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README.md
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# vgpu_unlock
# vgpu\_unlock
Unlock vGPU functionality for consumer grade GPUs.
## Important!
This tool is a work in progress. In the current state it does not work.
## Description
This tool enables the use of Geforce and Quadro GPUs with the NVIDIA vGPU
software. NVIDIA vGPU normally only supports a few Tesla GPUs but since some
Geforce and Quadro GPUs share the same physical chip as the Tesla this is only
a software limitation for those GPUs. This tool works by intercepting the ioctl
syscalls between the userspace nvidia-vgpud and nvidia-vgpu-mgr services and
the kernel driver. Doing this allows the script to alter the identification and
capabilities that the user space services relies on to determine if the GPU is
vGPU capable.
## Dependencies:
* This tool requires Python3, the latest version is recommended.
* The python package "frida" is required. `pip3 install frida`.
* The tool requires the NVIDIA GRID vGPU driver to be properly installed for it
to do its job. This special driver is only accessible to NVIDIA enterprise
customers. The script has only been tested with 11.3 for "KVM on Linux" and
may or may not work on other versions.
## Installation:
The NVIDIA vGPU drivers will create an nvidia-vgpud and nvidia-vgpu-mgr
systemd service. All we have to do is replace the path
/usr/bin/<executable> in /lib/systemd/system/nvidia-vgpud.service and
/lib/systemd/system/nvidia-vgpu-mgr.service with the path to the vgpu\_unlock
script and pass the original executable path as the first argument.
---
**NOTE**
This script will only work if there exists a vGPU compatible Tesla GPU that
uses the same physical chip as the actual GPU being used.
---

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vgpu_unlock Executable file
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#!/bin/python3
#
# vGPU unlock script for consumer GPUs.
#
# Copyright 2021 Jonathan Johansson
# This file is part of the "vgpu_unlock" project, and is distributed under the MIT License.
# See the LICENSE file for more details.
#
import errno
import frida
import os
import queue
import subprocess
import sys
import time
script_source = r"""
// Value of the "request" argument used by nvidia-vgpud and nvidia-vgpu-mgr
// when calling ioctl to read the PCI device ID and type (and possibly
// other things) from the GPU.
var REQ_QUERY_GPU = ptr("0xC020462A");
// When issuing ioctl with REQ_QUERY_GPU then the "argp" argument is a
// pointer to a structure something like this:
//
// struct arg {
// uint32_t unknown_1; // Initialized prior to call.
// uint32_t unknown_2; // Initialized prior to call.
// uint32_t op_type; // Operation type, see comment below.
// uint32_t padding_1; // Always set to 0 prior to call.
// void* result; // Pointer initialized prior to call.
// // Pointee initialized to 0 prior to call.
// // Pointee is written by ioctl call.
// uint32_t unknown_4; // Set to 0x10 for READ_PCI_ID and set to 4 for
// READ_DEV_TYPE prior to call.
// uint32_t status; // Written by ioctl call. See comment below.
// }
// These are the observed values for the op_type member.
var OP_READ_DEV_TYPE = 0x800289; // *result type is uint64_t.
var OP_READ_PCI_ID = 0x20801801; // *result type in uint32_t, the uppper 16
// bits is the device ID.
// nvidia-vgpu-mgr expects this value for a vGPU capable GPU.
var DEV_TYPE_VGPU_CAPABLE = uint64(3);
// When ioctl returns success (retval >= 0) but sets the status value of
// the arg structure to 3 then nvidia-vgpud will sleep for a bit (first
// 0.1s then 1s then 10s) then issue the same ioctl call again until the
// status differs from 3. It will attempt this for up to 24h before giving
// up.
var STATUS_TRY_AGAIN = 3;
Interceptor.attach(Module.getExportByName(null, "ioctl"), {
onEnter(args) {
console.log("ioctl called");
this.request = args[1];
this.argp = args[2];
},
onLeave(retVal) {
if(!this.request.equals(REQ_QUERY_GPU)) {
// Not a call we care about.
return;
}
if(retVal.toInt32() < 0) {
// Call failed.
return;
}
// Lookup status value according to struct above.
var status = this.argp.add(0x1C).readU32();
if(status == STATUS_TRY_AGAIN) {
// Driver will try again.
return;
}
var op_type = this.argp.add(8).readU32();
if(op_type == OP_READ_PCI_ID) {
// Lookup address of the device ID, note that we point directly at
// the upper 16 bits of the word.
var devid_ptr = this.argp.add(0x10).readPointer().add(2);
// Now we replace the device ID with a spoofed value that needs to
// be determined such that the spoofed value represents a GPU with
// vGPU support that uses the same GPU chip as our actual GPU.
var actual_devid = devid_ptr.readU16();
var spoofed_devid = actual_devid;
// GP102
if(actual_devid == 0x1b00 || // TITAN X (Pascal)
actual_devid == 0x1b02 || // TITAN Xp
actual_devid == 0x1b06 || // GTX 1080 Ti
actual_devid == 0x1b30) { // Quadro P6000
spoofed_devid = 0x1b38; // Tesla P40
}
// GP104
if(actual_devid == 0x1b80 || // GTX 1080
actual_devid == 0x1b81 || // GTX 1070
actual_devid == 0x1b82 || // GTX 1070 Ti
actual_devid == 0x1b83 || // GTX 1060 6GB
actual_devid == 0x1b84 || // GTX 1060 3GB
actual_devid == 0x1bb0) { // Quadro P5000
spoofed_devid = 0x1bb3; // Tesla P4
}
// TU102
if(actual_devid == 0x1e02 || // TITAN RTX
actual_devid == 0x1e04 || // RTX 2080 Ti
actual_devid == 0x1e07) { // RTX 2080 Ti
spoofed_devid = 0x1e30; // Quadro RTX 6000
}
devid_ptr.writeU16(spoofed_devid);
}
if(op_type == OP_READ_DEV_TYPE) {
// Set device type to vGPU capable.
var dev_type_ptr = this.argp.add(0x10).readPointer();
dev_type_ptr.writeU64(DEV_TYPE_VGPU_CAPABLE);
}
}
});
"""
device = frida.get_local_device()
child_processes = queue.Queue()
def instrument(pid):
"""Instrument and resume process.
:param pid: Process identifier
"""
session = device.attach(pid)
# We need to also instrument the children since nvidia-vgpud forks itself
# when initially launched.
session.enable_child_gating()
script = session.create_script(script_source)
script.load()
device.resume(pid)
def on_child_added(child):
"""Callback for when a new child process has been created.
:param child: The newly created child process.
"""
child_processes.put(child.pid)
instrument(child.pid)
def wait_exit(pid):
"""Wait for a process to terminate.
:param pid: Process ID of the target process.
"""
while 1:
time.sleep(.1)
try:
os.kill(pid, 0)
except OSError as e:
if e.errno == errno.ESRCH:
break
def main():
"""Entrypoint."""
# Behave at least a little bit like a forking service.
if sys.argv[1] != "-f":
subprocess.Popen([sys.argv[0], "-f"] + sys.argv[1:])
exit()
device.on("child-added", on_child_added)
pid = device.spawn(sys.argv[2])
instrument(pid)
# Wait for everything to terminate before exiting.
wait_exit(pid)
while not child_processes.empty():
wait_exit(child_processes.get_nowait())
if __name__ == "__main__":
main()