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// Hyperbolic Rogue -- Euclidean geometry
// Copyright (C) 2011-2019 Zeno Rogue, see 'hyper.cpp' for details
/** \file euclid.cpp
* \ brief Euclidean geometry , including 2 D , 3 D , and quotient spaces
*/
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# include "hyper.h"
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namespace hr {
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EX namespace euc {
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# if HDR
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struct coord : array < int , 3 > {
coord ( ) { }
coord ( int x , int y , int z ) { self [ 0 ] = x ; self [ 1 ] = y ; self [ 2 ] = z ; }
coord & operator + = ( coord b ) { for ( int i : { 0 , 1 , 2 } ) self [ i ] + = b [ i ] ; return self ; }
coord & operator - = ( coord b ) { for ( int i : { 0 , 1 , 2 } ) self [ i ] - = b [ i ] ; return self ; }
coord operator + ( coord b ) const { coord a = self ; return a + = b ; }
coord operator - ( coord b ) const { coord a = self ; return a - = b ; }
coord operator - ( ) const { return coord ( - self [ 0 ] , - self [ 1 ] , - self [ 2 ] ) ; }
coord & operator + ( ) { return self ; }
const coord & operator + ( ) const { return self ; }
coord operator * ( int x ) const { return coord ( x * self [ 0 ] , x * self [ 1 ] , x * self [ 2 ] ) ; }
friend coord operator * ( int x , const coord & y ) { return coord ( x * y [ 0 ] , x * y [ 1 ] , x * y [ 2 ] ) ; }
} ;
typedef array < coord , 3 > intmatrix ;
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# endif
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EX const coord euzero = coord ( 0 , 0 , 0 ) ;
EX const coord eutester = coord ( 3 , 7 , 0 ) ;
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EX intmatrix euzeroall = make_array < coord > ( euzero , euzero , euzero ) ;
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static const intmatrix main_axes = make_array < coord > ( coord ( 1 , 0 , 0 ) , coord ( 0 , 1 , 0 ) , coord ( 0 , 0 , 1 ) ) ;
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EX vector < coord > get_shifttable ( ) {
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static const coord D0 = main_axes [ 0 ] ;
static const coord D1 = main_axes [ 1 ] ;
static const coord D2 = main_axes [ 2 ] ;
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vector < coord > shifttable ;
switch ( geometry ) {
case gCubeTiling :
shifttable = { + D0 , + D1 , + D2 } ;
break ;
case gRhombic3 :
shifttable = { D0 + D1 , D0 + D2 , D1 + D2 , D1 - D2 , D0 - D2 , D0 - D1 } ;
break ;
case gBitrunc3 :
shifttable = { 2 * D0 , 2 * D1 , 2 * D2 , D0 + D1 + D2 , D0 + D1 - D2 , D0 - D1 - D2 , D0 - D1 + D2 } ;
break ;
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case gEuclid :
shifttable = { D0 , D1 , D1 - D0 , - D0 , - D1 , D0 - D1 } ;
break ;
case gEuclidSquare :
shifttable = { D0 , D1 , - D0 , - D1 } ;
break ;
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default :
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printf ( " euc::get_shifttable() called in geometry that is not euclid3 " ) ;
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exit ( 1 ) ;
}
// reverse everything
int s = isize ( shifttable ) ;
for ( int i = 0 ; i < s ; i + + ) shifttable . push_back ( - shifttable [ i ] ) ;
return shifttable ;
}
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EX coord basic_canonicalize ( coord x ) ;
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# if HDR
struct torus_config {
/** periods entered by the user */
intmatrix user_axes ;
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/** OR'ed flags: 1 -- flip X in 3D, 2 -- flip Y in 3D, 4 -- flip X/Y in 3D, 8 -- Klein bottle in 2D, 16 -- third turn in 3D, 32 -- Hantzsche-Wendt in 3D */
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int twisted ;
torus_config ( ) { }
torus_config ( intmatrix user_axes , int twisted ) : user_axes ( user_axes ) , twisted ( twisted ) { }
} ;
struct torus_config_full : torus_config {
/** optimal representation of the periods */
intmatrix optimal_axes ;
/** regular axes (?) */
intmatrix regular_axes ;
/** in 2D: the period vector which is reflected */
gp : : loc twisted_vec ;
/** in 2D: a vector orthogonal to twisted_vec */
gp : : loc ortho_vec ;
/** determinant */
int det ;
/** the number of infinite dimensions */
int infinite_dims ;
/** ? */
intmatrix inverse_axes ;
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/** for canonicalization on tori */
unordered_map < coord , int > hash ;
vector < coord > seq ;
int index ;
void reset ( ) { index = 0 ; hash . clear ( ) ; seq . clear ( ) ; }
/** add to the tori canonicalization list */
void add ( coord val ) ;
/** get the representative on the tori canonicalization list */
coord get ( coord x ) ;
/** find the equivalence class of coo */
coord compute_cat ( coord coo ) ;
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/** canonicalize coord x; in case of twisting, adjust d, M, and mirr accordingly */
void canonicalize ( coord & x , coord & d , transmatrix & M , bool & mirr ) ;
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} ;
# endif
EX torus_config eu_input , eu_edit ;
EX torus_config_full eu ;
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struct hrmap_euclidean : hrmap_standard {
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vector < coord > shifttable ;
vector < transmatrix > tmatrix ;
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map < coord , heptagon * > spacemap ;
map < heptagon * , coord > ispacemap ;
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cell * camelot_center ;
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map < gp : : loc , struct cdata > eucdata ;
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vector < cell * > toruscells ;
vector < cell * > & allcells ( ) override {
if ( bounded ) {
if ( isize ( toruscells ) = = 0 ) {
celllister cl ( getOrigin ( ) - > c7 , 1000 , 1000000 , NULL ) ;
toruscells = cl . lst ;
}
return toruscells ;
}
return hrmap : : allcells ( ) ;
}
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hrmap_euclidean ( ) {
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shifttable = get_shifttable ( ) ;
tmatrix . resize ( S7 ) ;
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for ( int i = 0 ; i < S7 ; i + + )
tmatrix [ i ] = eumove ( shifttable [ i ] ) ;
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camelot_center = NULL ;
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build_torus3 ( geometry ) ;
if ( ! valid_irr_torus ( ) ) {
addMessage ( XLAT ( " Error: period mismatch " ) ) ;
eu_input = irr : : base_config ;
build_torus3 ( geometry ) ;
}
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}
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heptagon * getOrigin ( ) override {
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return get_at ( euzero ) ;
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}
heptagon * get_at ( coord at ) {
if ( spacemap . count ( at ) )
return spacemap [ at ] ;
else {
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auto h = tailored_alloc < heptagon > ( S7 ) ;
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if ( ! IRREGULAR )
h - > c7 = newCell ( S7 , h ) ;
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else {
coord m0 = shifttable [ 0 ] ;
transmatrix dummy ;
bool mirr ;
auto ati = at ;
irr : : base_config . canonicalize ( ati , m0 , dummy , mirr ) ;
indenter id ( 2 ) ;
for ( int spin = 0 ; spin < S7 ; spin + + ) if ( shifttable [ spin ] = = m0 ) {
irr : : link_to_base ( h , heptspin ( ( ( hrmap_euclidean * ) irr : : base ) - > get_at ( ati ) , spin , mirr ) ) ;
break ;
}
}
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h - > distance = 0 ;
h - > cdata = NULL ;
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h - > alt = NULL ;
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if ( S7 ! = 14 )
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h - > zebraval = gmod ( at [ 0 ] + at [ 1 ] * 2 + at [ 2 ] * 4 , 5 ) ;
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else
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h - > zebraval = at [ 0 ] & 1 ;
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spacemap [ at ] = h ;
ispacemap [ h ] = at ;
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return h ;
}
}
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heptagon * create_step ( heptagon * parent , int d ) override {
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int d1 = ( d + S7 / 2 ) % S7 ;
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bool mirr = false ;
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transmatrix I ;
auto v = ispacemap [ parent ] + shifttable [ d ] ;
auto st = shifttable [ d1 ] ;
eu . canonicalize ( v , st , I , mirr ) ;
if ( eu . twisted )
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for ( int i = 0 ; i < S7 ; i + + ) if ( shifttable [ i ] = = st ) d1 = i ;
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heptagon * h = get_at ( v ) ;
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h - > c . connect ( d1 , parent , d , mirr ) ;
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return h ;
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}
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transmatrix adj ( heptagon * h , int i ) override {
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if ( ! eu . twisted ) return tmatrix [ i ] ;
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transmatrix res = tmatrix [ i ] ;
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coord id = ispacemap [ h ] ;
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id + = shifttable [ i ] ;
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auto dummy = euzero ;
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bool dm = false ;
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eu . canonicalize ( id , dummy , res , dm ) ;
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return res ;
}
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transmatrix adj ( cell * c , int i ) override {
if ( WDIM = = 3 ) return adj ( c - > master , i ) ;
else return hrmap_standard : : adj ( c , i ) ;
}
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void draw_at ( cell * at , const shiftmatrix & where ) override {
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dq : : clear_all ( ) ;
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dq : : enqueue_by_matrix ( at - > master , where * master_relative ( centerover , true ) ) ;
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while ( ! dq : : drawqueue . empty ( ) ) {
auto & p = dq : : drawqueue . front ( ) ;
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heptagon * h = p . first ;
shiftmatrix V = p . second ;
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dq : : drawqueue . pop ( ) ;
cell * c = h - > c7 ;
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bool draw = drawcell_subs ( c , V * spin ( master_to_c7_angle ( ) ) ) ;
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if ( in_wallopt ( ) & & isWall3 ( c ) & & isize ( dq : : drawqueue ) > 1000 & & ! hybrid : : pmap ) continue ;
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if ( draw ) for ( int i = 0 ; i < S7 ; i + + )
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dq : : enqueue_by_matrix ( h - > move ( i ) , optimized_shift ( V * adj ( h , i ) ) ) ;
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}
}
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transmatrix relative_matrix ( heptagon * h2 , heptagon * h1 , const hyperpoint & hint ) override {
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if ( eu . twisted ) {
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if ( h1 = = h2 ) return Id ;
for ( int s = 0 ; s < S7 ; s + + ) if ( h2 = = h1 - > move ( s ) ) return adj ( h1 , s ) ;
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coord c1 = ispacemap [ h1 ] ;
coord c2 = ispacemap [ h2 ] ;
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transmatrix T = eumove ( c2 - c1 ) ;
transmatrix I = Id ;
coord cs = c1 ;
for ( int s = 0 ; s < 4 ; s + + ) {
for ( int a = - 1 ; a < = 1 ; a + + )
for ( int b = - 1 ; b < = 1 ; b + + ) {
if ( b & & WDIM = = 2 ) continue ;
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transmatrix T1 = I * eumove ( ( c2 - cs ) + a * eu . user_axes [ 0 ] + b * eu . user_axes [ 1 ] ) ;
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if ( hdist ( tC0 ( T1 ) , hint ) < hdist ( tC0 ( T ) , hint ) )
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T = T1 ;
}
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auto co = eu . user_axes [ WDIM - 1 ] ;
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cs + = co ;
I = I * eumove ( co ) ;
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auto dummy = euzero ;
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bool dm = false ;
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eu . canonicalize ( cs , dummy , I , dm ) ;
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}
return T ;
}
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auto d = ispacemap [ h2 ] - ispacemap [ h1 ] ;
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d = basic_canonicalize ( d ) ;
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return eumove ( d ) ;
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}
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vector < hyperpoint > get_vertices ( cell * c ) override {
vector < hyperpoint > res ;
if ( S7 < 14 )
for ( ld a : { - .5 , .5 } ) for ( ld b : { - .5 , .5 } ) for ( ld c : { - .5 , .5 } ) res . push_back ( hpxy3 ( a , b , c ) ) ;
if ( S7 = = 12 ) {
res . push_back ( hpxy3 ( 1 , 0 , 0 ) ) ;
res . push_back ( hpxy3 ( - 1 , 0 , 0 ) ) ;
res . push_back ( hpxy3 ( 0 , 1 , 0 ) ) ;
res . push_back ( hpxy3 ( 0 , - 1 , 0 ) ) ;
res . push_back ( hpxy3 ( 0 , 0 , 1 ) ) ;
res . push_back ( hpxy3 ( 0 , 0 , - 1 ) ) ;
}
if ( S7 = = 14 ) {
for ( ld a : { - 1. , - .5 , 0. , .5 , 1. } )
for ( ld b : { - 1. , - .5 , 0. , .5 , 1. } )
for ( ld c : { - 1. , - .5 , 0. , .5 , 1. } )
if ( a = = 0 | | b = = 0 | | c = = 0 )
if ( a = = .5 | | a = = - .5 | | b = = .5 | | b = = - .5 | | c = = .5 | | c = = - .5 )
if ( a = = 1 | | a = = - 1 | | b = = 1 | | b = = - 1 | | c = = 1 | | c = = - 1 )
res . push_back ( hpxy3 ( a , b , c ) ) ;
}
return res ;
}
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} ;
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hrmap_euclidean * cubemap ( ) {
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if ( fake : : in ( ) ) return FPIU ( cubemap ( ) ) ;
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return ( ( hrmap_euclidean * ) currentmap ) ;
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}
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hrmap_euclidean * eucmap ( ) {
return cubemap ( ) ;
}
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EX vector < coord > & get_current_shifttable ( ) { return cubemap ( ) - > shifttable ; }
EX map < coord , heptagon * > & get_spacemap ( ) { return cubemap ( ) - > spacemap ; }
EX map < heptagon * , coord > & get_ispacemap ( ) { return cubemap ( ) - > ispacemap ; }
EX cell * & get_camelot_center ( ) { return cubemap ( ) - > camelot_center ; }
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EX heptagon * get_at ( coord co ) { return cubemap ( ) - > get_at ( co ) ; }
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EX hrmap * new_map ( ) {
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return new hrmap_euclidean ;
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}
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EX transmatrix move_matrix ( heptagon * h , int i ) {
return cubemap ( ) - > adj ( h , i ) ;
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}
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EX bool pseudohept ( cell * c ) {
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coord co = cubemap ( ) - > ispacemap [ c - > master ] ;
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if ( S7 = = 12 ) {
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for ( int i = 0 ; i < 3 ; i + + ) if ( ( co [ i ] & 1 ) ) return false ;
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}
else {
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for ( int i = 0 ; i < 3 ; i + + ) if ( ! ( co [ i ] & 1 ) ) return false ;
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}
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return true ;
}
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EX int dist_alt ( cell * c ) {
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if ( WDIM = = 2 ) {
auto v = full_coords2 ( c ) ;
return euclidAlt ( v . first , v . second ) ;
}
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if ( specialland = = laCamelot ) return dist_relative ( c ) + roundTableRadius ( c ) ;
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auto v = cubemap ( ) - > ispacemap [ c - > master ] ;
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if ( S7 = = 6 ) return v [ 2 ] ;
else if ( S7 = = 12 ) return ( v [ 0 ] + v [ 1 ] + v [ 2 ] ) / 2 ;
else return v [ 2 ] / 2 ;
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}
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EX bool get_emerald ( cell * c ) {
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auto v = cubemap ( ) - > ispacemap [ c - > master ] ;
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int s0 = 0 , s1 = 0 ;
for ( int i = 0 ; i < 3 ; i + + ) {
v [ i ] = gmod ( v [ i ] , 6 ) ;
int d = min ( v [ i ] , 6 - v [ i ] ) ; ;
s0 + = min ( v [ i ] , 6 - v [ i ] ) ;
s1 + = 3 - d ;
}
if ( s0 = = s1 ) println ( hlog , " equality " ) ;
return s0 > s1 ;
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}
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bool cellvalid ( coord v ) {
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if ( S7 = = 6 ) return true ;
if ( S7 = = 12 ) return ( v [ 0 ] + v [ 1 ] + v [ 2 ] ) % 2 = = 0 ;
if ( S7 = = 14 ) return v [ 0 ] % 2 = = v [ 1 ] % 2 & & v [ 0 ] % 2 = = v [ 2 ] % 2 ;
return false ;
}
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EX int celldistance ( coord v ) {
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if ( S7 = = 6 )
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return abs ( v [ 0 ] ) + abs ( v [ 1 ] ) + abs ( v [ 2 ] ) ;
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else {
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for ( int i = 0 ; i < 3 ; i + + ) v [ i ] = abs ( v [ i ] ) ;
sort ( v . begin ( ) , v . end ( ) ) ;
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int dist = 0 ;
if ( S7 = = 12 ) {
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int d = v [ 1 ] - v [ 0 ] ; v [ 1 ] - = d ; v [ 2 ] - = d ;
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dist + = d ;
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int m = min ( ( v [ 2 ] - v [ 0 ] ) , v [ 0 ] ) ;
dist + = 2 * m ;
v [ 0 ] - = m ; v [ 1 ] - = m ; v [ 2 ] - = m * 2 ;
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if ( v [ 0 ] )
dist + = ( v [ 0 ] + v [ 1 ] + v [ 2 ] ) / 2 ;
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else
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dist + = v [ 2 ] ;
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}
else {
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dist = v [ 0 ] + ( v [ 1 ] - v [ 0 ] ) / 2 + ( v [ 2 ] - v [ 0 ] ) / 2 ;
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}
return dist ;
}
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}
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EX int celldistance ( cell * c1 , cell * c2 ) {
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auto cm = cubemap ( ) ;
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if ( GDIM = = 2 )
return dist ( full_coords2 ( c1 ) , full_coords2 ( c2 ) ) ;
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return celldistance ( basic_canonicalize ( cm - > ispacemap [ c1 - > master ] - cm - > ispacemap [ c2 - > master ] ) ) ;
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}
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EX void set_land ( cell * c ) {
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setland ( c , specialland ) ;
auto m = cubemap ( ) ;
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auto co = m - > ispacemap [ c - > master ] ;
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int dv = 1 ;
if ( geometry ! = gCubeTiling ) dv = 2 ;
int hash = 0 ;
for ( int a = 0 ; a < 3 ; a + + ) hash = 1317 * hash + co [ a ] / 4 ;
set_euland3 ( c , co [ 0 ] * 120 , co [ 1 ] * 120 , ( co [ 1 ] + co [ 2 ] ) / dv , hash ) ;
}
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EX int dist_relative ( cell * c ) {
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auto m = cubemap ( ) ;
auto & cc = m - > camelot_center ;
int r = roundTableRadius ( NULL ) ;
cell * start = m - > gamestart ( ) ;
if ( ! cc ) {
cc = start ;
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while ( euc : : celldistance ( cc , start ) < r + 5 )
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cc = cc - > cmove ( hrand ( cc - > type ) ) ;
}
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return euc : : celldistance ( cc , c ) - r ;
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}
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/* quotient spaces */
int determinant ( const intmatrix T ) {
int det = 0 ;
for ( int i = 0 ; i < 3 ; i + + )
det + = T [ 0 ] [ i ] * T [ 1 ] [ ( i + 1 ) % 3 ] * T [ 2 ] [ ( i + 2 ) % 3 ] ;
for ( int i = 0 ; i < 3 ; i + + )
det - = T [ 0 ] [ i ] * T [ 1 ] [ ( i + 2 ) % 3 ] * T [ 2 ] [ ( i + 1 ) % 3 ] ;
return det ;
}
intmatrix scaled_inverse ( const intmatrix T ) {
intmatrix T2 ;
for ( int i = 0 ; i < 3 ; i + + )
for ( int j = 0 ; j < 3 ; j + + )
T2 [ j ] [ i ] = ( T [ ( i + 1 ) % 3 ] [ ( j + 1 ) % 3 ] * T [ ( i + 2 ) % 3 ] [ ( j + 2 ) % 3 ] - T [ ( i + 1 ) % 3 ] [ ( j + 2 ) % 3 ] * T [ ( i + 2 ) % 3 ] [ ( j + 1 ) % 3 ] ) ;
return T2 ;
}
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EX torus_config torus3 ( int x , int y , int z ) {
intmatrix T0 = euzeroall ;
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tie ( T0 [ 0 ] [ 0 ] , T0 [ 1 ] [ 1 ] , T0 [ 2 ] [ 2 ] ) = make_tuple ( x , y , z ) ;
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return { T0 , 0 } ;
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}
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EX torus_config clear_torus3 ( ) {
return { euzeroall , 0 } ;
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}
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coord torus_config_full : : compute_cat ( coord coo ) {
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coord cat = euzero ;
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auto & T2 = inverse_axes ;
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for ( int i = 0 ; i < 3 ; i + + ) {
int val = T2 [ 0 ] [ i ] * coo [ 0 ] + T2 [ 1 ] [ i ] * coo [ 1 ] + T2 [ 2 ] [ i ] * coo [ 2 ] ;
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if ( i < WDIM - infinite_dims ) val = gmod ( val , det ) ;
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cat + = val * main_axes [ i ] ;
}
return cat ;
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}
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EX bool valid_third_turn ( const intmatrix & m ) {
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if ( m [ 0 ] [ 2 ] ! = - m [ 0 ] [ 0 ] - m [ 0 ] [ 1 ] ) return false ;
if ( m [ 1 ] [ 0 ] ! = m [ 0 ] [ 1 ] ) return false ;
if ( m [ 1 ] [ 1 ] ! = m [ 0 ] [ 2 ] ) return false ;
if ( m [ 1 ] [ 2 ] ! = m [ 0 ] [ 0 ] ) return false ;
if ( m [ 2 ] [ 0 ] ! = m [ 2 ] [ 1 ] ) return false ;
if ( m [ 2 ] [ 0 ] ! = m [ 2 ] [ 2 ] ) return false ;
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return true ;
}
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EX torus_config make_hantzsche_wendt ( int v ) {
intmatrix im ;
for ( int i = 0 ; i < 3 ; i + + )
for ( int j = 0 ; j < 3 ; j + + ) im [ i ] [ j ] = 0 ;
for ( int i = 0 ; i < 3 ; i + + ) {
im [ i ] [ i ] = v ;
im [ i ] [ ( i + 1 ) % 3 ] = v ;
}
return { im , 32 } ;
}
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EX bool valid_hantzsche_wendt ( const intmatrix & m ) {
return m [ 0 ] [ 0 ] > 0 & & m = = make_hantzsche_wendt ( m [ 0 ] [ 0 ] ) . user_axes ;
}
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EX torus_config make_third_turn ( int a , int b , int c ) {
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intmatrix T0 ;
T0 [ 0 ] [ 0 ] = a ;
T0 [ 0 ] [ 1 ] = b ;
T0 [ 2 ] [ 0 ] = c ;
T0 [ 0 ] [ 2 ] = - T0 [ 0 ] [ 0 ] - T0 [ 0 ] [ 1 ] ;
T0 [ 1 ] [ 0 ] = T0 [ 0 ] [ 1 ] ;
T0 [ 1 ] [ 1 ] = T0 [ 0 ] [ 2 ] ;
T0 [ 1 ] [ 2 ] = T0 [ 0 ] [ 0 ] ;
T0 [ 2 ] [ 1 ] = T0 [ 2 ] [ 2 ] = c ;
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return { T0 , 8 } ;
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}
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EX torus_config make_quarter_turn ( int a , int b , int c ) {
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intmatrix T0 = euzeroall ;
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T0 [ 0 ] [ 0 ] = a ;
T0 [ 0 ] [ 1 ] = b ;
T0 [ 2 ] [ 0 ] = c ;
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return { T0 , 5 } ;
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}
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void torus_config_full : : add ( coord val ) {
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auto cat = compute_cat ( val ) ; if ( hash . count ( cat ) ) return ; hash [ cat ] = isize ( seq ) ; seq . push_back ( val ) ;
}
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coord torus_config_full : : get ( coord x ) {
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auto cat = compute_cat ( x ) ;
auto & st = cubemap ( ) - > shifttable ;
while ( ! hash . count ( cat ) ) {
if ( index = = isize ( seq ) ) throw hr_exception ( ) ;
auto v = seq [ index + + ] ;
for ( auto s : st ) add ( v + s ) ;
}
return seq [ hash [ cat ] ] ;
}
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EX bool valid_irr_torus ( ) {
if ( ! IRREGULAR ) return true ;
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if ( eu . twisted ) return false ;
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for ( int i = 0 ; i < 2 ; i + + ) {
auto x = eu . user_axes [ i ] ;
coord dm = eutester ;
transmatrix dummy = Id ;
bool mirr = false ;
irr : : base_config . canonicalize ( x , dm , dummy , mirr ) ;
auto x0 = eu . user_axes [ i ] ;
auto dm0 = eutester ;
eu . canonicalize ( x0 , dm0 , dummy , mirr ) ;
if ( x0 ! = euzero | | dm0 ! = eutester ) return false ;
}
return true ;
}
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EX void build_torus3 ( eGeometry g ) {
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int dim = ginf [ g ] . g . gameplay_dimension ;
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eu . user_axes = eu_input . user_axes ;
if ( dim = = 2 ) eu . user_axes [ 2 ] = euzero ;
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eu . optimal_axes = eu . user_axes ;
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again :
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for ( int i = 0 ; i < dim ; i + + ) if ( eu . optimal_axes [ i ] < euzero ) eu . optimal_axes [ i ] = - eu . optimal_axes [ i ] ;
if ( eu . optimal_axes [ 0 ] < eu . optimal_axes [ 1 ] ) swap ( eu . optimal_axes [ 0 ] , eu . optimal_axes [ 1 ] ) ;
if ( eu . optimal_axes [ 1 ] < eu . optimal_axes [ dim - 1 ] ) swap ( eu . optimal_axes [ 1 ] , eu . optimal_axes [ dim - 1 ] ) ;
if ( eu . optimal_axes [ 0 ] < eu . optimal_axes [ 1 ] ) swap ( eu . optimal_axes [ 0 ] , eu . optimal_axes [ 1 ] ) ;
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for ( int i = 0 ; i < 3 ; i + + ) {
int i1 = ( i + 1 ) % 3 ;
int i2 = ( i + 2 ) % 3 ;
for ( int a = - 10 ; a < = 10 ; a + + )
for ( int b = - 10 ; b < = 10 ; b + + ) {
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coord cand = eu . optimal_axes [ i ] + eu . optimal_axes [ i1 ] * a + eu . optimal_axes [ i2 ] * b ;
if ( celldistance ( cand ) < celldistance ( eu . optimal_axes [ i ] ) ) {
eu . optimal_axes [ i ] = cand ;
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goto again ;
}
}
}
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eu . regular_axes = eu . optimal_axes ;
eu . infinite_dims = dim ;
for ( int i = 0 ; i < dim ; i + + ) if ( eu . optimal_axes [ i ] ! = euzero ) eu . infinite_dims - - ;
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int attempt = 0 ;
next_attempt :
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for ( int i = dim - eu . infinite_dims ; i < 3 ; i + + )
eu . regular_axes [ i ] = main_axes [ ( attempt + i ) % 3 ] ;
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eu . det = determinant ( eu . regular_axes ) ;
if ( eu . det = = 0 ) {
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attempt + + ;
if ( attempt = = 3 ) {
println ( hlog , " weird singular! \n " ) ;
exit ( 1 ) ;
}
goto next_attempt ;
}
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if ( eu . det < 0 ) eu . det = - eu . det ;
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eu . inverse_axes = scaled_inverse ( eu . regular_axes ) ;
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eu . reset ( ) ;
eu . add ( euzero ) ;
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eu . twisted = eu_input . twisted ;
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if ( dim = = 3 ) {
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auto & T0 = eu . user_axes ;
if ( valid_third_turn ( eu . user_axes ) ) {
eu . twisted & = 16 ;
if ( g = = gRhombic3 & & ( T0 [ 2 ] [ 2 ] & 1 ) ) eu . twisted = 0 ;
if ( g = = gBitrunc3 & & ( T0 [ 0 ] [ 0 ] & 1 ) ) eu . twisted = 0 ;
if ( g = = gBitrunc3 & & ( T0 [ 1 ] [ 1 ] & 1 ) ) eu . twisted = 0 ;
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}
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else if ( valid_hantzsche_wendt ( eu . user_axes ) ) {
eu . twisted & = 32 ;
if ( g = = gBitrunc3 & & ( T0 [ 0 ] [ 0 ] & 1 ) ) eu . twisted = 0 ;
}
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else {
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eu . twisted & = 7 ;
if ( g ! = gCubeTiling & & ( ( T0 [ 0 ] [ 0 ] + T0 [ 2 ] [ 2 ] ) & 1 ) ) eu . twisted & = ~ 1 ;
if ( g ! = gCubeTiling & & ( ( T0 [ 1 ] [ 1 ] + T0 [ 2 ] [ 2 ] ) & 1 ) ) eu . twisted & = ~ 2 ;
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for ( int i = 0 ; i < 3 ; i + + ) for ( int j = 0 ; j < 3 ; j + + )
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if ( i ! = j & & T0 [ i ] [ j ] ) eu . twisted = 0 ;
if ( T0 [ 2 ] [ 2 ] = = 0 ) eu . twisted = 0 ;
if ( T0 [ 0 ] [ 0 ] ! = T0 [ 1 ] [ 1 ] ) eu . twisted & = 3 ;
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}
}
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else {
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eu . twisted & = 8 ;
eu . twisted_vec = to_loc ( eu . user_axes [ 1 ] ) ;
eu . ortho_vec = to_loc ( eu . user_axes [ 0 ] ) ;
if ( eu . twisted_vec = = gp : : loc { 0 , 0 } ) eu . twisted = 0 ;
if ( chiral ( eu . twisted_vec ) ) eu . twisted = 0 ;
if ( dscalar ( eu . twisted_vec , eu . ortho_vec ) )
eu . twisted = 0 ;
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}
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set_flag ( ginf [ g ] . flags , qANYQ , eu . infinite_dims < dim ) ;
set_flag ( ginf [ g ] . flags , qBOUNDED , eu . infinite_dims = = 0 ) ;
set_flag ( ginf [ g ] . flags , qSMALL , eu . infinite_dims = = 0 & & eu . det < = 4096 ) ;
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bool nonori = false ;
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if ( eu . twisted & 1 ) nonori = ! nonori ;
if ( eu . twisted & 2 ) nonori = ! nonori ;
if ( eu . twisted & 4 ) nonori = ! nonori ;
if ( eu . twisted & 8 ) nonori = ! nonori ;
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set_flag ( ginf [ g ] . flags , qNONORIENTABLE , nonori ) ;
}
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EX void build_torus3 ( ) {
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for ( eGeometry g : { gEuclid , gEuclidSquare , gCubeTiling , gRhombic3 , gBitrunc3 } )
build_torus3 ( g ) ;
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}
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void swap01 ( transmatrix & M ) {
for ( int i = 0 ; i < 4 ; i + + ) swap ( M [ i ] [ 0 ] , M [ i ] [ 1 ] ) ;
}
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gp : : loc ort1 ( ) { return ( S3 = = 3 ? gp : : loc ( 1 , - 2 ) : gp : : loc ( 0 , 1 ) ) ; }
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int diagonal_cross ( const coord & a , const coord & b ) {
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return a [ 0 ] * b [ 1 ] + a [ 1 ] * b [ 2 ] + a [ 2 ] * b [ 0 ]
- b [ 0 ] * a [ 1 ] - b [ 1 ] * a [ 2 ] - b [ 2 ] * a [ 0 ] ;
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}
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void torus_config_full : : canonicalize ( coord & x , coord & d , transmatrix & M , bool & mirr ) {
if ( ! twisted ) {
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if ( infinite_dims = = WDIM ) return ;
if ( infinite_dims = = WDIM - 1 ) {
auto & o = optimal_axes ;
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while ( celldistance ( x + o [ 0 ] ) < = celldistance ( x ) ) x + = o [ 0 ] ;
while ( celldistance ( x - o [ 0 ] ) < celldistance ( x ) ) x - = o [ 0 ] ;
return ;
}
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x = get ( x ) ;
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return ;
}
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auto & T0 = user_axes ;
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if ( twisted & 32 ) {
int period = T0 [ 0 ] [ 0 ] ;
auto & coo = x ;
while ( true ) {
restart :
/* These coordinates cause the algorithm below to go in circles. We simply break if they are detected */
if ( coo [ 0 ] > = 0 & & coo [ 1 ] = = period - coo [ 0 ] & & coo [ 2 ] = = - coo [ 1 ] & & coo [ 0 ] * 2 > period & & coo [ 0 ] < period ) return ;
if ( coo [ 0 ] * 2 < = - period & & coo [ 0 ] > = - period & & coo [ 2 ] = = period + coo [ 0 ] & & coo [ 2 ] = = - coo [ 1 ] ) return ;
/* apply periods */
for ( int i = 0 ; i < 3 ; i + + ) {
int j = ( i + 1 ) % 3 ;
int k = ( i + 2 ) % 3 ;
int v1 = coo [ i ] + coo [ j ] ;
int v2 = coo [ i ] - coo [ j ] ;
if ( v1 > = period ) {
coo [ i ] - = period ; coo [ j ] - = period ;
}
else if ( v1 < - period ) {
coo [ i ] + = period ; coo [ j ] + = period ;
}
else if ( v2 > = period ) {
coo [ i ] - = period ; coo [ j ] + = period ;
}
else if ( v2 < - period ) {
coo [ i ] + = period ; coo [ j ] - = period ;
}
else continue ;
d [ j ] = - d [ j ] ; d [ k ] = - d [ k ] ;
coo [ j ] = - coo [ j ] ; coo [ k ] = - coo [ k ] ;
transmatrix S = Id ;
S [ j ] [ j ] = - 1 ; S [ k ] [ k ] = - 1 ;
M = M * S ;
goto restart ;
}
return ;
}
}
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if ( twisted & 16 ) {
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int period = T0 [ 2 ] [ 2 ] ;
transmatrix RotYZX = Zero ;
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RotYZX [ 1 ] [ 0 ] = 1 ;
RotYZX [ 2 ] [ 1 ] = 1 ;
RotYZX [ 0 ] [ 2 ] = 1 ;
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RotYZX [ 3 ] [ 3 ] = 1 ;
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auto & coo = x ;
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while ( true ) {
auto coosum = coo [ 0 ] + coo [ 1 ] + coo [ 2 ] ;
if ( coosum > = 3 * period ) {
coo [ 0 ] - = period , coo [ 1 ] - = period , coo [ 2 ] - = period ;
tie ( d [ 0 ] , d [ 1 ] , d [ 2 ] ) = make_tuple ( d [ 1 ] , d [ 2 ] , d [ 0 ] ) ;
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tie ( coo [ 0 ] , coo [ 1 ] , coo [ 2 ] ) = make_tuple ( coo [ 1 ] , coo [ 2 ] , coo [ 0 ] ) ;
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M = M * RotYZX ;
}
else if ( coosum < 0 ) {
coo [ 0 ] + = period , coo [ 1 ] + = period , coo [ 2 ] + = period ;
tie ( d [ 0 ] , d [ 1 ] , d [ 2 ] ) = make_tuple ( d [ 2 ] , d [ 0 ] , d [ 1 ] ) ;
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tie ( coo [ 0 ] , coo [ 1 ] , coo [ 2 ] ) = make_tuple ( coo [ 2 ] , coo [ 0 ] , coo [ 1 ] ) ;
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M = M * RotYZX * RotYZX ;
}
else break ;
}
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if ( T0 [ 0 ] ! = euzero ) {
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while ( diagonal_cross ( coo , T0 [ 1 ] ) < 0 ) coo - = T0 [ 0 ] ;
while ( diagonal_cross ( coo , T0 [ 1 ] ) > 0 ) coo + = T0 [ 0 ] ;
while ( diagonal_cross ( coo , T0 [ 0 ] ) > 0 ) coo - = T0 [ 1 ] ;
while ( diagonal_cross ( coo , T0 [ 0 ] ) < 0 ) coo + = T0 [ 1 ] ;
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}
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return ;
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}
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if ( WDIM = = 3 ) {
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auto & coo = x ;
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while ( coo [ 2 ] > = T0 [ 2 ] [ 2 ] ) {
coo [ 2 ] - = T0 [ 2 ] [ 2 ] ;
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if ( twisted & 1 ) coo [ 0 ] * = - 1 , d [ 0 ] * = - 1 , M = M * MirrorX ;
if ( twisted & 2 ) coo [ 1 ] * = - 1 , d [ 1 ] * = - 1 , M = M * MirrorY ;
if ( twisted & 4 ) swap ( coo [ 0 ] , coo [ 1 ] ) , swap01 ( M ) , swap ( d [ 0 ] , d [ 1 ] ) ;
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}
while ( coo [ 2 ] < 0 ) {
coo [ 2 ] + = T0 [ 2 ] [ 2 ] ;
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if ( twisted & 4 ) swap ( coo [ 0 ] , coo [ 1 ] ) , swap ( d [ 0 ] , d [ 1 ] ) , swap01 ( M ) ;
if ( twisted & 1 ) coo [ 0 ] * = - 1 , d [ 0 ] * = - 1 , M = M * MirrorX ;
if ( twisted & 2 ) coo [ 1 ] * = - 1 , d [ 1 ] * = - 1 , M = M * MirrorY ;
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}
for ( int i : { 0 , 1 } )
if ( T0 [ i ] [ i ] ) coo [ i ] = gmod ( coo [ i ] , T0 [ i ] [ i ] ) ;
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return ;
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}
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else {
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gp : : loc coo = to_loc ( x ) ;
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gp : : loc ort = ort1 ( ) * twisted_vec ;
int dsc = dscalar ( twisted_vec , twisted_vec ) ;
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gp : : loc d0 ( d [ 0 ] , d [ 1 ] ) ;
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hyperpoint h = eumove ( to_coord ( twisted_vec ) ) * C0 ;
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while ( true ) {
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int dsx = dscalar ( coo , twisted_vec ) ;
if ( dsx > = dsc ) coo = coo - twisted_vec ;
else if ( dsx < 0 ) coo = coo + twisted_vec ;
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else break ;
M = M * spintox ( h ) * MirrorY * rspintox ( h ) ;
auto s = ort * dscalar ( d0 , ort ) * 2 ;
auto v = dscalar ( ort , ort ) ;
s . first / = v ;
s . second / = v ;
d0 = d0 - s ;
s = ort * dscalar ( coo , ort ) * 2 ;
s . first / = v ;
s . second / = v ;
coo = coo - s ;
mirr = ! mirr ;
}
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if ( ortho_vec ! = gp : : loc { 0 , 0 } ) {
int osc = dscalar ( ortho_vec , ortho_vec ) ;
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while ( true ) {
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int dsx = dscalar ( coo , ortho_vec ) ;
if ( dsx > = osc ) coo = coo - ortho_vec ;
else if ( dsx < 0 ) coo = coo + ortho_vec ;
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else break ;
}
}
d [ 0 ] = d0 . first ; d [ 1 ] = d0 . second ;
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x = to_coord ( coo ) ;
return ;
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}
}
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coord basic_canonicalize ( coord x ) {
transmatrix M = Id ;
auto dummy = euzero ;
bool dm = false ;
eu . canonicalize ( x , dummy , M , dm ) ;
return x ;
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}
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EX void prepare_torus3 ( ) {
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eu_edit = eu_input ;
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}
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EX void show_fundamental ( ) {
initquickqueue ( ) ;
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shiftmatrix M = ggmatrix ( cwt . at ) ;
shiftpoint h0 = M * C0 ;
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auto & T_edit = eu_edit . user_axes ;
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hyperpoint ha = M . T * ( eumove ( T_edit [ 0 ] ) * C0 - C0 ) / 2 ;
hyperpoint hb = M . T * ( eumove ( T_edit [ 1 ] ) * C0 - C0 ) / 2 ;
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if ( WDIM = = 3 ) {
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hyperpoint hc = M . T * ( eumove ( T_edit [ 2 ] ) * C0 - C0 ) / 2 ;
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for ( int d : { - 1 , 1 } ) for ( int e : { - 1 , 1 } ) {
queueline ( h0 + d * ha + e * hb - hc , h0 + d * ha + e * hb + hc , 0xFFFFFFFF ) ;
queueline ( h0 + d * hb + e * hc - ha , h0 + d * hb + e * hc + ha , 0xFFFFFFFF ) ;
queueline ( h0 + d * hc + e * ha - hb , h0 + d * hc + e * ha + hb , 0xFFFFFFFF ) ;
}
}
else {
queueline ( h0 + ha + hb , h0 + ha - hb , 0xFFFFFFFF ) ;
queueline ( h0 - ha + hb , h0 - ha - hb , 0xFFFFFFFF ) ;
queueline ( h0 + ha + hb , h0 - ha + hb , 0xFFFFFFFF ) ;
queueline ( h0 + ha - hb , h0 - ha - hb , 0xFFFFFFFF ) ;
}
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quickqueue ( ) ;
}
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intmatrix on_periods ( gp : : loc a , gp : : loc b ) {
intmatrix res ;
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for ( int i = 0 ; i < 3 ; i + + ) for ( int j = 0 ; j < 3 ; j + + ) res [ i ] [ j ] = 0 ;
res [ 0 ] [ 0 ] = a . first ;
res [ 0 ] [ 1 ] = a . second ;
res [ 1 ] [ 0 ] = b . first ;
res [ 1 ] [ 1 ] = b . second ;
res [ 2 ] [ 2 ] = 1 ;
return res ;
}
torus_config single_row_torus ( int qty , int dy ) {
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return { on_periods ( gp : : loc { dy , - 1 } , gp : : loc { qty , 0 } ) , 0 } ;
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}
torus_config regular_torus ( gp : : loc p ) {
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return { on_periods ( p , gp : : loc ( 0 , 1 ) * p ) , 0 } ;
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}
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EX torus_config rectangular_torus ( int x , int y , bool klein ) {
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if ( S3 = = 3 ) y / = 2 ;
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return { on_periods ( ort1 ( ) * gp : : loc ( y , 0 ) , gp : : loc ( x , 0 ) ) , klein ? 8 : 0 } ;
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}
void torus_config_option ( string name , char key , torus_config tc ) {
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dialog : : addBoolItem ( name , eu_edit . user_axes = = tc . user_axes & & eu_edit . twisted = = tc . twisted & & PURE , key ) ;
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dialog : : add_action ( [ tc ] {
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stop_game ( ) ;
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eu_input = eu_edit = tc ;
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set_variation ( eVariation : : pure ) ;
start_game ( ) ;
} ) ;
}
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EX int quotient_size = 2 ;
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EX void show_torus3 ( ) {
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int dim = WDIM ;
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auto & T_edit = eu_edit . user_axes ;
auto & twisted_edit = eu_edit . twisted ;
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cmode = sm : : SIDE | sm : : MAYDARK | sm : : TORUSCONFIG ;
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gamescreen ( 1 ) ;
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dialog : : init ( XLAT ( " Euclidean quotient spaces " ) ) ;
for ( int y = 0 ; y < dim + 1 ; y + + )
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dialog : : addBreak ( 100 ) ;
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dialog : : addInfo ( XLAT ( " columns specify periods " ) ) ;
dialog : : addInfo ( XLAT ( " (vectors you need to take to get back to start) " ) ) ;
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dialog : : addBreak ( 50 ) ;
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show_fundamental ( ) ;
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if ( dim = = 3 ) {
bool nondiag = false ;
for ( int i = 0 ; i < dim ; i + + )
for ( int j = 0 ; j < dim ; j + + )
if ( T_edit [ i ] [ j ] & & i ! = j ) nondiag = true ;
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if ( valid_third_turn ( T_edit ) ) {
auto g = geometry ;
if ( g = = gCubeTiling | |
( g = = gRhombic3 & & T_edit [ 2 ] [ 2 ] % 2 = = 0 ) | |
( g = = gBitrunc3 & & T_edit [ 0 ] [ 0 ] % 2 = = 0 & & T_edit [ 1 ] [ 1 ] % 2 = = 0 ) )
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dialog : : addBoolItem ( XLAT ( " third-turn space " ) , twisted_edit & 16 , ' x ' ) ;
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else
dialog : : addBoolItem ( XLAT ( " make it even " ) , twisted_edit & 16 , ' x ' ) ;
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dialog : : add_action ( [ ] { eu_edit . twisted ^ = 16 ; } ) ;
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}
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if ( valid_hantzsche_wendt ( T_edit ) ) {
auto g = geometry ;
if ( g = = gCubeTiling | | g = = gRhombic3 | | ( g = = gBitrunc3 & & T_edit [ 0 ] [ 0 ] % 2 = = 0 ) )
dialog : : addBoolItem ( XLAT ( " Hantzsche-Wendt space " ) , twisted_edit & 32 , ' x ' ) ;
else
dialog : : addBoolItem ( XLAT ( " make it even " ) , twisted_edit & 32 , ' x ' ) ;
dialog : : add_action ( [ ] { eu_edit . twisted ^ = 32 ; } ) ;
}
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if ( nondiag ) {
dialog : : addInfo ( XLAT ( " twisting implemented only for diagonal matrices " ) ) ;
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dialog : : addInfo ( XLAT ( " or for columns : (A,B,C), (B,C,A), (D,D,D) where A+B+C=0 " ) ) ;
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dialog : : addBreak ( 200 ) ;
}
else if ( T_edit [ dim - 1 ] [ dim - 1 ] = = 0 ) {
dialog : : addInfo ( XLAT ( " nothing to twist " ) ) ;
dialog : : addInfo ( XLAT ( " change the bottom left corner " ) ) ;
dialog : : addBreak ( 100 ) ;
}
else {
auto g = geometry ;
if ( g = = gCubeTiling | | ( T_edit [ 0 ] [ 0 ] + T_edit [ 2 ] [ 2 ] ) % 2 = = 0 )
dialog : : addBoolItem ( XLAT ( " flip X coordinate " ) , twisted_edit & 1 , ' x ' ) ;
else
dialog : : addBoolItem ( XLAT ( " flipping X impossible " ) , twisted_edit & 1 , ' x ' ) ;
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dialog : : add_action ( [ ] { eu_edit . twisted ^ = 1 ; } ) ;
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if ( g = = gCubeTiling | | ( T_edit [ 1 ] [ 1 ] + T_edit [ 2 ] [ 2 ] ) % 2 = = 0 )
dialog : : addBoolItem ( XLAT ( " flip Y coordinate " ) , twisted_edit & 2 , ' y ' ) ;
else
dialog : : addBoolItem ( XLAT ( " flipping Y impossible " ) , twisted_edit & 2 , ' y ' ) ;
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dialog : : add_action ( [ ] { eu_edit . twisted ^ = 2 ; } ) ;
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if ( T_edit [ 0 ] [ 0 ] = = T_edit [ 1 ] [ 1 ] )
dialog : : addBoolItem ( XLAT ( " swap X and Y " ) , twisted_edit & 4 , ' z ' ) ;
else
dialog : : addBoolItem ( XLAT ( " swapping impossible " ) , twisted_edit & 4 , ' z ' ) ;
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dialog : : add_action ( [ ] { eu_edit . twisted ^ = 4 ; } ) ;
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}
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dialog : : addBreak ( 50 ) ;
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dialog : : addItem ( " special manifolds " , ' S ' ) ;
dialog : : add_action ( [ ] {
dialog : : editNumber ( quotient_size , 1 , 12 , 1 , 2 , " special manifold size " , " " ) ;
dialog : : extra_options = [ ] {
auto q = quotient_size ;
torus_config_option ( XLAT ( " third-turn space " ) , ' A ' , make_third_turn ( q , 0 , q ) ) ;
torus_config_option ( XLAT ( " quarter-turn space " ) , ' B ' , make_quarter_turn ( q , 0 , q ) ) ;
torus_config_option ( XLAT ( " Hantzsche-Wendt space " ) , ' C ' , make_hantzsche_wendt ( q ) ) ;
} ;
} ) ;
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}
else {
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if ( T_edit [ 1 ] [ 0 ] = = 0 & & T_edit [ 1 ] [ 1 ] = = 0 )
dialog : : addInfo ( XLAT ( " change the second column for Möbius bands and Klein bottles " ) ) ;
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else if ( chiral ( to_loc ( T_edit [ 1 ] ) ) )
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dialog : : addInfo ( XLAT ( " second period is chiral -- cannot be mirrored " ) ) ;
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else if ( dscalar ( to_loc ( T_edit [ 1 ] ) , to_loc ( T_edit [ 0 ] ) ) )
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dialog : : addInfo ( XLAT ( " periods must be orthogonal for mirroring " ) ) ;
else {
dialog : : addBoolItem ( XLAT ( " mirror flip in the second period " ) , twisted_edit & 8 , ' x ' ) ;
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dialog : : add_action ( [ ] { eu_edit . twisted ^ = 8 ; } ) ;
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}
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dialog : : addBreak ( 50 ) ;
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torus_config_option ( XLAT ( " single-cell torus " ) , ' A ' , regular_torus ( gp : : loc { 1 , 0 } ) ) ;
torus_config_option ( XLAT ( " large regular torus " ) , ' B ' , regular_torus ( gp : : loc { 12 , 0 } ) ) ;
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torus_config_option ( XLAT ( " Klein bottle " ) , ' C ' , rectangular_torus ( 12 , 6 , true ) ) ;
torus_config_option ( XLAT ( " cylinder " ) , ' D ' , rectangular_torus ( 6 , 0 , false ) ) ;
torus_config_option ( XLAT ( " Möbius band " ) , ' E ' , rectangular_torus ( 6 , 0 , true ) ) ;
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if ( S3 = = 3 ) torus_config_option ( XLAT ( " seven-colorable torus " ) , ' F ' , regular_torus ( gp : : loc { 1 , 2 } ) ) ;
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if ( S3 = = 3 ) torus_config_option ( XLAT ( " HyperRogue classic torus " ) , ' G ' , single_row_torus ( 381 , - 22 ) ) ;
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torus_config_option ( XLAT ( " no quotient " ) , ' H ' , rectangular_torus ( 0 , 0 , false ) ) ;
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}
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dialog : : addBreak ( 50 ) ;
dialog : : addBoolItem ( XLAT ( " standard rotation " ) , eqmatrix ( models : : euclidean_spin , Id ) , ' s ' ) ;
dialog : : add_action ( [ ] { rotate_view ( models : : euclidean_spin ) ; } ) ;
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# if CAP_RUG
if ( GDIM = = 2 ) {
dialog : : addBoolItem ( XLAT ( " hypersian rug mode " ) , ( rug : : rugged ) , ' u ' ) ;
dialog : : add_action ( rug : : select ) ;
}
# endif
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dialog : : addBreak ( 50 ) ;
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char xch = ' p ' ;
for ( eGeometry g : { gCubeTiling , gRhombic3 , gBitrunc3 } ) {
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if ( dim = = 2 ) g = geometry ;
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dialog : : addItem ( XLAT ( ginf [ g ] . menu_displayed_name ) , xch + + ) ;
dialog : : add_action ( [ g ] {
stop_game ( ) ;
set_geometry ( g ) ;
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eu_input = eu_edit ;
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start_game ( ) ;
} ) ;
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if ( dim = = 2 ) break ;
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}
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dialog : : addBreak ( 50 ) ;
dialog : : addBack ( ) ;
dialog : : display ( ) ;
int i = - 1 ;
for ( auto & v : dialog : : items ) if ( v . type = = dialog : : diBreak ) {
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if ( i > = 0 & & i < dim ) {
for ( int j = 0 ; j < dim ; j + + ) {
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char ch = ' a ' + i * 3 + j ;
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if ( displayfr ( dialog : : dcenter + dialog : : dfspace * 4 * ( j - ( dim - 1. ) / 2 ) , v . position , 2 , dialog : : dfsize , its ( T_edit [ j ] [ i ] ) , 0xFFFFFF , 8 ) )
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getcstat = ch ;
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dialog : : add_key_action ( ch , [ i , j ] {
auto & T_edit = eu_edit . user_axes ;
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dialog : : editNumber ( T_edit [ j ] [ i ] , - 10 , + 10 , 1 , 0 , " " , XLAT (
" This matrix lets you play on the quotient spaces of three-dimensional. "
" Euclidean space. Every column specifies a translation vector which "
" takes you back to the starting point. For example, if you put "
" set 2, 6, 0 on the diagonal, you get back to the starting point "
" if you move 2 steps in the X direction, 6 steps in the Y direction "
" (the quotient space is infinite in the Z direction). \n \n "
" You can also introduce twists for diagonal matrices: after going "
" the given number of steps in the Z direction, the space is also "
" mirrored or rotated. (More general 'twisted' spaces are currently "
" not implemented.) "
)
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) ;
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dialog : : extra_options = show_fundamental ;
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} ) ;
}
}
i + + ;
}
}
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# if CAP_COMMANDLINE
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int euArgs ( ) {
using namespace arg ;
if ( 0 ) ;
else if ( argis ( " -t3 " ) ) {
PHASEFROM ( 2 ) ;
stop_game ( ) ;
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auto & T0 = eu_input . user_axes ;
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for ( int i = 0 ; i < 3 ; i + + )
for ( int j = 0 ; j < 3 ; j + + ) {
shift ( ) ; T0 [ i ] [ j ] = argi ( ) ;
}
build_torus3 ( ) ;
}
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else if ( argis ( " -t2 " ) ) {
PHASEFROM ( 2 ) ;
stop_game ( ) ;
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auto & T0 = eu_input . user_axes ;
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for ( int i = 0 ; i < 2 ; i + + )
for ( int j = 0 ; j < 2 ; j + + ) {
shift ( ) ; T0 [ i ] [ j ] = argi ( ) ;
}
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shift ( ) ; eu_input . twisted = argi ( ) ;
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build_torus3 ( ) ;
}
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else if ( argis ( " -twistthird " ) ) {
PHASEFROM ( 2 ) ;
stop_game ( ) ;
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shift ( ) ; int a = argi ( ) ;
shift ( ) ; int b = argi ( ) ;
shift ( ) ; int c = argi ( ) ;
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eu_input = make_third_turn ( a , b , c ) ;
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build_torus3 ( ) ;
}
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else if ( argis ( " -twist3 " ) ) {
PHASEFROM ( 2 ) ;
stop_game ( ) ;
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auto & T0 = eu_input . user_axes ;
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for ( int i = 0 ; i < 3 ; i + + )
for ( int j = 0 ; j < 3 ; j + + ) T0 [ i ] [ j ] = 0 ;
for ( int i = 0 ; i < 3 ; i + + ) {
shift ( ) ; T0 [ i ] [ i ] = argi ( ) ;
}
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shift ( ) ; eu_input . twisted = argi ( ) ;
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build_torus3 ( ) ;
}
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else if ( argis ( " -hw " ) ) {
PHASEFROM ( 2 ) ;
stop_game ( ) ;
shift ( ) ;
eu_input = make_hantzsche_wendt ( argi ( ) ) ;
build_torus3 ( ) ;
}
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else if ( argis ( " -twisttest " ) ) {
start_game ( ) ;
celllister cl ( cwt . at , 10000 , 10000 , NULL ) ;
for ( cell * c : cl . lst ) {
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heptagon * h = c - > master ;
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for ( int i = 0 ; i < S7 ; i + + )
for ( int j = 0 ; j < S7 ; j + + )
for ( int k = 0 ; k < S7 ; k + + )
for ( int l = 0 ; l < S7 ; l + + )
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if ( h - > move ( i ) & & c - > move ( k ) & & h - > move ( i ) - > move ( j ) = = h - > move ( k ) - > move ( l ) & & h - > move ( i ) - > move ( j ) ) {
transmatrix T1 = move_matrix ( h , i ) * move_matrix ( h - > move ( i ) , j ) ;
transmatrix T2 = move_matrix ( h , k ) * move_matrix ( h - > move ( k ) , l ) ;
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if ( ! eqmatrix ( T1 , T2 ) ) {
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println ( hlog , c , " @ " , cubemap ( ) - > ispacemap [ c - > master ] , " : " , i , " / " , j , " / " , k , " / " , l , " :: " , T1 , " vs " , T2 ) ;
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exit ( 1 ) ;
}
}
}
}
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else return 1 ;
return 0 ;
}
auto euhook = addHook ( hooks_args , 100 , euArgs ) ;
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# endif
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EX int dscalar ( gp : : loc e1 , gp : : loc e2 ) {
return 2 * ( e1 . first * e2 . first + e1 . second * e2 . second ) + ( S3 = = 3 ? e1 . first * e2 . second + e2 . first * e1 . second : 0 ) ;
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}
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EX int dsquare ( gp : : loc e ) { return dscalar ( e , e ) / 2 ; }
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EX int dcross ( gp : : loc e1 , gp : : loc e2 ) {
return e1 . first * e2 . second - e1 . second * e2 . first ;
}
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EX gp : : loc full_coords2 ( cell * c ) {
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if ( INVERSE ) {
cell * c1 = gp : : get_mapped ( c ) ;
return UIU ( full_coords2 ( c1 ) ) ;
}
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auto ans = eucmap ( ) - > ispacemap [ c - > master ] ;
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if ( S7 = = 4 & & BITRUNCATED ) {
if ( c = = c - > master - > c7 ) return to_loc ( ans ) * gp : : loc ( 1 , 1 ) ;
else {
auto res = full_coords2 ( c - > cmove ( 0 ) ) + full_coords2 ( c - > cmove ( 4 ) ) ;
res . first / = 2 ;
res . second / = 2 ;
return res ;
}
}
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if ( BITRUNCATED )
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return to_loc ( ans ) * gp : : loc ( 1 , 1 ) + ( c = = c - > master - > c7 ? gp : : loc ( 0 , 0 ) : gp : : eudir ( ( c - > c . spin ( 0 ) + 4 ) % 6 ) ) ;
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if ( GOLDBERG ) {
auto li = gp : : get_local_info ( c ) ;
gp : : loc shift ( 0 , 0 ) ;
if ( li . first_dir > = 0 ) shift = gp : : eudir ( li . last_dir ) * li . relative ;
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return to_loc ( ans ) * gp : : param + shift ;
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}
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return to_loc ( ans ) ;
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}
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/** this is slow, but we use it only for small p's */
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EX cell * at ( gp : : loc p ) {
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cellwalker cw ( currentmap - > gamestart ( ) ) ;
while ( p . first - - ) cw + = revstep ;
cw + + ;
while ( p . second - - ) cw + = revstep ;
return cw . at ;
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}
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EX coord to_coord ( gp : : loc p ) { return coord ( p . first , p . second , 0 ) ; }
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EX gp : : loc sdxy ( ) { return to_loc ( eu . user_axes [ 1 ] ) * gp : : univ_param ( ) ; }
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EX pair < bool , string > coord_display ( const shiftmatrix & V , cell * c ) {
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if ( c ! = c - > master - > c7 ) return { false , " " } ;
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hyperpoint hx = eumove ( main_axes [ 0 ] ) * C0 ;
hyperpoint hy = eumove ( main_axes [ 1 ] ) * C0 ;
hyperpoint hz = WDIM = = 2 ? C0 : eumove ( main_axes [ 2 ] ) * C0 ;
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hyperpoint h = kz ( inverse ( build_matrix ( hx , hy , hz , C03 ) ) * inverse_shift ( ggmatrix ( cwt . at - > master - > c7 ) , V ) * C0 ) ;
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if ( WDIM = = 3 )
return { true , fts ( h [ 0 ] ) + " , " + fts ( h [ 1 ] ) + " , " + fts ( h [ 2 ] ) } ;
else
return { true , fts ( h [ 0 ] ) + " , " + fts ( h [ 1 ] ) } ;
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}
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EX gp : : loc to_loc ( const coord & v ) { return gp : : loc ( v [ 0 ] , v [ 1 ] ) ; }
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EX map < gp : : loc , cdata > & get_cdata ( ) { return eucmap ( ) - > eucdata ; }
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EX transmatrix eumove ( coord co ) {
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const double q3 = sqrt ( double ( 3 ) ) ;
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if ( WDIM = = 3 ) {
return eupush3 ( co [ 0 ] , co [ 1 ] , co [ 2 ] ) ;
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}
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transmatrix Mat = Id ;
if ( a4 ) {
Mat [ 0 ] [ LDIM ] + = co [ 0 ] * cgi . tessf ;
Mat [ 1 ] [ LDIM ] + = co [ 1 ] * cgi . tessf ;
}
else {
Mat [ 0 ] [ LDIM ] + = ( co [ 0 ] + co [ 1 ] * .5 ) * cgi . tessf ;
Mat [ 1 ] [ LDIM ] + = co [ 1 ] * q3 / 2 * cgi . tessf ;
}
return Mat ;
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}
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EX transmatrix eumove ( gp : : loc co ) { return eumove ( to_coord ( co ) ) ; }
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EX bool chiral ( gp : : loc g ) {
int x = g . first ;
int y = g . second ;
if ( x = = 0 ) return false ;
if ( y = = 0 ) return false ;
if ( x + y = = 0 ) return false ;
if ( x = = y ) return false ;
if ( S3 = = 3 & & y = = - 2 * x ) return false ;
if ( S3 = = 3 & & x = = - 2 * y ) return false ;
return true ;
}
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EX void twist_once ( gp : : loc coo ) {
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coo = coo - eu . twisted_vec * gp : : univ_param ( ) ;
if ( eu . twisted & 8 ) {
gp : : loc ort = ort1 ( ) * eu . twisted_vec * gp : : univ_param ( ) ;
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auto s = ort * dscalar ( coo , ort ) * 2 ;
auto v = dscalar ( ort , ort ) ;
s . first / = v ;
s . second / = v ;
coo = coo - s ;
}
}
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EX int dist ( int sx , int sy , bool reduce IS ( true ) ) {
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int z0 = abs ( sx ) ;
int z1 = abs ( sy ) ;
if ( a4 & & BITRUNCATED )
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return ( z0 = = z1 & & z0 > 0 & & ! reduce ) ? z0 + 1 : max ( z0 , z1 ) ;
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if ( a4 ) return z0 + z1 ;
int z2 = abs ( sx + sy ) ;
return max ( max ( z0 , z1 ) , z2 ) ;
}
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EX int dist ( gp : : loc a , gp : : loc b ) {
return dist ( a . first - b . first , a . second - b . second , ( a . first ^ a . second ) & 1 ) ;
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}
EX int cyldist ( gp : : loc a , gp : : loc b ) {
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a = to_loc ( basic_canonicalize ( to_coord ( a ) ) ) ;
b = to_loc ( basic_canonicalize ( to_coord ( b ) ) ) ;
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if ( ! quotient ) return dist ( a , b ) ;
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int best = 0 ;
for ( int sa = 0 ; sa < 16 ; sa + + ) {
auto _a = a , _b = b ;
if ( sa & 1 ) twist_once ( _a ) ;
if ( sa & 2 ) twist_once ( _b ) ;
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if ( sa & 4 ) _a = _a + eu . ortho_vec * gp : : univ_param ( ) ;
if ( sa & 8 ) _b = _b + eu . ortho_vec * gp : : univ_param ( ) ;
int val = dist ( _a , _b ) ;
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if ( sa = = 0 | | val < best ) best = val ;
}
return best ;
}
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EX void generate ( ) {
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# if MAXMDIM >= 4
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if ( fake : : in ( ) ) {
fake : : generate ( ) ;
return ;
}
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auto v = euc : : get_shifttable ( ) ;
auto & cs = cgi . cellshape ;
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cgi . loop = 4 ;
cgi . schmid = 3 ;
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if ( S7 = = 6 ) {
cgi . adjcheck = 1 ;
cgi . face = 4 ;
for ( int w = 0 ; w < 6 ; w + + ) {
for ( int a = 0 ; a < 4 ; a + + ) {
int t [ 3 ] ;
t [ 0 ] = ( w > = 3 ) ? - 1 : 1 ;
t [ 1 ] = among ( a , 0 , 3 ) ? - 1 : 1 ;
t [ 2 ] = among ( a , 2 , 3 ) ? - 1 : 1 ;
int x = w % 3 ;
int y = ( x + 2 ) % 3 ;
int z = ( y + 2 ) % 3 ;
cs . push_back ( hpxy3 ( t [ x ] / 2. , t [ y ] / 2. , t [ z ] / 2. ) ) ;
}
}
}
if ( S7 = = 12 ) {
cgi . adjcheck = sqrt ( 2 ) ;
cgi . face = 4 ;
for ( int w = 0 ; w < 12 ; w + + ) {
auto co = v [ w ] ;
vector < int > valid ;
for ( int c = 0 ; c < 3 ; c + + ) if ( co [ c ] ) valid . push_back ( c ) ;
int third = 3 - valid [ 1 ] - valid [ 0 ] ;
hyperpoint v0 = cpush0 ( valid [ 0 ] , co [ valid [ 0 ] ] > 0 ? 1 : - 1 ) ;
hyperpoint v1 = cpush0 ( valid [ 1 ] , co [ valid [ 1 ] ] > 0 ? 1 : - 1 ) ;
cs . push_back ( v0 ) ;
cs . push_back ( v0 / 2 + v1 / 2 + cpush0 ( third , .5 ) - C0 ) ;
cs . push_back ( v1 ) ;
cs . push_back ( v0 / 2 + v1 / 2 + cpush0 ( third , - .5 ) - C0 ) ;
}
}
if ( S7 = = 14 ) {
cgi . adjcheck = 2 ;
cgi . face = 4 ; /* the first face */
auto v = euc : : get_shifttable ( ) ;
for ( int w = 0 ; w < 14 ; w + + ) {
if ( w % 7 < 3 ) {
int z = w > = 7 ? - 1 : 1 ;
cs . push_back ( cpush0 ( w % 7 , z ) + cpush0 ( ( w % 7 + 1 ) % 3 , 1 / 2. ) - C0 ) ;
cs . push_back ( cpush0 ( w % 7 , z ) + cpush0 ( ( w % 7 + 2 ) % 3 , 1 / 2. ) - C0 ) ;
cs . push_back ( cpush0 ( w % 7 , z ) + cpush0 ( ( w % 7 + 1 ) % 3 , - 1 / 2. ) - C0 ) ;
cs . push_back ( cpush0 ( w % 7 , z ) + cpush0 ( ( w % 7 + 2 ) % 3 , - 1 / 2. ) - C0 ) ;
}
else {
auto t = v [ w ] ;
ld x = t [ 0 ] , y = t [ 1 ] , z = t [ 2 ] ;
for ( hyperpoint h : {
hpxy3 ( x , y / 2 , 0 ) , hpxy3 ( x / 2 , y , 0 ) , hpxy3 ( 0 , y , z / 2 ) ,
hpxy3 ( 0 , y / 2 , z ) , hpxy3 ( x / 2 , 0 , z ) , hpxy3 ( x , 0 , z / 2 )
} ) cs . push_back ( h ) ;
}
}
}
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reg3 : : make_vertices_only ( ) ;
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# endif
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}
/** @brief returns true if the current geometry is based on this module
* ( For example , Archimedean , kite , or fake with underlying non - Euclidean geometry returns false )
*/
EX bool in ( ) {
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if ( fake : : in ( ) ) return FPIU ( in ( ) ) ;
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return euclid & & standard_tiling ( ) ;
}
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EX bool in ( int dim ) { return in ( ) & & WDIM = = dim ; }
EX bool in ( int dim , int s7 ) { return in ( dim ) & & S7 = = s7 ; }
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EX }
EX gp : : loc euc2_coordinates ( cell * c ) { return euc : : full_coords2 ( c ) ; }
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}