Exemple #1
0
void LinearOSNS::computeDiagonalInteractionBlock(const InteractionsGraph::VDescriptor& vd)
{
  DEBUG_BEGIN("LinearOSNS::computeDiagonalInteractionBlock(const InteractionsGraph::VDescriptor& vd)\n");

  // Computes matrix _interactionBlocks[inter1][inter1] (and allocates memory if
  // necessary) one or two DS are concerned by inter1 .  How
  // _interactionBlocks are computed depends explicitely on the type of
  // Relation of each Interaction.

  // Warning: we suppose that at this point, all non linear
  // operators (G for lagrangian relation for example) have been
  // computed through plug-in mechanism.

  // Get dimension of the NonSmoothLaw (ie dim of the interactionBlock)
  SP::InteractionsGraph indexSet = simulation()->indexSet(indexSetLevel());
  SP::Interaction inter = indexSet->bundle(vd);
  // Get osi property from interaction
  // We assume that all ds in vertex_inter have the same osi.
  SP::OneStepIntegrator Osi = indexSet->properties(vd).osi;
  //SP::OneStepIntegrator Osi = simulation()->integratorOfDS(ds);
  OSI::TYPES  osiType = Osi->getType();


  // At most 2 DS are linked by an Interaction
  SP::DynamicalSystem DS1;
  SP::DynamicalSystem DS2;
  unsigned int pos1, pos2;
  // --- Get the dynamical system(s) (edge(s)) connected to the current interaction (vertex) ---
  if (indexSet->properties(vd).source != indexSet->properties(vd).target)
  {
    DEBUG_PRINT("a two DS Interaction\n");
    DS1 = indexSet->properties(vd).source;
    DS2 = indexSet->properties(vd).target;
  }
  else
  {
    DEBUG_PRINT("a single DS Interaction\n");
    DS1 = indexSet->properties(vd).source;
    DS2 = DS1;
    // \warning this looks like some debug code, but it gets executed even with NDEBUG.
    // may be compiler does something smarter, but still it should be rewritten. --xhub
    InteractionsGraph::OEIterator oei, oeiend;
    for (std11::tie(oei, oeiend) = indexSet->out_edges(vd);
         oei != oeiend; ++oei)
    {
      // note : at most 4 edges
      DS2 = indexSet->bundle(*oei);
      if (DS2 != DS1)
      {
        assert(false);
        break;
      }
    }
  }
  assert(DS1);
  assert(DS2);
  pos1 = indexSet->properties(vd).source_pos;
  pos2 = indexSet->properties(vd).target_pos;

  // --- Check block size ---
  assert(indexSet->properties(vd).block->size(0) == inter->nonSmoothLaw()->size());
  assert(indexSet->properties(vd).block->size(1) == inter->nonSmoothLaw()->size());

  // --- Compute diagonal block ---
  // Block to be set in OSNS Matrix, corresponding to
  // the current interaction
  SP::SiconosMatrix currentInteractionBlock = indexSet->properties(vd).block;
  SP::SiconosMatrix leftInteractionBlock, rightInteractionBlock;

  RELATION::TYPES relationType;
  double h = simulation()->currentTimeStep();

  // General form of the interactionBlock is : interactionBlock =
  // a*extraInteractionBlock + b * leftInteractionBlock * centralInteractionBlocks
  // * rightInteractionBlock a and b are scalars, centralInteractionBlocks a
  // matrix depending on the integrator (and on the DS), the
  // simulation type ...  left, right and extra depend on the relation
  // type and the non smooth law.
  relationType = inter->relation()->getType();
  VectorOfSMatrices& workMInter = *indexSet->properties(vd).workMatrices;

  inter->getExtraInteractionBlock(currentInteractionBlock, workMInter);

  unsigned int nslawSize = inter->nonSmoothLaw()->size();
  // loop over the DS connected to the interaction.
  bool endl = false;
  unsigned int pos = pos1;
  for (SP::DynamicalSystem ds = DS1; !endl; ds = DS2)
  {
    assert(ds == DS1 || ds == DS2);
    endl = (ds == DS2);
    unsigned int sizeDS = ds->dimension();
    // get _interactionBlocks corresponding to the current DS
    // These _interactionBlocks depends on the relation type.
    leftInteractionBlock.reset(new SimpleMatrix(nslawSize, sizeDS));
    inter->getLeftInteractionBlockForDS(pos, leftInteractionBlock, workMInter);
    DEBUG_EXPR(leftInteractionBlock->display(););
    // Computing depends on relation type -> move this in Interaction method?
    if (relationType == FirstOrder)
    {

      rightInteractionBlock.reset(new SimpleMatrix(sizeDS, nslawSize));

      inter->getRightInteractionBlockForDS(pos, rightInteractionBlock, workMInter);

      if (osiType == OSI::EULERMOREAUOSI)
      {
        if ((std11::static_pointer_cast<EulerMoreauOSI> (Osi))->useGamma() || (std11::static_pointer_cast<EulerMoreauOSI> (Osi))->useGammaForRelation())
        {
          *rightInteractionBlock *= (std11::static_pointer_cast<EulerMoreauOSI> (Osi))->gamma();
        }
      }

      // for ZOH, we have a different formula ...
      if (osiType == OSI::ZOHOSI && indexSet->properties(vd).forControl)
      {
        *rightInteractionBlock = std11::static_pointer_cast<ZeroOrderHoldOSI>(Osi)->Bd(ds);
        prod(*leftInteractionBlock, *rightInteractionBlock, *currentInteractionBlock, false);
      }
      else
      {
        // centralInteractionBlock contains a lu-factorized matrix and we solve
        // centralInteractionBlock * X = rightInteractionBlock with PLU
        SP::SiconosMatrix centralInteractionBlock = getOSIMatrix(Osi, ds);
        centralInteractionBlock->PLUForwardBackwardInPlace(*rightInteractionBlock);
        inter->computeKhat(*rightInteractionBlock, workMInter, h); // if K is non 0

        //      integration of r with theta method removed
        //      *currentInteractionBlock += h *Theta[*itDS]* *leftInteractionBlock * (*rightInteractionBlock); //left = C, right = W.B
        //gemm(h,*leftInteractionBlock,*rightInteractionBlock,1.0,*currentInteractionBlock);
        *leftInteractionBlock *= h;
        prod(*leftInteractionBlock, *rightInteractionBlock, *currentInteractionBlock, false);
        //left = C, right = inv(W).B
      }

    }
    else if (relationType == Lagrangian ||
             relationType == NewtonEuler)
    {

      SP::BoundaryCondition bc;
      Type::Siconos dsType = Type::value(*ds);
      if (dsType == Type::LagrangianLinearTIDS || dsType == Type::LagrangianDS)
      {
        SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
        if (d->boundaryConditions()) bc = d->boundaryConditions();
      }
      else if (dsType == Type::NewtonEulerDS)
      {
        SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
        if (d->boundaryConditions()) bc = d->boundaryConditions();
      }
      if (bc)
      {
        for (std::vector<unsigned int>::iterator itindex = bc->velocityIndices()->begin() ;
             itindex != bc->velocityIndices()->end();
             ++itindex)
        {
          // (nslawSize,sizeDS));
          SP::SiconosVector coltmp(new SiconosVector(nslawSize));
          coltmp->zero();
          leftInteractionBlock->setCol(*itindex, *coltmp);
        }
      }
      DEBUG_PRINT("leftInteractionBlock after application of boundary conditions\n");
      DEBUG_EXPR(leftInteractionBlock->display(););
Exemple #2
0
void OneStepNSProblem::updateInteractionBlocks()
{
  DEBUG_PRINT("OneStepNSProblem::updateInteractionBlocks() starts\n");
  // The present functions checks various conditions and possibly
  // compute interactionBlocks matrices.
  //
  // Let interi and interj be two Interactions.
  //
  // Things to be checked are:
  //  1 - is the topology time invariant?
  //  2 - does interactionBlocks[interi][interj] already exists (ie has been
  //  computed in a previous time step)?
  //  3 - do we need to compute this interactionBlock? A interactionBlock is
  //  to be computed if interi and interj are in IndexSet1 AND if interi and
  //  interj have common DynamicalSystems.
  //
  // The possible cases are:
  //
  //  - If 1 and 2 are true then it does nothing. 3 is not checked.
  //  - If 1 == true, 2 == false, 3 == false, it does nothing.
  //  - If 1 == true, 2 == false, 3 == true, it computes the
  //    interactionBlock.
  //  - If 1==false, 2 is not checked, and the interactionBlock is
  //    computed if 3==true.
  //

  // Get index set from Simulation
  SP::InteractionsGraph indexSet = simulation()->indexSet(indexSetLevel());

  bool isLinear = simulation()->model()->nonSmoothDynamicalSystem()->isLinear();

  // we put diagonal informations on vertices
  // self loops with bgl are a *nightmare* at the moment
  // (patch 65198 on standard boost install)

  if (indexSet->properties().symmetric)
  {
    DEBUG_PRINT("OneStepNSProblem::updateInteractionBlocks(). Symmetric case");
    InteractionsGraph::VIterator vi, viend;
    for (std11::tie(vi, viend) = indexSet->vertices();
         vi != viend; ++vi)
    {
      SP::Interaction inter = indexSet->bundle(*vi);
      unsigned int nslawSize = inter->nonSmoothLaw()->size();
      if (! indexSet->properties(*vi).block)
      {
        indexSet->properties(*vi).block.reset(new SimpleMatrix(nslawSize, nslawSize));
      }

      if (!isLinear || !_hasBeenUpdated)
      {
        computeDiagonalInteractionBlock(*vi);
      }
    }

    /* interactionBlock must be zeroed at init */
    std::vector<bool> initialized;
    initialized.resize(indexSet->edges_number());
    std::fill(initialized.begin(), initialized.end(), false);

    InteractionsGraph::EIterator ei, eiend;
    for (std11::tie(ei, eiend) = indexSet->edges();
         ei != eiend; ++ei)
    {
      SP::Interaction inter1 = indexSet->bundle(indexSet->source(*ei));
      SP::Interaction inter2 = indexSet->bundle(indexSet->target(*ei));

      /* on adjoint graph there is at most 2 edges between source and target */
      InteractionsGraph::EDescriptor ed1, ed2;
      std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*ei), indexSet->target(*ei));

      assert(*ei == ed1 || *ei == ed2);

      /* the first edge has the lower index */
      assert(indexSet->index(ed1) <= indexSet->index(ed2));

      // Memory allocation if needed
      unsigned int nslawSize1 = inter1->nonSmoothLaw()->size();
      unsigned int nslawSize2 = inter2->nonSmoothLaw()->size();
      unsigned int isrc = indexSet->index(indexSet->source(*ei));
      unsigned int itar = indexSet->index(indexSet->target(*ei));

      SP::SiconosMatrix currentInteractionBlock;

      if (itar > isrc) // upper block
      {
        if (! indexSet->properties(ed1).upper_block)
        {
          indexSet->properties(ed1).upper_block.reset(new SimpleMatrix(nslawSize1, nslawSize2));
          if (ed2 != ed1)
            indexSet->properties(ed2).upper_block = indexSet->properties(ed1).upper_block;
        }
        currentInteractionBlock = indexSet->properties(ed1).upper_block;
      }
      else  // lower block
      {
        if (! indexSet->properties(ed1).lower_block)
        {
          indexSet->properties(ed1).lower_block.reset(new SimpleMatrix(nslawSize1, nslawSize2));
          if (ed2 != ed1)
            indexSet->properties(ed2).lower_block = indexSet->properties(ed1).lower_block;
        }
        currentInteractionBlock = indexSet->properties(ed1).lower_block;
      }

      if (!initialized[indexSet->index(ed1)])
      {
        initialized[indexSet->index(ed1)] = true;
        currentInteractionBlock->zero();
      }
      if (!isLinear || !_hasBeenUpdated)
      {
        {
          computeInteractionBlock(*ei);
        }

        // allocation for transposed block
        // should be avoided

        if (itar > isrc) // upper block has been computed
        {
          if (!indexSet->properties(ed1).lower_block)
          {
            indexSet->properties(ed1).lower_block.
            reset(new SimpleMatrix(indexSet->properties(ed1).upper_block->size(1),
                                   indexSet->properties(ed1).upper_block->size(0)));
          }
          indexSet->properties(ed1).lower_block->trans(*indexSet->properties(ed1).upper_block);
          indexSet->properties(ed2).lower_block = indexSet->properties(ed1).lower_block;
        }
        else
        {
          assert(itar < isrc);    // lower block has been computed
          if (!indexSet->properties(ed1).upper_block)
          {
            indexSet->properties(ed1).upper_block.
            reset(new SimpleMatrix(indexSet->properties(ed1).lower_block->size(1),
                                   indexSet->properties(ed1).lower_block->size(0)));
          }
          indexSet->properties(ed1).upper_block->trans(*indexSet->properties(ed1).lower_block);
          indexSet->properties(ed2).upper_block = indexSet->properties(ed1).upper_block;
        }
      }
    }
  }
  else // not symmetric => follow out_edges for each vertices
  {
    DEBUG_PRINT("OneStepNSProblem::updateInteractionBlocks(). Non symmetric case\n");

    InteractionsGraph::VIterator vi, viend;

    for (std11::tie(vi, viend) = indexSet->vertices();
         vi != viend; ++vi)
    {
      DEBUG_PRINT("OneStepNSProblem::updateInteractionBlocks(). Computation of diaganal block\n");
      SP::Interaction inter = indexSet->bundle(*vi);
      unsigned int nslawSize = inter->nonSmoothLaw()->size();
      if (! indexSet->properties(*vi).block)
      {
        indexSet->properties(*vi).block.reset(new SimpleMatrix(nslawSize, nslawSize));
      }

      if (!isLinear || !_hasBeenUpdated)
      {
        computeDiagonalInteractionBlock(*vi);
      }

      /* on a undirected graph, out_edges gives all incident edges */
      InteractionsGraph::OEIterator oei, oeiend;
      /* interactionBlock must be zeroed at init */
      std::map<SP::SiconosMatrix, bool> initialized;
      for (std11::tie(oei, oeiend) = indexSet->out_edges(*vi);
           oei != oeiend; ++oei)
      {
        /* on adjoint graph there is at most 2 edges between source and target */
        InteractionsGraph::EDescriptor ed1, ed2;
        std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*oei), indexSet->target(*oei));
        if (indexSet->properties(ed1).upper_block)
        {
          initialized[indexSet->properties(ed1).upper_block] = false;
        }
        // if(indexSet->properties(ed2).upper_block)
        // {
        //   initialized[indexSet->properties(ed2).upper_block] = false;
        // }

        if (indexSet->properties(ed1).lower_block)
        {
          initialized[indexSet->properties(ed1).lower_block] = false;
        }
        // if(indexSet->properties(ed2).lower_block)
        // {
        //   initialized[indexSet->properties(ed2).lower_block] = false;
        // }

      }

      for (std11::tie(oei, oeiend) = indexSet->out_edges(*vi);
           oei != oeiend; ++oei)
      {
        DEBUG_PRINT("OneStepNSProblem::updateInteractionBlocks(). Computation of extra-diaganal block\n");

        /* on adjoint graph there is at most 2 edges between source and target */
        InteractionsGraph::EDescriptor ed1, ed2;
        std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*oei), indexSet->target(*oei));

        assert(*oei == ed1 || *oei == ed2);

        /* the first edge as the lower index */
        assert(indexSet->index(ed1) <= indexSet->index(ed2));

        SP::Interaction inter1 = indexSet->bundle(indexSet->source(*oei));
        SP::Interaction inter2 = indexSet->bundle(indexSet->target(*oei));

        // Memory allocation if needed
        unsigned int nslawSize1 = inter1->nonSmoothLaw()->size();
        unsigned int nslawSize2 = inter2->nonSmoothLaw()->size();
        unsigned int isrc = indexSet->index(indexSet->source(*oei));
        unsigned int itar = indexSet->index(indexSet->target(*oei));

        SP::SiconosMatrix currentInteractionBlock;

        if (itar > isrc) // upper block
        {
          if (! indexSet->properties(ed1).upper_block)
          {
            indexSet->properties(ed1).upper_block.reset(new SimpleMatrix(nslawSize1, nslawSize2));
            initialized[indexSet->properties(ed1).upper_block] = false;
            if (ed2 != ed1)
              indexSet->properties(ed2).upper_block = indexSet->properties(ed1).upper_block;
          }
          currentInteractionBlock = indexSet->properties(ed1).upper_block;

        }
        else  // lower block
        {
          if (! indexSet->properties(ed1).lower_block)
          {
            indexSet->properties(ed1).lower_block.reset(new SimpleMatrix(nslawSize1, nslawSize2));
            initialized[indexSet->properties(ed1).lower_block] = false;
            if (ed2 != ed1)
              indexSet->properties(ed2).lower_block = indexSet->properties(ed1).lower_block;
          }
          currentInteractionBlock = indexSet->properties(ed1).lower_block;
        }


        if (!initialized[currentInteractionBlock])
        {
          initialized[currentInteractionBlock] = true;
          currentInteractionBlock->zero();
        }

        if (!isLinear || !_hasBeenUpdated)
        {
          if (isrc != itar)
            computeInteractionBlock(*oei);
        }

      }
    }
  }


  DEBUG_EXPR(displayBlocks(indexSet););
void MLCPProjectOnConstraints::displayBlocks(SP::InteractionsGraph indexSet)
{

  std::cout <<  "MLCPProjectOnConstraints::displayBlocks(SP::InteractionsGraph indexSet) " << std::endl;
  std::cout << "                          indexSet :" << indexSet << std::endl;


  InteractionsGraph::VIterator vi, viend;
  for (std11::tie(vi, viend) = indexSet->vertices();
       vi != viend; ++vi)
  {
    SP::Interaction inter = indexSet->bundle(*vi);
    std::cout << "                          vertex :" << *vi << std::endl;
    std::cout << "                          bundle :" << indexSet->bundle(*vi) << std::endl;

    if (indexSet->blockProj[*vi])
    {
      std::cout << "                          blockProj ";
      indexSet->blockProj[*vi]->display();
    }

    InteractionsGraph::OEIterator oei, oeiend;



    for (std11::tie(oei, oeiend) = indexSet->out_edges(*vi);
         oei != oeiend; ++oei)
    {
      unsigned int isrc = indexSet->index(indexSet->source(*oei));
      unsigned int itar = indexSet->index(indexSet->target(*oei));
      std::cout << "                          isrc :" << isrc << std::endl;
      std::cout << "                          itar :" << itar << std::endl;


      InteractionsGraph::EDescriptor ed1, ed2;
      std::cout << "                          outedges :" << *oei << std::endl;
      std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*oei), indexSet->target(*oei));
      std::cout << "                          edges(ed1,ed2) :" << ed1 << " " << ed2  << std::endl;
      std::cout << "                          (ed1)->upper_blockProj : ";
      if (indexSet->upper_blockProj[ed1])
      {
        std::cout << indexSet->upper_blockProj[ed1] << "   :" ;
        indexSet->upper_blockProj[ed1]->display();
      }
      else
        std::cout << "NULL " << std::endl;

      std::cout << "                          (ed1)->lower_blockProj : ";
      if (indexSet->lower_blockProj[ed1])
      {
        std::cout << indexSet->lower_blockProj[ed1] << "   :" ;
        indexSet->lower_blockProj[ed1]->display();
      }
      else
        std::cout << "NULL " << std::endl;

      std::cout << "                          (ed2)->upper_blockProj : ";
      if (indexSet->upper_blockProj[ed2])
      {
        std::cout << indexSet->upper_blockProj[ed2] << "   :" ;
        indexSet->upper_blockProj[ed2]->display();
      }
      else
        std::cout << "NULL" << std::endl;

      std::cout << "                          (ed2)->lower_blockProj : ";
      if (indexSet->lower_blockProj[ed2])
      {
        std::cout << indexSet->lower_blockProj[ed2] << "   :" ;
        indexSet->lower_blockProj[ed2]->display();
      }
      else
        std::cout << "NULL" << std::endl;
    }

  }
}
void MLCPProjectOnConstraints::updateInteractionBlocks()
{
  // The present functions checks various conditions and possibly
  // compute interactionBlocks matrices.
  //
  // Let interi and interj be two Interactions.
  //
  // Things to be checked are:
  //  1 - is the topology time invariant?
  //  2 - does interactionBlocks[interi][interj] already exists (ie has been
  //  computed in a previous time step)?
  //  3 - do we need to compute this interactionBlock? A interactionBlock is
  //  to be computed if interi and interj are in IndexSet1 AND if interi and
  //  interj have common DynamicalSystems.
  //
  // The possible cases are:
  //
  //  - If 1 and 2 are true then it does nothing. 3 is not checked.
  //  - If 1 == true, 2 == false, 3 == false, it does nothing.
  //  - If 1 == true, 2 == false, 3 == true, it computes the
  //    interactionBlock.
  //  - If 1==false, 2 is not checked, and the interactionBlock is
  //    computed if 3==true.
  //

#ifdef MLCPPROJ_DEBUG
  std::cout <<  " " << std::endl;
  std::cout <<  "===================================================" << std::endl;
  std::cout <<  "MLCPProjectOnConstraints::updateInteractionBlocks()" << std::endl;
#endif



  // Get index set from Simulation
  SP::InteractionsGraph indexSet = simulation()->indexSet(indexSetLevel());

  // It seems that index() in not update in Index(0)
  // see comment in void Simulation::updateIndexSets()
  if (indexSetLevel() == 0)
  {
    indexSet->update_vertices_indices();
    indexSet->update_edges_indices();
  }

  bool isLinear = simulation()->model()->nonSmoothDynamicalSystem()->isLinear();





  // we put diagonal informations on vertices
  // self loops with bgl are a *nightmare* at the moment
  // (patch 65198 on standard boost install)

  if (indexSet->properties().symmetric)
  {
    RuntimeException::selfThrow
      (" MLCPProjectOnConstraints::updateInteractionBlocks() - not yet implemented for symmetric case");
  }
  else // not symmetric => follow out_edges for each vertices
  {
    if (!_hasBeenUpdated)
    {
      //      printf("MLCPProjectOnConstraints::updateInteractionBlocks must be updated.\n");
      _n = 0;
      _m = 0;
      _curBlock = 0;
    }
    InteractionsGraph::VIterator vi, viend;
    for (std11::tie(vi, viend) = indexSet->vertices();
         vi != viend; ++vi)
    {




      SP::Interaction inter = indexSet->bundle(*vi);
      unsigned int nslawSize = std11::static_pointer_cast<OSNSMatrixProjectOnConstraints>
        (_M)->computeSizeForProjection(inter);
#ifdef MLCPPROJ_DEBUG
      std::cout << " " << std::endl;
      std::cout <<  "Start to work on Interaction " << inter->number() << "of vertex" << *vi <<  std::endl;
#endif
      if (! indexSet->blockProj[*vi])
      {
#ifdef MLCPPROJ_DEBUG
        std::cout <<  "Allocation of blockProj of size " << nslawSize << " x " << nslawSize << " for interaction " << inter->number() <<  std::endl;
#endif
        indexSet->blockProj[*vi].reset(new SimpleMatrix(nslawSize, nslawSize));
      }

      if (!isLinear || !_hasBeenUpdated)
      {
        computeDiagonalInteractionBlock(*vi);
      }






      /* on a undirected graph, out_edges gives all incident edges */
      InteractionsGraph::OEIterator oei, oeiend;
      /* interactionBlock must be zeroed at init */
      std::map<SP::SiconosMatrix, bool> initialized;
      for (std11::tie(oei, oeiend) = indexSet->out_edges(*vi);
           oei != oeiend; ++oei)
      {
        /* on adjoint graph there is at most 2 edges between source and target */
        InteractionsGraph::EDescriptor ed1, ed2;
        std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*oei), indexSet->target(*oei));
        if (indexSet->upper_blockProj[ed1])
        {
          initialized[indexSet->upper_blockProj[ed1]] = false;
        }
        // if(indexSet->upper_blockProj[ed2])
        // {
        //   initialized[indexSet->upper_blockProj[ed1]] = false;
        // }

        if (indexSet->lower_blockProj[ed1])
        {
          initialized[indexSet->lower_blockProj[ed2]] = false;
        }
        // if(indexSet->lower_blockProj[ed2])
        // {
        //   initialized[indexSet->lower_blockProj[ed2]] = false;
        // }
      }


      for (std11::tie(oei, oeiend) = indexSet->out_edges(*vi);
           oei != oeiend; ++oei)
      {

        /* on adjoint graph there is at most 2 edges between source and target */
        InteractionsGraph::EDescriptor ed1, ed2;
        std11::tie(ed1, ed2) = indexSet->edges(indexSet->source(*oei), indexSet->target(*oei));

        assert(*oei == ed1 || *oei == ed2);

        /* the first edge as the lower index */
        assert(indexSet->index(ed1) <= indexSet->index(ed2));

        SP::Interaction inter1 = indexSet->bundle(indexSet->source(*oei));
        SP::Interaction inter2 = indexSet->bundle(indexSet->target(*oei));

        // Memory allocation if needed
        unsigned int nslawSize1 = std11::static_pointer_cast<OSNSMatrixProjectOnConstraints>
          (_M)->computeSizeForProjection(inter1);
        unsigned int nslawSize2 = std11::static_pointer_cast<OSNSMatrixProjectOnConstraints>
          (_M)->computeSizeForProjection(inter2);
        unsigned int isrc = indexSet->index(indexSet->source(*oei));
        unsigned int itar = indexSet->index(indexSet->target(*oei));

        SP::SiconosMatrix currentInteractionBlock;

        if (itar > isrc) // upper block
        {
          if (! indexSet->upper_blockProj[ed1])
          {
            indexSet->upper_blockProj[ed1].reset(new SimpleMatrix(nslawSize1, nslawSize2));
            initialized[indexSet->upper_blockProj[ed1]] = false;
#ifdef MLCPPROJ_DEBUG
            std::cout <<  "Allocation of upper_blockProj " <<  indexSet->upper_blockProj[ed1].get() << " of edge " << ed1 << " of size " << nslawSize1 << " x " << nslawSize2 << " for interaction " << inter1->number() << " and interaction " <<  inter2->number() <<  std::endl;
#endif

            if (ed2 != ed1)
              indexSet->upper_blockProj[ed2] = indexSet->upper_blockProj[ed1];
          }
#ifdef MLCPPROJ_DEBUG
          else
            std::cout <<  "No Allocation of upper_blockProj of size " << nslawSize1 << " x " << nslawSize2 <<  std::endl;
#endif
          currentInteractionBlock = indexSet->upper_blockProj[ed1];
#ifdef MLCPPROJ_DEBUG
          std::cout << "currentInteractionBlock->size(0)" << currentInteractionBlock->size(0) << std::endl;
          std::cout << "currentInteractionBlock->size(1)" << currentInteractionBlock->size(1) << std::endl;

          std::cout << "inter1->display() " << inter1->number() << std::endl;
          //inter1->display();

          std::cout << "inter2->display() " << inter2->number() << std::endl;
          //inter2->display();
#endif
        }
        else  // lower block
        {
          if (! indexSet->lower_blockProj[ed1])
          {

#ifdef MLCPPROJ_DEBUG
            std::cout <<  "Allocation of lower_blockProj of size " << nslawSize1 << " x " << nslawSize2 << " for interaction " << inter1->number() << " and interaction " <<  inter2->number() <<  std::endl;
#endif
            indexSet->lower_blockProj[ed1].reset(new SimpleMatrix(nslawSize1, nslawSize2));
            initialized[indexSet->lower_blockProj[ed1]] = false;
            if (ed2 != ed1)
              indexSet->lower_blockProj[ed2] = indexSet->lower_blockProj[ed1];
          }
#ifdef MLCPPROJ_DEBUG
          else
            std::cout <<  "No Allocation of lower_blockProj of size " << nslawSize1 << " x " << nslawSize2 <<  std::endl;
#endif
          currentInteractionBlock = indexSet->lower_blockProj[ed1];

#ifdef MLCPPROJ_DEBUG
          std::cout << "currentInteractionBlock->size(0)" << currentInteractionBlock->size(0) << std::endl;
          std::cout << "currentInteractionBlock->size(1)" << currentInteractionBlock->size(1) << std::endl;


          std::cout << "inter1->display() " << inter1->number() << std::endl;
          //inter1->display();

          std::cout << "inter2->display() " << inter2->number() << std::endl;
          //inter2->display();
#endif

        }



        //assert(indexSet->index(ed1));

        if (!initialized[currentInteractionBlock])
        {
          initialized[currentInteractionBlock] = true;
          currentInteractionBlock->zero();
        }


        if (!isLinear || !_hasBeenUpdated)
        {
          if (isrc != itar)
            computeInteractionBlock(*oei);
        }

      }
    }
  }
#ifdef MLCPPROJ_DEBUG
  displayBlocks(indexSet);
#endif

}
void MLCPProjectOnConstraints::postComputeLagrangianR(SP::Interaction inter, unsigned int pos)
{
  SP::LagrangianR  lr = std11::static_pointer_cast<LagrangianR>(inter->relation());
#ifdef MLCPPROJ_DEBUG
  printf("MLCPProjectOnConstraints::postComputeLagrangian inter->y(0)\n");
  inter->y(0)->display();
  printf("MLCPProjectOnConstraints::postComputeLagrangian lr->jachq \n");
  lr->jachq()->display();
  printf("MLCPProjectOnConstraints::postComputeLagrangianR q before update\n");

  
  SP::InteractionsGraph indexSet = simulation()->indexSet(indexSetLevel());
  InteractionsGraph::VDescriptor ui = indexSet->descriptor(inter);
  InteractionsGraph::OEIterator oei, oeiend;
    for(std11::tie(oei, oeiend) = indexSet->out_edges(ui);
        oei != oeiend; ++oei)
    {
      
      SP::LagrangianDS lds =  std11::static_pointer_cast<LagrangianDS>(indexSet->bundle(*oei));
      lds->q()->display();
  }
#endif



  //unsigned int sizeY = inter->nonSmoothLaw()->size();

  // y and lambda vectors
  SP::SiconosVector lambda = inter->lambda(0);
  SP::SiconosVector y = inter->y(0);
  unsigned int sizeY = std11::static_pointer_cast<OSNSMatrixProjectOnConstraints>
    (_M)->computeSizeForProjection(inter);
  // Copy _w/_z values, starting from index pos into y/lambda.

  //setBlock(*_w, y, sizeY, pos, 0);
  setBlock(*_z, lambda, sizeY, pos, 0);

#ifdef MLCPPROJ_DEBUG
  printf("MLCPP lambda of Interaction is pos =%i :\n", pos);
  //  aBuff->display();
  lambda->display();
  unsigned int nslawsize = inter->nonSmoothLaw()->size();
  SP::SiconosVector aBuff(new SiconosVector(nslawsize));
  setBlock(*_z, aBuff, sizeY, pos, 0);
  SP::SiconosMatrix J = lr->jachq();
  SP::SimpleMatrix aux(new SimpleMatrix(*J));
  aux->trans();
  // SP::SiconosVector tmp(new SiconosVector(*(lr->q())));
  // prod(*aux, *aBuff, *(tmp), false);
  // //prod(*aux,*lambda,*(lr->q()),false);
  // std:: std::cout << " tmp =  tmp + J^T * lambda" << std::endl;
  // tmp->display();
#endif



  // // WARNING : Must not be done here. and should be called with the correct time.
  // // compute p(0)
  // inter->computeInput(0.0 ,0);

  // // \warning aBuff should normally be in lambda[0]
  // // The update of the position in DS should be made
  // //  in MoreauJeanOSI::upateState or ProjectedMoreauJeanOSI::updateState
  // SP::SiconosMatrix J=lr->jachq();
  // SP::SimpleMatrix aux(new SimpleMatrix(*J));
  // aux->trans();

  // SP::SiconosVector tmp (new SiconosVector(*(lr->q())));
  // std:: std::cout << " tmp ="<<std::endl;
  // tmp->display();
  // std:: std::cout << " lr->q() ="<<std::endl;
  // lr->q()->display();

  // //prod(*aux,*lambda,*(lr->q()),false);
  // prod(*aux,*aBuff,*(tmp),false);
  // std:: std::cout << " tmp =  tmp + J * lambda"<<std::endl;
  // tmp->display();


  // // The following step should be done on MoreauJeanOSI::upateState or ProjectedMoreauJeanOSI::updateState
  // DSIterator itDS = inter->dynamicalSystemsBegin();
  // while(itDS!=inter->dynamicalSystemsEnd())
  // {
  //   Type::Siconos dsType = Type::value(**itDS);
  //   if((dsType !=Type::LagrangianDS) and
  //      (dsType !=Type::LagrangianLinearTIDS) )
  //   {
  //     RuntimeException::selfThrow("MLCPProjectOnConstraint::postCompute- ds is not of Lagrangian DS type.");
  //   }

  //   SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (*itDS);
  //   SP::SiconosVector q = d->q();

  //   *q +=  *d->p(0);
  //    std::cout << " q=" << std::endl;
  //   q->display();
  //   itDS++;
  // }

  // if ((*lr->q() - *tmp).normInf() > 1e-12)
  // {
  //   RuntimeException::selfThrow("youyou");
  // }

#ifdef MLCPPROJ_DEBUG
  printf("MLCPProjectOnConstraints::postComputeLagrangianR _z\n");
  _z->display();
  printf("MLCPProjectOnConstraints::postComputeLagrangianR updated\n");
  
  VectorOfBlockVectors& DSlink = *(indexSet->properties(ui)).DSlink;
//  (*DSlink[LagrangianR::q0]).display();
//  (lr->q())->display();
#endif



  //RuntimeException::selfThrow("MLCPProjectOnConstraints::postComputeLagrangianR() - not yet implemented");
}