Files
oopt-gnpy/gnpy/tools/cli_examples.py
EstherLerouzic 54a3725e17 Add a -spectrum option to input external file to define spectrum
The option is only set for gnpy-transmission-main.

The spectrum file is a list of spectrum objects, each defining
f_min, f_max and spectrum attributes using the same meaning as SI
in eqpt_config.json for baud_rate, roll_off, tx_osnr. slot_width is
used for the occupation of each carrier around their central frequency,
so slot_width corresponds to spacing of SI.
Unlike SI, the frequencies are defined includint f_min and f_max.
The partitions must be contiguous not overlapping.

Pref.p_span0 object records the req_power, while
ref_carrier records info that will be useful for equalization ie baud_rate.

For now, I have not integrated the possibility to directly use
transceivers type and mode in the list.

User can define sets of contiguous channels and a label to identify
the spectrum bands. If no label are defined, the program justs uses
the index + baud rate of the spectrum bands as label.

Print results per spectrum label

If propagated spectrum has mixed rates, then prints results (GSNR and OSNR)
for each propagated spectrum type according to its label.

Print per label channel power of elements

Per channel power prints were previously only showing the noiseless
reference channel power and only an average power.
With this change, we add a new information on the print:
the average total power (signal + noise + non-linear noise).
If there are several spectrum types propagating, the average per
spectrum is displayed using the label.
For this purpose, label and total power are recorded in each element
upon propagation

Note that the difference between this total power and the existing
channel power represents the added noise for the considered OMS.
Indeed ROADMs equalize per channel total power, so that power displayed
in 'actual pch (dBm)' may contain some noise contribution accumulated
with previous propagation.
Because 'reference pch out (dBm)' is for the noiseless reference,
it is exactly set to the target power and 'actual pch (dBm)' is always
matching 'reference pch out (dBm)' in ROADM prints.

Add examples and tests for -spectrum option

initial_spectrum1.json reproduces exactly the case of SI
initial_spectrum2.json sets half of the spectrum with 50GHz 32Gbauds and
half with 75GHz 64 Gbauds. Power setting is not set for the second half,
So that equalization will depend on ROADM settings.

Signed-off-by: EstherLerouzic <esther.lerouzic@orange.com>
Change-Id: Ibc01e59e461e5e933e95d23dacbc5289e275ccf7
2022-11-09 14:39:25 +01:00

458 lines
21 KiB
Python

#!/usr/bin/env python3
# -*- coding: utf-8 -*-
'''
gnpy.tools.cli_examples
=======================
Common code for CLI examples
'''
import argparse
import logging
import sys
from math import ceil
from numpy import linspace, mean
from pathlib import Path
import gnpy.core.ansi_escapes as ansi_escapes
from gnpy.core.elements import Transceiver, Fiber, RamanFiber
from gnpy.core.equipment import trx_mode_params
import gnpy.core.exceptions as exceptions
from gnpy.core.network import build_network
from gnpy.core.parameters import SimParams
from gnpy.core.utils import db2lin, lin2db, automatic_nch
from gnpy.topology.request import (ResultElement, jsontocsv, compute_path_dsjctn, requests_aggregation,
BLOCKING_NOPATH, correct_json_route_list,
deduplicate_disjunctions, compute_path_with_disjunction,
PathRequest, compute_constrained_path, propagate)
from gnpy.topology.spectrum_assignment import build_oms_list, pth_assign_spectrum
from gnpy.tools.json_io import (load_equipment, load_network, load_json, load_requests, save_network,
requests_from_json, disjunctions_from_json, save_json, load_initial_spectrum)
from gnpy.tools.plots import plot_baseline, plot_results
_logger = logging.getLogger(__name__)
_examples_dir = Path(__file__).parent.parent / 'example-data'
_help_footer = '''
This program is part of GNPy, https://github.com/TelecomInfraProject/oopt-gnpy
Learn more at https://gnpy.readthedocs.io/
'''
_help_fname_json = 'FILE.json'
_help_fname_json_csv = 'FILE.(json|csv)'
def show_example_data_dir():
print(f'{_examples_dir}/')
def load_common_data(equipment_filename, topology_filename, simulation_filename, save_raw_network_filename):
'''Load common configuration from JSON files'''
try:
equipment = load_equipment(equipment_filename)
network = load_network(topology_filename, equipment)
if save_raw_network_filename is not None:
save_network(network, save_raw_network_filename)
print(f'{ansi_escapes.blue}Raw network (no optimizations) saved to {save_raw_network_filename}{ansi_escapes.reset}')
if not simulation_filename:
sim_params = {}
if next((node for node in network if isinstance(node, RamanFiber)), None) is not None:
print(f'{ansi_escapes.red}Invocation error:{ansi_escapes.reset} '
f'RamanFiber requires passing simulation params via --sim-params')
sys.exit(1)
else:
sim_params = load_json(simulation_filename)
SimParams.set_params(sim_params)
except exceptions.EquipmentConfigError as e:
print(f'{ansi_escapes.red}Configuration error in the equipment library:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.NetworkTopologyError as e:
print(f'{ansi_escapes.red}Invalid network definition:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.ParametersError as e:
print(f'{ansi_escapes.red}Simulation parameters error:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.ConfigurationError as e:
print(f'{ansi_escapes.red}Configuration error:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.ServiceError as e:
print(f'{ansi_escapes.red}Service error:{ansi_escapes.reset} {e}')
sys.exit(1)
return (equipment, network)
def _setup_logging(args):
logging.basicConfig(level={2: logging.DEBUG, 1: logging.INFO, 0: logging.CRITICAL}.get(args.verbose, logging.DEBUG))
def _add_common_options(parser: argparse.ArgumentParser, network_default: Path):
parser.add_argument('topology', nargs='?', type=Path, metavar='NETWORK-TOPOLOGY.(json|xls|xlsx)',
default=network_default,
help='Input network topology')
parser.add_argument('-v', '--verbose', action='count', default=0,
help='Increase verbosity (can be specified several times)')
parser.add_argument('-e', '--equipment', type=Path, metavar=_help_fname_json,
default=_examples_dir / 'eqpt_config.json', help='Equipment library')
parser.add_argument('--sim-params', type=Path, metavar=_help_fname_json,
default=None, help='Path to the JSON containing simulation parameters (required for Raman). '
f'Example: {_examples_dir / "sim_params.json"}')
parser.add_argument('--save-network', type=Path, metavar=_help_fname_json,
help='Save the final network as a JSON file')
parser.add_argument('--save-network-before-autodesign', type=Path, metavar=_help_fname_json,
help='Dump the network into a JSON file prior to autodesign')
parser.add_argument('--no-insert-edfas', action='store_true',
help='Disable insertion of EDFAs after ROADMs and fibers '
'as well as splitting of fibers by auto-design.')
def transmission_main_example(args=None):
parser = argparse.ArgumentParser(
description='Send a full spectrum load through the network from point A to point B',
epilog=_help_footer,
formatter_class=argparse.ArgumentDefaultsHelpFormatter,
)
_add_common_options(parser, network_default=_examples_dir / 'edfa_example_network.json')
parser.add_argument('--show-channels', action='store_true', help='Show final per-channel OSNR and GSNR summary')
parser.add_argument('-pl', '--plot', action='store_true')
parser.add_argument('-l', '--list-nodes', action='store_true', help='list all transceiver nodes')
parser.add_argument('-po', '--power', default=0, help='channel ref power in dBm')
parser.add_argument('--spectrum', type=Path, help='user defined mixed rate spectrum JSON file')
parser.add_argument('source', nargs='?', help='source node')
parser.add_argument('destination', nargs='?', help='destination node')
args = parser.parse_args(args if args is not None else sys.argv[1:])
_setup_logging(args)
(equipment, network) = load_common_data(args.equipment, args.topology, args.sim_params, args.save_network_before_autodesign)
if args.plot:
plot_baseline(network)
transceivers = {n.uid: n for n in network.nodes() if isinstance(n, Transceiver)}
if not transceivers:
sys.exit('Network has no transceivers!')
if len(transceivers) < 2:
sys.exit('Network has only one transceiver!')
if args.list_nodes:
for uid in transceivers:
print(uid)
sys.exit()
# First try to find exact match if source/destination provided
if args.source:
source = transceivers.pop(args.source, None)
valid_source = True if source else False
else:
source = None
_logger.info('No source node specified: picking random transceiver')
if args.destination:
destination = transceivers.pop(args.destination, None)
valid_destination = True if destination else False
else:
destination = None
_logger.info('No destination node specified: picking random transceiver')
# If no exact match try to find partial match
if args.source and not source:
# TODO code a more advanced regex to find nodes match
source = next((transceivers.pop(uid) for uid in transceivers
if args.source.lower() in uid.lower()), None)
if args.destination and not destination:
# TODO code a more advanced regex to find nodes match
destination = next((transceivers.pop(uid) for uid in transceivers
if args.destination.lower() in uid.lower()), None)
# If no partial match or no source/destination provided pick random
if not source:
source = list(transceivers.values())[0]
del transceivers[source.uid]
if not destination:
destination = list(transceivers.values())[0]
_logger.info(f'source = {args.source!r}')
_logger.info(f'destination = {args.destination!r}')
params = {}
params['request_id'] = 0
params['trx_type'] = ''
params['trx_mode'] = ''
params['source'] = source.uid
params['destination'] = destination.uid
params['bidir'] = False
params['nodes_list'] = [destination.uid]
params['loose_list'] = ['strict']
params['format'] = ''
params['path_bandwidth'] = 0
params['effective_freq_slot'] = None
trx_params = trx_mode_params(equipment)
if args.power:
trx_params['power'] = db2lin(float(args.power)) * 1e-3
params.update(trx_params)
initial_spectrum = None
nb_channels = automatic_nch(trx_params['f_min'], trx_params['f_max'], trx_params['spacing'])
if args.spectrum:
initial_spectrum = load_initial_spectrum(args.spectrum)
nb_channels = len(initial_spectrum)
print('User input for spectrum used for propagation instead of SI')
params['nb_channel'] = nb_channels
req = PathRequest(**params)
req.initial_spectrum = initial_spectrum
print(f'There are {nb_channels} channels propagating')
power_mode = equipment['Span']['default'].power_mode
print('\n'.join([f'Power mode is set to {power_mode}',
f'=> it can be modified in eqpt_config.json - Span']))
pref_ch_db = lin2db(req.power * 1e3) # reference channel power / span (SL=20dB)
pref_total_db = pref_ch_db + lin2db(req.nb_channel) # reference total power / span (SL=20dB)
try:
build_network(network, equipment, pref_ch_db, pref_total_db, args.no_insert_edfas)
except exceptions.NetworkTopologyError as e:
print(f'{ansi_escapes.red}Invalid network definition:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.ConfigurationError as e:
print(f'{ansi_escapes.red}Configuration error:{ansi_escapes.reset} {e}')
sys.exit(1)
path = compute_constrained_path(network, req)
spans = [s.params.length for s in path if isinstance(s, RamanFiber) or isinstance(s, Fiber)]
print(f'\nThere are {len(spans)} fiber spans over {sum(spans)/1000:.0f} km between {source.uid} '
f'and {destination.uid}')
print(f'\nNow propagating between {source.uid} and {destination.uid}:')
power_range = [0]
if power_mode:
# power cannot be changed in gain mode
try:
p_start, p_stop, p_step = equipment['SI']['default'].power_range_db
p_num = abs(int(round((p_stop - p_start) / p_step))) + 1 if p_step != 0 else 1
power_range = list(linspace(p_start, p_stop, p_num))
except TypeError:
print('invalid power range definition in eqpt_config, should be power_range_db: [lower, upper, step]')
for dp_db in power_range:
req.power = db2lin(pref_ch_db + dp_db) * 1e-3
# if initial spectrum did not contain any power, now we need to use this one.
# note the initial power defines a differential wrt req.power so that if req.power is set to 2mW (3dBm)
# and initial spectrum was set to 0, this sets a initial per channel delta power to -3dB, so that
# whatever the equalization, -3 dB is applied on all channels (ie initial power in initial spectrum pre-empts
# "--power" option)
if power_mode:
print(f'\nPropagating with input power = {ansi_escapes.cyan}{lin2db(req.power*1e3):.2f} dBm{ansi_escapes.reset}:')
else:
print(f'\nPropagating in {ansi_escapes.cyan}gain mode{ansi_escapes.reset}: power cannot be set manually')
infos = propagate(path, req, equipment)
if len(power_range) == 1:
for elem in path:
print(elem)
if power_mode:
print(f'\nTransmission result for input power = {lin2db(req.power*1e3):.2f} dBm:')
else:
print(f'\nTransmission results:')
print(f' Final GSNR (0.1 nm): {ansi_escapes.cyan}{mean(destination.snr_01nm):.02f} dB{ansi_escapes.reset}')
else:
print(path[-1])
if args.save_network is not None:
save_network(network, args.save_network)
print(f'{ansi_escapes.blue}Network (after autodesign) saved to {args.save_network}{ansi_escapes.reset}')
if args.show_channels:
print('\nThe GSNR per channel at the end of the line is:')
print(
'{:>5}{:>26}{:>26}{:>28}{:>28}{:>28}' .format(
'Ch. #',
'Channel frequency (THz)',
'Channel power (dBm)',
'OSNR ASE (signal bw, dB)',
'SNR NLI (signal bw, dB)',
'GSNR (signal bw, dB)'))
for final_carrier, ch_osnr, ch_snr_nl, ch_snr in zip(
infos.carriers, path[-1].osnr_ase, path[-1].osnr_nli, path[-1].snr):
ch_freq = final_carrier.frequency * 1e-12
ch_power = lin2db(final_carrier.power.signal * 1e3)
print(
'{:5}{:26.5f}{:26.2f}{:28.2f}{:28.2f}{:28.2f}' .format(
final_carrier.channel_number, round(
ch_freq, 5), round(
ch_power, 2), round(
ch_osnr, 2), round(
ch_snr_nl, 2), round(
ch_snr, 2)))
if not args.source:
print(f'\n(No source node specified: picked {source.uid})')
elif not valid_source:
print(f'\n(Invalid source node {args.source!r} replaced with {source.uid})')
if not args.destination:
print(f'\n(No destination node specified: picked {destination.uid})')
elif not valid_destination:
print(f'\n(Invalid destination node {args.destination!r} replaced with {destination.uid})')
if args.plot:
plot_results(network, path, source, destination)
def _path_result_json(pathresult):
return {'response': [n.json for n in pathresult]}
def path_requests_run(args=None):
parser = argparse.ArgumentParser(
description='Compute performance for a list of services provided in a json file or an excel sheet',
epilog=_help_footer,
formatter_class=argparse.ArgumentDefaultsHelpFormatter,
)
_add_common_options(parser, network_default=_examples_dir / 'meshTopologyExampleV2.xls')
parser.add_argument('service_filename', nargs='?', type=Path, metavar='SERVICES-REQUESTS.(json|xls|xlsx)',
default=_examples_dir / 'meshTopologyExampleV2.xls',
help='Input service file')
parser.add_argument('-bi', '--bidir', action='store_true',
help='considers that all demands are bidir')
parser.add_argument('-o', '--output', type=Path, metavar=_help_fname_json_csv,
help='Store satisifed requests into a JSON or CSV file')
args = parser.parse_args(args if args is not None else sys.argv[1:])
_setup_logging(args)
_logger.info(f'Computing path requests {args.service_filename} into JSON format')
(equipment, network) = load_common_data(args.equipment, args.topology, args.sim_params, args.save_network_before_autodesign)
# Build the network once using the default power defined in SI in eqpt config
# TODO power density: db2linp(ower_dbm": 0)/power_dbm": 0 * nb channels as defined by
# spacing, f_min and f_max
p_db = equipment['SI']['default'].power_dbm
p_total_db = p_db + lin2db(automatic_nch(equipment['SI']['default'].f_min,
equipment['SI']['default'].f_max, equipment['SI']['default'].spacing))
try:
build_network(network, equipment, p_db, p_total_db, args.no_insert_edfas)
except exceptions.NetworkTopologyError as e:
print(f'{ansi_escapes.red}Invalid network definition:{ansi_escapes.reset} {e}')
sys.exit(1)
except exceptions.ConfigurationError as e:
print(f'{ansi_escapes.red}Configuration error:{ansi_escapes.reset} {e}')
sys.exit(1)
if args.save_network is not None:
save_network(network, args.save_network)
print(f'{ansi_escapes.blue}Network (after autodesign) saved to {args.save_network}{ansi_escapes.reset}')
oms_list = build_oms_list(network, equipment)
try:
data = load_requests(args.service_filename, equipment, bidir=args.bidir,
network=network, network_filename=args.topology)
rqs = requests_from_json(data, equipment)
except exceptions.ServiceError as e:
print(f'{ansi_escapes.red}Service error:{ansi_escapes.reset} {e}')
sys.exit(1)
# check that request ids are unique. Non unique ids, may
# mess the computation: better to stop the computation
all_ids = [r.request_id for r in rqs]
if len(all_ids) != len(set(all_ids)):
for item in list(set(all_ids)):
all_ids.remove(item)
msg = f'Requests id {all_ids} are not unique'
_logger.critical(msg)
sys.exit()
rqs = correct_json_route_list(network, rqs)
# pths = compute_path(network, equipment, rqs)
dsjn = disjunctions_from_json(data)
print(f'{ansi_escapes.blue}List of disjunctions{ansi_escapes.reset}')
print(dsjn)
# need to warn or correct in case of wrong disjunction form
# disjunction must not be repeated with same or different ids
dsjn = deduplicate_disjunctions(dsjn)
# Aggregate demands with same exact constraints
print(f'{ansi_escapes.blue}Aggregating similar requests{ansi_escapes.reset}')
rqs, dsjn = requests_aggregation(rqs, dsjn)
# TODO export novel set of aggregated demands in a json file
print(f'{ansi_escapes.blue}The following services have been requested:{ansi_escapes.reset}')
print(rqs)
print(f'{ansi_escapes.blue}Computing all paths with constraints{ansi_escapes.reset}')
try:
pths = compute_path_dsjctn(network, equipment, rqs, dsjn)
except exceptions.DisjunctionError as this_e:
print(f'{ansi_escapes.red}Disjunction error:{ansi_escapes.reset} {this_e}')
sys.exit(1)
print(f'{ansi_escapes.blue}Propagating on selected path{ansi_escapes.reset}')
propagatedpths, reversed_pths, reversed_propagatedpths = compute_path_with_disjunction(network, equipment, rqs, pths)
# Note that deepcopy used in compute_path_with_disjunction returns
# a list of nodes which are not belonging to network (they are copies of the node objects).
# so there can not be propagation on these nodes.
pth_assign_spectrum(pths, rqs, oms_list, reversed_pths)
print(f'{ansi_escapes.blue}Result summary{ansi_escapes.reset}')
header = ['req id', ' demand', ' GSNR@bandwidth A-Z (Z-A)', ' GSNR@0.1nm A-Z (Z-A)',
' Receiver minOSNR', ' mode', ' Gbit/s', ' nb of tsp pairs',
'N,M or blocking reason']
data = []
data.append(header)
for i, this_p in enumerate(propagatedpths):
rev_pth = reversed_propagatedpths[i]
if rev_pth and this_p:
psnrb = f'{round(mean(this_p[-1].snr),2)} ({round(mean(rev_pth[-1].snr),2)})'
psnr = f'{round(mean(this_p[-1].snr_01nm), 2)}' +\
f' ({round(mean(rev_pth[-1].snr_01nm),2)})'
elif this_p:
psnrb = f'{round(mean(this_p[-1].snr),2)}'
psnr = f'{round(mean(this_p[-1].snr_01nm),2)}'
try:
if rqs[i].blocking_reason in BLOCKING_NOPATH:
line = [f'{rqs[i].request_id}', f' {rqs[i].source} to {rqs[i].destination} :',
f'-', f'-', f'-', f'{rqs[i].tsp_mode}', f'{round(rqs[i].path_bandwidth * 1e-9,2)}',
f'-', f'{rqs[i].blocking_reason}']
else:
line = [f'{rqs[i].request_id}', f' {rqs[i].source} to {rqs[i].destination} : ', psnrb,
psnr, f'-', f'{rqs[i].tsp_mode}', f'{round(rqs[i].path_bandwidth * 1e-9, 2)}',
f'-', f'{rqs[i].blocking_reason}']
except AttributeError:
line = [f'{rqs[i].request_id}', f' {rqs[i].source} to {rqs[i].destination} : ', psnrb,
psnr, f'{rqs[i].OSNR + equipment["SI"]["default"].sys_margins}',
f'{rqs[i].tsp_mode}', f'{round(rqs[i].path_bandwidth * 1e-9,2)}',
f'{ceil(rqs[i].path_bandwidth / rqs[i].bit_rate) }', f'({rqs[i].N},{rqs[i].M})']
data.append(line)
col_width = max(len(word) for row in data for word in row[2:]) # padding
firstcol_width = max(len(row[0]) for row in data) # padding
secondcol_width = max(len(row[1]) for row in data) # padding
for row in data:
firstcol = ''.join(row[0].ljust(firstcol_width))
secondcol = ''.join(row[1].ljust(secondcol_width))
remainingcols = ''.join(word.center(col_width, ' ') for word in row[2:])
print(f'{firstcol} {secondcol} {remainingcols}')
print(f'{ansi_escapes.yellow}Result summary shows mean GSNR and OSNR (average over all channels){ansi_escapes.reset}')
if args.output:
result = []
# assumes that list of rqs and list of propgatedpths have same order
for i, pth in enumerate(propagatedpths):
result.append(ResultElement(rqs[i], pth, reversed_propagatedpths[i]))
temp = _path_result_json(result)
if args.output.suffix.lower() == '.json':
save_json(temp, args.output)
print(f'{ansi_escapes.blue}Saved JSON to {args.output}{ansi_escapes.reset}')
elif args.output.suffix.lower() == '.csv':
with open(args.output, "w", encoding='utf-8') as fcsv:
jsontocsv(temp, equipment, fcsv)
print(f'{ansi_escapes.blue}Saved CSV to {args.output}{ansi_escapes.reset}')
else:
print(f'{ansi_escapes.red}Cannot save output: neither JSON nor CSV file{ansi_escapes.reset}')
sys.exit(1)