/* * This program source code file is part of KICAD, a free EDA CAD application. * * Copyright (C) 2011 jean-pierre.charras * Copyright (C) 1992-2021 Kicad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 3 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . */ #include #include #include #include #include "common_data.h" #include "pcb_calculator_frame.h" extern double DoubleFromString( const wxString& TextValue ); // Display a selection of usual Er, TanD, Rho values // List format is // A helper function to find the choice in a list of values // return true if a index in aList that matches aValue is found. static bool findMatch( wxArrayString& aList, const wxString& aValue, int& aIdx ) { bool success = false; // Find the previous choice index: aIdx = 0; // Some countries use comma instead of point as separator. // The value can be enter with pint or comma // use point for string comparisons: wxString cvalue = aValue; cvalue.Replace( ',', '.' ); // First compare strings: for( wxString& text: aList ) { if( text.IsEmpty() ) // No match found: select the empty line choice break; wxString val_str = text.BeforeFirst( ' ' ); val_str.Replace( ',', '.' ); // compare string values if( val_str == cvalue ) { success = true; break; } aIdx++; } // Due to multiple ways to write a double, if string values // do not match, compare double values if( !success ) { struct lconv* lc = localeconv(); char localeDecimalSeparator = *lc->decimal_point; if( localeDecimalSeparator == ',' ) cvalue.Replace( '.', ',' ); double curr_value; cvalue.ToDouble( &curr_value ); aIdx = 0; for( wxString& text: aList ) { if( text.IsEmpty() ) // No match found: select the empty line choice break; double val; wxString val_str = text.BeforeFirst( ' ' ); if( localeDecimalSeparator == ',' ) val_str.Replace( '.', ',' ); val_str.ToDouble( &val );; if( curr_value == val ) { success = true; break; } aIdx++; } } return success; } void PCB_CALCULATOR_FRAME::OnTranslineEpsilonR_Button( wxCommandEvent& event ) { wxArrayString list = StandardRelativeDielectricConstantList(); list.Add( "" ); // Add an empty line for no selection // Find the previous choice index: wxString prevChoiceStr = m_Value_EpsilonR->GetValue(); int prevChoice = 0; findMatch( list, prevChoiceStr, prevChoice ); int index = wxGetSingleChoiceIndex( wxEmptyString, _( "Relative Dielectric Constants" ), list, prevChoice ); if( index >= 0 && !list.Item( index ).IsEmpty() ) // i.e. non canceled. m_Value_EpsilonR->SetValue( list.Item( index ).BeforeFirst( ' ' ) ); } void PCB_CALCULATOR_FRAME::OnTranslineTanD_Button( wxCommandEvent& event ) { wxArrayString list = StandardLossTangentList(); list.Add( "" ); // Add an empty line for no selection // Find the previous choice index: wxString prevChoiceStr = m_Value_TanD->GetValue(); int prevChoice = 0; findMatch( list, prevChoiceStr, prevChoice ); int index = wxGetSingleChoiceIndex( wxEmptyString, _( "Dielectric Loss Factor" ), list, prevChoice, nullptr ); if( index >= 0 && !list.Item( index ).IsEmpty() ) // i.e. non canceled. m_Value_TanD->SetValue( list.Item( index ).BeforeFirst( ' ' ) ); } void PCB_CALCULATOR_FRAME::OnTranslineRho_Button( wxCommandEvent& event ) { wxArrayString list = StandardResistivityList(); list.Add( "" ); // Add an empty line for no selection // Find the previous choice index: wxString prevChoiceStr = m_Value_Rho->GetValue(); int prevChoice = 0; findMatch( list, prevChoiceStr, prevChoice ); int index = wxGetSingleChoiceIndex( wxEmptyString, _( "Specific Resistance" ), list, prevChoice, nullptr ); if( index >= 0 && !list.Item( index ).IsEmpty() ) // i.e. non canceled. m_Value_Rho->SetValue( list.Item( index ).BeforeFirst( ' ' ) ); } // Minor helper struct to handle dialog items for a given parameter struct DLG_PRM_DATA { wxStaticText* name; wxTextCtrl* value; UNIT_SELECTOR* unit; }; void PCB_CALCULATOR_FRAME::TranslineTypeSelection( enum TRANSLINE_TYPE_ID aType ) { m_currTransLineType = aType; if( (m_currTransLineType < START_OF_LIST_TYPE ) || ( m_currTransLineType >= END_OF_LIST_TYPE ) ) { m_currTransLineType = DEFAULT_TYPE; } m_translineBitmap->SetBitmap( *m_transline_list[m_currTransLineType]->m_Icon ); // This helper bitmap is shown for coupled microstrip only: m_bmCMicrostripZoddZeven->Show( aType == C_MICROSTRIP_TYPE ); m_bmCMicrostripZoddZeven->SetBitmap( KiBitmap( BITMAPS::microstrip_zodd_zeven ) ); m_fgSizerZcomment->Show( aType == C_MICROSTRIP_TYPE ); TRANSLINE_IDENT* tr_ident = m_transline_list[m_currTransLineType]; m_currTransLine = tr_ident->m_TLine; m_radioBtnPrm1->Show( tr_ident->m_HasPrmSelection ); m_radioBtnPrm2->Show( tr_ident->m_HasPrmSelection ); // Setup messages wxStaticText* left_msg_list[] = { m_left_message1, m_left_message2, m_left_message3, m_left_message4, m_left_message5, m_left_message6, m_left_message7, m_left_message8, nullptr }; wxStaticText* msg_list[] = { m_Message1, m_Message2, m_Message3, m_Message4, m_Message5, m_Message6, m_Message7, m_Message8, nullptr }; unsigned jj = 0; for( ; jj < tr_ident->m_Messages.GetCount(); jj++ ) { if( left_msg_list[jj] == nullptr ) break; left_msg_list[jj]->SetLabel( tr_ident->m_Messages[jj] ); msg_list[jj]->SetLabel( wxEmptyString ); } while( left_msg_list[jj] ) { left_msg_list[jj]->SetLabel( wxEmptyString ); msg_list[jj]->SetLabel( wxEmptyString ); jj++; } // Init parameters dialog items struct DLG_PRM_DATA substrateprms[] = { { m_EpsilonR_label, m_Value_EpsilonR, nullptr }, { m_TanD_label, m_Value_TanD, nullptr }, { m_Rho_label, m_Value_Rho, nullptr }, { m_substrate_prm4_label, m_Substrate_prm4_Value, m_SubsPrm4_choiceUnit }, { m_substrate_prm5_label, m_Substrate_prm5_Value, m_SubsPrm5_choiceUnit }, { m_substrate_prm6_label, m_Substrate_prm6_Value, m_SubsPrm6_choiceUnit }, { m_substrate_prm7_label, m_Substrate_prm7_Value, m_SubsPrm7_choiceUnit }, { m_substrate_prm8_label, m_Substrate_prm8_Value, m_SubsPrm8_choiceUnit }, { m_substrate_prm9_label, m_Substrate_prm9_Value, m_SubsPrm9_choiceUnit } }; #define substrateprms_cnt (sizeof(substrateprms)/sizeof(substrateprms[0])) struct DLG_PRM_DATA physprms[] = { { m_phys_prm1_label, m_Phys_prm1_Value, m_choiceUnit_Param1 }, { m_phys_prm2_label, m_Phys_prm2_Value, m_choiceUnit_Param2 }, { m_phys_prm3_label, m_Phys_prm3_Value, m_choiceUnit_Param3 } }; #define physprms_cnt (sizeof(physprms)/sizeof(physprms[0])) struct DLG_PRM_DATA elecprms[] = { { m_elec_prm1_label, m_Elec_prm1_Value, m_choiceUnit_ElecPrm1 }, { m_elec_prm2_label, m_Elec_prm2_Value, m_choiceUnit_ElecPrm2 }, { m_elec_prm3_label, m_Elec_prm3_Value, m_choiceUnit_ElecPrm3 } }; #define elecprms_cnt (sizeof(elecprms)/sizeof(elecprms[0])) struct DLG_PRM_DATA frequencyprms[] = { { m_Frequency_label,m_Value_Frequency_Ctrl, m_choiceUnit_Frequency } }; #define frequencyprms_cnt (sizeof(frequencyprms)/sizeof(frequencyprms[0])) unsigned idxsubs = 0; unsigned idxphys = 0; unsigned idxelec = 0; unsigned idxfreq = 0; for( unsigned ii = 0; ii < tr_ident->GetPrmsCount(); ii++ ) { TRANSLINE_PRM* prm = tr_ident->GetPrm( ii ); struct DLG_PRM_DATA * data = nullptr; switch( prm->m_Type ) { case PRM_TYPE_SUBS: wxASSERT( idxsubs < substrateprms_cnt ); data = &substrateprms[idxsubs]; idxsubs++; break; case PRM_TYPE_PHYS: wxASSERT( idxphys < physprms_cnt ); data = &physprms[idxphys]; idxphys++; break; case PRM_TYPE_ELEC: wxASSERT( idxelec < elecprms_cnt ); data = &elecprms[idxelec]; idxelec++; break; case PRM_TYPE_FREQUENCY: wxASSERT( idxfreq < frequencyprms_cnt ); data = &frequencyprms[idxfreq]; idxfreq++; break; } wxASSERT ( data ); data->name->SetToolTip( prm->m_ToolTip ); data->name->SetLabel( prm->m_DlgLabel != "" ? prm->m_DlgLabel + ':' : "" ); prm->m_ValueCtrl = data->value; if( prm->m_Id != DUMMY_PRM ) { data->value->SetValue( wxString::Format( "%g", prm->m_Value ) ); data->value->Enable( true ); } else { data->value->SetValue( wxEmptyString ); data->value->Enable( false ); } if( prm->m_ConvUnit ) prm->m_UnitCtrl = data->unit; if( data->unit ) { data->unit->Show( prm->m_ConvUnit ); data->unit->Enable( prm->m_ConvUnit ); data->unit->SetSelection( prm->m_UnitSelection ); } } // Clear all unused params for( ; idxsubs < substrateprms_cnt; idxsubs++ ) { substrateprms[idxsubs].name->SetLabel(wxEmptyString); substrateprms[idxsubs].name->SetToolTip(wxEmptyString); substrateprms[idxsubs].value->SetValue(wxEmptyString); substrateprms[idxsubs].value->Enable( false ); if( substrateprms[idxsubs].unit) { substrateprms[idxsubs].unit->Show( false ); substrateprms[idxsubs].unit->Enable( false ); substrateprms[idxsubs].unit->SetSelection( 0 ); } } for( ; idxphys < physprms_cnt; idxphys++ ) { physprms[idxphys].name->SetLabel(wxEmptyString); physprms[idxphys].name->SetToolTip(wxEmptyString); physprms[idxphys].value->SetValue(wxEmptyString); physprms[idxphys].value->Enable( false ); if( physprms[idxphys].unit) { physprms[idxphys].unit->Show( false ); physprms[idxphys].unit->Enable( false ); physprms[idxphys].unit->SetSelection( 0 ); } } for( ; idxelec < elecprms_cnt; idxelec++) { elecprms[idxelec].name->SetLabel(wxEmptyString); elecprms[idxelec].name->SetToolTip(wxEmptyString); elecprms[idxelec].value->SetValue(wxEmptyString); elecprms[idxelec].value->Enable( false ); if( elecprms[idxelec].unit) { elecprms[idxelec].unit->Show( false ); elecprms[idxelec].unit->Enable( false ); elecprms[idxelec].unit->SetSelection( 0 ); } } for( ; idxfreq < frequencyprms_cnt; idxfreq++ ) { frequencyprms[idxfreq].name->SetLabel(wxEmptyString); frequencyprms[idxfreq].name->SetToolTip(wxEmptyString); frequencyprms[idxfreq].value->SetValue(wxEmptyString); frequencyprms[idxfreq].value->Enable( false ); if( frequencyprms[idxfreq].unit ) { frequencyprms[idxfreq].unit->Show( false ); frequencyprms[idxfreq].unit->Enable( false ); frequencyprms[idxfreq].unit->SetSelection( 0 ); } } } void PCB_CALCULATOR_FRAME::TransfDlgDataToTranslineParams() { TRANSLINE_IDENT* tr_ident = m_transline_list[m_currTransLineType]; for( unsigned ii = 0; ii < tr_ident->GetPrmsCount(); ii++ ) { TRANSLINE_PRM* prm = tr_ident->GetPrm( ii ); wxTextCtrl * value_ctrl = (wxTextCtrl * ) prm->m_ValueCtrl; wxString value_txt = value_ctrl->GetValue(); double value = DoubleFromString(value_txt); prm->m_Value = value; UNIT_SELECTOR * unit_ctrl = (UNIT_SELECTOR * ) prm->m_UnitCtrl; if( unit_ctrl ) { prm->m_UnitSelection = unit_ctrl->GetSelection(); value *= unit_ctrl->GetUnitScale(); } prm->m_NormalizedValue = value; } } void PCB_CALCULATOR_FRAME::OnTranslineSelection( wxCommandEvent& event ) { enum TRANSLINE_TYPE_ID id = (enum TRANSLINE_TYPE_ID) event.GetSelection(); TranslineTypeSelection( id ); // Texts and units choice widgets can have their size modified: // The new size must be taken in account m_panelTransline->GetSizer()->Layout(); m_panelTransline->Refresh(); } void PCB_CALCULATOR_FRAME::OnTransLineResetButtonClick( wxCommandEvent& event ) { TranslineTypeSelection( DEFAULT_TYPE ); m_TranslineSelection->SetSelection( DEFAULT_TYPE ); m_panelTransline->GetSizer()->Layout(); m_panelTransline->Refresh(); }