Mercurial > octave-nkf
view src/unwind-prot.h @ 14138:72c96de7a403 stable
maint: update copyright notices for 2012
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Mon, 02 Jan 2012 14:25:41 -0500 |
| parents | e0e50f48df37 |
| children |
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/* Copyright (C) 1993-2012 John W. Eaton Copyright (C) 2009-2010 VZLU Prague 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/>. */ #if !defined (octave_unwind_prot_h) #define octave_unwind_prot_h 1 #include <cstddef> #include <string> #include <memory> // This class allows registering cleanup actions. class OCTINTERP_API unwind_protect { public: // A generic unwind_protect element. Knows how to run itself and discard itself. // Also, contains a pointer to the next element. class elem { elem *next; public: elem (void) : next (0) { } virtual void run (void) { } virtual ~elem (void) { } friend class unwind_protect; private: // No copying! elem (const elem&); elem& operator = (const elem&); }; // An element that merely runs a void (*)(void) function. class fcn_elem : public elem { public: fcn_elem (void (*fptr) (void)) : e_fptr (fptr) { } void run (void) { e_fptr (); } private: void (*e_fptr) (void); }; // An element that stores a variable of type T along with a void (*) (T) // function pointer, and calls the function with the parameter. template <class T> class fcn_arg_elem : public elem { public: fcn_arg_elem (void (*fcn) (T), T arg) : e_fcn (fcn), e_arg (arg) { } void run (void) { e_fcn (e_arg); } private: // No copying! fcn_arg_elem (const fcn_arg_elem&); fcn_arg_elem& operator = (const fcn_arg_elem&); void (*e_fcn) (T); T e_arg; }; // An element that stores a variable of type T along with a void (*) (const T&) // function pointer, and calls the function with the parameter. template <class T> class fcn_crefarg_elem : public elem { public: fcn_crefarg_elem (void (*fcn) (const T&), T arg) : e_fcn (fcn), e_arg (arg) { } void run (void) { e_fcn (e_arg); } private: void (*e_fcn) (const T&); T e_arg; }; // An element for calling a member function. template <class T> class method_elem : public elem { public: method_elem (T *obj, void (T::*method) (void)) : e_obj (obj), e_method (method) { } void run (void) { (e_obj->*e_method) (); } private: T *e_obj; void (T::*e_method) (void); // No copying! method_elem (const method_elem&); method_elem operator = (const method_elem&); }; // An element that stores arbitrary variable, and restores it. template <class T> class restore_var_elem : public elem { public: restore_var_elem (T& ref, const T& val) : e_ptr (&ref), e_val (val) { } void run (void) { *e_ptr = e_val; } private: // No copying! restore_var_elem (const restore_var_elem&); restore_var_elem& operator = (const restore_var_elem&); T *e_ptr, e_val; }; // Deletes a class allocated using new. template <class T> class delete_ptr_elem : public elem { public: delete_ptr_elem (T *ptr) : e_ptr (ptr) { } void run (void) { delete e_ptr; } private: T *e_ptr; // No copying! delete_ptr_elem (const delete_ptr_elem&); delete_ptr_elem operator = (const delete_ptr_elem&); }; unwind_protect (void) : head () { } void add (elem *new_elem) { new_elem->next = head; head = new_elem; } // For backward compatibility. void add (void (*fcn) (void *), void *ptr = 0) { add (new fcn_arg_elem<void *> (fcn, ptr)); } // Call to void func (void). void add_fcn (void (*fcn) (void)) { add (new fcn_elem (fcn)); } // Call to void func (T). template <class T> void add_fcn (void (*action) (T), T val) { add (new fcn_arg_elem<T> (action, val)); } // Call to void func (const T&). template <class T> void add_fcn (void (*action) (const T&), T val) { add (new fcn_crefarg_elem<T> (action, val)); } // Call to T::method (void). template <class T> void add_method (T *obj, void (T::*method) (void)) { add (new method_elem<T> (obj, method)); } // Call to delete (T*). template <class T> void add_delete (T *obj) { add (new delete_ptr_elem<T> (obj)); } // Protect any variable. template <class T> void protect_var (T& var) { add (new restore_var_elem<T> (var, var)); } // Protect any variable, value given. template <class T> void protect_var (T& var, const T& val) { add (new restore_var_elem<T> (var, val)); } operator bool (void) const { return head != 0; } void run_top (void) { if (head) { // No leak on exception! std::auto_ptr<elem> ptr (head); head = ptr->next; ptr->run (); } } void run_top (int num) { while (num-- > 0) run_top (); } void discard_top (void) { if (head) { elem *ptr = head; head = ptr->next; delete ptr; } } void discard_top (int num) { while (num-- > 0) discard_top (); } void run (void) { while (head) run_top (); } void discard (void) { while (head) discard_top (); } // Destructor should not raise an exception, so all actions registered should // be exception-safe (but setting error_state is allowed). If you're not sure, // see unwind_protect_safe. ~unwind_protect (void) { run (); } private: elem *head; // No copying! unwind_protect (const unwind_protect&); unwind_protect& operator = (const unwind_protect&); }; // Like unwind_protect, but this one will guard against the possibility of seeing // an exception (or interrupt) in the cleanup actions. Not that we can do much about // it, but at least we won't crash. class OCTINTERP_API unwind_protect_safe : public unwind_protect { static void gripe_exception (void); public: ~unwind_protect_safe (void) { while (*this) { try { run_top (); } catch (...) // Yes, the black hole. Remember we're in a dtor. { gripe_exception (); } } } }; #endif