# Copyright 2023 highstreet technologies GmbH # # 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. #!/usr/bin/python """ A Class representing an O-RAN Near real-time intelligent controller (ORanNearRtRic) """ from typing import overload from network_generation.model.python.tower import Tower from network_generation.model.python.o_ran_cu import ORanCu from network_generation.model.python.o_ran_object import IORanObject from network_generation.model.python.o_ran_node import ORanNode from network_generation.model.python.o_ran_termination_point import ORanTerminationPoint from network_generation.model.python.hexagon import Hex import network_generation.model.python.hexagon as Hexagon import xml.etree.ElementTree as ET # Define the "IORanNearRtRic" interface class IORanNearRtRic(IORanObject): def __init__(self, **kwargs): super().__init__(**kwargs) # Define an abstract O-RAN Node class class ORanNearRtRic(ORanNode, IORanNearRtRic): def __init__(self, o_ran_near_rt_ric_data: IORanNearRtRic = None, **kwargs): super().__init__(o_ran_near_rt_ric_data, **kwargs) self._o_ran_cus: list[ORanCu] = self._calculate_o_ran_cus() def _calculate_o_ran_cus(self) -> list[ORanCu]: hex_ring_radius: int = self.spiralRadiusProfile.oRanNearRtRicSpiralRadiusOfOCus hex_list: list[Hex] = self.spiralRadiusProfile.oRanCuSpiral( self.position, hex_ring_radius ) result: list[ORanCu] = [] for index, hex in enumerate(hex_list): s: str = "00" + str(index) name: str = "-".join( [self.name.replace("NearRtRic", "CU"), s[len(s) - 2 : len(s)]] ) network_center: dict = self.parent.parent.center newGeo = Hexagon.hex_to_geo_location( self.layout, hex, network_center ).json() result.append( ORanCu( { "name": name, "geoLocation": newGeo, "position": hex, "layout": self.layout, "spiralRadiusProfile": self.spiralRadiusProfile, "parent": self } ) ) return result @property def o_ran_cus(self) -> list[ORanCu]: return self._o_ran_cus @property def towers(self) -> list[Tower]: result: list[Tower] = [] for cu in self.o_ran_cus: for tower in cu.towers: result.append(tower) return result @property def termination_points(self) -> list[ORanTerminationPoint]: result: list[ORanTerminationPoint] = super().termination_points phy_tp: str = "-".join([self.name, "phy".upper()]) result.append({"tp-id": phy_tp, "name": phy_tp}) for interface in ["a1", "o1", "o2", "e2"]: id:str = "-".join([self.name, interface.upper()]) result.append(ORanTerminationPoint({"id": id, "name":id, "supporter": phy_tp, "parent":self})) return result def to_topology_nodes(self) -> list[dict[str, dict]]: result: list[dict[str, dict]] = super().to_topology_nodes() for o_ran_cu in self.o_ran_cus: result.extend(o_ran_cu.to_topology_nodes()) return result def to_topology_links(self) -> list[dict[str, dict]]: result: list[dict[str, dict]] = super().to_topology_links() for o_ran_cu in self.o_ran_cus: result.extend(o_ran_cu.to_topology_links()) return result def toKml(self) -> ET.Element: ric: ET.Element = ET.Element("Folder") open: ET.Element = ET.SubElement(ric, "open") open.text = "1" name: ET.Element = ET.SubElement(ric, "name") name.text = self.name for o_ran_cu in self.o_ran_cus: ric.append(o_ran_cu.toKml()) return ric def toSvg(self) -> None: return None