void TestLabel( NETLIST_OBJECT_LIST* aList, unsigned aNetItemRef, unsigned aStartNet )
{
unsigned netItemTst = aStartNet;
int erc = 1;
/* Review the list of labels connected to NetItemRef. */
for( ; ; netItemTst++ )
{
if( netItemTst == aNetItemRef )
continue;
/* Is always in the same net? */
if( ( netItemTst == aList->size() )
|| ( aList->GetItemNet( aNetItemRef ) != aList->GetItemNet( netItemTst ) ) )
{
/* End Netcode found. */
if( erc )
{
/* Glabel or SheetLabel orphaned. */
Diagnose( aList->GetItem( aNetItemRef ), NULL, -1, WAR );
}
return;
}
if( aList->GetItem( aNetItemRef )->IsLabelConnected( aList->GetItem( netItemTst ) ) )
erc = 0;
//same thing, different order.
if( aList->GetItem( netItemTst )->IsLabelConnected( aList->GetItem( aNetItemRef ) ) )
erc = 0;
}
}
int Gen3D::compute(const char *)
{
int i;
isset = 0;
if(Diagnose()<0)
return FAIL;
int numVelos=0;
int numGeos=0;
int numPress=0;
float *xCoords,*yCoords,*zCoords;
float *xCoordsIn,*yCoordsIn,*zCoordsIn;
float *uIn, *vIn, *wIn;
int *plist,*clist,*vlist,*tlist;
int no_pl,no_vl,no_points;
if (isset)
{
}
else // (isset=0)
{
polyIn = (coDoPolygons *)p_inPoly->getCurrentObject();
no_pl = polyIn->getNumPolygons();
no_vl = polyIn->getNumVertices();
no_points = polyIn->getNumPoints();
polyIn->getAddresses(&xCoordsIn,&yCoordsIn,&zCoordsIn,&clist,&plist);
int nelem = no_pl;
int nconn = 8*no_pl;
int ncoord = 2*no_points;
int *elem;
int *conn;
gridOutObj = new coDoUnstructuredGrid(p_outGrid->getObjName(),nelem,nconn,ncoord,1);
gridOutObj->getAddresses(&elem,&conn,&xCoords,&yCoords,&zCoords);
gridOutObj->getTypeList(&tlist);
for(i=0;i<no_pl;i++)
{
tlist[i]=TYPE_HEXAGON;
}
// element list is easy as we just have hexas ...
for(i=0;i<no_pl;i++)
{
elem[i] = 8*i;
}
// connectivity list made of corner list
for(i=0;i<no_pl;i++)
{
conn[8*i+0] = clist[plist[i]+0];
conn[8*i+1] = clist[plist[i]+1];
conn[8*i+2] = clist[plist[i]+2];
conn[8*i+3] = clist[plist[i]+3];
conn[8*i+4] = clist[plist[i]+0]+no_points;
conn[8*i+5] = clist[plist[i]+1]+no_points;
conn[8*i+6] = clist[plist[i]+2]+no_points;
conn[8*i+7] = clist[plist[i]+3]+no_points;
}
// the coordinate list is easy as soon as we know in which direction to expand ...
// to find out in which coordinate plain (XY, XZ, YZ) the 2D grid lies in,
// we get a normal vector in the first element
float x1,x2,x3,y1,y2,y3,z1,z2,z3,nx,ny,nz;
x1 = xCoordsIn[0]; y1 = xCoordsIn[0]; z1 = zCoordsIn[0];
x2 = xCoordsIn[1]; y2 = xCoordsIn[1]; z2 = zCoordsIn[1];
x3 = xCoordsIn[2]; y3 = xCoordsIn[2]; z3 = zCoordsIn[2];
nx = (fabs) ( 1000*(y2-y1)*(z3-z1)-1000*(z2-z1)*(y3-y1) );
ny = (fabs) ( 1000*(z2-z1)*(x3-x1)-1000*(x2-x1)*(z3-z1) );
nz = (fabs) ( 1000*(x2-x1)*(y3-y1)-1000*(y2-y1)*(x3-x1) );
float min = FLT_MAX;
int min_axis[3] = {0,0,0};
if (nx<min)
{
min_axis[0]=1;
min_axis[1]=0;
min_axis[2]=0;
}
if (ny<min)
{
min_axis[0]=0;
min_axis[1]=1;
min_axis[2]=0;
}
if (nz<min)
{
min_axis[0]=0;
min_axis[1]=0;
min_axis[2]=1;
}
// we'd like to have a XY-grid, so we exchange the corrdinates ...
float *tmp;
if (min_axis[0]==1) //YZ
{
tmp=xCoordsIn;
xCoordsIn=zCoordsIn;
zCoordsIn=tmp;
}
if (min_axis[1]==1) //XZ
{
tmp=yCoordsIn;
yCoordsIn=zCoordsIn;
zCoordsIn=tmp;
}
float delta = p_thick->getValue();
for(i=0;i<no_points;i++)
{
zCoords[i]=zCoordsIn[i]-min_axis[2]*delta/2.;
zCoords[i+no_points]=zCoordsIn[i]+min_axis[2]*delta/2.;
yCoords[i]=yCoordsIn[i]-min_axis[1]*delta/2.;
yCoords[i+no_points]=yCoordsIn[i]+min_axis[1]*delta/2.;
xCoords[i]=xCoordsIn[i]-min_axis[0]*delta/2.;
xCoords[i+no_points]=xCoordsIn[i]-min_axis[0]*delta/2.;
}
p_outGrid->setCurrentObject(gridOutObj);
// velocity
veloInObj = (coDoVec3 *)p_inVelo->getCurrentObject();
no_points = veloInObj->getNumPoints();
// change of axis to xy!
veloInObj->getAddresses(&uIn,&vIn,&wIn);
float *uOut = new float[2*no_points];
float *vOut = new float[2*no_points];
float *wOut = new float[2*no_points];
if (min_axis[0]==1) //YZ
{
tmp=uIn;
uIn=wIn;
wIn=tmp;
}
if (min_axis[1]==1) //XZ
{
tmp=vIn;
vIn=wIn;
wIn=tmp;
}
for (i=0;i<no_points;i++)
{
uOut[i]=uIn[i];
uOut[i+no_points]=uIn[i];
vOut[i]=vIn[i];
vOut[i+no_points]=vIn[i];
wOut[i]=wIn[i];
wOut[i+no_points]=wIn[i];
}
veloOutObj = new coDoVec3(p_outVelo->getObjName(),2*no_points,uOut,vOut,wOut);
p_outVelo->setCurrentObject(veloOutObj);
}
return SUCCESS;
}
void DIALOG_ERC::TestErc( wxArrayString* aMessagesList )
{
wxFileName fn;
m_writeErcFile = m_WriteResultOpt->GetValue();
m_TestSimilarLabels = m_cbTestSimilarLabels->GetValue();
m_tstUniqueGlobalLabels = m_cbTestUniqueGlbLabels->GetValue();
// Build the whole sheet list in hierarchy (sheet, not screen)
SCH_SHEET_LIST sheets;
sheets.AnnotatePowerSymbols( Prj().SchLibs() );
if( m_parent->CheckAnnotate( aMessagesList, false ) )
{
if( aMessagesList )
{
wxString msg = _( "Annotation required!" );
msg += wxT( "\n" );
aMessagesList->Add( msg );
}
return;
}
SCH_SCREENS screens;
// Erase all previous DRC markers.
screens.DeleteAllMarkers( MARKER_BASE::MARKER_ERC );
for( SCH_SCREEN* screen = screens.GetFirst(); screen != NULL; screen = screens.GetNext() )
{
/* Ff wire list has changed, delete Undo Redo list to avoid pointers on deleted
* data problems.
*/
if( screen->SchematicCleanUp( NULL ) )
screen->ClearUndoRedoList();
}
/* Test duplicate sheet names inside a given sheet, one cannot have sheets with
* duplicate names (file names can be duplicated).
*/
TestDuplicateSheetNames( true );
std::auto_ptr<NETLIST_OBJECT_LIST> objectsConnectedList( m_parent->BuildNetListBase() );
// Reset the connection type indicator
objectsConnectedList->ResetConnectionsType();
unsigned lastNet;
unsigned nextNet = lastNet = 0;
int MinConn = NOC;
for( unsigned net = 0; net < objectsConnectedList->size(); net++ )
{
if( objectsConnectedList->GetItemNet( lastNet ) !=
objectsConnectedList->GetItemNet( net ) )
{
// New net found:
MinConn = NOC;
nextNet = net;
}
switch( objectsConnectedList->GetItemType( net ) )
{
// These items do not create erc problems
case NET_ITEM_UNSPECIFIED:
case NET_SEGMENT:
case NET_BUS:
case NET_JUNCTION:
case NET_LABEL:
case NET_BUSLABELMEMBER:
case NET_PINLABEL:
case NET_GLOBBUSLABELMEMBER:
break;
case NET_HIERLABEL:
case NET_HIERBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_SHEETBUSLABELMEMBER:
// ERC problems when pin sheets do not match hierarchical labels.
// Each pin sheet must match a hierarchical label
// Each hierarchical label must match a pin sheet
objectsConnectedList->TestforNonOrphanLabel( net, nextNet );
break;
case NET_GLOBLABEL:
if( m_tstUniqueGlobalLabels )
objectsConnectedList->TestforNonOrphanLabel( net, nextNet );
break;
case NET_NOCONNECT:
// ERC problems when a noconnect symbol is connected to more than one pin.
MinConn = NET_NC;
if( objectsConnectedList->CountPinsInNet( nextNet ) > 1 )
Diagnose( objectsConnectedList->GetItem( net ), NULL, MinConn, UNC );
break;
case NET_PIN:
// Look for ERC problems between pins:
TestOthersItems( objectsConnectedList.get(), net, nextNet, &MinConn );
break;
}
lastNet = net;
}
// Test similar labels (i;e. labels which are identical when
// using case insensitive comparisons)
if( m_TestSimilarLabels )
objectsConnectedList->TestforSimilarLabels();
// Displays global results:
updateMarkerCounts( &screens );
// Display diags:
DisplayERC_MarkersList();
// Display new markers:
m_parent->GetCanvas()->Refresh();
if( m_writeErcFile )
{
fn = g_RootSheet->GetScreen()->GetFileName();
fn.SetExt( wxT( "erc" ) );
wxFileDialog dlg( this, _( "ERC File" ), fn.GetPath(), fn.GetFullName(),
_( "Electronic rule check file (.erc)|*.erc" ),
wxFD_SAVE );
if( dlg.ShowModal() == wxID_CANCEL )
return;
if( WriteDiagnosticERC( dlg.GetPath() ) )
{
Close( true );
ExecuteFile( this, Pgm().GetEditorName(), QuoteFullPath( fn ) );
}
}
}
VOID
DigiDPCService( IN PKDPC Dpc,
IN PVOID DeferredContext,
IN PVOID SystemContext1,
IN PVOID SystemContext2 )
{
extern BOOLEAN DigiDriverInitialized; // from init.c
PDIGI_CONTROLLER_EXTENSION ControllerExt = DeferredContext;
DigiDump( DIGIDPCFLOW, ("DigiBoard: Entering DigiDPCService\n") );
// Ensure the controller is intialized.
if( DigiDriverInitialized // We can't get here if we're not initialized. --SWA
&& ControllerExt->ControllerState == DIGI_DEVICE_STATE_INITIALIZED )
{
USHORT DownloadRequest, FepStat;
USHORT Ein, Eout;
EnableWindow( ControllerExt, ControllerExt->Global.Window );
FepStat =
READ_REGISTER_USHORT( (PUSHORT)((PUCHAR)ControllerExt->VirtualAddress+
FEP_FEPSTAT) );
DownloadRequest =
READ_REGISTER_USHORT( (PUSHORT)((PUCHAR)ControllerExt->VirtualAddress+
FEP_DLREQ) );
Ein =
READ_REGISTER_USHORT( (PUSHORT)((PUCHAR)ControllerExt->VirtualAddress+
FEP_EIN) );
Eout =
READ_REGISTER_USHORT( (PUSHORT)((PUCHAR)ControllerExt->VirtualAddress+
FEP_EOUT) );
DisableWindow( ControllerExt );
if (FepStat!=FEP_FEPSTAT_OK)
{
LARGE_INTEGER CurrentSystemTime;
KeQuerySystemTime( &CurrentSystemTime );
InterlockedIncrement(&ControllerExt->WindowFailureCount);
DigiDump( DIGIERRORS, ("DigiBoard: Memory Window Failure (%d)\n", ControllerExt->WindowFailureCount));
if (CurrentSystemTime.HighPart!=ControllerExt->LastErrorLogTime.HighPart)
{
PHYSICAL_ADDRESS Signature;
Signature.LowPart = 0x5a5a5a5a;
ControllerExt->LastErrorLogTime = CurrentSystemTime;
DigiLogError( ControllerExt->DriverObject,
NULL,
Diagnose(ControllerExt),
Signature,
0,
0,
(UCHAR)ControllerExt->WindowFailureCount,
__LINE__,
STATUS_SUCCESS,
SERIAL_MEMORY_WINDOW_FAILURE,
ControllerExt->ControllerName.Length+1,
ControllerExt->ControllerName.Buffer,
0,
NULL );
}
}
else if( DownloadRequest ) // Look and see if there is a download request
{
// The Controller is requesting a concentrator download.
XXDownload( ControllerExt );
//
// We don't service any ports until all concentrator
// requests have been satisfied.
//
}
else if( Ein != Eout )
{
//
// Architecture ensures we have exclusive access to events on the controller.
// (We reschedule ourselves to run, so two instances cannot coexist.)
//
DigiServiceEvent( ControllerExt, Ein, Eout );
}
}
// Reset our timer.
KeSetTimer( &ControllerExt->PollTimer,
ControllerExt->PollTimerLength,
&ControllerExt->PollDpc );
DigiDump( DIGIDPCFLOW, ("DigiBoard: Exiting DigiDPCService\n") );
} // DigiDPCService
void TestOthersItems( NETLIST_OBJECT_LIST* aList,
unsigned aNetItemRef, unsigned aNetStart,
int* aNetNbItems, int* aMinConnexion )
{
unsigned netItemTst = aNetStart;
int jj;
int erc = OK;
/* Analysis of the table of connections. */
int ref_elect_type = aList->GetItem( aNetItemRef )->m_ElectricalType;
int local_minconn = NOC;
if( ref_elect_type == PIN_NC )
local_minconn = NPI;
/* Test pins connected to NetItemRef */
for( ; ; netItemTst++ )
{
if( aNetItemRef == netItemTst )
continue;
// We examine only a given net. We stop the search if the net changes
if( ( netItemTst >= aList->size() ) // End of list
|| ( aList->GetItemNet( aNetItemRef ) !=
aList->GetItemNet( netItemTst ) ) ) // End of net
{
/* End net code found: minimum connection test. */
if( ( *aMinConnexion < NET_NC ) && ( local_minconn < NET_NC ) )
{
/* Not connected or not driven pin. */
bool seterr = true;
if( local_minconn == NOC &&
aList->GetItemType( aNetItemRef ) == NET_PIN )
{
/* This pin is not connected: for multiple part per
* package, and duplicated pin,
* search for an other instance of this pin
* this will be flagged only if all instances of this pin
* are not connected
* TODO test also if instances connected are connected to
* the same net
*/
for( unsigned duplicate = 0; duplicate < aList->size(); duplicate++ )
{
if( aList->GetItemType( duplicate ) != NET_PIN )
continue;
if( duplicate == aNetItemRef )
continue;
if( aList->GetItem( aNetItemRef )->m_PinNum !=
aList->GetItem( duplicate )->m_PinNum )
continue;
if( ( (SCH_COMPONENT*) aList->GetItem( aNetItemRef )->
m_Link )->GetRef( &aList->GetItem( aNetItemRef )-> m_SheetPath ) !=
( (SCH_COMPONENT*) aList->GetItem( duplicate )->m_Link )
->GetRef( &aList->GetItem( duplicate )->m_SheetPath ) )
continue;
// Same component and same pin. Do dot create error for this pin
// if the other pin is connected (i.e. if duplicate net has an other
// item)
if( (duplicate > 0)
&& ( aList->GetItemNet( duplicate ) ==
aList->GetItemNet( duplicate - 1 ) ) )
seterr = false;
if( (duplicate < aList->size() - 1)
&& ( aList->GetItemNet( duplicate ) ==
aList->GetItemNet( duplicate + 1 ) ) )
seterr = false;
}
}
if( seterr )
Diagnose( aList->GetItem( aNetItemRef ), NULL, local_minconn, WAR );
*aMinConnexion = DRV; // inhibiting other messages of this
// type for the net.
}
return;
}
switch( aList->GetItemType( netItemTst ) )
{
case NET_ITEM_UNSPECIFIED:
case NET_SEGMENT:
case NET_BUS:
case NET_JUNCTION:
case NET_LABEL:
case NET_HIERLABEL:
case NET_BUSLABELMEMBER:
case NET_HIERBUSLABELMEMBER:
case NET_SHEETBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_GLOBLABEL:
case NET_GLOBBUSLABELMEMBER:
case NET_PINLABEL:
break;
case NET_NOCONNECT:
local_minconn = std::max( NET_NC, local_minconn );
break;
case NET_PIN:
jj = aList->GetItem( netItemTst )->m_ElectricalType;
local_minconn = std::max( MinimalReq[ref_elect_type][jj], local_minconn );
if( netItemTst <= aNetItemRef )
break;
*aNetNbItems += 1;
if( erc == OK )
{
erc = DiagErc[ref_elect_type][jj];
if( erc != OK )
{
if( aList->GetConnectionType( netItemTst ) == UNCONNECTED )
{
Diagnose( aList->GetItem( aNetItemRef ),
aList->GetItem( netItemTst ),
0, erc );
aList->SetConnectionType( netItemTst, NOCONNECT_SYMBOL_PRESENT );
}
}
}
break;
}
}
}
int
Sample::compute(const char *)
{
int x_value, y_value, z_value;
int s;
bool nan_flag = false; //TODO: Is this the right default-value?
float fill = .0; //TODO: Is this the right default-value?
int outside;
const char *object_type = NULL;
unstruct_grid::vecFlag typeFlag = unstruct_grid::DONTKNOW;
ias grids;
ias data;
grids.resize(1);
data.resize(1);
eps = epsParam->getValue();
if (eps < 0.0)
{
sendError("eps < 0.0 not allowed - please choose a valid eps");
return FAIL;
}
s = iSizeChoiceParam->getValue() + 1;
if (s == 1)
{
x_value = iSizeParam->getValue();
}
else
{
x_value = 2 << s;
}
s = jSizeChoiceParam->getValue() + 1;
if (s == 1)
{
y_value = jSizeParam->getValue();
}
else
{
y_value = 2 << s;
}
s = kSizeChoiceParam->getValue() + 1;
if (s == 1)
{
z_value = kSizeParam->getValue();
}
else
{
z_value = 2 << s;
}
if (x_value < 2)
{
sendWarning("Size in X dimension is less than 2, assuming 2");
iSizeParam->setValue(2);
x_value = 2;
}
if (y_value < 2)
{
sendWarning("Size in Y dimension is less than 2, assuming 2");
jSizeParam->setValue(2);
y_value = 2;
}
if (z_value < 2)
{
sendWarning("Size in Z dimension is less than 2, assuming 2");
kSizeParam->setValue(2);
z_value = 2;
}
outside = outsideChoiceParam->getValue();
if (outside == Sample::OUTSIDE_MAX_FLT)
{
nan_flag = true;
}
else if (outside == Sample::OUTSIDE_NUMBER)
{
fill = fillValueParam->getValue();
nan_flag = false;
}
bool isStrGrid = false;
// here we try to retrieve the data object from the required port
const coDistributedObject *GridObj = Grid_In_Port->getCurrentObject();
TimeSteps = 0;
if (!GridObj)
{
sendError("cannot retrieve the grid object");
return FAIL;
}
else if (strcmp(GridObj->getType(), "SETELE") == 0)
{
// Time Steps or not...
const coDoSet *setGrid = (const coDoSet *)(GridObj);
gridTimeSteps = setGrid->getAllElements(&num_set_ele);
if (GridObj->getAttribute("TIMESTEP"))
{
// We have timesteps
TimeSteps = 1;
gridTimeSteps = setGrid->getAllElements(&num_set_ele);
grids.resize(num_set_ele);
data.resize(num_set_ele);
for (int time = 0; time < num_set_ele; ++time)
{
if (gridTimeSteps[time]->isType("SETELE"))
{
// extract list from the set gridTimeSteps[time]
const coDistributedObject *const *elemsInGridTimeSteps;
int numInGridTimeSteps;
elemsInGridTimeSteps = ((coDoSet *)(gridTimeSteps[time]))->getAllElements(&numInGridTimeSteps);
//ExpandSetList (elemsInGridTimeSteps, numInGridTimeSteps, "UNSGRD", grids[time]);
ExpandSetList(elemsInGridTimeSteps, numInGridTimeSteps, &object_type, grids[time]);
}
else if (!object_type)
{
if (gridTimeSteps[time]->isType("POINTS")
|| gridTimeSteps[time]->isType("UNSGRD")
|| gridTimeSteps[time]->isType("UNIGRD")
|| gridTimeSteps[time]->isType("RCTGRD")
|| gridTimeSteps[time]->isType("STRGRD"))
{
object_type = gridTimeSteps[time]->getType();
grids[time].resize(1);
grids[time][0] = gridTimeSteps[time];
}
else
{
// Strange object in the grid object
sendError("Objects in the grid object have to be sets, unstructured grids or points");
return FAIL;
}
}
else if (strcmp(gridTimeSteps[time]->getType(), object_type) == 0)
{
grids[time].resize(1);
grids[time][0] = gridTimeSteps[time];
}
else
{
// Strange object in the grid object
sendError("Objects in the grid object have to be sets, unstructured grids or points");
return FAIL;
}
}
if (object_type && (!strcmp(object_type, "UNIGRD") || !strcmp(object_type, "RCTGRD") || !strcmp(object_type, "STRGRD")))
{
isStrGrid = true;
}
}
else
{
// Static grid
// We may set up grids
num_blocks = ExpandSetList(gridTimeSteps, num_set_ele, &object_type, grids[0]);
if (!object_type || (strcmp(object_type, "UNSGRD") != 0
&& strcmp(object_type, "POINTS") != 0
&& strcmp(object_type, "UNIGRD") != 0
&& strcmp(object_type, "RCTGRD") != 0
&& strcmp(object_type, "STRGRD") != 0))
{
// Strange object in the grid object
sendError("Objects in the grid object have to be sets, unstructured grids or points");
return FAIL;
}
}
}
else if (strcmp(GridObj->getType(), "UNSGRD") == 0)
{
object_type = "UNSGRD";
num_blocks = 1;
grids[0].push_back(GridObj);
}
else if (strcmp(GridObj->getType(), "UNIGRD") == 0)
{
object_type = "UNIGRD";
num_blocks = 1;
grids[0].push_back(GridObj);
isStrGrid = true;
}
else if (strcmp(GridObj->getType(), "RCTGRD") == 0)
{
object_type = "RCTGRD";
num_blocks = 1;
grids[0].push_back(GridObj);
isStrGrid = true;
}
else if (strcmp(GridObj->getType(), "STRGRD") == 0)
{
object_type = "STRGRD";
num_blocks = 1;
grids[0].push_back(GridObj);
isStrGrid = true;
}
else if (strcmp(GridObj->getType(), "POINTS") == 0)
{
object_type = "POINTS";
num_blocks = 1;
grids[0].push_back(GridObj);
}
else
{
sendError("Sorry, only objects of type unstructured grid or points are supported");
return FAIL;
}
fprintf(stderr, "isStrGrid=%d, type=%s\n", int(isStrGrid), object_type);
if (!object_type)
{
sendError("Sorry, only objects of type unstructured grid or points are supported");
return FAIL;
}
if (strcmp(object_type, "POINTS") == 0)
{
typeFlag = unstruct_grid::POINT;
}
// here we try to retrieve the data object from the port
const coDistributedObject *DataObj = Data_In_Port->getCurrentObject();
if (!DataObj)
{
cerr << "data: NULL" << endl;
if (typeFlag != unstruct_grid::POINT)
{
sendError("cannot retrieve data object");
return FAIL;
}
}
else if (strcmp(DataObj->getType(), "SETELE") == 0)
{
// Time Steps or not...: that is decided according to the grid.
if (strcmp(GridObj->getType(), "SETELE") != 0)
{
sendError("Grid object is a set, but not the data");
return FAIL;
}
int data_num_set_ele;
int data_num_blocks;
coDoSet *setData = (coDoSet *)(DataObj);
dataTimeSteps = setData->getAllElements(&data_num_set_ele);
if (TimeSteps)
{
// We have timesteps
if (data_num_set_ele != num_set_ele)
{
sendError("Number of time steps in grid does not match data set");
return FAIL;
}
for (int time = 0; time < num_set_ele; ++time)
{
if (strcmp(dataTimeSteps[time]->getType(), "SETELE") == 0)
{
// extract list from the set gridTimeSteps[time]
int numInDataTimeSteps;
const coDistributedObject *const *elemsInDataTimeSteps = ((coDoSet *)(dataTimeSteps[time]))->getAllElements(&numInDataTimeSteps);
const char *type = NULL;
int num_data = ExpandSetList(elemsInDataTimeSteps, numInDataTimeSteps, &type, data[time]);
if (!type)
{
sendError("Invalid data");
return FAIL;
}
if (num_data != grids[time].size())
{
sendError("Cannot match grids and data sets -- data must be node based");
return FAIL;
}
// try first vector
if (strcmp(type, "USTVDT") == 0)
{
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::VECTOR;
}
else
{
sendError("Cannot decide between vector, scalar, and point");
return FAIL;
}
}
// then try scalar
else if (strcmp(type, "USTSDT") == 0)
{
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::SCALAR;
}
else
{
sendError("Cannot decide between vector, scalar, and point");
return FAIL;
}
}
else if (strcmp(type, "POINTS") == 0)
{
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::POINT;
}
else
{
sendError("Cannot decide between vector, scalar, and point");
return FAIL;
}
}
else
{
sendError("Invalid data type");
return FAIL;
}
}
else if (strcmp(dataTimeSteps[time]->getType(), "USTSDT") == 0)
{
data[time].resize(1);
data[time][0] = dataTimeSteps[time];
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::SCALAR;
}
else if (typeFlag == unstruct_grid::VECTOR)
{
sendError("Cannot decide between vector and scalar");
return FAIL;
}
}
else if (strcmp(dataTimeSteps[time]->getType(), "USTVDT") == 0)
{
data[time].resize(1);
data[time][0] = dataTimeSteps[time];
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::VECTOR;
}
else if (typeFlag != unstruct_grid::VECTOR)
{
sendError("Cannot decide between vector and scalar");
return FAIL;
}
}
else if (strcmp(dataTimeSteps[time]->getType(), "POINTS") == 0)
{
data[time].resize(1);
data[time][0] = dataTimeSteps[time];
if (typeFlag == unstruct_grid::DONTKNOW)
{
typeFlag = unstruct_grid::POINT;
}
else if (typeFlag != unstruct_grid::POINT)
{
sendError("Cannot decide between vector, scalar and point");
return FAIL;
}
}
else
{
sendError("Object of incorrect type in data set");
return FAIL;
}
}
} // static set... set up data
else
{
const char *type = NULL;
data_num_blocks = ExpandSetList(dataTimeSteps, data_num_set_ele, &type, data[0]);
if (!type)
{
sendError("Invalid data");
return FAIL;
}
if (data_num_blocks != num_blocks)
{
sendError("Grid and data sets do not match for the accepted types");
return FAIL;
}
if (typeFlag == unstruct_grid::DONTKNOW)
{
if (strcmp(type, "USTSDT") == 0)
{
typeFlag = unstruct_grid::SCALAR;
}
else if (strcmp(type, "USTVDT") == 0)
{
typeFlag = unstruct_grid::VECTOR;
}
else if (strcmp(type, "POINTS") == 0)
{
typeFlag = unstruct_grid::POINT;
}
else
{
sendError("Invalid data type");
return FAIL;
}
}
}
}
else if (strcmp(DataObj->getType(), "USTSDT") == 0)
{
data[0].resize(1);
data[0][0] = (DataObj);
if (typeFlag == unstruct_grid::DONTKNOW)
typeFlag = unstruct_grid::SCALAR;
}
else if (strcmp(DataObj->getType(), "USTVDT") == 0)
{
data[0].resize(1);
data[0][0] = (DataObj);
if (typeFlag == unstruct_grid::DONTKNOW)
typeFlag = unstruct_grid::VECTOR;
}
else if (strcmp(DataObj->getType(), "POINTS") == 0)
{
data[0].resize(1);
data[0][0] = (DataObj);
if (typeFlag == unstruct_grid::DONTKNOW)
typeFlag = unstruct_grid::POINT;
}
else
{
sendError("Only scalar or vector unstructured data, points or sets thereof are supported");
return FAIL;
}
coDoUniformGrid **destGrids = NULL;
const coDistributedObject *refGrid = Reference_Grid_In_Port->getCurrentObject();
if (refGrid)
{
if (TimeSteps)
{
destGrids = new coDoUniformGrid *[num_set_ele];
}
else
{
destGrids = new coDoUniformGrid *[1];
}
if (!strcmp(refGrid->getType(), "SETELE"))
{
coDoSet *set = (coDoSet *)refGrid;
int refgrid_num_set_ele;
const coDistributedObject *const *refGridTimeSteps = set->getAllElements(&refgrid_num_set_ele);
if (TimeSteps)
{
if (refgrid_num_set_ele != num_set_ele)
{
sendError("Number of time steps in reference grid does not match data set");
return FAIL;
}
for (int i = 0; i < num_set_ele; i++)
{
if (strcmp(refGridTimeSteps[i]->getType(), "UNIGRD"))
{
sendError("Reference grid must be a uniform grid or a set thereof");
return FAIL;
}
coDoUniformGrid *ugr = (coDoUniformGrid *)refGridTimeSteps[i];
destGrids[i] = ugr;
}
}
}
else
{
if (strcmp(refGrid->getType(), "UNIGRD"))
{
sendError("Reference grid must be a uniform grid or a set thereof");
return FAIL;
}
coDoUniformGrid *ugr = (coDoUniformGrid *)refGrid;
if (TimeSteps)
{
for (int i = 0; i < num_set_ele; i++)
{
destGrids[i] = ugr;
}
}
else
{
destGrids[0] = ugr;
}
}
}
if (Diagnose(grids, data, typeFlag, isStrGrid) < 0)
{
sendError("Grid and data are not compatible or an undefined problem occurred");
return FAIL;
}
// check struncture of grids, sdata and vdata
// Diagnose
// check dimension of grid and data
/*
int numElems, numIndices, numCoords, numData;
((coDoUnstructuredGrid *)GridObj)->getGridSize(&numElems, &numIndices, &numCoords);
numData = ((coDoFloat*)DataObj)->getNumPoints();
if (numData != numCoords)
{
if (numData == numElems)
{
sendError("Sample supports only vertex based data - you seem to have cell based data");
return FAIL;
}
else
{
char str[500];
sprintf (str, "Dimension of data doesn't match dimension of grid - found %d coordinates and %d data", numCoords, numData);
sendError(str);
return FAIL;
}
}
*/
// now we create an object for the output port: get the name and make the Obj
const char *Grid_outObjName = Grid_Out_Port->getObjName();
const char *Data_outObjName = Data_Out_Port->getObjName();
char time_grid_name[64];
char time_data_name[64];
strcpy(time_grid_name, Grid_outObjName);
strcpy(time_data_name, Data_outObjName);
coDistributedObject **usg = new coDistributedObject *[grids.size() + 1];
usg[grids.size()] = 0;
coDistributedObject **str = new coDistributedObject *[grids.size() + 1];
str[grids.size()] = 0;
int strelem;
for (strelem = 0; strelem < grids.size(); ++strelem)
{
str[strelem] = NULL;
}
float gmin[3] = { FLT_MAX, FLT_MAX, FLT_MAX },
gmax[3] = { -FLT_MAX, -FLT_MAX, -FLT_MAX };
if (!destGrids && p_bounding_box->getValue() == 1) // automatic globally
{
for (int time = 0; time < grids.size(); time++)
{
unstruct_grid *calc_grid = new unstruct_grid(grids[time],
typeFlag, isStrGrid);
calc_grid->automaticBoundBox();
const float *min, *max;
calc_grid->getMinMax(min, max);
for (int i = 0; i < 3; i++)
{
if (min[i] < gmin[i])
gmin[i] = min[i];
if (max[i] > gmax[i])
gmax[i] = max[i];
}
delete calc_grid;
}
}
for (int time = 0; time < grids.size(); time++)
{
if (TimeSteps)
{
sprintf(time_grid_name, "%s_%d", Grid_outObjName, time);
sprintf(time_data_name, "%s_%d", Data_outObjName, time);
}
// unstruct_grid *calc_grid=new unstruct_grid((coDoUnstructuredGrid*)GridObj);
//int size = grids[time].size ();
//@@@ int num_compressed = grids[time].num_compressed();
unstruct_grid *calc_grid = new unstruct_grid(grids[time], typeFlag, isStrGrid);
if (destGrids)
{
float min[3], max[3];
destGrids[time]->getMinMax(&min[0], &max[0],
&min[1], &max[1],
&min[2], &max[2]);
p_P1bound_manual->setValue(min[0], min[1], min[2]);
p_P2bound_manual->setValue(max[0], max[1], max[2]);
calc_grid->manualBoundBox(min[0], min[1], min[2],
max[0], max[1], max[2]);
destGrids[time]->getGridSize(&x_value, &y_value, &z_value);
}
else if (p_bounding_box->getValue() == 0) // automatic per timestep
{
calc_grid->automaticBoundBox();
const float *min, *max;
calc_grid->getMinMax(min, max);
p_P1bound_manual->setValue(min[0], min[1], min[2]);
p_P2bound_manual->setValue(max[0], max[1], max[2]);
}
else if (p_bounding_box->getValue() == 1) // automatic globally
{
calc_grid->manualBoundBox(gmin[0], gmin[1], gmin[2],
gmax[0], gmax[1], gmax[2]);
}
else if (p_bounding_box->getValue() == 2) // manual
{
calc_grid->manualBoundBox(p_P1bound_manual->getValue(0),
p_P1bound_manual->getValue(1),
p_P1bound_manual->getValue(2),
p_P2bound_manual->getValue(0),
p_P2bound_manual->getValue(1),
p_P2bound_manual->getValue(2));
}
const coDistributedObject **ndata = NULL;
if (data.size() > time && data[time].size() > 0)
ndata = &data[time][0];
calc_grid->set_value(nan_flag, fill);
// create data on strcutured grid
if (grids[time].size() <= 0)
{
x_value = y_value = z_value = 1;
}
if ((typeFlag == unstruct_grid::SCALAR || typeFlag == unstruct_grid::VECTOR) && isStrGrid)
{
calc_grid->sample_structured(ndata,
time_grid_name, &usg[time],
time_data_name, &str[time], x_value, y_value, z_value);
}
else if (typeFlag == unstruct_grid::POINT)
{
calc_grid->sample_points(ndata,
time_grid_name, &usg[time],
time_data_name, &str[time], x_value, y_value, z_value,
p_pointSampling->getValue());
}
else
{
switch (p_algorithm->getValue())
{
case SAMPLE_ACCURATE:
// sl: this algorithm (the "old" one)
// is not as exact as it promises.
// The problem is that internally it calculates
// the indices around the element nodes approximating
// by default... As a result of this, strange
// effects appear sometimes near the borders.
// For this reason, and because it is very slow
// (that is why it is not worth the effort correcting
// the inaccuracies near the borders),
// the other new algorithms are recommended,
// especially SAMPLE_NO_HOLES_BETTER.
calc_grid->sample_accu(ndata, /*&sdata[time][0] */
time_grid_name, &usg[time],
time_data_name, &str[time], x_value, y_value, z_value, eps);
break;
case SAMPLE_HOLES:
calc_grid->sample_holes(ndata,
time_grid_name, &usg[time], time_data_name, &str[time], x_value, y_value, z_value);
break;
case SAMPLE_NO_HOLES:
calc_grid->sample_no_holes(ndata,
time_grid_name, &usg[time],
time_data_name, &str[time], x_value, y_value, z_value, 0);
break;
case SAMPLE_NO_HOLES_BETTER:
calc_grid->sample_no_holes(ndata,
time_grid_name, &usg[time],
time_data_name, &str[time], x_value, y_value, z_value, 1);
break;
}
}
// attach the name of the input data object to the output grid object
if ((typeFlag == unstruct_grid::SCALAR || typeFlag == unstruct_grid::VECTOR) && isStrGrid)
{
const char **names, **values;
int n = grids[time][0]->getAllAttributes(&names, &values);
for (int i = 0; i < n; i++)
{
if (strcmp(names[i], "Transformation") != 0)
{
usg[time]->addAttribute(names[i], values[i]);
}
}
}
else
{
usg[time]->copyAllAttributes(grids[time][0]);
}
if (ndata)
{
usg[time]->addAttribute("DataObjectName", (*ndata)->getName());
str[time]->copyAllAttributes((*ndata) /*sdata[time][0] */);
}
delete calc_grid;
}
// tell the output port that this is his object
if (TimeSteps == 0)
{
Grid_Out_Port->setCurrentObject(usg[0]);
Data_Out_Port->setCurrentObject(str[0]);
}
else
{
coDoSet *gridOutTime = new coDoSet(Grid_outObjName, usg);
sprintf(time_grid_name, "1 %d", (int)grids.size());
gridOutTime->addAttribute("TIMESTEP", time_grid_name);
Grid_Out_Port->setCurrentObject(gridOutTime);
// if(typeFlag == unstruct_grid::SCALAR){
coDoSet *dataOutTime = new coDoSet(Data_outObjName, str);
dataOutTime->addAttribute("TIMESTEP", time_grid_name);
Data_Out_Port->setCurrentObject(dataOutTime);
// }
}
// Add INTERACTOR attribute to the grid
coFeedback feedback("Sample");
feedback.addPara(iSizeParam);
feedback.addPara(jSizeParam);
feedback.addPara(kSizeParam);
feedback.addPara(p_P1bound_manual);
feedback.addPara(p_P2bound_manual);
coDistributedObject *obj = Grid_Out_Port->getCurrentObject();
if (obj)
feedback.apply(obj);
return SUCCESS;
}
void TestLabel(WinEDA_DrawPanel * panel, wxDC * DC,
ObjetNetListStruct * NetItemRef, ObjetNetListStruct * StartNet)
/***********************************************************************/
/* Routine controlant qu'un sheetLabel est bien connecte a un Glabel de la
sous-feuille correspondante
*/
{
ObjetNetListStruct * NetItemTst, * Lim;
int erc = 1;
/* Analyse de la table des connexions : */
Lim = g_TabObjNet + g_NbrObjNet;
NetItemTst = StartNet;
/* Examen de la liste des Labels connectees a NetItemRef */
for ( ; ; NetItemTst ++ )
{
if( NetItemTst == NetItemRef ) continue;
/* Est - on toujours dans le meme net ? */
if( ( NetItemTst == Lim ) ||
( NetItemRef->m_NetCode != NetItemTst->m_NetCode ) )
{ /* Fin de netcode trouve */
if( erc )
{ /* GLabel ou SheetLabel orphelin */
Diagnose(panel, DC, NetItemRef, NULL, -1, WAR);
}
return;
}
if( (NetItemRef->m_Type == NET_GLOBLABEL) ||
(NetItemRef->m_Type == NET_GLOBBUSLABELMEMBER) )
{
switch ( NetItemTst->m_Type )
{
case NET_SEGMENT:
case NET_BUS:
case NET_JONCTION:
case NET_LABEL:
case NET_GLOBLABEL:
case NET_BUSLABELMEMBER:
case NET_GLOBBUSLABELMEMBER:
case NET_PINLABEL:
case NET_NOCONNECT:
case NET_PIN:
break;
case NET_SHEETBUSLABELMEMBER:
case NET_SHEETLABEL:
/* Tst si le GLabel est bien dans la bonne sousfeuille */
if( NetItemRef->m_SheetNumber == NetItemTst->m_NumInclude )
{
erc = 0;
}
break;
}
}
else
{
switch ( NetItemTst->m_Type )
{
case NET_SEGMENT:
case NET_BUS:
case NET_JONCTION:
case NET_LABEL:
case NET_BUSLABELMEMBER:
case NET_SHEETBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_PINLABEL:
case NET_NOCONNECT:
case NET_PIN:
break;
case NET_GLOBLABEL:
case NET_GLOBBUSLABELMEMBER:
/* Tst si le GLabel est bien dans la bonne sous-feuille */
if( NetItemTst->m_SheetNumber == NetItemRef->m_NumInclude )
{
erc = 0;
}
break;
}
}
}
}
static void TestOthersItems(WinEDA_DrawPanel * panel, wxDC * DC,
ObjetNetListStruct * NetItemRef,
ObjetNetListStruct * netstart,
int * NetNbItems, int * MinConnexion)
/********************************************************************/
/* Routine testant les conflits electriques entre
NetItemRef
et les autres items du meme net
*/
{
ObjetNetListStruct * NetItemTst, * Lim;
int ref_elect_type, jj, erc = OK, local_minconn;
/* Analyse de la table des connexions : */
Lim = g_TabObjNet + g_NbrObjNet; // pointe la fin de la liste
ref_elect_type = NetItemRef->m_ElectricalType;
NetItemTst = netstart;
local_minconn = NOC;
/* Examen de la liste des Pins connectees a NetItemRef */
for ( ; ; NetItemTst ++ )
{
if ( NetItemRef == NetItemTst ) continue;
/* Est - on toujours dans le meme net ? */
if( (NetItemTst >= Lim) || // fin de liste (donc fin de net)
(NetItemRef->m_NetCode != NetItemTst->m_NetCode) ) // fin de net
{ /* Fin de netcode trouve: Tst connexion minimum */
if( (*MinConnexion < NET_NC ) &&
(local_minconn < NET_NC ) ) /* pin non connectée ou non pilotee */
{
Diagnose(panel, DC, NetItemRef, NULL, local_minconn, WAR);
* MinConnexion = DRV; // inhibition autres messages de ce type pour ce net
}
return;
}
switch ( NetItemTst->m_Type )
{
case NET_SEGMENT:
case NET_BUS:
case NET_JONCTION:
case NET_LABEL:
case NET_GLOBLABEL:
case NET_BUSLABELMEMBER:
case NET_GLOBBUSLABELMEMBER:
case NET_SHEETBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_PINLABEL:
break;
case NET_NOCONNECT:
local_minconn = MAX( NET_NC, local_minconn);
break;
case NET_PIN:
jj = NetItemTst->m_ElectricalType;
local_minconn = MAX( MinimalReq[ref_elect_type][jj], local_minconn );
if ( NetItemTst <= NetItemRef ) break;
*NetNbItems += 1;
if( erc == OK ) // 1 marqueur par pin maxi
{
erc = DiagErc[ref_elect_type][jj];
if (erc != OK )
{
if( NetItemTst->m_FlagOfConnection == 0 )
{
Diagnose(panel, DC, NetItemRef, NetItemTst, 0, erc);
NetItemTst->m_FlagOfConnection = (IsConnectType) 1;
}
}
}
break;
}
}
}
void WinEDA_ErcFrame::TestErc(wxCommandEvent& event)
/**************************************************/
{
ObjetNetListStruct * NetItemRef, * OldItem, * StartNet, * Lim;
int NetNbItems, MinConn;
if ( ! DiagErcTableInit )
{
memcpy(DiagErc, DefaultDiagErc, sizeof (DefaultDiagErc));
DiagErcTableInit = TRUE;
}
WriteFichierERC = m_WriteResultOpt->GetValue();
if( CheckAnnotate(m_Parent, 0) )
{
DisplayError(this, _("Annotation Required!") );
return;
}
/* Effacement des anciens marqueurs DRC */
DelERCMarkers(event);
wxClientDC dc(m_Parent->DrawPanel);
m_Parent->DrawPanel->PrepareGraphicContext(&dc);
g_EESchemaVar.NbErrorErc = 0;
g_EESchemaVar.NbWarningErc = 0;
SchematicCleanUp(&dc);
BuildNetList(m_Parent, ScreenSch);
/* Analyse de la table des connexions : */
Lim = g_TabObjNet + g_NbrObjNet;
/* Reset du flag m_FlagOfConnection, utilise par la suite */
for (NetItemRef = g_TabObjNet; NetItemRef < Lim; NetItemRef ++ )
NetItemRef->m_FlagOfConnection = (IsConnectType) 0;
NetNbItems = 0;
MinConn = NOC;
StartNet = OldItem = NetItemRef = g_TabObjNet;
for ( ; NetItemRef < Lim; NetItemRef ++ )
{
/* Tst changement de net */
if( OldItem->m_NetCode != NetItemRef->m_NetCode)
{
MinConn = NOC;
NetNbItems = 0;
StartNet = NetItemRef;
}
switch ( NetItemRef->m_Type )
{
case NET_SEGMENT:
case NET_BUS:
case NET_JONCTION:
case NET_LABEL:
case NET_BUSLABELMEMBER:
case NET_PINLABEL:
break;
case NET_GLOBLABEL:
case NET_GLOBBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_SHEETBUSLABELMEMBER:
TestLabel(m_Parent->DrawPanel, &dc, NetItemRef, StartNet);
break;
case NET_NOCONNECT:
MinConn = NET_NC;
if( NetNbItems != 0 )
Diagnose(m_Parent->DrawPanel, &dc, NetItemRef, NULL, MinConn, UNC);
break;
case NET_PIN:
TestOthersItems(m_Parent->DrawPanel, &dc,
NetItemRef, StartNet, &NetNbItems , &MinConn);
break;
}
OldItem = NetItemRef;
}
FreeTabNetList(g_TabObjNet, g_NbrObjNet );
wxString num;
num.Printf(wxT("%d"), g_EESchemaVar.NbErrorErc);
m_TotalErrCount->SetLabel(num);
num.Printf(wxT("%d"), g_EESchemaVar.NbErrorErc-g_EESchemaVar.NbWarningErc);
m_LastErrCount->SetLabel(num);
num.Printf(wxT("%d"), g_EESchemaVar.NbWarningErc);
m_LastWarningCount->SetLabel(num);
/* Generation ouverture fichier diag */
if( WriteFichierERC == TRUE )
{
wxString ErcFullFileName;
ErcFullFileName = ScreenSch->m_FileName;
ChangeFileNameExt(ErcFullFileName, wxT(".erc"));
ErcFullFileName = EDA_FileSelector(_("ERC file:"),
wxEmptyString, /* Chemin par defaut */
ErcFullFileName, /* nom fichier par defaut */
wxT(".erc"), /* extension par defaut */
wxT("*.erc"), /* Masque d'affichage */
this,
wxSAVE,
TRUE
);
if ( ErcFullFileName.IsEmpty()) return;
if ( WriteDiagnosticERC(ErcFullFileName) )
{
Close(TRUE);
wxString editorname = GetEditorName();
AddDelimiterString(ErcFullFileName);
ExecuteFile(this, editorname, ErcFullFileName);
}
}
}
void DIALOG_ERC::TestErc( wxArrayString* aMessagesList )
{
wxFileName fn;
if( !DiagErcTableInit )
{
memcpy( DiagErc, DefaultDiagErc, sizeof(DefaultDiagErc) );
DiagErcTableInit = true;
}
m_writeErcFile = m_WriteResultOpt->GetValue();
/* Build the whole sheet list in hierarchy (sheet, not screen) */
SCH_SHEET_LIST sheets;
sheets.AnnotatePowerSymbols();
if( m_parent->CheckAnnotate( aMessagesList, false ) )
{
if( aMessagesList )
{
wxString msg = _( "Annotation required!" );
msg += wxT( "\n" );
aMessagesList->Add( msg );
}
return;
}
SCH_SCREENS screens;
// Erase all previous DRC markers.
screens.DeleteAllMarkers( MARK_ERC );
for( SCH_SCREEN* screen = screens.GetFirst(); screen != NULL; screen = screens.GetNext() )
{
/* Ff wire list has changed, delete Undo Redo list to avoid pointers on deleted
* data problems.
*/
if( screen->SchematicCleanUp( NULL ) )
screen->ClearUndoRedoList();
}
/* Test duplicate sheet names inside a given sheet, one cannot have sheets with
* duplicate names (file names can be duplicated).
*/
TestDuplicateSheetNames( true );
NETLIST_OBJECT_LIST* objectsConnectedList = m_parent->BuildNetListBase();
// Reset the connection type indicator
objectsConnectedList->ResetConnectionsType();
unsigned lastNet;
unsigned nextNet = lastNet = 0;
int NetNbItems = 0;
int MinConn = NOC;
for( unsigned net = 0; net < objectsConnectedList->size(); net++ )
{
if( objectsConnectedList->GetItemNet( lastNet ) !=
objectsConnectedList->GetItemNet( net ) )
{
// New net found:
MinConn = NOC;
NetNbItems = 0;
nextNet = net;
}
switch( objectsConnectedList->GetItemType( net ) )
{
// These items do not create erc problems
case NET_ITEM_UNSPECIFIED:
case NET_SEGMENT:
case NET_BUS:
case NET_JUNCTION:
case NET_LABEL:
case NET_BUSLABELMEMBER:
case NET_PINLABEL:
case NET_GLOBLABEL:
case NET_GLOBBUSLABELMEMBER:
break;
case NET_HIERLABEL:
case NET_HIERBUSLABELMEMBER:
case NET_SHEETLABEL:
case NET_SHEETBUSLABELMEMBER:
// ERC problems when pin sheets do not match hierarchical labels.
// Each pin sheet must match a hierarchical label
// Each hierarchical label must match a pin sheet
TestLabel( objectsConnectedList, net, nextNet );
break;
case NET_NOCONNECT:
// ERC problems when a noconnect symbol is connected to more than one pin.
MinConn = NET_NC;
if( NetNbItems != 0 )
Diagnose( objectsConnectedList->GetItem( net ), NULL, MinConn, UNC );
break;
case NET_PIN:
// Look for ERC problems between pins:
TestOthersItems( objectsConnectedList, net, nextNet, &NetNbItems, &MinConn );
break;
}
lastNet = net;
}
// Displays global results:
wxString num;
int markers = screens.GetMarkerCount();
int warnings = screens.GetMarkerCount( WAR );
num.Printf( wxT( "%d" ), markers );
m_TotalErrCount->SetLabel( num );
num.Printf( wxT( "%d" ), markers - warnings );
m_LastErrCount->SetLabel( num );
num.Printf( wxT( "%d" ), warnings );
m_LastWarningCount->SetLabel( num );
// Display diags:
DisplayERC_MarkersList();
// Display new markers:
m_parent->GetCanvas()->Refresh();
if( m_writeErcFile )
{
fn = g_RootSheet->GetScreen()->GetFileName();
fn.SetExt( wxT( "erc" ) );
wxFileDialog dlg( this, _( "ERC File" ), fn.GetPath(), fn.GetFullName(),
_( "Electronic rule check file (.erc)|*.erc" ),
wxFD_SAVE | wxFD_OVERWRITE_PROMPT );
if( dlg.ShowModal() == wxID_CANCEL )
return;
if( WriteDiagnosticERC( dlg.GetPath() ) )
{
Close( true );
ExecuteFile( this, wxGetApp().GetEditorName(), QuoteFullPath( fn ) );
}
}
}
