#!/usr/bin/env python3 import os import re import sys import json import zipfile import threading import subprocess import itertools import configparser import time import uuid from collections import OrderedDict import paramiko import pandas as pd import rpc import rpc.client from common import * class Server: def __init__(self, name, general_config, server_config): self.name = name self.username = general_config["username"] self.password = general_config["password"] self.transport = general_config["transport"].lower() self.nic_ips = server_config["nic_ips"] self.mode = server_config["mode"] self.irq_scripts_dir = "/usr/src/local/mlnx-tools/ofed_scripts" if "irq_scripts_dir" in server_config and server_config["irq_scripts_dir"]: self.irq_scripts_dir = server_config["irq_scripts_dir"] self.local_nic_info = [] self._nics_json_obj = {} self.svc_restore_dict = {} self.sysctl_restore_dict = {} self.tuned_restore_dict = {} self.governor_restore = "" self.tuned_profile = "" self.enable_adq = False self.adq_priority = None if "adq_enable" in server_config and server_config["adq_enable"]: self.enable_adq = server_config["adq_enable"] self.adq_priority = 1 if "tuned_profile" in server_config: self.tuned_profile = server_config["tuned_profile"] if not re.match("^[A-Za-z0-9]*$", name): self.log_print("Please use a name which contains only letters or numbers") sys.exit(1) def log_print(self, msg): print("[%s] %s" % (self.name, msg), flush=True) def get_uncommented_lines(self, lines): return [line for line in lines if line and not line.startswith('#')] def get_nic_name_by_ip(self, ip): if not self._nics_json_obj: nics_json_obj = self.exec_cmd(["ip", "-j", "address", "show"]) self._nics_json_obj = list(filter(lambda x: x["addr_info"], json.loads(nics_json_obj))) for nic in self._nics_json_obj: for addr in nic["addr_info"]: if ip in addr["local"]: return nic["ifname"] def set_local_nic_info_helper(self): pass def set_local_nic_info(self, pci_info): def extract_network_elements(json_obj): nic_list = [] if isinstance(json_obj, list): for x in json_obj: nic_list.extend(extract_network_elements(x)) elif isinstance(json_obj, dict): if "children" in json_obj: nic_list.extend(extract_network_elements(json_obj["children"])) if "class" in json_obj.keys() and "network" in json_obj["class"]: nic_list.append(json_obj) return nic_list self.local_nic_info = extract_network_elements(pci_info) def exec_cmd(self, cmd, stderr_redirect=False, change_dir=None): return "" def configure_system(self): self.configure_services() self.configure_sysctl() self.configure_tuned() self.configure_cpu_governor() self.configure_irq_affinity() def configure_adq(self): self.adq_load_modules() self.adq_configure_nic() def adq_load_modules(self): self.log_print("Modprobing ADQ-related Linux modules...") adq_module_deps = ["sch_mqprio", "act_mirred", "cls_flower"] for module in adq_module_deps: try: self.exec_cmd(["sudo", "modprobe", module]) self.log_print("%s loaded!" % module) except CalledProcessError as e: self.log_print("ERROR: failed to load module %s" % module) self.log_print("%s resulted in error: %s" % (e.cmd, e.output)) def adq_configure_nic(self): self.log_print("Configuring NIC port settings for ADQ testing...") # Reload the driver first, to make sure any previous settings are re-set. try: self.exec_cmd(["sudo", "rmmod", "ice"]) self.exec_cmd(["sudo", "modprobe", "ice"]) except CalledProcessError as e: self.log_print("ERROR: failed to reload ice module!") self.log_print("%s resulted in error: %s" % (e.cmd, e.output)) nic_names = [self.get_nic_name_by_ip(n) for n in self.nic_ips] for nic in nic_names: self.log_print(nic) try: self.exec_cmd(["sudo", "ethtool", "-K", nic, "hw-tc-offload", "on"]) # Enable hardware TC offload self.exec_cmd(["sudo", "ethtool", "--set-priv-flags", nic, "channel-inline-flow-director", "on"]) # Enable Intel Flow Director self.exec_cmd(["sudo", "ethtool", "--set-priv-flags", nic, "fw-lldp-agent", "off"]) # Disable LLDP self.exec_cmd(["sudo", "ethtool", "--set-priv-flags", nic, "channel-pkt-inspect-optimize", "off"]) # Disable channel packet inspection optimization except CalledProcessError as e: self.log_print("ERROR: failed to configure NIC port using ethtool!") self.log_print("%s resulted in error: %s" % (e.cmd, e.output)) self.log_print("Please update your NIC driver and firmware versions and try again.") self.log_print(self.exec_cmd(["sudo", "ethtool", "-k", nic])) self.log_print(self.exec_cmd(["sudo", "ethtool", "--show-priv-flags", nic])) def configure_services(self): self.log_print("Configuring active services...") svc_config = configparser.ConfigParser(strict=False) # Below list is valid only for RHEL / Fedora systems and might not # contain valid names for other distributions. svc_target_state = { "firewalld": "inactive", "irqbalance": "inactive", "lldpad.service": "inactive", "lldpad.socket": "inactive" } for service in svc_target_state: out = self.exec_cmd(["sudo", "systemctl", "show", "--no-page", service]) out = "\n".join(["[%s]" % service, out]) svc_config.read_string(out) if "LoadError" in svc_config[service] and "not found" in svc_config[service]["LoadError"]: continue service_state = svc_config[service]["ActiveState"] self.log_print("Current state of %s service is %s" % (service, service_state)) self.svc_restore_dict.update({service: service_state}) if service_state != "inactive": self.log_print("Disabling %s. It will be restored after the test has finished." % service) self.exec_cmd(["sudo", "systemctl", "stop", service]) def configure_sysctl(self): self.log_print("Tuning sysctl settings...") busy_read = 0 if self.enable_adq and self.mode == "spdk": busy_read = 1 sysctl_opts = { "net.core.busy_poll": 0, "net.core.busy_read": busy_read, "net.core.somaxconn": 4096, "net.core.netdev_max_backlog": 8192, "net.ipv4.tcp_max_syn_backlog": 16384, "net.core.rmem_max": 268435456, "net.core.wmem_max": 268435456, "net.ipv4.tcp_mem": "268435456 268435456 268435456", "net.ipv4.tcp_rmem": "8192 1048576 33554432", "net.ipv4.tcp_wmem": "8192 1048576 33554432", "net.ipv4.route.flush": 1, "vm.overcommit_memory": 1, } for opt, value in sysctl_opts.items(): self.sysctl_restore_dict.update({opt: self.exec_cmd(["sysctl", "-n", opt]).strip()}) self.log_print(self.exec_cmd(["sudo", "sysctl", "-w", "%s=%s" % (opt, value)]).strip()) def configure_tuned(self): if not self.tuned_profile: self.log_print("WARNING: Tuned profile not set in configration file. Skipping configuration.") return self.log_print("Configuring tuned-adm profile to %s." % self.tuned_profile) service = "tuned" tuned_config = configparser.ConfigParser(strict=False) out = self.exec_cmd(["sudo", "systemctl", "show", "--no-page", service]) out = "\n".join(["[%s]" % service, out]) tuned_config.read_string(out) tuned_state = tuned_config[service]["ActiveState"] self.svc_restore_dict.update({service: tuned_state}) if tuned_state != "inactive": profile = self.exec_cmd(["cat", "/etc/tuned/active_profile"]).strip() profile_mode = self.exec_cmd(["cat", "/etc/tuned/profile_mode"]).strip() self.tuned_restore_dict = { "profile": profile, "mode": profile_mode } self.exec_cmd(["sudo", "systemctl", "start", service]) self.exec_cmd(["sudo", "tuned-adm", "profile", self.tuned_profile]) self.log_print("Tuned profile set to %s." % self.exec_cmd(["cat", "/etc/tuned/active_profile"])) def configure_cpu_governor(self): self.log_print("Setting CPU governor to performance...") # This assumes that there is the same CPU scaling governor on each CPU self.governor_restore = self.exec_cmd(["cat", "/sys/devices/system/cpu/cpu0/cpufreq/scaling_governor"]).strip() self.exec_cmd(["sudo", "cpupower", "frequency-set", "-g", "performance"]) def configure_irq_affinity(self): self.log_print("Setting NIC irq affinity for NICs...") irq_script_path = os.path.join(self.irq_scripts_dir, "set_irq_affinity.sh") nic_names = [self.get_nic_name_by_ip(n) for n in self.nic_ips] for nic in nic_names: irq_cmd = ["sudo", irq_script_path, nic] self.log_print(irq_cmd) self.exec_cmd(irq_cmd, change_dir=self.irq_scripts_dir) def restore_services(self): self.log_print("Restoring services...") for service, state in self.svc_restore_dict.items(): cmd = "stop" if state == "inactive" else "start" self.exec_cmd(["sudo", "systemctl", cmd, service]) def restore_sysctl(self): self.log_print("Restoring sysctl settings...") for opt, value in self.sysctl_restore_dict.items(): self.log_print(self.exec_cmd(["sudo", "sysctl", "-w", "%s=%s" % (opt, value)]).strip()) def restore_tuned(self): self.log_print("Restoring tuned-adm settings...") if not self.tuned_restore_dict: return if self.tuned_restore_dict["mode"] == "auto": self.exec_cmd(["sudo", "tuned-adm", "auto_profile"]) self.log_print("Reverted tuned-adm to auto_profile.") else: self.exec_cmd(["sudo", "tuned-adm", "profile", self.tuned_restore_dict["profile"]]) self.log_print("Reverted tuned-adm to %s profile." % self.tuned_restore_dict["profile"]) def restore_governor(self): self.log_print("Restoring CPU governor setting...") if self.governor_restore: self.exec_cmd(["sudo", "cpupower", "frequency-set", "-g", self.governor_restore]) self.log_print("Reverted CPU governor to %s." % self.governor_restore) class Target(Server): def __init__(self, name, general_config, target_config): super(Target, self).__init__(name, general_config, target_config) # Defaults self.enable_sar = False self.sar_delay = 0 self.sar_interval = 0 self.sar_count = 0 self.enable_pcm = False self.pcm_dir = "" self.pcm_delay = 0 self.pcm_interval = 0 self.pcm_count = 0 self.enable_bandwidth = 0 self.bandwidth_count = 0 self.enable_dpdk_memory = False self.dpdk_wait_time = 0 self.enable_zcopy = False self.scheduler_name = "static" self.null_block = 0 self._nics_json_obj = json.loads(self.exec_cmd(["ip", "-j", "address", "show"])) self.subsystem_info_list = [] if "null_block_devices" in target_config: self.null_block = target_config["null_block_devices"] if "sar_settings" in target_config: self.enable_sar, self.sar_delay, self.sar_interval, self.sar_count = target_config["sar_settings"] if "pcm_settings" in target_config: self.enable_pcm = True self.pcm_dir, self.pcm_delay, self.pcm_interval, self.pcm_count = target_config["pcm_settings"] if "enable_bandwidth" in target_config: self.enable_bandwidth, self.bandwidth_count = target_config["enable_bandwidth"] if "enable_dpdk_memory" in target_config: self.enable_dpdk_memory, self.dpdk_wait_time = target_config["enable_dpdk_memory"] if "scheduler_settings" in target_config: self.scheduler_name = target_config["scheduler_settings"] if "zcopy_settings" in target_config: self.enable_zcopy = target_config["zcopy_settings"] self.script_dir = os.path.dirname(os.path.abspath(sys.argv[0])) self.spdk_dir = os.path.abspath(os.path.join(self.script_dir, "../../../")) self.set_local_nic_info(self.set_local_nic_info_helper()) self.configure_system() if self.enable_adq: self.configure_adq() self.sys_config() def set_local_nic_info_helper(self): return json.loads(self.exec_cmd(["lshw", "-json"])) def exec_cmd(self, cmd, stderr_redirect=False, change_dir=None): stderr_opt = None if stderr_redirect: stderr_opt = subprocess.STDOUT if change_dir: old_cwd = os.getcwd() os.chdir(change_dir) self.log_print("Changing directory to %s" % change_dir) out = check_output(cmd, stderr=stderr_opt).decode(encoding="utf-8") if change_dir: os.chdir(old_cwd) self.log_print("Changing directory to %s" % old_cwd) return out def zip_spdk_sources(self, spdk_dir, dest_file): self.log_print("Zipping SPDK source directory") fh = zipfile.ZipFile(dest_file, "w", zipfile.ZIP_DEFLATED) for root, directories, files in os.walk(spdk_dir, followlinks=True): for file in files: fh.write(os.path.relpath(os.path.join(root, file))) fh.close() self.log_print("Done zipping") def read_json_stats(self, file): with open(file, "r") as json_data: data = json.load(json_data) job_pos = 0 # job_post = 0 because using aggregated results # Check if latency is in nano or microseconds to choose correct dict key def get_lat_unit(key_prefix, dict_section): # key prefix - lat, clat or slat. # dict section - portion of json containing latency bucket in question # Return dict key to access the bucket and unit as string for k, v in dict_section.items(): if k.startswith(key_prefix): return k, k.split("_")[1] def get_clat_percentiles(clat_dict_leaf): if "percentile" in clat_dict_leaf: p99_lat = float(clat_dict_leaf["percentile"]["99.000000"]) p99_9_lat = float(clat_dict_leaf["percentile"]["99.900000"]) p99_99_lat = float(clat_dict_leaf["percentile"]["99.990000"]) p99_999_lat = float(clat_dict_leaf["percentile"]["99.999000"]) return [p99_lat, p99_9_lat, p99_99_lat, p99_999_lat] else: # Latest fio versions do not provide "percentile" results if no # measurements were done, so just return zeroes return [0, 0, 0, 0] read_iops = float(data["jobs"][job_pos]["read"]["iops"]) read_bw = float(data["jobs"][job_pos]["read"]["bw"]) lat_key, lat_unit = get_lat_unit("lat", data["jobs"][job_pos]["read"]) read_avg_lat = float(data["jobs"][job_pos]["read"][lat_key]["mean"]) read_min_lat = float(data["jobs"][job_pos]["read"][lat_key]["min"]) read_max_lat = float(data["jobs"][job_pos]["read"][lat_key]["max"]) clat_key, clat_unit = get_lat_unit("clat", data["jobs"][job_pos]["read"]) read_p99_lat, read_p99_9_lat, read_p99_99_lat, read_p99_999_lat = get_clat_percentiles( data["jobs"][job_pos]["read"][clat_key]) if "ns" in lat_unit: read_avg_lat, read_min_lat, read_max_lat = [x / 1000 for x in [read_avg_lat, read_min_lat, read_max_lat]] if "ns" in clat_unit: read_p99_lat = read_p99_lat / 1000 read_p99_9_lat = read_p99_9_lat / 1000 read_p99_99_lat = read_p99_99_lat / 1000 read_p99_999_lat = read_p99_999_lat / 1000 write_iops = float(data["jobs"][job_pos]["write"]["iops"]) write_bw = float(data["jobs"][job_pos]["write"]["bw"]) lat_key, lat_unit = get_lat_unit("lat", data["jobs"][job_pos]["write"]) write_avg_lat = float(data["jobs"][job_pos]["write"][lat_key]["mean"]) write_min_lat = float(data["jobs"][job_pos]["write"][lat_key]["min"]) write_max_lat = float(data["jobs"][job_pos]["write"][lat_key]["max"]) clat_key, clat_unit = get_lat_unit("clat", data["jobs"][job_pos]["write"]) write_p99_lat, write_p99_9_lat, write_p99_99_lat, write_p99_999_lat = get_clat_percentiles( data["jobs"][job_pos]["write"][clat_key]) if "ns" in lat_unit: write_avg_lat, write_min_lat, write_max_lat = [x / 1000 for x in [write_avg_lat, write_min_lat, write_max_lat]] if "ns" in clat_unit: write_p99_lat = write_p99_lat / 1000 write_p99_9_lat = write_p99_9_lat / 1000 write_p99_99_lat = write_p99_99_lat / 1000 write_p99_999_lat = write_p99_999_lat / 1000 return [read_iops, read_bw, read_avg_lat, read_min_lat, read_max_lat, read_p99_lat, read_p99_9_lat, read_p99_99_lat, read_p99_999_lat, write_iops, write_bw, write_avg_lat, write_min_lat, write_max_lat, write_p99_lat, write_p99_9_lat, write_p99_99_lat, write_p99_999_lat] def parse_results(self, results_dir, initiator_count=None, run_num=None): files = os.listdir(results_dir) fio_files = filter(lambda x: ".fio" in x, files) json_files = [x for x in files if ".json" in x] headers = ["read_iops", "read_bw", "read_avg_lat_us", "read_min_lat_us", "read_max_lat_us", "read_p99_lat_us", "read_p99.9_lat_us", "read_p99.99_lat_us", "read_p99.999_lat_us", "write_iops", "write_bw", "write_avg_lat_us", "write_min_lat_us", "write_max_lat_us", "write_p99_lat_us", "write_p99.9_lat_us", "write_p99.99_lat_us", "write_p99.999_lat_us"] aggr_headers = ["iops", "bw", "avg_lat_us", "min_lat_us", "max_lat_us", "p99_lat_us", "p99.9_lat_us", "p99.99_lat_us", "p99.999_lat_us"] header_line = ",".join(["Name", *headers]) aggr_header_line = ",".join(["Name", *aggr_headers]) # Create empty results file csv_file = "nvmf_results.csv" with open(os.path.join(results_dir, csv_file), "w") as fh: fh.write(aggr_header_line + "\n") rows = set() for fio_config in fio_files: self.log_print("Getting FIO stats for %s" % fio_config) job_name, _ = os.path.splitext(fio_config) # Look in the filename for rwmixread value. Function arguments do # not have that information. # TODO: Improve this function by directly using workload params instead # of regexing through filenames. if "read" in job_name: rw_mixread = 1 elif "write" in job_name: rw_mixread = 0 else: rw_mixread = float(re.search(r"m_(\d+)", job_name).group(1)) / 100 # If "_CPU" exists in name - ignore it # Initiators for the same job could have diffrent num_cores parameter job_name = re.sub(r"_\d+CPU", "", job_name) job_result_files = [x for x in json_files if job_name in x] self.log_print("Matching result files for current fio config:") for j in job_result_files: self.log_print("\t %s" % j) # There may have been more than 1 initiator used in test, need to check that # Result files are created so that string after last "_" separator is server name inits_names = set([os.path.splitext(x)[0].split("_")[-1] for x in job_result_files]) inits_avg_results = [] for i in inits_names: self.log_print("\tGetting stats for initiator %s" % i) # There may have been more than 1 test run for this job, calculate average results for initiator i_results = [x for x in job_result_files if i in x] i_results_filename = re.sub(r"run_\d+_", "", i_results[0].replace("json", "csv")) separate_stats = [] for r in i_results: stats = self.read_json_stats(os.path.join(results_dir, r)) separate_stats.append(stats) self.log_print(stats) init_results = [sum(x) for x in zip(*separate_stats)] init_results = [x / len(separate_stats) for x in init_results] inits_avg_results.append(init_results) self.log_print("\tAverage results for initiator %s" % i) self.log_print(init_results) with open(os.path.join(results_dir, i_results_filename), "w") as fh: fh.write(header_line + "\n") fh.write(",".join([job_name, *["{0:.3f}".format(x) for x in init_results]]) + "\n") # Sum results of all initiators running this FIO job. # Latency results are an average of latencies from accros all initiators. inits_avg_results = [sum(x) for x in zip(*inits_avg_results)] inits_avg_results = OrderedDict(zip(headers, inits_avg_results)) for key in inits_avg_results: if "lat" in key: inits_avg_results[key] /= len(inits_names) # Aggregate separate read/write values into common labels # Take rw_mixread into consideration for mixed read/write workloads. aggregate_results = OrderedDict() for h in aggr_headers: read_stat, write_stat = [float(value) for key, value in inits_avg_results.items() if h in key] if "lat" in h: _ = rw_mixread * read_stat + (1 - rw_mixread) * write_stat else: _ = read_stat + write_stat aggregate_results[h] = "{0:.3f}".format(_) rows.add(",".join([job_name, *aggregate_results.values()])) # Save results to file for row in rows: with open(os.path.join(results_dir, csv_file), "a") as fh: fh.write(row + "\n") self.log_print("You can find the test results in the file %s" % os.path.join(results_dir, csv_file)) def measure_sar(self, results_dir, sar_file_name): self.log_print("Waiting %d delay before measuring SAR stats" % self.sar_delay) time.sleep(self.sar_delay) out = self.exec_cmd(["sar", "-P", "ALL", "%s" % self.sar_interval, "%s" % self.sar_count]) with open(os.path.join(results_dir, sar_file_name), "w") as fh: for line in out.split("\n"): if "Average" in line and "CPU" in line: self.log_print("Summary CPU utilization from SAR:") self.log_print(line) if "Average" in line and "all" in line: self.log_print(line) fh.write(out) def measure_pcm_memory(self, results_dir, pcm_file_name): time.sleep(self.pcm_delay) cmd = ["%s/pcm-memory.x" % self.pcm_dir, "%s" % self.pcm_interval, "-csv=%s/%s" % (results_dir, pcm_file_name)] pcm_memory = subprocess.Popen(cmd) time.sleep(self.pcm_count) pcm_memory.terminate() def measure_pcm(self, results_dir, pcm_file_name): time.sleep(self.pcm_delay) cmd = ["%s/pcm.x" % self.pcm_dir, "%s" % self.pcm_interval, "-i=%s" % self.pcm_count, "-csv=%s/%s" % (results_dir, pcm_file_name)] subprocess.run(cmd) df = pd.read_csv(os.path.join(results_dir, pcm_file_name), header=[0, 1]) df = df.rename(columns=lambda x: re.sub(r'Unnamed:[\w\s]*$', '', x)) skt = df.loc[:, df.columns.get_level_values(1).isin({'UPI0', 'UPI1', 'UPI2'})] skt_pcm_file_name = "_".join(["skt", pcm_file_name]) skt.to_csv(os.path.join(results_dir, skt_pcm_file_name), index=False) def measure_pcm_power(self, results_dir, pcm_power_file_name): time.sleep(self.pcm_delay) out = self.exec_cmd(["%s/pcm-power.x" % self.pcm_dir, "%s" % self.pcm_interval, "-i=%s" % self.pcm_count]) with open(os.path.join(results_dir, pcm_power_file_name), "w") as fh: fh.write(out) def measure_bandwidth(self, results_dir, bandwidth_file_name): self.exec_cmd(["bwm-ng", "-o csv", "-F %s/%s" % (results_dir, bandwidth_file_name), "-a 1", "-t 1000", "-c %s" % self.bandwidth_count]) def measure_dpdk_memory(self, results_dir): self.log_print("INFO: waiting to generate DPDK memory usage") time.sleep(self.dpdk_wait_time) self.log_print("INFO: generating DPDK memory usage") rpc.env.env_dpdk_get_mem_stats os.rename("/tmp/spdk_mem_dump.txt", "%s/spdk_mem_dump.txt" % (results_dir)) def sys_config(self): self.log_print("====Kernel release:====") self.log_print(os.uname().release) self.log_print("====Kernel command line:====") with open('/proc/cmdline') as f: cmdline = f.readlines() self.log_print('\n'.join(self.get_uncommented_lines(cmdline))) self.log_print("====sysctl conf:====") with open('/etc/sysctl.conf') as f: sysctl = f.readlines() self.log_print('\n'.join(self.get_uncommented_lines(sysctl))) self.log_print("====Cpu power info:====") self.log_print(self.exec_cmd(["cpupower", "frequency-info"])) self.log_print("====zcopy settings:====") self.log_print("zcopy enabled: %s" % (self.enable_zcopy)) self.log_print("====Scheduler settings:====") self.log_print("SPDK scheduler: %s" % (self.scheduler_name)) class Initiator(Server): def __init__(self, name, general_config, initiator_config): super(Initiator, self).__init__(name, general_config, initiator_config) # Required fields self.ip = initiator_config["ip"] self.remote_nic_ips = initiator_config["remote_nic_ips"] # Defaults self.cpus_allowed = None self.cpus_allowed_policy = "shared" self.spdk_dir = "/tmp/spdk" self.fio_bin = "/usr/src/fio/fio" self.nvmecli_bin = "nvme" self.cpu_frequency = None self.subsystem_info_list = [] if "spdk_dir" in initiator_config: self.spdk_dir = initiator_config["spdk_dir"] if "fio_bin" in initiator_config: self.fio_bin = initiator_config["fio_bin"] if "nvmecli_bin" in initiator_config: self.nvmecli_bin = initiator_config["nvmecli_bin"] if "cpus_allowed" in initiator_config: self.cpus_allowed = initiator_config["cpus_allowed"] if "cpus_allowed_policy" in initiator_config: self.cpus_allowed_policy = initiator_config["cpus_allowed_policy"] if "cpu_frequency" in initiator_config: self.cpu_frequency = initiator_config["cpu_frequency"] if os.getenv('SPDK_WORKSPACE'): self.spdk_dir = os.getenv('SPDK_WORKSPACE') self.ssh_connection = paramiko.SSHClient() self.ssh_connection.set_missing_host_key_policy(paramiko.AutoAddPolicy()) self.ssh_connection.connect(self.ip, username=self.username, password=self.password) self.exec_cmd(["sudo", "rm", "-rf", "%s/nvmf_perf" % self.spdk_dir]) self.exec_cmd(["mkdir", "-p", "%s" % self.spdk_dir]) self._nics_json_obj = json.loads(self.exec_cmd(["ip", "-j", "address", "show"])) self.set_local_nic_info(self.set_local_nic_info_helper()) self.set_cpu_frequency() self.configure_system() if self.enable_adq: self.configure_adq() self.sys_config() def set_local_nic_info_helper(self): return json.loads(self.exec_cmd(["lshw", "-json"])) def __del__(self): self.ssh_connection.close() def exec_cmd(self, cmd, stderr_redirect=False, change_dir=None): if change_dir: cmd = ["cd", change_dir, ";", *cmd] # In case one of the command elements contains whitespace and is not # already quoted, # (e.g. when calling sysctl) quote it again to prevent expansion # when sending to remote system. for i, c in enumerate(cmd): if (" " in c or "\t" in c) and not (c.startswith("'") and c.endswith("'")): cmd[i] = '"%s"' % c cmd = " ".join(cmd) # Redirect stderr to stdout thanks using get_pty option if needed _, stdout, _ = self.ssh_connection.exec_command(cmd, get_pty=stderr_redirect) out = stdout.read().decode(encoding="utf-8") # Check the return code rc = stdout.channel.recv_exit_status() if rc: raise CalledProcessError(int(rc), cmd, out) return out def put_file(self, local, remote_dest): ftp = self.ssh_connection.open_sftp() ftp.put(local, remote_dest) ftp.close() def get_file(self, remote, local_dest): ftp = self.ssh_connection.open_sftp() ftp.get(remote, local_dest) ftp.close() def copy_result_files(self, dest_dir): self.log_print("Copying results") if not os.path.exists(dest_dir): os.mkdir(dest_dir) # Get list of result files from initiator and copy them back to target file_list = self.exec_cmd(["ls", "%s/nvmf_perf" % self.spdk_dir]).strip().split("\n") for file in file_list: self.get_file(os.path.join(self.spdk_dir, "nvmf_perf", file), os.path.join(dest_dir, file)) self.log_print("Done copying results") def discover_subsystems(self, address_list, subsys_no): num_nvmes = range(0, subsys_no) nvme_discover_output = "" for ip, subsys_no in itertools.product(address_list, num_nvmes): self.log_print("Trying to discover: %s:%s" % (ip, 4420 + subsys_no)) nvme_discover_cmd = ["sudo", "%s" % self.nvmecli_bin, "discover", "-t", "%s" % self.transport, "-s", "%s" % (4420 + subsys_no), "-a", "%s" % ip] try: stdout = self.exec_cmd(nvme_discover_cmd) if stdout: nvme_discover_output = nvme_discover_output + stdout except CalledProcessError: # Do nothing. In case of discovering remote subsystems of kernel target # we expect "nvme discover" to fail a bunch of times because we basically # scan ports. pass subsystems = re.findall(r'trsvcid:\s(\d+)\s+' # get svcid number r'subnqn:\s+([a-zA-Z0-9\.\-\:]+)\s+' # get NQN id r'traddr:\s+(\d{1,3}\.\d{1,3}\.\d{1,3}\.\d{1,3})', # get IP address nvme_discover_output) # from nvme discovery output subsystems = filter(lambda x: x[-1] in address_list, subsystems) subsystems = list(set(subsystems)) subsystems.sort(key=lambda x: x[1]) self.log_print("Found matching subsystems on target side:") for s in subsystems: self.log_print(s) self.subsystem_info_list = subsystems def gen_fio_filename_conf(self, *args, **kwargs): # Logic implemented in SPDKInitiator and KernelInitiator classes pass def gen_fio_config(self, rw, rwmixread, block_size, io_depth, subsys_no, num_jobs=None, ramp_time=0, run_time=10): fio_conf_template = """ [global] ioengine={ioengine} {spdk_conf} thread=1 group_reporting=1 direct=1 percentile_list=50:90:99:99.5:99.9:99.99:99.999 norandommap=1 rw={rw} rwmixread={rwmixread} bs={block_size} time_based=1 ramp_time={ramp_time} runtime={run_time} """ if "spdk" in self.mode: bdev_conf = self.gen_spdk_bdev_conf(self.subsystem_info_list) self.exec_cmd(["echo", "'%s'" % bdev_conf, ">", "%s/bdev.conf" % self.spdk_dir]) ioengine = "%s/build/fio/spdk_bdev" % self.spdk_dir spdk_conf = "spdk_json_conf=%s/bdev.conf" % self.spdk_dir else: ioengine = "libaio" spdk_conf = "" out = self.exec_cmd(["sudo", "nvme", "list", "|", "grep", "-E", "'SPDK|Linux'", "|", "awk", "'{print $1}'"]) subsystems = [x for x in out.split("\n") if "nvme" in x] if self.cpus_allowed is not None: self.log_print("Limiting FIO workload execution on specific cores %s" % self.cpus_allowed) cpus_num = 0 cpus = self.cpus_allowed.split(",") for cpu in cpus: if "-" in cpu: a, b = cpu.split("-") a = int(a) b = int(b) cpus_num += len(range(a, b)) else: cpus_num += 1 self.num_cores = cpus_num threads = range(0, self.num_cores) elif hasattr(self, 'num_cores'): self.log_print("Limiting FIO workload execution to %s cores" % self.num_cores) threads = range(0, int(self.num_cores)) else: self.num_cores = len(subsystems) threads = range(0, len(subsystems)) if "spdk" in self.mode: filename_section = self.gen_fio_filename_conf(self.subsystem_info_list, threads, io_depth, num_jobs) else: filename_section = self.gen_fio_filename_conf(threads, io_depth, num_jobs) fio_config = fio_conf_template.format(ioengine=ioengine, spdk_conf=spdk_conf, rw=rw, rwmixread=rwmixread, block_size=block_size, ramp_time=ramp_time, run_time=run_time) if num_jobs: fio_config = fio_config + "numjobs=%s \n" % num_jobs if self.cpus_allowed is not None: fio_config = fio_config + "cpus_allowed=%s \n" % self.cpus_allowed fio_config = fio_config + "cpus_allowed_policy=%s \n" % self.cpus_allowed_policy fio_config = fio_config + filename_section fio_config_filename = "%s_%s_%s_m_%s" % (block_size, io_depth, rw, rwmixread) if hasattr(self, "num_cores"): fio_config_filename += "_%sCPU" % self.num_cores fio_config_filename += ".fio" self.exec_cmd(["mkdir", "-p", "%s/nvmf_perf" % self.spdk_dir]) self.exec_cmd(["echo", "'%s'" % fio_config, ">", "%s/nvmf_perf/%s" % (self.spdk_dir, fio_config_filename)]) self.log_print("Created FIO Config:") self.log_print(fio_config) return os.path.join(self.spdk_dir, "nvmf_perf", fio_config_filename) def set_cpu_frequency(self): if self.cpu_frequency is not None: try: self.exec_cmd(["sudo", "cpupower", "frequency-set", "-g", "userspace"], True) self.exec_cmd(["sudo", "cpupower", "frequency-set", "-f", "%s" % self.cpu_frequency], True) self.log_print(self.exec_cmd(["sudo", "cpupower", "frequency-info"])) except Exception: self.log_print("ERROR: cpu_frequency will not work when intel_pstate is enabled!") sys.exit() else: self.log_print("WARNING: you have disabled intel_pstate and using default cpu governance.") def run_fio(self, fio_config_file, run_num=None): job_name, _ = os.path.splitext(fio_config_file) self.log_print("Starting FIO run for job: %s" % job_name) self.log_print("Using FIO: %s" % self.fio_bin) if run_num: for i in range(1, run_num + 1): output_filename = job_name + "_run_" + str(i) + "_" + self.name + ".json" output = self.exec_cmd(["sudo", self.fio_bin, fio_config_file, "--output-format=json", "--output=%s" % output_filename], True) self.log_print(output) else: output_filename = job_name + "_" + self.name + ".json" output = self.exec_cmd(["sudo", self.fio_bin, fio_config_file, "--output-format=json", "--output" % output_filename], True) self.log_print(output) self.log_print("FIO run finished. Results in: %s" % output_filename) def sys_config(self): self.log_print("====Kernel release:====") self.log_print(self.exec_cmd(["uname", "-r"])) self.log_print("====Kernel command line:====") cmdline = self.exec_cmd(["cat", "/proc/cmdline"]) self.log_print('\n'.join(self.get_uncommented_lines(cmdline.splitlines()))) self.log_print("====sysctl conf:====") sysctl = self.exec_cmd(["cat", "/etc/sysctl.conf"]) self.log_print('\n'.join(self.get_uncommented_lines(sysctl.splitlines()))) self.log_print("====Cpu power info:====") self.log_print(self.exec_cmd(["cpupower", "frequency-info"])) class KernelTarget(Target): def __init__(self, name, general_config, target_config): super(KernelTarget, self).__init__(name, general_config, target_config) # Defaults self.nvmet_bin = "nvmetcli" if "nvmet_bin" in target_config: self.nvmet_bin = target_config["nvmet_bin"] def __del__(self): nvmet_command(self.nvmet_bin, "clear") def kernel_tgt_gen_subsystem_conf(self, nvme_list, address_list): nvmet_cfg = { "ports": [], "hosts": [], "subsystems": [], } # Split disks between NIC IP's disks_per_ip = int(len(nvme_list) / len(address_list)) disk_chunks = [nvme_list[i * disks_per_ip:disks_per_ip + disks_per_ip * i] for i in range(0, len(address_list))] subsys_no = 1 port_no = 0 for ip, chunk in zip(address_list, disk_chunks): for disk in chunk: nqn = "nqn.2018-09.io.spdk:cnode%s" % subsys_no nvmet_cfg["subsystems"].append({ "allowed_hosts": [], "attr": { "allow_any_host": "1", "serial": "SPDK00%s" % subsys_no, "version": "1.3" }, "namespaces": [ { "device": { "path": disk, "uuid": "%s" % uuid.uuid4() }, "enable": 1, "nsid": subsys_no } ], "nqn": nqn }) nvmet_cfg["ports"].append({ "addr": { "adrfam": "ipv4", "traddr": ip, "trsvcid": "%s" % (4420 + port_no), "trtype": "%s" % self.transport }, "portid": subsys_no, "referrals": [], "subsystems": [nqn] }) subsys_no += 1 port_no += 1 self.subsystem_info_list.append([port_no, nqn, ip]) with open("kernel.conf", "w") as fh: fh.write(json.dumps(nvmet_cfg, indent=2)) pass def tgt_start(self): self.log_print("Configuring kernel NVMeOF Target") if self.null_block: print("Configuring with null block device.") null_blk_list = ["/dev/nullb{}".format(x) for x in range(self.null_block)] self.kernel_tgt_gen_subsystem_conf(null_blk_list, self.nic_ips) self.subsys_no = len(null_blk_list) else: print("Configuring with NVMe drives.") nvme_list = get_nvme_devices() self.kernel_tgt_gen_subsystem_conf(nvme_list, self.nic_ips) self.subsys_no = len(nvme_list) nvmet_command(self.nvmet_bin, "clear") nvmet_command(self.nvmet_bin, "restore kernel.conf") self.log_print("Done configuring kernel NVMeOF Target") class SPDKTarget(Target): def __init__(self, name, general_config, target_config): super(SPDKTarget, self).__init__(name, general_config, target_config) # Required fields self.core_mask = target_config["core_mask"] self.num_cores = self.get_num_cores(self.core_mask) # Defaults self.dif_insert_strip = False self.null_block_dif_type = 0 self.num_shared_buffers = 4096 if "num_shared_buffers" in target_config: self.num_shared_buffers = target_config["num_shared_buffers"] if "null_block_dif_type" in target_config: self.null_block_dif_type = target_config["null_block_dif_type"] if "dif_insert_strip" in target_config: self.dif_insert_strip = target_config["dif_insert_strip"] def get_num_cores(self, core_mask): if "0x" in core_mask: return bin(int(core_mask, 16)).count("1") else: num_cores = 0 core_mask = core_mask.replace("[", "") core_mask = core_mask.replace("]", "") for i in core_mask.split(","): if "-" in i: x, y = i.split("-") num_cores += len(range(int(x), int(y))) + 1 else: num_cores += 1 return num_cores def spdk_tgt_configure(self): self.log_print("Configuring SPDK NVMeOF target via RPC") numa_list = get_used_numa_nodes() # Create RDMA transport layer rpc.nvmf.nvmf_create_transport(self.client, trtype=self.transport, num_shared_buffers=self.num_shared_buffers, dif_insert_or_strip=self.dif_insert_strip, sock_priority=self.adq_priority) self.log_print("SPDK NVMeOF transport layer:") rpc.client.print_dict(rpc.nvmf.nvmf_get_transports(self.client)) if self.null_block: self.spdk_tgt_add_nullblock(self.null_block) self.spdk_tgt_add_subsystem_conf(self.nic_ips, self.null_block) else: self.spdk_tgt_add_nvme_conf() self.spdk_tgt_add_subsystem_conf(self.nic_ips) self.log_print("Done configuring SPDK NVMeOF Target") def spdk_tgt_add_nullblock(self, null_block_count): md_size = 0 block_size = 4096 if self.null_block_dif_type != 0: md_size = 128 self.log_print("Adding null block bdevices to config via RPC") for i in range(null_block_count): self.log_print("Setting bdev protection to :%s" % self.null_block_dif_type) rpc.bdev.bdev_null_create(self.client, 102400, block_size + md_size, "Nvme{}n1".format(i), dif_type=self.null_block_dif_type, md_size=md_size) self.log_print("SPDK Bdevs configuration:") rpc.client.print_dict(rpc.bdev.bdev_get_bdevs(self.client)) def spdk_tgt_add_nvme_conf(self, req_num_disks=None): self.log_print("Adding NVMe bdevs to config via RPC") bdfs = get_nvme_devices_bdf() bdfs = [b.replace(":", ".") for b in bdfs] if req_num_disks: if req_num_disks > len(bdfs): self.log_print("ERROR: Requested number of disks is more than available %s" % len(bdfs)) sys.exit(1) else: bdfs = bdfs[0:req_num_disks] for i, bdf in enumerate(bdfs): rpc.bdev.bdev_nvme_attach_controller(self.client, name="Nvme%s" % i, trtype="PCIe", traddr=bdf) self.log_print("SPDK Bdevs configuration:") rpc.client.print_dict(rpc.bdev.bdev_get_bdevs(self.client)) def spdk_tgt_add_subsystem_conf(self, ips=None, req_num_disks=None): self.log_print("Adding subsystems to config") port = "4420" if not req_num_disks: req_num_disks = get_nvme_devices_count() # Distribute bdevs between provided NICs num_disks = range(0, req_num_disks) if len(num_disks) == 1: disks_per_ip = 1 else: disks_per_ip = int(len(num_disks) / len(ips)) disk_chunks = [num_disks[i * disks_per_ip:disks_per_ip + disks_per_ip * i] for i in range(0, len(ips))] # Create subsystems, add bdevs to namespaces, add listeners for ip, chunk in zip(ips, disk_chunks): for c in chunk: nqn = "nqn.2018-09.io.spdk:cnode%s" % c serial = "SPDK00%s" % c bdev_name = "Nvme%sn1" % c rpc.nvmf.nvmf_create_subsystem(self.client, nqn, serial, allow_any_host=True, max_namespaces=8) rpc.nvmf.nvmf_subsystem_add_ns(self.client, nqn, bdev_name) rpc.nvmf.nvmf_subsystem_add_listener(self.client, nqn, trtype=self.transport, traddr=ip, trsvcid=port, adrfam="ipv4") self.subsystem_info_list.append([port, nqn, ip]) self.log_print("SPDK NVMeOF subsystem configuration:") rpc.client.print_dict(rpc.nvmf.nvmf_get_subsystems(self.client)) def tgt_start(self): if self.null_block: self.subsys_no = 1 else: self.subsys_no = get_nvme_devices_count() self.log_print("Starting SPDK NVMeOF Target process") nvmf_app_path = os.path.join(self.spdk_dir, "build/bin/nvmf_tgt") proc = subprocess.Popen([nvmf_app_path, "--wait-for-rpc", "-m", self.core_mask]) self.pid = os.path.join(self.spdk_dir, "nvmf.pid") with open(self.pid, "w") as fh: fh.write(str(proc.pid)) self.nvmf_proc = proc self.log_print("SPDK NVMeOF Target PID=%s" % self.pid) self.log_print("Waiting for spdk to initilize...") while True: if os.path.exists("/var/tmp/spdk.sock"): break time.sleep(1) self.client = rpc.client.JSONRPCClient("/var/tmp/spdk.sock") if self.enable_zcopy: rpc.sock.sock_impl_set_options(self.client, impl_name="posix", enable_zerocopy_send=True) self.log_print("Target socket options:") rpc.client.print_dict(rpc.sock.sock_impl_get_options(self.client, impl_name="posix")) if self.enable_adq: rpc.sock.sock_impl_set_options(self.client, impl_name="posix", enable_placement_id=1) rpc.bdev.bdev_nvme_set_options(self.client, timeout_us=0, action_on_timeout=None, nvme_adminq_poll_period_us=100000, retry_count=4) rpc.nvmf.nvmf_set_config(self.client, acceptor_poll_rate=10000) rpc.app.framework_set_scheduler(self.client, name=self.scheduler_name) rpc.framework_start_init(self.client) self.spdk_tgt_configure() def __del__(self): if hasattr(self, "nvmf_proc"): try: self.nvmf_proc.terminate() self.nvmf_proc.wait() except Exception as e: self.log_print(e) self.nvmf_proc.kill() self.nvmf_proc.communicate() class KernelInitiator(Initiator): def __init__(self, name, general_config, initiator_config): super(KernelInitiator, self).__init__(name, general_config, initiator_config) # Defaults self.extra_params = "" if "extra_params" in initiator_config: self.extra_params = initiator_config["extra_params"] def __del__(self): self.ssh_connection.close() def kernel_init_connect(self, address_list, subsys_no): self.log_print("Below connection attempts may result in error messages, this is expected!") for subsystem in self.subsystem_info_list: self.log_print("Trying to connect %s %s %s" % subsystem) self.exec_cmd(["sudo", self.nvmecli_bin, "connect", "-t", self.transport, "-s", subsystem[0], "-n", subsystem[1], "-a", subsystem[2], self.extra_params]) time.sleep(2) def kernel_init_disconnect(self, address_list, subsys_no): for subsystem in self.subsystem_info_list: self.exec_cmd(["sudo", self.nvmecli_bin, "disconnect", "-n", subsystem[1]]) time.sleep(1) def gen_fio_filename_conf(self, threads, io_depth, num_jobs=1): out = self.exec_cmd(["sudo", "nvme", "list", "|", "grep", "-E", "'SPDK|Linux'", "|", "awk", "'{print $1}'"]) nvme_list = [x for x in out.split("\n") if "nvme" in x] filename_section = "" nvme_per_split = int(len(nvme_list) / len(threads)) remainder = len(nvme_list) % len(threads) iterator = iter(nvme_list) result = [] for i in range(len(threads)): result.append([]) for j in range(nvme_per_split): result[i].append(next(iterator)) if remainder: result[i].append(next(iterator)) remainder -= 1 for i, r in enumerate(result): header = "[filename%s]" % i disks = "\n".join(["filename=%s" % x for x in r]) job_section_qd = round((io_depth * len(r)) / num_jobs) if job_section_qd == 0: job_section_qd = 1 iodepth = "iodepth=%s" % job_section_qd filename_section = "\n".join([filename_section, header, disks, iodepth]) return filename_section class SPDKInitiator(Initiator): def __init__(self, name, general_config, initiator_config): super(SPDKInitiator, self).__init__(name, general_config, initiator_config) # Required fields self.num_cores = initiator_config["num_cores"] def install_spdk(self, local_spdk_zip): self.put_file(local_spdk_zip, "/tmp/spdk_drop.zip") self.log_print("Copied sources zip from target") self.exec_cmd(["unzip", "-qo", "/tmp/spdk_drop.zip", "-d", self.spdk_dir]) self.log_print("Sources unpacked") self.log_print("Using fio binary %s" % self.fio_bin) self.exec_cmd(["git", "-C", self.spdk_dir, "submodule", "update", "--init"]) self.exec_cmd(["git", "-C", self.spdk_dir, "clean", "-ffdx"]) self.exec_cmd(["cd", self.spdk_dir, "&&", "./configure", "--with-rdma", "--with-fio=%s" % os.path.dirname(self.fio_bin)]) self.exec_cmd(["make", "-C", self.spdk_dir, "clean"]) self.exec_cmd(["make", "-C", self.spdk_dir, "-j$(($(nproc)*2))"]) self.log_print("SPDK built") self.exec_cmd(["sudo", "%s/scripts/setup.sh" % self.spdk_dir]) def gen_spdk_bdev_conf(self, remote_subsystem_list): bdev_cfg_section = { "subsystems": [ { "subsystem": "bdev", "config": [] } ] } for i, subsys in enumerate(remote_subsystem_list): sub_port, sub_nqn, sub_addr = map(lambda x: str(x), subsys) nvme_ctrl = { "method": "bdev_nvme_attach_controller", "params": { "name": "Nvme{}".format(i), "trtype": self.transport, "traddr": sub_addr, "trsvcid": sub_port, "subnqn": sub_nqn, "adrfam": "IPv4" } } if self.enable_adq: nvme_ctrl["params"].update({"priority": "1"}) bdev_cfg_section["subsystems"][0]["config"].append(nvme_ctrl) return json.dumps(bdev_cfg_section, indent=2) def gen_fio_filename_conf(self, subsystems, threads, io_depth, num_jobs=1): filename_section = "" if len(threads) >= len(subsystems): threads = range(0, len(subsystems)) filenames = ["Nvme%sn1" % x for x in range(0, len(subsystems))] nvme_per_split = int(len(subsystems) / len(threads)) remainder = len(subsystems) % len(threads) iterator = iter(filenames) result = [] for i in range(len(threads)): result.append([]) for j in range(nvme_per_split): result[i].append(next(iterator)) if remainder: result[i].append(next(iterator)) remainder -= 1 for i, r in enumerate(result): header = "[filename%s]" % i disks = "\n".join(["filename=%s" % x for x in r]) job_section_qd = round((io_depth * len(r)) / num_jobs) if job_section_qd == 0: job_section_qd = 1 iodepth = "iodepth=%s" % job_section_qd filename_section = "\n".join([filename_section, header, disks, iodepth]) return filename_section if __name__ == "__main__": spdk_zip_path = "/tmp/spdk.zip" target_results_dir = "/tmp/results" if (len(sys.argv) > 1): config_file_path = sys.argv[1] else: script_full_dir = os.path.dirname(os.path.realpath(__file__)) config_file_path = os.path.join(script_full_dir, "config.json") print("Using config file: %s" % config_file_path) with open(config_file_path, "r") as config: data = json.load(config) initiators = [] fio_cases = [] general_config = data["general"] target_config = data["target"] initiator_configs = [data[x] for x in data.keys() if "initiator" in x] for k, v in data.items(): if "target" in k: if data[k]["mode"] == "spdk": target_obj = SPDKTarget(k, data["general"], v) elif data[k]["mode"] == "kernel": target_obj = KernelTarget(k, data["general"], v) pass elif "initiator" in k: if data[k]["mode"] == "spdk": init_obj = SPDKInitiator(k, data["general"], v) elif data[k]["mode"] == "kernel": init_obj = KernelInitiator(k, data["general"], v) initiators.append(init_obj) elif "fio" in k: fio_workloads = itertools.product(data[k]["bs"], data[k]["qd"], data[k]["rw"]) fio_run_time = data[k]["run_time"] fio_ramp_time = data[k]["ramp_time"] fio_rw_mix_read = data[k]["rwmixread"] fio_run_num = data[k]["run_num"] if "run_num" in data[k].keys() else None fio_num_jobs = data[k]["num_jobs"] if "num_jobs" in data[k].keys() else None else: continue # Copy and install SPDK on remote initiators if "skip_spdk_install" not in data["general"]: target_obj.zip_spdk_sources(target_obj.spdk_dir, spdk_zip_path) threads = [] for i in initiators: if i.mode == "spdk": t = threading.Thread(target=i.install_spdk, args=(spdk_zip_path,)) threads.append(t) t.start() for t in threads: t.join() target_obj.tgt_start() try: os.mkdir(target_results_dir) except FileExistsError: pass for i in initiators: i.discover_subsystems(i.remote_nic_ips, target_obj.subsys_no) # Poor mans threading # Run FIO tests for block_size, io_depth, rw in fio_workloads: threads = [] configs = [] for i in initiators: if i.mode == "kernel": i.kernel_init_connect(i.remote_nic_ips, target_obj.subsys_no) cfg = i.gen_fio_config(rw, fio_rw_mix_read, block_size, io_depth, target_obj.subsys_no, fio_num_jobs, fio_ramp_time, fio_run_time) configs.append(cfg) for i, cfg in zip(initiators, configs): t = threading.Thread(target=i.run_fio, args=(cfg, fio_run_num)) threads.append(t) if target_obj.enable_sar: sar_file_name = "_".join([str(block_size), str(rw), str(io_depth), "sar"]) sar_file_name = ".".join([sar_file_name, "txt"]) t = threading.Thread(target=target_obj.measure_sar, args=(target_results_dir, sar_file_name)) threads.append(t) if target_obj.enable_pcm: pcm_fnames = ["%s_%s_%s_%s.csv" % (block_size, rw, io_depth, x) for x in ["pcm_cpu", "pcm_memory", "pcm_power"]] pcm_cpu_t = threading.Thread(target=target_obj.measure_pcm, args=(target_results_dir, pcm_fnames[0],)) pcm_mem_t = threading.Thread(target=target_obj.measure_pcm_memory, args=(target_results_dir, pcm_fnames[1],)) pcm_pow_t = threading.Thread(target=target_obj.measure_pcm_power, args=(target_results_dir, pcm_fnames[2],)) threads.append(pcm_cpu_t) threads.append(pcm_mem_t) threads.append(pcm_pow_t) if target_obj.enable_bandwidth: bandwidth_file_name = "_".join(["bandwidth", str(block_size), str(rw), str(io_depth)]) bandwidth_file_name = ".".join([bandwidth_file_name, "csv"]) t = threading.Thread(target=target_obj.measure_bandwidth, args=(target_results_dir, bandwidth_file_name,)) threads.append(t) if target_obj.enable_dpdk_memory: t = threading.Thread(target=target_obj.measure_dpdk_memory, args=(target_results_dir)) threads.append(t) for t in threads: t.start() for t in threads: t.join() for i in initiators: if i.mode == "kernel": i.kernel_init_disconnect(i.remote_nic_ips, target_obj.subsys_no) i.copy_result_files(target_results_dir) target_obj.restore_governor() target_obj.restore_tuned() target_obj.restore_services() target_obj.restore_sysctl() for i in initiators: i.restore_governor() i.restore_tuned() i.restore_services() i.restore_sysctl() target_obj.parse_results(target_results_dir)