+
+ // Perform contractions
+ bool something_changed = false;
+ GINAC_ASSERT(v.size() > 1);
+ exvector::iterator it1, itend = v.end(), next_to_last = itend - 1;
+ for (it1 = v.begin(); it1 != next_to_last; it1++) {
+
+try_again:
+ if (!is_a<indexed>(*it1))
+ continue;
+
+ bool first_noncommutative = (it1->return_type() != return_types::commutative);
+
+ // Indexed factor found, get free indices and look for contraction
+ // candidates
+ exvector free1, dummy1;
+ find_free_and_dummy(ex_to<indexed>(*it1).seq.begin() + 1, ex_to<indexed>(*it1).seq.end(), free1, dummy1);
+
+ exvector::iterator it2;
+ for (it2 = it1 + 1; it2 != itend; it2++) {
+
+ if (!is_a<indexed>(*it2))
+ continue;
+
+ bool second_noncommutative = (it2->return_type() != return_types::commutative);
+
+ // Find free indices of second factor and merge them with free
+ // indices of first factor
+ exvector un;
+ find_free_and_dummy(ex_to<indexed>(*it2).seq.begin() + 1, ex_to<indexed>(*it2).seq.end(), un, dummy1);
+ un.insert(un.end(), free1.begin(), free1.end());
+
+ // Check whether the two factors share dummy indices
+ exvector free, dummy;
+ find_free_and_dummy(un, free, dummy);
+ size_t num_dummies = dummy.size();
+ if (num_dummies == 0)
+ continue;
+
+ // At least one dummy index, is it a defined scalar product?
+ bool contracted = false;
+ if (free.empty()) {
+
+ // Find minimal dimension of all indices of both factors
+ exvector::const_iterator dit = ex_to<indexed>(*it1).seq.begin() + 1, ditend = ex_to<indexed>(*it1).seq.end();
+ ex dim = ex_to<idx>(*dit).get_dim();
+ ++dit;
+ for (; dit != ditend; ++dit) {
+ dim = minimal_dim(dim, ex_to<idx>(*dit).get_dim());
+ }
+ dit = ex_to<indexed>(*it2).seq.begin() + 1;
+ ditend = ex_to<indexed>(*it2).seq.end();
+ for (; dit != ditend; ++dit) {
+ dim = minimal_dim(dim, ex_to<idx>(*dit).get_dim());
+ }
+
+ // User-defined scalar product?
+ if (sp.is_defined(*it1, *it2, dim)) {
+
+ // Yes, substitute it
+ *it1 = sp.evaluate(*it1, *it2, dim);
+ *it2 = _ex1;
+ goto contraction_done;
+ }
+ }
+
+ // Try to contract the first one with the second one
+ contracted = ex_to<basic>(it1->op(0)).contract_with(it1, it2, v);
+ if (!contracted) {
+
+ // That didn't work; maybe the second object knows how to
+ // contract itself with the first one
+ contracted = ex_to<basic>(it2->op(0)).contract_with(it2, it1, v);
+ }
+ if (contracted) {
+contraction_done:
+ if (first_noncommutative || second_noncommutative
+ || is_exactly_a<add>(*it1) || is_exactly_a<add>(*it2)
+ || is_exactly_a<mul>(*it1) || is_exactly_a<mul>(*it2)
+ || is_exactly_a<ncmul>(*it1) || is_exactly_a<ncmul>(*it2)) {
+
+ // One of the factors became a sum or product:
+ // re-expand expression and run again
+ // Non-commutative products are always re-expanded to give
+ // eval_ncmul() the chance to re-order and canonicalize
+ // the product
+ ex r = (non_commutative ? ex(ncmul(v, true)) : ex(mul(v)));
+ return simplify_indexed(r, free_indices, dummy_indices, sp);
+ }
+
+ // Both objects may have new indices now or they might
+ // even not be indexed objects any more, so we have to
+ // start over
+ something_changed = true;
+ goto try_again;
+ }
+ }
+ }
+
+ // Find free indices (concatenate them all and call find_free_and_dummy())
+ // and all dummy indices that appear
+ exvector un, individual_dummy_indices;
+ for (it1 = v.begin(), itend = v.end(); it1 != itend; ++it1) {
+ exvector free_indices_of_factor;
+ if (is_a<indexed>(*it1)) {
+ exvector dummy_indices_of_factor;
+ find_free_and_dummy(ex_to<indexed>(*it1).seq.begin() + 1, ex_to<indexed>(*it1).seq.end(), free_indices_of_factor, dummy_indices_of_factor);
+ individual_dummy_indices.insert(individual_dummy_indices.end(), dummy_indices_of_factor.begin(), dummy_indices_of_factor.end());
+ } else
+ free_indices_of_factor = it1->get_free_indices();
+ un.insert(un.end(), free_indices_of_factor.begin(), free_indices_of_factor.end());
+ }
+ exvector local_dummy_indices;
+ find_free_and_dummy(un, free_indices, local_dummy_indices);
+ local_dummy_indices.insert(local_dummy_indices.end(), individual_dummy_indices.begin(), individual_dummy_indices.end());
+
+ // Filter out the dummy indices with variance
+ exvector variant_dummy_indices;
+ find_variant_indices(local_dummy_indices, variant_dummy_indices);
+
+ // Any indices with variance present at all?
+ if (!variant_dummy_indices.empty()) {
+
+ // Yes, bring the product into a canonical order that only depends on
+ // the base expressions of indexed objects
+ if (!non_commutative)
+ std::sort(v.begin(), v.end(), ex_base_is_less());
+
+ exvector moved_indices;
+
+ // Iterate over all indexed objects in the product
+ for (it1 = v.begin(), itend = v.end(); it1 != itend; ++it1) {
+ if (!is_a<indexed>(*it1))
+ continue;
+
+ if (reposition_dummy_indices(*it1, variant_dummy_indices, moved_indices))
+ something_changed = true;
+ }
+ }
+
+ ex r;
+ if (something_changed)
+ r = non_commutative ? ex(ncmul(v, true)) : ex(mul(v));
+ else
+ r = e;
+
+ // The result should be symmetric with respect to exchange of dummy
+ // indices, so if the symmetrization vanishes, the whole expression is
+ // zero. This detects things like eps.i.j.k * p.j * p.k = 0.
+ if (local_dummy_indices.size() >= 2) {
+ exvector dummy_syms;
+ dummy_syms.reserve(local_dummy_indices.size());
+ for (exvector::const_iterator it = local_dummy_indices.begin(); it != local_dummy_indices.end(); ++it)
+ dummy_syms.push_back(it->op(0));
+ if (symmetrize(r, dummy_syms).is_zero()) {
+ free_indices.clear();
+ return _ex0;
+ }
+ }
+
+ // Dummy index renaming
+ r = rename_dummy_indices(r, dummy_indices, local_dummy_indices);
+
+ // Product of indexed object with a scalar?
+ if (is_exactly_a<mul>(r) && r.nops() == 2
+ && is_exactly_a<numeric>(r.op(1)) && is_a<indexed>(r.op(0)))
+ return ex_to<basic>(r.op(0).op(0)).scalar_mul_indexed(r.op(0), ex_to<numeric>(r.op(1)));
+ else
+ return r;