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path: root/crates/ra_hir/src/ty/infer/unify.rs
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//! Unification and canonicalization logic.

use super::InferenceContext;
use crate::db::HirDatabase;
use crate::ty::{Canonical, InferTy, TraitRef, Ty};

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<super::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.var_unification_table.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.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),
                    };
                    let position = self.add(free_var);
                    Ty::Bound(position as u32)
                }
            }
            _ => ty,
        })
    }

    fn do_canonicalize_trait_ref(&mut self, trait_ref: TraitRef) -> TraitRef {
        let substs = trait_ref
            .substs
            .iter()
            .map(|ty| self.do_canonicalize_ty(ty.clone()))
            .collect::<Vec<_>>();
        TraitRef { trait_: trait_ref.trait_, substs: substs.into() }
    }

    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,
        }
    }

    pub fn canonicalize_ty(mut self, ty: Ty) -> Canonicalized<Ty> {
        let result = self.do_canonicalize_ty(ty);
        self.into_canonicalized(result)
    }

    pub fn canonicalize_trait_ref(mut self, trait_ref: TraitRef) -> Canonicalized<TraitRef> {
        let result = self.do_canonicalize_trait_ref(trait_ref);
        self.into_canonicalized(result)
    }
}

impl<T> Canonicalized<T> {
    pub fn decanonicalize_ty(&self, ty: Ty) -> Ty {
        ty.fold(&mut |ty| match ty {
            Ty::Bound(idx) => {
                if (idx as usize) < self.free_vars.len() {
                    Ty::Infer(self.free_vars[idx as usize])
                } else {
                    Ty::Bound(idx)
                }
            }
            ty => 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 =
            (0..solution.num_vars).map(|_| ctx.new_type_var()).collect::<Vec<_>>().into();
        for (i, ty) in solution.value.into_iter().enumerate() {
            let var = self.free_vars[i];
            ctx.unify(&Ty::Infer(var), &ty.subst_bound_vars(&new_vars));
        }
    }
}