/***********************************************************************/ /* component_class.cpp : handle the class SCH_COMPONENT */ /***********************************************************************/ #include "fctsys.h" #include "gr_basic.h" #include "common.h" #include "confirm.h" #include "program.h" #include "libcmp.h" #include "general.h" #include "macros.h" #include "protos.h" #include #include WX_DEFINE_OBJARRAY( ArrayOfSheetLists ); /*******************************************************************/ SCH_COMPONENT::SCH_COMPONENT( const wxPoint& aPos, SCH_ITEM* aParent ) : SCH_ITEM( aParent, TYPE_SCH_COMPONENT ) /*******************************************************************/ { m_Multi = 0; /* In multi unit chip - which unit to draw. */ m_Pos = aPos; m_Convert = 0; /* De Morgan Handling */ /* The rotation/mirror transformation matrix. pos normal */ m_Transform[0][0] = 1; m_Transform[0][1] = 0; m_Transform[1][0] = 0; m_Transform[1][1] = -1; m_Fields.reserve( NUMBER_OF_FIELDS ); for( int i = 0; iSetParent( this ); } } /** * Function AddHierarchicalReference * adds a full hierachical reference (path + local reference) * @param aPath = hierarchical path (//component timestamp> like /05678E50/A23EF560) * @param aRef = local reference like C45, R56 * @param aMulti = part selection, used in multi part per package (0 or 1 for non multi) */ void SCH_COMPONENT::AddHierarchicalReference( const wxString& aPath, const wxString& aRef, int aMulti ) { wxString h_path, h_ref; wxStringTokenizer tokenizer; wxString separators( wxT( " " ) ); // Search for an existing path and remove it if found (should not occur) for( unsigned ii = 0; iim_Name.IsEmpty() ) return field->m_Name; else return ReturnDefaultFieldName( aFieldNdx ); } return wxEmptyString; } /****************************************************************/ wxString SCH_COMPONENT::GetPath( DrawSheetPath* sheet ) /****************************************************************/ { wxString str; str.Printf( wxT( "%8.8lX" ), m_TimeStamp ); return sheet->Path() + str; } /********************************************************************/ const wxString SCH_COMPONENT::GetRef( DrawSheetPath* sheet ) /********************************************************************/ { wxString path = GetPath( sheet ); wxString h_path, h_ref; wxStringTokenizer tokenizer; wxString separators( wxT( " " ) ); for( unsigned ii = 0; iim_Text.IsEmpty() ) { SetRef( sheet, GetField( REFERENCE )->m_Text ); return GetField( REFERENCE )->m_Text; } return m_PrefixString; } /***********************************************************************/ void SCH_COMPONENT::SetRef( DrawSheetPath* sheet, const wxString& ref ) /***********************************************************************/ { wxString path = GetPath( sheet ); bool notInArray = true; wxString h_path, h_ref; wxStringTokenizer tokenizer; wxString separators( wxT( " " ) ); //check to see if it is already there before inserting it for( unsigned ii = 0; iim_Text.IsEmpty() || ( abs( rf->m_Pos.x - m_Pos.x ) + abs( rf->m_Pos.y - m_Pos.y ) > 10000) ) { // move it to a reasonable position rf->m_Pos = m_Pos; rf->m_Pos.x += 50; // a slight offset rf->m_Pos.y += 50; } rf->m_Text = ref; // for drawing. } /***********************************************************/ int SCH_COMPONENT::GetUnitSelection( DrawSheetPath* aSheet ) /***********************************************************/ //returns the unit selection, for the given sheet path. { wxString path = GetPath( aSheet ); wxString h_path, h_multi; wxStringTokenizer tokenizer; wxString separators( wxT( " " ) ); for( unsigned ii = 0; iiGetBoundaryBox( m_Multi, m_Convert ); x0 = BoundaryBox.GetX(); xm = BoundaryBox.GetRight(); // We must reverse Y values, because matrix orientation // suppose Y axis normal for the library items coordinates, // m_Transform reverse Y values, but BoundaryBox is already reversed! y0 = -BoundaryBox.GetY(); ym = -BoundaryBox.GetBottom(); } else /* if lib Entry not found, give a reasonable size */ { x0 = y0 = -50; xm = ym = 50; } /* Compute the real Boundary box (rotated, mirrored ...)*/ int x1 = m_Transform[0][0] * x0 + m_Transform[0][1] * y0; int y1 = m_Transform[1][0] * x0 + m_Transform[1][1] * y0; int x2 = m_Transform[0][0] * xm + m_Transform[0][1] * ym; int y2 = m_Transform[1][0] * xm + m_Transform[1][1] * ym; // H and W must be > 0: if( x2 < x1 ) EXCHG( x2, x1 ); if( y2 < y1 ) EXCHG( y2, y1 ); BoundaryBox.SetX( x1 ); BoundaryBox.SetY( y1 ); BoundaryBox.SetWidth( x2 - x1 ); BoundaryBox.SetHeight( y2 - y1 ); BoundaryBox.Offset( m_Pos ); return BoundaryBox; } /**************************************************************************/ void SCH_COMPONENT::SwapData( SCH_COMPONENT* copyitem ) /**************************************************************************/ /* Used if undo / redo command: * swap data between this and copyitem */ { EXCHG( m_ChipName, copyitem->m_ChipName ); EXCHG( m_Pos, copyitem->m_Pos ); EXCHG( m_Multi, copyitem->m_Multi ); EXCHG( m_Convert, copyitem->m_Convert ); EXCHG( m_Transform[0][0], copyitem->m_Transform[0][0] ); EXCHG( m_Transform[0][1], copyitem->m_Transform[0][1] ); EXCHG( m_Transform[1][0], copyitem->m_Transform[1][0] ); EXCHG( m_Transform[1][1], copyitem->m_Transform[1][1] ); m_Fields.swap( copyitem->m_Fields ); // std::vector's swap() // Reparent items after copying data // (after swap(), m_Parent member does not point to the right parent): for( int ii = 0; ii < copyitem->GetFieldCount(); ++ii ) { copyitem->GetField(ii)->SetParent( copyitem ); } for( int ii = 0; ii < GetFieldCount(); ++ii ) { GetField(ii)->SetParent( this ); } } /***********************************************************************/ void SCH_COMPONENT::Place( WinEDA_SchematicFrame* frame, wxDC* DC ) /***********************************************************************/ { /* save old text in undo list */ if( g_ItemToUndoCopy && ( g_ItemToUndoCopy->Type() == Type() ) && ( (m_Flags & IS_NEW) == 0 ) ) { /* restore old values and save new ones */ SwapData( (SCH_COMPONENT*) g_ItemToUndoCopy ); /* save in undo list */ frame->SaveCopyInUndoList( this, IS_CHANGED ); /* restore new values */ SwapData( (SCH_COMPONENT*) g_ItemToUndoCopy ); SAFE_DELETE( g_ItemToUndoCopy ); } SCH_ITEM::Place( frame, DC ); } /**********************************************************/ void SCH_COMPONENT::ClearAnnotation( DrawSheetPath* aSheet ) /**********************************************************/ /** * Suppress annotation ( i.i IC23 changed to IC? and part reset to 1) * @param aSheet: DrawSheetPath value: if NULL remove all annotations, * else remove annotation relative to this sheetpath */ { wxString defRef = m_PrefixString; bool KeepMulti = false; EDA_LibComponentStruct* Entry; wxString separators( wxT( " " ) ); wxArrayString reference_fields; Entry = FindLibPart( m_ChipName.GetData(), wxEmptyString, FIND_ROOT ); if( Entry && Entry->m_UnitSelectionLocked ) KeepMulti = true; while( defRef.Last() == '?' ) defRef.RemoveLast(); defRef.Append( wxT( "?" ) ); wxString multi = wxT( "1" ); if( KeepMulti ) // We cannot remove all annotations: part selection must be kept { wxString NewHref; wxString path; if( aSheet ) path = GetPath( aSheet );; for( unsigned int ii = 0; ii< m_PathsAndReferences.GetCount(); ii++ ) { // Break hierachical reference in path, ref and multi selection: reference_fields = wxStringTokenize( m_PathsAndReferences[ii], separators ); if( aSheet == NULL || reference_fields[0].Cmp( path ) == 0 ) { if( KeepMulti ) // Get and keep part selection multi = reference_fields[2]; NewHref = reference_fields[0]; NewHref << wxT( " " ) << defRef << wxT( " " ) << multi; m_PathsAndReferences[ii] = NewHref; } } } else { m_PathsAndReferences.Empty(); // Empty strings, but does not free memory because a new annotation will reuse it m_Multi = 1; } // These 2 changes do not work in complex hierarchy. // When a clear annotation is made, the calling function must call a // UpdateAllScreenReferences for the active sheet. // But this call cannot made here. m_Fields[REFERENCE].m_Text = defRef; //for drawing. } /*****************************************************************/ void SCH_COMPONENT::SetRotationMiroir( int type_rotate ) /******************************************************************/ /* Compute the new matrix transform for a schematic component * in order to have the requested transform (type_rotate = rot, mirror..) * which is applied to the initial transform. */ { int TempMat[2][2]; bool Transform = FALSE; switch( type_rotate ) { case CMP_ORIENT_0: case CMP_NORMAL: /* Position Initiale */ m_Transform[0][0] = 1; m_Transform[1][1] = -1; m_Transform[1][0] = m_Transform[0][1] = 0; break; case CMP_ROTATE_CLOCKWISE: /* Rotate + */ TempMat[0][0] = TempMat[1][1] = 0; TempMat[0][1] = 1; TempMat[1][0] = -1; Transform = TRUE; break; case CMP_ROTATE_COUNTERCLOCKWISE: /* Rotate - */ TempMat[0][0] = TempMat[1][1] = 0; TempMat[0][1] = -1; TempMat[1][0] = 1; Transform = TRUE; break; case CMP_MIROIR_Y: /* MirrorY */ TempMat[0][0] = -1; TempMat[1][1] = 1; TempMat[0][1] = TempMat[1][0] = 0; Transform = TRUE; break; case CMP_MIROIR_X: /* MirrorX */ TempMat[0][0] = 1; TempMat[1][1] = -1; TempMat[0][1] = TempMat[1][0] = 0; Transform = TRUE; break; case CMP_ORIENT_90: SetRotationMiroir( CMP_ORIENT_0 ); SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); break; case CMP_ORIENT_180: SetRotationMiroir( CMP_ORIENT_0 ); SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); break; case CMP_ORIENT_270: SetRotationMiroir( CMP_ORIENT_0 ); SetRotationMiroir( CMP_ROTATE_CLOCKWISE ); break; case (CMP_ORIENT_0 + CMP_MIROIR_X): SetRotationMiroir( CMP_ORIENT_0 ); SetRotationMiroir( CMP_MIROIR_X ); break; case (CMP_ORIENT_0 + CMP_MIROIR_Y): SetRotationMiroir( CMP_ORIENT_0 ); SetRotationMiroir( CMP_MIROIR_Y ); break; case (CMP_ORIENT_90 + CMP_MIROIR_X): SetRotationMiroir( CMP_ORIENT_90 ); SetRotationMiroir( CMP_MIROIR_X ); break; case (CMP_ORIENT_90 + CMP_MIROIR_Y): SetRotationMiroir( CMP_ORIENT_90 ); SetRotationMiroir( CMP_MIROIR_Y ); break; case (CMP_ORIENT_180 + CMP_MIROIR_X): SetRotationMiroir( CMP_ORIENT_180 ); SetRotationMiroir( CMP_MIROIR_X ); break; case (CMP_ORIENT_180 + CMP_MIROIR_Y): SetRotationMiroir( CMP_ORIENT_180 ); SetRotationMiroir( CMP_MIROIR_Y ); break; case (CMP_ORIENT_270 + CMP_MIROIR_X): SetRotationMiroir( CMP_ORIENT_270 ); SetRotationMiroir( CMP_MIROIR_X ); break; case (CMP_ORIENT_270 + CMP_MIROIR_Y): SetRotationMiroir( CMP_ORIENT_270 ); SetRotationMiroir( CMP_MIROIR_Y ); break; default: Transform = FALSE; DisplayError( NULL, wxT( "SetRotateMiroir() error: ill value" ) ); break; } if( Transform ) { /* The new matrix transform is the old matrix transform modified by the * requested transformation, which is the TempMat transform (rot, mirror ..) * in order to have (in term of matrix transform): * transform coord = new_m_Transform * coord * where transform coord is the coord modified by new_m_Transform from the initial * value coord. * new_m_Transform is computed (from old_m_Transform and TempMat) to have: * transform coord = old_m_Transform * coord * TempMat */ int NewMatrix[2][2]; NewMatrix[0][0] = m_Transform[0][0] * TempMat[0][0] + m_Transform[1][0] * TempMat[0][1]; NewMatrix[0][1] = m_Transform[0][1] * TempMat[0][0] + m_Transform[1][1] * TempMat[0][1]; NewMatrix[1][0] = m_Transform[0][0] * TempMat[1][0] + m_Transform[1][0] * TempMat[1][1]; NewMatrix[1][1] = m_Transform[0][1] * TempMat[1][0] + m_Transform[1][1] * TempMat[1][1]; m_Transform[0][0] = NewMatrix[0][0]; m_Transform[0][1] = NewMatrix[0][1]; m_Transform[1][0] = NewMatrix[1][0]; m_Transform[1][1] = NewMatrix[1][1]; } } /****************************************************/ int SCH_COMPONENT::GetRotationMiroir() /****************************************************/ { int type_rotate = CMP_ORIENT_0; int TempMat[2][2], MatNormal[2][2]; int ii; bool found = FALSE; memcpy( TempMat, m_Transform, sizeof(TempMat) ); SetRotationMiroir( CMP_ORIENT_0 ); memcpy( MatNormal, m_Transform, sizeof(MatNormal) ); for( ii = 0; ii < 4; ii++ ) { if( memcmp( TempMat, m_Transform, sizeof(MatNormal) ) == 0 ) { found = TRUE; break; } SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); } if( !found ) { type_rotate = CMP_MIROIR_X + CMP_ORIENT_0; SetRotationMiroir( CMP_NORMAL ); SetRotationMiroir( CMP_MIROIR_X ); for( ii = 0; ii < 4; ii++ ) { if( memcmp( TempMat, m_Transform, sizeof(MatNormal) ) == 0 ) { found = TRUE; break; } SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); } } if( !found ) { type_rotate = CMP_MIROIR_Y + CMP_ORIENT_0; SetRotationMiroir( CMP_NORMAL ); SetRotationMiroir( CMP_MIROIR_Y ); for( ii = 0; ii < 4; ii++ ) { if( memcmp( TempMat, m_Transform, sizeof(MatNormal) ) == 0 ) { found = TRUE; break; } SetRotationMiroir( CMP_ROTATE_COUNTERCLOCKWISE ); } } memcpy( m_Transform, TempMat, sizeof(m_Transform) ); if( found ) { return type_rotate + ii; } else { wxBell(); return CMP_NORMAL; } } /***********************************************************************/ wxPoint SCH_COMPONENT::GetScreenCoord( const wxPoint& coord ) /***********************************************************************/ /* Renvoie la coordonn�e du point coord, en fonction de l'orientation * du composant (rotation, miroir). * Les coord sont toujours relatives a l'ancre (coord 0,0) du composant */ { wxPoint screenpos; screenpos.x = m_Transform[0][0] * coord.x + m_Transform[0][1] * coord.y; screenpos.y = m_Transform[1][0] * coord.x + m_Transform[1][1] * coord.y; return screenpos; } #if defined (DEBUG) /** * Function Show * is used to output the object tree, currently for debugging only. * @param nestLevel An aid to prettier tree indenting, and is the level * of nesting of this object within the overall tree. * @param os The ostream& to output to. */ void SCH_COMPONENT::Show( int nestLevel, std::ostream& os ) { // for now, make it look like XML: NestedSpace( nestLevel, os ) << '<' << GetClass().Lower().mb_str() << " ref=\"" << ReturnFieldName( 0 ) << '"' << " chipName=\"" << m_ChipName.mb_str() << '"' << m_Pos << " layer=\"" << m_Layer << '"' << "/>\n"; // skip the reference, it's been output already. for( int i = 1; im_Text; if( !value.IsEmpty() ) { NestedSpace( nestLevel + 1, os ) << "\n"; } } NestedSpace( nestLevel, os ) << "\n"; } #endif /****************************************/ bool SCH_COMPONENT::Save( FILE* f ) const /****************************************/ { int ii, Success = true; char Name1[256], Name2[256]; wxArrayString reference_fields; static wxString delimiters( wxT( " " ) ); //this is redundant with the AR entries below, but it makes the //files backwards-compatible. if( m_PathsAndReferences.GetCount() > 0 ) { reference_fields = wxStringTokenize( m_PathsAndReferences[0], delimiters ); strncpy( Name1, CONV_TO_UTF8( reference_fields[1] ), sizeof(Name1) ); } else { if( GetField( REFERENCE )->m_Text.IsEmpty() ) strncpy( Name1, CONV_TO_UTF8( m_PrefixString ), sizeof(Name1) ); else strncpy( Name1, CONV_TO_UTF8( GetField( REFERENCE )->m_Text ), sizeof(Name1) ); } for( ii = 0; ii < (int) strlen( Name1 ); ii++ ) { if( Name1[ii] <= ' ' ) Name1[ii] = '~'; } if( !m_ChipName.IsEmpty() ) { strncpy( Name2, CONV_TO_UTF8( m_ChipName ), sizeof(Name2) ); for( ii = 0; ii < (int) strlen( Name2 ); ii++ ) if( Name2[ii] <= ' ' ) Name2[ii] = '~'; } else strncpy( Name2, NULL_STRING, sizeof(Name2) ); fprintf( f, "$Comp\n" ); if( fprintf( f, "L %s %s\n", Name2, Name1 ) == EOF ) { Success = false; return Success; } /* Generation de numero d'unit, convert et Time Stamp*/ if( fprintf( f, "U %d %d %8.8lX\n", m_Multi, m_Convert, m_TimeStamp ) == EOF ) { Success = false; return Success; } /* Save the position */ if( fprintf( f, "P %d %d\n", m_Pos.x, m_Pos.y ) == EOF ) { Success = false; return Success; } /* If this is a complex hierarchy; save hierarchical references. * but for simple hierarchies it is not necessary. * the reference inf is already saved * this is usefull for old eeschema version compatibility */ if( m_PathsAndReferences.GetCount() > 1 ) { for( unsigned int ii = 0; ii< m_PathsAndReferences.GetCount(); ii++ ) { /*format: * AR Path="/140/2" Ref="C99" Part="1" * where 140 is the uid of the containing sheet * and 2 is the timestamp of this component. * (timestamps are actually 8 hex chars) * Ref is the conventional component reference for this 'path' * Part is the conventional component part selection for this 'path' */ reference_fields = wxStringTokenize( m_PathsAndReferences[ii], delimiters ); if( fprintf( f, "AR Path=\"%s\" Ref=\"%s\" Part=\"%s\" \n", CONV_TO_UTF8( reference_fields[0] ), CONV_TO_UTF8( reference_fields[1] ), CONV_TO_UTF8( reference_fields[2] ) ) == EOF ) { Success = false; return Success; } } } for( int fieldNdx = 0; fieldNdxm_Text.IsEmpty() && defaultName == field->m_Name ) continue; if( !field->Save( f ) ) { Success = false; break; } } if( !Success ) return Success; /* Generation du num unit, position, box ( ancienne norme )*/ if( fprintf( f, "\t%-4d %-4d %-4d\n", m_Multi, m_Pos.x, m_Pos.y ) == EOF ) { Success = false; return Success; } if( fprintf( f, "\t%-4d %-4d %-4d %-4d\n", m_Transform[0][0], m_Transform[0][1], m_Transform[1][0], m_Transform[1][1] ) == EOF ) { Success = false; return Success; } fprintf( f, "$EndComp\n" ); return Success; } EDA_Rect SCH_COMPONENT::GetBoundingBox() { const int PADDING = 40; // This gives a reasonable approximation (but some things are missing so...) EDA_Rect bbox = GetBoundaryBox(); // Include BoundingBoxes of fields for( int ii = 0; ii < GetFieldCount(); ii++ ) { bbox.Merge( GetField( ii )->GetBoundaryBox() ); } // ... add padding bbox.Inflate( PADDING, PADDING ); return bbox; }