a RG5d?) @sdZddlmZddlmZmZddlmZddlm Z m Z ddl Z dZ dd d d d d ddddddddddddddddddd d!d"d#d$d%d&d'Z e D] Zee e<qejd(ejd)ejd*ejd+ejd,iZd-d.d/ZejgZGd0d1d1eZd6d2d3Zd4d5ZdS)7a  Maple code printer The MapleCodePrinter converts single SymPy expressions into single Maple expressions, using the functions defined in the Maple objects where possible. FIXME: This module is still under actively developed. Some functions may be not completed. )S)IntegerIntegerConstant) CodePrinter) precedence PRECEDENCEN) sincostanseccsccotsinhcoshtanhsechcschcothexpfloor factorial bernoullieuler fibonaccigcdlcm conjugateCiChiEiLiSiShierferfcharmonicLambertWsqrtabslnarcsinarccosarctanarcsecarccscarccotarcsinharccosharctanharcsecharccscharccothceilmaxminZdoublefactorial pochhammerBesselIBesselJBesselKBesselYHankelH1HankelH2AiryAiAiryBiAppellF1FresnelCFresnelSLerchPhi)AbslogasinacosatanasecacscacotasinhacoshatanhasechacschacothceilingMaxMin factorial2RisingFactorialbesselibesseljbesselkbesselyhankelh1hankelh2airyaiairybiappellf1fresnelcfresnelslerchphiPizexp(1)Catalangammaz(1/2 + (1/2)*sqrt(5))=z<>)z==z!=cseZdZdZdZdZddddddZdCfdd Zd d Zd d Z ddZ ddZ ddZ ddZ ddZddZddZddZddZd d!Zd"d#Zd$d%Zd&d'Zd(d)Zd*d+Zd,d-Zd.d/ZdDd1d2Zd3d4Zd5d6Zd7d8Zd9d:Zd;d<Z d=d>Z!d?d@Z"dAdBZ#Z$S)EMapleCodePrinterzF Printer which converts a SymPy expression into a maple code. Z_maplemapleNautoT)order full_prechumaninlineallow_unknown_functionscs>|dur i}t|tt|_|di}|j|dS)Nuser_functions)super__init__dictknown_functionsgetupdate)selfsettings userfuncs __class__P/var/www/html/django/DPS/env/lib/python3.9/site-packages/sympy/printing/maple.pyrscs    zMapleCodePrinter.__init__cCsd|S)Nz%s;r})rx codestringr}r}r~_get_statementkszMapleCodePrinter._get_statementcCs d|S)Nz# {})format)rxtextr}r}r~ _get_commentnszMapleCodePrinter._get_commentcCsd|||jdS)Nz {} := {}; precision)revalf _settings)rxnamevaluer}r}r~_declare_number_constqsz&MapleCodePrinter._declare_number_constcCs|SNr})rxlinesr}r}r~ _format_codeuszMapleCodePrinter._format_codecCs|t|Sr_printlistrxexprr}r}r~ _print_tuplexszMapleCodePrinter._print_tuplecCs|t|Srrrr}r}r~ _print_Tuple{szMapleCodePrinter._print_TuplecCs&||j}||j}dj||dS)Nz{lhs} := {rhs})lhsrhs)rrrr)rxrrrr}r}r~_print_Assignment~s  z"MapleCodePrinter._print_AssignmentcKst|}|jdkr$d||j|S|jdtjfvrDd||jS|jdtj fvrfd||jSdj||j|||j|dSdS) Nz1/%sg?zsqrt(%s)gz 1/sqrt(%s)z {base}^{exp})baser)rr parenthesizerrHalfrr)rxrkwargsPRECr}r}r~ _print_Pows   zMapleCodePrinter._print_PowcsT|jdjdur*|jdjtjkr*tdfdd|jD}d|}dj|dS) NrTzAll Piecewise expressions must contain an (expr, True) statement to be used as a default condition. Without one, the generated expression may not evaluate to anything under some condition.csNg|]F\}}|dur8|tjur8dj||dndj|dqS)Tz{c}, {e})cez{e})r)r BooleanTruerr).0rrrxr}r~ sz5MapleCodePrinter._print_Piecewise..z, zpiecewise({_inbrace}))_inbrace)argscondrr ValueErrorjoinr)rxrZ _coup_listrr}rr~_print_Piecewises"  z!MapleCodePrinter._print_PiecewisecCs,t|jt|j}}djt|t|dS)Nz{p}/{q})pq)intrrrstr)rxrrrr}r}r~_print_Rationalsz MapleCodePrinter._print_RationalcCsJt|}||j|}||j|}|j}|tvr:t|}dj|||dS)Nz{lhs} {rel_op} {rhs})rrel_opr)rrrrrspec_relational_opsr)rxrrlhs_coderhs_codeopr}r}r~_print_Relationalsz"MapleCodePrinter._print_RelationalcCst|Sr)number_symbolsrr}r}r~_print_NumberSymbolsz$MapleCodePrinter._print_NumberSymbolcCsdS)Nz -infinityr}rr}r}r~_print_NegativeInfinitysz(MapleCodePrinter._print_NegativeInfinitycCsdS)Ninfinityr}rr}r}r~_print_Infinitysz MapleCodePrinter._print_InfinitycCs ||jSr)rlabelrr}r}r~ _print_IdxszMapleCodePrinter._print_IdxcCsdS)Ntruer}rr}r}r~_print_BooleanTruesz#MapleCodePrinter._print_BooleanTruecCsdS)Nfalser}rr}r}r~_print_BooleanFalsesz$MapleCodePrinter._print_BooleanFalsecCs |rdSdS)Nrrr}rr}r}r~ _print_boolszMapleCodePrinter._print_boolcCsdS)N undefinedr}rr}r}r~ _print_NaNszMapleCodePrinter._print_NaNFcCsFtj|jvr"dj|rdndd}n dj|||r:dndd}|S)NzMatrix([], storage = {storage})sparseZ rectangular)storagez#Matrix({list}, storage = {storage}))rr)rZeroshaperrtolist)rxrrZ_strMr}r}r~ _get_matrixs    zMapleCodePrinter._get_matrixcCs:dj|j|jtddd||jd||jddS)Nz{parent}[{i_maple}, {j_maple}]AtomT)strict)parentZi_mapleZj_maple)rrrrrijrr}r}r~_print_MatrixElements z%MapleCodePrinter._print_MatrixElementcCs|j|ddS)NFrrrr}r}r~_print_MatrixBasesz"MapleCodePrinter._print_MatrixBasecCs|j|ddS)NTrrrr}r}r~_print_SparseRepMatrixsz'MapleCodePrinter._print_SparseRepMatrixcCs8t|jttfr |t|Sdj||jdSdS)Nz$Matrix({var_size}, shape = identity))Zvar_size) isinstancerowsrrrsympy SparseMatrixrrr}r}r~_print_Identitysz MapleCodePrinter._print_Identitycst|t|j}d}t|dtjtjtjtjfsJ|d|dd}}|dusZ|dkrtd fdd|DSdj |d fdd|DdSdS) Nrr.c3s|]}|VqdSrrr_mrrxr}r~ z1MapleCodePrinter._print_MatMul..z{c}*{m}c3s|]}|VqdSrrrrr}r~rr)rm) rrrrr MatrixBase MatrixExpr MatrixSlice MatrixSymbolrr)rxr _fact_listZ_constr}rr~ _print_MatMuls zMapleCodePrinter._print_MatMulcCsdj||j||jdS)NzMatrixPower({A}, {n}))An)rrrrrr}r}r~ _print_MatPowszMapleCodePrinter._print_MatPowcs,t|t|j}dfdd|DS)N*c3s|]}|VqdSrrrrr}r~rrz:MapleCodePrinter._print_HadamardProduct..)rrrr)rxrrr}rr~_print_HadamardProducts z'MapleCodePrinter._print_HadamardProductcCsX|j\}\}}|dkr2dj||||d}ndj||d}dj|||dS)Nrz {var}${order})varrlz{var})rzdiff({func_expr}, {sec_arg}))Z func_exprZsec_arg)rrr)rxr_f_var_orderZ _second_argr}r}r~_print_Derivatives z"MapleCodePrinter._print_Derivative)N)F)%__name__ __module__ __qualname____doc__ printmethodlanguage_default_settingsrsrrrrrrrrrrrrrrrrrrrrrrrrrrrr __classcell__r}r}r{r~riTsL    ricKst|||S)aUConverts ``expr`` to a string of Maple code. Parameters ========== expr : Expr A SymPy expression to be converted. assign_to : optional When given, the argument is used as the name of the variable to which the expression is assigned. Can be a string, ``Symbol``, ``MatrixSymbol``, or ``Indexed`` type. This can be helpful for expressions that generate multi-line statements. precision : integer, optional The precision for numbers such as pi [default=16]. user_functions : dict, optional A dictionary where keys are ``FunctionClass`` instances and values are their string representations. Alternatively, the dictionary value can be a list of tuples i.e. [(argument_test, cfunction_string)]. See below for examples. human : bool, optional If True, the result is a single string that may contain some constant declarations for the number symbols. If False, the same information is returned in a tuple of (symbols_to_declare, not_supported_functions, code_text). [default=True]. contract: bool, optional If True, ``Indexed`` instances are assumed to obey tensor contraction rules and the corresponding nested loops over indices are generated. Setting contract=False will not generate loops, instead the user is responsible to provide values for the indices in the code. [default=True]. inline: bool, optional If True, we try to create single-statement code instead of multiple statements. [default=True]. )ridoprint)r assign_toryr}r}r~ maple_codes$rcKstt|fi|dS)a&Prints the Maple representation of the given expression. See :func:`maple_code` for the meaning of the optional arguments. Examples ======== >>> from sympy import print_maple_code, symbols >>> x, y = symbols('x y') >>> print_maple_code(x, assign_to=y) y := x N)printr)rryr}r}r~print_maple_code*s r)N)r sympy.corersympy.core.numbersrrZsympy.printing.codeprinterrsympy.printing.precedencerrrZ_known_func_same_nameru_funcreExp1rf EulerGamma GoldenRatiorrComplexInfinityZnot_supported_symbolrirrr}r}r}r~sn   $  0 '