%global _empty_manifest_terminate_build 0
Name:		python-pyCHNOSZ
Version:	0.8.12
Release:	1
Summary:	Python wrapper for the R package CHNOSZ.
License:	MIT License
URL:		https://pypi.org/project/pyCHNOSZ/
Source0:	https://mirrors.nju.edu.cn/pypi/web/packages/9f/6c/adb44cf05fb9c3069c4779bcf8386d2684c088d532b6369439274d39d091/pyCHNOSZ-0.8.12.tar.gz
BuildArch:	noarch

Requires:	python3-rpy2
Requires:	python3-pandas
Requires:	python3-ipython
Requires:	python3-plotly
Requires:	python3-simplegeneric
Requires:	python3-chemparse

%description
# pyCHNOSZ

Author: Dr. Grayson Boyer, GEOPIG Lab, Arizona State University

[CHNOSZ](https://www.chnosz.net/) is a package written by [Dr. Jeff Dick](https://chnosz.net/jeff/) for performing thermodynamic calculations in aqueous geochemistry and biogeochemistry. pyCHNOSZ is a wrapper for CHNOSZ that allows these calculations to be carried out in Python 3 Jupyter notebooks.

## Features

The following CHNOSZ functions are supported in pyCHNOSZ:

- [info](https://chnosz.net/manual/info.html) - Search for chemical species by name or formula and retrieve their thermodynamic parameters.
- [add_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Add or overwrite species in the OBIGT thermodynamic database by supplying a comma separated value (csv) file with custom data.
- [mod_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Modify species in the OBIGT thermodynamic database. Optionally, supply a Pandas dataframe containing custom data.
- [reset](https://chnosz.net/manual/thermo.html) - reset data to default values.
- [subcrt](https://chnosz.net/manual/subcrt.html) - Calculate standard state partial molal thermodynamic properties of reactions at elevated temperatures and pressures.
- [basis](https://chnosz.net/manual/basis.html) - Define basis species of a chemical system.
- [species](https://chnosz.net/manual/species.html) - Define the species of interest in a system.
- [equilibrate](https://chnosz.net/manual/equilibrate.html) - Calculate equilibrium chemical activities of species from the affinities of formation of the species at unit activity.
- [affinity](https://chnosz.net/manual/affinity.html) - Calculate the chemical affinities of formation reactions of species.
- [diagram](https://chnosz.net/manual/diagram.html) - Plot equilibrium chemical activity (1-D speciation) or equal-activity (2-D predominance) diagrams as a function of chemical activities of basis species, temperature and/or pressure.


## Requirements

This package must be installed into an environment with an [R](https://www.r-project.org/) installation. See [these instructions](https://docs.anaconda.com/anaconda/user-guide/tasks/using-r-language/) for installing R with Anaconda. Additionally, the CHNOSZ package for R must be installed (see instructions below).

## Installation

### Installing CHNOSZ

Open an R session. Install the CHNOSZ package with:

```r
install.packages("CHNOSZ")
```

Once CHNOSZ is installed you may quit the R session.

### Installing pyCHNOSZ

Install pyCHNOSZ using pip:

```
$ pip install pyCHNOSZ
```

## Usage

Import pyCHNOSZ in your python code with:
```python
import pyCHNOSZ
```

In the following examples, pyCHNOSZ functions are imported with:
```python
from pyCHNOSZ import info, add_OBIGT, mod_OBIGT, reset, subcrt
```

### Search for chemical species

The `info()` function can be used to look up chemical species by name or formula. If names or formulas are provided, database index integers are returned. A list of integers will look up chemical species by index and return a table of thermodynamic properties. See the `info()` function's [original documentation](https://chnosz.net/manual/info.html) to learn more about what this function can do. A few examples are shown below.

Look up the database index value of Fe+2:

```python
info("Fe+2")
```

Look up multiple chemical species:

```python
info(["HCO3-", "CH4"])
```

Define chemical states:

```python
info(["HCO3-", "CH4"], state=["aq", "gas"])
```

Search species by index values to look up their thermodynamic parameters.

```python
info([13, 872])
```

Nest `info` functions to look up thermodynamic properties directly from names or formulas:

```python
info(info("Fe+2"))
```

Look up and add a protein to the database:

```python
info("LYSC_CHICK")
```

### Add or replace thermodynamic data in the database

See the original R documentation for `add_OBIGT()` and `reset()` for basic useage. A few examples are given below.

Load the SUPCRT92 database.

```python
a = add_OBIGT("SUPCRT92")
```

The variable `a` is assigned a list of integers corresponding to the indices of chemical species that are added or replaced in the OBIGT thermodynamic database used by pyCHNOSZ.

It is possible to add a custom table of thermodynamic parameters.

```python
a = add_OBIGT("my_custom_entries.csv")
info(a) # confirm new entries have been added
```

The entries of `my_custom_entries.csv` would then be available for thermodynamic calculations with `subcrt()`, for example.

Reset thermodynamic database to its original configuration.

```python
reset()
```

Modify values in the thermodynamic database with `mod_OBIGT()`:

```python
mod_OBIGT("HCO3-", G = -140283.7, Cp = -9)
info(info("HCO3-"))
```

### Calculate thermodynamic properties of reactions

See the [original documentation](https://chnosz.net/manual/subcrt.html) for `subcrt()`. Useage in pyCHNOSZ is the same, except python lists are used in place of R's vectors. The function produces a dictionary of results stored in pandas dataframes. An example is shown below for the reaction H<sub>2 (aq)</sub> + 0.5 O<sub>2 (gas)</sub> = H<sub>2</sub>O<sub>(liq)</sub> at 30 and 50 degrees C and 100 bars pressure:

```python
subcrt(species=["H2", "O2", "H2O"], coeff=[-1.0, -0.5, 1.0],
       state=["aq", "gas", "liq"], T=[30, 50], P=100)
```

Output is a python dictionary of dataframes:
```
subcrt: 3 species at 2 values of T (ºC) and P (bar) (wet) [energy units: cal]

{'reaction':       coeff    name formula state  ispecies
 62     -1.0      H2      H2    aq      62.0
 2612   -0.5  oxygen      O2   gas    2612.0
 1       1.0   water     H2O   liq       1.0,
 'out':       T    P       rho       logK             G             H         S  \
 1  30.0  100  1.000017  43.855086 -60832.380282 -67420.887872 -21.89070   
 2  50.0  100  0.992305  40.834419 -60379.262657 -67882.530994 -23.36663   
 
           V         Cp  
 1 -7.494052 -24.126268  
 2 -8.259704 -20.941879  }
```

### More examples:

For more examples, like plotting activity and predominance diagrams, check out the [pyCHNOSZ demo notebook](https://nbviewer.org/github/worm-portal/pyCHNOSZ/blob/master/test/pyCHNOSZ-demo.ipynb).




%package -n python3-pyCHNOSZ
Summary:	Python wrapper for the R package CHNOSZ.
Provides:	python-pyCHNOSZ
BuildRequires:	python3-devel
BuildRequires:	python3-setuptools
BuildRequires:	python3-pip
%description -n python3-pyCHNOSZ
# pyCHNOSZ

Author: Dr. Grayson Boyer, GEOPIG Lab, Arizona State University

[CHNOSZ](https://www.chnosz.net/) is a package written by [Dr. Jeff Dick](https://chnosz.net/jeff/) for performing thermodynamic calculations in aqueous geochemistry and biogeochemistry. pyCHNOSZ is a wrapper for CHNOSZ that allows these calculations to be carried out in Python 3 Jupyter notebooks.

## Features

The following CHNOSZ functions are supported in pyCHNOSZ:

- [info](https://chnosz.net/manual/info.html) - Search for chemical species by name or formula and retrieve their thermodynamic parameters.
- [add_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Add or overwrite species in the OBIGT thermodynamic database by supplying a comma separated value (csv) file with custom data.
- [mod_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Modify species in the OBIGT thermodynamic database. Optionally, supply a Pandas dataframe containing custom data.
- [reset](https://chnosz.net/manual/thermo.html) - reset data to default values.
- [subcrt](https://chnosz.net/manual/subcrt.html) - Calculate standard state partial molal thermodynamic properties of reactions at elevated temperatures and pressures.
- [basis](https://chnosz.net/manual/basis.html) - Define basis species of a chemical system.
- [species](https://chnosz.net/manual/species.html) - Define the species of interest in a system.
- [equilibrate](https://chnosz.net/manual/equilibrate.html) - Calculate equilibrium chemical activities of species from the affinities of formation of the species at unit activity.
- [affinity](https://chnosz.net/manual/affinity.html) - Calculate the chemical affinities of formation reactions of species.
- [diagram](https://chnosz.net/manual/diagram.html) - Plot equilibrium chemical activity (1-D speciation) or equal-activity (2-D predominance) diagrams as a function of chemical activities of basis species, temperature and/or pressure.


## Requirements

This package must be installed into an environment with an [R](https://www.r-project.org/) installation. See [these instructions](https://docs.anaconda.com/anaconda/user-guide/tasks/using-r-language/) for installing R with Anaconda. Additionally, the CHNOSZ package for R must be installed (see instructions below).

## Installation

### Installing CHNOSZ

Open an R session. Install the CHNOSZ package with:

```r
install.packages("CHNOSZ")
```

Once CHNOSZ is installed you may quit the R session.

### Installing pyCHNOSZ

Install pyCHNOSZ using pip:

```
$ pip install pyCHNOSZ
```

## Usage

Import pyCHNOSZ in your python code with:
```python
import pyCHNOSZ
```

In the following examples, pyCHNOSZ functions are imported with:
```python
from pyCHNOSZ import info, add_OBIGT, mod_OBIGT, reset, subcrt
```

### Search for chemical species

The `info()` function can be used to look up chemical species by name or formula. If names or formulas are provided, database index integers are returned. A list of integers will look up chemical species by index and return a table of thermodynamic properties. See the `info()` function's [original documentation](https://chnosz.net/manual/info.html) to learn more about what this function can do. A few examples are shown below.

Look up the database index value of Fe+2:

```python
info("Fe+2")
```

Look up multiple chemical species:

```python
info(["HCO3-", "CH4"])
```

Define chemical states:

```python
info(["HCO3-", "CH4"], state=["aq", "gas"])
```

Search species by index values to look up their thermodynamic parameters.

```python
info([13, 872])
```

Nest `info` functions to look up thermodynamic properties directly from names or formulas:

```python
info(info("Fe+2"))
```

Look up and add a protein to the database:

```python
info("LYSC_CHICK")
```

### Add or replace thermodynamic data in the database

See the original R documentation for `add_OBIGT()` and `reset()` for basic useage. A few examples are given below.

Load the SUPCRT92 database.

```python
a = add_OBIGT("SUPCRT92")
```

The variable `a` is assigned a list of integers corresponding to the indices of chemical species that are added or replaced in the OBIGT thermodynamic database used by pyCHNOSZ.

It is possible to add a custom table of thermodynamic parameters.

```python
a = add_OBIGT("my_custom_entries.csv")
info(a) # confirm new entries have been added
```

The entries of `my_custom_entries.csv` would then be available for thermodynamic calculations with `subcrt()`, for example.

Reset thermodynamic database to its original configuration.

```python
reset()
```

Modify values in the thermodynamic database with `mod_OBIGT()`:

```python
mod_OBIGT("HCO3-", G = -140283.7, Cp = -9)
info(info("HCO3-"))
```

### Calculate thermodynamic properties of reactions

See the [original documentation](https://chnosz.net/manual/subcrt.html) for `subcrt()`. Useage in pyCHNOSZ is the same, except python lists are used in place of R's vectors. The function produces a dictionary of results stored in pandas dataframes. An example is shown below for the reaction H<sub>2 (aq)</sub> + 0.5 O<sub>2 (gas)</sub> = H<sub>2</sub>O<sub>(liq)</sub> at 30 and 50 degrees C and 100 bars pressure:

```python
subcrt(species=["H2", "O2", "H2O"], coeff=[-1.0, -0.5, 1.0],
       state=["aq", "gas", "liq"], T=[30, 50], P=100)
```

Output is a python dictionary of dataframes:
```
subcrt: 3 species at 2 values of T (ºC) and P (bar) (wet) [energy units: cal]

{'reaction':       coeff    name formula state  ispecies
 62     -1.0      H2      H2    aq      62.0
 2612   -0.5  oxygen      O2   gas    2612.0
 1       1.0   water     H2O   liq       1.0,
 'out':       T    P       rho       logK             G             H         S  \
 1  30.0  100  1.000017  43.855086 -60832.380282 -67420.887872 -21.89070   
 2  50.0  100  0.992305  40.834419 -60379.262657 -67882.530994 -23.36663   
 
           V         Cp  
 1 -7.494052 -24.126268  
 2 -8.259704 -20.941879  }
```

### More examples:

For more examples, like plotting activity and predominance diagrams, check out the [pyCHNOSZ demo notebook](https://nbviewer.org/github/worm-portal/pyCHNOSZ/blob/master/test/pyCHNOSZ-demo.ipynb).




%package help
Summary:	Development documents and examples for pyCHNOSZ
Provides:	python3-pyCHNOSZ-doc
%description help
# pyCHNOSZ

Author: Dr. Grayson Boyer, GEOPIG Lab, Arizona State University

[CHNOSZ](https://www.chnosz.net/) is a package written by [Dr. Jeff Dick](https://chnosz.net/jeff/) for performing thermodynamic calculations in aqueous geochemistry and biogeochemistry. pyCHNOSZ is a wrapper for CHNOSZ that allows these calculations to be carried out in Python 3 Jupyter notebooks.

## Features

The following CHNOSZ functions are supported in pyCHNOSZ:

- [info](https://chnosz.net/manual/info.html) - Search for chemical species by name or formula and retrieve their thermodynamic parameters.
- [add_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Add or overwrite species in the OBIGT thermodynamic database by supplying a comma separated value (csv) file with custom data.
- [mod_OBIGT](https://chnosz.net/manual/add.OBIGT.html) - Modify species in the OBIGT thermodynamic database. Optionally, supply a Pandas dataframe containing custom data.
- [reset](https://chnosz.net/manual/thermo.html) - reset data to default values.
- [subcrt](https://chnosz.net/manual/subcrt.html) - Calculate standard state partial molal thermodynamic properties of reactions at elevated temperatures and pressures.
- [basis](https://chnosz.net/manual/basis.html) - Define basis species of a chemical system.
- [species](https://chnosz.net/manual/species.html) - Define the species of interest in a system.
- [equilibrate](https://chnosz.net/manual/equilibrate.html) - Calculate equilibrium chemical activities of species from the affinities of formation of the species at unit activity.
- [affinity](https://chnosz.net/manual/affinity.html) - Calculate the chemical affinities of formation reactions of species.
- [diagram](https://chnosz.net/manual/diagram.html) - Plot equilibrium chemical activity (1-D speciation) or equal-activity (2-D predominance) diagrams as a function of chemical activities of basis species, temperature and/or pressure.


## Requirements

This package must be installed into an environment with an [R](https://www.r-project.org/) installation. See [these instructions](https://docs.anaconda.com/anaconda/user-guide/tasks/using-r-language/) for installing R with Anaconda. Additionally, the CHNOSZ package for R must be installed (see instructions below).

## Installation

### Installing CHNOSZ

Open an R session. Install the CHNOSZ package with:

```r
install.packages("CHNOSZ")
```

Once CHNOSZ is installed you may quit the R session.

### Installing pyCHNOSZ

Install pyCHNOSZ using pip:

```
$ pip install pyCHNOSZ
```

## Usage

Import pyCHNOSZ in your python code with:
```python
import pyCHNOSZ
```

In the following examples, pyCHNOSZ functions are imported with:
```python
from pyCHNOSZ import info, add_OBIGT, mod_OBIGT, reset, subcrt
```

### Search for chemical species

The `info()` function can be used to look up chemical species by name or formula. If names or formulas are provided, database index integers are returned. A list of integers will look up chemical species by index and return a table of thermodynamic properties. See the `info()` function's [original documentation](https://chnosz.net/manual/info.html) to learn more about what this function can do. A few examples are shown below.

Look up the database index value of Fe+2:

```python
info("Fe+2")
```

Look up multiple chemical species:

```python
info(["HCO3-", "CH4"])
```

Define chemical states:

```python
info(["HCO3-", "CH4"], state=["aq", "gas"])
```

Search species by index values to look up their thermodynamic parameters.

```python
info([13, 872])
```

Nest `info` functions to look up thermodynamic properties directly from names or formulas:

```python
info(info("Fe+2"))
```

Look up and add a protein to the database:

```python
info("LYSC_CHICK")
```

### Add or replace thermodynamic data in the database

See the original R documentation for `add_OBIGT()` and `reset()` for basic useage. A few examples are given below.

Load the SUPCRT92 database.

```python
a = add_OBIGT("SUPCRT92")
```

The variable `a` is assigned a list of integers corresponding to the indices of chemical species that are added or replaced in the OBIGT thermodynamic database used by pyCHNOSZ.

It is possible to add a custom table of thermodynamic parameters.

```python
a = add_OBIGT("my_custom_entries.csv")
info(a) # confirm new entries have been added
```

The entries of `my_custom_entries.csv` would then be available for thermodynamic calculations with `subcrt()`, for example.

Reset thermodynamic database to its original configuration.

```python
reset()
```

Modify values in the thermodynamic database with `mod_OBIGT()`:

```python
mod_OBIGT("HCO3-", G = -140283.7, Cp = -9)
info(info("HCO3-"))
```

### Calculate thermodynamic properties of reactions

See the [original documentation](https://chnosz.net/manual/subcrt.html) for `subcrt()`. Useage in pyCHNOSZ is the same, except python lists are used in place of R's vectors. The function produces a dictionary of results stored in pandas dataframes. An example is shown below for the reaction H<sub>2 (aq)</sub> + 0.5 O<sub>2 (gas)</sub> = H<sub>2</sub>O<sub>(liq)</sub> at 30 and 50 degrees C and 100 bars pressure:

```python
subcrt(species=["H2", "O2", "H2O"], coeff=[-1.0, -0.5, 1.0],
       state=["aq", "gas", "liq"], T=[30, 50], P=100)
```

Output is a python dictionary of dataframes:
```
subcrt: 3 species at 2 values of T (ºC) and P (bar) (wet) [energy units: cal]

{'reaction':       coeff    name formula state  ispecies
 62     -1.0      H2      H2    aq      62.0
 2612   -0.5  oxygen      O2   gas    2612.0
 1       1.0   water     H2O   liq       1.0,
 'out':       T    P       rho       logK             G             H         S  \
 1  30.0  100  1.000017  43.855086 -60832.380282 -67420.887872 -21.89070   
 2  50.0  100  0.992305  40.834419 -60379.262657 -67882.530994 -23.36663   
 
           V         Cp  
 1 -7.494052 -24.126268  
 2 -8.259704 -20.941879  }
```

### More examples:

For more examples, like plotting activity and predominance diagrams, check out the [pyCHNOSZ demo notebook](https://nbviewer.org/github/worm-portal/pyCHNOSZ/blob/master/test/pyCHNOSZ-demo.ipynb).




%prep
%autosetup -n pyCHNOSZ-0.8.12

%build
%py3_build

%install
%py3_install
install -d -m755 %{buildroot}/%{_pkgdocdir}
if [ -d doc ]; then cp -arf doc %{buildroot}/%{_pkgdocdir}; fi
if [ -d docs ]; then cp -arf docs %{buildroot}/%{_pkgdocdir}; fi
if [ -d example ]; then cp -arf example %{buildroot}/%{_pkgdocdir}; fi
if [ -d examples ]; then cp -arf examples %{buildroot}/%{_pkgdocdir}; fi
pushd %{buildroot}
if [ -d usr/lib ]; then
	find usr/lib -type f -printf "/%h/%f\n" >> filelist.lst
fi
if [ -d usr/lib64 ]; then
	find usr/lib64 -type f -printf "/%h/%f\n" >> filelist.lst
fi
if [ -d usr/bin ]; then
	find usr/bin -type f -printf "/%h/%f\n" >> filelist.lst
fi
if [ -d usr/sbin ]; then
	find usr/sbin -type f -printf "/%h/%f\n" >> filelist.lst
fi
touch doclist.lst
if [ -d usr/share/man ]; then
	find usr/share/man -type f -printf "/%h/%f.gz\n" >> doclist.lst
fi
popd
mv %{buildroot}/filelist.lst .
mv %{buildroot}/doclist.lst .

%files -n python3-pyCHNOSZ -f filelist.lst
%dir %{python3_sitelib}/*

%files help -f doclist.lst
%{_docdir}/*

%changelog
* Wed May 31 2023 Python_Bot <Python_Bot@openeuler.org> - 0.8.12-1
- Package Spec generated