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278 lines
11 KiB
278 lines
11 KiB
gRPC C++ - Building from source |
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=========================== |
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This document has detailed instructions on how to build gRPC C++ from source. Note that it only covers the build of gRPC itself and is mostly meant for gRPC C++ contributors and/or power users. |
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Other should follow the user instructions. See the [How to use](https://github.com/grpc/grpc/tree/master/src/cpp#to-start-using-grpc-c) instructions for guidance on how to add gRPC as a dependency to a C++ application (there are several ways and system wide installation is often not the best choice). |
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# Pre-requisites |
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## Linux |
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```sh |
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$ [sudo] apt-get install build-essential autoconf libtool pkg-config |
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``` |
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If you plan to build using CMake |
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```sh |
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$ [sudo] apt-get install cmake |
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``` |
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If you are a contributor and plan to build and run tests, install the following as well: |
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```sh |
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$ # clang and LLVM C++ lib is only required for sanitizer builds |
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$ [sudo] apt-get install clang libc++-dev |
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``` |
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## MacOS |
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On a Mac, you will first need to |
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install Xcode or |
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[Command Line Tools for Xcode](https://developer.apple.com/download/more/) |
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and then run the following command from a terminal: |
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```sh |
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$ [sudo] xcode-select --install |
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``` |
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To build gRPC from source, you may need to install the following |
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packages from [Homebrew](https://brew.sh): |
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```sh |
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$ brew install autoconf automake libtool shtool |
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``` |
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If you plan to build using CMake, follow the instructions from https://cmake.org/download/ |
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*Tip*: when building, |
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you *may* want to explicitly set the `LIBTOOL` and `LIBTOOLIZE` |
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environment variables when running `make` to ensure the version |
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installed by `brew` is being used: |
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```sh |
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$ LIBTOOL=glibtool LIBTOOLIZE=glibtoolize make |
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``` |
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## Windows |
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To prepare for cmake + Microsoft Visual C++ compiler build |
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- Install Visual Studio 2015 or 2017 (Visual C++ compiler will be used). |
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- Install [Git](https://git-scm.com/). |
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- Install [CMake](https://cmake.org/download/). |
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- Install [nasm](https://www.nasm.us/) and add it to `PATH` (`choco install nasm`) - *required by boringssl* |
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- (Optional) Install [Ninja](https://ninja-build.org/) (`choco install ninja`) |
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# Clone the repository (including submodules) |
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Before building, you need to clone the gRPC github repository and download submodules containing source code |
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for gRPC's dependencies (that's done by the `submodule` command or `--recursive` flag). Use following commands |
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to clone the gRPC repository at the [latest stable release tag](https://github.com/grpc/grpc/releases) |
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## Unix |
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```sh |
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$ git clone -b RELEASE_TAG_HERE https://github.com/grpc/grpc |
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$ cd grpc |
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$ git submodule update --init |
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``` |
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## Windows |
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``` |
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> git clone -b RELEASE_TAG_HERE https://github.com/grpc/grpc |
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> cd grpc |
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> git submodule update --init |
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``` |
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NOTE: The `bazel` build tool uses a different model for dependencies. You only need to worry about downloading submodules if you're building |
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with something else than `bazel` (e.g. `cmake`). |
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# Build from source |
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In the C++ world, there's no "standard" build system that would work for in all supported use cases and on all supported platforms. |
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Therefore, gRPC supports several major build systems, which should satisfy most users. Depending on your needs |
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we recommend building using `bazel` or `cmake`. |
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## Building with bazel (recommended) |
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Bazel is the primary build system for gRPC C++ and if you're comfortable with using bazel, we can certainly recommend it. |
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Using bazel will give you the best developer experience as well as faster and cleaner builds. |
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You'll need `bazel` version `1.0.0` or higher to build gRPC. |
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See [Installing Bazel](https://docs.bazel.build/versions/master/install.html) for instructions how to install bazel on your system. |
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We support building with `bazel` on Linux, MacOS and Windows. |
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From the grpc repository root |
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``` |
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# Build gRPC C++ |
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$ bazel build :all |
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``` |
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``` |
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# Run all the C/C++ tests |
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$ bazel test --config=dbg //test/... |
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``` |
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NOTE: If you are gRPC maintainer and you have access to our test cluster, you should use the our [gRPC's Remote Execution environment](tools/remote_build/README.md) |
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to get significant improvement to the build and test speed (and a bunch of other very useful features). |
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## Building with CMake |
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### Linux/Unix, Using Make |
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Run from grpc directory after cloning the repo with --recursive or updating submodules. |
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``` |
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$ mkdir -p cmake/build |
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$ cd cmake/build |
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$ cmake ../.. |
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$ make |
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``` |
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If you want to build shared libraries (`.so` files), run `cmake` with `-DBUILD_SHARED_LIBS=ON`. |
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### Windows, Using Visual Studio 2015 or 2017 |
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When using the "Visual Studio" generator, |
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cmake will generate a solution (`grpc.sln`) that contains a VS project for |
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every target defined in `CMakeLists.txt` (+ few extra convenience projects |
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added automatically by cmake). After opening the solution with Visual Studio |
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you will be able to browse and build the code. |
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``` |
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> @rem Run from grpc directory after cloning the repo with --recursive or updating submodules. |
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> md .build |
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> cd .build |
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> cmake .. -G "Visual Studio 14 2015" |
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> cmake --build . --config Release |
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``` |
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Using gRPC C++ as a DLL is not recommended, but you can still enable it by running `cmake` with `-DBUILD_SHARED_LIBS=ON`. |
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### Windows, Using Ninja (faster build). |
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Please note that when using Ninja, you will still need Visual C++ (part of Visual Studio) |
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installed to be able to compile the C/C++ sources. |
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``` |
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> @rem Run from grpc directory after cloning the repo with --recursive or updating submodules. |
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> cd cmake |
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> md build |
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> cd build |
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> call "%VS140COMNTOOLS%..\..\VC\vcvarsall.bat" x64 |
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> cmake ..\.. -GNinja -DCMAKE_BUILD_TYPE=Release |
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> cmake --build . |
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``` |
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Using gRPC C++ as a DLL is not recommended, but you can still enable it by running `cmake` with `-DBUILD_SHARED_LIBS=ON`. |
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### Windows: A note on building shared libs (DLLs) |
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Windows DLL build is supported at a "best effort" basis and we don't recommend using gRPC C++ as a DLL as there are some known drawbacks around how C++ DLLs work on Windows. For example, there is no stable C++ ABI and you can't safely allocate memory in one DLL, and free it in another etc. |
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That said, we don't actively prohibit building DLLs on windows (it can be enabled in cmake with `-DBUILD_SHARED_LIBS=ON`), and are free to use the DLL builds |
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at your own risk. |
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- you've been warned that there are some important drawbacks and some things might not work at all or will be broken in interesting ways. |
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- we don't have extensive testing for DLL builds in place (to avoid maintenance costs, increased test duration etc.) so regressions / build breakages might occur |
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### Dependency management |
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gRPC's CMake build system has two options for handling dependencies. |
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CMake can build the dependencies for you, or it can search for libraries |
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that are already installed on your system and use them to build gRPC. |
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This behavior is controlled by the `gRPC_<depname>_PROVIDER` CMake variables, |
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e.g. `gRPC_CARES_PROVIDER`. The options that these variables take are as follows: |
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* module - build dependencies alongside gRPC. The source code is obtained from |
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gRPC's git submodules. |
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* package - use external copies of dependencies that are already available |
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on your system. These could come from your system package manager, or perhaps |
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you pre-installed them using CMake with the `CMAKE_INSTALL_PREFIX` option. |
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For example, if you set `gRPC_CARES_PROVIDER=module`, then CMake will build |
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c-ares before building gRPC. On the other hand, if you set |
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`gRPC_CARES_PROVIDER=package`, then CMake will search for a copy of c-ares |
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that's already installed on your system and use it to build gRPC. |
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### Install after build |
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Perform the following steps to install gRPC using CMake. |
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* Set `-DgRPC_INSTALL=ON` |
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* Build the `install` target |
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The install destination is controlled by the |
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[`CMAKE_INSTALL_PREFIX`](https://cmake.org/cmake/help/latest/variable/CMAKE_INSTALL_PREFIX.html) variable. |
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If you are running CMake v3.13 or newer you can build gRPC's dependencies |
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in "module" mode and install them alongside gRPC in a single step. |
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[Example](test/distrib/cpp/run_distrib_test_cmake_module_install.sh) |
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If you are building gRPC < 1.27 or if you are using CMake < 3.13 you will need |
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to select "package" mode (rather than "module" mode) for the dependencies. |
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This means you will need to have external copies of these libraries available |
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on your system. This [example](test/distrib/cpp/run_distrib_test_cmake.sh) shows |
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how to install dependencies with cmake before proceeding to installing gRPC itself. |
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``` |
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# NOTE: all of gRPC's dependencies need to be already installed |
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$ cmake ../.. -DgRPC_INSTALL=ON \ |
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-DCMAKE_BUILD_TYPE=Release \ |
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-DgRPC_ABSL_PROVIDER=package \ |
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-DgRPC_CARES_PROVIDER=package \ |
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-DgRPC_PROTOBUF_PROVIDER=package \ |
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-DgRPC_RE2_PROVIDER=package \ |
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-DgRPC_SSL_PROVIDER=package \ |
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-DgRPC_ZLIB_PROVIDER=package |
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$ make |
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$ make install |
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``` |
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### Cross-compiling |
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You can use CMake to cross-compile gRPC for another architecture. In order to |
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do so, you will first need to build `protoc` and `grpc_cpp_plugin` |
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for the host architecture. These tools are used during the build of gRPC, so |
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we need copies of executables that can be run natively. |
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You will likely need to install the toolchain for the platform you are |
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targeting for your cross-compile. Once you have done so, you can write a |
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toolchain file to tell CMake where to find the compilers and system tools |
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that will be used for this build. |
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This toolchain file is specified to CMake by setting the `CMAKE_TOOLCHAIN_FILE` |
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variable. |
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``` |
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$ cmake ../.. -DCMAKE_TOOLCHAIN_FILE=path/to/file |
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$ make |
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``` |
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[Cross-compile example](test/distrib/cpp/run_distrib_test_cmake_aarch64_cross.sh) |
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### A note on SONAME and its ABI compatibility implications in the cmake build |
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Best efforts are made to bump the SONAME revision during ABI breaches. While a |
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change in the SONAME clearly indicates an ABI incompatibility, no hard guarantees |
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can be made about any sort of ABI stability across the same SONAME version. |
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## Building with make on UNIX systems (deprecated) |
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NOTE: `make` used to be gRPC's default build system, but we're no longer recommending it. You should use `bazel` or `cmake` instead. The `Makefile` is only intended for internal usage and is not meant for public consumption. |
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From the grpc repository root |
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```sh |
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$ make |
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``` |
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NOTE: if you get an error on linux such as 'aclocal-1.15: command not found', which can happen if you ran 'make' before installing the pre-reqs, try the following: |
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```sh |
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$ git clean -f -d -x && git submodule foreach --recursive git clean -f -d -x |
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$ [sudo] apt-get install build-essential autoconf libtool pkg-config |
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$ make |
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``` |
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### A note on `protoc` |
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By default gRPC uses [protocol buffers](https://github.com/protocolbuffers/protobuf), |
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you will need the `protoc` compiler to generate stub server and client code. |
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If you compile gRPC from source, as described above, the Makefile will |
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automatically try compiling the `protoc` in third_party if you cloned the |
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repository recursively and it detects that you do not already have 'protoc' compiler |
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installed.
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