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[dev.typeparams] go/types: move interface checking into separate file

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This is a port of CL 321549 to go/types. Specifically, the same checker
methods were moved.

Change-Id: I491a8c5a985d71ebb23e4b34541a557da0af0cfc
Reviewed-on: https://go-review.googlesource.com/c/go/+/324752
Trust: Robert Findley <rfindley@google.com>
Run-TryBot: Robert Findley <rfindley@google.com>
TryBot-Result: Go Bot <gobot@golang.org>
Reviewed-by: Robert Griesemer <gri@golang.org>
This commit is contained in:
Rob Findley 2021-06-03 11:04:50 -04:00 committed by Robert Findley
parent 090a17c998
commit ffc74ad5d3
2 changed files with 321 additions and 310 deletions
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321
src/go/types/interface.go Normal file
View File

@ -0,0 +1,321 @@
// 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 types
import (
"go/ast"
"go/internal/typeparams"
"go/token"
"sort"
)
func (check *Checker) interfaceType(ityp *Interface, iface *ast.InterfaceType, def *Named) {
var tlist *ast.Ident // "type" name of first entry in a type list declaration
var types []ast.Expr
for _, f := range iface.Methods.List {
if len(f.Names) > 0 {
// We have a method with name f.Names[0], or a type
// of a type list (name.Name == "type").
// (The parser ensures that there's only one method
// and we don't care if a constructed AST has more.)
name := f.Names[0]
if name.Name == "_" {
check.errorf(name, _BlankIfaceMethod, "invalid method name _")
continue // ignore
}
if name.Name == "type" {
// Always collect all type list entries, even from
// different type lists, under the assumption that
// the author intended to include all types.
types = append(types, f.Type)
if tlist != nil && tlist != name {
check.errorf(name, _Todo, "cannot have multiple type lists in an interface")
}
tlist = name
continue
}
typ := check.typ(f.Type)
sig, _ := typ.(*Signature)
if sig == nil {
if typ != Typ[Invalid] {
check.invalidAST(f.Type, "%s is not a method signature", typ)
}
continue // ignore
}
// Always type-check method type parameters but complain if they are not enabled.
// (This extra check is needed here because interface method signatures don't have
// a receiver specification.)
if sig.tparams != nil {
var at positioner = f.Type
if tparams := typeparams.Get(f.Type); tparams != nil {
at = tparams
}
check.errorf(at, _Todo, "methods cannot have type parameters")
}
// use named receiver type if available (for better error messages)
var recvTyp Type = ityp
if def != nil {
recvTyp = def
}
sig.recv = NewVar(name.Pos(), check.pkg, "", recvTyp)
m := NewFunc(name.Pos(), check.pkg, name.Name, sig)
check.recordDef(name, m)
ityp.methods = append(ityp.methods, m)
} else {
// We have an embedded type. completeInterface will
// eventually verify that we have an interface.
ityp.embeddeds = append(ityp.embeddeds, check.typ(f.Type))
check.posMap[ityp] = append(check.posMap[ityp], f.Type.Pos())
}
}
// type constraints
ityp.types = _NewSum(check.collectTypeConstraints(iface.Pos(), types))
if len(ityp.methods) == 0 && ityp.types == nil && len(ityp.embeddeds) == 0 {
// empty interface
ityp.allMethods = markComplete
return
}
// sort for API stability
sortMethods(ityp.methods)
sortTypes(ityp.embeddeds)
check.later(func() { check.completeInterface(iface.Pos(), ityp) })
}
func (check *Checker) collectTypeConstraints(pos token.Pos, types []ast.Expr) []Type {
list := make([]Type, 0, len(types)) // assume all types are correct
for _, texpr := range types {
if texpr == nil {
check.invalidAST(atPos(pos), "missing type constraint")
continue
}
list = append(list, check.varType(texpr))
}
// Ensure that each type is only present once in the type list. Types may be
// interfaces, which may not be complete yet. It's ok to do this check at the
// end because it's not a requirement for correctness of the code.
// Note: This is a quadratic algorithm, but type lists tend to be short.
check.later(func() {
for i, t := range list {
if t := asInterface(t); t != nil {
check.completeInterface(types[i].Pos(), t)
}
if includes(list[:i], t) {
check.softErrorf(types[i], _Todo, "duplicate type %s in type list", t)
}
}
})
return list
}
// includes reports whether typ is in list.
func includes(list []Type, typ Type) bool {
for _, e := range list {
if Identical(typ, e) {
return true
}
}
return false
}
func (check *Checker) completeInterface(pos token.Pos, ityp *Interface) {
if ityp.allMethods != nil {
return
}
// completeInterface may be called via the LookupFieldOrMethod,
// MissingMethod, Identical, or IdenticalIgnoreTags external API
// in which case check will be nil. In this case, type-checking
// must be finished and all interfaces should have been completed.
if check == nil {
panic("internal error: incomplete interface")
}
if trace {
// Types don't generally have position information.
// If we don't have a valid pos provided, try to use
// one close enough.
if !pos.IsValid() && len(ityp.methods) > 0 {
pos = ityp.methods[0].pos
}
check.trace(pos, "complete %s", ityp)
check.indent++
defer func() {
check.indent--
check.trace(pos, "=> %s (methods = %v, types = %v)", ityp, ityp.allMethods, ityp.allTypes)
}()
}
// An infinitely expanding interface (due to a cycle) is detected
// elsewhere (Checker.validType), so here we simply assume we only
// have valid interfaces. Mark the interface as complete to avoid
// infinite recursion if the validType check occurs later for some
// reason.
ityp.allMethods = markComplete
// Methods of embedded interfaces are collected unchanged; i.e., the identity
// of a method I.m's Func Object of an interface I is the same as that of
// the method m in an interface that embeds interface I. On the other hand,
// if a method is embedded via multiple overlapping embedded interfaces, we
// don't provide a guarantee which "original m" got chosen for the embedding
// interface. See also issue #34421.
//
// If we don't care to provide this identity guarantee anymore, instead of
// reusing the original method in embeddings, we can clone the method's Func
// Object and give it the position of a corresponding embedded interface. Then
// we can get rid of the mpos map below and simply use the cloned method's
// position.
var seen objset
var methods []*Func
mpos := make(map[*Func]token.Pos) // method specification or method embedding position, for good error messages
addMethod := func(pos token.Pos, m *Func, explicit bool) {
switch other := seen.insert(m); {
case other == nil:
methods = append(methods, m)
mpos[m] = pos
case explicit:
check.errorf(atPos(pos), _DuplicateDecl, "duplicate method %s", m.name)
check.errorf(atPos(mpos[other.(*Func)]), _DuplicateDecl, "\tother declaration of %s", m.name) // secondary error, \t indented
default:
// We have a duplicate method name in an embedded (not explicitly declared) method.
// Check method signatures after all types are computed (issue #33656).
// If we're pre-go1.14 (overlapping embeddings are not permitted), report that
// error here as well (even though we could do it eagerly) because it's the same
// error message.
check.later(func() {
if !check.allowVersion(m.pkg, 1, 14) || !check.identical(m.typ, other.Type()) {
check.errorf(atPos(pos), _DuplicateDecl, "duplicate method %s", m.name)
check.errorf(atPos(mpos[other.(*Func)]), _DuplicateDecl, "\tother declaration of %s", m.name) // secondary error, \t indented
}
})
}
}
for _, m := range ityp.methods {
addMethod(m.pos, m, true)
}
// collect types
allTypes := ityp.types
posList := check.posMap[ityp]
for i, typ := range ityp.embeddeds {
pos := posList[i] // embedding position
utyp := under(typ)
etyp := asInterface(utyp)
if etyp == nil {
if utyp != Typ[Invalid] {
var format string
if _, ok := utyp.(*_TypeParam); ok {
format = "%s is a type parameter, not an interface"
} else {
format = "%s is not an interface"
}
// TODO: correct error code.
check.errorf(atPos(pos), _InvalidIfaceEmbed, format, typ)
}
continue
}
check.completeInterface(pos, etyp)
for _, m := range etyp.allMethods {
addMethod(pos, m, false) // use embedding position pos rather than m.pos
}
allTypes = intersect(allTypes, etyp.allTypes)
}
if methods != nil {
sort.Sort(byUniqueMethodName(methods))
ityp.allMethods = methods
}
ityp.allTypes = allTypes
}
// intersect computes the intersection of the types x and y.
// Note: A incomming nil type stands for the top type. A top
// type result is returned as nil.
func intersect(x, y Type) (r Type) {
defer func() {
if r == theTop {
r = nil
}
}()
switch {
case x == theBottom || y == theBottom:
return theBottom
case x == nil || x == theTop:
return y
case y == nil || x == theTop:
return x
}
xtypes := unpackType(x)
ytypes := unpackType(y)
// Compute the list rtypes which includes only
// types that are in both xtypes and ytypes.
// Quadratic algorithm, but good enough for now.
// TODO(gri) fix this
var rtypes []Type
for _, x := range xtypes {
if includes(ytypes, x) {
rtypes = append(rtypes, x)
}
}
if rtypes == nil {
return theBottom
}
return _NewSum(rtypes)
}
func sortTypes(list []Type) {
sort.Stable(byUniqueTypeName(list))
}
// byUniqueTypeName named type lists can be sorted by their unique type names.
type byUniqueTypeName []Type
func (a byUniqueTypeName) Len() int { return len(a) }
func (a byUniqueTypeName) Less(i, j int) bool { return sortName(a[i]) < sortName(a[j]) }
func (a byUniqueTypeName) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
func sortName(t Type) string {
if named := asNamed(t); named != nil {
return named.obj.Id()
}
return ""
}
func sortMethods(list []*Func) {
sort.Sort(byUniqueMethodName(list))
}
func assertSortedMethods(list []*Func) {
if !debug {
panic("internal error: assertSortedMethods called outside debug mode")
}
if !sort.IsSorted(byUniqueMethodName(list)) {
panic("internal error: methods not sorted")
}
}
// byUniqueMethodName method lists can be sorted by their unique method names.
type byUniqueMethodName []*Func
func (a byUniqueMethodName) Len() int { return len(a) }
func (a byUniqueMethodName) Less(i, j int) bool { return a[i].Id() < a[j].Id() }
func (a byUniqueMethodName) Swap(i, j int) { a[i], a[j] = a[j], a[i] }

310
src/go/types/typexpr.go
View File

@ -12,7 +12,6 @@ import (
"go/constant" "go/constant"
"go/internal/typeparams" "go/internal/typeparams"
"go/token" "go/token"
"sort"
"strconv" "strconv"
"strings" "strings"
) )
@ -758,277 +757,6 @@ func (check *Checker) declareInSet(oset *objset, pos token.Pos, obj Object) bool
return true return true
} }
func (check *Checker) interfaceType(ityp *Interface, iface *ast.InterfaceType, def *Named) {
var tlist *ast.Ident // "type" name of first entry in a type list declaration
var types []ast.Expr
for _, f := range iface.Methods.List {
if len(f.Names) > 0 {
// We have a method with name f.Names[0], or a type
// of a type list (name.Name == "type").
// (The parser ensures that there's only one method
// and we don't care if a constructed AST has more.)
name := f.Names[0]
if name.Name == "_" {
check.errorf(name, _BlankIfaceMethod, "invalid method name _")
continue // ignore
}
if name.Name == "type" {
// Always collect all type list entries, even from
// different type lists, under the assumption that
// the author intended to include all types.
types = append(types, f.Type)
if tlist != nil && tlist != name {
check.errorf(name, _Todo, "cannot have multiple type lists in an interface")
}
tlist = name
continue
}
typ := check.typ(f.Type)
sig, _ := typ.(*Signature)
if sig == nil {
if typ != Typ[Invalid] {
check.invalidAST(f.Type, "%s is not a method signature", typ)
}
continue // ignore
}
// Always type-check method type parameters but complain if they are not enabled.
// (This extra check is needed here because interface method signatures don't have
// a receiver specification.)
if sig.tparams != nil {
var at positioner = f.Type
if tparams := typeparams.Get(f.Type); tparams != nil {
at = tparams
}
check.errorf(at, _Todo, "methods cannot have type parameters")
}
// use named receiver type if available (for better error messages)
var recvTyp Type = ityp
if def != nil {
recvTyp = def
}
sig.recv = NewVar(name.Pos(), check.pkg, "", recvTyp)
m := NewFunc(name.Pos(), check.pkg, name.Name, sig)
check.recordDef(name, m)
ityp.methods = append(ityp.methods, m)
} else {
// We have an embedded type. completeInterface will
// eventually verify that we have an interface.
ityp.embeddeds = append(ityp.embeddeds, check.typ(f.Type))
check.posMap[ityp] = append(check.posMap[ityp], f.Type.Pos())
}
}
// type constraints
ityp.types = _NewSum(check.collectTypeConstraints(iface.Pos(), types))
if len(ityp.methods) == 0 && ityp.types == nil && len(ityp.embeddeds) == 0 {
// empty interface
ityp.allMethods = markComplete
return
}
// sort for API stability
sortMethods(ityp.methods)
sortTypes(ityp.embeddeds)
check.later(func() { check.completeInterface(iface.Pos(), ityp) })
}
func (check *Checker) completeInterface(pos token.Pos, ityp *Interface) {
if ityp.allMethods != nil {
return
}
// completeInterface may be called via the LookupFieldOrMethod,
// MissingMethod, Identical, or IdenticalIgnoreTags external API
// in which case check will be nil. In this case, type-checking
// must be finished and all interfaces should have been completed.
if check == nil {
panic("internal error: incomplete interface")
}
if trace {
// Types don't generally have position information.
// If we don't have a valid pos provided, try to use
// one close enough.
if !pos.IsValid() && len(ityp.methods) > 0 {
pos = ityp.methods[0].pos
}
check.trace(pos, "complete %s", ityp)
check.indent++
defer func() {
check.indent--
check.trace(pos, "=> %s (methods = %v, types = %v)", ityp, ityp.allMethods, ityp.allTypes)
}()
}
// An infinitely expanding interface (due to a cycle) is detected
// elsewhere (Checker.validType), so here we simply assume we only
// have valid interfaces. Mark the interface as complete to avoid
// infinite recursion if the validType check occurs later for some
// reason.
ityp.allMethods = markComplete
// Methods of embedded interfaces are collected unchanged; i.e., the identity
// of a method I.m's Func Object of an interface I is the same as that of
// the method m in an interface that embeds interface I. On the other hand,
// if a method is embedded via multiple overlapping embedded interfaces, we
// don't provide a guarantee which "original m" got chosen for the embedding
// interface. See also issue #34421.
//
// If we don't care to provide this identity guarantee anymore, instead of
// reusing the original method in embeddings, we can clone the method's Func
// Object and give it the position of a corresponding embedded interface. Then
// we can get rid of the mpos map below and simply use the cloned method's
// position.
var seen objset
var methods []*Func
mpos := make(map[*Func]token.Pos) // method specification or method embedding position, for good error messages
addMethod := func(pos token.Pos, m *Func, explicit bool) {
switch other := seen.insert(m); {
case other == nil:
methods = append(methods, m)
mpos[m] = pos
case explicit:
check.errorf(atPos(pos), _DuplicateDecl, "duplicate method %s", m.name)
check.errorf(atPos(mpos[other.(*Func)]), _DuplicateDecl, "\tother declaration of %s", m.name) // secondary error, \t indented
default:
// We have a duplicate method name in an embedded (not explicitly declared) method.
// Check method signatures after all types are computed (issue #33656).
// If we're pre-go1.14 (overlapping embeddings are not permitted), report that
// error here as well (even though we could do it eagerly) because it's the same
// error message.
check.later(func() {
if !check.allowVersion(m.pkg, 1, 14) || !check.identical(m.typ, other.Type()) {
check.errorf(atPos(pos), _DuplicateDecl, "duplicate method %s", m.name)
check.errorf(atPos(mpos[other.(*Func)]), _DuplicateDecl, "\tother declaration of %s", m.name) // secondary error, \t indented
}
})
}
}
for _, m := range ityp.methods {
addMethod(m.pos, m, true)
}
// collect types
allTypes := ityp.types
posList := check.posMap[ityp]
for i, typ := range ityp.embeddeds {
pos := posList[i] // embedding position
utyp := under(typ)
etyp := asInterface(utyp)
if etyp == nil {
if utyp != Typ[Invalid] {
var format string
if _, ok := utyp.(*_TypeParam); ok {
format = "%s is a type parameter, not an interface"
} else {
format = "%s is not an interface"
}
// TODO: correct error code.
check.errorf(atPos(pos), _InvalidIfaceEmbed, format, typ)
}
continue
}
check.completeInterface(pos, etyp)
for _, m := range etyp.allMethods {
addMethod(pos, m, false) // use embedding position pos rather than m.pos
}
allTypes = intersect(allTypes, etyp.allTypes)
}
if methods != nil {
sort.Sort(byUniqueMethodName(methods))
ityp.allMethods = methods
}
ityp.allTypes = allTypes
}
// intersect computes the intersection of the types x and y.
// Note: A incomming nil type stands for the top type. A top
// type result is returned as nil.
func intersect(x, y Type) (r Type) {
defer func() {
if r == theTop {
r = nil
}
}()
switch {
case x == theBottom || y == theBottom:
return theBottom
case x == nil || x == theTop:
return y
case y == nil || x == theTop:
return x
}
xtypes := unpackType(x)
ytypes := unpackType(y)
// Compute the list rtypes which includes only
// types that are in both xtypes and ytypes.
// Quadratic algorithm, but good enough for now.
// TODO(gri) fix this
var rtypes []Type
for _, x := range xtypes {
if includes(ytypes, x) {
rtypes = append(rtypes, x)
}
}
if rtypes == nil {
return theBottom
}
return _NewSum(rtypes)
}
func sortTypes(list []Type) {
sort.Stable(byUniqueTypeName(list))
}
// byUniqueTypeName named type lists can be sorted by their unique type names.
type byUniqueTypeName []Type
func (a byUniqueTypeName) Len() int { return len(a) }
func (a byUniqueTypeName) Less(i, j int) bool { return sortName(a[i]) < sortName(a[j]) }
func (a byUniqueTypeName) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
func sortName(t Type) string {
if named := asNamed(t); named != nil {
return named.obj.Id()
}
return ""
}
func sortMethods(list []*Func) {
sort.Sort(byUniqueMethodName(list))
}
func assertSortedMethods(list []*Func) {
if !debug {
panic("internal error: assertSortedMethods called outside debug mode")
}
if !sort.IsSorted(byUniqueMethodName(list)) {
panic("internal error: methods not sorted")
}
}
// byUniqueMethodName method lists can be sorted by their unique method names.
type byUniqueMethodName []*Func
func (a byUniqueMethodName) Len() int { return len(a) }
func (a byUniqueMethodName) Less(i, j int) bool { return a[i].Id() < a[j].Id() }
func (a byUniqueMethodName) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
func (check *Checker) tag(t *ast.BasicLit) string { func (check *Checker) tag(t *ast.BasicLit) string {
if t != nil { if t != nil {
if t.Kind == token.STRING { if t.Kind == token.STRING {
@ -1162,41 +890,3 @@ func embeddedFieldIdent(e ast.Expr) *ast.Ident {
} }
return nil // invalid embedded field return nil // invalid embedded field
} }
func (check *Checker) collectTypeConstraints(pos token.Pos, types []ast.Expr) []Type {
list := make([]Type, 0, len(types)) // assume all types are correct
for _, texpr := range types {
if texpr == nil {
check.invalidAST(atPos(pos), "missing type constraint")
continue
}
list = append(list, check.varType(texpr))
}
// Ensure that each type is only present once in the type list. Types may be
// interfaces, which may not be complete yet. It's ok to do this check at the
// end because it's not a requirement for correctness of the code.
// Note: This is a quadratic algorithm, but type lists tend to be short.
check.later(func() {
for i, t := range list {
if t := asInterface(t); t != nil {
check.completeInterface(types[i].Pos(), t)
}
if includes(list[:i], t) {
check.softErrorf(types[i], _Todo, "duplicate type %s in type list", t)
}
}
})
return list
}
// includes reports whether typ is in list.
func includes(list []Type, typ Type) bool {
for _, e := range list {
if Identical(typ, e) {
return true
}
}
return false
}