How to uniquely identify computer (mainboard) using C#(.Net/Mono, local application)?
Edition. We can identify mainboard in .Net using something like this (see Get Unique System Identifiers in C#):
using System.Management;
...
ManagementObjectSearcher searcher = new ManagementObjectSearcher("select * from Win32_MotherboardDevice");
...
But unfortunately Mono does not support System.Management. How to do it under Mono for Linux? - I don't know :(
Write a function that takes a few unique hardware parameters as input and generates a hash out of them.
For example, Windows activation looks at the following hardware characteristics:
Display Adapter
SCSI Adapter
IDE Adapter (effectively the motherboard)
Network Adapter (NIC) and its MAC Address
RAM Amount Range (i.e., 0-64mb, 64-128mb, etc.)
Processor Type
Processor Serial Number
Hard Drive Device
Hard Drive Volume Serial Number (VSN)
CD-ROM / CD-RW / DVD-ROM
You can pick up a few of them to generate your unique computer identifier.
Please see: Get Unique System Identifiers in C#
You realistically have MotherboardID, CPUID, Disk Serial and MAC address, from experience none of them are 100%.
Our stats show
Disk serial Is missing 0.1 %
MAC Is missing 1.3 %
Motherboard ID Is missing 30 %
CPUID Is missing 99 %
0.04% of machines tested yielded no information, we couldn't even read the computer name. It maybe that these were some kind of virtual PC, HyperV or VMWare instance, or maybe just very locked down? In any case your design has to be able to cope with these cases.
Disk serial is the most reliable, but easy to change, mac can be changed and depending on the filtering applied when reading it can change if device drivers are added (hyperv, wireshark etc).
Motherboard and CPUID sometimes return values that are invalid "NONE", "AAAA..", "XXXX..." etc.
You should also note that these functions can be very slow to call (they may take a few seconds even on a fast PC), so it may be worth kicking them off on a background thread as early as possible, you ideally don't want to be blocking on them.
Try this:
http://carso-owen.blogspot.com/2007/02/how-to-get-my-motherboard-serial-number.html
Personally though, I'd go with hard drive serial number. If a mainboard dies and is replaced, that PC isn't valid any more. If the HDD drive is replaced, it doesn't matter too much because the software was on it.
Of course, on the other hand, if the HDD is just moved elsewhere, the information goes with it, so you might want to look at a combination of serial numbers, depending what you want it for.
How about the MAC address of the network card?
Related
I'd like to find a way to figure out physical slot of a PCI-E device from the bus address. I would like to use to modify a driver/kernel module, so it would enumerate the devices (with the same ID) and disambiguate the device files according to physical slot. Like /dev/device_physslot . The driver will run on Ubuntu 18
lspci is capable to show physical slot number in the verbose presentation
However, as I found out, it accomplishes it over sysfs, which cannot be accessed from kernel module.
So I need to do it somehow with system calls.
Or perhaps it is possible to figure out, where sysfs gets /sys/bus/pci/slots/slot_num/address property?
First of all, I would say to you that I write this question from nothing because I have attempt to find good documentation but nothing stand out...
What happens when we squeeze a key?
I think this is complex but I hope you can help me.
What I search to know : all (but especially the program start on the host machine and how the key electric signal is encoded and send...)
The eXtensible Host Controller (xHC) has a Periodic Transfer Ring. Windows programs this ring to trigger a transfer every time an interval in milliseconds has passed. The right interval is specified in the USB descriptor returned by the USB device. When the transfer occurs, the xHC puts a Transfer Event TRB on the event ring and triggers an MSI-X interrupt which bypasses the IOAPIC as some kind of inter-processor interrupt. If Windows detects some change in the keys pressed, it will send a message to the application which currently has focus (calling the window's procedure) with the key pressed in one of the argument.
I don't know about electrical signals but I know the eXtensible Host Controller is the USB controller responsible to interact with USB on modern Windows systems. Since Windows nowadays requires an x64 processor, the xHC must be present on your motherboard. The xHC is a PCI-Express device which is compliant with the PCI-Express specification.
To find an xHC, you:
Find the RSDP ACPI table in RAM;
This table will be found by the UEFI firmware which acts as some kind of small operating-system (OS) during boot of the computer. Then, the OS developers will write a small UEFI application named bootx64.efi that they will place on a FAT32 partition on the hard-disk. They will place this app in the /boot/efi directory. The UEFI firmware will directly launch that application on boot of the computer which allows to have an OS which doesn't require user input to be launched (similarly to how it used to work with the legacy BIOS fetching the first sector of the hard-disk and executing the instructions found there).
The UEFI application is compiled in practice with either EDK2 or gnu-efi. These compilers are aware of the UEFI environment and specification. They thus compile the code to system calls that are present during boot and available for the UEFI application written by the OS developers. The System Tables (often the ACPI tables) are given as an argument to the "main" function (often called UefiMain) called by the UEFI firmware in the UEFI application. The code of the application can thus simply use these arguments to find the RSDP table and pass it to the OS.
Find the MCFG ACPI table using the RSDP;
The chain of table is RSDP -> XSDT -> MCFG. Once the OS found the MCFG, this table specifies the base address of the PCI configuration space. To interact with PCI devices you use memory mapped IO (MMIO). You write to some position in RAM and it will instead write to the registers of the PCI devices. The MCFG thus specifies the base address at which you will start finding MMIO registers for the different PCI devices that are plugged into the computer.
Iterate on the PCI devices and look at their IDs until you find an xHC.
To iterate on the PCI devices, the PCI convention specifies a formula which is the following:
UINT64 physical_address = base_address + ((bus - first_bus) << 20 | device << 15 | function << 12);
The base_address is for a specific segment group. Each segment group can have 256 buses (suitable for large servers or large computers with lots of components). There can be up to 65536 segment groups and each can have up to 256 PCI buses. Each PCI bus can have up to 32 devices plugged onto it and each device can have up to 8 functions. Each function can also be a PCI bridge. This is quite straightforward to understand because the terminology is clear. The bus here is an actual serial bus that the PCI devices (like a network card, a graphics card, an xHC, an AHCI, etc.) use to communicate with RAM. The function is a functionality of the PCI device like controlling USB devices, hard-disks, HDMI screens (for graphics cards), etc. The PCI bridge bridges a PCI bus to another PCI bus. It means you can have almost an infinite amount of devices with the PCI specification because the bridges allow to extend the tree of devices by adding other PCI host controllers.
Meanwhile, the bus is simply a number between 0 and 255. The first bus is specified in the MCFG ACPI table for a specific segment group. The device is a number between 0 and 31 and the function is a number between 0 and 7. This formula returns a physical address which points to a conventional configuration space (it is the same for all functions) which has specific registers. These registers are used to determine what is the type of device and to load a proper driver for it. Each function of each device thus gets a configuration space.
For the xHC, there will be only one function and the IDs returned by its configuration space will be 0x0C for the class ID and 0x03 for the subclass ID (https://wiki.osdev.org/EXtensible_Host_Controller_Interface).
Once you found an xHC, it gets rather complex. You need to initialize it and get the USB devices which are plugged in the computer at the current moment. You need to take several steps to get the xHC operational. For this part, I'll leave you to read the xHCI specification which (on chapter 4) specifies exactly the steps which need to be taken (https://www.intel.com/content/dam/www/public/us/en/documents/technical-specifications/extensible-host-controler-interface-usb-xhci.pdf).
For the keyboard portion I'll leave you to read one of my answer on the stackexchange for computer science: https://cs.stackexchange.com/questions/141870/when-are-a-controllers-registers-loaded-and-ready-to-inform-an-i-o-operation/141918#141918.
Some good links:
https://wiki.osdev.org/Universal_Serial_Bus
https://wiki.osdev.org/PCI
Coming form this question yesterday, I decided to port this library to my board. I was aware that I needed to change something, so I compiled the library, call it on a small program and see what happens. The 1st problem is here:
// Check for GPIO and peripheral addresses from device tree.
// Adapted from code in the RPi.GPIO library at:
// http://sourceforge.net/p/raspberry-gpio-python/
FILE *fp = fopen("/proc/device-tree/soc/ranges", "rb");
if (fp == NULL) {
return MMIO_ERROR_OFFSET;
}
This lib is aimed for Rpi, os the structure of the system on my board is not the same. So I was wondering if somebody could tell me where I could find this file or how it looks like so I can find it by my self in order to proceed the job.
Thanks.
You don't necessarily want that "file" (or more precisely /proc node).
The code this is found in is setting up to do direct memory mapped I/O using what appears to be a pi-specific gpio-flavored version of the /dev/mem type of device driver for exposing hardware special function registers to userspace.
To port this to your board, you would need to first determine if there is a /dev/mem or similar capability in your kernel which you can activate. Then you would need to determine the appropriate I/O registers for GPIO pins. The pi-specific code is reading the Device Tree to figure this out, but there are other ways, for example you can manually read the programmer's manual of the SoC on which you are running.
Another approach you can consider is adding some small microcontroller (or yes, barebones ***duino) to the system, and using that to collect information from various sensors and peripherals. This can then be forwarded to the SoC over a UART link, or queried out via I2C or similar - add a small amount of cost and some degree of bottleneck, but also means that the software on the SoC then becomes very portable - to a different comparable chip, or perhaps even to run on a desktop PC during development.
How to get CPU/Processor serial number or unique ID in perl for windows machine without using any modules, probably using syscalls or something?
http://metacpan.org/pod/Win32::SystemInfo. Without modules you can learn source code of this module and use it. You will see that module imports function GetSystemInfo from kernel32.dll and than uses it, you can do it in the same way
You can't get a CPU serial number. For a brief time, Intel issued a series of Pentium III processors where each chip had a unique serial number. It became a PR mess for them over privacy concerns and they discontinued that set of instructions in subsequent processor releases.
But if you are looking for a "unique id" for a Windows install that is mostly guaranteed to by unique, you can try any of the following:
Generate a unique GUID (uuidgen, CoCreateGuid), save it out to the registry/disk, then read it back later.
Get the Machine SID. http://www.perlmonks.org/?node_id=645077
How to find size of a semaphore object in windows?
I tried using sizeof() but we cannot give name of the sempahore object as an argument to sizeof. It has to be the handle. sizeof(HANDLE) gives us the size of handle and not semaphore.
This what is known as an "opaque handle.". There is no way to know how big it really is, what it contains or how any of the functions work internally. This gives Microsoft the ability to completely rewrite the implementation with each new version of Windows if they want to without worrying about breaking existing code. It's a similar concept to having a public and private interface to a class. Since we are not working on the Windows kernel, we only get to see the public interface.
Update:
It might be possible to get a rough idea of how big they are by creating a bunch and monitoring what happens to your memory usage in Process Explorer. However, since there is a good chance that they live in the kernel and not in user space, it might not show up at all. In any case, there are no guarantees about any other version of Windows, past or future, including patches/service packs.
It's something "hidden" from you. You can't say how big it is. And it's a kernel object, so it probably doesn't even live in your address space. It's like asking "how big is the Process Table?", or "how many MB is Windows wasting?".
I'll add that I have made a small test on my Windows 7 32 bits machine: 100000 kernel semaphores (with name X{number} with 0 <= number < 100000)) : 4 mb of kernel memory and 8 mb of user space (both measured with Task Manager). It's about 40 bytes/semaphore in kernel space and 80 bytes/semaphore in user space! (this in Win32... In 64 bits it'll probably double)