kicad/pcbnew/plugins/kicad/kicad_plugin.cpp

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2012 CERN
* Copyright (C) 1992-2021 KiCad Developers, see AUTHORS.txt for contributors.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include <advanced_config.h>
#include <base_units.h>
#include <board.h>
#include <board_design_settings.h>
#include <boost/ptr_container/ptr_map.hpp>
#include <confirm.h>
#include <convert_basic_shapes_to_polygon.h> // for enum RECT_CHAMFER_POSITIONS definition
#include <core/arraydim.h>
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#include <pcb_dimension.h>
#include <footprint.h>
#include <fp_shape.h>
#include <kicad_string.h>
#include <kiface_i.h>
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#include <locale_io.h>
#include <macros.h>
#include <pad.h>
#include <pcb_group.h>
#include <pcb_shape.h>
#include <pcb_target.h>
#include <pcb_text.h>
#include <pcbnew_settings.h>
#include <plugins/kicad/kicad_plugin.h>
#include <plugins/kicad/pcb_parser.h>
#include <trace_helpers.h>
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#include <pcb_track.h>
#include <widgets/progress_reporter.h>
#include <wildcards_and_files_ext.h>
#include <wx/dir.h>
#include <wx/log.h>
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#include <wx_filename.h>
#include <zone.h>
#include <zones.h>
using namespace PCB_KEYS_T;
/**
* Helper class for creating a footprint library cache.
*
* The new footprint library design is a file path of individual footprint files that contain
* a single footprint per file. This class is a helper only for the footprint portion of the
* PLUGIN API, and only for the #PCB_IO plugin. It is private to this implementation file so
* it is not placed into a header.
*/
class FP_CACHE_ITEM
{
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WX_FILENAME m_filename;
std::unique_ptr<FOOTPRINT> m_footprint;
public:
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FP_CACHE_ITEM( FOOTPRINT* aFootprint, const WX_FILENAME& aFileName );
const WX_FILENAME& GetFileName() const { return m_filename; }
const FOOTPRINT* GetFootprint() const { return m_footprint.get(); }
};
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FP_CACHE_ITEM::FP_CACHE_ITEM( FOOTPRINT* aFootprint, const WX_FILENAME& aFileName ) :
m_filename( aFileName ),
m_footprint( aFootprint )
{ }
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typedef boost::ptr_map< wxString, FP_CACHE_ITEM > FOOTPRINT_MAP;
class FP_CACHE
{
PCB_IO* m_owner; // Plugin object that owns the cache.
wxFileName m_lib_path; // The path of the library.
wxString m_lib_raw_path; // For quick comparisons.
FOOTPRINT_MAP m_footprints; // Map of footprint filename to FOOTPRINT*.
bool m_cache_dirty; // Stored separately because it's expensive to check
// m_cache_timestamp against all the files.
long long m_cache_timestamp; // A hash of the timestamps for all the footprint
// files.
public:
FP_CACHE( PCB_IO* aOwner, const wxString& aLibraryPath );
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wxString GetPath() const { return m_lib_raw_path; }
bool IsWritable() const { return m_lib_path.IsOk() && m_lib_path.IsDirWritable(); }
bool Exists() const { return m_lib_path.IsOk() && m_lib_path.DirExists(); }
FOOTPRINT_MAP& GetFootprints() { return m_footprints; }
// Most all functions in this class throw IO_ERROR exceptions. There are no
// error codes nor user interface calls from here, nor in any PLUGIN.
// Catch these exceptions higher up please.
/**
* Save the footprint cache or a single footprint from it to disk
*
* @param aFootprint if set, save only this footprint, otherwise, save the full library
*/
void Save( FOOTPRINT* aFootprint = nullptr );
void Load();
void Remove( const wxString& aFootprintName );
/**
* Generate a timestamp representing all source files in the cache (including the
* parent directory).
* Timestamps should not be considered ordered. They either match or they don't.
*/
static long long GetTimestamp( const wxString& aLibPath );
/**
* Return true if the cache is not up-to-date.
*/
bool IsModified();
/**
* Check if \a aPath is the same as the current cache path.
*
* This tests paths by converting \a aPath using the native separators. Internally
* #FP_CACHE stores the current path using native separators. This prevents path
* miscompares on Windows due to the fact that paths can be stored with / instead of \\
* in the footprint library table.
*
* @param aPath is the library path to test against.
* @return true if \a aPath is the same as the cache path.
*/
bool IsPath( const wxString& aPath ) const;
};
FP_CACHE::FP_CACHE( PCB_IO* aOwner, const wxString& aLibraryPath )
{
m_owner = aOwner;
m_lib_raw_path = aLibraryPath;
m_lib_path.SetPath( aLibraryPath );
m_cache_timestamp = 0;
m_cache_dirty = true;
}
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void FP_CACHE::Save( FOOTPRINT* aFootprint )
{
m_cache_timestamp = 0;
if( !m_lib_path.DirExists() && !m_lib_path.Mkdir() )
{
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THROW_IO_ERROR( wxString::Format( _( "Cannot create footprint library '%s'." ),
m_lib_raw_path ) );
}
if( !m_lib_path.IsDirWritable() )
{
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THROW_IO_ERROR( wxString::Format( _( "Footprint library '%s' is read only." ),
m_lib_raw_path ) );
}
for( FOOTPRINT_MAP::iterator it = m_footprints.begin(); it != m_footprints.end(); ++it )
{
if( aFootprint && aFootprint != it->second->GetFootprint() )
continue;
WX_FILENAME fn = it->second->GetFileName();
wxString tempFileName =
#ifdef USE_TMP_FILE
wxFileName::CreateTempFileName( fn.GetPath() );
#else
fn.GetFullPath();
#endif
// Allow file output stream to go out of scope to close the file stream before
// renaming the file.
{
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wxLogTrace( traceKicadPcbPlugin, wxT( "Creating temporary library file '%s'." ),
tempFileName );
FILE_OUTPUTFORMATTER formatter( tempFileName );
m_owner->SetOutputFormatter( &formatter );
m_owner->Format( (BOARD_ITEM*) it->second->GetFootprint() );
}
#ifdef USE_TMP_FILE
wxRemove( fn.GetFullPath() ); // it is not an error if this does not exist
// Even on Linux you can see an _intermittent_ error when calling wxRename(),
// and it is fully inexplicable. See if this dodges the error.
wxMilliSleep( 250L );
if( !wxRenameFile( tempFileName, fn.GetFullPath() ) )
{
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wxString msg = wxString::Format( _( "Cannot rename temporary file '%s' to '%s'" ),
tempFileName,
fn.GetFullPath() );
THROW_IO_ERROR( msg );
}
#endif
m_cache_timestamp += fn.GetTimestamp();
}
m_cache_timestamp += m_lib_path.GetModificationTime().GetValue().GetValue();
// If we've saved the full cache, we clear the dirty flag.
if( !aFootprint )
m_cache_dirty = false;
}
void FP_CACHE::Load()
{
m_cache_dirty = false;
m_cache_timestamp = 0;
wxDir dir( m_lib_raw_path );
if( !dir.IsOpened() )
{
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wxString msg = wxString::Format( _( "Footprint library '%s' not found." ),
m_lib_raw_path );
THROW_IO_ERROR( msg );
}
wxString fullName;
wxString fileSpec = wxT( "*." ) + KiCadFootprintFileExtension;
// wxFileName construction is egregiously slow. Construct it once and just swap out
// the filename thereafter.
WX_FILENAME fn( m_lib_raw_path, wxT( "dummyName" ) );
if( dir.GetFirst( &fullName, fileSpec ) )
{
wxString cacheError;
do
{
fn.SetFullName( fullName );
// Queue I/O errors so only files that fail to parse don't get loaded.
try
{
FILE_LINE_READER reader( fn.GetFullPath() );
m_owner->m_parser->SetLineReader( &reader );
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FOOTPRINT* footprint = (FOOTPRINT*) m_owner->m_parser->Parse();
wxString fpName = fn.GetName();
footprint->SetFPID( LIB_ID( wxEmptyString, fpName ) );
m_footprints.insert( fpName, new FP_CACHE_ITEM( footprint, fn ) );
}
catch( const IO_ERROR& ioe )
{
if( !cacheError.IsEmpty() )
cacheError += "\n\n";
cacheError += ioe.What();
}
} while( dir.GetNext( &fullName ) );
m_cache_timestamp = GetTimestamp( m_lib_raw_path );
if( !cacheError.IsEmpty() )
THROW_IO_ERROR( cacheError );
}
}
void FP_CACHE::Remove( const wxString& aFootprintName )
{
FOOTPRINT_MAP::const_iterator it = m_footprints.find( aFootprintName );
if( it == m_footprints.end() )
{
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wxString msg = wxString::Format( _( "Library '%s' has no footprint '%s'." ),
m_lib_raw_path,
aFootprintName );
THROW_IO_ERROR( msg );
}
// Remove the footprint from the cache and delete the footprint file from the library.
wxString fullPath = it->second->GetFileName().GetFullPath();
m_footprints.erase( aFootprintName );
wxRemoveFile( fullPath );
}
bool FP_CACHE::IsPath( const wxString& aPath ) const
{
return aPath == m_lib_raw_path;
}
bool FP_CACHE::IsModified()
{
m_cache_dirty = m_cache_dirty || GetTimestamp( m_lib_path.GetFullPath() ) != m_cache_timestamp;
return m_cache_dirty;
}
long long FP_CACHE::GetTimestamp( const wxString& aLibPath )
{
wxString fileSpec = wxT( "*." ) + KiCadFootprintFileExtension;
return TimestampDir( aLibPath, fileSpec );
}
void PCB_IO::Save( const wxString& aFileName, BOARD* aBoard, const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
wxString sanityResult = aBoard->GroupsSanityCheck();
if( sanityResult != wxEmptyString )
{
KIDIALOG dlg( nullptr, wxString::Format(
_( "Please report this bug. Error validating group structure: %s"
"\n\nSave anyway?" ), sanityResult ),
_( "Internal group data structure corrupt" ),
wxOK | wxCANCEL | wxICON_ERROR );
dlg.SetOKLabel( _( "Save Anyway" ) );
if( dlg.ShowModal() == wxID_CANCEL )
return;
}
init( aProperties );
m_board = aBoard; // after init()
// Prepare net mapping that assures that net codes saved in a file are consecutive integers
m_mapping->SetBoard( aBoard );
FILE_OUTPUTFORMATTER formatter( aFileName );
m_out = &formatter; // no ownership
m_out->Print( 0, "(kicad_pcb (version %d) (generator pcbnew)\n", SEXPR_BOARD_FILE_VERSION );
Format( aBoard, 1 );
m_out->Print( 0, ")\n" );
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m_out = nullptr;
}
BOARD_ITEM* PCB_IO::Parse( const wxString& aClipboardSourceInput )
{
std::string input = TO_UTF8( aClipboardSourceInput );
STRING_LINE_READER reader( input, wxT( "clipboard" ) );
m_parser->SetLineReader( &reader );
try
{
return m_parser->Parse();
}
catch( const PARSE_ERROR& parse_error )
{
if( m_parser->IsTooRecent() )
throw FUTURE_FORMAT_ERROR( parse_error, m_parser->GetRequiredVersion() );
else
throw;
}
}
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void PCB_IO::Format( const BOARD_ITEM* aItem, int aNestLevel ) const
{
LOCALE_IO toggle; // public API function, perform anything convenient for caller
switch( aItem->Type() )
{
case PCB_T:
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format( static_cast<const BOARD*>( aItem ), aNestLevel );
break;
case PCB_DIM_ALIGNED_T:
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case PCB_DIM_CENTER_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
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format( static_cast<const PCB_DIMENSION_BASE*>( aItem ), aNestLevel );
break;
case PCB_SHAPE_T:
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format( static_cast<const PCB_SHAPE*>( aItem ), aNestLevel );
break;
case PCB_FP_SHAPE_T:
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format( static_cast<const FP_SHAPE*>( aItem ), aNestLevel );
break;
case PCB_TARGET_T:
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format( static_cast<const PCB_TARGET*>( aItem ), aNestLevel );
break;
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case PCB_FOOTPRINT_T:
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format( static_cast<const FOOTPRINT*>( aItem ), aNestLevel );
break;
case PCB_PAD_T:
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format( static_cast<const PAD*>( aItem ), aNestLevel );
break;
case PCB_TEXT_T:
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format( static_cast<const PCB_TEXT*>( aItem ), aNestLevel );
break;
case PCB_FP_TEXT_T:
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format( static_cast<const FP_TEXT*>( aItem ), aNestLevel );
break;
case PCB_GROUP_T:
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format( static_cast<const PCB_GROUP*>( aItem ), aNestLevel );
break;
case PCB_TRACE_T:
case PCB_ARC_T:
case PCB_VIA_T:
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format( static_cast<const PCB_TRACK*>( aItem ), aNestLevel );
break;
case PCB_FP_ZONE_T:
case PCB_ZONE_T:
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format( static_cast<const ZONE*>( aItem ), aNestLevel );
break;
default:
wxFAIL_MSG( wxT( "Cannot format item " ) + aItem->GetClass() );
}
}
void PCB_IO::formatLayer( const BOARD_ITEM* aItem ) const
{
PCB_LAYER_ID layer = aItem->GetLayer();
m_out->Print( 0, " (layer %s)", m_out->Quotew( LSET::Name( layer ) ).c_str() );
}
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void PCB_IO::formatSetup( const BOARD* aBoard, int aNestLevel ) const
{
// Setup
m_out->Print( aNestLevel, "(setup\n" );
// Save the board physical stackup structure
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const BOARD_STACKUP& stackup = aBoard->GetDesignSettings().GetStackupDescriptor();
if( aBoard->GetDesignSettings().m_HasStackup )
stackup.FormatBoardStackup( m_out, aBoard, aNestLevel+1 );
BOARD_DESIGN_SETTINGS& dsnSettings = aBoard->GetDesignSettings();
m_out->Print( aNestLevel+1, "(pad_to_mask_clearance %s)\n",
FormatInternalUnits( dsnSettings.m_SolderMaskMargin ).c_str() );
if( dsnSettings.m_SolderMaskMinWidth )
m_out->Print( aNestLevel+1, "(solder_mask_min_width %s)\n",
FormatInternalUnits( dsnSettings.m_SolderMaskMinWidth ).c_str() );
if( dsnSettings.m_SolderPasteMargin != 0 )
m_out->Print( aNestLevel+1, "(pad_to_paste_clearance %s)\n",
FormatInternalUnits( dsnSettings.m_SolderPasteMargin ).c_str() );
if( dsnSettings.m_SolderPasteMarginRatio != 0 )
m_out->Print( aNestLevel+1, "(pad_to_paste_clearance_ratio %s)\n",
Double2Str( dsnSettings.m_SolderPasteMarginRatio ).c_str() );
if( dsnSettings.m_AuxOrigin != wxPoint( 0, 0 ) )
m_out->Print( aNestLevel+1, "(aux_axis_origin %s %s)\n",
FormatInternalUnits( dsnSettings.m_AuxOrigin.x ).c_str(),
FormatInternalUnits( dsnSettings.m_AuxOrigin.y ).c_str() );
if( dsnSettings.m_GridOrigin != wxPoint( 0, 0 ) )
m_out->Print( aNestLevel+1, "(grid_origin %s %s)\n",
FormatInternalUnits( dsnSettings.m_GridOrigin.x ).c_str(),
FormatInternalUnits( dsnSettings.m_GridOrigin.y ).c_str() );
aBoard->GetPlotOptions().Format( m_out, aNestLevel+1 );
m_out->Print( aNestLevel, ")\n\n" );
}
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void PCB_IO::formatGeneral( const BOARD* aBoard, int aNestLevel ) const
{
const BOARD_DESIGN_SETTINGS& dsnSettings = aBoard->GetDesignSettings();
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel, "(general\n" );
m_out->Print( aNestLevel+1, "(thickness %s)\n",
FormatInternalUnits( dsnSettings.GetBoardThickness() ).c_str() );
m_out->Print( aNestLevel, ")\n\n" );
aBoard->GetPageSettings().Format( m_out, aNestLevel, m_ctl );
aBoard->GetTitleBlock().Format( m_out, aNestLevel, m_ctl );
}
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void PCB_IO::formatBoardLayers( const BOARD* aBoard, int aNestLevel ) const
{
m_out->Print( aNestLevel, "(layers\n" );
// Save only the used copper layers from front to back.
for( LSEQ cu = aBoard->GetEnabledLayers().CuStack(); cu; ++cu )
{
PCB_LAYER_ID layer = *cu;
m_out->Print( aNestLevel+1, "(%d %s %s", layer,
m_out->Quotew( LSET::Name( layer ) ).c_str(),
LAYER::ShowType( aBoard->GetLayerType( layer ) ) );
if( LSET::Name( layer ) != m_board->GetLayerName( layer ) )
m_out->Print( 0, " %s", m_out->Quotew( m_board->GetLayerName( layer ) ).c_str() );
m_out->Print( 0, ")\n" );
}
// Save used non-copper layers in the order they are defined.
// desired sequence for non Cu BOARD layers.
static const PCB_LAYER_ID non_cu[] =
{
B_Adhes, // 32
F_Adhes,
B_Paste,
F_Paste,
B_SilkS,
F_SilkS,
B_Mask,
F_Mask,
Dwgs_User,
Cmts_User,
Eco1_User,
Eco2_User,
Edge_Cuts,
Margin,
B_CrtYd,
F_CrtYd,
B_Fab,
F_Fab,
User_1,
User_2,
User_3,
User_4,
User_5,
User_6,
User_7,
User_8,
User_9
};
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for( LSEQ seq = aBoard->GetEnabledLayers().Seq( non_cu, arrayDim( non_cu ) ); seq; ++seq )
{
PCB_LAYER_ID layer = *seq;
m_out->Print( aNestLevel+1, "(%d %s user", layer,
m_out->Quotew( LSET::Name( layer ) ).c_str() );
if( m_board->GetLayerName( layer ) != LSET::Name( layer ) )
m_out->Print( 0, " %s", m_out->Quotew( m_board->GetLayerName( layer ) ).c_str() );
m_out->Print( 0, ")\n" );
}
m_out->Print( aNestLevel, ")\n\n" );
}
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void PCB_IO::formatNetInformation( const BOARD* aBoard, int aNestLevel ) const
{
for( NETINFO_ITEM* net : *m_mapping )
{
if( net == nullptr ) // Skip not actually existing nets (orphan nets)
continue;
m_out->Print( aNestLevel, "(net %d %s)\n",
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m_mapping->Translate( net->GetNetCode() ),
m_out->Quotew( net->GetNetname() ).c_str() );
}
m_out->Print( 0, "\n" );
}
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void PCB_IO::formatProperties( const BOARD* aBoard, int aNestLevel ) const
{
for( const std::pair<const wxString, wxString>& prop : aBoard->GetProperties() )
{
m_out->Print( aNestLevel, "(property %s %s)\n",
m_out->Quotew( prop.first ).c_str(),
m_out->Quotew( prop.second ).c_str() );
}
if( !aBoard->GetProperties().empty() )
m_out->Print( 0, "\n" );
}
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void PCB_IO::formatHeader( const BOARD* aBoard, int aNestLevel ) const
{
formatGeneral( aBoard, aNestLevel );
// Layers list.
formatBoardLayers( aBoard, aNestLevel );
// Setup
formatSetup( aBoard, aNestLevel );
// Properties
formatProperties( aBoard, aNestLevel );
// Save net codes and names
formatNetInformation( aBoard, aNestLevel );
}
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void PCB_IO::format( const BOARD* aBoard, int aNestLevel ) const
{
std::set<BOARD_ITEM*, BOARD_ITEM::ptr_cmp> sorted_footprints( aBoard->Footprints().begin(),
aBoard->Footprints().end() );
std::set<BOARD_ITEM*, BOARD_ITEM::ptr_cmp> sorted_drawings( aBoard->Drawings().begin(),
aBoard->Drawings().end() );
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std::set<PCB_TRACK*, PCB_TRACK::cmp_tracks> sorted_tracks( aBoard->Tracks().begin(),
aBoard->Tracks().end() );
std::set<BOARD_ITEM*, BOARD_ITEM::ptr_cmp> sorted_zones( aBoard->Zones().begin(),
aBoard->Zones().end() );
std::set<BOARD_ITEM*, BOARD_ITEM::ptr_cmp> sorted_groups( aBoard->Groups().begin(),
aBoard->Groups().end() );
formatHeader( aBoard, aNestLevel );
// Save the footprints.
for( BOARD_ITEM* footprint : sorted_footprints )
{
Format( footprint, aNestLevel );
m_out->Print( 0, "\n" );
}
// Save the graphical items on the board (not owned by a footprint)
for( BOARD_ITEM* item : sorted_drawings )
Format( item, aNestLevel );
if( sorted_drawings.size() )
m_out->Print( 0, "\n" );
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// Do not save PCB_MARKERs, they can be regenerated easily.
// Save the tracks and vias.
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for( PCB_TRACK* track : sorted_tracks )
Format( track, aNestLevel );
if( sorted_tracks.size() )
m_out->Print( 0, "\n" );
// Save the polygon (which are the newer technology) zones.
for( auto zone : sorted_zones )
Format( zone, aNestLevel );
// Save the groups
for( BOARD_ITEM* group : sorted_groups )
Format( group, aNestLevel );
}
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void PCB_IO::format( const PCB_DIMENSION_BASE* aDimension, int aNestLevel ) const
{
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const PCB_DIM_ALIGNED* aligned = dynamic_cast<const PCB_DIM_ALIGNED*>( aDimension );
const PCB_DIM_ORTHOGONAL* ortho = dynamic_cast<const PCB_DIM_ORTHOGONAL*>( aDimension );
const PCB_DIM_CENTER* center = dynamic_cast<const PCB_DIM_CENTER*>( aDimension );
const PCB_DIM_LEADER* leader = dynamic_cast<const PCB_DIM_LEADER*>( aDimension );
m_out->Print( aNestLevel, "(dimension" );
if( aDimension->IsLocked() )
m_out->Print( 0, " locked" );
if( aDimension->Type() == PCB_DIM_ALIGNED_T )
m_out->Print( 0, " (type aligned)" );
else if( aDimension->Type() == PCB_DIM_LEADER_T )
m_out->Print( 0, " (type leader)" );
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else if( aDimension->Type() == PCB_DIM_CENTER_T )
m_out->Print( 0, " (type center)" );
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else if( aDimension->Type() == PCB_DIM_ORTHOGONAL_T )
m_out->Print( 0, " (type orthogonal)" );
else
wxFAIL_MSG( wxT( "Cannot format unknown dimension type!" ) );
formatLayer( aDimension );
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m_out->Print( 0, " (tstamp %s)", TO_UTF8( aDimension->m_Uuid.AsString() ) );
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+1, "(pts (xy %s %s) (xy %s %s))\n",
FormatInternalUnits( aDimension->GetStart().x ).c_str(),
FormatInternalUnits( aDimension->GetStart().y ).c_str(),
FormatInternalUnits( aDimension->GetEnd().x ).c_str(),
FormatInternalUnits( aDimension->GetEnd().y ).c_str() );
if( aligned )
m_out->Print( aNestLevel+1, "(height %s)\n",
FormatInternalUnits( aligned->GetHeight() ).c_str() );
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if( ortho )
m_out->Print( aNestLevel+1, "(orientation %d)\n",
static_cast<int>( ortho->GetOrientation() ) );
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if( !center )
{
Format( &aDimension->Text(), aNestLevel + 1 );
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m_out->Print( aNestLevel + 1, "(format" );
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if( !aDimension->GetPrefix().IsEmpty() )
m_out->Print( 0, " (prefix %s)", m_out->Quotew( aDimension->GetPrefix() ).c_str() );
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if( !aDimension->GetSuffix().IsEmpty() )
m_out->Print( 0, " (suffix %s)", m_out->Quotew( aDimension->GetSuffix() ).c_str() );
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m_out->Print( 0, " (units %d) (units_format %d) (precision %d)",
static_cast<int>( aDimension->GetUnitsMode() ),
static_cast<int>( aDimension->GetUnitsFormat() ), aDimension->GetPrecision() );
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if( aDimension->GetOverrideTextEnabled() )
m_out->Print( 0, " (override_value %s)",
m_out->Quotew( aDimension->GetOverrideText() ).c_str() );
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if( aDimension->GetSuppressZeroes() )
m_out->Print( 0, " suppress_zeroes" );
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m_out->Print( 0, ")\n" );
}
m_out->Print( aNestLevel+1, "(style (thickness %s) (arrow_length %s) (text_position_mode %d)",
FormatInternalUnits( aDimension->GetLineThickness() ).c_str(),
FormatInternalUnits( aDimension->GetArrowLength() ).c_str(),
static_cast<int>( aDimension->GetTextPositionMode() ) );
if( aligned )
{
m_out->Print( 0, " (extension_height %s)",
FormatInternalUnits( aligned->GetExtensionHeight() ).c_str() );
}
if( leader )
m_out->Print( 0, " (text_frame %d)", static_cast<int>( leader->GetTextFrame() ) );
m_out->Print( 0, " (extension_offset %s)",
FormatInternalUnits( aDimension->GetExtensionOffset() ).c_str() );
if( aDimension->GetKeepTextAligned() )
m_out->Print( 0, " keep_text_aligned" );
m_out->Print( 0, ")\n" );
m_out->Print( aNestLevel, ")\n" );
}
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void PCB_IO::format( const PCB_SHAPE* aShape, int aNestLevel ) const
{
std::string locked = aShape->IsLocked() ? " locked" : "";
switch( aShape->GetShape() )
{
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case PCB_SHAPE_TYPE::SEGMENT: // Line
m_out->Print( aNestLevel, "(gr_line%s (start %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aShape->GetStart() ).c_str(),
FormatInternalUnits( aShape->GetEnd() ).c_str() );
if( aShape->GetAngle() != 0.0 )
m_out->Print( 0, " (angle %s)", FormatAngle( aShape->GetAngle() ).c_str() );
break;
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case PCB_SHAPE_TYPE::RECT: // Rectangle
m_out->Print( aNestLevel, "(gr_rect%s (start %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aShape->GetStart() ).c_str(),
FormatInternalUnits( aShape->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::CIRCLE: // Circle
m_out->Print( aNestLevel, "(gr_circle%s (center %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aShape->GetStart() ).c_str(),
FormatInternalUnits( aShape->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::ARC: // Arc
m_out->Print( aNestLevel, "(gr_arc%s (start %s) (end %s) (angle %s)",
locked.c_str(),
FormatInternalUnits( aShape->GetStart() ).c_str(),
FormatInternalUnits( aShape->GetEnd() ).c_str(),
FormatAngle( aShape->GetAngle() ).c_str() );
break;
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case PCB_SHAPE_TYPE::POLYGON: // Polygon
if( aShape->IsPolyShapeValid() )
{
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const SHAPE_POLY_SET& poly = aShape->GetPolyShape();
const SHAPE_LINE_CHAIN& outline = poly.Outline( 0 );
m_out->Print( aNestLevel, "(gr_poly%s\n", locked.c_str() );
m_out->Print( aNestLevel+1, "(pts\n" );
bool need_newline = false;
for( int ii = 0; ii < outline.PointCount(); ++ii )
{
int nestLevel = ii == 0 ? aNestLevel + 2 : 0;
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if( ii && ( !( ii % 4 ) || !ADVANCED_CFG::GetCfg().m_CompactSave ) )
{
// newline every 4 pts.
nestLevel = aNestLevel + 2;
m_out->Print( 0, "\n" );
need_newline = false;
}
int ind = outline.ArcIndex( ii );
if( ind < 0 )
{
m_out->Print( nestLevel, "%s(xy %s)",
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nestLevel ? "" : " ",
FormatInternalUnits( outline.CPoint( ii ) ).c_str() );
need_newline = true;
}
else
{
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const SHAPE_ARC& arc = outline.Arc( ind );
m_out->Print( aNestLevel, "%s(arc (start %s) (mid %s) (end %s))",
nestLevel ? "" : " ",
FormatInternalUnits( arc.GetP0() ).c_str(),
FormatInternalUnits( arc.GetArcMid() ).c_str(),
FormatInternalUnits( arc.GetP1() ).c_str() );
need_newline = true;
do
{
++ii;
} while( ii < outline.PointCount() && outline.ArcIndex( ii ) == ind );
--ii;
}
}
if( need_newline )
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+1, ")" );
}
else
{
wxFAIL_MSG( wxT( "Cannot format invalid polygon." ) );
return;
}
break;
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case PCB_SHAPE_TYPE::CURVE: // Bezier curve
m_out->Print( aNestLevel, "(gr_curve%s (pts (xy %s) (xy %s) (xy %s) (xy %s))",
locked.c_str(),
FormatInternalUnits( aShape->GetStart() ).c_str(),
FormatInternalUnits( aShape->GetBezControl1() ).c_str(),
FormatInternalUnits( aShape->GetBezControl2() ).c_str(),
FormatInternalUnits( aShape->GetEnd() ).c_str() );
break;
default:
wxFAIL_MSG( "PCB_IO::format cannot format unknown PCB_SHAPE shape:"
+ PCB_SHAPE_TYPE_T_asString( aShape->GetShape()) );
return;
};
formatLayer( aShape );
m_out->Print( 0, " (width %s)", FormatInternalUnits( aShape->GetWidth() ).c_str() );
// The filled flag represents if a solid fill is present on circles, rectangles and polygons
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if( ( aShape->GetShape() == PCB_SHAPE_TYPE::POLYGON )
|| ( aShape->GetShape() == PCB_SHAPE_TYPE::RECT )
|| ( aShape->GetShape() == PCB_SHAPE_TYPE::CIRCLE ) )
{
if( aShape->IsFilled() )
m_out->Print( 0, " (fill solid)" );
else
m_out->Print( 0, " (fill none)" );
}
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m_out->Print( 0, " (tstamp %s)", TO_UTF8( aShape->m_Uuid.AsString() ) );
m_out->Print( 0, ")\n" );
}
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void PCB_IO::format( const FP_SHAPE* aFPShape, int aNestLevel ) const
{
std::string locked = aFPShape->IsLocked() ? " locked" : "";
switch( aFPShape->GetShape() )
{
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case PCB_SHAPE_TYPE::SEGMENT: // Line
m_out->Print( aNestLevel, "(fp_line%s (start %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aFPShape->GetStart0() ).c_str(),
FormatInternalUnits( aFPShape->GetEnd0() ).c_str() );
break;
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case PCB_SHAPE_TYPE::RECT: // Rectangle
m_out->Print( aNestLevel, "(fp_rect%s (start %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aFPShape->GetStart0() ).c_str(),
FormatInternalUnits( aFPShape->GetEnd0() ).c_str() );
break;
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case PCB_SHAPE_TYPE::CIRCLE: // Circle
m_out->Print( aNestLevel, "(fp_circle%s (center %s) (end %s)",
locked.c_str(),
FormatInternalUnits( aFPShape->GetStart0() ).c_str(),
FormatInternalUnits( aFPShape->GetEnd0() ).c_str() );
break;
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case PCB_SHAPE_TYPE::ARC: // Arc
m_out->Print( aNestLevel, "(fp_arc%s (start %s) (end %s) (angle %s)",
locked.c_str(),
FormatInternalUnits( aFPShape->GetStart0() ).c_str(),
FormatInternalUnits( aFPShape->GetEnd0() ).c_str(),
FormatAngle( aFPShape->GetAngle() ).c_str() );
break;
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case PCB_SHAPE_TYPE::POLYGON: // Polygonal segment
if( aFPShape->IsPolyShapeValid() )
{
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const SHAPE_POLY_SET& poly = aFPShape->GetPolyShape();
const SHAPE_LINE_CHAIN& outline = poly.Outline( 0 );
m_out->Print( aNestLevel, "(fp_poly%s (pts",
locked.c_str() );
for( int ii = 0; ii < outline.PointCount(); ++ii )
{
int nestLevel = 0;
if( ii && ( !( ii%4 ) || !ADVANCED_CFG::GetCfg().m_CompactSave ) )
{
// newline every 4 pts.
nestLevel = aNestLevel + 1;
m_out->Print( 0, "\n" );
}
int ind = outline.ArcIndex( ii );
if( ind < 0 )
{
m_out->Print( nestLevel, "%s(xy %s)",
nestLevel ? "" : " ", FormatInternalUnits( outline.CPoint( ii ) ).c_str() );
}
else
{
auto& arc = outline.Arc( ind );
m_out->Print( aNestLevel, "%s(arc (start %s) (mid %s) (end %s))",
nestLevel ? "" : " ",
FormatInternalUnits( arc.GetP0() ).c_str(),
FormatInternalUnits( arc.GetArcMid() ).c_str(),
FormatInternalUnits( arc.GetP1() ).c_str() );
do
{
++ii;
} while( ii < outline.PointCount() && outline.ArcIndex( ii ) == ind );
--ii;
}
}
m_out->Print( 0, ")" );
}
else
{
wxFAIL_MSG( wxT( "Cannot format invalid polygon." ) );
return;
}
break;
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case PCB_SHAPE_TYPE::CURVE: // Bezier curve
m_out->Print( aNestLevel, "(fp_curve%s (pts (xy %s) (xy %s) (xy %s) (xy %s))",
locked.c_str(),
FormatInternalUnits( aFPShape->GetStart0() ).c_str(),
FormatInternalUnits( aFPShape->GetBezier0_C1() ).c_str(),
FormatInternalUnits( aFPShape->GetBezier0_C2() ).c_str(),
FormatInternalUnits( aFPShape->GetEnd0() ).c_str() );
break;
default:
wxFAIL_MSG( "PCB_IO::format cannot format unknown FP_SHAPE shape:"
+ PCB_SHAPE_TYPE_T_asString( aFPShape->GetShape() ) );
return;
};
formatLayer( aFPShape );
m_out->Print( 0, " (width %s)", FormatInternalUnits( aFPShape->GetWidth() ).c_str() );
// The filled flag represents if a solid fill is present on circles, rectangles and polygons
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if( ( aFPShape->GetShape() == PCB_SHAPE_TYPE::POLYGON )
|| ( aFPShape->GetShape() == PCB_SHAPE_TYPE::RECT )
|| ( aFPShape->GetShape() == PCB_SHAPE_TYPE::CIRCLE ) )
{
if( aFPShape->IsFilled() )
m_out->Print( 0, " (fill solid)" );
else
m_out->Print( 0, " (fill none)" );
}
2020-11-14 01:16:02 +00:00
m_out->Print( 0, " (tstamp %s)", TO_UTF8( aFPShape->m_Uuid.AsString() ) );
m_out->Print( 0, ")\n" );
}
2020-12-20 18:44:13 +00:00
void PCB_IO::format( const PCB_TARGET* aTarget, int aNestLevel ) const
{
m_out->Print( aNestLevel, "(target %s (at %s) (size %s)",
( aTarget->GetShape() ) ? "x" : "plus",
FormatInternalUnits( aTarget->GetPosition() ).c_str(),
FormatInternalUnits( aTarget->GetSize() ).c_str() );
if( aTarget->GetWidth() != 0 )
m_out->Print( 0, " (width %s)", FormatInternalUnits( aTarget->GetWidth() ).c_str() );
formatLayer( aTarget );
2020-02-20 12:11:04 +00:00
m_out->Print( 0, " (tstamp %s)", TO_UTF8( aTarget->m_Uuid.AsString() ) );
m_out->Print( 0, ")\n" );
}
2020-12-20 18:44:13 +00:00
void PCB_IO::format( const FOOTPRINT* aFootprint, int aNestLevel ) const
{
if( !( m_ctl & CTL_OMIT_INITIAL_COMMENTS ) )
{
const wxArrayString* initial_comments = aFootprint->GetInitialComments();
if( initial_comments )
{
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for( unsigned i = 0; i < initial_comments->GetCount(); ++i )
m_out->Print( aNestLevel, "%s\n", TO_UTF8( (*initial_comments)[i] ) );
m_out->Print( 0, "\n" ); // improve readability?
}
}
if( m_ctl & CTL_OMIT_LIBNAME )
m_out->Print( aNestLevel, "(footprint %s",
m_out->Quotes( aFootprint->GetFPID().GetLibItemName() ).c_str() );
else
m_out->Print( aNestLevel, "(footprint %s",
m_out->Quotes( aFootprint->GetFPID().Format() ).c_str() );
if( !( m_ctl & CTL_OMIT_FOOTPRINT_VERSION ) )
m_out->Print( 0, " (version %d) (generator pcbnew)", SEXPR_BOARD_FILE_VERSION );
if( aFootprint->IsLocked() )
m_out->Print( 0, " locked" );
if( aFootprint->IsPlaced() )
m_out->Print( 0, " placed" );
formatLayer( aFootprint );
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+1, "(tedit %lX)", (unsigned long)aFootprint->GetLastEditTime() );
if( !( m_ctl & CTL_OMIT_TSTAMPS ) )
m_out->Print( 0, " (tstamp %s)", TO_UTF8( aFootprint->m_Uuid.AsString() ) );
2020-02-20 12:11:04 +00:00
m_out->Print( 0, "\n" );
if( !( m_ctl & CTL_OMIT_AT ) )
{
m_out->Print( aNestLevel+1, "(at %s",
FormatInternalUnits( aFootprint->GetPosition() ).c_str() );
if( aFootprint->GetOrientation() != 0.0 )
m_out->Print( 0, " %s", FormatAngle( aFootprint->GetOrientation() ).c_str() );
m_out->Print( 0, ")\n" );
}
if( !aFootprint->GetDescription().IsEmpty() )
m_out->Print( aNestLevel+1, "(descr %s)\n",
m_out->Quotew( aFootprint->GetDescription() ).c_str() );
if( !aFootprint->GetKeywords().IsEmpty() )
m_out->Print( aNestLevel+1, "(tags %s)\n",
m_out->Quotew( aFootprint->GetKeywords() ).c_str() );
const std::map<wxString, wxString>& props = aFootprint->GetProperties();
for( const std::pair<const wxString, wxString>& prop : props )
{
m_out->Print( aNestLevel+1, "(property %s %s)\n",
m_out->Quotew( prop.first ).c_str(),
m_out->Quotew( prop.second ).c_str() );
}
if( !( m_ctl & CTL_OMIT_PATH ) && !aFootprint->GetPath().empty() )
m_out->Print( aNestLevel+1, "(path %s)\n",
m_out->Quotew( aFootprint->GetPath().AsString() ).c_str() );
if( aFootprint->GetPlacementCost90() != 0 )
m_out->Print( aNestLevel+1, "(autoplace_cost90 %d)\n", aFootprint->GetPlacementCost90() );
if( aFootprint->GetPlacementCost180() != 0 )
m_out->Print( aNestLevel+1, "(autoplace_cost180 %d)\n", aFootprint->GetPlacementCost180() );
if( aFootprint->GetLocalSolderMaskMargin() != 0 )
m_out->Print( aNestLevel+1, "(solder_mask_margin %s)\n",
FormatInternalUnits( aFootprint->GetLocalSolderMaskMargin() ).c_str() );
if( aFootprint->GetLocalSolderPasteMargin() != 0 )
m_out->Print( aNestLevel+1, "(solder_paste_margin %s)\n",
FormatInternalUnits( aFootprint->GetLocalSolderPasteMargin() ).c_str() );
if( aFootprint->GetLocalSolderPasteMarginRatio() != 0 )
m_out->Print( aNestLevel+1, "(solder_paste_ratio %s)\n",
Double2Str( aFootprint->GetLocalSolderPasteMarginRatio() ).c_str() );
if( aFootprint->GetLocalClearance() != 0 )
m_out->Print( aNestLevel+1, "(clearance %s)\n",
FormatInternalUnits( aFootprint->GetLocalClearance() ).c_str() );
if( aFootprint->GetZoneConnection() != ZONE_CONNECTION::INHERITED )
2019-12-28 07:43:29 +00:00
m_out->Print( aNestLevel+1, "(zone_connect %d)\n",
static_cast<int>( aFootprint->GetZoneConnection() ) );
if( aFootprint->GetThermalWidth() != 0 )
m_out->Print( aNestLevel+1, "(thermal_width %s)\n",
FormatInternalUnits( aFootprint->GetThermalWidth() ).c_str() );
if( aFootprint->GetThermalGap() != 0 )
m_out->Print( aNestLevel+1, "(thermal_gap %s)\n",
FormatInternalUnits( aFootprint->GetThermalGap() ).c_str() );
// Attributes
if( aFootprint->GetAttributes() )
{
m_out->Print( aNestLevel+1, "(attr" );
if( aFootprint->GetAttributes() & FP_SMD )
m_out->Print( 0, " smd" );
if( aFootprint->GetAttributes() & FP_THROUGH_HOLE )
m_out->Print( 0, " through_hole" );
if( aFootprint->GetAttributes() & FP_BOARD_ONLY )
m_out->Print( 0, " board_only" );
if( aFootprint->GetAttributes() & FP_EXCLUDE_FROM_POS_FILES )
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m_out->Print( 0, " exclude_from_pos_files" );
if( aFootprint->GetAttributes() & FP_EXCLUDE_FROM_BOM )
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m_out->Print( 0, " exclude_from_bom" );
m_out->Print( 0, ")\n" );
}
Format( (BOARD_ITEM*) &aFootprint->Reference(), aNestLevel + 1 );
Format( (BOARD_ITEM*) &aFootprint->Value(), aNestLevel + 1 );
2020-11-13 15:15:52 +00:00
std::set<PAD*, FOOTPRINT::cmp_pads> sorted_pads( aFootprint->Pads().begin(),
aFootprint->Pads().end() );
std::set<BOARD_ITEM*, FOOTPRINT::cmp_drawings> sorted_drawings(
aFootprint->GraphicalItems().begin(),
aFootprint->GraphicalItems().end() );
std::set<BOARD_ITEM*, BOARD_ITEM::ptr_cmp> sorted_zones( aFootprint->Zones().begin(),
aFootprint->Zones().end() );
std::set<BOARD_ITEM*, PCB_GROUP::ptr_cmp> sorted_groups( aFootprint->Groups().begin(),
aFootprint->Groups().end() );
// Save drawing elements.
for( BOARD_ITEM* gr : sorted_drawings )
Format( gr, aNestLevel+1 );
// Save pads.
2020-11-12 22:30:02 +00:00
for( PAD* pad : sorted_pads )
Format( pad, aNestLevel+1 );
// Save zones.
for( BOARD_ITEM* zone : sorted_zones )
Format( zone, aNestLevel + 1 );
// Save groups.
for( BOARD_ITEM* group : sorted_groups )
Format( group, aNestLevel + 1 );
// Save 3D info.
auto bs3D = aFootprint->Models().begin();
auto es3D = aFootprint->Models().end();
while( bs3D != es3D )
{
if( !bs3D->m_Filename.IsEmpty() )
{
m_out->Print( aNestLevel+1, "(model %s%s\n",
m_out->Quotew( bs3D->m_Filename ).c_str(),
bs3D->m_Show ? "" : " hide" );
if( bs3D->m_Opacity != 1.0 )
m_out->Print( aNestLevel+2, "(opacity %0.4f)", bs3D->m_Opacity );
m_out->Print( aNestLevel+2, "(offset (xyz %s %s %s))\n",
Double2Str( bs3D->m_Offset.x ).c_str(),
Double2Str( bs3D->m_Offset.y ).c_str(),
Double2Str( bs3D->m_Offset.z ).c_str() );
m_out->Print( aNestLevel+2, "(scale (xyz %s %s %s))\n",
Double2Str( bs3D->m_Scale.x ).c_str(),
Double2Str( bs3D->m_Scale.y ).c_str(),
Double2Str( bs3D->m_Scale.z ).c_str() );
m_out->Print( aNestLevel+2, "(rotate (xyz %s %s %s))\n",
Double2Str( bs3D->m_Rotation.x ).c_str(),
Double2Str( bs3D->m_Rotation.y ).c_str(),
Double2Str( bs3D->m_Rotation.z ).c_str() );
m_out->Print( aNestLevel+1, ")\n" );
}
++bs3D;
}
m_out->Print( aNestLevel, ")\n" );
}
void PCB_IO::formatLayers( LSET aLayerMask, int aNestLevel ) const
{
2020-12-20 18:50:45 +00:00
std::string output;
if( aNestLevel == 0 )
output += ' ';
output += "(layers";
static const LSET cu_all( LSET::AllCuMask() );
static const LSET fr_bk( 2, B_Cu, F_Cu );
static const LSET adhes( 2, B_Adhes, F_Adhes );
static const LSET paste( 2, B_Paste, F_Paste );
static const LSET silks( 2, B_SilkS, F_SilkS );
static const LSET mask( 2, B_Mask, F_Mask );
static const LSET crt_yd( 2, B_CrtYd, F_CrtYd );
static const LSET fab( 2, B_Fab, F_Fab );
LSET cu_mask = cu_all;
// output copper layers first, then non copper
if( ( aLayerMask & cu_mask ) == cu_mask )
{
output += " *.Cu";
aLayerMask &= ~cu_all; // clear bits, so they are not output again below
}
else if( ( aLayerMask & cu_mask ) == fr_bk )
{
output += " F&B.Cu";
aLayerMask &= ~fr_bk;
}
if( ( aLayerMask & adhes ) == adhes )
{
output += " *.Adhes";
aLayerMask &= ~adhes;
}
if( ( aLayerMask & paste ) == paste )
{
output += " *.Paste";
aLayerMask &= ~paste;
}
if( ( aLayerMask & silks ) == silks )
{
output += " *.SilkS";
aLayerMask &= ~silks;
}
if( ( aLayerMask & mask ) == mask )
{
output += " *.Mask";
aLayerMask &= ~mask;
}
if( ( aLayerMask & crt_yd ) == crt_yd )
{
output += " *.CrtYd";
aLayerMask &= ~crt_yd;
}
if( ( aLayerMask & fab ) == fab )
{
output += " *.Fab";
aLayerMask &= ~fab;
}
// output any individual layers not handled in wildcard combos above
wxString layerName;
for( LAYER_NUM layer = 0; layer < PCB_LAYER_ID_COUNT; ++layer )
{
if( aLayerMask[layer] )
{
layerName = LSET::Name( PCB_LAYER_ID( layer ) );
output += ' ';
output += m_out->Quotew( layerName );
}
}
m_out->Print( aNestLevel, "%s)", output.c_str() );
}
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void PCB_IO::format( const PAD* aPad, int aNestLevel ) const
{
const char* shape;
switch( aPad->GetShape() )
{
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case PAD_SHAPE::CIRCLE: shape = "circle"; break;
case PAD_SHAPE::RECT: shape = "rect"; break;
case PAD_SHAPE::OVAL: shape = "oval"; break;
case PAD_SHAPE::TRAPEZOID: shape = "trapezoid"; break;
case PAD_SHAPE::CHAMFERED_RECT:
case PAD_SHAPE::ROUNDRECT: shape = "roundrect"; break;
case PAD_SHAPE::CUSTOM: shape = "custom"; break;
default:
THROW_IO_ERROR( wxString::Format( _( "unknown pad type: %d"), aPad->GetShape() ) );
}
const char* type;
switch( aPad->GetAttribute() )
{
case PAD_ATTRIB::PTH: type = "thru_hole"; break;
case PAD_ATTRIB::SMD: type = "smd"; break;
case PAD_ATTRIB::CONN: type = "connect"; break;
case PAD_ATTRIB::NPTH: type = "np_thru_hole"; break;
default:
THROW_IO_ERROR( wxString::Format( "unknown pad attribute: %d", aPad->GetAttribute() ) );
}
const char* property = nullptr;
switch( aPad->GetProperty() )
{
case PAD_PROP::NONE: break; // could be "none"
case PAD_PROP::BGA: property = "PAD_PROP::BGA"; break;
case PAD_PROP::FIDUCIAL_GLBL: property = "pad_prop_fiducial_glob"; break;
case PAD_PROP::FIDUCIAL_LOCAL: property = "pad_prop_fiducial_loc"; break;
case PAD_PROP::TESTPOINT: property = "PAD_PROP::TESTPOINT"; break;
case PAD_PROP::HEATSINK: property = "PAD_PROP::HEATSINK"; break;
case PAD_PROP::CASTELLATED: property = "PAD_PROP::CASTELLATED"; break;
default:
THROW_IO_ERROR( wxString::Format( "unknown pad property: %d", aPad->GetProperty() ) );
}
m_out->Print( aNestLevel, "(pad %s %s %s",
m_out->Quotew( aPad->GetName() ).c_str(),
type,
shape );
if( aPad->IsLocked() )
m_out->Print( 0, " locked" );
m_out->Print( 0, " (at %s", FormatInternalUnits( aPad->GetPos0() ).c_str() );
if( aPad->GetOrientation() != 0.0 )
m_out->Print( 0, " %s", FormatAngle( aPad->GetOrientation() ).c_str() );
m_out->Print( 0, ")" );
m_out->Print( 0, " (size %s)", FormatInternalUnits( aPad->GetSize() ).c_str() );
if( (aPad->GetDelta().GetWidth()) != 0 || (aPad->GetDelta().GetHeight() != 0 ) )
m_out->Print( 0, " (rect_delta %s)", FormatInternalUnits( aPad->GetDelta() ).c_str() );
wxSize sz = aPad->GetDrillSize();
wxPoint shapeoffset = aPad->GetOffset();
if( (sz.GetWidth() > 0) || (sz.GetHeight() > 0) ||
(shapeoffset.x != 0) || (shapeoffset.y != 0) )
{
m_out->Print( 0, " (drill" );
if( aPad->GetDrillShape() == PAD_DRILL_SHAPE_OBLONG )
m_out->Print( 0, " oval" );
if( sz.GetWidth() > 0 )
m_out->Print( 0, " %s", FormatInternalUnits( sz.GetWidth() ).c_str() );
if( sz.GetHeight() > 0 && sz.GetWidth() != sz.GetHeight() )
m_out->Print( 0, " %s", FormatInternalUnits( sz.GetHeight() ).c_str() );
if( (shapeoffset.x != 0) || (shapeoffset.y != 0) )
m_out->Print( 0, " (offset %s)", FormatInternalUnits( aPad->GetOffset() ).c_str() );
m_out->Print( 0, ")" );
}
// Add pad property, if exists.
if( property )
m_out->Print( 0, " (property %s)", property );
formatLayers( aPad->GetLayerSet() );
if( aPad->GetAttribute() == PAD_ATTRIB::PTH )
{
if( aPad->GetRemoveUnconnected() )
{
m_out->Print( 0, " (remove_unused_layers)" );
if( aPad->GetKeepTopBottom() )
m_out->Print( 0, " (keep_end_layers)" );
}
}
// Output the radius ratio for rounded and chamfered rect pads
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if( aPad->GetShape() == PAD_SHAPE::ROUNDRECT || aPad->GetShape() == PAD_SHAPE::CHAMFERED_RECT)
{
m_out->Print( 0, " (roundrect_rratio %s)",
Double2Str( aPad->GetRoundRectRadiusRatio() ).c_str() );
}
// Output the chamfer corners for chamfered rect pads
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if( aPad->GetShape() == PAD_SHAPE::CHAMFERED_RECT)
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+1, "(chamfer_ratio %s)",
Double2Str( aPad->GetChamferRectRatio() ).c_str() );
m_out->Print( 0, " (chamfer" );
if( ( aPad->GetChamferPositions() & RECT_CHAMFER_TOP_LEFT ) )
m_out->Print( 0, " top_left" );
if( ( aPad->GetChamferPositions() & RECT_CHAMFER_TOP_RIGHT ) )
m_out->Print( 0, " top_right" );
if( ( aPad->GetChamferPositions() & RECT_CHAMFER_BOTTOM_LEFT ) )
m_out->Print( 0, " bottom_left" );
if( ( aPad->GetChamferPositions() & RECT_CHAMFER_BOTTOM_RIGHT ) )
m_out->Print( 0, " bottom_right" );
m_out->Print( 0, ")" );
}
std::string output;
// Unconnected pad is default net so don't save it.
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if( !( m_ctl & CTL_OMIT_PAD_NETS ) && aPad->GetNetCode() != NETINFO_LIST::UNCONNECTED )
{
StrPrintf( &output, " (net %d %s)", m_mapping->Translate( aPad->GetNetCode() ),
m_out->Quotew( aPad->GetNetname() ).c_str() );
}
// Pin functions and types are closely related to nets, so if CTL_OMIT_NETS is set, omit
// them as well (for instance when saved from library editor).
if( !( m_ctl & CTL_OMIT_PAD_NETS ) )
{
if( !aPad->GetPinFunction().IsEmpty() )
{
StrPrintf( &output, " (pinfunction %s)",
m_out->Quotew( aPad->GetPinFunction() ).c_str() );
}
if( !aPad->GetPinType().IsEmpty() )
{
StrPrintf( &output, " (pintype %s)",
m_out->Quotew( aPad->GetPinType() ).c_str() );
}
}
if( aPad->GetPadToDieLength() != 0 )
{
StrPrintf( &output, " (die_length %s)",
FormatInternalUnits( aPad->GetPadToDieLength() ).c_str() );
}
if( aPad->GetLocalSolderMaskMargin() != 0 )
{
StrPrintf( &output, " (solder_mask_margin %s)",
FormatInternalUnits( aPad->GetLocalSolderMaskMargin() ).c_str() );
}
if( aPad->GetLocalSolderPasteMargin() != 0 )
{
StrPrintf( &output, " (solder_paste_margin %s)",
FormatInternalUnits( aPad->GetLocalSolderPasteMargin() ).c_str() );
}
if( aPad->GetLocalSolderPasteMarginRatio() != 0 )
{
StrPrintf( &output, " (solder_paste_margin_ratio %s)",
Double2Str( aPad->GetLocalSolderPasteMarginRatio() ).c_str() );
}
if( aPad->GetLocalClearance() != 0 )
{
StrPrintf( &output, " (clearance %s)",
FormatInternalUnits( aPad->GetLocalClearance() ).c_str() );
}
if( aPad->GetEffectiveZoneConnection() != ZONE_CONNECTION::INHERITED )
{
StrPrintf( &output, " (zone_connect %d)",
static_cast<int>( aPad->GetEffectiveZoneConnection() ) );
}
if( aPad->GetThermalSpokeWidth() != 0 )
{
StrPrintf( &output, " (thermal_width %s)",
FormatInternalUnits( aPad->GetThermalSpokeWidth() ).c_str() );
}
if( aPad->GetThermalGap() != 0 )
{
StrPrintf( &output, " (thermal_gap %s)",
FormatInternalUnits( aPad->GetThermalGap() ).c_str() );
}
if( output.size() )
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+1, "%s", output.c_str()+1 ); // +1 skips 1st space on 1st element
}
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if( aPad->GetShape() == PAD_SHAPE::CUSTOM )
{
m_out->Print( 0, "\n");
m_out->Print( aNestLevel+1, "(options" );
if( aPad->GetCustomShapeInZoneOpt() == CUST_PAD_SHAPE_IN_ZONE_CONVEXHULL )
m_out->Print( 0, " (clearance convexhull)" );
#if 1 // Set to 1 to output the default option
else
m_out->Print( 0, " (clearance outline)" );
#endif
// Output the anchor pad shape (circle/rect)
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if( aPad->GetAnchorPadShape() == PAD_SHAPE::RECT )
shape = "rect";
else
shape = "circle";
m_out->Print( 0, " (anchor %s)", shape );
m_out->Print( 0, ")"); // end of (options ...
// Output graphic primitive of the pad shape
m_out->Print( 0, "\n");
m_out->Print( aNestLevel+1, "(primitives" );
int nested_level = aNestLevel+2;
// Output all basic shapes
for( const std::shared_ptr<PCB_SHAPE>& primitive : aPad->GetPrimitives() )
{
m_out->Print( 0, "\n");
switch( primitive->GetShape() )
{
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case PCB_SHAPE_TYPE::SEGMENT: // usual segment : line with rounded ends
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m_out->Print( nested_level, "(gr_line (start %s) (end %s)",
FormatInternalUnits( primitive->GetStart() ).c_str(),
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FormatInternalUnits( primitive->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::RECT:
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m_out->Print( nested_level, "(gr_rect (start %s) (end %s)",
FormatInternalUnits( primitive->GetStart() ).c_str(),
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FormatInternalUnits( primitive->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::ARC: // Arc with rounded ends
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m_out->Print( nested_level, "(gr_arc (start %s) (end %s) (angle %s)",
FormatInternalUnits( primitive->GetStart() ).c_str(),
FormatInternalUnits( primitive->GetEnd() ).c_str(),
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FormatAngle( primitive->GetAngle() ).c_str() );
break;
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case PCB_SHAPE_TYPE::CIRCLE: // ring or circle (circle if width == 0
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m_out->Print( nested_level, "(gr_circle (center %s) (end %s)",
FormatInternalUnits( primitive->GetStart() ).c_str(),
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FormatInternalUnits( primitive->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::CURVE: // Bezier Curve
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m_out->Print( nested_level, "(gr_curve (pts (xy %s) (xy %s) (xy %s) (xy %s))",
FormatInternalUnits( primitive->GetStart() ).c_str(),
FormatInternalUnits( primitive->GetBezControl1() ).c_str(),
FormatInternalUnits( primitive->GetBezControl2() ).c_str(),
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FormatInternalUnits( primitive->GetEnd() ).c_str() );
break;
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case PCB_SHAPE_TYPE::POLYGON: // polygon
if( primitive->GetPolyShape().COutline( 0 ).CPoints().size() < 2 )
break; // Malformed polygon.
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{
m_out->Print( nested_level, "(gr_poly (pts\n");
// Write the polygon corners coordinates:
int newLine = 0;
for( const VECTOR2I &pt : primitive->GetPolyShape().COutline( 0 ).CPoints() )
{
if( newLine == 0 )
m_out->Print( nested_level+1, "(xy %s)",
FormatInternalUnits( (wxPoint) pt ).c_str() );
else
m_out->Print( 0, " (xy %s)",
FormatInternalUnits( (wxPoint) pt ).c_str() );
if( ++newLine > 4 || !ADVANCED_CFG::GetCfg().m_CompactSave )
{
newLine = 0;
m_out->Print( 0, "\n" );
}
}
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m_out->Print( newLine ? 0 : nested_level, ")" );
}
break;
default:
break;
}
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m_out->Print( 0, " (width %s)",
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FormatInternalUnits( primitive->GetWidth() ).c_str() );
if( primitive->IsFilled() )
m_out->Print( 0, " (fill yes)" );
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m_out->Print( 0, ")" );
}
m_out->Print( 0, "\n");
m_out->Print( aNestLevel+1, ")" ); // end of (basic_shapes
}
m_out->Print( 0, " (tstamp %s)", TO_UTF8( aPad->m_Uuid.AsString() ) );
m_out->Print( 0, ")\n" );
}
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void PCB_IO::format( const PCB_TEXT* aText, int aNestLevel ) const
{
m_out->Print( aNestLevel, "(gr_text %s (at %s",
m_out->Quotew( aText->GetText() ).c_str(),
FormatInternalUnits( aText->GetTextPos() ).c_str() );
if( aText->GetTextAngle() != 0.0 )
m_out->Print( 0, " %s", FormatAngle( aText->GetTextAngle() ).c_str() );
m_out->Print( 0, ")" );
formatLayer( aText );
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m_out->Print( 0, " (tstamp %s)", TO_UTF8( aText->m_Uuid.AsString() ) );
m_out->Print( 0, "\n" );
// PCB_TEXTS are never hidden, so always omit "hide" attribute
aText->EDA_TEXT::Format( m_out, aNestLevel, m_ctl | CTL_OMIT_HIDE );
m_out->Print( aNestLevel, ")\n" );
}
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void PCB_IO::format( const PCB_GROUP* aGroup, int aNestLevel ) const
{
// Don't write empty groups
if( aGroup->GetItems().empty() )
return;
m_out->Print( aNestLevel, "(group %s (id %s)\n",
m_out->Quotew( aGroup->GetName() ).c_str(),
TO_UTF8( aGroup->m_Uuid.AsString() ) );
m_out->Print( aNestLevel + 1, "(members\n" );
wxArrayString memberIds;
for( BOARD_ITEM* member : aGroup->GetItems() )
memberIds.Add( member->m_Uuid.AsString() );
memberIds.Sort();
for( const wxString& memberId : memberIds )
m_out->Print( aNestLevel + 2, "%s\n", TO_UTF8( memberId ) );
m_out->Print( aNestLevel + 1, ")\n" ); // Close `members` token.
m_out->Print( aNestLevel, ")\n" ); // Close `group` token.
}
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void PCB_IO::format( const FP_TEXT* aText, int aNestLevel ) const
{
std::string type;
switch( aText->GetType() )
{
case FP_TEXT::TEXT_is_REFERENCE: type = "reference"; break;
case FP_TEXT::TEXT_is_VALUE: type = "value"; break;
case FP_TEXT::TEXT_is_DIVERS: type = "user";
}
m_out->Print( aNestLevel, "(fp_text %s %s (at %s",
type.c_str(),
m_out->Quotew( aText->GetText() ).c_str(),
FormatInternalUnits( aText->GetPos0() ).c_str() );
// Due to Pcbnew history, fp_text angle is saved as an absolute on screen angle,
// but internally the angle is held relative to its parent footprint. parent
// may be NULL when saving a footprint outside a BOARD.
double orient = aText->GetTextAngle();
2020-11-13 15:15:52 +00:00
FOOTPRINT* parent = (FOOTPRINT*) aText->GetParent();
if( parent )
{
// GetTextAngle() is always in -360..+360 range because of
// FP_TEXT::SetTextAngle(), but summing that angle with an
// additional board angle could kick sum up >= 360 or <= -360, so to have
// consistent results, normalize again for the BOARD save. A footprint
// save does not use this code path since parent is NULL.
#if 0
// This one could be considered reasonable if you like positive angles
// in your board text.
orient = NormalizeAnglePos( orient + parent->GetOrientation() );
#else
// Choose compatibility for now, even though this is only a 720 degree clamp
// with two possible values for every angle.
orient = NormalizeAngle360Min( orient + parent->GetOrientation() );
#endif
}
if( orient != 0.0 )
m_out->Print( 0, " %s", FormatAngle( orient ).c_str() );
if( !aText->IsKeepUpright() )
m_out->Print( 0, " unlocked" );
m_out->Print( 0, ")" );
formatLayer( aText );
if( !aText->IsVisible() )
m_out->Print( 0, " hide" );
m_out->Print( 0, "\n" );
aText->EDA_TEXT::Format( m_out, aNestLevel, m_ctl | CTL_OMIT_HIDE );
m_out->Print( aNestLevel + 1, "(tstamp %s)\n", TO_UTF8( aText->m_Uuid.AsString() ) );
m_out->Print( aNestLevel, ")\n" );
}
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void PCB_IO::format( const PCB_TRACK* aTrack, int aNestLevel ) const
{
if( aTrack->Type() == PCB_VIA_T )
{
PCB_LAYER_ID layer1, layer2;
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const PCB_VIA* via = static_cast<const PCB_VIA*>( aTrack );
BOARD* board = (BOARD*) via->GetParent();
wxCHECK_RET( board != nullptr, wxT( "Via " ) +
via->GetSelectMenuText( EDA_UNITS::MILLIMETRES ) + wxT( " has no parent." ) );
m_out->Print( aNestLevel, "(via" );
via->LayerPair( &layer1, &layer2 );
switch( via->GetViaType() )
{
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case VIATYPE::THROUGH: // Default shape not saved.
break;
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case VIATYPE::BLIND_BURIED:
m_out->Print( 0, " blind" );
break;
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case VIATYPE::MICROVIA:
m_out->Print( 0, " micro" );
break;
default:
THROW_IO_ERROR( wxString::Format( _( "unknown via type %d" ), via->GetViaType() ) );
}
if( via->IsLocked() )
m_out->Print( 0, " locked" );
m_out->Print( 0, " (at %s) (size %s)",
FormatInternalUnits( aTrack->GetStart() ).c_str(),
FormatInternalUnits( aTrack->GetWidth() ).c_str() );
// Old boards were using UNDEFINED_DRILL_DIAMETER value in file for via drill when
// via drill was the netclass value.
// recent boards always set the via drill to the actual value, but now we need to
// always store the drill value, because netclass value is not stored in the board file.
// Otherwise the drill value of some (old) vias can be unknown
if( via->GetDrill() != UNDEFINED_DRILL_DIAMETER )
m_out->Print( 0, " (drill %s)", FormatInternalUnits( via->GetDrill() ).c_str() );
else // Probably old board!
m_out->Print( 0, " (drill %s)", FormatInternalUnits( via->GetDrillValue() ).c_str() );
m_out->Print( 0, " (layers %s %s)",
m_out->Quotew( LSET::Name( layer1 ) ).c_str(),
m_out->Quotew( LSET::Name( layer2 ) ).c_str() );
if( via->GetRemoveUnconnected() )
{
m_out->Print( 0, " (remove_unused_layers)" );
if( via->GetKeepTopBottom() )
m_out->Print( 0, " (keep_end_layers)" );
}
if( via->GetIsFree() )
m_out->Print( 0, " (free)" );
}
else if( aTrack->Type() == PCB_ARC_T )
{
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const PCB_ARC* arc = static_cast<const PCB_ARC*>( aTrack );
std::string locked = arc->IsLocked() ? " locked" : "";
m_out->Print( aNestLevel, "(arc%s (start %s) (mid %s) (end %s) (width %s)",
locked.c_str(),
FormatInternalUnits( arc->GetStart() ).c_str(),
FormatInternalUnits( arc->GetMid() ).c_str(),
FormatInternalUnits( arc->GetEnd() ).c_str(),
FormatInternalUnits( arc->GetWidth() ).c_str() );
m_out->Print( 0, " (layer %s)", m_out->Quotew( LSET::Name( arc->GetLayer() ) ).c_str() );
}
else
{
std::string locked = aTrack->IsLocked() ? " locked" : "";
m_out->Print( aNestLevel, "(segment%s (start %s) (end %s) (width %s)",
locked.c_str(),
FormatInternalUnits( aTrack->GetStart() ).c_str(),
FormatInternalUnits( aTrack->GetEnd() ).c_str(),
FormatInternalUnits( aTrack->GetWidth() ).c_str() );
m_out->Print( 0, " (layer %s)", m_out->Quotew( LSET::Name( aTrack->GetLayer() ) ).c_str() );
}
m_out->Print( 0, " (net %d)", m_mapping->Translate( aTrack->GetNetCode() ) );
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m_out->Print( 0, " (tstamp %s)", TO_UTF8( aTrack->m_Uuid.AsString() ) );
m_out->Print( 0, ")\n" );
}
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void PCB_IO::format( const ZONE* aZone, int aNestLevel ) const
{
std::string locked = aZone->IsLocked() ? " locked" : "";
// Save the NET info; For keepout zones, net code and net name are irrelevant
// so be sure a dummy value is stored, just for ZONE compatibility
// (perhaps netcode and netname should be not stored)
m_out->Print( aNestLevel, "(zone%s (net %d) (net_name %s)",
locked.c_str(),
aZone->GetIsRuleArea() ? 0 : m_mapping->Translate( aZone->GetNetCode() ),
m_out->Quotew( aZone->GetIsRuleArea() ? wxT("") : aZone->GetNetname() ).c_str() );
// If a zone exists on multiple layers, format accordingly
if( aZone->GetLayerSet().count() > 1 )
{
formatLayers( aZone->GetLayerSet() );
}
else
{
formatLayer( aZone );
}
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m_out->Print( 0, " (tstamp %s)", TO_UTF8( aZone->m_Uuid.AsString() ) );
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if( !aZone->GetZoneName().empty() )
m_out->Print( 0, " (name %s)", m_out->Quotew( aZone->GetZoneName() ).c_str() );
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// Save the outline aux info
std::string hatch;
switch( aZone->GetHatchStyle() )
{
default:
case ZONE_BORDER_DISPLAY_STYLE::NO_HATCH: hatch = "none"; break;
case ZONE_BORDER_DISPLAY_STYLE::DIAGONAL_EDGE: hatch = "edge"; break;
case ZONE_BORDER_DISPLAY_STYLE::DIAGONAL_FULL: hatch = "full"; break;
}
m_out->Print( 0, " (hatch %s %s)\n", hatch.c_str(),
FormatInternalUnits( aZone->GetBorderHatchPitch() ).c_str() );
if( aZone->GetPriority() > 0 )
m_out->Print( aNestLevel+1, "(priority %d)\n", aZone->GetPriority() );
m_out->Print( aNestLevel+1, "(connect_pads" );
switch( aZone->GetPadConnection() )
{
default:
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case ZONE_CONNECTION::THERMAL: // Default option not saved or loaded.
break;
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case ZONE_CONNECTION::THT_THERMAL:
m_out->Print( 0, " thru_hole_only" );
break;
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case ZONE_CONNECTION::FULL:
m_out->Print( 0, " yes" );
break;
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case ZONE_CONNECTION::NONE:
m_out->Print( 0, " no" );
break;
}
m_out->Print( 0, " (clearance %s))\n",
FormatInternalUnits( aZone->GetLocalClearance() ).c_str() );
m_out->Print( aNestLevel+1, "(min_thickness %s)",
FormatInternalUnits( aZone->GetMinThickness() ).c_str() );
// write it only if V 6.O version option is used (i.e. do not write if the "legacy"
// algorithm is used)
if( !aZone->GetFilledPolysUseThickness() )
m_out->Print( 0, " (filled_areas_thickness no)" );
m_out->Print( 0, "\n" );
if( aZone->GetIsRuleArea() )
{
m_out->Print( aNestLevel + 1,
"(keepout (tracks %s) (vias %s) (pads %s ) (copperpour %s) "
"(footprints %s))\n",
aZone->GetDoNotAllowTracks() ? "not_allowed" : "allowed",
aZone->GetDoNotAllowVias() ? "not_allowed" : "allowed",
aZone->GetDoNotAllowPads() ? "not_allowed" : "allowed",
aZone->GetDoNotAllowCopperPour() ? "not_allowed" : "allowed",
aZone->GetDoNotAllowFootprints() ? "not_allowed" : "allowed" );
}
m_out->Print( aNestLevel + 1, "(fill" );
// Default is not filled.
if( aZone->IsFilled() )
m_out->Print( 0, " yes" );
// Default is polygon filled.
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if( aZone->GetFillMode() == ZONE_FILL_MODE::HATCH_PATTERN )
m_out->Print( 0, " (mode hatch)" );
m_out->Print( 0, " (thermal_gap %s) (thermal_bridge_width %s)",
FormatInternalUnits( aZone->GetThermalReliefGap() ).c_str(),
FormatInternalUnits( aZone->GetThermalReliefSpokeWidth() ).c_str() );
if( aZone->GetCornerSmoothingType() != ZONE_SETTINGS::SMOOTHING_NONE )
{
m_out->Print( 0, " (smoothing" );
switch( aZone->GetCornerSmoothingType() )
{
case ZONE_SETTINGS::SMOOTHING_CHAMFER:
m_out->Print( 0, " chamfer" );
break;
case ZONE_SETTINGS::SMOOTHING_FILLET:
m_out->Print( 0, " fillet" );
break;
default:
THROW_IO_ERROR( wxString::Format( _( "unknown zone corner smoothing type %d" ),
aZone->GetCornerSmoothingType() ) );
}
m_out->Print( 0, ")" );
if( aZone->GetCornerRadius() != 0 )
m_out->Print( 0, " (radius %s)",
FormatInternalUnits( aZone->GetCornerRadius() ).c_str() );
}
if( aZone->GetIslandRemovalMode() != ISLAND_REMOVAL_MODE::ALWAYS )
{
m_out->Print( 0, " (island_removal_mode %d) (island_area_min %s)",
static_cast<int>( aZone->GetIslandRemovalMode() ),
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FormatInternalUnits( aZone->GetMinIslandArea() / IU_PER_MM ).c_str() );
}
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if( aZone->GetFillMode() == ZONE_FILL_MODE::HATCH_PATTERN )
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+2, "(hatch_thickness %s) (hatch_gap %s) (hatch_orientation %s)",
FormatInternalUnits( aZone->GetHatchThickness() ).c_str(),
FormatInternalUnits( aZone->GetHatchGap() ).c_str(),
Double2Str( aZone->GetHatchOrientation() ).c_str() );
if( aZone->GetHatchSmoothingLevel() > 0 )
{
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+2, "(hatch_smoothing_level %d) (hatch_smoothing_value %s)",
aZone->GetHatchSmoothingLevel(),
Double2Str( aZone->GetHatchSmoothingValue() ).c_str() );
}
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+2, "(hatch_border_algorithm %s) (hatch_min_hole_area %s)",
aZone->GetHatchBorderAlgorithm() ? "hatch_thickness" : "min_thickness",
Double2Str( aZone->GetHatchHoleMinArea() ).c_str() );
}
m_out->Print( 0, ")\n" );
if( aZone->GetNumCorners() )
{
SHAPE_POLY_SET::POLYGON poly = aZone->Outline()->Polygon(0);
for( auto& chain : poly )
{
m_out->Print( aNestLevel + 1, "(polygon\n" );
m_out->Print( aNestLevel + 2, "(pts" );
bool need_newline = true;
for( int ii = 0; ii < chain.PointCount(); ++ii )
{
int nestLevel = 0;
if( !( ii % 4 ) || !ADVANCED_CFG::GetCfg().m_CompactSave ) // newline every 4 pts
{
nestLevel = aNestLevel + 3;
m_out->Print( 0, "\n" );
need_newline = false;
}
int ind = chain.ArcIndex( ii );
if( ind < 0 )
{
m_out->Print( nestLevel, "%s(xy %s)",
nestLevel ? "" : " ",
FormatInternalUnits( chain.CPoint( ii ) ).c_str() );
need_newline = true;
}
else
{
auto& arc = chain.Arc( ind );
m_out->Print( aNestLevel, "%s(arc (start %s) (mid %s) (end %s))",
nestLevel ? "" : " ",
FormatInternalUnits( arc.GetP0() ).c_str(),
FormatInternalUnits( arc.GetArcMid() ).c_str(),
FormatInternalUnits( arc.GetP1() ).c_str() );
need_newline = true;
do
{
++ii;
} while( ii < chain.PointCount() && chain.ArcIndex( ii ) == ind );
--ii;
}
}
if( need_newline )
m_out->Print( 0, "\n" );
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m_out->Print( aNestLevel + 2, ")\n" );
m_out->Print( aNestLevel + 1, ")\n" );
}
}
// Save the PolysList (filled areas)
for( PCB_LAYER_ID layer : aZone->GetLayerSet().Seq() )
{
const SHAPE_POLY_SET& fv = aZone->GetFilledPolysList( layer );
for( int ii = 0; ii < fv.OutlineCount(); ++ii )
{
m_out->Print( aNestLevel + 1, "(filled_polygon\n" );
m_out->Print( aNestLevel + 2, "(layer %s)\n",
m_out->Quotew( LSET::Name( layer ) ).c_str() );
if( aZone->IsIsland( layer, ii ) )
m_out->Print( aNestLevel + 2, "(island)\n" );
m_out->Print( aNestLevel + 2, "(pts" );
const SHAPE_LINE_CHAIN& chain = fv.COutline( ii );
bool need_newline = true;
for( int jj = 0; jj < chain.PointCount(); ++jj )
{
int nestLevel = 0;
if( !( jj%4 ) || !ADVANCED_CFG::GetCfg().m_CompactSave ) // newline every 4 pts
{
nestLevel = aNestLevel + 3;
m_out->Print( 0, "\n" );
need_newline = false;
}
int ind = chain.ArcIndex( jj );
if( ind < 0 )
{
m_out->Print( nestLevel, "%s(xy %s)",
nestLevel ? "" : " ",
FormatInternalUnits( chain.CPoint( jj ) ).c_str() );
need_newline = true;
}
else
{
auto& arc = chain.Arc( ind );
m_out->Print( aNestLevel, "%s(arc (start %s) (mid %s) (end %s))",
nestLevel ? "" : " ",
FormatInternalUnits( arc.GetP0() ).c_str(),
FormatInternalUnits( arc.GetArcMid() ).c_str(),
FormatInternalUnits( arc.GetP1() ).c_str() );
need_newline = true;
do
{
++jj;
} while( jj < chain.PointCount() && chain.ArcIndex( jj ) == ind );
--jj;
}
}
if( need_newline )
m_out->Print( 0, "\n" );
m_out->Print( aNestLevel+2, ")\n" );
m_out->Print( aNestLevel+1, ")\n" );
}
// Save the filling segments list
const auto& segs = aZone->FillSegments( layer );
if( segs.size() )
{
m_out->Print( aNestLevel + 1, "(fill_segments\n" );
m_out->Print( aNestLevel + 2, "(layer %s)\n",
TO_UTF8( BOARD::GetStandardLayerName( layer ) ) );
for( ZONE_SEGMENT_FILL::const_iterator it = segs.begin(); it != segs.end(); ++it )
{
m_out->Print( aNestLevel + 2, "(pts (xy %s) (xy %s))\n",
FormatInternalUnits( wxPoint( it->A ) ).c_str(),
FormatInternalUnits( wxPoint( it->B ) ).c_str() );
}
m_out->Print( aNestLevel + 1, ")\n" );
}
}
m_out->Print( aNestLevel, ")\n" );
}
PCB_IO::PCB_IO( int aControlFlags ) :
m_cache( nullptr ),
m_ctl( aControlFlags ),
m_parser( new PCB_PARSER() ),
m_mapping( new NETINFO_MAPPING() )
{
init( nullptr );
m_out = &m_sf;
}
PCB_IO::~PCB_IO()
{
delete m_cache;
delete m_parser;
delete m_mapping;
}
BOARD* PCB_IO::Load( const wxString& aFileName, BOARD* aAppendToMe, const PROPERTIES* aProperties,
PROJECT* aProject, PROGRESS_REPORTER* aProgressReporter )
{
FILE_LINE_READER reader( aFileName );
unsigned lineCount = 0;
if( aProgressReporter )
{
aProgressReporter->Report( wxString::Format( _( "Loading %s..." ), aFileName ) );
if( !aProgressReporter->KeepRefreshing() )
THROW_IO_ERROR( _( "Open cancelled by user." ) );
while( reader.ReadLine() )
lineCount++;
reader.Rewind();
}
BOARD* board = DoLoad( reader, aAppendToMe, aProperties, aProgressReporter, lineCount );
// Give the filename to the board if it's new
if( !aAppendToMe )
board->SetFileName( aFileName );
return board;
}
BOARD* PCB_IO::DoLoad( LINE_READER& aReader, BOARD* aAppendToMe, const PROPERTIES* aProperties,
PROGRESS_REPORTER* aProgressReporter, unsigned aLineCount)
{
init( aProperties );
m_parser->SetLineReader( &aReader );
m_parser->SetBoard( aAppendToMe );
m_parser->SetProgressReporter( aProgressReporter, &aReader, aLineCount );
BOARD* board;
try
{
board = dynamic_cast<BOARD*>( m_parser->Parse() );
}
catch( const FUTURE_FORMAT_ERROR& )
{
// Don't wrap a FUTURE_FORMAT_ERROR in another
throw;
}
catch( const PARSE_ERROR& parse_error )
{
if( m_parser->IsTooRecent() )
throw FUTURE_FORMAT_ERROR( parse_error, m_parser->GetRequiredVersion() );
else
throw;
}
if( !board )
{
// The parser loaded something that was valid, but wasn't a board.
THROW_PARSE_ERROR( _( "This file does not contain a PCB." ), m_parser->CurSource(),
m_parser->CurLine(), m_parser->CurLineNumber(), m_parser->CurOffset() );
}
return board;
}
void PCB_IO::init( const PROPERTIES* aProperties )
{
m_board = nullptr;
m_reader = nullptr;
m_props = aProperties;
}
void PCB_IO::validateCache( const wxString& aLibraryPath, bool checkModified )
{
if( !m_cache || !m_cache->IsPath( aLibraryPath ) || ( checkModified && m_cache->IsModified() ) )
{
// a spectacular episode in memory management:
delete m_cache;
m_cache = new FP_CACHE( this, aLibraryPath );
m_cache->Load();
}
}
void PCB_IO::FootprintEnumerate( wxArrayString& aFootprintNames, const wxString& aLibPath,
bool aBestEfforts, const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
wxDir dir( aLibPath );
wxString errorMsg;
init( aProperties );
try
{
validateCache( aLibPath );
}
catch( const IO_ERROR& ioe )
{
errorMsg = ioe.What();
}
// Some of the files may have been parsed correctly so we want to add the valid files to
// the library.
2020-11-14 19:16:42 +00:00
for( const auto& footprint : m_cache->GetFootprints() )
aFootprintNames.Add( footprint.first );
if( !errorMsg.IsEmpty() && !aBestEfforts )
THROW_IO_ERROR( errorMsg );
}
2020-11-13 15:15:52 +00:00
const FOOTPRINT* PCB_IO::getFootprint( const wxString& aLibraryPath,
const wxString& aFootprintName,
const PROPERTIES* aProperties,
bool checkModified )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
init( aProperties );
try
{
validateCache( aLibraryPath, checkModified );
}
catch( const IO_ERROR& )
{
// do nothing with the error
}
2020-11-14 19:16:42 +00:00
FOOTPRINT_MAP& footprints = m_cache->GetFootprints();
FOOTPRINT_MAP::const_iterator it = footprints.find( aFootprintName );
2020-11-14 19:16:42 +00:00
if( it == footprints.end() )
return nullptr;
return it->second->GetFootprint();
}
2020-11-13 15:15:52 +00:00
const FOOTPRINT* PCB_IO::GetEnumeratedFootprint( const wxString& aLibraryPath,
const wxString& aFootprintName,
const PROPERTIES* aProperties )
{
return getFootprint( aLibraryPath, aFootprintName, aProperties, false );
}
bool PCB_IO::FootprintExists( const wxString& aLibraryPath, const wxString& aFootprintName,
const PROPERTIES* aProperties )
{
// Note: checking the cache sounds like a good idea, but won't catch files which differ
// only in case.
//
// Since this goes out to the native filesystem, we get platform differences (ie: MSW's
// case-insensitive filesystem) handled "for free".
// Warning: footprint names frequently contain a point. So be careful when initializing
// wxFileName, and use a CTOR with extension specified
wxFileName footprintFile( aLibraryPath, aFootprintName, KiCadFootprintFileExtension );
return footprintFile.Exists();
}
FOOTPRINT* PCB_IO::FootprintLoad( const wxString& aLibraryPath,
const wxString& aFootprintName,
bool aKeepUUID,
2020-11-13 15:15:52 +00:00
const PROPERTIES* aProperties )
{
2020-11-13 15:15:52 +00:00
const FOOTPRINT* footprint = getFootprint( aLibraryPath, aFootprintName, aProperties, true );
if( footprint )
{
FOOTPRINT* copy;
if( aKeepUUID )
copy = static_cast<FOOTPRINT*>( footprint->Clone() );
else
copy = static_cast<FOOTPRINT*>( footprint->Duplicate() );
copy->SetParent( nullptr );
return copy;
}
return nullptr;
}
2020-11-13 15:15:52 +00:00
void PCB_IO::FootprintSave( const wxString& aLibraryPath, const FOOTPRINT* aFootprint,
const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
init( aProperties );
// In this public PLUGIN API function, we can safely assume it was
// called for saving into a library path.
m_ctl = CTL_FOR_LIBRARY;
validateCache( aLibraryPath );
if( !m_cache->IsWritable() )
{
if( !m_cache->Exists() )
{
2021-06-27 13:24:02 +00:00
const wxString msg = wxString::Format( _( "Library '%s' does not exist.\n"
"Would you like to create it?"),
aLibraryPath );
if( wxMessageBox( msg, _( "Library Not Found"), wxYES_NO | wxICON_QUESTION ) != wxYES )
return;
// Save throws its own IO_ERROR on failure, so no need to recreate here
m_cache->Save( nullptr );
}
else
{
2021-06-27 13:24:02 +00:00
wxString msg = wxString::Format( _( "Library '%s' is read only." ), aLibraryPath );
THROW_IO_ERROR( msg );
}
}
wxString footprintName = aFootprint->GetFPID().GetLibItemName();
2020-11-14 19:16:42 +00:00
FOOTPRINT_MAP& footprints = m_cache->GetFootprints();
// Quietly overwrite footprint and delete footprint file from path for any by same name.
wxFileName fn( aLibraryPath, aFootprint->GetFPID().GetLibItemName(),
KiCadFootprintFileExtension );
// Write through symlinks, don't replace them
WX_FILENAME::ResolvePossibleSymlinks( fn );
if( !fn.IsOk() )
{
2021-06-27 13:24:02 +00:00
THROW_IO_ERROR( wxString::Format( _( "Footprint file name '%s' is not valid." ),
fn.GetFullPath() ) );
}
if( fn.FileExists() && !fn.IsFileWritable() )
{
2021-06-27 13:24:02 +00:00
THROW_IO_ERROR( wxString::Format( _( "Insufficient permissions to delete '%s'." ),
fn.GetFullPath() ) );
}
wxString fullPath = fn.GetFullPath();
wxString fullName = fn.GetFullName();
2020-11-14 19:16:42 +00:00
FOOTPRINT_MAP::const_iterator it = footprints.find( footprintName );
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if( it != footprints.end() )
{
wxLogTrace( traceKicadPcbPlugin, wxT( "Removing footprint file '%s'." ), fullPath );
2020-11-14 19:16:42 +00:00
footprints.erase( footprintName );
wxRemoveFile( fullPath );
}
// I need my own copy for the cache
2020-11-13 15:15:52 +00:00
FOOTPRINT* footprint = static_cast<FOOTPRINT*>( aFootprint->Clone() );
// It's orientation should be zero and it should be on the front layer.
2020-11-13 15:15:52 +00:00
footprint->SetOrientation( 0 );
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if( footprint->GetLayer() != F_Cu )
{
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PCBNEW_SETTINGS* cfg = dynamic_cast<PCBNEW_SETTINGS*>( Kiface().KifaceSettings() );
2020-02-20 12:11:04 +00:00
if( cfg )
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footprint->Flip( footprint->GetPosition(), cfg->m_FlipLeftRight );
else
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footprint->Flip( footprint->GetPosition(), false );
}
// Detach it from the board
footprint->SetParent( nullptr );
wxLogTrace( traceKicadPcbPlugin, wxT( "Creating s-expr footprint file '%s'." ), fullPath );
footprints.insert( footprintName,
new FP_CACHE_ITEM( footprint, WX_FILENAME( fn.GetPath(), fullName ) ) );
2020-11-13 15:15:52 +00:00
m_cache->Save( footprint );
}
void PCB_IO::FootprintDelete( const wxString& aLibraryPath, const wxString& aFootprintName,
const PROPERTIES* aProperties )
{
LOCALE_IO toggle; // toggles on, then off, the C locale.
init( aProperties );
validateCache( aLibraryPath );
if( !m_cache->IsWritable() )
{
2021-06-27 13:24:02 +00:00
THROW_IO_ERROR( wxString::Format( _( "Library '%s' is read only." ),
aLibraryPath.GetData() ) );
}
m_cache->Remove( aFootprintName );
}
long long PCB_IO::GetLibraryTimestamp( const wxString& aLibraryPath ) const
{
return FP_CACHE::GetTimestamp( aLibraryPath );
}
void PCB_IO::FootprintLibCreate( const wxString& aLibraryPath, const PROPERTIES* aProperties )
{
if( wxDir::Exists( aLibraryPath ) )
{
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THROW_IO_ERROR( wxString::Format( _( "Cannot overwrite library path '%s'." ),
aLibraryPath.GetData() ) );
}
LOCALE_IO toggle;
init( aProperties );
delete m_cache;
m_cache = new FP_CACHE( this, aLibraryPath );
m_cache->Save();
}
bool PCB_IO::FootprintLibDelete( const wxString& aLibraryPath, const PROPERTIES* aProperties )
{
wxFileName fn;
fn.SetPath( aLibraryPath );
// Return if there is no library path to delete.
if( !fn.DirExists() )
return false;
if( !fn.IsDirWritable() )
{
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THROW_IO_ERROR( wxString::Format( _( "Insufficient permissions to delete folder '%s'." ),
aLibraryPath.GetData() ) );
}
wxDir dir( aLibraryPath );
if( dir.HasSubDirs() )
{
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THROW_IO_ERROR( wxString::Format( _( "Library folder '%s' has unexpected sub-folders." ),
aLibraryPath.GetData() ) );
}
// All the footprint files must be deleted before the directory can be deleted.
if( dir.HasFiles() )
{
unsigned i;
wxFileName tmp;
wxArrayString files;
wxDir::GetAllFiles( aLibraryPath, &files );
for( i = 0; i < files.GetCount(); i++ )
{
tmp = files[i];
if( tmp.GetExt() != KiCadFootprintFileExtension )
{
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THROW_IO_ERROR( wxString::Format( _( "Unexpected file '%s' found in library "
"path '%s'." ),
files[i].GetData(),
aLibraryPath.GetData() ) );
}
}
for( i = 0; i < files.GetCount(); i++ )
wxRemoveFile( files[i] );
}
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wxLogTrace( traceKicadPcbPlugin, wxT( "Removing footprint library '%s'." ),
aLibraryPath.GetData() );
// 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( !wxRmdir( aLibraryPath ) )
{
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THROW_IO_ERROR( wxString::Format( _( "Footprint library '%s' cannot be deleted." ),
aLibraryPath.GetData() ) );
}
// For some reason removing a directory in Windows is not immediately updated. This delay
// prevents an error when attempting to immediately recreate the same directory when over
// writing an existing library.
#ifdef __WINDOWS__
wxMilliSleep( 250L );
#endif
if( m_cache && !m_cache->IsPath( aLibraryPath ) )
{
delete m_cache;
m_cache = nullptr;
}
return true;
}
bool PCB_IO::IsFootprintLibWritable( const wxString& aLibraryPath )
{
LOCALE_IO toggle;
init( nullptr );
validateCache( aLibraryPath );
return m_cache->IsWritable();
}