#!/usr/bin/env python3 """ analyze-archive - generate PTA energy model from dfatool benchmark traces analyze-archive generates a PTA energy model from one or more annotated traces generated by dfatool. By default, it does nothing else. Cross-Validation help: If is "montecarlo": Randomly divide data into 2/3 training and 1/3 validation, times. Reported model quality is the average of all validation runs. Data is partitioned without regard for parameter values, so a specific parameter combination may be present in both training and validation sets or just one of them. If is "kfold": Perform k-fold cross validation with k=. Divide data into 1-1/k training and 1/k validation, times. In the first set, items 0, k, 2k, ... ard used for validation, in the second set, items 1, k+1, 2k+1, ... and so on. validation, times. Reported model quality is the average of all validation runs. Data is partitioned without regard for parameter values, so a specific parameter combination may be present in both training and validation sets or just one of them. Trace Export: Each JSON file lists all occurences of the corresponding state/transition in the benchmark's PTA trace. Each occurence contains the corresponding PTA parameters (if any) in 'parameter' and measurement results in 'offline'. As measurements are typically run repeatedly, 'offline' is in turn a list of measurements: offline[0]['uW'] is the power trace of the first measurement of this state/transition, offline[1]['uW'] corresponds t the second measurement, etc. Values are provided in microwatts. For example, TX.json[0].offline[0].uW corresponds to the first measurement of the first TX state in the benchmark, and TX.json[5].offline[2].uW corresponds to the third measurement of the sixth TX state in the benchmark. WARNING: Several GB of RAM and disk space are required for complex measurements. (JSON files may grow very large -- we trade efficiency for easy handling) """ import argparse import json import logging import random import sys from dfatool import plotter from dfatool.loader import RawData, pta_trace_to_aggregate from dfatool.functions import gplearn_to_function from dfatool.model import PTAModel from dfatool.validation import CrossValidator from dfatool.utils import filter_aggregate_by_param from dfatool.automata import PTA ### PELT import numpy as np # Very short benchmark yielded approx. 3 times the speed of solution not using sort # checks the percentiles if refinement is necessary def needs_refinement(signal, thresh): sorted_signal = sorted(signal) length_of_signal = len(signal) percentile_size = int() percentile_size = length_of_signal // 100 lower_percentile = sorted_signal[0:percentile_size] upper_percentile = sorted_signal[ length_of_signal - percentile_size : length_of_signal ] lower_percentile_mean = np.mean(lower_percentile) upper_percentile_mean = np.mean(upper_percentile) median = np.median(sorted_signal) dist = median - lower_percentile_mean if dist > thresh: return True dist = upper_percentile_mean - median if dist > thresh: return True return False ### /PELT def print_model_quality(results): for state_or_tran in results.keys(): print() for key, result in results[state_or_tran].items(): if "smape" in result: print( "{:20s} {:15s} {:.2f}% / {:.0f}".format( state_or_tran, key, result["smape"], result["mae"] ) ) else: print("{:20s} {:15s} {:.0f}".format(state_or_tran, key, result["mae"])) def format_quality_measures(result): if "smape" in result: return "{:6.2f}% / {:9.0f}".format(result["smape"], result["mae"]) else: return "{:6} {:9.0f}".format("", result["mae"]) def model_quality_table(result_lists, info_list): print( "{:20s} {:15s} {:19s} {:19s} {:19s}".format( "key", "attribute", "static".center(19), "parameterized".center(19), "LUT".center(19), ) ) for state_or_tran in result_lists[0]["by_name"].keys(): for key in result_lists[0]["by_name"][state_or_tran].keys(): buf = "{:20s} {:15s}".format(state_or_tran, key) for i, results in enumerate(result_lists): info = info_list[i] buf += " ||| " if info is None or info(state_or_tran, key): result = results["by_name"][state_or_tran][key] buf += format_quality_measures(result) else: buf += "{:7}----{:8}".format("", "") print(buf) def model_summary_table(result_list): buf = "transition duration" for results in result_list: if len(buf): buf += " ||| " buf += format_quality_measures(results["duration_by_trace"]) print(buf) buf = "total energy " for results in result_list: if len(buf): buf += " ||| " buf += format_quality_measures(results["energy_by_trace"]) print(buf) buf = "rel total energy " for results in result_list: if len(buf): buf += " ||| " buf += format_quality_measures(results["rel_energy_by_trace"]) print(buf) buf = "state-only energy " for results in result_list: if len(buf): buf += " ||| " buf += format_quality_measures(results["state_energy_by_trace"]) print(buf) buf = "transition timeout " for results in result_list: if len(buf): buf += " ||| " buf += format_quality_measures(results["timeout_by_trace"]) print(buf) def print_text_model_data(model, pm, pq, lm, lq, am, ai, aq): print("") print(r"key attribute $1 - \frac{\sigma_X}{...}$") for state_or_tran in model.by_name.keys(): for attribute in model.attributes(state_or_tran): print( "{} {} {:.8f}".format( state_or_tran, attribute, model.stats.generic_param_dependence_ratio( state_or_tran, attribute ), ) ) print("") print(r"key attribute parameter $1 - \frac{...}{...}$") for state_or_tran in model.by_name.keys(): for attribute in model.attributes(state_or_tran): for param in model.parameters(): print( "{} {} {} {:.8f}".format( state_or_tran, attribute, param, model.stats.param_dependence_ratio( state_or_tran, attribute, param ), ) ) if state_or_tran in model._num_args: for arg_index in range(model._num_args[state_or_tran]): print( "{} {} {:d} {:.8f}".format( state_or_tran, attribute, arg_index, model.stats.arg_dependence_ratio( state_or_tran, attribute, arg_index ), ) ) def print_html_model_data(model, pm, pq, lm, lq, am, ai, aq): state_attributes = model.attributes(model.states()[0]) print( "" ) for state in model.states(): print("", end="") print("".format(state), end="") for attribute in state_attributes: unit = "" if attribute == "power": unit = "µW" print( "".format( pm(state, attribute), unit, pq["by_name"][state][attribute]["smape"] ), end="", ) print("") print("
state" + "".join(state_attributes) + "
{}{:.0f} {} ({:.1f}%)
") trans_attributes = model.attributes(model.transitions()[0]) if "rel_energy_prev" in trans_attributes: trans_attributes.remove("rel_energy_next") print( "" ) for trans in model.transitions(): print("", end="") print("".format(trans), end="") for attribute in trans_attributes: unit = "" if attribute == "duration": unit = "µs" elif attribute in ["energy", "rel_energy_prev"]: unit = "pJ" print( "".format( pm(trans, attribute), unit, pq["by_name"][trans][attribute]["smape"] ), end="", ) print("") print("
transition" + "".join(trans_attributes) + "
{}{:.0f} {} ({:.1f}%)
") if __name__ == "__main__": ignored_trace_indexes = [] safe_functions_enabled = False function_override = {} show_models = [] show_quality = [] pta = None energymodel_export_file = None trace_export_dir = None xv_method = None xv_count = 10 parser = argparse.ArgumentParser( formatter_class=argparse.RawDescriptionHelpFormatter, description=__doc__ ) parser.add_argument( "--info", action="store_true", help="Show state duration and (for each state and transition) number of measurements and parameter values)", ) parser.add_argument( "--no-cache", action="store_true", help="Do not load cached measurement results" ) parser.add_argument( "--plot-unparam", metavar="::[;::