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cmd/compile/internal/types2: detect constraint type inference cycles

See the detailed explanations in the code.

Fixes #48136.

Change-Id: I1667aabfbbff97967913b080c77e7ec04ea82feb
Reviewed-on: https://go-review.googlesource.com/c/go/+/347300
Trust: Robert Griesemer <gri@golang.org>
Trust: Cuong Manh Le <cuong.manhle.vn@gmail.com>
Run-TryBot: Robert Griesemer <gri@golang.org>
TryBot-Result: Go Bot <gobot@golang.org>
Reviewed-by: Robert Findley <rfindley@google.com>
This commit is contained in:
Robert Griesemer 2021-09-02 16:43:29 -07:00
parent 28dae3defb
commit 9133245be7
2 changed files with 160 additions and 0 deletions

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@ -9,6 +9,7 @@ package types2
import ( import (
"bytes" "bytes"
"cmd/compile/internal/syntax" "cmd/compile/internal/syntax"
"fmt"
) )
const useConstraintTypeInference = true const useConstraintTypeInference = true
@ -409,6 +410,34 @@ func (check *Checker) inferB(tparams []*TypeParam, targs []Type, report bool) (t
} }
} }
// The data structure of each (provided or inferred) type represents a graph, where
// each node corresponds to a type and each (directed) vertice points to a component
// type. The substitution process described above repeatedly replaces type parameter
// nodes in these graphs with the graphs of the types the type parameters stand for,
// which creates a new (possibly bigger) graph for each type.
// The substitution process will not stop if the replacement graph for a type parameter
// also contains that type parameter.
// For instance, for [A interface{ *A }], without any type argument provided for A,
// unification produces the type list [*A]. Substituting A in *A with the value for
// A will lead to infinite expansion by producing [**A], [****A], [********A], etc.,
// because the graph A -> *A has a cycle through A.
// Generally, cycles may occur across multiple type parameters and inferred types
// (for instance, consider [P interface{ *Q }, Q interface{ func(P) }]).
// We eliminate cycles by walking the graphs for all type parameters. If a cycle
// through a type parameter is detected, cycleFinder nils out the respectice type
// which kills the cycle; this also means that the respective type could not be
// inferred.
//
// TODO(gri) If useful, we could report the respective cycle as an error. We don't
// do this now because type inference will fail anyway, and furthermore,
// constraints with cycles of this kind cannot currently be satisfied by
// any user-suplied type. But should that change, reporting an error
// would be wrong.
w := cycleFinder{tparams, types, make(map[Type]bool)}
for _, t := range tparams {
w.typ(t) // t != nil
}
// dirty tracks the indices of all types that may still contain type parameters. // dirty tracks the indices of all types that may still contain type parameters.
// We know that nil type entries and entries corresponding to provided (non-nil) // We know that nil type entries and entries corresponding to provided (non-nil)
// type arguments are clean, so exclude them from the start. // type arguments are clean, so exclude them from the start.
@ -457,3 +486,98 @@ func (check *Checker) inferB(tparams []*TypeParam, targs []Type, report bool) (t
return return
} }
type cycleFinder struct {
tparams []*TypeParam
types []Type
seen map[Type]bool
}
func (w *cycleFinder) typ(typ Type) {
if w.seen[typ] {
// We have seen typ before. If it is one of the type parameters
// in tparams, iterative substitution will lead to infinite expansion.
// Nil out the corresponding type which effectively kills the cycle.
if tpar, _ := typ.(*TypeParam); tpar != nil {
if i := tparamIndex(w.tparams, tpar); i >= 0 {
// cycle through tpar
w.types[i] = nil
}
}
// If we don't have one of our type parameters, the cycle is due
// to an ordinary recursive type and we can just stop walking it.
return
}
w.seen[typ] = true
defer delete(w.seen, typ)
switch t := typ.(type) {
case *Basic, *top:
// nothing to do
case *Array:
w.typ(t.elem)
case *Slice:
w.typ(t.elem)
case *Struct:
w.varList(t.fields)
case *Pointer:
w.typ(t.base)
// case *Tuple:
// This case should not occur because tuples only appear
// in signatures where they are handled explicitly.
case *Signature:
// There are no "method types" so we should never see a recv.
assert(t.recv == nil)
if t.params != nil {
w.varList(t.params.vars)
}
if t.results != nil {
w.varList(t.results.vars)
}
case *Union:
for _, t := range t.terms {
w.typ(t.typ)
}
case *Interface:
for _, m := range t.methods {
w.typ(m.typ)
}
for _, t := range t.embeddeds {
w.typ(t)
}
case *Map:
w.typ(t.key)
w.typ(t.elem)
case *Chan:
w.typ(t.elem)
case *Named:
for _, tpar := range t.TArgs().list() {
w.typ(tpar)
}
case *TypeParam:
if i := tparamIndex(w.tparams, t); i >= 0 && w.types[i] != nil {
w.typ(w.types[i])
}
default:
panic(fmt.Sprintf("unexpected %T", typ))
}
}
func (w *cycleFinder) varList(list []*Var) {
for _, v := range list {
w.typ(v.typ)
}
}

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@ -0,0 +1,36 @@
// Copyright 2021 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package p
func f1[P interface{ *P }]() {}
func f2[P interface{ func(P) }]() {}
func f3[P, Q interface{ func(Q) P }]() {}
func f4[P interface{ *Q }, Q interface{ func(P) }]() {}
func f5[P interface{ func(P) }]() {}
func f6[P interface { *Tree[P] }, Q any ]() {}
func _() {
f1( /* ERROR cannot infer P */ )
f2( /* ERROR cannot infer P */ )
f3( /* ERROR cannot infer P */ )
f4( /* ERROR cannot infer P */ )
f5( /* ERROR cannot infer P */ )
f6( /* ERROR cannot infer P */ )
}
type Tree[P any] struct {
left, right *Tree[P]
data P
}
// test case from issue
func foo[Src interface { func() Src }]() Src {
return foo[Src]
}
func _() {
foo( /* ERROR cannot infer Src */ )
}