-use crate::consts::{constant_simple, constant_context};
-use crate::rustc::lint::LateContext;
-use crate::rustc::hir::*;
-use crate::rustc::ty::{TypeckTables};
-use std::hash::{Hash, Hasher};
-use std::collections::hash_map::DefaultHasher;
-use crate::syntax::ast::Name;
-use crate::syntax::ptr::P;
+use crate::consts::{constant_context, constant_simple};
use crate::utils::differing_macro_contexts;
+use rustc::hir::*;
+use rustc::lint::LateContext;
+use rustc::ty::TypeckTables;
+use std::collections::hash_map::DefaultHasher;
+use std::hash::{Hash, Hasher};
+use syntax::ast::Name;
+use syntax::ptr::P;
/// Type used to check whether two ast are the same. This is different from the
/// operator
}
}
- /// Check whether two statements are the same.
+ /// Checks whether two statements are the same.
pub fn eq_stmt(&mut self, left: &Stmt, right: &Stmt) -> bool {
match (&left.node, &right.node) {
- (&StmtKind::Decl(ref l, _), &StmtKind::Decl(ref r, _)) => {
- if let (&DeclKind::Local(ref l), &DeclKind::Local(ref r)) = (&l.node, &r.node) {
- both(&l.ty, &r.ty, |l, r| self.eq_ty(l, r)) && both(&l.init, &r.init, |l, r| self.eq_expr(l, r))
- } else {
- false
- }
+ (&StmtKind::Local(ref l), &StmtKind::Local(ref r)) => {
+ self.eq_pat(&l.pat, &r.pat)
+ && both(&l.ty, &r.ty, |l, r| self.eq_ty(l, r))
+ && both(&l.init, &r.init, |l, r| self.eq_expr(l, r))
},
- (&StmtKind::Expr(ref l, _), &StmtKind::Expr(ref r, _)) | (&StmtKind::Semi(ref l, _), &StmtKind::Semi(ref r, _)) => {
+ (&StmtKind::Expr(ref l), &StmtKind::Expr(ref r)) | (&StmtKind::Semi(ref l), &StmtKind::Semi(ref r)) => {
self.eq_expr(l, r)
},
_ => false,
}
}
- /// Check whether two blocks are the same.
+ /// Checks whether two blocks are the same.
pub fn eq_block(&mut self, left: &Block, right: &Block) -> bool {
over(&left.stmts, &right.stmts, |l, r| self.eq_stmt(l, r))
&& both(&left.expr, &right.expr, |l, r| self.eq_expr(l, r))
}
+ #[allow(clippy::similar_names)]
pub fn eq_expr(&mut self, left: &Expr, right: &Expr) -> bool {
if self.ignore_fn && differing_macro_contexts(left.span, right.span) {
return false;
}
- if let (Some(l), Some(r)) = (constant_simple(self.cx, self.tables, left), constant_simple(self.cx, self.tables, right)) {
+ if let (Some(l), Some(r)) = (
+ constant_simple(self.cx, self.tables, left),
+ constant_simple(self.cx, self.tables, right),
+ ) {
if l == r {
return true;
}
}
match (&left.node, &right.node) {
- (&ExprKind::AddrOf(l_mut, ref le), &ExprKind::AddrOf(r_mut, ref re)) => l_mut == r_mut && self.eq_expr(le, re),
+ (&ExprKind::AddrOf(l_mut, ref le), &ExprKind::AddrOf(r_mut, ref re)) => {
+ l_mut == r_mut && self.eq_expr(le, re)
+ },
(&ExprKind::Continue(li), &ExprKind::Continue(ri)) => {
both(&li.label, &ri.label, |l, r| l.ident.as_str() == r.ident.as_str())
},
- (&ExprKind::Assign(ref ll, ref lr), &ExprKind::Assign(ref rl, ref rr)) => self.eq_expr(ll, rl) && self.eq_expr(lr, rr),
+ (&ExprKind::Assign(ref ll, ref lr), &ExprKind::Assign(ref rl, ref rr)) => {
+ self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
+ },
(&ExprKind::AssignOp(ref lo, ref ll, ref lr), &ExprKind::AssignOp(ref ro, ref rl, ref rr)) => {
lo.node == ro.node && self.eq_expr(ll, rl) && self.eq_expr(lr, rr)
},
(&ExprKind::Call(ref l_fun, ref l_args), &ExprKind::Call(ref r_fun, ref r_args)) => {
!self.ignore_fn && self.eq_expr(l_fun, r_fun) && self.eq_exprs(l_args, r_args)
},
- (&ExprKind::Cast(ref lx, ref lt), &ExprKind::Cast(ref rx, ref rt)) |
- (&ExprKind::Type(ref lx, ref lt), &ExprKind::Type(ref rx, ref rt)) => self.eq_expr(lx, rx) && self.eq_ty(lt, rt),
+ (&ExprKind::Cast(ref lx, ref lt), &ExprKind::Cast(ref rx, ref rt))
+ | (&ExprKind::Type(ref lx, ref lt), &ExprKind::Type(ref rx, ref rt)) => {
+ self.eq_expr(lx, rx) && self.eq_ty(lt, rt)
+ },
(&ExprKind::Field(ref l_f_exp, ref l_f_ident), &ExprKind::Field(ref 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(ref la, ref li), &ExprKind::Index(ref ra, ref ri)) => self.eq_expr(la, ra) && self.eq_expr(li, ri),
- (&ExprKind::If(ref lc, ref lt, ref le), &ExprKind::If(ref rc, ref rt, ref re)) => {
- self.eq_expr(lc, rc) && self.eq_expr(&**lt, &**rt) && both(le, re, |l, r| self.eq_expr(l, r))
+ (&ExprKind::Index(ref la, ref li), &ExprKind::Index(ref ra, ref ri)) => {
+ self.eq_expr(la, ra) && self.eq_expr(li, ri)
},
(&ExprKind::Lit(ref l), &ExprKind::Lit(ref r)) => l.node == r.node,
(&ExprKind::Loop(ref lb, ref ll, ref lls), &ExprKind::Loop(ref rb, ref rl, ref rls)) => {
lls == rls && self.eq_block(lb, rb) && both(ll, rl, |l, r| l.ident.as_str() == r.ident.as_str())
},
(&ExprKind::Match(ref le, ref la, ref ls), &ExprKind::Match(ref re, ref ra, ref rs)) => {
- ls == rs && self.eq_expr(le, re) && over(la, ra, |l, r| {
- self.eq_expr(&l.body, &r.body) && both(&l.guard, &r.guard, |l, r| self.eq_guard(l, r))
- && over(&l.pats, &r.pats, |l, r| self.eq_pat(l, r))
- })
+ ls == rs
+ && self.eq_expr(le, re)
+ && over(la, ra, |l, r| {
+ self.eq_expr(&l.body, &r.body)
+ && both(&l.guard, &r.guard, |l, r| self.eq_guard(l, r))
+ && over(&l.pats, &r.pats, |l, r| self.eq_pat(l, r))
+ })
},
(&ExprKind::MethodCall(ref l_path, _, ref l_args), &ExprKind::MethodCall(ref r_path, _, ref r_args)) => {
!self.ignore_fn && self.eq_path_segment(l_path, r_path) && self.eq_exprs(l_args, r_args)
},
(&ExprKind::Repeat(ref le, ref ll_id), &ExprKind::Repeat(ref re, ref rl_id)) => {
let mut celcx = constant_context(self.cx, self.cx.tcx.body_tables(ll_id.body));
- let ll = celcx.expr(&self.cx.tcx.hir.body(ll_id.body).value);
+ let ll = celcx.expr(&self.cx.tcx.hir().body(ll_id.body).value);
let mut celcx = constant_context(self.cx, self.cx.tcx.body_tables(rl_id.body));
- let rl = celcx.expr(&self.cx.tcx.hir.body(rl_id.body).value);
+ let rl = celcx.expr(&self.cx.tcx.hir().body(rl_id.body).value);
self.eq_expr(le, re) && ll == rl
},
(&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(ref l_path, ref lf, ref lo), &ExprKind::Struct(ref r_path, ref rf, ref ro)) => {
- self.eq_qpath(l_path, r_path) && both(lo, ro, |l, r| self.eq_expr(l, r))
+ self.eq_qpath(l_path, r_path)
+ && both(lo, ro, |l, r| self.eq_expr(l, r))
&& over(lf, rf, |l, r| self.eq_field(l, r))
},
(&ExprKind::Tup(ref l_tup), &ExprKind::Tup(ref r_tup)) => self.eq_exprs(l_tup, r_tup),
(&ExprKind::Unary(l_op, ref le), &ExprKind::Unary(r_op, ref re)) => l_op == r_op && self.eq_expr(le, re),
(&ExprKind::Array(ref l), &ExprKind::Array(ref r)) => self.eq_exprs(l, r),
(&ExprKind::While(ref lc, ref lb, ref ll), &ExprKind::While(ref rc, ref rb, ref rl)) => {
- self.eq_expr(lc, rc) && self.eq_block(lb, rb) && both(ll, rl, |l, r| l.ident.as_str() == r.ident.as_str())
+ self.eq_expr(lc, rc)
+ && self.eq_block(lb, rb)
+ && both(ll, rl, |l, r| l.ident.as_str() == r.ident.as_str())
},
+ (&ExprKind::DropTemps(ref le), &ExprKind::DropTemps(ref re)) => self.eq_expr(le, re),
_ => false,
}
}
left.name == right.name
}
- /// Check whether two patterns are the same.
+ /// Checks whether two patterns are the same.
pub fn eq_pat(&mut self, left: &Pat, right: &Pat) -> bool {
match (&left.node, &right.node) {
(&PatKind::Box(ref l), &PatKind::Box(ref r)) => self.eq_pat(l, r),
(&PatKind::TupleStruct(ref lp, ref la, ls), &PatKind::TupleStruct(ref rp, ref ra, rs)) => {
self.eq_qpath(lp, rp) && over(la, ra, |l, r| self.eq_pat(l, r)) && ls == rs
},
- (&PatKind::Binding(ref lb, _, ref li, ref lp), &PatKind::Binding(ref rb, _, ref ri, ref rp)) => {
+ (&PatKind::Binding(ref lb, .., ref li, ref lp), &PatKind::Binding(ref rb, .., ref ri, ref rp)) => {
lb == rb && li.name.as_str() == ri.name.as_str() && both(lp, rp, |l, r| self.eq_pat(l, r))
},
(&PatKind::Path(ref l), &PatKind::Path(ref r)) => self.eq_qpath(l, r),
},
(&PatKind::Ref(ref le, ref lm), &PatKind::Ref(ref re, ref rm)) => lm == rm && self.eq_pat(le, re),
(&PatKind::Slice(ref ls, ref li, ref le), &PatKind::Slice(ref rs, ref ri, ref re)) => {
- over(ls, rs, |l, r| self.eq_pat(l, r)) && over(le, re, |l, r| self.eq_pat(l, r))
+ 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,
}
}
+ #[allow(clippy::similar_names)]
fn eq_qpath(&mut self, left: &QPath, right: &QPath) -> bool {
match (left, right) {
(&QPath::Resolved(ref lty, ref lpath), &QPath::Resolved(ref rty, ref rpath)) => {
&& 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),
- )
+ && both(&Some(&left.bindings[0].ty), &Some(&right.bindings[0].ty), |l, r| {
+ self.eq_ty(l, r)
+ })
} else {
false
}
self.eq_ty_kind(&left.node, &right.node)
}
+ #[allow(clippy::similar_names)]
pub fn eq_ty_kind(&mut self, left: &TyKind, right: &TyKind) -> bool {
match (left, right) {
(&TyKind::Slice(ref l_vec), &TyKind::Slice(ref r_vec)) => self.eq_ty(l_vec, r_vec),
let mut celcx = constant_context(self.cx, self.cx.tcx.body_tables(ll_id.body));
self.tables = self.cx.tcx.body_tables(ll_id.body);
- let ll = celcx.expr(&self.cx.tcx.hir.body(ll_id.body).value);
+ let ll = celcx.expr(&self.cx.tcx.hir().body(ll_id.body).value);
let mut celcx = constant_context(self.cx, self.cx.tcx.body_tables(rl_id.body));
self.tables = self.cx.tcx.body_tables(rl_id.body);
- let rl = celcx.expr(&self.cx.tcx.hir.body(rl_id.body).value);
+ let rl = celcx.expr(&self.cx.tcx.hir().body(rl_id.body).value);
let eq_ty = self.eq_ty(lt, rt);
self.tables = full_table;
eq_ty && ll == rl
},
- (&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::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)
},
fn swap_binop<'a>(binop: BinOpKind, lhs: &'a Expr, rhs: &'a Expr) -> Option<(BinOpKind, &'a Expr, &'a Expr)> {
match binop {
- BinOpKind::Add |
- BinOpKind::Mul |
- BinOpKind::Eq |
- BinOpKind::Ne |
- BinOpKind::BitAnd |
- BinOpKind::BitXor |
- BinOpKind::BitOr => Some((binop, rhs, lhs)),
+ BinOpKind::Add
+ | BinOpKind::Mul
+ | 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::Shl |
- BinOpKind::Shr |
- BinOpKind::Rem |
- BinOpKind::Sub |
- BinOpKind::Div |
- BinOpKind::And |
- BinOpKind::Or => None,
+ BinOpKind::Shl
+ | BinOpKind::Shr
+ | BinOpKind::Rem
+ | BinOpKind::Sub
+ | BinOpKind::Div
+ | BinOpKind::And
+ | BinOpKind::Or => None,
}
}
-/// Check if the two `Option`s are both `None` or some equal values as per
+/// Checks if the two `Option`s are both `None` or some equal values as per
/// `eq_fn`.
fn both<X, F>(l: &Option<X>, r: &Option<X>, mut eq_fn: F) -> bool
where
.map_or_else(|| r.is_none(), |x| r.as_ref().map_or(false, |y| eq_fn(x, y)))
}
-/// Check if two slices are equal as per `eq_fn`.
+/// Checks if two slices are equal as per `eq_fn`.
fn over<X, F>(left: &[X], right: &[X], mut eq_fn: F) -> bool
where
F: FnMut(&X, &X) -> bool,
left.len() == right.len() && left.iter().zip(right).all(|(x, y)| eq_fn(x, y))
}
-
/// 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.
BlockCheckMode::UnsafeBlock(_) => 1,
BlockCheckMode::PushUnsafeBlock(_) => 2,
BlockCheckMode::PopUnsafeBlock(_) => 3,
- }.hash(&mut self.s);
+ }
+ .hash(&mut self.s);
}
- #[allow(clippy::many_single_char_names)]
+ #[allow(clippy::many_single_char_names, clippy::too_many_lines)]
pub fn hash_expr(&mut self, e: &Expr) {
- if let Some(e) = constant_simple(self.cx, self.tables, e) {
+ let simple_const = constant_simple(self.cx, self.tables, 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.is_some().hash(&mut self.s);
+
+ if let Some(e) = simple_const {
return e.hash(&mut self.s);
}
+ std::mem::discriminant(&e.node).hash(&mut self.s);
+
match e.node {
ExprKind::AddrOf(m, ref e) => {
- let c: fn(_, _) -> _ = ExprKind::AddrOf;
- c.hash(&mut self.s);
m.hash(&mut self.s);
self.hash_expr(e);
},
ExprKind::Continue(i) => {
- let c: fn(_) -> _ = ExprKind::Continue;
- c.hash(&mut self.s);
if let Some(i) = i.label {
self.hash_name(i.ident.name);
}
},
ExprKind::Yield(ref e) => {
- let c: fn(_) -> _ = ExprKind::Yield;
- c.hash(&mut self.s);
self.hash_expr(e);
},
ExprKind::Assign(ref l, ref r) => {
- let c: fn(_, _) -> _ = ExprKind::Assign;
- c.hash(&mut self.s);
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::AssignOp(ref o, ref l, ref r) => {
- let c: fn(_, _, _) -> _ = ExprKind::AssignOp;
- c.hash(&mut self.s);
o.hash(&mut self.s);
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::Block(ref b, _) => {
- let c: fn(_, _) -> _ = ExprKind::Block;
- c.hash(&mut self.s);
self.hash_block(b);
},
ExprKind::Binary(op, ref l, ref r) => {
- let c: fn(_, _, _) -> _ = ExprKind::Binary;
- c.hash(&mut self.s);
op.node.hash(&mut self.s);
self.hash_expr(l);
self.hash_expr(r);
},
ExprKind::Break(i, ref j) => {
- let c: fn(_, _) -> _ = ExprKind::Break;
- c.hash(&mut self.s);
if let Some(i) = i.label {
self.hash_name(i.ident.name);
}
}
},
ExprKind::Box(ref e) => {
- let c: fn(_) -> _ = ExprKind::Box;
- c.hash(&mut self.s);
self.hash_expr(e);
},
ExprKind::Call(ref fun, ref args) => {
- let c: fn(_, _) -> _ = ExprKind::Call;
- c.hash(&mut self.s);
self.hash_expr(fun);
self.hash_exprs(args);
},
ExprKind::Cast(ref e, ref _ty) => {
- let c: fn(_, _) -> _ = ExprKind::Cast;
- c.hash(&mut self.s);
self.hash_expr(e);
// TODO: _ty
},
ExprKind::Closure(cap, _, eid, _, _) => {
- let c: fn(_, _, _, _, _) -> _ = ExprKind::Closure;
- c.hash(&mut self.s);
match cap {
CaptureClause::CaptureByValue => 0,
CaptureClause::CaptureByRef => 1,
- }.hash(&mut self.s);
- self.hash_expr(&self.cx.tcx.hir.body(eid).value);
+ }
+ .hash(&mut self.s);
+ self.hash_expr(&self.cx.tcx.hir().body(eid).value);
},
ExprKind::Field(ref e, ref f) => {
- let c: fn(_, _) -> _ = ExprKind::Field;
- c.hash(&mut self.s);
self.hash_expr(e);
self.hash_name(f.name);
},
ExprKind::Index(ref a, ref i) => {
- let c: fn(_, _) -> _ = ExprKind::Index;
- c.hash(&mut self.s);
self.hash_expr(a);
self.hash_expr(i);
},
- ExprKind::InlineAsm(..) => {
- let c: fn(_, _, _) -> _ = ExprKind::InlineAsm;
- c.hash(&mut self.s);
- },
- ExprKind::If(ref cond, ref t, ref e) => {
- let c: fn(_, _, _) -> _ = ExprKind::If;
- c.hash(&mut self.s);
- self.hash_expr(cond);
- self.hash_expr(&**t);
- if let Some(ref e) = *e {
- self.hash_expr(e);
- }
- },
+ ExprKind::InlineAsm(..) => {},
ExprKind::Lit(ref l) => {
- let c: fn(_) -> _ = ExprKind::Lit;
- c.hash(&mut self.s);
l.hash(&mut self.s);
},
ExprKind::Loop(ref b, ref i, _) => {
- let c: fn(_, _, _) -> _ = ExprKind::Loop;
- c.hash(&mut self.s);
self.hash_block(b);
if let Some(i) = *i {
self.hash_name(i.ident.name);
}
},
ExprKind::Match(ref e, ref arms, ref s) => {
- let c: fn(_, _, _) -> _ = ExprKind::Match;
- c.hash(&mut self.s);
self.hash_expr(e);
for arm in arms {
s.hash(&mut self.s);
},
ExprKind::MethodCall(ref path, ref _tys, ref args) => {
- let c: fn(_, _, _) -> _ = ExprKind::MethodCall;
- c.hash(&mut self.s);
self.hash_name(path.ident.name);
self.hash_exprs(args);
},
ExprKind::Repeat(ref e, ref l_id) => {
- let c: fn(_, _) -> _ = ExprKind::Repeat;
- c.hash(&mut self.s);
self.hash_expr(e);
let full_table = self.tables;
self.tables = self.cx.tcx.body_tables(l_id.body);
- self.hash_expr(&self.cx.tcx.hir.body(l_id.body).value);
+ self.hash_expr(&self.cx.tcx.hir().body(l_id.body).value);
self.tables = full_table;
},
ExprKind::Ret(ref e) => {
- let c: fn(_) -> _ = ExprKind::Ret;
- c.hash(&mut self.s);
if let Some(ref e) = *e {
self.hash_expr(e);
}
},
ExprKind::Path(ref qpath) => {
- let c: fn(_) -> _ = ExprKind::Path;
- c.hash(&mut self.s);
self.hash_qpath(qpath);
},
ExprKind::Struct(ref path, ref fields, ref expr) => {
- let c: fn(_, _, _) -> _ = ExprKind::Struct;
- c.hash(&mut self.s);
-
self.hash_qpath(path);
for f in fields {
}
},
ExprKind::Tup(ref tup) => {
- let c: fn(_) -> _ = ExprKind::Tup;
- c.hash(&mut self.s);
self.hash_exprs(tup);
},
ExprKind::Type(ref e, ref _ty) => {
- let c: fn(_, _) -> _ = ExprKind::Type;
- c.hash(&mut self.s);
self.hash_expr(e);
// TODO: _ty
},
ExprKind::Unary(lop, ref le) => {
- let c: fn(_, _) -> _ = ExprKind::Unary;
- c.hash(&mut self.s);
-
lop.hash(&mut self.s);
self.hash_expr(le);
},
ExprKind::Array(ref v) => {
- let c: fn(_) -> _ = ExprKind::Array;
- c.hash(&mut self.s);
-
self.hash_exprs(v);
},
ExprKind::While(ref cond, ref b, l) => {
- let c: fn(_, _, _) -> _ = ExprKind::While;
- c.hash(&mut self.s);
-
self.hash_expr(cond);
self.hash_block(b);
if let Some(l) = l {
self.hash_name(l.ident.name);
}
},
+ ExprKind::Err => {},
+ ExprKind::DropTemps(ref e) => {
+ self.hash_expr(e);
+ },
}
}
self.hash_name(path.ident.name);
},
}
- // self.cx.tables.qpath_def(p, id).hash(&mut self.s);
+ // self.cx.tables.qpath_res(p, id).hash(&mut self.s);
}
pub fn hash_path(&mut self, p: &Path) {
}
pub fn hash_stmt(&mut self, b: &Stmt) {
- match b.node {
- StmtKind::Decl(ref decl, _) => {
- let c: fn(_, _) -> _ = StmtKind::Decl;
- c.hash(&mut self.s);
+ std::mem::discriminant(&b.node).hash(&mut self.s);
- if let DeclKind::Local(ref local) = decl.node {
- if let Some(ref init) = local.init {
- self.hash_expr(init);
- }
+ match b.node {
+ StmtKind::Local(ref local) => {
+ if let Some(ref init) = local.init {
+ self.hash_expr(init);
}
},
- StmtKind::Expr(ref expr, _) => {
- let c: fn(_, _) -> _ = StmtKind::Expr;
- c.hash(&mut self.s);
+ StmtKind::Item(..) => {},
+ StmtKind::Expr(ref expr) => {
self.hash_expr(expr);
},
- StmtKind::Semi(ref expr, _) => {
- let c: fn(_, _) -> _ = StmtKind::Semi;
- c.hash(&mut self.s);
+ StmtKind::Semi(ref expr) => {
self.hash_expr(expr);
},
}
pub fn hash_guard(&mut self, g: &Guard) {
match g {
Guard::If(ref expr) => {
- let c: fn(_) -> _ = Guard::If;
- c.hash(&mut self.s);
self.hash_expr(expr);
- }
+ },
}
}
}