/usr/include/planarity/graphStructures.h

#ifndef GRAPHSTRUCTURE_H
#define GRAPHSTRUCTURE_H

/*
Copyright (c) 1997-2015, John M. Boyer
All rights reserved.
See the LICENSE.TXT file for licensing information.
*/

#include <stdio.h>
#include "appconst.h"
#include "listcoll.h"
#include "stack.h"

#include "graphFunctionTable.h"
#include "graphExtensions.private.h"

#ifdef __cplusplus
extern "C" {
#endif

// A return value to indicate success prior to completely processing a graph, whereas
// OK signifies EMBEDDABLE (no unreducible obstructions) and NOTOK signifies an exception.
#define NONEMBEDDABLE   -1

// The initial setting for the edge storage capacity expressed as a constant factor of N,
// which is the number of vertices in the graph. By default, array E is allocated enough
// space to contain 3N edges, which is 6N arcs (half edges), but this initial setting
// can be overridden using gp_EnsureArcCapacity(), which is especially efficient if done
// before calling gp_InitGraph() or gp_Read().
#define DEFAULT_EDGE_LIMIT      3

/********************************************************************
 Edge Record Definition

 An edge is defined by a pair of edge records, or arcs, allocated in
 array E of a graph.  An edge record represents the edge in the
 adjacency list of each vertex to which the edge is incident.

 link[2]: the next and previous edge records (arcs) in the adjacency
          list that contains this edge record.

 v: The vertex neighbor of the vertex whose adjacency list contains
    this edge record (an index into array V).

 flags: Bits 0-15 reserved for library; bits 16 and higher for apps
        Bit 0: Visited
        Bit 1: DFS type has been set, versus not set
        Bit 2: DFS tree edge, versus cycle edge (co-tree edge, etc.)
        Bit 3: DFS arc to descendant, versus arc to ancestor
        Bit 4: Inverted (same as marking an edge with a "sign" of -1)
        Bit 5: Arc is directed into the containing vertex only
        Bit 6: Arc is directed from the containing vertex only
 ********************************************************************/

typedef struct
{
	int  link[2];
	int  neighbor;
	unsigned flags;
} edgeRec;

typedef edgeRec * edgeRecP;

#if NIL == 0
#define gp_IsArc(e) (e)
#define gp_IsNotArc(e) (!(e))
#define gp_GetFirstEdge(theGraph) (2)
#elif NIL == -1
#define gp_IsArc(e) ((e) != NIL)
#define gp_IsNotArc(e) ((e) == NIL)
#define gp_GetFirstEdge(theGraph) (0)
#else
#error NIL must be 0 or -1
#endif

#define gp_EdgeInUse(theGraph, e) (gp_IsVertex(gp_GetNeighbor(theGraph, e)))
#define gp_EdgeNotInUse(theGraph, e) (gp_IsNotVertex(gp_GetNeighbor(theGraph, e)))
#define gp_EdgeIndexBound(theGraph) (gp_GetFirstEdge(theGraph) + (theGraph)->arcCapacity)
#define gp_EdgeInUseIndexBound(theGraph) (gp_GetFirstEdge(theGraph) + (((theGraph)->M + sp_GetCurrentSize((theGraph)->edgeHoles)) << 1))

// An edge is represented by two consecutive edge records (arcs) in the edge array E.
// If an even number, xor 1 will add one; if an odd number, xor 1 will subtract 1
#define gp_GetTwinArc(theGraph, Arc) ((Arc) ^ 1)

// Access to adjacency list pointers
#define gp_GetNextArc(theGraph, e) (theGraph->E[e].link[0])
#define gp_GetPrevArc(theGraph, e) (theGraph->E[e].link[1])
#define gp_GetAdjacentArc(theGraph, e, theLink) (theGraph->E[e].link[theLink])

#define gp_SetNextArc(theGraph, e, newNextArc) (theGraph->E[e].link[0] = newNextArc)
#define gp_SetPrevArc(theGraph, e, newPrevArc) (theGraph->E[e].link[1] = newPrevArc)
#define gp_SetAdjacentArc(theGraph, e, theLink, newArc) (theGraph->E[e].link[theLink] = newArc)

// Access to vertex 'neighbor' member indicated by arc
#define gp_GetNeighbor(theGraph, e) (theGraph->E[e].neighbor)
#define gp_SetNeighbor(theGraph, e, v) (theGraph->E[e].neighbor = v)

// Initializer for edge flags
#define gp_InitEdgeFlags(theGraph, e) (theGraph->E[e].flags = 0)

// Definitions of and access to edge flags
#define EDGE_VISITED_MASK		1
#define gp_GetEdgeVisited(theGraph, e) (theGraph->E[e].flags&EDGE_VISITED_MASK)
#define gp_ClearEdgeVisited(theGraph, e) (theGraph->E[e].flags &= ~EDGE_VISITED_MASK)
#define gp_SetEdgeVisited(theGraph, e) (theGraph->E[e].flags |= EDGE_VISITED_MASK)

// The edge type is defined by bits 1-3, 2+4+8=14
#define EDGE_TYPE_MASK		14

// Call gp_GetEdgeType(), then compare to one of these four possibilities
// EDGE_TYPE_CHILD - edge record is an arc to a DFS child
// EDGE_TYPE_FORWARD - edge record is an arc to a DFS descendant, not a DFS child
// EDGE_TYPE_PARENT - edge record is an arc to the DFS parent
// EDGE_TYPE_BACK - edge record is an arc to a DFS ancestor, not the DFS parent
#define EDGE_TYPE_CHILD     14
#define EDGE_TYPE_FORWARD   10
#define EDGE_TYPE_PARENT    6
#define EDGE_TYPE_BACK      2

// EDGE_TYPE_NOTDEFINED - the edge record type has not been defined
// EDGE_TYPE_RANDOMTREE - edge record is part of a randomly generated tree
#define EDGE_TYPE_NOTDEFINED	0
#define EDGE_TYPE_RANDOMTREE	4

#define gp_GetEdgeType(theGraph, e) (theGraph->E[e].flags&EDGE_TYPE_MASK)
#define gp_ClearEdgeType(theGraph, e) (theGraph->E[e].flags &= ~EDGE_TYPE_MASK)
#define gp_SetEdgeType(theGraph, e, type) (theGraph->E[e].flags |= type)
#define gp_ResetEdgeType(theGraph, e, type) \
	(theGraph->E[e].flags = (theGraph->E[e].flags & ~EDGE_TYPE_MASK) | type)

#define EDGEFLAG_INVERTED_MASK 16
#define gp_GetEdgeFlagInverted(theGraph, e) (theGraph->E[e].flags & EDGEFLAG_INVERTED_MASK)
#define gp_SetEdgeFlagInverted(theGraph, e) (theGraph->E[e].flags |= EDGEFLAG_INVERTED_MASK)
#define gp_ClearEdgeFlagInverted(theGraph, e) (theGraph->E[e].flags &= (~EDGEFLAG_INVERTED_MASK))
#define gp_XorEdgeFlagInverted(theGraph, e) (theGraph->E[e].flags ^= EDGEFLAG_INVERTED_MASK)

#define EDGEFLAG_DIRECTION_INONLY	32
#define EDGEFLAG_DIRECTION_OUTONLY	64
#define EDGEFLAG_DIRECTION_MASK		96

// Returns the direction, if any, of the edge record
#define gp_GetDirection(theGraph, e) (theGraph->E[e].flags & EDGEFLAG_DIRECTION_MASK)

//A direction of 0 clears directedness. Otherwise, edge record e is set
//to edgeFlag_Direction and e's twin arc is set to the opposing setting.
#define gp_SetDirection(theGraph, e, edgeFlag_Direction) \
{ \
	if (edgeFlag_Direction == EDGEFLAG_DIRECTION_INONLY) \
	{ \
		theGraph->E[e].flags |= EDGEFLAG_DIRECTION_INONLY; \
		theGraph->E[gp_GetTwinArc(theGraph, e)].flags |= EDGEFLAG_DIRECTION_OUTONLY; \
	} \
	else if (edgeFlag_Direction == EDGEFLAG_DIRECTION_OUTONLY) \
	{ \
		theGraph->E[e].flags |= EDGEFLAG_DIRECTION_OUTONLY; \
		theGraph->E[gp_GetTwinArc(theGraph, e)].flags |= EDGEFLAG_DIRECTION_INONLY; \
	} \
	else \
	{ \
		theGraph->E[e].flags &= ~(EDGEFLAG_DIRECTION_INONLY|EDGEFLAG_DIRECTION_OUTONLY); \
		theGraph->E[gp_GetTwinArc(theGraph, e)].flags &= ~EDGEFLAG_DIRECTION_MASK; \
	} \
}

#define gp_CopyEdgeRec(dstGraph, edst, srcGraph, esrc) (dstGraph->E[edst] = srcGraph->E[esrc])

/********************************************************************
 Vertex Record Definition

 This record definition provides the data members needed for the
 core structural information for both vertices and virtual vertices.
 Vertices are also equipped with additional information provided by
 the vertexInfo structure.

 The vertices of a graph are stored in the first N locations of array V.
 Virtual vertices are secondary vertices used to help represent the
 main vertices in substructural components of a graph (e.g. biconnected
 components).

 link[2]: the first and last edge records (arcs) in the adjacency list
          of the vertex.

 index: In vertices, stores either the depth first index of a vertex or
        the original array index of the vertex if the vertices of the
        graph are sorted by DFI.
        In virtual vertices, the index may be used to indicate the vertex
        that the virtual vertex represents, unless an algorithm has some
        other way of making the association (for example, the planarity
        algorithms rely on biconnected components and therefore place
        virtual vertices of a vertex at positions corresponding to the
        DFS children of the vertex).

 flags: Bits 0-15 reserved for library; bits 16 and higher for apps
        Bit 0: visited, for vertices and virtual vertices
				Use in lieu of TYPE_VERTEX_VISITED in K4 algorithm
		Bit 1: Obstruction type VERTEX_TYPE_SET (versus not set, i.e. VERTEX_TYPE_UNKNOWN)
		Bit 2: Obstruction type qualifier RYW (set) versus RXW (clear)
		Bit 3: Obstruction type qualifier high (set) versus low (clear)
 ********************************************************************/

typedef struct
{
	int  link[2];
	int  index;
	unsigned flags;
} vertexRec;

typedef vertexRec * vertexRecP;

// Accessors for vertex adjacency list links
#define gp_GetFirstArc(theGraph, v) (theGraph->V[v].link[0])
#define gp_GetLastArc(theGraph, v) (theGraph->V[v].link[1])
#define gp_GetArc(theGraph, v, theLink) (theGraph->V[v].link[theLink])

#define gp_SetFirstArc(theGraph, v, newFirstArc) (theGraph->V[v].link[0] = newFirstArc)
#define gp_SetLastArc(theGraph, v, newLastArc) (theGraph->V[v].link[1] = newLastArc)
#define gp_SetArc(theGraph, v, theLink, newArc) (theGraph->V[v].link[theLink] = newArc)

// Vertex conversions and iteration
#if NIL == 0
#define gp_IsVertex(v) (v)
#define gp_IsNotVertex(v) (!(v))

#define gp_GetFirstVertex(theGraph) (1)
#define gp_GetLastVertex(theGraph) ((theGraph)->N)
#define gp_VertexInRange(theGraph, v) ((v) <= (theGraph)->N)
#define gp_VertexInRangeDescending(theGraph, v) (v)

#define gp_PrimaryVertexIndexBound(theGraph) (gp_GetFirstVertex(theGraph) + (theGraph)->N)
#define gp_VertexIndexBound(theGraph) (gp_PrimaryVertexIndexBound(theGraph) + (theGraph)->N)

#define gp_IsVirtualVertex(theGraph, v) ((v) > theGraph->N)
#define gp_IsNotVirtualVertex(theGraph, v) ((v) <= theGraph->N)
#define gp_VirtualVertexInUse(theGraph, virtualVertex) (gp_IsArc(gp_GetFirstArc(theGraph, virtualVertex)))
#define gp_VirtualVertexNotInUse(theGraph, virtualVertex) (gp_IsNotArc(gp_GetFirstArc(theGraph, virtualVertex)))
#define gp_GetFirstVirtualVertex(theGraph) (theGraph->N + 1)
#define gp_GetLastVirtualVertex(theGraph) (theGraph->N + theGraph->NV)
#define gp_VirtualVertexInRange(theGraph, v) ((v) <= theGraph->N + theGraph->NV)

#elif NIL == -1
#define gp_IsVertex(v) ((v) != NIL)
#define gp_IsNotVertex(v) ((v) == NIL)

#define gp_GetFirstVertex(theGraph) (0)
#define gp_GetLastVertex(theGraph) ((theGraph)->N - 1)
#define gp_VertexInRange(theGraph, v) ((v) < (theGraph)->N)
#define gp_VertexInRangeDescending(theGraph, v) ((v) >= 0)

#define gp_PrimaryVertexIndexBound(theGraph) (gp_GetFirstVertex(theGraph) + (theGraph)->N)
#define gp_VertexIndexBound(theGraph) (gp_PrimaryVertexIndexBound(theGraph) + (theGraph)->N)

#define gp_IsVirtualVertex(theGraph, v) ((v) >= theGraph->N)
#define gp_IsNotVirtualVertex(theGraph, v) ((v) < theGraph->N)
#define gp_VirtualVertexInUse(theGraph, virtualVertex) (gp_IsArc(gp_GetFirstArc(theGraph, virtualVertex)))
#define gp_VirtualVertexNotInUse(theGraph, virtualVertex) (gp_IsNotArc(gp_GetFirstArc(theGraph, virtualVertex)))
#define gp_GetFirstVirtualVertex(theGraph) (theGraph->N)
#define gp_GetLastVirtualVertex(theGraph) (theGraph->N + theGraph->NV - 1)
#define gp_VirtualVertexInRange(theGraph, v) ((v) < theGraph->N + theGraph->NV)

#else
#error NIL must be 0 or -1
#endif

#define gp_GetRootFromDFSChild(theGraph, c) ((c) + theGraph->N)
#define gp_GetDFSChildFromRoot(theGraph, R) ((R) - theGraph->N)
#define gp_GetPrimaryVertexFromRoot(theGraph, R) gp_GetVertexParent(theGraph, gp_GetDFSChildFromRoot(theGraph, R))

#define gp_IsSeparatedDFSChild(theGraph, theChild) (gp_VirtualVertexInUse(theGraph, gp_GetRootFromDFSChild(theGraph, theChild)))
#define gp_IsNotSeparatedDFSChild(theGraph, theChild) (gp_VirtualVertexNotInUse(theGraph, gp_GetRootFromDFSChild(theGraph, theChild)))

#define gp_IsDFSTreeRoot(theGraph, v) gp_IsNotVertex(gp_GetVertexParent(theGraph, v))
#define gp_IsNotDFSTreeRoot(theGraph, v) gp_IsVertex(gp_GetVertexParent(theGraph, v))

// Accessors for vertex index
#define gp_GetVertexIndex(theGraph, v) (theGraph->V[v].index)
#define gp_SetVertexIndex(theGraph, v, theIndex) (theGraph->V[v].index = theIndex)

// Initializer for vertex flags
#define gp_InitVertexFlags(theGraph, v) (theGraph->V[v].flags = 0)

// Definitions and accessors for vertex flags
#define VERTEX_VISITED_MASK		1
#define gp_GetVertexVisited(theGraph, v) (theGraph->V[v].flags&VERTEX_VISITED_MASK)
#define gp_ClearVertexVisited(theGraph, v) (theGraph->V[v].flags &= ~VERTEX_VISITED_MASK)
#define gp_SetVertexVisited(theGraph, v) (theGraph->V[v].flags |= VERTEX_VISITED_MASK)

// The obstruction type is defined by bits 1-3, 2+4+8=14
// Bit 1 - 2 if type set, 0 if not
// Bit 2 - 4 if Y side, 0 if X side
// Bit 3 - 8 if high, 0 if low
#define VERTEX_OBSTRUCTIONTYPE_MASK		14

// Call gp_GetVertexObstructionType, then compare to one of these four possibilities
// VERTEX_OBSTRUCTIONTYPE_HIGH_RXW - On the external face path between vertices R and X
// VERTEX_OBSTRUCTIONTYPE_LOW_RXW  - X or on the external face path between vertices X and W
// VERTEX_OBSTRUCTIONTYPE_HIGH_RYW - On the external face path between vertices R and Y
// VERTEX_OBSTRUCTIONTYPE_LOW_RYW  - Y or on the external face path between vertices Y and W
// VERTEX_OBSTRUCTIONTYPE_UNKNOWN  - corresponds to all three bits off
#define VERTEX_OBSTRUCTIONTYPE_HIGH_RXW    	10
#define VERTEX_OBSTRUCTIONTYPE_LOW_RXW     	2
#define VERTEX_OBSTRUCTIONTYPE_HIGH_RYW    	14
#define VERTEX_OBSTRUCTIONTYPE_LOW_RYW    	6
#define VERTEX_OBSTRUCTIONTYPE_UNKNOWN		0

#define VERTEX_OBSTRUCTIONTYPE_MARKED		2
#define VERTEX_OBSTRUCTIONTYPE_UNMARKED		0

#define gp_GetVertexObstructionType(theGraph, v) (theGraph->V[v].flags&VERTEX_OBSTRUCTIONTYPE_MASK)
#define gp_ClearVertexObstructionType(theGraph, v) (theGraph->V[v].flags &= ~VERTEX_OBSTRUCTIONTYPE_MASK)
#define gp_SetVertexObstructionType(theGraph, v, type) (theGraph->V[v].flags |= type)
#define gp_ResetVertexObstructionType(theGraph, v, type) \
	(theGraph->V[v].flags = (theGraph->V[v].flags & ~VERTEX_OBSTRUCTIONTYPE_MASK) | type)

#define gp_CopyVertexRec(dstGraph, vdst, srcGraph, vsrc) (dstGraph->V[vdst] = srcGraph->V[vsrc])

#define gp_SwapVertexRec(dstGraph, vdst, srcGraph, vsrc) \
	{ \
		vertexRec tempV = dstGraph->V[vdst]; \
		dstGraph->V[vdst] = srcGraph->V[vsrc]; \
		srcGraph->V[vsrc] = tempV; \
	}

/********************************************************************
 This structure defines a pair of links used by each vertex and virtual vertex
 to create "short circuit" paths that eliminate unimportant vertices from
 the external face, enabling more efficient traversal of the external face.

 It is also possible to embed the "short circuit" edges, but this approach
 creates a better separation of concerns, imparts greater clarity, and
 removes exceptionalities for handling additional fake "short circuit" edges.

 vertex[2]: The two adjacent vertices along the external face, possibly
 	 	    short-circuiting paths of inactive vertices.
*/

typedef struct
{
    int vertex[2];
} extFaceLinkRec;

typedef extFaceLinkRec * extFaceLinkRecP;

#define gp_GetExtFaceVertex(theGraph, v, link) (theGraph->extFace[v].vertex[link])
#define gp_SetExtFaceVertex(theGraph, v, link, theVertex) (theGraph->extFace[v].vertex[link] = theVertex)

/********************************************************************
 Vertex Info Structure Definition.

 This structure equips the primary (non-virtual) vertices with additional
 information needed for lowpoint and planarity-related algorithms.

	parent: The DFI of the DFS tree parent of this vertex
	leastAncestor: min(DFI of neighbors connected by backedge)
	lowpoint: min(leastAncestor, min(lowpoint of DFS Children))

	visitedInfo: enables algorithms to manage vertex visitation with more than
				 just a flag.  For example, the planarity test flags visitation
				 as a step number that implicitly resets on each step, whereas
				 part of the planar drawing method signifies a first visitation
				 by storing the index of the first edge used to reach a vertex
	pertinentEdge: Used by the planarity method; during Walkup, each vertex
	            that is directly adjacent via a back edge to the vertex v
	            currently being embedded will have the forward edge's index
	            stored in this field.  During Walkdown, each vertex for which
	            this field is set will cause a back edge to be embedded.
                Implicitly resets at each vertex step of the planarity method
	pertinentRootsList: used by Walkup to store a list of child bicomp roots of
                a vertex descendant of the current vertex that are pertinent
                and must be merged by the Walkdown in order to embed the cycle
                edges of the current vertex.  Future pertinent child bicomp roots
                are placed at the end of the list to ensure bicomps that are
                only pertinent are processed first.
    futurePertinentChild: indicates a DFS child with a lowpoint less than the
    			current vertex v.  This member is initialized to the start of
    			the sortedDFSChildList and is advanced in a relaxed manner as
    			needed until one with a lowpoint less than v is found or until
    			there are no more children.
    sortedDFSChildList: at the start of embedding, the list of DFS children of
    			this vertex is calculated in ascending order by DFI (sorted in
    			linear time). The list is used during Walkdown processing of
    			a vertex to process all of its children.  It is also used in
    			future pertinence management when processing the ancestors of
    			the vertex. When a child C is merged into the same bicomp as
    			the vertex, it is removed from the list.
	fwdArcList: at the start of embedding, the "back" edges from a vertex to
                its DFS *descendants* (i.e. the forward arcs of the back edges)
                are separated from the main adjacency list and placed in a
                circular list until they are embedded. The list is sorted in
                ascending DFI order of the descendants (in linear time).
                This member indicates a node in that list.
*/

typedef struct
{
	int parent, leastAncestor, lowpoint;

    int visitedInfo;

    int pertinentEdge,
		pertinentRoots,
		futurePertinentChild,
		sortedDFSChildList,
		fwdArcList;
} vertexInfo;

typedef vertexInfo * vertexInfoP;

#define gp_GetVertexVisitedInfo(theGraph, v) (theGraph->VI[v].visitedInfo)
#define gp_SetVertexVisitedInfo(theGraph, v, theVisitedInfo) (theGraph->VI[v].visitedInfo = theVisitedInfo)

#define gp_GetVertexParent(theGraph, v) (theGraph->VI[v].parent)
#define gp_SetVertexParent(theGraph, v, theParent) (theGraph->VI[v].parent = theParent)

#define gp_GetVertexLeastAncestor(theGraph, v) (theGraph->VI[v].leastAncestor)
#define gp_SetVertexLeastAncestor(theGraph, v, theLeastAncestor) (theGraph->VI[v].leastAncestor = theLeastAncestor)

#define gp_GetVertexLowpoint(theGraph, v) (theGraph->VI[v].lowpoint)
#define gp_SetVertexLowpoint(theGraph, v, theLowpoint) (theGraph->VI[v].lowpoint = theLowpoint)

#define gp_GetVertexPertinentEdge(theGraph, v) (theGraph->VI[v].pertinentEdge)
#define gp_SetVertexPertinentEdge(theGraph, v, e) (theGraph->VI[v].pertinentEdge = e)

#define gp_GetVertexPertinentRootsList(theGraph, v) (theGraph->VI[v].pertinentRoots)
#define gp_SetVertexPertinentRootsList(theGraph, v, pertinentRootsHead) (theGraph->VI[v].pertinentRoots = pertinentRootsHead)

#define gp_GetVertexFirstPertinentRoot(theGraph, v) gp_GetRootFromDFSChild(theGraph, theGraph->VI[v].pertinentRoots)
#define gp_GetVertexFirstPertinentRootChild(theGraph, v) (theGraph->VI[v].pertinentRoots)
#define gp_GetVertexLastPertinentRoot(theGraph, v)  gp_GetRootFromDFSChild(theGraph, LCGetPrev(theGraph->BicompRootLists, theGraph->VI[v].pertinentRoots, NIL))
#define gp_GetVertexLastPertinentRootChild(theGraph, v)  LCGetPrev(theGraph->BicompRootLists, theGraph->VI[v].pertinentRoots, NIL)

#define gp_DeleteVertexPertinentRoot(theGraph, v, R) \
			gp_SetVertexPertinentRootsList(theGraph, v, \
				LCDelete(theGraph->BicompRootLists, gp_GetVertexPertinentRootsList(theGraph, v), gp_GetDFSChildFromRoot(theGraph, R)))

#define gp_PrependVertexPertinentRoot(theGraph, v, R) \
			gp_SetVertexPertinentRootsList(theGraph, v, \
				LCPrepend(theGraph->BicompRootLists, gp_GetVertexPertinentRootsList(theGraph, v), gp_GetDFSChildFromRoot(theGraph, R)))

#define gp_AppendVertexPertinentRoot(theGraph, v, R) \
			gp_SetVertexPertinentRootsList(theGraph, v, \
				LCAppend(theGraph->BicompRootLists, gp_GetVertexPertinentRootsList(theGraph, v), gp_GetDFSChildFromRoot(theGraph, R)))

#define gp_GetVertexFuturePertinentChild(theGraph, v) (theGraph->VI[v].futurePertinentChild)
#define gp_SetVertexFuturePertinentChild(theGraph, v, theFuturePertinentChild) (theGraph->VI[v].futurePertinentChild = theFuturePertinentChild)

// Used to advance futurePertinentChild of w to the next separated DFS child with a lowpoint less than v
// Once futurePertinentChild advances past a child, no future planarity operation could make that child
// relevant to future pertinence
#define gp_UpdateVertexFuturePertinentChild(theGraph, w, v) \
	while (gp_IsVertex(theGraph->VI[w].futurePertinentChild)) \
	{ \
		/* Skip children that 1) aren't future pertinent, 2) have been merged into the bicomp with w */ \
		if (gp_GetVertexLowpoint(theGraph, theGraph->VI[w].futurePertinentChild) >= v || \
			gp_IsNotSeparatedDFSChild(theGraph, theGraph->VI[w].futurePertinentChild)) \
        { \
			theGraph->VI[w].futurePertinentChild = \
					gp_GetVertexNextDFSChild(theGraph, w, gp_GetVertexFuturePertinentChild(theGraph, w)); \
        } \
        else break; \
	}

#define gp_GetVertexSortedDFSChildList(theGraph, v) (theGraph->VI[v].sortedDFSChildList)
#define gp_SetVertexSortedDFSChildList(theGraph, v, theSortedDFSChildList) (theGraph->VI[v].sortedDFSChildList = theSortedDFSChildList)

#define gp_GetVertexNextDFSChild(theGraph, v, c) LCGetNext(theGraph->sortedDFSChildLists, gp_GetVertexSortedDFSChildList(theGraph, v), c)

#define gp_AppendDFSChild(theGraph, v, c) \
		LCAppend(theGraph->sortedDFSChildLists, gp_GetVertexSortedDFSChildList(theGraph, v), c)

#define gp_GetVertexFwdArcList(theGraph, v) (theGraph->VI[v].fwdArcList)
#define gp_SetVertexFwdArcList(theGraph, v, theFwdArcList) (theGraph->VI[v].fwdArcList = theFwdArcList)

#define gp_CopyVertexInfo(dstGraph, dstI, srcGraph, srcI) (dstGraph->VI[dstI] = srcGraph->VI[srcI])

#define gp_SwapVertexInfo(dstGraph, dstPos, srcGraph, srcPos) \
	{ \
		vertexInfo tempVI = dstGraph->VI[dstPos]; \
		dstGraph->VI[dstPos] = srcGraph->VI[srcPos]; \
		srcGraph->VI[srcPos] = tempVI; \
	}

/********************************************************************
 Variables needed in embedding by Kuratowski subgraph isolator:
        minorType: the type of planarity obstruction found.
        v: the current vertex being processed
        r: the root of the bicomp on which the Walkdown failed
        x,y: stopping vertices on bicomp rooted by r
        w: pertinent vertex on ext. face path below x and y
        px, py: attachment points of x-y path,
        z: Unused except in minors D and E (not needed in A, B, C).

        ux,dx: endpoints of unembedded edge that helps connext x with
                ancestor of v
        uy,dy: endpoints of unembedded edge that helps connext y with
                ancestor of v
        dw: descendant endpoint in unembedded edge to v
        uz,dz: endpoints of unembedded edge that helps connext z with
                ancestor of v (for minors B and E, not A, C, D).
*/

typedef struct
{
    int minorType;
    int v, r, x, y, w, px, py, z;
    int ux, dx, uy, dy, dw, uz, dz;
} isolatorContext;

typedef isolatorContext * isolatorContextP;

#define MINORTYPE_A         1
#define MINORTYPE_B         2
#define MINORTYPE_C         4
#define MINORTYPE_D         8
#define MINORTYPE_E         16
#define MINORTYPE_E1        32
#define MINORTYPE_E2        64
#define MINORTYPE_E3        128
#define MINORTYPE_E4        256

#define MINORTYPE_E5        512
#define MINORTYPE_E6        1024
#define MINORTYPE_E7        2048

/********************************************************************
 Graph structure definition
        V : Array of vertex records (allocated size N + NV)
        VI: Array of additional vertexInfo structures (allocated size N)
        N : Number of primary vertices (the "order" of the graph)
        NV: Number of virtual vertices (currently always equal to N)

        E : Array of edge records (edge records come in pairs and represent half edges, or arcs)
        M: Number of edges (the "size" of the graph)
        arcCapacity: the maximum number of edge records allowed in E (the size of E)
        edgeHoles: free locations in E where edges have been deleted

        theStack: Used by various graph routines needing a stack
        internalFlags: Additional state information about the graph
        embedFlags: controls type of embedding (e.g. planar)

        IC: contains additional useful variables for Kuratowski subgraph isolation.
        BicompRootLists: storage space for pertinent bicomp root lists that develop
                        during embedding
        sortedDFSChildLists: storage for the sorted DFS child lists of each vertex
        extFace: Array of (N + NV) external face short circuit records

        extensions: a list of extension data structures
        functions: a table of function pointers that can be overloaded to provide
                   extension behaviors to the graph
*/

typedef struct
{
        vertexRecP V;
        vertexInfoP VI;
        int N, NV;

        edgeRecP E;
        int M, arcCapacity;
        stackP edgeHoles;

        stackP theStack;
        int internalFlags, embedFlags;

        isolatorContext IC;
        listCollectionP BicompRootLists, sortedDFSChildLists;
        extFaceLinkRecP extFace;

        graphExtensionP extensions;
        graphFunctionTable functions;

} baseGraphStructure;

typedef baseGraphStructure * graphP;

/* Flags for graph:
        FLAGS_DFSNUMBERED is set if DFSNumber() has succeeded for the graph
        FLAGS_SORTEDBYDFI records whether the graph is in original vertex
                order or sorted by depth first index.  Successive calls to
                SortVertices() toggle this bit.
        FLAGS_OBSTRUCTIONFOUND is set by gp_Embed() if an embedding obstruction
                was isolated in the graph returned.  It is cleared by gp_Embed()
                if an obstruction was not found.  The flag is used by
                gp_TestEmbedResultIntegrity() to decide what integrity tests to run.
        FLAGS_ZEROBASEDIO is typically set by gp_Read() to indicate that the
        		adjacency list representation began with index 0.
*/

#define FLAGS_DFSNUMBERED       1
#define FLAGS_SORTEDBYDFI       2
#define FLAGS_OBSTRUCTIONFOUND  4
#define FLAGS_ZEROBASEDIO		8

/********************************************************************
 More link structure accessors/manipulators
 ********************************************************************/

// Definitions that enable getting the next or previous arc
// as if the adjacency list were circular, i.e. that the
// first arc and last arc were linked
#define gp_GetNextArcCircular(theGraph, e) \
	(gp_IsArc(gp_GetNextArc(theGraph, e)) ? \
			gp_GetNextArc(theGraph, e) : \
			gp_GetFirstArc(theGraph, theGraph->E[gp_GetTwinArc(theGraph, e)].neighbor))

#define gp_GetPrevArcCircular(theGraph, e) \
	(gp_IsArc(gp_GetPrevArc(theGraph, e)) ? \
		gp_GetPrevArc(theGraph, e) : \
		gp_GetLastArc(theGraph, theGraph->E[gp_GetTwinArc(theGraph, e)].neighbor))

// Definitions that make the cross-link binding between a vertex and an arc
// The old first or last arc should be bound to this arc by separate calls,
// e.g. see gp_AttachFirstArc() and gp_AttachLastArc()
#define gp_BindFirstArc(theGraph, v, arc) \
	{ \
		gp_SetPrevArc(theGraph, arc, NIL); \
		gp_SetFirstArc(theGraph, v, arc); \
    }

#define gp_BindLastArc(theGraph, v, arc) \
	{ \
    	gp_SetNextArc(theGraph, arc, NIL); \
    	gp_SetLastArc(theGraph, v, arc); \
    }

// Attaches an arc between the current binding between a vertex and its first arc
#define gp_AttachFirstArc(theGraph, v, arc) \
	{ \
		if (gp_IsArc(gp_GetFirstArc(theGraph, v))) \
		{ \
			gp_SetNextArc(theGraph, arc, gp_GetFirstArc(theGraph, v)); \
			gp_SetPrevArc(theGraph, gp_GetFirstArc(theGraph, v), arc); \
		} \
		else gp_BindLastArc(theGraph, v, arc); \
		gp_BindFirstArc(theGraph, v, arc); \
	}

// Attaches an arc between the current binding betwen a vertex and its last arc
#define gp_AttachLastArc(theGraph, v, arc) \
	{ \
		if (gp_IsArc(gp_GetLastArc(theGraph, v))) \
		{ \
			gp_SetPrevArc(theGraph, arc, gp_GetLastArc(theGraph, v)); \
			gp_SetNextArc(theGraph, gp_GetLastArc(theGraph, v), arc); \
		} \
		else gp_BindFirstArc(theGraph, v, arc); \
		gp_BindLastArc(theGraph, v, arc); \
	}

// Moves an arc that is in the adjacency list of v to the start of the adjacency list
#define gp_MoveArcToFirst(theGraph, v, arc) \
	if (arc != gp_GetFirstArc(theGraph, v)) \
	{ \
		/* If the arc is last in the adjacency list of uparent,
		   then we delete it by adjacency list end management */ \
		if (arc == gp_GetLastArc(theGraph, v)) \
		{ \
		    gp_SetNextArc(theGraph, gp_GetPrevArc(theGraph, arc), NIL); \
			gp_SetLastArc(theGraph, v, gp_GetPrevArc(theGraph, arc)); \
		} \
		/* Otherwise, we delete the arc from the middle of the list */ \
		else \
		{ \
			gp_SetNextArc(theGraph, gp_GetPrevArc(theGraph, arc), gp_GetNextArc(theGraph, arc)); \
			gp_SetPrevArc(theGraph, gp_GetNextArc(theGraph, arc), gp_GetPrevArc(theGraph, arc)); \
		} \
\
		/* Now add arc e as the new first arc of uparent.
		   Note that the adjacency list is non-empty at this time */ \
		 gp_SetNextArc(theGraph, arc, gp_GetFirstArc(theGraph, v)); \
		 gp_SetPrevArc(theGraph, gp_GetFirstArc(theGraph, v), arc); \
		 gp_BindFirstArc(theGraph, v, arc); \
	}

// Moves an arc that is in the adjacency list of v to the end of the adjacency list
#define gp_MoveArcToLast(theGraph, v, arc) \
	if (arc != gp_GetLastArc(theGraph, v)) \
	{ \
		 /* If the arc is first in the adjacency list of vertex v,
		    then we delete it by adjacency list end management */ \
		 if (arc == gp_GetFirstArc(theGraph, v)) \
		 { \
			 gp_SetPrevArc(theGraph, gp_GetNextArc(theGraph, arc), NIL); \
			 gp_SetFirstArc(theGraph, v, gp_GetNextArc(theGraph, arc)); \
		 } \
		 /* Otherwise, we delete the arc from the middle of the list */ \
		 else \
		 { \
			 gp_SetNextArc(theGraph, gp_GetPrevArc(theGraph, arc), gp_GetNextArc(theGraph, arc)); \
			 gp_SetPrevArc(theGraph, gp_GetNextArc(theGraph, arc), gp_GetPrevArc(theGraph, arc)); \
		 } \
\
		 /* Now add the arc as the new last arc of v.
		    Note that the adjacency list is non-empty at this time */ \
		 gp_SetPrevArc(theGraph, arc, gp_GetLastArc(theGraph, v)); \
		 gp_SetNextArc(theGraph, gp_GetLastArc(theGraph, v), arc); \
		 gp_BindLastArc(theGraph, v, arc); \
	}

// Methods for attaching an arc into the adjacency list or detaching an arc from it.
// The terms AddArc, InsertArc and DeleteArc are not used because the arcs are not
// inserted or added to or deleted from storage (only whole edges are inserted or deleted)
void	gp_AttachArc(graphP theGraph, int v, int e, int link, int newArc);
void 	gp_DetachArc(graphP theGraph, int arc);

/********************************************************************
 PERTINENT()
 A vertex is pertinent in a partially processed graph if there is an
 unprocessed back edge between the vertex v whose edges are currently
 being processed and either the vertex or a DFS descendant D of the
 vertex not in the same bicomp as the vertex.

 The vertex is either directly adjacent to v by an unembedded back edge
 or there is an unembedded back edge (v, D) and the vertex is a cut
 vertex in the partially processed graph along the DFS tree path from
 D to v.

 Pertinence is a dynamic property that can change for a vertex after
 each edge addition.  In other words, a vertex can become non-pertinent
 during step v as more back edges to v are embedded.
 ********************************************************************/

#define PERTINENT(theGraph, theVertex) \
		(gp_IsArc(gp_GetVertexPertinentEdge(theGraph, theVertex)) || \
		 gp_IsVertex(gp_GetVertexPertinentRootsList(theGraph, theVertex)))

#define NOTPERTINENT(theGraph, theVertex) \
		(gp_IsNotArc(gp_GetVertexPertinentEdge(theGraph, theVertex)) && \
		 gp_IsNotVertex(gp_GetVertexPertinentRootsList(theGraph, theVertex)))

/********************************************************************
 FUTUREPERTINENT()
 A vertex is future-pertinent in a partially processed graph if
 there is an unprocessed back edge between a DFS ancestor A of the
 vertex v whose edges are currently being processed and either
 theVertex or a DFS descendant D of theVertex not in the same bicomp
 as theVertex.

 Either theVertex is directly adjacent to A by an unembedded back edge
 or there is an unembedded back edge (A, D) and theVertex is a cut
 vertex in the partially processed graph along the DFS tree path from
 D to A.

 If no more edges are added to the partially processed graph prior to
 processing the edges of A, then the vertex would be pertinent.
 The addition of edges to the partially processed graph can alter
 both the pertinence and future pertinence of a vertex.  For example,
 if the vertex is pertinent due to an unprocessed back edge (v, D1) and
 future pertinent due to an unprocessed back edge (A, D2), then the
 vertex may lose both its pertinence and future pertinence when edge
 (v, D1) is added if D2 is in the same subtree as D1.

 Generally, pertinence and future pertinence are dynamic properties
 that can change for a vertex after each edge addition.

 Note that gp_UpdateVertexFuturePertinentChild() must be called before
 this macro. Since it is a statement and not a void expression, the
 desired commented out version does not compile (except with special
 compiler extensions not assumed by this code).
 ********************************************************************/

#define FUTUREPERTINENT(theGraph, theVertex, v) \
        (  theGraph->VI[theVertex].leastAncestor < v || \
           (gp_IsVertex(theGraph->VI[theVertex].futurePertinentChild) && \
            theGraph->VI[theGraph->VI[theVertex].futurePertinentChild].lowpoint < v) )

#define NOTFUTUREPERTINENT(theGraph, theVertex, v) \
        (  theGraph->VI[theVertex].leastAncestor >= v && \
           (gp_IsNotVertex(theGraph->VI[theVertex].futurePertinentChild) || \
            theGraph->VI[theGraph->VI[theVertex].futurePertinentChild].lowpoint >= v) )

// This is the definition that would be preferrable if a while loop could be a void expression
//#define FUTUREPERTINENT(theGraph, theVertex, v)
//        (  theGraph->VI[theVertex].leastAncestor < v ||
//           ((gp_UpdateVertexFuturePertinentChild(theGraph, theVertex, v),
//        	   gp_IsArc(theGraph->VI[theVertex].futurePertinentChild)) &&
//             theGraph->VI[theGraph->VI[theVertex].futurePertinentChild].lowpoint < v) )

/********************************************************************
 INACTIVE()
 For planarity algorithms, a vertex is inactive if it is neither pertinent
 nor future pertinent.
 ********************************************************************/

#define INACTIVE(theGraph, theVertex, v) \
        (  NOTPERTINENT(theGraph, theVertex) && \
           NOTFUTUREPERTINENT(theGraph, theVertex, v))

#ifdef __cplusplus
}
#endif

#endif
libplanarity-dev 3.0.0.5-1+b1 / usr / include / planarity / graphStructures.h
