# Development Install required tools: - cmake version 3.24 or higher - go version 1.22 or higher - gcc version 11.4.0 or higher ```bash brew install go cmake gcc ``` Optionally enable debugging and more verbose logging: ```bash # At build time export CGO_CFLAGS="-g" # At runtime export OLLAMA_DEBUG=1 ``` Get the required libraries and build the native LLM code: ```bash go generate ./... ``` Then build ollama: ```bash go build . ``` Now you can run `ollama`: ```bash ./ollama ``` ### Linux #### Linux CUDA (NVIDIA) _Your operating system distribution may already have packages for NVIDIA CUDA. Distro packages are often preferable, but instructions are distro-specific. Please consult distro-specific docs for dependencies if available!_ Install `cmake` and `golang` as well as [NVIDIA CUDA](https://developer.nvidia.com/cuda-downloads) development and runtime packages. Typically the build scripts will auto-detect CUDA, however, if your Linux distro or installation approach uses unusual paths, you can specify the location by specifying an environment variable `CUDA_LIB_DIR` to the location of the shared libraries, and `CUDACXX` to the location of the nvcc compiler. You can customize set set of target CUDA architectues by setting `CMAKE_CUDA_ARCHITECTURES` (e.g. "50;60;70") Then generate dependencies: ``` go generate ./... ``` Then build the binary: ``` go build . ``` #### Linux ROCm (AMD) _Your operating system distribution may already have packages for AMD ROCm and CLBlast. Distro packages are often preferable, but instructions are distro-specific. Please consult distro-specific docs for dependencies if available!_ Install [CLBlast](https://github.com/CNugteren/CLBlast/blob/master/doc/installation.md) and [ROCm](https://rocm.docs.amd.com/en/latest/) development packages first, as well as `cmake` and `golang`. Typically the build scripts will auto-detect ROCm, however, if your Linux distro or installation approach uses unusual paths, you can specify the location by specifying an environment variable `ROCM_PATH` to the location of the ROCm install (typically `/opt/rocm`), and `CLBlast_DIR` to the location of the CLBlast install (typically `/usr/lib/cmake/CLBlast`). You can also customize the AMD GPU targets by setting AMDGPU_TARGETS (e.g. `AMDGPU_TARGETS="gfx1101;gfx1102"`) ``` go generate ./... ``` Then build the binary: ``` go build . ``` ROCm requires elevated privileges to access the GPU at runtime. On most distros you can add your user account to the `render` group, or run as root. #### Advanced CPU Settings By default, running `go generate ./...` will compile a few different variations of the LLM library based on common CPU families and vector math capabilities, including a lowest-common-denominator which should run on almost any 64 bit CPU somewhat slowly. At runtime, Ollama will auto-detect the optimal variation to load. If you would like to build a CPU-based build customized for your processor, you can set `OLLAMA_CUSTOM_CPU_DEFS` to the llama.cpp flags you would like to use. For example, to compile an optimized binary for an Intel i9-9880H, you might use: ``` OLLAMA_CUSTOM_CPU_DEFS="-DLLAMA_AVX=on -DLLAMA_AVX2=on -DLLAMA_F16C=on -DLLAMA_FMA=on" go generate ./... go build . ``` #### Containerized Linux Build If you have Docker available, you can build linux binaries with `./scripts/build_linux.sh` which has the CUDA and ROCm dependencies included. The resulting binary is placed in `./dist` ### Windows Note: The windows build for Ollama is still under development. Install required tools: - MSVC toolchain - C/C++ and cmake as minimal requirements - Go version 1.22 or higher - MinGW (pick one variant) with GCC. - [MinGW-w64](https://www.mingw-w64.org/) - [MSYS2](https://www.msys2.org/) ```powershell $env:CGO_ENABLED="1" go generate ./... go build . ``` #### Windows CUDA (NVIDIA) In addition to the common Windows development tools described above, install CUDA after installing MSVC. - [NVIDIA CUDA](https://docs.nvidia.com/cuda/cuda-installation-guide-microsoft-windows/index.html) #### Windows ROCm (AMD Radeon) In addition to the common Windows development tools described above, install AMDs HIP package after installing MSVC. - [AMD HIP](https://www.amd.com/en/developer/resources/rocm-hub/hip-sdk.html) - [Strawberry Perl](https://strawberryperl.com/) Lastly, add `ninja.exe` included with MSVC to the system path (e.g. `C:\Program Files (x86)\Microsoft Visual Studio\2019\Community\Common7\IDE\CommonExtensions\Microsoft\CMake\Ninja`).