Tool for building software and configuring builds.

Best way to get vMake is with LuaRocks: luarocks install vmake
Alternatively, clone this repo (preferably, a tagged version) and place/symlink vmake.lua into a $LUA_PATH directory (depends on your environment; the working directory is generally amongst them).

To use vMake, you need to write a "vMakefile". Only one I'm aware of is Beelzebub's.
It uses every feature of vMake.

Your vMakefile should always begin with...

#!/usr/bin/env lua
require "vmake"

... after which, you should declare all your projects, configurations, architectures, and command-line options.
As the code is not preprocessed/parsed in any way, feel free to include full proper Lua code to do whatever computation is required for the declared objects.

After everything is set up, simply call vmake() to act.

vMake works through a set of declared objects, which tell it which projects are available, what components a project (or another component) has, rules which create files, available configurations and architectures, and command-line options.

These two have identical roles and abilities but different semantics.
They represent major decisions in the build process, and, once defined, are available for every project.

If no configuration or architecture is provided, default ones (called "default-conf" or "default-arch") will be provided.

A default configuration and architecture can be specified with the Default function as such:

Default "amd64" "debug"

(note for those who are inexperienced with Lua: this is equivalent to Default("amd64")("debug") but it looks more declarative that way.)

These can be declared simply like...

Configuration "release"

... or with more information, such as...

Architecture "amd64" {
    Data = {
        Opts_GCC = List { "-m64" },

        Opts_NASM = List { "-f", "elf64" },
    },

    Base = "x86",
}

As seen in the example above, they support inheritance, of sorts. Every confiuration can have a base configuration (used for data resolution), and every architecture can have a base architecture (same reason).

The architecture and configuration of the current build are available in the selArch and selConf fields of the local environment argument of every function.

The difference in semantics between configurations and architectures are as follows:

• A configuration represents the behaviour of the build. By far the most common examples are debug and release, where the former normally includes debug symbols and forbids optimization, while the latter excludes symbols and enables optimization.
• An architecture represents the platform/environment in which a build is used. Examples include win64, android-armv7, linux-i346.

Architectures, configurations and projects cannot share names.

Projects represent top-level components which can be selected for building.
These can contain components and everything that a component can contain.

At least one project must be defined for vMake to be able to do anything. An error will be shown if none is provided.

A default project can be specified with the Default function, just like architectures and configurations:

Default "Beelzebub"

Project names must be unique, and cannot be shared with architectures and configurations.

A component (and, transitively, top-level projects) represent a piece (maybe whole) of a project.
They are defined by the following main properties:

• Output: one or more files which are produced by this component;
• Dependencies (optional): One or more top-level projects or sibling components which must be fully build prior to starting building this one;
• Directory (optional): A directory represented by this component;
• Description (optional): A textual description of this component.

Besides these properties, a component may contain other components and rules.

Building a component generally means that every file listed in its output is produced when it is done.

Components cannot have the name of a project, architecture or configuration, nor that of a sibling component.

Rules provide the means to construct files.

They do this through three functions/properties:

• Filter: Can be either of the following types...
  • string or Path: Matches the specific path exactly;
  • List of strings and Paths: Matches any path in the list;
  • function: Is given a destination path as argument and returns a boolean for a definitive answer, or a Path or List for further lookup.
• Source: Can be either of the following types...
  • string or Path: The destination file requires this specific source file;
  • List of strings and Paths: The destination file requires these specific source files;
  • function: Is given a destination path as argument and returns a Path or List of strings and Paths representing the source(s) for the destination path.
• Action: A function which is given the destination Path and List of sources (even if just one), and should perform the steps necessary to obtain the destination path;
• Shared: Whether the rule can be used by child components of the container or not.

There should be rules available for every file that doesn't exist.

Rules cannot have the names of a project, configuration or architecture.

All the objects above form hierarchies, and can contain arbitrary data in a property named Data.

The parent of a rule or component is the containing component (or project). Projects have no parent.
The parent of an architecture or configuration is the one named as its Base.

When data keys are resolved in a function (through its local environment), it starts at the containing object and works its way up the hierarchy. Resolution stops when the key is found in the Data of an object.

Data keys can only be strings, and values which are functions are called only once with a local environment to provide the actual data. This resolution happens on-demand, the first time a data key is retrieved.

Data containers cannot be modified.

Besides the type, there is no restriction on the value of keys.

Command-line options can be declared for build configuration (or other purposes).
One must have a long name (at least two characters), and an optional short name (precisely one character).

To be documented later. For examples, refer to Beelzebub's vMakefile linked above.

A vMakefile can declare an output directory, which is used by vMake to create temporary files (if/when needed) and should be used by components to locate their output as well.

This is provided through the OutputDirectory function as such:

OutputDirectory "./.vmake"
--  or
OutputDirectory(function()
    return "./.vmake/" .. (selArch.NormalizedName .. "." .. selConf.NormalizedName)
end)

The latter example is actually the default value, resulting in a path like ./.vmake/arch.conf/.

Objects declared in vMakefiles make use of functions for providing non-constant values to data items and the majority of properties.

All these functions run with restricted local environment tables.

This table contains the following keys:

• outDir: Output directory of the vMakefile, of type Path;
• selProj: Top-level project selected to be built;
• selArch: Architecture selected for the build;
• selConf: Configuration selected for the build;
• data: Data container of the current object;
• rule: Current rule, if within one;
• comp: Current component (top-level projects included), or component which contains the current rule, if within any;
• proj: Current top-level project, or the top-level project which contains the current component or rule, if within any;
• arch: Current architecture, if within one;
• conf: Current configuration, if within one;
• opt: Current command-line option, if within one.

The following functions are allowed in restricted environments:

• DoNothing: Does exactly nothing;
• List: Instances a list from a table or from a string;
• CartesianProduct: Returns the cartesian product of the given lists;
• NewList: Creates an empty list;
• Path: Instances a path from a string;
• FilePath: Instances a file path from a string;
• DirPath: Instances a directory path from a string;
• L: Creates a lambda (function) from a string;
• GetConfiguration: Retrieves a declared configuration by name;
• GetArchitecture: Retrieves a declared architecture by name;
• TransferArgument: Transfers a command-line argument to sub-invocations of the vMakefile when called with multiple target tuples;
• MSG: Prints a debug message, all arguments are concatenated and newline is added at the end;
• assertType: Asserts the type of a given value;
• type is mostly the same as standard Lua, except it's extended to discriminate vMake objects (Project, CmdOpt, etc.);
• tonumber, tostring, and error are taken from the standard Lua environment.

When any other key is requested from the local environment table, it attempts data resolution (in its data key) if possible.
Failure to retrieve a key results in an error, not a nil value as typical.

Attempts to modify this table also result in an error.

A build targets a specific (top-level) project, architecture and configuration.
vMake can try to build multiple projects, architecture, and configuration combinations.

vMake's goal is to construct the files listed in the output of the selected project(s). To do this, it employs the work item resolution algorithm.

When vMake tries to figure out how to construct a file, it employs a simple resolution algorithm.

First, it looks through all the rules of the current component to find one whose filter matches the path.
If more than one rule matches, it's considered an error.

If a rule wasn't found, it looks through the output list of all child components for a matching path.
If more than one component lists the path as an output, it's also considered an error.

If no rule or child component output was found to match the path, it restarts the algorithm from the parent component/project, if any, but will only accept shared rules.

If a rule is found, a work item is created.
This work item becomes a dependency of whatever requested this file.

If a work item is created (from a rule), the sources of this file are retrieved according to the rule and this algorithm is applied to each of them as well.

If a source of an item cannot be found, and it does not exist in the filesystem, it is clearly an error.

The build process occurs by calling the Actions of every rule involved, for all the work items created.
These functions can only use a subset of the vMake API which can be translated into shell commands.

A work item will only be executed after all its dependencies have successfully executed.

Having an overview of the whole project, vMake is capable of building only the pieces which are missing or out-of-date.
This is the default behaviour.

The opposite of this is a full build, which will execute every single work item to reconstruct every file possible.
To force a full build, pass the --full command-line argument to the vMakefile.

vMake is capable of using either Make (preferred) or GNU Parallel, which are optional depdendencies, to perform builds in parallel.

To use parallelism, pass the --jobs=#/-j # command-line argument to the vMakefile, where # is the desired number of jobs that can run in parallel. 0 means unlimited, and 1 means usual serial execution.
To get the best performance out of parallel builds, it is recommended to provide the number of hardware threads to this argument. 0 usually yields equally good results, though.

vMake is capable of generating fully-featured makefiles, even when targetting multiple projects, architectures, or configurations.
It will use Make's ability to run parallel builds as well.

This is especially powerful when trying to build multiple targets, as they have no dependencies between each-other.

vMake even identifies order-only dependencies (e.g. directories) and uses them accordingly to improve performance and correctness.

Firstly, the directed dependency graph represented by all the work items (some of which are grouped into work loads) is levelled. Items which have no dependencies, or all dependencies are up-to-date, are on level 0, and all the others are one level higher than their highest dependency.
This means every work item can be executed as soon as possible and no later.

The work items are executed and all the vMake functions they call are actually turned into shell commands which are logged.
When all the items finished execution, vMake knows every single command (or sequence of) that needs to be invoked to perform the build, and precisely when it can be executed.

These commands are written into files, separated by level, and then parallel is invoked with them.

vMake is normally perfectly capable of reporting errors even when its actions are invoked indirectly by Make, or GNU Parallel by reading its log files and correlating them with its record of commands and work items.

It will report precisely which commands failed (together with rule and destination path), with status code.
Note: It will report any number of failed commands, not just one.

Parallel builds will be faster than serial builds, with the possible exception of some extreme edge cases.
It's hardly slower than GNU Make in parallel speed on a more modern system. It has to figure out the dependency graph and simulate every rule action.

In practice, this overhead is nearly constant relative to the size of the project.
Having in mind that vMake also offers build configuration (through command-line options), this overhead is orders of magnitude better than running ./configure or similar tools before building.

Both partial and full builds can be parallelized, and the computation of work item levels takes this choice into account as well.

The CmdOpt class (command-line options) coupled with the data resolution algorithm allows the build system to be fully configurable and highly flexible.

The parsing of command-line arguments is done by vMake and the vMakefile only needs to handle the value(s) given to it.
There are optional features which are nice to have as well, such as autocompletion.

vMake provides a --help option that displays information about all the available command-line options, as well as --_completion (hidden option) for autocompleting any argument.

The --help command provides usage instruction and documents all the available (non-hidden) command-line options, top-level projects, architectures, and configurations.

vMake provides the ability to obtain autocomplete entries for a given command stub, by passing the command (up to the cursor) to the --_completion option.
When values are to be autocompleted (instead of option/project/architecture/configuration names), the job is delegated to the correct command-line option.