Mercurial > octave-nkf
view libinterp/corefcn/toplev.h @ 20500:44eb1102f8a8
don't recycle scanf format string if all conversions are done (bug #45808)
* oct-stream.cc, oct-stream.h (scanf_format_elt::special_conversion):
New enum value, no_conversion.
(scanf_format_list::next): If not cycling through the list, return
dummy scanf_format_elt after list has been exhausted.
(octave_base_stream::do_scanf): Only cycle through the format list
more than once if there are conversions to make and the limit on the
number of values to convert has not been reached.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Wed, 26 Aug 2015 16:05:49 -0400 |
| parents | 7ac907da9fba |
| children | 9502e0142c19 |
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/* Copyright (C) 1993-2015 John W. Eaton 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_toplev_h) #define octave_toplev_h 1 #include <cstdio> #include <deque> #include <string> class octave_value; class octave_value_list; class octave_function; class octave_user_script; class tree_statement; class tree_statement_list; class charMatrix; #include "quit.h" #include "input.h" #include "oct-map.h" #include "symtab.h" typedef void (*octave_exit_func) (int); extern OCTINTERP_API octave_exit_func octave_exit; extern OCTINTERP_API bool quit_allowed; extern OCTINTERP_API bool quitting_gracefully; extern OCTINTERP_API int exit_status; extern OCTINTERP_API void clean_up_and_exit (int status, bool safe_to_return = false); extern OCTINTERP_API void recover_from_exception (void); extern OCTINTERP_API int main_loop (void); extern OCTINTERP_API void octave_add_atexit_function (const std::string& fname); extern OCTINTERP_API bool octave_remove_atexit_function (const std::string& fname); // TRUE means we are ready to interpret commands, but not everything // is ready for interactive use. extern OCTINTERP_API bool octave_interpreter_ready; // TRUE means we've processed all the init code and we are good to go. extern OCTINTERP_API bool octave_initialized; class OCTINTERP_API octave_call_stack { protected: octave_call_stack (void) : cs (), curr_frame (0) { } public: class stack_frame { public: friend class octave_call_stack; stack_frame (octave_function *fcn = 0, symbol_table::scope_id scope = 0, symbol_table::context_id context = 0, size_t prev = 0) : m_fcn (fcn), m_line (-1), m_column (-1), m_scope (scope), m_context (context), m_prev (prev) { } stack_frame (const stack_frame& elt) : m_fcn (elt.m_fcn), m_line (elt.m_line), m_column (elt.m_column), m_scope (elt.m_scope), m_context (elt.m_context), m_prev (elt.m_prev) { } int line (void) const { return m_line; } int column (void) const { return m_column; } std::string fcn_file_name (void) const; std::string fcn_name (bool print_subfn = true) const; private: octave_function *m_fcn; int m_line; int m_column; symbol_table::scope_id m_scope; symbol_table::context_id m_context; size_t m_prev; }; typedef std::deque<stack_frame>::iterator iterator; typedef std::deque<stack_frame>::const_iterator const_iterator; typedef std::deque<stack_frame>::reverse_iterator reverse_iterator; typedef std::deque<stack_frame>::const_reverse_iterator const_reverse_iterator; static void create_instance (void); static bool instance_ok (void) { bool retval = true; if (! instance) create_instance (); if (! instance) { error ("unable to create call stack object!"); retval = false; } return retval; } // Current function (top of stack). static octave_function *current (void) { return instance_ok () ? instance->do_current () : 0; } // Current line in current function. static int current_line (void) { return instance_ok () ? instance->do_current_line () : -1; } // Current column in current function. static int current_column (void) { return instance_ok () ? instance->do_current_column () : -1; } // Line in user code caller. static int caller_user_code_line (void) { return instance_ok () ? instance->do_caller_user_code_line () : -1; } // Column in user code caller. static int caller_user_code_column (void) { return instance_ok () ? instance->do_caller_user_code_column () : -1; } // Caller function, may be built-in. static octave_function *caller (void) { return instance_ok () ? instance->do_caller () : 0; } static size_t current_frame (void) { return instance_ok () ? instance->do_current_frame () : 0; } static size_t size (void) { return instance_ok () ? instance->do_size () : 0; } static size_t num_user_code_frames (octave_idx_type& curr_user_frame) { return instance_ok () ? instance->do_num_user_code_frames (curr_user_frame) : 0; } static symbol_table::scope_id current_scope (void) { return instance_ok () ? instance->do_current_scope () : 0; } static symbol_table::context_id current_context (void) { return instance_ok () ? instance->do_current_context () : 0; } /* static stack_frame frame (size_t idx) { return instance_ok () ? instance->do_frame (idx) : stack_frame (); } */ // Function at location N on the call stack (N == 0 is current), may // be built-in. static octave_function *element (size_t n) { return instance_ok () ? instance->do_element (n) : 0; } // First user-defined function on the stack. static octave_user_code *caller_user_code (size_t nskip = 0) { return instance_ok () ? instance->do_caller_user_code (nskip) : 0; } // Return TRUE if all elements on the call stack are scripts. static bool all_scripts (void) { return instance_ok () ? instance->do_all_scripts () : false; } static void push (octave_function *f, symbol_table::scope_id scope = symbol_table::current_scope (), symbol_table::context_id context = symbol_table::current_context ()) { if (instance_ok ()) instance->do_push (f, scope, context); } static void push (symbol_table::scope_id scope = symbol_table::current_scope (), symbol_table::context_id context = symbol_table::current_context ()) { if (instance_ok ()) instance->do_push (0, scope, context); } static void set_location (int l, int c) { if (instance_ok ()) instance->do_set_location (l, c); } static void set_line (int l) { if (instance_ok ()) instance->do_set_line (l); } static void set_column (int c) { if (instance_ok ()) instance->do_set_column (c); } static bool goto_frame (size_t n = 0, bool verbose = false) { return instance_ok () ? instance->do_goto_frame (n, verbose) : false; } static void restore_frame (size_t n) { goto_frame (n); } static bool goto_frame_relative (int n, bool verbose = false) { return instance_ok () ? instance->do_goto_frame_relative (n, verbose) : false; } static void goto_caller_frame (void) { if (instance_ok ()) instance->do_goto_caller_frame (); } static void goto_base_frame (void) { if (instance_ok ()) instance->do_goto_base_frame (); } static octave_map backtrace (size_t nskip = 0) { octave_idx_type curr_user_frame = -1; return instance_ok () ? instance->do_backtrace (nskip, curr_user_frame, true) : octave_map (); } static octave_map backtrace (size_t nskip, octave_idx_type& curr_user_frame, bool print_subfn = true) { return instance_ok () ? instance->do_backtrace (nskip, curr_user_frame, print_subfn) : octave_map (); } static std::list<octave_call_stack::stack_frame> backtrace_frames (size_t nskip = 0) { octave_idx_type curr_user_frame = -1; return instance_ok () ? instance->do_backtrace_frames (nskip, curr_user_frame) : std::list<octave_call_stack::stack_frame> (); } static std::list<octave_call_stack::stack_frame> backtrace_frames (size_t nskip, octave_idx_type& curr_user_frame) { return instance_ok () ? instance->do_backtrace_frames (nskip, curr_user_frame) : std::list<octave_call_stack::stack_frame> (); } static octave_map empty_backtrace (void); static void pop (void) { if (instance_ok ()) instance->do_pop (); } static void clear (void) { if (instance_ok ()) instance->do_clear (); } private: // The current call stack. std::deque<stack_frame> cs; size_t curr_frame; static octave_call_stack *instance; static void cleanup_instance (void) { delete instance; instance = 0; } int do_current_line (void) const; int do_current_column (void) const; int do_caller_user_code_line (void) const; int do_caller_user_code_column (void) const; octave_function *do_caller (void) const { return curr_frame > 1 ? cs[curr_frame-1].m_fcn : cs[0].m_fcn; } size_t do_current_frame (void) { return curr_frame; } size_t do_size (void) { return cs.size (); } size_t do_num_user_code_frames (octave_idx_type& curr_user_frame) const; symbol_table::scope_id do_current_scope (void) const { return curr_frame > 0 && curr_frame < cs.size () ? cs[curr_frame].m_scope : 0; } symbol_table::context_id do_current_context (void) const { return curr_frame > 0 && curr_frame < cs.size () ? cs[curr_frame].m_context : 0; } /* const stack_frame& do_frame (size_t idx) { static stack_frame foobar; return idx < cs.size () ? cs[idx] : foobar; } */ octave_function *do_element (size_t n) { octave_function *retval = 0; if (cs.size () > n) { stack_frame& elt = cs[n]; retval = elt.m_fcn; } return retval; } octave_user_code *do_caller_user_code (size_t nskip) const; bool do_all_scripts (void) const; void do_push (octave_function *fcn, symbol_table::scope_id scope, symbol_table::context_id context) { size_t prev_frame = curr_frame; curr_frame = cs.size (); cs.push_back (stack_frame (fcn, scope, context, prev_frame)); symbol_table::set_scope_and_context (scope, context); } octave_function *do_current (void) const { octave_function *retval = 0; if (! cs.empty ()) { const stack_frame& elt = cs[curr_frame]; retval = elt.m_fcn; } return retval; } void do_set_location (int l, int c) { if (! cs.empty ()) { stack_frame& elt = cs.back (); elt.m_line = l; elt.m_column = c; } } void do_set_line (int l) { if (! cs.empty ()) { stack_frame& elt = cs.back (); elt.m_line = l; } } void do_set_column (int c) { if (! cs.empty ()) { stack_frame& elt = cs.back (); elt.m_column = c; } } std::list<octave_call_stack::stack_frame> do_backtrace_frames (size_t nskip, octave_idx_type& curr_user_frame) const; octave_map do_backtrace (size_t nskip, octave_idx_type& curr_user_frame, bool print_subfn) const; bool do_goto_frame (size_t n, bool verbose); bool do_goto_frame_relative (int n, bool verbose); void do_goto_caller_frame (void); void do_goto_base_frame (void); void do_pop (void) { if (cs.size () > 1) { const stack_frame& elt = cs.back (); curr_frame = elt.m_prev; cs.pop_back (); const stack_frame& new_elt = cs[curr_frame]; symbol_table::set_scope_and_context (new_elt.m_scope, new_elt.m_context); } } void do_clear (void) { cs.clear (); } }; // Call a function with exceptions handled to avoid problems with // errors while shutting down. #define OCTAVE_IGNORE_EXCEPTION(E) \ catch (E) \ { \ std::cerr << "error: ignoring " #E " while preparing to exit" << std::endl; \ recover_from_exception (); \ } #define OCTAVE_SAFE_CALL(F, ARGS) \ do \ { \ try \ { \ unwind_protect frame; \ \ frame.protect_var (Vdebug_on_error); \ frame.protect_var (Vdebug_on_warning); \ \ Vdebug_on_error = false; \ Vdebug_on_warning = false; \ \ F ARGS; \ } \ OCTAVE_IGNORE_EXCEPTION (octave_interrupt_exception) \ OCTAVE_IGNORE_EXCEPTION (octave_execution_exception) \ OCTAVE_IGNORE_EXCEPTION (std::bad_alloc) \ \ if (error_state) \ error_state = 0; \ } \ while (0) #endif