Metadata-Version: 2.1
Name: pdr
Version: 0.7.1
Summary: Planetary Data Reader
Home-page: https://github.com/MillionConcepts/pdr
Author: Chase Million
Author-email: chase@millionconcepts.com
Classifier: Development Status :: 4 - Beta
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: BSD License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.9
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: pds4-tools
Requires-Dist: multidict
Requires-Dist: pandas
Requires-Dist: numpy
Requires-Dist: python-Levenshtein
Requires-Dist: dustgoggles
Requires-Dist: more-itertools
Provides-Extra: browsify
Requires-Dist: matplotlib ; extra == 'browsify'
Provides-Extra: fits
Requires-Dist: astropy ; extra == 'fits'
Provides-Extra: notebooks
Requires-Dist: jupyter ; extra == 'notebooks'
Requires-Dist: matplotlib ; extra == 'notebooks'
Provides-Extra: pvl
Requires-Dist: pvl ; extra == 'pvl'
Provides-Extra: tiff
Requires-Dist: pillow ; extra == 'tiff'

README.md
## The Planetary Data Reader (pdr)

This tool provides a single command---`read(‘/path/to/file’)`---for ingesting
_all_ common planetary data types. It is currently in development. Almost every kind
of "primary observational data" product currently archived in the PDS
(under PDS3 or PDS4) should be covered eventually. [Currently-supported datasets are listed here.](supported_datasets.md) 

If the software fails while attempting to read from datasets that we have listed as supported, please submit an issue with a link to the file and information about the error (if applicable). There might also be datasets that work but are not listed. We would like to hear about those too. If a dataset is not yet supported that you would like us to consider prioritizing, [please fill out this request form](https://docs.google.com/forms/d/1JHyMDzC9LlXY4MOMcHqV5fbseSB096_PsLshAMqMWBw/viewform).

### Installation
_pdr_ is now on `conda` and `pip`. We recommend (and only officially support) installation into a `conda` environment.
You can do this like so: 

```
conda create --name pdrenv
conda activate pdrenv
conda install -c conda-forge pdr
```
The minimum supported version of Python is _3.9_.

Using the conda install will install all dependencies in the environment.yml 
file (both required and optional) for pdr. If you'd prefer to forego the 
optional dependencies, please use minimal_environment.yml in your 
installation. This is not supported through a direct conda install as 
described above and will reqiore additional steps. Optional dependencies 
and the added functionality they support are listed below:

  - `pvl`: allows `Data.load("LABEL", as_pvl=True)` which will load PDS3 labels as `pvl` objects rather than plain text
  - `astropy`: adds support for FITS files
  - `jupyter`: allows usage of the Example Jupyter Notebook (and other jupyter notebooks you create)
  - `pillow`: adds support for TIFF files and browse image rendering
  - `matplotlib`: allows usage of `save_sparklines`, an experimental browse function

### Usage

(You can check out our example Notebook on Binder for a 
quick interactive demo of functionality: 
[![Binder](https://mybinder.org/badge_logo.svg)](https://mybinder.org/v2/gh/millionconcepts/pdr/master))

Just open and python shell and run `import pdr` and then `pdr.read(filename)`, 
where _filename_ is the full path to a data file _or_ a metadata / label file 
(extensions .LBL, .lbl, or .xml). `read()` will look for corresponding data 
or metadata files in the same path, or read metadata directly from the data file 
if it has an attached label.

`read` returns a `pdr.Data` object whose attributes include all of the data
and metadata. Data attributes take their names directly from the product's
label. They can be accessed either as attributes or using
`dict`-style \[\] index notation. For example, PDS3 image objects are often
named "IMAGE", so you could examine a PDS3 image as an array with:
```
>>> data = pdr.read("/path/to/cr0_398560467edr_f0030004ccam02012m1.LBL")
>>> data['IMAGE']
array([[21, 21, 20, ..., 19, 19, 20],
       [21, 21, 21, ..., 19, 20, 20],
       [21, 21, 20, ..., 20, 20, 20],
       ...,
       [25, 25, 25, ..., 26, 26, 26],
       [25, 25, 25, ..., 27, 26, 26],
       [24, 25, 25, ..., 26, 26, 26]], dtype=int16)
```
Parsed metadata are stored in a `pdr.Metadata` object and exposed as the
`metadata` property of a `pdr.Data` object. You can access metadata values 
with `dict`-style \[\] index notation or the convenience method `metaget`. 
For instance:
```
>>> data.metaget('INSTRUMENT_HOST_NAME')
'MARS SCIENCE LABORATORY'
```
Some PDS products (like this one) contain multiple data objects. You can look
at all of the objects associated with a product with `.keys()`:
```
>>> data.keys()
['LABEL',
 'IMAGE_HEADER',
 'ANCILLARY_TABLE',
 'CMD_REPLY_FRAME_SOHB_TABLE',
 'SOH_BEFORE_CHECKSUM_TABLE',
 'TAKE_IMAGE_TIME_TABLE',
 'CMD_REPLY_FRAME_SOHA_TABLE',
 'SOH_AFTER_CHECKSUM_TABLE',
 'MUHEADER_TABLE',
 'MUFOOTER_TABLE',
 'IMAGE_REPLY_TABLE',
 'IMAGE',
 'MODEL_DESC']
 ```

### Output data types
In general:
+ Image data are presented as NumPy `ndarray` objects.
+ Table data are presented as pandas `DataFrame` objects. 
+ Parsed label contents (metadata fields + values) are presented in a
`pdr.Metadata` object (behaves much like a `dict`).
+ Header and label contents are presented as plain text (`str` objects), 
`bytes`, or, for PDS4 labels, `pds4_tools.reader.label_objects.Label` objects.
+ Other data are presented as simple python types (`str`, `tuple`, `dict`).
+ There might be rare exceptions.

### Notes and Caveats
#### Additional processing
Some data, especially calibrated image data, require the application of
additional offsets or scale factors to convert the storage units to meaningful
physical units. The information on how and when to apply such adjustments is
typically stored (as plain text) in the instrument SIS, and the scale factors
themselves are often (but not always) stored in the label. Image data also 
often contain special constants (like missing or invalid data), and these 
constants are often not explicitly specified in the label. 
`pdr` is therefore not guaranteed to correctly apply -- or even know 
anything about -- these constants.

`pdr.Data` objects offer a convenience method that attempts to mask invalid
values and apply any scaling and offset specified in the label. Use it like:
`scaled_image = data.get_scaled('IMAGE')`. However, we do not perform science
validation of these outputs, so **do not trust that they are ready for
analysis** without further processing or validation. Contributions towards 
making this more effective for specific data product types are very much 
welcomed.

If you'd like to visualize the outputs that this creates, the `dump_browse`
method creates separate browse files for all currently-loaded objects 
(as .jpg, .txt., or .csv) in your working directory. Use it like: 
`data.dump_browse()`. This uses the `get_scaled` method for images and will 
also output browse products for tables and labels.

#### .FMT files
Some PDS3 table formats are defined in external reference files (usually 
with a `.FMT` extension). You can often find these in the LABEL or DOCUMENT
subdirectories of data archive volumes. If you place the relevant format
files in the same directory as the data files you are trying to read, `pdr`
will be able to use them to interpret the table data. If you attempt to read 
a table object that requires a format file that is not present, `pdr` will
not be able to open the table object, and will throw a warning that includes 
the format file name in order to help you go find it. Future functionality 
may make this process smoother.

#### Data attribute naming
The observational and metadata attributes (or keys) of `pdr.Data`
objects take their names directly from the metadata files. We believe that
maintaining this strong correlation between the representation of the data
in-language and the representation of the data in-file is important, even when
it causes us to break strict PEP-8 standards for attribute capitalization.
There are three exceptions at present:
1. Some table formats include repeated column names. For usability and
compatibility, we force these to be unique by suffixing 0-indexed increasing
integers. So a table definition with two separate columns named "COLUMN" will 
return a pandas DataFrame with columns named "COLUMN_0" and "COLUMN_1."
2. PDS3 data object names sometimes contain spaces. _pdr_ replaces the spaces
with underscores in order to make them usable as attributes.

#### PDS4 products
`pdr.Data` wraps [`pds4_tools`](https://github.com/Small-Bodies-Node/pds4_tools/) 
to read PDS4 products. All valid PDS4 products should be fully supported. `pdr`
modifies some `pds4_tools` outputs in order to provide interface and behavior
consistency. In general, you should be able to use `pdr` with PDS4 products 
the same way you do with PDS3 products.

Some PDS data products have both PDS3 and PDS4 labels. Data object names, 
metadata, and even data field names and format specifications often differ 
slightly between these labels, so `pdr` may produce slightly different outputs
depending on which label you use to initialize it. This is not a bug. 
However, in general, if a PDS3 label is available, we recommend initializing 
the object from the PDS3 label rather than the PDS4 label.

#### Lazy loading
Because many planetary data objects are very large, `pdr` helps conserve 
your time and memory by loading them lazily. It loads data objects into memory
when they are explicitly referenced, not when `pdr.Data` is initialized. 
For example, referencing`data.IMAGE` will immediately load the IMAGE object if 
it has not already been loaded. Alternatively, you can load objects by using 
the `load` method, like `data.load("IMAGE")`. You can also pass the 'all' 
argument to load all data objects, like `data.load("all")`. 

#### Missing files
If a file referenced by a label is missing, *pdr* will throw warnings and
populate the associated attribute from the portion of the label that mentions
that file. You are most likely to encounter this for DESCRIPTION files in
document formats (like .TXT). These warnings do not prevent you from using
objects loaded from files that are actually present in your filesystem.

#### Big files (like HiRISE)
`pdr` currently performs no special memory management, so use caution 
when attempting to read very large files. We intend to implement memory
management in the future.

### tests

Our testing methodology for *pdr* currently focuses on end-to-end integration
testing to ensure consistency, coverage of supported datasets, and 
(to the extent we can verify it) correctness of output.

the test suite for *pdr* lives in a different repository: 
https://github.com/MillionConcepts/pdr-tests. Its core is an application called
**ix**. It should be considered a fairly complete alpha; we are actively using 
it both as a regression test suite and an active development tool.

---
This work is supported by NASA grant No. 80NSSC21K0885.




