Authors:
Bla | Son-link | Guillermo-C-A |
---|---|---|
Backend and distribution | GUI frontend | Backend |
Before installing or running Hwmon it is essential to have a system with GNU/Linux along with python 3. To see the version of Python you have installed on your system you have to execute these sentences in the terminal:
python --version
or
python3 --version
And you will keep the name (without -version) that returns python 3.xx. Where de xx can be any number (ex: 3.5, 3.8, etc...).
In this case, we will keep the name "python3", since it is the "executable" of version 3 for python.
To install Hwmon you can choose to do it in an automatic or manual way, but it is recommended to do the manual installation since it is the most updated version compared to the automatic version.
Regardless of whether it is manual or not, you must have pip or pip3 installed. Depending on the name where the python3 version is hosted, it will have to be installed in one way or another.
python3 -> sudo apt install python3-pip
python -> sudo apt install python-pip
If you want to install the automatic version, you will only have to execute this sentence:
python3 -> pip3 install hwmon
python -> pip install hwmon
In case it is manual, you will have to follow these steps:
-
Installing git if you don't have it installed
sudo apt install git-all
-
Execute these sentences at the terminal
git clone https://github.com/Guillermo-C-A/Hwmon-python.git cd Hwmon-python python3 -> pip3 install . python -> pip install .
Ex:
-
Use our terminal interface to see everything our library has to offer :)
cd bin python3 -> python3 hwmon-cli --help python -> python hwmon-cli --help
Ex:
python3 -> python3 hwmon-cli --sensors python -> python hwmon-cli --sensors
More examples:
python3 -> python3 hwmon-cli --cpu --gpu --sensors python -> python hwmon-cli --cpu --gpu --sensors
We are open to new ideas and people who want to improve this project, so feel free to open pull requests or leave us your opinions/problems with the application in this section.
Don't forget to give a star to this repository :D
The information presented in this library may vary depending on the distribution or kernel being executed, to the point of giving error in certain functions such as GPU.
In case this happens, inform us of the error so that we can fix the fault :)
Tested and stable kernels:
- 5.8 (Ubuntu 20)
- 5.4.0.42.46 (Ubuntu 20)
It has also been tested on three different computers with AMD CPU and GPU configurations successfully and stably
We are currently working in parallel to develop the interfaces for this library. You can download the terminal interface this link
In addition, the desktop GUI is in the process of being created.
Hwmon has been created with the intention of replacing Linux libraries and APIs which obtain system information without the need to depend on dependencies outside a standard Linux system.
The only requirements for running Hwmon on a system are:
- The OS is Linux
- Have python 3
- Install hwmon library
Hwmon is also a library developed expressly by and for Python 3 with functions that are easy to understand and operate, which read and synthesize in the same library all the useful information for monitoring a Linux system that can be found in the /sys, /proc and /dev folders. So only the information that the system itself has recorded will be obtained.
As already mentioned, Hwmon does not require any dependencies or programs and is a library created with the standard Python 3 libraries. Which is not the case like other library/software such as:
- Pysensors
- lm-sensors
- psutil
Where you need files and other softwares to be able to work, so if you're missing some of that, it just doesn't work. They are also heavier solutions in terms of file sizes than Hwmon.
Yes. Hwmon is able to return and print the same information that is obtained when installing and running sensors.
And it even prints the information on the screen in a nice and friendly way so that it is more useful and easy to understand.
Hwmon is able to extract:
- Information from the sensors available on the computer
- Processor information
- System memory information
- Sent and received packet information
- USB devices connected to the computer
- Disks connected to the computer
- BIOS information
- GPU information
All this information is extracted respectively from the following sites:
- Sensors: /sys/class/hwmon
- CPU: /proc/cpuinfo and /proc/stat
- RAM: /proc/meminfo
- Network: /proc/net/dev
- USB: /dev/input/by-id
- Disks: /dev/disk/by-id
- GPU: /sys/class/graphics or /sys/class/drm/card0/device/
- BIOS: /sys/class/dmi/id/
from hwmon import Hwmon
To access the sensor subclass, the following statement will be executed:
sensors = Hwmon.HW()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print all the sensor information of the system in a tabular and nice way.
sensors.print_data()
amdgpu
vddgfx 0.862 v
power1 35.04 w
fan1 1119 RPM
edge 33.0 C
nct6779
AUXTIN3 -28.0 C
in3 3.344 v
fan3 0 RPM
in7 3.472 v
AUXTIN0 -2.5 C
in12 1.68 v
in0 0.568 v
PCH_CPU_TEMP 0.0 C
SMBUSMASTER 0 32.5 C
in4 1.84 v
fan4 0 RPM
in8 3.264 v
AUXTIN1 85.0 C
in13 0.944 v
in1 0.0 v
fan1 0 RPM
PCH_CHIP_CPU_MAX_TEMP 0.0 C
in5 0.84 v
SYSTIN 31.0 C
in10 0.352 v
fan5 0 RPM
in9 0.0 v
AUXTIN2 23.0 C
in14 1.848 v
in2 3.344 v
fan2 1945 RPM
PCH_CHIP_TEMP 0.0 C
in6 1.536 v
CPUTIN 33.0 C
in11 1.056 v
k10temp
Tdie 32.625 C
Tctl 32.625 C
In case we are interested in getting the information from the sensors instead of printing it on the screen, we will execute the following sentence:
sensors.data()
{'amdgpu': {'vddgfx': '0.862 v',
'power1': '34.169 w',
'fan1': '1120 RPM',
'edge': '33.0 C'},
'nct6779': {'AUXTIN3': '-28.0 C',
'in3': '3.344 v',
'fan3': '0 RPM',
'in7': '3.472 v',
'AUXTIN0': '-2.5 C',
'in12': '1.68 v',
'in0': '0.568 v',
'PCH_CPU_TEMP': '0.0 C',
'SMBUSMASTER 0': '32.5 C',
'in4': '1.84 v',
'fan4': '0 RPM',
'in8': '3.264 v',
'AUXTIN1': '85.0 C',
'in13': '0.944 v',
'in1': '0.0 v',
'fan1': '0 RPM',
'PCH_CHIP_CPU_MAX_TEMP': '0.0 C',
'in5': '0.84 v',
'SYSTIN': '31.0 C',
'in10': '0.352 v',
'fan5': '0 RPM',
'in9': '0.0 v',
'AUXTIN2': '23.0 C',
'in14': '1.848 v',
'in2': '3.344 v',
'fan2': '1945 RPM',
'PCH_CHIP_TEMP': '0.0 C',
'in6': '1.536 v',
'CPUTIN': '33.0 C',
'in11': '1.056 v'},
'k10temp': {'Tdie': '32.625 C', 'Tctl': '32.625 C'}}
To access the processor subclass, the following sentence will be executed
cpu = Hwmon.CPU()
Being the functions that interest us in this case: data() and print_data(). Let's see an example of each function:
This function will print all the information of the system processor in a tabular and nice way.
cpu.print_data()
Name AMD Ryzen 5 1400 Quad-Core Processor
CPU_usage 26.71
cores 4
threads 8
cpu MHz
0 1374.813
1 1374.788
2 1374.887
3 1374.75
4 1510.204
5 1501.796
6 3475.097
7 2196.461
Max MHz 3800
Average_MHz 1772.85
In case we are interested in obtaining the information from the processor instead of printing it on the screen, we will execute the following sentence:
cpu.data()
{'Name': 'AMD Ryzen 5 1400 Quad-Core Processor',
'CPU_usage': -34.37,
'cores': '4',
'threads': '8',
'cpu MHz': {0: 1374.906,
1: 1374.774,
2: 1374.735,
3: 1374.718,
4: 1374.724,
5: 1374.91,
6: 1374.804,
7: 1374.706},
'Max MHz': 3800,
'Average_MHz': 1374.78}
To access the system memory subclass, the following sentence will be executed:
memory = Hwmon.MEM()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print in a tabular and nice way all the information in the system memory.
memory.print_data()
MemTotal 7.768MB
MemFree 2.569MB
MemAvailable 4.349MB
Buffers 156.973KB
Cached 1.850MB
SwapCached 0B
Active 3.608MB
Inactive 1.012MB
Active(anon) 2.576MB
Inactive(anon) 116.551KB
Active(file) 1.032MB
Inactive(file) 919.520KB
Unevictable 32.0B
Mlocked 32.0B
SwapTotal 2.000MB
SwapFree 2.000MB
Dirty 960.0B
Writeback 0B
AnonPages 2.617MB
Mapped 683.496KB
Shmem 118.547KB
KReclaimable 122.035KB
Slab 270.754KB
SReclaimable 122.035KB
SUnreclaim 148.719KB
KernelStack 24.109KB
PageTables 70.258KB
NFS_Unstable 0B
Bounce 0B
WritebackTmp 0B
CommitLimit 5.884MB
Committed_AS 11.335MB
VmallocTotal 32.000GB
VmallocUsed 40.414KB
VmallocChunk 0B
Percpu 14.250KB
HardwareCorrupted 0B
AnonHugePages 0B
ShmemHugePages 0B
ShmemPmdMapped 0B
CmaTotal 0B
CmaFree 0B
HugePages_Total 0B
HugePages_Free 0B
HugePages_Rsvd 0B
HugePages_Surp 0B
Hugepagesize 2.000KB
Hugetlb 0B
DirectMap4k 447.266KB
DirectMap2M 6.498MB
DirectMap1G 2.000MB
In case we are interested in obtaining the information from memory instead of printing it out on the screen, we will execute the following sentence:
memory.data()
{'MemTotal': '7.768MB',
'MemFree': '2.569MB',
'MemAvailable': '4.349MB',
'Buffers': '156.980KB',
'Cached': '1.850MB',
'SwapCached': '0B',
'Active': '3.608MB',
'Inactive': '1.012MB',
'Active(anon)': '2.576MB',
'Inactive(anon)': '116.551KB',
'Active(file)': '1.032MB',
'Inactive(file)': '919.520KB',
'Unevictable': '32.0B',
'Mlocked': '32.0B',
'SwapTotal': '2.000MB',
'SwapFree': '2.000MB',
'Dirty': '964.0B',
'Writeback': '0B',
'AnonPages': '2.616MB',
'Mapped': '683.496KB',
'Shmem': '118.547KB',
'KReclaimable': '122.035KB',
'Slab': '270.754KB',
'SReclaimable': '122.035KB',
'SUnreclaim': '148.719KB',
'KernelStack': '24.109KB',
'PageTables': '70.258KB',
'NFS_Unstable': '0B',
'Bounce': '0B',
'WritebackTmp': '0B',
'CommitLimit': '5.884MB',
'Committed_AS': '11.335MB',
'VmallocTotal': '32.000GB',
'VmallocUsed': '40.414KB',
'VmallocChunk': '0B',
'Percpu': '14.250KB',
'HardwareCorrupted': '0B',
'AnonHugePages': '0B',
'ShmemHugePages': '0B',
'ShmemPmdMapped': '0B',
'CmaTotal': '0B',
'CmaFree': '0B',
'HugePages_Total': '0B',
'HugePages_Free': '0B',
'HugePages_Rsvd': '0B',
'HugePages_Surp': '0B',
'Hugepagesize': '2.000KB',
'Hugetlb': '0B',
'DirectMap4k': '447.266KB',
'DirectMap2M': '6.498MB',
'DirectMap1G': '2.000MB'}
To access the network subclass, the following sentence will be executed:
net = Hwmon.NET()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print in a tabular and nice way all the information of the system network.
net.print_data()
lo
receive
bytes 7593337
packets 14478
errs 0
drop 0
fifo 0
frame 0
compressed 0
multicast 0
transmit
bytes 14478
packets 0
errs 0
drop 0
fifo 0
colls 0
carrier 0
enp37s0
receive
bytes 1279460566
packets 864808
errs 0
drop 0
fifo 0
frame 0
compressed 0
multicast 507
transmit
bytes 362337
packets 0
errs 0
drop 0
fifo 0
colls 0
carrier 0
docker0
receive
bytes 0
packets 0
errs 0
drop 0
fifo 0
frame 0
compressed 0
multicast 0
transmit
bytes 0
packets 0
errs 0
drop 0
fifo 0
colls 0
carrier 0
In case we are interested in getting the information from the network instead of printing it on the screen, we will execute the following sentence:
net.data()
{' lo': {'receive': {'bytes': 7605359,
'packets': 14503,
'errs': 0,
'drop': 0,
'fifo': 0,
'frame': 0,
'compressed': 0,
'multicast': 0},
'transmit': {'bytes': 14503,
'packets': 0,
'errs': 0,
'drop': 0,
'fifo': 0,
'colls': 0,
'carrier': 0}},
'enp37s0': {'receive': {'bytes': 1279460566,
'packets': 864808,
'errs': 0,
'drop': 0,
'fifo': 0,
'frame': 0,
'compressed': 0,
'multicast': 507},
'transmit': {'bytes': 362337,
'packets': 0,
'errs': 0,
'drop': 0,
'fifo': 0,
'colls': 0,
'carrier': 0}},
'docker0': {'receive': {'bytes': 0,
'packets': 0,
'errs': 0,
'drop': 0,
'fifo': 0,
'frame': 0,
'compressed': 0,
'multicast': 0},
'transmit': {'bytes': 0,
'packets': 0,
'errs': 0,
'drop': 0,
'fifo': 0,
'colls': 0,
'carrier': 0}}}
To access the USB subclass, the following sentence will be executed:
usb = Hwmon.USB()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print in a tabular and nice way all the information of the USBs in the system.
usb.print_data()
usb-Logitech_Gaming_Mouse_G300-mouse
usb-CHICONY_USB_Keyboard
usb-Logitech_Gaming_Mouse_G300
usb-Logitech_Gaming_Mouse_G300-if01
In case we are interested in getting the information from the sensors instead of printing it on the screen, we will execute the following sentence:
usb.data()
['usb-Logitech_Gaming_Mouse_G300-mouse',
'usb-CHICONY_USB_Keyboard',
'usb-Logitech_Gaming_Mouse_G300',
'usb-Logitech_Gaming_Mouse_G300-if01']
To access the subclass of the disks, the following sentence will be executed:
disk = Hwmon.DISK()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print in a tabular and nice way all the information of the disks in the system.
disk.print_data()
wwn-0x50014ee202380e97
ata-WDC_WD3200BEVT-22ZCT0_WD-WXEY08F45384
wwn-0x500080dc007530e0
ata-TOSHIBA-TL100_27NB51GCKSZU
wwn-0x50014ee20b769657
ata-WDC_WD20EZRX-22D8PB0_WD-WCC4M1ZJ83JD
In case we are interested in getting the information from the sensors instead of printing it on the screen, we will execute the following sentence:
disk.data()
['wwn-0x500080dc007530e0',
'ata-WDC_WD3200BEVT-22ZCT0_WD-WXEY08F45384',
'ata-TOSHIBA-TL100_27NB51GCKSZU',
'wwn-0x50014ee202380e97',
'wwn-0x50014ee20b769657',
'ata-WDC_WD20EZRX-22D8PB0_WD-WCC4M1ZJ83JD']
To access the GPU subclass, the following statement will be executed:
gpu = Hwmon.GPU()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print all the information of the GPU in a tabular and nice way.
gpu.print_data()
amdgpudrmfb
Resolution 1680x1050p
gpu_busy_percent 0 %
mem_info_vram_used 361.31MB
current_link_width 16
mem_info_vis_vram_used 46.77MB
mem_info_vis_vram_total 256.00MB
current_link_speed 8 GT/s
mem_busy_percent 19 %
mem_info_gtt_used 52.29MB
mem_info_vram_total 8.00GB
vbios_version 113-C9403100_101
mem_info_gtt_total 5.83GB
In case we are interested in getting the information from the gpu instead of printing it on the screen, we will execute the following sentence:
gpu.data()
{'amdgpudrmfb':
{'Resolution': '1680x1050p',
'gpu_busy_percent': '0 %',
'mem_info_vram_used': '367.23MB',
'current_link_width': '16',
'mem_info_vis_vram_used': '46.77MB',
'mem_info_vis_vram_total': '256.00MB',
'current_link_speed': '8 GT/s',
'mem_busy_percent': '19 %',
'mem_info_gtt_used': '56.88MB',
'mem_info_vram_total': '8.00GB',
'vbios_version': '113-C9403100_101',
'mem_info_gtt_total': '5.83GB'}}
To access the BIOS subclass, the following statement will be executed:
bios = Hwmon.BIOS()
Being the functions that interest us in this case: data() and print_data() . Let's see an example of each function:
This function will print all the information of the GPU in a tabular and nice way.
bios.print_data()
bios_date 12/20/2018
bios_version P5.50
board_vendor ASRock
chassis_type 3
bios_vendor American Megatrends Inc.
board_asset_tag
board_version
board_name AB350M-HDV
In case we are interested in getting the information from the gpu instead of printing it on the screen, we will execute the following sentence:
bios.data()
{'bios_date': '12/20/2018',
'bios_version': 'P5.50',
'board_vendor': 'ASRock',
'chassis_type': '3',
'bios_vendor': 'American Megatrends Inc.',
'board_asset_tag': '',
'board_version': '',
'board_name': 'AB350M-HDV'}