o FZh$@sddlmZddlmZddlmZmZmZmZm Z m Z ddl m Z ddl mZddlmZmZmZmZddlmZdd Zd d Zd d ZGdddZeZe dZeeddZeeddZeeddZeeddZeeddZeeddZeeddZeeddZeeddZeeddZejddej ddej!ddej"d dej#d!dej$d"dej%d#dej&d$dej'd%dej(d&di Z)eee e d'dZd(S))) defaultdict)Q)AddMulPowNumber NumberSymbolSymbol) ImaginaryUnit)Abs) EquivalentAndOrImplies)MatMulctfdd|jDS)a Apply all arguments of the expression to the fact structure. Parameters ========== symbol : Symbol A placeholder symbol. fact : Boolean Resulting ``Boolean`` expression. expr : Expr Examples ======== >>> from sympy import Q >>> from sympy.assumptions.sathandlers import allargs >>> from sympy.abc import x, y >>> allargs(x, Q.negative(x) | Q.positive(x), x*y) (Q.negative(x) | Q.positive(x)) & (Q.negative(y) | Q.positive(y)) cg|]}|qSsubs.0argfactsymbolrL/var/www/auris/lib/python3.10/site-packages/sympy/assumptions/sathandlers.py (zallargs..)r argsrrexprrrrallargsr"cr)a Apply any argument of the expression to the fact structure. Parameters ========== symbol : Symbol A placeholder symbol. fact : Boolean Resulting ``Boolean`` expression. expr : Expr Examples ======== >>> from sympy import Q >>> from sympy.assumptions.sathandlers import anyarg >>> from sympy.abc import x, y >>> anyarg(x, Q.negative(x) & Q.positive(x), x*y) (Q.negative(x) & Q.positive(x)) | (Q.negative(y) & Q.positive(y)) crrrrrrrrDrzanyarg..)rrr rrranyarg+r#r$cs8fdd|jDtfddttD}|S)a Apply exactly one argument of the expression to the fact structure. Parameters ========== symbol : Symbol A placeholder symbol. fact : Boolean Resulting ``Boolean`` expression. expr : Expr Examples ======== >>> from sympy import Q >>> from sympy.assumptions.sathandlers import exactlyonearg >>> from sympy.abc import x, y >>> exactlyonearg(x, Q.positive(x), x*y) (Q.positive(x) & ~Q.positive(y)) | (Q.positive(y) & ~Q.positive(x)) crrrrrrrr`rz!exactlyonearg..c sBg|]}t|gddd||ddDRqS)cSsg|]}|qSrr)rZlitrrrrasz,exactlyonearg...N)r )ri) pred_argsrrras )rrrangelen)rrr!resr)rr'rr exactlyoneargGs   r+c@s8eZdZdZddZddZddZdd Zd d Zd S) ClassFactRegistrya Register handlers against classes. Explanation =========== ``register`` method registers the handler function for a class. Here, handler function should return a single fact. ``multiregister`` method registers the handler function for multiple classes. Here, handler function should return a container of multiple facts. ``registry(expr)`` returns a set of facts for *expr*. Examples ======== Here, we register the facts for ``Abs``. >>> from sympy import Abs, Equivalent, Q >>> from sympy.assumptions.sathandlers import ClassFactRegistry >>> reg = ClassFactRegistry() >>> @reg.register(Abs) ... def f1(expr): ... return Q.nonnegative(expr) >>> @reg.register(Abs) ... def f2(expr): ... arg = expr.args[0] ... return Equivalent(~Q.zero(arg), ~Q.zero(expr)) Calling the registry with expression returns the defined facts for the expression. >>> from sympy.abc import x >>> reg(Abs(x)) {Q.nonnegative(Abs(x)), Equivalent(~Q.zero(x), ~Q.zero(Abs(x)))} Multiple facts can be registered at once by ``multiregister`` method. >>> reg2 = ClassFactRegistry() >>> @reg2.multiregister(Abs) ... def _(expr): ... arg = expr.args[0] ... return [Q.even(arg) >> Q.even(expr), Q.odd(arg) >> Q.odd(expr)] >>> reg2(Abs(x)) {Implies(Q.even(x), Q.even(Abs(x))), Implies(Q.odd(x), Q.odd(Abs(x)))} cCstt|_tt|_dSN)r frozenset singlefacts multifacts)selfrrr__init__s zClassFactRegistry.__init__cfdd}|S)Ncsj|hO<|Sr-)r/)funcclsr1rr_sz%ClassFactRegistry.register.._r)r1r6r7rr5rregisterszClassFactRegistry.registercr3)Ncs"D] }j||hO<q|Sr-)r0)r4r6classesr1rrr7sz*ClassFactRegistry.multiregister.._r)r1r:r7rr9r multiregisterszClassFactRegistry.multiregistercCsd|j|}|jD]}t||r||j|O}q|j|}|jD]}t||r-||j|O}q||fSr-)r/ issubclassr0)r1keyZret1kZret2rrr __getitem__s      zClassFactRegistry.__getitem__csJt}|t\}}|fdd|D|D] }||q|S)Nc3s|]}|VqdSr-r)rhr!rr sz-ClassFactRegistry.__call__..)settypeupdate)r1r!retZ handlers1Z handlers2r@rrAr__call__s zClassFactRegistry.__call__N) __name__ __module__ __qualname____doc__r2r8r;r?rGrrrrr,hs/ r,xcCsd|jd}t|tt|t|t|t|?t|t|?t|t|?gS)Nr)rr nonnegativer zeroevenoddinteger)r!rrrrr7s r7c Cstttt|t|?tttt|t|?tttt|t|?tttt|t|?tttt|t|?tttt|t|?gSr-) r"rLrpositivenegativerealrationalrQr+rArrrr7scC:tttt|}tttt|}t|t|t|Sr-r"rLrrTr+ irrationalrr!Z allargs_realZonearg_irrationalrrrr7c Cstt|tttt|tttt|t|?tttt|t|?tttt|t|?ttt t|t |?t ttt|t |?ttt t|t |?gSr-) r rrNr$rLr"rRrTrUrQr+Z commutativerArrrr7scCs$tttt|}t|t|Sr-)r"rLrprimer)r!Z allargs_primerrrr7scCsDttttttB|}tttt|}t|t|t|Sr-)r"rLr imaginaryrTr+r)r!Zallargs_imag_or_realZonearg_imaginaryrrrr7scCrVr-rWrYrrrr7rZcCs:tttt|}tttt|}t|t|t|Sr-)r"rLrrQr$rOrr )r!Zallargs_integerZ anyarg_evenrrrr7 scCs:tttt|}tttt|}t|tt||Sr-)r"rLrZsquareZ invertiblerr )r!Zallargs_squareZallargs_invertiblerrrr7rZc Cs|j|j}}t|t|@t|@t|?t|t|@t|@t|?t|t|@t|@t|?tt |t |t |@gSr-) baseexprrTrOrMrP nonpositiver rNrR)r!r]r^rrrr7 s &&&cC|jSr-)Z is_positiveorrr.rccCr`r-)is_zerorarrrrc/rdcCr`r-)Z is_negativerarrrrc0rdcCr`r-)Z is_rationalrarrrrc1rdcCr`r-)Z is_irrationalrarrrrc2rdcCr`r-)Zis_evenrarrrrc3rdcCr`r-)Zis_oddrarrrrc4rdcCr`r-)Z is_imaginaryrarrrrc5rdcCr`r-)Zis_primerarrrrc6rdcCr`r-)Z is_compositerarrrrc7rdcCsBg}tD]\}}||}||}|dur|t||q|Sr-)_old_assump_gettersitemsappendr )r!rFpgetterpredproprrrr7:sN)* collectionsrZsympy.assumptions.askrZ sympy.corerrrrrr Zsympy.core.numbersr Z$sympy.functions.elementary.complexesr Zsympy.logic.boolalgr r rrZsympy.matrices.expressionsrr"r$r+r,Zclass_fact_registryrLr;r7r8rRrNrSrUrXrOrPr\r[Z compositerfrrrrs\     !X