示例#1
0
文件: flow.cpp 项目: Rona111/frePPLe
DECLARE_EXPORT void Flow::validate(Action action)
{
  // Catch null operation and buffer pointers
  Operation* oper = getOperation();
  Buffer* buf = getBuffer();
  if (!oper || !buf)
  {
    // This flow is not a valid one since it misses essential information
    if (!oper && !buf)
      throw DataException("Missing operation and buffer on a flow");
    else if (!oper)
      throw DataException("Missing operation on a flow with buffer '"
          + buf->getName() + "'");
    else
      throw DataException("Missing buffer on a flow with operation '"
          + oper->getName() + "'");
  }

  // Check if a flow with 1) identical buffer, 2) identical operation and
  // 3) overlapping effectivity dates already exists, and 4) same
  // flow type.
  Operation::flowlist::const_iterator i = oper->getFlows().begin();
  for (; i != oper->getFlows().end(); ++i)
    if (i->getBuffer() == buf
        && i->getEffective().overlap(getEffective())
        && i->getType() == getType()
        && &*i != this)
      break;

  // Apply the appropriate action
  switch (action)
  {
    case ADD:
      if (i != oper->getFlows().end())
        throw DataException("Flow of '" + oper->getName() + "' and '" +
            buf->getName() + "' already exists");
      break;
    case CHANGE:
      throw DataException("Can't update a flow");
    case ADD_CHANGE:
      // ADD is handled in the code after the switch statement
      if (i == oper->getFlows().end()) break;
      throw DataException("Can't update a flow between '" +
        oper->getName() + "' and '" + buf->getName() + "')");
    case REMOVE:
      // Delete the temporary flow object
      delete this;
      // Nothing to delete
      if (i == oper->getFlows().end())
        throw DataException("Can't remove nonexistent flow of '"
            + oper->getName() + "' and '" + buf->getName() + "'");
      // Delete
      delete &*i;
  }

  // Set a flag to make sure the level computation is triggered again
  HasLevel::triggerLazyRecomputation();
}
示例#2
0
文件: flow.cpp 项目: frePPLe/frePPLe
Object* Flow::finder(const DataValueDict& d)
{
  // Check operation
  const DataValue* tmp = d.get(Tags::operation);
  if (!tmp)
    return nullptr;
  Operation* oper = static_cast<Operation*>(tmp->getObject());

  // Check buffer field
  tmp = d.get(Tags::buffer);
  if (!tmp)
    return nullptr;
  Buffer* buf = static_cast<Buffer*>(tmp->getObject());

  // Walk over all flows of the operation, and return
  // the first one with matching
  const DataValue* hasEffectiveStart = d.get(Tags::effective_start);
  Date effective_start;
  if (hasEffectiveStart)
    effective_start = hasEffectiveStart->getDate();
  const DataValue* hasEffectiveEnd = d.get(Tags::effective_end);
  Date effective_end;
  if (hasEffectiveEnd)
    effective_end = hasEffectiveEnd->getDate();
  const DataValue* hasPriority = d.get(Tags::priority);
  int priority = 1;
  if (hasPriority)
    priority = hasPriority->getInt();
  const DataValue* hasName = d.get(Tags::name);
  string name;
  if (hasName)
    name = hasName->getString();
  for (Operation::flowlist::const_iterator fl = oper->getFlows().begin();
    fl != oper->getFlows().end(); ++fl)
  {
    if (fl->getBuffer() != buf)
      continue;
    if (hasEffectiveStart && fl->getEffectiveStart() != effective_start)
      continue;
    if (hasEffectiveEnd && fl->getEffectiveEnd() != effective_end)
      continue;
    if (hasPriority && fl->getPriority() != priority)
      continue;
    if (hasName && fl->getName() != name)
      continue;
    return const_cast<Flow*>(&*fl);
  }
  return nullptr;
}
示例#3
0
DECLARE_EXPORT PyObject* printModelSize(PyObject* self, PyObject* args)
{
  // Free Python interpreter for other threads
  Py_BEGIN_ALLOW_THREADS

  // Execute and catch exceptions
  size_t count, memsize;
  try
  {

    // Intro
    logger << endl << "Size information of frePPLe " << PACKAGE_VERSION
        << " (" << __DATE__ << ")" << endl << endl;

    // Print current locale
#if defined(HAVE_SETLOCALE) || defined(_MSC_VER)
    logger << "Locale: " << setlocale(LC_ALL,NULL) << endl << endl;
#else
    logger << endl;
#endif

    // Print loaded modules
    Environment::printModules();

    // Print the number of clusters
    logger << "Clusters: " << HasLevel::getNumberOfClusters()
        << " (hanging: " << HasLevel::getNumberOfHangingClusters() << ")"
        << endl << endl;

    // Header for memory size
    logger << "Memory usage:" << endl;
    logger << "Model        \tNumber\tMemory" << endl;
    logger << "-----        \t------\t------" << endl;

    // Plan
    size_t total = Plan::instance().getSize();
    logger << "Plan         \t1\t"<< Plan::instance().getSize() << endl;

    // Locations
    memsize = 0;
    for (Location::iterator l = Location::begin(); l != Location::end(); ++l)
      memsize += l->getSize();
    logger << "Location     \t" << Location::size() << "\t" << memsize << endl;
    total += memsize;

    // Customers
    memsize = 0;
    for (Customer::iterator c = Customer::begin(); c != Customer::end(); ++c)
      memsize += c->getSize();
    logger << "Customer     \t" << Customer::size() << "\t" << memsize << endl;
    total += memsize;

    // Buffers
    memsize = 0;
    for (Buffer::iterator b = Buffer::begin(); b != Buffer::end(); ++b)
      memsize += b->getSize();
    logger << "Buffer       \t" << Buffer::size() << "\t" << memsize << endl;
    total += memsize;

    // Setup matrices
    memsize = 0;
    for (SetupMatrix::iterator s = SetupMatrix::begin(); s != SetupMatrix::end(); ++s)
      memsize += s->getSize();
    logger << "Setup matrix \t" << SetupMatrix::size() << "\t" << memsize << endl;
    total += memsize;

    // Resources
    memsize = 0;
    for (Resource::iterator r = Resource::begin(); r != Resource::end(); ++r)
      memsize += r->getSize();
    logger << "Resource     \t" << Resource::size() << "\t" << memsize << endl;
    total += memsize;

    // Skills and resourceskills
    size_t countResourceSkills(0), memResourceSkills(0);
    memsize = 0;
    for (Skill::iterator sk = Skill::begin(); sk != Skill::end(); ++sk)
    {
      memsize += sk->getSize();
      for (Skill::resourcelist::const_iterator rs = sk->getResources().begin();
          rs != sk->getResources().end(); ++rs)
      {
        ++countResourceSkills;
        memResourceSkills += rs->getSize();
      }
    }
    logger << "Skill     \t" << Skill::size() << "\t" << memsize << endl;
    logger << "ResourceSkill     \t" << countResourceSkills << "\t" << memResourceSkills << endl;
    total += memsize;

    // Operations, flows and loads
    size_t countFlows(0), memFlows(0), countLoads(0), memLoads(0);
    memsize = 0;
    for (Operation::iterator o = Operation::begin(); o != Operation::end(); ++o)
    {
      memsize += o->getSize();
      for (Operation::flowlist::const_iterator fl = o->getFlows().begin();
          fl != o->getFlows().end(); ++ fl)
      {
        ++countFlows;
        memFlows += fl->getSize();
      }
      for (Operation::loadlist::const_iterator ld = o->getLoads().begin();
          ld != o->getLoads().end(); ++ ld)
      {
        ++countLoads;
        memLoads += ld->getSize();
      }
    }
    logger << "Operation    \t" << Operation::size() << "\t" << memsize << endl;
    logger << "Flow         \t" << countFlows << "\t" << memFlows  << endl;
    logger << "Load         \t" << countLoads << "\t" << memLoads  << endl;
    total += memsize + memFlows + memLoads;

    // Calendars (which includes the buckets)
    memsize = 0;
    for (Calendar::iterator cl = Calendar::begin(); cl != Calendar::end(); ++cl)
      memsize += cl->getSize();
    logger << "Calendar     \t" << Calendar::size() << "\t" << memsize  << endl;
    total += memsize;

    // Items
    memsize = 0;
    for (Item::iterator i = Item::begin(); i != Item::end(); ++i)
      memsize += i->getSize();
    logger << "Item         \t" << Item::size() << "\t" << memsize  << endl;
    total += memsize;

    // Demands
    memsize = 0;
    size_t c_count = 0, c_memsize = 0;
    for (Demand::iterator dm = Demand::begin(); dm != Demand::end(); ++dm)
    {
      memsize += dm->getSize();
      for (Problem::const_iterator cstrnt(dm->getConstraints().begin());
        cstrnt != dm->getConstraints().end(); ++cstrnt)
      {
        ++c_count;
        c_memsize += cstrnt->getSize();
      }
    }
    logger << "Demand       \t" << Demand::size() << "\t" << memsize  << endl;
    logger << "Constraints  \t" << c_count << "\t" << c_memsize  << endl;
    total += memsize + c_memsize;

    // Operationplans
    size_t countloadplans(0), countflowplans(0);
    memsize = count = 0;
    for (OperationPlan::iterator j = OperationPlan::begin();
        j!=OperationPlan::end(); ++j)
    {
      ++count;
      memsize += sizeof(*j);
      countloadplans += j->sizeLoadPlans();
      countflowplans += j->sizeFlowPlans();
    }
    total += memsize;
    logger << "OperationPlan\t" << count << "\t" << memsize << endl;

    // Flowplans
    memsize = countflowplans * sizeof(FlowPlan);
    total +=  memsize;
    logger << "FlowPlan     \t" << countflowplans << "\t" << memsize << endl;

    // Loadplans
    memsize = countloadplans * sizeof(LoadPlan);
    total +=  memsize;
    logger << "LoadPlan     \t" << countloadplans << "\t" << memsize << endl;

    // Problems
    memsize = count = 0;
    for (Problem::const_iterator pr = Problem::begin(); pr!=Problem::end(); ++pr)
    {
      ++count;
      memsize += pr->getSize();
    }
    total += memsize;
    logger << "Problem      \t" << count << "\t" << memsize << endl;

    // TOTAL
    logger << "Total        \t\t" << total << endl << endl;
  }
  catch (...)
  {
    Py_BLOCK_THREADS;
    PythonType::evalException();
    return NULL;
  }
  Py_END_ALLOW_THREADS   // Reclaim Python interpreter
  return Py_BuildValue("");
}
示例#4
0
DECLARE_EXPORT void HasLevel::computeLevels()
{
  computationBusy = true;
  // Get exclusive access to this function in a multi-threaded environment.
  static Mutex levelcomputationbusy;
  ScopeMutexLock l(levelcomputationbusy);

  // Another thread may already have computed the levels while this thread was
  // waiting for the lock. In that case the while loop will be skipped.
  while (recomputeLevels)
  {
    // Reset the recomputation flag. Note that during the computation the flag
    // could be switched on again by some model change in a different thread.
    // In that case, the while loop will be rerun.
    recomputeLevels = false;

    // Force creation of all delivery operations f
    for (Demand::iterator gdem = Demand::begin();
        gdem != Demand::end(); ++gdem)
        gdem->getDeliveryOperation();

    // Reset current levels on buffers, resources and operations.
    // Also force the creation of all producing operations on the buffers.
    size_t numbufs = Buffer::size();
    // Creating the producing operations of the buffers can cause new buffers
    // to be created. We repeat this loop until no new buffers are being added.
    // This isn't the most efficient loop, but it remains cheap and fast...
    while (true)
    {
      for (Buffer::iterator gbuf = Buffer::begin();
          gbuf != Buffer::end(); ++gbuf)
      {
        gbuf->cluster = 0;
        gbuf->lvl = -1;
        gbuf->getProducingOperation();
      }
      size_t numbufs_after = Buffer::size();
      if (numbufs == numbufs_after)
        break;
      else
        numbufs = numbufs_after;
    }
    for (Resource::iterator gres = Resource::begin();
        gres != Resource::end(); ++gres)
    {
      gres->cluster = 0;
      gres->lvl = -1;
    }
    for (Operation::iterator gop = Operation::begin();
        gop != Operation::end(); ++gop)
    {
      gop->cluster = 0;
      gop->lvl = -1;
    }

    // Loop through all operations
    stack< pair<Operation*,int> > stack;
    Operation* cur_oper;
    int cur_level;
    Buffer *cur_buf;
    const Flow* cur_Flow;
    bool search_level;
    int cur_cluster;
    numberOfLevels = 0;
    numberOfClusters = 0;
    map<Operation*,short> visited;
    for (Operation::iterator g = Operation::begin();
        g != Operation::end(); ++g)
    {
      // Select a new cluster number
      if (g->cluster)
        cur_cluster = g->cluster;
      else
      {
        // Detect hanging operations
        if (g->getFlows().empty() && g->getLoads().empty()
            && g->getSuperOperations().empty()
            && g->getSubOperations().empty()
           )
        {
          // Cluster 0 keeps all dangling operations
          g->lvl = 0;
          continue;
        }
        cur_cluster = ++numberOfClusters;
        if (numberOfClusters >= UINT_MAX)
          throw LogicException("Too many clusters");
      }

#ifdef CLUSTERDEBUG
      logger << "Investigating operation '" << &*g
          << "' - current cluster " << g->cluster << endl;
#endif

      // Do we need to activate the level search?
      // Criterion are:
      //   - Not used in a super operation
      //   - Have a producing flow on the operation itself
      //     or on any of its sub operations
      search_level = false;
      if (g->getSuperOperations().empty())
      {
        search_level = true;
        // Does the operation itself have producing flows?
        for (Operation::flowlist::const_iterator fl = g->getFlows().begin();
            fl != g->getFlows().end() && search_level; ++fl)
          if (fl->isProducer()) search_level = false;
        if (search_level)
        {
          // Do suboperations have a producing flow?
          for (Operation::Operationlist::const_reverse_iterator
              i = g->getSubOperations().rbegin();
              i != g->getSubOperations().rend() && search_level;
              ++i)
            for (Operation::flowlist::const_iterator
                fl = (*i)->getOperation()->getFlows().begin();
                fl != (*i)->getOperation()->getFlows().end() && search_level;
                ++fl)
              if (fl->isProducer()) search_level = false;
        }
      }

      // If both the level and the cluster are de-activated, then we can move on
      if (!search_level && g->cluster) continue;

      // Start recursing
      // Note that as soon as push an operation on the stack we set its
      // cluster and/or level. This is avoid that operations are needlessly
      // pushed a second time on the stack.
      stack.push(make_pair(&*g, search_level ? 0 : -1));
      visited.clear();
      g->cluster = cur_cluster;
      if (search_level) g->lvl = 0;
      while (!stack.empty())
      {
        // Take the top of the stack
        cur_oper = stack.top().first;
        cur_level = stack.top().second;
        stack.pop();

        // Keep track of the maximum number of levels
        if (cur_level > numberOfLevels)
          numberOfLevels = cur_level;

#ifdef CLUSTERDEBUG
        logger << "    Recursing in Operation '" << *(cur_oper)
            << "' - current level " << cur_level << endl;
#endif
        // Detect loops in the supply chain
        map<Operation*,short>::iterator detectloop = visited.find(cur_oper);
        if (detectloop == visited.end())
          // Keep track of operations already visited
          visited.insert(make_pair(cur_oper,0));
        else if (++(detectloop->second) > 1)
          // Already visited this operation enough times - don't repeat
          continue;

        // Push sub operations on the stack
        for (Operation::Operationlist::const_reverse_iterator
            i = cur_oper->getSubOperations().rbegin();
            i != cur_oper->getSubOperations().rend();
            ++i)
        {
          if ((*i)->getOperation()->lvl < cur_level)
          {
            // Search level and cluster
            stack.push(make_pair((*i)->getOperation(),cur_level));
            (*i)->getOperation()->lvl = cur_level;
            (*i)->getOperation()->cluster = cur_cluster;
          }
          else if (!(*i)->getOperation()->cluster)
          {
            // Search for clusters information only
            stack.push(make_pair((*i)->getOperation(),-1));
            (*i)->getOperation()->cluster = cur_cluster;
          }
          // else: no search required
        }

        // Push super operations on the stack
        for (list<Operation*>::const_reverse_iterator
            j = cur_oper->getSuperOperations().rbegin();
            j != cur_oper->getSuperOperations().rend();
            ++j)
        {
          if ((*j)->lvl < cur_level)
          {
            // Search level and cluster
            stack.push(make_pair(*j,cur_level));
            (*j)->lvl = cur_level;
            (*j)->cluster = cur_cluster;
          }
          else if (!(*j)->cluster)
          {
            // Search for clusters information only
            stack.push(make_pair(*j,-1));
            (*j)->cluster = cur_cluster;
          }
          // else: no search required
        }

        // Update level of resources linked to current operation
        for (Operation::loadlist::const_iterator gres =
            cur_oper->getLoads().begin();
            gres != cur_oper->getLoads().end(); ++gres)
        {
          Resource *resptr = gres->getResource();
          // Update the level of the resource
          if (resptr->lvl < cur_level) resptr->lvl = cur_level;
          // Update the cluster of the resource and operations using it
          if (!resptr->cluster)
          {
            resptr->cluster = cur_cluster;
            // Find more operations connected to this cluster by the resource
            for (Resource::loadlist::const_iterator resops =
                resptr->getLoads().begin();
                resops != resptr->getLoads().end(); ++resops)
              if (!resops->getOperation()->cluster)
              {
                stack.push(make_pair(resops->getOperation(),-1));
                resops->getOperation()->cluster = cur_cluster;
              }
          }
        }

        // Now loop through all flows of the operation
        for (Operation::flowlist::const_iterator
            gflow = cur_oper->getFlows().begin();
            gflow != cur_oper->getFlows().end();
            ++gflow)
        {
          cur_Flow = &*gflow;
          cur_buf = cur_Flow->getBuffer();

          // Check whether the level search needs to continue
          search_level = cur_level!=-1 && cur_buf->lvl<cur_level+1;

          // Check if the buffer needs processing
          if (search_level || !cur_buf->cluster)
          {
            // Update the cluster of the current buffer
            cur_buf->cluster = cur_cluster;

            // Loop through all flows of the buffer
            for (Buffer::flowlist::const_iterator
                buffl = cur_buf->getFlows().begin();
                buffl != cur_buf->getFlows().end();
                ++buffl)
            {
              // Check level recursion
              if (cur_Flow->isConsumer() && search_level)
              {
                if (buffl->getOperation()->lvl < cur_level+1
                    && &*buffl != cur_Flow && buffl->isProducer())
                {
                  stack.push(make_pair(buffl->getOperation(),cur_level+1));
                  buffl->getOperation()->lvl = cur_level+1;
                  buffl->getOperation()->cluster = cur_cluster;
                }
                else if (!buffl->getOperation()->cluster)
                {
                  stack.push(make_pair(buffl->getOperation(),-1));
                  buffl->getOperation()->cluster = cur_cluster;
                }
                if (cur_level+1 > numberOfLevels)
                  numberOfLevels = cur_level+1;
                cur_buf->lvl = cur_level+1;
              }
              // Check cluster recursion
              else if (!buffl->getOperation()->cluster)
              {
                stack.push(make_pair(buffl->getOperation(),-1));
                buffl->getOperation()->cluster = cur_cluster;
              }
            }
          }  // End of needs-procssing if statement
        } // End of flow loop

      }     // End while stack not empty

    } // End of Operation loop

    // The above loop will visit ALL operations and recurse through the
    // buffers and resources connected to them.
    // Missing from the loop are buffers and resources that have no flows or
    // loads at all. We catch those poor lonely fellows now...
    for (Buffer::iterator gbuf2 = Buffer::begin();
        gbuf2 != Buffer::end(); ++gbuf2)
      if (gbuf2->getFlows().empty()) gbuf2->cluster = 0;
    for (Resource::iterator gres2 = Resource::begin();
        gres2 != Resource::end(); ++gres2)
      if (gres2->getLoads().empty()) gres2->cluster = 0;

  } // End of while recomputeLevels. The loop will be repeated as long as model
  // changes are done during the recomputation.

  // Unlock the exclusive access to this function
  computationBusy = false;
}
示例#5
0
void OperationItemSupplier::trimExcess(bool zero_or_minimum) const
{
  // This method can only trim operations not loading a resource
  if (getLoads().begin() != getLoads().end())
    return;

  for (Operation::flowlist::const_iterator fliter = getFlows().begin();
    fliter != getFlows().end(); ++fliter)
  {
    if (fliter->getQuantity() <= 0)
      // Strange, shouldn't really happen
      continue;
    FlowPlan* candidate = nullptr;
    double curmin = 0;
    double oh = 0;
    double excess_min = DBL_MAX;

    for (Buffer::flowplanlist::const_iterator flplniter = fliter->getBuffer()->getFlowPlans().begin();
      flplniter != fliter->getBuffer()->getFlowPlans().end();
      ++flplniter)
    {
      // For any operationplan we get the onhand when its successor
      // replenishment arrives. If that onhand is higher than the minimum
      // onhand value we can resize it.
      // This is only valid in unconstrained plans and when there are
      // no upstream activities.
      if (flplniter->getEventType() == 3 && zero_or_minimum)
        curmin = flplniter->getMin();
      else if (flplniter->getEventType() == 1)
      {
        const FlowPlan* flpln = static_cast<const FlowPlan*>(&*flplniter);
        if (oh - curmin < excess_min)
        {
          excess_min = oh - curmin;
          if (excess_min < 0)
            excess_min = 0;
        }
        if (flpln->getQuantity() > 0 && !flpln->getOperationPlan()->getLocked() && (!candidate || candidate->getDate() != flpln->getDate()))
        {
          if (candidate
            && excess_min > ROUNDING_ERROR
            && candidate->getQuantity() > excess_min + ROUNDING_ERROR
            && candidate->getQuantity() > getSizeMinimum() + ROUNDING_ERROR
            )
          {
            // This candidate can now be resized
            candidate->setQuantity(candidate->getQuantity() - excess_min, false);
            candidate = nullptr;
          }
          else if (flpln->getOperation() == this)
            candidate = const_cast<FlowPlan*>(flpln);
          else
            candidate = nullptr;
          excess_min = DBL_MAX;
        }
      }
      oh = flplniter->getOnhand();
    }
    if (candidate
      && excess_min > ROUNDING_ERROR
      && candidate->getQuantity() > excess_min + ROUNDING_ERROR
      && candidate->getQuantity() > getSizeMinimum() + ROUNDING_ERROR
      )
      // Resize the last candidate at the end of the horizon
      candidate->setQuantity(candidate->getQuantity() - excess_min, false);
  }
}
示例#6
0
DECLARE_EXPORT void SolverMRP::solve(const Flow* fl, void* v)  // @todo implement search mode
{
  // Note: This method is only called for consuming flows and for the leading
  // flow of an alternate group. See SolverMRP::checkOperation

  SolverMRPdata* data = static_cast<SolverMRPdata*>(v);
  if (fl->hasAlternates())
  {
    // CASE I: It is an alternate flow.
    // We ask each alternate flow in order of priority till we find a flow
    // that has a non-zero reply.

    // 1) collect a list of alternates
    list<const Flow*> thealternates;
    const Flow *x = fl->hasAlternates() ? fl : fl->getAlternate();
    for (Operation::flowlist::const_iterator i = fl->getOperation()->getFlows().begin();
        i != fl->getOperation()->getFlows().end(); ++i)
      if ((i->getAlternate() == x || &*i == x)
          && i->getEffective().within(data->state->q_flowplan->getDate()))
        thealternates.push_front(&*i);

    // 2) Sort the list
    thealternates.sort(sortFlow);

    // 3) Control the planning mode
    bool originalPlanningMode = data->constrainedPlanning;
    data->constrainedPlanning = true;
    const Flow *firstAlternate = NULL;
    double firstQuantity = 0.0;

    // Remember the top constraint
    bool originalLogConstraints = data->logConstraints;
    //Problem* topConstraint = data->planningDemand->getConstraints().top();

    // 4) Loop through the alternates till we find a non-zero reply
    Date min_next_date(Date::infiniteFuture);
    double ask_qty;
    FlowPlan *flplan = data->state->q_flowplan;
    for (list<const Flow*>::const_iterator i = thealternates.begin();
        i != thealternates.end();)
    {
      const Flow *curflow = *i;
      data->state->q_flowplan = flplan; // because q_flowplan can change

      // 4a) Switch to this flow
      if (data->state->q_flowplan->getFlow() != curflow)
        data->state->q_flowplan->setFlow(curflow);

      // 4b) Call the Python user exit if there is one
      if (userexit_flow)
      {
        PythonObject result = userexit_flow.call(data->state->q_flowplan, PythonObject(data->constrainedPlanning));
        if (!result.getBool())
        {
          // Return value is false, alternate rejected
          if (data->getSolver()->getLogLevel()>1)
            logger << indent(curflow->getOperation()->getLevel())
                << "   User exit disallows consumption from '"
                << (*i)->getBuffer()->getName() << "'" << endl;
          // Move to the next alternate
          if (++i != thealternates.end() && data->getSolver()->getLogLevel()>1)
            logger << indent(curflow->getOperation()->getLevel()) << "   Alternate flow switches from '"
                << curflow->getBuffer()->getName() << "' to '"
                << (*i)->getBuffer()->getName() << "'" << endl;
          continue;
        }
      }

      // Remember the first alternate
      if (!firstAlternate)
      {
        firstAlternate = *i;
        firstQuantity = data->state->q_flowplan->getQuantity();
      }

      // Constraint tracking
      if (*i != firstAlternate)
        // Only enabled on first alternate
        data->logConstraints = false;
      else
        // Keep track of constraints, if enabled
        data->logConstraints = originalLogConstraints;

      // 4c) Ask the buffer
      data->state->q_qty = ask_qty = - data->state->q_flowplan->getQuantity();
      data->state->q_date = data->state->q_flowplan->getDate();
      CommandManager::Bookmark* topcommand = data->setBookmark();
      curflow->getBuffer()->solve(*this,data);

      // 4d) A positive reply: exit the loop
      if (data->state->a_qty > ROUNDING_ERROR)
      {
        // Update the opplan, which is required to (1) update the flowplans
        // and to (2) take care of lot sizing constraints of this operation.
        if (data->state->a_qty < ask_qty - ROUNDING_ERROR)
        {
          flplan->setQuantity(-data->state->a_qty, true);
          data->state->a_qty = -flplan->getQuantity();
        }
        if (data->state->a_qty > ROUNDING_ERROR)
        {
          data->constrainedPlanning = originalPlanningMode;
          data->logConstraints = originalLogConstraints;
          return;
        }
      }

      // 4e) Undo the plan on the alternate
      data->rollback(topcommand);

      // 4f) Prepare for the next alternate
      if (data->state->a_date < min_next_date)
        min_next_date = data->state->a_date;
      if (++i != thealternates.end() && data->getSolver()->getLogLevel()>1)
        logger << indent(curflow->getOperation()->getLevel()) << "   Alternate flow switches from '"
            << curflow->getBuffer()->getName() << "' to '"
            << (*i)->getBuffer()->getName() << "'" << endl;
    }

    // 5) No reply found, all alternates are infeasible
    if (!originalPlanningMode)
    {
      assert(firstAlternate);
      // Unconstrained plan: Plan on the primary alternate
      // Switch to this flow
      if (flplan->getFlow() != firstAlternate)
        flplan->setFlow(firstAlternate);
      // Message
      if (data->getSolver()->getLogLevel()>1)
        logger << indent(fl->getOperation()->getLevel())
            << "   Alternate flow plans unconstrained on alternate '"
            << firstAlternate->getBuffer()->getName() << "'" << endl;
      // Plan unconstrained
      data->constrainedPlanning = false;
      data->state->q_flowplan = flplan; // because q_flowplan can change
      flplan->setQuantity(firstQuantity, true);
      data->state->q_qty = ask_qty = - flplan->getQuantity();
      data->state->q_date = flplan->getDate();
      firstAlternate->getBuffer()->solve(*this,data);
      data->state->a_qty = -flplan->getQuantity();
      // Restore original planning mode
      data->constrainedPlanning = originalPlanningMode;
    }
    else
    {
      // Constrained plan: Return 0
      data->state->a_date = min_next_date;
      data->state->a_qty = 0;
      if (data->getSolver()->getLogLevel()>1)
        logger << indent(fl->getOperation()->getLevel()) <<
            "   Alternate flow doesn't find supply on any alternate : "
            << data->state->a_qty << "  " << data->state->a_date << endl;
    }
  }
  else
  {
    // CASE II: Not an alternate flow.
    // In this case, this method is passing control on to the buffer.
    data->state->q_qty = - data->state->q_flowplan->getQuantity();
    data->state->q_date = data->state->q_flowplan->getDate();
    if (data->state->q_qty != 0.0)
    {
      fl->getBuffer()->solve(*this,data);
      if (data->state->a_date > fl->getEffective().getEnd())
      {
        // The reply date must be less than the effectivity end date: after
        // that date the flow in question won't consume any material any more.
        if (data->getSolver()->getLogLevel()>1
            && data->state->a_qty < ROUNDING_ERROR)
          logger << indent(fl->getBuffer()->getLevel()) << "  Buffer '"
              << fl->getBuffer()->getName() << "' answer date is adjusted to "
              << fl->getEffective().getEnd()
              << " because of a date effective flow" << endl;
        data->state->a_date = fl->getEffective().getEnd();
      }
    }
    else
    {
      // It's a zero quantity flowplan.
      // E.g. because it is not effective.
      data->state->a_date = data->state->q_date;
      data->state->a_qty = 0.0;
    }
  }
}
示例#7
0
extern "C" PyObject* OperationItemDistribution::createOrder(
  PyObject *self, PyObject *args, PyObject *kwdict
  )
{
  // Parse the Python arguments
  PyObject* pydest = NULL;
  unsigned long id = 0;
  const char* ref = NULL;
  PyObject* pyitem = NULL;
  PyObject* pyorigin = NULL;
  double qty = 0;
  PyObject* pystart = NULL;
  PyObject* pyend = NULL;
  int consume = 1;
  const char* status = NULL;
  const char* source = NULL;
  static const char *kwlist[] = {
    "destination", "id", "reference", "item", "origin", "quantity", "start",
    "end", "consume_material", "status", "source", NULL
    };
  int ok = PyArg_ParseTupleAndKeywords(
    args, kwdict, "|OkzOOdOOpzz:createOrder", const_cast<char**>(kwlist),
    &pydest, &id, &ref, &pyitem, &pyorigin, &qty, &pystart, &pyend,
    &consume, &status, &source
    );
  if (!ok)
    return NULL;
  Date start = pystart ? PythonData(pystart).getDate() : Date::infinitePast;
  Date end = pyend ? PythonData(pyend).getDate() : Date::infinitePast;

  // Validate all arguments
  if (!pydest || !pyitem)
  {
    PyErr_SetString(PythonDataException, "item and destination arguments are mandatory");
    return NULL;
  }
  PythonData dest_tmp(pydest);
  if (!dest_tmp.check(Location::metadata))
  {
    PyErr_SetString(PythonDataException, "destination argument must be of type location");
    return NULL;
  }
  PythonData item_tmp(pyitem);
  if (!item_tmp.check(Item::metadata))
  {
    PyErr_SetString(PythonDataException, "item argument must be of type item");
    return NULL;
  }
  PythonData origin_tmp(pyorigin);
  if (pyorigin && !origin_tmp.check(Location::metadata))
  {
    PyErr_SetString(PythonDataException, "origin argument must be of type location");
    return NULL;
  }
  Item *item = static_cast<Item*>(item_tmp.getObject());
  Location *dest = static_cast<Location*>(dest_tmp.getObject());
  Location *origin = pyorigin ? static_cast<Location*>(origin_tmp.getObject()) : NULL;

  // Find or create the destination buffer.
  Buffer* destbuffer = NULL;
  for (Buffer::iterator bufiter = Buffer::begin(); bufiter != Buffer::end(); ++bufiter)
  {
    if (bufiter->getLocation() == dest && bufiter->getItem() == item)
    {
      if (destbuffer)
      {
        stringstream o;
        o << "Multiple buffers found for item '" << item << "'' and location'" << dest << "'";
        throw DataException(o.str());
      }
      destbuffer = &*bufiter;
    }
  }
  if (!destbuffer)
  {
    // Create the destination buffer
    destbuffer = new BufferDefault();
    stringstream o;
    o << item << " @ " << dest;
    destbuffer->setName(o.str());
    destbuffer->setItem(item);
    destbuffer->setLocation(dest);
  }

  // Build the producing operation for this buffer.
  destbuffer->getProducingOperation();

  // Look for a matching operation replenishing this buffer.
  Operation *oper = NULL;
  for (Buffer::flowlist::const_iterator flowiter = destbuffer->getFlows().begin();
    flowiter != destbuffer->getFlows().end() && !oper; ++flowiter)
  {
    if (flowiter->getOperation()->getType() != *OperationItemDistribution::metadata
      || flowiter->getQuantity() <= 0)
        continue;
    OperationItemDistribution* opitemdist = static_cast<OperationItemDistribution*>(flowiter->getOperation());
    if (origin)
    {
      // Origin must match as well
      for (Operation::flowlist::const_iterator fl = opitemdist->getFlows().begin();
          fl != opitemdist->getFlows().end(); ++ fl)
      {
        if (fl->getQuantity() < 0 && fl->getBuffer()->getLocation()->isMemberOf(origin))
          oper = opitemdist;
      }
    }
    else
      oper = opitemdist;
  }

  // No matching operation is found.
  if (!oper)
  {
    // We'll create one now, but that requires that we have an origin defined.
    if (!origin)
      throw DataException("Origin location is needed on this distribution order");
    Buffer* originbuffer = NULL;
    for (Buffer::iterator bufiter = Buffer::begin(); bufiter != Buffer::end(); ++bufiter)
    {
      if (bufiter->getLocation() == origin && bufiter->getItem() == item)
      {
        if (originbuffer)
        {
          stringstream o;
          o << "Multiple buffers found for item '" << item << "'' and location'" << dest << "'";
          throw DataException(o.str());
        }
        originbuffer = &*bufiter;
      }
    }
    if (!originbuffer)
    {
      // Create the origin buffer
      originbuffer = new BufferDefault();
      stringstream o;
      o << item << " @ " << origin;
      originbuffer->setName(o.str());
      originbuffer->setItem(item);
      originbuffer->setLocation(origin);
    }
    // Note: We know that we need to create a new one. An existing one would
    // have created an operation on the buffer already.
    ItemDistribution *itemdist = new ItemDistribution();
    itemdist->setOrigin(origin);
    itemdist->setItem(item);
    itemdist->setDestination(dest);
    oper = new OperationItemDistribution(itemdist, originbuffer, destbuffer);
    new ProblemInvalidData(oper, "Distribution orders on unauthorized lanes", "operation",
      Date::infinitePast, Date::infiniteFuture, 1);
  }

  // Finally, create the operationplan
  OperationPlan *opplan = oper->createOperationPlan(qty, start, end, NULL, NULL, 0, false);
  if (id)
    opplan->setIdentifier(id);
  if (status)
    opplan->setStatus(status);
  if (ref)
    opplan->setReference(ref);
  if (!consume)
    opplan->setConsumeMaterial(false);
  opplan->activate();

  // Return result
  Py_INCREF(opplan);
  return opplan;
}