Writing your own diagnostic script
Last updated on 2024-11-26 | Edit this page
Overview
Questions
- How do I write a new diagnostic in ESMValTool?
- How do I use the preprocessor output in a Python diagnostic?
Objectives
- Write a new Python diagnostic script.
- Explain how a diagnostic script reads the preprocessor output.
Introduction
The diagnostic script is an important component of ESMValTool and it is where the scientific analysis or performance metric is implemented. With ESMValTool, you can adapt an existing diagnostic or write a new script from scratch. Diagnostics can be written in a number of open source languages such as Python, R, Julia and NCL but we will focus on understanding and writing Python diagnostics in this lesson.
In this lesson, we will explain how to find an existing diagnostic and run it using ESMValTool installed in editable/development mode. For a development installation, see the instructions in the lesson Development and contribution. Also, we will work with the recipe [recipe_python.yml][recipe] and the diagnostic script [diagnostic.py][diagnostic] called by this recipe that we have seen in the lesson Running your first recipe .
Let’s get started!
Understanding an existing Python diagnostic
If you clone the ESMValTool repository, a folder called
ESMValTool
is created in your home/working directory, see
the instructions in the lesson Development and contribution .
The folder ESMValTool
contains the source code of the
tool. We can find the recipe recipe_python.yml
and the
python script diagnostic.py
in these directories:
- ~/ESMValTool/esmvaltool/recipes/examples/recipe_python.yml
- ~/ESMValTool/esmvaltool/diag_scripts/examples/diagnostic.py
Let’s have look at the code in diagnostic.py
. For
reference, we show the diagnostic code in the dropdown box below. There
are four main sections in the script:
- A description i.e. the
docstring
(line 1). - Import statements (line 2-16).
- Functions that implement our analysis (line 21-102).
- A typical Python top-level script
i.e.
if __name__ == '__main__'
(line 105-108).
PYTHON
1: """Python example diagnostic."""
2: import logging
3: from pathlib import Path
4: from pprint import pformat
5:
6: import iris
7:
8: from esmvaltool.diag_scripts.shared import (
9: group_metadata,
10: run_diagnostic,
11: save_data,
12: save_figure,
13: select_metadata,
14: sorted_metadata,
15: )
16: from esmvaltool.diag_scripts.shared.plot import quickplot
17:
18: logger = logging.getLogger(Path(__file__).stem)
19:
20:
21: def get_provenance_record(attributes, ancestor_files):
22: """Create a provenance record describing the diagnostic data and plot."""
23: caption = caption = attributes['caption'].format(**attributes)
24:
25: record = {
26: 'caption': caption,
27: 'statistics': ['mean'],
28: 'domains': ['global'],
29: 'plot_types': ['zonal'],
30: 'authors': [
31: 'andela_bouwe',
32: 'righi_mattia',
33: ],
34: 'references': [
35: 'acknow_project',
36: ],
37: 'ancestors': ancestor_files,
38: }
39: return record
40:
41:
42: def compute_diagnostic(filename):
43: """Compute an example diagnostic."""
44: logger.debug("Loading %s", filename)
45: cube = iris.load_cube(filename)
46:
47: logger.debug("Running example computation")
48: cube = iris.util.squeeze(cube)
49: return cube
50:
51:
52: def plot_diagnostic(cube, basename, provenance_record, cfg):
53: """Create diagnostic data and plot it."""
54:
55: # Save the data used for the plot
56: save_data(basename, provenance_record, cfg, cube)
57:
58: if cfg.get('quickplot'):
59: # Create the plot
60: quickplot(cube, **cfg['quickplot'])
61: # And save the plot
62: save_figure(basename, provenance_record, cfg)
63:
64:
65: def main(cfg):
66: """Compute the time average for each input dataset."""
67: # Get a description of the preprocessed data that we will use as input.
68: input_data = cfg['input_data'].values()
69:
70: # Demonstrate use of metadata access convenience functions.
71: selection = select_metadata(input_data, short_name='tas', project='CMIP5')
72: logger.info("Example of how to select only CMIP5 temperature data:\n%s",
73: pformat(selection))
74:
75: selection = sorted_metadata(selection, sort='dataset')
76: logger.info("Example of how to sort this selection by dataset:\n%s",
77: pformat(selection))
78:
79: grouped_input_data = group_metadata(input_data,
80: 'variable_group',
81: sort='dataset')
82: logger.info(
83: "Example of how to group and sort input data by variable groups from "
84: "the recipe:\n%s", pformat(grouped_input_data))
85:
86: # Example of how to loop over variables/datasets in alphabetical order
87: groups = group_metadata(input_data, 'variable_group', sort='dataset')
88: for group_name in groups:
89: logger.info("Processing variable %s", group_name)
90: for attributes in groups[group_name]:
91: logger.info("Processing dataset %s", attributes['dataset'])
92: input_file = attributes['filename']
93: cube = compute_diagnostic(input_file)
94:
95: output_basename = Path(input_file).stem
96: if group_name != attributes['short_name']:
97: output_basename = group_name + '_' + output_basename
98: if "caption" not in attributes:
99: attributes['caption'] = input_file
100: provenance_record = get_provenance_record(
101: attributes, ancestor_files=[input_file])
102: plot_diagnostic(cube, output_basename, provenance_record, cfg)
103:
104:
105: if __name__ == '__main__':
106:
107: with run_diagnostic() as config:
108: main(config)
What is the starting point of a diagnostic?
- Can you spot a function called
main
in the code above? - What are its input arguments?
- How many times is this function mentioned?
- The
main
function is defined in line 65 asmain(cfg)
. - The input argument to this function is the variable
cfg
, a Python dictionary that holds all the necessary information needed to run the diagnostic script such as the location of input data and various settings. We will next parse thiscfg
variable in themain
function and extract information as needed to do our analyses (e.g. in line 68). - The
main
function is called near the very end on line 108. So, it is mentioned twice in our code - once where it is called by the top-level Python script and second where it is defined.
The function run_diagnostic
The function run_diagnostic
(line 107) is called a
context manager provided with ESMValTool and is the main entry point for
most Python diagnostics.
Preprocessor-diagnostic interface
In the previous exercise, we have seen that the variable
cfg
is the input argument of the main
function. The first argument passed to the diagnostic via the
cfg
dictionary is a path to a file called
settings.yml
. The ESMValTool documentation page provides an
overview of what is in this file, see [Diagnostic script
interfaces][interface].
What information do I need when writing a diagnostic script?
From the lesson Configuration, we
saw how to change the configuration settings before running a recipe.
First we set the option remove_preproc_dir
to
false
in the configuration file, then run the recipe
recipe_python.yml
:
- Find one example of the file
settings.yml
in therun
directory? - Open the file
settings.yml
and look at theinput_files
list. It contains paths to some filesmetadata.yml
. What information do you think is saved in those files?
- One example of
settings.yml
can be found in the directory: path_to_recipe_output/run/map/script1/settings.yml - The
metadata.yml
files hold information about the preprocessed data. There is one file for each variable having detailed information on your data including project (e.g., CMIP6, CMIP5), dataset names (e.g., BCC-ESM1, CanESM2), variable attributes (e.g., standard_name, units), preprocessor applied and time range of the data. You can use all of this information in your own diagnostic.
Diagnostic shared functions
Looking at the code in diagnostic.py
, we see that
input_data
is read from the cfg
dictionary
(line 68). Now we can group the input_data
according to
some criteria such as the model or experiment. To do so, ESMValTool
provides many functions such as select_metadata
(line 71),
sorted_metadata
(line 75), and group_metadata
(line 79). As you can see in line 8, these functions are imported from
esmvaltool.diag_scripts.shared
that means these are shared
across several diagnostics scripts. A list of available functions and
their description can be found in [The ESMValTool Diagnostic API
reference][shared].
Extracting information needed for analyses
We have seen the functions used for selecting, sorting and grouping data in the script. What do these functions do?
Answer
There is a statement after use of
select_metadata
,sorted_metadata
andgroup_metadata
that starts withlogger.info
(lines 72, 76 and 82). These lines print output to the log files. In the previous exercise, we ran the reciperecipe_python.yml
. If you look at the log filerecipe_python_#_#/run/map/script1/log.txt
inesmvaltool_output
directory, you can see the output from each of these functions, for example:2023-06-28 12:47:14,038 [2548510] INFO diagnostic,106 Example of how to group and sort input data by variable groups from the recipe: {'tas': [{'alias': 'CMIP5', 'caption': 'Global map of {long_name} in January 2000 according to ' '{dataset}.\n', 'dataset': 'bcc-csm1-1', 'diagnostic': 'map', 'end_year': 2000, 'ensemble': 'r1i1p1', 'exp': 'historical', 'filename': '~/recipe_python_20230628_124639/preproc/map/tas/
CMIP5_bcc-csm1-1_Amon_historical_r1i1p1_tas_2000-P1M.nc',
'frequency': 'mon', 'institute': ['BCC'], 'long_name': 'Near-Surface Air Temperature', 'mip': 'Amon', 'modeling_realm': ['atmos'], 'preprocessor': 'to_degrees_c', 'product': ['output1', 'output2'], 'project': 'CMIP5', 'recipe_dataset_index': 1, 'short_name': 'tas', 'standard_name': 'air_temperature', 'start_year': 2000, 'timerange': '2000/P1M', 'units': 'degrees_C', 'variable_group': 'tas', 'version': 'v1'}, {'activity': 'CMIP', 'alias': 'CMIP6', 'caption': 'Global map of {long_name} in January 2000 according to ' '{dataset}.\n', 'dataset': 'BCC-ESM1', 'diagnostic': 'map', 'end_year': 2000, 'ensemble': 'r1i1p1f1', 'exp': 'historical', 'filename': '~/recipe_python_20230628_124639/preproc/map/tas/
CMIP6_BCC-ESM1_Amon_historical_r1i1p1f1_tas_gn_2000-P1M.nc',
Challenge
'frequency': 'mon',
'grid': 'gn',
'institute': ['BCC'],
'long_name': 'Near-Surface Air Temperature',
'mip': 'Amon',
'modeling_realm': ['atmos'],
'preprocessor': 'to_degrees_c',
'project': 'CMIP6',
'recipe_dataset_index': 0,
'short_name': 'tas',
'standard_name': 'air_temperature',
'start_year': 2000,
'timerange': '2000/P1M',
'units': 'degrees_C',
'variable_group': 'tas',
'version': 'v20181214'}]}
This is how we can access preprocessed data within our diagnostic.
Diagnostic computation
After grouping and selecting data, we can read individual attributes
(such as filename) of each item. Here, we have grouped the input data by
variables
, so we loop over the variables (line 88).
Following this is a call to the function compute_diagnostic
(line 93). Let’s look at the definition of this function in line 42,
where the actual analysis of the data is done.
Note that output from the ESMValCore preprocessor is in the form of
NetCDF files. Here, compute_diagnostic
uses Iris
to read data from a netCDF file and performs an operation
squeeze
to remove any dimensions of length one. We can
adapt this function to add our own analysis. As an example, here we
calculate the bias using the average of the data using Iris cubes.
PYTHON
def compute_diagnostic(filename):
"""Compute an example diagnostic."""
logger.debug("Loading %s", filename)
cube = iris.load_cube(filename)
logger.debug("Running example computation")
cube = iris.util.squeeze(cube)
# Calculate a bias using the average of data
cube.data = cube.core_data() - cube.core_data.mean()
return cube
iris cubes
Iris reads data from NetCDF files into data structures called cubes. The data in these cubes can be modified, combined with other cubes’ data or plotted.
Reading data using xarray
Alternately, you can use xarrays to read the data instead of Iris.
First, import xarray
package at the top of the script
as:
Then, change the compute_diagnostic
as:
PYTHON
def compute_diagnostic(filename):
"""Compute an example diagnostic."""
logger.debug("Loading %s", filename)
dataset = xr.open_dataset(filename)
#do your analyses on the data here
return dataset
Caution: If you read data using xarray keep in mind to change accordingly the other functions in the diagnostic which are dealing at the moment with Iris cubes.
Reading data using the netCDF4 package
Yet another option to read the NetCDF file data is to use the [netCDF-4 Python interface][netCDF] to the netCDF C library.
First, import the netCDF4
package at the top of the
script as:
Then, change compute_diagnostic
as:
PYTHON
def compute_diagnostic(filename):
"""Compute an example diagnostic."""
logger.debug("Loading %s", filename)
nc_data = netCDF4.Dataset(filename,'r')
#do your analyses on the data here
return nc_data
Caution: If you read data using netCDF4 keep in mind to change accordingly the other functions in the diagnostic which are dealing at the moment with Iris cubes.
Diagnostic output
Plotting the output
Often, the end product of a diagnostic script is a plot or figure.
The Iris cube returned from the compute_diagnostic
function
(line 93) is passed to the plot_diagnostic
function (line
102). Let’s have a look at the definition of this function in line 52.
This is where we would plug in our plotting routine in the diagnostic
script.
More specifically, the quickplot
function (line 60) can
be replaced with the function of our choice. As can be seen, this
function uses **cfg['quickplot']
as an input argument. If
you look at the diagnostic section in the recipe
recipe_python.yml
, you see quickplot
is a key
there:
This way, we can pass arguments such as the type of plot
pcolormesh
and the colormap cmap:Reds
from the
recipe to the quickplot
function in the diagnostic.
Passing arguments from the recipe to the diagnostic
Change the type of the plot and its colormap and inspect the output figure.
ESMValTool gallery
ESMValTool makes it possible to produce a wide array of plots and figures as seen in the gallery.
Saving the output
In our example, the function save_data
in line 56 is
used to save the Iris cube. The saved files can be found under the
work
directory in a .nc
format. There is also
the function save_figure
in line 62 to save the plots under
the plot
directory in a .png
format (or
preferred format specified in your configuration settings). Again, you
may choose your own method of saving the output.
Recording the provenance
When developing a diagnostic script, it is good practice to record
provenance. To do so, we use the function
get_provenance_record
(line 100). Let us have a look at the
definition of this function in line 21 where we describe the diagnostic
data and plot. Using the dictionary record
, it is possible
to add custom provenance to our diagnostics output. Provenance is stored
in the W3C PROV
XML format and also in an SVG file under the
work
and plot
directory. For more information,
see [recording provenance][provenance].
Congratulations!
You now know the basic diagnostic script structure and some available tools for putting together your own diagnostics. Have a look at existing recipes and diagnostics in the repository for more examples of functions you can use in your diagnostics!
Key Points
- ESMValTool provides helper functions to interface a Python diagnostic script with preprocessor output.
- Existing diagnostics can be used as templates and modified to write new diagnostics.
- Helper functions can be imported from
esmvaltool.diag_scripts.shared
and used in your own diagnostic script.