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## ## This file is part of GAP, a system for computational discrete algebra. ## This file's authors include Thomas Breuer, Frank Celler, Alexander Hulpke. ## ## Copyright of GAP belongs to its developers, whose names are too numerous ## to list here. Please refer to the COPYRIGHT file for details. ## ## SPDX-License-Identifier: GPL-2.0-or-later ## ## This file contains methods for associative words in syllable ## representation. ## ## Currently, there are four representations for objects with the external ## representation as list of generators numbers and exponents (so not only ## for associative words but perhaps also for elements in a finitely ## presented group). ## ## The representations differ w.r.t. the space needed by the internal ## representation: ## ## the first three need 8, 16, 32 bits for each generator/exponent pair, and ## the last uses the list defined by the external representation also as ## internal data. ## ## The result of an arithmetic operation with objects of the same ## representation will be also of that representation if this is possible. ## The result of an arithmetic operation with objects of different ## representations will be the bigger one of the two if this is possible. ## Otherwise `ObjByExtRep' will choose the smallest possible representation. ## In all cases the representation of the operands is *not* changed. ## ############################################################################# ## #R Is8BitsAssocWord( <obj> ) #R Is16BitsAssocWord( <obj> ) #R Is32BitsAssocWord( <obj> ) #R IsInfBitsAssocWord( <obj> ) ## DeclareRepresentation( "Is8BitsAssocWord", IsSyllableAssocWordRep and IsDataObjectRep, [] ); DeclareRepresentation( "Is16BitsAssocWord", IsSyllableAssocWordRep and IsDataObjectRep, [] ); DeclareRepresentation( "Is32BitsAssocWord", IsSyllableAssocWordRep and IsDataObjectRep, [] ); DeclareRepresentation( "IsInfBitsAssocWord", IsSyllableAssocWordRep and IsPositionalObjectRep,[]); ############################################################################# ## #V AWP_PURE_TYPE #V AWP_NR_BITS_EXP #V AWP_NR_GENS #V AWP_NR_BITS_PAIR #V AWP_FUN_OBJ_BY_VECTOR #V AWP_FUN_ASSOC_WORD #V AWP_FIRST_FREE ## ## are positions of non-defining data in the types of associative words, ## namely ## - the pure type of the object itself, without knowledge features, ## - the number of bits available for each exponent, ## - the number of generators, ## - the number of bits available for each generator/exponent pair, ## - the construction function to be called by `ObjByVector', ## - the construction function to be called by `AssocWord', ## - the first position that can be used for private purposes. ## ## This data must be provided already in the construction of the family, ## in order to make sure that calls of `NewType' fetch types that know ## this data. ## ############################################################################# ## #F InfBits_AssocWord( <Type>, <list> ) ## BindGlobal( "InfBits_AssocWord", function( Type, list ) local n, i, j; # Check that the data is admissible. n:= Type![ AWP_NR_GENS ]; if Length( list ) mod 2 <> 0 then Error( "<list> must have even length" ); fi; for i in [ 1 .. Length( list ) / 2 ] do j:= 2*i - 1; if not ( IsInt( list[j] ) and list[j] > 0 and list[j] <= n ) then Error( "value at odd position <j> must denote generator" ); fi; if not IsInt( list[ j+1 ] ) then Error( "value at even position <j+1> must be an integer" ); fi; od; return Objectify( Type, [ Immutable( list ) ] ); end ); # code for printing words in factored form. This pattern searching clearly # is improvable BindGlobal("FindSubstringPowers",function(l,n) local new,t,i,step,lstep,z,zz,j,a,k,good,bad,lim,plim; new:=0; t:=[]; z:=Length(l); # first deal with large powers to avoid x^1000 being an obstacle. plim:=9; # length for treating large powers-1 j:=1; while j+plim<=Length(l) do if ForAll([1..plim],x->l[j]=l[j+x]) then k:=j+plim; while k<Length(l) and l[j]=l[k+1] do k:=k+1; od; zz:=[0,l[j],k-j+1]; a:=Position(t,zz); if a=fail then new:=new+1; t[new]:=zz; a:=new; fi; l:=Concatenation(l{[1..j-1]},[a+n],l{[k+1..Length(l)]}); fi; j:=j+1; od; z:=Length(l); # long matches first, we then treat the subpatterns themselves again j:=QuoInt(z,2); lstep:=j; while lstep>=2 do step:=lstep; zz:=z-2*step+1; #Print(step," ",z," ",zz,"\n"); i:=1; while i<=zz do good:=true; bad:=true; k:=i; lim:=i+step-1; while good and k<=lim do good:=l[k]=l[k+step]; if bad and l[k]<>l[i] then bad:=false;fi; k:=k+1; od; if good and not bad then # found # step match of nonidentity pattern # did we recognize a power of a power only? a:=First(Difference(DivisorsInt(step),[1,step]), d->ForAll([1..step/d],q->ForAll([0..d-1],x-> l[i+x]=l[i+q*d+x]))); if a<>fail then #Print(i," ",a," ",step," ",z,"\n"); # a is the length of the subpattern we should have recognized. step:=a; zz:=z-2*step+1; fi; # any further match? j:=i+step; while j<=zz and ForAll([j..j+step-1],x->l[x]=l[x+step]) do j:=j+step; od; new:=new+1; t[new]:=l{[i..i+step-1]}; # new unit zz:=1+(j-i)/step; l:=Concatenation(l{[1..i-1]},ListWithIdenticalEntries(zz,new+n), l{[j+step..z]}); i:=i+zz-1; # position after the repeat z:=Length(l); if step<>lstep then # we temporarily used a shorter length -- reset step:=lstep; i:=i; fi; # we only need to use the *rest* for pattern length. This will help # for huge powers of short expressions. lstep:=Minimum(lstep,QuoInt(z-zz,2)); zz:=z-2*step+1; fi; i:=i+1; od; lstep:=lstep-1; od; return [l,t]; end); # should we try to find subword run lengths? Can be true, false, or a length # threshold up to which to try. PRINTWORDPOWERS:=true; DeclareGlobalName("DoNSAW"); BindGlobal( "DoNSAW", function(l,names,tseed) local a,n,t, word, exp, i,j, str; n:=Length(names); if (PRINTWORDPOWERS=true or (IsInt(PRINTWORDPOWERS) and Length(l)<PRINTWORDPOWERS)) and ValueOption("printnopowers")<>true then if Length(l)>0 and n=infinity then n:=2*(Maximum(List(l,AbsInt))+1); fi; a:=FindSubstringPowers(l,n+Length(tseed)); # tseed numbers are used already else a:=[l,[]]; fi; word:=a[1]; a[2]:=Concatenation(tseed,a[2]); i:= 1; str:= ""; while i <= Length(word) do if i>1 then Add( str, '*' ); fi; exp:=1; if word[i]>n then t:=a[2][word[i]-n]; # is it a power stored specially? if t[1]=0 then if t[2]<0 then Append( str, names[ -t[2] ] ); Append( str, "^-" ); Append( str, String(t[3])); else Append( str, names[ t[2] ] ); Append( str, "^" ); Append( str, String(t[3])); fi; else # decode longer word -- it will occur as power, so use () Add(str,'('); Append(str,DoNSAW(t,names,Filtered(a[2],x->x[1]=0))); Add(str,')'); fi; elif word[i]<0 then Append( str, names[ -word[i] ] ); exp:=-1; else Append( str, names[ word[i] ] ); fi; if i<Length(word) and word[i]=word[i+1] then j:=i; i:=i+1; while i<=Length(word) and word[j]=word[i] do i:=i+1; od; Add( str, '^' ); Append( str, String(exp*(i-j)) ); elif exp=-1 then Append(str,"^-1"); i:=i+1; else # no power -- just normal letter i:=i+1; fi; od; ConvertToStringRep( str ); return str; end ); BindGlobal("NiceStringAssocWord",function(elm) local names,word; names:= FamilyObj( elm )!.names; word:= LetterRepAssocWord( elm ); if Length(word)=0 then return "<identity ...>"; fi; word:=DoNSAW(word,names,[]); return word; end); ############################################################################# ## #M Print( <w> ) ## InstallMethod( PrintObj, "for an associative word", true, [ IsAssocWord ], 0, function( elm ) Print(NiceStringAssocWord(elm)); end ); ############################################################################# ## #M String( <w> ) ## InstallMethod( String, "for an associative word", true, [ IsAssocWord ], 0, NiceStringAssocWord); ############################################################################# ## #F AssocWord( <Type>, <descr> ) ## InstallGlobalFunction( AssocWord, function( Type, descr ) return Type; end ); ############################################################################# ## #M ObjByExtRep( <F>, <descr> ) ## BindGlobal("SyllableWordObjByExtRep",function( F, descr ) local maxexp, # maximal exponent in `descr' i, # loop over exponents in `descr' expbits; # list of maximal exponents for the four representations maxexp:= 0; for i in [ 2, 4 .. Length( descr ) ] do if maxexp < descr[i] then maxexp:= descr[i]; elif maxexp < - descr[i] then maxexp:= - descr[i]; fi; od; if IsInfBitsFamily(F) then return AssocWord( F!.types[4], descr ); fi; expbits:= F!.expBitsInfo; if maxexp < expbits[2] then if maxexp < expbits[1] then return AssocWord( F!.types[1], descr ); else return AssocWord( F!.types[2], descr ); fi; elif maxexp < expbits[3] then return AssocWord( F!.types[3], descr ); else return AssocWord( F!.types[4], descr ); fi; end ); InstallMethod( ObjByExtRep, "for a family of associative words, and a homogeneous list", true, [ IsAssocWordFamily and IsSyllableWordsFamily, IsHomogeneousList ], 0, SyllableWordObjByExtRep); InstallMethod(SyllableRepAssocWord, "assoc word: via extrep", true, [ IsAssocWord ], 0, w->SyllableWordObjByExtRep(FamilyObj(w),ExtRepOfObj(w))); InstallMethod(SyllableRepAssocWord, "assoc word in syllable rep", true, [ IsAssocWord and IsSyllableAssocWordRep], 0, w->w); InstallOtherMethod( ObjByExtRep, "for a 8Bits-family of associative words, and a homogeneous list", true, [ IsAssocWordFamily and Is8BitsFamily, IsHomogeneousList ], 0, function( F, descr ) return AssocWord( F!.types[1], descr ); end ); InstallOtherMethod( ObjByExtRep, "for a 16Bits-family of associative words, and a homogeneous list", true, [ IsAssocWordFamily and Is16BitsFamily, IsHomogeneousList ], 0, function( F, descr ) return AssocWord( F!.types[2], descr ); end ); InstallOtherMethod( ObjByExtRep, "for a 32Bits-family of associative words, and a homogeneous list", true, [ IsAssocWordFamily and Is32BitsFamily, IsHomogeneousList ], 0, function( F, descr ) return AssocWord( F!.types[3], descr ); end ); InstallOtherMethod( ObjByExtRep, "for a InfBits-family of associative words, and a homogeneous list", true, [ IsAssocWordFamily and IsInfBitsFamily, IsHomogeneousList ], 0, function( F, descr ) return AssocWord( F!.types[4], descr ); end ); ############################################################################# ## #M ObjByExtRep( <F>, <expbits>, <maxcand>, <descr> ) ## ## is an object that belongs to the smallest possible type that has ## at least <expbits> bits for the exponent and that allows <maxcand> as ## exponent. ## ## If the family itself knows that its objects have (at most) a specified ## size then objects of the corresponding type are created faster. ## InstallOtherMethod( ObjByExtRep, "for a fam. of assoc. words, a cyclotomic, an int., and a homog. list", true, [ IsAssocWordFamily and IsSyllableWordsFamily, IsCyclotomic, IsInt, IsHomogeneousList ], 0, function( F, exp, maxcand, descr ) local info, expbits; # Choose the appropriate type. if maxcand < 0 then maxcand:= - maxcand; fi; info:= F!.expBitsInfo; expbits:= F!.expBits; if exp <= expbits[2] and maxcand < info[2] then if exp <= expbits[1] and maxcand < info[1] then return AssocWord( F!.types[1], descr ); else return AssocWord( F!.types[2], descr ); fi; elif exp <= expbits[3] and maxcand < info[3] then return AssocWord( F!.types[3], descr ); else return AssocWord( F!.types[4], descr ); fi; end ); ############################################################################# ## #M Install (internal) methods for objects of the 8 bits type ## InstallMethod( ExtRepOfObj, "for an 8 bits assoc. word", true, [ Is8BitsAssocWord ], 0, 8Bits_ExtRepOfObj ); InstallMethod( \=, "for two 8 bits assoc. words", IsIdenticalObj, [ Is8BitsAssocWord, Is8BitsAssocWord ], 0, 8Bits_Equal ); InstallMethod( \<, "for two 8 bits assoc. words", IsIdenticalObj, [ Is8BitsAssocWord, Is8BitsAssocWord ], 0, 8Bits_Less ); InstallMethod( \*, "for two 8 bits assoc. words", IsIdenticalObj, [ Is8BitsAssocWord, Is8BitsAssocWord ], 0, 8Bits_Product ); InstallMethod( \/, "for two 8 bits assoc. words", IsIdenticalObj, [ Is8BitsAssocWord, Is8BitsAssocWord and IsMultiplicativeElementWithInverse ], 0, 8Bits_Quotient ); InstallMethod( OneOp, "for an 8 bits assoc. word-with-one", true, [ Is8BitsAssocWord and IsAssocWordWithOne ], 0, x -> 8Bits_AssocWord( FamilyObj( x )!.types[1], [] ) ); InstallMethod( \^, "for an 8 bits assoc. word, and zero (in small integer rep)", true, [ Is8BitsAssocWord and IsMultiplicativeElementWithOne, IsZeroCyc and IsSmallIntRep ], 0, 8Bits_Power ); InstallMethod( \^, "for an 8 bits assoc. word, and a small negative integer", true, [ Is8BitsAssocWord and IsMultiplicativeElementWithInverse, IsInt and IsNegRat and IsSmallIntRep ], 0, 8Bits_Power ); InstallMethod( \^, "for an 8 bits assoc. word, and a small positive integer", true, [ Is8BitsAssocWord, IsPosInt and IsSmallIntRep ], 0, 8Bits_Power ); InstallMethod( ExponentSyllable, "for an 8 bits assoc. word, and a pos. integer", true, [ Is8BitsAssocWord, IsPosInt ], 0, 8Bits_ExponentSyllable ); InstallMethod( GeneratorSyllable, "for an 8 bits assoc. word, and an integer", true, [ Is8BitsAssocWord, IsInt ], 0, 8Bits_GeneratorSyllable ); InstallMethod( NumberSyllables, "for an 8 bits assoc. word", true, [ Is8BitsAssocWord ], 0, NBits_NumberSyllables ); InstallMethod( ExponentSums, "for an 8 bits assoc. word", true, [ Is8BitsAssocWord ], 0, 8Bits_ExponentSums1 ); InstallOtherMethod( ExponentSums, "for an 8 bits assoc. word, and two integers", true, [ Is8BitsAssocWord, IsInt, IsInt ], 0, 8Bits_ExponentSums3 ); InstallOtherMethod( Length, "for an 8 bits assoc. word", true, [ Is8BitsAssocWord ], 0, 8Bits_LengthWord ); ############################################################################# ## #M Install (internal) methods for objects of the 16 bits type ## InstallMethod( ExtRepOfObj, "for a 16 bits assoc. word", true, [ Is16BitsAssocWord ], 0, 16Bits_ExtRepOfObj ); InstallMethod( \=, "for two 16 bits assoc. words", IsIdenticalObj, [ Is16BitsAssocWord, Is16BitsAssocWord ], 0, 16Bits_Equal ); InstallMethod( \<, "for two 16 bits assoc. words", IsIdenticalObj, [ Is16BitsAssocWord, Is16BitsAssocWord ], 0, 16Bits_Less ); InstallMethod( \*, "for two 16 bits assoc. words", IsIdenticalObj, [ Is16BitsAssocWord, Is16BitsAssocWord ], 0, 16Bits_Product ); InstallMethod( \/, "for two 16 bits assoc. words", IsIdenticalObj, [ Is16BitsAssocWord, Is16BitsAssocWord and IsMultiplicativeElementWithInverse ], 0, 16Bits_Quotient ); InstallMethod( OneOp, "for a 16 bits assoc. word-with-one", true, [ Is16BitsAssocWord and IsAssocWordWithOne ], 0, x -> 16Bits_AssocWord( FamilyObj( x )!.types[2], [] ) ); InstallMethod( \^, "for a 16 bits assoc. word, and zero (in small integer rep)", true, [ Is16BitsAssocWord and IsMultiplicativeElementWithOne, IsZeroCyc and IsSmallIntRep ], 0, 16Bits_Power ); InstallMethod( \^, "for a 16 bits assoc. word, and a small negative integer", true, [ Is16BitsAssocWord and IsMultiplicativeElementWithInverse, IsInt and IsNegRat and IsSmallIntRep ], 0, 16Bits_Power ); InstallMethod( \^, "for a 16 bits assoc. word, and a small positive integer", true, [ Is16BitsAssocWord, IsPosInt and IsSmallIntRep ], 0, 16Bits_Power ); InstallMethod( ExponentSyllable, "for a 16 bits assoc. word, and pos. integer", true, [ Is16BitsAssocWord, IsPosInt ], 0, 16Bits_ExponentSyllable ); InstallMethod( GeneratorSyllable, "for a 16 bits assoc. word, and integer", true, [ Is16BitsAssocWord, IsInt ], 0, 16Bits_GeneratorSyllable ); InstallMethod( NumberSyllables, "for a 16 bits assoc. word", true, [ Is16BitsAssocWord ], 0, NBits_NumberSyllables ); InstallMethod( ExponentSums, "for a 16 bits assoc. word", true, [ Is16BitsAssocWord ], 0, 16Bits_ExponentSums1 ); InstallOtherMethod( ExponentSums, "for a 16 bits assoc. word, and two integers", true, [ Is16BitsAssocWord, IsInt, IsInt ], 0, 16Bits_ExponentSums3 ); InstallOtherMethod( Length, "for a 16 bits assoc. word", true, [ Is16BitsAssocWord ], 0, 16Bits_LengthWord ); ############################################################################# ## #M Install (internal) methods for objects of the 32 bits type ## InstallMethod( ExtRepOfObj, "for a 32 bits assoc. word", true, [ Is32BitsAssocWord ], 0, 32Bits_ExtRepOfObj ); InstallMethod( \=, "for two 32 bits assoc. words", IsIdenticalObj, [ Is32BitsAssocWord, Is32BitsAssocWord ], 0, 32Bits_Equal ); InstallMethod( \<, "for two 32 bits assoc. words", IsIdenticalObj, [ Is32BitsAssocWord, Is32BitsAssocWord ], 0, 32Bits_Less ); InstallMethod( \*, "for two 32 bits assoc. words", IsIdenticalObj, [ Is32BitsAssocWord, Is32BitsAssocWord ], 0, 32Bits_Product ); InstallMethod( \/, "for two 32 bits assoc. words", IsIdenticalObj, [ Is32BitsAssocWord, Is32BitsAssocWord and IsMultiplicativeElementWithInverse ], 0, 32Bits_Quotient ); InstallMethod( OneOp, "for a 32 bits assoc. word-with-one", true, [ Is32BitsAssocWord and IsAssocWordWithOne ], 0, x -> 32Bits_AssocWord( FamilyObj( x )!.types[3], [] ) ); InstallMethod( \^, "for a 32 bits assoc. word, and zero (in small integer rep)", true, [ Is32BitsAssocWord and IsMultiplicativeElementWithOne, IsZeroCyc and IsSmallIntRep ], 0, 32Bits_Power ); InstallMethod( \^, "for a 32 bits assoc. word, and a small negative integer", true, [ Is32BitsAssocWord and IsMultiplicativeElementWithInverse, IsInt and IsNegRat and IsSmallIntRep ], 0, 32Bits_Power ); InstallMethod( \^, "for a 32 bits assoc. word, and a small positive integer", true, [ Is32BitsAssocWord, IsPosInt and IsSmallIntRep ], 0, 32Bits_Power ); InstallMethod( ExponentSyllable, "for a 32 bits assoc. word, and pos. integer", true, [ Is32BitsAssocWord, IsPosInt ], 0, 32Bits_ExponentSyllable ); InstallMethod( GeneratorSyllable, "for a 32 bits assoc. word, and pos. integer", true, [ Is32BitsAssocWord, IsPosInt ], 0, 32Bits_GeneratorSyllable ); InstallMethod( NumberSyllables, "for a 32 bits assoc. word", true, [ Is32BitsAssocWord ], 0, NBits_NumberSyllables ); InstallMethod( ExponentSums, "for a 32 bits assoc. word", true, [ Is32BitsAssocWord ], 0, 32Bits_ExponentSums1 ); InstallOtherMethod( ExponentSums, "for a 32 bits assoc. word", true, [ Is32BitsAssocWord, IsInt, IsInt ], 0, 32Bits_ExponentSums3 ); InstallOtherMethod( Length, "for a 32 bits assoc. word", true, [ Is32BitsAssocWord ], 0, 32Bits_LengthWord ); ############################################################################# ## #M Install methods for objects of the infinity type ## BindGlobal( "InfBits_ExtRepOfObj", elm->elm![1] ); InstallMethod( ExtRepOfObj, "for a inf. bits assoc. word", true, [ IsInfBitsAssocWord ], 0, InfBits_ExtRepOfObj ); BindGlobal( "InfBits_Equal", {x,y} -> x![1] = y![1] ); InstallMethod( \=, "for two inf. bits assoc. words", IsIdenticalObj, [ IsInfBitsAssocWord, IsInfBitsAssocWord ], 0, InfBits_Equal ); BindGlobal( "InfBits_Less", function( u, v ) local lu, lv, # length of u/v as a list len, # difference in length of u/v as words i, # loop variable lexico; # flag for the lexicoghraphic ordering of u and v u := u![1]; lu := Length(u); v := v![1]; lv := Length(v); ## Discard a common prefix in u and v and decide if u is ## lexicographically smaller than v. i := 1; while i <= lu and i <= lv and u[i] = v[i] do i := i+1; od; if i > lu then ## u is a prefix of v. return lu < lv; fi; if i > lv then ## v is a prefix of u, but not equal to u. return false; fi; ## Decide if u is lexicographically smaller than v. if i mod 2 = 1 then ## the generators in u and v differ lexico := u[i] < v[i]; i := i+1; else ## the exponents in u and v differ if u[i] = -v[i] then lexico := u[i] < 0; else ## Here we have to look at the next generator in the word whose ## syllable has the smaller absolute exponent in order to decide ## which word is smaller. if AbsInt(u[i]) > AbsInt(v[i]) then if i+1 <= lv then lexico := u[i-1] < v[i+1]; else ## Ignoring the common prefix, v is empty. return false; fi; else ## |u[i]| < |v[i]| if i+1 <= lu then lexico := u[i+1] < v[i-1]; else ## Ignoring the common prefix, u is empty. return true; fi; fi; fi; fi; ## Now compute the difference of the lengths len := 0; while i <= lu and i <= lv do len := len + AbsInt(u[i]); len := len - AbsInt(v[i]); i := i+2; od; ## Only one of the following while loops will be executed. while i <= lu do len := len + AbsInt(u[i]); i := i+2; od; while i <= lv do len := len - AbsInt(v[i]); i := i+2; od; if len = 0 then return lexico; fi; return len < 0; end ); InstallMethod( \<, "for two inf. bits assoc. words", IsIdenticalObj, [ IsInfBitsAssocWord, IsInfBitsAssocWord ], 100, InfBits_Less ); BindGlobal( "InfBits_One", x -> InfBits_AssocWord( FamilyObj(x)!.types[4],[] ) ); InstallMethod( OneOp, "for an inf. bits assoc. word-with-one", true, [ IsInfBitsAssocWord and IsAssocWordWithOne ], 0, InfBits_One ); BindGlobal( "InfBits_ExponentSyllable", function( x, i ) return x![1][ 2*i ]; end ); InstallMethod( ExponentSyllable, "for an inf. bits assoc. word, and a pos. integer", true, [ IsInfBitsAssocWord, IsPosInt ], 0, InfBits_ExponentSyllable ); BindGlobal( "InfBits_GeneratorSyllable", function( x, i ) return x![1][2*i-1]; end ); InstallMethod( GeneratorSyllable, "for an inf. bits assoc. word, and an integer", true, [ IsInfBitsAssocWord, IsInt ], 0, InfBits_GeneratorSyllable ); BindGlobal( "InfBits_NumberSyllables", x -> Length( x![1] ) / 2 ); InstallMethod( NumberSyllables, "for an inf. bits assoc. word", true, [ IsInfBitsAssocWord ], 0, InfBits_NumberSyllables ); BindGlobal( "InfBits_ExponentSums1", function( obj ) local expvec, i; #expvec:= []; #for i in [ 1 .. TypeObj( obj )![ AWP_NR_GENS ] ] do # expvec[i]:= 0; #od; expvec:=ListWithIdenticalEntries(TypeObj( obj )![ AWP_NR_GENS ],0); obj:= obj![1]; for i in [ 1, 3 .. Length( obj ) - 1 ] do expvec[ obj[i] ]:= expvec[ obj[i] ] + obj[ i+1 ]; od; return expvec; end ); InstallMethod( ExponentSums, "for an inf. bits assoc. word", true, [ IsInfBitsAssocWord ], 0, InfBits_ExponentSums1 ); BindGlobal( "InfBits_ExponentSums3", function( obj, from, to ) local expvec, i; if from < 1 then Error("<from> must be a positive integer"); fi; if to < 1 then Error("<to> must be a positive integer"); fi; if from > to then return []; fi; expvec:=ListWithIdenticalEntries(TypeObj( obj )![ AWP_NR_GENS ],0); # the syllable representation is a sparse representation obj:= obj![1]; for i in [ 1, 3.. Length(obj)-1 ] do if obj[i] in [from..to] then expvec[ obj[i] ]:= expvec[ obj[i] ] + obj[ i+1 ]; fi; od; return expvec{[from..to]}; end ); InstallOtherMethod( ExponentSums, "for an inf. bits assoc. word, and two integers", true, [ IsInfBitsAssocWord, IsInt, IsInt ], 1, InfBits_ExponentSums3 ); ############################################################################# ## #F ObjByVector( <Type>, <vector> ) #T ObjByVector( <Fam>, <vector> ) ## InstallGlobalFunction( ObjByVector, function( Type, vec ) return Type; end ); BindGlobal( "InfBits_ObjByVector", function( type, vec ) local expr, i; expr:= []; for i in [ 1 .. Length( vec ) ] do if vec[i] <> 0 then Add( expr, i ); Add( expr, vec[i] ); fi; od; return ObjByExtRep( FamilyType(type), expr ); end ); ############################################################################# ## #M ObjByExtRep( <Fam>, <exp>, <maxcand>, <descr> ) ## ## If the family does already know that all only words in a prescribed ## type will be constructed then we store this in the family, ## and `ObjByExtRep' will construct only such objects. ## InstallOtherMethod( ObjByExtRep, "for an 8 bits assoc. words family, two integers, and a list", true, [ IsAssocWordFamily and Is8BitsFamily, IsInt, IsInt, IsHomogeneousList ], 0, function( F, exp, maxcand, descr ) return 8Bits_AssocWord( F!.types[1], descr ); end ); InstallOtherMethod( ObjByExtRep, "for a 16 bits assoc. words family, two integers, and a list", true, [ IsAssocWordFamily and Is16BitsFamily, IsInt, IsInt, IsHomogeneousList ], 0, function( F, exp, maxcand, descr ) return 16Bits_AssocWord( F!.types[2], descr ); end ); InstallOtherMethod( ObjByExtRep, "for a 32 bits assoc. words family, two integers, and a list", true, [ IsAssocWordFamily and Is32BitsFamily, IsInt, IsInt, IsHomogeneousList ], 0, function( F, exp, maxcand, descr ) return 32Bits_AssocWord( F!.types[3], descr ); end ); InstallOtherMethod( ObjByExtRep, "for an inf. bits assoc. words family, two integers, and a list", true, [ IsAssocWordFamily and IsInfBitsFamily, IsCyclotomic, IsInt, IsHomogeneousList ], 0, function( F, exp, maxcand, descr ) return InfBits_AssocWord( F!.types[4], descr ); end ); ############################################################################# ## #F StoreInfoFreeMagma( <F>, <names>, <req> ) ## ## does the administrative work in the construction of free semigroups, ## free monoids, and free groups. ## ## <F> is the family of objects, <names> is a list of generators names, ## and <req> is the required category for the elements, that is, ## `IsAssocWord', `IsAssocWordWithOne', or `IsAssocWordWithInverse'. ## InstallGlobalFunction( StoreInfoFreeMagma, function( F, names, req ) local rank, rbits, K, expB, typesList; # Store the names, initialize the types list. typesList := []; F!.names := Immutable( names ); # for letter word families we do not need these types if not IsFinite( names ) then SetFilterObj( F, IsInfBitsFamily ); else # Install the data (number of bits available for exponents). # Note that in the case of the 32 bits representation, # at most 28 bits are allowed for the exponents in order to avoid # overflow checks. rank := Length( names ); rbits := 1; while 2^rbits < rank do rbits:= rbits + 1; od; expB := [ 8 - rbits, 16 - rbits, Minimum( 32 - rbits, 28 ), infinity ]; # Note that one bit of the exponents is needed for the sign, # and we disallow the use of a representation if at most two # additional bits would be available. if expB[1] <= 3 then expB[1]:= 0; fi; if expB[2] <= 3 then expB[2]:= 0; fi; if expB[3] <= 3 then expB[3]:= 0; fi; MakeImmutable(expB); F!.expBits := expB; F!.expBitsInfo := MakeImmutable([ 2^( F!.expBits[1] - 1 ), 2^( F!.expBits[2] - 1 ), 2^( F!.expBits[3] - 1 ), infinity ]); # Store the internal types. K:= NewType( F, Is8BitsAssocWord and req ); StrictBindOnce(K, AWP_PURE_TYPE , K); StrictBindOnce(K, AWP_NR_BITS_EXP , F!.expBits[1]); StrictBindOnce(K, AWP_NR_GENS , rank); StrictBindOnce(K, AWP_NR_BITS_PAIR , 8); StrictBindOnce(K, AWP_FUN_OBJ_BY_VECTOR, 8Bits_ObjByVector); StrictBindOnce(K, AWP_FUN_ASSOC_WORD , 8Bits_AssocWord); typesList[1]:= K; K:= NewType( F, Is16BitsAssocWord and req ); StrictBindOnce(K, AWP_PURE_TYPE , K); StrictBindOnce(K, AWP_NR_BITS_EXP , F!.expBits[2]); StrictBindOnce(K, AWP_NR_GENS , rank); StrictBindOnce(K, AWP_NR_BITS_PAIR , 16); StrictBindOnce(K, AWP_FUN_OBJ_BY_VECTOR, 16Bits_ObjByVector); StrictBindOnce(K, AWP_FUN_ASSOC_WORD , 16Bits_AssocWord); typesList[2]:= K; K:= NewType( F, Is32BitsAssocWord and req ); StrictBindOnce(K, AWP_PURE_TYPE , K); StrictBindOnce(K, AWP_NR_BITS_EXP , F!.expBits[3]); StrictBindOnce(K, AWP_NR_GENS , rank); StrictBindOnce(K, AWP_NR_BITS_PAIR , 32); StrictBindOnce(K, AWP_FUN_OBJ_BY_VECTOR, 32Bits_ObjByVector); StrictBindOnce(K, AWP_FUN_ASSOC_WORD , 32Bits_AssocWord); typesList[3]:= K; fi; K:= NewType( F, IsInfBitsAssocWord and req ); StrictBindOnce(K, AWP_PURE_TYPE , K); StrictBindOnce(K, AWP_NR_BITS_EXP , infinity); StrictBindOnce(K, AWP_NR_GENS , Length( names )); StrictBindOnce(K, AWP_NR_BITS_PAIR , infinity); StrictBindOnce(K, AWP_FUN_OBJ_BY_VECTOR , InfBits_ObjByVector); StrictBindOnce(K, AWP_FUN_ASSOC_WORD , InfBits_AssocWord); typesList[4]:= K; F!.types := MakeImmutable(typesList); if IsBLetterWordsFamily(F) then K:= NewType( F, IsBLetterAssocWordRep and req ); else K:= NewType( F, IsWLetterAssocWordRep and req ); fi; F!.letterWordType:=K; end ); ############################################################################# ## #R IsInfiniteListOfNamesRep( <list> ) ## ## is a representation of a list <list> containing at position $i$ ## either the string `<string>$i$' or the string `<init>[$i$]', ## where the latter holds if and only if $i$ does not exceed the ## length of the list <init>. ## ## <string> is stored at position 1 in the positional object <list>, ## <init> is stored at position 2. ## DeclareRepresentation( "IsInfiniteListOfNamesRep", IsPositionalObjectRep, [ 1, 2 ] ); InstallMethod( PrintObj, "for an infinite list of names", true, [ IsList and IsInfiniteListOfNamesRep ], 0, function( list ) Print( "InfiniteListOfNames( \"", list![1], "\", ", list![2], " )" ); end ); InstallMethod( ViewObj, "for an infinite list of names", true, [ IsList and IsInfiniteListOfNamesRep ], 0, function( list ) Print( "[ ", list[1], ", ", list[2], ", ... ]" ); end ); InstallMethod( \[\], "for an infinite list of names", true, [ IsList and IsInfiniteListOfNamesRep, IsPosInt ], 0, function( list, pos ) local entry; if pos <= Length( list![2] ) then entry:= list![2][ pos ]; else entry:= Concatenation( list![1], String( pos ) ); ConvertToStringRep( entry ); fi; return entry; end ); InstallMethod( Length, "for an infinite list of names", true, [ IsList and IsInfiniteListOfNamesRep ], 0, list -> infinity ); InstallMethod( Position, "for an infinite list of names, an object, and zero", true, [ IsList and IsInfiniteListOfNamesRep, IsObject, IsZeroCyc ], 0, function( list, obj, zero ) local digits, pos, i; # Check whether `obj' is in the initial segment, and if not, # whether `obj' matches the names in the rest of the list.. pos:= Position( list![2], obj ); if pos <> fail then return pos; elif ( not IsString( obj ) ) or Length( obj ) <= Length( list![1] ) or obj{ [ 1 .. Length( list![1] ) ] } <> list![1] then return fail; fi; # Convert the suffix to a number if possible. digits:= "0123456789"; pos:= 0; for i in [ Length( list![1] ) + 1 .. Length( obj ) ] do if obj[i] in digits then pos:= 10*pos + Position( digits, obj[i], 0 ) - 1; else return fail; fi; od; # If the number belongs to a position in the initial segment, # `obj' is not in the list. if pos <= Length( list![2] ) then pos:= fail; fi; return pos; end ); ############################################################################# ## #F InfiniteListOfNames( <string> ) #F InfiniteListOfNames( <string>, <init> ) ## InstallGlobalFunction( InfiniteListOfNames, function( arg ) local string, init, list; if Length( arg ) = 1 and IsString( arg[1] ) then string := Immutable( arg[1] ); init := Immutable( [] ); elif Length( arg ) = 2 and IsString( arg[1] ) and IsList( arg[2] ) then string := Immutable( arg[1] ); init := Immutable( arg[2] ); else Error( "usage: InfiniteListOfNames( <string>[, <init>] )" ); fi; list:= Objectify( NewType( CollectionsFamily( FamilyObj( string ) ), IsList and IsDenseList and IsConstantTimeAccessList and IsInfiniteListOfNamesRep ), [ string, init ] ); SetIsFinite( list, false ); SetIsEmpty( list, false ); if IsHPCGAP then MakeReadOnlyObj( list ); fi; SetLength( list, infinity ); #T meaningless since not attribute storing! return list; end ); ############################################################################# ## #R IsInfiniteListOfGeneratorsRep( <Fam> ) ## ## is a representation used for lists containing at position $i$ the $i$-th ## generator of the ``free something family'' <Fam>. ## Note that we have to distinguish the cases of associative words and ## nonassociative words, since they have different external representations. ## ## The family <Fam> is stored at position 1 in the list object, ## at position 2 a (possibly empty) list of initial generators is stored. ## DeclareRepresentation( "IsInfiniteListOfGeneratorsRep", IsPositionalObjectRep, [ 1, 2 ] ); InstallMethod( ViewObj, "for an infinite list of generators", true, [ IsList and IsInfiniteListOfGeneratorsRep ], 0, function( list ) Print( "[ ", list[1], ", ", list[2], ", ... ]" ); end ); InstallMethod( PrintObj, "for an infinite list of generators", true, [ IsList and IsInfiniteListOfGeneratorsRep ], 0, function( list ) Print( "[ ", list[1], ", ", list[2], ", ... ]" ); end ); InstallMethod( Length, "for an infinite list of generators", true, [ IsList and IsInfiniteListOfGeneratorsRep ], 0, list -> infinity ); InstallMethod( \[\], "for an infinite list of generators", true, [ IsList and IsInfiniteListOfGeneratorsRep, IsPosInt ], 0, function( list, i ) if i <= Length( list![2] ) then return list![2][i]; elif IsAssocWordFamily( list![1] ) then if IsLetterWordsFamily(list![1]) then return AssocWordByLetterRep( list![1], [ i ] ); else return ObjByExtRep( list![1], [ i, 1 ] ); fi; else return ObjByExtRep( list![1], i ); fi; end ); InstallMethod( Position, "for an infinite list of generators, an object, and zero", true, [ IsList and IsInfiniteListOfGeneratorsRep, IsObject, IsZeroCyc ], 0, function( list, obj, zero ) local ext; if FamilyObj( obj ) <> list![1] then return fail; fi; if IsAssocWord( obj ) then ext:=LetterRepAssocWord(obj); if Length(ext)<> 1 or ext[1]<0 then return fail; else return ext[1]; fi; else ext:= ExtRepOfObj( obj ); if not IsInt( ext ) then return fail; else return ext; fi; fi; end ); ############################################################################# ## #M Random( <list> ) . . . . . . . . . . for an infinite list of generators ## InstallMethodWithRandomSource( Random, "for a random source and an infinite list of generators", [ IsRandomSource, IsList and IsInfiniteListOfGeneratorsRep ], 0, function( rs, list ) local pos; pos:= Random( rs, Integers ); if 0 <= pos then return list[ 2 * pos + 1 ]; else return list[ -2 * pos ]; fi; end ); #T should be moved to list.gi, or? ############################################################################# ## #F InfiniteListOfGenerators( <F> ) #F InfiniteListOfGenerators( <F>, <init> ) ## InstallGlobalFunction( InfiniteListOfGenerators, function( arg ) local F, init, list; if Length( arg ) = 1 and IsFamily( arg[1] ) then F := arg[1]; init := Immutable( [] ); elif Length( arg ) = 2 and IsFamily( arg[1] ) and IsList( arg[2] ) then F := arg[1]; init := Immutable( arg[2] ); fi; list:= Objectify( NewType( CollectionsFamily( F ), IsList and IsDenseList and IsConstantTimeAccessList and IsInfiniteListOfGeneratorsRep ), [ F, init ] ); SetIsFinite( list, false ); SetIsEmpty( list, false ); if IsHPCGAP then MakeReadOnlyObj( list ); fi; SetLength( list, infinity ); #T meaningless since not attribute storing! return list; end ); # letter representation InstallOtherMethod(LetterRepAssocWord,"syllable rep, generators", true, #TODO: This should be IsElmsColls once the tietze code is fixed. [IsSyllableAssocWordRep,IsList],0, function ( word, generators ) local ind,n,i,e,l,g; ind:=[]; n:=1; for i in generators do ind[GeneratorSyllable(i,1)]:=n; n:=n+1; od; e:=ExtRepOfObj(word); l:=[]; for i in [1,3..Length(e)-1] do g:=ind[e[i]]; n:=e[i+1]; if n<0 then g:=-g; n:=-n; fi; Append(l,ListWithIdenticalEntries(n,g)); od; return l; end ); InstallMethod(LetterRepAssocWord,"syllable rep",true, [IsSyllableAssocWordRep],0, function(word) local n,i,e,l,g; e:=ExtRepOfObj(word); l:=[]; for i in [1,3..Length(e)-1] do g:=e[i]; n:=e[i+1]; if n<0 then g:=-g; n:=-n; fi; Append(l,ListWithIdenticalEntries(n,g)); od; return l; end ); InstallMethod(AssocWordByLetterRep,"family, list: syllables",true, [IsSyllableWordsFamily,IsHomogeneousList],0, function ( wfam,word ) local e,lg,i,num,mex; # first generate an external representation e:=[]; mex:=1; lg:=0; i:=0; for num in word do if num<0 then if -num=lg then # increase exponent e[i]:=e[i]-1; mex:=Maximum(mex,-e[i]); else # add new generator/exponent pair Append(e,[-num,-1]); lg:=-num; i:=i+2; fi; else if num=lg then # increase exponent e[i]:=e[i]+1; mex:=Maximum(mex,e[i]); else # add new generator/exponent pair Append(e,[num,1]); lg:=num; i:=i+2; fi; fi; od; # then build a word from it e:=ObjByExtRep(wfam,mex,mex,e); return e; end ); InstallOtherMethod(AssocWordByLetterRep,"family, list, gens: syllables",true, [IsSyllableWordsFamily,IsHomogeneousList,IsHomogeneousList],0, function (fam, word, fgens ) local ind,e,lg,i,num,mex; # index the generators ind:=List(fgens,i->GeneratorSyllable(i,1)); # first generate an external representation e:=[]; mex:=1; lg:=0; i:=0; for num in word do if num<0 then if -num=lg then # increase exponent e[i]:=e[i]-1; mex:=Maximum(mex,-e[i]); else # add new generator/exponent pair Append(e,[ind[-num],-1]); lg:=-num; i:=i+2; fi; else if num=lg then # increase exponent e[i]:=e[i]+1; mex:=Maximum(mex,e[i]); else # add new generator/exponent pair Append(e,[ind[num],1]); lg:=num; i:=i+2; fi; fi; od; # then build a word from it e:=ObjByExtRep(fam,mex,mex,e); return e; end ); ############################################################################# ## #M Length( <w> ) ## InstallOtherMethod( Length, "for an assoc. word in syllable rep", true, [ IsAssocWord and IsSyllableAssocWordRep], 0, function( w ) local len, i; w:= ExtRepOfObj( w ); len:= 0; for i in [ 2, 4 .. Length( w ) ] do len:= len + AbsInt( w[i] ); od; return len; end ); ############################################################################# ## #M ExponentSyllable( <w>, <n> ) ## InstallMethod( ExponentSyllable, "for an assoc. word in syllable rep, and a positive integer", true, [ IsAssocWord and IsSyllableAssocWordRep, IsPosInt ], 0, function( w, n ) return ExtRepOfObj( w )[ 2*n ]; end ); ############################################################################# ## #M GeneratorSyllable( <w>, <n> ) ## InstallMethod( GeneratorSyllable, "for an assoc. word in syllable rep, and a positive integer", true, [ IsAssocWord and IsSyllableAssocWordRep, IsPosInt ], 0, function( w, n ) return ExtRepOfObj( w )[ 2*n-1 ]; end ); ############################################################################# ## #M NumberSyllables( <w> ) ## InstallMethod( NumberSyllables, "for an assoc. word in syllable rep", true, [ IsAssocWord and IsSyllableAssocWordRep], 0, w -> Length( ExtRepOfObj( w ) ) / 2 ); ############################################################################# ## #M ExponentSumWord( <w>, <gen> ) ## InstallMethod( ExponentSumWord, "syllable rep as.word, gen", IsIdenticalObj, [ IsAssocWord and IsSyllableAssocWordRep, IsAssocWord ], 0, function( w, gen ) local n, g, i; w:= ExtRepOfObj( w ); gen:= ExtRepOfObj( gen ); if Length( gen ) <> 2 or ( gen[2] <> 1 and gen[2] <> -1 ) then Error( "<gen> must be a generator" ); fi; n:= 0; g:= gen[1]; for i in [ 1, 3 .. Length( w ) - 1 ] do if w[i] = g then n:= n + w[ i+1 ]; fi; od; if gen[2] = -1 then n:= -n; fi; return n; end ); ############################################################################# ## #M ExponentSums( <f>,<w> ) ## InstallOtherMethod( ExponentSums, "for a group and an assoc. word in syllable rep", true, [ IsGroup, IsAssocWord ], 0, function( f, w ) local l,gens,g,i,p; Info(InfoWarning,2,"obsolete undocumented method"); gens:=List(FreeGeneratorsOfFpGroup(f),ExtRepOfObj); g:=gens{[1..Length(gens)]}[1]; l:=List(gens,x->0); w:= ExtRepOfObj( w ); for i in [ 1, 3 .. Length( w ) - 1 ] do p:=Position(g,w[i]); l[p]:=l[p]+w[i+1]; od; for i in [1..Length(l)] do if gens[i][2]=-1 then l[i]:=-l[i];fi; od; return l; end ); InstallGlobalFunction(FreelyReducedLetterRepWord,function(w) local i; i:=1; while i<Length(w) do if w[i]=-w[i+1] then w:=Concatenation(w{[1..i-1]},w{[i+2..Length(w)]}); # there could be cancellation of previous if i>1 then i:=i-1; fi; else i:=i+1; fi; od; return w; end); InstallGlobalFunction(WordProductLetterRep,function(arg) local l,r,i,j,b,p,lc; l:=arg[1]; lc:=false; for p in [2..Length(arg)] do r:=arg[p]; b:=Length(r); if Length(l)=0 then l:=r; elif b>0 then # find cancellation i:=Length(l); j:=1; while i>0 and j<=b and l[i]=-r[j] do i:=i-1;j:=j+1; od; if j>b then l:=l{[1..i]}; lc:=true; elif i=0 then l:=r{[j..b]}; lc:=true; else if j=1 and lc then # No cancellation, and l was changed already: Append Append(l,r); else l:=Concatenation(l{[1..i]},r{[j..b]}); lc:=true; fi; fi; fi; od; return l; end); [ Dauer der Verarbeitung: 0.15 Sekunden (vorverarbeitet) ] |
2026-03-28