rust-clippy/clippy_lints/src/utils/ast_utils.rs
bors 3899d6001c Auto merge of #5878 - flip1995:rustup, r=flip1995
Rustup

r? @ghost

changelog: none
2020-08-08 17:28:34 +00:00

523 lines
21 KiB
Rust

//! Utilities for manipulating and extracting information from `rustc_ast::ast`.
//!
//! - The `eq_foobar` functions test for semantic equality but ignores `NodeId`s and `Span`s.
#![allow(clippy::similar_names, clippy::wildcard_imports, clippy::enum_glob_use)]
use crate::utils::{both, over};
use rustc_ast::ast::{self, *};
use rustc_ast::ptr::P;
use rustc_span::symbol::Ident;
use std::mem;
/// Checks if each element in the first slice is contained within the latter as per `eq_fn`.
pub fn unordered_over<X>(left: &[X], right: &[X], mut eq_fn: impl FnMut(&X, &X) -> bool) -> bool {
left.len() == right.len() && left.iter().all(|l| right.iter().any(|r| eq_fn(l, r)))
}
pub fn eq_id(l: Ident, r: Ident) -> bool {
l.name == r.name
}
pub fn eq_pat(l: &Pat, r: &Pat) -> bool {
use PatKind::*;
match (&l.kind, &r.kind) {
(Paren(l), _) => eq_pat(l, r),
(_, Paren(r)) => eq_pat(l, r),
(Wild, Wild) | (Rest, Rest) => true,
(Lit(l), Lit(r)) => eq_expr(l, r),
(Ident(b1, i1, s1), Ident(b2, i2, s2)) => b1 == b2 && eq_id(*i1, *i2) && both(s1, s2, |l, r| eq_pat(l, r)),
(Range(lf, lt, le), Range(rf, rt, re)) => {
eq_expr_opt(lf, rf) && eq_expr_opt(lt, rt) && eq_range_end(&le.node, &re.node)
},
(Box(l), Box(r))
| (Ref(l, Mutability::Not), Ref(r, Mutability::Not))
| (Ref(l, Mutability::Mut), Ref(r, Mutability::Mut)) => eq_pat(l, r),
(Tuple(l), Tuple(r)) | (Slice(l), Slice(r)) => over(l, r, |l, r| eq_pat(l, r)),
(Path(lq, lp), Path(rq, rp)) => both(lq, rq, |l, r| eq_qself(l, r)) && eq_path(lp, rp),
(TupleStruct(lp, lfs), TupleStruct(rp, rfs)) => eq_path(lp, rp) && over(lfs, rfs, |l, r| eq_pat(l, r)),
(Struct(lp, lfs, lr), Struct(rp, rfs, rr)) => {
lr == rr && eq_path(lp, rp) && unordered_over(lfs, rfs, |lf, rf| eq_field_pat(lf, rf))
},
(Or(ls), Or(rs)) => unordered_over(ls, rs, |l, r| eq_pat(l, r)),
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
_ => false,
}
}
pub fn eq_range_end(l: &RangeEnd, r: &RangeEnd) -> bool {
match (l, r) {
(RangeEnd::Excluded, RangeEnd::Excluded) => true,
(RangeEnd::Included(l), RangeEnd::Included(r)) => {
matches!(l, RangeSyntax::DotDotEq) == matches!(r, RangeSyntax::DotDotEq)
},
_ => false,
}
}
pub fn eq_field_pat(l: &FieldPat, r: &FieldPat) -> bool {
l.is_placeholder == r.is_placeholder
&& eq_id(l.ident, r.ident)
&& eq_pat(&l.pat, &r.pat)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
}
pub fn eq_qself(l: &QSelf, r: &QSelf) -> bool {
l.position == r.position && eq_ty(&l.ty, &r.ty)
}
pub fn eq_path(l: &Path, r: &Path) -> bool {
over(&l.segments, &r.segments, |l, r| eq_path_seg(l, r))
}
pub fn eq_path_seg(l: &PathSegment, r: &PathSegment) -> bool {
eq_id(l.ident, r.ident) && both(&l.args, &r.args, |l, r| eq_generic_args(l, r))
}
pub fn eq_generic_args(l: &GenericArgs, r: &GenericArgs) -> bool {
match (l, r) {
(GenericArgs::AngleBracketed(l), GenericArgs::AngleBracketed(r)) => {
over(&l.args, &r.args, |l, r| eq_angle_arg(l, r))
},
(GenericArgs::Parenthesized(l), GenericArgs::Parenthesized(r)) => {
over(&l.inputs, &r.inputs, |l, r| eq_ty(l, r)) && eq_fn_ret_ty(&l.output, &r.output)
},
_ => false,
}
}
pub fn eq_angle_arg(l: &AngleBracketedArg, r: &AngleBracketedArg) -> bool {
match (l, r) {
(AngleBracketedArg::Arg(l), AngleBracketedArg::Arg(r)) => eq_generic_arg(l, r),
(AngleBracketedArg::Constraint(l), AngleBracketedArg::Constraint(r)) => eq_assoc_constraint(l, r),
_ => false,
}
}
pub fn eq_generic_arg(l: &GenericArg, r: &GenericArg) -> bool {
match (l, r) {
(GenericArg::Lifetime(l), GenericArg::Lifetime(r)) => eq_id(l.ident, r.ident),
(GenericArg::Type(l), GenericArg::Type(r)) => eq_ty(l, r),
(GenericArg::Const(l), GenericArg::Const(r)) => eq_expr(&l.value, &r.value),
_ => false,
}
}
pub fn eq_expr_opt(l: &Option<P<Expr>>, r: &Option<P<Expr>>) -> bool {
both(l, r, |l, r| eq_expr(l, r))
}
pub fn eq_expr(l: &Expr, r: &Expr) -> bool {
use ExprKind::*;
if !over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r)) {
return false;
}
match (&l.kind, &r.kind) {
(Paren(l), _) => eq_expr(l, r),
(_, Paren(r)) => eq_expr(l, r),
(Err, Err) => true,
(Box(l), Box(r)) | (Try(l), Try(r)) | (Await(l), Await(r)) => eq_expr(l, r),
(Array(l), Array(r)) | (Tup(l), Tup(r)) => over(l, r, |l, r| eq_expr(l, r)),
(Repeat(le, ls), Repeat(re, rs)) => eq_expr(le, re) && eq_expr(&ls.value, &rs.value),
(Call(lc, la), Call(rc, ra)) => eq_expr(lc, rc) && over(la, ra, |l, r| eq_expr(l, r)),
(MethodCall(lc, la, _), MethodCall(rc, ra, _)) => eq_path_seg(lc, rc) && over(la, ra, |l, r| eq_expr(l, r)),
(Binary(lo, ll, lr), Binary(ro, rl, rr)) => lo.node == ro.node && eq_expr(ll, rl) && eq_expr(lr, rr),
(Unary(lo, l), Unary(ro, r)) => mem::discriminant(lo) == mem::discriminant(ro) && eq_expr(l, r),
(Lit(l), Lit(r)) => l.kind == r.kind,
(Cast(l, lt), Cast(r, rt)) | (Type(l, lt), Type(r, rt)) => eq_expr(l, r) && eq_ty(lt, rt),
(Let(lp, le), Let(rp, re)) => eq_pat(lp, rp) && eq_expr(le, re),
(If(lc, lt, le), If(rc, rt, re)) => eq_expr(lc, rc) && eq_block(lt, rt) && eq_expr_opt(le, re),
(While(lc, lt, ll), While(rc, rt, rl)) => eq_label(ll, rl) && eq_expr(lc, rc) && eq_block(lt, rt),
(ForLoop(lp, li, lt, ll), ForLoop(rp, ri, rt, rl)) => {
eq_label(ll, rl) && eq_pat(lp, rp) && eq_expr(li, ri) && eq_block(lt, rt)
},
(Loop(lt, ll), Loop(rt, rl)) => eq_label(ll, rl) && eq_block(lt, rt),
(Block(lb, ll), Block(rb, rl)) => eq_label(ll, rl) && eq_block(lb, rb),
(TryBlock(l), TryBlock(r)) => eq_block(l, r),
(Yield(l), Yield(r)) | (Ret(l), Ret(r)) => eq_expr_opt(l, r),
(Break(ll, le), Break(rl, re)) => eq_label(ll, rl) && eq_expr_opt(le, re),
(Continue(ll), Continue(rl)) => eq_label(ll, rl),
(Assign(l1, l2, _), Assign(r1, r2, _)) | (Index(l1, l2), Index(r1, r2)) => eq_expr(l1, r1) && eq_expr(l2, r2),
(AssignOp(lo, lp, lv), AssignOp(ro, rp, rv)) => lo.node == ro.node && eq_expr(lp, rp) && eq_expr(lv, rv),
(Field(lp, lf), Field(rp, rf)) => eq_id(*lf, *rf) && eq_expr(lp, rp),
(Match(ls, la), Match(rs, ra)) => eq_expr(ls, rs) && over(la, ra, |l, r| eq_arm(l, r)),
(Closure(lc, la, lm, lf, lb, _), Closure(rc, ra, rm, rf, rb, _)) => {
lc == rc && la.is_async() == ra.is_async() && lm == rm && eq_fn_decl(lf, rf) && eq_expr(lb, rb)
},
(Async(lc, _, lb), Async(rc, _, rb)) => lc == rc && eq_block(lb, rb),
(Range(lf, lt, ll), Range(rf, rt, rl)) => ll == rl && eq_expr_opt(lf, rf) && eq_expr_opt(lt, rt),
(AddrOf(lbk, lm, le), AddrOf(rbk, rm, re)) => lbk == rbk && lm == rm && eq_expr(le, re),
(Path(lq, lp), Path(rq, rp)) => both(lq, rq, |l, r| eq_qself(l, r)) && eq_path(lp, rp),
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
(Struct(lp, lfs, lb), Struct(rp, rfs, rb)) => {
eq_path(lp, rp) && eq_expr_opt(lb, rb) && unordered_over(lfs, rfs, |l, r| eq_field(l, r))
},
_ => false,
}
}
pub fn eq_field(l: &Field, r: &Field) -> bool {
l.is_placeholder == r.is_placeholder
&& eq_id(l.ident, r.ident)
&& eq_expr(&l.expr, &r.expr)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
}
pub fn eq_arm(l: &Arm, r: &Arm) -> bool {
l.is_placeholder == r.is_placeholder
&& eq_pat(&l.pat, &r.pat)
&& eq_expr(&l.body, &r.body)
&& eq_expr_opt(&l.guard, &r.guard)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
}
pub fn eq_label(l: &Option<Label>, r: &Option<Label>) -> bool {
both(l, r, |l, r| eq_id(l.ident, r.ident))
}
pub fn eq_block(l: &Block, r: &Block) -> bool {
l.rules == r.rules && over(&l.stmts, &r.stmts, |l, r| eq_stmt(l, r))
}
pub fn eq_stmt(l: &Stmt, r: &Stmt) -> bool {
use StmtKind::*;
match (&l.kind, &r.kind) {
(Local(l), Local(r)) => {
eq_pat(&l.pat, &r.pat)
&& both(&l.ty, &r.ty, |l, r| eq_ty(l, r))
&& eq_expr_opt(&l.init, &r.init)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
},
(Item(l), Item(r)) => eq_item(l, r, eq_item_kind),
(Expr(l), Expr(r)) | (Semi(l), Semi(r)) => eq_expr(l, r),
(Empty, Empty) => true,
(MacCall(l), MacCall(r)) => l.1 == r.1 && eq_mac_call(&l.0, &r.0) && over(&l.2, &r.2, |l, r| eq_attr(l, r)),
_ => false,
}
}
pub fn eq_item<K>(l: &Item<K>, r: &Item<K>, mut eq_kind: impl FnMut(&K, &K) -> bool) -> bool {
eq_id(l.ident, r.ident)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
&& eq_vis(&l.vis, &r.vis)
&& eq_kind(&l.kind, &r.kind)
}
pub fn eq_item_kind(l: &ItemKind, r: &ItemKind) -> bool {
use ItemKind::*;
match (l, r) {
(ExternCrate(l), ExternCrate(r)) => l == r,
(Use(l), Use(r)) => eq_use_tree(l, r),
(Static(lt, lm, le), Static(rt, rm, re)) => lm == rm && eq_ty(lt, rt) && eq_expr_opt(le, re),
(Const(ld, lt, le), Const(rd, rt, re)) => eq_defaultness(*ld, *rd) && eq_ty(lt, rt) && eq_expr_opt(le, re),
(Fn(ld, lf, lg, lb), Fn(rd, rf, rg, rb)) => {
eq_defaultness(*ld, *rd) && eq_fn_sig(lf, rf) && eq_generics(lg, rg) && both(lb, rb, |l, r| eq_block(l, r))
},
(Mod(l), Mod(r)) => l.inline == r.inline && over(&l.items, &r.items, |l, r| eq_item(l, r, eq_item_kind)),
(ForeignMod(l), ForeignMod(r)) => {
both(&l.abi, &r.abi, |l, r| eq_str_lit(l, r))
&& over(&l.items, &r.items, |l, r| eq_item(l, r, eq_foreign_item_kind))
},
(TyAlias(ld, lg, lb, lt), TyAlias(rd, rg, rb, rt)) => {
eq_defaultness(*ld, *rd)
&& eq_generics(lg, rg)
&& over(lb, rb, |l, r| eq_generic_bound(l, r))
&& both(lt, rt, |l, r| eq_ty(l, r))
},
(Enum(le, lg), Enum(re, rg)) => {
over(&le.variants, &re.variants, |l, r| eq_variant(l, r)) && eq_generics(lg, rg)
},
(Struct(lv, lg), Struct(rv, rg)) | (Union(lv, lg), Union(rv, rg)) => {
eq_variant_data(lv, rv) && eq_generics(lg, rg)
},
(Trait(la, lu, lg, lb, li), Trait(ra, ru, rg, rb, ri)) => {
la == ra
&& matches!(lu, Unsafe::No) == matches!(ru, Unsafe::No)
&& eq_generics(lg, rg)
&& over(lb, rb, |l, r| eq_generic_bound(l, r))
&& over(li, ri, |l, r| eq_item(l, r, eq_assoc_item_kind))
},
(TraitAlias(lg, lb), TraitAlias(rg, rb)) => eq_generics(lg, rg) && over(lb, rb, |l, r| eq_generic_bound(l, r)),
(
Impl {
unsafety: lu,
polarity: lp,
defaultness: ld,
constness: lc,
generics: lg,
of_trait: lot,
self_ty: lst,
items: li,
},
Impl {
unsafety: ru,
polarity: rp,
defaultness: rd,
constness: rc,
generics: rg,
of_trait: rot,
self_ty: rst,
items: ri,
},
) => {
matches!(lu, Unsafe::No) == matches!(ru, Unsafe::No)
&& matches!(lp, ImplPolarity::Positive) == matches!(rp, ImplPolarity::Positive)
&& eq_defaultness(*ld, *rd)
&& matches!(lc, ast::Const::No) == matches!(rc, ast::Const::No)
&& eq_generics(lg, rg)
&& both(lot, rot, |l, r| eq_path(&l.path, &r.path))
&& eq_ty(lst, rst)
&& over(li, ri, |l, r| eq_item(l, r, eq_assoc_item_kind))
},
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
(MacroDef(l), MacroDef(r)) => l.macro_rules == r.macro_rules && eq_mac_args(&l.body, &r.body),
_ => false,
}
}
pub fn eq_foreign_item_kind(l: &ForeignItemKind, r: &ForeignItemKind) -> bool {
use ForeignItemKind::*;
match (l, r) {
(Static(lt, lm, le), Static(rt, rm, re)) => lm == rm && eq_ty(lt, rt) && eq_expr_opt(le, re),
(Fn(ld, lf, lg, lb), Fn(rd, rf, rg, rb)) => {
eq_defaultness(*ld, *rd) && eq_fn_sig(lf, rf) && eq_generics(lg, rg) && both(lb, rb, |l, r| eq_block(l, r))
},
(TyAlias(ld, lg, lb, lt), TyAlias(rd, rg, rb, rt)) => {
eq_defaultness(*ld, *rd)
&& eq_generics(lg, rg)
&& over(lb, rb, |l, r| eq_generic_bound(l, r))
&& both(lt, rt, |l, r| eq_ty(l, r))
},
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
_ => false,
}
}
pub fn eq_assoc_item_kind(l: &AssocItemKind, r: &AssocItemKind) -> bool {
use AssocItemKind::*;
match (l, r) {
(Const(ld, lt, le), Const(rd, rt, re)) => eq_defaultness(*ld, *rd) && eq_ty(lt, rt) && eq_expr_opt(le, re),
(Fn(ld, lf, lg, lb), Fn(rd, rf, rg, rb)) => {
eq_defaultness(*ld, *rd) && eq_fn_sig(lf, rf) && eq_generics(lg, rg) && both(lb, rb, |l, r| eq_block(l, r))
},
(TyAlias(ld, lg, lb, lt), TyAlias(rd, rg, rb, rt)) => {
eq_defaultness(*ld, *rd)
&& eq_generics(lg, rg)
&& over(lb, rb, |l, r| eq_generic_bound(l, r))
&& both(lt, rt, |l, r| eq_ty(l, r))
},
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
_ => false,
}
}
pub fn eq_variant(l: &Variant, r: &Variant) -> bool {
l.is_placeholder == r.is_placeholder
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
&& eq_vis(&l.vis, &r.vis)
&& eq_id(l.ident, r.ident)
&& eq_variant_data(&l.data, &r.data)
&& both(&l.disr_expr, &r.disr_expr, |l, r| eq_expr(&l.value, &r.value))
}
pub fn eq_variant_data(l: &VariantData, r: &VariantData) -> bool {
use VariantData::*;
match (l, r) {
(Unit(_), Unit(_)) => true,
(Struct(l, _), Struct(r, _)) | (Tuple(l, _), Tuple(r, _)) => over(l, r, |l, r| eq_struct_field(l, r)),
_ => false,
}
}
pub fn eq_struct_field(l: &StructField, r: &StructField) -> bool {
l.is_placeholder == r.is_placeholder
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
&& eq_vis(&l.vis, &r.vis)
&& both(&l.ident, &r.ident, |l, r| eq_id(*l, *r))
&& eq_ty(&l.ty, &r.ty)
}
pub fn eq_fn_sig(l: &FnSig, r: &FnSig) -> bool {
eq_fn_decl(&l.decl, &r.decl) && eq_fn_header(&l.header, &r.header)
}
pub fn eq_fn_header(l: &FnHeader, r: &FnHeader) -> bool {
matches!(l.unsafety, Unsafe::No) == matches!(r.unsafety, Unsafe::No)
&& l.asyncness.is_async() == r.asyncness.is_async()
&& matches!(l.constness, Const::No) == matches!(r.constness, Const::No)
&& eq_ext(&l.ext, &r.ext)
}
pub fn eq_generics(l: &Generics, r: &Generics) -> bool {
over(&l.params, &r.params, |l, r| eq_generic_param(l, r))
&& over(&l.where_clause.predicates, &r.where_clause.predicates, |l, r| {
eq_where_predicate(l, r)
})
}
pub fn eq_where_predicate(l: &WherePredicate, r: &WherePredicate) -> bool {
use WherePredicate::*;
match (l, r) {
(BoundPredicate(l), BoundPredicate(r)) => {
over(&l.bound_generic_params, &r.bound_generic_params, |l, r| {
eq_generic_param(l, r)
}) && eq_ty(&l.bounded_ty, &r.bounded_ty)
&& over(&l.bounds, &r.bounds, |l, r| eq_generic_bound(l, r))
},
(RegionPredicate(l), RegionPredicate(r)) => {
eq_id(l.lifetime.ident, r.lifetime.ident) && over(&l.bounds, &r.bounds, |l, r| eq_generic_bound(l, r))
},
(EqPredicate(l), EqPredicate(r)) => eq_ty(&l.lhs_ty, &r.lhs_ty) && eq_ty(&l.rhs_ty, &r.rhs_ty),
_ => false,
}
}
pub fn eq_use_tree(l: &UseTree, r: &UseTree) -> bool {
eq_path(&l.prefix, &r.prefix) && eq_use_tree_kind(&l.kind, &r.kind)
}
pub fn eq_use_tree_kind(l: &UseTreeKind, r: &UseTreeKind) -> bool {
use UseTreeKind::*;
match (l, r) {
(Glob, Glob) => true,
(Simple(l, _, _), Simple(r, _, _)) => both(l, r, |l, r| eq_id(*l, *r)),
(Nested(l), Nested(r)) => over(l, r, |(l, _), (r, _)| eq_use_tree(l, r)),
_ => false,
}
}
pub fn eq_defaultness(l: Defaultness, r: Defaultness) -> bool {
matches!((l, r), (Defaultness::Final, Defaultness::Final) | (Defaultness::Default(_), Defaultness::Default(_)))
}
pub fn eq_vis(l: &Visibility, r: &Visibility) -> bool {
use VisibilityKind::*;
match (&l.node, &r.node) {
(Public, Public) | (Inherited, Inherited) | (Crate(_), Crate(_)) => true,
(Restricted { path: l, .. }, Restricted { path: r, .. }) => eq_path(l, r),
_ => false,
}
}
pub fn eq_fn_decl(l: &FnDecl, r: &FnDecl) -> bool {
eq_fn_ret_ty(&l.output, &r.output)
&& over(&l.inputs, &r.inputs, |l, r| {
l.is_placeholder == r.is_placeholder
&& eq_pat(&l.pat, &r.pat)
&& eq_ty(&l.ty, &r.ty)
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
})
}
pub fn eq_fn_ret_ty(l: &FnRetTy, r: &FnRetTy) -> bool {
match (l, r) {
(FnRetTy::Default(_), FnRetTy::Default(_)) => true,
(FnRetTy::Ty(l), FnRetTy::Ty(r)) => eq_ty(l, r),
_ => false,
}
}
pub fn eq_ty(l: &Ty, r: &Ty) -> bool {
use TyKind::*;
match (&l.kind, &r.kind) {
(Paren(l), _) => eq_ty(l, r),
(_, Paren(r)) => eq_ty(l, r),
(Never, Never) | (Infer, Infer) | (ImplicitSelf, ImplicitSelf) | (Err, Err) | (CVarArgs, CVarArgs) => true,
(Slice(l), Slice(r)) => eq_ty(l, r),
(Array(le, ls), Array(re, rs)) => eq_ty(le, re) && eq_expr(&ls.value, &rs.value),
(Ptr(l), Ptr(r)) => l.mutbl == r.mutbl && eq_ty(&l.ty, &r.ty),
(Rptr(ll, l), Rptr(rl, r)) => {
both(ll, rl, |l, r| eq_id(l.ident, r.ident)) && l.mutbl == r.mutbl && eq_ty(&l.ty, &r.ty)
},
(BareFn(l), BareFn(r)) => {
l.unsafety == r.unsafety
&& eq_ext(&l.ext, &r.ext)
&& over(&l.generic_params, &r.generic_params, |l, r| eq_generic_param(l, r))
&& eq_fn_decl(&l.decl, &r.decl)
},
(Tup(l), Tup(r)) => over(l, r, |l, r| eq_ty(l, r)),
(Path(lq, lp), Path(rq, rp)) => both(lq, rq, |l, r| eq_qself(l, r)) && eq_path(lp, rp),
(TraitObject(lg, ls), TraitObject(rg, rs)) => ls == rs && over(lg, rg, |l, r| eq_generic_bound(l, r)),
(ImplTrait(_, lg), ImplTrait(_, rg)) => over(lg, rg, |l, r| eq_generic_bound(l, r)),
(Typeof(l), Typeof(r)) => eq_expr(&l.value, &r.value),
(MacCall(l), MacCall(r)) => eq_mac_call(l, r),
_ => false,
}
}
pub fn eq_ext(l: &Extern, r: &Extern) -> bool {
use Extern::*;
match (l, r) {
(None, None) | (Implicit, Implicit) => true,
(Explicit(l), Explicit(r)) => eq_str_lit(l, r),
_ => false,
}
}
pub fn eq_str_lit(l: &StrLit, r: &StrLit) -> bool {
l.style == r.style && l.symbol == r.symbol && l.suffix == r.suffix
}
pub fn eq_poly_ref_trait(l: &PolyTraitRef, r: &PolyTraitRef) -> bool {
eq_path(&l.trait_ref.path, &r.trait_ref.path)
&& over(&l.bound_generic_params, &r.bound_generic_params, |l, r| {
eq_generic_param(l, r)
})
}
pub fn eq_generic_param(l: &GenericParam, r: &GenericParam) -> bool {
use GenericParamKind::*;
l.is_placeholder == r.is_placeholder
&& eq_id(l.ident, r.ident)
&& over(&l.bounds, &r.bounds, |l, r| eq_generic_bound(l, r))
&& match (&l.kind, &r.kind) {
(Lifetime, Lifetime) => true,
(Type { default: l }, Type { default: r }) => both(l, r, |l, r| eq_ty(l, r)),
(Const { ty: l, kw_span: _ }, Const { ty: r, kw_span: _ }) => eq_ty(l, r),
_ => false,
}
&& over(&l.attrs, &r.attrs, |l, r| eq_attr(l, r))
}
pub fn eq_generic_bound(l: &GenericBound, r: &GenericBound) -> bool {
use GenericBound::*;
match (l, r) {
(Trait(ptr1, tbm1), Trait(ptr2, tbm2)) => tbm1 == tbm2 && eq_poly_ref_trait(ptr1, ptr2),
(Outlives(l), Outlives(r)) => eq_id(l.ident, r.ident),
_ => false,
}
}
pub fn eq_assoc_constraint(l: &AssocTyConstraint, r: &AssocTyConstraint) -> bool {
use AssocTyConstraintKind::*;
eq_id(l.ident, r.ident)
&& match (&l.kind, &r.kind) {
(Equality { ty: l }, Equality { ty: r }) => eq_ty(l, r),
(Bound { bounds: l }, Bound { bounds: r }) => over(l, r, |l, r| eq_generic_bound(l, r)),
_ => false,
}
}
pub fn eq_mac_call(l: &MacCall, r: &MacCall) -> bool {
eq_path(&l.path, &r.path) && eq_mac_args(&l.args, &r.args)
}
pub fn eq_attr(l: &Attribute, r: &Attribute) -> bool {
use AttrKind::*;
l.style == r.style
&& match (&l.kind, &r.kind) {
(DocComment(l1, l2), DocComment(r1, r2)) => l1 == r1 && l2 == r2,
(Normal(l), Normal(r)) => eq_path(&l.path, &r.path) && eq_mac_args(&l.args, &r.args),
_ => false,
}
}
pub fn eq_mac_args(l: &MacArgs, r: &MacArgs) -> bool {
use MacArgs::*;
match (l, r) {
(Empty, Empty) => true,
(Delimited(_, ld, lts), Delimited(_, rd, rts)) => ld == rd && lts.eq_unspanned(rts),
(Eq(_, lts), Eq(_, rts)) => lts.eq_unspanned(rts),
_ => false,
}
}