# -*- coding: utf-8 -*-
"""Modules for providing a convenient data structure for solph results.
Information about the possible usage is provided within the examples.
SPDX-FileCopyrightText: Uwe Krien <krien@uni-bremen.de>
SPDX-FileCopyrightText: Simon Hilpert
SPDX-FileCopyrightText: Cord Kaldemeyer
SPDX-FileCopyrightText: Stephan Günther
SPDX-FileCopyrightText: henhuy
SPDX-License-Identifier: MIT
"""
import sys
from itertools import groupby
import pandas as pd
from oemof.network.network import Node
from oemof.solph.helpers import flatten
from pyomo.core.base.var import Var
[docs]def get_tuple(x):
"""
Get oemof tuple within iterable or create it.
Tuples from Pyomo are of type `(n, n, int)`, `(n, n)` and `(n, int)`.
For single nodes `n` a tuple with one object `(n,)` is created.
"""
for i in x:
if isinstance(i, tuple):
return i
elif issubclass(type(i), Node):
return i,
# for standalone variables, x is used as identifying tuple
if isinstance(x, tuple):
return x
[docs]def get_timestep(x):
"""
Get the timestep from oemof tuples.
The timestep from tuples `(n, n, int)`, `(n, n)`, `(n, int)` and (n,)
is fetched as the last element. For time-independent data (scalars)
zero ist returned.
"""
if all(issubclass(type(n), Node) for n in x):
return 0
else:
return x[-1]
[docs]def remove_timestep(x):
"""
Remove the timestep from oemof tuples.
The timestep is removed from tuples of type `(n, n, int)` and `(n, int)`.
"""
if all(issubclass(type(n), Node) for n in x):
return x
else:
return x[:-1]
[docs]def create_dataframe(om):
"""
Create a result dataframe with all optimization data.
Results from Pyomo are written into pandas DataFrame where separate columns
are created for the variable index e.g. for tuples of the flows and
components or the timesteps.
"""
# get all pyomo variables including their block
block_vars = []
for bv in om.component_data_objects(Var):
block_vars.append(bv.parent_component())
block_vars = list(set(block_vars))
# write them into a dict with tuples as keys
var_dict = {(str(bv).split('.')[0], str(bv).split('.')[-1], i): bv[i].value
for bv in block_vars for i in getattr(bv, '_index')}
# use this to create a pandas dataframe
df = pd.DataFrame(list(var_dict.items()), columns=['pyomo_tuple', 'value'])
df['variable_name'] = df['pyomo_tuple'].str[1]
# adapt the dataframe by separating tuple data into columns depending
# on which dimension the variable/parameter has (scalar/sequence).
# columns for the oemof tuple and timestep are created
df['oemof_tuple'] = df['pyomo_tuple'].map(get_tuple)
df['timestep'] = df['oemof_tuple'].map(get_timestep)
df['oemof_tuple'] = df['oemof_tuple'].map(remove_timestep)
# order the data by oemof tuple and timestep
df = df.sort_values(['oemof_tuple', 'timestep'], ascending=[True, True])
# drop empty decision variables
df = df.dropna(subset=['value'])
return df
[docs]def results(om):
"""
Create a result dictionary from the result DataFrame.
Results from Pyomo are written into a dictionary of pandas objects where
a Series holds all scalar values and a dataframe all sequences for nodes
and flows.
The dictionary is keyed by the nodes e.g. `results[idx]['scalars']`
and flows e.g. `results[n, n]['sequences']`.
"""
df = create_dataframe(om)
# create a dict of dataframes keyed by oemof tuples
df_dict = {k if len(k) > 1 else (k[0], None):
v[['timestep', 'variable_name', 'value']]
for k, v in df.groupby('oemof_tuple')}
# create final result dictionary by splitting up the dataframes in the
# dataframe dict into a series for scalar data and dataframe for sequences
result = {}
for k in df_dict:
df_dict[k].set_index('timestep', inplace=True)
df_dict[k] = df_dict[k].pivot(columns='variable_name', values='value')
try:
df_dict[k].index = om.es.timeindex
except ValueError as e:
msg = ("\nFlow: {0}-{1}. This could be caused by NaN-values in"
" your input data.")
raise type(e)(str(e) + msg.format(k[0].label, k[1].label)
).with_traceback(sys.exc_info()[2])
try:
condition = df_dict[k].isnull().any()
scalars = df_dict[k].loc[:, condition].dropna().iloc[0]
sequences = df_dict[k].loc[:, ~condition]
result[k] = {'scalars': scalars, 'sequences': sequences}
except IndexError:
error_message = ('Cannot access index on result data. ' +
'Did the optimization terminate' +
' without errors?')
raise IndexError(error_message)
# add dual variables for bus constraints
if om.dual is not None:
grouped = groupby(sorted(om.Bus.balance.iterkeys()), lambda p: p[0])
for bus, timesteps in grouped:
duals = [om.dual[om.Bus.balance[bus, t]] for _, t in timesteps]
df = pd.DataFrame({'duals': duals}, index=om.es.timeindex)
if (bus, None) not in result.keys():
result[(bus, None)] = {
'sequences': df, 'scalars': pd.Series(dtype=float)}
else:
result[(bus, None)]['sequences']['duals'] = duals
return result
[docs]def convert_keys_to_strings(result, keep_none_type=False):
"""
Convert the dictionary keys to strings.
All (tuple) keys of the result object e.g. results[(pp1, bus1)] are
converted into strings that represent the object labels
e.g. results[('pp1','bus1')].
"""
if keep_none_type:
converted = {
tuple([str(e) if e is not None else None for e in k])
if isinstance(k, tuple)
else str(k) if k is not None else None: v
for k, v in result.items()
}
else:
converted = {
tuple(map(str, k))
if isinstance(k, tuple)
else str(k): v
for k, v in result.items()
}
return converted
def __separate_attrs(system, get_flows=False, exclude_none=True):
"""
Create a dictionary with flow scalars and series.
The dictionary is structured with flows as tuples and nested dictionaries
holding the scalars and series e.g.
{(node1, node2): {'scalars': {'attr1': scalar, 'attr2': 'text'},
'sequences': {'attr1': iterable, 'attr2': iterable}}}
om : A solved oemof.solph.Model.
Returns
-------
dict
"""
def detect_scalars_and_sequences(com):
com_data = {'scalars': {}, 'sequences': {}}
exclusions = ('__', '_', 'registry', 'inputs', 'outputs',
'register',
'Label', 'from_object', 'input', 'output',
'constraint_group')
attrs = [i for i in dir(com)
if not (callable(i) or i.startswith(exclusions))]
for a in attrs:
attr_value = getattr(com, a)
# Iterate trough investment and add scalars and sequences with
# "investment" prefix to component data:
if attr_value.__class__.__name__ == 'Investment':
invest_data = detect_scalars_and_sequences(attr_value)
com_data['scalars'].update(
{
'investment_' + str(k): v
for k, v in invest_data['scalars'].items()
}
)
com_data['sequences'].update(
{
'investment_' + str(k): v
for k, v in invest_data['sequences'].items()
}
)
continue
if isinstance(attr_value, str):
com_data['scalars'][a] = attr_value
continue
# If the label is a tuple it is iterable, therefore it should be
# converted to a string. Otherwise it will be a sequence.
if a == 'label':
attr_value = str(attr_value)
# check if attribute is iterable
# see: https://stackoverflow.com/questions/1952464/
# in-python-how-do-i-determine-if-an-object-is-iterable
try:
_ = (e for e in attr_value)
com_data['sequences'][a] = attr_value
except TypeError:
com_data['scalars'][a] = attr_value
com_data['sequences'] = flatten(com_data['sequences'])
move_undetected_scalars(com_data)
if exclude_none:
remove_nones(com_data)
com_data = {
'scalars': pd.Series(com_data['scalars']),
'sequences': pd.DataFrame(com_data['sequences'])
}
return com_data
def move_undetected_scalars(com):
for ckey, value in list(com['sequences'].items()):
if isinstance(value, str):
com['scalars'][ckey] = value
del com['sequences'][ckey]
continue
try:
_ = (e for e in value)
except TypeError:
com['scalars'][ckey] = value
del com['sequences'][ckey]
else:
try:
if not value.default_changed:
com['scalars'][ckey] = value.default
del com['sequences'][ckey]
except AttributeError:
pass
def remove_nones(com):
for ckey, value in list(com['scalars'].items()):
if value is None:
del com['scalars'][ckey]
for ckey, value in list(com['sequences'].items()):
if (
len(value) == 0 or
value[0] is None
):
del com['sequences'][ckey]
# Check if system is es or om:
if system.__class__.__name__ == 'EnergySystem':
components = system.flows() if get_flows else system.nodes
else:
components = system.flows if get_flows else system.es.nodes
data = {}
for com_key in components:
component = components[com_key] if get_flows else com_key
component_data = detect_scalars_and_sequences(component)
comkey = com_key if get_flows else (com_key, None)
data[comkey] = component_data
return data
[docs]def parameter_as_dict(system, exclude_none=True):
"""
Create a result dictionary containing node parameters.
Results are written into a dictionary of pandas objects where
a Series holds all scalar values and a dataframe all sequences for nodes
and flows.
The dictionary is keyed by flows (n, n) and nodes (n, None), e.g.
`parameter[(n, n)]['sequences']` or `parameter[(n, n)]['scalars']`.
Parameters
----------
system: energy_system.EnergySystem
A populated energy system.
exclude_none: bool
If True, all scalars and sequences containing None values are excluded
Returns
-------
dict: Parameters for all nodes and flows
"""
flow_data = __separate_attrs(system, True, exclude_none)
node_data = __separate_attrs(system, False, exclude_none)
flow_data.update(node_data)
return flow_data