private function cpu_temp_linux() { $temp_c = -1; // Try hwmon interface $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/temp2_input', 'POSITIVE_NUMERIC', array('name' => 'coretemp')); if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp1_input', 'POSITIVE_NUMERIC', array('name' => 'k10temp')); } if ($raw_temp == -1) { // Try ACPI thermal // Assuming the system thermal sensor comes 2nd to the ACPI CPU temperature // It appears that way on a ThinkPad T60, but TODO find a better way to validate $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/thermal/thermal_zone*/temp', 'POSITIVE_NUMERIC', null, 2); } if ($raw_temp != -1) { if ($raw_temp > 1000) { $raw_temp = $raw_temp / 1000; } $temp_c = pts_math::set_precision($raw_temp, 2); } if ($temp_c == -1) { // Try LM_Sensors $sensors = phodevi_linux_parser::read_sensors(array('CPU Temp', 'Core 0', 'Core0 Temp', 'Core1 Temp')); if ($sensors != false && is_numeric($sensors) && $sensors > 0) { $temp_c = $sensors; } } if (pts_client::executable_in_path('ipmitool')) { $ipmi = phodevi_linux_parser::read_ipmitool_sensor('Temp 0'); if ($ipmi > 0 && is_numeric($ipmi)) { $temp_c = $ipmi; } } return $temp_c; }
public static function read_sensor() { // Read the processor temperature $temp_c = -1; if (phodevi::is_bsd()) { $cpu_temp = phodevi_bsd_parser::read_sysctl(array('hw.sensors.acpi_tz0.temp0', 'dev.cpu.0.temperature', 'hw.sensors.cpu0.temp0')); if ($cpu_temp != false) { if (($end = strpos($cpu_temp, 'degC')) || ($end = strpos($cpu_temp, 'C')) > 0) { $cpu_temp = substr($cpu_temp, 0, $end); } if (is_numeric($cpu_temp)) { $temp_c = $cpu_temp; } } else { $acpi = phodevi_bsd_parser::read_sysctl('hw.acpi.thermal.tz0.temperature'); if (($end = strpos($acpi, 'C')) > 0) { $acpi = substr($acpi, 0, $end); } if (is_numeric($acpi)) { $temp_c = $acpi; } } } else { if (phodevi::is_linux()) { // Try hwmon interface $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp1_input', 'POSITIVE_NUMERIC', array('name' => 'coretemp')); if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp1_input', 'POSITIVE_NUMERIC', array('name' => 'k10temp')); } if ($raw_temp == -1) { // Try ACPI thermal // Assuming the system thermal sensor comes 2nd to the ACPI CPU temperature // It appears that way on a ThinkPad T60, but TODO find a better way to validate $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/thermal/thermal_zone*/temp', 'POSITIVE_NUMERIC', null, 2); } if ($raw_temp != -1) { if ($raw_temp > 1000) { $raw_temp = $raw_temp / 1000; } $temp_c = pts_math::set_precision($raw_temp, 2); } if ($temp_c == -1) { // Try LM_Sensors $sensors = phodevi_linux_parser::read_sensors(array('CPU Temp', 'Core 0', 'Core0 Temp', 'Core1 Temp')); if ($sensors != false && is_numeric($sensors) && $sensors > 0) { $temp_c = $sensors; } } if (pts_client::executable_in_path('ipmitool')) { $ipmi = phodevi_linux_parser::read_ipmitool_sensor('Temp 0'); if ($ipmi > 0 && is_numeric($ipmi)) { $temp_c = $ipmi; } } } } return $temp_c; }
public static function read_sensor() { if (phodevi::is_linux()) { $sensor = phodevi_linux_parser::read_sensors(array('V5', '+5V')); } else { $sensor = -1; } return $sensor; }
public static function read_sensor() { if (phodevi::is_linux()) { $sensor = phodevi_linux_parser::read_sensors('VCore'); } else { $sensor = -1; } return $sensor; }
public static function read_sensor() { // Reads the system's temperature $temp_c = -1; if (phodevi::is_linux()) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp3_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp2_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); } if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp1_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); } if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/temp1_input', 'POSITIVE_NUMERIC'); } if ($raw_temp != -1) { if ($raw_temp > 1000) { $raw_temp = $raw_temp / 1000; } $temp_c = pts_math::set_precision($raw_temp, 2); } if ($temp_c == -1) { $acpi = phodevi_linux_parser::read_acpi(array('/thermal_zone/THM1/temperature', '/thermal_zone/TZ00/temperature', '/thermal_zone/TZ01/temperature'), 'temperature'); if (($end = strpos($acpi, ' ')) > 0) { $temp_c = substr($acpi, 0, $end); } } if ($temp_c == -1) { $sensors = phodevi_linux_parser::read_sensors(array('Sys Temp', 'Board Temp')); if ($sensors != false && is_numeric($sensors)) { $temp_c = $sensors; } } if ($temp_c == -1 && is_file('/sys/class/thermal/thermal_zone0/temp')) { $temp_c = pts_file_io::file_get_contents('/sys/class/thermal/thermal_zone0/temp'); if ($temp_c > 1000) { $temp_c = pts_math::set_precision($temp_c / 1000, 1); } } } else { if (phodevi::is_bsd()) { $acpi = phodevi_bsd_parser::read_sysctl(array('hw.sensors.acpi_tz1.temp0', 'hw.acpi.thermal.tz1.temperature')); if (($end = strpos($acpi, ' degC')) > 0 || ($end = strpos($acpi, 'C')) > 0) { $acpi = substr($acpi, 0, $end); if (is_numeric($acpi)) { $temp_c = $acpi; } } } } return $temp_c; }
public function read_sensor() { $sensor = -1; if (phodevi::is_linux()) { if ($this->voltage_to_monitor == '12v') { $sensor = phodevi_linux_parser::read_sensors(array('V12', '+12V')); } elseif ($this->voltage_to_monitor == '5v') { $sensor = phodevi_linux_parser::read_sensors(array('V5', '+5V')); } elseif ($this->voltage_to_monitor == '3v') { $sensor = phodevi_linux_parser::read_sensors(array('V3.3', '+3.3V')); } } return $sensor; }
private function sys_temp_linux() { $temp_c = -1; $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp3_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp2_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); } if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/device/temp1_input', 'POSITIVE_NUMERIC', array('name' => '!coretemp,!radeon,!nouveau')); } if ($raw_temp == -1) { $raw_temp = phodevi_linux_parser::read_sysfs_node('/sys/class/hwmon/hwmon*/temp1_input', 'POSITIVE_NUMERIC'); } if ($raw_temp != -1) { if ($raw_temp > 1000) { $raw_temp = $raw_temp / 1000; } $temp_c = pts_math::set_precision($raw_temp, 2); } if ($temp_c == -1) { $acpi = phodevi_linux_parser::read_acpi(array('/thermal_zone/THM1/temperature', '/thermal_zone/TZ00/temperature', '/thermal_zone/TZ01/temperature'), 'temperature'); if (($end = strpos($acpi, ' ')) > 0) { $temp_c = substr($acpi, 0, $end); } } if ($temp_c == -1) { $sensors = phodevi_linux_parser::read_sensors(array('Sys Temp', 'Board Temp')); if ($sensors != false && is_numeric($sensors)) { $temp_c = $sensors; } } if ($temp_c == -1 && is_file('/sys/class/thermal/thermal_zone0/temp')) { $temp_c = pts_file_io::file_get_contents('/sys/class/thermal/thermal_zone0/temp'); if ($temp_c > 1000) { $temp_c = pts_math::set_precision($temp_c / 1000, 1); } } return $temp_c; }
private function cpu_voltage_linux() { $voltage = phodevi_linux_parser::read_sensors(array('VCore', 'Vcore')); return $voltage; }