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|
//! Unification and canonicalization logic.
use std::borrow::Cow;
use ena::unify::{InPlaceUnificationTable, NoError, UnifyKey, UnifyValue};
use test_utils::tested_by;
use super::{InferenceContext, Obligation};
use crate::{
db::HirDatabase, utils::make_mut_slice, Canonical, InEnvironment, InferTy, ProjectionPredicate,
ProjectionTy, Substs, TraitRef, Ty, TypeCtor, TypeWalk,
};
impl<'a, D: HirDatabase> InferenceContext<'a, D> {
pub(super) fn canonicalizer<'b>(&'b mut self) -> Canonicalizer<'a, 'b, D>
where
'a: 'b,
{
Canonicalizer { ctx: self, free_vars: Vec::new(), var_stack: Vec::new() }
}
}
pub(super) struct Canonicalizer<'a, 'b, D: HirDatabase>
where
'a: 'b,
{
ctx: &'b mut InferenceContext<'a, D>,
free_vars: Vec<InferTy>,
/// A stack of type variables that is used to detect recursive types (which
/// are an error, but we need to protect against them to avoid stack
/// overflows).
var_stack: Vec<TypeVarId>,
}
pub(super) struct Canonicalized<T> {
pub value: Canonical<T>,
free_vars: Vec<InferTy>,
}
impl<'a, 'b, D: HirDatabase> Canonicalizer<'a, 'b, D>
where
'a: 'b,
{
fn add(&mut self, free_var: InferTy) -> usize {
self.free_vars.iter().position(|&v| v == free_var).unwrap_or_else(|| {
let next_index = self.free_vars.len();
self.free_vars.push(free_var);
next_index
})
}
fn do_canonicalize_ty(&mut self, ty: Ty) -> Ty {
ty.fold(&mut |ty| match ty {
Ty::Infer(tv) => {
let inner = tv.to_inner();
if self.var_stack.contains(&inner) {
// recursive type
return tv.fallback_value();
}
if let Some(known_ty) =
self.ctx.table.var_unification_table.inlined_probe_value(inner).known()
{
self.var_stack.push(inner);
let result = self.do_canonicalize_ty(known_ty.clone());
self.var_stack.pop();
result
} else {
let root = self.ctx.table.var_unification_table.find(inner);
let free_var = match tv {
InferTy::TypeVar(_) => InferTy::TypeVar(root),
InferTy::IntVar(_) => InferTy::IntVar(root),
InferTy::FloatVar(_) => InferTy::FloatVar(root),
InferTy::MaybeNeverTypeVar(_) => InferTy::MaybeNeverTypeVar(root),
};
let position = self.add(free_var);
Ty::Bound(position as u32)
}
}
_ => ty,
})
}
fn do_canonicalize_trait_ref(&mut self, mut trait_ref: TraitRef) -> TraitRef {
for ty in make_mut_slice(&mut trait_ref.substs.0) {
*ty = self.do_canonicalize_ty(ty.clone());
}
trait_ref
}
fn into_canonicalized<T>(self, result: T) -> Canonicalized<T> {
Canonicalized {
value: Canonical { value: result, num_vars: self.free_vars.len() },
free_vars: self.free_vars,
}
}
fn do_canonicalize_projection_ty(&mut self, mut projection_ty: ProjectionTy) -> ProjectionTy {
for ty in make_mut_slice(&mut projection_ty.parameters.0) {
*ty = self.do_canonicalize_ty(ty.clone());
}
projection_ty
}
fn do_canonicalize_projection_predicate(
&mut self,
projection: ProjectionPredicate,
) -> ProjectionPredicate {
let ty = self.do_canonicalize_ty(projection.ty);
let projection_ty = self.do_canonicalize_projection_ty(projection.projection_ty);
ProjectionPredicate { ty, projection_ty }
}
// FIXME: add some point, we need to introduce a `Fold` trait that abstracts
// over all the things that can be canonicalized (like Chalk and rustc have)
pub(crate) fn canonicalize_ty(mut self, ty: Ty) -> Canonicalized<Ty> {
let result = self.do_canonicalize_ty(ty);
self.into_canonicalized(result)
}
pub(crate) fn canonicalize_obligation(
mut self,
obligation: InEnvironment<Obligation>,
) -> Canonicalized<InEnvironment<Obligation>> {
let result = match obligation.value {
Obligation::Trait(tr) => Obligation::Trait(self.do_canonicalize_trait_ref(tr)),
Obligation::Projection(pr) => {
Obligation::Projection(self.do_canonicalize_projection_predicate(pr))
}
};
self.into_canonicalized(InEnvironment {
value: result,
environment: obligation.environment,
})
}
}
impl<T> Canonicalized<T> {
pub fn decanonicalize_ty(&self, mut ty: Ty) -> Ty {
ty.walk_mut_binders(
&mut |ty, binders| match ty {
&mut Ty::Bound(idx) => {
if idx as usize >= binders && (idx as usize - binders) < self.free_vars.len() {
*ty = Ty::Infer(self.free_vars[idx as usize - binders]);
}
}
_ => {}
},
0,
);
ty
}
pub fn apply_solution(
&self,
ctx: &mut InferenceContext<'_, impl HirDatabase>,
solution: Canonical<Vec<Ty>>,
) {
// the solution may contain new variables, which we need to convert to new inference vars
let new_vars = Substs((0..solution.num_vars).map(|_| ctx.table.new_type_var()).collect());
for (i, ty) in solution.value.into_iter().enumerate() {
let var = self.free_vars[i];
ctx.table.unify(&Ty::Infer(var), &ty.subst_bound_vars(&new_vars));
}
}
}
pub fn unify(ty1: &Canonical<Ty>, ty2: &Canonical<Ty>) -> Option<Substs> {
let mut table = InferenceTable::new();
let vars =
Substs::builder(ty1.num_vars).fill(std::iter::repeat_with(|| table.new_type_var())).build();
let ty_with_vars = ty1.value.clone().subst_bound_vars(&vars);
if !table.unify(&ty_with_vars, &ty2.value) {
return None;
}
Some(
Substs::builder(ty1.num_vars)
.fill(vars.iter().map(|v| table.resolve_ty_completely(v.clone())))
.build(),
)
}
#[derive(Clone, Debug)]
pub(crate) struct InferenceTable {
pub(super) var_unification_table: InPlaceUnificationTable<TypeVarId>,
}
impl InferenceTable {
pub fn new() -> Self {
InferenceTable { var_unification_table: InPlaceUnificationTable::new() }
}
pub fn new_type_var(&mut self) -> Ty {
Ty::Infer(InferTy::TypeVar(self.var_unification_table.new_key(TypeVarValue::Unknown)))
}
pub fn new_integer_var(&mut self) -> Ty {
Ty::Infer(InferTy::IntVar(self.var_unification_table.new_key(TypeVarValue::Unknown)))
}
pub fn new_float_var(&mut self) -> Ty {
Ty::Infer(InferTy::FloatVar(self.var_unification_table.new_key(TypeVarValue::Unknown)))
}
pub fn new_maybe_never_type_var(&mut self) -> Ty {
Ty::Infer(InferTy::MaybeNeverTypeVar(
self.var_unification_table.new_key(TypeVarValue::Unknown),
))
}
pub fn resolve_ty_completely(&mut self, ty: Ty) -> Ty {
self.resolve_ty_completely_inner(&mut Vec::new(), ty)
}
pub fn resolve_ty_as_possible(&mut self, ty: Ty) -> Ty {
self.resolve_ty_as_possible_inner(&mut Vec::new(), ty)
}
pub fn unify(&mut self, ty1: &Ty, ty2: &Ty) -> bool {
self.unify_inner(ty1, ty2, 0)
}
pub fn unify_substs(&mut self, substs1: &Substs, substs2: &Substs, depth: usize) -> bool {
substs1.0.iter().zip(substs2.0.iter()).all(|(t1, t2)| self.unify_inner(t1, t2, depth))
}
fn unify_inner(&mut self, ty1: &Ty, ty2: &Ty, depth: usize) -> bool {
if depth > 1000 {
// prevent stackoverflows
panic!("infinite recursion in unification");
}
if ty1 == ty2 {
return true;
}
// try to resolve type vars first
let ty1 = self.resolve_ty_shallow(ty1);
let ty2 = self.resolve_ty_shallow(ty2);
match (&*ty1, &*ty2) {
(Ty::Apply(a_ty1), Ty::Apply(a_ty2)) if a_ty1.ctor == a_ty2.ctor => {
self.unify_substs(&a_ty1.parameters, &a_ty2.parameters, depth + 1)
}
_ => self.unify_inner_trivial(&ty1, &ty2),
}
}
pub(super) fn unify_inner_trivial(&mut self, ty1: &Ty, ty2: &Ty) -> bool {
match (ty1, ty2) {
(Ty::Unknown, _) | (_, Ty::Unknown) => true,
(Ty::Infer(InferTy::TypeVar(tv1)), Ty::Infer(InferTy::TypeVar(tv2)))
| (Ty::Infer(InferTy::IntVar(tv1)), Ty::Infer(InferTy::IntVar(tv2)))
| (Ty::Infer(InferTy::FloatVar(tv1)), Ty::Infer(InferTy::FloatVar(tv2)))
| (
Ty::Infer(InferTy::MaybeNeverTypeVar(tv1)),
Ty::Infer(InferTy::MaybeNeverTypeVar(tv2)),
) => {
// both type vars are unknown since we tried to resolve them
self.var_unification_table.union(*tv1, *tv2);
true
}
// The order of MaybeNeverTypeVar matters here.
// Unifying MaybeNeverTypeVar and TypeVar will let the latter become MaybeNeverTypeVar.
// Unifying MaybeNeverTypeVar and other concrete type will let the former become it.
(Ty::Infer(InferTy::TypeVar(tv)), other)
| (other, Ty::Infer(InferTy::TypeVar(tv)))
| (Ty::Infer(InferTy::MaybeNeverTypeVar(tv)), other)
| (other, Ty::Infer(InferTy::MaybeNeverTypeVar(tv)))
| (Ty::Infer(InferTy::IntVar(tv)), other @ ty_app!(TypeCtor::Int(_)))
| (other @ ty_app!(TypeCtor::Int(_)), Ty::Infer(InferTy::IntVar(tv)))
| (Ty::Infer(InferTy::FloatVar(tv)), other @ ty_app!(TypeCtor::Float(_)))
| (other @ ty_app!(TypeCtor::Float(_)), Ty::Infer(InferTy::FloatVar(tv))) => {
// the type var is unknown since we tried to resolve it
self.var_unification_table.union_value(*tv, TypeVarValue::Known(other.clone()));
true
}
_ => false,
}
}
/// If `ty` is a type variable with known type, returns that type;
/// otherwise, return ty.
pub fn resolve_ty_shallow<'b>(&mut self, ty: &'b Ty) -> Cow<'b, Ty> {
let mut ty = Cow::Borrowed(ty);
// The type variable could resolve to a int/float variable. Hence try
// resolving up to three times; each type of variable shouldn't occur
// more than once
for i in 0..3 {
if i > 0 {
tested_by!(type_var_resolves_to_int_var);
}
match &*ty {
Ty::Infer(tv) => {
let inner = tv.to_inner();
match self.var_unification_table.inlined_probe_value(inner).known() {
Some(known_ty) => {
// The known_ty can't be a type var itself
ty = Cow::Owned(known_ty.clone());
}
_ => return ty,
}
}
_ => return ty,
}
}
log::error!("Inference variable still not resolved: {:?}", ty);
ty
}
/// Resolves the type as far as currently possible, replacing type variables
/// by their known types. All types returned by the infer_* functions should
/// be resolved as far as possible, i.e. contain no type variables with
/// known type.
fn resolve_ty_as_possible_inner(&mut self, tv_stack: &mut Vec<TypeVarId>, ty: Ty) -> Ty {
ty.fold(&mut |ty| match ty {
Ty::Infer(tv) => {
let inner = tv.to_inner();
if tv_stack.contains(&inner) {
tested_by!(type_var_cycles_resolve_as_possible);
// recursive type
return tv.fallback_value();
}
if let Some(known_ty) =
self.var_unification_table.inlined_probe_value(inner).known()
{
// known_ty may contain other variables that are known by now
tv_stack.push(inner);
let result = self.resolve_ty_as_possible_inner(tv_stack, known_ty.clone());
tv_stack.pop();
result
} else {
ty
}
}
_ => ty,
})
}
/// Resolves the type completely; type variables without known type are
/// replaced by Ty::Unknown.
fn resolve_ty_completely_inner(&mut self, tv_stack: &mut Vec<TypeVarId>, ty: Ty) -> Ty {
ty.fold(&mut |ty| match ty {
Ty::Infer(tv) => {
let inner = tv.to_inner();
if tv_stack.contains(&inner) {
tested_by!(type_var_cycles_resolve_completely);
// recursive type
return tv.fallback_value();
}
if let Some(known_ty) =
self.var_unification_table.inlined_probe_value(inner).known()
{
// known_ty may contain other variables that are known by now
tv_stack.push(inner);
let result = self.resolve_ty_completely_inner(tv_stack, known_ty.clone());
tv_stack.pop();
result
} else {
tv.fallback_value()
}
}
_ => ty,
})
}
}
/// The ID of a type variable.
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug)]
pub struct TypeVarId(pub(super) u32);
impl UnifyKey for TypeVarId {
type Value = TypeVarValue;
fn index(&self) -> u32 {
self.0
}
fn from_index(i: u32) -> Self {
TypeVarId(i)
}
fn tag() -> &'static str {
"TypeVarId"
}
}
/// The value of a type variable: either we already know the type, or we don't
/// know it yet.
#[derive(Clone, PartialEq, Eq, Debug)]
pub enum TypeVarValue {
Known(Ty),
Unknown,
}
impl TypeVarValue {
fn known(&self) -> Option<&Ty> {
match self {
TypeVarValue::Known(ty) => Some(ty),
TypeVarValue::Unknown => None,
}
}
}
impl UnifyValue for TypeVarValue {
type Error = NoError;
fn unify_values(value1: &Self, value2: &Self) -> Result<Self, NoError> {
match (value1, value2) {
// We should never equate two type variables, both of which have
// known types. Instead, we recursively equate those types.
(TypeVarValue::Known(t1), TypeVarValue::Known(t2)) => panic!(
"equating two type variables, both of which have known types: {:?} and {:?}",
t1, t2
),
// If one side is known, prefer that one.
(TypeVarValue::Known(..), TypeVarValue::Unknown) => Ok(value1.clone()),
(TypeVarValue::Unknown, TypeVarValue::Known(..)) => Ok(value2.clone()),
(TypeVarValue::Unknown, TypeVarValue::Unknown) => Ok(TypeVarValue::Unknown),
}
}
}
|