/** * Defines a `class` declaration. * * Specification: $(LINK2 https://dlang.org/spec/class.html, Classes) * * Copyright: Copyright (C) 1999-2022 by The D Language Foundation, All Rights Reserved * Authors: $(LINK2 https://www.digitalmars.com, Walter Bright) * License: $(LINK2 https://www.boost.org/LICENSE_1_0.txt, Boost License 1.0) * Source: $(LINK2 https://github.com/dlang/dmd/blob/master/src/dmd/dclass.d, _dclass.d) * Documentation: https://dlang.org/phobos/dmd_dclass.html * Coverage: https://codecov.io/gh/dlang/dmd/src/master/src/dmd/dclass.d */ module dmd.dclass; import core.stdc.stdio; import core.stdc.string; import dmd.aggregate; import dmd.apply; import dmd.arraytypes; import dmd.astenums; import dmd.attrib; import dmd.gluelayer; import dmd.declaration; import dmd.dscope; import dmd.dsymbol; import dmd.dsymbolsem; import dmd.func; import dmd.globals; import dmd.id; import dmd.identifier; import dmd.mtype; import dmd.objc; import dmd.root.rmem; import dmd.target; import dmd.visitor; /*********************************************************** */ extern (C++) struct BaseClass { Type type; // (before semantic processing) ClassDeclaration sym; uint offset; // 'this' pointer offset // for interfaces: Array of FuncDeclaration's making up the vtbl[] FuncDeclarations vtbl; // if BaseClass is an interface, these // are a copy of the InterfaceDeclaration.interfaces BaseClass[] baseInterfaces; extern (D) this(Type type) { //printf("BaseClass(this = %p, '%s')\n", this, type.toChars()); this.type = type; } /**************************************** * Fill in vtbl[] for base class based on member functions of class cd. * Input: * vtbl if !=NULL, fill it in * newinstance !=0 means all entries must be filled in by members * of cd, not members of any base classes of cd. * Returns: * true if any entries were filled in by members of cd (not exclusively * by base classes) */ extern (C++) bool fillVtbl(ClassDeclaration cd, FuncDeclarations* vtbl, int newinstance) { bool result = false; //printf("BaseClass.fillVtbl(this='%s', cd='%s')\n", sym.toChars(), cd.toChars()); if (vtbl) vtbl.setDim(sym.vtbl.dim); // first entry is ClassInfo reference for (size_t j = sym.vtblOffset(); j < sym.vtbl.dim; j++) { FuncDeclaration ifd = sym.vtbl[j].isFuncDeclaration(); //printf(" vtbl[%d] is '%s'\n", j, ifd ? ifd.toChars() : "null"); assert(ifd); // Find corresponding function in this class auto tf = ifd.type.toTypeFunction(); auto fd = cd.findFunc(ifd.ident, tf); if (fd && !fd.isAbstract()) { if (fd.toParent() == cd) result = true; } else fd = null; if (vtbl) (*vtbl)[j] = fd; } return result; } extern (D) void copyBaseInterfaces(BaseClasses* vtblInterfaces) { //printf("+copyBaseInterfaces(), %s\n", sym.toChars()); // if (baseInterfaces.length) // return; auto bc = cast(BaseClass*)mem.xcalloc(sym.interfaces.length, BaseClass.sizeof); baseInterfaces = bc[0 .. sym.interfaces.length]; //printf("%s.copyBaseInterfaces()\n", sym.toChars()); for (size_t i = 0; i < baseInterfaces.length; i++) { BaseClass* b = &baseInterfaces[i]; BaseClass* b2 = sym.interfaces[i]; assert(b2.vtbl.dim == 0); // should not be filled yet memcpy(b, b2, BaseClass.sizeof); if (i) // single inheritance is i==0 vtblInterfaces.push(b); // only need for M.I. b.copyBaseInterfaces(vtblInterfaces); } //printf("-copyBaseInterfaces\n"); } } enum ClassFlags : uint { none = 0x0, isCOMclass = 0x1, noPointers = 0x2, hasOffTi = 0x4, hasCtor = 0x8, hasGetMembers = 0x10, hasTypeInfo = 0x20, isAbstract = 0x40, isCPPclass = 0x80, hasDtor = 0x100, } /*********************************************************** */ extern (C++) class ClassDeclaration : AggregateDeclaration { extern (C++) __gshared { // Names found by reading object.d in druntime ClassDeclaration object; ClassDeclaration throwable; ClassDeclaration exception; ClassDeclaration errorException; ClassDeclaration cpp_type_info_ptr; // Object.__cpp_type_info_ptr } ClassDeclaration baseClass; // NULL only if this is Object FuncDeclaration staticCtor; FuncDeclaration staticDtor; Dsymbols vtbl; // Array of FuncDeclaration's making up the vtbl[] Dsymbols vtblFinal; // More FuncDeclaration's that aren't in vtbl[] // Array of BaseClass's; first is super, rest are Interface's BaseClasses* baseclasses; /* Slice of baseclasses[] that does not include baseClass */ BaseClass*[] interfaces; // array of base interfaces that have their own vtbl[] BaseClasses* vtblInterfaces; // the ClassInfo object for this ClassDeclaration TypeInfoClassDeclaration vclassinfo; // true if this is a COM class bool com; /// true if this is a scope class bool stack; /// if this is a C++ class, this is the slot reserved for the virtual destructor int cppDtorVtblIndex = -1; /// to prevent recursive attempts private bool inuse; ThreeState isabstract; /// set the progress of base classes resolving Baseok baseok; /** * Data for a class declaration that is needed for the Objective-C * integration. */ ObjcClassDeclaration objc; Symbol* cpp_type_info_ptr_sym; // cached instance of class Id.cpp_type_info_ptr final extern (D) this(const ref Loc loc, Identifier id, BaseClasses* baseclasses, Dsymbols* members, bool inObject) { objc = ObjcClassDeclaration(this); if (!id) id = Identifier.generateAnonymousId("class"); super(loc, id); static immutable msg = "only object.d can define this reserved class name"; if (baseclasses) { // Actually, this is a transfer this.baseclasses = baseclasses; } else this.baseclasses = new BaseClasses(); this.members = members; //printf("ClassDeclaration(%s), dim = %d\n", ident.toChars(), this.baseclasses.dim); // For forward references type = new TypeClass(this); // Look for special class names if (id == Id.__sizeof || id == Id.__xalignof || id == Id._mangleof) error("illegal class name"); // BUG: What if this is the wrong TypeInfo, i.e. it is nested? if (id.toChars()[0] == 'T') { if (id == Id.TypeInfo) { if (!inObject) error("%s", msg.ptr); Type.dtypeinfo = this; } if (id == Id.TypeInfo_Class) { if (!inObject) error("%s", msg.ptr); Type.typeinfoclass = this; } if (id == Id.TypeInfo_Interface) { if (!inObject) error("%s", msg.ptr); Type.typeinfointerface = this; } if (id == Id.TypeInfo_Struct) { if (!inObject) error("%s", msg.ptr); Type.typeinfostruct = this; } if (id == Id.TypeInfo_Pointer) { if (!inObject) error("%s", msg.ptr); Type.typeinfopointer = this; } if (id == Id.TypeInfo_Array) { if (!inObject) error("%s", msg.ptr); Type.typeinfoarray = this; } if (id == Id.TypeInfo_StaticArray) { //if (!inObject) // Type.typeinfostaticarray.error("%s", msg); Type.typeinfostaticarray = this; } if (id == Id.TypeInfo_AssociativeArray) { if (!inObject) error("%s", msg.ptr); Type.typeinfoassociativearray = this; } if (id == Id.TypeInfo_Enum) { if (!inObject) error("%s", msg.ptr); Type.typeinfoenum = this; } if (id == Id.TypeInfo_Function) { if (!inObject) error("%s", msg.ptr); Type.typeinfofunction = this; } if (id == Id.TypeInfo_Delegate) { if (!inObject) error("%s", msg.ptr); Type.typeinfodelegate = this; } if (id == Id.TypeInfo_Tuple) { if (!inObject) error("%s", msg.ptr); Type.typeinfotypelist = this; } if (id == Id.TypeInfo_Const) { if (!inObject) error("%s", msg.ptr); Type.typeinfoconst = this; } if (id == Id.TypeInfo_Invariant) { if (!inObject) error("%s", msg.ptr); Type.typeinfoinvariant = this; } if (id == Id.TypeInfo_Shared) { if (!inObject) error("%s", msg.ptr); Type.typeinfoshared = this; } if (id == Id.TypeInfo_Wild) { if (!inObject) error("%s", msg.ptr); Type.typeinfowild = this; } if (id == Id.TypeInfo_Vector) { if (!inObject) error("%s", msg.ptr); Type.typeinfovector = this; } } if (id == Id.Object) { if (!inObject) error("%s", msg.ptr); object = this; } if (id == Id.Throwable) { if (!inObject) error("%s", msg.ptr); throwable = this; } if (id == Id.Exception) { if (!inObject) error("%s", msg.ptr); exception = this; } if (id == Id.Error) { if (!inObject) error("%s", msg.ptr); errorException = this; } if (id == Id.cpp_type_info_ptr) { if (!inObject) error("%s", msg.ptr); cpp_type_info_ptr = this; } baseok = Baseok.none; } static ClassDeclaration create(const ref Loc loc, Identifier id, BaseClasses* baseclasses, Dsymbols* members, bool inObject) { return new ClassDeclaration(loc, id, baseclasses, members, inObject); } override const(char)* toPrettyChars(bool qualifyTypes = false) { if (objc.isMeta) return .objc.toPrettyChars(this, qualifyTypes); return super.toPrettyChars(qualifyTypes); } override ClassDeclaration syntaxCopy(Dsymbol s) { //printf("ClassDeclaration.syntaxCopy('%s')\n", toChars()); ClassDeclaration cd = s ? cast(ClassDeclaration)s : new ClassDeclaration(loc, ident, null, null, false); cd.storage_class |= storage_class; cd.baseclasses.setDim(this.baseclasses.dim); for (size_t i = 0; i < cd.baseclasses.dim; i++) { BaseClass* b = (*this.baseclasses)[i]; auto b2 = new BaseClass(b.type.syntaxCopy()); (*cd.baseclasses)[i] = b2; } ScopeDsymbol.syntaxCopy(cd); return cd; } override Scope* newScope(Scope* sc) { auto sc2 = super.newScope(sc); if (isCOMclass()) { /* This enables us to use COM objects under Linux and * work with things like XPCOM */ sc2.linkage = target.systemLinkage(); } return sc2; } /********************************************* * Determine if 'this' is a base class of cd. * This is used to detect circular inheritance only. */ final bool isBaseOf2(ClassDeclaration cd) pure nothrow @nogc { if (!cd) return false; //printf("ClassDeclaration.isBaseOf2(this = '%s', cd = '%s')\n", toChars(), cd.toChars()); for (size_t i = 0; i < cd.baseclasses.dim; i++) { BaseClass* b = (*cd.baseclasses)[i]; if (b.sym == this || isBaseOf2(b.sym)) return true; } return false; } enum OFFSET_RUNTIME = 0x76543210; enum OFFSET_FWDREF = 0x76543211; /******************************************* * Determine if 'this' is a base class of cd. */ bool isBaseOf(ClassDeclaration cd, int* poffset) pure nothrow @nogc { //printf("ClassDeclaration.isBaseOf(this = '%s', cd = '%s')\n", toChars(), cd.toChars()); if (poffset) *poffset = 0; while (cd) { assert(cd.baseClass || cd.semanticRun >= PASS.semanticdone || cd.isInterfaceDeclaration()); if (this == cd.baseClass) return true; cd = cd.baseClass; } return false; } /********************************************* * Determine if 'this' has complete base class information. * This is used to detect forward references in covariant overloads. */ final bool isBaseInfoComplete() const { return baseok >= Baseok.done; } override final Dsymbol search(const ref Loc loc, Identifier ident, int flags = SearchLocalsOnly) { //printf("%s.ClassDeclaration.search('%s', flags=x%x)\n", toChars(), ident.toChars(), flags); //if (_scope) printf("%s baseok = %d\n", toChars(), baseok); if (_scope && baseok < Baseok.done) { if (!inuse) { // must semantic on base class/interfaces inuse = true; dsymbolSemantic(this, null); inuse = false; } } if (!members || !symtab) // opaque or addMember is not yet done { // .stringof is always defined (but may be hidden by some other symbol) if (ident != Id.stringof && !(flags & IgnoreErrors) && semanticRun < PASS.semanticdone) error("is forward referenced when looking for `%s`", ident.toChars()); //*(char*)0=0; return null; } auto s = ScopeDsymbol.search(loc, ident, flags); // don't search imports of base classes if (flags & SearchImportsOnly) return s; if (s) return s; // Search bases classes in depth-first, left to right order foreach (b; (*baseclasses)[]) { if (!b.sym) continue; if (!b.sym.symtab) { error("base `%s` is forward referenced", b.sym.ident.toChars()); continue; } import dmd.access : symbolIsVisible; s = b.sym.search(loc, ident, flags); if (!s) continue; else if (s == this) // happens if s is nested in this and derives from this s = null; else if (!(flags & IgnoreSymbolVisibility) && !(s.visible().kind == Visibility.Kind.protected_) && !symbolIsVisible(this, s)) s = null; else break; } return s; } /************************************ * Search base classes in depth-first, left-to-right order for * a class or interface named 'ident'. * Stops at first found. Does not look for additional matches. * Params: * ident = identifier to search for * Returns: * ClassDeclaration if found, null if not */ final ClassDeclaration searchBase(Identifier ident) { foreach (b; *baseclasses) { auto cdb = b.type.isClassHandle(); if (!cdb) // https://issues.dlang.org/show_bug.cgi?id=10616 return null; if (cdb.ident.equals(ident)) return cdb; auto result = cdb.searchBase(ident); if (result) return result; } return null; } final override void finalizeSize() { assert(sizeok != Sizeok.done); // Set the offsets of the fields and determine the size of the class if (baseClass) { assert(baseClass.sizeok == Sizeok.done); alignsize = baseClass.alignsize; if (classKind == ClassKind.cpp) structsize = target.cpp.derivedClassOffset(baseClass); else structsize = baseClass.structsize; } else if (classKind == ClassKind.objc) structsize = 0; // no hidden member for an Objective-C class else if (isInterfaceDeclaration()) { if (interfaces.length == 0) { alignsize = target.ptrsize; structsize = target.ptrsize; // allow room for __vptr } } else { alignsize = target.ptrsize; structsize = target.ptrsize; // allow room for __vptr if (hasMonitor()) structsize += target.ptrsize; // allow room for __monitor } //printf("finalizeSize() %s, sizeok = %d\n", toChars(), sizeok); size_t bi = 0; // index into vtblInterfaces[] /**** * Runs through the inheritance graph to set the BaseClass.offset fields. * Recursive in order to account for the size of the interface classes, if they are * more than just interfaces. * Params: * cd = interface to look at * baseOffset = offset of where cd will be placed * Returns: * subset of instantiated size used by cd for interfaces */ uint membersPlace(ClassDeclaration cd, uint baseOffset) { //printf(" membersPlace(%s, %d)\n", cd.toChars(), baseOffset); uint offset = baseOffset; foreach (BaseClass* b; cd.interfaces) { if (b.sym.sizeok != Sizeok.done) b.sym.finalizeSize(); assert(b.sym.sizeok == Sizeok.done); if (!b.sym.alignsize) b.sym.alignsize = target.ptrsize; alignmember(structalign_t(cast(ushort)b.sym.alignsize), b.sym.alignsize, &offset); assert(bi < vtblInterfaces.dim); BaseClass* bv = (*vtblInterfaces)[bi]; if (b.sym.interfaces.length == 0) { //printf("\tvtblInterfaces[%d] b=%p b.sym = %s, offset = %d\n", bi, bv, bv.sym.toChars(), offset); bv.offset = offset; ++bi; // All the base interfaces down the left side share the same offset for (BaseClass* b2 = bv; b2.baseInterfaces.length; ) { b2 = &b2.baseInterfaces[0]; b2.offset = offset; //printf("\tvtblInterfaces[%d] b=%p sym = %s, offset = %d\n", bi, b2, b2.sym.toChars(), b2.offset); } } membersPlace(b.sym, offset); //printf(" %s size = %d\n", b.sym.toChars(), b.sym.structsize); offset += b.sym.structsize; if (alignsize < b.sym.alignsize) alignsize = b.sym.alignsize; } return offset - baseOffset; } structsize += membersPlace(this, structsize); if (isInterfaceDeclaration()) { sizeok = Sizeok.done; return; } // FIXME: Currently setFieldOffset functions need to increase fields // to calculate each variable offsets. It can be improved later. fields.setDim(0); FieldState fieldState; fieldState.offset = structsize; foreach (s; *members) { s.setFieldOffset(this, fieldState, false); } sizeok = Sizeok.done; // Calculate fields[i].overlapped checkOverlappedFields(); } /************** * Returns: true if there's a __monitor field */ final bool hasMonitor() { return classKind == ClassKind.d; } final bool isFuncHidden(FuncDeclaration fd) { //printf("ClassDeclaration.isFuncHidden(class = %s, fd = %s)\n", toChars(), fd.toPrettyChars()); Dsymbol s = search(Loc.initial, fd.ident, IgnoreAmbiguous | IgnoreErrors); if (!s) { //printf("not found\n"); /* Because, due to a hack, if there are multiple definitions * of fd.ident, NULL is returned. */ return false; } s = s.toAlias(); if (auto os = s.isOverloadSet()) { foreach (sm; os.a) { auto fm = sm.isFuncDeclaration(); if (overloadApply(fm, s => fd == s.isFuncDeclaration())) return false; } return true; } else { auto f = s.isFuncDeclaration(); //printf("%s fdstart = %p\n", s.kind(), fdstart); if (overloadApply(f, s => fd == s.isFuncDeclaration())) return false; return !fd.parent.isTemplateMixin(); } } /**************** * Find virtual function matching identifier and type. * Used to build virtual function tables for interface implementations. * Params: * ident = function's identifier * tf = function's type * Returns: * function symbol if found, null if not * Errors: * prints error message if more than one match */ final FuncDeclaration findFunc(Identifier ident, TypeFunction tf) { //printf("ClassDeclaration.findFunc(%s, %s) %s\n", ident.toChars(), tf.toChars(), toChars()); FuncDeclaration fdmatch = null; FuncDeclaration fdambig = null; void updateBestMatch(FuncDeclaration fd) { fdmatch = fd; fdambig = null; //printf("Lfd fdmatch = %s %s [%s]\n", fdmatch.toChars(), fdmatch.type.toChars(), fdmatch.loc.toChars()); } void searchVtbl(ref Dsymbols vtbl) { bool seenInterfaceVirtual; foreach (s; vtbl) { auto fd = s.isFuncDeclaration(); if (!fd) continue; // the first entry might be a ClassInfo //printf("\t[%d] = %s\n", i, fd.toChars()); if (ident != fd.ident || fd.type.covariant(tf) != Covariant.yes) { //printf("\t\t%d\n", fd.type.covariant(tf)); continue; } //printf("fd.parent.isClassDeclaration() = %p\n", fd.parent.isClassDeclaration()); if (!fdmatch) { updateBestMatch(fd); continue; } if (fd == fdmatch) continue; /* Functions overriding interface functions for extern(C++) with VC++ * are not in the normal vtbl, but in vtblFinal. If the implementation * is again overridden in a child class, both would be found here. * The function in the child class should override the function * in the base class, which is done here, because searchVtbl is first * called for the child class. Checking seenInterfaceVirtual makes * sure, that the compared functions are not in the same vtbl. */ if (fd.interfaceVirtual && fd.interfaceVirtual is fdmatch.interfaceVirtual && !seenInterfaceVirtual && fdmatch.type.covariant(fd.type) == Covariant.yes) { seenInterfaceVirtual = true; continue; } { // Function type matching: exact > covariant MATCH m1 = tf.equals(fd.type) ? MATCH.exact : MATCH.nomatch; MATCH m2 = tf.equals(fdmatch.type) ? MATCH.exact : MATCH.nomatch; if (m1 > m2) { updateBestMatch(fd); continue; } else if (m1 < m2) continue; } { MATCH m1 = (tf.mod == fd.type.mod) ? MATCH.exact : MATCH.nomatch; MATCH m2 = (tf.mod == fdmatch.type.mod) ? MATCH.exact : MATCH.nomatch; if (m1 > m2) { updateBestMatch(fd); continue; } else if (m1 < m2) continue; } { // The way of definition: non-mixin > mixin MATCH m1 = fd.parent.isClassDeclaration() ? MATCH.exact : MATCH.nomatch; MATCH m2 = fdmatch.parent.isClassDeclaration() ? MATCH.exact : MATCH.nomatch; if (m1 > m2) { updateBestMatch(fd); continue; } else if (m1 < m2) continue; } fdambig = fd; //printf("Lambig fdambig = %s %s [%s]\n", fdambig.toChars(), fdambig.type.toChars(), fdambig.loc.toChars()); } } searchVtbl(vtbl); for (auto cd = this; cd; cd = cd.baseClass) { searchVtbl(cd.vtblFinal); } if (fdambig) error("ambiguous virtual function `%s`", fdambig.toChars()); return fdmatch; } /**************************************** */ final bool isCOMclass() const { return com; } bool isCOMinterface() const { return false; } final bool isCPPclass() const { return classKind == ClassKind.cpp; } bool isCPPinterface() const { return false; } /**************************************** */ final bool isAbstract() { enum log = false; if (isabstract != ThreeState.none) return isabstract == ThreeState.yes; if (log) printf("isAbstract(%s)\n", toChars()); bool no() { if (log) printf("no\n"); isabstract = ThreeState.no; return false; } bool yes() { if (log) printf("yes\n"); isabstract = ThreeState.yes; return true; } if (storage_class & STC.abstract_ || _scope && _scope.stc & STC.abstract_) return yes(); if (errors) return no(); /* https://issues.dlang.org/show_bug.cgi?id=11169 * Resolve forward references to all class member functions, * and determine whether this class is abstract. */ static int func(Dsymbol s) { auto fd = s.isFuncDeclaration(); if (!fd) return 0; if (fd.storage_class & STC.static_) return 0; if (fd.isAbstract()) return 1; return 0; } for (size_t i = 0; i < members.dim; i++) { auto s = (*members)[i]; if (s.apply(&func)) { return yes(); } } /* If the base class is not abstract, then this class cannot * be abstract. */ if (!isInterfaceDeclaration() && (!baseClass || !baseClass.isAbstract())) return no(); /* If any abstract functions are inherited, but not overridden, * then the class is abstract. Do this by checking the vtbl[]. * Need to do semantic() on class to fill the vtbl[]. */ this.dsymbolSemantic(null); /* The next line should work, but does not because when ClassDeclaration.dsymbolSemantic() * is called recursively it can set PASS.semanticdone without finishing it. */ //if (semanticRun < PASS.semanticdone) { /* Could not complete semantic(). Try running semantic() on * each of the virtual functions, * which will fill in the vtbl[] overrides. */ static int virtualSemantic(Dsymbol s) { auto fd = s.isFuncDeclaration(); if (fd && !(fd.storage_class & STC.static_) && !fd.isUnitTestDeclaration()) fd.dsymbolSemantic(null); return 0; } for (size_t i = 0; i < members.dim; i++) { auto s = (*members)[i]; s.apply(&virtualSemantic); } } /* Finally, check the vtbl[] */ foreach (i; 1 .. vtbl.dim) { auto fd = vtbl[i].isFuncDeclaration(); //if (fd) printf("\tvtbl[%d] = [%s] %s\n", i, fd.loc.toChars(), fd.toPrettyChars()); if (!fd || fd.isAbstract()) { return yes(); } } return no(); } /**************************************** * Determine if slot 0 of the vtbl[] is reserved for something else. * For class objects, yes, this is where the classinfo ptr goes. * For COM interfaces, no. * For non-COM interfaces, yes, this is where the Interface ptr goes. * Returns: * 0 vtbl[0] is first virtual function pointer * 1 vtbl[0] is classinfo/interfaceinfo pointer */ int vtblOffset() const { return classKind == ClassKind.cpp ? 0 : 1; } /**************************************** */ override const(char)* kind() const { return "class"; } /**************************************** */ override final void addLocalClass(ClassDeclarations* aclasses) { if (classKind != ClassKind.objc) aclasses.push(this); } override final void addObjcSymbols(ClassDeclarations* classes, ClassDeclarations* categories) { .objc.addSymbols(this, classes, categories); } // Back end Dsymbol vtblsym; final Dsymbol vtblSymbol() { if (!vtblsym) { auto vtype = Type.tvoidptr.immutableOf().sarrayOf(vtbl.dim); auto var = new VarDeclaration(loc, vtype, Identifier.idPool("__vtbl"), null, STC.immutable_ | STC.static_); var.addMember(null, this); var.isdataseg = 1; var._linkage = LINK.d; var.semanticRun = PASS.semanticdone; // no more semantic wanted vtblsym = var; } return vtblsym; } override final inout(ClassDeclaration) isClassDeclaration() inout @nogc nothrow pure @safe { return this; } override void accept(Visitor v) { v.visit(this); } } /*********************************************************** */ extern (C++) final class InterfaceDeclaration : ClassDeclaration { extern (D) this(const ref Loc loc, Identifier id, BaseClasses* baseclasses) { super(loc, id, baseclasses, null, false); if (id == Id.IUnknown) // IUnknown is the root of all COM interfaces { com = true; classKind = ClassKind.cpp; // IUnknown is also a C++ interface } } override InterfaceDeclaration syntaxCopy(Dsymbol s) { InterfaceDeclaration id = s ? cast(InterfaceDeclaration)s : new InterfaceDeclaration(loc, ident, null); ClassDeclaration.syntaxCopy(id); return id; } override Scope* newScope(Scope* sc) { auto sc2 = super.newScope(sc); if (com) sc2.linkage = LINK.windows; else if (classKind == ClassKind.cpp) sc2.linkage = LINK.cpp; else if (classKind == ClassKind.objc) sc2.linkage = LINK.objc; return sc2; } /******************************************* * Determine if 'this' is a base class of cd. * (Actually, if it is an interface supported by cd) * Output: * *poffset offset to start of class * OFFSET_RUNTIME must determine offset at runtime * Returns: * false not a base * true is a base */ override bool isBaseOf(ClassDeclaration cd, int* poffset) pure nothrow @nogc { //printf("%s.InterfaceDeclaration.isBaseOf(cd = '%s')\n", toChars(), cd.toChars()); assert(!baseClass); foreach (b; cd.interfaces) { //printf("\tX base %s\n", b.sym.toChars()); if (this == b.sym) { //printf("\tfound at offset %d\n", b.offset); if (poffset) { // don't return incorrect offsets // https://issues.dlang.org/show_bug.cgi?id=16980 *poffset = cd.sizeok == Sizeok.done ? b.offset : OFFSET_FWDREF; } // printf("\tfound at offset %d\n", b.offset); return true; } if (baseClassImplementsInterface(this, b, poffset)) return true; } if (cd.baseClass && isBaseOf(cd.baseClass, poffset)) return true; if (poffset) *poffset = 0; return false; } /******************************************* */ override const(char)* kind() const { return "interface"; } /**************************************** * Determine if slot 0 of the vtbl[] is reserved for something else. * For class objects, yes, this is where the ClassInfo ptr goes. * For COM interfaces, no. * For non-COM interfaces, yes, this is where the Interface ptr goes. */ override int vtblOffset() const { if (isCOMinterface() || isCPPinterface()) return 0; return 1; } override bool isCPPinterface() const { return classKind == ClassKind.cpp; } override bool isCOMinterface() const { return com; } override inout(InterfaceDeclaration) isInterfaceDeclaration() inout { return this; } override void accept(Visitor v) { v.visit(this); } } /** * Returns whether `bc` implements `id`, including indirectly (`bc` implements an interfaces * that inherits from `id`) * * Params: * id = the interface * bc = the base class * poffset = out parameter, offset of the interface in an object * * Returns: * true if the `bc` implements `id`, false otherwise **/ private bool baseClassImplementsInterface(InterfaceDeclaration id, BaseClass* bc, int* poffset) pure nothrow @nogc { //printf("%s.InterfaceDeclaration.isBaseOf(bc = '%s')\n", id.toChars(), bc.sym.toChars()); for (size_t j = 0; j < bc.baseInterfaces.length; j++) { BaseClass* b = &bc.baseInterfaces[j]; //printf("\tY base %s\n", b.sym.toChars()); if (id == b.sym) { //printf("\tfound at offset %d\n", b.offset); if (poffset) { *poffset = b.offset; } return true; } if (baseClassImplementsInterface(id, b, poffset)) { return true; } } if (poffset) *poffset = 0; return false; }