Mercurial > octave
view libinterp/parse-tree/bp-table.cc @ 25347:af3319d86a5f
eliminate some global references to interpreter internals
* bp-table.h, bp-table.cc (bp_table::m_interpreter): New data member.
(get_user_code): Deprecate.
* interpreter.h, interpreter.cc (interpreter::get_user_code):
New function. Change all uses of global get_uesr_code to use
interpreter::get_user_code instead.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Thu, 03 May 2018 16:04:53 -0400 |
| parents | 4d7790d9793f |
| children | bc5f225bc578 |
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/* Copyright (C) 2001-2018 Ben Sapp Copyright (C) 2007-2009 John Swensen 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 <algorithm> #include <fstream> #include <limits> #include <list> #include <map> #include <set> #include <string> #include <sstream> #include <iostream> #include "file-ops.h" #include "bp-table.h" #include "defun-int.h" #include "call-stack.h" #include "error.h" #include "interpreter.h" #include "interpreter-private.h" #include "oct-map.h" #include "octave-link.h" #include "ov-usr-fcn.h" #include "ov.h" #include "ovl.h" #include "pager.h" #include "parse.h" #include "pt-eval.h" #include "pt-exp.h" #include "pt-stmt.h" #include "sighandlers.h" #include "symtab.h" namespace octave { // Clear all reasons to stop, other than breakpoints. void bp_table::dbclear_all_signals (void) { Vdebug_on_error = false; bp_table::m_errors_that_stop.clear (); Vdebug_on_caught = false; bp_table::m_caught_that_stop.clear (); Vdebug_on_warning = false; bp_table::m_warnings_that_stop.clear (); Vdebug_on_interrupt = false; } // Process the "warn", "errs", "caught" and "intr" fields for a call of // "dbstop (p)". void bp_table::dbstop_process_map_args (const octave_map& mv) { // process errs // why so many levels of indirection needed? bool fail = false; Cell U = mv.contents ("errs"); if (U.numel () != 1) fail = (U.numel () > 1); else { Array<octave_value> W = U.index (static_cast<octave_idx_type> (0)); if (W.isempty () || W(0).isempty ()) Vdebug_on_error = 1; // like "dbstop if error" with no identifier else if (! W(0).iscell ()) fail = true; else { Cell V = W(0).cell_value (); for (int i = 0; i < V.numel (); i++) { m_errors_that_stop.insert (V(i).string_value ()); Vdebug_on_error = 1; } } } if (fail) error ("dbstop: invalid 'errs' field"); // process caught // why so many levels of indirection needed? fail = false; U = mv.contents ("caught"); if (U.numel () != 1) fail = (U.numel () > 1); else { Array<octave_value> W = U.index (static_cast<octave_idx_type> (0)); if (W.isempty () || W(0).isempty ()) Vdebug_on_caught = 1; // like "dbstop if caught error" with no ID else if (! W(0).iscell ()) fail = true; else { Cell V = W(0).cell_value (); for (int i = 0; i < V.numel (); i++) { m_caught_that_stop.insert (V(i).string_value ()); Vdebug_on_caught = 1; } } } if (fail) error ("dbstop: invalid 'caught' field"); // process warn // why so many levels of indirection needed? fail = false; U = mv.contents ("warn"); if (U.numel () != 1) fail = (U.numel () > 1); else { Array<octave_value> W = U.index (static_cast<octave_idx_type> (0)); if (W.isempty () || W(0).isempty ()) Vdebug_on_warning = 1; // like "dbstop if warning" with no identifier else if (! W(0).iscell ()) fail = true; else { Cell V = W(0).cell_value (); for (int i = 0; i < V.numel (); i++) { m_warnings_that_stop.insert (V(i).string_value ()); Vdebug_on_warning = 1; } } } if (fail) error ("dbstop: invalid 'warn' field"); // process interrupt if (mv.isfield ("intr")) Vdebug_on_interrupt = 1; } // Insert a breakpoint in function fcn at line within file fname, // to stop only when condition is true. // Record in m_bp_set that fname contains a breakpoint. bool bp_table::add_breakpoint_1 (octave_user_code *fcn, const std::string& fname, const bp_table::intmap& line, const std::string& condition, bp_table::intmap& retval) { bool found = false; tree_statement_list *cmds = fcn->body (); std::string file = fcn->fcn_file_name (); if (cmds) { retval = cmds->add_breakpoint (file, line, condition); for (auto& idx_line_p : retval) { if (idx_line_p.second != 0) { // Normalize to store only the file name. // Otherwise, there can be an entry for both // file>subfunction and file, which causes a crash on // dbclear all const char *s = strchr (fname.c_str (), '>'); if (s) m_bp_set.insert (fname.substr (0, s - fname.c_str ())); else m_bp_set.insert (fname); found = true; break; } } } return found; } // Cursory check that cond is a valid condition to use for a breakpoint. // Currently allows conditions with side-effects, like 'y+=10' and 'y++'; // it is odd that the former is not flagged by "is_assignment_expression". // Throws an exception if not valid. bool bp_table::condition_valid (const std::string& cond) { if (cond.length () > 0) { parser parser (cond + " ;"); // ; to reject partial expr like "y==" parser.reset (); int parse_status = parser.run (); if (parse_status) error ("dbstop: Cannot parse condition '%s'", cond.c_str ()); else { tree_statement *stmt = nullptr; if (! parser.m_stmt_list) error ("dbstop: " "condition is not empty, but has nothing to evaluate"); else { if (parser.m_stmt_list->length () == 1 && (stmt = parser.m_stmt_list->front ()) && stmt->is_expression ()) { tree_expression *expr = stmt->expression (); if (expr->is_assignment_expression ()) error ("dbstop: condition cannot be an assignment. " "Did you mean '=='?"); } else error ("dbstop: condition must be an expression"); } } } return true; } enum dbstop_args { dbstop_in, dbstop_at, dbstop_if, dbstop_none }; // Parse parameters (args) of dbstop and dbclear commands. // For dbstop, who=="dbstop"; for dbclear, who=="dbclear". // The syntax is: dbstop [[in] symbol] [[at] line [line [...]]] [if condition] // where the form of condition depends on whether or not a file or line has // been seen. // Also execute "if [error|warning|interrupt|naninf]" clauses. void bp_table::parse_dbfunction_params (const char *who, const octave_value_list& args, std::string& symbol_name, bp_table::intmap& lines, std::string& cond) { int nargin = args.length (); int list_idx = 0; symbol_name = ""; lines = bp_table::intmap (); if (nargin == 0 || ! args(0).is_string ()) print_usage (who); // elements already processed bool seen_in = false, seen_at = false, seen_if = false; int pos = 0; dbstop_args tok = dbstop_none; while (pos < nargin) { // allow "in" and "at" to be implicit if (args(pos).is_string ()) { std::string arg = args(pos).string_value (); if (arg == "in") { tok = dbstop_in; pos++; } else if (arg == "at") { tok = dbstop_at; pos++; } else if (arg == "if") { tok = dbstop_if; pos++; } else if (atoi (args(pos).string_value ().c_str ()) > 0) tok = dbstop_at; else tok = dbstop_in; } else tok = dbstop_at; if (pos >= nargin) error ("%s: '%s' missing argument", who, (tok == dbstop_in ? "in" : (tok == dbstop_at ? "at" : "if"))); // process the actual arguments switch (tok) { case dbstop_in: symbol_name = args(pos).string_value (); if (seen_in) error ("%s: Too many function names specified -- %s", who, symbol_name.c_str ()); else if (seen_at || seen_if) error ("%s: function name must come before line number and 'if'", who); seen_in = true; pos++; break; case dbstop_at: if (seen_at) error ("%s: Only one 'at' clause is allowed -- %s", who, args(pos).string_value ().c_str ()); else if (seen_if) error ("%s: line number must come before 'if' clause\n"); seen_at = true; if (! seen_in) { // It was a line number. Get function name from debugger. if (Vdebugging) symbol_name = m_interpreter.get_user_code ()->profiler_name (); else error ("%s: function name must come before line number " "and 'if'", who); seen_in = true; } else if (seen_if) error ("%s: line number must come before 'if' clause\n"); // Read a list of line numbers (or arrays thereof) for ( ; pos < nargin; pos++) { if (args(pos).is_string ()) { int line = atoi (args(pos).string_value ().c_str ()); if (line > 0) lines[list_idx++] = line; else break; // may be "if" } else if (args(pos).isnumeric ()) { const NDArray arg = args(pos).array_value (); for (octave_idx_type j = 0; j < arg.numel (); j++) lines[list_idx++] = static_cast<int> (arg.elem (j)); } else error ("%s: Invalid argument type %s", args(pos).type_name ().c_str ()); } break; case dbstop_if: if (seen_in) // conditional breakpoint { cond = ""; // remaining arguments form condition for (; pos < nargin; pos++) { if (args(pos).is_string ()) cond += ' ' + args(pos).string_value (); else error ("%s: arguments to 'if' must all be strings", who); } cond = cond.substr (1); // omit initial space } else // stop on event (error, warning, interrupt, NaN/inf) { std::string condition = args(pos).string_value (); int on_off = ! strcmp(who, "dbstop"); // list of error/warning IDs to update std::set<std::string> *id_list = nullptr; bool *stop_flag = nullptr; // Vdebug_on_... flag if (condition == "error") { id_list = &m_errors_that_stop; stop_flag = &Vdebug_on_error; } else if (condition == "warning") { id_list = &m_warnings_that_stop; stop_flag = &Vdebug_on_warning; } else if (condition == "caught" && nargin > pos+1 && args(pos+1).string_value () == "error") { id_list = &m_caught_that_stop; stop_flag = &Vdebug_on_caught; pos++; } else if (condition == "interrupt") { Vdebug_on_interrupt = on_off; } else if (condition == "naninf") { #if defined (DBSTOP_NANINF) Vdebug_on_naninf = on_off; enable_fpe (on_off); #else warning ("%s: condition '%s' not yet supported", who, condition.c_str ()); #endif } else error ("%s: invalid condition %s", who, condition.c_str ()); // process ID list for "dbstop if error <error_ID>" etc if (id_list) { pos++; if (pos < nargin) // only affect a single error ID { if (! args(pos).is_string () || nargin > pos+1) error ("%s: ID must be a single string", who); else if (on_off == 1) { id_list->insert (args(pos).string_value ()); *stop_flag = true; } else { id_list->erase (args(pos).string_value ()); if (id_list->empty ()) *stop_flag = false; } } else // unqualified. Turn all on or off { id_list->clear (); *stop_flag = on_off; if (stop_flag == &Vdebug_on_error) { // Matlab stops on both. Vdebug_on_interrupt = on_off; } } } pos = nargin; } break; default: // dbstop_none should never occur break; } } } /* %!test %! dbclear all; # Clear out breakpoints before test %! dbstop help; %! dbstop in ls; %! dbstop help at 100; %! dbstop in ls 100; %! dbstop help 201 if a==5; %! dbstop if error Octave:undefined-function; %! s = dbstatus; %! dbclear all; %! assert ({s.bkpt(:).name}, {"help", "help", "help>do_contents", "ls", "ls"}); %! assert ([s.bkpt(:).line], [48, 100, 201, 58, 100]); %! assert (s.errs, {"Octave:undefined-function"}); */ // Return the sub/nested/main function of MAIN_FCN that contains // line number LINENO of the source file. // If END_LINE != 0, *END_LINE is set to last line of the returned function. static octave_user_code * find_fcn_by_line (octave_user_code *main_fcn, int lineno, int *end_line = nullptr) { octave_user_code *retval = nullptr; octave_user_code *next_fcn = nullptr; // 1st function starting after lineno // Find innermost nested (or parent) function containing lineno. int earliest_end = std::numeric_limits<int>::max (); std::map<std::string, octave_value> subfcns = main_fcn->subfunctions (); for (const auto& str_val_p : subfcns) { if (str_val_p.second.is_user_function ()) { auto *dbg_subfcn = str_val_p.second.user_function_value (); // Check if lineno is within dbg_subfcn. // FIXME: we could break when beginning_line() > lineno, // but that makes the code "fragile" // if the order of walking subfcns changes, // for a minor speed improvement in non-critical code. if (dbg_subfcn->ending_line () < earliest_end && dbg_subfcn->ending_line () >= lineno && dbg_subfcn->beginning_line () <= lineno) { earliest_end = dbg_subfcn->ending_line (); retval = find_fcn_by_line (dbg_subfcn, lineno, &earliest_end); } // Find the first fcn starting after lineno. // This is used if line is not inside any function. if (dbg_subfcn->beginning_line () >= lineno && ! next_fcn) next_fcn = dbg_subfcn; } } // The breakpoint is either in the subfunction found above, // or in the main function, which we check now. if (main_fcn->is_user_function ()) { int e = dynamic_cast<octave_user_function *> (main_fcn)->ending_line (); if (e >= lineno && e < earliest_end) retval = main_fcn; if (! retval) retval = next_fcn; } else // main_fcn is a script. { if (! retval) retval = main_fcn; } if (end_line && earliest_end < *end_line) *end_line = earliest_end; return retval; } // Given file name fname, find the subfunction at line and create // a breakpoint there. Put the system into debug_mode. bp_table::intmap bp_table::add_breakpoint (const std::string& fname, const bp_table::intmap& line, const std::string& condition) { octave_user_code *main_fcn = m_interpreter.get_user_code (fname); if (! main_fcn) error ("add_breakpoint: unable to find function '%s'\n", fname.c_str ()); condition_valid (condition); // Throw error if condition not valid. intmap retval; octave_idx_type len = line.size (); for (int i = 0; i < len; i++) { const_intmap_iterator m = line.find (i); if (m != line.end ()) { int lineno = m->second; octave_user_code *dbg_fcn = find_fcn_by_line (main_fcn, lineno); // We've found the right (sub)function. Now insert the breakpoint. // We insert all breakpoints. // If multiple are in the same function, we insert multiple times. intmap ret_one; if (dbg_fcn && add_breakpoint_1 (dbg_fcn, fname, line, condition, ret_one)) retval.insert (std::pair<int,int> (i, ret_one.find (i)->second)); } } tree_evaluator::debug_mode = bp_table::have_breakpoints () || Vdebugging; return retval; } int bp_table::remove_breakpoint_1 (octave_user_code *fcn, const std::string& fname, const bp_table::intmap& line) { int retval = 0; std::string file = fcn->fcn_file_name (); tree_statement_list *cmds = fcn->body (); // FIXME: move the operation on cmds to the tree_statement_list class? if (cmds) { octave_value_list results = cmds->list_breakpoints (); if (results.length () > 0) { octave_idx_type len = line.size (); for (int i = 0; i < len; i++) { const_intmap_iterator p = line.find (i); if (p != line.end ()) { int lineno = p->second; cmds->delete_breakpoint (lineno); if (! file.empty ()) octave_link::update_breakpoint (false, file, lineno); } } results = cmds->list_breakpoints (); auto it = m_bp_set.find (fname); if (results.empty () && it != m_bp_set.end ()) m_bp_set.erase (it); } retval = results.length (); } return retval; } int bp_table::remove_breakpoint (const std::string& fname, const bp_table::intmap& line) { int retval = 0; octave_idx_type len = line.size (); if (len == 0) { intmap results = remove_all_breakpoints_in_file (fname); retval = results.size (); } else { octave_user_code *dbg_fcn = m_interpreter.get_user_code (fname); if (! dbg_fcn) error ("remove_breakpoint: unable to find function %s\n", fname.c_str ()); retval = remove_breakpoint_1 (dbg_fcn, fname, line); // Search subfunctions in the order they appear in the file. const std::list<std::string> subfcn_names = dbg_fcn->subfunction_names (); std::map<std::string, octave_value> subfcns = dbg_fcn->subfunctions (); for (const auto& subf_nm : subfcn_names) { const auto q = subfcns.find (subf_nm); if (q != subfcns.end ()) { octave_user_code *dbg_subfcn = q->second.user_code_value (); retval += remove_breakpoint_1 (dbg_subfcn, fname, line); } } } tree_evaluator::debug_mode = bp_table::have_breakpoints () || Vdebugging; return retval; } // Remove all breakpoints from a file, including those in subfunctions. bp_table::intmap bp_table::remove_all_breakpoints_in_file (const std::string& fname, bool silent) { intmap retval; octave_user_code *dbg_fcn = m_interpreter.get_user_code (fname); if (dbg_fcn) { std::string file = dbg_fcn->fcn_file_name (); tree_statement_list *cmds = dbg_fcn->body (); if (cmds) { retval = cmds->remove_all_breakpoints (file); auto it = m_bp_set.find (fname); if (it != m_bp_set.end ()) m_bp_set.erase (it); } } else if (! silent) error ("remove_all_breakpoint_in_file: " "unable to find function %s\n", fname.c_str ()); tree_evaluator::debug_mode = bp_table::have_breakpoints () || Vdebugging; return retval; } void bp_table::remove_all_breakpoints (void) { // Odd loop structure required because delete will invalidate // m_bp_set iterators. for (auto it = m_bp_set.cbegin (), it_next = it; it != m_bp_set.cend (); it = it_next) { ++it_next; remove_all_breakpoints_in_file (*it); } tree_evaluator::debug_mode = bp_table::have_breakpoints () || Vdebugging; } std::string find_bkpt_list (octave_value_list slist, std::string match) { std::string retval; for (int i = 0; i < slist.length (); i++) { if (slist(i).string_value () == match) { retval = slist(i).string_value (); break; } } return retval; } bp_table::fname_bp_map bp_table::get_breakpoint_list (const octave_value_list& fname_list) { fname_bp_map retval; // make copy since changes may invalidate iters of m_bp_set. std::set<std::string> tmp_bp_set = m_bp_set; for (auto& bp_fname : tmp_bp_set) { if (fname_list.empty () || find_bkpt_list (fname_list, bp_fname) != "") { octave_user_code *dbg_fcn = m_interpreter.get_user_code (bp_fname); if (dbg_fcn) { tree_statement_list *cmds = dbg_fcn->body (); // FIXME: move the operation on cmds to the // tree_statement_list class? if (cmds) { std::list<bp_type> bkpts = cmds->breakpoints_and_conds (); if (! bkpts.empty ()) retval[bp_fname] = bkpts; } // look for breakpoints in subfunctions const std::list<std::string> subf_nm = dbg_fcn->subfunction_names (); std::map<std::string, octave_value> subfcns = dbg_fcn->subfunctions (); for (const auto& subfcn_nm : subf_nm) { const auto q = subfcns.find (subfcn_nm); if (q != subfcns.end ()) { octave_user_code *dbg_subfcn = q->second.user_code_value (); cmds = dbg_subfcn->body (); if (cmds) { std::list<bp_type> bkpts = cmds->breakpoints_and_conds (); if (! bkpts.empty ()) { std::string key = bp_fname + '>' + dbg_subfcn->name (); retval[key] = bkpts; } } } } } } } return retval; } // Report the status of "dbstop if error ..." and "dbstop if warning ..." // If to_screen is true, the output goes to octave_stdout; otherwise it is // returned. // If dbstop if error is true but no explicit IDs are specified, the return // value will have an empty field called "errs". If IDs are specified, the // "errs" field will have a row per ID. If dbstop if error is false, there // is no "errs" field. The "warn" field is set similarly by dbstop if warning octave_map bp_table::stop_on_err_warn_status (bool to_screen) { octave_map retval; // print dbstop if error information if (Vdebug_on_error) { if (m_errors_that_stop.empty ()) { if (to_screen) octave_stdout << "stop if error\n"; else retval.assign ("errs", octave_value("")); } else { Cell errs (dim_vector (bp_table::m_errors_that_stop.size (), 1)); int i = 0; for (const auto& e : m_errors_that_stop) { if (to_screen) octave_stdout << "stop if error " << e << "\n"; else errs(i++) = e; } if (! to_screen) retval.assign ("errs", octave_value (errs)); } } // print dbstop if caught error information if (Vdebug_on_caught) { if (m_caught_that_stop.empty ()) { if (to_screen) octave_stdout << "stop if caught error\n"; else retval.assign ("caught", octave_value("")); } else { Cell errs (dim_vector (m_caught_that_stop.size (), 1)); int i = 0; for (const auto& e : m_caught_that_stop) { if (to_screen) octave_stdout << "stop if caught error " << e << "\n"; else errs(i++) = e; } if (! to_screen) retval.assign ("caught", octave_value (errs)); } } // print dbstop if warning information if (Vdebug_on_warning) { if (m_warnings_that_stop.empty ()) { if (to_screen) octave_stdout << "stop if warning\n"; else retval.assign ("warn", octave_value("")); } else { Cell warn (dim_vector (m_warnings_that_stop.size (), 1)); int i = 0; for (const auto& w : m_warnings_that_stop) { if (to_screen) octave_stdout << "stop if warning " << w << "\n"; else warn(i++) = w; } if (! to_screen) retval.assign ("warn", octave_value (warn)); } } // print dbstop if interrupt information if (Vdebug_on_interrupt) { if (to_screen) octave_stdout << "stop if interrupt\n"; else retval.assign ("intr", octave_value ()); } return retval; } octave_user_code * get_user_code (const std::string& fname) { interpreter& interp = __get_interpreter__ ("get_user_code"); return interp.get_user_code (fname); } }