blender-archive/source/blender/freestyle/intern/stroke/Operators.h

/*
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program 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.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
 */

#ifndef __FREESTYLE_OPERATORS_H__
#define __FREESTYLE_OPERATORS_H__

/** \file
 * \ingroup freestyle
 * \brief Class gathering stroke creation algorithms
 */

#include <iostream>
#include <vector>

#include "Chain.h"
#include "ChainingIterators.h"
#include "Predicates0D.h"
#include "Predicates1D.h"
#include "StrokeShader.h"

#include "../system/TimeStamp.h"

#include "../view_map/Interface1D.h"
#include "../view_map/ViewMap.h"

#ifdef WITH_CXX_GUARDEDALLOC
#  include "MEM_guardedalloc.h"
#endif

namespace Freestyle {

/*! Class defining the operators used in a style module.
 *  There are 4 classes of operators: Selection, Chaining, Splitting and Creating.
 *  All these operators are user controlled in the scripting language through Functors, Predicates
 *  and Shaders that are taken as arguments.
 */
class Operators {

 public:
  typedef vector<Interface1D *> I1DContainer;
  typedef vector<Stroke *> StrokesContainer;

  //
  // Operators
  //
  ////////////////////////////////////////////////

  /*! Selects the ViewEdges of the ViewMap verifying a specified condition.
   *  \param pred: The predicate expressing this condition
   */
  static int select(UnaryPredicate1D &pred);

  /*! Builds a set of chains from the current set of ViewEdges.
   *  Each ViewEdge of the current list starts a new chain.
   *  The chaining operator then iterates over the ViewEdges
   *  of the ViewMap using the user specified iterator.
   *  This operator only iterates using the increment operator and is therefore unidirectional.
   *  \param it:
   *           The iterator on the ViewEdges of the ViewMap. It contains the chaining rule.
   *  \param pred:
   *           The predicate on the ViewEdge that expresses the stopping condition.
   *  \param modifier:
   *           A function that takes a ViewEdge as argument and that is used to modify the
   *           processed ViewEdge state (the timestamp incrementation is a typical illustration of
   *           such a modifier)
   */
  static int chain(ViewEdgeInternal::ViewEdgeIterator &it,
                   UnaryPredicate1D &pred,
                   UnaryFunction1D_void &modifier);

  /*! Builds a set of chains from the current set of ViewEdges.
   *  Each ViewEdge of the current list starts a new chain. The chaining operator then iterates
   *  over the ViewEdges
   *  of the ViewMap using the user specified iterator.
   *  This operator only iterates using the increment operator and is therefore unidirectional.
   *  This chaining operator is different from the previous one because it doesn't take any
   *  modifier as argument. Indeed, the time stamp (insuring that a ViewEdge is processed one time)
   *  is automatically managed in this case.
   *  \param it:
   *           The iterator on the ViewEdges of the ViewMap. It contains the chaining rule.
   *  \param pred:
   *           The predicate on the ViewEdge that expresses the stopping condition.
   */
  static int chain(ViewEdgeInternal::ViewEdgeIterator &it, UnaryPredicate1D &pred);

  /*! Builds a set of chains from the current set of ViewEdges.
   *  Each ViewEdge of the current list potentially starts a new chain. The chaining operator then
   *  iterates over the ViewEdges of the ViewMap using the user specified iterator.
   *  This operator iterates both using the increment and decrement operators and is therefore
   *  bidirectional. This operator works with a ChainingIterator which contains the chaining rules.
   *  It is this last one which can be told to chain only edges that belong to the selection or not
   *  to process twice a ViewEdge during the chaining. Each time a ViewEdge is added to a chain,
   *  its chaining time stamp is incremented. This allows you to keep track of the number of chains
   *  to which a ViewEdge belongs to.
   *  \param it:
   *           The ChainingIterator on the ViewEdges of the ViewMap. It contains the chaining rule.
   *  \param pred:
   *           The predicate on the ViewEdge that expresses the stopping condition.
   */
  static int bidirectionalChain(ChainingIterator &it, UnaryPredicate1D &pred);

  /*! The only difference with the above bidirectional chaining algorithm is that we don't need to
   *  pass a stopping criterion. This might be desirable when the stopping criterion is already
   *  contained in the iterator definition. Builds a set of chains from the current set of
   *  ViewEdges. Each ViewEdge of the current list potentially starts a new chain. The chaining
   *  operator then iterates over the ViewEdges of the ViewMap using the user specified iterator.
   *  This operator iterates both using the increment and decrement operators and is therefore
   *  bidirectional. This operator works with a ChainingIterator which contains the chaining rules.
   *  It is this last one which can be told to chain only edges that belong to the selection or not
   *  to process twice a ViewEdge during the chaining. Each time a ViewEdge is added to a chain,
   *  its chaining time stamp is incremented. This allows you to keep track of the number of chains
   *  to which a ViewEdge belongs to.
   *  \param it:
   *           The ChainingIterator on the ViewEdges of the ViewMap. It contains the chaining rule.
   */
  static int bidirectionalChain(ChainingIterator &it);

  /*! Splits each chain of the current set of chains in a sequential way.
   *  The points of each chain are processed (with a specified sampling) sequentially.
   *  Each time a user specified starting condition is verified, a new chain begins and ends as
   *  soon as a user-defined stopping predicate is verified.
   *  This allows chains overlapping rather than chains partitioning.
   *  The first point of the initial chain is the first point of one of the resulting chains.
   *  The splitting ends when no more chain can start.
   *  \param startingPred:
   *           The predicate on a point that expresses the starting condition
   *  \param stoppingPred:
   *           The predicate on a point that expresses the stopping condition
   *  \param sampling:
   *           The resolution used to sample the chain for the predicates evaluation.
   *           (The chain is not actually resampled, a virtual point only progresses along the
   *           curve using this resolution)
   */
  static int sequentialSplit(UnaryPredicate0D &startingPred,
                             UnaryPredicate0D &stoppingPred,
                             float sampling = 0.0f);

  /*! Splits each chain of the current set of chains in a sequential way.
   *  The points of each chain are processed (with a specified sampling) sequentially and each time
   *  a user specified condition is verified, the chain is split into two chains.
   *  The resulting set of chains is a partition of the initial chain
   *  \param pred:
   *           The predicate on a point that expresses the splitting condition
   *  \param sampling:
   *           The resolution used to sample the chain for the predicate evaluation.
   *           (The chain is not actually resampled, a virtual point only progresses along the
   *           curve using this resolution)
   */
  static int sequentialSplit(UnaryPredicate0D &pred, float sampling = 0.0f);

  /*! Splits the current set of chains in a recursive way.
   *  We process the points of each chain (with a specified sampling) to find the point
   *  minimizing a specified function. The chain is split in two at this point and the two new
   *  chains are processed in the same way. The recursivity level is controlled through a
   *  predicate 1D that expresses a stopping condition on the chain that is about to be processed.
   *  \param func:
   *           The Unary Function evaluated at each point of the chain.
   *           The splitting point is the point minimizing this function
   *  \param pred:
   *           The Unary Predicate ex pressing the recursivity stopping condition.
   *           This predicate is evaluated for each curve before it actually gets split.
   *           If pred(chain) is true, the curve won't be split anymore.
   *  \param sampling:
   *           The resolution used to sample the chain for the predicates evaluation. (The chain
   *           is not actually resampled, a virtual point only progresses along the curve using
   *           this resolution)
   */
  static int recursiveSplit(UnaryFunction0D<double> &func,
                            UnaryPredicate1D &pred,
                            float sampling = 0);

  /*! Splits the current set of chains in a recursive way.
   *  We process the points of each chain (with a specified sampling) to find the point minimizing
   *  a specified function. The chain is split in two at this point and the two new chains are
   *  processed in the same way. The user can specify a 0D predicate to make a first selection on
   *  the points that can potentially be split. A point that doesn't verify the 0D predicate
   *  won't be candidate in realizing the min. The recursivity level is controlled through a
   *  predicate 1D that expresses a stopping condition on the chain that is about to be processed.
   *  \param func:
   *           The Unary Function evaluated at each point of the chain.
   *           The splitting point is the point minimizing this function
   *  \param pred0d:
   *           The Unary Predicate 0D used to select the candidate points where the split can
   *           occur. For example, it is very likely that would rather have your chain splitting
   *           around its middle point than around one of its extremities. A 0D predicate working
   *           on the curvilinear abscissa allows to add this kind of constraints.
   *  \param pred:
   *           The Unary Predicate ex pressing the recursivity stopping condition.
   *           This predicate is evaluated for each curve before it actually gets split.
   *           If pred(chain) is true, the curve won't be split anymore.
   *  \param sampling:
   *           The resolution used to sample the chain for the predicates evaluation. (The chain
   *           is not actually resampled, a virtual point only progresses along the curve using
   *           this resolution)
   */
  static int recursiveSplit(UnaryFunction0D<double> &func,
                            UnaryPredicate0D &pred0d,
                            UnaryPredicate1D &pred,
                            float sampling = 0.0f);

  /*! Sorts the current set of chains (or viewedges)
   *  according to the comparison predicate given as argument.
   *  \param pred:
   *           The binary predicate used for the comparison
   */
  static int sort(BinaryPredicate1D &pred);

  /*! Creates and shades the strokes from the current set of chains.
   *  A predicate can be specified to make a selection pass on the chains.
   *  \param pred:
   *           The predicate that a chain must verify in order to be transform as a stroke
   *  \param shaders:
   *           The list of shaders used to shade the strokes
   */
  static int create(UnaryPredicate1D &pred, vector<StrokeShader *> shaders);

  //
  // Data access
  //
  ////////////////////////////////////////////////

  static ViewEdge *getViewEdgeFromIndex(unsigned i)
  {
    return dynamic_cast<ViewEdge *>(_current_view_edges_set[i]);
  }

  static Chain *getChainFromIndex(unsigned i)
  {
    return dynamic_cast<Chain *>(_current_chains_set[i]);
  }

  static Stroke *getStrokeFromIndex(unsigned i)
  {
    return _current_strokes_set[i];
  }

  static unsigned getViewEdgesSize()
  {
    return _current_view_edges_set.size();
  }

  static unsigned getChainsSize()
  {
    return _current_chains_set.size();
  }

  static unsigned getStrokesSize()
  {
    return _current_strokes_set.size();
  }

  //
  // Not exported in Python
  //
  //////////////////////////////////////////////////

  static StrokesContainer *getStrokesSet()
  {
    return &_current_strokes_set;
  }

  static void reset(bool removeStrokes = true);

 private:
  Operators()
  {
  }

  static I1DContainer _current_view_edges_set;
  static I1DContainer _current_chains_set;
  static I1DContainer *_current_set;
  static StrokesContainer _current_strokes_set;

#ifdef WITH_CXX_GUARDEDALLOC
  MEM_CXX_CLASS_ALLOC_FUNCS("Freestyle:Operators")
#endif
};

} /* namespace Freestyle */

#endif  // __FREESTYLE_OPERATORS_H__