use crate::mir::interpret::{AllocRange, ConstValue, GlobalAlloc, Pointer, Provenance, Scalar}; use crate::ty::subst::{GenericArg, GenericArgKind, Subst}; use crate::ty::{self, ConstInt, DefIdTree, ParamConst, ScalarInt, Ty, TyCtxt, TypeFoldable}; use rustc_apfloat::ieee::{Double, Single}; use rustc_data_structures::fx::FxHashMap; use rustc_data_structures::sso::SsoHashSet; use rustc_hir as hir; use rustc_hir::def::{self, CtorKind, DefKind, Namespace}; use rustc_hir::def_id::{DefId, DefIdSet, CRATE_DEF_INDEX, LOCAL_CRATE}; use rustc_hir::definitions::{DefPathData, DefPathDataName, DisambiguatedDefPathData}; use rustc_hir::ItemKind; use rustc_session::config::TrimmedDefPaths; use rustc_session::cstore::{ExternCrate, ExternCrateSource}; use rustc_span::symbol::{kw, Ident, Symbol}; use rustc_target::abi::Size; use rustc_target::spec::abi::Abi; use std::cell::Cell; use std::char; use std::collections::BTreeMap; use std::convert::TryFrom; use std::fmt::{self, Write as _}; use std::iter; use std::ops::{ControlFlow, Deref, DerefMut}; // `pretty` is a separate module only for organization. use super::*; macro_rules! p { (@$lit:literal) => { write!(scoped_cx!(), $lit)? }; (@write($($data:expr),+)) => { write!(scoped_cx!(), $($data),+)? }; (@print($x:expr)) => { scoped_cx!() = $x.print(scoped_cx!())? }; (@$method:ident($($arg:expr),*)) => { scoped_cx!() = scoped_cx!().$method($($arg),*)? }; ($($elem:tt $(($($args:tt)*))?),+) => {{ $(p!(@ $elem $(($($args)*))?);)+ }}; } macro_rules! define_scoped_cx { ($cx:ident) => { #[allow(unused_macros)] macro_rules! scoped_cx { () => { $cx }; } }; } thread_local! { static FORCE_IMPL_FILENAME_LINE: Cell = const { Cell::new(false) }; static SHOULD_PREFIX_WITH_CRATE: Cell = const { Cell::new(false) }; static NO_TRIMMED_PATH: Cell = const { Cell::new(false) }; static NO_QUERIES: Cell = const { Cell::new(false) }; static NO_VISIBLE_PATH: Cell = const { Cell::new(false) }; } /// Avoids running any queries during any prints that occur /// during the closure. This may alter the appearance of some /// types (e.g. forcing verbose printing for opaque types). /// This method is used during some queries (e.g. `explicit_item_bounds` /// for opaque types), to ensure that any debug printing that /// occurs during the query computation does not end up recursively /// calling the same query. pub fn with_no_queries R, R>(f: F) -> R { NO_QUERIES.with(|no_queries| { let old = no_queries.replace(true); let result = f(); no_queries.set(old); result }) } /// Force us to name impls with just the filename/line number. We /// normally try to use types. But at some points, notably while printing /// cycle errors, this can result in extra or suboptimal error output, /// so this variable disables that check. pub fn with_forced_impl_filename_line R, R>(f: F) -> R { FORCE_IMPL_FILENAME_LINE.with(|force| { let old = force.replace(true); let result = f(); force.set(old); result }) } /// Adds the `crate::` prefix to paths where appropriate. pub fn with_crate_prefix R, R>(f: F) -> R { SHOULD_PREFIX_WITH_CRATE.with(|flag| { let old = flag.replace(true); let result = f(); flag.set(old); result }) } /// Prevent path trimming if it is turned on. Path trimming affects `Display` impl /// of various rustc types, for example `std::vec::Vec` would be trimmed to `Vec`, /// if no other `Vec` is found. pub fn with_no_trimmed_paths R, R>(f: F) -> R { NO_TRIMMED_PATH.with(|flag| { let old = flag.replace(true); let result = f(); flag.set(old); result }) } /// Prevent selection of visible paths. `Display` impl of DefId will prefer visible (public) reexports of types as paths. pub fn with_no_visible_paths R, R>(f: F) -> R { NO_VISIBLE_PATH.with(|flag| { let old = flag.replace(true); let result = f(); flag.set(old); result }) } /// The "region highlights" are used to control region printing during /// specific error messages. When a "region highlight" is enabled, it /// gives an alternate way to print specific regions. For now, we /// always print those regions using a number, so something like "`'0`". /// /// Regions not selected by the region highlight mode are presently /// unaffected. #[derive(Copy, Clone, Default)] pub struct RegionHighlightMode { /// If enabled, when we see the selected region, use "`'N`" /// instead of the ordinary behavior. highlight_regions: [Option<(ty::RegionKind, usize)>; 3], /// If enabled, when printing a "free region" that originated from /// the given `ty::BoundRegionKind`, print it as "`'1`". Free regions that would ordinarily /// have names print as normal. /// /// This is used when you have a signature like `fn foo(x: &u32, /// y: &'a u32)` and we want to give a name to the region of the /// reference `x`. highlight_bound_region: Option<(ty::BoundRegionKind, usize)>, } impl RegionHighlightMode { /// If `region` and `number` are both `Some`, invokes /// `highlighting_region`. pub fn maybe_highlighting_region( &mut self, region: Option>, number: Option, ) { if let Some(k) = region { if let Some(n) = number { self.highlighting_region(k, n); } } } /// Highlights the region inference variable `vid` as `'N`. pub fn highlighting_region(&mut self, region: ty::Region<'_>, number: usize) { let num_slots = self.highlight_regions.len(); let first_avail_slot = self.highlight_regions.iter_mut().find(|s| s.is_none()).unwrap_or_else(|| { bug!("can only highlight {} placeholders at a time", num_slots,) }); *first_avail_slot = Some((*region, number)); } /// Convenience wrapper for `highlighting_region`. pub fn highlighting_region_vid(&mut self, vid: ty::RegionVid, number: usize) { self.highlighting_region(&ty::ReVar(vid), number) } /// Returns `Some(n)` with the number to use for the given region, if any. fn region_highlighted(&self, region: ty::Region<'_>) -> Option { self.highlight_regions.iter().find_map(|h| match h { Some((r, n)) if r == region => Some(*n), _ => None, }) } /// Highlight the given bound region. /// We can only highlight one bound region at a time. See /// the field `highlight_bound_region` for more detailed notes. pub fn highlighting_bound_region(&mut self, br: ty::BoundRegionKind, number: usize) { assert!(self.highlight_bound_region.is_none()); self.highlight_bound_region = Some((br, number)); } } /// Trait for printers that pretty-print using `fmt::Write` to the printer. pub trait PrettyPrinter<'tcx>: Printer< 'tcx, Error = fmt::Error, Path = Self, Region = Self, Type = Self, DynExistential = Self, Const = Self, > + fmt::Write { /// Like `print_def_path` but for value paths. fn print_value_path( self, def_id: DefId, substs: &'tcx [GenericArg<'tcx>], ) -> Result { self.print_def_path(def_id, substs) } fn in_binder(self, value: &ty::Binder<'tcx, T>) -> Result where T: Print<'tcx, Self, Output = Self, Error = Self::Error> + TypeFoldable<'tcx>, { value.as_ref().skip_binder().print(self) } fn wrap_binder Result>( self, value: &ty::Binder<'tcx, T>, f: F, ) -> Result where T: Print<'tcx, Self, Output = Self, Error = Self::Error> + TypeFoldable<'tcx>, { f(value.as_ref().skip_binder(), self) } /// Prints comma-separated elements. fn comma_sep(mut self, mut elems: impl Iterator) -> Result where T: Print<'tcx, Self, Output = Self, Error = Self::Error>, { if let Some(first) = elems.next() { self = first.print(self)?; for elem in elems { self.write_str(", ")?; self = elem.print(self)?; } } Ok(self) } /// Prints `{f: t}` or `{f as t}` depending on the `cast` argument fn typed_value( mut self, f: impl FnOnce(Self) -> Result, t: impl FnOnce(Self) -> Result, conversion: &str, ) -> Result { self.write_str("{")?; self = f(self)?; self.write_str(conversion)?; self = t(self)?; self.write_str("}")?; Ok(self) } /// Prints `<...>` around what `f` prints. fn generic_delimiters( self, f: impl FnOnce(Self) -> Result, ) -> Result; /// Returns `true` if the region should be printed in /// optional positions, e.g., `&'a T` or `dyn Tr + 'b`. /// This is typically the case for all non-`'_` regions. fn region_should_not_be_omitted(&self, region: ty::Region<'_>) -> bool; // Defaults (should not be overridden): /// If possible, this returns a global path resolving to `def_id` that is visible /// from at least one local module, and returns `true`. If the crate defining `def_id` is /// declared with an `extern crate`, the path is guaranteed to use the `extern crate`. fn try_print_visible_def_path(self, def_id: DefId) -> Result<(Self, bool), Self::Error> { if NO_VISIBLE_PATH.with(|flag| flag.get()) { return Ok((self, false)); } let mut callers = Vec::new(); self.try_print_visible_def_path_recur(def_id, &mut callers) } /// Try to see if this path can be trimmed to a unique symbol name. fn try_print_trimmed_def_path( mut self, def_id: DefId, ) -> Result<(Self::Path, bool), Self::Error> { if !self.tcx().sess.opts.debugging_opts.trim_diagnostic_paths || matches!(self.tcx().sess.opts.trimmed_def_paths, TrimmedDefPaths::Never) || NO_TRIMMED_PATH.with(|flag| flag.get()) || SHOULD_PREFIX_WITH_CRATE.with(|flag| flag.get()) { return Ok((self, false)); } match self.tcx().trimmed_def_paths(()).get(&def_id) { None => Ok((self, false)), Some(symbol) => { self.write_str(&symbol.as_str())?; Ok((self, true)) } } } /// Does the work of `try_print_visible_def_path`, building the /// full definition path recursively before attempting to /// post-process it into the valid and visible version that /// accounts for re-exports. /// /// This method should only be called by itself or /// `try_print_visible_def_path`. /// /// `callers` is a chain of visible_parent's leading to `def_id`, /// to support cycle detection during recursion. fn try_print_visible_def_path_recur( mut self, def_id: DefId, callers: &mut Vec, ) -> Result<(Self, bool), Self::Error> { define_scoped_cx!(self); debug!("try_print_visible_def_path: def_id={:?}", def_id); // If `def_id` is a direct or injected extern crate, return the // path to the crate followed by the path to the item within the crate. if def_id.index == CRATE_DEF_INDEX { let cnum = def_id.krate; if cnum == LOCAL_CRATE { return Ok((self.path_crate(cnum)?, true)); } // In local mode, when we encounter a crate other than // LOCAL_CRATE, execution proceeds in one of two ways: // // 1. For a direct dependency, where user added an // `extern crate` manually, we put the `extern // crate` as the parent. So you wind up with // something relative to the current crate. // 2. For an extern inferred from a path or an indirect crate, // where there is no explicit `extern crate`, we just prepend // the crate name. match self.tcx().extern_crate(def_id) { Some(&ExternCrate { src, dependency_of, span, .. }) => match (src, dependency_of) { (ExternCrateSource::Extern(def_id), LOCAL_CRATE) => { debug!("try_print_visible_def_path: def_id={:?}", def_id); return Ok(( if !span.is_dummy() { self.print_def_path(def_id, &[])? } else { self.path_crate(cnum)? }, true, )); } (ExternCrateSource::Path, LOCAL_CRATE) => { debug!("try_print_visible_def_path: def_id={:?}", def_id); return Ok((self.path_crate(cnum)?, true)); } _ => {} }, None => { return Ok((self.path_crate(cnum)?, true)); } } } if def_id.is_local() { return Ok((self, false)); } let visible_parent_map = self.tcx().visible_parent_map(()); let mut cur_def_key = self.tcx().def_key(def_id); debug!("try_print_visible_def_path: cur_def_key={:?}", cur_def_key); // For a constructor, we want the name of its parent rather than . if let DefPathData::Ctor = cur_def_key.disambiguated_data.data { let parent = DefId { krate: def_id.krate, index: cur_def_key .parent .expect("`DefPathData::Ctor` / `VariantData` missing a parent"), }; cur_def_key = self.tcx().def_key(parent); } let visible_parent = match visible_parent_map.get(&def_id).cloned() { Some(parent) => parent, None => return Ok((self, false)), }; if callers.contains(&visible_parent) { return Ok((self, false)); } callers.push(visible_parent); // HACK(eddyb) this bypasses `path_append`'s prefix printing to avoid // knowing ahead of time whether the entire path will succeed or not. // To support printers that do not implement `PrettyPrinter`, a `Vec` or // linked list on the stack would need to be built, before any printing. match self.try_print_visible_def_path_recur(visible_parent, callers)? { (cx, false) => return Ok((cx, false)), (cx, true) => self = cx, } callers.pop(); let actual_parent = self.tcx().parent(def_id); debug!( "try_print_visible_def_path: visible_parent={:?} actual_parent={:?}", visible_parent, actual_parent, ); let mut data = cur_def_key.disambiguated_data.data; debug!( "try_print_visible_def_path: data={:?} visible_parent={:?} actual_parent={:?}", data, visible_parent, actual_parent, ); match data { // In order to output a path that could actually be imported (valid and visible), // we need to handle re-exports correctly. // // For example, take `std::os::unix::process::CommandExt`, this trait is actually // defined at `std::sys::unix::ext::process::CommandExt` (at time of writing). // // `std::os::unix` rexports the contents of `std::sys::unix::ext`. `std::sys` is // private so the "true" path to `CommandExt` isn't accessible. // // In this case, the `visible_parent_map` will look something like this: // // (child) -> (parent) // `std::sys::unix::ext::process::CommandExt` -> `std::sys::unix::ext::process` // `std::sys::unix::ext::process` -> `std::sys::unix::ext` // `std::sys::unix::ext` -> `std::os` // // This is correct, as the visible parent of `std::sys::unix::ext` is in fact // `std::os`. // // When printing the path to `CommandExt` and looking at the `cur_def_key` that // corresponds to `std::sys::unix::ext`, we would normally print `ext` and then go // to the parent - resulting in a mangled path like // `std::os::ext::process::CommandExt`. // // Instead, we must detect that there was a re-export and instead print `unix` // (which is the name `std::sys::unix::ext` was re-exported as in `std::os`). To // do this, we compare the parent of `std::sys::unix::ext` (`std::sys::unix`) with // the visible parent (`std::os`). If these do not match, then we iterate over // the children of the visible parent (as was done when computing // `visible_parent_map`), looking for the specific child we currently have and then // have access to the re-exported name. DefPathData::TypeNs(ref mut name) if Some(visible_parent) != actual_parent => { let reexport = self .tcx() .item_children(visible_parent) .iter() .find(|child| child.res.opt_def_id() == Some(def_id)) .map(|child| child.ident.name); if let Some(reexport) = reexport { *name = reexport; } } // Re-exported `extern crate` (#43189). DefPathData::CrateRoot => { data = DefPathData::TypeNs(self.tcx().crate_name(def_id.krate)); } _ => {} } debug!("try_print_visible_def_path: data={:?}", data); Ok((self.path_append(Ok, &DisambiguatedDefPathData { data, disambiguator: 0 })?, true)) } fn pretty_path_qualified( self, self_ty: Ty<'tcx>, trait_ref: Option>, ) -> Result { if trait_ref.is_none() { // Inherent impls. Try to print `Foo::bar` for an inherent // impl on `Foo`, but fallback to `::bar` if self-type is // anything other than a simple path. match self_ty.kind() { ty::Adt(..) | ty::Foreign(_) | ty::Bool | ty::Char | ty::Str | ty::Int(_) | ty::Uint(_) | ty::Float(_) => { return self_ty.print(self); } _ => {} } } self.generic_delimiters(|mut cx| { define_scoped_cx!(cx); p!(print(self_ty)); if let Some(trait_ref) = trait_ref { p!(" as ", print(trait_ref.print_only_trait_path())); } Ok(cx) }) } fn pretty_path_append_impl( mut self, print_prefix: impl FnOnce(Self) -> Result, self_ty: Ty<'tcx>, trait_ref: Option>, ) -> Result { self = print_prefix(self)?; self.generic_delimiters(|mut cx| { define_scoped_cx!(cx); p!("impl "); if let Some(trait_ref) = trait_ref { p!(print(trait_ref.print_only_trait_path()), " for "); } p!(print(self_ty)); Ok(cx) }) } fn pretty_print_type(mut self, ty: Ty<'tcx>) -> Result { define_scoped_cx!(self); match *ty.kind() { ty::Bool => p!("bool"), ty::Char => p!("char"), ty::Int(t) => p!(write("{}", t.name_str())), ty::Uint(t) => p!(write("{}", t.name_str())), ty::Float(t) => p!(write("{}", t.name_str())), ty::RawPtr(ref tm) => { p!(write( "*{} ", match tm.mutbl { hir::Mutability::Mut => "mut", hir::Mutability::Not => "const", } )); p!(print(tm.ty)) } ty::Ref(r, ty, mutbl) => { p!("&"); if self.region_should_not_be_omitted(r) { p!(print(r), " "); } p!(print(ty::TypeAndMut { ty, mutbl })) } ty::Never => p!("!"), ty::Tuple(ref tys) => { p!("(", comma_sep(tys.iter())); if tys.len() == 1 { p!(","); } p!(")") } ty::FnDef(def_id, substs) => { let sig = self.tcx().fn_sig(def_id).subst(self.tcx(), substs); p!(print(sig), " {{", print_value_path(def_id, substs), "}}"); } ty::FnPtr(ref bare_fn) => p!(print(bare_fn)), ty::Infer(infer_ty) => { let verbose = self.tcx().sess.verbose(); if let ty::TyVar(ty_vid) = infer_ty { if let Some(name) = self.infer_ty_name(ty_vid) { p!(write("{}", name)) } else { if verbose { p!(write("{:?}", infer_ty)) } else { p!(write("{}", infer_ty)) } } } else { if verbose { p!(write("{:?}", infer_ty)) } else { p!(write("{}", infer_ty)) } } } ty::Error(_) => p!("[type error]"), ty::Param(ref param_ty) => p!(write("{}", param_ty)), ty::Bound(debruijn, bound_ty) => match bound_ty.kind { ty::BoundTyKind::Anon => self.pretty_print_bound_var(debruijn, bound_ty.var)?, ty::BoundTyKind::Param(p) => p!(write("{}", p)), }, ty::Adt(def, substs) => { p!(print_def_path(def.did, substs)); } ty::Dynamic(data, r) => { let print_r = self.region_should_not_be_omitted(r); if print_r { p!("("); } p!("dyn ", print(data)); if print_r { p!(" + ", print(r), ")"); } } ty::Foreign(def_id) => { p!(print_def_path(def_id, &[])); } ty::Projection(ref data) => p!(print(data)), ty::Placeholder(placeholder) => p!(write("Placeholder({:?})", placeholder)), ty::Opaque(def_id, substs) => { // FIXME(eddyb) print this with `print_def_path`. // We use verbose printing in 'NO_QUERIES' mode, to // avoid needing to call `predicates_of`. This should // only affect certain debug messages (e.g. messages printed // from `rustc_middle::ty` during the computation of `tcx.predicates_of`), // and should have no effect on any compiler output. if self.tcx().sess.verbose() || NO_QUERIES.with(|q| q.get()) { p!(write("Opaque({:?}, {:?})", def_id, substs)); return Ok(self); } return with_no_queries(|| { let def_key = self.tcx().def_key(def_id); if let Some(name) = def_key.disambiguated_data.data.get_opt_name() { p!(write("{}", name)); // FIXME(eddyb) print this with `print_def_path`. if !substs.is_empty() { p!("::"); p!(generic_delimiters(|cx| cx.comma_sep(substs.iter()))); } return Ok(self); } // Grab the "TraitA + TraitB" from `impl TraitA + TraitB`, // by looking up the projections associated with the def_id. let bounds = self.tcx().explicit_item_bounds(def_id); let mut first = true; let mut is_sized = false; p!("impl"); for (predicate, _) in bounds { let predicate = predicate.subst(self.tcx(), substs); let bound_predicate = predicate.kind(); if let ty::PredicateKind::Trait(pred) = bound_predicate.skip_binder() { let trait_ref = bound_predicate.rebind(pred.trait_ref); // Don't print +Sized, but rather +?Sized if absent. if Some(trait_ref.def_id()) == self.tcx().lang_items().sized_trait() { is_sized = true; continue; } p!( write("{}", if first { " " } else { "+" }), print(trait_ref.print_only_trait_path()) ); first = false; } } if !is_sized { p!(write("{}?Sized", if first { " " } else { "+" })); } else if first { p!(" Sized"); } Ok(self) }); } ty::Str => p!("str"), ty::Generator(did, substs, movability) => { p!(write("[")); match movability { hir::Movability::Movable => {} hir::Movability::Static => p!("static "), } if !self.tcx().sess.verbose() { p!("generator"); // FIXME(eddyb) should use `def_span`. if let Some(did) = did.as_local() { let hir_id = self.tcx().hir().local_def_id_to_hir_id(did); let span = self.tcx().hir().span(hir_id); p!(write( "@{}", // This may end up in stderr diagnostics but it may also be emitted // into MIR. Hence we use the remapped path if available self.tcx().sess.source_map().span_to_embeddable_string(span) )); } else { p!(write("@"), print_def_path(did, substs)); } } else { p!(print_def_path(did, substs)); p!(" upvar_tys=("); if !substs.as_generator().is_valid() { p!("unavailable"); } else { self = self.comma_sep(substs.as_generator().upvar_tys())?; } p!(")"); if substs.as_generator().is_valid() { p!(" ", print(substs.as_generator().witness())); } } p!("]") } ty::GeneratorWitness(types) => { p!(in_binder(&types)); } ty::Closure(did, substs) => { p!(write("[")); if !self.tcx().sess.verbose() { p!(write("closure")); // FIXME(eddyb) should use `def_span`. if let Some(did) = did.as_local() { let hir_id = self.tcx().hir().local_def_id_to_hir_id(did); if self.tcx().sess.opts.debugging_opts.span_free_formats { p!("@", print_def_path(did.to_def_id(), substs)); } else { let span = self.tcx().hir().span(hir_id); p!(write( "@{}", // This may end up in stderr diagnostics but it may also be emitted // into MIR. Hence we use the remapped path if available self.tcx().sess.source_map().span_to_embeddable_string(span) )); } } else { p!(write("@"), print_def_path(did, substs)); } } else { p!(print_def_path(did, substs)); if !substs.as_closure().is_valid() { p!(" closure_substs=(unavailable)"); } else { p!(" closure_kind_ty=", print(substs.as_closure().kind_ty())); p!( " closure_sig_as_fn_ptr_ty=", print(substs.as_closure().sig_as_fn_ptr_ty()) ); p!(" upvar_tys=("); self = self.comma_sep(substs.as_closure().upvar_tys())?; p!(")"); } } p!("]"); } ty::Array(ty, sz) => { p!("[", print(ty), "; "); if self.tcx().sess.verbose() { p!(write("{:?}", sz)); } else if let ty::ConstKind::Unevaluated(..) = sz.val { // Do not try to evaluate unevaluated constants. If we are const evaluating an // array length anon const, rustc will (with debug assertions) print the // constant's path. Which will end up here again. p!("_"); } else if let Some(n) = sz.val.try_to_bits(self.tcx().data_layout.pointer_size) { p!(write("{}", n)); } else if let ty::ConstKind::Param(param) = sz.val { p!(write("{}", param)); } else { p!("_"); } p!("]") } ty::Slice(ty) => p!("[", print(ty), "]"), } Ok(self) } fn pretty_print_bound_var( &mut self, debruijn: ty::DebruijnIndex, var: ty::BoundVar, ) -> Result<(), Self::Error> { if debruijn == ty::INNERMOST { write!(self, "^{}", var.index()) } else { write!(self, "^{}_{}", debruijn.index(), var.index()) } } fn infer_ty_name(&self, _: ty::TyVid) -> Option { None } fn pretty_print_dyn_existential( mut self, predicates: &'tcx ty::List>>, ) -> Result { // Generate the main trait ref, including associated types. let mut first = true; if let Some(principal) = predicates.principal() { self = self.wrap_binder(&principal, |principal, mut cx| { define_scoped_cx!(cx); p!(print_def_path(principal.def_id, &[])); let mut resugared = false; // Special-case `Fn(...) -> ...` and resugar it. let fn_trait_kind = cx.tcx().fn_trait_kind_from_lang_item(principal.def_id); if !cx.tcx().sess.verbose() && fn_trait_kind.is_some() { if let ty::Tuple(ref args) = principal.substs.type_at(0).kind() { let mut projections = predicates.projection_bounds(); if let (Some(proj), None) = (projections.next(), projections.next()) { let tys: Vec<_> = args.iter().map(|k| k.expect_ty()).collect(); p!(pretty_fn_sig(&tys, false, proj.skip_binder().ty)); resugared = true; } } } // HACK(eddyb) this duplicates `FmtPrinter`'s `path_generic_args`, // in order to place the projections inside the `<...>`. if !resugared { // Use a type that can't appear in defaults of type parameters. let dummy_cx = cx.tcx().mk_ty_infer(ty::FreshTy(0)); let principal = principal.with_self_ty(cx.tcx(), dummy_cx); let args = cx.generic_args_to_print( cx.tcx().generics_of(principal.def_id), principal.substs, ); // Don't print `'_` if there's no unerased regions. let print_regions = args.iter().any(|arg| match arg.unpack() { GenericArgKind::Lifetime(r) => *r != ty::ReErased, _ => false, }); let mut args = args.iter().cloned().filter(|arg| match arg.unpack() { GenericArgKind::Lifetime(_) => print_regions, _ => true, }); let mut projections = predicates.projection_bounds(); let arg0 = args.next(); let projection0 = projections.next(); if arg0.is_some() || projection0.is_some() { let args = arg0.into_iter().chain(args); let projections = projection0.into_iter().chain(projections); p!(generic_delimiters(|mut cx| { cx = cx.comma_sep(args)?; if arg0.is_some() && projection0.is_some() { write!(cx, ", ")?; } cx.comma_sep(projections) })); } } Ok(cx) })?; first = false; } define_scoped_cx!(self); // Builtin bounds. // FIXME(eddyb) avoid printing twice (needed to ensure // that the auto traits are sorted *and* printed via cx). let mut auto_traits: Vec<_> = predicates.auto_traits().map(|did| (self.tcx().def_path_str(did), did)).collect(); // The auto traits come ordered by `DefPathHash`. While // `DefPathHash` is *stable* in the sense that it depends on // neither the host nor the phase of the moon, it depends // "pseudorandomly" on the compiler version and the target. // // To avoid that causing instabilities in compiletest // output, sort the auto-traits alphabetically. auto_traits.sort(); for (_, def_id) in auto_traits { if !first { p!(" + "); } first = false; p!(print_def_path(def_id, &[])); } Ok(self) } fn pretty_fn_sig( mut self, inputs: &[Ty<'tcx>], c_variadic: bool, output: Ty<'tcx>, ) -> Result { define_scoped_cx!(self); p!("(", comma_sep(inputs.iter().copied())); if c_variadic { if !inputs.is_empty() { p!(", "); } p!("..."); } p!(")"); if !output.is_unit() { p!(" -> ", print(output)); } Ok(self) } fn pretty_print_const( mut self, ct: &'tcx ty::Const<'tcx>, print_ty: bool, ) -> Result { define_scoped_cx!(self); if self.tcx().sess.verbose() { p!(write("Const({:?}: {:?})", ct.val, ct.ty)); return Ok(self); } macro_rules! print_underscore { () => {{ if print_ty { self = self.typed_value( |mut this| { write!(this, "_")?; Ok(this) }, |this| this.print_type(ct.ty), ": ", )?; } else { write!(self, "_")?; } }}; } match ct.val { ty::ConstKind::Unevaluated(uv) => { if let Some(promoted) = uv.promoted { let substs = uv.substs_.unwrap(); p!(print_value_path(uv.def.did, substs)); p!(write("::{:?}", promoted)); } else { let tcx = self.tcx(); match tcx.def_kind(uv.def.did) { DefKind::Static | DefKind::Const | DefKind::AssocConst => { p!(print_value_path(uv.def.did, uv.substs(tcx))) } _ => { if uv.def.is_local() { let span = tcx.def_span(uv.def.did); if let Ok(snip) = tcx.sess.source_map().span_to_snippet(span) { p!(write("{}", snip)) } else { print_underscore!() } } else { print_underscore!() } } } } } ty::ConstKind::Infer(..) => print_underscore!(), ty::ConstKind::Param(ParamConst { name, .. }) => p!(write("{}", name)), ty::ConstKind::Value(value) => { return self.pretty_print_const_value(value, ct.ty, print_ty); } ty::ConstKind::Bound(debruijn, bound_var) => { self.pretty_print_bound_var(debruijn, bound_var)? } ty::ConstKind::Placeholder(placeholder) => p!(write("Placeholder({:?})", placeholder)), ty::ConstKind::Error(_) => p!("[const error]"), }; Ok(self) } fn pretty_print_const_scalar( self, scalar: Scalar, ty: Ty<'tcx>, print_ty: bool, ) -> Result { match scalar { Scalar::Ptr(ptr, _size) => self.pretty_print_const_scalar_ptr(ptr, ty, print_ty), Scalar::Int(int) => self.pretty_print_const_scalar_int(int, ty, print_ty), } } fn pretty_print_const_scalar_ptr( mut self, ptr: Pointer, ty: Ty<'tcx>, print_ty: bool, ) -> Result { define_scoped_cx!(self); let (alloc_id, offset) = ptr.into_parts(); match ty.kind() { // Byte strings (&[u8; N]) ty::Ref( _, ty::TyS { kind: ty::Array( ty::TyS { kind: ty::Uint(ty::UintTy::U8), .. }, ty::Const { val: ty::ConstKind::Value(ConstValue::Scalar(int)), .. }, ), .. }, _, ) => match self.tcx().get_global_alloc(alloc_id) { Some(GlobalAlloc::Memory(alloc)) => { let len = int.assert_bits(self.tcx().data_layout.pointer_size); let range = AllocRange { start: offset, size: Size::from_bytes(len) }; if let Ok(byte_str) = alloc.get_bytes(&self.tcx(), range) { p!(pretty_print_byte_str(byte_str)) } else { p!("") } } // FIXME: for statics and functions, we could in principle print more detail. Some(GlobalAlloc::Static(def_id)) => p!(write("", def_id)), Some(GlobalAlloc::Function(_)) => p!(""), None => p!(""), }, ty::FnPtr(_) => { // FIXME: We should probably have a helper method to share code with the "Byte strings" // printing above (which also has to handle pointers to all sorts of things). match self.tcx().get_global_alloc(alloc_id) { Some(GlobalAlloc::Function(instance)) => { self = self.typed_value( |this| this.print_value_path(instance.def_id(), instance.substs), |this| this.print_type(ty), " as ", )?; } _ => self = self.pretty_print_const_pointer(ptr, ty, print_ty)?, } } // Any pointer values not covered by a branch above _ => { self = self.pretty_print_const_pointer(ptr, ty, print_ty)?; } } Ok(self) } fn pretty_print_const_scalar_int( mut self, int: ScalarInt, ty: Ty<'tcx>, print_ty: bool, ) -> Result { define_scoped_cx!(self); match ty.kind() { // Bool ty::Bool if int == ScalarInt::FALSE => p!("false"), ty::Bool if int == ScalarInt::TRUE => p!("true"), // Float ty::Float(ty::FloatTy::F32) => { p!(write("{}f32", Single::try_from(int).unwrap())) } ty::Float(ty::FloatTy::F64) => { p!(write("{}f64", Double::try_from(int).unwrap())) } // Int ty::Uint(_) | ty::Int(_) => { let int = ConstInt::new(int, matches!(ty.kind(), ty::Int(_)), ty.is_ptr_sized_integral()); if print_ty { p!(write("{:#?}", int)) } else { p!(write("{:?}", int)) } } // Char ty::Char if char::try_from(int).is_ok() => { p!(write("{:?}", char::try_from(int).unwrap())) } // Pointer types ty::Ref(..) | ty::RawPtr(_) | ty::FnPtr(_) => { let data = int.assert_bits(self.tcx().data_layout.pointer_size); self = self.typed_value( |mut this| { write!(this, "0x{:x}", data)?; Ok(this) }, |this| this.print_type(ty), " as ", )?; } // For function type zsts just printing the path is enough ty::FnDef(d, s) if int == ScalarInt::ZST => { p!(print_value_path(*d, s)) } // Nontrivial types with scalar bit representation _ => { let print = |mut this: Self| { if int.size() == Size::ZERO { write!(this, "transmute(())")?; } else { write!(this, "transmute(0x{:x})", int)?; } Ok(this) }; self = if print_ty { self.typed_value(print, |this| this.print_type(ty), ": ")? } else { print(self)? }; } } Ok(self) } /// This is overridden for MIR printing because we only want to hide alloc ids from users, not /// from MIR where it is actually useful. fn pretty_print_const_pointer( mut self, _: Pointer, ty: Ty<'tcx>, print_ty: bool, ) -> Result { if print_ty { self.typed_value( |mut this| { this.write_str("&_")?; Ok(this) }, |this| this.print_type(ty), ": ", ) } else { self.write_str("&_")?; Ok(self) } } fn pretty_print_byte_str(mut self, byte_str: &'tcx [u8]) -> Result { define_scoped_cx!(self); p!("b\""); for &c in byte_str { for e in std::ascii::escape_default(c) { self.write_char(e as char)?; } } p!("\""); Ok(self) } fn pretty_print_const_value( mut self, ct: ConstValue<'tcx>, ty: Ty<'tcx>, print_ty: bool, ) -> Result { define_scoped_cx!(self); if self.tcx().sess.verbose() { p!(write("ConstValue({:?}: ", ct), print(ty), ")"); return Ok(self); } let u8_type = self.tcx().types.u8; match (ct, ty.kind()) { // Byte/string slices, printed as (byte) string literals. ( ConstValue::Slice { data, start, end }, ty::Ref(_, ty::TyS { kind: ty::Slice(t), .. }, _), ) if *t == u8_type => { // The `inspect` here is okay since we checked the bounds, and there are // no relocations (we have an active slice reference here). We don't use // this result to affect interpreter execution. let byte_str = data.inspect_with_uninit_and_ptr_outside_interpreter(start..end); self.pretty_print_byte_str(byte_str) } ( ConstValue::Slice { data, start, end }, ty::Ref(_, ty::TyS { kind: ty::Str, .. }, _), ) => { // The `inspect` here is okay since we checked the bounds, and there are no // relocations (we have an active `str` reference here). We don't use this // result to affect interpreter execution. let slice = data.inspect_with_uninit_and_ptr_outside_interpreter(start..end); let s = std::str::from_utf8(slice).expect("non utf8 str from miri"); p!(write("{:?}", s)); Ok(self) } (ConstValue::ByRef { alloc, offset }, ty::Array(t, n)) if *t == u8_type => { let n = n.val.try_to_bits(self.tcx().data_layout.pointer_size).unwrap(); // cast is ok because we already checked for pointer size (32 or 64 bit) above let range = AllocRange { start: offset, size: Size::from_bytes(n) }; let byte_str = alloc.get_bytes(&self.tcx(), range).unwrap(); p!("*"); p!(pretty_print_byte_str(byte_str)); Ok(self) } // Aggregates, printed as array/tuple/struct/variant construction syntax. // // NB: the `potentially_has_param_types_or_consts` check ensures that we can use // the `destructure_const` query with an empty `ty::ParamEnv` without // introducing ICEs (e.g. via `layout_of`) from missing bounds. // E.g. `transmute([0usize; 2]): (u8, *mut T)` needs to know `T: Sized` // to be able to destructure the tuple into `(0u8, *mut T) // // FIXME(eddyb) for `--emit=mir`/`-Z dump-mir`, we should provide the // correct `ty::ParamEnv` to allow printing *all* constant values. (_, ty::Array(..) | ty::Tuple(..) | ty::Adt(..)) if !ty.potentially_has_param_types_or_consts() => { let contents = self.tcx().destructure_const( ty::ParamEnv::reveal_all() .and(self.tcx().mk_const(ty::Const { val: ty::ConstKind::Value(ct), ty })), ); let fields = contents.fields.iter().copied(); match *ty.kind() { ty::Array(..) => { p!("[", comma_sep(fields), "]"); } ty::Tuple(..) => { p!("(", comma_sep(fields)); if contents.fields.len() == 1 { p!(","); } p!(")"); } ty::Adt(def, _) if def.variants.is_empty() => { self = self.typed_value( |mut this| { write!(this, "unreachable()")?; Ok(this) }, |this| this.print_type(ty), ": ", )?; } ty::Adt(def, substs) => { let variant_idx = contents.variant.expect("destructed const of adt without variant idx"); let variant_def = &def.variants[variant_idx]; p!(print_value_path(variant_def.def_id, substs)); match variant_def.ctor_kind { CtorKind::Const => {} CtorKind::Fn => { p!("(", comma_sep(fields), ")"); } CtorKind::Fictive => { p!(" {{ "); let mut first = true; for (field_def, field) in iter::zip(&variant_def.fields, fields) { if !first { p!(", "); } p!(write("{}: ", field_def.ident), print(field)); first = false; } p!(" }}"); } } } _ => unreachable!(), } Ok(self) } (ConstValue::Scalar(scalar), _) => self.pretty_print_const_scalar(scalar, ty, print_ty), // FIXME(oli-obk): also pretty print arrays and other aggregate constants by reading // their fields instead of just dumping the memory. _ => { // fallback p!(write("{:?}", ct)); if print_ty { p!(": ", print(ty)); } Ok(self) } } } } // HACK(eddyb) boxed to avoid moving around a large struct by-value. pub struct FmtPrinter<'a, 'tcx, F>(Box>); pub struct FmtPrinterData<'a, 'tcx, F> { tcx: TyCtxt<'tcx>, fmt: F, empty_path: bool, in_value: bool, pub print_alloc_ids: bool, used_region_names: FxHashSet, region_index: usize, binder_depth: usize, printed_type_count: usize, pub region_highlight_mode: RegionHighlightMode, pub name_resolver: Option Option>>, } impl Deref for FmtPrinter<'a, 'tcx, F> { type Target = FmtPrinterData<'a, 'tcx, F>; fn deref(&self) -> &Self::Target { &self.0 } } impl DerefMut for FmtPrinter<'_, '_, F> { fn deref_mut(&mut self) -> &mut Self::Target { &mut self.0 } } impl FmtPrinter<'a, 'tcx, F> { pub fn new(tcx: TyCtxt<'tcx>, fmt: F, ns: Namespace) -> Self { FmtPrinter(Box::new(FmtPrinterData { tcx, fmt, empty_path: false, in_value: ns == Namespace::ValueNS, print_alloc_ids: false, used_region_names: Default::default(), region_index: 0, binder_depth: 0, printed_type_count: 0, region_highlight_mode: RegionHighlightMode::default(), name_resolver: None, })) } } // HACK(eddyb) get rid of `def_path_str` and/or pass `Namespace` explicitly always // (but also some things just print a `DefId` generally so maybe we need this?) fn guess_def_namespace(tcx: TyCtxt<'_>, def_id: DefId) -> Namespace { match tcx.def_key(def_id).disambiguated_data.data { DefPathData::TypeNs(..) | DefPathData::CrateRoot | DefPathData::ImplTrait => { Namespace::TypeNS } DefPathData::ValueNs(..) | DefPathData::AnonConst | DefPathData::ClosureExpr | DefPathData::Ctor => Namespace::ValueNS, DefPathData::MacroNs(..) => Namespace::MacroNS, _ => Namespace::TypeNS, } } impl TyCtxt<'t> { /// Returns a string identifying this `DefId`. This string is /// suitable for user output. pub fn def_path_str(self, def_id: DefId) -> String { self.def_path_str_with_substs(def_id, &[]) } pub fn def_path_str_with_substs(self, def_id: DefId, substs: &'t [GenericArg<'t>]) -> String { let ns = guess_def_namespace(self, def_id); debug!("def_path_str: def_id={:?}, ns={:?}", def_id, ns); let mut s = String::new(); let _ = FmtPrinter::new(self, &mut s, ns).print_def_path(def_id, substs); s } } impl fmt::Write for FmtPrinter<'_, '_, F> { fn write_str(&mut self, s: &str) -> fmt::Result { self.fmt.write_str(s) } } impl Printer<'tcx> for FmtPrinter<'_, 'tcx, F> { type Error = fmt::Error; type Path = Self; type Region = Self; type Type = Self; type DynExistential = Self; type Const = Self; fn tcx(&'a self) -> TyCtxt<'tcx> { self.tcx } fn print_def_path( mut self, def_id: DefId, substs: &'tcx [GenericArg<'tcx>], ) -> Result { define_scoped_cx!(self); if substs.is_empty() { match self.try_print_trimmed_def_path(def_id)? { (cx, true) => return Ok(cx), (cx, false) => self = cx, } match self.try_print_visible_def_path(def_id)? { (cx, true) => return Ok(cx), (cx, false) => self = cx, } } let key = self.tcx.def_key(def_id); if let DefPathData::Impl = key.disambiguated_data.data { // Always use types for non-local impls, where types are always // available, and filename/line-number is mostly uninteresting. let use_types = !def_id.is_local() || { // Otherwise, use filename/line-number if forced. let force_no_types = FORCE_IMPL_FILENAME_LINE.with(|f| f.get()); !force_no_types }; if !use_types { // If no type info is available, fall back to // pretty printing some span information. This should // only occur very early in the compiler pipeline. let parent_def_id = DefId { index: key.parent.unwrap(), ..def_id }; let span = self.tcx.def_span(def_id); self = self.print_def_path(parent_def_id, &[])?; // HACK(eddyb) copy of `path_append` to avoid // constructing a `DisambiguatedDefPathData`. if !self.empty_path { write!(self, "::")?; } write!( self, "", // This may end up in stderr diagnostics but it may also be emitted // into MIR. Hence we use the remapped path if available self.tcx.sess.source_map().span_to_embeddable_string(span) )?; self.empty_path = false; return Ok(self); } } self.default_print_def_path(def_id, substs) } fn print_region(self, region: ty::Region<'_>) -> Result { self.pretty_print_region(region) } fn print_type(mut self, ty: Ty<'tcx>) -> Result { let type_length_limit = self.tcx.type_length_limit(); if type_length_limit.value_within_limit(self.printed_type_count) { self.printed_type_count += 1; self.pretty_print_type(ty) } else { write!(self, "...")?; Ok(self) } } fn print_dyn_existential( self, predicates: &'tcx ty::List>>, ) -> Result { self.pretty_print_dyn_existential(predicates) } fn print_const(self, ct: &'tcx ty::Const<'tcx>) -> Result { self.pretty_print_const(ct, true) } fn path_crate(mut self, cnum: CrateNum) -> Result { self.empty_path = true; if cnum == LOCAL_CRATE { if self.tcx.sess.rust_2018() { // We add the `crate::` keyword on Rust 2018, only when desired. if SHOULD_PREFIX_WITH_CRATE.with(|flag| flag.get()) { write!(self, "{}", kw::Crate)?; self.empty_path = false; } } } else { write!(self, "{}", self.tcx.crate_name(cnum))?; self.empty_path = false; } Ok(self) } fn path_qualified( mut self, self_ty: Ty<'tcx>, trait_ref: Option>, ) -> Result { self = self.pretty_path_qualified(self_ty, trait_ref)?; self.empty_path = false; Ok(self) } fn path_append_impl( mut self, print_prefix: impl FnOnce(Self) -> Result, _disambiguated_data: &DisambiguatedDefPathData, self_ty: Ty<'tcx>, trait_ref: Option>, ) -> Result { self = self.pretty_path_append_impl( |mut cx| { cx = print_prefix(cx)?; if !cx.empty_path { write!(cx, "::")?; } Ok(cx) }, self_ty, trait_ref, )?; self.empty_path = false; Ok(self) } fn path_append( mut self, print_prefix: impl FnOnce(Self) -> Result, disambiguated_data: &DisambiguatedDefPathData, ) -> Result { self = print_prefix(self)?; // Skip `::{{constructor}}` on tuple/unit structs. if let DefPathData::Ctor = disambiguated_data.data { return Ok(self); } // FIXME(eddyb) `name` should never be empty, but it // currently is for `extern { ... }` "foreign modules". let name = disambiguated_data.data.name(); if name != DefPathDataName::Named(kw::Empty) { if !self.empty_path { write!(self, "::")?; } if let DefPathDataName::Named(name) = name { if Ident::with_dummy_span(name).is_raw_guess() { write!(self, "r#")?; } } let verbose = self.tcx.sess.verbose(); disambiguated_data.fmt_maybe_verbose(&mut self, verbose)?; self.empty_path = false; } Ok(self) } fn path_generic_args( mut self, print_prefix: impl FnOnce(Self) -> Result, args: &[GenericArg<'tcx>], ) -> Result { self = print_prefix(self)?; // Don't print `'_` if there's no unerased regions. let print_regions = args.iter().any(|arg| match arg.unpack() { GenericArgKind::Lifetime(r) => *r != ty::ReErased, _ => false, }); let args = args.iter().cloned().filter(|arg| match arg.unpack() { GenericArgKind::Lifetime(_) => print_regions, _ => true, }); if args.clone().next().is_some() { if self.in_value { write!(self, "::")?; } self.generic_delimiters(|cx| cx.comma_sep(args)) } else { Ok(self) } } } impl PrettyPrinter<'tcx> for FmtPrinter<'_, 'tcx, F> { fn infer_ty_name(&self, id: ty::TyVid) -> Option { self.0.name_resolver.as_ref().and_then(|func| func(id)) } fn print_value_path( mut self, def_id: DefId, substs: &'tcx [GenericArg<'tcx>], ) -> Result { let was_in_value = std::mem::replace(&mut self.in_value, true); self = self.print_def_path(def_id, substs)?; self.in_value = was_in_value; Ok(self) } fn in_binder(self, value: &ty::Binder<'tcx, T>) -> Result where T: Print<'tcx, Self, Output = Self, Error = Self::Error> + TypeFoldable<'tcx>, { self.pretty_in_binder(value) } fn wrap_binder Result>( self, value: &ty::Binder<'tcx, T>, f: C, ) -> Result where T: Print<'tcx, Self, Output = Self, Error = Self::Error> + TypeFoldable<'tcx>, { self.pretty_wrap_binder(value, f) } fn typed_value( mut self, f: impl FnOnce(Self) -> Result, t: impl FnOnce(Self) -> Result, conversion: &str, ) -> Result { self.write_str("{")?; self = f(self)?; self.write_str(conversion)?; let was_in_value = std::mem::replace(&mut self.in_value, false); self = t(self)?; self.in_value = was_in_value; self.write_str("}")?; Ok(self) } fn generic_delimiters( mut self, f: impl FnOnce(Self) -> Result, ) -> Result { write!(self, "<")?; let was_in_value = std::mem::replace(&mut self.in_value, false); let mut inner = f(self)?; inner.in_value = was_in_value; write!(inner, ">")?; Ok(inner) } fn region_should_not_be_omitted(&self, region: ty::Region<'_>) -> bool { let highlight = self.region_highlight_mode; if highlight.region_highlighted(region).is_some() { return true; } if self.tcx.sess.verbose() { return true; } let identify_regions = self.tcx.sess.opts.debugging_opts.identify_regions; match *region { ty::ReEarlyBound(ref data) => { data.name != kw::Empty && data.name != kw::UnderscoreLifetime } ty::ReLateBound(_, ty::BoundRegion { kind: br, .. }) | ty::ReFree(ty::FreeRegion { bound_region: br, .. }) | ty::RePlaceholder(ty::Placeholder { name: br, .. }) => { if let ty::BrNamed(_, name) = br { if name != kw::Empty && name != kw::UnderscoreLifetime { return true; } } if let Some((region, _)) = highlight.highlight_bound_region { if br == region { return true; } } false } ty::ReVar(_) if identify_regions => true, ty::ReVar(_) | ty::ReErased => false, ty::ReStatic | ty::ReEmpty(_) => true, } } fn pretty_print_const_pointer( self, p: Pointer, ty: Ty<'tcx>, print_ty: bool, ) -> Result { let print = |mut this: Self| { define_scoped_cx!(this); if this.print_alloc_ids { p!(write("{:?}", p)); } else { p!("&_"); } Ok(this) }; if print_ty { self.typed_value(print, |this| this.print_type(ty), ": ") } else { print(self) } } } // HACK(eddyb) limited to `FmtPrinter` because of `region_highlight_mode`. impl FmtPrinter<'_, '_, F> { pub fn pretty_print_region(mut self, region: ty::Region<'_>) -> Result { define_scoped_cx!(self); // Watch out for region highlights. let highlight = self.region_highlight_mode; if let Some(n) = highlight.region_highlighted(region) { p!(write("'{}", n)); return Ok(self); } if self.tcx.sess.verbose() { p!(write("{:?}", region)); return Ok(self); } let identify_regions = self.tcx.sess.opts.debugging_opts.identify_regions; // These printouts are concise. They do not contain all the information // the user might want to diagnose an error, but there is basically no way // to fit that into a short string. Hence the recommendation to use // `explain_region()` or `note_and_explain_region()`. match *region { ty::ReEarlyBound(ref data) => { if data.name != kw::Empty { p!(write("{}", data.name)); return Ok(self); } } ty::ReLateBound(_, ty::BoundRegion { kind: br, .. }) | ty::ReFree(ty::FreeRegion { bound_region: br, .. }) | ty::RePlaceholder(ty::Placeholder { name: br, .. }) => { if let ty::BrNamed(_, name) = br { if name != kw::Empty && name != kw::UnderscoreLifetime { p!(write("{}", name)); return Ok(self); } } if let Some((region, counter)) = highlight.highlight_bound_region { if br == region { p!(write("'{}", counter)); return Ok(self); } } } ty::ReVar(region_vid) if identify_regions => { p!(write("{:?}", region_vid)); return Ok(self); } ty::ReVar(_) => {} ty::ReErased => {} ty::ReStatic => { p!("'static"); return Ok(self); } ty::ReEmpty(ty::UniverseIndex::ROOT) => { p!("'"); return Ok(self); } ty::ReEmpty(ui) => { p!(write("'", ui)); return Ok(self); } } p!("'_"); Ok(self) } } /// Folds through bound vars and placeholders, naming them struct RegionFolder<'a, 'tcx> { tcx: TyCtxt<'tcx>, current_index: ty::DebruijnIndex, region_map: BTreeMap>, name: &'a mut (dyn FnMut(ty::BoundRegion) -> ty::Region<'tcx> + 'a), } impl<'a, 'tcx> ty::TypeFolder<'tcx> for RegionFolder<'a, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.tcx } fn fold_binder>( &mut self, t: ty::Binder<'tcx, T>, ) -> ty::Binder<'tcx, T> { self.current_index.shift_in(1); let t = t.super_fold_with(self); self.current_index.shift_out(1); t } fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> { match *t.kind() { _ if t.has_vars_bound_at_or_above(self.current_index) || t.has_placeholders() => { return t.super_fold_with(self); } _ => {} } t } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { let name = &mut self.name; let region = match *r { ty::ReLateBound(_, br) => self.region_map.entry(br).or_insert_with(|| name(br)), ty::RePlaceholder(ty::PlaceholderRegion { name: kind, .. }) => { // If this is an anonymous placeholder, don't rename. Otherwise, in some // async fns, we get a `for<'r> Send` bound match kind { ty::BrAnon(_) | ty::BrEnv => r, _ => { // Index doesn't matter, since this is just for naming and these never get bound let br = ty::BoundRegion { var: ty::BoundVar::from_u32(0), kind }; self.region_map.entry(br).or_insert_with(|| name(br)) } } } _ => return r, }; if let ty::ReLateBound(debruijn1, br) = *region { assert_eq!(debruijn1, ty::INNERMOST); self.tcx.mk_region(ty::ReLateBound(self.current_index, br)) } else { region } } } // HACK(eddyb) limited to `FmtPrinter` because of `binder_depth`, // `region_index` and `used_region_names`. impl FmtPrinter<'_, 'tcx, F> { pub fn name_all_regions( mut self, value: &ty::Binder<'tcx, T>, ) -> Result<(Self, T, BTreeMap>), fmt::Error> where T: Print<'tcx, Self, Output = Self, Error = fmt::Error> + TypeFoldable<'tcx>, { fn name_by_region_index(index: usize) -> Symbol { match index { 0 => Symbol::intern("'r"), 1 => Symbol::intern("'s"), i => Symbol::intern(&format!("'t{}", i - 2)), } } // Replace any anonymous late-bound regions with named // variants, using new unique identifiers, so that we can // clearly differentiate between named and unnamed regions in // the output. We'll probably want to tweak this over time to // decide just how much information to give. if self.binder_depth == 0 { self.prepare_late_bound_region_info(value); } let mut empty = true; let mut start_or_continue = |cx: &mut Self, start: &str, cont: &str| { let w = if empty { empty = false; start } else { cont }; let _ = write!(cx, "{}", w); }; let do_continue = |cx: &mut Self, cont: Symbol| { let _ = write!(cx, "{}", cont); }; define_scoped_cx!(self); let mut region_index = self.region_index; // If we want to print verbosly, then print *all* binders, even if they // aren't named. Eventually, we might just want this as the default, but // this is not *quite* right and changes the ordering of some output // anyways. let (new_value, map) = if self.tcx().sess.verbose() { // anon index + 1 (BrEnv takes 0) -> name let mut region_map: BTreeMap = BTreeMap::default(); let bound_vars = value.bound_vars(); for var in bound_vars { match var { ty::BoundVariableKind::Region(ty::BrNamed(_, name)) => { start_or_continue(&mut self, "for<", ", "); do_continue(&mut self, name); } ty::BoundVariableKind::Region(ty::BrAnon(i)) => { start_or_continue(&mut self, "for<", ", "); let name = loop { let name = name_by_region_index(region_index); region_index += 1; if !self.used_region_names.contains(&name) { break name; } }; do_continue(&mut self, name); region_map.insert(i + 1, name); } ty::BoundVariableKind::Region(ty::BrEnv) => { start_or_continue(&mut self, "for<", ", "); let name = loop { let name = name_by_region_index(region_index); region_index += 1; if !self.used_region_names.contains(&name) { break name; } }; do_continue(&mut self, name); region_map.insert(0, name); } _ => continue, } } start_or_continue(&mut self, "", "> "); self.tcx.replace_late_bound_regions(value.clone(), |br| { let kind = match br.kind { ty::BrNamed(_, _) => br.kind, ty::BrAnon(i) => { let name = region_map[&(i + 1)]; ty::BrNamed(DefId::local(CRATE_DEF_INDEX), name) } ty::BrEnv => { let name = region_map[&0]; ty::BrNamed(DefId::local(CRATE_DEF_INDEX), name) } }; self.tcx.mk_region(ty::ReLateBound( ty::INNERMOST, ty::BoundRegion { var: br.var, kind }, )) }) } else { let tcx = self.tcx; let mut name = |br: ty::BoundRegion| { start_or_continue(&mut self, "for<", ", "); let kind = match br.kind { ty::BrNamed(_, name) => { do_continue(&mut self, name); br.kind } ty::BrAnon(_) | ty::BrEnv => { let name = loop { let name = name_by_region_index(region_index); region_index += 1; if !self.used_region_names.contains(&name) { break name; } }; do_continue(&mut self, name); ty::BrNamed(DefId::local(CRATE_DEF_INDEX), name) } }; tcx.mk_region(ty::ReLateBound(ty::INNERMOST, ty::BoundRegion { var: br.var, kind })) }; let mut folder = RegionFolder { tcx, current_index: ty::INNERMOST, name: &mut name, region_map: BTreeMap::new(), }; let new_value = value.clone().skip_binder().fold_with(&mut folder); let region_map = folder.region_map; start_or_continue(&mut self, "", "> "); (new_value, region_map) }; self.binder_depth += 1; self.region_index = region_index; Ok((self, new_value, map)) } pub fn pretty_in_binder(self, value: &ty::Binder<'tcx, T>) -> Result where T: Print<'tcx, Self, Output = Self, Error = fmt::Error> + TypeFoldable<'tcx>, { let old_region_index = self.region_index; let (new, new_value, _) = self.name_all_regions(value)?; let mut inner = new_value.print(new)?; inner.region_index = old_region_index; inner.binder_depth -= 1; Ok(inner) } pub fn pretty_wrap_binder Result>( self, value: &ty::Binder<'tcx, T>, f: C, ) -> Result where T: Print<'tcx, Self, Output = Self, Error = fmt::Error> + TypeFoldable<'tcx>, { let old_region_index = self.region_index; let (new, new_value, _) = self.name_all_regions(value)?; let mut inner = f(&new_value, new)?; inner.region_index = old_region_index; inner.binder_depth -= 1; Ok(inner) } #[instrument(skip(self), level = "debug")] fn prepare_late_bound_region_info(&mut self, value: &ty::Binder<'tcx, T>) where T: TypeFoldable<'tcx>, { struct LateBoundRegionNameCollector<'a, 'tcx> { tcx: TyCtxt<'tcx>, used_region_names: &'a mut FxHashSet, type_collector: SsoHashSet>, } impl<'tcx> ty::fold::TypeVisitor<'tcx> for LateBoundRegionNameCollector<'_, 'tcx> { type BreakTy = (); fn tcx_for_anon_const_substs(&self) -> Option> { Some(self.tcx) } #[instrument(skip(self), level = "trace")] fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { trace!("address: {:p}", r); if let ty::ReLateBound(_, ty::BoundRegion { kind: ty::BrNamed(_, name), .. }) = *r { self.used_region_names.insert(name); } else if let ty::RePlaceholder(ty::PlaceholderRegion { name: ty::BrNamed(_, name), .. }) = *r { self.used_region_names.insert(name); } r.super_visit_with(self) } // We collect types in order to prevent really large types from compiling for // a really long time. See issue #83150 for why this is necessary. #[instrument(skip(self), level = "trace")] fn visit_ty(&mut self, ty: Ty<'tcx>) -> ControlFlow { let not_previously_inserted = self.type_collector.insert(ty); if not_previously_inserted { ty.super_visit_with(self) } else { ControlFlow::CONTINUE } } } self.used_region_names.clear(); let mut collector = LateBoundRegionNameCollector { tcx: self.tcx, used_region_names: &mut self.used_region_names, type_collector: SsoHashSet::new(), }; value.visit_with(&mut collector); self.region_index = 0; } } impl<'tcx, T, P: PrettyPrinter<'tcx>> Print<'tcx, P> for ty::Binder<'tcx, T> where T: Print<'tcx, P, Output = P, Error = P::Error> + TypeFoldable<'tcx>, { type Output = P; type Error = P::Error; fn print(&self, cx: P) -> Result { cx.in_binder(self) } } impl<'tcx, T, U, P: PrettyPrinter<'tcx>> Print<'tcx, P> for ty::OutlivesPredicate where T: Print<'tcx, P, Output = P, Error = P::Error>, U: Print<'tcx, P, Output = P, Error = P::Error>, { type Output = P; type Error = P::Error; fn print(&self, mut cx: P) -> Result { define_scoped_cx!(cx); p!(print(self.0), ": ", print(self.1)); Ok(cx) } } macro_rules! forward_display_to_print { ($($ty:ty),+) => { $(impl fmt::Display for $ty { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { ty::tls::with(|tcx| { tcx.lift(*self) .expect("could not lift for printing") .print(FmtPrinter::new(tcx, f, Namespace::TypeNS))?; Ok(()) }) } })+ }; } macro_rules! define_print_and_forward_display { (($self:ident, $cx:ident): $($ty:ty $print:block)+) => { $(impl<'tcx, P: PrettyPrinter<'tcx>> Print<'tcx, P> for $ty { type Output = P; type Error = fmt::Error; fn print(&$self, $cx: P) -> Result { #[allow(unused_mut)] let mut $cx = $cx; define_scoped_cx!($cx); let _: () = $print; #[allow(unreachable_code)] Ok($cx) } })+ forward_display_to_print!($($ty),+); }; } // HACK(eddyb) this is separate because `ty::RegionKind` doesn't need lifting. impl fmt::Display for ty::RegionKind { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { ty::tls::with(|tcx| { self.print(FmtPrinter::new(tcx, f, Namespace::TypeNS))?; Ok(()) }) } } /// Wrapper type for `ty::TraitRef` which opts-in to pretty printing only /// the trait path. That is, it will print `Trait` instead of /// `>`. #[derive(Copy, Clone, TypeFoldable, Lift)] pub struct TraitRefPrintOnlyTraitPath<'tcx>(ty::TraitRef<'tcx>); impl fmt::Debug for TraitRefPrintOnlyTraitPath<'tcx> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Display::fmt(self, f) } } /// Wrapper type for `ty::TraitRef` which opts-in to pretty printing only /// the trait name. That is, it will print `Trait` instead of /// `>`. #[derive(Copy, Clone, TypeFoldable, Lift)] pub struct TraitRefPrintOnlyTraitName<'tcx>(ty::TraitRef<'tcx>); impl fmt::Debug for TraitRefPrintOnlyTraitName<'tcx> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Display::fmt(self, f) } } impl ty::TraitRef<'tcx> { pub fn print_only_trait_path(self) -> TraitRefPrintOnlyTraitPath<'tcx> { TraitRefPrintOnlyTraitPath(self) } pub fn print_only_trait_name(self) -> TraitRefPrintOnlyTraitName<'tcx> { TraitRefPrintOnlyTraitName(self) } } impl ty::Binder<'tcx, ty::TraitRef<'tcx>> { pub fn print_only_trait_path(self) -> ty::Binder<'tcx, TraitRefPrintOnlyTraitPath<'tcx>> { self.map_bound(|tr| tr.print_only_trait_path()) } } forward_display_to_print! { Ty<'tcx>, &'tcx ty::List>>, &'tcx ty::Const<'tcx>, // HACK(eddyb) these are exhaustive instead of generic, // because `for<'tcx>` isn't possible yet. ty::Binder<'tcx, ty::ExistentialPredicate<'tcx>>, ty::Binder<'tcx, ty::TraitRef<'tcx>>, ty::Binder<'tcx, ty::ExistentialTraitRef<'tcx>>, ty::Binder<'tcx, TraitRefPrintOnlyTraitPath<'tcx>>, ty::Binder<'tcx, TraitRefPrintOnlyTraitName<'tcx>>, ty::Binder<'tcx, ty::FnSig<'tcx>>, ty::Binder<'tcx, ty::TraitPredicate<'tcx>>, ty::Binder<'tcx, ty::SubtypePredicate<'tcx>>, ty::Binder<'tcx, ty::ProjectionPredicate<'tcx>>, ty::Binder<'tcx, ty::OutlivesPredicate, ty::Region<'tcx>>>, ty::Binder<'tcx, ty::OutlivesPredicate, ty::Region<'tcx>>>, ty::OutlivesPredicate, ty::Region<'tcx>>, ty::OutlivesPredicate, ty::Region<'tcx>> } define_print_and_forward_display! { (self, cx): &'tcx ty::List> { p!("{{", comma_sep(self.iter()), "}}") } ty::TypeAndMut<'tcx> { p!(write("{}", self.mutbl.prefix_str()), print(self.ty)) } ty::ExistentialTraitRef<'tcx> { // Use a type that can't appear in defaults of type parameters. let dummy_self = cx.tcx().mk_ty_infer(ty::FreshTy(0)); let trait_ref = self.with_self_ty(cx.tcx(), dummy_self); p!(print(trait_ref.print_only_trait_path())) } ty::ExistentialProjection<'tcx> { let name = cx.tcx().associated_item(self.item_def_id).ident; p!(write("{} = ", name), print(self.ty)) } ty::ExistentialPredicate<'tcx> { match *self { ty::ExistentialPredicate::Trait(x) => p!(print(x)), ty::ExistentialPredicate::Projection(x) => p!(print(x)), ty::ExistentialPredicate::AutoTrait(def_id) => { p!(print_def_path(def_id, &[])); } } } ty::FnSig<'tcx> { p!(write("{}", self.unsafety.prefix_str())); if self.abi != Abi::Rust { p!(write("extern {} ", self.abi)); } p!("fn", pretty_fn_sig(self.inputs(), self.c_variadic, self.output())); } ty::TraitRef<'tcx> { p!(write("<{} as {}>", self.self_ty(), self.print_only_trait_path())) } TraitRefPrintOnlyTraitPath<'tcx> { p!(print_def_path(self.0.def_id, self.0.substs)); } TraitRefPrintOnlyTraitName<'tcx> { p!(print_def_path(self.0.def_id, &[])); } ty::ParamTy { p!(write("{}", self.name)) } ty::ParamConst { p!(write("{}", self.name)) } ty::SubtypePredicate<'tcx> { p!(print(self.a), " <: ", print(self.b)) } ty::CoercePredicate<'tcx> { p!(print(self.a), " -> ", print(self.b)) } ty::TraitPredicate<'tcx> { p!(print(self.trait_ref.self_ty()), ": ", print(self.trait_ref.print_only_trait_path())) } ty::ProjectionPredicate<'tcx> { p!(print(self.projection_ty), " == ", print(self.ty)) } ty::ProjectionTy<'tcx> { p!(print_def_path(self.item_def_id, self.substs)); } ty::ClosureKind { match *self { ty::ClosureKind::Fn => p!("Fn"), ty::ClosureKind::FnMut => p!("FnMut"), ty::ClosureKind::FnOnce => p!("FnOnce"), } } ty::Predicate<'tcx> { let binder = self.kind(); p!(print(binder)) } ty::PredicateKind<'tcx> { match *self { ty::PredicateKind::Trait(ref data) => { p!(print(data)) } ty::PredicateKind::Subtype(predicate) => p!(print(predicate)), ty::PredicateKind::Coerce(predicate) => p!(print(predicate)), ty::PredicateKind::RegionOutlives(predicate) => p!(print(predicate)), ty::PredicateKind::TypeOutlives(predicate) => p!(print(predicate)), ty::PredicateKind::Projection(predicate) => p!(print(predicate)), ty::PredicateKind::WellFormed(arg) => p!(print(arg), " well-formed"), ty::PredicateKind::ObjectSafe(trait_def_id) => { p!("the trait `", print_def_path(trait_def_id, &[]), "` is object-safe") } ty::PredicateKind::ClosureKind(closure_def_id, _closure_substs, kind) => { p!("the closure `", print_value_path(closure_def_id, &[]), write("` implements the trait `{}`", kind)) } ty::PredicateKind::ConstEvaluatable(uv) => { p!("the constant `", print_value_path(uv.def.did, uv.substs_.map_or(&[], |x| x)), "` can be evaluated") } ty::PredicateKind::ConstEquate(c1, c2) => { p!("the constant `", print(c1), "` equals `", print(c2), "`") } ty::PredicateKind::TypeWellFormedFromEnv(ty) => { p!("the type `", print(ty), "` is found in the environment") } } } GenericArg<'tcx> { match self.unpack() { GenericArgKind::Lifetime(lt) => p!(print(lt)), GenericArgKind::Type(ty) => p!(print(ty)), GenericArgKind::Const(ct) => p!(print(ct)), } } } fn for_each_def(tcx: TyCtxt<'_>, mut collect_fn: impl for<'b> FnMut(&'b Ident, Namespace, DefId)) { // Iterate all local crate items no matter where they are defined. let hir = tcx.hir(); for item in hir.items() { if item.ident.name.as_str().is_empty() || matches!(item.kind, ItemKind::Use(_, _)) { continue; } let def_id = item.def_id.to_def_id(); let ns = tcx.def_kind(def_id).ns().unwrap_or(Namespace::TypeNS); collect_fn(&item.ident, ns, def_id); } // Now take care of extern crate items. let queue = &mut Vec::new(); let mut seen_defs: DefIdSet = Default::default(); for &cnum in tcx.crates(()).iter() { let def_id = DefId { krate: cnum, index: CRATE_DEF_INDEX }; // Ignore crates that are not direct dependencies. match tcx.extern_crate(def_id) { None => continue, Some(extern_crate) => { if !extern_crate.is_direct() { continue; } } } queue.push(def_id); } // Iterate external crate defs but be mindful about visibility while let Some(def) = queue.pop() { for child in tcx.item_children(def).iter() { if child.vis != ty::Visibility::Public { continue; } match child.res { def::Res::Def(DefKind::AssocTy, _) => {} def::Res::Def(DefKind::TyAlias, _) => {} def::Res::Def(defkind, def_id) => { if let Some(ns) = defkind.ns() { collect_fn(&child.ident, ns, def_id); } if seen_defs.insert(def_id) { queue.push(def_id); } } _ => {} } } } } /// The purpose of this function is to collect public symbols names that are unique across all /// crates in the build. Later, when printing about types we can use those names instead of the /// full exported path to them. /// /// So essentially, if a symbol name can only be imported from one place for a type, and as /// long as it was not glob-imported anywhere in the current crate, we can trim its printed /// path and print only the name. /// /// This has wide implications on error messages with types, for example, shortening /// `std::vec::Vec` to just `Vec`, as long as there is no other `Vec` importable anywhere. /// /// The implementation uses similar import discovery logic to that of 'use' suggestions. fn trimmed_def_paths(tcx: TyCtxt<'_>, (): ()) -> FxHashMap { let mut map: FxHashMap = FxHashMap::default(); if let TrimmedDefPaths::GoodPath = tcx.sess.opts.trimmed_def_paths { // For good paths causing this bug, the `rustc_middle::ty::print::with_no_trimmed_paths` // wrapper can be used to suppress this query, in exchange for full paths being formatted. tcx.sess.delay_good_path_bug("trimmed_def_paths constructed"); } let unique_symbols_rev: &mut FxHashMap<(Namespace, Symbol), Option> = &mut FxHashMap::default(); for symbol_set in tcx.resolutions(()).glob_map.values() { for symbol in symbol_set { unique_symbols_rev.insert((Namespace::TypeNS, *symbol), None); unique_symbols_rev.insert((Namespace::ValueNS, *symbol), None); unique_symbols_rev.insert((Namespace::MacroNS, *symbol), None); } } for_each_def(tcx, |ident, ns, def_id| { use std::collections::hash_map::Entry::{Occupied, Vacant}; match unique_symbols_rev.entry((ns, ident.name)) { Occupied(mut v) => match v.get() { None => {} Some(existing) => { if *existing != def_id { v.insert(None); } } }, Vacant(v) => { v.insert(Some(def_id)); } } }); for ((_, symbol), opt_def_id) in unique_symbols_rev.drain() { use std::collections::hash_map::Entry::{Occupied, Vacant}; if let Some(def_id) = opt_def_id { match map.entry(def_id) { Occupied(mut v) => { // A single DefId can be known under multiple names (e.g., // with a `pub use ... as ...;`). We need to ensure that the // name placed in this map is chosen deterministically, so // if we find multiple names (`symbol`) resolving to the // same `def_id`, we prefer the lexicographically smallest // name. // // Any stable ordering would be fine here though. if *v.get() != symbol { if v.get().as_str() > symbol.as_str() { v.insert(symbol); } } } Vacant(v) => { v.insert(symbol); } } } } map } pub fn provide(providers: &mut ty::query::Providers) { *providers = ty::query::Providers { trimmed_def_paths, ..*providers }; }