* Implementation of GiNaC's indexed expressions. */
/*
- * GiNaC Copyright (C) 1999-2001 Johannes Gutenberg University Mainz, Germany
+ * GiNaC Copyright (C) 1999-2002 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
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
+#include <iostream>
#include <stdexcept>
-#include <algorithm>
#include "indexed.h"
#include "idx.h"
#include "mul.h"
#include "ncmul.h"
#include "power.h"
+#include "symmetry.h"
+#include "operators.h"
#include "lst.h"
-#include "inifcns.h"
#include "print.h"
#include "archive.h"
#include "utils.h"
-#include "debugmsg.h"
namespace GiNaC {
GINAC_IMPLEMENT_REGISTERED_CLASS(indexed, exprseq)
//////////
-// default constructor, destructor, copy constructor assignment operator and helpers
+// default ctor, dtor, copy ctor, assignment operator and helpers
//////////
-indexed::indexed() : symmetry(unknown)
+indexed::indexed() : symtree(sy_none())
{
- debugmsg("indexed default constructor", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
}
void indexed::copy(const indexed & other)
{
inherited::copy(other);
- symmetry = other.symmetry;
+ symtree = other.symtree;
}
DEFAULT_DESTROY(indexed)
// other constructors
//////////
-indexed::indexed(const ex & b) : inherited(b), symmetry(unknown)
+indexed::indexed(const ex & b) : inherited(b), symtree(sy_none())
{
- debugmsg("indexed constructor from ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, const ex & i1) : inherited(b, i1), symmetry(unknown)
+indexed::indexed(const ex & b, const ex & i1) : inherited(b, i1), symtree(sy_none())
{
- debugmsg("indexed constructor from ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, const ex & i1, const ex & i2) : inherited(b, i1, i2), symmetry(unknown)
+indexed::indexed(const ex & b, const ex & i1, const ex & i2) : inherited(b, i1, i2), symtree(sy_none())
{
- debugmsg("indexed constructor from ex,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3) : inherited(b, i1, i2, i3), symmetry(unknown)
+indexed::indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3) : inherited(b, i1, i2, i3), symtree(sy_none())
{
- debugmsg("indexed constructor from ex,ex,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3, const ex & i4) : inherited(b, i1, i2, i3, i4), symmetry(unknown)
+indexed::indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3, const ex & i4) : inherited(b, i1, i2, i3, i4), symtree(sy_none())
{
- debugmsg("indexed constructor from ex,ex,ex,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, symmetry_type symm, const ex & i1, const ex & i2) : inherited(b, i1, i2), symmetry(symm)
+indexed::indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2) : inherited(b, i1, i2), symtree(symm)
{
- debugmsg("indexed constructor from ex,symmetry,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, symmetry_type symm, const ex & i1, const ex & i2, const ex & i3) : inherited(b, i1, i2, i3), symmetry(symm)
+indexed::indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2, const ex & i3) : inherited(b, i1, i2, i3), symtree(symm)
{
- debugmsg("indexed constructor from ex,symmetry,ex,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, symmetry_type symm, const ex & i1, const ex & i2, const ex & i3, const ex & i4) : inherited(b, i1, i2, i3, i4), symmetry(symm)
+indexed::indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2, const ex & i3, const ex & i4) : inherited(b, i1, i2, i3, i4), symtree(symm)
{
- debugmsg("indexed constructor from ex,symmetry,ex,ex,ex,ex", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, const exvector & v) : inherited(b), symmetry(unknown)
+indexed::indexed(const ex & b, const exvector & v) : inherited(b), symtree(sy_none())
{
- debugmsg("indexed constructor from ex,exvector", LOGLEVEL_CONSTRUCT);
seq.insert(seq.end(), v.begin(), v.end());
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(const ex & b, symmetry_type symm, const exvector & v) : inherited(b), symmetry(symm)
+indexed::indexed(const ex & b, const symmetry & symm, const exvector & v) : inherited(b), symtree(symm)
{
- debugmsg("indexed constructor from ex,symmetry,exvector", LOGLEVEL_CONSTRUCT);
seq.insert(seq.end(), v.begin(), v.end());
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
+ validate();
}
-indexed::indexed(symmetry_type symm, const exprseq & es) : inherited(es), symmetry(symm)
+indexed::indexed(const symmetry & symm, const exprseq & es) : inherited(es), symtree(symm)
{
- debugmsg("indexed constructor from symmetry,exprseq", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
}
-indexed::indexed(symmetry_type symm, const exvector & v, bool discardable) : inherited(v, discardable), symmetry(symm)
+indexed::indexed(const symmetry & symm, const exvector & v, bool discardable) : inherited(v, discardable), symtree(symm)
{
- debugmsg("indexed constructor from symmetry,exvector", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
}
-indexed::indexed(symmetry_type symm, exvector * vp) : inherited(vp), symmetry(symm)
+indexed::indexed(const symmetry & symm, exvector * vp) : inherited(vp), symtree(symm)
{
- debugmsg("indexed constructor from symmetry,exvector *", LOGLEVEL_CONSTRUCT);
tinfo_key = TINFO_indexed;
- assert_all_indices_of_type_idx();
}
//////////
indexed::indexed(const archive_node &n, const lst &sym_lst) : inherited(n, sym_lst)
{
- debugmsg("indexed constructor from archive_node", LOGLEVEL_CONSTRUCT);
- unsigned int symm;
- if (!(n.find_unsigned("symmetry", symm)))
- throw (std::runtime_error("unknown indexed symmetry type in archive"));
+ if (!n.find_ex("symmetry", symtree, sym_lst)) {
+ // GiNaC versions <= 0.9.0 had an unsigned "symmetry" property
+ unsigned symm = 0;
+ n.find_unsigned("symmetry", symm);
+ switch (symm) {
+ case 1:
+ symtree = sy_symm();
+ break;
+ case 2:
+ symtree = sy_anti();
+ break;
+ default:
+ symtree = sy_none();
+ break;
+ }
+ const_cast<symmetry &>(ex_to<symmetry>(symtree)).validate(seq.size() - 1);
+ }
}
void indexed::archive(archive_node &n) const
{
inherited::archive(n);
- n.add_unsigned("symmetry", symmetry);
+ n.add_ex("symmetry", symtree);
}
DEFAULT_UNARCHIVE(indexed)
//////////
-// functions overriding virtual functions from bases classes
+// functions overriding virtual functions from base classes
//////////
void indexed::print(const print_context & c, unsigned level) const
{
- debugmsg("indexed print", LOGLEVEL_PRINT);
GINAC_ASSERT(seq.size() > 0);
- if (is_of_type(c, print_tree)) {
+ if (is_a<print_tree>(c)) {
c.s << std::string(level, ' ') << class_name()
<< std::hex << ", hash=0x" << hashvalue << ", flags=0x" << flags << std::dec
- << ", " << seq.size()-1 << " indices";
- switch (symmetry) {
- case symmetric: c.s << ", symmetric"; break;
- case antisymmetric: c.s << ", antisymmetric"; break;
- default: break;
- }
- c.s << std::endl;
+ << ", " << seq.size()-1 << " indices"
+ << ", symmetry=" << symtree << std::endl;
unsigned delta_indent = static_cast<const print_tree &>(c).delta_indent;
seq[0].print(c, level + delta_indent);
printindices(c, level + delta_indent);
} else {
- bool is_tex = is_of_type(c, print_latex);
+ bool is_tex = is_a<print_latex>(c);
const ex & base = seq[0];
- bool need_parens = is_ex_exactly_of_type(base, add) || is_ex_exactly_of_type(base, mul)
- || is_ex_exactly_of_type(base, ncmul) || is_ex_exactly_of_type(base, power)
- || is_ex_of_type(base, indexed);
+
+ if (precedence() <= level)
+ c.s << (is_tex ? "{(" : "(");
if (is_tex)
c.s << "{";
- if (need_parens)
- c.s << "(";
- base.print(c);
- if (need_parens)
- c.s << ")";
+ base.print(c, precedence());
if (is_tex)
c.s << "}";
printindices(c, level);
+ if (precedence() <= level)
+ c.s << (is_tex ? ")}" : ")");
}
}
return inherited::info(inf);
}
-struct idx_is_not : public binary_function<ex, unsigned, bool> {
+struct idx_is_not : public std::binary_function<ex, unsigned, bool> {
bool operator() (const ex & e, unsigned inf) const {
- return !(ex_to_idx(e).get_value().info(inf));
+ return !(ex_to<idx>(e).get_value().info(inf));
}
};
int indexed::compare_same_type(const basic & other) const
{
- GINAC_ASSERT(is_of_type(other, indexed));
+ GINAC_ASSERT(is_a<indexed>(other));
return inherited::compare_same_type(other);
}
-// The main difference between sort_index_vector() and canonicalize_indices()
-// is that the latter takes the symmetry of the object into account. Once we
-// implement mixed symmetries, canonicalize_indices() will only be able to
-// reorder index pairs with known symmetry properties, while sort_index_vector()
-// always sorts the whole vector.
-
-/** Bring a vector of indices into a canonic order. This operation only makes
- * sense if the object carrying these indices is either symmetric or totally
- * antisymmetric with respect to the indices.
- *
- * @param itbegin Start of index vector
- * @param itend End of index vector
- * @param antisymm Whether the object is antisymmetric
- * @return the sign introduced by the reordering of the indices if the object
- * is antisymmetric (or 0 if two equal indices are encountered). For
- * symmetric objects, this is always +1. If the index vector was
- * already in a canonic order this function returns INT_MAX. */
-static int canonicalize_indices(exvector::iterator itbegin, exvector::iterator itend, bool antisymm)
-{
- bool something_changed = false;
- int sig = 1;
-
- // Simple bubble sort algorithm should be sufficient for the small
- // number of indices expected
- exvector::iterator it1 = itbegin, next_to_last_idx = itend - 1;
- while (it1 != next_to_last_idx) {
- exvector::iterator it2 = it1 + 1;
- while (it2 != itend) {
- int cmpval = it1->compare(*it2);
- if (cmpval == 1) {
- it1->swap(*it2);
- something_changed = true;
- if (antisymm)
- sig = -sig;
- } else if (cmpval == 0 && antisymm) {
- something_changed = true;
- sig = 0;
- }
- it2++;
- }
- it1++;
- }
-
- return something_changed ? sig : INT_MAX;
-}
-
ex indexed::eval(int level) const
{
// First evaluate children, then we will end up here again
if (level > 1)
- return indexed(symmetry, evalchildren(level));
+ return indexed(ex_to<symmetry>(symtree), evalchildren(level));
const ex &base = seq[0];
// If the base object is 0, the whole object is 0
if (base.is_zero())
- return _ex0();
+ return _ex0;
// If the base object is a product, pull out the numeric factor
- if (is_ex_exactly_of_type(base, mul) && is_ex_exactly_of_type(base.op(base.nops() - 1), numeric)) {
+ if (is_exactly_a<mul>(base) && is_exactly_a<numeric>(base.op(base.nops() - 1))) {
exvector v(seq);
- ex f = ex_to_numeric(base.op(base.nops() - 1));
+ ex f = ex_to<numeric>(base.op(base.nops() - 1));
v[0] = seq[0] / f;
return f * thisexprseq(v);
}
// Canonicalize indices according to the symmetry properties
- if (seq.size() > 2 && (symmetry == symmetric || symmetry == antisymmetric)) {
- exvector v(seq);
- int sig = canonicalize_indices(v.begin() + 1, v.end(), symmetry == antisymmetric);
+ if (seq.size() > 2) {
+ exvector v = seq;
+ GINAC_ASSERT(is_exactly_a<symmetry>(symtree));
+ int sig = canonicalize(v.begin() + 1, ex_to<symmetry>(symtree));
if (sig != INT_MAX) {
// Something has changed while sorting indices, more evaluations later
if (sig == 0)
- return _ex0();
+ return _ex0;
return ex(sig) * thisexprseq(v);
}
}
// Let the class of the base object perform additional evaluations
- return base.bp->eval_indexed(*this);
-}
-
-int indexed::degree(const ex & s) const
-{
- return is_equal(*s.bp) ? 1 : 0;
-}
-
-int indexed::ldegree(const ex & s) const
-{
- return is_equal(*s.bp) ? 1 : 0;
-}
-
-ex indexed::coeff(const ex & s, int n) const
-{
- if (is_equal(*s.bp))
- return n==1 ? _ex1() : _ex0();
- else
- return n==0 ? ex(*this) : _ex0();
+ return ex_to<basic>(base).eval_indexed(*this);
}
ex indexed::thisexprseq(const exvector & v) const
{
- return indexed(symmetry, v);
+ return indexed(ex_to<symmetry>(symtree), v);
}
ex indexed::thisexprseq(exvector * vp) const
{
- return indexed(symmetry, vp);
+ return indexed(ex_to<symmetry>(symtree), vp);
}
ex indexed::expand(unsigned options) const
{
GINAC_ASSERT(seq.size() > 0);
- if ((options & expand_options::expand_indexed) && is_ex_exactly_of_type(seq[0], add)) {
+ if ((options & expand_options::expand_indexed) && is_exactly_a<add>(seq[0])) {
// expand_indexed expands (a+b).i -> a.i + b.i
const ex & base = seq[0];
- ex sum = _ex0();
+ ex sum = _ex0;
for (unsigned i=0; i<base.nops(); i++) {
exvector s = seq;
s[0] = base.op(i);
exvector::const_iterator it=seq.begin() + 1, itend = seq.end();
- if (is_of_type(c, print_latex)) {
+ if (is_a<print_latex>(c)) {
// TeX output: group by variance
bool first = true;
bool covariant = true;
while (it != itend) {
- bool cur_covariant = (is_ex_of_type(*it, varidx) ? ex_to_varidx(*it).is_covariant() : true);
- if (first || cur_covariant != covariant) {
+ bool cur_covariant = (is_a<varidx>(*it) ? ex_to<varidx>(*it).is_covariant() : true);
+ if (first || cur_covariant != covariant) { // Variance changed
+ // The empty {} prevents indices from ending up on top of each other
if (!first)
- c.s << "}";
+ c.s << "}{}";
covariant = cur_covariant;
if (covariant)
c.s << "_{";
}
}
-/** Check whether all indices are of class idx. This function is used
- * internally to make sure that all constructed indexed objects really
- * carry indices and not some other classes. */
-void indexed::assert_all_indices_of_type_idx(void) const
+/** Check whether all indices are of class idx and validate the symmetry
+ * tree. This function is used internally to make sure that all constructed
+ * indexed objects really carry indices and not some other classes. */
+void indexed::validate(void) const
{
GINAC_ASSERT(seq.size() > 0);
exvector::const_iterator it = seq.begin() + 1, itend = seq.end();
while (it != itend) {
- if (!is_ex_of_type(*it, idx))
+ if (!is_a<idx>(*it))
throw(std::invalid_argument("indices of indexed object must be of type idx"));
it++;
}
+
+ if (!symtree.is_zero()) {
+ if (!is_exactly_a<symmetry>(symtree))
+ throw(std::invalid_argument("symmetry of indexed object must be of type symmetry"));
+ const_cast<symmetry &>(ex_to<symmetry>(symtree)).validate(seq.size() - 1);
+ }
+}
+
+/** Implementation of ex::diff() for an indexed object always returns 0.
+ *
+ * @see ex::diff */
+ex indexed::derivative(const symbol & s) const
+{
+ return _ex0;
}
//////////
* by the function */
static ex rename_dummy_indices(const ex & e, exvector & global_dummy_indices, exvector & local_dummy_indices)
{
- int global_size = global_dummy_indices.size(),
- local_size = local_dummy_indices.size();
+ unsigned global_size = global_dummy_indices.size(),
+ local_size = local_dummy_indices.size();
// Any local dummy indices at all?
if (local_size == 0)
// More local indices than we encountered before, add the new ones
// to the global set
+ int old_global_size = global_size;
int remaining = local_size - global_size;
exvector::const_iterator it = local_dummy_indices.begin(), itend = local_dummy_indices.end();
while (it != itend && remaining > 0) {
}
it++;
}
- }
- // Replace index symbols in expression
- GINAC_ASSERT(local_size <= global_size);
- bool all_equal = true;
- lst local_syms, global_syms;
- for (unsigned i=0; i<local_size; i++) {
- ex loc_sym = local_dummy_indices[i].op(0);
- ex glob_sym = global_dummy_indices[i].op(0);
- if (!loc_sym.is_equal(glob_sym)) {
- all_equal = false;
- local_syms.append(loc_sym);
- global_syms.append(glob_sym);
- }
+ // If this is the first set of local indices, do nothing
+ if (old_global_size == 0)
+ return e;
}
- if (all_equal)
+ GINAC_ASSERT(local_size <= global_size);
+
+ // Construct lists of index symbols
+ exlist local_syms, global_syms;
+ for (unsigned i=0; i<local_size; i++)
+ local_syms.push_back(local_dummy_indices[i].op(0));
+ shaker_sort(local_syms.begin(), local_syms.end(), ex_is_less(), ex_swap());
+ for (unsigned i=0; i<global_size; i++)
+ global_syms.push_back(global_dummy_indices[i].op(0));
+ shaker_sort(global_syms.begin(), global_syms.end(), ex_is_less(), ex_swap());
+
+ // Remove common indices
+ exlist local_uniq, global_uniq;
+ set_difference(local_syms.begin(), local_syms.end(), global_syms.begin(), global_syms.end(), std::back_insert_iterator<exlist>(local_uniq), ex_is_less());
+ set_difference(global_syms.begin(), global_syms.end(), local_syms.begin(), local_syms.end(), std::back_insert_iterator<exlist>(global_uniq), ex_is_less());
+
+ // Replace remaining non-common local index symbols by global ones
+ if (local_uniq.empty())
return e;
- else
- return e.subs(local_syms, global_syms);
+ else {
+ while (global_uniq.size() > local_uniq.size())
+ global_uniq.pop_back();
+ return e.subs(lst(local_uniq), lst(global_uniq));
+ }
}
/** Simplify product of indexed expressions (commutative, noncommutative and
{
// Remember whether the product was commutative or noncommutative
// (because we chop it into factors and need to reassemble later)
- bool non_commutative = is_ex_exactly_of_type(e, ncmul);
+ bool non_commutative = is_exactly_a<ncmul>(e);
// Collect factors in an exvector, store squares twice
exvector v;
v.reserve(e.nops() * 2);
- if (is_ex_exactly_of_type(e, power)) {
+ if (is_exactly_a<power>(e)) {
// We only get called for simple squares, split a^2 -> a*a
- GINAC_ASSERT(e.op(1).is_equal(_ex2()));
+ GINAC_ASSERT(e.op(1).is_equal(_ex2));
v.push_back(e.op(0));
v.push_back(e.op(0));
} else {
- for (int i=0; i<e.nops(); i++) {
+ for (unsigned i=0; i<e.nops(); i++) {
ex f = e.op(i);
- if (is_ex_exactly_of_type(f, power) && f.op(1).is_equal(_ex2())) {
+ if (is_exactly_a<power>(f) && f.op(1).is_equal(_ex2)) {
v.push_back(f.op(0));
v.push_back(f.op(0));
- } else if (is_ex_exactly_of_type(f, ncmul)) {
+ } else if (is_exactly_a<ncmul>(f)) {
// Noncommutative factor found, split it as well
non_commutative = true; // everything becomes noncommutative, ncmul will sort out the commutative factors later
- for (int j=0; j<f.nops(); j++)
+ for (unsigned j=0; j<f.nops(); j++)
v.push_back(f.op(j));
} else
v.push_back(f);
for (it1 = v.begin(); it1 != next_to_last; it1++) {
try_again:
- if (!is_ex_of_type(*it1, indexed))
+ 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);
+ 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_ex_of_type(*it2, indexed))
+ 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);
+ 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);
- if (dummy.size() == 0)
+ unsigned 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.size() == 0) {
+ if (free.empty()) {
if (sp.is_defined(*it1, *it2)) {
*it1 = sp.evaluate(*it1, *it2);
- *it2 = _ex1();
+ *it2 = _ex1;
goto contraction_done;
}
}
- // Contraction of symmetric with antisymmetric object is zero
- if ((ex_to_indexed(*it1).symmetry == indexed::symmetric &&
- ex_to_indexed(*it2).symmetry == indexed::antisymmetric
- || ex_to_indexed(*it1).symmetry == indexed::antisymmetric &&
- ex_to_indexed(*it2).symmetry == indexed::symmetric)
- && dummy.size() > 1) {
- free_indices.clear();
- return _ex0();
- }
-
// Try to contract the first one with the second one
- contracted = it1->op(0).bp->contract_with(it1, it2, v);
+ 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 = it2->op(0).bp->contract_with(it2, it1, v);
+ contracted = ex_to<basic>(it2->op(0)).contract_with(it2, it1, v);
}
if (contracted) {
contraction_done:
if (first_noncommutative || second_noncommutative
- || is_ex_exactly_of_type(*it1, add) || is_ex_exactly_of_type(*it2, add)
- || is_ex_exactly_of_type(*it1, mul) || is_ex_exactly_of_type(*it2, mul)
- || is_ex_exactly_of_type(*it1, ncmul) || is_ex_exactly_of_type(*it2, ncmul)) {
+ || 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
it1 = v.begin(); itend = v.end();
while (it1 != itend) {
exvector free_indices_of_factor;
- if (is_ex_of_type(*it1, indexed)) {
+ 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);
+ 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();
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) {
+ lst dummy_syms;
+ for (int i=0; i<local_dummy_indices.size(); i++)
+ dummy_syms.append(local_dummy_indices[i].op(0));
+ if (r.symmetrize(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_ex_exactly_of_type(r, mul) && r.nops() == 2
- && is_ex_exactly_of_type(r.op(1), numeric) && is_ex_of_type(r.op(0), indexed))
- return r.op(0).op(0).bp->scalar_mul_indexed(r.op(0), ex_to_numeric(r.op(1)));
+ 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;
}
// Simplification of single indexed object: just find the free indices
// and perform dummy index renaming
- if (is_ex_of_type(e_expanded, indexed)) {
- const indexed &i = ex_to_indexed(e_expanded);
+ if (is_a<indexed>(e_expanded)) {
+ const indexed &i = ex_to<indexed>(e_expanded);
exvector local_dummy_indices;
find_free_and_dummy(i.seq.begin() + 1, i.seq.end(), free_indices, local_dummy_indices);
return rename_dummy_indices(e_expanded, dummy_indices, local_dummy_indices);
// Simplification of sum = sum of simplifications, check consistency of
// free indices in each term
- if (is_ex_exactly_of_type(e_expanded, add)) {
+ if (is_exactly_a<add>(e_expanded)) {
bool first = true;
- ex sum = _ex0();
+ ex sum = _ex0;
free_indices.clear();
for (unsigned i=0; i<e_expanded.nops(); i++) {
} else {
if (!indices_consistent(free_indices, free_indices_of_term))
throw (std::runtime_error("simplify_indexed: inconsistent indices in sum"));
- if (is_ex_of_type(sum, indexed) && is_ex_of_type(term, indexed))
- sum = sum.op(0).bp->add_indexed(sum, term);
+ if (is_a<indexed>(sum) && is_a<indexed>(term))
+ sum = ex_to<basic>(sum.op(0)).add_indexed(sum, term);
else
sum += term;
}
}
// Simplification of products
- if (is_ex_exactly_of_type(e_expanded, mul)
- || is_ex_exactly_of_type(e_expanded, ncmul)
- || (is_ex_exactly_of_type(e_expanded, power) && is_ex_of_type(e_expanded.op(0), indexed) && e_expanded.op(1).is_equal(_ex2())))
+ if (is_exactly_a<mul>(e_expanded)
+ || is_exactly_a<ncmul>(e_expanded)
+ || (is_exactly_a<power>(e_expanded) && is_a<indexed>(e_expanded.op(0)) && e_expanded.op(1).is_equal(_ex2)))
return simplify_indexed_product(e_expanded, free_indices, dummy_indices, sp);
// Cannot do anything
return e_expanded;
}
-ex simplify_indexed(const ex & e)
+/** Simplify/canonicalize expression containing indexed objects. This
+ * performs contraction of dummy indices where possible and checks whether
+ * the free indices in sums are consistent.
+ *
+ * @return simplified expression */
+ex ex::simplify_indexed(void) const
{
exvector free_indices, dummy_indices;
scalar_products sp;
- return simplify_indexed(e, free_indices, dummy_indices, sp);
+ return GiNaC::simplify_indexed(*this, free_indices, dummy_indices, sp);
}
-ex simplify_indexed(const ex & e, const scalar_products & sp)
+/** Simplify/canonicalize expression containing indexed objects. This
+ * performs contraction of dummy indices where possible, checks whether
+ * the free indices in sums are consistent, and automatically replaces
+ * scalar products by known values if desired.
+ *
+ * @param sp Scalar products to be replaced automatically
+ * @return simplified expression */
+ex ex::simplify_indexed(const scalar_products & sp) const
{
exvector free_indices, dummy_indices;
- return simplify_indexed(e, free_indices, dummy_indices, sp);
+ return GiNaC::simplify_indexed(*this, free_indices, dummy_indices, sp);
+}
+
+/** Symmetrize expression over its free indices. */
+ex ex::symmetrize(void) const
+{
+ return GiNaC::symmetrize(*this, get_free_indices());
}
-ex symmetrize(const ex & e)
+/** Antisymmetrize expression over its free indices. */
+ex ex::antisymmetrize(void) const
{
- return symmetrize(e, e.get_free_indices());
+ return GiNaC::antisymmetrize(*this, get_free_indices());
}
-ex antisymmetrize(const ex & e)
+/** Symmetrize expression by cyclic permutation over its free indices. */
+ex ex::symmetrize_cyclic(void) const
{
- return antisymmetrize(e, e.get_free_indices());
+ return GiNaC::symmetrize_cyclic(*this, get_free_indices());
}
//////////
void scalar_products::debugprint(void) const
{
std::cerr << "map size=" << spm.size() << std::endl;
- for (spmap::const_iterator cit=spm.begin(); cit!=spm.end(); ++cit) {
- const spmapkey & k = cit->first;
+ spmap::const_iterator i = spm.begin(), end = spm.end();
+ while (i != end) {
+ const spmapkey & k = i->first;
std::cerr << "item key=(" << k.first << "," << k.second;
- std::cerr << "), value=" << cit->second << std::endl;
+ std::cerr << "), value=" << i->second << std::endl;
+ ++i;
}
}
spmapkey scalar_products::make_key(const ex & v1, const ex & v2)
{
// If indexed, extract base objects
- ex s1 = is_ex_of_type(v1, indexed) ? v1.op(0) : v1;
- ex s2 = is_ex_of_type(v2, indexed) ? v2.op(0) : v2;
+ ex s1 = is_a<indexed>(v1) ? v1.op(0) : v1;
+ ex s2 = is_a<indexed>(v2) ? v2.op(0) : v2;
// Enforce canonical order in pair
if (s1.compare(s2) > 0)