DECLARE_EXPORT void Plan::setCurrent (Date l)
{
// Update the time
cur_Date = l;
// Let all operationplans check for new ProblemBeforeCurrent and
// ProblemBeforeFence problems.
for (Operation::iterator i = Operation::begin(); i != Operation::end(); ++i)
i->setChanged();
}
DECLARE_EXPORT PyObject* eraseModel(PyObject* self, PyObject* args)
{
// Pick up arguments
PyObject *obj = NULL;
int ok = PyArg_ParseTuple(args, "|O:erase", &obj);
if (!ok) return NULL;
// Validate the argument
bool deleteStaticModel = false;
if (obj) deleteStaticModel = PythonData(obj).getBool();
// Execute and catch exceptions
Py_BEGIN_ALLOW_THREADS // Free Python interpreter for other threads
try
{
if (deleteStaticModel)
{
// Delete all entities.
// The order is chosen to minimize the work of the individual destructors.
// E.g. the destructor of the item class recurses over all demands and
// all buffers. It is much faster if there are none already.
Operation::clear();
Demand::clear();
Buffer::clear();
Resource::clear();
SetupMatrix::clear();
Location::clear();
Customer::clear();
Calendar::clear();
Supplier::clear();
Item::clear();
Plan::instance().setName("");
Plan::instance().setDescription("");
// The setup operation is a static singleton and should always be around
OperationSetup::setupoperation = new OperationSetup();
OperationSetup::setupoperation->setName("setup operation");
}
else
{
// Delete the operationplans only
for (Operation::iterator gop = Operation::begin();
gop != Operation::end(); ++gop)
gop->deleteOperationPlans();
}
}
catch (...)
{
Py_BLOCK_THREADS;
PythonType::evalException();
return NULL;
}
Py_END_ALLOW_THREADS // Reclaim Python interpreter
return Py_BuildValue("");
}
DECLARE_EXPORT Skill::~Skill()
{
// The ResourceSkill objects are automatically deleted by the destructor
// of the Association list class.
// Clean up the references on the load models
for (Operation::iterator o = Operation::begin(); o != Operation::end(); ++o)
for(Operation::loadlist::const_iterator l = o->getLoads().begin();
l != o->getLoads().end(); ++l)
if (l->getSkill() == this)
const_cast<Load&>(*l).setSkill(NULL);
}
Location::~Location()
{
// Remove all references from buffers to this location
for (Buffer::iterator buf = Buffer::begin();
buf != Buffer::end(); ++buf)
if (buf->getLocation() == this)
buf->setLocation(nullptr);
// Remove all references from resources to this location
for (Resource::iterator res = Resource::begin();
res != Resource::end(); ++res)
if (res->getLocation() == this)
res->setLocation(nullptr);
// Remove all references from operations to this location
for (Operation::iterator oper = Operation::begin();
oper != Operation::end(); ++oper)
if (oper->getLocation() == this)
oper->setLocation(nullptr);
// Remove all references from demands to this location
for (Demand::iterator dmd = Demand::begin();
dmd != Demand::end(); ++dmd)
if (dmd->getLocation() == this)
dmd->setLocation(nullptr);
// Remove all item suppliers referencing this location
for (Supplier::iterator sup = Supplier::begin();
sup != Supplier::end(); ++sup)
{
for (Supplier::itemlist::const_iterator it = sup->getItems().begin();
it != sup->getItems().end(); )
{
if (it->getLocation() == this)
{
const ItemSupplier *itemsup = &*it;
++it; // Advance iterator before the delete
delete itemsup;
}
else
++it;
}
}
// The ItemDistribution objects are automatically deleted by the
// destructor of the Association list class.
}
DECLARE_EXPORT Location::~Location()
{
// Remove all references from buffers to this location
for (Buffer::iterator buf = Buffer::begin();
buf != Buffer::end(); ++buf)
if (buf->getLocation() == this) buf->setLocation(NULL);
// Remove all references from resources to this location
for (Resource::iterator res = Resource::begin();
res != Resource::end(); ++res)
if (res->getLocation() == this) res->setLocation(NULL);
// Remove all references from operations to this location
for (Operation::iterator oper = Operation::begin();
oper != Operation::end(); ++oper)
if (oper->getLocation() == this) oper->setLocation(NULL);
}
void Load::writer(const MetaCategory* c, Serializer* o)
{
bool firstload = true;
for (Operation::iterator i = Operation::begin(); i != Operation::end(); ++i)
for (Operation::loadlist::const_iterator j = i->getLoads().begin(); j != i->getLoads().end(); ++j)
{
if (firstload)
{
o->BeginList(Tags::loads);
firstload = false;
}
// We use the FULL mode, to force the loads being written regardless
// of the depth in the XML tree.
o->writeElement(Tags::load, &*j, FULL);
}
if (!firstload) o->EndList(Tags::loads);
}
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("");
}
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;
}
