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*
* This file is part of Tulip (www.tulip-software.org)
*
* Authors: David Auber and the Tulip development Team
* from LaBRI, University of Bordeaux
*
* Tulip is free software; you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* Tulip is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details.
*
*/
#ifndef Tulip_SUPERGRAPH_H
#define Tulip_SUPERGRAPH_H
#include <iostream>
#include <string>
#include <vector>
#include <climits>
#include <tulip/tulipconf.h>
#include <tulip/DataSet.h>
#include <tulip/Node.h>
#include <tulip/Edge.h>
#include <tulip/Observable.h>
namespace tlp {
class PropertyInterface;
class BooleanProperty;
class PluginProgress;
template<class C>struct Iterator;
/**
* @enum This Enum describes the possible types of an element of the graph.
*
* It is used in functions that can return an edge or a node, to distinguish between the two cases.
**/
enum ElementType {
/** This element describes a node **/
NODE = 0,
/** This element describes an edge **/
EDGE = 1
};
/**
* @ingroup Graph
* @brief Loads a graph from a file (extension can be any of the Tulip supported input graph file format).
*
* This function loads a graph serialized in a file trough the available Tulip import plugins.
* Since Tulip 4.8, the selection of the import plugin is based on the provided filename extension.
* The import will fail if the selected import plugin is not loaded.
* The graph file formats that can currently be imported are : TLP (*.tlp, *.tlp.gz), TLP Binary (*.tlpb, *.tlpb.gz), TLP JSON (*.json),
* Gephi (*.gexf), Pajek (*.net, *.paj), GML (*.gml), Graphviz (*.dot) and UCINET (*.txt)
*
* Before Tulip 4.8 and as a fallback, the function uses the "TLP Import" import plugin
* (always loaded as it is linked into the tulip-core library).
*
* If the import fails (no such file, parse error, ...) NULL is returned.
*
* @param filename the file in one of the supported formats to parse.
* @return Graph* the imported Graph, NULL if the import failed.
**/
TLP_SCOPE Graph * loadGraph(const std::string &filename, tlp::PluginProgress* progress = NULL);
/**
* @ingroup Graph
* @brief Saves the corresponding graph to a file (extension can be any of the Tulip supported ouput graph file format)..
*
* This function serializes the corresponding graph and all its subgraphs (depending on the format) to a file
* through the available Tulip export plugins.
* Since Tulip 4.8, the selection of the export plugin is based on the provided filename extension.
* The export will fail if the selected export plugin is not loaded.
* The file formats the graph can be exported to are : TLP (*.tlp, *.tlp.gz), TLP Binary (*.tlpb, *.tlpb.gz),
* TLP JSON (*.json) and GML (*.gml)
*
* This function checks the file name for the '.gz' extension and uses a compressed output if supported (TLP and TLP Binary only).
*
* Before Tulip 4.8 and as a fallback, this function uses the "TLP Export" export plugin
* (always loaded as it is linked into the tulip-core library).
*
* @param graph the graph to save.
* @param filename the file to save the graph to.
* @return bool whether the export was successfull or not.
**/
TLP_SCOPE bool saveGraph(Graph* graph, const std::string &filename, tlp::PluginProgress* progress = NULL);
/**
* @ingroup Graph
* @brief Exports a graph using the specified export plugin with parameters stored in the DataSet.
*
* You determine the destination, whether by using a fstream, or by saving the contents of the stream to the destination of your choice.
*
* @param graph The graph to export.
* @param outputStream The stream to export to. Can be a standard ostream, an ofstream, or even a gzipped ostream.
* @param format The format to use to export the Graph.
* @param dataSet The parameters to pass to the export plugin (e.g. additional data, options for the format)
* @param progress A PluginProgress to report the progress of the operation, as well as final state. Defaults to NULL.
* @return bool Whether the export was successfull or not.
**/
TLP_SCOPE bool exportGraph(Graph *graph, std::ostream &outputStream, const std::string &format, DataSet &dataSet, PluginProgress *progress=NULL);
/**
* @ingroup Graph
* @brief Imports a graph using the specified import plugin with the parameters stored in the DataSet.
*
* If no graph is passed, then a new graph will be created. You can pass a graph in order to import data into it.
* Returns the graph with imported data, or NULL if the import failed. In this case, the Pluginprogress should have an error that can be displayed.
*
* @param format The format to use to import the graph.
* @param dataSet The parameters to pass to the import plugin (file to read, ...)
* @param progress A PluginProgress to report the progress of the operation, as well as final state. Defaults to NULL.
* @param newGraph The graph to import the data into. This can be usefull to import data into a subgraph. Defaults to NULL.
* @return :Graph* The graph containing the imported data, or NULL in case of failure.
**/
TLP_SCOPE Graph* importGraph(const std::string &format, DataSet &dataSet, PluginProgress *progress=NULL,Graph *newGraph=NULL);
/**
* @ingroup Graph
* @brief Creates a new, empty graph.
*
* This is a simple method factory to create a Graph implementation (remember, Graph is only an interface).
*
* This is the recommended way to create a new Graph.
*
* @return :Graph* A new, empty graph.
**/
TLP_SCOPE Graph* newGraph();
/**
* @ingroup Graph
* Appends the selected part of the graph inG (properties, nodes and edges) into the graph outG.
* If no selection is done (inSel=NULL), the whole inG graph is appended.
* The output selection is used to select the appended nodes & edges
* \warning The input selection is extended to all selected edge ends.
*/
TLP_SCOPE void copyToGraph(Graph *outG, const Graph *inG, BooleanProperty* inSelection=NULL, BooleanProperty* outSelection=NULL );
/**
* @ingroup Graph
* Removes the selected part of the graph ioG (properties values, nodes and edges).
* If no selection is done (inSel=NULL), the whole graph is reseted to default value.
* \warning The selection is extended to all selected edge ends.
*/
TLP_SCOPE void removeFromGraph(Graph * ioG, BooleanProperty* inSelection=NULL);
/**
* @ingroup Graph
* Gets an iterator over the root graphs. That is all the currently existing graphs which have been created using the tlp::newGraph, tlp::loadGraph or tlp::importGraph functions and are the root graphs of an existing graph hierarchy.
* @return An iterator over all the root graphs. The caller of this function is responsible of the deletion of the returned iterator.
*/
TLP_SCOPE Iterator<Graph*>* getRootGraphs();
/**
* @ingroup Graph
* The class Graph is the interface of a Graph in the Tulip Library.
*
* There are a few principles to know when working with a Tulip Graph.
*
* @chapter Directed
* Every edge is directed in a Tulip Graph.
* You can choose to ignore this, but every edge has a source and destination.
*
* @chapter Inheritance
*
* Subgraphs inherit from their parent graph.
* This is true of nodes and edges; every node and edge in a subgraph also exists in each of its parent graphs.
* This is also true of properties; every property in a graph exist in all of its subgraphs, except if it has been replaced
* by a local property.
*
* For instance, if you have the following graph hierarchy:
* root
* / \
* A B
*
* Every node in A is in root, and every node in B is in root.
* Nodes can be in A and root but not B; or in B and root but not A.
*
* For instance, imagine a graph. You want to compare it to its Delaunay triangulation.
* You need to create a subgraph that is a clone of the original (say this is A) to keep the original graph,
* and another copy (say this one is B) on which you will perform the delaunay triangulation.
*
* B will have none of the original edges, and A will have only the original edges.
*
* As for properties; let's imagine the same graph hierarchy.
* You want to compare two different layouts on the same graph.
* You need to create two clone subgraphs, on each you make the 'viewLayout' property local.
* This results in A and B having different values for the layout, but everything else in common.
* You then can apply two different algorithms on A and B (e.g. Bubble Tree and Tree Radial).
*
* @chapter Meta Nodes
* A meta node is a node representing a subgraph of the current graph.
*
* @chapter Undo Redo
* The Tulip Graph object supports for undo and redo of modifications.
*The operations affect the whole graph hierarchy, and cannot be limited to a subgraph.
*
*/
class TLP_SCOPE Graph : public Observable {
friend class GraphAbstract;
friend class GraphUpdatesRecorder;
friend class GraphDecorator;
friend class PropertyManager;
friend class PropertyInterface;
public:
Graph():id(0) {}
virtual ~Graph() {}
/**
* @brief Applies an algorithm plugin, identified by its name.
* Algorithm plugins are subclasses of the tlp::Algorithm interface.
* Parameters are transmitted to the algorithm trough the DataSet.
* To determine a plugin's parameters, you can either:
*
* * refer to its documentation
*
* * use buildDefaultDataSet on the plugin object if you have an instance of it
*
* * call getPluginParameters() with the name of the plugin on the PluginLister
*
*
* If an error occurs, a message describing the error should be stored in errorMessage.
*
* @param algorithm The algorithm to apply.
* @param errorMessage A string that will be modified to contain an error message should an error occur.
* @param dataSet The parameters to the algorithm. Defaults to NULL.
* @param progress A PluginProgress to report the progress of the operation, as well as final state. Defaults to NULL.
* @return bool Whether the algorithm was successfully applied.
**/
bool applyAlgorithm(const std::string &algorithm, std::string &errorMessage, DataSet *dataSet=NULL, PluginProgress *progress=NULL);
//=========================================================================
// Graph hierarchy access and building
//=========================================================================
/**
* @brief Removes all nodes, edges and sub-graphs from this graph.
*
* Contrarily to creating a new Graph, this keeps attributes and properties.
*
* @return void
**/
virtual void clear()=0;
/**
* @brief Creates and returns a new sub-graph of this graph.
*
* If a BooleanProperty is provided, all the nodes and edges for which it is true will be added to the subgraph.
* If none is provided, then the subgraph will be empty.
*
* The id parameter should only be provided if you know exactly what you are doing; as Tulip will manage the subgraphs IDs when left to 0.
* It is only used by the Graph loading as subgraphs ids are preserved when saving/loading a Graph.
*
* @param selection The elements to add to the new subgraph. Defaults to 0.
* @param name The name of the newly created subgraph. Defaults to "unnamed".
* @return :Graph* The newly created subgraph.
**/
virtual Graph *addSubGraph(BooleanProperty *selection=NULL,
const std::string& name = "unnamed")=0;
/**
* @brief Creates and returns a new named sub-graph of this graph.
*
* @param name The name of the newly created subgraph.
* @return :Graph* The newly created subgraph.
**/
Graph *addSubGraph(const std::string& name);
/**
* @brief Creates and returns a subgraph that contains all the elements of this graph.
*
* @param name The name of the newly created subgraph. Defaults to "unnamed".
* @param addSibling if true the clone subgraph will be a sibling of this graph, if false (the default) it will be a subgraph of this graph
* @return :Graph* The newly created clone subgraph. NULL will be returned if addSibling is set to true and this graph is a root graph.
**/
virtual Graph* addCloneSubGraph(const std::string& name = "unnamed", bool addSibling = false);
/**
* @brief Creates and returns a new sub-graph of the graph induced by a set of nodes.
* Every node contained in the given set of nodes is added to the subgraph.
* Every edge connecting any two nodes in the set of given nodes is also added.
* @param nodeSet The nodes to add to the subgraph. All the edges between these nodes are added too.
* @param parentSubGraph If provided, is used as parent graph for the newly created subgraph instead of the graph this method is called on.
* @return The newly created subgraph.
*/
Graph *inducedSubGraph(const std::set<node>& nodeSet,
Graph* parentSubGraph = NULL);
/**
* @brief Deletes a sub-graph of this graph.
* All subgraphs of the removed graph are re-parented to this graph.
* For instance, with a graph hierarchy as follows :
* root
* / \
* A B
* /|\
* C D E
*
* @code root->delSubGraph(B);
* would result in the following hierarchy:
* root
* / | \\
* A C D E
*
* @param graph The subgraph to delete.
*
* @see delAllSubGraphs() if you want to remove all descendants of a graph.
*/
virtual void delSubGraph(Graph *graph)=0;
/**
* @brief Deletes a sub-graph of this graph and all of its sub-graphs.
** For instance, with a graph hierarchy as follows :
* root
* / \
* A B
* /|\
* C D E
*
* @codeline root->delSubGraph(B); @endcode
* would result in the following hierarchy:
* root
* |
* A
*
* @param graph The subgraph to delete.
* @see delSubGraph() if you want to keep the descendants of the subgraph to remove.
*/
virtual void delAllSubGraphs(Graph *graph)=0;
/**
* @brief Returns the parent of the graph. If called on the root graph, it returns itself.
* @return The parent of this graph (or itself if it is the root graph).
* @see getRoot() to directly retrieve the root graph.
*/
virtual Graph* getSuperGraph()const =0;
/**
* @brief Gets the root graph of the graph hierarchy.
* @return The root graph of the graph hierarchy.
*/
virtual Graph* getRoot() const =0;
/**
* @cond DOXYGEN_HIDDEN
* @brief Sets the parent of a graph.
* @warning ONLY USE IF YOU KNOW EXACTLY WHAT YOU ARE DOING.
* @endcond
*/
virtual void setSuperGraph(Graph *)=0;
/**
* @brief Gets an iterator over all the sub-graphs of the graph.
* For instance, in the following graph hierarchy:
** root
* / \
* A B
* /|\
* C D E
*
* @codeline root->getSubGraphs(); @endcode
* Will return an iterator over A and B, but not C, D and E.
* @return An iterator over this graph's direct subgraphs.
*/
virtual Iterator<Graph *> * getSubGraphs() const=0;
/**
* @brief This method returns the nth subgraph.
* Since subgraphs order cannot be ensured in every implementation, this method should be equivalent to:
* @code
int i=0;
Iterator<Graph *> *it = g->getSubGraphs();
while (it->hasNext()) {
Graph *result = it->next();
if (i++ == n) {
delete it;
return result;
}
}
delete it;
return NULL;
* @endcode
* @param n the index of the subgraph to retrieve.
* @return The n-th subgraph.
*/
virtual Graph *getNthSubGraph(unsigned int n) const;
/**
* @brief Return the number of direct sub-graphs.
* For instance, in the following graph hierarchy:
* root
* / \
* A B
* /|\
* C D E
*
* @codeline root->numberOfSubGraphs(); @endcode
* Will return 2.
* @return The number of direct subgraphs.
* @see numberOfDescendantGraphs() to count in the whole hierarchy.
*/
virtual unsigned int numberOfSubGraphs() const=0;
/**
* @brief Return the number of descendant sub-graphs.
* For instance, in the following graph hierarchy:
* root
* / \
* A B
* /|\
* C D E
*
* @codeline root->numberOfSubGraphs(); @endcode
* Will return 5.
* @return The number of descendants subgraphs.
* @see numberOfSubGraphs() to count only direct subgraphs.
*/
virtual unsigned int numberOfDescendantGraphs() const=0;
/**
* @brief Indicates if the graph argument is a direct sub-graph.
* @param subGraph The graph to check is a subgraph of this graph.
* @return Whether subGraph is a direct subgraph of this graph.
* @see isDescendantGraph() to search in the whole hierarchy.
*/
virtual bool isSubGraph(const Graph* subGraph) const=0;
/**
* @brief Indicates if the graph argument is a descendant of this graph.
* @param subGraph The graph to check is a descendant of this graph.
* @return Whether subGraph is a descendant of this graph.
* @see isSubGraph to search only in direct subgraphs.
*/
virtual bool isDescendantGraph(const Graph* subGraph) const=0;
/**
* @brief Returns a pointer on the sub-graph with the corresponding id
* or NULL if there is no sub-graph with that id.
* @param id The id of the subgraph to retrieve.
* @return A subgraph of the given id, or null if no such subgraph exists on this graph.
* @see getDescendantGraph(unsigned int) to search in the whole hierarchy.
*/
virtual Graph* getSubGraph(unsigned int id) const=0;
/**
* @brief Returns a pointer on the sub-graph with the corresponding name
* or NULL if there is no sub-graph with that name.
* @param name The name of the subgraph to retrieve.
* @return A Graph named name, or NULL if no such subgraph exists on this graph.
* @see getDescendantGraph(const std::string &) to search in the whole hierarchy.
*/
virtual Graph* getSubGraph(const std::string &name) const=0;
/**
* @brief Returns a pointer on the descendant with the corresponding id
* or NULL if there is no descendant with that id.
* @param id The id of the descendant graph to retrieve.
* @return A graph with the given id, or NULL if no such graph exists in this graph's descendants.
* @see getSubGraph(unsigned int) to search only in direct subgraphs.
*/
virtual Graph* getDescendantGraph(unsigned int id) const=0;
/**
* @brief Returns a pointer on the first descendant graph with the corresponding name
* or NULL if there is no descendant graph with that name.
* @param name The name of the descendant graph to look for.
* @return A graph named name, or NULL if there is no such graph in this graph's descendants.
* @see getSubGraph(const std::string &) to search only in direct subgraphs.
*/
virtual Graph* getDescendantGraph(const std::string &name) const=0;
/**
* @brief Gets an iterator over all the descendant sub-graphs of the graph.
* For instance, in the following graph hierarchy:
** root
* / \
* A B
* /|\
* C D E
*
* @codeline root->getSubGraphs(); @endcode
* Will return an iterator over A B, C, D and E.
* @return An iterator over this graph's descendant subgraphs.
*/
Iterator<Graph *> * getDescendantGraphs() const;
//==============================================================================
// Modification of the graph structure
//==============================================================================
/**
* @brief Adds a new node in the graph and returns it. This node is also added in all
* the ancestor graphs.
* @return The newly added node.
* @see addNodes() if you want to add more than one node.
*/
virtual node addNode()=0;
/**
* @brief Adds new nodes in the graph and returns them in the addedNodes vector.
* The new nodes are also added in all the ancestor graphs.
*
* @param nbNodes The number of nodes to add.
* @param addedNodes The newly added nodes. This vector is cleared before being filled.
* @see addNode() to add a single node.
*/
virtual void addNodes(unsigned int nbNodes, std::vector<node>& addedNodes)=0;
/**
* @brief Adds an existing node in the graph. This node is also added in all the ancestor graphs.
* This node must exists in the graph hierarchy (which means it must exist in the root graph).
* You cannot add a node to the root graph this way (as it must already be an element of the root graph).
* @warning Using this method on the root graph will display a warning on the console.
*
* @param n The node to add to a subgraph. This node must exist in the root graph.
* @see addNode() to add a new node to a graph.
*/
virtual void addNode(const node n)=0;
/**
* @brief Adds existing nodes in the graph. The nodes are also added in all the ancestor graphs.
* as with addNode(const tlp::node), the nodes must exist in the graph hierarchy and thus exist in the root graph,
* and node cannot be added this way to the root graph.
* @warning Using this method on the root graph will display a warning on the console.
* @warning The graph does not take ownership of the Iterator.
*
* @param nodes An iterator over nodes to add to this subgraph. The graph does not takes ownership of this iterator.
*/
virtual void addNodes(Iterator<node>* nodes)=0;
/**
* @brief Adds existing nodes in the graph. The nodes are also added in all the ancestor graphs.
* as with addNode(const tlp::node), the nodes must exist in the graph hierarchy and thus exist in the root graph,
* and nodes cannot be added this way to the root graph.
* @warning Using this method on the root graph will display a warning on the console.
*
* @param nodes a vector of nodes to add to this subgraph.
*/
void addNodes(const std::vector<node>& nodes);
/**
* @brief Deletes a node in the graph.
* This node is also removed in the sub-graphs hierarchy of the current graph.
* @param n The node to delete.
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
* @see delNodes() to remove multiple nodes.
*/
virtual void delNode(const node n, bool deleteInAllGraphs = false)=0;
/**
* @brief Deletes nodes in the graph.
* These nodes are also removed in the sub-graphs hierarchy of the current graph.
* @warning the graph does not take ownership of the Iterator.
* @param it The nodes to delete.
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
* @see delNode() to remove a single node.
*/
virtual void delNodes(Iterator<node>* it, bool deleteInAllGraphs = false)=0;
/**
* @brief Deletes nodes in the graph.
* These nodes are also removed in the sub-graphs hierarchy of the current graph.
* @warning the graph does not take ownership of the Iterator.
* @param nodes a vector of the nodes to delete.
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
* @see delNode() to remove a single node.
*/
void delNodes(const std::vector<node>& nodes, bool deleteInAllGraphs = false);
/**
* @brief Adds a new edge in the graph
* This edge is also added in all the super-graph of the graph.
* @param source The source of the edge.
* @param target The target of the edge.
* @return The newly added edge.
* @see addEdges() to add multiple edges at once.
*/
virtual edge addEdge(const node source, const node target)=0;
/**
* @brief Adds new edges in the graph and returns them the addedEdges vector.
* The new edges are also added in all the graph ancestors.
*
* @warning If the edges vector contains a node that does not belong to this graph,
* undefined behavior will ensue.
* @param edges A vector describing between which nodes to add edges.
* The first element of the pair is the source, the second is the destination.
* @param addedEdges The newly added edges. This vector is cleared before being filled.
*
*/
virtual void addEdges(const std::vector<std::pair<node, node> >& edges,
std::vector<edge>& addedEdges)=0;
/**
* @brief Adds an existing edge in the graph. This edge is also added in all
* the ancestor graphs.
* The edge must be an element of the graph hierarchy, thus it must be
* an element of the root graph.
* @warning Using this method on the root graph will display a warning on the console.
* @param e The edge to add to this subgraph.
* @see addEgdes() to add more than one edge at once.
* @see addNode() to add nodes.
*/
virtual void addEdge(const edge e)=0;
/**
* @brief Adds existing edges in the graph. The edges are also added in all
* the ancestor graphs.
* The added edges must be elements of the graph hierarchy,
* thus they must be elements of the root graph.
* @warning Using this method on the root graph will display a warning on the console.
* @warning The graph does not take ownership of the iterator.
* @param edges The edges to add on this subgraph.
*/
virtual void addEdges(Iterator<edge>* edges)=0;
/**
* @brief Adds existing edges in the graph. The edges are also added in all
* the ancestor graphs.
* The added edges must be elements of the graph hierarchy,
* thus they must be elements of the root graph.
* @warning Using this method on the root graph will display a warning on the console.
* @param edges a vector of the edges to add on this subgraph.
*/
void addEdges(const std::vector<edge>& edges);
/**
* @brief Deletes an edge in the graph. The edge is also removed in
* the sub-graphs hierarchy.
* The ordering of remaining edges is preserved.
* @param e The edge to delete.
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
*/
virtual void delEdge(const edge e, bool deleteInAllGraphs = false)=0;
/**
* @brief Deletes edges in the graph. These edges are also removed in the sub-graphs hierarchy.
* The ordering of remaining edges is preserved.
* @warning The graph does not take ownership of the Iterator.
* @param itE
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
*/
virtual void delEdges(Iterator<edge>* itE, bool deleteInAllGraphs = false)=0;
/**
* @brief Deletes edges in the graph. These edges are also removed in the sub-graphs hierarchy.
* The ordering of remaining edges is preserved.
* @warning The graph does not take ownership of the Iterator.
* @param edges a vector of the edges to delete
* @param deleteInAllGraphs Whether to delete in all its parent graphs or only in this graph. By default only removes in the current graph.
*/
void delEdges(const std::vector<edge>& edges, bool deleteInAllGraphs = false);
/**
* @brief Sets the order of the edges around a node.
* This operation ensures that adjacent edges of a node will
* be ordered as they are in the vector of edges given in parameter.
*
* This can be useful if you want to make sure you retrieve the edges in a specific order when iterating upon them.
* @param n The node whose edges to order.
* @param edges The edges, in the order you want them.
*/
virtual void setEdgeOrder(const node n,const std::vector<edge> &edges)=0;
/**
* @brief Swaps two edges in the adjacency list of a node.
* @param n The node on whoch to swap the edges order.
* @param e1 The first edge, that will take the second edge's position.
* @param e2 The second edge, that will take the first edge's position.
*/
virtual void swapEdgeOrder(const node n,const edge e1, const edge e2)=0;
/**
* @brief Sets the source of an edge to be the given node.
* @param e The edge to change the source of.
* @param source The new source of the edge.
*/
virtual void setSource(const edge e, const node source) = 0;
/**
* @brief Sets the target of an edge to be the given node.
* @param e The edge to change the target of.
* @param target The new target of the edge.
*/
virtual void setTarget(const edge e, const node target) = 0;
/**
* @brief Sets both the source and the target of an edge.
* @param e The edge to set the source and target of.
* @param source The new source of the edge.
* @param target The new target of the edge.
*/
virtual void setEnds(const edge e, const node source, const node target) = 0;
/**
* @brief Reverses the direction of an edge, the source becomes the target and the target
* becomes the source.
* @warning The ordering is global to the entire graph hierarchy. Thus, by changing
* the ordering of a graph you change the ordering of the hierarchy.
* @param e The edge top reverse.
*/
virtual void reverse(const edge e)=0;
// Attempts to reserve enough space to store nodes.
// Only defined on root graph.
virtual void reserveNodes(unsigned int nbNodes) = 0;
// Attempts to reserve enough space to store edges.
// Only defined on root graph.
virtual void reserveEdges(unsigned int nbEdges) = 0;
//================================================================================
//Iterators on the graph structure.
//================================================================================
/**
* @brief Finds the first node whose input degree equals 0.
*
* @return tlp::node The first encountered node with input degree of 0, or an invalid node if none was found.
**/
virtual tlp::node getSource() const;
/**
* @brief Returns the first node in the graph.
*
*/
virtual node getOneNode() const =0;
/**
* @brief Returns a random node in the graph.
*
* @since Tulip 4.8
*
*/
virtual node getRandomNode() const =0;
/**
* @brief Gets an iterator over this graph's nodes.
* @return An iterator over all the nodes of this graph.
* @see getInNodes()
* @see getOutNodes()
* @see getInOutNodes()
* @see getEdges()
*/
virtual Iterator<node>* getNodes() const =0;
/**
* @brief Gets the i-th node in the input nodes of a given node.
* An input node 'in' of a node 'N' is the source of an edge going from
* 'in' to 'N'. e.g.
* @code
* node in = graph->addNode();
* node N = graph->addNode();
* graph->addEdge(in, N);
* //in == graph->getInNode(N, 1);
* @endcode
*
* If you have 5 input nodes on a node N, then
* @codeline graph->getInNode(2); @endcode
* will return the second of those nodes.
* It will ignore the output nodes of this node.
* @param n The node to get an input node of.
* @param i The index of the input node to get.
* @return The i-th input node of the given node.
* @see getInNodes()
* @see getInEdges()
*/
virtual node getInNode(const node n,unsigned int i)const =0;
/**
* @brief Gets an iterator over the input nodes of a node.
* @param n The node to get the input nodes of.
* @return An iterator over the input nodes of a node.
* @see getInNode()
* @see getInOutNodes()
* @see getInEdges()
*/
virtual Iterator<node>* getInNodes(const node n) const =0;
/**
* @brief Gets the i-th node in the output nodes of a given node.
* An output node 'out' of a node 'N' is the target of an edge going from
* 'N' to 'out'. e.g.
* @code
* node N = graph->addNode();
* node out = graph->addNode();
* graph->addEdge(N, out);
* //out == graph->getOutNode(N, 1);
* @endcode
*
* If you have 5 output nodes on a node N, then
* @codeline graph->getOutNode(2); @endcode
* will return the second of those nodes.
* It will ignore the input nodes of this node.
* @param n The node to get an output node of.
* @param i The index of the output node to get.
* @return The i-th output node of the given node.
* @see getOutNodes()
* @see getOutEdges()
*/
virtual node getOutNode(const node n,unsigned int i) const =0;
/**
* @brief Gets an iterator over the output nodes of a node.
* @param n The node to get the output nodes of.
* @return An iterator over the output nodes of a node.
* @see getOutNode()
* @see getInOutNodes()
* @see getOutEdges()
*/
virtual Iterator<node>* getOutNodes(const node n) const =0;
/**
* @brief Gets an iterator over the neighbors of a given node.
* @param n The node to retrieve the neighbors of.
* @return An iterator over the node's neighbors.
*/
virtual Iterator<node>* getInOutNodes(const node n) const =0;
/**
* @brief Gets an iterator performing a breadth-first search on the graph.
* @param root The node from whom to start the BFS. If not provided, the root
* node will be assigned to a source node in the graph (node with input degree equals to 0).
* If there is no source node in the graph, a random node will be picked.
* @return A stable iterator over the graph nodes in the BFS order.
*/
virtual Iterator<node>* bfs(const node root = node()) const = 0;
/**
* @brief Gets an iterator performing a depth-first search on the graph.
* @param root The node from whom to start the DFS. If not provided, the root
* node will be assigned to a source node in the graph (node with input degree equals to 0).
* If there is no source node in the graph, a random node will be picked.
* @return A stable iterator over the graph nodes in the DFS order.
*/
virtual Iterator<node>* dfs(const node root = node()) const = 0;
/**
* @brief Gets the underlying graph of a meta node.
* @param metaNode The metanode.
* @return The Graph pointed to by the metanode.
* @see getEdgeMetaInfo()
*/
virtual Graph* getNodeMetaInfo(const node metaNode) const = 0;
/**
* @brief Get an iterator over all the graph's edges.
* @return An iterator over all the graph's edges.
* @see getInEdges()
* @see getOutEdges()
* @see getInOutEdges()
*/
virtual Iterator<edge>* getEdges() const =0;
/**
* @brief Returns the first edge in the graph.
*
*/
virtual edge getOneEdge() const =0;
/**
* @brief Returns a random edge in the graph.
*
* @since Tulip 4.8
*
*/
virtual edge getRandomEdge() const =0;
/**
* @brief Gets an iterator over the output edges of a node.
* @param n The node to get the output edges from.
* @return An iterator over the node's output edges.
* @see getEdges()
* @see getOutEdges()
* @see getInOutEdges()
*/
virtual Iterator<edge>* getOutEdges(const node n) const =0;
/**
* @brief Gets an iterator over the edges of a node.
* @param n The node to get the edges from.
* @return An iterator over the node's edges.
* @see getEdges()
* @see getOutEdges()
* @see getInEdges()
*/
virtual Iterator<edge>* getInOutEdges(const node n) const =0;
/**
* @brief Gets an iterator over the input edges of a node.
* @param n The node to get the input edges from.
* @return An iterator over the node's input edges.
* @see getEdges()
* @see getOutEdges()
* @see getInOutEdges()
*/
virtual Iterator<edge>* getInEdges(const node n) const =0;
/**
* @brief Gets an iterator over the edges composing a meta edge.
* @param metaEdge The metaEdge to get the real edges of.
* @return An Iterator over the edges composing the metaEdge.
* @see getNodeMetaInfo()
*/
virtual Iterator<edge>* getEdgeMetaInfo(const edge metaEdge) const =0;
//================================================================================
// Graph, nodes and edges information about the graph stucture
//================================================================================
/**
* @brief Gets the unique identifier of the graph.
* @return The unique identifier of this graph.
*/
unsigned int getId() const {
return id;
}
/**
* @brief Gets the number of nodes in this graph.
* @return The number of nodes in this graph.
* @see numberOfEdges()
*/
virtual unsigned int numberOfNodes()const =0;
/**
* @brief Gets the number of edges in this graph.
* @return The number of edges in this graph.
* @see numberOfNodes()
*/
virtual unsigned int numberOfEdges()const =0;
/**
* @param n The node to get the degree of.
* @return The degree of the given node.
*/
virtual unsigned int deg(const node n)const =0;
/**
* @brief Get the input degree of a node.
* @param n The node to get the input degree of.
* @return The input degree of the given node.
*/
virtual unsigned int indeg(const node n)const =0;
/**
* @brief Get the output degree of a node.
* @param n The node to get the output degree of.
* @return The output degree of the given node.
*/
virtual unsigned int outdeg(const node n)const =0;
/**
* @brief Gets the source of an edge.
* @param e The edge to get the source of.
* @return The source of the given edge.
*/
virtual node source(const edge e)const =0;
/**
* @brief Gets the target of an edge.
* @param e The edge to get the target of.
* @return The target of the given edge.
*/
virtual node target(const edge e)const =0;
/**
* @brief Gets the source and the target of an edge.
* @param e The edge to get the ends of.
* @return A pair whose first element is the source, and second is the target.
*/
virtual const std::pair<node, node>& ends(const edge e)const=0;
/**
* @brief Gets the opposite node of n through e.
* @param e The edge linking the two nodes.
* @param n The node at one end of e.
* @return The node at the other end of e.
*/
virtual node opposite(const edge e, const node n)const =0;
/**
* @brief Checks if an element belongs to this graph.
* @param n The node to check if it is an element of the graph.
* @return Whether or not the element belongs to the graph.
*/
virtual bool isElement(const node n) const =0;
/**
* @brief Checks if a node is a meta node.
* @param n The node to check if it is a meta node.
* @return Whether or not the node is a meta node.
*/
virtual bool isMetaNode(const node n) const =0;
/**
* @brief Checks if an element belongs to this graph.
* @param e The edge to check if it is an element of the graph.
* @return Whether or not the element belongs to the graph.
*/
virtual bool isElement(const edge e) const =0;
/**
* @brief Checks if an edge is a meta edge.
* @param e The edge to check if it is a meta edge.
* @return Whether or not the edge is a meta edge.
*/
virtual bool isMetaEdge(const edge e) const =0;
/**
* @brief Checks if an edge exists between two given nodes.
* @param source The source of the hypothetical edge.
* @param target The target of the hypothetical edge.
* @param directed When set to false edges from target to source are also considered
* @return true if such an edge exists
*/
virtual bool hasEdge(const node source, const node target,
bool directed = true) const {
return existEdge(source, target, directed).isValid();
}
/**
* @brief Returns all the edges between two nodes.
* @param source The source of the hypothetical edges.
* @param target The target of the hypothetical edges.
* @param directed When set to false edges from target to source are also considered
* @return a vector of existing edges
*/
virtual std::vector<edge> getEdges(const node source, const node target,
bool directed = true) const=0;
/**
* @brief Returns the first edge found between the two given nodes.
* @warning This function always returns an edge,
* you need to check if this edge is valid with edge::isValid().
* @param source The source of the hypothetical edge.
* @param target The target of the hypothetical edge.
* @param directed When set to false
* an edge from target to source may also be returned
* @return An edge that is only valid if it exists.
*/
virtual edge existEdge(const node source, const node target,
bool directed = true) const=0;
//================================================================================
// Access to the graph attributes and to the node/edge property.
//================================================================================
/**
* @brief Sets the name of the graph.
* The name does not have to be unique, it is used for convenience.
* @param name The new name of the graph.
*/
virtual void setName(const std::string &name) = 0;
/**
* @brief Retrieves the name of the graph.
* @return The name of the graph.
*/
virtual std::string getName() const = 0;
/**
* @brief Gets the attributes of the graph.
*
* The attributes contains the name and any user-defined value.
* @return The attributes of the graph.
*/
const DataSet & getAttributes() const {
return (const_cast<Graph *>(this))->getNonConstAttributes();
}
/**
* @brief Gets an attribute on the graph.
* @param name The name of the attribute to set.
* @param value The value to set.
* @return Whether the setting of the attribute was sucessful.
*/
template<typename ATTRIBUTETYPE>
bool getAttribute(const std::string &name, ATTRIBUTETYPE& value) const;
/**
* @brief Gets a copy of the attribute.
* @param name The name of the attribute to retrieve.
* @return A copy of the attribute to retrieve.
*/
DataType* getAttribute(const std::string& name) const;
/**
* @brief Sets an attribute on the graph.
* @param name The name of the attribute to set.
* @param value The value to set on this attribute.
*/
template<typename ATTRIBUTETYPE>
void setAttribute(const std::string &name,const ATTRIBUTETYPE &value);
/**
* @brief Sets an attribute on the graph.
* @param name The name of the attribute to set.
* @param value The value to set.
*/
void setAttribute(const std::string &name, const DataType* value);
/**
* @brief Removes an attribute on the graph.
* @param name The name of the attribute to remove.
*/
void removeAttribute(const std::string &name) {
notifyRemoveAttribute(name);
getNonConstAttributes().remove(name);
}
/**
* @brief Checks if an attribute exists.
* @param name The name of the attribute to check for.
* @return Whether the attribute exists.
*/
bool attributeExist(const std::string &name) {
return getAttributes().exist(name);
}
/**
* @brief Adds a property to the graph.
* The graph takes ownership of the property. If you want to delete it, use
* Graph::delLocalProperty().
* @param name The unique identifier of the property.
* @param prop The property to add.
*/
virtual void addLocalProperty(const std::string &name, PropertyInterface *prop)=0;
/**
* @brief Gets an existing property.
* In DEBUG mode an assertion checks the existence of the property.
*
* The graph keeps ownership of the property, if you wish to remove it from the graph use
* Graph::delLocalProperty().
*
* @param name The unique identifier of the property.
* @return An existing property, or NULL if no property with the given name exists.
*/
virtual PropertyInterface* getProperty(const std::string& name) const = 0;
/**
* @brief Gets a property on this graph.
* The name of a property indentifies it uniquely.
* Either there already exists a property with the given name, in which case it is returned.
* Either no such porperty exists and it is created.
*
* The graph keeps ownership of the property, if you wish to remove it fgrom the graph use
* Graph::delLocalProperty().
* @warning using the wrong template parameter will cause a segmentation fault.
* @param The unique identifier of the property.
* @return The property of given name.
*/
template<typename PropertyType>
PropertyType* getLocalProperty(const std::string &name);
/**
* @brief Gets a property on this graph or one of its ancestors.
* If the property already exists on the graph or in one of its ancestors, it is returned.
* Otherwise a new property is created on this graph.
*
* The graph keeps ownership of the property, if you wish to remove it from the graph use
* Graph::delLocalProperty().
*
* @warning using the wrong propertyType will result in a segmentation fault. Using an invalid property type will always return NULL.
* @param name The unique identifier of the property.
* @return An existing property, or a new one if none exists with the given name.
*/
template<typename PropertyType>
PropertyType* getProperty(const std::string &name);
/**
* @brief Gets a property on this graph, and this graph only.
* This forwards the call to the template version of getLocalProperty(), with the correct template parameter deduced from the propertyType parameter.
*
* The graph keeps ownership of the property, if you wish to remove it from the graph use
* Graph::delLocalProperty().
*
* @warning using the wrong propertyType will result in a segmentation fault. Using an invalid property type will always return NULL.
* @param propertyName The unique identifier of the property.
* @param propertyType A string describing the type of the property.
* @return The property of given name.
* @see getLocalProperty().
*/
PropertyInterface *getLocalProperty(const std::string& propertyName, const std::string& propertyType);
/**
* @brief Gets a property on this graph or one of its ancestors.
* This forwards the call to the template version of getProperty(), with the correct template parameter deduced from the propertyType parameter.
*
* The graph keeps ownership of the property, if you wish to remove it from the graph use
* Graph::delLocalProperty().
*
* @warning using the wrong propertyType will result in a segmentation fault. Using an invalid property type will always return NULL.
* @param propertyName The unique identifier of the property.
* @param propertyType A string describing the type of the property.
* @return The property of given name.
* @see getProperty().
*/
PropertyInterface *getProperty(const std::string& propertyName, const std::string& propertyType);
/**
* @brief Checks if a property exists in this graph or one of its ancestors.
* @param The unique identifier of the property.
* @return Whether a property with the given name exists.
*/
virtual bool existProperty(const std::string& name) const = 0;
/**
* @brief Checks if a property exists in this graph.
* @param The unique identifier of the property.
* @return Whether a property with the given name exists.
*/
virtual bool existLocalProperty(const std::string& name) const = 0;
/**
* @brief Removes and deletes a property from this graph.
* The property is removed from the graph's property pool, meaning its name can now be used by another property.
* The object is deleted and the memory freed.
* @param name The unique identifier of the property.
*/
virtual void delLocalProperty(const std::string& name)=0;
/**
* @brief Gets an iterator over the names of the local properties of this graph.
* @return An iterator over this graph's properties names.
*/
virtual Iterator<std::string>* getLocalProperties() const=0;
/**
* @brief Gets an iterator over the local properties of this graph.
* @return An iterator over this graph's properties.
*/
virtual Iterator<PropertyInterface*>* getLocalObjectProperties() const=0;
/**
* @brief Gets an iterator over the names of the properties inherited from this graph's ancestors,
* excluding this graph's local properties.
* @return An iterator over the names of the properties this graph inherited.
*/
virtual Iterator<std::string>* getInheritedProperties() const=0;
/**
* @brief Gets an iterator over the properties inherited from this graph's ancestors,
* excluding this graph's local properties.
* @return An iterator over the properties this graph inherited.
*/
virtual Iterator<PropertyInterface*>* getInheritedObjectProperties() const=0;
/**
* @brief Gets an iterator over the names of all the properties attached to this graph,
* whether they are local or inherited.
* @return An iterator over the names of all the properties attached to this graph.
*/
virtual Iterator<std::string>* getProperties() const=0;
/**
* @brief Gets an iterator over the properties attached to this graph,
* whether they are local or inherited.
* @return An iterator over all of the properties attached to this graph.
*/
virtual Iterator<PropertyInterface*>* getObjectProperties() const=0;
/**
* @brief Runs a plugin on the graph, whose result is a property.
*
* @param algorithm The name of the plugin to run.
* @param result The property in which to put the results. All previous values will be erased.
* @param errorMessage Stores the error message if the plugin fails.
* @param progress A means of feedback during the plugin execution. Some plugins support being stopped or cancelled through this.
* @param parameters The parameters of the algorithm. Some algorithms use this DataSet to output some additional information.
* @return Whether the plugin executed successfully or not. If not, check the error message.
*
* @see PluginLister::getPluginParameters() to retrieve the list of default parameters for the pligin.
*/
bool applyPropertyAlgorithm(const std::string &algorithm,
PropertyInterface* result,
std::string &errorMessage,
PluginProgress *progress=NULL,
DataSet *parameters=NULL);
// updates management
/**
* @brief Saves the current state of the whole graph hierarchy and allows to revert to this state later on, using pop().
* All modifications except those altering the ordering of the edges will be undone.
*
* This allows to undo/redo modifications on a graph.
* This is mostly useful from a user interface point of view, but some algorithms use this mechanism to clean up before finishing.
* For instance:
* @code
* Graph* graph = tlp::newGraph();
* DoubleProperty* prop = graph->getProperty<DoubleProperty>("metric");
* string errorMessage;
*
* //our super metric stuff we want to kee
* DoubleProperty* superProperty = graph->getProperty<DoubleProperty>("superStuff");
* vector<PropertyInterface*> propertiesToKeep;
* propertiesToKeep.push_back(superProperty);
*
*
* //apply some metric
* graph->applyPropertyAlgorithm("Degree", prop, errorMessage);
*
* // save this state to be able to revert to it later
* //however we do not want to allow to unpop(), which would go forward again to the state where prop contains 'Depth'.
* //this saves some memory.
* //Also we always want to keep the value of our super property, so we pass it in the collection of properties to leave unaffected by the pop().
* graph->push(false, propertiesToKeep);
*
* //compute the quality of this metric, or whatever makes sense
* int degreeQuality = prop->getMax();
*
* //compute another metric
* graph->applyPropertyAlgorithm("Depth", prop, errorMessage);
*
* //compute our secret metric, that depends on depth
* graph->applyPropertyAlgorithm("MySuperSecretAlgorithm", superProperty, errorMessage);
*
* //compute its quality
* int depthQuality = prop->getMax();
*
* //if the degree was better, revert back to the state where its contents were in prop.
* if(degreeQuality > depthQuality) {
* //this does not affect superProperty, as we told the system not to consider it when recording modifications to potentially revert.
* graph->pop();
* }
*
* //do some stuff using our high quality metric
* ColorProperty* color = graph->getProperty("viewColor");
* graph->applyPropertyAlgorithm("Color Mapping", color, errorMessage);
*
* @endcode
*
* @param unpopAllowed Whether or not to allow to re-do the modifications once they are undone.
* @param propertiesToPreserveOnPop A collection of properties whose state to preserve when using pop().
* @see pop()
* @see unpop()
* @see canPop()
* @see canUnPop()
* @see canPopThenUnPop()
*/
virtual void push(bool unpopAllowed = true,
std::vector<PropertyInterface*>* propertiesToPreserveOnPop= NULL)=0;
/**
* @brief Undoes modifications and reverts the whole graph hierarchy back to a previous state.
*
* @param unpopAllowed Whether or not it is possible to redo what will be undoe by this call.
*/
virtual void pop(bool unpopAllowed = true)=0;
/**
* @brief Re-perform actions that were undone using pop().
*
* For instance:
* @code
* DoubleProperty* prop = graph->getProperty<DoubleProperty>("metric");
* string errorMessage;
*
* //apply some metric
* graph->applyPropertyAlgorithm("Degree", prop, errorMessage);
*
* // save this state to be able to revert to it later
* graph->push();
*
* //compute the quality of this metric, or whatever makes sense
* int degreeQuality = prop->getMax();
*
* //compute another metric
* graph->applyPropertyAlgorithm("Depth", prop, errorMessage);
*
* //compute its quality
* int depthQuality = prop->getMax();
*
* //if the degree was better, revert back to the state where its contents were in prop.
* if(degreeQuality > depthQuality) {
* graph->pop();
* }
*
* ...
*
* //revert back to the depth for some reason.
* graph->unpop();
* @endcode
*/
virtual void unpop()=0;
/**
* @brief Checks if there is a state to revert to.
* @return Whether there was a previous call to push() that was not yet pop()'ed.
*/
virtual bool canPop()=0;
/**
* @brief Checks if the last undone modifications can be redone.
* @return Whether it is possible to re-do modifications that have been undone by pop().
*/
virtual bool canUnpop()=0;
/**
* @brief Checks if it is possible to call pop() and then unPop(), to undo then re-do modifications.
* @return Whether it is possible to undo and then redo.
*/
virtual bool canPopThenUnpop()=0;
// meta nodes management
/**
* @brief Creates a meta-node from a set of nodes.
* Every edges from any node in the set to another node of the graph will be replaced with meta edges
* from the meta node to the other nodes.
* @warning This method will fail when called on the root graph.
*
* @param nodeSet The nodes to put into the meta node.
* @param multiEdges Whether a meta edge should be created for each underlying edge.
* @param delAllEdge Whether the underlying edges will be removed from the whole hierarchy.
* @return The newly created meta node.
*/
node createMetaNode(const std::set<node> &nodeSet, bool multiEdges = true, bool delAllEdge = true);
/**
* @brief Populates a quotient graph with one meta node
* for each iterated graph.
*
* @param itS a Graph iterator, (typically a subgraph iterator)
* @param quotientGraph the graph that will contain the meta nodes
* @param metaNodes will contains all the added meta nodes after the call
*
*/
void createMetaNodes(Iterator<Graph *> *itS, Graph *quotientGraph,
std::vector<node>& metaNodes);
/**
* @brief Closes an existing subgraph into a metanode. Edges from nodes
* in the subgraph to nodes outside the subgraph are replaced with
* edges from the metanode to the nodes outside the subgraph.
* @warning this method will fail when called on the root graph.
*
* @param subGraph an existing subgraph
* @param multiEdges indicates if a meta edge will be created for each underlying edge
* @param delAllEdge indicates if the underlying edges will be removed from the entire hierarchy
*/
node createMetaNode(Graph* subGraph, bool multiEdges = true, bool delAllEdge = true);
/**
* @brief Opens a metanode and replaces all edges between that
* meta node and other nodes in the graph.
*
* @warning this method will fail when called on the root graph.
*
* @param n The meta node to open.
* @param updateProperties If set to true, open meta node will update inner nodes layout, color, size, etc
*/
void openMetaNode(node n, bool updateProperties=true);
protected:
virtual DataSet &getNonConstAttributes() = 0;
// designed to reassign an id to a previously deleted elt
// used by GraphUpdatesRecorder
virtual node restoreNode(node)=0;
virtual void restoreNodes(const std::vector<node>& nodes)=0;
virtual edge restoreEdge(edge, node source, node target)=0;
virtual void restoreEdges(const std::vector<edge>& edges,
const std::vector<std::pair<node, node> >& ends)=0;
// designed to only update own structures
// used by GraphUpdatesRecorder
virtual void removeNode(const node)=0;
virtual void removeEdge(const edge)=0;
// to check if a property can be deleted
// used by PropertyManager
virtual bool canDeleteProperty(Graph* g, PropertyInterface *prop) {
return getRoot()->canDeleteProperty(g, prop);
}
// local property renaming
// can failed if a property with the same name already exists
virtual bool renameLocalProperty(PropertyInterface* prop,
const std::string& newName)=0;
// internally used to deal with sub graph deletion
virtual void removeSubGraph(Graph*)=0;
virtual void clearSubGraphs()=0;
virtual void restoreSubGraph(Graph*)=0;
virtual void setSubGraphToKeep(Graph*)=0;
// for notification of GraphObserver
void notifyAddNode(const node n);
void notifyAddNode(Graph*, const node n) {
notifyAddNode(n);
}
void notifyAddEdge(const edge e);
void notifyAddEdge(Graph*, const edge e) {
notifyAddEdge(e);
}
void notifyBeforeSetEnds(const edge e);
void notifyBeforeSetEnds(Graph*, const edge e) {
notifyBeforeSetEnds(e);
}
void notifyAfterSetEnds(const edge e);
void notifyAfterSetEnds(Graph*, const edge e) {
notifyAfterSetEnds(e);
}
void notifyDelNode(const node n);
void notifyDelNode(Graph*, const node n) {
notifyDelNode(n);
}
void notifyDelEdge(const edge e);
void notifyDelEdge(Graph*, const edge e) {
notifyDelEdge(e);
}
void notifyReverseEdge(const edge e);
void notifyReverseEdge(Graph*, const edge e) {
notifyReverseEdge(e);
}
void notifyBeforeAddSubGraph(const Graph*);
void notifyAfterAddSubGraph(const Graph*);
void notifyBeforeAddSubGraph(Graph*, const Graph* sg) {
notifyBeforeAddSubGraph(sg);
}
void notifyAfterAddSubGraph(Graph*, const Graph* sg) {
notifyAfterAddSubGraph(sg);
}
void notifyBeforeDelSubGraph(const Graph*);
void notifyAfterDelSubGraph(const Graph*);
void notifyBeforeDelSubGraph(Graph*, const Graph* sg) {
notifyBeforeDelSubGraph(sg);
}
void notifyAfterDelSubGraph(Graph*, const Graph* sg) {
notifyAfterDelSubGraph(sg);
}
void notifyBeforeAddDescendantGraph(const Graph*);
void notifyAfterAddDescendantGraph(const Graph*);
void notifyBeforeDelDescendantGraph(const Graph*);
void notifyAfterDelDescendantGraph(const Graph*);
void notifyBeforeAddLocalProperty(const std::string&);
void notifyAddLocalProperty(const std::string&);
void notifyAddLocalProperty(Graph*, const std::string& name) {
notifyAddLocalProperty(name);
}
void notifyBeforeDelLocalProperty(const std::string&);
void notifyAfterDelLocalProperty(const std::string&);
void notifyDelLocalProperty(Graph*, const std::string& name) {
notifyBeforeDelLocalProperty(name);
}
void notifyBeforeSetAttribute(const std::string&);
void notifyBeforeSetAttribute(Graph*, const std::string& name) {
notifyBeforeSetAttribute(name);
}
void notifyAfterSetAttribute(const std::string&);
void notifyAfterSetAttribute(Graph*, const std::string& name) {
notifyAfterSetAttribute(name);
}
void notifyRemoveAttribute(const std::string&);
void notifyRemoveAttribute(Graph*, const std::string& name) {
notifyRemoveAttribute(name);
}
void notifyDestroy();
void notifyDestroy(Graph*) {
notifyDestroy();
}
unsigned int id;
TLP_HASH_MAP<std::string, tlp::PropertyInterface*> circularCalls;
};
/**
* @ingroup Observation
* Event class for specific events on Graph
**/
class TLP_SCOPE GraphEvent :public Event {
public:
// be careful about the ordering of the constants
// in the enum below because it is used in some assertions
enum GraphEventType {
TLP_ADD_NODE = 0,
TLP_DEL_NODE = 1,
TLP_ADD_EDGE = 2,
TLP_DEL_EDGE = 3,
TLP_REVERSE_EDGE = 4,
TLP_BEFORE_SET_ENDS = 5,
TLP_AFTER_SET_ENDS = 6,
TLP_ADD_NODES = 7,
TLP_ADD_EDGES = 8,
TLP_BEFORE_ADD_DESCENDANTGRAPH = 9,
TLP_AFTER_ADD_DESCENDANTGRAPH = 10,
TLP_BEFORE_DEL_DESCENDANTGRAPH = 11,
TLP_AFTER_DEL_DESCENDANTGRAPH = 12,
TLP_BEFORE_ADD_SUBGRAPH = 13,
TLP_AFTER_ADD_SUBGRAPH = 14,
TLP_BEFORE_DEL_SUBGRAPH = 15,
TLP_AFTER_DEL_SUBGRAPH = 16,
TLP_ADD_LOCAL_PROPERTY = 17,
TLP_BEFORE_DEL_LOCAL_PROPERTY = 18,
TLP_AFTER_DEL_LOCAL_PROPERTY = 19,
TLP_ADD_INHERITED_PROPERTY = 20,
TLP_BEFORE_DEL_INHERITED_PROPERTY = 21,
TLP_AFTER_DEL_INHERITED_PROPERTY = 22,
TLP_BEFORE_RENAME_LOCAL_PROPERTY = 23,
TLP_AFTER_RENAME_LOCAL_PROPERTY = 24,
TLP_BEFORE_SET_ATTRIBUTE = 25,
TLP_AFTER_SET_ATTRIBUTE = 26,
TLP_REMOVE_ATTRIBUTE = 27,
TLP_BEFORE_ADD_LOCAL_PROPERTY = 28,
TLP_BEFORE_ADD_INHERITED_PROPERTY = 29
};
// constructor for node/edge events
GraphEvent(const Graph& g, GraphEventType graphEvtType, unsigned int id,
Event::EventType evtType = Event::TLP_MODIFICATION)
: Event(g, evtType), evtType(graphEvtType) {
info.eltId = id;
}
// constructor for nodes events
GraphEvent(const Graph& g, GraphEventType graphEvtType,
const std::vector<node>& nodes,
Event::EventType evtType = Event::TLP_MODIFICATION)
: Event(g, evtType), evtType(graphEvtType) {
info.nodes = &nodes;
}
// constructor for edges events
GraphEvent(const Graph& g, GraphEventType graphEvtType,
const std::vector<edge>& edges,
Event::EventType evtType = Event::TLP_MODIFICATION)
: Event(g, evtType), evtType(graphEvtType) {
info.edges = &edges;
}
// constructor for subgraph events
GraphEvent(const Graph& g, GraphEventType graphEvtType,
const Graph* sg)
: Event(g, Event::TLP_MODIFICATION), evtType(graphEvtType) {
info.subGraph = sg;
}
// constructor for attribute/property events
GraphEvent(const Graph& g, GraphEventType graphEvtType,
const std::string& str,
Event::EventType evtType = Event::TLP_MODIFICATION)
: Event(g, evtType), evtType(graphEvtType) {
info.name = new std::string(str);
}
// constructor for rename property events
GraphEvent(const Graph& g, GraphEventType graphEvtType,
PropertyInterface* prop,
const std::string& newName)
: Event(g, Event::TLP_MODIFICATION), evtType(graphEvtType) {
info.renamedProp =
new std::pair<PropertyInterface*,std::string>(prop, newName);
}
// destructor needed to cleanup name if any
~GraphEvent() {
if (evtType > TLP_AFTER_DEL_SUBGRAPH) {
if (evtType == TLP_BEFORE_RENAME_LOCAL_PROPERTY ||
evtType == TLP_AFTER_RENAME_LOCAL_PROPERTY)
delete info.renamedProp;
else
delete info.name;
}
}
Graph* getGraph() const {
return static_cast<Graph *>(sender());
}
node getNode() const {
assert(evtType < TLP_ADD_EDGE);
return node(info.eltId);
}
edge getEdge() const {
assert(evtType > TLP_DEL_NODE && evtType < TLP_ADD_NODES);
return edge(info.eltId);
}
const std::vector<node>& getNodes() const {
assert(evtType == TLP_ADD_NODES);
return *(info.nodes);
}
const std::vector<edge>& getEdges() const {
assert(evtType == TLP_ADD_EDGES);
return *(info.edges);
}
const Graph* getSubGraph() const {
assert(evtType > TLP_ADD_EDGES && evtType < TLP_ADD_LOCAL_PROPERTY);
return info.subGraph;
}
const std::string& getAttributeName() const {
assert(evtType > TLP_AFTER_DEL_INHERITED_PROPERTY);
return *(info.name);
}
const std::string& getPropertyName() const;
PropertyInterface* getProperty() const {
assert(evtType == TLP_BEFORE_RENAME_LOCAL_PROPERTY ||
evtType == TLP_AFTER_RENAME_LOCAL_PROPERTY);
return info.renamedProp->first;
}
const std::string& getPropertyNewName() const {
assert(evtType == TLP_BEFORE_RENAME_LOCAL_PROPERTY);
return info.renamedProp->second;
}
const std::string& getPropertyOldName() const {
assert(evtType == TLP_AFTER_RENAME_LOCAL_PROPERTY);
return info.renamedProp->second;
}
GraphEventType getType() const {
return evtType;
}
protected:
GraphEventType evtType;
union {
unsigned int eltId;
const Graph* subGraph;
std::string* name;
const std::vector<node>* nodes;
const std::vector<edge>* edges;
std::pair<PropertyInterface*, std::string>* renamedProp;
} info;
};
}
///Print the graph (only nodes and edges) in ostream, in the tulip format
TLP_SCOPE std::ostream& operator<< (std::ostream &,const tlp::Graph *);
//================================================================================
// these functions allow to use tlp::Graph as a key in a hash-based data structure (e.g. hashmap).
//================================================================================
#ifndef DOXYGEN_NOTFOR_DEVEL
TLP_BEGIN_HASH_NAMESPACE {
template <>
struct TLP_SCOPE hash<const tlp::Graph *> {
size_t operator()(const tlp::Graph *s) const {return size_t(s->getId());}
};
template <>
struct TLP_SCOPE hash<tlp::Graph *> {
size_t operator()(tlp::Graph *s) const {return size_t(s->getId());}
};
} TLP_END_HASH_NAMESPACE
#endif // DOXYGEN_NOTFOR_DEVEL
#include "cxx/Graph.cxx"
#endif
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