# Copyright 2009-2019 TerraPower, LLC
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Welcome to the Advanced Reactor Modeling Interface (ARMI).
This module initializes the ARMI platform. The bootstrap process is broken into several phases:
* Import fundamental dependencies in Python library and some third-party libs
* Investigate environment: Check Python version, check code version, check MPI situation,
check for TTY/GUI/interactivity,
* Set up temp dirs
* Set up printout table formats (in preparation of logging info)
* Initialize all possible nuclide objects in the nuclide directory
* Discover and register available built-in :py:mod:`plugins <armi.plugins>`
(custom ones registered after input available)
* Discover and define all potential configuration settings from available plugins
* Read input files
* Update :py:mod:`nuclide directory <armi.nucDirectory>` with depletion info based on config
* Discover and define all state :py:mod:`Parameters <armi.reactor.parameters>` on data model
(possibly dependent on config)
* Discover :py:mod:`Entry points <armi.cli>` from plugins
* Choose entry point based on user command
If using the ``run`` entry point, additional work is done:
* Build :py:mod:`reactor model <armi.reactor>` based on input
* Build :py:mod:`operator object <armi.operators>` with specific calculation loop
* Build ordered interface stack based on configuration settings
* Begin looping over interface stack, operating upon data model according to operator design
* Loop until complete
* Wrap up
* Quit
"""
import atexit
import datetime
import importlib
import os
import signal
import subprocess
import sys
import traceback
from typing import Optional, List, Type
import warnings
# The _bootstrap module performs operations that may need to occur before it is
# necessarily safe to import the rest of the ARMI system. Things like:
# - configure the MPI environment
# - detect the nature of interaction with the user (terminal UI, GUI, unsupervized, etc)
# - Initialize the nuclide database
import armi._bootstrap
from armi import context
from armi.context import (
ROOT,
RES,
DOC,
USER,
START_TIME,
CURRENT_MODE,
MPI_COMM,
MPI_RANK,
MPI_NODENAME,
MPI_NODENAMES,
MPI_DISTRIBUTABLE,
MPI_SIZE,
APP_DATA,
)
from armi.context import Mode
from armi import cli
from armi.meta import __version__
from armi import apps
from armi import pluginManager
from armi import plugins
from armi import runLog
from armi.reactor import flags
from armi.reactor import parameters
from armi.nucDirectory import nuclideBases
import __main__ as main
# ARMI does not configure its own application by default. This is mostly to catch issues
# involving calling code that requires the framework to be configured before that has
# explicitly taken place. An application should call `configure()` with its App class in
# order for ARMI to work properly
_app: Optional[apps.App] = None
_ARMI_CONFIGURE_CONTEXT: Optional[str] = None
# Advanced flag used in documentation builds to avoid isConfigured guards.
_ignoreConfigures = False
[docs]def isStableReleaseVersion(version=None):
"""Determine if the version should be considered a stable release"""
version = version or __version__
return "-" not in version
[docs]def init(choice=None, fName=None, cs=None):
"""
Scan a directory for armi inputs and load one to interact with.
Parameters
----------
choice : int, optional
Automatically run with this item out of the menu
that would be produced of existing xml files.
fName : str, optional
An actual case name to load. e.g. ntTwr1.xml
cs : object, optional
If supplied, supercede the other case input methods and use the object directly
Examples
--------
>>> o = armi.init()
"""
from armi import cases
from armi import settings
if cs is None:
if fName is None:
fName = settings.promptForSettingsFile(choice)
cs = settings.Settings(fName)
# clear out any old masterCs objects
settings.setMasterCs(cs)
armiCase = cases.Case(cs=cs)
armiCase.checkInputs()
try:
return armiCase.initializeOperator()
except: # Catch any and all errors. Naked exception on purpose.
# Concatenate errors to the primary log file.
runLog.close()
raise
[docs]def getDefaultPlugins() -> List[Type[plugins.ArmiPlugin]]:
"""
Return a list containing the default set of ARMI Framework plugins.
This is useful for an application to fold all of the ARMI Framework's capabilities
into its own set of plugins.
"""
from armi import cli
from armi import bookkeeping
from armi.physics import fuelCycle
from armi.physics import neutronics
from armi.physics import safety
from armi import reactor
defaultPlugins = [
cli.EntryPointsPlugin,
bookkeeping.BookkeepingPlugin,
fuelCycle.FuelHandlerPlugin,
neutronics.NeutronicsPlugin,
safety.SafetyPlugin,
reactor.ReactorPlugin,
]
return defaultPlugins
[docs]def getDefaultPluginManager() -> pluginManager.ArmiPluginManager:
"""
Return a plugin manager containing the default set of ARMI Framework plugins.
This is useful when using standalone facilities of ARMI without a specific
application.
"""
pm = plugins.getNewPluginManager()
for plugin in getDefaultPlugins():
pm.register(plugin)
return pm
[docs]def getPluginManager() -> Optional[pluginManager.ArmiPluginManager]:
"""
Return the plugin manager, if there is one.
"""
global _app
if _app is None:
return None
return _app.pluginManager
[docs]def getPluginManagerOrFail() -> pluginManager.ArmiPluginManager:
"""
Return the plugin manager. Raise an error if there is none.
"""
global _app
assert _app is not None, (
"The ARMI plugin manager was requested, no App has been configured. Ensure "
"that `armi.configure()` has been called before attempting to interact with "
"the plugin manager."
)
return _app.pluginManager
[docs]def getApp() -> Optional[apps.App]:
global _app
return _app
def _cleanupOnCancel(signum, _frame):
"""Helper function to clean up upon cancellation."""
print(
"Caught Cancel signal ({}); cleaning temporary files and exiting..."
"".format(signum),
file=sys.stderr,
)
context.cleanTempDirs()
sys.stdout.flush()
sys.stderr.flush()
sys.exit(1) # since we're handling the signal we have to cancel
def _liveInterpreter():
"""
Return whether we are running within a live/interactive python interpreter.
"""
return not hasattr(main, "__file__")
[docs]def applyAsyncioWindowsWorkaround() -> None:
"""
Apply Asyncio workaround for Windows and Python 3.8.
This prevents a NotImplementedError on Windows with Python 3.8
his error showed up during jupyter notebook built-tests and documentation.
See https://bugs.python.org/issue37373
"""
import asyncio # pylint: disable=import-outside-toplevel; packed with workaround for easy removal
if (
sys.version_info[0] == 3
and sys.version_info[1] >= 8
and sys.platform.startswith("win")
):
asyncio.set_event_loop_policy(asyncio.WindowsSelectorEventLoopPolicy())
applyAsyncioWindowsWorkaround()
# The ``atexit`` handler is like putting it in a finally after everything.
atexit.register(context.cleanTempDirs)
# register cleanups upon HPC cancellations. Linux clusters will send a different signal.
# SIGBREAK doesn't exist on non-windows
# This actually doesn't work in mpi runs because MSMPI's mpiexec does not pass signals.
if os.name == "nt":
signal.signal(signal.SIGBREAK, _cleanupOnCancel) # pylint: disable=no-member
signal.signal(signal.SIGINT, _cleanupOnCancel)