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Ahmed Hesham 9ba6f062d4 Add support for allocating DMA buffers (#2170 )

This adds support for allocating DMA buffers on systems that support it,
i.e. Linux and Android.

On mainline Linux, starting version 5.6 (equivalent to Android 12),
there is a new kernel module framework available called [DMA-BUF
Heaps](https://github.com/torvalds/linux/blob/master/drivers/dma-buf/dma-heap.c).
The goal of this framework is to provide a standardised way for user
applications to allocate and share memory buffers between different
devices, subsystems, etc. The main feature of interest is that the
framework provides device-agnostic allocation; it abstracts away the
underlying hardware, and provides a single IOCTL,
`DMA_HEAP_IOCTL_ALLOC`. Mainline implementation provides two heaps that
act as character devices that can allocate DMA buffers; system, which
uses the buddy allocator, and cma, which uses the
[CMA](https://developer.toradex.com/software/linux-resources/linux-features/contiguous-memory-allocator-cma-linux/)
(Contiguous Memory Allocator). Both of these are [kernel configuration
options](https://github.com/torvalds/linux/blob/master/drivers/dma-buf/heaps/Kconfig)
that need to be enabled when building the Linux kernel. Generally, any
kernel module implementing this framework is made available under
/dev/dma_heaps/<heap_name>, e.g. /dev/dma_heaps/system.

The implementation currently only supports one type of DMA heaps;
`system`, the default device path for which is `/dev/dma_heap/system`.
The path can be overridden at runtime using an environment variable,
`OCL_CTS_DMA_HEAP_PATH_SYSTEM`, if needed. Extending this in the future
should be trivial (subject to platform support), by adding an entry to
the enum `dma_buf_heap_type`, and an appropriate default path and
overriding environment variable name.

The proposed implementation will conditionally compile if the conditions
are met (i.e. building for Linux or Android, using kernel headers >=
5.6.0), and will provide a compile-time warning otherwise, and return
`-1` as the DMA handle in runtime if not.

To demonstrate the functionality, a new test is added for the
`cl_khr_external_memory_dma_buf` extension. If the extension is
supported by the device, a DMA buffer will be allocated and used to
create a CL buffer, that is then used by a simple kernel.

This should provide a way forward for adding more tests that depend on
DMA buffers.

---------

Signed-off-by: Gorazd Sumkovski <gorazd.sumkovski@arm.com>
Signed-off-by: Ahmed Hesham <ahmed.hesham@arm.com>
Co-authored-by: Gorazd Sumkovski <gorazd.sumkovski@arm.com>

2025-02-26 09:51:22 -08:00

.github

Add Android to the CI build matrix (#2165 )

2024-12-03 08:56:46 -08:00

test_common

Add support for allocating DMA buffers (#2170 )

2025-02-26 09:51:22 -08:00

test_conformance

Add support for allocating DMA buffers (#2170 )

2025-02-26 09:51:22 -08:00

.clang-format

clang-format: indent continued lines (#739 )

2020-04-17 10:54:58 +01:00

.gitattributes

Add SPIR-V binaries for OpenCL C++ tests.

2017-07-25 20:39:41 +05:30

.gitignore

[NFC] Add .gitignore file (#2216 )

2025-01-09 20:55:37 -08:00

check-format.sh

Bump clang-format version to 14 (#1983 )

2024-06-25 09:44:31 -07:00

CMakeLists.txt

Generate the SPIR-V shaders automatically at build time (#2200 )

2025-02-11 08:43:37 -08:00

CODE_OF_CONDUCT.md

Create CODE_OF_CONDUCT.md

2018-10-10 16:02:58 -04:00

LICENSE.txt

Change name to LICENSE.txt, revert to Apache 2.0

2018-10-03 10:08:39 -04:00

presubmit.sh

Add Android to the CI build matrix (#2165 )

2024-12-03 08:56:46 -08:00

README.md

Add new extensions to conformance csv files (#2096 )

2024-10-08 09:58:31 -07:00

README.md

OpenCL Conformance Test Suite (CTS)

This is the OpenCL CTS for all versions of the Khronos OpenCL standard.

Building the CTS

The CTS supports Linux, Windows, macOS, and Android platforms. In particular, GitHub Actions CI builds against Ubuntu 20.04, Windows-latest, and macos-latest.

Compiling the CTS requires the following CMake configuration options to be set:

CL_INCLUDE_DIR Points to the unified OpenCL-Headers.
CL_LIB_DIR Directory containing the OpenCL library to build against.
OPENCL_LIBRARIES Name of the OpenCL library to link.

It is advised that the OpenCL ICD-Loader is used as the OpenCL library to build against. Where CL_LIB_DIR points to a build of the ICD loader and OPENCL_LIBRARIES is "OpenCL".

Example Build

Steps on a Linux platform to clone dependencies from GitHub sources, configure a build, and compile.

git clone https://github.com/KhronosGroup/OpenCL-CTS.git
git clone https://github.com/KhronosGroup/OpenCL-Headers.git
git clone https://github.com/KhronosGroup/OpenCL-ICD-Loader.git

mkdir OpenCL-ICD-Loader/build
cmake -S OpenCL-ICD-Loader -B OpenCL-ICD-Loader/build \
      -DOPENCL_ICD_LOADER_HEADERS_DIR=$PWD/OpenCL-Headers
cmake --build ./OpenCL-ICD-Loader/build --config Release

mkdir OpenCL-CTS/build
cmake -S OpenCL-CTS -B OpenCL-CTS/build \
      -DCL_INCLUDE_DIR=$PWD/OpenCL-Headers \
      -DCL_LIB_DIR=$PWD/OpenCL-ICD-Loader/build \
      -DOPENCL_LIBRARIES=OpenCL
cmake --build OpenCL-CTS/build --config Release

Running the CTS

A build of the CTS contains multiple executables representing the directories in the test_conformance folder. Each of these executables contains sub-tests, and possibly smaller granularities of testing within the sub-tests.

See the --help output on each executable for the list of sub-tests available, as well as other options for configuring execution.

If the OpenCL library built against is the ICD Loader, and the vendor library to be tested is not registered in the default ICD Loader location then the OCL_ICD_FILENAMES environment variable will need to be set for the ICD Loader to detect the OpenCL library to use at runtime. For example, to run the basic tests on a Linux platform:

OCL_ICD_FILENAMES=/path/to/vendor_lib.so ./test_basic

Offline Compilation

Testing OpenCL drivers which do not have a runtime compiler can be done by using additional command line arguments provided by the test harness for tests which require compilation, these are:

--compilation-mode Selects if OpenCL-C source code should be compiled using an external tool before being passed on to the OpenCL driver in that form for testing. Online is the default mode, but also accepts the values spir-v, and binary.
--compilation-cache-mode Controls how the compiled OpenCL-C source code should be cached on disk.
--compilation-cache-path Accepts a path to a directory where the compiled binary cache should be stored on disk.
--compilation-program Accepts a path to an executable (default: cl_offline_compiler) invoked by the test harness to perform offline compilation of OpenCL-C source code. This executable must match the interface description.

Generating a Conformance Report

The Khronos Conformance Process Document details the steps required for a conformance submission. In this repository opencl_conformance_tests_full.csv defines the full list of tests which must be run for conformance. The output log of which must be included alongside a filled in submission details template.

Utility script run_conformance.py can be used to help generating the submission log, although it is not required.

Git tags are used to define the version of the repository conformance submissions are made against.

Contributing

Contributions are welcome to the project from Khronos members and non-members alike via GitHub Pull Requests (PR). Alternatively, if you've found a bug or have a question please file an issue in the GitHub project. First time contributors will be required to sign the Khronos Contributor License Agreement (CLA) before their PR can be merged.

PRs to the repository are required to be clang-format clean to pass CI. Developers can either use the git-clang-format tool locally to verify this before contributing, or update their PR based on the diff provided by a failing CI job.