// // Copyright (c) Microsoft Corporation. All rights reserved. // namespace System.Activities.DynamicUpdate { using System; using System.Activities.DynamicUpdate; using System.Activities.Validation; using System.Collections; using System.Collections.Generic; using System.Diagnostics.CodeAnalysis; using System.Globalization; using System.Linq; using System.Runtime; using System.Runtime.CompilerServices; public class DynamicUpdateMapBuilder { private HashSet disallowUpdateInside; public DynamicUpdateMapBuilder() { } public bool ForImplementation { get; set; } public ISet DisallowUpdateInside { get { if (this.disallowUpdateInside == null) { this.disallowUpdateInside = new HashSet(ReferenceEqualityComparer.Instance); } return this.disallowUpdateInside; } } public Func LookupMapItem { get; set; } public Func LookupImplementationMap { get; set; } public LocationReferenceEnvironment UpdatedEnvironment { get; set; } public Activity UpdatedWorkflowDefinition { get; set; } public LocationReferenceEnvironment OriginalEnvironment { get; set; } public Activity OriginalWorkflowDefinition { get; set; } // Internal hook to allow DynamicUpdateServices to surface a customized error message when // there is an invalid activity in the disallowUpdateInsideActivities list internal Func OnInvalidActivityToBlockUpdate { get; set; } // Internal hook to allow DynamicUpdateServices to surface a customized error message when // there is an invalid activity in the disallowUpdateInsideActivities list internal Func OnInvalidImplementationMapAssociation { get; set; } public DynamicUpdateMap CreateMap() { IList activitiesBlockingUpdate; return CreateMap(out activitiesBlockingUpdate); } [SuppressMessage(FxCop.Category.Design, FxCop.Rule.AvoidOutParameters, Justification = "Approved Design. Need to return the map and the block list.")] public DynamicUpdateMap CreateMap(out IList activitiesBlockingUpdate) { RequireProperty(this.LookupMapItem, "LookupMapItem"); RequireProperty(this.UpdatedWorkflowDefinition, "UpdatedWorkflowDefinition"); RequireProperty(this.OriginalWorkflowDefinition, "OriginalWorkflowDefinition"); Finalizer finalizer = new Finalizer(this); DynamicUpdateMap result = finalizer.FinalizeUpdate(out activitiesBlockingUpdate); return result; } private static void CacheMetadata(Activity workflowDefinition, LocationReferenceEnvironment environment, ActivityUtilities.ProcessActivityCallback callback, bool forImplementation) { IList validationErrors = null; ActivityUtilities.CacheRootMetadata(workflowDefinition, environment, ProcessTreeOptions(forImplementation), callback, ref validationErrors); ActivityValidationServices.ThrowIfViolationsExist(validationErrors); } static DynamicUpdateMapEntry GetParentEntry(Activity originalActivity, DynamicUpdateMap updateMap) { if (originalActivity.Parent != null && originalActivity.Parent.MemberOf == originalActivity.MemberOf) { DynamicUpdateMapEntry parentEntry; updateMap.TryGetUpdateEntry(originalActivity.Parent.InternalId, out parentEntry); Fx.Assert(parentEntry != null, "We process in IdSpace order, so we always process parents before their children"); return parentEntry; } return null; } static IEnumerable GetPublicDeclaredChildren(Activity activity, bool includeExpressions) { IEnumerable result = activity.Children.Concat( activity.ImportedChildren).Concat( activity.Delegates.Select(d => d.Handler)).Concat( activity.ImportedDelegates.Select(d => d.Handler)); if (includeExpressions) { result = result.Concat( activity.RuntimeVariables.Select(v => v.Default)).Concat( activity.RuntimeArguments.Select(a => a.IsBound ? a.BoundArgument.Expression : null)); } return result.Where(a => a != null && a.Parent == activity); } private static ProcessActivityTreeOptions ProcessTreeOptions(bool forImplementation) { return forImplementation ? ProcessActivityTreeOptions.DynamicUpdateOptionsForImplementation : ProcessActivityTreeOptions.DynamicUpdateOptions; } private static void RequireProperty(object value, string name) { if (value == null) { throw FxTrace.Exception.AsError(new InvalidOperationException(SR.UpdateMapBuilderRequiredProperty(name))); } } internal class ReferenceEqualityComparer : IEqualityComparer { public static readonly IEqualityComparer Instance = new ReferenceEqualityComparer(); ReferenceEqualityComparer() { } public new bool Equals(object x, object y) { return object.ReferenceEquals(x, y); } public int GetHashCode(object obj) { return RuntimeHelpers.GetHashCode(obj); } } // Preparer walks the tree and identifies, for each object in the tree, an ID that can be // attached to an object in the new definition to match it to the equivalent object in the // old definition. internal class Preparer { private Dictionary updateableObjects; private Activity originalProgram; private LocationReferenceEnvironment originalEnvironment; private bool forImplementation; public Preparer(Activity originalProgram, LocationReferenceEnvironment originalEnvironment, bool forImplementation) { this.originalProgram = originalProgram; this.originalEnvironment = originalEnvironment; this.forImplementation = forImplementation; } public Dictionary Prepare() { this.updateableObjects = new Dictionary(ReferenceEqualityComparer.Instance); CacheMetadata(this.originalProgram, this.originalEnvironment, null, this.forImplementation); IdSpace idSpace = GetIdSpace(); if (idSpace != null) { for (int i = 1; i <= idSpace.MemberCount; i++) { ProcessElement(idSpace[i]); } } return this.updateableObjects; } IdSpace GetIdSpace() { return this.forImplementation ? this.originalProgram.ParentOf : this.originalProgram.MemberOf; } void ProcessElement(Activity currentElement) { // Attach the original Activity ID to the activity // The origin of a variable default is the same as the origin of the variable itself. // So we don't attach match info for the default, since that would conflict with // the match info for the variable. if (currentElement.RelationshipToParent != Activity.RelationshipType.VariableDefault || currentElement.Origin == null) { ValidateOrigin(currentElement.Origin, currentElement); this.updateableObjects[currentElement.Origin ?? currentElement] = new DynamicUpdateMapItem(currentElement.InternalId); } // Attach the original variable index to the variable IList variables = currentElement.RuntimeVariables; for (int i = 0; i < variables.Count; i++) { Variable variable = variables[i]; if (string.IsNullOrEmpty(variable.Name)) { ValidateOrigin(variable.Origin, variable); this.updateableObjects[variable.Origin ?? variable] = new DynamicUpdateMapItem(currentElement.InternalId, i); } } } void ValidateOrigin(object origin, object element) { if (origin != null) { DynamicUpdateMapItem mapItem; if (this.updateableObjects.TryGetValue(origin, out mapItem)) { string error = null; if (mapItem.IsVariableMapItem) { Variable dupe = GetVariable(mapItem); Variable elementVar = element as Variable; if (elementVar != null) { error = SR.DuplicateOriginVariableVariable(origin, dupe.Name, elementVar.Name); } else { error = SR.DuplicateOriginActivityVariable(origin, element, dupe.Name); } } else { Activity dupe = GetActivity(mapItem); Variable elementVar = element as Variable; if (elementVar != null) { error = SR.DuplicateOriginActivityVariable(origin, dupe, elementVar.Name); } else { error = SR.DuplicateOriginActivityActivity(origin, dupe, element); } } throw FxTrace.Exception.AsError(new InvalidWorkflowException(error)); } } } Activity GetActivity(DynamicUpdateMapItem mapItem) { return GetIdSpace()[mapItem.OriginalId]; } Variable GetVariable(DynamicUpdateMapItem mapItem) { return GetIdSpace()[mapItem.OriginalVariableOwnerId].RuntimeVariables[mapItem.OriginalId]; } } // Builds an Update Map given an old and new definition, and matches between them internal class Finalizer { BitArray foundOriginalElements; DynamicUpdateMapBuilder builder; DynamicUpdateMap updateMap; Dictionary savedOriginalValues; bool savedOriginalValuesForReferencedChildren; IList blockList; // dictionary from expression root to the activity that can make it go idle Dictionary expressionRootsThatCanInduceIdle; public Finalizer(DynamicUpdateMapBuilder builder) { this.builder = builder; this.savedOriginalValues = new Dictionary(ReferenceEqualityComparer.Instance); this.Matcher = new DefinitionMatcher(builder.LookupMapItem); } public DynamicUpdateMap FinalizeUpdate(out IList blockList) { this.updateMap = new DynamicUpdateMap(); this.blockList = new List(); // cache metadata of originalProgram CacheMetadata(this.builder.OriginalWorkflowDefinition, this.builder.OriginalEnvironment, null, this.builder.ForImplementation); IdSpace originalIdSpace = this.builder.ForImplementation ? this.builder.OriginalWorkflowDefinition.ParentOf : this.builder.OriginalWorkflowDefinition.MemberOf; if (originalIdSpace == null) { Fx.Assert(this.builder.ForImplementation, "An activity must be a member of an IdSpace"); throw FxTrace.Exception.AsError(new InvalidOperationException(SR.InvalidOriginalWorkflowDefinitionForImplementationMapCreation)); } this.Matcher.OldIdSpace = originalIdSpace; this.foundOriginalElements = new BitArray(originalIdSpace.MemberCount); // cache metadata of modifiedProgram before iterative ProcessElement() CacheMetadata(this.builder.UpdatedWorkflowDefinition, this.builder.UpdatedEnvironment, CheckCanArgumentOrVariableDefaultInduceIdle, this.builder.ForImplementation); IdSpace idSpace = this.builder.ForImplementation ? this.builder.UpdatedWorkflowDefinition.ParentOf : this.builder.UpdatedWorkflowDefinition.MemberOf; if (idSpace == null) { Fx.Assert(this.builder.ForImplementation, "An activity must be a member of an IdSpace"); throw FxTrace.Exception.AsError(new InvalidOperationException(SR.InvalidUpdatedWorkflowDefinitionForImplementationMapCreation)); } this.Matcher.NewIdSpace = idSpace; // check if any of the activities or variables from the original definition // were reused in the updated definition for (int i = 1; i < originalIdSpace.MemberCount + 1; i++) { CheckForReusedActivity(originalIdSpace[i]); } // most of the updatemap construction processing for (int i = 1; i < idSpace.MemberCount + 1; i++) { ProcessElement(idSpace[i]); } // if an activity doesn't have an entry by this point, that means it was removed for (int i = 0; i < this.foundOriginalElements.Count; i++) { if (!this.foundOriginalElements[i]) { DynamicUpdateMapEntry removalEntry = new DynamicUpdateMapEntry(i + 1, 0); Activity originalActivity = originalIdSpace[i + 1]; removalEntry.Parent = GetParentEntry(originalActivity, this.updateMap); if (!removalEntry.IsParentRemovedOrBlocked) { removalEntry.DisplayName = originalActivity.DisplayName; } this.updateMap.AddEntry(removalEntry); } } if (this.builder.ForImplementation) { this.updateMap.IsForImplementation = true; // gather arguments diff between new and old activity definitions this.updateMap.OldArguments = ArgumentInfo.List(builder.OriginalWorkflowDefinition); this.updateMap.NewArguments = ArgumentInfo.List(builder.UpdatedWorkflowDefinition); } // Validate the Disallow entries foreach (Activity disallowActivity in this.builder.DisallowUpdateInside) { if (disallowActivity == null) { continue; } if (disallowActivity.MemberOf != idSpace) { ThrowInvalidActivityToBlockUpdate(disallowActivity); } } this.updateMap.NewDefinitionMemberCount = idSpace.MemberCount; blockList = this.blockList; return this.updateMap; } internal bool? AllowUpdateInsideCurrentActivity { get; set; } internal string UpdateDisallowedReason { get; set; } internal Dictionary SavedOriginalValuesForCurrentActivity { get; set; } internal DefinitionMatcher Matcher { get; private set; } internal Dictionary ExpressionRootsThatCanInduceIdle { get { return this.expressionRootsThatCanInduceIdle; } } void BlockUpdate(Activity activity, UpdateBlockedReason reason, DynamicUpdateMapEntry entry, string message = null) { Fx.Assert(activity.MemberOf == (this.builder.ForImplementation ? activity.RootActivity.ParentOf : activity.RootActivity.MemberOf), "Should have called other overload of BlockUpdate"); BlockUpdate(activity, entry.OldActivityId.ToString(CultureInfo.InvariantCulture), reason, entry, message); } internal void BlockUpdate(Activity activity, string originalActivityId, UpdateBlockedReason reason, DynamicUpdateMapEntry entry, string message = null) { Fx.Assert(reason != UpdateBlockedReason.NotBlocked, "Invalid block reason"); if (!entry.IsRuntimeUpdateBlocked) { entry.BlockReason = reason; if (reason == UpdateBlockedReason.Custom) { entry.BlockReasonMessage = message; } entry.ImplementationUpdateMap = null; this.blockList.Add(new ActivityBlockingUpdate(activity, originalActivityId, message ?? UpdateBlockedReasonMessages.Get(reason))); } } internal void SetOriginalValue(Activity key, object value, bool isReferencedChild) { if (isReferencedChild) { this.savedOriginalValuesForReferencedChildren = true; } else { this.savedOriginalValues[key] = value; } } internal object GetSavedOriginalValueFromParent(Activity key) { object result = null; this.savedOriginalValues.TryGetValue(key, out result); return result; } void ProcessElement(Activity currentElement) { Activity originalElement = this.Matcher.GetMatch(currentElement); if (originalElement != null) { // this means it's an existing one DynamicUpdateMapEntry mapEntry = this.CreateMapEntry(currentElement, originalElement); mapEntry.Parent = GetParentEntry(originalElement, this.updateMap); if (this.builder.DisallowUpdateInside.Contains(currentElement)) { mapEntry.IsUpdateBlockedByUpdateAuthor = true; } if (originalElement.GetType() != currentElement.GetType()) { // returned matching activity's type doesn't really match the currentElement BlockUpdate(currentElement, UpdateBlockedReason.TypeChange, mapEntry, SR.DUActivityTypeMismatch(currentElement.GetType(), originalElement.GetType())); } if (this.DelegateArgumentsChanged(currentElement, originalElement)) { this.BlockUpdate(currentElement, UpdateBlockedReason.DelegateArgumentChange, mapEntry); } DynamicUpdateMap implementationMap = null; if (this.builder.LookupImplementationMap != null) { implementationMap = this.builder.LookupImplementationMap(currentElement); } // fill ArgumentEntries // get arguments diff info from implementation map if it exists // we do this before user participation, so that we don't call into user code // if the update is invalid IList oldArguments = GetOriginalArguments(mapEntry, implementationMap, currentElement, originalElement); if (oldArguments != null) { CreateArgumentEntries(mapEntry, currentElement.RuntimeArguments, oldArguments); } // Capture any saved original value associated with this activity by its parent mapEntry.SavedOriginalValueFromParent = GetSavedOriginalValueFromParent(currentElement); if (mapEntry.IsRuntimeUpdateBlocked) { // don't allow activity to participate if update isn't possible anyway mapEntry.EnvironmentUpdateMap = null; return; } OnCreateDynamicUpdateMap(currentElement, originalElement, mapEntry, this.Matcher); if (mapEntry.IsRuntimeUpdateBlocked) { // if the activity disabled update, we can't rely on the variable matches, // so no point in proceeding mapEntry.EnvironmentUpdateMap = null; return; } // variable entries need to be calculated after activity participation, since // the activity can participate in matching them CreateVariableEntries(false, mapEntry, currentElement.RuntimeVariables, originalElement.RuntimeVariables, originalElement); CreateVariableEntries(true, mapEntry, currentElement.ImplementationVariables, originalElement.ImplementationVariables, originalElement); if (mapEntry.HasEnvironmentUpdates) { FillEnvironmentMapMemberCounts(mapEntry.EnvironmentUpdateMap, currentElement, originalElement, oldArguments); } else { Fx.Assert(originalElement.SymbolCount == currentElement.SymbolCount || originalElement.ImplementationVariables.Count != currentElement.ImplementationVariables.Count, "Should have environment update if symbol count changed"); } if (!mapEntry.IsParentRemovedOrBlocked && !mapEntry.IsUpdateBlockedByUpdateAuthor) { NestedIdSpaceFinalizer nestedFinalizer = new NestedIdSpaceFinalizer(this, implementationMap, currentElement, originalElement, null); nestedFinalizer.ValidateOrCreateImplementationMap(mapEntry); } } } internal static void FillEnvironmentMapMemberCounts(EnvironmentUpdateMap envMap, Activity currentElement, Activity originalElement, IList oldArguments) { envMap.NewVariableCount = currentElement.RuntimeVariables != null ? currentElement.RuntimeVariables.Count : 0; envMap.NewPrivateVariableCount = currentElement.ImplementationVariables != null ? currentElement.ImplementationVariables.Count : 0; envMap.NewArgumentCount = currentElement.RuntimeArguments != null ? currentElement.RuntimeArguments.Count : 0; envMap.OldVariableCount = originalElement.RuntimeVariables.Count; envMap.OldPrivateVariableCount = originalElement.ImplementationVariables.Count; envMap.OldArgumentCount = oldArguments != null ? oldArguments.Count : 0; Fx.Assert((originalElement.HandlerOf == null && currentElement.HandlerOf == null) || (originalElement.HandlerOf.RuntimeDelegateArguments.Count == currentElement.HandlerOf.RuntimeDelegateArguments.Count), "RuntimeDelegateArguments count must not have changed."); envMap.RuntimeDelegateArgumentCount = originalElement.HandlerOf == null ? 0 : originalElement.HandlerOf.RuntimeDelegateArguments.Count; } DynamicUpdateMapEntry CreateMapEntry(Activity currentActivity, Activity matchingOriginal) { Fx.Assert(currentActivity != null && matchingOriginal != null, "this entry creation is only for existing activity's ID change."); this.foundOriginalElements[matchingOriginal.InternalId - 1] = true; DynamicUpdateMapEntry entry = new DynamicUpdateMapEntry(matchingOriginal.InternalId, currentActivity.InternalId); this.updateMap.AddEntry(entry); return entry; } internal void OnCreateDynamicUpdateMap(Activity currentElement, Activity originalElement, DynamicUpdateMapEntry mapEntry, IDefinitionMatcher matcher) { this.AllowUpdateInsideCurrentActivity = null; this.UpdateDisallowedReason = null; this.SavedOriginalValuesForCurrentActivity = null; this.savedOriginalValuesForReferencedChildren = false; currentElement.OnInternalCreateDynamicUpdateMap(this, matcher, originalElement); if (this.AllowUpdateInsideCurrentActivity == false) { this.BlockUpdate(currentElement, originalElement.Id, UpdateBlockedReason.Custom, mapEntry, this.UpdateDisallowedReason); } if (this.SavedOriginalValuesForCurrentActivity != null && this.SavedOriginalValuesForCurrentActivity.Count > 0) { mapEntry.SavedOriginalValues = this.SavedOriginalValuesForCurrentActivity; } if (this.savedOriginalValuesForReferencedChildren) { this.BlockUpdate(currentElement, originalElement.Id, UpdateBlockedReason.SavedOriginalValuesForReferencedChildren, mapEntry); } } void CreateVariableEntries(bool forImplementationVariables, DynamicUpdateMapEntry mapEntry, IList newVariables, IList oldVariables, Activity originalElement) { if (newVariables != null && newVariables.Count > 0) { for (int i = 0; i < newVariables.Count; i++) { Variable newVariable = newVariables[i]; int originalIndex = this.Matcher.GetMatchIndex(newVariable, originalElement, forImplementationVariables); if (originalIndex != i) { EnsureEnvironmentUpdateMap(mapEntry); EnvironmentUpdateMapEntry environmentEntry = new EnvironmentUpdateMapEntry { OldOffset = originalIndex, NewOffset = i, }; if (forImplementationVariables) { mapEntry.EnvironmentUpdateMap.PrivateVariableEntries.Add(environmentEntry); } else { mapEntry.EnvironmentUpdateMap.VariableEntries.Add(environmentEntry); } if (originalIndex == EnvironmentUpdateMapEntry.NonExistent) { Activity idleActivity = GetIdleActivity(newVariable.Default); if (idleActivity != null) { // If an variable default expression goes idle, the activity it is declared on can potentially // resume execution before the default expression is evaluated. We can't allow that. this.BlockUpdate(newVariable.Owner, UpdateBlockedReason.AddedIdleExpression, mapEntry, SR.AddedIdleVariableDefaultBlockDU(newVariable.Name, idleActivity)); } else if (newVariable.IsHandle) { this.BlockUpdate(newVariable.Owner, UpdateBlockedReason.NewHandle, mapEntry); } environmentEntry.IsNewHandle = newVariable.IsHandle; } } } } // We don't normally create entries for removals, but we need to ensure that // environment update happens if there are only removals. if (oldVariables != null && (newVariables == null || newVariables.Count < oldVariables.Count)) { EnsureEnvironmentUpdateMap(mapEntry); } } internal void CreateArgumentEntries(DynamicUpdateMapEntry mapEntry, IList newArguments, IList oldArguments) { RuntimeArgument newIdleArgument; Activity idleActivity; if (!CreateArgumentEntries(mapEntry, newArguments, oldArguments, this.expressionRootsThatCanInduceIdle, out newIdleArgument, out idleActivity)) { // If an argument expression goes idle, the activity it is declared on can potentially // resume execution before the argument is evaluated. We can't allow that. this.BlockUpdate(newIdleArgument.Owner, UpdateBlockedReason.AddedIdleExpression, mapEntry, SR.AddedIdleArgumentBlockDU(newIdleArgument.Name, idleActivity)); return; } } // if it detects any added argument whose Expression can induce idle, it returns FALSE along with newIdleArgument and idleActivity. Return true otherwise. internal static bool CreateArgumentEntries(DynamicUpdateMapEntry mapEntry, IList newArguments, IList oldArguments, Dictionary expressionRootsThatCanInduceIdle, out RuntimeArgument newIdleArgument, out Activity idleActivity) { newIdleArgument = null; idleActivity = null; if (newArguments != null && newArguments.Count > 0) { for (int i = 0; i < newArguments.Count; i++) { RuntimeArgument newArgument = newArguments[i]; int oldIndex = oldArguments.IndexOf(new ArgumentInfo(newArgument)); Fx.Assert(oldIndex >= 0 || oldIndex == EnvironmentUpdateMapEntry.NonExistent, "NonExistent constant should be consistent with IndexOf"); if (oldIndex != i) { EnsureEnvironmentUpdateMap(mapEntry); mapEntry.EnvironmentUpdateMap.ArgumentEntries.Add(new EnvironmentUpdateMapEntry { OldOffset = oldIndex, NewOffset = i }); if (oldIndex == EnvironmentUpdateMapEntry.NonExistent && newArgument.IsBound) { Activity expressionRoot = newArgument.BoundArgument.Expression; if (expressionRoot != null && expressionRootsThatCanInduceIdle != null && expressionRootsThatCanInduceIdle.TryGetValue(expressionRoot, out idleActivity)) { newIdleArgument = newArgument; return false; } } } } } // We don't normally create entries for removals, but we need to ensure that // environment update happens if there are only removals. if (oldArguments != null && (newArguments == null || newArguments.Count < oldArguments.Count)) { EnsureEnvironmentUpdateMap(mapEntry); } return true; } IList GetOriginalArguments(DynamicUpdateMapEntry mapEntry, DynamicUpdateMap implementationMap, Activity updatedActivity, Activity originalActivity) { bool argumentsChangedFromImplementationMap = false; if (implementationMap != null && !implementationMap.ArgumentsAreUnknown) { argumentsChangedFromImplementationMap = !ActivityComparer.ListEquals(implementationMap.NewArguments, implementationMap.OldArguments); bool dynamicArgumentsDetected = !ActivityComparer.ListEquals(ArgumentInfo.List(updatedActivity), implementationMap.NewArguments); if (argumentsChangedFromImplementationMap && dynamicArgumentsDetected) { // this is to ensure no dynamic arguments were added, removed or rearranged as the arguments owning activity was being consumed // at the same time the activity has arguments changed from its implementation map. // the list of RuntimeArguments obtained from the configured activity and the list of ArgumentInfos obtained from // the implementation map must match exactly. Otherwise this activity is blocked for update. this.BlockUpdate(updatedActivity, UpdateBlockedReason.DynamicArguments, mapEntry, SR.NoDynamicArgumentsInActivityDefinitionChange); return null; } } return argumentsChangedFromImplementationMap ? implementationMap.OldArguments : ArgumentInfo.List(originalActivity); } Activity GetIdleActivity(Activity expressionRoot) { Activity result = null; if (expressionRoot != null && this.expressionRootsThatCanInduceIdle != null) { this.expressionRootsThatCanInduceIdle.TryGetValue(expressionRoot, out result); } return result; } static void EnsureEnvironmentUpdateMap(DynamicUpdateMapEntry mapEntry) { if (!mapEntry.HasEnvironmentUpdates) { mapEntry.EnvironmentUpdateMap = new EnvironmentUpdateMap(); } } void CheckForReusedActivity(Activity activity) { if (activity.RootActivity != this.builder.OriginalWorkflowDefinition) { throw FxTrace.Exception.AsError(new InvalidWorkflowException(SR.OriginalActivityReusedInModifiedDefinition(activity))); } IList variables = activity.RuntimeVariables; for (int i = 0; i < variables.Count; i++) { if (variables[i].Owner.RootActivity != this.builder.OriginalWorkflowDefinition) { throw FxTrace.Exception.AsError(new InvalidWorkflowException(SR.OriginalVariableReusedInModifiedDefinition(variables[i].Name))); } } } void CheckCanArgumentOrVariableDefaultInduceIdle(ActivityUtilities.ChildActivity childActivity, ActivityUtilities.ActivityCallStack parentChain) { Activity activity = childActivity.Activity; if (!(activity.IsExpressionRoot || activity.RelationshipToParent == Activity.RelationshipType.VariableDefault)) { return; } if (activity.HasNonEmptySubtree) { ActivityUtilities.FinishCachingSubtree( childActivity, parentChain, ProcessTreeOptions(this.builder.ForImplementation), (a, c) => CheckCanActivityInduceIdle(activity, a.Activity)); } else { CheckCanActivityInduceIdle(activity, activity); } } void CheckCanActivityInduceIdle(Activity activity, Activity expressionRoot) { if (activity.InternalCanInduceIdle) { if (this.expressionRootsThatCanInduceIdle == null) { this.expressionRootsThatCanInduceIdle = new Dictionary(ReferenceEqualityComparer.Instance); } if (!this.expressionRootsThatCanInduceIdle.ContainsKey(expressionRoot)) { this.expressionRootsThatCanInduceIdle.Add(expressionRoot, activity); } } } bool DelegateArgumentsChanged(Activity newActivity, Activity oldActivity) { // check DelegateArguments of ActivityDelegate owning the handler if (newActivity.HandlerOf == null) { Fx.Assert(oldActivity.HandlerOf == null, "Once two activities have been matched, either both must be handlers or both must not be handlers."); return false; } Fx.Assert(oldActivity.HandlerOf != null, "Once two activities have been matched, either both must be handlers or both must not be handlers."); return !ActivityComparer.ListEquals(newActivity.HandlerOf.RuntimeDelegateArguments, oldActivity.HandlerOf.RuntimeDelegateArguments); } void ThrowInvalidActivityToBlockUpdate(Activity activity) { Exception exception; if (builder.OnInvalidActivityToBlockUpdate != null) { exception = builder.OnInvalidActivityToBlockUpdate(activity); } else { exception = new InvalidOperationException(SR.InvalidActivityToBlockUpdate(activity)); } throw FxTrace.Exception.AsError(exception); } internal void ThrowInvalidImplementationMapAssociation(Activity activity) { Exception exception; if (builder.OnInvalidImplementationMapAssociation != null) { exception = builder.OnInvalidImplementationMapAssociation(activity); } else { exception = new InvalidOperationException(SR.InvalidImplementationMapAssociation(activity)); } throw FxTrace.Exception.AsError(exception); } } internal interface IDefinitionMatcher { void AddMatch(Activity newChild, Activity oldChild, Activity source); void AddMatch(Variable newVariable, Variable oldVariable, Activity source); Activity GetMatch(Activity newActivity); Variable GetMatch(Variable newVariable); } internal class DefinitionMatcher : IDefinitionMatcher { Dictionary newToOldMatches; Func matchInfoLookup; internal DefinitionMatcher(Func matchInfoLookup) { this.matchInfoLookup = matchInfoLookup; this.newToOldMatches = new Dictionary(ReferenceEqualityComparer.Instance); } internal IdSpace NewIdSpace { get; set; } internal IdSpace OldIdSpace { get; set; } // The following methods are intended to be called by the activity author // (via UpdateMapMetadata), and should validate accordingly public void AddMatch(Activity newChild, Activity oldChild, Activity source) { Fx.Assert(source != null, "source cannot be null."); if (newChild.Parent != source) { throw FxTrace.Exception.Argument("newChild", SR.AddMatchActivityNewParentMismatch( source, newChild, newChild.Parent)); } if (newChild.MemberOf != newChild.Parent.MemberOf) { throw FxTrace.Exception.Argument("newChild", SR.AddMatchActivityPrivateChild(newChild)); } if (oldChild.Parent != null && oldChild.MemberOf != oldChild.Parent.MemberOf) { throw FxTrace.Exception.Argument("oldChild", SR.AddMatchActivityPrivateChild(oldChild)); } if (!ParentsMatch(newChild, oldChild)) { throw FxTrace.Exception.Argument("oldChild", SR.AddMatchActivityNewAndOldParentMismatch( newChild, oldChild, newChild.Parent, oldChild.Parent)); } // Only one updated activity can match a given original activity foreach (Activity newSibling in GetPublicDeclaredChildren(newChild.Parent, true)) { if (GetMatch(newSibling) == oldChild) { this.newToOldMatches[newSibling] = null; break; } } this.newToOldMatches[newChild] = oldChild; } public void AddMatch(Variable newVariable, Variable oldVariable, Activity source) { if (!ActivityComparer.SignatureEquals(newVariable, oldVariable)) { throw FxTrace.Exception.Argument("newVariable", SR.AddMatchVariableSignatureMismatch( source, newVariable.Name, newVariable.Type, newVariable.Modifiers, oldVariable.Name, oldVariable.Type, oldVariable.Modifiers)); } if (newVariable.Owner != source) { throw FxTrace.Exception.Argument("newVariable", SR.AddMatchVariableNewParentMismatch( source, newVariable.Name, newVariable.Owner)); } if (GetMatch(newVariable.Owner) != oldVariable.Owner) { throw FxTrace.Exception.Argument("oldVariable", SR.AddMatchVariableNewAndOldParentMismatch( newVariable.Name, oldVariable.Name, newVariable.Owner, oldVariable.Owner)); } if (!newVariable.IsPublic) { throw FxTrace.Exception.Argument("newVariable", SR.AddMatchVariablePrivateChild(newVariable.Name)); } if (!oldVariable.IsPublic) { throw FxTrace.Exception.Argument("oldVariable", SR.AddMatchVariablePrivateChild(oldVariable.Name)); } // Only one updated variable can match a given original variable foreach (Variable newSibling in newVariable.Owner.RuntimeVariables) { if (GetMatch(newSibling) == oldVariable) { this.newToOldMatches[newSibling] = EnvironmentUpdateMapEntry.NonExistent; break; } } this.newToOldMatches[newVariable] = oldVariable.Owner.RuntimeVariables.IndexOf(oldVariable); } public Activity GetMatch(Activity newChild) { object result; if (this.newToOldMatches.TryGetValue(newChild, out result)) { return (Activity)result; } if (newChild.MemberOf != this.NewIdSpace) { // We can only match the IdSpace being updated. return null; } if (newChild.Origin != null && newChild.RelationshipToParent == Activity.RelationshipType.VariableDefault) { // Auto-generated variable defaults have the same origin as the variable itself, // so the match info comes from the variable. foreach (Variable variable in newChild.Parent.RuntimeVariables) { if (variable.Default == newChild) { Variable originalVariable = GetMatch(variable); if (originalVariable != null && originalVariable.Origin != null) { return originalVariable.Default; } } } return null; } DynamicUpdateMapItem matchInfo = this.matchInfoLookup(newChild.Origin ?? newChild); if (matchInfo == null || matchInfo.IsVariableMapItem) { return null; } Activity originalActivity = this.OldIdSpace[matchInfo.OriginalId]; if (originalActivity != null && ParentsMatch(newChild, originalActivity)) { this.newToOldMatches.Add(newChild, originalActivity); return originalActivity; } else { return null; } } public Variable GetMatch(Variable newVariable) { Activity matchingOwner = GetMatch(newVariable.Owner); if (matchingOwner == null) { return null; } int index = GetMatchIndex(newVariable, matchingOwner, false); if (index >= 0) { return matchingOwner.RuntimeVariables[index]; } return null; } // return -1 if there is no match internal int GetMatchIndex(Variable newVariable, Activity matchingOwner, bool forImplementation) { object result; if (this.newToOldMatches.TryGetValue(newVariable, out result)) { return (int)result; } IList originalVariables; if (forImplementation) { originalVariables = matchingOwner.ImplementationVariables; } else { originalVariables = matchingOwner.RuntimeVariables; } int oldIndex = -1; if (String.IsNullOrEmpty(newVariable.Name)) { if (forImplementation) { // HasPrivateMemberChanged must have detected any presence of nameless private variable in advance. oldIndex = newVariable.Owner.ImplementationVariables.IndexOf(newVariable); } else { // only for those variables without names, we attempt to match by MapItem tag DynamicUpdateMapItem matchInfo = this.matchInfoLookup(newVariable.Origin ?? newVariable); if (matchInfo != null && matchInfo.IsVariableMapItem && matchingOwner.InternalId == matchInfo.OriginalVariableOwnerId) { // "matchingOwner.InternalId != matchInfo.OriginalVariableOwnerId" means the variable has been moved to a different owner, // and it is treated as a new variable addition. oldIndex = matchInfo.OriginalId; } } } else { // named variables are matched by their Name, Type and Modifiers for (int i = 0; i < originalVariables.Count; i++) { if (ActivityComparer.SignatureEquals(newVariable, originalVariables[i])) { // match by sig----ure(Name, Type, Modifier) found oldIndex = i; break; } } } if (oldIndex >= 0 && oldIndex < originalVariables.Count) { this.newToOldMatches.Add(newVariable, oldIndex); return oldIndex; } return EnvironmentUpdateMapEntry.NonExistent; } bool ParentsMatch(Activity currentActivity, Activity originalActivity) { if (currentActivity.Parent == null) { return originalActivity.Parent == null; } else { if (currentActivity.RelationshipToParent != originalActivity.RelationshipToParent || (currentActivity.HandlerOf != null && currentActivity.HandlerOf.ParentCollectionType != originalActivity.HandlerOf.ParentCollectionType)) { return false; } if (currentActivity.Parent == currentActivity.MemberOf.Owner) { return originalActivity.Parent == this.OldIdSpace.Owner; } return originalActivity.Parent != null && GetMatch(currentActivity.Parent) == originalActivity.Parent; } } } internal class NestedIdSpaceFinalizer : IDefinitionMatcher { Finalizer finalizer; DynamicUpdateMap userProvidedMap; DynamicUpdateMap generatedMap; Activity updatedActivity; Activity originalActivity; bool invalidMatchInCurrentActivity; NestedIdSpaceFinalizer parent; public NestedIdSpaceFinalizer(Finalizer finalizer, DynamicUpdateMap implementationMap, Activity updatedActivity, Activity originalActivity, NestedIdSpaceFinalizer parent) { this.finalizer = finalizer; this.userProvidedMap = implementationMap; this.updatedActivity = updatedActivity; this.originalActivity = originalActivity; this.parent = parent; } public void ValidateOrCreateImplementationMap(DynamicUpdateMapEntry mapEntry) { // check applicability of the provided implementation map if (this.userProvidedMap != null) { IdSpace privateIdSpace = updatedActivity.ParentOf; if (privateIdSpace == null) { this.finalizer.ThrowInvalidImplementationMapAssociation(updatedActivity); } if (!this.userProvidedMap.IsNoChanges && privateIdSpace.MemberCount != this.userProvidedMap.NewDefinitionMemberCount) { BlockUpdate(updatedActivity, UpdateBlockedReason.InvalidImplementationMap, mapEntry, SR.InvalidImplementationMap(this.userProvidedMap.NewDefinitionMemberCount, privateIdSpace.MemberCount)); return; } } // The only difference between updatedActivity and originalActivity is changes in the outer IdSpace. // The implementation IdSpace should never change in response to outer IdSpace changes. // The only exception is addition/removal/rearrangement of RuntimeArguments and their Expressions in the private IdSpace for the sake of supporting Receive Content Parameter change. // If any argument change is detected and nothing else changed in the private IdSpace, // HasPrivateMemberOtherThanArgumentsChanged will return FALSE as well as returning a generated implementation Map. // Also, when userProvidedMap exists, we don't allow changes to arguments inside the private IdSpace DynamicUpdateMap argumentChangesMap; if (ActivityComparer.HasPrivateMemberOtherThanArgumentsChanged(this, updatedActivity, originalActivity, this.parent == null, out argumentChangesMap) || (argumentChangesMap != null && this.userProvidedMap != null)) { // either of the following two must have occured here. // A. // members in the private IdSpace(or nested IdSpaces) must have changed. // addition/removal/rearrangement of arguments and their expressions in the private IdSpace are not considered as change. // // B. // addition/removal/rearrangement of arguments or their expressions in the private IdSpace occured and no other members in the private IdSpace(or nested IdSpaces) changed except their id shift. // Due to the id shift caused by argument change, an implementation map("argumentChangesMap") was created. // In addition to "argumentChangesMap", there is also a user provided map. This blocks DU. // generate a warning and block update inside this activity BlockUpdate(updatedActivity, UpdateBlockedReason.PrivateMembersHaveChanged, mapEntry); return; } if (updatedActivity.ParentOf != null) { GenerateMap(argumentChangesMap); if (this.generatedMap == null) { mapEntry.ImplementationUpdateMap = this.userProvidedMap; } else { if (this.userProvidedMap == null || this.userProvidedMap.IsNoChanges) { FillGeneratedMap(); } else { MergeProvidedMapIntoGeneratedMap(); } mapEntry.ImplementationUpdateMap = this.generatedMap; } } } // AddMatch is a no-op, since any matches come from the provided implementation map. // However an invalid match can still cause us to disallow update public void AddMatch(Activity newChild, Activity oldChild, Activity source) { if (newChild.Parent != source || newChild.MemberOf != source.MemberOf || GetMatch(newChild) != oldChild) { this.invalidMatchInCurrentActivity = true; } } public void AddMatch(Variable newVariable, Variable oldVariable, Activity source) { if (newVariable.Owner != source || !newVariable.IsPublic || GetMatch(newVariable) != oldVariable) { this.invalidMatchInCurrentActivity = true; } } public Activity GetMatch(Activity newActivity) { NestedIdSpaceFinalizer owningFinalizer = this; do { // The original definition being updated still needs to reference the updated implementation. // So even if we have a provided impl map, there should be no ID changes between updatedActivity and original activity. if (newActivity.MemberOf == owningFinalizer.updatedActivity.ParentOf) { return owningFinalizer.originalActivity.ParentOf[newActivity.InternalId]; } owningFinalizer = owningFinalizer.parent; } while (owningFinalizer != null); return this.finalizer.Matcher.GetMatch(newActivity); } public Variable GetMatch(Variable newVariable) { Fx.Assert(newVariable.Owner.MemberOf == this.updatedActivity.ParentOf, "Should only call GetMatch for variables owned by the participating activity"); int index = newVariable.Owner.RuntimeVariables.IndexOf(newVariable); if (index >= 0) { Activity matchingOwner = GetMatch(newVariable.Owner); if (matchingOwner != null && matchingOwner.RuntimeVariables.Count > index) { return matchingOwner.RuntimeVariables[index]; } } return null; } public void CreateArgumentEntries(DynamicUpdateMapEntry mapEntry, IList newArguments, IList oldArguments) { RuntimeArgument newIdleArgument; Activity idleActivity; if (!DynamicUpdateMapBuilder.Finalizer.CreateArgumentEntries(mapEntry, newArguments, oldArguments, this.finalizer.ExpressionRootsThatCanInduceIdle, out newIdleArgument, out idleActivity)) { // If an argument expression goes idle, the activity it is declared on can potentially // resume execution before the argument is evaluated. We can't allow that. this.BlockUpdate(newIdleArgument.Owner, UpdateBlockedReason.AddedIdleExpression, mapEntry, SR.AddedIdleArgumentBlockDU(newIdleArgument.Name, idleActivity)); return; } } void BlockUpdate(Activity updatedActivity, UpdateBlockedReason reason, DynamicUpdateMapEntry entry, string message = null) { Activity originalActivity = GetMatch(updatedActivity); Fx.Assert(originalActivity != null, "Cannot block update inside an added activity"); this.finalizer.BlockUpdate(updatedActivity, originalActivity.Id, reason, entry, message); } // This method allows activities in the implementation IdSpace to participate in map creation. // This is necessary because they may need to save original values for properties whose value // may be set by referencing activity properties. (E.g. ) // They may also disable update based on observed property values. However they are not allowed // to change or add any matches, because the implementation IdSpace should not be changing // based on public property changes. // if argumentChangesMap is non-null, it will be used as the initial generatedMap onto which original values are saved. void GenerateMap(DynamicUpdateMap argumentChangesMap) { IdSpace updatedIdSpace = this.updatedActivity.ParentOf; IdSpace originalIdSpace = this.originalActivity.ParentOf; for (int i = 1; i <= updatedIdSpace.MemberCount; i++) { DynamicUpdateMapEntry providedEntry = null; if (this.userProvidedMap != null && !this.userProvidedMap.IsNoChanges) { bool isNewlyAdded = !this.userProvidedMap.TryGetUpdateEntryByNewId(i, out providedEntry); if (isNewlyAdded || providedEntry.IsRuntimeUpdateBlocked || providedEntry.IsUpdateBlockedByUpdateAuthor || providedEntry.IsParentRemovedOrBlocked) { // No need to save original values or block update continue; } } DynamicUpdateMapEntry argumentChangesMapEntry = null; if (argumentChangesMap != null) { Fx.Assert(!argumentChangesMap.IsNoChanges, "argumentChangesMap will never be NoChanges map because it is automatically created only when there is argument changes."); bool isNewlyAdded = !argumentChangesMap.TryGetUpdateEntryByNewId(i, out argumentChangesMapEntry); if (isNewlyAdded) { // No need to save original values or block update continue; } } // We only need to save this map entry if it has some non-default value. DynamicUpdateMapEntry generatedEntry = GenerateEntry(argumentChangesMapEntry, providedEntry, i); DynamicUpdateMap providedImplementationMap = providedEntry != null ? providedEntry.ImplementationUpdateMap : null; if (generatedEntry.IsRuntimeUpdateBlocked || generatedEntry.SavedOriginalValues != null || generatedEntry.SavedOriginalValueFromParent != null || generatedEntry.ImplementationUpdateMap != providedImplementationMap || generatedEntry.IsIdChange || generatedEntry.HasEnvironmentUpdates) { EnsureGeneratedMap(); this.generatedMap.AddEntry(generatedEntry); } } if (argumentChangesMap != null && argumentChangesMap.entries != null) { // add all IsRemoved entries foreach (DynamicUpdateMapEntry entry in argumentChangesMap.entries) { if (entry.IsRemoval) { EnsureGeneratedMap(); this.generatedMap.AddEntry(entry); } } } } void EnsureGeneratedMap() { if (this.generatedMap == null) { this.generatedMap = new DynamicUpdateMap { IsForImplementation = true, NewDefinitionMemberCount = this.updatedActivity.ParentOf.MemberCount }; } } DynamicUpdateMapEntry GenerateEntry(DynamicUpdateMapEntry argumentChangesMapEntry, DynamicUpdateMapEntry providedEntry, int id) { DynamicUpdateMapEntry generatedEntry; Activity updatedChild; Activity originalChild; // argumentChangesMapEntry and providedEntry are mutually exclusive. // both cannot be non-null at the same time although both may be null at the same time. if (argumentChangesMapEntry == null) { int originalIndex = providedEntry != null ? providedEntry.OldActivityId : id; generatedEntry = new DynamicUpdateMapEntry(originalIndex, id); // we assume nothing has changed in the private IdSpace updatedChild = this.updatedActivity.ParentOf[id]; originalChild = this.originalActivity.ParentOf[id]; } else { generatedEntry = argumentChangesMapEntry; // activity IDs in the private IdSpace has changed due to arguments change inside the private IdSpace updatedChild = this.updatedActivity.ParentOf[argumentChangesMapEntry.NewActivityId]; originalChild = this.originalActivity.ParentOf[argumentChangesMapEntry.OldActivityId]; } // Allow the activity to participate this.invalidMatchInCurrentActivity = false; this.finalizer.OnCreateDynamicUpdateMap(updatedChild, originalChild, generatedEntry, this); if (this.invalidMatchInCurrentActivity && !generatedEntry.IsRuntimeUpdateBlocked) { BlockUpdate(updatedChild, UpdateBlockedReason.ChangeMatchesInImplementation, generatedEntry); } // Fill in the rest of the map entry; generatedEntry.SavedOriginalValueFromParent = this.finalizer.GetSavedOriginalValueFromParent(updatedChild); DynamicUpdateMap childImplementationMap = providedEntry != null ? providedEntry.ImplementationUpdateMap : null; if (!generatedEntry.IsRuntimeUpdateBlocked) { NestedIdSpaceFinalizer nestedFinalizer = new NestedIdSpaceFinalizer(this.finalizer, childImplementationMap, updatedChild, originalChild, this); nestedFinalizer.ValidateOrCreateImplementationMap(generatedEntry); } return generatedEntry; } // The generated map only contains entries that have some non-default value. For it to be a valid // implementation map, we need to fill in all the unchanged entries. void FillGeneratedMap() { Fx.Assert(this.generatedMap != null, "If there were no generated entries then we don't need a generated map."); this.generatedMap.ArgumentsAreUnknown = true; for (int i = 1; i <= this.originalActivity.ParentOf.MemberCount; i++) { DynamicUpdateMapEntry entry; if (!this.generatedMap.TryGetUpdateEntry(i, out entry)) { entry = new DynamicUpdateMapEntry(i, i); this.generatedMap.AddEntry(entry); } entry.Parent = GetParentEntry(this.originalActivity.ParentOf[i], this.generatedMap); } } void MergeProvidedMapIntoGeneratedMap() { this.generatedMap.OldArguments = this.userProvidedMap.OldArguments; this.generatedMap.NewArguments = this.userProvidedMap.NewArguments; for (int i = 1; i <= this.userProvidedMap.OldDefinitionMemberCount; i++) { // Get/create the matching generated entry DynamicUpdateMapEntry providedEntry; this.userProvidedMap.TryGetUpdateEntry(i, out providedEntry); DynamicUpdateMapEntry generatedEntry = GetOrCreateGeneratedEntry(providedEntry); if (generatedEntry.IsRemoval || generatedEntry.IsRuntimeUpdateBlocked || generatedEntry.IsUpdateBlockedByUpdateAuthor || generatedEntry.IsParentRemovedOrBlocked) { continue; } // Disable update if there's a conflict int newActivityId = providedEntry.NewActivityId; if (HasOverlap(providedEntry.SavedOriginalValues, generatedEntry.SavedOriginalValues) || (HasSavedOriginalValuesForChildren(newActivityId, this.userProvidedMap) && HasSavedOriginalValuesForChildren(newActivityId, this.generatedMap))) { Activity updatedChild = this.updatedActivity.ParentOf[generatedEntry.NewActivityId]; BlockUpdate(updatedChild, UpdateBlockedReason.GeneratedAndProvidedMapConflict, generatedEntry, SR.GeneratedAndProvidedMapConflict); } else { generatedEntry.SavedOriginalValues = DynamicUpdateMapEntry.Merge(generatedEntry.SavedOriginalValues, providedEntry.SavedOriginalValues); } } } DynamicUpdateMapEntry GetOrCreateGeneratedEntry(DynamicUpdateMapEntry providedEntry) { // Get or create the matching entry DynamicUpdateMapEntry generatedEntry; if (!this.generatedMap.TryGetUpdateEntry(providedEntry.OldActivityId, out generatedEntry)) { generatedEntry = new DynamicUpdateMapEntry(providedEntry.OldActivityId, providedEntry.NewActivityId) { DisplayName = providedEntry.DisplayName, BlockReason = providedEntry.BlockReason, BlockReasonMessage = providedEntry.BlockReasonMessage, IsUpdateBlockedByUpdateAuthor = providedEntry.IsUpdateBlockedByUpdateAuthor, }; this.generatedMap.AddEntry(generatedEntry); } else { Fx.Assert(providedEntry.NewActivityId == generatedEntry.NewActivityId && providedEntry.DisplayName == generatedEntry.DisplayName && !providedEntry.IsRuntimeUpdateBlocked && !providedEntry.IsUpdateBlockedByUpdateAuthor, "GeneratedEntry should be created with correct ID, and should not be created for an entry that has blocked update"); } // Copy/fill additional values generatedEntry.EnvironmentUpdateMap = providedEntry.EnvironmentUpdateMap; if (providedEntry.Parent != null) { DynamicUpdateMapEntry parentEntry; this.generatedMap.TryGetUpdateEntry(providedEntry.Parent.OldActivityId, out parentEntry); Fx.Assert(parentEntry != null, "We process in IdSpace order, so we always process parents before their children"); generatedEntry.Parent = parentEntry; } if (generatedEntry.SavedOriginalValueFromParent == null) { generatedEntry.SavedOriginalValueFromParent = providedEntry.SavedOriginalValueFromParent; } if (generatedEntry.ImplementationUpdateMap == null) { generatedEntry.ImplementationUpdateMap = providedEntry.ImplementationUpdateMap; } return generatedEntry; } bool HasOverlap(IDictionary providedValues, IDictionary generatedValues) { return providedValues != null && generatedValues != null && providedValues.Keys.Any(k => generatedValues.ContainsKey(k)); } bool HasSavedOriginalValuesForChildren(int parentNewActivityId, DynamicUpdateMap map) { foreach (Activity child in GetPublicDeclaredChildren(this.updatedActivity.ParentOf[parentNewActivityId], false)) { DynamicUpdateMapEntry childEntry; if (map.TryGetUpdateEntryByNewId(child.InternalId, out childEntry) && childEntry.SavedOriginalValueFromParent != null) { return true; } } return false; } } } }