Mercurial > octave
view libinterp/corefcn/stack-frame.h @ 30564:796f54d4ddbf stable
update Octave Project Developers copyright for the new year
In files that have the "Octave Project Developers" copyright notice,
update for 2021.
In all .txi and .texi files except gpl.txi and gpl.texi in the
doc/liboctave and doc/interpreter directories, change the copyright
to "Octave Project Developers", the same as used for other source
files. Update copyright notices for 2022 (not done since 2019). For
gpl.txi and gpl.texi, change the copyright notice to be "Free Software
Foundation, Inc." and leave the date at 2007 only because this file
only contains the text of the GPL, not anything created by the Octave
Project Developers.
Add Paul Thomas to contributors.in.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Tue, 28 Dec 2021 18:22:40 -0500 |
| parents | a61e1a0f6024 |
| children | e88a07dec498 |
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//////////////////////////////////////////////////////////////////////// // // Copyright (C) 1993-2022 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 (octave_stack_frame_h) #define octave_stack_frame_h 1 #include "octave-config.h" #include <deque> #include <iosfwd> #include <list> #include <map> #include <memory> #include <string> class octave_value; class octave_value_list; #include "error.h" #include "ov-fcn.h" #include "ov-usr-fcn.h" #include "syminfo.h" #include "symscope.h" // Variable values are stored in the stack_frame objects that make up // the call_stack. There are four separate stack_frame objects // corresponding to the following language elements: // // * user-defined functions // // These are .m files. They have local variables. // // * scripts // // These are .m files, but not functions. They access variables, // but do not store any values directly. All values are stored in // the stack frame corresponding to the scope in which they are // executed. // // * scopes that do not correspond to functions // // This is primarily used by the top-level scope but the // interpreter may also create temporary scopes in which to // evaluate functions or scripts. // // * compiled functions // // These are built-in functions and dynamically-loaded compiled // functions (.mex and .oct files) and do not contain variable // values of their own. They are skipped when Octave displays a // stack trace. // // All stack frames also contain the following data: // // * a reference to the evaluator that contains the frame // // Global variables are now stored in the evaluator and this link // gives us immediate access to them. // // * line and column in the source file where the stack frame was created // // These values are used to print stack traces. // // * A pointer to the nearest parent frame that contains variable // info (the "static" link) // // A frame that contains variable info may be a user-defined // function, script, or scope frame. This pointer should never // point to a compiled function stack frame. // // * A pointer to the nearest lexical parent frame (the "access" link) // // Used to access non-local variables for nested and anonymous // functions or as a link to the parent frame in which a script is // executed. This pointer should only point to a parent function // stack frame. namespace octave { class tree_evaluator; class symbol_info_list; class unwind_protect; class stack_frame_walker; class stack_frame { public: typedef std::map<std::string, octave_value> local_vars_map; // Markers indicating the type of a variable. Values for local // variables are stored in the stack frame. Values for // global variables are stored in the tree_evaluator object that // contains the stack frame. Values for persistent variables are // stored in the function scope corresponding to the stack frame. enum scope_flags { LOCAL, GLOBAL, PERSISTENT }; // Index into the list of automatic variables for user-defined // function stack frames. enum auto_var_type { ARG_NAMES, IGNORED, NARGIN, NARGOUT, SAVED_WARNING_STATES, NUM_AUTO_VARS }; stack_frame (void) = delete; stack_frame (tree_evaluator& tw, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link, const std::shared_ptr<stack_frame>& access_link) : m_evaluator (tw), m_is_closure_context (false), m_line (-1), m_column (-1), m_index (index), m_parent_link (parent_link), m_static_link (static_link), m_access_link (access_link), m_dispatch_class () { } // Compiled function. static stack_frame * create (tree_evaluator& tw, octave_function *fcn, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link); // Script. static stack_frame * create (tree_evaluator& tw, octave_user_script *script, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link); // User-defined function. static stack_frame * create (tree_evaluator& tw, octave_user_function *fcn, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link, const std::shared_ptr<stack_frame>& access_link = std::shared_ptr<stack_frame> ()); // Anonymous user-defined function with init vars. static stack_frame * create (tree_evaluator& tw, octave_user_function *fcn, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link, const local_vars_map& local_vars, const std::shared_ptr<stack_frame>& access_link = std::shared_ptr<stack_frame> ()); // Scope. static stack_frame * create (tree_evaluator& tw, const symbol_scope& scope, std::size_t index, const std::shared_ptr<stack_frame>& parent_link, const std::shared_ptr<stack_frame>& static_link); stack_frame (const stack_frame& elt) = default; stack_frame& operator = (const stack_frame& elt) = delete; virtual ~stack_frame (void) = default; // FIXME: It would be nice to eliminate these but there are a few // places where we still need to know the specific type of the // stack frame that we are handling. virtual bool is_compiled_fcn_frame (void) const { return false; } virtual bool is_user_script_frame (void) const { return false; } virtual bool is_user_fcn_frame (void) const { return false; } virtual bool is_scope_frame (void) const { return false; } virtual void clear_values (void); std::size_t index (void) const { return m_index; } void line (int l) { m_line = l; } int line (void) const { return m_line; } void column (int c) { m_column = c; } int column (void) const { return m_column; } std::string fcn_file_name (void) const { octave_function *fcn = function (); return fcn ? fcn->fcn_file_name () : ""; } std::string fcn_name (bool print_subfn = true) const { std::string retval; octave_function *fcn = function (); if (fcn) { std::string parent_fcn_name = fcn->parent_fcn_name (); if (print_subfn && ! parent_fcn_name.empty ()) retval = parent_fcn_name + '>'; if (fcn->is_anonymous_function ()) retval += "@<anonymous>"; else retval += fcn->name (); } else retval = "<unknown>"; return retval; } virtual symbol_scope get_scope (void) const = 0; virtual octave_function * function (void) const { return nullptr; } virtual unwind_protect * unwind_protect_frame (void) { return nullptr; } symbol_info_list make_symbol_info_list (const std::list<symbol_record>& symrec_list) const; octave_value who (const string_vector& patterns, bool have_regexp, bool return_list, bool verbose, const std::string& whos_line_fmt, const std::string& msg); symbol_info_list all_variables (void); octave_value workspace (void); std::list<std::string> variable_names (void) const; // Look for named symbol visible from current scope. Don't // attempt to insert if missing. virtual symbol_record lookup_symbol (const std::string&) const = 0; // Look for named symbol visible from current scope. Attempt to // insert if missing. virtual symbol_record insert_symbol (const std::string&) = 0; symbol_info_list glob_symbol_info (const std::string& pattern); symbol_info_list regexp_symbol_info (const std::string& pattern); symbol_info_list get_symbol_info (void) { return all_variables (); } void make_persistent (const symbol_record& sym) { if (sym.is_formal ()) { std::string nm = sym.name (); error ("can't make function parameter %s persistent", nm.c_str ()); } if (is_global (sym)) { std::string nm = sym.name (); error ("can't make global variable '%s' persistent", nm.c_str ()); } install_variable (sym, octave_value (), false); mark_persistent (sym); } void make_global (const symbol_record& sym) { if (is_persistent (sym)) { std::string nm = sym.name (); error ("can't make persistent variable '%s' global", nm.c_str ()); } install_variable (sym, octave_value (), true); mark_global (sym); } std::shared_ptr<stack_frame> parent_link (void) const {return m_parent_link; } std::shared_ptr<stack_frame> static_link (void) const {return m_static_link; } std::shared_ptr<stack_frame> access_link (void) const {return m_access_link; } virtual std::size_t size (void) const; virtual void resize (std::size_t); void mark_global (const symbol_record& sym) { mark_scope (sym, GLOBAL); } void unmark_global (const symbol_record& sym) { mark_scope (sym, LOCAL); } void mark_persistent (const symbol_record& sym) { mark_scope (sym, PERSISTENT); } void unmark_persistent (const symbol_record& sym) { mark_scope (sym, LOCAL); } bool is_defined (const symbol_record& sym) const { octave_value val = varval (sym); return val.is_defined (); } bool is_variable (const symbol_record& sym) const { octave_value val = varval (sym); return val.is_defined (); } bool is_variable (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? is_variable (sym) : false; } bool is_local_variable (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? (is_variable (sym) && ! is_global (sym)) : false; } bool is_object (const symbol_record& sym) const { octave_value val = varval (sym); return val.isobject (); } bool is_object (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? is_object (sym) : false; } virtual scope_flags scope_flag (const symbol_record&) const = 0; virtual scope_flags get_scope_flag (std::size_t) const; virtual void set_scope_flag (std::size_t, scope_flags); bool is_global (const symbol_record& sym) const { return scope_flag (sym) == GLOBAL; } bool is_global (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? is_global (sym) : false; } bool is_persistent (const symbol_record& sym) const { return scope_flag (sym) == PERSISTENT; } bool is_persistent (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? is_persistent (sym) : false; } void install_variable (const symbol_record& sym, const octave_value& value, bool global); void install_variable (const std::string& name, const octave_value& value, bool global) { symbol_record sym = insert_symbol (name); install_variable (sym, value, global); } virtual octave_value get_auto_fcn_var (auto_var_type) const = 0; virtual void set_auto_fcn_var (auto_var_type, const octave_value&) = 0; virtual octave_value varval (const symbol_record& sym) const = 0;; virtual octave_value varval (std::size_t data_offset) const; octave_value varval (const std::string& name) const { symbol_record sym = lookup_symbol (name); return sym ? varval (sym) : octave_value (); } virtual octave_value& varref (const symbol_record& sym) = 0; virtual octave_value& varref (std::size_t data_offset); void assign (const symbol_record& sym, const octave_value& val) { octave_value& lhs = varref (sym); if (lhs.get_count () == 1) lhs.call_object_destructor (); // Regularize a null matrix if stored into a variable. lhs = val.storable_value (); } void assign (const std::string& name, const octave_value& val) { symbol_record sym = insert_symbol (name); assign (sym, val); } void assign (octave_value::assign_op op, const symbol_record& sym, const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs) { if (idx.empty ()) { if (op == octave_value::op_asn_eq) assign (sym, rhs); else varref (sym).assign (op, rhs); } else varref (sym).assign (op, type, idx, rhs); } void non_const_unary_op (octave_value::unary_op op, const symbol_record& sym, const std::string& type, const std::list<octave_value_list>& idx) { if (idx.empty ()) varref (sym).non_const_unary_op (op); else varref (sym).non_const_unary_op (op, type, idx); } octave_value value (const symbol_record& sym, const std::string& type, const std::list<octave_value_list>& idx) const { octave_value retval = varval (sym); if (! idx.empty ()) { if (retval.is_constant ()) retval = retval.subsref (type, idx); else { octave_value_list t = retval.subsref (type, idx, 1); retval = t.length () > 0 ? t(0) : octave_value (); } } return retval; } octave_value find_subfunction (const std::string& name) const { symbol_scope scope = get_scope (); return scope.find_subfunction (name); } void clear (const symbol_record& sym) { if (is_global (sym)) unmark_global (sym); assign (sym, octave_value ()); if (is_persistent (sym)) unmark_persistent (sym); } void clear_objects (void); void clear_variable (const std::string& name); void clear_variable_pattern (const std::string& pattern); void clear_variable_pattern (const string_vector& patterns); void clear_variable_regexp (const std::string& pattern); void clear_variable_regexp (const string_vector& patterns); void clear_variables (void); std::string get_dispatch_class (void) const { return m_dispatch_class; } void set_dispatch_class (const std::string& class_name) { m_dispatch_class = class_name; } void display_stopped_in_message (std::ostream& os) const; virtual void mark_scope (const symbol_record&, scope_flags) = 0; virtual void display (bool follow = true) const; virtual void accept (stack_frame_walker& sfw) = 0; virtual void break_closure_cycles (const std::shared_ptr<stack_frame>&) { } void mark_closure_context (void) { m_is_closure_context = true; } bool is_closure_context (void) const { return m_is_closure_context; } protected: // Reference to the call stack that contains this frame. Global // variables are stored in the call stack. This link gives us // immediate access to them. tree_evaluator& m_evaluator; // TRUE if this stack frame is saved with a handle to a nested // function (closure). bool m_is_closure_context; // The line and column of the source file where this stack frame // was created. Used to print stack traces. int m_line; int m_column; // Index in call stack. std::size_t m_index; // Pointer to the nearest parent frame. May include compiled // functions. std::shared_ptr<stack_frame> m_parent_link; // Pointer to the nearest parent frame that contains variable // information (script, function, or scope). This link skips over // compiled function parent frames. std::shared_ptr<stack_frame> m_static_link; // Pointer to the nearest lexical parent frame. Used to access // non-local variables for nested and anonymous functions or as a // link to the parent frame in which a script is executed. std::shared_ptr<stack_frame> m_access_link; // Allow function handles to temporarily store their dispatch class // in the call stack. std::string m_dispatch_class; }; } #endif