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// Hyperbolic Rogue -- rule generator
// Copyright (C) 2011-2021 Zeno Rogue, see 'hyper.cpp' for details
/** \file rulegen.cpp
* \ brief An algorithm to create strict tree rules for arb tessellations
*/
# include "hyper.h"
namespace hr {
EX namespace rulegen {
/* limits */
EX int max_retries = 999 ;
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EX int max_tcellcount = 1000000 ;
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EX int max_adv_steps = 100 ;
EX int max_examine_branch = 5040 ;
EX int max_bdata = 1000 ;
/* other parameters */
EX int dlbonus = 0 ;
# if HDR
/** exception thrown by this algoritm in case of any problems */
struct rulegen_failure : hr_exception {
rulegen_failure ( string _s ) : hr_exception ( _s ) { }
} ;
/** this exception is thrown if we want to restart the computation -- this is normal, but if thrown more than max_retries times, just surrender */
struct rulegen_retry : rulegen_failure {
rulegen_retry ( string _s ) : rulegen_failure ( _s ) { }
} ;
/** this exception is thrown in case if we run into a special case that is not implemented yet */
struct rulegen_surrender : rulegen_failure {
rulegen_surrender ( string _s ) : rulegen_failure ( _s ) { }
} ;
const int MYSTERY = 31999 ;
const int MYSTERY_DIST = 31998 ;
# endif
/* === tcell === */
/** number of tcells created */
EX int tcellcount = 0 ;
/** number of tcells united into other tcells */
EX int tunified = 0 ;
# if HDR
struct tcell * tmove ( tcell * c , int d ) ;
/** rulegen algorithm works on tcells which have their own map generation */
struct tcell {
/** tcells form a list */
tcell * next ;
/** shape ID in arb::current */
int id ;
/** degree */
int type ;
/** distance from the root */
short dist ;
/** cached code */
short code ;
/** direction to the parent in the tree */
short parent_dir ;
/** can we assume that dist is correct? if we assumed that the dist is correct but then find out it was wrong, throw an error */
bool is_solid ;
bool distance_fixed ;
/** sometimes we find out that multiple tcells represent the same actual cell -- in this case we unify them; unified_to is used for the union-find algorithm */
walker < tcell > unified_to ;
int degree ( ) { return type ; }
connection_table < tcell > c ;
tcell * & move ( int d ) { return c . move ( d ) ; }
tcell * & modmove ( int d ) { return c . modmove ( d ) ; }
tcell * cmove ( int d ) { return tmove ( this , d ) ; }
tcell * cmodmove ( int d ) { return tmove ( this , c . fix ( d ) ) ; }
tcell ( ) { }
} ;
inline void print ( hstream & hs , tcell * h ) { print ( hs , " P " , index_pointer ( h ) ) ; }
using twalker = walker < tcell > ;
# endif
queue < reaction_t > fix_queue ;
bool in_fixing = false ;
void unify_distances ( tcell * c1 , tcell * c2 ) ;
void handle_distance_errors ( ) ;
void process_fix_queue ( ) {
if ( in_fixing ) return ;
in_fixing = true ;
while ( ! fix_queue . empty ( ) ) {
fix_queue . front ( ) ( ) ;
fix_queue . pop ( ) ;
}
in_fixing = false ;
handle_distance_errors ( ) ;
}
void ufind ( twalker & p ) {
if ( p . at - > unified_to . at = = p . at ) return ;
twalker p1 = p . at - > unified_to ;
ufind ( p1 ) ;
p . at - > unified_to = p1 ;
p = p1 + p . spin ;
}
EX tcell * first_tcell = nullptr ;
void connect_and_check ( twalker p1 , twalker p2 ) ;
void unify ( twalker pw1 , twalker pw2 ) ;
tcell * gen_tcell ( int id ) {
int d = isize ( arb : : current . shapes [ id ] . connections ) ;
auto c = tailored_alloc < tcell > ( d ) ;
c - > id = id ;
c - > next = first_tcell ;
c - > unified_to = twalker ( c , 0 ) ;
c - > is_solid = false ;
c - > distance_fixed = false ;
c - > dist = MYSTERY ;
c - > code = MYSTERY ;
c - > parent_dir = MYSTERY ;
first_tcell = c ;
// println(hlog, c, " is a new tcell of id ", id);
tcellcount + + ;
return c ;
}
tcell * tmove ( tcell * c , int d ) {
if ( c - > move ( d ) ) return c - > move ( d ) ;
auto & co = arb : : current . shapes [ c - > id ] . connections [ d ] ;
auto cd = twalker ( c , d ) ;
ufind ( cd ) ;
tcell * c1 = gen_tcell ( co . sid ) ;
connect_and_check ( cd , twalker ( c1 , co . eid ) ) ;
return c1 ;
}
/** check whether we have completed the vertex to the right of edge d of c */
void check_loops ( twalker pw ) {
ufind ( pw ) ;
auto & shs = arb : : current . shapes ;
int id = pw . at - > id ;
int valence = shs [ id ] . vertex_valence [ pw . spin ] ;
int steps = 0 ;
twalker pwf = pw ;
twalker pwb = pw ;
while ( true ) {
if ( ! pwb . peek ( ) ) break ;
pwb = pwb + wstep - 1 ;
steps + + ;
if ( pwb = = pwf ) {
if ( steps = = valence ) return ; /* that's great, we already know this loop */
else throw hr_exception ( " vertex valence too small " ) ;
}
if ( steps = = valence ) {
fix_queue . push ( [ = ] { unify ( pwf , pwb ) ; } ) ;
return ;
}
}
while ( true ) {
pwf + + ;
if ( ! pwf . peek ( ) ) break ;
pwf + = wstep ;
steps + + ;
if ( pwb = = pwf ) {
if ( steps = = valence ) return ; /* that's great, we already know this loop */
else throw hr_exception ( " vertex valence too small " ) ;
}
if ( steps = = valence ) {
fix_queue . push ( [ = ] { unify ( pwf , pwb ) ; } ) ;
return ;
}
}
if ( steps = = valence - 1 ) {
connect_and_check ( pwb , pwf ) ;
}
}
void connect_and_check ( twalker p1 , twalker p2 ) {
p1 . at - > c . connect ( p1 . spin , p2 . at , p2 . spin , false ) ;
fix_queue . push ( [ = ] { check_loops ( p1 ) ; } ) ;
fix_queue . push ( [ = ] { check_loops ( p2 ) ; } ) ;
process_fix_queue ( ) ;
}
void unify ( twalker pw1 , twalker pw2 ) {
ufind ( pw1 ) ;
ufind ( pw2 ) ;
if ( pw1 . at - > unified_to . at ! = pw1 . at )
throw hr_exception ( " not unified to itself " ) ;
if ( pw2 . at - > unified_to . at ! = pw2 . at )
throw hr_exception ( " not unified to itself " ) ;
if ( pw1 . at = = pw2 . at ) {
if ( pw1 . spin ! = pw2 . spin ) throw hr_exception ( " called unify with self and wrong direction " ) ;
return ;
}
if ( pw1 . at - > id ! = pw2 . at - > id )
throw hr_exception ( " unifying two cells of different id's " ) ;
auto & shs = arb : : current . shapes ;
int id = pw1 . at - > id ;
for ( int i = 0 ; i < shs [ id ] . size ( ) ; i + + ) {
if ( ! pw2 . peek ( ) ) {
/* no need to reconnect */
}
else if ( ! pw1 . peek ( ) ) {
connect_and_check ( pw1 , pw2 + wstep ) ;
}
else {
fix_queue . push ( [ = ] { unify ( pw1 + wstep , pw2 + wstep ) ; } ) ;
auto ss = pw1 + wstep ;
connect_and_check ( pw1 , pw2 + wstep ) ;
connect_and_check ( pw1 , ss ) ;
}
pw1 + + ;
pw2 + + ;
}
pw2 . at - > unified_to = pw1 - pw2 . spin ;
tunified + + ;
unify_distances ( pw1 . at , pw2 . at ) ;
}
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EX vector < tcell * > t_origin ;
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void delete_tmap ( ) {
while ( first_tcell ) {
auto second = first_tcell - > next ;
tailored_delete ( first_tcell ) ;
first_tcell = second ;
}
tcellcount = 0 ;
tunified = 0 ;
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t_origin . clear ( ) ;
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}
/* used in the debugger */
EX vector < twalker > debuglist ;
/* === distances === */
bool no_errors = false ;
struct hr_solid_error : rulegen_retry {
hr_solid_error ( ) : rulegen_retry ( " solid error " ) { }
} ;
int solid_errors ;
void fix_distances_rec ( tcell * c ) {
c - > distance_fixed = true ;
vector < tcell * > q = { c } ;
for ( int qi = 0 ; qi < isize ( q ) ; qi + + ) {
c = q [ qi ] ;
auto & d = c - > dist ;
restart :
for ( int i = 0 ; i < c - > type ; i + + ) {
tcell * c1 = c - > cmove ( i ) ;
if ( c1 - > dist = = MYSTERY ) continue ;
auto & d1 = c1 - > dist ;
if ( d > d1 + 1 ) { d = d1 + 1 ; goto restart ; }
if ( d1 > d + 1 ) {
if ( c1 - > is_solid ) {
if ( debugflags & DF_GEOM )
println ( hlog , " solid " , c1 , " changes " , d1 , " to " , d + 1 ) ;
solid_errors + + ;
}
d1 = d + 1 ;
q . push_back ( c1 ) ;
}
}
}
}
EX int prepare_around_radius ;
void fix_distances ( tcell * c ) {
fix_distances_rec ( c ) ;
handle_distance_errors ( ) ;
}
void calc_distances ( tcell * c ) {
if ( c - > dist ! = MYSTERY ) return ;
c - > dist = MYSTERY_DIST ;
fix_distances ( c ) ;
}
void prepare_around ( tcell * c ) {
vector < tcell * > q ;
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set < tcell * > visited ;
auto visit = [ & ] ( tcell * x ) {
if ( visited . count ( x ) ) return ;
visited . insert ( x ) ;
q . push_back ( x ) ;
} ;
visit ( c ) ;
int next_lev = 1 ;
int cdist = 0 ;
for ( int i = 0 ; i < isize ( q ) ; i + + ) {
if ( i = = next_lev ) { cdist + + ; if ( cdist = = prepare_around_radius ) break ; next_lev = isize ( q ) ; }
tcell * cx = q [ i ] ;
for ( int d = 0 ; d < cx - > type ; d + + ) visit ( cx - > cmove ( d ) ) ;
}
for ( auto cx : q ) calc_distances ( cx ) ;
}
void unify_distances ( tcell * c1 , tcell * c2 ) {
int d1 = c1 - > dist ;
int d2 = c2 - > dist ;
int d = min ( d1 , d2 ) ;
c1 - > dist = d ;
c2 - > dist = d ;
if ( c1 - > is_solid & & d ! = d1 ) solid_errors + + ;
if ( c2 - > is_solid & & d ! = d2 ) solid_errors + + ;
c1 - > distance_fixed = c1 - > distance_fixed | | c2 - > distance_fixed ;
c1 - > is_solid = c1 - > is_solid | | c2 - > is_solid ;
if ( c1 - > dist < MYSTERY )
fix_distances_rec ( c1 ) ;
}
void handle_distance_errors ( ) {
bool b = solid_errors ;
solid_errors = 0 ;
if ( b & & ! no_errors ) {
prepare_around_radius + + ;
if ( debugflags & DF_GEOM )
println ( hlog , " increased prepare_around_radius to " , prepare_around_radius ) ;
throw hr_solid_error ( ) ;
}
}
/** make sure that we know c->dist */
void be_solid ( tcell * c ) {
if ( c - > is_solid ) return ;
if ( tcellcount > = max_tcellcount )
throw rulegen_surrender ( " max_tcellcount exceeded " ) ;
prepare_around ( c ) ;
c - > is_solid = true ;
}
/** which neighbor will become the parent of c */
int get_parent_dir ( tcell * c ) {
if ( c - > parent_dir ! = MYSTERY ) return c - > parent_dir ;
int bestd = - 1 ;
vector < int > bestrootpath ;
be_solid ( c ) ;
if ( c - > dist > 0 ) {
auto & sh = arb : : current . shapes [ c - > id ] ;
int n = sh . size ( ) ;
int k = sh . cycle_length ;
vector < int > olen ;
for ( int i = 0 ; i < k ; i + + ) {
vector < int > nearer ;
for ( int j = 0 ; j < n / k ; j + + ) {
tcell * c1 = c - > cmove ( i + j * k ) ;
be_solid ( c1 ) ;
olen . push_back ( c1 - > dist ) ;
if ( c1 - > dist < c - > dist ) {
nearer . push_back ( j ) ;
}
}
if ( nearer . size ( ) = = 1 ) { bestd = i + nearer [ 0 ] * k ; break ; }
if ( nearer . size ( ) = = 2 & & nearer [ 1 ] = = nearer [ 0 ] + 1 ) {
bestd = i + nearer [ 0 ] * k ;
break ;
}
if ( nearer . size ( ) = = 2 & & nearer [ 0 ] = = 0 & & nearer [ 1 ] = = n / k - 1 ) {
bestd = i + nearer [ 1 ] * k ;
break ;
}
if ( nearer . size ( ) > 1 ) throw rulegen_failure ( " still confused " ) ;
}
if ( bestd = = - 1 ) throw rulegen_failure ( " should not happen " ) ;
}
c - > parent_dir = bestd ;
return bestd ;
}
/** determine states for tcells */
# if HDR
using aid_t = pair < int , int > ;
struct analyzer {
vector < twalker > spread ;
vector < int > parent_id ;
vector < int > spin ;
void add_step ( int pid , int s ) {
twalker cw = spread [ pid ] ;
cw = cw + s + wstep ;
spread . push_back ( cw ) ;
parent_id . push_back ( pid ) ;
spin . push_back ( s ) ;
}
} ;
# endif
map < aid_t , analyzer > analyzers ;
EX aid_t get_aid ( twalker cw ) {
ufind ( cw ) ;
auto ide = cw . at - > id ;
return { ide , gmod ( cw . to_spin ( 0 ) , arb : : current . shapes [ ide ] . cycle_length ) } ;
}
EX analyzer & get_analyzer ( twalker cw ) {
auto aid = get_aid ( cw ) ;
auto & a = analyzers [ aid ] ;
if ( a . spread . empty ( ) ) {
a . spread . push_back ( cw ) ;
a . parent_id . push_back ( - 1 ) ;
a . spin . push_back ( - 1 ) ;
for ( int i = 0 ; i < cw . at - > type ; i + + )
a . add_step ( 0 , i ) ;
}
return a ;
}
EX vector < twalker > spread ( analyzer & a , twalker cw ) {
vector < twalker > res ;
int N = isize ( a . spread ) ;
res . reserve ( N ) ;
res . push_back ( cw ) ;
for ( int i = 1 ; i < N ; i + + )
res . push_back ( res [ a . parent_id [ i ] ] + a . spin [ i ] + wstep ) ;
return res ;
}
void extend_analyzer ( twalker cw_target , int dir , int id , int mism , twalker rg ) {
if ( debugflags & DF_GEOM )
println ( hlog , " extend called, cw_target = " , cw_target ) ;
twalker cw_conflict = cw_target + dir + wstep ;
auto & a_target = get_analyzer ( cw_target ) ;
auto & a_conflict = get_analyzer ( cw_conflict ) ;
twalker model = a_target . spread [ 0 ] + dir + wstep ;
auto res = spread ( a_conflict , model ) ;
vector < int > ids_to_add ;
int k = id ;
while ( k ) {
ids_to_add . emplace_back ( a_conflict . spin [ k ] ) ;
k = a_conflict . parent_id [ k ] ;
}
int gid = 1 + dir ;
bool added = false ;
while ( ! ids_to_add . empty ( ) ) {
int spin = ids_to_add . back ( ) ;
ids_to_add . pop_back ( ) ;
int next_gid = - 1 ;
for ( int i = 0 ; i < isize ( a_target . parent_id ) ; i + + )
if ( a_target . parent_id [ i ] = = gid & & a_target . spin [ i ] = = spin ) {
next_gid = i ;
}
if ( next_gid = = - 1 ) {
next_gid = isize ( a_target . parent_id ) ;
a_target . add_step ( gid , spin ) ;
added = true ;
}
gid = next_gid ;
}
if ( mism = = 0 & & ! added )
throw rulegen_failure ( " no extension " ) ;
}
# if HDR
using code_t = pair < aid_t , vector < int > > ;
struct treestate {
int id ;
bool known ;
vector < int > rules ;
twalker giver ;
int sid ;
int parent_dir ;
tcell * where_seen ;
code_t code ;
bool is_live ;
bool is_possible_parent ;
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bool is_root ;
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vector < pair < int , int > > possible_parents ;
} ;
static const int C_IGNORE = 0 ;
static const int C_CHILD = 1 ;
static const int C_UNCLE = 2 ;
static const int C_EQUAL = 4 ;
static const int C_NEPHEW = 6 ;
static const int C_PARENT = 8 ;
# endif
EX vector < treestate > treestates ;
set < twalker > sideswap ;
/** is what on the left side, or the right side, of to_what? */
int get_side ( tcell * what , tcell * to_what ) {
twalker w ( what , - 1 ) ;
twalker tw ( to_what , - 1 ) ;
auto adv = [ ] ( twalker & cw ) {
int d = get_parent_dir ( cw . at ) ;
cw . spin = d ;
cw + = wstep ;
} ;
while ( w . at ! = tw . at ) {
ufind ( w ) ; ufind ( tw ) ;
if ( w . at - > dist > tw . at - > dist )
adv ( w ) ;
else if ( w . at - > dist < tw . at - > dist )
adv ( tw ) ;
else {
adv ( w ) ; adv ( tw ) ;
}
}
if ( w . spin = = - 1 | | tw . spin = = - 1 ) return 0 ;
int d = get_parent_dir ( w . at ) ;
if ( d > = 0 ) {
twalker last ( w . at , d ) ;
return last . to_spin ( w . spin ) - last . to_spin ( tw . spin ) ;
}
// failed to solve this in the simple way (ended at the root) -- go around the tree
twalker wl ( what , get_parent_dir ( what ) ) ;
twalker wr = wl ;
auto go = [ & ] ( twalker & cw , int delta ) {
int d = get_parent_dir ( cw . at ) ;
if ( cw . spin = = d | | get_parent_dir ( cw . peek ( ) ) = = ( cw + wstep ) . spin )
cw + = wstep ;
cw + = delta ;
} ;
while ( true ) {
go ( wl , - 1 ) ;
go ( wr , + 1 ) ;
if ( wl . at = = to_what ) return + 1 ;
if ( wr . at = = to_what ) return - 1 ;
}
}
code_t id_at_spin ( twalker cw ) {
code_t res ;
ufind ( cw ) ;
res . first = get_aid ( cw ) ;
auto & a = get_analyzer ( cw ) ;
vector < twalker > sprawl = spread ( a , cw ) ;
int id = 0 ;
for ( auto cs : sprawl ) {
be_solid ( cs . at ) ;
be_solid ( cw . at ) ;
ufind ( cw ) ;
ufind ( cs ) ;
int x ;
int pid = a . parent_id [ id ] ;
if ( pid > - 1 & & ( res . second [ pid ] ! = C_CHILD ) ) {
x = C_IGNORE ;
}
else {
int p = get_parent_dir ( cs . at ) ;
if ( p > = 0 & & get_parent_dir ( cs . at ) = = cs . spin )
x = C_CHILD ;
else {
int y = cs . at - > dist - cs . peek ( ) - > dist ;
if ( y = = 1 ) x = C_NEPHEW ;
else if ( y = = 0 ) x = C_EQUAL ;
else if ( y = = - 1 ) x = C_UNCLE ;
else throw rulegen_failure ( " distance problem " ) ;
auto gs = get_side ( cs . at , cs . peek ( ) ) ;
if ( gs = = 0 & & x = = C_UNCLE ) x = C_PARENT ;
if ( gs > 0 ) x + + ;
}
}
res . second . push_back ( x ) ;
id + + ;
}
return res ;
}
map < code_t , int > code_to_id ;
EX pair < int , int > get_code ( tcell * c ) {
if ( c - > code ! = MYSTERY ) {
int bestd = c - > parent_dir ;
if ( bestd = = - 1 ) bestd = 0 ;
return { bestd , c - > code } ;
}
be_solid ( c ) ;
for ( int i = 0 ; i < c - > type ; i + + ) {
twalker cw0 ( c , i ) ;
twalker cw ( c , i ) ;
cw + = wstep ;
int val = 0 ;
while ( cw . at ! = cw0 . at ) {
ufind ( cw0 ) ; ufind ( cw ) ;
be_solid ( cw . at ) ;
cw + + ;
cw + = wstep ;
val + + ;
if ( val > 1000 )
throw rulegen_failure ( " excessive valence problem " ) ;
}
}
int bestd = get_parent_dir ( c ) ;
if ( bestd = = - 1 ) bestd = 0 ;
indenter ind ( 2 ) ;
code_t v = id_at_spin ( twalker ( c , bestd ) ) ;
if ( code_to_id . count ( v ) ) {
c - > code = code_to_id [ v ] ;
return { bestd , code_to_id [ v ] } ;
}
int id = isize ( treestates ) ;
code_to_id [ v ] = id ;
if ( c - > code ! = MYSTERY & & ( c - > code ! = id | | c - > parent_dir ! = bestd ) ) exit ( 1 ) ;
c - > code = id ;
treestates . emplace_back ( ) ;
auto & nts = treestates . back ( ) ;
nts . id = id ;
nts . code = v ;
nts . where_seen = c ;
nts . known = false ;
nts . is_live = true ;
return { bestd , id } ;
}
/* == rule generation == */
struct mismatch_error : rulegen_retry {
mismatch_error ( ) : rulegen_retry ( " mismatch error " ) { }
} ;
struct double_edges : rulegen_surrender {
double_edges ( ) : rulegen_surrender ( " double edges detected " ) { }
} ;
EX int rule_root ;
vector < int > gen_rule ( twalker cwmain ) ;
EX int try_count ;
vector < tcell * > important ;
vector < tcell * > cq ;
# if HDR
/* special codes */
static const int DIR_UNKNOWN = - 1 ;
static const int DIR_MULTI_GO_LEFT = - 2 ;
static const int DIR_MULTI_GO_RIGHT = - 3 ;
static const int DIR_LEFT = - 4 ;
static const int DIR_RIGHT = - 5 ;
static const int DIR_PARENT = - 6 ;
# endif
vector < int > gen_rule ( twalker cwmain ) {
vector < int > cids ;
for ( int a = 0 ; a < cwmain . at - > type ; a + + ) {
auto front = cwmain + a ;
tcell * c1 = front . cpeek ( ) ;
be_solid ( c1 ) ;
if ( a = = 0 & & cwmain . at - > dist ) { cids . push_back ( DIR_PARENT ) ; continue ; }
if ( c1 - > dist < = cwmain . at - > dist ) { cids . push_back ( DIR_UNKNOWN ) ; continue ; }
auto co = get_code ( c1 ) ;
auto & d1 = co . first ;
auto & id1 = co . second ;
if ( c1 - > cmove ( d1 ) ! = cwmain . at | | c1 - > c . spin ( d1 ) ! = front . spin ) {
cids . push_back ( DIR_UNKNOWN ) ; continue ;
}
cids . push_back ( id1 ) ;
}
return cids ;
}
void rules_iteration_for ( tcell * c ) {
indenter ri ( 2 ) ;
auto co = get_code ( c ) ;
auto & d = co . first ;
auto & id = co . second ;
twalker cwmain ( c , d ) ;
ufind ( cwmain ) ;
vector < int > cids = gen_rule ( cwmain ) ;
auto & ts = treestates [ id ] ;
if ( ! ts . known ) {
ts . known = true ;
ts . rules = cids ;
ts . giver = cwmain ;
ts . sid = cwmain . at - > id ;
ts . parent_dir = cwmain . spin ;
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ts . is_root = c - > dist = = 0 ;
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for ( int d = 0 ; d < c - > type ; d + + )
cq . push_back ( c - > cmove ( d ) ) ;
}
else if ( ts . rules ! = cids ) {
auto & r = ts . rules ;
if ( debugflags & DF_GEOM ) {
println ( hlog , " merging " , ts . rules , " vs " , cids ) ;
println ( hlog , " C " , treestates [ id ] . code , " [ " , id , " ] " ) ;
}
int mismatches = 0 ;
for ( int z = 0 ; z < isize ( cids ) ; z + + ) {
if ( r [ z ] = = cids [ z ] ) continue ;
if ( r [ z ] < 0 | | cids [ z ] < 0 )
throw rulegen_failure ( " neg rule mismatch " ) ;
auto & c1 = treestates [ r [ z ] ] . code . second ;
auto & c2 = treestates [ cids [ z ] ] . code . second ;
if ( debugflags & DF_GEOM ) {
println ( hlog , " direction " , z , " : " ) ;
println ( hlog , " A " , treestates [ r [ z ] ] . code , " [ " , r [ z ] , " ] " ) ;
println ( hlog , " B " , treestates [ cids [ z ] ] . code , " [ " , cids [ z ] , " ] " ) ;
}
if ( isize ( c1 ) ! = isize ( c2 ) ) {
throw rulegen_failure ( " length mismatch " ) ;
}
for ( int k = 0 ; k < isize ( c1 ) ; k + + ) {
if ( c1 [ k ] = = C_IGNORE | | c2 [ k ] = = C_IGNORE ) continue ;
if ( c1 [ k ] ! = c2 [ k ] ) {
if ( debugflags & DF_GEOM ) {
println ( hlog , " code mismatch ( " , c1 [ k ] , " vs " , c2 [ k ] , " at position " , k , " out of " , isize ( c1 ) , " ) " ) ;
println ( hlog , " rulegiver = " , treestates [ id ] . giver , " c = " , cwmain ) ;
println ( hlog , " gshvid = " , c - > id ) ;
println ( hlog , " cellcount = " , tcellcount , " - " , tunified , " codes discovered = " , isize ( treestates ) ) ;
}
extend_analyzer ( cwmain , z , k , mismatches , treestates [ id ] . giver ) ;
mismatches + + ;
}
}
}
debuglist = { cwmain , ts . giver } ;
if ( mismatches )
throw mismatch_error ( ) ;
throw rulegen_failure ( " no mismatches?! " ) ;
}
}
void minimize_rules ( ) {
if ( debugflags & DF_GEOM )
println ( hlog , " minimizing rules... " ) ;
int next_id = isize ( treestates ) ;
vector < int > new_id ( next_id ) ;
map < aid_t , int > new_id_of ;
int new_ids = 0 ;
for ( int id = 0 ; id < next_id ; id + + ) {
auto aid = get_aid ( treestates [ id ] . giver ) ;
if ( ! new_id_of . count ( aid ) ) new_id_of [ aid ] = new_ids + + ;
new_id [ id ] = new_id_of [ aid ] ;
}
int last_new_ids = 0 ;
while ( new_ids > last_new_ids & & new_ids < next_id ) {
last_new_ids = new_ids ;
map < vector < int > , int > hashes ;
new_ids = 0 ;
auto last_new_id = new_id ;
for ( int id = 0 ; id < next_id ; id + + ) {
vector < int > hash ;
hash . push_back ( last_new_id [ id ] ) ;
auto & ts = treestates [ id ] ;
for ( auto & r : ts . rules )
if ( r > = 0 ) hash . push_back ( last_new_id [ r ] ) ;
else hash . push_back ( r ) ;
if ( ! hashes . count ( hash ) )
hashes [ hash ] = new_ids + + ;
new_id [ id ] = hashes [ hash ] ;
}
}
if ( debugflags & DF_GEOM )
println ( hlog , " final new_ids = " , new_ids , " / " , next_id ) ;
if ( 1 ) {
vector < int > old_id ( new_ids , - 1 ) ;
for ( int i = 0 ; i < next_id ; i + + ) if ( old_id [ new_id [ i ] ] = = - 1 ) old_id [ new_id [ i ] ] = i ;
for ( int i = 0 ; i < new_ids ; i + + ) treestates [ i ] = treestates [ old_id [ i ] ] ;
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for ( int i = 0 ; i < new_ids ; i + + ) treestates [ i ] . id = i ;
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treestates . resize ( new_ids ) ;
for ( auto & ts : treestates ) {
for ( auto & r : ts . rules )
if ( r > = 0 ) r = new_id [ r ] ;
}
for ( auto & p : code_to_id ) p . second = new_id [ p . second ] ;
}
}
void find_possible_parents ( ) {
for ( auto & ts : treestates ) {
ts . is_possible_parent = false ;
for ( int r : ts . rules )
if ( r = = DIR_PARENT )
ts . is_possible_parent = true ;
}
while ( true ) {
int changes = 0 ;
for ( auto & ts : treestates ) ts . possible_parents . clear ( ) ;
for ( auto & ts : treestates )
if ( ts . is_possible_parent ) {
int rid = 0 ;
for ( int r : ts . rules ) {
if ( r > = 0 ) treestates [ r ] . possible_parents . emplace_back ( ts . id , rid ) ;
rid + + ;
}
}
for ( auto & ts : treestates )
if ( ts . is_possible_parent & & ts . possible_parents . empty ( ) ) {
ts . is_possible_parent = false ;
changes + + ;
}
if ( ! changes ) break ;
}
int pp = 0 ;
for ( auto & ts : treestates ) if ( ts . is_possible_parent ) pp + + ;
if ( debugflags & DF_GEOM )
println ( hlog , pp , " of " , isize ( treestates ) , " states are possible_parents " ) ;
}
/* == branch testing == */
struct bad_tree : rulegen_retry {
bad_tree ( ) : rulegen_retry ( " bad tree " ) { }
} ;
bool equiv ( twalker w1 , twalker w2 ) ;
inline bool IS_DIR_MULTI ( int d ) { return among ( d , DIR_MULTI_GO_LEFT , DIR_MULTI_GO_RIGHT ) ; }
struct branchdata {
int id ;
int dir ;
twalker at ;
int temporary ;
void step ( ) {
if ( treestates [ id ] . rules [ dir ] < 0 )
throw rulegen_failure ( " invalid step " ) ;
id = treestates [ id ] . rules [ dir ] ; dir = 0 ; at + = wstep ;
auto co = get_code ( at . at ) ;
auto & d1 = co . first ;
auto & id1 = co . second ;
if ( id ! = id1 | | d1 ! = at . spin ) {
important . push_back ( at . at ) ;
if ( debugflags & DF_GEOM )
println ( hlog , " expected " , id , " found " , id1 , " at " , at ) ;
important . push_back ( at . at - > cmove ( get_parent_dir ( at . at ) ) ) ;
throw bad_tree ( ) ;
}
}
void spin ( int i ) {
at + = i ;
dir + = i ;
dir = gmod ( dir , isize ( treestates [ id ] . rules ) ) ;
}
void spin_full ( int i ) {
spin ( i ) ;
while ( IS_DIR_MULTI ( treestates [ id ] . rules [ dir ] ) )
spin ( i ) ;
}
} ;
inline void print ( hstream & hs , const branchdata & bd ) { print ( hs , " [ " , bd . id , " : " , bd . dir , " " , bd . at , " : " , bd . temporary , " ] " ) ; }
/* we need to be careful with multiple edges */
bool paired ( twalker w1 , twalker w2 ) {
if ( w1 + wstep = = w2 ) return true ;
if ( w1 . cpeek ( ) = = w2 . at & & w2 . cpeek ( ) = = w1 . at ) {
return true ;
}
return false ;
}
bool equiv ( twalker w1 , twalker w2 ) {
if ( w1 = = w2 ) return true ;
if ( w1 . at = = w2 . at & & w1 . cpeek ( ) = = w2 . cpeek ( ) ) {
return true ;
}
return false ;
}
void advance ( vector < branchdata > & bdata , branchdata at , int dir , bool start_forward , bool stack , int distlimit ) {
if ( start_forward ) {
at . step ( ) ;
at . spin_full ( dir ) ;
}
else {
at . spin_full ( dir ) ;
}
vector < branchdata > b ;
int steps = 0 ;
while ( true ) {
steps + + ; if ( steps = = max_adv_steps )
throw rulegen_failure ( " max_adv_steps exceeded " ) ;
auto & ts = treestates [ at . id ] ;
auto r = ts . rules [ at . dir ] ;
if ( r < 0 ) {
at . temporary = 0 ;
b . push_back ( at ) ;
break ;
}
else if ( ! treestates [ r ] . is_live ) {
advance ( b , at , dir , true , false , distlimit ) ;
if ( b . back ( ) . dir = = 0 )
b . pop_back ( ) ;
else
advance ( b , at , - dir , true , true , distlimit ) ;
at . spin_full ( dir ) ;
}
else {
at . step ( ) ;
if ( at . at . at - > dist < distlimit | | ! ts . is_live ) at . spin_full ( dir ) ;
else {
at . temporary = dir ;
b . push_back ( at ) ;
break ;
}
}
}
if ( stack ) {
while ( b . size ( ) ) { bdata . push_back ( b . back ( ) ) ; b . pop_back ( ) ; }
}
else {
for ( auto & bd : b ) bdata . push_back ( bd ) ;
}
}
map < int , branchdata > split ;
void assign_lr ( branchdata bd , int dir ) {
if ( dir ) { bd . spin_full ( dir ) ; if ( bd . dir = = 0 ) bd . dir = bd . at . at - > type ; }
auto & r = treestates [ bd . id ] . rules ;
for ( int i = 0 ; i < isize ( r ) ; i + + ) {
if ( ! among ( r [ i ] , DIR_UNKNOWN , DIR_LEFT , DIR_RIGHT ) ) continue ;
int val = i < bd . dir ? DIR_LEFT : DIR_RIGHT ;
if ( r [ i ] = = DIR_UNKNOWN )
r [ i ] = val ;
else if ( r [ i ] ! = val ) {
if ( debugflags & DF_GEOM ) {
println ( hlog , " state " , bd . id , " index " , i , " : " , bd . dir , " / " , bd . at . at - > type , " was " , split [ bd . id ] ) ;
println ( hlog , important ) ;
}
important . push_back ( bd . at . at ) ;
important . push_back ( split [ bd . id ] . at . at ) ;
throw mismatch_error ( ) ;
}
}
split [ bd . id ] = bd ;
}
set < vector < int > > branch_hashes ;
void examine_branch ( int id , int left , int right ) {
auto rg = treestates [ id ] . giver ;
if ( debugflags & DF_GEOM )
println ( hlog , " need to examine branches " , tie ( left , right ) , " of " , id , " starting from " , rg ) ;
vector < branchdata > bdata ;
int dist_at = rg . at - > dist ;
while ( left ! = right ) {
/* can be false in case of multi-edges */
if ( treestates [ id ] . rules [ left ] > = 0 ) {
if ( bdata . size ( ) & & bdata . back ( ) . dir = = 0 )
bdata . pop_back ( ) ;
else {
auto bl = branchdata { id , left , rg + left , dist_at + dlbonus } ;
advance ( bdata , bl , - 1 , true , true , dist_at + 5 ) ;
}
}
left + + ;
if ( left = = rg . at - > type ) left = 0 ;
if ( treestates [ id ] . rules [ left ] > = 0 ) {
auto br = branchdata { id , left , rg + left , dist_at + dlbonus } ;
advance ( bdata , br , + 1 , true , false , dist_at + 5 ) ;
}
}
int steps = 0 ;
while ( true ) {
steps + + ;
if ( steps = = max_examine_branch )
throw rulegen_failure ( " max_examine_branch exceeded " ) ;
if ( isize ( bdata ) > max_bdata )
throw rulegen_failure ( " max_bdata exceeded " ) ;
/* advance both */
vector < branchdata > bdata2 ;
int advcount = 0 , eatcount = 0 ;
for ( int i = 0 ; i < isize ( bdata ) ; i + = 2 ) {
if ( ! bdata [ i ] . temporary & & ! bdata [ i + 1 ] . temporary & & paired ( bdata [ i ] . at , bdata [ i + 1 ] . at ) & & min ( bdata [ i ] . at . at - > dist , bdata [ i + 1 ] . at . at - > dist ) < = dist_at ) {
advcount + + ;
if ( bdata2 . size ( ) & & ! bdata2 . back ( ) . temporary & & equiv ( bdata2 . back ( ) . at , bdata [ i ] . at ) ) {
assign_lr ( bdata [ i ] , 0 ) ;
eatcount + + ; bdata2 . pop_back ( ) ;
}
else
advance ( bdata2 , bdata [ i ] , - 1 , false , true , dist_at + dlbonus ) ;
if ( i + 2 < isize ( bdata ) & & ! bdata [ i + 1 ] . temporary & & ! bdata [ i + 2 ] . temporary & & equiv ( bdata [ i + 1 ] . at , bdata [ i + 2 ] . at ) ) {
assign_lr ( bdata [ i + 1 ] , + 1 ) ;
eatcount + + ; i + = 2 ; bdata2 . push_back ( bdata [ i + 1 ] ) ;
}
else
advance ( bdata2 , bdata [ i + 1 ] , + 1 , false , false , dist_at + dlbonus ) ;
}
else {
if ( bdata [ i ] . temporary & & bdata [ i ] . at . at - > dist < = dist_at + dlbonus - 2 ) {
advcount + + ;
advance ( bdata2 , bdata [ i ] , bdata [ i ] . temporary , false , bdata [ i ] . temporary < 0 , dist_at + dlbonus ) ;
}
else bdata2 . push_back ( bdata [ i ] ) ;
if ( bdata [ i + 1 ] . temporary & & bdata [ i + 1 ] . at . at - > dist < = dist_at + 3 ) {
advcount + + ;
advance ( bdata2 , bdata [ i + 1 ] , bdata [ i + 1 ] . temporary , false , bdata [ i + 1 ] . temporary < 0 , dist_at + dlbonus ) ;
}
else bdata2 . push_back ( bdata [ i + 1 ] ) ;
}
}
bdata = bdata2 ;
if ( ! advcount ) dist_at + + ;
if ( advcount ) {
vector < int > hash ;
for ( int i = 0 ; i < isize ( bdata ) ; i + + ) {
hash . push_back ( bdata [ i ] . id ) ;
hash . push_back ( bdata [ i ] . dir ) ;
hash . push_back ( bdata [ i ] . temporary ) ;
hash . push_back ( bdata [ i ] . at . at - > dist - dist_at ) ;
}
if ( branch_hashes . count ( hash ) ) {
return ;
}
branch_hashes . insert ( hash ) ;
}
}
}
/* == main algorithm == */
void clear_codes ( ) {
treestates . clear ( ) ;
code_to_id . clear ( ) ;
auto c = first_tcell ;
while ( c ) {
c - > code = MYSTERY ;
c = c - > next ;
}
}
void rules_iteration ( ) {
clear_codes ( ) ;
cq = important ;
if ( debugflags & DF_GEOM )
println ( hlog , " important = " , cq ) ;
for ( int i = 0 ; i < isize ( cq ) ; i + + ) {
rules_iteration_for ( cq [ i ] ) ;
}
if ( debugflags & DF_GEOM )
println ( hlog , " number of treestates = " , isize ( treestates ) ) ;
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rule_root = get_code ( t_origin [ 0 ] ) . second ;
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if ( debugflags & DF_GEOM )
println ( hlog , " rule_root = " , rule_root ) ;
int N = isize ( important ) ;
for ( int id = 0 ; id < isize ( treestates ) ; id + + ) {
if ( ! treestates [ id ] . known ) {
important . push_back ( treestates [ id ] . where_seen ) ;
if ( debugflags & DF_GEOM )
println ( hlog , " no rule found for " , id ) ;
continue ;
}
}
if ( isize ( important ) ! = N )
throw mismatch_error ( ) ;
int new_deadends = - 1 ;
while ( new_deadends ) {
new_deadends = 0 ;
for ( int id = 0 ; id < isize ( treestates ) ; id + + ) {
auto & ts = treestates [ id ] ;
if ( ! ts . known ) continue ;
if ( ! ts . is_live ) continue ;
int children = 0 ;
for ( int i : ts . rules ) if ( i > = 0 & & treestates [ i ] . is_live ) children + + ;
if ( ! children )
treestates [ id ] . is_live = false , new_deadends + + ;
}
if ( debugflags & DF_GEOM )
println ( hlog , " deadend states found: " , new_deadends ) ;
}
for ( int id = 0 ; id < isize ( treestates ) ; id + + ) {
auto & rg = treestates [ id ] . giver ;
auto & r = treestates [ id ] . rules ;
for ( int p = 0 ; p < 2 ; p + + )
for ( int it = 0 ; it < isize ( r ) ; it + + ) {
for ( int i = 0 ; i < isize ( r ) ; i + + ) {
int i1 = gmod ( i + 1 , isize ( r ) ) ;
if ( ( rg + i ) . peek ( ) = = ( rg + i1 ) . peek ( ) ) {
if ( r [ i1 ] = = DIR_UNKNOWN & & ( r [ i ] > = ( p ? DIR_UNKNOWN : 0 ) | | r [ i ] = = DIR_PARENT | | r [ i ] = = DIR_MULTI_GO_LEFT ) )
r [ i1 ] = DIR_MULTI_GO_LEFT ;
if ( r [ i ] = = DIR_UNKNOWN & & ( r [ i1 ] > = 0 | | r [ i1 ] = = DIR_PARENT | | r [ i + 1 ] = = DIR_MULTI_GO_RIGHT ) )
r [ i ] = DIR_MULTI_GO_RIGHT ;
}
}
}
}
// print_rules();
branch_hashes . clear ( ) ;
for ( int id = 0 ; id < isize ( treestates ) ; id + + ) if ( treestates [ id ] . is_live ) {
auto & r = treestates [ id ] . rules ;
int last_live_branch = - 1 ;
int first_live_branch = - 1 ;
for ( int i = 0 ; i < isize ( r ) ; i + + )
if ( r [ i ] > = 0 & & treestates [ r [ i ] ] . is_live ) {
if ( first_live_branch = = - 1 ) first_live_branch = i ;
if ( last_live_branch > = 0 )
examine_branch ( id , last_live_branch , i ) ;
else for ( int a = 0 ; a < i ; a + + )
if ( r [ a ] = = DIR_UNKNOWN ) r [ a ] = DIR_LEFT ;
last_live_branch = i ;
}
if ( id = = 0 ) examine_branch ( id , last_live_branch , first_live_branch ) ;
for ( int a = last_live_branch ; a < isize ( r ) ; a + + )
if ( r [ a ] = = DIR_UNKNOWN ) r [ a ] = DIR_RIGHT ;
}
if ( isize ( important ) ! = N )
throw mismatch_error ( ) ;
minimize_rules ( ) ;
find_possible_parents ( ) ;
for ( int id = 0 ; id < isize ( treestates ) ; id + + ) {
auto & ts = treestates [ id ] ;
for ( auto & r : ts . rules ) if ( r = = DIR_UNKNOWN )
throw rulegen_failure ( " UNKNOWN remaining " ) ;
}
if ( isize ( important ) ! = N )
throw mismatch_error ( ) ;
}
void clear_tcell_data ( ) {
auto c = first_tcell ;
while ( c ) {
c - > is_solid = false ;
c - > dist = MYSTERY ;
c - > parent_dir = MYSTERY ;
c - > code = MYSTERY ;
c - > distance_fixed = false ;
c = c - > next ;
}
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for ( auto & c : t_origin ) c - > dist = 0 ;
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}
void cleanup ( ) {
clear_tcell_data ( ) ;
analyzers . clear ( ) ;
code_to_id . clear ( ) ;
split . clear ( ) ;
important . clear ( ) ;
}
void clear_all ( ) {
treestates . clear ( ) ;
cleanup ( ) ;
}
bool double_edges_check ( cell * c , set < int > & visited ) {
int i = shvid ( c ) ;
if ( visited . count ( i ) ) return false ;
visited . insert ( i ) ;
for ( int j = 0 ; j < c - > type ; j + + ) {
cellwalker cw ( c , j ) ;
bool on = true ;
if ( double_edges_check ( cw . cpeek ( ) , visited ) ) return true ;
int qty = 0 ;
for ( int k = 0 ; k < = c - > type ; k + + ) {
bool on2 = ( cw + k ) . cpeek ( ) = = cw . cpeek ( ) ;
if ( on ! = on2 ) qty + + ;
on = on2 ;
}
if ( qty > 2 ) return true ;
}
return false ;
}
EX void generate_rules ( ) {
delete_tmap ( ) ;
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if ( ! arb : : in ( ) ) try {
arb : : convert : : convert ( ) ;
}
catch ( hr_exception & e ) {
throw rulegen_surrender ( " conversion failure " ) ;
}
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prepare_around_radius = 1 ;
clear_all ( ) ;
analyzers . clear ( ) ;
split . clear ( ) ;
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t_origin . clear ( ) ;
for ( auto & ts : arb : : current . shapes ) {
tcell * c = gen_tcell ( ts . id ) ;
c - > dist = 0 ;
t_origin . push_back ( c ) ;
}
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set < int > visited ;
if ( double_edges_check ( currentmap - > gamestart ( ) , visited ) )
throw double_edges ( ) ;
try_count = 0 ;
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important = t_origin ;
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retry :
try {
rules_iteration ( ) ;
}
catch ( rulegen_retry & e ) {
try_count + + ;
if ( try_count > = max_retries )
throw ;
if ( debugflags & DF_GEOM ) println ( hlog , " attempt: " , try_count ) ;
auto c = first_tcell ;
while ( c ) {
c - > is_solid = false ;
c - > parent_dir = MYSTERY ;
c - > code = MYSTERY ;
c = c - > next ;
}
goto retry ;
}
}
int reclevel ;
void build_test ( ) ;
/* == hrmap_rulegen == */
struct hrmap_rulegen : hrmap {
hrmap * base ;
heptagon * origin ;
heptagon * gen ( int s , int d , bool c7 ) {
int t = arb : : current . shapes [ treestates [ s ] . sid ] . size ( ) ;
heptagon * h = init_heptagon ( t ) ;
if ( c7 ) h - > c7 = newCell ( t , h ) ;
h - > distance = d ;
h - > fieldval = s ;
h - > zebraval = treestates [ s ] . sid ;
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h - > s = hsA ;
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return h ;
}
~ hrmap_rulegen ( ) {
clearfrom ( origin ) ;
}
hrmap_rulegen ( ) {
origin = gen ( rule_root , 0 , true ) ;
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origin - > s = hsOrigin ;
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}
hrmap_rulegen ( heptagon * h ) {
origin = h ;
}
heptagon * getOrigin ( ) override {
return origin ;
}
int get_rule ( heptspin hs ) {
int s = hs . at - > fieldval ;
return treestates [ s ] . rules [ hs . spin ] ;
}
static void hsconnect ( heptspin a , heptspin b ) {
a . at - > c . connect ( a . spin , b . at , b . spin , false ) ;
}
void group_connect ( heptspin a , heptspin b ) {
/* go leftmost with a */
while ( get_rule ( a ) = = DIR_MULTI_GO_LEFT | | get_rule ( a - 1 ) = = DIR_MULTI_GO_RIGHT )
a - - ;
/* go rightmost with b */
while ( get_rule ( b ) = = DIR_MULTI_GO_RIGHT | | get_rule ( b + 1 ) = = DIR_MULTI_GO_LEFT )
b + + ;
int gr = 0 ;
// verify_connection(a, b);
while ( true ) {
hsconnect ( a , b ) ; gr + + ;
bool can_a = get_rule ( a ) = = DIR_MULTI_GO_RIGHT | | get_rule ( a + 1 ) = = DIR_MULTI_GO_LEFT ;
if ( can_a ) a + + ;
bool can_b = get_rule ( b ) = = DIR_MULTI_GO_LEFT | | get_rule ( b - 1 ) = = DIR_MULTI_GO_RIGHT ;
if ( can_b ) b - - ;
if ( can_a & & can_b ) continue ;
if ( can_a | | can_b )
throw rulegen_failure ( " multi disagreement " ) ;
break ;
}
}
heptagon * create_step ( heptagon * h , int d ) override {
heptspin hs ( h , d ) ;
int r = get_rule ( hs ) ;
indenter ind ( 2 ) ;
if ( hlog . indentation > = 6000 )
throw rulegen_failure ( " failed to create_step " ) ;
if ( r > = 0 ) {
auto h1 = gen ( r , h - > distance + 1 , h - > c7 ) ;
auto hs1 = heptspin ( h1 , 0 ) ;
// verify_connection(hs, hs1);
hsconnect ( hs , hs1 ) ;
return h1 ;
}
else if ( r = = DIR_PARENT ) {
auto & hts = treestates [ h - > fieldval ] ;
auto & choices = hts . possible_parents ;
if ( choices . empty ( ) ) throw rulegen_failure ( " no possible parents " ) ;
auto selected = hrand_elt ( choices ) ;
auto h1 = gen ( selected . first , h - > distance - 1 , h - > c7 ) ;
auto hs1 = heptspin ( h1 , selected . second ) ;
hsconnect ( hs , hs1 ) ;
return h1 ;
}
else if ( r = = DIR_UNKNOWN )
throw rulegen_failure ( " UNKNOWN rule remained " ) ;
else if ( r = = DIR_MULTI_GO_LEFT ) {
// hs = (hs - 1) + wstep;
hsconnect ( hs , hs - 1 + wstep - 1 ) ;
return h - > move ( d ) ;
}
else if ( r = = DIR_MULTI_GO_RIGHT ) {
// hs = (hs + 1) + wstep;
hsconnect ( hs , hs + 1 + wstep + 1 ) ;
return h - > move ( d ) ;
}
else if ( r = = DIR_LEFT | | r = = DIR_RIGHT ) {
heptspin hs1 = hs ;
int delta = r = = DIR_LEFT ? - 1 : 1 ;
int rev = ( DIR_LEFT ^ DIR_RIGHT ^ r ) ;
while ( IS_DIR_MULTI ( get_rule ( hs1 ) ) ) hs1 + = delta ;
hs1 + = delta ;
while ( true ) {
int r1 = get_rule ( hs1 ) ;
if ( r1 = = rev ) {
group_connect ( hs , hs1 ) ;
return hs1 . at ;
}
else if ( IS_DIR_MULTI ( r1 ) ) {
hs1 + = delta ;
}
else if ( r1 = = r | | r1 = = DIR_PARENT | | r1 > = 0 ) {
hs1 + = wstep ;
while ( get_rule ( hs1 ) = = ( r = = DIR_RIGHT ? DIR_MULTI_GO_RIGHT : DIR_MULTI_GO_LEFT ) ) {
hs1 + = delta ;
}
hs1 + = delta ;
}
else throw rulegen_failure ( " bad R1 " ) ;
}
}
else throw rulegen_failure ( " bad R " ) ;
throw rulegen_failure ( " impossible " ) ;
}
int get_arb_dir ( int s , int dir ) {
int sid = treestates [ s ] . sid ;
int N = arb : : current . shapes [ sid ] . size ( ) ;
return gmod ( dir + treestates [ s ] . parent_dir , N ) ;
}
transmatrix adj ( heptagon * h , int dir ) override {
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if ( h - > fieldval = = - 1 )
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return arb : : get_adj ( arb : : current_or_slided ( ) , h - > zebraval , dir , - 1 , - 1 ) ;
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int s = h - > fieldval ;
int dir0 = get_arb_dir ( s , dir ) ;
int dir1 = - 1 ;
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int sid1 = - 1 ;
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if ( h - > c . move ( dir ) ) {
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auto s1 = h - > c . move ( dir ) - > fieldval ;
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dir1 = get_arb_dir ( s1 , h - > c . spin ( dir ) ) ;
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sid1 = treestates [ s1 ] . sid ;
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}
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return arb : : get_adj ( arb : : current_or_slided ( ) , treestates [ s ] . sid , dir0 , sid1 , dir1 ) ;
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}
int shvid ( cell * c ) override {
return c - > master - > zebraval ;
}
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transmatrix relative_matrixh ( heptagon * h2 , heptagon * h1 , const hyperpoint & hint ) override {
return relative_matrix_recursive ( h2 , h1 ) ;
}
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hyperpoint get_corner ( cell * c , int cid , ld cf ) {
if ( c - > master - > fieldval = = - 1 ) {
auto & sh = arb : : current_or_slided ( ) . shapes [ c - > master - > zebraval ] ;
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cid = gmod ( cid , sh . size ( ) ) ;
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return normalize ( C0 + ( sh . vertices [ cid ] - C0 ) * 3 / cf ) ;
}
int s = c - > master - > fieldval ;
auto & sh = arb : : current_or_slided ( ) . shapes [ c - > master - > zebraval ] ;
auto dir = get_arb_dir ( s , cid ) ;
return normalize ( C0 + ( sh . vertices [ dir ] - C0 ) * 3 / cf ) ;
}
void find_cell_connection ( cell * c , int d ) override {
if ( c - > master - > cmove ( d ) = = & oob ) {
c - > c . connect ( d , & out_of_bounds , 0 , false ) ;
}
else hrmap : : find_cell_connection ( c , d ) ;
}
bool strict_tree_rules ( ) { return true ; }
virtual bool link_alt ( heptagon * h , heptagon * alt , hstate firststate , int dir ) override {
auto & hts = treestates [ h - > fieldval ] ;
int psid = hts . sid ;
if ( firststate = = hsOrigin ) {
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alt - > s = hsOrigin ;
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for ( auto & ts : treestates ) if ( ts . sid = = psid & & ts . is_root ) {
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alt - > fieldval = ts . id ;
// ts.parent_dir should be 0, but anyway
altmap : : relspin ( alt ) = gmod ( ts . parent_dir - hts . parent_dir , isize ( hts . rules ) ) ;
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return true ;
}
return false ;
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}
int odir = hts . parent_dir + dir ;
int cl = arb : : current . shapes [ psid ] . cycle_length ;
vector < int > choices ;
for ( auto & ts : treestates )
if ( ts . is_possible_parent & & ts . sid = = psid )
if ( gmod ( ts . parent_dir - odir , cl ) = = 0 )
choices . push_back ( ts . id ) ;
alt - > fieldval = hrand_elt ( choices , - 1 ) ;
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alt - > s = hsA ;
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if ( alt - > fieldval = = - 1 ) return false ;
altmap : : relspin ( alt ) = dir ;
return true ;
}
} ;
EX int get_arb_dir ( cell * c , int dir ) {
return ( ( hrmap_rulegen * ) currentmap ) - > get_arb_dir ( c - > master - > fieldval , dir ) ;
}
EX hrmap * new_hrmap_rulegen_alt ( heptagon * h ) {
return new hrmap_rulegen ( h ) ;
}
EX hrmap * new_hrmap_rulegen ( ) { return new hrmap_rulegen ( ) ; }
EX int get_state ( cell * c ) {
return c - > master - > fieldval ;
}
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string rules_known_for = " unknown " ;
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string rule_status ;
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EX bool known ( ) {
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return arb : : current . have_tree | | rules_known_for = = arb : : current . name ;
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}
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EX bool prepare_rules ( ) {
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if ( known ( ) ) return true ;
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try {
generate_rules ( ) ;
rules_known_for = arb : : current . name ;
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rule_status = XLAT ( " rules generated successfully: %1 states using %2-%3 cells " ,
its ( isize ( treestates ) ) , its ( tcellcount ) , its ( tunified ) ) ;
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return true ;
}
catch ( rulegen_retry & e ) {
rule_status = XLAT ( " too difficult: %1 " , e . what ( ) ) ;
}
catch ( rulegen_surrender & e ) {
rule_status = XLAT ( " too difficult: %1 " , e . what ( ) ) ;
}
catch ( rulegen_failure & e ) {
rule_status = XLAT ( " bug: %1 " , e . what ( ) ) ;
}
return false ;
}
int args ( ) {
using namespace arg ;
if ( 0 ) ;
else if ( argis ( " -rulegen " ) ) {
PHASEFROM ( 3 ) ;
prepare_rules ( ) ;
}
else if ( argis ( " -rulegen-cleanup " ) )
cleanup ( ) ;
else if ( argis ( " -rulegen-play " ) ) {
PHASEFROM ( 3 ) ;
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if ( prepare_rules ( ) ) {
stop_game ( ) ;
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arb : : convert : : activate ( ) ;
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start_game ( ) ;
}
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}
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else if ( argis ( " -d:rulegen " ) ) {
launch_dialog ( show ) ;
}
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else return 1 ;
return 0 ;
}
auto hooks =
addHook ( hooks_args , 100 , args )
+ addHook ( hooks_configfile , 100 , [ ] {
param_i ( max_retries , " max_retries " ) ;
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param_i ( max_tcellcount , " max_tcellcount " )
- > editable ( 0 , 16000000 , 100000 , " maximum cellcount " , " controls the max memory usage of conversion algorithm -- the algorithm fails if exceeded " , ' c ' ) ;
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param_i ( max_adv_steps , " max_adv_steps " ) ;
param_i ( max_examine_branch , " max_examine_branch " ) ;
param_i ( max_bdata , " max_bdata " ) ;
param_i ( dlbonus , " dlbonus " ) ;
} ) ;
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EX void parse_treestate ( arb : : arbi_tiling & c , exp_parser & ep ) {
if ( ! c . have_tree ) {
c . have_tree = true ;
treestates . clear ( ) ;
rule_root = 0 ;
}
treestates . emplace_back ( ) ;
auto & ts = treestates . back ( ) ;
ts . id = isize ( treestates ) - 1 ;
ts . sid = ep . iparse ( ) ;
ts . parent_dir = 0 ;
if ( ! arb : : correct_index ( ts . sid , isize ( c . shapes ) ) )
throw hr_parse_exception ( " incorrect treestate index at " + ep . where ( ) ) ;
int N = c . shapes [ ts . sid ] . size ( ) ;
for ( int i = 0 ; i < N ; i + + ) {
ep . force_eat ( " , " ) ; ep . skip_white ( ) ;
if ( ep . eat ( " PARENT " ) ) ts . rules . push_back ( DIR_PARENT ) ;
else if ( ep . eat ( " LEFT " ) ) ts . rules . push_back ( DIR_LEFT ) ;
else if ( ep . eat ( " RIGHT " ) ) ts . rules . push_back ( DIR_RIGHT ) ;
else { int i = ep . iparse ( ) ; ts . rules . push_back ( i ) ; }
}
ep . force_eat ( " ) " ) ;
}
EX void verify_parsed_treestates ( ) {
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if ( rule_root < 0 | | rule_root > = isize ( treestates ) )
throw hr_parse_exception ( " undefined treestate as root " ) ;
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for ( auto & ts : treestates ) for ( auto & r : ts . rules ) {
if ( r < 0 & & ! among ( r , DIR_PARENT , DIR_LEFT , DIR_RIGHT ) )
throw hr_parse_exception ( " negative number in treestates " ) ;
if ( r > isize ( treestates ) )
throw hr_parse_exception ( " undefined treestate " ) ;
}
for ( auto & sh : arb : : current . shapes ) sh . cycle_length = sh . size ( ) ;
find_possible_parents ( ) ;
}
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EX void show ( ) {
cmode = sm : : SIDE | sm : : MAYDARK ;
gamescreen ( 1 ) ;
dialog : : init ( XLAT ( " strict tree maps " ) ) ;
dialog : : addHelp ( XLAT (
" Strict tree maps are generated using a more powerful algorithm. This algorithms supports horocycles and knows the expansion rates of various "
" tessellations (contrary to the basic implementation of Archimedean, tes, and unrectified/warped/untruncated tessellations). You can convert mostly any "
" non-spherical periodic 2D tessellation to strict tree based. Switching the map format erases your map. " ) ) ;
if ( kite : : in ( ) ) {
dialog : : addInfo ( " not available in aperiodic tessellations " ) ;
dialog : : addBack ( ) ;
dialog : : display ( ) ;
}
else if ( WDIM = = 3 ) {
dialog : : addInfo ( " not available in 3D tessellations " ) ;
dialog : : addBack ( ) ;
dialog : : display ( ) ;
}
dialog : : addBoolItem ( XLAT ( " in tes internal format " ) , arb : : in ( ) , ' t ' ) ;
dialog : : add_action ( [ ] {
if ( ! arb : : in ( ) ) {
arb : : convert : : convert ( ) ;
arb : : convert : : activate ( ) ;
start_game ( ) ;
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rule_status = XLAT ( " converted successfully -- %1 cell types " , its ( isize ( arb : : current . shapes ) ) ) ;
rules_known_for = " unknown " ;
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}
else if ( arb : : convert : : in ( ) ) {
stop_game ( ) ;
geometry = arb : : convert : : base_geometry ;
variation = arb : : convert : : base_variation ;
start_game ( ) ;
}
else {
addMessage ( XLAT ( " cannot be disabled for this tiling " ) ) ;
}
} ) ;
dialog : : addBoolItem ( XLAT ( " strict tree based " ) , currentmap - > strict_tree_rules ( ) , ' s ' ) ;
dialog : : add_action ( [ ] {
if ( ! currentmap - > strict_tree_rules ( ) ) {
if ( prepare_rules ( ) ) {
println ( hlog , " prepare_rules returned true " ) ;
stop_game ( ) ;
arb : : convert : : activate ( ) ;
start_game ( ) ;
delete_tmap ( ) ;
}
}
else if ( arb : : current . have_tree ) {
addMessage ( XLAT ( " cannot be disabled for this tiling " ) ) ;
}
else {
rules_known_for = " unknown " ;
rule_status = " manually disabled " ;
stop_game ( ) ;
start_game ( ) ;
}
} ) ;
add_edit ( max_tcellcount ) ;
dialog : : addBreak ( 100 ) ;
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dialog : : addHelp ( rule_status ) ;
dialog : : items . back ( ) . color = known ( ) ? 0x00FF00 : rules_known_for = = " unknown " ? 0xFFFF00 : 0xFF0000 ;
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dialog : : addBreak ( 100 ) ;
dialog : : addBack ( ) ;
dialog : : display ( ) ;
}
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EX }
}