#include "ExNode.hh" #include "Cleanup.hh" #include "Exceptions.hh" #include "Algorithm.hh" #include "pythoncdb/py_kernel.hh" #include #include #include #include #include "DisplayTeX.hh" #include "DisplaySympy.hh" #include "DisplayTerminal.hh" #include //#define DEBUG 1 using namespace cadabra; ExNode::ExNode(const Kernel& k, std::shared_ptr ex_) : IndexClassifier(k), ex(ex_), indices_only(false), args_only(false), terms_only(false), factors_only(false), indnxtit(get_kernel_from_scope()->properties), use_sibling_iterator(false), use_index_iterator(false) { } ExNode ExNode::copy() const { ExNode ret(kernel, ex); ret.it=it; ret.tag=tag; ret.indices_only=indices_only; ret.args_only=args_only; ret.terms_only=terms_only; ret.factors_only=factors_only; ret.nxtit=nxtit; ret.sibnxtit=sibnxtit; ret.indnxtit=indnxtit; ret.use_sibling_iterator=use_sibling_iterator; ret.use_index_iterator=use_index_iterator; ret.topit=topit; ret.stopit=stopit; ret.ind_free=ind_free; ret.ind_dummy=ind_dummy; ret.ind_pos_dummy=ind_pos_dummy; return ret; } ExNode ExNode::getitem_string(std::string tag) { ExNode ret(kernel, ex); ret.tag=tag; ret.ex=ex; ret.topit=it; ret.stopit=it; ret.stopit.skip_children(); ++ret.stopit; ret.update(true); return ret; } ExNode ExNode::getitem_iterator(ExNode it) { if(it.ex!=ex) { std::cerr << "Need to convert iterator" << std::endl; } ExNode ret=it; return ret; } void ExNode::setitem_string(std::string, std::shared_ptr) { // ExNode ret(ex); // ret.tag=tag; // ret.ex=ex; // ret.topit=it; // ret.stopit=it; // ret.stopit.skip_children(); // ++ret.stopit; // ret.update(true); // std::cerr << "will set iterator range to value" << std::endl; //// Ex::iterator it=ex->begin(); //// //// size_t num=ex->number_of_children(it); //// if(index>=0 && (size_t)indexreplace(ex->child(it, index), val.begin()); //// else //// throw ArgumentException("index "+std::to_string(index)+" out of range, must be smaller than "+std::to_string(num)); // // return ret; } void ExNode::setitem_iterator(ExNode en, std::shared_ptr val) { std::cerr << "Setitem iterator" << std::endl; Ex::iterator use; if(en.ex!=ex) { std::cerr << "Setitem need to convert iterator" << std::endl; auto path=en.ex->path_from_iterator(en.it, en.topit); use=ex->iterator_from_path(path, topit); } else use=en.it; Ex::iterator top=val->begin(); if(*top->name=="") { // std::cerr << "top is empty" << std::endl; top=val->begin(top); } ex->replace(use, top); } ExNode ExNode::terms() { ExNode ret(kernel, ex); ret.topit=it; ret.terms_only=true; ret.factors_only=false; ret.use_sibling_iterator=true; ret.update(true); return ret; } ExNode ExNode::factors() { ExNode ret(kernel, ex); ret.topit=it; ret.terms_only=false; ret.factors_only=true; ret.use_sibling_iterator=true; ret.update(true); return ret; } ExNode ExNode::own_indices() { ExNode ret(kernel, ex); ret.topit=it; ret.indices_only=true; ret.use_sibling_iterator=true; ret.update(true); return ret; } ExNode ExNode::indices() { ExNode ret(kernel, ex); ret.topit=it; ret.ind_free.clear(); ret.ind_dummy.clear(); ret.indices_only=true; ret.use_index_iterator=true; ret.update(true); return ret; } ExNode ExNode::free_indices() { ExNode ret(kernel, ex); ret.topit=it; ret.ind_free.clear(); ret.ind_dummy.clear(); classify_indices(it, ret.ind_free, ret.ind_dummy); fill_index_position_map(it, ret.ind_dummy, ret.ind_pos_dummy); ret.indices_only=true; ret.use_index_iterator=true; ret.update(true); return ret; } ExNode ExNode::args() { ExNode ret(kernel, ex); ret.topit=it; ret.args_only=true; ret.use_sibling_iterator=true; ret.update(true); return ret; } ExNode ExNode::children() { ExNode ret(kernel, ex); ret.topit=it; ret.use_sibling_iterator=true; ret.update(true); return ret; } void ExNode::replace(std::shared_ptr rep) { #ifdef DEBUG std::cerr << "next at " << nxtit << std::endl; #endif while(nxtit!=stopit && ex->is_in_subtree(nxtit, it)) update(false); #ifdef DEBUG std::cerr << nxtit.node << std::endl; std::cerr << stopit.node << std::endl; if(nxtit==stopit) std::cerr << "updated next to be at stopit" << std::endl; else std::cerr << "updated next at " << nxtit << std::endl; #endif it=ex->replace(it, rep->begin()); } ExNode ExNode::insert(std::shared_ptr rep) { ExNode ret(kernel, ex); ret.it=ex->insert_subtree(it, rep->begin()); return ret; } ExNode ExNode::insert_it(ExNode rep) { ExNode ret(kernel, ex); ret.it=ex->insert_subtree(it, rep.it); return ret; } ExNode ExNode::append_child(std::shared_ptr rep) { ExNode ret(kernel, ex); ret.it=ex->append_child(it, rep->begin()); return ret; } ExNode ExNode::append_child_it(ExNode rep) { ExNode ret(kernel, ex); ret.it=ex->append_child(it, rep.it); return ret; } ExNode ExNode::add_ex(std::shared_ptr other) { // std::cerr << it << std::endl; // std::cerr << "- - - " << std::endl; // std::cerr << ex->begin() << std::endl; if(ex->is_head(it) || *(ex->parent(it)->name)!="\\sum") ex->wrap(it, str_node("\\sum")); auto sumnode=ex->parent(it); ExNode ret(kernel, ex); // std::cerr << ex->begin() << std::endl; ret.it=ex->insert_subtree_after(it, other->begin()); cleanup_dispatch(*get_kernel_from_scope(), *ex, sumnode); // std::cerr << "----" << std::endl; // std::cerr << ex->begin() << std::endl; // std::cerr << "====" << std::endl; return *this; } void ExNode::erase() { ex->erase(it); } std::string ExNode::get_name() const { if(!ex->is_valid(it)) throw ConsistencyException("Cannot print the value of an iterator before the first 'next'."); return *it->name; } void ExNode::set_name(std::string nm) { if(!ex->is_valid(it)) throw ConsistencyException("Cannot set the value of an iterator before the first 'next'."); it->name = name_set.insert(nm).first; } cadabra::Ex ExNode::get_ex() const { return Ex(it); } str_node::parent_rel_t ExNode::get_parent_rel() const { if(!ex->is_valid(it)) throw ConsistencyException("Cannot get the value of an iterator before the first 'next'."); return it->fl.parent_rel; } void ExNode::set_parent_rel(str_node::parent_rel_t pr) { if(!ex->is_valid(it)) throw ConsistencyException("Cannot set the value of an iterator before the first 'next'."); it->fl.parent_rel=pr; } pybind11::object ExNode::get_multiplier() const { if(!ex->is_valid(it)) throw ConsistencyException("Cannot get the multiplier of an iterator before the first 'next'."); pybind11::object mpq = pybind11::module::import("gmpy2").attr("mpq"); auto m = *it->multiplier; pybind11::object mult = mpq(m.get_num().get_si(), m.get_den().get_si()); return mult; } void ExNode::set_multiplier(pybind11::object mult) { if(!ex->is_valid(it)) throw ConsistencyException("Cannot set the multiplier of an iterator before the first 'next'."); pybind11::object mpq = pybind11::module::import("gmpy2").attr("mpq"); multiply(it->multiplier, pybind11::cast(mult)); } ExNode& ExNode::iter() { return *this; } void ExNode::update(bool first) { if(use_sibling_iterator) { if(terms_only) { if(*topit->name=="\\sum") { if(first) sibnxtit=ex->begin(topit); else ++sibnxtit; } else { if(Algorithm::is_termlike(topit)) { if(Ex::is_head(topit)==false && *Ex::parent(topit)->name=="\\sum") sibnxtit=ex->end(topit); else { if(first) sibnxtit=topit; else sibnxtit=ex->end(topit); } } else sibnxtit=ex->end(topit); } } else if(factors_only) { if(*topit->name=="\\prod") { if(first) sibnxtit=ex->begin(topit); else ++sibnxtit; } else { if(first) sibnxtit=topit; else sibnxtit=ex->end(topit); } } else { if(first) sibnxtit=ex->begin(topit); else ++sibnxtit; } if(!indices_only && !args_only) return; // any sibling is ok. while(sibnxtit!=ex->end(topit)) { if(indices_only) if(sibnxtit->fl.parent_rel==str_node::p_sub || sibnxtit->fl.parent_rel==str_node::p_super) return; if(args_only) if(sibnxtit->fl.parent_rel==str_node::p_none) return; ++sibnxtit; } } else if(use_index_iterator) { if(first) indnxtit=cadabra::index_iterator::begin(get_kernel_from_scope()->properties, topit); else ++indnxtit; // Test if this is a dummy index. Ex::iterator tofind=indnxtit; while(ind_pos_dummy.find(tofind)!=ind_pos_dummy.end()) { #ifdef DEBUG std::cerr << "considered " << tofind << " but that's a dummy" << std::endl; #endif ++indnxtit; tofind=indnxtit; if(indnxtit==cadabra::index_iterator::end(get_kernel_from_scope()->properties, topit)) break; } } else { #ifdef DEBUG std::cerr << "update normal iterator" << std::endl; #endif if(first) nxtit=topit; else ++nxtit; #ifdef DEBUG if(nxtit==stopit) std::cerr << "update reached end" << std::endl; #endif while(nxtit!=stopit) { #ifdef DEBUG std::cerr << "update at " << nxtit << std::endl; #endif if(tag=="" || *nxtit->name==tag) return; ++nxtit; } } } ExNode& ExNode::next() { if(use_sibling_iterator) { if(sibnxtit==ex->end(topit)) throw pybind11::stop_iteration(); it=sibnxtit; } else if(use_index_iterator) { if(indnxtit==cadabra::index_iterator::end(get_kernel_from_scope()->properties, topit)) throw pybind11::stop_iteration(); it=indnxtit; } else { if(nxtit==stopit) throw pybind11::stop_iteration(); it=nxtit; } update(false); return *this; } std::string ExNode::__str__() const { if(!ex->is_valid(it)) throw ConsistencyException("Cannot print iterator before the first 'next'."); std::ostringstream str; // // // if(state()==Algorithm::result_t::l_no_action) // // str << "(unchanged)" << std::endl; // DisplayTeX dt(get_kernel_from_scope()->properties, ex); DisplayTerminal dt(*get_kernel_from_scope(), it, true); dt.output(str, it); return str.str(); } std::string ExNode::_latex_() const { if(!ex->is_valid(it)) throw ConsistencyException("Cannot print iterator LaTeX form before the first 'next'."); std::ostringstream str; DisplayTeX dt(*get_kernel_from_scope(), it); dt.output(str, it); return str.str(); } ExNode Ex_iter(std::shared_ptr ex) { ExNode ret(*get_kernel_from_scope(), ex); ret.ex=ex; ret.topit=ex->begin(); ret.stopit=ex->end(); ret.update(true); return ret; } ExNode Ex_top(std::shared_ptr ex) { ExNode ret(*get_kernel_from_scope(), ex); ret.ex=ex; ret.topit=ex->begin(); ret.stopit=ex->end(); ret.it=ret.topit; return ret; } bool Ex_matches(std::shared_ptr ex, ExNode& other) { Ex_comparator comp(get_kernel_from_scope()->properties); auto ret=comp.equal_subtree(ex->begin(), other.it); if(ret==Ex_comparator::match_t::no_match_less || ret==Ex_comparator::match_t::no_match_greater) return false; return true; } bool Ex_matches_Ex(std::shared_ptr ex, std::shared_ptr other) { Ex_comparator comp(get_kernel_from_scope()->properties); auto ret=comp.equal_subtree(ex->begin(), other->begin()); if(ret==Ex_comparator::match_t::no_match_less || ret==Ex_comparator::match_t::no_match_greater) return false; return true; } bool ExNode_less(ExNode& one, ExNode& two) { Ex_comparator comp(get_kernel_from_scope()->properties); auto ret=comp.equal_subtree(one.it, two.it); if(ret==Ex_comparator::match_t::no_match_less) return true; return false; } bool ExNode_greater(ExNode& one, ExNode& two) { Ex_comparator comp(get_kernel_from_scope()->properties); auto ret=comp.equal_subtree(one.it, two.it); if(ret==Ex_comparator::match_t::no_match_greater) return true; return false; } ExNode Ex_getitem_string(std::shared_ptr ex, std::string tag) { ExNode ret(*get_kernel_from_scope(), ex); ret.tag=tag; ret.ex=ex; ret.topit=ex->begin(); ret.stopit=ex->end(); ret.update(true); return ret; } ExNode Ex_getitem_iterator(std::shared_ptr ex, ExNode en) { Ex::iterator use; if(en.ex!=ex) { // std::cerr << "Need to convert iterator " << en.it << std::endl; // std::cerr << "for " << en.topit << std::endl; // std::cerr << "to one for " << ex->begin() << std::endl; auto path=en.ex->path_from_iterator(en.it, en.topit); use=ex->iterator_from_path(path, ex->begin()); } else use=en.it; // use=ex->begin(); This does not help ExNode ret(*get_kernel_from_scope(), ex); ret.ex=ex; ret.topit=use; ret.it=use; use.skip_children(); ++use; ret.stopit=use; ret.update(true); // std::cerr << "Set to go" << std::endl; // std::cerr << ret.topit << std::endl; return ret; }