Mercurial > octave
view libinterp/octave-value/cdef-object.cc @ 31105:670a0d878af1
eliminate WHO arguments from interpreter-private functions
* interpreter-private.h, inpterpreter-private.cc (__get_interpreter__,
__get_dynamic_loader__, __get_error_system__, __get_gh_manager__,
__get_help_system__, __get_input_system__, __get_load_path__,
__get_load_save_system__, __get_event_manager__,
__get_output_system__, __get_type_info__, __get_symbol_table__,
__get_current_scope__, __require_current_scope__, __get_evaluator__,
__get_bp_table__, __get_child_list__, __get_cdef_manager__,
__get_display_info__, __get_gtk_manager__): Eliminate WHO argument.
Previously, it was never displayed by __get_interpreter__. And, as
pointed out by Petter Tomner in patch #10216, passing a std::string
object could have performance issues.
(__get_interpreter__): Eliminate useless call to error. Display
message to std::cerr then abort.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Wed, 22 Jun 2022 12:48:59 -0400 |
| parents | 83f9f8bda883 |
| children | e88a07dec498 |
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//////////////////////////////////////////////////////////////////////// // // Copyright (C) 2012-2022 The Octave Project Developers // // See the file COPYRIGHT.md in the top-level directory of this // distribution or <https://octave.org/copyright/>. // // 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 // <https://www.gnu.org/licenses/>. // //////////////////////////////////////////////////////////////////////// #if defined (HAVE_CONFIG_H) # include "config.h" #endif #include "cdef-class.h" #include "cdef-object.h" #include "cdef-property.h" #include "cdef-utils.h" #include "interpreter.h" #include "interpreter-private.h" #include "ov-classdef.h" // Define to 1 to enable debugging statements. #define DEBUG_TRACE 0 namespace octave { void cdef_object_rep::release (const cdef_object& obj) { // We need to be careful to keep a reference to the object if we are // calling the delete method. The object is passed to the delete // method as an argument and if the count is already zero when we // do that, then we will increment the count while creating the // argument list for the delete method and then it will be decremented // back to zero and we'll find ourselves in an infinite loop. if (m_count - 1 > static_count ()) { --m_count; return; } if (is_handle_object () && ! is_meta_object ()) { unwind_protect frame; // Clear interrupts. frame.protect_var (octave_interrupt_state); octave_interrupt_state = 0; // Disallow quit(). frame.protect_var (quit_allowed); quit_allowed = false; interpreter& interp = __get_interpreter__ (); interpreter_try (frame); try { // Call classdef "delete()" method on object get_class ().delete_object (obj); } catch (const interrupt_exception&) { interp.recover_from_exception (); warning ("interrupt occurred in handle class delete method"); } catch (const execution_exception& ee) { interp.recover_from_exception (); std::string msg = ee.message (); warning ("error caught while executing handle class delete method:\n%s\n", msg.c_str ()); } catch (const exit_exception&) { // This shouldn't happen since we disabled quit above. warning ("exit disabled while executing handle class delete method"); } catch (...) // Yes, the black hole. We're in a d-tor. { // This shouldn't happen, in theory. warning ("internal error: unhandled exception in handle class delete method"); } } // Now it is safe to set the count to zero. m_count--; destroy (); } cdef_class cdef_object_rep::get_class (void) const { err_invalid_object ("get_class"); } std::string cdef_object_rep::class_name (void) const { return get_class ().get_name (); } 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_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); // FIXME: Why not const here? for (auto& prop_val : props) { 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) = prop_val.second.get_value (a_obj(i), false); retval.setfield (prop_val.first, cvalue); } else { Cell cvalue (dim_vector (1, 1), prop_val.second.get_value (*this, false)); retval.setfield (prop_val.first, cvalue); } } } return retval; } cdef_class cdef_object::get_class (void) const { return m_rep->get_class (); } cdef_class cdef_object_base::get_class (void) const { return cdef_class (m_klass); } void cdef_object_base::set_class (const cdef_class& cls) { if ((m_klass.ok () && cls.ok () && cls != get_class ()) || (m_klass.ok () && ! cls.ok ()) || (! m_klass.ok () && cls.ok ())) { m_klass = cls; } } cdef_object_rep * cdef_object_base::make_array (void) const { cdef_object_rep *r = new cdef_object_array (); r->set_class (get_class ()); return r; } octave_value_list cdef_object_array::subsref (const std::string& type, const std::list<octave_value_list>& idx, int /* nargout */, std::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 ()) { m_count++; 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& ie) { // Rethrow to allow more info to be reported later. ie.set_pos_if_unset (ival.length (), i+1); throw; } is_scalar = is_scalar && iv(i).is_scalar (); } Array<cdef_object> ires = m_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 = m_array.numel (); // dummy variables std::size_t dummy_skip; cdef_class dummy_cls; for (octave_idx_type i = 0; i < n; i++) { octave_value_list r = m_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; } OCTAVE_FALLTHROUGH; 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 ()) error ("can't assign %s object into array of %s objects", rhs_obj.class_name ().c_str (), class_name ().c_str ()); 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& ie) { ie.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 = m_array.numel (); m_array.assign (iv, rhs_mat, cdef_object ()); if (m_array.numel () > n) fill_empty_values (); m_count++; retval = to_ov (cdef_object (this)); } else { const octave_value_list& ivl = idx.front (); // Fill in trailing singleton dimensions so that // array.index doesn't create a new blank entry (bug #46660). const octave_idx_type one = static_cast<octave_idx_type> (1); const octave_value_list& ival = ivl.length () >= 2 ? ivl : ((m_array.dims ()(0) == 1) ? ovl (one, ivl(0)) : ovl (ivl(0), one)); 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& ie) { // Rethrow to allow more info to be reported later. ie.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 = m_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 ()) error ("subsasgn: invalid assignment into array of %s objects", class_name ().c_str ()); // 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 = m_array.numel (); m_array.assign (iv, rhs_a); if (m_array.numel () > n) fill_empty_values (); } m_count++; retval = to_ov (cdef_object (this)); } 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 (); } } } void cdef_object_scalar::break_closure_cycles (const std::shared_ptr<stack_frame>& frame) { for (octave_idx_type i = 0; i < m_map.nfields (); i++) m_map.contents(i).break_closure_cycles (frame); } octave_value_list cdef_object_scalar::subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout, std::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] == '(') { auto it = idx.begin (); args = *++it; skip++; } if (meth.is_static ()) retval = meth.execute (args, _nargout, true, "subsref"); else { m_count++; retval = meth.execute (cdef_object (this), args, _nargout, true, "subsref"); } } if (skip == 0) { cdef_property prop = cls.find_property (name); if (! prop.ok ()) error ("subsref: unknown method or property: %s", name.c_str ()); if (prop.is_constant ()) retval(0) = prop.get_value (true, "subsref"); else { m_count++; retval(0) = prop.get_value (cdef_object (this), true, "subsref"); } skip = 1; } break; } case '(': { const octave_value_list& ival = idx.front (); m_count++; 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 ()) error ("subsasgn: unknown property: %s", name.c_str ()); if (prop.is_constant ()) error ("subsasgn: cannot assign constant property: %s", name.c_str ()); m_count++; 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); } } break; case '(': { m_count++; 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); m_ctor_list[cls] = supcls_list; } bool cdef_object_scalar::is_constructed_for (const cdef_class& cls) const { return (is_constructed () || m_ctor_list.find (cls) == m_ctor_list.end ()); } bool cdef_object_scalar::is_partially_constructed_for (const cdef_class& cls) const { if (is_constructed ()) return true; std::map<cdef_class, std::list<cdef_class>>::const_iterator it = m_ctor_list.find (cls); if (it == m_ctor_list.end () || it->second.empty ()) return true; for (const auto& cdef_cls : it->second) if (! is_partially_constructed_for (cdef_cls)) return false; return true; } void cdef_object_scalar::mark_as_constructed (const cdef_class& cls) { m_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 } }