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|
#!/usr/bin/env python3
import getopt
import json
import numpy as np
import os
import re
import sys
import plotter
from copy import deepcopy
from dfatool import aggregate_measures, regression_measures, is_numeric, powerset
from dfatool import append_if_set, mean_or_none
from matplotlib.patches import Polygon
from scipy import optimize
opts = {}
def load_json(filename):
with open(filename, "r") as f:
return json.load(f)
def save_json(data, filename):
with open(filename, "w") as f:
return json.dump(data, f)
def print_data(aggregate):
for key in sorted(aggregate.keys()):
data = aggregate[key]
name, params = key
print("%s @ %s : ~ = %.f (%.f, %.f) µ_σ_outer = %.f n = %d" %
(name, params, np.median(data['means']), np.percentile(data['means'], 25),
np.percentile(data['means'], 75), np.mean(data['stds']), len(data['means'])))
def flatten(somelist):
return [item for sublist in somelist for item in sublist]
def mimosa_data(elem):
means = [x['uW_mean'] for x in elem['offline']]
durations = [x['us'] - 20 for x in elem['offline']]
stds = [x['uW_std'] for x in elem['offline']]
energies = [x['uW_mean'] * (x['us'] - 20) for x in elem['offline']]
clips = [x['clip_rate'] for x in elem['offline']]
substate_thresholds = []
substate_data = []
timeouts = []
rel_energies_prev = []
rel_energies_next = []
if 'timeout' in elem['offline'][0]:
timeouts = [x['timeout'] for x in elem['offline']]
if 'uW_mean_delta_prev' in elem['offline'][0]:
rel_energies_prev = [x['uW_mean_delta_prev'] * (x['us'] - 20) for x in elem['offline']]
if 'uW_mean_delta_next' in elem['offline'][0]:
rel_energies_next = [x['uW_mean_delta_next'] * (x['us'] - 20) for x in elem['offline']]
for x in elem['offline']:
if 'substates' in x:
substate_thresholds.append(x['substates']['threshold'])
substate_data.append(x['substates']['states'])
return (means, stds, durations, energies, rel_energies_prev,
rel_energies_next, clips, timeouts, substate_thresholds)
def online_data(elem):
means = [int(x['power']) for x in elem['online']]
durations = [int(x['time']) for x in elem['online']]
return means, durations
# parameters = statistic variables such as txpower, bitrate etc.
# variables = function variables/parameters set by linear regression
def str_to_param_function(function_string, parameters, variables):
rawfunction = function_string
dependson = [False] * len(parameters)
for i in range(len(parameters)):
if rawfunction.find("global(%s)" % (parameters[i])) >= 0:
dependson[i] = True
rawfunction = rawfunction.replace("global(%s)" % (parameters[i]), "arg[%d]" % (i))
if rawfunction.find("local(%s)" % (parameters[i])) >= 0:
dependson[i] = True
rawfunction = rawfunction.replace("local(%s)" % (parameters[i]), "arg[%d]" % (i))
for i in range(len(variables)):
rawfunction = rawfunction.replace("param(%d)" % (i), "param[%d]" % (i))
fitfunc = eval("lambda param, arg: " + rawfunction);
return fitfunc, dependson
def mk_function_data(name, paramdata, parameters, dependson, datatype):
X = [[] for i in range(len(parameters))]
Xm = [[] for i in range(len(parameters))]
Y = []
Ym = []
num_valid = 0
num_total = 0
for key, val in paramdata.items():
if key[0] == name and len(key[1]) == len(parameters):
valid = True
num_total += 1
for i in range(len(parameters)):
if dependson[i] and not is_numeric(key[1][i]):
valid = False
if valid:
num_valid += 1
Y.extend(val[datatype])
Ym.append(np.median(val[datatype]))
for i in range(len(parameters)):
if dependson[i] or is_numeric(key[1][i]):
X[i].extend([int(key[1][i])] * len(val[datatype]))
Xm[i].append(int(key[1][i]))
else:
X[i].extend([0] * len(val[datatype]))
Xm[i].append(0)
for i in range(len(parameters)):
X[i] = np.array(X[i])
Xm[i] = np.array(Xm[i])
X = tuple(X)
Xm = tuple(Xm)
Y = np.array(Y)
Ym = np.array(Ym)
return X, Y, Xm, Ym, num_valid, num_total
def raw_num0_8(num):
return (8 - num1(num))
def raw_num0_16(num):
return (16 - num1(num))
def raw_num1(num):
return bin(int(num)).count("1")
num0_8 = np.vectorize(raw_num0_8)
num0_16 = np.vectorize(raw_num0_16)
num1 = np.vectorize(raw_num1)
def try_fits(name, datatype, paramidx, paramdata):
functions = {
'linear' : lambda param, arg: param[0] + param[1] * arg,
'logarithmic' : lambda param, arg: param[0] + param[1] * np.log(arg),
'logarithmic1' : lambda param, arg: param[0] + param[1] * np.log(arg + 1),
'exponential' : lambda param, arg: param[0] + param[1] * np.exp(arg),
#'polynomial' : lambda param, arg: param[0] + param[1] * arg + param[2] * arg ** 2,
'square' : lambda param, arg: param[0] + param[1] * arg ** 2,
'fractional' : lambda param, arg: param[0] + param[1] / arg,
'sqrt' : lambda param, arg: param[0] + param[1] * np.sqrt(arg),
'num0_8' : lambda param, arg: param[0] + param[1] * num0_8(arg),
'num0_16' : lambda param, arg: param[0] + param[1] * num0_16(arg),
'num1' : lambda param, arg: param[0] + param[1] * num1(arg),
}
results = dict([[key, []] for key in functions.keys()])
errors = {}
allvalues = [(*key[1][:paramidx], *key[1][paramidx+1:]) for key in paramdata.keys() if key[0] == name]
allvalues = list(set(allvalues))
for value in allvalues:
X = []
Xm = []
Y = []
Ym = []
num_valid = 0
num_total = 0
for key, val in paramdata.items():
if key[0] == name and len(key[1]) > paramidx and (*key[1][:paramidx], *key[1][paramidx+1:]) == value:
num_total += 1
if is_numeric(key[1][paramidx]):
num_valid += 1
Y.extend(val[datatype])
Ym.append(np.median(val[datatype]))
X.extend([int(key[1][paramidx])] * len(val[datatype]))
Xm.append(int(key[1][paramidx]))
if int(key[1][paramidx]) == 0:
functions.pop('fractional', None)
if int(key[1][paramidx]) <= 0:
functions.pop('logarithmic', None)
if int(key[1][paramidx]) < 0:
functions.pop('logarithmic1', None)
functions.pop('sqrt', None)
if int(key[1][paramidx]) > 64:
functions.pop('exponential', None)
# there should be -at least- two values when fitting
if num_valid > 1:
Y = np.array(Y)
Ym = np.array(Ym)
X = np.array(X)
Xm = np.array(Xm)
for kind, function in functions.items():
results[kind] = {}
errfunc = lambda P, X, y: function(P, X) - y
try:
res = optimize.least_squares(errfunc, [0, 1], args=(X, Y), xtol=2e-15)
measures = regression_measures(function(res.x, X), Y)
for k, v in measures.items():
if not k in results[kind]:
results[kind][k] = []
results[kind][k].append(v)
except:
pass
for function_name, result in results.items():
if len(result) > 0 and function_name in functions:
errors[function_name] = {}
for measure in result.keys():
errors[function_name][measure] = np.mean(result[measure])
return errors
def fit_function(function, name, datatype, parameters, paramdata, xaxis=None, yaxis=None):
variables = list(map(lambda x: float(x), function['params']))
fitfunc, dependson = str_to_param_function(function['raw'], parameters, variables)
X, Y, Xm, Ym, num_valid, num_total = mk_function_data(name, paramdata, parameters, dependson, datatype)
if num_valid > 0:
if num_valid != num_total:
num_invalid = num_total - num_valid
print("Warning: fit(%s): %d of %d states had incomplete parameter hashes" % (name, num_invalid, len(paramdata)))
errfunc = lambda P, X, y: fitfunc(P, X) - y
try:
res = optimize.least_squares(errfunc, variables, args=(X, Y), xtol=2e-15) # loss='cauchy'
except ValueError as err:
function['error'] = str(err)
return
#x1 = optimize.curve_fit(lambda param, *arg: fitfunc(param, arg), X, Y, functionparams)
measures = regression_measures(fitfunc(res.x, X), Y)
if res.status <= 0:
function['error'] = res.message
return
if 'fit' in opts:
for i in range(len(parameters)):
plotter.plot_param_fit(function['raw'], name, fitfunc, res.x, parameters, datatype, i, X, Y, xaxis, yaxis)
function['params'] = list(res.x)
function['fit'] = measures
else:
function['error'] = 'log contained no numeric parameters'
def assess_function(function, name, datatype, parameters, paramdata):
variables = list(map(lambda x: float(x), function['params']))
fitfunc, dependson = str_to_param_function(function['raw'], parameters, variables)
X, Y, Xm, Ym, num_valid, num_total = mk_function_data(name, paramdata, parameters, dependson, datatype)
if num_valid > 0:
return regression_measures(fitfunc(variables, X), Y)
else:
return None
def xv_assess_function(name, funbase, what, validation, mae, smape):
goodness = assess_function(funbase, name, what, parameters, validation)
if goodness != None:
if not name in mae:
mae[name] = []
if not name in smape:
smape[name] = []
append_if_set(mae, goodness, 'mae')
append_if_set(smape, goodness, 'smape')
def xv2_assess_function(name, funbase, what, validation, mae, smape, rmsd):
goodness = assess_function(funbase, name, what, parameters, validation)
if goodness != None:
if goodness['mae'] < 10e9:
mae.append(goodness['mae'])
rmsd.append(goodness['rmsd'])
smape.append(goodness['smape'])
else:
print('[!] Ignoring MAE of %d (SMAPE %.f)' % (goodness['mae'], goodness['smape']))
# Returns the values used for each parameter in the measurement, e.g.
# { 'txpower' : [1, 2, 4, 8], 'length' : [16] }
# non-numeric values such as '' are skipped
def param_values(parameters, by_param):
paramvalues = dict([[param, set()] for param in parameters])
for _, paramvalue in by_param.keys():
for i, param in enumerate(parameters):
if is_numeric(paramvalue[i]):
paramvalues[param].add(paramvalue[i])
return paramvalues
# Returns the values used for each function argument in the measurement, e.g.
# { 'data': [], 'length' : [16, 31, 32] }
# non-numeric values such as '' or 'long_test_string' are skipped
def arg_values(name, by_arg):
TODO
argvalues = dict([[arg, set()] for arg in parameters])
for _, paramvalue in by_param.keys():
for i, param in enumerate(parameters):
if is_numeric(paramvalue[i]):
paramvalues[param].add(paramvalue[i])
return paramvalues
def mk_param_key(elem):
name = elem['name']
paramtuple = ()
if 'parameter' in elem:
paramkeys = sorted(elem['parameter'].keys())
paramtuple = tuple([elem['parameter'][x] for x in paramkeys])
return (name, paramtuple)
def mk_arg_key(elem):
name = elem['name']
argtuple = ()
if 'args' in elem:
argtuple = tuple(elem['args'])
return (name, argtuple)
def add_data_to_aggregate(aggregate, key, isa, data):
if not key in aggregate:
aggregate[key] = {
'isa' : isa,
}
for datakey in data.keys():
aggregate[key][datakey] = []
for datakey, dataval in data.items():
aggregate[key][datakey].extend(dataval)
def fake_add_data_to_aggregate(aggregate, key, isa, database, idx):
timeout_val = []
if len(database['timeouts']):
timeout_val = [database['timeouts'][idx]]
rel_energy_p_val = []
if len(database['rel_energies_prev']):
rel_energy_p_val = [database['rel_energies_prev'][idx]]
rel_energy_n_val = []
if len(database['rel_energies_next']):
rel_energy_n_val = [database['rel_energies_next'][idx]]
add_data_to_aggregate(aggregate, key, isa, {
'means' : [database['means'][idx]],
'stds' : [database['stds'][idx]],
'durations' : [database['durations'][idx]],
'energies' : [database['energies'][idx]],
'rel_energies_prev' : rel_energy_p_val,
'rel_energies_next' : rel_energy_n_val,
'clip_rate' : [database['clip_rate'][idx]],
'timeouts' : timeout_val,
})
def weight_by_name(aggdata):
total = {}
count = {}
weight = {}
for key in aggdata.keys():
if not key[0] in total:
total[key[0]] = 0
total[key[0]] += len(aggdata[key]['means'])
count[key] = len(aggdata[key]['means'])
for key in aggdata.keys():
weight[key] = float(count[key]) / total[key[0]]
return weight
# returns the mean standard deviation of all measurements of 'what'
# (e.g. power consumption or timeout) for state/transition 'name' where
# parameter 'index' is dynamic and all other parameters are fixed.
# I.e., if parameters are a, b, c ∈ {1,2,3} and 'index' corresponds to b', then
# this function returns the mean of the standard deviations of (a=1, b=*, c=1),
# (a=1, b=*, c=2), and so on
def mean_std_by_param(data, keys, name, what, index):
partitions = []
for key in keys:
partition = []
for k, v in data.items():
if (*k[1][:index], *k[1][index+1:]) == key and k[0] == name:
partition.extend(v[what])
partitions.append(partition)
return np.mean([np.std(partition) for partition in partitions])
# returns the mean standard deviation of all measurements of 'what'
# (e.g. energy or duration) for transition 'name' where
# the 'index'th argumetn is dynamic and all other arguments are fixed.
# I.e., if arguments are a, b, c ∈ {1,2,3} and 'index' is 1, then
# this function returns the mean of the standard deviations of (a=1, b=*, c=1),
# (a=1, b=*, c=2), and so on
def mean_std_by_arg(data, keys, name, what, index):
return mean_std_by_param(data, keys, name, what, index)
# returns the mean standard deviation of all measurements of 'what'
# (e.g. power consumption or timeout) for state/transition 'name' where the
# trace of previous transitions is fixed except for a single transition,
# whose occurence or absence is silently ignored.
# this is done separately for each transition (-> returns a dictionary)
def mean_std_by_trace_part(data, transitions, name, what):
ret = {}
for transition in transitions:
keys = set(map(lambda x : (x[0], x[1], tuple([y for y in x[2] if y != transition])), data.keys()))
ret[transition] = {}
partitions = []
for key in keys:
partition = []
for k, v in data.items():
key_without_transition = (k[0], k[1], tuple([y for y in k[2] if y != transition]))
if key[0] == name and key == key_without_transition:
partition.extend(v[what])
if len(partition):
partitions.append(partition)
ret[transition] = np.mean([np.std(partition) for partition in partitions])
return ret
def load_run_elem(index, element, trace, by_name, by_arg, by_param, by_trace):
means, stds, durations, energies, rel_energies_prev, rel_energies_next, clips, timeouts, sub_thresholds = mimosa_data(element)
online_means = []
online_durations = []
if element['isa'] == 'state':
online_means, online_durations = online_data(element)
arg_key = mk_arg_key(element)
param_key = mk_param_key(element)
pre_trace = tuple(map(lambda x : x['name'], trace[1:index:2]))
trace_key = (*param_key, pre_trace)
name = element['name']
elem_data = {
'means' : means,
'stds' : stds,
'durations' : durations,
'energies' : energies,
'rel_energies_prev' : rel_energies_prev,
'rel_energies_next' : rel_energies_next,
'clip_rate' : clips,
'timeouts' : timeouts,
'sub_thresholds' : sub_thresholds,
'param' : [param_key[1]] * len(means),
'online_means' : online_means,
'online_durations' : online_durations,
}
add_data_to_aggregate(by_name, name, element['isa'], elem_data)
add_data_to_aggregate(by_arg, arg_key, element['isa'], elem_data)
add_data_to_aggregate(by_param, param_key, element['isa'], elem_data)
add_data_to_aggregate(by_trace, trace_key, element['isa'], elem_data)
def fmap(reftype, name, funtype):
if funtype == 'linear':
return "%s(%s)" % (reftype, name)
if funtype == 'logarithmic':
return "np.log(%s(%s))" % (reftype, name)
if funtype == 'logarithmic1':
return "np.log(%s(%s) + 1)" % (reftype, name)
if funtype == 'exponential':
return "np.exp(%s(%s))" % (reftype, name)
if funtype == 'square':
return "%s(%s)**2" % (reftype, name)
if funtype == 'fractional':
return "1 / %s(%s)" % (reftype, name)
if funtype == 'sqrt':
return "np.sqrt(%s(%s))" % (reftype, name)
if funtype == 'num0_8':
return "num0_8(%s(%s))" % (reftype, name)
if funtype == 'num0_16':
return "num0_16(%s(%s))" % (reftype, name)
if funtype == 'num1':
return "num1(%s(%s))" % (reftype, name)
return "ERROR"
def fguess_to_function(name, datatype, aggdata, parameters, paramdata, yaxis):
best_fit = {}
fitguess = aggdata['fit_guess']
params = list(filter(lambda x : x in fitguess, parameters))
if len(params) > 0:
for param in params:
best_fit_val = np.inf
for func_name, fit_val in fitguess[param].items():
if fit_val['rmsd'] < best_fit_val:
best_fit_val = fit_val['rmsd']
best_fit[param] = func_name
buf = '0'
pidx = 0
for elem in powerset(best_fit.items()):
buf += " + param(%d)" % pidx
pidx += 1
for fun in elem:
buf += " * %s" % fmap('global', *fun)
aggdata['function']['estimate'] = {
'raw' : buf,
'params' : list(np.ones((pidx))),
'base' : [best_fit[param] for param in params]
}
fit_function(
aggdata['function']['estimate'], name, datatype, parameters,
paramdata, yaxis=yaxis)
def arg_fguess_to_function(name, datatype, aggdata, arguments, argdata, yaxis):
best_fit = {}
fitguess = aggdata['arg_fit_guess']
args = list(filter(lambda x : x in fitguess, arguments))
if len(args) > 0:
for arg in args:
best_fit_val = np.inf
for func_name, fit_val in fitguess[arg].items():
if fit_val['rmsd'] < best_fit_val:
best_fit_val = fit_val['rmsd']
best_fit[arg] = func_name
buf = '0'
pidx = 0
for elem in powerset(best_fit.items()):
buf += " + param(%d)" % pidx
pidx += 1
for fun in elem:
buf += " * %s" % fmap('local', *fun)
aggdata['arg_function']['estimate'] = {
'raw' : buf,
'params' : list(np.ones((pidx))),
'base' : [best_fit[arg] for arg in args]
}
fit_function(
aggdata['arg_function']['estimate'], name, datatype, arguments,
argdata, yaxis=yaxis)
def param_measures(name, paramdata, key, fun):
mae = []
smape = []
rmsd = []
for pkey, pval in paramdata.items():
if pkey[0] == name:
# Median ist besseres Maß für MAE / SMAPE,
# Mean ist besseres für SSR. Da least_squares SSR optimiert
# nutzen wir hier auch Mean.
goodness = aggregate_measures(fun(pval[key]), pval[key])
append_if_set(mae, goodness, 'mae')
append_if_set(rmsd, goodness, 'rmsd')
append_if_set(smape, goodness, 'smape')
ret = {
'mae' : mean_or_none(mae),
'rmsd' : mean_or_none(rmsd),
'smape' : mean_or_none(smape)
}
return ret
def arg_measures(name, argdata, key, fun):
return param_measures(name, argdata, key, fun)
def keydata(name, val, argdata, paramdata, tracedata, key):
ret = {
'count' : len(val[key]),
'median' : np.median(val[key]),
'mean' : np.mean(val[key]),
'mean_goodness' : aggregate_measures(np.mean(val[key]), val[key]),
'median_goodness' : aggregate_measures(np.median(val[key]), val[key]),
'param_mean_goodness' : param_measures(name, paramdata, key, np.mean),
'param_median_goodness' : param_measures(name, paramdata, key, np.median),
'std_inner' : np.std(val[key]),
'std_param' : np.mean([np.std(paramdata[x][key]) for x in paramdata.keys() if x[0] == name]),
'std_trace' : np.mean([np.std(tracedata[x][key]) for x in tracedata.keys() if x[0] == name]),
'std_by_param' : {},
'fit_guess' : {},
'function' : {},
}
if val['isa'] == 'transition':
ret['arg_mean_goodness'] = arg_measures(name, argdata, key, np.mean)
ret['arg_median_goodness'] = arg_measures(name, argdata, key, np.median)
ret['std_arg'] = np.mean([np.std(argdata[x][key]) for x in argdata.keys() if x[0] == name])
ret['std_by_arg'] = {}
ret['arg_fit_guess'] = {}
ret['arg_function'] = {}
return ret
def splitidx_kfold(length, num_slices):
pairs = []
indexes = np.arange(length)
for i in range(0, num_slices):
training = np.delete(indexes, slice(i, None, num_slices))
validation = indexes[i::num_slices]
pairs.append((training, validation))
return pairs
def splitidx_srs(length, num_slices):
pairs = []
for i in range(0, num_slices):
shuffled = np.random.permutation(np.arange(length))
border = int(length * float(2) / 3)
training = shuffled[:border]
validation = shuffled[border:]
pairs.append((training, validation))
return pairs
def val_run(aggdata, split_fun, count):
mae = []
smape = []
rmsd = []
pairs = split_fun(len(aggdata), count)
for i in range(0, count):
training = aggdata[pairs[i][0]]
validation = aggdata[pairs[i][1]]
median = np.median(training)
goodness = aggregate_measures(median, validation)
append_if_set(mae, goodness, 'mae')
append_if_set(rmsd, goodness, 'rmsd')
append_if_set(smape, goodness, 'smape')
mae_mean = np.mean(mae)
rmsd_mean = np.mean(rmsd)
if len(smape):
smape_mean = np.mean(smape)
else:
smape_mean = -1
return mae_mean, smape_mean, rmsd_mean
# by_trace is not part of the cross-validation process
def val_run_fun(aggdata, by_trace, name, key, funtype1, funtype2, splitfun, count):
aggdata = aggdata[name]
isa = aggdata['isa']
mae = []
smape = []
rmsd = []
estimates = []
pairs = splitfun(len(aggdata[key]), count)
for i in range(0, count):
bpa_training = {}
bpa_validation = {}
for idx in pairs[i][0]:
bpa_key = (name, aggdata['param'][idx])
fake_add_data_to_aggregate(bpa_training, bpa_key, isa, aggdata, idx)
for idx in pairs[i][1]:
bpa_key = (name, aggdata['param'][idx])
fake_add_data_to_aggregate(bpa_validation, bpa_key, isa, aggdata, idx)
fake_by_name = { name : aggdata }
ares = analyze(fake_by_name, {}, bpa_training, by_trace, parameters)
if name in ares[isa] and funtype2 in ares[isa][name][funtype1]['function']:
xv2_assess_function(name, ares[isa][name][funtype1]['function'][funtype2], key, bpa_validation, mae, smape, rmsd)
if funtype2 == 'estimate':
if 'base' in ares[isa][name][funtype1]['function'][funtype2]:
estimates.append(tuple(ares[isa][name][funtype1]['function'][funtype2]['base']))
else:
estimates.append(None)
return mae, smape, rmsd, estimates
# by_trace is not part of the cross-validation process
def val_run_fun_p(aggdata, by_trace, name, key, funtype1, funtype2, splitfun, count):
aggdata = dict([[x, aggdata[x]] for x in aggdata if x[0] == name])
isa = aggdata[list(aggdata.keys())[0]]['isa']
mae = []
smape = []
rmsd = []
estimates = []
pairs = splitfun(len(aggdata.keys()), count) # pairs are by_param index arrays
keys = sorted(aggdata.keys())
for i in range(0, count):
bpa_training = dict([[keys[x], aggdata[keys[x]]] for x in pairs[i][0]])
bpa_validation = dict([[keys[x], aggdata[keys[x]]] for x in pairs[i][1]])
bna_training = {}
for val in bpa_training.values():
for idx in range(0, len(val[key])):
fake_add_data_to_aggregate(bna_training, name, isa, val, idx)
ares = analyze(bna_training, {}, bpa_training, by_trace, parameters)
if name in ares[isa] and funtype2 in ares[isa][name][funtype1]['function']:
xv2_assess_function(name, ares[isa][name][funtype1]['function'][funtype2], key, bpa_validation, mae, smape, rmsd)
if funtype2 == 'estimate':
if 'base' in ares[isa][name][funtype1]['function'][funtype2]:
estimates.append(tuple(ares[isa][name][funtype1]['function'][funtype2]['base']))
else:
estimates.append(None)
return mae, smape, rmsd, estimates
def crossvalidate(by_name, by_param, by_trace, model, parameters):
param_mc_count = 200
paramv = param_values(parameters, by_param)
for name in sorted(by_name.keys()):
isa = by_name[name]['isa']
by_name[name]['means'] = np.array(by_name[name]['means'])
by_name[name]['energies'] = np.array(by_name[name]['energies'])
by_name[name]['rel_energies_prev'] = np.array(by_name[name]['rel_energies_prev'])
by_name[name]['rel_energies_next'] = np.array(by_name[name]['rel_energies_next'])
by_name[name]['durations'] = np.array(by_name[name]['durations'])
if isa == 'state':
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['means'], splitidx_srs, 200)
print('%16s, static power, Monte Carlo: MAE %8.f µW, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['means'], splitidx_kfold, 10)
print('%16s, static power, 10-fold sys: MAE %8.f µW, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
else:
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['energies'], splitidx_srs, 200)
print('%16s, static energy, Monte Carlo: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['energies'], splitidx_kfold, 10)
print('%16s, static energy, 10-fold sys: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['rel_energies_prev'], splitidx_srs, 200)
print('%16s, static rel_energy_p, Monte Carlo: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['rel_energies_prev'], splitidx_kfold, 10)
print('%16s, static rel_energy_p, 10-fold sys: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['rel_energies_next'], splitidx_srs, 200)
print('%16s, static rel_energy_n, Monte Carlo: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['rel_energies_next'], splitidx_kfold, 10)
print('%16s, static rel_energy_n, 10-fold sys: MAE %8.f pJ, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['durations'], splitidx_srs, 200)
print('%16s, static duration, Monte Carlo: MAE %8.f µs, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
mae_mean, smape_mean, rms_mean = val_run(by_name[name]['durations'], splitidx_kfold, 10)
print('%16s, static duration, 10-fold sys: MAE %8.f µs, SMAPE %6.2f%%, RMS %d' % (name, mae_mean, smape_mean, rms_mean))
def print_estimates(estimates, total):
histogram = {}
buf = ' '
for estimate in estimates:
if not estimate in histogram:
histogram[estimate] = 1
else:
histogram[estimate] += 1
for estimate, count in sorted(histogram.items(), key=lambda kv: kv[1], reverse=True):
buf += ' %.f%% %s' % (count * 100 / total, estimate)
if len(estimates):
print(buf)
def val_run_funs(by_name, by_trace, name, key1, key2, key3, unit):
mae, smape, rmsd, estimates = val_run_fun(by_name, by_trace, name, key1, key2, key3, splitidx_srs, param_mc_count)
print('%16s, %8s %10s, Monte Carlo: MAE %8.f %s, SMAPE %6.2f%%, RMS %d' % (
name, key3, key2, np.mean(mae), unit, np.mean(smape), np.mean(rmsd)))
print_estimates(estimates, param_mc_count)
mae, smape, rmsd, estimates = val_run_fun(by_name, by_trace, name, key1, key2, key3, splitidx_kfold, 10)
print('%16s, %8s %10s, 10-fold sys: MAE %8.f %s, SMAPE %6.2f%%, RMS %d' % (
name, key3, key2, np.mean(mae), unit, np.mean(smape), np.mean(rmsd)))
print_estimates(estimates, 10)
mae, smape, rmsd, estimates = val_run_fun_p(by_param, by_trace, name, key1, key2, key3, splitidx_srs, param_mc_count)
print('%16s, %8s %10s, param-aware Monte Carlo: MAE %8.f %s, SMAPE %6.2f%%, RMS %d' % (
name, key3, key2, np.mean(mae), unit, np.mean(smape), np.mean(rmsd)))
print_estimates(estimates, param_mc_count)
mae, smape, rmsd, estimates = val_run_fun_p(by_param, by_trace, name, key1, key2, key3, splitidx_kfold, 10)
print('%16s, %8s %10s, param-aware 10-fold sys: MAE %8.f %s, SMAPE %6.2f%%, RMS %d' % (
name, key3, key2, np.mean(mae), unit, np.mean(smape), np.mean(rmsd)))
print_estimates(estimates, 10)
if 'power' in model[isa][name] and 'function' in model[isa][name]['power']:
if 'user' in model[isa][name]['power']['function']:
val_run_funs(by_name, by_trace, name, 'means', 'power', 'user', 'µW')
if 'estimate' in model[isa][name]['power']['function']:
val_run_funs(by_name, by_trace, name, 'means', 'power', 'estimate', 'µW')
if 'timeout' in model[isa][name] and 'function' in model[isa][name]['timeout']:
if 'user' in model[isa][name]['timeout']['function']:
val_run_funs(by_name, by_trace, name, 'timeouts', 'timeout', 'user', 'µs')
if 'estimate' in model[isa][name]['timeout']['function']:
val_run_funs(by_name, by_trace, name, 'timeouts', 'timeout', 'estimate', 'µs')
if 'duration' in model[isa][name] and 'function' in model[isa][name]['duration']:
if 'user' in model[isa][name]['duration']['function']:
val_run_funs(by_name, by_trace, name, 'durations', 'duration', 'user', 'µs')
if 'estimate' in model[isa][name]['duration']['function']:
val_run_funs(by_name, by_trace, name, 'durations', 'duration', 'estimate', 'µs')
if 'energy' in model[isa][name] and 'function' in model[isa][name]['energy']:
if 'user' in model[isa][name]['energy']['function']:
val_run_funs(by_name, by_trace, name, 'energies', 'energy', 'user', 'pJ')
if 'estimate' in model[isa][name]['energy']['function']:
val_run_funs(by_name, by_trace, name, 'energies', 'energy', 'estimate', 'pJ')
if 'rel_energy_prev' in model[isa][name] and 'function' in model[isa][name]['rel_energy_prev']:
if 'user' in model[isa][name]['rel_energy_prev']['function']:
val_run_funs(by_name, by_trace, name, 'rel_energies_prev', 'rel_energy_prev', 'user', 'pJ')
if 'estimate' in model[isa][name]['rel_energy_prev']['function']:
val_run_funs(by_name, by_trace, name, 'rel_energies_prev', 'rel_energy_prev', 'estimate', 'pJ')
if 'rel_energy_next' in model[isa][name] and 'function' in model[isa][name]['rel_energy_next']:
if 'user' in model[isa][name]['rel_energy_next']['function']:
val_run_funs(by_name, by_trace, name, 'rel_energies_next', 'rel_energy_next', 'user', 'pJ')
if 'estimate' in model[isa][name]['rel_energy_next']['function']:
val_run_funs(by_name, by_trace, name, 'rel_energies_next', 'rel_energy_next', 'estimate', 'pJ')
return
for i, param in enumerate(parameters):
user_mae = {}
user_smape = {}
estimate_mae = {}
estimate_smape = {}
for val in paramv[param]:
bpa_training = dict([[x, by_param[x]] for x in by_param if x[1][i] != val])
bpa_validation = dict([[x, by_param[x]] for x in by_param if x[1][i] == val])
to_pop = []
for name in by_name.keys():
if not any(map(lambda x : x[0] == name, bpa_training.keys())):
to_pop.append(name)
for name in to_pop:
by_name.pop(name, None)
ares = analyze(by_name, {}, bpa_training, by_trace, parameters)
for name in sorted(ares['state'].keys()):
state = ares['state'][name]
if 'function' in state['power']:
if 'user' in state['power']['function']:
xv_assess_function(name, state['power']['function']['user'], 'means', bpa_validation, user_mae, user_smape)
if 'estimate' in state['power']['function']:
xv_assess_function(name, state['power']['function']['estimate'], 'means', bpa_validation, estimate_mae, estimate_smape)
for name in sorted(ares['transition'].keys()):
trans = ares['transition'][name]
if 'timeout' in trans and 'function' in trans['timeout']:
if 'user' in trans['timeout']['function']:
xv_assess_function(name, trans['timeout']['function']['user'], 'timeouts', bpa_validation, user_mae, user_smape)
if 'estimate' in trans['timeout']['function']:
xv_assess_function(name, trans['timeout']['function']['estimate'], 'timeouts', bpa_validation, estimate_mae, estimate_smape)
for name in sorted(user_mae.keys()):
if by_name[name]['isa'] == 'state':
print('user function %s power by %s: MAE %.f µW, SMAPE %.2f%%' % (
name, param, np.mean(user_mae[name]), np.mean(user_smape[name])))
else:
print('user function %s timeout by %s: MAE %.f µs, SMAPE %.2f%%' % (
name, param, np.mean(user_mae[name]), np.mean(user_smape[name])))
for name in sorted(estimate_mae.keys()):
if by_name[name]['isa'] == 'state':
print('estimate function %s power by %s: MAE %.f µW, SMAPE %.2f%%' % (
name, param, np.mean(estimate_mae[name]), np.mean(estimate_smape[name])))
else:
print('estimate function %s timeout by %s: MAE %.f µs, SMAPE %.2f%%' % (
name, param, np.mean(estimate_mae[name]), np.mean(estimate_smape[name])))
def validate(by_name, by_param, parameters):
aggdata = {
'state' : {},
'transition' : {},
}
for key, val in by_name.items():
name = key
isa = val['isa']
model = data['model'][isa][name]
if isa == 'state':
aggdata[isa][name] = {
'power' : {
'goodness' : aggregate_measures(model['power']['static'], val['means']),
'median' : np.median(val['means']),
'mean' : np.mean(val['means']),
'std_inner' : np.std(val['means']),
'function' : {},
},
'online_power' : {
'goodness' : regression_measures(np.array(val['online_means']), np.array(val['means'])),
'median' : np.median(val['online_means']),
'mean' : np.mean(val['online_means']),
'std_inner' : np.std(val['online_means']),
'function' : {},
},
'online_duration' : {
'goodness' : regression_measures(np.array(val['online_durations']), np.array(val['durations'])),
'median' : np.median(val['online_durations']),
'mean' : np.mean(val['online_durations']),
'std_inner' : np.std(val['online_durations']),
'function' : {},
},
'clip' : {
'mean' : np.mean(val['clip_rate']),
'max' : max(val['clip_rate']),
},
'timeout' : {},
}
if 'function' in model['power']:
aggdata[isa][name]['power']['function'] = {
'estimate' : {
'fit' : assess_function(model['power']['function']['estimate'],
name, 'means', parameters, by_param),
},
'user': {
'fit' : assess_function(model['power']['function']['user'],
name, 'means', parameters, by_param),
},
}
if isa == 'transition':
aggdata[isa][name] = {
'duration' : {
'goodness' : aggregate_measures(model['duration']['static'], val['durations']),
'median' : np.median(val['durations']),
'mean' : np.mean(val['durations']),
'std_inner' : np.std(val['durations']),
'function' : {},
},
'energy' : {
'goodness' : aggregate_measures(model['energy']['static'], val['energies']),
'median' : np.median(val['energies']),
'mean' : np.mean(val['energies']),
'std_inner' : np.std(val['energies']),
'function' : {},
},
'rel_energy_prev' : {
'goodness' : aggregate_measures(model['rel_energy_prev']['static'], val['rel_energies_prev']),
'median' : np.median(val['rel_energies_prev']),
'mean' : np.mean(val['rel_energies_prev']),
'std_inner' : np.std(val['rel_energies_prev']),
'function' : {},
},
'rel_energy_next' : {
'goodness' : aggregate_measures(model['rel_energy_next']['static'], val['rel_energies_next']),
'median' : np.median(val['rel_energies_next']),
'mean' : np.mean(val['rel_energies_next']),
'std_inner' : np.std(val['rel_energies_next']),
'function' : {},
},
'clip' : {
'mean' : np.mean(val['clip_rate']),
'max' : max(val['clip_rate']),
},
'timeout' : {},
}
if 'function' in model['timeout']:
aggdata[isa][name]['timeout'] = {
'median' : np.median(val['timeouts']),
'mean' : np.mean(val['timeouts']),
'function': {
'estimate' : {
'fit' : assess_function(model['timeout']['function']['estimate'],
name, 'timeouts', parameters, by_param),
},
'user': {
'fit' : assess_function(model['timeout']['function']['user'],
name, 'timeouts', parameters, by_param),
},
},
}
return aggdata
def analyze_by_param(aggval, by_param, allvalues, name, key1, key2, param, param_idx):
aggval[key1]['std_by_param'][param] = mean_std_by_param(
by_param, allvalues, name, key2, param_idx)
if aggval[key1]['std_by_param'][param] > 0 and aggval[key1]['std_param'] / aggval[key1]['std_by_param'][param] < 0.6:
aggval[key1]['fit_guess'][param] = try_fits(name, key2, param_idx, by_param)
def analyze_by_arg(aggval, by_arg, allvalues, name, key1, key2, arg_name, arg_idx):
aggval[key1]['std_by_arg'][arg_name] = mean_std_by_arg(
by_arg, allvalues, name, key2, arg_idx)
if aggval[key1]['std_by_arg'][arg_name] > 0 and aggval[key1]['std_arg'] / aggval[key1]['std_by_arg'][arg_name] < 0.6:
aggval[key1]['arg_fit_guess'][arg_name] = try_fits(name, key2, arg_idx, by_arg)
def maybe_fit_function(aggval, model, by_param, parameters, name, key1, key2, unit):
if 'function' in model[key1] and 'user' in model[key1]['function']:
aggval[key1]['function']['user'] = {
'raw' : model[key1]['function']['user']['raw'],
'params' : model[key1]['function']['user']['params'],
}
fit_function(
aggval[key1]['function']['user'], name, key2, parameters, by_param,
yaxis='%s %s by param [%s]' % (name, key1, unit))
def analyze(by_name, by_arg, by_param, by_trace, parameters):
aggdata = {
'state' : {},
'transition' : {},
}
transition_names = list(map(lambda x: x[0], filter(lambda x: x[1]['isa'] == 'transition', by_name.items())))
for name, val in by_name.items():
isa = val['isa']
model = data['model'][isa][name]
aggdata[isa][name] = {
'power' : keydata(name, val, by_arg, by_param, by_trace, 'means'),
'duration' : keydata(name, val, by_arg, by_param, by_trace, 'durations'),
'energy' : keydata(name, val, by_arg, by_param, by_trace, 'energies'),
'clip' : {
'mean' : np.mean(val['clip_rate']),
'max' : max(val['clip_rate']),
},
'timeout' : {},
}
aggval = aggdata[isa][name]
aggval['power']['std_outer'] = np.mean(val['stds'])
if isa == 'transition':
aggval['rel_energy_prev'] = keydata(name, val, by_arg, by_param, by_trace, 'rel_energies_prev')
aggval['rel_energy_next'] = keydata(name, val, by_arg, by_param, by_trace, 'rel_energies_next')
aggval['timeout'] = keydata(name, val, by_arg, by_param, by_trace, 'timeouts')
for i, param in enumerate(sorted(data['model']['parameter'].keys())):
values = list(set([key[1][i] for key in by_param.keys() if key[0] == name and key[1][i] != '']))
allvalues = [(*key[1][:i], *key[1][i+1:]) for key in by_param.keys() if key[0] == name]
#allvalues = list(set(allvalues))
if len(values) > 1:
if isa == 'state':
analyze_by_param(aggval, by_param, allvalues, name, 'power', 'means', param, i)
else:
analyze_by_param(aggval, by_param, allvalues, name, 'duration', 'durations', param, i)
analyze_by_param(aggval, by_param, allvalues, name, 'energy', 'energies', param, i)
analyze_by_param(aggval, by_param, allvalues, name, 'rel_energy_prev', 'rel_energies_prev', param, i)
analyze_by_param(aggval, by_param, allvalues, name, 'rel_energy_next', 'rel_energies_next', param, i)
analyze_by_param(aggval, by_param, allvalues, name, 'timeout', 'timeouts', param, i)
if isa == 'state':
fguess_to_function(name, 'means', aggval['power'], parameters, by_param,
'estimated %s power by param [µW]' % name)
maybe_fit_function(aggval, model, by_param, parameters, name, 'power', 'means', 'µW')
if aggval['power']['std_param'] > 0 and aggval['power']['std_trace'] / aggval['power']['std_param'] < 0.5:
aggval['power']['std_by_trace'] = mean_std_by_trace_part(by_trace, transition_names, name, 'means')
else:
fguess_to_function(name, 'durations', aggval['duration'], parameters, by_param,
'estimated %s duration by param [µs]' % name)
fguess_to_function(name, 'energies', aggval['energy'], parameters, by_param,
'estimated %s energy by param [pJ]' % name)
fguess_to_function(name, 'rel_energies_prev', aggval['rel_energy_prev'], parameters, by_param,
'estimated relative_prev %s energy by param [pJ]' % name)
fguess_to_function(name, 'rel_energies_next', aggval['rel_energy_next'], parameters, by_param,
'estimated relative_next %s energy by param [pJ]' % name)
fguess_to_function(name, 'timeouts', aggval['timeout'], parameters, by_param,
'estimated %s timeout by param [µs]' % name)
maybe_fit_function(aggval, model, by_param, parameters, name, 'duration', 'durations', 'µs')
maybe_fit_function(aggval, model, by_param, parameters, name, 'energy', 'energies', 'pJ')
maybe_fit_function(aggval, model, by_param, parameters, name, 'rel_energy_prev', 'rel_energies_prev', 'pJ')
maybe_fit_function(aggval, model, by_param, parameters, name, 'rel_energy_next', 'rel_energies_next', 'pJ')
maybe_fit_function(aggval, model, by_param, parameters, name, 'timeout', 'timeouts', 'µs')
for i, arg in enumerate(model['parameters']):
values = list(set([key[1][i] for key in by_arg.keys() if key[0] == name and is_numeric(key[1][i])]))
allvalues = [(*key[1][:i], *key[1][i+1:]) for key in by_arg.keys() if key[0] == name]
analyze_by_arg(aggval, by_arg, allvalues, name, 'duration', 'durations', arg['name'], i)
analyze_by_arg(aggval, by_arg, allvalues, name, 'energy', 'energies', arg['name'], i)
analyze_by_arg(aggval, by_arg, allvalues, name, 'rel_energy_prev', 'rel_energies_prev', arg['name'], i)
analyze_by_arg(aggval, by_arg, allvalues, name, 'rel_energy_next', 'rel_energies_next', arg['name'], i)
analyze_by_arg(aggval, by_arg, allvalues, name, 'timeout', 'timeouts', arg['name'], i)
arguments = list(map(lambda x: x['name'], model['parameters']))
arg_fguess_to_function(name, 'durations', aggval['duration'], arguments, by_arg,
'estimated %s duration by arg [µs]' % name)
arg_fguess_to_function(name, 'energies', aggval['energy'], arguments, by_arg,
'estimated %s energy by arg [pJ]' % name)
arg_fguess_to_function(name, 'rel_energies_prev', aggval['rel_energy_prev'], arguments, by_arg,
'estimated relative_prev %s energy by arg [pJ]' % name)
arg_fguess_to_function(name, 'rel_energies_next', aggval['rel_energy_next'], arguments, by_arg,
'estimated relative_next %s energy by arg [pJ]' % name)
arg_fguess_to_function(name, 'timeouts', aggval['timeout'], arguments, by_arg,
'estimated %s timeout by arg [µs]' % name)
return aggdata
try:
raw_opts, args = getopt.getopt(sys.argv[1:], "", [
"fit", "states", "transitions", "params", "clipping", "timing",
"histogram", "substates", "validate", "crossvalidate", "ignore-trace-idx="])
for option, parameter in raw_opts:
optname = re.sub(r'^--', '', option)
opts[optname] = parameter
if 'ignore-trace-idx' in opts:
opts['ignore-trace-idx'] = int(opts['ignore-trace-idx'])
except getopt.GetoptError as err:
print(err)
sys.exit(2)
data = load_json(args[0])
by_name = {}
by_arg = {}
by_param = {}
by_trace = {}
parameters = sorted(data['model']['parameter'].keys())
for arg in args:
mdata = load_json(arg)
for runidx, run in enumerate(mdata['traces']):
if 'ignore-trace-idx' not in opts or opts['ignore-trace-idx'] != runidx:
for i, elem in enumerate(run['trace']):
if elem['name'] != 'UNINITIALIZED':
load_run_elem(i, elem, run['trace'], by_name, by_arg, by_param, by_trace)
if 'states' in opts:
if 'params' in opts:
plotter.plot_states_param(data['model'], by_param)
else:
plotter.plot_states(data['model'], by_name)
if 'timing' in opts:
plotter.plot_states_duration(data['model'], by_name)
plotter.plot_states_duration(data['model'], by_param)
if 'clipping' in opts:
plotter.plot_states_clips(data['model'], by_name)
if 'transitions' in opts:
plotter.plot_transitions(data['model'], by_name)
if 'timing' in opts:
plotter.plot_transitions_duration(data['model'], by_name)
plotter.plot_transitions_timeout(data['model'], by_param)
if 'clipping' in opts:
plotter.plot_transitions_clips(data['model'], by_name)
if 'histogram' in opts:
for key in sorted(by_name.keys()):
plotter.plot_histogram(by_name[key]['means'])
if 'substates' in opts:
if 'params' in opts:
plotter.plot_substate_thresholds_p(data['model'], by_param)
else:
plotter.plot_substate_thresholds(data['model'], by_name)
if 'validate' in opts:
data['aggregate'] = validate(by_name, by_param, parameters)
elif 'crossvalidate' in opts:
crossvalidate(by_name, by_param, by_trace, data['model'], parameters)
else:
data['aggregate'] = analyze(by_name, by_arg, by_param, by_trace, parameters)
# TODO optionally also plot data points for states/transitions which do not have
# a function, but may depend on a parameter (visualization is always good!)
save_json(data, args[0])
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