kicad/eeschema/sch_screen.cpp

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2013 Jean-Pierre Charras, jp.charras at wanadoo.fr
* Copyright (C) 2012 SoftPLC Corporation, Dick Hollenbeck <dick@softplc.com>
* Copyright (C) 2008 Wayne Stambaugh <stambaughw@gmail.com>
* Copyright (C) 1992-2023 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 2
* 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, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include <stack>
#include <wx/filefn.h>
#include <eda_item.h>
#include <id.h>
#include <string_utils.h>
#include <kiway.h>
#include <plotters/plotter.h>
#include <sch_plotter.h>
#include <project.h>
#include <project_sch.h>
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
#include <reporter.h>
#include <trace_helpers.h>
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#include <sch_edit_frame.h>
#include <sch_item.h>
#include <symbol_library.h>
#include <connection_graph.h>
#include <lib_pin.h>
#include <sch_symbol.h>
#include <sch_junction.h>
#include <sch_line.h>
#include <sch_marker.h>
#include <sch_sheet.h>
#include <sch_sheet_pin.h>
#include <sch_text.h>
#include <schematic.h>
#include <symbol_lib_table.h>
2018-09-03 13:58:47 +00:00
#include <tool/common_tools.h>
#include <sim/sim_model.h> // For V6 to V7 simulation model migration.
#include <locale_io.h>
#include <algorithm>
// TODO(JE) Debugging only
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#include <core/profile.h>
#include "sch_bus_entry.h"
/*
* Flag to enable profiling of the TestDanglingEnds() function.
* @ingroup trace_env_vars
*/
static const wxChar DanglingProfileMask[] = wxT( "DANGLING_PROFILE" );
SCH_SCREEN::SCH_SCREEN( EDA_ITEM* aParent ) :
BASE_SCREEN( aParent, SCH_SCREEN_T ),
m_fileFormatVersionAtLoad( 0 ),
m_paper( wxT( "A4" ) ),
m_isReadOnly( false ),
m_fileExists( false )
{
2015-02-28 20:50:35 +00:00
m_modification_sync = 0;
m_refCount = 0;
Mark null project initial screen as zoom-initialized The variable `m_Initialized` in `BASE_SCREEN` is used by `SCH_EDIT_FRAME` to mark whether a screen had its zoom level initialized by the "zoom to fit screen" action. When this variable is `false`, the function `SCH_EDIT_FRAME::DisplayCurrentSheet()` performs "zoom to fit screen", modifying the zoom level. This function is indirectly called in the undo routines, so if `m_Initialized` is not set to `true`, a zoom change will occur when the user undoes an operation, a behavior that is undesired. `m_Initialized` was not initialized to `true` for the null schematic (the schematic that is loaded if no project is loaded), causing the aforementioned undesired behavior. To prevent this, I've changed the `SCH_EDIT_FRAME` constructor to set `m_Initialized` to `true`, since it zooms to fit screen already. I've moved `m_Initialized` from `BASE_SCREEN` to `SCH_SCREEN`, as it is used only in Eeschema, and renamed it to `m_zoomInitialized`, a name I believe that better describes what this variable does. I've also introduced the function `SCH_EDIT_FRAME::initScreenZoom()` to group the "zoom to fit screen" action with setting `m_Initialized` to `true`, as they often should occur together. I'd also like to say that I'm not confident whether `SCH_EDIT_FRAME::DisplayCurrentSheet()` should perform the zoom level initialization at this point, but I have decided to not change this behavior for now, as the commit history suggests it's several years old. Fixes https://gitlab.com/kicad/code/kicad/issues/7343
2021-01-30 22:47:39 +00:00
m_zoomInitialized = false;
m_LastZoomLevel = 1.0;
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// Suitable for schematic only. For symbol_editor and viewlib, must be set to true
m_Center = false;
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InitDataPoints( m_paper.GetSizeIU( schIUScale.IU_PER_MILS ) );
}
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SCH_SCREEN::~SCH_SCREEN()
{
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
clearLibSymbols();
FreeDrawList();
}
SCHEMATIC* SCH_SCREEN::Schematic() const
{
wxCHECK_MSG( GetParent() && GetParent()->Type() == SCHEMATIC_T, nullptr,
wxT( "SCH_SCREEN must have a SCHEMATIC parent!" ) );
return static_cast<SCHEMATIC*>( GetParent() );
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
void SCH_SCREEN::clearLibSymbols()
{
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for( const std::pair<const wxString, LIB_SYMBOL*>& libSymbol : m_libSymbols )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
delete libSymbol.second;
m_libSymbols.clear();
}
void SCH_SCREEN::SetFileName( const wxString& aFileName )
{
wxASSERT( aFileName.IsEmpty() || wxIsAbsolutePath( aFileName ) );
m_fileName = aFileName;
}
void SCH_SCREEN::IncRefCount()
{
m_refCount++;
}
void SCH_SCREEN::DecRefCount()
{
wxCHECK_RET( m_refCount != 0, wxT( "Screen reference count already zero. Bad programmer!" ) );
m_refCount--;
}
bool SCH_SCREEN::HasItems( KICAD_T aItemType ) const
{
2020-12-20 18:59:07 +00:00
EE_RTREE::EE_TYPE sheets = m_rtree.OfType( aItemType );
return sheets.begin() != sheets.end();
}
bool SCH_SCREEN::ClassOf( const EDA_ITEM* aItem )
{
return aItem && SCH_SCREEN_T == aItem->Type();
}
void SCH_SCREEN::Append( SCH_ITEM* aItem, bool aUpdateLibSymbol )
{
if( aItem->Type() != SCH_SHEET_PIN_T && aItem->Type() != SCH_FIELD_T )
{
// Ensure the item can reach the SCHEMATIC through this screen
aItem->SetParent( this );
if( aItem->Type() == SCH_SYMBOL_T && aUpdateLibSymbol )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( aItem );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
if( symbol->GetLibSymbolRef() )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
symbol->GetLibSymbolRef()->GetDrawItems().sort();
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
auto it = m_libSymbols.find( symbol->GetSchSymbolLibraryName() );
if( it == m_libSymbols.end() || !it->second )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
m_libSymbols[symbol->GetSchSymbolLibraryName()] =
new LIB_SYMBOL( *symbol->GetLibSymbolRef() );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
}
else
{
// The original library symbol may have changed since the last time
// it was added to the schematic. If it has changed, then a new name
// must be created for the library symbol list to prevent all of the
// other schematic symbols referencing that library symbol from changing.
2021-06-10 18:51:46 +00:00
LIB_SYMBOL* foundSymbol = it->second;
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
foundSymbol->GetDrawItems().sort();
if( *foundSymbol != *symbol->GetLibSymbolRef() )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
wxString newName;
std::vector<wxString> matches;
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
getLibSymbolNameMatches( *symbol, matches );
foundSymbol = nullptr;
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
for( const wxString& libSymbolName : matches )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
it = m_libSymbols.find( libSymbolName );
if( it == m_libSymbols.end() )
continue;
foundSymbol = it->second;
wxCHECK2( foundSymbol, continue );
wxString tmp = symbol->GetLibSymbolRef()->GetName();
// Temporarily update the new symbol library symbol name so it
// doesn't fail on the name comparison below.
symbol->GetLibSymbolRef()->SetName( foundSymbol->GetName() );
if( *foundSymbol == *symbol->GetLibSymbolRef() )
{
newName = libSymbolName;
symbol->GetLibSymbolRef()->SetName( tmp );
break;
}
symbol->GetLibSymbolRef()->SetName( tmp );
foundSymbol = nullptr;
}
if( !foundSymbol )
{
int cnt = 1;
newName.Printf( wxT( "%s_%d" ),
symbol->GetLibId().GetUniStringLibItemName(),
cnt );
while( m_libSymbols.find( newName ) != m_libSymbols.end() )
{
cnt += 1;
newName.Printf( wxT( "%s_%d" ),
symbol->GetLibId().GetUniStringLibItemName(),
cnt );
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
}
// Update the schematic symbol library link as this symbol only exists
// in the schematic.
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
symbol->SetSchSymbolLibraryName( newName );
if( !foundSymbol )
{
// Update the schematic symbol library link as this symbol does not
// exist in any symbol library.
LIB_ID newLibId( wxEmptyString, newName );
LIB_SYMBOL* newLibSymbol = new LIB_SYMBOL( *symbol->GetLibSymbolRef() );
newLibSymbol->SetLibId( newLibId );
newLibSymbol->SetName( newName );
symbol->SetLibSymbol( newLibSymbol->Flatten().release() );
m_libSymbols[newName] = newLibSymbol;
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
}
}
}
}
m_rtree.insert( aItem );
--m_modification_sync;
}
}
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
void SCH_SCREEN::Append( SCH_SCREEN* aScreen )
{
wxCHECK_RET( aScreen, "Invalid screen object." );
// No need to descend the hierarchy. Once the top level screen is copied, all of its
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
// children are copied as well.
2021-11-23 21:18:04 +00:00
for( SCH_ITEM* aItem : aScreen->m_rtree )
Append( aItem );
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
aScreen->Clear( false );
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
}
void SCH_SCREEN::Clear( bool aFree )
{
if( aFree )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
FreeDrawList();
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
clearLibSymbols();
}
else
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
m_rtree.clear();
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
}
// Clear the project settings
m_virtualPageNumber = m_pageCount = 1;
m_titles.Clear();
}
void SCH_SCREEN::FreeDrawList()
{
// We don't know which order we will encounter dependent items (e.g. pins or fields), so
// we store the items to be deleted until we've fully cleared the tree before deleting
std::vector<SCH_ITEM*> delete_list;
std::copy_if( m_rtree.begin(), m_rtree.end(), std::back_inserter( delete_list ),
[]( SCH_ITEM* aItem )
{
return ( aItem->Type() != SCH_SHEET_PIN_T && aItem->Type() != SCH_FIELD_T );
} );
m_rtree.clear();
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for( SCH_ITEM* item : delete_list )
delete item;
}
void SCH_SCREEN::Update( SCH_ITEM* aItem, bool aUpdateLibSymbol )
{
if( Remove( aItem, aUpdateLibSymbol ) )
Append( aItem, aUpdateLibSymbol );
}
bool SCH_SCREEN::Remove( SCH_ITEM* aItem, bool aUpdateLibSymbol )
{
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
bool retv = m_rtree.remove( aItem );
// Check if the library symbol for the removed schematic symbol is still required.
if( retv && aItem->Type() == SCH_SYMBOL_T && aUpdateLibSymbol )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
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SCH_SYMBOL* removedSymbol = static_cast<SCH_SYMBOL*>( aItem );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
bool removeUnusedLibSymbol = true;
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for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
if( removedSymbol->GetSchSymbolLibraryName() == symbol->GetSchSymbolLibraryName() )
{
removeUnusedLibSymbol = false;
break;
}
}
if( removeUnusedLibSymbol )
{
auto it = m_libSymbols.find( removedSymbol->GetSchSymbolLibraryName() );
if( it != m_libSymbols.end() )
{
delete it->second;
m_libSymbols.erase( it );
}
}
}
return retv;
}
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void SCH_SCREEN::DeleteItem( SCH_ITEM* aItem )
{
wxCHECK_RET( aItem, wxT( "Cannot delete invalid item from screen." ) );
// Markers are not saved in the file, no need to flag as modified.
// TODO: Maybe we should have a listing somewhere of items that aren't saved?
if( aItem->Type() != SCH_MARKER_T )
SetContentModified();
Remove( aItem );
if( aItem->Type() == SCH_SHEET_PIN_T )
{
// This structure is attached to a sheet, get the parent sheet object.
SCH_SHEET_PIN* sheetPin = (SCH_SHEET_PIN*) aItem;
SCH_SHEET* sheet = sheetPin->GetParent();
wxCHECK_RET( sheet, wxT( "Sheet pin parent not properly set, bad programmer!" ) );
sheet->RemovePin( sheetPin );
return;
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
delete aItem;
}
bool SCH_SCREEN::CheckIfOnDrawList( const SCH_ITEM* aItem ) const
{
return m_rtree.contains( aItem, true );
}
2008-02-26 19:19:54 +00:00
SCH_ITEM* SCH_SCREEN::GetItem( const VECTOR2I& aPosition, int aAccuracy, KICAD_T aType ) const
{
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BOX2I bbox;
bbox.SetOrigin( aPosition );
bbox.Inflate( aAccuracy );
for( SCH_ITEM* item : Items().Overlapping( aType, bbox ) )
{
if( item->HitTest( aPosition, aAccuracy ) )
return item;
}
return nullptr;
}
std::set<SCH_ITEM*> SCH_SCREEN::MarkConnections( SCH_LINE* aSegment, bool aSecondPass )
{
#define PROCESSED CANDIDATE // Don't use SKIP_STRUCT; IsConnected() returns false if it's set.
std::set<SCH_ITEM*> retval;
std::stack<SCH_LINE*> to_search;
wxCHECK_MSG( aSegment && aSegment->Type() == SCH_LINE_T, retval, wxT( "Invalid pointer." ) );
to_search.push( aSegment );
while( !to_search.empty() )
{
SCH_ITEM* item = to_search.top();
to_search.pop();
if( item->HasFlag( PROCESSED ) )
continue;
item->SetFlags( PROCESSED );
for( SCH_ITEM* candidate : Items().Overlapping( SCH_LINE_T, item->GetBoundingBox() ) )
{
SCH_LINE* line = static_cast<SCH_LINE*>( candidate );
if( line->HasFlag( PROCESSED ) )
continue;
// Skip connecting lines on different layers (e.g. buses)
if( item->GetLayer() != line->GetLayer() )
continue;
for( VECTOR2I pt : { line->GetStartPoint(), line->GetEndPoint() } )
{
if( item->IsConnected( pt ) )
{
SCH_ITEM* junction = GetItem( pt, 0, SCH_JUNCTION_T );
SCH_ITEM* pin = GetItem( pt, 0, SCH_PIN_T );
if( item->IsSelected() && aSecondPass )
{
if( junction )
retval.insert( junction );
retval.insert( line );
to_search.push( line );
}
else if( !junction && !pin )
{
retval.insert( line );
to_search.push( line );
}
break;
}
else if( line->GetLayer() == LAYER_NOTES && item->GetLayer() == LAYER_NOTES )
{
retval.insert( line );
to_search.push( line );
}
}
}
}
for( SCH_ITEM* item : Items() )
item->ClearTempFlags();
return retval;
}
bool SCH_SCREEN::IsJunction( const VECTOR2I& aPosition ) const
{
bool hasExplicitJunction;
bool hasBusEntry;
bool isJunction = doIsJunction( aPosition, false, &hasExplicitJunction, &hasBusEntry );
return isJunction;
}
bool SCH_SCREEN::IsExplicitJunction( const VECTOR2I& aPosition ) const
{
bool hasExplicitJunction;
bool hasBusEntry;
bool isJunction = doIsJunction( aPosition, false, &hasExplicitJunction, &hasBusEntry );
return isJunction && !hasBusEntry;
}
bool SCH_SCREEN::IsExplicitJunctionNeeded( const VECTOR2I& aPosition ) const
{
bool hasExplicitJunction;
bool hasBusEntry;
bool isJunction = doIsJunction( aPosition, false, &hasExplicitJunction, &hasBusEntry );
return isJunction && !hasBusEntry && !hasExplicitJunction;
}
SPIN_STYLE SCH_SCREEN::GetLabelOrientationForPoint( const VECTOR2I& aPosition,
SPIN_STYLE aDefaultOrientation,
const SCH_SHEET_PATH* aSheet ) const
{
auto ret = aDefaultOrientation;
for( SCH_ITEM* item : Items().Overlapping( aPosition ) )
{
if( item->GetEditFlags() & STRUCT_DELETED )
continue;
switch( item->Type() )
{
case SCH_BUS_WIRE_ENTRY_T:
{
auto busEntry = static_cast<const SCH_BUS_WIRE_ENTRY*>( item );
if( busEntry->m_connected_bus_item )
{
// bus connected, take the bus direction into consideration ony if it is
// vertical or horizontal
auto bus = static_cast<const SCH_LINE*>( busEntry->m_connected_bus_item );
if( bus->Angle().AsDegrees() == 90.0 )
{
// bus is vertical -> label shall be horizontal and
// shall be placed to the side where the bus entry is
if( aPosition.x < bus->GetPosition().x )
ret = SPIN_STYLE::LEFT;
else if( aPosition.x > bus->GetPosition().x )
ret = SPIN_STYLE::RIGHT;
}
else if( bus->Angle().AsDegrees() == 0.0 )
{
// bus is horizontal -> label shall be vertical and
// shall be placed to the side where the bus entry is
if( aPosition.y < bus->GetPosition().y )
ret = SPIN_STYLE::UP;
else if( aPosition.y > bus->GetPosition().y )
ret = SPIN_STYLE::BOTTOM;
}
}
}
break;
case SCH_LINE_T:
{
auto line = static_cast<const SCH_LINE*>( item );
// line angles goes between -90 and 90 degrees, but normalize
auto angle = line->Angle().Normalize90().AsDegrees();
if( -45 < angle && angle <= 45 )
{
if( line->GetStartPoint().x <= line->GetEndPoint().x )
ret = line->GetEndPoint() == aPosition ? SPIN_STYLE::RIGHT : SPIN_STYLE::LEFT;
else
ret = line->GetEndPoint() == aPosition ? SPIN_STYLE::LEFT : SPIN_STYLE::RIGHT;
}
else
{
if( line->GetStartPoint().y <= line->GetEndPoint().y )
ret = line->GetEndPoint() == aPosition ? SPIN_STYLE::BOTTOM : SPIN_STYLE::UP;
else
ret = line->GetEndPoint() == aPosition ? SPIN_STYLE::UP : SPIN_STYLE::BOTTOM;
}
}
break;
case SCH_SYMBOL_T:
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
for( SCH_PIN* pin : symbol->GetPins( aSheet ) )
{
if( pin->GetPosition() == aPosition )
{
if( pin->GetOrientation() == PIN_ORIENTATION::PIN_RIGHT )
ret = SPIN_STYLE::LEFT;
else if( pin->GetOrientation() == PIN_ORIENTATION::PIN_LEFT )
ret = SPIN_STYLE::RIGHT;
else if( pin->GetOrientation() == PIN_ORIENTATION::PIN_UP )
ret = SPIN_STYLE::BOTTOM;
else if( pin->GetOrientation() == PIN_ORIENTATION::PIN_DOWN )
ret = SPIN_STYLE::UP;
switch( static_cast<SYMBOL_ORIENTATION_T>(
symbol->GetOrientation() & ( ~( SYM_MIRROR_X | SYM_MIRROR_Y ) ) ) )
{
case SYM_ROTATE_CLOCKWISE:
case SYM_ORIENT_90:
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::LEFT;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::UP;
if( symbol->GetOrientation() & SYM_MIRROR_X )
{
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::UP;
}
if( symbol->GetOrientation() & SYM_MIRROR_Y )
{
if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::LEFT;
}
break;
case SYM_ROTATE_COUNTERCLOCKWISE:
case SYM_ORIENT_270:
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::LEFT;
else if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::UP;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::BOTTOM;
if( symbol->GetOrientation() & SYM_MIRROR_X )
{
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::UP;
}
if( symbol->GetOrientation() & SYM_MIRROR_Y )
{
if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::LEFT;
}
break;
case SYM_ORIENT_180:
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::UP;
else if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::LEFT;
if( symbol->GetOrientation() & SYM_MIRROR_X )
{
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::UP;
}
if( symbol->GetOrientation() & SYM_MIRROR_Y )
{
if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::LEFT;
}
break;
case SYM_ORIENT_0:
case SYM_NORMAL:
default:
if( symbol->GetOrientation() & SYM_MIRROR_X )
{
if( ret == SPIN_STYLE::UP )
ret = SPIN_STYLE::BOTTOM;
else if( ret == SPIN_STYLE::BOTTOM )
ret = SPIN_STYLE::UP;
}
if( symbol->GetOrientation() & SYM_MIRROR_Y )
{
if( ret == SPIN_STYLE::LEFT )
ret = SPIN_STYLE::RIGHT;
else if( ret == SPIN_STYLE::RIGHT )
ret = SPIN_STYLE::LEFT;
}
break;
}
break;
}
}
}
break;
default: break;
}
}
return ret;
}
bool SCH_SCREEN::IsExplicitJunctionAllowed( const VECTOR2I& aPosition ) const
{
bool hasExplicitJunction;
bool hasBusEntry;
bool isJunction = doIsJunction( aPosition, true, &hasExplicitJunction, &hasBusEntry );
return isJunction && !hasBusEntry;
}
bool SCH_SCREEN::doIsJunction( const VECTOR2I& aPosition, bool aBreakCrossings,
bool* aHasExplicitJunctionDot, bool* aHasBusEntry ) const
{
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enum layers { WIRES = 0, BUSES };
*aHasExplicitJunctionDot = false;
*aHasBusEntry = false;
bool breakLines[ 2 ] = { false };
std::unordered_set<int> exitAngles[ 2 ];
std::vector<const SCH_LINE*> midPointLines[ 2 ];
2019-05-17 09:29:52 +00:00
2022-01-08 13:23:32 +00:00
// A pin at 90° still shouldn't match a line at 90° so just give pins unique numbers
int uniqueAngle = 10000;
for( const SCH_ITEM* item : Items().Overlapping( aPosition ) )
{
if( item->GetEditFlags() & STRUCT_DELETED )
continue;
switch( item->Type() )
{
case SCH_JUNCTION_T:
if( item->HitTest( aPosition, -1 ) )
*aHasExplicitJunctionDot = true;
break;
case SCH_LINE_T:
{
const SCH_LINE* line = static_cast<const SCH_LINE*>( item );
int layer;
if( line->GetStartPoint() == line->GetEndPoint() )
break;
else if( line->GetLayer() == LAYER_WIRE )
layer = WIRES;
else if( line->GetLayer() == LAYER_BUS )
layer = BUSES;
else
break;
if( line->IsConnected( aPosition ) )
{
breakLines[ layer ] = true;
exitAngles[ layer ].insert( line->GetAngleFrom( aPosition ) );
}
else if( line->HitTest( aPosition, -1 ) )
{
if( aBreakCrossings )
breakLines[ layer ] = true;
// Defer any line midpoints until we know whether or not we're breaking them
midPointLines[ layer ].push_back( line );
}
}
break;
case SCH_BUS_WIRE_ENTRY_T:
if( item->IsConnected( aPosition ) )
{
breakLines[ BUSES ] = true;
exitAngles[ BUSES ].insert( uniqueAngle++ );
breakLines[ WIRES ] = true;
exitAngles[ WIRES ].insert( uniqueAngle++ );
*aHasBusEntry = true;
}
break;
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case SCH_SYMBOL_T:
case SCH_SHEET_T:
if( item->IsConnected( aPosition ) )
{
breakLines[ WIRES ] = true;
exitAngles[ WIRES ].insert( uniqueAngle++ );
}
break;
default:
break;
}
}
for( int layer : { WIRES, BUSES } )
{
if( breakLines[ layer ] )
{
for( const SCH_LINE* line : midPointLines[ layer ] )
{
exitAngles[ layer ].insert( line->GetAngleFrom( aPosition ) );
exitAngles[ layer ].insert( line->GetReverseAngleFrom( aPosition ) );
}
}
}
return exitAngles[ WIRES ].size() >= 3 || exitAngles[ BUSES ].size() >= 3;
}
bool SCH_SCREEN::IsTerminalPoint( const VECTOR2I& aPosition, int aLayer ) const
{
wxCHECK_MSG( aLayer == LAYER_NOTES || aLayer == LAYER_BUS || aLayer == LAYER_WIRE, false,
wxT( "Invalid layer type passed to SCH_SCREEN::IsTerminalPoint()." ) );
SCH_SHEET_PIN* sheetPin;
SCH_LABEL_BASE* label;
switch( aLayer )
{
case LAYER_BUS:
if( GetBus( aPosition ) )
return true;
sheetPin = GetSheetPin( aPosition );
if( sheetPin && sheetPin->IsConnected( aPosition ) )
return true;
label = GetLabel( aPosition );
if( label && !label->IsNew() && label->IsConnected( aPosition ) )
return true;
break;
case LAYER_NOTES:
if( GetLine( aPosition ) )
return true;
break;
case LAYER_WIRE:
if( GetItem( aPosition, 1, SCH_BUS_WIRE_ENTRY_T ) )
return true;
if( GetItem( aPosition, 1, SCH_JUNCTION_T ) )
return true;
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if( GetPin( aPosition, nullptr, true ) )
return true;
if( GetWire( aPosition ) )
return true;
label = GetLabel( aPosition, 1 );
if( label && !label->IsNew() && label->IsConnected( aPosition ) )
return true;
sheetPin = GetSheetPin( aPosition );
if( sheetPin && sheetPin->IsConnected( aPosition ) )
return true;
break;
default:
break;
}
return false;
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
void SCH_SCREEN::UpdateSymbolLinks( REPORTER* aReporter )
{
wxCHECK_RET( Schematic(), "Cannot call SCH_SCREEN::UpdateSymbolLinks with no SCHEMATIC" );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
wxString msg;
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std::unique_ptr< LIB_SYMBOL > libSymbol;
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std::vector<SCH_SYMBOL*> symbols;
SYMBOL_LIB_TABLE* libs = PROJECT_SCH::SchSymbolLibTable( &Schematic()->Prj() );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
// This will be a nullptr if an s-expression schematic is loaded.
SYMBOL_LIBS* legacyLibs = PROJECT_SCH::SchLibs( &Schematic()->Prj() );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
2021-11-23 21:18:04 +00:00
for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
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symbols.push_back( static_cast<SCH_SYMBOL*>( item ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
// Remove them from the R tree. There bounding box size may change.
2021-11-23 21:18:04 +00:00
for( SCH_SYMBOL* symbol : symbols )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
Remove( symbol );
// Clear all existing symbol links.
clearLibSymbols();
for( SCH_SYMBOL* symbol : symbols )
{
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LIB_SYMBOL* tmp = nullptr;
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
libSymbol.reset();
// If the symbol is already in the internal library, map the symbol to it.
auto it = m_libSymbols.find( symbol->GetSchSymbolLibraryName() );
if( ( it != m_libSymbols.end() ) )
{
if( aReporter )
{
msg.Printf( _( "Setting schematic symbol '%s %s' library identifier to '%s'." ),
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symbol->GetField( REFERENCE_FIELD )->GetText(),
symbol->GetField( VALUE_FIELD )->GetText(),
UnescapeString( symbol->GetLibId().Format() ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
aReporter->ReportTail( msg, RPT_SEVERITY_INFO );
}
// Internal library symbols are already flattened so just make a copy.
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symbol->SetLibSymbol( new LIB_SYMBOL( *it->second ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
continue;
}
if( !symbol->GetLibId().IsValid() )
{
if( aReporter )
{
msg.Printf( _( "Schematic symbol reference '%s' library identifier is not valid. "
"Unable to link library symbol." ),
UnescapeString( symbol->GetLibId().Format() ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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aReporter->ReportTail( msg, RPT_SEVERITY_WARNING );
}
continue;
}
// LIB_TABLE_BASE::LoadSymbol() throws an IO_ERROR if the library nickname
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
// is not found in the table so check if the library still exists in the table
// before attempting to load the symbol.
if( !libs->HasLibrary( symbol->GetLibId().GetLibNickname() ) && !legacyLibs )
{
if( aReporter )
{
msg.Printf( _( "Symbol library '%s' not found and no fallback cache library "
"available. Unable to link library symbol." ),
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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symbol->GetLibId().GetLibNickname().wx_str() );
aReporter->ReportTail( msg, RPT_SEVERITY_WARNING );
}
continue;
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
if( libs->HasLibrary( symbol->GetLibId().GetLibNickname() ) )
{
try
{
tmp = libs->LoadSymbol( symbol->GetLibId() );
}
catch( const IO_ERROR& ioe )
{
if( aReporter )
{
msg.Printf( _( "I/O error %s resolving library symbol %s" ), ioe.What(),
UnescapeString( symbol->GetLibId().Format() ) );
aReporter->ReportTail( msg, RPT_SEVERITY_ERROR );
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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}
}
if( !tmp && legacyLibs && legacyLibs->GetLibraryCount() )
{
SYMBOL_LIB& legacyCacheLib = legacyLibs->back();
// It better be the cache library.
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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wxCHECK2( legacyCacheLib.IsCache(), continue );
wxString id = symbol->GetLibId().Format();
id.Replace( ':', '_' );
if( aReporter )
{
msg.Printf( _( "Falling back to cache to set symbol '%s:%s' link '%s'." ),
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symbol->GetField( REFERENCE_FIELD )->GetText(),
symbol->GetField( VALUE_FIELD )->GetText(),
UnescapeString( id ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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aReporter->ReportTail( msg, RPT_SEVERITY_WARNING );
}
tmp = legacyCacheLib.FindSymbol( id );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
}
if( tmp )
{
// We want a full symbol not just the top level child symbol.
libSymbol = tmp->Flatten();
libSymbol->SetParent();
m_libSymbols.insert( { symbol->GetSchSymbolLibraryName(),
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new LIB_SYMBOL( *libSymbol.get() ) } );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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if( aReporter )
{
msg.Printf( _( "Setting schematic symbol '%s %s' library identifier to '%s'." ),
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symbol->GetField( REFERENCE_FIELD )->GetText(),
symbol->GetField( VALUE_FIELD )->GetText(),
UnescapeString( symbol->GetLibId().Format() ) );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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aReporter->ReportTail( msg, RPT_SEVERITY_INFO );
}
}
else
{
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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if( aReporter )
{
msg.Printf( _( "No library symbol found for schematic symbol '%s %s'." ),
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symbol->GetField( REFERENCE_FIELD )->GetText(),
symbol->GetField( VALUE_FIELD )->GetText() );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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aReporter->ReportTail( msg, RPT_SEVERITY_ERROR );
}
}
if( libSymbol.get() ) // Only change the old link if the new link exists
symbol->SetLibSymbol( libSymbol.release() );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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}
// Changing the symbol may adjust the bbox of the symbol. This re-inserts the
// item with the new bbox
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for( SCH_SYMBOL* symbol : symbols )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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Append( symbol );
}
void SCH_SCREEN::UpdateLocalLibSymbolLinks()
{
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std::vector<SCH_SYMBOL*> symbols;
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for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
symbols.push_back( static_cast<SCH_SYMBOL*>( item ) );
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for( SCH_SYMBOL* symbol : symbols )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
// Changing the symbol may adjust the bbox of the symbol; remove and reinsert it afterwards.
m_rtree.remove( symbol );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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auto it = m_libSymbols.find( symbol->GetSchSymbolLibraryName() );
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LIB_SYMBOL* libSymbol = nullptr;
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
if( it != m_libSymbols.end() )
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libSymbol = new LIB_SYMBOL( *it->second );
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
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symbol->SetLibSymbol( libSymbol );
m_rtree.insert( symbol );
}
}
void SCH_SCREEN::SetConnectivityDirty()
{
for( SCH_ITEM* item : Items() )
item->SetConnectivityDirty( true );
}
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void SCH_SCREEN::Print( const RENDER_SETTINGS* aSettings )
{
// Ensure links are up to date, even if a library was reloaded for some reason:
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std::vector<SCH_ITEM*> junctions;
std::vector<SCH_ITEM*> bitmaps;
std::vector<SCH_ITEM*> other;
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for( SCH_ITEM* item : Items() )
{
if( item->IsMoving() )
continue;
if( item->Type() == SCH_JUNCTION_T )
junctions.push_back( item );
else if( item->Type() == SCH_BITMAP_T )
bitmaps.push_back( item );
else
other.push_back( item );
}
/// Sort to ensure plot-order consistency with screen drawing
std::stable_sort( other.begin(), other.end(),
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[]( const SCH_ITEM* a, const SCH_ITEM* b )
{
if( a->Type() == b->Type() )
return a->GetLayer() > b->GetLayer();
return a->Type() < b->Type();
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} );
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for( SCH_ITEM* item : bitmaps )
item->Print( aSettings, VECTOR2I( 0, 0 ) );
for( SCH_ITEM* item : other )
item->PrintBackground( aSettings, VECTOR2I( 0, 0 ) );
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for( SCH_ITEM* item : other )
item->Print( aSettings, VECTOR2I( 0, 0 ) );
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for( SCH_ITEM* item : junctions )
item->Print( aSettings, VECTOR2I( 0, 0 ) );
}
void SCH_SCREEN::Plot( PLOTTER* aPlotter, const SCH_PLOT_SETTINGS& aPlotSettings ) const
{
// Ensure links are up to date, even if a library was reloaded for some reason:
std::vector<SCH_ITEM*> junctions;
std::vector<SCH_ITEM*> bitmaps;
std::vector<SCH_SYMBOL*> symbols;
std::vector<SCH_ITEM*> other;
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for( SCH_ITEM* item : Items() )
{
if( item->IsMoving() )
continue;
if( item->Type() == SCH_JUNCTION_T )
junctions.push_back( item );
else if( item->Type() == SCH_BITMAP_T )
bitmaps.push_back( item );
else
other.push_back( item );
// Where the symbols overlap each other, we need to plot the text items a second
// time to get them on top of the overlapping element. This collection is in addition
// to the symbols already collected in `other`
if( item->Type() == SCH_SYMBOL_T )
{
for( SCH_ITEM* sym : m_rtree.Overlapping( SCH_SYMBOL_T, item->GetBoundingBox() ) )
{
if( sym != item )
{
symbols.push_back( static_cast<SCH_SYMBOL*>( item ) );
break;
}
}
}
}
/// Sort to ensure plot-order consistency with screen drawing
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std::sort( other.begin(), other.end(),
[]( const SCH_ITEM* a, const SCH_ITEM* b )
{
if( a->Type() == b->Type() )
return a->GetLayer() > b->GetLayer();
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return a->Type() > b->Type();
} );
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int defaultPenWidth = aPlotter->RenderSettings()->GetDefaultPenWidth();
constexpr bool background = true;
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// Bitmaps are drawn first to ensure they are in the background
// This is particularly important for the wxPostscriptDC (used in *nix printers) as
// the bitmap PS command clears the screen
for( const SCH_ITEM* item : bitmaps )
{
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aPlotter->SetCurrentLineWidth( std::max( item->GetPenWidth(), defaultPenWidth ) );
item->Plot( aPlotter, background, aPlotSettings );
}
// Plot the background items
for( const SCH_ITEM* item : other )
{
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aPlotter->SetCurrentLineWidth( std::max( item->GetPenWidth(), defaultPenWidth ) );
item->Plot( aPlotter, background, aPlotSettings );
}
// Plot the foreground items
for( const SCH_ITEM* item : other )
{
aPlotter->SetCurrentLineWidth( std::max( item->GetPenWidth(), defaultPenWidth ) );
item->Plot( aPlotter, !background, aPlotSettings );
}
// After plotting the symbols as a group above (in `other`), we need to overplot the pins
// and symbols to ensure that they are always visible
for( const SCH_SYMBOL* sym :symbols )
{
aPlotter->SetCurrentLineWidth( std::max( sym->GetPenWidth(), defaultPenWidth ) );
for( SCH_FIELD field : sym->GetFields() )
{
field.ClearRenderCache();
field.Plot( aPlotter, false, aPlotSettings );
}
sym->PlotPins( aPlotter );
if( sym->GetDNP() )
sym->PlotDNP( aPlotter );
}
for( const SCH_ITEM* item : junctions )
{
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aPlotter->SetCurrentLineWidth( std::max( item->GetPenWidth(), defaultPenWidth ) );
item->Plot( aPlotter, !background, aPlotSettings );
}
}
void SCH_SCREEN::ClearDrawingState()
{
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for( SCH_ITEM* item : Items() )
item->ClearTempFlags();
}
LIB_PIN* SCH_SCREEN::GetPin( const VECTOR2I& aPosition, SCH_SYMBOL** aSymbol,
bool aEndPointOnly ) const
{
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SCH_SYMBOL* candidate = nullptr;
LIB_PIN* pin = nullptr;
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for( SCH_ITEM* item : Items().Overlapping( SCH_SYMBOL_T, aPosition ) )
{
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candidate = static_cast<SCH_SYMBOL*>( item );
if( aEndPointOnly )
{
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pin = nullptr;
if( !candidate->GetLibSymbolRef() )
continue;
std::vector<LIB_PIN*> pins;
candidate->GetLibPins( pins );
for( LIB_PIN* test_pin : pins )
{
if( candidate->GetPinPhysicalPosition( test_pin ) == aPosition )
{
pin = test_pin;
break;
}
}
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if( pin )
break;
}
else
{
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pin = (LIB_PIN*) candidate->GetDrawItem( aPosition, LIB_PIN_T );
if( pin )
break;
}
}
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if( pin && aSymbol )
*aSymbol = candidate;
return pin;
}
SCH_SHEET_PIN* SCH_SCREEN::GetSheetPin( const VECTOR2I& aPosition ) const
{
SCH_SHEET_PIN* sheetPin = nullptr;
for( SCH_ITEM* item : Items().Overlapping( SCH_SHEET_T, aPosition ) )
{
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SCH_SHEET* sheet = static_cast<SCH_SHEET*>( item );
sheetPin = sheet->GetPin( aPosition );
if( sheetPin )
break;
}
return sheetPin;
}
size_t SCH_SCREEN::CountConnectedItems( const VECTOR2I& aPos, bool aTestJunctions ) const
{
size_t count = 0;
for( const SCH_ITEM* item : Items().Overlapping( aPos ) )
{
if( ( item->Type() != SCH_JUNCTION_T || aTestJunctions ) && item->IsConnected( aPos ) )
count++;
}
return count;
}
void SCH_SCREEN::ClearAnnotation( SCH_SHEET_PATH* aSheetPath, bool aResetPrefix )
{
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for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
symbol->ClearAnnotation( aSheetPath, aResetPrefix );
}
}
void SCH_SCREEN::EnsureAlternateReferencesExist()
{
if( GetClientSheetPaths().size() <= 1 ) // No need for alternate reference
return;
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for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
// Add (when not existing) all sheet path entries
for( const SCH_SHEET_PATH& sheet : GetClientSheetPaths() )
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symbol->AddSheetPathReferenceEntryIfMissing( sheet.Path() );
}
}
void SCH_SCREEN::GetHierarchicalItems( std::vector<SCH_ITEM*>* aItems ) const
{
for( SCH_ITEM* item : Items() )
{
if( item->IsType( { SCH_SYMBOL_T, SCH_SHEET_T, SCH_LABEL_LOCATE_ANY_T } ) )
aItems->push_back( item );
}
}
void SCH_SCREEN::GetSheets( std::vector<SCH_ITEM*>* aItems ) const
{
for( SCH_ITEM* item : Items().OfType( SCH_SHEET_T ) )
aItems->push_back( item );
std::sort( aItems->begin(), aItems->end(),
[]( EDA_ITEM* a, EDA_ITEM* b ) -> bool
{
if( a->GetPosition().x == b->GetPosition().x )
{
// Ensure deterministic sort
if( a->GetPosition().y == b->GetPosition().y )
return a->m_Uuid < b->m_Uuid;
return a->GetPosition().y < b->GetPosition().y;
}
else
{
return a->GetPosition().x < b->GetPosition().x;
}
} );
}
void SCH_SCREEN::TestDanglingEnds( const SCH_SHEET_PATH* aPath,
std::function<void( SCH_ITEM* )>* aChangedHandler ) const
{
PROF_TIMER timer( __FUNCTION__ );
std::vector<DANGLING_END_ITEM> endPoints;
auto getends =
[&]( SCH_ITEM* item )
{
if( item->IsConnectable() )
item->GetEndPoints( endPoints );
};
auto update_state =
[&]( SCH_ITEM* item )
{
if( item->UpdateDanglingState( endPoints, aPath ) )
{
if( aChangedHandler )
(*aChangedHandler)( item );
}
};
for( SCH_ITEM* item : Items() )
{
getends( item );
item->RunOnChildren( getends );
}
for( SCH_ITEM* item : Items() )
{
update_state( item );
item->RunOnChildren( update_state );
}
if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) )
timer.Show();
}
SCH_LINE* SCH_SCREEN::GetLine( const VECTOR2I& aPosition, int aAccuracy, int aLayer,
SCH_LINE_TEST_T aSearchType ) const
{
// an accuracy of 0 had problems with rounding errors; use at least 1
aAccuracy = std::max( aAccuracy, 1 );
for( SCH_ITEM* item : Items().Overlapping( aPosition, aAccuracy ) )
{
if( item->Type() != SCH_LINE_T )
continue;
if( item->GetLayer() != aLayer )
continue;
if( !item->HitTest( aPosition, aAccuracy ) )
continue;
switch( aSearchType )
{
case ENTIRE_LENGTH_T:
return (SCH_LINE*) item;
case EXCLUDE_END_POINTS_T:
if( !( (SCH_LINE*) item )->IsEndPoint( aPosition ) )
return (SCH_LINE*) item;
break;
case END_POINTS_ONLY_T:
if( ( (SCH_LINE*) item )->IsEndPoint( aPosition ) )
return (SCH_LINE*) item;
}
}
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return nullptr;
}
std::vector<SCH_LINE*> SCH_SCREEN::GetBusesAndWires( const VECTOR2I& aPosition,
bool aIgnoreEndpoints ) const
{
std::vector<SCH_LINE*> retVal;
for( SCH_ITEM* item : Items().Overlapping( SCH_LINE_T, aPosition ) )
{
if( item->IsType( { SCH_ITEM_LOCATE_WIRE_T, SCH_ITEM_LOCATE_BUS_T } ) )
{
SCH_LINE* wire = static_cast<SCH_LINE*>( item );
if( aIgnoreEndpoints && wire->IsEndPoint( aPosition ) )
continue;
if( IsPointOnSegment( wire->GetStartPoint(), wire->GetEndPoint(), aPosition ) )
retVal.push_back( wire );
}
}
return retVal;
}
std::vector<VECTOR2I> SCH_SCREEN::GetConnections() const
{
std::vector<VECTOR2I> retval;
for( SCH_ITEM* item : Items() )
{
// Avoid items that are changing
if( !( item->GetEditFlags() & ( IS_MOVING | IS_DELETED ) ) )
{
std::vector<VECTOR2I> pts = item->GetConnectionPoints();
retval.insert( retval.end(), pts.begin(), pts.end() );
}
}
// We always have some overlapping connection points. Drop duplicates here
std::sort( retval.begin(), retval.end(),
[]( const VECTOR2I& a, const VECTOR2I& b ) -> bool
{
return a.x < b.x || ( a.x == b.x && a.y < b.y );
} );
retval.erase( std::unique( retval.begin(), retval.end() ), retval.end() );
return retval;
}
std::vector<VECTOR2I> SCH_SCREEN::GetNeededJunctions( const std::deque<EDA_ITEM*>& aItems ) const
{
std::vector<VECTOR2I> pts;
std::vector<VECTOR2I> connections = GetConnections();
for( const EDA_ITEM* edaItem : aItems )
{
const SCH_ITEM* item = dynamic_cast<const SCH_ITEM*>( edaItem );
if( !item || !item->IsConnectable() )
continue;
std::vector<VECTOR2I> new_pts = item->GetConnectionPoints();
pts.insert( pts.end(), new_pts.begin(), new_pts.end() );
// If the item is a line, we also add any connection points from the rest of the schematic
// that terminate on the line after it is moved.
if( item->Type() == SCH_LINE_T )
{
SCH_LINE* line = (SCH_LINE*) item;
for( const VECTOR2I& pt : connections )
{
if( IsPointOnSegment( line->GetStartPoint(), line->GetEndPoint(), pt ) )
pts.push_back( pt );
}
}
}
// We always have some overlapping connection points. Drop duplicates here
std::sort( pts.begin(), pts.end(),
[]( const VECTOR2I& a, const VECTOR2I& b ) -> bool
{
return a.x < b.x || ( a.x == b.x && a.y < b.y );
} );
pts.erase( unique( pts.begin(), pts.end() ), pts.end() );
// We only want the needed junction points, remove all the others
pts.erase( std::remove_if( pts.begin(), pts.end(),
[this]( const VECTOR2I& a ) -> bool
{
return !IsExplicitJunctionNeeded( a );
} ),
pts.end() );
return pts;
}
SCH_LABEL_BASE* SCH_SCREEN::GetLabel( const VECTOR2I& aPosition, int aAccuracy ) const
{
for( SCH_ITEM* item : Items().Overlapping( aPosition, aAccuracy ) )
{
switch( item->Type() )
{
case SCH_LABEL_T:
case SCH_GLOBAL_LABEL_T:
case SCH_HIER_LABEL_T:
case SCH_DIRECTIVE_LABEL_T:
if( item->HitTest( aPosition, aAccuracy ) )
return static_cast<SCH_LABEL_BASE*>( item );
break;
default:
;
}
}
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return nullptr;
}
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void SCH_SCREEN::AddLibSymbol( LIB_SYMBOL* aLibSymbol )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
{
wxCHECK( aLibSymbol, /* void */ );
wxString libSymbolName = aLibSymbol->GetLibId().Format().wx_str();
auto it = m_libSymbols.find( libSymbolName );
if( it != m_libSymbols.end() )
{
delete it->second;
m_libSymbols.erase( it );
}
m_libSymbols[libSymbolName] = aLibSymbol;
}
void SCH_SCREEN::AddBusAlias( std::shared_ptr<BUS_ALIAS> aAlias )
{
m_aliases.insert( aAlias );
}
void SCH_SCREEN::SetLegacySymbolInstanceData()
{
for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
// Add missing value and footprint instance data for legacy schematics.
for( const SCH_SYMBOL_INSTANCE& instance : symbol->GetInstanceReferences() )
{
symbol->AddHierarchicalReference( instance.m_Path, instance.m_Reference,
instance.m_Unit );
}
}
}
void SCH_SCREEN::FixLegacyPowerSymbolMismatches()
{
for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
// Fix pre-8.0 legacy power symbols with invisible pins
// that have mismatched pin names and value fields
if( symbol->GetLibSymbolRef()
&& symbol->GetLibSymbolRef()->IsPower()
&& symbol->GetAllLibPins().size() > 0
&& symbol->GetAllLibPins()[0]->IsGlobalPower()
&& !symbol->GetAllLibPins()[0]->IsVisible() )
{
symbol->SetValueFieldText( symbol->GetAllLibPins()[0]->GetName() );
}
}
}
size_t SCH_SCREEN::getLibSymbolNameMatches( const SCH_SYMBOL& aSymbol,
std::vector<wxString>& aMatches )
{
wxString searchName = aSymbol.GetLibId().GetUniStringLibId();
if( m_libSymbols.find( searchName ) != m_libSymbols.end() )
aMatches.emplace_back( searchName );
searchName = aSymbol.GetLibId().GetUniStringLibItemName() + wxS( "_" );
long tmp;
wxString suffix;
for( auto& pair : m_libSymbols )
{
if( pair.first.StartsWith( searchName, &suffix ) && suffix.ToLong( &tmp ) )
aMatches.emplace_back( pair.first );
}
return aMatches.size();
}
void SCH_SCREEN::PruneOrphanedSymbolInstances( const wxString& aProjectName,
const SCH_SHEET_LIST& aValidSheetPaths )
{
// The project name cannot be empty. Projects older than 7.0 did not save project names
// when saving instance data. Running this algorithm with an empty project name would
// clobber all instance data for projects other than the current one when a schematic
// file is shared across multiple projects.
wxCHECK( !aProjectName.IsEmpty(), /* void */ );
for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
wxCHECK2( symbol, continue );
std::set<KIID_PATH> pathsToPrune;
const std::vector<SCH_SYMBOL_INSTANCE> instances = symbol->GetInstanceReferences();
for( const SCH_SYMBOL_INSTANCE& instance : instances )
{
// Ignore instance paths from other projects.
if( aProjectName != instance.m_ProjectName )
continue;
std::optional<SCH_SHEET_PATH> pathFound =
aValidSheetPaths.GetSheetPathByKIIDPath( instance.m_Path );
// Check for paths that do not exist in the current project and paths that do
// not contain the current symbol.
if( !pathFound )
pathsToPrune.emplace( instance.m_Path );
else if( pathFound.value().LastScreen() != this )
pathsToPrune.emplace( pathFound.value().Path() );
}
for( const KIID_PATH& sheetPath : pathsToPrune )
{
wxLogTrace( traceSchSheetPaths, wxS( "Pruning project '%s' symbol instance %s." ),
aProjectName, sheetPath.AsString() );
symbol->RemoveInstance( sheetPath );
}
}
}
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
#if defined(DEBUG)
void SCH_SCREEN::Show( int nestLevel, std::ostream& os ) const
{
// for now, make it look like XML, expand on this later.
NestedSpace( nestLevel, os ) << '<' << GetClass().Lower().mb_str() << ">\n";
for( const SCH_ITEM* item : Items() )
item->Show( nestLevel + 1, os );
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
NestedSpace( nestLevel, os ) << "</" << GetClass().Lower().mb_str() << ">\n";
}
#endif
SCH_SCREENS::SCH_SCREENS( SCH_SHEET* aSheet )
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{
m_index = 0;
buildScreenList( aSheet );
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}
SCH_SCREENS::~SCH_SCREENS()
{
}
SCH_SCREEN* SCH_SCREENS::GetFirst()
{
m_index = 0;
if( m_screens.size() > 0 )
return m_screens[0];
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return nullptr;
}
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SCH_SCREEN* SCH_SCREENS::GetNext()
{
if( m_index < m_screens.size() )
m_index++;
return GetScreen( m_index );
}
SCH_SCREEN* SCH_SCREENS::GetScreen( unsigned int aIndex ) const
{
if( aIndex < m_screens.size() )
return m_screens[ aIndex ];
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return nullptr;
}
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SCH_SHEET* SCH_SCREENS::GetSheet( unsigned int aIndex ) const
{
if( aIndex < m_sheets.size() )
return m_sheets[ aIndex ];
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return nullptr;
}
void SCH_SCREENS::addScreenToList( SCH_SCREEN* aScreen, SCH_SHEET* aSheet )
{
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if( aScreen == nullptr )
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return;
for( const SCH_SCREEN* screen : m_screens )
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{
if( screen == aScreen )
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return;
}
m_screens.push_back( aScreen );
m_sheets.push_back( aSheet );
}
2008-02-26 19:19:54 +00:00
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
void SCH_SCREENS::buildScreenList( SCH_SHEET* aSheet )
{
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
if( aSheet && aSheet->Type() == SCH_SHEET_T )
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{
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
SCH_SCREEN* screen = aSheet->GetScreen();
wxCHECK_RET( screen, "No screen for aSheet" );
addScreenToList( screen, aSheet );
for( SCH_ITEM* item : screen->Items().OfType( SCH_SHEET_T ) )
buildScreenList( static_cast<SCH_SHEET*>( item ) );
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}
}
void SCH_SCREENS::ClearAnnotationOfNewSheetPaths( SCH_SHEET_LIST& aInitialSheetPathList )
{
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SCH_SCREEN* first = GetFirst();
if( !first )
return;
SCHEMATIC* sch = first->Schematic();
wxCHECK_RET( sch, "Null schematic in SCH_SCREENS::ClearAnnotationOfNewSheetPaths" );
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// Clear the annotation for symbols inside new sheetpaths not already in aInitialSheetList
SCH_SCREENS screensList( sch->Root() ); // The list of screens, shared by sheet paths
screensList.BuildClientSheetPathList(); // build the shared by sheet paths, by screen
// Search for new sheet paths, not existing in aInitialSheetPathList
// and existing in sheetpathList
for( SCH_SHEET_PATH& sheetpath : sch->GetSheets() )
{
bool path_exists = false;
for( const SCH_SHEET_PATH& existing_sheetpath: aInitialSheetPathList )
{
if( existing_sheetpath.Path() == sheetpath.Path() )
{
path_exists = true;
break;
}
}
if( !path_exists )
{
// A new sheet path is found: clear the annotation corresponding to this new path:
SCH_SCREEN* curr_screen = sheetpath.LastScreen();
// Clear annotation and create the AR for this path, if not exists,
// when the screen is shared by sheet paths.
// Otherwise ClearAnnotation do nothing, because the F1 field is used as
// reference default value and takes the latest displayed value
curr_screen->EnsureAlternateReferencesExist();
curr_screen->ClearAnnotation( &sheetpath, false );
}
}
}
int SCH_SCREENS::ReplaceDuplicateTimeStamps()
{
std::vector<SCH_ITEM*> items;
int count = 0;
auto timestamp_cmp = []( const EDA_ITEM* a, const EDA_ITEM* b ) -> bool
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{
return a->m_Uuid < b->m_Uuid;
};
std::set<EDA_ITEM*, decltype( timestamp_cmp )> unique_stamps( timestamp_cmp );
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for( SCH_SCREEN* screen : m_screens )
screen->GetHierarchicalItems( &items );
if( items.size() < 2 )
return 0;
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for( EDA_ITEM* item : items )
{
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if( !unique_stamps.insert( item ).second )
{
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// Reset to fully random UUID. This may lose reference, but better to be
// deterministic about it rather than to have duplicate UUIDs with random
// side-effects.
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const_cast<KIID&>( item->m_Uuid ) = KIID();
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count++;
// @todo If the item is a sheet, we need to decend the heirarchy from the sheet
// and repace all instances of the changed UUID in sheet paths. Otherwise,
// all instance paths with the sheet's UUID will get clobbered.
}
}
return count;
}
void SCH_SCREENS::ClearEditFlags()
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
for( SCH_ITEM* item : screen->Items() )
item->ClearEditFlags();
}
}
void SCH_SCREENS::DeleteMarker( SCH_MARKER* aMarker )
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
for( SCH_ITEM* item : screen->Items().OfType( SCH_MARKER_T ) )
{
if( item == aMarker )
{
screen->DeleteItem( item );
return;
}
}
}
}
void SCH_SCREENS::DeleteMarkers( enum MARKER_BASE::TYPEMARKER aMarkerType, int aErrorCode,
bool aIncludeExclusions )
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
std::vector<SCH_ITEM*> markers;
for( SCH_ITEM* item : screen->Items().OfType( SCH_MARKER_T ) )
{
SCH_MARKER* marker = static_cast<SCH_MARKER*>( item );
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std::shared_ptr<RC_ITEM>rcItem = marker->GetRCItem();
if( marker->GetMarkerType() == aMarkerType
&& ( aErrorCode == ERCE_UNSPECIFIED || rcItem->GetErrorCode() == aErrorCode )
&& ( !marker->IsExcluded() || aIncludeExclusions ) )
{
markers.push_back( item );
}
}
for( SCH_ITEM* marker : markers )
screen->DeleteItem( marker );
}
}
void SCH_SCREENS::DeleteAllMarkers( enum MARKER_BASE::TYPEMARKER aMarkerType,
bool aIncludeExclusions )
{
DeleteMarkers( aMarkerType, ERCE_UNSPECIFIED, aIncludeExclusions );
}
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
void SCH_SCREENS::UpdateSymbolLinks( REPORTER* aReporter )
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
Make the new schematic and symbol library file formats the default. This is a very large and potentially disruptive change so this will be an unusually long and detailed commit message. The new file formats are now the default in both the schematic and symbol library editors. Existing symbol libraries will be saved in their current format until new features are added to library symbols. Once this happens, both the legacy schematic and symbol file formats will be no longer be savable and existing libraries will have to be converted. Saving to the legacy file formats is still available for round robin testing and should not be used for normal editing. When loading the legacy schematic file, it is imperative that the schematic library symbols are rescued and/or remapped to valid library identifiers. Otherwise, there will be no way to link to the original library symbol and the user will be required manually set the library identifier. The cached symbol will be saved in the schematic file so the last library symbol in the cache will still be used but there will be no way to update it from the original library. The next save after loading a legacy schematic file will be converted to the s-expression file format. Schematics with hierarchical sheets will automatically have all sheet file name extensions changed to .kicad_sym and saved to the new format as well. Appending schematics requires that the schematic to append has already been converted to the new file format. This is required to ensure that library symbols are guaranteed to be valid for the appended schematic. The schematic symbol library symbol link resolution has been moved out of the SCH_COMPONENT object and move into the SCH_SCREEN object that owns the symbol. This was done to ensure that there is a single place where the library symbol links get resolved rather than the dozen or so different code paths that previously existed. It also removes the necessity of the SCH_COMPONENT object of requiring any knowledge of the symbol library table and/or the cache library. When opening an s-expression schematic, the legacy cache library is not loaded so any library symbols not rescued cannot be loaded. Broken library symbol links will have to be manually resolved by adding the cache library to the symbol library table and changing the links in the schematic symbol. Now that the library symbols are embedded in the schematic file, the SCH_SCREEN object maintains the list of library symbols for the schematic automatically. No external manipulation of this library cache should ever occur. ADDED: S-expression schematic and symbol library file formats.
2020-04-16 16:43:50 +00:00
screen->UpdateSymbolLinks( aReporter );
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SCH_SCREEN* first = GetFirst();
if( !first )
return;
SCHEMATIC* sch = first->Schematic();
wxCHECK_RET( sch, "Null schematic in SCH_SCREENS::UpdateSymbolLinks" );
SCH_SHEET_LIST sheets = sch->GetSheets();
// All of the library symbols have been replaced with copies so the connection graph
// pointers are stale.
if( sch->ConnectionGraph() )
sch->ConnectionGraph()->Recalculate( sheets, true );
}
bool SCH_SCREENS::HasNoFullyDefinedLibIds()
{
bool has_symbols = false;
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
for( SCH_ITEM* item : screen->Items().OfType( SCH_SYMBOL_T ) )
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
has_symbols = true;
if( !symbol->GetLibId().GetLibNickname().empty() )
return false;
}
}
// return true (i.e. has no fully defined symbol) only if at least one symbol is found
return has_symbols ? true : false;
}
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
size_t SCH_SCREENS::GetLibNicknames( wxArrayString& aLibNicknames )
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
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for( SCH_ITEM* item : screen->Items().OfType( SCH_SYMBOL_T ) )
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
{
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SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
const UTF8& nickname = symbol->GetLibId().GetLibNickname();
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
if( !nickname.empty() && ( aLibNicknames.Index( nickname ) == wxNOT_FOUND ) )
aLibNicknames.Add( nickname );
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
}
}
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
return aLibNicknames.GetCount();
}
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
int SCH_SCREENS::ChangeSymbolLibNickname( const wxString& aFrom, const wxString& aTo )
{
SCH_SCREEN* screen;
int cnt = 0;
for( screen = GetFirst(); screen; screen = GetNext() )
{
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for( SCH_ITEM* item : screen->Items().OfType( SCH_SYMBOL_T ) )
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
{
2021-11-23 21:18:04 +00:00
SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
Use legacy schematic plugin for loading schematics in all code paths. Use the legacy plugin schematic loader in the sheet edit and append schematic code paths. Check for fully qualified LIB_ID objects (must have library nickname) when loading existing schematics when edit sheets. Rewrite append schematic feature to handle import issues rather than change the name and file name of all of the sheets in the imported schematic. This includes the following: - Load the schematic into a temporary SCH_SHEET object. - Make sure the imported schematic does not cause any hierarchy recursion issues. - Verify the imported schematic uses fully qualified #LIB_ID objects (symbol library table). - Check to see if any symbol libraries need to be added to the current project's symbol library table. This includes: - Check if the symbol library already exists in the project or global symbol library table. - Convert symbol library URLS that use the ${KIPRJMOD} environment variable to absolute paths. ${KIPRJMOD} will not be the same for this project. - Check for duplicate symbol library nicknames and change the new symbol library nickname to prevent library name clashes. - Update all schematic symbol LIB_ID object library nicknames when the library nickname was changed to prevent clashes. - Check for duplicate sheet names which is illegal and automatically rename any duplicate sheets in the imported schematic. - Clear all of the annotation in the imported schematic to prevent clashes. - Append the objects from the temporary sheet to the current page. - Replace any duplicate time stamps. - Refresh the symbol library links. Add support code to SCH_SCREEN object to assist with schematic import. Doxygen comment cleaning. Fixes lp:1731760 https://bugs.launchpad.net/kicad/+bug/1731760
2017-11-17 17:00:04 +00:00
if( symbol->GetLibId().GetLibNickname() != aFrom )
continue;
LIB_ID id = symbol->GetLibId();
id.SetLibNickname( aTo );
symbol->SetLibId( id );
cnt++;
}
}
return cnt;
}
bool SCH_SCREENS::HasSchematic( const wxString& aSchematicFileName )
{
for( const SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
{
if( screen->GetFileName() == aSchematicFileName )
return true;
}
return false;
}
bool SCH_SCREENS::CanCauseCaseSensitivityIssue( const wxString& aSchematicFileName ) const
{
wxString lhsLower;
wxString rhsLower;
wxFileName lhs;
wxFileName rhs = aSchematicFileName;
wxCHECK( rhs.IsAbsolute(), false );
for( const SCH_SCREEN* screen : m_screens )
{
lhs = screen->GetFileName();
if( lhs.GetPath() != rhs.GetPath() )
continue;
lhsLower = lhs.GetFullName().Lower();
rhsLower = rhs.GetFullName().Lower();
if( lhsLower == rhsLower && lhs.GetFullName() != rhs.GetFullName() )
return true;
}
return false;
}
void SCH_SCREENS::BuildClientSheetPathList()
{
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SCH_SCREEN* first = GetFirst();
if( !first )
return;
SCHEMATIC* sch = first->Schematic();
wxCHECK_RET( sch, "Null schematic in SCH_SCREENS::BuildClientSheetPathList" );
for( SCH_SCREEN* curr_screen = GetFirst(); curr_screen; curr_screen = GetNext() )
curr_screen->GetClientSheetPaths().clear();
for( SCH_SHEET_PATH& sheetpath : sch->GetSheets() )
{
SCH_SCREEN* used_screen = sheetpath.LastScreen();
// Search for the used_screen in list and add this unique sheet path:
for( SCH_SCREEN* curr_screen = GetFirst(); curr_screen; curr_screen = GetNext() )
{
if( used_screen == curr_screen )
{
curr_screen->GetClientSheetPaths().push_back( sheetpath );
break;
}
}
}
}
void SCH_SCREENS::SetLegacySymbolInstanceData()
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
screen->SetLegacySymbolInstanceData();
}
void SCH_SCREENS::FixLegacyPowerSymbolMismatches()
{
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
screen->FixLegacyPowerSymbolMismatches();
}
void SCH_SCREEN::MigrateSimModels()
{
LOCALE_IO toggle;
// V6 schematics may specify model names in Value fields, which we don't do in V7.
// Migrate by adding an equivalent model for these symbols.
for( SCH_ITEM* item : Items().OfType( SCH_SYMBOL_T ) )
{
SCH_SYMBOL* symbol = static_cast<SCH_SYMBOL*>( item );
SIM_MODEL::MigrateSimModel<SCH_SYMBOL, SCH_FIELD>( *symbol, &Schematic()->Prj() );
}
}
void SCH_SCREENS::PruneOrphanedSymbolInstances( const wxString& aProjectName,
const SCH_SHEET_LIST& aValidSheetPaths )
{
wxCHECK( !aProjectName.IsEmpty(), /* void */ );
for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() )
screen->PruneOrphanedSymbolInstances( aProjectName, aValidSheetPaths );
}