[5940] | 1 | ### =========================================================================== |
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| 2 | ### |
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| 3 | ### Build coordnates mask |
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| 4 | ### |
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| 5 | ### =========================================================================== |
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| 6 | # creates file coordinates_mask.nc used by mosaix from NEMO netcdf files |
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| 7 | # coordinates.nc and bathymetry.nc (on the same grid as coordinates.nc) |
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| 8 | |
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| 9 | import numpy as np |
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| 10 | import xarray as xr |
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| 11 | import nemo |
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[5947] | 12 | import datetime, os, platform, argparse |
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[5940] | 13 | |
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[5947] | 14 | ## SVN information |
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| 15 | __Author__ = "$Author: $" |
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| 16 | __Date__ = "$Date: $" |
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| 17 | __Revision__ = "$Revision: $" |
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| 18 | __Id__ = "$Id: $" |
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| 19 | __HeadURL__ = "$HeadURL: $" |
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| 20 | __SVN_Date__ = "$SVN_Date: $" |
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| 21 | ### |
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| 22 | |
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| 23 | ### ===== Handling command line parameters ================================================== |
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| 24 | # Creating a parser |
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| 25 | parser = argparse.ArgumentParser ( |
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| 26 | description = """Read coordinates and bathymetry to build masks, grid bounds and areas for MOSAIX""", |
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| 27 | epilog='-------- End of the help message --------') |
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| 28 | |
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| 29 | # Adding arguments |
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| 30 | parser.add_argument ('--model' , help='oce model name', type=str, default='eORCA1.2', choices=('paleORCA', 'ORCA2.3', 'ORCA2.4', 'eORCA1.2', 'eORCA025', 'eORCA025.1') ) |
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| 31 | parser.add_argument ('--bathy' , help='bathymetry file name', type=str, default='bathy_meter.nc' ) |
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| 32 | parser.add_argument ('--coord' , help='coordinates file name', type=str, default='coordinates.nc' ) |
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| 33 | parser.add_argument ('--fout' , help='output file name (given as an input to MOSAIX)', type=str, default='coordinates_mask.nc' ) |
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| 34 | parser.add_argument ('--ocePerio', help='periodicity of ocean grid', type=int, default=0, choices=(1, 2, 3, 4, 5, 6) ) |
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| 35 | parser.add_argument ('--nemo4Ubug',help='reproduce NEMO lbc_lnk bug for U grid and periodicity 4', type=bool, default=False, choices=(True, False) ) |
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| 36 | parser.add_argument ('--straits' , help='modify grid metrics for selected strait points (depends on model name)', type=bool, default=False, choices=(True, False) ) |
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| 37 | parser.add_argument ('--coordPerio', help='impose periodicity of coordinates and areas through lbc', type=bool, default=False, choices=(True, False) ) |
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| 38 | parser.add_argument ('--maskbathy', help='use the same formula as in NEMO to compute mask_T from the bathymetry file. Does not always give the same result as NEMO ???', type=bool, default=False, choices=(True, False) ) |
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| 39 | |
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| 40 | # Parse command line |
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| 41 | myargs = parser.parse_args() |
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| 42 | |
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| 43 | # ocean model name |
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| 44 | model = myargs.model |
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| 45 | |
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| 46 | # bathymetry input file |
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| 47 | n_bathy = myargs.bathy |
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| 48 | # coordinates input file |
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| 49 | n_coord = myargs.coord |
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| 50 | # coordinates and mask output file |
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| 51 | n_out = myargs.fout |
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| 52 | |
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[5940] | 53 | # reproduce periodicity lbclnk bug for U and nperio = 4 |
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[5947] | 54 | nemoUbug = myargs.nemo4Ubug |
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[5940] | 55 | # change metrics (and bathymetry) for straits |
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[5947] | 56 | straits = myargs.straits |
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[5940] | 57 | # periodicity imposed on coordinates, metrics and areas |
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[5947] | 58 | coordperio = myargs.coordPerio |
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[5940] | 59 | # function used to compute mask_T from bathymetry |
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[5947] | 60 | maskbathynemo = myargs.maskbathy |
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[5940] | 61 | |
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[5947] | 62 | # type of grid periodicity |
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| 63 | nperio = myargs.ocePerio |
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[5940] | 64 | |
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[5947] | 65 | # check of periodicity with type of grid |
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| 66 | if model in ('eORCA1.2', 'paleORCA', 'ORCA025', 'eORCA025', 'eORCA025.1') : |
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| 67 | if nperio != 0 : |
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| 68 | if nperio != 6 : |
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| 69 | print(f'Warning ! model = {model} and ocePerio = {nperio} instead of 6 !') |
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| 70 | else : |
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| 71 | nperio = 6 |
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[5940] | 72 | |
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[5947] | 73 | if model in ('ORCA2.3', 'ORCA2.4') : |
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| 74 | if nperio != 0 : |
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| 75 | if nperio != 4 : |
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| 76 | print(f'Attention ! model = {model} and ocePerio = {nperio} instead of 4 !') |
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| 77 | else : |
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| 78 | nperio = 4 |
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[5940] | 79 | |
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[5947] | 80 | print(f' model = {model}\n ocePerio = {nperio}\n bathy = {n_bathy}\n coord = {n_coord}\n fout = {n_out}') |
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| 81 | print(f' Switchs : nemo4Ubug = {nemoUbug}, straits = {straits}, coordPerio = {coordperio}, maskbathy = {maskbathynemo}') |
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[5940] | 82 | |
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[5947] | 83 | ## |
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| 84 | #!!! bathymetry and coordinates files |
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| 85 | ## |
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[5940] | 86 | |
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| 87 | # open input files while removing the time dimension |
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| 88 | f_coord = xr.open_dataset (n_coord, decode_times=False).squeeze() |
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| 89 | f_bathy = xr.open_dataset (n_bathy, decode_times=False).squeeze() |
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| 90 | |
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| 91 | # Suppress time if necessary |
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| 92 | try : |
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| 93 | del f_coord['time'] |
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| 94 | print ('time successfully removed') |
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| 95 | except : |
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| 96 | pass |
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| 97 | print ('failed to suppress time') |
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| 98 | |
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[5947] | 99 | # rename latitude, longitude and grid variables in bathymetry |
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[5940] | 100 | Bathymetry = f_bathy['Bathymetry'].copy() |
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| 101 | |
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| 102 | try : |
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| 103 | Bathymetry = Bathymetry.rename ({'nav_lat':'nav_lat_grid_T', 'nav_lon':'nav_lon_grid_T'}) |
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| 104 | print ('Bathymetry file: Normal case') |
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| 105 | except : |
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| 106 | print ('Bathymetry file: Exception') |
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| 107 | nav_lon_grid_T = f_bathy ['nav_lon'] |
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| 108 | nav_lat_grid_T = f_bathy ['nav_lat'] |
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| 109 | Bathymetry = xr.DataArray (Bathymetry, coords = { "nav_lat_grid_T": (["y", "x"], nav_lat_grid_T), |
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| 110 | "nav_lon_grid_T": (["y", "x"], nav_lon_grid_T) } ) |
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| 111 | |
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| 112 | Bathymetry = Bathymetry.rename ({'y':'y_grid_T', 'x':'x_grid_T'}) |
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| 113 | |
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[5947] | 114 | # modify Bathymetry in straits for select grids (might change computed mask_T) |
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[5940] | 115 | if straits : |
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| 116 | # Open straits for usual grids |
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| 117 | if model == 'ORCA2.3' : |
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| 118 | # orca_r2: Gibraltar strait open |
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| 119 | Bathymetry[101,139] = 284. |
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| 120 | # orca_r2: Bab el Mandeb strait open |
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| 121 | Bathymetry[87,159] = 137. |
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| 122 | |
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[5947] | 123 | # impose periodicity of bathymetry |
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[5940] | 124 | Bathymetry = nemo.lbc (Bathymetry, nperio=nperio, cd_type='T') |
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[5947] | 125 | # suppress ocean points at southernmost position only if nperio in {3, 4, 5, 6} |
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[5942] | 126 | if nperio in (3, 4, 5, 6) : |
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[5947] | 127 | Bathymetry[0,:] = 0.0 |
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[5940] | 128 | |
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[5947] | 129 | ## |
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| 130 | #!!! Create masks from bathymetry |
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| 131 | ## |
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[5940] | 132 | |
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[5947] | 133 | # Creation of mask_T following choosed option maskbathy |
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[5940] | 134 | if maskbathynemo : |
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| 135 | # Use same formula as domzgr. |
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[5947] | 136 | mask_T = xr.where (Bathymetry - 1. + 0.1 >= 0.0, 1, 0).astype (dtype='f4') |
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[5940] | 137 | else : |
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[5947] | 138 | mask_T = xr.where (Bathymetry > 0.0, 1, 0).astype (dtype='f4') |
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[5940] | 139 | |
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| 140 | # Creation of U, V, W, F masks from mask_T |
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| 141 | mask_U = mask_T * mask_T.shift (x_grid_T=-1) |
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| 142 | mask_V = mask_T * mask_T.shift (y_grid_T=-1) |
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| 143 | mask_F = mask_T * mask_T.shift (y_grid_T=-1) * mask_T.shift (x_grid_T=-1) * mask_T.shift (y_grid_T=-1, x_grid_T=-1) |
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| 144 | mask_W = mask_T |
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| 145 | |
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[5947] | 146 | # loop on TUVFW to modify coordinates and attributes of mask_[TUVFW] and maskutil_[TUVFW] |
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[5940] | 147 | for cd_type in ['T', 'U', 'V', 'F', 'W'] : |
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| 148 | MaskName = 'mask_' + cd_type |
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| 149 | UtilName = 'maskutil_' + cd_type |
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[5947] | 150 | # impose periodicity of chosen grid model on masks |
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| 151 | locals()[MaskName] = nemo.lbc (locals()[MaskName], nperio=nperio, cd_type=cd_type, nemo_4U_bug=nemoUbug).astype (dtype='f4') |
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| 152 | # rename masks coordinates |
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| 153 | if cd_type != 'T' : |
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| 154 | locals()[MaskName] = locals()[MaskName].rename \ |
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| 155 | ( {'y_grid_T' : 'y_grid_'+cd_type, 'x_grid_T' : 'x_grid_'+cd_type, |
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| 156 | 'nav_lat_grid_T': 'nav_lat_grid_'+cd_type, 'nav_lon_grid_T': 'nav_lon_grid_'+cd_type} ) |
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| 157 | |
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| 158 | # create masks without duplicate points : maskutil_[TUVWF] |
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[5940] | 159 | locals()[UtilName] = nemo.lbc_mask (locals()[MaskName].copy(), nperio=nperio, cd_type=cd_type) |
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[5947] | 160 | |
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| 161 | #set name attribute of mask dataset |
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| 162 | locals()[MaskName].name = MaskName |
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[5940] | 163 | locals()[UtilName].name = UtilName |
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| 164 | |
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[5947] | 165 | # remove _FillVallue from mskutil |
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| 166 | locals()[MaskName].encoding['_FillValue'] = None |
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| 167 | locals()[UtilName].encoding['_FillValue'] = None |
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[5940] | 168 | |
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[5947] | 169 | # add masks attributes |
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| 170 | locals()[MaskName].attrs['cell_measures'] = 'area: area_grid_'+cd_type |
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| 171 | locals()[UtilName].attrs['cell_measures'] = 'area: area_grid_'+cd_type |
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[5940] | 172 | |
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[5947] | 173 | ## |
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| 174 | #!!! create grid coordinates from NEMO coordinates.nc file |
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| 175 | ## |
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[5940] | 176 | |
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[5947] | 177 | angle = { 'lon' : 'glam', 'lat' : 'gphi' } |
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| 178 | gridv = { 'T' : 't', 'U' : 'u', 'V' : 'v', 'F' : 'f', 'W' : 't' } |
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| 179 | for cd_type in ['T', 'U', 'V', 'F', 'W'] : |
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| 180 | for dir_type in ['lon', 'lat'] : |
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| 181 | coord_name = 'nav_' + dir_type + '_grid_' + cd_type |
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| 182 | dir_name = angle[dir_type]+gridv[cd_type] |
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| 183 | # impose or not periodicity on coordinates read from file |
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| 184 | if coordperio : |
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| 185 | locals()[coord_name] = nemo.lbc (f_coord [dir_name].copy(), nperio=nperio, cd_type=cd_type, nemo_4U_bug=nemoUbug) |
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| 186 | else : |
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| 187 | locals()[coord_name] = f_coord [dir_name].copy() |
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[5940] | 188 | |
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[5947] | 189 | locals()[coord_name] = locals()[coord_name].rename( {'y':'y_grid_'+cd_type, 'x':'x_grid_'+cd_type} ) |
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| 190 | |
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[5940] | 191 | # remove _FillValue and missing_value |
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| 192 | locals()[coord_name].encoding['_FillValue'] = None |
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| 193 | locals()[coord_name].encoding['missing_value'] = None |
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| 194 | |
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[5947] | 195 | # define name attribute |
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| 196 | locals()[coord_name].name = coord_name |
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[5940] | 197 | |
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| 198 | # add coordinates attributes |
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[5947] | 199 | locals()[coord_name].attrs['bounds'] ='bounds_' + dir_type + '_grid_' + cd_type |
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[5940] | 200 | |
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[5947] | 201 | locals()['nav_lon_grid_'+cd_type].attrs['standard_name'] = 'longitude' |
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| 202 | locals()['nav_lon_grid_'+cd_type].attrs['long_name'] = 'Longitude' |
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| 203 | locals()['nav_lon_grid_'+cd_type].attrs['units'] = 'degrees_east' |
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| 204 | locals()['nav_lat_grid_'+cd_type].attrs['standard_name'] = 'latitude' |
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| 205 | locals()['nav_lat_grid_'+cd_type].attrs['long_name'] = 'Latitude' |
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| 206 | locals()['nav_lat_grid_'+cd_type].attrs['units'] = 'degrees_north' |
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[5940] | 207 | |
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[5947] | 208 | ## |
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| 209 | #!!! compute areas of cells at coordinate points |
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| 210 | ## |
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[5940] | 211 | |
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| 212 | # create areas variables for grid cells from NEMO coordinates.nc file |
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| 213 | # create new variables e1 e2 to keep f_coord the same |
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| 214 | for cd_type in ['t', 'u', 'v', 'f'] : |
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| 215 | for axis in ['1', '2'] : |
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| 216 | coordName = 'e' + axis + cd_type |
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| 217 | locals()[coordName]=f_coord[coordName].copy() |
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| 218 | # remove zero values from areas |
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| 219 | # need to be define for the extended grid south of -80S |
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| 220 | # some point are undefined but you need to have e1 and e2 .NE. 0 |
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| 221 | locals()[coordName]=xr.where(locals()[coordName] == 0.0, 1.0e2, locals()[coordName]) |
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| 222 | |
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| 223 | # Correct areas for straits |
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| 224 | if straits : |
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| 225 | # ORCA R2 configuration |
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| 226 | if model == 'ORCA2.3' : |
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| 227 | # Gibraltar : e2u reduced to 20 km |
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| 228 | e2u[101,138:140] = 20.e3 |
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| 229 | # Bab el Mandeb : e2u reduced to 30 km |
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| 230 | # e1v reduced to 18 km |
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| 231 | e1v[87,159] = 18.e3 |
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| 232 | e2u[87,159] = 30.e3 |
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| 233 | # Danish Straits: e2u reduced to 10 km |
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| 234 | e2u[115,144:146] = 10.e3 |
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| 235 | # ORCA R1 configuration |
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| 236 | if model == 'eORCA1.2' : |
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| 237 | # Gibraltar : e2u reduced to 20 km |
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| 238 | e2u[240,281:283] = 20.e3 |
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| 239 | # Bhosporus : e2u reduced to 10 km |
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| 240 | e2u[247,313:315] = 10.e3 |
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| 241 | # Lombok : e1v reduced to 13 km |
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| 242 | e1v[163:165,43] = 13.e3 |
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| 243 | # Sumba : e1v reduced to 8 km |
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| 244 | e1v[163:165,47] = 8.e3 |
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| 245 | # Ombai : e1v reduced to 13 km |
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| 246 | e1v[163:165,52] = 13.e3 |
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| 247 | # Timor Passage : e1v reduced to 20 km |
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| 248 | #e1v[163:165,55] = 20.e3 |
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| 249 | # W Halmahera : e1v reduced to 30 km |
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| 250 | e1v[180:182,54] = 30.e3 |
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| 251 | # E Halmahera : e1v reduced to 50 km |
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| 252 | e1v[180:182,57] = 50.e3 |
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| 253 | # ORCA R05 configuration |
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| 254 | if model == 'ORCA.05' : |
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| 255 | # Reduced e2u at the Gibraltar Strait |
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| 256 | e2u[326,562:564] = 20.e3 |
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| 257 | # Reduced e2u at the Bosphore Strait |
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| 258 | e2u[342,626:628] = 10.e3 |
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| 259 | # Reduced e2u at the Sumba Strait |
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| 260 | e2u[231,92:94] = 40.e3 |
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| 261 | # Reduced e2u at the Ombai Strait |
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| 262 | e2u[231,102] = 15.e3 |
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| 263 | # Reduced e2u at the Palk Strait |
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| 264 | e2u[269,14] = 10.e3 |
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| 265 | # Reduced e1v at the Lombok Strait |
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| 266 | e1v[231:233,86] = 10.e3 |
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| 267 | # Reduced e1v at the Bab el Mandeb |
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| 268 | e1v[275,661] = 25.e3 |
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| 269 | |
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[5947] | 270 | # compute cells areas |
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[5940] | 271 | |
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[5947] | 272 | for cd_type in ['T', 'U', 'V', 'F', 'W'] : |
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| 273 | areaName = 'area_grid_' + cd_type |
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| 274 | if coordperio : |
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| 275 | locals()[areaName] = nemo.lbc (locals()['e1'+gridv[cd_type]]*locals()['e2'+gridv[cd_type]], |
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| 276 | nperio=nperio, cd_type=cd_type, nemo_4U_bug=nemoUbug) |
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| 277 | else : |
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| 278 | locals()[areaName] = locals()['e1'+gridv[cd_type]]*locals()['e2'+gridv[cd_type]] |
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[5940] | 279 | |
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[5947] | 280 | # rename indices |
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| 281 | locals()[areaName] = locals()[areaName].rename ({'y':'y_grid_'+cd_type, 'x':'x_grid_'+cd_type}) |
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[5940] | 282 | |
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[5947] | 283 | # add attributes |
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| 284 | locals()[areaName].name = areaName |
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| 285 | locals()[areaName].attrs['standard_name'] = 'cell_area' |
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| 286 | locals()[areaName].attrs['units'] = 'm2' |
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[5940] | 287 | |
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[5947] | 288 | # remove fill values |
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[5940] | 289 | locals()[areaName].encoding['_FillValue'] = None |
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| 290 | |
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[5947] | 291 | ## |
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| 292 | #!!! compute grid bounds !!! |
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| 293 | ## |
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| 294 | |
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| 295 | #--------------------------------------------------------------- |
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| 296 | # function to generate grid bounds from NEMO coordinates.nc file |
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| 297 | def set_bounds (cdgrd) : |
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| 298 | ''' |
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| 299 | Constructs lon/lat bounds |
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| 300 | Bounds are numerated counter clockwise, from bottom left |
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| 301 | See NEMO file OPA_SRC/IOM/iom.F90, ROUTINE set_grid_bounds, for more details |
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| 302 | ''' |
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| 303 | # Define offset of coordinate representing bottom-left corner |
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| 304 | if cdgrd in ['T', 'W'] : |
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| 305 | icnr = -1 ; jcnr = -1 |
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| 306 | corner_lon = f_coord ['glamf'].copy() ; corner_lat = f_coord ['gphif'].copy() |
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| 307 | center_lon = f_coord ['glamt'].copy() ; center_lat = f_coord ['gphit'].copy() |
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| 308 | if cdgrd == 'U' : |
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| 309 | icnr = 0 ; jcnr = -1 |
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| 310 | corner_lon = f_coord ['glamv'].copy() ; corner_lat = f_coord ['gphiv'].copy() |
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| 311 | center_lon = f_coord ['glamu'].copy() ; center_lat = f_coord ['gphiu'].copy() |
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| 312 | if cdgrd == 'V' : |
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| 313 | icnr = -1 ; jcnr = 0 |
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| 314 | corner_lon = f_coord ['glamu'].copy() ; corner_lat = f_coord ['gphiu'].copy() |
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| 315 | center_lon = f_coord ['glamv'].copy() ; center_lat = f_coord ['gphiv'].copy() |
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| 316 | if cdgrd == 'F' : |
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| 317 | icnr = -1 ; jcnr = -1 |
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| 318 | corner_lon = f_coord ['glamt'].copy() ; corner_lat = f_coord ['gphit'].copy() |
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| 319 | center_lon = f_coord ['glamf'].copy() ; center_lat = f_coord ['gphif'].copy() |
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| 320 | |
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| 321 | jpj, jpi = corner_lon.shape ; |
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| 322 | nvertex = 4 |
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| 323 | dims = ['y_grid_' + cdgrd, 'x_grid_' + cdgrd, 'nvertex_grid_' + cdgrd] |
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| 324 | |
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| 325 | bounds_lon = xr.DataArray (np.zeros ((jpj, jpi, nvertex)), dims=dims) |
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| 326 | bounds_lat = xr.DataArray (np.zeros ((jpj, jpi, nvertex)), dims=dims) |
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| 327 | |
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| 328 | idx = [(jcnr,icnr), (jcnr,icnr+1), (jcnr+1,icnr+1), (jcnr+1,icnr)] |
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| 329 | |
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| 330 | # Compute cell vertices that can be defined, |
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| 331 | # and complete with periodicity |
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| 332 | for nn in range (nvertex) : |
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| 333 | tmp = np.roll (corner_lon, shift=tuple(-1*np.array(idx[nn])), axis=(-2,-1)) |
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| 334 | bounds_lon[1:jpj,1:jpi,nn] = tmp[1:jpj,1:jpi] |
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| 335 | tmp = np.roll (corner_lat, shift=tuple(-1*np.array(idx[nn])), axis=(-2,-1)) |
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| 336 | bounds_lat[1:jpj,1:jpi,nn] = tmp[1:jpj,1:jpi] |
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| 337 | bounds_lon[:,:,nn] = nemo.lbc (bounds_lon[:,:,nn], nperio=nperio, cd_type=cdgrd, nemo_4U_bug=nemoUbug) |
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| 338 | bounds_lat[:,:,nn] = nemo.lbc (bounds_lat[:,:,nn], nperio=nperio, cd_type=cdgrd, nemo_4U_bug=nemoUbug) |
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| 339 | |
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| 340 | # Zero-size cells at closed boundaries if cell points provided, |
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| 341 | # otherwise they are closed cells with unrealistic bounds |
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| 342 | if not (nperio == 1 or nperio == 4 or nperio == 6) : |
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| 343 | for nn in range (nvertex) : |
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| 344 | bounds_lon[:,0,nn] = center_lon[:,0] # (West or jpni = 1), closed E-W |
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| 345 | bounds_lat[:,0,nn] = center_lat[:,0] |
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| 346 | bounds_lon[:,jpi,nn] = center_lon[:,jpi] # (East or jpni = 1), closed E-W |
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| 347 | bounds_lat[:,jpi,nn] = center_lat[:,jpi] |
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| 348 | if nperio != 2 : |
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| 349 | for nn in range (nvertex) : |
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| 350 | bounds_lon[0,:,nn] = center_lon[0,:] # (South or jpnj = 1), not symmetric |
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| 351 | bounds_lat[0,:,nn] = center_lat[0,:] |
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| 352 | if nperio < 3 : |
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| 353 | for nn in range (nvertex) : |
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| 354 | bounds_lon[jpj,:,nn] = center_lon[jpj,:] # (North or jpnj = 1), no north fold |
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| 355 | bounds_lat[jpj,:,nn] = center_lat[jpj,:] |
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| 356 | |
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| 357 | # Rotate cells at the north fold |
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| 358 | if nperio >= 3 : |
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| 359 | # Working array for location of northfold |
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| 360 | z_fld = nemo.lbc (np.ones ((jpj, jpi)), nperio=nperio, cd_type=cdgrd, psgn=-1., nemo_4U_bug=nemoUbug) |
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| 361 | z_fld = np.repeat((z_fld == -1.0)[...,np.newaxis],4,axis=2) |
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| 362 | # circular shift of 2 indices in bounds third index |
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| 363 | bounds_lon_tmp = np.roll (bounds_lon, shift=-2, axis=2) |
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| 364 | bounds_lat_tmp = np.roll (bounds_lat, shift=-2, axis=2) |
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| 365 | bounds_lon[:,:,:] = np.where (z_fld, bounds_lon_tmp[:,:,:] , bounds_lon[:,:,:] ) |
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| 366 | bounds_lat[:,:,:] = np.where (z_fld, bounds_lat_tmp[:,:,:] , bounds_lat[:,:,:] ) |
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| 367 | |
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| 368 | # Invert cells at the symmetric equator |
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| 369 | if nperio == 2 : |
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| 370 | bounds_lon_tmp = np.roll (bounds_lon, shift=-2, axis=2) |
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| 371 | bounds_lat_tmp = np.roll (bounds_lat, shift=-2, axis=2) |
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| 372 | bounds_lon [0,:,:] = bounds_lon [0,:,:] |
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| 373 | bounds_lat [0,:,:] = bounds_lat [0,:,:] |
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| 374 | |
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| 375 | #bounds_lon.attrs['coordinates'] = 'nav_lat_grid_' + cdgrd + ' nav_lon_grid_' + cdgrd |
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| 376 | #bounds_lat.attrs['coordinates'] = 'nav_lat_grid_' + cdgrd + ' nav_lon_grid_' + cdgrd |
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| 377 | bounds_lon.attrs['units'] = 'degrees_east' |
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| 378 | bounds_lat.attrs['units'] = 'degrees_north' |
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| 379 | bounds_lon.name = 'bounds_lon_grid_' + cdgrd |
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| 380 | bounds_lat.name = 'bounds_lat_grid_' + cdgrd |
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| 381 | # remove _FillValue |
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| 382 | bounds_lon.encoding['_FillValue'] = None |
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| 383 | bounds_lat.encoding['_FillValue'] = None |
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| 384 | |
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| 385 | return bounds_lon, bounds_lat |
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| 386 | #------------------------------------------------------------ |
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| 387 | |
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[5940] | 388 | bounds_lon_grid_T, bounds_lat_grid_T = set_bounds ('T') |
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| 389 | bounds_lon_grid_U, bounds_lat_grid_U = set_bounds ('U') |
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| 390 | bounds_lon_grid_V, bounds_lat_grid_V = set_bounds ('V') |
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| 391 | bounds_lon_grid_W, bounds_lat_grid_W = set_bounds ('W') |
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| 392 | bounds_lon_grid_F, bounds_lat_grid_F = set_bounds ('F') |
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| 393 | |
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| 394 | # build xarray dataset to be saved |
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| 395 | ds = xr.Dataset ({ |
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| 396 | 'mask_T' : mask_T , |
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| 397 | 'mask_U' : mask_U , |
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| 398 | 'mask_V' : mask_V , |
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| 399 | 'mask_W' : mask_W , |
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| 400 | 'mask_F' : mask_F , |
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| 401 | 'area_grid_T' : area_grid_T, |
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| 402 | 'area_grid_U' : area_grid_U, |
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| 403 | 'area_grid_V' : area_grid_V, |
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| 404 | 'area_grid_W' : area_grid_W, |
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| 405 | 'area_grid_F' : area_grid_F, |
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| 406 | 'maskutil_T' : maskutil_T , |
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| 407 | 'maskutil_U' : maskutil_U , |
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| 408 | 'maskutil_V' : maskutil_V , |
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| 409 | 'maskutil_W' : maskutil_W , |
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| 410 | 'maskutil_F' : maskutil_F , |
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| 411 | 'bounds_lon_grid_T': bounds_lon_grid_T, |
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| 412 | 'bounds_lat_grid_T': bounds_lat_grid_T, |
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| 413 | 'bounds_lon_grid_U': bounds_lon_grid_U, |
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| 414 | 'bounds_lat_grid_U': bounds_lat_grid_U, |
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| 415 | 'bounds_lon_grid_V': bounds_lon_grid_V, |
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| 416 | 'bounds_lat_grid_V': bounds_lat_grid_V, |
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| 417 | 'bounds_lon_grid_W': bounds_lon_grid_W, |
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| 418 | 'bounds_lat_grid_W': bounds_lat_grid_W, |
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| 419 | 'bounds_lon_grid_F': bounds_lon_grid_F, |
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| 420 | 'bounds_lat_grid_F': bounds_lat_grid_F, |
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| 421 | }) |
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| 422 | |
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| 423 | #replace nav_lon nav_lat with variables obtained from NEMO coordinates.nc file |
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[5947] | 424 | #by construction nav_lon nav_lat come from the bathymetry |
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[5940] | 425 | for cd_type in ['T', 'U', 'V', 'F', 'W'] : |
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[5947] | 426 | for dir_type in ['lon', 'lat'] : |
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[5940] | 427 | coord_name = 'nav_' + dir_type + '_grid_' + cd_type |
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| 428 | ds.coords[coord_name]=locals()[coord_name] |
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| 429 | |
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| 430 | ds.attrs['name'] = 'coordinates_mask' |
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| 431 | ds.attrs['description'] = 'coordinates and mask for MOSAIX' |
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| 432 | ds.attrs['title'] = 'coordinates_mask' |
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| 433 | ds.attrs['source'] = 'IPSL Earth system model' |
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| 434 | ds.attrs['group'] = 'ICMC IPSL Climate Modelling Center' |
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| 435 | ds.attrs['Institution'] = 'IPSL https.//www.ipsl.fr' |
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| 436 | ds.attrs['Model'] = model |
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| 437 | ds.attrs['timeStamp'] = '{:%Y-%b-%d %H:%M:%S}'.format (datetime.datetime.now ()) |
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| 438 | ds.attrs['history'] = 'Build from ' + n_coord + ' and ' + n_bathy |
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| 439 | ds.attrs['directory'] = os.getcwd () |
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| 440 | ds.attrs['user'] = os.getlogin () |
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| 441 | ds.attrs['HOSTNAME'] = platform.node () |
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| 442 | ds.attrs['Python'] = 'Python version: ' + platform.python_version () |
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| 443 | ds.attrs['xarray'] = 'xarray version: ' + xr.__version__ |
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| 444 | ds.attrs['OS'] = platform.system () |
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| 445 | ds.attrs['release'] = platform.release () |
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| 446 | ds.attrs['hardware'] = platform.machine () |
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| 447 | |
---|
| 448 | ds.attrs['SVN_Author'] = "$Author: $" |
---|
| 449 | ds.attrs['SVN_Date'] = "$Date: $" |
---|
| 450 | ds.attrs['SVN_Revision'] = "$Revision: $" |
---|
| 451 | ds.attrs['SVN_Id'] = "$Id: Build_coordinates_mask.py $" |
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| 452 | ds.attrs['SVN_HeadURL'] = "$HeadURL: http://forge.ipsl.jussieu.fr/igcmg/svn/TOOLS/MOSAIX/Build_coordinates_mask.py $" |
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| 453 | |
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| 454 | # save to output file |
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| 455 | ds.to_netcdf (n_out) |
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