/** @file indexed.h * * Interface to GiNaC's indexed expressions. */ /* * GiNaC Copyright (C) 1999-2016 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 * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #ifndef GINAC_INDEXED_H #define GINAC_INDEXED_H #include "exprseq.h" #include "wildcard.h" #include namespace GiNaC { class scalar_products; class symmetry; /** This class holds an indexed expression. It consists of a 'base' expression * (the expression being indexed) which can be accessed as op(0), and n (n >= 0) * indices (all of class idx), accessible as op(1)..op(n). */ class indexed : public exprseq { GINAC_DECLARE_REGISTERED_CLASS(indexed, exprseq) friend ex simplify_indexed(const ex & e, exvector & free_indices, exvector & dummy_indices, const scalar_products & sp); friend ex simplify_indexed_product(const ex & e, exvector & free_indices, exvector & dummy_indices, const scalar_products & sp); friend bool reposition_dummy_indices(ex & e, exvector & variant_dummy_indices, exvector & moved_indices); // other constructors public: /** Construct indexed object with no index. * * @param b Base expression * @return newly constructed indexed object */ indexed(const ex & b); /** Construct indexed object with one index. The index must be of class idx. * * @param b Base expression * @param i1 The index * @return newly constructed indexed object */ indexed(const ex & b, const ex & i1); /** Construct indexed object with two indices. The indices must be of class idx. * * @param b Base expression * @param i1 First index * @param i2 Second index * @return newly constructed indexed object */ indexed(const ex & b, const ex & i1, const ex & i2); /** Construct indexed object with three indices. The indices must be of class idx. * * @param b Base expression * @param i1 First index * @param i2 Second index * @param i3 Third index * @return newly constructed indexed object */ indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3); /** Construct indexed object with four indices. The indices must be of class idx. * * @param b Base expression * @param i1 First index * @param i2 Second index * @param i3 Third index * @param i4 Fourth index * @return newly constructed indexed object */ indexed(const ex & b, const ex & i1, const ex & i2, const ex & i3, const ex & i4); /** Construct indexed object with two indices and a specified symmetry. The * indices must be of class idx. * * @param b Base expression * @param symm Symmetry of indices * @param i1 First index * @param i2 Second index * @return newly constructed indexed object */ indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2); /** Construct indexed object with three indices and a specified symmetry. * The indices must be of class idx. * * @param b Base expression * @param symm Symmetry of indices * @param i1 First index * @param i2 Second index * @param i3 Third index * @return newly constructed indexed object */ indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2, const ex & i3); /** Construct indexed object with four indices and a specified symmetry. The * indices must be of class idx. * * @param b Base expression * @param symm Symmetry of indices * @param i1 First index * @param i2 Second index * @param i3 Third index * @param i4 Fourth index * @return newly constructed indexed object */ indexed(const ex & b, const symmetry & symm, const ex & i1, const ex & i2, const ex & i3, const ex & i4); /** Construct indexed object with a specified vector of indices. The indices * must be of class idx. * * @param b Base expression * @param iv Vector of indices * @return newly constructed indexed object */ indexed(const ex & b, const exvector & iv); /** Construct indexed object with a specified vector of indices and * symmetry. The indices must be of class idx. * * @param b Base expression * @param symm Symmetry of indices * @param iv Vector of indices * @return newly constructed indexed object */ indexed(const ex & b, const symmetry & symm, const exvector & iv); // internal constructors indexed(const symmetry & symm, const exprseq & es); indexed(const symmetry & symm, const exvector & v); indexed(const symmetry & symm, exvector && v); // functions overriding virtual functions from base classes public: unsigned precedence() const override {return 55;} bool info(unsigned inf) const override; ex eval() const override; ex real_part() const override; ex imag_part() const override; exvector get_free_indices() const override; /** Save (a.k.a. serialize) indexed object into archive. */ void archive(archive_node& n) const override; /** Read (a.k.a. deserialize) indexed object from archive. */ void read_archive(const archive_node& n, lst& syms) override; protected: ex derivative(const symbol & s) const override; ex thiscontainer(const exvector & v) const override; ex thiscontainer(exvector && v) const override; unsigned return_type() const override; return_type_t return_type_tinfo() const override { return op(0).return_type_tinfo(); } ex expand(unsigned options = 0) const override; // new virtual functions which can be overridden by derived classes // none // non-virtual functions in this class public: /** Check whether all index values have a certain property. * @see class info_flags */ bool all_index_values_are(unsigned inf) const; /** Return a vector containing the object's indices. */ exvector get_indices() const; /** Return a vector containing the dummy indices of the object, if any. */ exvector get_dummy_indices() const; /** Return a vector containing the dummy indices in the contraction with * another indexed object. This is symmetric: a.get_dummy_indices(b) * == b.get_dummy_indices(a) */ exvector get_dummy_indices(const indexed & other) const; /** Check whether the object has an index that forms a dummy index pair * with a given index. */ bool has_dummy_index_for(const ex & i) const; /** Return symmetry properties. */ ex get_symmetry() const {return symtree;} protected: void printindices(const print_context & c, unsigned level) const; void print_indexed(const print_context & c, const char *openbrace, const char *closebrace, unsigned level) const; void do_print(const print_context & c, unsigned level) const; void do_print_latex(const print_latex & c, unsigned level) const; void do_print_tree(const print_tree & c, unsigned level) const; void validate() const; // member variables protected: ex symtree; /**< Index symmetry (tree of symmetry objects) */ }; GINAC_DECLARE_UNARCHIVER(indexed); class spmapkey { public: spmapkey() : dim(wild()) {} spmapkey(const ex & v1, const ex & v2, const ex & dim = wild()); bool operator==(const spmapkey &other) const; bool operator<(const spmapkey &other) const; void debugprint() const; protected: ex v1, v2, dim; }; typedef std::map spmap; /** Helper class for storing information about known scalar products which * are to be automatically replaced by simplify_indexed(). * * @see simplify_indexed */ class scalar_products { public: /** Register scalar product pair and its value. */ void add(const ex & v1, const ex & v2, const ex & sp); /** Register scalar product pair and its value for a specific space dimension. */ void add(const ex & v1, const ex & v2, const ex & dim, const ex & sp); /** Register list of vectors. This adds all possible pairs of products * a.i * b.i with the value a*b (note that this is not a scalar vector * product but an ordinary product of scalars). */ void add_vectors(const lst & l, const ex & dim = wild()); /** Clear all registered scalar products. */ void clear(); bool is_defined(const ex & v1, const ex & v2, const ex & dim) const; ex evaluate(const ex & v1, const ex & v2, const ex & dim) const; void debugprint() const; protected: spmap spm; /*< Map from defined scalar product pairs to their values */ }; // utility functions /** Returns all dummy indices from the expression */ exvector get_all_dummy_indices(const ex & e); /** More reliable version of the form. The former assumes that e is an * expanded expression. */ exvector get_all_dummy_indices_safely(const ex & e); /** Returns b with all dummy indices, which are listed in va, renamed * if modify_va is set to TRUE all dummy indices of b will be appended to va */ ex rename_dummy_indices_uniquely(exvector & va, const ex & b, bool modify_va = false); /** Returns b with all dummy indices, which are common with a, renamed */ ex rename_dummy_indices_uniquely(const ex & a, const ex & b); /** Same as above, where va and vb contain the indices of a and b and are sorted */ ex rename_dummy_indices_uniquely(const exvector & va, const exvector & vb, const ex & b); /** Similar to above, where va and vb are the same and the return value is a list of two lists * for substitution in b */ lst rename_dummy_indices_uniquely(const exvector & va, const exvector & vb); /** This function returns the given expression with expanded sums * for all dummy index summations, where the dimensionality of * the dummy index is a nonnegative integer. * Optionally all indices with a variance will be substituted by * indices with the corresponding numeric values without variance. * * @param e the given expression * @param subs_idx indicates if variance of dummy indices should be neglected */ ex expand_dummy_sum(const ex & e, bool subs_idx = false); } // namespace GiNaC #endif // ndef GINAC_INDEXED_H