NodeInfo.cs source code in C# .NET

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Code:

/ 4.0 / 4.0 / untmp / DEVDIV_TFS / Dev10 / Releases / RTMRel / ndp / fx / src / DataEntity / System / Data / Query / InternalTrees / NodeInfo.cs / 1305376 / NodeInfo.cs

                            //---------------------------------------------------------------------- 
// 
//      Copyright (c) Microsoft Corporation.  All rights reserved.
// 
// 
// @owner  [....]
// @backupOwner [....] 
//--------------------------------------------------------------------- 

using System; 
using System.Collections.Generic;
using System.Globalization;
using System.Diagnostics;
using System.Data.Common; 
using md=System.Data.Metadata.Edm;
 
namespace System.Data.Query.InternalTrees 
{
    ///  
    /// The KeySet class encapsulates all information about the keys of a RelOp node in
    /// the query tree.
    /// A KeyVec is logically a set of vars that uniquely identify the row of the current
    /// RelOp. Some RelOps may have no unique keys - such a state is identified by the 
    /// "NoKeys" property
    ///  
    internal class KeyVec 
    {
        #region private state 
        private VarVec m_keys;
        private bool m_noKeys;
        #endregion
 
        #region constructors
        internal KeyVec(Command itree) 
        { 
            m_keys = itree.CreateVarVec();
            m_noKeys = true; 
        }
        #endregion

        internal void InitFrom(KeyVec keyset) 
        {
            m_keys.InitFrom(keyset.m_keys); 
            m_noKeys = keyset.m_noKeys; 
        }
 
        internal void InitFrom(IEnumerable varSet)
        {
            InitFrom(varSet, false);
        } 

        internal void InitFrom(IEnumerable varSet, bool ignoreParameters) 
        { 
            m_keys.InitFrom(varSet, ignoreParameters);
            // Bug 434541: An empty set of keys is not the same as "no" keys. 
            // Caveat Emptor
            m_noKeys = false;
        }
        internal void InitFrom(KeyVec left, KeyVec right) 
        {
            if (left.m_noKeys || right.m_noKeys) 
            { 
                m_noKeys = true;
            } 
            else
            {
                m_noKeys = false;
                m_keys.InitFrom(left.m_keys); 
                m_keys.Or(right.m_keys);
            } 
        } 
        internal void InitFrom(List keyVecList)
        { 
            m_noKeys = false;
            m_keys.Clear();
            foreach (KeyVec keyVec in keyVecList)
            { 
                if (keyVec.m_noKeys)
                { 
                    m_noKeys = true; 
                    return;
                } 
                m_keys.Or(keyVec.m_keys);
            }
        }
        internal void Clear() 
        {
            m_noKeys = true; 
            m_keys.Clear(); 
        }
 
        internal VarVec KeyVars { get { return m_keys; } }
        internal bool NoKeys { get { return m_noKeys; } set { m_noKeys = value; } }
    }
 
    /// 
    /// The NodeInfo class represents additional information about a node in the tree. 
    /// By default, this includes a set of external references for each node (ie) references 
    /// to Vars that are not defined in the same subtree
    /// The NodeInfo class also includes a "hashValue" that is a hash value for the entire 
    /// subtree rooted at this node
    /// NOTE: When adding a new member to track inforation, make sure to update the Clear method
    /// in this class to set that member to the default value.
    ///  
    internal class NodeInfo
    { 
        #region private state 
        private VarVec m_externalReferences;
        protected int m_hashValue; // hash value for the node 
        #endregion

        #region constructors
        internal NodeInfo(Command cmd) 
        {
            m_externalReferences = cmd.CreateVarVec(); 
        } 
        #endregion
 
        #region public methods
        /// 
        /// Clear out all information - usually used by a Recompute
        ///  
        internal virtual void Clear()
        { 
            m_externalReferences.Clear(); 
            m_hashValue = 0;
        } 

        /// 
        /// All external references from this node
        ///  
        internal VarVec ExternalReferences
        { 
            get { return m_externalReferences; } 
        }
 
        /// 
        /// Get the hash value for this nodeInfo
        /// 
        internal int HashValue 
        {
            get { return m_hashValue; } 
        } 

        ///  
        /// Compute the hash value for a Vec
        /// 
        /// 
        ///  
        internal static int GetHashValue(VarVec vec)
        { 
            int hashValue = 0; 
            foreach (Var v in vec)
            { 
                hashValue ^= v.GetHashCode();
            }
            return hashValue;
        } 

        ///  
        /// Computes the hash value for this node. The hash value is simply the 
        /// local hash value for this node info added with the hash values of the child
        /// nodes 
        /// 
        /// current command
        /// current node
        internal virtual void ComputeHashValue(Command cmd, Node n) 
        {
            m_hashValue = 0; 
            foreach (Node chi in n.Children) 
            {
                NodeInfo chiNodeInfo = cmd.GetNodeInfo(chi); 
                m_hashValue ^= chiNodeInfo.HashValue;
            }

            m_hashValue = (m_hashValue << 4) ^ ((int)n.Op.OpType); // include the optype somehow 
            // Now compute my local hash value
            m_hashValue = (m_hashValue << 4) ^ GetHashValue(m_externalReferences); 
        } 
        #endregion
    } 

    /// 
    /// Enum describing row counts
    ///  
    internal enum RowCount : byte
    { 
        ///  
        /// Zero rows
        ///  
        Zero = 0,

        /// 
        /// One row 
        /// 
        One = 1, 
 
        /// 
        /// Unbounded (unknown number of rows) 
        /// 
        Unbounded = 2,
    }
 
    /// 
    /// An ExtendedNodeInfo class adds additional information to a standard NodeInfo. 
    /// This class is usually applicable only to RelOps and PhysicalOps. 
    /// The ExtendedNodeInfo class has in addition to the information maintained by NodeInfo
    /// the following 
    /// - a set of local definitions
    /// - a set of definitions
    /// - a set of keys
    /// - a set of non-nullable definitions 
    /// - a set of non-nullable definitions that are visible at this node
    /// NOTE: When adding a new member to track inforation, make sure to update the Clear method 
    /// in this class to set that member to the default value. 
    /// 
    internal class ExtendedNodeInfo : NodeInfo 
    {
        #region private
        private VarVec m_localDefinitions;
        private VarVec m_definitions; 
        private KeyVec m_keys;
        private VarVec m_nonNullableDefinitions; 
        private VarVec m_nonNullableVisibleDefinitions; 
        private RowCount m_minRows;
        private RowCount m_maxRows; 
        #endregion

        #region constructors
        internal ExtendedNodeInfo(Command cmd) 
            : base(cmd)
        { 
            m_localDefinitions = cmd.CreateVarVec(); 
            m_definitions = cmd.CreateVarVec();
            m_nonNullableDefinitions = cmd.CreateVarVec(); 
            m_nonNullableVisibleDefinitions = cmd.CreateVarVec();
            m_keys = new KeyVec(cmd);
            m_minRows = RowCount.Zero;
            m_maxRows = RowCount.Unbounded; 
        }
        #endregion 
 
        #region public methods
 
        internal override void Clear()
        {
            base.Clear();
            m_definitions.Clear(); 
            m_localDefinitions.Clear();
            m_nonNullableDefinitions.Clear(); 
            m_nonNullableVisibleDefinitions.Clear(); 
            m_keys.Clear();
            m_minRows = RowCount.Zero; 
            m_maxRows = RowCount.Unbounded;
        }

        ///  
        /// Compute the hash value for this node
        ///  
        ///  
        /// 
        internal override void ComputeHashValue(Command cmd, Node n) 
        {
            base.ComputeHashValue(cmd, n);
            m_hashValue = (m_hashValue << 4) ^ NodeInfo.GetHashValue(this.Definitions);
            m_hashValue = (m_hashValue << 4) ^ NodeInfo.GetHashValue(this.Keys.KeyVars); 
            return;
        } 
 
        /// 
        /// Definitions made specifically by this node 
        /// 
        internal VarVec LocalDefinitions { get { return m_localDefinitions; } }
        /// 
        /// All definitions visible as outputs of this node 
        /// 
        internal VarVec Definitions { get { return m_definitions; } } 
        ///  
        /// The keys for this node
        ///  
        internal KeyVec Keys { get { return m_keys; } }
        /// 
        /// The definitions of vars that are guaranteed to be non-nullable when output from this node
        ///  
        internal VarVec NonNullableDefinitions { get { return m_nonNullableDefinitions; } }
        ///  
        /// The definitions that come from the rel-op inputs of this node that are guaranteed to be non-nullable 
        /// 
        internal VarVec NonNullableVisibleDefinitions { get { return m_nonNullableVisibleDefinitions; } } 
        /// 
        /// Min number of rows returned from this node
        /// 
        internal RowCount MinRows 
        {
            get { return m_minRows; } 
            set { m_minRows = value; ValidateRowCount(); } 
        }
        ///  
        /// Max rows returned from this node
        /// 
        internal RowCount MaxRows
        { 
            get { return m_maxRows; }
            set { m_maxRows = value; ValidateRowCount(); } 
        } 

        ///  
        /// Set the rowcount for this node
        /// 
        /// min rows produced by this node
        /// max rows produced by this node 
        internal void SetRowCount(RowCount minRows, RowCount maxRows)
        { 
            m_minRows = minRows; 
            m_maxRows = maxRows;
            ValidateRowCount(); 
        }

        /// 
        /// Initialize the rowcounts for this node from the source node 
        /// 
        /// nodeinfo of source 
        internal void InitRowCountFrom(ExtendedNodeInfo source) 
        {
            m_minRows = source.m_minRows; 
            m_maxRows = source.m_maxRows;
        }

        #endregion 

        #region private methods 
        private void ValidateRowCount() 
        {
            Debug.Assert(m_maxRows >= m_minRows, "MaxRows less than MinRows?"); 
        }
        #endregion
    }
 
    /// 
    /// The NodeInfoVisitor is a simple class (ab)using the Visitor pattern to define 
    /// NodeInfo semantics for various nodes in the tree 
    /// 
    internal class NodeInfoVisitor : BasicOpVisitorOfT 
    {
        #region public methods
        /// 
        /// The only public method. Recomputes the nodeInfo for a node in the tree, 
        /// but only if the node info has already been computed.
        /// Assumes that the NodeInfo for each child (if computed already) is valid 
        ///  
        /// Node to get NodeInfo for
        internal void RecomputeNodeInfo(Node n) 
        {
            if (n.IsNodeInfoInitialized)
            {
                NodeInfo nodeInfo = VisitNode(n); 
                nodeInfo.ComputeHashValue(this.m_command, n); // compute the hash value for this node
            } 
        } 
        #endregion
 
        #region constructors
        /// 
        /// Basic constructor
        ///  
        /// 
        internal NodeInfoVisitor(Command command) 
        { 
            m_command = command;
        } 
        #endregion

        #region private state
        private Command m_command; 
        #endregion
 
        #region private methods 
        private NodeInfo GetNodeInfo(Node n)
        { 
            return n.GetNodeInfo(m_command);
        }
        private ExtendedNodeInfo GetExtendedNodeInfo(Node n)
        { 
            return n.GetExtendedNodeInfo(m_command);
        } 
        private NodeInfo InitNodeInfo(Node n) 
        {
            NodeInfo nodeInfo = GetNodeInfo(n); 
            nodeInfo.Clear();
            return nodeInfo;
        }
        private ExtendedNodeInfo InitExtendedNodeInfo(Node n) 
        {
            ExtendedNodeInfo nodeInfo = GetExtendedNodeInfo(n); 
            nodeInfo.Clear(); 
            return nodeInfo;
        } 
        #endregion

        #region VisitorHelpers
        ///  
        /// Default implementation for scalarOps. Simply adds up external references
        /// from each child 
        ///  
        /// 
        ///  
        protected override NodeInfo VisitDefault(Node n)
        {
            Debug.Assert(n.Op.IsScalarOp || n.Op.IsAncillaryOp, "not a supported optype");
 
            NodeInfo nodeInfo = InitNodeInfo(n);
            // My external references are simply the combination of external references 
            // of all my children 
            foreach (Node chi in n.Children)
            { 
                NodeInfo childNodeInfo = GetNodeInfo(chi);
                nodeInfo.ExternalReferences.Or(childNodeInfo.ExternalReferences);
            }
            return nodeInfo; 
        }
 
        ///  
        /// The given definition is non nullable if it is a non-null constant
        /// or a reference to non-nullable input 
        /// 
        /// 
        /// 
        ///  
        private bool IsDefinitionNonNullable(Node definition, VarVec nonNullableInputs)
        { 
            return (definition.Op.OpType == OpType.Constant 
                || definition.Op.OpType == OpType.InternalConstant
                || definition.Op.OpType == OpType.NullSentinel 
                || definition.Op.OpType == OpType.VarRef
                    && nonNullableInputs.IsSet(((VarRefOp)definition.Op).Var));
        }
        #endregion 

        #region IOpVisitor Members 
 
        #region MiscOps
        #endregion 

        #region AncillarOps
        #endregion
 
        #region ScalarOps
        ///  
        /// The only special case among all scalar and ancillaryOps. Simply adds 
        /// its var to the list of unreferenced Ops
        ///  
        /// The VarRefOp
        /// Current node
        /// 
        public override NodeInfo Visit(VarRefOp op, Node n) 
        {
            NodeInfo nodeInfo = InitNodeInfo(n); 
            nodeInfo.ExternalReferences.Set(op.Var); 
            return nodeInfo;
        } 

        #endregion

        #region RelOps 
        protected override NodeInfo VisitRelOpDefault(RelOp op, Node n)
        { 
            return Unimplemented(n); 
        }
 
        /// 
        /// Definitions = Local Definitions = referenced table columns
        /// External References = none
        /// Keys = keys of entity type 
        /// RowCount (default): MinRows = 0, MaxRows = *
        /// NonNullableDefinitions : non nullable table columns that are definitions 
        /// NonNullableInputDefinitions : default(empty) because cannot be used 
        /// 
        /// ScanTable/ScanView op 
        /// current subtree
        /// nodeinfo for this subtree
        protected override NodeInfo VisitTableOp(ScanTableBaseOp op, Node n)
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
            // #479372 - only the "referenced" columns of the table should 
            // show up in the definitions 
            nodeInfo.LocalDefinitions.Or(op.Table.ReferencedColumns);
            nodeInfo.Definitions.Or(op.Table.ReferencedColumns); 

            // get table's keys - but only if the key columns have been referenced
            if (op.Table.ReferencedColumns.Subsumes(op.Table.Keys))
            { 
                nodeInfo.Keys.InitFrom(op.Table.Keys);
            } 
            // no external references 

            //non-nullable definitions 
            nodeInfo.NonNullableDefinitions.Or(op.Table.NonNullableColumns);
            nodeInfo.NonNullableDefinitions.And(nodeInfo.Definitions);

            return nodeInfo; 
        }
 
        ///  
        /// Computes a NodeInfo for an UnnestOp.
        /// Definitions = columns of the table produced by this Op 
        /// Keys = none
        /// External References = the unnestVar + any external references of the
        ///   computed Var (if any)
        /// RowCount (default): MinRows = 0; MaxRows = * 
        /// NonNullableDefinitions: default(empty)
        /// NonNullableInputDefinitions : default(empty) because cannot be used 
        ///  
        /// 
        ///  
        /// 
        public override NodeInfo Visit(UnnestOp op, Node n)
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 
            foreach (Var v in op.Table.Columns)
            { 
                nodeInfo.LocalDefinitions.Set(v); 
                nodeInfo.Definitions.Set(v);
            } 
            // no keys

            // If I have a child, then my external references are my child's external references.
            // Otherwise, my external reference is my unnestVar 
            if (n.HasChild0)
            { 
                NodeInfo childNodeInfo = GetNodeInfo(n.Child0); 
                nodeInfo.ExternalReferences.Or(childNodeInfo.ExternalReferences);
            } 
            else
            {
                nodeInfo.ExternalReferences.Set(op.Var);
            } 

            return nodeInfo; 
        } 

        ///  
        /// Walk through the computed vars defined by a VarDefListNode, and look for
        /// "simple" Var renames. Build up a mapping from original Vars to the renamed Vars
        /// 
        /// the varDefListNode subtree 
        /// A dictionary of Var->Var renames
        internal static Dictionary ComputeVarRemappings(Node varDefListNode) 
        { 
            Debug.Assert(varDefListNode.Op.OpType == OpType.VarDefList);
 
            Dictionary varMap = new Dictionary();
            foreach (Node varDefNode in varDefListNode.Children)
            {
                VarRefOp varRefOp = varDefNode.Child0.Op as VarRefOp; 
                if (varRefOp != null)
                { 
                    VarDefOp varDefOp = varDefNode.Op as VarDefOp; 
                    Debug.Assert(varDefOp != null);
                    varMap[varRefOp.Var] = varDefOp.Var; 
                }
            }
            return varMap;
        } 

        ///  
        /// Computes a NodeInfo for a ProjectOp. 
        /// Definitions = the Vars property of this Op
        /// LocalDefinitions = list of computed Vars produced by this node 
        /// Keys = Keys of the input Relop (if they are all preserved)
        /// External References = any external references from the computed Vars
        /// RowCount = Input's RowCount
        /// NonNullabeDefinitions = Outputs that are either among the NonNullableDefinitions of the child or 
        ///                         are constants defined on this node
        /// NonNullableInputDefinitions = NonNullableDefinitions of the child 
        ///  
        /// The ProjectOp
        /// corresponding Node 
        /// 
        public override NodeInfo Visit(ProjectOp op, Node n)
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 

            // Walk through my outputs and identify my "real" definitions 
            ExtendedNodeInfo relOpChildNodeInfo = GetExtendedNodeInfo(n.Child0); 
            // In the first pass, only definitions of the child are considered
            // to be definitions - everything else is an external reference 
            foreach (Var v in op.Outputs)
            {
                if (relOpChildNodeInfo.Definitions.IsSet(v))
                { 
                    nodeInfo.Definitions.Set(v);
                } 
                else 
                {
                    nodeInfo.ExternalReferences.Set(v); 
                }
            }

            //Nonnullable definitions 
            nodeInfo.NonNullableDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions);
            nodeInfo.NonNullableDefinitions.And(op.Outputs); 
            nodeInfo.NonNullableVisibleDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions); 

            // Local definitions 
            foreach (Node chi in n.Child1.Children)
            {
                VarDefOp varDefOp = chi.Op as VarDefOp;
                NodeInfo chiNodeInfo = GetNodeInfo(chi.Child0); 
                nodeInfo.LocalDefinitions.Set(varDefOp.Var);
                nodeInfo.ExternalReferences.Clear(varDefOp.Var); 
                nodeInfo.Definitions.Set(varDefOp.Var); 
                nodeInfo.ExternalReferences.Or(chiNodeInfo.ExternalReferences);
 
                if (IsDefinitionNonNullable(chi.Child0, nodeInfo.NonNullableVisibleDefinitions))
                {
                    nodeInfo.NonNullableDefinitions.Set(varDefOp.Var);
                } 
            }
            nodeInfo.ExternalReferences.Minus(relOpChildNodeInfo.Definitions); 
            nodeInfo.ExternalReferences.Or(relOpChildNodeInfo.ExternalReferences); 

            // Get the set of keys - simply the list of my child's keys, unless 
            // they're not all defined
            nodeInfo.Keys.NoKeys = true;
            if (!relOpChildNodeInfo.Keys.NoKeys)
            { 
                // Check to see if any of my child's keys have been left by the wayside
                // in that case, mark this node as having no keys 
                VarVec keyVec = m_command.CreateVarVec(relOpChildNodeInfo.Keys.KeyVars); 
                Dictionary varRenameMap = ComputeVarRemappings(n.Child1);
                VarVec mappedKeyVec = keyVec.Remap(varRenameMap); 
                VarVec mappedKeyVecClone = mappedKeyVec.Clone();
                VarVec opVars = m_command.CreateVarVec(op.Outputs);
                mappedKeyVec.Minus(opVars);
                if (mappedKeyVec.IsEmpty) 
                {
                    nodeInfo.Keys.InitFrom(mappedKeyVecClone); 
                } 
            }
 
            nodeInfo.InitRowCountFrom(relOpChildNodeInfo);
            return nodeInfo;
        }
 
        /// 
        /// Computes a NodeInfo for a FilterOp. 
        /// Definitions = Definitions of the input Relop 
        /// LocalDefinitions = None
        /// Keys = Keys of the input Relop 
        /// External References = any external references from the input + any external
        ///    references from the predicate
        /// MaxOneRow = Input's RowCount
        ///    If the predicate is a "false" predicate, then max RowCount is zero 
        ///    If we can infer additional info from the key-selector, we may be
        ///     able to get better estimates 
        /// NonNullabeDefinitions = NonNullabeDefinitions of the input RelOp 
        /// NonNullableInputDefinitions = NonNullabeDefinitions of the input RelOp
        ///  
        /// The FilterOp
        /// corresponding Node
        /// 
        public override NodeInfo Visit(FilterOp op, Node n) 
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 
            ExtendedNodeInfo relOpChildNodeInfo = GetExtendedNodeInfo(n.Child0); 
            NodeInfo predNodeInfo = GetNodeInfo(n.Child1);
 
            // definitions are my child's definitions
            nodeInfo.Definitions.Or(relOpChildNodeInfo.Definitions);
            // No local definitions
 
            // My external references are my child's external references + those made
            // by my predicate 
            nodeInfo.ExternalReferences.Or(relOpChildNodeInfo.ExternalReferences); 
            nodeInfo.ExternalReferences.Or(predNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Minus(relOpChildNodeInfo.Definitions); 

            // my keys are my child's keys
            nodeInfo.Keys.InitFrom(relOpChildNodeInfo.Keys);
 
            //The non-nullable definitions are same as these of the child
            nodeInfo.NonNullableDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions); 
            nodeInfo.NonNullableVisibleDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions); 

            // inherit max RowCount from child; set min RowCount to 0, because 
            // we require way more analysis to do anything smarter
            nodeInfo.MinRows = RowCount.Zero;
            // If the predicate is a "false" predicate, then we know that MaxRows
            // is zero as well 
            ConstantPredicateOp predicate = n.Child1.Op as ConstantPredicateOp;
            if (predicate != null && predicate.IsFalse) 
            { 
                nodeInfo.MaxRows = RowCount.Zero;
            } 
            else
            {
                nodeInfo.MaxRows = relOpChildNodeInfo.MaxRows;
            } 
            return nodeInfo;
        } 
 
        /// 
        /// Computes a NodeInfo for a GroupByOp. 
        /// Definitions = Keys + aggregates
        /// LocalDefinitions = Keys + Aggregates
        /// Keys = GroupBy Keys
        /// External References = any external references from the input + any external 
        ///    references from the local computed Vars
        /// RowCount = 
        ///          (1,1) if no group-by keys; 
        ///          otherwise if input MinRows is 1 then (1, input MaxRows);
        ///          otherwise (0, input MaxRows) 
        /// NonNullableDefinitions: non-nullable keys
        /// NonNullableInputDefinitions : default(empty)
        /// 
        /// The GroupByOp 
        /// corresponding Node
        ///  
        protected override NodeInfo VisitGroupByOp(GroupByBaseOp op, Node n) 
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 
            ExtendedNodeInfo relOpChildNodeInfo = GetExtendedNodeInfo(n.Child0);

            // all definitions are my outputs
            nodeInfo.Definitions.InitFrom(op.Outputs); 
            nodeInfo.LocalDefinitions.InitFrom(nodeInfo.Definitions);
            // my definitions are the keys and aggregates I define myself 
 
            // My references are my child's external references + those made
            // by my keys and my aggregates 
            nodeInfo.ExternalReferences.Or(relOpChildNodeInfo.ExternalReferences);
            foreach (Node chi in n.Child1.Children)
            {
                NodeInfo keyExprNodeInfo = GetNodeInfo(chi.Child0); 
                nodeInfo.ExternalReferences.Or(keyExprNodeInfo.ExternalReferences);
                if (IsDefinitionNonNullable(chi.Child0, relOpChildNodeInfo.NonNullableDefinitions)) 
                { 
                    nodeInfo.NonNullableDefinitions.Set(((VarDefOp)chi.Op).Var);
                } 
            }

            // Non-nullable definitions: also all the keys that come from the input
            nodeInfo.NonNullableDefinitions.Or(relOpChildNodeInfo.NonNullableDefinitions); 
            nodeInfo.NonNullableDefinitions.And(op.Keys);
 
            //Handle all aggregates 
            for (int i = 2; i < n.Children.Count; i++)
            { 
                foreach (Node chi in n.Children[i].Children)
                {
                    NodeInfo aggExprNodeInfo = GetNodeInfo(chi.Child0);
                    nodeInfo.ExternalReferences.Or(aggExprNodeInfo.ExternalReferences); 
                }
            } 
 
            // eliminate definitions of my input
            nodeInfo.ExternalReferences.Minus(relOpChildNodeInfo.Definitions); 

            // my keys are my grouping keys
            nodeInfo.Keys.InitFrom(op.Keys);
 
            // row counts
            nodeInfo.MinRows = op.Keys.IsEmpty ? RowCount.One : (relOpChildNodeInfo.MinRows == RowCount.One ? RowCount.One : RowCount.Zero); 
            nodeInfo.MaxRows = op.Keys.IsEmpty ? RowCount.One : relOpChildNodeInfo.MaxRows; 

            return nodeInfo; 
        }

        /// 
        /// Computes a NodeInfo for a CrossJoinOp. 
        /// Definitions = Definitions of my children
        /// LocalDefinitions = None 
        /// Keys = Concatenation of the keys of my children (if every one of them has keys; otherwise, null) 
        /// External References = any external references from the inputs
        /// RowCount: MinRows: min(min-rows of each child) 
        ///              MaxRows: max(max-rows of each child)
        /// NonNullableDefinitions : The NonNullableDefinitions of the children
        /// NonNullableInputDefinitions : default(empty) because cannot be used
        ///  
        /// The CrossJoinOp
        /// corresponding Node 
        ///  
        public override NodeInfo Visit(CrossJoinOp op, Node n)
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);

            // No definitions of my own. Simply inherit from my children
            // My external references are the union of my children's external 
            // references
            // And my keys are the concatenation of the keys of each of my 
            // inputs 
            List keyVecList = new List();
            RowCount maxCard = RowCount.Zero; 
            RowCount minCard = RowCount.One;
            foreach (Node chi in n.Children)
            {
                ExtendedNodeInfo chiNodeInfo = GetExtendedNodeInfo(chi); 
                nodeInfo.Definitions.Or(chiNodeInfo.Definitions);
                nodeInfo.ExternalReferences.Or(chiNodeInfo.ExternalReferences); 
                keyVecList.Add(chiNodeInfo.Keys); 

                nodeInfo.NonNullableDefinitions.Or(chiNodeInfo.NonNullableDefinitions); 

                // Not entirely precise, but good enough
                if (chiNodeInfo.MaxRows > maxCard)
                { 
                    maxCard = chiNodeInfo.MaxRows;
                } 
                if (chiNodeInfo.MinRows < minCard) 
                {
                    minCard = chiNodeInfo.MinRows; 
                }
            }
            nodeInfo.Keys.InitFrom(keyVecList);
 
            nodeInfo.SetRowCount(minCard, maxCard);
 
            return nodeInfo; 
        }
 
        /// 
        /// Computes a NodeInfo for an Inner/LeftOuter/FullOuter JoinOp.
        /// Definitions = Definitions of my children
        /// LocalDefinitions = None 
        /// Keys = Concatenation of the keys of my children (if every one of them has keys; otherwise, null)
        /// External References = any external references from the inputs + any external 
        ///    references from the join predicates 
        /// RowCount:
        ///    FullOuterJoin: MinRows = 0, MaxRows = N 
        ///    InnerJoin: MinRows = 0;
        ///               MaxRows = N; if both inputs have RowCount lesser than (or equal to) 1, then maxCard = 1
        ///    OuterJoin: MinRows = leftInput.MinRows
        ///               MaxRows = N; if both inputs have RowCount lesser than (or equal to) 1, then maxCard = 1 
        /// NonNullableDefinitions:
        ///    FullOuterJoin: None. 
        ///    InnerJoin: NonNullableDefinitions of both children 
        ///    LeftOuterJoin: NonNullableDefinitions of the left child
        /// NonNullableInputDefinitions : NonNullabeDefinitions of both children 
        /// 
        /// The JoinOp
        /// corresponding Node
        ///  
        protected override NodeInfo VisitJoinOp(JoinBaseOp op, Node n)
        { 
            if (!(op.OpType == OpType.InnerJoin || 
                  op.OpType == OpType.LeftOuterJoin ||
                  op.OpType == OpType.FullOuterJoin)) 
            {
                return Unimplemented(n);
            }
 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
 
            // No definitions of my own. Simply inherit from my children 
            // My external references are the union of my children's external
            // references 
            // And my keys are the concatenation of the keys of each of my
            // inputs
            ExtendedNodeInfo leftRelOpNodeInfo = GetExtendedNodeInfo(n.Child0);
            ExtendedNodeInfo rightRelOpNodeInfo = GetExtendedNodeInfo(n.Child1); 
            NodeInfo predNodeInfo = GetNodeInfo(n.Child2);
 
            nodeInfo.Definitions.Or(leftRelOpNodeInfo.Definitions); 
            nodeInfo.Definitions.Or(rightRelOpNodeInfo.Definitions);
 
            nodeInfo.ExternalReferences.Or(leftRelOpNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Or(rightRelOpNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Or(predNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Minus(nodeInfo.Definitions); 

            nodeInfo.Keys.InitFrom(leftRelOpNodeInfo.Keys, rightRelOpNodeInfo.Keys); 
 
            //Non-nullable definitions
            if (op.OpType == OpType.InnerJoin || op.OpType == OpType.LeftOuterJoin) 
            {
                nodeInfo.NonNullableDefinitions.InitFrom(leftRelOpNodeInfo.NonNullableDefinitions);
            }
            if (op.OpType == OpType.InnerJoin) 
            {
                nodeInfo.NonNullableDefinitions.Or(rightRelOpNodeInfo.NonNullableDefinitions); 
            } 
            nodeInfo.NonNullableVisibleDefinitions.InitFrom(leftRelOpNodeInfo.NonNullableDefinitions);
            nodeInfo.NonNullableVisibleDefinitions.Or(rightRelOpNodeInfo.NonNullableDefinitions); 

            RowCount maxRows;
            RowCount minRows;
            if (op.OpType == OpType.FullOuterJoin) 
            {
                minRows = RowCount.Zero; 
                maxRows = RowCount.Unbounded; 
            }
            else 
            {
                if ((leftRelOpNodeInfo.MaxRows > RowCount.One) ||
                    (rightRelOpNodeInfo.MaxRows > RowCount.One))
                { 
                    maxRows = RowCount.Unbounded;
                } 
                else 
                {
                    maxRows = RowCount.One; 
                }

                if (op.OpType == OpType.LeftOuterJoin)
                { 
                    minRows = leftRelOpNodeInfo.MinRows;
                } 
                else 
                {
                    minRows = RowCount.Zero; 
                }
            }

            nodeInfo.SetRowCount(minRows, maxRows); 

            return nodeInfo; 
        } 

        ///  
        /// Computes a NodeInfo for a CrossApply/OuterApply op.
        /// Definitions = Definitions of my children
        /// LocalDefinitions = None
        /// Keys = Concatenation of the keys of my children (if every one of them has keys; otherwise, null) 
        /// External References = any external references from the inputs
        /// RowCount: 
        ///    CrossApply: minRows=0; MaxRows=Unbounded 
        ///         (MaxRows = 1, if both inputs have MaxRow less than or equal to 1)
        ///    OuterApply: minRows=leftInput.MinRows; MaxRows=Unbounded 
        ///         (MaxRows = 1, if both inputs have MaxRow less than or equal to 1)
        /// NonNullableDefinitions =
        ///    CrossApply: NonNullableDefinitions of both children
        ///    OuterApply: NonNullableDefinitions of the left child 
        /// NonNullableInputDefinitions = NonNullabeDefinitions of both children
        ///  
        /// The ApplyOp 
        /// corresponding Node
        ///  
        protected override NodeInfo VisitApplyOp(ApplyBaseOp op, Node n)
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
 
            ExtendedNodeInfo leftRelOpNodeInfo = GetExtendedNodeInfo(n.Child0);
            ExtendedNodeInfo rightRelOpNodeInfo = GetExtendedNodeInfo(n.Child1); 
 
            nodeInfo.Definitions.Or(leftRelOpNodeInfo.Definitions);
            nodeInfo.Definitions.Or(rightRelOpNodeInfo.Definitions); 

            nodeInfo.ExternalReferences.Or(leftRelOpNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Or(rightRelOpNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Minus(nodeInfo.Definitions); 

            nodeInfo.Keys.InitFrom(leftRelOpNodeInfo.Keys, rightRelOpNodeInfo.Keys); 
 
            //NonNullableDefinitions
            nodeInfo.NonNullableDefinitions.InitFrom(leftRelOpNodeInfo.NonNullableDefinitions); 
            if (op.OpType == OpType.CrossApply)
            {
                nodeInfo.NonNullableDefinitions.Or(rightRelOpNodeInfo.NonNullableDefinitions);
            } 
            nodeInfo.NonNullableVisibleDefinitions.InitFrom(leftRelOpNodeInfo.NonNullableDefinitions);
            nodeInfo.NonNullableVisibleDefinitions.Or(rightRelOpNodeInfo.NonNullableDefinitions); 
 
            RowCount maxRows;
            if (leftRelOpNodeInfo.MaxRows <= RowCount.One && 
                rightRelOpNodeInfo.MaxRows <= RowCount.One)
            {
                maxRows = RowCount.One;
            } 
            else
            { 
                maxRows = RowCount.Unbounded; 
            }
            RowCount minRows = (op.OpType == OpType.CrossApply) ? RowCount.Zero : leftRelOpNodeInfo.MinRows; 
            nodeInfo.SetRowCount(minRows, maxRows);

            return nodeInfo;
        } 

        ///  
        /// Computes a NodeInfo for SetOps (UnionAll, Intersect, Except). 
        /// Definitions = OutputVars
        /// LocalDefinitions = OutputVars 
        /// Keys = Output Vars for Intersect, Except. For UnionAll ??
        /// External References = any external references from the inputs
        /// RowCount: Min = 0, Max = unbounded.
        ///    For UnionAlls, MinRows = max(MinRows of left and right inputs) 
        /// NonNullable definitions =
        ///     UnionAll - Columns that are NonNullableDefinitions on both (children) sides 
        ///     Except  - Columns that are NonNullableDefinitions on the left child side 
        ///     Intersect - Columns that are NonNullableDefinitions on either side
        /// NonNullableInputDefinitions = default(empty) because cannot be used 
        /// 
        /// The SetOp
        /// corresponding Node
        ///  
        protected override NodeInfo VisitSetOp(SetOp op, Node n)
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 

            // My definitions and my "all" definitions are simply my outputs 
            nodeInfo.Definitions.InitFrom(op.Outputs);
            nodeInfo.LocalDefinitions.InitFrom(op.Outputs);

            ExtendedNodeInfo leftChildNodeInfo = GetExtendedNodeInfo(n.Child0); 
            ExtendedNodeInfo rightChildNodeInfo = GetExtendedNodeInfo(n.Child1);
 
            RowCount minRows = RowCount.Zero; 

            // My external references are the external references of both of 
            // my inputs
            nodeInfo.ExternalReferences.Or(leftChildNodeInfo.ExternalReferences);
            nodeInfo.ExternalReferences.Or(rightChildNodeInfo.ExternalReferences);
 
            if (op.OpType == OpType.UnionAll)
            { 
                minRows = (leftChildNodeInfo.MinRows > rightChildNodeInfo.MinRows) ? leftChildNodeInfo.MinRows  : rightChildNodeInfo.MinRows; 
            }
 
            // for intersect, and exceptOps, the keys are simply the outputs.
            if (op.OpType == OpType.Intersect || op.OpType == OpType.Except)
            {
                nodeInfo.Keys.InitFrom(op.Outputs); 
            }
            else 
            { 
                // UnionAlls are a lot more complicated.  If we've gone through
                // keyPullup, we will have set some keys on it's input branches and 
                // what we need to do here is get the keys from each branch and re-map
                // them to the output vars.
                //
                // If the branchDiscriminator is not set on the unionAllOp, then 
                // we haven't been through key pullup and we can't look at the keys
                // that the child nodes have, because they're not discriminated. 
                // 
                // See the logic in KeyPullup, where we make sure that there are
                // actually branch discriminators on the input branches. 
                UnionAllOp unionAllOp = (UnionAllOp)op;

                if (null == unionAllOp.BranchDiscriminator)
                { 
                    nodeInfo.Keys.NoKeys = true;
                } 
                else 
                {
                    VarVec nodeKeys = m_command.CreateVarVec(); 
                    VarVec mappedKeyVec;
                    for (int i = 0; i < n.Children.Count; i++)
                    {
                        ExtendedNodeInfo childNodeInfo = n.Children[i].GetExtendedNodeInfo(m_command); 
                        if (!childNodeInfo.Keys.NoKeys && !childNodeInfo.Keys.KeyVars.IsEmpty)
                        { 
                            mappedKeyVec = childNodeInfo.Keys.KeyVars.Remap(unionAllOp.VarMap[i].GetReverseMap()); 
                            nodeKeys.Or(mappedKeyVec);
                        } 
                        else
                        {
                            // Each branch had better have keys, or we can't continue.
                            nodeKeys.Clear(); 
                            break;
                        } 
                    } 

                    // You might be tempted to ask: "Don't we need to add the branch discriminator 
                    // to the keys as well?"  The reason we don't is that we wouldn't be here unless
                    // we have a branch discriminator variable, which implies we've pulled up keys on
                    // the inputs, and they'll already have the branch descriminator set in the keys
                    // of each input, so we don't need to add that... 
                    if (nodeKeys.IsEmpty)
                    { 
                        nodeInfo.Keys.NoKeys = true; 
                    }
                    else 
                    {
                        nodeInfo.Keys.InitFrom(nodeKeys);
                    }
                } 
            }
 
            //Non-nullable definitions 
            VarVec leftNonNullableVars = leftChildNodeInfo.NonNullableDefinitions.Remap(op.VarMap[0].GetReverseMap());
            nodeInfo.NonNullableDefinitions.InitFrom(leftNonNullableVars); 

            if (op.OpType != OpType.Except)
            {
                VarVec rightNonNullableVars = rightChildNodeInfo.NonNullableDefinitions.Remap(op.VarMap[1].GetReverseMap()); 
                if (op.OpType == OpType.Intersect)
                { 
                    nodeInfo.NonNullableDefinitions.Or(rightNonNullableVars); 
                }
                else  //Union all 
                {
                    nodeInfo.NonNullableDefinitions.And(rightNonNullableVars);
                }
            } 

            nodeInfo.NonNullableDefinitions.And(op.Outputs); 
 
            nodeInfo.MinRows = minRows;
            return nodeInfo; 
        }

        /// 
        /// Computes a NodeInfo for a ConstrainedSortOp/SortOp. 
        /// Definitions = Definitions of the input Relop
        /// LocalDefinitions = not allowed 
        /// Keys = Keys of the input Relop 
        /// External References = any external references from the input + any external
        ///    references from the keys 
        /// RowCount = Input's RowCount
        /// NonNullabeDefinitions = NonNullabeDefinitions of the input RelOp
        /// NonNullableInputDefinitions = NonNullabeDefinitions of the input RelOp
        ///  
        /// The SortOp
        /// corresponding Node 
        ///  
        protected override NodeInfo VisitSortOp(SortBaseOp op, Node n)
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
            ExtendedNodeInfo relOpChildNodeInfo = GetExtendedNodeInfo(n.Child0);

            // definitions are my child's definitions 
            nodeInfo.Definitions.Or(relOpChildNodeInfo.Definitions);
 
            // My references are my child's external references + those made 
            // by my sort keys
            nodeInfo.ExternalReferences.Or(relOpChildNodeInfo.ExternalReferences); 
            nodeInfo.ExternalReferences.Minus(relOpChildNodeInfo.Definitions);

            // my keys are my child's keys
            nodeInfo.Keys.InitFrom(relOpChildNodeInfo.Keys); 

            //Non-nullable definitions are same as the input 
            nodeInfo.NonNullableDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions); 
            nodeInfo.NonNullableVisibleDefinitions.InitFrom(relOpChildNodeInfo.NonNullableDefinitions);
 
            //Row counts are same as the input
            nodeInfo.InitRowCountFrom(relOpChildNodeInfo);

            // For constrained sort, if the Limit value is Constant(1) and WithTies is false, 
            // then MinRows and MaxRows can be adjusted to 0, 1.
            if (OpType.ConstrainedSort == op.OpType && 
                OpType.Constant == n.Child2.Op.OpType && 
                !((ConstrainedSortOp)op).WithTies)
            { 
                ConstantBaseOp constOp = (ConstantBaseOp)n.Child2.Op;
                if(TypeHelpers.IsIntegerConstant(constOp.Type, constOp.Value, 1))
                {
                    nodeInfo.SetRowCount(RowCount.Zero, RowCount.One); 
                }
            } 
 
            return nodeInfo;
        } 

        /// 
        /// Computes a NodeInfo for Distinct.
        /// Definitions = OutputVars that are not external references 
        /// LocalDefinitions = None
        /// Keys = Output Vars 
        /// External References = any external references from the inputs 
        /// RowCount = Input's RowCount
        /// NonNullabeDefinitions : NonNullabeDefinitions of the input RelOp that are outputs 
        /// NonNullableInputDefinitions : default(empty) because cannot be used
        /// 
        /// The DistinctOp
        /// corresponding Node 
        /// 
        public override NodeInfo Visit(DistinctOp op, Node n) 
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
 
            //#497217 - The parameters should not be included as keys
            nodeInfo.Keys.InitFrom(op.Keys, true);

            // external references - inherit from child 
            ExtendedNodeInfo childNodeInfo = GetExtendedNodeInfo(n.Child0);
            nodeInfo.ExternalReferences.InitFrom(childNodeInfo.ExternalReferences); 
 
            // no local definitions - definitions are just the keys that are not external references
            foreach (Var v in op.Keys) 
            {
                if (childNodeInfo.Definitions.IsSet(v))
                {
                    nodeInfo.Definitions.Set(v); 
                }
                else 
                { 
                    nodeInfo.ExternalReferences.Set(v);
                } 
            }

            //Non-nullable definitions
            nodeInfo.NonNullableDefinitions.InitFrom(childNodeInfo.NonNullableDefinitions); 
            nodeInfo.NonNullableDefinitions.And(op.Keys);
 
            nodeInfo.InitRowCountFrom(childNodeInfo); 
            return nodeInfo;
        } 

        /// 
        /// Compute NodeInfo for a SingleRowOp.
        /// Definitions = child's definitions 
        /// Keys = child's keys
        /// Local Definitions = none 
        /// External references = child's external references 
        /// RowCount=(0,1)
        /// NonNullabeDefinitions = NonNullabeDefinitions of the input RelOp 
        /// NonNullableInputDefinitions : default(empty) because cannot be used
        /// 
        /// The SingleRowOp
        /// current subtree 
        /// NodeInfo for this node
        public override NodeInfo Visit(SingleRowOp op, Node n) 
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
            ExtendedNodeInfo childNodeInfo = GetExtendedNodeInfo(n.Child0); 
            nodeInfo.Definitions.InitFrom(childNodeInfo.Definitions);
            nodeInfo.Keys.InitFrom(childNodeInfo.Keys);
            nodeInfo.ExternalReferences.InitFrom(childNodeInfo.ExternalReferences);
            nodeInfo.NonNullableDefinitions.InitFrom(childNodeInfo.NonNullableDefinitions); 
            nodeInfo.SetRowCount(RowCount.Zero, RowCount.One);
            return nodeInfo; 
        } 

        ///  
        /// SingleRowTableOp
        /// No definitions, external references, non-nullable definitions
        /// Keys = empty list (not the same as "no keys")
        /// RowCount = (1,1) 
        /// 
        /// the SingleRowTableOp 
        /// current subtree 
        /// nodeInfo for this subtree
        public override NodeInfo Visit(SingleRowTableOp op, Node n) 
        {
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
            nodeInfo.Keys.NoKeys = false;
            nodeInfo.SetRowCount(RowCount.One, RowCount.One); 
            return nodeInfo;
        } 
 
        #endregion
 
        #region PhysicalOps
        /// 
        /// Computes a NodeInfo for a PhysicalProjectOp.
        /// Definitions = OutputVars 
        /// LocalDefinitions = None
        /// Keys = None 
        /// External References = any external references from the inputs 
        /// RowCount=default
        /// NonNullabeDefinitions = NonNullabeDefinitions of the input RelOp that are among the definitions 
        /// NonNullableInputDefinitions = NonNullabeDefinitions of the input RelOp
        /// 
        /// The PhysicalProjectOp
        /// corresponding Node 
        /// 
        public override NodeInfo Visit(PhysicalProjectOp op, Node n) 
        { 
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n);
            foreach (Node chi in n.Children) 
            {
                NodeInfo childNodeInfo = GetNodeInfo(chi);
                nodeInfo.ExternalReferences.Or(childNodeInfo.ExternalReferences);
            } 
            nodeInfo.Definitions.InitFrom(op.Outputs);
            nodeInfo.LocalDefinitions.InitFrom(nodeInfo.Definitions); 
 
            //
            // Inherit the keys from the child - but only if all the columns were projected 
            // out
            //
            ExtendedNodeInfo driverChildNodeInfo = GetExtendedNodeInfo(n.Child0);
            if (!driverChildNodeInfo.Keys.NoKeys) 
            {
                VarVec missingKeys = m_command.CreateVarVec(driverChildNodeInfo.Keys.KeyVars); 
                missingKeys.Minus(nodeInfo.Definitions); 
                if (missingKeys.IsEmpty)
                { 
                    nodeInfo.Keys.InitFrom(driverChildNodeInfo.Keys);
                }
            }
 
            //Non-nullable definitions
            nodeInfo.NonNullableDefinitions.Or(driverChildNodeInfo.NonNullableDefinitions); 
            nodeInfo.NonNullableDefinitions.And(nodeInfo.Definitions); 
            nodeInfo.NonNullableVisibleDefinitions.Or(driverChildNodeInfo.NonNullableVisibleDefinitions);
 
            return nodeInfo;
        }

        ///  
        /// Computes a NodeInfo for a NestOp (SingleStream/MultiStream).
        /// Definitions = OutputVars 
        /// LocalDefinitions = Collection Vars 
        /// Keys = Keys of my child
        /// External References = any external references from the inputs 
        /// RowCount=default
        /// 
        /// The NestOp
        /// corresponding Node 
        /// 
        protected override NodeInfo VisitNestOp(NestBaseOp op, Node n) 
        { 
            SingleStreamNestOp ssnOp = op as SingleStreamNestOp;
            ExtendedNodeInfo nodeInfo = InitExtendedNodeInfo(n); 

            foreach (CollectionInfo ci in op.CollectionInfo)
            {
                nodeInfo.LocalDefinitions.Set(ci.CollectionVar); 
            }
            nodeInfo.Definitions.InitFrom(op.Outputs); 
 
            // get external references from each child
            foreach (Node chi in n.Children) 
            {
                nodeInfo.ExternalReferences.Or(GetExtendedNodeInfo(chi).ExternalReferences);
            }
 
            // eliminate things I may have defined already (left correlation)
            nodeInfo.ExternalReferences.Minus(nodeInfo.Definitions); 
 
            // Keys are from the driving node only.
            if (ssnOp == null) 
            {
                nodeInfo.Keys.InitFrom(GetExtendedNodeInfo(n.Child0).Keys);
            }
            else 
            {
                nodeInfo.Keys.InitFrom(ssnOp.Keys); 
            } 
            return nodeInfo;
        } 

        #endregion

        #endregion 
    }
} 

// File provided for Reference Use Only by Microsoft Corporation (c) 2007.


                        

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