// Code generated by "go test -run=Generate -write=all"; DO NOT EDIT. // Source: ../../cmd/compile/internal/types2/named.go // Copyright 2011 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/token" "strings" "sync" "sync/atomic" ) // Type-checking Named types is subtle, because they may be recursively // defined, and because their full details may be spread across multiple // declarations (via methods). For this reason they are type-checked lazily, // to avoid information being accessed before it is complete. // // Conceptually, it is helpful to think of named types as having two distinct // sets of information: // - "LHS" information, defining their identity: Obj() and TypeArgs() // - "RHS" information, defining their details: TypeParams(), Underlying(), // and methods. // // In this taxonomy, LHS information is available immediately, but RHS // information is lazy. Specifically, a named type N may be constructed in any // of the following ways: // 1. type-checked from the source // 2. loaded eagerly from export data // 3. loaded lazily from export data (when using unified IR) // 4. instantiated from a generic type // // In cases 1, 3, and 4, it is possible that the underlying type or methods of // N may not be immediately available. // - During type-checking, we allocate N before type-checking its underlying // type or methods, so that we may resolve recursive references. // - When loading from export data, we may load its methods and underlying // type lazily using a provided load function. // - After instantiating, we lazily expand the underlying type and methods // (note that instances may be created while still in the process of // type-checking the original type declaration). // // In cases 3 and 4 this lazy construction may also occur concurrently, due to // concurrent use of the type checker API (after type checking or importing has // finished). It is critical that we keep track of state, so that Named types // are constructed exactly once and so that we do not access their details too // soon. // // We achieve this by tracking state with an atomic state variable, and // guarding potentially concurrent calculations with a mutex. At any point in // time this state variable determines which data on N may be accessed. As // state monotonically progresses, any data available at state M may be // accessed without acquiring the mutex at state N, provided N >= M. // // GLOSSARY: Here are a few terms used in this file to describe Named types: // - We say that a Named type is "instantiated" if it has been constructed by // instantiating a generic named type with type arguments. // - We say that a Named type is "declared" if it corresponds to a type // declaration in the source. Instantiated named types correspond to a type // instantiation in the source, not a declaration. But their Origin type is // a declared type. // - We say that a Named type is "resolved" if its RHS information has been // loaded or fully type-checked. For Named types constructed from export // data, this may involve invoking a loader function to extract information // from export data. For instantiated named types this involves reading // information from their origin. // - We say that a Named type is "expanded" if it is an instantiated type and // type parameters in its underlying type and methods have been substituted // with the type arguments from the instantiation. A type may be partially // expanded if some but not all of these details have been substituted. // Similarly, we refer to these individual details (underlying type or // method) as being "expanded". // - When all information is known for a named type, we say it is "complete". // // Some invariants to keep in mind: each declared Named type has a single // corresponding object, and that object's type is the (possibly generic) Named // type. Declared Named types are identical if and only if their pointers are // identical. On the other hand, multiple instantiated Named types may be // identical even though their pointers are not identical. One has to use // 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. // // A declaration such as: // // type S struct { ... } // // creates a defined type whose underlying type is a struct, // and binds this type to the object S, a [TypeName]. // Use [Named.Underlying] to access the underlying type. // Use [Named.Obj] to obtain the object S. // // Before type aliases (Go 1.9), the spec called defined types "named types". type Named struct { check *Checker // non-nil during type-checking; nil otherwise obj *TypeName // corresponding declared object for declared types; see above for instantiated types // fromRHS holds the type (on RHS of declaration) this *Named type is derived // from (for cycle reporting). Only used by validType, and therefore does not // require synchronization. fromRHS Type // information for instantiated types; nil otherwise inst *instance mu sync.Mutex // guards all fields below state_ uint32 // the current state of this type; must only be accessed atomically underlying Type // possibly a *Named during setup; never a *Named once set up completely tparams *TypeParamList // type parameters, or nil // methods declared for this type (not the method set of this type) // Signatures are type-checked lazily. // For non-instantiated types, this is a fully populated list of methods. For // instantiated types, methods are individually expanded when they are first // accessed. methods []*Func // loader may be provided to lazily load type parameters, underlying type, and methods. loader func(*Named) (tparams []*TypeParam, underlying Type, methods []*Func) } // instance holds information that is only necessary for instantiated named // types. 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. type namedState uint32 const ( unresolved namedState = iota // tparams, underlying type and methods might be unavailable resolved // resolve has run; methods might be incomplete (for instances) complete // all data is known ) // NewNamed returns a new named type for the given type name, underlying type, and associated methods. // If the given type name obj doesn't have a type yet, its type is set to the returned named type. // The underlying type must not be a *Named. func NewNamed(obj *TypeName, underlying Type, methods []*Func) *Named { if asNamed(underlying) != nil { panic("underlying type must not be *Named") } return (*Checker)(nil).newNamed(obj, underlying, methods) } // resolve resolves the type parameters, methods, and underlying type of n. // This information may be loaded from a provided loader function, or computed // from an origin type (in the case of instances). // // 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() *Named { if n.state() >= resolved { // avoid locking below return n } // TODO(rfindley): if n.check is non-nil we can avoid locking here, since // type-checking is not concurrent. Evaluate if this is worth doing. n.mu.Lock() defer n.mu.Unlock() if n.state() >= resolved { return n } if n.inst != nil { assert(n.underlying == nil) // n is an unresolved instance assert(n.loader == nil) // instances are created by instantiation, in which case n.loader is nil orig := n.inst.orig orig.resolve() underlying := n.expandUnderlying() n.tparams = orig.tparams n.underlying = underlying n.fromRHS = orig.fromRHS // for cycle detection if len(orig.methods) == 0 { n.setState(complete) // nothing further to do n.inst.ctxt = nil } else { n.setState(resolved) } return n } // TODO(mdempsky): Since we're passing n to the loader anyway // (necessary because types2 expects the receiver type for methods // on defined interface types to be the Named rather than the // underlying Interface), maybe it should just handle calling // SetTypeParams, SetUnderlying, and AddMethod instead? Those // methods would need to support reentrant calls though. It would // also make the API more future-proof towards further extensions. if n.loader != nil { assert(n.underlying == nil) assert(n.TypeArgs().Len() == 0) // instances are created by instantiation, in which case n.loader is nil tparams, underlying, methods := n.loader(n) n.tparams = bindTParams(tparams) n.underlying = underlying n.fromRHS = underlying // for cycle detection n.methods = methods n.loader = nil } n.setState(complete) return n } // state atomically accesses the current state of the receiver. func (n *Named) state() namedState { return namedState(atomic.LoadUint32(&n.state_)) } // setState atomically stores the given state for n. // Must only be called while holding n.mu. func (n *Named) setState(state namedState) { atomic.StoreUint32(&n.state_, uint32(state)) } // newNamed is like NewNamed but with a *Checker receiver. func (check *Checker) newNamed(obj *TypeName, underlying Type, methods []*Func) *Named { typ := &Named{check: check, obj: obj, fromRHS: underlying, underlying: underlying, methods: methods} if obj.typ == nil { obj.typ = typ } // Ensure that typ is always sanity-checked. if check != nil { check.needsCleanup(typ) } return typ } // newNamedInstance creates a new named instance for the given origin and type // arguments, recording pos as the position of its synthetic object (for error // reporting). // // If set, expanding is the named type instance currently being expanded, that // led to the creation of this instance. func (check *Checker) newNamedInstance(pos token.Pos, orig *Named, targs []Type, expanding *Named) *Named { assert(len(targs) > 0) obj := NewTypeName(pos, orig.obj.pkg, orig.obj.name, nil) inst := &instance{orig: orig, targs: newTypeList(targs)} // Only pass the expanding context to the new instance if their packages // match. Since type reference cycles are only possible within a single // package, this is sufficient for the purposes of short-circuiting cycles. // Avoiding passing the context in other cases prevents unnecessary coupling // of types across packages. if expanding != nil && expanding.Obj().pkg == obj.pkg { inst.ctxt = expanding.inst.ctxt } typ := &Named{check: check, obj: obj, inst: inst} obj.typ = typ // Ensure that typ is always sanity-checked. if check != nil { check.needsCleanup(typ) } return typ } func (t *Named) cleanup() { assert(t.inst == nil || t.inst.orig.inst == nil) // Ensure that every defined type created in the course of type-checking has // either non-*Named underlying type, or is unexpanded. // // This guarantees that we don't leak any types whose underlying type is // *Named, because any unexpanded instances will lazily compute their // underlying type by substituting in the underlying type of their origin. // The origin must have either been imported or type-checked and expanded // here, and in either case its underlying type will be fully expanded. switch t.underlying.(type) { case nil: if t.TypeArgs().Len() == 0 { panic("nil underlying") } case *Named, *Alias: t.under() // t.under may add entries to check.cleaners } t.check = nil } // Obj returns the type name for the declaration defining the named type t. For // instantiated types, this is same as the type name of the origin type. func (t *Named) Obj() *TypeName { if t.inst == nil { return t.obj } return t.inst.orig.obj } // Origin returns the generic type from which the named type t is // instantiated. If t is not an instantiated type, the result is t. func (t *Named) Origin() *Named { if t.inst == nil { return t } return t.inst.orig } // 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().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().tparams = bindTParams(tparams) } // TypeArgs returns the type arguments used to instantiate the named type t. func (t *Named) TypeArgs() *TypeList { if t.inst == nil { return nil } return t.inst.targs } // NumMethods returns the number of explicit methods defined for t. func (t *Named) NumMethods() int { 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. // // Methods are numbered deterministically: given the same list of source files // presented to the type checker, or the same sequence of NewMethod and AddMethod // calls, the mapping from method index to corresponding method remains the same. // But the specific ordering is not specified and must not be relied on as it may // change in the future. func (t *Named) Method(i int) *Func { t.resolve() if t.state() >= complete { return t.methods[i] } assert(t.inst != nil) // only instances should have incomplete methods orig := t.inst.orig t.mu.Lock() defer t.mu.Unlock() if len(t.methods) != len(orig.methods) { assert(len(t.methods) == 0) t.methods = make([]*Func, len(orig.methods)) } 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++ // Check if we've created all methods at this point. If we have, mark the // type as fully expanded. if t.inst.expandedMethods == len(orig.methods) { t.setState(complete) t.inst.ctxt = nil // no need for a context anymore } } return t.methods[i] } // expandMethod substitutes type arguments in the i'th method for an // instantiated receiver. func (t *Named) expandMethod(i int) *Func { // t.orig.methods is not lazy. origm is the method instantiated with its // receiver type parameters (the "origin" method). origm := t.inst.orig.Method(i) assert(origm != nil) check := t.check // Ensure that the original method is type-checked. if check != nil { check.objDecl(origm, nil) } origSig := origm.typ.(*Signature) rbase, _ := deref(origSig.Recv().Type()) // If rbase is t, then origm is already the instantiated method we're looking // for. In this case, we return origm to preserve the invariant that // traversing Method->Receiver Type->Method should get back to the same // method. // // This occurs if t is instantiated with the receiver type parameters, as in // the use of m in func (r T[_]) m() { r.m() }. if rbase == t { return origm } sig := origSig // We can only substitute if we have a correspondence between type arguments // and type parameters. This check is necessary in the presence of invalid // code. if origSig.RecvTypeParams().Len() == t.inst.targs.Len() { smap := makeSubstMap(origSig.RecvTypeParams().list(), t.inst.targs.list()) var ctxt *Context if check != nil { ctxt = check.context() } sig = check.subst(origm.pos, origSig, smap, t, ctxt).(*Signature) } if sig == origSig { // No substitution occurred, but we still need to create a new signature to // hold the instantiated receiver. copy := *origSig sig = © } var rtyp Type if origm.hasPtrRecv() { rtyp = NewPointer(t) } else { rtyp = t } sig.recv = cloneVar(origSig.recv, rtyp) return cloneFunc(origm, sig) } // SetUnderlying sets the underlying type and marks t as complete. // t must not have type arguments. func (t *Named) SetUnderlying(underlying Type) { assert(t.inst == nil) if underlying == nil { panic("underlying type must not be nil") } if asNamed(underlying) != nil { panic("underlying type must not be *Named") } t.resolve().underlying = underlying if t.fromRHS == nil { t.fromRHS = underlying // for cycle detection } } // AddMethod adds method m unless it is already in the method list. // The method must be in the same package as t, and t must not have // type arguments. func (t *Named) AddMethod(m *Func) { assert(samePkg(t.obj.pkg, m.pkg)) assert(t.inst == nil) t.resolve() if t.methodIndex(m.name, false) < 0 { t.methods = append(t.methods, m) } } // methodIndex returns the index of the method with the given name. // If foldCase is set, capitalization in the name is ignored. // The result is negative if no such method exists. func (t *Named) methodIndex(name string, foldCase bool) int { if name == "_" { return -1 } if foldCase { for i, m := range t.methods { if strings.EqualFold(m.name, name) { return i } } } else { for i, m := range t.methods { if m.name == name { return i } } } return -1 } // Underlying returns the [underlying type] of the named type t, resolving all // forwarding declarations. Underlying types are never Named, TypeParam, or // Alias types. // // [underlying type]: https://go.dev/ref/spec#Underlying_types. func (t *Named) Underlying() Type { // TODO(gri) Investigate if Unalias can be moved to where underlying is set. return Unalias(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 // the chain by setting the underlying type for each defined type in the // chain before returning it. If no underlying type is found or a cycle // is detected, the result is Typ[Invalid]. If a cycle is detected and // n0.check != nil, the cycle is reported. // // This is necessary because the underlying type of named may be itself a // named type that is incomplete: // // type ( // A B // B *C // C A // ) // // The type of C is the (named) type of A which is incomplete, // and which has as its underlying type the named type B. func (n0 *Named) under() Type { u := n0.Underlying() // If the underlying type of a defined type is not a defined // (incl. instance) type, then that is the desired underlying // type. var n1 *Named switch u1 := u.(type) { case nil: // After expansion via Underlying(), we should never encounter a nil // underlying. panic("nil underlying") default: // common case return u case *Named: // handled below n1 = u1 } if n0.check == nil { panic("Named.check == nil but type is incomplete") } // Invariant: after this point n0 as well as any named types in its // underlying chain should be set up when this function exits. check := n0.check n := n0 seen := make(map[*Named]int) // types that need their underlying type resolved var path []Object // objects encountered, for cycle reporting loop: for { seen[n] = len(seen) path = append(path, n.obj) n = n1 if i, ok := seen[n]; ok { // cycle check.cycleError(path[i:], firstInSrc(path[i:])) u = Typ[Invalid] break } u = n.Underlying() switch u1 := u.(type) { case nil: u = Typ[Invalid] break loop default: break loop case *Named: // Continue collecting *Named types in the chain. n1 = u1 } } for n := range seen { // We should never have to update the underlying type of an imported type; // those underlying types should have been resolved during the import. // Also, doing so would lead to a race condition (was go.dev/issue/31749). // Do this check always, not just in debug mode (it's cheap). if n.obj.pkg != check.pkg { panic("imported type with unresolved underlying type") } n.underlying = u } return u } func (n *Named) lookupMethod(pkg *Package, name string, foldCase bool) (int, *Func) { n.resolve() if samePkg(n.obj.pkg, pkg) || isExported(name) || foldCase { // 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). if i := n.Origin().methodIndex(name, foldCase); i >= 0 { // For instances, m.Method(i) will be different from the orig method. return i, n.Method(i) } } return -1, nil } // context returns the type-checker context. func (check *Checker) context() *Context { if check.ctxt == nil { check.ctxt = 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() Type { check := n.check if check != nil && check.conf._Trace { check.trace(n.obj.pos, "-- Named.expandUnderlying %s", n) check.indent++ defer func() { check.indent-- check.trace(n.obj.pos, "=> %s (tparams = %s, under = %s)", n, n.tparams.list(), n.underlying) }() } assert(n.inst.orig.underlying != nil) if n.inst.ctxt == nil { n.inst.ctxt = NewContext() } orig := n.inst.orig targs := n.inst.targs if asNamed(orig.underlying) != nil { // We should only get a Named underlying type here during type checking // (for example, in recursive type declarations). assert(check != nil) } if orig.tparams.Len() != targs.Len() { // Mismatching arg and tparam length may be checked elsewhere. return Typ[Invalid] } // 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()) var ctxt *Context if check != nil { ctxt = check.context() } underlying := n.check.subst(n.obj.pos, orig.underlying, smap, n, 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 // 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 { // If the underlying type doesn't actually use type parameters, it's // possible that it wasn't substituted. In this case we need to create // a new *Interface before modifying receivers. if iface == orig.underlying { old := iface iface = check.newInterface() iface.embeddeds = old.embeddeds assert(old.complete) // otherwise we are copying incomplete data iface.complete = old.complete iface.implicit = old.implicit // should be false but be conservative underlying = iface } iface.methods = methods iface.tset = nil // recompute type set with new methods // If check != nil, check.newInterface will have saved the interface for later completion. if check == nil { // golang/go#61561: all newly created interfaces must be fully evaluated iface.typeSet() } } } return underlying } // safeUnderlying returns the underlying type of typ without expanding // instances, to avoid infinite recursion. // // TODO(rfindley): eliminate this function or give it a better name. func safeUnderlying(typ Type) Type { if t := asNamed(typ); t != nil { return t.underlying } return typ.Underlying() }