1
0
mirror of https://github.com/golang/go synced 2024-11-23 04:00:03 -07:00

go/types, types2: ensure that named types never expand infinitely

During type-checking, newly created instances share a type checking
Context which de-duplicates identical instances. However, when
unexpanded types escape the type-checking pass or are created via calls
to Instantiate, they lack this shared context. As reported in #52728,
this may lead to infinitely many identical but distinct types that are
reachable via the API.

This CL introduces a new invariant that ensures we don't create such
infinitely expanding chains: instances created during expansion share a
context with the type that led to their creation. During expansion, the
expanding type passes its Context to any newly created instances.

This ensures that cycles will eventually terminate with a previously
seen instance. For example, if we have an instantiation chain
T1[P]->T2[P]->T3[P]->T1[P], by virtue of this Context passing the
expansion of T3[P] will find the instantiation T1[P].

In general, storing a Context in a Named type could lead to pinning
types in memory unnecessarily, but in this case the Context pins only
those types that are reachable from the original instance. This seems
like a reasonable compromise between lazy and eager expansion.

Our treatment of Context was a little haphazard: Checker.bestContext
made it easy to get a context at any point, but made it harder to reason
about which context is being used. To fix this, replace bestContext with
Checker.context, which returns the type-checking context and panics on a
nil receiver. Update all call-sites to verify that the Checker is
non-nil when context is called.

Also make it a panic to call subst with a nil context. Instead, update
subst to explicitly accept a local (=instance) context along with a
global context, and require that one of them is non-nil. Thread this
through to the call to Checker.instance, and handle context updating
there.

Fixes #52728

Change-Id: Ib7f26eb8c406290325bc3212fda25421a37a1e8e
Reviewed-on: https://go-review.googlesource.com/c/go/+/404885
Reviewed-by: Robert Griesemer <gri@google.com>
TryBot-Result: Gopher Robot <gobot@golang.org>
Run-TryBot: Robert Findley <rfindley@google.com>
This commit is contained in:
Robert Findley 2022-05-07 21:22:17 -04:00
parent 02e69cfa96
commit 47e34ca533
18 changed files with 389 additions and 212 deletions

View File

@ -72,13 +72,13 @@ func (check *Checker) instantiateSignature(pos syntax.Pos, typ *Signature, targs
}()
}
inst := check.instance(pos, typ, targs, check.bestContext(nil)).(*Signature)
inst := check.instance(pos, typ, targs, nil, check.context()).(*Signature)
assert(len(xlist) <= len(targs))
// verify instantiation lazily (was issue #50450)
check.later(func() {
tparams := typ.TypeParams().list()
if i, err := check.verify(pos, tparams, targs); err != nil {
if i, err := check.verify(pos, tparams, targs, check.context()); err != nil {
// best position for error reporting
pos := pos
if i < len(xlist) {
@ -395,7 +395,7 @@ func (check *Checker) arguments(call *syntax.CallExpr, sig *Signature, targs []T
// need to compute it from the adjusted list; otherwise we can
// simply use the result signature's parameter list.
if adjusted {
sigParams = check.subst(call.Pos(), sigParams, makeSubstMap(sig.TypeParams().list(), targs), nil).(*Tuple)
sigParams = check.subst(call.Pos(), sigParams, makeSubstMap(sig.TypeParams().list(), targs), nil, check.context()).(*Tuple)
} else {
sigParams = rsig.params
}

View File

@ -110,11 +110,11 @@ func (check *Checker) infer(pos syntax.Pos, tparams []*TypeParam, targs []Type,
renameMap := makeRenameMap(tparams, tparams2)
for i, tparam := range tparams {
tparams2[i].bound = check.subst(pos, tparam.bound, renameMap, nil)
tparams2[i].bound = check.subst(pos, tparam.bound, renameMap, nil, check.context())
}
tparams = tparams2
params = check.subst(pos, params, renameMap, nil).(*Tuple)
params = check.subst(pos, params, renameMap, nil, check.context()).(*Tuple)
}
}
@ -188,7 +188,7 @@ func (check *Checker) infer(pos syntax.Pos, tparams []*TypeParam, targs []Type,
// but that doesn't impact the isParameterized check for now).
if params.Len() > 0 {
smap := makeSubstMap(tparams, targs)
params = check.subst(nopos, params, smap, nil).(*Tuple)
params = check.subst(nopos, params, smap, nil, check.context()).(*Tuple)
}
// Unify parameter and argument types for generic parameters with typed arguments
@ -224,7 +224,7 @@ func (check *Checker) infer(pos syntax.Pos, tparams []*TypeParam, targs []Type,
}
}
smap := makeSubstMap(tparams, targs)
inferred := check.subst(arg.Pos(), tpar, smap, nil)
inferred := check.subst(arg.Pos(), tpar, smap, nil, check.context())
if inferred != tpar {
check.errorf(arg, "%s %s of %s does not match inferred type %s for %s", kind, targ, arg.expr, inferred, tpar)
} else {
@ -626,7 +626,7 @@ func (check *Checker) inferB(pos syntax.Pos, tparams []*TypeParam, targs []Type)
n := 0
for _, index := range dirty {
t0 := types[index]
if t1 := check.subst(nopos, t0, smap, nil); t1 != t0 {
if t1 := check.subst(nopos, t0, smap, nil, check.context()); t1 != t0 {
types[index] = t1
dirty[n] = index
n++

View File

@ -40,6 +40,9 @@ import (
// count is incorrect; for *Named types, a panic may occur later inside the
// *Named API.
func Instantiate(ctxt *Context, orig Type, targs []Type, validate bool) (Type, error) {
if ctxt == nil {
ctxt = NewContext()
}
if validate {
var tparams []*TypeParam
switch t := orig.(type) {
@ -51,34 +54,71 @@ func Instantiate(ctxt *Context, orig Type, targs []Type, validate bool) (Type, e
if len(targs) != len(tparams) {
return nil, fmt.Errorf("got %d type arguments but %s has %d type parameters", len(targs), orig, len(tparams))
}
if i, err := (*Checker)(nil).verify(nopos, tparams, targs); err != nil {
if i, err := (*Checker)(nil).verify(nopos, tparams, targs, ctxt); err != nil {
return nil, &ArgumentError{i, err}
}
}
inst := (*Checker)(nil).instance(nopos, orig, targs, ctxt)
inst := (*Checker)(nil).instance(nopos, orig, targs, nil, ctxt)
return inst, nil
}
// instance creates a type or function instance using the given original type
// typ and arguments targs. For Named types the resulting instance will be
// unexpanded. check may be nil.
func (check *Checker) instance(pos syntax.Pos, orig Type, targs []Type, ctxt *Context) (res Type) {
var h string
if ctxt != nil {
h = ctxt.instanceHash(orig, targs)
// typ may already have been instantiated with identical type arguments. In
// that case, re-use the existing instance.
if inst := ctxt.lookup(h, orig, targs); inst != nil {
return inst
// instance resolves a type or function instance for the given original type
// and type arguments. It looks for an existing identical instance in the given
// contexts, creating a new instance if none is found.
//
// If local is non-nil, it is the context associated with a Named instance
// type currently being expanded. If global is non-nil, it is the context
// associated with the current type-checking pass or call to Instantiate. At
// least one of local or global must be non-nil.
//
// For Named types the resulting instance may be unexpanded.
func (check *Checker) instance(pos syntax.Pos, orig Type, targs []Type, local, global *Context) (res Type) {
// The order of the contexts below matters: we always prefer instances in
// local in order to preserve reference cycles.
//
// Invariant: if local != nil, the returned instance will be the instance
// recorded in local.
var ctxts []*Context
if local != nil {
ctxts = append(ctxts, local)
}
if global != nil {
ctxts = append(ctxts, global)
}
assert(len(ctxts) > 0)
// Compute all hashes; hashes may differ across contexts due to different
// unique IDs for Named types within the hasher.
hashes := make([]string, len(ctxts))
for i, ctxt := range ctxts {
hashes[i] = ctxt.instanceHash(orig, targs)
}
// If local is non-nil, updateContexts return the type recorded in
// local.
updateContexts := func(res Type) Type {
for i := len(ctxts) - 1; i >= 0; i-- {
res = ctxts[i].update(hashes[i], orig, targs, res)
}
return res
}
// typ may already have been instantiated with identical type arguments. In
// that case, re-use the existing instance.
for i, ctxt := range ctxts {
if inst := ctxt.lookup(hashes[i], orig, targs); inst != nil {
return updateContexts(inst)
}
}
switch orig := orig.(type) {
case *Named:
res = check.newNamedInstance(pos, orig, targs)
res = check.newNamedInstance(pos, orig, targs, local) // substituted lazily
case *Signature:
assert(local == nil) // function instances cannot be reached from Named types
tparams := orig.TypeParams()
if !check.validateTArgLen(pos, tparams.Len(), len(targs)) {
return Typ[Invalid]
@ -86,7 +126,7 @@ func (check *Checker) instance(pos syntax.Pos, orig Type, targs []Type, ctxt *Co
if tparams.Len() == 0 {
return orig // nothing to do (minor optimization)
}
sig := check.subst(pos, orig, makeSubstMap(tparams.list(), targs), ctxt).(*Signature)
sig := check.subst(pos, orig, makeSubstMap(tparams.list(), targs), nil, global).(*Signature)
// If the signature doesn't use its type parameters, subst
// will not make a copy. In that case, make a copy now (so
// we can set tparams to nil w/o causing side-effects).
@ -104,13 +144,8 @@ func (check *Checker) instance(pos syntax.Pos, orig Type, targs []Type, ctxt *Co
panic(fmt.Sprintf("%v: cannot instantiate %v", pos, orig))
}
if ctxt != nil {
// It's possible that we've lost a race to add named to the context.
// In this case, use whichever instance is recorded in the context.
res = ctxt.update(h, orig, targs, res)
}
return res
// Update all contexts; it's possible that we've lost a race.
return updateContexts(res)
}
// validateTArgLen verifies that the length of targs and tparams matches,
@ -128,7 +163,7 @@ func (check *Checker) validateTArgLen(pos syntax.Pos, ntparams, ntargs int) bool
return true
}
func (check *Checker) verify(pos syntax.Pos, tparams []*TypeParam, targs []Type) (int, error) {
func (check *Checker) verify(pos syntax.Pos, tparams []*TypeParam, targs []Type, ctxt *Context) (int, error) {
smap := makeSubstMap(tparams, targs)
for i, tpar := range tparams {
// Ensure that we have a (possibly implicit) interface as type bound (issue #51048).
@ -137,7 +172,7 @@ func (check *Checker) verify(pos syntax.Pos, tparams []*TypeParam, targs []Type)
// as the instantiated type; before we can use it for bounds checking we
// need to instantiate it with the type arguments with which we instantiated
// the parameterized type.
bound := check.subst(pos, tpar.bound, smap, nil)
bound := check.subst(pos, tpar.bound, smap, nil, ctxt)
if err := check.implements(targs[i], bound); err != nil {
return i, err
}

View File

@ -79,6 +79,16 @@ import (
// Identical to compare them. For instantiated named types, their obj is a
// synthetic placeholder that records their position of the corresponding
// instantiation in the source (if they were constructed during type checking).
//
// To prevent infinite expansion of named instances that are created outside of
// type-checking, instances share a Context with other instances created during
// their expansion. Via the pidgeonhole principle, this guarantees that in the
// presence of a cycle of named types, expansion will eventually find an
// existing instance in the Context and short-circuit the expansion.
//
// Once an instance is complete, we can nil out this shared Context to unpin
// memory, though this Context may still be held by other incomplete instances
// in its "lineage".
// A Named represents a named (defined) type.
type Named struct {
@ -115,6 +125,7 @@ type instance struct {
orig *Named // original, uninstantiated type
targs *TypeList // type arguments
expandedMethods int // number of expanded methods; expandedMethods <= len(orig.methods)
ctxt *Context // local Context; set to nil after full expansion
}
// namedState represents the possible states that a named type may assume.
@ -143,7 +154,7 @@ func NewNamed(obj *TypeName, underlying Type, methods []*Func) *Named {
// After resolution, the type parameters, methods, and underlying type of n are
// accessible; but if n is an instantiated type, its methods may still be
// unexpanded.
func (n *Named) resolve(ctxt *Context) *Named {
func (n *Named) resolve() *Named {
if n.state() >= resolved { // avoid locking below
return n
}
@ -162,8 +173,8 @@ func (n *Named) resolve(ctxt *Context) *Named {
assert(n.loader == nil) // instances are created by instantiation, in which case n.loader is nil
orig := n.inst.orig
orig.resolve(ctxt)
underlying := n.expandUnderlying(ctxt)
orig.resolve()
underlying := n.expandUnderlying()
n.tparams = orig.tparams
n.underlying = underlying
@ -171,6 +182,7 @@ func (n *Named) resolve(ctxt *Context) *Named {
if len(orig.methods) == 0 {
n.setState(complete) // nothing further to do
n.inst.ctxt = nil
} else {
n.setState(resolved)
}
@ -225,11 +237,11 @@ func (check *Checker) newNamed(obj *TypeName, underlying Type, methods []*Func)
return typ
}
func (check *Checker) newNamedInstance(pos syntax.Pos, orig *Named, targs []Type) *Named {
func (check *Checker) newNamedInstance(pos syntax.Pos, orig *Named, targs []Type, local *Context) *Named {
assert(len(targs) > 0)
obj := NewTypeName(pos, orig.obj.pkg, orig.obj.name, nil)
inst := &instance{orig: orig, targs: newTypeList(targs)}
inst := &instance{orig: orig, targs: newTypeList(targs), ctxt: local}
typ := &Named{check: check, obj: obj, inst: inst}
obj.typ = typ
// Ensure that typ is always expanded and sanity-checked.
@ -280,13 +292,13 @@ func (t *Named) Origin() *Named {
// TypeParams returns the type parameters of the named type t, or nil.
// The result is non-nil for an (originally) generic type even if it is instantiated.
func (t *Named) TypeParams() *TypeParamList { return t.resolve(nil).tparams }
func (t *Named) TypeParams() *TypeParamList { return t.resolve().tparams }
// SetTypeParams sets the type parameters of the named type t.
// t must not have type arguments.
func (t *Named) SetTypeParams(tparams []*TypeParam) {
assert(t.inst == nil)
t.resolve(nil).tparams = bindTParams(tparams)
t.resolve().tparams = bindTParams(tparams)
}
// TypeArgs returns the type arguments used to instantiate the named type t.
@ -298,17 +310,17 @@ func (t *Named) TypeArgs() *TypeList {
}
// NumMethods returns the number of explicit methods defined for t.
//
// For an ordinary or instantiated type t, the receiver base type of these
// methods will be the named type t. For an uninstantiated generic type t, each
// method receiver will be instantiated with its receiver type parameters.
func (t *Named) NumMethods() int {
return len(t.Origin().resolve(nil).methods)
return len(t.Origin().resolve().methods)
}
// Method returns the i'th method of named type t for 0 <= i < t.NumMethods().
//
// For an ordinary or instantiated type t, the receiver base type of this
// method is the named type t. For an uninstantiated generic type t, each
// method receiver is instantiated with its receiver type parameters.
func (t *Named) Method(i int) *Func {
t.resolve(nil)
t.resolve()
if t.state() >= complete {
return t.methods[i]
@ -326,6 +338,7 @@ func (t *Named) Method(i int) *Func {
}
if t.methods[i] == nil {
assert(t.inst.ctxt != nil) // we should still have a context remaining from the resolution phase
t.methods[i] = t.expandMethod(i)
t.inst.expandedMethods++
@ -333,6 +346,7 @@ func (t *Named) Method(i int) *Func {
// type as fully expanded.
if t.inst.expandedMethods == len(orig.methods) {
t.setState(complete)
t.inst.ctxt = nil // no need for a context anymore
}
}
@ -372,9 +386,12 @@ func (t *Named) expandMethod(i int) *Func {
// and type parameters. This check is necessary in the presence of invalid
// code.
if origSig.RecvTypeParams().Len() == t.inst.targs.Len() {
ctxt := check.bestContext(nil)
smap := makeSubstMap(origSig.RecvTypeParams().list(), t.inst.targs.list())
sig = check.subst(origm.pos, origSig, smap, ctxt).(*Signature)
var global *Context
if check != nil {
global = check.context()
}
sig = check.subst(origm.pos, origSig, smap, t.inst.ctxt, global).(*Signature)
}
if sig == origSig {
@ -405,7 +422,7 @@ func (t *Named) SetUnderlying(underlying Type) {
if _, ok := underlying.(*Named); ok {
panic("underlying type must not be *Named")
}
t.resolve(nil).underlying = underlying
t.resolve().underlying = underlying
if t.fromRHS == nil {
t.fromRHS = underlying // for cycle detection
}
@ -415,17 +432,20 @@ func (t *Named) SetUnderlying(underlying Type) {
// t must not have type arguments.
func (t *Named) AddMethod(m *Func) {
assert(t.inst == nil)
t.resolve(nil)
t.resolve()
if i, _ := lookupMethod(t.methods, m.pkg, m.name, false); i < 0 {
t.methods = append(t.methods, m)
}
}
func (t *Named) Underlying() Type { return t.resolve(nil).underlying }
func (t *Named) Underlying() Type { return t.resolve().underlying }
func (t *Named) String() string { return TypeString(t, nil) }
// ----------------------------------------------------------------------------
// Implementation
//
// TODO(rfindley): reorganize the loading and expansion methods under this
// heading.
// under returns the expanded underlying type of n0; possibly by following
// forward chains of named types. If an underlying type is found, resolve
@ -522,7 +542,7 @@ func (n *Named) setUnderlying(typ Type) {
}
func (n *Named) lookupMethod(pkg *Package, name string, foldCase bool) (int, *Func) {
n.resolve(nil)
n.resolve()
// If n is an instance, we may not have yet instantiated all of its methods.
// Look up the method index in orig, and only instantiate method at the
// matching index (if any).
@ -534,26 +554,17 @@ func (n *Named) lookupMethod(pkg *Package, name string, foldCase bool) (int, *Fu
return i, n.Method(i)
}
// bestContext returns the best available context. In order of preference:
// - the given ctxt, if non-nil
// - check.ctxt, if check is non-nil
// - a new Context
func (check *Checker) bestContext(ctxt *Context) *Context {
if ctxt != nil {
return ctxt
// context returns the type-checker context.
func (check *Checker) context() *Context {
if check.ctxt == nil {
check.ctxt = NewContext()
}
if check != nil {
if check.ctxt == nil {
check.ctxt = NewContext()
}
return check.ctxt
}
return NewContext()
return check.ctxt
}
// expandUnderlying substitutes type arguments in the underlying type n.orig,
// returning the result. Returns Typ[Invalid] if there was an error.
func (n *Named) expandUnderlying(ctxt *Context) Type {
func (n *Named) expandUnderlying() Type {
check := n.check
if check != nil && check.conf.Trace {
check.trace(n.obj.pos, "-- Named.expandUnderlying %s", n)
@ -565,6 +576,9 @@ func (n *Named) expandUnderlying(ctxt *Context) Type {
}
assert(n.inst.orig.underlying != nil)
if n.inst.ctxt == nil {
n.inst.ctxt = NewContext()
}
orig := n.inst.orig
targs := n.inst.targs
@ -580,16 +594,20 @@ func (n *Named) expandUnderlying(ctxt *Context) Type {
return Typ[Invalid]
}
// We must always have a context, to avoid infinite recursion.
ctxt = check.bestContext(ctxt)
h := ctxt.instanceHash(orig, targs.list())
// ensure that an instance is recorded for h to avoid infinite recursion.
ctxt.update(h, orig, targs.list(), n)
// Ensure that an instance is recorded before substituting, so that we
// resolve n for any recursive references.
h := n.inst.ctxt.instanceHash(orig, targs.list())
n2 := n.inst.ctxt.update(h, orig, n.TypeArgs().list(), n)
assert(n == n2)
smap := makeSubstMap(orig.tparams.list(), targs.list())
underlying := n.check.subst(n.obj.pos, orig.underlying, smap, ctxt)
// If the underlying type of n is an interface, we need to set the receiver
// of its methods accurately -- we set the receiver of interface methods on
var global *Context
if check != nil {
global = check.context()
}
underlying := n.check.subst(n.obj.pos, orig.underlying, smap, n.inst.ctxt, global)
// If the underlying type of n is an interface, we need to set the receiver of
// its methods accurately -- we set the receiver of interface methods on
// the RHS of a type declaration to the defined type.
if iface, _ := underlying.(*Interface); iface != nil {
if methods, copied := replaceRecvType(iface.methods, orig, n); copied {

View File

@ -7,6 +7,7 @@ package types2_test
import (
"testing"
"cmd/compile/internal/syntax"
. "cmd/compile/internal/types2"
)
@ -73,3 +74,47 @@ func mustInstantiate(tb testing.TB, orig Type, targs ...Type) Type {
}
return inst
}
// Test that types do not expand infinitely, as in golang/go#52715.
func TestFiniteTypeExpansion(t *testing.T) {
const src = `
package p
type Tree[T any] struct {
*Node[T]
}
func (*Tree[R]) N(r R) R { return r }
type Node[T any] struct {
*Tree[T]
}
func (Node[Q]) M(Q) {}
type Inst = *Tree[int]
`
f, err := parseSrc("foo.go", src)
if err != nil {
t.Fatal(err)
}
pkg := NewPackage("p", f.PkgName.Value)
if err := NewChecker(nil, pkg, nil).Files([]*syntax.File{f}); err != nil {
t.Fatal(err)
}
firstFieldType := func(n *Named) *Named {
return n.Underlying().(*Struct).Field(0).Type().(*Pointer).Elem().(*Named)
}
Inst := pkg.Scope().Lookup("Inst").Type().(*Pointer).Elem().(*Named)
Node := firstFieldType(Inst)
Tree := firstFieldType(Node)
if !Identical(Inst, Tree) {
t.Fatalf("Not a cycle: got %v, want %v", Tree, Inst)
}
if Inst != Tree {
t.Errorf("Duplicate instances in cycle: %s (%p) -> %s (%p) -> %s (%p)", Inst, Inst, Node, Node, Tree, Tree)
}
}

View File

@ -283,18 +283,19 @@ func identical(x, y Type, cmpTags bool, p *ifacePair) bool {
}
smap := makeSubstMap(ytparams, targs)
var check *Checker // ok to call subst on a nil *Checker
var check *Checker // ok to call subst on a nil *Checker
ctxt := NewContext() // need a non-nil Context for the substitution below
// Constraints must be pair-wise identical, after substitution.
for i, xtparam := range xtparams {
ybound := check.subst(nopos, ytparams[i].bound, smap, nil)
ybound := check.subst(nopos, ytparams[i].bound, smap, nil, ctxt)
if !identical(xtparam.bound, ybound, cmpTags, p) {
return false
}
}
yparams = check.subst(nopos, y.params, smap, nil).(*Tuple)
yresults = check.subst(nopos, y.results, smap, nil).(*Tuple)
yparams = check.subst(nopos, y.params, smap, nil, ctxt).(*Tuple)
yresults = check.subst(nopos, y.results, smap, nil, ctxt).(*Tuple)
}
return x.variadic == y.variadic &&

View File

@ -143,7 +143,7 @@ func (check *Checker) funcType(sig *Signature, recvPar *syntax.Field, tparams []
// recvTPar.bound is (possibly) parameterized in the context of the
// receiver type declaration. Substitute parameters for the current
// context.
tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil)
tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil, check.context())
}
} else if len(tparams) < len(recvTParams) {
// Reporting an error here is a stop-gap measure to avoid crashes in the

View File

@ -49,7 +49,9 @@ func (m substMap) lookup(tpar *TypeParam) Type {
// from the incoming type.
//
// If the given context is non-nil, it is used in lieu of check.Config.Context.
func (check *Checker) subst(pos syntax.Pos, typ Type, smap substMap, ctxt *Context) Type {
func (check *Checker) subst(pos syntax.Pos, typ Type, smap substMap, local, global *Context) Type {
assert(local != nil || global != nil)
if smap.empty() {
return typ
}
@ -64,19 +66,20 @@ func (check *Checker) subst(pos syntax.Pos, typ Type, smap substMap, ctxt *Conte
// general case
subst := subster{
pos: pos,
smap: smap,
check: check,
ctxt: check.bestContext(ctxt),
pos: pos,
smap: smap,
check: check,
local: local,
global: global,
}
return subst.typ(typ)
}
type subster struct {
pos syntax.Pos
smap substMap
check *Checker // nil if called via Instantiate
ctxt *Context
pos syntax.Pos
smap substMap
check *Checker // nil if called via Instantiate
local, global *Context
}
func (subst *subster) typ(typ Type) Type {
@ -247,25 +250,11 @@ func (subst *subster) typ(typ Type) Type {
return t // nothing to substitute
}
// before creating a new named type, check if we have this one already
h := subst.ctxt.instanceHash(orig, newTArgs)
dump(">>> new type hash: %s", h)
if named := subst.ctxt.lookup(h, orig, newTArgs); named != nil {
dump(">>> found %s", named)
return named
}
// Create a new instance and populate the context to avoid endless
// recursion. The position used here is irrelevant because validation only
// occurs on t (we don't call validType on named), but we use subst.pos to
// help with debugging.
return subst.check.instance(subst.pos, orig, newTArgs, subst.ctxt)
// Note that if we were to expose substitution more generally (not just in
// the context of a declaration), we'd have to substitute in
// named.underlying as well.
//
// But this is unnecessary for now.
return subst.check.instance(subst.pos, orig, newTArgs, subst.local, subst.global)
case *TypeParam:
return subst.smap.lookup(t)

View File

@ -433,8 +433,7 @@ func (check *Checker) instantiatedType(x syntax.Expr, xlist []syntax.Expr, def *
}
// create the instance
ctxt := check.bestContext(nil)
inst := check.instance(x.Pos(), orig, targs, ctxt).(*Named)
inst := check.instance(x.Pos(), orig, targs, nil, check.context()).(*Named)
def.setUnderlying(inst)
// orig.tparams may not be set up, so we need to do expansion later.
@ -445,7 +444,7 @@ func (check *Checker) instantiatedType(x syntax.Expr, xlist []syntax.Expr, def *
check.recordInstance(x, inst.TypeArgs().list(), inst)
if check.validateTArgLen(x.Pos(), inst.TypeParams().Len(), inst.TypeArgs().Len()) {
if i, err := check.verify(x.Pos(), inst.TypeParams().list(), inst.TypeArgs().list()); err != nil {
if i, err := check.verify(x.Pos(), inst.TypeParams().list(), inst.TypeArgs().list(), check.context()); err != nil {
// best position for error reporting
pos := x.Pos()
if i < len(xlist) {

View File

@ -73,13 +73,13 @@ func (check *Checker) instantiateSignature(pos token.Pos, typ *Signature, targs
}()
}
inst := check.instance(pos, typ, targs, check.bestContext(nil)).(*Signature)
inst := check.instance(pos, typ, targs, nil, check.context()).(*Signature)
assert(len(xlist) <= len(targs))
// verify instantiation lazily (was issue #50450)
check.later(func() {
tparams := typ.TypeParams().list()
if i, err := check.verify(pos, tparams, targs); err != nil {
if i, err := check.verify(pos, tparams, targs, check.context()); err != nil {
// best position for error reporting
pos := pos
if i < len(xlist) {
@ -400,7 +400,7 @@ func (check *Checker) arguments(call *ast.CallExpr, sig *Signature, targs []Type
// need to compute it from the adjusted list; otherwise we can
// simply use the result signature's parameter list.
if adjusted {
sigParams = check.subst(call.Pos(), sigParams, makeSubstMap(sig.TypeParams().list(), targs), nil).(*Tuple)
sigParams = check.subst(call.Pos(), sigParams, makeSubstMap(sig.TypeParams().list(), targs), nil, check.context()).(*Tuple)
} else {
sigParams = rsig.params
}

View File

@ -110,11 +110,11 @@ func (check *Checker) infer(posn positioner, tparams []*TypeParam, targs []Type,
renameMap := makeRenameMap(tparams, tparams2)
for i, tparam := range tparams {
tparams2[i].bound = check.subst(posn.Pos(), tparam.bound, renameMap, nil)
tparams2[i].bound = check.subst(posn.Pos(), tparam.bound, renameMap, nil, check.context())
}
tparams = tparams2
params = check.subst(posn.Pos(), params, renameMap, nil).(*Tuple)
params = check.subst(posn.Pos(), params, renameMap, nil, check.context()).(*Tuple)
}
}
@ -188,7 +188,7 @@ func (check *Checker) infer(posn positioner, tparams []*TypeParam, targs []Type,
// but that doesn't impact the isParameterized check for now).
if params.Len() > 0 {
smap := makeSubstMap(tparams, targs)
params = check.subst(token.NoPos, params, smap, nil).(*Tuple)
params = check.subst(token.NoPos, params, smap, nil, check.context()).(*Tuple)
}
// Unify parameter and argument types for generic parameters with typed arguments
@ -225,7 +225,7 @@ func (check *Checker) infer(posn positioner, tparams []*TypeParam, targs []Type,
}
smap := makeSubstMap(tparams, targs)
// TODO(rFindley): pass a positioner here, rather than arg.Pos().
inferred := check.subst(arg.Pos(), tpar, smap, nil)
inferred := check.subst(arg.Pos(), tpar, smap, nil, check.context())
// _CannotInferTypeArgs indicates a failure of inference, though the actual
// error may be better attributed to a user-provided type argument (hence
// _InvalidTypeArg). We can't differentiate these cases, so fall back on
@ -626,7 +626,7 @@ func (check *Checker) inferB(posn positioner, tparams []*TypeParam, targs []Type
n := 0
for _, index := range dirty {
t0 := types[index]
if t1 := check.subst(token.NoPos, t0, smap, nil); t1 != t0 {
if t1 := check.subst(token.NoPos, t0, smap, nil, check.context()); t1 != t0 {
types[index] = t1
dirty[n] = index
n++

View File

@ -40,6 +40,9 @@ import (
// count is incorrect; for *Named types, a panic may occur later inside the
// *Named API.
func Instantiate(ctxt *Context, orig Type, targs []Type, validate bool) (Type, error) {
if ctxt == nil {
ctxt = NewContext()
}
if validate {
var tparams []*TypeParam
switch t := orig.(type) {
@ -51,34 +54,71 @@ func Instantiate(ctxt *Context, orig Type, targs []Type, validate bool) (Type, e
if len(targs) != len(tparams) {
return nil, fmt.Errorf("got %d type arguments but %s has %d type parameters", len(targs), orig, len(tparams))
}
if i, err := (*Checker)(nil).verify(token.NoPos, tparams, targs); err != nil {
if i, err := (*Checker)(nil).verify(token.NoPos, tparams, targs, ctxt); err != nil {
return nil, &ArgumentError{i, err}
}
}
inst := (*Checker)(nil).instance(token.NoPos, orig, targs, ctxt)
inst := (*Checker)(nil).instance(token.NoPos, orig, targs, nil, ctxt)
return inst, nil
}
// instance creates a type or function instance using the given original type
// typ and arguments targs. For Named types the resulting instance will be
// unexpanded. check may be nil.
func (check *Checker) instance(pos token.Pos, orig Type, targs []Type, ctxt *Context) (res Type) {
var h string
if ctxt != nil {
h = ctxt.instanceHash(orig, targs)
// typ may already have been instantiated with identical type arguments. In
// that case, re-use the existing instance.
if inst := ctxt.lookup(h, orig, targs); inst != nil {
return inst
// instance resolves a type or function instance for the given original type
// and type arguments. It looks for an existing identical instance in the given
// contexts, creating a new instance if none is found.
//
// If local is non-nil, it is the context associated with a Named instance
// type currently being expanded. If global is non-nil, it is the context
// associated with the current type-checking pass or call to Instantiate. At
// least one of local or global must be non-nil.
//
// For Named types the resulting instance may be unexpanded.
func (check *Checker) instance(pos token.Pos, orig Type, targs []Type, local, global *Context) (res Type) {
// The order of the contexts below matters: we always prefer instances in
// local in order to preserve reference cycles.
//
// Invariant: if local != nil, the returned instance will be the instance
// recorded in local.
var ctxts []*Context
if local != nil {
ctxts = append(ctxts, local)
}
if global != nil {
ctxts = append(ctxts, global)
}
assert(len(ctxts) > 0)
// Compute all hashes; hashes may differ across contexts due to different
// unique IDs for Named types within the hasher.
hashes := make([]string, len(ctxts))
for i, ctxt := range ctxts {
hashes[i] = ctxt.instanceHash(orig, targs)
}
// If local is non-nil, updateContexts return the type recorded in
// local.
updateContexts := func(res Type) Type {
for i := len(ctxts) - 1; i >= 0; i-- {
res = ctxts[i].update(hashes[i], orig, targs, res)
}
return res
}
// typ may already have been instantiated with identical type arguments. In
// that case, re-use the existing instance.
for i, ctxt := range ctxts {
if inst := ctxt.lookup(hashes[i], orig, targs); inst != nil {
return updateContexts(inst)
}
}
switch orig := orig.(type) {
case *Named:
res = check.newNamedInstance(pos, orig, targs)
res = check.newNamedInstance(pos, orig, targs, local) // substituted lazily
case *Signature:
assert(local == nil) // function instances cannot be reached from Named types
tparams := orig.TypeParams()
if !check.validateTArgLen(pos, tparams.Len(), len(targs)) {
return Typ[Invalid]
@ -86,7 +126,7 @@ func (check *Checker) instance(pos token.Pos, orig Type, targs []Type, ctxt *Con
if tparams.Len() == 0 {
return orig // nothing to do (minor optimization)
}
sig := check.subst(pos, orig, makeSubstMap(tparams.list(), targs), ctxt).(*Signature)
sig := check.subst(pos, orig, makeSubstMap(tparams.list(), targs), nil, global).(*Signature)
// If the signature doesn't use its type parameters, subst
// will not make a copy. In that case, make a copy now (so
// we can set tparams to nil w/o causing side-effects).
@ -104,13 +144,8 @@ func (check *Checker) instance(pos token.Pos, orig Type, targs []Type, ctxt *Con
panic(fmt.Sprintf("%v: cannot instantiate %v", pos, orig))
}
if ctxt != nil {
// It's possible that we've lost a race to add named to the context.
// In this case, use whichever instance is recorded in the context.
res = ctxt.update(h, orig, targs, res)
}
return res
// Update all contexts; it's possible that we've lost a race.
return updateContexts(res)
}
// validateTArgLen verifies that the length of targs and tparams matches,
@ -128,7 +163,7 @@ func (check *Checker) validateTArgLen(pos token.Pos, ntparams, ntargs int) bool
return true
}
func (check *Checker) verify(pos token.Pos, tparams []*TypeParam, targs []Type) (int, error) {
func (check *Checker) verify(pos token.Pos, tparams []*TypeParam, targs []Type, ctxt *Context) (int, error) {
smap := makeSubstMap(tparams, targs)
for i, tpar := range tparams {
// Ensure that we have a (possibly implicit) interface as type bound (issue #51048).
@ -137,7 +172,7 @@ func (check *Checker) verify(pos token.Pos, tparams []*TypeParam, targs []Type)
// as the instantiated type; before we can use it for bounds checking we
// need to instantiate it with the type arguments with which we instantiated
// the parameterized type.
bound := check.subst(pos, tpar.bound, smap, nil)
bound := check.subst(pos, tpar.bound, smap, nil, ctxt)
if err := check.implements(targs[i], bound); err != nil {
return i, err
}

View File

@ -79,6 +79,16 @@ import (
// Identical to compare them. For instantiated named types, their obj is a
// synthetic placeholder that records their position of the corresponding
// instantiation in the source (if they were constructed during type checking).
//
// To prevent infinite expansion of named instances that are created outside of
// type-checking, instances share a Context with other instances created during
// their expansion. Via the pidgeonhole principle, this guarantees that in the
// presence of a cycle of named types, expansion will eventually find an
// existing instance in the Context and short-circuit the expansion.
//
// Once an instance is complete, we can nil out this shared Context to unpin
// memory, though this Context may still be held by other incomplete instances
// in its "lineage".
// A Named represents a named (defined) type.
type Named struct {
@ -115,6 +125,7 @@ type instance struct {
orig *Named // original, uninstantiated type
targs *TypeList // type arguments
expandedMethods int // number of expanded methods; expandedMethods <= len(orig.methods)
ctxt *Context // local Context; set to nil after full expansion
}
// namedState represents the possible states that a named type may assume.
@ -143,7 +154,7 @@ func NewNamed(obj *TypeName, underlying Type, methods []*Func) *Named {
// After resolution, the type parameters, methods, and underlying type of n are
// accessible; but if n is an instantiated type, its methods may still be
// unexpanded.
func (n *Named) resolve(ctxt *Context) *Named {
func (n *Named) resolve() *Named {
if n.state() >= resolved { // avoid locking below
return n
}
@ -162,8 +173,8 @@ func (n *Named) resolve(ctxt *Context) *Named {
assert(n.loader == nil) // instances are created by instantiation, in which case n.loader is nil
orig := n.inst.orig
orig.resolve(ctxt)
underlying := n.expandUnderlying(ctxt)
orig.resolve()
underlying := n.expandUnderlying()
n.tparams = orig.tparams
n.underlying = underlying
@ -171,6 +182,7 @@ func (n *Named) resolve(ctxt *Context) *Named {
if len(orig.methods) == 0 {
n.setState(complete) // nothing further to do
n.inst.ctxt = nil
} else {
n.setState(resolved)
}
@ -225,11 +237,11 @@ func (check *Checker) newNamed(obj *TypeName, underlying Type, methods []*Func)
return typ
}
func (check *Checker) newNamedInstance(pos token.Pos, orig *Named, targs []Type) *Named {
func (check *Checker) newNamedInstance(pos token.Pos, orig *Named, targs []Type, local *Context) *Named {
assert(len(targs) > 0)
obj := NewTypeName(pos, orig.obj.pkg, orig.obj.name, nil)
inst := &instance{orig: orig, targs: newTypeList(targs)}
inst := &instance{orig: orig, targs: newTypeList(targs), ctxt: local}
typ := &Named{check: check, obj: obj, inst: inst}
obj.typ = typ
// Ensure that typ is always expanded and sanity-checked.
@ -280,13 +292,13 @@ func (t *Named) Origin() *Named {
// TypeParams returns the type parameters of the named type t, or nil.
// The result is non-nil for an (originally) generic type even if it is instantiated.
func (t *Named) TypeParams() *TypeParamList { return t.resolve(nil).tparams }
func (t *Named) TypeParams() *TypeParamList { return t.resolve().tparams }
// SetTypeParams sets the type parameters of the named type t.
// t must not have type arguments.
func (t *Named) SetTypeParams(tparams []*TypeParam) {
assert(t.inst == nil)
t.resolve(nil).tparams = bindTParams(tparams)
t.resolve().tparams = bindTParams(tparams)
}
// TypeArgs returns the type arguments used to instantiate the named type t.
@ -298,17 +310,17 @@ func (t *Named) TypeArgs() *TypeList {
}
// NumMethods returns the number of explicit methods defined for t.
//
// For an ordinary or instantiated type t, the receiver base type of these
// methods will be the named type t. For an uninstantiated generic type t, each
// method receiver will be instantiated with its receiver type parameters.
func (t *Named) NumMethods() int {
return len(t.Origin().resolve(nil).methods)
return len(t.Origin().resolve().methods)
}
// Method returns the i'th method of named type t for 0 <= i < t.NumMethods().
//
// For an ordinary or instantiated type t, the receiver base type of this
// method is the named type t. For an uninstantiated generic type t, each
// method receiver is instantiated with its receiver type parameters.
func (t *Named) Method(i int) *Func {
t.resolve(nil)
t.resolve()
if t.state() >= complete {
return t.methods[i]
@ -326,6 +338,7 @@ func (t *Named) Method(i int) *Func {
}
if t.methods[i] == nil {
assert(t.inst.ctxt != nil) // we should still have a context remaining from the resolution phase
t.methods[i] = t.expandMethod(i)
t.inst.expandedMethods++
@ -333,6 +346,7 @@ func (t *Named) Method(i int) *Func {
// type as fully expanded.
if t.inst.expandedMethods == len(orig.methods) {
t.setState(complete)
t.inst.ctxt = nil // no need for a context anymore
}
}
@ -372,9 +386,12 @@ func (t *Named) expandMethod(i int) *Func {
// and type parameters. This check is necessary in the presence of invalid
// code.
if origSig.RecvTypeParams().Len() == t.inst.targs.Len() {
ctxt := check.bestContext(nil)
smap := makeSubstMap(origSig.RecvTypeParams().list(), t.inst.targs.list())
sig = check.subst(origm.pos, origSig, smap, ctxt).(*Signature)
var global *Context
if check != nil {
global = check.context()
}
sig = check.subst(origm.pos, origSig, smap, t.inst.ctxt, global).(*Signature)
}
if sig == origSig {
@ -405,7 +422,7 @@ func (t *Named) SetUnderlying(underlying Type) {
if _, ok := underlying.(*Named); ok {
panic("underlying type must not be *Named")
}
t.resolve(nil).underlying = underlying
t.resolve().underlying = underlying
if t.fromRHS == nil {
t.fromRHS = underlying // for cycle detection
}
@ -415,17 +432,20 @@ func (t *Named) SetUnderlying(underlying Type) {
// t must not have type arguments.
func (t *Named) AddMethod(m *Func) {
assert(t.inst == nil)
t.resolve(nil)
t.resolve()
if i, _ := lookupMethod(t.methods, m.pkg, m.name, false); i < 0 {
t.methods = append(t.methods, m)
}
}
func (t *Named) Underlying() Type { return t.resolve(nil).underlying }
func (t *Named) Underlying() Type { return t.resolve().underlying }
func (t *Named) String() string { return TypeString(t, nil) }
// ----------------------------------------------------------------------------
// Implementation
//
// TODO(rfindley): reorganize the loading and expansion methods under this
// heading.
// under returns the expanded underlying type of n0; possibly by following
// forward chains of named types. If an underlying type is found, resolve
@ -522,7 +542,7 @@ func (n *Named) setUnderlying(typ Type) {
}
func (n *Named) lookupMethod(pkg *Package, name string, foldCase bool) (int, *Func) {
n.resolve(nil)
n.resolve()
// If n is an instance, we may not have yet instantiated all of its methods.
// Look up the method index in orig, and only instantiate method at the
// matching index (if any).
@ -534,26 +554,17 @@ func (n *Named) lookupMethod(pkg *Package, name string, foldCase bool) (int, *Fu
return i, n.Method(i)
}
// bestContext returns the best available context. In order of preference:
// - the given ctxt, if non-nil
// - check.ctxt, if check is non-nil
// - a new Context
func (check *Checker) bestContext(ctxt *Context) *Context {
if ctxt != nil {
return ctxt
// context returns the type-checker context.
func (check *Checker) context() *Context {
if check.ctxt == nil {
check.ctxt = NewContext()
}
if check != nil {
if check.ctxt == nil {
check.ctxt = NewContext()
}
return check.ctxt
}
return NewContext()
return check.ctxt
}
// expandUnderlying substitutes type arguments in the underlying type n.orig,
// returning the result. Returns Typ[Invalid] if there was an error.
func (n *Named) expandUnderlying(ctxt *Context) Type {
func (n *Named) expandUnderlying() Type {
check := n.check
if check != nil && trace {
check.trace(n.obj.pos, "-- Named.expandUnderlying %s", n)
@ -565,6 +576,9 @@ func (n *Named) expandUnderlying(ctxt *Context) Type {
}
assert(n.inst.orig.underlying != nil)
if n.inst.ctxt == nil {
n.inst.ctxt = NewContext()
}
orig := n.inst.orig
targs := n.inst.targs
@ -580,16 +594,20 @@ func (n *Named) expandUnderlying(ctxt *Context) Type {
return Typ[Invalid]
}
// We must always have a context, to avoid infinite recursion.
ctxt = check.bestContext(ctxt)
h := ctxt.instanceHash(orig, targs.list())
// ensure that an instance is recorded for h to avoid infinite recursion.
ctxt.update(h, orig, targs.list(), n)
// Ensure that an instance is recorded before substituting, so that we
// resolve n for any recursive references.
h := n.inst.ctxt.instanceHash(orig, targs.list())
n2 := n.inst.ctxt.update(h, orig, n.TypeArgs().list(), n)
assert(n == n2)
smap := makeSubstMap(orig.tparams.list(), targs.list())
underlying := n.check.subst(n.obj.pos, orig.underlying, smap, ctxt)
// If the underlying type of n is an interface, we need to set the receiver
// of its methods accurately -- we set the receiver of interface methods on
var global *Context
if check != nil {
global = check.context()
}
underlying := n.check.subst(n.obj.pos, orig.underlying, smap, n.inst.ctxt, global)
// If the underlying type of n is an interface, we need to set the receiver of
// its methods accurately -- we set the receiver of interface methods on
// the RHS of a type declaration to the defined type.
if iface, _ := underlying.(*Interface); iface != nil {
if methods, copied := replaceRecvType(iface.methods, orig, n); copied {

View File

@ -5,6 +5,9 @@
package types_test
import (
"go/ast"
"go/parser"
"go/token"
"testing"
. "go/types"
@ -86,3 +89,48 @@ func mustInstantiate(tb testing.TB, orig Type, targs ...Type) Type {
}
return inst
}
// Test that types do not expand infinitely, as in golang/go#52715.
func TestFiniteTypeExpansion(t *testing.T) {
const src = `
package p
type Tree[T any] struct {
*Node[T]
}
func (*Tree[R]) N(r R) R { return r }
type Node[T any] struct {
*Tree[T]
}
func (Node[Q]) M(Q) {}
type Inst = *Tree[int]
`
fset := token.NewFileSet()
f, err := parser.ParseFile(fset, "foo.go", src, 0)
if err != nil {
t.Fatal(err)
}
pkg := NewPackage("p", f.Name.Name)
if err := NewChecker(nil, fset, pkg, nil).Files([]*ast.File{f}); err != nil {
t.Fatal(err)
}
firstFieldType := func(n *Named) *Named {
return n.Underlying().(*Struct).Field(0).Type().(*Pointer).Elem().(*Named)
}
Inst := pkg.Scope().Lookup("Inst").Type().(*Pointer).Elem().(*Named)
Node := firstFieldType(Inst)
Tree := firstFieldType(Node)
if !Identical(Inst, Tree) {
t.Fatalf("Not a cycle: got %v, want %v", Tree, Inst)
}
if Inst != Tree {
t.Errorf("Duplicate instances in cycle: %s (%p) -> %s (%p) -> %s (%p)", Inst, Inst, Node, Node, Tree, Tree)
}
}

View File

@ -285,18 +285,19 @@ func identical(x, y Type, cmpTags bool, p *ifacePair) bool {
}
smap := makeSubstMap(ytparams, targs)
var check *Checker // ok to call subst on a nil *Checker
var check *Checker // ok to call subst on a nil *Checker
ctxt := NewContext() // need a non-nil Context for the substitution below
// Constraints must be pair-wise identical, after substitution.
for i, xtparam := range xtparams {
ybound := check.subst(token.NoPos, ytparams[i].bound, smap, nil)
ybound := check.subst(token.NoPos, ytparams[i].bound, smap, nil, ctxt)
if !identical(xtparam.bound, ybound, cmpTags, p) {
return false
}
}
yparams = check.subst(token.NoPos, y.params, smap, nil).(*Tuple)
yresults = check.subst(token.NoPos, y.results, smap, nil).(*Tuple)
yparams = check.subst(token.NoPos, y.params, smap, nil, ctxt).(*Tuple)
yresults = check.subst(token.NoPos, y.results, smap, nil, ctxt).(*Tuple)
}
return x.variadic == y.variadic &&

View File

@ -150,7 +150,7 @@ func (check *Checker) funcType(sig *Signature, recvPar *ast.FieldList, ftyp *ast
// recvTPar.bound is (possibly) parameterized in the context of the
// receiver type declaration. Substitute parameters for the current
// context.
tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil)
tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil, check.context())
}
} else if len(tparams) < len(recvTParams) {
// Reporting an error here is a stop-gap measure to avoid crashes in the

View File

@ -49,7 +49,9 @@ func (m substMap) lookup(tpar *TypeParam) Type {
// result type is different from the incoming type.
//
// If the given context is non-nil, it is used in lieu of check.Config.Context
func (check *Checker) subst(pos token.Pos, typ Type, smap substMap, ctxt *Context) Type {
func (check *Checker) subst(pos token.Pos, typ Type, smap substMap, local, global *Context) Type {
assert(local != nil || global != nil)
if smap.empty() {
return typ
}
@ -64,19 +66,20 @@ func (check *Checker) subst(pos token.Pos, typ Type, smap substMap, ctxt *Contex
// general case
subst := subster{
pos: pos,
smap: smap,
check: check,
ctxt: check.bestContext(ctxt),
pos: pos,
smap: smap,
check: check,
local: local,
global: global,
}
return subst.typ(typ)
}
type subster struct {
pos token.Pos
smap substMap
check *Checker // nil if called via Instantiate
ctxt *Context
pos token.Pos
smap substMap
check *Checker // nil if called via Instantiate
local, global *Context
}
func (subst *subster) typ(typ Type) Type {
@ -247,25 +250,11 @@ func (subst *subster) typ(typ Type) Type {
return t // nothing to substitute
}
// before creating a new named type, check if we have this one already
h := subst.ctxt.instanceHash(orig, newTArgs)
dump(">>> new type hash: %s", h)
if named := subst.ctxt.lookup(h, orig, newTArgs); named != nil {
dump(">>> found %s", named)
return named
}
// Create a new instance and populate the context to avoid endless
// recursion. The position used here is irrelevant because validation only
// occurs on t (we don't call validType on named), but we use subst.pos to
// help with debugging.
return subst.check.instance(subst.pos, orig, newTArgs, subst.ctxt)
// Note that if we were to expose substitution more generally (not just in
// the context of a declaration), we'd have to substitute in
// named.underlying as well.
//
// But this is unnecessary for now.
return subst.check.instance(subst.pos, orig, newTArgs, subst.local, subst.global)
case *TypeParam:
return subst.smap.lookup(t)

View File

@ -417,8 +417,7 @@ func (check *Checker) instantiatedType(ix *typeparams.IndexExpr, def *Named) (re
}
// create the instance
ctxt := check.bestContext(nil)
inst := check.instance(ix.Pos(), orig, targs, ctxt).(*Named)
inst := check.instance(ix.Pos(), orig, targs, nil, check.context()).(*Named)
def.setUnderlying(inst)
// orig.tparams may not be set up, so we need to do expansion later.
@ -429,7 +428,7 @@ func (check *Checker) instantiatedType(ix *typeparams.IndexExpr, def *Named) (re
check.recordInstance(ix.Orig, inst.TypeArgs().list(), inst)
if check.validateTArgLen(ix.Pos(), inst.TypeParams().Len(), inst.TypeArgs().Len()) {
if i, err := check.verify(ix.Pos(), inst.TypeParams().list(), inst.TypeArgs().list()); err != nil {
if i, err := check.verify(ix.Pos(), inst.TypeParams().list(), inst.TypeArgs().list(), check.context()); err != nil {
// best position for error reporting
pos := ix.Pos()
if i < len(ix.Indices) {