def main(argv): # If there are no arguments, send to the welcome screen if not len(sys.argv) > 1: full_paramfile = print_welcome() sys.exit() # Get the arguments import argparse parser = argparse.ArgumentParser() parser.add_argument("-dir", "--base_directory", type=str, help="The base directory with the MLE analyses. If this isn't defined I'll assume it's the same as the current directory.") parser.add_argument("-fname", "--fname_prefix", type=str, help="The prefix of your DEM WITHOUT EXTENSION!!! This must be supplied or you will get an error.") # What sort of analyses you want parser.add_argument("-PR", "--plot_rasters", type=bool, default=False, help="If this is true, I'll make raster plots of the m/n value and basin keys") parser.add_argument("-chi", "--plot_basic_chi", type=bool, default=False, help="If this is true I'll make basin chi plots for each basin coloured by elevation.") parser.add_argument("-PC", "--plot_chi_profiles", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by the MLE") parser.add_argument("-K", "--plot_chi_by_K", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by K. NOTE - you MUST have a column in your chi csv with the K value or this will break!") parser.add_argument("-pcbl", "--plot_chi_by_lith", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by litho. NOTE - you MUST have a column in your chi csv with the K value or this will break!") parser.add_argument("-PO", "--plot_outliers", type=bool, default=False, help="If this is true, I'll make chi-elevation plots with the outliers removed") parser.add_argument("-MLE", "--plot_MLE_movern", type=bool, default=False, help="If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries") parser.add_argument("-SA", "--plot_SA_data", type=bool, default=False, help="If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries") parser.add_argument("-MCMC", "--plot_MCMC", type=bool, default=False, help="If this is true, I'll make a plot of the MCMC analysis. Specify which basins you want with the -basin_keys flag.") parser.add_argument("-pts", "--point_uncertainty", type=bool, default=False, help="If this is true, I'll make a plot of the range in m/n from the MC points analysis") parser.add_argument("-hist", "--plot_histogram", type=bool, default=False, help="If this is true, I'll make plots of the pdfs of m/n values for each method.") # parser.add_argument("-basin_joyplot", "--basin_joyplot", type=bool, default=False, help="If this is true, I'll make a joyplot showing m/n for each basin from the chi points") parser.add_argument("-SUM", "--plot_summary", type=bool, default=False, help="If this is true, I'll make the summary CSV file and plot of the best fit m/n from each of the methods.") parser.add_argument("-ALL", "--all_movern_estimates", type=bool, default=False, help="If this is true, I'll make all the plots") # Plotting options parser.add_argument("-points", "--point_analysis", type=bool, default=False, help="If this is true then I'll assume that you're running the MLE analysis using the point method. Default = False") parser.add_argument("-show_SA_raw", "--show_SA_raw", type=bool, default=True, help="Show the raw S-A data in background of SA plot. Default = True") parser.add_argument("-show_SA_segments", "--show_SA_segments", type=bool, default=False, help="Show the segmented S-A data in SA plot. Default = False") parser.add_argument("-test_SA_regression", "--test_SA_regression", type=bool, default=False, help="If this is true I'll print the regression stats for the slope area plots.") parser.add_argument("-show_legend", "--show_legend", type=bool, default=True, help="If this is true, I'll display the legend for the SA plots.") parser.add_argument("-basin_keys", "--basin_keys",type=str,default = "", help = "This is a comma delimited string that gets the list of basins you want for the plotting. Default = no basins") # These control the format of your figures parser.add_argument("-fmt", "--FigFormat", type=str, default='png', help="Set the figure format for the plots. Default is png") parser.add_argument("-size", "--size_format", type=str, default='ESURF', help="Set the size format for the figure. Can be 'big' (16 inches wide), 'geomorphology' (6.25 inches wide), or 'ESURF' (4.92 inches wide) (defualt esurf).") parser.add_argument("-animate", "--animate", type=bool, default=True, help="If this is true I will create an animation of the chi plots. Must be used with the -PC flag set to True.") parser.add_argument("-keep_pngs", "--keep_pngs", type=bool, default=False, help="If this is true I will delete the png files when I animate the figures. Must be used with the -animate flag set to True.") args = parser.parse_args() if not args.fname_prefix: print("WARNING! You haven't supplied your DEM name. Please specify this with the flag '-fname'") sys.exit() # get the base directory if args.base_directory: Directory = args.base_directory else: Directory = os.getcwd() # check the basins print("You told me that the basin keys are: ") print(args.basin_keys) if len(args.basin_keys) == 0: print("No basins found, I will plot all of them") these_basin_keys = [] else: these_basin_keys = [int(item) for item in args.basin_keys.split(',')] print("The basins I will plot are:") print(these_basin_keys) # get the range of moverns, needed for plotting BasinDF = Helper.ReadBasinStatsCSV(Directory+"/sigma_10/", args.fname_prefix) # we need the column headers columns = BasinDF.columns[BasinDF.columns.str.contains('m_over_n')].tolist() moverns = [float(x.split("=")[-1]) for x in columns] start_movern = moverns[0] n_movern = len(moverns) d_movern = (moverns[-1] - moverns[0])/(n_movern-1) # loop through each sub-directory with the sensitivity results MLE_str = "sigma_" for subdir, dirs, files in os.walk(Directory): for dir in dirs: if MLE_str in dir: this_dir = Directory+"/"+dir+'/' # make the plots depending on your choices # make the plots depending on your choices if args.plot_rasters: MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, simple_format) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, size_format=args.size_format, FigFormat=simple_format) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_points", size_format=args.size_format, FigFormat=simple_format) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="SA", size_format=args.size_format, FigFormat=simple_format) if args.plot_basic_chi: MN.MakePlotsWithMLEStats(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) if args.plot_chi_profiles: MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat = simple_format, animate=args.animate, keep_pngs=args.keep_pngs) if args.plot_chi_by_K: MN.MakeChiPlotsColouredByK(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs) if args.plot_chi_by_lith: MN.MakeChiPlotsColouredByLith(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs) if args.plot_outliers: MN.PlotProfilesRemovingOutliers(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) if args.plot_MLE_movern: MN.PlotMLEWithMOverN(this_dir, args.fname_prefix,basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat =simple_format) if args.plot_SA_data: SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = simple_format,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = args.show_SA_segments,basin_keys = these_basin_keys) if args.test_SA_regression: #SA.TestSARegression(this_dir, args.fname_prefix) SA.LinearRegressionRawDataByChannel(this_dir,args.fname_prefix, basin_list=these_basin_keys) #SA.LinearRegressionSegmentedData(this_dir, args.fname_prefix, basin_list=these_basin_keys) if args.plot_MCMC: MN.plot_MCMC_analysis(this_dir, args.fname_prefix,basin_list=these_basin_keys, FigFormat= simple_format, size_format=args.size_format) if args.point_uncertainty: MN.PlotMCPointsUncertainty(this_dir, args.fname_prefix,basin_list=these_basin_keys, FigFormat=simple_format, size_format=args.size_format,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) if args.plot_histogram: MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend) if args.plot_summary: MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend) MN.MakeMOverNPlotOneMethod(this_dir,args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern,d_movern=d_movern,n_movern=n_movern,FigFormat=args.FigFormat,size_format=args.size_format) # if args.basin_joyplot: # MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) # MN.MakeBasinJoyplot(this_dir, args.fname_prefix, basin_list=these_basin_keys, FigFormat=simple_format, size_format=args.size_format) if args.all_movern_estimates: # plot the rasters MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, args.FigFormat) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_full", size_format=args.size_format, FigFormat=args.FigFormat) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_points", size_format=args.size_format, FigFormat=args.FigFormat) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="SA", size_format=args.size_format, FigFormat=args.FigFormat) # make the chi plots MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat = args.FigFormat, animate=True, keep_pngs=True) # make the SA plots SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = args.FigFormat,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = True, basin_keys = these_basin_keys) SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = args.FigFormat,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = False, basin_keys = these_basin_keys) #summary plots MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = args.FigFormat,size_format=args.size_format, show_legend=args.show_legend) #joyplot MN.MakeMOverNPlotOneMethod(this_dir,args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern,d_movern=d_movern,n_movern=n_movern,FigFormat=args.FigFormat,size_format=args.size_format) #MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend) # collate all the results to get the final figure MN.PlotSensitivityResultsSigma(Directory, args.fname_prefix,FigFormat=args.FigFormat,size_format=args.size_format,movern_method='points')
def main(argv): # print("On some windows systems you need to set an environment variable GDAL_DATA") # print("If the code crashes here it means the environment variable is not set") # print("Let me check gdal enviroment for you. Currently is is:") # print(os.environ['GDAL_DATA']) #os.environ['GDAL_DATA'] = os.popen('gdal-config --datadir').read().rstrip() #print("Now I am going to get the updated version:") #print(os.environ['GDAL_DATA']) # If there are no arguments, send to the welcome screen if not len(sys.argv) > 1: full_paramfile = print_welcome() sys.exit() # Get the arguments import argparse parser = argparse.ArgumentParser() # The location of the data files parser.add_argument( "-dir", "--base_directory", type=str, help= "The base directory that contains your data files. If this isn't defined I'll assume it's the same as the current directory." ) parser.add_argument( "-fname", "--fname_prefix", type=str, help= "The prefix of your DEM WITHOUT EXTENSION!!! This must be supplied or you will get an error (unless you're running the parallel plotting)." ) # What sort of analyses you want parser.add_argument( "-PR", "--plot_rasters", type=bool, default=False, help= "If this is true, I'll make raster plots of the m/n value and basin keys" ) parser.add_argument( "-chi", "--plot_basic_chi", type=bool, default=False, help= "If this is true I'll make basin chi plots for each basin coloured by elevation." ) parser.add_argument( "-PC", "--plot_chi_profiles", type=bool, default=False, help= "If this is true, I'll make chi-elevation plots for each basin coloured by the MLE" ) parser.add_argument( "-K", "--plot_chi_by_K", type=bool, default=False, help= "If this is true, I'll make chi-elevation plots for each basin coloured by K. NOTE - you MUST have a column in your chi csv with the K value or this will break!" ) parser.add_argument( "-pcbl", "--plot_chi_by_lith", type=bool, default=False, help= "If this is true, I'll make chi-elevation plots for each basin coloured by litho. NOTE - you MUST have a column in your chi csv with the K value or this will break!" ) parser.add_argument( "-PO", "--plot_outliers", type=bool, default=False, help= "If this is true, I'll make chi-elevation plots with the outliers removed" ) parser.add_argument( "-MLE", "--plot_MLE_movern", type=bool, default=False, help= "If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries" ) parser.add_argument( "-SA", "--plot_SA_data", type=bool, default=False, help= "If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries" ) parser.add_argument( "-MCMC", "--plot_MCMC", type=bool, default=False, help= "If this is true, I'll make a plot of the MCMC analysis. Specify which basins you want with the -basin_keys flag." ) parser.add_argument( "-pts", "--point_uncertainty", type=bool, default=False, help= "If this is true, I'll make a plot of the range in m/n from the MC points analysis" ) parser.add_argument( "-hist", "--plot_histogram", type=bool, default=False, help= "If this is true, I'll make plots of the pdfs of m/n values for each method." ) parser.add_argument( "-disorder", "--plot_disorder", type=bool, default=False, help="If this is true, I'll make plots of the chi disorder analysis.") parser.add_argument( "-SUM", "--plot_summary", type=bool, default=False, help= "If this is true, I'll make the summary CSV file and plot of the best fit concavity from each of the methods." ) parser.add_argument("-ALL", "--all_movern_estimates", type=bool, default=False, help="If this is true, I'll make all the plots") parser.add_argument( "-DisFxnDist", "--disorder_function_of_distance", type=bool, default=False, help= "If this is true, I'll make a plot of the disorder metric as a function of position" ) # Plotting options parser.add_argument( "-points", "--point_analysis", type=bool, default=False, help= "If this is true then I'll assume that you're running the MLE analysis using the point method. Default = False" ) parser.add_argument( "-show_SA_raw", "--show_SA_raw", type=bool, default=True, help="Show the raw S-A data in background of SA plot. Default = True") parser.add_argument( "-show_SA_segments", "--show_SA_segments", type=bool, default=False, help="Show the segmented S-A data in SA plot. Default = False") parser.add_argument( "-test_SA_regression", "--test_SA_regression", type=bool, default=False, help= "If this is true I'll print the regression stats for the slope area plots." ) parser.add_argument( "-show_legend", "--show_legend", type=bool, default=True, help="If this is true, I'll display the legend for plots.") parser.add_argument( "-no_legend", "--no_legend", dest="show_legend", action="store_false", help= "Flag to not display legends, I'll not display the legend for plots, default is for legend to be displayed. Note taht setting show_legend False does not achieve this due to bool issues with python parsing" ) # Options about basin selection parser.add_argument( "-basin_keys", "--basin_keys", type=str, default="", help= "This is a comma delimited string that gets the list of basins you want for the plotting. Default = no basins" ) parser.add_argument( "-basin_lists", "--basin_lists", type=str, default="", help= "This is a string that initiates a list of a list for grouping basins. The object becomes a list of a list but the syntax is comma seperated lists, and each one is separated by a colon. Default = no dict" ) parser.add_argument( "-group_names", "--group_names", type=str, default="", help="Names of the groups provided by basin_lists. Used in legends") # These control the format of your figures parser.add_argument( "-fmt", "--FigFormat", type=str, default='png', help="Set the figure format for the plots. Default is png") parser.add_argument( "-size", "--size_format", type=str, default='ESURF', help= "Set the size format for the figure. Can be 'big' (16 inches wide), 'geomorphology' (6.25 inches wide), or 'ESURF' (4.92 inches wide) (defualt esurf)." ) parser.add_argument( "-animate", "--animate", type=bool, default=True, help= "If this is true I will create an animation of the chi plots. Must be used with the -PC flag set to True." ) parser.add_argument( "-keep_pngs", "--keep_pngs", type=bool, default=False, help= "If this is true I will delete the png files when I animate the figures. Must be used with the -animate flag set to True." ) parser.add_argument( "-parallel", "--parallel", type=bool, default=False, help= "If this is true I'll assume you ran the code in parallel and append all your CSVs together before plotting." ) args = parser.parse_args() print(argv) print(args) if not args.fname_prefix: if not args.parallel: print( "WARNING! You haven't supplied your DEM name. Please specify this with the flag '-fname'" ) sys.exit() # get the base directory if args.base_directory: this_dir = args.base_directory # check if you remembered a / at the end of your path_name if not this_dir.endswith("/"): print( "You forgot the '/' at the end of the directory, appending...") this_dir = this_dir + "/" else: this_dir = os.getcwd() # check the basins print("You told me that the basin keys are: ") print(args.basin_keys) # See if a basin info file exists and if so get the basin list print("Let me check if there is a basins info csv file.") BasinInfoPrefix = args.fname_prefix + "_AllBasinsInfo.csv" BasinInfoFileName = this_dir + BasinInfoPrefix existing_basin_keys = [] if os.path.isfile(BasinInfoFileName): print("There is a basins info csv file") BasinInfoDF = Helper.ReadBasinInfoCSV(this_dir, args.fname_prefix) existing_basin_keys = list(BasinInfoDF['basin_key']) existing_basin_keys = [int(x) for x in existing_basin_keys] else: print( "I didn't find a basins info csv file. Check directory or filename." ) # Parse any lists, dicts, or list of lists from the arguments these_basin_keys = parse_list_from_string(args.basin_keys) basin_stack_list = parse_list_of_list_from_string(args.basin_lists) basin_stack_names = parse_string_list_from_string(args.group_names) # If the basin keys are not supplied then assume all basins are used. if these_basin_keys == []: these_basin_keys = existing_basin_keys # Python is so amazing. Look at the line below. Mask_basin_keys = [ i for i in existing_basin_keys if i not in these_basin_keys ] print("All basins are: ") print(existing_basin_keys) print("The basins to keep are:") print(these_basin_keys) print("The basins to mask are:") print(Mask_basin_keys) # This is an old version. It passes empty strings to the plotting functions. #if len(args.basin_keys) == 0: # print("No basins found, I will plot all of them") # # Note that if you pass an empty list to the plotting functions, they will plot all the basins # these_basin_keys = [] #else: # these_basin_keys = [int(item) for item in args.basin_keys.split(',')] # print("The basins I will plot are:") # print(these_basin_keys) # This checks to see if chi points method is being used. # If not, assumes only the disorder metric has been calculated Using_disorder_metric_only = check_if_disorder_metric_only( this_dir, args.fname_prefix) if not args.parallel: BasinDF = Helper.ReadBasinStatsCSV(this_dir, args.fname_prefix) else: BasinDF = Helper.AppendBasinCSVs(this_dir, args.fname_prefix) # if parallel, get the fname from the data directory. This assumes that your directory is called # something sensible that relates to the DEM name. split_fname = this_dir.split("/") split_fname = split_fname[len(split_fname) - 2] # get the range of moverns, needed for plotting # we need the column headers columns = BasinDF.columns[BasinDF.columns.str.contains( 'm_over_n')].tolist() moverns = [float(x.split("=")[-1]) for x in columns] start_movern = moverns[0] n_movern = len(moverns) x = Decimal((moverns[-1] - moverns[0]) / (n_movern - 1)) d_movern = round(x, 2) print('Start movern, n_movern, d_movern: ') print(start_movern, n_movern, d_movern) # some formatting for the figures if args.FigFormat == "manuscipt_svg": print( "You chose the manuscript svg option. This only works with the -ALL flag. For other flags it will default to simple svg" ) simple_format = "svg" elif args.FigFormat == "manuscript_png": print( "You chose the manuscript png option. This only works with the -ALL flag. For other flags it will default to simple png" ) simple_format = "png" else: simple_format = args.FigFormat # make the plots depending on your choices if args.plot_rasters: MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, simple_format, parallel=args.parallel) if args.plot_basic_chi: MN.MakePlotsWithMLEStats(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel) if args.plot_chi_profiles: if Using_disorder_metric_only: MN.MakeChiPlotsChi(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=args.FigFormat, animate=True, keep_pngs=True, parallel=args.parallel) else: MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=args.FigFormat, animate=True, keep_pngs=True, parallel=args.parallel) if args.plot_chi_by_K: MN.MakeChiPlotsColouredByK(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs, parallel=args.parallel) if args.plot_chi_by_lith: MN.MakeChiPlotsColouredByLith(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs, parallel=args.parallel) if args.plot_outliers: MN.PlotProfilesRemovingOutliers(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel) if args.plot_MLE_movern: MN.PlotMLEWithMOverN(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, parallel=args.parallel) if args.plot_SA_data: SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat=simple_format, size_format=args.size_format, show_raw=args.show_SA_raw, show_segments=args.show_SA_segments, basin_keys=these_basin_keys, parallel=args.parallel) if args.test_SA_regression: #SA.TestSARegression(this_dir, args.fname_prefix) SA.LinearRegressionRawDataByChannel(this_dir, args.fname_prefix, basin_list=these_basin_keys, parallel=args.parallel) #SA.LinearRegressionSegmentedData(this_dir, args.fname_prefix, basin_list=these_basin_keys) if args.plot_MCMC: MN.plot_MCMC_analysis(this_dir, args.fname_prefix, basin_list=these_basin_keys, FigFormat=simple_format, size_format=args.size_format, parallel=args.parallel) if args.point_uncertainty: MN.PlotMCPointsUncertainty(this_dir, args.fname_prefix, basin_list=these_basin_keys, FigFormat=simple_format, size_format=args.size_format, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel) if args.plot_histogram: MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.plot_summary: # This function creates a csv that has the concavity statistics in it MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, Chi_disorder=True) # This only prints the summary plots for bootstrap and disorder metrics MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, Chi_all=False, SA_raw=False, SA_segmented=False, SA_channels=False, Chi_bootstrap=True, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.plot_disorder: MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_disorder", size_format=args.size_format, FigFormat=args.FigFormat, parallel=args.parallel) # This function creates a csv that has the concavity statistics in it MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.all_movern_estimates: print("I am going to print out loads and loads of figures for you.") # plot the rasters MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, args.FigFormat, parallel=args.parallel) if not Using_disorder_metric_only: MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_full", size_format=args.size_format, FigFormat=args.FigFormat, parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_points", size_format=args.size_format, FigFormat=args.FigFormat, parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="SA", size_format=args.size_format, FigFormat=args.FigFormat, parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_disorder", size_format=args.size_format, FigFormat=args.FigFormat, parallel=args.parallel) # make the chi plots if Using_disorder_metric_only: MN.MakeChiPlotsChi(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=args.FigFormat, animate=True, keep_pngs=True, parallel=args.parallel) else: MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=args.FigFormat, animate=True, keep_pngs=True, parallel=args.parallel) # make the SA plots SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat=args.FigFormat, size_format=args.size_format, show_raw=args.show_SA_raw, show_segments=True, basin_keys=these_basin_keys, parallel=args.parallel) SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat=args.FigFormat, size_format=args.size_format, show_raw=args.show_SA_raw, show_segments=False, basin_keys=these_basin_keys, parallel=args.parallel) #summary plots # This function creates a csv that has the concavity statistics in it MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, Chi_disorder=True) # This only prints the summary plots for bootstrap and disorder metrics MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, Chi_all=False, SA_raw=False, SA_segmented=False, SA_channels=False, Chi_bootstrap=True, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.disorder_function_of_distance: # This function creates a csv that has the concavity statistics in it print("=====================================================") print("=====================================================") print("\n\n\n\nI am going to get the summary information.") # See if the summary already exists print("Let me check if there is a concavity summary csv file.") SummaryPrefix = args.fname_prefix + "_movern_summary.csv" SummaryFileName = this_dir + "summary_plots/" + SummaryPrefix print("The summary filename is: " + SummaryFileName) if os.path.isfile(SummaryFileName): print("There is already a summary file") else: print("No summray csv found. I will calculate a new one.") MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) # Okay, now we plot the metrics as a function of distance print("I am going to print the following lists of basins: ") print(basin_stack_list) MN.MakeMOverNDisorderDistancePlot(this_dir, args.fname_prefix, basin_list_list=basin_stack_list, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend, parallel=args.parallel, group_names=basin_stack_names)
def main(argv): # print("On some windows systems you need to set an environment variable GDAL_DATA") # print("If the code crashes here it means the environment variable is not set") # print("Let me check gdal enviroment for you. Currently is is:") # print(os.environ['GDAL_DATA']) #os.environ['GDAL_DATA'] = os.popen('gdal-config --datadir').read().rstrip() #print("Now I am going to get the updated version:") #print(os.environ['GDAL_DATA']) # If there are no arguments, send to the welcome screen if not len(sys.argv) > 1: full_paramfile = print_welcome() sys.exit() # Get the arguments import argparse parser = argparse.ArgumentParser() # The location of the data files parser.add_argument("-dir", "--base_directory", type=str, help="The base directory that contains your data files. If this isn't defined I'll assume it's the same as the current directory.") parser.add_argument("-fname", "--fname_prefix", type=str, help="The prefix of your DEM WITHOUT EXTENSION!!! This must be supplied or you will get an error (unless you're running the parallel plotting).") # What sort of analyses you want parser.add_argument("-PR", "--plot_rasters", type=bool, default=False, help="If this is true, I'll make raster plots of the m/n value and basin keys") parser.add_argument("-chi", "--plot_basic_chi", type=bool, default=False, help="If this is true I'll make basin chi plots for each basin coloured by elevation.") parser.add_argument("-PC", "--plot_chi_profiles", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by the MLE") parser.add_argument("-K", "--plot_chi_by_K", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by K. NOTE - you MUST have a column in your chi csv with the K value or this will break!") parser.add_argument("-pcbl", "--plot_chi_by_lith", type=bool, default=False, help="If this is true, I'll make chi-elevation plots for each basin coloured by litho. NOTE - you MUST have a column in your chi csv with the K value or this will break!") parser.add_argument("-PO", "--plot_outliers", type=bool, default=False, help="If this is true, I'll make chi-elevation plots with the outliers removed") parser.add_argument("-MLE", "--plot_MLE_movern", type=bool, default=False, help="If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries") parser.add_argument("-SA", "--plot_SA_data", type=bool, default=False, help="If this is true, I'll make a plot of the MLE values for each m/n showing how the MLE values change as you remove the tributaries") parser.add_argument("-MCMC", "--plot_MCMC", type=bool, default=False, help="If this is true, I'll make a plot of the MCMC analysis. Specify which basins you want with the -basin_keys flag.") parser.add_argument("-pts", "--point_uncertainty", type=bool, default=False, help="If this is true, I'll make a plot of the range in m/n from the MC points analysis") parser.add_argument("-hist", "--plot_histogram", type=bool, default=False, help="If this is true, I'll make plots of the pdfs of m/n values for each method.") parser.add_argument("-disorder", "--plot_disorder", type=bool, default=False, help="If this is true, I'll make plots of the chi disorder analysis.") # parser.add_argument("-basin_joyplot", "--basin_joyplot", type=bool, default=False, help="If this is true, I'll make a joyplot showing m/n for each basin from the chi points") parser.add_argument("-SUM", "--plot_summary", type=bool, default=False, help="If this is true, I'll make the summary CSV file and plot of the best fit concavity from each of the methods.") parser.add_argument("-ALL", "--all_movern_estimates", type=bool, default=False, help="If this is true, I'll make all the plots") # Plotting options parser.add_argument("-points", "--point_analysis", type=bool, default=False, help="If this is true then I'll assume that you're running the MLE analysis using the point method. Default = False") parser.add_argument("-show_SA_raw", "--show_SA_raw", type=bool, default=True, help="Show the raw S-A data in background of SA plot. Default = True") parser.add_argument("-show_SA_segments", "--show_SA_segments", type=bool, default=False, help="Show the segmented S-A data in SA plot. Default = False") parser.add_argument("-test_SA_regression", "--test_SA_regression", type=bool, default=False, help="If this is true I'll print the regression stats for the slope area plots.") parser.add_argument("-show_legend", "--show_legend", type=bool, default=True, help="If this is true, I'll display the legend for plots.") parser.add_argument("-no_legend", "--no_legend", dest="show_legend", action="store_false", help="Flag to not display legends, I'll not display the legend for plots, default is for legend to be displayed. Note taht setting show_legend False does not achieve this due to bool issues with python parsing") parser.add_argument("-basin_keys", "--basin_keys",type=str,default = "", help = "This is a comma delimited string that gets the list of basins you want for the plotting. Default = no basins") # These control the format of your figures parser.add_argument("-fmt", "--FigFormat", type=str, default='png', help="Set the figure format for the plots. Default is png") parser.add_argument("-size", "--size_format", type=str, default='ESURF', help="Set the size format for the figure. Can be 'big' (16 inches wide), 'geomorphology' (6.25 inches wide), or 'ESURF' (4.92 inches wide) (defualt esurf).") parser.add_argument("-animate", "--animate", type=bool, default=True, help="If this is true I will create an animation of the chi plots. Must be used with the -PC flag set to True.") parser.add_argument("-keep_pngs", "--keep_pngs", type=bool, default=False, help="If this is true I will delete the png files when I animate the figures. Must be used with the -animate flag set to True.") parser.add_argument("-parallel", "--parallel", type=bool, default=False, help="If this is true I'll assume you ran the code in parallel and append all your CSVs together before plotting.") args = parser.parse_args() print(argv) print(args) if not args.fname_prefix: if not args.parallel: print("WARNING! You haven't supplied your DEM name. Please specify this with the flag '-fname'") sys.exit() # check the basins print("You told me that the basin keys are: ") print(args.basin_keys) if len(args.basin_keys) == 0: print("No basins found, I will plot all of them") these_basin_keys = [] else: these_basin_keys = [int(item) for item in args.basin_keys.split(',')] print("The basins I will plot are:") print(these_basin_keys) # get the base directory if args.base_directory: this_dir = args.base_directory # check if you remembered a / at the end of your path_name if not this_dir.endswith("/"): print("You forgot the '/' at the end of the directory, appending...") this_dir = this_dir+"/" else: this_dir = os.getcwd() # get the range of moverns, needed for plotting if not args.parallel: BasinDF = Helper.ReadBasinStatsCSV(this_dir, args.fname_prefix) else: BasinDF = Helper.AppendBasinCSVs(this_dir, args.fname_prefix) # if parallel, get the fname from the data directory. This assumes that your directory is called # something sensible that relates to the DEM name. split_fname = this_dir.split("/") split_fname = split_fname[len(split_fname)-2] #args.fname_prefix = split_fname # commented out for now since base fname given, basins will always have basinX fname_prefix # # we need the column headers columns = BasinDF.columns[BasinDF.columns.str.contains('m_over_n')].tolist() moverns = [float(x.split("=")[-1]) for x in columns] start_movern = moverns[0] n_movern = len(moverns) x = Decimal((moverns[-1] - moverns[0])/(n_movern-1)) d_movern = round(x,2) print ('Start movern, n_movern, d_movern: ') print (start_movern, n_movern, d_movern) # some formatting for the figures if args.FigFormat == "manuscipt_svg": print("You chose the manuscript svg option. This only works with the -ALL flag. For other flags it will default to simple svg") simple_format = "svg" elif args.FigFormat == "manuscript_png": print("You chose the manuscript png option. This only works with the -ALL flag. For other flags it will default to simple png") simple_format = "png" else: simple_format = args.FigFormat # make the plots depending on your choices if args.plot_rasters: MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, simple_format, parallel=args.parallel) # MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, size_format=args.size_format, FigFormat=simple_format, parallel=args.parallel) # MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_points", size_format=args.size_format, FigFormat=simple_format,parallel=args.parallel) # MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="SA", size_format=args.size_format, FigFormat=simple_format,parallel=args.parallel) if args.plot_basic_chi: MN.MakePlotsWithMLEStats(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern,parallel=args.parallel) if args.plot_chi_profiles: MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat = simple_format, animate=args.animate, keep_pngs=args.keep_pngs, parallel=args.parallel) if args.plot_chi_by_K: MN.MakeChiPlotsColouredByK(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs, parallel=args.parallel) if args.plot_chi_by_lith: MN.MakeChiPlotsColouredByLith(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat=simple_format, animate=args.animate, keep_pngs=args.keep_pngs,parallel=args.parallel) if args.plot_outliers: MN.PlotProfilesRemovingOutliers(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern,parallel=args.parallel) if args.plot_MLE_movern: MN.PlotMLEWithMOverN(this_dir, args.fname_prefix,basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat =simple_format,parallel=args.parallel) if args.plot_SA_data: SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = simple_format,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = args.show_SA_segments,basin_keys = these_basin_keys, parallel=args.parallel) if args.test_SA_regression: #SA.TestSARegression(this_dir, args.fname_prefix) SA.LinearRegressionRawDataByChannel(this_dir,args.fname_prefix, basin_list=these_basin_keys, parallel=args.parallel) #SA.LinearRegressionSegmentedData(this_dir, args.fname_prefix, basin_list=these_basin_keys) if args.plot_MCMC: MN.plot_MCMC_analysis(this_dir, args.fname_prefix,basin_list=these_basin_keys, FigFormat= simple_format, size_format=args.size_format,parallel=args.parallel) if args.point_uncertainty: MN.PlotMCPointsUncertainty(this_dir, args.fname_prefix,basin_list=these_basin_keys, FigFormat=simple_format, size_format=args.size_format,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern,parallel=args.parallel) if args.plot_histogram: MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=simple_format, size_format=args.size_format, show_legend=args.show_legend) if args.plot_summary: MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend,parallel=args.parallel, Chi_disorder=True) # This only prints the summary plots for bootstrap and disorder metrics MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend,parallel=args.parallel, Chi_all = False, SA_raw = False, SA_segmented = False, SA_channels = False, Chi_bootstrap = True, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.plot_disorder: MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_disorder", size_format=args.size_format, FigFormat=args.FigFormat,parallel=args.parallel) MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend,parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True) if args.all_movern_estimates: # plot the rasters MN.MakeRasterPlotsBasins(this_dir, args.fname_prefix, args.size_format, args.FigFormat,parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_full", size_format=args.size_format, FigFormat=args.FigFormat,parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_points", size_format=args.size_format, FigFormat=args.FigFormat,parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="SA", size_format=args.size_format, FigFormat=args.FigFormat,parallel=args.parallel) MN.MakeRasterPlotsMOverN(this_dir, args.fname_prefix, start_movern, n_movern, d_movern, movern_method="Chi_disorder", size_format=args.size_format, FigFormat=args.FigFormat,parallel=args.parallel) # make the chi plots MN.MakeChiPlotsMLE(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, size_format=args.size_format, FigFormat = args.FigFormat, animate=True, keep_pngs=True,parallel=args.parallel) # make the SA plots SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = args.FigFormat,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = True, basin_keys = these_basin_keys, parallel=args.parallel) SA.SAPlotDriver(this_dir, args.fname_prefix, FigFormat = args.FigFormat,size_format=args.size_format, show_raw = args.show_SA_raw, show_segments = False, basin_keys = these_basin_keys, parallel=args.parallel) #summary plots MN.CompareMOverNEstimatesAllMethods(this_dir, args.fname_prefix, basin_list=these_basin_keys, start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, parallel=args.parallel, Chi_disorder=True) MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend,parallel=args.parallel, Chi_disorder=True) # This only prints the summary plots for bootstrap and disorder metrics MN.MakeMOverNSummaryPlot(this_dir, args.fname_prefix, basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat = simple_format,size_format=args.size_format, show_legend=args.show_legend,parallel=args.parallel, Chi_all = False, SA_raw = False, SA_segmented = False, SA_channels = False, Chi_bootstrap = True, Chi_disorder=True) MN.MakeMOverNSummaryHistogram(this_dir, args.fname_prefix,basin_list=these_basin_keys,start_movern=start_movern, d_movern=d_movern, n_movern=n_movern, FigFormat=args.FigFormat, size_format=args.size_format, show_legend=args.show_legend, Chi_disorder=True)