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9856cb2210
kicad/common/lset.cpp
Jeff Young 9856cb2210 An arbitrary layer flip can not be done without the board. 
(User-defined layers can be sided or not.)

Fixes https://gitlab.com/kicad/code/kicad/-/issues/20169
2025-03-05 17:59:22 +00:00

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2014 SoftPLC Corporation, Dick Hollenbeck <dick@softplc.com>
* Copyright The 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 <algorithm>
#include <bitset> // for bitset, __bitset<>::ref...
#include <cassert>
#include <cstdarg>
#include <iostream> // for string, endl, basic_ost...
#include <cstddef> // for size_t
#include <map>
#include <core/arraydim.h>
#include <layer_ids.h> // for PCB_LAYER_ID
#include <layer_range.h>
#include <lseq.h>
#include <macros.h> // for arrayDim
#include <wx/debug.h> // for wxASSERT, wxASSERT_MSG
#include <wx/string.h>
#include <lset.h>
LSET::LSET( std::initializer_list<PCB_LAYER_ID> aList ) :
LSET()
{
for( PCB_LAYER_ID layer : aList )
{
if( layer >= 0 )
set( layer );
}
}
LSET::LSET( const std::vector<PCB_LAYER_ID>& aList ) :
LSET()
{
for( PCB_LAYER_ID layer : aList )
{
if( layer >= 0 )
set( layer );
}
}
LSET::LSET( const LSEQ& aSeq ) :
LSET()
{
for( PCB_LAYER_ID layer : aSeq )
{
if( layer >= 0 )
set( layer );
}
}
LSET::LSET( const LAYER_RANGE& aRange )
{
for( PCB_LAYER_ID layer : aRange )
{
if( layer >= 0 )
set( layer );
}
}
int LSET::LayerCount( PCB_LAYER_ID aStart, PCB_LAYER_ID aEnd, int aCopperLayerCount )
{
int start = aStart;
int end = aEnd;
// Both layers need to be copper
wxCHECK( IsCopperLayer( aStart ) && IsCopperLayer( aEnd ), aCopperLayerCount );
if( aStart == B_Cu )
std::swap( start, end );
if( aStart == aEnd )
return 1;
if( aStart == F_Cu )
{
if ( aEnd == B_Cu )
return aCopperLayerCount;
else
return ( end - start ) / 2 - 1;
}
else if ( aEnd == B_Cu )
{
// Add 1 for the B_Cu layer
return aCopperLayerCount - start / 2 + 1;
}
return ( end - start ) / 2;
}
int LSET::NameToLayer( wxString& aName )
{
std::map<wxString, PCB_LAYER_ID> layerMap = {
{ "F.Cu", F_Cu },
{ "B.Cu", B_Cu },
{ "F.Adhes", F_Adhes },
{ "B.Adhes", B_Adhes },
{ "F.Paste", F_Paste },
{ "B.Paste", B_Paste },
{ "F.SilkS", F_SilkS },
{ "B.SilkS", B_SilkS },
{ "F.Mask", F_Mask },
{ "B.Mask", B_Mask },
{ "Dwgs.User", Dwgs_User },
{ "Cmts.User", Cmts_User },
{ "Eco1.User", Eco1_User },
{ "Eco2.User", Eco2_User },
{ "Edge.Cuts", Edge_Cuts },
{ "Margin", Margin },
{ "F.CrtYd", F_CrtYd },
{ "B.CrtYd", B_CrtYd },
{ "F.Fab", F_Fab },
{ "B.Fab", B_Fab },
{ "Rescue", Rescue },
{ "B.Cu", B_Cu },
};
if( auto it = layerMap.find( aName ); it != layerMap.end() )
return static_cast<int>( it->second );
if( aName.StartsWith( "User." ) )
{
long offset;
if( aName.Mid( 5 ).ToLong( &offset ) && offset > 0 )
return static_cast<int>( User_1 ) + ( offset - 1 ) * 2;
}
if( aName.StartsWith( "In" ) )
{
long offset;
wxString str_num = aName.Mid( 2 );
str_num.RemoveLast( 3 ); // Removes .Cu
if( str_num.ToLong( &offset ) && offset > 0 )
return static_cast<int>( In1_Cu ) + ( offset - 1 ) * 2;
}
return -1;
}
bool LSET::IsBetween( PCB_LAYER_ID aStart, PCB_LAYER_ID aEnd, PCB_LAYER_ID aLayer )
{
if( aLayer == aStart || aLayer == aEnd )
return true;
int start = std::min( aStart, aEnd );
int end = std::max( aStart, aEnd );
int layer = aLayer;
if( end == B_Cu )
{
//Reassign the end layer to the largest possible positive even number
end = std::numeric_limits<PCB_LAYER_ID>::max() & ~1;
}
return !( layer & 1 ) && ( layer >= start ) && ( layer <= end );
}
wxString LSET::Name( PCB_LAYER_ID aLayerId )
{
wxString txt;
// using a switch to explicitly show the mapping more clearly
switch( aLayerId )
{
case F_Cu: txt = wxT( "F.Cu" ); break;
case B_Cu: txt = wxT( "B.Cu" ); break;
// Technicals
case B_Adhes: txt = wxT( "B.Adhes" ); break;
case F_Adhes: txt = wxT( "F.Adhes" ); break;
case B_Paste: txt = wxT( "B.Paste" ); break;
case F_Paste: txt = wxT( "F.Paste" ); break;
case B_SilkS: txt = wxT( "B.SilkS" ); break;
case F_SilkS: txt = wxT( "F.SilkS" ); break;
case B_Mask: txt = wxT( "B.Mask" ); break;
case F_Mask: txt = wxT( "F.Mask" ); break;
// Users
case Dwgs_User: txt = wxT( "Dwgs.User" ); break;
case Cmts_User: txt = wxT( "Cmts.User" ); break;
case Eco1_User: txt = wxT( "Eco1.User" ); break;
case Eco2_User: txt = wxT( "Eco2.User" ); break;
case Edge_Cuts: txt = wxT( "Edge.Cuts" ); break;
case Margin: txt = wxT( "Margin" ); break;
// Footprint
case F_CrtYd: txt = wxT( "F.CrtYd" ); break;
case B_CrtYd: txt = wxT( "B.CrtYd" ); break;
case F_Fab: txt = wxT( "F.Fab" ); break;
case B_Fab: txt = wxT( "B.Fab" ); break;
// Rescue
case Rescue: txt = wxT( "Rescue" ); break;
default:
if( aLayerId < 0 )
txt = wxT( "UNDEFINED" );
else if( static_cast<int>( aLayerId ) & 1 )
{
int offset = ( aLayerId - Rescue ) / 2;
txt = wxString::Format( wxT( "User.%d" ), offset );
}
else
{
int offset = ( aLayerId - B_Cu ) / 2;
txt = wxString::Format( wxT( "In%d.Cu" ), offset );
}
}
return txt;
}
LSEQ LSET::CuStack() const
{
LSEQ ret;
ret.reserve( 32 );
for( auto it = copper_layers_begin(); it != copper_layers_end(); ++it )
ret.push_back( *it );
return ret;
}
LSEQ LSET::TechAndUserUIOrder() const
{
LSEQ ret;
ret.reserve( 32 );
ret = Seq( {
F_Adhes,
B_Adhes,
F_Paste,
B_Paste,
F_SilkS,
B_SilkS,
F_Mask,
B_Mask,
Dwgs_User,
Cmts_User,
Eco1_User,
Eco2_User,
Edge_Cuts,
Margin,
F_CrtYd,
B_CrtYd,
F_Fab,
B_Fab
} );
for( auto it = non_copper_layers_begin(); it != non_copper_layers_end(); ++it )
{
if( *it >= User_1 )
ret.push_back( *it );
}
return ret;
}
LSEQ LSET::Seq( const LSEQ& aSequence ) const
{
LSEQ ret;
for( PCB_LAYER_ID layer : aSequence )
{
if( test( layer ) )
ret.push_back( layer );
}
return ret;
}
LSEQ LSET::Seq() const
{
LSEQ ret;
ret.reserve( size() );
for( unsigned i = 0; i < size(); ++i )
{
if( test( i ) )
ret.push_back( PCB_LAYER_ID( i ) );
}
return ret;
}
LSEQ LSET::SeqStackupTop2Bottom( PCB_LAYER_ID aSelectedLayer ) const
{
LSEQ base_sequence = Seq( {
Edge_Cuts,
Margin,
Dwgs_User,
Cmts_User,
Eco1_User,
Eco2_User
} );
LSEQ top_tech_sequence = Seq( {
F_Fab,
F_SilkS,
F_Paste,
F_Adhes,
F_Mask,
F_CrtYd,
} );
LSEQ bottom_tech_sequence = Seq( {
B_CrtYd,
B_Mask,
B_Adhes,
B_Paste,
B_SilkS,
B_Fab,
} );
LSEQ seq = Seq( base_sequence );
for( auto it = non_copper_layers_begin(); it != non_copper_layers_end(); ++it )
{
if( *it >= User_1 )
seq.push_back( *it );
}
std::copy( top_tech_sequence.begin(), top_tech_sequence.end(), std::back_inserter( seq ) );
for( auto it = copper_layers_begin(); it != copper_layers_end(); ++it )
seq.push_back( *it );
std::copy( bottom_tech_sequence.begin(), bottom_tech_sequence.end(),
std::back_inserter( seq ) );
if( aSelectedLayer != UNDEFINED_LAYER )
{
auto it = std::find( seq.begin(), seq.end(), aSelectedLayer );
if( it != seq.end() )
{
seq.erase( it );
seq.insert( seq.begin(), aSelectedLayer );
}
}
return seq;
}
LSEQ LSET::SeqStackupForPlotting() const
{
// bottom-to-top stack-up layers
// Note that the bottom technical layers are flipped so that when plotting a bottom-side view,
// they appear in the correct sequence.
LSEQ bottom_tech_sequence = Seq( {
B_Cu,
B_Mask,
B_Paste,
B_SilkS,
B_Adhes,
B_CrtYd,
B_Fab,
} );
// Copper layers go here
LSEQ top_tech_sequence = Seq( {
F_Mask,
F_Paste,
F_SilkS,
F_Adhes,
F_CrtYd,
F_Fab,
} );
LSEQ user_sequence = Seq( {
Dwgs_User,
Cmts_User,
Eco1_User,
Eco2_User,
} );
// User layers go here
LSEQ base_sequence = Seq( {
Margin,
Edge_Cuts,
} );
LSEQ seq = Seq( bottom_tech_sequence );
std::vector<PCB_LAYER_ID> temp_layers;
// We are going to reverse the copper layers and then add them to the sequence
// because the plotting order is bottom-to-top
for( auto it = copper_layers_begin(); it != copper_layers_end(); ++it )
{
// Skip B_Cu because it is already in the sequence (if it exists)
if( *it != B_Cu )
temp_layers.push_back( *it );
}
for( auto it = temp_layers.rbegin(); it != temp_layers.rend(); ++it )
seq.push_back( *it );
std::copy( top_tech_sequence.begin(), top_tech_sequence.end(), std::back_inserter( seq ) );
std::copy( user_sequence.begin(), user_sequence.end(), std::back_inserter( seq ) );
temp_layers.clear();
for( auto it = non_copper_layers_begin(); it != non_copper_layers_end(); ++it )
{
if( *it >= User_1 )
temp_layers.push_back( *it );
}
for( auto it = temp_layers.rbegin(); it != temp_layers.rend(); ++it )
{
seq.push_back( *it );
}
std::copy( base_sequence.begin(), base_sequence.end(), std::back_inserter( seq ) );
return seq;
}
LSET& LSET::FlipStandardLayers( int aCopperLayersCount )
{
LSET oldMask = *this;
reset();
// Mapping for Copper and Non-Copper layers
const std::map<PCB_LAYER_ID, PCB_LAYER_ID> flip_map =
{
{F_Cu, B_Cu},
{B_Cu, F_Cu},
{F_SilkS, B_SilkS},
{B_SilkS, F_SilkS},
{F_Adhes, B_Adhes},
{B_Adhes, F_Adhes},
{F_Mask, B_Mask},
{B_Mask, F_Mask},
{F_Paste, B_Paste},
{B_Paste, F_Paste},
{F_CrtYd, B_CrtYd},
{B_CrtYd, F_CrtYd},
{F_Fab, B_Fab},
{B_Fab, F_Fab}
};
for( const auto& pair : flip_map )
{
if( oldMask.test( pair.first ) )
set( pair.second );
oldMask.set( pair.first, false );
}
if( aCopperLayersCount >= 4 )
{
LSET internalMask = oldMask & InternalCuMask();
int innerLayerCount = aCopperLayersCount - 2;
for( int ii = 1; ii <= innerLayerCount; ii++ )
{
if( internalMask.test( ( innerLayerCount - ii + 1 ) * 2 + B_Cu ) )
{
set( ii * 2 + B_Cu );
}
}
}
oldMask.ClearCopperLayers();
// Copy across any remaining, non-side-specific layers
for( PCB_LAYER_ID layer : oldMask )
set( layer );
return *this;
}
PCB_LAYER_ID LSET::ExtractLayer() const
{
unsigned set_count = count();
if( !set_count )
return UNSELECTED_LAYER;
else if( set_count > 1 )
return UNDEFINED_LAYER;
for( unsigned i=0; i < size(); ++i )
{
if( test( i ) )
return PCB_LAYER_ID( i );
}
wxASSERT( 0 ); // set_count was verified as 1 above, what did you break?
return UNDEFINED_LAYER;
}
LSET LSET::FrontAssembly()
{
static const LSET saved( { F_SilkS, F_Mask, F_Fab, F_CrtYd } );
return saved;
}
LSET LSET::BackAssembly()
{
static const LSET saved( { B_SilkS, B_Mask, B_Fab, B_CrtYd } );
return saved;
}
LSET LSET::InternalCuMask()
{
static const LSET saved( { In1_Cu, In2_Cu, In3_Cu, In4_Cu, In5_Cu, In6_Cu,
In7_Cu, In8_Cu, In9_Cu, In10_Cu, In11_Cu, In12_Cu,
In13_Cu, In14_Cu, In15_Cu, In16_Cu, In17_Cu, In18_Cu,
In19_Cu, In20_Cu, In21_Cu, In22_Cu, In23_Cu, In24_Cu,
In25_Cu, In26_Cu, In27_Cu, In28_Cu, In29_Cu, In30_Cu } );
return saved;
}
LSET LSET::AllCuMask( int aCuLayerCount )
{
LSET ret;
for( PCB_LAYER_ID layer : LAYER_RANGE( F_Cu, B_Cu, aCuLayerCount ) )
ret.set( layer );
return ret;
}
LSET LSET::AllNonCuMask()
{
LSET saved = LSET().set();
for( auto it = saved.copper_layers_begin(); it != saved.copper_layers_end(); ++it )
saved.reset( *it );
return saved;
}
LSET LSET::ExternalCuMask()
{
static const LSET saved( { F_Cu, B_Cu } );
return saved;
}
LSET LSET::AllLayersMask()
{
static const LSET saved = LSET().set();
return saved;
}
LSET LSET::BackTechMask()
{
static const LSET saved( { B_SilkS, B_Mask, B_Adhes, B_Paste, B_CrtYd, B_Fab } );
return saved;
}
LSET LSET::BackBoardTechMask()
{
static const LSET saved( { B_SilkS, B_Mask, B_Adhes, B_Paste } );
return saved;
}
LSET LSET::FrontTechMask()
{
static const LSET saved( { F_SilkS, F_Mask, F_Adhes, F_Paste, F_CrtYd, F_Fab } );
return saved;
}
LSET LSET::FrontBoardTechMask()
{
static const LSET saved( { F_SilkS, F_Mask, F_Adhes, F_Paste } );
return saved;
}
LSET LSET::AllTechMask()
{
static const LSET saved = BackTechMask() | FrontTechMask();
return saved;
}
LSET LSET::AllBoardTechMask()
{
static const LSET saved = BackBoardTechMask() | FrontBoardTechMask();
return saved;
}
LSET LSET::UserMask()
{
static const LSET saved( { Dwgs_User, Cmts_User, Eco1_User, Eco2_User, Edge_Cuts, Margin } );
return saved;
}
LSET LSET::PhysicalLayersMask()
{
static const LSET saved = AllBoardTechMask() | AllCuMask();
return saved;
}
LSET LSET::UserDefinedLayersMask( int aUserDefinedLayerCount )
{
LSET ret;
size_t layer = User_1;
for( int ulayer = 1; ulayer <= aUserDefinedLayerCount; ulayer++ )
{
if( layer > ret.size() )
break;
ret.set( layer );
layer += 2;
}
return ret;
}
LSET LSET::FrontMask()
{
static const LSET saved = FrontTechMask().set( F_Cu );
return saved;
}
LSET LSET::BackMask()
{
static const LSET saved = BackTechMask().set( B_Cu );
return saved;
}
LSET LSET::SideSpecificMask()
{
static const LSET saved = BackTechMask() | FrontTechMask() | AllCuMask();
return saved;
}
LSET LSET::ForbiddenFootprintLayers()
{
static const LSET saved = InternalCuMask();
return saved;
}
LSEQ LSET::UIOrder() const
{
LSEQ order = CuStack();
LSEQ techuser = TechAndUserUIOrder();
order.insert( order.end(), techuser.begin(), techuser.end() );
return order;
}
PCB_LAYER_ID ToLAYER_ID( int aLayer )
{
// We use std::numeric_limits<int>::max() to represent B_Cu for the connectivity_rtree
if( aLayer == std::numeric_limits<int>::max() )
return B_Cu;
wxASSERT( aLayer < GAL_LAYER_ID_END );
return PCB_LAYER_ID( aLayer );
}
GAL_SET::GAL_SET( const GAL_LAYER_ID* aArray, unsigned aCount ) : GAL_SET()
{
for( unsigned i = 0; i < aCount; ++i )
set( aArray[i] );
}
std::vector<GAL_LAYER_ID> GAL_SET::Seq() const
{
std::vector<GAL_LAYER_ID> ret;
for( size_t i = 0; i < size(); ++i )
{
if( test( i ) )
ret.push_back( static_cast<GAL_LAYER_ID>( i + GAL_LAYER_ID_START ) );
}
return ret;
}
GAL_SET GAL_SET::DefaultVisible()
{
static const GAL_LAYER_ID visible[] = {
LAYER_VIAS,
LAYER_VIA_MICROVIA,
LAYER_VIA_BBLIND,
LAYER_VIA_THROUGH,
// LAYER_HIDDEN_TEXT, // DEPCREATED SINCE 9.0. Invisible text hidden by default
LAYER_ANCHOR,
LAYER_RATSNEST,
LAYER_GRID,
LAYER_GRID_AXES,
LAYER_FOOTPRINTS_FR,
LAYER_FOOTPRINTS_BK,
LAYER_FP_TEXT,
LAYER_FP_VALUES,
LAYER_FP_REFERENCES,
LAYER_TRACKS,
LAYER_PAD_PLATEDHOLES,
LAYER_NON_PLATEDHOLES,
LAYER_PAD_HOLEWALLS,
LAYER_VIA_HOLES,
LAYER_VIA_HOLEWALLS,
LAYER_DRC_ERROR,
LAYER_DRC_WARNING,
LAYER_DRC_SHAPE1,
LAYER_DRC_SHAPE2,
// LAYER_DRC_EXCLUSION, // DRC exclusions hidden by default
LAYER_DRAWINGSHEET,
LAYER_GP_OVERLAY,
LAYER_SELECT_OVERLAY,
LAYER_PCB_BACKGROUND,
LAYER_CURSOR,
LAYER_AUX_ITEMS,
LAYER_DRAW_BITMAPS,
LAYER_PADS,
LAYER_ZONES,
LAYER_SHAPES,
LAYER_LOCKED_ITEM_SHADOW,
LAYER_CONFLICTS_SHADOW
};
static const GAL_SET saved( visible, arrayDim( visible ) );
return saved;
}
#ifndef SWIG // Skip SWIG generators for the iterators because it requires a default constructor
// Custom iterators for Copper and Non-Copper layers
LSET::copper_layers_iterator::copper_layers_iterator( const BASE_SET& set, size_t index ) :
BASE_SET::set_bits_iterator( set, index )
{
m_index = ( index + 1 ) & ~1;
advance_to_next_set_copper_bit();
}
PCB_LAYER_ID LSET::copper_layers_iterator::operator*() const
{
return static_cast<PCB_LAYER_ID>( m_index );
}
LSET::copper_layers_iterator& LSET::copper_layers_iterator::operator++()
{
next_copper_layer();
advance_to_next_set_copper_bit();
return *this;
}
void LSET::copper_layers_iterator::next_copper_layer()
{
if( m_index == F_Cu )
{
m_index += 4;
}
else if( m_index == B_Cu )
{
m_index = m_baseSet.size();
return;
}
else
{
m_index += 2;
if( m_index >= m_baseSet.size() )
m_index = B_Cu;
}
}
void LSET::copper_layers_iterator::advance_to_next_set_copper_bit()
{
while( m_index < m_baseSet.size() && !m_baseSet.test( m_index ) )
next_copper_layer();
}
LSET::non_copper_layers_iterator::non_copper_layers_iterator( const BASE_SET& set, size_t index ) :
BASE_SET::set_bits_iterator( set, index )
{
advance_to_next_set_non_copper_bit();
}
PCB_LAYER_ID LSET::non_copper_layers_iterator::operator*() const
{
return static_cast<PCB_LAYER_ID>( m_index );
}
LSET::non_copper_layers_iterator& LSET::non_copper_layers_iterator::operator++()
{
++m_index;
advance_to_next_set_non_copper_bit();
return *this;
}
void LSET::non_copper_layers_iterator::advance_to_next_set_non_copper_bit()
{
while( m_index < m_baseSet.size() && ( m_index % 2 != 1 || !m_baseSet.test( m_index ) ) )
{
++m_index;
}
}
LSET::copper_layers_iterator LSET::copper_layers_begin() const
{
return copper_layers_iterator( *this, 0 );
}
LSET::copper_layers_iterator LSET::copper_layers_end() const
{
return copper_layers_iterator( *this, size() );
}
LSET::non_copper_layers_iterator LSET::non_copper_layers_begin() const
{
return non_copper_layers_iterator( *this, 0 );
}
LSET::non_copper_layers_iterator LSET::non_copper_layers_end() const
{
return non_copper_layers_iterator( *this, size() );
}
LSET& LSET::ClearCopperLayers()
{
for( size_t ii = 0; ii < size(); ii += 2 )
reset( ii );
return *this;
}
LSET& LSET::ClearNonCopperLayers()
{
for( size_t ii = 1; ii < size(); ii += 2 )
reset( ii );
return *this;
}
LSET& LSET::ClearUserDefinedLayers()
{
for( size_t ii = User_1; ii < size(); ii += 2 )
reset( ii );
return *this;
}
#endif
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