Halide is a programming language designed to make it easier to write high-performance image and array processing code on modern machines. Halide currently targets:

• CPU architectures: X86, ARM, Hexagon, PowerPC, RISC-V, WebAssembly
• Operating systems: Linux, Windows, macOS, Android, iOS, Qualcomm QuRT
• GPU Compute APIs: CUDA, OpenCL, Apple Metal, Microsoft Direct X 12, Vulkan

Rather than being a standalone programming language, Halide is embedded in C++. This means you write C++ code that builds an in-memory representation of a Halide pipeline using Halide's C++ API. You can then compile this representation to an object file, or JIT-compile it and run it in the same process. Halide also provides a Python binding that provides full support for writing Halide embedded in Python without C++.

Halide requires C++17 (or later) to use.

For more detail about what Halide is, see https://halide-lang.org.

For API documentation see https://halide-lang.org/docs.

For some example code, read through the tutorials online at https://halide-lang.org/tutorials. The corresponding code is in the tutorials/ directory. Larger examples are in the apps/ directory.

If you've acquired a full source distribution and want to build Halide, see the notes below.

We provide binary wheels on PyPI. Halide provides bindings for C++ and Python. Even if you only intend to use Halide from C++, pip may be the easiest way to get a binary build of Halide.

Full releases may be installed with pip like so:

$ pip install halide

Every commit to main is published to our package index as a development version. If you use uv, you can pin the nightly Halide in a project like so:

$ uv add halide --prerelease=allow --index https://pypi.halide-lang.org/simple

Or install directly with pip:

$ pip install halide --pre --extra-index-url https://pypi.halide-lang.org/simple

Currently, we provide wheels for: Windows x86-64, macOS x86-64, macOS arm64, and Linux x86-64. The Linux wheels are built for manylinux_2_28, which makes them broadly compatible (Debian 10, Ubuntu 18.10, Fedora 29).

For C++ usage of the pip package: On Linux and macOS, CMake's find_package command should find Halide as long as you're in the same virtual environment you installed it in. On Windows, you will need to add the virtual environment root directory to CMAKE_PREFIX_PATH. This can be done by running set CMAKE_PREFIX_PATH=%VIRTUAL_ENV% in cmd.

Other build systems can find the Halide root path by running python -c "import halide; print(halide.install_dir())".

Alternatively, if you use macOS, you can install Halide via Homebrew like so:

$ brew install halide

The latest version of Halide can always be found on GitHub at https://github.com/halide/Halide/releases

We provide binary releases for many popular platforms and architectures, including 32/64-bit x86 Windows, 64-bit x86/ARM macOS, and 32/64-bit x86/ARM Ubuntu Linux.

The Linux tarballs are built on a recent Ubuntu LTS; if your distribution is too old, it might not have the requisite glibc. The pip wheels are built for manylinux_2_28 and are more broadly compatible.

If you use vcpkg to manage dependencies, you can install Halide via:

$ vcpkg install halide:x64-windows # or x64-linux/x64-osx

One caveat: vcpkg installs only the minimum Halide backends required to compile code for the active platform. If you want to include all the backends, you should install halide[target-all]:x64-windows instead.

We are interested in bringing Halide to other popular package managers and Linux distribution repositories! We track the status of various distributions of Halide in this GitHub issue. If you have experience publishing packages we would be happy to work with you!

There are two sets of platform requirements relevant to Halide: those required to run the compiler library in either JIT or AOT mode, and those required to run the binary outputs of the AOT compiler.

These are the tested host toolchain and platform combinations for building and running the Halide compiler library.

Some users have successfully built Halide for Linux using Clang 9.0.0+, for Windows using ClangCL 11.0.0+, and for Windows ARM64 by cross-compiling with MSVC. We do not actively test these scenarios, however, so your mileage may vary.

Beyond these, we are willing to support (by accepting PRs for) platform and toolchain combinations that still receive active, first-party, public support from their original vendors. For instance, at time of writing, this excludes Windows 7 and includes Ubuntu 18.04 LTS.

Compiled AOT pipelines are expected to have much broader platform support. The binaries use the C ABI, and we expect any compliant C compiler to be able to use the generated headers correctly. The C++ bindings currently require C++17. If you discover a compatibility problem with a generated pipeline, please open an issue.

At any point in time, building Halide requires either the latest stable version of LLVM, the previous stable version of LLVM, or trunk. At the time of writing, this means versions 23, 22, and 21 are supported, but 20 is not.

We publish the LLVM builds we use in CI as Python packages on our package index. This is the easiest way to get a suitable LLVM on any platform. From the Halide source tree, install with uv:

$ uv sync --group ci-llvm-22 --no-install-project
$ export Halide_LLVM_ROOT=$(halide-llvm --prefix)

Replace 22 with the desired LLVM major version (21, 22, 23, or main). Binary wheels are available for Linux (x86-64, x86-32, AArch64, ARMv7), macOS (x86-64, ARM64), and Windows (x86-64, x86-32).

On macOS, Homebrew is also a good option: brew install llvm. On Debian flavors of Linux, the LLVM APT repo works well; use the provided installation script.

$ git clone --depth 1 --branch llvmorg-21.1.8 https://github.com/llvm/llvm-project.git

$ cmake -G Ninja -S llvm-project/llvm -B build \
        -DCMAKE_BUILD_TYPE=Release \
        -DLLVM_ENABLE_PROJECTS="clang;lld;clang-tools-extra" \
        -DLLVM_ENABLE_RUNTIMES=compiler-rt \
        -DLLVM_TARGETS_TO_BUILD="WebAssembly;X86;AArch64;ARM;Hexagon;NVPTX;PowerPC;RISCV" \
        -DLLVM_ENABLE_ASSERTIONS=ON \
        -DLLVM_ENABLE_EH=ON \
        -DLLVM_ENABLE_RTTI=ON \
        -DLLVM_ENABLE_HTTPLIB=OFF \
        -DLLVM_ENABLE_LIBEDIT=OFF \
        -DLLVM_ENABLE_LIBXML2=OFF \
        -DLLVM_ENABLE_TERMINFO=OFF \
        -DLLVM_ENABLE_ZLIB=OFF \
        -DLLVM_ENABLE_ZSTD=OFF \
        -DLLVM_BUILD_32_BITS=OFF
$ cmake --build build
$ cmake --install build --prefix llvm-install

This is discussed in greater detail in BuildingHalideWithCMake.md. CMake version 3.28+ is required to build Halide.

After acquiring LLVM, change directory to the Halide repository and run:

$ cmake -G Ninja -S . -B build -DCMAKE_BUILD_TYPE=Release -DHalide_LLVM_ROOT=$LLVM_ROOT
$ cmake --build build

Setting -DHalide_LLVM_ROOT is not required if you have a suitable system-wide version installed. However, if you have multiple LLVMs installed, it can pick between them. Do not use a relative path for Halide_LLVM_ROOT. It can cause problems on some systems.

If you use Homebrew on macOS, you can use the provided CMake preset:

$ cmake --preset=macOS -S . -B build
$ cmake --build build

This automatically finds LLVM from Homebrew's install path.

We suggest building with Visual Studio 2022. Your mileage may vary with earlier versions. Be sure to install the "C++ CMake tools for Windows" in the Visual Studio installer. For older versions of Visual Studio, do not install the CMake tools, but instead acquire CMake and Ninja from their respective project websites.

These instructions start from the D: drive. We assume this git repo is cloned to D:\Halide. We also assume that your shell environment is set up correctly. For a 64-bit build, run:

D:\> "C:\Program Files (x86)\Microsoft Visual Studio\2022\Community\VC\Auxiliary\Build\vcvarsall.bat" x64

For a 32-bit build, run:

D:\> "C:\Program Files (x86)\Microsoft Visual Studio\2022\Community\VC\Auxiliary\Build\vcvarsall.bat" x64_x86

The best way to get compatible dependencies on Windows is to use vcpkg. Install it like so:

D:\> git clone https://github.com/Microsoft/vcpkg.git
D:\> cd vcpkg
D:\vcpkg> .\bootstrap-vcpkg.bat -disableMetrics
...
CMake projects should use: "-DCMAKE_TOOLCHAIN_FILE=D:/vcpkg/scripts/buildsystems/vcpkg.cmake"

Halide includes a vcpkg-configuration.json that automatically configures overlay ports and overlay triplets. These overlays redirect LLVM and Python to system installations, so vcpkg only builds the smaller dependencies (flatbuffers, wabt, pybind11, etc.). You must have LLVM and Python installed separately (see Acquiring LLVM above).

Create a separate build tree and call CMake with vcpkg's toolchain. This will build in either 32-bit or 64-bit depending on the environment script (vcvars) that was run earlier.

D:\Halide> cmake -G Ninja -S . -B build ^
                 --toolchain D:/vcpkg/scripts/buildsystems/vcpkg.cmake ^
                 -DCMAKE_BUILD_TYPE=Release

Or use a CMake preset (e.g. for a Visual Studio build):

D:\Halide> cmake --preset=win64  &:: or win32 for 32-bit
D:\Halide> cmake --build build\win64

For a Ninja-based build with vcpkg:

D:\Halide> cmake --preset=release-vcpkg -S . -B build
D:\Halide> cmake --build build

To run all the tests:

D:\Halide> ctest --test-dir build --output-on-failure

Subsets of the tests can be selected with -L and include correctness, generator, error, and the other directory names under tests/.

D:\> git clone --depth 1 --branch llvmorg-21.1.8 https://github.com/llvm/llvm-project.git

D:\> cmake -G Ninja -S llvm-project\llvm -B build ^
           -DCMAKE_BUILD_TYPE=Release ^
           -DLLVM_ENABLE_PROJECTS=clang;lld;clang-tools-extra ^
           -DLLVM_ENABLE_RUNTIMES=compiler-rt ^
           -DLLVM_TARGETS_TO_BUILD=WebAssembly;X86;AArch64;ARM;Hexagon;NVPTX;PowerPC;RISCV ^
           -DLLVM_ENABLE_ASSERTIONS=ON ^
           -DLLVM_ENABLE_EH=ON ^
           -DLLVM_ENABLE_RTTI=ON ^
           -DLLVM_ENABLE_HTTPLIB=OFF ^
           -DLLVM_ENABLE_LIBEDIT=OFF ^
           -DLLVM_ENABLE_LIBXML2=OFF ^
           -DLLVM_ENABLE_TERMINFO=OFF ^
           -DLLVM_ENABLE_ZLIB=OFF ^
           -DLLVM_ENABLE_ZSTD=OFF ^
           -DLLVM_BUILD_32_BITS=OFF

D:\> cmake --build build --config Release
D:\> cmake --install build --prefix llvm-install

Do what the buildbots do: https://buildbot.halide-lang.org/master/#/builders

If the row that best matches your system is red, then maybe things aren't just broken for you. If it's green, then you can click through to the latest build and see the commands that the build bots run. Open a step ("Configure Halide" is useful) and look at the "stdio" logs in the viewer. These logs contain the full commands that were run, as well as the environment variables they were run with.

TL;DR: Have LLVM 17 (or greater) installed and run make in the root directory of the repository (where this README is).

By default, make will use the llvm-config tool found in the PATH. If you want to use a different LLVM, such as a custom-built one following the instructions above, set the following environment variable:

$ export LLVM_CONFIG="$LLVM_ROOT/bin/llvm-config"

Now you should be able to just run make in the root directory of the Halide source tree. make run_tests will run the JIT test suite, and make test_apps will make sure all the apps compile and run (but won't check their output).

When building the tests, you can set the AOT compilation target with the HL_TARGET environment variable.

If you wish to build Halide in a separate directory, you can do that like so:

$ cd ..
$ mkdir halide_build
$ cd halide_build
$ make -f ../Halide/Makefile

HL_JIT_TARGET=... will set Halide's JIT compilation target.

HL_DEBUG_CODEGEN=1 will print out pseudocode for what Halide is compiling. Higher numbers will print more detail.

HL_NUM_THREADS=... specifies the number of threads to create for the thread pool. When the async scheduling directive is used, more threads than this number may be required and thus allocated. A maximum of 256 threads is allowed. (By default, the number of cores on the host is used.)

HL_TRACE_FILE=... specifies a binary target file to dump tracing data into (ignored unless at least one trace_ feature is enabled in the target). The output can be parsed programmatically by starting from the code in utils/HalideTraceViz.cpp.

We have more documentation in doc/, the following links might be helpful:

The following links are of greater interest to developers wishing to contribute code to Halide: