sonic-buildimage/platform/mellanox/mlnx-platform-api/sonic_platform/fan.py

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#!/usr/bin/env python
#############################################################################
# Mellanox
#
# Module contains an implementation of SONiC Platform Base API and
# provides the FANs status which are available in the platform
#
#############################################################################
import os.path
import subprocess
try:
from sonic_platform_base.fan_base import FanBase
except ImportError as e:
raise ImportError (str(e) + "- required module not found")
LED_ON = 1
LED_OFF = 0
PWM_MAX = 255
FAN_PATH = "/var/run/hw-management/thermal/"
LED_PATH = "/var/run/hw-management/led/"
CONFIG_PATH = "/var/run/hw-management/config"
# fan_dir isn't supported on Spectrum 1. It is supported on Spectrum 2 and later switches
FAN_DIR = "/var/run/hw-management/system/fan_dir"
COOLING_STATE_PATH = "/var/run/hw-management/thermal/cooling_cur_state"
# Platforms with unplugable FANs:
# 1. don't have fanX_status and should be treated as always present
platform_with_unplugable_fan = ['x86_64-mlnx_msn2010-r0', 'x86_64-mlnx_msn2100-r0']
class Fan(FanBase):
"""Platform-specific Fan class"""
STATUS_LED_COLOR_ORANGE = "orange"
min_cooling_level = 2
MIN_VALID_COOLING_LEVEL = 1
MAX_VALID_COOLING_LEVEL = 10
# PSU fan speed vector
PSU_FAN_SPEED = ['0x3c', '0x3c', '0x3c', '0x3c', '0x3c',
'0x3c', '0x3c', '0x46', '0x50', '0x5a', '0x64']
def __init__(self, has_fan_dir, fan_index, drawer_index = 1, psu_fan = False, platform = None):
# API index is starting from 0, Mellanox platform index is starting from 1
self.index = fan_index + 1
self.drawer_index = drawer_index + 1
self.is_psu_fan = psu_fan
self.always_presence = False if platform not in platform_with_unplugable_fan else True
self.fan_min_speed_path = "fan{}_min".format(self.index)
if not self.is_psu_fan:
self.fan_speed_get_path = "fan{}_speed_get".format(self.index)
self.fan_speed_set_path = "fan{}_speed_set".format(self.index)
self.fan_presence_path = "fan{}_status".format(self.drawer_index)
self.fan_max_speed_path = "fan{}_max".format(self.index)
self._name = "fan{}".format(fan_index + 1)
else:
self.fan_speed_get_path = "psu{}_fan1_speed_get".format(self.index)
self.fan_presence_path = "psu{}_fan1_speed_get".format(self.index)
self._name = 'psu_{}_fan_{}'.format(self.index, 1)
self.fan_max_speed_path = None
self.psu_i2c_bus_path = os.path.join(CONFIG_PATH, 'psu{0}_i2c_bus'.format(self.index))
self.psu_i2c_addr_path = os.path.join(CONFIG_PATH, 'psu{0}_i2c_addr'.format(self.index))
self.psu_i2c_command_path = os.path.join(CONFIG_PATH, 'fan_command')
self.fan_status_path = "fan{}_fault".format(self.index)
self.fan_green_led_path = "led_fan{}_green".format(self.drawer_index)
self.fan_red_led_path = "led_fan{}_red".format(self.drawer_index)
self.fan_orange_led_path = "led_fan{}_orange".format(self.drawer_index)
self.fan_pwm_path = "pwm1"
self.fan_led_cap_path = "led_fan{}_capability".format(self.drawer_index)
if has_fan_dir:
self.fan_dir = FAN_DIR
else:
self.fan_dir = None
def get_direction(self):
"""
Retrieves the fan's direction
Returns:
A string, either FAN_DIRECTION_INTAKE or FAN_DIRECTION_EXHAUST
depending on fan direction
Notes:
What Mellanox calls forward:
Air flows from fans side to QSFP side, for example: MSN2700-CS2F
which means intake in community
What Mellanox calls reverse:
Air flow from QSFP side to fans side, for example: MSN2700-CS2R
which means exhaust in community
According to hw-mgmt:
1 stands for forward, in other words intake
0 stands for reverse, in other words exhaust
"""
if not self.fan_dir or self.is_psu_fan or not self.get_presence():
return self.FAN_DIRECTION_NOT_APPLICABLE
try:
with open(os.path.join(self.fan_dir), 'r') as fan_dir:
fan_dir_bits = int(fan_dir.read().strip())
fan_mask = 1 << self.drawer_index - 1
if fan_dir_bits & fan_mask:
return self.FAN_DIRECTION_INTAKE
else:
return self.FAN_DIRECTION_EXHAUST
except (ValueError, IOError) as e:
raise RuntimeError("Failed to read fan direction status to {}".format(repr(e)))
def get_name(self):
return self._name
def get_status(self):
"""
Retrieves the operational status of fan
Returns:
bool: True if fan is operating properly, False if not
"""
status = 0
if self.is_psu_fan:
status = 0
else:
try:
with open(os.path.join(FAN_PATH, self.fan_status_path), 'r') as fault_status:
status = int(fault_status.read().strip())
except (ValueError, IOError):
status = 1
return status == 0
def get_presence(self):
"""
Retrieves the presence status of fan
Returns:
bool: True if fan is present, False if not
"""
status = 0
if self.is_psu_fan:
if os.path.exists(os.path.join(FAN_PATH, self.fan_presence_path)):
status = 1
else:
status = 0
else:
if self.always_presence:
status = 1
else:
try:
with open(os.path.join(FAN_PATH, self.fan_presence_path), 'r') as presence_status:
status = int(presence_status.read().strip())
except (ValueError, IOError):
status = 0
return status == 1
def _get_min_speed_in_rpm(self):
speed = 0
try:
with open(os.path.join(FAN_PATH, self.fan_min_speed_path), 'r') as min_fan_speed:
speed = int(min_fan_speed.read())
except (ValueError, IOError):
speed = 0
return speed
def _get_max_speed_in_rpm(self):
speed = 0
try:
with open(os.path.join(FAN_PATH, self.fan_max_speed_path), 'r') as max_fan_speed:
speed = int(max_fan_speed.read().strip())
except (ValueError, IOError):
speed = 0
return speed
def get_speed(self):
"""
Retrieves the speed of fan
Returns:
int: percentage of the max fan speed
"""
speed = 0
try:
with open(os.path.join(FAN_PATH, self.fan_speed_get_path), 'r') as fan_curr_speed:
speed_in_rpm = int(fan_curr_speed.read().strip())
except (ValueError, IOError):
speed_in_rpm = 0
if self.fan_max_speed_path is None:
# in case of max speed unsupported, we just return speed in unit of RPM.
return speed_in_rpm
max_speed_in_rpm = self._get_max_speed_in_rpm()
speed = 100*speed_in_rpm/max_speed_in_rpm
if speed > 100:
speed = 100
return speed
def get_target_speed(self):
"""
Retrieves the expected speed of fan
Returns:
int: percentage of the max fan speed
"""
if self.is_psu_fan:
# Not like system fan, psu fan speed can not be modified, so target speed is N/A
return self.get_speed()
try:
with open(os.path.join(FAN_PATH, self.fan_speed_set_path), 'r') as fan_pwm:
pwm = int(fan_pwm.read().strip())
except (ValueError, IOError):
pwm = 0
speed = int(round(pwm*100.0/PWM_MAX))
return speed
def set_speed(self, speed):
"""
Set fan speed to expected value
Args:
speed: An integer, the percentage of full fan speed to set fan to,
in the range 0 (off) to 100 (full speed)
Returns:
bool: True if set success, False if fail.
"""
status = True
if self.is_psu_fan:
if not self.get_presence():
return False
from .thermal import logger
try:
with open(self.psu_i2c_bus_path, 'r') as f:
bus = f.read().strip()
with open(self.psu_i2c_addr_path, 'r') as f:
addr = f.read().strip()
with open(self.psu_i2c_command_path, 'r') as f:
command = f.read().strip()
speed = Fan.PSU_FAN_SPEED[int(speed / 10)]
command = "i2cset -f -y {0} {1} {2} {3} wp".format(bus, addr, command, speed)
subprocess.check_call(command, shell = True)
return True
except subprocess.CalledProcessError as ce:
logger.log_error('Failed to call command {}, return code={}, command output={}'.format(ce.cmd, ce.returncode, ce.output))
return False
except Exception as e:
logger.log_error('Failed to set PSU FAN speed - {}'.format(e))
return False
try:
cooling_level = int(speed / 10)
if cooling_level < self.min_cooling_level:
cooling_level = self.min_cooling_level
speed = self.min_cooling_level * 10
self.set_cooling_level(cooling_level, cooling_level)
pwm = int(round(PWM_MAX*speed/100.0))
with open(os.path.join(FAN_PATH, self.fan_speed_set_path), 'w') as fan_pwm:
fan_pwm.write(str(pwm))
except (ValueError, IOError):
status = False
return status
def _get_led_capability(self):
cap_list = None
try:
with open(os.path.join(LED_PATH, self.fan_led_cap_path), 'r') as fan_led_cap:
caps = fan_led_cap.read()
cap_list = caps.split()
except (ValueError, IOError):
status = 0
return cap_list
def set_status_led(self, color):
"""
Set led to expected color
Args:
color: A string representing the color with which to set the
fan module status LED
Returns:
bool: True if set success, False if fail.
"""
led_cap_list = self._get_led_capability()
if led_cap_list is None:
return False
if self.is_psu_fan:
# PSU fan led status is not able to set
return False
status = False
try:
if color == 'green':
with open(os.path.join(LED_PATH, self.fan_green_led_path), 'w') as fan_led:
fan_led.write(str(LED_ON))
elif color == 'red':
# Some fan don't support red led but support orange led, in this case we set led to orange
if 'red' in led_cap_list:
led_path = os.path.join(LED_PATH, self.fan_red_led_path)
elif 'orange' in led_cap_list:
led_path = os.path.join(LED_PATH, self.fan_orange_led_path)
else:
return False
with open(led_path, 'w') as fan_led:
fan_led.write(str(LED_ON))
elif color == 'off':
with open(os.path.join(LED_PATH, self.fan_green_led_path), 'w') as fan_led:
fan_led.write(str(LED_OFF))
with open(os.path.join(LED_PATH, self.fan_red_led_path), 'w') as fan_led:
fan_led.write(str(LED_OFF))
else:
status = False
except (ValueError, IOError):
status = False
return status
def get_speed_tolerance(self):
"""
Retrieves the speed tolerance of the fan
Returns:
An integer, the percentage of variance from target speed which is
considered tolerable
"""
# The tolerance value is fixed as 50% for all the Mellanox platform
return 50
@classmethod
def set_cooling_level(cls, level, cur_state):
"""
Change cooling level. The input level should be an integer value [1, 10].
1 means 10%, 2 means 20%, 10 means 100%.
"""
if not isinstance(level, int):
raise RuntimeError("Failed to set cooling level, input parameter must be integer")
if level < cls.MIN_VALID_COOLING_LEVEL or level > cls.MAX_VALID_COOLING_LEVEL:
raise RuntimeError("Failed to set cooling level, level value must be in range [{}, {}], got {}".format(
cls.MIN_VALID_COOLING_LEVEL,
cls.MAX_VALID_COOLING_LEVEL,
level
))
try:
# Reset FAN cooling level vector. According to low level team,
# if we need set cooling level to X, we need first write a (10+X)
# to cooling_cur_state file to reset the cooling level vector.
with open(COOLING_STATE_PATH, 'w') as cooling_state:
cooling_state.write(str(level + 10))
# We need set cooling level after resetting the cooling level vector
with open(COOLING_STATE_PATH, 'w') as cooling_state:
cooling_state.write(str(cur_state))
except (ValueError, IOError) as e:
raise RuntimeError("Failed to set cooling level - {}".format(e))
@classmethod
def get_cooling_level(cls):
try:
with open(COOLING_STATE_PATH, 'r') as cooling_state:
cooling_level = int(cooling_state.read().strip())
return cooling_level
except (ValueError, IOError) as e:
raise RuntimeError("Failed to get cooling level - {}".format(e))