#!/usr/bin/env python3 import argparse import os import random import re import shutil import time import datetime import signal import common_functions as cf # All common functions will be at common_functions module import common_parameters as cp # All common parameters will be at common_parameters module import sys import signal import threading from threading import Thread, Lock from classes.RunGDB import RunGDB from classes.SummaryFile import SummaryFile from classes.Logging import Logging from classes.SignalApp import SignalApp """ [THIS FUNCTION CAN BE EDITED IF DESIRED] User defined function this function must return an empty or not string. The string will be appended in the last collum of summary CSV file the column will have 'user_defined' as header if the string is always empty the column will be empty, otherwise it will contain the returned values for each injection """ def receiveSignal(signalNumber, frame): global logging logging.info("Esperando sincronismo del final") try: syncro.wait() except: syncro.abort() logging.info("Breakpoint inicial fuera de tiempo") logging.info("Alcanzado el breakpoint, y recibida la señal {}".format(signalNumber)); def receiveEnd(signalNumber, frame): global logging logging.info("Esperando sincronismo del final") try: wait_finish.wait() except: wait_finish.abort() logging.info("Hang timeout execution") logging.info("Recibida la señal de final del programa {}".format(signalNumber)); def user_defined_function(injection_output_path): # This is a temporary example for carol-fi-codes suite # it will search for a LOGFILENAME int the benchmark output if it finds # then the desired pattern will be returned with open(injection_output_path, "r") as fp: for l in fp.readlines(): m = re.match(r"LOGFILENAME:.*/(\S+).*", l) if m: return m.group(1) return "" """ CTRL + C event """ def signal_handler(sig, frame): global kill_strings, exit_injector exit_injector = True for cmd in kill_strings.split(";"): os.system(cmd + " > /dev/null 2>&1") os.system("rm -f {}/bin/*".format(current_path)) print("Current_path "+current_path) for th in gpus_threads: th.join() #sys.exit(0) """ Check if app stops execution (otherwise kill it after a time) """ def check_finish(max_wait_time, logging, timestamp_start, process, thread, kill_string): is_hang = False # Wait maxWaitTimes the normal duration of the program before killing it # max_wait_time = int(conf.get(section, "maxWaitTimes")) * end_time sleep_time = max_wait_time / cp.NUM_DIVISION_TIMES if cp.DEBUG: cf.printf("THREAD: {} MAX_WAIT_TIME {} CHECK FINISH SLEEP_TIME {}".format(thread, max_wait_time, sleep_time)) # Watchdog to avoid hangs p_is_alive = process.is_alive() now = int(time.time()) diff_time = now - timestamp_start while diff_time < max_wait_time and p_is_alive: time.sleep(sleep_time) p_is_alive = process.is_alive() now = int(time.time()) diff_time = now - timestamp_start # Process finished ok if not p_is_alive: logging.debug("PROCESS NOT RUNNING") if cp.DEBUG: cf.printf("THREAD {} PROCESS NOT RUNNING".format(thread)) # check execution finished before or after waitTime if diff_time < max_wait_time: logging.info("Execution on thread {} finished before waitTime. {} seconds.".format(thread, diff_time)) else: logging.info("Execution on thread {} finished after waitTime. {} seconds.".format(thread, diff_time)) is_hang = True logging.debug("now: {}".format(now)) logging.debug("timestampStart: {}".format(timestamp_start)) # Kill all the processes to make sure the machine is clean for another test cf.kill_all(kill_string=kill_string, logging=logging) # Also kill the subprocess process.kill_subprocess() return is_hang """ Copy the logs and output(if fault not masked) to a selected folder """ def save_output(is_sdc, is_hang, is_crash, is_masked, logging, unique_id, flip_log_file, inj_output_path, inj_err_path, diff_log_path, diff_err_path, signal_app_log_path, thread): # FI successful fi_injected = False if os.path.isfile(flip_log_file): with open(flip_log_file, "r") as fp: content = fp.read() if re.search('Fault Injection Successful', content): fi_injected = True fp.close() dt = datetime.datetime.fromtimestamp(time.time()) ymd = dt.strftime('%Y_%m_%d') y_m_d_h_m_s = dt.strftime('%Y_%m_%d_%H_%M_%S') y_m_d_h_m_s = unique_id + "-" + y_m_d_h_m_s dir_d_t = os.path.join(ymd, y_m_d_h_m_s) # Log and create the paths if not fi_injected: cp_dir = os.path.join(cp.LOGS_PATH, 'failed-injection', dir_d_t) logging.summary("Fault Injection Failed") elif is_hang: cp_dir = os.path.join(cp.LOGS_PATH, 'hangs', dir_d_t) logging.summary("Hang") elif is_crash: cp_dir = os.path.join(cp.LOGS_PATH, 'crashs', dir_d_t) logging.summary("Crash") elif is_sdc: cp_dir = os.path.join(cp.LOGS_PATH, 'sdcs', dir_d_t) logging.summary("SDC") elif is_masked: cp_dir = os.path.join(cp.LOGS_PATH, 'masked', dir_d_t) logging.summary("Masked") elif not os.path.isfile(inj_output_path): cp_dir = os.path.join(cp.LOGS_PATH, 'no_output_generated', dir_d_t) logging.summary("no_output_generated") else: cp_dir = os.path.join(cp.LOGS_PATH, 'unknown', dir_d_t) logging.summary("Unknown") if not os.path.isdir(cp_dir): os.makedirs(cp_dir) # Moving all necessary files for file_to_move in [flip_log_file, inj_output_path, inj_err_path, diff_log_path, diff_err_path, signal_app_log_path]: try: shutil.move(file_to_move, cp_dir) except Exception as err: if cp.DEBUG: cf.printf("THREAD {} ERROR ON MOVING {} -- {}".format(thread, file_to_move, str(err))) """ Check output files for SDCs """ def check_sdcs_and_app_crash(logging, sdc_check_script, inj_output_path, inj_err_path, diff_log_path, diff_err_path): is_sdc = False is_masked = False is_app_crash = [False] if not os.path.isfile(inj_output_path): logging.error("outputFile not found: " + inj_output_path) is_app_crash = True elif not os.path.isfile(cp.GOLD_OUTPUT_PATH): logging.error("gold_file not found: " + cp.GOLD_OUTPUT_PATH) raise ValueError("GOLD FILE NOT FOUND") elif not os.path.isfile(sdc_check_script): logging.error("sdc check script file not found: " + sdc_check_script) raise ValueError("SDC CHECK SCRIPT NOT FOUND: " + sdc_check_script) elif not os.path.isfile(inj_err_path): logging.error("possible crash, stderr not found: " + inj_output_path) is_app_crash[0] = True elif not os.path.isfile(cp.GOLD_ERR_PATH): logging.error("gold_err_file not found: " + cp.GOLD_ERR_PATH) raise ValueError("GOLD ERR FILE NOT FOUND: " + cp.GOLD_ERR_PATH) # Removing the output trash info # It automatically overwrite the file in the output path cf.remove_useless_information_from_output(output_file_path=inj_output_path) cf.remove_useless_information_from_output(output_file_path=inj_err_path) if os.path.isfile(cp.GOLD_OUTPUT_PATH) and os.path.isfile(inj_output_path) and os.path.isfile( cp.GOLD_ERR_PATH) and os.path.isfile(inj_err_path): # Set environ variables for sdc_check_script os.environ['GOLD_OUTPUT_PATH'] = cp.GOLD_OUTPUT_PATH os.environ['INJ_OUTPUT_PATH'] = inj_output_path os.environ['GOLD_ERR_PATH'] = cp.GOLD_ERR_PATH os.environ['INJ_ERR_PATH'] = inj_err_path os.environ['DIFF_LOG'] = diff_log_path os.environ['DIFF_ERR_LOG'] = diff_err_path compare_script_result = os.system("sh " + sdc_check_script) if compare_script_result != 0: raise ValueError("SDC/Crash script returned a value different from 0. Cannot proceed") # Test if files are ok with open(diff_log_path, 'r') as fi: out_lines = fi.readlines() if len(out_lines) != 0: for carol_fi_signal in cp.SIGNALS: for line in out_lines: if carol_fi_signal in line: #print("FAIL=="+line+"====") is_app_crash[0] = True if len (is_app_crash) == 1: is_app_crash.append(carol_fi_signal) else: is_app_crash[1]=is_app_crash[1]+" "+carol_fi_signal break if (not is_app_crash[0]): # Check if NVIDIA signals on output is_masked= True for line in out_lines: if 'FAIL' in line: #print("FAIL=="+line+"====") is_sdc= True is_masked=False break else: is_sdc= False is_masked=False # if is_app_crash[0]: # break #if not is_app_crash: # is_sdc = True # with open(diff_err_path, 'r') as fi_err: # err_lines = fi_err.readlines() # if len(err_lines) != 0: # is_app_crash[0] = True # if len (is_app_crash) == 1: # is_app_crash.append('Unknown') return is_sdc, is_app_crash, is_masked """ Check the carolfi-xxxx logfile the status of the injected fault """ def check_injection_outcome(host_thread, logging, injection_site): # Search for set values for register # Must be done before save output # Check THREAD FOCUS. Check if could change the block and the thread register = block = thread = "___" # Search for block block_focus = logging.search("CUDA_BLOCK_FOCUS") if block_focus: m = re.search(r"CUDA_BLOCK_FOCUS:.*block[ ]+\((\d+),(\d+),(\d+)\).*", block_focus) if m: block = "{}_{}_{}".format(m.group(1), m.group(2), m.group(3)) thread_focus = logging.search("CUDA_THREAD_FOCUS") # Search for thread if thread_focus: m = re.search(r"CUDA_THREAD_FOCUS:.*thread[ ]+\((\d+),(\d+),(\d+)\).*", thread_focus) if m: thread = "{}_{}_{}".format(m.group(1), m.group(2), m.group(3)) register_selected = logging.search("SELECTED_REGISTER") # Search for the register if register_selected: m = re.search(r"SELECTED_REGISTER:(\S+).*", register_selected) if m: register = m.group(1) # Was the fault injected? try: old_value = re.findall(r'old_value:(\S+)', logging.search("old_value"))[0] new_value = re.findall(r'new_value:(\S+)', logging.search("new_value"))[0] fi_successful = True # Check specific outcomes # No need to process for RF instruction = 'register' assm_line = logging.search("ASSM_LINE") dpc={} dpc['absoluto']="0x"+re.match(r".*0x([0-9a-fA-F]+) <.*",assm_line).group(1) dpc['relativo']=assm_line.split('<')[1].split('>')[0] #print("---PC: "+dpc['absoluto']+ "PC rel"+dpc['relativo']) pc=dpc['absoluto']+"<"+dpc['relativo']+">" if cp.INJECTION_SITES[injection_site] in [cp.INST_OUT, cp.INST_ADD]: # if fault was injected ASSM_LINE MUST be in the logfile instruction = re.match(r".*:\t(\S+) .*", assm_line).group(1) except TypeError as te: instruction = new_value = old_value = None pc = instruction fi_successful = False if cp.DEBUG: cf.printf("THREAD {} FAULT WAS NOT INJECTED. ERROR {}".format(host_thread, te)) return block, fi_successful, new_value, old_value, register, thread, instruction, pc """ Function to run one execution of the fault injector return old register value, new register value """ def gdb_inject_fault(**kwargs): global kill_strings, logging # These are the mandatory parameters bits_to_flip = kwargs.get('bits_to_flip') fault_model = kwargs.get('fault_model') unique_id = kwargs.get('unique_id') max_time = kwargs.get('max_time') end_time = kwargs.get('end_time') current_path_local = kwargs.get('current_path') # injection site injection_site = kwargs.get('injection_site') benchmark_args = kwargs.get('benchmark_args') benchmark_binary = kwargs.get('benchmark_binary') host_thread = kwargs.get('host_thread') seq_signals = kwargs.get('seq_signals') init_sleep = kwargs.get('init_sleep') sdc_check_script = kwargs.get('gold_check_script') maxregs=kwargs.get('max_regs') # signalCmd signal_cmd = kwargs.get("signal_cmd") gdb_exec_name = kwargs.get('gdb_path') gdb_kernel = kwargs.get('kernel') # Define all path to current thread execution # Logging file flip_log_file = cp.LOG_DEFAULT_NAME.format(unique_id) inj_output_path = cp.INJ_OUTPUT_PATH.format(unique_id) inj_err_path = cp.INJ_ERR_PATH.format(unique_id) signal_app_log = cp.SIGNAL_APP_LOG.format(unique_id) diff_log_path = cp.DIFF_LOG.format(unique_id) diff_err_path = cp.DIFF_ERR_LOG.format(unique_id) # Starting FI process if cp.DEBUG: cf.printf("THREAD {} STARTING GDB SCRIPT".format(host_thread)) logging = Logging(log_file=flip_log_file, unique_id=unique_id) logging.info("Starting GDB script") #init_wait_time = uniform(0, end_time * cp.MAX_SIGNAL_BEFORE_ENDING) #time_to_sleep = (max_wait_time - self.__init_wait_time) / seq_signals # Generate configuration file for specific test gdb_env_string = "{}|{}|{}|{}|{}|{}|file {}; set args {}|{}".format(gdb_kernel,os.getpid(),maxregs,",".join(str(i) for i in bits_to_flip), fault_model, flip_log_file, benchmark_binary, benchmark_args, injection_site) if cp.DEBUG: cf.printf("THREAD {} ENV GENERATE FINISHED".format(host_thread)) # First we have to start the SignalApp thread signal_app_thread = SignalApp(max_wait_time=end_time, signal_cmd=signal_cmd, log_path=signal_app_log, unique_id=unique_id, signals_to_send=seq_signals, init_sleep=init_sleep,syncro=syncro,waitfinish=wait_finish) # Create one thread to start gdb script # Start fault injection process fi_process = RunGDB(unique_id=unique_id, gdb_exec_name=gdb_exec_name, flip_script=cp.FLIP_SCRIPT, carol_fi_base_path=current_path_local, gdb_env_string=gdb_env_string, gpu_to_execute=host_thread, inj_output_path=inj_output_path, inj_err_path=inj_err_path) if cp.DEBUG: cf.printf("THREAD {} STARTING PROCESS".format(host_thread)) # Starting both threads fi_process.start() #if cp.DEBUG: # cf.printf( "Waiting breakpoint.....") signal_app_thread.start() if cp.DEBUG: cf.printf("THREAD {} PROCESSES SPAWNED".format(host_thread)) # Start counting time timestamp_start = int(time.time()) # Check if app stops execution (otherwise kill it after a time) # max_wait_time, logging, timestamp_start, thread, kill_string is_hang = check_finish(max_wait_time=max_time, logging=logging, timestamp_start=timestamp_start, process=fi_process, thread=host_thread, kill_string=kill_strings) #init_hang=signal_app_thread.ishang) if cp.DEBUG: cf.printf("THREAD {} FINISH CHECK OK".format(host_thread)) # finishing and removing thrash fi_process.join() # fi_process.terminate() signal_app_thread.join() # Get the signal init wait time before destroy the thread signal_init_wait_time = signal_app_thread.get_int_wait_time() del fi_process, signal_app_thread if cp.DEBUG: cf.printf("THREAD {} PROCESS JOINED".format(host_thread)) # Change the behavior of this function if any other information # needs to be added in the final summary user_defined_string = user_defined_function(injection_output_path=inj_output_path) # # Check output files for SDCs is_sdc, is_crash, is_masked = check_sdcs_and_app_crash(logging=logging, sdc_check_script=sdc_check_script, inj_output_path=inj_output_path, inj_err_path=inj_err_path, diff_log_path=diff_log_path, diff_err_path=diff_err_path) if cp.DEBUG: cf.printf("THREAD {} CHECK SDCs OK".format(host_thread)) # Check if the carolfi logfile contains the information # to confirm the fault injection outcome block, fi_successful, new_value, old_value, register, thread, instruction,pc = check_injection_outcome( host_thread=host_thread, logging=logging, injection_site=injection_site ) # Copy output files to a folder save_output(is_sdc=is_sdc, is_hang=is_hang,is_crash=is_crash[0],is_masked=is_masked, logging=logging, unique_id=unique_id, flip_log_file=flip_log_file, inj_output_path=inj_output_path, inj_err_path=inj_err_path, diff_log_path=diff_log_path, diff_err_path=diff_err_path, signal_app_log_path=signal_app_log, thread=host_thread) if cp.DEBUG: cf.printf("THREAD {} SAVE OUTPUT AND RETURN".format(host_thread)) return_list = [register, old_value, new_value, fi_successful, is_hang, is_crash, is_sdc, is_masked, signal_init_wait_time, block, thread, instruction, pc, user_defined_string] return return_list """ This function will select the bits that will be flipped if it is least significant bits it will reduce the starting bit range """ def bit_flip_selection(fault_model): # Randomly select (a) bit(s) to flip # Max double bit flip max_size_register_fault_model = cp.SINGLE_MAX_SIZE_REGISTER # Max size of bits to flip is 2, max double bit flip bits_to_flip = [0] # Single bit flip if fault_model == cp.FLIP_SINGLE_BIT: bits_to_flip[0] = random.randint(0, max_size_register_fault_model - 1) # Double bit flip elif fault_model == cp.FLIP_TWO_BITS: bits_to_flip = [0] * 2 bits_to_flip[0] = random.randint(0, max_size_register_fault_model - 1) # Make sure that the same bit is not going to be selected r = [i for i in range(0, bits_to_flip[0])] r += [i for i in range(bits_to_flip[0] + 1, max_size_register_fault_model)] bits_to_flip[1] = random.choice(r) # Random value elif fault_model == cp.RANDOM_VALUE: bits_to_flip[0] = str(hex(random.randint(0, cp.MAX_INT_32))) # Zero value elif fault_model == cp.ZERO_VALUE: bits_to_flip[0] = 0 # Least 16 bits elif fault_model == cp.LEAST_16_BITS: bits_to_flip[0] = random.randint(0, 15) # Least 8 bits elif fault_model == cp.LEAST_8_BITS: bits_to_flip[0] = random.randint(0, 7) return bits_to_flip """ print the info for each fault """ def pretty_print(header, row): fault_injected = row[9] normal_print = "\033[0;37;49m" failed_print = "\033[1;37;41m" injected_print = "\033[1;37;42m" output_str = "fault status: " output_str += injected_print + "Injected" if fault_injected else failed_print + "Failed" output_str += normal_print cf.printf(output_str) output_str = "" for name, value in zip(header, row): if name != "fault_successful": output_str += "{}: {}\n".format(name, value) cf.printf(output_str) cf.printf() """ This injector has two injection options this function performs fault injection by sending a SIGINT signal to the application """ def fault_injection_by_signal(**kwargs): # Global rows list global lock, exit_injector,num_rounds,kill_strings benchmark_binary = kwargs.get('benchmark_binary') #kwargs['signal_cmd'] = "killall -2 {}".format(os.path.basename(benchmark_binary)) kwargs['signal_cmd'] = "pgrep {}".format(os.path.basename(benchmark_binary)) fault_models = kwargs.get('fault_models') iterations = kwargs.get('iterations') host_thread = kwargs.get('host_thread') injection_site = kwargs.get('injection_site') summary_file = kwargs.get('summary_file') header = kwargs.get('header') max_fallos=10 acc_fault_injected=0 cf.printf("-----------------------------------------------------------------------------------------------") # Execute the fault injector for each one of the sections(apps) of the configuration file for fault_model in fault_models: # Execute iterations number of fault injection for a specific app try: ret_profiler = cf.load_config_file("tmpxxx_num_rounds.conf") num_rounds=int(ret_profiler.get('DEFAULT', 'Ocurrencias')) os.system ("rm tmpxxx_num_rounds.conf") except: num_rounds = 1 while num_rounds <= iterations: if exit_injector: return # Generate an unique id for this fault injection # Thread is for multi gpu unique_id = "{}_{}_{}".format(num_rounds, fault_model, host_thread) bits_to_flip = bit_flip_selection(fault_model=fault_model) kwargs['unique_id'] = unique_id kwargs['bits_to_flip'] = bits_to_flip kwargs['fault_model'] = fault_model fi_tic = int(time.time()) [register, old_val, new_val, fault_injected, hang, crash, masked,sdc, signal_init_time, block, thread, instruction, pc, user_defined_val] = gdb_inject_fault(**kwargs) # Time toc fi_toc = int(time.time()) # FI injection time injection_time = fi_toc - fi_tic if len(crash)==1: tmp="--" else: tmp=crash[1] row = [unique_id, register, num_rounds, fault_model, thread, block, old_val, new_val, injection_site, fault_injected, hang, crash[0], sdc, masked ,tmp,injection_time, signal_init_time, bits_to_flip, instruction, pc, user_defined_val] if fault_injected: # output_str = "THREAD:{}, FAULT NUM:{}".format(host_thread, num_rounds) #output_str += " {}: {},".format(name, value) #for name, value in zip(header, row): # :-1 to remove the last comma #cf.printf(output_str[:-1]) with lock: summary_file.write_row(row) num_rounds += 1 acc_fault_injeted=0 else: acc_fault_injected+=1 if (acc_fault_injected == (max_fallos/2)): for cmd in kill_strings.split(";"): os.system(cmd + " > /dev/null 2>&1") for th in gpus_threads: try: th.join() except: nulo=1 time.sleep(240) if (acc_fault_injected == max_fallos): exit_injector=True for cmd in kill_strings.split(";"): os.system(cmd + " > /dev/null 2>&1") for th in gpus_threads: try: th.join() except: nulo=1 f=open("tmpxxx_num_rounds.conf","w") f.write("[DEFAULT] \nOcurrencias = "+str(num_rounds)+"\n") f.close() pretty_print(header=header, row=row) return num_rounds """ Main function """ def main(): global kill_strings, current_path, gpus_threads, lock, syncro, wait_finish signal.signal(cp.SIGNAL_STOP,receiveSignal); signal.signal(cp.SIGNAL_EXIT,receiveEnd); parser = argparse.ArgumentParser() parser.add_argument('-c', '--conf', dest="config_file", help='Configuration file', required=True) parser.add_argument('-i', '--iter', dest="iterations", help='How many times to repeat the programs in the configuration file', required=True, type=int) parser.add_argument('-n', '--n_gpus', dest="n_gpus", help="The number of available GPUs to perform FI." " Default is 1.", required=False, default=1, type=int) parser.add_argument('-d', '--device', dest="device", help="The GPU to perform FI." " Default is 0.", required=False, default=0, type=int) args = parser.parse_args() if args.iterations < 1: parser.error('Iterations must be greater than zero') # Start with a different seed every time to vary the random numbers generated # the seed will be the current number of second since 01/01/70 random.seed() # Read the configuration file with data for all the apps that will be executed conf = cf.load_config_file(args.config_file) benchmark_binary_default = conf.get('DEFAULT', 'benchmarkBinary') if (args.device>0): cp.LOGS_PATH="{}-{}-{}".format(cp.LOGS_PATH,args.device,benchmark_binary_default.split('/')[-1]) cp.rewrite_path() # Connect signal SIGINT to stop the fault injector kill_strings = "" signal.signal(signal.SIGINT, signal_handler) # First set env vars current_path = cf.set_python_env() cf.printf("2 - Starting fault injection") cf.printf("###################################################") cf.printf("2 - {} faults will be injected".format(args.iterations)) cf.printf("###################################################") ######################################################################## # Creating a summary csv file csv_file = conf.get("DEFAULT", "csvFile") # Csv log fieldnames = ['unique_id', 'register', 'iteration', 'fault_model', 'thread', 'block', 'old_value', 'new_value', 'inj_site', 'fault_successful', 'hang', 'crash', 'masked', 'sdc', 'Exception','time', 'inj_time_location', 'bits_flipped', 'instruction', 'pc', 'user_defined'] if os.path.exists("tmpxxx_num_rounds.conf"): mode='a' else: mode='w' summary_file = SummaryFile(filename=csv_file, fieldnames=fieldnames, mode=mode) #'w' # Lock for summary file parallel lock = Lock() # Define the number of threads tha will execute num_gpus = args.n_gpus device=args.device iterations = args.iterations if args.n_gpus > args.iterations: num_gpus = args.iterations bin_path = current_path + '/bin' if not os.path.exists(bin_path): os.mkdir(bin_path) # Create tmp path and clean it if it exists tmp_path = current_path + "/" + cp.LOGS_PATH + "/tmp" if not os.path.exists(tmp_path): raise FileNotFoundError(tmp_path + " path does not exists, run app_profile.py to create it") # Set binaries for the injection gdb_path_default = conf.get('DEFAULT', 'gdbExecName') each_thread_iterations = iterations / num_gpus gpus_threads = [] kernel_info_dict = cf.load_file(cp.KERNEL_INFO_DIR) for thread_id in range(0+device, num_gpus+device): gdb = "{}/bin/{}_{}".format(current_path, os.path.basename(gdb_path_default), thread_id) benchmark_binary = "{}/bin/{}_{}".format(current_path, os.path.basename(benchmark_binary_default), thread_id) os.system("ln -s {} {}".format(gdb_path_default, gdb)) os.system("ln -s {} {}".format(benchmark_binary_default, benchmark_binary)) # These are the mandatory parameters kwargs = { 'injection_site': conf.get('DEFAULT', 'injectionSite'), 'fault_models': [int(i) for i in str(conf.get('DEFAULT', 'faultModel')).split(',')], 'max_time': float(kernel_info_dict['max_time']) * float(conf.get('DEFAULT', 'maxWaitTimes')), 'end_time': float(kernel_info_dict['max_time_kernel']), 'max_regs': int(kernel_info_dict['max_regs']), 'iterations': each_thread_iterations, 'benchmark_binary': benchmark_binary, 'benchmark_args': conf.get('DEFAULT', 'benchmarkArgs'), 'host_thread':thread_id, 'gdb_path': gdb, 'current_path': current_path, 'seq_signals': int(conf.get('DEFAULT', 'seqSignals')), 'init_sleep': float(conf.get('DEFAULT', 'initSleep')), 'kernel':conf.get('DEFAULT', 'section_begin'), 'gold_check_script': "{}/{}".format(current_path, conf.get('DEFAULT', 'goldenCheckScript')), 'summary_file': summary_file, 'header': fieldnames } syncro = threading.Barrier(2, timeout=kwargs.get('max_time') ) wait_finish = threading.Barrier(2, timeout=kwargs.get('max_time')) kill_strings += "killall -9 {};killall -9 {};".format(os.path.basename(benchmark_binary), os.path.basename(gdb)) fi_master_thread = Thread(target=fault_injection_by_signal, kwargs=kwargs) gpus_threads.append(fi_master_thread) #ret=0 for thread in gpus_threads: thread.start() for thread in gpus_threads: thread.join() #ret += acc_fault_injected os.system("rm -f {}/bin/*".format(current_path)) if exit_injector: cf.printf("\nKeyboardInterrupt detected, exiting gracefully!( at least trying :) )") else: cf.printf("Fault injection finished, results can be found in {}".format(csv_file)) ######################################################################## #if (iterations==num_rounds): # sys.exit(0) #else: # sys.exit(1) return (iterations==num_rounds) ######################################################################## # Main # ######################################################################## kill_strings = None current_path = None lock = None exit_injector = False gpus_threads = [] if __name__ == "__main__": main()