// Copyright 2012-2015 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. use rustc::dep_graph::DepGraph; use rustc::front; use rustc::front::map as hir_map; use rustc_mir as mir; use rustc::mir::mir_map::MirMap; use rustc::session::{Session, CompileResult, compile_result_from_err_count}; use rustc::session::config::{self, Input, OutputFilenames, OutputType}; use rustc::session::search_paths::PathKind; use rustc::lint; use rustc::middle::{self, dependency_format, stability, reachable}; use rustc::middle::privacy::AccessLevels; use rustc::ty::{self, TyCtxt}; use rustc::util::common::time; use rustc::util::nodemap::NodeSet; use rustc_back::sha2::{Sha256, Digest}; use rustc_borrowck as borrowck; use rustc_resolve as resolve; use rustc_metadata::macro_import; use rustc_metadata::creader::LocalCrateReader; use rustc_metadata::cstore::CStore; use rustc_trans::back::link; use rustc_trans::back::write; use rustc_trans as trans; use rustc_typeck as typeck; use rustc_privacy; use rustc_plugin::registry::Registry; use rustc_plugin as plugin; use rustc_front::hir; use rustc_front::lowering::{lower_crate, LoweringContext}; use rustc_passes::{no_asm, loops, consts, const_fn, rvalues, static_recursion}; use rustc_const_eval::check_match; use super::Compilation; use serialize::json; use std::collections::HashMap; use std::env; use std::ffi::{OsString, OsStr}; use std::fs; use std::io::{self, Write}; use std::path::{Path, PathBuf}; use syntax::ast::{self, NodeIdAssigner}; use syntax::attr::{self, AttrMetaMethods}; use syntax::diagnostics; use syntax::fold::Folder; use syntax::parse::{self, PResult, token}; use syntax::util::node_count::NodeCounter; use syntax::visit; use syntax; use syntax_ext; pub fn compile_input(sess: &Session, cstore: &CStore, cfg: ast::CrateConfig, input: &Input, outdir: &Option, output: &Option, addl_plugins: Option>, control: &CompileController) -> CompileResult { macro_rules! controller_entry_point { ($point: ident, $tsess: expr, $make_state: expr, $phase_result: expr) => {{ let state = $make_state; let phase_result: &CompileResult = &$phase_result; if phase_result.is_ok() || control.$point.run_callback_on_error { (control.$point.callback)(state); } if control.$point.stop == Compilation::Stop { return compile_result_from_err_count($tsess.err_count()); } }} } // We need nested scopes here, because the intermediate results can keep // large chunks of memory alive and we want to free them as soon as // possible to keep the peak memory usage low let (outputs, trans) = { let (outputs, expanded_crate, id) = { let krate = match phase_1_parse_input(sess, cfg, input) { Ok(krate) => krate, Err(mut parse_error) => { parse_error.emit(); return Err(1); } }; controller_entry_point!(after_parse, sess, CompileState::state_after_parse(input, sess, outdir, &krate), Ok(())); let outputs = build_output_filenames(input, outdir, output, &krate.attrs, sess); let id = link::find_crate_name(Some(sess), &krate.attrs, input); let expanded_crate = phase_2_configure_and_expand(sess, &cstore, krate, &id[..], addl_plugins)?; (outputs, expanded_crate, id) }; controller_entry_point!(after_expand, sess, CompileState::state_after_expand(input, sess, outdir, &expanded_crate, &id[..]), Ok(())); let expanded_crate = assign_node_ids(sess, expanded_crate); // Lower ast -> hir. let lcx = LoweringContext::new(sess, Some(&expanded_crate)); let dep_graph = DepGraph::new(sess.opts.build_dep_graph); let mut hir_forest = time(sess.time_passes(), "lowering ast -> hir", || hir_map::Forest::new(lower_crate(&lcx, &expanded_crate), dep_graph)); // Discard MTWT tables that aren't required past lowering to HIR. if !sess.opts.debugging_opts.keep_mtwt_tables && !sess.opts.debugging_opts.save_analysis { syntax::ext::mtwt::clear_tables(); } let arenas = ty::CtxtArenas::new(); let hir_map = make_map(sess, &mut hir_forest); write_out_deps(sess, &outputs, &id); { let _ignore = hir_map.dep_graph.in_ignore(); controller_entry_point!(after_write_deps, sess, CompileState::state_after_write_deps(input, sess, outdir, &hir_map, &expanded_crate, &hir_map.krate(), &id[..], &lcx), Ok(())); } time(sess.time_passes(), "attribute checking", || { front::check_attr::check_crate(sess, &expanded_crate); }); time(sess.time_passes(), "early lint checks", || lint::check_ast_crate(sess, &expanded_crate)); let opt_crate = if sess.opts.debugging_opts.keep_ast || sess.opts.debugging_opts.save_analysis { Some(&expanded_crate) } else { drop(expanded_crate); None }; phase_3_run_analysis_passes(sess, &cstore, hir_map, &arenas, &id, control.make_glob_map, |tcx, mir_map, analysis, result| { { // Eventually, we will want to track plugins. let _ignore = tcx.dep_graph.in_ignore(); let state = CompileState::state_after_analysis(input, &tcx.sess, outdir, opt_crate, tcx.map.krate(), &analysis, mir_map.as_ref(), tcx, &lcx, &id); (control.after_analysis.callback)(state); if control.after_analysis.stop == Compilation::Stop { return Err(0usize); } } result?; if log_enabled!(::log::INFO) { println!("Pre-trans"); tcx.print_debug_stats(); } let trans = phase_4_translate_to_llvm(tcx, mir_map.unwrap(), analysis); if log_enabled!(::log::INFO) { println!("Post-trans"); tcx.print_debug_stats(); } // Discard interned strings as they are no longer required. token::get_ident_interner().clear(); Ok((outputs, trans)) })?? }; let phase5_result = phase_5_run_llvm_passes(sess, &trans, &outputs); controller_entry_point!(after_llvm, sess, CompileState::state_after_llvm(input, sess, outdir, &trans), phase5_result); phase5_result?; phase_6_link_output(sess, &trans, &outputs); Ok(()) } /// The name used for source code that doesn't originate in a file /// (e.g. source from stdin or a string) pub fn anon_src() -> String { "".to_string() } pub fn source_name(input: &Input) -> String { match *input { // FIXME (#9639): This needs to handle non-utf8 paths Input::File(ref ifile) => ifile.to_str().unwrap().to_string(), Input::Str { ref name, .. } => name.clone(), } } /// CompileController is used to customise compilation, it allows compilation to /// be stopped and/or to call arbitrary code at various points in compilation. /// It also allows for various flags to be set to influence what information gets /// collected during compilation. /// /// This is a somewhat higher level controller than a Session - the Session /// controls what happens in each phase, whereas the CompileController controls /// whether a phase is run at all and whether other code (from outside the /// the compiler) is run between phases. /// /// Note that if compilation is set to stop and a callback is provided for a /// given entry point, the callback is called before compilation is stopped. /// /// Expect more entry points to be added in the future. pub struct CompileController<'a> { pub after_parse: PhaseController<'a>, pub after_expand: PhaseController<'a>, pub after_write_deps: PhaseController<'a>, pub after_analysis: PhaseController<'a>, pub after_llvm: PhaseController<'a>, pub make_glob_map: resolve::MakeGlobMap, } impl<'a> CompileController<'a> { pub fn basic() -> CompileController<'a> { CompileController { after_parse: PhaseController::basic(), after_expand: PhaseController::basic(), after_write_deps: PhaseController::basic(), after_analysis: PhaseController::basic(), after_llvm: PhaseController::basic(), make_glob_map: resolve::MakeGlobMap::No, } } } pub struct PhaseController<'a> { pub stop: Compilation, // If true then the compiler will try to run the callback even if the phase // ends with an error. Note that this is not always possible. pub run_callback_on_error: bool, pub callback: Box () + 'a>, } impl<'a> PhaseController<'a> { pub fn basic() -> PhaseController<'a> { PhaseController { stop: Compilation::Continue, run_callback_on_error: false, callback: box |_| {}, } } } /// State that is passed to a callback. What state is available depends on when /// during compilation the callback is made. See the various constructor methods /// (`state_*`) in the impl to see which data is provided for any given entry point. pub struct CompileState<'a, 'ast: 'a, 'tcx: 'a> { pub input: &'a Input, pub session: &'a Session, pub cfg: Option<&'a ast::CrateConfig>, pub krate: Option<&'a ast::Crate>, pub crate_name: Option<&'a str>, pub output_filenames: Option<&'a OutputFilenames>, pub out_dir: Option<&'a Path>, pub expanded_crate: Option<&'a ast::Crate>, pub hir_crate: Option<&'a hir::Crate>, pub ast_map: Option<&'a hir_map::Map<'ast>>, pub mir_map: Option<&'a MirMap<'tcx>>, pub analysis: Option<&'a ty::CrateAnalysis<'a>>, pub tcx: Option<&'a TyCtxt<'tcx>>, pub lcx: Option<&'a LoweringContext<'a>>, pub trans: Option<&'a trans::CrateTranslation>, } impl<'a, 'ast, 'tcx> CompileState<'a, 'ast, 'tcx> { fn empty(input: &'a Input, session: &'a Session, out_dir: &'a Option) -> CompileState<'a, 'ast, 'tcx> { CompileState { input: input, session: session, out_dir: out_dir.as_ref().map(|s| &**s), cfg: None, krate: None, crate_name: None, output_filenames: None, expanded_crate: None, hir_crate: None, ast_map: None, analysis: None, mir_map: None, tcx: None, lcx: None, trans: None, } } fn state_after_parse(input: &'a Input, session: &'a Session, out_dir: &'a Option, krate: &'a ast::Crate) -> CompileState<'a, 'ast, 'tcx> { CompileState { krate: Some(krate), ..CompileState::empty(input, session, out_dir) } } fn state_after_expand(input: &'a Input, session: &'a Session, out_dir: &'a Option, expanded_crate: &'a ast::Crate, crate_name: &'a str) -> CompileState<'a, 'ast, 'tcx> { CompileState { crate_name: Some(crate_name), expanded_crate: Some(expanded_crate), ..CompileState::empty(input, session, out_dir) } } fn state_after_write_deps(input: &'a Input, session: &'a Session, out_dir: &'a Option, hir_map: &'a hir_map::Map<'ast>, krate: &'a ast::Crate, hir_crate: &'a hir::Crate, crate_name: &'a str, lcx: &'a LoweringContext<'a>) -> CompileState<'a, 'ast, 'tcx> { CompileState { crate_name: Some(crate_name), ast_map: Some(hir_map), krate: Some(krate), hir_crate: Some(hir_crate), lcx: Some(lcx), ..CompileState::empty(input, session, out_dir) } } fn state_after_analysis(input: &'a Input, session: &'a Session, out_dir: &'a Option, krate: Option<&'a ast::Crate>, hir_crate: &'a hir::Crate, analysis: &'a ty::CrateAnalysis, mir_map: Option<&'a MirMap<'tcx>>, tcx: &'a TyCtxt<'tcx>, lcx: &'a LoweringContext<'a>, crate_name: &'a str) -> CompileState<'a, 'ast, 'tcx> { CompileState { analysis: Some(analysis), mir_map: mir_map, tcx: Some(tcx), krate: krate, hir_crate: Some(hir_crate), lcx: Some(lcx), crate_name: Some(crate_name), ..CompileState::empty(input, session, out_dir) } } fn state_after_llvm(input: &'a Input, session: &'a Session, out_dir: &'a Option, trans: &'a trans::CrateTranslation) -> CompileState<'a, 'ast, 'tcx> { CompileState { trans: Some(trans), ..CompileState::empty(input, session, out_dir) } } } pub fn phase_1_parse_input<'a>(sess: &'a Session, cfg: ast::CrateConfig, input: &Input) -> PResult<'a, ast::Crate> { // These may be left in an incoherent state after a previous compile. // `clear_tables` and `get_ident_interner().clear()` can be used to free // memory, but they do not restore the initial state. syntax::ext::mtwt::reset_tables(); token::reset_ident_interner(); let continue_after_error = sess.opts.continue_parse_after_error; sess.diagnostic().set_continue_after_error(continue_after_error); let krate = time(sess.time_passes(), "parsing", || { match *input { Input::File(ref file) => { parse::parse_crate_from_file(file, cfg.clone(), &sess.parse_sess) } Input::Str { ref input, ref name } => { parse::parse_crate_from_source_str(name.clone(), input.clone(), cfg.clone(), &sess.parse_sess) } } })?; sess.diagnostic().set_continue_after_error(true); if sess.opts.debugging_opts.ast_json_noexpand { println!("{}", json::as_json(&krate)); } if sess.opts.debugging_opts.input_stats { println!("Lines of code: {}", sess.codemap().count_lines()); println!("Pre-expansion node count: {}", count_nodes(&krate)); } if let Some(ref s) = sess.opts.debugging_opts.show_span { syntax::show_span::run(sess.diagnostic(), s, &krate); } Ok(krate) } fn count_nodes(krate: &ast::Crate) -> usize { let mut counter = NodeCounter::new(); visit::walk_crate(&mut counter, krate); counter.count } // For continuing compilation after a parsed crate has been // modified /// Run the "early phases" of the compiler: initial `cfg` processing, /// loading compiler plugins (including those from `addl_plugins`), /// syntax expansion, secondary `cfg` expansion, synthesis of a test /// harness if one is to be provided and injection of a dependency on the /// standard library and prelude. /// /// Returns `None` if we're aborting after handling -W help. pub fn phase_2_configure_and_expand(sess: &Session, cstore: &CStore, mut krate: ast::Crate, crate_name: &str, addl_plugins: Option>) -> Result { let time_passes = sess.time_passes(); // strip before anything else because crate metadata may use #[cfg_attr] // and so macros can depend on configuration variables, such as // // #[macro_use] #[cfg(foo)] // mod bar { macro_rules! baz!(() => {{}}) } // // baz! should not use this definition unless foo is enabled. let mut feature_gated_cfgs = vec![]; krate = time(time_passes, "configuration 1", || { sess.track_errors(|| { syntax::config::strip_unconfigured_items(sess.diagnostic(), krate, &mut feature_gated_cfgs) }) })?; *sess.crate_types.borrow_mut() = collect_crate_types(sess, &krate.attrs); sess.crate_disambiguator.set(token::intern(&compute_crate_disambiguator(sess))); time(time_passes, "recursion limit", || { middle::recursion_limit::update_recursion_limit(sess, &krate); }); time(time_passes, "gated macro checking", || { sess.track_errors(|| { let features = syntax::feature_gate::check_crate_macros(sess.codemap(), &sess.parse_sess.span_diagnostic, &krate); // these need to be set "early" so that expansion sees `quote` if enabled. *sess.features.borrow_mut() = features; }) })?; krate = time(time_passes, "crate injection", || { syntax::std_inject::maybe_inject_crates_ref(krate, sess.opts.alt_std_name.clone()) }); let macros = time(time_passes, "macro loading", || macro_import::read_macro_defs(sess, &cstore, &krate, crate_name)); let mut addl_plugins = Some(addl_plugins); let registrars = time(time_passes, "plugin loading", || { plugin::load::load_plugins(sess, &cstore, &krate, crate_name, addl_plugins.take().unwrap()) }); let mut registry = Registry::new(sess, &krate); time(time_passes, "plugin registration", || { if sess.features.borrow().rustc_diagnostic_macros { registry.register_macro("__diagnostic_used", diagnostics::plugin::expand_diagnostic_used); registry.register_macro("__register_diagnostic", diagnostics::plugin::expand_register_diagnostic); registry.register_macro("__build_diagnostic_array", diagnostics::plugin::expand_build_diagnostic_array); } for registrar in registrars { registry.args_hidden = Some(registrar.args); (registrar.fun)(&mut registry); } }); let Registry { syntax_exts, early_lint_passes, late_lint_passes, lint_groups, llvm_passes, attributes, mir_passes, .. } = registry; sess.track_errors(|| { let mut ls = sess.lint_store.borrow_mut(); for pass in early_lint_passes { ls.register_early_pass(Some(sess), true, pass); } for pass in late_lint_passes { ls.register_late_pass(Some(sess), true, pass); } for (name, to) in lint_groups { ls.register_group(Some(sess), true, name, to); } *sess.plugin_llvm_passes.borrow_mut() = llvm_passes; sess.mir_passes.borrow_mut().extend(mir_passes); *sess.plugin_attributes.borrow_mut() = attributes.clone(); })?; // Lint plugins are registered; now we can process command line flags. if sess.opts.describe_lints { super::describe_lints(&sess.lint_store.borrow(), true); return Err(0); } sess.track_errors(|| sess.lint_store.borrow_mut().process_command_line(sess))?; krate = time(time_passes, "expansion", || { // Windows dlls do not have rpaths, so they don't know how to find their // dependencies. It's up to us to tell the system where to find all the // dependent dlls. Note that this uses cfg!(windows) as opposed to // targ_cfg because syntax extensions are always loaded for the host // compiler, not for the target. let mut _old_path = OsString::new(); if cfg!(windows) { _old_path = env::var_os("PATH").unwrap_or(_old_path); let mut new_path = sess.host_filesearch(PathKind::All) .get_dylib_search_paths(); new_path.extend(env::split_paths(&_old_path)); env::set_var("PATH", &env::join_paths(new_path).unwrap()); } let features = sess.features.borrow(); let cfg = syntax::ext::expand::ExpansionConfig { crate_name: crate_name.to_string(), features: Some(&features), recursion_limit: sess.recursion_limit.get(), trace_mac: sess.opts.debugging_opts.trace_macros, }; let mut ecx = syntax::ext::base::ExtCtxt::new(&sess.parse_sess, krate.config.clone(), cfg, &mut feature_gated_cfgs); syntax_ext::register_builtins(&mut ecx.syntax_env); let (ret, macro_names) = syntax::ext::expand::expand_crate(ecx, macros, syntax_exts, krate); if cfg!(windows) { env::set_var("PATH", &_old_path); } *sess.available_macros.borrow_mut() = macro_names; ret }); // Needs to go *after* expansion to be able to check the results // of macro expansion. This runs before #[cfg] to try to catch as // much as possible (e.g. help the programmer avoid platform // specific differences) time(time_passes, "complete gated feature checking 1", || { sess.track_errors(|| { let features = syntax::feature_gate::check_crate(sess.codemap(), &sess.parse_sess.span_diagnostic, &krate, &attributes, sess.opts.unstable_features); *sess.features.borrow_mut() = features; }) })?; // JBC: make CFG processing part of expansion to avoid this problem: // strip again, in case expansion added anything with a #[cfg]. krate = sess.track_errors(|| { let krate = time(time_passes, "configuration 2", || { syntax::config::strip_unconfigured_items(sess.diagnostic(), krate, &mut feature_gated_cfgs) }); time(time_passes, "gated configuration checking", || { let features = sess.features.borrow(); feature_gated_cfgs.sort(); feature_gated_cfgs.dedup(); for cfg in &feature_gated_cfgs { cfg.check_and_emit(sess.diagnostic(), &features, sess.codemap()); } }); krate })?; krate = time(time_passes, "maybe building test harness", || { syntax::test::modify_for_testing(&sess.parse_sess, &sess.opts.cfg, krate, sess.diagnostic()) }); krate = time(time_passes, "prelude injection", || syntax::std_inject::maybe_inject_prelude(&sess.parse_sess, krate)); time(time_passes, "checking that all macro invocations are gone", || syntax::ext::expand::check_for_macros(&sess.parse_sess, &krate)); time(time_passes, "checking for inline asm in case the target doesn't support it", || no_asm::check_crate(sess, &krate)); // One final feature gating of the true AST that gets compiled // later, to make sure we've got everything (e.g. configuration // can insert new attributes via `cfg_attr`) time(time_passes, "complete gated feature checking 2", || { sess.track_errors(|| { let features = syntax::feature_gate::check_crate(sess.codemap(), &sess.parse_sess.span_diagnostic, &krate, &attributes, sess.opts.unstable_features); *sess.features.borrow_mut() = features; }) })?; time(time_passes, "const fn bodies and arguments", || const_fn::check_crate(sess, &krate))?; if sess.opts.debugging_opts.input_stats { println!("Post-expansion node count: {}", count_nodes(&krate)); } Ok(krate) } pub fn assign_node_ids(sess: &Session, krate: ast::Crate) -> ast::Crate { struct NodeIdAssigner<'a> { sess: &'a Session, } impl<'a> Folder for NodeIdAssigner<'a> { fn new_id(&mut self, old_id: ast::NodeId) -> ast::NodeId { assert_eq!(old_id, ast::DUMMY_NODE_ID); self.sess.next_node_id() } } let krate = time(sess.time_passes(), "assigning node ids", || NodeIdAssigner { sess: sess }.fold_crate(krate)); if sess.opts.debugging_opts.ast_json { println!("{}", json::as_json(&krate)); } krate } pub fn make_map<'ast>(sess: &Session, forest: &'ast mut hir_map::Forest) -> hir_map::Map<'ast> { // Construct the HIR map time(sess.time_passes(), "indexing hir", move || hir_map::map_crate(forest)) } /// Run the resolution, typechecking, region checking and other /// miscellaneous analysis passes on the crate. Return various /// structures carrying the results of the analysis. pub fn phase_3_run_analysis_passes<'tcx, F, R>(sess: &'tcx Session, cstore: &CStore, hir_map: hir_map::Map<'tcx>, arenas: &'tcx ty::CtxtArenas<'tcx>, name: &str, make_glob_map: resolve::MakeGlobMap, f: F) -> Result where F: FnOnce(&TyCtxt<'tcx>, Option>, ty::CrateAnalysis, CompileResult) -> R { macro_rules! try_with_f { ($e: expr, ($t: expr, $m: expr, $a: expr)) => { match $e { Ok(x) => x, Err(x) => { f($t, $m, $a, Err(x)); return Err(x); } } } } let time_passes = sess.time_passes(); time(time_passes, "external crate/lib resolution", || LocalCrateReader::new(sess, cstore, &hir_map, name).read_crates()); let lang_items = time(time_passes, "language item collection", || { sess.track_errors(|| { middle::lang_items::collect_language_items(&sess, &hir_map) }) })?; let resolve::CrateMap { def_map, freevars, export_map, trait_map, glob_map, } = time(time_passes, "resolution", || resolve::resolve_crate(sess, &hir_map, make_glob_map)); let mut analysis = ty::CrateAnalysis { export_map: export_map, access_levels: AccessLevels::default(), reachable: NodeSet(), name: name, glob_map: glob_map, }; let named_region_map = time(time_passes, "lifetime resolution", || middle::resolve_lifetime::krate(sess, &hir_map, &def_map.borrow()))?; time(time_passes, "looking for entry point", || middle::entry::find_entry_point(sess, &hir_map)); sess.plugin_registrar_fn.set(time(time_passes, "looking for plugin registrar", || { plugin::build::find_plugin_registrar(sess.diagnostic(), &hir_map) })); let region_map = time(time_passes, "region resolution", || middle::region::resolve_crate(sess, &hir_map)); time(time_passes, "loop checking", || loops::check_crate(sess, &hir_map)); time(time_passes, "static item recursion checking", || static_recursion::check_crate(sess, &def_map.borrow(), &hir_map))?; let index = stability::Index::new(&hir_map); TyCtxt::create_and_enter(sess, arenas, def_map, named_region_map, hir_map, freevars, region_map, lang_items, index, name, |tcx| { // passes are timed inside typeck try_with_f!(typeck::check_crate(tcx, trait_map), (tcx, None, analysis)); time(time_passes, "const checking", || consts::check_crate(tcx)); analysis.access_levels = time(time_passes, "privacy checking", || { rustc_privacy::check_crate(tcx, &analysis.export_map) }); // Do not move this check past lint time(time_passes, "stability index", || { tcx.stability.borrow_mut().build(tcx, &analysis.access_levels) }); time(time_passes, "intrinsic checking", || middle::intrinsicck::check_crate(tcx)); time(time_passes, "effect checking", || middle::effect::check_crate(tcx)); time(time_passes, "match checking", || check_match::check_crate(tcx)); // this must run before MIR dump, because // "not all control paths return a value" is reported here. // // maybe move the check to a MIR pass? time(time_passes, "liveness checking", || middle::liveness::check_crate(tcx)); time(time_passes, "rvalue checking", || rvalues::check_crate(tcx)); let mut mir_map = time(time_passes, "MIR dump", || mir::mir_map::build_mir_for_crate(tcx)); time(time_passes, "MIR passes", || { let mut passes = sess.mir_passes.borrow_mut(); // Push all the built-in passes. passes.push_pass(box mir::transform::remove_dead_blocks::RemoveDeadBlocks); passes.push_pass(box mir::transform::type_check::TypeckMir); passes.push_pass(box mir::transform::simplify_cfg::SimplifyCfg); // Late passes passes.push_pass(box mir::transform::no_landing_pads::NoLandingPads); passes.push_pass(box mir::transform::remove_dead_blocks::RemoveDeadBlocks); passes.push_pass(box mir::transform::erase_regions::EraseRegions); // And run everything. passes.run_passes(tcx, &mut mir_map); }); time(time_passes, "borrow checking", || borrowck::check_crate(tcx, &mir_map)); // Avoid overwhelming user with errors if type checking failed. // I'm not sure how helpful this is, to be honest, but it avoids // a // lot of annoying errors in the compile-fail tests (basically, // lint warnings and so on -- kindck used to do this abort, but // kindck is gone now). -nmatsakis if sess.err_count() > 0 { return Ok(f(tcx, Some(mir_map), analysis, Err(sess.err_count()))); } analysis.reachable = time(time_passes, "reachability checking", || reachable::find_reachable(tcx, &analysis.access_levels)); time(time_passes, "death checking", || { middle::dead::check_crate(tcx, &analysis.access_levels); }); let ref lib_features_used = time(time_passes, "stability checking", || stability::check_unstable_api_usage(tcx)); time(time_passes, "unused lib feature checking", || { stability::check_unused_or_stable_features(&tcx.sess, lib_features_used) }); time(time_passes, "lint checking", || lint::check_crate(tcx, &analysis.access_levels)); // The above three passes generate errors w/o aborting if sess.err_count() > 0 { return Ok(f(tcx, Some(mir_map), analysis, Err(sess.err_count()))); } Ok(f(tcx, Some(mir_map), analysis, Ok(()))) }) } /// Run the translation phase to LLVM, after which the AST and analysis can pub fn phase_4_translate_to_llvm<'tcx>(tcx: &TyCtxt<'tcx>, mir_map: MirMap<'tcx>, analysis: ty::CrateAnalysis) -> trans::CrateTranslation { let time_passes = tcx.sess.time_passes(); time(time_passes, "resolving dependency formats", || dependency_format::calculate(&tcx.sess)); // Option dance to work around the lack of stack once closures. time(time_passes, "translation", move || trans::trans_crate(tcx, &mir_map, analysis)) } /// Run LLVM itself, producing a bitcode file, assembly file or object file /// as a side effect. pub fn phase_5_run_llvm_passes(sess: &Session, trans: &trans::CrateTranslation, outputs: &OutputFilenames) -> CompileResult { if sess.opts.cg.no_integrated_as { let mut map = HashMap::new(); map.insert(OutputType::Assembly, None); time(sess.time_passes(), "LLVM passes", || write::run_passes(sess, trans, &map, outputs)); write::run_assembler(sess, outputs); // Remove assembly source, unless --save-temps was specified if !sess.opts.cg.save_temps { fs::remove_file(&outputs.temp_path(OutputType::Assembly)).unwrap(); } } else { time(sess.time_passes(), "LLVM passes", || write::run_passes(sess, trans, &sess.opts.output_types, outputs)); } if sess.err_count() > 0 { Err(sess.err_count()) } else { Ok(()) } } /// Run the linker on any artifacts that resulted from the LLVM run. /// This should produce either a finished executable or library. pub fn phase_6_link_output(sess: &Session, trans: &trans::CrateTranslation, outputs: &OutputFilenames) { time(sess.time_passes(), "linking", || link::link_binary(sess, trans, outputs, &trans.link.crate_name)); } fn escape_dep_filename(filename: &str) -> String { // Apparently clang and gcc *only* escape spaces: // http://llvm.org/klaus/clang/commit/9d50634cfc268ecc9a7250226dd5ca0e945240d4 filename.replace(" ", "\\ ") } fn write_out_deps(sess: &Session, outputs: &OutputFilenames, id: &str) { let mut out_filenames = Vec::new(); for output_type in sess.opts.output_types.keys() { let file = outputs.path(*output_type); match *output_type { OutputType::Exe => { for output in sess.crate_types.borrow().iter() { let p = link::filename_for_input(sess, *output, id, outputs); out_filenames.push(p); } } _ => { out_filenames.push(file); } } } // Write out dependency rules to the dep-info file if requested if !sess.opts.output_types.contains_key(&OutputType::DepInfo) { return; } let deps_filename = outputs.path(OutputType::DepInfo); let result = (|| -> io::Result<()> { // Build a list of files used to compile the output and // write Makefile-compatible dependency rules let files: Vec = sess.codemap() .files .borrow() .iter() .filter(|fmap| fmap.is_real_file()) .filter(|fmap| !fmap.is_imported()) .map(|fmap| escape_dep_filename(&fmap.name)) .collect(); let mut file = fs::File::create(&deps_filename)?; for path in &out_filenames { write!(file, "{}: {}\n\n", path.display(), files.join(" "))?; } // Emit a fake target for each input file to the compilation. This // prevents `make` from spitting out an error if a file is later // deleted. For more info see #28735 for path in files { writeln!(file, "{}:", path)?; } Ok(()) })(); match result { Ok(()) => {} Err(e) => { sess.fatal(&format!("error writing dependencies to `{}`: {}", deps_filename.display(), e)); } } } pub fn collect_crate_types(session: &Session, attrs: &[ast::Attribute]) -> Vec { // Unconditionally collect crate types from attributes to make them used let attr_types: Vec = attrs.iter() .filter_map(|a| { if a.check_name("crate_type") { match a.value_str() { Some(ref n) if *n == "rlib" => { Some(config::CrateTypeRlib) } Some(ref n) if *n == "dylib" => { Some(config::CrateTypeDylib) } Some(ref n) if *n == "lib" => { Some(config::default_lib_output()) } Some(ref n) if *n == "staticlib" => { Some(config::CrateTypeStaticlib) } Some(ref n) if *n == "bin" => Some(config::CrateTypeExecutable), Some(_) => { session.add_lint(lint::builtin::UNKNOWN_CRATE_TYPES, ast::CRATE_NODE_ID, a.span, "invalid `crate_type` value".to_string()); None } _ => { session.struct_span_err(a.span, "`crate_type` requires a value") .note("for example: `#![crate_type=\"lib\"]`") .emit(); None } } } else { None } }) .collect(); // If we're generating a test executable, then ignore all other output // styles at all other locations if session.opts.test { return vec![config::CrateTypeExecutable]; } // Only check command line flags if present. If no types are specified by // command line, then reuse the empty `base` Vec to hold the types that // will be found in crate attributes. let mut base = session.opts.crate_types.clone(); if base.is_empty() { base.extend(attr_types); if base.is_empty() { base.push(link::default_output_for_target(session)); } base.sort(); base.dedup(); } base.into_iter() .filter(|crate_type| { let res = !link::invalid_output_for_target(session, *crate_type); if !res { session.warn(&format!("dropping unsupported crate type `{}` for target `{}`", *crate_type, session.opts.target_triple)); } res }) .collect() } pub fn compute_crate_disambiguator(session: &Session) -> String { let mut hasher = Sha256::new(); let mut metadata = session.opts.cg.metadata.clone(); // We don't want the crate_disambiguator to dependent on the order // -C metadata arguments, so sort them: metadata.sort(); // Every distinct -C metadata value is only incorporated once: metadata.dedup(); hasher.input_str("metadata"); for s in &metadata { // Also incorporate the length of a metadata string, so that we generate // different values for `-Cmetadata=ab -Cmetadata=c` and // `-Cmetadata=a -Cmetadata=bc` hasher.input_str(&format!("{}", s.len())[..]); hasher.input_str(&s[..]); } let mut hash = hasher.result_str(); // If this is an executable, add a special suffix, so that we don't get // symbol conflicts when linking against a library of the same name. if session.crate_types.borrow().contains(&config::CrateTypeExecutable) { hash.push_str("-exe"); } hash } pub fn build_output_filenames(input: &Input, odir: &Option, ofile: &Option, attrs: &[ast::Attribute], sess: &Session) -> OutputFilenames { match *ofile { None => { // "-" as input file will cause the parser to read from stdin so we // have to make up a name // We want to toss everything after the final '.' let dirpath = match *odir { Some(ref d) => d.clone(), None => PathBuf::new(), }; // If a crate name is present, we use it as the link name let stem = sess.opts .crate_name .clone() .or_else(|| attr::find_crate_name(attrs).map(|n| n.to_string())) .unwrap_or(input.filestem()); OutputFilenames { out_directory: dirpath, out_filestem: stem, single_output_file: None, extra: sess.opts.cg.extra_filename.clone(), outputs: sess.opts.output_types.clone(), } } Some(ref out_file) => { let unnamed_output_types = sess.opts .output_types .values() .filter(|a| a.is_none()) .count(); let ofile = if unnamed_output_types > 1 { sess.warn("ignoring specified output filename because multiple outputs were \ requested"); None } else { Some(out_file.clone()) }; if *odir != None { sess.warn("ignoring --out-dir flag due to -o flag."); } let cur_dir = Path::new(""); OutputFilenames { out_directory: out_file.parent().unwrap_or(cur_dir).to_path_buf(), out_filestem: out_file.file_stem() .unwrap_or(OsStr::new("")) .to_str() .unwrap() .to_string(), single_output_file: ofile, extra: sess.opts.cg.extra_filename.clone(), outputs: sess.opts.output_types.clone(), } } } }