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cmd/compile: fix CheckSize() calculation for -G=3 and stencils

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Because the Align/Width of pointer types are always set when created,
CalcSize() never descends past a pointer. Therefore, we need to do
CheckSize() at every level when creating type. We need to do this for
types creates by types2-to-types1 conversion and also by type
substitution (mostly for stenciling). We also need to do
Defer/ResumeCheckSize() at the top level in each of these cases to deal
with potentially recursive types.

These changes fix issue #47929 and also allow us to remove the
special-case CheckSize() call that causes the problem for issue #47901.

Fixes #47901
Fixes #47929

Change-Id: Icd8192431c145009cd6df2f4ade6db7da0f4dd3e
Reviewed-on: https://go-review.googlesource.com/c/go/+/344829
Trust: Dan Scales <danscales@google.com>
Reviewed-by: Keith Randall <khr@golang.org>
This commit is contained in:
Dan Scales 2021-08-24 15:34:52 -07:00
parent e1fcf8857e
commit 099b819085
4 changed files with 88 additions and 38 deletions
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24
src/cmd/compile/internal/noder/types.go
View File

@ -30,21 +30,11 @@ func (g *irgen) pkg(pkg *types2.Package) *types.Pkg {
// typ converts a types2.Type to a types.Type, including caching of previously
// translated types.
func (g *irgen) typ(typ types2.Type) *types.Type {
// Defer the CheckSize calls until we have fully-defined a
// (possibly-recursive) top-level type.
types.DeferCheckSize()
res := g.typ1(typ)
// Calculate the size for all concrete types seen by the frontend. The old
// typechecker calls CheckSize() a lot, and we want to eliminate calling
// it eventually, so we should do it here instead. We only call it for
// top-level types (i.e. we do it here rather in typ1), to make sure that
// recursive types have been fully constructed before we call CheckSize.
if res != nil && !res.IsUntyped() && !res.IsFuncArgStruct() && !res.HasTParam() {
types.CheckSize(res)
if res.IsPtr() {
// Pointers always have their size set, even though their element
// may not have its size set.
types.CheckSize(res.Elem())
}
}
types.ResumeCheckSize()
return res
}
@ -59,6 +49,12 @@ func (g *irgen) typ1(typ types2.Type) *types.Type {
res, ok := g.typs[typ]
if !ok {
res = g.typ0(typ)
// Calculate the size for all concrete types seen by the frontend.
// This is the replacement for the CheckSize() calls in the types1
// typechecker. These will be deferred until the top-level g.typ().
if res != nil && !res.IsUntyped() && !res.IsFuncArgStruct() && !res.HasTParam() {
types.CheckSize(res)
}
g.typs[typ] = res
}
return res

52
src/cmd/compile/internal/typecheck/subr.go
View File

@ -1003,6 +1003,15 @@ type Tsubster struct {
// result is t; otherwise the result is a new type. It deals with recursive types
// by using TFORW types and finding partially or fully created types via sym.Def.
func (ts *Tsubster) Typ(t *types.Type) *types.Type {
// Defer the CheckSize calls until we have fully-defined
// (possibly-recursive) top-level type.
types.DeferCheckSize()
r := ts.typ1(t)
types.ResumeCheckSize()
return r
}
func (ts *Tsubster) typ1(t *types.Type) *types.Type {
if !t.HasTParam() && t.Kind() != types.TFUNC {
// Note: function types need to be copied regardless, as the
// types of closures may contain declarations that need
@ -1047,7 +1056,7 @@ func (ts *Tsubster) Typ(t *types.Type) *types.Type {
// the tparam/targs mapping from subst.
neededTargs = make([]*types.Type, len(t.RParams()))
for i, rparam := range t.RParams() {
neededTargs[i] = ts.Typ(rparam)
neededTargs[i] = ts.typ1(rparam)
if !types.Identical(neededTargs[i], rparam) {
targsChanged = true
}
@ -1085,26 +1094,26 @@ func (ts *Tsubster) Typ(t *types.Type) *types.Type {
}
// Substitute the underlying typeparam (e.g. T in P[T], see
// the example describing type P[T] above).
newt = ts.Typ(t.Underlying())
newt = ts.typ1(t.Underlying())
assert(newt != t)
case types.TARRAY:
elem := t.Elem()
newelem := ts.Typ(elem)
newelem := ts.typ1(elem)
if newelem != elem || targsChanged {
newt = types.NewArray(newelem, t.NumElem())
}
case types.TPTR:
elem := t.Elem()
newelem := ts.Typ(elem)
newelem := ts.typ1(elem)
if newelem != elem || targsChanged {
newt = types.NewPtr(newelem)
}
case types.TSLICE:
elem := t.Elem()
newelem := ts.Typ(elem)
newelem := ts.typ1(elem)
if newelem != elem || targsChanged {
newt = types.NewSlice(newelem)
}
@ -1159,22 +1168,17 @@ func (ts *Tsubster) Typ(t *types.Type) *types.Type {
}
case types.TMAP:
newkey := ts.Typ(t.Key())
newval := ts.Typ(t.Elem())
newkey := ts.typ1(t.Key())
newval := ts.typ1(t.Elem())
if newkey != t.Key() || newval != t.Elem() || targsChanged {
newt = types.NewMap(newkey, newval)
}
case types.TCHAN:
elem := t.Elem()
newelem := ts.Typ(elem)
newelem := ts.typ1(elem)
if newelem != elem || targsChanged {
newt = types.NewChan(newelem, t.ChanDir())
if !newt.HasTParam() {
// TODO(danscales): not sure why I have to do this
// only for channels.....
types.CheckSize(newt)
}
}
case types.TFORW:
if ts.SubstForwFunc != nil {
@ -1194,7 +1198,7 @@ func (ts *Tsubster) Typ(t *types.Type) *types.Type {
for i := 0; i < nt; i++ {
term, tilde := t.Term(i)
tildes[i] = tilde
newterms[i] = ts.Typ(term)
newterms[i] = ts.typ1(term)
if newterms[i] != term {
changed = true
}
@ -1212,24 +1216,24 @@ func (ts *Tsubster) Typ(t *types.Type) *types.Type {
return t
}
if t.Sym() == nil && t.Kind() != types.TINTER {
// Not a named type or interface type, so there was no forwarding type
// and there are no methods to substitute.
assert(t.Methods().Len() == 0)
return newt
}
if forw != nil {
forw.SetUnderlying(newt)
newt = forw
}
if !newt.HasTParam() {
// Calculate the size of any new types created. These will be
// deferred until the top-level ts.Typ() or g.typ() (if this is
// called from g.fillinMethods()).
types.CheckSize(newt)
}
if t.Kind() != types.TINTER && t.Methods().Len() > 0 {
// Fill in the method info for the new type.
var newfields []*types.Field
newfields = make([]*types.Field, t.Methods().Len())
for i, f := range t.Methods().Slice() {
t2 := ts.Typ(f.Type)
t2 := ts.typ1(f.Type)
oldsym := f.Nname.Sym()
newsym := MakeFuncInstSym(oldsym, ts.Targs, true)
var nname *ir.Name
@ -1272,7 +1276,7 @@ func (ts *Tsubster) tstruct(t *types.Type, force bool) *types.Type {
newfields = make([]*types.Field, t.NumFields())
}
for i, f := range t.Fields().Slice() {
t2 := ts.Typ(f.Type)
t2 := ts.typ1(f.Type)
if (t2 != f.Type || f.Nname != nil) && newfields == nil {
newfields = make([]*types.Field, t.NumFields())
for j := 0; j < i; j++ {
@ -1325,7 +1329,7 @@ func (ts *Tsubster) tinter(t *types.Type) *types.Type {
}
var newfields []*types.Field
for i, f := range t.Methods().Slice() {
t2 := ts.Typ(f.Type)
t2 := ts.typ1(f.Type)
if (t2 != f.Type || f.Nname != nil) && newfields == nil {
newfields = make([]*types.Field, t.Methods().Len())
for j := 0; j < i; j++ {

21
test/typeparam/issue47901.go Normal file
View File

@ -0,0 +1,21 @@
// run -gcflags=-G=3
// 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 main
type Chan[T any] chan Chan[T]
func (ch Chan[T]) recv() Chan[T] {
return <-ch
}
func main() {
ch := Chan[int](make(chan Chan[int]))
go func() {
ch <- make(Chan[int])
}()
ch.recv()
}

29
test/typeparam/issue47929.go Normal file
View File

@ -0,0 +1,29 @@
// compile -G=3 -p=p
// 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 v4
var sink interface{}
//go:noinline
func Do(result, body interface{}) {
sink = &result
}
func DataAction(result DataActionResponse, body DataActionRequest) {
Do(&result, body)
}
type DataActionRequest struct {
Action *interface{}
}
type DataActionResponse struct {
ValidationErrors *ValidationError
}
type ValidationError struct {
}