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|
#!/usr/bin/env python3
import csv
import io
import json
import numpy as np
import os
import re
from scipy import optimize
from sklearn.metrics import r2_score
import struct
import sys
import tarfile
from multiprocessing import Pool
from automata import PTA
from functions import analytic
from functions import AnalyticFunction
from utils import vprint, is_numeric, soft_cast_int, param_slice_eq, compute_param_statistics
arg_support_enabled = True
def running_mean(x: np.ndarray, N: int) -> np.ndarray:
"""
Compute running average.
arguments:
x -- NumPy array
N -- how many items to average
"""
cumsum = np.cumsum(np.insert(x, 0, 0))
return (cumsum[N:] - cumsum[:-N]) / N
def gplearn_to_function(function_str: str):
"""
Convert gplearn-style function string to Python function.
Takes a function string like "mul(add(X0, X1), X2)" and returns
a Python function implementing the specified behaviour,
e.g. "lambda x, y, z: (x + y) * z".
Supported functions:
add -- x + y
sub -- x - y
mul -- x * y
div -- x / y if |y| > 0.001, otherwise 1
sqrt -- sqrt(|x|)
log -- log(|x|) if |x| > 0.001, otherwise 0
inv -- 1 / x if |x| > 0.001, otherwise 0
"""
eval_globals = {
'add' : lambda x, y : x + y,
'sub' : lambda x, y : x - y,
'mul' : lambda x, y : x * y,
'div' : lambda x, y : np.divide(x, y) if np.abs(y) > 0.001 else 1.,
'sqrt': lambda x : np.sqrt(np.abs(x)),
'log' : lambda x : np.log(np.abs(x)) if np.abs(x) > 0.001 else 0.,
'inv' : lambda x : 1. / x if np.abs(x) > 0.001 else 0.,
}
last_arg_index = 0
for i in range(0, 100):
if function_str.find('X{:d}'.format(i)) >= 0:
last_arg_index = i
arg_list = []
for i in range(0, last_arg_index+1):
arg_list.append('X{:d}'.format(i))
eval_str = 'lambda {}, *whatever: {}'.format(','.join(arg_list), function_str)
print(eval_str)
return eval(eval_str, eval_globals)
def _arg_name(arg_index: int) -> str:
return '~arg{:02}'.format(arg_index)
def append_if_set(aggregate: dict, data: dict, key: str):
"""Append data[key] to aggregate if key in data."""
if key in data:
aggregate.append(data[key])
def mean_or_none(arr):
"""Compute mean of NumPy array arr, return -1 if empty."""
if len(arr):
return np.mean(arr)
return -1
def aggregate_measures(aggregate: float, actual: list) -> dict:
"""
Calculate error measures for model value on data list.
arguments:
aggregate -- model value (float or int)
actual -- real-world / reference values (list of float or int)
return value:
See regression_measures
"""
aggregate_array = np.array([aggregate] * len(actual))
return regression_measures(aggregate_array, np.array(actual))
def regression_measures(predicted: np.ndarray, actual: np.ndarray):
"""
Calculate error measures by comparing model values to reference values.
arguments:
predicted -- model values (np.ndarray)
actual -- real-world / reference values (np.ndarray)
Returns a dict containing the following measures:
mae -- Mean Absolute Error
mape -- Mean Absolute Percentage Error,
if all items in actual are non-zero (NaN otherwise)
smape -- Symmetric Mean Absolute Percentage Error,
if no 0,0-pairs are present in actual and predicted (NaN otherwise)
msd -- Mean Square Deviation
rmsd -- Root Mean Square Deviation
ssr -- Sum of Squared Residuals
rsq -- R^2 measure, see sklearn.metrics.r2_score
count -- Number of values
"""
if type(predicted) != np.ndarray:
raise ValueError('first arg must be ndarray, is {}'.format(type(predicted)))
if type(actual) != np.ndarray:
raise ValueError('second arg must be ndarray, is {}'.format(type(actual)))
deviations = predicted - actual
#mean = np.mean(actual)
if len(deviations) == 0:
return {}
measures = {
'mae' : np.mean(np.abs(deviations), dtype=np.float64),
'msd' : np.mean(deviations**2, dtype=np.float64),
'rmsd' : np.sqrt(np.mean(deviations**2), dtype=np.float64),
'ssr' : np.sum(deviations**2, dtype=np.float64),
'rsq' : r2_score(actual, predicted),
'count' : len(actual),
}
#rsq_quotient = np.sum((actual - mean)**2, dtype=np.float64) * np.sum((predicted - mean)**2, dtype=np.float64)
if np.all(actual != 0):
measures['mape'] = np.mean(np.abs(deviations / actual)) * 100 # bad measure
else:
measures['mape'] = np.nan
if np.all(np.abs(predicted) + np.abs(actual) != 0):
measures['smape'] = np.mean(np.abs(deviations) / (( np.abs(predicted) + np.abs(actual)) / 2 )) * 100
else:
measures['smape'] = np.nan
#if np.all(rsq_quotient != 0):
# measures['rsq'] = (np.sum((actual - mean) * (predicted - mean), dtype=np.float64)**2) / rsq_quotient
return measures
class KeysightCSV:
"""Simple loader for Keysight CSV data, as exported by the windows software."""
def __init__(self):
"""Create a new KeysightCSV object."""
pass
def load_data(self, filename: str):
"""
Load log data from filename, return timestamps and currents.
Returns two one-dimensional NumPy arrays: timestamps and corresponding currents.
"""
with open(filename) as f:
for i, _ in enumerate(f):
pass
timestamps = np.ndarray((i-3), dtype=float)
currents = np.ndarray((i-3), dtype=float)
# basically seek back to start
with open(filename) as f:
for _ in range(4):
next(f)
reader = csv.reader(f, delimiter=',')
for i, row in enumerate(reader):
timestamps[i] = float(row[0])
currents[i] = float(row[2]) * -1
return timestamps, currents
def by_name_to_by_param(by_name: dict):
"""
Convert aggregation by name to aggregation by name and parameter values.
"""
by_param = dict()
for name in by_name.keys():
for i, parameters in enumerate(by_name[name]['param']):
param_key = (name, tuple(parameters))
if param_key not in by_param:
by_param[param_key] = dict()
for key in by_name[name].keys():
by_param[param_key][key] = list()
by_param[param_key]['attributes'] = by_name[name]['attributes']
# special case for PTA models
if 'isa' in by_name[name]:
by_param[param_key]['isa'] = by_name[name]['isa']
for attribute in by_name[name]['attributes']:
by_param[param_key][attribute].append(by_name[name][attribute][i])
return by_param
def _xv_partitions_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 _xv_partition_montecarlo(length):
shuffled = np.random.permutation(np.arange(length))
border = int(length * float(2) / 3)
training = shuffled[:border]
validation = shuffled[border:]
return (training, validation)
class CrossValidator:
"""
Cross-Validation helper for model generation.
Given a set of measurements and a model class, it will partition the
data into training and validation sets, train the model on the training
set, and assess its quality on the validation set. This is repeated
several times depending on cross-validation algorithm and configuration.
Reports the mean model error over all cross-validation runs.
"""
def __init__(self, model_class, by_name, parameters, arg_count):
"""
Create a new CrossValidator object.
Does not perform cross-validation yet.
arguments:
model_class -- model class/type used for model synthesis,
e.g. PTAModel or AnalyticModel. model_class must have a
constructor accepting (by_name, parameters, arg_count, verbose = False)
and provide an assess method.
by_name -- measurements aggregated by state/transition/function/... name.
Layout: by_name[name][attribute] = list of data. Additionally,
by_name[name]['attributes'] must be set to the list of attributes,
e.g. ['power'] or ['duration', 'energy'].
"""
self.model_class = model_class
self.by_name = by_name
self.names = sorted(by_name.keys())
self.parameters = sorted(parameters)
self.arg_count = arg_count
def montecarlo(self, model_getter, count = 200):
"""
Perform Monte Carlo cross-validation and return average model quality.
The by_name data is randomly divided into 2/3 training and 1/3
validation. After creating a model for the training set, the
model type returned by model_getter is evaluated on the validation set.
This is repeated count times (defaulting to 200); the average of all
measures is returned to the user.
arguments:
model_getter -- function with signature (model_object) -> model,
e.g. lambda m: m.get_fitted()[0] to evaluate the parameter-aware
model with automatic parameter detection.
count -- number of validation runs to perform, defaults to 200
return value:
dict of model quality measures.
{
'by_name' : {
for each name: {
for each attribute: {
'mae' : mean of all mean absolute errors
'mae_list' : list of the individual MAE values encountered during cross-validation
'smape' : mean of all symmetric mean absolute percentage errors
'smape_list' : list of the individual SMAPE values encountered during cross-validation
}
}
}
}
"""
ret = {
'by_name' : dict()
}
for name in self.names:
ret['by_name'][name] = dict()
for attribute in self.by_name[name]['attributes']:
ret['by_name'][name][attribute] = {
'mae_list': list(),
'smape_list': list()
}
for _ in range(count):
res = self._single_montecarlo(model_getter)
for name in self.names:
for attribute in self.by_name[name]['attributes']:
ret['by_name'][name][attribute]['mae_list'].append(res['by_name'][name][attribute]['mae'])
ret['by_name'][name][attribute]['smape_list'].append(res['by_name'][name][attribute]['smape'])
for name in self.names:
for attribute in self.by_name[name]['attributes']:
ret['by_name'][name][attribute]['mae'] = np.mean(ret['by_name'][name][attribute]['mae_list'])
ret['by_name'][name][attribute]['smape'] = np.mean(ret['by_name'][name][attribute]['smape_list'])
return ret
def _single_montecarlo(self, model_getter):
training = dict()
validation = dict()
for name in self.names:
training[name] = {
'attributes' : self.by_name[name]['attributes']
}
validation[name] = {
'attributes' : self.by_name[name]['attributes']
}
if 'isa' in self.by_name[name]:
training[name]['isa'] = self.by_name[name]['isa']
validation[name]['isa'] = self.by_name[name]['isa']
data_count = len(self.by_name[name]['param'])
training_subset, validation_subset = _xv_partition_montecarlo(data_count)
for attribute in self.by_name[name]['attributes']:
self.by_name[name][attribute] = np.array(self.by_name[name][attribute])
training[name][attribute] = self.by_name[name][attribute][training_subset]
validation[name][attribute] = self.by_name[name][attribute][validation_subset]
# We can't use slice syntax for 'param', which may contain strings and other odd values
training[name]['param'] = list()
validation[name]['param'] = list()
for idx in training_subset:
training[name]['param'].append(self.by_name[name]['param'][idx])
for idx in validation_subset:
validation[name]['param'].append(self.by_name[name]['param'][idx])
training_data = self.model_class(training, self.parameters, self.arg_count, verbose = False)
training_model = model_getter(training_data)
validation_data = self.model_class(validation, self.parameters, self.arg_count, verbose = False)
return validation_data.assess(training_model)
def _preprocess_measurement(measurement):
setup = measurement['setup']
mim = MIMOSA(float(setup['mimosa_voltage']), int(setup['mimosa_shunt']))
charges, triggers = mim.load_data(measurement['content'])
trigidx = mim.trigger_edges(triggers)
triggers = []
cal_edges = mim.calibration_edges(running_mean(mim.currents_nocal(charges[0:trigidx[0]]), 10))
calfunc, caldata = mim.calibration_function(charges, cal_edges)
vcalfunc = np.vectorize(calfunc, otypes=[np.float64])
processed_data = {
'fileno' : measurement['fileno'],
'info' : measurement['info'],
'triggers' : len(trigidx),
'first_trig' : trigidx[0] * 10,
'calibration' : caldata,
'trace' : mim.analyze_states(charges, trigidx, vcalfunc)
}
return processed_data
class ParamStats:
def __init__(self, by_name, by_param, parameter_names, arg_count, use_corrcoef = False, verbose = False):
"""
Compute standard deviation and correlation coefficient on parameterized data partitions.
It is strongly recommended to vary all parameter values evenly.
For instance, given two parameters, providing only the combinations
(1, 1), (5, 1), (7, 1,) (10, 1), (1, 2), (1, 6) will lead to bogus results.
It is better to provide (1, 1), (5, 1), (1, 2), (5, 2), ... (i.e. a cross product of all individual parameter values)
arguments:
by_name -- ground truth partitioned by state/transition name.
by_name[state_or_trans][attribute] must be a list or 1-D numpy array.
by_name[state_or_trans]['param'] must be a list of parameter values
corresponding to the ground truth, e.g. [[1, 2, 3], ...] if the
first ground truth element has the (lexically) first parameter set to 1,
the second to 2 and the third to 3.
by_param -- ground truth partitioned by state/transition name and parameters.
by_name[(state_or_trans, *)][attribute] must be a list or 1-D numpy array.
parameter_names -- list of parameter names, must have the same order as the parameter
values in by_param (lexical sorting is recommended).
arg_count -- dict providing the number of functions args ("local parameters") for each function.
use_corrcoef -- use correlation coefficient instead of stddev heuristic for parameter detection
"""
self.stats = dict()
self.use_corrcoef = use_corrcoef
# Note: This is deliberately single-threaded. The overhead incurred
# by multiprocessing is higher than the speed gained by parallel
# computation of statistics measures.
for state_or_tran in by_name.keys():
self.stats[state_or_tran] = dict()
for attribute in by_name[state_or_tran]['attributes']:
self.stats[state_or_tran][attribute] = compute_param_statistics(by_name, by_param, parameter_names, arg_count, state_or_tran, attribute, verbose = verbose)
def _generic_param_independence_ratio(self, state_or_trans, attribute):
"""
Return the heuristic ratio of parameter independence for state_or_trans and attribute.
This is not supported if the correlation coefficient is used.
A value close to 1 means no influence, a value close to 0 means high probability of influence.
"""
statistics = self.stats[state_or_trans][attribute]
if self.use_corrcoef:
# not supported
raise ValueError
if statistics['std_static'] == 0:
return 0
return statistics['std_param_lut'] / statistics['std_static']
def generic_param_dependence_ratio(self, state_or_trans, attribute):
"""
Return the heuristic ratio of parameter dependence for state_or_trans and attribute.
This is not supported if the correlation coefficient is used.
A value close to 0 means no influence, a value close to 1 means high probability of influence.
"""
return 1 - self._generic_param_independence_ratio(state_or_trans, attribute)
def _param_independence_ratio(self, state_or_trans, attribute, param):
"""
Return the heuristic ratio of parameter independence for state_or_trans, attribute, and param.
A value close to 1 means no influence, a value close to 0 means high probability of influence.
"""
statistics = self.stats[state_or_trans][attribute]
if self.use_corrcoef:
return 1 - np.abs(statistics['corr_by_param'][param])
if statistics['std_by_param'][param] == 0:
if statistics['std_param_lut'] != 0:
raise RuntimeError("wat")
# In general, std_param_lut < std_by_param. So, if std_by_param == 0, std_param_lut == 0 follows.
# This means that the variation of param does not affect the model quality -> no influence, return 1
return 1
return statistics['std_param_lut'] / statistics['std_by_param'][param]
def param_dependence_ratio(self, state_or_trans, attribute, param):
"""
Return the heuristic ratio of parameter dependence for state_or_trans, attribute, and param.
A value close to 0 means no influence, a value close to 1 means high probability of influence.
"""
return 1 - self._param_independence_ratio(state_or_trans, attribute, param)
def _arg_independence_ratio(self, state_or_trans, attribute, arg_index):
statistics = self.stats[state_or_trans][attribute]
if self.use_corrcoef:
return 1 - np.abs(statistics['corr_by_arg'][arg_index])
if statistics['std_by_arg'][arg_index] == 0:
if statistics['std_param_lut'] != 0:
raise RuntimeError("wat")
# In general, std_param_lut < std_by_arg. So, if std_by_arg == 0, std_param_lut == 0 follows.
# This means that the variation of arg does not affect the model quality -> no influence, return 1
return 1
return statistics['std_param_lut'] / statistics['std_by_arg'][arg_index]
def arg_dependence_ratio(self, state_or_trans, attribute, arg_index):
return 1 - self._arg_independence_ratio(state_or_trans, attribute, arg_index)
# This heuristic is very similar to the "function is not much better than
# median" checks in get_fitted. So far, doing it here as well is mostly
# a performance and not an algorithm quality decision.
# --df, 2018-04-18
def depends_on_param(self, state_or_trans, attribute, param):
"""Return whether attribute of state_or_trans depens on param."""
if self.use_corrcoef:
return self.param_dependence_ratio(state_or_trans, attribute, param) > 0.1
else:
return self.param_dependence_ratio(state_or_trans, attribute, param) > 0.5
# See notes on depends_on_param
def depends_on_arg(self, state_or_trans, attribute, arg_index):
"""Return whether attribute of state_or_trans depens on arg_index."""
if self.use_corrcoef:
return self.arg_dependence_ratio(state_or_trans, attribute, arg_index) > 0.1
else:
return self.arg_dependence_ratio(state_or_trans, attribute, arg_index) > 0.5
class TimingData:
"""
Loader for timing model traces measured with on-board timers using ``harness.OnboardTimerHarness``.
Excpets a specific trace format and UART log output (as produced by
generate-dfa-benchmark.py). Prunes states from output. (TODO)
"""
def __init__(self, filenames):
"""
Create a new TimingData object.
Each filenames element corresponds to a measurement run.
"""
self.filenames = filenames.copy()
self.traces_by_fileno = []
self.setup_by_fileno = []
self.preprocessed = False
self._parameter_names = None
self.version = 0
def _concatenate_analyzed_traces(self):
self.traces = []
for trace_group in self.traces_by_fileno:
for trace in trace_group:
# TimingHarness logs states, but does not aggregate any data for them at the moment -> throw all states away
transitions = list(filter(lambda x: x['isa'] == 'transition', trace['trace']))
self.traces.append({
'id' : trace['id'],
'trace': transitions,
})
for i, trace in enumerate(self.traces):
trace['orig_id'] = trace['id']
trace['id'] = i
for log_entry in trace['trace']:
paramkeys = sorted(log_entry['parameter'].keys())
paramvalues = [soft_cast_int(log_entry['parameter'][x]) for x in paramkeys]
if not 'param' in log_entry['offline_aggregates']:
log_entry['offline_aggregates']['param'] = list()
if 'duration' in log_entry['offline_aggregates']:
for i in range(len(log_entry['offline_aggregates']['duration'])):
log_entry['offline_aggregates']['param'].append(paramvalues)
def _preprocess_0(self):
for filename in self.filenames:
with open(filename, 'r') as f:
log_data = json.load(f)
self.traces_by_fileno.append(log_data['traces'])
self._concatenate_analyzed_traces()
def get_preprocessed_data(self, verbose = True):
"""
Return a list of DFA traces annotated with timing, and parameter data.
Suitable for the PTAModel constructor.
See PTAModel(...) docstring for format details.
"""
self.verbose = verbose
if self.preprocessed:
return self.traces
if self.version == 0:
self._preprocess_0()
self.preprocessed = True
return self.traces
def sanity_check_aggregate(aggregate):
for key in aggregate:
if not 'param' in aggregate[key]:
raise RuntimeError('aggregate[{}][param] does not exist'.format(key))
if not 'attributes' in aggregate[key]:
raise RuntimeError('aggregate[{}][attributes] does not exist'.format(key))
for attribute in aggregate[key]['attributes']:
if not attribute in aggregate[key]:
raise RuntimeError('aggregate[{}][{}] does not exist, even though it is contained in aggregate[{}][attributes]'.format(key, attribute, key))
param_len = len(aggregate[key]['param'])
attr_len = len(aggregate[key][attribute])
if param_len != attr_len:
raise RuntimeError('parameter mismatch: len(aggregate[{}][param]) == {} != len(aggregate[{}][{}]) == {}'.format(key, param_len, key, attribute, attr_len))
class RawData:
"""
Loader for hardware model traces measured with MIMOSA.
Expects a specific trace format and UART log output (as produced by the
dfatool benchmark generator). Loads data, prunes bogus measurements, and
provides preprocessed data suitable for PTAModel.
"""
def __init__(self, filenames):
"""
Create a new RawData object.
Each filename element corresponds to a measurement run.
"""
self.filenames = filenames.copy()
self.traces_by_fileno = []
self.setup_by_fileno = []
self.version = 0
self.preprocessed = False
self._parameter_names = None
def _state_is_too_short(self, online, offline, state_duration, next_transition):
# We cannot control when an interrupt causes a state to be left
if next_transition['plan']['level'] == 'epilogue':
return False
# Note: state_duration is stored as ms, not us
return offline['us'] < state_duration * 500
def _state_is_too_long(self, online, offline, state_duration, prev_transition):
# If the previous state was left by an interrupt, we may have some
# waiting time left over. So it's okay if the current state is longer
# than expected.
if prev_transition['plan']['level'] == 'epilogue':
return False
# state_duration is stored as ms, not us
return offline['us'] > state_duration * 1500
def _measurement_is_valid(self, processed_data):
setup = self.setup_by_fileno[processed_data['fileno']]
traces = self.traces_by_fileno[processed_data['fileno']]
state_duration = setup['state_duration']
# Check trigger count
sched_trigger_count = 0
for run in traces:
sched_trigger_count += len(run['trace'])
if sched_trigger_count != processed_data['triggers']:
processed_data['error'] = 'got {got:d} trigger edges, expected {exp:d}'.format(
got = processed_data['triggers'],
exp = sched_trigger_count
)
return False
# Check state durations. Very short or long states can indicate a
# missed trigger signal which wasn't detected due to duplicate
# triggers elsewhere
online_datapoints = []
for run_idx, run in enumerate(traces):
for trace_part_idx in range(len(run['trace'])):
online_datapoints.append((run_idx, trace_part_idx))
for offline_idx, online_ref in enumerate(online_datapoints):
online_run_idx, online_trace_part_idx = online_ref
offline_trace_part = processed_data['trace'][offline_idx]
online_trace_part = traces[online_run_idx]['trace'][online_trace_part_idx]
if self._parameter_names == None:
self._parameter_names = sorted(online_trace_part['parameter'].keys())
if sorted(online_trace_part['parameter'].keys()) != self._parameter_names:
processed_data['error'] = 'Offline #{off_idx:d} (online {on_name:s} @ {on_idx:d}/{on_sub:d}) has inconsistent paramete set: should be {param_want:s}, is {param_is:s}'.format(
off_idx = offline_idx, on_idx = online_run_idx,
on_sub = online_trace_part_idx,
on_name = online_trace_part['name'],
param_want = self._parameter_names,
param_is = sorted(online_trace_part['parameter'].keys())
)
if online_trace_part['isa'] != offline_trace_part['isa']:
processed_data['error'] = 'Offline #{off_idx:d} (online {on_name:s} @ {on_idx:d}/{on_sub:d}) claims to be {off_isa:s}, but should be {on_isa:s}'.format(
off_idx = offline_idx, on_idx = online_run_idx,
on_sub = online_trace_part_idx,
on_name = online_trace_part['name'],
off_isa = offline_trace_part['isa'],
on_isa = online_trace_part['isa'])
return False
# Clipping in UNINITIALIZED (offline_idx == 0) can happen during
# calibration and is handled by MIMOSA
if offline_idx != 0 and offline_trace_part['clip_rate'] != 0:
processed_data['error'] = 'Offline #{off_idx:d} (online {on_name:s} @ {on_idx:d}/{on_sub:d}) was clipping {clip:f}% of the time'.format(
off_idx = offline_idx, on_idx = online_run_idx,
on_sub = online_trace_part_idx,
on_name = online_trace_part['name'],
clip = offline_trace_part['clip_rate'] * 100,
)
return False
if online_trace_part['isa'] == 'state' and online_trace_part['name'] != 'UNINITIALIZED':
online_prev_transition = traces[online_run_idx]['trace'][online_trace_part_idx-1]
online_next_transition = traces[online_run_idx]['trace'][online_trace_part_idx+1]
try:
if self._state_is_too_short(online_trace_part, offline_trace_part, state_duration, online_next_transition):
processed_data['error'] = 'Offline #{off_idx:d} (online {on_name:s} @ {on_idx:d}/{on_sub:d}) is too short (duration = {dur:d} us)'.format(
off_idx = offline_idx, on_idx = online_run_idx,
on_sub = online_trace_part_idx,
on_name = online_trace_part['name'],
dur = offline_trace_part['us'])
return False
if self._state_is_too_long(online_trace_part, offline_trace_part, state_duration, online_prev_transition):
processed_data['error'] = 'Offline #{off_idx:d} (online {on_name:s} @ {on_idx:d}/{on_sub:d}) is too long (duration = {dur:d} us)'.format(
off_idx = offline_idx, on_idx = online_run_idx,
on_sub = online_trace_part_idx,
on_name = online_trace_part['name'],
dur = offline_trace_part['us'])
return False
except KeyError:
pass
# TODO es gibt next_transitions ohne 'plan'
return True
def _merge_measurement_into_online_data(self, measurement):
online_datapoints = []
traces = self.traces_by_fileno[measurement['fileno']]
for run_idx, run in enumerate(traces):
for trace_part_idx in range(len(run['trace'])):
online_datapoints.append((run_idx, trace_part_idx))
for offline_idx, online_ref in enumerate(online_datapoints):
online_run_idx, online_trace_part_idx = online_ref
offline_trace_part = measurement['trace'][offline_idx]
online_trace_part = traces[online_run_idx]['trace'][online_trace_part_idx]
if not 'offline' in online_trace_part:
online_trace_part['offline'] = [offline_trace_part]
else:
online_trace_part['offline'].append(offline_trace_part)
paramkeys = sorted(online_trace_part['parameter'].keys())
paramvalue = [soft_cast_int(online_trace_part['parameter'][x]) for x in paramkeys]
# NB: Unscheduled transitions do not have an 'args' field set.
# However, they should only be caused by interrupts, and
# interrupts don't have args anyways.
if arg_support_enabled and 'args' in online_trace_part:
paramvalue.extend(map(soft_cast_int, online_trace_part['args']))
if not 'offline_aggregates' in online_trace_part:
online_trace_part['offline_attributes'] = ['power', 'duration', 'energy']
online_trace_part['offline_aggregates'] = {
'power' : [],
'duration' : [],
'power_std' : [],
'energy' : [],
'paramkeys' : [],
'param': [],
}
if online_trace_part['isa'] == 'transition':
online_trace_part['offline_attributes'].extend(['rel_energy_prev', 'rel_energy_next', 'timeout'])
online_trace_part['offline_aggregates']['rel_energy_prev'] = []
online_trace_part['offline_aggregates']['rel_energy_next'] = []
online_trace_part['offline_aggregates']['timeout'] = []
# Note: All state/transitions are 20us "too long" due to injected
# active wait states. These are needed to work around MIMOSA's
# relatively low sample rate of 100 kHz (10us) and removed here.
online_trace_part['offline_aggregates']['power'].append(
offline_trace_part['uW_mean'])
online_trace_part['offline_aggregates']['duration'].append(
offline_trace_part['us'] - 20)
online_trace_part['offline_aggregates']['power_std'].append(
offline_trace_part['uW_std'])
online_trace_part['offline_aggregates']['energy'].append(
offline_trace_part['uW_mean'] * (offline_trace_part['us'] - 20))
online_trace_part['offline_aggregates']['paramkeys'].append(paramkeys)
online_trace_part['offline_aggregates']['param'].append(paramvalue)
if online_trace_part['isa'] == 'transition':
online_trace_part['offline_aggregates']['rel_energy_prev'].append(
offline_trace_part['uW_mean_delta_prev'] * (offline_trace_part['us'] - 20))
online_trace_part['offline_aggregates']['rel_energy_next'].append(
offline_trace_part['uW_mean_delta_next'] * (offline_trace_part['us'] - 20))
online_trace_part['offline_aggregates']['timeout'].append(
offline_trace_part['timeout'])
def _concatenate_analyzed_traces(self):
self.traces = []
for trace in self.traces_by_fileno:
self.traces.extend(trace)
for i, trace in enumerate(self.traces):
trace['orig_id'] = trace['id']
trace['id'] = i
def get_preprocessed_data(self, verbose = True):
"""
Return a list of DFA traces annotated with energy, timing, and parameter data.
Suitable for the PTAModel constructor.
See PTAModel(...) docstring for format details.
"""
self.verbose = verbose
if self.preprocessed:
return self.traces
if self.version == 0:
self._preprocess_0()
self.preprocessed = True
return self.traces
def _preprocess_0(self):
"""Load raw MIMOSA data and turn it into measurements which are ready to be analyzed."""
mim_files = []
for i, filename in enumerate(self.filenames):
with tarfile.open(filename) as tf:
self.setup_by_fileno.append(json.load(tf.extractfile('setup.json')))
self.traces_by_fileno.append(json.load(tf.extractfile('src/apps/DriverEval/DriverLog.json')))
for member in tf.getmembers():
_, extension = os.path.splitext(member.name)
if extension == '.mim':
mim_files.append({
'content' : tf.extractfile(member).read(),
'fileno' : i,
'info' : member,
'setup' : self.setup_by_fileno[i],
'traces' : self.traces_by_fileno[i],
})
with Pool() as pool:
measurements = pool.map(_preprocess_measurement, mim_files)
num_valid = 0
for measurement in measurements:
if self._measurement_is_valid(measurement):
self._merge_measurement_into_online_data(measurement)
num_valid += 1
else:
vprint(self.verbose, '[W] Skipping {ar:s}/{m:s}: {e:s}'.format(
ar = self.filenames[measurement['fileno']],
m = measurement['info'].name,
e = measurement['error']))
vprint(self.verbose, '[I] {num_valid:d}/{num_total:d} measurements are valid'.format(
num_valid = num_valid,
num_total = len(measurements)))
self._concatenate_analyzed_traces()
self.preprocessing_stats = {
'num_runs' : len(measurements),
'num_valid' : num_valid
}
class ParallelParamFit:
"""
Fit a set of functions on parameterized measurements.
One parameter is variale, all others are fixed. Reports the best-fitting
function type for each parameter.
"""
def __init__(self, by_param):
"""Create a new ParallelParamFit object."""
self.fit_queue = []
self.by_param = by_param
def enqueue(self, state_or_tran, attribute, param_index, param_name, safe_functions_enabled = False):
"""
Add state_or_tran/attribute/param_name to fit queue.
This causes fit() to compute the best-fitting function for this model part.
"""
self.fit_queue.append({
'key' : [state_or_tran, attribute, param_name],
'args' : [self.by_param, state_or_tran, attribute, param_index, safe_functions_enabled]
})
def fit(self):
"""
Fit functions on previously enqueue data.
Fitting is one in parallel with one process per core.
Results can be accessed using the public ParallelParamFit.results object.
"""
with Pool() as pool:
self.results = pool.map(_try_fits_parallel, self.fit_queue)
def _try_fits_parallel(arg):
return {
'key' : arg['key'],
'result' : _try_fits(*arg['args'])
}
def _try_fits(by_param, state_or_tran, model_attribute, param_index, safe_functions_enabled = False):
functions = analytic.functions(safe_functions_enabled = safe_functions_enabled)
for param_key in filter(lambda x: x[0] == state_or_tran, by_param.keys()):
# We might remove elements from 'functions' while iterating over
# its keys. A generator will not allow this, so we need to
# convert to a list.
function_names = list(functions.keys())
for function_name in function_names:
function_object = functions[function_name]
if is_numeric(param_key[1][param_index]) and not function_object.is_valid(param_key[1][param_index]):
functions.pop(function_name, None)
raw_results = {}
ref_results = {
'mean' : [],
'median' : []
}
results = {}
for param_key in filter(lambda x: x[0] == state_or_tran, by_param.keys()):
X = []
Y = []
num_valid = 0
num_total = 0
for k, v in by_param.items():
if param_slice_eq(k, param_key, param_index):
num_total += 1
if is_numeric(k[1][param_index]):
num_valid += 1
X.extend([float(k[1][param_index])] * len(v[model_attribute]))
Y.extend(v[model_attribute])
if num_valid > 2:
X = np.array(X)
Y = np.array(Y)
for function_name, param_function in functions.items():
raw_results[function_name] = {}
error_function = param_function.error_function
res = optimize.least_squares(error_function, [0, 1], args=(X, Y), xtol=2e-15)
measures = regression_measures(param_function.eval(res.x, X), Y)
for measure, error_rate in measures.items():
if not measure in raw_results[function_name]:
raw_results[function_name][measure] = []
raw_results[function_name][measure].append(error_rate)
#print(function_name, res, measures)
mean_measures = aggregate_measures(np.mean(Y), Y)
ref_results['mean'].append(mean_measures['rmsd'])
median_measures = aggregate_measures(np.median(Y), Y)
ref_results['median'].append(median_measures['rmsd'])
if not len(ref_results['mean']):
# Insufficient data for fitting
return {
'best' : None,
'best_rmsd' : np.inf,
'results' : results,
}
best_fit_val = np.inf
best_fit_name = None
for function_name, result in raw_results.items():
if len(result) > 0:
results[function_name] = {}
for measure in result.keys():
results[function_name][measure] = np.mean(result[measure])
rmsd = results[function_name]['rmsd']
if rmsd < best_fit_val:
best_fit_val = rmsd
best_fit_name = function_name
return {
'best' : best_fit_name,
'best_rmsd' : best_fit_val,
'mean_rmsd' : np.mean(ref_results['mean']),
'median_rmsd' : np.mean(ref_results['median']),
'results' : results
}
def _num_args_from_by_name(by_name):
num_args = dict()
for key, value in by_name.items():
if 'args' in value:
num_args[key] = len(value['args'][0])
return num_args
class AnalyticModel:
u"""
Parameter-aware analytic energy/data size/... model.
Supports both static and parameter-based model attributes, and automatic detection of parameter-dependence.
The model heavily relies on two internal data structures:
PTAModel.by_name and PTAModel.by_param.
These provide measurements aggregated by (function/state/...) name
and (for by_param) parameter values. Layout:
dictionary with one key per name ('send', 'TX', ...) or
one key per name and parameter combination
(('send', (1, 2)), ('send', (2, 3)), ('TX', (1, 2)), ('TX', (2, 3)), ...).
Parameter values must be ordered corresponding to the lexically sorted parameter names.
Each element is in turn a dict with the following elements:
- param: list of parameter values in each measurement (-> list of lists)
- attributes: list of keys that should be analyzed,
e.g. ['power', 'duration']
- for each attribute mentioned in 'attributes': A list with measurements.
All list except for 'attributes' must have the same length.
For example:
parameters = ['foo_count', 'irrelevant']
by_name = {
'foo' : [1, 1, 2],
'bar' : [5, 6, 7],
'attributes' : ['foo', 'bar'],
'param' : [[1, 0], [1, 0], [2, 0]]
}
methods:
get_static -- return static (parameter-unaware) model.
get_param_lut -- return parameter-aware look-up-table model. Cannot model parameter combinations not present in by_param.
get_fitted -- return parameter-aware model using fitted functions for behaviour prediction.
variables:
names -- function/state/... names (i.e., the keys of by_name)
parameters -- parameter names
stats -- ParamStats object providing parameter-dependency statistics for each name and attribute
assess -- calculate model quality
"""
def __init__(self, by_name, parameters, verbose = True):
"""Create a new AnalyticModel and compute parameter statistics."""
self.cache = dict()
self.by_name = by_name
self.by_param = by_name_to_by_param(by_name)
self.names = sorted(by_name.keys())
self.parameters = sorted(parameters)
self.verbose = verbose
self._num_args = _num_args_from_by_name(by_name)
self.stats = ParamStats(self.by_name, self.by_param, self.parameters, self._num_args, verbose = verbose)
def _get_model_from_dict(self, model_dict, model_function):
model = {}
for name, elem in model_dict.items():
model[name] = {}
for key in elem['attributes']:
try:
model[name][key] = model_function(elem[key])
except RuntimeWarning:
vprint(self.verbose, '[W] Got no data for {} {}'.format(name, key))
except FloatingPointError as fpe:
vprint(self.verbose, '[W] Got no data for {} {}: {}'.format(name, key, fpe))
return model
def get_static(self):
"""
Get static model function: name, attribute -> model value.
Uses the median of by_name for modeling.
"""
static_model = self._get_model_from_dict(self.by_name, np.median)
def static_median_getter(name, key, **kwargs):
return static_model[name][key]
return static_median_getter
def get_static_using_mean(self):
"""
Get static model function: name, attribute -> model value.
Uses the mean of by_name for modeling.
"""
static_model = self._get_model_from_dict(self.by_name, np.mean)
def static_mean_getter(name, key, **kwargs):
return static_model[name][key]
return static_mean_getter
def get_param_lut(self, fallback = False):
"""
Get parameter-look-up-table model function: name, attribute, parameter values -> model value.
The function can only give model values for parameter combinations
present in by_param. By default, it raises KeyError for other values.
arguments:
fallback -- Fall back to the (non-parameter-aware) static model when encountering unknown parameter values
"""
static_model = self._get_model_from_dict(self.by_name, np.median)
lut_model = self._get_model_from_dict(self.by_param, np.median)
def lut_median_getter(name, key, param, arg = [], **kwargs):
param.extend(map(soft_cast_int, arg))
try:
return lut_model[(name, tuple(param))][key]
except KeyError:
if fallback:
return static_model[name][key]
raise
return lut_median_getter
def get_fitted(self, safe_functions_enabled = False):
"""
Get paramete-aware model function and model information function.
Returns two functions:
model_function(name, attribute, param=parameter values) -> model value.
model_info(name, attribute) -> {'fit_result' : ..., 'function' : ... } or None
"""
if 'fitted_model_getter' in self.cache and 'fitted_info_getter' in self.cache:
return self.cache['fitted_model_getter'], self.cache['fitted_info_getter']
static_model = self._get_model_from_dict(self.by_name, np.median)
param_model = dict([[name, {}] for name in self.by_name.keys()])
paramfit = ParallelParamFit(self.by_param)
for name in self.by_name.keys():
for attribute in self.by_name[name]['attributes']:
for param_index, param in enumerate(self.parameters):
if self.stats.depends_on_param(name, attribute, param):
paramfit.enqueue(name, attribute, param_index, param, False)
if arg_support_enabled and name in self._num_args:
for arg_index in range(self._num_args[name]):
if self.stats.depends_on_arg(name, attribute, arg_index):
paramfit.enqueue(name, attribute, len(self.parameters) + arg_index, arg_index, False)
paramfit.fit()
for name in self.by_name.keys():
num_args = 0
if name in self._num_args:
num_args = self._num_args[name]
for attribute in self.by_name[name]['attributes']:
fit_result = {}
for result in paramfit.results:
if result['key'][0] == name and result['key'][1] == attribute and result['result']['best'] != None:
this_result = result['result']
if this_result['best_rmsd'] >= min(this_result['mean_rmsd'], this_result['median_rmsd']):
vprint(self.verbose, '[I] Not modeling {} {} as function of {}: best ({:.0f}) is worse than ref ({:.0f}, {:.0f})'.format(
name, attribute, result['key'][2], this_result['best_rmsd'],
this_result['mean_rmsd'], this_result['median_rmsd']))
# See notes on depends_on_param
elif this_result['best_rmsd'] >= 0.8 * min(this_result['mean_rmsd'], this_result['median_rmsd']):
vprint(self.verbose, '[I] Not modeling {} {} as function of {}: best ({:.0f}) is not much better than ({:.0f}, {:.0f})'.format(
name, attribute, result['key'][2], this_result['best_rmsd'],
this_result['mean_rmsd'], this_result['median_rmsd']))
else:
fit_result[result['key'][2]] = this_result
if len(fit_result.keys()):
x = analytic.function_powerset(fit_result, self.parameters, num_args)
x.fit(self.by_param, name, attribute)
if x.fit_success:
param_model[name][attribute] = {
'fit_result': fit_result,
'function' : x
}
def model_getter(name, key, **kwargs):
if 'arg' in kwargs and 'param' in kwargs:
kwargs['param'].extend(map(soft_cast_int, kwargs['arg']))
if key in param_model[name]:
param_list = kwargs['param']
param_function = param_model[name][key]['function']
if param_function.is_predictable(param_list):
return param_function.eval(param_list)
return static_model[name][key]
def info_getter(name, key):
if key in param_model[name]:
return param_model[name][key]
return None
self.cache['fitted_model_getter'] = model_getter
self.cache['fitted_info_getter'] = info_getter
return model_getter, info_getter
def assess(self, model_function):
"""
Calculate MAE, SMAPE, etc. of model_function for each by_name entry.
state/transition/... name and parameter values are fed into model_function.
The by_name entries of this AnalyticModel are used as ground truth and
compared with the values predicted by model_function.
For proper model assessments, the data used to generate model_function
and the data fed into this AnalyticModel instance must be mutually
exclusive (e.g. by performing cross validation). Otherwise,
overfitting cannot be detected.
"""
detailed_results = {}
for name, elem in sorted(self.by_name.items()):
detailed_results[name] = {}
for attribute in elem['attributes']:
predicted_data = np.array(list(map(lambda i: model_function(name, attribute, param=elem['param'][i]), range(len(elem[attribute])))))
measures = regression_measures(predicted_data, elem[attribute])
detailed_results[name][attribute] = measures
return {
'by_name' : detailed_results,
}
def to_json(self):
# TODO
pass
def _add_trace_data_to_aggregate(aggregate, key, element):
# Only cares about element['isa'], element['offline_aggregates'], and
# element['plan']['level']
if not key in aggregate:
aggregate[key] = {
'isa' : element['isa']
}
for datakey in element['offline_aggregates'].keys():
aggregate[key][datakey] = []
if element['isa'] == 'state':
aggregate[key]['attributes'] = ['power']
else:
# TODO do not hardcode values
aggregate[key]['attributes'] = ['duration', 'energy', 'rel_energy_prev', 'rel_energy_next']
if 'plan' in element and element['plan']['level'] == 'epilogue':
aggregate[key]['attributes'].insert(0, 'timeout')
attributes = aggregate[key]['attributes'].copy()
for attribute in attributes:
if attribute not in element['offline_aggregates']:
aggregate[key]['attributes'].remove(attribute)
for datakey, dataval in element['offline_aggregates'].items():
aggregate[key][datakey].extend(dataval)
def pta_trace_to_aggregate(traces, ignore_trace_indexes = []):
u"""
Convert preprocessed DFA traces from peripherals/drivers to by_name aggregate for PTAModel.
arguments:
traces -- [ ... Liste von einzelnen Läufen (d.h. eine Zustands- und Transitionsfolge UNINITIALIZED -> foo -> FOO -> bar -> BAR -> ...)
Jeder Lauf:
- id: int Nummer des Laufs, beginnend bei 1
- trace: [ ... Liste von Zuständen und Transitionen
Jeweils:
- name: str Name
- isa: str state // transition
- parameter: { ... globaler Parameter: aktueller wert. null falls noch nicht eingestellt }
- args: [ Funktionsargumente, falls isa == 'transition' ]
- offline_aggregates:
- power: [float(uW)] Mittlere Leistung während Zustand/Transitions
- power_std: [float(uW^2)] Standardabweichung der Leistung
- duration: [int(us)] Dauer
- energy: [float(pJ)] Energieaufnahme des Zustands / der Transition
- clip_rate: [float(0..1)] Clipping
- paramkeys: [[str]] Name der berücksichtigten Parameter
- param: [int // str] Parameterwerte. Quasi-Duplikat von 'parameter' oben
Falls isa == 'transition':
- timeout: [int(us)] Dauer des vorherigen Zustands
- rel_energy_prev: [int(pJ)]
- rel_energy_next: [int(pJ)]
]
]
ignore_trace_indexes -- list of trace indexes. The corresponding taces will be ignored.
returns a tuple of three elements:
by_name -- measurements aggregated by state/transition name, annotated with parameter values
parameter_names -- list of parameter names
arg_count -- dict mapping transition names to the number of arguments of their corresponding driver function
by_name layout:
Dictionary with one key per state/transition ('send', 'TX', ...).
Each element is in turn a dict with the following elements:
- isa: 'state' or 'transition'
- power: list of mean power measurements in µW
- duration: list of durations in µs
- power_std: list of stddev of power per state/transition
- energy: consumed energy (power*duration) in pJ
- paramkeys: list of parameter names in each measurement (-> list of lists)
- param: list of parameter values in each measurement (-> list of lists)
- attributes: list of keys that should be analyzed,
e.g. ['power', 'duration']
additionally, only if isa == 'transition':
- timeout: list of duration of previous state in µs
- rel_energy_prev: transition energy relative to previous state mean power in pJ
- rel_energy_next: transition energy relative to next state mean power in pJ
"""
arg_count = dict()
by_name = dict()
parameter_names = sorted(traces[0]['trace'][0]['parameter'].keys())
for run in traces:
if run['id'] not in ignore_trace_indexes:
for elem in run['trace']:
if elem['isa'] == 'transition' and not elem['name'] in arg_count and 'args' in elem:
arg_count[elem['name']] = len(elem['args'])
if elem['name'] != 'UNINITIALIZED':
_add_trace_data_to_aggregate(by_name, elem['name'], elem)
for elem in by_name.values():
for key in elem['attributes']:
elem[key] = np.array(elem[key])
return by_name, parameter_names, arg_count
class PTAModel:
u"""
Parameter-aware PTA-based energy model.
Supports both static and parameter-based model attributes, and automatic detection of parameter-dependence.
The model heavily relies on two internal data structures:
PTAModel.by_name and PTAModel.by_param.
These provide measurements aggregated by state/transition name
and (in case of by_para) parameter values. Layout:
dictionary with one key per state/transition ('send', 'TX', ...) or
one key per state/transition and parameter combination
(('send', (1, 2)), ('send', (2, 3)), ('TX', (1, 2)), ('TX', (2, 3)), ...).
For by_param, parameter values are ordered corresponding to the lexically sorted parameter names.
Each element is in turn a dict with the following elements:
- isa: 'state' or 'transition'
- power: list of mean power measurements in µW
- duration: list of durations in µs
- power_std: list of stddev of power per state/transition
- energy: consumed energy (power*duration) in pJ
- paramkeys: list of parameter names in each measurement (-> list of lists)
- param: list of parameter values in each measurement (-> list of lists)
- attributes: list of keys that should be analyzed,
e.g. ['power', 'duration']
additionally, only if isa == 'transition':
- timeout: list of duration of previous state in µs
- rel_energy_prev: transition energy relative to previous state mean power in pJ
- rel_energy_next: transition energy relative to next state mean power in pJ
"""
def __init__(self, by_name, parameters, arg_count, traces = [], ignore_trace_indexes = [], discard_outliers = None, function_override = {}, verbose = True, use_corrcoef = False, hwmodel = None):
"""
Prepare a new PTA energy model.
Actual model generation is done on-demand by calling the respective functions.
arguments:
by_name -- state/transition measurements aggregated by name, as returned by pta_trace_to_aggregate.
parameters -- list of parameter names, as returned by pta_trace_to_aggregate
arg_count -- function arguments, as returned by pta_trace_to_aggregate
traces -- list of preprocessed DFA traces, as returned by RawData.get_preprocessed_data()
ignore_trace_indexes -- list of trace indexes. The corresponding traces will be ignored.
discard_outliers -- currently not supported: threshold for outlier detection and removel (float).
Outlier detection is performed individually for each state/transition in each trace,
so it only works if the benchmark ran several times.
Given "data" (a set of measurements of the same thing, e.g. TX duration in the third benchmark trace),
"m" (the median of all attribute measurements with the same parameters, which may include data from other traces),
a data point X is considered an outlier if
| 0.6745 * (X - m) / median(|data - m|) | > discard_outliers .
function_override -- dict of overrides for automatic parameter function generation.
If (state or transition name, model attribute) is present in function_override,
the corresponding text string is the function used for analytic (parameter-aware/fitted)
modeling of this attribute. It is passed to AnalyticFunction, see
there for the required format. Note that this happens regardless of
parameter dependency detection: The provided analytic function will be assigned
even if it seems like the model attribute is static / parameter-independent.
verbose -- print informative output, e.g. when removing an outlier
use_corrcoef -- use correlation coefficient instead of stddev comparison
to detect whether a model attribute depends on a parameter
hwmodel -- hardware model suitable for PTA.from_hwmodel
"""
self.by_name = by_name
self.by_param = by_name_to_by_param(by_name)
self._parameter_names = sorted(parameters)
self._num_args = arg_count
self._use_corrcoef = use_corrcoef
self.traces = traces
self.stats = ParamStats(self.by_name, self.by_param, self._parameter_names, self._num_args, self._use_corrcoef, verbose = verbose)
self.cache = {}
np.seterr('raise')
self._outlier_threshold = discard_outliers
self.function_override = function_override
self.verbose = verbose
self.hwmodel = hwmodel
self.ignore_trace_indexes = ignore_trace_indexes
self._aggregate_to_ndarray(self.by_name)
def distinct_param_values(self, state_or_tran, param_index = None, arg_index = None):
if param_index != None:
param_values = map(lambda x: x[param_index], self.by_name[state_or_tran]['param'])
return sorted(set(param_values))
def _aggregate_to_ndarray(self, aggregate):
for elem in aggregate.values():
for key in elem['attributes']:
elem[key] = np.array(elem[key])
# This heuristic is very similar to the "function is not much better than
# median" checks in get_fitted. So far, doing it here as well is mostly
# a performance and not an algorithm quality decision.
# --df, 2018-04-18
def depends_on_param(self, state_or_trans, key, param):
return self.stats.depends_on_param(state_or_trans, key, param)
# See notes on depends_on_param
def depends_on_arg(self, state_or_trans, key, param):
return self.stats.depends_on_arg(state_or_trans, key, param)
def _get_model_from_dict(self, model_dict, model_function):
model = {}
for name, elem in model_dict.items():
model[name] = {}
for key in elem['attributes']:
try:
model[name][key] = model_function(elem[key])
except RuntimeWarning:
vprint(self.verbose, '[W] Got no data for {} {}'.format(name, key))
except FloatingPointError as fpe:
vprint(self.verbose, '[W] Got no data for {} {}: {}'.format(name, key, fpe))
return model
def get_static(self):
"""
Get static model function: name, attribute -> model value.
Uses the median of by_name for modeling.
"""
static_model = self._get_model_from_dict(self.by_name, np.median)
def static_median_getter(name, key, **kwargs):
return static_model[name][key]
return static_median_getter
def get_static_using_mean(self):
"""
Get static model function: name, attribute -> model value.
Uses the mean of by_name for modeling.
"""
static_model = self._get_model_from_dict(self.by_name, np.mean)
def static_mean_getter(name, key, **kwargs):
return static_model[name][key]
return static_mean_getter
def get_param_lut(self, fallback = False):
"""
Get parameter-look-up-table model function: name, attribute, parameter values -> model value.
The function can only give model values for parameter combinations
present in by_param. By default, it raises KeyError for other values.
arguments:
fallback -- Fall back to the (non-parameter-aware) static model when encountering unknown parameter values
"""
static_model = self._get_model_from_dict(self.by_name, np.median)
lut_model = self._get_model_from_dict(self.by_param, np.median)
def lut_median_getter(name, key, param, arg = [], **kwargs):
param.extend(map(soft_cast_int, arg))
try:
return lut_model[(name, tuple(param))][key]
except KeyError:
if fallback:
return static_model[name][key]
raise
return lut_median_getter
def param_index(self, param_name):
if param_name in self._parameter_names:
return self._parameter_names.index(param_name)
return len(self._parameter_names) + int(param_name)
def param_name(self, param_index):
if param_index < len(self._parameter_names):
return self._parameter_names[param_index]
return str(param_index)
def get_fitted(self, safe_functions_enabled = False):
"""
Get paramete-aware model function and model information function.
Returns two functions:
model_function(name, attribute, param=parameter values) -> model value.
model_info(name, attribute) -> {'fit_result' : ..., 'function' : ... } or None
"""
if 'fitted_model_getter' in self.cache and 'fitted_info_getter' in self.cache:
return self.cache['fitted_model_getter'], self.cache['fitted_info_getter']
static_model = self._get_model_from_dict(self.by_name, np.median)
param_model = dict([[state_or_tran, {}] for state_or_tran in self.by_name.keys()])
paramfit = ParallelParamFit(self.by_param)
for state_or_tran in self.by_name.keys():
for model_attribute in self.by_name[state_or_tran]['attributes']:
fit_results = {}
for parameter_index, parameter_name in enumerate(self._parameter_names):
if self.depends_on_param(state_or_tran, model_attribute, parameter_name):
paramfit.enqueue(state_or_tran, model_attribute, parameter_index, parameter_name, safe_functions_enabled)
if arg_support_enabled and self.by_name[state_or_tran]['isa'] == 'transition':
for arg_index in range(self._num_args[state_or_tran]):
if self.depends_on_arg(state_or_tran, model_attribute, arg_index):
paramfit.enqueue(state_or_tran, model_attribute, len(self._parameter_names) + arg_index, arg_index, safe_functions_enabled)
paramfit.fit()
for state_or_tran in self.by_name.keys():
num_args = 0
if arg_support_enabled and self.by_name[state_or_tran]['isa'] == 'transition':
num_args = self._num_args[state_or_tran]
for model_attribute in self.by_name[state_or_tran]['attributes']:
fit_results = {}
for result in paramfit.results:
if result['key'][0] == state_or_tran and result['key'][1] == model_attribute:
fit_result = result['result']
if fit_result['best_rmsd'] >= min(fit_result['mean_rmsd'], fit_result['median_rmsd']):
vprint(self.verbose, '[I] Not modeling {} {} as function of {}: best ({:.0f}) is worse than ref ({:.0f}, {:.0f})'.format(
state_or_tran, model_attribute, result['key'][2], fit_result['best_rmsd'],
fit_result['mean_rmsd'], fit_result['median_rmsd']))
# See notes on depends_on_param
elif fit_result['best_rmsd'] >= 0.8 * min(fit_result['mean_rmsd'], fit_result['median_rmsd']):
vprint(self.verbose, '[I] Not modeling {} {} as function of {}: best ({:.0f}) is not much better than ({:.0f}, {:.0f})'.format(
state_or_tran, model_attribute, result['key'][2], fit_result['best_rmsd'],
fit_result['mean_rmsd'], fit_result['median_rmsd']))
else:
fit_results[result['key'][2]] = fit_result
if (state_or_tran, model_attribute) in self.function_override:
function_str = self.function_override[(state_or_tran, model_attribute)]
x = AnalyticFunction(function_str, self._parameter_names, num_args)
x.fit(self.by_param, state_or_tran, model_attribute)
if x.fit_success:
param_model[state_or_tran][model_attribute] = {
'fit_result': fit_results,
'function' : x
}
elif len(fit_results.keys()):
x = analytic.function_powerset(fit_results, self._parameter_names, num_args)
x.fit(self.by_param, state_or_tran, model_attribute)
if x.fit_success:
param_model[state_or_tran][model_attribute] = {
'fit_result': fit_results,
'function' : x
}
def model_getter(name, key, **kwargs):
if 'arg' in kwargs and 'param' in kwargs:
kwargs['param'].extend(map(soft_cast_int, kwargs['arg']))
if key in param_model[name]:
param_list = kwargs['param']
param_function = param_model[name][key]['function']
if param_function.is_predictable(param_list):
return param_function.eval(param_list)
return static_model[name][key]
def info_getter(name, key):
if key in param_model[name]:
return param_model[name][key]
return None
self.cache['fitted_model_getter'] = model_getter
self.cache['fitted_info_getter'] = info_getter
return model_getter, info_getter
def to_json(self):
static_model = self.get_static()
_, param_info = self.get_fitted()
pta = PTA.from_json(self.hwmodel)
pta.update(static_model, param_info)
return pta.to_json()
def states(self):
return sorted(list(filter(lambda k: self.by_name[k]['isa'] == 'state', self.by_name.keys())))
def transitions(self):
return sorted(list(filter(lambda k: self.by_name[k]['isa'] == 'transition', self.by_name.keys())))
def states_and_transitions(self):
ret = self.states()
ret.extend(self.transitions())
return ret
def parameters(self):
return self._parameter_names
def attributes(self, state_or_trans):
return self.by_name[state_or_trans]['attributes']
def assess(self, model_function):
"""
Calculate MAE, SMAPE, etc. of model_function for each by_name entry.
state/transition/... name and parameter values are fed into model_function.
The by_name entries of this PTAModel are used as ground truth and
compared with the values predicted by model_function.
If 'traces' was set when creating this object, the model quality is
also assessed on a per-trace basis.
For proper model assessments, the data used to generate model_function
and the data fed into this AnalyticModel instance must be mutually
exclusive (e.g. by performing cross validation). Otherwise,
overfitting cannot be detected.
"""
detailed_results = {}
model_energy_list = []
real_energy_list = []
model_rel_energy_list = []
model_state_energy_list = []
model_duration_list = []
real_duration_list = []
model_timeout_list = []
real_timeout_list = []
for name, elem in sorted(self.by_name.items()):
detailed_results[name] = {}
for key in elem['attributes']:
predicted_data = np.array(list(map(lambda i: model_function(name, key, param=elem['param'][i]), range(len(elem[key])))))
measures = regression_measures(predicted_data, elem[key])
detailed_results[name][key] = measures
for trace in self.traces:
if trace['id'] not in self.ignore_trace_indexes:
for rep_id in range(len(trace['trace'][0]['offline'])):
model_energy = 0.
real_energy = 0.
model_rel_energy = 0.
model_state_energy = 0.
model_duration = 0.
real_duration = 0.
model_timeout = 0.
real_timeout = 0.
for i, trace_part in enumerate(trace['trace']):
name = trace_part['name']
prev_name = trace['trace'][i-1]['name']
isa = trace_part['isa']
if name != 'UNINITIALIZED':
param = trace_part['offline_aggregates']['param'][rep_id]
prev_param = trace['trace'][i-1]['offline_aggregates']['param'][rep_id]
power = trace_part['offline'][rep_id]['uW_mean']
duration = trace_part['offline'][rep_id]['us']
prev_duration = trace['trace'][i-1]['offline'][rep_id]['us']
real_energy += power * duration
if isa == 'state':
model_energy += model_function(name, 'power', param=param) * duration
else:
model_energy += model_function(name, 'energy', param=param)
# If i == 1, the previous state was UNINITIALIZED, for which we do not have model data
if i == 1:
model_rel_energy += model_function(name, 'energy', param=param)
else:
model_rel_energy += model_function(prev_name, 'power', param=prev_param) * (prev_duration + duration)
model_state_energy += model_function(prev_name, 'power', param=prev_param) * (prev_duration + duration)
model_rel_energy += model_function(name, 'rel_energy_prev', param=param)
real_duration += duration
model_duration += model_function(name, 'duration', param=param)
if 'plan' in trace_part and trace_part['plan']['level'] == 'epilogue':
real_timeout += trace_part['offline'][rep_id]['timeout']
model_timeout += model_function(name, 'timeout', param=param)
real_energy_list.append(real_energy)
model_energy_list.append(model_energy)
model_rel_energy_list.append(model_rel_energy)
model_state_energy_list.append(model_state_energy)
real_duration_list.append(real_duration)
model_duration_list.append(model_duration)
real_timeout_list.append(real_timeout)
model_timeout_list.append(model_timeout)
if len(self.traces):
return {
'by_name' : detailed_results,
'duration_by_trace' : regression_measures(np.array(model_duration_list), np.array(real_duration_list)),
'energy_by_trace' : regression_measures(np.array(model_energy_list), np.array(real_energy_list)),
'timeout_by_trace' : regression_measures(np.array(model_timeout_list), np.array(real_timeout_list)),
'rel_energy_by_trace' : regression_measures(np.array(model_rel_energy_list), np.array(real_energy_list)),
'state_energy_by_trace' : regression_measures(np.array(model_state_energy_list), np.array(real_energy_list)),
}
return {
'by_name' : detailed_results
}
class MIMOSA:
"""
MIMOSA log loader for DFA traces with auto-calibration.
Expects a MIMOSA log file generated via dfatool and a dfatool-generated
benchmark: There is an automatic calibration step at the start and the
trigger pin is high iff a transition is active. The resulting data
is a list of state/transition/state/transition/... measurements.
"""
def __init__(self, voltage, shunt, verbose = True):
"""
Initialize MIMOSA loader for a specific voltage and shunt setting.
arguments:
voltage -- MIMOSA voltage used for measurements
shunt -- Shunt value in Ohms
verbose -- notify about invalid data and the likes
"""
self.voltage = voltage
self.shunt = shunt
self.verbose = verbose
self.r1 = 984 # "1k"
self.r2 = 99013 # "100k"
def charge_to_current_nocal(self, charge):
u"""Convert charge per 10µs to mean currents without accounting for calibration."""
ua_max = 1.836 / self.shunt * 1000000
ua_step = ua_max / 65535
return charge * ua_step
def _load_tf(self, tf):
num_bytes = tf.getmember('/tmp/mimosa//mimosa_scale_1.tmp').size
charges = np.ndarray(shape=(int(num_bytes / 4)), dtype=np.int32)
triggers = np.ndarray(shape=(int(num_bytes / 4)), dtype=np.int8)
with tf.extractfile('/tmp/mimosa//mimosa_scale_1.tmp') as f:
content = f.read()
iterator = struct.iter_unpack('<I', content)
i = 0
for word in iterator:
charges[i] = (word[0] >> 4)
triggers[i] = (word[0] & 0x08) >> 3
i += 1
return charges, triggers
def load_data(self, raw_data):
"""Load a MIMOSA log archive from a raw bytestring."""
with io.BytesIO(raw_data) as data_object:
with tarfile.open(fileobj = data_object) as tf:
return self._load_tf(tf)
def load_file(self, filename):
"""Load a MIMOSA log archive from a filename."""
with tarfile.open(filename) as tf:
return self._load_tf(tf)
def currents_nocal(self, charges):
u"""Convert charge per 10µs to mean currents without accounting for calibration."""
ua_max = 1.836 / self.shunt * 1000000
ua_step = ua_max / 65535
return charges.astype(np.double) * ua_step
def trigger_edges(self, triggers):
"""
Return indexes of trigger edges (both 0->1 and 1->0) in log data.
arguments:
triggers -- trigger array as returned by load_data
Ignores the first 10 seconds, which are used for calibration and may
contain bogus triggers due to DUT resets. Returns a list of int.
"""
trigidx = []
prevtrig = triggers[0]
# the device is reset for MIMOSA calibration in the first 10s and may
# send bogus interrupts -> bogus triggers
for i in range(1000000, triggers.shape[0]):
trig = triggers[i]
if trig != prevtrig:
# Due to MIMOSA's integrate-read-reset cycle, the trigger
# appears two points (20µs) before the corresponding data
trigidx.append(i+2)
prevtrig = trig
return trigidx
def calibration_edges(self, currents):
"""
Return start/stop indexes of calibration measurements.
arguments:
currents -- uncalibrated currents as reported by MIMOSA. For best results,
it may help to use a running mean, like so:
currents = running_mean(currents_nocal(..., 10))
Returns six indexes:
- Disconnected start
- Disconnected stop
- R1 (1 kOhm) start
- R1 (1 kOhm) stop
- R2 (100 kOhm) start
- R2 (100 kOhm) stop
"""
r1idx = 0
r2idx = 0
ua_r1 = self.voltage / self.r1 * 1000000
# first second may be bogus
for i in range(100000, len(currents)):
if r1idx == 0 and currents[i] > ua_r1 * 0.6:
r1idx = i
elif r1idx != 0 and r2idx == 0 and i > (r1idx + 180000) and currents[i] < ua_r1 * 0.4:
r2idx = i
# 2s disconnected, 2s r1, 2s r2 with r1 < r2 -> ua_r1 > ua_r2
# allow 5ms buffer in both directions to account for bouncing relais contacts
return r1idx - 180500, r1idx - 500, r1idx + 500, r2idx - 500, r2idx + 500, r2idx + 180500
def calibration_function(self, charges, cal_edges):
u"""
Calculate calibration function from previously determined calibration phase.
arguments:
charges -- raw charges from MIMOSA
cal_edges -- calibration edges as returned by calibration_edges
returns (calibration_function, calibration_data):
calibration_function -- charge in pJ (float) -> current in uA (float).
Converts the amount of charge in a 10 µs interval to the
mean current during the same interval.
calibration_data -- dict containing the following keys:
edges -- calibration points in the log file, in µs
offset -- ...
offset2 -- ...
slope_low -- ...
slope_high -- ...
add_low -- ...
add_high -- ..
r0_err_uW -- mean error of uncalibrated data at "∞ Ohm" in µW
r0_std_uW -- standard deviation of uncalibrated data at "∞ Ohm" in µW
r1_err_uW -- mean error of uncalibrated data at 1 kOhm
r1_std_uW -- stddev at 1 kOhm
r2_err_uW -- mean error at 100 kOhm
r2_std_uW -- stddev at 100 kOhm
"""
dis_start, dis_end, r1_start, r1_end, r2_start, r2_end = cal_edges
if dis_start < 0:
dis_start = 0
chg_r0 = charges[dis_start:dis_end]
chg_r1 = charges[r1_start:r1_end]
chg_r2 = charges[r2_start:r2_end]
cal_0_mean = np.mean(chg_r0)
cal_r1_mean = np.mean(chg_r1)
cal_r2_mean = np.mean(chg_r2)
ua_r1 = self.voltage / self.r1 * 1000000
ua_r2 = self.voltage / self.r2 * 1000000
if cal_r2_mean > cal_0_mean:
b_lower = (ua_r2 - 0) / (cal_r2_mean - cal_0_mean)
else:
vprint(self.verbose, '[W] 0 uA == %.f uA during calibration' % (ua_r2))
b_lower = 0
b_upper = (ua_r1 - ua_r2) / (cal_r1_mean - cal_r2_mean)
a_lower = -b_lower * cal_0_mean
a_upper = -b_upper * cal_r2_mean
if self.shunt == 680:
# R1 current is higher than shunt range -> only use R2 for calibration
def calfunc(charge):
if charge < cal_0_mean:
return 0
else:
return charge * b_lower + a_lower
else:
def calfunc(charge):
if charge < cal_0_mean:
return 0
if charge <= cal_r2_mean:
return charge * b_lower + a_lower
else:
return charge * b_upper + a_upper + ua_r2
caldata = {
'edges' : [x * 10 for x in cal_edges],
'offset': cal_0_mean,
'offset2' : cal_r2_mean,
'slope_low' : b_lower,
'slope_high' : b_upper,
'add_low' : a_lower,
'add_high' : a_upper,
'r0_err_uW' : np.mean(self.currents_nocal(chg_r0)) * self.voltage,
'r0_std_uW' : np.std(self.currents_nocal(chg_r0)) * self.voltage,
'r1_err_uW' : (np.mean(self.currents_nocal(chg_r1)) - ua_r1) * self.voltage,
'r1_std_uW' : np.std(self.currents_nocal(chg_r1)) * self.voltage,
'r2_err_uW' : (np.mean(self.currents_nocal(chg_r2)) - ua_r2) * self.voltage,
'r2_std_uW' : np.std(self.currents_nocal(chg_r2)) * self.voltage,
}
#print("if charge < %f : return 0" % cal_0_mean)
#print("if charge <= %f : return charge * %f + %f" % (cal_r2_mean, b_lower, a_lower))
#print("else : return charge * %f + %f + %f" % (b_upper, a_upper, ua_r2))
return calfunc, caldata
"""
def calcgrad(self, currents, threshold):
grad = np.gradient(running_mean(currents * self.voltage, 10))
# len(grad) == len(currents) - 9
subst = []
lastgrad = 0
for i in range(len(grad)):
# minimum substate duration: 10ms
if np.abs(grad[i]) > threshold and i - lastgrad > 50:
# account for skew introduced by running_mean and current
# ramp slope (parasitic capacitors etc.)
subst.append(i+10)
lastgrad = i
if lastgrad != i:
subst.append(i+10)
return subst
# TODO konfigurierbare min/max threshold und len(gradidx) > X, binaere
# Sache nach noetiger threshold. postprocessing mit
# "zwei benachbarte substates haben sehr aehnliche werte / niedrige stddev" -> mergen
# ... min/max muessen nicht vorgegeben werden, sind ja bekannt (0 / np.max(grad))
# TODO bei substates / index foo den offset durch running_mean beachten
# TODO ggf. clustering der 'abs(grad) > threshold' und bestimmung interessanter
# uebergaenge dadurch?
def gradfoo(self, currents):
gradients = np.abs(np.gradient(running_mean(currents * self.voltage, 10)))
gradmin = np.min(gradients)
gradmax = np.max(gradients)
threshold = np.mean([gradmin, gradmax])
gradidx = self.calcgrad(currents, threshold)
num_substates = 2
while len(gradidx) != num_substates:
if gradmax - gradmin < 0.1:
# We did our best
return threshold, gradidx
if len(gradidx) > num_substates:
gradmin = threshold
else:
gradmax = threshold
threshold = np.mean([gradmin, gradmax])
gradidx = self.calcgrad(currents, threshold)
return threshold, gradidx
"""
def analyze_states(self, charges, trigidx, ua_func):
u"""
Split log data into states and transitions and return mean power and duration for each element.
arguments:
charges -- raw charges (each element describes the charge transferred during 10 µs)
trigidx -- "charges" indexes corresponding to a trigger edge
ua_func -- charge -> current function as returned by calibration_function
returns a list of (alternating) states and transitions.
Each element is a dict containing:
- isa: 'state' oder 'transition'
- clip_rate: range(0..1) Anteil an Clipping im Energieverbrauch
- raw_mean: Mittelwert der Rohwerte
- raw_std: Standardabweichung der Rohwerte
- uW_mean: Mittelwert der (kalibrierten) Leistungsaufnahme
- uW_std: Standardabweichung der (kalibrierten) Leistungsaufnahme
- us: Dauer
Nur falls isa == 'transition':
- timeout: Dauer des vorherigen Zustands
- uW_mean_delta_prev: Differenz zwischen uW_mean und uW_mean des vorherigen Zustands
- uW_mean_delta_next: Differenz zwischen uW_mean und uW_mean des Folgezustands
"""
previdx = 0
is_state = True
iterdata = []
for idx in trigidx:
range_raw = charges[previdx:idx]
range_ua = ua_func(range_raw)
substates = {}
if previdx != 0 and idx - previdx > 200:
thr, subst = 0, [] #self.gradfoo(range_ua)
if len(subst):
statelist = []
prevsubidx = 0
for subidx in subst:
statelist.append({
'duration': (subidx - prevsubidx) * 10,
'uW_mean' : np.mean(range_ua[prevsubidx : subidx] * self.voltage),
'uW_std' : np.std(range_ua[prevsubidx : subidx] * self.voltage),
})
prevsubidx = subidx
substates = {
'threshold' : thr,
'states' : statelist,
}
isa = 'state'
if not is_state:
isa = 'transition'
data = {
'isa': isa,
'clip_rate' : np.mean(range_raw == 65535),
'raw_mean': np.mean(range_raw),
'raw_std' : np.std(range_raw),
'uW_mean' : np.mean(range_ua * self.voltage),
'uW_std' : np.std(range_ua * self.voltage),
'us' : (idx - previdx) * 10,
}
if 'states' in substates:
data['substates'] = substates
ssum = np.sum(list(map(lambda x : x['duration'], substates['states'])))
if ssum != data['us']:
vprint(self.verbose, "ERR: duration %d vs %d" % (data['us'], ssum))
if isa == 'transition':
# subtract average power of previous state
# (that is, the state from which this transition originates)
data['uW_mean_delta_prev'] = data['uW_mean'] - iterdata[-1]['uW_mean']
# placeholder to avoid extra cases in the analysis
data['uW_mean_delta_next'] = data['uW_mean']
data['timeout'] = iterdata[-1]['us']
elif len(iterdata) > 0:
# subtract average power of next state
# (the state into which this transition leads)
iterdata[-1]['uW_mean_delta_next'] = iterdata[-1]['uW_mean'] - data['uW_mean']
iterdata.append(data)
previdx = idx
is_state = not is_state
return iterdata
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