// Licensed to the .NET Foundation under one or more agreements. // The .NET Foundation licenses this file to you under the MIT license. using System; using System.Collections; using System.Collections.Generic; using System.Diagnostics; using System.Dynamic; using System.Linq.Expressions; using System.Globalization; using System.Reflection; using System.Runtime.InteropServices; using ComTypes = System.Runtime.InteropServices.ComTypes; namespace System.Management.Automation.ComInterop { /// /// A wrapper around a COM object that implements IDispatch /// /// This currently has the following issues: /// 1. IDispatch cannot distinguish between properties and methods with 0 arguments (and non-0 /// default arguments?). So obj.foo() is ambiguous as it could mean invoking method foo, /// or it could mean invoking the function pointer returned by property foo. /// We are attempting to find whether we need to call a method or a property by examining /// the ITypeInfo associated with the IDispatch. ITypeInfo tells us what parameters the method /// expects, is it a method or a property, what is the default property of the object, how to /// create an enumerator for collections etc. /// /// We also support events for IDispatch objects: /// Background: /// COM objects support events through a mechanism known as Connect Points. /// Connection Points are separate objects created off the actual COM /// object (this is to prevent circular references between event sink /// and event source). When clients want to sink events generated by /// COM object they would implement callback interfaces (aka source /// interfaces) and hand it over (advise) to the Connection Point. /// /// Implementation details: /// When IDispatchComObject.TryGetMember request is received we first check /// whether the requested member is a property or a method. If this check /// fails we will try to determine whether an event is requested. To do /// so we will do the following set of steps: /// 1. Verify the COM object implements IConnectionPointContainer /// 2. Attempt to find COM object's coclass's description /// a. Query the object for IProvideClassInfo interface. Go to 3, if found /// b. From object's IDispatch retrieve primary interface description /// c. Scan coclasses declared in object's type library. /// d. Find coclass implementing this particular primary interface /// 3. Scan coclass for all its source interfaces. /// 4. Check whether to any of the methods on the source interfaces matches /// the request name /// /// Once we determine that TryGetMember requests an event we will return /// an instance of BoundDispEvent class. This class has InPlaceAdd and /// InPlaceSubtract operators defined. Calling InPlaceAdd operator will: /// 1. An instance of ComEventSinksContainer class is created (unless /// RCW already had one). This instance is associated to the RCW in attempt /// to bind the lifetime of event sinks to the lifetime of the RCW itself, /// meaning event sink will be collected once the RCW is collected (this /// is the same way event sinks lifetime is controlled by PIAs). /// Notice: ComEventSinksContainer contains a Finalizer which will go and /// unadvise all event sinks. /// Notice: ComEventSinksContainer is a list of ComEventSink objects. /// 2. Unless we have already created a ComEventSink for the required /// source interface, we will create and advise a new ComEventSink. Each /// ComEventSink implements a single source interface that COM object /// supports. /// 3. ComEventSink contains a map between method DISPIDs to the /// multicast delegate that will be invoked when the event is raised. /// 4. ComEventSink implements IReflect interface which is exposed as /// custom IDispatch to COM consumers. This allows us to intercept calls /// to IDispatch.Invoke and apply custom logic - in particular we will /// just find and invoke the multicast delegate corresponding to the invoked /// dispid. /// internal sealed class IDispatchComObject : ComObject, IDynamicMetaObjectProvider { private ComTypeDesc _comTypeDesc; private static readonly Dictionary s_cacheComTypeDesc = new Dictionary(); internal IDispatchComObject(IDispatch rcw) : base(rcw) { DispatchObject = rcw; } public override string ToString() { ComTypeDesc ctd = _comTypeDesc; string typeName = null; if (ctd != null) { typeName = ctd.TypeName; } if (string.IsNullOrEmpty(typeName)) { typeName = "IDispatch"; } return $"{RuntimeCallableWrapper} ({typeName})"; } public ComTypeDesc ComTypeDesc { get { EnsureScanDefinedMethods(); return _comTypeDesc; } } public IDispatch DispatchObject { get; } private static int GetIDsOfNames(IDispatch dispatch, string name, out int dispId) { int[] dispIds = new int[1]; Guid emptyRiid = Guid.Empty; int hresult = dispatch.TryGetIDsOfNames( ref emptyRiid, new string[] { name }, 1, 0, dispIds); dispId = dispIds[0]; return hresult; } internal bool TryGetGetItem(out ComMethodDesc value) { ComMethodDesc methodDesc = _comTypeDesc.GetItem; if (methodDesc != null) { value = methodDesc; return true; } return SlowTryGetGetItem(out value); } private bool SlowTryGetGetItem(out ComMethodDesc value) { EnsureScanDefinedMethods(); ComMethodDesc methodDesc = _comTypeDesc.GetItem; // Without type information, we really don't know whether or not we have a property getter. if (methodDesc == null) { string name = "[PROPERTYGET, DISPID(0)]"; _comTypeDesc.EnsureGetItem(new ComMethodDesc(name, ComDispIds.DISPID_VALUE, ComTypes.INVOKEKIND.INVOKE_PROPERTYGET)); methodDesc = _comTypeDesc.GetItem; } value = methodDesc; return true; } internal bool TryGetSetItem(out ComMethodDesc value) { ComMethodDesc methodDesc = _comTypeDesc.SetItem; if (methodDesc != null) { value = methodDesc; return true; } return SlowTryGetSetItem(out value); } private bool SlowTryGetSetItem(out ComMethodDesc value) { EnsureScanDefinedMethods(); ComMethodDesc methodDesc = _comTypeDesc.SetItem; // Without type information, we really don't know whether or not we have a property setter. if (methodDesc == null) { string name = "[PROPERTYPUT, DISPID(0)]"; _comTypeDesc.EnsureSetItem(new ComMethodDesc(name, ComDispIds.DISPID_VALUE, ComTypes.INVOKEKIND.INVOKE_PROPERTYPUT)); methodDesc = _comTypeDesc.SetItem; } value = methodDesc; return true; } internal bool TryGetMemberMethod(string name, out ComMethodDesc method) { EnsureScanDefinedMethods(); return _comTypeDesc.TryGetFunc(name, out method); } internal bool TryGetMemberEvent(string name, out ComEventDesc @event) { EnsureScanDefinedEvents(); return _comTypeDesc.TryGetEvent(name, out @event); } internal bool TryGetMemberMethodExplicit(string name, out ComMethodDesc method) { EnsureScanDefinedMethods(); int hresult = GetIDsOfNames(DispatchObject, name, out int dispId); if (hresult == ComHresults.S_OK) { ComMethodDesc cmd = new ComMethodDesc(name, dispId, ComTypes.INVOKEKIND.INVOKE_FUNC); _comTypeDesc.AddFunc(name, cmd); method = cmd; return true; } if (hresult == ComHresults.DISP_E_UNKNOWNNAME) { method = null; return false; } throw Error.CouldNotGetDispId(name, string.Create(CultureInfo.InvariantCulture, $"0x{hresult:X})")); } internal bool TryGetPropertySetterExplicit(string name, out ComMethodDesc method, Type limitType, bool holdsNull) { EnsureScanDefinedMethods(); int hresult = GetIDsOfNames(DispatchObject, name, out int dispId); if (hresult == ComHresults.S_OK) { // we do not know whether we have put or putref here // and we will not guess and pretend we found both. ComMethodDesc put = new ComMethodDesc(name, dispId, ComTypes.INVOKEKIND.INVOKE_PROPERTYPUT); _comTypeDesc.AddPut(name, put); ComMethodDesc putref = new ComMethodDesc(name, dispId, ComTypes.INVOKEKIND.INVOKE_PROPERTYPUTREF); _comTypeDesc.AddPutRef(name, putref); if (ComBinderHelpers.PreferPut(limitType, holdsNull)) { method = put; } else { method = putref; } return true; } if (hresult == ComHresults.DISP_E_UNKNOWNNAME) { method = null; return false; } throw Error.CouldNotGetDispId(name, string.Create(CultureInfo.InvariantCulture, $"0x{hresult:X})")); } internal override IList GetMemberNames(bool dataOnly) { EnsureScanDefinedMethods(); EnsureScanDefinedEvents(); return ComTypeDesc.GetMemberNames(dataOnly); } internal override IList> GetMembers(IEnumerable names) { names ??= GetMemberNames(true); Type comType = RuntimeCallableWrapper.GetType(); var members = new List>(); foreach (string name in names) { if (name == null) { continue; } if (ComTypeDesc.TryGetFunc(name, out ComMethodDesc method) && method.IsDataMember) { try { object value = comType.InvokeMember( method.Name, BindingFlags.GetProperty, null, RuntimeCallableWrapper, Array.Empty(), CultureInfo.InvariantCulture ); members.Add(new KeyValuePair(method.Name, value)); //evaluation failed for some reason. pass exception out } catch (Exception ex) { members.Add(new KeyValuePair(method.Name, ex)); } } } return members.ToArray(); } DynamicMetaObject IDynamicMetaObjectProvider.GetMetaObject(Expression parameter) { EnsureScanDefinedMethods(); return new IDispatchMetaObject(parameter, this); } private static void GetFuncDescForDescIndex(ComTypes.ITypeInfo typeInfo, int funcIndex, out ComTypes.FUNCDESC funcDesc, out IntPtr funcDescHandle) { IntPtr pFuncDesc; typeInfo.GetFuncDesc(funcIndex, out pFuncDesc); // GetFuncDesc should never return null, this is just to be safe if (pFuncDesc == IntPtr.Zero) { throw Error.CannotRetrieveTypeInformation(); } funcDesc = (ComTypes.FUNCDESC)Marshal.PtrToStructure(pFuncDesc, typeof(ComTypes.FUNCDESC)); funcDescHandle = pFuncDesc; } private void EnsureScanDefinedEvents() { // _comTypeDesc.Events is null if we have not yet attempted // to scan the object for events. if (_comTypeDesc?.Events != null) { return; } // check type info in the type descriptions cache ComTypes.ITypeInfo typeInfo = ComRuntimeHelpers.GetITypeInfoFromIDispatch(DispatchObject); if (typeInfo == null) { _comTypeDesc = ComTypeDesc.CreateEmptyTypeDesc(); return; } ComTypes.TYPEATTR typeAttr = ComRuntimeHelpers.GetTypeAttrForTypeInfo(typeInfo); if (_comTypeDesc == null) { lock (s_cacheComTypeDesc) { if (s_cacheComTypeDesc.TryGetValue(typeAttr.guid, out _comTypeDesc) && _comTypeDesc.Events != null) { return; } } } ComTypeDesc typeDesc = ComTypeDesc.FromITypeInfo(typeInfo, typeAttr); ComTypes.ITypeInfo classTypeInfo; Dictionary events; var cpc = RuntimeCallableWrapper as ComTypes.IConnectionPointContainer; if (cpc == null) { // No ICPC - this object does not support events events = ComTypeDesc.EmptyEvents; } else if ((classTypeInfo = GetCoClassTypeInfo(RuntimeCallableWrapper, typeInfo)) == null) { // no class info found - this object may support events // but we could not discover those events = ComTypeDesc.EmptyEvents; } else { events = new Dictionary(); ComTypes.TYPEATTR classTypeAttr = ComRuntimeHelpers.GetTypeAttrForTypeInfo(classTypeInfo); for (int i = 0; i < classTypeAttr.cImplTypes; i++) { classTypeInfo.GetRefTypeOfImplType(i, out int hRefType); classTypeInfo.GetRefTypeInfo(hRefType, out ComTypes.ITypeInfo interfaceTypeInfo); classTypeInfo.GetImplTypeFlags(i, out ComTypes.IMPLTYPEFLAGS flags); if ((flags & ComTypes.IMPLTYPEFLAGS.IMPLTYPEFLAG_FSOURCE) != 0) { ScanSourceInterface(interfaceTypeInfo, ref events); } } if (events.Count == 0) { events = ComTypeDesc.EmptyEvents; } } lock (s_cacheComTypeDesc) { if (s_cacheComTypeDesc.TryGetValue(typeAttr.guid, out ComTypeDesc cachedTypeDesc)) { _comTypeDesc = cachedTypeDesc; } else { _comTypeDesc = typeDesc; s_cacheComTypeDesc.Add(typeAttr.guid, _comTypeDesc); } _comTypeDesc.Events = events; } } private static void ScanSourceInterface(ComTypes.ITypeInfo sourceTypeInfo, ref Dictionary events) { ComTypes.TYPEATTR sourceTypeAttribute = ComRuntimeHelpers.GetTypeAttrForTypeInfo(sourceTypeInfo); for (int index = 0; index < sourceTypeAttribute.cFuncs; index++) { IntPtr funcDescHandleToRelease = IntPtr.Zero; try { GetFuncDescForDescIndex(sourceTypeInfo, index, out ComTypes.FUNCDESC funcDesc, out funcDescHandleToRelease); // we are not interested in hidden or restricted functions for now. if ((funcDesc.wFuncFlags & (int)ComTypes.FUNCFLAGS.FUNCFLAG_FHIDDEN) != 0) { continue; } if ((funcDesc.wFuncFlags & (int)ComTypes.FUNCFLAGS.FUNCFLAG_FRESTRICTED) != 0) { continue; } string name = ComRuntimeHelpers.GetNameOfMethod(sourceTypeInfo, funcDesc.memid); name = name.ToUpper(System.Globalization.CultureInfo.InvariantCulture); // Sometimes coclass has multiple source interfaces. Usually this is caused by // adding new events and putting them on new interfaces while keeping the // old interfaces around. This may cause name collisions which we are // resolving by keeping only the first event with the same name. if (!events.ContainsKey(name)) { ComEventDesc eventDesc = new ComEventDesc { Dispid = funcDesc.memid, SourceIID = sourceTypeAttribute.guid }; events.Add(name, eventDesc); } } finally { if (funcDescHandleToRelease != IntPtr.Zero) { sourceTypeInfo.ReleaseFuncDesc(funcDescHandleToRelease); } } } } private static ComTypes.ITypeInfo GetCoClassTypeInfo(object rcw, ComTypes.ITypeInfo typeInfo) { Debug.Assert(typeInfo != null); if (rcw is IProvideClassInfo provideClassInfo) { IntPtr typeInfoPtr = IntPtr.Zero; try { provideClassInfo.GetClassInfo(out typeInfoPtr); if (typeInfoPtr != IntPtr.Zero) { return Marshal.GetObjectForIUnknown(typeInfoPtr) as ComTypes.ITypeInfo; } } finally { if (typeInfoPtr != IntPtr.Zero) { Marshal.Release(typeInfoPtr); } } } // retrieving class information through IPCI has failed - // we can try scanning the typelib to find the coclass typeInfo.GetContainingTypeLib(out ComTypes.ITypeLib typeLib, out int _); string typeName = ComRuntimeHelpers.GetNameOfType(typeInfo); ComTypeLibDesc typeLibDesc = ComTypeLibDesc.GetFromTypeLib(typeLib); ComTypeClassDesc coclassDesc = typeLibDesc.GetCoClassForInterface(typeName); if (coclassDesc == null) { return null; } Guid coclassGuid = coclassDesc.Guid; typeLib.GetTypeInfoOfGuid(ref coclassGuid, out ComTypes.ITypeInfo typeInfoCoClass); return typeInfoCoClass; } private void EnsureScanDefinedMethods() { if (_comTypeDesc?.Funcs != null) { return; } ComTypes.ITypeInfo typeInfo = ComRuntimeHelpers.GetITypeInfoFromIDispatch(DispatchObject); if (typeInfo == null) { _comTypeDesc = ComTypeDesc.CreateEmptyTypeDesc(); return; } ComTypes.TYPEATTR typeAttr = ComRuntimeHelpers.GetTypeAttrForTypeInfo(typeInfo); if (_comTypeDesc == null) { lock (s_cacheComTypeDesc) { if (s_cacheComTypeDesc.TryGetValue(typeAttr.guid, out _comTypeDesc) && _comTypeDesc.Funcs != null) { return; } } } if (typeAttr.typekind == ComTypes.TYPEKIND.TKIND_INTERFACE) { // We have typeinfo for custom interface. Get typeinfo for Dispatch interface. typeInfo = ComTypeInfo.GetDispatchTypeInfoFromCustomInterfaceTypeInfo(typeInfo); typeAttr = ComRuntimeHelpers.GetTypeAttrForTypeInfo(typeInfo); } if (typeAttr.typekind == ComTypes.TYPEKIND.TKIND_COCLASS) { // We have typeinfo for the COClass. Find the default interface and get typeinfo for default interface. typeInfo = ComTypeInfo.GetDispatchTypeInfoFromCoClassTypeInfo(typeInfo); typeAttr = ComRuntimeHelpers.GetTypeAttrForTypeInfo(typeInfo); } ComTypeDesc typeDesc = ComTypeDesc.FromITypeInfo(typeInfo, typeAttr); ComMethodDesc getItem = null; ComMethodDesc setItem = null; Hashtable funcs = new Hashtable(typeAttr.cFuncs); Hashtable puts = new Hashtable(); Hashtable putrefs = new Hashtable(); for (int definedFuncIndex = 0; definedFuncIndex < typeAttr.cFuncs; definedFuncIndex++) { IntPtr funcDescHandleToRelease = IntPtr.Zero; try { GetFuncDescForDescIndex(typeInfo, definedFuncIndex, out ComTypes.FUNCDESC funcDesc, out funcDescHandleToRelease); if ((funcDesc.wFuncFlags & (int)ComTypes.FUNCFLAGS.FUNCFLAG_FRESTRICTED) != 0) { // This function is not meant for the script user to use. continue; } ComMethodDesc method = new ComMethodDesc(typeInfo, funcDesc); string name = method.Name.ToUpper(CultureInfo.InvariantCulture); if ((funcDesc.invkind & ComTypes.INVOKEKIND.INVOKE_PROPERTYPUT) != 0) { // If there is a getter for this put, use that ReturnType as the // PropertyType. if (funcs.ContainsKey(name)) { method.InputType = ((ComMethodDesc)funcs[name]).ReturnType; } puts.Add(name, method); // for the special dispId == 0, we need to store // the method descriptor for the Do(SetItem) binder. if (method.DispId == ComDispIds.DISPID_VALUE && setItem == null) { setItem = method; } continue; } if ((funcDesc.invkind & ComTypes.INVOKEKIND.INVOKE_PROPERTYPUTREF) != 0) { // If there is a getter for this put, use that ReturnType as the // PropertyType. if (funcs.ContainsKey(name)) { method.InputType = ((ComMethodDesc)funcs[name]).ReturnType; } putrefs.Add(name, method); // for the special dispId == 0, we need to store // the method descriptor for the Do(SetItem) binder. if (method.DispId == ComDispIds.DISPID_VALUE && setItem == null) { setItem = method; } continue; } if (funcDesc.memid == ComDispIds.DISPID_NEWENUM) { funcs.Add("GETENUMERATOR", method); continue; } // If there is a setter for this put, update the InputType from our // ReturnType. if (puts.ContainsKey(name)) { ((ComMethodDesc)puts[name]).InputType = method.ReturnType; } if (putrefs.ContainsKey(name)) { ((ComMethodDesc)putrefs[name]).InputType = method.ReturnType; } funcs.Add(name, method); // for the special dispId == 0, we need to store the method descriptor // for the Do(GetItem) binder. if (funcDesc.memid == ComDispIds.DISPID_VALUE) { getItem = method; } } finally { if (funcDescHandleToRelease != IntPtr.Zero) { typeInfo.ReleaseFuncDesc(funcDescHandleToRelease); } } } lock (s_cacheComTypeDesc) { if (s_cacheComTypeDesc.TryGetValue(typeAttr.guid, out ComTypeDesc cachedTypeDesc)) { _comTypeDesc = cachedTypeDesc; } else { _comTypeDesc = typeDesc; s_cacheComTypeDesc.Add(typeAttr.guid, _comTypeDesc); } _comTypeDesc.Funcs = funcs; _comTypeDesc.Puts = puts; _comTypeDesc.PutRefs = putrefs; _comTypeDesc.EnsureGetItem(getItem); _comTypeDesc.EnsureSetItem(setItem); } } internal bool TryGetPropertySetter(string name, out ComMethodDesc method, Type limitType, bool holdsNull) { EnsureScanDefinedMethods(); if (ComBinderHelpers.PreferPut(limitType, holdsNull)) { return _comTypeDesc.TryGetPut(name, out method) || _comTypeDesc.TryGetPutRef(name, out method); } return _comTypeDesc.TryGetPutRef(name, out method) || _comTypeDesc.TryGetPut(name, out method); } } }