ngiab-data-preprocess 4.3.1

Graphical Tools for creating Next Gen Water model input data.

NGIAB Data Preprocess

This repository contains tools for preparing data to run a next gen simulation using NGIAB. The tools allow you to select a catchment of interest on an interactive map, choose a date range, and prepare the data with just a few clicks!

Table of Contents

1. What does this tool do?
2. What does it not do?
   • Evaluation
   • Visualisation
3. Requirements
4. Installation and Running
   • Running without install
5. For legacy pip installation
6. Development Installation
7. Usage
8. CLI Documentation
   • Arguments
   • Usage Notes
   • Examples

What does this tool do?

This tool prepares data to run a next gen simulation by creating a run package that can be used with NGIAB.
It uses geometry and model attributes from the v2.2 hydrofabric more information on all data sources here.
The raw forcing data is nwm retrospective v3 forcing data or the AORC 1km gridded data depending on user input

1. Subset (delineate) everything upstream of your point of interest (catchment, gage, flowpath etc). Outputs as a geopackage.
2. Calculates Forcings as a weighted mean of the gridded AORC forcings. Weights are calculated using exact extract and computed with numpy.
3. Creates configuration files needed to run nextgen.
   • realization.json - ngen model configuration
   • troute.yaml - routing configuration.
   • per catchment model configuration
4. Optionally Runs a non-interactive Next gen in a box.

What does it not do?

Evaluation

For automatic evaluation using Teehr, please run NGIAB interactively using the guide.sh script.

Visualisation

For automatic interactive visualisation, please run NGIAB interactively using the guide.sh script

Requirements

• This tool is officially supported on macOS or Ubuntu (tested on 22.04 & 24.04). To use it on Windows, please install WSL.

Installation and Running

It is highly recommended to use Astral UV to install and run this tool. It works similarly to pip and conda, and I would also recommend you use it for other python projects as it is so useful.

# Install UV
curl -LsSf https://astral.sh/uv/install.sh | sh
# It can be installed via pip if that fails
# pip install uv

# Create a virtual environment in the current directory
uv venv

# Install the tool in the virtual environment 
uv pip install ngiab_data_preprocess

# To run the cli
uv run cli --help

# To run the map 
uv run map_app

UV automatically detects any virtual environments in the current directory and will use them when you use uv run.

Running without install

This package supports pipx and uvx which means you can run the tool without installing it. No virtual environment needed, just UV.

# run this from anywhere 
uvx --from ngiab_data_preprocess cli --help
# for the map
uvx --from ngiab_data_preprocess map_app

For legacy pip installation

Click here to expand

# If you're installing this on jupyterhub / 2i2c you HAVE TO DEACTIVATE THE CONDA ENV
(notebook) jovyan@jupyter-user:~$ conda deactivate
jovyan@jupyter-user:~$
# The interactive map won't work on 2i2c

# This tool is likely to not work without a virtual environment
python3 -m venv .venv
source .venv/bin/activate
# installing and running the tool
pip install 'ngiab_data_preprocess'
python -m map_app
# CLI instructions at the bottom of the README

Development Installation

Click to expand installation steps

To install and run the tool, follow these steps:

1. Clone the repository:

   git clone https://github.com/CIROH-UA/NGIAB_data_preprocess
   cd NGIAB_data_preprocess
   

2. Create a virtual environment:

   uv venv
   

3. Install the tool:

   uv pip install -e .
   

4. Run the map app:

   uv run map_app
   

Usage

Running the command uv run map_app will open the app in a new browser tab.

To use the tool:

1. Select the catchment you're interested in on the map.
2. Pick the time period you want to simulate.
3. Click the following buttons in order:
   1. Create subset gpkg
   2. Create Forcing from Zarrs
   3. Create Realization

Once all the steps are finished, you can run NGIAB on the folder shown underneath the subset button.

Note: When using the tool, the default output will be stored in the ~/ngiab_preprocess_output/<your-input-feature>/ folder. There is no overwrite protection on the folders.

CLI Documentation

Arguments

• -h, --help: Show the help message and exit.
• -i INPUT_FEATURE, --input_feature INPUT_FEATURE: ID of feature to subset. Providing a prefix will automatically convert to catid, e.g., cat-5173 or gage-01646500 or wb-1234.
• --vpu VPU_ID : The id of the vpu to subset e.g 01. 10 = 10L + 10U and 03 = 03N + 03S + 03W. --help will display all the options.
• -l, --latlon: Use latitude and longitude instead of catid. Expects comma-separated values via the CLI, e.g., python -m ngiab_data_cli -i 54.33,-69.4 -l -s.
• -g, --gage: Use gage ID instead of catid. Expects a single gage ID via the CLI, e.g., python -m ngiab_data_cli -i 01646500 -g -s.
• -s, --subset: Subset the hydrofabric to the given feature.
• -f, --forcings: Generate forcings for the given feature.
• -r, --realization: Create a realization for the given feature.
• --start_date START_DATE, --start START_DATE: Start date for forcings/realization (format YYYY-MM-DD).
• --end_date END_DATE, --end END_DATE: End date for forcings/realization (format YYYY-MM-DD).
• -o OUTPUT_NAME, --output_name OUTPUT_NAME: Name of the output folder.
• --source : The datasource you want to use, either nwm for retrospective v3 or aorc. Default is nwm
• -D, --debug: Enable debug logging.
• --run: Automatically run Next Gen against the output folder.
• --validate: Run every missing step required to run ngiab.
• -a, --all: Run all operations: subset, forcings, realization, run Next Gen

Usage Notes

• If your input has a prefix of gage-, you do not need to pass -g.
• The -l, -g, -s, -f, -r flags can be combined like normal CLI flags. For example, to subset, generate forcings, and create a realization, you can use -sfr or -s -f -r.
• When using the --all flag, it automatically sets subset, forcings, realization, and run to True.
• Using the --run flag automatically sets the --validate flag.

Examples

0. Prepare everything for a nextgen run at a given gage:

   python -m ngiab_data_cli -i gage-10154200 -sfr --start 2022-01-01 --end 2022-02-28 
   #         add --run or replace -sfr with --all to run nextgen in a box too
   # to name the folder, add -o folder_name
   

1. Subset hydrofabric using catchment ID or VPU:

   python -m ngiab_data_cli -i cat-7080 -s
   python -m ngiab_data_cli --vpu 01 -s
   

2. Generate forcings using a single catchment ID:

   python -m ngiab_data_cli -i cat-5173 -f --start 2022-01-01 --end 2022-02-28
   

3. Create realization using a lat/lon pair and output to a named folder:

   python -m ngiab_data_cli -i 33.22,-87.54 -l -r --start 2022-01-01 --end 2022-02-28 -o custom_output
   

4. Perform all operations using a lat/lon pair:

   python -m ngiab_data_cli -i 33.22,-87.54 -l -s -f -r --start 2022-01-01 --end 2022-02-28
   

5. Subset hydrofabric using gage ID:

   python -m ngiab_data_cli -i 10154200 -g -s
   # or
   python -m ngiab_data_cli -i gage-10154200 -s
   

6. Generate forcings using a single gage ID:

   python -m ngiab_data_cli -i 01646500 -g -f --start 2022-01-01 --end 2022-02-28
   

7. Run all operations, including Next Gen and evaluation/plotting:

   python -m ngiab_data_cli -i cat-5173 -a --start 2022-01-01 --end 2022-02-28