Mercurial > octave-nkf
view libinterp/octave-value/ov-classdef.cc @ 20615:729a85dafba8
use new string_value method to handle value extraction errors
* ov-class.cc, ov-classdef.cc, ov-fcn-handle.cc, ov-fcn-inline.cc,
ov.cc, pt-idx.cc: Use new string_value method.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Thu, 08 Oct 2015 17:55:57 -0400 |
| parents | c1a6c31ac29a |
| children |
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/* Copyright (C) 2012-2015 Michael Goffioul This file is part of Octave. Octave 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 3 of the License, or (at your option) any later version. Octave 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 Octave; see the file COPYING. If not, see <http://www.gnu.org/licenses/>. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include <algorithm> #include "defun.h" #include "load-path.h" #include "ov-builtin.h" #include "ov-classdef.h" #include "ov-fcn-handle.h" #include "ov-typeinfo.h" #include "ov-usr-fcn.h" #include "pt-assign.h" #include "pt-classdef.h" #include "pt-funcall.h" #include "pt-misc.h" #include "pt-stmt.h" #include "pt-walk.h" #include "singleton-cleanup.h" #include "symtab.h" #include "toplev.h" #include "Array.cc" // Define to 1 to enable debugging statements. #define DEBUG_TRACE 0 static void gripe_method_access (const std::string& from, const cdef_method& meth) { octave_value acc = meth.get ("Access"); std::string acc_s; if (acc.is_string ()) acc_s = acc.string_value (); else acc_s = "class-restricted"; error ("%s: method `%s' has %s access and cannot be run in this context", from.c_str (), meth.get_name ().c_str (), acc_s.c_str ()); } static void gripe_property_access (const std::string& from, const cdef_property& prop, bool is_set = false) { octave_value acc = prop.get (is_set ? "SetAccess" : "GetAccess"); std::string acc_s; if (acc.is_string ()) acc_s = acc.string_value (); else acc_s = "class-restricted"; if (is_set) error ("%s: property `%s' has %s access and cannot be set in this context", from.c_str (), prop.get_name ().c_str (), acc_s.c_str ()); else error ("%s: property `%s' has %s access and cannot be obtained in this context", from.c_str (), prop.get_name ().c_str (), acc_s.c_str ()); } static std::string get_base_name (const std::string& nm) { std::string::size_type pos = nm.find_last_of ('.'); if (pos != std::string::npos) return nm.substr (pos + 1); return nm; } static void make_function_of_class (const std::string& class_name, const octave_value& fcn) { octave_function *of = fcn.function_value (); of->stash_dispatch_class (class_name); octave_user_function *uf = of->user_function_value (true); if (uf) { if (get_base_name (class_name) == uf->name ()) { uf->mark_as_class_constructor (); uf->mark_as_classdef_constructor (); } else uf->mark_as_class_method (); } } static void make_function_of_class (const cdef_class& cls, const octave_value& fcn) { make_function_of_class (cls.get_name (), fcn); } static octave_value make_fcn_handle (octave_builtin::fcn ff, const std::string& nm) { octave_value fcn (new octave_builtin (ff, nm)); octave_value fcn_handle (new octave_fcn_handle (fcn, nm)); return fcn_handle; } static octave_value make_fcn_handle (const octave_value& fcn, const std::string& nm) { octave_value retval; if (fcn.is_defined ()) retval = octave_value (new octave_fcn_handle (fcn, nm)); return retval; } inline octave_value_list execute_ov (octave_value val, const octave_value_list& args, int nargout) { std::list<octave_value_list> idx (1, args); std::string type ("("); return val.subsref (type, idx, nargout); } static cdef_class lookup_class (const std::string& name, bool error_if_not_found = true, bool load_if_not_found = true) { return cdef_manager::find_class (name, error_if_not_found, load_if_not_found); } static cdef_class lookup_class (const cdef_class& cls) { // FIXME: placeholder for the time being, the purpose // is to centralized any class update activity here. return cls; } static cdef_class lookup_class (const octave_value& ov) { if (ov.is_string()) return lookup_class (ov.string_value ()); else { cdef_class cls (to_cdef (ov)); return lookup_class (cls); } return cdef_class (); } static std::list<cdef_class> lookup_classes (const Cell& cls_list) { std::list<cdef_class> retval; for (int i = 0; i < cls_list.numel (); i++) { cdef_class c = lookup_class (cls_list(i)); if (! error_state) retval.push_back (c); else { retval.clear (); break; } } return retval; } static octave_value to_ov (const std::list<cdef_class>& class_list) { Cell cls (class_list.size (), 1); int i = 0; for (std::list<cdef_class>::const_iterator it = class_list.begin (); it != class_list.end (); ++it, ++i) cls(i) = to_ov (*it); return octave_value (cls); } static bool is_superclass (const cdef_class& clsa, const cdef_class& clsb, bool allow_equal = true, int max_depth = -1) { bool retval = false; if (allow_equal && clsa == clsb) retval = true; else if (max_depth != 0) { Cell c = clsb.get ("SuperClasses").cell_value (); for (int i = 0; ! retval && i < c.numel (); i++) { cdef_class cls = lookup_class (c(i)); retval = is_superclass (clsa, cls, true, max_depth < 0 ? max_depth : max_depth-1); } } return retval; } inline bool is_strict_superclass (const cdef_class& clsa, const cdef_class& clsb) { return is_superclass (clsa, clsb, false); } inline bool is_direct_superclass (const cdef_class& clsa, const cdef_class& clsb) { return is_superclass (clsa, clsb, false, 1); } static octave_value_list class_get_properties (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1 && args(0).type_name () == "object") { cdef_class cls (to_cdef (args(0))); retval(0) = cls.get_properties (); } return retval; } static cdef_class get_class_context (std::string& name, bool& in_constructor) { cdef_class cls; octave_function* fcn = octave_call_stack::current (); in_constructor = false; if (fcn && (fcn->is_class_method () || fcn->is_classdef_constructor () || fcn->is_anonymous_function_of_class () || (fcn->is_private_function () && ! fcn->dispatch_class ().empty ()))) { cls = lookup_class (fcn->dispatch_class ()); name = fcn->name (); in_constructor = fcn->is_classdef_constructor (); } return cls; } inline cdef_class get_class_context (void) { std::string dummy_string; bool dummy_bool; return get_class_context (dummy_string, dummy_bool); } static bool in_class_method (const cdef_class& cls) { cdef_class ctx = get_class_context (); return (ctx.ok () && is_superclass (ctx, cls)); } static bool check_access (const cdef_class& cls, const octave_value& acc, const std::string& meth_name = std::string (), const std::string& prop_name = std::string (), bool is_prop_set = false) { if (acc.is_string ()) { std::string acc_s = acc.string_value (); if (acc_s == "public") return true; cdef_class ctx = get_class_context (); // The access is private or protected, this requires a // valid class context. if (ctx.ok ()) { if (acc_s == "private") return (ctx == cls); else if (acc_s == "protected") { if (is_superclass (cls, ctx)) // Calling a protected method in a superclass. return true; else if (is_strict_superclass (ctx, cls)) { // Calling a protected method or property in a derived class. // This is only allowed if the context class knows about it // and has access to it. if (! meth_name.empty ()) { cdef_method m = ctx.find_method (meth_name); if (m.ok ()) return check_access (ctx, m.get ("Access"), meth_name); return false; } else if (! prop_name.empty ()) { cdef_property p = ctx.find_property (prop_name); if (p.ok ()) { octave_value p_access = p.get (is_prop_set ? "SetAccess" : "GetAccess"); return check_access (ctx, p_access, meth_name, prop_name, is_prop_set); } return false; } else panic_impossible (); } return false; } else panic_impossible (); } } else if (acc.is_cell ()) { Cell acc_c = acc.cell_value (); cdef_class ctx = get_class_context (); // At this point, a class context is always required. if (ctx.ok ()) { if (ctx == cls) return true; for (int i = 0; i < acc.numel (); i++) { cdef_class acc_cls (to_cdef (acc_c(i))); if (is_superclass (acc_cls, ctx)) return true; } } } else error ("invalid property/method access in class `%s'", cls.get_name ().c_str ()); return false; } static bool is_dummy_method (const octave_value& fcn) { bool retval = false; if (fcn.is_defined ()) { if (fcn.is_user_function ()) { octave_user_function *uf = fcn.user_function_value (true); if (! uf || ! uf->body ()) retval = true; } } else retval = true; return retval; } bool is_method_executing (const octave_value& ov, const cdef_object& obj) { octave_function* stack_fcn = octave_call_stack::current (); octave_function* method_fcn = ov.function_value (true); // Does the top of the call stack match our target function? if (stack_fcn && stack_fcn == method_fcn) { octave_user_function* uf = method_fcn->user_function_value (true); // We can only check the context object for user-function (not builtin), // where we have access to the parameters (arguments and return values). // That's ok as there's no need to call this function for builtin // methods. if (uf) { // At this point, the method is executing, but we still need to // check the context object for which the method is executing. For // methods, it's the first argument of the function; for ctors, it // is the first return value. tree_parameter_list* pl = uf->is_classdef_constructor () ? uf->return_list () : uf->parameter_list (); if (pl && pl->size () > 0) { octave_value arg0 = pl->front ()->lvalue ().value (); if (arg0.is_defined () && arg0.type_name () == "object") { cdef_object arg0_obj = to_cdef (arg0); return obj.is (arg0_obj); } } } } return false; } static octave_value_list class_get_methods (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1 && args(0).type_name () == "object") { cdef_class cls (to_cdef (args(0))); retval(0) = cls.get_methods (); } return retval; } static octave_value_list class_get_superclasses (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1 && args(0).type_name () == "object" && args(0).class_name () == "meta.class") { cdef_class cls (to_cdef (args(0))); Cell classes = cls.get ("SuperClasses").cell_value (); retval(0) = to_ov (lookup_classes (classes)); } return retval; } static octave_value_list class_get_inferiorclasses (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1 && args(0).type_name () == "object" && args(0).class_name () == "meta.class") { cdef_class cls (to_cdef (args(0))); Cell classes = cls.get ("InferiorClasses").cell_value (); retval(0) = to_ov (lookup_classes (classes)); } return retval; } static octave_value_list class_fromName (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1) { std::string name = args(0).string_value ("fromName: invalid class name, expected a string value"); retval(0) = to_ov (lookup_class (name)); } else error ("fromName: invalid number of parameters"); return retval; } static octave_value_list class_fevalStatic (const octave_value_list& args, int nargout) { octave_value_list retval; if (args.length () > 1 && args(0).type_name () == "object") { cdef_class cls (to_cdef (args(0))); if (! error_state) { std::string meth_name = args(1).string_value ("fevalStatic: invalid method name, expected a string value"); cdef_method meth = cls.find_method (meth_name); if (meth.ok ()) { if (meth.is_static ()) retval = meth.execute (args.splice (0, 2), nargout, true, "fevalStatic"); else error ("fevalStatic: method `%s' is not static", meth_name.c_str ()); } else error ("fevalStatic: method not found: %s", meth_name.c_str ()); } else error ("fevalStatic: invalid object, expected a meta.class object"); } else error ("fevalStatic: invalid arguments"); return retval; } static octave_value_list class_getConstant (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 2 && args(0).type_name () == "object" && args(0).class_name () == "meta.class") { cdef_class cls = to_cdef (args(0)); if (! error_state) { std::string prop_name = args(1).string_value ("getConstant: invalid property name, expected a string value"); cdef_property prop = cls.find_property (prop_name); if (prop.ok ()) { if (prop.is_constant ()) retval(0) = prop.get_value (true, "getConstant"); else error ("getConstant: property `%s' is not constant", prop_name.c_str ()); } else error ("getConstant: property not found: %s", prop_name.c_str ()); } else error ("getConstant: invalid object, expected a meta.class object"); } else error ("getConstant: invalid arguments"); return retval; } #define META_CLASS_CMP(OP, CLSA, CLSB, FUN) \ static octave_value_list \ class_ ## OP (const octave_value_list& args, int /* nargout */) \ { \ octave_value_list retval; \ \ if (args.length () == 2 \ && args(0).type_name () == "object" \ && args(1).type_name () == "object" \ && args(0).class_name () == "meta.class" \ && args(1).class_name () == "meta.class") \ { \ cdef_class clsa = to_cdef (args(0)); \ \ cdef_class clsb = to_cdef (args(1)); \ \ if (! error_state) \ retval(0) = FUN (CLSA, CLSB); \ else \ error (#OP ": invalid objects, expected meta.class objects"); \ } \ else \ error (#OP ": invalid arguments"); \ \ return retval; \ } META_CLASS_CMP (lt, clsb, clsa, is_strict_superclass) META_CLASS_CMP (le, clsb, clsa, is_superclass) META_CLASS_CMP (gt, clsa, clsb, is_strict_superclass) META_CLASS_CMP (ge, clsa, clsb, is_superclass) META_CLASS_CMP (eq, clsa, clsb, operator==) META_CLASS_CMP (ne, clsa, clsb, operator!=) octave_value_list property_get_defaultvalue (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1 && args(0).type_name () == "object") { cdef_property prop (to_cdef (args(0))); retval(0) = prop.get ("DefaultValue"); if (! retval(0).is_defined ()) error_with_id ("Octave:class:NotDefaultDefined", "no default value for property `%s'", prop.get_name ().c_str ()); } return retval; } static octave_value_list handle_delete (const octave_value_list& /* args */, int /* nargout */) { octave_value_list retval; // FIXME: implement this return retval; } static cdef_class make_class (const std::string& name, const std::list<cdef_class>& super_list = std::list<cdef_class> ()) { cdef_class cls (name, super_list); cls.set_class (cdef_class::meta_class ()); cls.put ("Abstract", false); cls.put ("ConstructOnLoad", false); cls.put ("ContainingPackage", Matrix ()); cls.put ("Description", std::string ()); cls.put ("DetailedDescription", std::string ()); cls.put ("Events", Cell ()); cls.put ("Hidden", false); cls.put ("InferiorClasses", Cell ()); cls.put ("Methods", Cell ()); cls.put ("Properties", Cell ()); cls.put ("Sealed", false); if (name == "handle") { cls.put ("HandleCompatible", true); cls.mark_as_handle_class (); } else if (super_list.empty ()) { cls.put ("HandleCompatible", false); } else { bool all_handle_compatible = true; bool has_handle_class = false; for (std::list<cdef_class>::const_iterator it = super_list.begin (); it != super_list.end (); ++it) { all_handle_compatible = all_handle_compatible && it->get ("HandleCompatible").bool_value (); has_handle_class = has_handle_class || it->is_handle_class (); } if (has_handle_class && ! all_handle_compatible) error ("%s: cannot mix handle and non-HandleCompatible classes", name.c_str ()); else { cls.put ("HandleCompatible", all_handle_compatible); if (has_handle_class) cls.mark_as_handle_class (); } } if (! name.empty ()) cdef_manager::register_class (cls); return cls; } static cdef_class make_class (const std::string& name, const cdef_class& super) { return make_class (name, std::list<cdef_class> (1, super)); } static cdef_class make_meta_class (const std::string& name, const cdef_class& super) { cdef_class cls = make_class (name, super); cls.put ("Sealed", true); cls.mark_as_meta_class (); return cls; } static cdef_property make_property (const cdef_class& cls, const std::string& name, const octave_value& get_method = Matrix (), const std::string& get_access = "public", const octave_value& set_method = Matrix (), const std::string& set_access = "public") { cdef_property prop (name); prop.set_class (cdef_class::meta_property ()); prop.put ("Description", std::string ()); prop.put ("DetailedDescription", std::string ()); prop.put ("Abstract", false); prop.put ("Constant", false); prop.put ("GetAccess", get_access); prop.put ("SetAccess", set_access); prop.put ("Dependent", false); prop.put ("Transient", false); prop.put ("Hidden", false); prop.put ("GetObservable", false); prop.put ("SetObservable", false); prop.put ("GetMethod", get_method); prop.put ("SetMethod", set_method); prop.put ("DefiningClass", to_ov (cls)); prop.put ("DefaultValue", octave_value ()); prop.put ("HasDefault", false); std::string class_name = cls.get_name (); if (! get_method.is_empty ()) make_function_of_class (class_name, get_method); if (! set_method.is_empty ()) make_function_of_class (class_name, set_method); return prop; } inline cdef_property make_attribute (const cdef_class& cls, const std::string& name) { return make_property (cls, name, Matrix (), "public", Matrix (), "private"); } static cdef_method make_method (const cdef_class& cls, const std::string& name, const octave_value& fcn,const std::string& m_access = "public", bool is_static = false) { cdef_method meth (name); meth.set_class (cdef_class::meta_method ()); meth.put ("Abstract", false); meth.put ("Access", m_access); meth.put ("DefiningClass", to_ov (cls)); meth.put ("Description", std::string ()); meth.put ("DetailedDescription", std::string ()); meth.put ("Hidden", false); meth.put ("Sealed", true); meth.put ("Static", is_static); if (fcn.is_defined ()) make_function_of_class (cls, fcn); meth.set_function (fcn); if (is_dummy_method (fcn)) meth.mark_as_external (cls.get_name ()); return meth; } inline cdef_method make_method (const cdef_class& cls, const std::string& name, octave_builtin::fcn ff, const std::string& m_access = "public", bool is_static = false) { octave_value fcn (new octave_builtin (ff, name)); return make_method (cls, name, fcn, m_access, is_static); } static cdef_package make_package (const std::string& nm, const std::string& parent = std::string ()) { cdef_package pack (nm); pack.set_class (cdef_class::meta_package ()); if (parent.empty ()) pack.put ("ContainingPackage", Matrix ()); else pack.put ("ContainingPackage", to_ov (cdef_manager::find_package (parent))); if (! nm.empty ()) cdef_manager::register_package (pack); return pack; } //---------------------------------------------------------------------------- int octave_classdef::t_id (-1); const std::string octave_classdef::t_name ("object"); void octave_classdef::register_type (void) { t_id = octave_value_typeinfo::register_type (octave_classdef::t_name, "<unknown>", octave_value (new octave_classdef ())); } octave_value_list octave_classdef::subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { size_t skip = 0; octave_value_list retval; cdef_class cls = object.get_class (); if (! in_class_method (cls) && ! called_from_builtin ()) { cdef_method meth = cls.find_method ("subsref"); if (meth.ok ()) { octave_value_list args; args(1) = make_idx_args (type, idx, "subsref"); count++; args(0) = octave_value (this); retval = meth.execute (args, nargout, true, "subsref"); return retval; } } // At this point, the default subsref mechanism must be used. retval = object.subsref (type, idx, nargout, skip, cdef_class ()); if (type.length () > skip && idx.size () > skip) retval = retval(0).next_subsref (nargout, type, idx, skip); return retval; } octave_value octave_classdef::subsref (const std::string& type, const std::list<octave_value_list>& idx, bool auto_add) { size_t skip = 0; octave_value_list retval; // This variant of subsref is used to create temporary values when doing // assignment with multi-level indexing. AFAIK this is only used for internal // purpose (not sure we should even implement this) and any overload subsref // should not be called. retval = object.subsref (type, idx, 1, skip, cdef_class (), auto_add); if (type.length () > skip && idx.size () > skip) retval = retval(0).next_subsref (1, type, idx, skip); return retval.length () > 0 ? retval(0) : octave_value (); } octave_value octave_classdef::subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs) { octave_value retval; cdef_class cls = object.get_class (); if (! in_class_method (cls) && ! called_from_builtin ()) { cdef_method meth = cls.find_method ("subsasgn"); if (meth.ok ()) { octave_value_list args; args(1) = make_idx_args (type, idx, "subsasgn"); count++; args(0) = octave_value (this); args(2) = rhs; octave_value_list retlist; retlist = meth.execute (args, 1, true, "subsasgn"); if (retlist.length () > 0) retval = retlist(0); else error ("overloaded method `subsasgn' did not return any value"); } } if (! retval.is_defined ()) retval = object.subsasgn (type, idx, rhs); return retval; } octave_value octave_classdef::undef_subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs) { if (type.length () == 1 && type[0] == '(') { object = object.make_array (); return subsasgn (type, idx, rhs); } else return octave_base_value::undef_subsasgn (type, idx, rhs); return octave_value (); } void octave_classdef::print (std::ostream& os, bool) { if (! called_from_builtin ()) { cdef_method meth = object.get_class ().find_method ("disp"); if (meth.ok ()) { octave_value_list args; count++; args(0) = octave_value (this); indent (os); meth.execute (args, 0, true, "disp"); return; } } print_raw (os); } void octave_classdef::print_raw (std::ostream& os, bool) const { indent (os); os << "<object "; if (object.is_array ()) os << "array "; os << class_name () << ">"; newline (os); } bool octave_classdef::print_name_tag (std::ostream& os, const std::string& name) const { return octave_base_value::print_name_tag (os, name); } void octave_classdef::print_with_name (std::ostream& os, const std::string& name, bool print_padding) { cdef_method meth = object.get_class ().find_method ("display"); if (meth.ok ()) { octave_value_list args; count++; args(0) = octave_value (this); string_vector arg_names (1); arg_names[0] = name; args.stash_name_tags (arg_names); indent (os); meth.execute (args, 0, true, "display"); } else octave_base_value::print_with_name (os, name, print_padding); } bool octave_classdef::is_instance_of (const std::string& cls_name) const { cdef_class cls = lookup_class (cls_name, false, false); if (cls.ok ()) return is_superclass (cls, object.get_class ()); return false; } //---------------------------------------------------------------------------- class octave_classdef_meta : public octave_function { public: octave_classdef_meta (const cdef_meta_object& obj) : object (obj) { } ~octave_classdef_meta (void) { object.meta_release (); } octave_function* function_value (bool = false) { return this; } octave_value_list subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { return object.meta_subsref (type, idx, nargout); } octave_value subsref (const std::string& type, const std::list<octave_value_list>& idx) { octave_value_list retval; retval = subsref (type, idx, 1); return (retval.length () > 0 ? retval(0) : octave_value ()); } octave_value_list do_multi_index_op (int nargout, const octave_value_list& idx) { // Emulate ()-type meta subsref std::list<octave_value_list> l (1, idx); std::string type ("("); return subsref (type, l, nargout); } bool is_postfix_index_handled (char type) const { return object.meta_is_postfix_index_handled (type); } bool is_classdef_constructor (const std::string& cname = std::string ()) const { bool retval = false; if (object.is_class ()) { if (cname.empty ()) retval = true; else { cdef_class cls (object); if (cls.get_name () == cname) retval = true; } } return retval; } private: cdef_meta_object object; }; //---------------------------------------------------------------------------- class octave_classdef_superclass_ref : public octave_function { public: octave_classdef_superclass_ref (const octave_value_list& a) : octave_function (), args (a) { } ~octave_classdef_superclass_ref (void) { } octave_function* function_value (bool = false) { return this; } octave_value_list subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { size_t skip = 0; octave_value_list retval; switch (type[0]) { case '(': skip = 1; retval = do_multi_index_op (type.length () > 1 ? 1 : nargout, idx.front ()); break; default: retval = do_multi_index_op (1, octave_value_list ()); break; } if (type.length () > skip && idx.size () > skip && retval.length () > 0) retval = retval(0).next_subsref (nargout, type, idx, skip); return retval; } octave_value subsref (const std::string& type, const std::list<octave_value_list>& idx) { octave_value_list retval; retval = subsref (type, idx, 1); return (retval.length () > 0 ? retval(0) : octave_value ()); } octave_value_list do_multi_index_op (int nargout, const octave_value_list& idx) { octave_value_list retval; std::string meth_name; bool in_constructor; cdef_class ctx; ctx = get_class_context (meth_name, in_constructor); if (! error_state && ctx.ok ()) { std::string mname = args(0).string_value (); std::string cname = args(1).string_value (); cdef_class cls = lookup_class (cname); if (in_constructor) { if (is_direct_superclass (cls, ctx)) { if (is_constructed_object (mname)) { octave_value sym = symbol_table::varval (mname); cls.run_constructor (to_cdef_ref (sym), idx); retval(0) = sym; } else error ("cannot call superclass constructor with " "variable `%s'", mname.c_str ()); } else error ("`%s' is not a direct superclass of `%s'", cname.c_str (), ctx.get_name ().c_str ()); } else { if (mname == meth_name) { if (is_strict_superclass (cls, ctx)) { // I see 2 possible implementations here: // 1) use cdef_object::subsref with a different class // context; this avoids duplicating code, but // assumes the object is always the first argument // 2) lookup the method manually and call // cdef_method::execute; this duplicates part of // logic in cdef_object::subsref, but avoid the // assumption of 1) // Not being sure about the assumption of 1), I // go with option 2) for the time being. cdef_method meth = cls.find_method (meth_name, false); if (meth.ok ()) retval = meth.execute (idx, nargout, true, meth_name); else error ("no method `%s' found in superclass `%s'", meth_name.c_str (), cname.c_str ()); } else error ("`%s' is not a superclass of `%s'", cname.c_str (), ctx.get_name ().c_str ()); } else error ("method name mismatch (`%s' != `%s')", mname.c_str (), meth_name.c_str ()); } } else if (! error_state) error ("superclass calls can only occur in methods or constructors"); return retval; } private: bool is_constructed_object (const std::string nm) { octave_function *of = octave_call_stack::current (); if (of->is_classdef_constructor ()) { octave_user_function *uf = of->user_function_value (true); if (uf) { tree_parameter_list *ret_list = uf->return_list (); if (ret_list && ret_list->length () == 1) return (ret_list->front ()->name () == nm); } } return false; } private: octave_value_list args; }; //---------------------------------------------------------------------------- octave_map cdef_object::map_value (void) const { octave_map retval; warning_with_id ("Octave:classdef-to-struct", "struct: converting a classdef object into a struct " "overrides the access restrictions defined for properties. " "All properties are returned, including private and " "protected ones."); cdef_class cls = get_class (); if (cls.ok ()) { std::map<std::string, cdef_property> props; props = cls.get_property_map (cdef_class::property_all); for (std::map<std::string, cdef_property>::iterator it = props.begin (); it != props.end (); ++it) { octave_value pvalue; if (is_array ()) { Array<cdef_object> a_obj = array_value (); Cell cvalue (a_obj.dims ()); for (octave_idx_type i = 0; i < a_obj.numel (); i++) cvalue (i) = it->second.get_value (a_obj(i), false); retval.setfield (it->first, cvalue); } else { Cell cvalue (dim_vector (1, 1), it->second.get_value (*this, false)); retval.setfield (it->first, cvalue); } } } return retval; } string_vector cdef_object_rep::map_keys (void) const { cdef_class cls = get_class (); if (cls.ok ()) return cls.get_names (); return string_vector (); } octave_value_list cdef_object_scalar::subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout, size_t& skip, const cdef_class& context, bool auto_add) { skip = 0; cdef_class cls = (context.ok () ? context : get_class ()); octave_value_list retval; if (! cls.ok ()) return retval; switch (type[0]) { case '.': { std::string name = (idx.front ())(0).string_value (); cdef_method meth = cls.find_method (name); if (meth.ok ()) { int _nargout = (type.length () > 2 ? 1 : nargout); octave_value_list args; skip = 1; if (type.length () > 1 && type[1] == '(') { std::list<octave_value_list>::const_iterator it = idx.begin (); args = *++it; skip++; } if (meth.is_static ()) retval = meth.execute (args, _nargout, true, "subsref"); else { refcount++; retval = meth.execute (cdef_object (this), args, _nargout, true, "subsref"); } } if (skip == 0) { cdef_property prop = cls.find_property (name); if (prop.ok ()) { if (prop.is_constant ()) retval(0) = prop.get_value (true, "subsref"); else { refcount++; retval(0) = prop.get_value (cdef_object (this), true, "subsref"); } skip = 1; } else error ("subsref: unknown method or property: %s", name.c_str ()); } break; } case '(': { const octave_value_list& ival = idx.front (); refcount++; cdef_object this_obj (this); if (ival.empty ()) { skip++; retval(0) = to_ov (this_obj); } else { Array<cdef_object> arr (dim_vector (1, 1), this_obj); cdef_object new_obj = cdef_object (new cdef_object_array (arr)); new_obj.set_class (get_class ()); retval = new_obj.subsref (type, idx, nargout, skip, cls, auto_add); } } break; default: error ("object cannot be indexed with `%c'", type[0]); break; } return retval; } octave_value cdef_object_scalar::subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs) { octave_value retval; cdef_class cls = get_class (); switch (type[0]) { case '.': { std::string name = (idx.front ())(0).string_value (); cdef_property prop = cls.find_property (name); if (prop.ok ()) { if (prop.is_constant ()) error ("subsasgn: cannot assign constant property: %s", name.c_str ()); else { refcount++; cdef_object obj (this); if (type.length () == 1) { prop.set_value (obj, rhs, true, "subsasgn"); retval = to_ov (obj); } else { octave_value val = prop.get_value (obj, true, "subsasgn"); std::list<octave_value_list> args (idx); args.erase (args.begin ()); val = val.assign (octave_value::op_asn_eq, type.substr (1), args, rhs); if (val.class_name () != "object" || ! to_cdef (val).is_handle_object ()) prop.set_value (obj, val, true, "subsasgn"); retval = to_ov (obj); } } } else error ("subsasgn: unknown property: %s", name.c_str ()); } break; case '(': { refcount++; cdef_object this_obj (this); Array<cdef_object> arr (dim_vector (1, 1), this_obj); cdef_object new_obj = cdef_object (new cdef_object_array (arr)); new_obj.set_class (get_class ()); octave_value tmp = new_obj.subsasgn (type, idx, rhs); retval = tmp; } break; default: error ("subsasgn: object cannot be index with `%c'", type[0]); break; } return retval; } void cdef_object_scalar::mark_for_construction (const cdef_class& cls) { std::string cls_name = cls.get_name (); Cell supcls = cls.get ("SuperClasses").cell_value (); std::list<cdef_class> supcls_list = lookup_classes (supcls); ctor_list[cls] = supcls_list; } octave_value_list cdef_object_array::subsref (const std::string& type, const std::list<octave_value_list>& idx, int /* nargout */, size_t& skip, const cdef_class& /* context */, bool auto_add) { octave_value_list retval; skip = 1; switch (type[0]) { case '(': { const octave_value_list& ival = idx.front (); if (ival.empty ()) { refcount++; retval(0) = to_ov (cdef_object (this)); break; } bool is_scalar = true; Array<idx_vector> iv (dim_vector (1, ival.length ())); for (int i = 0; i < ival.length (); i++) { try { iv(i) = ival(i).index_vector (); } catch (index_exception& e) { // Rethrow to allow more info to be reported later. e.set_pos_if_unset (ival.length (), i+1); throw; } is_scalar = is_scalar && iv(i).is_scalar (); } Array<cdef_object> ires = array.index (iv, auto_add); // If resizing is enabled (auto_add = true), it's possible // indexing was out-of-bound and the result array contains // invalid cdef_objects. if (auto_add) fill_empty_values (ires); if (is_scalar) retval(0) = to_ov (ires(0)); else { cdef_object array_obj (new cdef_object_array (ires)); array_obj.set_class (get_class ()); retval(0) = to_ov (array_obj); } } break; case '.': if (type.size () == 1 && idx.size () == 1) { Cell c (dims ()); octave_idx_type n = array.numel (); // dummy variables size_t dummy_skip; cdef_class dummy_cls; for (octave_idx_type i = 0; i < n; i++) { octave_value_list r = array(i).subsref (type, idx, 1, dummy_skip, dummy_cls); if (r.length () > 0) c(i) = r(0); } retval(0) = octave_value (c, true); break; } // fall through "default" default: error ("can't perform indexing operation on array of %s objects", class_name ().c_str ()); break; } return retval; } octave_value cdef_object_array::subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs) { octave_value retval; switch (type[0]) { case '(': if (type.length () == 1) { cdef_object rhs_obj = to_cdef (rhs); if (rhs_obj.get_class () == get_class ()) { const octave_value_list& ival = idx.front (); bool is_scalar = true; Array<idx_vector> iv (dim_vector (1, ival.length ())); for (int i = 0; i < ival.length (); i++) { try { iv(i) = ival(i).index_vector (); } catch (index_exception& e) { e.set_pos_if_unset (ival.length (), i+1); throw; // var name set in pt-idx.cc / pt-assign.cc } is_scalar = is_scalar && iv(i).is_scalar (); } Array<cdef_object> rhs_mat; if (! rhs_obj.is_array ()) { rhs_mat = Array<cdef_object> (dim_vector (1, 1)); rhs_mat(0) = rhs_obj; } else rhs_mat = rhs_obj.array_value (); octave_idx_type n = array.numel (); array.assign (iv, rhs_mat, cdef_object ()); if (array.numel () > n) fill_empty_values (); refcount++; retval = to_ov (cdef_object (this)); } else error ("can't assign %s object into array of %s objects.", rhs_obj.class_name ().c_str (), class_name ().c_str ()); } else { const octave_value_list& ival = idx.front (); bool is_scalar = true; Array<idx_vector> iv (dim_vector (1, ival.length ())); for (int i = 0; i < ival.length (); i++) { try { iv(i) = ival(i).index_vector (); } catch (index_exception& e) { // Rethrow to allow more info to be reported later. e.set_pos_if_unset (ival.length (), i+1); throw; } is_scalar = is_scalar && iv(i).is_scalar (); if (! is_scalar) error ("subsasgn: invalid indexing for object array " "assignment, the index must reference a single " "object in the array."); } Array<cdef_object> a = array.index (iv, true); if (a.numel () != 1) error ("subsasgn: invalid indexing for object array " "assignment"); cdef_object obj = a(0); int ignore_copies = 0; // If the object in 'a' is not valid, this means the index // was out-of-bound and we need to create a new object. if (! obj.ok ()) obj = get_class ().construct_object (octave_value_list ()); else // Optimize the subsasgn call to come. There are 2 copies // that we can safely ignore: // - 1 in "array" // - 1 in "a" ignore_copies = 2; std::list<octave_value_list> next_idx (idx); next_idx.erase (next_idx.begin ()); octave_value tmp = obj.subsasgn (type.substr (1), next_idx, rhs, ignore_copies); cdef_object robj = to_cdef (tmp); if (robj.ok () && ! robj.is_array () && robj.get_class () == get_class ()) { // Small optimization, when dealing with handle // objects, we don't need to re-assign the result // of subsasgn back into the array. if (! robj.is (a(0))) { Array<cdef_object> rhs_a (dim_vector (1, 1), robj); octave_idx_type n = array.numel (); array.assign (iv, rhs_a); if (array.numel () > n) fill_empty_values (); } refcount++; retval = to_ov (cdef_object (this)); } else error ("subasgn: invalid assignment into array of %s " "objects", class_name ().c_str ()); } break; default: error ("can't perform indexing operation on array of %s objects", class_name ().c_str ()); break; } return retval; } void cdef_object_array::fill_empty_values (Array<cdef_object>& arr) { cdef_class cls = get_class (); cdef_object obj; int n = arr.numel (); for (int i = 0; i < n; i++) { if (! arr.xelem (i).ok ()) { if (! obj.ok ()) { obj = cls.construct_object (octave_value_list ()); arr.xelem (i) = obj; } else arr.xelem (i) = obj.copy (); } } } bool cdef_object_scalar::is_constructed_for (const cdef_class& cls) const { return (is_constructed () || ctor_list.find (cls) == ctor_list.end ()); } bool cdef_object_scalar::is_partially_constructed_for (const cdef_class& cls) const { std::map< cdef_class, std::list<cdef_class> >::const_iterator it; if (is_constructed ()) return true; else if ((it = ctor_list.find (cls)) == ctor_list.end () || it->second.empty ()) return true; for (std::list<cdef_class>::const_iterator lit = it->second.begin (); lit != it->second.end (); ++lit) if (! is_constructed_for (*lit)) return false; return true; } void cdef_object_scalar::mark_as_constructed (const cdef_class& cls) { ctor_list.erase (cls); } handle_cdef_object::~handle_cdef_object (void) { #if DEBUG_TRACE std::cerr << "deleting " << get_class ().get_name () << " object (handle)" << std::endl; #endif } value_cdef_object::~value_cdef_object (void) { #if DEBUG_TRACE std::cerr << "deleting " << get_class ().get_name () << " object (value)" << std::endl; #endif } cdef_class::cdef_class_rep::cdef_class_rep (const std::list<cdef_class>& superclasses) : cdef_meta_object_rep (), member_count (0), handle_class (false), object_count (0), meta (false) { put ("SuperClasses", to_ov (superclasses)); implicit_ctor_list = superclasses; } cdef_method cdef_class::cdef_class_rep::find_method (const std::string& nm, bool local) { method_iterator it = method_map.find (nm); if (it == method_map.end ()) { // FIXME: look into class directory } else { cdef_method& meth = it->second; // FIXME: check if method reload needed if (meth.ok ()) return meth; } if (! local) { // Look into superclasses Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cdef_method meth = cls.find_method (nm); if (meth.ok ()) return meth; } } return cdef_method (); } class ctor_analyzer : public tree_walker { public: ctor_analyzer (const std::string& ctor, const std::string& obj) : tree_walker (), who (ctor), obj_name (obj) { } void visit_statement_list (tree_statement_list& t) { for (tree_statement_list::const_iterator it = t.begin (); it != t.end (); ++it) (*it)->accept (*this); } void visit_statement (tree_statement& t) { if (t.is_expression ()) t.expression ()->accept (*this); } void visit_simple_assignment (tree_simple_assignment& t) { t.right_hand_side ()->accept (*this); } void visit_multi_assignment (tree_multi_assignment& t) { t.right_hand_side ()->accept (*this); } void visit_index_expression (tree_index_expression& t) { t.expression ()->accept (*this); } void visit_funcall (tree_funcall& t) { octave_value fcn = t.function (); if (fcn.is_function ()) { octave_function *of = fcn.function_value (true); if (of) { if (of->name () == "__superclass_reference__") { octave_value_list args = t.arguments (); if (args(0).string_value () == obj_name) { std::string class_name = args(1).string_value (); cdef_class cls = lookup_class (class_name, false); if (cls.ok ()) ctor_list.push_back (cls); } } } } } std::list<cdef_class> get_constructor_list (void) const { return ctor_list; } // NO-OP void visit_anon_fcn_handle (tree_anon_fcn_handle&) { } void visit_argument_list (tree_argument_list&) { } void visit_binary_expression (tree_binary_expression&) { } void visit_break_command (tree_break_command&) { } void visit_colon_expression (tree_colon_expression&) { } void visit_continue_command (tree_continue_command&) { } void visit_global_command (tree_global_command&) { } void visit_persistent_command (tree_persistent_command&) { } void visit_decl_elt (tree_decl_elt&) { } void visit_decl_init_list (tree_decl_init_list&) { } void visit_simple_for_command (tree_simple_for_command&) { } void visit_complex_for_command (tree_complex_for_command&) { } void visit_octave_user_script (octave_user_script&) { } void visit_octave_user_function (octave_user_function&) { } void visit_function_def (tree_function_def&) { } void visit_identifier (tree_identifier&) { } void visit_if_clause (tree_if_clause&) { } void visit_if_command (tree_if_command&) { } void visit_if_command_list (tree_if_command_list&) { } void visit_switch_case (tree_switch_case&) { } void visit_switch_case_list (tree_switch_case_list&) { } void visit_switch_command (tree_switch_command&) { } void visit_matrix (tree_matrix&) { } void visit_cell (tree_cell&) { } void visit_no_op_command (tree_no_op_command&) { } void visit_constant (tree_constant&) { } void visit_fcn_handle (tree_fcn_handle&) { } void visit_parameter_list (tree_parameter_list&) { } void visit_postfix_expression (tree_postfix_expression&) { } void visit_prefix_expression (tree_prefix_expression&) { } void visit_return_command (tree_return_command&) { } void visit_return_list (tree_return_list&) { } void visit_try_catch_command (tree_try_catch_command&) { } void visit_unwind_protect_command (tree_unwind_protect_command&) { } void visit_while_command (tree_while_command&) { } void visit_do_until_command (tree_do_until_command&) { } private: /* The name of the constructor being analyzed */ std::string who; /* The name of the first output argument of the constructor */ std::string obj_name; /* The list of superclass constructors that are explicitly called */ std::list<cdef_class> ctor_list; }; void cdef_class::cdef_class_rep::install_method (const cdef_method& meth) { method_map[meth.get_name ()] = meth; member_count++; if (meth.is_constructor ()) { // Analyze the constructor code to determine what superclass // constructors are called explicitly. octave_function *of = meth.get_function ().function_value (true); if (of) { octave_user_function *uf = of->user_function_value (true); if (uf) { tree_parameter_list *ret_list = uf->return_list (); tree_statement_list *body = uf->body (); if (ret_list && ret_list->size () == 1) { std::string obj_name = ret_list->front ()->name (); ctor_analyzer a (meth.get_name (), obj_name); body->accept (a); std::list<cdef_class> explicit_ctor_list = a.get_constructor_list (); for (std::list<cdef_class>::const_iterator it = explicit_ctor_list.begin (); it != explicit_ctor_list.end (); ++it) { #if DEBUG_TRACE std::cerr << "explicit superclass constructor: " << it->get_name () << std::endl; #endif implicit_ctor_list.remove (*it); } } else error ("%s: invalid constructor output arguments", meth.get_name ().c_str ()); } } } } void cdef_class::cdef_class_rep::load_all_methods (void) { // FIXME: re-scan class directory } Cell cdef_class::cdef_class_rep::get_methods (void) { std::map<std::string,cdef_method> meths; find_methods (meths, false); Cell c (meths.size (), 1); int idx = 0; for (std::map<std::string,cdef_method>::const_iterator it = meths.begin (); it != meths.end (); ++it, ++idx) c (idx, 0) = to_ov (it->second); return c; } void cdef_class::cdef_class_rep::find_methods (std::map<std::string, cdef_method>& meths, bool only_inherited) { load_all_methods (); method_const_iterator it; for (it = method_map.begin (); it != method_map.end (); ++it) { if (! it->second.is_constructor ()) { std::string nm = it->second.get_name (); if (meths.find (nm) == meths.end ()) { if (only_inherited) { octave_value acc = it->second.get ("Access"); if (! acc.is_string () || acc.string_value () == "private") continue; } meths[nm] = it->second; } } } // Look into superclasses Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cls.get_rep ()->find_methods (meths, true); } } cdef_property cdef_class::cdef_class_rep::find_property (const std::string& nm) { property_iterator it = property_map.find (nm); if (it != property_map.end ()) { cdef_property& prop = it->second; if (prop.ok ()) return prop; } // Look into superclasses Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cdef_property prop = cls.find_property (nm); if (prop.ok ()) return prop; } return cdef_property (); } void cdef_class::cdef_class_rep::install_property (const cdef_property& prop) { property_map[prop.get_name ()] = prop; member_count++; } Cell cdef_class::cdef_class_rep::get_properties (int mode) { std::map<std::string,cdef_property> props; props = get_property_map (mode); Cell c (props.size (), 1); int idx = 0; for (std::map<std::string,cdef_property>::const_iterator it = props.begin (); it != props.end (); ++it, ++idx) c (idx, 0) = to_ov (it->second); return c; } std::map<std::string, cdef_property> cdef_class::cdef_class_rep::get_property_map (int mode) { std::map<std::string,cdef_property> props; find_properties (props, mode); return props; } void cdef_class::cdef_class_rep::find_properties (std::map<std::string, cdef_property>& props, int mode) { property_const_iterator it; for (it = property_map.begin (); it != property_map.end (); ++it) { std::string nm = it->second.get_name (); if (props.find (nm) == props.end ()) { if (mode == property_inherited) { octave_value acc = it->second.get ("GetAccess"); if (! acc.is_string () || acc.string_value () == "private") continue; } props[nm] = it->second; } } // Look into superclasses Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cls.get_rep ()->find_properties (props, (mode == property_all ? property_all : property_inherited)); } } void cdef_class::cdef_class_rep::find_names (std::set<std::string>& names, bool all) { load_all_methods (); for (method_const_iterator it = method_map.begin (); it != method_map.end(); ++it) { if (! it->second.is_constructor ()) { std::string nm = it->second.get_name (); if (! all) { octave_value acc = it->second.get ("Access"); if (! acc.is_string() || acc.string_value () != "public") continue; } names.insert (nm); } } for (property_const_iterator it = property_map.begin (); it != property_map.end (); ++it) { std::string nm = it->second.get_name (); if (! all) { octave_value acc = it->second.get ("GetAccess"); if (! acc.is_string() || acc.string_value () != "public") continue; } names.insert (nm); } // Look into superclasses Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cls.get_rep ()->find_names (names, all); } } string_vector cdef_class::cdef_class_rep::get_names (void) { std::set<std::string> names; find_names (names, false); string_vector v (names.size ()); int idx = 0; for (std::set<std::string>::const_iterator it = names.begin (); it != names.end (); ++it, ++idx) v[idx] = *it; return v.sort (true); } void cdef_class::cdef_class_rep::delete_object (cdef_object obj) { method_iterator it = method_map.find ("delete"); if (it != method_map.end ()) { cdef_class cls = obj.get_class (); obj.set_class (wrap ()); it->second.execute (obj, octave_value_list (), 0, false); obj.set_class (cls); } // FIXME: should we destroy corresponding properties here? // Call "delete" in super classes Cell super_classes = get ("SuperClasses").cell_value (); for (int i = 0; i < super_classes.numel (); i++) { cdef_class cls = lookup_class (super_classes(i)); cls.delete_object (obj); } } octave_value_list cdef_class::cdef_class_rep::meta_subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { size_t skip = 1; octave_value_list retval; switch (type[0]) { case '(': // Constructor call #if DEBUG_TRACE std::cerr << "constructor" << std::endl; #endif retval(0) = construct (idx.front ()); break; case '.': // Static method, constant (or property?) #if DEBUG_TRACE std::cerr << "static method/property" << std::endl; #endif if (idx.front ().length () == 1) { std::string nm = idx.front ()(0).string_value ("invalid meta.class indexing, expected a method or property name"); cdef_method meth = find_method (nm); if (meth.ok ()) { if (meth.is_static ()) { octave_value_list args; if (type.length () > 1 && idx.size () > 1 && type[1] == '(') { args = *(++(idx.begin ())); skip++; } retval = meth.execute (args, (type.length () > skip ? 1 : nargout), true, "meta.class"); } else error ("method `%s' is not static", nm.c_str ()); } else { cdef_property prop = find_property (nm); if (prop.ok ()) { if (prop.is_constant ()) retval(0) = prop.get_value (true, "meta.class"); else error ("property `%s' is not constant", nm.c_str ()); } else error ("no such method or property `%s'", nm.c_str ()); } } else error ("invalid meta.class indexing"); break; default: error ("invalid meta.class indexing"); break; } if (type.length () > skip && idx.size () > skip && ! retval.empty ()) retval = retval(0).next_subsref (nargout, type, idx, skip); return retval; } void cdef_class::cdef_class_rep::meta_release (void) { cdef_manager::unregister_class (wrap ()); } void cdef_class::cdef_class_rep::initialize_object (cdef_object& obj) { // Populate the object with default property values std::list<cdef_class> super_classes = lookup_classes ( get ("SuperClasses").cell_value ()); for (std::list<cdef_class>::iterator it = super_classes.begin (); it != super_classes.end (); ++it) it->initialize_object (obj); for (property_const_iterator it = property_map.begin (); it != property_map.end (); ++it) { if (! it->second.get ("Dependent").bool_value ()) { octave_value pvalue = it->second.get ("DefaultValue"); if (pvalue.is_defined ()) obj.put (it->first, pvalue); else obj.put (it->first, octave_value (Matrix ())); } } refcount++; obj.mark_for_construction (cdef_class (this)); } void cdef_class::cdef_class_rep::run_constructor (cdef_object& obj, const octave_value_list& args) { octave_value_list empty_args; for (std::list<cdef_class>::const_iterator it = implicit_ctor_list.begin (); it != implicit_ctor_list.end (); ++it) { cdef_class supcls = lookup_class (*it); supcls.run_constructor (obj, empty_args); } std::string cls_name = get_name (); std::string ctor_name = get_base_name (cls_name); cdef_method ctor = find_method (ctor_name); if (ctor.ok ()) { octave_value_list ctor_args (args); octave_value_list ctor_retval; ctor_args.prepend (to_ov (obj)); ctor_retval = ctor.execute (ctor_args, 1, true, "constructor"); if (ctor_retval.length () == 1) obj = to_cdef (ctor_retval(0)); else { error ("%s: invalid number of output arguments for classdef constructor", ctor_name.c_str ()); return; } } obj.mark_as_constructed (wrap ()); } octave_value cdef_class::cdef_class_rep::construct (const octave_value_list& args) { cdef_object obj = construct_object (args); if (obj.ok ()) return to_ov (obj); return octave_value (); } cdef_object cdef_class::cdef_class_rep::construct_object (const octave_value_list& args) { if (! is_abstract ()) { cdef_object obj; if (is_meta_class ()) { // This code path is only used to create empty meta objects // as filler for the empty values within a meta object array. cdef_class this_cls = wrap (); static cdef_object empty_class; if (this_cls == cdef_class::meta_class ()) { if (! empty_class.ok ()) empty_class = make_class ("", std::list<cdef_class> ()); obj = empty_class; } else if (this_cls == cdef_class::meta_property ()) { static cdef_property empty_property; if (! empty_class.ok ()) empty_class = make_class ("", std::list<cdef_class> ()); if (! empty_property.ok ()) empty_property = make_property (empty_class, ""); obj = empty_property; } else if (this_cls == cdef_class::meta_method ()) { static cdef_method empty_method; if (! empty_class.ok ()) empty_class = make_class ("", std::list<cdef_class> ()); if (! empty_method.ok ()) empty_method = make_method (empty_class, "", octave_value ()); obj = empty_method; } else if (this_cls == cdef_class::meta_package ()) { static cdef_package empty_package; if (! empty_package.ok ()) empty_package = make_package (""); obj = empty_package; } else panic_impossible (); return obj; } else { if (is_handle_class ()) obj = cdef_object (new handle_cdef_object ()); else obj = cdef_object (new value_cdef_object ()); obj.set_class (wrap ()); initialize_object (obj); run_constructor (obj, args); return obj; } } else error ("cannot instantiate object for abstract class `%s'", get_name ().c_str ()); return cdef_object (); } static octave_value compute_attribute_value (tree_classdef_attribute* t) { if (t->expression ()) { if (t->expression ()->is_identifier ()) { std::string s = t->expression ()->name (); if (s == "public") return std::string ("public"); else if (s == "protected") return std::string ("protected"); else if (s == "private") return std::string ("private"); } return t->expression ()->rvalue1 (); } else return octave_value (true); } template<class T> static std::string attribute_value_to_string (T* t, octave_value v) { if (v.is_string ()) return v.string_value (); else if (t->expression ()) return t->expression ()->original_text (); else return std::string ("true"); } cdef_class cdef_class::make_meta_class (tree_classdef* t, bool is_at_folder) { cdef_class retval; std::string class_name, full_class_name; // Class creation class_name = full_class_name = t->ident ()->name (); if (! t->package_name ().empty ()) full_class_name = t->package_name () + "." + full_class_name; #if DEBUG_TRACE std::cerr << "class: " << full_class_name << std::endl; #endif std::list<cdef_class> slist; if (t->superclass_list ()) { for (tree_classdef_superclass_list::iterator it = t->superclass_list ()->begin (); it != t->superclass_list ()->end (); ++it) { std::string sclass_name = (*it)->class_name (); #if DEBUG_TRACE std::cerr << "superclass: " << sclass_name << std::endl; #endif cdef_class sclass = lookup_class (sclass_name); if (! sclass.get ("Sealed").bool_value ()) slist.push_back (sclass); else { error ("`%s' cannot inherit from `%s', because it is sealed", full_class_name.c_str (), sclass_name.c_str ()); return retval; } } } retval = ::make_class (full_class_name, slist); // Package owning this class if (! t->package_name ().empty ()) { cdef_package pack = cdef_manager::find_package (t->package_name ()); if (pack.ok ()) retval.put ("ContainingPackage", to_ov (pack)); } // Class attributes if (t->attribute_list ()) { for (tree_classdef_attribute_list::iterator it = t->attribute_list ()->begin (); it != t->attribute_list ()->end (); ++it) { std::string aname = (*it)->ident ()->name (); octave_value avalue = compute_attribute_value (*it); #if DEBUG_TRACE std::cerr << "class attribute: " << aname << " = " << attribute_value_to_string (*it, avalue) << std::endl; #endif retval.put (aname, avalue); } } tree_classdef_body* b = t->body (); if (b) { // Keep track of the get/set accessor methods. They will be used // later on when creating properties. std::map<std::string, octave_value> get_methods; std::map<std::string, octave_value> set_methods; // Method blocks std::list<tree_classdef_methods_block *> mb_list = b->methods_list (); for (tree_classdef_body::methods_list_iterator it = mb_list.begin (); it != mb_list.end (); ++it) { std::map<std::string, octave_value> amap; #if DEBUG_TRACE std::cerr << "method block" << std::endl; #endif // Method attributes if ((*it)->attribute_list ()) { for (tree_classdef_attribute_list::iterator ait = (*it)->attribute_list ()->begin (); ait != (*it)->attribute_list ()->end (); ++ait) { std::string aname = (*ait)->ident ()->name (); octave_value avalue = compute_attribute_value (*ait); #if DEBUG_TRACE std::cerr << "method attribute: " << aname << " = " << attribute_value_to_string (*ait, avalue) << std::endl; #endif amap[aname] = avalue; } } // Methods if ((*it)->element_list ()) { for (tree_classdef_methods_list::iterator mit = (*it)->element_list ()->begin (); mit != (*it)->element_list ()->end (); ++mit) { std::string mname = mit->function_value ()->name (); std::string mprefix = mname.substr (0, 4); if (mprefix == "get.") get_methods[mname.substr (4)] = make_fcn_handle (*mit, full_class_name + ">" + mname); else if (mprefix == "set.") set_methods[mname.substr (4)] = make_fcn_handle (*mit, full_class_name + ">" + mname); else { cdef_method meth = make_method (retval, mname, *mit); #if DEBUG_TRACE std::cerr << (mname == class_name ? "constructor" : "method") << ": " << mname << std::endl; #endif for (std::map<std::string, octave_value>::iterator ait = amap.begin (); ait != amap.end (); ++ait) meth.put (ait->first, ait->second); retval.install_method (meth); } } } } if (is_at_folder) { // Look for all external methods visible on octave path at the // time of loading of the class. // // TODO: This is an "extension" to Matlab behavior, which only // looks in the @-folder containing the original classdef // file. However, this is easier to implement it that way at // the moment. std::list<std::string> external_methods = load_path::methods (full_class_name); for (std::list<std::string>::const_iterator it = external_methods.begin (); it != external_methods.end (); ++it) { // TODO: should we issue a warning if the method is already // defined in the classdef file? if (*it != class_name && ! retval.find_method (*it, true).ok ()) { // Create a dummy method that is used until the actual // method is loaded. octave_user_function *fcn = new octave_user_function (); fcn->stash_function_name (*it); cdef_method meth = make_method (retval, *it, octave_value (fcn)); retval.install_method (meth); } } } // Property blocks // FIXME: default property expression should be able to call static // methods of the class being constructed. A restricted CLASSNAME // symbol should be added to the scope before evaluating default // value expressions. std::list<tree_classdef_properties_block *> pb_list = b->properties_list (); for (tree_classdef_body::properties_list_iterator it = pb_list.begin (); it != pb_list.end (); ++it) { std::map<std::string, octave_value> amap; #if DEBUG_TRACE std::cerr << "property block" << std::endl; #endif // Property attributes if ((*it)->attribute_list ()) { for (tree_classdef_attribute_list::iterator ait = (*it)->attribute_list ()->begin (); ait != (*it)->attribute_list ()->end (); ++ait) { std::string aname = (*ait)->ident ()->name (); octave_value avalue = compute_attribute_value (*ait); #if DEBUG_TRACE std::cerr << "property attribute: " << aname << " = " << attribute_value_to_string (*ait, avalue) << std::endl; #endif if (aname == "Access") { amap["GetAccess"] = avalue; amap["SetAccess"] = avalue; } else amap[aname] = avalue; } } // Properties if ((*it)->element_list ()) { for (tree_classdef_property_list::iterator pit = (*it)->element_list ()->begin (); pit != (*it)->element_list ()->end (); ++pit) { std::string prop_name = (*pit)->ident ()->name (); cdef_property prop = ::make_property (retval, prop_name); #if DEBUG_TRACE std::cerr << "property: " << (*pit)->ident ()->name () << std::endl; #endif if ((*pit)->expression ()) { octave_value pvalue = (*pit)->expression ()->rvalue1 (); #if DEBUG_TRACE std::cerr << "property default: " << attribute_value_to_string (*pit, pvalue) << std::endl; #endif prop.put ("DefaultValue", pvalue); } // Install property attributes. This is done before assigning // the property accessors so we can do validationby using // cdef_property methods. for (std::map<std::string, octave_value>::iterator ait = amap.begin (); ait != amap.end (); ++ait) prop.put (ait->first, ait->second); // Install property access methods, if any. Remove the // accessor methods from the temporary storage map, so we can // detect which ones are invalid and do not correspond to a // defined property. std::map<std::string, octave_value>::iterator git = get_methods.find (prop_name); if (git != get_methods.end ()) { make_function_of_class (retval, git->second); prop.put ("GetMethod", git->second); get_methods.erase (git); } std::map<std::string, octave_value>::iterator sit = set_methods.find (prop_name); if (sit != set_methods.end ()) { make_function_of_class (retval, sit->second); prop.put ("SetMethod", sit->second); set_methods.erase (sit); } retval.install_property (prop); } } } } return retval; } octave_function* cdef_class::get_method_function (const std::string& /* nm */) { octave_classdef_meta* p = new octave_classdef_meta (*this); return p; } octave_value cdef_property::cdef_property_rep::get_value (const cdef_object& obj, bool do_check_access, const std::string& who) { octave_value retval; if (do_check_access && ! check_get_access ()) { gripe_property_access (who, wrap (), false); return retval; } if (! obj.is_constructed ()) { cdef_class cls (to_cdef (get ("DefiningClass"))); if (! obj.is_partially_constructed_for (cls)) { error ("cannot reference properties of class `%s' for non-constructed object", cls.get_name ().c_str ()); return retval; } } octave_value get_fcn = get ("GetMethod"); // FIXME: should check whether we're already in get accessor method if (get_fcn.is_empty () || is_method_executing (get_fcn, obj)) retval = obj.get (get ("Name").string_value ()); else { octave_value_list args; args(0) = to_ov (obj); args = execute_ov (get_fcn, args, 1); retval = args(0); } return retval; } octave_value cdef_property::cdef_property_rep::get_value (bool do_check_access, const std::string& who) { if (do_check_access && ! check_get_access ()) { gripe_property_access (who, wrap (), false); return octave_value (); } return get ("DefaultValue"); } bool cdef_property::cdef_property_rep::is_recursive_set (const cdef_object& /* obj */) const { // FIXME: implement return false; } void cdef_property::cdef_property_rep::set_value (cdef_object& obj, const octave_value& val, bool do_check_access, const std::string& who) { if (do_check_access && ! check_set_access ()) { gripe_property_access (who, wrap (), true); return; } if (! obj.is_constructed ()) { cdef_class cls (to_cdef (get ("DefiningClass"))); if (! obj.is_partially_constructed_for (cls)) { error ("cannot reference properties of class `%s' for non-constructed object", cls.get_name ().c_str ()); return; } } octave_value set_fcn = get ("SetMethod"); if (set_fcn.is_empty () || is_method_executing (set_fcn, obj)) obj.put (get ("Name").string_value (), val); else { octave_value_list args; args(0) = to_ov (obj); args(1) = val; args = execute_ov (set_fcn, args, 1); if (args.length () > 0 && args(0).is_defined ()) { if (args (0).is_classdef_object ()) { cdef_object new_obj = to_cdef (args(0)); obj = new_obj; } else ::warning ("set-method of property `%s' returned a non-classdef object", get_name ().c_str ()); } } } bool cdef_property::cdef_property_rep::check_get_access (void) const { cdef_class cls (to_cdef (get ("DefiningClass"))); return ::check_access (cls, get ("GetAccess"), std::string (), get_name (), false); return false; } bool cdef_property::cdef_property_rep::check_set_access (void) const { cdef_class cls (to_cdef (get ("DefiningClass"))); return ::check_access (cls, get ("SetAccess"), std::string (), get_name (), true); return false; } void cdef_method::cdef_method_rep::check_method (void) { if (is_external ()) { if (is_dummy_method (function)) { std::string name = get_name (); std::string cls_name = dispatch_type; std::string pack_name; size_t pos = cls_name.rfind ('.'); if (pos != std::string::npos) { pack_name = cls_name.substr (0, pos); cls_name = cls_name.substr (pos + 1); } std::string dir_name; std::string file_name = load_path::find_method (cls_name, name, dir_name, pack_name); if (! file_name.empty ()) { octave_function *fcn = load_fcn_from_file (file_name, dir_name, dispatch_type, pack_name); if (fcn) { function = octave_value (fcn); make_function_of_class (dispatch_type, function); } } } else { // FIXME: check out-of-date status } if (is_dummy_method (function)) error ("no definition found for method `%s' of class `%s'", get_name ().c_str (), dispatch_type.c_str ()); } } octave_value_list cdef_method::cdef_method_rep::execute (const octave_value_list& args, int nargout, bool do_check_access, const std::string& who) { octave_value_list retval; if (do_check_access && ! check_access ()) { gripe_method_access (who, wrap ()); return retval; } if (! get ("Abstract").bool_value ()) { check_method (); if (function.is_defined ()) retval = execute_ov (function, args, nargout); } else error ("%s: cannot execute abstract method", get ("Name").string_value ().c_str ()); return retval; } octave_value_list cdef_method::cdef_method_rep::execute (const cdef_object& obj, const octave_value_list& args, int nargout, bool do_check_access, const std::string& who) { octave_value_list retval; if (do_check_access && ! check_access ()) { gripe_method_access (who, wrap ()); return retval; } if (! get ("Abstract").bool_value ()) { check_method (); if (function.is_defined ()) { octave_value_list new_args; new_args.resize (args.length () + 1); new_args(0) = to_ov (obj); for (int i = 0; i < args.length (); i++) new_args(i+1) = args(i); retval = execute_ov (function, new_args, nargout); } } else error ("%s: cannot execute abstract method", get ("Name").string_value ().c_str ()); return retval; } bool cdef_method::cdef_method_rep::is_constructor (void) const { if (function.is_function()) return function.function_value ()->is_classdef_constructor (); return false; } bool cdef_method::cdef_method_rep::check_access (void) const { cdef_class cls (to_cdef (get ("DefiningClass"))); return ::check_access (cls, get ("Access"), get_name ()); } octave_value_list cdef_method::cdef_method_rep::meta_subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { octave_value_list retval; switch (type[0]) { case '(': retval = execute (idx.front (), type.length () > 1 ? 1 : nargout, true); break; default: error ("invalid meta.method indexing"); break; } if (type.length () > 1 && idx.size () > 1 && ! retval.empty ()) retval = retval(0).next_subsref (nargout, type, idx, 1); return retval; } static cdef_package lookup_package (const std::string& name) { return cdef_manager::find_package (name); } static octave_value_list package_fromName (const octave_value_list& args, int /* nargout */) { octave_value_list retval; if (args.length () == 1) { std::string name = args(0).string_value ("fromName: invalid package name, expected a string value"); retval(0) = to_ov (lookup_package (name)); } else error ("fromName: invalid number of parameters"); return retval; } static octave_value_list package_get_classes (const octave_value_list& args, int /* nargout */) { octave_value_list retval (1, Matrix ()); if (args.length () == 1 && args(0).type_name () == "object" && args(0).class_name () == "meta.package") { cdef_package pack (to_cdef (args(0))); retval(0) = pack.get_classes (); } return retval; } static octave_value_list package_get_functions (const octave_value_list& args, int /* nargout */) { octave_value_list retval (1, Matrix ()); if (args.length () == 0 && args(0).type_name () == "object" && args(0).class_name () == "meta.package") { cdef_package pack (to_cdef (args(0))); retval(0) = pack.get_functions (); } return retval; } static octave_value_list package_get_packages (const octave_value_list& args, int /* nargout */) { octave_value_list retval (1, Matrix ()); if (args.length () == 0 && args(0).type_name () == "object" && args(0).class_name () == "meta.package") { cdef_package pack (to_cdef (args(0))); retval(0) = pack.get_packages (); } return retval; } static octave_value_list package_getAllPackages (const octave_value_list& /* args */, int /* nargout */) { std::map<std::string, cdef_package> toplevel_packages; std::list<std::string> names = load_path::get_all_package_names (); toplevel_packages["meta"] = cdef_manager::find_package ("meta", false, false); for (std::list<std::string>::const_iterator it = names.begin (); it != names.end (); ++it) toplevel_packages[*it] = cdef_manager::find_package (*it, false, true); Cell c (toplevel_packages.size (), 1); int i = 0; for (std::map<std::string, cdef_package>::const_iterator it = toplevel_packages.begin (); it != toplevel_packages.end (); ++it) c(i++,0) = to_ov (it->second); return octave_value_list (octave_value (c)); } void cdef_package::cdef_package_rep::install_class (const cdef_class& cls, const std::string& nm) { class_map[nm] = cls; member_count++; } void cdef_package::cdef_package_rep::install_function (const octave_value& fcn, const std::string& nm) { function_map[nm] = fcn; } void cdef_package::cdef_package_rep::install_package (const cdef_package& pack, const std::string& nm) { package_map[nm] = pack; member_count++; } template<class T1, class T2> Cell map2Cell (const std::map<T1, T2>& m) { Cell retval (1, m.size ()); int i = 0; for (typename std::map<T1, T2>::const_iterator it = m.begin (); it != m.end (); ++it, ++i) { retval(i) = to_ov (it->second); } return retval; } Cell cdef_package::cdef_package_rep::get_classes (void) const { return map2Cell (class_map); } Cell cdef_package::cdef_package_rep::get_functions (void) const { return map2Cell (function_map); } Cell cdef_package::cdef_package_rep::get_packages (void) const { return map2Cell (package_map); } octave_value cdef_package::cdef_package_rep::find (const std::string& nm) { std::string symbol_name = get_name () + "." + nm; return symbol_table::find (symbol_name, octave_value_list (), true, false); } octave_value_list cdef_package::cdef_package_rep::meta_subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout) { octave_value_list retval; switch (type[0]) { case '.': if (idx.front ().length () == 1) { std::string nm = idx.front ()(0).string_value ("invalid meta.package indexing, expected a symbol name"); #if DEBUG_TRACE std::cerr << "meta.package query: " << nm << std::endl; #endif octave_value o = find (nm); if (o.is_defined ()) { if (o.is_function ()) { octave_function* fcn = o.function_value (); // NOTE: the case where the package query is the last // part of this subsref index is handled in the parse // tree, because there is some logic to handle magic // "end" that makes it impossible to execute the // function call at this stage. if (type.size () > 1 && ! fcn->is_postfix_index_handled (type[1])) { octave_value_list tmp_args; retval = o.do_multi_index_op (nargout, tmp_args); } else retval(0) = o; if (type.size () > 1 && idx.size () > 1) retval = retval(0).next_subsref (nargout, type, idx, 1); } else if (type.size () > 1 && idx.size () > 1) retval = o.next_subsref (nargout, type, idx, 1); else retval(0) = o; } else if (! error_state) error ("member `%s' in package `%s' does not exist", nm.c_str (), get_name ().c_str ()); } else error ("invalid meta.package indexing"); break; default: error ("invalid meta.package indexing"); break; } return retval; } void cdef_package::cdef_package_rep::meta_release (void) { // FIXME: Do we really want to unregister the package, as it // could still be referenced by classes or sub-packages? // If the package object is recreated later on, it won't // match the one already referenced by those classes or // sub-packages. //cdef_manager::unregister_package (wrap ()); } cdef_class cdef_class::_meta_class = cdef_class (); cdef_class cdef_class::_meta_property = cdef_class (); cdef_class cdef_class::_meta_method = cdef_class (); cdef_class cdef_class::_meta_package = cdef_class (); cdef_package cdef_package::_meta = cdef_package (); void install_classdef (void) { octave_classdef::register_type (); /* bootstrap */ cdef_class handle = make_class ("handle"); cdef_class meta_class = cdef_class::_meta_class = make_meta_class ("meta.class", handle); handle.set_class (meta_class); meta_class.set_class (meta_class); /* meta classes */ cdef_class meta_property = cdef_class::_meta_property = make_meta_class ("meta.property", handle); cdef_class meta_method = cdef_class::_meta_method = make_meta_class ("meta.method", handle); cdef_class meta_package = cdef_class::_meta_package = make_meta_class ("meta.package", handle); cdef_class meta_event = make_meta_class ("meta.event", handle); cdef_class meta_dynproperty = make_meta_class ("meta.dynamicproperty", handle); /* meta.class properties */ meta_class.install_property (make_attribute (meta_class, "Abstract")); meta_class.install_property (make_attribute (meta_class, "ConstructOnLoad")); meta_class.install_property (make_property (meta_class, "ContainingPackage")); meta_class.install_property (make_property (meta_class, "Description")); meta_class.install_property (make_property (meta_class, "DetailedDescription")); meta_class.install_property (make_property (meta_class, "Events")); meta_class.install_property (make_attribute (meta_class, "HandleCompatible")); meta_class.install_property (make_attribute (meta_class, "Hidden")); meta_class.install_property (make_property (meta_class, "InferiorClasses", make_fcn_handle (class_get_inferiorclasses, "meta.class>get.InferiorClasses"), "public", Matrix (), "private")); meta_class.install_property (make_property (meta_class, "Methods", make_fcn_handle (class_get_methods, "meta.class>get.Methods"), "public", Matrix (), "private")); meta_class.install_property (make_property (meta_class, "MethodList", make_fcn_handle (class_get_methods, "meta.class>get.MethodList"), "public", Matrix (), "private")); meta_class.install_property (make_attribute (meta_class, "Name")); meta_class.install_property (make_property (meta_class, "Properties", make_fcn_handle (class_get_properties, "meta.class>get.Properties"), "public", Matrix (), "private")); meta_class.install_property (make_property (meta_class, "PropertyList", make_fcn_handle (class_get_properties, "meta.class>get.PropertyList"), "public", Matrix (), "private")); meta_class.install_property (make_attribute (meta_class, "Sealed")); meta_class.install_property (make_property (meta_class, "SuperClasses", make_fcn_handle (class_get_superclasses, "meta.class>get.SuperClasses"), "public", Matrix (), "private")); meta_class.install_property (make_property (meta_class, "SuperClassList", make_fcn_handle (class_get_superclasses, "meta.class>get.SuperClassList"), "public", Matrix (), "private")); /* meta.class methods */ meta_class.install_method (make_method (meta_class, "fromName", class_fromName, "public", true)); meta_class.install_method (make_method (meta_class, "fevalStatic", class_fevalStatic, "public", false)); meta_class.install_method (make_method (meta_class, "getConstant", class_getConstant, "public", false)); meta_class.install_method (make_method (meta_class, "eq", class_eq)); meta_class.install_method (make_method (meta_class, "ne", class_ne)); meta_class.install_method (make_method (meta_class, "lt", class_lt)); meta_class.install_method (make_method (meta_class, "le", class_le)); meta_class.install_method (make_method (meta_class, "gt", class_gt)); meta_class.install_method (make_method (meta_class, "ge", class_ge)); /* meta.method properties */ meta_method.install_property (make_attribute (meta_method, "Abstract")); meta_method.install_property (make_attribute (meta_method, "Access")); meta_method.install_property (make_attribute (meta_method, "DefiningClass")); meta_method.install_property (make_attribute (meta_method, "Description")); meta_method.install_property (make_attribute (meta_method, "DetailedDescription")); meta_method.install_property (make_attribute (meta_method, "Hidden")); meta_method.install_property (make_attribute (meta_method, "Name")); meta_method.install_property (make_attribute (meta_method, "Sealed")); meta_method.install_property (make_attribute (meta_method, "Static")); /* meta.property properties */ meta_property.install_property (make_attribute (meta_property, "Name")); meta_property.install_property (make_attribute (meta_property, "Description")); meta_property.install_property (make_attribute (meta_property, "DetailedDescription")); meta_property.install_property (make_attribute (meta_property, "Abstract")); meta_property.install_property (make_attribute (meta_property, "Constant")); meta_property.install_property (make_attribute (meta_property, "GetAccess")); meta_property.install_property (make_attribute (meta_property, "SetAccess")); meta_property.install_property (make_attribute (meta_property, "Dependent")); meta_property.install_property (make_attribute (meta_property, "Transient")); meta_property.install_property (make_attribute (meta_property, "Hidden")); meta_property.install_property (make_attribute (meta_property, "GetObservable")); meta_property.install_property (make_attribute (meta_property, "SetObservable")); meta_property.install_property (make_attribute (meta_property, "GetMethod")); meta_property.install_property (make_attribute (meta_property, "SetMethod")); meta_property.install_property (make_attribute (meta_property, "DefiningClass")); meta_property.install_property (make_property (meta_property, "DefaultValue", make_fcn_handle (property_get_defaultvalue, "meta.property>get.DefaultValue"), "public", Matrix (), "private")); meta_property.install_property (make_attribute (meta_property, "HasDefault")); /* meta.property events */ // FIXME: add events /* handle methods */ handle.install_method (make_method (handle, "delete", handle_delete)); /* meta.package properties */ meta_package.install_property (make_attribute (meta_package, "Name")); meta_package.install_property (make_property (meta_package, "ContainingPackage")); meta_package.install_property (make_property (meta_package, "ClassList", make_fcn_handle (package_get_classes, "meta.package>get.ClassList"), "public", Matrix (), "private")); meta_package.install_property (make_property (meta_package, "Classes", make_fcn_handle (package_get_classes, "meta.package>get.Classes"), "public", Matrix (), "private")); meta_package.install_property (make_property (meta_package, "FunctionList", make_fcn_handle (package_get_functions, "meta.package>get.FunctionList"), "public", Matrix (), "private")); meta_package.install_property (make_property (meta_package, "Functions", make_fcn_handle (package_get_functions, "meta.package>get.Functions"), "public", Matrix (), "private")); meta_package.install_property (make_property (meta_package, "PackageList", make_fcn_handle (package_get_packages, "meta.package>get.PackageList"), "public", Matrix (), "private")); meta_package.install_property (make_property (meta_package, "Packages", make_fcn_handle (package_get_packages, "meta.package>get.Packages"), "public", Matrix (), "private")); meta_package.install_method (make_method (meta_package, "fromName", package_fromName, "public", true)); meta_package.install_method (make_method (meta_package, "getAllPackages", package_getAllPackages, "public", true)); /* create "meta" package */ cdef_package package_meta = cdef_package::_meta = make_package ("meta"); package_meta.install_class (meta_class, "class"); package_meta.install_class (meta_property, "property"); package_meta.install_class (meta_method, "method"); package_meta.install_class (meta_package, "package"); package_meta.install_class (meta_event, "event"); package_meta.install_class (meta_dynproperty, "dynproperty"); /* install built-in classes into the symbol table */ symbol_table::install_built_in_function ("meta.class", octave_value (meta_class.get_constructor_function ())); symbol_table::install_built_in_function ("meta.method", octave_value (meta_method.get_constructor_function ())); symbol_table::install_built_in_function ("meta.property", octave_value (meta_property.get_constructor_function ())); symbol_table::install_built_in_function ("meta.package", octave_value (meta_package.get_constructor_function ())); symbol_table::install_built_in_function ("meta.event", octave_value (meta_event.get_constructor_function ())); symbol_table::install_built_in_function ("meta.dynproperty", octave_value (meta_dynproperty.get_constructor_function ())); } //---------------------------------------------------------------------------- cdef_manager* cdef_manager::instance = 0; void cdef_manager::create_instance (void) { instance = new cdef_manager (); if (instance) singleton_cleanup_list::add (cleanup_instance); } cdef_class cdef_manager::do_find_class (const std::string& name, bool error_if_not_found, bool load_if_not_found) { std::map<std::string, cdef_class>::iterator it = all_classes.find (name); if (it == all_classes.end ()) { if (load_if_not_found) { octave_value ov_cls; size_t pos = name.rfind ('.'); if (pos == std::string::npos) ov_cls = symbol_table::find (name); else { std::string pack_name = name.substr (0, pos); cdef_package pack = do_find_package (pack_name, false, true); if (pack.ok ()) ov_cls = pack.find (name.substr (pos+1)); } if (ov_cls.is_defined ()) it = all_classes.find (name); } } if (it == all_classes.end ()) { if (error_if_not_found) error ("class not found: %s", name.c_str ()); } else { cdef_class cls = it->second; if (! cls.is_builtin ()) cls = lookup_class (cls); if (cls.ok ()) return cls; else all_classes.erase (it); } return cdef_class (); } octave_function* cdef_manager::do_find_method_symbol (const std::string& method_name, const std::string& class_name) { octave_function *retval = 0; cdef_class cls = find_class (class_name, false, false); if (cls.ok ()) { cdef_method meth = cls.find_method (method_name); if (meth.ok ()) retval = new octave_classdef_meta (meth); } return retval; } cdef_package cdef_manager::do_find_package (const std::string& name, bool error_if_not_found, bool load_if_not_found) { cdef_package retval; std::map<std::string, cdef_package>::const_iterator it = all_packages.find (name); if (it != all_packages.end ()) { retval = it->second; if (! retval.ok ()) error ("invalid package `%s'", name.c_str ()); } else { if (load_if_not_found && load_path::find_package (name)) { size_t pos = name.find ('.'); if (pos == std::string::npos) retval = make_package (name, std::string ()); else { std::string parent_name = name.substr (0, pos); retval = make_package (name, parent_name); } } else if (error_if_not_found) error ("unknown package `%s'", name.c_str ()); } return retval; } octave_function* cdef_manager::do_find_package_symbol (const std::string& pack_name) { octave_function* retval = 0; cdef_package pack = find_package (pack_name, false); if (pack.ok ()) retval = new octave_classdef_meta (pack); return retval; } //---------------------------------------------------------------------------- DEFUN (__meta_get_package__, args, , "") { octave_value retval; if (args.length () == 1) { std::string cname = args(0).string_value ("invalid package name, expected a string value"); retval = to_ov (lookup_package (cname)); } else print_usage (); return retval; } DEFUN (__superclass_reference__, args, /* nargout */, "-*- texinfo -*-\n\ @deftypefn {Built-in Function} {} __superclass_reference__ ()\n\ Undocumented internal function.\n\ @end deftypefn") { return octave_value (new octave_classdef_superclass_ref (args)); } DEFUN (__meta_class_query__, args, /* nargout */, "-*- texinfo -*-\n\ @deftypefn {Built-in Function} {} __meta_class_query__ ()\n\ Undocumented internal function.\n\ @end deftypefn") { octave_value retval; #if DEBUG_TRACE std::cerr << "__meta_class_query__ (" << args(0).string_value () << ")" << std::endl; #endif if (args.length () == 1) { std::string cls = args(0).string_value ("invalid class name, expected a string value"); retval = to_ov (lookup_class (cls)); } else print_usage (); return retval; } DEFUN (metaclass, args, /* nargout */, "-*- texinfo -*-\n\ @deftypefn {Built-in Function} {} metaclass (obj)\n\ Returns the meta.class object corresponding to the class of @var{obj}.\n\ @end deftypefn") { octave_value retval; if (args.length () == 1) { cdef_object obj = to_cdef (args(0)); if (! error_state) retval = to_ov (obj.get_class ()); else print_usage (); } else print_usage (); return retval; } /* ;;; Local Variables: *** ;;; mode: C++ *** ;;; End: *** */