// Copyright 2016 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Definition of steps of the build system. //! //! This is where some of the real meat of rustbuild is located, in how we //! define targets and the dependencies amongst them. This file can sort of be //! viewed as just defining targets in a makefile which shell out to predefined //! functions elsewhere about how to execute the target. //! //! The primary function here you're likely interested in is the `build_rules` //! function. This will create a `Rules` structure which basically just lists //! everything that rustbuild can do. Each rule has a human-readable name, a //! path associated with it, some dependencies, and then a closure of how to //! actually perform the rule. //! //! All steps below are defined in self-contained units, so adding a new target //! to the build system should just involve adding the meta information here //! along with the actual implementation elsewhere. You can find more comments //! about how to define rules themselves below. use std::collections::{HashMap, HashSet}; use std::mem; use check::{self, TestKind}; use compile; use dist; use doc; use flags::Subcommand; use install; use native; use {Compiler, Build, Mode}; pub fn run(build: &Build) { let rules = build_rules(build); let steps = rules.plan(); rules.run(&steps); } pub fn build_rules(build: &Build) -> Rules { let mut rules = Rules::new(build); // This is the first rule that we're going to define for rustbuild, which is // used to compile LLVM itself. All rules are added through the `rules` // structure created above and are configured through a builder-style // interface. // // First up we see the `build` method. This represents a rule that's part of // the top-level `build` subcommand. For example `./x.py build` is what this // is associating with. Note that this is normally only relevant if you flag // a rule as `default`, which we'll talk about later. // // Next up we'll see two arguments to this method: // // * `llvm` - this is the "human readable" name of this target. This name is // not accessed anywhere outside this file itself (e.g. not in // the CLI nor elsewhere in rustbuild). The purpose of this is to // easily define dependencies between rules. That is, other rules // will depend on this with the name "llvm". // * `src/llvm` - this is the relevant path to the rule that we're working // with. This path is the engine behind how commands like // `./x.py build src/llvm` work. This should typically point // to the relevant component, but if there's not really a // path to be assigned here you can pass something like // `path/to/nowhere` to ignore it. // // After we create the rule with the `build` method we can then configure // various aspects of it. For example this LLVM rule uses `.host(true)` to // flag that it's a rule only for host targets. In other words, LLVM isn't // compiled for targets configured through `--target` (e.g. those we're just // building a standard library for). // // Next up the `dep` method will add a dependency to this rule. The closure // is yielded the step that represents executing the `llvm` rule itself // (containing information like stage, host, target, ...) and then it must // return a target that the step depends on. Here LLVM is actually // interesting where a cross-compiled LLVM depends on the host LLVM, but // otherwise it has no dependencies. // // To handle this we do a bit of dynamic dispatch to see what the dependency // is. If we're building a LLVM for the build triple, then we don't actually // have any dependencies! To do that we return a dependency on the "dummy" // target which does nothing. // // If we're build a cross-compiled LLVM, however, we need to assemble the // libraries from the previous compiler. This step has the same name as // ours (llvm) but we want it for a different target, so we use the // builder-style methods on `Step` to configure this target to the build // triple. // // Finally, to finish off this rule, we define how to actually execute it. // That logic is all defined in the `native` module so we just delegate to // the relevant function there. The argument to the closure passed to `run` // is a `Step` (defined below) which encapsulates information like the // stage, target, host, etc. rules.build("llvm", "src/llvm") .host(true) .dep(move |s| { if s.target == build.config.build { dummy(s, build) } else { s.target(&build.config.build) } }) .run(move |s| native::llvm(build, s.target)); // Ok! After that example rule that's hopefully enough to explain what's // going on here. You can check out the API docs below and also see a bunch // more examples of rules directly below as well. // dummy rule to do nothing, useful when a dep maps to no deps rules.build("dummy", "path/to/nowhere"); // the compiler with no target libraries ready to go rules.build("rustc", "src/rustc") .dep(move |s| { if s.stage == 0 { dummy(s, build) } else { s.name("librustc") .host(&build.config.build) .stage(s.stage - 1) } }) .run(move |s| compile::assemble_rustc(build, s.stage, s.target)); // Helper for loading an entire DAG of crates, rooted at `name` let krates = |name: &str| { let mut ret = Vec::new(); let mut list = vec![name]; let mut visited = HashSet::new(); while let Some(krate) = list.pop() { let default = krate == name; let krate = &build.crates[krate]; let path = krate.path.strip_prefix(&build.src).unwrap(); ret.push((krate, path.to_str().unwrap(), default)); for dep in krate.deps.iter() { if visited.insert(dep) && dep != "build_helper" { list.push(dep); } } } return ret }; // ======================================================================== // Crate compilations // // Tools used during the build system but not shipped rules.build("libstd", "src/libstd") .dep(|s| s.name("build-crate-std_shim")); rules.build("libtest", "src/libtest") .dep(|s| s.name("build-crate-test_shim")); rules.build("librustc", "src/librustc") .dep(|s| s.name("build-crate-rustc-main")); for (krate, path, _default) in krates("std_shim") { rules.build(&krate.build_step, path) .dep(move |s| s.name("rustc").host(&build.config.build).target(s.host)) .dep(move |s| { if s.host == build.config.build { dummy(s, build) } else { s.host(&build.config.build) } }) .run(move |s| { if s.host == build.config.build { compile::std(build, s.target, &s.compiler()) } else { compile::std_link(build, s.target, s.stage, s.host) } }); } for (krate, path, default) in krates("test_shim") { rules.build(&krate.build_step, path) .dep(|s| s.name("libstd")) .dep(move |s| { if s.host == build.config.build { dummy(s, build) } else { s.host(&build.config.build) } }) .default(default) .run(move |s| { if s.host == build.config.build { compile::test(build, s.target, &s.compiler()) } else { compile::test_link(build, s.target, s.stage, s.host) } }); } for (krate, path, default) in krates("rustc-main") { rules.build(&krate.build_step, path) .dep(|s| s.name("libtest")) .dep(move |s| s.name("llvm").host(&build.config.build).stage(0)) .dep(move |s| { if s.host == build.config.build { dummy(s, build) } else { s.host(&build.config.build) } }) .host(true) .default(default) .run(move |s| { if s.host == build.config.build { compile::rustc(build, s.target, &s.compiler()) } else { compile::rustc_link(build, s.target, s.stage, s.host) } }); } // ======================================================================== // Test targets // // Various unit tests and tests suites we can run { let mut suite = |name, path, dir, mode| { rules.test(name, path) .dep(|s| s.name("libtest")) .dep(|s| s.name("tool-compiletest").target(s.host)) .dep(|s| s.name("test-helpers")) .dep(move |s| { if s.target.contains("android") { s.name("android-copy-libs") } else { dummy(s, build) } }) .default(true) .run(move |s| { check::compiletest(build, &s.compiler(), s.target, dir, mode) }); }; suite("check-rpass", "src/test/run-pass", "run-pass", "run-pass"); suite("check-cfail", "src/test/compile-fail", "compile-fail", "compile-fail"); suite("check-pfail", "src/test/parse-fail", "parse-fail", "parse-fail"); suite("check-rfail", "src/test/run-fail", "run-fail", "run-fail"); suite("check-rpass-valgrind", "src/test/run-pass-valgrind", "run-pass-valgrind", "run-pass-valgrind"); suite("check-mir-opt", "src/test/mir-opt", "mir-opt", "mir-opt"); if build.config.codegen_tests { suite("check-codegen", "src/test/codegen", "codegen", "codegen"); } suite("check-codegen-units", "src/test/codegen-units", "codegen-units", "codegen-units"); suite("check-incremental", "src/test/incremental", "incremental", "incremental"); suite("check-ui", "src/test/ui", "ui", "ui"); suite("check-pretty", "src/test/pretty", "pretty", "pretty"); suite("check-pretty-rpass", "src/test/run-pass/pretty", "pretty", "run-pass"); suite("check-pretty-rfail", "src/test/run-pass/pretty", "pretty", "run-fail"); suite("check-pretty-valgrind", "src/test/run-pass-valgrind", "pretty", "run-pass-valgrind"); } if build.config.build.contains("msvc") { // nothing to do for debuginfo tests } else if build.config.build.contains("apple") { rules.test("check-debuginfo", "src/test/debuginfo") .dep(|s| s.name("libtest")) .dep(|s| s.name("tool-compiletest").host(s.host)) .dep(|s| s.name("test-helpers")) .dep(|s| s.name("debugger-scripts")) .run(move |s| check::compiletest(build, &s.compiler(), s.target, "debuginfo-lldb", "debuginfo")); } else { rules.test("check-debuginfo", "src/test/debuginfo") .dep(|s| s.name("libtest")) .dep(|s| s.name("tool-compiletest").host(s.host)) .dep(|s| s.name("test-helpers")) .dep(|s| s.name("debugger-scripts")) .run(move |s| check::compiletest(build, &s.compiler(), s.target, "debuginfo-gdb", "debuginfo")); } rules.test("debugger-scripts", "src/etc/lldb_batchmode.py") .run(move |s| dist::debugger_scripts(build, &build.sysroot(&s.compiler()), s.target)); { let mut suite = |name, path, dir, mode| { rules.test(name, path) .dep(|s| s.name("librustc")) .dep(|s| s.name("tool-compiletest").target(s.host)) .default(true) .host(true) .run(move |s| { check::compiletest(build, &s.compiler(), s.target, dir, mode) }); }; suite("check-rpass-full", "src/test/run-pass-fulldeps", "run-pass", "run-pass-fulldeps"); suite("check-cfail-full", "src/test/compile-fail-fulldeps", "compile-fail", "compile-fail-fulldeps"); suite("check-rmake", "src/test/run-make", "run-make", "run-make"); suite("check-rustdoc", "src/test/rustdoc", "rustdoc", "rustdoc"); suite("check-pretty-rpass-full", "src/test/run-pass-fulldeps", "pretty", "run-pass-fulldeps"); suite("check-pretty-rfail-full", "src/test/run-fail-fulldeps", "pretty", "run-fail-fulldeps"); } for (krate, path, _default) in krates("std_shim") { rules.test(&krate.test_step, path) .dep(|s| s.name("libtest")) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libstd, TestKind::Test, Some(&krate.name))); } rules.test("check-std-all", "path/to/nowhere") .dep(|s| s.name("libtest")) .default(true) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libstd, TestKind::Test, None)); // std benchmarks for (krate, path, _default) in krates("std_shim") { rules.bench(&krate.bench_step, path) .dep(|s| s.name("libtest")) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libstd, TestKind::Bench, Some(&krate.name))); } rules.bench("bench-std-all", "path/to/nowhere") .dep(|s| s.name("libtest")) .default(true) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libstd, TestKind::Bench, None)); for (krate, path, _default) in krates("test_shim") { rules.test(&krate.test_step, path) .dep(|s| s.name("libtest")) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libtest, TestKind::Test, Some(&krate.name))); } rules.test("check-test-all", "path/to/nowhere") .dep(|s| s.name("libtest")) .default(true) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Libtest, TestKind::Test, None)); for (krate, path, _default) in krates("rustc-main") { rules.test(&krate.test_step, path) .dep(|s| s.name("librustc")) .host(true) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Librustc, TestKind::Test, Some(&krate.name))); } rules.test("check-rustc-all", "path/to/nowhere") .dep(|s| s.name("librustc")) .default(true) .host(true) .run(move |s| check::krate(build, &s.compiler(), s.target, Mode::Librustc, TestKind::Test, None)); rules.test("check-linkchecker", "src/tools/linkchecker") .dep(|s| s.name("tool-linkchecker")) .dep(|s| s.name("default:doc")) .default(true) .host(true) .run(move |s| check::linkcheck(build, s.stage, s.target)); rules.test("check-cargotest", "src/tools/cargotest") .dep(|s| s.name("tool-cargotest")) .dep(|s| s.name("librustc")) .host(true) .run(move |s| check::cargotest(build, s.stage, s.target)); rules.test("check-tidy", "src/tools/tidy") .dep(|s| s.name("tool-tidy").stage(0)) .default(true) .host(true) .run(move |s| check::tidy(build, 0, s.target)); rules.test("check-error-index", "src/tools/error_index_generator") .dep(|s| s.name("libstd")) .dep(|s| s.name("tool-error-index").host(s.host)) .default(true) .host(true) .run(move |s| check::error_index(build, &s.compiler())); rules.test("check-docs", "src/doc") .dep(|s| s.name("libtest")) .default(true) .host(true) .run(move |s| check::docs(build, &s.compiler())); rules.test("check-distcheck", "distcheck") .dep(|s| s.name("dist-src")) .run(move |_| check::distcheck(build)); rules.build("test-helpers", "src/rt/rust_test_helpers.c") .run(move |s| native::test_helpers(build, s.target)); rules.test("android-copy-libs", "path/to/nowhere") .dep(|s| s.name("libtest")) .run(move |s| check::android_copy_libs(build, &s.compiler(), s.target)); // ======================================================================== // Build tools // // Tools used during the build system but not shipped rules.build("tool-rustbook", "src/tools/rustbook") .dep(|s| s.name("librustc")) .run(move |s| compile::tool(build, s.stage, s.target, "rustbook")); rules.build("tool-error-index", "src/tools/error_index_generator") .dep(|s| s.name("librustc")) .run(move |s| compile::tool(build, s.stage, s.target, "error_index_generator")); rules.build("tool-tidy", "src/tools/tidy") .dep(|s| s.name("libstd")) .run(move |s| compile::tool(build, s.stage, s.target, "tidy")); rules.build("tool-linkchecker", "src/tools/linkchecker") .dep(|s| s.name("libstd")) .run(move |s| compile::tool(build, s.stage, s.target, "linkchecker")); rules.build("tool-cargotest", "src/tools/cargotest") .dep(|s| s.name("libstd")) .run(move |s| compile::tool(build, s.stage, s.target, "cargotest")); rules.build("tool-compiletest", "src/tools/compiletest") .dep(|s| s.name("libtest")) .run(move |s| compile::tool(build, s.stage, s.target, "compiletest")); // ======================================================================== // Documentation targets rules.doc("doc-book", "src/doc/book") .dep(move |s| s.name("tool-rustbook").target(&build.config.build)) .default(build.config.docs) .run(move |s| doc::rustbook(build, s.stage, s.target, "book")); rules.doc("doc-nomicon", "src/doc/nomicon") .dep(move |s| s.name("tool-rustbook").target(&build.config.build)) .default(build.config.docs) .run(move |s| doc::rustbook(build, s.stage, s.target, "nomicon")); rules.doc("doc-standalone", "src/doc") .dep(move |s| s.name("rustc").host(&build.config.build).target(&build.config.build)) .default(build.config.docs) .run(move |s| doc::standalone(build, s.stage, s.target)); rules.doc("doc-error-index", "src/tools/error_index_generator") .dep(move |s| s.name("tool-error-index").target(&build.config.build)) .dep(move |s| s.name("librustc")) .default(build.config.docs) .host(true) .run(move |s| doc::error_index(build, s.stage, s.target)); for (krate, path, default) in krates("std_shim") { rules.doc(&krate.doc_step, path) .dep(|s| s.name("libstd")) .default(default && build.config.docs) .run(move |s| doc::std(build, s.stage, s.target)); } for (krate, path, default) in krates("test_shim") { rules.doc(&krate.doc_step, path) .dep(|s| s.name("libtest")) .default(default && build.config.docs) .run(move |s| doc::test(build, s.stage, s.target)); } for (krate, path, default) in krates("rustc-main") { rules.doc(&krate.doc_step, path) .dep(|s| s.name("librustc")) .host(true) .default(default && build.config.compiler_docs) .run(move |s| doc::rustc(build, s.stage, s.target)); } // ======================================================================== // Distribution targets rules.dist("dist-rustc", "src/librustc") .dep(move |s| s.name("rustc").host(&build.config.build)) .host(true) .default(true) .run(move |s| dist::rustc(build, s.stage, s.target)); rules.dist("dist-std", "src/libstd") .dep(move |s| { // We want to package up as many target libraries as possible // for the `rust-std` package, so if this is a host target we // depend on librustc and otherwise we just depend on libtest. if build.config.host.iter().any(|t| t == s.target) { s.name("librustc") } else { s.name("libtest") } }) .default(true) .run(move |s| dist::std(build, &s.compiler(), s.target)); rules.dist("dist-mingw", "path/to/nowhere") .run(move |s| dist::mingw(build, s.target)); rules.dist("dist-src", "src") .default(true) .host(true) .run(move |_| dist::rust_src(build)); rules.dist("dist-docs", "src/doc") .default(true) .dep(|s| s.name("default:doc")) .run(move |s| dist::docs(build, s.stage, s.target)); rules.dist("dist-analysis", "analysis") .dep(|s| s.name("dist-std")) .default(true) .run(move |s| dist::analysis(build, &s.compiler(), s.target)); rules.dist("install", "src") .dep(|s| s.name("default:dist")) .run(move |s| install::install(build, s.stage, s.target)); rules.verify(); return rules; fn dummy<'a>(s: &Step<'a>, build: &'a Build) -> Step<'a> { s.name("dummy").stage(0) .target(&build.config.build) .host(&build.config.build) } } #[derive(PartialEq, Eq, Hash, Clone, Debug)] struct Step<'a> { /// Human readable name of the rule this step is executing. Possible names /// are all defined above in `build_rules`. name: &'a str, /// The stage this step is executing in. This is typically 0, 1, or 2. stage: u32, /// This step will likely involve a compiler, and the target that compiler /// itself is built for is called the host, this variable. Typically this is /// the target of the build machine itself. host: &'a str, /// The target that this step represents generating. If you're building a /// standard library for a new suite of targets, for example, this'll be set /// to those targets. target: &'a str, } impl<'a> Step<'a> { /// Creates a new step which is the same as this, except has a new name. fn name(&self, name: &'a str) -> Step<'a> { Step { name: name, ..*self } } /// Creates a new step which is the same as this, except has a new stage. fn stage(&self, stage: u32) -> Step<'a> { Step { stage: stage, ..*self } } /// Creates a new step which is the same as this, except has a new host. fn host(&self, host: &'a str) -> Step<'a> { Step { host: host, ..*self } } /// Creates a new step which is the same as this, except has a new target. fn target(&self, target: &'a str) -> Step<'a> { Step { target: target, ..*self } } /// Returns the `Compiler` structure that this step corresponds to. fn compiler(&self) -> Compiler<'a> { Compiler::new(self.stage, self.host) } } struct Rule<'a> { /// The human readable name of this target, defined in `build_rules`. name: &'a str, /// The path associated with this target, used in the `./x.py` driver for /// easy and ergonomic specification of what to do. path: &'a str, /// The "kind" of top-level command that this rule is associated with, only /// relevant if this is a default rule. kind: Kind, /// List of dependencies this rule has. Each dependency is a function from a /// step that's being executed to another step that should be executed. deps: Vec) -> Step<'a> + 'a>>, /// How to actually execute this rule. Takes a step with contextual /// information and then executes it. run: Box) + 'a>, /// Whether or not this is a "default" rule. That basically means that if /// you run, for example, `./x.py test` whether it's included or not. default: bool, /// Whether or not this is a "host" rule, or in other words whether this is /// only intended for compiler hosts and not for targets that are being /// generated. host: bool, } #[derive(PartialEq)] enum Kind { Build, Test, Bench, Dist, Doc, } impl<'a> Rule<'a> { fn new(name: &'a str, path: &'a str, kind: Kind) -> Rule<'a> { Rule { name: name, deps: Vec::new(), run: Box::new(|_| ()), path: path, kind: kind, default: false, host: false, } } } /// Builder pattern returned from the various methods on `Rules` which will add /// the rule to the internal list on `Drop`. struct RuleBuilder<'a: 'b, 'b> { rules: &'b mut Rules<'a>, rule: Rule<'a>, } impl<'a, 'b> RuleBuilder<'a, 'b> { fn dep(&mut self, f: F) -> &mut Self where F: Fn(&Step<'a>) -> Step<'a> + 'a, { self.rule.deps.push(Box::new(f)); self } fn run(&mut self, f: F) -> &mut Self where F: Fn(&Step<'a>) + 'a, { self.rule.run = Box::new(f); self } fn default(&mut self, default: bool) -> &mut Self { self.rule.default = default; self } fn host(&mut self, host: bool) -> &mut Self { self.rule.host = host; self } } impl<'a, 'b> Drop for RuleBuilder<'a, 'b> { fn drop(&mut self) { let rule = mem::replace(&mut self.rule, Rule::new("", "", Kind::Build)); let prev = self.rules.rules.insert(rule.name, rule); if let Some(prev) = prev { panic!("duplicate rule named: {}", prev.name); } } } pub struct Rules<'a> { build: &'a Build, sbuild: Step<'a>, rules: HashMap<&'a str, Rule<'a>>, } impl<'a> Rules<'a> { fn new(build: &'a Build) -> Rules<'a> { Rules { build: build, sbuild: Step { stage: build.flags.stage.unwrap_or(2), target: &build.config.build, host: &build.config.build, name: "", }, rules: HashMap::new(), } } /// Creates a new rule of `Kind::Build` with the specified human readable /// name and path associated with it. /// /// The builder returned should be configured further with information such /// as how to actually run this rule. fn build<'b>(&'b mut self, name: &'a str, path: &'a str) -> RuleBuilder<'a, 'b> { self.rule(name, path, Kind::Build) } /// Same as `build`, but for `Kind::Test`. fn test<'b>(&'b mut self, name: &'a str, path: &'a str) -> RuleBuilder<'a, 'b> { self.rule(name, path, Kind::Test) } /// Same as `build`, but for `Kind::Bench`. fn bench<'b>(&'b mut self, name: &'a str, path: &'a str) -> RuleBuilder<'a, 'b> { self.rule(name, path, Kind::Bench) } /// Same as `build`, but for `Kind::Doc`. fn doc<'b>(&'b mut self, name: &'a str, path: &'a str) -> RuleBuilder<'a, 'b> { self.rule(name, path, Kind::Doc) } /// Same as `build`, but for `Kind::Dist`. fn dist<'b>(&'b mut self, name: &'a str, path: &'a str) -> RuleBuilder<'a, 'b> { self.rule(name, path, Kind::Dist) } fn rule<'b>(&'b mut self, name: &'a str, path: &'a str, kind: Kind) -> RuleBuilder<'a, 'b> { RuleBuilder { rules: self, rule: Rule::new(name, path, kind), } } /// Verify the dependency graph defined by all our rules are correct, e.g. /// everything points to a valid something else. fn verify(&self) { for rule in self.rules.values() { for dep in rule.deps.iter() { let dep = dep(&self.sbuild.name(rule.name)); if self.rules.contains_key(&dep.name) || dep.name.starts_with("default:") { continue } panic!("\ invalid rule dependency graph detected, was a rule added and maybe typo'd? `{}` depends on `{}` which does not exist ", rule.name, dep.name); } } } pub fn print_help(&self, command: &str) { let kind = match command { "build" => Kind::Build, "doc" => Kind::Doc, "test" => Kind::Test, "bench" => Kind::Bench, "dist" => Kind::Dist, _ => return, }; let rules = self.rules.values().filter(|r| r.kind == kind); let rules = rules.filter(|r| !r.path.contains("nowhere")); let mut rules = rules.collect::>(); rules.sort_by_key(|r| r.path); println!("Available paths:\n"); for rule in rules { print!(" ./x.py {} {}", command, rule.path); println!(""); } } /// Construct the top-level build steps that we're going to be executing, /// given the subcommand that our build is performing. fn plan(&self) -> Vec> { // Ok, the logic here is pretty subtle, and involves quite a few // conditionals. The basic idea here is to: // // 1. First, filter all our rules to the relevant ones. This means that // the command specified corresponds to one of our `Kind` variants, // and we filter all rules based on that. // // 2. Next, we determine which rules we're actually executing. If a // number of path filters were specified on the command line we look // for those, otherwise we look for anything tagged `default`. // // 3. Finally, we generate some steps with host and target information. // // The last step is by far the most complicated and subtle. The basic // thinking here is that we want to take the cartesian product of // specified hosts and targets and build rules with that. The list of // hosts and targets, if not specified, come from the how this build was // configured. If the rule we're looking at is a host-only rule the we // ignore the list of targets and instead consider the list of hosts // also the list of targets. // // Once the host and target lists are generated we take the cartesian // product of the two and then create a step based off them. Note that // the stage each step is associated was specified with the `--step` // flag on the command line. let (kind, paths) = match self.build.flags.cmd { Subcommand::Build { ref paths } => (Kind::Build, &paths[..]), Subcommand::Doc { ref paths } => (Kind::Doc, &paths[..]), Subcommand::Test { ref paths, test_args: _ } => (Kind::Test, &paths[..]), Subcommand::Bench { ref paths, test_args: _ } => (Kind::Bench, &paths[..]), Subcommand::Dist { install } => { if install { return vec![self.sbuild.name("install")] } else { (Kind::Dist, &[][..]) } } Subcommand::Clean => panic!(), }; self.rules.values().filter(|rule| rule.kind == kind).filter(|rule| { (paths.len() == 0 && rule.default) || paths.iter().any(|path| { path.ends_with(rule.path) }) }).flat_map(|rule| { let hosts = if self.build.flags.host.len() > 0 { &self.build.flags.host } else { &self.build.config.host }; let targets = if self.build.flags.target.len() > 0 { &self.build.flags.target } else { &self.build.config.target }; // If --target was specified but --host wasn't specified, don't run // any host-only tests let arr = if rule.host { if self.build.flags.target.len() > 0 && self.build.flags.host.len() == 0 { &hosts[..0] } else { hosts } } else { targets }; hosts.iter().flat_map(move |host| { arr.iter().map(move |target| { self.sbuild.name(rule.name).target(target).host(host) }) }) }).collect() } /// Execute all top-level targets indicated by `steps`. /// /// This will take the list returned by `plan` and then execute each step /// along with all required dependencies as it goes up the chain. fn run(&self, steps: &[Step<'a>]) { self.build.verbose("bootstrap top targets:"); for step in steps.iter() { self.build.verbose(&format!("\t{:?}", step)); } // Using `steps` as the top-level targets, make a topological ordering // of what we need to do. let mut order = Vec::new(); let mut added = HashSet::new(); for step in steps.iter().cloned() { self.fill(step, &mut order, &mut added); } // Print out what we're doing for debugging self.build.verbose("bootstrap build plan:"); for step in order.iter() { self.build.verbose(&format!("\t{:?}", step)); } // And finally, iterate over everything and execute it. for step in order.iter() { if self.build.flags.keep_stage.map_or(false, |s| step.stage <= s) { self.build.verbose(&format!("keeping step {:?}", step)); continue; } self.build.verbose(&format!("executing step {:?}", step)); (self.rules[step.name].run)(step); } } /// Performs topological sort of dependencies rooted at the `step` /// specified, pushing all results onto the `order` vector provided. /// /// In other words, when this method returns, the `order` vector will /// contain a list of steps which if executed in order will eventually /// complete the `step` specified as well. /// /// The `added` set specified here is the set of steps that are already /// present in `order` (and hence don't need to be added again). fn fill(&self, step: Step<'a>, order: &mut Vec>, added: &mut HashSet>) { if !added.insert(step.clone()) { return } for dep in self.rules[step.name].deps.iter() { let dep = dep(&step); if dep.name.starts_with("default:") { let kind = match &dep.name[8..] { "doc" => Kind::Doc, "dist" => Kind::Dist, kind => panic!("unknown kind: `{}`", kind), }; let host = self.build.config.host.iter().any(|h| h == dep.target); let rules = self.rules.values().filter(|r| r.default); for rule in rules.filter(|r| r.kind == kind && (!r.host || host)) { self.fill(dep.name(rule.name), order, added); } } else { self.fill(dep, order, added); } } order.push(step); } }