use log::info; use rustc::session::config::{Input, OutputFilenames, ErrorOutputType}; use rustc::session::{self, config, early_error, filesearch, Session, DiagnosticOutput}; use rustc::session::CrateDisambiguator; use rustc::ty; use rustc::lint; use rustc_codegen_utils::codegen_backend::CodegenBackend; #[cfg(parallel_compiler)] use rustc_data_structures::jobserver; use rustc_data_structures::sync::{Lock, Lrc}; use rustc_data_structures::stable_hasher::StableHasher; use rustc_data_structures::fingerprint::Fingerprint; use rustc_data_structures::thin_vec::ThinVec; use rustc_data_structures::fx::{FxHashSet, FxHashMap}; use rustc_errors::registry::Registry; use rustc_lint; use rustc_metadata::dynamic_lib::DynamicLibrary; use rustc_mir; use rustc_passes; use rustc_plugin; use rustc_privacy; use rustc_resolve; use rustc_typeck; use std::env; use std::env::consts::{DLL_PREFIX, DLL_SUFFIX}; use std::io::{self, Write}; use std::mem; use std::path::{Path, PathBuf}; use std::sync::atomic::{AtomicBool, Ordering}; use std::sync::{Arc, Mutex, Once}; use std::ops::DerefMut; use smallvec::SmallVec; use syntax::ptr::P; use syntax::mut_visit::{*, MutVisitor, visit_clobber}; use syntax::ast::BlockCheckMode; use syntax::util::lev_distance::find_best_match_for_name; use syntax::source_map::{FileLoader, RealFileLoader, SourceMap}; use syntax::symbol::{Symbol, sym}; use syntax::{self, ast, attr}; use syntax_pos::edition::Edition; #[cfg(not(parallel_compiler))] use std::{thread, panic}; pub fn diagnostics_registry() -> Registry { let mut all_errors = Vec::new(); all_errors.extend_from_slice(&rustc::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_typeck::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_resolve::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_privacy::error_codes::DIAGNOSTICS); // FIXME: need to figure out a way to get these back in here // all_errors.extend_from_slice(get_codegen_backend(sess).diagnostics()); all_errors.extend_from_slice(&rustc_metadata::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_passes::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_plugin::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&rustc_mir::error_codes::DIAGNOSTICS); all_errors.extend_from_slice(&syntax::error_codes::DIAGNOSTICS); Registry::new(&all_errors) } /// Adds `target_feature = "..."` cfgs for a variety of platform /// specific features (SSE, NEON etc.). /// /// This is performed by checking whether a whitelisted set of /// features is available on the target machine, by querying LLVM. pub fn add_configuration( cfg: &mut ast::CrateConfig, sess: &Session, codegen_backend: &dyn CodegenBackend, ) { let tf = sym::target_feature; cfg.extend( codegen_backend .target_features(sess) .into_iter() .map(|feat| (tf, Some(feat))), ); if sess.crt_static_feature() { cfg.insert((tf, Some(Symbol::intern("crt-static")))); } } pub fn create_session( sopts: config::Options, cfg: FxHashSet<(String, Option)>, diagnostic_output: DiagnosticOutput, file_loader: Option>, input_path: Option, lint_caps: FxHashMap, ) -> (Lrc, Lrc>, Lrc) { let descriptions = diagnostics_registry(); let loader = file_loader.unwrap_or(box RealFileLoader); let source_map = Lrc::new(SourceMap::with_file_loader( loader, sopts.file_path_mapping(), )); let mut sess = session::build_session_with_source_map( sopts, input_path, descriptions, source_map.clone(), diagnostic_output, lint_caps, ); let codegen_backend = get_codegen_backend(&sess); rustc_lint::register_builtins(&mut sess.lint_store.borrow_mut(), Some(&sess)); if sess.unstable_options() { rustc_lint::register_internals(&mut sess.lint_store.borrow_mut(), Some(&sess)); } let mut cfg = config::build_configuration(&sess, config::to_crate_config(cfg)); add_configuration(&mut cfg, &sess, &*codegen_backend); sess.parse_sess.config = cfg; (Lrc::new(sess), Lrc::new(codegen_backend), source_map) } // Temporarily have stack size set to 32MB to deal with various crates with long method // chains or deep syntax trees, except when on Haiku. // FIXME(oli-obk): get https://github.com/rust-lang/rust/pull/55617 the finish line #[cfg(not(target_os = "haiku"))] const STACK_SIZE: usize = 32 * 1024 * 1024; #[cfg(target_os = "haiku")] const STACK_SIZE: usize = 16 * 1024 * 1024; fn get_stack_size() -> Option { // FIXME: Hacks on hacks. If the env is trying to override the stack size // then *don't* set it explicitly. if env::var_os("RUST_MIN_STACK").is_none() { Some(STACK_SIZE) } else { None } } struct Sink(Arc>>); impl Write for Sink { fn write(&mut self, data: &[u8]) -> io::Result { Write::write(&mut *self.0.lock().unwrap(), data) } fn flush(&mut self) -> io::Result<()> { Ok(()) } } #[cfg(not(parallel_compiler))] pub fn scoped_thread R + Send, R: Send>(cfg: thread::Builder, f: F) -> R { struct Ptr(*mut ()); unsafe impl Send for Ptr {} unsafe impl Sync for Ptr {} let mut f = Some(f); let run = Ptr(&mut f as *mut _ as *mut ()); let mut result = None; let result_ptr = Ptr(&mut result as *mut _ as *mut ()); let thread = cfg.spawn(move || { let run = unsafe { (*(run.0 as *mut Option)).take().unwrap() }; let result = unsafe { &mut *(result_ptr.0 as *mut Option) }; *result = Some(run()); }); match thread.unwrap().join() { Ok(()) => result.unwrap(), Err(p) => panic::resume_unwind(p), } } #[cfg(not(parallel_compiler))] pub fn spawn_thread_pool R + Send, R: Send>( edition: Edition, _threads: usize, stderr: &Option>>>, f: F, ) -> R { let mut cfg = thread::Builder::new().name("rustc".to_string()); if let Some(size) = get_stack_size() { cfg = cfg.stack_size(size); } scoped_thread(cfg, || { syntax::with_globals(edition, || { ty::tls::GCX_PTR.set(&Lock::new(0), || { if let Some(stderr) = stderr { io::set_panic(Some(box Sink(stderr.clone()))); } ty::tls::with_thread_locals(|| f()) }) }) }) } #[cfg(parallel_compiler)] pub fn spawn_thread_pool R + Send, R: Send>( edition: Edition, threads: usize, stderr: &Option>>>, f: F, ) -> R { use rayon::{ThreadBuilder, ThreadPool, ThreadPoolBuilder}; let gcx_ptr = &Lock::new(0); let mut config = ThreadPoolBuilder::new() .acquire_thread_handler(jobserver::acquire_thread) .release_thread_handler(jobserver::release_thread) .num_threads(threads) .deadlock_handler(|| unsafe { ty::query::handle_deadlock() }); if let Some(size) = get_stack_size() { config = config.stack_size(size); } let with_pool = move |pool: &ThreadPool| pool.install(move || f()); syntax::with_globals(edition, || { syntax::GLOBALS.with(|syntax_globals| { syntax_pos::GLOBALS.with(|syntax_pos_globals| { // The main handler runs for each Rayon worker thread and sets up // the thread local rustc uses. syntax_globals and syntax_pos_globals are // captured and set on the new threads. ty::tls::with_thread_locals sets up // thread local callbacks from libsyntax let main_handler = move |thread: ThreadBuilder| { syntax::GLOBALS.set(syntax_globals, || { syntax_pos::GLOBALS.set(syntax_pos_globals, || { if let Some(stderr) = stderr { io::set_panic(Some(box Sink(stderr.clone()))); } ty::tls::with_thread_locals(|| { ty::tls::GCX_PTR.set(gcx_ptr, || thread.run()) }) }) }) }; config.build_scoped(main_handler, with_pool).unwrap() }) }) }) } fn load_backend_from_dylib(path: &Path) -> fn() -> Box { let lib = DynamicLibrary::open(Some(path)).unwrap_or_else(|err| { let err = format!("couldn't load codegen backend {:?}: {:?}", path, err); early_error(ErrorOutputType::default(), &err); }); unsafe { match lib.symbol("__rustc_codegen_backend") { Ok(f) => { mem::forget(lib); mem::transmute::<*mut u8, _>(f) } Err(e) => { let err = format!("couldn't load codegen backend as it \ doesn't export the `__rustc_codegen_backend` \ symbol: {:?}", e); early_error(ErrorOutputType::default(), &err); } } } } pub fn get_codegen_backend(sess: &Session) -> Box { static INIT: Once = Once::new(); static mut LOAD: fn() -> Box = || unreachable!(); INIT.call_once(|| { let codegen_name = sess.opts.debugging_opts.codegen_backend.as_ref() .unwrap_or(&sess.target.target.options.codegen_backend); let backend = match &codegen_name[..] { filename if filename.contains(".") => { load_backend_from_dylib(filename.as_ref()) } codegen_name => get_codegen_sysroot(codegen_name), }; unsafe { LOAD = backend; } }); let backend = unsafe { LOAD() }; backend.init(sess); backend } // This is used for rustdoc, but it uses similar machinery to codegen backend // loading, so we leave the code here. It is potentially useful for other tools // that want to invoke the rustc binary while linking to rustc as well. pub fn rustc_path<'a>() -> Option<&'a Path> { static RUSTC_PATH: once_cell::sync::OnceCell> = once_cell::sync::OnceCell::new(); const BIN_PATH: &str = env!("RUSTC_INSTALL_BINDIR"); RUSTC_PATH.get_or_init(|| get_rustc_path_inner(BIN_PATH)).as_ref().map(|v| &**v) } fn get_rustc_path_inner(bin_path: &str) -> Option { sysroot_candidates().iter() .filter_map(|sysroot| { let candidate = sysroot.join(bin_path).join(if cfg!(target_os = "windows") { "rustc.exe" } else { "rustc" }); if candidate.exists() { Some(candidate) } else { None } }) .next() } fn sysroot_candidates() -> Vec { let target = session::config::host_triple(); let mut sysroot_candidates = vec![filesearch::get_or_default_sysroot()]; let path = current_dll_path().and_then(|s| s.canonicalize().ok()); if let Some(dll) = path { // use `parent` twice to chop off the file name and then also the // directory containing the dll which should be either `lib` or `bin`. if let Some(path) = dll.parent().and_then(|p| p.parent()) { // The original `path` pointed at the `rustc_driver` crate's dll. // Now that dll should only be in one of two locations. The first is // in the compiler's libdir, for example `$sysroot/lib/*.dll`. The // other is the target's libdir, for example // `$sysroot/lib/rustlib/$target/lib/*.dll`. // // We don't know which, so let's assume that if our `path` above // ends in `$target` we *could* be in the target libdir, and always // assume that we may be in the main libdir. sysroot_candidates.push(path.to_owned()); if path.ends_with(target) { sysroot_candidates.extend(path.parent() // chop off `$target` .and_then(|p| p.parent()) // chop off `rustlib` .and_then(|p| p.parent()) // chop off `lib` .map(|s| s.to_owned())); } } } return sysroot_candidates; #[cfg(unix)] fn current_dll_path() -> Option { use std::ffi::{OsStr, CStr}; use std::os::unix::prelude::*; unsafe { let addr = current_dll_path as usize as *mut _; let mut info = mem::zeroed(); if libc::dladdr(addr, &mut info) == 0 { info!("dladdr failed"); return None } if info.dli_fname.is_null() { info!("dladdr returned null pointer"); return None } let bytes = CStr::from_ptr(info.dli_fname).to_bytes(); let os = OsStr::from_bytes(bytes); Some(PathBuf::from(os)) } } #[cfg(windows)] fn current_dll_path() -> Option { use std::ffi::OsString; use std::os::windows::prelude::*; extern "system" { fn GetModuleHandleExW(dwFlags: u32, lpModuleName: usize, phModule: *mut usize) -> i32; fn GetModuleFileNameW(hModule: usize, lpFilename: *mut u16, nSize: u32) -> u32; } const GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS: u32 = 0x00000004; unsafe { let mut module = 0; let r = GetModuleHandleExW(GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS, current_dll_path as usize, &mut module); if r == 0 { info!("GetModuleHandleExW failed: {}", io::Error::last_os_error()); return None } let mut space = Vec::with_capacity(1024); let r = GetModuleFileNameW(module, space.as_mut_ptr(), space.capacity() as u32); if r == 0 { info!("GetModuleFileNameW failed: {}", io::Error::last_os_error()); return None } let r = r as usize; if r >= space.capacity() { info!("our buffer was too small? {}", io::Error::last_os_error()); return None } space.set_len(r); let os = OsString::from_wide(&space); Some(PathBuf::from(os)) } } } pub fn get_codegen_sysroot(backend_name: &str) -> fn() -> Box { // For now we only allow this function to be called once as it'll dlopen a // few things, which seems to work best if we only do that once. In // general this assertion never trips due to the once guard in `get_codegen_backend`, // but there's a few manual calls to this function in this file we protect // against. static LOADED: AtomicBool = AtomicBool::new(false); assert!(!LOADED.fetch_or(true, Ordering::SeqCst), "cannot load the default codegen backend twice"); let target = session::config::host_triple(); let sysroot_candidates = sysroot_candidates(); let sysroot = sysroot_candidates.iter() .map(|sysroot| { let libdir = filesearch::relative_target_lib_path(&sysroot, &target); sysroot.join(libdir).with_file_name( option_env!("CFG_CODEGEN_BACKENDS_DIR").unwrap_or("codegen-backends")) }) .filter(|f| { info!("codegen backend candidate: {}", f.display()); f.exists() }) .next(); let sysroot = sysroot.unwrap_or_else(|| { let candidates = sysroot_candidates.iter() .map(|p| p.display().to_string()) .collect::>() .join("\n* "); let err = format!("failed to find a `codegen-backends` folder \ in the sysroot candidates:\n* {}", candidates); early_error(ErrorOutputType::default(), &err); }); info!("probing {} for a codegen backend", sysroot.display()); let d = sysroot.read_dir().unwrap_or_else(|e| { let err = format!("failed to load default codegen backend, couldn't \ read `{}`: {}", sysroot.display(), e); early_error(ErrorOutputType::default(), &err); }); let mut file: Option = None; let expected_name = format!("rustc_codegen_llvm-{}", backend_name); for entry in d.filter_map(|e| e.ok()) { let path = entry.path(); let filename = match path.file_name().and_then(|s| s.to_str()) { Some(s) => s, None => continue, }; if !(filename.starts_with(DLL_PREFIX) && filename.ends_with(DLL_SUFFIX)) { continue } let name = &filename[DLL_PREFIX.len() .. filename.len() - DLL_SUFFIX.len()]; if name != expected_name { continue } if let Some(ref prev) = file { let err = format!("duplicate codegen backends found\n\ first: {}\n\ second: {}\n\ ", prev.display(), path.display()); early_error(ErrorOutputType::default(), &err); } file = Some(path.clone()); } match file { Some(ref s) => return load_backend_from_dylib(s), None => { let err = format!("failed to load default codegen backend for `{}`, \ no appropriate codegen dylib found in `{}`", backend_name, sysroot.display()); early_error(ErrorOutputType::default(), &err); } } } pub(crate) fn compute_crate_disambiguator(session: &Session) -> CrateDisambiguator { use std::hash::Hasher; // The crate_disambiguator is a 128 bit hash. The disambiguator is fed // into various other hashes quite a bit (symbol hashes, incr. comp. hashes, // debuginfo type IDs, etc), so we don't want it to be too wide. 128 bits // should still be safe enough to avoid collisions in practice. let mut hasher = StableHasher::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.write(b"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.write_usize(s.len()); hasher.write(s.as_bytes()); } // Also incorporate crate type, so that we don't get symbol conflicts when // linking against a library of the same name, if this is an executable. let is_exe = session .crate_types .borrow() .contains(&config::CrateType::Executable); hasher.write(if is_exe { b"exe" } else { b"lib" }); CrateDisambiguator::from(hasher.finish::()) } 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(sym::crate_type) { match a.value_str() { Some(sym::rlib) => Some(config::CrateType::Rlib), Some(sym::dylib) => Some(config::CrateType::Dylib), Some(sym::cdylib) => Some(config::CrateType::Cdylib), Some(sym::lib) => Some(config::default_lib_output()), Some(sym::staticlib) => Some(config::CrateType::Staticlib), Some(sym::proc_dash_macro) => Some(config::CrateType::ProcMacro), Some(sym::bin) => Some(config::CrateType::Executable), Some(n) => { let crate_types = vec![ sym::rlib, sym::dylib, sym::cdylib, sym::lib, sym::staticlib, sym::proc_dash_macro, sym::bin ]; if let ast::MetaItemKind::NameValue(spanned) = a.meta().unwrap().kind { let span = spanned.span; let lev_candidate = find_best_match_for_name( crate_types.iter(), &n.as_str(), None ); if let Some(candidate) = lev_candidate { session.buffer_lint_with_diagnostic( lint::builtin::UNKNOWN_CRATE_TYPES, ast::CRATE_NODE_ID, span, "invalid `crate_type` value", lint::builtin::BuiltinLintDiagnostics:: UnknownCrateTypes( span, "did you mean".to_string(), format!("\"{}\"", candidate) ) ); } else { session.buffer_lint( lint::builtin::UNKNOWN_CRATE_TYPES, ast::CRATE_NODE_ID, span, "invalid `crate_type` value" ); } } None } None => 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::CrateType::Executable]; } // 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(::rustc_codegen_utils::link::default_output_for_target( session, )); } else { base.sort(); base.dedup(); } } base.retain(|crate_type| { let res = !::rustc_codegen_utils::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 }); base } 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 = (*odir).as_ref().cloned().unwrap_or_default(); // 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_else(|| input.filestem().to_owned()); 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( "due to multiple output types requested, the explicitly specified \ output file name will be adapted for each output type", ); None } else { if !sess.opts.cg.extra_filename.is_empty() { sess.warn("ignoring -C extra-filename flag due to -o flag"); } Some(out_file.clone()) }; if *odir != None { sess.warn("ignoring --out-dir flag due to -o flag"); } OutputFilenames { out_directory: out_file.parent().unwrap_or_else(|| Path::new("")).to_path_buf(), out_filestem: out_file .file_stem() .unwrap_or_default() .to_str() .unwrap() .to_string(), single_output_file: ofile, extra: sess.opts.cg.extra_filename.clone(), outputs: sess.opts.output_types.clone(), } } } } // Note: Also used by librustdoc, see PR #43348. Consider moving this struct elsewhere. // // FIXME: Currently the `everybody_loops` transformation is not applied to: // * `const fn`, due to issue #43636 that `loop` is not supported for const evaluation. We are // waiting for miri to fix that. // * `impl Trait`, due to issue #43869 that functions returning impl Trait cannot be diverging. // Solving this may require `!` to implement every trait, which relies on the an even more // ambitious form of the closed RFC #1637. See also [#34511]. // // [#34511]: https://github.com/rust-lang/rust/issues/34511#issuecomment-322340401 pub struct ReplaceBodyWithLoop<'a> { within_static_or_const: bool, nested_blocks: Option>, sess: &'a Session, } impl<'a> ReplaceBodyWithLoop<'a> { pub fn new(sess: &'a Session) -> ReplaceBodyWithLoop<'a> { ReplaceBodyWithLoop { within_static_or_const: false, nested_blocks: None, sess } } fn run R>(&mut self, is_const: bool, action: F) -> R { let old_const = mem::replace(&mut self.within_static_or_const, is_const); let old_blocks = self.nested_blocks.take(); let ret = action(self); self.within_static_or_const = old_const; self.nested_blocks = old_blocks; ret } fn should_ignore_fn(ret_ty: &ast::FnDecl) -> bool { if let ast::FunctionRetTy::Ty(ref ty) = ret_ty.output { fn involves_impl_trait(ty: &ast::Ty) -> bool { match ty.kind { ast::TyKind::ImplTrait(..) => true, ast::TyKind::Slice(ref subty) | ast::TyKind::Array(ref subty, _) | ast::TyKind::Ptr(ast::MutTy { ty: ref subty, .. }) | ast::TyKind::Rptr(_, ast::MutTy { ty: ref subty, .. }) | ast::TyKind::Paren(ref subty) => involves_impl_trait(subty), ast::TyKind::Tup(ref tys) => any_involves_impl_trait(tys.iter()), ast::TyKind::Path(_, ref path) => path.segments.iter().any(|seg| { match seg.args.as_ref().map(|generic_arg| &**generic_arg) { None => false, Some(&ast::GenericArgs::AngleBracketed(ref data)) => { let types = data.args.iter().filter_map(|arg| match arg { ast::GenericArg::Type(ty) => Some(ty), _ => None, }); any_involves_impl_trait(types.into_iter()) || data.constraints.iter().any(|c| { match c.kind { ast::AssocTyConstraintKind::Bound { .. } => true, ast::AssocTyConstraintKind::Equality { ref ty } => involves_impl_trait(ty), } }) }, Some(&ast::GenericArgs::Parenthesized(ref data)) => { any_involves_impl_trait(data.inputs.iter()) || any_involves_impl_trait(data.output.iter()) } } }), _ => false, } } fn any_involves_impl_trait<'a, I: Iterator>>(mut it: I) -> bool { it.any(|subty| involves_impl_trait(subty)) } involves_impl_trait(ty) } else { false } } } impl<'a> MutVisitor for ReplaceBodyWithLoop<'a> { fn visit_item_kind(&mut self, i: &mut ast::ItemKind) { let is_const = match i { ast::ItemKind::Static(..) | ast::ItemKind::Const(..) => true, ast::ItemKind::Fn(ref decl, ref header, _, _) => header.constness.node == ast::Constness::Const || Self::should_ignore_fn(decl), _ => false, }; self.run(is_const, |s| noop_visit_item_kind(i, s)) } fn flat_map_trait_item(&mut self, i: ast::TraitItem) -> SmallVec<[ast::TraitItem; 1]> { let is_const = match i.kind { ast::TraitItemKind::Const(..) => true, ast::TraitItemKind::Method(ast::MethodSig { ref decl, ref header, .. }, _) => header.constness.node == ast::Constness::Const || Self::should_ignore_fn(decl), _ => false, }; self.run(is_const, |s| noop_flat_map_trait_item(i, s)) } fn flat_map_impl_item(&mut self, i: ast::ImplItem) -> SmallVec<[ast::ImplItem; 1]> { let is_const = match i.kind { ast::ImplItemKind::Const(..) => true, ast::ImplItemKind::Method(ast::MethodSig { ref decl, ref header, .. }, _) => header.constness.node == ast::Constness::Const || Self::should_ignore_fn(decl), _ => false, }; self.run(is_const, |s| noop_flat_map_impl_item(i, s)) } fn visit_anon_const(&mut self, c: &mut ast::AnonConst) { self.run(true, |s| noop_visit_anon_const(c, s)) } fn visit_block(&mut self, b: &mut P) { fn stmt_to_block(rules: ast::BlockCheckMode, s: Option, sess: &Session) -> ast::Block { ast::Block { stmts: s.into_iter().collect(), rules, id: sess.next_node_id(), span: syntax_pos::DUMMY_SP, } } fn block_to_stmt(b: ast::Block, sess: &Session) -> ast::Stmt { let expr = P(ast::Expr { id: sess.next_node_id(), kind: ast::ExprKind::Block(P(b), None), span: syntax_pos::DUMMY_SP, attrs: ThinVec::new(), }); ast::Stmt { id: sess.next_node_id(), kind: ast::StmtKind::Expr(expr), span: syntax_pos::DUMMY_SP, } } let empty_block = stmt_to_block(BlockCheckMode::Default, None, self.sess); let loop_expr = P(ast::Expr { kind: ast::ExprKind::Loop(P(empty_block), None), id: self.sess.next_node_id(), span: syntax_pos::DUMMY_SP, attrs: ThinVec::new(), }); let loop_stmt = ast::Stmt { id: self.sess.next_node_id(), span: syntax_pos::DUMMY_SP, kind: ast::StmtKind::Expr(loop_expr), }; if self.within_static_or_const { noop_visit_block(b, self) } else { visit_clobber(b.deref_mut(), |b| { let mut stmts = vec![]; for s in b.stmts { let old_blocks = self.nested_blocks.replace(vec![]); stmts.extend(self.flat_map_stmt(s).into_iter().filter(|s| s.is_item())); // we put a Some in there earlier with that replace(), so this is valid let new_blocks = self.nested_blocks.take().unwrap(); self.nested_blocks = old_blocks; stmts.extend(new_blocks.into_iter().map(|b| block_to_stmt(b, &self.sess))); } let mut new_block = ast::Block { stmts, ..b }; if let Some(old_blocks) = self.nested_blocks.as_mut() { //push our fresh block onto the cache and yield an empty block with `loop {}` if !new_block.stmts.is_empty() { old_blocks.push(new_block); } stmt_to_block(b.rules, Some(loop_stmt), self.sess) } else { //push `loop {}` onto the end of our fresh block and yield that new_block.stmts.push(loop_stmt); new_block } }) } } // in general the pretty printer processes unexpanded code, so // we override the default `visit_mac` method which panics. fn visit_mac(&mut self, mac: &mut ast::Mac) { noop_visit_mac(mac, self) } }