user0/rust
1
0
Fork 0
Code Issues Pull requests Projects Releases Packages Wiki Activity Actions
rust/src/librustc/util/ppaux.rs
Ariel Ben-Yehuda 36eb09f356 Create a FreshFloatTy separate from FreshIntTy 
There is no subtyping relationship between the types (or their non-freshened
variants), so they can not be merged.

Fixes #22645
Fixes #24352
Fixes #23825

Should fix #25235 (no test in issue).
Should fix #19976 (test is outdated).
2015-05-12 21:45:56 +03:00

1574 lines
49 KiB
Rust
Raw Blame History

// Copyright 2012 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use middle::def;
use middle::region;
use middle::subst::{VecPerParamSpace,Subst};
use middle::subst;
use middle::ty::{BoundRegion, BrAnon, BrNamed};
use middle::ty::{ReEarlyBound, BrFresh, ctxt};
use middle::ty::{ReFree, ReScope, ReInfer, ReStatic, Region, ReEmpty};
use middle::ty::{ReSkolemized, ReVar, BrEnv};
use middle::ty::{mt, Ty, ParamTy};
use middle::ty::{ty_bool, ty_char, ty_struct, ty_enum};
use middle::ty::{ty_err, ty_str, ty_vec, ty_float, ty_bare_fn};
use middle::ty::{ty_param, ty_ptr, ty_rptr, ty_tup};
use middle::ty::ty_closure;
use middle::ty::{ty_uniq, ty_trait, ty_int, ty_uint, ty_infer};
use middle::ty;
use middle::ty_fold::TypeFoldable;
use std::collections::HashMap;
use std::collections::hash_state::HashState;
use std::hash::Hash;
use std::rc::Rc;
use syntax::abi;
use syntax::ast_map;
use syntax::codemap::{Span, Pos};
use syntax::parse::token;
use syntax::print::pprust;
use syntax::ptr::P;
use syntax::{ast, ast_util};
use syntax::owned_slice::OwnedSlice;
/// Produces a string suitable for debugging output.
pub trait Repr<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String;
}
/// Produces a string suitable for showing to the user.
pub trait UserString<'tcx> : Repr<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String;
}
pub fn note_and_explain_region(cx: &ctxt,
prefix: &str,
region: ty::Region,
suffix: &str) -> Option<Span> {
match explain_region_and_span(cx, region) {
(ref str, Some(span)) => {
cx.sess.span_note(
span,
&format!("{}{}{}", prefix, *str, suffix));
Some(span)
}
(ref str, None) => {
cx.sess.note(
&format!("{}{}{}", prefix, *str, suffix));
None
}
}
}
/// When a free region is associated with `item`, how should we describe the item in the error
/// message.
fn item_scope_tag(item: &ast::Item) -> &'static str {
match item.node {
ast::ItemImpl(..) => "impl",
ast::ItemStruct(..) => "struct",
ast::ItemEnum(..) => "enum",
ast::ItemTrait(..) => "trait",
ast::ItemFn(..) => "function body",
_ => "item"
}
}
pub fn explain_region_and_span(cx: &ctxt, region: ty::Region)
-> (String, Option<Span>) {
return match region {
ReScope(scope) => {
let new_string;
let on_unknown_scope = || {
(format!("unknown scope: {:?}. Please report a bug.", scope), None)
};
let span = match scope.span(&cx.map) {
Some(s) => s,
None => return on_unknown_scope(),
};
let tag = match cx.map.find(scope.node_id()) {
Some(ast_map::NodeBlock(_)) => "block",
Some(ast_map::NodeExpr(expr)) => match expr.node {
ast::ExprCall(..) => "call",
ast::ExprMethodCall(..) => "method call",
ast::ExprMatch(_, _, ast::MatchSource::IfLetDesugar { .. }) => "if let",
ast::ExprMatch(_, _, ast::MatchSource::WhileLetDesugar) => "while let",
ast::ExprMatch(_, _, ast::MatchSource::ForLoopDesugar) => "for",
ast::ExprMatch(..) => "match",
_ => "expression",
},
Some(ast_map::NodeStmt(_)) => "statement",
Some(ast_map::NodeItem(it)) => item_scope_tag(&*it),
Some(_) | None => {
// this really should not happen
return on_unknown_scope();
}
};
let scope_decorated_tag = match scope {
region::CodeExtent::Misc(_) => tag,
region::CodeExtent::ParameterScope { .. } => {
"scope of parameters for function"
}
region::CodeExtent::DestructionScope(_) => {
new_string = format!("destruction scope surrounding {}", tag);
&*new_string
}
region::CodeExtent::Remainder(r) => {
new_string = format!("block suffix following statement {}",
r.first_statement_index);
&*new_string
}
};
explain_span(cx, scope_decorated_tag, span)
}
ReFree(ref fr) => {
let prefix = match fr.bound_region {
BrAnon(idx) => {
format!("the anonymous lifetime #{} defined on", idx + 1)
}
BrFresh(_) => "an anonymous lifetime defined on".to_string(),
_ => {
format!("the lifetime {} as defined on",
bound_region_ptr_to_string(cx, fr.bound_region))
}
};
match cx.map.find(fr.scope.node_id) {
Some(ast_map::NodeBlock(ref blk)) => {
let (msg, opt_span) = explain_span(cx, "block", blk.span);
(format!("{} {}", prefix, msg), opt_span)
}
Some(ast_map::NodeItem(it)) => {
let tag = item_scope_tag(&*it);
let (msg, opt_span) = explain_span(cx, tag, it.span);
(format!("{} {}", prefix, msg), opt_span)
}
Some(_) | None => {
// this really should not happen
(format!("{} unknown free region bounded by scope {:?}", prefix, fr.scope), None)
}
}
}
ReStatic => { ("the static lifetime".to_string(), None) }
ReEmpty => { ("the empty lifetime".to_string(), None) }
ReEarlyBound(ref data) => {
(format!("{}", token::get_name(data.name)), None)
}
// I believe these cases should not occur (except when debugging,
// perhaps)
ty::ReInfer(_) | ty::ReLateBound(..) => {
(format!("lifetime {:?}", region), None)
}
};
fn explain_span(cx: &ctxt, heading: &str, span: Span)
-> (String, Option<Span>) {
let lo = cx.sess.codemap().lookup_char_pos_adj(span.lo);
(format!("the {} at {}:{}", heading, lo.line, lo.col.to_usize()),
Some(span))
}
}
pub fn bound_region_ptr_to_string(cx: &ctxt, br: BoundRegion) -> String {
bound_region_to_string(cx, "", false, br)
}
pub fn bound_region_to_string(cx: &ctxt,
prefix: &str, space: bool,
br: BoundRegion) -> String {
let space_str = if space { " " } else { "" };
if cx.sess.verbose() {
return format!("{}{}{}", prefix, br.repr(cx), space_str)
}
match br {
BrNamed(_, name) => {
format!("{}{}{}", prefix, token::get_name(name), space_str)
}
BrAnon(_) | BrFresh(_) | BrEnv => prefix.to_string()
}
}
// In general, if you are giving a region error message,
// you should use `explain_region()` or, better yet,
// `note_and_explain_region()`
pub fn region_ptr_to_string(cx: &ctxt, region: Region) -> String {
region_to_string(cx, "&", true, region)
}
pub fn region_to_string(cx: &ctxt, prefix: &str, space: bool, region: Region) -> String {
let space_str = if space { " " } else { "" };
if cx.sess.verbose() {
return format!("{}{}{}", prefix, region.repr(cx), space_str)
}
// 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::ReScope(_) => prefix.to_string(),
ty::ReEarlyBound(ref data) => {
token::get_name(data.name).to_string()
}
ty::ReLateBound(_, br) => bound_region_to_string(cx, prefix, space, br),
ty::ReFree(ref fr) => bound_region_to_string(cx, prefix, space, fr.bound_region),
ty::ReInfer(ReSkolemized(_, br)) => {
bound_region_to_string(cx, prefix, space, br)
}
ty::ReInfer(ReVar(_)) => prefix.to_string(),
ty::ReStatic => format!("{}'static{}", prefix, space_str),
ty::ReEmpty => format!("{}'<empty>{}", prefix, space_str),
}
}
pub fn mutability_to_string(m: ast::Mutability) -> String {
match m {
ast::MutMutable => "mut ".to_string(),
ast::MutImmutable => "".to_string(),
}
}
pub fn mt_to_string<'tcx>(cx: &ctxt<'tcx>, m: &mt<'tcx>) -> String {
format!("{}{}",
mutability_to_string(m.mutbl),
ty_to_string(cx, m.ty))
}
pub fn vec_map_to_string<T, F>(ts: &[T], f: F) -> String where
F: FnMut(&T) -> String,
{
let tstrs = ts.iter().map(f).collect::<Vec<String>>();
format!("[{}]", tstrs.connect(", "))
}
pub fn ty_to_string<'tcx>(cx: &ctxt<'tcx>, typ: &ty::TyS<'tcx>) -> String {
fn bare_fn_to_string<'tcx>(cx: &ctxt<'tcx>,
opt_def_id: Option<ast::DefId>,
unsafety: ast::Unsafety,
abi: abi::Abi,
ident: Option<ast::Ident>,
sig: &ty::PolyFnSig<'tcx>)
-> String {
let mut s = String::new();
match unsafety {
ast::Unsafety::Normal => {}
ast::Unsafety::Unsafe => {
s.push_str(&unsafety.to_string());
s.push(' ');
}
};
if abi != abi::Rust {
s.push_str(&format!("extern {} ", abi.to_string()));
};
s.push_str("fn");
match ident {
Some(i) => {
s.push(' ');
s.push_str(&token::get_ident(i));
}
_ => { }
}
push_sig_to_string(cx, &mut s, '(', ')', sig);
match opt_def_id {
Some(def_id) => {
s.push_str(" {");
let path_str = ty::item_path_str(cx, def_id);
s.push_str(&path_str[..]);
s.push_str("}");
}
None => { }
}
s
}
fn closure_to_string<'tcx>(cx: &ctxt<'tcx>, cty: &ty::ClosureTy<'tcx>) -> String {
let mut s = String::new();
s.push_str("[closure");
push_sig_to_string(cx, &mut s, '(', ')', &cty.sig);
s.push(']');
s
}
fn push_sig_to_string<'tcx>(cx: &ctxt<'tcx>,
s: &mut String,
bra: char,
ket: char,
sig: &ty::PolyFnSig<'tcx>) {
s.push(bra);
let strs = sig.0.inputs
.iter()
.map(|a| ty_to_string(cx, *a))
.collect::<Vec<_>>();
s.push_str(&strs.connect(", "));
if sig.0.variadic {
s.push_str(", ...");
}
s.push(ket);
match sig.0.output {
ty::FnConverging(t) => {
if !ty::type_is_nil(t) {
s.push_str(" -> ");
s.push_str(&ty_to_string(cx, t));
}
}
ty::FnDiverging => {
s.push_str(" -> !");
}
}
}
fn infer_ty_to_string(cx: &ctxt, ty: ty::InferTy) -> String {
let print_var_ids = cx.sess.verbose();
match ty {
ty::TyVar(ref vid) if print_var_ids => vid.repr(cx),
ty::IntVar(ref vid) if print_var_ids => vid.repr(cx),
ty::FloatVar(ref vid) if print_var_ids => vid.repr(cx),
ty::TyVar(_) | ty::IntVar(_) | ty::FloatVar(_) => format!("_"),
ty::FreshTy(v) => format!("FreshTy({})", v),
ty::FreshIntTy(v) => format!("FreshIntTy({})", v),
ty::FreshFloatTy(v) => format!("FreshFloatTy({})", v)
}
}
// pretty print the structural type representation:
match typ.sty {
ty_bool => "bool".to_string(),
ty_char => "char".to_string(),
ty_int(t) => ast_util::int_ty_to_string(t, None).to_string(),
ty_uint(t) => ast_util::uint_ty_to_string(t, None).to_string(),
ty_float(t) => ast_util::float_ty_to_string(t).to_string(),
ty_uniq(typ) => format!("Box<{}>", ty_to_string(cx, typ)),
ty_ptr(ref tm) => {
format!("*{} {}", match tm.mutbl {
ast::MutMutable => "mut",
ast::MutImmutable => "const",
}, ty_to_string(cx, tm.ty))
}
ty_rptr(r, ref tm) => {
let mut buf = region_ptr_to_string(cx, *r);
buf.push_str(&mt_to_string(cx, tm));
buf
}
ty_tup(ref elems) => {
let strs = elems
.iter()
.map(|elem| ty_to_string(cx, *elem))
.collect::<Vec<_>>();
match &strs[..] {
[ref string] => format!("({},)", string),
strs => format!("({})", strs.connect(", "))
}
}
ty_bare_fn(opt_def_id, ref f) => {
bare_fn_to_string(cx, opt_def_id, f.unsafety, f.abi, None, &f.sig)
}
ty_infer(infer_ty) => infer_ty_to_string(cx, infer_ty),
ty_err => "[type error]".to_string(),
ty_param(ref param_ty) => param_ty.user_string(cx),
ty_enum(did, substs) | ty_struct(did, substs) => {
let base = ty::item_path_str(cx, did);
parameterized(cx, &base, substs, did, &[],
|| ty::lookup_item_type(cx, did).generics)
}
ty_trait(ref data) => {
data.user_string(cx)
}
ty::ty_projection(ref data) => {
format!("<{} as {}>::{}",
data.trait_ref.self_ty().user_string(cx),
data.trait_ref.user_string(cx),
data.item_name.user_string(cx))
}
ty_str => "str".to_string(),
ty_closure(ref did, substs) => {
let closure_tys = cx.closure_tys.borrow();
closure_tys.get(did).map(|closure_type| {
closure_to_string(cx, &closure_type.subst(cx, substs))
}).unwrap_or_else(|| {
if did.krate == ast::LOCAL_CRATE {
let span = cx.map.span(did.node);
format!("[closure {}]", span.repr(cx))
} else {
format!("[closure]")
}
})
}
ty_vec(t, sz) => {
let inner_str = ty_to_string(cx, t);
match sz {
Some(n) => format!("[{}; {}]", inner_str, n),
None => format!("[{}]", inner_str),
}
}
}
}
pub fn explicit_self_category_to_str(category: &ty::ExplicitSelfCategory)
-> &'static str {
match *category {
ty::StaticExplicitSelfCategory => "static",
ty::ByValueExplicitSelfCategory => "self",
ty::ByReferenceExplicitSelfCategory(_, ast::MutMutable) => {
"&mut self"
}
ty::ByReferenceExplicitSelfCategory(_, ast::MutImmutable) => "&self",
ty::ByBoxExplicitSelfCategory => "Box<self>",
}
}
pub fn parameterized<'tcx,GG>(cx: &ctxt<'tcx>,
base: &str,
substs: &subst::Substs<'tcx>,
did: ast::DefId,
projections: &[ty::ProjectionPredicate<'tcx>],
get_generics: GG)
-> String
where GG : FnOnce() -> ty::Generics<'tcx>
{
if cx.sess.verbose() {
let mut strings = vec![];
match substs.regions {
subst::ErasedRegions => {
strings.push(format!(".."));
}
subst::NonerasedRegions(ref regions) => {
for region in regions.iter() {
strings.push(region.repr(cx));
}
}
}
for ty in substs.types.iter() {
strings.push(ty.repr(cx));
}
for projection in projections.iter() {
strings.push(format!("{}={}",
projection.projection_ty.item_name.user_string(cx),
projection.ty.user_string(cx)));
}
return if strings.is_empty() {
format!("{}", base)
} else {
format!("{}<{}>", base, strings.connect(","))
};
}
let mut strs = Vec::new();
match substs.regions {
subst::ErasedRegions => { }
subst::NonerasedRegions(ref regions) => {
for &r in regions.iter() {
let s = region_to_string(cx, "", false, r);
if s.is_empty() {
// This happens when the value of the region
// parameter is not easily serialized. This may be
// because the user omitted it in the first place,
// or because it refers to some block in the code,
// etc. I'm not sure how best to serialize this.
strs.push(format!("'_"));
} else {
strs.push(s)
}
}
}
}
// It is important to execute this conditionally, only if -Z
// verbose is false. Otherwise, debug logs can sometimes cause
// ICEs trying to fetch the generics early in the pipeline. This
// is kind of a hacky workaround in that -Z verbose is required to
// avoid those ICEs.
let generics = get_generics();
let has_self = substs.self_ty().is_some();
let tps = substs.types.get_slice(subst::TypeSpace);
let ty_params = generics.types.get_slice(subst::TypeSpace);
let has_defaults = ty_params.last().map_or(false, |def| def.default.is_some());
let num_defaults = if has_defaults {
ty_params.iter().zip(tps.iter()).rev().take_while(|&(def, &actual)| {
match def.default {
Some(default) => {
if !has_self && ty::type_has_self(default) {
// In an object type, there is no `Self`, and
// thus if the default value references Self,
// the user will be required to give an
// explicit value. We can't even do the
// substitution below to check without causing
// an ICE. (#18956).
false
} else {
default.subst(cx, substs) == actual
}
}
None => false
}
}).count()
} else {
0
};
for t in &tps[..tps.len() - num_defaults] {
strs.push(ty_to_string(cx, *t))
}
for projection in projections {
strs.push(format!("{}={}",
projection.projection_ty.item_name.user_string(cx),
projection.ty.user_string(cx)));
}
if cx.lang_items.fn_trait_kind(did).is_some() && projections.len() == 1 {
let projection_ty = projections[0].ty;
let tail =
if ty::type_is_nil(projection_ty) {
format!("")
} else {
format!(" -> {}", projection_ty.user_string(cx))
};
format!("{}({}){}",
base,
if strs[0].starts_with("(") && strs[0].ends_with(",)") {
&strs[0][1 .. strs[0].len() - 2] // Remove '(' and ',)'
} else if strs[0].starts_with("(") && strs[0].ends_with(")") {
&strs[0][1 .. strs[0].len() - 1] // Remove '(' and ')'
} else {
&strs[0][..]
},
tail)
} else if !strs.is_empty() {
format!("{}<{}>", base, strs.connect(", "))
} else {
format!("{}", base)
}
}
pub fn ty_to_short_str<'tcx>(cx: &ctxt<'tcx>, typ: Ty<'tcx>) -> String {
let mut s = typ.repr(cx).to_string();
if s.len() >= 32 {
s = (&s[0..32]).to_string();
}
return s;
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for Option<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
match self {
&None => "None".to_string(),
&Some(ref t) => t.repr(tcx),
}
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for P<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
(**self).repr(tcx)
}
}
impl<'tcx,T:Repr<'tcx>,U:Repr<'tcx>> Repr<'tcx> for Result<T,U> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
match self {
&Ok(ref t) => t.repr(tcx),
&Err(ref u) => format!("Err({})", u.repr(tcx))
}
}
}
impl<'tcx> Repr<'tcx> for () {
fn repr(&self, _tcx: &ctxt) -> String {
"()".to_string()
}
}
impl<'a, 'tcx, T: ?Sized +Repr<'tcx>> Repr<'tcx> for &'a T {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
Repr::repr(*self, tcx)
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for Rc<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
(&**self).repr(tcx)
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for Box<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
(&**self).repr(tcx)
}
}
fn repr_vec<'tcx, T:Repr<'tcx>>(tcx: &ctxt<'tcx>, v: &[T]) -> String {
vec_map_to_string(v, |t| t.repr(tcx))
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for [T] {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
repr_vec(tcx, self)
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for OwnedSlice<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
repr_vec(tcx, &self[..])
}
}
// This is necessary to handle types like Option<Vec<T>>, for which
// autoderef cannot convert the &[T] handler
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for Vec<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
repr_vec(tcx, &self[..])
}
}
impl<'tcx, T:UserString<'tcx>> UserString<'tcx> for Vec<T> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let strs: Vec<String> =
self.iter().map(|t| t.user_string(tcx)).collect();
strs.connect(", ")
}
}
impl<'tcx> Repr<'tcx> for def::Def {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
/// This curious type is here to help pretty-print trait objects. In
/// a trait object, the projections are stored separately from the
/// main trait bound, but in fact we want to package them together
/// when printing out; they also have separate binders, but we want
/// them to share a binder when we print them out. (And the binder
/// pretty-printing logic is kind of clever and we don't want to
/// reproduce it.) So we just repackage up the structure somewhat.
///
/// Right now there is only one trait in an object that can have
/// projection bounds, so we just stuff them altogether. But in
/// reality we should eventually sort things out better.
type TraitAndProjections<'tcx> =
(ty::TraitRef<'tcx>, Vec<ty::ProjectionPredicate<'tcx>>);
impl<'tcx> UserString<'tcx> for TraitAndProjections<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let &(ref trait_ref, ref projection_bounds) = self;
let base = ty::item_path_str(tcx, trait_ref.def_id);
parameterized(tcx,
&base,
trait_ref.substs,
trait_ref.def_id,
&projection_bounds[..],
|| ty::lookup_trait_def(tcx, trait_ref.def_id).generics.clone())
}
}
impl<'tcx> UserString<'tcx> for ty::TyTrait<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let &ty::TyTrait { ref principal, ref bounds } = self;
let mut components = vec![];
let tap: ty::Binder<TraitAndProjections<'tcx>> =
ty::Binder((principal.0.clone(),
bounds.projection_bounds.iter().map(|x| x.0.clone()).collect()));
// Generate the main trait ref, including associated types.
components.push(tap.user_string(tcx));
// Builtin bounds.
for bound in &bounds.builtin_bounds {
components.push(bound.user_string(tcx));
}
// Region, if not obviously implied by builtin bounds.
if bounds.region_bound != ty::ReStatic {
// Region bound is implied by builtin bounds:
components.push(bounds.region_bound.user_string(tcx));
}
components.retain(|s| !s.is_empty());
components.connect(" + ")
}
}
impl<'tcx> Repr<'tcx> for ty::TypeParameterDef<'tcx> {
fn repr(&self, _tcx: &ctxt<'tcx>) -> String {
format!("TypeParameterDef({:?}, {:?}/{})",
self.def_id,
self.space,
self.index)
}
}
impl<'tcx> Repr<'tcx> for ty::RegionParameterDef {
fn repr(&self, tcx: &ctxt) -> String {
format!("RegionParameterDef(name={}, def_id={}, bounds={})",
token::get_name(self.name),
self.def_id.repr(tcx),
self.bounds.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::TyS<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
ty_to_string(tcx, self)
}
}
impl<'tcx> Repr<'tcx> for ty::mt<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
mt_to_string(tcx, self)
}
}
impl<'tcx> Repr<'tcx> for subst::Substs<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("Substs[types={}, regions={}]",
self.types.repr(tcx),
self.regions.repr(tcx))
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for subst::VecPerParamSpace<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("[{};{};{}]",
self.get_slice(subst::TypeSpace).repr(tcx),
self.get_slice(subst::SelfSpace).repr(tcx),
self.get_slice(subst::FnSpace).repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::ItemSubsts<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("ItemSubsts({})", self.substs.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for subst::RegionSubsts {
fn repr(&self, tcx: &ctxt) -> String {
match *self {
subst::ErasedRegions => "erased".to_string(),
subst::NonerasedRegions(ref regions) => regions.repr(tcx)
}
}
}
impl<'tcx> Repr<'tcx> for ty::BuiltinBounds {
fn repr(&self, _tcx: &ctxt) -> String {
let mut res = Vec::new();
for b in self {
res.push(match b {
ty::BoundSend => "Send".to_string(),
ty::BoundSized => "Sized".to_string(),
ty::BoundCopy => "Copy".to_string(),
ty::BoundSync => "Sync".to_string(),
});
}
res.connect("+")
}
}
impl<'tcx> Repr<'tcx> for ty::ParamBounds<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
let mut res = Vec::new();
res.push(self.builtin_bounds.repr(tcx));
for t in &self.trait_bounds {
res.push(t.repr(tcx));
}
res.connect("+")
}
}
impl<'tcx> Repr<'tcx> for ty::TraitRef<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
// when printing out the debug representation, we don't need
// to enumerate the `for<...>` etc because the debruijn index
// tells you everything you need to know.
let base = ty::item_path_str(tcx, self.def_id);
let result = parameterized(tcx, &base, self.substs, self.def_id, &[],
|| ty::lookup_trait_def(tcx, self.def_id).generics.clone());
match self.substs.self_ty() {
None => result,
Some(sty) => format!("<{} as {}>", sty.repr(tcx), result)
}
}
}
impl<'tcx> Repr<'tcx> for ty::TraitDef<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("TraitDef(generics={}, trait_ref={})",
self.generics.repr(tcx),
self.trait_ref.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ast::TraitItem {
fn repr(&self, _tcx: &ctxt) -> String {
let kind = match self.node {
ast::ConstTraitItem(..) => "ConstTraitItem",
ast::MethodTraitItem(..) => "MethodTraitItem",
ast::TypeTraitItem(..) => "TypeTraitItem",
};
format!("{}({}, id={})", kind, self.ident, self.id)
}
}
impl<'tcx> Repr<'tcx> for ast::Expr {
fn repr(&self, _tcx: &ctxt) -> String {
format!("expr({}: {})", self.id, pprust::expr_to_string(self))
}
}
impl<'tcx> Repr<'tcx> for ast::Path {
fn repr(&self, _tcx: &ctxt) -> String {
format!("path({})", pprust::path_to_string(self))
}
}
impl<'tcx> UserString<'tcx> for ast::Path {
fn user_string(&self, _tcx: &ctxt) -> String {
pprust::path_to_string(self)
}
}
impl<'tcx> Repr<'tcx> for ast::Ty {
fn repr(&self, _tcx: &ctxt) -> String {
format!("type({})", pprust::ty_to_string(self))
}
}
impl<'tcx> Repr<'tcx> for ast::Item {
fn repr(&self, tcx: &ctxt) -> String {
format!("item({})", tcx.map.node_to_string(self.id))
}
}
impl<'tcx> Repr<'tcx> for ast::Lifetime {
fn repr(&self, _tcx: &ctxt) -> String {
format!("lifetime({}: {})", self.id, pprust::lifetime_to_string(self))
}
}
impl<'tcx> Repr<'tcx> for ast::Stmt {
fn repr(&self, _tcx: &ctxt) -> String {
format!("stmt({}: {})",
ast_util::stmt_id(self),
pprust::stmt_to_string(self))
}
}
impl<'tcx> Repr<'tcx> for ast::Pat {
fn repr(&self, _tcx: &ctxt) -> String {
format!("pat({}: {})", self.id, pprust::pat_to_string(self))
}
}
impl<'tcx> Repr<'tcx> for ty::BoundRegion {
fn repr(&self, tcx: &ctxt) -> String {
match *self {
ty::BrAnon(id) => format!("BrAnon({})", id),
ty::BrNamed(id, name) => {
format!("BrNamed({}, {})", id.repr(tcx), token::get_name(name))
}
ty::BrFresh(id) => format!("BrFresh({})", id),
ty::BrEnv => "BrEnv".to_string()
}
}
}
impl<'tcx> Repr<'tcx> for ty::Region {
fn repr(&self, tcx: &ctxt) -> String {
match *self {
ty::ReEarlyBound(ref data) => {
format!("ReEarlyBound({}, {:?}, {}, {})",
data.param_id,
data.space,
data.index,
token::get_name(data.name))
}
ty::ReLateBound(binder_id, ref bound_region) => {
format!("ReLateBound({:?}, {})",
binder_id,
bound_region.repr(tcx))
}
ty::ReFree(ref fr) => fr.repr(tcx),
ty::ReScope(id) => {
format!("ReScope({:?})", id)
}
ty::ReStatic => {
"ReStatic".to_string()
}
ty::ReInfer(ReVar(ref vid)) => {
format!("{:?}", vid)
}
ty::ReInfer(ReSkolemized(id, ref bound_region)) => {
format!("re_skolemized({}, {})", id, bound_region.repr(tcx))
}
ty::ReEmpty => {
"ReEmpty".to_string()
}
}
}
}
impl<'tcx> UserString<'tcx> for ty::Region {
fn user_string(&self, tcx: &ctxt) -> String {
region_to_string(tcx, "", false, *self)
}
}
impl<'tcx> Repr<'tcx> for ty::FreeRegion {
fn repr(&self, tcx: &ctxt) -> String {
format!("ReFree({}, {})",
self.scope.repr(tcx),
self.bound_region.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for region::CodeExtent {
fn repr(&self, _tcx: &ctxt) -> String {
match *self {
region::CodeExtent::ParameterScope { fn_id, body_id } =>
format!("ParameterScope({}, {})", fn_id, body_id),
region::CodeExtent::Misc(node_id) =>
format!("Misc({})", node_id),
region::CodeExtent::DestructionScope(node_id) =>
format!("DestructionScope({})", node_id),
region::CodeExtent::Remainder(rem) =>
format!("Remainder({}, {})", rem.block, rem.first_statement_index),
}
}
}
impl<'tcx> Repr<'tcx> for region::DestructionScopeData {
fn repr(&self, _tcx: &ctxt) -> String {
match *self {
region::DestructionScopeData{ node_id } =>
format!("DestructionScopeData {{ node_id: {} }}", node_id),
}
}
}
impl<'tcx> Repr<'tcx> for ast::DefId {
fn repr(&self, tcx: &ctxt) -> String {
// Unfortunately, there seems to be no way to attempt to print
// a path for a def-id, so I'll just make a best effort for now
// and otherwise fallback to just printing the crate/node pair
if self.krate == ast::LOCAL_CRATE {
match tcx.map.find(self.node) {
Some(ast_map::NodeItem(..)) |
Some(ast_map::NodeForeignItem(..)) |
Some(ast_map::NodeImplItem(..)) |
Some(ast_map::NodeTraitItem(..)) |
Some(ast_map::NodeVariant(..)) |
Some(ast_map::NodeStructCtor(..)) => {
return format!(
"{:?}:{}",
*self,
ty::item_path_str(tcx, *self))
}
_ => {}
}
}
return format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ty::TypeScheme<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("TypeScheme {{generics: {}, ty: {}}}",
self.generics.repr(tcx),
self.ty.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::Generics<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("Generics(types: {}, regions: {})",
self.types.repr(tcx),
self.regions.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::GenericPredicates<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("GenericPredicates(predicates: {})",
self.predicates.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::InstantiatedPredicates<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("InstantiatedPredicates({})",
self.predicates.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::ItemVariances {
fn repr(&self, tcx: &ctxt) -> String {
format!("ItemVariances(types={}, \
regions={})",
self.types.repr(tcx),
self.regions.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::Variance {
fn repr(&self, _: &ctxt) -> String {
// The first `.to_string()` returns a &'static str (it is not an implementation
// of the ToString trait). Because of that, we need to call `.to_string()` again
// if we want to have a `String`.
let result: &'static str = (*self).to_string();
result.to_string()
}
}
impl<'tcx> Repr<'tcx> for ty::ImplOrTraitItem<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("ImplOrTraitItem({})",
match *self {
ty::ImplOrTraitItem::MethodTraitItem(ref i) => i.repr(tcx),
ty::ImplOrTraitItem::ConstTraitItem(ref i) => i.repr(tcx),
ty::ImplOrTraitItem::TypeTraitItem(ref i) => i.repr(tcx),
})
}
}
impl<'tcx> Repr<'tcx> for ty::AssociatedConst<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("AssociatedConst(name: {}, ty: {}, vis: {}, def_id: {})",
self.name.repr(tcx),
self.ty.repr(tcx),
self.vis.repr(tcx),
self.def_id.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::AssociatedType {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("AssociatedType(name: {}, vis: {}, def_id: {})",
self.name.repr(tcx),
self.vis.repr(tcx),
self.def_id.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::Method<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("Method(name: {}, generics: {}, predicates: {}, fty: {}, \
explicit_self: {}, vis: {}, def_id: {})",
self.name.repr(tcx),
self.generics.repr(tcx),
self.predicates.repr(tcx),
self.fty.repr(tcx),
self.explicit_self.repr(tcx),
self.vis.repr(tcx),
self.def_id.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ast::Name {
fn repr(&self, _tcx: &ctxt) -> String {
token::get_name(*self).to_string()
}
}
impl<'tcx> UserString<'tcx> for ast::Name {
fn user_string(&self, _tcx: &ctxt) -> String {
token::get_name(*self).to_string()
}
}
impl<'tcx> Repr<'tcx> for ast::Ident {
fn repr(&self, _tcx: &ctxt) -> String {
token::get_ident(*self).to_string()
}
}
impl<'tcx> Repr<'tcx> for ast::ExplicitSelf_ {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ast::Visibility {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ty::BareFnTy<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("BareFnTy {{unsafety: {}, abi: {}, sig: {}}}",
self.unsafety,
self.abi.to_string(),
self.sig.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::FnSig<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("fn{} -> {}", self.inputs.repr(tcx), self.output.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::FnOutput<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
match *self {
ty::FnConverging(ty) =>
format!("FnConverging({0})", ty.repr(tcx)),
ty::FnDiverging =>
"FnDiverging".to_string()
}
}
}
impl<'tcx> Repr<'tcx> for ty::MethodCallee<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("MethodCallee {{origin: {}, ty: {}, {}}}",
self.origin.repr(tcx),
self.ty.repr(tcx),
self.substs.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::MethodOrigin<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
match self {
&ty::MethodStatic(def_id) => {
format!("MethodStatic({})", def_id.repr(tcx))
}
&ty::MethodStaticClosure(def_id) => {
format!("MethodStaticClosure({})", def_id.repr(tcx))
}
&ty::MethodTypeParam(ref p) => {
p.repr(tcx)
}
&ty::MethodTraitObject(ref p) => {
p.repr(tcx)
}
}
}
}
impl<'tcx> Repr<'tcx> for ty::MethodParam<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("MethodParam({},{})",
self.trait_ref.repr(tcx),
self.method_num)
}
}
impl<'tcx> Repr<'tcx> for ty::MethodObject<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("MethodObject({},{},{})",
self.trait_ref.repr(tcx),
self.method_num,
self.vtable_index)
}
}
impl<'tcx> Repr<'tcx> for ty::BuiltinBound {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> UserString<'tcx> for ty::BuiltinBound {
fn user_string(&self, _tcx: &ctxt) -> String {
match *self {
ty::BoundSend => "Send".to_string(),
ty::BoundSized => "Sized".to_string(),
ty::BoundCopy => "Copy".to_string(),
ty::BoundSync => "Sync".to_string(),
}
}
}
impl<'tcx> Repr<'tcx> for Span {
fn repr(&self, tcx: &ctxt) -> String {
tcx.sess.codemap().span_to_string(*self).to_string()
}
}
impl<'tcx, A:UserString<'tcx>> UserString<'tcx> for Rc<A> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let this: &A = &**self;
this.user_string(tcx)
}
}
impl<'tcx> UserString<'tcx> for ty::ParamBounds<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let mut result = Vec::new();
let s = self.builtin_bounds.user_string(tcx);
if !s.is_empty() {
result.push(s);
}
for n in &self.trait_bounds {
result.push(n.user_string(tcx));
}
result.connect(" + ")
}
}
impl<'tcx> Repr<'tcx> for ty::ExistentialBounds<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
let mut res = Vec::new();
let region_str = self.region_bound.repr(tcx);
if !region_str.is_empty() {
res.push(region_str);
}
for bound in &self.builtin_bounds {
res.push(bound.repr(tcx));
}
for projection_bound in &self.projection_bounds {
res.push(projection_bound.repr(tcx));
}
res.connect("+")
}
}
impl<'tcx> UserString<'tcx> for ty::BuiltinBounds {
fn user_string(&self, tcx: &ctxt) -> String {
self.iter()
.map(|bb| bb.user_string(tcx))
.collect::<Vec<String>>()
.connect("+")
.to_string()
}
}
impl<'tcx, T> UserString<'tcx> for ty::Binder<T>
where T : UserString<'tcx> + TypeFoldable<'tcx>
{
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
// Replace any anonymous late-bound regions with named
// variants, using gensym'd 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.
let mut names = Vec::new();
let (unbound_value, _) = ty::replace_late_bound_regions(tcx, self, |br| {
ty::ReLateBound(ty::DebruijnIndex::new(1), match br {
ty::BrNamed(_, name) => {
names.push(token::get_name(name));
br
}
ty::BrAnon(_) |
ty::BrFresh(_) |
ty::BrEnv => {
let name = token::gensym("'r");
names.push(token::get_name(name));
ty::BrNamed(ast_util::local_def(ast::DUMMY_NODE_ID), name)
}
})
});
let names: Vec<_> = names.iter().map(|s| &s[..]).collect();
let value_str = unbound_value.user_string(tcx);
if names.is_empty() {
value_str
} else {
format!("for<{}> {}", names.connect(","), value_str)
}
}
}
impl<'tcx> UserString<'tcx> for ty::TraitRef<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
let path_str = ty::item_path_str(tcx, self.def_id);
parameterized(tcx, &path_str, self.substs, self.def_id, &[],
|| ty::lookup_trait_def(tcx, self.def_id).generics.clone())
}
}
impl<'tcx> UserString<'tcx> for Ty<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
ty_to_string(tcx, *self)
}
}
impl<'tcx> UserString<'tcx> for ast::Ident {
fn user_string(&self, _tcx: &ctxt) -> String {
token::get_name(self.name).to_string()
}
}
impl<'tcx> Repr<'tcx> for abi::Abi {
fn repr(&self, _tcx: &ctxt) -> String {
self.to_string()
}
}
impl<'tcx> UserString<'tcx> for abi::Abi {
fn user_string(&self, _tcx: &ctxt) -> String {
self.to_string()
}
}
impl<'tcx> Repr<'tcx> for ty::UpvarId {
fn repr(&self, tcx: &ctxt) -> String {
format!("UpvarId({};`{}`;{})",
self.var_id,
ty::local_var_name_str(tcx, self.var_id),
self.closure_expr_id)
}
}
impl<'tcx> Repr<'tcx> for ast::Mutability {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ty::BorrowKind {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ty::UpvarBorrow {
fn repr(&self, tcx: &ctxt) -> String {
format!("UpvarBorrow({}, {})",
self.kind.repr(tcx),
self.region.repr(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::UpvarCapture {
fn repr(&self, tcx: &ctxt) -> String {
match *self {
ty::UpvarCapture::ByValue => format!("ByValue"),
ty::UpvarCapture::ByRef(ref data) => format!("ByRef({})", data.repr(tcx)),
}
}
}
impl<'tcx> Repr<'tcx> for ty::IntVid {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", self)
}
}
impl<'tcx> Repr<'tcx> for ty::FloatVid {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", self)
}
}
impl<'tcx> Repr<'tcx> for ty::RegionVid {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", self)
}
}
impl<'tcx> Repr<'tcx> for ty::TyVid {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", self)
}
}
impl<'tcx> Repr<'tcx> for ty::IntVarValue {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ast::IntTy {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ast::UintTy {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ast::FloatTy {
fn repr(&self, _tcx: &ctxt) -> String {
format!("{:?}", *self)
}
}
impl<'tcx> Repr<'tcx> for ty::ExplicitSelfCategory {
fn repr(&self, _: &ctxt) -> String {
explicit_self_category_to_str(self).to_string()
}
}
impl<'tcx> UserString<'tcx> for ParamTy {
fn user_string(&self, _tcx: &ctxt) -> String {
format!("{}", token::get_name(self.name))
}
}
impl<'tcx> Repr<'tcx> for ParamTy {
fn repr(&self, tcx: &ctxt) -> String {
let ident = self.user_string(tcx);
format!("{}/{:?}.{}", ident, self.space, self.idx)
}
}
impl<'tcx, A:Repr<'tcx>, B:Repr<'tcx>> Repr<'tcx> for (A,B) {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
let &(ref a, ref b) = self;
format!("({},{})", a.repr(tcx), b.repr(tcx))
}
}
impl<'tcx, T:Repr<'tcx>> Repr<'tcx> for ty::Binder<T> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("Binder({})", self.0.repr(tcx))
}
}
impl<'tcx, S, K, V> Repr<'tcx> for HashMap<K, V, S>
where K: Hash + Eq + Repr<'tcx>,
V: Repr<'tcx>,
S: HashState,
{
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("HashMap({})",
self.iter()
.map(|(k,v)| format!("{} => {}", k.repr(tcx), v.repr(tcx)))
.collect::<Vec<String>>()
.connect(", "))
}
}
impl<'tcx, T, U> Repr<'tcx> for ty::OutlivesPredicate<T,U>
where T : Repr<'tcx> + TypeFoldable<'tcx>,
U : Repr<'tcx> + TypeFoldable<'tcx>,
{
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("OutlivesPredicate({}, {})",
self.0.repr(tcx),
self.1.repr(tcx))
}
}
impl<'tcx, T, U> UserString<'tcx> for ty::OutlivesPredicate<T,U>
where T : UserString<'tcx> + TypeFoldable<'tcx>,
U : UserString<'tcx> + TypeFoldable<'tcx>,
{
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
format!("{} : {}",
self.0.user_string(tcx),
self.1.user_string(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::EquatePredicate<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("EquatePredicate({}, {})",
self.0.repr(tcx),
self.1.repr(tcx))
}
}
impl<'tcx> UserString<'tcx> for ty::EquatePredicate<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
format!("{} == {}",
self.0.user_string(tcx),
self.1.user_string(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::TraitPredicate<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("TraitPredicate({})",
self.trait_ref.repr(tcx))
}
}
impl<'tcx> UserString<'tcx> for ty::TraitPredicate<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
format!("{} : {}",
self.trait_ref.self_ty().user_string(tcx),
self.trait_ref.user_string(tcx))
}
}
impl<'tcx> UserString<'tcx> for ty::ProjectionPredicate<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
format!("{} == {}",
self.projection_ty.user_string(tcx),
self.ty.user_string(tcx))
}
}
impl<'tcx> Repr<'tcx> for ty::ProjectionTy<'tcx> {
fn repr(&self, tcx: &ctxt<'tcx>) -> String {
format!("{}::{}",
self.trait_ref.repr(tcx),
self.item_name.repr(tcx))
}
}
impl<'tcx> UserString<'tcx> for ty::ProjectionTy<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
format!("<{} as {}>::{}",
self.trait_ref.self_ty().user_string(tcx),
self.trait_ref.user_string(tcx),
self.item_name.user_string(tcx))
}
}
impl<'tcx> UserString<'tcx> for ty::Predicate<'tcx> {
fn user_string(&self, tcx: &ctxt<'tcx>) -> String {
match *self {
ty::Predicate::Trait(ref data) => data.user_string(tcx),
ty::Predicate::Equate(ref predicate) => predicate.user_string(tcx),
ty::Predicate::RegionOutlives(ref predicate) => predicate.user_string(tcx),
ty::Predicate::TypeOutlives(ref predicate) => predicate.user_string(tcx),
ty::Predicate::Projection(ref predicate) => predicate.user_string(tcx),
}
}
}
impl<'tcx> Repr<'tcx> for ast::Unsafety {
fn repr(&self, _: &ctxt<'tcx>) -> String {
format!("{:?}", *self)
}
}
Reference in a new issue View git blame Copy permalink