#!/usr/bin/env python3 from __future__ import print_function import argparse import configparser import dbus import glob import gzip import os import re import struct import subprocess import sys from collections import defaultdict from dbus.mainloop.glib import DBusGMainLoop from errno import EACCES, EPERM from gi.repository import GLib from mmio import MMIO, MMIOError from multiprocessing import cpu_count from platform import uname from threading import Event, Thread from time import time DEFAULT_SYSFS_POWER_PATH = '/sys/class/power_supply/AC*/online' VOLTAGE_PLANES = {'CORE': 0, 'GPU': 1, 'CACHE': 2, 'UNCORE': 3, 'ANALOGIO': 4} CURRENT_PLANES = {'CORE': 0, 'GPU': 1, 'CACHE': 2} TRIP_TEMP_RANGE = [40, 97] UNDERVOLT_KEYS = ('UNDERVOLT', 'UNDERVOLT.AC', 'UNDERVOLT.BATTERY') ICCMAX_KEYS = ('ICCMAX', 'ICCMAX.AC', 'ICCMAX.BATTERY') power = {'source': None, 'method': 'polling'} platform_info_bits = { 'maximum_non_turbo_ratio': [8, 15], 'maximum_efficiency_ratio': [40, 47], 'minimum_operating_ratio': [48, 55], 'feature_ppin_cap': [23, 23], 'feature_programmable_turbo_ratio': [28, 28], 'feature_programmable_tdp_limit': [29, 29], 'number_of_additional_tdp_profiles': [33, 34], 'feature_programmable_temperature_target': [30, 30], 'feature_low_power_mode': [32, 32], } thermal_status_bits = { 'thermal_limit_status': [0, 0], 'thermal_limit_log': [1, 1], 'prochot_or_forcepr_status': [2, 2], 'prochot_or_forcepr_log': [3, 3], 'crit_temp_status': [4, 4], 'crit_temp_log': [5, 5], 'thermal_threshold1_status': [6, 6], 'thermal_threshold1_log': [7, 7], 'thermal_threshold2_status': [8, 8], 'thermal_threshold2_log': [9, 9], 'power_limit_status': [10, 10], 'power_limit_log': [11, 11], 'current_limit_status': [12, 12], 'current_limit_log': [13, 13], 'cross_domain_limit_status': [14, 14], 'cross_domain_limit_log': [15, 15], 'cpu_temp': [16, 22], 'temp_resolution': [27, 30], 'reading_valid': [31, 31], } supported_cpus = { 'Haswell': (0x3C, 0x3F, 0x45, 0x46), 'Broadwell': (0x3D, 0x47, 0x4F, 0x56), 'Skylake': (0x4E, 0x55), 'Skylake-S': (0x5E,), 'Ice Lake': (0x7E,), 'Kaby Lake (R)': (0x8E, 0x9E), 'Coffee Lake': (0x9E,), 'Cannon Lake': (0x66,), } class bcolors: YELLOW = '\033[93m' GREEN = '\033[92m' RED = '\033[91m' RESET = '\033[0m' BOLD = '\033[1m' OK = bcolors.GREEN + bcolors.BOLD + 'OK' + bcolors.RESET ERR = bcolors.RED + bcolors.BOLD + 'ERR' + bcolors.RESET LIM = bcolors.YELLOW + bcolors.BOLD + 'LIM' + bcolors.RESET def fatal(msg, code=1): print('[E] {:s}'.format(msg), file=sys.stderr) sys.exit(code) def warning(msg): print('[W] {:s}'.format(msg), file=sys.stderr) def writemsr(msr, val): msr_list = ['/dev/cpu/{:d}/msr'.format(x) for x in range(cpu_count())] if not os.path.exists(msr_list[0]): try: subprocess.check_call(('modprobe', 'msr')) except subprocess.CalledProcessError: fatal('Unable to load the msr module.') try: for addr in msr_list: f = os.open(addr, os.O_WRONLY) os.lseek(f, msr, os.SEEK_SET) os.write(f, struct.pack('Q', val)) os.close(f) except (IOError, OSError) as e: if e.errno == EPERM or e.errno == EACCES: fatal( 'Unable to write to MSR. Try to disable Secure Boot ' 'and check if your kernel does not restrict access to MSR.' ) else: raise e # returns the value between from_bit and to_bit as unsigned long def readmsr(msr, from_bit=0, to_bit=63, cpu=None, flatten=False): assert cpu is None or cpu in range(cpu_count()) if from_bit > to_bit: fatal('Wrong readmsr bit params') msr_list = ['/dev/cpu/{:d}/msr'.format(x) for x in range(cpu_count())] if not os.path.exists(msr_list[0]): try: subprocess.check_call(('modprobe', 'msr')) except subprocess.CalledProcessError: fatal('Unable to load the msr module.') try: output = [] for addr in msr_list: f = os.open(addr, os.O_RDONLY) os.lseek(f, msr, os.SEEK_SET) val = struct.unpack('Q', os.read(f, 8))[0] os.close(f) output.append(get_value_for_bits(val, from_bit, to_bit)) if flatten: return output[0] if len(set(output)) == 1 else output return output[cpu] if cpu is not None else output except (IOError, OSError) as e: if e.errno == EPERM or e.errno == EACCES: fatal('Unable to read from MSR. Try to disable Secure Boot.') else: raise e def cpu_usage_pct(exit_event, interval=1.0): last_idle = last_total = 0 for i in range(2): with open('/proc/stat') as f: fields = [float(column) for column in f.readline().strip().split()[1:]] idle, total = fields[3], sum(fields) idle_delta, total_delta = idle - last_idle, total - last_total last_idle, last_total = idle, total if i == 0: exit_event.wait(interval) return 100.0 * (1.0 - idle_delta / total_delta) def get_value_for_bits(val, from_bit=0, to_bit=63): mask = sum(2 ** x for x in range(from_bit, to_bit + 1)) return (val & mask) >> from_bit def is_on_battery(config): try: for path in glob.glob(config.get('GENERAL', 'Sysfs_Power_Path', fallback=DEFAULT_SYSFS_POWER_PATH)): with open(path) as f: return not bool(int(f.read())) raise except: warning('No valid Sysfs_Power_Path found! Trying upower method #1') try: out = subprocess.check_output(('upower', '-i', '/org/freedesktop/UPower/devices/line_power_AC')) res = re.search(rb'online:\s+(yes|no)', out).group(1).decode().strip() if res == 'yes': return False elif res == 'no': return True raise except: warning('Trying upower method #2') try: out = subprocess.check_output(('upower', '-i', '/org/freedesktop/UPower/devices/battery_BAT0')) res = re.search(rb'state:\s+(.+)', out).group(1).decode().strip() if res == 'discharging': return True elif res in ('fully-charged', 'charging'): return False except: pass warning('No valid power detection methods found. Assuming that the system is running on battery power.') return True def get_cpu_platform_info(): features_msr_value = readmsr(0xCE, cpu=0) cpu_platform_info = {} for key, value in platform_info_bits.items(): cpu_platform_info[key] = int(get_value_for_bits(features_msr_value, value[0], value[1])) return cpu_platform_info def get_reset_thermal_status(): # read thermal status thermal_status_msr_value = readmsr(0x19C) thermal_status = [] for core in range(cpu_count()): thermal_status_core = {} for key, value in thermal_status_bits.items(): thermal_status_core[key] = int(get_value_for_bits(thermal_status_msr_value[core], value[0], value[1])) thermal_status.append(thermal_status_core) # reset log bits writemsr(0x19C, 0) return thermal_status def get_time_unit(): # 0.000977 is the time unit of my CPU # TODO formula might be different for other CPUs return 1.0 / 2 ** readmsr(0x606, 16, 19, cpu=0) def get_power_unit(): # 0.125 is the power unit of my CPU # TODO formula might be different for other CPUs return 1.0 / 2 ** readmsr(0x606, 0, 3, cpu=0) def get_critical_temp(): # the critical temperature for my CPU is 100 'C return readmsr(0x1A2, 16, 23, cpu=0) def get_cur_pkg_power_limits(): value = readmsr(0x610, 0, 55, flatten=True) return { 'PL1': get_value_for_bits(value, 0, 14), 'TW1': get_value_for_bits(value, 17, 23), 'PL2': get_value_for_bits(value, 32, 46), 'TW2': get_value_for_bits(value, 49, 55), } def calc_time_window_vars(t): time_unit = get_time_unit() for Y in range(2 ** 5): for Z in range(2 ** 2): if t <= (2 ** Y) * (1.0 + Z / 4.0) * time_unit: return (Y, Z) raise ValueError('Unable to find a good combination!') def calc_undervolt_msr(plane, offset): """Return the value to be written in the MSR 150h for setting the given offset voltage (in mV) to the given voltage plane. """ assert offset <= 0 assert plane in VOLTAGE_PLANES offset = int(round(offset * 1.024)) offset = 0xFFE00000 & ((offset & 0xFFF) << 21) return 0x8000001100000000 | (VOLTAGE_PLANES[plane] << 40) | offset def calc_undervolt_mv(msr_value): """Return the offset voltage (in mV) from the given raw MSR 150h value. """ offset = (msr_value & 0xFFE00000) >> 21 offset = offset if offset <= 0x400 else -(0x800 - offset) return int(round(offset / 1.024)) def get_undervolt(plane=None, convert=False): planes = [plane] if plane in VOLTAGE_PLANES else VOLTAGE_PLANES out = {} for plane in planes: writemsr(0x150, 0x8000001000000000 | (VOLTAGE_PLANES[plane] << 40)) read_value = readmsr(0x150, flatten=True) & 0xFFFFFFFF out[plane] = calc_undervolt_mv(read_value) if convert else read_value return out def undervolt(config): for plane in VOLTAGE_PLANES: write_offset_mv = config.getfloat( 'UNDERVOLT.{:s}'.format(power['source']), plane, fallback=config.getfloat('UNDERVOLT', plane, fallback=0.0) ) write_value = calc_undervolt_msr(plane, write_offset_mv) writemsr(0x150, write_value) if args.debug: write_value &= 0xFFFFFFFF read_value = get_undervolt(plane)[plane] read_offset_mv = calc_undervolt_mv(read_value) match = OK if write_value == read_value else ERR print( '[D] Undervolt plane {:s} - write {:.0f} mV ({:#x}) - read {:.0f} mV ({:#x}) - match {}'.format( plane, write_offset_mv, write_value, read_offset_mv, read_value, match ) ) def calc_icc_max_msr(plane, current): """Return the value to be written in the MSR 150h for setting the given IccMax (in A) to the given current plane. """ assert 0 < current <= 0x3FF assert plane in CURRENT_PLANES current = int(round(current * 4)) return 0x8000001700000000 | (CURRENT_PLANES[plane] << 40) | current def calc_icc_max_amp(msr_value): """Return the max current (in A) from the given raw MSR 150h value. """ return (msr_value & 0x3FF) / 4.0 def get_icc_max(plane=None, convert=False): planes = [plane] if plane in CURRENT_PLANES else CURRENT_PLANES out = {} for plane in planes: writemsr(0x150, 0x8000001600000000 | (CURRENT_PLANES[plane] << 40)) read_value = readmsr(0x150, flatten=True) & 0x3FF out[plane] = calc_icc_max_amp(read_value) if convert else read_value return out def set_icc_max(config): for plane in CURRENT_PLANES: try: write_current_amp = config.getfloat( 'ICCMAX.{:s}'.format(power['source']), plane, fallback=config.getfloat('ICCMAX', plane, fallback=-1.0) ) if write_current_amp > 0: write_value = calc_icc_max_msr(plane, write_current_amp) writemsr(0x150, write_value) if args.debug: write_value &= 0x3FF read_value = get_icc_max(plane)[plane] read_current_A = calc_icc_max_amp(read_value) match = OK if write_value == read_value else ERR print( '[D] IccMax plane {:s} - write {:.2f} A ({:#x}) - read {:.2f} A ({:#x}) - match {}'.format( plane, write_current_amp, write_value, read_current_A, read_value, match ) ) except (configparser.NoSectionError, configparser.NoOptionError): pass def load_config(): config = configparser.ConfigParser() config.read(args.config) # config values sanity check for power_source in ('AC', 'BATTERY'): for option in ('Update_Rate_s', 'PL1_Tdp_W', 'PL1_Duration_s', 'PL2_Tdp_W', 'PL2_Duration_S'): value = config.getfloat(power_source, option, fallback=None) if value is not None: value = config.set(power_source, option, str(max(0.1, value))) elif option == 'Update_Rate_s': fatal('The mandatory "Update_Rate_s" parameter is missing.') trip_temp = config.getfloat(power_source, 'Trip_Temp_C', fallback=None) if trip_temp is not None: valid_trip_temp = min(TRIP_TEMP_RANGE[1], max(TRIP_TEMP_RANGE[0], trip_temp)) if trip_temp != valid_trip_temp: config.set(power_source, 'Trip_Temp_C', str(valid_trip_temp)) print( '[!] Overriding invalid "Trip_Temp_C" value in "{:s}": {:.1f} -> {:.1f}'.format( power_source, trip_temp, valid_trip_temp ) ) # fix any invalid value (ie. > 0) in the undervolt settings for key in UNDERVOLT_KEYS: for plane in VOLTAGE_PLANES: if key in config: value = config.getfloat(key, plane) valid_value = min(0, value) if value != valid_value: config.set(key, plane, str(valid_value)) print( '[!] Overriding invalid "{:s}" value in "{:s}" voltage plane: {:.0f} -> {:.0f}'.format( key, plane, value, valid_value ) ) # handle the case where only one of UNDERVOLT.AC, UNDERVOLT.BATTERY keys exists # by forcing the other key to all zeros (ie. no undervolt) if any(key in config for key in UNDERVOLT_KEYS[1:]): for key in UNDERVOLT_KEYS[1:]: if key not in config: config.add_section(key) for plane in VOLTAGE_PLANES: value = config.getfloat(key, plane, fallback=0.0) config.set(key, plane, str(value)) iccmax_enabled = False # check for invalid values (ie. <= 0 or > 0x3FF) in the IccMax settings for key in ICCMAX_KEYS: for plane in CURRENT_PLANES: if key in config: try: value = config.getfloat(key, plane) if value <= 0 or value >= 0x3FF: raise ValueError iccmax_enabled = True except ValueError: warning('Invalid value for {:s} in {:s}'.format(plane, key)) config.remove_option(key, plane) except configparser.NoOptionError: pass if iccmax_enabled: warning('Warning! Raising IccMax above design limits can damage your system!') return config def calc_reg_values(platform_info, config): regs = defaultdict(dict) for power_source in ('AC', 'BATTERY'): if platform_info['feature_programmable_temperature_target'] != 1: warning("Setting temperature target is not supported by this CPU") else: # the critical temperature for my CPU is 100 'C critical_temp = get_critical_temp() # update the allowed temp range to keep at least 3 'C from the CPU critical temperature global TRIP_TEMP_RANGE TRIP_TEMP_RANGE[1] = min(TRIP_TEMP_RANGE[1], critical_temp - 3) Trip_Temp_C = config.getfloat(power_source, 'Trip_Temp_C', fallback=None) if Trip_Temp_C is not None: trip_offset = int(round(critical_temp - Trip_Temp_C)) regs[power_source]['MSR_TEMPERATURE_TARGET'] = trip_offset << 24 else: print('[I] {:s} trip temperature is disabled in config.'.format(power_source)) power_unit = get_power_unit() PL1_Tdp_W = config.getfloat(power_source, 'PL1_Tdp_W', fallback=None) PL1_Duration_s = config.getfloat(power_source, 'PL1_Duration_s', fallback=None) PL2_Tdp_W = config.getfloat(power_source, 'PL2_Tdp_W', fallback=None) PL2_Duration_s = config.getfloat(power_source, 'PL2_Duration_s', fallback=None) if (PL1_Tdp_W, PL1_Duration_s, PL2_Tdp_W, PL2_Duration_s).count(None) < 4: cur_pkg_power_limits = get_cur_pkg_power_limits() if PL1_Tdp_W is None: PL1 = cur_pkg_power_limits['PL1'] print('[I] {:s} PL1_Tdp_W disabled in config.'.format(power_source)) else: PL1 = int(round(PL1_Tdp_W / power_unit)) if PL1_Duration_s is None: TW1 = cur_pkg_power_limits['TW1'] print('[I] {:s} PL1_Duration_s disabled in config.'.format(power_source)) else: Y, Z = calc_time_window_vars(PL1_Duration_s) TW1 = Y | (Z << 5) if PL2_Tdp_W is None: PL2 = cur_pkg_power_limits['PL2'] print('[I] {:s} PL2_Tdp_W disabled in config.'.format(power_source)) else: PL2 = int(round(PL2_Tdp_W / power_unit)) if PL2_Duration_s is None: TW2 = cur_pkg_power_limits['TW2'] print('[I] {:s} PL2_Duration_s disabled in config.'.format(power_source)) else: Y, Z = calc_time_window_vars(PL2_Duration_s) TW2 = Y | (Z << 5) regs[power_source]['MSR_PKG_POWER_LIMIT'] = ( PL1 | (1 << 15) | (TW1 << 17) | (PL2 << 32) | (1 << 47) | (TW2 << 49) ) else: print('[I] {:s} package power limits are disabled in config.'.format(power_source)) # cTDP c_tdp_target_value = config.getint(power_source, 'cTDP', fallback=None) if c_tdp_target_value is not None: if platform_info['feature_programmable_tdp_limit'] != 1: print("[W] cTDP setting not supported by this CPU") elif platform_info['number_of_additional_tdp_profiles'] < c_tdp_target_value: print("[W] the configured cTDP profile is not supported by this CPU") else: valid_c_tdp_target_value = max(0, c_tdp_target_value) regs[power_source]['MSR_CONFIG_TDP_CONTROL'] = valid_c_tdp_target_value return regs def set_hwp(pref): # set HWP energy performance hints assert pref in ('performance', 'balance_performance', 'default', 'balance_power', 'power') CPUs = [ '/sys/devices/system/cpu/cpu{:d}/cpufreq/energy_performance_preference'.format(x) for x in range(cpu_count()) ] for i, c in enumerate(CPUs): with open(c, 'wb') as f: f.write(pref.encode()) if args.debug: with open(c) as f: read_value = f.read().strip() match = OK if pref == read_value else ERR print('[D] HWP for cpu{:d} - write "{:s}" - read "{:s}" - match {}'.format(i, pref, read_value, match)) def power_thread(config, regs, exit_event): try: mchbar_mmio = MMIO(0xFED159A0, 8) except MMIOError: fatal('Unable to open /dev/mem. Try to disable Secure Boot.') while not exit_event.is_set(): # print thermal status if args.debug: thermal_status = get_reset_thermal_status() for index, core_thermal_status in enumerate(thermal_status): for key, value in core_thermal_status.items(): print('[D] core {} thermal status: {} = {}'.format(index, key.replace("_", " "), value)) # switch back to sysfs polling if power['method'] == 'polling': power['source'] = 'BATTERY' if is_on_battery(config) else 'AC' # set temperature trip point if 'MSR_TEMPERATURE_TARGET' in regs[power['source']]: write_value = regs[power['source']]['MSR_TEMPERATURE_TARGET'] writemsr(0x1A2, write_value) if args.debug: read_value = readmsr(0x1A2, 24, 29, flatten=True) match = OK if write_value >> 24 == read_value else ERR print( '[D] TEMPERATURE_TARGET - write {:#x} - read {:#x} - match {}'.format( write_value >> 24, read_value, match ) ) # set cTDP if 'MSR_CONFIG_TDP_CONTROL' in regs[power['source']]: write_value = regs[power['source']]['MSR_CONFIG_TDP_CONTROL'] writemsr(0x64B, write_value) if args.debug: read_value = readmsr(0x64B, 0, 1, flatten=True) match = OK if write_value == read_value else ERR print( '[D] CONFIG_TDP_CONTROL - write {:#x} - read {:#x} - match {}'.format( write_value, read_value, match ) ) # set PL1/2 on MSR write_value = regs[power['source']]['MSR_PKG_POWER_LIMIT'] writemsr(0x610, write_value) if args.debug: read_value = readmsr(0x610, 0, 55, flatten=True) match = OK if write_value == read_value else ERR print( '[D] MSR PACKAGE_POWER_LIMIT - write {:#x} - read {:#x} - match {}'.format( write_value, read_value, match ) ) # set MCHBAR register to the same PL1/2 values mchbar_mmio.write32(0, write_value & 0xFFFFFFFF) mchbar_mmio.write32(4, write_value >> 32) if args.debug: read_value = mchbar_mmio.read32(0) | (mchbar_mmio.read32(4) << 32) match = OK if write_value == read_value else ERR print( '[D] MCHBAR PACKAGE_POWER_LIMIT - write {:#x} - read {:#x} - match {}'.format( write_value, read_value, match ) ) wait_t = config.getfloat(power['source'], 'Update_Rate_s') enable_hwp_mode = config.getboolean('AC', 'HWP_Mode', fallback=False) if power['source'] == 'AC' and enable_hwp_mode: cpu_usage = cpu_usage_pct(exit_event, interval=wait_t) # set full performance mode only when load is greater than this threshold (~ at least 1 core full speed) performance_mode = cpu_usage > 100.0 / (cpu_count() * 1.25) # check again if we are on AC, since in the meantime we might have switched to BATTERY if (power['method'] == 'dbus' and power['source'] == 'AC') or ( power['method'] == 'polling' and not is_on_battery(config) ): set_hwp('performance' if performance_mode else 'balance_performance') else: exit_event.wait(wait_t) def check_kernel(): if os.geteuid() != 0: fatal('No root no party. Try again with sudo.') kernel_config = None try: with open(os.path.join('/boot', 'config-{:s}'.format(uname()[2]))) as f: kernel_config = f.read() except IOError: config_gz_path = os.path.join('/proc', 'config.gz') try: if not os.path.isfile(config_gz_path): subprocess.check_call(('modprobe', 'configs')) with gzip.open(config_gz_path) as f: kernel_config = f.read().decode() except (subprocess.CalledProcessError, IOError): pass if kernel_config is None: print('[W] Unable to obtain and validate kernel config.') elif not re.search('CONFIG_DEVMEM=y', kernel_config): fatal('Bad kernel config: you need CONFIG_DEVMEM=y.') elif not re.search('CONFIG_X86_MSR=(y|m)', kernel_config): fatal('Bad kernel config: you need CONFIG_X86_MSR builtin or as module.') def check_cpu(): try: with open('/proc/cpuinfo') as f: cpuinfo = {} for row in f.readlines(): try: key, value = map(lambda x: x.strip(), row.split(':')) if key == 'processor' and value == '1': break try: cpuinfo[key] = int(value, 0) except ValueError: cpuinfo[key] = value except ValueError: pass if cpuinfo['vendor_id'] != 'GenuineIntel': fatal('This tool is designed for Intel CPUs only.') cpu_model = None for model in supported_cpus: if cpuinfo['model'] in supported_cpus[model]: cpu_model = model break if cpuinfo['cpu family'] != 6 or cpu_model is None: fatal('Your CPU model is not supported.') print('[I] Detected CPU architecture: Intel {:s}'.format(cpu_model)) except: fatal('Unable to identify CPU model.') def monitor(exit_event, wait): IA32_THERM_STATUS = 0x19C IA32_PERF_STATUS = 0x198 MSR_RAPL_POWER_UNIT = 0x606 MSR_INTEL_PKG_ENERGY_STATUS = 0x611 MSR_PP1_ENERGY_STATUS = 0x641 MSR_DRAM_ENERGY_STATUS = 0x619 wait = max(0.1, wait) rapl_power_unit = 0.5 ** readmsr(MSR_RAPL_POWER_UNIT, from_bit=8, to_bit=12, cpu=0) power_plane_msr = { 'Package': MSR_INTEL_PKG_ENERGY_STATUS, 'Graphics': MSR_PP1_ENERGY_STATUS, 'DRAM': MSR_DRAM_ENERGY_STATUS, } prev_energy = { 'Package': (readmsr(MSR_INTEL_PKG_ENERGY_STATUS, cpu=0) * rapl_power_unit, time()), 'Graphics': (readmsr(MSR_PP1_ENERGY_STATUS, cpu=0) * rapl_power_unit, time()), 'DRAM': (readmsr(MSR_DRAM_ENERGY_STATUS, cpu=0) * rapl_power_unit, time()), } undervolt_values = get_undervolt(convert=True) undervolt_output = ' | '.join('{:s}: {:.2f} mV'.format(plane, undervolt_values[plane]) for plane in VOLTAGE_PLANES) print('[D] Undervolt offsets: {:s}'.format(undervolt_output)) iccmax_values = get_icc_max(convert=True) iccmax_output = ' | '.join('{:s}: {:.2f} A'.format(plane, iccmax_values[plane]) for plane in CURRENT_PLANES) print('[D] IccMax: {:s}'.format(iccmax_output)) print('[D] Realtime monitoring of throttling causes:\n') while not exit_event.is_set(): value = readmsr(IA32_THERM_STATUS, from_bit=0, to_bit=15, cpu=0) offsets = {'Thermal': 0, 'Power': 10, 'Current': 12, 'Cross-domain (e.g. GPU)': 14} output = ('{:s}: {:s}'.format(cause, LIM if bool((value >> offsets[cause]) & 1) else OK) for cause in offsets) # ugly code, just testing... vcore = readmsr(IA32_PERF_STATUS, from_bit=32, to_bit=47, cpu=0) / (2.0 ** 13) * 1000 stats2 = {'VCore': '{:.0f} mV'.format(vcore)} for power_plane in ('Package', 'Graphics', 'DRAM'): energy_j = readmsr(power_plane_msr[power_plane], cpu=0) * rapl_power_unit now = time() prev_energy[power_plane], energy_w = ( (energy_j, now), (energy_j - prev_energy[power_plane][0]) / (now - prev_energy[power_plane][1]), ) stats2[power_plane] = '{:.1f} W'.format(energy_w) output2 = ('{:s}: {:s}'.format(label, stats2[label]) for label in stats2) print('[{}] {} || {}{}'.format(power['source'], ' - '.join(output), ' - '.join(output2), ' ' * 10), end='\r') exit_event.wait(wait) def main(): global args parser = argparse.ArgumentParser() exclusive_group = parser.add_mutually_exclusive_group() exclusive_group.add_argument('--debug', action='store_true', help='add some debug info and additional checks') exclusive_group.add_argument( '--monitor', metavar='update_rate', const=1.0, type=float, nargs='?', help='realtime monitoring of throttling causes (default 1s)', ) parser.add_argument('--config', default='/etc/lenovo_fix.conf', help='override default config file path') parser.add_argument('--force', action='store_true', help='bypass compatibility checks (EXPERTS only)') args = parser.parse_args() if not args.force: check_kernel() check_cpu() print('[I] Loading config file.') config = load_config() power['source'] = 'BATTERY' if is_on_battery(config) else 'AC' platform_info = get_cpu_platform_info() if args.debug: for key, value in platform_info.items(): print('[D] cpu platform info: {} = {}'.format(key.replace("_", " "), value)) regs = calc_reg_values(platform_info, config) if not config.getboolean('GENERAL', 'Enabled'): return exit_event = Event() thread = Thread(target=power_thread, args=(config, regs, exit_event)) thread.daemon = True thread.start() undervolt(config) set_icc_max(config) # handle dbus events for applying undervolt/IccMax on resume from sleep/hybernate def handle_sleep_callback(sleeping): if not sleeping: undervolt(config) set_icc_max(config) def handle_ac_callback(*args): try: power['source'] = 'BATTERY' if args[1]['Online'] == 0 else 'AC' power['method'] = 'dbus' except: power['method'] = 'polling' DBusGMainLoop(set_as_default=True) bus = dbus.SystemBus() # add dbus receiver only if undervolt/IccMax is enabled in config if any( config.getfloat(key, plane, fallback=0) != 0 for plane in VOLTAGE_PLANES for key in UNDERVOLT_KEYS + ICCMAX_KEYS ): bus.add_signal_receiver( handle_sleep_callback, 'PrepareForSleep', 'org.freedesktop.login1.Manager', 'org.freedesktop.login1' ) bus.add_signal_receiver( handle_ac_callback, signal_name="PropertiesChanged", dbus_interface="org.freedesktop.DBus.Properties", path="/org/freedesktop/UPower/devices/line_power_AC", ) print('[I] Starting main loop.') if args.monitor is not None: monitor_thread = Thread(target=monitor, args=(exit_event, args.monitor)) monitor_thread.daemon = True monitor_thread.start() try: loop = GLib.MainLoop() loop.run() except (KeyboardInterrupt, SystemExit): pass exit_event.set() loop.quit() thread.join(timeout=1) if args.monitor is not None: monitor_thread.join(timeout=0.1) if __name__ == '__main__': main()