// Code generated by "go test -run=Generate -write=all"; DO NOT EDIT. // Source: ../../cmd/compile/internal/types2/object.go // Copyright 2013 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 ( "bytes" "fmt" "go/constant" "go/token" "strings" "unicode" "unicode/utf8" ) // An Object is a named language entity. // An Object may be a constant ([Const]), type name ([TypeName]), // variable or struct field ([Var]), function or method ([Func]), // imported package ([PkgName]), label ([Label]), // built-in function ([Builtin]), // or the predeclared identifier 'nil' ([Nil]). // // The environment, which is structured as a tree of Scopes, // maps each name to the unique Object that it denotes. type Object interface { Parent() *Scope // scope in which this object is declared; nil for methods and struct fields Pos() token.Pos // position of object identifier in declaration Pkg() *Package // package to which this object belongs; nil for labels and objects in the Universe scope Name() string // package local object name Type() Type // object type Exported() bool // reports whether the name starts with a capital letter Id() string // object name if exported, qualified name if not exported (see func Id) // String returns a human-readable string of the object. // Use [ObjectString] to control how package names are formatted in the string. String() string // order reflects a package-level object's source order: if object // a is before object b in the source, then a.order() < b.order(). // order returns a value > 0 for package-level objects; it returns // 0 for all other objects (including objects in file scopes). order() uint32 // color returns the object's color. color() color // setType sets the type of the object. setType(Type) // setOrder sets the order number of the object. It must be > 0. setOrder(uint32) // setColor sets the object's color. It must not be white. setColor(color color) // setParent sets the parent scope of the object. setParent(*Scope) // sameId reports whether obj.Id() and Id(pkg, name) are the same. // If foldCase is true, names are considered equal if they are equal with case folding // and their packages are ignored (e.g., pkg1.m, pkg1.M, pkg2.m, and pkg2.M are all equal). sameId(pkg *Package, name string, foldCase bool) bool // scopePos returns the start position of the scope of this Object scopePos() token.Pos // setScopePos sets the start position of the scope for this Object. setScopePos(pos token.Pos) } func isExported(name string) bool { ch, _ := utf8.DecodeRuneInString(name) return unicode.IsUpper(ch) } // Id returns name if it is exported, otherwise it // returns the name qualified with the package path. func Id(pkg *Package, name string) string { if isExported(name) { return name } // unexported names need the package path for differentiation // (if there's no package, make sure we don't start with '.' // as that may change the order of methods between a setup // inside a package and outside a package - which breaks some // tests) path := "_" // pkg is nil for objects in Universe scope and possibly types // introduced via Eval (see also comment in object.sameId) if pkg != nil && pkg.path != "" { path = pkg.path } return path + "." + name } // An object implements the common parts of an Object. type object struct { parent *Scope pos token.Pos pkg *Package name string typ Type order_ uint32 color_ color scopePos_ token.Pos } // color encodes the color of an object (see Checker.objDecl for details). type color uint32 // An object may be painted in one of three colors. // Color values other than white or black are considered grey. const ( white color = iota black grey // must be > white and black ) func (c color) String() string { switch c { case white: return "white" case black: return "black" default: return "grey" } } // colorFor returns the (initial) color for an object depending on // whether its type t is known or not. func colorFor(t Type) color { if t != nil { return black } return white } // Parent returns the scope in which the object is declared. // The result is nil for methods and struct fields. func (obj *object) Parent() *Scope { return obj.parent } // Pos returns the declaration position of the object's identifier. func (obj *object) Pos() token.Pos { return obj.pos } // Pkg returns the package to which the object belongs. // The result is nil for labels and objects in the Universe scope. func (obj *object) Pkg() *Package { return obj.pkg } // Name returns the object's (package-local, unqualified) name. func (obj *object) Name() string { return obj.name } // Type returns the object's type. func (obj *object) Type() Type { return obj.typ } // Exported reports whether the object is exported (starts with a capital letter). // It doesn't take into account whether the object is in a local (function) scope // or not. func (obj *object) Exported() bool { return isExported(obj.name) } // Id is a wrapper for Id(obj.Pkg(), obj.Name()). func (obj *object) Id() string { return Id(obj.pkg, obj.name) } func (obj *object) String() string { panic("abstract") } func (obj *object) order() uint32 { return obj.order_ } func (obj *object) color() color { return obj.color_ } func (obj *object) scopePos() token.Pos { return obj.scopePos_ } func (obj *object) setParent(parent *Scope) { obj.parent = parent } func (obj *object) setType(typ Type) { obj.typ = typ } func (obj *object) setOrder(order uint32) { assert(order > 0); obj.order_ = order } func (obj *object) setColor(color color) { assert(color != white); obj.color_ = color } func (obj *object) setScopePos(pos token.Pos) { obj.scopePos_ = pos } func (obj *object) sameId(pkg *Package, name string, foldCase bool) bool { // If we don't care about capitalization, we also ignore packages. if foldCase && strings.EqualFold(obj.name, name) { return true } // spec: // "Two identifiers are different if they are spelled differently, // or if they appear in different packages and are not exported. // Otherwise, they are the same." if obj.name != name { return false } // obj.Name == name if obj.Exported() { return true } // not exported, so packages must be the same return samePkg(obj.pkg, pkg) } // cmp reports whether object a is ordered before object b. // cmp returns: // // -1 if a is before b // 0 if a is equivalent to b // +1 if a is behind b // // Objects are ordered nil before non-nil, exported before // non-exported, then by name, and finally (for non-exported // functions) by package path. func (a *object) cmp(b *object) int { if a == b { return 0 } // Nil before non-nil. if a == nil { return -1 } if b == nil { return +1 } // Exported functions before non-exported. ea := isExported(a.name) eb := isExported(b.name) if ea != eb { if ea { return -1 } return +1 } // Order by name and then (for non-exported names) by package. if a.name != b.name { return strings.Compare(a.name, b.name) } if !ea { return strings.Compare(a.pkg.path, b.pkg.path) } return 0 } // A PkgName represents an imported Go package. // PkgNames don't have a type. type PkgName struct { object imported *Package used bool // set if the package was used } // NewPkgName returns a new PkgName object representing an imported package. // The remaining arguments set the attributes found with all Objects. func NewPkgName(pos token.Pos, pkg *Package, name string, imported *Package) *PkgName { return &PkgName{object{nil, pos, pkg, name, Typ[Invalid], 0, black, nopos}, imported, false} } // Imported returns the package that was imported. // It is distinct from Pkg(), which is the package containing the import statement. func (obj *PkgName) Imported() *Package { return obj.imported } // A Const represents a declared constant. type Const struct { object val constant.Value } // NewConst returns a new constant with value val. // The remaining arguments set the attributes found with all Objects. func NewConst(pos token.Pos, pkg *Package, name string, typ Type, val constant.Value) *Const { return &Const{object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}, val} } // Val returns the constant's value. func (obj *Const) Val() constant.Value { return obj.val } func (*Const) isDependency() {} // a constant may be a dependency of an initialization expression // A TypeName is an [Object] that represents a type with a name: // a defined type ([Named]), // an alias type ([Alias]), // a type parameter ([TypeParam]), // or a predeclared type such as int or error. type TypeName struct { object } // NewTypeName returns a new type name denoting the given typ. // The remaining arguments set the attributes found with all Objects. // // The typ argument may be a defined (Named) type or an alias type. // It may also be nil such that the returned TypeName can be used as // argument for NewNamed, which will set the TypeName's type as a side- // effect. func NewTypeName(pos token.Pos, pkg *Package, name string, typ Type) *TypeName { return &TypeName{object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}} } // NewTypeNameLazy returns a new defined type like NewTypeName, but it // lazily calls resolve to finish constructing the Named object. func _NewTypeNameLazy(pos token.Pos, pkg *Package, name string, load func(named *Named) (tparams []*TypeParam, underlying Type, methods []*Func)) *TypeName { obj := NewTypeName(pos, pkg, name, nil) NewNamed(obj, nil, nil).loader = load return obj } // IsAlias reports whether obj is an alias name for a type. func (obj *TypeName) IsAlias() bool { switch t := obj.typ.(type) { case nil: return false // case *Alias: // handled by default case case *Basic: // unsafe.Pointer is not an alias. if obj.pkg == Unsafe { return false } // Any user-defined type name for a basic type is an alias for a // basic type (because basic types are pre-declared in the Universe // scope, outside any package scope), and so is any type name with // a different name than the name of the basic type it refers to. // Additionally, we need to look for "byte" and "rune" because they // are aliases but have the same names (for better error messages). return obj.pkg != nil || t.name != obj.name || t == universeByte || t == universeRune case *Named: return obj != t.obj case *TypeParam: return obj != t.obj default: return true } } // A Variable represents a declared variable (including function parameters and results, and struct fields). type Var struct { object embedded bool // if set, the variable is an embedded struct field, and name is the type name isField bool // var is struct field used bool // set if the variable was used origin *Var // if non-nil, the Var from which this one was instantiated } // NewVar returns a new variable. // The arguments set the attributes found with all Objects. func NewVar(pos token.Pos, pkg *Package, name string, typ Type) *Var { return &Var{object: object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}} } // NewParam returns a new variable representing a function parameter. func NewParam(pos token.Pos, pkg *Package, name string, typ Type) *Var { return &Var{object: object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}, used: true} // parameters are always 'used' } // NewField returns a new variable representing a struct field. // For embedded fields, the name is the unqualified type name // under which the field is accessible. func NewField(pos token.Pos, pkg *Package, name string, typ Type, embedded bool) *Var { return &Var{object: object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}, embedded: embedded, isField: true} } // Anonymous reports whether the variable is an embedded field. // Same as Embedded; only present for backward-compatibility. func (obj *Var) Anonymous() bool { return obj.embedded } // Embedded reports whether the variable is an embedded field. func (obj *Var) Embedded() bool { return obj.embedded } // IsField reports whether the variable is a struct field. func (obj *Var) IsField() bool { return obj.isField } // Origin returns the canonical Var for its receiver, i.e. the Var object // recorded in Info.Defs. // // For synthetic Vars created during instantiation (such as struct fields or // function parameters that depend on type arguments), this will be the // corresponding Var on the generic (uninstantiated) type. For all other Vars // Origin returns the receiver. func (obj *Var) Origin() *Var { if obj.origin != nil { return obj.origin } return obj } func (*Var) isDependency() {} // a variable may be a dependency of an initialization expression // A Func represents a declared function, concrete method, or abstract // (interface) method. Its Type() is always a *Signature. // An abstract method may belong to many interfaces due to embedding. type Func struct { object hasPtrRecv_ bool // only valid for methods that don't have a type yet; use hasPtrRecv() to read origin *Func // if non-nil, the Func from which this one was instantiated } // NewFunc returns a new function with the given signature, representing // the function's type. func NewFunc(pos token.Pos, pkg *Package, name string, sig *Signature) *Func { var typ Type if sig != nil { typ = sig } else { // Don't store a (typed) nil *Signature. // We can't simply replace it with new(Signature) either, // as this would violate object.{Type,color} invariants. // TODO(adonovan): propose to disallow NewFunc with nil *Signature. } return &Func{object{nil, pos, pkg, name, typ, 0, colorFor(typ), nopos}, false, nil} } // Signature returns the signature (type) of the function or method. func (obj *Func) Signature() *Signature { if obj.typ != nil { return obj.typ.(*Signature) // normal case } // No signature: Signature was called either: // - within go/types, before a FuncDecl's initially // nil Func.Type was lazily populated, indicating // a types bug; or // - by a client after NewFunc(..., nil), // which is arguably a client bug, but we need a // proposal to tighten NewFunc's precondition. // For now, return a trivial signature. return new(Signature) } // FullName returns the package- or receiver-type-qualified name of // function or method obj. func (obj *Func) FullName() string { var buf bytes.Buffer writeFuncName(&buf, obj, nil) return buf.String() } // Scope returns the scope of the function's body block. // The result is nil for imported or instantiated functions and methods // (but there is also no mechanism to get to an instantiated function). func (obj *Func) Scope() *Scope { return obj.typ.(*Signature).scope } // Origin returns the canonical Func for its receiver, i.e. the Func object // recorded in Info.Defs. // // For synthetic functions created during instantiation (such as methods on an // instantiated Named type or interface methods that depend on type arguments), // this will be the corresponding Func on the generic (uninstantiated) type. // For all other Funcs Origin returns the receiver. func (obj *Func) Origin() *Func { if obj.origin != nil { return obj.origin } return obj } // Pkg returns the package to which the function belongs. // // The result is nil for methods of types in the Universe scope, // like method Error of the error built-in interface type. func (obj *Func) Pkg() *Package { return obj.object.Pkg() } // hasPtrRecv reports whether the receiver is of the form *T for the given method obj. func (obj *Func) hasPtrRecv() bool { // If a method's receiver type is set, use that as the source of truth for the receiver. // Caution: Checker.funcDecl (decl.go) marks a function by setting its type to an empty // signature. We may reach here before the signature is fully set up: we must explicitly // check if the receiver is set (we cannot just look for non-nil obj.typ). if sig, _ := obj.typ.(*Signature); sig != nil && sig.recv != nil { _, isPtr := deref(sig.recv.typ) return isPtr } // If a method's type is not set it may be a method/function that is: // 1) client-supplied (via NewFunc with no signature), or // 2) internally created but not yet type-checked. // For case 1) we can't do anything; the client must know what they are doing. // For case 2) we can use the information gathered by the resolver. return obj.hasPtrRecv_ } func (*Func) isDependency() {} // a function may be a dependency of an initialization expression // A Label represents a declared label. // Labels don't have a type. type Label struct { object used bool // set if the label was used } // NewLabel returns a new label. func NewLabel(pos token.Pos, pkg *Package, name string) *Label { return &Label{object{pos: pos, pkg: pkg, name: name, typ: Typ[Invalid], color_: black}, false} } // A Builtin represents a built-in function. // Builtins don't have a valid type. type Builtin struct { object id builtinId } func newBuiltin(id builtinId) *Builtin { return &Builtin{object{name: predeclaredFuncs[id].name, typ: Typ[Invalid], color_: black}, id} } // Nil represents the predeclared value nil. type Nil struct { object } func writeObject(buf *bytes.Buffer, obj Object, qf Qualifier) { var tname *TypeName typ := obj.Type() switch obj := obj.(type) { case *PkgName: fmt.Fprintf(buf, "package %s", obj.Name()) if path := obj.imported.path; path != "" && path != obj.name { fmt.Fprintf(buf, " (%q)", path) } return case *Const: buf.WriteString("const") case *TypeName: tname = obj buf.WriteString("type") if isTypeParam(typ) { buf.WriteString(" parameter") } case *Var: if obj.isField { buf.WriteString("field") } else { buf.WriteString("var") } case *Func: buf.WriteString("func ") writeFuncName(buf, obj, qf) if typ != nil { WriteSignature(buf, typ.(*Signature), qf) } return case *Label: buf.WriteString("label") typ = nil case *Builtin: buf.WriteString("builtin") typ = nil case *Nil: buf.WriteString("nil") return default: panic(fmt.Sprintf("writeObject(%T)", obj)) } buf.WriteByte(' ') // For package-level objects, qualify the name. if obj.Pkg() != nil && obj.Pkg().scope.Lookup(obj.Name()) == obj { buf.WriteString(packagePrefix(obj.Pkg(), qf)) } buf.WriteString(obj.Name()) if typ == nil { return } if tname != nil { switch t := typ.(type) { case *Basic: // Don't print anything more for basic types since there's // no more information. return case genericType: if t.TypeParams().Len() > 0 { newTypeWriter(buf, qf).tParamList(t.TypeParams().list()) } } if tname.IsAlias() { buf.WriteString(" =") if alias, ok := typ.(*Alias); ok { // materialized? (gotypesalias=1) typ = alias.fromRHS } } else if t, _ := typ.(*TypeParam); t != nil { typ = t.bound } else { // TODO(gri) should this be fromRHS for *Named? // (See discussion in #66559.) typ = under(typ) } } // Special handling for any: because WriteType will format 'any' as 'any', // resulting in the object string `type any = any` rather than `type any = // interface{}`. To avoid this, swap in a different empty interface. if obj.Name() == "any" && obj.Parent() == Universe { assert(Identical(typ, &emptyInterface)) typ = &emptyInterface } buf.WriteByte(' ') WriteType(buf, typ, qf) } func packagePrefix(pkg *Package, qf Qualifier) string { if pkg == nil { return "" } var s string if qf != nil { s = qf(pkg) } else { s = pkg.Path() } if s != "" { s += "." } return s } // ObjectString returns the string form of obj. // The Qualifier controls the printing of // package-level objects, and may be nil. func ObjectString(obj Object, qf Qualifier) string { var buf bytes.Buffer writeObject(&buf, obj, qf) return buf.String() } func (obj *PkgName) String() string { return ObjectString(obj, nil) } func (obj *Const) String() string { return ObjectString(obj, nil) } func (obj *TypeName) String() string { return ObjectString(obj, nil) } func (obj *Var) String() string { return ObjectString(obj, nil) } func (obj *Func) String() string { return ObjectString(obj, nil) } func (obj *Label) String() string { return ObjectString(obj, nil) } func (obj *Builtin) String() string { return ObjectString(obj, nil) } func (obj *Nil) String() string { return ObjectString(obj, nil) } func writeFuncName(buf *bytes.Buffer, f *Func, qf Qualifier) { if f.typ != nil { sig := f.typ.(*Signature) if recv := sig.Recv(); recv != nil { buf.WriteByte('(') if _, ok := recv.Type().(*Interface); ok { // gcimporter creates abstract methods of // named interfaces using the interface type // (not the named type) as the receiver. // Don't print it in full. buf.WriteString("interface") } else { WriteType(buf, recv.Type(), qf) } buf.WriteByte(')') buf.WriteByte('.') } else if f.pkg != nil { buf.WriteString(packagePrefix(f.pkg, qf)) } } buf.WriteString(f.name) }