*/
/*
- * GiNaC Copyright (C) 1999-2001 Johannes Gutenberg University Mainz, Germany
+ * GiNaC Copyright (C) 1999-2018 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 "times.h"
-#include <utility>
-#include <vector>
-#include <set>
+#include "ginac.h"
+#include "timer.h"
+using namespace GiNaC;
+
#include <map>
-#include <typeinfo>
+#include <set>
#include <stdexcept>
+#include <typeinfo>
+#include <utility>
+#include <vector>
+using namespace std;
// whether to run this beast or not:
-static const bool do_test = true;
+constexpr bool do_test = true;
// regularization parameter:
static const symbol x("x");
/* F_ab(a, i, b, j, "x") is a common pattern in all vertex evaluators. */
static ex F_ab(int a, int i, int b, int j, const symbol &x)
{
+ using GiNaC::tgamma;
if ((i==0 && a<=0) || (j==0 && b<=0))
return 0;
else
vertex(ijpair ij = ijpair(0,0)) : indices(ij) { }
void increment_indices(const ijpair &ind) { indices.first += ind.first; indices.second += ind.second; }
virtual ~vertex() { }
- virtual vertex* copy(void) const = 0;
- virtual ijpair get_increment(void) const { return indices; }
+ virtual vertex* copy() const = 0;
+ virtual ijpair get_increment() const { return indices; }
virtual const ex evaluate(const symbol &x, const unsigned grad) const = 0;
bool operator==(const vertex &v) const { return (indices==v.indices); }
bool operator<(const vertex &v) const { return (indices<v.indices); }
class Sigma : public vertex {
public:
Sigma(ijpair ij = ijpair(0,0)) : vertex(ij) { }
- vertex* copy(void) const { return new Sigma(*this); }
- ijpair get_increment(void) const { return ijpair(indices.first+indices.second+1, 0); }
- const ex evaluate(const symbol &x, const unsigned grad) const;
+ vertex* copy() const override { return new Sigma(*this); }
+ ijpair get_increment() const override { return ijpair(indices.first+indices.second+1, 0); }
+ const ex evaluate(const symbol &x, const unsigned grad) const override;
private:
};
}
-/** Class of vertices of type Sigma_flipped, sitting in the upper fermionline of Vacuum; no consequences for Gamma. */
+/** Class of vertices of type Sigma_flipped, sitting in the upper fermion line of Vacuum; no consequences for Gamma. */
class Sigma_flipped : public Sigma {
public:
Sigma_flipped(ijpair ij = ijpair(0,0)) : Sigma(ij) { }
- vertex* copy(void) const { return new Sigma_flipped(*this); }
- ijpair get_increment(void) const { return ijpair(0, indices.first+indices.second+1); }
- const ex evaluate(const symbol &x, const unsigned grad) const { return Sigma::evaluate(x, grad); }
+ vertex* copy() const override { return new Sigma_flipped(*this); }
+ ijpair get_increment() const override { return ijpair(0, indices.first+indices.second+1); }
+ const ex evaluate(const symbol &x, const unsigned grad) const override { return Sigma::evaluate(x, grad); }
private:
};
class Gamma : public vertex {
public:
Gamma(ijpair ij = ijpair(0,0)) : vertex(ij) { }
- vertex* copy(void) const { return new Gamma(*this); }
- ijpair get_increment(void) const { return ijpair(indices.first+indices.second+1, 0); }
- const ex evaluate(const symbol &x, const unsigned grad) const;
+ vertex* copy() const override { return new Gamma(*this); }
+ ijpair get_increment() const override { return ijpair(indices.first+indices.second+1, 0); }
+ const ex evaluate(const symbol &x, const unsigned grad) const override;
private:
};
class Vacuum : public vertex {
public:
Vacuum(ijpair ij = ijpair(0,0)) : vertex(ij) { }
- vertex* copy(void) const { return new Vacuum(*this); }
- ijpair get_increment() const { return ijpair(0, indices.first+indices.second+1); }
- const ex evaluate(const symbol &x, const unsigned grad) const;
+ vertex* copy() const override { return new Vacuum(*this); }
+ ijpair get_increment() const override { return ijpair(0, indices.first+indices.second+1); }
+ const ex evaluate(const symbol &x, const unsigned grad) const override;
private:
};
~node() { delete vert; }
void add_child(const node &, bool = false);
const ex evaluate(const symbol &x, unsigned grad) const;
- unsigned total_edges(void) const;
+ unsigned total_edges() const;
bool operator==(const node &) const;
bool operator<(const node &) const;
private:
return (product * vert->evaluate(x,grad));
}
-unsigned node::total_edges(void) const
+unsigned node::total_edges() const
{
unsigned accu = 0;
for (multiset<child>::const_iterator i=children.begin(); i!=children.end(); ++i) {
bool(cuts & 16)));
}
-static unsigned test_tree(const node (*tree_generator)(unsigned=0))
+static unsigned test_tree(const node tree_generator(unsigned))
{
- const int edges = tree_generator().total_edges();
- const int vertices = edges+1;
+ const int edges = tree_generator(0).total_edges();
+ const int vertices = edges+1;
// fill a vector of all possible 2^edges combinations of cuts...
vector<node> counter;
// ...the sum, when evaluated and reexpanded, is the antipode...
ex result = 0;
for (vector<node>::iterator i=counter.begin(); i!=counter.end(); ++i)
- result = (result+i->evaluate(x,vertices)).series(x==0,vertices).expand();
+ result = (result+i->evaluate(x,vertices-1)).series(x==0,vertices-1).expand();
// ...and has the nice property that in each term all the Eulers cancel:
if (result.has(Euler)) {
return 0;
}
-unsigned time_antipode(void)
+unsigned time_antipode()
{
unsigned result = 0;
timer jaeger_le_coultre;
cout << "timing computation of antipodes in Yukawa theory" << flush;
- clog << "-------computation of antipodes in Yukawa theory" << endl;
if (do_test) {
jaeger_le_coultre.start();
result += test_tree(tree5); cout << '.' << flush;
result += test_tree(tree6); cout << '.' << flush;
- if (!result) {
- cout << " passed ";
- clog << "(no output)" << endl;
- } else {
- cout << " failed ";
- }
- cout << int(1000*jaeger_le_coultre.read())*0.001 << "s (total)" << endl;
+ cout << jaeger_le_coultre.read() << "s (total)" << endl;
} else {
cout << " disabled" << endl;
- clog << "(no output)" << endl;
}
-
return result;
}
+
+extern void randomify_symbol_serials();
+
+int main(int argc, char** argv)
+{
+ randomify_symbol_serials();
+ cout << setprecision(2) << showpoint;
+ return time_antipode();
+}