X-Git-Url: https://www.ginac.de/ginac.git//ginac.git?p=ginac.git;a=blobdiff_plain;f=check%2Fexam_inifcns_nstdsums.cpp;h=8434fd1e699d28cd3cd1d69506f03b037bd5ddca;hp=df8a4193354c02426e5529b3ec5df23997456340;hb=8ce440866e23bd6e534131b117fd6ec34484e5e5;hpb=2478df378bbdbae452288eb3aa16928e168b7fc2 diff --git a/check/exam_inifcns_nstdsums.cpp b/check/exam_inifcns_nstdsums.cpp index df8a4193..8434fd1e 100644 --- a/check/exam_inifcns_nstdsums.cpp +++ b/check/exam_inifcns_nstdsums.cpp @@ -4,7 +4,7 @@ * functions. */ /* - * GiNaC Copyright (C) 1999-2003 Johannes Gutenberg University Mainz, Germany + * GiNaC Copyright (C) 1999-2004 Johannes Gutenberg University Mainz, Germany * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by @@ -155,6 +155,14 @@ static unsigned inifcns_test_HLi() Digits = digitsbuf; + // conjugate test + numeric cdif = ex_to(H(lst(2,2,1),5.0-5.0*I) - H(lst(2,2,1),5.0+5.0*I)); + numeric cadd = ex_to(H(lst(2,2,1),5.0-5.0*I) + H(lst(2,2,1),5.0+5.0*I)); + if ((cdif.real() > prec) || (cadd.imag() > prec)) { + clog << "complex conjugation test of H({2,2,1},5.0-5.0*I) seems to be wrong: " << cdif << " " << cadd << endl; + result++; + } + return result; } @@ -212,6 +220,73 @@ static unsigned inifcns_test_zeta() } +//////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// +// H/Li exam +//////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// + + +static unsigned inifcns_test_LiG() +{ + int digitsbuf = Digits; + Digits = 17; + ex prec = 5 * pow(10, -(int)Digits); + numeric almostone("0.99999999999999999999"); + unsigned result = 0; + + lst res; + + res.append(Li(lst(4), lst(6)).hold() - Li(4, 6.0)); + res.append(G(lst(0,0,5.0,0,2.0,0,0,0,3.0),0.5).hold() + + Li(lst(3,2,4), lst(numeric(1,10), numeric(5,2), numeric(2,3)))); + res.append(Li(lst(2,1,1), lst(almostone, almostone, almostone)) - zeta(lst(2,1,1))); + + // check Li_{1,1} against known expression + symbol x("x"), y("y"); + ex eps = 1e-30*I; + ex s1 = Li(lst(1,1),lst(x,y)); + ex s2 = log(1-1/x/y-eps)*log((1-1/x-eps)/(1/x/y-1/x)) + Li(2,(1-1/x/y-eps)/(1/x-1/x/y)) + - log(-1/x/y-eps)*log((-1/x-eps)/(1/x/y-1/x)) - Li(2,(-1/x/y-eps)/(1/x-1/x/y)) + - log(-1/x/y-eps)*log(1-1/x-eps) + log(-1/x/y-eps)*log(-1/x-eps); + res.append(s1.subs(lst(x==numeric(1)/2, y==3)) - s2.subs(lst(x==numeric(1)/2, y==3))); + res.append(s1.subs(lst(x==numeric(3)/2, y==numeric(1)/2)) - s2.subs(lst(x==numeric(3)/2, y==numeric(1)/2))); + res.append(s1.subs(lst(x==2, y==numeric(4)/5)) - s2.subs(lst(x==2, y==numeric(4)/5))); + + // shuffle and quasi-shuffle identities + res.append(G(lst(0,0.2),1).hold() * G(lst(0.5),1).hold() - G(lst(0.5,0,0.2),1).hold() + - G(lst(0,0.5,0.2),1).hold() - G(lst(0,0.2,0.5),1).hold()); + res.append(G(lst(0,0.5),1).hold() * G(lst(0.6),1).hold() - G(lst(0,0.5,0.5*0.6),1).hold() + - G(lst(0.6,0,0.5*0.6),1).hold() + G(lst(0,0,0.5*0.6),1).hold()); + res.append(Li(lst(2),lst(numeric(1,5))).hold() * Li(lst(3),lst(7)).hold() - Li(lst(2,3),lst(numeric(1,5),7)).hold() + - Li(lst(3,2),lst(7,numeric(1,5))).hold() - Li(lst(5),lst(numeric(7,5))).hold()); + symbol a1, a2, a3, a4; + res.append((G(lst(a1,a2),1) * G(lst(a3,a4),1) - G(lst(a1,a2,a3,a4),1) + - G(lst(a1,a3,a2,a4),1) - G(lst(a3,a1,a2,a4),1) + - G(lst(a1,a3,a4,a2),1) - G(lst(a3,a1,a4,a2),1) - G(lst(a3,a4,a1,a2),1)) + .subs(lst(a1==numeric(1)/10, a2==numeric(3)/10, a3==numeric(7)/10, a4==5))); + res.append(G(lst(-0.009),1).hold() * G(lst(-8,1.4999),1).hold() - G(lst(-0.009,-8,1.4999),1).hold() + - G(lst(-8,-0.009,1.4999),1).hold() - G(lst(-8,1.4999,-0.009),1).hold()); + res.append(G(lst(sqrt(numeric(1)/2)+I*sqrt(numeric(1)/2)),1).hold() * G(lst(1.51,-0.999),1).hold() + - G(lst(sqrt(numeric(1)/2)+I*sqrt(numeric(1)/2),1.51,-0.999),1).hold() + - G(lst(1.51,sqrt(numeric(1)/2)+I*sqrt(numeric(1)/2),-0.999),1).hold() + - G(lst(1.51,-0.999,sqrt(numeric(1)/2)+I*sqrt(numeric(1)/2)),1).hold()); + // checks for hoelder convolution which is used if one argument has a distance to one smaller than 0.01 + res.append(G(lst(0, 1.2, 1, 1.01), 1).hold() - G(lst(0, 1.2, 1, numeric("1.009999999999999999")), 1).hold()); + + for (lst::const_iterator it = res.begin(); it != res.end(); it++) { + ex diff = abs((*it).evalf()); + if (diff > prec) { + clog << *it << " seems to be wrong: " << diff << endl; + result++; + } + cout << "." << flush; + } + + return result; +} + + unsigned exam_inifcns_nstdsums(void) { unsigned result = 0; @@ -219,12 +294,10 @@ unsigned exam_inifcns_nstdsums(void) cout << "examining consistency of nestedsums functions" << flush; clog << "----------consistency of nestedsums functions:" << endl; - cout << "zeta" << flush; result += inifcns_test_zeta(); - cout << "S" << flush; result += inifcns_test_S(); - cout << "H/Li" << flush; result += inifcns_test_HLi(); + result += inifcns_test_LiG(); if (!result) { cout << " passed " << endl;