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pretty.rs
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pretty.rs
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use crate::mir::interpret::{AllocRange, GlobalAlloc, Pointer, Provenance, Scalar};
use crate::query::IntoQueryParam;
use crate::query::Providers;
use crate::traits::util::supertraits_for_pretty_printing;
use crate::ty::{
self, ConstInt, ParamConst, ScalarInt, Term, TermKind, Ty, TyCtxt, TypeFoldable,
TypeSuperFoldable, TypeSuperVisitable, TypeVisitable, TypeVisitableExt,
};
use crate::ty::{GenericArg, GenericArgKind};
use rustc_apfloat::ieee::{Double, Single};
use rustc_apfloat::Float;
use rustc_data_structures::fx::{FxHashMap, FxIndexMap};
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, ModDefId, CRATE_DEF_ID, LOCAL_CRATE};
use rustc_hir::definitions::{DefKey, DefPathData, DefPathDataName, DisambiguatedDefPathData};
use rustc_hir::LangItem;
use rustc_session::config::TrimmedDefPaths;
use rustc_session::cstore::{ExternCrate, ExternCrateSource};
use rustc_session::Limit;
use rustc_span::sym;
use rustc_span::symbol::{kw, Ident, Symbol};
use rustc_span::FileNameDisplayPreference;
use rustc_target::abi::Size;
use rustc_target::spec::abi::Abi;
use smallvec::SmallVec;
use std::cell::Cell;
use std::collections::BTreeMap;
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)) => {
$x.print(scoped_cx!())?
};
(@$method:ident($($arg:expr),*)) => {
scoped_cx!().$method($($arg),*)?
};
($($elem:tt $(($($args:tt)*))?),+) => {{
$(p!(@ $elem $(($($args)*))?);)+
}};
}
macro_rules! define_scoped_cx {
($cx:ident) => {
macro_rules! scoped_cx {
() => {
$cx
};
}
};
}
thread_local! {
static FORCE_IMPL_FILENAME_LINE: Cell<bool> = const { Cell::new(false) };
static SHOULD_PREFIX_WITH_CRATE: Cell<bool> = const { Cell::new(false) };
static NO_TRIMMED_PATH: Cell<bool> = const { Cell::new(false) };
static FORCE_TRIMMED_PATH: Cell<bool> = const { Cell::new(false) };
static NO_QUERIES: Cell<bool> = const { Cell::new(false) };
static NO_VISIBLE_PATH: Cell<bool> = const { Cell::new(false) };
}
macro_rules! define_helper {
($($(#[$a:meta])* fn $name:ident($helper:ident, $tl:ident);)+) => {
$(
#[must_use]
pub struct $helper(bool);
impl $helper {
pub fn new() -> $helper {
$helper($tl.with(|c| c.replace(true)))
}
}
$(#[$a])*
pub macro $name($e:expr) {
{
let _guard = $helper::new();
$e
}
}
impl Drop for $helper {
fn drop(&mut self) {
$tl.with(|c| c.set(self.0))
}
}
pub fn $name() -> bool {
$tl.with(|c| c.get())
}
)+
}
}
define_helper!(
/// 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.
fn with_no_queries(NoQueriesGuard, NO_QUERIES);
/// 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.
fn with_forced_impl_filename_line(ForcedImplGuard, FORCE_IMPL_FILENAME_LINE);
/// Adds the `crate::` prefix to paths where appropriate.
fn with_crate_prefix(CratePrefixGuard, SHOULD_PREFIX_WITH_CRATE);
/// 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.
fn with_no_trimmed_paths(NoTrimmedGuard, NO_TRIMMED_PATH);
fn with_forced_trimmed_paths(ForceTrimmedGuard, FORCE_TRIMMED_PATH);
/// Prevent selection of visible paths. `Display` impl of DefId will prefer
/// visible (public) reexports of types as paths.
fn with_no_visible_paths(NoVisibleGuard, NO_VISIBLE_PATH);
);
/// 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<'tcx> {
/// If enabled, when we see the selected region, use "`'N`"
/// instead of the ordinary behavior.
highlight_regions: [Option<(ty::Region<'tcx>, 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<'tcx> RegionHighlightMode<'tcx> {
/// If `region` and `number` are both `Some`, invokes
/// `highlighting_region`.
pub fn maybe_highlighting_region(
&mut self,
region: Option<ty::Region<'tcx>>,
number: Option<usize>,
) {
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<'tcx>, 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,
tcx: TyCtxt<'tcx>,
vid: ty::RegionVid,
number: usize,
) {
self.highlighting_region(ty::Region::new_var(tcx, vid), number)
}
/// Returns `Some(n)` with the number to use for the given region, if any.
fn region_highlighted(&self, region: ty::Region<'tcx>) -> Option<usize> {
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> + fmt::Write {
/// Like `print_def_path` but for value paths.
fn print_value_path(
&mut self,
def_id: DefId,
args: &'tcx [GenericArg<'tcx>],
) -> Result<(), PrintError> {
self.print_def_path(def_id, args)
}
fn in_binder<T>(&mut self, value: &ty::Binder<'tcx, T>) -> Result<(), PrintError>
where
T: Print<'tcx, Self> + TypeFoldable<TyCtxt<'tcx>>,
{
value.as_ref().skip_binder().print(self)
}
fn wrap_binder<T, F: FnOnce(&T, &mut Self) -> Result<(), fmt::Error>>(
&mut self,
value: &ty::Binder<'tcx, T>,
f: F,
) -> Result<(), PrintError>
where
T: Print<'tcx, Self> + TypeFoldable<TyCtxt<'tcx>>,
{
f(value.as_ref().skip_binder(), self)
}
/// Prints comma-separated elements.
fn comma_sep<T>(&mut self, mut elems: impl Iterator<Item = T>) -> Result<(), PrintError>
where
T: Print<'tcx, Self>,
{
if let Some(first) = elems.next() {
first.print(self)?;
for elem in elems {
self.write_str(", ")?;
elem.print(self)?;
}
}
Ok(())
}
/// Prints `{f: t}` or `{f as t}` depending on the `cast` argument
fn typed_value(
&mut self,
f: impl FnOnce(&mut Self) -> Result<(), PrintError>,
t: impl FnOnce(&mut Self) -> Result<(), PrintError>,
conversion: &str,
) -> Result<(), PrintError> {
self.write_str("{")?;
f(self)?;
self.write_str(conversion)?;
t(self)?;
self.write_str("}")?;
Ok(())
}
/// Prints `<...>` around what `f` prints.
fn generic_delimiters(
&mut self,
f: impl FnOnce(&mut Self) -> Result<(), PrintError>,
) -> Result<(), PrintError>;
/// 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 should_print_region(&self, region: ty::Region<'tcx>) -> bool;
fn reset_type_limit(&mut self) {}
// 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(&mut self, def_id: DefId) -> Result<bool, PrintError> {
if NO_VISIBLE_PATH.with(|flag| flag.get()) {
return Ok(false);
}
let mut callers = Vec::new();
self.try_print_visible_def_path_recur(def_id, &mut callers)
}
// Given a `DefId`, produce a short name. For types and traits, it prints *only* its name,
// For associated items on traits it prints out the trait's name and the associated item's name.
// For enum variants, if they have an unique name, then we only print the name, otherwise we
// print the enum name and the variant name. Otherwise, we do not print anything and let the
// caller use the `print_def_path` fallback.
fn force_print_trimmed_def_path(&mut self, def_id: DefId) -> Result<bool, PrintError> {
let key = self.tcx().def_key(def_id);
let visible_parent_map = self.tcx().visible_parent_map(());
let kind = self.tcx().def_kind(def_id);
let get_local_name = |this: &Self, name, def_id, key: DefKey| {
if let Some(visible_parent) = visible_parent_map.get(&def_id)
&& let actual_parent = this.tcx().opt_parent(def_id)
&& let DefPathData::TypeNs(_) = key.disambiguated_data.data
&& Some(*visible_parent) != actual_parent
{
this.tcx()
// FIXME(typed_def_id): Further propagate ModDefId
.module_children(ModDefId::new_unchecked(*visible_parent))
.iter()
.filter(|child| child.res.opt_def_id() == Some(def_id))
.find(|child| child.vis.is_public() && child.ident.name != kw::Underscore)
.map(|child| child.ident.name)
.unwrap_or(name)
} else {
name
}
};
if let DefKind::Variant = kind
&& let Some(symbol) = self.tcx().trimmed_def_paths(()).get(&def_id)
{
// If `Assoc` is unique, we don't want to talk about `Trait::Assoc`.
self.write_str(get_local_name(self, *symbol, def_id, key).as_str())?;
return Ok(true);
}
if let Some(symbol) = key.get_opt_name() {
if let DefKind::AssocConst | DefKind::AssocFn | DefKind::AssocTy = kind
&& let Some(parent) = self.tcx().opt_parent(def_id)
&& let parent_key = self.tcx().def_key(parent)
&& let Some(symbol) = parent_key.get_opt_name()
{
// Trait
self.write_str(get_local_name(self, symbol, parent, parent_key).as_str())?;
self.write_str("::")?;
} else if let DefKind::Variant = kind
&& let Some(parent) = self.tcx().opt_parent(def_id)
&& let parent_key = self.tcx().def_key(parent)
&& let Some(symbol) = parent_key.get_opt_name()
{
// Enum
// For associated items and variants, we want the "full" path, namely, include
// the parent type in the path. For example, `Iterator::Item`.
self.write_str(get_local_name(self, symbol, parent, parent_key).as_str())?;
self.write_str("::")?;
} else if let DefKind::Struct
| DefKind::Union
| DefKind::Enum
| DefKind::Trait
| DefKind::TyAlias
| DefKind::Fn
| DefKind::Const
| DefKind::Static(_) = kind
{
} else {
// If not covered above, like for example items out of `impl` blocks, fallback.
return Ok(false);
}
self.write_str(get_local_name(self, symbol, def_id, key).as_str())?;
return Ok(true);
}
Ok(false)
}
/// 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<bool, PrintError> {
if FORCE_TRIMMED_PATH.with(|flag| flag.get()) {
let trimmed = self.force_print_trimmed_def_path(def_id)?;
if trimmed {
return Ok(true);
}
}
if !self.tcx().sess.opts.unstable_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(false);
}
match self.tcx().trimmed_def_paths(()).get(&def_id) {
None => Ok(false),
Some(symbol) => {
write!(self, "{}", Ident::with_dummy_span(*symbol))?;
Ok(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.
///
/// This method returns false if we can't print the visible path, so
/// `print_def_path` can fall back on the item's real definition path.
fn try_print_visible_def_path_recur(
&mut self,
def_id: DefId,
callers: &mut Vec<DefId>,
) -> Result<bool, PrintError> {
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 let Some(cnum) = def_id.as_crate_root() {
if cnum == LOCAL_CRATE {
self.path_crate(cnum)?;
return Ok(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) => {
// NOTE(eddyb) the only reason `span` might be dummy,
// that we're aware of, is that it's the `std`/`core`
// `extern crate` injected by default.
// FIXME(eddyb) find something better to key this on,
// or avoid ending up with `ExternCrateSource::Extern`,
// for the injected `std`/`core`.
if span.is_dummy() {
self.path_crate(cnum)?;
return Ok(true);
}
// Disable `try_print_trimmed_def_path` behavior within
// the `print_def_path` call, to avoid infinite recursion
// in cases where the `extern crate foo` has non-trivial
// parents, e.g. it's nested in `impl foo::Trait for Bar`
// (see also issues #55779 and #87932).
with_no_visible_paths!(self.print_def_path(def_id, &[])?);
return Ok(true);
}
(ExternCrateSource::Path, LOCAL_CRATE) => {
self.path_crate(cnum)?;
return Ok(true);
}
_ => {}
},
None => {
self.path_crate(cnum)?;
return Ok(true);
}
}
}
if def_id.is_local() {
return Ok(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 <unnamed>.
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 Some(visible_parent) = visible_parent_map.get(&def_id).cloned() else {
return Ok(false);
};
let actual_parent = self.tcx().opt_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` reexports 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 => {
// Item might be re-exported several times, but filter for the one
// that's public and whose identifier isn't `_`.
let reexport = self
.tcx()
// FIXME(typed_def_id): Further propagate ModDefId
.module_children(ModDefId::new_unchecked(visible_parent))
.iter()
.filter(|child| child.res.opt_def_id() == Some(def_id))
.find(|child| child.vis.is_public() && child.ident.name != kw::Underscore)
.map(|child| child.ident.name);
if let Some(new_name) = reexport {
*name = new_name;
} else {
// There is no name that is public and isn't `_`, so bail.
return Ok(false);
}
}
// 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);
if callers.contains(&visible_parent) {
return Ok(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)? {
false => return Ok(false),
true => {}
}
callers.pop();
self.path_append(|_| Ok(()), &DisambiguatedDefPathData { data, disambiguator: 0 })?;
Ok(true)
}
fn pretty_path_qualified(
&mut self,
self_ty: Ty<'tcx>,
trait_ref: Option<ty::TraitRef<'tcx>>,
) -> Result<(), PrintError> {
if trait_ref.is_none() {
// Inherent impls. Try to print `Foo::bar` for an inherent
// impl on `Foo`, but fallback to `<Foo>::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(|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(())
})
}
fn pretty_path_append_impl(
&mut self,
print_prefix: impl FnOnce(&mut Self) -> Result<(), PrintError>,
self_ty: Ty<'tcx>,
trait_ref: Option<ty::TraitRef<'tcx>>,
) -> Result<(), PrintError> {
print_prefix(self)?;
self.generic_delimiters(|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(())
})
}
fn pretty_print_type(&mut self, ty: Ty<'tcx>) -> Result<(), PrintError> {
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.should_print_region(r) {
p!(print(r), " ");
}
p!(print(ty::TypeAndMut { ty, mutbl }))
}
ty::Never => p!("!"),
ty::Tuple(tys) => {
p!("(", comma_sep(tys.iter()));
if tys.len() == 1 {
p!(",");
}
p!(")")
}
ty::FnDef(def_id, args) => {
if with_no_queries() {
p!(print_def_path(def_id, args));
} else {
let sig = self.tcx().fn_sig(def_id).instantiate(self.tcx(), args);
p!(print(sig), " {{", print_value_path(def_id, args), "}}");
}
}
ty::FnPtr(ref bare_fn) => p!(print(bare_fn)),
ty::Infer(infer_ty) => {
if self.should_print_verbose() {
p!(write("{:?}", ty.kind()));
return Ok(());
}
if let ty::TyVar(ty_vid) = infer_ty {
if let Some(name) = self.ty_infer_name(ty_vid) {
p!(write("{}", name))
} else {
p!(write("{}", infer_ty))
}
} else {
p!(write("{}", infer_ty))
}
}
ty::Error(_) => p!("{{type error}}"),
ty::Param(ref param_ty) => p!(print(param_ty)),
ty::Bound(debruijn, bound_ty) => match bound_ty.kind {
ty::BoundTyKind::Anon => {
rustc_type_ir::debug_bound_var(self, debruijn, bound_ty.var)?
}
ty::BoundTyKind::Param(_, s) => match self.should_print_verbose() {
true => p!(write("{:?}", ty.kind())),
false => p!(write("{s}")),
},
},
ty::Adt(def, args) => {
p!(print_def_path(def.did(), args));
}
ty::Dynamic(data, r, repr) => {
let print_r = self.should_print_region(r);
if print_r {
p!("(");
}
match repr {
ty::Dyn => p!("dyn "),
ty::DynStar => p!("dyn* "),
}
p!(print(data));
if print_r {
p!(" + ", print(r), ")");
}
}
ty::Foreign(def_id) => {
p!(print_def_path(def_id, &[]));
}
ty::Alias(ty::Projection | ty::Inherent | ty::Weak, ref data) => {
if !(self.should_print_verbose() || with_no_queries())
&& self.tcx().is_impl_trait_in_trait(data.def_id)
{
return self.pretty_print_opaque_impl_type(data.def_id, data.args);
} else {
p!(print(data))
}
}
ty::Placeholder(placeholder) => match placeholder.bound.kind {
ty::BoundTyKind::Anon => p!(write("{placeholder:?}")),
ty::BoundTyKind::Param(_, name) => match self.should_print_verbose() {
true => p!(write("{:?}", ty.kind())),
false => p!(write("{name}")),
},
},
ty::Alias(ty::Opaque, ty::AliasTy { def_id, args, .. }) => {
// 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.
// [Unless `-Zverbose` is used, e.g. in the output of
// `tests/ui/nll/ty-outlives/impl-trait-captures.rs`, for
// example.]
if self.should_print_verbose() {
// FIXME(eddyb) print this with `print_def_path`.
p!(write("Opaque({:?}, {})", def_id, args.print_as_list()));
return Ok(());
}
let parent = self.tcx().parent(def_id);
match self.tcx().def_kind(parent) {
DefKind::TyAlias | DefKind::AssocTy => {
// NOTE: I know we should check for NO_QUERIES here, but it's alright.
// `type_of` on a type alias or assoc type should never cause a cycle.
if let ty::Alias(ty::Opaque, ty::AliasTy { def_id: d, .. }) =
*self.tcx().type_of(parent).instantiate_identity().kind()
{
if d == def_id {
// If the type alias directly starts with the `impl` of the
// opaque type we're printing, then skip the `::{opaque#1}`.
p!(print_def_path(parent, args));
return Ok(());
}
}
// Complex opaque type, e.g. `type Foo = (i32, impl Debug);`
p!(print_def_path(def_id, args));
return Ok(());
}
_ => {
if with_no_queries() {
p!(print_def_path(def_id, &[]));
return Ok(());
} else {
return self.pretty_print_opaque_impl_type(def_id, args);
}
}
}
}
ty::Str => p!("str"),
ty::Coroutine(did, args, movability) => {
p!(write("{{"));
let coroutine_kind = self.tcx().coroutine_kind(did).unwrap();
let should_print_movability =
self.should_print_verbose() || coroutine_kind == hir::CoroutineKind::Coroutine;
if should_print_movability {
match movability {
hir::Movability::Movable => {}
hir::Movability::Static => p!("static "),
}
}
if !self.should_print_verbose() {
p!(write("{}", coroutine_kind));
// FIXME(eddyb) should use `def_span`.
if let Some(did) = did.as_local() {
let span = self.tcx().def_span(did);
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, args));
}
} else {
p!(print_def_path(did, args));
p!(" upvar_tys=(");
if !args.as_coroutine().is_valid() {
p!("unavailable");
} else {
self.comma_sep(args.as_coroutine().upvar_tys().iter())?;
}
p!(")");
if args.as_coroutine().is_valid() {
p!(" ", print(args.as_coroutine().witness()));
}
}
p!("}}")
}
ty::CoroutineWitness(did, args) => {
p!(write("{{"));
if !self.tcx().sess.verbose() {
p!("coroutine witness");
// FIXME(eddyb) should use `def_span`.
if let Some(did) = did.as_local() {
let span = self.tcx().def_span(did);
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, args));
}
} else {
p!(print_def_path(did, args));
}
p!("}}")
}
ty::Closure(did, args) => {
p!(write("{{"));
if !self.should_print_verbose() {
p!(write("closure"));
// FIXME(eddyb) should use `def_span`.
if let Some(did) = did.as_local() {
if self.tcx().sess.opts.unstable_opts.span_free_formats {
p!("@", print_def_path(did.to_def_id(), args));
} else {
let span = self.tcx().def_span(did);
let preference = if FORCE_TRIMMED_PATH.with(|flag| flag.get()) {
FileNameDisplayPreference::Short
} else {
FileNameDisplayPreference::Remapped
};
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_string(span, preference)
));
}
} else {
p!(write("@"), print_def_path(did, args));
}
} else {
p!(print_def_path(did, args));
if !args.as_closure().is_valid() {
p!(" closure_args=(unavailable)");
p!(write(" args={}", args.print_as_list()));
} else {
p!(" closure_kind_ty=", print(args.as_closure().kind_ty()));
p!(
" closure_sig_as_fn_ptr_ty=",
print(args.as_closure().sig_as_fn_ptr_ty())
);
p!(" upvar_tys=(");
self.comma_sep(args.as_closure().upvar_tys().iter())?;
p!(")");
}
}
p!("}}");
}
ty::Array(ty, sz) => p!("[", print(ty), "; ", print(sz), "]"),
ty::Slice(ty) => p!("[", print(ty), "]"),
}
Ok(())
}
fn pretty_print_opaque_impl_type(
&mut self,
def_id: DefId,
args: &'tcx ty::List<ty::GenericArg<'tcx>>,
) -> Result<(), PrintError> {
let tcx = self.tcx();
// Grab the "TraitA + TraitB" from `impl TraitA + TraitB`,
// by looking up the projections associated with the def_id.
let bounds = tcx.explicit_item_bounds(def_id);
let mut traits = FxIndexMap::default();
let mut fn_traits = FxIndexMap::default();
let mut is_sized = false;
let mut lifetimes = SmallVec::<[ty::Region<'tcx>; 1]>::new();
for (predicate, _) in bounds.iter_instantiated_copied(tcx, args) {
let bound_predicate = predicate.kind();
match bound_predicate.skip_binder() {
ty::ClauseKind::Trait(pred) => {
let trait_ref = bound_predicate.rebind(pred.trait_ref);
// Don't print + Sized, but rather + ?Sized if absent.
if Some(trait_ref.def_id()) == tcx.lang_items().sized_trait() {
is_sized = true;
continue;
}
self.insert_trait_and_projection(trait_ref, None, &mut traits, &mut fn_traits);
}
ty::ClauseKind::Projection(pred) => {
let proj_ref = bound_predicate.rebind(pred);
let trait_ref = proj_ref.required_poly_trait_ref(tcx);
// Projection type entry -- the def-id for naming, and the ty.
let proj_ty = (proj_ref.projection_def_id(), proj_ref.term());
self.insert_trait_and_projection(
trait_ref,
Some(proj_ty),
&mut traits,
&mut fn_traits,
);
}
ty::ClauseKind::TypeOutlives(outlives) => {
lifetimes.push(outlives.1);
}
_ => {}
}
}
write!(self, "impl ")?;
let mut first = true;
// Insert parenthesis around (Fn(A, B) -> C) if the opaque ty has more than one other trait
let paren_needed = fn_traits.len() > 1 || traits.len() > 0 || !is_sized;
for (fn_once_trait_ref, entry) in fn_traits {
write!(self, "{}", if first { "" } else { " + " })?;
write!(self, "{}", if paren_needed { "(" } else { "" })?;
self.wrap_binder(&fn_once_trait_ref, |trait_ref, cx| {
define_scoped_cx!(cx);
// Get the (single) generic ty (the args) of this FnOnce trait ref.
let generics = tcx.generics_of(trait_ref.def_id);
let own_args = generics.own_args_no_defaults(tcx, trait_ref.args);
match (entry.return_ty, own_args[0].expect_ty()) {
// We can only print `impl Fn() -> ()` if we have a tuple of args and we recorded
// a return type.
(Some(return_ty), arg_tys) if matches!(arg_tys.kind(), ty::Tuple(_)) => {
let name = if entry.fn_trait_ref.is_some() {
"Fn"
} else if entry.fn_mut_trait_ref.is_some() {
"FnMut"
} else {
"FnOnce"
};
p!(write("{}(", name));
for (idx, ty) in arg_tys.tuple_fields().iter().enumerate() {
if idx > 0 {
p!(", ");
}
p!(print(ty));
}
p!(")");
if let Some(ty) = return_ty.skip_binder().ty() {
if !ty.is_unit() {
p!(" -> ", print(return_ty));
}
}
p!(write("{}", if paren_needed { ")" } else { "" }));