The driver code in the new patch series is split to more simple patches for easy review. The definitions are added to the header files as they become to be used. The patches introduces a driver for the Hyper-V virtual compute hardware devices. This driver powers the Windows Subsystem for Linux (WSL) and will soon power the Windows Subsystem for Android (WSA). Per earlier feedback, the driver is now located under the Hyper-V node as it is not a classic Linux GPU (KMS/DRM) driver and really only make sense when running under a Windows host under Hyper-V. Although we refer to this driver as VGPU for shorthand, in reality this is a generic virtualization infrastructure for various class of compute accelerators, the most popular and ubiquitous being the GPU. We support virtualization of non-GPU devices through this infrastructure. These devices are exposed to user-space and used by various API and framework, such as CUDA, OpenCL, OpenVINO, OneAPI, DX12, etc... One critical piece of feedback, provided by the community in our earlier submission, was the lack of an open source user-space to go along with our kernel compute driver. At the time we only had CUDA and DX12 user-space APIs, both of which being closed source. This is a divisive issue in the community and is heavily debated (https://lwn.net/Articles/821817/). We took this feedback to heart and we spent the last year working on a way to address this key piece of feedback. Working closely with our partner Intel, we're happy to say that we now have a fully open source user-space for the OpenCL, OpenVINO and OneAPI compute family of APIs on Intel GPU platforms. This is supported by this open source project (https://github.com/intel/compute-runtime). To make it easy for our partners to build compute drivers, which are usable in both Windows and WSL environment, we provide a library, that provides a stable interface to our compute device abstraction. This was originally part of the libdxcore closed source API, but have now spawn that off into it's own open source project (https://github.com/microsoft/libdxg). Between the Intel compute runtime project and libdxg, we now have a fully open source implementation of our virtualized compute stack inside of WSL. We will continue to support both open source user-space API against our compute abstraction as well as closed source one (CUDA, DX12), leaving it to the API owners and partners to decide what makes the most sense for them. A lot of efforts went into addressing community feedback in this revised set of patches and we hope this is getting closer to what the community would like to see. We're looking forward additional feedback. Driver overview ------------------------------------------------------- dxgkrnl is a driver for Hyper-V virtual compute devices, such as VGPU devices, which are projected to a Linux virtual machine (VM) by a Windows host. dxgkrnl works in context of WDDM (Windows Display Driver Model) for GPU or MCDM (Microsoft Compute Driver Model) for non-GPU devices. WDDM/MCDM consists of the following components: - Graphics or Compute applications - A graphics or compute user mode API (for example OpenGL, Vulkan, OpenCL, OpenVINO, OneAPI, CUDA, DX12, ...) - User Mode Driver (UMD), written by a hardware vendor - optional libdxg library helping UMD portability across Windows and Linux - dxgkrnl Linux kernel driver (this driver) - Kernel mode port driver on the Windows host (dxgkrnl.sys / dxgmms2.sys) - Kernel mode miniport driver (KMD) on the Windows host, written by a hardware vendor running on the Windows host and interfacing with the hardware device. dxgkrnl exposes a subset the WDDM/MCDM D3DKMT interface to user space. See https://docs.microsoft.com/en-us/windows-hardware/drivers/ddi/d3dkmthk/ This interface provides user space with an abstracted view and control of compute devices in a portable way across Windows and WSL. It is used for devices such as GPU or AI/ML processors. This interface is mapped to custom IOCTLs on Linux (see d3dkmthk.h). The libdxg library translates the D3DKMT interface calls to the driver IOCTLs. A more detailed overview of this architecture is available here: https://devblogs.microsoft.com/directx/directx-heart-linux/ Virtual compute devices are paravirtualized, meaning that the actual communication with the corresponding device hardware happens on the host. The version of dxgkrnl inside of the Linux kernel coordinates with the version of dxgkrnl running on Windows to provide a consistent and portable abstraction for the device that the various APIs and UMD can rely on across Windows and Linux. Dxgkrnl creates the /dev/dxg device, which can be used to enumerate virtual compute devices (also called adapters). UMD or an API runtime open the device and send ioctls to create various device objects (dxgdevice, dxgcontext, dxgallocation, etc., defined in dxgkrnl.h) and to submit work to the device. The WDDM objects are represented in user mode as opaque handles (struct d3dkmthandle). Dxgkrnl creates a dxgprocess object for each process, which opens the /dev/dxg device. This object has a handle table, which is used to translate d3dkmt handles to kernel objects. Handle table definitions are in hmgr.h. There is also a global handle table for objects, which do not belong to a particular process. Driver initialization ------------------------------------------------------- When dxgkrnl is loaded, dxgkrnl registers for virtual PCI device arrival notifications and VM bus channel device notifications (see dxgmodule.c). When the first virtual device is started, dxgkrnl creates a misc device (/dev/dxg). A user mode client can open the /dev/dxg device and send IOCTLs to enumerate and control virtual compute devices. Virtual compute device initialization ------------------------------------------------------- A virtual device is represented by a dxgadapter object. It is created when the corresponding device arrives on the virtual PCI bus. The device vendor is PCI_VENDOR_ID_MICROSOFT and the device id is PCI_DEVICE_ID_VIRTUAL_RENDER. The adapter is started when the corresponding VM bus channel and the global VM bus channel are initialized. Dynamic arrival/removal of devices is supported. Internal objects ------------------------------------------------------- dxgkrnl creates various internal objects in response to IOCTL calls. The corresponsing objects are also created on the host. Each object is placed to a process or global handle table. Object handles (d3dkmthandle) are returned to user mode. The object handles are also used to reference objects on the host. Corresponding objects in the guest and the host have the same handle value to avoid handle translation. The internal objects are: - dxgadapter Represents a virtual compute device object. It is created for every device projected by the host to the VM. - dxgprocess The object is created for each Linux process, which opens /dxg/dev. It has the object handle table, which holds pointers to all internal objects, which are created by this process. - dxgcontext Represents a device execution thread in the packet scheduling mode (as oppose to the hardware scheduling mode). - dxghwqueue Represents a device execution thread in the hardware scheduling mode. - dxgdevice A collection of device contexts, allocations, resources, sync objects, etc. - dxgallocation Represents a device accessible memory allocation. - dxgresource A collection of dxgallocation objects. This object could be shared between devices and processes. - dxgsharedresource Represents a dxgresource object, which is sharable between processes. - dxgsyncobject Represents a device synchronization object, which is used to synchronize execution of DMA buffers in the device execution contexts. - dxgsharedsyncobject Represent a device synchronization object, which is sharable between processes. - dxgpagingqueue Represents a queue, which is used to manage residency of the device allocation objects. Communications with the host ------------------------------------------------------- Dxgkrnl communicates with the host via Hyper-V VM bus channels. There is a global channel and a per virtual computed device channel. The VM bus messages are defined in dxgvmbus.h and the implementation is in dxgvmbus.c. Most VM bus messages to the host are synchronous. When the host enables the asynchronous mode, some high frequency VM bus messages are sent asynchronously to improve performance. When async messages are enabled, all VM bus messages are sent only via the global channel to maintain the order of messages on the host. The host could send asynchronous messages to the Linux dxgkrnl driver via the global VM bus channel. The host messages are handled by dxgvmbuschannel_receive(). PCI config space of the device is used to exchange information between the host and the guest during dxgkrnl initialization. Look at dxg_pci_probe_device(). CPU access to device accessible allocations ------------------------------------------------------- D3DKMT API allows creation of allocations, which are accessible by the device and the CPU. The global VM bus channels has associated IO space, which is used to implement CPU access to CPU visible allocations. For each such allocation the host allocates a portion of the guest IO space and maps it to the allocation memory (it could be in system memory or in device local memory). A user mode application calls the LX_DXLOCK2 ioctl to get the allocation CPU address. Dxgkrnl uses vm_mmap to allocate a user space virtual address range and maps it to the allocation IO space using io_remap_pfn_range(). This way Linux user mode virtual addresses point to the host system memory or device local memory. Sharing objects between processes ------------------------------------------------------- Some dxgkrnl objects could be shared between processes. This includes resources (dxgresource) and synchronization objects (dxgsyncobject). The WDDM API provides a way to share objects using so called "NT handles". "NT handle" on Windows is a native Windows process handle (HANDLE). "NT handles" are implemented as file descriptors (FD) on Linux. The LX_DXSHAREOBJECTS ioctl is used to get an FD for a shared object. Before a shared object can be used, it needs to be "opened" to get the "local" d3dkmthandle handle. The LX_DXOPENRESOURCEFROMNTHANDLE and LX_DXOPENSYNCOBJECTFROMNTHANDLE2 ioctls are used to open a shared object Iouri Tarassov (30): drivers: hv: dxgkrnl: Add virtual compute device VM bus channel guids drivers: hv: dxgkrnl: Driver initialization and loading drivers: hv: dxgkrnl: Add VM bus message support, initialize VM bus channels. drivers: hv: dxgkrnl: Creation of dxgadapter object drivers: hv: dxgkrnl: Opening of /dev/dxg device and dxgprocess creation drivers: hv: dxgkrnl: Enumerate and open dxgadapter objects drivers: hv: dxgkrnl: Creation of dxgdevice objects drivers: hv: dxgkrnl: Creation of dxgcontext objects drivers: hv: dxgkrnl: Creation of compute device allocations and resources drivers: hv: dxgkrnl: Creation of compute device sync objects drivers: hv: dxgkrnl: Operations using sync objects drivers: hv: dxgkrnl: Sharing of dxgresource objects drivers: hv: dxgkrnl: Sharing of sync objects drivers: hv: dxgkrnl: Creation of hardware queues. Sync object operations to hw queue. drivers: hv: dxgkrnl: Creation of paging queue objects. drivers: hv: dxgkrnl: Submit execution commands to the compute device drivers: hv: dxgkrnl: Share objects with the host drivers: hv: dxgkrnl: Query the dxgdevice state drivers: hv: dxgkrnl: Map(unmap) CPU address to device allocation drivers: hv: dxgkrnl: Manage device allocation properties drivers: hv: dxgkrnl: Flush heap transitions drivers: hv: dxgkrnl: Query video memory information drivers: hv: dxgkrnl: The escape ioctl drivers: hv: dxgkrnl: Ioctl to put device to error state drivers: hv: dxgkrnl: Ioctls to query statistics and clock calibration drivers: hv: dxgkrnl: Offer and reclaim allocations drivers: hv: dxgkrnl: Ioctls to manage scheduling priority drivers: hv: dxgkrnl: Manage residency of allocations drivers: hv: dxgkrnl: Manage compute device virtual addresses drivers: hv: dxgkrnl: Add support to map guest pages by host MAINTAINERS | 7 + drivers/hv/Kconfig | 2 + drivers/hv/Makefile | 1 + drivers/hv/dxgkrnl/Kconfig | 26 + drivers/hv/dxgkrnl/Makefile | 5 + drivers/hv/dxgkrnl/dxgadapter.c | 1375 ++++++++ drivers/hv/dxgkrnl/dxgkrnl.h | 962 ++++++ drivers/hv/dxgkrnl/dxgmodule.c | 942 ++++++ drivers/hv/dxgkrnl/dxgprocess.c | 334 ++ drivers/hv/dxgkrnl/dxgvmbus.c | 3788 ++++++++++++++++++++++ drivers/hv/dxgkrnl/dxgvmbus.h | 868 +++++ drivers/hv/dxgkrnl/hmgr.c | 566 ++++ drivers/hv/dxgkrnl/hmgr.h | 112 + drivers/hv/dxgkrnl/ioctl.c | 5368 +++++++++++++++++++++++++++++++ drivers/hv/dxgkrnl/misc.c | 43 + drivers/hv/dxgkrnl/misc.h | 96 + include/linux/hyperv.h | 16 + include/uapi/misc/d3dkmthk.h | 1679 ++++++++++ 18 files changed, 16190 insertions(+) create mode 100644 drivers/hv/dxgkrnl/Kconfig create mode 100644 drivers/hv/dxgkrnl/Makefile create mode 100644 drivers/hv/dxgkrnl/dxgadapter.c create mode 100644 drivers/hv/dxgkrnl/dxgkrnl.h create mode 100644 drivers/hv/dxgkrnl/dxgmodule.c create mode 100644 drivers/hv/dxgkrnl/dxgprocess.c create mode 100644 drivers/hv/dxgkrnl/dxgvmbus.c create mode 100644 drivers/hv/dxgkrnl/dxgvmbus.h create mode 100644 drivers/hv/dxgkrnl/hmgr.c create mode 100644 drivers/hv/dxgkrnl/hmgr.h create mode 100644 drivers/hv/dxgkrnl/ioctl.c create mode 100644 drivers/hv/dxgkrnl/misc.c create mode 100644 drivers/hv/dxgkrnl/misc.h create mode 100644 include/uapi/misc/d3dkmthk.h -- 2.35.1