コード例 #1
0
def get_tempdata_fpath(caseutc, fmt, vrbl, validutc, initutc, mem):
    if caseutc is None:
        casestr = "cNone"
    else:
        casestr = utils.string_from_time('dir', caseutc, strlen='day')

    if fmt is None:
        fmt = "fNone"

    if vrbl is None:
        vrbl = "vNone"

    if validutc is None:
        validstr = "uNone"
    else:
        validstr = utils.string_from_time('dir', validutc, strlen='minute')

    if initutc is None:
        initstr = "iNone"
    else:
        initstr = utils.string_from_time('dir', initutc, strlen='hour')

    if mem is None:
        mem = "mNone"

    fname = "temp_{}_{}_{}_{}_{}_{}.npy".format(casestr, initstr, validstr,
                                                vrbl, fmt, mem)
    fpath = os.path.join(tempdir_root, fname)
    utils.trycreate(fpath, debug=False)
    return fpath
コード例 #2
0
ファイル: ruc.py プロジェクト: johnrobertlawson/evac 
    def plot_variable(self,va,lv,**kwargs):
        self.fig = plt.figure()
        m, x, y  = self.basemap_setup(nc,**kwargs)
        # Scales, colourmaps in here

        data = self.get(va,**kwargs)
        if not 'scale' in kwargs:
            m.contourf(x,y,data)
        else:
            m.contourf(x,y,data,N.arange(*kwargs['scale']))

        if self.C.plot_titles:
            title = utils.string_from_time('title',self.t)
            plt.title(title)
        if self.C.colorbar:
            plt.colorbar(orientation='horizontal')

        # SAVE FIGURE
        datestr = utils.string_from_time('output',self.t)
        lv_na = utils.get_level_naming(lv,va)
        na = (va,lv_na,datestr)
        self.fname = self.create_fname(*na)
        # pdb.set_trace()
        self.save(self.fig,self.output_root,self.fname)
        plt.close()
コード例 #3
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def get_random_d01(caseutc):
    initutc = CASES[caseutc][0]
    casestr = utils.string_from_time('dir', caseutc, strlen='day')
    initstr = utils.string_from_time('dir', initutc, strlen='hour')
    print("Loading random d01 wrfout for", casestr)

    m01dir = os.path.join(ensroot, initstr, "m01")

    d01_fname = get_wrfout_fname(initutc, 1)
    d01_fpath = os.path.join(m01dir, d01_fname)
    d01_nc = Dataset(d01_fpath)

    return d01_nc
コード例 #4
0
ファイル: ruc.py プロジェクト: johnrobertlawson/evac 
    def plot_streamlines(self,va,lv,**kwargs):
        fig = plt.figure()

        # Scales, colourmaps in here

        # Get data
        u_all = self.get('U10',**kwargs)[:]
        v_all = self.get('V10',**kwargs)[:]

        u = self.cut_2D_array(u_all)
        v = self.cut_2D_array(v_all)
        m, x, y  = self.basemap_setup(**kwargs)
        """
        # Density depends on which version
        # Wanting to match 3 km WRF (which had 2.5 density)
        # Should work out dx, dy in __init__ method!

        WRF_density = 2.5
        WRF_res = 3.0

        if self.version == 3:
            RUC_res = 13.0

        density = WRF_density * RUC_res/WRF_res
        """
        density = 2.5

        #x = N.array(range(u.shape[0]))
        #y = N.array(range(v.shape[1]))

        #pdb.set_trace()
        #m.streamplot(x[self.x_dim/2,:],y[:,self.y_dim/2],u,v,density=density,linewidth=0.75,color='k')
        #m.streamplot(x[y.shape[1]/2,:],y[:,x.shape[0]/2],u,v,density=density,linewidth=0.75,color='k')
        #plt.streamplot(x[:,0],y[0,:],u,v)#,density=density,linewidth=0.75,color='k')
        m.streamplot(y[0,:],x[:,0],u,v,density=density,linewidth=0.75,color='k')
        #m.quiver(x,y,u,v)

        if self.C.plot_titles:
            title = utils.string_from_time('title',self.t)
            plt.title(title)

        # SAVE FIGURE
        datestr = utils.string_from_time('output',self.t)
        lv_na = utils.get_level_naming(va,lv=lv)
        na = (va,lv_na,datestr)
        self.fname = self.create_fname(*na)
        # pdb.set_trace()
        self.save(fig,self.output_root,self.fname)
        plt.close()
コード例 #5
0
ファイル: ecmwf.py プロジェクト: johnrobertlawson/evac 
    def plot(self,va,lv,times,outdir=False,**kwargs):
        for t in times:

            fig = plt.figure()
            data = self.get(va,lv,t)
            m, x, y = self.basemap_setup()

            if 'scale' in kwargs:
                S = kwargs['scale']
                f1 = m.contour(x,y,data,S,colors='k')
            else:
                f1 = m.contour(x,y,data,colors='k')

            if kwargs['title']:
                title = utils.string_from_time('title',t)
                plt.title(title)

            if 'wind_overlay' in kwargs:
                jet = kwargs['wind_overlay']
                wind = self.get('wind',lv,t)
                windplot = m.contourf(x,y,wind,jet,alpha=0.6)
                plt.colorbar(windplot)

            elif 'W_overlay' in kwargs:
                Wscale = kwargs['W_overlay']
                W = self.get('W',lv,t)
                windplot = m.contourf(x,y,W,alpha=0.6)
                plt.colorbar(windplot)


            # if self.C.colorbar:
                # plt.colorbar(orientation='horizontal')

            datestr = utils.string_from_time('output',t)
            fname = '_'.join(('ECMWF',va,str(lv),datestr)) + '.png'

            print(("Plotting {0} at {1} for {2}".format(
                        va,lv,datestr)))

            plt.clabel(f1, inline=1, fmt='%4u', fontsize=12, colors='k')

            utils.trycreate(outdir)
            plt.savefig(os.path.join(outdir,fname))
            plt.clf()
            plt.close()
コード例 #6
0
def return_all_mrms(caseutc, vrbl):
    """ Return sorted dictionary of times and files.
    """
    fdir, key, dlat = lookup_mrms_metadata(caseutc, vrbl)
    casestr = utils.string_from_time('dir', caseutc, strlen='day')

    FILES = {}
    # Open all netcdf files in this folder, and create list of times
    nclist = glob.glob(os.path.join(fdir, "*.netcdf"))
    for f in nclist:
        utcstr, _ext = os.path.basename(f).split('.')
        assert _ext == "netcdf"
        fmt = "%Y%m%d-%H%M%S"
        utc = datetime.datetime.strptime(utcstr, fmt)

        FILES[utc] = f
    utcs = sorted(FILES.keys())

    # pdb.set_trace()

    return FILES, utcs, key, fdir
コード例 #7
0
CASES_narr[datetime.datetime(2017, 5, 4, 0, 0,
                             0)] = datetime.datetime(2017, 5, 4, 12, 0, 0)

# Load tornado report CSV to plot lat/lon

# Load severe hail reports, or draw a swathe of SVR reports with Python?
# Could plot hail reports as proxy for mesocyclonic activity.

fig, _axes = plt.subplots(ncols=4, nrows=4, figsize=(12, 10))
fig_fname = "case_outline.png"
fig_fpath = os.path.join(outroot, fig_fname)
axes = _axes.flat

# For each case...
for caseutc, plotutc in CASES_narr.items():
    casestr = utils.string_from_time('dir', plotutc, strlen='hour')
    narr_fname = f'merged_AWIP32.{casestr}.3D'
    narr_fpath = os.path.join(narrroot, narr_fname)

    # Load NARR data
    # G = GribFile(fpath)
    G = NARRFile(narr_fpath)
    data_925 = G.get("HGT", level="level 925")[0, 0, :, :]
    data_500 = G.get("HGT", level="level 500")[0, 0, :, :]

    # lats = G.lats
    # lons = G.lons

    # Plot 500 hPa height, 925 hPa height from NARR
    ax = next(axes)
    m = create_bmap(50.0, -55.0, 25.0, -130.0, ax=ax)
コード例 #8
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        nneighs = len(neighs)

        # DATA = {dom: {dBZ: {score: N.zeros([ninit,4]) for score in scores} for dBZ in dBZs} for dom in thedoms.keys()}
        DATA = {s: N.zeros([2, len(dBZs), nneighs, len(fcstmins),len(initutcs)]) for s in scores}
                    # '-' if score == "FI" else '--'
        LS = dict(FI='-',FISS='-.',RES='--',REL='--',UNC='--',FISS2='-.',RES_REL=':',FISS_WoF='-.',eFSS='-')
        assert sorted(LS.keys()) == sorted(scores)
        all_neighs = []
        for dom_pp, initutc, fcstmin, score in itertools.product(domkeys,initutcs,fcstmins,scores):
            # if score in ("RES_REL","FISS_WoF"):
                # continue
            domidx = domkeys.index(dom_pp)
            fidx = fcstmins.index(fcstmin)
            iidx = initutcs.index(initutc)
            dx = thedoms[dom_pp]
            initstr = utils.string_from_time('dir',initutc,strlen='hour')
            fi_fpath = os.path.join(outroot,initstr,'FI_{}_{}min_{}.png'.format(dom_pp,fcstmin,score))

            fdir_fi = os.path.join(npyroot,initstr,"FI")
            fpath = generate_fname(vrbl=vrbl,metric='FI',suffix="efss",
                        fcstmin=fcstmin,dom_pp=dom_pp,ensmember='all',
                        fdir=fdir_fi,extension='.pickle')
            
            with open(fpath,'rb') as f:
                fi = pickle.load(f)


            toplot = {}
            # dBZs = sorted(fi.keys())
            neighs = sorted(fi[dBZs[0]].keys())
            all_neighs.append(neighs)
コード例 #9
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    def plot_radar(self,
                   outdir=False,
                   fig=False,
                   ax=False,
                   fname=False,
                   Nlim=False,
                   Elim=False,
                   Slim=False,
                   Wlim=False,
                   cb=True,
                   drawcounties=False,
                   save='auto'):
        """
        Plot radar data.

        Args:

        save        :   (str,bool) - If 'auto', saving will only occur if
                        fig and ax are not specified.
                        If True, the figure is saved; if False, not.
        """
        # if not fig:
        # fig, ax = plt.subplots()
        # self.generate_basemap(fig,ax,Nlim,Elim,Slim,Wlim)
        #lons, lats = self.m.makegrid(self.xlen,self.ylen)
        if isinstance(Nlim, float):
            data, lats, lons = self.get_subdomain(Nlim, Elim, Slim, Wlim)
        else:
            data = self.data
            lats = self.lats  #flip lats upside down?
            lons = self.lons
            # x,y = self.m(*N.meshgrid(lons,lats))

        # xx,uy = self.m(lons,lats)
        # x,y = self.m(*N.meshgrid(lons,lats))
        # x,y = self.m(*N.meshgrid(lons,lats[::-1]))

        # Custom colorbar
        radarcmap = ct.reflect_ncdc(self.clvs)
        # radarcmap = ct.ncdc_modified_ISU(self.clvs)

        # Convert pixel levels to dBZ
        dBZ = self.get_dBZ(data)

        # dBZ[dBZ<0] = 0

        # def plot2D(self,data,fname,outdir,plottype='contourf',
        # save=1,smooth=1,lats=False,lons=False,
        # clvs=False,cmap=False,title=False,colorbar=True,
        # locations=False):
        if not fname:
            tstr = utils.string_from_time('output', self.utc)
            fname = 'verif_radar_{0}.png'.format(tstr)
        F = BirdsEye(fig=fig, ax=ax, proj=self.proj)
        if cb:
            cb = 'horizontal'
        if save is 'auto':
            if (fig is not False) and (ax is not False):
                save = False
            else:
                save = True
        F.plot2D(
            dBZ,
            fname,
            outdir=outdir,
            lats=lats,
            lons=lons,
            cmap=radarcmap,
            clvs=N.arange(5, 90, 5),
            cb=cb,
            cblabel='Composite reflectivity (dBZ)',
            drawcounties=drawcounties,
            save=save,
            lat_ts=50.0,
        )
コード例 #10
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# PLOTTING COMPUTED SCORES
plot_detscores = 0
plot_crps = 0
plot_object_hist = 0

# OBSERVATION GROUPS
ST4 = ObsGroup(st4dir, 'stageiv')
RADARS = ObsGroup(radardir, 'radar')
OBS = (ST4, RADARS)

init_dict = {}
for caseutc, initutcs in CASES.items():
    if caseutc in skiplist:
        print("Skipping {} - in skiplist.".format(caseutc))
        continue
    casestr = utils.string_from_time('dir', caseutc, strlen='day')
    for initutc in initutcs:
        initdir = utils.string_from_time('dir', initutc, strlen='hour')
        ensdir = os.path.join(ensroot, initdir)
        npydir = os.path.join(npyroot, initdir)
        outdir = os.path.join(outroot, casestr, initdir)

        init_dict[initutc] = npydir

        if not load_ens_switch:
            continue
        E = Ensemble(ensdir, initutc, ndoms=2, ctrl=False)
        V = Verif(ensemble=E,
                  obs=OBS,
                  outdir=outdir,
                  datadir=npydir,
コード例 #11
0
def gather_commands_one(i):
    commands = []
    caseutc, initutc, mem, vrbl = i

    initstr = utils.string_from_time('dir', initutc, strlen='hour')
    casestr = utils.string_from_time('dir', caseutc, strlen='day')
    memdir = os.path.join(ensroot, initstr, mem)
    # print("Appending interpolation commands for",mem,"forecast grids of",vrbl,"on", initstr)

    for validutc in generate_valid_utcs(initutc):
        #print(stars,validutc,stars)
        ### d01_3km (d01 cut to d02)
        save_to_fpath = get_extraction_fpaths(vrbl,
                                              "d01_3km",
                                              validutc,
                                              caseutc=caseutc,
                                              initutc=initutc,
                                              mem=mem)
        if not os.path.exists(save_to_fpath):
            data, latsA, lonsA = get_data(vrbl=vrbl,
                                          fmt="d01_raw",
                                          validutc=validutc,
                                          caseutc=caseutc,
                                          initutc=initutc,
                                          mem=mem)
            latsB, lonsB = get_data(caseutc, "d02_raw", latlon_only=True)
            commands.append(
                (data, latsA, lonsA, latsB, lonsB, True, save_to_fpath))

        ### d02_1km - should be a simple one...
        ### todo: compare interp to raw data! They should be very similar
        save_to_fpath = get_extraction_fpaths(vrbl,
                                              "d02_1km",
                                              validutc,
                                              caseutc=caseutc,
                                              initutc=initutc,
                                              mem=mem)
        if not os.path.exists(save_to_fpath):
            data, latsA, lonsA = get_data(vrbl=vrbl,
                                          fmt="d02_raw",
                                          validutc=validutc,
                                          caseutc=caseutc,
                                          initutc=initutc,
                                          mem=mem)
            latsB, lonsB = get_data(caseutc, "d02_raw", latlon_only=True)
            commands.append(
                (data, latsA, lonsA, latsB, lonsB, False, save_to_fpath))

        ### d02_3km (d02 interpolated to 3 km)
        save_to_fpath = get_extraction_fpaths(vrbl,
                                              "d02_3km",
                                              validutc,
                                              caseutc=caseutc,
                                              initutc=initutc,
                                              mem=mem)
        if not os.path.exists(save_to_fpath):
            data, latsA, lonsA = get_data(vrbl=vrbl,
                                          fmt="d02_raw",
                                          validutc=validutc,
                                          caseutc=caseutc,
                                          initutc=initutc,
                                          mem=mem)
            latsB, lonsB = get_data(caseutc, "d01_3km", latlon_only=True)
            commands.append(
                (data, latsA, lonsA, latsB, lonsB, False, save_to_fpath))
    # pdb.set_trace()
    return commands
コード例 #12
0
def lookup_mrms_metadata(caseutc, vrbl):
    """ Return the folder, variable key, grid-spacing of a MRMS dataset.

    fname convention is
    YYYYMMDD-HHMMSS.netcdf

    (Az Shear is per second)

    2016, LL Az Shear:
    /work/john.lawson/MRMS_data/rot-dz/20160331/processed/nofake/merged/MergedLLShear/00.00/*
    LatGridSpacing = 0.01
    MergedLLShear, pixel_x, pixel_y, pixel_count

    2016, ML Az Shear:
    /work/john.lawson/MRMS_data/rot-dz/20160331/processed/nofake/merged/MergedMLShear/00.00/*
    LatGridSpacing = 0.01
    MergedMLShear, pixel_x, pixel_y, pixel_count

    2016, DZ:
    /work/john.lawson/MRMS_data/rot-dz/20160331/processed/nofake/merged/MergedReflectivityQCComposite/00.00/*
    LatGridSpacing: 0.01
    MergedReflectivityQCComposite, ...

    2017, LL Az Shear:
    /work/john.lawson/MRMS_data/rot-dz/20170501/MergedAzShear_0-2kmAGL/00.00/*
    LatGridSpacing = 0.005
    MergedAzShear_0-2kmAGL, ...

    2017, ML Az Shear:
    /work/john.lawson/MRMS_data/rot-dz/20170501/MergedAzShear_2-5kmAGL/00.00/*
    LatGridSpacing: 0.005
    MergedAzShear_2-5kmAGL, ...

    2017 DZ:
    /work/john.lawson/MRMS_data/rot-dz/20170501/MergedReflectivityQCComposite/00.50/*
    LatGridSpacing: 0.01
    MergedReflectivityQCComposite, ...


    """
    casestr = utils.string_from_time('dir', caseutc, strlen='day')

    if caseutc.year == 2016:
        dlat = 0.01
        if vrbl == "DZ":
            key = "MergedReflectivityQCComposite"
        elif vrbl == "AWS02":
            key = 'MergedLLShear'
        elif vrbl == "AWS25":
            key = 'MergedMLShear'
        else:
            raise Exception

        fdir = os.path.join(mrmsdir, casestr, "processed", "nofake", "merged",
                            key, "00.00")
    elif caseutc.year == 2017:
        if vrbl == "DZ":
            dlat = 0.01
            key = 'MergedReflectivityQCComposite'
            subdir = "00.50"
        elif vrbl == "AWS02":
            dlat = 0.005
            key = 'MergedAzShear_0-2kmAGL'
            subdir = "00.00"
        elif vrbl == "AWS25":
            dlat = 0.005
            key = 'MergedAzShear_2-5kmAGL'
            subdir = "00.00"
        else:
            raise Exception

        fdir = os.path.join(mrmsdir, casestr, key, subdir)
    else:
        raise Exception

    return fdir, key, dlat
コード例 #13
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def get_data(caseutc,
             fmt,
             vrbl=None,
             validutc=None,
             initutc=None,
             mem=None,
             latlon_only=False,
             load_latlons=False):
    """ Whatever
    """
    casestr = utils.string_from_time('dir', caseutc, strlen='day')
    if mem:
        assert initutc
        assert (vrbl in FCST_VRBLS) or (vrbl in other_list)
        initstr = utils.string_from_time('dir', initutc, strlen='hour')
        memdir = os.path.join(ensroot, initstr, mem)

    latf, lonf = get_llf_fpath(casestr, fmt)
    if latlon_only:
        if load_latlons:
            return N.load(latf), N.load(lonf)
        else:
            return latf, lonf

    else:
        data_fpath = get_tempdata_fpath(caseutc, fmt, vrbl, validutc, initutc,
                                        mem)

    if fmt == "d01_raw":
        # Load lat/lon grid
        latf, lonf = get_llf_fpath(casestr, "d01_raw")

        # Load 3-km wrfout domain as is, on 2D
        fname = get_wrfout_fname(initutc, dom=1)
        fpath = os.path.join(memdir, fname)
        W = WRFOut(fpath)

        # if vrbl in ("Wmax","UH02","UH25","RAINNC"):
        data = W.get(utc=validutc, vrbl=vrbl)[0, 0, :, :]

    elif fmt == "d02_raw":
        # Load lat/lon grid
        latf, lonf = get_llf_fpath(casestr, "d02_raw")

        # Load 1-km wrfout domain as is, on 2D
        fname = get_wrfout_fname(initutc, dom=2)
        fpath = os.path.join(memdir, fname)
        W = WRFOut(fpath)

        # if vrbl in ("Wmax","UH02","UH25","RAINNC"):
        data = W.get(utc=validutc, vrbl=vrbl)[0, 0, :, :]

    elif fmt in ("mrms_aws_raw", "mrms_dz_raw"):
        latf, lonf = get_llf_fpath(casestr, fmt)

        # Load MRMS data, 2D
        FILES, utcs, key, fdir = return_all_mrms(caseutc, vrbl)
        t = closest(utcs, validutc, return_val=True)
        fpath = os.path.join(fdir, FILES[t])
        mrms_nc = Dataset(fpath)

        # d01_nc = get_random_d01(caseutc)
        data = _unsparsify(
            vrbl=key,
            mrms_nc=mrms_nc,
        )  #d01_nc=d01_nc)
        with N.errstate(invalid='ignore'):
            data[data < -100] = N.nan
            data[data > 100] = N.nan
        # pdb.set_trace()

    elif fmt == "stageiv_raw":
        latf, lonf = get_llf_fpath(casestr, "stageiv_raw")
        # Load stage iv data
        data = ST4.get(utc=validutc)[0, 0, :, :]
        # pdb.set_trace()

    elif fmt == 'nexrad_raw':
        latf, lonf = get_llf_fpath(casestr, "nexrad_raw")
        # Load stage iv data
        data = RADARS.get(utc=validutc)

    else:
        print("fmt not valid.")
        assert True is False

    # This is now done in _save function
    # if N.ma.is_masked(data):
    # data = data.data

    # pdb.set_trace()
    _save(arr=data, file=data_fpath)

    if load_latlons:
        return data_fpath, N.load(latf), N.load(lonf)
    else:
        return data_fpath, latf, lonf
コード例 #14
0
    def plot(
        self,
        data=None,
        outdir=False,
        fig=False,
        ax=False,
        fname=False,
        # Nlim=False, Elim=False, Slim=False,Wlim=False,
        cb=True,
        drawcounties=False,
        save='auto',
        lats=None,
        lons=None,
        proj='merc',
    ):
        """ Plot data.

        Todo:
            * This doesn't feel right. Plotting should be done elsewhere.

        Args:

        save        :   (str,bool) - If 'auto', saving will only occur if
                        fig and ax are not specified.
                        If True, the figure is saved; if False, not.
        """
        # if isinstance(Nlim,float):
        # data, lats, lons = self.get_subdomain(Nlim,Elim,Slim,Wlim)
        # else:
        # if not given, try to use self's

        if data == None:
            data = self.get()
        # data = getattr(self,'data',data)
        if lats == None:
            lats = self.lats
        # lats = getattr(self,'lats',lats)
        if lons == None:
            lons = self.lons
        # lons = getattr(self,'lons',lons)

        # Need to implement options for this
        cmap = None
        clvs = None

        if not fname:
            tstr = utils.string_from_time('output', self.utc)
            fname = 'verif_ST4_{0}.png'.format(tstr)
        F = BirdsEye(fig=fig, ax=ax, proj=proj)
        if cb:
            cb = 'horizontal'
        if save == 'auto':
            if (fig is not False) and (ax is not False):
                save = False
            else:
                save = True
        F.plot2D(
            data,
            fname,
            outdir=outdir,
            lats=lats,
            lons=lons,
            cmap=cmap,
            clvs=clvs,
            cb=cb,
            cblabel='Accumulated precipitation (mm)',
            drawcounties=drawcounties,
            save=save,
            lat_ts=50.0,
        )