The C based gRPC (C++, Python, Ruby, Objective-C, PHP, C#) https://grpc.io/
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Jan Tattermusch 40d808ffdc Merge pull request #2474 from nicolasnoble/lets-actually-build-32-bits 10 years ago
..
src/core/surface Add missing file 10 years ago
tools Make this more robust against merges 10 years ago
vsprojects Faking tools target for win32. 10 years ago
BUILD.template Minor doc fix in BUILD and BUILD.template 10 years ago
Makefile.template Making sure that 32 bits is being built and run on Jenkins. 10 years ago
README.md Adding some documentation about the build/template system. 10 years ago
gRPC.podspec.template Move head podspec to v0.7. 10 years ago

README.md

Quick justification

We've approached the problem of the build system from a lot of different angles. The main issue was that there isn't a single build system that was going to single handedly cover all of our usage cases.

So instead we decided to work the following way:

  • A build.json file at the root is the source of truth for listing all of the target and files needed to build grpc and its tests, as well as basic system dependencies description.

  • Each project file (Makefile, Visual Studio project files, Bazel's BUILD) is a plain-text template that uses the build.json file to generate the final output file.

This way we can maintain as many project system as we see fit, without having to manually maintain them when we add or remove new code to the repository. Only the structure of the project file is relevant to the template. The actual list of source code and targets isn't.

We currently have template files for GNU Make, Visual Studio 2010 to 2015, and Bazel. In the future, we would like to expand to generating gyp or cmake project files (or potentially both), XCode project files, and an Android.mk file to be able to compile gRPC using Android's NDK.

We'll gladly accept contribution that'd create additional project files using that system.

Structure of build.json

The build.json file has the following structure:

{
  "settings": { ... },   # global settings, such as version number
  "filegroups": [ ... ], # groups of file that is automatically expanded
  "libs": [ ... ],       # list of libraries to build
  "targets": [ ... ],    # list of targets to build
}

The filegroups are helpful to re-use a subset of files in multiple targets. One filegroups entry has the following structure:

{
  "name": "arbitrary string", # the name of the filegroup
  "public_headers": [ ... ],  # list of public headers defined in that filegroup
  "headers": [ ... ],         # list of headers defined in that filegroup
  "src": [ ... ],             # list of source files defined in that filegroup
}

The libs array contains the list of all the libraries we describe. Some may be helper libraries for the tests. Some may be installable libraries. Some may be helper libraries for installable binaries.

The targets array contains the list of all the binary targets we describe. Some may be installable binaries.

One libs or targets entry has the following structure:

{
  "name": "arbitrary string", # the name of the library
  "build": "build type",      # in which situation we want that library to be
                              # built and potentially installed
  "language": "...",          # the language tag; "c" or "c++"
  "public_headers": [ ... ],  # list of public headers to install
  "headers": [ ... ],         # list of headers used by that target
  "src": [ ... ],             # list of files to compile
  "secure": "...",            # "yes", "no" or "check"
  "baselib": boolean,         # this is a low level library that has system
                              # dependencies
  "vs_project_guid: "...",    # Visual Studio's unique guid for that project
  "filegroups": [ ... ],      # list of filegroups to merge to that project
                              # note that this will be expanded automatically
  "deps": [ ... ],            # list of libraries this target depends on
}

The "build" tag

Currently, the "build" tag have these meanings:

  • "all": library to build on "make all", and install on the system.
  • "protoc": a protoc plugin to build on "make all" and install on the system.
  • "priviate": a library to only build for tests.
  • "test": a test binary to run on "make test".

All of the targets should always be present in the generated project file, if possible and applicable. But the build tag is what should group the targets together in a single build command.

The "secure" tag

This means this target requires OpenSSL one way or another. The values can be "yes", "no" and "check". The default value is "check". It means that the target requires OpenSSL, but that since the target depends on another one that is supposed to also import OpenSSL, the import should then be implicitely transitive. "check" should then only disable that target if OpenSSL hasn't been found or is unavailable.

The "baselib" boolean

This means this is a library that will provide most of the features for gRPC. In particular, if we're locally building OpenSSL, protobuf or zlib, then we should merge OpenSSL, protobuf or zlib inside that library. That effect depends on the "language" tag. OpenSSL and zlib are for "c" libraries, while protobuf is for "c++" ones.

The template system

We're currently using the mako templates renderer. That choice enables us to simply render text files without dragging with us a lot of other features. Feel free to explore the current templates in that directory. The simplest one is probably BUILD.template which is used to create the Bazel project file.

The renderer engine

As mentioned, the renderer is using mako templates, but some glue is needed to process all of that. See the buildgen folder for more details. We're mainly loading the build.json file, and massaging it, in order to get the list of properties we need, into a Python dictionary, that is then passed to the template while rending it.

The plugins

The file build.json itself isn't passed straight to the template files. It is first processed and modified by a few plugins. For example, the filegroups expander is a plugin.

The structure of a plugin is simple. The plugin must defined the function mako_plugin that takes a Python dictionary. That dictionary represents the current state of the build.json contents. The plugin can alter it to whatever feature it needs to add.