kicad/eeschema/sch_sexpr_plugin.cpp

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2020 CERN
*
* @author Wayne Stambaugh <stambaughw@gmail.com>
*
* 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, see <http://www.gnu.org/licenses/>.
*/
#include <algorithm>
#include <boost/algorithm/string/join.hpp>
#include <cctype>
// For some reason wxWidgets is built with wxUSE_BASE64 unset so expose the wxWidgets
// base64 code.
#define wxUSE_BASE64 1
#include <wx/base64.h>
#include <wx/mstream.h>
#include <wx/filename.h>
#include <wx/tokenzr.h>
#include <build_version.h>
#include <gal/color4d.h>
#include <pgm_base.h>
#include <gr_text.h>
#include <kiway.h>
#include <kicad_string.h>
#include <richio.h>
#include <core/typeinfo.h>
#include <plotter.h> // PLOT_DASH_TYPE
#include <properties.h>
#include <trace_helpers.h>
#include <sch_bitmap.h>
#include <sch_bus_entry.h>
#include <sch_component.h>
#include <sch_edit_frame.h> // COMPONENT_ORIENTATION_T
#include <sch_junction.h>
#include <sch_line.h>
#include <sch_marker.h>
#include <sch_no_connect.h>
#include <sch_text.h>
#include <sch_sheet.h>
#include <sch_bitmap.h>
#include <bus_alias.h>
#include <sch_sexpr_plugin.h>
#include <template_fieldnames.h>
#include <sch_screen.h>
#include <class_libentry.h>
#include <class_library.h>
#include <lib_arc.h>
#include <lib_bezier.h>
#include <lib_circle.h>
#include <lib_field.h>
#include <lib_pin.h>
#include <lib_polyline.h>
#include <lib_rectangle.h>
#include <lib_text.h>
#include <pin_shape.h>
#include <pin_type.h>
#include <eeschema_id.h> // for MAX_UNIT_COUNT_PER_PACKAGE definition
#include <sch_file_versions.h>
#include <schematic_lexer.h>
#include <sch_reference_list.h>
#include <sch_sexpr_parser.h>
#include <symbol_lib_table.h> // for PropPowerSymsOnly definintion.
#include <confirm.h>
#include <tool/selection.h>
#include <default_values.h> // For some default values
using namespace TSCHEMATIC_T;
#define SCH_PARSE_ERROR( text, reader, pos ) \
THROW_PARSE_ERROR( text, reader.GetSource(), reader.Line(), \
reader.LineNumber(), pos - reader.Line() )
static const char* emptyString = "";
/**
* Fill token formatting helper.
*/
static void formatFill( const LIB_ITEM* aItem, OUTPUTFORMATTER& aFormatter, int aNestLevel )
{
wxCHECK_RET( aItem && aItem->IsFillable() && aItem->GetFillMode() != NO_FILL,
"Invalid fill item." );
aFormatter.Print( aNestLevel, "(fill (type %s))",
aItem->GetFillMode() == FILLED_SHAPE ? "outline" : "background" );
}
static const char* getPinElectricalTypeToken( ELECTRICAL_PINTYPE aType )
{
switch( aType )
{
case ELECTRICAL_PINTYPE::PT_INPUT:
return SCHEMATIC_LEXER::TokenName( T_input );
case ELECTRICAL_PINTYPE::PT_OUTPUT:
return SCHEMATIC_LEXER::TokenName( T_output );
case ELECTRICAL_PINTYPE::PT_BIDI:
return SCHEMATIC_LEXER::TokenName( T_bidirectional );
case ELECTRICAL_PINTYPE::PT_TRISTATE:
return SCHEMATIC_LEXER::TokenName( T_tri_state );
case ELECTRICAL_PINTYPE::PT_PASSIVE:
return SCHEMATIC_LEXER::TokenName( T_passive );
case ELECTRICAL_PINTYPE::PT_UNSPECIFIED:
return SCHEMATIC_LEXER::TokenName( T_unspecified );
case ELECTRICAL_PINTYPE::PT_POWER_IN:
return SCHEMATIC_LEXER::TokenName( T_power_in );
case ELECTRICAL_PINTYPE::PT_POWER_OUT:
return SCHEMATIC_LEXER::TokenName( T_power_out );
case ELECTRICAL_PINTYPE::PT_OPENCOLLECTOR:
return SCHEMATIC_LEXER::TokenName( T_open_collector );
case ELECTRICAL_PINTYPE::PT_OPENEMITTER:
return SCHEMATIC_LEXER::TokenName( T_open_emitter );
case ELECTRICAL_PINTYPE::PT_NC:
return SCHEMATIC_LEXER::TokenName( T_unconnected );
default:
wxFAIL_MSG( "Missing symbol library pin connection type" );
}
return emptyString;
}
static const char* getPinShapeToken( GRAPHIC_PINSHAPE aShape )
{
switch( aShape )
{
case GRAPHIC_PINSHAPE::LINE:
return SCHEMATIC_LEXER::TokenName( T_line );
case GRAPHIC_PINSHAPE::INVERTED:
return SCHEMATIC_LEXER::TokenName( T_inverted );
case GRAPHIC_PINSHAPE::CLOCK:
return SCHEMATIC_LEXER::TokenName( T_clock );
case GRAPHIC_PINSHAPE::INVERTED_CLOCK:
return SCHEMATIC_LEXER::TokenName( T_inverted_clock );
case GRAPHIC_PINSHAPE::INPUT_LOW:
return SCHEMATIC_LEXER::TokenName( T_input_low );
case GRAPHIC_PINSHAPE::CLOCK_LOW:
return SCHEMATIC_LEXER::TokenName( T_clock_low );
case GRAPHIC_PINSHAPE::OUTPUT_LOW:
return SCHEMATIC_LEXER::TokenName( T_output_low );
case GRAPHIC_PINSHAPE::FALLING_EDGE_CLOCK:
return SCHEMATIC_LEXER::TokenName( T_edge_clock_high );
case GRAPHIC_PINSHAPE::NONLOGIC:
return SCHEMATIC_LEXER::TokenName( T_non_logic );
default:
wxFAIL_MSG( "Missing symbol library pin shape type" );
}
return emptyString;
}
static float getPinAngle( int aOrientation )
{
switch( aOrientation )
{
case PIN_RIGHT:
return 0.0;
case PIN_LEFT:
return 180.0;
case PIN_UP:
return 90.0;
case PIN_DOWN:
return 270.0;
default:
wxFAIL_MSG( "Missing symbol library pin orientation type" );
return 0.0;
}
}
static const char* getSheetPinShapeToken( PINSHEETLABEL_SHAPE aShape )
{
switch( aShape )
{
case PINSHEETLABEL_SHAPE::PS_INPUT: return SCHEMATIC_LEXER::TokenName( T_input );
case PINSHEETLABEL_SHAPE::PS_OUTPUT: return SCHEMATIC_LEXER::TokenName( T_output );
case PINSHEETLABEL_SHAPE::PS_BIDI: return SCHEMATIC_LEXER::TokenName( T_bidirectional );
case PINSHEETLABEL_SHAPE::PS_TRISTATE: return SCHEMATIC_LEXER::TokenName( T_tri_state );
case PINSHEETLABEL_SHAPE::PS_UNSPECIFIED: return SCHEMATIC_LEXER::TokenName( T_passive );
default: wxFAIL; return SCHEMATIC_LEXER::TokenName( T_passive );
}
}
static double getSheetPinAngle( SHEET_SIDE aSide )
{
double retv;
switch( aSide )
{
case SHEET_UNDEFINED_SIDE:
case SHEET_LEFT_SIDE: retv = 180.0; break;
case SHEET_RIGHT_SIDE: retv = 0.0; break;
case SHEET_TOP_SIDE: retv = 90.0; break;
case SHEET_BOTTOM_SIDE: retv = 270.0; break;
default: wxFAIL; retv = 0.0; break;
}
return retv;
}
static wxString getLineStyleToken( PLOT_DASH_TYPE aStyle )
{
wxString token;
switch( aStyle )
{
case PLOT_DASH_TYPE::DASH: token = "dash"; break;
case PLOT_DASH_TYPE::DOT: token = "dot"; break;
case PLOT_DASH_TYPE::DASHDOT: token = "dash_dot"; break;
case PLOT_DASH_TYPE::SOLID:
default: token = "solid"; break;
}
return token;
}
static const char* getTextTypeToken( KICAD_T aType )
{
switch( aType )
{
case SCH_TEXT_T: return SCHEMATIC_LEXER::TokenName( T_text );
case SCH_LABEL_T: return SCHEMATIC_LEXER::TokenName( T_label );
case SCH_GLOBAL_LABEL_T: return SCHEMATIC_LEXER::TokenName( T_global_label );
case SCH_HIER_LABEL_T: return SCHEMATIC_LEXER::TokenName( T_hierarchical_label );
default: wxFAIL; return SCHEMATIC_LEXER::TokenName( T_text );
}
}
/**
* Write stroke definition to \a aFormatter.
*
* This only writes the stroke definition if \a aWidth, \a aStyle and \a aColor are
* not the default setting or are not defined.
*
* @param aFormatter A pointer to the #OUTPUTFORMATTER object to write to.
* @param aNestLevel The nest level to indent the stroke definition.
* @param aWidth The stroke line width in internal units.
* @param aStyle The stroke line style.
* @param aColor The stroke line color.
*/
static void formatStroke( OUTPUTFORMATTER* aFormatter, int aNestLevel, int aWidth,
PLOT_DASH_TYPE aStyle, const COLOR4D& aColor )
{
wxASSERT( aFormatter != nullptr );
aFormatter->Print( aNestLevel, "(stroke" );
if( !( aWidth == 0 ) )
aFormatter->Print( 0, " (width %s)", FormatInternalUnits( aWidth ).c_str() );
if( !( aStyle == PLOT_DASH_TYPE::DEFAULT || aStyle == PLOT_DASH_TYPE::SOLID ) )
aFormatter->Print( 0, " (type %s)", TO_UTF8( getLineStyleToken( aStyle ) ) );
if( !( aColor == COLOR4D::UNSPECIFIED ) )
aFormatter->Print( 0, " (color %d %d %d %s)",
KiROUND( aColor.r * 255.0 ),
KiROUND( aColor.g * 255.0 ),
KiROUND( aColor.b * 255.0 ),
Double2Str( aColor.a ).c_str() );
aFormatter->Print( 0, ")" );
}
/**
* A cache assistant for the part library portion of the #SCH_PLUGIN API, and only for the
* #SCH_SEXPR_PLUGIN, so therefore is private to this implementation file, i.e. not placed
* into a header.
*/
class SCH_SEXPR_PLUGIN_CACHE
{
static int m_modHash; // Keep track of the modification status of the library.
wxString m_fileName; // Absolute path and file name.
wxFileName m_libFileName; // Absolute path and file name is required here.
wxDateTime m_fileModTime;
LIB_PART_MAP m_symbols; // Map of names of #LIB_PART pointers.
bool m_isWritable;
bool m_isModified;
int m_versionMajor;
int m_versionMinor;
int m_libType; // Is this cache a component or symbol library.
static FILL_T parseFillMode( LINE_READER& aReader, const char* aLine,
const char** aOutput );
LIB_PART* removeSymbol( LIB_PART* aAlias );
static void saveSymbolDrawItem( LIB_ITEM* aItem, OUTPUTFORMATTER& aFormatter,
int aNestLevel );
static void saveArc( LIB_ARC* aArc, OUTPUTFORMATTER& aFormatter, int aNestLevel = 0 );
static void saveBezier( LIB_BEZIER* aBezier, OUTPUTFORMATTER& aFormatter,
int aNestLevel = 0 );
static void saveCircle( LIB_CIRCLE* aCircle, OUTPUTFORMATTER& aFormatter,
int aNestLevel = 0 );
static void saveField( LIB_FIELD* aField, OUTPUTFORMATTER& aFormatter, int aNestLevel = 0 );
static void savePin( LIB_PIN* aPin, OUTPUTFORMATTER& aFormatter, int aNestLevel = 0 );
static void savePolyLine( LIB_POLYLINE* aPolyLine, OUTPUTFORMATTER& aFormatter,
int aNestLevel = 0 );
static void saveRectangle( LIB_RECTANGLE* aRectangle, OUTPUTFORMATTER& aFormatter,
int aNestLevel = 0 );
static void saveText( LIB_TEXT* aText, OUTPUTFORMATTER& aFormatter, int aNestLevel = 0 );
static void saveDcmInfoAsFields( LIB_PART* aSymbol, OUTPUTFORMATTER& aFormatter,
int aNestLevel = 0, int aFirstId = MANDATORY_FIELDS );
friend SCH_SEXPR_PLUGIN;
public:
SCH_SEXPR_PLUGIN_CACHE( const wxString& aLibraryPath );
~SCH_SEXPR_PLUGIN_CACHE();
int GetModifyHash() const { return m_modHash; }
// Most all functions in this class throw IO_ERROR exceptions. There are no
// error codes nor user interface calls from here, nor in any SCH_PLUGIN objects.
// Catch these exceptions higher up please.
/// Save the entire library to file m_libFileName;
void Save();
void Load();
void AddSymbol( const LIB_PART* aPart );
void DeleteSymbol( const wxString& aName );
// If m_libFileName is a symlink follow it to the real source file
wxFileName GetRealFile() const;
wxDateTime GetLibModificationTime();
bool IsFile( const wxString& aFullPathAndFileName ) const;
bool IsFileChanged() const;
void SetModified( bool aModified = true ) { m_isModified = aModified; }
wxString GetLogicalName() const { return m_libFileName.GetName(); }
void SetFileName( const wxString& aFileName ) { m_libFileName = aFileName; }
wxString GetFileName() const { return m_libFileName.GetFullPath(); }
static LIB_PART* LoadPart( LINE_READER& aReader, int aMajorVersion, int aMinorVersion,
LIB_PART_MAP* aMap = nullptr );
static void SaveSymbol( LIB_PART* aSymbol, OUTPUTFORMATTER& aFormatter,
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
int aNestLevel = 0, const wxString& aLibName = wxEmptyString );
};
SCH_SEXPR_PLUGIN::SCH_SEXPR_PLUGIN()
{
init( NULL );
}
SCH_SEXPR_PLUGIN::~SCH_SEXPR_PLUGIN()
{
delete m_cache;
}
void SCH_SEXPR_PLUGIN::init( KIWAY* aKiway, const PROPERTIES* aProperties )
{
m_version = 0;
m_rootSheet = NULL;
m_props = aProperties;
m_kiway = aKiway;
m_cache = NULL;
m_out = NULL;
m_fieldId = 100; // number arbitrarily > MANDATORY_FIELDS or SHEET_MANDATORY_FIELDS
}
SCH_SHEET* SCH_SEXPR_PLUGIN::Load( const wxString& aFileName, KIWAY* aKiway,
SCH_SHEET* aAppendToMe, const PROPERTIES* aProperties )
{
wxASSERT( !aFileName || aKiway != NULL );
LOCALE_IO toggle; // toggles on, then off, the C locale.
SCH_SHEET* sheet;
wxFileName fn = aFileName;
// Unfortunately child sheet file names the legacy schematic file format are not fully
// qualified and are always appended to the project path. The aFileName attribute must
// always be an absolute path so the project path can be used for load child sheet files.
wxASSERT( fn.IsAbsolute() );
if( aAppendToMe )
{
wxLogTrace( traceSchLegacyPlugin, "Append \"%s\" to sheet \"%s\".",
aFileName, aAppendToMe->GetFileName() );
wxFileName normedFn = aAppendToMe->GetFileName();
if( !normedFn.IsAbsolute() )
{
if( aFileName.Right( normedFn.GetFullPath().Length() ) == normedFn.GetFullPath() )
m_path = aFileName.Left( aFileName.Length() - normedFn.GetFullPath().Length() );
}
if( m_path.IsEmpty() )
m_path = aKiway->Prj().GetProjectPath();
wxLogTrace( traceSchLegacyPlugin, "Normalized append path \"%s\".", m_path );
}
else
{
m_path = aKiway->Prj().GetProjectPath();
}
m_currentPath.push( m_path );
init( aKiway, aProperties );
if( aAppendToMe == NULL )
{
// Clean up any allocated memory if an exception occurs loading the schematic.
std::unique_ptr< SCH_SHEET > newSheet( new SCH_SHEET );
newSheet->SetFileName( aFileName );
m_rootSheet = newSheet.get();
loadHierarchy( newSheet.get() );
// If we got here, the schematic loaded successfully.
sheet = newSheet.release();
2020-05-05 19:12:56 +00:00
m_rootSheet = nullptr; // Quiet Coverity warning.
}
else
{
m_rootSheet = aAppendToMe->GetRootSheet();
wxASSERT( m_rootSheet != NULL );
sheet = aAppendToMe;
loadHierarchy( sheet );
}
wxASSERT( m_currentPath.size() == 1 ); // only the project path should remain
return sheet;
}
// Everything below this comment is recursive. Modify with care.
void SCH_SEXPR_PLUGIN::loadHierarchy( SCH_SHEET* aSheet )
{
SCH_SCREEN* screen = NULL;
if( !aSheet->GetScreen() )
{
// SCH_SCREEN objects store the full path and file name where the SCH_SHEET object only
// stores the file name and extension. Add the project path to the file name and
// extension to compare when calling SCH_SHEET::SearchHierarchy().
wxFileName fileName = aSheet->GetFileName();
if( !fileName.IsAbsolute() )
fileName.MakeAbsolute( m_currentPath.top() );
// Save the current path so that it gets restored when decending and ascending the
// sheet hierarchy which allows for sheet schematic files to be nested in folders
// relative to the last path a schematic was loaded from.
wxLogTrace( traceSchLegacyPlugin, "Saving path \"%s\"", m_currentPath.top() );
m_currentPath.push( fileName.GetPath() );
wxLogTrace( traceSchLegacyPlugin, "Current path \"%s\"", m_currentPath.top() );
wxLogTrace( traceSchLegacyPlugin, "Loading \"%s\"", fileName.GetFullPath() );
m_rootSheet->SearchHierarchy( fileName.GetFullPath(), &screen );
if( screen )
{
aSheet->SetScreen( screen );
// Do not need to load the sub-sheets - this has already been done.
}
else
{
aSheet->SetScreen( new SCH_SCREEN( m_kiway ) );
aSheet->GetScreen()->SetFileName( fileName.GetFullPath() );
try
{
loadFile( fileName.GetFullPath(), aSheet );
}
catch( const IO_ERROR& ioe )
{
// If there is a problem loading the root sheet, there is no recovery.
if( aSheet == m_rootSheet )
throw( ioe );
// For all subsheets, queue up the error message for the caller.
if( !m_error.IsEmpty() )
m_error += "\n";
m_error += ioe.What();
}
// This was moved out of the try{} block so that any sheets definitionsthat
// the plugin fully parsed before the exception was raised will be loaded.
for( auto aItem : aSheet->GetScreen()->Items().OfType( SCH_SHEET_T ) )
{
wxCHECK2( aItem->Type() == SCH_SHEET_T, /* do nothing */ );
auto sheet = static_cast<SCH_SHEET*>( aItem );
// Recursion starts here.
loadHierarchy( sheet );
}
}
m_currentPath.pop();
wxLogTrace( traceSchLegacyPlugin, "Restoring path \"%s\"", m_currentPath.top() );
}
}
void SCH_SEXPR_PLUGIN::loadFile( const wxString& aFileName, SCH_SHEET* aSheet )
{
FILE_LINE_READER reader( aFileName );
SCH_SEXPR_PARSER parser( &reader );
parser.ParseSchematic( aSheet );
}
void SCH_SEXPR_PLUGIN::Save( const wxString& aFileName, SCH_SHEET* aSheet, KIWAY* aKiway,
const PROPERTIES* aProperties )
{
wxCHECK_RET( aSheet != NULL, "NULL SCH_SHEET object." );
wxCHECK_RET( !aFileName.IsEmpty(), "No schematic file name defined." );
LOCALE_IO toggle; // toggles on, then off, the C locale, to write floating point values.
init( aKiway, aProperties );
wxFileName fn = aFileName;
// File names should be absolute. Don't assume everything relative to the project path
// works properly.
wxASSERT( fn.IsAbsolute() );
FILE_OUTPUTFORMATTER formatter( fn.GetFullPath() );
m_out = &formatter; // no ownership
Format( aSheet );
}
void SCH_SEXPR_PLUGIN::Format( SCH_SHEET* aSheet )
{
wxCHECK_RET( aSheet != NULL, "NULL SCH_SHEET* object." );
wxCHECK_RET( m_kiway != NULL, "NULL KIWAY* object." );
SCH_SCREEN* screen = aSheet->GetScreen();
wxCHECK( screen, /* void */ );
m_out->Print( 0, "(kicad_sch (version %d) (host eeschema %s)\n\n",
SEXPR_SCHEMATIC_FILE_VERSION,
m_out->Quotew( GetBuildVersion() ).c_str() );
// Root sheet must have a permanent UUID.
// if( aSheet->IsRootSheet() && aSheet->m_Uuid.IsLegacyTimestamp() )
// const_cast<KIID&>( aSheet->m_Uuid ).ConvertTimestampToUuid();
// m_out->Print( 1, "(uuid %s)\n\n", m_out->Quotew( aSheet->m_Uuid.AsString() ).c_str() );
screen->GetPageSettings().Format( m_out, 1, 0 );
m_out->Print( 0, "\n" );
screen->GetTitleBlock().Format( m_out, 1, 0 );
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
// Save cache library.
m_out->Print( 1, "(lib_symbols\n" );
for( auto libSymbol : screen->GetLibSymbols() )
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
SCH_SEXPR_PLUGIN_CACHE::SaveSymbol( libSymbol.second, *m_out, 2, libSymbol.first );
m_out->Print( 1, ")\n\n" );
// @todo save schematic instance information (page #).
for( const auto& alias : screen->GetBusAliases() )
{
saveBusAlias( alias, 1 );
}
// Enforce item ordering
auto cmp = []( const SCH_ITEM* a, const SCH_ITEM* b ) { return *a < *b; };
std::multiset<SCH_ITEM*, decltype( cmp )> save_map( cmp );
for( auto item : screen->Items() )
save_map.insert( item );
KICAD_T itemType = TYPE_NOT_INIT;
SCH_LAYER_ID layer = SCH_LAYER_ID_START;
for( SCH_ITEM* item : save_map )
{
if( itemType != item->Type() )
{
itemType = item->Type();
if( itemType != SCH_COMPONENT_T
&& itemType != SCH_JUNCTION_T
&& itemType != SCH_SHEET_T )
m_out->Print( 0, "\n" );
}
switch( item->Type() )
{
case SCH_COMPONENT_T:
m_out->Print( 0, "\n" );
saveSymbol( static_cast<SCH_COMPONENT*>( item ), 1 );
break;
case SCH_BITMAP_T:
saveBitmap( static_cast<SCH_BITMAP*>( item ), 1 );
break;
case SCH_SHEET_T:
m_out->Print( 0, "\n" );
saveSheet( static_cast<SCH_SHEET*>( item ), 1 );
break;
case SCH_JUNCTION_T:
saveJunction( static_cast<SCH_JUNCTION*>( item ), 1 );
break;
case SCH_NO_CONNECT_T:
saveNoConnect( static_cast<SCH_NO_CONNECT*>( item ), 1 );
break;
case SCH_BUS_WIRE_ENTRY_T:
case SCH_BUS_BUS_ENTRY_T:
saveBusEntry( static_cast<SCH_BUS_ENTRY_BASE*>( item ), 1 );
break;
case SCH_LINE_T:
if( layer != item->GetLayer() )
{
if( layer == SCH_LAYER_ID_START )
{
layer = item->GetLayer();
}
else
{
layer = item->GetLayer();
m_out->Print( 0, "\n" );
}
}
saveLine( static_cast<SCH_LINE*>( item ), 1 );
break;
case SCH_TEXT_T:
case SCH_LABEL_T:
case SCH_GLOBAL_LABEL_T:
case SCH_HIER_LABEL_T:
saveText( static_cast<SCH_TEXT*>( item ), 1 );
break;
default:
wxASSERT( "Unexpected schematic object type in SCH_SEXPR_PLUGIN::Format()" );
}
}
// If this is the root sheet, save all of the sheet paths.
if( aSheet->IsRootSheet() )
{
m_out->Print( 0, "\n" );
m_out->Print( 1, "(symbol_instances\n" );
SCH_SHEET_LIST sheetPaths( aSheet );
for( auto sheetPath : sheetPaths )
{
SCH_REFERENCE_LIST instances;
sheetPath.GetComponents( instances, true, true );
instances.SortByReferenceOnly();
for( size_t i = 0; i < instances.GetCount(); i++ )
{
m_out->Print( 2, "(path %s (reference %s) (unit %d))\n",
m_out->Quotew( instances[i].GetPath() ).c_str(),
m_out->Quotew( instances[i].GetRef() ).c_str(),
instances[i].GetUnit() );
}
}
m_out->Print( 1, ")\n" ); // Close instances token.
}
else if( screen->m_symbolInstances.size() )
{
m_out->Print( 0, "\n" );
m_out->Print( 1, "(symbol_instances\n" );
for( auto instance : screen->m_symbolInstances )
{
m_out->Print( 2, "(path %s (reference %s) (unit %d))\n",
m_out->Quotew( instance.m_Path.AsString() ).c_str(),
m_out->Quotew( instance.m_Reference ).c_str(),
instance.m_Unit );
}
m_out->Print( 1, ")\n" ); // Close instances token.
}
m_out->Print( 0, ")\n" );
}
void SCH_SEXPR_PLUGIN::Format( SELECTION* aSelection, OUTPUTFORMATTER* aFormatter )
{
m_out = aFormatter;
for( unsigned i = 0; i < aSelection->GetSize(); ++i )
{
SCH_ITEM* item = (SCH_ITEM*) aSelection->GetItem( i );
switch( item->Type() )
{
case SCH_COMPONENT_T:
saveSymbol( static_cast< SCH_COMPONENT* >( item ), 0 );
break;
case SCH_BITMAP_T:
saveBitmap( static_cast< SCH_BITMAP* >( item ), 0 );
break;
case SCH_SHEET_T:
saveSheet( static_cast< SCH_SHEET* >( item ), 0 );
break;
case SCH_JUNCTION_T:
saveJunction( static_cast< SCH_JUNCTION* >( item ), 0 );
break;
case SCH_NO_CONNECT_T:
saveNoConnect( static_cast< SCH_NO_CONNECT* >( item ), 0 );
break;
case SCH_BUS_WIRE_ENTRY_T:
case SCH_BUS_BUS_ENTRY_T:
saveBusEntry( static_cast< SCH_BUS_ENTRY_BASE* >( item ), 0 );
break;
case SCH_LINE_T:
saveLine( static_cast< SCH_LINE* >( item ), 0 );
break;
case SCH_TEXT_T:
case SCH_LABEL_T:
case SCH_GLOBAL_LABEL_T:
case SCH_HIER_LABEL_T:
saveText( static_cast< SCH_TEXT* >( item ), 0 );
break;
default:
wxASSERT( "Unexpected schematic object type in SCH_SEXPR_PLUGIN::Format()" );
}
}
}
void SCH_SEXPR_PLUGIN::saveSymbol( SCH_COMPONENT* aSymbol, int aNestLevel )
{
wxCHECK_RET( aSymbol != nullptr && m_out != nullptr, "" );
std::string libName;
wxArrayString reference_fields;
static wxString delimiters( wxT( " " ) );
wxString part_name = aSymbol->GetLibId().Format();
if( part_name.size() )
{
libName = toUTFTildaText( part_name );
}
else
{
libName = "_NONAME_";
}
double angle;
int orientation = aSymbol->GetOrientation() & ~( CMP_MIRROR_X | CMP_MIRROR_Y );
if( orientation == CMP_ORIENT_90 )
angle = 90.0;
else if( orientation == CMP_ORIENT_180 )
angle = 180.0;
else if( orientation == CMP_ORIENT_270 )
angle = 270.0;
else
angle = 0.0;
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_out->Print( aNestLevel, "(symbol" );
if( !aSymbol->UseLibIdLookup() )
m_out->Print( 0, " (lib_name %s)",
m_out->Quotew( aSymbol->GetSchSymbolLibraryName() ).c_str() );
m_out->Print( 0, " (lib_id %s) (at %s %s %s)",
m_out->Quotew( aSymbol->GetLibId().Format().wx_str() ).c_str(),
FormatInternalUnits( aSymbol->GetPosition().x ).c_str(),
FormatInternalUnits( aSymbol->GetPosition().y ).c_str(),
FormatAngle( angle * 10.0 ).c_str() );
bool mirrorX = aSymbol->GetOrientation() & CMP_MIRROR_X;
bool mirrorY = aSymbol->GetOrientation() & CMP_MIRROR_Y;
if( mirrorX || mirrorY )
{
m_out->Print( 0, " (mirror" );
if( mirrorX )
m_out->Print( 0, " x" );
if( mirrorY )
m_out->Print( 0, " y" );
m_out->Print( 0, ")" );
}
if( !( aSymbol->GetInstanceReferences().size() > 1 ) )
m_out->Print( 0, " (unit %d)", aSymbol->GetUnit() );
if( aSymbol->GetConvert() == LIB_ITEM::LIB_CONVERT::DEMORGAN )
m_out->Print( 0, " (convert %d)", aSymbol->GetConvert() );
m_out->Print( 0, "\n" );
// @todo Convert to full UUID if current UUID is a legacy time stamp.
m_out->Print( aNestLevel + 1, "(uuid %s)\n",
m_out->Quotew( aSymbol->m_Uuid.AsString() ).c_str() );
m_fieldId = MANDATORY_FIELDS;
for( SCH_FIELD& field : aSymbol->GetFields() )
{
saveField( &field, aNestLevel + 1 );
}
m_out->Print( aNestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN::saveField( SCH_FIELD* aField, int aNestLevel )
{
wxCHECK_RET( aField != nullptr && m_out != nullptr, "" );
wxString fieldName = aField->GetName();
// For some reason (bug in legacy parser?) the field ID for non-mandatory fields is -1 so
// check for this in order to correctly use the field name.
if( aField->GetParent()->Type() == SCH_COMPONENT_T )
{
if( aField->GetId() >= 0 && aField->GetId() < MANDATORY_FIELDS )
fieldName = TEMPLATE_FIELDNAME::GetDefaultFieldName( aField->GetId() );
}
else if( aField->GetParent()->Type() == SCH_SHEET_T )
{
if( aField->GetId() >= 0 && aField->GetId() < SHEET_MANDATORY_FIELDS )
fieldName = SCH_SHEET::GetDefaultFieldName( aField->GetId() );
}
if( aField->GetId() == -1 /* undefined ID */ )
{
aField->SetId( m_fieldId );
m_fieldId += 1;
}
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_out->Print( aNestLevel, "(property %s %s (id %d) (at %s %s %s)",
m_out->Quotew( fieldName ).c_str(),
m_out->Quotew( aField->GetText() ).c_str(),
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
aField->GetId(),
FormatInternalUnits( aField->GetPosition().x ).c_str(),
FormatInternalUnits( aField->GetPosition().y ).c_str(),
FormatAngle( aField->GetTextAngleDegrees() * 10.0 ).c_str() );
if( !aField->IsDefaultFormatting()
|| ( aField->GetTextHeight() != Mils2iu( DEFAULT_SIZE_TEXT ) ) )
{
m_out->Print( 0, "\n" );
aField->Format( m_out, aNestLevel, 0 );
m_out->Print( aNestLevel, ")\n" ); // Closes property token with font effects.
}
else
{
m_out->Print( 0, ")\n" ); // Closes property token without font effects.
}
}
void SCH_SEXPR_PLUGIN::saveBitmap( SCH_BITMAP* aBitmap, int aNestLevel )
{
wxCHECK_RET( aBitmap != nullptr && m_out != nullptr, "" );
const wxImage* image = aBitmap->GetImage()->GetImageData();
wxCHECK_RET( image != NULL, "wxImage* is NULL" );
m_out->Print( aNestLevel, "(image (at %s %s)",
FormatInternalUnits( aBitmap->GetPosition().x ).c_str(),
FormatInternalUnits( aBitmap->GetPosition().y ).c_str() );
if( aBitmap->GetImage()->GetScale() != 1.0 )
m_out->Print( 0, " (scale %g)", aBitmap->GetImage()->GetScale() );
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel + 1, "(data" );
wxMemoryOutputStream stream;
image->SaveFile( stream, wxBITMAP_TYPE_PNG );
// Write binary data in hexadecimal form (ASCII)
wxStreamBuffer* buffer = stream.GetOutputStreamBuffer();
wxString out = wxBase64Encode( buffer->GetBufferStart(), buffer->GetBufferSize() );
// Apparently the MIME standard character width for base64 encoding is 76 (unconfirmed)
// so use it in a vein attempt to be standard like.
#define MIME_BASE64_LENGTH 76
size_t first = 0;
while( first < out.Length() )
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel + 2, "%s", TO_UTF8( out( first, MIME_BASE64_LENGTH ) ) );
first += MIME_BASE64_LENGTH;
}
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel + 1, ")\n" ); // Closes data token.
m_out->Print( aNestLevel, ")\n" ); // Closes image token.
}
void SCH_SEXPR_PLUGIN::saveSheet( SCH_SHEET* aSheet, int aNestLevel )
{
wxCHECK_RET( aSheet != nullptr && m_out != nullptr, "" );
m_out->Print( aNestLevel, "(sheet (at %s %s) (size %s %s)\n",
FormatInternalUnits( aSheet->GetPosition().x ).c_str(),
FormatInternalUnits( aSheet->GetPosition().y ).c_str(),
FormatInternalUnits( aSheet->GetSize().GetWidth() ).c_str(),
FormatInternalUnits( aSheet->GetSize().GetHeight() ).c_str() );
if( !aSheet->UsesDefaultStroke() )
{
formatStroke( m_out, aNestLevel + 1, aSheet->GetBorderWidth(), PLOT_DASH_TYPE::SOLID,
aSheet->GetBorderColor() );
m_out->Print( 0, "\n" );
}
if( !( aSheet->GetBackgroundColor() == COLOR4D::UNSPECIFIED ) )
{
m_out->Print( aNestLevel + 1, "(fill (color %d %d %d %0.4f))",
KiROUND( aSheet->GetBackgroundColor().r * 255.0 ),
KiROUND( aSheet->GetBackgroundColor().g * 255.0 ),
KiROUND( aSheet->GetBackgroundColor().b * 255.0 ),
aSheet->GetBackgroundColor().a );
m_out->Print( 0, "\n" );
}
m_out->Print( aNestLevel + 1, "(uuid %s)", TO_UTF8( aSheet->m_Uuid.AsString() ) );
m_out->Print( 0, "\n" );
m_fieldId = SHEET_MANDATORY_FIELDS;
2020-05-06 15:55:37 +00:00
for( SCH_FIELD& field : aSheet->GetFields() )
{
2020-05-06 15:55:37 +00:00
saveField( &field, aNestLevel + 1 );
}
for( const SCH_SHEET_PIN* pin : aSheet->GetPins() )
{
m_out->Print( aNestLevel + 1, "(pin %s %s (at %s %s %s)",
EscapedUTF8( pin->GetText() ).c_str(),
getSheetPinShapeToken( pin->GetShape() ),
FormatInternalUnits( pin->GetPosition().x ).c_str(),
FormatInternalUnits( pin->GetPosition().y ).c_str(),
FormatAngle( getSheetPinAngle( pin->GetEdge() ) * 10.0 ).c_str() );
if( !pin->IsDefaultFormatting()
|| ( pin->GetTextHeight() != Mils2iu( DEFAULT_SIZE_TEXT ) ) )
{
m_out->Print( 0, "\n" );
pin->Format( m_out, aNestLevel + 1, 0 );
m_out->Print( aNestLevel + 1, ")\n" ); // Closes pin token with font effects.
}
else
{
m_out->Print( 0, ")\n" ); // Closes pin token without font effects.
}
}
m_out->Print( aNestLevel, ")\n" ); // Closes sheet token.
}
void SCH_SEXPR_PLUGIN::saveJunction( SCH_JUNCTION* aJunction, int aNestLevel )
{
wxCHECK_RET( aJunction != nullptr && m_out != nullptr, "" );
m_out->Print( aNestLevel, "(junction (at %s %s))\n",
FormatInternalUnits( aJunction->GetPosition().x ).c_str(),
FormatInternalUnits( aJunction->GetPosition().y ).c_str() );
}
void SCH_SEXPR_PLUGIN::saveNoConnect( SCH_NO_CONNECT* aNoConnect, int aNestLevel )
{
wxCHECK_RET( aNoConnect != nullptr && m_out != nullptr, "" );
m_out->Print( aNestLevel, "(no_connect (at %s %s))\n",
FormatInternalUnits( aNoConnect->GetPosition().x ).c_str(),
FormatInternalUnits( aNoConnect->GetPosition().y ).c_str() );
}
void SCH_SEXPR_PLUGIN::saveBusEntry( SCH_BUS_ENTRY_BASE* aBusEntry, int aNestLevel )
{
wxCHECK_RET( aBusEntry != nullptr && m_out != nullptr, "" );
// Bus to bus entries are converted to bus line segments.
if( aBusEntry->GetClass() == "SCH_BUS_BUS_ENTRY" )
{
SCH_LINE busEntryLine( aBusEntry->GetPosition(), LAYER_BUS );
busEntryLine.SetEndPoint( aBusEntry->m_End() );
saveLine( &busEntryLine, aNestLevel );
}
else
{
m_out->Print( aNestLevel, "(bus_entry (at %s %s) (size %s %s))\n",
FormatInternalUnits( aBusEntry->GetPosition().x ).c_str(),
FormatInternalUnits( aBusEntry->GetPosition().y ).c_str(),
FormatInternalUnits( aBusEntry->GetSize().GetWidth() ).c_str(),
FormatInternalUnits( aBusEntry->GetSize().GetHeight() ).c_str() );
}
}
void SCH_SEXPR_PLUGIN::saveLine( SCH_LINE* aLine, int aNestLevel )
{
wxCHECK_RET( aLine != nullptr && m_out != nullptr, "" );
wxString lineType;
switch( aLine->GetLayer() )
{
case LAYER_BUS: lineType = "bus"; break;
case LAYER_WIRE: lineType = "wire"; break;
case LAYER_NOTES:
default: lineType = "polyline"; break;
}
m_out->Print( aNestLevel, "(%s (pts (xy %s %s) (xy %s %s))",
TO_UTF8( lineType ),
FormatInternalUnits( aLine->GetStartPoint().x ).c_str(),
FormatInternalUnits( aLine->GetStartPoint().y ).c_str(),
FormatInternalUnits( aLine->GetEndPoint().x ).c_str(),
FormatInternalUnits( aLine->GetEndPoint().y ).c_str() );
if( !aLine->UsesDefaultStroke() )
{
m_out->Print( 0, " " );
formatStroke( m_out, 0, aLine->GetLineSize(), aLine->GetLineStyle(),
aLine->GetLineColor() );
}
m_out->Print( 0, ")\n" );
}
void SCH_SEXPR_PLUGIN::saveText( SCH_TEXT* aText, int aNestLevel )
{
wxCHECK_RET( aText != nullptr && m_out != nullptr, "" );
double angle;
switch( aText->GetLabelSpinStyle() )
{
case LABEL_SPIN_STYLE::RIGHT: angle = 0.0; break;
case LABEL_SPIN_STYLE::UP: angle = 90.0; break;
case LABEL_SPIN_STYLE::LEFT: angle = 180.0; break;
case LABEL_SPIN_STYLE::BOTTOM: angle = 270.0; break;
default: wxFAIL; angle = 0.0; break;
}
m_out->Print( aNestLevel, "(%s %s",
getTextTypeToken( aText->Type() ),
m_out->Quotew( aText->GetText() ).c_str() );
if( ( aText->Type() == SCH_GLOBAL_LABEL_T ) || ( aText->Type() == SCH_HIER_LABEL_T ) )
m_out->Print( 0, " (shape %s)", getSheetPinShapeToken( aText->GetShape() ) );
if( aText->GetText().Length() < 50 )
{
m_out->Print( 0, " (at %s %s %s)",
FormatInternalUnits( aText->GetPosition().x ).c_str(),
FormatInternalUnits( aText->GetPosition().y ).c_str(),
FormatAngle( angle * 10.0 ).c_str() );
}
else
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel + 1, "(at %s %s %s)",
FormatInternalUnits( aText->GetPosition().x ).c_str(),
FormatInternalUnits( aText->GetPosition().y ).c_str(),
FormatAngle( aText->GetTextAngle() ).c_str() );
}
if( !aText->IsDefaultFormatting()
|| ( aText->GetTextHeight() != Mils2iu( DEFAULT_SIZE_TEXT ) ) )
{
m_out->Print( 0, "\n" );
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
aText->Format( m_out, aNestLevel, 0 );
m_out->Print( aNestLevel, ")\n" ); // Closes text token with font effects.
}
else
{
m_out->Print( 0, ")\n" ); // Closes text token without font effects.
}
}
void SCH_SEXPR_PLUGIN::saveBusAlias( std::shared_ptr<BUS_ALIAS> aAlias, int aNestLevel )
{
wxCHECK_RET( aAlias != NULL, "BUS_ALIAS* is NULL" );
wxString members;
for( auto member : aAlias->Members() )
{
if( members.IsEmpty() )
members = m_out->Quotew( member );
else
members += " " + m_out->Quotew( member );
}
m_out->Print( aNestLevel, "(bus_alias %s (members %s))\n",
m_out->Quotew( aAlias->GetName() ).c_str(),
TO_UTF8( members ) );
}
int SCH_SEXPR_PLUGIN_CACHE::m_modHash = 1; // starts at 1 and goes up
SCH_SEXPR_PLUGIN_CACHE::SCH_SEXPR_PLUGIN_CACHE( const wxString& aFullPathAndFileName ) :
m_fileName( aFullPathAndFileName ),
m_libFileName( aFullPathAndFileName ),
m_isWritable( true ),
m_isModified( false )
{
m_versionMajor = -1;
m_versionMinor = -1;
m_libType = LIBRARY_TYPE_EESCHEMA;
}
SCH_SEXPR_PLUGIN_CACHE::~SCH_SEXPR_PLUGIN_CACHE()
{
// When the cache is destroyed, all of the alias objects on the heap should be deleted.
for( LIB_PART_MAP::iterator it = m_symbols.begin(); it != m_symbols.end(); ++it )
delete it->second;
m_symbols.clear();
}
// If m_libFileName is a symlink follow it to the real source file
wxFileName SCH_SEXPR_PLUGIN_CACHE::GetRealFile() const
{
wxFileName fn( m_libFileName );
#ifndef __WINDOWS__
if( fn.Exists( wxFILE_EXISTS_SYMLINK ) )
{
char buffer[ PATH_MAX + 1 ];
ssize_t pathLen = readlink( TO_UTF8( fn.GetFullPath() ), buffer, PATH_MAX );
if( pathLen > 0 )
{
buffer[ pathLen ] = '\0';
fn.Assign( fn.GetPath() + wxT( "/" ) + wxString::FromUTF8( buffer ) );
fn.Normalize();
}
}
#endif
return fn;
}
wxDateTime SCH_SEXPR_PLUGIN_CACHE::GetLibModificationTime()
{
wxFileName fn = GetRealFile();
// update the writable flag while we have a wxFileName, in a network this
// is possibly quite dynamic anyway.
m_isWritable = fn.IsFileWritable();
return fn.GetModificationTime();
}
bool SCH_SEXPR_PLUGIN_CACHE::IsFile( const wxString& aFullPathAndFileName ) const
{
return m_fileName == aFullPathAndFileName;
}
bool SCH_SEXPR_PLUGIN_CACHE::IsFileChanged() const
{
wxFileName fn = GetRealFile();
if( m_fileModTime.IsValid() && fn.IsOk() && fn.FileExists() )
return fn.GetModificationTime() != m_fileModTime;
return false;
}
LIB_PART* SCH_SEXPR_PLUGIN_CACHE::removeSymbol( LIB_PART* aPart )
{
wxCHECK_MSG( aPart != NULL, NULL, "NULL pointer cannot be removed from library." );
LIB_PART* firstChild = NULL;
LIB_PART_MAP::iterator it = m_symbols.find( aPart->GetName() );
if( it == m_symbols.end() )
return NULL;
// If the entry pointer doesn't match the name it is mapped to in the library, we
// have done something terribly wrong.
wxCHECK_MSG( *it->second == aPart, NULL,
"Pointer mismatch while attempting to remove alias entry <" + aPart->GetName() +
"> from library cache <" + m_libFileName.GetName() + ">." );
// If the symbol is a root symbol used by other symbols find the first alias that uses
// the root part and make it the new root.
if( aPart->IsRoot() )
{
for( auto entry : m_symbols )
{
if( entry.second->IsAlias()
&& entry.second->GetParent().lock() == aPart->SharedPtr() )
{
firstChild = entry.second;
break;
}
}
if( firstChild )
{
for( LIB_ITEM& drawItem : aPart->GetDrawItems() )
{
if( drawItem.Type() == LIB_FIELD_T )
{
LIB_FIELD& field = static_cast<LIB_FIELD&>( drawItem );
if( firstChild->FindField( field.GetCanonicalName() ) )
continue;
}
LIB_ITEM* newItem = (LIB_ITEM*) drawItem.Clone();
drawItem.SetParent( firstChild );
firstChild->AddDrawItem( newItem );
}
// Reparent the remaining aliases.
for( auto entry : m_symbols )
{
if( entry.second->IsAlias()
&& entry.second->GetParent().lock() == aPart->SharedPtr() )
entry.second->SetParent( firstChild );
}
}
}
m_symbols.erase( it );
delete aPart;
m_isModified = true;
++m_modHash;
return firstChild;
}
void SCH_SEXPR_PLUGIN_CACHE::AddSymbol( const LIB_PART* aPart )
{
// aPart is cloned in PART_LIB::AddPart(). The cache takes ownership of aPart.
wxString name = aPart->GetName();
LIB_PART_MAP::iterator it = m_symbols.find( name );
if( it != m_symbols.end() )
{
removeSymbol( it->second );
}
m_symbols[ name ] = const_cast< LIB_PART* >( aPart );
m_isModified = true;
++m_modHash;
}
void SCH_SEXPR_PLUGIN_CACHE::Load()
{
if( !m_libFileName.FileExists() )
{
THROW_IO_ERROR( wxString::Format( _( "Library file \"%s\" not found." ),
m_libFileName.GetFullPath() ) );
}
wxCHECK_RET( m_libFileName.IsAbsolute(),
wxString::Format( "Cannot use relative file paths in sexpr plugin to "
"open library \"%s\".", m_libFileName.GetFullPath() ) );
wxLogTrace( traceSchLegacyPlugin, "Loading sexpr symbol library file \"%s\"",
m_libFileName.GetFullPath() );
FILE_LINE_READER reader( m_libFileName.GetFullPath() );
SCH_SEXPR_PARSER parser( &reader );
parser.ParseLib( m_symbols );
++m_modHash;
// Remember the file modification time of library file when the
// cache snapshot was made, so that in a networked environment we will
// reload the cache as needed.
m_fileModTime = GetLibModificationTime();
}
LIB_PART* SCH_SEXPR_PLUGIN_CACHE::LoadPart( LINE_READER& aReader, int aMajorVersion,
int aMinorVersion, LIB_PART_MAP* aMap )
{
std::unique_ptr< LIB_PART > part( new LIB_PART( wxEmptyString ) );
return part.release();
}
void SCH_SEXPR_PLUGIN_CACHE::Save()
{
if( !m_isModified )
return;
LOCALE_IO toggle; // toggles on, then off, the C locale.
// Write through symlinks, don't replace them.
wxFileName fn = GetRealFile();
std::unique_ptr< FILE_OUTPUTFORMATTER > formatter( new FILE_OUTPUTFORMATTER( fn.GetFullPath() ) );
formatter->Print( 0, "(kicad_symbol_lib (version %d) (host kicad_symbol_editor %s)\n",
SEXPR_SYMBOL_LIB_FILE_VERSION,
formatter->Quotew( GetBuildVersion() ).c_str() );
for( auto parent : m_symbols )
{
// Save the root symbol first so alias can inherit from them.
if( parent.second->IsRoot() )
{
SaveSymbol( parent.second, *formatter.get(), 1 );
// Save all of the aliases associated with the current root symbol.
for( auto alias : m_symbols )
{
if( !alias.second->IsAlias() )
continue;
std::shared_ptr<LIB_PART> aliasParent = alias.second->GetParent().lock();
if( aliasParent.get() != parent.second )
continue;
SaveSymbol( alias.second, *formatter.get(), 1 );
}
}
}
formatter->Print( 0, ")\n" );
formatter.reset();
m_fileModTime = fn.GetModificationTime();
m_isModified = false;
}
void SCH_SEXPR_PLUGIN_CACHE::SaveSymbol( LIB_PART* aSymbol, OUTPUTFORMATTER& aFormatter,
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
int aNestLevel, const wxString& aLibName )
{
wxCHECK_RET( aSymbol, "Invalid LIB_PART pointer." );
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
std::string name = aFormatter.Quotew( aSymbol->GetLibId().Format().wx_str() );
std::string unitName = aSymbol->GetLibId().GetLibItemName();
if( !aLibName.IsEmpty() )
{
name = aFormatter.Quotew( aLibName );
LIB_ID unitId;
wxCHECK2( unitId.Parse( aLibName, LIB_ID::ID_SCH ) < 0, /* do nothing */ );
unitName = unitId.GetLibItemName();
}
if( aSymbol->IsRoot() )
{
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
aFormatter.Print( aNestLevel, "(symbol %s", name.c_str() );
if( aSymbol->IsPower() )
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
aFormatter.Print( 0, " (power)" );
// TODO: add uuid token here.
// TODO: add anchor position token here.
if( !aSymbol->ShowPinNumbers() )
aFormatter.Print( 0, " (pin_numbers hide)" );
if( aSymbol->GetPinNameOffset() != Mils2iu( DEFAULT_PIN_NAME_OFFSET )
|| !aSymbol->ShowPinNames() )
{
aFormatter.Print( 0, " (pin_names" );
if( aSymbol->GetPinNameOffset() != Mils2iu( DEFAULT_PIN_NAME_OFFSET ) )
aFormatter.Print( 0, " (offset %s)",
FormatInternalUnits( aSymbol->GetPinNameOffset() ).c_str() );
if( !aSymbol->ShowPinNames() )
aFormatter.Print( 0, " hide" );
aFormatter.Print( 0, ")" );
}
// TODO: add atomic token here.
// TODO: add required token here."
aFormatter.Print( 0, "\n" );
LIB_FIELDS fields;
aSymbol->GetFields( fields );
for( auto field : fields )
saveField( &field, aFormatter, aNestLevel + 1 );
int lastFieldId = fields.back().GetId() + 1;
// @todo At some point in the future the lock status (all units interchangeable) should
// be set deterministically. For now a custom lock properter is used to preserve the
// locked flag state.
if( aSymbol->UnitsLocked() )
{
LIB_FIELD locked( lastFieldId, "ki_locked" );
saveField( &locked, aFormatter, aNestLevel + 1 );
lastFieldId += 1;
}
saveDcmInfoAsFields( aSymbol, aFormatter, aNestLevel, lastFieldId );
// Save the draw items grouped by units.
std::vector<PART_UNITS> units = aSymbol->GetUnitDrawItems();
for( auto unit : units )
{
aFormatter.Print( aNestLevel + 1, "(symbol \"%s_%d_%d\"\n",
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
unitName.c_str(), unit.m_unit, unit.m_convert );
for( auto item : unit.m_items )
saveSymbolDrawItem( item, aFormatter, aNestLevel + 2 );
aFormatter.Print( aNestLevel + 1, ")\n" );
}
}
else
{
std::shared_ptr<LIB_PART> parent = aSymbol->GetParent().lock();
wxASSERT( parent );
aFormatter.Print( aNestLevel, "(symbol %s (extends %s)\n",
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
name.c_str(),
aFormatter.Quotew( parent->GetName() ).c_str() );
LIB_FIELD tmp = parent->GetValueField();
tmp.SetText( aSymbol->GetName() );
saveField( &tmp, aFormatter, aNestLevel + 1 );
if( !aSymbol->GetDocFileName().IsEmpty() )
{
tmp = *aSymbol->GetField( DATASHEET );
tmp.SetText( aSymbol->GetDocFileName() );
saveField( &tmp, aFormatter, aNestLevel + 1 );
}
saveDcmInfoAsFields( aSymbol, aFormatter, aNestLevel, MANDATORY_FIELDS );
}
aFormatter.Print( aNestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::saveDcmInfoAsFields( LIB_PART* aSymbol, OUTPUTFORMATTER& aFormatter,
int aNestLevel, int aFirstId )
{
wxCHECK_RET( aSymbol, "Invalid LIB_PART pointer." );
int id = aFirstId;
if( !aSymbol->GetKeyWords().IsEmpty() )
{
LIB_FIELD keywords( id, wxString( "ki_keywords" ) );
keywords.SetVisible( false );
keywords.SetText( aSymbol->GetKeyWords() );
saveField( &keywords, aFormatter, aNestLevel + 1 );
id += 1;
}
if( !aSymbol->GetDescription().IsEmpty() )
{
LIB_FIELD description( id, wxString( "ki_description" ) );
description.SetVisible( false );
description.SetText( aSymbol->GetDescription() );
saveField( &description, aFormatter, aNestLevel + 1 );
id += 1;
}
wxArrayString fpFilters = aSymbol->GetFootprints();
if( !fpFilters.IsEmpty() )
{
wxString tmp;
for( auto filter : fpFilters )
{
if( tmp.IsEmpty() )
tmp = filter;
else
tmp += "\n" + filter;
}
LIB_FIELD description( id, wxString( "ki_fp_filters" ) );
description.SetVisible( false );
description.SetText( tmp );
saveField( &description, aFormatter, aNestLevel + 1 );
id += 1;
}
}
void SCH_SEXPR_PLUGIN_CACHE::saveSymbolDrawItem( LIB_ITEM* aItem, OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aItem, "Invalid LIB_ITEM pointer." );
switch( aItem->Type() )
{
case LIB_ARC_T:
saveArc( (LIB_ARC*) aItem, aFormatter, aNestLevel );
break;
case LIB_BEZIER_T:
saveBezier( (LIB_BEZIER*) aItem, aFormatter, aNestLevel );
break;
case LIB_CIRCLE_T:
saveCircle( ( LIB_CIRCLE* ) aItem, aFormatter, aNestLevel );
break;
case LIB_PIN_T:
savePin( (LIB_PIN* ) aItem, aFormatter, aNestLevel );
break;
case LIB_POLYLINE_T:
savePolyLine( ( LIB_POLYLINE* ) aItem, aFormatter, aNestLevel );
break;
case LIB_RECTANGLE_T:
saveRectangle( ( LIB_RECTANGLE* ) aItem, aFormatter, aNestLevel );
break;
case LIB_TEXT_T:
saveText( ( LIB_TEXT* ) aItem, aFormatter, aNestLevel );
break;
default:
;
}
}
void SCH_SEXPR_PLUGIN_CACHE::saveArc( LIB_ARC* aArc,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aArc && aArc->Type() == LIB_ARC_T, "Invalid LIB_ARC object." );
int x1 = aArc->GetFirstRadiusAngle();
if( x1 > 1800 )
x1 -= 3600;
int x2 = aArc->GetSecondRadiusAngle();
if( x2 > 1800 )
x2 -= 3600;
aFormatter.Print( aNestLevel,
"(arc (start %s %s) (end %s %s) (radius (at %s %s) (length %s) "
"(angles %g %g))",
FormatInternalUnits( aArc->GetStart().x ).c_str(),
FormatInternalUnits( aArc->GetStart().y ).c_str(),
FormatInternalUnits( aArc->GetEnd().x ).c_str(),
FormatInternalUnits( aArc->GetEnd().y ).c_str(),
FormatInternalUnits( aArc->GetPosition().x ).c_str(),
FormatInternalUnits( aArc->GetPosition().y ).c_str(),
FormatInternalUnits( aArc->GetRadius() ).c_str(),
static_cast<double>( x1 ) / 10.0,
static_cast<double>( x2 ) / 10.0 );
bool needsSpace = false;
bool onNewLine = false;
if( aArc->GetWidth() != 0 && aArc->GetWidth() != Mils2iu( DEFAULT_LINE_THICKNESS ) )
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 1, "(stroke (width %s))",
FormatInternalUnits( aArc->GetWidth() ).c_str() );
needsSpace = true;
onNewLine = true;
}
if( aArc->GetFillMode() != NO_FILL )
{
if( !onNewLine || needsSpace )
aFormatter.Print( 0, " " );
formatFill( static_cast< LIB_ITEM* >( aArc ), aFormatter, 0 );
}
if( onNewLine )
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel, ")\n" );
}
else
{
aFormatter.Print( 0, ")\n" );
}
}
void SCH_SEXPR_PLUGIN_CACHE::saveBezier( LIB_BEZIER* aBezier,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aBezier && aBezier->Type() == LIB_BEZIER_T, "Invalid LIB_BEZIER object." );
int newLine = 0;
int lineCount = 1;
aFormatter.Print( aNestLevel, "(bezier\n" );
aFormatter.Print( aNestLevel + 1, "(pts " );
for( const auto& pt : aBezier->GetPoints() )
{
if( newLine == 4 )
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 3, " (xy %s %s)",
FormatInternalUnits( pt.x ).c_str(),
FormatInternalUnits( pt.y ).c_str() );
newLine = 0;
lineCount += 1;
}
else
{
aFormatter.Print( 0, " (xy %s %s)",
FormatInternalUnits( pt.x ).c_str(),
FormatInternalUnits( pt.y ).c_str() );
}
newLine += 1;
}
if( lineCount == 1 )
{
aFormatter.Print( 0, ")\n" ); // Closes pts token on same line.
}
else
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 1, ")\n" ); // Closes pts token with multiple lines.
}
bool needsSpace = false;
if( aBezier->GetWidth() != 0 && aBezier->GetWidth() != Mils2iu( DEFAULT_LINE_THICKNESS ) )
{
aFormatter.Print( aNestLevel + 1, "(stroke (width %s))",
FormatInternalUnits( aBezier->GetWidth() ).c_str() );
needsSpace = true;
if( aBezier->GetFillMode() == NO_FILL )
aFormatter.Print( 0, "\n" );
}
if( aBezier->GetFillMode() != NO_FILL )
{
if( needsSpace )
{
aFormatter.Print( 0, " " );
formatFill( static_cast< LIB_ITEM* >( aBezier ), aFormatter, 0 );
}
else
{
formatFill( static_cast< LIB_ITEM* >( aBezier ), aFormatter, aNestLevel + 1 );
}
aFormatter.Print( 0, "\n" );
}
aFormatter.Print( aNestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::saveCircle( LIB_CIRCLE* aCircle,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aCircle && aCircle->Type() == LIB_CIRCLE_T, "Invalid LIB_CIRCLE object." );
aFormatter.Print( aNestLevel, "(circle (center %s %s) (radius %s)",
FormatInternalUnits( aCircle->GetPosition().x ).c_str(),
FormatInternalUnits( aCircle->GetPosition().y ).c_str(),
FormatInternalUnits( aCircle->GetRadius() ).c_str() );
if( aCircle->GetWidth() != 0 && aCircle->GetWidth() != Mils2iu( DEFAULT_LINE_THICKNESS ) )
{
aFormatter.Print( 0, " (stroke (width %s))",
FormatInternalUnits( aCircle->GetWidth() ).c_str() );
}
if( aCircle->GetFillMode() != NO_FILL )
{
aFormatter.Print( 0, " " );
formatFill( static_cast< LIB_ITEM* >( aCircle ), aFormatter, 0 );
}
aFormatter.Print( 0, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::saveField( LIB_FIELD* aField,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aField && aField->Type() == LIB_FIELD_T, "Invalid LIB_FIELD object." );
aFormatter.Print( aNestLevel, "(property %s %s (id %d) (at %s %s %g)",
aFormatter.Quotew( aField->GetName() ).c_str(),
aFormatter.Quotew( aField->GetText() ).c_str(),
aField->GetId(),
FormatInternalUnits( aField->GetPosition().x ).c_str(),
FormatInternalUnits( aField->GetPosition().y ).c_str(),
static_cast<double>( aField->GetTextAngle() ) / 10.0 );
if( aField->IsDefaultFormatting()
&& ( aField->GetTextHeight() == Mils2iu( DEFAULT_SIZE_TEXT ) ) )
{
aFormatter.Print( 0, ")\n" ); // Close property token if no font effects.
}
else
{
aFormatter.Print( 0, "\n" );
aField->Format( &aFormatter, aNestLevel, 0 );
aFormatter.Print( aNestLevel, ")\n" ); // Close property token.
}
}
void SCH_SEXPR_PLUGIN_CACHE::savePin( LIB_PIN* aPin,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aPin && aPin->Type() == LIB_PIN_T, "Invalid LIB_PIN object." );
aPin->ClearFlags( IS_CHANGED );
aFormatter.Print( aNestLevel, "(pin %s %s (at %s %s %s) (length %s)",
getPinElectricalTypeToken( aPin->GetType() ),
getPinShapeToken( aPin->GetShape() ),
FormatInternalUnits( aPin->GetPosition().x ).c_str(),
FormatInternalUnits( aPin->GetPosition().y ).c_str(),
FormatAngle( getPinAngle( aPin->GetOrientation() ) * 10.0 ).c_str(),
FormatInternalUnits( aPin->GetLength() ).c_str() );
int nestLevel = 0;
if( aPin->GetNameTextSize() != Mils2iu( DEFAULT_PINNAME_SIZE )
|| aPin->GetNumberTextSize() != Mils2iu( DEFAULT_PINNUM_SIZE ) )
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 1, "(name %s",
aFormatter.Quotew( aPin->GetName() ).c_str() );
// This follows the EDA_TEXT effects formatting for future expansion.
if( aPin->GetNameTextSize() != Mils2iu( DEFAULT_PINNAME_SIZE ) )
aFormatter.Print( 0, " (effects (font (size %s %s)))",
FormatInternalUnits( aPin->GetNameTextSize() ).c_str(),
FormatInternalUnits( aPin->GetNameTextSize() ).c_str() );
aFormatter.Print( 0, ")\n" );
aFormatter.Print( aNestLevel + 1, "(number %s",
aFormatter.Quotew( aPin->GetNumber() ).c_str() );
// This follows the EDA_TEXT effects formatting for future expansion.
if( aPin->GetNumberTextSize() != Mils2iu( DEFAULT_PINNUM_SIZE ) )
aFormatter.Print( 0, " (effects (font (size %s %s)))",
FormatInternalUnits( aPin->GetNumberTextSize() ).c_str(),
FormatInternalUnits( aPin->GetNumberTextSize() ).c_str() );
aFormatter.Print( 0, ")\n" );
nestLevel = aNestLevel + 1;
}
else
{
aFormatter.Print( 0, " (name %s) (number %s)",
aFormatter.Quotew( aPin->GetName() ).c_str(),
aFormatter.Quotew( aPin->GetNumber() ).c_str() );
}
if( !aPin->IsVisible() )
aFormatter.Print( nestLevel, " hide" );
if( nestLevel )
nestLevel -= 1;
aFormatter.Print( nestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::savePolyLine( LIB_POLYLINE* aPolyLine,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aPolyLine && aPolyLine->Type() == LIB_POLYLINE_T, "Invalid LIB_POLYLINE object." );
int newLine = 0;
int lineCount = 1;
aFormatter.Print( aNestLevel, "(polyline\n" );
aFormatter.Print( aNestLevel + 1, "(pts" );
for( const auto& pt : aPolyLine->GetPolyPoints() )
{
if( newLine == 4 )
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 3, " (xy %s %s)",
FormatInternalUnits( pt.x ).c_str(),
FormatInternalUnits( pt.y ).c_str() );
newLine = 0;
lineCount += 1;
}
else
{
aFormatter.Print( 0, " (xy %s %s)",
FormatInternalUnits( pt.x ).c_str(),
FormatInternalUnits( pt.y ).c_str() );
}
newLine += 1;
}
if( lineCount == 1 )
{
aFormatter.Print( 0, ")\n" ); // Closes pts token on same line.
}
else
{
aFormatter.Print( 0, "\n" );
aFormatter.Print( aNestLevel + 1, ")\n" ); // Closes pts token with multiple lines.
}
bool needsSpace = false;
if( aPolyLine->GetWidth() != 0 && aPolyLine->GetWidth() != Mils2iu( DEFAULT_LINE_THICKNESS ) )
{
aFormatter.Print( aNestLevel + 1, "(stroke (width %s))",
FormatInternalUnits( aPolyLine->GetWidth() ).c_str() );
needsSpace = true;
if( aPolyLine->GetFillMode() == NO_FILL )
aFormatter.Print( 0, "\n" );
}
if( aPolyLine->GetFillMode() != NO_FILL )
{
if( needsSpace )
{
aFormatter.Print( 0, " " );
formatFill( static_cast< LIB_ITEM* >( aPolyLine ), aFormatter, 0 );
}
else
{
formatFill( static_cast< LIB_ITEM* >( aPolyLine ), aFormatter, aNestLevel + 1 );
}
aFormatter.Print( 0, "\n" );
}
aFormatter.Print( aNestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::saveRectangle( LIB_RECTANGLE* aRectangle,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aRectangle && aRectangle->Type() == LIB_RECTANGLE_T,
"Invalid LIB_RECTANGLE object." );
aFormatter.Print( aNestLevel, "(rectangle (start %s %s) (end %s %s)",
FormatInternalUnits( aRectangle->GetPosition().x ).c_str(),
FormatInternalUnits( aRectangle->GetPosition().y ).c_str(),
FormatInternalUnits( aRectangle->GetEnd().x ).c_str(),
FormatInternalUnits( aRectangle->GetEnd().y ).c_str() );
bool needsSpace = false;
if( aRectangle->GetWidth() != 0 && aRectangle->GetWidth() != Mils2iu( DEFAULT_LINE_THICKNESS ) )
{
aFormatter.Print( 0, " (stroke (width %s))",
FormatInternalUnits( aRectangle->GetWidth() ).c_str() );
needsSpace = true;
}
if( aRectangle->GetFillMode() != NO_FILL )
{
if( needsSpace )
aFormatter.Print( 0, " " );
formatFill( static_cast< LIB_ITEM* >( aRectangle ), aFormatter, 0 );
}
aFormatter.Print( 0, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::saveText( LIB_TEXT* aText,
OUTPUTFORMATTER& aFormatter,
int aNestLevel )
{
wxCHECK_RET( aText && aText->Type() == LIB_TEXT_T, "Invalid LIB_TEXT object." );
aFormatter.Print( aNestLevel, "(text %s (at %s %s %g)\n",
aFormatter.Quotew( aText->GetText() ).c_str(),
FormatInternalUnits( aText->GetPosition().x ).c_str(),
FormatInternalUnits( aText->GetPosition().y ).c_str(),
aText->GetTextAngle() );
aText->Format( &aFormatter, aNestLevel, 0 );
aFormatter.Print( aNestLevel, ")\n" );
}
void SCH_SEXPR_PLUGIN_CACHE::DeleteSymbol( const wxString& aSymbolName )
{
LIB_PART_MAP::iterator it = m_symbols.find( aSymbolName );
if( it == m_symbols.end() )
THROW_IO_ERROR( wxString::Format( _( "library %s does not contain a symbol named %s" ),
m_libFileName.GetFullName(), aSymbolName ) );
LIB_PART* part = it->second;
if( part->IsRoot() )
{
LIB_PART* rootPart = part;
// Remove the root symbol and all it's children.
m_symbols.erase( it );
LIB_PART_MAP::iterator it1 = m_symbols.begin();
while( it1 != m_symbols.end() )
{
if( it1->second->IsAlias() && it1->second->GetParent().lock() == rootPart->SharedPtr() )
{
delete it1->second;
it1 = m_symbols.erase( it1 );
}
else
{
it1++;
}
}
delete rootPart;
}
else
{
// Just remove the alias.
m_symbols.erase( it );
delete part;
}
++m_modHash;
m_isModified = true;
}
void SCH_SEXPR_PLUGIN::cacheLib( const wxString& aLibraryFileName )
{
if( !m_cache || !m_cache->IsFile( aLibraryFileName ) || m_cache->IsFileChanged() )
{
// a spectacular episode in memory management:
delete m_cache;
m_cache = new SCH_SEXPR_PLUGIN_CACHE( aLibraryFileName );
// Because m_cache is rebuilt, increment PART_LIBS::s_modify_generation
// to modify the hash value that indicate component to symbol links
// must be updated.
PART_LIBS::s_modify_generation++;
if( !isBuffering( m_props ) )
m_cache->Load();
}
}
bool SCH_SEXPR_PLUGIN::isBuffering( const PROPERTIES* aProperties )
{
return ( aProperties && aProperties->Exists( SCH_SEXPR_PLUGIN::PropBuffering ) );
}
int SCH_SEXPR_PLUGIN::GetModifyHash() const
{
if( m_cache )
return m_cache->GetModifyHash();
// If the cache hasn't been loaded, it hasn't been modified.
return 0;
}
void SCH_SEXPR_PLUGIN::EnumerateSymbolLib( wxArrayString& aSymbolNameList,
const wxString& aLibraryPath,
const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
m_props = aProperties;
bool powerSymbolsOnly = ( aProperties &&
aProperties->find( SYMBOL_LIB_TABLE::PropPowerSymsOnly ) != aProperties->end() );
cacheLib( aLibraryPath );
const LIB_PART_MAP& symbols = m_cache->m_symbols;
for( LIB_PART_MAP::const_iterator it = symbols.begin(); it != symbols.end(); ++it )
{
if( !powerSymbolsOnly || it->second->IsPower() )
aSymbolNameList.Add( it->first );
}
}
void SCH_SEXPR_PLUGIN::EnumerateSymbolLib( std::vector<LIB_PART*>& aSymbolList,
const wxString& aLibraryPath,
const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
m_props = aProperties;
bool powerSymbolsOnly = ( aProperties &&
aProperties->find( SYMBOL_LIB_TABLE::PropPowerSymsOnly ) != aProperties->end() );
cacheLib( aLibraryPath );
const LIB_PART_MAP& symbols = m_cache->m_symbols;
for( LIB_PART_MAP::const_iterator it = symbols.begin(); it != symbols.end(); ++it )
{
if( !powerSymbolsOnly || it->second->IsPower() )
aSymbolList.push_back( it->second );
}
}
LIB_PART* SCH_SEXPR_PLUGIN::LoadSymbol( const wxString& aLibraryPath, const wxString& aSymbolName,
const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
m_props = aProperties;
cacheLib( aLibraryPath );
LIB_PART_MAP::const_iterator it = m_cache->m_symbols.find( aSymbolName );
if( it == m_cache->m_symbols.end() )
return nullptr;
return it->second;
}
void SCH_SEXPR_PLUGIN::SaveSymbol( const wxString& aLibraryPath, const LIB_PART* aSymbol,
const PROPERTIES* aProperties )
{
m_props = aProperties;
cacheLib( aLibraryPath );
m_cache->AddSymbol( aSymbol );
if( !isBuffering( aProperties ) )
m_cache->Save();
}
void SCH_SEXPR_PLUGIN::DeleteSymbol( const wxString& aLibraryPath, const wxString& aSymbolName,
const PROPERTIES* aProperties )
{
m_props = aProperties;
cacheLib( aLibraryPath );
m_cache->DeleteSymbol( aSymbolName );
if( !isBuffering( aProperties ) )
m_cache->Save();
}
void SCH_SEXPR_PLUGIN::CreateSymbolLib( const wxString& aLibraryPath,
const PROPERTIES* aProperties )
{
if( wxFileExists( aLibraryPath ) )
{
THROW_IO_ERROR( wxString::Format(
_( "symbol library \"%s\" already exists, cannot create a new library" ),
aLibraryPath.GetData() ) );
}
LOCALE_IO toggle;
m_props = aProperties;
delete m_cache;
m_cache = new SCH_SEXPR_PLUGIN_CACHE( aLibraryPath );
m_cache->SetModified();
m_cache->Save();
m_cache->Load(); // update m_writable and m_mod_time
}
bool SCH_SEXPR_PLUGIN::DeleteSymbolLib( const wxString& aLibraryPath,
const PROPERTIES* aProperties )
{
wxFileName fn = aLibraryPath;
if( !fn.FileExists() )
return false;
// Some of the more elaborate wxRemoveFile() crap puts up its own wxLog dialog
// we don't want that. we want bare metal portability with no UI here.
if( wxRemove( aLibraryPath ) )
{
THROW_IO_ERROR( wxString::Format( _( "library \"%s\" cannot be deleted" ),
aLibraryPath.GetData() ) );
}
if( m_cache && m_cache->IsFile( aLibraryPath ) )
{
delete m_cache;
m_cache = 0;
}
return true;
}
void SCH_SEXPR_PLUGIN::SaveLibrary( const wxString& aLibraryPath, const PROPERTIES* aProperties )
{
if( !m_cache )
m_cache = new SCH_SEXPR_PLUGIN_CACHE( aLibraryPath );
wxString oldFileName = m_cache->GetFileName();
if( !m_cache->IsFile( aLibraryPath ) )
{
m_cache->SetFileName( aLibraryPath );
}
// This is a forced save.
m_cache->SetModified();
m_cache->Save();
m_cache->SetFileName( oldFileName );
}
bool SCH_SEXPR_PLUGIN::CheckHeader( const wxString& aFileName )
{
// Open file and check first line
wxTextFile tempFile;
tempFile.Open( aFileName );
wxString firstline;
// read the first line
firstline = tempFile.GetFirstLine();
tempFile.Close();
return firstline.StartsWith( "EESchema" );
}
bool SCH_SEXPR_PLUGIN::IsSymbolLibWritable( const wxString& aLibraryPath )
{
return wxFileName::IsFileWritable( aLibraryPath );
}
LIB_PART* SCH_SEXPR_PLUGIN::ParsePart( LINE_READER& reader, int aMajorVersion,
int aMinorVersion )
{
return SCH_SEXPR_PLUGIN_CACHE::LoadPart( reader, aMajorVersion, aMinorVersion );
}
void SCH_SEXPR_PLUGIN::FormatPart( LIB_PART* part, OUTPUTFORMATTER & formatter )
{
SCH_SEXPR_PLUGIN_CACHE::SaveSymbol( part, formatter );
}
const char* SCH_SEXPR_PLUGIN::PropBuffering = "buffering";