tt, press[izs[ip]],
                         lon[ixs[ip]], lat[iys[ip]], &temp, ci, cw, 1);
 
      /* Set mass... */
      double m = mass[ARRAY_3D(ixs[ip], iys[ip], ny, izs[ip], nz)];
 
      /* Calculate volume mixing ratio... */
      atm->q[ctl->qnt_Cx][ip] = MA / ctl->molmass * m
        / (1e9 * RHO(press[izs[ip]], temp) * area[iys[ip]] * dz);
    }
#ifdef _OPENACC
#pragma acc exit data delete(ixs,iys,izs,z,press,mass,area,lon,lat)
#endif
 
  /* Free... */
  free(mass);
  free(lon);
  free(lat);
  free(area);
  free(z);
  free(press);
  free(ixs);
  free(iys);
  free(izs);
}
 
/*****************************************************************************/
 
void module_chem_init(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm) {
 
#pragma omp parallel for default(shared)
  for (int ip = 0; ip < atm->np; ip++) {
 
    /* Set H2O and O3 using meteo data... */
    INTPOL_INIT;
    if (ctl->qnt_Ch2o >= 0) {
      double h2o;
      INTPOL_3D(h2o, 1);
      SET_ATM(qnt_Ch2o, h2o);
    }
    if (ctl->qnt_Co3 >= 0) {
      double o3;
      INTPOL_3D(o3, 1);
      SET_ATM(qnt_Co3, o3);
    }
 
    /* Set radical species... */
    SET_ATM(qnt_Coh, clim_oh(ctl, clim, atm->time[ip],
                             atm->lon[ip], atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_Cho2, clim_zm(&clim->ho2, atm->time[ip],
                              atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_Ch2o2, clim_zm(&clim->h2o2, atm->time[ip],
                               atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_Co1d, clim_zm(&clim->o1d, atm->time[ip],
                              atm->lat[ip], atm->p[ip]));
  }
}
 
/*****************************************************************************/
 
void module_convection(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt,
  double *rs) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_CONVECTION", "PHYSICS", NVTX_GPU);
 
  /* Create random numbers... */
  module_rng(ctl, rs, (size_t) atm->np, 0);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt,rs)") {
 
    /* Interpolate CAPE... */
    double cape;
    INTPOL_INIT;
    INTPOL_2D(cape, 1);
 
    /* Check threshold... */
    if (isfinite(cape) && cape >= ctl->conv_cape) {
 
      /* Check CIN... */
      if (ctl->conv_cin > 0) {
        double cin;
        INTPOL_2D(cin, 0);
        if (isfinite(cin) && cin >= ctl->conv_cin)
          continue;
      }
 
      /* Interpolate equilibrium level... */
      double pel;
      INTPOL_2D(pel, 0);
 
      /* Check whether particle is above cloud top... */
      if (!isfinite(pel) || atm->p[ip] < pel)
        continue;
 
      /* Set pressure range for vertical mixing... */
      double pbot = atm->p[ip];
      double ptop = atm->p[ip];
      if (ctl->conv_mix_bot == 1) {
        double ps;
        INTPOL_2D(ps, 0);
        pbot = ps;
      }
      if (ctl->conv_mix_top == 1)
        ptop = pel;
 
      /* Get density range... */
      double tbot, ttop;
      intpol_met_time_3d(met0, met0->t, met1, met1->t, atm->time[ip],
                         pbot, atm->lon[ip], atm->lat[ip], &tbot, ci, cw, 1);
      intpol_met_time_3d(met0, met0->t, met1, met1->t, atm->time[ip],
                         ptop, atm->lon[ip], atm->lat[ip], &ttop, ci, cw, 1);
      double rhobot = pbot / tbot;
      double rhotop = ptop / ttop;
 
      /* Get new density... */
      double rho = rhobot + (rhotop - rhobot) * rs[ip];
 
      /* Get pressure... */
      atm->p[ip] = LIN(rhobot, pbot, rhotop, ptop, rho);
    }
  }
}
 
/*****************************************************************************/
 
void module_decay(
  ctl_t * ctl,
  clim_t * clim,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_DECAY", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0)
    ERRMSG("Module needs quantity mass or volume mixing ratio!");
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,atm,dt)") {
 
    /* Get weighting factor... */
    double w = tropo_weight(clim, atm->time[ip], atm->lat[ip], atm->p[ip]);
 
    /* Set lifetime... */
    double tdec = w * ctl->tdec_trop + (1 - w) * ctl->tdec_strat;
 
    /* Calculate exponential decay... */
    double aux = exp(-dt[ip] / tdec);
    if (ctl->qnt_m >= 0) {
      if (ctl->qnt_mloss_decay >= 0)
        atm->q[ctl->qnt_mloss_decay][ip]
          += atm->q[ctl->qnt_m][ip] * (1 - aux);
      atm->q[ctl->qnt_m][ip] *= aux;
      if (ctl->qnt_loss_rate >= 0)
        atm->q[ctl->qnt_loss_rate][ip] += 1 / tdec;
    }
    if (ctl->qnt_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] *= aux;
  }
}
 
/*****************************************************************************/
 
void module_diffusion_meso(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  cache_t * cache,
  double *dt,
  double *rs) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_TURBMESO", "PHYSICS", NVTX_GPU);
 
  /* Create random numbers... */
  module_rng(ctl, rs, 3 * (size_t) atm->np, 1);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1,
                "acc data present(ctl,met0,met1,atm,cache,dt,rs)") {
 
    /* Get indices... */
    int ix = locate_reg(met0->lon, met0->nx, atm->lon[ip]);
    int iy = locate_reg(met0->lat, met0->ny, atm->lat[ip]);
    int iz = locate_irr(met0->p, met0->np, atm->p[ip]);
 
    /* Get standard deviations of local wind data... */
    float umean = 0, usig = 0, vmean = 0, vsig = 0, wmean = 0, wsig = 0;
    for (int i = 0; i < 2; i++)
      for (int j = 0; j < 2; j++)
        for (int k = 0; k < 2; k++) {
          umean += met0->u[ix + i][iy + j][iz + k];
          usig += SQR(met0->u[ix + i][iy + j][iz + k]);
          vmean += met0->v[ix + i][iy + j][iz + k];
          vsig += SQR(met0->v[ix + i][iy + j][iz + k]);
          wmean += met0->w[ix + i][iy + j][iz + k];
          wsig += SQR(met0->w[ix + i][iy + j][iz + k]);
 
          umean += met1->u[ix + i][iy + j][iz + k];
          usig += SQR(met1->u[ix + i][iy + j][iz + k]);
          vmean += met1->v[ix + i][iy + j][iz + k];
          vsig += SQR(met1->v[ix + i][iy + j][iz + k]);
          wmean += met1->w[ix + i][iy + j][iz + k];
          wsig += SQR(met1->w[ix + i][iy + j][iz + k]);
        }
    usig = usig / 16.f - SQR(umean / 16.f);
    usig = (usig > 0 ? sqrtf(usig) : 0);
    vsig = vsig / 16.f - SQR(vmean / 16.f);
    vsig = (vsig > 0 ? sqrtf(vsig) : 0);
    wsig = wsig / 16.f - SQR(wmean / 16.f);
    wsig = (wsig > 0 ? sqrtf(wsig) : 0);
 
    /* Set temporal correlations for mesoscale fluctuations... */
    double r = 1 - 2 * fabs(dt[ip]) / ctl->dt_met;
    double r2 = sqrt(1 - r * r);
 
    /* Calculate horizontal mesoscale wind fluctuations... */
    if (ctl->turb_mesox > 0) {
      cache->uvwp[ip][0] =
        (float) (r * cache->uvwp[ip][0] +
                 r2 * rs[3 * ip] * ctl->turb_mesox * usig);
      atm->lon[ip] +=
        DX2DEG(cache->uvwp[ip][0] * dt[ip] / 1000., atm->lat[ip]);
 
      cache->uvwp[ip][1] =
        (float) (r * cache->uvwp[ip][1] +
                 r2 * rs[3 * ip + 1] * ctl->turb_mesox * vsig);
      atm->lat[ip] += DY2DEG(cache->uvwp[ip][1] * dt[ip] / 1000.);
    }
 
    /* Calculate vertical mesoscale wind fluctuations... */
    if (ctl->turb_mesoz > 0) {
      cache->uvwp[ip][2] =
        (float) (r * cache->uvwp[ip][2] +
                 r2 * rs[3 * ip + 2] * ctl->turb_mesoz * wsig);
      atm->p[ip] += cache->uvwp[ip][2] * dt[ip];
    }
  }
}
 
/*****************************************************************************/
 
void module_diffusion_turb(
  ctl_t * ctl,
  clim_t * clim,
  atm_t * atm,
  double *dt,
  double *rs) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_TURBDIFF", "PHYSICS", NVTX_GPU);
 
  /* Create random numbers... */
  module_rng(ctl, rs, 3 * (size_t) atm->np, 1);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,atm,dt,rs)") {
 
    /* Get weighting factor... */
    double w = tropo_weight(clim, atm->time[ip], atm->lat[ip], atm->p[ip]);
 
    /* Set diffusivity... */
    double dx = w * ctl->turb_dx_trop + (1 - w) * ctl->turb_dx_strat;
    double dz = w * ctl->turb_dz_trop + (1 - w) * ctl->turb_dz_strat;
 
    /* Horizontal turbulent diffusion... */
    if (dx > 0) {
      double sigma = sqrt(2.0 * dx * fabs(dt[ip]));
      atm->lon[ip] += DX2DEG(rs[3 * ip] * sigma / 1000., atm->lat[ip]);
      atm->lat[ip] += DY2DEG(rs[3 * ip + 1] * sigma / 1000.);
    }
 
    /* Vertical turbulent diffusion... */
    if (dz > 0) {
      double sigma = sqrt(2.0 * dz * fabs(dt[ip]));
      atm->p[ip] += DZ2DP(rs[3 * ip + 2] * sigma / 1000., atm->p[ip]);
    }
  }
}
 
/*****************************************************************************/
 
void module_dry_deposition(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_DRYDEPO", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0)
    ERRMSG("Module needs quantity mass or volume mixing ratio!");
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
    /* Get surface pressure... */
    double ps;
    INTPOL_INIT;
    INTPOL_2D(ps, 1);
 
    /* Check whether particle is above the surface layer... */
    if (atm->p[ip] < ps - ctl->dry_depo_dp)
      continue;
 
    /* Set depth of surface layer... */
    double dz = 1000. * (Z(ps - ctl->dry_depo_dp) - Z(ps));
 
    /* Calculate sedimentation velocity for particles... */
    double v_dep;
    if (ctl->qnt_rp > 0 && ctl->qnt_rhop > 0) {
 
      /* Get temperature... */
      double t;
      INTPOL_3D(t, 1);
 
      /* Set deposition velocity... */
      v_dep = sedi(atm->p[ip], t, atm->q[ctl->qnt_rp][ip],
                   atm->q[ctl->qnt_rhop][ip]);
    }
 
    /* Use explicit sedimentation velocity for gases... */
    else
      v_dep = ctl->dry_depo_vdep;
 
    /* Calculate loss of mass based on deposition velocity... */
    double aux = exp(-dt[ip] * v_dep / dz);
    if (ctl->qnt_m >= 0) {
      if (ctl->qnt_mloss_dry >= 0)
        atm->q[ctl->qnt_mloss_dry][ip]
          += atm->q[ctl->qnt_m][ip] * (1 - aux);
      atm->q[ctl->qnt_m][ip] *= aux;
      if (ctl->qnt_loss_rate >= 0)
        atm->q[ctl->qnt_loss_rate][ip] += v_dep / dz;
    }
    if (ctl->qnt_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] *= aux;
  }
}
 
/*****************************************************************************/
 
void module_h2o2_chem(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_H2O2CHEM", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0)
    ERRMSG("Module needs quantity mass or volume mixing ratio!");
 
  /* Parameter of SO2 correction... */
  const double a = 3.12541941e-06;
  const double b = -5.72532259e-01;
  const double low = pow(1 / a, 1 / b);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(clim,ctl,met0,met1,atm,dt)") {
 
    /* Check whether particle is inside cloud... */
    double lwc, rwc;
    INTPOL_INIT;
    INTPOL_3D(lwc, 1);
    INTPOL_3D(rwc, 0);
    if (!(lwc > 0 || rwc > 0))
      continue;
 
    /* Get temperature... */
    double t;
    INTPOL_3D(t, 0);
 
    /* Get molecular density... */
    double M = MOLEC_DENS(atm->p[ip], t);
 
    /* Reaction rate (Berglen et al., 2004)... */
    double k = 9.1e7 * exp(-29700 / RI * (1. / t - 1. / 298.15));       /* (Maass, 1999), unit: M^(-2) */
 
    /* Henry constant of SO2... */
    double H_SO2 = 1.3e-2 * exp(2900 * (1. / t - 1. / 298.15)) * RI * t;
    double K_1S = 1.23e-2 * exp(2.01e3 * (1. / t - 1. / 298.15));       /* unit: mol/L */
 
    /* Henry constant of H2O2... */
    double H_h2o2 = 8.3e2 * exp(7600 * (1 / t - 1 / 298.15)) * RI * t;
 
    /* Correction factor for high SO2 concentration
       (if qnt_Cx is defined, the correction is switched on)... */
    double cor = 1;
    if (ctl->qnt_Cx >= 0)
      cor = atm->q[ctl->qnt_Cx][ip] >
        low ? a * pow(atm->q[ctl->qnt_Cx][ip], b) : 1;
 
    double h2o2 = H_h2o2
      * clim_zm(&clim->h2o2, atm->time[ip], atm->lat[ip], atm->p[ip])
      * M * cor * 1000 / AVO;   /* unit: mol/L */
 
    /* Volume water content in cloud [m^3 m^(-3)]... */
    double rho_air = 100 * atm->p[ip] / (RI * t) * MA / 1000;
    double CWC = (lwc + rwc) * rho_air / 1000;
 
    /* Calculate exponential decay (Rolph et al., 1992)... */
    double rate_coef = k * K_1S * h2o2 * H_SO2 * CWC;
    double aux = exp(-dt[ip] * rate_coef);
    if (ctl->qnt_m >= 0) {
      if (ctl->qnt_mloss_h2o2 >= 0)
        atm->q[ctl->qnt_mloss_h2o2][ip] += atm->q[ctl->qnt_m][ip] * (1 - aux);
      atm->q[ctl->qnt_m][ip] *= aux;
      if (ctl->qnt_loss_rate >= 0)
        atm->q[ctl->qnt_loss_rate][ip] += rate_coef;
    }
    if (ctl->qnt_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] *= aux;
  }
}
 
/*****************************************************************************/
 
void module_isosurf_init(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  cache_t * cache) {
 
  double t;
 
  /* Set timer... */
  SELECT_TIMER("MODULE_ISOSURF", "PHYSICS", NVTX_GPU);
 
  /* Init... */
  INTPOL_INIT;
 
  /* Save pressure... */
  if (ctl->isosurf == 1)
    for (int ip = 0; ip < atm->np; ip++)
      cache->iso_var[ip] = atm->p[ip];
 
  /* Save density... */
  else if (ctl->isosurf == 2)
    for (int ip = 0; ip < atm->np; ip++) {
      INTPOL_3D(t, 1);
      cache->iso_var[ip] = atm->p[ip] / t;
    }
 
  /* Save potential temperature... */
  else if (ctl->isosurf == 3)
    for (int ip = 0; ip < atm->np; ip++) {
      INTPOL_3D(t, 1);
      cache->iso_var[ip] = THETA(atm->p[ip], t);
    }
 
  /* Read balloon pressure data... */
  else if (ctl->isosurf == 4) {
 
    /* Write info... */
    LOG(1, "Read balloon pressure data: %s", ctl->balloon);
 
    /* Open file... */
    FILE *in;
    if (!(in = fopen(ctl->balloon, "r")))
      ERRMSG("Cannot open file!");
 
    /* Read pressure time series... */
    char line[LEN];
    while (fgets(line, LEN, in))
      if (sscanf(line, "%lg %lg", &(cache->iso_ts[cache->iso_n]),
                 &(cache->iso_ps[cache->iso_n])) == 2)
        if ((++cache->iso_n) > NP)
          ERRMSG("Too many data points!");
 
    /* Check number of points... */
    if (cache->iso_n < 1)
      ERRMSG("Could not read any data!");
 
    /* Close file... */
    fclose(in);
  }
}
 
/*****************************************************************************/
 
void module_isosurf(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  cache_t * cache,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_ISOSURF", "PHYSICS", NVTX_GPU);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 0, "acc data present(ctl,met0,met1,atm,cache,dt)") {
 
    /* Init... */
    double t;
    INTPOL_INIT;
 
    /* Restore pressure... */
    if (ctl->isosurf == 1)
      atm->p[ip] = cache->iso_var[ip];
 
    /* Restore density... */
    else if (ctl->isosurf == 2) {
      INTPOL_3D(t, 1);
      atm->p[ip] = cache->iso_var[ip] * t;
    }
 
    /* Restore potential temperature... */
    else if (ctl->isosurf == 3) {
      INTPOL_3D(t, 1);
      atm->p[ip] = 1000. * pow(cache->iso_var[ip] / t, -1. / 0.286);
    }
 
    /* Interpolate pressure... */
    else if (ctl->isosurf == 4) {
      if (atm->time[ip] <= cache->iso_ts[0])
        atm->p[ip] = cache->iso_ps[0];
      else if (atm->time[ip] >= cache->iso_ts[cache->iso_n - 1])
        atm->p[ip] = cache->iso_ps[cache->iso_n - 1];
      else {
        int idx = locate_irr(cache->iso_ts, cache->iso_n, atm->time[ip]);
        atm->p[ip] = LIN(cache->iso_ts[idx], cache->iso_ps[idx],
                         cache->iso_ts[idx + 1], cache->iso_ps[idx + 1],
                         atm->time[ip]);
      }
    }
  }
}
 
/*****************************************************************************/
 
#ifdef KPP
void module_kpp_chem(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_KPP_CHEM", "PHYSICS", NVTX_GPU);
 
  const int nvar = NVAR, nfix = NFIX, nreact = NREACT;
  double rtol[1] = { 1.0e-3 };
  double atol[1] = { 1.0 };
 
  /* Loop over particles... */
#ifdef _OPENACC
#pragma acc data copy(rtol,atol,nvar,nfix,nreact)
#endif
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,met0,met1,atm,dt) ") {
 
    double var[nvar], fix[nfix], rconst[nreact];
    for (int i = 0; i < nvar; i++) {
      var[i] = 0.0;
    }
    for (int i = 0; i < nfix; i++) {
      fix[i] = 0.0;
    }
    for (int i = 0; i < nreact; i++) {
      rconst[i] = 0.0;
    }
    /* Initialize... */
    kpp_chem_initialize(ctl, clim, met0, met1, atm, var, fix, rconst, ip);
 
    /* Integrate... */
    double rpar[20];
    int ipar[20];
 
    for (int i = 0; i < 20; i++) {
      ipar[i] = 0;
      rpar[i] = 0.0;
    }                           /* for */
 
    ipar[0] = 0;                /* 0: F=F(y), i.e. independent of t (autonomous); 0:F=F(t,y), i.e. depends on t (non-autonomous) */
    ipar[1] = 1;                /* 0: NVAR-dimentional vector of tolerances; 1:scalar tolerances */
    ipar[3] = 4;                /* choice of the method:Rodas3 */
 
    Rosenbrock(var, fix, rconst, 0, ctl->dt_kpp,
               atol, rtol, &FunTemplate, &JacTemplate, rpar, ipar);
 
    /* Output to air parcel.. */
    kpp_chem_output2atm(atm, ctl, met0, met1, var, ip);
 
  }
}
#endif
 
/*****************************************************************************/
 
void module_meteo(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_METEO", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_tsts >= 0)
    if (ctl->qnt_tice < 0 || ctl->qnt_tnat < 0)
      ERRMSG("Need T_ice and T_NAT to calculate T_STS!");
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 0, "acc data present(ctl,clim,met0,met1,atm,dt)") {
 
    double ps, ts, zs, us, vs, lsm, sst, pbl, pt, pct, pcb, cl, plcl, plfc,
      pel, cape, cin, o3c, pv, t, tt, u, v, w, h2o, h2ot, o3,
      lwc, rwc, iwc, swc, cc, z, zt;
 
    /* Interpolate meteo data... */
    INTPOL_INIT;
    INTPOL_TIME_ALL(atm->time[ip], atm->p[ip], atm->lon[ip], atm->lat[ip]);
 
    /* Set quantities... */
    SET_ATM(qnt_ps, ps);
    SET_ATM(qnt_ts, ts);
    SET_ATM(qnt_zs, zs);
    SET_ATM(qnt_us, us);
    SET_ATM(qnt_vs, vs);
    SET_ATM(qnt_lsm, lsm);
    SET_ATM(qnt_sst, sst);
    SET_ATM(qnt_pbl, pbl);
    SET_ATM(qnt_pt, pt);
    SET_ATM(qnt_tt, tt);
    SET_ATM(qnt_zt, zt);
    SET_ATM(qnt_h2ot, h2ot);
    SET_ATM(qnt_zg, z);
    SET_ATM(qnt_p, atm->p[ip]);
    SET_ATM(qnt_t, t);
    SET_ATM(qnt_rho, RHO(atm->p[ip], t));
    SET_ATM(qnt_u, u);
    SET_ATM(qnt_v, v);
    SET_ATM(qnt_w, w);
    SET_ATM(qnt_h2o, h2o);
    SET_ATM(qnt_o3, o3);
    SET_ATM(qnt_lwc, lwc);
    SET_ATM(qnt_rwc, rwc);
    SET_ATM(qnt_iwc, iwc);
    SET_ATM(qnt_swc, swc);
    SET_ATM(qnt_cc, cc);
    SET_ATM(qnt_pct, pct);
    SET_ATM(qnt_pcb, pcb);
    SET_ATM(qnt_cl, cl);
    SET_ATM(qnt_plcl, plcl);
    SET_ATM(qnt_plfc, plfc);
    SET_ATM(qnt_pel, pel);
    SET_ATM(qnt_cape, cape);
    SET_ATM(qnt_cin, cin);
    SET_ATM(qnt_o3c, o3c);
    SET_ATM(qnt_hno3,
            clim_zm(&clim->hno3, atm->time[ip], atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_oh, clim_oh(ctl, clim, atm->time[ip],
                            atm->lon[ip], atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_h2o2, clim_zm(&clim->h2o2, atm->time[ip],
                              atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_ho2, clim_zm(&clim->ho2, atm->time[ip],
                             atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_o1d, clim_zm(&clim->o1d, atm->time[ip],
                             atm->lat[ip], atm->p[ip]));
    SET_ATM(qnt_vh, sqrt(u * u + v * v));
    SET_ATM(qnt_vz, -1e3 * H0 / atm->p[ip] * w);
    SET_ATM(qnt_psat, PSAT(t));
    SET_ATM(qnt_psice, PSICE(t));
    SET_ATM(qnt_pw, PW(atm->p[ip], h2o));
    SET_ATM(qnt_sh, SH(h2o));
    SET_ATM(qnt_rh, RH(atm->p[ip], t, h2o));
    SET_ATM(qnt_rhice, RHICE(atm->p[ip], t, h2o));
    SET_ATM(qnt_theta, THETA(atm->p[ip], t));
    SET_ATM(qnt_zeta, atm->q[ctl->qnt_zeta][ip]);
    SET_ATM(qnt_zeta_d, ZETA(ps, atm->p[ip], t));
    SET_ATM(qnt_tvirt, TVIRT(t, h2o));
    SET_ATM(qnt_lapse, lapse_rate(t, h2o));
    SET_ATM(qnt_pv, pv);
    SET_ATM(qnt_tdew, TDEW(atm->p[ip], h2o));
    SET_ATM(qnt_tice, TICE(atm->p[ip], h2o));
    SET_ATM(qnt_tnat,
            nat_temperature(atm->p[ip], h2o,
                            clim_zm(&clim->hno3, atm->time[ip],
                                    atm->lat[ip], atm->p[ip])));
    SET_ATM(qnt_tsts,
            0.5 * (atm->q[ctl->qnt_tice][ip] + atm->q[ctl->qnt_tnat][ip]));
  }
}
 
/*****************************************************************************/
 
void module_mixing(
  ctl_t * ctl,
  clim_t * clim,
  atm_t * atm,
  double t) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_MIXING", "PHYSICS", NVTX_GPU);
 
  /* Allocate... */
  const int np = atm->np;
  int *restrict const ixs = (int *) malloc((size_t) np * sizeof(int));
  int *restrict const iys = (int *) malloc((size_t) np * sizeof(int));
  int *restrict const izs = (int *) malloc((size_t) np * sizeof(int));
 
  /* Set grid box size... */
  const double dz = (ctl->mixing_z1 - ctl->mixing_z0) / ctl->mixing_nz;
  const double dlon = (ctl->mixing_lon1 - ctl->mixing_lon0) / ctl->mixing_nx;
  const double dlat = (ctl->mixing_lat1 - ctl->mixing_lat0) / ctl->mixing_ny;
 
  /* Set time interval... */
  const double t0 = t - 0.5 * ctl->dt_mod;
  const double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Get indices... */
#ifdef _OPENACC
#pragma acc enter data create(ixs[0:np],iys[0:np],izs[0:np])
#pragma acc data present(ctl,clim,atm,ixs,iys,izs)
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++) {
    ixs[ip] = (int) ((atm->lon[ip] - ctl->mixing_lon0) / dlon);
    iys[ip] = (int) ((atm->lat[ip] - ctl->mixing_lat0) / dlat);
    izs[ip] = (int) ((Z(atm->p[ip]) - ctl->mixing_z0) / dz);
    if (atm->time[ip] < t0 || atm->time[ip] > t1
        || ixs[ip] < 0 || ixs[ip] >= ctl->mixing_nx
        || iys[ip] < 0 || iys[ip] >= ctl->mixing_ny
        || izs[ip] < 0 || izs[ip] >= ctl->mixing_nz)
      izs[ip] = -1;
  }
 
  /* Calculate interparcel mixing... */
  if (ctl->qnt_m >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_m);
  if (ctl->qnt_vmr >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_vmr);
  if (ctl->qnt_Ch2o >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Ch2o);
  if (ctl->qnt_Co3 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Co3);
  if (ctl->qnt_Cco >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cco);
  if (ctl->qnt_Coh >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Coh);
  if (ctl->qnt_Ch >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Ch);
  if (ctl->qnt_Cho2 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cho2);
  if (ctl->qnt_Ch2o2 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Ch2o2);
  if (ctl->qnt_Co1d >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Co1d);
  if (ctl->qnt_Co3p >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Co3p);
  if (ctl->qnt_Cccl4 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cccl4);
  if (ctl->qnt_Cccl3f >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cccl3f);
  if (ctl->qnt_Cccl2f2 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cccl2f2);
  if (ctl->qnt_Cn2o >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Cn2o);
  if (ctl->qnt_Csf6 >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_Csf6);
  if (ctl->qnt_aoa >= 0)
    module_mixing_help(ctl, clim, atm, ixs, iys, izs, ctl->qnt_aoa);
 
  /* Free... */
#ifdef _OPENACC
#pragma acc exit data delete(ixs,iys,izs)
#endif
  free(ixs);
  free(iys);
  free(izs);
}
 
/*****************************************************************************/
 
void module_mixing_help(
  ctl_t * ctl,
  clim_t * clim,
  atm_t * atm,
  const int *ixs,
  const int *iys,
  const int *izs,
  int qnt_idx) {
 
  /* Allocate... */
  const int np = atm->np;
  const int ngrid = ctl->mixing_nx * ctl->mixing_ny * ctl->mixing_nz;
  double *restrict const cmean =
    (double *) malloc((size_t) ngrid * sizeof(double));
  int *restrict const count = (int *) malloc((size_t) ngrid * sizeof(int));
 
  /* Init... */
#ifdef _OPENACC
#pragma acc enter data create(cmean[0:ngrid],count[0:ngrid])
#pragma acc data present(ctl,clim,atm,ixs,iys,izs,cmean,count)
#pragma acc parallel loop independent gang vector
#else
#ifdef __NVCOMPILER
#pragma novector
#endif
#pragma omp parallel for
#endif
  for (int i = 0; i < ngrid; i++) {
    count[i] = 0;
    cmean[i] = 0;
  }
 
  /* Loop over particles... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#endif
  for (int ip = 0; ip < np; ip++)
    if (izs[ip] >= 0) {
      int idx = ARRAY_3D
        (ixs[ip], iys[ip], ctl->mixing_ny, izs[ip], ctl->mixing_nz);
#ifdef _OPENACC
#pragma acc atomic update
#endif
      cmean[idx] += atm->q[qnt_idx][ip];
#ifdef _OPENACC
#pragma acc atomic update
#endif
      count[idx]++;
    }
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#ifdef __NVCOMPILER
#pragma novector
#endif
#pragma omp parallel for
#endif
  for (int i = 0; i < ngrid; i++)
    if (count[i] > 0)
      cmean[i] /= count[i];
 
  /* Calculate interparcel mixing... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for
#endif
  for (int ip = 0; ip < np; ip++)
    if (izs[ip] >= 0) {
 
      /* Set mixing parameter... */
      double mixparam = 1.0;
      if (ctl->mixing_trop < 1 || ctl->mixing_strat < 1) {
        double w =
          tropo_weight(clim, atm->time[ip], atm->lat[ip], atm->p[ip]);
        mixparam = w * ctl->mixing_trop + (1 - w) * ctl->mixing_strat;
      }
 
      /* Adjust quantity... */
      atm->q[qnt_idx][ip] +=
        (cmean
         [ARRAY_3D(ixs[ip], iys[ip], ctl->mixing_ny, izs[ip], ctl->mixing_nz)]
         - atm->q[qnt_idx][ip]) * mixparam;
    }
 
  /* Free... */
#ifdef _OPENACC
#pragma acc exit data delete(cmean,count)
#endif
  free(cmean);
  free(count);
}
 
/*****************************************************************************/
 
void module_oh_chem(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_OHCHEM", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0)
    ERRMSG("Module needs quantity mass or volume mixing ratio!");
 
  /* Parameter of SO2 correction... */
  const double a = 4.71572206e-08;
  const double b = -8.28782867e-01;
  const double low = pow(1 / a, 1 / b);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,met0,met1,atm,dt)") {
 
    /* Get temperature... */
    double t;
    INTPOL_INIT;
    INTPOL_3D(t, 1);
 
    /* Calculate molecular density... */
    double M = MOLEC_DENS(atm->p[ip], t);
 
    /* Use constant reaction rate... */
    double k = NAN;
    if (ctl->oh_chem_reaction == 1)
      k = ctl->oh_chem[0];
 
    /* Calculate bimolecular reaction rate... */
    else if (ctl->oh_chem_reaction == 2)
      k = ctl->oh_chem[0] * exp(-ctl->oh_chem[1] / t);
 
    /* Calculate termolecular reaction rate... */
    if (ctl->oh_chem_reaction == 3) {
 
      /* Calculate rate coefficient for X + OH + M -> XOH + M
         (JPL Publication 19-05) ... */
      double k0 =
        ctl->oh_chem[0] * (ctl->oh_chem[1] !=
                           0 ? pow(298. / t, ctl->oh_chem[1]) : 1.);
      double ki =
        ctl->oh_chem[2] * (ctl->oh_chem[3] !=
                           0 ? pow(298. / t, ctl->oh_chem[3]) : 1.);
      double c = log10(k0 * M / ki);
      k = k0 * M / (1. + k0 * M / ki) * pow(0.6, 1. / (1. + c * c));
    }
 
    /* Correction factor for high SO2 concentration
       (if qnt_Cx is defined, the correction is switched on)... */
    double cor = 1;
    if (ctl->qnt_Cx >= 0)
      cor =
        atm->q[ctl->qnt_Cx][ip] >
        low ? a * pow(atm->q[ctl->qnt_Cx][ip], b) : 1;
 
    /* Calculate exponential decay... */
    double rate_coef = k * clim_oh(ctl, clim, atm->time[ip], atm->lon[ip],
                                   atm->lat[ip], atm->p[ip]) * M * cor;
    double aux = exp(-dt[ip] * rate_coef);
    if (ctl->qnt_m >= 0) {
      if (ctl->qnt_mloss_oh >= 0)
        atm->q[ctl->qnt_mloss_oh][ip]
          += atm->q[ctl->qnt_m][ip] * (1 - aux);
      atm->q[ctl->qnt_m][ip] *= aux;
      if (ctl->qnt_loss_rate >= 0)
        atm->q[ctl->qnt_loss_rate][ip] += rate_coef;
    }
    if (ctl->qnt_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] *= aux;
  }
}
 
/*****************************************************************************/
 
void module_position(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_POSITION", "PHYSICS", NVTX_GPU);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
    /* Init... */
    double ps;
    INTPOL_INIT;
 
    /* Calculate modulo... */
    atm->lon[ip] = FMOD(atm->lon[ip], 360.);
    atm->lat[ip] = FMOD(atm->lat[ip], 360.);
 
    /* Check latitude... */
    while (atm->lat[ip] < -90 || atm->lat[ip] > 90) {
      if (atm->lat[ip] > 90) {
        atm->lat[ip] = 180 - atm->lat[ip];
        atm->lon[ip] += 180;
      }
      if (atm->lat[ip] < -90) {
        atm->lat[ip] = -180 - atm->lat[ip];
        atm->lon[ip] += 180;
      }
    }
 
    /* Check longitude... */
    while (atm->lon[ip] < -180)
      atm->lon[ip] += 360;
    while (atm->lon[ip] >= 180)
      atm->lon[ip] -= 360;
 
    /* Check pressure... */
    if (atm->p[ip] < met0->p[met0->np - 1]) {
      if (ctl->reflect)
        atm->p[ip] = 2. * met0->p[met0->np - 1] - atm->p[ip];
      else
        atm->p[ip] = met0->p[met0->np - 1];
    } else if (atm->p[ip] > 300.) {
      INTPOL_2D(ps, 1);
      if (atm->p[ip] > ps) {
        if (ctl->reflect)
          atm->p[ip] = 2. * ps - atm->p[ip];
        else
          atm->p[ip] = ps;
      }
    }
  }
}
 
/*****************************************************************************/
 
void module_rng_init(
  int ntask) {
 
  /* Initialize GSL random number generators... */
  gsl_rng_env_setup();
  if (omp_get_max_threads() > NTHREADS)
    ERRMSG("Too many threads!");
  for (int i = 0; i < NTHREADS; i++) {
    rng[i] = gsl_rng_alloc(gsl_rng_default);
    gsl_rng_set(rng[i], gsl_rng_default_seed
                + (long unsigned) (ntask * NTHREADS + i));
  }
 
  /* Initialize cuRAND random number generators... */
#ifdef CURAND
  if (curandCreateGenerator(&rng_curand, CURAND_RNG_PSEUDO_DEFAULT) !=
      CURAND_STATUS_SUCCESS)
    ERRMSG("Cannot create random number generator!");
  if (curandSetPseudoRandomGeneratorSeed(rng_curand, ntask) !=
      CURAND_STATUS_SUCCESS)
    ERRMSG("Cannot set seed for random number generator!");
  if (curandSetStream
      (rng_curand,
       (cudaStream_t) acc_get_cuda_stream(acc_async_sync)) !=
      CURAND_STATUS_SUCCESS)
    ERRMSG("Cannot set stream for random number generator!");
#endif
}
 
/*****************************************************************************/
 
void module_rng(
  ctl_t * ctl,
  double *rs,
  size_t n,
  int method) {
 
  /* Use GSL random number generators... */
  if (ctl->rng_type == 0) {
 
    /* Uniform distribution... */
    if (method == 0) {
#pragma omp parallel for default(shared)
      for (size_t i = 0; i < n; ++i)
        rs[i] = gsl_rng_uniform(rng[omp_get_thread_num()]);
    }
 
    /* Normal distribution... */
    else if (method == 1) {
#pragma omp parallel for default(shared)
      for (size_t i = 0; i < n; ++i)
        rs[i] = gsl_ran_gaussian_ziggurat(rng[omp_get_thread_num()], 1.0);
    }
 
    /* Update of random numbers on device... */
#ifdef _OPENACC
#pragma acc update device(rs[:n])
#endif
  }
 
  /* Use Squares random number generator (Widynski, 2022)... */
  else if (ctl->rng_type == 1) {
 
    /* Set key (don't change this!)... */
    const uint64_t key = 0xc8e4fd154ce32f6d;
 
    /* Uniform distribution... */
#ifdef _OPENACC
#pragma acc data present(rs)
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
    for (size_t i = 0; i < n + 1; ++i) {
      uint64_t r, t, x, y, z;
      y = x = (rng_ctr + i) * key;
      z = y + key;
      x = x * x + y;
      x = (x >> 32) | (x << 32);
      x = x * x + z;
      x = (x >> 32) | (x << 32);
      x = x * x + y;
      x = (x >> 32) | (x << 32);
      t = x = x * x + z;
      x = (x >> 32) | (x << 32);
      r = t ^ ((x * x + y) >> 32);
      rs[i] = (double) r / (double) UINT64_MAX;
    }
    rng_ctr += n + 1;
 
    /* Normal distribution... */
    if (method == 1) {
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
      for (size_t i = 0; i < n; i += 2) {
        double r = sqrt(-2.0 * log(rs[i]));
        double phi = 2.0 * M_PI * rs[i + 1];
        rs[i] = r * cosf((float) phi);
        rs[i + 1] = r * sinf((float) phi);
      }
    }
  }
 
  /* Use cuRAND random number generators... */
  else if (ctl->rng_type == 2) {
#ifdef CURAND
#pragma acc host_data use_device(rs)
    {
 
      /* Uniform distribution... */
      if (method == 0) {
        if (curandGenerateUniformDouble(rng_curand, rs, (n < 4 ? 4 : n)) !=
            CURAND_STATUS_SUCCESS)
          ERRMSG("Cannot create random numbers!");
      }
 
      /* Normal distribution... */
      else if (method == 1) {
        if (curandGenerateNormalDouble
            (rng_curand, rs, (n < 4 ? 4 : n), 0.0,
             1.0) != CURAND_STATUS_SUCCESS)
          ERRMSG("Cannot create random numbers!");
      }
    }
#else
    ERRMSG("MPTRAC was compiled without cuRAND!");
#endif
  }
}
 
/*****************************************************************************/
 
void module_sedi(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_SEDI", "PHYSICS", NVTX_GPU);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
    /* Get temperature... */
    double t;
    INTPOL_INIT;
    INTPOL_3D(t, 1);
 
    /* Sedimentation velocity... */
    double v_s = sedi(atm->p[ip], t, atm->q[ctl->qnt_rp][ip],
                      atm->q[ctl->qnt_rhop][ip]);
 
    /* Calculate pressure change... */
    atm->p[ip] += DZ2DP(v_s * dt[ip] / 1000., atm->p[ip]);
  }
}
 
/*****************************************************************************/
 
void module_sort(
  ctl_t * ctl,
  met_t * met0,
  atm_t * atm) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_SORT", "PHYSICS", NVTX_GPU);
 
  /* Allocate... */
  const int np = atm->np;
  double *restrict const a = (double *) malloc((size_t) np * sizeof(double));
  int *restrict const p = (int *) malloc((size_t) np * sizeof(int));
 
#ifdef _OPENACC
#pragma acc enter data create(a[0:np],p[0:np])
#pragma acc data present(ctl,met0,atm,a,p)
#endif
 
  /* Get box index... */
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++) {
    a[ip] =
      (double) ((locate_reg(met0->lon, met0->nx, atm->lon[ip]) * met0->ny +
                 locate_reg(met0->lat, met0->ny, atm->lat[ip]))
                * met0->np + locate_irr(met0->p, met0->np, atm->p[ip]));
    p[ip] = ip;
  }
 
  /* Sorting... */
#ifdef _OPENACC
#pragma acc host_data use_device(a, p)
#endif
#ifdef THRUST
  thrustSortWrapper(a, np, p);
#else
  ERRMSG("MPTRAC was compiled without Thrust library!");
#endif
 
  /* Sort data... */
  module_sort_help(atm->time, p, np);
  module_sort_help(atm->p, p, np);
  module_sort_help(atm->lon, p, np);
  module_sort_help(atm->lat, p, np);
  for (int iq = 0; iq < ctl->nq; iq++)
    module_sort_help(atm->q[iq], p, np);
 
  /* Free... */
#ifdef _OPENACC
#pragma acc exit data delete(a,p)
#endif
  free(a);
  free(p);
}
 
/*****************************************************************************/
 
void module_sort_help(
  double *a,
  const int *p,
  const int np) {
 
  /* Allocate... */
  double *restrict const help =
    (double *) malloc((size_t) np * sizeof(double));
 
  /* Reordering of array... */
#ifdef _OPENACC
#pragma acc enter data create(help[0:np])
#pragma acc data present(a,p,help)
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++)
    help[ip] = a[p[ip]];
#ifdef _OPENACC
#pragma acc parallel loop independent gang vector
#else
#pragma omp parallel for default(shared)
#endif
  for (int ip = 0; ip < np; ip++)
    a[ip] = help[ip];
 
  /* Free... */
#ifdef _OPENACC
#pragma acc exit data delete(help)
#endif
  free(help);
}
 
/*****************************************************************************/
 
void module_timesteps(
  ctl_t * ctl,
  met_t * met0,
  atm_t * atm,
  double *dt,
  double t) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_TIMESTEPS", "PHYSICS", NVTX_GPU);
 
  const double latmin = gsl_stats_min(met0->lat, 1, (size_t) met0->ny),
    latmax = gsl_stats_max(met0->lat, 1, (size_t) met0->ny);
 
  const int local =
    (fabs(met0->lon[met0->nx - 1] - met0->lon[0] - 360.0) >= 0.01);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 0, "acc data present(ctl,atm,met0,dt)") {
 
    /* Set time step for each air parcel... */
    if ((ctl->direction * (atm->time[ip] - ctl->t_start) >= 0
         && ctl->direction * (atm->time[ip] - ctl->t_stop) <= 0
         && ctl->direction * (atm->time[ip] - t) < 0))
      dt[ip] = t - atm->time[ip];
    else
      dt[ip] = 0.0;
 
    /* Check horizontal boundaries of local meteo data... */
    if (local && (atm->lon[ip] <= met0->lon[0]
                  || atm->lon[ip] >= met0->lon[met0->nx - 1]
                  || atm->lat[ip] <= latmin || atm->lat[ip] >= latmax))
      dt[ip] = 0.0;
  }
}
 
/*****************************************************************************/
 
void module_timesteps_init(
  ctl_t * ctl,
  atm_t * atm) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_TIMESTEPS", "PHYSICS", NVTX_GPU);
 
  /* Set start time... */
  if (ctl->direction == 1) {
    ctl->t_start = gsl_stats_min(atm->time, 1, (size_t) atm->np);
    if (ctl->t_stop > 1e99)
      ctl->t_stop = gsl_stats_max(atm->time, 1, (size_t) atm->np);
  } else {
    ctl->t_start = gsl_stats_max(atm->time, 1, (size_t) atm->np);
    if (ctl->t_stop > 1e99)
      ctl->t_stop = gsl_stats_min(atm->time, 1, (size_t) atm->np);
  }
 
  /* Check time interval... */
  if (ctl->direction * (ctl->t_stop - ctl->t_start) <= 0)
    ERRMSG("Nothing to do! Check T_STOP and DIRECTION!");
 
  /* Round start time... */
  if (ctl->direction == 1)
    ctl->t_start = floor(ctl->t_start / ctl->dt_mod) * ctl->dt_mod;
  else
    ctl->t_start = ceil(ctl->t_start / ctl->dt_mod) * ctl->dt_mod;
}
 
/*****************************************************************************/
 
void module_tracer_chem(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_TRACERCHEM", "PHYSICS", NVTX_GPU);
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,clim,met0,atm,met1,dt)") {
 
    /* Get temperature... */
    double t;
    INTPOL_INIT;
    INTPOL_3D(t, 1);
 
    /* Get molecular density... */
    double M = MOLEC_DENS(atm->p[ip], t);
 
    /* Get total column ozone... */
    double o3c;
    INTPOL_2D(o3c, 1);
 
    /* Get solar zenith angle... */
    double sza = sza_calc(atm->time[ip], atm->lon[ip], atm->lat[ip]);
 
    /* Get O(1D) volume mixing ratio... */
    double o1d = clim_zm(&clim->o1d, atm->time[ip], atm->lat[ip], atm->p[ip]);
 
    /* Reactions for CFC-10... */
    if (ctl->qnt_Cccl4 >= 0) {
      double K_o1d = ARRHENIUS(3.30e-10, 0, t) * o1d * M;
      double K_hv = clim_photo(clim->photo.ccl4, &(clim->photo),
                               atm->p[ip], sza, o3c);
      atm->q[ctl->qnt_Cccl4][ip] *= exp(-dt[ip] * (K_hv + K_o1d));
    }
 
    /* Reactions for CFC-11... */
    if (ctl->qnt_Cccl3f >= 0) {
      double K_o1d = ARRHENIUS(2.30e-10, 0, t) * o1d * M;
      double K_hv = clim_photo(clim->photo.ccl3f, &(clim->photo),
                               atm->p[ip], sza, o3c);
      atm->q[ctl->qnt_Cccl3f][ip] *= exp(-dt[ip] * (K_hv + K_o1d));
    }
 
    /* Reactions for CFC-12... */
    if (ctl->qnt_Cccl2f2 >= 0) {
      double K_o1d = ARRHENIUS(1.40e-10, -25, t) * o1d * M;
      double K_hv = clim_photo(clim->photo.ccl2f2, &(clim->photo),
                               atm->p[ip], sza, o3c);
      atm->q[ctl->qnt_Cccl2f2][ip] *= exp(-dt[ip] * (K_hv + K_o1d));
    }
 
    /* Reactions for N2O... */
    if (ctl->qnt_Cn2o >= 0) {
      double K_o1d = ARRHENIUS(1.19e-10, -20, t) * o1d * M;
      double K_hv = clim_photo(clim->photo.n2o, &(clim->photo),
                               atm->p[ip], sza, o3c);
      atm->q[ctl->qnt_Cn2o][ip] *= exp(-dt[ip] * (K_hv + K_o1d));
    }
  }
}
 
/*****************************************************************************/
 
void module_wet_deposition(
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double *dt) {
 
  /* Set timer... */
  SELECT_TIMER("MODULE_WETDEPO", "PHYSICS", NVTX_GPU);
 
  /* Check quantity flags... */
  if (ctl->qnt_m < 0 && ctl->qnt_vmr < 0)
    ERRMSG("Module needs quantity mass or volume mixing ratio!");
 
  /* Loop over particles... */
  PARTICLE_LOOP(0, atm->np, 1, "acc data present(ctl,met0,met1,atm,dt)") {
 
    /* Check whether particle is below cloud top... */
    double pct;
    INTPOL_INIT;
    INTPOL_2D(pct, 1);
    if (!isfinite(pct) || atm->p[ip] <= pct)
      continue;
 
    /* Get cloud bottom pressure... */
    double pcb;
    INTPOL_2D(pcb, 0);
 
    /* Estimate precipitation rate (Pisso et al., 2019)... */
    double cl;
    INTPOL_2D(cl, 0);
    double Is =
      pow(1. / ctl->wet_depo_pre[0] * cl, 1. / ctl->wet_depo_pre[1]);
    if (Is < 0.01)
      continue;
 
    /* Check whether particle is inside or below cloud... */
    double lwc, rwc, iwc, swc;
    INTPOL_3D(lwc, 1);
    INTPOL_3D(rwc, 0);
    INTPOL_3D(iwc, 0);
    INTPOL_3D(swc, 0);
    int inside = (lwc > 0 || rwc > 0 || iwc > 0 || swc > 0);
 
    /* Get temperature... */
    double t;
    INTPOL_3D(t, 0);
 
    /* Calculate in-cloud scavenging coefficient... */
    double lambda = 0;
    if (inside) {
 
      /* Calculate retention factor... */
      double eta;
      if (t > 273.15)
        eta = 1;
      else if (t <= 238.15)
        eta = ctl->wet_depo_ic_ret_ratio;
      else
        eta = LIN(273.15, 1, 238.15, ctl->wet_depo_ic_ret_ratio, t);
 
      /* Use exponential dependency for particles ... */
      if (ctl->wet_depo_ic_a > 0)
        lambda = ctl->wet_depo_ic_a * pow(Is, ctl->wet_depo_ic_b) * eta;
 
      /* Use Henry's law for gases... */
      else if (ctl->wet_depo_ic_h[0] > 0) {
 
        /* Get Henry's constant (Sander, 2015)... */
        double h = ctl->wet_depo_ic_h[0]
          * exp(ctl->wet_depo_ic_h[1] * (1. / t - 1. / 298.15));
 
        /* Use effective Henry's constant for SO2
           (Berglen, 2004; Simpson, 2012)... */
        if (ctl->wet_depo_ic_h[2] > 0) {
          double H_ion = pow(10, ctl->wet_depo_ic_h[2] * (-1));
          double K_1 = 1.23e-2 * exp(2.01e3 * (1. / t - 1. / 298.15));
          double K_2 = 6e-8 * exp(1.12e3 * (1. / t - 1. / 298.15));
          h *= (1 + K_1 / H_ion + K_1 * K_2 / pow(H_ion, 2));
        }
 
        /* Estimate depth of cloud layer... */
        double dz = 1e3 * (Z(pct) - Z(pcb));
 
        /* Calculate scavenging coefficient (Draxler and Hess, 1997)... */
        lambda = h * RI * t * Is / 3.6e6 / dz * eta;
      }
    }
 
    /* Calculate below-cloud scavenging coefficient... */
    else {
 
      /* Calculate retention factor... */
      double eta;
      if (t > 270)
        eta = 1;
      else
        eta = ctl->wet_depo_bc_ret_ratio;
 
      /* Use exponential dependency for particles... */
      if (ctl->wet_depo_bc_a > 0)
        lambda = ctl->wet_depo_bc_a * pow(Is, ctl->wet_depo_bc_b) * eta;
 
      /* Use Henry's law for gases... */
      else if (ctl->wet_depo_bc_h[0] > 0) {
 
        /* Get Henry's constant (Sander, 2015)... */
        double h = ctl->wet_depo_bc_h[0]
          * exp(ctl->wet_depo_bc_h[1] * (1. / t - 1. / 298.15));
 
        /* Estimate depth of cloud layer... */
        double dz = 1e3 * (Z(pct) - Z(pcb));
 
        /* Calculate scavenging coefficient (Draxler and Hess, 1997)... */
        lambda = h * RI * t * Is / 3.6e6 / dz * eta;
      }
    }
 
    /* Calculate exponential decay of mass... */
    double aux = exp(-dt[ip] * lambda);
    if (ctl->qnt_m >= 0) {
      if (ctl->qnt_mloss_wet >= 0)
        atm->q[ctl->qnt_mloss_wet][ip]
          += atm->q[ctl->qnt_m][ip] * (1 - aux);
      atm->q[ctl->qnt_m][ip] *= aux;
      if (ctl->qnt_loss_rate >= 0)
        atm->q[ctl->qnt_loss_rate][ip] += lambda;
    }
    if (ctl->qnt_vmr >= 0)
      atm->q[ctl->qnt_vmr][ip] *= aux;
  }
}
 
/*****************************************************************************/
 
double nat_temperature(
  const double p,
  const double h2o,
  const double hno3) {
 
  /* Check water vapor volume mixing ratio... */
  double h2o_help = MAX(h2o, 0.1e-6);
 
  /* Calculate T_NAT... */
  double p_hno3 = hno3 * p / 1.333224;
  double p_h2o = h2o_help * p / 1.333224;
  double a = 0.009179 - 0.00088 * log10(p_h2o);
  double b = (38.9855 - log10(p_hno3) - 2.7836 * log10(p_h2o)) / a;
  double c = -11397.0 / a;
  double tnat = (-b + sqrt(b * b - 4. * c)) / 2.;
  double x2 = (-b - sqrt(b * b - 4. * c)) / 2.;
  if (x2 > 0)
    tnat = x2;
 
  return tnat;
}
 
/*****************************************************************************/
 
int read_atm(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  int result;
 
  /* Set timer... */
  SELECT_TIMER("READ_ATM", "INPUT", NVTX_READ);
 
  /* Init... */
  atm->np = 0;
 
  /* Write info... */
  LOG(1, "Read atmospheric data: %s", filename);
 
  /* Read ASCII data... */
  if (ctl->atm_type == 0)
    result = read_atm_asc(filename, ctl, atm);
 
  /* Read binary data... */
  else if (ctl->atm_type == 1)
    result = read_atm_bin(filename, ctl, atm);
 
  /* Read netCDF data... */
  else if (ctl->atm_type == 2)
    result = read_atm_nc(filename, ctl, atm);
 
  /* Read CLaMS data... */
  else if (ctl->atm_type == 3 || ctl->atm_type == 4)
    result = read_atm_clams(filename, ctl, atm);
 
  /* Error... */
  else
    ERRMSG("Atmospheric data type not supported!");
 
  /* Check result... */
  if (result != 1)
    return 0;
 
  /* Check number of air parcels... */
  if (atm->np < 1)
    ERRMSG("Can not read any data!");
 
  /* Write info... */
  double mini, maxi;
  LOG(2, "Number of particles: %d", atm->np);
  gsl_stats_minmax(&mini, &maxi, atm->time, 1, (size_t) atm->np);
  LOG(2, "Time range: %.2f ... %.2f s", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, atm->p, 1, (size_t) atm->np);
  LOG(2, "Altitude range: %g ... %g km", Z(maxi), Z(mini));
  LOG(2, "Pressure range: %g ... %g hPa", maxi, mini);
  gsl_stats_minmax(&mini, &maxi, atm->lon, 1, (size_t) atm->np);
  LOG(2, "Longitude range: %g ... %g deg", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, atm->lat, 1, (size_t) atm->np);
  LOG(2, "Latitude range: %g ... %g deg", mini, maxi);
  for (int iq = 0; iq < ctl->nq; iq++) {
    char msg[5 * LEN];
    sprintf(msg, "Quantity %s range: %s ... %s %s",
            ctl->qnt_name[iq], ctl->qnt_format[iq],
            ctl->qnt_format[iq], ctl->qnt_unit[iq]);
    gsl_stats_minmax(&mini, &maxi, atm->q[iq], 1, (size_t) atm->np);
    LOG(2, msg, mini, maxi);
  }
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
int read_atm_asc(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  /* Open file... */
  FILE *in;
  if (!(in = fopen(filename, "r"))) {
    WARN("Cannot open file!");
    return 0;
  }
 
  /* Read line... */
  char line[LEN];
  while (fgets(line, LEN, in)) {
 
    /* Read data... */
    char *tok;
    TOK(line, tok, "%lg", atm->time[atm->np]);
    TOK(NULL, tok, "%lg", atm->p[atm->np]);
    TOK(NULL, tok, "%lg", atm->lon[atm->np]);
    TOK(NULL, tok, "%lg", atm->lat[atm->np]);
    for (int iq = 0; iq < ctl->nq; iq++)
      TOK(NULL, tok, "%lg", atm->q[iq][atm->np]);
 
    /* Convert altitude to pressure... */
    atm->p[atm->np] = P(atm->p[atm->np]);
 
    /* Increment data point counter... */
    if ((++atm->np) > NP)
      ERRMSG("Too many data points!");
  }
 
  /* Close file... */
  fclose(in);
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
int read_atm_bin(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  /* Open file... */
  FILE *in;
  if (!(in = fopen(filename, "r")))
    return 0;
 
  /* Check version of binary data... */
  int version;
  FREAD(&version, int,
        1,
        in);
  if (version != 100)
    ERRMSG("Wrong version of binary data!");
 
  /* Read data... */
  FREAD(&atm->np, int,
        1,
        in);
  FREAD(atm->time, double,
          (size_t) atm->np,
        in);
  FREAD(atm->p, double,
          (size_t) atm->np,
        in);
  FREAD(atm->lon, double,
          (size_t) atm->np,
        in);
  FREAD(atm->lat, double,
          (size_t) atm->np,
        in);
  for (int iq = 0; iq < ctl->nq; iq++)
    FREAD(atm->q[iq], double,
            (size_t) atm->np,
          in);
 
  /* Read final flag... */
  int final;
  FREAD(&final, int,
        1,
        in);
  if (final != 999)
    ERRMSG("Error while reading binary data!");
 
  /* Close file... */
  fclose(in);
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
int read_atm_clams(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  int ncid, varid;
 
  /* Open file... */
  if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR)
    return 0;
 
  /* Get dimensions... */
  NC_INQ_DIM("NPARTS", &atm->np, 1, NP);
 
  /* Get time... */
  if (nc_inq_varid(ncid, "TIME_INIT", &varid) == NC_NOERR) {
    NC(nc_get_var_double(ncid, varid, atm->time));
  } else {
    WARN("TIME_INIT not found use time instead!");
    double time_init;
    NC_GET_DOUBLE("time", &time_init, 1);
    for (int ip = 0; ip < atm->np; ip++) {
      atm->time[ip] = time_init;
    }
  }
 
  /* Read zeta coordinate, pressure is optional... */
  if (ctl->advect_vert_coord == 1) {
    NC_GET_DOUBLE("ZETA", atm->q[ctl->qnt_zeta], 1);
    NC_GET_DOUBLE("PRESS", atm->p, 0);
  }
 
  /* Read pressure, zeta coordinate is optional... */
  else {
    if (nc_inq_varid(ncid, "PRESS_INIT", &varid) == NC_NOERR) {
      NC(nc_get_var_double(ncid, varid, atm->p));
    } else {
      WARN("PRESS_INIT not found use PRESS instead!");
      nc_inq_varid(ncid, "PRESS", &varid);
      NC(nc_get_var_double(ncid, varid, atm->p));
    }
  }
 
  /* Read longitude and latitude... */
  NC_GET_DOUBLE("LON", atm->lon, 1);
  NC_GET_DOUBLE("LAT", atm->lat, 1);
 
  /* Close file... */
  NC(nc_close(ncid));
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
int read_atm_nc(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  int ncid, varid;
 
  /* Open file... */
  if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR)
    return 0;
 
  /* Get dimensions... */
  NC_INQ_DIM("obs", &atm->np, 1, NP);
 
  /* Read geolocations... */
  NC_GET_DOUBLE("time", atm->time, 1);
  NC_GET_DOUBLE("press", atm->p, 1);
  NC_GET_DOUBLE("lon", atm->lon, 1);
  NC_GET_DOUBLE("lat", atm->lat, 1);
 
  /* Read variables... */
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_GET_DOUBLE(ctl->qnt_name[iq], atm->q[iq], 0);
 
  /* Close file... */
  NC(nc_close(ncid));
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
void read_clim(
  ctl_t * ctl,
  clim_t * clim) {
 
  /* Set timer... */
  SELECT_TIMER("READ_CLIM", "INPUT", NVTX_READ);
 
  /* Init tropopause climatology... */
  clim_tropo_init(clim);
 
  /* Read photolysis rates... */
  if (ctl->clim_photo[0] != '-')
    read_clim_photo(ctl->clim_photo, &clim->photo);
 
  /* Read HNO3 climatology... */
  if (ctl->clim_hno3_filename[0] != '-')
    read_clim_zm(ctl->clim_hno3_filename, "HNO3", &clim->hno3);
 
  /* Read OH climatology... */
  if (ctl->clim_oh_filename[0] != '-') {
    read_clim_zm(ctl->clim_oh_filename, "OH", &clim->oh);
    if (ctl->oh_chem_beta > 0)
      clim_oh_diurnal_correction(ctl, clim);
  }
 
  /* Read H2O2 climatology... */
  if (ctl->clim_h2o2_filename[0] != '-')
    read_clim_zm(ctl->clim_h2o2_filename, "H2O2", &clim->h2o2);
 
  /* Read HO2 climatology... */
  if (ctl->clim_ho2_filename[0] != '-')
    read_clim_zm(ctl->clim_ho2_filename, "HO2", &clim->ho2);
 
  /* Read O(1D) climatology... */
  if (ctl->clim_o1d_filename[0] != '-')
    read_clim_zm(ctl->clim_o1d_filename, "O1D", &clim->o1d);
 
  /* Read CFC-10 time series... */
  if (ctl->clim_ccl4_timeseries[0] != '-')
    read_clim_ts(ctl->clim_ccl4_timeseries, &clim->ccl4);
 
  /* Read CFC-11 time series... */
  if (ctl->clim_ccl3f_timeseries[0] != '-')
    read_clim_ts(ctl->clim_ccl3f_timeseries, &clim->ccl3f);
 
  /* Read CFC-12 time series... */
  if (ctl->clim_ccl2f2_timeseries[0] != '-')
    read_clim_ts(ctl->clim_ccl2f2_timeseries, &clim->ccl2f2);
 
  /* Read N2O time series... */
  if (ctl->clim_n2o_timeseries[0] != '-')
    read_clim_ts(ctl->clim_n2o_timeseries, &clim->n2o);
 
  /* Read SF6 time series... */
  if (ctl->clim_sf6_timeseries[0] != '-')
    read_clim_ts(ctl->clim_sf6_timeseries, &clim->sf6);
}
 
/*****************************************************************************/
 
void read_clim_photo(
  const char *filename,
  clim_photo_t * photo) {
 
  int ncid, varid, ip, is, io;
 
  double *help1, *help2, *help3, *help4;
 
  /* Write info... */
  LOG(1, "Read photolysis rates: %s", filename);
 
  /* Open netCDF file... */
  if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR) {
    WARN("Photolysis rate data are missing!");
    return;
  }
 
  /* Read pressure data... */
  NC_INQ_DIM("press", &photo->np, 2, CP);
  NC_GET_DOUBLE("press", photo->p, 1);
  if (photo->p[0] < photo->p[1])
    ERRMSG("Pressure data are not descending!");
 
  /* Read total column ozone data... */
  NC_INQ_DIM("total_o3col", &photo->no3c, 2, CO3);
  NC_GET_DOUBLE("total_o3col", photo->o3c, 1);
  if (photo->o3c[0] > photo->o3c[1])
    ERRMSG("Total column ozone data are not ascending!");
 
  /* Read solar zenith angle data... */
  NC_INQ_DIM("sza", &photo->nsza, 2, CSZA);
  NC_GET_DOUBLE("sza", photo->sza, 1);
  if (photo->sza[0] > photo->sza[1])
    ERRMSG("Solar zenith angle data are not ascending!");
 
  /* Read data... */
  ALLOC(help1, double,
        photo->np * photo->nsza * photo->no3c);
  ALLOC(help2, double,
        photo->np * photo->nsza * photo->no3c);
  ALLOC(help3, double,
        photo->np * photo->nsza * photo->no3c);
  ALLOC(help4, double,
        photo->np * photo->nsza * photo->no3c);
  NC_GET_DOUBLE("J_N2O", help1, 1);
  NC_GET_DOUBLE("J_CCl4", help2, 1);
  NC_GET_DOUBLE("J_CFC-11", help3, 1);
  NC_GET_DOUBLE("J_CFC-12", help4, 1);
  for (ip = 0; ip < photo->np; ip++)
    for (is = 0; is < photo->nsza; is++)
      for (io = 0; io < photo->no3c; io++) {
        photo->n2o[ip][is][io] =
          help1[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->ccl4[ip][is][io] =
          help2[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->ccl3f[ip][is][io] =
          help3[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->ccl2f2[ip][is][io] =
          help4[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
      }
 
  NC_GET_DOUBLE("J_O2", help1, 1);
  NC_GET_DOUBLE("J_O3b", help2, 1);
  NC_GET_DOUBLE("J_O3a", help3, 1);
  NC_GET_DOUBLE("J_H2O2", help4, 1);
  for (ip = 0; ip < photo->np; ip++)
    for (is = 0; is < photo->nsza; is++)
      for (io = 0; io < photo->no3c; io++) {
        photo->o2[ip][is][io] =
          help1[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->o3_1[ip][is][io] =
          help2[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->o3_2[ip][is][io] =
          help3[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
        photo->h2o2[ip][is][io] =
          help4[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
      }
  NC_GET_DOUBLE("J_H2O", help1, 1);
  for (ip = 0; ip < photo->np; ip++)
    for (is = 0; is < photo->nsza; is++)
      for (io = 0; io < photo->no3c; io++)
        photo->h2o[ip][is][io] =
          help1[ARRAY_3D(ip, is, photo->nsza, io, photo->no3c)];
  free(help1);
  free(help2);
  free(help3);
  free(help4);
 
  /* Close netCDF file... */
  NC(nc_close(ncid));
 
  /* Write info... */
  LOG(2, "Number of pressure levels: %d", photo->np);
  LOG(2, "Altitude levels: %g, %g ... %g km",
      Z(photo->p[0]), Z(photo->p[1]), Z(photo->p[photo->np - 1]));
  LOG(2, "Pressure levels: %g, %g ... %g hPa",
      photo->p[0], photo->p[1], photo->p[photo->np - 1]);
  LOG(2, "Number of solar zenith angles: %d", photo->nsza);
  LOG(2, "Solar zenith angles: %g, %g ... %g deg",
      photo->sza[0] * 180. / M_PI, photo->sza[1] * 180. / M_PI,
      photo->sza[photo->nsza - 1] * 180. / M_PI);
  LOG(2, "Number of total column ozone values: %d", photo->no3c);
  LOG(2, "Total column ozone: %g, %g ... %g DU",
      photo->o3c[0], photo->o3c[1], photo->o3c[photo->no3c - 1]);
  LOG(2, "N2O photolysis rate: %g, %g ... %g s**-1",
      photo->n2o[0][0][0], photo->n2o[1][0][0],
      photo->n2o[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "CCl4 photolysis rate: %g, %g ... %g s**-1",
      photo->ccl4[0][0][0], photo->ccl4[1][0][0],
      photo->ccl4[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "CFC-11 photolysis rate: %g, %g ... %g s**-1",
      photo->ccl3f[0][0][0], photo->ccl3f[1][0][0],
      photo->ccl3f[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "CFC-12 photolysis rate: %g, %g ... %g s**-1",
      photo->ccl2f2[0][0][0], photo->ccl2f2[1][0][0],
      photo->ccl2f2[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "O2 photolysis rate: %g, %g ... %g s**-1",
      photo->o2[0][0][0], photo->o2[1][0][0],
      photo->o2[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "O3 -> O(1D) photolysis rate: %g, %g ... %g s**-1",
      photo->o3_1[0][0][0], photo->o3_1[1][0][0],
      photo->o3_1[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "O3 -> O(3P) photolysis rate: %g, %g ... %g s**-1",
      photo->o3_2[0][0][0], photo->o3_2[1][0][0],
      photo->o3_2[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "H2O2 photolysis rate: %g, %g ... %g s**-1",
      photo->h2o2[0][0][0], photo->h2o2[1][0][0],
      photo->h2o2[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
  LOG(2, "H2O photolysis rate: %g, %g ... %g s**-1",
      photo->h2o[0][0][0], photo->h2o[1][0][0],
      photo->h2o[photo->np - 1][photo->nsza - 1][photo->no3c - 1]);
}
 
/*****************************************************************************/
 
int read_clim_ts(
  const char *filename,
  clim_ts_t * ts) {
 
  /* Write info... */
  LOG(1, "Read climatological time series: %s", filename);
 
  /* Open file... */
  FILE *in;
  if (!(in = fopen(filename, "r"))) {
    WARN("Cannot open file!");
    return 0;
  }
 
  /* Read data... */
  char line[LEN];
  int nh = 0;
  while (fgets(line, LEN, in))
    if (sscanf(line, "%lg %lg", &ts->time[nh], &ts->vmr[nh]) == 2) {
 
      /* Convert years to seconds... */
      ts->time[nh] = (ts->time[nh] - 2000.0) * 365.25 * 86400.;
 
      /* Check data... */
      if (nh > 0 && ts->time[nh] <= ts->time[nh - 1])
        ERRMSG("Time series must be ascending!");
 
      /* Count time steps... */
      if ((++nh) >= CTS)
        ERRMSG("Too many data points!");
    }
 
  /* Close file... */
  fclose(in);
 
  /* Check number of data points... */
  ts->ntime = nh;
  if (nh < 2)
    ERRMSG("Not enough data points!");
 
  /* Write info... */
  LOG(2, "Number of time steps: %d", ts->ntime);
  LOG(2, "Time steps: %.2f, %.2f ... %.2f s", ts->time[0], ts->time[1],
      ts->time[nh - 1]);
  LOG(2, "Volume mixing ratio range: %g ... %g ppv",
      gsl_stats_min(ts->vmr, 1, (size_t) nh), gsl_stats_max(ts->vmr, 1,
                                                            (size_t) nh));
 
  /* Exit success... */
  return 1;
}
 
/*****************************************************************************/
 
void read_clim_zm(
  const char *filename,
  char *varname,
  clim_zm_t * zm) {
 
  int ncid, varid, it, iy, iz, iz2, nt;
 
  double *help, varmin = 1e99, varmax = -1e99;
 
  /* Write info... */
  LOG(1, "Read %s data: %s", varname, filename);
 
  /* Open netCDF file... */
  if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR) {
    WARN("%s climatology data are missing!", varname);
    return;
  }
 
  /* Read pressure data... */
  NC_INQ_DIM("press", &zm->np, 2, CP);
  NC_GET_DOUBLE("press", zm->p, 1);
  if (zm->p[0] < zm->p[1])
    ERRMSG("Pressure data are not descending!");
 
  /* Read latitudes... */
  NC_INQ_DIM("lat", &zm->nlat, 2, CY);
  NC_GET_DOUBLE("lat", zm->lat, 1);
  if (zm->lat[0] > zm->lat[1])
    ERRMSG("Latitude data are not ascending!");
 
  /* Set time data (for monthly means)... */
  zm->ntime = 12;
  zm->time[0] = 1209600.00;
  zm->time[1] = 3888000.00;
  zm->time[2] = 6393600.00;
  zm->time[3] = 9072000.00;
  zm->time[4] = 11664000.00;
  zm->time[5] = 14342400.00;
  zm->time[6] = 16934400.00;
  zm->time[7] = 19612800.00;
  zm->time[8] = 22291200.00;
  zm->time[9] = 24883200.00;
  zm->time[10] = 27561600.00;
  zm->time[11] = 30153600.00;
 
  /* Check number of timesteps... */
  NC_INQ_DIM("time", &nt, 12, 12);
 
  /* Read data... */
  ALLOC(help, double,
        zm->nlat * zm->np * zm->ntime);
  NC_GET_DOUBLE(varname, help, 1);
  for (it = 0; it < zm->ntime; it++)
    for (iz = 0; iz < zm->np; iz++)
      for (iy = 0; iy < zm->nlat; iy++)
        zm->vmr[it][iz][iy] = help[ARRAY_3D(it, iz, zm->np, iy, zm->nlat)];
  free(help);
 
  /* Fix data gaps... */
  for (it = 0; it < zm->ntime; it++)
    for (iy = 0; iy < zm->nlat; iy++)
      for (iz = 0; iz < zm->np; iz++) {
        if (zm->vmr[it][iz][iy] < 0) {
          for (iz2 = 0; iz2 < zm->np; iz2++)
            if (zm->vmr[it][iz2][iy] >= 0) {
              zm->vmr[it][iz][iy] = zm->vmr[it][iz2][iy];
              break;
            }
          for (iz2 = zm->np - 1; iz2 >= 0; iz2--)
            if (zm->vmr[it][iz2][iy] >= 0) {
              zm->vmr[it][iz][iy] = zm->vmr[it][iz2][iy];
              break;
            }
        }
        varmin = MIN(varmin, zm->vmr[it][iz][iy]);
        varmax = MAX(varmax, zm->vmr[it][iz][iy]);
      }
 
  /* Close netCDF file... */
  NC(nc_close(ncid));
 
  /* Write info... */
  LOG(2, "Number of time steps: %d", zm->ntime);
  LOG(2, "Time steps: %.2f, %.2f ... %.2f s",
      zm->time[0], zm->time[1], zm->time[zm->ntime - 1]);
  LOG(2, "Number of pressure levels: %d", zm->np);
  LOG(2, "Altitude levels: %g, %g ... %g km",
      Z(zm->p[0]), Z(zm->p[1]), Z(zm->p[zm->np - 1]));
  LOG(2, "Pressure levels: %g, %g ... %g hPa", zm->p[0],
      zm->p[1], zm->p[zm->np - 1]);
  LOG(2, "Number of latitudes: %d", zm->nlat);
  LOG(2, "Latitudes: %g, %g ... %g deg",
      zm->lat[0], zm->lat[1], zm->lat[zm->nlat - 1]);
  LOG(2, "%s volume mixing ratio range: %g ... %g ppv", varname, varmin,
      varmax);
}
 
/*****************************************************************************/
 
void read_ctl(
  const char *filename,
  int argc,
  char *argv[],
  ctl_t * ctl) {
 
  /* Set timer... */
  SELECT_TIMER("READ_CTL", "INPUT", NVTX_READ);
 
  /* Write info... */
  LOG(1, "\nMassive-Parallel Trajectory Calculations (MPTRAC)\n"
      "(executable: %s | version: %s | compiled: %s, %s)\n",
      argv[0], VERSION, __DATE__, __TIME__);
 
  /* Initialize quantity indices... */
  ctl->qnt_idx = -1;
  ctl->qnt_ens = -1;
  ctl->qnt_stat = -1;
  ctl->qnt_m = -1;
  ctl->qnt_vmr = -1;
  ctl->qnt_rp = -1;
  ctl->qnt_rhop = -1;
  ctl->qnt_ps = -1;
  ctl->qnt_ts = -1;
  ctl->qnt_zs = -1;
  ctl->qnt_us = -1;
  ctl->qnt_vs = -1;
  ctl->qnt_lsm = -1;
  ctl->qnt_sst = -1;
  ctl->qnt_pbl = -1;
  ctl->qnt_pt = -1;
  ctl->qnt_tt = -1;
  ctl->qnt_zt = -1;
  ctl->qnt_h2ot = -1;
  ctl->qnt_zg = -1;
  ctl->qnt_p = -1;
  ctl->qnt_t = -1;
  ctl->qnt_rho = -1;
  ctl->qnt_u = -1;
  ctl->qnt_v = -1;
  ctl->qnt_w = -1;
  ctl->qnt_h2o = -1;
  ctl->qnt_o3 = -1;
  ctl->qnt_lwc = -1;
  ctl->qnt_rwc = -1;
  ctl->qnt_iwc = -1;
  ctl->qnt_swc = -1;
  ctl->qnt_cc = -1;
  ctl->qnt_pct = -1;
  ctl->qnt_pcb = -1;
  ctl->qnt_cl = -1;
  ctl->qnt_plcl = -1;
  ctl->qnt_plfc = -1;
  ctl->qnt_pel = -1;
  ctl->qnt_cape = -1;
  ctl->qnt_cin = -1;
  ctl->qnt_o3c = -1;
  ctl->qnt_hno3 = -1;
  ctl->qnt_oh = -1;
  ctl->qnt_h2o2 = -1;
  ctl->qnt_ho2 = -1;
  ctl->qnt_o1d = -1;
  ctl->qnt_mloss_oh = -1;
  ctl->qnt_mloss_h2o2 = -1;
  ctl->qnt_mloss_kpp = -1;
  ctl->qnt_mloss_wet = -1;
  ctl->qnt_mloss_dry = -1;
  ctl->qnt_mloss_decay = -1;
  ctl->qnt_loss_rate = -1;
  ctl->qnt_psat = -1;
  ctl->qnt_psice = -1;
  ctl->qnt_pw = -1;
  ctl->qnt_sh = -1;
  ctl->qnt_rh = -1;
  ctl->qnt_rhice = -1;
  ctl->qnt_theta = -1;
  ctl->qnt_zeta = -1;
  ctl->qnt_zeta_d = -1;
  ctl->qnt_tvirt = -1;
  ctl->qnt_lapse = -1;
  ctl->qnt_vh = -1;
  ctl->qnt_vz = -1;
  ctl->qnt_pv = -1;
  ctl->qnt_tdew = -1;
  ctl->qnt_tice = -1;
  ctl->qnt_tsts = -1;
  ctl->qnt_tnat = -1;
  ctl->qnt_Cx = -1;
  ctl->qnt_Ch2o = -1;
  ctl->qnt_Co3 = -1;
  ctl->qnt_Cco = -1;
  ctl->qnt_Coh = -1;
  ctl->qnt_Ch = -1;
  ctl->qnt_Cho2 = -1;
  ctl->qnt_Ch2o2 = -1;
  ctl->qnt_Co1d = -1;
  ctl->qnt_Co3p = -1;
  ctl->qnt_Cccl4 = -1;
  ctl->qnt_Cccl3f = -1;
  ctl->qnt_Cccl2f2 = -1;
  ctl->qnt_Cn2o = -1;
  ctl->qnt_Csf6 = -1;
  ctl->qnt_aoa = -1;
 
  /* Read quantities... */
  ctl->nq = (int) scan_ctl(filename, argc, argv, "NQ", -1, "0", NULL);
  if (ctl->nq > NQ)
    ERRMSG("Too many quantities!");
  for (int iq = 0; iq < ctl->nq; iq++) {
 
    /* Read quantity name and format... */
    scan_ctl(filename, argc, argv, "QNT_NAME", iq, "", ctl->qnt_name[iq]);
    scan_ctl(filename, argc, argv, "QNT_LONGNAME", iq, ctl->qnt_name[iq],
             ctl->qnt_longname[iq]);
    scan_ctl(filename, argc, argv, "QNT_FORMAT", iq, "%g",
             ctl->qnt_format[iq]);
    if (strcasecmp(ctl->qnt_name[iq], "aoa") == 0)
      sprintf(ctl->qnt_format[iq], "%%.2f");
 
    /* Try to identify quantity... */
    SET_QNT(qnt_idx, "idx", "particle index", "-")
      SET_QNT(qnt_ens, "ens", "ensemble index", "-")
      SET_QNT(qnt_stat, "stat", "station flag", "-")
      SET_QNT(qnt_m, "m", "mass", "kg")
      SET_QNT(qnt_vmr, "vmr", "volume mixing ratio", "ppv")
      SET_QNT(qnt_rp, "rp", "particle radius", "microns")
      SET_QNT(qnt_rhop, "rhop", "particle density", "kg/m^3")
      SET_QNT(qnt_ps, "ps", "surface pressure", "hPa")
      SET_QNT(qnt_ts, "ts", "surface temperature", "K")
      SET_QNT(qnt_zs, "zs", "surface height", "km")
      SET_QNT(qnt_us, "us", "surface zonal wind", "m/s")
      SET_QNT(qnt_vs, "vs", "surface meridional wind", "m/s")
      SET_QNT(qnt_lsm, "lsm", "land-sea mask", "1")
      SET_QNT(qnt_sst, "sst", "sea surface temperature", "K")
      SET_QNT(qnt_pbl, "pbl", "planetary boundary layer", "hPa")
      SET_QNT(qnt_pt, "pt", "tropopause pressure", "hPa")
      SET_QNT(qnt_tt, "tt", "tropopause temperature", "K")
      SET_QNT(qnt_zt, "zt", "tropopause geopotential height", "km")
      SET_QNT(qnt_h2ot, "h2ot", "tropopause water vapor", "ppv")
      SET_QNT(qnt_zg, "zg", "geopotential height", "km")
      SET_QNT(qnt_p, "p", "pressure", "hPa")
      SET_QNT(qnt_t, "t", "temperature", "K")
      SET_QNT(qnt_rho, "rho", "air density", "kg/m^3")
      SET_QNT(qnt_u, "u", "zonal wind", "m/s")
      SET_QNT(qnt_v, "v", "meridional wind", "m/s")
      SET_QNT(qnt_w, "w", "vertical velocity", "hPa/s")
      SET_QNT(qnt_h2o, "h2o", "water vapor", "ppv")
      SET_QNT(qnt_o3, "o3", "ozone", "ppv")
      SET_QNT(qnt_lwc, "lwc", "cloud liquid water content", "kg/kg")
      SET_QNT(qnt_rwc, "rwc", "cloud rain water content", "kg/kg")
      SET_QNT(qnt_iwc, "iwc", "cloud ice water content", "kg/kg")
      SET_QNT(qnt_swc, "iwc", "cloud snow water content", "kg/kg")
      SET_QNT(qnt_cc, "cc", "cloud cover", "1")
      SET_QNT(qnt_pct, "pct", "cloud top pressure", "hPa")
      SET_QNT(qnt_pcb, "pcb", "cloud bottom pressure", "hPa")
      SET_QNT(qnt_cl, "cl", "total column cloud water", "kg/m^2")
      SET_QNT(qnt_plcl, "plcl", "lifted condensation level", "hPa")
      SET_QNT(qnt_plfc, "plfc", "level of free convection", "hPa")
      SET_QNT(qnt_pel, "pel", "equilibrium level", "hPa")
      SET_QNT(qnt_cape, "cape", "convective available potential energy",
              "J/kg")
      SET_QNT(qnt_cin, "cin", "convective inhibition", "J/kg")
      SET_QNT(qnt_o3c, "o3c", "total column ozone", "DU")
      SET_QNT(qnt_hno3, "hno3", "nitric acid", "ppv")
      SET_QNT(qnt_oh, "oh", "hydroxyl radical", "ppv")
      SET_QNT(qnt_h2o2, "h2o2", "hydrogen peroxide", "ppv")
      SET_QNT(qnt_ho2, "ho2", "hydroperoxyl radical", "ppv")
      SET_QNT(qnt_o1d, "o1d", "atomic oxygen", "ppv")
      SET_QNT(qnt_mloss_oh, "mloss_oh", "mass loss due to OH chemistry", "kg")
      SET_QNT(qnt_mloss_h2o2, "mloss_h2o2", "mass loss due to H2O2 chemistry",
              "kg")
      SET_QNT(qnt_mloss_kpp, "mloss_kpp", "mass loss due to kpp chemistry",
              "kg")
      SET_QNT(qnt_mloss_wet, "mloss_wet", "mass loss due to wet deposition",
              "kg")
      SET_QNT(qnt_mloss_dry, "mloss_dry", "mass loss due to dry deposition",
              "kg")
      SET_QNT(qnt_mloss_decay, "mloss_decay",
              "mass loss due to exponential decay", "kg")
      SET_QNT(qnt_loss_rate, "loss_rate", "total loss rate", "s^-1")
      SET_QNT(qnt_psat, "psat", "saturation pressure over water", "hPa")
      SET_QNT(qnt_psice, "psice", "saturation pressure over ice", "hPa")
      SET_QNT(qnt_pw, "pw", "partial water vapor pressure", "hPa")
      SET_QNT(qnt_sh, "sh", "specific humidity", "kg/kg")
      SET_QNT(qnt_rh, "rh", "relative humidity", "%%")
      SET_QNT(qnt_rhice, "rhice", "relative humidity over ice", "%%")
      SET_QNT(qnt_theta, "theta", "potential temperature", "K")
      SET_QNT(qnt_zeta, "zeta", "zeta coordinate", "K")
      SET_QNT(qnt_zeta_d, "zeta_d", "diagnosed zeta coordinate", "K")
      SET_QNT(qnt_tvirt, "tvirt", "virtual temperature", "K")
      SET_QNT(qnt_lapse, "lapse", "temperature lapse rate", "K/km")
      SET_QNT(qnt_vh, "vh", "horizontal velocity", "m/s")
      SET_QNT(qnt_vz, "vz", "vertical velocity", "m/s")
      SET_QNT(qnt_pv, "pv", "potential vorticity", "PVU")
      SET_QNT(qnt_tdew, "tdew", "dew point temperature", "K")
      SET_QNT(qnt_tice, "tice", "frost point temperature", "K")
      SET_QNT(qnt_tsts, "tsts", "STS existence temperature", "K")
      SET_QNT(qnt_tnat, "tnat", "NAT existence temperature", "K")
      SET_QNT(qnt_Cx, "Cx", "Trace species x volume mixing ratio", "ppv")
      SET_QNT(qnt_Ch2o, "Ch2o", "H2O volume mixing ratio", "ppv")
      SET_QNT(qnt_Co3, "Co3", "O3 volume mixing ratio", "ppv")
      SET_QNT(qnt_Cco, "Cco", "CO volume mixing ratio", "ppv")
      SET_QNT(qnt_Coh, "Coh", "HO volume mixing ratio", "ppv")
      SET_QNT(qnt_Ch, "Ch", "H radical volume mixing ratio", "ppv")
      SET_QNT(qnt_Cho2, "Cho2", "HO2 volume mixing ratio", "ppv")
      SET_QNT(qnt_Ch2o2, "Ch2o2", "H2O2 volume mixing ratio", "ppv")
      SET_QNT(qnt_Co1d, "Co1d", "O(1D) volume mixing ratio", "ppv")
      SET_QNT(qnt_Co3p, "Co3p", "O(3P) radical volume mixing ratio", "ppv")
      SET_QNT(qnt_Cccl4, "Cccl4", "CCl4 (CFC-10) volume mixing ratio", "ppv")
      SET_QNT(qnt_Cccl3f, "Cccl3f", "CCl3F (CFC-11) volume mixing ratio",
              "ppv")
      SET_QNT(qnt_Cccl2f2, "Cccl2f2", "CCl2F2 (CFC-12) volume mixing ratio",
              "ppv")
      SET_QNT(qnt_Cn2o, "Cn2o", "N2O volume mixing ratio", "ppv")
      SET_QNT(qnt_Csf6, "Csf6", "SF6 volume mixing ratio", "ppv")
      SET_QNT(qnt_aoa, "aoa", "age of air", "s")
      scan_ctl(filename, argc, argv, "QNT_UNIT", iq, "", ctl->qnt_unit[iq]);
  }
 
  /* Vertical coordinates and velocities... */
  ctl->advect_vert_coord =
    (int) scan_ctl(filename, argc, argv, "ADVECT_VERT_COORD", -1, "0", NULL);
  if (ctl->advect_vert_coord < 0 || ctl->advect_vert_coord > 2)
    ERRMSG("Set advect_vert_coord to 0, 1, or 2!");
  if (ctl->advect_vert_coord == 1 && ctl->qnt_zeta < 0)
    ERRMSG("Please add zeta to your quantities for diabatic calculations!");
  ctl->met_vert_coord =
    (int) scan_ctl(filename, argc, argv, "MET_VERT_COORD", -1, "0", NULL);
  if (ctl->advect_vert_coord == 2 && ctl->met_vert_coord != 1)
    ERRMSG
      ("Using ADVECT_VERT_COORD = 2 requires meteo data on model levels!");
  ctl->met_clams =
    (int) scan_ctl(filename, argc, argv, "MET_CLAMS", -1, "0", NULL);
  ctl->advect_cpl_zeta_and_press_modules =
    (int) scan_ctl(filename, argc, argv, "ADVECT_ZETA_PRESS_MODULES", -1, "1",
                   NULL);
 
  /* Time steps of simulation... */
  ctl->direction =
    (int) scan_ctl(filename, argc, argv, "DIRECTION", -1, "1", NULL);
  if (ctl->direction != -1 && ctl->direction != 1)
    ERRMSG("Set DIRECTION to -1 or 1!");
  ctl->t_stop = scan_ctl(filename, argc, argv, "T_STOP", -1, "1e100", NULL);
  ctl->dt_mod = scan_ctl(filename, argc, argv, "DT_MOD", -1, "180", NULL);
 
  /* Meteo data... */
  scan_ctl(filename, argc, argv, "METBASE", -1, "-", ctl->metbase);
  ctl->dt_met = scan_ctl(filename, argc, argv, "DT_MET", -1, "3600", NULL);
  ctl->met_convention =
    (int) scan_ctl(filename, argc, argv, "MET_CONVENTION", -1, "0", NULL);
  ctl->met_type =
    (int) scan_ctl(filename, argc, argv, "MET_TYPE", -1, "0", NULL);
  if (ctl->advect_vert_coord == 1 && ctl->met_type != 0)
    ERRMSG
      ("Please use meteorological files in netcdf format for diabatic calculations.");
  ctl->met_nc_scale =
    (int) scan_ctl(filename, argc, argv, "MET_NC_SCALE", -1, "1", NULL);
  ctl->met_zfp_prec =
    (int) scan_ctl(filename, argc, argv, "MET_ZFP_PREC", -1, "8", NULL);
  ctl->met_zfp_tol_t =
    scan_ctl(filename, argc, argv, "MET_ZFP_TOL_T", -1, "5.0", NULL);
  ctl->met_zfp_tol_z =
    scan_ctl(filename, argc, argv, "MET_ZFP_TOL_Z", -1, "0.5", NULL);
  ctl->met_cms_heur =
    (int) scan_ctl(filename, argc, argv, "MET_CMS_HEUR", -1, "1", NULL);
  ctl->met_cms_eps_z =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_Z", -1, "1.0", NULL);
  ctl->met_cms_eps_t =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_T", -1, "0.05", NULL);
  ctl->met_cms_eps_u =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_U", -1, "0.05", NULL);
  ctl->met_cms_eps_v =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_V", -1, "0.05", NULL);
  ctl->met_cms_eps_w =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_W", -1, "1.0", NULL);
  ctl->met_cms_eps_pv =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_PV", -1, "1.0", NULL);
  ctl->met_cms_eps_h2o =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_H2O", -1, "1.0", NULL);
  ctl->met_cms_eps_o3 =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_O3", -1, "1.0", NULL);
  ctl->met_cms_eps_lwc =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_LWC", -1, "1.0", NULL);
  ctl->met_cms_eps_rwc =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_RWC", -1, "1.0", NULL);
  ctl->met_cms_eps_iwc =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_IWC", -1, "1.0", NULL);
  ctl->met_cms_eps_swc =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_SWC", -1, "1.0", NULL);
  ctl->met_cms_eps_cc =
    scan_ctl(filename, argc, argv, "MET_CMS_EPS_CC", -1, "1.0", NULL);
  ctl->met_dx = (int) scan_ctl(filename, argc, argv, "MET_DX", -1, "1", NULL);
  ctl->met_dy = (int) scan_ctl(filename, argc, argv, "MET_DY", -1, "1", NULL);
  ctl->met_dp = (int) scan_ctl(filename, argc, argv, "MET_DP", -1, "1", NULL);
  if (ctl->met_dx < 1 || ctl->met_dy < 1 || ctl->met_dp < 1)
    ERRMSG("MET_DX, MET_DY, and MET_DP need to be greater than zero!");
  ctl->met_sx = (int) scan_ctl(filename, argc, argv, "MET_SX", -1, "1", NULL);
  ctl->met_sy = (int) scan_ctl(filename, argc, argv, "MET_SY", -1, "1", NULL);
  ctl->met_sp = (int) scan_ctl(filename, argc, argv, "MET_SP", -1, "1", NULL);
  if (ctl->met_sx < 1 || ctl->met_sy < 1 || ctl->met_sp < 1)
    ERRMSG("MET_SX, MET_SY, and MET_SP need to be greater than zero!");
  ctl->met_detrend =
    scan_ctl(filename, argc, argv, "MET_DETREND", -1, "-999", NULL);
  ctl->met_np = (int) scan_ctl(filename, argc, argv, "MET_NP", -1, "0", NULL);
  if (ctl->met_np > EP)
    ERRMSG("Too many levels!");
  ctl->met_press_level_def =
    (int) scan_ctl(filename, argc, argv, "MET_PRESS_LEVEL_DEF", -1, "-1",
                   NULL);
  if (ctl->met_press_level_def >= 0) {
    level_definitions(ctl);
  } else {
    if (ctl->met_np > 0) {
      for (int ip = 0; ip < ctl->met_np; ip++)
        ctl->met_p[ip] =
          scan_ctl(filename, argc, argv, "MET_P", ip, "", NULL);
    }
  }
  ctl->met_geopot_sx
    = (int) scan_ctl(filename, argc, argv, "MET_GEOPOT_SX", -1, "-1", NULL);
  ctl->met_geopot_sy
    = (int) scan_ctl(filename, argc, argv, "MET_GEOPOT_SY", -1, "-1", NULL);
  ctl->met_relhum
    = (int) scan_ctl(filename, argc, argv, "MET_RELHUM", -1, "0", NULL);
  ctl->met_tropo =
    (int) scan_ctl(filename, argc, argv, "MET_TROPO", -1, "3", NULL);
  if (ctl->met_tropo < 0 || ctl->met_tropo > 5)
    ERRMSG("Set MET_TROPO = 0 ... 5!");
  ctl->met_tropo_pv =
    scan_ctl(filename, argc, argv, "MET_TROPO_PV", -1, "3.5", NULL);
  ctl->met_tropo_theta =
    scan_ctl(filename, argc, argv, "MET_TROPO_THETA", -1, "380", NULL);
  ctl->met_tropo_spline =
    (int) scan_ctl(filename, argc, argv, "MET_TROPO_SPLINE", -1, "1", NULL);
  ctl->met_dt_out =
    scan_ctl(filename, argc, argv, "MET_DT_OUT", -1, "0.1", NULL);
  ctl->met_cache =
    (int) scan_ctl(filename, argc, argv, "MET_CACHE", -1, "0", NULL);
  ctl->met_mpi_share =
    (int) scan_ctl(filename, argc, argv, "MET_MPI_SHARE", -1, "0", NULL);
 
  /* Sorting... */
  ctl->sort_dt = scan_ctl(filename, argc, argv, "SORT_DT", -1, "-999", NULL);
 
  /* Isosurface parameters... */
  ctl->isosurf =
    (int) scan_ctl(filename, argc, argv, "ISOSURF", -1, "0", NULL);
  scan_ctl(filename, argc, argv, "BALLOON", -1, "-", ctl->balloon);
 
  /* Random number generator... */
  ctl->rng_type =
    (int) scan_ctl(filename, argc, argv, "RNG_TYPE", -1, "0", NULL);
  if (ctl->rng_type < 0 || ctl->rng_type > 2)
    ERRMSG("Set RNG_TYPE to 0, 1, or 2!");
 
  /* Advection parameters... */
  ctl->advect = (int) scan_ctl(filename, argc, argv, "ADVECT", -1, "2", NULL);
  if (!(ctl->advect == 0 || ctl->advect == 1
        || ctl->advect == 2 || ctl->advect == 4))
    ERRMSG("Set ADVECT to 0, 1, 2, or 4!");
  ctl->reflect =
    (int) scan_ctl(filename, argc, argv, "REFLECT", -1, "0", NULL);
 
  /* Diffusion parameters... */
  ctl->turb_dx_trop =
    scan_ctl(filename, argc, argv, "TURB_DX_TROP", -1, "50", NULL);
  ctl->turb_dx_strat =
    scan_ctl(filename, argc, argv, "TURB_DX_STRAT", -1, "0", NULL);
  ctl->turb_dz_trop =
    scan_ctl(filename, argc, argv, "TURB_DZ_TROP", -1, "0", NULL);
  ctl->turb_dz_strat =
    scan_ctl(filename, argc, argv, "TURB_DZ_STRAT", -1, "0.1", NULL);
  ctl->turb_mesox =
    scan_ctl(filename, argc, argv, "TURB_MESOX", -1, "0.16", NULL);
  ctl->turb_mesoz =
    scan_ctl(filename, argc, argv, "TURB_MESOZ", -1, "0.16", NULL);
 
  /* Convection... */
  ctl->conv_cape
    = scan_ctl(filename, argc, argv, "CONV_CAPE", -1, "-999", NULL);
  ctl->conv_cin
    = scan_ctl(filename, argc, argv, "CONV_CIN", -1, "-999", NULL);
  ctl->conv_dt = scan_ctl(filename, argc, argv, "CONV_DT", -1, "-999", NULL);
  ctl->conv_mix_bot
    = (int) scan_ctl(filename, argc, argv, "CONV_MIX_BOT", -1, "1", NULL);
  ctl->conv_mix_top
    = (int) scan_ctl(filename, argc, argv, "CONV_MIX_TOP", -1, "1", NULL);
 
  /* Boundary conditions... */
  ctl->bound_mass =
    scan_ctl(filename, argc, argv, "BOUND_MASS", -1, "-999", NULL);
  ctl->bound_mass_trend =
    scan_ctl(filename, argc, argv, "BOUND_MASS_TREND", -1, "0", NULL);
  ctl->bound_vmr =
    scan_ctl(filename, argc, argv, "BOUND_VMR", -1, "-999", NULL);
  ctl->bound_vmr_trend =
    scan_ctl(filename, argc, argv, "BOUND_VMR_TREND", -1, "0", NULL);
  ctl->bound_lat0 =
    scan_ctl(filename, argc, argv, "BOUND_LAT0", -1, "-999", NULL);
  ctl->bound_lat1 =
    scan_ctl(filename, argc, argv, "BOUND_LAT1", -1, "-999", NULL);
  ctl->bound_p0 =
    scan_ctl(filename, argc, argv, "BOUND_P0", -1, "-999", NULL);
  ctl->bound_p1 =
    scan_ctl(filename, argc, argv, "BOUND_P1", -1, "-999", NULL);
  ctl->bound_dps =
    scan_ctl(filename, argc, argv, "BOUND_DPS", -1, "-999", NULL);
  ctl->bound_dzs =
    scan_ctl(filename, argc, argv, "BOUND_DZS", -1, "-999", NULL);
  ctl->bound_zetas =
    scan_ctl(filename, argc, argv, "BOUND_ZETAS", -1, "-999", NULL);
  ctl->bound_pbl =
    (int) scan_ctl(filename, argc, argv, "BOUND_PBL", -1, "0", NULL);
 
  /* Species parameters... */
  scan_ctl(filename, argc, argv, "SPECIES", -1, "-", ctl->species);
  if (strcasecmp(ctl->species, "CF2Cl2") == 0) {
    ctl->molmass = 120.907;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 3e-5;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 3500.0;
  } else if (strcasecmp(ctl->species, "CFCl3") == 0) {
    ctl->molmass = 137.359;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1.1e-4;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 3300.0;
  } else if (strcasecmp(ctl->species, "CH4") == 0) {
    ctl->molmass = 16.043;
    ctl->oh_chem_reaction = 2;
    ctl->oh_chem[0] = 2.45e-12;
    ctl->oh_chem[1] = 1775;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1.4e-5;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 1600.0;
  } else if (strcasecmp(ctl->species, "CO") == 0) {
    ctl->molmass = 28.01;
    ctl->oh_chem_reaction = 3;
    ctl->oh_chem[0] = 6.9e-33;
    ctl->oh_chem[1] = 2.1;
    ctl->oh_chem[2] = 1.1e-12;
    ctl->oh_chem[3] = -1.3;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 9.7e-6;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 1300.0;
  } else if (strcasecmp(ctl->species, "CO2") == 0) {
    ctl->molmass = 44.009;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 3.3e-4;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 2400.0;
  } else if (strcasecmp(ctl->species, "H2O") == 0) {
    ctl->molmass = 18.01528;
  } else if (strcasecmp(ctl->species, "N2O") == 0) {
    ctl->molmass = 44.013;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 2.4e-4;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 2600.;
  } else if (strcasecmp(ctl->species, "NH3") == 0) {
    ctl->molmass = 17.031;
    ctl->oh_chem_reaction = 2;
    ctl->oh_chem[0] = 1.7e-12;
    ctl->oh_chem[1] = 710;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 5.9e-1;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 4200.0;
  } else if (strcasecmp(ctl->species, "HNO3") == 0) {
    ctl->molmass = 63.012;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 2.1e3;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 8700.0;
  } else if (strcasecmp(ctl->species, "NO") == 0) {
    ctl->molmass = 30.006;
    ctl->oh_chem_reaction = 3;
    ctl->oh_chem[0] = 7.1e-31;
    ctl->oh_chem[1] = 2.6;
    ctl->oh_chem[2] = 3.6e-11;
    ctl->oh_chem[3] = 0.1;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1.9e-5;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 1600.0;
  } else if (strcasecmp(ctl->species, "NO2") == 0) {
    ctl->molmass = 46.005;
    ctl->oh_chem_reaction = 3;
    ctl->oh_chem[0] = 1.8e-30;
    ctl->oh_chem[1] = 3.0;
    ctl->oh_chem[2] = 2.8e-11;
    ctl->oh_chem[3] = 0.0;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1.2e-4;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 2400.0;
  } else if (strcasecmp(ctl->species, "O3") == 0) {
    ctl->molmass = 47.997;
    ctl->oh_chem_reaction = 2;
    ctl->oh_chem[0] = 1.7e-12;
    ctl->oh_chem[1] = 940;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1e-4;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 2800.0;
  } else if (strcasecmp(ctl->species, "SF6") == 0) {
    ctl->molmass = 146.048;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 2.4e-6;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 3100.0;
  } else if (strcasecmp(ctl->species, "SO2") == 0) {
    ctl->molmass = 64.066;
    ctl->oh_chem_reaction = 3;
    ctl->oh_chem[0] = 2.9e-31;
    ctl->oh_chem[1] = 4.1;
    ctl->oh_chem[2] = 1.7e-12;
    ctl->oh_chem[3] = -0.2;
    ctl->wet_depo_ic_h[0] = ctl->wet_depo_bc_h[0] = 1.3e-2;
    ctl->wet_depo_ic_h[1] = ctl->wet_depo_bc_h[1] = 2900.0;
  }
 
  /* Molar mass... */
  char defstr[LEN];
  sprintf(defstr, "%g", ctl->molmass);
  ctl->molmass = scan_ctl(filename, argc, argv, "MOLMASS", -1, defstr, NULL);
 
  /* OH chemistry... */
  sprintf(defstr, "%d", ctl->oh_chem_reaction);
  ctl->oh_chem_reaction =
    (int) scan_ctl(filename, argc, argv, "OH_CHEM_REACTION", -1, defstr,
                   NULL);
  for (int ip = 0; ip < 4; ip++) {
    sprintf(defstr, "%g", ctl->oh_chem[ip]);
    ctl->oh_chem[ip] =
      scan_ctl(filename, argc, argv, "OH_CHEM", ip, defstr, NULL);
  }
  ctl->oh_chem_beta =
    scan_ctl(filename, argc, argv, "OH_CHEM_BETA", -1, "0", NULL);
 
  /* H2O2 chemistry... */
  ctl->h2o2_chem_reaction =
    (int) scan_ctl(filename, argc, argv, "H2O2_CHEM_REACTION", -1, "0", NULL);
 
  /* KPP chemistry... */
  ctl->kpp_chem =
    (int) scan_ctl(filename, argc, argv, "KPP_CHEM", -1, "0", NULL);
  ctl->dt_kpp = scan_ctl(filename, argc, argv, "DT_KPP", -1, "1800", NULL);
 
  /* First order tracer chemistry... */
  ctl->tracer_chem =
    (int) scan_ctl(filename, argc, argv, "TRACER_CHEM", -1, "0", NULL);
 
  /* Wet deposition... */
  for (int ip = 0; ip < 3; ip++) {
    sprintf(defstr, "%g", ctl->wet_depo_ic_h[ip]);
    ctl->wet_depo_ic_h[ip] =
      scan_ctl(filename, argc, argv, "WET_DEPO_IC_H", ip, defstr, NULL);
  }
  for (int ip = 0; ip < 1; ip++) {
    sprintf(defstr, "%g", ctl->wet_depo_bc_h[ip]);
    ctl->wet_depo_bc_h[ip] =
      scan_ctl(filename, argc, argv, "WET_DEPO_BC_H", ip, defstr, NULL);
  }
  ctl->wet_depo_ic_a =
    scan_ctl(filename, argc, argv, "WET_DEPO_IC_A", -1, "0", NULL);
  ctl->wet_depo_ic_b =
    scan_ctl(filename, argc, argv, "WET_DEPO_IC_B", -1, "0", NULL);
  ctl->wet_depo_bc_a =
    scan_ctl(filename, argc, argv, "WET_DEPO_BC_A", -1, "0", NULL);
  ctl->wet_depo_bc_b =
    scan_ctl(filename, argc, argv, "WET_DEPO_BC_B", -1, "0", NULL);
  ctl->wet_depo_pre[0] =
    scan_ctl(filename, argc, argv, "WET_DEPO_PRE", 0, "0.5", NULL);
  ctl->wet_depo_pre[1] =
    scan_ctl(filename, argc, argv, "WET_DEPO_PRE", 1, "0.36", NULL);
  ctl->wet_depo_ic_ret_ratio =
    scan_ctl(filename, argc, argv, "WET_DEPO_IC_RET_RATIO", -1, "1", NULL);
  ctl->wet_depo_bc_ret_ratio =
    scan_ctl(filename, argc, argv, "WET_DEPO_BC_RET_RATIO", -1, "1", NULL);
 
  /* Dry deposition... */
  ctl->dry_depo_vdep =
    scan_ctl(filename, argc, argv, "DRY_DEPO_VDEP", -1, "0", NULL);
  ctl->dry_depo_dp =
    scan_ctl(filename, argc, argv, "DRY_DEPO_DP", -1, "30", NULL);
 
  /* Climatological data... */
  scan_ctl(filename, argc, argv, "CLIM_PHOTO", -1,
           "../../data/clams_photolysis_rates.nc", ctl->clim_photo);
  scan_ctl(filename, argc, argv, "CLIM_HNO3_FILENAME", -1,
           "../../data/gozcards_HNO3.nc", ctl->clim_hno3_filename);
  scan_ctl(filename, argc, argv, "CLIM_OH_FILENAME", -1,
           "../../data/clams_radical_species_vmr.nc", ctl->clim_oh_filename);
  scan_ctl(filename, argc, argv, "CLIM_H2O2_FILENAME", -1,
           "../../data/cams_H2O2.nc", ctl->clim_h2o2_filename);
  scan_ctl(filename, argc, argv, "CLIM_HO2_FILENAME", -1,
           "../../data/clams_radical_species_vmr.nc", ctl->clim_ho2_filename);
  scan_ctl(filename, argc, argv, "CLIM_O1D_FILENAME", -1,
           "../../data/clams_radical_species_vmr.nc", ctl->clim_o1d_filename);
  scan_ctl(filename, argc, argv, "CLIM_CCL4_TIMESERIES", -1,
           "../../data/noaa_gml_ccl4.tab", ctl->clim_ccl4_timeseries);
  scan_ctl(filename, argc, argv, "CLIM_CCL3F_TIMESERIES", -1,
           "../../data/noaa_gml_cfc11.tab", ctl->clim_ccl3f_timeseries);
  scan_ctl(filename, argc, argv, "CLIM_CCL2F2_TIMESERIES", -1,
           "../../data/noaa_gml_cfc12.tab", ctl->clim_ccl2f2_timeseries);
  scan_ctl(filename, argc, argv, "CLIM_N2O_TIMESERIES", -1,
           "../../data/noaa_gml_n2o.tab", ctl->clim_n2o_timeseries);
  scan_ctl(filename, argc, argv, "CLIM_SF6_TIMESERIES", -1,
           "../../data/noaa_gml_sf6.tab", ctl->clim_sf6_timeseries);
 
  /* Mixing... */
  ctl->mixing_dt =
    scan_ctl(filename, argc, argv, "MIXING_DT", -1, "3600.", NULL);
  ctl->mixing_trop =
    scan_ctl(filename, argc, argv, "MIXING_TROP", -1, "-999", NULL);
  ctl->mixing_strat =
    scan_ctl(filename, argc, argv, "MIXING_STRAT", -1, "-999", NULL);
  ctl->mixing_z0 =
    scan_ctl(filename, argc, argv, "MIXING_Z0", -1, "-5", NULL);
  ctl->mixing_z1 =
    scan_ctl(filename, argc, argv, "MIXING_Z1", -1, "85", NULL);
  ctl->mixing_nz =
    (int) scan_ctl(filename, argc, argv, "MIXING_NZ", -1, "90", NULL);
  ctl->mixing_lon0 =
    scan_ctl(filename, argc, argv, "MIXING_LON0", -1, "-180", NULL);
  ctl->mixing_lon1 =
    scan_ctl(filename, argc, argv, "MIXING_LON1", -1, "180", NULL);
  ctl->mixing_nx =
    (int) scan_ctl(filename, argc, argv, "MIXING_NX", -1, "360", NULL);
  ctl->mixing_lat0 =
    scan_ctl(filename, argc, argv, "MIXING_LAT0", -1, "-90", NULL);
  ctl->mixing_lat1 =
    scan_ctl(filename, argc, argv, "MIXING_LAT1", -1, "90", NULL);
  ctl->mixing_ny =
    (int) scan_ctl(filename, argc, argv, "MIXING_NY", -1, "180", NULL);
 
  /* Chemistry grid... */
  ctl->chemgrid_z0 =
    scan_ctl(filename, argc, argv, "CHEMGRID_Z0", -1, "-5", NULL);
  ctl->chemgrid_z1 =
    scan_ctl(filename, argc, argv, "CHEMGRID_Z1", -1, "85", NULL);
  ctl->chemgrid_nz =
    (int) scan_ctl(filename, argc, argv, "CHEMGRID_NZ", -1, "90", NULL);
  ctl->chemgrid_lon0 =
    scan_ctl(filename, argc, argv, "CHEMGRID_LON0", -1, "-180", NULL);
  ctl->chemgrid_lon1 =
    scan_ctl(filename, argc, argv, "CHEMGRID_LON1", -1, "180", NULL);
  ctl->chemgrid_nx =
    (int) scan_ctl(filename, argc, argv, "CHEMGRID_NX", -1, "360", NULL);
  ctl->chemgrid_lat0 =
    scan_ctl(filename, argc, argv, "CHEMGRID_LAT0", -1, "-90", NULL);
  ctl->chemgrid_lat1 =
    scan_ctl(filename, argc, argv, "CHEMGRID_LAT1", -1, "90", NULL);
  ctl->chemgrid_ny =
    (int) scan_ctl(filename, argc, argv, "CHEMGRID_NY", -1, "180", NULL);
 
  /* Exponential decay... */
  ctl->tdec_trop = scan_ctl(filename, argc, argv, "TDEC_TROP", -1, "0", NULL);
  ctl->tdec_strat
    = scan_ctl(filename, argc, argv, "TDEC_STRAT", -1, "0", NULL);
 
  /* PSC analysis... */
  ctl->psc_h2o = scan_ctl(filename, argc, argv, "PSC_H2O", -1, "4e-6", NULL);
  ctl->psc_hno3 =
    scan_ctl(filename, argc, argv, "PSC_HNO3", -1, "9e-9", NULL);
 
  /* Output of atmospheric data... */
  scan_ctl(filename, argc, argv, "ATM_BASENAME", -1, "-", ctl->atm_basename);
  scan_ctl(filename, argc, argv, "ATM_GPFILE", -1, "-", ctl->atm_gpfile);
  ctl->atm_dt_out =
    scan_ctl(filename, argc, argv, "ATM_DT_OUT", -1, "86400", NULL);
  ctl->atm_filter =
    (int) scan_ctl(filename, argc, argv, "ATM_FILTER", -1, "0", NULL);
  ctl->atm_stride =
    (int) scan_ctl(filename, argc, argv, "ATM_STRIDE", -1, "1", NULL);
  ctl->atm_type =
    (int) scan_ctl(filename, argc, argv, "ATM_TYPE", -1, "0", NULL);
  ctl->atm_type_out =
    (int) scan_ctl(filename, argc, argv, "ATM_TYPE_OUT", -1, "-1", NULL);
  if (ctl->atm_type_out == -1)
    ctl->atm_type_out = ctl->atm_type;
  ctl->obs_type =
    (int) scan_ctl(filename, argc, argv, "OBS_TYPE", -1, "0", NULL);
 
  /* Output of CSI data... */
  scan_ctl(filename, argc, argv, "CSI_BASENAME", -1, "-", ctl->csi_basename);
  scan_ctl(filename, argc, argv, "CSI_KERNEL", -1, "-", ctl->csi_kernel);
  ctl->csi_dt_out =
    scan_ctl(filename, argc, argv, "CSI_DT_OUT", -1, "86400", NULL);
  scan_ctl(filename, argc, argv, "CSI_OBSFILE", -1, "-", ctl->csi_obsfile);
  ctl->csi_obsmin =
    scan_ctl(filename, argc, argv, "CSI_OBSMIN", -1, "0", NULL);
  ctl->csi_modmin =
    scan_ctl(filename, argc, argv, "CSI_MODMIN", -1, "0", NULL);
  ctl->csi_z0 = scan_ctl(filename, argc, argv, "CSI_Z0", -1, "-5", NULL);
  ctl->csi_z1 = scan_ctl(filename, argc, argv, "CSI_Z1", -1, "85", NULL);
  ctl->csi_nz = (int) scan_ctl(filename, argc, argv, "CSI_NZ", -1, "1", NULL);
  ctl->csi_lon0 =
    scan_ctl(filename, argc, argv, "CSI_LON0", -1, "-180", NULL);
  ctl->csi_lon1 = scan_ctl(filename, argc, argv, "CSI_LON1", -1, "180", NULL);
  ctl->csi_nx =
    (int) scan_ctl(filename, argc, argv, "CSI_NX", -1, "360", NULL);
  ctl->csi_lat0 = scan_ctl(filename, argc, argv, "CSI_LAT0", -1, "-90", NULL);
  ctl->csi_lat1 = scan_ctl(filename, argc, argv, "CSI_LAT1", -1, "90", NULL);
  ctl->csi_ny =
    (int) scan_ctl(filename, argc, argv, "CSI_NY", -1, "180", NULL);
 
  /* Output of ensemble data... */
  scan_ctl(filename, argc, argv, "ENS_BASENAME", -1, "-", ctl->ens_basename);
  ctl->ens_dt_out =
    scan_ctl(filename, argc, argv, "ENS_DT_OUT", -1, "86400", NULL);
 
  /* Output of grid data... */
  scan_ctl(filename, argc, argv, "GRID_BASENAME", -1, "-",
           ctl->grid_basename);
  scan_ctl(filename, argc, argv, "GRID_KERNEL", -1, "-", ctl->grid_kernel);
  scan_ctl(filename, argc, argv, "GRID_GPFILE", -1, "-", ctl->grid_gpfile);
  ctl->grid_dt_out =
    scan_ctl(filename, argc, argv, "GRID_DT_OUT", -1, "86400", NULL);
  ctl->grid_sparse =
    (int) scan_ctl(filename, argc, argv, "GRID_SPARSE", -1, "0", NULL);
  ctl->grid_stddev =
    (int) scan_ctl(filename, argc, argv, "GRID_STDDEV", -1, "0", NULL);
  ctl->grid_z0 = scan_ctl(filename, argc, argv, "GRID_Z0", -1, "-5", NULL);
  ctl->grid_z1 = scan_ctl(filename, argc, argv, "GRID_Z1", -1, "85", NULL);
  ctl->grid_nz =
    (int) scan_ctl(filename, argc, argv, "GRID_NZ", -1, "1", NULL);
  ctl->grid_lon0 =
    scan_ctl(filename, argc, argv, "GRID_LON0", -1, "-180", NULL);
  ctl->grid_lon1 =
    scan_ctl(filename, argc, argv, "GRID_LON1", -1, "180", NULL);
  ctl->grid_nx =
    (int) scan_ctl(filename, argc, argv, "GRID_NX", -1, "360", NULL);
  ctl->grid_lat0 =
    scan_ctl(filename, argc, argv, "GRID_LAT0", -1, "-90", NULL);
  ctl->grid_lat1 =
    scan_ctl(filename, argc, argv, "GRID_LAT1", -1, "90", NULL);
  ctl->grid_ny =
    (int) scan_ctl(filename, argc, argv, "GRID_NY", -1, "180", NULL);
  ctl->grid_type =
    (int) scan_ctl(filename, argc, argv, "GRID_TYPE", -1, "0", NULL);
 
  /* Output of profile data... */
  scan_ctl(filename, argc, argv, "PROF_BASENAME", -1, "-",
           ctl->prof_basename);
  scan_ctl(filename, argc, argv, "PROF_OBSFILE", -1, "-", ctl->prof_obsfile);
  ctl->prof_z0 = scan_ctl(filename, argc, argv, "PROF_Z0", -1, "0", NULL);
  ctl->prof_z1 = scan_ctl(filename, argc, argv, "PROF_Z1", -1, "60", NULL);
  ctl->prof_nz =
    (int) scan_ctl(filename, argc, argv, "PROF_NZ", -1, "60", NULL);
  ctl->prof_lon0 =
    scan_ctl(filename, argc, argv, "PROF_LON0", -1, "-180", NULL);
  ctl->prof_lon1 =
    scan_ctl(filename, argc, argv, "PROF_LON1", -1, "180", NULL);
  ctl->prof_nx =
    (int) scan_ctl(filename, argc, argv, "PROF_NX", -1, "360", NULL);
  ctl->prof_lat0 =
    scan_ctl(filename, argc, argv, "PROF_LAT0", -1, "-90", NULL);
  ctl->prof_lat1 =
    scan_ctl(filename, argc, argv, "PROF_LAT1", -1, "90", NULL);
  ctl->prof_ny =
    (int) scan_ctl(filename, argc, argv, "PROF_NY", -1, "180", NULL);
 
  /* Output of sample data... */
  scan_ctl(filename, argc, argv, "SAMPLE_BASENAME", -1, "-",
           ctl->sample_basename);
  scan_ctl(filename, argc, argv, "SAMPLE_KERNEL", -1, "-",
           ctl->sample_kernel);
  scan_ctl(filename, argc, argv, "SAMPLE_OBSFILE", -1, "-",
           ctl->sample_obsfile);
  ctl->sample_dx =
    scan_ctl(filename, argc, argv, "SAMPLE_DX", -1, "50", NULL);
  ctl->sample_dz =
    scan_ctl(filename, argc, argv, "SAMPLE_DZ", -1, "-999", NULL);
 
  /* Output of station data... */
  scan_ctl(filename, argc, argv, "STAT_BASENAME", -1, "-",
           ctl->stat_basename);
  ctl->stat_lon = scan_ctl(filename, argc, argv, "STAT_LON", -1, "0", NULL);
  ctl->stat_lat = scan_ctl(filename, argc, argv, "STAT_LAT", -1, "0", NULL);
  ctl->stat_r = scan_ctl(filename, argc, argv, "STAT_R", -1, "50", NULL);
  ctl->stat_t0 =
    scan_ctl(filename, argc, argv, "STAT_T0", -1, "-1e100", NULL);
  ctl->stat_t1 = scan_ctl(filename, argc, argv, "STAT_T1", -1, "1e100", NULL);
 
  /* Output of VTK data... */
  scan_ctl(filename, argc, argv, "VTK_BASENAME", -1, "-", ctl->vtk_basename);
  ctl->vtk_dt_out =
    scan_ctl(filename, argc, argv, "VTK_DT_OUT", -1, "86400", NULL);
  ctl->vtk_stride =
    (int) scan_ctl(filename, argc, argv, "VTK_STRIDE", -1, "1", NULL);
  ctl->vtk_scale =
    scan_ctl(filename, argc, argv, "VTK_SCALE", -1, "1.0", NULL);
  ctl->vtk_offset =
    scan_ctl(filename, argc, argv, "VTK_OFFSET", -1, "0.0", NULL);
  ctl->vtk_sphere =
    (int) scan_ctl(filename, argc, argv, "VTK_SPHERE", -1, "0", NULL);
}
 
/*****************************************************************************/
 
void read_kernel(
  const char *filename,
  double kz[EP],
  double kw[EP],
  int *nk) {
 
  /* Write info... */
  LOG(1, "Read kernel function: %s", filename);
 
  /* Open file... */
  FILE *in;
  if (!(in = fopen(filename, "r")))
    ERRMSG("Cannot open file!");
 
  /* Read data... */
  char line[LEN];
  int n = 0;
  while (fgets(line, LEN, in))
    if (sscanf(line, "%lg %lg", &kz[n], &kw[n]) == 2) {
      if (n > 0 && kz[n] < kz[n - 1])
        ERRMSG("Height levels must be ascending!");
      if ((++n) >= EP)
        ERRMSG("Too many height levels!");
    }
 
  /* Close file... */
  fclose(in);
 
  /* Check number of data points... */
  *nk = n;
  if (n < 2)
    ERRMSG("Not enough height levels!");
 
  /* Normalize kernel function... */
  double kmax = gsl_stats_max(kw, 1, (size_t) n);
  for (int iz = 0; iz < n; iz++)
    kw[iz] /= kmax;
}
 
/*****************************************************************************/
 
int read_met(
  const char *filename,
  ctl_t * ctl,
  clim_t * clim,
  met_t * met) {
 
  /* Write info... */
  LOG(1, "Read meteo data: %s", filename);
 
  /* Initialize rank... */
  int rank = 0;
#ifdef MPI
  if (ctl->met_mpi_share)
    MPI_Comm_rank(MPI_COMM_WORLD, &rank);
#endif
 
  /* Read netCDF data... */
  if (!ctl->met_mpi_share || rank == 0) {
    if (ctl->met_type == 0) {
 
      int ncid;
 
      /* Open netCDF file... */
      if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR) {
        WARN("Cannot open file!");
        return 0;
      }
 
      /* Read coordinates of meteo data... */
      read_met_grid(filename, ncid, ctl, met);
 
      /* Read meteo data on vertical levels... */
      read_met_levels(ncid, ctl, met);
 
      /* Extrapolate data for lower boundary... */
      read_met_extrapolate(met);
 
      /* Read surface data... */
      read_met_surface(ncid, met, ctl);
 
      /* Fix polar winds... */
      read_met_polar_winds(met);
 
      /* Create periodic boundary conditions... */
      read_met_periodic(met);
 
      /* Downsampling... */
      read_met_sample(ctl, met);
 
      /* Calculate geopotential heights... */
      read_met_geopot(ctl, met);
 
      /* Calculate potential vorticity... */
      read_met_pv(met);
 
      /* Calculate boundary layer data... */
      read_met_pbl(met);
 
      /* Calculate tropopause data... */
      read_met_tropo(ctl, clim, met);
 
      /* Calculate cloud properties... */
      read_met_cloud(met);
 
      /* Calculate convective available potential energy... */
      read_met_cape(clim, met);
 
      /* Calculate total column ozone... */
      read_met_ozone(met);
 
      /* Detrending... */
      read_met_detrend(ctl, met);
 
      /* Check meteo data and smooth zeta profiles ... */
      if (ctl->advect_vert_coord == 1)
        read_met_monotonize(met);
 
      /* Close file... */
      NC(nc_close(ncid));
    }
 
    /* Read binary data... */
    else if (ctl->met_type >= 1 && ctl->met_type <= 5) {
 
      FILE *in;
 
      double r;
 
      int year, mon, day, hour, min, sec;
 
      /* Set timer... */
      SELECT_TIMER("READ_MET_BIN", "INPUT", NVTX_READ);
 
      /* Open file... */
      if (!(in = fopen(filename, "r"))) {
        WARN("Cannot open file!");
        return 0;
      }
 
      /* Check type of binary data... */
      int met_type;
      FREAD(&met_type, int,
            1,
            in);
      if (met_type != ctl->met_type)
        ERRMSG("Wrong MET_TYPE of binary data!");
 
      /* Check version of binary data... */
      int version;
      FREAD(&version, int,
            1,
            in);
      if (version != 100 && version != 101 && version != 102)
        ERRMSG("Wrong version of binary data!");
 
      /* Read time... */
      FREAD(&met->time, double,
            1,
            in);
      jsec2time(met->time, &year, &mon, &day, &hour, &min, &sec, &r);
      LOG(2, "Time: %.2f (%d-%02d-%02d, %02d:%02d UTC)",
          met->time, year, mon, day, hour, min);
      if (year < 1900 || year > 2100 || mon < 1 || mon > 12
          || day < 1 || day > 31 || hour < 0 || hour > 23)
        ERRMSG("Error while reading time!");
 
      /* Read dimensions... */
      FREAD(&met->nx, int,
            1,
            in);
      LOG(2, "Number of longitudes: %d", met->nx);
      if (met->nx < 2 || met->nx > EX)
        ERRMSG("Number of longitudes out of range!");
 
      FREAD(&met->ny, int,
            1,
            in);
      LOG(2, "Number of latitudes: %d", met->ny);
      if (met->ny < 2 || met->ny > EY)
        ERRMSG("Number of latitudes out of range!");
 
      FREAD(&met->np, int,
            1,
            in);
      LOG(2, "Number of levels: %d", met->np);
      if (met->np < 2 || met->np > EP)
        ERRMSG("Number of levels out of range!");
 
      /* Read grid... */
      FREAD(met->lon, double,
              (size_t) met->nx,
            in);
      LOG(2, "Longitudes: %g, %g ... %g deg",
          met->lon[0], met->lon[1], met->lon[met->nx - 1]);
 
      FREAD(met->lat, double,
              (size_t) met->ny,
            in);
      LOG(2, "Latitudes: %g, %g ... %g deg",
          met->lat[0], met->lat[1], met->lat[met->ny - 1]);
 
      FREAD(met->p, double,
              (size_t) met->np,
            in);
      LOG(2, "Altitude levels: %g, %g ... %g km",
          Z(met->p[0]), Z(met->p[1]), Z(met->p[met->np - 1]));
      LOG(2, "Pressure levels: %g, %g ... %g hPa",
          met->p[0], met->p[1], met->p[met->np - 1]);
 
      /* Read surface data... */
      read_met_bin_2d(in, met, met->ps, "PS");
      read_met_bin_2d(in, met, met->ts, "TS");
      read_met_bin_2d(in, met, met->zs, "ZS");
      read_met_bin_2d(in, met, met->us, "US");
      read_met_bin_2d(in, met, met->vs, "VS");
      if (version >= 101) {
        read_met_bin_2d(in, met, met->lsm, "LSM");
        read_met_bin_2d(in, met, met->sst, "SST");
      }
      read_met_bin_2d(in, met, met->pbl, "PBL");
      read_met_bin_2d(in, met, met->pt, "PT");
      read_met_bin_2d(in, met, met->tt, "TT");
      read_met_bin_2d(in, met, met->zt, "ZT");
      read_met_bin_2d(in, met, met->h2ot, "H2OT");
      read_met_bin_2d(in, met, met->pct, "PCT");
      read_met_bin_2d(in, met, met->pcb, "PCB");
      read_met_bin_2d(in, met, met->cl, "CL");
      read_met_bin_2d(in, met, met->plcl, "PLCL");
      read_met_bin_2d(in, met, met->plfc, "PLFC");
      read_met_bin_2d(in, met, met->pel, "PEL");
      read_met_bin_2d(in, met, met->cape, "CAPE");
      read_met_bin_2d(in, met, met->cin, "CIN");
 
      /* Read level data... */
      read_met_bin_3d(in, ctl, met, met->z, "Z", -1e34f, 1e34f);
      read_met_bin_3d(in, ctl, met, met->t, "T", 0, 1e34f);
      read_met_bin_3d(in, ctl, met, met->u, "U", -1e34f, 1e34f);
      read_met_bin_3d(in, ctl, met, met->v, "V", -1e34f, 1e34f);
      read_met_bin_3d(in, ctl, met, met->w, "W", -1e34f, 1e34f);
      read_met_bin_3d(in, ctl, met, met->pv, "PV", -1e34f, 1e34f);
      read_met_bin_3d(in, ctl, met, met->h2o, "H2O", 0, 1e34f);
      read_met_bin_3d(in, ctl, met, met->o3, "O3", 0, 1e34f);
      read_met_bin_3d(in, ctl, met, met->lwc, "LWC", 0, 1e34f);
      if (version >= 102)
        read_met_bin_3d(in, ctl, met, met->rwc, "RWC", 0, 1e34f);
      read_met_bin_3d(in, ctl, met, met->iwc, "IWC", 0, 1e34f);
      if (version >= 102)
        read_met_bin_3d(in, ctl, met, met->swc, "SWC", 0, 1e34f);
      if (version >= 101)
        read_met_bin_3d(in, ctl, met, met->cc, "CC", 0, 1);
 
      /* Read final flag... */
      int final;
      FREAD(&final, int,
            1,
            in);
      if (final != 999)
        ERRMSG("Error while reading binary data!");
 
      /* Close file... */
      fclose(in);
    }
 
    /* Not implemented... */
    else
      ERRMSG("MET_TYPE not implemented!");
  }
 
  /* Broadcast data via MPI... */
#ifdef MPI
  if (ctl->met_mpi_share) {
 
    /* Set timer... */
    SELECT_TIMER("READ_MET_MPI_BCAST", "COMM", NVTX_SEND);
    LOG(2, "Broadcast data on rank %d...", rank);
 
    /* Broadcast... */
    broadcast_large_data(met, sizeof(met_t));
  }
#endif
 
  /* Return success... */
  return 1;
}
 
/*****************************************************************************/
 
void read_met_bin_2d(
  FILE * in,
  met_t * met,
  float var[EX][EY],
  char *varname) {
 
  float *help;
 
  /* Allocate... */
  ALLOC(help, float,
        EX * EY);
 
  /* Read uncompressed... */
  LOG(2, "Read 2-D variable: %s (uncompressed)", varname);
  FREAD(help, float,
          (size_t) (met->nx * met->ny),
        in);
 
  /* Copy data... */
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      var[ix][iy] = help[ARRAY_2D(ix, iy, met->ny)];
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void read_met_bin_3d(
  FILE * in,
  ctl_t * ctl,
  met_t * met,
  float var[EX][EY][EP],
  char *varname,
  float bound_min,
  float bound_max) {
 
  float *help;
 
  /* Allocate... */
  ALLOC(help, float,
        EX * EY * EP);
 
  /* Read uncompressed data... */
  if (ctl->met_type == 1) {
    LOG(2, "Read 3-D variable: %s (uncompressed)", varname);
    FREAD(help, float,
            (size_t) (met->nx * met->ny * met->np),
          in);
  }
 
  /* Read packed data... */
  else if (ctl->met_type == 2)
    compress_pck(varname, help, (size_t) (met->ny * met->nx),
                 (size_t) met->np, 1, in);
 
  /* Read zfp data... */
  else if (ctl->met_type == 3) {
#ifdef ZFP
    int precision;
    FREAD(&precision, int,
          1,
          in);
 
    double tolerance;
    FREAD(&tolerance, double,
          1,
          in);
 
    compress_zfp(varname, help, met->np, met->ny, met->nx, precision,
                 tolerance, 1, in);
#else
    ERRMSG("MPTRAC was compiled without zfp compression!");
#endif
  }
 
  /* Read zstd data... */
  else if (ctl->met_type == 4) {
#ifdef ZSTD
    compress_zstd(varname, help, (size_t) (met->np * met->ny * met->nx), 1,
                  in);
#else
    ERRMSG("MPTRAC was compiled without zstd compression!");
#endif
  }
 
  /* Read cmultiscale data... */
  else if (ctl->met_type == 5) {
#ifdef CMS
    compress_cms(ctl, varname, help, (size_t) met->nx, (size_t) met->ny,
                 (size_t) met->np, 1, in);
#else
    ERRMSG("MPTRAC was compiled without cmultiscale compression!");
#endif
  }
 
  /* Copy data... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      for (int ip = 0; ip < met->np; ip++) {
        var[ix][iy][ip] = help[ARRAY_3D(ix, iy, met->ny, ip, met->np)];
        if (var[ix][iy][ip] < bound_min)
          var[ix][iy][ip] = bound_min;
        else if (var[ix][iy][ip] > bound_max)
          var[ix][iy][ip] = bound_max;
      }
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void read_met_cape(
  clim_t * clim,
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_CAPE", "METPROC", NVTX_READ);
  LOG(2, "Calculate CAPE...");
 
  /* Vertical spacing (about 100 m)... */
  const double pfac = 1.01439, dz0 = RI / MA / G0 * log(pfac);
 
  /* Loop over columns... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Get potential temperature and water vapor at lowest 50 hPa... */
      int n = 0;
      double h2o = 0, t, theta = 0;
      double pbot = MIN(met->ps[ix][iy], met->p[0]);
      double ptop = pbot - 50.;
      for (int ip = 0; ip < met->np; ip++) {
        if (met->p[ip] <= pbot) {
          theta += THETA(met->p[ip], met->t[ix][iy][ip]);
          h2o += met->h2o[ix][iy][ip];
          n++;
        }
        if (met->p[ip] < ptop && n > 0)
          break;
      }
      theta /= n;
      h2o /= n;
 
      /* Cannot compute anything if water vapor is missing... */
      met->plcl[ix][iy] = NAN;
      met->plfc[ix][iy] = NAN;
      met->pel[ix][iy] = NAN;
      met->cape[ix][iy] = NAN;
      met->cin[ix][iy] = NAN;
      if (h2o <= 0)
        continue;
 
      /* Find lifted condensation level (LCL)... */
      ptop = P(20.);
      pbot = met->ps[ix][iy];
      do {
        met->plcl[ix][iy] = (float) (0.5 * (pbot + ptop));
        t = theta / pow(1000. / met->plcl[ix][iy], 0.286);
        if (RH(met->plcl[ix][iy], t, h2o) > 100.)
          ptop = met->plcl[ix][iy];
        else
          pbot = met->plcl[ix][iy];
      } while (pbot - ptop > 0.1);
 
      /* Calculate CIN up to LCL... */
      INTPOL_INIT;
      double dcape, dz, h2o_env, t_env;
      double p = met->ps[ix][iy];
      met->cape[ix][iy] = met->cin[ix][iy] = 0;
      do {
        dz = dz0 * TVIRT(t, h2o);
        p /= pfac;
        t = theta / pow(1000. / p, 0.286);
        intpol_met_space_3d(met, met->t, p, met->lon[ix], met->lat[iy],
                            &t_env, ci, cw, 1);
        intpol_met_space_3d(met, met->h2o, p, met->lon[ix], met->lat[iy],
                            &h2o_env, ci, cw, 0);
        dcape = 1e3 * G0 * (TVIRT(t, h2o) - TVIRT(t_env, h2o_env)) /
          TVIRT(t_env, h2o_env) * dz;
        if (dcape < 0)
          met->cin[ix][iy] += fabsf((float) dcape);
      } while (p > met->plcl[ix][iy]);
 
      /* Calculate level of free convection (LFC), equilibrium level (EL),
         and convective available potential energy (CAPE)... */
      dcape = 0;
      p = met->plcl[ix][iy];
      t = theta / pow(1000. / p, 0.286);
      ptop = 0.75 * clim_tropo(clim, met->time, met->lat[iy]);
      do {
        dz = dz0 * TVIRT(t, h2o);
        p /= pfac;
        t -= lapse_rate(t, h2o) * dz;
        double psat = PSAT(t);
        h2o = psat / (p - (1. - EPS) * psat);
        intpol_met_space_3d(met, met->t, p, met->lon[ix], met->lat[iy],
                            &t_env, ci, cw, 1);
        intpol_met_space_3d(met, met->h2o, p, met->lon[ix], met->lat[iy],
                            &h2o_env, ci, cw, 0);
        double dcape_old = dcape;
        dcape = 1e3 * G0 * (TVIRT(t, h2o) - TVIRT(t_env, h2o_env)) /
          TVIRT(t_env, h2o_env) * dz;
        if (dcape > 0) {
          met->cape[ix][iy] += (float) dcape;
          if (!isfinite(met->plfc[ix][iy]))
            met->plfc[ix][iy] = (float) p;
        } else if (dcape_old > 0)
          met->pel[ix][iy] = (float) p;
        if (dcape < 0 && !isfinite(met->plfc[ix][iy]))
          met->cin[ix][iy] += fabsf((float) dcape);
      } while (p > ptop);
 
      /* Check results... */
      if (!isfinite(met->plfc[ix][iy]))
        met->cin[ix][iy] = NAN;
    }
}
 
/*****************************************************************************/
 
void read_met_cloud(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_CLOUD", "METPROC", NVTX_READ);
  LOG(2, "Calculate cloud data...");
 
  /* Loop over columns... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Init... */
      met->pct[ix][iy] = NAN;
      met->pcb[ix][iy] = NAN;
      met->cl[ix][iy] = 0;
 
      /* Loop over pressure levels... */
      for (int ip = 0; ip < met->np - 1; ip++) {
 
        /* Check pressure... */
        if (met->p[ip] > met->ps[ix][iy] || met->p[ip] < P(20.))
          continue;
 
        /* Check ice water and liquid water content... */
        if (met->iwc[ix][iy][ip] > 0 || met->rwc[ix][iy][ip] > 0
            || met->lwc[ix][iy][ip] > 0 || met->swc[ix][iy][ip] > 0) {
 
          /* Get cloud top pressure ... */
          met->pct[ix][iy]
            = (float) (0.5 * (met->p[ip] + (float) met->p[ip + 1]));
 
          /* Get cloud bottom pressure ... */
          if (!isfinite(met->pcb[ix][iy]))
            met->pcb[ix][iy]
              = (float) (0.5 * (met->p[ip] + met->p[MAX(ip - 1, 0)]));
        }
 
        /* Get cloud water... */
        met->cl[ix][iy] += (float)
          (0.5 * (met->lwc[ix][iy][ip] + met->lwc[ix][iy][ip + 1]
                  + met->rwc[ix][iy][ip] + met->rwc[ix][iy][ip + 1]
                  + met->iwc[ix][iy][ip] + met->iwc[ix][iy][ip + 1]
                  + met->swc[ix][iy][ip] + met->swc[ix][iy][ip + 1])
           * 100. * (met->p[ip] - met->p[ip + 1]) / G0);
      }
    }
}
 
/*****************************************************************************/
 
void read_met_detrend(
  ctl_t * ctl,
  met_t * met) {
 
  met_t *help;
 
  /* Check parameters... */
  if (ctl->met_detrend <= 0)
    return;
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_DETREND", "METPROC", NVTX_READ);
  LOG(2, "Detrend meteo data...");
 
  /* Allocate... */
  ALLOC(help, met_t, 1);
 
  /* Calculate standard deviation... */
  double sigma = ctl->met_detrend / 2.355;
  double tssq = 2. * SQR(sigma);
 
  /* Calculate box size in latitude... */
  int sy = (int) (3. * DY2DEG(sigma) / fabs(met->lat[1] - met->lat[0]));
  sy = MIN(MAX(1, sy), met->ny / 2);
 
  /* Calculate background... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++) {
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Calculate Cartesian coordinates... */
      double x0[3];
      geo2cart(0.0, met->lon[ix], met->lat[iy], x0);
 
      /* Calculate box size in longitude... */
      int sx =
        (int) (3. * DX2DEG(sigma, met->lat[iy]) /
               fabs(met->lon[1] - met->lon[0]));
      sx = MIN(MAX(1, sx), met->nx / 2);
 
      /* Init... */
      float wsum = 0;
      for (int ip = 0; ip < met->np; ip++) {
        help->t[ix][iy][ip] = 0;
        help->u[ix][iy][ip] = 0;
        help->v[ix][iy][ip] = 0;
        help->w[ix][iy][ip] = 0;
      }
 
      /* Loop over neighboring grid points... */
      for (int ix2 = ix - sx; ix2 <= ix + sx; ix2++) {
        int ix3 = ix2;
        if (ix3 < 0)
          ix3 += met->nx;
        else if (ix3 >= met->nx)
          ix3 -= met->nx;
        for (int iy2 = MAX(iy - sy, 0);
             iy2 <= MIN(iy + sy, met->ny - 1); iy2++) {
 
          /* Calculate Cartesian coordinates... */
          double x1[3];
          geo2cart(0.0, met->lon[ix3], met->lat[iy2], x1);
 
          /* Calculate weighting factor... */
          float w = (float) exp(-DIST2(x0, x1) / tssq);
 
          /* Add data... */
          wsum += w;
          for (int ip = 0; ip < met->np; ip++) {
            help->t[ix][iy][ip] += w * met->t[ix3][iy2][ip];
            help->u[ix][iy][ip] += w * met->u[ix3][iy2][ip];
            help->v[ix][iy][ip] += w * met->v[ix3][iy2][ip];
            help->w[ix][iy][ip] += w * met->w[ix3][iy2][ip];
          }
        }
      }
 
      /* Normalize... */
      for (int ip = 0; ip < met->np; ip++) {
        help->t[ix][iy][ip] /= wsum;
        help->u[ix][iy][ip] /= wsum;
        help->v[ix][iy][ip] /= wsum;
        help->w[ix][iy][ip] /= wsum;
      }
    }
  }
 
  /* Subtract background... */
#pragma omp parallel for default(shared) collapse(3)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      for (int ip = 0; ip < met->np; ip++) {
        met->t[ix][iy][ip] -= help->t[ix][iy][ip];
        met->u[ix][iy][ip] -= help->u[ix][iy][ip];
        met->v[ix][iy][ip] -= help->v[ix][iy][ip];
        met->w[ix][iy][ip] -= help->w[ix][iy][ip];
      }
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void read_met_extrapolate(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_EXTRAPOLATE", "METPROC", NVTX_READ);
  LOG(2, "Extrapolate meteo data...");
 
  /* Loop over columns... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Find lowest valid data point... */
      int ip0;
      for (ip0 = met->np - 1; ip0 >= 0; ip0--)
        if (!isfinite(met->t[ix][iy][ip0])
            || !isfinite(met->u[ix][iy][ip0])
            || !isfinite(met->v[ix][iy][ip0])
            || !isfinite(met->w[ix][iy][ip0]))
          break;
 
      /* Extrapolate... */
      for (int ip = ip0; ip >= 0; ip--) {
        met->t[ix][iy][ip] = met->t[ix][iy][ip + 1];
        met->u[ix][iy][ip] = met->u[ix][iy][ip + 1];
        met->v[ix][iy][ip] = met->v[ix][iy][ip + 1];
        met->w[ix][iy][ip] = met->w[ix][iy][ip + 1];
        met->h2o[ix][iy][ip] = met->h2o[ix][iy][ip + 1];
        met->o3[ix][iy][ip] = met->o3[ix][iy][ip + 1];
        met->lwc[ix][iy][ip] = met->lwc[ix][iy][ip + 1];
        met->rwc[ix][iy][ip] = met->rwc[ix][iy][ip + 1];
        met->iwc[ix][iy][ip] = met->iwc[ix][iy][ip + 1];
        met->swc[ix][iy][ip] = met->swc[ix][iy][ip + 1];
        met->cc[ix][iy][ip] = met->cc[ix][iy][ip + 1];
      }
    }
}
 
/*****************************************************************************/
 
void read_met_geopot(
  ctl_t * ctl,
  met_t * met) {
 
  float *help;
 
  double logp[EP];
 
  int dx = ctl->met_geopot_sx, dy = ctl->met_geopot_sy;
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_GEOPOT", "METPROC", NVTX_READ);
  LOG(2, "Calculate geopotential heights...");
 
  /* Allocate... */
  ALLOC(help, float,
        EX * EY * EP);
 
  /* Calculate log pressure... */
#pragma omp parallel for default(shared)
  for (int ip = 0; ip < met->np; ip++)
    logp[ip] = log(met->p[ip]);
 
  /* Apply hydrostatic equation to calculate geopotential heights... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Get surface height and pressure... */
      double zs = met->zs[ix][iy];
      double lnps = log(met->ps[ix][iy]);
 
      /* Get temperature and water vapor at the surface... */
      int ip0 = locate_irr(met->p, met->np, met->ps[ix][iy]);
      double ts = LIN(met->p[ip0], met->t[ix][iy][ip0], met->p[ip0 + 1],
                      met->t[ix][iy][ip0 + 1], met->ps[ix][iy]);
      double h2os = LIN(met->p[ip0], met->h2o[ix][iy][ip0], met->p[ip0 + 1],
                        met->h2o[ix][iy][ip0 + 1], met->ps[ix][iy]);
 
      /* Upper part of profile... */
      met->z[ix][iy][ip0 + 1]
        = (float) (zs +
                   ZDIFF(lnps, ts, h2os, logp[ip0 + 1],
                         met->t[ix][iy][ip0 + 1], met->h2o[ix][iy][ip0 + 1]));
      for (int ip = ip0 + 2; ip < met->np; ip++)
        met->z[ix][iy][ip]
          = (float) (met->z[ix][iy][ip - 1] +
                     ZDIFF(logp[ip - 1], met->t[ix][iy][ip - 1],
                           met->h2o[ix][iy][ip - 1], logp[ip],
                           met->t[ix][iy][ip], met->h2o[ix][iy][ip]));
 
      /* Lower part of profile... */
      met->z[ix][iy][ip0]
        = (float) (zs +
                   ZDIFF(lnps, ts, h2os, logp[ip0],
                         met->t[ix][iy][ip0], met->h2o[ix][iy][ip0]));
      for (int ip = ip0 - 1; ip >= 0; ip--)
        met->z[ix][iy][ip]
          = (float) (met->z[ix][iy][ip + 1] +
                     ZDIFF(logp[ip + 1], met->t[ix][iy][ip + 1],
                           met->h2o[ix][iy][ip + 1], logp[ip],
                           met->t[ix][iy][ip], met->h2o[ix][iy][ip]));
    }
 
  /* Check control parameters... */
  if (dx == 0 || dy == 0)
    return;
 
  /* Default smoothing parameters... */
  if (dx < 0 || dy < 0) {
    if (fabs(met->lon[1] - met->lon[0]) < 0.5) {
      dx = 3;
      dy = 2;
    } else {
      dx = 6;
      dy = 4;
    }
  }
 
  /* Calculate weights for smoothing... */
  float ws[dx + 1][dy + 1];
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix <= dx; ix++)
    for (int iy = 0; iy < dy; iy++)
      ws[ix][iy] = (1.0f - (float) ix / (float) dx)
        * (1.0f - (float) iy / (float) dy);
 
  /* Copy data... */
#pragma omp parallel for default(shared) collapse(3)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      for (int ip = 0; ip < met->np; ip++)
        help[ARRAY_3D(ip, ix, met->nx, iy, met->ny)] = met->z[ix][iy][ip];
 
  /* Horizontal smoothing... */
#pragma omp parallel for default(shared) collapse(3)
  for (int ip = 0; ip < met->np; ip++)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++) {
        float res = 0, wsum = 0;
        int iy0 = MAX(iy - dy + 1, 0);
        int iy1 = MIN(iy + dy - 1, met->ny - 1);
        for (int ix2 = ix - dx + 1; ix2 <= ix + dx - 1; ++ix2) {
          int ix3 = ix2;
          if (ix3 < 0)
            ix3 += met->nx;
          else if (ix3 >= met->nx)
            ix3 -= met->nx;
          for (int iy2 = iy0; iy2 <= iy1; ++iy2)
            if (isfinite(help[ARRAY_3D(ip, ix3, met->nx, iy2, met->ny)])) {
              float w = ws[abs(ix - ix2)][abs(iy - iy2)];
              res += w * help[ARRAY_3D(ip, ix3, met->nx, iy2, met->ny)];
              wsum += w;
            }
        }
        if (wsum > 0)
          met->z[ix][iy][ip] = res / wsum;
        else
          met->z[ix][iy][ip] = NAN;
      }
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void read_met_grid(
  const char *filename,
  int ncid,
  ctl_t * ctl,
  met_t * met) {
 
  char levname[LEN], tstr[10];
 
  double rtime = 0, r, r2;
 
  int varid, year2, mon2, day2, hour2, min2, sec2,
    year, mon, day, hour, min, sec;
 
  size_t np;
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_GRID", "INPUT", NVTX_READ);
  LOG(2, "Read meteo grid information...");
 
  /* MPTRAC meteo files... */
  if (ctl->met_clams == 0) {
 
    /* Get time from filename... */
    met->time = time_from_filename(filename, 16);
 
    /* Check time information from data file... */
    jsec2time(met->time, &year, &mon, &day, &hour, &min, &sec, &r);
    if (nc_inq_varid(ncid, "time", &varid) == NC_NOERR) {
      NC(nc_get_var_double(ncid, varid, &rtime));
      if (fabs(year * 10000. + mon * 100. + day + hour / 24. - rtime) > 1.0)
        WARN("Time information in meteo file does not match filename!");
    } else
      WARN("Time information in meteo file is missing!");
  }
 
  /* CLaMS meteo files... */
  else {
 
    /* Read time from file... */
    NC_GET_DOUBLE("time", &rtime, 0);
 
    /* Get time from filename (considering the century)... */
    if (rtime < 0)
      sprintf(tstr, "19%.2s", &filename[strlen(filename) - 11]);
    else
      sprintf(tstr, "20%.2s", &filename[strlen(filename) - 11]);
    year = atoi(tstr);
    sprintf(tstr, "%.2s", &filename[strlen(filename) - 9]);
    mon = atoi(tstr);
    sprintf(tstr, "%.2s", &filename[strlen(filename) - 7]);
    day = atoi(tstr);
    sprintf(tstr, "%.2s", &filename[strlen(filename) - 5]);
    hour = atoi(tstr);
    time2jsec(year, mon, day, hour, 0, 0, 0, &met->time);
  }
 
  /* Check time... */
  if (year < 1900 || year > 2100 || mon < 1 || mon > 12
      || day < 1 || day > 31 || hour < 0 || hour > 23)
    ERRMSG("Cannot read time from filename!");
  jsec2time(met->time, &year2, &mon2, &day2, &hour2, &min2, &sec2, &r2);
  LOG(2, "Time: %.2f (%d-%02d-%02d, %02d:%02d UTC)",
      met->time, year2, mon2, day2, hour2, min2);
 
  /* Get grid dimensions... */
  NC_INQ_DIM("lon", &met->nx, 2, EX);
  LOG(2, "Number of longitudes: %d", met->nx);
 
  NC_INQ_DIM("lat", &met->ny, 2, EY);
  LOG(2, "Number of latitudes: %d", met->ny);
 
  int dimid2;
  sprintf(levname, "lev");
  if (nc_inq_dimid(ncid, levname, &dimid2) != NC_NOERR)
    sprintf(levname, "plev");
  if (nc_inq_dimid(ncid, levname, &dimid2) != NC_NOERR)
    sprintf(levname, "hybrid");
 
  NC_INQ_DIM(levname, &met->np, 1, EP);
  if (met->np == 1) {
    sprintf(levname, "lev_2");
    if (nc_inq_dimid(ncid, levname, &dimid2) != NC_NOERR) {
      sprintf(levname, "plev");
      NC(nc_inq_dimid(ncid, levname, &dimid2));
    }
    NC(nc_inq_dimlen(ncid, dimid2, &np));
    met->np = (int) np;
  }
  LOG(2, "Number of levels: %d", met->np);
  if (met->np < 2 || met->np > EP)
    ERRMSG("Number of levels out of range!");
 
  /* Read longitudes and latitudes... */
  NC_GET_DOUBLE("lon", met->lon, 1);
  LOG(2, "Longitudes: %g, %g ... %g deg",
      met->lon[0], met->lon[1], met->lon[met->nx - 1]);
  NC_GET_DOUBLE("lat", met->lat, 1);
  LOG(2, "Latitudes: %g, %g ... %g deg",
      met->lat[0], met->lat[1], met->lat[met->ny - 1]);
 
  /* Read pressure levels... */
  if (ctl->met_np <= 0) {
    NC_GET_DOUBLE(levname, met->p, 1);
    for (int ip = 0; ip < met->np; ip++)
      met->p[ip] /= 100.;
    LOG(2, "Altitude levels: %g, %g ... %g km",
        Z(met->p[0]), Z(met->p[1]), Z(met->p[met->np - 1]));
    LOG(2, "Pressure levels: %g, %g ... %g hPa",
        met->p[0], met->p[1], met->p[met->np - 1]);
  }
 
  /* Read hybrid levels... */
  if (strcasecmp(levname, "hybrid") == 0)
    NC_GET_DOUBLE("hybrid", met->hybrid, 1);
}
 
/*****************************************************************************/
 
void read_met_levels(
  int ncid,
  ctl_t * ctl,
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_LEVELS", "INPUT", NVTX_READ);
  LOG(2, "Read level data...");
 
  /* Read temperature... */
  if (!read_met_nc_3d(ncid, "t", "T", "temp", "TEMP", ctl, met, met->t, 1.0))
    ERRMSG("Cannot read temperature!");
 
  /* Read horizontal wind and vertical velocity... */
  if (!read_met_nc_3d(ncid, "u", "U", NULL, NULL, ctl, met, met->u, 1.0))
    ERRMSG("Cannot read zonal wind!");
  if (!read_met_nc_3d(ncid, "v", "V", NULL, NULL, ctl, met, met->v, 1.0))
    ERRMSG("Cannot read meridional wind!");
  if (!read_met_nc_3d
      (ncid, "w", "W", "omega", "OMEGA", ctl, met, met->w, 0.01f))
    WARN("Cannot read vertical velocity!");
 
  /* Read water vapor... */
  if (!ctl->met_relhum) {
    if (!read_met_nc_3d
        (ncid, "q", "Q", "sh", "SH", ctl, met, met->h2o, (float) (MA / MH2O)))
      WARN("Cannot read specific humidity!");
  } else {
    if (!read_met_nc_3d
        (ncid, "rh", "RH", NULL, NULL, ctl, met, met->h2o, 0.01f))
      WARN("Cannot read relative humidity!");
#pragma omp parallel for default(shared) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        for (int ip = 0; ip < met->np; ip++) {
          double pw = met->h2o[ix][iy][ip] * PSAT(met->t[ix][iy][ip]);
          met->h2o[ix][iy][ip] =
            (float) (pw / (met->p[ip] - (1.0 - EPS) * pw));
        }
  }
 
  /* Read ozone... */
  if (!read_met_nc_3d
      (ncid, "o3", "O3", NULL, NULL, ctl, met, met->o3, (float) (MA / MO3)))
    WARN("Cannot read ozone data!");
 
  /* Read cloud data... */
  if (!read_met_nc_3d
      (ncid, "clwc", "CLWC", NULL, NULL, ctl, met, met->lwc, 1.0))
    WARN("Cannot read cloud liquid water content!");
  if (!read_met_nc_3d
      (ncid, "crwc", "CRWC", NULL, NULL, ctl, met, met->rwc, 1.0))
    WARN("Cannot read cloud rain water content!");
  if (!read_met_nc_3d
      (ncid, "ciwc", "CIWC", NULL, NULL, ctl, met, met->iwc, 1.0))
    WARN("Cannot read cloud ice water content!");
  if (!read_met_nc_3d
      (ncid, "cswc", "CSWC", NULL, NULL, ctl, met, met->swc, 1.0))
    WARN("Cannot read cloud snow water content!");
  if (!read_met_nc_3d(ncid, "cc", "CC", NULL, NULL, ctl, met, met->cc, 1.0))
    WARN("Cannot read cloud cover!");
 
  /* Read zeta and zeta_dot... */
  if (!read_met_nc_3d
      (ncid, "ZETA", "zeta", NULL, NULL, ctl, met, met->zetal, 1.0))
    WARN("Cannot read ZETA in meteo data!");
  if (ctl->advect_vert_coord == 1) {
    if (!read_met_nc_3d
        (ncid, "ZETA_DOT_TOT", "zeta_dot_clr", NULL, NULL, ctl, met,
         met->zeta_dotl, 0.00001157407f)) {
      if (!read_met_nc_3d
          (ncid, "ZETA_DOT_TOT", "ZETA_DOT_clr", NULL, NULL, ctl, met,
           met->zeta_dotl, 0.00001157407f)) {
        WARN("Cannot read vertical velocity!");
      }
    }
  }
 
  /* Store velocities on model levels for diabatic advection... */
  if (ctl->met_vert_coord == 1) {
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        for (int ip = 0; ip < met->np; ip++) {
          met->ul[ix][iy][ip] = met->u[ix][iy][ip];
          met->vl[ix][iy][ip] = met->v[ix][iy][ip];
          met->wl[ix][iy][ip] = met->w[ix][iy][ip];
        }
 
    /* Original number of vertical levels... */
    met->npl = met->np;
  }
 
  /* Read pressure on model levels... */
  if (ctl->met_np > 0 || ctl->met_vert_coord == 1) {
 
    /* Read data... */
    if (!read_met_nc_3d
        (ncid, "pl", "PL", "pressure", "PRESSURE", ctl, met, met->pl, 0.01f))
      if (!read_met_nc_3d
          (ncid, "press", "PRESS", NULL, NULL, ctl, met, met->pl, 1.0))
        ERRMSG("Cannot read pressure on model levels!");
 
    /* Check ordering of pressure levels... */
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        for (int ip = 1; ip < met->np; ip++)
          if ((met->pl[ix][iy][0] > met->pl[ix][iy][1]
               && met->pl[ix][iy][ip - 1] <= met->pl[ix][iy][ip])
              || (met->pl[ix][iy][0] < met->pl[ix][iy][1]
                  && met->pl[ix][iy][ip - 1] >= met->pl[ix][iy][ip]))
            ERRMSG("Pressure profiles are not monotonic!");
  }
 
  /* Interpolate from model levels to pressure levels... */
  if (ctl->met_np > 0) {
 
    /* Interpolate variables... */
    read_met_ml2pl(ctl, met, met->t, "T");
    read_met_ml2pl(ctl, met, met->u, "U");
    read_met_ml2pl(ctl, met, met->v, "V");
    read_met_ml2pl(ctl, met, met->w, "W");
    read_met_ml2pl(ctl, met, met->h2o, "H2O");
    read_met_ml2pl(ctl, met, met->o3, "O3");
    read_met_ml2pl(ctl, met, met->lwc, "LWC");
    read_met_ml2pl(ctl, met, met->rwc, "RWC");
    read_met_ml2pl(ctl, met, met->iwc, "IWC");
    read_met_ml2pl(ctl, met, met->swc, "SWC");
    read_met_ml2pl(ctl, met, met->cc, "CC");
 
    /* Set new pressure levels... */
    met->np = ctl->met_np;
    for (int ip = 0; ip < met->np; ip++)
      met->p[ip] = ctl->met_p[ip];
  }
 
  /* Check ordering of pressure levels... */
  for (int ip = 1; ip < met->np; ip++)
    if (met->p[ip - 1] < met->p[ip])
      ERRMSG("Pressure levels must be descending!");
}
 
/*****************************************************************************/
 
void read_met_ml2pl(
  ctl_t * ctl,
  met_t * met,
  float var[EX][EY][EP],
  char *varname) {
 
  double aux[EP], p[EP];
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_ML2PL", "METPROC", NVTX_READ);
  LOG(2, "Interpolate meteo data to pressure levels: %s", varname);
 
  /* Loop over columns... */
#pragma omp parallel for default(shared) private(aux,p) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Copy pressure profile... */
      for (int ip = 0; ip < met->np; ip++)
        p[ip] = met->pl[ix][iy][ip];
 
      /* Interpolate... */
      for (int ip = 0; ip < ctl->met_np; ip++) {
        double pt = ctl->met_p[ip];
        if ((pt > p[0] && p[0] > p[1]) || (pt < p[0] && p[0] < p[1]))
          pt = p[0];
        else if ((pt > p[met->np - 1] && p[1] > p[0])
                 || (pt < p[met->np - 1] && p[1] < p[0]))
          pt = p[met->np - 1];
        int ip2 = locate_irr(p, met->np, pt);
        aux[ip] = LIN(p[ip2], var[ix][iy][ip2],
                      p[ip2 + 1], var[ix][iy][ip2 + 1], pt);
      }
 
      /* Copy data... */
      for (int ip = 0; ip < ctl->met_np; ip++)
        var[ix][iy][ip] = (float) aux[ip];
    }
}
 
/*****************************************************************************/
 
void read_met_monotonize(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_MONOTONIZE", "METPROC", NVTX_READ);
  LOG(2, "Make zeta profiles monotone...");
 
  /* Create monotone zeta profiles... */
#pragma omp parallel for default(shared) collapse(2)
  for (int i = 0; i < met->nx; i++)
    for (int j = 0; j < met->ny; j++) {
      int k = 1;
 
      while (k < met->npl) {    /* Check if there is an inversion at level k... */
        if ((met->zetal[i][j][k - 1] >= met->zetal[i][j][k])) {
          /* Find the upper level k+l over the inversion... */
          int l = 0;
          do {
            l++;
          }
          while ((met->zetal[i][j][k - 1] >=
                  met->zetal[i][j][k + l]) & (k + l < met->npl));
 
          /* Interpolate linear between the top and bottom 
             of the inversion... */
          float s =
            (float) (met->zetal[i][j][k + l] - met->zetal[i][j][k - 1])
            / (float) (met->hybrid[k + l] - met->hybrid[k - 1]);
 
          for (int m = k; m < k + l; m++) {
            float d = (float) (met->hybrid[m] - met->hybrid[k - 1]);
            met->zetal[i][j][m] = s * d + met->zetal[i][j][k - 1];
          }
 
          /* Search for more inversions above the last inversion ... */
          k = k + l;
        } else {
          k++;
        }
      }
    }
 
  /* Create monotone pressure profiles... */
#pragma omp parallel for default(shared) collapse(2)
  for (int i = 0; i < met->nx; i++)
    for (int j = 0; j < met->ny; j++) {
      int k = 1;
 
      while (k < met->npl) {    /* Check if there is an inversion at level k... */
        if ((met->pl[i][j][k - 1] <= met->pl[i][j][k])) {
          /* Find the upper level k+l over the inversion... */
          int l = 0;
          do {
            l++;
          }
          while ((met->pl[i][j][k - 1] <= met->pl[i][j][k + l]) & (k + l <
                                                                   met->npl));
 
          /* Interpolate linear between the top and bottom 
             of the inversion... */
          float s = (float) (met->pl[i][j][k + l] - met->pl[i][j][k - 1])
            / (float) (met->hybrid[k + l] - met->hybrid[k - 1]);
 
          for (int m = k; m < k + l; m++) {
            float d = (float) (met->hybrid[m] - met->hybrid[k - 1]);
            met->pl[i][j][m] = s * d + met->pl[i][j][k - 1];
          }
 
          /* Search for more inversions above the last inversion ... */
          k = k + l;
        } else {
          k++;
        }
      }
    }
}
 
/*****************************************************************************/
 
int read_met_nc_2d(
  int ncid,
  char *varname,
  char *varname2,
  char *varname3,
  char *varname4,
  ctl_t * ctl,
  met_t * met,
  float dest[EX][EY],
  float scl,
  int init) {
 
  char varsel[LEN];
 
  float offset, scalfac;
 
  int varid;
 
  /* Check if variable exists... */
  if (nc_inq_varid(ncid, varname, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname);
  else if (varname2 != NULL
           && nc_inq_varid(ncid, varname2, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname2);
  else if (varname3 != NULL
           && nc_inq_varid(ncid, varname3, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname3);
  else if (varname4 != NULL
           && nc_inq_varid(ncid, varname4, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname4);
  else
    return 0;
 
  /* Read packed data... */
  if (ctl->met_nc_scale
      && nc_get_att_float(ncid, varid, "add_offset", &offset) == NC_NOERR
      && nc_get_att_float(ncid, varid, "scale_factor",
                          &scalfac) == NC_NOERR) {
 
    /* Allocate... */
    short *help;
    ALLOC(help, short,
          EX * EY * EP);
 
    /* Read fill value and missing value... */
    short fillval, missval;
    if (nc_get_att_short(ncid, varid, "_FillValue", &fillval) != NC_NOERR)
      fillval = 0;
    if (nc_get_att_short(ncid, varid, "missing_value", &missval) != NC_NOERR)
      missval = 0;
 
    /* Write info... */
    LOG(2, "Read 2-D variable: %s"
        " (FILL = %d, MISS = %d, SCALE = %g, OFFSET = %g)",
        varsel, fillval, missval, scalfac, offset);
 
    /* Read data... */
    NC(nc_get_var_short(ncid, varid, help));
 
    /* Check meteo data layout... */
    if (ctl->met_convention != 0)
      ERRMSG("Meteo data layout not implemented for packed netCDF files!");
 
    /* Copy and check data... */
#pragma omp parallel for default(shared) num_threads(12)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++) {
        if (init)
          dest[ix][iy] = 0;
        short aux = help[ARRAY_2D(iy, ix, met->nx)];
        if ((fillval == 0 || aux != fillval)
            && (missval == 0 || aux != missval)
            && fabsf(aux * scalfac + offset) < 1e14f)
          dest[ix][iy] += scl * (aux * scalfac + offset);
        else
          dest[ix][iy] = NAN;
      }
 
    /* Free... */
    free(help);
  }
 
  /* Unpacked data... */
  else {
 
    /* Allocate... */
    float *help;
    ALLOC(help, float,
          EX * EY);
 
    /* Read fill value and missing value... */
    float fillval, missval;
    if (nc_get_att_float(ncid, varid, "_FillValue", &fillval) != NC_NOERR)
      fillval = 0;
    if (nc_get_att_float(ncid, varid, "missing_value", &missval) != NC_NOERR)
      missval = 0;
 
    /* Write info... */
    LOG(2, "Read 2-D variable: %s (FILL = %g, MISS = %g)",
        varsel, fillval, missval);
 
    /* Read data... */
    NC(nc_get_var_float(ncid, varid, help));
 
    /* Check meteo data layout... */
    if (ctl->met_convention == 0) {
 
      /* Copy and check data (ordering: lat, lon)... */
#pragma omp parallel for default(shared) num_threads(12)
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++) {
          if (init)
            dest[ix][iy] = 0;
          float aux = help[ARRAY_2D(iy, ix, met->nx)];
          if ((fillval == 0 || aux != fillval)
              && (missval == 0 || aux != missval)
              && fabsf(aux) < 1e14f)
            dest[ix][iy] += scl * aux;
          else
            dest[ix][iy] = NAN;
        }
 
    } else {
 
      /* Copy and check data (ordering: lon, lat)... */
#pragma omp parallel for default(shared) num_threads(12)
      for (int iy = 0; iy < met->ny; iy++)
        for (int ix = 0; ix < met->nx; ix++) {
          if (init)
            dest[ix][iy] = 0;
          float aux = help[ARRAY_2D(ix, iy, met->ny)];
          if ((fillval == 0 || aux != fillval)
              && (missval == 0 || aux != missval)
              && fabsf(aux) < 1e14f)
            dest[ix][iy] += scl * aux;
          else
            dest[ix][iy] = NAN;
        }
    }
 
    /* Free... */
    free(help);
  }
 
  /* Return... */
  return 1;
}
 
/*****************************************************************************/
 
int read_met_nc_3d(
  int ncid,
  char *varname,
  char *varname2,
  char *varname3,
  char *varname4,
  ctl_t * ctl,
  met_t * met,
  float dest[EX][EY][EP],
  float scl) {
 
  char varsel[LEN];
 
  float offset, scalfac;
 
  int varid;
 
  /* Check if variable exists... */
  if (nc_inq_varid(ncid, varname, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname);
  else if (varname2 != NULL
           && nc_inq_varid(ncid, varname2, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname2);
  else if (varname3 != NULL
           && nc_inq_varid(ncid, varname3, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname3);
  else if (varname4 != NULL
           && nc_inq_varid(ncid, varname4, &varid) == NC_NOERR)
    sprintf(varsel, "%s", varname4);
  else
    return 0;
 
  /* Read packed data... */
  if (ctl->met_nc_scale
      && nc_get_att_float(ncid, varid, "add_offset", &offset) == NC_NOERR
      && nc_get_att_float(ncid, varid, "scale_factor",
                          &scalfac) == NC_NOERR) {
 
    /* Allocate... */
    short *help;
    ALLOC(help, short,
          EX * EY * EP);
 
    /* Read fill value and missing value... */
    short fillval, missval;
    if (nc_get_att_short(ncid, varid, "_FillValue", &fillval) != NC_NOERR)
      fillval = 0;
    if (nc_get_att_short(ncid, varid, "missing_value", &missval) != NC_NOERR)
      missval = 0;
 
    /* Write info... */
    LOG(2, "Read 3-D variable: %s "
        "(FILL = %d, MISS = %d, SCALE = %g, OFFSET = %g)",
        varsel, fillval, missval, scalfac, offset);
 
    /* Read data... */
    NC(nc_get_var_short(ncid, varid, help));
 
    /* Check meteo data layout... */
    if (ctl->met_convention != 0)
      ERRMSG("Meteo data layout not implemented for packed netCDF files!");
 
    /* Copy and check data... */
#pragma omp parallel for default(shared) num_threads(12)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        for (int ip = 0; ip < met->np; ip++) {
          short aux = help[ARRAY_3D(ip, iy, met->ny, ix, met->nx)];
          if ((fillval == 0 || aux != fillval)
              && (missval == 0 || aux != missval)
              && fabsf(aux * scalfac + offset) < 1e14f)
            dest[ix][iy][ip] = scl * (aux * scalfac + offset);
          else
            dest[ix][iy][ip] = NAN;
        }
 
    /* Free... */
    free(help);
  }
 
  /* Unpacked data... */
  else {
 
    /* Allocate... */
    float *help;
    ALLOC(help, float,
          EX * EY * EP);
 
    /* Read fill value and missing value... */
    float fillval, missval;
    if (nc_get_att_float(ncid, varid, "_FillValue", &fillval) != NC_NOERR)
      fillval = 0;
    if (nc_get_att_float(ncid, varid, "missing_value", &missval) != NC_NOERR)
      missval = 0;
 
    /* Write info... */
    LOG(2, "Read 3-D variable: %s (FILL = %g, MISS = %g)",
        varsel, fillval, missval);
 
    /* Read data... */
    NC(nc_get_var_float(ncid, varid, help));
 
    /* Check meteo data layout... */
    if (ctl->met_convention == 0) {
 
      /* Copy and check data (ordering: lev, lat, lon)... */
#pragma omp parallel for default(shared) num_threads(12)
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++)
          for (int ip = 0; ip < met->np; ip++) {
            float aux = help[ARRAY_3D(ip, iy, met->ny, ix, met->nx)];
            if ((fillval == 0 || aux != fillval)
                && (missval == 0 || aux != missval)
                && fabsf(aux) < 1e14f)
              dest[ix][iy][ip] = scl * aux;
            else
              dest[ix][iy][ip] = NAN;
          }
 
    } else {
 
      /* Copy and check data (ordering: lon, lat, lev)... */
#pragma omp parallel for default(shared) num_threads(12)
      for (int ip = 0; ip < met->np; ip++)
        for (int iy = 0; iy < met->ny; iy++)
          for (int ix = 0; ix < met->nx; ix++) {
            float aux = help[ARRAY_3D(ix, iy, met->ny, ip, met->np)];
            if ((fillval == 0 || aux != fillval)
                && (missval == 0 || aux != missval)
                && fabsf(aux) < 1e14f)
              dest[ix][iy][ip] = scl * aux;
            else
              dest[ix][iy][ip] = NAN;
          }
    }
 
    /* Free... */
    free(help);
  }
 
  /* Return... */
  return 1;
}
 
/*****************************************************************************/
 
void read_met_pbl(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_PBL", "METPROC", NVTX_READ);
  LOG(2, "Calculate planetary boundary layer...");
 
  /* Parameters used to estimate the height of the PBL
     (e.g., Vogelezang and Holtslag, 1996; Seidel et al., 2012)... */
  const double rib_crit = 0.25, dz = 0.05, umin = 5.0;
 
  /* Loop over grid points... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Set bottom level of PBL... */
      double pbl_bot = met->ps[ix][iy] + DZ2DP(dz, met->ps[ix][iy]);
 
      /* Find lowest level near the bottom... */
      int ip;
      for (ip = 1; ip < met->np; ip++)
        if (met->p[ip] < pbl_bot)
          break;
 
      /* Get near surface data... */
      double zs = LIN(met->p[ip - 1], met->z[ix][iy][ip - 1],
                      met->p[ip], met->z[ix][iy][ip], pbl_bot);
      double ts = LIN(met->p[ip - 1], met->t[ix][iy][ip - 1],
                      met->p[ip], met->t[ix][iy][ip], pbl_bot);
      double us = LIN(met->p[ip - 1], met->u[ix][iy][ip - 1],
                      met->p[ip], met->u[ix][iy][ip], pbl_bot);
      double vs = LIN(met->p[ip - 1], met->v[ix][iy][ip - 1],
                      met->p[ip], met->v[ix][iy][ip], pbl_bot);
      double h2os = LIN(met->p[ip - 1], met->h2o[ix][iy][ip - 1],
                        met->p[ip], met->h2o[ix][iy][ip], pbl_bot);
      double tvs = THETAVIRT(pbl_bot, ts, h2os);
 
      /* Init... */
      double rib_old = 0;
 
      /* Loop over levels... */
      for (; ip < met->np; ip++) {
 
        /* Get squared horizontal wind speed... */
        double vh2
          = SQR(met->u[ix][iy][ip] - us) + SQR(met->v[ix][iy][ip] - vs);
        vh2 = MAX(vh2, SQR(umin));
 
        /* Calculate bulk Richardson number... */
        double rib = G0 * 1e3 * (met->z[ix][iy][ip] - zs) / tvs
          * (THETAVIRT(met->p[ip], met->t[ix][iy][ip],
                       met->h2o[ix][iy][ip]) - tvs) / vh2;
 
        /* Check for critical value... */
        if (rib >= rib_crit) {
          met->pbl[ix][iy] = (float) (LIN(rib_old, met->p[ip - 1],
                                          rib, met->p[ip], rib_crit));
          if (met->pbl[ix][iy] > pbl_bot)
            met->pbl[ix][iy] = (float) pbl_bot;
          break;
        }
 
        /* Save Richardson number... */
        rib_old = rib;
      }
    }
}
 
/*****************************************************************************/
 
void read_met_periodic(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_PERIODIC", "METPROC", NVTX_READ);
  LOG(2, "Apply periodic boundary conditions...");
 
  /* Check longitudes... */
  if (!(fabs(met->lon[met->nx - 1] - met->lon[0]
             + met->lon[1] - met->lon[0] - 360) < 0.01))
    return;
 
  /* Increase longitude counter... */
  if ((++met->nx) >= EX)
    ERRMSG("Cannot create periodic boundary conditions!");
 
  /* Set longitude... */
  met->lon[met->nx - 1] = met->lon[met->nx - 2] + met->lon[1] - met->lon[0];
 
  /* Loop over latitudes and pressure levels... */
#pragma omp parallel for default(shared)
  for (int iy = 0; iy < met->ny; iy++) {
    met->ps[met->nx - 1][iy] = met->ps[0][iy];
    met->zs[met->nx - 1][iy] = met->zs[0][iy];
    met->ts[met->nx - 1][iy] = met->ts[0][iy];
    met->us[met->nx - 1][iy] = met->us[0][iy];
    met->vs[met->nx - 1][iy] = met->vs[0][iy];
    met->lsm[met->nx - 1][iy] = met->lsm[0][iy];
    met->sst[met->nx - 1][iy] = met->sst[0][iy];
    for (int ip = 0; ip < met->np; ip++) {
      met->t[met->nx - 1][iy][ip] = met->t[0][iy][ip];
      met->u[met->nx - 1][iy][ip] = met->u[0][iy][ip];
      met->v[met->nx - 1][iy][ip] = met->v[0][iy][ip];
      met->w[met->nx - 1][iy][ip] = met->w[0][iy][ip];
      met->h2o[met->nx - 1][iy][ip] = met->h2o[0][iy][ip];
      met->o3[met->nx - 1][iy][ip] = met->o3[0][iy][ip];
      met->lwc[met->nx - 1][iy][ip] = met->lwc[0][iy][ip];
      met->rwc[met->nx - 1][iy][ip] = met->rwc[0][iy][ip];
      met->iwc[met->nx - 1][iy][ip] = met->iwc[0][iy][ip];
      met->swc[met->nx - 1][iy][ip] = met->swc[0][iy][ip];
      met->cc[met->nx - 1][iy][ip] = met->cc[0][iy][ip];
    }
    for (int ip = 0; ip < met->npl; ip++) {
      met->ul[met->nx - 1][iy][ip] = met->ul[0][iy][ip];
      met->vl[met->nx - 1][iy][ip] = met->vl[0][iy][ip];
      met->wl[met->nx - 1][iy][ip] = met->wl[0][iy][ip];
      met->pl[met->nx - 1][iy][ip] = met->pl[0][iy][ip];
      met->zetal[met->nx - 1][iy][ip] = met->zetal[0][iy][ip];
      met->zeta_dotl[met->nx - 1][iy][ip] = met->zeta_dotl[0][iy][ip];
    }
  }
}
 
/*****************************************************************************/
 
void read_met_polar_winds(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_POLAR_WINDS", "METPROC", NVTX_READ);
  LOG(2, "Apply fix for polar winds...");
 
  /* Check latitudes... */
  if (fabs(met->lat[0]) < 89.999 || fabs(met->lat[met->ny - 1]) < 89.999)
    return;
 
  /* Loop over hemispheres... */
  for (int ihem = 0; ihem < 2; ihem++) {
 
    /* Set latitude indices... */
    int i89 = 1, i90 = 0, sign = 1;
    if (ihem == 1) {
      i89 = met->ny - 2;
      i90 = met->ny - 1;
    }
    if (met->lat[i90] < 0)
      sign = -1;
 
    /* Look-up table of cosinus and sinus... */
    double clon[EX], slon[EX];
#pragma omp parallel for default(shared)
    for (int ix = 0; ix < met->nx; ix++) {
      clon[ix] = cos(sign * met->lon[ix] / 180. * M_PI);
      slon[ix] = sin(sign * met->lon[ix] / 180. * M_PI);
    }
 
    /* Loop over levels... */
#pragma omp parallel for default(shared)
    for (int ip = 0; ip < met->np; ip++) {
 
      /* Transform 89 degree u and v winds into Cartesian coordinates and take the mean... */
      double vel89x = 0, vel89y = 0;
      for (int ix = 0; ix < met->nx; ix++) {
        vel89x +=
          (met->u[ix][i89][ip] * clon[ix] -
           met->v[ix][i89][ip] * slon[ix]) / met->nx;
        vel89y +=
          (met->u[ix][i89][ip] * slon[ix] +
           met->v[ix][i89][ip] * clon[ix]) / met->nx;
      }
 
      /* Replace 90 degree winds by 89 degree mean... */
      for (int ix = 0; ix < met->nx; ix++) {
        met->u[ix][i90][ip]
          = (float) (vel89x * clon[ix] + vel89y * slon[ix]);
        met->v[ix][i90][ip]
          = (float) (-vel89x * slon[ix] + vel89y * clon[ix]);
      }
    }
  }
}
 
/*****************************************************************************/
 
void read_met_pv(
  met_t * met) {
 
  double pows[EP];
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_PV", "METPROC", NVTX_READ);
  LOG(2, "Calculate potential vorticity...");
 
  /* Set powers... */
#pragma omp parallel for default(shared)
  for (int ip = 0; ip < met->np; ip++)
    pows[ip] = pow(1000. / met->p[ip], 0.286);
 
  /* Loop over grid points... */
#pragma omp parallel for default(shared)
  for (int ix = 0; ix < met->nx; ix++) {
 
    /* Set indices... */
    int ix0 = MAX(ix - 1, 0);
    int ix1 = MIN(ix + 1, met->nx - 1);
 
    /* Loop over grid points... */
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Set indices... */
      int iy0 = MAX(iy - 1, 0);
      int iy1 = MIN(iy + 1, met->ny - 1);
 
      /* Set auxiliary variables... */
      double latr = 0.5 * (met->lat[iy1] + met->lat[iy0]);
      double dx = 1000. * DEG2DX(met->lon[ix1] - met->lon[ix0], latr);
      double dy = 1000. * DEG2DY(met->lat[iy1] - met->lat[iy0]);
      double c0 = cos(met->lat[iy0] / 180. * M_PI);
      double c1 = cos(met->lat[iy1] / 180. * M_PI);
      double cr = cos(latr / 180. * M_PI);
      double vort = 2 * 7.2921e-5 * sin(latr * M_PI / 180.);
 
      /* Loop over grid points... */
      for (int ip = 0; ip < met->np; ip++) {
 
        /* Get gradients in longitude... */
        double dtdx
          = (met->t[ix1][iy][ip] - met->t[ix0][iy][ip]) * pows[ip] / dx;
        double dvdx = (met->v[ix1][iy][ip] - met->v[ix0][iy][ip]) / dx;
 
        /* Get gradients in latitude... */
        double dtdy
          = (met->t[ix][iy1][ip] - met->t[ix][iy0][ip]) * pows[ip] / dy;
        double dudy
          = (met->u[ix][iy1][ip] * c1 - met->u[ix][iy0][ip] * c0) / dy;
 
        /* Set indices... */
        int ip0 = MAX(ip - 1, 0);
        int ip1 = MIN(ip + 1, met->np - 1);
 
        /* Get gradients in pressure... */
        double dtdp, dudp, dvdp;
        double dp0 = 100. * (met->p[ip] - met->p[ip0]);
        double dp1 = 100. * (met->p[ip1] - met->p[ip]);
        if (ip != ip0 && ip != ip1) {
          double denom = dp0 * dp1 * (dp0 + dp1);
          dtdp = (dp0 * dp0 * met->t[ix][iy][ip1] * pows[ip1]
                  - dp1 * dp1 * met->t[ix][iy][ip0] * pows[ip0]
                  + (dp1 * dp1 - dp0 * dp0) * met->t[ix][iy][ip] * pows[ip])
            / denom;
          dudp = (dp0 * dp0 * met->u[ix][iy][ip1]
                  - dp1 * dp1 * met->u[ix][iy][ip0]
                  + (dp1 * dp1 - dp0 * dp0) * met->u[ix][iy][ip])
            / denom;
          dvdp = (dp0 * dp0 * met->v[ix][iy][ip1]
                  - dp1 * dp1 * met->v[ix][iy][ip0]
                  + (dp1 * dp1 - dp0 * dp0) * met->v[ix][iy][ip])
            / denom;
        } else {
          double denom = dp0 + dp1;
          dtdp =
            (met->t[ix][iy][ip1] * pows[ip1] -
             met->t[ix][iy][ip0] * pows[ip0]) / denom;
          dudp = (met->u[ix][iy][ip1] - met->u[ix][iy][ip0]) / denom;
          dvdp = (met->v[ix][iy][ip1] - met->v[ix][iy][ip0]) / denom;
        }
 
        /* Calculate PV... */
        met->pv[ix][iy][ip] = (float)
          (1e6 * G0 *
           (-dtdp * (dvdx - dudy / cr + vort) + dvdp * dtdx - dudp * dtdy));
      }
    }
  }
 
  /* Fix for polar regions... */
#pragma omp parallel for default(shared)
  for (int ix = 0; ix < met->nx; ix++)
    for (int ip = 0; ip < met->np; ip++) {
      met->pv[ix][0][ip]
        = met->pv[ix][1][ip]
        = met->pv[ix][2][ip];
      met->pv[ix][met->ny - 1][ip]
        = met->pv[ix][met->ny - 2][ip]
        = met->pv[ix][met->ny - 3][ip];
    }
}
 
/*****************************************************************************/
 
void read_met_ozone(
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_OZONE", "METPROC", NVTX_READ);
  LOG(2, "Calculate total column ozone...");
 
  /* Loop over columns... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
 
      /* Integrate... */
      double cd = 0;
      for (int ip = 1; ip < met->np; ip++)
        if (met->p[ip - 1] <= met->ps[ix][iy]) {
          double vmr = 0.5 * (met->o3[ix][iy][ip - 1] + met->o3[ix][iy][ip]);
          double dp = met->p[ip - 1] - met->p[ip];
          cd += vmr * MO3 / MA * dp * 1e2 / G0;
        }
 
      /* Convert to Dobson units... */
      met->o3c[ix][iy] = (float) (cd / 2.1415e-5);
    }
}
 
/*****************************************************************************/
 
void read_met_sample(
  ctl_t * ctl,
  met_t * met) {
 
  met_t *help;
 
  /* Check parameters... */
  if (ctl->met_dp <= 1 && ctl->met_dx <= 1 && ctl->met_dy <= 1
      && ctl->met_sp <= 1 && ctl->met_sx <= 1 && ctl->met_sy <= 1)
    return;
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_SAMPLE", "METPROC", NVTX_READ);
  LOG(2, "Downsampling of meteo data...");
 
  /* Allocate... */
  ALLOC(help, met_t, 1);
 
  /* Copy data... */
  help->nx = met->nx;
  help->ny = met->ny;
  help->np = met->np;
  memcpy(help->lon, met->lon, sizeof(met->lon));
  memcpy(help->lat, met->lat, sizeof(met->lat));
  memcpy(help->p, met->p, sizeof(met->p));
 
  /* Smoothing... */
  for (int ix = 0; ix < met->nx; ix += ctl->met_dx) {
    for (int iy = 0; iy < met->ny; iy += ctl->met_dy) {
      for (int ip = 0; ip < met->np; ip += ctl->met_dp) {
        help->ps[ix][iy] = 0;
        help->zs[ix][iy] = 0;
        help->ts[ix][iy] = 0;
        help->us[ix][iy] = 0;
        help->vs[ix][iy] = 0;
        help->lsm[ix][iy] = 0;
        help->sst[ix][iy] = 0;
        help->t[ix][iy][ip] = 0;
        help->u[ix][iy][ip] = 0;
        help->v[ix][iy][ip] = 0;
        help->w[ix][iy][ip] = 0;
        help->h2o[ix][iy][ip] = 0;
        help->o3[ix][iy][ip] = 0;
        help->lwc[ix][iy][ip] = 0;
        help->rwc[ix][iy][ip] = 0;
        help->iwc[ix][iy][ip] = 0;
        help->swc[ix][iy][ip] = 0;
        help->cc[ix][iy][ip] = 0;
        float wsum = 0;
        for (int ix2 = ix - ctl->met_sx + 1; ix2 <= ix + ctl->met_sx - 1;
             ix2++) {
          int ix3 = ix2;
          if (ix3 < 0)
            ix3 += met->nx;
          else if (ix3 >= met->nx)
            ix3 -= met->nx;
 
          for (int iy2 = MAX(iy - ctl->met_sy + 1, 0);
               iy2 <= MIN(iy + ctl->met_sy - 1, met->ny - 1); iy2++)
            for (int ip2 = MAX(ip - ctl->met_sp + 1, 0);
                 ip2 <= MIN(ip + ctl->met_sp - 1, met->np - 1); ip2++) {
              float w = (1.0f - (float) abs(ix - ix2) / (float) ctl->met_sx)
                * (1.0f - (float) abs(iy - iy2) / (float) ctl->met_sy)
                * (1.0f - (float) abs(ip - ip2) / (float) ctl->met_sp);
              help->ps[ix][iy] += w * met->ps[ix3][iy2];
              help->zs[ix][iy] += w * met->zs[ix3][iy2];
              help->ts[ix][iy] += w * met->ts[ix3][iy2];
              help->us[ix][iy] += w * met->us[ix3][iy2];
              help->vs[ix][iy] += w * met->vs[ix3][iy2];
              help->lsm[ix][iy] += w * met->lsm[ix3][iy2];
              help->sst[ix][iy] += w * met->sst[ix3][iy2];
              help->t[ix][iy][ip] += w * met->t[ix3][iy2][ip2];
              help->u[ix][iy][ip] += w * met->u[ix3][iy2][ip2];
              help->v[ix][iy][ip] += w * met->v[ix3][iy2][ip2];
              help->w[ix][iy][ip] += w * met->w[ix3][iy2][ip2];
              help->h2o[ix][iy][ip] += w * met->h2o[ix3][iy2][ip2];
              help->o3[ix][iy][ip] += w * met->o3[ix3][iy2][ip2];
              help->lwc[ix][iy][ip] += w * met->lwc[ix3][iy2][ip2];
              help->rwc[ix][iy][ip] += w * met->rwc[ix3][iy2][ip2];
              help->iwc[ix][iy][ip] += w * met->iwc[ix3][iy2][ip2];
              help->swc[ix][iy][ip] += w * met->swc[ix3][iy2][ip2];
              help->cc[ix][iy][ip] += w * met->cc[ix3][iy2][ip2];
              wsum += w;
            }
        }
        help->ps[ix][iy] /= wsum;
        help->zs[ix][iy] /= wsum;
        help->ts[ix][iy] /= wsum;
        help->us[ix][iy] /= wsum;
        help->vs[ix][iy] /= wsum;
        help->lsm[ix][iy] /= wsum;
        help->sst[ix][iy] /= wsum;
        help->t[ix][iy][ip] /= wsum;
        help->u[ix][iy][ip] /= wsum;
        help->v[ix][iy][ip] /= wsum;
        help->w[ix][iy][ip] /= wsum;
        help->h2o[ix][iy][ip] /= wsum;
        help->o3[ix][iy][ip] /= wsum;
        help->lwc[ix][iy][ip] /= wsum;
        help->rwc[ix][iy][ip] /= wsum;
        help->iwc[ix][iy][ip] /= wsum;
        help->swc[ix][iy][ip] /= wsum;
        help->cc[ix][iy][ip] /= wsum;
      }
    }
  }
 
  /* Downsampling... */
  met->nx = 0;
  for (int ix = 0; ix < help->nx; ix += ctl->met_dx) {
    met->lon[met->nx] = help->lon[ix];
    met->ny = 0;
    for (int iy = 0; iy < help->ny; iy += ctl->met_dy) {
      met->lat[met->ny] = help->lat[iy];
      met->ps[met->nx][met->ny] = help->ps[ix][iy];
      met->zs[met->nx][met->ny] = help->zs[ix][iy];
      met->ts[met->nx][met->ny] = help->ts[ix][iy];
      met->us[met->nx][met->ny] = help->us[ix][iy];
      met->vs[met->nx][met->ny] = help->vs[ix][iy];
      met->lsm[met->nx][met->ny] = help->lsm[ix][iy];
      met->sst[met->nx][met->ny] = help->sst[ix][iy];
      met->np = 0;
      for (int ip = 0; ip < help->np; ip += ctl->met_dp) {
        met->p[met->np] = help->p[ip];
        met->t[met->nx][met->ny][met->np] = help->t[ix][iy][ip];
        met->u[met->nx][met->ny][met->np] = help->u[ix][iy][ip];
        met->v[met->nx][met->ny][met->np] = help->v[ix][iy][ip];
        met->w[met->nx][met->ny][met->np] = help->w[ix][iy][ip];
        met->h2o[met->nx][met->ny][met->np] = help->h2o[ix][iy][ip];
        met->o3[met->nx][met->ny][met->np] = help->o3[ix][iy][ip];
        met->lwc[met->nx][met->ny][met->np] = help->lwc[ix][iy][ip];
        met->rwc[met->nx][met->ny][met->np] = help->rwc[ix][iy][ip];
        met->iwc[met->nx][met->ny][met->np] = help->iwc[ix][iy][ip];
        met->swc[met->nx][met->ny][met->np] = help->swc[ix][iy][ip];
        met->cc[met->nx][met->ny][met->np] = help->cc[ix][iy][ip];
        met->np++;
      }
      met->ny++;
    }
    met->nx++;
  }
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void read_met_surface(
  int ncid,
  met_t * met,
  ctl_t * ctl) {
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_SURFACE", "INPUT", NVTX_READ);
  LOG(2, "Read surface data...");
 
  /* MPTRAC meteo data... */
  if (ctl->met_clams == 0) {
 
    /* Read surface pressure... */
    if (read_met_nc_2d
        (ncid, "lnsp", "LNSP", NULL, NULL, ctl, met, met->ps, 1.0f, 1)) {
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++)
          met->ps[ix][iy] = (float) (exp(met->ps[ix][iy]) / 100.);
    } else
      if (!read_met_nc_2d
          (ncid, "ps", "PS", "sp", "SP", ctl, met, met->ps, 0.01f, 1)) {
      WARN("Cannot not read surface pressure data (use lowest level)!");
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++)
          met->ps[ix][iy] = (float) met->p[0];
    }
 
    /* Read geopotential height at the surface... */
    if (!read_met_nc_2d
        (ncid, "z", "Z", NULL, NULL, ctl, met, met->zs,
         (float) (1. / (1000. * G0)), 1))
      if (!read_met_nc_2d
          (ncid, "zm", "ZM", NULL, NULL, ctl, met, met->zs,
           (float) (1. / 1000.), 1))
        WARN("Cannot read surface geopotential height!");
 
    /* Read temperature at the surface... */
    if (!read_met_nc_2d
        (ncid, "t2m", "T2M", "2t", "2T", ctl, met, met->ts, 1.0, 1))
      WARN("Cannot read surface temperature!");
 
    /* Read zonal wind at the surface... */
    if (!read_met_nc_2d
        (ncid, "u10m", "U10M", "10u", "10U", ctl, met, met->us, 1.0, 1))
      WARN("Cannot read surface zonal wind!");
 
    /* Read meridional wind at the surface... */
    if (!read_met_nc_2d
        (ncid, "v10m", "V10M", "10v", "10V", ctl, met, met->vs, 1.0, 1))
      WARN("Cannot read surface meridional wind!");
 
    /* Read land-sea mask... */
    if (!read_met_nc_2d
        (ncid, "lsm", "LSM", NULL, NULL, ctl, met, met->lsm, 1.0, 1))
      WARN("Cannot read land-sea mask!");
 
    /* Read sea surface temperature... */
    if (!read_met_nc_2d
        (ncid, "sstk", "SSTK", "sst", "SST", ctl, met, met->sst, 1.0, 1))
      WARN("Cannot read sea surface temperature!");
  }
 
  /* CLaMS meteo data... */
  else {
 
    /* Read surface pressure... */
    if (!read_met_nc_2d
        (ncid, "ps", "PS", NULL, NULL, ctl, met, met->ps, 0.01f, 1)) {
      WARN("Cannot not read surface pressure data (use lowest level)!");
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++)
          met->ps[ix][iy] = (float) met->p[0];
    }
 
    /* Read geopotential height at the surface
       (use lowermost level of 3-D data field)... */
    float *help;
    ALLOC(help, float,
          EX * EY * EP);
    memcpy(help, met->pl, sizeof(met->pl));
    if (!read_met_nc_3d
        (ncid, "gph", "GPH", NULL, NULL, ctl, met, met->pl,
         (float) (1e-3 / G0))) {
      ERRMSG("Cannot read geopotential height!");
    } else
      for (int ix = 0; ix < met->nx; ix++)
        for (int iy = 0; iy < met->ny; iy++)
          met->zs[ix][iy] = met->pl[ix][iy][0];
    memcpy(met->pl, help, sizeof(met->pl));
    free(help);
 
    /* Read temperature at the surface... */
    if (!read_met_nc_2d
        (ncid, "t2", "T2", NULL, NULL, ctl, met, met->ts, 1.0, 1))
      WARN("Cannot read surface temperature!");
 
    /* Read zonal wind at the surface... */
    if (!read_met_nc_2d
        (ncid, "u10", "U10", NULL, NULL, ctl, met, met->us, 1.0, 1))
      WARN("Cannot read surface zonal wind!");
 
    /* Read meridional wind at the surface... */
    if (!read_met_nc_2d
        (ncid, "v10", "V10", NULL, NULL, ctl, met, met->vs, 1.0, 1))
      WARN("Cannot read surface meridional wind!");
 
    /* Read land-sea mask... */
    if (!read_met_nc_2d
        (ncid, "lsm", "LSM", NULL, NULL, ctl, met, met->lsm, 1.0, 1))
      WARN("Cannot read land-sea mask!");
 
    /* Read sea surface temperature... */
    if (!read_met_nc_2d
        (ncid, "sstk", "SSTK", NULL, NULL, ctl, met, met->sst, 1.0, 1))
      WARN("Cannot read sea surface temperature!");
  }
}
 
/*****************************************************************************/
 
void read_met_tropo(
  ctl_t * ctl,
  clim_t * clim,
  met_t * met) {
 
  double p2[200], pv[EP], pv2[200], t[EP], t2[200], th[EP],
    th2[200], z[EP], z2[200];
 
  /* Set timer... */
  SELECT_TIMER("READ_MET_TROPO", "METPROC", NVTX_READ);
  LOG(2, "Calculate tropopause...");
 
  /* Get altitude and pressure profiles... */
#pragma omp parallel for default(shared)
  for (int iz = 0; iz < met->np; iz++)
    z[iz] = Z(met->p[iz]);
#pragma omp parallel for default(shared)
  for (int iz = 0; iz <= 190; iz++) {
    z2[iz] = 4.5 + 0.1 * iz;
    p2[iz] = P(z2[iz]);
  }
 
  /* Do not calculate tropopause... */
  if (ctl->met_tropo == 0)
#pragma omp parallel for default(shared) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        met->pt[ix][iy] = NAN;
 
  /* Use tropopause climatology... */
  else if (ctl->met_tropo == 1) {
#pragma omp parallel for default(shared) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++)
        met->pt[ix][iy] = (float) clim_tropo(clim, met->time, met->lat[iy]);
  }
 
  /* Use cold point... */
  else if (ctl->met_tropo == 2) {
 
    /* Loop over grid points... */
#pragma omp parallel for default(shared) private(t,t2) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++) {
 
        /* Interpolate temperature profile... */
        for (int iz = 0; iz < met->np; iz++)
          t[iz] = met->t[ix][iy][iz];
        spline(z, t, met->np, z2, t2, 171, ctl->met_tropo_spline);
 
        /* Find minimum... */
        int iz = (int) gsl_stats_min_index(t2, 1, 171);
        if (iz > 0 && iz < 170)
          met->pt[ix][iy] = (float) p2[iz];
        else
          met->pt[ix][iy] = NAN;
      }
  }
 
  /* Use WMO definition... */
  else if (ctl->met_tropo == 3 || ctl->met_tropo == 4) {
 
    /* Loop over grid points... */
#pragma omp parallel for default(shared) private(t,t2) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++) {
 
        /* Interpolate temperature profile... */
        int iz;
        for (iz = 0; iz < met->np; iz++)
          t[iz] = met->t[ix][iy][iz];
        spline(z, t, met->np, z2, t2, 191, ctl->met_tropo_spline);
 
        /* Find 1st tropopause... */
        met->pt[ix][iy] = NAN;
        for (iz = 0; iz <= 170; iz++) {
          int found = 1;
          for (int iz2 = iz + 1; iz2 <= iz + 20; iz2++)
            if (LAPSE(p2[iz], t2[iz], p2[iz2], t2[iz2]) > 2.0) {
              found = 0;
              break;
            }
          if (found) {
            if (iz > 0 && iz < 170)
              met->pt[ix][iy] = (float) p2[iz];
            break;
          }
        }
 
        /* Find 2nd tropopause... */
        if (ctl->met_tropo == 4) {
          met->pt[ix][iy] = NAN;
          for (; iz <= 170; iz++) {
            int found = 1;
            for (int iz2 = iz + 1; iz2 <= iz + 10; iz2++)
              if (LAPSE(p2[iz], t2[iz], p2[iz2], t2[iz2]) < 3.0) {
                found = 0;
                break;
              }
            if (found)
              break;
          }
          for (; iz <= 170; iz++) {
            int found = 1;
            for (int iz2 = iz + 1; iz2 <= iz + 20; iz2++)
              if (LAPSE(p2[iz], t2[iz], p2[iz2], t2[iz2]) > 2.0) {
                found = 0;
                break;
              }
            if (found) {
              if (iz > 0 && iz < 170)
                met->pt[ix][iy] = (float) p2[iz];
              break;
            }
          }
        }
      }
  }
 
  /* Use dynamical tropopause... */
  else if (ctl->met_tropo == 5) {
 
    /* Loop over grid points... */
#pragma omp parallel for default(shared) private(pv,pv2,th,th2) collapse(2)
    for (int ix = 0; ix < met->nx; ix++)
      for (int iy = 0; iy < met->ny; iy++) {
 
        /* Interpolate potential vorticity profile... */
        for (int iz = 0; iz < met->np; iz++)
          pv[iz] = met->pv[ix][iy][iz];
        spline(z, pv, met->np, z2, pv2, 171, ctl->met_tropo_spline);
 
        /* Interpolate potential temperature profile... */
        for (int iz = 0; iz < met->np; iz++)
          th[iz] = THETA(met->p[iz], met->t[ix][iy][iz]);
        spline(z, th, met->np, z2, th2, 171, ctl->met_tropo_spline);
 
        /* Find dynamical tropopause... */
        met->pt[ix][iy] = NAN;
        for (int iz = 0; iz <= 170; iz++)
          if (fabs(pv2[iz]) >= ctl->met_tropo_pv
              || th2[iz] >= ctl->met_tropo_theta) {
            if (iz > 0 && iz < 170)
              met->pt[ix][iy] = (float) p2[iz];
            break;
          }
      }
  }
 
  else
    ERRMSG("Cannot calculate tropopause!");
 
  /* Interpolate temperature, geopotential height, and water vapor... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++) {
      double h2ot, tt, zt;
      INTPOL_INIT;
      intpol_met_space_3d(met, met->t, met->pt[ix][iy], met->lon[ix],
                          met->lat[iy], &tt, ci, cw, 1);
      intpol_met_space_3d(met, met->z, met->pt[ix][iy], met->lon[ix],
                          met->lat[iy], &zt, ci, cw, 0);
      intpol_met_space_3d(met, met->h2o, met->pt[ix][iy], met->lon[ix],
                          met->lat[iy], &h2ot, ci, cw, 0);
      met->tt[ix][iy] = (float) tt;
      met->zt[ix][iy] = (float) zt;
      met->h2ot[ix][iy] = (float) h2ot;
    }
}
 
/*****************************************************************************/
 
void read_obs(
  const char *filename,
  ctl_t * ctl,
  double *rt,
  double *rz,
  double *rlon,
  double *rlat,
  double *robs,
  int *nobs) {
 
  /* Write info... */
  LOG(1, "Read observation data: %s", filename);
 
  /* Read data... */
  if (ctl->obs_type == 0)
    read_obs_asc(filename, rt, rz, rlon, rlat, robs, nobs);
  else if (ctl->obs_type == 1)
    read_obs_nc(filename, rt, rz, rlon, rlat, robs, nobs);
  else
    ERRMSG("Set OBS_TYPE to 0 or 1!");
 
  /* Check time... */
  for (int i = 1; i < *nobs; i++)
    if (rt[i] < rt[i - 1])
      ERRMSG("Time must be ascending!");
 
  /* Write info... */
  int n = *nobs;
  double mini, maxi;
  LOG(2, "Number of observations: %d", *nobs);
  gsl_stats_minmax(&mini, &maxi, rt, 1, (size_t) n);
  LOG(2, "Time range: %.2f ... %.2f s", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, rz, 1, (size_t) n);
  LOG(2, "Altitude range: %g ... %g km", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, rlon, 1, (size_t) n);
  LOG(2, "Longitude range: %g ... %g deg", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, rlat, 1, (size_t) n);
  LOG(2, "Latitude range: %g ... %g deg", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, robs, 1, (size_t) n);
  LOG(2, "Observation range: %g ... %g", mini, maxi);
}
 
/*****************************************************************************/
 
void read_obs_asc(
  const char *filename,
  double *rt,
  double *rz,
  double *rlon,
  double *rlat,
  double *robs,
  int *nobs) {
 
  /* Open observation data file... */
  FILE *in;
  if (!(in = fopen(filename, "r")))
    ERRMSG("Cannot open file!");
 
  /* Read observations... */
  char line[LEN];
  while (fgets(line, LEN, in))
    if (sscanf(line, "%lg %lg %lg %lg %lg", &rt[*nobs], &rz[*nobs],
               &rlon[*nobs], &rlat[*nobs], &robs[*nobs]) == 5)
      if ((++(*nobs)) >= NOBS)
        ERRMSG("Too many observations!");
 
  /* Close observation data file... */
  fclose(in);
}
 
/*****************************************************************************/
 
void read_obs_nc(
  const char *filename,
  double *rt,
  double *rz,
  double *rlon,
  double *rlat,
  double *robs,
  int *nobs) {
 
  int ncid, varid;
 
  /* Open netCDF file... */
  if (nc_open(filename, NC_NOWRITE, &ncid) != NC_NOERR)
    ERRMSG("Cannot open file!");
 
  /* Read the observations from the NetCDF file... */
  NC_INQ_DIM("nobs", nobs, 1, NOBS);
  NC_GET_DOUBLE("time", rt, 1);
  NC_GET_DOUBLE("alt", rz, 1);
  NC_GET_DOUBLE("lon", rlon, 1);
  NC_GET_DOUBLE("lat", rlat, 1);
  NC_GET_DOUBLE("obs", robs, 1);
 
  /* Close file... */
  NC(nc_close(ncid));
}
 
/*****************************************************************************/
 
double scan_ctl(
  const char *filename,
  int argc,
  char *argv[],
  const char *varname,
  int arridx,
  const char *defvalue,
  char *value) {
 
  FILE *in = NULL;
 
  char fullname1[LEN], fullname2[LEN], rval[LEN];
 
  int contain = 0, i;
 
  /* Open file... */
  if (filename[strlen(filename) - 1] != '-')
    if (!(in = fopen(filename, "r")))
      ERRMSG("Cannot open file!");
 
  /* Set full variable name... */
  if (arridx >= 0) {
    sprintf(fullname1, "%s[%d]", varname, arridx);
    sprintf(fullname2, "%s[*]", varname);
  } else {
    sprintf(fullname1, "%s", varname);
    sprintf(fullname2, "%s", varname);
  }
 
  /* Read data... */
  if (in != NULL) {
    char dummy[LEN], line[LEN], rvarname[LEN];
    while (fgets(line, LEN, in)) {
      if (sscanf(line, "%4999s %4999s %4999s", rvarname, dummy, rval) == 3)
        if (strcasecmp(rvarname, fullname1) == 0 ||
            strcasecmp(rvarname, fullname2) == 0) {
          contain = 1;
          break;
        }
    }
  }
  for (i = 1; i < argc - 1; i++)
    if (strcasecmp(argv[i], fullname1) == 0 ||
        strcasecmp(argv[i], fullname2) == 0) {
      sprintf(rval, "%s", argv[i + 1]);
      contain = 1;
      break;
    }
 
  /* Close file... */
  if (in != NULL)
    fclose(in);
 
  /* Check for missing variables... */
  if (!contain) {
    if (strlen(defvalue) > 0)
      sprintf(rval, "%s", defvalue);
    else
      ERRMSG("Missing variable %s!\n", fullname1);
  }
 
  /* Write info... */
  LOG(1, "%s = %s", fullname1, rval);
 
  /* Return values... */
  if (value != NULL)
    sprintf(value, "%s", rval);
  return atof(rval);
}
 
/*****************************************************************************/
 
double sedi(
  const double p,
  const double T,
  const double rp,
  const double rhop) {
 
  /* Convert particle radius from microns to m... */
  double rp_help = rp * 1e-6;
 
  /* Density of dry air [kg / m^3]... */
  double rho = RHO(p, T);
 
  /* Dynamic viscosity of air [kg / (m s)]... */
  double eta = 1.8325e-5 * (416.16 / (T + 120.)) * pow(T / 296.16, 1.5);
 
  /* Thermal velocity of an air molecule [m / s]... */
  double v = sqrt(8. * KB * T / (M_PI * 4.8096e-26));
 
  /* Mean free path of an air molecule [m]... */
  double lambda = 2. * eta / (rho * v);
 
  /* Knudsen number for air (dimensionless)... */
  double K = lambda / rp_help;
 
  /* Cunningham slip-flow correction (dimensionless)... */
  double G = 1. + K * (1.249 + 0.42 * exp(-0.87 / K));
 
  /* Sedimentation velocity [m / s]... */
  return 2. * SQR(rp_help) * (rhop - rho) * G0 / (9. * eta) * G;
}
 
/*****************************************************************************/
 
void spline(
  const double *x,
  const double *y,
  const int n,
  const double *x2,
  double *y2,
  const int n2,
  const int method) {
 
  /* Cubic spline interpolation... */
  if (method == 1) {
 
    /* Allocate... */
    gsl_interp_accel *acc;
    gsl_spline *s;
    acc = gsl_interp_accel_alloc();
    s = gsl_spline_alloc(gsl_interp_cspline, (size_t) n);
 
    /* Interpolate profile... */
    gsl_spline_init(s, x, y, (size_t) n);
    for (int i = 0; i < n2; i++)
      if (x2[i] <= x[0])
        y2[i] = y[0];
      else if (x2[i] >= x[n - 1])
        y2[i] = y[n - 1];
      else
        y2[i] = gsl_spline_eval(s, x2[i], acc);
 
    /* Free... */
    gsl_spline_free(s);
    gsl_interp_accel_free(acc);
  }
 
  /* Linear interpolation... */
  else {
    for (int i = 0; i < n2; i++)
      if (x2[i] <= x[0])
        y2[i] = y[0];
      else if (x2[i] >= x[n - 1])
        y2[i] = y[n - 1];
      else {
        int idx = locate_irr(x, n, x2[i]);
        y2[i] = LIN(x[idx], y[idx], x[idx + 1], y[idx + 1], x2[i]);
      }
  }
}
 
/*****************************************************************************/
 
float stddev(
  const float *data,
  const int n) {
 
  if (n <= 0)
    return 0;
 
  float mean = 0, var = 0;
 
  for (int i = 0; i < n; ++i) {
    mean += data[i];
    var += SQR(data[i]);
  }
 
  var = var / (float) n - SQR(mean / (float) n);
 
  return (var > 0 ? sqrtf(var) : 0);
}
 
/*****************************************************************************/
 
double sza_calc(
  const double sec,
  const double lon,
  const double lat) {
 
  /* Number of days and fraction with respect to 2000-01-01T12:00Z... */
  const double D = sec / 86400 - 0.5;
 
  /* Geocentric apparent ecliptic longitude [rad]... */
  const double g = (357.529 + 0.98560028 * D) * M_PI / 180;
  const double q = 280.459 + 0.98564736 * D;
  const double L = (q + 1.915 * sin(g) + 0.020 * sin(2 * g)) * M_PI / 180;
 
  /* Mean obliquity of the ecliptic [rad]... */
  const double e = (23.439 - 0.00000036 * D) * M_PI / 180;
 
  /* Declination [rad]... */
  const double sindec = sin(e) * sin(L);
 
  /* Right ascension [rad]... */
  const double ra = atan2(cos(e) * sin(L), cos(L));
 
  /* Greenwich Mean Sidereal Time [h]... */
  const double GMST = 18.697374558 + 24.06570982441908 * D;
 
  /* Local Sidereal Time [h]... */
  const double LST = GMST + lon / 15;
 
  /* Hour angle [rad]... */
  const double h = LST / 12 * M_PI - ra;
 
  /* Convert latitude... */
  const double lat_help = lat * M_PI / 180;
 
  /* Return solar zenith angle [rad]... */
  return acos(sin(lat_help) * sindec +
              cos(lat_help) * sqrt(1 - SQR(sindec)) * cos(h));
}
 
/*****************************************************************************/
 
void time2jsec(
  const int year,
  const int mon,
  const int day,
  const int hour,
  const int min,
  const int sec,
  const double remain,
  double *jsec) {
 
  struct tm t0, t1;
 
  t0.tm_year = 100;
  t0.tm_mon = 0;
  t0.tm_mday = 1;
  t0.tm_hour = 0;
  t0.tm_min = 0;
  t0.tm_sec = 0;
 
  t1.tm_year = year - 1900;
  t1.tm_mon = mon - 1;
  t1.tm_mday = day;
  t1.tm_hour = hour;
  t1.tm_min = min;
  t1.tm_sec = sec;
 
  *jsec = (double) timegm(&t1) - (double) timegm(&t0) + remain;
}
 
/*****************************************************************************/
 
void timer(
  const char *name,
  const char *group,
  int output) {
 
  static char names[NTIMER][100], groups[NTIMER][100];
 
  static double rt_name[NTIMER], rt_group[NTIMER],
    rt_min[NTIMER], rt_max[NTIMER], dt, t0, t1;
 
  static int iname = -1, igroup = -1, nname, ngroup, ct_name[NTIMER];
 
  /* Get time... */
  t1 = omp_get_wtime();
  dt = t1 - t0;
 
  /* Add elapsed time to current timers... */
  if (iname >= 0) {
    rt_name[iname] += dt;
    rt_min[iname] = (ct_name[iname] <= 0 ? dt : MIN(rt_min[iname], dt));
    rt_max[iname] = (ct_name[iname] <= 0 ? dt : MAX(rt_max[iname], dt));
    ct_name[iname]++;
  }
  if (igroup >= 0)
    rt_group[igroup] += t1 - t0;
 
  /* Report timers... */
  if (output) {
    for (int i = 0; i < nname; i++)
      LOG(1, "TIMER_%s = %.3f s    (min= %g s, mean= %g s,"
          " max= %g s, n= %d)", names[i], rt_name[i], rt_min[i],
          rt_name[i] / ct_name[i], rt_max[i], ct_name[i]);
    for (int i = 0; i < ngroup; i++)
      LOG(1, "TIMER_GROUP_%s = %.3f s", groups[i], rt_group[i]);
    double total = 0.0;
    for (int i = 0; i < nname; i++)
      total += rt_name[i];
    LOG(1, "TIMER_TOTAL = %.3f s", total);
  }
 
  /* Identify IDs of next timer... */
  for (iname = 0; iname < nname; iname++)
    if (strcasecmp(name, names[iname]) == 0)
      break;
  for (igroup = 0; igroup < ngroup; igroup++)
    if (strcasecmp(group, groups[igroup]) == 0)
      break;
 
  /* Check whether this is a new timer... */
  if (iname >= nname) {
    sprintf(names[iname], "%s", name);
    if ((++nname) >= NTIMER)
      ERRMSG("Too many timers!");
  }
 
  /* Check whether this is a new group... */
  if (igroup >= ngroup) {
    sprintf(groups[igroup], "%s", group);
    if ((++ngroup) >= NTIMER)
      ERRMSG("Too many groups!");
  }
 
  /* Save starting time... */
  t0 = t1;
}
 
/*****************************************************************************/
 
double time_from_filename(
  const char *filename,
  int offset) {
 
  char tstr[10];
 
  double t;
 
  /* Get time from filename... */
  int len = (int) strlen(filename);
  sprintf(tstr, "%.4s", &filename[len - offset]);
  int year = atoi(tstr);
  sprintf(tstr, "%.2s", &filename[len - offset + 5]);
  int mon = atoi(tstr);
  sprintf(tstr, "%.2s", &filename[len - offset + 8]);
  int day = atoi(tstr);
  sprintf(tstr, "%.2s", &filename[len - offset + 11]);
  int hour = atoi(tstr);
  sprintf(tstr, "%.2s", &filename[len - offset + 14]);
  int min = atoi(tstr);
 
  /* Check time... */
  if (year < 1900 || year > 2100 || mon < 1 || mon > 12 || day < 1
      || day > 31 || hour < 0 || hour > 23 || min < 0 || min > 59)
    ERRMSG("Cannot read time from filename!");
 
  /* Convert time to Julian seconds... */
  time2jsec(year, mon, day, hour, min, 0, 0.0, &t);
 
  /* Return time... */
  return t;
}
 
/*****************************************************************************/
 
double tropo_weight(
  const clim_t * clim,
  const double t,
  const double lat,
  const double p) {
 
  /* Get tropopause pressure... */
  double pt = clim_tropo(clim, t, lat);
 
  /* Get pressure range... */
  double p1 = pt * 0.866877899;
  double p0 = pt / 0.866877899;
 
  /* Get weighting factor... */
  if (p > p0)
    return 1;
  else if (p < p1)
    return 0;
  else
    return LIN(p0, 1.0, p1, 0.0, p);
}
 
/*****************************************************************************/
 
void write_atm(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  /* Set timer... */
  SELECT_TIMER("WRITE_ATM", "OUTPUT", NVTX_WRITE);
 
  /* Write info... */
  LOG(1, "Write atmospheric data: %s", filename);
 
  /* Write ASCII data... */
  if (ctl->atm_type_out == 0)
    write_atm_asc(filename, ctl, atm, t);
 
  /* Write binary data... */
  else if (ctl->atm_type_out == 1)
    write_atm_bin(filename, ctl, atm);
 
  /* Write netCDF data... */
  else if (ctl->atm_type_out == 2)
    write_atm_nc(filename, ctl, atm);
 
  /* Write CLaMS trajectory data... */
  else if (ctl->atm_type_out == 3)
    write_atm_clams_traj(filename, ctl, atm, t);
 
  /* Write CLaMS pos data... */
  else if (ctl->atm_type_out == 4)
    write_atm_clams(filename, ctl, atm);
 
  /* Error... */
  else
    ERRMSG("Atmospheric data type not supported!");
 
  /* Write info... */
  double mini, maxi;
  LOG(2, "Number of particles: %d", atm->np);
  gsl_stats_minmax(&mini, &maxi, atm->time, 1, (size_t) atm->np);
  LOG(2, "Time range: %.2f ... %.2f s", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, atm->p, 1, (size_t) atm->np);
  LOG(2, "Altitude range: %g ... %g km", Z(maxi), Z(mini));
  LOG(2, "Pressure range: %g ... %g hPa", maxi, mini);
  gsl_stats_minmax(&mini, &maxi, atm->lon, 1, (size_t) atm->np);
  LOG(2, "Longitude range: %g ... %g deg", mini, maxi);
  gsl_stats_minmax(&mini, &maxi, atm->lat, 1, (size_t) atm->np);
  LOG(2, "Latitude range: %g ... %g deg", mini, maxi);
  for (int iq = 0; iq < ctl->nq; iq++) {
    char msg[5 * LEN];
    sprintf(msg, "Quantity %s range: %s ... %s %s",
            ctl->qnt_name[iq], ctl->qnt_format[iq],
            ctl->qnt_format[iq], ctl->qnt_unit[iq]);
    gsl_stats_minmax(&mini, &maxi, atm->q[iq], 1, (size_t) atm->np);
    LOG(2, msg, mini, maxi);
  }
}
 
/*****************************************************************************/
 
void write_atm_asc(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  FILE *out;
 
  /* Set time interval for output... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Check if gnuplot output is requested... */
  if (ctl->atm_gpfile[0] != '-') {
 
    /* Create gnuplot pipe... */
    if (!(out = popen("gnuplot", "w")))
      ERRMSG("Cannot create pipe to gnuplot!");
 
    /* Set plot filename... */
    fprintf(out, "set out \"%s.png\"\n", filename);
 
    /* Set time string... */
    double r;
    int year, mon, day, hour, min, sec;
    jsec2time(t, &year, &mon, &day, &hour, &min, &sec, &r);
    fprintf(out, "timestr=\"%d-%02d-%02d, %02d:%02d UTC\"\n",
            year, mon, day, hour, min);
 
    /* Dump gnuplot file to pipe... */
    FILE *in;
    if (!(in = fopen(ctl->atm_gpfile, "r")))
      ERRMSG("Cannot open file!");
    char line[LEN];
    while (fgets(line, LEN, in))
      fprintf(out, "%s", line);
    fclose(in);
  }
 
  else {
 
    /* Create file... */
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
  }
 
  /* Write header... */
  fprintf(out,
          "# $1 = time [s]\n"
          "# $2 = altitude [km]\n"
          "# $3 = longitude [deg]\n" "# $4 = latitude [deg]\n");
  for (int iq = 0; iq < ctl->nq; iq++)
    fprintf(out, "# $%i = %s [%s]\n", iq + 5, ctl->qnt_name[iq],
            ctl->qnt_unit[iq]);
  fprintf(out, "\n");
 
  /* Write data... */
  for (int ip = 0; ip < atm->np; ip += ctl->atm_stride) {
 
    /* Check time... */
    if (ctl->atm_filter == 2 && (atm->time[ip] < t0 || atm->time[ip] > t1))
      continue;
 
    /* Write output... */
    fprintf(out, "%.2f %g %g %g", atm->time[ip], Z(atm->p[ip]),
            atm->lon[ip], atm->lat[ip]);
    for (int iq = 0; iq < ctl->nq; iq++) {
      fprintf(out, " ");
      if (ctl->atm_filter == 1 && (atm->time[ip] < t0 || atm->time[ip] > t1))
        fprintf(out, ctl->qnt_format[iq], NAN);
      else
        fprintf(out, ctl->qnt_format[iq], atm->q[iq][ip]);
    }
    fprintf(out, "\n");
  }
 
  /* Close file... */
  fclose(out);
}
 
/*****************************************************************************/
 
void write_atm_bin(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  FILE *out;
 
  /* Create file... */
  if (!(out = fopen(filename, "w")))
    ERRMSG("Cannot create file!");
 
  /* Write version of binary data... */
  int version = 100;
  FWRITE(&version, int,
         1,
         out);
 
  /* Write data... */
  FWRITE(&atm->np, int,
         1,
         out);
  FWRITE(atm->time, double,
           (size_t) atm->np,
         out);
  FWRITE(atm->p, double,
           (size_t) atm->np,
         out);
  FWRITE(atm->lon, double,
           (size_t) atm->np,
         out);
  FWRITE(atm->lat, double,
           (size_t) atm->np,
         out);
  for (int iq = 0; iq < ctl->nq; iq++)
    FWRITE(atm->q[iq], double,
             (size_t) atm->np,
           out);
 
  /* Write final flag... */
  int final = 999;
  FWRITE(&final, int,
         1,
         out);
 
  /* Close file... */
  fclose(out);
}
 
/*****************************************************************************/
 
void write_atm_clams(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  int tid, pid, ncid, varid;
  size_t start[2], count[2];
 
  /* Create file... */
  nc_create(filename, NC_CLOBBER, &ncid);
 
  /* Define dimensions... */
  NC(nc_def_dim(ncid, "time", 1, &tid));
  NC(nc_def_dim(ncid, "NPARTS", (size_t) atm->np, &pid));
 
  /* Define variables and their attributes... */
  int dim_ids[2] = { tid, pid };
  NC_DEF_VAR("time", NC_DOUBLE, 1, &tid, "Time",
             "seconds since 2000-01-01 00:00:00 UTC");
  NC_DEF_VAR("LAT", NC_DOUBLE, 1, &pid, "Latitude", "deg");
  NC_DEF_VAR("LON", NC_DOUBLE, 1, &pid, "Longitude", "deg");
  NC_DEF_VAR("PRESS", NC_DOUBLE, 1, &pid, "Pressure", "hPa");
  NC_DEF_VAR("ZETA", NC_DOUBLE, 1, &pid, "Zeta", "K");
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_DEF_VAR(ctl->qnt_name[iq], NC_DOUBLE, 2, dim_ids,
               ctl->qnt_name[iq], ctl->qnt_unit[iq]);
 
  /* Define global attributes... */
  NC_PUT_ATT_GLOBAL("exp_VERTCOOR_name", "zeta");
  NC_PUT_ATT_GLOBAL("model", "MPTRAC");
 
  /* End definitions... */
  NC(nc_enddef(ncid));
 
  /* Write data... */
  NC_PUT_DOUBLE("time", atm->time, 0);
  NC_PUT_DOUBLE("LAT", atm->lat, 0);
  NC_PUT_DOUBLE("LON", atm->lon, 0);
  NC_PUT_DOUBLE("PRESS", atm->p, 0);
  NC_PUT_DOUBLE("ZETA", atm->q[ctl->qnt_zeta_d], 0);
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_PUT_DOUBLE(ctl->qnt_name[iq], atm->q[iq], 0);
 
  /* Close file... */
  NC(nc_close(ncid));
}
 
/*****************************************************************************/
 
void write_atm_clams_traj(
  const char *dirname,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  /* Global Counter... */
  static size_t out_cnt = 0;
 
  double r, r_start, r_stop;
  int year, mon, day, hour, min, sec;
  int year_start, mon_start, day_start, hour_start, min_start, sec_start;
  int year_stop, mon_stop, day_stop, hour_stop, min_stop, sec_stop;
  char filename_out[2 * LEN] = "traj_fix_3d_YYYYMMDDHH_YYYYMMDDHH.nc";
 
  int ncid, varid, tid, pid, cid;
  int dim_ids[2];
 
  /* time, nparc */
  size_t start[2];
  size_t count[2];
 
  /* Determine start and stop times of calculation... */
  jsec2time(t, &year, &mon, &day, &hour, &min, &sec, &r);
  jsec2time(ctl->t_start, &year_start, &mon_start, &day_start, &hour_start,
            &min_start, &sec_start, &r_start);
  jsec2time(ctl->t_stop, &year_stop, &mon_stop, &day_stop, &hour_stop,
            &min_stop, &sec_stop, &r_stop);
 
  sprintf(filename_out, "%s/traj_fix_3d_%02d%02d%02d%02d_%02d%02d%02d%02d.nc",
          dirname,
          year_start % 100, mon_start, day_start, hour_start,
          year_stop % 100, mon_stop, day_stop, hour_stop);
  LOG(1, "Write traj file: %s", filename_out);
 
  /* Define hyperslap for the traj_file... */
  start[0] = out_cnt;
  start[1] = 0;
  count[0] = 1;
  count[1] = (size_t) atm->np;
 
  /* Create the file at the first timestep... */
  if (out_cnt == 0) {
 
    /* Create file... */
    nc_create(filename_out, NC_CLOBBER, &ncid);
 
    /* Define dimensions... */
    NC(nc_def_dim(ncid, "time", NC_UNLIMITED, &tid));
    NC(nc_def_dim(ncid, "NPARTS", (size_t) atm->np, &pid));
    NC(nc_def_dim(ncid, "TMDT", 7, &cid));
    dim_ids[0] = tid;
    dim_ids[1] = pid;
 
    /* Define variables and their attributes... */
    NC_DEF_VAR("time", NC_DOUBLE, 1, &tid, "Time",
               "seconds since 2000-01-01 00:00:00 UTC");
    NC_DEF_VAR("LAT", NC_DOUBLE, 2, dim_ids, "Latitude", "deg");
    NC_DEF_VAR("LON", NC_DOUBLE, 2, dim_ids, "Longitude", "deg");
    NC_DEF_VAR("PRESS", NC_DOUBLE, 2, dim_ids, "Pressure", "hPa");
    NC_DEF_VAR("ZETA", NC_DOUBLE, 2, dim_ids, "Zeta", "K");
    for (int iq = 0; iq < ctl->nq; iq++)
      NC_DEF_VAR(ctl->qnt_name[iq], NC_DOUBLE, 2, dim_ids,
                 ctl->qnt_name[iq], ctl->qnt_unit[iq]);
 
    /* Define global attributes... */
    NC_PUT_ATT_GLOBAL("exp_VERTCOOR_name", "zeta");
    NC_PUT_ATT_GLOBAL("model", "MPTRAC");
 
    /* End definitions... */
    NC(nc_enddef(ncid));
    NC(nc_close(ncid));
  }
 
  /* Increment global counter to change hyperslap... */
  out_cnt++;
 
  /* Open file... */
  NC(nc_open(filename_out, NC_WRITE, &ncid));
 
  /* Write data... */
  NC_PUT_DOUBLE("time", atm->time, 1);
  NC_PUT_DOUBLE("LAT", atm->lat, 1);
  NC_PUT_DOUBLE("LON", atm->lon, 1);
  NC_PUT_DOUBLE("PRESS", atm->p, 1);
  if (ctl->advect_vert_coord == 1) {
    NC_PUT_DOUBLE("ZETA", atm->q[ctl->qnt_zeta], 1);
  } else if (ctl->qnt_zeta >= 0) {
    NC_PUT_DOUBLE("ZETA", atm->q[ctl->qnt_zeta_d], 1);
  }
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_PUT_DOUBLE(ctl->qnt_name[iq], atm->q[iq], 1);
 
  /* Close file... */
  NC(nc_close(ncid));
 
  /* At the last time step create the init_fix_YYYYMMDDHH file... */
  if ((year == year_stop) && (mon == mon_stop)
      && (day == day_stop) && (hour == hour_stop)) {
 
    /* Set filename... */
    char filename_init[2 * LEN] = "./init_fix_YYYYMMDDHH.nc";
    sprintf(filename_init, "%s/init_fix_%02d%02d%02d%02d.nc",
            dirname, year_stop % 100, mon_stop, day_stop, hour_stop);
    LOG(1, "Write init file: %s", filename_init);
 
    /* Create file... */
    nc_create(filename_init, NC_CLOBBER, &ncid);
 
    /* Define dimensions... */
    NC(nc_def_dim(ncid, "time", 1, &tid));
    NC(nc_def_dim(ncid, "NPARTS", (size_t) atm->np, &pid));
    dim_ids[0] = tid;
    dim_ids[1] = pid;
 
    /* Define variables and their attributes... */
    NC_DEF_VAR("time", NC_DOUBLE, 1, &tid, "Time",
               "seconds since 2000-01-01 00:00:00 UTC");
    NC_DEF_VAR("LAT", NC_DOUBLE, 1, &pid, "Latitude", "deg");
    NC_DEF_VAR("LON", NC_DOUBLE, 1, &pid, "Longitude", "deg");
    NC_DEF_VAR("PRESS", NC_DOUBLE, 1, &pid, "Pressure", "hPa");
    NC_DEF_VAR("ZETA", NC_DOUBLE, 1, &pid, "Zeta", "K");
    for (int iq = 0; iq < ctl->nq; iq++)
      NC_DEF_VAR(ctl->qnt_name[iq], NC_DOUBLE, 2, dim_ids,
                 ctl->qnt_name[iq], ctl->qnt_unit[iq]);
 
    /* Define global attributes... */
    NC_PUT_ATT_GLOBAL("exp_VERTCOOR_name", "zeta");
    NC_PUT_ATT_GLOBAL("model", "MPTRAC");
 
    /* End definitions... */
    NC(nc_enddef(ncid));
 
    /* Write data... */
    NC_PUT_DOUBLE("time", atm->time, 0);
    NC_PUT_DOUBLE("LAT", atm->lat, 0);
    NC_PUT_DOUBLE("LON", atm->lon, 0);
    NC_PUT_DOUBLE("PRESS", atm->p, 0);
    NC_PUT_DOUBLE("ZETA", atm->q[ctl->qnt_zeta_d], 0);
    for (int iq = 0; iq < ctl->nq; iq++)
      NC_PUT_DOUBLE(ctl->qnt_name[iq], atm->q[iq], 0);
 
    /* Close file... */
    NC(nc_close(ncid));
  }
}
 
/*****************************************************************************/
 
void write_atm_nc(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm) {
 
  int ncid, obsid, varid;
 
  size_t start[2], count[2];
 
  /* Create file... */
  NC(nc_create(filename, NC_CLOBBER, &ncid));
 
  /* Define dimensions... */
  NC(nc_def_dim(ncid, "obs", (size_t) atm->np, &obsid));
 
  /* Define variables and their attributes... */
  NC_DEF_VAR("time", NC_DOUBLE, 1, &obsid, "time",
             "seconds since 2000-01-01 00:00:00 UTC");
  NC_DEF_VAR("press", NC_DOUBLE, 1, &obsid, "pressure", "hPa");
  NC_DEF_VAR("lon", NC_DOUBLE, 1, &obsid, "longitude", "degrees_east");
  NC_DEF_VAR("lat", NC_DOUBLE, 1, &obsid, "latitude", "degrees_north");
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_DEF_VAR(ctl->qnt_name[iq], NC_DOUBLE, 1, &obsid,
               ctl->qnt_longname[iq], ctl->qnt_unit[iq]);
 
  /* Define global attributes... */
  NC_PUT_ATT_GLOBAL("featureType", "point");
 
  /* End definitions... */
  NC(nc_enddef(ncid));
 
  /* Write data... */
  NC_PUT_DOUBLE("time", atm->time, 0);
  NC_PUT_DOUBLE("press", atm->p, 0);
  NC_PUT_DOUBLE("lon", atm->lon, 0);
  NC_PUT_DOUBLE("lat", atm->lat, 0);
  for (int iq = 0; iq < ctl->nq; iq++)
    NC_PUT_DOUBLE(ctl->qnt_name[iq], atm->q[iq], 0);
 
  /* Close file... */
  NC(nc_close(ncid));
}
 
/*****************************************************************************/
 
void write_csi(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  static FILE *out;
 
  static double *modmean, *obsmean, *obsstd, *rt, *rz, *rlon, *rlat, *robs,
    *area, dlon, dlat, dz, x[NCSI], y[NCSI], obsstdn[NCSI], kz[EP], kw[EP];
 
  static int *obscount, ct, cx, cy, cz, ip, ix, iy, iz, n, nobs, nk;
 
  /* Set timer... */
  SELECT_TIMER("WRITE_CSI", "OUTPUT", NVTX_WRITE);
 
  /* Init... */
  if (t == ctl->t_start) {
 
    /* Check quantity index for mass... */
    if (ctl->qnt_m < 0)
      ERRMSG("Need quantity mass!");
 
    /* Allocate... */
    ALLOC(area, double,
          ctl->csi_ny);
    ALLOC(rt, double,
          NOBS);
    ALLOC(rz, double,
          NOBS);
    ALLOC(rlon, double,
          NOBS);
    ALLOC(rlat, double,
          NOBS);
    ALLOC(robs, double,
          NOBS);
 
    /* Read observation data... */
    read_obs(ctl->csi_obsfile, ctl, rt, rz, rlon, rlat, robs, &nobs);
 
    /* Read kernel data... */
    if (ctl->csi_kernel[0] != '-')
      read_kernel(ctl->csi_kernel, kz, kw, &nk);
 
    /* Create new file... */
    LOG(1, "Write CSI data: %s", filename);
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
 
    /* Write header... */
    fprintf(out,
            "# $1 = time [s]\n"
            "# $2 = number of hits (cx)\n"
            "# $3 = number of misses (cy)\n"
            "# $4 = number of false alarms (cz)\n"
            "# $5 = number of observations (cx + cy)\n"
            "# $6 = number of forecasts (cx + cz)\n"
            "# $7 = bias (ratio of forecasts and observations) [%%]\n"
            "# $8 = probability of detection (POD) [%%]\n"
            "# $9 = false alarm rate (FAR) [%%]\n"
            "# $10 = critical success index (CSI) [%%]\n");
    fprintf(out,
            "# $11 = hits associated with random chance\n"
            "# $12 = equitable threat score (ETS) [%%]\n"
            "# $13 = Pearson linear correlation coefficient\n"
            "# $14 = Spearman rank-order correlation coefficient\n"
            "# $15 = column density mean error (F - O) [kg/m^2]\n"
            "# $16 = column density root mean square error (RMSE) [kg/m^2]\n"
            "# $17 = column density mean absolute error [kg/m^2]\n"
            "# $18 = log-likelihood function\n"
            "# $19 = number of data points\n\n");
 
    /* Set grid box size... */
    dz = (ctl->csi_z1 - ctl->csi_z0) / ctl->csi_nz;
    dlon = (ctl->csi_lon1 - ctl->csi_lon0) / ctl->csi_nx;
    dlat = (ctl->csi_lat1 - ctl->csi_lat0) / ctl->csi_ny;
 
    /* Set horizontal coordinates... */
    for (iy = 0; iy < ctl->csi_ny; iy++) {
      double lat = ctl->csi_lat0 + dlat * (iy + 0.5);
      area[iy] = dlat * dlon * SQR(RE * M_PI / 180.) * cos(lat * M_PI / 180.);
    }
  }
 
  /* Set time interval... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Allocate... */
  ALLOC(modmean, double,
        ctl->csi_nx * ctl->csi_ny * ctl->csi_nz);
  ALLOC(obsmean, double,
        ctl->csi_nx * ctl->csi_ny * ctl->csi_nz);
  ALLOC(obscount, int,
        ctl->csi_nx * ctl->csi_ny * ctl->csi_nz);
  ALLOC(obsstd, double,
        ctl->csi_nx * ctl->csi_ny * ctl->csi_nz);
 
  /* Loop over observations... */
  for (int i = 0; i < nobs; i++) {
 
    /* Check time... */
    if (rt[i] < t0)
      continue;
    else if (rt[i] >= t1)
      break;
 
    /* Check observation data... */
    if (!isfinite(robs[i]))
      continue;
 
    /* Calculate indices... */
    ix = (int) ((rlon[i] - ctl->csi_lon0) / dlon);
    iy = (int) ((rlat[i] - ctl->csi_lat0) / dlat);
    iz = (int) ((rz[i] - ctl->csi_z0) / dz);
 
    /* Check indices... */
    if (ix < 0 || ix >= ctl->csi_nx ||
        iy < 0 || iy >= ctl->csi_ny || iz < 0 || iz >= ctl->csi_nz)
      continue;
 
    /* Get mean observation index... */
    int idx = ARRAY_3D(ix, iy, ctl->csi_ny, iz, ctl->csi_nz);
    obsmean[idx] += robs[i];
    obsstd[idx] += SQR(robs[i]);
    obscount[idx]++;
  }
 
  /* Analyze model data... */
  for (ip = 0; ip < atm->np; ip++) {
 
    /* Check time... */
    if (atm->time[ip] < t0 || atm->time[ip] > t1)
      continue;
 
    /* Get indices... */
    ix = (int) ((atm->lon[ip] - ctl->csi_lon0) / dlon);
    iy = (int) ((atm->lat[ip] - ctl->csi_lat0) / dlat);
    iz = (int) ((Z(atm->p[ip]) - ctl->csi_z0) / dz);
 
    /* Check indices... */
    if (ix < 0 || ix >= ctl->csi_nx ||
        iy < 0 || iy >= ctl->csi_ny || iz < 0 || iz >= ctl->csi_nz)
      continue;
 
    /* Get total mass in grid cell... */
    int idx = ARRAY_3D(ix, iy, ctl->csi_ny, iz, ctl->csi_nz);
    modmean[idx] += kernel_weight(kz, kw, nk, atm->p[ip])
      * atm->q[ctl->qnt_m][ip];
  }
 
  /* Analyze all grid cells... */
  for (ix = 0; ix < ctl->csi_nx; ix++)
    for (iy = 0; iy < ctl->csi_ny; iy++)
      for (iz = 0; iz < ctl->csi_nz; iz++) {
 
        /* Calculate mean observation index... */
        int idx = ARRAY_3D(ix, iy, ctl->csi_ny, iz, ctl->csi_nz);
        if (obscount[idx] > 0) {
          obsmean[idx] /= obscount[idx];
          obsstd[idx] -= SQR(obsmean[idx]);
          obsstd[idx] = sqrt(obsstd[idx]);
        }
 
        /* Calculate column density... */
        if (modmean[idx] > 0)
          modmean[idx] /= (1e6 * area[iy]);
 
        /* Calculate CSI... */
        if (obscount[idx] > 0) {
          ct++;
          if (obsmean[idx] >= ctl->csi_obsmin &&
              modmean[idx] >= ctl->csi_modmin)
            cx++;
          else if (obsmean[idx] >= ctl->csi_obsmin &&
                   modmean[idx] < ctl->csi_modmin)
            cy++;
          else if (obsmean[idx] < ctl->csi_obsmin &&
                   modmean[idx] >= ctl->csi_modmin)
            cz++;
        }
 
        /* Save data for other verification statistics... */
        if (obscount[idx] > 0
            && (obsmean[idx] >= ctl->csi_obsmin
                || modmean[idx] >= ctl->csi_modmin)) {
          x[n] = modmean[idx];
          y[n] = obsmean[idx];
          if (modmean[idx] >= ctl->csi_modmin)
            obsstdn[n] = obsstd[idx];
          if ((++n) >= NCSI)
            ERRMSG("Too many data points to calculate statistics!");
        }
      }
 
  /* Write output... */
  if (fmod(t, ctl->csi_dt_out) == 0) {
 
    /* Calculate verification statistics
       (https://www.cawcr.gov.au/projects/verification/) ... */
    static double work[2 * NCSI], work2[2 * NCSI];;
    int n_obs = cx + cy;
    int n_for = cx + cz;
    double bias = (n_obs > 0) ? 100. * n_for / n_obs : NAN;
    double pod = (n_obs > 0) ? (100. * cx) / n_obs : NAN;
    double far = (n_for > 0) ? (100. * cz) / n_for : NAN;
    double csi = (cx + cy + cz > 0) ? (100. * cx) / (cx + cy + cz) : NAN;
    double cx_rd = (ct > 0) ? (1. * n_obs * n_for) / ct : NAN;
    double ets = (cx + cy + cz - cx_rd > 0) ?
      (100. * (cx - cx_rd)) / (cx + cy + cz - cx_rd) : NAN;
    double rho_p =
      (n > 0) ? gsl_stats_correlation(x, 1, y, 1, (size_t) n) : NAN;
    double rho_s =
      (n > 0) ? gsl_stats_spearman(x, 1, y, 1, (size_t) n, work) : NAN;
    for (int i = 0; i < n; i++) {
      work[i] = x[i] - y[i];
      work2[i] = (obsstdn[i] != 0) ? (x[i] - y[i]) / obsstdn[i] : 0;
    }
    double mean = (n > 0) ? gsl_stats_mean(work, 1, (size_t) n) : NAN;
    double rmse = (n > 0) ? gsl_stats_sd_with_fixed_mean(work, 1, (size_t) n,
                                                         0.0) : NAN;
    double absdev =
      (n > 0) ? gsl_stats_absdev_m(work, 1, (size_t) n, 0.0) : NAN;
    double loglikelihood =
      (n > 0) ? gsl_stats_tss(work2, 1, (size_t) n) * (-0.5) : GSL_NAN;
 
    /* Write... */
    fprintf(out,
            "%.2f %d %d %d %d %d %g %g %g %g %g %g %g %g %g %g %g %g %d\n", t,
            cx, cy, cz, n_obs, n_for, bias, pod, far, csi, cx_rd, ets, rho_p,
            rho_s, mean, rmse, absdev, loglikelihood, n);
 
    /* Set counters to zero... */
    n = ct = cx = cy = cz = 0;
  }
 
  /* Free... */
  free(modmean);
  free(obsmean);
  free(obscount);
  free(obsstd);
 
  /* Finalize... */
  if (t == ctl->t_stop) {
 
    /* Close output file... */
    fclose(out);
 
    /* Free... */
    free(area);
    free(rt);
    free(rz);
    free(rlon);
    free(rlat);
    free(robs);
  }
}
 
/*****************************************************************************/
 
void write_ens(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  static FILE *out;
 
  static double dummy, lat, lon, qm[NQ][NENS], qs[NQ][NENS], xm[NENS][3],
    x[3], zm[NENS];
 
  static int n[NENS];
 
  /* Set timer... */
  SELECT_TIMER("WRITE_ENS", "OUTPUT", NVTX_WRITE);
 
  /* Check quantities... */
  if (ctl->qnt_ens < 0)
    ERRMSG("Missing ensemble IDs!");
 
  /* Set time interval... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Init... */
  for (int i = 0; i < NENS; i++) {
    for (int iq = 0; iq < ctl->nq; iq++)
      qm[iq][i] = qs[iq][i] = 0;
    xm[i][0] = xm[i][1] = xm[i][2] = zm[i] = 0;
    n[i] = 0;
  }
 
  /* Loop over air parcels... */
  for (int ip = 0; ip < atm->np; ip++) {
 
    /* Check time... */
    if (atm->time[ip] < t0 || atm->time[ip] > t1)
      continue;
 
    /* Check ensemble ID... */
    if (atm->q[ctl->qnt_ens][ip] < 0 || atm->q[ctl->qnt_ens][ip] >= NENS)
      ERRMSG("Ensemble ID is out of range!");
 
    /* Get means... */
    geo2cart(0, atm->lon[ip], atm->lat[ip], x);
    for (int iq = 0; iq < ctl->nq; iq++) {
      qm[iq][ctl->qnt_ens] += atm->q[iq][ip];
      qs[iq][ctl->qnt_ens] += SQR(atm->q[iq][ip]);
    }
    xm[ctl->qnt_ens][0] += x[0];
    xm[ctl->qnt_ens][1] += x[1];
    xm[ctl->qnt_ens][2] += x[2];
    zm[ctl->qnt_ens] += Z(atm->p[ip]);
    n[ctl->qnt_ens]++;
  }
 
  /* Create file... */
  LOG(1, "Write ensemble data: %s", filename);
  if (!(out = fopen(filename, "w")))
    ERRMSG("Cannot create file!");
 
  /* Write header... */
  fprintf(out,
          "# $1 = time [s]\n"
          "# $2 = altitude [km]\n"
          "# $3 = longitude [deg]\n" "# $4 = latitude [deg]\n");
  for (int iq = 0; iq < ctl->nq; iq++)
    fprintf(out, "# $%d = %s (mean) [%s]\n", 5 + iq,
            ctl->qnt_name[iq], ctl->qnt_unit[iq]);
  for (int iq = 0; iq < ctl->nq; iq++)
    fprintf(out, "# $%d = %s (sigma) [%s]\n", 5 + ctl->nq + iq,
            ctl->qnt_name[iq], ctl->qnt_unit[iq]);
  fprintf(out, "# $%d = number of members\n\n", 5 + 2 * ctl->nq);
 
  /* Write data... */
  for (int i = 0; i < NENS; i++)
    if (n[i] > 0) {
      cart2geo(xm[i], &dummy, &lon, &lat);
      fprintf(out, "%.2f %g %g %g", t, zm[i] / n[i], lon, lat);
      for (int iq = 0; iq < ctl->nq; iq++) {
        fprintf(out, " ");
        fprintf(out, ctl->qnt_format[iq], qm[iq][i] / n[i]);
      }
      for (int iq = 0; iq < ctl->nq; iq++) {
        fprintf(out, " ");
        double var = qs[iq][i] / n[i] - SQR(qm[iq][i] / n[i]);
        fprintf(out, ctl->qnt_format[iq], (var > 0 ? sqrt(var) : 0));
      }
      fprintf(out, " %d\n", n[i]);
    }
 
  /* Close file... */
  fclose(out);
}
 
/*****************************************************************************/
 
void write_grid(
  const char *filename,
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double t) {
 
  static double kz[EP], kw[EP];
 
  static int nk;
 
  double *cd, *mean[NQ], *sigma[NQ], *vmr_impl, *z, *lon, *lat, *area, *press;
 
  int *ixs, *iys, *izs, *np;
 
  /* Set timer... */
  SELECT_TIMER("WRITE_GRID", "OUTPUT", NVTX_WRITE);
 
  /* Write info... */
  LOG(1, "Write grid data: %s", filename);
 
  /* Init... */
  if (t == ctl->t_start) {
 
    /* Read kernel data... */
    if (ctl->grid_kernel[0] != '-')
      read_kernel(ctl->grid_kernel, kz, kw, &nk);
  }
 
  /* Allocate... */
  ALLOC(cd, double,
        ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
  for (int iq = 0; iq < ctl->nq; iq++) {
    ALLOC(mean[iq], double,
          ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
    ALLOC(sigma[iq], double,
          ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
  }
  ALLOC(vmr_impl, double,
        ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
  ALLOC(z, double,
        ctl->grid_nz);
  ALLOC(lon, double,
        ctl->grid_nx);
  ALLOC(lat, double,
        ctl->grid_ny);
  ALLOC(area, double,
        ctl->grid_ny);
  ALLOC(press, double,
        ctl->grid_nz);
  ALLOC(np, int,
        ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
  ALLOC(ixs, int,
        atm->np);
  ALLOC(iys, int,
        atm->np);
  ALLOC(izs, int,
        atm->np);
 
  /* Set grid box size... */
  double dz = (ctl->grid_z1 - ctl->grid_z0) / ctl->grid_nz;
  double dlon = (ctl->grid_lon1 - ctl->grid_lon0) / ctl->grid_nx;
  double dlat = (ctl->grid_lat1 - ctl->grid_lat0) / ctl->grid_ny;
 
  /* Set vertical coordinates... */
#pragma omp parallel for default(shared)
  for (int iz = 0; iz < ctl->grid_nz; iz++) {
    z[iz] = ctl->grid_z0 + dz * (iz + 0.5);
    press[iz] = P(z[iz]);
  }
 
  /* Set horizontal coordinates... */
  for (int ix = 0; ix < ctl->grid_nx; ix++)
    lon[ix] = ctl->grid_lon0 + dlon * (ix + 0.5);
#pragma omp parallel for default(shared)
  for (int iy = 0; iy < ctl->grid_ny; iy++) {
    lat[iy] = ctl->grid_lat0 + dlat * (iy + 0.5);
    area[iy] = dlat * dlon * SQR(RE * M_PI / 180.)
      * cos(lat[iy] * M_PI / 180.);
  }
 
  /* Set time interval for output... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Get grid box indices... */
#pragma omp parallel for default(shared)
  for (int ip = 0; ip < atm->np; ip++) {
    ixs[ip] = (int) ((atm->lon[ip] - ctl->grid_lon0) / dlon);
    iys[ip] = (int) ((atm->lat[ip] - ctl->grid_lat0) / dlat);
    izs[ip] = (int) ((Z(atm->p[ip]) - ctl->grid_z0) / dz);
    if (atm->time[ip] < t0 || atm->time[ip] > t1
        || ixs[ip] < 0 || ixs[ip] >= ctl->grid_nx
        || iys[ip] < 0 || iys[ip] >= ctl->grid_ny
        || izs[ip] < 0 || izs[ip] >= ctl->grid_nz)
      izs[ip] = -1;
  }
 
  /* Average data... */
  for (int ip = 0; ip < atm->np; ip++)
    if (izs[ip] >= 0) {
      int idx =
        ARRAY_3D(ixs[ip], iys[ip], ctl->grid_ny, izs[ip], ctl->grid_nz);
      double kernel = kernel_weight(kz, kw, nk, atm->p[ip]);
      np[idx]++;
      for (int iq = 0; iq < ctl->nq; iq++) {
        mean[iq][idx] += kernel * atm->q[iq][ip];
        sigma[iq][idx] += SQR(kernel * atm->q[iq][ip]);
      }
    }
 
  /* Calculate column density and volume mixing ratio... */
#pragma omp parallel for default(shared)
  for (int ix = 0; ix < ctl->grid_nx; ix++)
    for (int iy = 0; iy < ctl->grid_ny; iy++)
      for (int iz = 0; iz < ctl->grid_nz; iz++) {
 
        /* Get grid index... */
        int idx = ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz);
 
        /* Calculate column density... */
        cd[idx] = NAN;
        if (ctl->qnt_m >= 0)
          cd[idx] = mean[ctl->qnt_m][idx] / (1e6 * area[iy]);
 
        /* Calculate volume mixing ratio (implicit)... */
        vmr_impl[idx] = NAN;
        if (ctl->qnt_m >= 0 && ctl->molmass > 0 && met0 != NULL
            && met1 != NULL) {
          vmr_impl[idx] = 0;
          if (mean[ctl->qnt_m][idx] > 0) {
 
            /* Get temperature... */
            double temp;
            INTPOL_INIT;
            intpol_met_time_3d(met0, met0->t, met1, met1->t, t, press[iz],
                               lon[ix], lat[iy], &temp, ci, cw, 1);
 
            /* Calculate volume mixing ratio... */
            vmr_impl[idx] = MA / ctl->molmass * mean[ctl->qnt_m][idx]
              / (RHO(press[iz], temp) * 1e6 * area[iy] * 1e3 * dz);
          }
        }
 
        /* Calculate mean... */
        if (np[idx] > 0)
          for (int iq = 0; iq < ctl->nq; iq++) {
            mean[iq][idx] /= np[idx];
            double var = sigma[iq][idx] / np[idx] - SQR(mean[iq][idx]);
            sigma[iq][idx] = (var > 0 ? sqrt(var) : 0);
        } else
          for (int iq = 0; iq < ctl->nq; iq++) {
            mean[iq][idx] = NAN;
            sigma[iq][idx] = NAN;
          }
      }
 
  /* Write ASCII data... */
  if (ctl->grid_type == 0)
    write_grid_asc(filename, ctl, cd, mean, sigma, vmr_impl,
                   t, z, lon, lat, area, dz, np);
 
  /* Write netCDF data... */
  else if (ctl->grid_type == 1)
    write_grid_nc(filename, ctl, cd, mean, sigma, vmr_impl,
                  t, z, lon, lat, area, dz, np);
 
  /* Error message... */
  else
    ERRMSG("Grid data format GRID_TYPE unknown!");
 
  /* Free... */
  free(cd);
  for (int iq = 0; iq < ctl->nq; iq++) {
    free(mean[iq]);
    free(sigma[iq]);
  }
  free(vmr_impl);
  free(z);
  free(lon);
  free(lat);
  free(area);
  free(press);
  free(np);
  free(ixs);
  free(iys);
  free(izs);
}
 
/*****************************************************************************/
 
void write_grid_asc(
  const char *filename,
  ctl_t * ctl,
  double *cd,
  double *mean[NQ],
  double *sigma[NQ],
  double *vmr_impl,
  double t,
  double *z,
  double *lon,
  double *lat,
  double *area,
  double dz,
  int *np) {
 
  FILE *out;
 
  /* Check if gnuplot output is requested... */
  if (ctl->grid_gpfile[0] != '-') {
 
    /* Create gnuplot pipe... */
    if (!(out = popen("gnuplot", "w")))
      ERRMSG("Cannot create pipe to gnuplot!");
 
    /* Set plot filename... */
    fprintf(out, "set out \"%s.png\"\n", filename);
 
    /* Set time string... */
    double r;
    int year, mon, day, hour, min, sec;
    jsec2time(t, &year, &mon, &day, &hour, &min, &sec, &r);
    fprintf(out, "timestr=\"%d-%02d-%02d, %02d:%02d UTC\"\n",
            year, mon, day, hour, min);
 
    /* Dump gnuplot file to pipe... */
    FILE *in;
    char line[LEN];
    if (!(in = fopen(ctl->grid_gpfile, "r")))
      ERRMSG("Cannot open file!");
    while (fgets(line, LEN, in))
      fprintf(out, "%s", line);
    fclose(in);
  }
 
  else {
 
    /* Create file... */
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
  }
 
  /* Write header... */
  fprintf(out,
          "# $1 = time [s]\n"
          "# $2 = altitude [km]\n"
          "# $3 = longitude [deg]\n"
          "# $4 = latitude [deg]\n"
          "# $5 = surface area [km^2]\n"
          "# $6 = layer depth [km]\n"
          "# $7 = column density (implicit) [kg/m^2]\n"
          "# $8 = volume mixing ratio (implicit) [ppv]\n"
          "# $9 = number of particles [1]\n");
  for (int iq = 0; iq < ctl->nq; iq++)
    fprintf(out, "# $%i = %s (mean) [%s]\n", 10 + iq, ctl->qnt_name[iq],
            ctl->qnt_unit[iq]);
  if (ctl->grid_stddev)
    for (int iq = 0; iq < ctl->nq; iq++)
      fprintf(out, "# $%i = %s (stddev) [%s]\n", 10 + ctl->nq + iq,
              ctl->qnt_name[iq], ctl->qnt_unit[iq]);
  fprintf(out, "\n");
 
  /* Write data... */
  for (int ix = 0; ix < ctl->grid_nx; ix++) {
    if (ix > 0 && ctl->grid_ny > 1 && !ctl->grid_sparse)
      fprintf(out, "\n");
    for (int iy = 0; iy < ctl->grid_ny; iy++) {
      if (iy > 0 && ctl->grid_nz > 1 && !ctl->grid_sparse)
        fprintf(out, "\n");
      for (int iz = 0; iz < ctl->grid_nz; iz++) {
        int idx = ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz);
        if (!ctl->grid_sparse || vmr_impl[idx] > 0) {
          fprintf(out, "%.2f %g %g %g %g %g %g %g %d", t, z[iz], lon[ix],
                  lat[iy], area[iy], dz, cd[idx], vmr_impl[idx], np[idx]);
          for (int iq = 0; iq < ctl->nq; iq++) {
            fprintf(out, " ");
            fprintf(out, ctl->qnt_format[iq], mean[iq][idx]);
          }
          if (ctl->grid_stddev)
            for (int iq = 0; iq < ctl->nq; iq++) {
              fprintf(out, " ");
              fprintf(out, ctl->qnt_format[iq], sigma[iq][idx]);
            }
          fprintf(out, "\n");
        }
      }
    }
  }
 
  /* Close file... */
  fclose(out);
}
 
/*****************************************************************************/
 
void write_grid_nc(
  const char *filename,
  ctl_t * ctl,
  double *cd,
  double *mean[NQ],
  double *sigma[NQ],
  double *vmr_impl,
  double t,
  double *z,
  double *lon,
  double *lat,
  double *area,
  double dz,
  int *np) {
 
  char longname[2 * LEN], varname[2 * LEN];
 
  double *help;
 
  int *help2, ncid, dimid[10], varid;
 
  size_t start[2], count[2];
 
  /* Allocate... */
  ALLOC(help, double,
        ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
  ALLOC(help2, int,
        ctl->grid_nx * ctl->grid_ny * ctl->grid_nz);
 
  /* Create file... */
  NC(nc_create(filename, NC_CLOBBER, &ncid));
 
  /* Define dimensions... */
  NC(nc_def_dim(ncid, "time", 1, &dimid[0]));
  NC(nc_def_dim(ncid, "z", (size_t) ctl->grid_nz, &dimid[1]));
  NC(nc_def_dim(ncid, "lat", (size_t) ctl->grid_ny, &dimid[2]));
  NC(nc_def_dim(ncid, "lon", (size_t) ctl->grid_nx, &dimid[3]));
  NC(nc_def_dim(ncid, "dz", 1, &dimid[4]));
 
  /* Define variables and their attributes... */
  NC_DEF_VAR("time", NC_DOUBLE, 1, &dimid[0], "time",
             "seconds since 2000-01-01 00:00:00 UTC");
  NC_DEF_VAR("z", NC_DOUBLE, 1, &dimid[1], "altitude", "km");
  NC_DEF_VAR("lat", NC_DOUBLE, 1, &dimid[2], "latitude", "degrees_north");
  NC_DEF_VAR("lon", NC_DOUBLE, 1, &dimid[3], "longitude", "degrees_east");
  NC_DEF_VAR("dz", NC_DOUBLE, 1, &dimid[1], "layer depth", "km");
  NC_DEF_VAR("area", NC_DOUBLE, 1, &dimid[2], "surface area", "km**2");
  NC_DEF_VAR("cd", NC_FLOAT, 4, dimid, "column density", "kg m**-2");
  NC_DEF_VAR("vmr_impl", NC_FLOAT, 4, dimid,
             "volume mixing ratio (implicit)", "ppv");
  NC_DEF_VAR("np", NC_INT, 4, dimid, "number of particles", "1");
  for (int iq = 0; iq < ctl->nq; iq++) {
    sprintf(varname, "%s_mean", ctl->qnt_name[iq]);
    sprintf(longname, "%s (mean)", ctl->qnt_longname[iq]);
    NC_DEF_VAR(varname, NC_DOUBLE, 4, dimid, longname, ctl->qnt_unit[iq]);
    if (ctl->grid_stddev) {
      sprintf(varname, "%s_stddev", ctl->qnt_name[iq]);
      sprintf(longname, "%s (stddev)", ctl->qnt_longname[iq]);
      NC_DEF_VAR(varname, NC_DOUBLE, 4, dimid, longname, ctl->qnt_unit[iq]);
    }
  }
  /* End definitions... */
  NC(nc_enddef(ncid));
 
  /* Write data... */
  NC_PUT_DOUBLE("time", &t, 0);
  NC_PUT_DOUBLE("lon", lon, 0);
  NC_PUT_DOUBLE("lat", lat, 0);
  NC_PUT_DOUBLE("z", z, 0);
  NC_PUT_DOUBLE("area", area, 0);
  NC_PUT_DOUBLE("dz", &dz, 0);
 
  for (int ix = 0; ix < ctl->grid_nx; ix++)
    for (int iy = 0; iy < ctl->grid_ny; iy++)
      for (int iz = 0; iz < ctl->grid_nz; iz++)
        help[ARRAY_3D(iz, iy, ctl->grid_ny, ix, ctl->grid_nx)] =
          cd[ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz)];
  NC_PUT_DOUBLE("cd", help, 0);
 
  for (int ix = 0; ix < ctl->grid_nx; ix++)
    for (int iy = 0; iy < ctl->grid_ny; iy++)
      for (int iz = 0; iz < ctl->grid_nz; iz++)
        help[ARRAY_3D(iz, iy, ctl->grid_ny, ix, ctl->grid_nx)] =
          vmr_impl[ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz)];
  NC_PUT_DOUBLE("vmr_impl", help, 0);
 
  for (int ix = 0; ix < ctl->grid_nx; ix++)
    for (int iy = 0; iy < ctl->grid_ny; iy++)
      for (int iz = 0; iz < ctl->grid_nz; iz++)
        help2[ARRAY_3D(iz, iy, ctl->grid_ny, ix, ctl->grid_nx)] =
          np[ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz)];
  NC_PUT_INT("np", help2, 0);
 
  for (int iq = 0; iq < ctl->nq; iq++) {
    sprintf(varname, "%s_mean", ctl->qnt_name[iq]);
    for (int ix = 0; ix < ctl->grid_nx; ix++)
      for (int iy = 0; iy < ctl->grid_ny; iy++)
        for (int iz = 0; iz < ctl->grid_nz; iz++)
          help[ARRAY_3D(iz, iy, ctl->grid_ny, ix, ctl->grid_nx)] =
            mean[iq][ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz)];
    NC_PUT_DOUBLE(varname, help, 0);
  }
 
  if (ctl->grid_stddev)
    for (int iq = 0; iq < ctl->nq; iq++) {
      sprintf(varname, "%s_stddev", ctl->qnt_name[iq]);
      for (int ix = 0; ix < ctl->grid_nx; ix++)
        for (int iy = 0; iy < ctl->grid_ny; iy++)
          for (int iz = 0; iz < ctl->grid_nz; iz++)
            help[ARRAY_3D(iz, iy, ctl->grid_ny, ix, ctl->grid_nx)] =
              sigma[iq][ARRAY_3D(ix, iy, ctl->grid_ny, iz, ctl->grid_nz)];
      NC_PUT_DOUBLE(varname, help, 0);
    }
 
  /* Close file... */
  NC(nc_close(ncid));
 
  /* Free... */
  free(help);
  free(help2);
}
 
/*****************************************************************************/
 
int write_met(
  const char *filename,
  ctl_t * ctl,
  met_t * met) {
 
  /* Set timer... */
  SELECT_TIMER("WRITE_MET", "OUTPUT", NVTX_WRITE);
 
  /* Write info... */
  LOG(1, "Write meteo data: %s", filename);
 
  /* Check compression flags... */
#ifndef ZFP
  if (ctl->met_type == 3)
    ERRMSG("MPTRAC was compiled without zfp compression!");
#endif
#ifndef ZSTD
  if (ctl->met_type == 4)
    ERRMSG("MPTRAC was compiled without zstd compression!");
#endif
#ifndef CMS
  if (ctl->met_type == 5)
    ERRMSG("MPTRAC was compiled without cmultiscale compression!");
#endif
 
  /* Write binary data... */
  if (ctl->met_type >= 1 && ctl->met_type <= 5) {
 
    /* Create file... */
    FILE *out;
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
 
    /* Write type of binary data... */
    FWRITE(&ctl->met_type, int,
           1,
           out);
 
    /* Write version of binary data... */
    int version = 102;
    FWRITE(&version, int,
           1,
           out);
 
    /* Write grid data... */
    FWRITE(&met->time, double,
           1,
           out);
    FWRITE(&met->nx, int,
           1,
           out);
    FWRITE(&met->ny, int,
           1,
           out);
    FWRITE(&met->np, int,
           1,
           out);
    FWRITE(met->lon, double,
             (size_t) met->nx,
           out);
    FWRITE(met->lat, double,
             (size_t) met->ny,
           out);
    FWRITE(met->p, double,
             (size_t) met->np,
           out);
 
    /* Write surface data... */
    write_met_bin_2d(out, met, met->ps, "PS");
    write_met_bin_2d(out, met, met->ts, "TS");
    write_met_bin_2d(out, met, met->zs, "ZS");
    write_met_bin_2d(out, met, met->us, "US");
    write_met_bin_2d(out, met, met->vs, "VS");
    write_met_bin_2d(out, met, met->lsm, "LSM");
    write_met_bin_2d(out, met, met->sst, "SST");
    write_met_bin_2d(out, met, met->pbl, "PBL");
    write_met_bin_2d(out, met, met->pt, "PT");
    write_met_bin_2d(out, met, met->tt, "TT");
    write_met_bin_2d(out, met, met->zt, "ZT");
    write_met_bin_2d(out, met, met->h2ot, "H2OT");
    write_met_bin_2d(out, met, met->pct, "PCT");
    write_met_bin_2d(out, met, met->pcb, "PCB");
    write_met_bin_2d(out, met, met->cl, "CL");
    write_met_bin_2d(out, met, met->plcl, "PLCL");
    write_met_bin_2d(out, met, met->plfc, "PLFC");
    write_met_bin_2d(out, met, met->pel, "PEL");
    write_met_bin_2d(out, met, met->cape, "CAPE");
    write_met_bin_2d(out, met, met->cin, "CIN");
 
    /* Write level data... */
    write_met_bin_3d(out, ctl, met, met->z, "Z",
                     (ctl->met_zfp_tol_z <= 0 ? ctl->met_zfp_prec : 0),
                     ctl->met_zfp_tol_z);
    write_met_bin_3d(out, ctl, met, met->t, "T",
                     (ctl->met_zfp_tol_t <= 0 ? ctl->met_zfp_prec : 0),
                     ctl->met_zfp_tol_t);
    write_met_bin_3d(out, ctl, met, met->u, "U", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->v, "V", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->w, "W", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->pv, "PV", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->h2o, "H2O", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->o3, "O3", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->lwc, "LWC", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->rwc, "RWC", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->iwc, "IWC", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->swc, "SWC", ctl->met_zfp_prec, 0);
    write_met_bin_3d(out, ctl, met, met->cc, "CC", ctl->met_zfp_prec, 0);
 
    /* Write final flag... */
    int final = 999;
    FWRITE(&final, int,
           1,
           out);
 
    /* Close file... */
    fclose(out);
  }
 
  return 0;
}
 
/*****************************************************************************/
 
void write_met_bin_2d(
  FILE * out,
  met_t * met,
  float var[EX][EY],
  char *varname) {
 
  float *help;
 
  /* Allocate... */
  ALLOC(help, float,
        EX * EY);
 
  /* Copy data... */
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      help[ARRAY_2D(ix, iy, met->ny)] = var[ix][iy];
 
  /* Write uncompressed data... */
  LOG(2, "Write 2-D variable: %s (uncompressed)", varname);
  FWRITE(help, float,
           (size_t) (met->nx * met->ny),
         out);
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void write_met_bin_3d(
  FILE * out,
  ctl_t * ctl,
  met_t * met,
  float var[EX][EY][EP],
  char *varname,
  int precision,
  double tolerance) {
 
  float *help;
 
  /* Allocate... */
  ALLOC(help, float,
        EX * EY * EP);
 
  /* Copy data... */
#pragma omp parallel for default(shared) collapse(2)
  for (int ix = 0; ix < met->nx; ix++)
    for (int iy = 0; iy < met->ny; iy++)
      for (int ip = 0; ip < met->np; ip++)
        help[ARRAY_3D(ix, iy, met->ny, ip, met->np)] = var[ix][iy][ip];
 
  /* Write uncompressed data... */
  if (ctl->met_type == 1) {
    LOG(2, "Write 3-D variable: %s (uncompressed)", varname);
    FWRITE(help, float,
             (size_t) (met->nx * met->ny * met->np),
           out);
  }
 
  /* Write packed data... */
  else if (ctl->met_type == 2)
    compress_pck(varname, help, (size_t) (met->ny * met->nx),
                 (size_t) met->np, 0, out);
 
  /* Write zfp data... */
#ifdef ZFP
  else if (ctl->met_type == 3) {
    FWRITE(&precision, int,
           1,
           out);
    FWRITE(&tolerance, double,
           1,
           out);
    compress_zfp(varname, help, met->np, met->ny, met->nx, precision,
                 tolerance, 0, out);
  }
#endif
 
  /* Write zstd data... */
#ifdef ZSTD
  else if (ctl->met_type == 4)
    compress_zstd(varname, help, (size_t) (met->np * met->ny * met->nx), 0,
                  out);
#endif
 
  /* Write cmultiscale data... */
#ifdef CMS
  else if (ctl->met_type == 5) {
    compress_cms(ctl, varname, help, (size_t) met->nx, (size_t) met->ny,
                 (size_t) met->np, 0, out);
  }
#endif
 
  /* Unknown method... */
  else {
    ERRMSG("MET_TYPE not supported!");
    LOG(3, "%d %g", precision, tolerance);
  }
 
  /* Free... */
  free(help);
}
 
/*****************************************************************************/
 
void write_output(
  const char *dirname,
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double t) {
 
  char ext[10], filename[2 * LEN];
 
  double r;
 
  int year, mon, day, hour, min, sec;
 
  /* Get time... */
  jsec2time(t, &year, &mon, &day, &hour, &min, &sec, &r);
 
  /* Update host... */
#ifdef _OPENACC
  if ((ctl->atm_basename[0] != '-' && fmod(t, ctl->atm_dt_out) == 0)
      || (ctl->grid_basename[0] != '-' && fmod(t, ctl->grid_dt_out) == 0)
      || (ctl->ens_basename[0] != '-' && fmod(t, ctl->ens_dt_out) == 0)
      || ctl->csi_basename[0] != '-' || ctl->prof_basename[0] != '-'
      || ctl->sample_basename[0] != '-' || ctl->stat_basename[0] != '-'
      || (ctl->vtk_basename[0] != '-' && fmod(t, ctl->vtk_dt_out) == 0)) {
    SELECT_TIMER("UPDATE_HOST", "MEMORY", NVTX_D2H);
#pragma acc update host(atm[:1])
  }
#endif
 
  /* Write atmospheric data... */
  if (ctl->atm_basename[0] != '-' &&
      (fmod(t, ctl->atm_dt_out) == 0 || t == ctl->t_stop)) {
    if (ctl->atm_type_out == 0)
      sprintf(ext, "tab");
    else if (ctl->atm_type_out == 1)
      sprintf(ext, "bin");
    else if (ctl->atm_type_out == 2)
      sprintf(ext, "nc");
    sprintf(filename, "%s/%s_%04d_%02d_%02d_%02d_%02d.%s",
            dirname, ctl->atm_basename, year, mon, day, hour, min, ext);
    write_atm(filename, ctl, atm, t);
  }
 
  /* Write gridded data... */
  if (ctl->grid_basename[0] != '-' && fmod(t, ctl->grid_dt_out) == 0) {
    sprintf(filename, "%s/%s_%04d_%02d_%02d_%02d_%02d.%s",
            dirname, ctl->grid_basename, year, mon, day, hour, min,
            ctl->grid_type == 0 ? "tab" : "nc");
    write_grid(filename, ctl, met0, met1, atm, t);
  }
 
  /* Write CSI data... */
  if (ctl->csi_basename[0] != '-') {
    sprintf(filename, "%s/%s.tab", dirname, ctl->csi_basename);
    write_csi(filename, ctl, atm, t);
  }
 
  /* Write ensemble data... */
  if (ctl->ens_basename[0] != '-' && fmod(t, ctl->ens_dt_out) == 0) {
    sprintf(filename, "%s/%s_%04d_%02d_%02d_%02d_%02d.tab",
            dirname, ctl->ens_basename, year, mon, day, hour, min);
    write_ens(filename, ctl, atm, t);
  }
 
  /* Write profile data... */
  if (ctl->prof_basename[0] != '-') {
    sprintf(filename, "%s/%s.tab", dirname, ctl->prof_basename);
    write_prof(filename, ctl, met0, met1, atm, t);
  }
 
  /* Write sample data... */
  if (ctl->sample_basename[0] != '-') {
    sprintf(filename, "%s/%s.tab", dirname, ctl->sample_basename);
    write_sample(filename, ctl, met0, met1, atm, t);
  }
 
  /* Write station data... */
  if (ctl->stat_basename[0] != '-') {
    sprintf(filename, "%s/%s.tab", dirname, ctl->stat_basename);
    write_station(filename, ctl, atm, t);
  }
 
  /* Write VTK data... */
  if (ctl->vtk_basename[0] != '-' && fmod(t, ctl->vtk_dt_out) == 0) {
    static int nvtk;
    if (t == ctl->t_start)
      nvtk = 0;
    sprintf(filename, "%s/%s_%05d.vtk", dirname, ctl->vtk_basename, ++nvtk);
    write_vtk(filename, ctl, atm, t);
  }
}
 
/*****************************************************************************/
 
void write_prof(
  const char *filename,
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double t) {
 
  static FILE *out;
 
  static double *mass, *obsmean, *rt, *rz, *rlon, *rlat, *robs, *area,
    dz, dlon, dlat, *lon, *lat, *z, *press, temp, vmr, h2o, o3;
 
  static int nobs, *obscount, ip, okay;
 
  /* Set timer... */
  SELECT_TIMER("WRITE_PROF", "OUTPUT", NVTX_WRITE);
 
  /* Init... */
  if (t == ctl->t_start) {
 
    /* Check quantity index for mass... */
    if (ctl->qnt_m < 0)
      ERRMSG("Need quantity mass!");
 
    /* Check molar mass... */
    if (ctl->molmass <= 0)
      ERRMSG("Specify molar mass!");
 
    /* Allocate... */
    ALLOC(lon, double,
          ctl->prof_nx);
    ALLOC(lat, double,
          ctl->prof_ny);
    ALLOC(area, double,
          ctl->prof_ny);
    ALLOC(z, double,
          ctl->prof_nz);
    ALLOC(press, double,
          ctl->prof_nz);
    ALLOC(rt, double,
          NOBS);
    ALLOC(rz, double,
          NOBS);
    ALLOC(rlon, double,
          NOBS);
    ALLOC(rlat, double,
          NOBS);
    ALLOC(robs, double,
          NOBS);
 
    /* Read observation data... */
    read_obs(ctl->prof_obsfile, ctl, rt, rz, rlon, rlat, robs, &nobs);
 
    /* Create new output file... */
    LOG(1, "Write profile data: %s", filename);
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
 
    /* Write header... */
    fprintf(out,
            "# $1 = time [s]\n"
            "# $2 = altitude [km]\n"
            "# $3 = longitude [deg]\n"
            "# $4 = latitude [deg]\n"
            "# $5 = pressure [hPa]\n"
            "# $6 = temperature [K]\n"
            "# $7 = volume mixing ratio [ppv]\n"
            "# $8 = H2O volume mixing ratio [ppv]\n"
            "# $9 = O3 volume mixing ratio [ppv]\n"
            "# $10 = observed BT index [K]\n"
            "# $11 = number of observations\n");
 
    /* Set grid box size... */
    dz = (ctl->prof_z1 - ctl->prof_z0) / ctl->prof_nz;
    dlon = (ctl->prof_lon1 - ctl->prof_lon0) / ctl->prof_nx;
    dlat = (ctl->prof_lat1 - ctl->prof_lat0) / ctl->prof_ny;
 
    /* Set vertical coordinates... */
    for (int iz = 0; iz < ctl->prof_nz; iz++) {
      z[iz] = ctl->prof_z0 + dz * (iz + 0.5);
      press[iz] = P(z[iz]);
    }
 
    /* Set horizontal coordinates... */
    for (int ix = 0; ix < ctl->prof_nx; ix++)
      lon[ix] = ctl->prof_lon0 + dlon * (ix + 0.5);
    for (int iy = 0; iy < ctl->prof_ny; iy++) {
      lat[iy] = ctl->prof_lat0 + dlat * (iy + 0.5);
      area[iy] = dlat * dlon * SQR(RE * M_PI / 180.)
        * cos(lat[iy] * M_PI / 180.);
    }
  }
 
  /* Set time interval... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Allocate... */
  ALLOC(mass, double,
        ctl->prof_nx * ctl->prof_ny * ctl->prof_nz);
  ALLOC(obsmean, double,
        ctl->prof_nx * ctl->prof_ny);
  ALLOC(obscount, int,
        ctl->prof_nx * ctl->prof_ny);
 
  /* Loop over observations... */
  for (int i = 0; i < nobs; i++) {
 
    /* Check time... */
    if (rt[i] < t0)
      continue;
    else if (rt[i] >= t1)
      break;
 
    /* Check observation data... */
    if (!isfinite(robs[i]))
      continue;
 
    /* Calculate indices... */
    int ix = (int) ((rlon[i] - ctl->prof_lon0) / dlon);
    int iy = (int) ((rlat[i] - ctl->prof_lat0) / dlat);
 
    /* Check indices... */
    if (ix < 0 || ix >= ctl->prof_nx || iy < 0 || iy >= ctl->prof_ny)
      continue;
 
    /* Get mean observation index... */
    int idx = ARRAY_2D(ix, iy, ctl->prof_ny);
    obsmean[idx] += robs[i];
    obscount[idx]++;
  }
 
  /* Analyze model data... */
  for (ip = 0; ip < atm->np; ip++) {
 
    /* Check time... */
    if (atm->time[ip] < t0 || atm->time[ip] > t1)
      continue;
 
    /* Get indices... */
    int ix = (int) ((atm->lon[ip] - ctl->prof_lon0) / dlon);
    int iy = (int) ((atm->lat[ip] - ctl->prof_lat0) / dlat);
    int iz = (int) ((Z(atm->p[ip]) - ctl->prof_z0) / dz);
 
    /* Check indices... */
    if (ix < 0 || ix >= ctl->prof_nx ||
        iy < 0 || iy >= ctl->prof_ny || iz < 0 || iz >= ctl->prof_nz)
      continue;
 
    /* Get total mass in grid cell... */
    int idx = ARRAY_3D(ix, iy, ctl->prof_ny, iz, ctl->prof_nz);
    mass[idx] += atm->q[ctl->qnt_m][ip];
  }
 
  /* Extract profiles... */
  for (int ix = 0; ix < ctl->prof_nx; ix++)
    for (int iy = 0; iy < ctl->prof_ny; iy++) {
      int idx2 = ARRAY_2D(ix, iy, ctl->prof_ny);
      if (obscount[idx2] > 0) {
 
        /* Check profile... */
        okay = 0;
        for (int iz = 0; iz < ctl->prof_nz; iz++) {
          int idx3 = ARRAY_3D(ix, iy, ctl->prof_ny, iz, ctl->prof_nz);
          if (mass[idx3] > 0) {
            okay = 1;
            break;
          }
        }
        if (!okay)
          continue;
 
        /* Write output... */
        fprintf(out, "\n");
 
        /* Loop over altitudes... */
        for (int iz = 0; iz < ctl->prof_nz; iz++) {
 
          /* Get temperature, water vapor, and ozone... */
          INTPOL_INIT;
          intpol_met_time_3d(met0, met0->t, met1, met1->t, t, press[iz],
                             lon[ix], lat[iy], &temp, ci, cw, 1);
          intpol_met_time_3d(met0, met0->h2o, met1, met1->h2o, t, press[iz],
                             lon[ix], lat[iy], &h2o, ci, cw, 0);
          intpol_met_time_3d(met0, met0->o3, met1, met1->o3, t, press[iz],
                             lon[ix], lat[iy], &o3, ci, cw, 0);
 
          /* Calculate volume mixing ratio... */
          int idx3 = ARRAY_3D(ix, iy, ctl->prof_ny, iz, ctl->prof_nz);
          vmr = MA / ctl->molmass * mass[idx3]
            / (RHO(press[iz], temp) * area[iy] * dz * 1e9);
 
          /* Write output... */
          fprintf(out, "%.2f %g %g %g %g %g %g %g %g %g %d\n",
                  t, z[iz], lon[ix], lat[iy], press[iz], temp, vmr, h2o, o3,
                  obsmean[idx2] / obscount[idx2], obscount[idx2]);
        }
      }
    }
 
  /* Free... */
  free(mass);
  free(obsmean);
  free(obscount);
 
  /* Finalize... */
  if (t == ctl->t_stop) {
 
    /* Close output file... */
    fclose(out);
 
    /* Free... */
    free(lon);
    free(lat);
    free(area);
    free(z);
    free(press);
    free(rt);
    free(rz);
    free(rlon);
    free(rlat);
    free(robs);
  }
}
 
/*****************************************************************************/
 
void write_sample(
  const char *filename,
  ctl_t * ctl,
  met_t * met0,
  met_t * met1,
  atm_t * atm,
  double t) {
 
  static FILE *out;
 
  static double area, dlat, rmax2, *rt, *rz, *rlon, *rlat, *robs, kz[EP],
    kw[EP];
 
  static int nobs, nk;
 
  /* Set timer... */
  SELECT_TIMER("WRITE_SAMPLE", "OUTPUT", NVTX_WRITE);
 
  /* Init... */
  if (t == ctl->t_start) {
 
    /* Allocate... */
    ALLOC(rt, double,
          NOBS);
    ALLOC(rz, double,
          NOBS);
    ALLOC(rlon, double,
          NOBS);
    ALLOC(rlat, double,
          NOBS);
    ALLOC(robs, double,
          NOBS);
 
    /* Read observation data... */
    read_obs(ctl->sample_obsfile, ctl, rt, rz, rlon, rlat, robs, &nobs);
 
    /* Read kernel data... */
    if (ctl->sample_kernel[0] != '-')
      read_kernel(ctl->sample_kernel, kz, kw, &nk);
 
    /* Create output file... */
    LOG(1, "Write sample data: %s", filename);
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
 
    /* Write header... */
    fprintf(out,
            "# $1 = time [s]\n"
            "# $2 = altitude [km]\n"
            "# $3 = longitude [deg]\n"
            "# $4 = latitude [deg]\n"
            "# $5 = surface area [km^2]\n"
            "# $6 = layer depth [km]\n"
            "# $7 = number of particles [1]\n"
            "# $8 = column density [kg/m^2]\n"
            "# $9 = volume mixing ratio [ppv]\n"
            "# $10 = observed BT index [K]\n\n");
 
    /* Set latitude range, squared radius, and area... */
    dlat = DY2DEG(ctl->sample_dx);
    rmax2 = SQR(ctl->sample_dx);
    area = M_PI * rmax2;
  }
 
  /* Set time interval for output... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Loop over observations... */
  for (int i = 0; i < nobs; i++) {
 
    /* Check time... */
    if (rt[i] < t0)
      continue;
    else if (rt[i] >= t1)
      break;
 
    /* Calculate Cartesian coordinates... */
    double x0[3];
    geo2cart(0, rlon[i], rlat[i], x0);
 
    /* Set pressure range... */
    double rp = P(rz[i]);
    double ptop = P(rz[i] + ctl->sample_dz);
    double pbot = P(rz[i] - ctl->sample_dz);
 
    /* Init... */
    double mass = 0;
    int np = 0;
 
    /* Loop over air parcels... */
#pragma omp parallel for default(shared) reduction(+:mass,np)
    for (int ip = 0; ip < atm->np; ip++) {
 
      /* Check time... */
      if (atm->time[ip] < t0 || atm->time[ip] > t1)
        continue;
 
      /* Check latitude... */
      if (fabs(rlat[i] - atm->lat[ip]) > dlat)
        continue;
 
      /* Check horizontal distance... */
      double x1[3];
      geo2cart(0, atm->lon[ip], atm->lat[ip], x1);
      if (DIST2(x0, x1) > rmax2)
        continue;
 
      /* Check pressure... */
      if (ctl->sample_dz > 0)
        if (atm->p[ip] > pbot || atm->p[ip] < ptop)
          continue;
 
      /* Add mass... */
      if (ctl->qnt_m >= 0)
        mass +=
          kernel_weight(kz, kw, nk, atm->p[ip]) * atm->q[ctl->qnt_m][ip];
      np++;
    }
 
    /* Calculate column density... */
    double cd = mass / (1e6 * area);
 
    /* Calculate volume mixing ratio... */
    double vmr = 0;
    if (ctl->molmass > 0 && ctl->sample_dz > 0) {
      if (mass > 0) {
 
        /* Get temperature... */
        double temp;
        INTPOL_INIT;
        intpol_met_time_3d(met0, met0->t, met1, met1->t, rt[i], rp,
                           rlon[i], rlat[i], &temp, ci, cw, 1);
 
        /* Calculate volume mixing ratio... */
        vmr = MA / ctl->molmass * mass
          / (RHO(rp, temp) * 1e6 * area * 1e3 * ctl->sample_dz);
      }
    } else
      vmr = NAN;
 
    /* Write output... */
    fprintf(out, "%.2f %g %g %g %g %g %d %g %g %g\n", rt[i], rz[i],
            rlon[i], rlat[i], area, ctl->sample_dz, np, cd, vmr, robs[i]);
  }
 
  /* Finalize...... */
  if (t == ctl->t_stop) {
 
    /* Close output file... */
    fclose(out);
 
    /* Free... */
    free(rt);
    free(rz);
    free(rlon);
    free(rlat);
    free(robs);
  }
}
 
/*****************************************************************************/
 
void write_station(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  static FILE *out;
 
  static double rmax2, x0[3], x1[3];
 
  /* Set timer... */
  SELECT_TIMER("WRITE_STATION", "OUTPUT", NVTX_WRITE);
 
  /* Init... */
  if (t == ctl->t_start) {
 
    /* Write info... */
    LOG(1, "Write station data: %s", filename);
 
    /* Create new file... */
    if (!(out = fopen(filename, "w")))
      ERRMSG("Cannot create file!");
 
    /* Write header... */
    fprintf(out,
            "# $1 = time [s]\n"
            "# $2 = altitude [km]\n"
            "# $3 = longitude [deg]\n" "# $4 = latitude [deg]\n");
    for (int iq = 0; iq < ctl->nq; iq++)
      fprintf(out, "# $%i = %s [%s]\n", (iq + 5),
              ctl->qnt_name[iq], ctl->qnt_unit[iq]);
    fprintf(out, "\n");
 
    /* Set geolocation and search radius... */
    geo2cart(0, ctl->stat_lon, ctl->stat_lat, x0);
    rmax2 = SQR(ctl->stat_r);
  }
 
  /* Set time interval for output... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Loop over air parcels... */
  for (int ip = 0; ip < atm->np; ip++) {
 
    /* Check time... */
    if (atm->time[ip] < t0 || atm->time[ip] > t1)
      continue;
 
    /* Check time range for station output... */
    if (atm->time[ip] < ctl->stat_t0 || atm->time[ip] > ctl->stat_t1)
      continue;
 
    /* Check station flag... */
    if (ctl->qnt_stat >= 0)
      if ((int) atm->q[ctl->qnt_stat][ip])
        continue;
 
    /* Get Cartesian coordinates... */
    geo2cart(0, atm->lon[ip], atm->lat[ip], x1);
 
    /* Check horizontal distance... */
    if (DIST2(x0, x1) > rmax2)
      continue;
 
    /* Set station flag... */
    if (ctl->qnt_stat >= 0)
      atm->q[ctl->qnt_stat][ip] = 1;
 
    /* Write data... */
    fprintf(out, "%.2f %g %g %g",
            atm->time[ip], Z(atm->p[ip]), atm->lon[ip], atm->lat[ip]);
    for (int iq = 0; iq < ctl->nq; iq++) {
      fprintf(out, " ");
      fprintf(out, ctl->qnt_format[iq], atm->q[iq][ip]);
    }
    fprintf(out, "\n");
  }
 
  /* Close file... */
  if (t == ctl->t_stop)
    fclose(out);
}
 
/*****************************************************************************/
 
void write_vtk(
  const char *filename,
  ctl_t * ctl,
  atm_t * atm,
  double t) {
 
  FILE *out;
 
  /* Set timer... */
  SELECT_TIMER("WRITE_VTK", "OUTPUT", NVTX_WRITE);
 
  /* Write info... */
  LOG(1, "Write VTK data: %s", filename);
 
  /* Set time interval for output... */
  double t0 = t - 0.5 * ctl->dt_mod;
  double t1 = t + 0.5 * ctl->dt_mod;
 
  /* Create file... */
  if (!(out = fopen(filename, "w")))
    ERRMSG("Cannot create file!");
 
  /* Count data points... */
  int np = 0;
  for (int ip = 0; ip < atm->np; ip += ctl->vtk_stride) {
    if (atm->time[ip] < t0 || atm->time[ip] > t1)
      continue;
    np++;
  }
 
  /* Write header... */
  fprintf(out,
          "# vtk DataFile Version 3.0\n"
          "vtk output\n" "ASCII\n" "DATASET POLYDATA\n");
 
  /* Write point coordinates... */
  fprintf(out, "POINTS %d float\n", np);
  if (ctl->vtk_sphere) {
    for (int ip = 0; ip < atm->np; ip += ctl->vtk_stride) {
      if (atm->time[ip] < t0 || atm->time[ip] > t1)
        continue;
      double radius = (RE + Z(atm->p[ip]) * ctl->vtk_scale
                       + ctl->vtk_offset) / RE;
      double x = radius * cos(atm->lat[ip] / 180. * M_PI)
        * cos(atm->lon[ip] / 180. * M_PI);
      double y = radius * cos(atm->lat[ip] / 180. * M_PI)
        * sin(atm->lon[ip] / 180. * M_PI);
      double z = radius * sin(atm->lat[ip] / 180. * M_PI);
      fprintf(out, "%g %g %g\n", x, y, z);
    }
  } else
    for (int ip = 0; ip < atm->np; ip += ctl->vtk_stride) {
      if (atm->time[ip] < t0 || atm->time[ip] > t1)
        continue;
      fprintf(out, "%g %g %g\n", atm->lon[ip], atm->lat[ip],
              Z(atm->p[ip]) * ctl->vtk_scale + ctl->vtk_offset);
    }
 
  /* Write point data... */
  fprintf(out, "POINT_DATA %d\n", np);
  for (int iq = 0; iq < ctl->nq; iq++) {
    fprintf(out, "SCALARS %s float 1\n" "LOOKUP_TABLE default\n",
            ctl->qnt_name[iq]);
    for (int ip = 0; ip < atm->np; ip += ctl->vtk_stride) {
      if (atm->time[ip] < t0 || atm->time[ip] > t1)
        continue;
      fprintf(out, "%g\n", atm->q[iq][ip]);
    }
  }
 
  /* Close file... */
  fclose(out);
}