rust/src/librustc/middle/ty/flags.rs

// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.

use middle::subst;
use middle::ty::{self, Ty, TypeFlags, TypeFoldable};

pub struct FlagComputation {
    pub flags: TypeFlags,

    // maximum depth of any bound region that we have seen thus far
    pub depth: u32,
}

impl FlagComputation {
    fn new() -> FlagComputation {
        FlagComputation { flags: TypeFlags::empty(), depth: 0 }
    }

    pub fn for_sty(st: &ty::TypeVariants) -> FlagComputation {
        let mut result = FlagComputation::new();
        result.add_sty(st);
        result
    }

    fn add_flags(&mut self, flags: TypeFlags) {
        self.flags = self.flags | (flags & TypeFlags::NOMINAL_FLAGS);
    }

    fn add_depth(&mut self, depth: u32) {
        if depth > self.depth {
            self.depth = depth;
        }
    }

    /// Adds the flags/depth from a set of types that appear within the current type, but within a
    /// region binder.
    fn add_bound_computation(&mut self, computation: &FlagComputation) {
        self.add_flags(computation.flags);

        // The types that contributed to `computation` occurred within
        // a region binder, so subtract one from the region depth
        // within when adding the depth to `self`.
        let depth = computation.depth;
        if depth > 0 {
            self.add_depth(depth - 1);
        }
    }

    fn add_sty(&mut self, st: &ty::TypeVariants) {
        match st {
            &ty::TyBool |
            &ty::TyChar |
            &ty::TyInt(_) |
            &ty::TyFloat(_) |
            &ty::TyUint(_) |
            &ty::TyStr => {
            }

            // You might think that we could just return TyError for
            // any type containing TyError as a component, and get
            // rid of the TypeFlags::HAS_TY_ERR flag -- likewise for ty_bot (with
            // the exception of function types that return bot).
            // But doing so caused sporadic memory corruption, and
            // neither I (tjc) nor nmatsakis could figure out why,
            // so we're doing it this way.
            &ty::TyError => {
                self.add_flags(TypeFlags::HAS_TY_ERR)
            }

            &ty::TyParam(ref p) => {
                self.add_flags(TypeFlags::HAS_LOCAL_NAMES);
                if p.space == subst::SelfSpace {
                    self.add_flags(TypeFlags::HAS_SELF);
                } else {
                    self.add_flags(TypeFlags::HAS_PARAMS);
                }
            }

            &ty::TyClosure(_, ref substs) => {
                self.add_flags(TypeFlags::HAS_TY_CLOSURE);
                self.add_flags(TypeFlags::HAS_LOCAL_NAMES);
                self.add_substs(&substs.func_substs);
                self.add_tys(&substs.upvar_tys);
            }

            &ty::TyInfer(_) => {
                self.add_flags(TypeFlags::HAS_LOCAL_NAMES); // it might, right?
                self.add_flags(TypeFlags::HAS_TY_INFER)
            }

            &ty::TyEnum(_, substs) | &ty::TyStruct(_, substs) => {
                self.add_substs(substs);
            }

            &ty::TyProjection(ref data) => {
                self.add_flags(TypeFlags::HAS_PROJECTION);
                self.add_projection_ty(data);
            }

            &ty::TyTrait(box ty::TraitTy { ref principal, ref bounds }) => {
                let mut computation = FlagComputation::new();
                computation.add_substs(principal.0.substs);
                for projection_bound in &bounds.projection_bounds {
                    let mut proj_computation = FlagComputation::new();
                    proj_computation.add_projection_predicate(&projection_bound.0);
                    self.add_bound_computation(&proj_computation);
                }
                self.add_bound_computation(&computation);

                self.add_bounds(bounds);
            }

            &ty::TyBox(tt) | &ty::TyArray(tt, _) | &ty::TySlice(tt) => {
                self.add_ty(tt)
            }

            &ty::TyRawPtr(ref m) => {
                self.add_ty(m.ty);
            }

            &ty::TyRef(r, ref m) => {
                self.add_region(*r);
                self.add_ty(m.ty);
            }

            &ty::TyTuple(ref ts) => {
                self.add_tys(&ts[..]);
            }

            &ty::TyFnDef(_, ref f) | &ty::TyFnPtr(ref f) => {
                self.add_fn_sig(&f.sig);
            }
        }
    }

    fn add_ty(&mut self, ty: Ty) {
        self.add_flags(ty.flags.get());
        self.add_depth(ty.region_depth);
    }

    fn add_tys(&mut self, tys: &[Ty]) {
        for &ty in tys {
            self.add_ty(ty);
        }
    }

    fn add_fn_sig(&mut self, fn_sig: &ty::PolyFnSig) {
        let mut computation = FlagComputation::new();

        computation.add_tys(&fn_sig.0.inputs);

        if let ty::FnConverging(output) = fn_sig.0.output {
            computation.add_ty(output);
        }

        self.add_bound_computation(&computation);
    }

    fn add_region(&mut self, r: ty::Region) {
        match r {
            ty::ReVar(..) |
            ty::ReSkolemized(..) => { self.add_flags(TypeFlags::HAS_RE_INFER); }
            ty::ReLateBound(debruijn, _) => { self.add_depth(debruijn.depth); }
            ty::ReEarlyBound(..) => { self.add_flags(TypeFlags::HAS_RE_EARLY_BOUND); }
            ty::ReStatic => {}
            _ => { self.add_flags(TypeFlags::HAS_FREE_REGIONS); }
        }

        if !r.is_global() {
            self.add_flags(TypeFlags::HAS_LOCAL_NAMES);
        }
    }

    fn add_projection_predicate(&mut self, projection_predicate: &ty::ProjectionPredicate) {
        self.add_projection_ty(&projection_predicate.projection_ty);
        self.add_ty(projection_predicate.ty);
    }

    fn add_projection_ty(&mut self, projection_ty: &ty::ProjectionTy) {
        self.add_substs(projection_ty.trait_ref.substs);
    }

    fn add_substs(&mut self, substs: &subst::Substs) {
        self.add_tys(substs.types.as_slice());
        match substs.regions {
            subst::ErasedRegions => {}
            subst::NonerasedRegions(ref regions) => {
                for &r in regions {
                    self.add_region(r);
                }
            }
        }
    }

    fn add_bounds(&mut self, bounds: &ty::ExistentialBounds) {
        self.add_region(bounds.region_bound);
    }
}
split ty.rs into smaller parts 2015-09-06 21:51:58 +03:00			`// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT`
			`// file at the top-level directory of this distribution and at`
			`// http://rust-lang.org/COPYRIGHT.`
			`//`
			`// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or`
			`// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license`
			`// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your`
			`// option. This file may not be copied, modified, or distributed`
			`// except according to those terms.`

			`use middle::subst;`
Refactor away extension traits RegionEscape and HasTypeFlags 2015-12-18 10:07:06 +00:00			`use middle::ty::{self, Ty, TypeFlags, TypeFoldable};`
split ty.rs into smaller parts 2015-09-06 21:51:58 +03:00
			`pub struct FlagComputation {`
			`pub flags: TypeFlags,`

			`// maximum depth of any bound region that we have seen thus far`
			`pub depth: u32,`
			`}`

			`impl FlagComputation {`
			`fn new() -> FlagComputation {`
			`FlagComputation { flags: TypeFlags::empty(), depth: 0 }`
			`}`

			`pub fn for_sty(st: &ty::TypeVariants) -> FlagComputation {`
			`let mut result = FlagComputation::new();`
			`result.add_sty(st);`
			`result`
			`}`

			`fn add_flags(&mut self, flags: TypeFlags) {`
			`self.flags = self.flags \| (flags & TypeFlags::NOMINAL_FLAGS);`
			`}`

			`fn add_depth(&mut self, depth: u32) {`
			`if depth > self.depth {`
			`self.depth = depth;`
			`}`
			`}`

			`/// Adds the flags/depth from a set of types that appear within the current type, but within a`
			`/// region binder.`
			`fn add_bound_computation(&mut self, computation: &FlagComputation) {`
			`self.add_flags(computation.flags);`

			// The types that contributed to `computation` occurred within
			`// a region binder, so subtract one from the region depth`
			// within when adding the depth to `self`.
			`let depth = computation.depth;`
			`if depth > 0 {`
			`self.add_depth(depth - 1);`
			`}`
			`}`

			`fn add_sty(&mut self, st: &ty::TypeVariants) {`
			`match st {`
			`&ty::TyBool \|`
			`&ty::TyChar \|`
			`&ty::TyInt(_) \|`
			`&ty::TyFloat(_) \|`
			`&ty::TyUint(_) \|`
			`&ty::TyStr => {`
			`}`

			`// You might think that we could just return TyError for`
			`// any type containing TyError as a component, and get`
			`// rid of the TypeFlags::HAS_TY_ERR flag -- likewise for ty_bot (with`
			`// the exception of function types that return bot).`
			`// But doing so caused sporadic memory corruption, and`
			`// neither I (tjc) nor nmatsakis could figure out why,`
			`// so we're doing it this way.`
			`&ty::TyError => {`
			`self.add_flags(TypeFlags::HAS_TY_ERR)`
			`}`

			`&ty::TyParam(ref p) => {`
			`self.add_flags(TypeFlags::HAS_LOCAL_NAMES);`
			`if p.space == subst::SelfSpace {`
			`self.add_flags(TypeFlags::HAS_SELF);`
			`} else {`
			`self.add_flags(TypeFlags::HAS_PARAMS);`
			`}`
			`}`

			`&ty::TyClosure(_, ref substs) => {`
			`self.add_flags(TypeFlags::HAS_TY_CLOSURE);`
			`self.add_flags(TypeFlags::HAS_LOCAL_NAMES);`
			`self.add_substs(&substs.func_substs);`
			`self.add_tys(&substs.upvar_tys);`
			`}`

			`&ty::TyInfer(_) => {`
			`self.add_flags(TypeFlags::HAS_LOCAL_NAMES); // it might, right?`
			`self.add_flags(TypeFlags::HAS_TY_INFER)`
			`}`

			`&ty::TyEnum(_, substs) \| &ty::TyStruct(_, substs) => {`
			`self.add_substs(substs);`
			`}`

			`&ty::TyProjection(ref data) => {`
			`self.add_flags(TypeFlags::HAS_PROJECTION);`
			`self.add_projection_ty(data);`
			`}`

			`&ty::TyTrait(box ty::TraitTy { ref principal, ref bounds }) => {`
			`let mut computation = FlagComputation::new();`
			`computation.add_substs(principal.0.substs);`
			`for projection_bound in &bounds.projection_bounds {`
			`let mut proj_computation = FlagComputation::new();`
			`proj_computation.add_projection_predicate(&projection_bound.0);`
			`self.add_bound_computation(&proj_computation);`
			`}`
			`self.add_bound_computation(&computation);`

			`self.add_bounds(bounds);`
			`}`

			`&ty::TyBox(tt) \| &ty::TyArray(tt, _) \| &ty::TySlice(tt) => {`
			`self.add_ty(tt)`
			`}`

			`&ty::TyRawPtr(ref m) => {`
			`self.add_ty(m.ty);`
			`}`

			`&ty::TyRef(r, ref m) => {`
			`self.add_region(*r);`
			`self.add_ty(m.ty);`
			`}`

			`&ty::TyTuple(ref ts) => {`
			`self.add_tys(&ts[..]);`
			`}`

Split TyBareFn into TyFnDef and TyFnPtr. There's a lot of stuff wrong with the representation of these types: TyFnDef doesn't actually uniquely identify a function, TyFnPtr is used to represent method calls, TyFnDef in the sub-expression of a cast isn't correctly reified, and probably some other stuff I haven't discovered yet. Splitting them seems like the right first step, though. 2015-06-13 13:15:03 -07:00			`&ty::TyFnDef(_, ref f) \| &ty::TyFnPtr(ref f) => {`
split ty.rs into smaller parts 2015-09-06 21:51:58 +03:00			`self.add_fn_sig(&f.sig);`
			`}`
			`}`
			`}`

			`fn add_ty(&mut self, ty: Ty) {`
			`self.add_flags(ty.flags.get());`
			`self.add_depth(ty.region_depth);`
			`}`

			`fn add_tys(&mut self, tys: &[Ty]) {`
			`for &ty in tys {`
			`self.add_ty(ty);`
			`}`
			`}`

			`fn add_fn_sig(&mut self, fn_sig: &ty::PolyFnSig) {`
			`let mut computation = FlagComputation::new();`

			`computation.add_tys(&fn_sig.0.inputs);`

			`if let ty::FnConverging(output) = fn_sig.0.output {`
			`computation.add_ty(output);`
			`}`

			`self.add_bound_computation(&computation);`
			`}`

			`fn add_region(&mut self, r: ty::Region) {`
			`match r {`
			`ty::ReVar(..) \|`
			`ty::ReSkolemized(..) => { self.add_flags(TypeFlags::HAS_RE_INFER); }`
			`ty::ReLateBound(debruijn, _) => { self.add_depth(debruijn.depth); }`
			`ty::ReEarlyBound(..) => { self.add_flags(TypeFlags::HAS_RE_EARLY_BOUND); }`
			`ty::ReStatic => {}`
			`_ => { self.add_flags(TypeFlags::HAS_FREE_REGIONS); }`
			`}`

			`if !r.is_global() {`
			`self.add_flags(TypeFlags::HAS_LOCAL_NAMES);`
			`}`
			`}`

			`fn add_projection_predicate(&mut self, projection_predicate: &ty::ProjectionPredicate) {`
			`self.add_projection_ty(&projection_predicate.projection_ty);`
			`self.add_ty(projection_predicate.ty);`
			`}`

			`fn add_projection_ty(&mut self, projection_ty: &ty::ProjectionTy) {`
			`self.add_substs(projection_ty.trait_ref.substs);`
			`}`

			`fn add_substs(&mut self, substs: &subst::Substs) {`
			`self.add_tys(substs.types.as_slice());`
			`match substs.regions {`
			`subst::ErasedRegions => {}`
			`subst::NonerasedRegions(ref regions) => {`
			`for &r in regions {`
			`self.add_region(r);`
			`}`
			`}`
			`}`
			`}`

			`fn add_bounds(&mut self, bounds: &ty::ExistentialBounds) {`
			`self.add_region(bounds.region_bound);`
			`}`
			`}`