Ninja ===== Evan Martin Introduction ------------ Ninja is yet another build system. It takes as input the interdependencies of files (typically source code and output executables) and orchestrates building them, _quickly_. Ninja joins a sea of other build systems. Its distinguishing goal is to be fast. It is born from my work on the Chromium browser project, which has over 30,000 source files and whose other build systems (including one built from custom non-recursive Makefiles) can take ten seconds to start building after changing one file. Ninja is under a second. Philosophical overview ~~~~~~~~~~~~~~~~~~~~~~ Build systems get slow when they need to make decisions. When you are in a edit-compile cycle you want it to be as fast as possible -- you want the build system to do the minimum work necessary to figure out what needs to be built immediately. Ninja contains the barest functionality necessary to describe arbitrary dependency graphs. Its lack of syntax makes it impossible to express complex decisions. Instead, Ninja is intended to be used with a separate program generating its input files. The generator program (like the `./configure` found in autotools projects) can analyze system dependencies and make as many decisions as possible up front so that incremental builds stay fast. Going beyond autotools, even build-time decisions like "which compiler flags should I use?" or "should I build a debug or release-mode binary?" belong in the `.ninja` file generator. Conceptual overview ~~~~~~~~~~~~~~~~~~~ Ninja evaluates a graph of dependencies between files, and runs whichever commands are necessary to make your build target up to date. If you are familiar with Make, Ninja is very similar. A build file (default name: `build.ninja`) provides a list of _rules_ -- short names for longer commands, like how to run the compiler -- along with a list of _build_ statements saying how to build files using the rules -- which rule to apply to which inputs to produce which outputs. Conceptually, `build` statements describe the dependency graph of your project, while `rule` statements describe how to generate the files along a given edge of the graph. Design goals ~~~~~~~~~~~~ Here are some of the design goals of Ninja: * very fast (i.e., instant) incremental builds, even for very large projects. * very little policy about how code is built; "explicit is better than implicit". * get dependencies correct, and in particular situations that are difficult to get right with Makefiles (e.g. outputs need an implicit dependency on the command line used to generate them; to build C source code you need to use gcc's `-M` flags for header dependencies). * when convenience and speed are in conflict, prefer speed. Some explicit _non-goals_: * convenient syntax for writing build files by hand. _You should generate your ninja files using another program_. This is how we can sidestep many policy decisions. * built-in rules. _Out of the box, Ninja has no rules for e.g. compiling C code._ * build-time customization of the build. _Options belong in the program that generates the ninja files_. * build-time decision-making ability such as conditionals or search paths. _Making decisions is slow._ To restate, Ninja is faster than other build systems because it is painfully simple. You must tell Ninja exactly what to do when you create your project's `.ninja` files. Comparison to GNU make ~~~~~~~~~~~~~~~~~~~~~~ Ninja is closest in spirit and functionality to make. But fundamentally, make has a lot of _features_: suffix rules, functions, built-in rules that e.g. search for RCS files when building source. Many projects find make alone adequate for their build problems. In contrast, Ninja has almost no features; just those necessary to get builds correct while punting most complexity to generation of the ninja input files. Ninja by itself is unlikely to be useful for most projects. Here are some of the features ninja adds to make. (These sorts of features can often be implemented using more complicated Makefiles, but they are not part of make itself.) * A Ninja rule may point at a path for extra implicit dependency information. This makes it easy to get header dependencies correct for C/C++ code. * A build edge may have multiple outputs. * Outputs implicitly depend on the command line that was used to generate them, which means that changing e.g. compilation flags will cause the outputs to rebuild. * Output directories are always implicitly created before running the command that relies on them. * Rules can provide shorter descriptions of the command being run, so you can print e.g. `CC foo.o` instead of a long command line while building. * Command output is always buffered. This means commands running in parallel don't interleave their output, and when a command fails we can print its failure output next to the full command line that produced the failure. Getting started --------------- Start by downloading the code from https://github.com/martine/ninja[the github repo]. The included `bootstrap.sh` should hopefully produce a working `ninja` binary, by first blindly compiling all non-test files together then re-building Ninja using itself. Usage is currently just ---------------- ninja target ---------------- where `target` is a known output described by `build.ninja` in the current directory. There is no installation step; the only files of interest to a user are the resulting binary and this manual. Creating .ninja files --------------------- Here's a basic `.ninja` file that demonstrates most of the syntax. It will be used as an example for the following sections. --------------------------------- cflags = -Wall rule cc command = gcc $cflags -c $in -o $out build foo.o: cc foo.c --------------------------------- Variables ~~~~~~~~~ Despite the non-goal of being convenient to write by hand, to keep build files readable (debuggable), Ninja supports declaring shorter reusable names for strings. A declaration like the following ---------------- cflags = -g ---------------- can be used on the right side of an equals sign, dereferencing it with a dollar sign, like this: ---------------- rule cc command = gcc $cflags -c $in -o $out ---------------- Variables can also be referenced using curly braces like `${in}`. Variables might better be called "bindings", in that a given variable cannot be changed, only shadowed. There is more on how shadowing works later in this document. Rules ~~~~~ Rules declare a short name for a command line. They begin with a line consisting of the `rule` keyword and a name for the rule. Then follows an indented set of `variable = value` lines. The basic example above declares a new rule named `cc`, along with the command to run. (In the context of a rule, the `command` variable is special and defines the command to run. A full list of special variables is provided in <>.) Within the context of a rule, two additional special variables are available: `$in` expands to the list of input files (`foo.c`) and `$out` to the output file (`foo.o`) for the command. Build statements ~~~~~~~~~~~~~~~~ Build statements declare a relationship between input and output files. They begin with the `build` keyword, and have the format +build _outputs_: _rulename_ _inputs_+. Such a declaration says that all of the output files are derived from the input files. When the output files are missing or when the inputs change, Ninja will run the rule to regenerate the outputs. The basic example above describes how to build `foo.o`, using the `cc` rule. In the scope of a `build` block (including in the evaluation of its associated `rule`), the variable `$in` is the list of inputs and the variable `$out` is the list of outputs. A build statement may be followed by an indented set of `key = value` pairs, much like a rule. These variables will shadow any variables when evaluating the variables in the command. For example: ---------------- cflags = -Wall -Werror rule cc command = gcc $cflags -c $in -o $out # If left unspecified, builds get the outer $cflags. build foo.o: cc foo.c # But you can can shadow variables like cflags for a particular build. build special.o: cc special.c cflags = -Wall # The variable was only shadowed for the scope of special.o; # Subsequent build lines get the outer (original) cflags. build bar.o: cc bar.c ---------------- For more discussion of how scoping works, consult <>. If you need more complicated information passed from the build statement to the rule (for example, if the rule needs "the file extension of the first input"), pass that through as an extra variable, like how `cflags` is passed above. If the top-level Ninja file is specified as an output of any build statement and it is out of date, Ninja will rebuild and reload it before building the targets requested by the user. The `phony` rule ~~~~~~~~~~~~~~~~ The special rule name `phony` can be used to create aliases for other targets. For example: ---------------- build foo: phony some/file/in/a/faraway/subdir/foo ---------------- This makes `ninja foo` build the longer path. Semantically, the `phony` rule is equivalent to a plain rule where the `command` does nothing, but phony rules are handled specially in that they aren't printed when run, logged (see below), nor do they contribute to the command count printed as part of the build process. `phony' can also be used to create dummy targets for files which may not exist at build time. If a phony build statement is written without any dependencies, the target will be considered out of date if it does not exist. Without a phony build statement, Ninja will report an error if the file does not exist and is required by the build. Default target statements ~~~~~~~~~~~~~~~~~~~~~~~~~ By default, if no targets are specified on the command line, Ninja will build every output that is not named as an input elsewhere. You can override this behavior using a default target statement. A default target statement causes Ninja to build only a given subset of output files if none are specified on the command line. Default target statements begin with the `default` keyword, and have the format +default _targets_+. A default target statement must appear after the build statement that declares the target as an output file. They are cumulative, so multiple statements may be used to extend the list of default targets. For example: ---------------- default foo bar default baz ---------------- This causes Ninja to build the `foo`, `bar` and `baz` targets by default. The Ninja log ~~~~~~~~~~~~~ For each built file, Ninja keeps a log of the command used to build it. Using this log Ninja can know when an existing output was built with a different command line than the build files specify (i.e., the command line changed) and knows to rebuild the file. The log file is kept in the build root in a file called `.ninja_log`. If you provide a variable named `builddir` in the outermost scope, `.ninja_log` will be kept in that directory instead. Generating Ninja files ---------------------- The Ninja distribution includes a tiny (<100 line) Python module to facilitate generating Ninja files. It allows you to make Python calls like `ninja.rule(name='foo', command='bar', depfile='$out.d')` and it will generate the appropriate syntax. Integration with other build systems ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ *gyp*. http://gyp.googlecode.com[gyp, the system used to generate build files for the Chromium browser] can generate ninja files for Linux. See http://code.google.com/p/chromium/wiki/NinjaBuild[the Chromium Ninja documentation] for details. *CMake*. Various people have worked on generating Ninja files from CMake. Currently, it sounds like https://github.com/pcc/CMake/tree/ninja-generator[pcc's branch] is the one to try. *Autotools*. In theory, you could coax Automake into producing .ninja files as well, but I haven't tried it. It may very well be the case that most projects use too much Makefile syntax in their `.am` files for this to work. Extra tools ----------- The `-t` flag on the Ninja command line runs some tools that I have found useful during Ninja's development. The current tools are: `query`:: dump the inputs and outputs of a given target. `browse`:: browse the dependency graph in a web browser. Clicking a file focuses the view on that file, showing inputs and outputs. This feature requires a Python installation. `graph`:: output a file in the syntax used by `graphviz`, a automatic graph layout tool. Use it like: +ninja -t graph _target_ | dot -Tpng -ograph.png /dev/stdin+ . In the Ninja source tree, `ninja graph` generates an image for Ninja itself. If no target is given generate a graph for all root targets. `targets`:: output a list of targets either by rule or by depth. If used like this +ninja -t targets rule _name_+ it prints the list of targets using the given rule to be built. If no rule is given, it prints the source files (the leaves of the graph). If used like this +ninja -t targets depth _digit_+ it prints the list of targets in a depth-first manner starting by the root targets (the ones with no outputs). Indentation is used to mark dependencies. If the depth is zero it prints all targets. If no arguments are provided +ninja -t targets depth 1+ is assumed. In this mode targets may be listed several times. If used like this +ninja -t targets all+ it prints all the targets available without indentation and it is way faster than the _depth_ mode. It returns non-zero if an error occurs. `rules`:: output the list of all rules with their description if they have one. It can be used to know which rule name to pass to +ninja -t targets rule _name_+. `clean`:: remove built files. If used like this +ninja -t clean+ it removes all the built files, except for those created by the generator. If used like this +ninja -t clean -g+ it also removes built files created by the generator. If used like this +ninja -t clean _targets..._+ it removes the given targets and recursively all files built for it. If used like this +ninja -t clean -r _rules_+ it removes all files built using the given rules. The depfiles are not removed. Files created but not referenced in the graph are not removed. This tool takes in account the +-v+ and the +-n+ options (note that +-n+ implies +-v+). It returns non-zero if an error occurs. Ninja file reference -------------------- A file is a series of declarations. A declaration can be one of: 1. A rule declaration, which begins with +rule _rulename_+, and then has a series of indented lines defining variables. 2. A build edge, which looks like +build _output1_ _output2_: _rulename_ _input1_ _input2_+. + Implicit dependencies may be tacked on the end with +| _dependency1_ _dependency2_+. + Order-only dependencies may be tacked on the end with +|| _dependency1_ _dependency2_+. (See <>.) 3. Variable declarations, which look like +_variable_ = _value_+. 4. Default target statements, which look like +default _target1_ _target2_+. 5. References to more files, which look like +subninja _path_+ or +include _path_+. The difference between these is explained below <>. Comments begin with `#` and extend to the end of the line. Newlines are significant, but they can be escaped by putting a `$` before them. To produce a literal `$` in a path or variable value use `$$`. Other whitespace is only significant if it's at the beginning of a line. If a line is intended more than the previous one, it's considered part of its parent's scope; if it is indented less than the previous one, it closes the previous scope. Rule variables ~~~~~~~~~~~~~~ [[ref_rule]] A `rule` block contains a list of `key = value` declarations that affect the processing of the rule. Here is a full list of special keys. `command` (_required_):: the command line to run. This string (after $variables are expanded) is passed directly to `sh -c` without interpretation by Ninja. `depfile`:: path to an optional `Makefile` that contains extra _implicit dependencies_ (see <>). This is explicitly to support `gcc` and its `-M` family of flags, which output the list of headers a given `.c` file depends on. + Use it like in the following example: + ---- rule cc depfile = $out.d command = gcc -MMD -MF $out.d [other gcc flags here] ---- + When loading a `depfile`, Ninja implicitly adds edges such that it is not an error if the listed dependency is missing. This allows you to delete a depfile-discovered header file and rebuild, without the build aborting due to a missing input. `description`:: a short description of the command, used to pretty-print the command as it's running. The `-v` flag controls whether to print the full command or its description; if a command fails, the full command line will always be printed before the command's output. `generator`:: if present, specifies that this rule is used to re-invoke the generator program. Files built using `generator` rules are treated specially in two ways: firstly, they will not be rebuilt if the command line changes; and secondly, they are not cleaned by default. Additionally, the special `$in` and `$out` variables expand to the space-separated list of files provided to the `build` line referencing this `rule`. Build dependencies ~~~~~~~~~~~~~~~~~~ [[ref_dependencies]] There are three types of build dependencies which are subtly different. 1. _Explicit dependencies_, as listed in a build line. These are available as the `$in` variable in the rule. Changes in these files cause the output to be rebuilt; if these file are missing and Ninja doesn't know how to build them, the build is aborted. + This is the standard form of dependency to be used for e.g. the source file of a compile command. 2. _Implicit dependencies_, either as picked up from a `depfile` attribute on a rule or from the syntax +| _dep1_ _dep2_+ on the end of a build line. The semantics are identical to explicit dependencies, the only difference is that implicit dependencies don't show up in the `$in` variable. + This is for expressing dependencies that don't show up on the command line of the command; for example, for a rule that runs a script, the script itself should be an implicit dependency, as changes to the script should cause the output to rebuild. + Note that dependencies as loaded through depfiles have slightly different semantics, as described in the <>. 3. _Order-only dependencies_, expressed with the syntax +|| _dep1_ _dep2_+ on the end of a build line. When these are missing, the output is not rebuilt until they are built, but once they are available further changes to the files do not affect the output. + Order-only dependencies can be useful for bootstrapping dependencies that are only discovered during build time: for example, to generate a header file before starting a subsequent compilation step. (Once the header is used in compilation, a generated dependency file will then express the implicit dependency.) Evaluation and scoping ~~~~~~~~~~~~~~~~~~~~~~ [[ref_scope]] Top-level variable declarations are scoped to the file they occur in. The `subninja` keyword, used to include another `.ninja` file, introduces a new scope. The included `subninja` file may use the variables from the parent file, and shadow their values for the file's scope, but it won't affect values of the variables in the parent. To include another `.ninja` file in the current scope, much like a C `#include` statement, use `include` instead of `subninja`. Variable declarations indented in a `build` block are scoped to the `build` block. This scope is inherited by the `rule`. The full lookup order for a variable referenced in a rule is: 1. Rule-level variables (i.e. `$in`, `$command`). 2. Build-level variables from the `build` that references this rule. 3. File-level variables from the file that the `build` line was in. 4. Variables from the file that included that file using the `subninja` keyword. Variable expansion ~~~~~~~~~~~~~~~~~~ Variables are expanded in three cases: in the right side of a `name = value` statement, in paths in a `build` statement and in paths in a `default` statement. When a `name = value` statement is evaluated, its right-hand side is expanded once (according to the above scoping rules) immediately, and from then on `$name` expands to the static string as the result of the expansion. It is never the case that you'll need to "double-escape" a variable with some syntax like `$$foo`. A `build` or `default` statement is first parsed as a space-separated list of filenames and then each name is expanded. This means that spaces within a variable will result in spaces in the expanded filename. ---- spaced = foo bar build $spaced/baz other: ... # The above build line has two outputs: "foo bar/baz" and "other". ---- In a `name = value` statement, whitespace at the beginning of a value is always stripped. Whitespace at the beginning of a line after a line continuation is also stripped. ---- two_words_with_one_space = foo $ bar one_word_with_no_space = foo$ bar ---- Future work ----------- Some pieces I'd like to add: _inotify_. I had originally intended to make Ninja be memory-resident and to use `inotify` to keep the build state hot at all times. But upon writing the code I found it was fast enough to run from scratch each time. Perhaps a slower computer would still benefit from inotify; the data structures are set up such that using inotify shouldn't be hard. _build estimation and analysis_. As part of build correctness, Ninja keeps a log of the time spent on each build statement. This log format could be adjusted to instead store timing information across multiple runs. From that, the total time necessary to build could be estimated, allowing Ninja to print status like "3 minutes until complete" when building. Additionally, a tool could output which commands are the slowest or which directories take the most time to build. _many others_. See the `todo` file included in the distribution.