rust/clippy_utils/src/hir_utils.rs
2021-09-14 09:59:06 -07:00

967 lines
38 KiB
Rust

use crate::consts::{constant_context, constant_simple};
use crate::differing_macro_contexts;
use crate::source::snippet_opt;
use rustc_ast::ast::InlineAsmTemplatePiece;
use rustc_data_structures::fx::FxHasher;
use rustc_hir::def::Res;
use rustc_hir::HirIdMap;
use rustc_hir::{
BinOpKind, Block, BodyId, Expr, ExprField, ExprKind, FnRetTy, GenericArg, GenericArgs, Guard, HirId,
InlineAsmOperand, Lifetime, LifetimeName, ParamName, Pat, PatField, PatKind, Path, PathSegment, QPath, Stmt,
StmtKind, Ty, TyKind, TypeBinding,
};
use rustc_lexer::{tokenize, TokenKind};
use rustc_lint::LateContext;
use rustc_middle::ty::TypeckResults;
use rustc_span::Symbol;
use std::hash::{Hash, Hasher};
/// Type used to check whether two ast are the same. This is different from the
/// operator
/// `==` on ast types as this operator would compare true equality with ID and
/// span.
///
/// Note that some expressions kinds are not considered but could be added.
pub struct SpanlessEq<'a, 'tcx> {
/// Context used to evaluate constant expressions.
cx: &'a LateContext<'tcx>,
maybe_typeck_results: Option<&'tcx TypeckResults<'tcx>>,
allow_side_effects: bool,
expr_fallback: Option<Box<dyn FnMut(&Expr<'_>, &Expr<'_>) -> bool + 'a>>,
}
impl<'a, 'tcx> SpanlessEq<'a, 'tcx> {
pub fn new(cx: &'a LateContext<'tcx>) -> Self {
Self {
cx,
maybe_typeck_results: cx.maybe_typeck_results(),
allow_side_effects: true,
expr_fallback: None,
}
}
/// Consider expressions containing potential side effects as not equal.
pub fn deny_side_effects(self) -> Self {
Self {
allow_side_effects: false,
..self
}
}
pub fn expr_fallback(self, expr_fallback: impl FnMut(&Expr<'_>, &Expr<'_>) -> bool + 'a) -> Self {
Self {
expr_fallback: Some(Box::new(expr_fallback)),
..self
}
}
/// Use this method to wrap comparisons that may involve inter-expression context.
/// See `self.locals`.
pub fn inter_expr(&mut self) -> HirEqInterExpr<'_, 'a, 'tcx> {
HirEqInterExpr {
inner: self,
locals: HirIdMap::default(),
}
}
#[allow(dead_code)]
pub fn eq_block(&mut self, left: &Block<'_>, right: &Block<'_>) -> bool {
self.inter_expr().eq_block(left, right)
}
pub fn eq_expr(&mut self, left: &Expr<'_>, right: &Expr<'_>) -> bool {
self.inter_expr().eq_expr(left, right)
}
pub fn eq_path_segment(&mut self, left: &PathSegment<'_>, right: &PathSegment<'_>) -> bool {
self.inter_expr().eq_path_segment(left, right)
}
pub fn eq_path_segments(&mut self, left: &[PathSegment<'_>], right: &[PathSegment<'_>]) -> bool {
self.inter_expr().eq_path_segments(left, right)
}
}
pub struct HirEqInterExpr<'a, 'b, 'tcx> {
inner: &'a mut SpanlessEq<'b, 'tcx>,
// When binding are declared, the binding ID in the left expression is mapped to the one on the
// right. For example, when comparing `{ let x = 1; x + 2 }` and `{ let y = 1; y + 2 }`,
// these blocks are considered equal since `x` is mapped to `y`.
locals: HirIdMap<HirId>,
}
impl HirEqInterExpr<'_, '_, '_> {
pub fn eq_stmt(&mut self, left: &Stmt<'_>, right: &Stmt<'_>) -> bool {
match (&left.kind, &right.kind) {
(&StmtKind::Local(l), &StmtKind::Local(r)) => {
// This additional check ensures that the type of the locals are equivalent even if the init
// expression or type have some inferred parts.
if let Some(typeck) = self.inner.maybe_typeck_results {
let l_ty = typeck.pat_ty(l.pat);
let r_ty = typeck.pat_ty(r.pat);
if !rustc_middle::ty::TyS::same_type(l_ty, r_ty) {
return false;
}
}
// eq_pat adds the HirIds to the locals map. We therefor call it last to make sure that
// these only get added if the init and type is equal.
both(&l.init, &r.init, |l, r| self.eq_expr(l, r))
&& both(&l.ty, &r.ty, |l, r| self.eq_ty(l, r))
&& self.eq_pat(l.pat, r.pat)
},
(&StmtKind::Expr(l), &StmtKind::Expr(r)) | (&StmtKind::Semi(l), &StmtKind::Semi(r)) => self.eq_expr(l, r),
_ => false,
}
}
/// Checks whether two blocks are the same.
fn eq_block(&mut self, left: &Block<'_>, right: &Block<'_>) -> bool {
match (left.stmts, left.expr, right.stmts, right.expr) {
([], None, [], None) => {
// For empty blocks, check to see if the tokens are equal. This will catch the case where a macro
// expanded to nothing, or the cfg attribute was used.
let (left, right) = match (
snippet_opt(self.inner.cx, left.span),
snippet_opt(self.inner.cx, right.span),
) {
(Some(left), Some(right)) => (left, right),
_ => return true,
};
let mut left_pos = 0;
let left = tokenize(&left)
.map(|t| {
let end = left_pos + t.len;
let s = &left[left_pos..end];
left_pos = end;
(t, s)
})
.filter(|(t, _)| {
!matches!(
t.kind,
TokenKind::LineComment { .. } | TokenKind::BlockComment { .. } | TokenKind::Whitespace
)
})
.map(|(_, s)| s);
let mut right_pos = 0;
let right = tokenize(&right)
.map(|t| {
let end = right_pos + t.len;
let s = &right[right_pos..end];
right_pos = end;
(t, s)
})
.filter(|(t, _)| {
!matches!(
t.kind,
TokenKind::LineComment { .. } | TokenKind::BlockComment { .. } | TokenKind::Whitespace
)
})
.map(|(_, s)| s);
left.eq(right)
},
_ => {
over(left.stmts, right.stmts, |l, r| self.eq_stmt(l, r))
&& both(&left.expr, &right.expr, |l, r| self.eq_expr(l, r))
},
}
}
pub fn eq_body(&mut self, left: BodyId, right: BodyId) -> bool {
let cx = self.inner.cx;
let eval_const = |body| constant_context(cx, cx.tcx.typeck_body(body)).expr(&cx.tcx.hir().body(body).value);
eval_const(left) == eval_const(right)
}
#[allow(clippy::similar_names)]
pub fn eq_expr(&mut self, left: &Expr<'_>, right: &Expr<'_>) -> bool {
if !self.inner.allow_side_effects && differing_macro_contexts(left.span, right.span) {
return false;
}
if let Some(typeck_results) = self.inner.maybe_typeck_results {
if let (Some(l), Some(r)) = (
constant_simple(self.inner.cx, typeck_results, left),
constant_simple(self.inner.cx, typeck_results, right),
) {
if l == r {
return true;
}
}
}
let is_eq = match (
&reduce_exprkind(self.inner.cx, &left.kind),
&reduce_exprkind(self.inner.cx, &right.kind),
) {
(&ExprKind::AddrOf(lb, l_mut, le), &ExprKind::AddrOf(rb, r_mut, re)) => {
lb == rb && l_mut == r_mut && self.eq_expr(le, re)
},
(&ExprKind::Continue(li), &ExprKind::Continue(ri)) => {
both(&li.label, &ri.label, |l, r| l.ident.name == r.ident.name)
},
(&ExprKind::Assign(ll, lr, _), &ExprKind::Assign(rl, rr, _)) => {
self.inner.allow_side_effects && self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
},
(&ExprKind::AssignOp(ref lo, ll, lr), &ExprKind::AssignOp(ref ro, rl, rr)) => {
self.inner.allow_side_effects && lo.node == ro.node && self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
},
(&ExprKind::Block(l, _), &ExprKind::Block(r, _)) => self.eq_block(l, r),
(&ExprKind::Binary(l_op, ll, lr), &ExprKind::Binary(r_op, rl, rr)) => {
l_op.node == r_op.node && self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
|| swap_binop(l_op.node, ll, lr).map_or(false, |(l_op, ll, lr)| {
l_op == r_op.node && self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
})
},
(&ExprKind::Break(li, ref le), &ExprKind::Break(ri, ref re)) => {
both(&li.label, &ri.label, |l, r| l.ident.name == r.ident.name)
&& both(le, re, |l, r| self.eq_expr(l, r))
},
(&ExprKind::Box(l), &ExprKind::Box(r)) => self.eq_expr(l, r),
(&ExprKind::Call(l_fun, l_args), &ExprKind::Call(r_fun, r_args)) => {
self.inner.allow_side_effects && self.eq_expr(l_fun, r_fun) && self.eq_exprs(l_args, r_args)
},
(&ExprKind::Cast(lx, lt), &ExprKind::Cast(rx, rt)) | (&ExprKind::Type(lx, lt), &ExprKind::Type(rx, rt)) => {
self.eq_expr(lx, rx) && self.eq_ty(lt, rt)
},
(&ExprKind::Field(l_f_exp, ref l_f_ident), &ExprKind::Field(r_f_exp, ref r_f_ident)) => {
l_f_ident.name == r_f_ident.name && self.eq_expr(l_f_exp, r_f_exp)
},
(&ExprKind::Index(la, li), &ExprKind::Index(ra, ri)) => self.eq_expr(la, ra) && self.eq_expr(li, ri),
(&ExprKind::If(lc, lt, ref le), &ExprKind::If(rc, rt, ref re)) => {
self.eq_expr(lc, rc) && self.eq_expr(&**lt, &**rt) && both(le, re, |l, r| self.eq_expr(l, r))
},
(&ExprKind::Let(lp, le, _), &ExprKind::Let(rp, re, _)) => self.eq_pat(lp, rp) && self.eq_expr(le, re),
(&ExprKind::Lit(ref l), &ExprKind::Lit(ref r)) => l.node == r.node,
(&ExprKind::Loop(lb, ref ll, ref lls, _), &ExprKind::Loop(rb, ref rl, ref rls, _)) => {
lls == rls && self.eq_block(lb, rb) && both(ll, rl, |l, r| l.ident.name == r.ident.name)
},
(&ExprKind::Match(le, la, ref ls), &ExprKind::Match(re, ra, ref rs)) => {
ls == rs
&& self.eq_expr(le, re)
&& over(la, ra, |l, r| {
self.eq_pat(l.pat, r.pat)
&& both(&l.guard, &r.guard, |l, r| self.eq_guard(l, r))
&& self.eq_expr(l.body, r.body)
})
},
(&ExprKind::MethodCall(l_path, _, l_args, _), &ExprKind::MethodCall(r_path, _, r_args, _)) => {
self.inner.allow_side_effects && self.eq_path_segment(l_path, r_path) && self.eq_exprs(l_args, r_args)
},
(&ExprKind::Repeat(le, ref ll_id), &ExprKind::Repeat(re, ref rl_id)) => {
self.eq_expr(le, re) && self.eq_body(ll_id.body, rl_id.body)
},
(&ExprKind::Ret(ref l), &ExprKind::Ret(ref r)) => both(l, r, |l, r| self.eq_expr(l, r)),
(&ExprKind::Path(ref l), &ExprKind::Path(ref r)) => self.eq_qpath(l, r),
(&ExprKind::Struct(l_path, lf, ref lo), &ExprKind::Struct(r_path, rf, ref ro)) => {
self.eq_qpath(l_path, r_path)
&& both(lo, ro, |l, r| self.eq_expr(l, r))
&& over(lf, rf, |l, r| self.eq_expr_field(l, r))
},
(&ExprKind::Tup(l_tup), &ExprKind::Tup(r_tup)) => self.eq_exprs(l_tup, r_tup),
(&ExprKind::Unary(l_op, le), &ExprKind::Unary(r_op, re)) => l_op == r_op && self.eq_expr(le, re),
(&ExprKind::Array(l), &ExprKind::Array(r)) => self.eq_exprs(l, r),
(&ExprKind::DropTemps(le), &ExprKind::DropTemps(re)) => self.eq_expr(le, re),
_ => false,
};
is_eq || self.inner.expr_fallback.as_mut().map_or(false, |f| f(left, right))
}
fn eq_exprs(&mut self, left: &[Expr<'_>], right: &[Expr<'_>]) -> bool {
over(left, right, |l, r| self.eq_expr(l, r))
}
fn eq_expr_field(&mut self, left: &ExprField<'_>, right: &ExprField<'_>) -> bool {
left.ident.name == right.ident.name && self.eq_expr(left.expr, right.expr)
}
fn eq_guard(&mut self, left: &Guard<'_>, right: &Guard<'_>) -> bool {
match (left, right) {
(Guard::If(l), Guard::If(r)) => self.eq_expr(l, r),
(Guard::IfLet(lp, le), Guard::IfLet(rp, re)) => self.eq_pat(lp, rp) && self.eq_expr(le, re),
_ => false,
}
}
fn eq_generic_arg(&mut self, left: &GenericArg<'_>, right: &GenericArg<'_>) -> bool {
match (left, right) {
(GenericArg::Const(l), GenericArg::Const(r)) => self.eq_body(l.value.body, r.value.body),
(GenericArg::Lifetime(l_lt), GenericArg::Lifetime(r_lt)) => Self::eq_lifetime(l_lt, r_lt),
(GenericArg::Type(l_ty), GenericArg::Type(r_ty)) => self.eq_ty(l_ty, r_ty),
(GenericArg::Infer(l_inf), GenericArg::Infer(r_inf)) => self.eq_ty(&l_inf.to_ty(), &r_inf.to_ty()),
_ => false,
}
}
fn eq_lifetime(left: &Lifetime, right: &Lifetime) -> bool {
left.name == right.name
}
fn eq_pat_field(&mut self, left: &PatField<'_>, right: &PatField<'_>) -> bool {
let (PatField { ident: li, pat: lp, .. }, PatField { ident: ri, pat: rp, .. }) = (&left, &right);
li.name == ri.name && self.eq_pat(lp, rp)
}
/// Checks whether two patterns are the same.
fn eq_pat(&mut self, left: &Pat<'_>, right: &Pat<'_>) -> bool {
match (&left.kind, &right.kind) {
(&PatKind::Box(l), &PatKind::Box(r)) => self.eq_pat(l, r),
(&PatKind::Struct(ref lp, la, ..), &PatKind::Struct(ref rp, ra, ..)) => {
self.eq_qpath(lp, rp) && over(la, ra, |l, r| self.eq_pat_field(l, r))
},
(&PatKind::TupleStruct(ref lp, la, ls), &PatKind::TupleStruct(ref rp, ra, rs)) => {
self.eq_qpath(lp, rp) && over(la, ra, |l, r| self.eq_pat(l, r)) && ls == rs
},
(&PatKind::Binding(lb, li, _, ref lp), &PatKind::Binding(rb, ri, _, ref rp)) => {
let eq = lb == rb && both(lp, rp, |l, r| self.eq_pat(l, r));
if eq {
self.locals.insert(li, ri);
}
eq
},
(&PatKind::Path(ref l), &PatKind::Path(ref r)) => self.eq_qpath(l, r),
(&PatKind::Lit(l), &PatKind::Lit(r)) => self.eq_expr(l, r),
(&PatKind::Tuple(l, ls), &PatKind::Tuple(r, rs)) => ls == rs && over(l, r, |l, r| self.eq_pat(l, r)),
(&PatKind::Range(ref ls, ref le, li), &PatKind::Range(ref rs, ref re, ri)) => {
both(ls, rs, |a, b| self.eq_expr(a, b)) && both(le, re, |a, b| self.eq_expr(a, b)) && (li == ri)
},
(&PatKind::Ref(le, ref lm), &PatKind::Ref(re, ref rm)) => lm == rm && self.eq_pat(le, re),
(&PatKind::Slice(ls, ref li, le), &PatKind::Slice(rs, ref ri, re)) => {
over(ls, rs, |l, r| self.eq_pat(l, r))
&& over(le, re, |l, r| self.eq_pat(l, r))
&& both(li, ri, |l, r| self.eq_pat(l, r))
},
(&PatKind::Wild, &PatKind::Wild) => true,
_ => false,
}
}
#[allow(clippy::similar_names)]
fn eq_qpath(&mut self, left: &QPath<'_>, right: &QPath<'_>) -> bool {
match (left, right) {
(&QPath::Resolved(ref lty, lpath), &QPath::Resolved(ref rty, rpath)) => {
both(lty, rty, |l, r| self.eq_ty(l, r)) && self.eq_path(lpath, rpath)
},
(&QPath::TypeRelative(lty, lseg), &QPath::TypeRelative(rty, rseg)) => {
self.eq_ty(lty, rty) && self.eq_path_segment(lseg, rseg)
},
(&QPath::LangItem(llang_item, _), &QPath::LangItem(rlang_item, _)) => llang_item == rlang_item,
_ => false,
}
}
fn eq_path(&mut self, left: &Path<'_>, right: &Path<'_>) -> bool {
match (left.res, right.res) {
(Res::Local(l), Res::Local(r)) => l == r || self.locals.get(&l) == Some(&r),
(Res::Local(_), _) | (_, Res::Local(_)) => false,
_ => over(left.segments, right.segments, |l, r| self.eq_path_segment(l, r)),
}
}
fn eq_path_parameters(&mut self, left: &GenericArgs<'_>, right: &GenericArgs<'_>) -> bool {
if !(left.parenthesized || right.parenthesized) {
over(left.args, right.args, |l, r| self.eq_generic_arg(l, r)) // FIXME(flip1995): may not work
&& over(left.bindings, right.bindings, |l, r| self.eq_type_binding(l, r))
} else if left.parenthesized && right.parenthesized {
over(left.inputs(), right.inputs(), |l, r| self.eq_ty(l, r))
&& both(&Some(&left.bindings[0].ty()), &Some(&right.bindings[0].ty()), |l, r| {
self.eq_ty(l, r)
})
} else {
false
}
}
pub fn eq_path_segments(&mut self, left: &[PathSegment<'_>], right: &[PathSegment<'_>]) -> bool {
left.len() == right.len() && left.iter().zip(right).all(|(l, r)| self.eq_path_segment(l, r))
}
pub fn eq_path_segment(&mut self, left: &PathSegment<'_>, right: &PathSegment<'_>) -> bool {
// The == of idents doesn't work with different contexts,
// we have to be explicit about hygiene
left.ident.name == right.ident.name && both(&left.args, &right.args, |l, r| self.eq_path_parameters(l, r))
}
#[allow(clippy::similar_names)]
fn eq_ty(&mut self, left: &Ty<'_>, right: &Ty<'_>) -> bool {
match (&left.kind, &right.kind) {
(&TyKind::Slice(l_vec), &TyKind::Slice(r_vec)) => self.eq_ty(l_vec, r_vec),
(&TyKind::Array(lt, ref ll_id), &TyKind::Array(rt, ref rl_id)) => {
self.eq_ty(lt, rt) && self.eq_body(ll_id.body, rl_id.body)
},
(&TyKind::Ptr(ref l_mut), &TyKind::Ptr(ref r_mut)) => {
l_mut.mutbl == r_mut.mutbl && self.eq_ty(&*l_mut.ty, &*r_mut.ty)
},
(&TyKind::Rptr(_, ref l_rmut), &TyKind::Rptr(_, ref r_rmut)) => {
l_rmut.mutbl == r_rmut.mutbl && self.eq_ty(&*l_rmut.ty, &*r_rmut.ty)
},
(&TyKind::Path(ref l), &TyKind::Path(ref r)) => self.eq_qpath(l, r),
(&TyKind::Tup(l), &TyKind::Tup(r)) => over(l, r, |l, r| self.eq_ty(l, r)),
(&TyKind::Infer, &TyKind::Infer) => true,
_ => false,
}
}
fn eq_type_binding(&mut self, left: &TypeBinding<'_>, right: &TypeBinding<'_>) -> bool {
left.ident.name == right.ident.name && self.eq_ty(left.ty(), right.ty())
}
}
/// Some simple reductions like `{ return }` => `return`
fn reduce_exprkind<'hir>(cx: &LateContext<'_>, kind: &'hir ExprKind<'hir>) -> &'hir ExprKind<'hir> {
if let ExprKind::Block(block, _) = kind {
match (block.stmts, block.expr) {
// From an `if let` expression without an `else` block. The arm for the implicit wild pattern is an empty
// block with an empty span.
([], None) if block.span.is_empty() => &ExprKind::Tup(&[]),
// `{}` => `()`
([], None) => match snippet_opt(cx, block.span) {
// Don't reduce if there are any tokens contained in the braces
Some(snip)
if tokenize(&snip)
.map(|t| t.kind)
.filter(|t| {
!matches!(
t,
TokenKind::LineComment { .. } | TokenKind::BlockComment { .. } | TokenKind::Whitespace
)
})
.ne([TokenKind::OpenBrace, TokenKind::CloseBrace].iter().copied()) =>
{
kind
},
_ => &ExprKind::Tup(&[]),
},
([], Some(expr)) => match expr.kind {
// `{ return .. }` => `return ..`
ExprKind::Ret(..) => &expr.kind,
_ => kind,
},
([stmt], None) => match stmt.kind {
StmtKind::Expr(expr) | StmtKind::Semi(expr) => match expr.kind {
// `{ return ..; }` => `return ..`
ExprKind::Ret(..) => &expr.kind,
_ => kind,
},
_ => kind,
},
_ => kind,
}
} else {
kind
}
}
fn swap_binop<'a>(
binop: BinOpKind,
lhs: &'a Expr<'a>,
rhs: &'a Expr<'a>,
) -> Option<(BinOpKind, &'a Expr<'a>, &'a Expr<'a>)> {
match binop {
BinOpKind::Add | BinOpKind::Eq | BinOpKind::Ne | BinOpKind::BitAnd | BinOpKind::BitXor | BinOpKind::BitOr => {
Some((binop, rhs, lhs))
},
BinOpKind::Lt => Some((BinOpKind::Gt, rhs, lhs)),
BinOpKind::Le => Some((BinOpKind::Ge, rhs, lhs)),
BinOpKind::Ge => Some((BinOpKind::Le, rhs, lhs)),
BinOpKind::Gt => Some((BinOpKind::Lt, rhs, lhs)),
BinOpKind::Mul // Not always commutative, e.g. with matrices. See issue #5698
| BinOpKind::Shl
| BinOpKind::Shr
| BinOpKind::Rem
| BinOpKind::Sub
| BinOpKind::Div
| BinOpKind::And
| BinOpKind::Or => None,
}
}
/// Checks if the two `Option`s are both `None` or some equal values as per
/// `eq_fn`.
pub fn both<X>(l: &Option<X>, r: &Option<X>, mut eq_fn: impl FnMut(&X, &X) -> bool) -> bool {
l.as_ref()
.map_or_else(|| r.is_none(), |x| r.as_ref().map_or(false, |y| eq_fn(x, y)))
}
/// Checks if two slices are equal as per `eq_fn`.
pub fn over<X>(left: &[X], right: &[X], mut eq_fn: impl FnMut(&X, &X) -> bool) -> bool {
left.len() == right.len() && left.iter().zip(right).all(|(x, y)| eq_fn(x, y))
}
/// Counts how many elements of the slices are equal as per `eq_fn`.
pub fn count_eq<X: Sized>(
left: &mut dyn Iterator<Item = X>,
right: &mut dyn Iterator<Item = X>,
mut eq_fn: impl FnMut(&X, &X) -> bool,
) -> usize {
left.zip(right).take_while(|(l, r)| eq_fn(l, r)).count()
}
/// Checks if two expressions evaluate to the same value, and don't contain any side effects.
pub fn eq_expr_value(cx: &LateContext<'_>, left: &Expr<'_>, right: &Expr<'_>) -> bool {
SpanlessEq::new(cx).deny_side_effects().eq_expr(left, right)
}
/// Type used to hash an ast element. This is different from the `Hash` trait
/// on ast types as this
/// trait would consider IDs and spans.
///
/// All expressions kind are hashed, but some might have a weaker hash.
pub struct SpanlessHash<'a, 'tcx> {
/// Context used to evaluate constant expressions.
cx: &'a LateContext<'tcx>,
maybe_typeck_results: Option<&'tcx TypeckResults<'tcx>>,
s: FxHasher,
}
impl<'a, 'tcx> SpanlessHash<'a, 'tcx> {
pub fn new(cx: &'a LateContext<'tcx>) -> Self {
Self {
cx,
maybe_typeck_results: cx.maybe_typeck_results(),
s: FxHasher::default(),
}
}
pub fn finish(self) -> u64 {
self.s.finish()
}
pub fn hash_block(&mut self, b: &Block<'_>) {
for s in b.stmts {
self.hash_stmt(s);
}
if let Some(e) = b.expr {
self.hash_expr(e);
}
std::mem::discriminant(&b.rules).hash(&mut self.s);
}
#[allow(clippy::too_many_lines)]
pub fn hash_expr(&mut self, e: &Expr<'_>) {
let simple_const = self
.maybe_typeck_results
.and_then(|typeck_results| constant_simple(self.cx, typeck_results, e));
// const hashing may result in the same hash as some unrelated node, so add a sort of
// discriminant depending on which path we're choosing next
simple_const.hash(&mut self.s);
if simple_const.is_some() {
return;
}
std::mem::discriminant(&e.kind).hash(&mut self.s);
match e.kind {
ExprKind::AddrOf(kind, m, e) => {
std::mem::discriminant(&kind).hash(&mut self.s);
m.hash(&mut self.s);
self.hash_expr(e);
},
ExprKind::Continue(i) => {
if let Some(i) = i.label {
self.hash_name(i.ident.name);
}
},
ExprKind::Assign(l, r, _) => {
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::AssignOp(ref o, l, r) => {
std::mem::discriminant(&o.node).hash(&mut self.s);
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::Block(b, _) => {
self.hash_block(b);
},
ExprKind::Binary(op, l, r) => {
std::mem::discriminant(&op.node).hash(&mut self.s);
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::Break(i, ref j) => {
if let Some(i) = i.label {
self.hash_name(i.ident.name);
}
if let Some(j) = *j {
self.hash_expr(&*j);
}
},
ExprKind::Box(e) | ExprKind::DropTemps(e) | ExprKind::Yield(e, _) => {
self.hash_expr(e);
},
ExprKind::Call(fun, args) => {
self.hash_expr(fun);
self.hash_exprs(args);
},
ExprKind::Cast(e, ty) | ExprKind::Type(e, ty) => {
self.hash_expr(e);
self.hash_ty(ty);
},
ExprKind::Closure(cap, _, eid, _, _) => {
std::mem::discriminant(&cap).hash(&mut self.s);
// closures inherit TypeckResults
self.hash_expr(&self.cx.tcx.hir().body(eid).value);
},
ExprKind::Field(e, ref f) => {
self.hash_expr(e);
self.hash_name(f.name);
},
ExprKind::Index(a, i) => {
self.hash_expr(a);
self.hash_expr(i);
},
ExprKind::InlineAsm(asm) => {
for piece in asm.template {
match piece {
InlineAsmTemplatePiece::String(s) => s.hash(&mut self.s),
InlineAsmTemplatePiece::Placeholder {
operand_idx,
modifier,
span: _,
} => {
operand_idx.hash(&mut self.s);
modifier.hash(&mut self.s);
},
}
}
asm.options.hash(&mut self.s);
for (op, _op_sp) in asm.operands {
match op {
InlineAsmOperand::In { reg, expr } => {
reg.hash(&mut self.s);
self.hash_expr(expr);
},
InlineAsmOperand::Out { reg, late, expr } => {
reg.hash(&mut self.s);
late.hash(&mut self.s);
if let Some(expr) = expr {
self.hash_expr(expr);
}
},
InlineAsmOperand::InOut { reg, late, expr } => {
reg.hash(&mut self.s);
late.hash(&mut self.s);
self.hash_expr(expr);
},
InlineAsmOperand::SplitInOut {
reg,
late,
in_expr,
out_expr,
} => {
reg.hash(&mut self.s);
late.hash(&mut self.s);
self.hash_expr(in_expr);
if let Some(out_expr) = out_expr {
self.hash_expr(out_expr);
}
},
InlineAsmOperand::Const { anon_const } => self.hash_body(anon_const.body),
InlineAsmOperand::Sym { expr } => self.hash_expr(expr),
}
}
},
ExprKind::Let(pat, expr, _) => {
self.hash_expr(expr);
self.hash_pat(pat);
},
ExprKind::LlvmInlineAsm(..) | ExprKind::Err => {},
ExprKind::Lit(ref l) => {
l.node.hash(&mut self.s);
},
ExprKind::Loop(b, ref i, ..) => {
self.hash_block(b);
if let Some(i) = *i {
self.hash_name(i.ident.name);
}
},
ExprKind::If(cond, then, ref else_opt) => {
self.hash_expr(cond);
self.hash_expr(then);
if let Some(e) = *else_opt {
self.hash_expr(e);
}
},
ExprKind::Match(e, arms, ref s) => {
self.hash_expr(e);
for arm in arms {
self.hash_pat(arm.pat);
if let Some(ref e) = arm.guard {
self.hash_guard(e);
}
self.hash_expr(arm.body);
}
s.hash(&mut self.s);
},
ExprKind::MethodCall(path, ref _tys, args, ref _fn_span) => {
self.hash_name(path.ident.name);
self.hash_exprs(args);
},
ExprKind::ConstBlock(ref l_id) => {
self.hash_body(l_id.body);
},
ExprKind::Repeat(e, ref l_id) => {
self.hash_expr(e);
self.hash_body(l_id.body);
},
ExprKind::Ret(ref e) => {
if let Some(e) = *e {
self.hash_expr(e);
}
},
ExprKind::Path(ref qpath) => {
self.hash_qpath(qpath);
},
ExprKind::Struct(path, fields, ref expr) => {
self.hash_qpath(path);
for f in fields {
self.hash_name(f.ident.name);
self.hash_expr(f.expr);
}
if let Some(e) = *expr {
self.hash_expr(e);
}
},
ExprKind::Tup(tup) => {
self.hash_exprs(tup);
},
ExprKind::Array(v) => {
self.hash_exprs(v);
},
ExprKind::Unary(lop, le) => {
std::mem::discriminant(&lop).hash(&mut self.s);
self.hash_expr(le);
},
}
}
pub fn hash_exprs(&mut self, e: &[Expr<'_>]) {
for e in e {
self.hash_expr(e);
}
}
pub fn hash_name(&mut self, n: Symbol) {
n.hash(&mut self.s);
}
pub fn hash_qpath(&mut self, p: &QPath<'_>) {
match *p {
QPath::Resolved(_, path) => {
self.hash_path(path);
},
QPath::TypeRelative(_, path) => {
self.hash_name(path.ident.name);
},
QPath::LangItem(lang_item, ..) => {
std::mem::discriminant(&lang_item).hash(&mut self.s);
},
}
// self.maybe_typeck_results.unwrap().qpath_res(p, id).hash(&mut self.s);
}
pub fn hash_pat(&mut self, pat: &Pat<'_>) {
std::mem::discriminant(&pat.kind).hash(&mut self.s);
match pat.kind {
PatKind::Binding(ann, _, _, pat) => {
std::mem::discriminant(&ann).hash(&mut self.s);
if let Some(pat) = pat {
self.hash_pat(pat);
}
},
PatKind::Box(pat) => self.hash_pat(pat),
PatKind::Lit(expr) => self.hash_expr(expr),
PatKind::Or(pats) => {
for pat in pats {
self.hash_pat(pat);
}
},
PatKind::Path(ref qpath) => self.hash_qpath(qpath),
PatKind::Range(s, e, i) => {
if let Some(s) = s {
self.hash_expr(s);
}
if let Some(e) = e {
self.hash_expr(e);
}
std::mem::discriminant(&i).hash(&mut self.s);
},
PatKind::Ref(pat, mu) => {
self.hash_pat(pat);
std::mem::discriminant(&mu).hash(&mut self.s);
},
PatKind::Slice(l, m, r) => {
for pat in l {
self.hash_pat(pat);
}
if let Some(pat) = m {
self.hash_pat(pat);
}
for pat in r {
self.hash_pat(pat);
}
},
PatKind::Struct(ref qpath, fields, e) => {
self.hash_qpath(qpath);
for f in fields {
self.hash_name(f.ident.name);
self.hash_pat(f.pat);
}
e.hash(&mut self.s);
},
PatKind::Tuple(pats, e) => {
for pat in pats {
self.hash_pat(pat);
}
e.hash(&mut self.s);
},
PatKind::TupleStruct(ref qpath, pats, e) => {
self.hash_qpath(qpath);
for pat in pats {
self.hash_pat(pat);
}
e.hash(&mut self.s);
},
PatKind::Wild => {},
}
}
pub fn hash_path(&mut self, path: &Path<'_>) {
match path.res {
// constant hash since equality is dependant on inter-expression context
Res::Local(_) => 1_usize.hash(&mut self.s),
_ => {
for seg in path.segments {
self.hash_name(seg.ident.name);
self.hash_generic_args(seg.args().args);
}
},
}
}
pub fn hash_stmt(&mut self, b: &Stmt<'_>) {
std::mem::discriminant(&b.kind).hash(&mut self.s);
match &b.kind {
StmtKind::Local(local) => {
self.hash_pat(local.pat);
if let Some(init) = local.init {
self.hash_expr(init);
}
},
StmtKind::Item(..) => {},
StmtKind::Expr(expr) | StmtKind::Semi(expr) => {
self.hash_expr(expr);
},
}
}
pub fn hash_guard(&mut self, g: &Guard<'_>) {
match g {
Guard::If(expr) | Guard::IfLet(_, expr) => {
self.hash_expr(expr);
},
}
}
pub fn hash_lifetime(&mut self, lifetime: Lifetime) {
std::mem::discriminant(&lifetime.name).hash(&mut self.s);
if let LifetimeName::Param(ref name) = lifetime.name {
std::mem::discriminant(name).hash(&mut self.s);
match name {
ParamName::Plain(ref ident) => {
ident.name.hash(&mut self.s);
},
ParamName::Fresh(ref size) => {
size.hash(&mut self.s);
},
ParamName::Error => {},
}
}
}
pub fn hash_ty(&mut self, ty: &Ty<'_>) {
std::mem::discriminant(&ty.kind).hash(&mut self.s);
self.hash_tykind(&ty.kind);
}
pub fn hash_tykind(&mut self, ty: &TyKind<'_>) {
match ty {
TyKind::Slice(ty) => {
self.hash_ty(ty);
},
TyKind::Array(ty, anon_const) => {
self.hash_ty(ty);
self.hash_body(anon_const.body);
},
TyKind::Ptr(ref mut_ty) => {
self.hash_ty(mut_ty.ty);
mut_ty.mutbl.hash(&mut self.s);
},
TyKind::Rptr(lifetime, ref mut_ty) => {
self.hash_lifetime(*lifetime);
self.hash_ty(mut_ty.ty);
mut_ty.mutbl.hash(&mut self.s);
},
TyKind::BareFn(bfn) => {
bfn.unsafety.hash(&mut self.s);
bfn.abi.hash(&mut self.s);
for arg in bfn.decl.inputs {
self.hash_ty(arg);
}
std::mem::discriminant(&bfn.decl.output).hash(&mut self.s);
match bfn.decl.output {
FnRetTy::DefaultReturn(_) => {},
FnRetTy::Return(ty) => {
self.hash_ty(ty);
},
}
bfn.decl.c_variadic.hash(&mut self.s);
},
TyKind::Tup(ty_list) => {
for ty in *ty_list {
self.hash_ty(ty);
}
},
TyKind::Path(ref qpath) => self.hash_qpath(qpath),
TyKind::OpaqueDef(_, arg_list) => {
self.hash_generic_args(arg_list);
},
TyKind::TraitObject(_, lifetime, _) => {
self.hash_lifetime(*lifetime);
},
TyKind::Typeof(anon_const) => {
self.hash_body(anon_const.body);
},
TyKind::Err | TyKind::Infer | TyKind::Never => {},
}
}
pub fn hash_body(&mut self, body_id: BodyId) {
// swap out TypeckResults when hashing a body
let old_maybe_typeck_results = self.maybe_typeck_results.replace(self.cx.tcx.typeck_body(body_id));
self.hash_expr(&self.cx.tcx.hir().body(body_id).value);
self.maybe_typeck_results = old_maybe_typeck_results;
}
fn hash_generic_args(&mut self, arg_list: &[GenericArg<'_>]) {
for arg in arg_list {
match *arg {
GenericArg::Lifetime(l) => self.hash_lifetime(l),
GenericArg::Type(ref ty) => self.hash_ty(ty),
GenericArg::Const(ref ca) => self.hash_body(ca.value.body),
GenericArg::Infer(ref inf) => self.hash_ty(&inf.to_ty()),
}
}
}
}