Re: [PATCH v3 0/9] Xilinx AI engine kernel driver

[Date Prev][Date Next][Thread Prev][Thread Next][Date Index][Thread Index]

 




On 12/15/20 7:23 AM, Alex Deucher wrote:
On Mon, Dec 14, 2020 at 7:24 PM Jiaying Liang<wendy.liang@xxxxxxxxxx>  wrote:
On 12/11/20 11:39 AM, Daniel Vetter wrote:
Hi all

On Fri, Dec 11, 2020 at 8:03 PM Alex Deucher<alexdeucher@xxxxxxxxx>   wrote:
On Mon, Nov 30, 2020 at 3:25 AM Wendy Liang<wendy.liang@xxxxxxxxxx>   wrote:
AI engine is the acceleration engine provided by Xilinx. These engines
provide high compute density for vector-based algorithms, and flexible
custom compute and data movement. It has core tiles for compute and
shim tiles to interface the FPGA fabric.

You can check the AI engine architecture document for more hardware details:
https://www.xilinx.com/support/documentation/architecture-manuals/am009-versal-ai-engine.pdf

This patch series adds a Linux kernel driver to manage the Xilinx AI
engine array device and AI engine partitions (groups of AI engine tiles
dedicated to an application).
Hi Wendy,

I think it would be good to provide an overview of how your stack
works in general.  That would give reviewers a better handle on how
all of this fits together.  I'd suggest including an overview in the
cover letter and also in the commit message and/or as a comment in the
code in one of the patches.  I'm not really an expert when it comes to
FPGAs, but this basically looks like a pretty low level interface to
set up the data fabric for a kernel that will run on the soft logic or
maybe the microcontroller on the board.  It doesn't have to be super
detailed, just a nice flow for how you might use this.  E.g.,

Userspace uses ioctls X, Y, Z to configure the data fabric for the
FPGA kernel.  The kernels can run on... .  DMA access to system memory
for data sets can be allocated using ioctl A.  DMA access is limited
by... . The user can then load the FPGA kernel on to one of the
engines using ioctl B and finally they can kick off the whole thing
using ioctl C.  FPGA kernels are compiled using YYY toolchain and use
use the following runtime (link to runtime) to configure the data
fabric using ioctls X, Y, Z.
At least for drm drivers we ideally have that as a .rst file in
Documentation/. With that you can even do full svg graphs, or just dot
graphs, of the overall stack if you really want to go overboard :-)

It would also be good to go over the security implications of the
design.  E.g., can the FPGA kernel(s) access the DMA engine directly,
or is it limited to just the DMA regions set up by the ioctls?  Also,
does the hardware and software design allow for multiple users?  If
so, how does that work?
I've also seen indications that there's some on-chip or on-card
memory. How that's planned to be used and whether we want to manage
this (maybe even with something like ttm) would be good to understand.

All excellent questions from Alex, just figured I add some more.

Cheers, Daniel
Hi Alex, Daniel,

Below is an overview of the driver.

AI engine kernel driver manages Xilinx AI engine device. An AI engine device
contains cores tiles and SHIM tiles. Core tiles are the computation tiles
, the SHIM tiles are the tiles interfacing to external components.

            +--------+--------+--------+--------+
             | Core        | Core        | Core        | Core | ...
             |                |                | |                |
            +-----------------------------------+
             | Core        | Core        | Core        | Core     | ...
             |                |                | |             |
            +--------+--------+--------+---------
             ...
            +--------+--------+-----------------+
            | SHIM        | SHIM       | SHIM       |SHIM        |
            | PL            | PL           | PL            |PL | NOC  |
            +---+----+---+----+---+-----+-------+
    AXI Streams   |        |                |              |    |AXI MM
                         |        |                | |    |
Events Singals |        |                |              |    |
                         |        |                | |    |
                         |        |                | |    |
            +---+--------+--------+-----+ +--+------+
            |       FPGA                                        | |
NOC        |
            | | |                  |
            +---------------------------+ +--+-------+
                                             |
                                             |
                                         +---+------+
                                         |   DDR           |
                                         +----------+

Each Core tile contains computing module, local memory and DMA module. The
local memory DMA module takes data from or to the AXI streams and writes
it to or reads it from the local memory. The computing module can also
directly get/put data from/to the AXI stream. The AIE SHIM enables AIE tiles
to get/put data from/to AXI streams from FPGA, enables external master to
access AI engine address space through AXI MM. SHIM NoC module has DMA
engine,
which can access extern memory though AXI MM and push it to internal AXI
streams.

At runtime, the AI engine tiles interconnection needs to be configured
so that
it can get fetch data from external components or adjacent tiles, and AI
engine
core program needs to be loaded. And then user application can push data
to the
AI engine array and start/stop AI engine core. AI engine device errors
can be
raised as events, the AI engine kernel driver listens to the events
interrupt
to monitor runtime async device errors.

Instead of application directly interacting with the AI engine kernel
APIs, user
application/libraries interacts with AI engine userspace library:
https://github.com/Xilinx/embeddedsw/tree/master/XilinxProcessorIPLib/drivers/aienginev2
It provides cross OSes low level functional abstraction such as how to
connect one
stream port to another stream port, how to configure core tile local DMA.

The AI engine library can be used by other runtime libraries such as
Xilinx runtime (XRT)
library:https://xilinx.github.io/XRT/master/html/index.html,
which provides acceleration abstraction for Xilinx accelerators, it has
extensions
to interface to other acceleration framework such as OpenCL.
XRT provides buffer handling abstractions for user application to share
data between
applicaiton and devices.

Here is an example of application runtime stack:

              +----------------------------+
              |      Application                              |
              | |
              +----------------------------+
              |       XRT                                        |
              | |
              +----------------------------+
              |      AIE Library                               |
              | |
             +----------------------------+
      +----------------------------------------+
Kern    +----------------------------+
              |         AIE Partition                        +--+
             +----------------------------+    |
                    |----------------------------+
              +----------------------------+
               |         AIE Device                           |
               | |
              +----------------------------+



The AI engine kernel driver provides the following user interfaces:
   * AIE device driver is the root device driver to manage the partitions of
     of the AI engine device array. AI engine array can be partitioned into
     column wised isolated partitions. Each applicaiton can only access its
     own partitions.
   * AIE device driver monitors the interrupt from the AI enigne device. All
     AI engine tiles shared the same interrupt for error events.
   * AIE partition driver controls address mapping and access of the
     registers/local memories of the tiles within a partition.
     * It provides mmap operation to enable application to direclty
access the
       tiles local memories for small data update such as parameter
update for
       performance.
     * It provides mmap operatio to map all the registers as readonly for
       application to poll registers efficiently to check status.
     * It provides ioctl for userspace to pass I/O commands to write/mask
write
       the registers. How to configure is defined by userspace. Userspace
will
       pass the I/O commands sequence to the kernel driver, and kernel driver
       will validate the commands before it writes to the registers.
     * It provides ioctl to import dmabuf and ioctl to configure the the
DMA module
       in the SHIM tile which can access memory outside AI engine array.

The buffer management is out of this driver. In the above example, user
application
uses Xilinx runtime(XRT), XRT is the one to manage the buffers.

So if I understand this correctly, this driver handles the resource
management for the AI engines, PLs (programmable logic), and DMA
streams.  I think it's important to understand that there are multiple
address spaces here.  Normally when we talk about DMA in the kernel we
are referring to devices accessing an external resource like system
memory on the host CPU or another device's MMIO space (e.g., another
PCIe device).  It would be good to clarify which address spaces the
DMAs in your diagram refer to.  I think the DMAs in the AI engines are
specifically for DMAs within the AI engine logic (e.g., between AIs in
a partition).  How is DMA to system memory handled?  What about
dedicated memory on the FPGA (e.g., HBM or DDR on the FPGA itself)?
Is that what you are exposing as DMA bufs?  When you allocate a
DMA-buf for a partition, is that partition only allowed to access
memory that is part of that DMA buf?  I presume there is some
scatter/gather table that sets up the DMA range that the partition can
access?  Who loads the soft logic (Is that the PL or some other IP)?
Is the soft logic partitioned as well?  If I had some soft logic I
wanted to run on the FPGA, what would the kernel driver interaction
sequence look like?  Maybe using the OpenCL soft logic would be a good
example.  E.g.,

The AI engine driver only manage the resources within the AI

engine array. There are two types of DMAs of the AI engine device.

one is the AI engine tile local memory DMA which can only access the local

memory. There is another type of DMA which is in the SHIM tile. This

DMA can access external address space such as DDR. Although it can acess

the memory on fpga if user configure the platform that way, it is preferred to

use PL data mover to move data between FPGA memory and AI engine device.

The PL data mover will not be managed by the AI engine driver.

One SHIM DMA has up to 16 buffer descriptors to use.

Xilinx FPGA manager is the one used to program the FPGA soft logic.

E.g. when XRT is used, if AI engine is connected to FPGA logic, the XRT stack is

the one to manage the configuration sequence.

1. user has soft logic blob generated by their soft logic compiler (is
this compiler open source?)
The soft logic blob is generated by Xilinx tools which is not open source yet.
2. user calls AI engine kernel driver to allocate the required
resources (AI engines, AI engine DMAs, doorbells of some sort?  etc.)

User will call AI engine kernel driver to allocate required resources within

the AI engine array at runtime.

However the patches for it is not in this patch set.

3. user calls AI engine kernel driver to allocate system memory and/or
FGPA memory that can be used by the soft logic blob

AI engine kernel driver doesn't allocate system memory. User can use other

kernel driver to allocate memory.

E.g. when XRT is used, user calls XRT kernel driver (zocl) to allocate system memory.

So far, the FPGA memory is usually assigned to a soft data mover when the platform is

created. Are you considering to have the FPGA memory in the DMA pool of the

system? If it is dedicated to a device, can reserved memory solve this problem?

The AI engine kernel driver doesn't consider this yet.

4. user calls AI engine kernel driver to load soft logic

I assume you are referring to the soft logic on the FPGA side which is not

part of the AI engine device. FPGA manager is the one to load the soft logic on FPGA.

5. user interfaces with soft logic (how? presumably via some memory
resource allocated in 2 and 3?)

I assume you are referring to the soft logic on the FPGA side (not the AI engine device)

The user interface with soft logic is managed by the soft logic IP driver.

Each soft logic has some memory mapped control registers. User can access those

registers through the soft logic IP driver.

About memory allocation, I think it is better to manage the shared memory out of

a specific device driver. Are you looking for memory management which covers

both the system memory and fpga memory, and the device can specify which memory

it prefers?


Thanks,

Wendy


Thanks,

Alex


Best Regards,

Wendy

Thanks,

Alex


v3:
* unlock AIE dev mutex after failed to gain the partition lock in
    errors handing
* replace pointer with __u64 and enum with __u32 in ioctl

v2:
* Fix dtschema check errors
* Fix test bot warning on interrupt implementation. Removed set but
    unused  varaible.
* Fix compilation unused function warning of firmware change in case
    ZynqMP firmware is not configured
* There are other warning on ZynqMP firmware reported from testbot
    which is not introduced by this patch set.
    "[PATCH] firmware: xlnx-zynqmp: fix compilation warning" is submitted
    for those fixes.


Izhar Ameer Shaikh (1):
    firmware: xilinx: Add IOCTL support for AIE ISR Clear

Nishad Saraf (2):
    misc: xilinx-ai-engine: Add support to request device management
      services
    misc: xilinx-ai-engine: Add support for servicing error interrupts

Wendy Liang (6):
    dt-binding: soc: xilinx: ai-engine: Add AI engine binding
    misc: Add Xilinx AI engine device driver
    misc: xilinx-ai-engine: Implement AI engine cleanup sequence
    misc: xilinx-ai-engine: expose AI engine tile memories to userspace
    misc: xilinx-ai-engine: add setting shim dma bd operation
    misc: xilinx-ai-engine: add request and release tiles

   .../bindings/soc/xilinx/xlnx,ai-engine.yaml        | 126 ++++
   MAINTAINERS                                        |   8 +
   drivers/firmware/xilinx/zynqmp.c                   |  14 +
   drivers/misc/Kconfig                               |  12 +
   drivers/misc/Makefile                              |   1 +
   drivers/misc/xilinx-ai-engine/Makefile             |  16 +
   drivers/misc/xilinx-ai-engine/ai-engine-aie.c      | 608 +++++++++++++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-clock.c    | 245 ++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-dev.c      | 496 ++++++++++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-dma.c      | 481 +++++++++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-internal.h | 519 ++++++++++++++++
   .../misc/xilinx-ai-engine/ai-engine-interrupt.c    | 659 +++++++++++++++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-mem.c      | 275 +++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-part.c     | 635 ++++++++++++++++++++
   drivers/misc/xilinx-ai-engine/ai-engine-res.c      | 219 +++++++
   drivers/misc/xilinx-ai-engine/ai-engine-reset.c    | 159 +++++
   include/linux/firmware/xlnx-zynqmp.h               |   8 +
   include/uapi/linux/xlnx-ai-engine.h                | 238 ++++++++
   18 files changed, 4719 insertions(+)
   create mode 100644 Documentation/devicetree/bindings/soc/xilinx/xlnx,ai-engine.yaml
   create mode 100644 drivers/misc/xilinx-ai-engine/Makefile
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-aie.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-clock.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-dev.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-dma.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-internal.h
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-interrupt.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-mem.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-part.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-res.c
   create mode 100644 drivers/misc/xilinx-ai-engine/ai-engine-reset.c
   create mode 100644 include/uapi/linux/xlnx-ai-engine.h

--
2.7.4

_______________________________________________
dri-devel mailing list
dri-devel@xxxxxxxxxxxxxxxxxxxxx
https://lists.freedesktop.org/mailman/listinfo/dri-devel
_______________________________________________
dri-devel mailing list
dri-devel@xxxxxxxxxxxxxxxxxxxxx
https://lists.freedesktop.org/mailman/listinfo/dri-devel



[Index of Archives]     [Device Tree Compilter]     [Device Tree Spec]     [Linux Driver Backports]     [Video for Linux]     [Linux USB Devel]     [Linux PCI Devel]     [Linux Audio Users]     [Linux Kernel]     [Linux SCSI]     [XFree86]     [Yosemite Backpacking]


  Powered by Linux