// --------------------------------------------------------------------------- // - Cell.cpp - // - afnix:sps module - cell class implementation - // --------------------------------------------------------------------------- // - This program is free software; you can redistribute it and/or modify - // - it provided that this copyright notice is kept intact. - // - - // - 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. In no event shall - // - the copyright holder be liable for any direct, indirect, incidental or - // - special damages arising in any way out of the use of this software. - // --------------------------------------------------------------------------- // - copyright (c) 1999-2007 amaury darsch - // --------------------------------------------------------------------------- #include "Cell.hpp" #include "Spssid.hxx" #include "Vector.hpp" #include "Output.hpp" #include "Integer.hpp" #include "Runnable.hpp" #include "QuarkZone.hpp" #include "Exception.hpp" namespace afnix { // ------------------------------------------------------------------------- // - private section - // ------------------------------------------------------------------------- // this procedure returns a new cell object for deserialization static Serial* mksob (void) { return new Cell; } // register this cell serial id static const t_byte SERIAL_ID = Serial::setsid (SERIAL_CELL_ID, mksob); // ------------------------------------------------------------------------- // - class section - // ------------------------------------------------------------------------- // create an empty cell Cell::Cell (void) { d_quark = 0; p_cobj = nilp; d_const = false; } // create a cell with a literal Cell::Cell (Literal* cobj) { d_quark = 0; Object::iref (p_cobj = cobj); d_const = false; } // create a cell by name with a literal Cell::Cell (const String& name, Literal* cobj) { d_quark = name.toquark (); Object::iref (p_cobj = cobj); d_const = false; } // copy construct this cell Cell::Cell (const Cell& that) { that.rdlock (); d_quark = that.d_quark; d_const = that.d_const; Object::iref (p_cobj = that.p_cobj); that.unlock (); } // destroy this cell Cell::~Cell (void) { Object::dref (p_cobj); } // return the class name String Cell::repr (void) const { return "Cell"; } // return a clone of this object Object* Cell::clone (void) const { return new Cell (*this); } // assign a cell to this one Cell& Cell::operator = (const Cell& that) { if (this == &that) return *this; wrlock (); that.rdlock (); d_quark = that.d_quark; d_const = that.d_const; Object::iref (that.p_cobj); Object::dref (p_cobj); p_cobj = that.p_cobj; that.unlock (); unlock (); return *this; } // match a quark against the cell bool Cell::operator == (const long quark) const { rdlock (); bool result = (d_quark == quark); unlock (); return result; } // return the cell serial code t_byte Cell::serialid (void) const { return SERIAL_CELL_ID; } // serialize this cell void Cell::wrstream (Output& os) const { rdlock (); try { const String& name = String::qmap (d_quark); name.wrstream (os); if (p_cobj == nilp) { Serial::wrnilid (os); } else { p_cobj->serialize (os); } unlock (); } catch (...) { unlock (); throw; } } // deserialize this cell void Cell::rdstream (Input& is) { wrlock (); String sval; sval.rdstream (is); Object* cobj = Serial::deserialize (is); d_quark = sval.toquark (); p_cobj = dynamic_cast (cobj); if ((cobj != nilp) && (p_cobj == nilp)) { unlock (); throw Exception ("type-error", "invalid cell type object", Object::repr (cobj)); } Object::iref (p_cobj); unlock (); } // return the cell name String Cell::getname (void) const { rdlock (); String result = String::qmap (d_quark); unlock (); return result; } // set the cell name void Cell::setname (const String& name) { wrlock (); d_quark = name.toquark (); unlock (); } // return the cell literal value Literal* Cell::get (void) const { rdlock (); Literal* result = p_cobj; unlock (); return result; } // set the cell value void Cell::set (Literal* cobj) { wrlock (); if (d_const == true) { unlock (); throw Exception ("const-error", "cell const violation"); } Object::iref (cobj); Object::dref (p_cobj); p_cobj = cobj; unlock (); } // map the cell literal to a string String Cell::tostring (void) const { rdlock (); try { String result = (p_cobj == nilp) ? "nil" : p_cobj->tostring (); unlock (); return result; } catch (...) { unlock (); throw; } } // ------------------------------------------------------------------------- // - object section - // ------------------------------------------------------------------------- // the quark zone static const long QUARK_ZONE_LENGTH = 5; static QuarkZone zone (QUARK_ZONE_LENGTH); // the object supported quarks static const long QUARK_GET = zone.intern ("get"); static const long QUARK_SET = zone.intern ("set"); static const long QUARK_GETNAME = zone.intern ("get-name"); static const long QUARK_SETNAME = zone.intern ("set-name"); static const long QUARK_TOSTRING = zone.intern ("to-string"); // create a new object in a generic way Object* Cell::mknew (Vector* argv) { // get number of arguments long argc = (argv == nilp) ? 0 : argv->length (); // check for 0 argument if (argc == 0) return new Cell; // check for 1 argument if (argc == 1) { Object* lobj = argv->get (0); Literal* cobj = dynamic_cast (lobj); if ((lobj != nilp) && (cobj == nilp)) throw Exception ("type-error", "invalid object for cell constructor", Object::repr (lobj)); return new Cell (cobj); } // check for 2 arguments if (argc == 2) { String name = argv->getstring (0); Object* lobj = argv->get (1); Literal* cobj = dynamic_cast (lobj); if ((lobj != nilp) && (cobj == nilp)) throw Exception ("type-error", "invalid object for cell constructor", Object::repr (lobj)); return new Cell (name, cobj); } throw Exception ("argument-error", "too many arguments with cell"); } // return true if the given quark is defined bool Cell::isquark (const long quark, const bool hflg) const { rdlock (); if (zone.exists (quark) == true) { unlock (); return true; } bool result = hflg ? Object::isquark (quark, hflg) : false; unlock (); return result; } // set an object to this object Object* Cell::vdef (Runnable* robj, Nameset* nset, Object* object) { wrlock (); try { Literal* lobj = dynamic_cast (object); if (lobj != nilp) { set (lobj); robj->post (lobj); unlock (); return lobj; } throw Exception ("type-error", "invalid object with cell vdef", Object::repr (object)); } catch (...) { unlock (); throw; } } // apply this object with a set of arguments and a quark Object* Cell::apply (Runnable* robj, Nameset* nset, const long quark, Vector* argv) { // get the number of arguments long argc = (argv == nilp) ? 0 : argv->length (); // dispatch 0 argument if (argc == 0) { if (quark == QUARK_GETNAME) return new String (getname ()); if (quark == QUARK_TOSTRING) return new String (tostring ()); if (quark == QUARK_GET) { rdlock (); Object* result = get (); robj->post (result); unlock (); return result; } } // dispatch 1 argument if (argc == 1) { if (quark == QUARK_SETNAME) { String name = argv->getstring (0); setname (name); return nilp; } if (quark == QUARK_SET) { Object* obj = argv->get (0); Literal* cobj = dynamic_cast (obj); if ((obj != nilp) && (cobj == nilp)) throw Exception ("type-error", "invalid object to set in cell", Object::repr (obj)); set (cobj); return nilp; } } // call the object method return Object::apply (robj, nset, quark, argv); } }