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#!/usr/bin/env python3
# ============LICENSE_START=======================================================
# Copyright (C) 2020 Nordix Foundation.
# ================================================================================
# Modification Copyright 2020 Huawei Technologies Co., Ltd
# ================================================================================
# 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.
#
# SPDX-License-Identifier: Apache-2.0
# ============LICENSE_END=========================================================
__author__ = "Eliezio Oliveira <eliezio.oliveira@est.tech>"
__copyright__ = "Copyright (C) 2020 Nordix Foundation, and Huawei"
__license__ = "Apache 2.0"
import time
from concurrent.futures import ThreadPoolExecutor
from threading import Timer
import sysrepo as sr
YANG_MODULE_NAME = 'pnf-swm'
#
# ----- BEGIN Finite State Machine definitions -----
#
# Actions
ACT_PRE_CHECK = 'PRE_CHECK'
ACT_DOWNLOAD_NE_SW = 'DOWNLOAD_NE_SW'
ACT_ACTIVATE_NE_SW = 'ACTIVATE_NE_SW'
ACT_CANCEL = 'CANCEL'
# States
ST_CREATED = 'CREATED'
ST_INITIALIZED = 'INITIALIZED'
ST_DOWNLOAD_IN_PROGRESS = 'DOWNLOAD_IN_PROGRESS'
ST_DOWNLOAD_COMPLETED = 'DOWNLOAD_COMPLETED'
ST_ACTIVATION_IN_PROGRESS = 'ACTIVATION_IN_PROGRESS'
ST_ACTIVATION_COMPLETED = 'ACTIVATION_COMPLETED'
# Timeout used for timed transitions
TO_DOWNLOAD = 7
TO_ACTIVATION = 7
def timestamper(sess, key_id):
xpath = xpath_of(key_id, 'state-change-time')
now = time.strftime("%Y-%m-%dT%H:%M:%SZ", time.gmtime())
state = sr.Val(now, sr.SR_STRING_T)
sess.set_item(xpath, state)
def xpath_of(key_id, leaf_id):
selector = "[neIdentifier='{0}']".format(key_id) if key_id else ''
return "/%s:software-management/pnf-software-package%s/%s" % (YANG_MODULE_NAME, selector, leaf_id)
"""
The finite state machine (FSM) is represented as a dictionary where the current state is the key, and its value is
an object (also represented as a dictionary) with the following optional attributes:
- on_enter: a function called when FSM enters this state;
- transitions: a dictionary mapping every acceptable action to the target state;
- timed_transition: a pair for a timed transition that will automatically occur after a given interval.
"""
STATE_MACHINE = {
ST_CREATED: {
'transitions': {ACT_PRE_CHECK: ST_INITIALIZED}
},
ST_INITIALIZED: {
'on_enter': timestamper,
'transitions': {ACT_DOWNLOAD_NE_SW: ST_DOWNLOAD_IN_PROGRESS}
},
ST_DOWNLOAD_IN_PROGRESS: {
'on_enter': timestamper,
'timed_transition': (TO_DOWNLOAD, ST_DOWNLOAD_COMPLETED),
'transitions': {ACT_CANCEL: ST_INITIALIZED}
},
ST_DOWNLOAD_COMPLETED: {
'on_enter': timestamper,
'transitions': {ACT_ACTIVATE_NE_SW: ST_ACTIVATION_IN_PROGRESS}
},
ST_ACTIVATION_IN_PROGRESS: {
'on_enter': timestamper,
'timed_transition': (TO_ACTIVATION, ST_ACTIVATION_COMPLETED),
'transitions': {ACT_CANCEL: ST_DOWNLOAD_COMPLETED}
},
ST_ACTIVATION_COMPLETED: {
'on_enter': timestamper,
'transitions': {ACT_ACTIVATE_NE_SW: ST_ACTIVATION_IN_PROGRESS}
}
}
#
# ----- END Finite State Machine definitions -----
#
def main():
try:
conn = sr.Connection(YANG_MODULE_NAME)
sess = sr.Session(conn)
subscribe = sr.Subscribe(sess)
subscribe.module_change_subscribe(YANG_MODULE_NAME, module_change_cb, conn)
try:
print_current_config(sess, YANG_MODULE_NAME)
except Exception as e:
print(e)
sr.global_loop()
print("Application exit requested, exiting.")
except Exception as e:
print(e)
# Function to be called for subscribed client of given session whenever configuration changes.
def module_change_cb(sess, module_name, event, private_ctx):
try:
conn = private_ctx
change_path = xpath_of(None, 'action')
it = sess.get_changes_iter(change_path)
while True:
change = sess.get_change_next(it)
if change is None:
break
handle_change(conn, change.oper(), change.old_val(), change.new_val())
except Exception as e:
print(e)
return sr.SR_ERR_OK
# Function to print current configuration state.
# It does so by loading all the items of a session and printing them out.
def print_current_config(session, module_name):
select_xpath = "/" + module_name + ":*//*"
values = session.get_items(select_xpath)
if values is not None:
print("========== BEGIN CONFIG ==========")
for i in range(values.val_cnt()):
print(values.val(i).to_string(), end='')
print("=========== END CONFIG ===========")
def handle_change(conn, op, old_val, new_val):
"""
Handle individual changes on the model.
"""
if op == sr.SR_OP_CREATED:
print("CREATED: %s" % new_val.to_string())
xpath = new_val.xpath()
last_node = xpath_ctx.last_node(xpath)
# Warning: 'key_value' modifies 'xpath'!
key_id = xpath_ctx.key_value(xpath, 'pnf-software-package', 'neIdentifier')
if key_id and last_node == 'action':
executor.submit(execute_action, conn, key_id, new_val.data().get_enum())
elif op == sr.SR_OP_DELETED:
print("DELETED: %s" % old_val.to_string())
elif op == sr.SR_OP_MODIFIED:
print("MODIFIED: %s to %s" % (old_val.to_string(), new_val.to_string()))
elif op == sr.SR_OP_MOVED:
print("MOVED: %s after %s" % (new_val.xpath(), old_val.xpath()))
def execute_action(conn, key_id, action):
sess = sr.Session(conn)
try:
cur_state = sess.get_item(xpath_of(key_id, 'current-status')).data().get_enum()
next_state_str = STATE_MACHINE[cur_state]['transitions'].get(action, None)
if next_state_str:
handle_set_state(conn, key_id, next_state_str)
sess.delete_item(xpath_of(key_id, 'action'))
sess.commit()
finally:
sess.session_stop()
def handle_set_state(conn, key_id, state_str):
sess = sr.Session(conn)
try:
state = sr.Val(state_str, sr.SR_ENUM_T)
sess.set_item(xpath_of(key_id, 'current-status'), state)
on_enter = STATE_MACHINE[state_str].get('on_enter', None)
if on_enter:
# noinspection PyCallingNonCallable
on_enter(sess, key_id)
sess.commit()
delay, next_state_str = STATE_MACHINE[state_str].get('timed_transition', [0, None])
if delay:
Timer(delay, handle_set_state, (conn, key_id, next_state_str)).start()
finally:
sess.session_stop()
if __name__ == '__main__':
xpath_ctx = sr.Xpath_Ctx()
executor = ThreadPoolExecutor(max_workers=2)
main()
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