* functions. */
/*
- * GiNaC Copyright (C) 1999-2001 Johannes Gutenberg University Mainz, Germany
+ * GiNaC Copyright (C) 1999-2020 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
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
- * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
-#include "exams.h"
+#include "ginac.h"
+using namespace GiNaC;
+
+#include <iostream>
+using namespace std;
/* Assorted tests on other transcendental functions. */
-static unsigned inifcns_consist_trans(void)
+static unsigned inifcns_consist_trans()
{
+ using GiNaC::asin; using GiNaC::acos;
+ using GiNaC::asinh; using GiNaC::acosh; using GiNaC::atanh;
+
unsigned result = 0;
symbol x("x");
ex chk;
/* Simple tests on the tgamma function. We stuff in arguments where the results
* exists in closed form and check if it's ok. */
-static unsigned inifcns_consist_gamma(void)
+static unsigned inifcns_consist_gamma()
{
+ using GiNaC::tgamma;
unsigned result = 0;
ex e;
/* Simple tests on the Psi-function (aka polygamma-function). We stuff in
arguments where the result exists in closed form and check if it's ok. */
-static unsigned inifcns_consist_psi(void)
+static unsigned inifcns_consist_psi()
{
+ using GiNaC::log;
+ using GiNaC::tgamma;
+
unsigned result = 0;
symbol x;
ex e, f;
/* Simple tests on the Riemann Zeta function. We stuff in arguments where the
* result exists in closed form and check if it's ok. Of course, this checks
* the Bernoulli numbers as a side effect. */
-static unsigned inifcns_consist_zeta(void)
+static unsigned inifcns_consist_zeta()
{
unsigned result = 0;
ex e;
return result;
}
-unsigned exam_inifcns(void)
+static unsigned inifcns_consist_abs()
+{
+ unsigned result = 0;
+ realsymbol a("a"), b("b"), x("x"), y("y");
+ possymbol p("p");
+ symbol z("z");
+
+ if (!abs(exp(x+I*y)).eval().is_equal(exp(x)))
+ ++result;
+
+ if (!abs(pow(p,a+I*b)).eval().is_equal(pow(p,a)))
+ ++result;
+
+ if (!abs(sqrt(p)).eval().is_equal(sqrt(p)))
+ ++result;
+
+ if (!abs(-sqrt(p)).eval().is_equal(sqrt(p)))
+ ++result;
+
+ // also checks that abs(p)=p
+ if (!abs(pow(p,a+I*b)).eval().is_equal(pow(p,a)))
+ ++result;
+
+ if (!abs(pow(x+I*y,a)).eval().is_equal(pow(abs(x+I*y),a)))
+ ++result;
+
+ // it is not necessary a simplification if the following is really evaluated
+ if (!abs(pow(x+I*y,a+I*b)).eval().is_equal(abs(pow(x+I*y,a+I*b))))
+ ++result;
+
+ // check expansion of abs
+ if (!abs(-7*z*a*p).expand(expand_options::expand_transcendental).is_equal(7*abs(z)*abs(a)*p))
+ ++result;
+
+ if (!abs(z.conjugate()).eval().is_equal(abs(z)))
+ ++result;
+
+ if (!abs(step(z)).eval().is_equal(step(z)))
+ ++result;
+
+ if (!abs(p).info(info_flags::positive) || !abs(a).info(info_flags::real))
+ ++result;
+
+ if (abs(a).info(info_flags::positive) || !abs(a).info(info_flags::real))
+ ++result;
+
+ if (abs(z).info(info_flags::positive) || !abs(z).info(info_flags::real))
+ ++result;
+
+ return result;
+}
+
+static unsigned inifcns_consist_exp()
+{
+ unsigned result = 0;
+ symbol a("a"), b("b");
+
+ if (!exp(a+b).expand(expand_options::expand_transcendental).is_equal(exp(a)*exp(b)))
+ ++result;
+
+ // shall not be expanded since the arg is not add
+ if (!exp(pow(a+b,2)).expand(expand_options::expand_transcendental).is_equal(exp(pow(a+b,2))))
+ ++result;
+
+ // expand now
+ if (!exp(pow(a+b,2)).expand(expand_options::expand_function_args | expand_options::expand_transcendental)
+ .is_equal(exp(a*a)*exp(b*b)*exp(2*a*b)))
+ ++result;
+
+ return result;
+}
+
+static unsigned inifcns_consist_log()
+{
+ using GiNaC::log;
+ unsigned result = 0;
+ symbol z("a"), w("b");
+ realsymbol a("a"), b("b");
+ possymbol p("p"), q("q");
+
+ // do not expand
+ if (!log(z*w).expand(expand_options::expand_transcendental).is_equal(log(z*w)))
+ ++result;
+
+ // do not expand
+ if (!log(a*b).expand(expand_options::expand_transcendental).is_equal(log(a*b)))
+ ++result;
+
+ // shall expand
+ if (!log(p*q).expand(expand_options::expand_transcendental).is_equal(log(p) + log(q)))
+ ++result;
+
+ // a bit more complicated
+ ex e1 = log(-7*p*pow(q,3)*a*pow(b,2)*z*w).expand(expand_options::expand_transcendental);
+ ex e2 = log(7)+log(p)+log(pow(q,3))+log(-z*a*w*pow(b,2));
+ if (!e1.is_equal(e2))
+ ++result;
+
+ // shall not do for non-real powers
+ if (ex(log(pow(p,z))).is_equal(z*log(p)))
+ ++result;
+
+ // shall not do for non-positive basis
+ if (ex(log(pow(a,b))).is_equal(b*log(a)))
+ ++result;
+
+ // infinite recursion log_series
+ ex e(log(-p));
+ ex ser = ex_to<pseries>(e.series(z, 1))
+ .convert_to_poly(/* no_order = */ true);
+ if (!ser.is_equal(e)) {
+ clog << "series(" << e << ", " << z << "): wrong result" << endl;
+ ++result;
+ }
+
+ return result;
+}
+
+static unsigned inifcns_consist_various()
+{
+ unsigned result = 0;
+ symbol n;
+
+ if ( binomial(n, 0) != 1 ) {
+ clog << "ERROR: binomial(n,0) != 1" << endl;
+ ++result;
+ }
+
+ return result;
+}
+
+/* Several tests for derivatives */
+static unsigned inifcns_consist_derivatives()
+{
+ unsigned result = 0;
+ symbol z, w;
+ realsymbol x;
+ ex e, e1;
+
+ e=pow(x,z).conjugate().diff(x);
+ e1=pow(x,z).conjugate()*z.conjugate()/x;
+ if (! (e-e1).normal().is_zero() ) {
+ clog << "ERROR: pow(x,z).conjugate().diff(x) " << e << " != " << e1 << endl;
+ ++result;
+ }
+
+ e=pow(w,z).conjugate().diff(w);
+ e1=pow(w,z).conjugate()*z.conjugate()/w;
+ if ( (e-e1).normal().is_zero() ) {
+ clog << "ERROR: pow(w,z).conjugate().diff(w) " << e << " = " << e1 << endl;
+ ++result;
+ }
+
+ e=atanh(x).imag_part().diff(x);
+ if (! e.is_zero() ) {
+ clog << "ERROR: atanh(x).imag_part().diff(x) " << e << " != 0" << endl;
+ ++result;
+ }
+
+ e=atanh(w).imag_part().diff(w);
+ if ( e.is_zero() ) {
+ clog << "ERROR: atanh(w).imag_part().diff(w) " << e << " = 0" << endl;
+ ++result;
+ }
+
+ e=atanh(x).real_part().diff(x);
+ e1=pow(1-x*x,-1);
+ if (! (e-e1).normal().is_zero() ) {
+ clog << "ERROR: atanh(x).real_part().diff(x) " << e << " != " << e1 << endl;
+ ++result;
+ }
+
+ e=atanh(w).real_part().diff(w);
+ e1=pow(1-w*w,-1);
+ if ( (e-e1).normal().is_zero() ) {
+ clog << "ERROR: atanh(w).real_part().diff(w) " << e << " = " << e1 << endl;
+ ++result;
+ }
+
+ e=abs(log(z)).diff(z);
+ e1=(conjugate(log(z))/z+log(z)/conjugate(z))/abs(log(z))/2;
+ if (! (e-e1).normal().is_zero() ) {
+ clog << "ERROR: abs(log(z)).diff(z) " << e << " != " << e1 << endl;
+ ++result;
+ }
+
+ e=Order(pow(x,4)).diff(x);
+ e1=Order(pow(x,3));
+ if (! (e-e1).normal().is_zero() ) {
+ clog << "ERROR: Order(pow(x,4)).diff(x) " << e << " != " << e1 << endl;
+ ++result;
+ }
+
+ return result;
+}
+
+unsigned exam_inifcns()
{
unsigned result = 0;
cout << "examining consistency of symbolic functions" << flush;
- clog << "----------consistency of symbolic functions:" << endl;
result += inifcns_consist_trans(); cout << '.' << flush;
result += inifcns_consist_gamma(); cout << '.' << flush;
result += inifcns_consist_psi(); cout << '.' << flush;
result += inifcns_consist_zeta(); cout << '.' << flush;
-
- if (!result) {
- cout << " passed " << endl;
- clog << "(no output)" << endl;
- } else {
- cout << " failed " << endl;
- }
+ result += inifcns_consist_abs(); cout << '.' << flush;
+ result += inifcns_consist_exp(); cout << '.' << flush;
+ result += inifcns_consist_log(); cout << '.' << flush;
+ result += inifcns_consist_various(); cout << '.' << flush;
+ result += inifcns_consist_derivatives(); cout << '.' << flush;
return result;
}
+
+int main(int argc, char** argv)
+{
+ return exam_inifcns();
+}