The Premake source code is organized into a few different folders:
src/actions
contains the code for the built-on actions and exporters, e.g. "vs2012" or "gmake". We are gradually migrating these into independent modules, but for now they live here.
src/base
contains the core Lua scripts, the code that is used to read and process your project scripts, and supporting logic for the actions and exporters.
src/host
contains all of the C language code, logic that either can't easily be written in Lua because of the way it needs to interact with the underlying operating system, or because a Lua implementation would be too slow. We try to keep C code to a minimum and use Lua whenever we can, to enable overrides and call arrays.
src/tools
contains the adapters for command line toolsets like GCC and Clang. We will probably be migrating these toward modules in the near-ish future as well.
modules
contains the official set of modules which are distributed as part of Premake. These modules add support for additional languages and toolsets to the core code in the src
folder.
In addition to those general categories, there are a few special files of note:
src/_premake_main.lua
contains the Lua-side program entry point, and is responsible for the main application flow. The C-side program entry point main()
is located in src/host/premake_main.c
.
src/_premake_init.lua
sets up much of the initial configuration, including all of the project scripting functions, the default set of command line arguments, and the default project configurations.
src/_modules.lua
contains the list of built-in modules which are automatically loaded in startup. See Embedding Modules for more information.
src/_manifest.lua
lists the Lua scripts that should be embedded into the Premake executable when making the release builds. There are separate manifests for Premake's core scripts and each embedded module.
Execution starts at main()
in src/host/premake_main.c
, which calls into to src/host/premake.c
to do the real bootstrapping work:
premake_init()
installs all of Premake's native C extensions to the Lua scripting environment.
premake_execute()
finds and runs src/_premake_main.lua
, which may be embedded into the executable for a release build, or located on the filesystem.
src/_premake_main.lua
in turn reads src/_manifest.lua
and loads all of the scripts listed there. Notably, this includes src/_premake_init.lua
which does
Once src/premake_main.lua
has finished, premake_execute()
calls _premake_main()
, which located at the end of src/_premake_main.lua
, and waits for it to return.
At this point, execution has moved into and remains in Lua; extending Premake by overriding functions and call arrays now becomes possible.
_premake_main()
uses a call array to control the high-level process of evaluating the user scripts and acting on the results. Notable functions in this list include:
prepareEnvironment()
sets more global variables and otherwise gets the script environment ready to use.
locateUserScript()
handles finding the user's project script, i.e. premake5.lua
on the file system.
checkInteractive()
is responsible for launching the REPL prompt, if requested.
runSystemScript()
runs the user's system script, and runUserScript()
runs the project script found by locateUserScript()
.
processCommandLine()
handles any command line options and sets the target action and arguments. This needs to happen after the project script has run, in case it defines new options or modifies the behavior of existing options—a common point of confusion.
bake()
takes all of the project and configuration information that has been specified in the user's project script and prepares it for use by the target action, a somewhat convoluted process that is implemented in src/base/oven.lua
.
validate()
examines the processed configuration information and tries to make sure it all makes sense, and that all required data is available. The main validation logic is located in src/base/validation.lua
.
callAction()
passes each workspace, project, rule, and other container to the target action, causing the appropriate result--like generating a Visual Studio project or GNU makefile--to occur. This container iteration is done in action.call()
in src/base/action.lua
.
Calling the action, via callAction()
, is where the interesting part for most people begins. Control now transfers to one of exporters, causing the project files to be written. For more information on how that happens, see Creating a New Action.