Leaked source code of windows server 2003
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//+-------------------------------------------------------------------------
//
// Microsoft Windows
//
// Copyright (C) Microsoft Corporation, 1997 - 1997
//
// File: gmobj.h
//
//--------------------------------------------------------------------------
//
// GMOBJ.H: Grapical model objects declarations
//
#ifndef _GMOBJ_H_
#define _GMOBJ_H_
#include <list> // STL list template
#include <assert.h>
#include <iostream>
#include <fstream>
#include "model.h" // Graphical model
#include "gmprop.h" // Properties and proplists
#include "mbnflags.h" // Belief network marking flags static declarations
class CLAMP; // An instantiation for a node, discrete or continuous
class GOBJMBN; // A named object in a belief network
class GNODEMBN; // A node in a belief network
class GNODEMBND; // A discrete node
class GEDGEMBN; // An arc in a belief network
class MBNET; // A belief network
class MBNET_MODIFIER; // An object that alters a belief network
class GOBJMBN_INFER_ENGINE; // Abstract class for inference engine, based on MBNET_MODIFIER
class GOBJMBN_CLIQSET; // A group of junction trees, based on GOBJMBN_INFER_ENGINE
class GOBJMBN_CLIQUE; // A clique in a junction tree
class GEDGEMBN_SEPSET; // An edge in the junction tree (sepset)
class GOBJMBN_DOMAIN; // Named, sharable state space domain
// Define VGNODEMBN, an array of nodes
DEFINEVP(GNODEMBN);
DEFINEVCP(GNODEMBN);
struct PTPOS
{
PTPOS( long x = 0, long y = 0 )
: _x(x),_y(y)
{}
long _x;
long _y;
};
////////////////////////////////////////////////////////////////////
// class GEDGEMBN:
// An edge of any kind in belief network.
////////////////////////////////////////////////////////////////////
class GEDGEMBN : public GEDGE
{
public:
enum ETYPE
{
ETNONE = GELEM::EGELM_EDGE, // None
ETPROB, // Probabilistic
ETCLIQUE, // Clique membership
ETJTREE, // Junction tree linkage
ETUNDIR, // Undirected edge for topological operations
ETDIR, // Directed edge for topological operations
ETCLIQSET, // Link to a root clique in a jtree
ETEXPAND // Link from original to expanded node
};
GEDGEMBN ( GOBJMBN * pgnSource,
GOBJMBN * pgnSink )
: GEDGE( pgnSource, pgnSink )
{}
GOBJMBN * PobjSource () { return (GOBJMBN *) GEDGE::PnodeSource(); }
GOBJMBN * PobjSink () { return (GOBJMBN *) GEDGE::PnodeSink(); }
virtual GEDGEMBN * CloneNew ( MODEL & modelSelf, // the original network
MODEL & modelNew, // the new network
GOBJMBN * pgobjmbnSource, // the original source node
GOBJMBN * pgobjmbnSink, // the original sink node
GEDGEMBN * pgdegeNew = NULL ); // the new edge or NULL
virtual INT EType () const
{ return ETNONE ; }
virtual ~ GEDGEMBN () {}
// Accessors for the array of flag bits
bool BFlag ( IBFLAG ibf ) const
{ return _vFlags.BFlag( ibf ); }
bool BSetBFlag ( IBFLAG ibf, bool bValue = true )
{ return _vFlags.BSetBFlag( ibf, bValue ); }
protected:
VFLAGS _vFlags; // Bit vector of flags
HIDE_UNSAFE(GEDGEMBN);
};
////////////////////////////////////////////////////////////////////
// class CLAMP:
// A forced value (evidence) for a node, continuous or discrete.
// Use assignment operator to update.
////////////////////////////////////////////////////////////////////
class CLAMP
{
public:
CLAMP ( bool bDiscrete = true, RST rst = 0.0, bool bActive = false )
: _bDiscrete(bDiscrete),
_bActive(bActive),
_rst(rst)
{
}
bool BActive () const { return _bActive; }
bool BDiscrete () const { return _bActive; }
const RST & Rst () const
{
assert( BActive() && ! BDiscrete() );
return _rst;
}
IST Ist () const
{
assert( BActive() && BDiscrete() );
return IST(_rst);
}
bool operator == ( const CLAMP & clamp ) const
{
return _bDiscrete == clamp._bDiscrete
&& _bActive == clamp._bActive
&& (!_bActive || _rst == clamp._rst);
}
bool operator != ( const CLAMP & clamp ) const
{
return ! (self == clamp);
}
protected:
bool _bActive; // Is this clamp active?
bool _bDiscrete; // Is this discrete or continuous?
RST _rst; // State (coerced to integer if discrete)
};
////////////////////////////////////////////////////////////////////
// class GNODEMBN:
// A node in belief network, continuous or discrete.
// Hungarian: "gndbn"
////////////////////////////////////////////////////////////////////
class GNODEMBN : public GOBJMBN
{
friend class DSCPARSER;
friend class MBNET;
public:
GNODEMBN ();
virtual ~ GNODEMBN();
virtual INT EType () const
{ return EBNO_NODE ; }
virtual GOBJMBN * CloneNew ( MODEL & modelSelf,
MODEL & modelNew,
GOBJMBN * pgobjNew = NULL );
// Node sub-type: use IType() to access.
enum FNODETYPE
{ // Flag definitions (i.e., bits, not values)
FND_Void = 0, // Node is abstract base class
FND_Valid = 1, // Node is usable
FND_Discrete = 2 // Node is discrete
};
UINT CParent () const { return CSourceArcByEType( GEDGEMBN::ETPROB ); }
UINT CChild () const { return CSinkArcByEType( GEDGEMBN::ETPROB ); }
INT & ITopLevel () { return _iTopLevel; }
INT ITopLevel () const { return _iTopLevel; }
PTPOS & PtPos () { return _ptPos; }
ZSTR & ZsFullName () { return _zsFullName; }
LTBNPROP & LtProp () { return _ltProp; }
virtual void Dump ();
virtual void Visit ( bool bUpwards = true );
// Add topological elements to given array; if "include self", self is last.
// Fill array with parent pointers (follow directed arcs)
void GetParents ( VPGNODEMBN & vpgnode, // Result array
bool bIncludeSelf = false, // Place self as last entry in list
bool bUseExpansion = true ); // If expanded, use expansion only
void GetFamily ( VPGNODEMBN & vpgnode,
bool bUseExpansion = true )
{ GetParents(vpgnode,true,bUseExpansion); }
// Fill array with child pointers (follow directed arcs)
void GetChildren ( VPGNODEMBN & vpgnode, bool bIncludeSelf = false );
// Fill array with neighbors (follow undirected arcs)
void GetNeighbors ( VPGNODEMBN & vpgnode, bool bIncludeSelf = false );
// Return true if a node is neighbor
bool BIsNeighbor ( GNODEMBN * pgndmb );
// Return the index number of the parent or child or -1 if no relation.
int IParent ( GNODEMBN * pgndmb, bool bReverse = false );
int IChild ( GNODEMBN * pgndmb, bool bReverse = false );
// Build the probability descriptor describing the node and its parents
void GetVtknpd ( VTKNPD & vtknpd, bool bUseExpansion = true );
// Query and access clamping information
const CLAMP & ClampIface () const { return _clampIface; }
CLAMP & ClampIface () { return _clampIface; }
protected:
INT _iTopLevel; // Topological level
LTBNPROP _ltProp; // The list of user-definable properties
PTPOS _ptPos; // Display position in graphical display
ZSTR _zsFullName; // Full name of node
CLAMP _clampIface; // User interface clamp
protected:
// Compare the topology of this node to that of the given distribution
// token list to this. If 'pvpgnode', fill it with pointers to
// the parent nodes
bool BMatchTopology ( MBNET & mbnet,
const VTKNPD & vtknpd,
VPGNODEMBN * pvpgnode = NULL );
HIDE_UNSAFE(GNODEMBN);
};
////////////////////////////////////////////////////////////////////
// class GEDGEMBN_U: An undirected edge
////////////////////////////////////////////////////////////////////
class GEDGEMBN_U : public GEDGEMBN
{
public:
GEDGEMBN_U ( GNODEMBN * pgnSource,
GNODEMBN * pgnSink )
: GEDGEMBN( pgnSource, pgnSink )
{}
virtual INT EType () const
{ return ETUNDIR; }
virtual ~ GEDGEMBN_U() {}
};
////////////////////////////////////////////////////////////////////
// class GEDGEMBN_D: A directed edge
////////////////////////////////////////////////////////////////////
class GEDGEMBN_D : public GEDGEMBN
{
public:
GEDGEMBN_D ( GNODEMBN * pgnSource,
GNODEMBN * pgnSink )
: GEDGEMBN( pgnSource, pgnSink )
{}
virtual INT EType () const
{ return ETDIR; }
virtual ~ GEDGEMBN_D() {}
};
////////////////////////////////////////////////////////////////////
// class GEDGEMBN_PROB:
// A probabilistic arc in a belief network.
////////////////////////////////////////////////////////////////////
class GEDGEMBN_PROB : public GEDGEMBN_D
{
public:
GEDGEMBN_PROB ( GNODEMBN * pgndSource,
GNODEMBN * pgndSink )
: GEDGEMBN_D( pgndSource, pgndSink )
{}
virtual INT EType () const
{ return ETPROB ; }
virtual ~ GEDGEMBN_PROB () {}
virtual GEDGEMBN * CloneNew ( MODEL & modelSelf, // the original network
MODEL & modelNew, // the new network
GOBJMBN * pgobjmbnSource, // the original source node
GOBJMBN * pgobjmbnSink, // the original sink node
GEDGEMBN * pgdegeNew = NULL ); // the new edge or NULL
GNODEMBN * PgndSource () { return (GNODEMBN *) GEDGE::PnodeSource(); }
GNODEMBN * PgndSink () { return (GNODEMBN *) GEDGE::PnodeSink(); }
HIDE_UNSAFE(GEDGEMBN_PROB);
};
////////////////////////////////////////////////////////////////////
// class GNODEMBND:
// A discrete node in belief network.
////////////////////////////////////////////////////////////////////
class GNODEMBND : public GNODEMBN
{
friend class DSCPARSER;
public:
GNODEMBND ();
virtual ~ GNODEMBND ();
virtual GOBJMBN * CloneNew ( MODEL & modelSelf,
MODEL & modelNew,
GOBJMBN * pgobjNew = NULL );
UINT CState() const
{ return _vzsrState.size(); }
const VZSREF & VzsrStates() const
{ return _vzsrState; }
void SetStates ( const VZSREF & vzsrState )
{ _vzsrState = vzsrState; }
// Return true if there's an associated distribution
bool BHasDist () const
{ return _refbndist.BRef(); }
// Set the distribution from the given net's distribution map
void SetDist ( MBNET & mbnet );
// Bind the given distribution this node
void SetDist ( BNDIST * pbndist );
// Return the distribution
BNDIST & Bndist ()
{
assert( BHasDist() );
return *_refbndist;
}
const BNDIST & Bndist () const
{
assert( BHasDist() );
return *_refbndist;
}
// Return true if the distribution is dense (false ==> sparse)
bool BDense () const
{
assert( BHasDist() );
return _refbndist->BDense() ;
}
// Return the discrete dimension vector of this node if possible;
// return false if any parent is not discrete.
bool BGetVimd ( VIMD & vimd, // Dimension array to fill
bool bIncludeSelf = false, // Place self as last entry in list
bool bUseExpansion = true ); // If expanded, use expansion only
void Dump ();
void ClearDist()
{
_refbndist = NULL;
}
const REFBNDIST & RefBndist ()
{ return _refbndist; }
bool BCheckDistDense ();
const ZSREF ZsrDomain() const
{ return _zsrDomain; }
void SetDomain ( const GOBJMBN_DOMAIN & gobjrdom );
protected:
VZSREF _vzsrState; // Names of states
ZSREF _zsrDomain; // Domain of states, if any
REFBNDIST _refbndist; // Distribution object
HIDE_UNSAFE(GNODEMBND);
};
DEFINEVP(GNODEMBND); // A vector containing pointers to nodes
DEFINEV(VPGNODEMBN); // A vector of vectors containing pointers to nodes
DEFINEV(VPGNODEMBND); // A vector of vectors containing pointers to discrete nodes
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
//
// MBNET_MODIFIER: A generic superclass for active objects
// which modify a belief network in a reversible fashion.
// The belief network (MBNET) object maintains a stack of these
// things and calls each object's Destroy() function as necessary
// to "unstack".
//
// These objects should be reusable; that is, the outer level
// creator may call Create(), followed by Destroy(), followed by
// Create() again.
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
class MBNET_MODIFIER : public GOBJMBN
{
public:
MBNET_MODIFIER ( MBNET & model )
: _model(model)
{}
virtual ~ MBNET_MODIFIER () {}
virtual INT EType () const
{ return EBNO_MBNET_MODIFIER; }
// Perform any creation-time operations
virtual void Create () = 0;
// Perform any special destruction
virtual void Destroy () = 0;
// Return true if positions in modifier stack can be reversed;
// default is "no" (false).
virtual bool BCommute ( const MBNET_MODIFIER & mbnmod )
{ return false; }
// Return true if construction resulted in no modifications to network
// i.e., operation was moot; default is "no" (false).
virtual bool BMoot ()
{ return false; }
MBNET & Model () { return _model; }
protected:
MBNET & _model; // The model we're operating on
HIDE_UNSAFE(MBNET_MODIFIER);
};
// Define an array of pointers to modifiers, "VPMBNET_MODIFIER".
DEFINEVP(MBNET_MODIFIER);
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
// MBNET_NODE_RANKER: A generic superclass for external objects
// which rank or order nodes by some criteria. Operates as
// a function object; i.e., it is activated by use of the
// function call operator.
//
// Objects of subclasses of this class must be reusable.
// That is, the functin call operator must be callable
// repeatedly.
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
class MBNET_NODE_RANKER : public GOBJMBN
{
public:
MBNET_NODE_RANKER ( MBNET & model )
: _model(model)
{}
virtual ~ MBNET_NODE_RANKER () {}
virtual INT EType () const
{ return EBNO_NODE_RANKER; }
MBNET & Model () { return _model; }
// The ranking function
virtual void operator () () = 0;
// Return the number of items ranked
INT CRanked () const { return _vzsrNodes.size(); }
// Return the nodes in rank order
const VZSREF VzsrefNodes () const { return _vzsrNodes; }
// Return the computed values in rank order
const VLREAL VlrValues () const { return _vlrValues; }
protected:
MBNET & _model; // The model we're operating on
VZSREF _vzsrNodes; // The names of the nodes in rank order
VLREAL _vlrValues; // THe values associated with the ranking (if any)
protected:
void Clear ()
{
_vzsrNodes.clear();
_vlrValues.resize(0);
}
HIDE_UNSAFE(MBNET_NODE_RANKER);
};
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
// class MBNET: a belief network
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
class MBNET : public MODEL
{
public:
MBNET ();
virtual ~ MBNET ();
// Clone this belief network from another
virtual void Clone ( MODEL & model );
// Accessor for map of distribution
MPPD & Mppd () { return _mppd; }
// Return true if an edge is allowed between these two nodes
bool BAcyclicEdge ( GNODEMBN * pgndSource, GNODEMBN * pgndSink );
// Add a named object to the graph and symbol table
virtual void AddElem ( SZC szcName, GOBJMBN * pgobj );
// Delete named objects
virtual void DeleteElem ( GOBJMBN * pgelem );
void AddElem ( GOBJMBN * pgobjUnnamed )
{ MODEL::AddElem( pgobjUnnamed ); }
void AddElem ( GEDGEMBN * pgedge )
{ MODEL::AddElem( pgedge ); }
// Topology and distribution management
// Add arcs conforming to the defined distributions
virtual void CreateTopology ();
// Destroy arcs.
virtual void DestroyTopology ( bool bDirectedOnly = true ) ;
// Connect distribution information in MPPD to nodes
virtual void BindDistributions ( bool bBind = true );
void ClearDistributions ()
{ BindDistributions( false ); }
// Write debugging info out
virtual void Dump ();
// Network walking/marking helpers
void ClearNodeMarks ();
void TopSortNodes ();
// Index-to-name mapping functions
// Find the named object by index
GOBJMBN * PgobjFindByIndex ( int inm );
// Return the index of a name
int INameIndex ( ZSREF zsr );
// Return the index of an object's name
int INameIndex ( const GOBJMBN * pgobj );
// Return the highest+1 name index
int CNameMax () const { return _vzsrNames.size(); }
// Causal Independence expansion operations (automatic during inference)
virtual void ExpandCI ();
virtual void UnexpandCI ();
// Inference operations
// Return the most recently created inference engine
GOBJMBN_INFER_ENGINE * PInferEngine ();
// Create an inference engine
void CreateInferEngine ( REAL rEstimatedMaximumSize = 10e6 );
// Destroy an inference engine
void DestroyInferEngine ();
protected:
MPPD _mppd; // Declared probability distributions
VZSREF _vzsrNames; // Array associating indicies to names
int _inmFree; // First free entry in _vsrNodes
INT _iInferEngID; // Next inference engine identifier
VPMBNET_MODIFIER _vpModifiers; // The stack of active modifiers
protected:
int CreateNameIndex ( const GOBJMBN * pgobj );
void DeleteNameIndex ( const GOBJMBN * pgobj );
void DeleteNameIndex ( int inm );
void PopModifierStack ( bool bAll = false );
void PushModifierStack ( MBNET_MODIFIER * pmodf );
MBNET_MODIFIER * PModifierStackTop ();
void VerifyTopology ();
HIDE_UNSAFE(MBNET);
};
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
// class MBNETDSC:
// Subclass of MBNET that knows how to load and save DSC from
// the DSC file format.
////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////
class MBNETDSC : public MBNET
{
public:
MBNETDSC ();
virtual ~ MBNETDSC ();
// Parse the network from a DSC file
virtual bool BParse ( SZC szcFn, FILE * pfErr = NULL );
// Print the network in DSC format
virtual void Print ( FILE * pf = NULL );
// Token translation
// Map a string to a token
static TOKEN TokenFind ( SZC szc );
// Map a distribution type to a token
static SZC SzcDist ( BNDIST::EDIST edist );
// Map a token to a string
static SZC SzcTokenMap ( TOKEN tkn );
protected:
// DSC file printing functions
FILE * _pfDsc; // Output print destination
protected:
void PrintHeaderBlock();
void PrintPropertyDeclarations();
void PrintNodes();
void PrintDomains();
void PrintTopologyAndDistributions();
void PrintDistribution ( GNODEMBN & gnode, BNDIST & bndist );
void PrintPropertyList ( LTBNPROP & ltprop );
HIDE_UNSAFE(MBNETDSC);
};
class BNWALKER : public GRPHWALKER<GNODEMBN>
{
protected:
bool BSelect ( GNODEMBN * pgn );
bool BMark ( GNODEMBN * pgn );
};
#endif