# -*- coding: iso-8859-15 -*- # Python to manage plot data in netCDF files. # From L. Fita work in different places: LMD (France) # More information at: http://www.xn--llusfb-5va.cat/python/PyNCplot # # pyNCplot and its component drawing.py comes with ABSOLUTELY NO WARRANTY. # This work is licendes under a Creative Commons # Attribution-ShareAlike 4.0 International License (http://creativecommons.org/licenses/by-sa/4.0) # import numpy as np import os from netCDF4 import Dataset as NetCDFFile import nc_var_tools as ncvar import drawing_tools as drw import generic_tools as gen from optparse import OptionParser import sys from cStringIO import StringIO import numpy.ma as ma ## e.g. # drawing.py -f /media/data2/etudes/WRF_LMDZ/WL_HyMeX/IIphase/medic950116/wlmdza/wrfout/wrfout_d01_1995-01-13_00:00:00 -o create_movie -S 'draw_2D_shad#Time@WRFTimes@10@95@191@1#tas:East_West|-1,North_South|-1,Time|2:longitude:latitude:Summer:270.,300.:tas|at|t=0:pdf:None:None' -v T2 ## e.g. # drawing.py -o draw_2D_shad -f wrfout_d01_2001-11-11_00:00:00 -S 'tas:west_east|-1,south_north|-1,Time|2:XLONG:XLAT:auto:rainbow,auto,auto:Srange,Srange:tas|at|2001-11-11|02|UTC:png:None:cyl,l:True' -v T2 ## e.g. # drawing.py -o draw_2D_shad_time -f wrfout_d01_2001-11-11_00:00:00 -S 'hurs~west_east|-1,south_north|27,Time|-1~XLONG~WRFtime~auto~Blues,auto,auto~Srange,Srange~tas|evolution|at|south_north=27~png~None~WRFtime|hours!since!1949-12-01|exct,1,h|$%d^{%H}$|date!($[DD]^{[HH]}$)~True' -v Q2 ## e.g. #drawing.py -o draw_2D_shad_time -f ERAI_pl201507_130.nc -S 'ta~lon|52,lat|30,time|76@100~lev~time~auto~rainbow,auto,vertical~200.,310.~data,data~ta|in|valley|from|ERA-Interim~png~transpose~time|hours!since!2015-07-01!00:00:00|exct,12,h|$%d^{%H}$|date!($[DD]^{[HH]}$)~True' -v t ## e.g. #drawing.py -o draw_2D_shad_time -f ERAI_pl201507_130.nc -S 'ta~lon|52,lat|30,time|76@100~lev~time~auto~rainbow,auto,vertical~200.,310.~data,fixpixel~ta|in|valley|from|ERA-Interim~png~transpose~time|hours!since!2015-07-01!00:00:00|exct,12,h|$%d^{%H}$|date!($[DD]^{[HH]}$)~True' -v t ## e.g. # drawing.py -o draw_2D_shad_cont -f wrfout_d01_2001-11-11_00:00:00 -S 'huss,tas:west_east|-1,south_north|-1,Time|2:Time|2:XLONG:XLAT:auto:Blues,auto,auto:fixc,r:%3g:Srange,Srange:260,300,9:huss|&|tas|at|2001-11-11|02|UTC:png:None:cyl,c:True' -v Q2,T2 ## e.g. # drawing.py -o draw_2D_shad_cont_time -f wrfout_d01_2001-11-11_00:00:00 -S 'hfls,tas;west_east|-1,south_north|27,Time|-1;south_north|27;XLONG;WRFtime;auto;BuPu,auto,auto;fixc,y;%3g;Srange,Srange;260,300,9;huss|&|tas|evolution|at|south_north=27;png;None;WRFtime|hours!since!1949-12-01|exct,1,h|$%d^{%H}$|date!($[DD]^{[HH]}$);True' -v LH,T2 ## e.g. # drawing.py -o draw_2D_shad_line -f wrfout_d01_2001-11-11_00:00:00,wrfout_d01_2001-11-11_00:00:00 -S 'hus,hgt:west_east|-1,south_north|96,Time|2,bottom_top|-1:XLONG:ZNU:auto:rainbow,auto,horizontal:Srange,Srange:k,0.,4000.,auto,auto,auto,45.:vert.|sec.|hus|at|y=96|on|2001-11-11|02|UTC:png:flip@y:None:True' -v QVAPOR,HGT ## e.g. # drawing.py -o draw_barbs -f wrfout_d01_2001-11-11_00:00:00 -S 'west_east|XLONG|-1,west_east_stag|XLONG|0@239@1,south_north|XLAT|15,bottom_top|ZNU|-1,bottom_top_stag|ZNW|0@39@1,Time|WRFtime|3:10@2,colormap@rainbow,7.:uw,ms-1:XLONG:ZNW:None:auto:flip@y:vertical|cross|section|wind|speed|at|y=15|on|2001-11-10|03|UTC:png:wind_barbs_2001111003_uw:True' -v U,W ## e.g. # drawing.py -f geo_em.d02.nc -o draw_topo_geogrid -S '0.,1500.:None:2km!domain!centered!at!SIRTA:png:cyl,i:True' ## e.g. # python ../drawing.py -f ~/etudes/domains/SIRTA/geo_em.d01.nc,/home/lluis/etudes/domains/SIRTA/geo_em.d02.nc -o draw_topo_geogrid_boxes -S '0.,1500.:None:WRF!domain!centered!at!SIRTA:png:cyl,i:d01$_{15k}$,d02$_{3k}$:0|10:True' ## e.g. # drawing.py -f ~/etudes/domains/MEDCORDEX/geo_em.d01.nc -o draw_2D_shad_cont -S 'height,landmask:Time|0:Time|0:XLONG_M:XLAT_M:terrain:fixc,k:None:0.,3000.:0,1,10:MEDCORDEX height & landmask:pdf:False:lcc,i' -v HGT_M,LANDMASK ## e.g. # $ drawing.py -f WRF/current/hurs_wrfout_tturb_xmean_last.nc,WRF/micro1/hurs_wrfout_tturb_xmean_last.nc,WRF/micro2/hurs_wrfout_tturb_xmean_last.nc,WRF_LMDZ/AR40/hurs_wrfout_tturb_xmean_last.nc,WRF_LMDZ/NPv31/hurs_wrfout_tturb_xmean_last.nc,LMDZ/AR40/hurs_reproj-histins_tturb_xmean_last.nc,LMDZ/NPv31/hurs_reproj-histins_tturb_xmean_last.nc -o draw_lines -S 'lat:x:lat ($degrees\ North$):auto:auto:wcurr,wmp1,wmp2,wlmdza,wlmdzb,lmdza,lmdzb:hurs:all model-experiments meridional hurs$_{[tturb\ xmean\ last]}$:0|auto:None:-:,:2.:2.:all:Nlines_hurs_wrfout_tturb-xmean-last:png:True' -v hursturbmean ## e.g. # drawing.py -o draw_lines_time -f wrfout_d01_2001-11-11_00:00:00_west_east_B20-E20-I1_south_north_B20-E20-I1.nc,wrfout_d01_2001-11-11_00:00:00_west_east_B25-E25-I1_south_north_B25-E25-I1.nc,wrfout_d01_2001-11-11_00:00:00_west_east_B35-E35-I1_south_north_B35-E35-I1.nc -S 'WRFtime;y;time ([DD]${[HH]}$);auto;we=20$\times$sn=20,we=25$\times$sn=25,we=35$\times$sn=35;tas;tas|evolution|at|3|different|grid|points;None;time|hours!since!1949-12-01_00:00:00|exct,3,h|%d$^{%H}$;0|12;pdf;-;r,g,b;.;2.;2.;all;-1;True' -v T2 ## e.g. # drawing.py -o draw_lines_time -f 'TRMM_1999-2010_prec_mm-year_hydyearsum_sellonlatbox2005_fldmean.nc%time|-1;lon|0;lat|0,CRUNCEP_1999-2010_prec_mm-year_hydyearsum_sellonlatbox2005_fldmean.nc%time|-1;lon|0;lat|0,WFDEIgpcc_1999-2010_prec_mm-year_hydyearsum_sellonlatbox2005_fldmean.nc%time|-1;lon|0;lat|0' -S 'time;y;time;auto;TRMM,CRUNCEP,WFDEIgpcc;prec;prec|hydrological|year;auto,auto;time|exct,1,y|%Y;0|auto;png;-;k,b,g;.;2;2;all;-1;True' -v prec ## e.g. # drawing.py -o draw_Neighbourghood_evol -S 'vas:Time|-1|WRFtime,south_north|44|XLAT,west_east|88|XLONG:south_north,west_east:5:auto:time|($[DD]^{[HH]}$),time|($[DD]^{[HH]}$):exct,1,h|exct,3,h:$%d^{%H}$,$%d^{%H}$:5|pts|neighbourghood|temporal|evolution|on|2001|Nov.|at|x=88,|y=44:0.0,20.:rainbow,auto,auto:auto:png:vas_Neigh_evol:True' -f ~/PY/wrfout_d01_2001-11-11_00:00:00 -v V10 ## e.g. # drawing.py -o draw_points -S 'SuperStorm/tslist.dat,#,3,2,1:SuperStorm|sfc|stations:auto:cyl,i:labelled,10,r:auto:None:0:png:stations_loc:True' -f 'geo_em.d02.nc,XLONG_M,XLAT_M,HGT_M,Time|0@west_east|30;180;1@south_north|175;255;1,height,0.,1500.,terrain,auto,auto,m' ## e.g. # drawing.py -o draw_WindRose -S 'lon|7;lat|2:anglespeedfreq;16;8;40.;auto;auto:November!ERA-I!daily!mean!wind!at!850!hPa:png:cardinals:False:WindRose:True' -v u,v -f reg1_daymean_mon11_lev850_kmh.nc ## e.g. # drawing.py -o draw_WindRose -S 'lon|7;lat|2:linepoint;multicoltime;time;auto;auto;auto;auto;exct,5,d;%m/%d;date!([DD]/[MM]):November!ERA-I!daily!mean!wind!at!850!hPa:png:cardinals:False:WindRose:True' -v u,v -f reg1_daymean_mon11_lev850_kmh.nc ## e.g. # drawing.py -o draw_Taylor -f 'file0.nc@var,file1.nc@var,file2.nc@var,file3.nc@var' -S '$10.\sin(0.05t2\pi)$:x:8:k,b,r,g,#FFBB00:$10.25\sin(0.025+0.05t2\pi)$,$10.25\sin(0.025+0.05125t2\pi)$,$10.5\sin(0.05+0.05t2\pi)$,$10.\sin(0.05+0.0525t2\pi)$:legend,0,8:norm:sinus!Taylor!diagram:png:yes:True' -v reffile.nc,var ## e.g. # drawing.py -o draw_timeSeries -f ~/PY/ERAI_pl199501_131-132.nc -S 'lon|240,lat|120,time|-1,lev|0:Srange,Srange:ua:date|($[MM]^{[DD]}$):exct,15,d:$%m^{%d}$:January|1995|ERA-Interim|x-wind|at|i=240,|j=120,|k=0:ua:0|12:png:r:-:2:x:2:20:yes' -v var131,time ## e.g. # drawing.py -o draw_trajectories -f 'medic950116/control/trajectory.dat@-1@etudes/domains/WL_HyMeX_HighRes_C/geo_em.d01.nc#XLONG_M#XLAT_M@t-step|3600.|19950115000000,medic950116/wlmdza/trajectory.dat@-1@etudes/domains/WL_HyMeX_C/geo_em.d01.nc#XLONG_M#XLAT_M@t-step|3600.|19950115000000,medic950116/wlmdzb/trajectory.dat@-1@etudes/domains/WL_HyMeX_C/geo_em.d01.nc#XLONG_M#XLAT_M@t-step|3600.|19950115000000,medic950116/wlmdzb_cyc/trajectory.dat@-1@etudes/domains/WL_HyMeX_C/geo_em.d01.nc#XLONG_M#XLAT_M@t-step|3600.|19950115000000' -S 'spaghetti_date@-@None@1@o@1@$%d^{%H}$@8@6@4@4|$WRF_{CRM}$,$LMDZ_{AR4.0}$,$LMDZ_{NPv3.1}$,$LMDZ_{NPv3.1b}$|15,28,26,39|medicane trajectories|png|cyl,i|0@8|yes' -v 'medic950116/obs/trajectory.dat,satellite,-1,0.9999998779E+03,t-step|1800.|19950115000000@auto' ## e.g. # drawing.py -o draw_2D_shad_2cont -f hur_157_100000_20051214000000-20051218000000.nc,z_129_100000_20051214000000-20051218000000.nc,ta_130_100000_20051214000000-20051218000000.nc -S 'hur@100000,z@100000,ta@100000:time|0,lev|0,lat|-1,lon|-1:time|0,lev|0,lat|-1,lon|-1:time|0,lev|0,lat|-1,lon|-1:lon:lat:auto:BuPu,auto,auto:fixc,green:None:fixc,red:None:60.,100.:-700.,4000.,8:265.,300.,8:hur|z|ta|@100000|on|20051214000000:png:flip@y:cyl,l:yes' -v hur,z,ta ## e.g. # drawing.py -o draw_ptZvals -f MountainPeaks.nc -S 'height:lon,lat:auto:x:5.:-180.,-90.,180.,90.:0,9000.:ptlabel,name,8,0,4:Mountain!peaks:rainbow,auto,auto:cyl,l:png:yes' -v height ## e.g. # drawing.py -o draw_vectors -f wrfout_d01_1995-01-01_00:00:00 -S 'T|Time|Times|2,Y|south_north|XLAT|-1,X|west_east|XLONG|-1:auto:3@3,wind@rainbow@Srange|Srange,9:10m wind,ms-1:cyl,l:WRF!10!m!winds!on!Dec.!1st!1995!06!UTC:png:winds:yes' -v U10,V10 ## e.g.# drawing.py -o draw_vertical_levels -f wrfout_d01_1995-01-01_00:00:00 -S 'true,true:false,false:wrfout!vertical!levels!(LUPA):png:4|12:yes' -v WRFz ## e.g. # drawing.py -o draw_subbasin -f Caceres_subbasin.nc -S 'Caceres:None:cyl,l:2:True:Parana!subbasins!from!Cáceres:png:0:Caceres_subbasin:True:True' ## e.g. # drawing.py -o draw_basins -f routing.nc -S '-5,5,42.,52.:l:rainbow,auto,auto:1,1000:True:True:True:ORCDHIEE|river-basins:png:basins_named:True' -v nav_lon,nav_lat,trip,basins ## e.g. # drawing.py -o draw_river_desc -f river_desc.nc -S 'Y|lat|lat|-1,X|lon|lon|-1:red,green:Blues:cyl,l:ORCDHIEE|rivers:png:0:or_rivers:True' -v Amazon,Parana ## e.g. # drawing.py -f forcing_Amazonia.nc,forcing_Amazonia.nc -o draw_2lines_time -S 'tstep:Excts:Excts:exct,5,y;%Y:x:tas,wss:r,b:2.:-,-:None:,;,:WFD!forcing!evolution!at!Amazonia:year:0|12:../LaTeX/figs/forcing_Amazonia_tas-wss:png:yes' -v Tair,Wind ## e.g. # drawing.py -o draw_bar -f 'Forcing_rainstats_OKstomate_CRUNCEP_spinup_SESA_norm_meanstd_stat2.nc;time_counter,0@12@1;time_counter;rainnorm:Forcing_rainstats_OKstomate_CRUNCEP_spinup_SACZ_norm_meanstd_stat2.nc;time_counter,0@12@1;time_counter;rainnorm' -S 'Stringlist,%s,January@Feburary@March@Arpil@May@June@July@August@September@October@November@December,25,pretty,auto,auto,auto:time!since!1958-01-01:pr:y:seconds:mmd-1:SESA,SACZ:#AA0000,#0000AA:1000000.:normalized!evolution!of!precipitaion!with!CRU-NCEP!forcing:0|10:png:bar_rain_CRU-NCEP_norm:yes' ## e.g. # drawing.py -o draw_bar_time -f 'Forcing_rainstats_OKstomate_CRUNCEP_spinup_SESA_DJFmean_norm_meanstd_stat2.nc;time_centered,-1;time_centered;rainnorm:Forcing_rainstats_OKstomate_CRUNCEP_spinup_SACZ_DJFmean_norm_meanstd_stat2.nc;time_centered,-1;time_centered;rainnorm' -S 'auto;pr;1;y;None;year|seconds!since!1958-01-01!00:00:00|exct,5,y|%Y;SESA,SACZ;#AA0000,#0000AA;10000000.;normalized!evolution!of!DJFmean!of!precipitaion!with!CRU-NCEP!forcing;0|10;png;bar_time_rain_CRU-NCEP_DJFmean_norm;yes' ## e.g. # drawing.py -o draw_bar_line -f 'Forcing_rainstats_OKstomate_CRUNCEP_spinup_SESA_norm_meanstd_stat2.nc;time_counter,0@12@1;time_counter;rainnorm;bar:Forcing_rainstats_OKstomate_CRUNCEP_spinup_SESA_norm_meanstd_stat2.nc;time_counter,12@24@1;time_counter;rainnorm;bar:Forcing_rainstats_OKstomate_CRUNCEP_spinup_SACZ_norm_meanstd_stat2.nc;time_counter,0@12@1;time_counter;rainnorm;line:Forcing_rainstats_OKstomate_CRUNCEP_spinup_SACZ_norm_meanstd_stat2.nc;time_counter,12@24@1;time_counter;rainnorm;line' -S 'Stringlist,%s,January@Feburary@March@April@May@June@July@August@September@October@November@December@Jan@Feb@Mar@Apr@May@Jun@Jul@Aug@Sept@Oct@Nov@Dec,25,pretty,auto,auto,auto:time!since!1958-01-01:pr:x:-4.,4.:seconds:1:$SESA_{1958}$,$SESA_{1959}$,$SACZ_{1958}$,$SACZ_{1959}$:#AA0000,#0000AA:1000000.:#00AA00,#AAAA00:-.:,:2.:2.:all:normalized!evolution!of!precipitation!with!CRU-NCEP!forcing:0|10:png:bar-line_rain_CRU-NCEP_norm:yes' ## e.g. # drawing.py -o draw_bar_line_time -f 'Forcing_rainstats_OKstomate_SESA_DJFmean_norm_meanstd_stat2.nc;time_centered,-1;time_centered;rainnorm;bar:Forcing_rainstats_OKstomate_SACZ_DJFmean_norm_meanstd_stat2.nc;time_centered,-1;time_centered;rainnorm;bar:DiPolo_evapstats_OKstomate_SESA_DJFmean_stat2.nc;time_centered,-1;time_centered;evap_stats;line:DiPolo_evapnustats_OKstomate_SESA_DJFmean_stat2.nc;time_centered,-1;time_centered;evapnu_stats;line:DiPolo_evspsblvegstats_OKstomate_SESA_DJFmean_stat2.nc;time_centered,-1;time_centered;evspsblveg_stats;line:DiPolo_transpirstats_OKstomate_SESA_DJFmean_stat2.nc;time_centered,-1;time_centered;transpir_stats;line:DiPolo_evapstats_OKstomate_SACZ_DJFmean_stat2.nc;time_centered,-1;time_centered;evap_stats;line:DiPolo_evapnustats_OKstomate_SACZ_DJFmean_stat2.nc;time_centered,-1;time_centered;evapnu_stats;line:DiPolo_evspsblvegstats_OKstomate_SACZ_DJFmean_stat2.nc;time_centered,-1;time_centered;evspsblveg_stats;line:DiPolo_transpirstats_OKstomate_SACZ_DJFmean_stat2.nc;time_centered,-1;time_centered;transpir_stats;line' -S 'auto;pr;y;None;1;year|seconds!since!1958-01-01!00:00:00|exct,5,y|%Y;SESA,SACZ,SESA!evap,evapnu,evspblveg,transpir,SACZ!evap,None,None,None;#AA0000,#0000AA;10000000.;#AAAA00,#00AAAA,#AA00AA,#AAAAAA,#AAAA00,#00AAAA,#AA00AA,#AAAAAA;-,-,-,-,--,--,--,--;,;2.;2.;all;normalized!evolution!of!DJFmean!with!WFD3!forcing;0|10;png;bar_time_rain_CRU-NCEP_DJFmean_norm;yes' ## e.g. # drawing.py -o draw_time_lag -f 'Forcing_rainstats_OKstomate_SESA_norm_meanstd_stat2.nc;time_centered,-1;time_counter;rainnorm%DiPolo_evapstats_SESA_norm_meanstd_OKstomate.nc;time_counter,-1|stats,2;time_counter;evapnorm:Forcing_rainstats_OKstomate_SACZ_norm_meanstd_stat2.nc;time_centered,-1;time_counter;rainnorm%DiPolo_evapstats_SACZ_norm_meanstd_OKstomate.nc;time_counter,-1|stats,2;time_counter;evapnorm' -S 'auto;centered;pr;1;evap;1;-5,5;-2,2;year|seconds!since!1958-01-01!00:00:00|exct,5,y|%Y;SESA,SACZ;simplepts,1,#AA0000@#0000AA,x,2.;1-month!time-lag!at!SACZ!between!pr!&!evap!normalized!by!mean/stddev;0|12;png;mon1_timelag_pr-evap_SACZ;yes' ## e.g. # drawing.py -o draw_ensembles_time -f 'Forcing_rain_SESA.nc;time_counter,-1|stats,0;time_centered;rain_stats;ensemble#Forcing_rain_SESA.nc;time_counter,-1|stats,1;time_centered;rain_stats;ensemble#Forcing_rain_SESA.nc;time_counter,-1|stats,2;time_centered;rain_stats;data' -S 'auto;y;tas;mm/d;auto,auto;#0000FF:-:2.:,:2.;year|seconds!since!1958-01-01!00:00:00|exct,5,y|%Y;FromFile;$pr_{space-mean}^{SESA}$;cloud,#AAAADD,auto;$pr_{space-mean}$!evolution!at!SESA;0|10;png;Forcing_pr_spacemean;no;yes' ## e.g. # drawing.py -o draw_cycle -f 'Forcing_tairstats_OKstomate_CRUNCEP_spinup_SESA.nc;time_counter,-1|stats,2;time_centered;tair_stats' -S 'auto;y;centered;tair;K;None;12,3;lines,rainbow,horizontal,auto,-,2.;1,3,5@Sep/Nov,Jan/Jul,Mar/May;year|seconds!since!1958-01-01!00:00:00|exct,5,y|%Y;SESA;year-evolution!of!CRUNCEP!tair!forcing!at!SESA;0|10;png;cycle_tair_CRUNCEP_spinup_SESA;yes' ## e.g. # drawing.py -o draw_multi_2D_shad -f '../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|0;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|1;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|2;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|3' -S 'tas:XLONG:XLAT:auto:rainbow,auto,auto:Srange,Srange:png:None:cyl,l:0!UTC,1!UTC,2!UTC,3!UTC:2:2:tas!at!2001-11-11:True' # movie_2D_shad -f '../PY/wrfout_d01_1995-01-01_00:00:00' -S 'tas:west_east|-1,south_north|-1,Time|-1:XLONG:XLAT:auto:rainbow,auto,auto:Srange,Srange:png:None:cyl,l:Time,Times:WRFdate,$%d^{%H}$:15:mp4' -v T2 ## e.g. # drawing.py -o draw_SkewT -f UWyoming_snd_87576.nc -S 'time|0:auto:auto:Sounding!at!Ezeiza!airport!on!3rd!July!1998:png:yes' -v ta,tda,pres ## e.g. # drawing.py -o draw_multi_SkewT -f 'UWyoming_snd_87576.nc:pres|-1,time|0:ta,pres;UWyoming_snd_87576.nc:pres|-1,time|0:tda,pres' -S 'auto:auto:multilines!ta,tda!#6464FF,#FF6464!-!,!2:0,auto:Sounding!at!Ezeiza!airport!on!3rd!July!1998:png:yes' ## e.g. # drawing.py -o draw_2D_shad_contdisc -f 'simout_snddiags.nc;ta;time;pres;time|-1,pres|-1@UWyoming_snd_87576.nc;ta;time;pres;time|-1,pres|-1' -S 'ta:time,bottom_top:Vfix,auto,3600.,auto,Vfix,auto,50.,auto:auto:Srange,Srange:auto:obs!&!sim!Ezeiza!airport!sounding:pdf:flip@y:None:yes' ## e.g. # drawing.py -o draw_2D_shad_contdisc_time -f 'simout_snddiags.nc;ta;time;pres;time|-1,pres|-1@UWyoming_snd_87576.nc;ta;time;pres;time|-1,pres|-1' -S 'ta;y;auto|exct,12,h|%d$^{%H}$|time!($[DD]^{[HH]}$);Vfix,auto,50.,auto;auto;Srange,Srange;auto;obs!&!sim!Ezeiza!airport!sounding;pdf;flip@y;None;yes' ## e.g. # drawing.py -o draw_2D_shad_contdisc -f 'simout_sfcdiags.nc;tdas;XLONG;XLAT;Time|0,time|0,west_east|-1,south_north|-1@all_single-stations.nc;tdas;stslon;stslat;time|0,lon|-1,lat|-1' -S 'tdas:west_east,south_north:auto:YlGnBu,auto,auto:286.,298.:auto:obs!&!sim!tdas!on!1995/01/01!00!UTC:png:None:cyl,f:sponge,0.1,0.1:yes' ## e.g. # drawing.py -o draw_multiWindRose -f '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/sounding_uava_10868.nc@pres|-1;time|1@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_38lev.nc@bottom_top|-1;time|0@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_50lev.nc@bottom_top|-1;time|0@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_50lev_assigned.nc@bottom_top|-1;time|0@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_80lev.nc@bottom_top|-1;time|0@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_120lev.nc@bottom_top|-1;time|0@ua,va#/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_NOaerosol.nc@bottom_top|-1;time|0@ua,va' -S 'linepoint;multicol;pres;-;auto;spectral;auto:obs,38lev,50lev,50leva,80lev,120lev:WindRose!obs!sim!comparison!on!2012/10/23!00!UTC:png:auto:True' ## e.g. # drawing.py -o draw_stations_map -f stations.inf -S 'snd|x|#FFAAAA|2|8@sfc|x|#AAFFAA|2|8:cyl,l:1.,20.,35.,49.:FPS!Alps!stations:pdf:true' ## e.g. # drawing.py -o draw_WRFeta_levels -f 120lev/simin_vars.nc,80lev/simin_vars.nc,50lev/simin_vars.nc,50lev_assigned/simin_vars.nc,38lev/simin_vars.nc -f '120lev,80lev,50lev,50leva,38lev:auto:auto:0|6|2:FPS!Alps!vert!levels:pdf:no:true' ## e.g. # drawing.py -o draw_2Dshad_map -S 'orog;$conv^{ini}$;lat|-1,lon|-1;lon;lat;auto;rainbow#auto#auto#time@minutes!since!1949-12-01!00:00:00|exct,6,h|%d$^{%H}$|date!([DD]$^{[HH]}$);Srange,Srange;convini|Case1|1a;pdf;binary|shadow,NW,auto|-70.,-36,-62.,-30.;cyl,c;yes' -v convini -f UBA_ERA-I_1a_2D.nc ## e.g. # $pyHOME/drawing.py -o draw_river_pattern -S 'ORCHIDEEdef:ORCHIDEEdef:auto:cyl,l:None:-100.|-65.|-20.|15.:False:True:South|America|ORCHIDEE|routing|0.5|deg:pdf:0|10|1:True' -v Parana,Amazon ## e.g. # python ${pyHOME}/drawing.py -o draw_topofix_geogrid_boxes -f geo_em.d01.nc,geo_em.d02.nc -S 'None:RELAMPAGO!explicit!convection!configuration:pdf:cyl,i:d01$_{8k}$,d02$_{1.6k}$:0|10|1:auto:0.17|horizontal|8|10|-45.|0.8|0.15|#CCCCFF:auto:auto:auto:auto:auto:True' ## e.g. # drawing.py -o draw_geogrid_landuse -f geo_em.d01.nc -S None:PICT!AMBA-NO!WRF!domains!land-use!d0!(15!km):pdf-png:cyl,l:usgs|0.9:auto:auto:auto:auto:auto:True ####### # create_movie: Function to create a movie assuming ImageMagick installed! # draw_2D_shad: plotting a fields with shading # draw_2D_shad_cont: plotting two fields, one with shading and the other with contour lines # draw_2D_shad_contdisc: plotting one continuous fields with shading and another discrete one with points # draw_2D_shad_contdisc_time: plotting one continuous fields with shading and another discrete one with # points with a time-axis # draw_2D_shad_2cont: plotting three fields, one with shading and the other two with contour lines # draw_2D_shad_cont_time: plotting two fields, one with shading and the other with contour lines being # one of the dimensions of time characteristics # draw_2D_shad_line: plotting a fields with shading and another with line # draw_2D_shad_line_time: plotting a fields with shading and a line with time values # draw_2D_shad_time: plotting a fields with shading with time values # draw_2Dshad_map: plotting a shadow field with a background map # draw_2lines: Fucntion to plot two lines in different axes (x/x2 or y/y2) # draw_2lines_time: Function to plot two time-lines in different axes (x/x2 or y/y2) # draw_bar: Function to plot a bar char figure with multiple sources # draw_bar_line: Function to plot a bar char and line figure with multiple sources # draw_bar_line_time: Function to plot a bar char and line figure with multiple sources with a time-axis # draw_bar_time: Function to plot a bar char figure with multiple sources and time axis # draw_barbs: Function to plot wind barbs # draw_basins: Function to plot river basins with their discharge vector and basins id (from 'routing.nc') # draw_cycle: Function to plot a variale with a circular cycle # draw_ensembles_time: Function to plot an ensembles of data following an axis-time # draw_geogrid_landuse: plotting land-use data from geo_em.d[nn].nc WPS files # draw_lines: Function to draw different lines at the same time from different files # draw_lines_time: Function to draw different lines at the same time from different files with times # draw_multi_2D_shad: plotting multiple 2D fields with same projection with shading and sharing colorbar # draw_multi_SkewT: creation of a SkewT-logP diagram with multiple lines using matplotlib's API example # draw_multiWindRose: Function to plot multiple wind rose (from where the dinw blows) # draw_Neighbourghood_evol: Function to draw the temporal evolution of a neighbourghood around a point # draw_points: Function to plot a series of points # draw_points_lonlat: Function to plot a series of lon/lat points # draw_ptZvals: Function to plot a given list of points by their Z value and a colorbar # draw_river_pattern: Function to plot rivers' patterns from ORCHIDEE's routing scheme file # ('routing.nc' and 'river_desc.nc') # draw_SkewT: creation of a SkewT-logP diagram using matplotlib's API example # draw_stations_map: Function to plot a map with the stations # draw_time_lag: Function to plot a time-lag figure with multiple sources (x, previous values; y, future values) # draw_timeSeries: Function to draw a time-series # draw_topo_geogrid: plotting geo_em.d[nn].nc topography from WPS files # draw_topo_geogrid_boxes: plotting different geo_em.d[nn].nc topography from WPS files # draw_topofix_geogrid_boxes: plotting different geo_em.d[nn].nc topography from WPS files # on a fixed low-level enhanced color mode # draw_trajectories: Function to draw different trajectories at the same time # draw_vals_trajectories: Function to draw values from the outputs from 'compute_tevolboxtraj' # draw_vectors: Function to plot wind vectors # movievalslice: Function to prode variable slice according to a geneation of a movie # variable_values: Function to give back values for a given variable # draw_river_desc: Function to plot rivers' description from ORCHIDEE's routing scheme # draw_subbasin: Function to plot subbasin from 'routnig.nc' ORCDHIEE # draw_Taylor: Function to draw a Taylor diagram (Taylor 2001) # draw_vertical_levels: plotting vertical levels distribution # draw_WindRose: Function to plot a wind rose (from where the dinw blows) # draw_WRFeta_levels: Function to plot vertical levels from WRF wrfinput_d[nn] file # movie_2D_shad: creation of a movie with shading mainn = 'drawing.py' errormsg = 'ERROR -- error -- ERROR -- error' infmsg = 'INFORMATION -- information -- INFORMATION -- information' warnmsg = 'WARNING -- waring -- WARNING -- warning' fillValue=1.e20 namegraphics = ['create_movie', 'draw_2D_shad', 'draw_2Dshad_map', \ 'draw_2D_shad_time', \ 'draw_2D_shad_cont', 'draw_2D_shad_contdisc', 'draw_2D_shad_contdisc_time', \ 'draw_2D_shad_2cont', 'draw_2D_shad_cont_time', \ 'draw_2D_shad_line', \ 'draw_2D_shad_line_time', 'draw_bar', 'draw_bar_line', 'draw_bar_line_time', \ 'draw_bar_time', 'draw_barbs', 'draw_basins', 'draw_cycle', 'draw_ensembles_time', \ 'draw_2lines', 'draw_2lines_time', 'draw_geogrid_landuse', \ 'draw_lines', 'draw_lines_time', \ 'draw_multi_2D_shad', 'draw_multi_SkewT', 'draw_multiWindRose', \ 'draw_Neighbourghood_evol', \ 'draw_points', 'draw_points_lonlat', \ 'draw_ptZvals', 'draw_river_desc', 'draw_river_pattern', 'draw_SkewT', \ 'draw_subbasin', \ 'draw_stations_map', 'draw_Taylor', \ 'draw_time_lag', 'draw_timeSeries', 'draw_topo_geogrid', \ 'draw_topo_geogrid_boxes', 'draw_topofix_geogrid_boxes', 'draw_trajectories', \ 'draw_vals_trajectories', \ 'draw_vectors', 'draw_vertical_levels', 'list_graphics', 'draw_WindRose', \ 'draw_WRFeta_levels', 'movie_2D_shad', 'variable_values'] def draw_2D_shad(ncfile, values, varn, axfig=None, fig=None): """ plotting a fields with shading draw_2D_shad(ncfile, values, varn) ncfile= file to use values=[vnamefs]:[dimvals]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[sminv],[smaxv]:[figt]: [kindfig]:[reverse]:[mapv]:[close] [vnamefs]: Name in the figure of the variable to be shaded [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not valules= 'rh:z|-1,x|-1:z|-1,x|-1:lat:pressure:BuPu:0.,100.:rh:pdf:flip@y:None' varn= [varsn] name of the variable to plot with shading """ fname = 'draw_2D_shad' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad.__doc__ quit() expectargs = '[vnamefs]:[dimvals]:[dimxvn]:[dimyvn]:[dimxyf]:[colbarvals]:' + \ '[sminv],[smaxv]:[figt]:[kindfig]:[reverse]:[mapv]:[close]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0] dimvals= values.split(':')[1].replace('|',':') vdimxn = values.split(':')[2] vdimyn = values.split(':')[3] dimxyf = values.split(':')[4] colorbarvals = values.split(':')[5] shadminmax = values.split(':')[6] figtitle = values.split(':')[7].replace('|',' ') figkind = values.split(':')[8] revals = values.split(':')[9] mapvalue = values.split(':')[10] close = gen.Str_Bool(values.split(':')[11]) ncfiles = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' varns = sorted(objsf.variables.keys()) print ' available ones:', varns quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) # Masking if exists 'missing_value' attribute if gen.searchInlist(objvars.ncattrs(), 'missing_value'): missval = objvars.missing_value print infmsg valshad = ma.masked_equal(valshad,missval) valshad = ma.masked_greater(valshad,0.95*missval) print ' ' + fname + ": masking by 'missing_value':", missval, " !!" print ' masked', np.sum(valshad.mask), 'values' # Dimensions names ## print fname + ' obj dimnames: ', objvars.dimensions, dimvals, len(dimvals.split(',')) ## dimnamesv = [] ## for idd in range(len(objvars.dimensions)): ## cutdim = False ## for idc in range(len(dimvals.split(','))): ## dimcutn = dimvals.split(',')[idc].split(':')[0] ## print objvars.dimensions[idd], dimcutn ## if objvars.dimensions[idd] == dimcutn: ## cutdim = True ## break ## if not cutdim: dimnamesv.append(objvars.dimensions[idd]) dimnamesv = [vdimxn, vdimyn] if drw.searchInlist(objvars.ncattrs(),'units'): varunits = objvars.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimxn + "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimyn + "' without units!!" odimyu = '-' odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow(valshad, vnamesfig, odimxv, odimyv, odimxu, odimyu, xaxis, \ yaxis, dimnamesv, colormapv, shading_nx, varunits, figtitle, figkind, revals, \ mapvalue, close) return def draw_2D_shad_time(ncfile, values, varn): """ plotting a fields with shading with time values draw_2D_shad_time(ncfile, values, varn) ncfile= file to use values=[vnamefs]~[dimvals]~[dimxvn]~[dimyvn]~[dimvfmt]~[colorbarvals]~[sminv],[smaxv]~[gridkind]~[figt]~ [kindfig]~[reverse]~[timevals]~[close] [vnamefs]: Name in the figure of the variable to be shaded [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) ('WRFtime' for WRF times) [dimvfmt]=[dvs],[dvf],[Ndv],[ordv]: format of the values for the non-temporal axis (or 'auto') [dvs]: style of non-temporal axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dvf]: format of the labels at the x-axis ('auto' for '%5g') [Ndv]: Number of ticks at the x-axis ('auto' for 5) [ordv]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [gridkind]= [gridxk],[gridyk] kind of grid along x and y axis 'data': size pixel along the given axis change according to the values along the axis 'fixpixel': size pixel along the given axis does not change [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: '|' list of transformations to apply to the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [timevals]: [timen]|[units]|[kind]|[tfmt]|[label]|[timeaxis] time labels characteristics [timen]; name of the time variable ('WRFtime' for WRF times) [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [label]; label at the graph ('!' for spaces) [close]: should figure be closed (finished) values='dtcon~Time|-1,bottom_top|-1~presmean~time~auto~seismic,auto,auto~-3.e-6,3.e-6~monthly|' 'dtcon~pdf~transpose~time|hours!since!1949-12-01|exct,2,d|%d|date!([DD])~True varn= [varsn] name of the variable to plot with shading """ fname = 'draw_2D_shad_time' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_time.__doc__ quit() farguments = '[vnamefs]~[dimvals]~[dimxvn]~[dimyvn]~[dimvfmt]~[colorbarvals]~' + \ '[sminv],[smaxv]~[gridkind]~[figt]~[kindfig]~[reverse]~[timevals]~[close]' drw.check_arguments(fname,values,farguments,'~') vnamesfig = values.split('~')[0] dimvals= values.split('~')[1].replace('|',':') vdimxn = values.split('~')[2] vdimyn = values.split('~')[3] dimvfmt = values.split('~')[4] colorbarvals = values.split('~')[5] shadminmax = values.split('~')[6] gridkind = values.split('~')[7] figtitle = values.split('~')[8].replace('|',' ') figkind = values.split('~')[9] revals = values.split('~')[10] timevals = values.split('~')[11] close = gen.Str_Bool(values.split('~')[12]) ncfiles = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) dimnamesv = [vdimxn, vdimyn] varunits = objvars.getncattr('units') if vdimxn != 'WRFtime' and not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ": shading file '" + ncfiles + \ "' does not have dimension variable '" + vdimxn + "' !!" quit(-1) if vdimyn != 'WRFtime' and not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ": shading file '" + ncfiles + \ "' does not have dimension variable '" + vdimyn + " !!'" quit(-1) timename = timevals.split('|')[0] timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] timelabel = timevals.split('|')[4].replace('!',' ') if vdimxn == 'WRFtime' or vdimyn == 'WRFtime': tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10]+ '000000' tunitsval = tunitsec[0] timewrfv = objsf.variables['Times'] dt = timewrfv.shape[0] cftimes = np.zeros((dt), dtype=np.float) for it in range(dt): wrfdates = gen.datetimeStr_conversion(timewrfv[it,:],'WRFdatetime', \ 'matYmdHMS') cftimes[it] = gen.realdatetime1_CFcompilant(wrfdates, refdate, tunitsval) if vdimxn != 'WRFtime': objdimx = objsf.variables[vdimxn] objdimxv = objdimx[:] odimxu = objdimx.getncattr('units') else: objdimxv = cftimes odimxu = timeunit if vdimyn != 'WRFtime': objdimy = objsf.variables[vdimyn] objdimyv = objdimy[:] odimyu = objdimy.getncattr('units') else: objdimyv = cftimes odimyu = timeunit if len(objdimxv.shape) <= 2: odimxv0 = objdimxv[:] elif len(objdimxv.shape) == 3: odimxv0 = objdimxv[0,:] else: print errormsg print ' ' + fname + ': shape of dimension variable:', objdimxv.shape, \ ' not ready!!' quit(-1) if len(objdimyv.shape) <= 2: odimyv0 = objdimyv[:] elif len(objdimyv.shape) == 3: odimyv0 = objdimyv[0,:] else: print errormsg print ' ' + fname + ': shape of dimension variable:', objdimyv.shape, \ ' not ready!!' quit(-1) # Dimensional values if vdimxn != 'WRFtime': odxv, dimsdxv = drw.slice_variable(objsf.variables[vdimxn], dimvals.replace(',','|')) else: odxv = cftimes dimsdxv = ['Time'] if vdimyn != 'WRFtime': odyv, dimsdyv = drw.slice_variable(objsf.variables[vdimyn], dimvals.replace(',','|')) else: odyv = cftimes dimsdyv = ['Time'] if vdimxn == timename: odimtv = odxv odimtu = timelabel timeaxis = 'x' odimvv = odyv odimvu = objdimy.getncattr('units') elif vdimyn == timename: odimtv = odyv odimtu = timelabel timeaxis = 'y' odimvv = odxv odimvu = objdimx.getncattr('units') else: print errormsg print ' ' + fname + ": time variable '" + timename + "' not found!!" quit(-1) timeinf = gen.CFtimeU_inf(timeunit) cftime = timeinf.Tunits + ' since ' + timeinf.refdate timepos, timelabels = drw.CFtimes_plot(odimtv, cftime, timekind, timefmt) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] if dimvfmt != 'auto': dimvfmt = dimvfmt + 'auto,auto,auto,auto' xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimvfmt,',') vaxis = [xstyl, xaxf, Nxax, xaxor] # kind of grid-pixels [gridxk, gridyk] = gridkind.split(',') if revals == 'None': revals = None drw.plot_2D_shadow_time(valshad, vnamesfig, odimvv, odimtv, odimvu, dimnamesv, \ vaxis, colormapv, shading_nx, varunits, gridxk, gridyk, figtitle, figkind, \ revals, timeaxis, timepos, timelabels, close) return def draw_2D_shad_cont(ncfile, values, varn): """ plotting two fields, one with shading and the other with contour lines draw_2D_shad_cont(ncfile, values, varn) ncfile= [ncfilevars],[ncfilevarc] files to use (one value, same file) values=[vnamefs]:[dimvals]:[dimvalc]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[ckind]:[clabfmt]:[sminv],[smaxv]:[sminc],[smaxv],[Nlev]:[figt]:[kindfig]:[reverse]:[mapv]:[close] [vnamefs],[vnamefc]: Name in the figure of the shaded and the contour variables [dimvals/c]: list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: names of the variables with the values of the dimensions for the plot [dimxyfmt]=[dxf],[Ndx],[dyf],[Ndy]: format of the values at each axis [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [ckind]: kind of contours 'cmap': as it gets from colorbar 'fixc,[colname]': fixed color [colname], all stright lines 'fixsigc,[colname]': fixed color [colname], >0 stright, <0 dashed line [clabfmt]: format of the labels in the contour (None, also possible) [smin/axv]: minimum and maximum value for the shading or 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [sminc]:[smaxv]:[Nlev]: minimum, maximum and number of values for the contour [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: does the values be transposed? 'True/False', [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lamvbert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not valules= 'rh,ta:z|-1,x|-1:z|-1,x|-1:lat:pressure:BuPu:fixsigc,black:%d:0.,100.:195.,305.,7:Meridonal|average|of|rh|&|ta:pdf:flip@y:None' varn= [varsn],[varcn] name of the variable to plot with shading variable with contour """ fname = 'draw_2D_shad_cont' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_cont.__doc__ quit() expectargs = '[vnamefs]:[dimvals]:[dimvalc]:[dimxvn]:[dimyvn]:[dimxyf]:' + \ '[colorbarvals]:[ckind]:[clabfmt]:[sminv],[smaxv]:[sminc],[smaxv],[Nlev]:' + \ '[figt]:[kindfig]:[reverse]:[mapv]:[close]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0].split(',') dimvals= values.split(':')[1].replace('|',':') dimvalc= values.split(':')[2].replace('|',':') vdimxn = values.split(':')[3] vdimyn = values.split(':')[4] dimxyf = values.split(':')[5] colorbarvals = values.split(':')[6] countkind = values.split(':')[7] countlabelfmt = values.split(':')[8] shadminmax = values.split(':')[9].split(',') contlevels = values.split(':')[10] figtitle = values.split(':')[11].replace('|',' ') figkind = values.split(':')[12] revals = values.split(':')[13] mapvalue = values.split(':')[14] close = gen.Str_Bool(values.split(':')[15]) if2filenames = ncfile.find(',') if if2filenames != -1: ncfiles = ncfile.split(',')[0] ncfilec = ncfile.split(',')[1] else: ncfiles = ncfile ncfilec = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) if not os.path.isfile(ncfilec): print errormsg print ' ' + fname + ': contour file "' + ncfilec + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') objcf = NetCDFFile(ncfilec, 'r') varns = varn.split(',')[0] varnc = varn.split(',')[1] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) if not objcf.variables.has_key(varnc): print errormsg print ' ' + fname + ': contour file "' + ncfilec + \ '" does not have variable "' + varnc + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] objvarc = objcf.variables[varnc] if len(objvars.shape) != len(objvarc.shape): print errormsg print ' ' + fname + ': shading variable "' + varns + '" has a shape: ', \ objvars.shape, 'different than contour variable "' + varnc + '": ', \ objvarc.shape,' !!!' quit(-1) for idim in range(len(objvars.shape)): if objvars.shape[idim] != objvarc.shape[idim]: print errormsg print ' ' + fname + ': shading variable "' + varns + '" has a shape: ', \ objvars.shape, 'different than contour variable "' + varnc + '": ', \ objvarc.shape,' !!!' quit(-1) valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) valcont, dimscont = drw.slice_variable(objvarc, dimvalc.replace(',','|')) # Dimensions names ## print fname + ' obj dimnames: ', objvars.dimensions, dimvals, len(dimvals.split(',')) ## dimnamesv = [] ## for idd in range(len(objvars.dimensions)): ## cutdim = False ## for idc in range(len(dimvals.split(','))): ## dimcutn = dimvals.split(',')[idc].split(':')[0] ## print objvars.dimensions[idd], dimcutn ## if objvars.dimensions[idd] == dimcutn: ## cutdim = True ## break ## if not cutdim: dimnamesv.append(objvars.dimensions[idd]) dimnamesv = [vdimxn, vdimyn] varunits = [] varunits.append(objvars.getncattr('units')) varunits.append(objvarc.getncattr('units')) if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] odimxu = objdimx.getncattr('units') odimyu = objdimy.getncattr('units') # Getting only that dimensions with coincident names odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) # dimnvx = objdimx.dimensions # cutslice = [] # for idimn in objdimx.dimensions: # found = False # for dimsn in dimsshad: # if idimn == dimsn: # cutslice.append(slice(0,len(objsf.dimensions[idimn]))) # found = True # if not found: cutslice.append(0) # # odimxv = objdimx[tuple(cutslice)] # # dimnvy = objdimy.dimensions # cutslice = [] # for idimn in objdimy.dimensions: # found = False # for dimsn in dimsshad: # if idimn == dimsn: # cutslice.append(slice(0,len(objsf.dimensions[idimn]))) # found = True # if not found: cutslice.append(0) # # odimyv = objdimy[tuple(cutslice)] # if len(objdimx.shape) <= 2: # odimxv = objdimx[:] # odimyv = objdimy[:] # elif len(objdimx.shape) == 3: # odimxv = objdimx[0,:] # odimyv = objdimy[0,:] # else: # print errormsg # print ' ' + fname + ': shape of dimension variable:', objdimx.shape, \ # ' not ready!!' # quit(-1) if countlabelfmt == 'None': countlfmt = None else: countlfmt = countlabelfmt # Shading limits shading_nx = drw.graphic_range(shadminmax,valshad) # Contour limits clevmin = np.float(contlevels.split(',')[0]) clevmax = np.float(contlevels.split(',')[1]) Nclevels = int(contlevels.split(',')[2]) levels_cont = gen.pretty_int(clevmin, clevmax, Nclevels) if len(levels_cont) <= 1: print warnmsg print ' ' + fname + ': wrong contour levels:', levels_cont,' !!' del(levels_cont) levels_cont = np.zeros((Nclevels), dtype=np.float) levels_cont = np.arange(7)*(clevmax - clevmin)/(Nclevels-1) print ' generating default ones: ',levels_cont if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow_contour(valshad, valcont, vnamesfig, odimxv, odimyv, odimxu, \ odimyu, xaxis, yaxis, dimnamesv, [colbarn, fmtcolbar, colbaror], countkind, \ countlfmt, shading_nx, levels_cont, varunits, figtitle, figkind, revals, \ mapvalue, close) return def draw_2D_shad_cont_time(ncfile, values, varn): """ plotting two fields, one with shading and the other with contour lines being one of the dimensions of time characteristics draw_2D_shad_cont_time(ncfile, values, varn) ncfile= [ncfilevars],[ncfilevarc] files to use (one value, same file) values=[vnamefs];[dimvals];[dimvalc];[dimxvn];[dimyvn];[dimxyf];[colorbarvals];[ckind];[clabfmt];[sminv],[smaxv];[sminc],[smaxv],[Nlev];[figt];[kindfig];[reverse];[timevals];[close] [vnamefs],[vnamefc]: Name in the figure of the shaded and the contour variables [dimvals/c]: list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimxvn]: name of the variables with the values of the dimension of the x-axis ('WRFtime' for WRF times) [dimyvn]: name of the variables with the values of the dimension of the y-axis ('WRFtime' for WRF times) [dimxyf]=[dxf],[Ndx],[dyf],[Ndy]: format of the values at each axis [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' (unique map plotted with constant pixel size) 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [ckind]: kind of contours 'cmap': as it gets from colorbar 'fixc,[colname]': fixed color [colname], all stright lines 'fixsigc,[colname]': fixed color [colname], >0 stright, <0 dashed line [clabfmt]: format of the labels in the contour (None, also possible) [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [sminc]:[smaxv]:[Nlev]: minimum, maximum and number of values for the contour [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: modification to the dimensions: 'transposed': transpose matrices 'flip',[x/y]: flip only the dimension [x] or [y] [timevals]: [timen]|[units]|[kind]|[tfmt]|[label] time labels characteristics [timen]; name of the time variable ('WRFtime' for WRF times) [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [label]; label at the graph ('!' for spaces) [close]: Whether figure should be finished or not valules= 'rh,ta;z|-1,x|-1;z|-1,x|-1;lat;pressure;BuPu;fixsigc,black;%d;0.,100.;195.,305.,7;Meridonal|average|of|rh|&|ta;pdf;flip@y;time!hours!since!1949/12/01|exct,5d|%d|date!([DD])' varn= [varsn],[varcn] name of the variable to plot with shading variable with contour """ fname = 'draw_2D_shad_cont_time' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_cont_time.__doc__ quit() expectargs = '[vnamefs];[dimvals];[dimvalc];[dimxvn];[dimyvn];[dimxyf];' + \ '[colorbarvals];[ckind];[clabfmt];[sminv],[smaxv];[sminc],[smaxv],[Nlev];' + \ '[figt];[kindfig];[reverse];[timevals];[close]' drw.check_arguments(fname,values,expectargs,';') vnamesfig = values.split(';')[0].split(',') dimvals= values.split(';')[1].replace('|',':') dimvalc= values.split(';')[2].replace('|',':') vdimxn = values.split(';')[3] vdimyn = values.split(';')[4] dimxyf = values.split(';')[5] colorbarvals = values.split(';')[6] countkind = values.split(';')[7] countlabelfmt = values.split(';')[8] shadminmax = values.split(';')[9] contlevels = values.split(';')[10] figtitle = values.split(';')[11].replace('|',' ') figkind = values.split(';')[12] revals = values.split(';')[13] timevals = values.split(';')[14] close = gen.Str_Bool(values.split(';')[15]) if2filenames = ncfile.find(',') if if2filenames != -1: ncfiles = ncfile.split(',')[0] ncfilec = ncfile.split(',')[1] else: ncfiles = ncfile ncfilec = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) if not os.path.isfile(ncfilec): print errormsg print ' ' + fname + ': contour file "' + ncfilec + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') objcf = NetCDFFile(ncfilec, 'r') varns = varn.split(',')[0] varnc = varn.split(',')[1] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) if not objcf.variables.has_key(varnc): print errormsg print ' ' + fname + ': contour file "' + ncfilec + \ '" does not have variable "' + varnc + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] objvarc = objcf.variables[varnc] if len(objvars.shape) != len(objvarc.shape): print errormsg print ' ' + fname + ': shading variable "' + varns + '" has a shape: ', \ objvars.shape, 'different than contour variable "' + varnc + '": ', \ objvarc.shape,' !!!' quit(-1) for idim in range(len(objvars.shape)): if objvars.shape[idim] != objvarc.shape[idim]: print errormsg print ' ' + fname + ': shading variable "' + varns + '" has a shape: ', \ objvars.shape, 'different than contour variable "' + varnc + '": ', \ objvarc.shape,' !!!' quit(-1) valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) valcont, dimscont = drw.slice_variable(objvarc, dimvalc.replace(',','|')) dimnamesv = [vdimxn, vdimyn] varunits = [] varunits.append(objvars.getncattr('units')) varunits.append(objvarc.getncattr('units')) if vdimxn != 'WRFtime' and not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if vdimyn != 'WRFtime' and not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) timename = timevals.split('|')[0] timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] timelabel = timevals.split('|')[4].replace('!',' ') if vdimxn == 'WRFtime' or vdimyn == 'WRFtime': tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10]+ '000000' tunitsval = tunitsec[0] timewrfv = objsf.variables['Times'] dt = timewrfv.shape[0] cftimes = np.zeros((dt), dtype=np.float) for it in range(dt): wrfdates = gen.datetimeStr_conversion(timewrfv[it,:],'WRFdatetime', \ 'matYmdHMS') cftimes[it] = gen.realdatetime1_CFcompilant(wrfdates, refdate, tunitsval) if vdimxn == timename: if vdimxn == 'WRFtime': timevals = cftimes timedims = ['Time'] else: timevals = objsf.variables[vdimxn][:] timedims = objsf.variables[vdimxn].dimensions dimt = 'x' ovalaxis = objsf.variables[vdimyn] ovalu = ovalaxis.getncattr('units') elif vdimyn == timename: if vdimyn == 'WRFtime': timevals = cftimes timedims = ['Time'] else: timevals = objsf.variables[vdimyn][:] timedims = objsf.variables[vdimyn].dimensions dimt = 'y' ovalaxis = objsf.variables[vdimxn] ovalu = ovalaxis.getncattr('units') else: print errormsg print ' ' + fname + ": time variable '" + timename + "' not found!!" quit(-1) timepos, timelabels = drw.CFtimes_plot(timevals, timeunit, timekind, timefmt) # Getting only that dimensions with coincident names dimnvx = ovalaxis.dimensions dimsliceaxis = [] for dimv in dimvals.split(','): adimvn = dimv.split(':')[0] adimval = dimv.split(':')[1] found = False for dimtn in timedims: if adimvn == dimtn: dimsliceaxis.append(adimvn + ':0') found = True break if not found: dimsliceaxis.append(dimv) dimsliceaxisS = '|'.join(dimsliceaxis) ovalaxisv, odimaxisv = drw.slice_variable(ovalaxis,dimsliceaxisS) if countlabelfmt == 'None': countlfmt = None else: countlfmt = countlabelfmt shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) clevmin = np.float(contlevels.split(',')[0]) clevmax = np.float(contlevels.split(',')[1]) Nclevels = int(contlevels.split(',')[2]) levels_cont = gen.pretty_int(clevmin, clevmax, Nclevels) if len(levels_cont) <= 1: print warnmsg print ' ' + fname + ': wrong contour levels:', levels_cont,' !!' del(levels_cont) levels_cont = np.zeros((Nclevels), dtype=np.float) levels_cont = np.arange(7)*(clevmax - clevmin)/(Nclevels-1) print ' generating default ones: ',levels_cont colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow_contour_time(valshad, valcont, vnamesfig, ovalaxisv, \ timevals, timepos, timelabels, ovalu, timelabel, dimt, xaxis, yaxis, \ dimnamesv, [colbarn, fmtcolbar, colbaror], countkind, countlfmt, shading_nx, \ levels_cont, varunits, figtitle, figkind, revals, close) return def draw_2D_shad_line(ncfile, values, varn): """ plotting a fields with shading and another with line draw_2D_shad_line(ncfile, values, varn) ncfile= [ncfiles],[ncfilel] file to use for the shading and for the line values=[vnamefs],[vnamefl]:[dimvals]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[smin/axv]:[linevalues]:[figt]: [kindfig]:[reverse]:[mapv]:[close] [vnamefs]: Name in the figure of the variable to be shaded [vnamefl]: Name in the figure of the variable to be lined [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [linevalues]=[colline],[sminl],[smaxl],[dls],[dlf],[Ndl],[ordl] [colline]: name of the color for the line [smin/axv]: minimum and maximum value for the line or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [dls]: style of line-axis ('auto' for 'pretty') [dlf]: format of the labels at the line-axis ('auto' for '%5g') [Ndl]: Number of ticks at the line-axis ('auto' for 5) [ordl]: angle of orientation of ticks at the line-axis ('auto' for horizontal) [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lamvbert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not valules= 'rh:z|-1,x|-1:z|-1,x|-1:lat:pressure:BuPu:0.,100.:rh:pdf:flip@y:None' varn= [varsn],[varnl] name of the variable to plot with shading and with line """ fname = 'draw_2D_shad_line' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_line.__doc__ quit() farguments = '[vnamefs],[vnamefl]:[dimvals]:[dimxvn]:[dimyvn]:' + \ '[dimxyfmt]:[colorbarvals]:[smin/axv]:[linevalues]:[figt]:[kindfig]:' + \ '[reverse]:[mapv]:[close]' drw.check_arguments(fname,values,farguments,':') vnamesfig = values.split(':')[0].split(',')[0] dimvals= values.split(':')[1].replace('|',':') vdimxn = values.split(':')[2] vdimyn = values.split(':')[3] dimxyf = values.split(':')[4] colorbarvals = values.split(':')[5] shadminmax = values.split(':')[6] linevalues = values.split(':')[7] figtitle = values.split(':')[8].replace('|',' ') figkind = values.split(':')[9] revals = values.split(':')[10] mapvalue = values.split(':')[11] close = gen.Str_Bool(values.split(':')[12]) ncfiles = ncfile.split(',')[0] if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) # Dimensions names dimnamesv = [vdimxn, vdimyn] varunits = objvars.getncattr('units') if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimxn + "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimyn + "' without units!!" odimyu = '-' odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) # line plot ## linearg = linevalues.split(',') if linevalues.split(',')[1][0:1] != 'S': linearg[1] = np.float(linevalues.split(',')[1]) if linevalues.split(',')[2][0:1] != 'S': linearg[2] = np.float(linevalues.split(',')[2]) if linearg[3] == 'auto': linearg[3] = 'pretty' if linearg[4] == 'auto': linearg[4] = '5g' if linearg[5] == 'auto': linearg[5] = 5 if linearg[6] == 'auto': linearg[6] = 0. ncfilel = ncfile.split(',')[1] vnamelfig = values.split(':')[0].split(',')[1] varnl = varn.split(',')[1] if not os.path.isfile(ncfilel): print errormsg print ' ' + fname + ': file for line "' + ncfilel + '" does not exist !!' quit(-1) objlf = NetCDFFile(ncfilel,'r') if not objlf.variables.has_key(varnl): print errormsg print ' ' + fname + ': line file "' + ncfilel + \ '" does not have variable "' + varnl + '" !!' quit(-1) objlvar = objlf.variables[varnl] linevals, dimsline = drw.slice_variable(objlvar, dimvals.replace(',','|')) varlunits = objlvar.units if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow_line(valshad, linevals, vnamesfig, vnamelfig, odimxv, odimyv, \ odimxu, odimyu, dimnamesv, xaxis, yaxis, colormapv, linearg, shading_nx, \ varunits, varlunits, figtitle, figkind, revals, mapvalue, close) objsf.close() objlf.close() return def draw_2D_shad_line_time(ncfile, values, varn): """ plotting a fields with shading and a line with time values draw_2D_shad_line(ncfile, values, varn) ncfile= [ncfiles],[ncfilel] files to use to draw with shading and the line values= [vnamefs],[vanemefl];[dimvals];[dimxvn];[dimyvn];[dimxyfmt];[colorbarvals];[sminv],[smaxv]; [figt];[kindfig];[reverse];[timevals];[close] [vnamefs]: Name in the figure of the variable to be shaded [vnamefl]: Name in the figure of the variable to be lined [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [linevalues]=[colline],[sminl],[smaxl],[dls],[dlf],[Ndl],[ordl] [colline]: name of the color for the line [smin/axv]: minimum and maximum value for the line or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [dls]: style of line-axis ('auto' for 'pretty') [dlf]: format of the labels at the line-axis ('auto' for '%5g') [Ndl]: Number of ticks at the line-axis ('auto' for 5) [ordl]: angle of orientation of ticks at the line-axis ('auto' for horizontal) [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [timevals]: [timen]|[units]|[kind]|[tfmt]|[label]|[timeaxis] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [label]; label at the graph ('!' for spaces) [close]: should figure be closed (finished) values='dtcon,prc:Time|-1,bottom_top|-1:presmean:time:seismic:-3.e-6,3.e-6:monthly|' 'dtcon:pdf:transpose:time|hours!since!1949-12-01|exct,2,d|%d|date!([DD])|x:True varn= [varsn].[varln] name of the variable to plot with shading and to plot with line """ fname = 'draw_2D_shad_line_time' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad__line_time.__doc__ quit() farguments = '[vnamefs],[vanemefl];[dimvals];[dimxvn];[dimyvn];[dimxyfmt];' + \ '[colorbarvals];[sminv],[smaxv];[linevalues];[figt];[kindfig];[reverse];[timevals];[close]' drw.check_arguments(fname,values,farguments,';') vnamesfig = values.split(';')[0] dimvals= values.split(';')[1].replace('|',':') vdimxn = values.split(';')[2] vdimyn = values.split(';')[3] dimxyfmt = values.split(';')[4] colorbarvals = values.split(';')[5] shadminmax = values.split(';')[6] linevalues = values.split(';')[7] figtitle = values.split(';')[8].replace('|',' ') figkind = values.split(';')[9] revals = values.split(';')[10] timevals = values.split(';')[11] close = gen.Str_Bool(values.split(';')[12]) ncfiles = ncfile.split(',')[0] ncfilel = ncfile.split(',')[1] vshadn = vnamesfig.split(',')[0] vlinen = vnamesfig.split(',')[1] if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) if not os.path.isfile(ncfilel): print errormsg print ' ' + fname + ': line file "' + ncfilel + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) dimnamesv = [vdimxn, vdimyn] varunits = objvars.getncattr('units') if vdimxn != 'WRFtime' and not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if vdimyn != 'WRFtime' and not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) timename = timevals.split('|')[0] timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] timelabel = timevals.split('|')[4].replace('!',' ') # Getting time as WRF Times if timename == 'WRFtime': dictslice = {} for dnv in dimvals.split(','): dimn = dnv.split(':')[0] dimv = dnv.split(':')[1] if dimv.find(',') != -1: dictslice[dimn] = list(np.array(dimv.split(','), dtype=int)) else: dictslice[dimn] = int(dimv) wrft = objsf.variables['Times'] slicewrft, dwrfd = ncvar.SliceVarDict(wrft, dictslice) timewrfv = wrft[tuple(slicewrft)] if len(timeunit.split(' ')) > 3: refdateS = timeunit.split(' ')[2] + ' ' + timeunit.split(' ')[3] else: refdateS = timeunit.split(' ')[2] + ' 00:00:00' tunitsval = timeunit.split(' ')[0] yrref=refdateS[0:4] monref=refdateS[5:7] dayref=refdateS[8:10] horref=refdateS[11:13] minref=refdateS[14:16] secref=refdateS[17:19] refdate = yrref + monref + dayref + horref + minref + secref dt = timewrfv.shape[0] cftimes = np.zeros((dt), dtype=np.float) for it in range(dt): wrfdates = gen.datetimeStr_conversion(timewrfv[it,:], \ 'WRFdatetime', 'matYmdHMS') cftimes[it] = gen.realdatetime1_CFcompilant(wrfdates, \ refdate, tunitsval) tunits = tunitsval + ' since ' + refdateS if vdimxn == timename: if timename != 'WRFtime': odimxv = objsf.variables[vdimxn][:] else: odimxv = cftimes odimxu = timelabel timeaxis = 'x' objdimyv = objsf.variables[vdimyn] odimyv = objdimyv[:] odimyu = objdimyv.getncattr('units') timepos, timelabels = drw.CFtimes_plot(odimxv, timeunit, timekind, timefmt) elif vdimyn == timename: if timename != 'WRFtime': odimyv = objsf.variables[vdimxn][:] else: odimyv = cftimes odimyu = timelabel timeaxis = 'y' objdimxv = objsf.variables[vdimxn] odimxv = objdimxv[:] odimxu = objdimxv.getncattr('units') timepos, timelabels = drw.CFtimes_plot(odimyv, timeunit, timekind, timefmt) else: print errormsg print ' ' + fname + ": time variable '" + timename + "' not found!!" quit(-1) shading_nx = shadminmax.split(',') # Line values ## linearg = linevalues.split(',') if linevalues.split(',')[1][0:1] != 'S': linearg[1] = np.float(linevalues.split(',')[1]) if linevalues.split(',')[2][0:1] != 'S': linearg[2] = np.float(linevalues.split(',')[2]) if linearg[3] == 'auto': linearg[3] = 'pretty' if linearg[4] == 'auto': linearg[4] = '5g' if linearg[5] == 'auto': linearg[5] = 5 if linearg[6] == 'auto': linearg[6] = 0. vnamelfig = values.split(':')[0].split(',')[1] varnl = varn.split(',')[1] objlf = NetCDFFile(ncfilel,'r') objlvar = objlf.variables[varnl] linevals, dimsline = drw.slice_variable(objlvar, dimvals.replace(',','|')) varlunits = objlvar.units colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow_line_time(valshad, linevals, vshadn, vlinen, odimxv, odimyv, \ odimxu, odimyu, dimnamesv, xaxis, yaxis, colormapv, linearg, shading_nx, \ varunits, varlunits, figtitle, figkind, revals, timeaxis, timepos, timelabels, \ close) objsf.close() objlf.close() return def draw_barbs(ncfile, values, varns): """ Function to plot wind barbs draw_barbs(ncfile, values, varns) values= [dimname]|[vardimname]|[value]:[vecvals]:[windlabs]:[dimxv]:[dimyv]:[mapvalues]:[dimxyfmt]: [transform]:[gtit]:[kindfig]:[figuren]:[close] [dimname]|[vardimname]|[value]: ',', list for each basic dimension '|' separated of: [dimname]: name of the dimension in the file [vardimname]: name of the variable with the values for the dimension in the file [value]: which value of the given dimension (-1, all; [ibeg]@[iend], i-range beginning, end) No value takes all the range of the dimension [vecvals]= [frequency],[color],[length] [frequency]: [xfreq]@[yfreq] frequency of values allong each axis ('None', all grid points; 'auto', computed automatically to have 20 vectors along each axis) [color]: color of the vectors ('auto', for 'red') two options: [colorname]: name of the color fixed for all vectors 'colormap'@[colormapname]: use colormap to provide the colors tacking wind speed as reference [length]: length of the wind barbs ('auto', for 9) [windlabs]= [windname],[windunits] [windname]: name of the wind variable in the graph [windunits]: units of the wind variable in the graph ('None', for the value in the file) [dimxvn]: Variables with the final values for the x dimension [dimyvn]: Variables with the final values for the y dimension [mapvalues]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [transform]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [gtit]= title of the graph ('|', for spaces) [kindfig]= kind of figure [figuren]= name of the figure [close]= whether figure should be finished or not ncfile= file to use varns= [uwind],[ywind] ',' list of the name of the variables with the u-wind,y-wind component """ fname = 'draw_barbs' if values == 'h': print fname + '_____________________________________________________________' print draw_barbs.__doc__ quit() expectargs = '[dimname]|[vardimname]|[value]:[vecvals]:[windlabs]:[dimxv]:' + \ '[dimyv]:[mapvalues]:[dimxyfmt]:[transform]:[gtit]:[kindfig]:[figuren]:[close]' drw.check_arguments(fname,values,expectargs,':') dimvals = values.split(':')[0] vecvals = values.split(':')[1] windlabels = values.split(':')[2] dimxvn = values.split(':')[3] dimyvn = values.split(':')[4] mapvalues = values.split(':')[5] dimxyfmt = values.split(':')[6] reverse = values.split(':')[7] gtit = values.split(':')[8] kindfig = values.split(':')[9] figuren = values.split(':')[10] close = gen.Str_Bool(values.split(':')[11]) of = NetCDFFile(ncfile,'r') # Dictionary with the dimension name and its associated variable and slice dims = {} for dimv in dimvals.split(','): dns = dimv.split('|') dims[dns[0]] = [dns[1], dns[2]] varNs = [dimxvn, dimyvn] for dn in dims.keys(): vdn = dims[dn] if vdn == dimxvn: dimx = len(of.dimensions[dn]) elif vdn == dimyvn: dimy = len(of.dimensions[dn]) # x-y variable-dimensions' names xydimns = [dimxvn, dimyvn] # x-y variable-dimensions' units xydimus = [] odimx = of.variables[xydimns[0]] odimax = odimx.ncattrs() if gen.searchInlist(odimax,'units'): xydimus.append(odimx.getncattr('units')) odimy = of.variables[xydimns[1]] xydimus.append(odimy.getncattr('units')) else: xydimus= [gen.variable_values(xydimns[0])[4],gen.variable_values(xydimns[1])[4]] ivar = 0 for wvar in varns.split(','): if not drw.searchInlist(of.variables.keys(), wvar): print errormsg print ' ' + fname + ": file does not have variable '" + wvar + "' !!" quit(-1) if ivar == 0: varNs.append(wvar) else: varNs.append(wvar) ivar = 0 for varN in varNs: varslice = [] ovarN = of.variables[varN] vard = ovarN.dimensions for vdn in vard: found = False for dd in dims.keys(): if dd == vdn: if dims[dd][1].find('@') != -1: rvals = dims[dd][1].split('@') varslice.append(slice(int(rvals[0]), int(rvals[1]))) elif dims[dd][1] == '-1': varslice.append(slice(0,len(of.dimensions[dd]))) else: varslice.append(int(dims[dd][1])) found = True break if not found: varslice.append(slice(0,len(of.dimensions[vdn]))) if ivar == 0: lonvals0 = np.squeeze(ovarN[tuple(varslice)]) elif ivar == 1: latvals0 = np.squeeze(ovarN[tuple(varslice)]) elif ivar == 2: uwvals = np.squeeze(np.array(ovarN[tuple(varslice)])) elif ivar == 3: vwvals = np.squeeze(ovarN[tuple(varslice)]) ivar = ivar + 1 # print 'Final shapes:',lonvals0.shape,':',latvals0.shape,':',uwvals.shape,':', # vwvals.shape if len(uwvals.shape) != 2 or len(vwvals.shape) != 2: print errormsg print ' ' + fname + ': wrong size of the wind fields! they must be ' + \ '2-dimensional!' print ' u-winds shape:',uwvals.shape,'dims:',of.variables[varNs[2]] print ' v-winds shape:',vwvals.shape,'dims:',of.variables[varNs[3]] print ' provide more values for their dimensions!!' quit(-1) if len(lonvals0.shape) == 1: lonvals, latvals = np.meshgrid(lonvals0, latvals0) else: lonvals = lonvals0 latvals = latvals0 # Vecor values if vecvals.split(',')[0] == 'None': freqv = None else: freqv = vecvals.split(',')[0] colorv = vecvals.split(',')[1] lengthv = vecvals.split(',')[2] # Vector labels windname = windlabels.split(',')[0] windunits = windlabels.split(',')[1] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if mapvalues == 'None': mapvs = None else: mapvs = mapvalues if reverse == 'None': revs = None else: revs = reverse drw.plot_barbs(lonvals, latvals, uwvals, vwvals, freqv, colorv, lengthv, \ windname, windunits, xaxis, yaxis, xydimns, xydimus, mapvs, revs, gtit, \ kindfig, figuren, close) return def draw_topo_geogrid(ncfile, values): """ plotting geo_em.d[nn].nc topography from WPS files draw_topo_geogrid(ncfile, values) ncfile= geo_em.d[nn].nc file to use values= [minTopo],[maxTopo]:[lonlatL]:[title]:[graphic_kind]:[mapvalues] [min/max]Topo: minimum and maximum values of topography to draw lonlatL: limits of longitudes and latitudes [lonmin, latmin, lonmax, latmax] or None title: title of the graph ('!' for spaces) graphic_kind: kind of figure (jpg, pdf, png) mapvalues: map characteristics [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full close: Whether figure should be finished or not """ fname = 'draw_topo_geogrid' if values == 'h': print fname + '_____________________________________________________________' print draw_topo_geogrid.__doc__ quit() expectargs= '[minTopo],[maxTopo]:[lonlatL]:[title]:[graphic_kind]:[mapvalues]:'+ \ '[close]' drw.check_arguments(fname,values,expectargs,':') mintopo = np.float(values.split(':')[0].split(',')[0]) maxtopo = np.float(values.split(':')[0].split(',')[1]) lonlatLS = values.split(':')[1] lonlatLv = lonlatLS.split(',')[0] if lonlatLv == 'None': lonlatL = None else: lonlatL = np.zeros((4), dtype=np.float) lonlatL[0] = np.float(lonlatLS.split(',')[0]) lonlatL[1] = np.float(lonlatLS.split(',')[1]) lonlatL[2] = np.float(lonlatLS.split(',')[2]) lonlatL[3] = np.float(lonlatLS.split(',')[3]) grtit = values.split(':')[2].replace('!',' ') kindfig = values.split(':')[3] mapvalues = values.split(':')[4] close = gen.Str_Bool(values.split(':')[5]) if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': domain file "' + ncfile + '" does not exist !!' quit(-1) objdomf = NetCDFFile(ncfile, 'r') objhgt = objdomf.variables['HGT_M'] objlon = objdomf.variables['XLONG_M'] objlat = objdomf.variables['XLAT_M'] topography = objhgt[0,:,:] drw.plot_topo_geogrid(topography, objlon, objlat, mintopo, maxtopo, lonlatL, \ grtit, kindfig, mapvalues, close) objdomf.close() return def draw_topo_geogrid_boxes(ncfiles, values): """ plotting different geo_em.d[nn].nc topography from WPS files draw_topo_geogrid_boxes(ncfiles, values) ncfiles= ',' list of geo_em.d[nn].nc files to use (first as topographyc reference) values= [minTopo],[maxTopo]:[lonlatL]:[title]:[graphic_kind]:[mapvalues]:[labels]:[legvals]:[close] [min/max]Topo: minimum and maximum values of topography to draw lonlatL: limits of longitudes and latitudes [lonmin, latmin, lonmax, latmax] or None title: title of the graph ('!' for spaces) graphic_kind: kind of figure (jpg, pdf, png) mapvalues: map characteristics [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full legvals: [locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) labels: labels to write in the graph ('!' for spaces) close: Whether figure should be finished or not """ # import matplotlib as mpl # mpl.use('Agg') import matplotlib.pyplot as plt fname = 'draw_topo_geogrid_boxes' if values == 'h': print fname + '_____________________________________________________________' print draw_topo_geogrid_boxes.__doc__ quit() expectargs = '[minTopo],[maxTopo]:[lonlatL]:[title]:[graphic_kind]:[mapvalues]:'+\ '[labels]:[legvals]:[close]' drw.check_arguments(fname,values,expectargs,':') mintopo = np.float(values.split(':')[0].split(',')[0]) maxtopo = np.float(values.split(':')[0].split(',')[1]) lonlatLS = values.split(':')[1] lonlatLv = lonlatLS.split(',')[0] if lonlatLv == 'None': lonlatL = None else: lonlatL = np.zeros((4), dtype=np.float) lonlatL[0] = np.float(lonlatLS.split(',')[0]) lonlatL[1] = np.float(lonlatLS.split(',')[1]) lonlatL[2] = np.float(lonlatLS.split(',')[2]) lonlatL[3] = np.float(lonlatLS.split(',')[3]) grtit = values.split(':')[2].replace('!', ' ') kindfig = values.split(':')[3] mapvalues = values.split(':')[4] labels = values.split(':')[5] legvals = values.split(':')[6] close = gen.Str_Bool(values.split(':')[7]) ncfile = ncfiles.split(',')[0] if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': domain file "' + ncfile + '" does not exist !!' quit(-1) objdomf = NetCDFFile(ncfile, 'r') objhgt = objdomf.variables['HGT_M'] objlon0 = objdomf.variables['XLONG_M'] objlat0 = objdomf.variables['XLAT_M'] topography = objhgt[0,:,:] Nfiles = len(ncfiles.split(',')) boxlabels = labels.split(',') Xboxlines = [] Yboxlines = [] for ifile in range(Nfiles): ncfile = ncfiles.split(',')[ifile] # print ifile, ncfile if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': domain file "' + ncfile + '" does not exist !!' quit(-1) objdomfi = NetCDFFile(ncfile, 'r') objlon = objdomfi.variables['XLONG_M'] objlat = objdomfi.variables['XLAT_M'] dx = objlon.shape[2] dy = objlon.shape[1] Xboxlines.append(objlon[0,0,:]) Yboxlines.append(objlat[0,0,:]) Xboxlines.append(objlon[0,dy-1,:]) Yboxlines.append(objlat[0,dy-1,:]) Xboxlines.append(objlon[0,:,0]) Yboxlines.append(objlat[0,:,0]) Xboxlines.append(objlon[0,:,dx-1]) Yboxlines.append(objlat[0,:,dx-1]) objdomfi.close() # Legend locleg, legfontsize = drw.legend_values(legvals,'|') drw.plot_topo_geogrid_boxes(topography, Xboxlines, Yboxlines, boxlabels, \ objlon0, objlat0, mintopo, maxtopo, lonlatL, grtit, kindfig, mapvalues, locleg,\ legfontsize, close) objdomf.close() return def movievalslice(origslice, dimmovien, framenum): """ Function to provide variable slice according to a geneation of a movie movievals(origslice, dimmovien, framenum) [origslice]= slice original as [dimname1]|[val1],[...,[dimnameN]|[valN]] ([val] = -1, full length) [dimmovien]= name of the dimension to produce the movie [framenum]= value of the frame to substitue in [origslice] as [dimmovien]|[framenum] >>> movievalslice('East_West|-1,North_South|-1,Time|2','Time',0) East_West|-1,North_South|-1,Time|0 """ fname = 'movievalslice' if origslice == 'h': print fname + '_____________________________________________________________' print movievalslice.__doc__ quit() dims = origslice.split(',') movieslice = '' idim = 0 for dimn in dims: dn = dimn.split('|')[0] if dn == dimmovien: movieslice = movieslice + dn + '|' + str(framenum) else: movieslice = movieslice + dimn if idim < len(dims)-1: movieslice = movieslice + ',' idim = idim + 1 return movieslice class Capturing(list): """ Class to capture function output as a list from: http://stackoverflow.com/questions/16571150/how-to-capture-stdout-output-from-a-python-function-call """ # from cStringIO import StringIO def __enter__(self): self._stdout = sys.stdout sys.stdout = self._stringio = StringIO() return self def __exit__(self, *args): self.extend(self._stringio.getvalue().splitlines()) sys.stdout = self._stdout def create_movie(netcdfile, values, variable): """ Function to create a movie assuming ImageMagick installed! values= [graph]#[movie_dimension]#[graph_values] [graph]: which graphic [movie_dimension]: [dimnmovie]@[dimvmovie]@[moviedelay]@[interval] [dimnmovie]; name of the dimension from which make the movie [dimvmovie]; name of the variable with the values of the dimension [moviedelay]; delay between frames [interval]; [beg]@[end]@[freq] or -1 (all) [graph_values]: values to generate the graphic netcdfile= netCDF file variable= variable to use (when applicable) """ fname = 'create_movie' if values == 'h': print fname + '_____________________________________________________________' print create_movie.__doc__ quit() graph = values.split('#')[0] movie_dim = values.split('#')[1] graph_vals = values.split('#')[2] ncobj = NetCDFFile(netcdfile, 'r') # Movie dimension ## dimnmovie = movie_dim.split('@')[0] dimvmovie = movie_dim.split('@')[1] moviedelay = movie_dim.split('@')[2] moviebeg = int(movie_dim.split('@')[3]) if not drw.searchInlist(ncobj.dimensions.keys(),dimnmovie): print errormsg print ' ' + fname + ": file '" + netcdfile + "' has not dimension '" + \ dimnmovie + "' !!!" quit(-1) objdmovie = ncobj.dimensions[dimnmovie] dmovie = len(objdmovie) if moviebeg != -1: moviend = int(movie_dim.split('@')[4]) moviefreq = int(movie_dim.split('@')[5]) else: moviebeg = 0 moviend = dmovie moviefreq = 1 if dimvmovie == 'WRFTimes': objvdmovie = ncobj.variables['Times'] vdmovieunits = '' valsdmovie = [] for it in range(objvdmovie.shape[0]): valsdmovie.append(drw.datetimeStr_conversion(objvdmovie[it,:], \ 'WRFdatetime', 'Y/m/d H-M-S')) elif dimvmovie == 'CFtime': objvdmovie = ncobj.variables['time'] vdmovieunits = '' print objvdmovie.units valsdmovie0 = drw.netCDFdatetime_realdatetime(objvdmovie.units, 'standard', \ objvdmovie[:]) valsdmovie = [] for it in range(objvdmovie.shape[0]): valsdmovie.append(drw.datetimeStr_conversion(valsdmovie0[it,:], \ 'matYmdHMS', 'Y/m/d H-M-S')) else: if not drw.searchInlist(ncobj.variables.keys(),dimvmovie): print errormsg print ' ' + fname + ": file '" + netcdfile + "' has not variable '" + \ dimvmovie + "' !!!" quit(-1) vdmovieunits = objvdmovie.getncattr('units') objvdmovie = ncobj.variables[dimvmovie] if len(objvdmovie.shape) == 1: vasldmovie = objvdmovie[:] else: print errormsg print ' ' + fname + ': shape', objvdmovie.shape, 'of variable with ' + \ 'dimension movie values not ready!!!' quit(-1) ncobj.close() os.system('rm frame_*.png > /dev/null') # graphic ## if graph == 'draw_2D_shad': graphvals = graph_vals.split(':') for iframe in range(moviebeg,moviend,moviefreq): iframeS = str(iframe).zfill(4) drw.percendone((iframe-moviebeg)/moviefreq,(moviend-moviebeg)/moviefreq, \ 5, 'frames') titgraph = dimnmovie + '|=|' + str(valsdmovie[iframe]) + '|' + \ vdmovieunits graphvals[1] = movievalslice(graphvals[1],dimnmovie,iframe) graphvals[6] = titgraph graphvals[7] = 'png' graphv = drw.numVector_String(graphvals, ":") with Capturing() as output: draw_2D_shad(netcdfile, graphv, variable) os.system('mv 2Dfields_shadow.png frame_' + iframeS + '.png') else: print errormsg print ' ' + fname + ": graphic '" + graph + "' not defined !!!" quit(-1) os.system('convert -delay ' + moviedelay + ' -loop 0 frame_*.png create_movie.gif') print "Succesfuly creation of movie file 'create_movie.gif' !!!" return def draw_lines(ncfilens, values, varname): """ Function to draw different lines at the same time from different files draw_lines(ncfilens, values, varname): ncfilens= [filen] ',' separated list of netCDF files values= [dimvname]:[valuesaxis]:[dimtit]:[dimxyfmt]:[vrange]:[leglabels]:[vtit]:[title]:[legvals]:[colns]:[lines] [points]:[lwdths]:[psizes]:[freqv]:[figname]:[graphk]:[close] [dimvname]: ',' list of names of the variable with he values of the common dimension [valuesaxis]: which axis will be used for the values ('x', or 'y') [dimtit]: title for the common dimension ('|' for spaces) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [vrange]=[ymin],[ymax] range for the plot ('auto' for current range of values) [leglabels]: ',' separated list of names for the legend ('!' for spaces, '*' for no label) [vartit]: name of the variable in the graph [title]: title of the plot ('|' for spaces) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [colns]= ',' list of color names ('None' for automatic, single value for all the same) [lines]= ',' list of style of lines ('None' for automatic, single value for all the same) [points]= '@' list of style of points ('None' for automatic, single value for all the same) [lwdths]= ',' list of withs of lines ('None' for automatic, single value for all the same) [psizes]= ',' list of size of points ('None' for automatic, single value for all the same) [freqv]= frequency of values ('all' for all values) [figname]= name of the figure [graphk]: kind of the graphic [close]: should figure be closed (finished) varname= variable to plot values= 'XLAT:x:latitude:32x32:$wss^{*}$:wss Taylor's turbulence term:pdf' """ fname = 'draw_lines' if values == 'h': print fname + '_____________________________________________________________' print draw_lines.__doc__ quit() expectargs = '[dimvname]:[valuesaxis]:[dimtit]:[dimxyfmt]:[vrange]:[leglabels]:'+\ '[vtit]:[title]:[legvals]:[colns]:[lines]:[points]:[lwdths]:[psizes]:[freqv]:'+\ '[figname]:[graphk]:[close]' drw.check_arguments(fname,values,expectargs,':') ncfiles = ncfilens.split(',') dimvnames = values.split(':')[0] valuesaxis = values.split(':')[1] dimtit = values.split(':')[2].replace('|', ' ') dimxyfmt = values.split(':')[3] vrange = values.split(':')[4] leglabels = gen.latex_text(values.split(':')[5].replace('!',' ')) vartit = values.split(':')[6] title = values.split(':')[7].replace('|',' ') legvals = values.split(':')[8] colns = gen.str_list(values.split(':')[9], ',') lines = gen.str_list(values.split(':')[10], ',') points = gen.str_list(values.split(':')[11], '@') lwdths = gen.str_list_k(values.split(':')[12], ',', 'R') psizes = gen.str_list_k(values.split(':')[13], ',', 'R') freqv0 = values.split(':')[14] figname = values.split(':')[15] graphk = values.split(':')[16] close = gen.Str_Bool(values.split(':')[17]) Nfiles = len(ncfiles) # Getting trajectotries ## varvalues = [] dimvalues = [] print ' ' + fname ifn = 0 for ifile in ncfiles: filen = ifile.split('@')[0] print ' filen:',filen if not os.path.isfile(filen): print errormsg print ' ' + fname + ": netCDF file '" + filen + "' does not exist !!" quit(-1) objfile = NetCDFFile(filen, 'r') if dimvnames.find(',') != -1: dimvname = dimvnames.split(',') else: dimvname = [dimvnames] found = False for dvn in dimvname: if objfile.variables.has_key(dvn): found = True break if not found: print errormsg print ' ' + fname + ": netCDF file '" + filen + \ "' does not have variables '" + dimvnames + "' !!" quit(-1) if not objfile.variables.has_key(varname): print errormsg print ' ' + fname + ": netCDF file '" + filen + \ "' does not have variable '" + varname + "' !!" quit(-1) vvobj = objfile.variables[varname] if len(vvobj.shape) != 1: print errormsg print ' ' + fname + ': wrong shape:',vvobj.shape," of variable '" + \ varname + "' !!" quit(-1) for dimvn in dimvname: if drw.searchInlist(objfile.variables, dimvn): vdobj = objfile.variables[dimvn] if len(vdobj.shape) != 1: print errormsg print ' ' + fname + ': wrong shape:',vdobj.shape, \ " of variable '" + dimvn + "' !!" quit(-1) break varvalues.append(vvobj[:]) dimvalues.append(vdobj[:]) if ifn == 0: varunits = vvobj.units objfile.close() ifn = ifn + 1 if freqv0 == 'all': freqv = None else: freqv = int(freqv0) # Legend locleg, legfontsize = drw.legend_values(legvals,'|') # axis xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # range if vrange == 'auto': rng = None else: rng = np.array(vrange.split(','), dtype=np.float) drw.plot_lines(dimvalues, varvalues, valuesaxis, dimtit, xaxis, yaxis, rng, \ leglabels.split(','), vartit, varunits, title, locleg, legfontsize, colns, \ lines, points, lwdths, psizes, freqv, figname, graphk, close) return def draw_lines_time(ncfilens, values, varnames): """ Function to draw different lines at the same time from different files with times draw_lines_time(ncfilens, values, varname): ncfilens= [filen]%[dimval] ',' separated list of netCDF files and the 'slice' along the dimensions of the file [dimval]: ';' list of [dimn]|[dimval] to get the values for [varn] [dimn]: name of the dimension [dimval]: value of the dimension variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size values= [dimvname];[valuesaxis];[dimtit];[dimxyfmt];[leglabels];[vtit];[title];[rangevals];[timevals]; [legvals];[graphk];[collines];[points];[linewidths];[pointsizes];[pointfreq];[period];[close] [dimvname]: ',' list of names of the variables with the values of the common dimension for all lines ('WRFtime' for WRF Times variable) [valuesaxis]: which axis will be used for the values ('x', or 'y') [dimtit]: title for the common dimension ('|' for spaces) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [leglabels]: ',' separated list of names for the legend ('None', no legend '!' for spaces, '*' for no label) [vartit]: name of the variable in the graph [title]: title of the plot ('|' for spaces) [rangevals]: Range of the axis with the values ('None' for 'auto','auto') [vmin],[vmax]: minimum and maximum values where [vmNN] can also be: 'auto': the computed minimumm or maximum of the values [timevals]: [timen]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [legvals]=[locleg]|[fontsize]|[Ncols] [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [Ncols]: number of columns in the legend [graphk]: kind of the output of the graphic ('png', 'pdf', 'eps', ...) [lines]: ',' list of type of lines (matplotlib syntax), 'None' for automatic, providing a single value will be used the same for all the lines [collines]: ',' list of colors for the lines (matplotlib syntax), 'None' for automatic, single value all the same [points]: '@' list of type of points (matplotlib syntax ',' no points) for the lines, 'None' for automatic, single value all the same [linewidths]: ',' list of widths for the lines, None for automatic, single value all the same [pointsizes]: ',' list of widths for the lines, None for automatic, single value all the same [pointfreq]: frequency of point plotting (every given number of values), 'all' to plot all values using all time steps 'runmean',[Nsteps]: computing a running mean of [Nsteps] along all values [period]: which period of the data to plot: '-1': all period of data [beg],[end]: beginning and end of the period in reference time-units of first file [close]: Whether figure should be finished or not varnames= ',' list of variable names to plot (assuming only 1 variable per file consecutively). With a single value will be used for all files values= 'time;y;time ([DD]${[HH]}$);32x32;$wss^{*}$;wss Taylor's turbulence term;time|hours!since!1949-12-01_00:00:00;exct,12,h|%d$^{%H}$;2;pdf' """ fname = 'draw_lines_time' if values == 'h': print fname + '_____________________________________________________________' print draw_lines_time.__doc__ quit() expectargs = '[dimvname];[valuesaxis];[dimtit];[dimxyfmt];[leglabels];[vtit];' + \ '[title];[rangevals];[timevals];[legvals];[graphk];[lines];[collines];' + \ '[points];[linewidths];[pointsizes];[pointfreq];[period];[close]' drw.check_arguments(fname,values,expectargs,';') ncfiledims = ncfilens.split(',') dimvname0 = values.split(';')[0] valuesaxis = values.split(';')[1] dimtit = values.split(';')[2].replace('|',' ') dimxyfmt = values.split(';')[3] leglabels = gen.latex_text(values.split(';')[4]).replace('!',' ') vartit = values.split(';')[5] title = values.split(';')[6].replace('|',' ') rangevals = values.split(';')[7] timevals = values.split(';')[8] legvals = values.split(';')[9] graphk = values.split(';')[10] lines0 = values.split(';')[11] collines0 = values.split(';')[12] points0 = values.split(';')[13] linewidths0 = values.split(';')[14] pointsizes0 = values.split(';')[15] pointfreq0 = values.split(';')[16] period = values.split(';')[17] close = gen.Str_Bool(values.split(';')[18]) Nfiles = len(ncfiledims) # Multiple variable-dimension names? if dimvname0.find(',') != -1: dimvname = dimvname0.split(',') else: dimvname = [dimvname0] # Multiple variables? if varnames.find(',') != -1: varname = varnames.split(',') else: varname = [varnames] # Multiple lines types? if lines0.find(',') != -1: lines = lines0.split(',') elif lines0 == 'None': lines = None else: lines = [] for il in range(Nfiles): lines.append(lines0) # Multiple color names? if collines0.find(',') != -1: collines = collines0.split(',') elif collines0 == 'None': collines = None else: collines = [] for ip in range(Nfiles): collines.append(collines0) # Multiple point types? if points0.find(',') != -1: if len(points0) == 1: points = [] for ip in range(Nfiles): points.append(points0) else: points = points0.split('@') elif points0 == 'None': points = None else: points = [] for ip in range(Nfiles): points.append(points0) # Multiple line sizes? if linewidths0.find(',') != -1: linewidths = [] Nlines = len(linewidths0.split(',')) for il in range(Nlines): linewidths.append(np.float(linewidths0.split(',')[il])) elif linewidths0 == 'None': linewidths = None else: linewidths = [np.float(linewidths0)] # Multiple point sizes? if pointsizes0.find(',') != -1: pointsizes = [] Npts = len(pointsizes0.split(',')) for ip in Npts: pointsizes.append(np.float(pointsizes0.split(',')[ip])) elif pointsizes0 == 'None': pointsizes = None else: pointsizes = [np.float(pointsizes0)] timename = timevals.split('|')[0] timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] if rangevals == 'None': valmin = 'auto' valmax = 'auto' else: valmin = rangevals.split(',')[0] valmax = rangevals.split(',')[1] if valmin != 'auto': valmin = np.float(valmin) if valmax != 'auto': valmax = np.float(valmax) # Legend locleg, legfontsize, Ncols = drw.legend_values(legvals,'|') legconf = [locleg, legfontsize, Ncols] # Getting values ## varvalues = [] dimvalues = [] timvalues = [] timvals0 = timvalues ifn = 0 mintval = 1.e20 maxtval = -1.e20 for ifile in ncfiledims: filen = ifile.split('%')[0] dims = ifile.split('%')[1] print ' filen:', filen, 'section:', dims if not os.path.isfile(filen): print errormsg print ' ' + fname + ": netCDF file '" + filen + "' does not exist !!" quit(-1) objfile = NetCDFFile(filen, 'r') founddvar = False for dvar in dimvname: if dvar != 'WRFtime' and objfile.variables.has_key(dvar): founddvar = True vdobj = objfile.variables[dvar] uvd = str(vdobj.units) if len(vdobj.shape) != 1: print errormsg print ' ' + fname + ': wrong shape:',vdobj.shape," of " + \ "variable '" + dvar + "' !!" quit(-1) vdvals = vdobj[:] break elif dvar == 'WRFtime' and objfile.variables.has_key('Times'): founddvar = True timeunit = 'minutes since 1949-12-01 00:00:00' uvd = timeunit tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ '000000' tunitsval = tunitsec[0] timewrfv = objfile.variables['Times'] dt = timewrfv.shape[0] vdvals = np.zeros((dt), dtype=np.float) for it in range(dt): wrfdates = gen.datetimeStr_conversion(timewrfv[it,:], \ 'WRFdatetime', 'matYmdHMS') vdvals[it] = gen.realdatetime1_CFcompilant(wrfdates, refdate, \ tunitsval) if not founddvar: print errormsg print ' ' + fname + ": netCDF file '" + filen + \ "' has any variable '", dimvname, "' !!" print ' available variables:', objfile.variables.keys() quit(-1) foundvar = False for var in varname: if objfile.variables.has_key(var): foundvar = True vvobj0 = objfile.variables[var] # Slicing variables dictslice = {} for dnv in dims.split(';'): dimn = dnv.split('|')[0] dimv = dnv.split('|')[1] if dimv.find(',') != -1: dictslice[dimn] = list(np.array(dimv.split('@'), dtype=int)) else: dictslice[dimn] = int(dimv) slicev, ddv = ncvar.SliceVarDict(vvobj0, dictslice) vvobj = vvobj0[tuple(slicev)] if len(vvobj.shape) != 1: print errormsg print ' ' + fname + ': wrong shape:',vvobj.shape," of " + \ "variable '" + var + "' !!" quit(-1) break if not foundvar: print errormsg print ' ' + fname + ": netCDF file '" + filen + \ "' has any variable '", varname, "' !!" quit(-1) if uvd.find('month') != -1: print warnmsg print ' ' + fname + ": transforming time units from 'months' to 'days'!!" timevals0, tunits0 = gen.CFmonthU_daysU(vdvals[:], vdobj.units) else: timevals0 = vdvals[:] tunits0 = uvd # Getting period if ifn > 0: # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(timevals0, timeunit, tunits0) else: timeunit = tunits0 reftvals = timevals0 dimt = len(vdvals[:]) if period == '-1': if pointfreq0[0:7] == 'runmean': Nstps = int(pointfreq0.split(',')[1]) print ' Running mean of ', Nstps, 'time steps !!' varvalues.append(gen.running_mean(vvobj[:], Nstps, 'vals')) else: varvalues.append(vvobj[:]) dimvalues.append(reftvals) mindvals = np.min(reftvals) maxdvals = np.max(reftvals) else: ibeg=-1 iend=-1 tbeg = np.float(period.split(',')[0]) tend = np.float(period.split(',')[1]) for it in range(dimt-1): if reftvals[it] <= tbeg and reftvals[it+1] > tbeg: ibeg = it if reftvals[it] <= tend and reftvals[it+1] > tend: iend = it + 1 if ibeg != -1 and iend != -1: break if ibeg == -1 and iend == -1: print warnmsg print ' ' + fname + ': Period:',tbeg,',',tend,'not found!!' print ' ibeg:',ibeg,'iend:',iend print ' period in file:',np.min(reftvals), np.max(reftvals) print ' getting all the period in file !!!' ibeg = 0 iend = dimt elif iend == -1: iend = dimt print warnmsg print ' ' + fname + ': end of Period:',tbeg,',',tend,'not found!!' print ' getting last available time instead' print ' ibeg:',ibeg,'iend:',iend print ' period in file:',np.min(reftvals), np.max(reftvals) elif ibeg == -1: ibeg = 0 print warnmsg print ' ' + fname + ': beginning of Period:',tbeg,',',tend, \ 'not found!!' print ' getting first available time instead' print ' ibeg:',ibeg,'iend:',iend print ' period in file:',np.min(reftvals), np.max(reftvals) if pointfreq0[0:7] == 'runmean': Nstps = int(pointfreq0.split(',')[1]) print ' Running mean of ', Nstps, 'time steps !!' varvalues.append(gen.runnig_mean(vvobj[ibeg:iend], Nstps, 'vals')) else: varvalues.append(vvobj[ibeg:iend]) dimvalues.append(reftvals[ibeg:iend]) mindvals = np.min(reftvals[ibeg:iend]) maxdvals = np.max(reftvals[ibeg:iend]) dimt = iend - ibeg if mindvals < mintval: mintval = mindvals if maxdvals > maxtval: maxtval = maxdvals print ' ' + fname + ": file '" + filen + "' period:", mindvals, '->', maxdvals if ifn == 0: varunits = gen.units_lunits(vvobj0.units) else: if varunits != gen.units_lunits(vvobj0.units): print errormsg print ' ' + fname + ': wrong units:', vvobj0.units, " of " + \ "variable '" + var + "' with respect first variable '", varunits, \ "' !!" quit(-1) objfile.close() ifn = ifn + 1 # Times ranget = [mintval, maxtval] dtvals = (maxtval - mintval)/dimt # dti = mintval-dtvals/2. # dte = maxtval+dtvals/2. dti = mintval dte = maxtval tvals = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS tU = timeunit.replace('!', ' ') print timeunit, timekind, timefmt timepos, timelabels = drw.CFtimes_plot(tvals, tU, timekind, timefmt) # print 'Lluis min/max tval +/- dtval/2:', mintval-dtvals/2., maxtval+dtvals/2.,'dt:', len(tvals) # for it in range(len(timepos)): # print timepos[it], timelabels[it] if leglabels != 'None': legvals = leglabels.split(',') else: legvals = None if pointfreq0 == 'all' or pointfreq0[0:7] == 'runmean': pointfreq = None else: pointfreq = int(pointfreq0) # axis xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] drw.plot_lines_time(dimvalues, varvalues, valuesaxis, xaxis, yaxis, dimtit, \ legvals, vartit, varunits, timepos, timelabels, title, legconf, ranget, \ graphk, valmin, valmax, lines, collines, points, linewidths, pointsizes, \ pointfreq, close) return def draw_Neighbourghood_evol(filen, values, variable): """ Function to draw the temporal evolution of a neighbourghood around a point draw_Neighbourghood_evol(filen, values, variable) filen= netCDF file name values= [gvarname]:[dimsval]:[neigdims]:[Nneig]:[Ncol]:[timetits]:[tkinds]: [timefmts]:[gtitle]:[shadxtrms]:[colobarvals]:[neighlinevals]:[gkind]:[ofile]:[close] [gvarname]: ':' list of names of the variables in the plot [dimsval]: [dimn1]|[val1]|[dimv1],...,[dimnN]|[valN]|[dimvN] dimension names, values to get: * [integer]: which value of the dimension * -1: all along the dimension * NOTE, no dim name all the dimension size 'WRFtime' for WRF times NOTE: when dimsval[X,Y] == neigdims[X,Y], valX,valY --> valX,valY-Nneig/2, valX,valY+Nneig/2 [neigdims]: [dimnX],[dimnY] dimensions mnames along which the neigbourghood should be defined [Nneig]: Number of grid points of the full side of the box (odd value) [Ncol]: Number of columns ('auto': square final plot) [gvarname]: name of the variable to appear in the graph [timetits]: [titX],[titY] titles of the axes ('|' for spaces) [tkinds]: [tkindX]|[tkindY] kinds of time to appear in the graph 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [timefmts]: [tfmtX],[tfmtY] format of the time labels [gtitle]: title of the graphic ('|' for spaces) [shadxtrms]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] characteristics of the colormap and colorbar [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [neighlinevals]=[linecol],[linestyle],[linewidth] characterisitcs of the lines to mark the limits of the neighborhood ('auto' for: ['#646464', '-', 2.]) [linecol]: color of the line [linestyle]: style of the line [linewidth]: width of the line [gkind]: kind of graphical output [ofile]: True/False whether the netcdf with data should be created or not [close]: Whether figure should be finished or not variable= name of the variable values = 'q:Time|-1|Times,bottom_top|6|ZNU,south_north|3|XLAT,west_east|26|XLONG:south_north,west_east:5:auto:time|($[DD]^{[HH]}$),time|($[DD]^{[HH]}$):exct,2,h|exct,1,d:$%d^{%H}$,$%d^{%H}$:5|pts|neighbourghood|temporal|evolution:0.0,0.004:BuPu:pdf:True' """ fname = 'draw_Neighbourghood_evol' if values == 'h': print fname + '_____________________________________________________________' print draw_Neighbourghood_evol.__doc__ quit() expectargs = '[gvarname]:[dimsval]:[neigdims]:[Nneig]:[Ncol]:' + \ '[timetits]:[tkinds]:[timefmts]:[gtitle]:[shadxtrms]:[colorbarvals]:' + \ '[neighlinevals]:[gkind]:[ofile]:[close]' drw.check_arguments(fname,values,expectargs,':') gvarname = values.split(':')[0] dimsval = values.split(':')[1].split(',') neigdims = values.split(':')[2].split(',') Nneig = int(values.split(':')[3]) Ncol0 = values.split(':')[4] timetits = values.split(':')[5].split(',') timekinds = values.split(':')[6].split('|') timefmts = values.split(':')[7].split(',') gtitle = values.split(':')[8].replace('|',' ') shadxtrms = values.split(':')[9].split(',') colorbarvals = values.split(':')[10] neighlinevals = values.split(':')[11] gkind = values.split(':')[12] ofile = values.split(':')[13] close = gen.Str_Bool(values.split(':')[14]) if Ncol0 != 'auto': Ncol = int(Ncol0) else: Ncol = Ncol0 timetits[0] = timetits[0].replace('|',' ') timetits[1] = timetits[1].replace('|',' ') if np.mod(Nneig,2) == 0: print errormsg print ' ' + fname + ": an odd value for 'Nneig':", Nneig, 'is required !!!' quit(-1) Nneig2 = int(Nneig/2) # Values to slice the variable dimvslice = {} dimvvalues = {} for dimvs in dimsval: dimn = dimvs.split('|')[0] dimv = int(dimvs.split('|')[1]) dimnv = dimvs.split('|')[2] dimvvalues[dimn] = dimnv dimvslice[dimn] = dimv ncobj = NetCDFFile(filen, 'r') varobj = ncobj.variables[variable] slicevar = [] newdimn = [] newdimsvar = {} for dimn in varobj.dimensions: if not drw.searchInlist(dimvslice.keys(), dimn): dimsize = len(ncobj.dimensions[dimn]) slicevar.append(slice(0, dimsize+1)) newdimn.append(dimn) newdimsvar[dimn] = dimsize for dimslicen in dimvslice.keys(): if dimn == dimslicen: if dimvslice[dimn] != -1: if drw.searchInlist(neigdims, dimn): slicevar.append(slice(dimvslice[dimn]-Nneig2, \ dimvslice[dimn]+Nneig2+1)) newdimn.append(dimn) newdimsvar[dimn] = Nneig break else: slicevar.append(slice(dimvslice[dimn], dimvslice[dimn]+1)) break else: dimsize = len(ncobj.dimensions[dimn]) slicevar.append(slice(0, dimsize+1)) newdimn.append(dimn) newdimsvar[dimn] = dimsize break varv = varobj[tuple(slicevar)] if len(newdimn) != 3: print errormsg print ' ' + fname + ': sliced variable with shape=', varv.shape, \ ' must have three dimensions',len(varv.shape),'given !!' quit(-1) newdims = [] for nwdims in newdimn: newdims.append(newdimsvar[nwdims]) # The dimension which is not in the neighbourhood dimensions must be time! for dim1 in newdimn: if not drw.searchInlist(neigdims, dim1): dimt = newdimsvar[dim1] dimtime = dim1 # Number of columns and rows if Ncol == 'auto': dimtsqx = int(np.sqrt(dimt)) else: dimtsqx = int(Ncol) dimtsqy = dimt/dimtsqx + 1 print ' ' + fname + '; plotting ', dimtsqx, 'x', dimtsqy, 'time-windows of:', \ Nneig, 'x', Nneig, 'grid-points' neighbourghood = np.ones((dimtsqy*Nneig,dimtsqx*Nneig), dtype=np.float)*fillValue for it in range(dimt): ity = int(it/dimtsqx) itx = it-ity*dimtsqx itty = (dimtsqy - ity - 1)*Nneig + Nneig2 ittx = itx*Nneig + Nneig2 neighbourghood[itty-Nneig2:itty+Nneig2+1,ittx-Nneig2:ittx+Nneig2+1]= \ varv[it,::-1,:] variablevals = drw.variables_values(variable) if drw.searchInlist(varobj.ncattrs(), 'units'): vunits = varobj.units else: vunits = variablevals[5] # Time values at the X/Y axes if dimvvalues[dimtime] == 'WRFtime': print ' ' + fname + ": WRF time variable!: 'Times'" refdate = '19491201000000' tunitsval = 'hours' dimtvalues = np.zeros((dimt), dtype=np.float) tvals = ncobj.variables['Times'] yrref=refdate[0:4] monref=refdate[4:6] dayref=refdate[6:8] horref=refdate[8:10] minref=refdate[10:12] secref=refdate[12:14] refdateS = yrref + '/' + monref + '/' + dayref + '_' + horref + ':' + \ minref + ':' + secref tunits = tunitsval + ' since ' + refdateS for it in range(dimt): wrfdates = drw.datetimeStr_conversion(tvals[it,:],'WRFdatetime', 'matYmdHMS') dimtvalues[it] = drw.realdatetime1_CFcompilant(wrfdates, refdate, tunitsval) else: dimtvalues = ncobj.variables[dimvvalues[dimtime]][:] tunits = ncobj.variables[newdimsvar[dimtime]].units dimxv = dimtvalues[0:dimtsqx] dimyv = dimtvalues[0:dimt:dimtsqx] dimn = ['time','time'] if ofile == 'True': ofilen = 'Neighbourghood_evol.nc' newnc = NetCDFFile(ofilen, 'w') # Dimensions newdim = newnc.createDimension('time',None) newdim = newnc.createDimension('y',dimtsqy*Nneig) newdim = newnc.createDimension('x',dimtsqx*Nneig) # Dimension values newvar = newnc.createVariable('time','f8',('time')) newvar[:] = np.arange(dimt) newattr = drw.basicvardef(newvar, 'time','time',tunits) # Neighbourhghood variable newvar = newnc.createVariable(variable + 'neigevol', 'f4', ('y','x'), \ fill_value=fillValue) newvar[:] = neighbourghood newnc.sync() newnc.close() print fname + ": Successfull generation of file '" + ofilen + "' !!" # Colorbar values colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] # Neighborhood line values if neighlinevals == 'auto': neiglinev = ['#646464', '-', 2.] else: neiglinev = neighlinevals.split(',') # Time ticks timeposX, timelabelsX = drw.CFtimes_plot(dimxv, tunits, timekinds[0], timefmts[0]) timeposY, timelabelsY = drw.CFtimes_plot(dimyv, tunits, timekinds[1], timefmts[1]) timepos = [timeposX[0:len(timeposX)], timeposY[len(timeposY):0:-1]] timelabels = [timelabelsX[0:len(timeposX)], timelabelsY[0:len(timeposY)]] for i in range(2): if shadxtrms[i][0:1] != 'S': shadxtrms[i] = np.float(shadxtrms[i]) drw.plot_Neighbourghood_evol(neighbourghood, dimxv, dimyv, gvarname, timetits, \ timepos, timelabels, colormapv, neiglinev, Nneig, shadxtrms, vunits, gtitle, \ gkind, close) def draw_points(filen, values): """ Function to plot a series of points read from an ASCII file with lon, lat, label draw_points(filen, values) [values]= [ptasciifile]:[gtit]:[dimxyfmt]:[mapvalues]:[kindfigure]:[pointcolor]:[pointlabels]: [legvals]:[figureko]:[figuren]:[close] [ptasciifile]:[file],[comchar],[collon],[collat],[lab] [file]: column ASCII file with the location of the points [comchar]: '|' list of characters for commentaries [collon]: number of column with the longitude of the points [collat]: number of column with the latitude of the points [collab]: number of column with the labels of the points ('None', and will get the values from the [pointlabels] variable [gtit]: title of the figure ('|' for spaces) [dimxyfmt]: [dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [mapvalues]: drawing coastaline ([proj],[res]) or None [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [kindfigure]: kind of figure 'legend': only points in the map with the legend with the names 'labelled',[txtsize],[txtcol],[txtbckgcol]: points with the names and size, color of text and background color ('None' for without) [pointcolor]: color for the points ('auto' for "red") [pointlabels]: ',' of labels [only used if [collab]='None'] ('None' for no labels, '!' for spaces) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figureko]: kind of the output file (pdf, png, ...) [figuren]: name of the figure [close]: Whether figure should be finished or not [filen]= [ncfile],[lonvarn],[latvarn][,[varn],[dimvals],[vargn],[min],[max],[colbarn],[fmtcolorbar],[orientation],[varu]] [ncfile]: netCDF to use to geolocalize the points [lonvarn]: name of the variable with the longitudes [latvarn]: name of the variable with the latitudes Optional values: [varn]: optional variable to add staff into the graph [dimval]: '@' list of [dimn]|[dimval] to get the values for [varn] [dimn]: name of the dimension [dimval]: value of the dimension variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg];[end];[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [vargn]: name of the variable in the graph [min]: minimum value for the extra variable [max]: maximum value for the extra variable [colbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [varu]: units of the variable """ fname = 'draw_points' if values == 'h': print fname + '_____________________________________________________________' print draw_points.__doc__ quit() expectargs = '[ptasciifile]:[gtit]:[dimxyfmt]:[mapvalues]:[kindfigure]:' + \ '[pointcolor]:[pointlabels]:[legvals]:[figurek]:[figuren]:[close]' drw.check_arguments(fname,values,expectargs,':') ptasciifile = values.split(':')[0] gtit = values.split(':')[1] dimxyfmt = values.split(':')[2] mapvalues = values.split(':')[3] kindfigure = values.split(':')[4] pointcolor = values.split(':')[5] pointlabels = values.split(':')[6].replace('!',' ') legvalues = values.split(':')[7] figureko = values.split(':')[8] figuren = values.split(':')[9] close = gen.Str_Bool(values.split(':')[10]) # Getting station locations ## filev = ptasciifile.split(',')[0] comchar = ptasciifile.split(',')[1].split('|') collon = int(ptasciifile.split(',')[2]) collat = int(ptasciifile.split(',')[3]) collab = ptasciifile.split(',')[4] if not os.path.isfile(filev): print errormsg print ' ' + fname + ": file '" + filev + "' does not exist!!" quit(-1) # Getting points position and labels oascii = open(filev, 'r') xptval = [] yptval = [] if collab != 'None': ptlabels = [] for line in oascii: if not drw.searchInlist(comchar, line[0:1]): linevals = drw.reduce_spaces(line) xptval.append(np.float(linevals[collon].replace('\n',''))) yptval.append(np.float(linevals[collat].replace('\n',''))) ptlabels.append(linevals[int(collab)].replace('\n','')) else: ptlabels = None for line in oascii: if not drw.searchInlist(comchar, line[0:1]): linevals = drw.reduce_spaces(line) xptval.append(np.float(linevals[collon].replace('\n',''))) yptval.append(np.float(linevals[collat].replace('\n',''))) oascii.close() if pointlabels != 'None' and collab == 'None': ptlabels = pointlabels.split(',') # Getting localization of the points ## filev = filen.split(',') Nvals = len(filev) ncfile = filev[0] lonvarn = filev[1] latvarn = filev[2] varn = None varextrav = None if Nvals == 12: varn = filev[3] dimvals = filev[4] varextrav = [filev[5], np.float(filev[6]), np.float(filev[7]), filev[8], \ filev[9], filev[10], filev[11]] if filev[9] == 'auto': varextrav[4] = '%6g' if filev[10] == 'auto': varextrav[5] = 'vertical' if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not exist!!" quit(-1) onc = NetCDFFile(ncfile, 'r') # Slicing lon,lats dd = {} for dn in dimvals.split('@'): ddn = dn.split('|')[0] ddv = dn.split('|')[1] dd[ddn] = ddv objlon = onc.variables[lonvarn] vard = objlon.dimensions slicevar = [] for dv in vard: found= False for dn in dd.keys(): if dn == dv: if dd[dn].find(';') == -1: if dd[dn] == '-1': slicevar.append(slice(0,len(onc.dimensions[dv]))) elif dd[dn] == '-9': slicevar.append(len(onc.dimensions[dv])) else: slicevar.append(int(dd[dn])) else: islc = int(dd[dn].split(';')[0]) eslc = int(dd[dn].split(';')[1]) tslc = int(dd[dn].split(';')[2]) slicevar.append(slice(islc,eslc,tslc)) found = True break if not found: slicevar.append(slice(0,len(onc.dimensions[dv]))) lonvals = np.squeeze(objlon[tuple(slicevar)]) objlat = onc.variables[latvarn] vard = objlat.dimensions slicevar = [] for dv in vard: found= False for dn in dd.keys(): if dn == dv: if dd[dn].find(';') == -1: if dd[dn] == '-1': slicevar.append(slice(0,len(onc.dimensions[dv]))) elif dd[dn] == '-9': slicevar.append(len(onc.dimensions[dv])) else: slicevar.append(int(dd[dn])) else: islc = int(dd[dn].split(';')[0]) eslc = int(dd[dn].split(';')[1]) tslc = int(dd[dn].split(';')[2]) slicevar.append(slice(islc,eslc,tslc)) found = True break if not found: slicevar.append(slice(0,len(onc.dimensions[dv]))) latvals = np.squeeze(objlat[tuple(slicevar)]) lonv, latv = drw.lonlat2D(lonvals, latvals) if varn is not None: objextra = onc.variables[varn] vard = objextra.dimensions slicevar = [] for dv in vard: found= False for dn in dd.keys(): if dn == dv: if dd[dn].find(';') == -1: if dd[dn] == '-1': slicevar.append(slice(0,len(onc.dimensions[dv]))) elif dd[dn] == '-9': slicevar.append(len(onc.dimensions[dv])) else: slicevar.append(int(dd[dn])) else: islc = int(dd[dn].split(';')[0]) eslc = int(dd[dn].split(';')[1]) tslc = int(dd[dn].split(';')[2]) slicevar.append(slice(islc,eslc,tslc)) found = True break if not found: slicevar.append(slice(0,len(onc.dimensions[dv]))) varextra = np.squeeze(objextra[tuple(slicevar)]) # Axis values xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if mapvalues == 'None': mapV = None else: mapV = mapvalues # legend locleg, sizeleg = drw.legend_values(legvalues, '|') drw.plot_points(xptval, yptval, lonv, latv, varextra, varextrav, gtit, xaxis, \ yaxis, mapV, kindfigure, pointcolor, ptlabels, locleg, sizeleg, figureko, \ figuren, close) onc.close() return def draw_points_lonlat(filen, values): """ Function to plot a series of lon/lat points filen= name of the file values= [lonvarname]:[latvarname]:[gkind]:[gtit]:[ptcolor]:[pttype]:[ptsize]:[labels]:[legvals]:[figureK]: [figclose] [lonvarname]: name of the variable longitude [latvarname]: name of the variable latitude [gkind]: kind of graphical output (pdf, png, ps) [gtit]: graphic title '!' for spaces [ptcolor]: color of the points ('auto', for "red") [pttype]: type of point [ptsize]: size of point [labels]: ',' list of labels to use [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figureK]= kind of figure 'legend': only points in the map with the legend with the names 'labelled',[txtsize],[txtcol]: points with the names and size, color of text [figclose]: whether figures should be closed or not """ fname = 'draw_points_lonlat' if values == 'h': print fname + '_____________________________________________________________' print draw_points_lonlat.__doc__ quit() expectargs = '[lonvarname]:[latvarname]:[gkind]:[gtit]:[ptcolor]:[pttype]:' + \ '[ptsize]:[labels]:[locleg]:[figureK]:[figclose]' drw.check_arguments(fname,values,expectargs,':') lonname = values.split(':')[0] latname = values.split(':')[1] kindfigure = values.split(':')[2] gtit = values.split(':')[3].replace('!',' ') pointcolor = values.split(':')[4] pointtype = values.split(':')[5] pointsize = np.float(values.split(':')[6]) labelsv = values.split(':')[7] legvals = values.split(':')[8] figureK = values.split(':')[9] figclose = gen.Str_Bool(values.split(':')[10]) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(lonname): print errormsg print fname + ": file '" + filen + "' does not have longitudes '" + lonname +\ "' !!" quit(-1) if not onc.variables.has_key(lonname): print errormsg print fname + ": file '" + filen + "' does not have longitudes '" + lonname +\ "' !!" quit(-1) olon = onc.variables[lonname] olat = onc.variables[latname] Ndimlon = len(olon.shape) if Ndimlon == 1: dx = olon.shape[0] dy = olat.shape[0] if dx == dy: lonvals = olon[:] latvals = olat[:] else: lonvals0 = np.zeros((dy,dx), dtype=np.float) latvals0 = np.zeros((dy,dx), dtype=np.float) for iL in range(dy): lonvals0[iL,:] = olon[:] for il in range(dx): latvals0[:,il] = olat[:] lonvals = lonvals0.flatten() latvals = latvals0.flatten() elif Ndimlon == 2: lonvals = olon[:].flatten() latvals = olat[:].flatten() elif Ndimlon == 3: lonvals = olon[1,:,:].flatten() latvals = olat[1,:,:].flatten() # Playing for Anna # lonvals = olon[:].flatten() # latvals = olat[:].flatten() elif Ndimlon == 4: lonvals = olon[1,0,:,:].flatten() latvals = olat[1,0,:,:].flatten() else: print errormsg print ' ' + fname + ': longitude size:',len(olon),' not ready!!' quit(-1) if labelsv == 'None': labels = None else: labels = labelsv.split(',') locleg, sizeleg = drw.legend_values(legvals,'|') drw.plot_list_points(lonvals, latvals, lonname, latname, gtit, figureK, pointcolor, pointtype, \ pointsize, labels, locleg, sizeleg, kindfigure, fname, figclose) onc.close() return def draw_timeSeries(filen, values, variables): """ Function to draw a time-series draw_timeSeries(filen, values, variable): filen= name of the file values= [dimvalues]:[sminv],[smaxv]:[gvarname]:[timetit]:[tkind]:[timefmt]:[title]:[leglabs]:[legvals]: [gkind]:[colorlines]:[typelines]:[widthlines]:[pointtype]:[pointfreq]:[figclose] [dimvalues]= ',' separated list of [dimname]|[slice] no given dimension takes all values [dimname]: name of dimension [slice]: value to take for the given dimension * [integer]: which value of the dimension * -1: all along the dimension * [beg]@[end]@[freq] slice from [beg] to [end] every [freq] * -9: last value of the dimension [sminv],[smaxv]: minimum and maximum value for the lines or one value for each extreme: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [gvarname]: name of the variable to appear in the graph [timetit]: title of the time axis (assumed x-axis, '|' for spaces) [tkind]: kind of time to appear in the graph (assumed x-axis) 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [timefmt]: format of the time labels (C-like) [title]: title of the graphic ('|' for spaces) [leglabs]: ',' separated list of labels for the lines [legvals]=[locleg]|[fontsize]: legend values [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [gkind]: kind of graphical output [colorlines]: ',' list of colors for the lines, 'None' for automatic, single value all the same [typelines]: ',' list of types for the lines, 'None' for automatic, single value all the same [widthlines]: ',' list of width for the lines, 'None' for automatic, single value all the same [pointtype]: ',' list of type of points for the lines, 'None' for automatic, single value all the same [pointsizee]: ',' list of size of points for the lines, 'None' for automatic, single value all the same [pointfreq]: frequency of point plotting, 'all' for all time steps [figclose]: whether figure should be closed or not variables= [varname],[timename] names of variable and variable with times """ fname = 'draw_timeSeries' if values == 'h': print fname + '_____________________________________________________________' print draw_timeSeries.__doc__ quit() expectargs= '[dimvalues]:[sminv],[smaxv]:[gvarname]:[timetit]:[tkind]:' + \ '[timefmt]:[title]:[leglabs]:[legvals]:[gkind]:[colorlines]:[typelines]:' + \ '[widthlines]:[pointtype]:[pointsize]:[pointfreq]:[figclose]' drw.check_arguments(fname,values,expectargs,':') dimvalues = values.split(':')[0] sminmaxv = values.split(':')[1] gvarname = gen.latex_text(values.split(':')[2]) timetit = values.split(':')[3].replace('|',' ') tkind = values.split(':')[4] timefmt = values.split(':')[5] title = gen.latex_text(values.split(':')[6].replace('|',' ')) leglabs = gen.str_list(values.split(':')[7], ',') legvals = values.split(':')[8] gkind = values.split(':')[9] colorlines = values.split(':')[10] typelines = values.split(':')[11] widthlines = values.split(':')[12] pointtype = values.split(':')[13] pointsize = values.split(':')[14] pointfreq0 = values.split(':')[15] figclose = gen.Str_Bool(values.split(':')[16]) ncobj = NetCDFFile(filen, 'r') variable = variables.split(',')[0] timevar = variables.split(',')[1] if not ncobj.variables.has_key(variable): print errormsg print ' ' + fname + ": file '" + filen + "' does not have variable '" + \ variable + "' !!" quit(-1) if not ncobj.variables.has_key(timevar): print errormsg print ' ' + fname + ": file '" + filen + "' does not have variable time '" \ + timevar + "' !!" quit(-1) varobj = ncobj.variables[variable] timeobj = ncobj.variables[timevar] # Slicing variables dictslice = {} for dnv in dimvalues.split(','): dimn = dnv.split('|')[0] dimv = dnv.split('|')[1] if dimv.find(',') != -1: dictslice[dimn] = list(np.array(dimv.split('@'), dtype=int)) else: dictslice[dimn] = int(dimv) slicet, ddt = ncvar.SliceVarDict(timeobj, dictslice) timevals = timeobj[tuple(slicet)] dimt = len(timevals) varattrs = varobj.ncattrs() if not gen.searchInlist(varattrs,'units'): print ' ' + fname + ": variable '" + variable + "' does not have units !!" print " using name in figure to search for them in 'variable_values.dat'" varvals = drw.variables_values(gvarname) gunits = varvals[5] print " getting units of '" + gvarname + "' as: '" + gunits + "'" else: gunits = varobj.getncattr('units') tunits = timeobj.getncattr('units') slicev, ddv = ncvar.SliceVarDict(varobj, dictslice) varvalues = varobj[tuple(slicev)] matvarvals = np.array(varvalues) if len(matvarvals.shape) != 1: print errormsg print ' ' + fname + ': wrong rank of values to plot!!' print ' resultant values to plot have a shape:', matvarvals.shape, \ 'it mast be of rank 1D' print ' provided slice:', slicev quit(-1) varvals = np.zeros((2,dimt), dtype=np.float) varvals[0,:], valpot, newgunits, Spot = drw.pot_values(varvalues.flatten(), gunits) varvals[1,:] = timeobj[:] # Min/max values in plot line_nx = [] if sminmaxv.split(',')[0][0:1] != 'S': line_nx.append(np.float(sminmaxv.split(',')[0])) else: line_nx.append(sminmaxv.split(',')[0]) if sminmaxv.split(',')[1][0:1] != 'S': line_nx.append(np.float(sminmaxv.split(',')[1])) else: line_nx.append(sminmaxv.split(',')[1]) tseriesvals = [] tseriesvals.append(varvals) collines = gen.str_list(colorlines, ',') typlines = gen.str_list(typelines, ',') wdthlines = gen.str_list(widthlines, ',') pttype = gen.str_list(pointtype, ',') ptsize = gen.str_list(pointsize, ',') if pointfreq0 == 'all': pointfreq = None else: pointfreq = int(pointfreq0) locleg, sizleg = drw.legend_values(legvals, '|') drw.plot_TimeSeries(tseriesvals, line_nx, Spot + gunits, tunits, 'TimeSeries', \ gvarname,timetit, tkind, timefmt, title, leglabs, locleg, sizleg, gkind, \ collines, typlines, pttype, wdthlines, ptsize, pointfreq, figclose) return #draw_timeSeries('wrfout_d01_1979-12-01_00:00:00_bottom_top_B6-E6-I1_south_north_B3-E3-I1_west_east_B26-E26-I1.nc', 'dt_con:time|($[DD]^{[HH]}$):exct,12,h:$%d^{%H}$:time|evolution|at|-1|6|3|26:1:pdf:None:None', 'LDQCON,time') def draw_trajectories(trjfilens, values, observations): """ Function to draw different trajectories at the same time Trajectories are readed from ASCII files with a pair of i,j grid points for each position of the trajectory i,j couples of trajectories for all files are referred to a netcdf file with a respective projection A complemtary file for observations is also added separately trjfilens= [filen]@[Tint]@[map]@[Ttrj] ',' separated list of ASCII files with trajectories, time intervals and reference maps (first one will be used to plot) [filen]: name of the file to use (lines with '#', not readed) with values as: [t-step] [x] [y] [Tint]: interval of time-steps to get from the file as [Tbeg]@[Tend] or -1 for all the interval [map]: [file]#[lonname]#[latname] common projection data [file]; netcdf file with the [lon],[lat] projection for the trajectory [lonname],[latname]; names of the longitudes and latitudes variables in [file] [Ttrj]|[val1]|[val2]|[...|[valN]]: kind of associated time values to the trajectory 't-step'|[dtime]|[idate]: each line corresponds to a consecutive time-step with the same deltatime [dtime]: length of time-step in seconds [idate]: date of the first time-step (in [YYYY][MM][DD][HH][MI][SS] format) 'CF-step'|[units]|[refdate]: each line corresponds to a consecutive CF time-step [units]: any of standard temporal CF units: weeks, days, hours, minutes, seconds, ... [refdate]: reference date of the CF time-units 'fulldate': each line provides the correspondance date (in [YYYY][MM][DD][HH][MI][SS] format) values= [plotkind]|[leglabels]|[lonlatlims]|[title]|[graphk]|[mapkind]|[legvals]|[figclose] [plotkind],[val1],[...,[valN]]: kind of plot to generate 'spaghetti'@[trjltype]@[trjlcol]@[trjlwdth]@[trjptyp]@[trjpsiz]: line-marker for each trajectory [trjltype]: ',' list of type of lines for each trajectory (single value same for all, 'None' for auto) [trjlcol]: ',' list of color of lines for each trajectory (single value same for all, 'None' for auto) [trjlwdth]: ',' list of width of lines for each trajectory (single value same for all, 'None' for auto) [trjptyp]: ',' list of type of points for each trajectory (single value same for all, 'None' for auto) [trjpsiz]: ',' list of size of points for each trajectory (single value same for all, 'None' for auto) 'spaghetti_date'@[trjltype]@[trjlcol]@[trjlwdth]@[trjptyp]@[trjpsiz]@[datefmt]@[datefontsize] @[datefreq]@[xoffset]@[yoffset]: line-marker for each trajectory with a given date format at each point [trjltype]: ',' list of type of lines for each trajectory (single value same for all, 'None' for auto) [trjlcol]: ',' list of color of lines for each trajectory (single value same for all, 'None' for auto) [trjlwdth]: ',' list of width of lines for each trajectory (single value same for all, 'None' for auto) [trjptyp]: ',' list of type of points for each trajectory (single value same for all, 'None' for auto) [trjpsiz]: ',' list of size of points for each trajectory (single value same for all, 'None' for auto) [datefmt]: format of the date to show (C-like mixed with LaTeX commands) [datefontsize]: font-size of the time-labels [datefreq]: frequency of time-labels [xoffset]: x-axis offset in pixels of the time-lables respect trajectory [yoffset]: y-axis offset in pixels of the time-lables respect trajectory [leglabels]: ',' separated list of names for the legend [lonlatlims]: ',' list of limits of the map [lonmin, latmin, lonmax, latmax] or None [title]: title of the plot ('!' for spaces) [graphk]: kind of output of the graphic (png, pdf, ...) [mapkind]: drawing coastaline ([proj],[res]) or None [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [legvals]=[locleg]@[fontsize]: legend values [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figclose]: whether figure should be closed or not observations= [obsfile],[obsname],[Tint],[null],[obstrjvals] ('None' for no observational/reference trajectory) [obsfile]: name fo the File with the observations as [t-step] [lat] [lon] [obsname]: name of the observations in the graph [Tint]: interval of time as [Tbeg]@[Tend] or -1 for all the interval [null]: null value for the observed trajectory [obstrjvals] = [Ttrj]@[obsltype]@[obslcol]@[obslwdth]@[obsptyp]@[obspsiz] values for the observational/reference trajectory in the plot [Ttrj]|[val1]|[val2]|[...|[valN]]: kind of associated time values to the trajectory 't-step'|[dtime]|[idate]: each line corresponds to a consecutive time-step with the same deltatime [dtime]: length of time-step in seconds [idate]: date of the first time-step (in [YYYY][MM][DD][HH][MI][SS] format) 'CF-step'|[units]|[refdate]: each line corresponds to a consecutive CF time-step [units]: any of standard temporal CF units: weeks, days, hours, minutes, seconds, ... [refdate]: reference date of the CF time-units 'fulldate': each line provides the correspondance date (in [YYYY][MM][DD][HH][MI][SS] format) [obsltype]: type of line for the observations/reference trajectory (single 'auto' for '-', 'k', 2, 'x', 2) [obslcol]: color of line for the observations/reference trajectory [obslwdth]: width of line for the observations/reference trajectory [obsptyp]: type of point for the observations/reference trajectory [obspsiz]: size of point for the observations/reference trajectory """ import datetime as dt fname = 'draw_trajectories' if values == 'h': print fname + '_____________________________________________________________' print draw_trajectories.__doc__ quit() expectargs = '[plotkind]|[leglabels]|[lonlatlims]|[title]|[graphk]|[mapkind]|' + \ '[legvals]|[figclose]' drw.check_arguments(fname,values,expectargs,'|') expectargs = '[obsfile],[obsname],[Tint],[null],[obstrjvals]' drw.check_arguments('obstraj',observations,expectargs,',') trjfiles = trjfilens.split(',') plotkind = values.split('|')[0] leglabels = values.split('|')[1] lonlatlims = values.split('|')[2] title = gen.latex_text(values.split('|')[3].replace('!',' ')) graphk = values.split('|')[4] mapkind = values.split('|')[5] legvals = values.split('|')[6] figclose = gen.Str_Bool(values.split('|')[7]) Nfiles = len(trjfiles) # plot kind plotkindv = plotkind.split('@') if plotkindv[0] == 'spaghetti': expectargs = 'spaghetti@[trjltype]@[trjlcol]@[trjlwdth]@[trjptyp]@[trjpsiz]' drw.check_arguments(plotkindv[0],plotkind,expectargs,'@') trjltype = gen.str_list(plotkindv[1], ',') trjlcol = gen.str_list(plotkindv[2], ',') trjlwdth = gen.str_list(plotkindv[3], ',') trjptyp = gen.str_list(plotkindv[4], ',') trjpsiz = gen.str_list(plotkindv[5], ',') elif plotkindv[0] == 'spaghetti_date': expectargs = 'spaghetti_date@[trjltype]@[trjlcol]@[trjlwdth]@[trjptyp]@' + \ '[trjpsiz]@[datefmt]@[datefontsize]@[datefreq]@[xoffset]@[yoffset]' drw.check_arguments(plotkindv[0],plotkind,expectargs,'@') trjltype = gen.str_list(plotkindv[1], ',') trjlcol = gen.str_list(plotkindv[2], ',') trjlwdth = gen.str_list(plotkindv[3], ',') trjptyp = gen.str_list(plotkindv[4], ',') trjpsiz = gen.str_list(plotkindv[5], ',') datefmt = gen.str_list(plotkindv[6], ',') datefsize = gen.str_list(plotkindv[7], ',') datefreq = int(plotkindv[8]) xoffset = int(plotkindv[9]) yoffset = int(plotkindv[10]) else: print errormsg print ' ' + fname + ": kind of plot '" + plotkindv[0] + "' not ready !!" print ' accepted ones:', ['spaghetti', 'spaghetti_date'] quit(-1) # Getting trajectotries ## lontrjvalues = [] lattrjvalues = [] timetrjvalues = [] ifn = 0 for ifile in trjfiles: filen = ifile.split('@')[0] Tint = ifile.split('@')[1] if not os.path.isfile(filen): print errormsg print ' ' + fname + ": trajectory file '" + filen + "' does not exist !!" quit(-1) print ' ', ifn+1, "trajectory'" + filen + "'" if Tint != '-1': Tbeg = Tint Tend = ifile.split('@')[2] mapv = ifile.split('@')[3] Tkind = ifile.split('@')[4] else: mapv = ifile.split('@')[2] Tkind = ifile.split('@')[3] # Charging longitude and latitude values ## lonvals, latvals = drw.lonlat_values(mapv.split('#')[0], mapv.split('#')[1], \ mapv.split('#')[2]) if ifn == 0: mapref = mapv ifn = ifn + 1 objfile = open(filen, 'r') trjtimev = [] trjxv = [] trjyv = [] for line in objfile: if line[0:1] != '#': trjtimev.append(int(line.split(' ')[0])) trjxv.append(int(line.split(' ')[1])) trjyv.append(int(line.split(' ')[2])) objfile.close() #Time-values Tkindv = Tkind.split('|') datesTtrj = [] if Tkindv[0] == 'CF-step': tunits = Tkindv[1] refdate = Tkindv[2] if tunits == 'weeks': dtime = tunis*7.*24.*3600. elif tunits == 'days': dtime = tunis*24.*3600. elif tunits == 'hours': dtime = tunis*3600. elif tunits == 'minutes': dtime = tunis*60. elif tunits == 'seconds': dtime = tunis else: print erromsg print ' '+ fname + ": time-units of CF time-trajectory '" + tunits + \ "' not ready !!" print ' available ones:', ['weeks', 'days', 'hours', 'minutes', \ 'seconds'] quit(-1) refdateT = gen.DateTimeStr_date(refdate) for it in trjtimev: datesTtrj.append(refdateT + dt.timedelta(seconds=it)) elif Tkindv[0] == 'fulldate': for it in trjtimev: datesTtrj.append(gen.DateTimeStr_date(it)) elif Tkindv[0] == 't-step': dtime = np.float(Tkindv[1]) idate = Tkindv[2] print ' ' + fname + ': idate:', idate refdateT = gen.DateTimeStr_date(idate) for it in range(len(trjtimev)): datesTtrj.append(refdateT + dt.timedelta(seconds=dtime*it)) else: print errormsg print ' ' +fname+ ": associated time kind of trajectory '" + Tkind[0] + \ "' not ready!!" print ' accepted ones:', ['t-step', 'CF-step'] if Tint != '-1': lontrjvalues.append(lonvals[trjyv[Tint:Tend+1], trjxv[Tint:Tend+1]]) lattrjvalues.append(latvals[trjyv[Tint:Tend+1], trjxv[Tint:Tend+1]]) timetrjvalues.append(datesTtrj[Tint:Tend+1]) else: lontrjvalues.append(lonvals[trjyv[:], trjxv[:]]) lattrjvalues.append(latvals[trjyv[:], trjxv[:]]) timetrjvalues.append(datesTtrj[:]) # lonlatlimits ## if lonlatlims == 'None': lonlatlimsv = None else: lonlatlimsv = np.zeros((4), dtype=np.float) lonlatlimsv[0] = np.float(lonlatlims.split(',')[0]) lonlatlimsv[1] = np.float(lonlatlims.split(',')[1]) lonlatlimsv[2] = np.float(lonlatlims.split(',')[2]) lonlatlimsv[3] = np.float(lonlatlims.split(',')[3]) # lon/lat objects ## objnc = NetCDFFile(mapref.split('#')[0]) lonobj = objnc.variables[mapref.split('#')[1]] latobj = objnc.variables[mapref.split('#')[2]] # map ## if mapkind == 'None': mapkindv = None else: mapkindv = mapkind if observations is None: obsname = None else: obsfile = observations.split(',')[0] obsname = observations.split(',')[1] Tint = observations.split(',')[2] null = np.float(observations.split(',')[3]) obstrajvals = observations.split(',')[4] if not os.path.isfile(obsfile): print errormsg print ' ' + fname + ": observations trajectory file '" + obsfile + \ "' does not exist !!" quit(-1) print ' ' + fname + ": observational trajectory in file: '" + obsfile + "'" objfile = open(obsfile, 'r') obstrjtimev = [] obstrjxv = [] obstrjyv = [] for line in objfile: if line[0:1] != '#': lon = np.float(line.split(' ')[2]) lat = np.float(line.split(' ')[1]) if not lon == null and not lat == null: obstrjtimev.append(int(line.split(' ')[0])) obstrjxv.append(lon) obstrjyv.append(lat) else: obstrjtimev.append(None) obstrjxv.append(None) obstrjyv.append(None) objfile.close() #Time-values Tkind = obstrajvals.split('@')[0] Tkindv = Tkind.split('|') datesTtrj = [] if Tkindv[0] == 'CF-step': tunits = Tkindv[1] refdate = Tkindv[2] if tunits == 'weeks': dtime = tunis*7.*24.*3600. elif tunits == 'days': dtime = tunis*24.*3600. elif tunits == 'hours': dtime = tunis*3600. elif tunits == 'minutes': dtime = tunis*60. elif tunits == 'seconds': dtime = tunis else: print erromsg print ' '+ fname + ": time-units of CF time-trajectory '" + tunits + \ "' not ready !!" print ' available ones:', ['weeks', 'days', 'hours', 'minutes', \ 'seconds'] quit(-1) refdateT = gen.DateTimeStr_date(refdate) for it in obstrjtimev: datesTtrj.append(refdateT + dt.timedelta(seconds=it)) elif Tkindv[0] == 'fulldate': for it in obstrjtimev: datesTtrj.append(gen.DateTimeStr_date(it)) elif Tkindv[0] == 't-step': dtime = np.float(Tkindv[1]) idate = Tkindv[2] refdateT = gen.DateTimeStr_date(idate) for it in range(len(obstrjtimev)): datesTtrj.append(refdateT + dt.timedelta(seconds=dtime*it)) else: print errormsg print ' ' +fname+ ": associated time kind of trajectory '" + Tkindv[0]+ \ "' not ready!!" print ' accepted ones:', ['t-step', 'CF-step'] # Parameters observational/reference trajectory obslv = obstrajvals.split('@')[1:6] if obslv[0] == 'auto': obslt = '-' obslc = 'k' obslw = '2' obspt = 'x' obsps = '2' else: obslt = obslv[0] obslc = obslv[1] obslw = np.float(obslv[2]) obspt = obslv[3] obsps = np.float(obslv[4]) if Tint != '-1': Tint = int(observations.split(',')[2].split('@')[0]) Tend = int(observations.split(',')[2].split('@')[1]) lontrjvalues.append(obstrjxv[Tint:Tend+1]) lattrjvalues.append(obstrjyv[Tint:Tend+1]) timetrjvalues.append(datesTtrj[Tint:Tend+1]) else: lontrjvalues.append(obstrjxv[:]) lattrjvalues.append(obstrjyv[:]) timetrjvalues.append(datesTtrj[:]) locleg, sizleg = drw.legend_values(legvals, '@') drw.plot_Trajectories(lontrjvalues, lattrjvalues, timetrjvalues, plotkindv, \ leglabels.split(','), trjltype, trjlcol, trjlwdth, trjptyp, trjpsiz, lonobj, \ latobj, [obslt, obslc, obslw, obspt, obsps], lonlatlimsv, title, graphk, \ mapkindv, obsname, locleg, sizleg, figclose) objnc.close() return def draw_vals_trajectories(ncfile, values, variable): """ Function to draw values from the outputs from 'compute_tevolboxtraj' draw_vals_trajectories(ncfile, values, variable) ncfile= [ncfile] ',' list of files to use values= [statisticskind]:[sminv],[smaxv]:[Tint]:[labels]:[legvals]:[gvarname]:[timetit]:[tkind]: [timefmt]:[title]:[gkind]:[colorlines]:[typelines]:[widthlines]:[pointtype]:[pointsizee]:[pointfreq]:[figclose] [statisticskind]=[statistics][kind] [statistics]: which statistics to use, from: 'center', 'min', 'max', 'mean', 'mean2', 'stdev' [kind]: 'box', 'circle' statistics taking the values from a box or a circle 'trj': value following the trajectory [sminv],[smaxv]: minimum and maximum value for the lines or one value for each extreme: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [Tint]: [Tbeg]@[Tend] or None, interval of time to plot or -1 for all the times [leglabels]: ',' separated list of labels for the legend [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [gvarname]: name of the variable to appear in the graph [timetit]: title of the time axis (assumed x-axis, '|' for spaces) [tkind]: kind of time to appear in the graph (assumed x-axis) 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [timefmt]: format of the time labels [title]: title of the graphic ('|' for spaces) [gkind]: kind of graphical output [colorlines]: ',' list of colors for the lines, 'None' for automatic, single value all the same [typelines]: ',' list of types for the lines, 'None' for automatic, single value all the same [widthlines]: ',' list of width for the lines, 'None' for automatic, single value all the same [pointtype]: ',' list of type of points for the lines, 'None' for automatic, single value all the same [pointsizee]: ',' list of size of points for the lines, 'None' for automatic, single value all the same [pointfreq]: frequency of point plotting, 'all' for all time steps [figclose]: whether figure should be close or not variable= variable to use """ fname = 'draw_vals_trajectories' if values == 'h': print fname + '_____________________________________________________________' print draw_vals_trajectories.__doc__ quit() expectargs = '[statisticskind]:[sminv],[smaxv]:[Tint]:[leglabels]:[legvals]:' + \ '[gvarname]:[timetit]:[tkind]:[timefmt]:[title]:[gkind]:[colorlines]:' + \ '[typelines]:[widthlines]:[pointtype]:[pointsizee]:[pointfreq]:[figclose]' drw.check_arguments(fname,values,expectargs,':') sims = ncfile.split(',') statisticskind = values.split(':')[0] sminmaxv = values.split(':')[1] Tint = values.split(':')[2] leglabels = values.split(':')[3].split(',') legvals = values.split(':')[4] gvarname = values.split(':')[5] timetit = values.split(':')[6].replace('|',' ') tkind = values.split(':')[7] timefmt = values.split(':')[8] title = values.split(':')[9].replace('|',' ') gkind = values.split(':')[10] colorlines = values.split(':')[11] typelines = values.split(':')[12] widthlines = values.split(':')[13] pointtype = values.split(':')[14] pointsize = values.split(':')[15] pointfreq0 = values.split(':')[16] figclose = gen.Str_Bool(values.split(':')[17]) Nsims = len(sims) if Tint != '-1': tini = np.float(Tint.split('@')[0]) tend = np.float(Tint.split('@')[1]) else: tini = -1. tend = -1. vartimetrjv = [] print ' ' + fname for trjfile in sims: print ' ' + trjfile + ' ...' if not os.path.isfile(trjfile): print errormsg print ' ' + fname + ": trajectory file: '" + trjfile + \ "' does not exist !!" quit(-1) trjobj = NetCDFFile(trjfile, 'r') otim = trjobj.variables['time'] if not trjobj.variables.has_key(statisticskind + '_' + variable): print errormsg print ' ' + fname + ": file '" + trjfile + "' does not have variable '"+\ statisticskind + '_' + variable + "' !!" quit(-1) ovar = trjobj.variables[statisticskind + '_' + variable] dimt = otim.shape[0] if trjfile == sims[0]: gunits = ovar.getncattr('units') lname = ovar.getncattr('long_name') tunits = otim.getncattr('units') if tini != -1: tiniid = -1 tendid = -1 for itv in range(dimt): if otim[itv] <= tini and otim[itv+1] >= tini: tiniid = itv if otim[itv] <= tend and otim[itv+1] >= tend: tendid = itv if tiniid == -1 or tendid == -1: print errormsg print ' ' + main + ' time interval ', tini,',',tend,' not found: ', \ tendid, ',', tiniid, ' !!' print ' data interval [',otim[0], otim[dimt-1],']' quit(-1) dimt = tendid - tiniid + 1 else: dimt = otim.shape[0] valsv = np.zeros((2,dimt), dtype=np.float) # Checking for time consistency if otim.getncattr('units') != tunits: print warnmsg print ' ' + fname + ': different time units in the plot!!' newtimes = gen.coincident_CFtimes(otim[:], tunits, otim.getncattr('units')) else: newtimes = otim[:] if tini == -1: valsv[1,:] = newtimes[:] valsv[0,:] = ovar[:] else: valsv[1,:] = newtimes[tiniid:tendid+1] valsv[0,:] = ovar[tiniid:tendid+1] vartimetrjv.append(valsv) trjobj.close() # Min/max values in plot line_nx = [] if sminmaxv.split(',')[0][0:1] != 'S': line_nx.append(np.float(sminmaxv.split(',')[0])) else: line_nx.append(sminmaxv.split(',')[0]) if sminmaxv.split(',')[1][0:1] != 'S': line_nx.append(np.float(sminmaxv.split(',')[1])) else: line_nx.append(sminmaxv.split(',')[1]) locleg, fsizeleg = drw.legend_values(legvals, '|') collines = gen.str_list(colorlines, ',') typlines = gen.str_list(typelines, ',') wdthlines = gen.str_list(widthlines, ',') pttype = gen.str_list(pointtype, ',') ptsize = gen.str_list(pointsize, ',') if pointfreq0 == 'all': pointfreq = None else: pointfreq = int(pointfreq0) figname = 'val_trajectories_' + statisticskind drw.plot_TimeSeries(vartimetrjv, line_nx, gunits, tunits, figname, gvarname, \ timetit, tkind, timefmt, title, leglabels, locleg, fsizeleg, gkind, \ collines, typlines, pttype, wdthlines, ptsize, pointfreq, figclose) return def variable_values(values): """ Function to give back values for a given variable values= [varname] name of the variable """ fname = 'variable_values' values = drw.variables_values(values) print fname,'values:',values print fname,'variable_name:',values[0] print fname,'standard_name:',values[1] print fname,'min,max:',str(values[2]) + ',' + str(values[3]) print fname,'long_name:',values[4] print fname,'units:',values[5] print fname,'shad_colors:',values[6] print fname,'all_values:',drw.numVector_String(values,',') return def draw_ptZvals(ncfile, values, variable): """ Function to plot a given list of points by their Z values according to a colorbar ncfile= netCDF file to use values= [fvname]:[XYvar]:[dimxyfmt]:[pointype]:[pointsize]:[graphlimits]:[nxtype]: [legend]:[figuretitle]:[cbarv]:[mapvalue]:[kindfig]:[figclose] [fvname]: name of the variable in the graph [XYvar]: [x],[y] variable names [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis ('auto', for 'pretty' at both axes) [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals 2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [ptype]: type of the point [ptsize]: size of the point [graphlimits]: minX,minY,maxX,maxY limits of the graph 'None' for the full size [nxtype]: minimum and maximum type 'auto': values taken from the extrems of the data [min],[max]: given minimum and maximum values [legend]: kind of legend 'None': no legend 'ptlabel',[varlabels],[fontsize],[xoffset],[yoffset]: label at the side of the point [varlabels]: variable in file with the labels for the points [fontsize]: font-size of the label [xoffset]: x-offset of the label respect the point in pixels [yoffset]: y-offset of the label respect the point in pixels 'legend',[varlabels],[location],[fontsize]: standard legend [varlabels]: variable in file with the labels for the points [location]: location of the legend ('0', for automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: size of the font for the legend ('auto' for 12) [figtitle]: title of the figure ('!' for spaces) [colorbarv]: list with the parameters of the color bar [colorbar, cbarfmt, cbaror] colorbar= name of the color bar to use cbarfmt= format of the numbers in the colorbar ('auto' for %6g) cbaror= orientation of the colorbar ('auto' for vertical) [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert-conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [kfig]: kind of figure [closefig]: boolean value whether figure should be close (finish) or not variable= name of the variable to plot """ fname = 'draw_ptZvals' import numpy.ma as ma if values == 'h': print fname + '_____________________________________________________________' print draw_ptZvals.__doc__ quit() expectargs = '[fvname]:[XYvar]:[dimxyfmt]:[pointype]:[pointsize]:[graphlmits]:'+ \ '[nxtype]:[legend]:[figuretit]:[colorbarv]:[mapvalue]:[kindfig]:[closefig]' drw.check_arguments(fname,values,expectargs,':') fvname = values.split(':')[0] XYvar = values.split(':')[1] dimxyfmt = values.split(':')[2] pointype = values.split(':')[3] pointsize = np.float(values.split(':')[4]) graphlimits = values.split(':')[5] nxtype = values.split(':')[6] legend = values.split(':')[7] figuretitle = values.split(':')[8].replace('!',' ') colorbarv = values.split(':')[9] mapvalue = values.split(':')[10] kindfig = values.split(':')[11] closefig = gen.Str_Bool(values.split(':')[12]) onc = NetCDFFile(ncfile, 'r') if not onc.variables.has_key(variable): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable '" + \ variable + "' !!" quit(-1) # points xvarn = XYvar.split(',')[0] yvarn = XYvar.split(',')[1] if not onc.variables.has_key(xvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have longitude " + \ "variable '" + xvarn + "' !!" quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have latitude " + \ "variable '" + yvarn + "' !!" quit(-1) oxvar = onc.variables[xvarn] oyvar = onc.variables[yvarn] ovarvar = onc.variables[variable] Lpts = len(oxvar[:].flatten()) pointvalues = ma.masked_array(np.zeros((Lpts,3), dtype=np.float)) pointvalues[:,0] = oxvar[:].flatten() pointvalues[:,1] = oyvar[:].flatten() pointvalues[:,2] = ovarvar[:].flatten() varattrs = ovarvar.ncattrs() if drw.searchInlist(varattrs, 'units'): fvunits = ovarvar.getncattr('units') else: fvunits = drw.variables_values(variable)[5] varattrs = oxvar.ncattrs() if drw.searchInlist(varattrs, 'units'): xvunits = oxvar.getncattr('units') else: xvunits = drw.variables_values(xvarn)[5] varattrs = oyvar.ncattrs() if drw.searchInlist(varattrs, 'units'): yvunits = oxvar.getncattr('units') else: yvunits = drw.variables_values(yvarn)[5] # Axis format xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # legend if legend.find(',') == -1: legvals = ['None'] else: legvals = legend.split(',') if not onc.variables.has_key(legvals[1]): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have labels " + \ "variable '" + legvals[1] + "' !!" quit(-1) ovarleg = onc.variables[legvals[1]] Lchar = ovarleg.shape[1] labs = ncvar.get_str_nc(ovarleg, Lchar) if legvals[0] == 'None': legendv = None elif legvals[0] == 'ptlabel': legendv = [legvals[0]] legendv.append(legvals[2]) legendv.append(np.float(legvals[3])) legendv.append(np.float(legvals[4])) legendv = legendv + labs elif legvals[0] == 'legend': legendv = [legvals[0]] legendv.append(int(legvals[2])) legendv.append(int(legvals[3])) legendv = legendv + labs else: print errormsg print ' ' + fname + ": kind of legend '" + legvals[0] + "' not ready !!" print ' available ones:', ['None', 'ptlabel', 'legend'] quit(-1) # colorbar values colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarv,',') # map value if mapvalue == 'None': mapvalue = None # Graph limits if graphlimits != 'None': graphlts = np.zeros((4), dtype=np.float) for il in range(4): graphlts[il] = np.float(graphlimits.split(',')[il]) pointvalues[:,0] = ma.masked_outside(pointvalues[:,0], graphlts[0], \ graphlts[2]) pointvalues[:,1] = ma.masked_outside(pointvalues[:,1], graphlts[1], \ graphlts[3]) else: graphlts = None drw.plot_ptZvals(fvname, fvunits, xvarn, yvarn, xvunits, yvunits, pointvalues, \ xaxis, yaxis, pointype, pointsize, graphlts, nxtype, figuretitle, [colbarn, \ fmtcolbar, colbaror], legendv, mapvalue, kindfig, closefig) return #draw_ptZvals('OBSnetcdf.nc', 'pracc:lon,lat:o:80:2,42,7,47,:values!of!values:Blues:cyl,l:pdf', 'pr') def draw_vectors(ncfile, values, varns): """ Function to plot wind vectors values= [dimname]|[vardimname]|[value]:[dimxyfmt]:[vecvals]:[windlabs]:[mapvalues]:[gtit]:[kindfig]:[figuren]: [closefig] 'X/Y/Z/T'|[dimname]|[vardimname]|[value]: ',', list for each basic dimension '|' separated of: [dimname]: name of the dimension in the file [vardimname]: name of the variable with the values for the dimension in the file [value]: which value of the given dimension is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]:[end] slice from [beg] to [end] * NOTE, no dim name all the dimension size No value takes all the range of the dimension [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis ('auto', for 'pretty' at both axes) [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals 2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [vecvals]= [frequency],[color],[length] [frequency]: [xfreq]@[yfreq] frequency of values allong each axis ('None', all grid points; 'auto', computed automatically to have 20 vectors along each axis) [color]: color of the vectors 'singlecol'@[colorn]: all the vectors same color ('auto': for 'red') and lengths according to wind's module 'wind'@[colorbar]@[sminv]|[smaxv]: color of the vectors according to wind speed sqrt(u^2+v^2) and given [colorbar] all vectors the same length [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) '3rdvar'@[colorbar]@[varn]@[units]@[sminv]|[smaxv]: color of the vectors according to a 3rd variable (to be added at -v) and given [colorbar] all vectors the same length [colorbar]: name of the colornbar to use [varn]: name of the variable to pick up values [units]: units of the variable [sminv]|[smaxv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [length]: length of the wind vectors ('auto', for 9) [windlabs]= [windname],[windunits] [windname]: name of the wind variable in the graph [windunits]: units of the wind variable in the graph ('None', for the value in the file) [mapvalues]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full gtit= title of the graph ('!', for spaces) kindfig= kind of figure figuren= name of the figure closefig= whether the figure should be closed ncfile= file to use varns= [uwind],[ywind] ',' list of the name of the variables with the u-wind,y-wind component """ fname = 'draw_vectors' if values == 'h': print fname + '_____________________________________________________________' print draw_vectors.__doc__ quit() expectargs = '[X/Y/Z/T]|[dimname]|[vardimname]|[value]:[dimxyfmt]:[vecvals]:' + \ '[windlabs]:[mapvalues]:[gtit]:[kindfig]:[figuren]:[closefig]' drw.check_arguments(fname,values,expectargs,':') dimvals = values.split(':')[0] dimxyfmt = values.split(':')[1] vecvals = values.split(':')[2] windlabels = values.split(':')[3] mapvalues = values.split(':')[4] gtit = values.split(':')[5].replace('!',' ') kindfig = values.split(':')[6] figuren = values.split(':')[7] closefig = gen.Str_Bool(values.split(':')[8]) of = NetCDFFile(ncfile,'r') dims = {} for dimv in dimvals.split(','): dns = dimv.split('|') dims[dns[0]] = [dns[1], dns[2], dns[3]] varNs = [] for dn in dims.keys(): if dn == 'X': varNs.append(dims[dn][1]) dimx = len(of.dimensions[dims[dn][0]]) xaxisvn = dims[dn][1] elif dn == 'Y': varNs.append(dims[dn][1]) dimy = len(of.dimensions[dims[dn][0]]) yaxisvn = dims[dn][1] ivar = 0 for wvar in varns.split(','): if not drw.searchInlist(of.variables.keys(), wvar): print errormsg print ' ' + fname + ": file does not have variable '" + wvar + "' !!" quit(-1) if ivar == 0: varNs.append(wvar) else: varNs.append(wvar) ivar = 0 for varN in varNs: varslice = [] ovarN = of.variables[varN] vard = ovarN.dimensions for vdn in vard: found = False for dd in dims.keys(): if dims[dd][0] == vdn: if dims[dd][2].find('@') != -1: rvals = dims[dd][2].split('@') varslice.append(slice(int(rvals[0]), int(rvals[1]))) elif dims[dd][2] == '-1': varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) else: varslice.append(int(dims[dd][2])) found = True break if not found: varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) if varN == dims['X'][1]: lonvals0 = np.squeeze(ovarN[tuple(varslice)]) xaxisu = ncvar.get_varunits(ovarN) elif varN == dims['Y'][1]: latvals0 = np.squeeze(ovarN[tuple(varslice)]) yaxisu = ncvar.get_varunits(ovarN) elif ivar == 2: uwvals = np.squeeze(np.array(ovarN[tuple(varslice)])) elif ivar == 3: vwvals = np.squeeze(ovarN[tuple(varslice)]) ivar = ivar + 1 # print 'Final shapes:',lonvals0.shape,':',latvals0.shape,':',uwvals.shape,':', # vwvals.shape if len(uwvals.shape) != 2 or len(vwvals.shape) != 2: print errormsg print ' ' + fname + ': wrong size of the wind fields! they must be ' + \ '2-dimensional!' print ' u-winds shape:',uwvals.shape,'dims:',of.variables[varNs[2]] print ' v-winds shape:',vwvals.shape,'dims:',of.variables[varNs[3]] print ' provide more values for their dimensions!!' quit(-1) if len(lonvals0.shape) == 1: lonvals, latvals = np.meshgrid(lonvals0, latvals0) else: lonvals = lonvals0 latvals = latvals0 # Vector values if vecvals.split(',')[0] == 'None': freqv = None else: freqv = vecvals.split(',')[0] colorvals = vecvals.split(',')[1] coln = colorvals.split('@')[0] colv = colorvals.split('@')[1] if coln == 'singlecol': colorv = colv shading_nx = None elif coln == 'wind': colorv = np.sqrt(uwvals**2 + vwvals**2) # Min/Max colorbar shadminmax = colorvals.split('@')[2] shading_nx = shadminmax.split('|') elif coln == '3rdvar': if len(varns.split(',')) != 3: print errormsg print ' ' + fname + ": color of vectors should be according to '" + \ coln + "' but a third varibale is not provided !!" print ' values provided:', varns.split(',') quit(-1) ocolvec = of.variables[varns.split(',')[2]] colorv = ocolvec[:] stdvn, lonvn, unitsvn = drw.var_3desc(ocolvec) colorvals = colorvals + '@' + stdvn + '@' + unitsvn # Min/Max colorbar shadminmax = colorvals.split('@')[4] shading_nx = shadminmax.split('|') else: print errormsg print ' ' + fname + ": color type '" + coln + "' not ready !!" quit(-1) lengthv = vecvals.split(',')[2] # Axis format xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Vector labels windname = windlabels.split(',')[0] windunits = windlabels.split(',')[1] drw.plot_vector(lonvals, latvals, uwvals, vwvals, xaxisvn, yaxisvn, xaxisu, \ yaxisu, freqv, xaxis, yaxis, colorvals, colorv, lengthv, shading_nx, windname, \ windunits, mapvalues, gtit, kindfig, figuren) of.close() return def draw_basins(ncfile, values): """ Function to plot river basins with their discharge vector and basins id (from 'routing.nc' - ORCHIDEE routing output) values= [lonlatbox]:[mapres]:[colorbarvals]:[xtrmbasin]:[mapdraw]:[veclength]:[plotcountry]:[basinidn]: [gtit]:[kindfig]:[figuren] [lonlatbox]= [lonSW],[lonNE],[latSW],[latNE] coordinates of the lon/lat box [mapres]= resolution of the mapping information to lon/lat * 'c': cure * 'l': low * 'i': intermediate * 'h': high * 'f': full [colorbarvals] = [cbarname],[fmtcolorbar],[orientation] [cbarname]: colorbar name for the colors [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto', 'horizontal') [xtrmbasin]= [minbasin],[maxbasin] minimum and maximum basin numbers to define color range [mapdraw]= whether to draw the map (and project the data) or not ('True/False') [plotcountry]= whether country lines should be plotted or not ('True/False') [plotbasinid]= whether id of the basins should be plotted or not ('True/False') [gtit]= title of the graph ('|', for spaces) [kindfig]= kind of figure [figuren]= name of the figure [closefig]= whether figure should be closed or not ncfile= file to use """ fname = 'draw_basins' if values == 'h': print fname + '_____________________________________________________________' print draw_vectors.__doc__ quit() expectargs = '[lonlatbox]:[mapres]:[cbarname]:[xtrmbasin]:[mapdraw]:' + \ '[plotcountry]:[basinidn]:[gtit]:[kindfig]:[figuren]:[closefig]' drw.check_arguments(fname,values,expectargs,':') varn='basins' lonname = 'nav_lon' latname = 'nav_lat' flowname = 'trip' lonlims =[] latlims =[] lonlims.append(np.float(values.split(':')[0].split(',')[0])) lonlims.append(np.float(values.split(':')[0].split(',')[1])) latlims.append(np.float(values.split(':')[0].split(',')[2])) latlims.append(np.float(values.split(':')[0].split(',')[3])) map_res = values.split(':')[1] colorbarvals = values.split(':')[2] vtit = 'basins' minbasin = np.int(values.split(':')[3].split(',')[0]) maxbasin = np.int(values.split(':')[3].split(',')[1]) mapdraw = gen.Str_Bool(values.split(':')[4]) plotcountry = gen.Str_Bool(values.split(':')[5]) plotbasinid = gen.Str_Bool(values.split(':')[6]) gtit = values.split(':')[7].replace('|',' ') kindfig = values.split(':')[8] figuren = values.split(':')[9] closefig = gen.Str_Bool(values.split(':')[10]) ofile = NetCDFFile(ncfile, 'r') obasins = ofile.variables[varn] olon = ofile.variables[lonname] olat = ofile.variables[latname] oflow = ofile.variables[flowname] lons = olon[:] lats = olat[:] lon, lat = drw.lonlat2D(lons, lats) nlon = lonlims[0] xlon = lonlims[1] nlat = latlims[0] xlat = latlims[1] imin, imax, jmin, jmax = gen.ijlonlat(lon, lat, nlon, xlon, nlat, xlat) colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') drw.plot_basins(lon[jmin:jmax,imin:imax], lat[jmin:jmax,imin:imax], \ oflow[jmin:jmax,imin:imax], colbarn+'@basin@-', fmtcolbar, colbaror, \ obasins[jmin:jmax,imin:imax], minbasin, maxbasin, 'outflow', '-', \ 'cyl,'+map_res, plotcountry, plotbasinid, gtit, kindfig, figuren, closefig) ofile.close() return def draw_basinsold(ncfile, values, varns): """ Function to plot wind basins values= [dimname]|[vardimname]|[value]:[vecvals]:[windlabs]:[mapvalues]: [gtit]:[kindfig]:[figuren] 'X/Y/Z/T'|[dimname]|[vardimname]|[value]: ',', list for each basic dimension '|' separated of: [dimname]: name of the dimension in the file [vardimname]: name of the variable with the values for the dimension in the file [value]: which value of the given dimension (-1, all; [ibeg]@[iend], i-range beginning, end) No value takes all the range of the dimension [vecvals]= [frequency],[color],[length] [frequency]: [xfreq]@[yfreq] frequency of values allong each axis ('None', all grid points; 'auto', computed automatically to have 20 vectors along each axis) [color]: [colorbar]@[varn]@[units]: color of the vectors according to a 3rd variable (to be added at -v) and given [colorbar] all vectors the same length [length]: length of the wind vectors ('auto', for 9) [windlabs]= [windname],[windunits] [windname]: name of the wind variable in the graph [windunits]: units of the wind variable in the graph ('None', for the value in the file) [mapvalues]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full gtit= title of the graph ('|', for spaces) kindfig= kind of figure figuren= name of the figure ncfile= file to use varns= [lon],[lat],[outflow],[basinID] ',' list of the name of the variables with the lon,lat, the outflow and the basin ID """ fname = 'draw_basins' if values == 'h': print fname + '_____________________________________________________________' print draw_vectors.__doc__ quit() expectargs = '[X/Y/Z/T]|[dimname]|[vardimname]|[value]:[vecvals]:[windlabs]:' + \ '[mapvalues]:[gtit]:[kindfig]:[figuren]' drw.check_arguments(fname,values,expectargs,':') dimvals = values.split(':')[0] vecvals = values.split(':')[1] windlabels = values.split(':')[2] mapvalues = values.split(':')[3] gtit = values.split(':')[4] kindfig = values.split(':')[5] figuren = values.split(':')[6] of = NetCDFFile(ncfile,'r') dims = {} for dimv in dimvals.split(','): dns = dimv.split('|') dims[dns[0]] = [dns[1], dns[2], dns[3]] varNs = [] for dn in dims.keys(): if dn == 'X': varNs.append(dims[dn][1]) dimx = len(of.dimensions[dims[dn][0]]) elif dn == 'Y': varNs.append(dims[dn][1]) dimy = len(of.dimensions[dims[dn][0]]) ivar = 0 for wvar in varns.split(','): if not drw.searchInlist(of.variables.keys(), wvar): print errormsg print ' ' + fname + ": file does not have variable '" + wvar + "' !!" quit(-1) if ivar == 0: varNs.append(wvar) else: varNs.append(wvar) ivar = 0 for varN in varNs: varslice = [] ovarN = of.variables[varN] vard = ovarN.dimensions for vdn in vard: found = False for dd in dims.keys(): if dims[dd][0] == vdn: if dims[dd][2].find('@') != -1: rvals = dims[dd][2].split('@') varslice.append(slice(int(rvals[0]), int(rvals[1]))) elif dims[dd][2] == '-1': varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) else: varslice.append(int(dims[dd][2])) found = True break if not found: varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) if varN == dims['X'][1]: lonvals0 = np.squeeze(ovarN[tuple(varslice)]) elif varN == dims['Y'][1]: latvals0 = np.squeeze(ovarN[tuple(varslice)]) ivar = ivar + 1 if len(lonvals0.shape) == 1: lonvals, latvals = np.meshgrid(lonvals0, latvals0) else: lonvals = lonvals0 latvals = latvals0 # Vector values if vecvals.split(',')[0] == 'None': freqv = None else: freqv = vecvals.split(',')[0] colorvals = vecvals.split(',')[1] if len(varn.split(',')) != 3: print errormsg print ' ' + fname + ": color of vectors should be according to '" + \ coln + "' but a third varibale is not provided !!" quit(-1) ocolvec = of.variables[varNs[3]] colorv = ocolvec[:] stdvn, lonvn, unitsvn = drw.var_3desc(ocolvec) colorvals = colorvals + '@' + stdvn + '@' + unitsvn lengthv = vecvals.split(',')[2] # Vector labels windname = windlabels.split(',')[0] windunits = windlabels.split(',')[1] # Vector angles oflow = ofile.variables[varNs[2]] angle = (oflow[:] - 1)*np.pi/4 xflow = np.where(oflow[:] < 9, np.float(lengthv)*np.sin(angle), 0.) yflow = np.where(oflow[:] < 9, np.float(lengthv)*np.cos(angle), 0.) drw.plot_basins(lonvals, latvals, xflow, yflow, freqv, colorvals, colorv, \ lengthv, windname, windunits, mapvalues, gtit, kindfig, figuren) of.close() return def draw_river_desc(ncfile, values, riverns): """ Function to plot rivers' description from ORCHIDEE's routing scheme file ('river_desc.nc') values= [dimname]|[vardimname]|[value]:[basinvals]:[upstreamvals]:[mapvalues]: [gtit]:[kindfig]:[legvals]:[figuren]:[closefig] 'X/Y'|[dimname]|[vardimname]|[value]: ',', list for each basic dimension '|' separated of: [dimname]= name of the dimension in the file for 'X' and 'Y' axis [vardimname]: name of the variable with the values for the dimension in the file [value]: which value of the given dimension is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]:[end] slice from [beg] to [end] * NOTE, no dim name all the dimension size No value takes all the range of the dimension [basinsvals]= [colorline] colors for the border line of each basin [basincolor]: ',' list of colors of the line to use to mark the basins contours (single value also possible) [upstreamvals]= [upstreamcolor]: colorbar to use to plot the basins upstream values [mapvalues]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [gtit]= title of the graph ('|', for spaces) [kindfig]= kind of figure (png, ps, pdf) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figuren]= name of the figure [closefig]= whether figure should be closed or not ncfile= file to use riverns= ',' list of the name of the rivers to plot """ import numpy.ma as ma fname = 'draw_river_desc' if values == 'h': print fname + '_____________________________________________________________' print draw_river_desc.__doc__ quit() expectargs = '[X/Y/Z/T]|[dimname]|[vardimname]|[value]:[basinvals]:' + \ '[upstreamvals]:[mapvalues]:[gtit]:[kindfig]:[legloc]:[figuren]:[closefig]' drw.check_arguments(fname,values,expectargs,':') dimvals = values.split(':')[0] basinvals = values.split(':')[1] upstreamvals = values.split(':')[2] mapvals = values.split(':')[3] gtit = values.split(':')[4].replace('|',' ') kindfig = values.split(':')[5] legloc = int(values.split(':')[6]) figuren = values.split(':')[7] closefig = gen.Str_Bool(values.split(':')[8]) basincol = basinvals if basincol.find(',') != 1: basincolor = basincol.split(',') else: basincolor = [basincol] upstreamcolor = upstreamvals of = NetCDFFile(ncfile,'r') dims = {} for dimv in dimvals.split(','): dns = dimv.split('|') dims[dns[0]] = [dns[1], dns[2], dns[3]] varNs = [] for dn in dims.keys(): if dn == 'X': varNs.append(dims[dn][1]) dimx = len(of.dimensions[dims[dn][0]]) elif dn == 'Y': varNs.append(dims[dn][1]) dimy = len(of.dimensions[dims[dn][0]]) if riverns.find(',') != -1: riverns = riverns.split(',') else: riverns = [riverns] rivers = [] riversubbasins = {} riversupstream = {} riversoutflow = {} for rivern in riverns: print rivern # subBasins basinvar = rivern + '_coding' if not drw.searchInlist(of.variables.keys(), basinvar): print errormsg print ' ' + fname + ": file does not have variable '" + basinvar + "' !!" quit(-1) rivers.append(rivern) obasin = of.variables[basinvar] riversubbasins[rivern] = obasin[:] if rivern == riverns[0]: finalmask = obasin[:].mask else: finalmask = finalmask * obasin[:].mask # upstream upstreamvar = rivern + '_upstream' if not drw.searchInlist(of.variables.keys(), upstreamvar): print errormsg print ' ' + fname + ": file does not have variable '" + upstreamvar + "' !!" quit(-1) oupstream = of.variables[upstreamvar] riversupstream[rivern] = oupstream[:] if rivern == riverns[0]: uunits = oupstream.getncattr('units') # River metadata fracvar = rivern + '_frac' if not drw.searchInlist(of.variables.keys(), fracvar): print errormsg print ' ' + fname + ": file does not have variable '" + fracvar + "' !!" quit(-1) ofrac = of.variables[fracvar] riversoutflow[rivern] = [ofrac.getncattr('Longitude_of_outflow_point'), \ ofrac.getncattr('Latitude_of_outflow_point')] ivar = 0 for varN in varNs: varslice = [] ovarN = of.variables[varN] vard = ovarN.dimensions for vdn in vard: found = False for dd in dims.keys(): if dims[dd][0] == vdn: if dims[dd][2].find('@') != -1: rvals = dims[dd][2].split('@') varslice.append(slice(int(rvals[0]), int(rvals[1]))) elif dims[dd][2] == '-1': varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) else: varslice.append(int(dims[dd][2])) found = True break if not found: varslice.append(slice(0,len(of.dimensions[dims[dd][0]]))) if varN == dims['X'][1]: lonvals0 = np.squeeze(ovarN[tuple(varslice)]) elif varN == dims['Y'][1]: latvals0 = np.squeeze(ovarN[tuple(varslice)]) ivar = ivar + 1 if len(lonvals0.shape) == 1: lonvals, latvals = np.meshgrid(lonvals0, latvals0) else: lonvals = lonvals0 latvals = latvals0 # Masking only the lon,lat with rivers malonvals = ma.masked_array(lonvals, mask=finalmask) malatvals = ma.masked_array(latvals, mask=finalmask) if mapvals == 'None': mapvalues = None else: mapvalues = mapvals drw.plot_river_desc(malonvals, malatvals, rivers, riversubbasins, riversupstream, riversoutflow, \ basincolor, upstreamcolor, uunits, mapvalues, gtit, kindfig, legloc, figuren, closefig) of.close() def draw_vertical_levels(ncfile, values, varn): """ plotting distribution of vertical levels draw_vertical_levels(ncfile, values, varn) ncfile= file to use values= [zlogs]:[plogs]:[title]:[graphic_kind]:[legvals]:[closefig] [zlogs]= zlog,dzlog zlog: to use logarithmic scale on the height axis ('true/false') dzlog: to use logarithmic scale on the difference of height between levels axis ('true/false') [plogs]= plog,dplog plog: to use logarithmic scale on the height axis ('true/false') dplog: to use logarithmic scale on the difference of height between levels axis ('true/false') [title]= title of the graph ('!' for spaces) [graphic_kind]= kind of figure (jpg, pdf, png) [legvals]=[locleg]|[fontsize] [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [closefig]= whether figures should be closed or not varn= [varnheight],[varnpres] [varnheight]: name of the variable with the height of the vertical levels 'WRFz': for WRF z-levels (computed as (PH + PHB)/g, from a PHB(0,i,j) = 0) [varnpres]: name of the variable with the pressure of the vertical levels ('None', for no pressure plot) 'WRFp': for WRF p-levels (computed as P + PB, from a PHB(0,i,j) = 0) """ fname = 'draw_vertical_levels' if values == 'h': print fname + '_____________________________________________________________' print draw_vertical_levels.__doc__ quit() expectargs = '[zlogs]:[plogs]:[title]:[graphic_kind]:[legloc]:[closefig]' drw.check_arguments(fname,values,expectargs,':') zlogv = gen.Str_Bool(values.split(':')[0].split(',')[0]) dzlogv = gen.Str_Bool(values.split(':')[0].split(',')[1]) plogv = gen.Str_Bool(values.split(':')[1].split(',')[0]) dplogv = gen.Str_Bool(values.split(':')[1].split(',')[1]) title = values.split(':')[2].replace('!',' ') kindfig = values.split(':')[3] legvals = values.split(':')[4] closefig = gen.Str_Bool(values.split(':')[5]) if varn.find(',') == -1: varnheight = varn varnpres = None pvals = None print warnmsg print ' ' + fname + ': assuming no pressure variable!!' else: varnheight = varn.split(',')[0] varnpres = varn.split(',')[1] if varnpres == 'None': varnpres = None pvals = None if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': file "' + ncfile + '" does not exist !!' quit(-1) objf = NetCDFFile(ncfile, 'r') if varnheight == 'WRFz': if not gen.searchInlist(objf.variables,'PH'): print errormsg print ' ' + fname + ": WRF file '" + ncfile + "' does not have " + \ "variable 'PH' !!" quit(-1) if not gen.searchInlist(objf.variables,'PHB'): print errormsg print ' ' + fname + ": WRF file '" + ncfile + "' does not have " + \ "variable 'PHB' !!" quit(-1) objph = objf.variables['PH'] objphb = objf.variables['PHB'] geop = objph[:] + objphb[:] ijz0 = gen.index_mat(geop[0,], 0.) zvals = geop[0, :, ijz0[0], ijz0[1]] / 9.8 else: if not gen.searchInlist(objf.variables, varnheight): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have height " + \ " variable '" + varnheight + "' !!" quit(-1) objvar = objf.variables[varn] if len(objvar.shape) == 4: print warnmsg print ' ' + fname + ": assuming that height variable '" + varnheight + \ "' with shape: dt,dz,dy,dx. Tacking first time-step" ijz0 = gen.index_mat(objvar[0,0,], 0.) zvals = objvar[0, :, ijz0[0], ijz0[1]] elif len(objvar.shape) == 3: print warnmsg print ' ' + fname + ": assuming that height variable '" + varnheight + \ "' with shape: dz,dy,dx" ijz0 = gen.index_mat(objvar[0,], 0.) zvals = objvar[:, ijz0[0], ijz0[1]] elif len(objvar.shape) == 2: print warnmsg print ' ' + fname + ": assuming that height variable '" + varnheight + \ "' with shape: dz,dyx" ijz0 = gen.index_mat(objvar[0,], 0.) zvals = objvar[:, ijz0[0]] else: zvals = objvar[:] # Pressure if varnpres is not None: if varnpres == 'WRFp': if not gen.searchInlist(objf.variables,'P'): print errormsg print ' ' + fname + ": WRF file '" + ncfile + "' does not have " + \ "variable 'P' !!" quit(-1) if not gen.searchInlist(objf.variables,'PB'): print errormsg print ' ' + fname + ": WRF file '" + ncfile + "' does not have " + \ "variable 'PB' !!" quit(-1) objph = objf.variables['P'] objphb = objf.variables['PB'] pres = objph[:] + objphb[:] pvals = pres[0, :, ijz0[0], ijz0[1]] else: if not gen.searchInlist(objf.variables, varnpres): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have pressure " + \ " variable '" + varnpres + "' !!" quit(-1) objvar = objf.variables[varnpres] if len(objvar.shape) == 4: print warnmsg print ' ' + fname + ": assuming that pressure variable '" + varnpres + \ "' with shape: dt,dz,dy,dx. Tacking first time-step" pvals = objvar[0, :, ijz0[0], ijz0[1]] elif len(objvar.shape) == 3: print warnmsg print ' ' + fname + ": assuming that pressure variable '" + varnpres + \ "' with shape: dz,dy,dx" pvals = objvar[:, ijz0[0], ijz0[1]] elif len(objvar.shape) == 2: print warnmsg print ' ' + fname + ": assuming that pressure variable '" + varnpres + \ "' with shape: dz,dyx" pvals = objvar[:, ijz0[0]] else: pvals = objvar[:] # Legend values legloc, legsize = drw.legend_values(legvals,'|') drw.plot_vertical_lev(zvals, pvals, zlogv, dzlogv, plogv, dplogv, title, kindfig,\ legloc, legsize, closefig) objf.close() return def draw_subbasin(ncfile, values): """ Function to plot subbasin from a given point of its discharge from 'routing.nc' ORCDHIEE file Each river is composed of different subbasins. Grouped up-flow. This function use a different color for the first level of suubbasins, and a different degree of color for the sub-subbasins of the first level It takes output from `subbasin' function from 'nc_var.py' ncfile= file to use produced with nc_var.py#subbasin function values= [subasiname]:[rangecolors]:[mapv]:[basinlinewidth]:[drawsubid]:[gtit]:[figkind]:[legvals]:[figurename]: [drawrivers]:[closefig] [subasiname]= name of the subbasin ('!' for spaces) [rcolor]= '@', list of 'r|g|b' 1-based colors (as much as first level sub-flow). 'None' for automatic [mapv]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [basinlinewidth]= with of the line to draw the basin [drawsubid]= wehther sub-flow ids should be plot or not [graphtit]= title of the graph ('|', for spaces) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figname]= name of the figure [drawrivers]= whether rivers from pythons' data-based have to be added or not [closefig]= whether figures should be closed or not """ fname = 'draw_subbasin' if values == 'h': print fname + '_____________________________________________________________' print draw_subbasin.__doc__ quit() expectargs = '[subasiname]:[rangecolors]:[mapv]:[basinlinewidth]:[drawsubid]:' + \ '[gtit]:[figkind]:[legloc]:[figurename]:[drawrivers]:[closefig]' drw.check_arguments(fname,values,expectargs,':') subbasiname = values.split(':')[0].replace('!',' ') rangecolors = values.split(':')[1] mapv = values.split(':')[2] basinlinewidth = np.float(values.split(':')[3]) drawsubid = gen.Str_Bool(values.split(':')[4]) gtit = values.split(':')[5].replace('!',' ') figkind = values.split(':')[6] legloc = int(values.split(':')[7]) figurename = values.split(':')[8] drawrivers = gen.Str_Bool(values.split(':')[9]) closefig = gen.Str_Bool(values.split(':')[10]) if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': file "' + ncfile + '" does not exist !!' quit(-1) objf = NetCDFFile(ncfile, 'r') searchvars = ['lon', 'lat', 'lonsubflow', 'latsubflow', 'outsubflow'] for searchvar in searchvars: if not gen.searchInlist(objf.variables,searchvar): print errormsg print ' ' + fname + ": WRF file '" + ncfile + "' does not have " + \ "variable '" + searchvar + "' !!" quit(-1) # lon,lat olon = objf.variables['lon'] olat = objf.variables['lat'] lon = olon[:] lat = olat[:] # sub-flow names osubnames = objf.variables['subflow'] subnames = drw.get_str_nc(osubnames, osubnames.shape[1]) # sub-flow lat, lon latlonsub = {} outflowsub = {} osublon = objf.variables['lonsubflow'] osublat = objf.variables['latsubflow'] oNsubflow = objf.variables['Nsubflow'] ooutsubflow = objf.variables['outsubflow'] Nsubflow = oNsubflow[:] isub = 0 for Ssub in subnames: sublatlon = [] suboutflow = [] for igrid in range(Nsubflow[isub]): sublatlon.append([osublat[isub,igrid], osublon[isub,igrid]]) suboutflow.append(ooutsubflow[isub,igrid]) latlonsub[Ssub] = sublatlon outflowsub[Ssub] = suboutflow isub = isub + 1 # colors if rangecolors == 'None': rangecols = None else: cols = rangecolors.split('@') Ncols = len(cols) rangecols = [] for icol in range(Ncols): cval = cols[icol].split('|') rangecols.append([np.float(cval[0]),np.float(cval[1]),np.float(cval[2])]) drw.plot_subbasin(subbasiname, lon, lat, subnames, latlonsub, outflowsub, \ rangecols, mapv, basinlinewidth, drawsubid, gtit, figkind, legloc, figurename, \ drawrivers, closefig) objf.close() return def draw_2lines(ncfiles, values, varnames): """ Fucntion to plot two lines in different axes (x/x2 or y/y2) values= [commonvardim]:[varangeA]:[varangeB]:[varangeaxis]:[axisvals]:[figvarns]:[colors]: [widths]:[styles]:[sizemarks]:[marks]:[graphtitle]:[labelaxis]:[legvals]:[figname]:[figkind]:[close] [commonvardim]: name of the common variable-dimension [varangeA]: ',' separated list of range (min,max) for A values ('None', automatic from 'variable_values.dat'; single 'Extrs' from values extremes) [varangeB]: ',' separated list of range (min,max) for B values ('None', automatic from 'variable_values.dat'; single 'Extrs' from values extremes) [varangeaxis]: ',' separated list of range (min,max) for common axis values ('None', automatic; 'Extrs' from values extremes) [axisvals]: which is the axis to plot the values ('x' or 'y') [figvarns]: ',' separated list of names of the variables in the plot [colors]: ',' list with color names of the lines for the variables ('None', automatic) [widths]: ',' list with widths of the lines for the variables ('None', automatic) [styles]: ',' list with the styles of the lines ('None', automatic) [sizemarks]: ',' list with the size of the markers of the lines ('None', automatic) [marks]: ';' list with the markers of the lines ('None', automatic) [graphtitle]: title of the figure ('!' for spaces) [labelaxis]: label in the figure of the common axis ('!' for spaces) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figname]: name of the figure [figkind]: kind of figure [close]: Whether figure should be finished or not ncfiles= ',' separated list of files to use varnames= ',' separated list of variables names in the files to plot """ fname = 'draw_2lines' if values == 'h': print fname + '_____________________________________________________________' print draw_2lines.__doc__ quit() expectargs = '[commonvardim]:[varangeA]:[varangeB]:' + \ '[varangeaxis]:[axisvals]:[figvarns]:[colors]:[widths]:[styles]:[sizemarks]:' + \ '[marks]:[graphtitle]:[labelaxis]:[lloc]:[figname]:[figkind]:[close]' drw.check_arguments(fname,values,expectargs,':') commonvardim = values.split(':')[0] varangeA0 = values.split(':')[1] varangeB0 = values.split(':')[2] varangeaxis0 = values.split(':')[3] axisvals = values.split(':')[4] figvarns = values.split(':')[5].split(',') colors = gen.str_list(values.split(':')[6],',') widths = gen.str_list_k(values.split(':')[7],',','np.float') styles = gen.str_list(values.split(':')[8],',') sizemarks = gen.str_list_k(values.split(':')[9],',','np.float') marks = gen.str_list(values.split(':')[10],';') graphtitle = values.split(':')[11].replace('!',' ') labelaxis = values.split(':')[12].replace('!',' ') legvals = values.split(':')[13] figname = values.split(':')[14] figkind = values.split(':')[15] close = gen.Str_Bool(values.split(':')[16]) files = ncfiles.split(',') invarns = varnames.split(',') varunits = [] # Values line A if not os.path.isfile(files[0]): print errormsg print ' ' + fname + ": file '" + files[0] + "' does not exist !!" quit(-1) oncA = NetCDFFile(files[0], 'r') if not gen.searchInlist(oncA.variables.keys(), invarns[0]): print errormsg print ' ' + fname + ": A file '" + files[0] + "' does not have variable '" +\ invarns[0] + "' !!" quit(-1) objvA = oncA.variables[invarns[0]] varvalsA = objvA[:] varangeA = np.zeros((2),dtype=np.float) valsA = gen.variables_values(invarns[0]) if gen.searchInlist(objvA.ncattrs(), 'units'): varunits.append(drw.units_lunits(objvA.getncattr('units'))) else: varunits.append(drw.units_lunits(valsA[5])) if varangeA0 == 'None': varangeA = [valsA[2], valsA[3]] elif varangeA0 == 'Extrs': varangeA = [np.min(varvalsA), np.max(varvalsA)] else: for iv in range(2): varangeA[iv] = np.float(varangeA0.split(',')[iv]) if not gen.searchInlist(oncA.variables.keys(), commonvardim): print errormsg print ' ' + fname + ": A file '" + files[0] + "' does not have common " + \ "dimvar '" + commonvardim + "' !!" quit(-1) objvd = oncA.variables[commonvardim] varvalsaxisA = objvd[:] oncA.close() # Values line B if not os.path.isfile(files[1]): print errormsg print ' ' + fname + ": file '" + files[1] + "' does not exist !!" quit(-1) oncB = NetCDFFile(files[1], 'r') if not gen.searchInlist(oncB.variables.keys(), invarns[1]): print errormsg print ' ' + fname + ": B file '" + files[1] + "' does not have variable '" +\ invarns[1] + "' !!" quit(-1) objvB = oncB.variables[invarns[1]] varvalsB = objvB[:] varangeB = np.zeros((2),dtype=np.float) valsB = gen.variables_values(invarns[1]) if gen.searchInlist(objvB.ncattrs(), 'units'): varunits.append(drw.units_lunits(objvB.getncattr('units'))) else: varunits.append(drw.units_lunits(valsB[5])) if varangeB0 == 'None': varangeB = [valsB[2], valsB[3]] elif varangeB0 == 'Extrs': varangeB = [np.min(varvalsB), np.max(varvalsB)] else: for iv in range(2): varangeB[iv] = np.float(varangeB0.split(',')[iv]) # Common vardim if not gen.searchInlist(oncB.variables.keys(), commonvardim): print errormsg print ' ' + fname + ": B file '" + files[1] + "' does not have common " + \ "dimvar '" + commonvardim + "' !!" quit(-1) objvd = oncB.variables[commonvardim] varvalsaxisB = objvd[:] # Range of the axis varangeaxis = np.zeros((2),dtype=np.float) valsVD = gen.variables_values(commonvardim) if gen.searchInlist(objvd.ncattrs(), 'units'): dimvarunits = drw.units_lunits(objvd.getncattr('units')) else: dimvarunits = drw.units_lunits(valsVD[5]) if varangeaxis0 == 'None': varangeaxis = [valsVD[2], valsVD[3]] elif varangeaxis0 == 'Extrs': varangeaxis[0] = np.min([np.min(varvalsaxisA), np.min(varvalsaxisB)]) varangeaxis[1] = np.max([np.max(varvalsaxisA), np.max(varvalsaxisB)]) else: for iv in range(2): varangeaxis[iv] = np.float(varangeaxis0.split(',')[iv]) oncB.close() labelaxis = valsVD[0] + ' (' + dimvarunits + ')' # Lines characteristics colvalues, linekinds, pointkinds, lwidths, psizes = drw.ColorsLinesPointsStyles( \ 2, colors, styles, marks, widths, sizemarks, 'None') # legend lloc, lsize = drw.legend_values(legvals,'|') drw.plot_2lines(varvalsA, varvalsB, varvalsaxisA, varvalsaxisB, varangeA, \ varangeB, varangeaxis, axisvals, figvarns, varunits, colvalues, lwidths, \ linekinds, psizes, pointkinds, graphtitle, labelaxis, lloc, lsize, figname, \ figkind, close) def draw_2lines_time(ncfiles, values, varnames): """ Function to plot two time-lines in different axes (x/x2 or y/y2) values= [timevardim]:[varangeA]:[varangeB]:[timeaxisfmt]:[timeaxis]:[figvarns]:[colors]: [widths]:[styles]:[sizemarks]:[marks]:[graphtitle]:[labelaxis]:[legvals]:[figname]:[figkind]:[close] [timevardim]: name of the common variable-dimension time [varangeA]: ',' separated list of range (min,max) for A values ('None', automatic from 'variables_values'; 'Extrs' from values extremes) [varangeB]: ',' separated list of range (min,max) for B values ('None', automatic from 'variables_values'; 'Extrs' from values extremes) [timeaxisfmt]=[tkind];[tfmt]: format of the ticks for the time axis: [kind]: kind of time to appear in the graph 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [timeaxis]: which is the time axis in the plot ('x' or 'y') [figvarns]: ',' separated list of names of the variables in the plot [colors]: ',' list with color names of the lines for the variables ('None', automatic) [widths]: ',' list with widths of the lines for the variables ('None', automatic) [styles]: ',' list with the styles of the lines ('None', automatic) [sizemarks]: ',' list with the size of the markers of the lines ('None', for 2.,2.) [marks]: ';' list with the markers of the lines ('None', automatic) [graphtitle]: title of the figure ('!' for spaces) [labelaxis]: label in the figure of the common axis ('!' for spaces) [legvals]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [figname]: name of the figure [figkind]: kind of figure [close]: Whether figure should be finished or not ncfiles= ',' separated list of files to use varnames= ',' separated list of variables names in the files to plot """ fname = 'draw_2lines_time' if values == 'h': print fname + '_____________________________________________________________' print draw_2lines_time.__doc__ quit() expectargs = '[timevardim]:[varangeA]:[varangeB]:[timeaxisfmt]:[timeaxis]:' + \ '[figvarns]:[colors]:[widths]:[styles]:[sizemarks]:[marks]:[graphtitle]:' + \ '[labelaxis]:[legvals]:[figname]:[figkind]:[close]' drw.check_arguments(fname,values,expectargs,':') timevardim = values.split(':')[0] varangeA0 = values.split(':')[1] varangeB0 = values.split(':')[2] timeaxisfmt = values.split(':')[3] timeaxis = values.split(':')[4] figvarns = values.split(':')[5].split(',') colors = gen.str_list(values.split(':')[6],',') widths = gen.str_list_k(values.split(':')[7],',','np.float') styles = gen.str_list(values.split(':')[8],',') sizemarks = gen.str_list_k(values.split(':')[9],',','np.float') marks = gen.str_list(values.split(':')[10],';') graphtitle = values.split(':')[11].replace('!',' ') labelaxis = values.split(':')[12].replace('!',' ') legvals = values.split(':')[13] figname = values.split(':')[14] figkind = values.split(':')[15] close = gen.Str_Bool(values.split(':')[16]) files = ncfiles.split(',') invarns = varnames.split(',') varunits = [] # Values line A if not os.path.isfile(files[0]): print errormsg print ' ' + fname + ": file '" + files[0] + "' does not exist !!" quit(-1) oncA = NetCDFFile(files[0], 'r') if not gen.searchInlist(oncA.variables.keys(), invarns[0]): print errormsg print ' ' + fname + ": A file '" + files[0] + "' does not have variable '" +\ invarns[0] + "' !!" quit(-1) if not gen.searchInlist(oncA.variables.keys(), timevardim): print errormsg print ' ' + fname + ": A file '" + files[0] + "' does not have time " + \ "variable '" + timevardim + "' !!" quit(-1) objvA = oncA.variables[invarns[0]] varvalsA = objvA[:] varangeA = np.zeros((2),dtype=np.float) objtA = oncA.variables[timevardim] timevalsA = objtA[:] trangeA = [np.min(timevalsA), np.max(timevalsA)] tunitsA = objtA.getncattr('units') if len(varvalsA.shape) != 1: print errormsg print ' ' + fname + ": variable '" + invarns[0] + "' has wrong shape:", \ varvalsA.shape, 'it must be 1D !!' quit(-1) valsA = gen.variables_values(invarns[0]) if gen.searchInlist(objvA.ncattrs(), 'units'): varunits.append(drw.units_lunits(objvA.getncattr('units'))) else: varunits.append(drw.units_lunits(valsA[5])) if varangeA0 == 'None': varangeA = [valsA[2], valsA[3]] elif varangeA0 == 'Extrs': varangeA = [np.min(varvalsA), np.max(varvalsA)] else: for iv in range(2): varangeA[iv] = np.float(varangeA0.split(',')[iv]) oncA.close() # Values line B if not os.path.isfile(files[1]): print errormsg print ' ' + fname + ": file '" + files[1] + "' does not exist !!" quit(-1) oncB = NetCDFFile(files[1], 'r') if not gen.searchInlist(oncB.variables.keys(), invarns[1]): print errormsg print ' ' + fname + ": B file '" + files[1] + "' does not have variable '" +\ invarns[1] + "' !!" quit(-1) if not gen.searchInlist(oncB.variables.keys(), timevardim): print errormsg print ' ' + fname + ": B file '" + files[1] + "' does not have time " + \ "variable '" + timevardim + "' !!" quit(-1) objvB = oncB.variables[invarns[1]] varvalsB = objvB[:] varangeB = np.zeros((2),dtype=np.float) objtB = oncB.variables[timevardim] timevalsB = objtB[:] tunitsB = objtB.getncattr('units') valsB = gen.variables_values(invarns[1]) if gen.searchInlist(objvB.ncattrs(), 'units'): varunits.append(drw.units_lunits(objvB.getncattr('units'))) else: varunits.append(drw.units_lunits(valsB[5])) if varangeB0 == 'None': varangeB = [valsB[2], valsB[3]] elif varangeB0 == 'Extrs': varangeB = [np.min(varvalsB), np.max(varvalsB)] else: for iv in range(2): varangeB[iv] = np.float(varangeB0.split(',')[iv]) oncB.close() # Time axis taking time units in line A as reference varvalsaxisB = gen.coincident_CFtimes(timevalsB, tunitsA, tunitsB) trangeB = [np.min(varvalsaxisB), np.max(varvalsaxisB)] varangeaxis = [np.min([trangeA[0],trangeB[0]]), np.max([trangeA[1],trangeB[1]])] timevals = np.arange(varangeaxis[0],varangeaxis[1]) tkind = timeaxisfmt.split(';')[0] tformat = timeaxisfmt.split(';')[1] tpos, tlabels = drw.CFtimes_plot(timevals, tunitsA, tkind, tformat) # Lines characteristics colvalues, linekinds, pointkinds, lwidths, psizes = drw.ColorsLinesPointsStyles( \ 2, colors, styles, marks, widths, sizemarks, 'None') # legend lloc, lsize = drw.legend_values(legvals,'|') drw.plot_2lines_time(varvalsA, varvalsB, timevalsA, varvalsaxisB, varangeA, \ varangeB, tpos, tlabels, timeaxis, figvarns, varunits, colvalues, lwidths, \ linekinds, psizes, pointkinds, graphtitle, labelaxis, lloc, lsize, figname, \ figkind, close) def draw_WindRose(ncfile, values, varnames): """ Function to plot a wind rose (from where the dinw blows) values=[dimvariables][kindRose]:[imgtit]:[imgkind]:[kindlabelsangle]:[freqfileout]:[fname]:[close] [dimvariables]: ';' list of [dimn]|[dvalue] dimension and slice along dimension to retrieve the winds [dimn]: name of the dimension [dvalue]: value for the slice in the given dimension * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg],[end],[freq] slice from [beg] to [end] every [freq] * NOTE, no dim name all the dimension size No value takes all the range of the dimension [kindRose]: [kind];[value1];[...[valueN]] Kind of rose to plot and values of the kind 'fill': filling the area since the center of the rose 'anglespeedfreq': grid of frequencies of each angle and speed following a given discretization values: ;[Nang];[Nspeed];[maxspeed];[cbar];[maxfreq] 'linepoint': consecutive (time, height, level, ...) line-point angle and speed values. Three different species 'multicol': line-marker color changing according to a third variable [extravarn] values: [extravarn];[line];[marker];[colbar];[Nang] 'multicoltime': line-marker color changing according to a temporal variable [extravarn] values: [extravarn];[line];[marker];[colbar];[Nang];[timekind];[timefmt];[timelabel] 'singlecol': same color for the line-marker values: [line];[marker];[col];[Nang] 'scatter': a marker for each wind at different values (time, height, level, ...). Three different species 'multicol':marker color changing according to a third variable [extravarn] values: [extravarn];[marker];[colbar];[Nang] 'multicoltime': marker color changing according to a temporal variable [extravarn] values: [extravarn];[line];[marker];[colbar];[Nang];[timekind];[timefmt];[timelabel] 'singlecol': same color for all the markers values: [marker];[col];[Nang] meaning (where apply): [extravarn]: name of the extra variable [line]: type of the line to draw [marker]: type of marker to use [colbar]: name of the colorbar ('auto' for 'spectral_r') [Nang]: number of angles to divide the rose ('auto' for 8) [Nspeed]: number of speeds to divide the wind speed distribution ('auto' for 8) [maxspeed]: maximum wind speed used to compute the frequency of distributions ('auto' for 40.) [timekind]; time computation of ticks 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [timefmt]; desired format of time labels (C-like) [timelabel]; label of time colorbar at the graph ('!' for spaces) imgtit: title of the image ('!' for spaces) imgkind: kind of output of the image kindlabelsangle: kind of labels for the angles of the wind Rose 'cardianals': Following combinations of 'N', 'E', 'S', 'W' according to Nang freqfileout: whether the file with the frequencies of wind angle and speeds should be created (only working for 'anglespeedfreq') fname: name of the figure close: whether figure should be closed or not ncfile= netCDF file with the winds and extra variable (if required) varnames= [windun],[windvn] variables' name """ fname = 'draw_WindRose' if values == 'h': print fname + '_____________________________________________________________' print draw_WindRose.__doc__ quit() expectargs = '[dimvariables]:[kindRose]:[imgtit]:[imgkind]:[kindlabelsangle]:' + \ '[freqfileout]:[fname]:[close]' drw.check_arguments(fname,values,expectargs,':') dimvariables = values.split(':')[0] KindRose = values.split(':')[1] imgtit = values.split(':')[2].replace('!',' ') imgkind = values.split(':')[3] kindlabelsangle = values.split(':')[4] freqfileout = gen.Str_Bool(values.split(':')[5]) fname = values.split(':')[6] close = gen.Str_Bool(values.split(':')[7]) uvarn = varnames.split(',')[0] vvarn = varnames.split(',')[1] windrosekinds = ['fill', 'linepoint', 'scatter'] if KindRose.find(';') == -1: print errormsg print ' ' + fname + ": all types '" + KindRose + "' require extra values !!" print " 'anglespeedfreq';[Nang];[Nspeed];[maxspeed];[freqcbar];[maxfreq]" print " 'linepoint';'singlecol';[line];[marker];[col];[Nang]" print " 'linepoint';'multiecoltime';[extravar];[line];[marker];[colbar];"+\ "[Nang];[timekind];[timefmt];[timelabel]" print " 'linepoint';'multiecol';[extravar];[line];[marker];[colbar];[Nang]" print " 'scatter';'multiecol';[extravar];[marker];[colbar]" print " 'scatter';'multiecoltime';[extravar];[marker];[colbar];[Nang];" + \ "[timekind];[timefmt];[timelabel]" print " 'scatter';'singlecol';[marker];[col];[Nang]" print " values provided: '" + KindRose + "'" quit(-1) lpvals = KindRose.split(';') lkind = lpvals[1] extravarn = None if lpvals[0] == 'anglespeedfreq': if len(lpvals) != 6: print errormsg print ' ' + fname + ": 'anglespeedfreq' requires 6 values !!" print " 'anglespeedfreq';[Nang];[Nspeed];[maxspeed];[freqcbar];[maxfreq]" print ' provided:', lpvals quit(-1) elif lpvals[0] == 'linepoint': if lkind == 'multicol': if len(lpvals) != 7: print errormsg print ' ' + fname + ": line-point kind '" + lkind + "' requires " + \ "6 values !!" print " 'multiecol';[extravarn];[line];[marker];[colbar];[Nang]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] elif lkind == 'multicoltime': if len(lpvals) != 10: print errormsg print ' '+fname + ": scatter kind '"+lkind+ "' requires 9 values !!" print " 'multicol';[extravarn];[line];[marker];[colbar];[Nang];"+ \ "[timekind];[timefmt];[timelabel]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] timekind = lpvals[6] timefmt = lpvals[7] elif lkind == 'singlecol': if len(lpvals) != 6: print errormsg print ' '+fname+": line-point kind '"+lkind+ "' requires 5 values !!" print " 'singlecol';[line];[marker];[col];[Nang]" print ' provided:', lpvals quit(-1) else: print errormsg print ' ' + fname + ": line-point kind '" + lkind + "' not ready !!" print ' ready ones: multicol, multicoltime, singlecol ' quit(-1) elif lpvals[0] == 'scatter': if lkind == 'multicol': if len(lpvals) != 6: print errormsg print ' '+fname+": scatter kind '"+lkind+"' requires 5 values !!" print " 'multicol';[extravarn];[marker];[colbar];[Nang]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] elif lkind == 'multicoltime': if len(lpvals) != 9: print errormsg print ' ' + fname + ": scatter kind '"+lkind+"' requires 8 values !!" print " 'multicol';[extravarn];[marker];[colbar];[Nang];" + \ "[timekind];[timefmt];[timelabel]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] timekind = lpvals[5] timefmt = lpvals[6] elif lkind == 'singlecol': if len(lpvals) != 5: print errormsg print ' '+fname + ": scatter kind '"+lkind+ "' requires 4 values !!" print " 'singlecol';[marker];[col];[Nang]" print ' provided:', lpvals quit(-1) else: print errormsg print ' ' + fname + ": scatter kind '" + lkind + "' not ready !!" print ' ready ones: multicol, multicoltime, singlecol ' quit(-1) else: print gen.errormsg print ' ' + fname + ": kind of WindRose '" + lpvals[0] + "' not ready !!" print ' available ones:', windrosekinds quit(-1) onc = NetCDFFile(ncfile,'r') oncvars = onc.variables.keys() if not gen.searchInlist(oncvars,uvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable " + \ "u_wind '" + uvarn + "' !!" print ' available variables:', oncvars quit(-1) if not gen.searchInlist(oncvars,vvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable " + \ "v_wind '" + vvarn + "' !!" print ' available variables:', oncvars quit(-1) if extravarn is not None: if not gen.searchInlist(oncvars,extravarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have extra " + \ "variable '" + extravarn + "' !!" print ' available variables:', oncvars quit(-1) # Getting the slice dictslice = {} for dnv in dimvariables.split(';'): dimn = dnv.split('|')[0] dimv = dnv.split('|')[1] if dimv.find(',') != -1: dictslice[dimn] = list(np.array(dimv.split(','), dtype=int)) else: dictslice[dimn] = int(dimv) # Getting variables ou = onc.variables[uvarn] sliceu, du = ncvar.SliceVarDict(ou, dictslice) uv = ou[tuple(sliceu)] ov = onc.variables[vvarn] slicev, dv = ncvar.SliceVarDict(ov, dictslice) vv = ov[tuple(slicev)] wunit = ov.getncattr('units') if extravarn is not None: oe = onc.variables[extravarn] slicee, de = ncvar.SliceVarDict(oe, dictslice) extrav = oe[tuple(slicee)] dime = extrav.shape[0] extraunit = oe.getncattr('units') else: dime = uv.shape[0] extrav = None extraunit = None onc.close() # Wind Rose is with the winds from where they come from! ang = np.arctan2(-vv, -uv) speed = np.sqrt(uv*uv + vv*vv) # re-setting to [0, 2pi] ang = np.where(ang <= 0., 2.*np.pi+ang, ang) ang = np.where(np.mod(ang,2.*np.pi) == 0., 0., ang) drw.plot_WindRose(ang, speed, dime, lpvals, kindlabelsangle, wunit, imgtit, \ imgkind, fname, close, ncfile, outputfile=freqfileout, ev=extrav, \ eunit=extraunit) return def draw_Taylor(ncfile, values, varname): """ Function to draw a Taylor diagram (Taylor 2001) From script: # Copyright: This document has been placed in the public domain. Taylor diagram (Taylor, 2001) test implementation. https://gist.github.com/ycopin/3342888 __version__ = "Time-stamp: <2012-02-17 20:59:35 ycopin>" __author__ = "Yannick Copin " ncfile= ',' list of netCDF file and vartiable to use ([ncfile1]@[var1], [...[nmcvileN]@[varN]]) values=[reflabel]:[mark]:[col]:[size]:[labels]:[[kindlabels]:[taylorkind]:[imgtit]:[figkind]:[outputfile]:[close] [reflabel]: label of the reference values in the graph [mark]: ',' list of kind of markers (single value for the same for all values) [col]: ',' list of color of markers (single value for the same for all values) [size]: ',' list of sizes of markers (single value for the same for all values) [labels]: ',' list of label of markers ('None' for without) [kindlabels]: kind of labels in plot 'markfollow': on top of the mark of each pair of stddev, corr 'legend',[loc],[charsize]: as a traditional legend and [loc] position [charsize] (size of labels, 'auto' for 12) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [taylorkind]: kind of Taylor plot 'direct': direct values 'norm': normalized to the stdandard deviation of reference [imgtit]: title of the image ('!' for spaces) [figkind]: kind of the figure [outputfile]: Whether is required to create a netcdf file with the information used in the Taylor diagram [close]: whether the figure has to be closed varname= [refncfile],[refvn] name of the reference faile and name of the variables within to use as reference """ from scipy import stats as sts fname = 'draw_Taylor' if values == 'h': print fname + '_____________________________________________________________' print draw_Taylor.__doc__ quit() expectargs = '[reflabel]:[mark]:[size]:[col]:[labels]:[kindlabels]:' + \ '[taylorkind]:[imgtit]:[figkind]:[outputfile]:[close]' drw.check_arguments(fname,values,expectargs,':') reflabel = values.split(':')[0] mark = values.split(':')[1] col = values.split(':')[2] size = values.split(':')[3] labels = values.split(':')[4] kindlabels = values.split(':')[5] taylorkind = values.split(':')[6] imgtit = values.split(':')[7].replace('!', ' ') figkind = values.split(':')[8] outputfile = gen.Str_Bool(values.split(':')[9]) close = gen.Str_Bool(values.split(':')[10]) # Reference parameters refncfile = varname.split(',')[0] refvn = varname.split(',')[1] # Marker types if mark.find(',') != -1: marktyp = mark.split(',') else: marktyp = [mark] # Marker sizes if size.find(',') != -1: marksize = size.split(',') else: marksize = [size] # Marker Colors if col.find(',') != -1: markcol = col.split(',') else: markcol = [col] # Marker Labels if labels != 'None': marklabs = [reflabel] + labels.split(',') else: marklabs = None # Getting reference values if not os.path.isfile(refncfile): print errormsg print ' ' + fname + ": reference file '" + refncfile + "' does not exist !!" quit(-1) # List of used files usedfilens = [] # List of used variables usedvarns = [] usedfilens.append(refncfile) usedvarns.append(refvn) oref = NetCDFFile(refncfile, 'r') refvars = oref.variables.keys() if not gen.searchInlist(refvars, refvn): print errormsg print ' ' + fname + ": reference file '" + refncfile + "' does not have " + \ "variable '" + refvn + "' !!" quit(-1) orefv = oref.variables[refvn] refvals = orefv[:] varunits = orefv.units oref.close() # Statistics values filevars = ncfile.split(',') Nfiles = len(filevars) meanvalues = [] stdvalues = [] corrvalues = [] corrpvalues = [] biasvalues = [] maevalues = [] rmsevalues = [] meanref = refvals.mean() stdref = refvals.std() if taylorkind == 'norm': print ' ' + fname + ': normalizing diagram' stdvalues.append(1.) else: stdvalues.append(stdref) meanvalues.append(meanref) corrvalues.append(1.) corrpvalues.append(1.) biasvalues.append(0.) maevalues.append(0.) rmsevalues.append(0.) print ' ' + fname + ': File statistics _______' for filevar in filevars: filen = filevar.split('@')[0] varn = filevar.split('@')[1] if not os.path.isfile(refncfile): print errormsg print ' ' + fname + ": file '" + filen + "' does not exist !!" quit(-1) ovalf = NetCDFFile(filen, 'r') valvars = ovalf.variables.keys() if not gen.searchInlist(valvars, varn): print errormsg print ' ' + fname + ": file '" + filen + "' does not have variable '" + \ varn + "' !!" quit(-1) oval = ovalf.variables[varn] vals = oval[:] ovalf.close() usedfilens.append(filen) usedvarns.append(varn) gen.same_shape(refvals,vals) if taylorkind == 'norm': valstdv = vals.std()/stdref else: valstdv = vals.std() corrv, corrp = sts.pearsonr(refvals, vals) diff = vals - refvals meanvalues.append(vals.mean()) stdvalues.append(valstdv) corrvalues.append(corrv) corrpvalues.append(corrp) biasvalues.append(diff.mean()) maevalues.append(np.abs(diff).mean()) rmsevalues.append(diff.std()) print ' ', filen, 'val bias:', diff.mean(), 'std:', valstdv, 'corr:', \ corrv, 'rmse:', diff.std() drw.plot_Taylor(stdvalues, corrvalues, corrpvalues, varunits, marktyp, marksize, \ markcol, marklabs, kindlabels, taylorkind, imgtit, figkind, close) if outputfile: ofilen = 'Taylor.nc' print ' ' + fname + ": creation of oputput file '" + ofilen + "' " outnc = NetCDFFile(ofilen, 'w') # create dimensions newdim = outnc.createDimension('file',Nfiles) newdim = outnc.createDimension('Lstring',256) # create variable-dimension newvar = outnc.createVariable('file', 'c', ('file','Lstring')) ncvar.writing_str_nc(newvar,usedfilens[1:-1],256) ncvar.basicvardef(newvar,'used_files','files used in Taylor plot','-') # Variables newvar = outnc.createVariable('refvar', 'c', ('Lstring')) ncvar.writing_1str_nc(newvar, 'refvarn', 256) ncvar.basicvardef(newvar,'refvar','reference variable', varunits) ncvar.set_attributek(newvar,'file',refncfile,'S') ncvar.set_attributek(newvar,'mean',meanref,'R') ncvar.set_attributek(newvar,'standard_deviation',stdref,'R') newvar = outnc.createVariable('varn', 'c', ('file','Lstring')) ncvar.writing_str_nc(newvar,usedvarns[1:-1],256) ncvar.basicvardef(newvar,'used_variables','variables used in Taylor plot','-') newvar = outnc.createVariable('stddev','f4',('file')) newvar[:] = stdvalues[1:Nfiles+1] ncvar.basicvardef(newvar,'standard_deviation','standard deviation',varunits) newvar = outnc.createVariable('corr','f4',('file')) newvar[:] = corrvalues[1:Nfiles+1] ncvar.basicvardef(newvar,'correlation','correlation with reference values', \ '-') newvar = outnc.createVariable('corrp','f4',('file')) newvar[:] = corrpvalues[1:Nfiles+1] ncvar.basicvardef(newvar,'p_value_correlations','p-value of the correlation'+\ ' with reference values', '-') newvar = outnc.createVariable('mean','f4',('file')) newvar[:] = meanvalues[1:Nfiles+1] ncvar.basicvardef(newvar,'mean','mean of values', varunits) newvar = outnc.createVariable('bias','f4',('file')) newvar[:] = biasvalues[1:Nfiles+1] ncvar.basicvardef(newvar,'bias','bias with reference values',varunits) newvar = outnc.createVariable('mae','f4',('file')) newvar[:] = maevalues[1:Nfiles+1] ncvar.basicvardef(newvar,'mae','Mean Absolute Error with reference values',varunits) newvar = outnc.createVariable('rmse','f4',('file')) newvar[:] = rmsevalues[1:Nfiles+1] ncvar.basicvardef(newvar,'rmse','Root Mean Square Error with reference values',varunits) # Global values outnc.setncattr('original_source_script', 'test_taylor_4panel.py') outnc.setncattr('authors_source_script', 'Yannick Copin') outnc.setncattr('url_source_script', 'http://www-pcmdi.llnl.gov/about/' + \ 'staff/Taylor/CV/Taylor_diagram_primer.htm') ncvar.add_global_PyNCplot(outnc, 'drawing.py', fname, '1.0') outnc.sync() outnc.close() print fname + ": succesful writting of file '" + ofilen + "' !!" return def draw_2D_shad_2cont(ncfile, values, varn): """ plotting three fields, one with shading and the other two with contour lines draw_2D_shad_2cont(ncfile, values, varn) ncfile= [ncfilevars],[ncfilevarc1],[ncfilevarc2] files to use (one value, same file) values=[vnamefs],[vnamefc1],[vnamefc2]:[dimvals]:[dimvalc1]:[dimvalc2]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]: [ckind1]:[clabfmt1]:[ckind2]:[clabfmt2]:[sminv],[smaxv]:[sminc1],[smaxc1],[Nlev1]:[sminc2],[smaxc2],[Nlev2]: [figt]:[kindfig]:[reverse]:[mapv]:[close] [vnamefs],[vnamefc1],[vnamefc2]: Name in the figure of the shaded and the contour variable1 and contour variable2 [dimvals/c1/c2]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: names of the variables with the values of the dimensions for the plot [dimxyfmt]=[dxf],[Ndx],[dyf],[Ndy]: format of the values at each axis [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [ckind1/2]: kind of contours for variable 1 andf variable 2 'cmap': as it gets from colorbar 'fixc,[colname]': fixed color [colname], all stright lines 'fixsigc,[colname]': fixed color [colname], >0 stright, <0 dashed line [clabfmt1/2]: format of the labels in the contour 1 and 2 (C-like, 'None', also possible) [smin/axv]: minimum and maximum value for the shading or 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [sminc1/2]:[smaxv1/2]:[Nlev1/2]: minimum, maximum and number of values for the contour 1 and 2 [figt]: title of the figure ('|' for spaces) [kindfig]: kind of figure [reverse]: does the values be transposed? 'True/False', [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lamvbert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not varn= [varsn],[varcn1],[varcn2] name of the variable to plot with shading variable with contour 1 and contour 2 """ fname = 'draw_2D_shad_2cont' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_2cont.__doc__ quit() expectargs = '[vnamefs],[vnamefc1],[vnamefc2]:[dimvals]:[dimvalc1]:[dimvalc2]:'+ \ '[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[ckind1]:[clabfmt1]:[ckind2]:' + \ '[clabfmt2]:[sminv],[smaxv]:[sminc1],[smaxc1],[Nlev1]:[sminc2],[smaxc2],' + \ '[Nlev2]:[figt]:[kindfig]:[reverse]:[mapv]:[close]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0].split(',') dimvals= values.split(':')[1].replace('|',':') dimvalc1= values.split(':')[2].replace('|',':') dimvalc2= values.split(':')[3].replace('|',':') vdimxn = values.split(':')[4] vdimyn = values.split(':')[5] dimxyf = values.split(':')[6] colorbarvals = values.split(':')[7] countkind1 = values.split(':')[8] countlabelfmt1 = values.split(':')[9] countkind2 = values.split(':')[10] countlabelfmt2 = values.split(':')[11] shadminmax = values.split(':')[12].split(',') contlevels1 = values.split(':')[13] contlevels2 = values.split(':')[14] figtitle = values.split(':')[15].replace('|',' ') figkind = values.split(':')[16] revals = values.split(':')[17] mapvalue = values.split(':')[18] close = gen.Str_Bool(values.split(':')[19]) if2filenames = ncfile.find(',') if if2filenames != -1: ncfiles = ncfile.split(',')[0] ncfilec1 = ncfile.split(',')[1] ncfilec2 = ncfile.split(',')[2] else: ncfiles = ncfile ncfilec1 = ncfile ncfilec2 = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) if not os.path.isfile(ncfilec1): print errormsg print ' ' + fname + ': contour file 1 "' + ncfilec1 + '" does not exist !!' quit(-1) if not os.path.isfile(ncfilec2): print errormsg print ' ' + fname + ': contour file 2 "' + ncfilec2 + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') objcf1 = NetCDFFile(ncfilec1, 'r') objcf2 = NetCDFFile(ncfilec2, 'r') VarNs = varn.split(',') if len(VarNs) != 3: print errormsg print ' ' + fname + ': 3 variables are required and there are:', len(VarNs),\ 'with names:', VarNs, '!!' print ' excpected vames for:', ['[varshad]', '[varcont1]', '[varcont2]'] quit(-1) varns = varn.split(',')[0] varnc1 = varn.split(',')[1] varnc2 = varn.split(',')[2] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' quit(-1) if not objcf1.variables.has_key(varnc1): print errormsg print ' ' + fname + ': contour file 1 "' + ncfilec1 + \ '" does not have variable "' + varnc1 + '" !!' quit(-1) if not objcf2.variables.has_key(varnc2): print errormsg print ' ' + fname + ': contour file 2 "' + ncfilec2 + \ '" does not have variable "' + varnc2 + '" !!' quit(-1) # Variables' values objvars = objsf.variables[varns] objvarc1 = objcf1.variables[varnc1] objvarc2 = objcf2.variables[varnc2] print dimvals.replace('|',':').replace(',','|') valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace('|',':').replace(',','|')) valcont1, dimscont1 = drw.slice_variable(objvarc1, dimvalc1.replace('|',':').replace(',','|')) valcont2, dimscont2 = drw.slice_variable(objvarc2, dimvalc2.replace('|',':').replace(',','|')) # Checking consistency of matrices gen.same_shape(valshad, valcont1) gen.same_shape(valshad, valcont2) dimnamesv = [vdimxn, vdimyn] varunits = [] varunits.append(objvars.getncattr('units')) varunits.append(objvarc1.getncattr('units')) varunits.append(objvarc2.getncattr('units')) if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] odimxu = objdimx.getncattr('units') odimyu = objdimy.getncattr('units') # Getting only that dimensions with coincident names odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) # Contour formats if countlabelfmt1 == 'None': countlfmt1 = None else: countlfmt1 = countlabelfmt1 if countlabelfmt2 == 'None': countlfmt2 = None else: countlfmt2 = countlabelfmt2 # Shading limits shading_nx = drw.graphic_range(shadminmax,valshad) # Contour limits c1levmin = np.float(contlevels1.split(',')[0]) c1levmax = np.float(contlevels1.split(',')[1]) Nc1levels = int(contlevels1.split(',')[2]) c2levmin = np.float(contlevels2.split(',')[0]) c2levmax = np.float(contlevels2.split(',')[1]) Nc2levels = int(contlevels2.split(',')[2]) levels_cont1 = gen.pretty_int(c1levmin, c1levmax, Nc1levels) levels_cont2 = gen.pretty_int(c2levmin, c2levmax, Nc2levels) # Checking range of contours if c1levmin > np.min(valcont1) or c1levmax < np.max(valcont1): print warnmsg print ' ' + fname + " variable '" + varnc1 + "' range contour 1:", \ np.min(valcont1), ',', np.max(valcont1), 'beyond provided range:', \ c1levmin, ',', c1levmax if c2levmin > np.min(valcont2) or c2levmax < np.max(valcont2): print warnmsg print ' ' + fname + " variable '" + varnc2 + "' range contour 2:", \ np.min(valcont2), ',', np.max(valcont2), 'beyond provided range:', \ c2levmin, ',', c2levmax if len(levels_cont1) <= 1: print warnmsg print ' ' + fname + ': wrong contour 1 levels:', levels_cont1, ' !!' del(levels_cont1) levels_cont1 = np.zeros((Nclevels1), dtype=np.float) levels_cont1 = np.arange(7)*(clevmax1 - clevmin1)/(Nclevels1-1) print ' generating default ones: ',levels_cont1 if len(levels_cont2) <= 1: print warnmsg print ' ' + fname + ': wrong contour 2 levels:', levels_cont2, ' !!' del(levels_cont2) levels_cont2 = np.zeros((Nclevels2), dtype=np.float) levels_cont2 = np.arange(7)*(clevmax2 - clevmin2)/(Nclevels2-1) print ' generating default ones: ',levels_cont2 if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2D_shadow_2contour(valshad, valcont1, valcont2, vnamesfig, odimxv, \ odimyv, odimxu, odimyu, xaxis, yaxis, dimnamesv, [colbarn,fmtcolbar,colbaror], \ countkind1, countlfmt1, countkind2, countlfmt2, shading_nx, levels_cont1, \ levels_cont2, varunits, figtitle, figkind, revals, mapvalue, close) return def draw_bar(ncfile, values): """ Function to plot a bar char figure with multiple sources ncfile = '#' list of [filen];[dimslice];[xvarn];[yvarn] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [xvarn]: name of the variable to use for the x-positions [yvarn]: name of the variable to use for the values values = [dimxyfmt]:[xaxislab]:[yaxislab]:[xunits]:[yunits]:[aval]:[labels]:[colors]:[wdth]:[graphtit]: [legvalues]:[kindfig]:[fign]:[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [xaxislab]: Label for the x-axis ('!' for spaces) [yaxislab]: Label for the y-axis ('!' for spaces) [xunits]: units of the x-label ('None' for no units) [yunits]: units of the y-label [aval]: which acis should be used for the values ('x' or 'y') [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [colors]: ',' list of colors (single value same color, 'auto' automatic) [wdth]: width of the bars [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_bar' if values == 'h': print fname + '____________________________________________________________' print draw_bar.__doc__ quit() expectargs = '[dimxyfmt]:[xaxislab]:[yaxislab]:[aval]:[xunits]:[yunits]:' + \ '[labels]:[colors]:[wdth]:[graphtit]:[legvalues]:[kindfig]:[fign]:[close]' drw.check_arguments(fname,values,expectargs,':') dimxyfmt = values.split(':')[0] xaxislab = values.split(':')[1].replace('!',' ') yaxislab = values.split(':')[2].replace('!',' ') aval = values.split(':')[3] xunits = values.split(':')[4] yunits = values.split(':')[5] labels = gen.str_list(values.split(':')[6].replace('!', ' '), ',') colors = gen.str_list(values.split(':')[7], ',') wdth = np.float(values.split(':')[8]) graphtit = values.split(':')[9].replace('!',' ') legvalues = values.split(':')[10] kindfig = values.split(':')[11] fign = values.split(':')[12] close = gen.Str_Bool(values.split(':')[13]) # files and values filedvs = ncfile.split('#') xvals = [] yvals = [] for fdv in filedvs: filen = fdv.split(';')[0] dimrange = fdv.split(';')[1] xvarn = fdv.split(';')[2] yvarn = fdv.split(';')[3] if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(xvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ xvarn + "' for the x-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) oxvar = onc.variables[xvarn] oyvar = onc.variables[yvarn] xvs, xdims = ncvar.slice_variable(oxvar, dimrange.replace(',',':')) yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) if len(xvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ xvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', xvs.shape, 'dimensions:', xdims, 'fix it!!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ yvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', yvs.shape, 'dimensions:', ydims, 'fix it!!' quit(-1) xvals.append(list(xvs)) yvals.append(list(yvs)) onc.close() xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Legend legloc, legsiz = drw.legend_values(legvalues,'|') # units if xunits == 'None': dxu = None else: dxu = xunits dyu = yunits drw.plot_bars(xvals, yvals, xaxis, yaxis, dxu, dyu, aval, xaxislab, yaxislab, \ labels, colors, wdth, graphtit, legloc, legsiz, kindfig, fign, close) return def draw_bar_time(ncfile, values): """ Function to plot a bar char figure with multiple sources and time-axis ncfile = '#' list of [filen];[dimslice];[tvarn];[yvarn] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [tvarn]: name of the variable time [yvarn]: name of the variable to use for the values values = [dimxyfmt];[yaxislab];[yunits];[aval];[rangevals];[timevals]; [labels];[colors];[wdth];[graphtit];[legvalues];[kindfig];[fign];[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [yaxislab]: Label for the y-axis ('!' for spaces) [yunits]: units of the y-label [aval]: which acis should be used for the values ('x' or 'y') [rangevals]: Range of the axis with the values (single 'None' for 'auto','auto') [vmin],[vmax]: minimum and maximum values 'auto': the computed minimumm or maximum of the values [timevals]: [timen]|[units]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [colors]: ',' list of colors (single value same color, 'auto' automatic) [wdth]: width of the bars [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_bar_time' if values == 'h': print fname + '____________________________________________________________' print draw_bar_time.__doc__ quit() expectargs = '[dimxyfmt];[yaxislab];[yunits];[aval];[rangevals];[timevals];' + \ '[labels];[colors];[wdth];[graphtit];[legvalues];[kindfig];[fign];[close]' drw.check_arguments(fname,values,expectargs,';') dimxyfmt = values.split(';')[0] yaxislab = values.split(';')[1].replace('!',' ') yunits = values.split(';')[2] aval = values.split(';')[3] rangevals = values.split(';')[4] timevals = values.split(';')[5] labels = gen.str_list(values.split(';')[6].replace('!', ' '), ',') colors = gen.str_list(values.split(';')[7], ',') wdth = np.float(values.split(';')[8]) graphtit = values.split(';')[9].replace('!',' ') legvalues = values.split(';')[10] kindfig = values.split(';')[11] fign = values.split(';')[12] close = gen.Str_Bool(values.split(';')[13]) # files and values filedvs = ncfile.split('#') tvals = [] yvals = [] # time-values expectargs = '[timen]|[units]|[kind]|[tfmt]' drw.check_arguments('timevals: '+fname,timevals,expectargs,'|') timen = timevals.split('|')[0].replace('!',' ') timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] for fdv in filedvs: filen = fdv.split(';')[0] dimrange = fdv.split(';')[1] tvarn = fdv.split(';')[2] yvarn = fdv.split(';')[3] if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(tvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ tvarn + "' for the time-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) otvar = onc.variables[tvarn] oyvar = onc.variables[yvarn] tvs, tdims = ncvar.slice_variable(otvar, dimrange.replace(',',':')) yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) tunitsvar = otvar.units if len(tvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ tvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', tvs.shape, 'dimensions:', tdims, 'fix it!!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ yvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', yvs.shape, 'dimensions:', ydims, 'fix it!!' quit(-1) uvd = timeunit tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ '000000' tunitsval = tunitsec[0] # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(tvs, timeunit, tunitsvar) tvals.append(list(reftvals)) yvals.append(list(yvs)) onc.close() # Times mintval = np.min(tvals) maxtval = np.max(tvals) dtvals = (maxtval - mintval)/10 dti = mintval dte = maxtval tvalsticks = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS timepos, timelabels = drw.CFtimes_plot(tvalsticks, timeunit, timekind, timefmt) # ranges valmin = np.min(yvals) valmax = np.max(yvals) if rangevals == 'None': valmin = np.min(yvals) valmax = np.max(yvals) else: if rangevals.split(',')[0] != 'auto': valmin = np.float(rangevals.split(',')[0]) if rangevals.split(',')[1] != 'auto': valmax = np.float(rangevals.split(',')[1]) yrange = [valmin, valmax] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Legend legloc, legsiz = drw.legend_values(legvalues,'|') dyu = yunits drw.plot_bars_time(tvals, yvals, timepos, timelabels, yaxis, dyu, aval, yrange, \ timen, yaxislab, labels, colors, wdth, graphtit, legloc, legsiz, kindfig, fign, \ close) return def draw_bar_line(ncfile, values): """ Function to plot a bar char and lines plot figure with multiple sources ncfile = '#' list of [filen];[dimslice];[xvarn];[yvarn];[kind] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [xvarn]: name of the variable to use for the x-positions [yvarn]: name of the variable to use for the values [kind]: Kind of plotting 'bar': for bar-plot 'line': for line-plot values = [dimxyfmt]:[xaxislab]:[yaxislab]:[xunits]:[yunits]:[aval]:[rangevals]:[labels]: [colors]:[wdth]:[colns]:[lines]:[points]:[lwdths]:[psizes]:[freqv]:[graphtit]:[legvalues]: [kindfig]:[fign]:[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [xaxislab]: Label for the x-axis ('!' for spaces) [yaxislab]: Label for the y-axis ('!' for spaces) [xunits]: units of the x-label ('None' for no units) [yunits]: units of the y-label [aval]: which acis should be used for the values ('x' or 'y') [rangevals]: Range of the axis with the values (single 'None' for 'auto','auto') [vmin],[vmax]: minimum and maximum values 'auto': the computed minimumm or maximum of the values [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [colors]: ',' list of colors (single value same color, 'auto' automatic) [wdth]: width of the bars [colns]= ',' list of color names ('None' for automatic, single value for all the same) [lines]= ',' list of style of lines ('None' for automatic, single value for all the same) [points]= '@' list of style of points ('None' for automatic, single value for all the same) [lwdths]= ',' list of withs of lines ('None' for automatic, single value for all the same) [psizes]= ',' list of size of points ('None' for automatic, single value for all the same) [freqv]= frequency of values ('all' for all values) [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_bar_line' if values == 'h': print fname + '____________________________________________________________' print draw_bar_line.__doc__ quit() expectargs = '[dimxyfmt]:[xaxislab]:[yaxislab]:[aval]:[rangevals]:[xunits]:' + \ '[yunits]:[labels]:[colors]:[wdth]:[colns]:[lines]:[points]:[lwdths]:' + \ '[psizes]:[freqv]:[graphtit]:[legvalues]:[kindfig]:[fign]:' + \ '[close]' drw.check_arguments(fname,values,expectargs,':') dimxyfmt = values.split(':')[0] xaxislab = values.split(':')[1].replace('!',' ') yaxislab = values.split(':')[2].replace('!',' ') aval = values.split(':')[3] rangevals = values.split(':')[4] xunits = values.split(':')[5] yunits = values.split(':')[6] labels = gen.str_list(values.split(':')[7].replace('!', ' '), ',') colors = gen.str_list(values.split(':')[8], ',') wdth = np.float(values.split(':')[9]) colns = gen.str_list(values.split(':')[10], ',') lines = gen.str_list(values.split(':')[11], ',') points = gen.str_list(values.split(':')[12], '@') lwdths = gen.str_list_k(values.split(':')[13], ',', 'R') psizes = gen.str_list_k(values.split(':')[14], ',', 'R') freqv0 = values.split(':')[15] graphtit = values.split(':')[16].replace('!',' ') legvalues = values.split(':')[17] kindfig = values.split(':')[18] fign = values.split(':')[19] close = gen.Str_Bool(values.split(':')[20]) # files and values filedvs = ncfile.split('#') barxvals = [] baryvals = [] linexvals = [] lineyvals = [] namebars = [] namelines = [] valmin = gen.fillValueF valmax = -gen.fillValueF print ' ' + fname + 'plotting _______' il = 0 for fdv in filedvs: filen = fdv.split(';')[0] dimrange = fdv.split(';')[1] xvarn = fdv.split(';')[2] yvarn = fdv.split(';')[3] plotk = fdv.split(';')[4] print ' ', filen, 'with', plotk if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(xvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ xvarn + "' for the x-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) oxvar = onc.variables[xvarn] oyvar = onc.variables[yvarn] xvs, xdims = ncvar.slice_variable(oxvar, dimrange.replace(',',':')) yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) if len(xvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ xvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', xvs.shape, 'dimensions:', xdims, 'fix it!!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ yvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', yvs.shape, 'dimensions:', ydims, 'fix it!!' quit(-1) # Location of each kind if plotk == 'bar': barxvals.append(list(xvs)) baryvals.append(list(yvs)) if labels is not None: namebars.append(labels[il]) elif plotk == 'line': linexvals.append(list(xvs)) lineyvals.append(list(yvs)) if labels is not None: namelines.append(labels[il]) else: print errormsg print ' ' + fname + ": kind of input '" + plotk + "' not ready!!" print ' available ones:', ['bar', 'line'] quit(-1) yvsn = np.min(yvs) yvsx = np.max(yvs) if yvsn < valmin: valmin = yvsn if yvsx > valmax: valmax = yvsx onc.close() il = il + 1 # ranges if rangevals == 'None': valmin = yvsn valmax = yvsx else: if rangevals.split(',')[0] != 'auto': valmin = np.float(rangevals.split(',')[0]) if rangevals.split(',')[1] != 'auto': valmax = np.float(rangevals.split(',')[1]) yrange = [valmin, valmax] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Frequqnecy for lines if freqv0 == 'all': freqv = None else: freqv = int(freqv0) # Legend legloc, legsiz = drw.legend_values(legvalues,'|') # units if xunits == 'None': dxu = None else: dxu = xunits dyu = yunits drw.plot_bars_line(barxvals, baryvals, linexvals, lineyvals, xaxis, yaxis, dxu, \ dyu, aval, yrange, xaxislab, yaxislab, namebars, namelines, colors, wdth, colns,\ lines, points, lwdths, psizes, freqv, graphtit, legloc, legsiz, kindfig, fign, \ close) return def draw_bar_line_time(ncfile, values): """ Function to plot a bar char and lines plot figure with multiple sources and time-axis ncfile = '#' list of [filen];[dimslice];[xvarn];[yvarn];[kind] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [tvarn]: name of the variable time [yvarn]: name of the variable to use for the values [kind]: Kind of plotting 'bar': for bar-plot 'line': for line-plot values = [dimxyfmt];[yaxislab];[yunits];[aval];[rangevals];[timevals];[labels]; [colors];[wdth];[colns];[lines];[points];[lwdths];[psizes];[freqv];[graphtit];[legvalues]; [kindfig];[fign];[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [yaxislab]: Label for the y-axis ('!' for spaces) [yunits]: units of the y-label [aval]: which acis should be used for the values ('x' or 'y') [rangevals]: Range of the axis with the values (single 'None' for 'auto','auto') [vmin],[vmax]: minimum and maximum values 'auto': the computed minimumm or maximum of the values [timevals]: [timen]|[units]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [colors]: ',' list of colors (single value same color, 'auto' automatic) [wdth]: width of the bars [colns]= ',' list of color names ('None' for automatic, single value for all the same) [lines]= ',' list of style of lines ('None' for automatic, single value for all the same) [points]= '@' list of style of points ('None' for automatic, single value for all the same) [lwdths]= ',' list of withs of lines ('None' for automatic, single value for all the same) [psizes]= ',' list of size of points ('None' for automatic, single value for all the same) [freqv]= frequency of values ('all' for all values) [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_bar_line_time' if values == 'h': print fname + '____________________________________________________________' print draw_bar_line_time.__doc__ quit() expectargs = '[dimxyfmt];[yaxislab];[aval];[rangevals];[yunits];' + \ '[timevals];[labels];[colors];[wdth];[colns];[lines];[points];' + \ '[lwdths];[psizes];[freqv];[graphtit];[legvalues];[kindfig];' + \ '[fign];[close]' drw.check_arguments(fname,values,expectargs,';') dimxyfmt = values.split(';')[0] yaxislab = values.split(';')[1].replace('!',' ') aval = values.split(';')[2] rangevals = values.split(';')[3] yunits = values.split(';')[4] timevals = values.split(';')[5] labels = gen.str_list(values.split(';')[6].replace('!', ' '), ',') colors = gen.str_list(values.split(';')[7], ',') wdth = np.float(values.split(';')[8]) colns = gen.str_list(values.split(';')[9], ',') lines = gen.str_list(values.split(';')[10], ',') points = gen.str_list(values.split(';')[11], '@') lwdths = gen.str_list_k(values.split(';')[12], ',', 'R') psizes = gen.str_list_k(values.split(';')[13], ',', 'R') freqv0 = values.split(';')[14] graphtit = values.split(';')[15].replace('!',' ') legvalues = values.split(';')[16] kindfig = values.split(';')[17] fign = values.split(';')[18] close = gen.Str_Bool(values.split(';')[19]) # files and values filedvs = ncfile.split('#') bartvals = [] baryvals = [] linetvals = [] lineyvals = [] namebars = [] namelines = [] # time-values expectargs = '[timen]|[units]|[kind]|[tfmt]' drw.check_arguments('timevals: '+fname,timevals,expectargs,'|') timen = timevals.split('|')[0].replace('!',' ') timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] valmin = gen.fillValueF valmax = -gen.fillValueF print ' ' + fname + 'plotting _______' il = 0 for fdv in filedvs: filen = fdv.split(';')[0] dimrange = fdv.split(';')[1] tvarn = fdv.split(';')[2] yvarn = fdv.split(';')[3] plotk = fdv.split(';')[4] print ' ', filen, 'with', plotk if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(tvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ xvarn + "' for the time-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' + fname + ': file "' + filen + "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) otvar = onc.variables[tvarn] oyvar = onc.variables[yvarn] tvs, tdims = ncvar.slice_variable(otvar, dimrange.replace(',',':')) yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) tunitsvar = otvar.units if len(tvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ tvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', tvs.shape, 'dimensions:', tdims, 'fix it!!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' + fname + ': provided slice:', dimrange, "for variable '" + \ yvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', yvs.shape, 'dimensions:', ydims, 'fix it!!' quit(-1) # time-values uvd = timeunit tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ '000000' tunitsval = tunitsec[0] # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(tvs, timeunit, tunitsvar) # Location of each kind if plotk == 'bar': bartvals.append(list(reftvals)) baryvals.append(list(yvs)) if labels is not None: namebars.append(labels[il]) elif plotk == 'line': linetvals.append(list(reftvals)) lineyvals.append(list(yvs)) if labels is not None: namelines.append(labels[il]) else: print errormsg print ' ' + fname + ": kind of input '" + plotk + "' not ready!!" print ' available ones:', ['bar', 'line'] quit(-1) yvsn = np.min(yvs) yvsx = np.max(yvs) if yvsn < valmin: valmin = yvsn if yvsx > valmax: valmax = yvsx onc.close() il = il + 1 # Times mintval = np.min(bartvals + linetvals) maxtval = np.max(bartvals + linetvals) dtvals = (maxtval - mintval)/10. dti = mintval dte = maxtval tvalsticks = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS timepos, timelabels = drw.CFtimes_plot(tvalsticks, timeunit, timekind, timefmt) # ranges if rangevals == 'None': valmin = valmin valmax = valmax else: if rangevals.split(',')[0] != 'auto': valmin = np.float(rangevals.split(',')[0]) if rangevals.split(',')[1] != 'auto': valmax = np.float(rangevals.split(',')[1]) yrange = [valmin, valmax] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Frequqnecy for lines if freqv0 == 'all': freqv = None else: freqv = int(freqv0) # Legend legloc, legsiz = drw.legend_values(legvalues,'|') # units dyu = yunits drw.plot_bars_line_time(bartvals, baryvals, linetvals, lineyvals, timepos, \ timelabels, yaxis, dyu, aval, yrange, timen, yaxislab, namebars, namelines, \ colors, wdth, colns, lines, points, lwdths, psizes, freqv, graphtit, legloc, \ legsiz, kindfig, fign, close) return def draw_time_lag(ncfile, values): """ Function to plot a time-lag figure with multiple sources (x, previous values; y, future values) ncfile = '#' list of couples ('%' formed) [prefilen];[predslice];[pretvarn];[prevarn]%[futfilen]; [futdslice];[futtvarn];[futvarn] 'pre': values to act as previous values 'fut': values to act as future values [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [tvarn]: name of the variable time [yvarn]: name of the variable to use for the values values = [dimxyfmt];[axeskind];[preaxislab];[preunits];[futaxislab];[futunits];[prerangevals]; [futrangevals];[timevals];[labels];[figlagkind];[graphtit];[legvalues];[kindfig];[fign];[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [axeskind]: type of axes to be plotted 'centered': crossed at 0,0 at the center of the figure 'box': around the figure [preaxislab]: Label for the future-axis ('!' for spaces) [preunits]: units of the future-label [futaxislab]: Label for the future-axis ('!' for spaces) [futunits]: units of the future-label [prerangevals]: Range of the previous axis with the values (single 'None' for 'auto','auto') [val1],[val2]: tacking the provided ',' separated list of desired [val1] and [val2] 'auto': automatically set up range using minv and maxv 'extremescentered': extremes automatically centered on zero by computing from data -absmax, absmax; absmax=max(abs(minval),maxval) 'meancentered': extremes automatically centered on mean by computing from data minv+meanv, maxv-meanv; meanv=(minval + maxval)/2. [futrangevals]: Range of the future axis with the values (single 'None' for 'auto','auto') [val1],[val2]: tacking the provided ',' separated list of desired [val1] and [val2] 'auto': automatically set up range using minv and maxv 'extremescentered': extremes automatically centered on zero by computing from data -absmax, absmax; absmax=max(abs(minval),maxval) 'meancentered': extremes automatically centered on mean by computing from data minv+meanv, maxv-meanv; meanv=(minval + maxval)/2. [timevals]: [timen]|[units]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [figlagkind]=[kindname],[valueskind] kind of time-lag plot 'repeatPeriod',[Nlag],[period],[colorbar],[cbarfmt],[cbaror],[ltype],[lwidth],[mtype],[msize]: time-lag for a given repeating sub-period, Line-conected points following a colorbar and time-values [Nlag]: number of time steps as lag [period]: period to be repeated allover the time-data [colorbar]: name of the color bar to use ('auto' for rainbow) [cbarfmt]: format of the numbers in the colorbar [cbaror]: orientation of the colorbar ('auto' for vertical) [ltype]: type of the lines (single value for the same, or 'auto') [lsize]: width of the lines (single value for the same, or 'auto') [mtype]: type of the markers (single value for the same, or 'auto') [msize]: size of the markers (single value for the same, or 'auto') 'shadTline',[Nlag],[colorbar],[cbarfmt],[cbaror],[ltype],[lwidth],[mtype],[msize]: Line-conected points following a colorbar and time-values [Nlag]: number of time steps as lag [colorbar]: name of the color bar to use ('auto' for rainbow) [cbarfmt]: format of the numbers in the colorbar [cbaror]: orientation of the colorbar ('auto' for vertical) [ltype]: type of the lines (single value for the same, or 'auto') [lsize]: width of the lines (single value for the same, or 'auto') [mtype]: type of the markers (single value for the same, or 'auto') [msize]: size of the markers (single value for the same, or 'auto') 'simplepts',[Nlag],[col],[type],[size]: Simple points assuming that values have all the same times [Nlag]: number of time steps as lag [col]: '@' list of colors of the points (single value for the same, or 'auto') [type]:types of the points (single value for the same, or 'auto') [size]: sizes of the points kind of lag-time figure (single value for the same, or 'auto') labels= list of labels for legend (None for no legend, and 'None' for no specific label) [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_time_lag' if values == 'h': print fname + '____________________________________________________________' print draw_time_lag.__doc__ quit() expectargs = '[dimxyfmt];[axeskind];[preaxislab];[preunits];[futaxislab];' + \ '[futunits];[prerangevals];[futrangevals];[timevals];[labels];[figlagkind];' + \ '[graphtit];[legvalues];[kindfig];[fign];[close]' drw.check_arguments(fname,values,expectargs,';') dimxyfmt = values.split(';')[0] axeskind = values.split(';')[1] preaxislab = values.split(';')[2].replace('!',' ') preunits = values.split(';')[3] futaxislab = values.split(';')[4].replace('!',' ') futunits = values.split(';')[5] prerangevals = values.split(';')[6] futrangevals = values.split(';')[7] timevals = values.split(';')[8] labels = gen.str_list(values.split(';')[9].replace('!', ' '), ',') figlagkind = values.split(';')[10] graphtit = values.split(';')[11].replace('!',' ') legvalues = values.split(';')[12] kindfig = values.split(';')[13] fign = values.split(';')[14] close = gen.Str_Bool(values.split(';')[15]) # files and values filedvs = ncfile.split('#') timevalues = [] prevalues = [] futvalues = [] # time-values expectargs = '[timen]|[units]|[kind]|[tfmt]' drw.check_arguments('timevals: '+fname,timevals,expectargs,'|') timen = timevals.split('|')[0].replace('!',' ') timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] preminval = gen.fillValue premaxval = -gen.fillValue futminval = gen.fillValue futmaxval = -gen.fillValue mintval = gen.fillValue maxtval = -gen.fillValue for fdvprefut in filedvs: prefutdv = fdvprefut.split('%') ifile=0 for fdv in prefutdv: expectargs = '[pre/fut]filen;[pre/fut]dslice;[pre/fut]tvarn;[pre/fut]varn' drw.check_arguments('filevalues: '+fname, fdv, expectargs,';') filen = fdv.split(';')[0] dimrange = fdv.split(';')[1] tvarn = fdv.split(';')[2] yvarn = fdv.split(';')[3] futfdv = fdvprefut.split('%')[1] if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if not onc.variables.has_key(tvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ tvarn + "' for the time-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) if not onc.variables.has_key(yvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) otvar = onc.variables[tvarn] oyvar = onc.variables[yvarn] tvs, tdims = ncvar.slice_variable(otvar, dimrange.replace(',',':')) yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) tunitsvar = otvar.units if len(tvs.shape) != 1: print errormsg print ' ' +fname+ ': provided slice:', dimrange, "for variable '" + \ tvarn + "' does not provide a rank-1 value !!" print ' resultant shape:', tvs.shape, 'dimensions:',tdims,'fix it!!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' +fname+ ': provided slice:', dimrange, "for variable '" + \ yvarn + "' does not provide a rank-1 value !!" print ' resultant shape:',yvs.shape, 'dimensions:',ydims,'fix it!!' quit(-1) uvd = timeunit tunitsec = timeunit.split(' ') if len(tunitsec) == 4: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ tunitsec[3][0:2] + tunitsec[3][3:5] + tunitsec[3][6:8] else: refdate = tunitsec[2][0:4]+tunitsec[2][5:7]+tunitsec[2][8:10] + \ '000000' tunitsval = tunitsec[0] # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(tvs, timeunit, tunitsvar) onc.close() reftn = reftvals.min() reftx = reftvals.max() if reftn < mintval: mintval = reftn if reftx > maxtval: maxtval = reftx if ifile == 0: timevalues.append(reftvals) prevalues.append(yvs) pren = yvs.min() prex = yvs.max() if pren < preminval: preminval = pren if prex > premaxval: premaxval = prex else: timevalues.append(reftvals) futvalues.append(yvs) futn = yvs.min() futx = yvs.max() if futn < futminval: futminval = futn if futx > futmaxval: futmaxval = futx ifile = ifile + 1 # Times if figlagkind[0:12] == 'repeatPeriod': per=int(figlagkind.split(',')[2]) dtvals = (maxtval - mintval)/10/per else: dtvals = (maxtval - mintval)/10 dti = mintval dte = maxtval tvalsticks = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS timepos, timelabels = drw.CFtimes_plot(tvalsticks, timeunit, timekind, timefmt) # ranges prerng = gen.minmax_range(preminval, premaxval, prerangevals) futrng = gen.minmax_range(futminval, futmaxval, futrangevals) xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Legend legloc, legsiz = drw.legend_values(legvalues,'|') drw.plot_time_lag(prevalues, futvalues, timevalues, xaxis, yaxis, axeskind, \ preaxislab, futaxislab, preunits, futunits, prerng, futrng, figlagkind, labels,\ timen, timepos, timelabels, graphtit, legloc, legsiz, kindfig, fign, close) return def draw_ensembles_time(ncfile, values): """ Function to plot an ensembles of data following an axis-time ncfile = '#' list of files [filen];[slice];[tvarn];[varn];[kinddata] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [tvarn]: name of the variable time ('WRFtime', for times from WRF) [varn]: name of the variable to use for the values [kinddata]: which kind of use should be done: 'data': to be plot as data 'ensemble': to be used as a member of the ensemble values = [dimxyfmt];[valaxis];[axislab];[axisunits];[rangevals];[datavals];[timevals];[valskind]; [labels];[figenskind];[graphtit];[legvalues];[kindfig];[fign];[outfile];[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [valaxis]: which axes should be used for the data [axislab]: Label for the values-axis ('!' for spaces) [axisunits]: units of the values-label [rangevals]: Range of the axis with the values (single 'None' for 'auto','auto') [vmin],[vmax]: minimum and maximum values 'auto': the computed minimumm or maximum of the values [datavals]: [color]:[linetype]:[linewidht]:[markertype]:[markersize] values for the data-lines [color]: '@' list of colors of the lines (single value for the same, or 'auto') [linetype]: '@' list of type of the lines (single value for the same, or 'auto') [linewidht]: '@' list of width of the lines (single value for the same, or 'auto') [markertype]: '@' list of type of the markers (single value for the same, or 'auto') [markersize]: '@' list of size of the markers (single value for the same, or 'auto') [timevals]: [timen]|[units]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [valskind]: way to compute the values to be plotted 'FromFile': from the files with the 'data' flag 'FromEns',[usedims],[stats]: from all the files with the 'ensemble' flag with statistics [stats], throughout dimensions [usedims] [usedims]= '@' list of dimensions to take to compute the statistics [stats]= statistics to use 'direct': without statistics 'mean': mean value of all files with ensemble flag 'median': median value of all files with ensemble flag 'weightedmean,[stats],[weights]': weighted mean value all files with ensemble flag [stats] = statistics to use from each member: 'direct', 'mean', 'median' [weights] = '@' list of weights [0,1] 'FromIndivEns',[usedims],[stats]: from each files with the 'ensemble' flag with statistics [stats], throughout dimensions [usedims] [usedims]= '@' list of dimensions to take to compute the statistics [stats]= statistics to use: 'mean': mean value of each file with ensemble flag 'median': median value of each file with ensemble flag [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [figenskind]=[kindname],[valueskind] kind of ensemble plot 'cloud',[color],[limits]: ensembles values as a cloud [color]: name of the color to use ('auto' for '#DDDDDD') [limits]: which stadistics to use for the plot ('auto' for extremes) '5quantile': 5quantile,95quantile of the values 'direct': below and up values are tacking directly from the provided data 'extremes': min,max of the values 'stddev': standard deviation fo the values (only available if there is one line) 'spaghetti',[color],[width],[type]: a line for each member [color]: name of the color to use for all lines ('auto' for '#DDDDDD') [width]: width of the line to use for all lines ('auto' for 0.5) [type]: type of the line to use for all lines ('auto' for '-') [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [outfile]: wehter or not a file with the result of the computation of the ensemble should be written or not (labelled 'ensemble_ofile.nc') [close]: whether figure should be close or not """ fname = 'draw_ensembles_time' if values == 'h': print fname + '____________________________________________________________' print draw_ensembles_time.__doc__ quit() expectargs = '[dimxyfmt];[axeskind];[axislab];[axisunits];[rangevals];' + \ '[datavals];[timevals];[valskind];[labels];[figenskind];[graphtit];' + \ '[legvalues];[kindfig];[fign];[outfile];[close]' drw.check_arguments(fname,values,expectargs,';') dimxyfmt = values.split(';')[0] valaxis = values.split(';')[1] axislab = values.split(';')[2].replace('!',' ') axisunits = values.split(';')[3] rangevals = values.split(';')[4] datavals = values.split(';')[5] timevals = values.split(';')[6] valskind = values.split(';')[7] labels = gen.str_list(values.split(';')[8].replace('!', ' '), ',') figenskind = values.split(';')[9] graphtit = values.split(';')[10].replace('!',' ') legvalues = values.split(';')[11] kindfig = values.split(';')[12] fign = values.split(';')[13] outfile = gen.Str_Bool(values.split(';')[14]) close = gen.Str_Bool(values.split(';')[15]) ofilen = 'ensemble_ofile.nc' # files valfiles = gen.str_list(ncfile, '#') # time-values expectargs = '[timen]|[units]|[kind]|[tfmt]' drw.check_arguments('timevals: '+fname,timevals,expectargs,'|') timen = timevals.split('|')[0].replace('!',' ') timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] linevals = [] ltimevals = [] ensvals = [] etimevals = [] # List of files used for the ensemble ensfilens = [] # List of files used for the ensemble with its dimension and variable name edv_filens = [] # Dictionary with the dimensions of the values from a given file dimsfile = {} mintval = gen.fillValueF maxtval = -gen.fillValueF minvval = gen.fillValueF maxvval = -gen.fillValueF ensfilens = [] ifile = 0 dimt = -gen.fillValueF for fdv in valfiles: fvals = fdv.split(';') expectedargs = '[filen];[slice];[tvarn];[varn];[kinddata]' gen.check_arguments('filevals: '+fname, fdv, expectedargs, ';') filen = fvals[0] dimrange = fvals[1] tvarn = fvals[2] yvarn = fvals[3] datatype = fvals[4] edv = filen + '#' + dimrange + '#' + yvarn if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if tvarn == 'WRFtime': datesv = [] if tvarn == 'WRFtime': fdates = onc.variables['Times'][:] for it in range(fdates.shape[0]): datesv.append(gen.datetimeStr_conversion(fdates[it,:], \ 'WRFdatetime','cfTime,' + timeunit)) tvs = np.array(datesv, dtype=np.float) tunitsvar = timeunit else: if not onc.variables.has_key(tvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ tvarn + "' for the time-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) otvar = onc.variables[tvarn] tvs, tdims = ncvar.slice_variable(otvar, dimrange.replace(',',':')) tunitsvar = otvar.units if not onc.variables.has_key(yvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) oyvar = onc.variables[yvarn] yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) dimsfile[edv] = ydims # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(tvs, timeunit, tunitsvar) onc.close() if len(reftvals) > dimt: dimt = len(reftvals) reftn = reftvals.min() reftx = reftvals.max() if reftn < mintval: mintval = reftn if reftx > maxtval: maxtval = reftx refvn = yvs.min() refvx = yvs.max() if refvn < minvval: minvval = refvn if refvx > maxvval: maxvval = refvx if datatype == 'data': if len(tvs.shape) != 1: print errormsg print ' ' +fname+ ': provided slice:', dimrange, "for variable '" + \ tvarn + "' and '" + datatype + "' does not provide a rank-1 value !!" print ' resultant shape:', tvs.shape, 'dimensions:',tdims,'fix it !!' quit(-1) if len(yvs.shape) != 1: print errormsg print ' ' +fname+ ': provided slice:', dimrange, "for variable '" + \ yvarn + "' and '" + datatype + "'does not provide a rank-1 value !!" print ' resultant shape:',yvs.shape, 'dimensions:',ydims,'fix it !!' quit(-1) linevals.append(yvs) ltimevals.append(reftvals) else: ensfilens.append(filen) edv_filens.append(edv) ensvals.append(yvs) etimevals.append(reftvals) ifile = ifile + 1 Nens = len(ensvals) valskindn = gen.str_list(valskind, ',')[0] ENSvals = [] TENSvals = [] # Getting values to draw as lines if valskindn == 'FromFile': if len(linevals) == 0: print errormsg print ' ' + fname + ": you asked to get data '" + valskind + \ "' but no file with flag 'data' was provided !!" print ' provided file characteristics _______' for fdv in prefutdv: print fdv.split(';') quit(-1) ENSvals = list(ensvals) TENSvals = list(etimevals) elif valskindn == 'FromEns': eSvals = valskind.split(',') expectedargs='FromEns,[usedims],[stats]' gen.check_arguments('FromEns: '+fname, valskind, expectedargs, ',') ensdims = eSvals[1].split('@') ensn = eSvals[2] iedv = 0 # Temporal slices for each file/variable Tslices = {} for edv in edv_filens: vvalues = ensvals[iedv] edv_dims = dimsfile[edv] idim = [] for dsts in ensdims: idim.append(edv_dims.index(dsts)) # Adding each running value as a new member of the ensemble NOTusedim = [] for dn in dimsfile[edv]: if not gen.searchInlist(ensdims, dn): NOTusedim.append(dn) varslices = gen.provide_slices(dimsfile[edv], vvalues.shape, NOTusedim) Tslices[edv] = varslices if iedv == 0: dimt = len(varslices) else: if dimt != len(varslices): print errormsg print ' ' + fname + ': this is too complicated !!' print ' for file:', iedv, ' with ', len(varslices), \ 'and initial dimt:', dimt print ' not ready to deal with files with different number '+ \ 'of time-steps!!' quit(-1) # Adding each not runnuning grid-point as a new ensemble member varslices = gen.provide_slices(dimsfile[edv], vvalues.shape, ensdims) for slc in varslices: ENSvals.append(np.squeeze(vvalues[tuple(slc)])) TENSvals.append(np.squeeze(np.array(etimevals[iedv]))) iedv = iedv + 1 lvals = np.zeros((dimt), dtype=np.float) for it in range(dimt): iedv = 0 Tvals = [] Tvalse = {} for edv in edv_filens: vvalues = ensvals[iedv] varslics = Tslices[edv] Tvals = Tvals + list(np.squeeze(vvalues[tuple(varslics[dimt-it-1])]).flatten()) Tvalse[edv] = np.squeeze(vvalues[tuple(varslics[dimt-it-1])]) aTvals = np.array(Tvals) if ensn == 'mean': lvals[it] = np.mean(aTvals) elif ensn == 'median': lvals[it] = np.median(aTvals) elif ensn[0:12] == 'weightedmean': expectedargs='FromEns,[usedims],weightedmean,[stats],[weights]' gen.check_arguments('FromEns: '+fname, valskind, expectedargs, ',') stats = eSvals[3] wgths = eSvals[4].split('@') wghtvs = np.array(wgths, dtype=np.float) if len(wgths) != Nens: print errormsg print ' ' + fname + ': the number of members of the ensemble:', \ Nens, 'and the number of provided weights:', len(wghts), \ 'do not coincide !!' print ' provided weights:', wgths print ' provided file characteristics _______' for fdv in prefutdv: print fdv.split(';') quit(-1) wgthvals = np.zeros((Nens), dtype=np.float) iedv = 0 for edv in edv_filens: if stats == 'mean': wgthvals[iedv] = np.mean(Tvalse[edv]) elif stats == 'median': wgthvals[iedv] = np.median(Tvalse[edv]) else: print errormsg print ' ' +fname+ ": statistics '" + eSvals[2] + "' not ready !!" print ' available ones:', ['mean', 'median'] quit(-1) lvals[it] = np.sum(wghtvals*wghtvs)/np.sum(wghtvs) else: print errormsg print ' ' + fname + ": for '" + valskindn + "'statistics '" + \ eSvals[2] + "' not ready !!" print ' available ones:', ['mean', 'median', 'weightedmean'] quit(-1) iedv = iedv + 1 linevals.append(lvals) ltimevals.append(np.squeeze(np.array(etimevals[0], dtype=np.float))) elif valskindn == 'FromIndivEns': indenfns = [] eSvals = valskind.split(',') expectedargs='FromIndivEns,[usedims],[stats]' gen.check_arguments('FromEns: '+fname, valskind, expectedargs, ',') ensdims = eSvals[1].split('@') ensn = eSvals[2] iedv = 0 evals = np.zeros((dimt, Nens), dtype=np.float) for edv in edv_filens: vvalues = ensvals[iedv] edv_dims = dimsfile[edv] filen = edv.split('#')[0] indenfns.append(filen) idim = [] for dsts in ensdims: idim.append(edv_dims.index(dsts)) # Adding each running value as a new member of the ensemble NOTusedim = [] for dn in dimsfile[edv]: if not gen.searchInlist(ensdims, dn): NOTusedim.append(dn) varslices = gen.provide_slices(dimsfile[edv], vvalues.shape, ensdims) for varslc in varslices: ENSvals.append(np.squeeze(vvalues[tuple(varslc)])) TENSvals.append(np.squeeze(np.array(etimevals[iedv], dtype=np.float))) # No need to repeat File name len(varslices)0 times # ensfilens.append(filen) if ensn == 'mean': linevals.append(np.mean(vvalues, axis=tuple(idim))) elif ensn == 'median': linevals.append(np.median(vvalues, axis=tuple(idim))) elif ensn == 'direct': if len(values.shape) != 1: print errormsg print ' ' +fname+ ': provided slice:', dimrange, \ "for variable '" + yvarn + "' and '" + datatype + \ "'does not provide a rank-1 value !!" print ' resultant shape:', yvs.shape, 'dimensions:', ydims, \ 'fix it !!' quit(-1) linevals.append(vvalues) else: print errormsg print ' ' + fname + ": for '" + valskindn + "' statistics '" + \ eSvals[2] + "' not ready !!" print ' available ones:', ['mean', 'median'] quit(-1) ltimevals.append(np.squeeze(np.array(etimevals[iedv], dtype=np.float))) iedv = iedv + 1 else: print errormsg print ' ' + fname + ": kind of values '" + valskindn + "' not ready !!" print ' available ones:', ['FromFile', 'FromEns', 'FromIndivEns'] quit(-1) Ndata = len(linevals) Nens = len(ENSvals) # Times dtvals = (maxtval - mintval)/10 dti = mintval dte = maxtval tvalsticks = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS timepos, timelabels = drw.CFtimes_plot(tvalsticks, timeunit, timekind, timefmt) # ranges if rangevals == 'None': valmin = minvval valmax = maxvval else: if rangevals.split(',')[0] != 'auto': valmin = np.float(rangevals.split(',')[0]) else: valmin = minvval if rangevals.split(',')[1] != 'auto': valmax = np.float(rangevals.split(',')[1]) else: valmax = maxvval xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Legend legloc, legsiz = drw.legend_values(legvalues,'|') valuesvals = [valaxis, axislab, axisunits, [valmin, valmax]] # line-characteristics expectargs = '[color]:[linetype]:[linewidht]:[markertype]:[markersize]' Lvals = datavals.split(':') gen.check_arguments('data-line characterisitcs: '+fname,datavals,expectargs,':') Lcol = Lvals[0] Ltype = Lvals[1] Lwidth = Lvals[2] Lmarker = Lvals[3] Lsizem = Lvals[4] if len(labels) != len(linevals): print errormsg print ' ' + fname + ': There are', len(linevals), 'lines to plot but', \ len(labels), 'labels provided !!' print ' provided labels:', labels quit(-1) if outfile: onew = NetCDFFile(ofilen, 'w') Lstr = 250 # Dimensions newdim = onew.createDimension('data', Ndata) newdim = onew.createDimension('ensemble', Nens) newdim = onew.createDimension('time', dimt) newdim = onew.createDimension('Lstring', Lstr) # Dimension variables newvar = onew.createVariable('time', 'f8', ('time')) ncvar.basicvardef(newvar, 'time', 'Time', timeunit) newvar.setncattr('axis', 'T') newvar.setncattr('_CoordinateAxisType', 'Time') newvar.setncattr('calendar', 'gregorian') newvar[:] = etimevals[0] newvar = onew.createVariable('ensfilen', 'c', ('ensemble', 'Lstring')) ncvar.basicvardef(newvar, 'ensfilen', 'name of files of the ensemble data', \ '-') newvals = ncvar.writing_str_nc(newvar, ensfilens, Lstr) onew.sync() # Global attributes ncvar.add_global_PyNCplot(onew, mainn, fname, '1.0') else: onew = None drw.plot_TimeEnsembles(linevals, ENSvals, ltimevals, TENSvals, xaxis, yaxis, \ valuesvals, Lcol, Ltype, Lwidth, Lmarker, Lsizem, labels, figenskind, timen, \ timepos, timelabels, graphtit, legloc, legsiz, kindfig, fign, onew, close) if onew is not None: ovals = onew.variables['vals'] if valskindn == 'FromEns': eSvals = valskind.split(',') ensdims = eSvals[1].split('@') ensn = eSvals[2] if ensn != 'weightedmean': txt = 'values retrieved from all ensembles file as ' + ensn + \ ' along dimensions ' + ','.join(ensdims) else: newvar = onew.createVariable('weight', 'f', ('ensemble')) ncvar.basicvardef(newvar, 'weight', 'weights for the weighted mean', \ '-') newvar[:] = wghtvs txt = 'values retrieved from all ensembles file as weighted mean' + \ ' along dimensions ' + ','.join(ensdims) newattr = ncvar.set_attribute(ovals, 'data_origin', txt) onew.sync() elif valskindn == 'FromIndivEns': eSvals = valskind.split(',') ensdims = eSvals[1].split('@') ensn = eSvals[2] txt = 'values retrieved from each ensembles file as ' + ensn + \ ' along dimensions ' + ','.join(ensdims) newattr = ncvar.set_attribute(ovals, 'data_origin', txt) newvar = onew.createVariable('datafilen', 'c', ('data', 'Lstring')) ncvar.basicvardef(newvar, 'datafilen', 'name of files for the ensemble ',\ 'data', '-') newvals = ncvar.writing_str_nc(newvar, indenfns, Lstr) onew.sync() onew.sync() onew.close() print fname + ": succesful writting of output file '" + ofilen + "' !!" return def draw_cycle(ncfile, values): """ Function to plot a variale with a circular cycle ncfile = '#' list of files [filen];[slice];[tvarn];[varn] [filen]: name of the file [dimslice]: '|' list of [dimn],[dimrange] [dimn]: name of the dimension [dimrange]: range for the slice * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [tvarn]: name of the variable time ('WRFtime', for times from WRF) [varn]: name of the variable to use for the values values = [dimxyfmt];[valaxis];[axeskind];[axislab];[axisunits];[rangevals];[cyclevals];[figcyckind]; [cycticks];[timevals];[labels];[graphtit];[legvalues];[kindfig];[fign];[outfile];[close] [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordy]: format of the values at each axis (or single 'auto' for 'auto','auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Stringlist', a given list of strings 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis [Ndx]: Number of ticks at the x-axis (for 'Stringlist', '@' list of labels) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis [Ndy]: Number of ticks at the y-axis [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [valaxis]: which axes should be used for the data [axeskind]: type of axes to be plotted 'centered': crossed at 0,0 at the center of the figure 'box': around the figure [axislab]: Label for the values-axis ('!' for spaces) [axisunits]: units of the values-label [rangevals]: Range of the axis with the values (single 'None' for 'auto','auto') [val1],[val2]: tacking the provided ',' separated list of desired [val1] and [val2] 'auto': automatically set up range using minv and maxv 'extremescentered': extremes automatically centered on zero by computing from data -absmax, absmax; absmax=max(abs(minval),maxval) 'meancentered': extremes automatically centered on mean by computing from data minv+meanv, maxv-meanv; meanv=(minval + maxval)/2. [cyclevals] = [cycle],[cycle0] [cycle]= numbers of time steps to use for the cycle [cycle0]= initial position of time steps whithin the cycle [figcyckind]=[kindname],[valueskind] kind of cycle plot 'cloud',[color]: values as a cloud of points [color]: name of the colorbar to use changing after the end of each cycle ('auto' for 'rainbow') 'lines',[color],[width],[type]: values a continuous line [color]: name of the colorbar to use changing after the end of each cycle ('auto' for 'rainbow') [width]: width of the line to use for all lines ('auto' for 0.5) [type]: type of the line to use for all lines ('auto' for '-') [cycticks]= [cycpos]@[cyclab] characteristics of the ticks for the cycle [cycpos]: ',' list of positions for the ticks (less than cycle/2) [cyclab]: ',' list of labels for the ticks (less than cycle/2) [timevals]: [timen]|[units]|[kind]|[tfmt] time labels characteristics [timen]; name of the time variable [units]; units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces) [kind]; kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]; desired format [labels]: ',' list of labels for the legend ('None' for no-labels, '!' for spaces) [graphtit]: title of the figure '!' for spaces [legvalues]=[locleg]|[fontsize]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [kindfig]: kind of output figure (png, pdf, ps) [fign]: name of the figure (without extension) [close]: whether figure should be close or not """ fname = 'draw_cycle' if values == 'h': print fname + '____________________________________________________________' print draw_cycle.__doc__ quit() expectargs = '[dimxyfmt];[valaxis];[axeskind];[axislab];[axisunits];' + \ '[rangevals];[cyclevals];[figcyckind];[cycticks];[timevals];[labels];'+ \ '[graphtit];[legvalues];[kindfig];[fign];[close]' drw.check_arguments(fname,values,expectargs,';') dimxyfmt = values.split(';')[0] valaxis = values.split(';')[1] axiskind = values.split(';')[2] axislab = values.split(';')[3].replace('!',' ') axisunits = values.split(';')[4] rangevals = values.split(';')[5] cyclevals = values.split(';')[6] figcyckind = values.split(';')[7] cycticks = values.split(';')[8].split('@') timevals = values.split(';')[9] labels = gen.str_list(values.split(';')[10].replace('!', ' '), ',') graphtit = values.split(';')[11].replace('!',' ') legvalues = values.split(';')[12] kindfig = values.split(';')[13] fign = values.split(';')[14] close = gen.Str_Bool(values.split(';')[15]) # cycle cycle = int(cyclevals.split(',')[0]) cycle0 = int(cyclevals.split(',')[1]) # time-values expectargs = '[timen]|[units]|[kind]|[tfmt]' drw.check_arguments('timevals: '+fname,timevals,expectargs,'|') timen = timevals.split('|')[0].replace('!',' ') timeunit = timevals.split('|')[1].replace('!',' ') timekind = timevals.split('|')[2] timefmt = timevals.split('|')[3] # files valfiles = gen.str_list(ncfile, '#') values = [] timevalues = [] mintval = gen.fillValueF maxtval = -gen.fillValueF minvval = gen.fillValueF maxvval = -gen.fillValueF ifile = 0 dimt = -gen.fillValueF for fdv in valfiles: fvals = fdv.split(';') expectedargs = '[filen];[slice];[tvarn];[varn]' gen.check_arguments('filevals: '+fname, fdv, expectedargs, ';') filen = fvals[0] dimrange = fvals[1] tvarn = fvals[2] yvarn = fvals[3] if not os.path.isfile(filen): print errormsg print ' ' + fname + ': file "' + filen + '" does not exist !!' quit(-1) onc = NetCDFFile(filen, 'r') if tvarn == 'WRFtime': datesv = [] if tvarn == 'WRFtime': fdates = onc.variables['Times'][:] for it in range(fdates.shape[0]): datesv.append(gen.datetimeStr_conversion(fdates[it,:], \ 'WRFdatetime','cfTime,' + timeunit)) tvs = np.array(datesv, dtype=np.float) tunitsvar = timeunit else: if not onc.variables.has_key(tvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ tvarn + "' for the time-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) otvar = onc.variables[tvarn] tvs, tdims = ncvar.slice_variable(otvar, dimrange.replace(',',':')) tunitsvar = otvar.units if not onc.variables.has_key(yvarn): print errormsg print ' ' +fname+ ': file "' +filen+ "' does not have variable '" + \ yvarn + "' for the y-values !!" print ' available ones:', onc.variables.keys() onc.close() quit(-1) oyvar = onc.variables[yvarn] yvs, ydims = ncvar.slice_variable(oyvar, dimrange.replace(',',':')) if len(yvs.shape) != 1: print errormsg print ' ' + fname + ': Wrong slice. There must be a 1D variable!!' print ' current shape:', yvs.shape quit(-1) # Referring all times to the same reference time! reftvals = gen.coincident_CFtimes(tvs, timeunit, tunitsvar) onc.close() if len(reftvals) > dimt: dimt = len(reftvals) reftn = reftvals.min() reftx = reftvals.max() if reftn < mintval: mintval = reftn if reftx > maxtval: maxtval = reftx refvn = yvs.min() refvx = yvs.max() if refvn < minvval: minvval = refvn if refvx > maxvval: maxvval = refvx values.append(yvs) timevalues.append(reftvals) ifile = ifile + 1 # cycle ticks pos=cycticks[0].split(',') ll=cycticks[1].split(',') ctick = [] clab = [] for ip in range(len(pos)): ctick.append(np.float(pos[ip])) clab.append(gen.latex_text(ll[ip])) # Times dtvals = (maxtval - mintval)/10 dti = mintval dte = maxtval tvalsticks = np.arange(dti, dte+dtvals, dtvals) dtiS = drw.datetimeStr_conversion(str(dti) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') dteS = drw.datetimeStr_conversion(str(dte) + ',' + timeunit, 'cfTime', \ 'Y/m/d H-M-S') print ' ' + fname + ': plotting from: ' + dtiS + ' to ' + dteS timepos, timelabels = drw.CFtimes_plot(tvalsticks, timeunit, timekind, timefmt) # ranges rng = gen.minmax_range(minvval, maxvval, rangevals) xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyfmt,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] # Legend legloc, legsiz = drw.legend_values(legvalues,'|') drw.plot_cycle(values, timevalues, xaxis, yaxis, valaxis, axiskind, axislab, \ axisunits, rng, cycle, cycle0, figcyckind, labels, ctick, clab, timen, timepos,\ timelabels, graphtit, legloc, legsiz, kindfig, fign, close) return def draw_multi_2D_shad(ncfiles, values, axfig=None, fig=None): """ plotting multiple 2D fields with same projection with shading and sharing colorbar draw_multi_2D_shad(ncfile, values, varn) ncfiles= ';' list of files to use as [filen]@[varn]@[dimvals] [filen]: name of the file [varn]: name of the variable in the file to be shaded [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size values=[vnamefs]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[sminv],[smaxv]: [kindfig]:[reverse]:[mapv]:[labels]:[Nrow]:[Ncol]:[globaltitle]:[close] [vnamefs]: Name in the figure of the variable to be shaded [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [kindfig]: kind of figure output file: png, pdf, ... [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [labels]: ',' list of consecutive labels for each individual panel ('!' for spaces) [Nrow]: number of rows in the figure [Ncol]: number of columns in the figure [globaltitle]: global title of the figure ('!' for spaces) [close]: Whether figure should be finished or not """ fname = 'draw_multi_2D_shad' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad.__doc__ quit() expectargs = '[vnamefs]:[dimxvn]:[dimyvn]:[dimxyf]:[colbarvals]:' + \ '[sminv],[smaxv]:[kindfig]:[reverse]:[mapv]:[labels]:[Nrow]:[Ncol]:' + \ '[globaltitle]:[close]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0] vdimxn = values.split(':')[1] vdimyn = values.split(':')[2] dimxyf = values.split(':')[3] colorbarvals = values.split(':')[4] shadminmax = values.split(':')[5] figkind = values.split(':')[6] revals = values.split(':')[7] mapvalue = values.split(':')[8] labels = values.split(':')[9].split(',') Nrow = int(values.split(':')[10]) Ncol = int(values.split(':')[11]) globaltitle = values.split(':')[12].replace('!', ' ') close = gen.Str_Bool(values.split(':')[13]) fvds = ncfiles.split(';') lvalshad = [] for fvd in fvds: ncfile = fvd.split('@')[0] varn = fvd.split('@')[1] dimvals = fvd.split('@')[2] if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': shading file "' + ncfile + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfile, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' varns = sorted(objsf.variables.keys()) print ' available ones:', varns quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, \ dimvals.replace('|',':').replace(',','|')) lvalshad.append(valshad) # Getting variable information from first file if fvd == fvds[0]: dimnamesv = [vdimxn, vdimyn] if drw.searchInlist(objvars.ncattrs(),'units'): varunits = objvars.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimxn + \ "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimyn + \ "' without units!!" odimyu = '-' odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], \ objdimx.dimensions, objdimy.dimensions, \ dimvals.replace(':','|').split(',')) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.multi_plot_2D_shadow(lvalshad, odimxv, odimyv, odimxu, odimyu, xaxis, yaxis, \ dimnamesv, colormapv, shading_nx, varunits, figkind, revals, mapvalue, labels, \ Nrow, Ncol, globaltitle, close) return #python drawing.py -o draw_multi_2D_shad -f '../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|0;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|1;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|2;../PY/wrfout_d01_1995-01-01_00:00:00@T2@west_east|-1,south_north|-1,Time|3' -S 'tas:XLONG:XLAT:auto:rainbow,auto,auto:Srange,Srange:png:None:cyl,l:0!UTC,1!UTC,2!UTC,3!UTC:2:2:tas!at!2001-11-11:True' def movie_2D_shad(ncfile, values, varn, axfig=None, fig=None): """ creation of a movie with shading movie_2D_shad(ncfile, values, varn) ncfile= file to use values=[vnamefs]:[dimvals]:[dimxvn]:[dimyvn]:[dimxyfmt]:[colorbarvals]:[sminv],[smaxv]:[figt]: [kindfig]:[reverse]:[mapv]:[moviedim]:[fps]:[kmov] [vnamefs]: Name in the figure of the variable to be shaded [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [kindfig]: kind of figure [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [movievals] = [moviedim],[movivar] way to get values for the movie [moviedime]: name of the dimension to get the movie (following outcome from [dimvals]) [movievar]: name of the variable to get the values [framelabels]: values for the production of the labels of each frame * 'varVal',[HeadTit],[TailTit],[fmt]: Following direct values from variable as: [HeadTit] + ' ' + [varValue] + ' ' + [TailTit] [HeadTit]: Head of title ('!', for spaces) [TailTit]: title of title ('!', for spaces) [fmt]: format of the values of the variable in the title (C-like and LaTeX-like combined) * 'listtit',[Ftitles]: Providing manually title for each frame [Ftitle]: '@' separated list of titles ('!', for titles) * 'CFdate',[datefmt]: Just title with the date (assuming CF-time compilant variable) [tfmt]: format of the date (C-like and LaTeX-like combined) * 'WRFdate',[datefmt]: Just title with the date (assuming WRF time variable) [tfmt]: format of the date (C-like and LaTeX-like combined) [fps]: frames per second of the output movie [kmov]: kind of movie (mp4, ....) varn= [varsn] name of the variable to plot with shading """ fname = 'movie_2D_shad' if values == 'h': print fname + '_____________________________________________________________' print movie_2D_shad.__doc__ quit() expectargs = '[vnamefs]:[dimvals]:[dimxvn]:[dimyvn]:[dimxyf]:[colbarvals]:' + \ '[sminv],[smaxv]:[kindfig]:[reverse]:[mapv]:[movidime]:[framelabels]:[fps]' + \ ':[kmov]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0] dimvals= values.split(':')[1].replace('|',':') vdimxn = values.split(':')[2] vdimyn = values.split(':')[3] dimxyf = values.split(':')[4] colorbarvals = values.split(':')[5] shadminmax = values.split(':')[6] figkind = values.split(':')[7] revals = values.split(':')[8] mapvalue = values.split(':')[9] movievals = values.split(':')[10].split(',') framelabelS = values.split(':')[11] fps = int(values.split(':')[12]) kmov = values.split(':')[13] ncfiles = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') varns = varn.split(',')[0] if not objsf.variables.has_key(varns): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varns + '" !!' varns = sorted(objsf.variables.keys()) print ' available ones:', varns quit(-1) # Variables' values objvars = objsf.variables[varns] valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) dimnamesv = [vdimxn, vdimyn] # Movie variable moviedim = movievals[0] movievar = movievals[1] idd = 0 for dn in objvars.dimensions: if dn == moviedim: NumDimT = idd break idd = idd + 1 if drw.searchInlist(objvars.ncattrs(),'units'): varunits = objvars.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimxn + "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimyn + "' without units!!" odimyu = '-' odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if mapvalue == 'None': mapvalue = None colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None if not objsf.variables.has_key(movievar): oncvars = objsf.variables.keys() oncvars.sort() print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable '" + \ movievar + "' to get from the values for the frames!!" print ' available ones:', oncvars quit(-1) omovievar = objsf.variables[movievar] movievarv, dimsmov = drw.slice_variable(omovievar, dimvals.replace(',','|')) # Labels for frames framelabels = [] if framelabelS[0:6] == 'varVal': HeadTit = framelabelS.split(',')[1] TailTit = framelabelS.split(',')[2] fmt = framelabelS.split(',')[3] if len(movievarv.shape) != 1: print errormsg print ' ' + fname + ": for frame labels type 'varVal' is required a " + \ " rank 1 variable !!" print " variable '" + movievar + "' shape:", vn.shape quit(-1) dimt = movievarv.shape[0] for it in range(dimt): framelabels.append(gen.latex_tex(HeadTit) + ' ' + \ '{}'.format(movievarv[it]) + ' ' + gen.latex_tex(TailTit)) elif framelabelS[0:7] == 'listtit': frameS = framelabelS.split(',')[1].split('@') dimt = len(frameS) for it in range(dimt): framelabels.append(gen.latex_tex(frameS[it].replace('!', ' '))) elif framelabelS[0:6] == 'CFdate': import datetime as dt tfmt = framelabelS.split(',')[1] if len(movievarv.shape) != 1: print errormsg print ' ' + fname + ": for frame labels type 'CFdate' is required a " + \ " rank 1 variable !!" print " variable '" + movievar + "' shape:", movievarv.shape quit(-1) tunits = omovievar.getncattr('units') tcalendar = omovievar.getncattr('calendar') datesv = gen.netCDFdatetime_realdatetime(tunits, tcalendar, movievarv[:]) dimt = omovievar.shape[0] for it in range(dimt): dateV = dt.datetime(datesv[it][0], datesv[it][1], datesv[it][2], \ datesv[it][3], datesv[it][4], datesv[it][5]) framelabels.append(dateV.strftime(tfmt)) elif framelabelS[0:7] == 'WRFdate': import datetime as dt tfmt = framelabelS.split(',')[1] if len(movievarv.shape) != 2: print errormsg print ' ' + fname + ": for frame labels type 'WRFtime' is required a "+ \ " rank 2 variable !!" print " variable '" + movievar + "' shape:", movievarv.shape quit(-1) timev, tunits = ncvar.compute_WRFtime(movievarv[:]) datesv = gen.netCDFdatetime_realdatetime(tunits, 'standard', timev) dimt = omovievar.shape[0] for it in range(dimt): dateV = dt.datetime(datesv[it][0], datesv[it][1], datesv[it][2], \ datesv[it][3], datesv[it][4], datesv[it][5]) framelabels.append(dateV.strftime(tfmt)) drw.movie_2D_shadow(valshad, NumDimT, vnamesfig, odimxv, odimyv, odimxu, odimyu, \ xaxis, yaxis, dimnamesv, colormapv, shading_nx, varunits, framelabels, \ figkind, revals, mapvalue, fps, kmov) return #python drawing.py -o movie_2D_shad -f '../PY/wrfout_d01_1995-01-01_00:00:00' -S 'tas:west_east|-1,south_north|-1,Time|-1:XLONG:XLAT:auto:rainbow,auto,auto:Srange,Srange:png:None:cyl,l:Time,Times:WRFdate,$%d^{%H}$:15:mp4' -v T2 def draw_SkewT(ncfile, values, varname): """ creation of a SkewT-logP diagram using matplotlib's API example https://matplotlib.org/examples/api/skewt.html (skewt.py, included as external python) draw_SkewT(ncfile, values, varn) ncfile= file to use values = [dimvals]:[taminv],[tamaxv]:[presminv],[presmaxv]:[figt]:[kindfig]: [close] [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [taminv],[tamaxv]: minimum and maximum of temperatures to plot [C] ('auto' for -50,50) [presminv],[presmaxv]: minimum and maximum of pressures to plot [hPa] ('auto' for 100.,1020.) [figt]: title of figure ('!' for spaces) [kindfig]: kind of graphical output (ps, png, pdf) [close]: wether figure should be closed or not varn= [tavarn],[tdavarn],[presvarn] """ fname = 'draw_SkewT' if values == 'h': print fname + '_____________________________________________________________' print draw_SkewT.__doc__ quit() expectargs = '[dimvals]:[taminv],[tamaxv]:[presminv],[presmaxv]:[figt]:' + \ '[kindfig]:[close]' drw.check_arguments(fname,values,expectargs,':') # Variables varns = varname.split(',') if len(varns) != 3: print errormsg print ' ' +fname+ ": requires 3 name of variables as '[tavarn],[tdavarn]" + \ ",[presvarn]' !!" print " variables provided: '" + varname + "' " quit(-1) dimvals= values.split(':')[0].replace('|',':') if values.split(':')[1] != 'auto': tanx = gen.str_list_k(values.split(':')[1], ',', 'np.float') else: tanx = [-50.,50.] if values.split(':')[2] != 'auto': presnx = gen.str_list_k(values.split(':')[2], ',', 'np.float') else: presnx = [100.,1020.] figt = values.split(':')[3].replace('!',' ') kindfig = values.split(':')[4] close = gen.Str_Bool(values.split(':')[5]) onc = NetCDFFile(ncfile, 'r') for varn in varns: if not onc.variables.has_key(varn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable '" + \ varn + "' !!" print ' available ones:', onc.variables.keys() quit(-1) ota = onc.variables[varns[0]] otda = onc.variables[varns[1]] opres = onc.variables[varns[2]] # Getting values tavals, tadims = drw.slice_variable(ota, dimvals.replace(',','|')) tdavals, tdadims = drw.slice_variable(otda, dimvals.replace(',','|')) presvals, presdims = drw.slice_variable(opres, dimvals.replace(',','|')) # Expected masked values if type(tavals) != type(gen.mamat): tavals = ma.masked_array(tavals) if type(tdavals) != type(gen.mamat): tdavals = ma.masked_array(tdavals) if type(presvals) != type(gen.mamat): presvals = ma.masked_array(presvals) drw.plot_SkewT(tavals, tdavals, presvals, tanx, presnx, figt, kindfig, close) onc.close() return #filen='/home/lluis/estudios/ChemGBsAs/tests/199807/obs/snd/UWyoming_snd_87576.nc' #values='time|0:auto:auto:Sounding!at!Ezeiza!airport!on!3rd!July!1998:png:yes' #varn='ta,tda,pres' #draw_SkewT(filen, values, varn) def draw_multi_SkewT(ncfiles, values): """ creation of a SkewT-logP diagram with multiple lines using matplotlib's API example https://matplotlib.org/examples/api/skewt.html (skewt.py, included as external python) draw_SkewT(ncfile, values, varn) ncfiles = ';' list of [filen]:[dimvals]:[varn],[presvarn] file and variables to use from each file [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [varn]: name of the variable to plot [C] [presvarn]: name of the variable with the pressures of [varn] [Pa] values = [taminv],[tamaxv]:[presminv],[presmaxv]:[kindgraph]:[legvals]:[figt]: [kindfig]:[close] [taminv],[tamaxv]: minimum and maximum of temperatures to plot [C] ('auto' for -50,50) [presminv],[presmaxv]: minimum and maximum of pressures to plot [hPa] ('auto' for 100.,1020.) [kindgraph]: kind of graphic to produce. To select from: 'multilines'![labels]![collines]![kindlines]![kindmarkers]![widthlines] [labels] = ',' separated list of labels for each file ('None' for no label) [collines] = ',' separated list of colors ('#RRGGBB' values) of lines for each file (1 value for all the lines the same) [kindmarkers] = ';' separated list of marker types (matplolib values) for each file (1 value for all the lines the same) [kindlines] = ';' separated list of line types (matplolib values) of lines for each file (1 value for all the lines the same) [widthlines] = ';' separated list of line widths (matplolib values) of lines for each file (1 value for all the lines the same) [legvals]=[loclegend],[fonstsize] values for the legend [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend ('auto' for 12) [figt]: title of figure ('!' for spaces) [kindfig]: kind of graphical output (ps, png, pdf) [close]: wether figure should be closed or not """ fname = 'draw_SkewT' if values == 'h': print fname + '_____________________________________________________________' print draw_SkewT.__doc__ quit() availgraph = ['multilines'] expectargs = '[taminv],[tamaxv]:[presminv],[presmaxv]:[figt]:[kindgraph]:' + \ '[legvals]:[kindfig]:[close]' drw.check_arguments(fname,values,expectargs,':') if values.split(':')[0] != 'auto': tanx = gen.str_list_k(values.split(':')[0], ',', 'np.float') else: tanx = [-50.,50.] if values.split(':')[1] != 'auto': presnx = gen.str_list_k(values.split(':')[1], ',', 'np.float') else: presnx = [100.,1020.] kindgraph = values.split(':')[2] legv = drw.legend_values(values.split(':')[3], ',') figt = values.split(':')[4].replace('!',' ') kindfig = values.split(':')[5] close = gen.Str_Bool(values.split(':')[6]) filevals = ncfiles.split(';') Nfiles = len(filevals) # Getting graphic parameters kindgraphv = kindgraph.split('!') kgraphS = kindgraphv[0] kgraphv = {} if kgraphS == 'multilines': kgraphv['labels'] = kindgraphv[1].split(',') kgraphv['collines'] = gen.str_list_rep(kindgraphv[2], ',', Nfiles) kgraphv['kindlines'] = gen.str_list_rep(kindgraphv[3], ',', Nfiles) kgraphv['kindmarkers'] = gen.str_list_rep(kindgraphv[4], ';', Nfiles) kgraphv['widthlines'] = gen.str_list_rep(kindgraphv[5], ',', Nfiles) else: print errormsg print ' ' + fname + ": graphic type '" + kindgraphv[0] + "' not ready !!" print ' available ones:', availgraph quit(-1) vavals = {} presvals = {} ifile = 0 # Getting values to plot for fileval in filevals: ncfile = fileval.split(':')[0] dimvals= fileval.split(':')[1].replace('|',':') varname = fileval.split(':')[2] # Variables varns = varname.split(',') if len(varns) != 2: print errormsg print ' ' +fname+ ": requires 2 name of variables as '[varn]," + \ "[presvarn]' !!" print " variables provided: '" + varname + "' " quit(-1) if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not exist !!" quit(-1) onc = NetCDFFile(ncfile, 'r') print ' ' + fname + ": getting from file '" + ncfile + "' variables:" , \ varns, 'with slice:', dimvals for varn in varns: if not onc.variables.has_key(varn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have " + \ "variable '" + varn + "' !!" print ' available ones:', onc.variables.keys() quit(-1) ov = onc.variables[varns[0]] opres = onc.variables[varns[1]] otime = onc.variables['time'] # Getting values vals, valdims = drw.slice_variable(ov, dimvals.replace(',','|')) pvals, presdims = drw.slice_variable(opres, dimvals.replace(',','|')) tvals, tdims = drw.slice_variable(otime, dimvals.replace(',','|')) # Expected masked values if type(vals) != type(gen.mamat): vavals[ifile] = ma.masked_array(vals) else: vavals[ifile] = vals if type(pvals) != type(gen.mamat): presvals[ifile] = ma.masked_array(pvals) else: presvals[ifile] = pvals ifile = ifile + 1 drw.plot_multi_SkewT(vavals, presvals, tanx, presnx, kgraphS, kgraphv, legv, \ figt, kindfig, close) onc.close() return #filen='/home/lluis/estudios/ChemGBsAs/tests/199807/obs/snd/UWyoming_snd_87576.nc:pres|-1,time|0:ta,pres;' + \ # '/home/lluis/estudios/ChemGBsAs/tests/199807/obs/snd/UWyoming_snd_87576.nc:pres|-1,time|0:tda,pres' #values='auto:auto:multilines!ta,tda!#6464FF,#FF6464!-!,!2:0,auto:Sounding!at!Ezeiza!airport!on!3rd!July!1998:png:yes' #draw_multi_SkewT(filen, values) def draw_2D_shad_contdisc(ncfiles, values, axfig=None, fig=None): """ plotting one continuous fields with shading and another discrete one with points draw_2D_shad_contdisc(ncfile, values) ncfiles= [contfilen];[contvarn];[dimxvarn];[dimyvarn];[dimvals]@[discfilen]; [discvarn];[dimxvarn];[dimyvarn];[dimvals] files and variables to use [contfilen]: name of the file with the continuous varible [contvarn]: name of the continuos variable [dimxvarn]: name of the variable with values for the x-dimension [dimyvarn]: name of the variable with values for the y-dimension [dimvals]: ',' list of [dimname]|[value] values to slice the variable: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [discfilen]: name of the file with the discrete varible [discvarn]: name of the discrete variable * NOTE: limits of the graph will be computed from the continuous variable values=[vnamefs]:[dvarxn],[dvaryn]:[dimxyfmt]:[colorbarvals]:[sminv],[smaxv]: [discvals]:[figt]:[kindfig]:[reverse]:[mapv]:[plotrange]:[close] [vnamefs]: Name in the figure of the variable to be shaded [dvarxn],[dvaryn]: name of the dimensions for the final x-axis and y-axis at the figure (from contfilen) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' ['auto'], 'horizontal') * NOTE: single 'auto' for 'rainbow,%6g,vertical' [smin/axv]: minimum and maximum values for the shading or string for each for: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val),percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val),percentile_(100-val)-median) [discvals]= [type],[size],[lwidth],[lcol] characteristics of the points for the discrete field [type]: type of point. Any marker from matoplib must be filled ! [size]: size of point [lwidth]: width of the line around the point [lcol]: color of the line around the point 'auto': for [type]='o', [size]=5, [lwdith]=0.25, [lcol]='#000000' [figt]: title of the figure ('!' for spaces) [kindfig]: kind of figure output (ps, png, pdf) [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [plotrange]: range of the plot 'strict': map covers only the minimum and maximum lon,lats from the locations of the discrtete points 'sponge,'[dlon],[dlat]: map covers an extended [dlon],[dlat] from the minimum and maximum lon,lats from the locations of the discrtete points 'fullcontinuous': map covers all the shadding area 'lonlatbox,[lonSW],[latSW],[lonNE],[latNE]': plotted map only covers a lon,lat box [close]: Whether figure should be finished or not """ fname = 'draw_2D_shad_contdisc' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_contdisc.__doc__ quit() expectargs = '[vnamefs]:[dvarxn],[dvaryn]:[dimxyfmt]:[colorbarvals]:[sminv],' + \ '[smaxv]:[discvals]:[figt]:[kindfig]:[reverse]:[mapv]:[plotrange]:[close]' drw.check_arguments(fname,values,expectargs,':') vnamesfig = values.split(':')[0] [dvarxn, dvaryn] = values.split(':')[1].split(',') dimxyf = values.split(':')[2] colorbarvals = values.split(':')[3] shadminmax = values.split(':')[4] discvals = values.split(':')[5] figt = values.split(':')[6].replace('!',' ') kindfig = values.split(':')[7] revals = values.split(':')[8] mapvalue = values.split(':')[9] plotrange = values.split(':')[10] close = gen.Str_Bool(values.split(':')[11]) ncs = ncfiles.split('@') filesinf = {} ifile = 0 for nc in ncs: if ifile == 0: hfn = 'cont' else: hfn = 'disc' filesinf[hfn + 'filen'] = nc.split(';')[0] filesinf[hfn + 'varn'] = nc.split(';')[1] filesinf[hfn + 'dimxvn'] = nc.split(';')[2] filesinf[hfn + 'dimyvn'] = nc.split(';')[3] filesinf[hfn + 'dimvals'] = nc.split(';')[4].replace('|',':') ifile = ifile + 1 for hfn in ['cont', 'disc']: ncfilen = filesinf[hfn + 'filen'] varn = filesinf[hfn + 'varn'] vdimxn = filesinf[hfn + 'dimxvn'] vdimyn = filesinf[hfn + 'dimyvn'] dimvals = filesinf[hfn + 'dimvals'] if not os.path.isfile(ncfilen): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + "' does " + \ "not exist !!" quit(-1) onc = NetCDFFile(ncfilen, 'r') if not onc.variables.has_key(varn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + \ "' does not have variable '" + varn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) # Variables' values ovar = onc.variables[varn] vals, dims = drw.slice_variable(ovar, dimvals.replace(',','|')) # Values have to be 2D if hfn == 'cont' and len(vals.shape) != 2: print errormsg print ' ' + fname + ": values have to be 2D !!" print ' provided shape:', vals.shape, 'for slice:', dimvals quit(-1) if drw.searchInlist(ovar.ncattrs(),'units'): varunits = ovar.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' # dimensions dimnamesv = [vdimxn, vdimyn] if not onc.variables.has_key(vdimxn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + \ "' does not have x-dimension variable '" + vdimxn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) if not onc.variables.has_key(vdimyn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + \ "' does not have y-dimension variable '" + vdimyn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) objdimx = onc.variables[vdimxn] objdimy = onc.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' +fname+": variable dimension '" + vdimxn + "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' +fname+": variable dimension '" + vdimyn + "' without units!!" odimyu = '-' odimxv0, odimyv0 = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], \ objdimx.dimensions, objdimy.dimensions, dimvals.replace(':','|').split(','),\ False) # Some statistics vn = np.min(vals) vx = np.max(vals) dxn = np.min(odimxv0) dxx = np.max(odimxv0) dyn = np.min(odimyv0) dyx = np.max(odimyv0) print gen.infmsg print ' ' + fname + ": for '" + hfn + "' ________" print ' values min:', vn, 'max:', vx print ' dimx min:', dxn, 'max:', dxx print ' dimy min:', dyn, 'max:', dyx if dxn == 0. and dxx == 0. and dyn == 0. and dyx == 0.: print errormsg print ' ' + fname + ': wrong boundaries from continuos field !!' print ' all are zero !!' quit(-1) if hfn == 'cont': if not gen.searchInlist(onc.dimensions, dvarxn): print errormsg print ' ' + fname + ": file '" + ncfilen + "' does not have " + \ "dimension '" + dvarxn + "' for final x-axis in figure !!" print ' available ones: ', onc.dimensions.keys() quit(-1) if not gen.searchInlist(onc.dimensions, dvaryn): print errormsg print ' ' + fname + ": file '" + ncfilen + "' does not have " + \ "dimension '" + dvaryn + "' for final y-axis in figure !!" print ' available ones: ', onc.dimensions.keys() quit(-1) # Getting the right shape of dimensions gdimx = len(onc.dimensions[dvarxn]) gdimy = len(onc.dimensions[dvaryn]) if vals.shape[1] == gdimx: contv = vals[:] else: contv = vals[:].transpose() odxv = np.zeros((gdimy,gdimx), dtype=np.float) odyv = np.zeros((gdimy,gdimx), dtype=np.float) if len(odimxv0.shape) == 2: if odimxv0.shape[1] == gdimx: odxv = odimxv0[:] else: odxv = odimxv0.transpose() else: for k in range(gdimy): odxv[k,:] = odimxv0[:] if len(odimyv0.shape) == 2: if odimyv0.shape[0] == gdimy: odyv = odimyv0[:] else: odyv = odimyv0.transpose() else: for k in range(gdimx): odyv[:,k] = odimyv0[:] diminfo = {} diminfo['units'] = [odimxu, odimyu] diminfo['names'] = [gen.variables_values(vdimxn)[0], \ gen.variables_values(vdimyn)[1]] varinfo = {} varinfo['units'] = varunits varinfo['name'] = vnamesfig # Absolute xtremes for the plot absxn = dxn absxx = dxx absyn = dyn absyx = dyx contxynx = [dxn, dxx, dyn, dyx] else: discvarv = [] discx = [] discy = [] # Assuming that discrete values are masked if type(vals) != type(gen.mamat): madiscvarv = ma.masked_array(vals) else: madiscvarv = vals if len(vals.shape) == 1: if type(madiscvarv.mask) == type(np.True_): discvarv = list(madiscvarv[:]) discx = list(odimxv0[:]) discy = list(odimyv0[:]) else: for i in range(vals.shape[0]): if not madiscvarv.mask[i]: discvarv.append(madiscvarv[i]) discx.append(odimxv0[i]) discy.append(odimyv0[i]) elif len(vals.shape) == 2: # Getting 2D dimensions [d2Dx, d2Dy] = np.meshgrid(odimxv0, odimyv0) # Checking for flipping axis? if d2Dx.shape[0] == vals.shape[1] and d2Dx.shape[1] == vals.shape[0]: print ' rotating values !' #madiscvarv = madiscvarv.transpose() d2Dx = d2Dx.transpose() d2Dy = d2Dy.transpose() # vals have to be 2D otherwise... ? dx = madiscvarv.shape[1] dy = madiscvarv.shape[0] for j in range(dy): for i in range(dx): if not madiscvarv.mask[j,i]: discvarv.append(madiscvarv[j,i]) discx.append(d2Dx[j,i]) discy.append(d2Dy[j,i]) else: # Values have to be 1D or 2D print errormsg print ' ' + fname + ": disc. values have to be 1D or 2D !!" print ' provided shape:', vals.shape, 'for slice:', dimvals quit(-1) Ndiscvals = len(discvarv) print ' getting:', Ndiscvals, 'discrete values' discv = np.zeros((Ndiscvals,3), dtype=np.float) discv[:,0] = discx[:] discv[:,1] = discy[:] discv[:,2] = discvarv[:] # Absolute xtremes for the plot absxn = np.max([absxn,dxn]) absxx = np.min([absxx,dxx]) absyn = np.max([absyn,dyn]) absyx = np.min([absyx,dyx]) onc.close() availplotrng = ['strict', 'sponge', 'fullcontinuous'] if plotrange[0:6] == 'strict': graphnx = [absxn, absxx, absyn, absyx] elif plotrange[0:6] == 'sponge': dlon = np.float(plotrange.split(',')[1]) dlat = np.float(plotrange.split(',')[2]) graphnx = [absxn-dlon, absxx+dlon, absyn-dlat, absyx+dlat] elif plotrange[0:14] == 'fullcontinuous': graphnx = contxynx elif plotrange[0:9] == 'lonlatbox': lonSW = np.float(plotrange.split(',')[1]) latSW = np.float(plotrange.split(',')[2]) lonNE = np.float(plotrange.split(',')[3]) latNE = np.float(plotrange.split(',')[4]) graphnx = [lonSW, lonNE, latSW, latNE] else: print errormsg print ' ' + fname + ": plot range '" + plotrange + "' not ready !!" print ' available ones:', availplotrng quit(-1) print " '" + plotrange + "' limits of the graphic:", graphnx shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if discvals == 'auto': discinfo = ['o', 5., 0.25, '#000000'] else: discinfo = [discvals.split(',')[0], np.float(discvals.split(',')[1]), \ np.float(discvals.split(',')[2]), discvals.split(',')[3]] if mapvalue == 'None': mapvalue = None if colorbarvals == 'auto': colorbarvals = 'rainbow,auto,auto' colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None drw.plot_2Dshad_obssim(discv, contv, odxv, odyv, revals, diminfo, xaxis, yaxis, \ colormapv, shading_nx, varinfo, discinfo, mapvalue, graphnx, figt, kindfig, \ close) return #contfilen = '/home/lluis/estudios/ChemGBsAs/tests/199501/simout_snddiags.nc;ta;time;pres;time|-1,pres|-1' #discfilen = '/home/lluis/estudios/ChemGBsAs/tests/199501/obs/snd/UWyoming_snd_87576.nc;ta;time;pres;time|-1,pres|-1' #values = 'ta:time,bottom_top:Vfix,auto,3600.,auto,Vfix,auto,50.,auto:auto:Srange,Srange:o,5.:obs!&!sim!Ezeiza!airport!sounding:pdf:flip@y:None:yes' #draw_2D_shad_contdisc(contfilen+'@'+discfilen, values, axfig=None, fig=None) def draw_2D_shad_contdisc_time(ncfiles, values, axfig=None, fig=None): """ plotting one continuous fields with shading and another discrete one with points with a time-axis draw_2D_shad_contdisc_time(ncfile, values) ncfiles= [contfilen];[contvarn];[dimtvarn];[dimvvarn];[dimvals]@[discfilen]; [discvarn];[dimtvarn];[dimvvarn];[dimvals] files and variables to use [contfilen]: name of the file with the continuous varible [contvarn]: name of the continuos variable [dimtvarn]: name of the variable with values for the time-dimension [dimvvarn]: name of the variable with values for the variable-dimension [dimvals]: ',' list of [dimname]|[value] values to slice the variable: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [discfilen]: name of the file with the discrete varible [discvarn]: name of the discrete variable * NOTE: limits of the graph will be computed from the continuous variable values=[vnamefs];[varaxis];[timevals];[dimvfmt];[colorbarvals];[sminv],[smaxv]; [discvals];[figt];[kindfig];[reverse];[mapv];[close] [vnamefs]: Name in the figure of the variable to be shaded [varaxis]: axis in the figure for the variable-axis ('x' or 'y') [timevals]: [units]|[kind]|[tfmt]|[label] time labels characteristics [units]: units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces), 'auto' for minutes!since!1949-12-01!00:00:00 [kind]: kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]: desired format (combination of 'C'-style values and LaTeX) [label]: label at the graph ('!' for spaces, combination of 'C'-style values and LaTeX) [dimvfmt]=[[dvs],[dvf],[Ndv],[ordv]: format of the values at variable-axis (or 'auto') [dvs]: style of variable-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dvf]: format of the labels at the var-axis ('auto' for '%5g') [Ndv]: Number of ticks at the var-axis ('auto' for 5) [ordv]: angle of orientation of ticks at the var-axis ('auto' for horizontal) [colorbarvals]=[colbarn],[fmtcolorbar],[orientation] [colorbarn]: name of the color bar [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' ['auto'], 'horizontal') * NOTE: single 'auto' for 'rainbow,%6g,vertical' [smin/axv]: minimum and maximum values for the shading or string for each for: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val),percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val),percentile_(100-val)-median) [discvals]= [type],[size],[lwidth],[lcol] characteristics of the points for the discrete field [type]: type of point. Any marker from matoplib must be filled ! [size]: size of point [lwidth]: width of the line around the point [lcol]: color of the line around the point 'auto': for [type]='o', [size]=5, [lwdith]=0.25, [lcol]='#000000' [figt]: title of the figure ('!' for spaces) [kindfig]: kind of figure output (ps, png, pdf) [reverse]: Transformation of the values * 'transpose': reverse the axes (x-->y, y-->x) * 'flip'@[x/y]: flip the axis x or y [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not """ fname = 'draw_2D_shad_contdisc_time' if values == 'h': print fname + '_____________________________________________________________' print draw_2D_shad_contdisc_time.__doc__ quit() expectargs = '[vnamefs];[varaxis];[timevals];[dimvfmt];[colorbarvals];' + \ '[sminv],[smaxv];[discvals];[figt];[kindfig];[reverse];[mapv];[close]' drw.check_arguments(fname,values,expectargs,';') vnamesfig = values.split(';')[0] varaxis = values.split(';')[1] timevals = values.split(';')[2].split('|') dimvfmt = values.split(';')[3] colorbarvals = values.split(';')[4] shadminmax = values.split(';')[5] discvals = values.split(';')[6] figt = values.split(';')[7].replace('!',' ') kindfig = values.split(';')[8] revals = values.split(';')[9] mapvalue = values.split(';')[10] close = gen.Str_Bool(values.split(';')[11]) if timevals[0] == 'auto': timevals[0] = 'minutes since 1949-12-01 00:00:00' else: timevals[0] = timevals[0].replace('!',' ') ncs = ncfiles.split('@') filesinf = {} ifile = 0 for nc in ncs: if ifile == 0: hfn = 'cont' else: hfn = 'disc' filesinf[hfn + 'filen'] = nc.split(';')[0] filesinf[hfn + 'varn'] = nc.split(';')[1] filesinf[hfn + 'dimtvn'] = nc.split(';')[2] filesinf[hfn + 'dimvvn'] = nc.split(';')[3] filesinf[hfn + 'dimvals'] = nc.split(';')[4].replace('|',':') ifile = ifile + 1 for hfn in ['cont', 'disc']: ncfilen = filesinf[hfn + 'filen'] varn = filesinf[hfn + 'varn'] vdimtn = filesinf[hfn + 'dimtvn'] vdimvn = filesinf[hfn + 'dimvvn'] dimvals = filesinf[hfn + 'dimvals'] if not os.path.isfile(ncfilen): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + "' does " + \ "not exist !!" quit(-1) onc = NetCDFFile(ncfilen, 'r') if not onc.variables.has_key(varn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfilen + \ "' does not have variable '" + varn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) # Variables' values ovar = onc.variables[varn] vals, dims = drw.slice_variable(ovar, dimvals.replace(',','|')) # Values have to be 2D (might not be true for disc?) if len(vals.shape) != 2: print errormsg print ' ' + fname + ": values have to be 2D !!" print ' provided shape:', vals.shape, 'for slice:', dimvals quit(-1) if drw.searchInlist(ovar.ncattrs(),'units'): varunits = ovar.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' # dimensions dimnamesv = [vdimtn, vdimvn] if not onc.variables.has_key(vdimtn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfile + \ "' does not have time-dimension variable '" + vdimtn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) if not onc.variables.has_key(vdimvn): print errormsg print ' ' + fname + ": '" + hfn + "' file '" + ncfile + \ "' does not have var-dimension variable '" + vdimvn + "' !!" varns = sorted(onc.variables.keys()) print ' available ones:', varns quit(-1) if vdimtn != 'WRFtime': objdimt = onc.variables[vdimtn] if drw.searchInlist(objdimt.ncattrs(),'units'): odimxu = objdimt.getncattr('units') else: print erormsg print ' ' +fname+": variable dimension '" + vdimxn + "' without units!!" quit(-1) else: objdimt = onc.variables['Times'] timev, odimxv = ncvar.compute_WRFtime(objdimt[:]) odimxv0 = ncvar.nericNCvariable_Dict({'time':timev.shape[0]}, ['time'], \ 'time', 'time', 'Time', tunits, timev) objdimv = onc.variables[vdimvn] if drw.searchInlist(objdimv.ncattrs(),'units'): odimvu = objdimv.getncattr('units') else: print warnmsg print ' ' +fname+": variable dimension '" + vdimvn + "' without units!!" odimvu = '-' odimxv0, odimyv0 = drw.dxdy_lonlatDIMS(objdimt[:], objdimv[:], \ objdimt.dimensions, objdimv.dimensions, dimvals.replace(':','|').split(','),\ False) # Getting same times odimxv0 = gen.coincident_CFtimes(odimxv0, timevals[0], odimxu) # Some statistics vn = np.min(vals) vx = np.max(vals) dxn = np.min(odimxv0) dxx = np.max(odimxv0) dyn = np.min(odimyv0) dyx = np.max(odimyv0) print gen.infmsg print ' ' + fname + ": for '" + hfn + "' ________" print ' values min:', vn, 'max:', vx print ' dimx min:', dxn, 'max:', dxx print ' dimy min:', dyn, 'max:', dyx if hfn == 'cont': # Getting time initialy as x-axis the right shape of dimensions gdimx = odimxv0.shape[0] if vals.shape[0] != gdimx: gdimy = vals.shape[0] else: gdimy = vals.shape[1] if vals.shape[1] == gdimx: contv = vals[:] else: contv = vals[:].transpose() odxv = np.zeros((gdimy,gdimx), dtype=np.float) odyv = np.zeros((gdimy,gdimx), dtype=np.float) if len(odimxv0.shape) == 2: if odimxv0.shape[1] == gdimx: odxv = odimxv0[:] else: odxv = odimxv0.transpose() else: for k in range(gdimy): odxv[k,:] = odimxv0[:] if len(odimyv0.shape) == 2: if odimyv0.shape[0] == gdimy: odyv = odimyv0[:] else: odyv = odimyv0.transpose() else: for k in range(gdimx): odyv[:,k] = odimyv0[:] diminfo = {} diminfo['units'] = [timevals[0], odimvu] diminfo['names'] = [gen.variables_values(vdimtn)[0], \ gen.variables_values(vdimvn)[1]] varinfo = {} varinfo['units'] = varunits varinfo['name'] = vnamesfig # Absolute xtremes for the plot absxn = dxn absxx = dxx absyn = dyn absyx = dyx else: discvarv = [] discx = [] discy = [] # Assuming that discrete values are masked if type(vals) != type(gen.mamat): madiscvarv = ma.masked_array(vals) else: madiscvarv = vals # Getting 2D dimensions [d2Dx, d2Dy] = np.meshgrid(odimxv0, odimyv0) # Checking for flipping axis? if d2Dx.shape[0] == vals.shape[1] and d2Dx.shape[1] == vals.shape[0]: print ' rotating values !' #madiscvarv = madiscvarv.transpose() d2Dx = d2Dx.transpose() d2Dy = d2Dy.transpose() # vals have to be 2D otherwise... ? dx = madiscvarv.shape[1] dy = madiscvarv.shape[0] for j in range(dy): for i in range(dx): if not madiscvarv.mask[j,i]: discvarv.append(madiscvarv[j,i]) discx.append(d2Dx[j,i]) discy.append(d2Dy[j,i]) Ndiscvals = len(discvarv) print ' getting:', Ndiscvals, 'discrete values' discv = np.zeros((Ndiscvals,3), dtype=np.float) discv[:,0] = discx[:] discv[:,1] = discy[:] discv[:,2] = discvarv[:] # Absolute xtremes for the plot absxn = np.max([absxn,dxn]) absxx = np.min([absxx,dxx]) absyn = np.max([absyn,dyn]) absyx = np.min([absyx,dyx]) onc.close() graphnx = [absxn, absxx, absyn, absyx] print 'limits of the graphic:', graphnx shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if discvals == 'auto': discinfo = ['o', 5., 0.25, '#000000'] else: discinfo = [discvals.split(',')[0], np.float(discvals.split(',')[1]), \ np.float(discvals.split(',')[2]), discvals.split(',')[3]] if mapvalue == 'None': mapvalue = None if colorbarvals == 'auto': colorbarvals = 'rainbow,auto,auto' colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvals,',') colormapv = [colbarn, fmtcolbar, colbaror] # format axes if dimvfmt == 'auto': axfmt = 'auto,auto,auto,auto,auto,auto,auto,auto' else: axfmt = 'auto,auto,auto,auto,' + dimvfmt xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(axfmt, ',') valaxis = [ystyl, yaxf, Nyax, yaxor] if revals == 'None': revals = None # time values timeinfo = {} timeinfo['units'] = timevals[0] timeinfo['name'] = timevals[3].replace('!', ' ') timeinfo['tpos'], timeinfo['tlabs'] = drw.CFtimes_plot([dxn, dxx], timevals[0], \ timevals[1], timevals[2]) drw.plot_2Dshad_obssim_time(discv, contv, odxv, odyv, varaxis, revals, diminfo, \ valaxis, timeinfo, colormapv, shading_nx, varinfo, discinfo, mapvalue, graphnx,\ figt, kindfig, close) return #contfilen = '/home/lluis/estudios/ChemGBsAs/tests/199501/simout_snddiags.nc;ta;time;pres;time|-1,pres|-1' #discfilen = '/home/lluis/estudios/ChemGBsAs/tests/199501/obs/snd/UWyoming_snd_87576.nc;ta;time;pres;time|-1,pres|-1' #values = 'ta;y;auto|exct,12,h|%d$^{%H}$|time!($[DD]^{[HH]}$);Vfix,auto,50.,auto;auto;Srange,Srange;auto;obs!&!sim!Ezeiza!airport!sounding;pdf;flip@y;None;yes' #draw_2D_shad_contdisc_time(contfilen+'@'+discfilen, values, axfig=None, fig=None) def draw_multiWindRose(ncfiles, values): """ Function to plot multiple wind rose (from where the dinw blows) ncfiles='#' separated list of [filen]@[dimvals]@[uvarn],[vvarn] [filen]: name of the file [dimvals]: ';' list of [dimn]|[dvalue] dimension and slice along dimension to retrieve the winds [dimn]: name of the dimension [dvalue]: value for the slice in the given dimension * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg],[end],[freq] slice from [beg] to [end] every [freq] * NOTE, no dim name all the dimension size No value takes all the range of the dimension [uvarn],[vvarn]: name of the x and y wind components values=[kindRose]:[labels]:[imgtit]:[imgkind]:[kindlabelsangle]:[close] [kindRose]: [kind];[value1];[...[valueN]] Kind of rose to plot and values of the kind 'linepoint': consecutive (time, height, level, ...) line-point angle and speed values. Three different species 'multicol': line-marker color changing according to a third variable [extravarn] values: [extravarn];[lines];[markers];[freqmarkers];[colbar];[Nang] 'multicoltime': line-marker color changing according to a temporal variable [extravarn] values: [extravarn];[lines];[markers];[colbar];[Nang];[timekind];[timefmt];[timelabel] 'singlecol': same color for the line-marker values: [lines];[markers];[cols];[Nang] 'scatter': a marker for each wind at different values (time, height, level, ...). Three different species 'multicol':marker color changing according to a third variable [extravarn] values: [extravarn];[markers];[colbar];[Nang] 'multicoltime': marker color changing according to a temporal variable [extravarn] values: [extravarn];[lines];[markers];[colbar];[Nang];[timekind];[timefmt];[timelabel] 'singlecol': same color for all the markers values: [markers];[cols];[Nang] meaning (where apply): [extravarn]: name of the extra variable [lines]: '@' separated list of type of lines (matplotlib ref) [markers]: '@' separated list of type of markers to use (matplotlib ref) [freqmarkers]: '@' separated list of frequency of drawing markers ('auto' for every 10) [cols] = '@' separated list of colors ('#[RR][GG][BB]) [colbar]: name of the colorbar ('auto' for 'spectral_r') [Nang]: number of angles to divide the rose ('auto' for 8) [Nspeed]: number of speeds to divide the wind speed distribution ('auto' for 8) [maxspeed]: maximum wind speed used to compute the frequency of distributions ('auto' for 40.) [timekind]; time computation of ticks 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [timefmt]; desired format of time labels (C-like) [timelabel]; label of time colorbar at the graph ('!' for spaces) labels: ',' separated list of labels for the legend ('None' for no label) imgtit: title of the image ('!' for spaces) imgkind: kind of file output of the image (ps, pns, pdf, ...) kindlabelsangle: kind of labels for the angles of the wind Rose 'cardianals': Following combinations of 'N', 'E', 'S', 'W' according to Nang close: whether figure should be closed or not """ fname = 'draw_multiWindRose' if values == 'h': print fname + '_____________________________________________________________' print draw_multiWindRose.__doc__ quit() expectargs = '[kindRose]:[labels]:[imgtit]:[imgkind]:[kindlabelsangle]:' + \ '[close]' drw.check_arguments(fname,values,expectargs,':') dimvariables = values.split(':')[0] KindRose = values.split(':')[0] labels = values.split(':')[1].split(',') imgtit = values.split(':')[2].replace('!',' ') imgkind = values.split(':')[3] kindlabelsangle = values.split(':')[4] close = gen.Str_Bool(values.split(':')[5]) windrosekinds = ['linepoint', 'scatter'] if KindRose.find(';') == -1: print errormsg print ' ' + fname + ": all types '" + KindRose + "' require extra values !!" print " 'linepoint';'singlecol';[line];[marker];[col];[Nang]" print " 'linepoint';'multiecoltime';[extravar];[line];[marker];[colbar];"+\ "[Nang];[timekind];[timefmt];[timelabel]" print " 'linepoint';'multiecol';[extravar];[line];[marker];[colbar];[Nang]" print " 'scatter';'multiecol';[extravar];[marker];[colbar]" print " 'scatter';'multiecoltime';[extravar];[marker];[colbar];[Nang];" + \ "[timekind];[timefmt];[timelabel]" print " 'scatter';'singlecol';[marker];[col];[Nang]" print " values provided: '" + KindRose + "'" quit(-1) lpvals = KindRose.split(';') lkind = lpvals[1] extravarn = None if lpvals[0] == 'linepoint': if lkind == 'multicol': if len(lpvals) != 8: print errormsg print ' ' + fname + ": line-point kind '" + lkind + "' requires " + \ "6 values !!" print " 'multiecol';[extravarn];[line];[marker];[freqmarker];" + \ "[colbar];[Nang]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] elif lkind == 'multicoltime': if len(lpvals) != 10: print errormsg print ' '+fname + ": scatter kind '"+lkind+ "' requires 9 values !!" print " 'multicol';[extravarn];[line];[marker];[colbar];[Nang];"+ \ "[timekind];[timefmt];[timelabel]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] timekind = lpvals[6] timefmt = lpvals[7] elif lkind == 'singlecol': if len(lpvals) != 6: print errormsg print ' '+fname+": line-point kind '"+lkind+ "' requires 5 values !!" print " 'singlecol';[line];[marker];[col];[Nang]" print ' provided:', lpvals quit(-1) else: print errormsg print ' ' + fname + ": line-point kind '" + lkind + "' not ready !!" print ' ready ones: multicol, multicoltime, singlecol ' quit(-1) elif lpvals[0] == 'scatter': if lkind == 'multicol': if len(lpvals) != 6: print errormsg print ' '+fname+": scatter kind '"+lkind+"' requires 5 values !!" print " 'multicol';[extravarn];[marker];[colbar];[Nang]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] elif lkind == 'multicoltime': if len(lpvals) != 9: print errormsg print ' ' + fname + ": scatter kind '"+lkind+"' requires 8 values !!" print " 'multicol';[extravarn];[marker];[colbar];[Nang];" + \ "[timekind];[timefmt];[timelabel]" print ' provided:', lpvals quit(-1) extravarn = lpvals[2] timekind = lpvals[5] timefmt = lpvals[6] elif lkind == 'singlecol': if len(lpvals) != 5: print errormsg print ' '+fname + ": scatter kind '"+lkind+ "' requires 4 values !!" print " 'singlecol';[marker];[col];[Nang]" print ' provided:', lpvals quit(-1) else: print errormsg print ' ' + fname + ": scatter kind '" + lkind + "' not ready !!" print ' ready ones: multicol, multicoltime, singlecol ' quit(-1) else: print gen.errormsg print ' ' + fname + ": kind of WindRose '" + lpvals[0] + "' not ready !!" print ' available ones:', windrosekinds quit(-1) angles = [] speeds = [] extravs = [] fvarns = ncfiles.split('#') for fvn in fvarns: ncfile = fvn.split('@')[0] dimvariables = fvn.split('@')[1] uvarn = fvn.split('@')[2].split(',')[0] vvarn = fvn.split('@')[2].split(',')[1] if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not exist !!" quit(-1) onc = NetCDFFile(ncfile,'r') oncvars0 = onc.variables.keys() oncvars = oncvars0 + [] oncvars.sort() if not gen.searchInlist(oncvars,uvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable " + \ "u_wind '" + uvarn + "' !!" print ' available variables:', oncvars quit(-1) if not gen.searchInlist(oncvars,vvarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have variable " + \ "v_wind '" + vvarn + "' !!" print ' available variables:', oncvars quit(-1) if extravarn is not None: if not gen.searchInlist(oncvars,extravarn): print errormsg print ' ' + fname + ": file '" + ncfile + "' does not have extra " + \ "variable '" + extravarn + "' !!" print ' available variables:', oncvars quit(-1) # Getting the slice dictslice = {} for dnv in dimvariables.split(';'): dimn = dnv.split('|')[0] dimv = dnv.split('|')[1] if dimv.find(',') != -1: dictslice[dimn] = list(np.array(dimv.split(','), dtype=int)) else: dictslice[dimn] = int(dimv) # Getting variables ou = onc.variables[uvarn] sliceu, du = ncvar.SliceVarDict(ou, dictslice) uv = ou[tuple(sliceu)] ov = onc.variables[vvarn] slicev, dv = ncvar.SliceVarDict(ov, dictslice) vv = ov[tuple(slicev)] wunit = ov.getncattr('units') if extravarn is not None: oe = onc.variables[extravarn] slicee, de = ncvar.SliceVarDict(oe, dictslice) extrav = oe[tuple(slicee)] dime = extrav.shape[0] extraunit = oe.getncattr('units') else: dime = uv.shape[0] extrav = None extraunit = None onc.close() # Wind Rose is with the winds from where they come from! ang = np.arctan2(-vv, -uv) speed = np.sqrt(uv*uv + vv*vv) # re-setting to [0, 2pi] ang = np.where(ang <= 0., 2.*np.pi+ang, ang) ang = np.where(np.mod(ang,2.*np.pi) == 0., 0., ang) angles.append(ang) speeds.append(speed) if extrav is not None: extravs.append(extrav) drw.plot_multiWindRose(angles, speeds, dime, lpvals, kindlabelsangle, wunit, \ labels, imgtit, imgkind, 'multi_WindRose', close, evs=extravs, eunit=extraunit) return #filenames='/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/sounding_uava_10868.nc@pres|-1;time|1@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_38lev.nc@bottom_top|-1;time|12@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_50lev.nc@bottom_top|-1;time|12@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_50lev_assigned.nc@bottom_top|-1;time|12@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_80lev.nc@bottom_top|-1;time|12@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_120lev.nc@bottom_top|-1;time|12@ua,va#' + \ # '/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/select/out/simout_vars_sndpt_10868_NOaerosol.nc@bottom_top|-1;time|12@ua,va' #wrkind='linepoint;multicol;pres;-;x;spectral;auto' #figvalues=wrkind + ':obs,38lev,50lev,50leva,80lev,120lev:WindRose!obs!,!sim!comparison!on!2012/10/23!12!UTC:png:auto:True' #draw_multiWindRose(filenames, figvalues) def draw_stations_map(filename, values): """ Function to plot a map with the stations filename= name of ASCII file with the values of the stations as: ('#' comments) [sttype],[label],[lon],[lat],[height] [sttype]: type of the station [label]: label of the station (LaTeX format, 'None' for no label) [lon]: longitude of the station [lat]: latitude of the station [height]: height of the station values=[stypevals]:[mapvals]:[SWNEbox]:[imgtit]:[imgkind]:[close] stypevals='@' separated list of [sttype]|[marker]|[color]|[size]|[fontsize] [sttype]: label of the type of the marker [marker]: type of the marker [color]: color of the marker [size]: size of the marker mapvals= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert-conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full SWNEbox: ',' list of the vertexs of the map [SWlon, NElon, SWlat, NElat] 'lonlatxtrms': to use the extremes of the lon,lat stations imgtit: title of the image ('!' for spaces) imgkind: kind of file output of the image (ps, pns, pdf, ...) close: whether figure should be closed or not """ fname = 'draw_stations_map' if values == 'h': print fname + '_____________________________________________________________' print draw_stations_map.__doc__ quit() expectargs = '[stypevals]:[mapvals]:[SWNEbox]:[imgtit]:[imgkind]:[close]' drw.check_arguments(fname,values,expectargs,':') stypevals = values.split(':')[0].split('@') mapvals = values.split(':')[1] SWNEboxS = values.split(':')[2] imgtit = values.split(':')[3].replace('!', ' ') imgkind = values.split(':')[4] close = gen.Str_Bool(values.split(':')[5]) if not os.path.isfile(filename): print errormsg print ' ' + fname + ": file '" + filename + "' does not exist !!" quit(-1) # Getting stations values styypes = {} sttyps = [] for stvs in stypevals: stv = stvs.split('|') styp = stv[0] smk = stv[1] scol = stv[2] ssz = np.float(stv[3]) fsz = stv[4] styypes[styp] = [smk, scol, ssz, fsz] sttyps.append(styp) ofile = open(filename, 'r') dicstations = {} nlonst = 100000. xlonst = -100000. nlatst = 100000. xlatst = -100000. for line in ofile: if line[0:1] != '#' and len(line) > 1: linev = line.replace('\n','').replace('\r','').split(',') ltyp = linev[0] lid = linev[1] llon = np.float(linev[2]) llat = np.float(linev[3]) lhgt = np.float(linev[4]) if nlonst > llon: nlonst=llon if xlonst < llon: xlonst=llon if nlatst > llat: nlatst=llat if xlatst < llat: xlatst=llat if not gen.searchInlist(sttyps, ltyp): print errormsg print ' ' + fname + ": station type '" + ltyp + "' not ready !!" print ' available ones:', sttyps quit(-1) typsv = styypes[ltyp] dicstations[lid] = [llon, llat, lhgt, lid, typsv[0], typsv[1], typsv[2], \ typsv[3]] ofile.close() if SWNEboxS == 'lonlatxtrms': SWNEbox = [nlonst, xlonst, nlatst, xlatst] else: SWNEbox = gen.str_list_k(SWNEboxS, ',', 'F') Nd = 100 nlon = SWNEbox[0] xlon = SWNEbox[1] nlat = SWNEbox[2] xlat = SWNEbox[3] ddlon = (xlon - nlon)/Nd ddlat = (xlat - nlat)/Nd if SWNEboxS == 'lonlatxtrms': SWNEbox = [nlonst-ddlon, xlonst+ddlon, nlatst-ddlat, xlatst+ddlat] nlon = SWNEbox[0] xlon = SWNEbox[1] nlat = SWNEbox[2] xlat = SWNEbox[3] lon1D = np.arange(nlon, xlon+ddlon, ddlon) lat1D = np.arange(nlat, xlat+ddlat, ddlat) drw.plot_stations_map(dicstations, lon1D, lat1D, mapvals, SWNEbox, ddlon, imgtit,\ imgkind, close) return def draw_WRFeta_levels(filenames, values): """ Function to plot vertical levels from WRF wrfinput_d[nn] file filenames= ',' list of name of files to use values = [labs]:[colors]:[markers]:[legvals]:[imgtit]:[imgkind]:[newfile]:[close] [labs]= ',' list of labels for the plot (LaTeX like) [colors]= ',' list of colors for the lines ('auto' for automatic) [markers]= '@' list of markers for the lines ('auto' for automatic) [legvals]=[loclegend]|[fonstsize]|[ncol] values for the legend [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend ('auto' for 12) [ncol]: number of columns ('auto' for 1) [imgtit]= title of the image ('!' for spaces) [imgkind]= kind of file output of the image (ps, pns, pdf, ...) [newfile]= whether the possible pre-existing file with the required data be should removed or not ('yes/no') [close]= whether figure should be closed or not * NOTE: A multi-panel plot will be drawn called `WRFeta_levels.png', and also an individual plot for each panel will be produced """ import subprocess as sub fname = 'draw_WRFeta_levels' if values == 'h': print fname + '_____________________________________________________________' print draw_WRFeta_levels.__doc__ quit() expectargs = '[labs]:[colors]:[markers]:[legvals]:[imgtit]:[imgkind]:' + \ '[newfile]:[close]' drw.check_arguments(fname,values,expectargs,':') labs = values.split(':')[0].split(',') colors = gen.auto_val_list(values.split(':')[1].split(','), len(labs), \ drw.colorsauto) markers = gen.auto_val_list(values.split(':')[2].split('@'), len(labs), \ drw.pointkindsauto) legvals = values.split(':')[3] imgtit = values.split(':')[4].replace('!', ' ') imgkind = values.split(':')[5] newfile = gen.Str_Bool(values.split(':')[6]) close = gen.Str_Bool(values.split(':')[7]) files = filenames.split(',') Nfiles = len(files) allhgtsea = [] allxhgt = [] allpsea = [] allpxhgt = [] allhgtxhgt = [] alldhgtsea = [] alldhgtxhgt = [] alldpsea = [] alldpxhgt = [] alletaw = [] alletau = [] alldimz = [] # Creation of a file with the data titS = imgtit.replace(' ','-') ofilen = 'WRFeta_levels_' + titS + '.nc' # Removing pre-existing file if newfile: if os.path.isfile(ofilen): print ' ' + fname + ": removing pre-existing file with required '" + \ "data '" + ofilen + "' !!" sub.call('rm ' + ofilen, shell=True) if not os.path.isfile(ofilen): maxdz = -10 for filen in files: if not os.path.isfile(filen): print errormsg print ' ' + fname + ": file '" + filen + "' does not exist !!" quit(-1) onc = NetCDFFile(filen, 'r') ophb = onc.variables['PHB'] opb = onc.variables['PB'] olandseamask = onc.variables['LANDMASK'] ohgt = onc.variables['HGT'] oznw = onc.variables['ZNW'] oznu = onc.variables['ZNU'] dimx = ophb.shape[3] dimy = ophb.shape[2] dimz = ophb.shape[1] dimt = ophb.shape[0] dimzp = opb.shape[1] if maxdz < dimz: maxdz = dimz for j in range(10,dimy): for i in range(10,dimx): if olandseamask[0,j,i] == 0: hgtssea = ophb[0,:,j,i]/9.8 pssea = opb[0,:,j,i] break maxhgt = np.max(ohgt[0,:,:]) ijxhgt = gen.index_mat(ohgt[0,:,:], maxhgt) hgtsxhgt = ophb[0,:, ijxhgt[0], ijxhgt[1]]/9.8 psxhgt = opb[0,:, ijxhgt[0], ijxhgt[1]] allhgtsea.append(hgtssea) allxhgt.append(maxhgt) allhgtxhgt.append(hgtsxhgt) allpsea.append(pssea) allpxhgt.append(psxhgt) alldhgtsea.append(hgtssea[1:dimz]-hgtssea[0:dimz-1]) alldhgtxhgt.append(hgtsxhgt[1:dimz]-hgtsxhgt[0:dimz-1]) alldpsea.append(pssea[0:dimzp-1]-pssea[1:dimzp]) alldpxhgt.append(psxhgt[0:dimzp-1]-psxhgt[1:dimzp]) alletaw.append(oznw[0,:]) alletau.append(oznu[0,:]) alldimz.append(dimz) onc.close() print infmsg print ' ' + fname + ": creation of file '" + ofilen + "' to keep required"+ \ "values to plot !!" onewnc = NetCDFFile(ofilen, 'w') # Dimensions newdim = onewnc.createDimension('Nfiles', Nfiles) newdim = onewnc.createDimension('Lstring', 250) newdim = onewnc.createDimension('evert', maxdz) # Variabledimensions newvar = onewnc.createVariable('Nfiles', 'c', ('Nfiles', 'Lstring')) ncvar.writing_str_nc(newvar, files, 250) ncvar.basicvardef(newvar,'files','Files used to retrieve data','-') newvar = onewnc.createVariable('evert_file', 'i', ('Nfiles')) ncvar.basicvardef(newvar,'evert_file','number vertical layers per file','-') newvar[:] = alldimz # Variables newvar = onewnc.createVariable('hgtsea', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'hgtsea','heights above sea point', 'm') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]] = allhgtsea[iff] newvar = onewnc.createVariable('pressea', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'pressea','pressures above sea point', 'Pa') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-1] = allpsea[iff] newvar = onewnc.createVariable('hgtmax', 'f', ('Nfiles')) ncvar.basicvardef(newvar,'hgtmax','maximum height', 'm') newvar[:] = allxhgt newvar = onewnc.createVariable('hgtxhgt', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'hgtxhgt','heights above maximum height', 'm') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]] = allhgtxhgt[iff] newvar = onewnc.createVariable('presxhgt', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'presxhgt','pressures above maximum height', 'Pa') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-1] = allpxhgt[iff] onewnc.sync() newvar = onewnc.createVariable('dhgtsea', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'dhgtsea','delta heights above sea point', 'm') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-1] = alldhgtsea[iff] newvar = onewnc.createVariable('dhgtxhgt', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'dhgtxhgt','delta heights above maximum height', 'm') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-1] = alldhgtxhgt[iff] newvar = onewnc.createVariable('dpressea', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'dpressea','delta pressures above sea point', 'Pa') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-2] = alldpsea[iff] newvar = onewnc.createVariable('dpresxhgt', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'dpresxhgt','delta pressures above maximum height', \ 'Pa') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-2] = alldpxhgt[iff] newvar = onewnc.createVariable('eta_full', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'eta_full','full eta layers', '-') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]] = alletaw[iff] newvar = onewnc.createVariable('eta_half', 'f', ('Nfiles', 'evert'), \ fill_value=gen.fillValueF) ncvar.basicvardef(newvar,'eta_half','half eta layers', '-') for iff in range(Nfiles): newvar[iff,0:alldimz[iff]-1] = alletau[iff] onewnc.sync() onewnc.close() print fname + ": succesfull written of file '" + ofilen + "' with all data !!" else: print fname + ": readding existing file '" + ofilen + "' with all data !!" print " if a new file is required set variable 'newfile' to 'yes'" onc = NetCDFFile(ofilen, 'r') ovar = onc.variables['hgtsea'] allhgtseav = ovar[:] ovar = onc.variables['pressea'] allpseav = ovar[:] ovar = onc.variables['hgtmax'] allxhgtv = ovar[:] ovar = onc.variables['hgtxhgt'] allhgtxhgtv = ovar[:] ovar = onc.variables['presxhgt'] allpxhgtv = ovar[:] ovar = onc.variables['dhgtsea'] alldhgtseav = ovar[:] ovar = onc.variables['dhgtxhgt'] alldhgtxhgtv = ovar[:] ovar = onc.variables['dpressea'] alldpseav = ovar[:] ovar = onc.variables['dpresxhgt'] alldpxhgtv = ovar[:] ovar = onc.variables['eta_full'] alletawv = ovar[:] ovar = onc.variables['eta_half'] alletauv = ovar[:] onc.close() for iff in range(Nfiles): if type(allhgtseav[iff,:]) == type(gen.mamat): allhgtsea.append(allhgtseav[iff,:].compressed()) allxhgt.append(allxhgtv[iff]) allhgtxhgt.append(allhgtxhgtv[iff,:].compressed()) allpsea.append(allpseav[iff,:].compressed()) allpxhgt.append(allpxhgtv[iff,:].compressed()) alldhgtsea.append(alldhgtseav[iff,:].compressed()) alldhgtxhgt.append(alldhgtxhgtv[iff,:].compressed()) alldpsea.append(alldpseav[iff,:].compressed()) alldpxhgt.append(alldpxhgtv[iff,:].compressed()) alletaw.append(alletawv[iff,:].compressed()) alletau.append(alletauv[iff,:].compressed()) else: allhgtsea.append(allhgtseav[iff,:]) allxhgt.append(allxhgtv[iff]) allhgtxhgt.append(allhgtxhgtv[iff,:]) allpsea.append(allpseav[iff,:]) allpxhgt.append(allpxhgtv[iff,:]) alldhgtsea.append(alldhgtseav[iff,:]) alldhgtxhgt.append(alldhgtxhgtv[iff,:]) alldpsea.append(alldpseav[iff,:]) alldpxhgt.append(alldpxhgtv[iff,:]) alletaw.append(alletawv[iff,:]) alletau.append(alletauv[iff,:]) # Legend locleg, legfontsize, legncol = drw.legend_values(legvals,'|') drw.plot_WRFeta_levels(allhgtsea, allpsea, allxhgt, allhgtxhgt, allpxhgt, \ alldhgtsea, alldhgtxhgt, alldpsea, alldpxhgt, alletaw, alletau, labs, colors, \ markers, [locleg, legfontsize, legncol], imgtit, imgkind, close) # Individual plots drw.plot_indiv_WRFeta_levels(allhgtsea, allpsea, allxhgt, allhgtxhgt, allpxhgt, \ alldhgtsea, alldhgtxhgt, alldpsea, alldpxhgt, alletaw, alletau, labs, colors, \ markers, [locleg, legfontsize, legncol], imgtit, imgkind, close) return # foldn='/media/lluis/ExtDiskC_ext3/DATA/estudios/FPS_Alps/additional/IOP/sims/wrfinput_select/' #fils=foldn + '120lev_cdxwrf2/simin_vars.nc,' + foldn + '120lev_assigned/simin_vars.nc,' + foldn + \ # '80lev_cdxwrf2/simin_vars.nc,' + foldn + '80lev_assigned/simin_vars.nc,' + foldn + \ # '50lev_cdxwrf2/simin_vars.nc,' + foldn + '50lev_assigned/simin_vars.nc,' + foldn + \ # '38lev_cdxwrf2/simin_vars.nc,' + foldn + '38lev_assigned/simin_vars.nc' #vals='120lev,120leva,80lev,8leva,50lev,50leva,38lev,38leva:auto:auto:0|4|2:FPS!Alps!vertical!levels:png:no:true' #print fils #draw_WRFeta_levels(fils, vals) def draw_2Dshad_map(ncfile, values, varn, axfig=None, fig=None): """ plotting a shadow field with a background map draw_2Dshad_map(ncfile, values, varn) ncfile= file to use values=[vnamemap];[vnamefs];[dimvals];[dimxvn];[dimyvn];[dimxyfmt]; [colorbarvals];[sminv],[smaxv];[figt];[kindfig];[mapkind];[mapv];[close] [vnamemap]: Name of the variable to be used for map [vnamefs]: Name in the figure of the variable to be shaded [dimvals]: ',' list of [dimname]|[value] telling at which dimension of the variable a given value is required: * [integer]: which value of the dimension * -1: all along the dimension * -9: last value of the dimension * [beg]@[end]@[inc] slice from [beg] to [end] every [inc] * NOTE, no dim name all the dimension size [dimx/yvn]: name of the variables with the values of the final dimensions (x,y) [dimxyfmt]=[dxs],[dxf],[Ndx],[ordx],[dys],[dyf],[Ndy],[ordx]: format of the values at each axis (or 'auto') [dxs]: style of x-axis ('auto' for 'pretty') 'Nfix', values computed at even 'Ndx' 'Vfix', values computed at even 'Ndx' increments 'pretty', values computed following aprox. 'Ndx' at 'pretty' intervals (2.,2.5,4,5,10) [dxf]: format of the labels at the x-axis ('auto' for '%5g') [Ndx]: Number of ticks at the x-axis ('auto' for 5) [ordx]: angle of orientation of ticks at the x-axis ('auto' for horizontal) [dys]: style of y-axis ('auto' for 'pretty') [dyf]: format of the labels at the y-axis ('auto' for '%5g') [Ndy]: Number of ticks at the y-axis ('auto' for 5) [ordy]: angle of orientation of ticks at the y-axis ('auto' for horizontal) [colorbarvals]=[colbarn]#[fmtcolorbar]#[orientation]#[colorbarticks] [colorbarn]: name of the color bar for the values to plot [fmtcolorbar]: format of the numbers in the color bar 'C'-like ('auto' for %6g) [orientation]: orientation of the colorbar ('vertical' (default, by 'auto'), 'horizontal') [colorbarticks]: kind of colorbarticks 'direct': direct values 'time'@[units]|[kind]|[tfmt]|[label] time labels characteristics [units]: units string according to CF conventions ([tunits] since [YYYY]-[MM]-[DD] [[HH]:[MI]:[SS]], '!' for spaces), 'auto' for minutes!since!1949-12-01!00:00:00 [kind]: kind of output 'Nval': according to a given number of values as 'Nval',[Nval] 'exct': according to an exact time unit as 'exct',[tunit]; tunit= [Nunits],[tu]; [tu]= 'c': centuries, 'y': year, 'm': month, 'w': week, 'd': day, 'h': hour, 'i': minute, 's': second, 'l': milisecond [tfmt]: desired format (combination of 'C'-style values and LaTeX) [label]: label at the graph ('!' for spaces, combination of 'C'-style values and LaTeX) [smin/axv]: minimum and maximum value for the shading or: 'Srange': for full range 'Saroundmean@val': for mean-xtrm,mean+xtrm where xtrm = np.min(mean-min@val,max@val-mean) 'Saroundminmax@val': for min*val,max*val 'Saroundpercentile@val': for median-xtrm,median+xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) 'Smean@val': for -xtrm,xtrm where xtrm = np.min(mean-min*@val,max*@val-mean) 'Smedian@val': for -xtrm,xtrm where xtrm = np.min(median-min@val,max@val-median) 'Spercentile@val': for -xtrm,xtrm where xtrm = np.min(median-percentile_(val), percentile_(100-val)-median) [figt]: title of the figure ('|' for spaces) [kindfig]: kind of file for the figure output (ps, eps, png, pdf, ...) [mapfmt] = [cbarmap]|[mapkind]|[lonlatbox] values for the map cbarmap: name of the colorbar for the map mapkind: kind of map to use in the plot 'direct': values are they come 'shadow',[pos],[enhance]: pseudo-shadding from a given location of the sun [pos]: 'N', 'NW' [enhance]: enhance factor for the shading ('auto' for 1./5.) lonlatbox: [lonSW],[latSW],[lonNE],[latNE] to plot only a lon,lat box 'full': for the whole domain [mapv]: map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [close]: Whether figure should be finished or not varn= [varsn] name of the variable to plot with shading """ fname = 'draw_2Dshad_map' if values == 'h': print fname + '_____________________________________________________________' print draw_2Dshad_map.__doc__ quit() availmapkind = ['direct', 'shadow'] availsunpos = ['N', 'NW'] expectargs = '[vnamemap];[vnamefs];[dimvals];[dimxvn];[dimyvn];[dimxyfmt];' + \ '[colorbarvals];[sminv],[smaxv];[figt];[kindfig];[mapfmt];[mapv];[close]' drw.check_arguments(fname,values,expectargs,';') vnamemap = values.split(';')[0] vnamesfig = values.split(';')[1] dimvals= values.split(';')[2].replace('|',':') vdimxn = values.split(';')[3] vdimyn = values.split(';')[4] dimxyf = values.split(';')[5] colorbarvals = values.split(';')[6] shadminmax = values.split(';')[7] figtitle = values.split(';')[8].replace('|',' ') figkind = values.split(';')[9] mapfmt = values.split(';')[10].split('|') mapvalue = values.split(';')[11] close = gen.Str_Bool(values.split(';')[12]) ncfiles = ncfile if not os.path.isfile(ncfiles): print errormsg print ' ' + fname + ': shading file "' + ncfiles + '" does not exist !!' quit(-1) objsf = NetCDFFile(ncfiles, 'r') # Map values if not objsf.variables.has_key(vnamemap): print errormsg print ' ' + fname + ": file does not have map variable '" + vnamemap + "' !!" varns = list(objsf.variables.keys()) varns.sort() print ' available ones:', varns quit(-1) omap = objsf.variables[vnamemap] valsmap, dimsmap = drw.slice_variable(omap, dimvals.replace(',','|')) if len(valsmap.shape) != 2: print errormsg print ' ' + fname + ': map values have to be 2-rank and they are:', \ len(valsmap.shape), '!!' quit(-1) dx = valsmap.shape[1] dy = valsmap.shape[0] mapkind = mapfmt[1] if mapfmt[2] == 'full': lonlatbox = None elif len(mapfmt[2].split(',')) == 4: lonlatbox = [] for lL in mapfmt[2].split(','): lonlatbox.append(np.float(lL)) else: print errormsg print ' ' + fname + ": lonlatbox value '" + mapfmt[2] + "' not ready !!" print ' for a lonlatbox 4 values are required. Values passed:', \ mapfmt[2].splot(',') quit(-1) if mapkind == 'direct': mapv = valsmap[:] elif mapkind[0:6] == 'shadow': mapv = np.zeros((dy,dx), dtype=np.float) sunpos = mapkind.split(',')[1] enhance = gen.auto_val(mapkind.split(',')[2], 1./5.) if sunpos == 'N': ## Linear shadow from N mapv[0:dy-1,:] = valsmap[1:dy,:] - valsmap[0:dy-1,:] elif sunpos == 'NW': ## Diagonal shadow from NW for i in range(dx-1): for j in range(dy-1): if (i-1 >= 0) and (j+1 <= dy-1): mapv[j,i] = valsmap[j+1,i-1] - valsmap[j,i] else: print errormsg print ' ' + fname + ": sun location for map sahdding '" + sunpos + \ "' not ready !!" print ' available ones:', availsunpos quit(-1) xmapv = np.max(mapv)*enhance mapv = np.where(mapv > xmapv, xmapv, mapv) mapv = ma.masked_less(mapv, 0.) else: print errormsg print ' ' + fname + ": kind of map '" + mapkind + "' not ready !!" print ' available ones:', availmapkind quit(-1) if not objsf.variables.has_key(varn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have variable "' + varn + '" !!' varns = list(objsf.variables.keys()) varns.sort() print ' available ones:', varns quit(-1) # Variables' values objvars = objsf.variables[varn] if type(objvars[:]) != type(gen.mamat): print errormsg print ' ' + fname + ": drawing variable is not masked !!" quit(-1) valshad, dimsshad = drw.slice_variable(objvars, dimvals.replace(',','|')) dimnamesv = [vdimxn, vdimyn] if drw.searchInlist(objvars.ncattrs(),'units'): varunits = objvars.getncattr('units') else: print warnmsg print ' ' + fname + ": variable '" + varn + "' without units!!" varunits = '-' if not objsf.variables.has_key(vdimxn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimxn + '" !!' quit(-1) if not objsf.variables.has_key(vdimyn): print errormsg print ' ' + fname + ': shading file "' + ncfiles + \ '" does not have dimension variable "' + vdimyn + '" !!' quit(-1) objdimx = objsf.variables[vdimxn] objdimy = objsf.variables[vdimyn] if drw.searchInlist(objdimx.ncattrs(),'units'): odimxu = objdimx.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimxn + "' without units!!" odimxu = '-' if drw.searchInlist(objdimy.ncattrs(),'units'): odimyu = objdimy.getncattr('units') else: print warnmsg print ' ' + fname + ": variable dimension '" + vdimyn + "' without units!!" odimyu = '-' odimxv, odimyv = drw.dxdy_lonlatDIMS(objdimx[:], objdimy[:], objdimx.dimensions, \ objdimy.dimensions, dimvals.replace(':','|').split(',')) shading_nx = [] if shadminmax.split(',')[0][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[0])) else: shading_nx.append(shadminmax.split(',')[0]) if shadminmax.split(',')[1][0:1] != 'S': shading_nx.append(np.float(shadminmax.split(',')[1])) else: shading_nx.append(shadminmax.split(',')[1]) if mapvalue == 'None': mapvalue = None colorbarv = colorbarvals.split('#') colorbarvalsS = ','.join(colorbarv[0:3]) colbarn, fmtcolbar, colbaror = drw.colorbar_vals(colorbarvalsS, ',') nbarv = np.min(valshad) xbarv = np.max(valshad) rbarv = xbarv - nbarv dbarv = rbarv/5. if colorbarv[3] == 'direct': cbarpos = gen.pretty_int(nbarv,xbarv+dbarv,5) cbarlab = [] for cpos in cbarpos: cbarlab.append('{:6g}'.format(cpos)) elif colorbarv[3][0:4] == 'time': timevals = colorbarv[3].split('@')[1] timeunit = timevals.split('|')[0].replace('!',' ') timekind = timevals.split('|')[1] timefmt = timevals.split('|')[2] timelabel = timevals.split('|')[3].replace('!',' ') cbarpos, cbarlab = drw.CFtimes_plot([nbarv, xbarv], timeunit, timekind, timefmt) vnamesfig = timelabel varunits = None fmtcolbar = '%s' colormapv = [vnamesfig, varunits, colbarn, fmtcolbar, colbaror, cbarpos, cbarlab] xstyl, xaxf, Nxax, xaxor, ystyl, yaxf, Nyax, yaxor = drw.format_axes(dimxyf,',') xaxis = [xstyl, xaxf, Nxax, xaxor] yaxis = [ystyl, yaxf, Nyax, yaxor] drw.plot_2Dshad_map(mapv, valshad, mapfmt[0], colormapv, xaxis, yaxis, odimxv, \ odimyv, lonlatbox, mapvalue, shading_nx, figtitle, figkind, close) return #ncfile = '/home/lluis/sandbox/get/UBA_ERA-I_1a_2D.nc' ##values='orog;$conv^{ini}$;lat|-1,lon|-1;lon;lat;auto;rainbow#auto#auto#direct;' + \ ## 'Srange,Srange;Case1|1a;pdf;binary|shadow,NW;cyl,c;yes' #values='orog;$conv^{ini}$;lat|-1,lon|-1;lon;lat;auto;rainbow#auto#auto#' + \ # 'time@minutes!since!1949-12-01!00:00:00|exct,12,h|%d$^{%H}$|date!'+ \ # '([DD]$^{[HH]}$);Srange,Srange;Case1|1a;pdf;binary|shadow,NW,auto|' + \ # '-70.,-36,-62.,-30.;cyl,c;yes' #draw_2Dshad_map(ncfile, values, 'convini', axfig=None, fig=None) def draw_river_pattern(values, riverns): """ Function to plot rivers' patterns from ORCHIDEE's routing scheme file ('routing.nc' and 'river_desc.nc') values= [routingvars]:[descvalues]:[rivervalues]:[mapvalues]:[stationsvalues]: [lonlatbox]:[drawcountry]:[drawbasinid]:[gtit]:[kindfig]:[legvals]: [closefig] [routingvars]= '|' list of [basinsfilen]|[basinsvarid]|[basinslonname]| [basinslatname]|[basinsflowname], names of the variables in routing scheme file with the required values to make the plot (use 'ORCHIDEEdef' to use its default values 'routing.nc|basins|nav_lon|nav_lat|trip') [basinsfilen]: name of the file with the basins' information [basinsvarid]: basins' id [basinslonname]: name of the variable with the longitudes [basinslatname]: name of the variable with the latitudes [basinsflowname]: name with the variable with the flow directions (1-8: N, NE, E, ..., NW; 97: sub-basin; 98: small to sea; 99: large to sea) [descvalues]= '|' list of [descfilen]|[TAILdesccoding]|[desclon]|[desclat], names of the variables from routing output required for the plot (use 'ORCHIDEEdef' to use its default values 'river_desc.nc|_coding|lon|lat') [descfilen]: netCDF file with the description of the rivers as in ORCHIDEE One ASCII variable per name of river with (e.g. Parana): double Parana_frac(lat, lon) ; Parana_frac:units = "-" ; Parana_frac:long_name = "Fraction of basin Parana per grid box" ; Parana_frac:missing_value = 1.e+20 ; Parana_frac:Nb_of_grid_points_in_basin = 380 ; Parana_frac:Longitude_of_outflow_point = -58.5 ; Parana_frac:Latitude_of_outflow_point = -34.5 ; Parana_frac:Number_of_streams = 380 ; Parana_frac:Total_number_of_hops_to_ocean = 6840 ; Parana_frac:Minimum_number_of_hops_to_ocean_for_any_stream = 1 ; Parana_frac:Average_number_of_hops_to_ocean_for_any_stream = 18 ; Parana_frac:Maximum_number_of_hops_to_ocean_for_any_stream = 32 ; Parana_frac:Average_residence_time_in_basin = 19153.2279625174 ; double Parana_upstream(lat, lon) ; Parana_upstream:units = "m^2" ; Parana_upstream:long_name = "Upstream area of basin Parana in the grid box" ; Parana_upstream:missing_value = 1.e+20 ; int Parana_coding(lat, lon) ; Parana_coding:units = "-" ; Parana_coding:long_name = "Pfafstetter codes of grid boxes in basin Parana" ; Parana_coding:missing_value = 999999999 ; [TAILdesccoding]: tail of the variable with the river coding as: [rivername][TAILdescoding] [desclon]: longitude values [desclat]: latitude values [rivervalues]= '|' separated list of [colordescid]|[rivercolor]|[rivernocolor]|[riverwidth] [riverwidth]|[rivercolortype] (use 'auto' for 'brg|#AAAAAAA|#CCCCCC|0.5|rivernum') [barcolordescid]: color bar to use to distinguish among selected rivers to draw [rivercolor]: color for the river-flows of the non selected rivers [rivernocolor]: color for the outflows of the non selected rivers [riverwidth]: width of the lines of the rivers' path [rivercolortype]: method to deterine color of the tracks of the rivers 'riverid': following ids of the rivers 'rivernum': following number of rivers to be plotted [mapvalues]= map characteristics: [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full [stationsvalues]= '|' list of values in order to add stations and its labels into the plot (use 'None' for no stations file) [stationsfilen]|[stname]| [stlonn]|[stlatn]|[stcol]|[stsize] [stationsfilen]: name of the netCDF file with the values of the stations |stloname]: variable with the name of the stations |stlonn]: variable with the longitude of the stations [stlatn]: variable with the latitude of the stations [stcol]: color to use for the labels of the stations [stsize]: character size to use for the labels of the stations [lonlatbox]= '|' separated list of [SWlon]|[SWlat]|[NElon]|[NElat] to define only a given region to plot as a lonlat box ('all' for all the area in file) [SWlon]: longitude SW vertex [SWlat]: latitude SW vertex [NElon]: longitude NE vertex [NElat]: latitude NE vertex [drawcountry]= whether country lines should be plotted or not [drawbasinid]= whether basins id should be plotted or not [gtit]= title of the graph ('|', for spaces) [kindfig]= kind of figure (png, ps, pdf) [legvals]= [locleg]|[fontsize]|[Ncol] ('auto' for 0|12|1) [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [Ncol]: numnber of columns [closefig]= whether figure should be closed or not riverns= ',' list of the names of the rivers to plot (as in [descfilen]) 'all': for all rivers in 'routing.nc' 'all_desc': for all rivers in `river_desc.nc' 'larger',[Npaths]: all river larger than [Npaths] grid points (NOT now) """ import numpy.ma as ma fname = 'draw_river_pattern' if values == 'h': print fname + '_____________________________________________________________' print draw_river_pattern.__doc__ quit() expectargs = '[routingvars]:[descvalues]:[rivervalues]:[mapvalues]:' + \ '[stationsvalues]:[lonlatbox]:[drawcountry]:[drawbasinid]:[gtit]:[kindfig]:' + \ '[legvals]:[closefig]' drw.check_arguments(fname,values,expectargs,':') routingvars = values.split(':')[0] descvalues = values.split(':')[1] rivervalues = values.split(':')[2] mapvals = values.split(':')[3] stationvalues = values.split(':')[4] lonlatbox = values.split(':')[5] drawcountry = gen.Str_Bool(values.split(':')[6]) drawbasinid = gen.Str_Bool(values.split(':')[7]) gtit = values.split(':')[8].replace('|',' ') kindfig = values.split(':')[9] legvals = values.split(':')[10] closefig = gen.Str_Bool(values.split(':')[11]) if routingvars == 'ORCHIDEEdef': basinsfilen = 'routing.nc' basinsvarid = 'basins' basinslonname = 'nav_lon' basinslatname = 'nav_lat' basinsflowname = 'trip' else: [basinsfilen, basinsvarid, basinslonname, basinslatname, basinsflowname] = \ routingvars.split('|') basinsvarns = [basinsvarid, basinslonname, basinslatname, basinsflowname] basinsexpectvars = ['basinsvarid', 'basinslonname', 'basinslatname', \ 'basinsflowname'] if descvalues == 'ORCHIDEEdef': descfilen = 'river_desc.nc' TAILdesccoding = '_coding' desclon = 'lon' desclat = 'lat' else: [descfilen, TAILdesccoding, desclon, desclat] = descvalues.split('|') descvarns = [desclon, desclat] descexpectvarns = ['desclon', 'desclat'] if rivervalues == 'auto': barcolordescid = 'brg' rivercolor = '#AAAAAA' rivernocolor = '#CCCCCC' riverwidth = 0.5 rivercolortype = 'rivernum' else: [barcolordescid, rivercolor, rivernocolor, riverwidth, rivercolortype] = \ rivervalues.split('|') riverwidth = np.float(riverwidth) if stationvalues == 'None': stationsfilen = None stn = None stlon = None stlat = None stcol = None stsize = None else: [stationsfilen, stname, stlonn, stlatn, stcol, stsize] = \ stationvalues.split('|') stsize = int(stsize) stvarns = [stname, stlonn, stlatn] stexpectvarns = ['stname', 'stlonn', 'stlatn'] # Getting rivers' information if not os.path.isfile(basinsfilen): print errormsg print ' ' + fname + ": file with basins information '" + basinsfilen + \ "' does not exist !!" quit(-1) oriver = NetCDFFile(basinsfilen, 'r') ivar = 0 for vn in basinsexpectvars: if not oriver.variables.has_key(basinsvarns[ivar]): print errormsg print ' ' +fname+ ": basins file '" + basinfilen + "' does not have " + \ vn + " as '" + basinsvarns[ivar] + "' !!" ivar = ivar + 1 obid = oriver.variables[basinsvarid] oblon = oriver.variables[basinslonname] oblat = oriver.variables[basinslatname] obflow = oriver.variables[basinsflowname] if routingvars == 'ORCHIDEEdef': # Data is fliped along latitudes bid = obid[::-1,:] blon = oblon[::-1,:] blat = oblat[::-1,:] bflow = obflow[::-1,:] else: bid = obid[:] blon = oblon[:] blat = oblat[:] bflow = obflow[:] oriver.close() # Getting rivers' description if not os.path.isfile(descfilen): print errormsg print ' ' + fname + ": file with decription information '" + descfilen + \ "' does not exist !!" quit(-1) odesc = NetCDFFile(descfilen, 'r') ivar = 0 for vn in descexpectvarns: if not odesc.variables.has_key(descvarns[ivar]): print errormsg print ' '+fname+": dfescription file '"+descfilen+"' does not have " + \ vn + " as '" + descvarns[ivar] + "' !!" ivar = ivar + 1 odlon = odesc.variables[desclon] odlat = odesc.variables[desclat] dlon = odlon[:] dlat = odlat[:] if stationsfilen is not None: # Getting staions' information if not os.path.isfile(stationsfilen): print errormsg print ' ' + fname + ": file with stations information '" + \ stationsfilen + "' does not exist !!" quit(-1) ostation = NetCDFFile(stationsfilen, 'r') ivar = 1 for vn in stexpectvars: if not ostation.variables.has_key(stvarns[ivar]): print errormsg print ' ' + fname + ": stations file '" + stationsfilen + \ "' does not have " + vn + " as '" + stvarns[ivar] + "' !!" ivar = ivar + 1 stname , stlonn, stlatn ostn = ostation.variables[stname] ostlon = ostation.variables[stlonn] ostlat = ostation.variables[stlatn] Lstr = ostn.dimensions[1] lenstr = len(ostaton.dimensions(Lstr)) stn = ncvar.get_str_nc(ostn, lenstr) stlon = ostlon[:] stlat = ostlat[:] ostation.close() # Lonlat box lon, lat = drw.lonlat2D(blon, blat) if lonlatbox == 'all': nlon = np.min(lon) nlat = np.min(lat) xlon = np.max(lon) xlat = np.max(lat) else: nlon = np.float(lonlatbox.split('|')[0]) nlat = np.float(lonlatbox.split('|')[1]) xlon = np.float(lonlatbox.split('|')[2]) xlat = np.float(lonlatbox.split('|')[3]) imin, imax, jmin, jmax = gen.ijlonlat(lon, lat, nlon, xlon, nlat, xlat) # Getting river's ids: if riverns.count(',') != 0: rns = riverns.split(',') else: if riverns == 'all': rns = [] rns = list(set(list(bid[jmin:jmax,imin:imax].compressed()))) elif riverns == 'all_desc': rns = [] ## Following river desc Ltail = len(TAILdesccoding) allvarns = odesc.variables.keys() for vn in allvarns: if vn.find(TAILdesccoding) != -1: Lvn = len(vn) rns.append(vn[0:Lvn-Ltail]) if len(rns) == 0: print errormsg print ' ' + fname + ": no river description found as '[rivername]"+ \ TAILdesccoding + "' !!" allvarns.sort() print " variables found in description file '" + descfilen + \ "': ", allvarns quit(-1) elif riverns[0:6] == 'larger': print errormsg print ' ' + fname + ": riverns == 'larger' not ready yet !!" quit(-1) else: rns = [riverns] codings = {} if riverns != 'all': print ' ' + fname + ': rivers to plot: [namne] [id] _____' for rn in rns: ocoding = odesc.variables[rn + TAILdesccoding] maskcoding = ocoding[:].mask rnid = bid[~maskcoding][0] if rnid != gen.mamat[0]: codings[rn] = rnid print rn ,':', rnid else: for rn in rns: codings[rn] = rn # legend values if legvals != 'auto': legvalues = drw.legend_values(legvals, '|') else: legvalues = [0, 12, 1] drw.plot_multi_river_pattern(lon[jmin:jmax,imin:imax], lat[jmin:jmax,imin:imax], \ bflow[jmin:jmax,imin:imax], bid[jmin:jmax,imin:imax], codings, dlon, dlat, \ stn, stlon, stlat, drawcountry, drawbasinid, barcolordescid, rivercolor, \ rivernocolor, riverwidth, rivercolortype, stcol, stsize, gtit, mapvals, \ kindfig, rns) return #values = 'ORCHIDEEdef:ORCHIDEEdef:auto:cyl,l:None:all:False:False:ORCHIDEEE|routing|' + \ # '0.5|deg:pdf:0|10|1:True' #riverns = 'all' #draw_river_pattern(values, riverns) def draw_topofix_geogrid_boxes(ncfiles, values): """ plotting different geo_em.d[nn].nc topography from WPS files draw_topo_geogrid_boxes(ncfiles, values) on a fixed low-level enhanced color mode ncfiles= ',' list of geo_em.d[nn].nc files to use (first as topographyc reference) values= [lonlatL]:[title]:[graphic_kind]:[mapvalues]:[labels]:[legvals]: [boxlvals]:[ColorLeg]:[mervals]:[parvals]:[coastlvals]:[countrylvals]: [stslvals]:[close] lonlatL: limits of longitudes and latitudes [lonmin, latmin, lonmax, latmax] or None title: title of the graph ('!' for spaces) graphic_kind: kind of figure (jpg, pdf, png) mapvalues: map characteristics [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full legvals: [locleg]|[fontsize]|[Ncol]: [locleg]: location of the legend (0, automatic) 1: 'upper right', 2: 'upper left', 3: 'lower left', 4: 'lower right', 5: 'right', 6: 'center left', 7: 'center right', 8: 'lower center', 9: 'upper center', 10: 'center' [fontsize]: font size for the legend (auto for 12) [Ncol]: number of columns (1) labels: labels to write in the graph ('!' for spaces) boxlvals: [line style]|[line width] values for the boxes (['-', 3], auto) [ColorLeg] = [ijstart, orientation, labsize, sqsize, labrotation, totboxlength, ibox, seacolor] values for the legend of colors of the topography ([0.95, 'vertical', 10., 10., 0., 0.8, 0.85, '#CCCCFF'], default) ijstart: initial position as fraction of figure on the oposite axis of orientation orientation: orientation of the legend labsize: font size of the labels sqsize: size of the squares of the legend labrotation: rotation of the labels of the legend totboxlength: total length of the color legend as percentage of the figure size along the given orientation ibox: starting at the given orientation as percentage of the figure seacolor: color for the sea mervals: [fontsize]|[color line]|[labels rotation]|[line width] values for the meridians ([8,'#AAAAAA', 0, 0.5], auto) parvals: [fontsize]|[color line]|[labels rotation]|[line width] values for the parallels ([8,'#AAAAAA', 0, 0.5], auto) coastlvals: [line width|color line] values for the coastline (None for any, [0.25,'#161616'], auto) countrylvals: [line width|color line] values for the countries (None for any, [0.25, '#161616'], auto) stslvals: [line width|color line] values for the states (None for any, None, [0.25, '#080808'], auto) close: Whether figure should be finished or not """ # import matplotlib as mpl # mpl.use('Agg') import matplotlib.pyplot as plt fname = 'draw_topofix_geogrid_boxes' if values == 'h': print fname + '_____________________________________________________________' print draw_topofix_geogrid_boxes.__doc__ quit() expectargs = '[lonlatL]:[title]:[graphic_kind]:[mapvalues]:[labels]:[legvals]:'+ \ '[boxlvals]:[ColorLeg]:[mervals]:[parvals]:[coastlvals]:[countrylvals]:'+ \ '[stsvals]:[close]' drw.check_arguments(fname,values,expectargs,':') lonlatLS = values.split(':')[0] lonlatLv = lonlatLS.split(',')[0] if lonlatLv == 'None': lonlatL = None else: lonlatL = np.zeros((4), dtype=np.float) lonlatL[0] = np.float(lonlatLS.split(',')[0]) lonlatL[1] = np.float(lonlatLS.split(',')[1]) lonlatL[2] = np.float(lonlatLS.split(',')[2]) lonlatL[3] = np.float(lonlatLS.split(',')[3]) grtit = values.split(':')[1].replace('!', ' ') kindfig = values.split(':')[2] mapvalues = values.split(':')[3] labels = values.split(':')[4] legvals = values.split(':')[5] boxlvals = values.split(':')[6] ColorLeg = values.split(':')[7] mervals = values.split(':')[8] parvals = values.split(':')[9] coastlvals = values.split(':')[10] countrylvals = values.split(':')[11] stslvals = values.split(':')[12] close = gen.Str_Bool(values.split(':')[13]) ncfile = ncfiles.split(',')[0] if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': domain file "' + ncfile + '" does not exist !!' quit(-1) objdomf = NetCDFFile(ncfile, 'r') objhgt = objdomf.variables['HGT_M'] objlandsea = objdomf.variables['LANDMASK'] objlon0 = objdomf.variables['XLONG_M'] objlat0 = objdomf.variables['XLAT_M'] topography = objhgt[0,:,:] landsea = objlandsea[0,:,:] Nfiles = len(ncfiles.split(',')) boxlabels = labels.split(',') Xboxlines = [] Yboxlines = [] for ifile in range(Nfiles): ncfile = ncfiles.split(',')[ifile] # print ifile, ncfile if not os.path.isfile(ncfile): print errormsg print ' ' + fname + ': domain file "' + ncfile + '" does not exist !!' quit(-1) objdomfi = NetCDFFile(ncfile, 'r') objlon = objdomfi.variables['XLONG_M'] objlat = objdomfi.variables['XLAT_M'] dx = objlon.shape[2] dy = objlon.shape[1] Xboxlines.append(objlon[0,0,:]) Yboxlines.append(objlat[0,0,:]) Xboxlines.append(objlon[0,dy-1,:]) Yboxlines.append(objlat[0,dy-1,:]) Xboxlines.append(objlon[0,:,0]) Yboxlines.append(objlat[0,:,0]) Xboxlines.append(objlon[0,:,dx-1]) Yboxlines.append(objlat[0,:,dx-1]) objdomfi.close() # Legend legvals = drw.legend_values(legvals,'|') if boxlvals != 'auto': Boxlvals = [str(boxlvals.split('|')[0]), int(boxlvals.split('|')[0])] else: Boxlvals = ['-', 3] if ColorLeg != 'auto': colorleg = [np.float(ColorLeg.split('|')[0]), ColorLeg.split('|')[1], \ np.float(ColorLeg.split('|')[2]), np.float(ColorLeg.split('|')[3]), \ np.float(ColorLeg.split('|')[4]), np.float(ColorLeg.split('|')[5]), \ np.float(ColorLeg.split('|')[6]), ColorLeg.split('|')[7]] else: colorleg = [0.8, 'vertical', 10., 10., 0., 0.8, 0.1, '#CCCCFF'] if mervals != 'auto': Mervals = [int(mervals.split('|')[0]), str(mervals.split('|')[1]), \ np.float(mervals.split('|')[2]), np.float(mervals.split('|')[3])] else: Mervals = [8,'#AAAAAA', 0, 0.5] if parvals != 'auto': Parvals = [int(parvals.split('|')[0]), str(parvals.split('|')[1]), \ np.float(parvals.split('|')[2]), np.float(parvals.split('|')[3])] else: Parvals = [8,'#AAAAAA', 0, 0.5] if coastlvals != 'auto': Coastlvals = [np.float(coastlvals.split('|')[0]), \ str(coastlvals.split('|')[1])] elif coastlvals == 'None': Coastlvals = None else: Coastlvals = [0.25,'#161616'] if countrylvals != 'auto': Countrylvals = [np.float(countrylvals.split('|')[0]), \ str(countrylvals.split('|')[1])] elif countrylvals == 'None': Countrylvals = None else: Countrylvals = [0.25,'#161616'] if stslvals != 'auto': Stslvals = [np.float(stslvals.split('|')[0]), str(stslvals.split('|')[1])] elif stslvals == 'None': Stslvals = None else: Stslvals = [0.25,'#080808'] drw.plot_topofix_geogrid_boxes(topography, landsea, Xboxlines, Yboxlines, \ boxlabels, objlon0, objlat0, lonlatL, grtit, kindfig, mapvalues, legvals, \ Boxlvals, colorleg, Mervals, Parvals, Coastlvals, Countrylvals, Stslvals, close) objdomf.close() return def draw_geogrid_landuse(ncfile, values): """ plotting land-use data from geo_em.d[nn].nc WPS files ncfile= geo_em.d[nn].nc file to use values=[lonlatL]:[title]:[graphic_kind]:[mapvalues]:[ColorLeg]:[mervals]:[parvals]: [coastlvals]:[countrylvals]:[stslvals]:[close] lonlatL: limits of longitudes and latitudes [lonmin, latmin, lonmax, latmax] or None title: title of the graph ('!' for spaces) graphic_kind: kind of figure (jpg, pdf, png) mapvalues: map characteristics [proj],[res] see full documentation: http://matplotlib.org/basemap/ [proj]: projection * 'cyl', cilindric * 'lcc', lambert conformal [res]: resolution: * 'c', crude * 'l', low * 'i', intermediate * 'h', high * 'f', full ColorLeg= [ijstart]|[lucolors] values for the legend of colors of the land-use ([0.85, 'usgscolors'], default) ijstart: initial position as fraction of figure on the oposite axis of orientation lucolors: name of the dictionary with the equivalences between land-use and color mervals: [fontsize]|[color line]|[labels rotation]|[line width] values for the meridians ([8,'#AAAAAA', 0, 0.5], auto) parvals: [fontsize]|[color line]|[labels rotation]|[line width] values for the parallels ([8,'#AAAAAA', 0, 0.5], auto) coastlvals: [line width|color line] values for the coastline (None for any, [0.25,'#161616'], auto) countrylvals: [line width|color line] values for the countries (None for any, [0.25, '#161616'], auto) stslvals: [line width|color line] values for the states (None for any, None, [0.25, '#080808'], auto) close: Whether figure should be finished or not """ import matplotlib.pyplot as plt fname = 'draw_geogrid_landuse' lucolorsavail = ['modifmodis', 'ugs'] if values == 'h': print fname + '_____________________________________________________________' print draw_geogrid_landuse.__doc__ quit() expectargs = '[lonlatL]:[title]:[graphic_kind]:[mapvalues]:[ColorLeg]:' + \ '[mervals]:[parvals]:[coastlvals]:[countrylvals]: [stslvals]:[close]' drw.check_arguments(fname,values,expectargs,':') lonlatLS = values.split(':')[0] lonlatLv = lonlatLS.split(',')[0] if lonlatLv == 'None': lonlatL = None else: lonlatL = np.zeros((4), dtype=np.float) lonlatL[0] = np.float(lonlatLS.split(',')[0]) lonlatL[1] = np.float(lonlatLS.split(',')[1]) lonlatL[2] = np.float(lonlatLS.split(',')[2]) lonlatL[3] = np.float(lonlatLS.split(',')[3]) grtit = values.split(':')[1].replace('!', ' ') kindfig = values.split(':')[2] mapvalues = values.split(':')[3] ColorLeg = values.split(':')[4] mervals = values.split(':')[5] parvals = values.split(':')[6] coastlvals = values.split(':')[7] countrylvals = values.split(':')[8] stslvals = values.split(':')[9] close = gen.Str_Bool(values.split(':')[10]) objdomf = NetCDFFile(ncfile, 'r') objhgt = objdomf.variables['HGT_M'] objlandsea = objdomf.variables['LANDMASK'] objlon0 = objdomf.variables['XLONG_M'] objlat0 = objdomf.variables['XLAT_M'] objlu = objdomf.variables['LU_INDEX'] lon = objlon0[0,:,:] lat = objlat0[0,:,:] topography = objhgt[0,:,:] landsea = objlandsea[0,:,:] lu = objlu[0,:,:] lucolorsS = ColorLeg.split('|')[0] ixleg = np.float(ColorLeg.split('|')[1]) if lucolorsS == 'usgs': lucolors = drw.usgscolors elif lucolorsS == 'modifmodis': lucolors = drw.modigbpmodisnoahcolors else: print errormsg print ' ' + fname + ": land-use colors dictinoary '" +lucolorsS + \ "' not available !!" print ' available ones:', lucolorsavail quit(-1) if mervals != 'auto': Mervals = [int(mervals.split('|')[0]), str(mervals.split('|')[1]), \ np.float(mervals.split('|')[2]), np.float(mervals.split('|')[3])] else: Mervals = [8,'#AAAAAA', 0, 0.5] if parvals != 'auto': Parvals = [int(parvals.split('|')[0]), str(parvals.split('|')[1]), \ np.float(parvals.split('|')[2]), np.float(parvals.split('|')[3])] else: Parvals = [8,'#AAAAAA', 0, 0.5] if coastlvals != 'auto': Coastlvals = [np.float(coastlvals.split('|')[0]), \ str(coastlvals.split('|')[1])] elif coastlvals == 'None': Coastlvals = None else: Coastlvals = [0.25,'#161616'] if countrylvals != 'auto': Countrylvals = [np.float(countrylvals.split('|')[0]), \ str(countrylvals.split('|')[1])] elif countrylvals == 'None': Countrylvals = None else: Countrylvals = [0.25,'#161616'] if stslvals != 'auto': Stslvals = [np.float(stslvals.split('|')[0]), str(stslvals.split('|')[1])] elif stslvals == 'None': Stslvals = None else: Stslvals = [0.25,'#080808'] drw.plot_landuse(lu, lon, lat, lonlatL ,mapvalues, ixleg, lucolors, grtit, \ kindfig, fname, Mervals, Parvals, Coastlvals, Countrylvals, Stslvals, close) return #quit() ####### ###### ##### #### ### ## # ngraphics = "'" + drw.numVector_String(namegraphics, "', '") + "'" ### Options ##string_operation="operation to make: " + '\n' + " out, output values -S inidim1,[inidim2,...]:enddim1,[enddim2,...]" string_operation="""operation to make: draw_topo_geogrid, draws topography from a WPS geo_em.d[nn].nc: -S [minTopo],[maxTopo]:[SW_lon],[SW_lat],[NE_lon],[NE_lat]:[title]:[graphic_kind]:[projection],[res_coastline] draw_2D_shad_cont, draws two 2D fields, first with shading second with contour lines: -v [varns],[varnc] -S [vnamefs],[vnamefc],[dimxvn],[dimyvn],[colorbar],[ckind],[clabfmt],[sminv]:[smaxv],[sminc]:[smaxv]:[Nlev],[figt],[kindfig],[reverse] [ckind]: 'cmap': as it gets from colorbar 'fixc,[colname]': fixed color [colname], all stright lines 'fixsignc,[colname]': fixed color [colname], >0 stright, <0 dashed line """ ####### ###### ##### #### ### ## # # Not checking file operation Notcheckingfile = ['draw_2D_shad_cont', 'draw_2D_shad_contdisc', \ 'draw_2D_shad_contdisc_time', 'draw_2D_shad_2cont', 'draw_2D_shad_cont_time', \ 'draw_2D_shad_line', 'draw_2D_shad_line_time', 'draw_2lines', 'draw_2lines_time', \ 'draw_bar', 'draw_bar_line', 'draw_bar_line_time', 'draw_bar_time', \ 'draw_cycle', 'draw_ensembles_time', 'draw_multi_2D_shad', 'draw_multi_SkewT', \ 'draw_lines', \ 'draw_lines_time', 'draw_multiWindRose', 'draw_points', 'draw_river_pattern', \ 'draw_Taylor', \ 'draw_time_lag', 'draw_topo_geogrid_boxes', 'draw_topofix_geogrid_boxes', \ 'draw_trajectories', 'draw_vals_trajectories', 'draw_WRFeta_levels', \ 'variable_values'] errormsg='ERROR -- error -- ERROR -- error' # From: http://stackoverflow.com/questions/4041238/why-use-def-main def main(): ####### ####### ## MAIN ####### parser = OptionParser() parser.add_option("-f", "--netCDF_file", dest="ncfile", help="file to use", metavar="FILE") parser.add_option("-o", "--operation", type='choice', dest="operation", choices=namegraphics, help="operation to make: " + ngraphics, metavar="OPER") parser.add_option("-S", "--valueS", dest="values", help="[WHEN APPLICABLE] values to use according to the operation", metavar="VALUES") parser.add_option("-v", "--variable", dest="varname", help="[WHEN APPLICABLE] variable to check", metavar="VAR") (opts, args) = parser.parse_args() varn=opts.varname oper=opts.operation if opts.operation is None: print errormsg print ' No operation provided !!' print " an operation must be provided as '-o [operationname]' " quit(-1) if opts.ncfile is None and not gen.searchInlist(Notcheckingfile, oper) and \ opts.values != 'h': print errormsg print ' ' + mainn + ": you must provide a file as '-f [filename]'!!" quit(-1) if opts.ncfile is not None and not os.path.isfile(opts.ncfile) and \ not gen.searchInlist(Notcheckingfile, oper): print errormsg print ' ' + mainn + ': File ' + opts.ncfile + ' does not exist !!' quit(-1) if oper == 'create_movie': create_movie(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad': draw_2D_shad(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2Dshad_map': draw_2Dshad_map(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_time': draw_2D_shad_time(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_cont': draw_2D_shad_cont(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_contdisc': draw_2D_shad_contdisc(opts.ncfile, opts.values) elif oper == 'draw_2D_shad_contdisc_time': draw_2D_shad_contdisc_time(opts.ncfile, opts.values) elif oper == 'draw_2D_shad_2cont': draw_2D_shad_2cont(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_cont_time': draw_2D_shad_cont_time(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_line': draw_2D_shad_line(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2D_shad_line_time': draw_2D_shad_line_time(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_bar': draw_bar(opts.ncfile, opts.values) elif oper == 'draw_bar_line': draw_bar_line(opts.ncfile, opts.values) elif oper == 'draw_bar_line_time': draw_bar_line_time(opts.ncfile, opts.values) elif oper == 'draw_bar_time': draw_bar_time(opts.ncfile, opts.values) elif oper == 'draw_barbs': draw_barbs(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_basins': draw_basins(opts.ncfile, opts.values) elif oper == 'draw_cycle': draw_cycle(opts.ncfile, opts.values) elif oper == 'draw_ensembles_time': draw_ensembles_time(opts.ncfile, opts.values) elif oper == 'draw_geogrid_landuse': draw_geogrid_landuse(opts.ncfile, opts.values) elif oper == 'draw_Neighbourghood_evol': draw_Neighbourghood_evol(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2lines': draw_2lines(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_2lines_time': draw_2lines_time(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_lines': draw_lines(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_lines_time': draw_lines_time(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_multi_2D_shad': draw_multi_2D_shad(opts.ncfile, opts.values) elif oper == 'draw_multi_SkewT': draw_multi_SkewT(opts.ncfile, opts.values) elif oper == 'draw_multiWindRose': draw_multiWindRose(opts.ncfile, opts.values) elif oper == 'draw_points': draw_points(opts.ncfile, opts.values) elif oper == 'draw_points_lonlat': draw_points_lonlat(opts.ncfile, opts.values) elif oper == 'draw_ptZvals': draw_ptZvals(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_river_desc': draw_river_desc(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_river_pattern': draw_river_pattern(opts.values, opts.varname) elif oper == 'draw_subbasin': draw_subbasin(opts.ncfile, opts.values) elif oper == 'draw_SkewT': draw_SkewT(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_stations_map': draw_stations_map(opts.ncfile, opts.values) elif oper == 'draw_Taylor': draw_Taylor(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_time_lag': draw_time_lag(opts.ncfile, opts.values) elif oper == 'draw_timeSeries': draw_timeSeries(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_topo_geogrid': draw_topo_geogrid(opts.ncfile, opts.values) elif oper == 'draw_topo_geogrid_boxes': draw_topo_geogrid_boxes(opts.ncfile, opts.values) elif oper == 'draw_topofix_geogrid_boxes': draw_topofix_geogrid_boxes(opts.ncfile, opts.values) elif oper == 'draw_trajectories': draw_trajectories(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_vals_trajectories': draw_vals_trajectories(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_vectors': draw_vectors(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_vertical_levels': draw_vertical_levels(opts.ncfile, opts.values, opts.varname) elif oper == 'list_graphics': # From: http://www.diveintopython.net/power_of_introspection/all_together.html import drawing as myself object = myself for opern in namegraphics: if opern != 'list_graphics': print opern + '_______ ______ _____ ____ ___ __ _' print getattr(object, opern).__doc__ elif oper == 'draw_WindRose': draw_WindRose(opts.ncfile, opts.values, opts.varname) elif oper == 'draw_WRFeta_levels': draw_WRFeta_levels(opts.ncfile, opts.values) elif oper == 'movie_2D_shad': movie_2D_shad(opts.ncfile, opts.values, opts.varname) elif oper == 'variable_values': variable_values(opts.values) else: print errormsg print ' ' + main + ": the graphic '" + oper + "' is not ready !!" print errormsg quit() if __name__ == '__main__': main()