/* File: la_exprsym.cpp Date and Time: Fri Jan 30 18:55:13 2015 */ #include "la_expr.h" using namespace NS_yacco2_T_enum;// enumerate using namespace NS_yacco2_err_symbols;// error symbols using namespace NS_yacco2_k_symbols;// lrk using namespace NS_yacco2_terminals;// terminals using namespace NS_yacco2_characters;// rc using namespace yacco2;// yacco2 library using namespace NS_la_expr;// grammar's ns // first set terminals // monolithic grammar --- no thread void Cla_expr::reduce_rhs_of_rule (yacco2::UINT Sub_rule_no,yacco2::Rule_s_reuse_entry** Recycled_rule){ int reducing_rule = rhs_to_rules_mapping_[Sub_rule_no]; Per_rule_s_reuse_table* rule_reuse_tbl_ptr = fsm_rules_reuse_table.per_rule_s_table_[reducing_rule]; Rule_s_reuse_entry* re(0); find_a_recycled_rule(rule_reuse_tbl_ptr,&re); (*Recycled_rule) = re; fnd_re: switch (Sub_rule_no){ case rhs1_Rla_expr_:{ Rla_expr* sym; if(re->rule_ == 0){ sym = new Rla_expr(parser__); re->rule_ = sym; }else{ sym = (Rla_expr*)re->rule_; } // no rule's constructor directive (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 2; sym->sr1(); return;} case rhs1_Re_:{ Re* sym; if(re->rule_ == 0){ sym = new Re(parser__); re->rule_ = sym; }else{ sym = (Re*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 3; sym->sr1(); return;} case rhs2_Re_:{ Re* sym; if(re->rule_ == 0){ sym = new Re(parser__); re->rule_ = sym; }else{ sym = (Re*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 3; sym->sr2(); return;} case rhs3_Re_:{ Re* sym; if(re->rule_ == 0){ sym = new Re(parser__); re->rule_ = sym; }else{ sym = (Re*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 2; return;} case rhs4_Re_:{ Re* sym; if(re->rule_ == 0){ sym = new Re(parser__); re->rule_ = sym; }else{ sym = (Re*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr4(); return;} case rhs1_Rerr_bad_oper_:{ Rerr_bad_oper* sym; if(re->rule_ == 0){ sym = new Rerr_bad_oper(parser__); re->rule_ = sym; }else{ sym = (Rerr_bad_oper*)re->rule_; } // no rule's constructor directive (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr1(); return;} case rhs1_Rt_:{ Rt* sym; if(re->rule_ == 0){ sym = new Rt(parser__); re->rule_ = sym; }else{ sym = (Rt*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr1(); return;} case rhs2_Rt_:{ Rt* sym; if(re->rule_ == 0){ sym = new Rt(parser__); re->rule_ = sym; }else{ sym = (Rt*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr2(); return;} case rhs3_Rt_:{ Rt* sym; if(re->rule_ == 0){ sym = new Rt(parser__); re->rule_ = sym; }else{ sym = (Rt*)re->rule_; } sym->ctor(); (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr3(); return;} case rhs1_Rminus_:{ Rminus* sym; if(re->rule_ == 0){ sym = new Rminus(parser__); re->rule_ = sym; }else{ sym = (Rminus*)re->rule_; } // no rule's constructor directive (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr1(); return;} case rhs1_Rplus_:{ Rplus* sym; if(re->rule_ == 0){ sym = new Rplus(parser__); re->rule_ = sym; }else{ sym = (Rplus*)re->rule_; } // no rule's constructor directive (*Recycled_rule)->rule_ = sym; sym->rule_info__.rhs_no_of_parms__ = 1; sym->sr1(); return;} default: return; } }