impl PartialEq for Constant {
fn eq(&self, other: &Self) -> bool {
match (self, other) {
- (&Constant::Str(ref ls), &Constant::Str(ref rs)) => ls == rs,
- (&Constant::Binary(ref l), &Constant::Binary(ref r)) => l == r,
- (&Constant::Char(l), &Constant::Char(r)) => l == r,
- (&Constant::Int(l), &Constant::Int(r)) => l == r,
- (&Constant::F64(l), &Constant::F64(r)) => {
+ (&Self::Str(ref ls), &Self::Str(ref rs)) => ls == rs,
+ (&Self::Binary(ref l), &Self::Binary(ref r)) => l == r,
+ (&Self::Char(l), &Self::Char(r)) => l == r,
+ (&Self::Int(l), &Self::Int(r)) => l == r,
+ (&Self::F64(l), &Self::F64(r)) => {
// We want `Fw32 == FwAny` and `FwAny == Fw64`, and by transitivity we must have
// `Fw32 == Fw64`, so don’t compare them.
// `to_bits` is required to catch non-matching 0.0, -0.0, and NaNs.
l.to_bits() == r.to_bits()
},
- (&Constant::F32(l), &Constant::F32(r)) => {
+ (&Self::F32(l), &Self::F32(r)) => {
// We want `Fw32 == FwAny` and `FwAny == Fw64`, and by transitivity we must have
// `Fw32 == Fw64`, so don’t compare them.
// `to_bits` is required to catch non-matching 0.0, -0.0, and NaNs.
f64::from(l).to_bits() == f64::from(r).to_bits()
},
- (&Constant::Bool(l), &Constant::Bool(r)) => l == r,
- (&Constant::Vec(ref l), &Constant::Vec(ref r)) | (&Constant::Tuple(ref l), &Constant::Tuple(ref r)) => {
- l == r
- },
- (&Constant::Repeat(ref lv, ref ls), &Constant::Repeat(ref rv, ref rs)) => ls == rs && lv == rv,
+ (&Self::Bool(l), &Self::Bool(r)) => l == r,
+ (&Self::Vec(ref l), &Self::Vec(ref r)) | (&Self::Tuple(ref l), &Self::Tuple(ref r)) => l == r,
+ (&Self::Repeat(ref lv, ref ls), &Self::Repeat(ref rv, ref rs)) => ls == rs && lv == rv,
// TODO: are there inter-type equalities?
_ => false,
}
{
std::mem::discriminant(self).hash(state);
match *self {
- Constant::Str(ref s) => {
+ Self::Str(ref s) => {
s.hash(state);
},
- Constant::Binary(ref b) => {
+ Self::Binary(ref b) => {
b.hash(state);
},
- Constant::Char(c) => {
+ Self::Char(c) => {
c.hash(state);
},
- Constant::Int(i) => {
+ Self::Int(i) => {
i.hash(state);
},
- Constant::F32(f) => {
+ Self::F32(f) => {
f64::from(f).to_bits().hash(state);
},
- Constant::F64(f) => {
+ Self::F64(f) => {
f.to_bits().hash(state);
},
- Constant::Bool(b) => {
+ Self::Bool(b) => {
b.hash(state);
},
- Constant::Vec(ref v) | Constant::Tuple(ref v) => {
+ Self::Vec(ref v) | Self::Tuple(ref v) => {
v.hash(state);
},
- Constant::Repeat(ref c, l) => {
+ Self::Repeat(ref c, l) => {
c.hash(state);
l.hash(state);
},
- Constant::RawPtr(u) => {
+ Self::RawPtr(u) => {
u.hash(state);
},
- Constant::Err(ref s) => {
+ Self::Err(ref s) => {
s.hash(state);
},
}
impl Constant {
pub fn partial_cmp(tcx: TyCtxt<'_>, cmp_type: Ty<'_>, left: &Self, right: &Self) -> Option<Ordering> {
match (left, right) {
- (&Constant::Str(ref ls), &Constant::Str(ref rs)) => Some(ls.cmp(rs)),
- (&Constant::Char(ref l), &Constant::Char(ref r)) => Some(l.cmp(r)),
- (&Constant::Int(l), &Constant::Int(r)) => {
+ (&Self::Str(ref ls), &Self::Str(ref rs)) => Some(ls.cmp(rs)),
+ (&Self::Char(ref l), &Self::Char(ref r)) => Some(l.cmp(r)),
+ (&Self::Int(l), &Self::Int(r)) => {
if let ty::Int(int_ty) = cmp_type.sty {
Some(sext(tcx, l, int_ty).cmp(&sext(tcx, r, int_ty)))
} else {
Some(l.cmp(&r))
}
},
- (&Constant::F64(l), &Constant::F64(r)) => l.partial_cmp(&r),
- (&Constant::F32(l), &Constant::F32(r)) => l.partial_cmp(&r),
- (&Constant::Bool(ref l), &Constant::Bool(ref r)) => Some(l.cmp(r)),
- (&Constant::Tuple(ref l), &Constant::Tuple(ref r)) | (&Constant::Vec(ref l), &Constant::Vec(ref r)) => l
+ (&Self::F64(l), &Self::F64(r)) => l.partial_cmp(&r),
+ (&Self::F32(l), &Self::F32(r)) => l.partial_cmp(&r),
+ (&Self::Bool(ref l), &Self::Bool(ref r)) => Some(l.cmp(r)),
+ (&Self::Tuple(ref l), &Self::Tuple(ref r)) | (&Self::Vec(ref l), &Self::Vec(ref r)) => l
.iter()
.zip(r.iter())
.map(|(li, ri)| Self::partial_cmp(tcx, cmp_type, li, ri))
.find(|r| r.map_or(true, |o| o != Ordering::Equal))
.unwrap_or_else(|| Some(l.len().cmp(&r.len()))),
- (&Constant::Repeat(ref lv, ref ls), &Constant::Repeat(ref rv, ref rs)) => {
+ (&Self::Repeat(ref lv, ref ls), &Self::Repeat(ref rv, ref rs)) => {
match Self::partial_cmp(tcx, cmp_type, lv, rv) {
Some(Equal) => Some(ls.cmp(rs)),
x => x,
}
/// Parses a `LitKind` to a `Constant`.
-pub fn lit_to_constant<'tcx>(lit: &LitKind, ty: Ty<'tcx>) -> Constant {
+pub fn lit_to_constant(lit: &LitKind, ty: Ty<'_>) -> Constant {
use syntax::ast::*;
match *lit {
ExprKind::Tup(ref tup) => self.multi(tup).map(Constant::Tuple),
ExprKind::Repeat(ref value, _) => {
let n = match self.tables.expr_ty(e).sty {
- ty::Array(_, n) => n.assert_usize(self.lcx.tcx).expect("array length"),
+ ty::Array(_, n) => n.eval_usize(self.lcx.tcx, self.lcx.param_env),
_ => span_bug!(e.span, "typeck error"),
};
self.expr(value).map(|v| Constant::Repeat(Box::new(v), n))
},
ConstValue::Slice { data, start, end } => match result.ty.sty {
ty::Ref(_, tam, _) => match tam.sty {
- ty::Str => String::from_utf8(data.bytes[start..end].to_owned())
- .ok()
- .map(Constant::Str),
+ ty::Str => String::from_utf8(
+ data.inspect_with_undef_and_ptr_outside_interpreter(start..end)
+ .to_owned(),
+ )
+ .ok()
+ .map(Constant::Str),
_ => None,
},
_ => None,