/* General utility routines for GDB, the GNU debugger. Copyright (C) 1986-2022 Free Software Foundation, Inc. This file is part of GDB. This program 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. This program 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 this program. If not, see . */ #include "defs.h" #include #include "gdbsupport/gdb_wait.h" #include "event-top.h" #include "gdbthread.h" #include "fnmatch.h" #include "gdb_bfd.h" #ifdef HAVE_SYS_RESOURCE_H #include #endif /* HAVE_SYS_RESOURCE_H */ #ifdef TUI #include "tui/tui.h" /* For tui_get_command_dimension. */ #endif #ifdef __GO32__ #include #endif #include #include "gdbcmd.h" #include "serial.h" #include "bfd.h" #include "target.h" #include "gdb-demangle.h" #include "expression.h" #include "language.h" #include "charset.h" #include "annotate.h" #include "filenames.h" #include "symfile.h" #include "gdbsupport/gdb_obstack.h" #include "gdbcore.h" #include "top.h" #include "main.h" #include "solist.h" #include "inferior.h" /* for signed_pointer_to_address */ #include "gdb_curses.h" #include "readline/readline.h" #include #include "interps.h" #include "gdbsupport/gdb_regex.h" #include "gdbsupport/job-control.h" #include "gdbsupport/selftest.h" #include "gdbsupport/gdb_optional.h" #include "cp-support.h" #include #include "gdbsupport/pathstuff.h" #include "cli/cli-style.h" #include "gdbsupport/scope-exit.h" #include "gdbarch.h" #include "cli-out.h" #include "gdbsupport/gdb-safe-ctype.h" #include "bt-utils.h" #include "gdbsupport/buildargv.h" void (*deprecated_error_begin_hook) (void); /* Prototypes for local functions */ static void vfprintf_maybe_filtered (struct ui_file *, const char *, va_list, bool) ATTRIBUTE_PRINTF (2, 0); static void fputs_maybe_filtered (const char *, struct ui_file *, int); static void prompt_for_continue (void); static void set_screen_size (void); static void set_width (void); /* Time spent in prompt_for_continue in the currently executing command waiting for user to respond. Initialized in make_command_stats_cleanup. Modified in prompt_for_continue and defaulted_query. Used in report_command_stats. */ static std::chrono::steady_clock::duration prompt_for_continue_wait_time; /* A flag indicating whether to timestamp debugging messages. */ static bool debug_timestamp = false; /* True means that strings with character values >0x7F should be printed as octal escapes. False means just print the value (e.g. it's an international character, and the terminal or window can cope.) */ bool sevenbit_strings = false; static void show_sevenbit_strings (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Printing of 8-bit characters " "in strings as \\nnn is %s.\n"), value); } /* String to be printed before warning messages, if any. */ const char *warning_pre_print = "\nwarning: "; bool pagination_enabled = true; static void show_pagination_enabled (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("State of pagination is %s.\n"), value); } /* Print a warning message. The first argument STRING is the warning message, used as an fprintf format string, the second is the va_list of arguments for that string. A warning is unfiltered (not paginated) so that the user does not need to page through each screen full of warnings when there are lots of them. */ void vwarning (const char *string, va_list args) { if (deprecated_warning_hook) (*deprecated_warning_hook) (string, args); else { gdb::optional term_state; if (target_supports_terminal_ours ()) { term_state.emplace (); target_terminal::ours_for_output (); } if (filtered_printing_initialized ()) gdb_stdout->wrap_here (0); /* Force out any buffered output. */ gdb_flush (gdb_stdout); if (warning_pre_print) fputs_unfiltered (warning_pre_print, gdb_stderr); vfprintf_unfiltered (gdb_stderr, string, args); fprintf_unfiltered (gdb_stderr, "\n"); } } /* Print an error message and return to command level. The first argument STRING is the error message, used as a fprintf string, and the remaining args are passed as arguments to it. */ void verror (const char *string, va_list args) { throw_verror (GENERIC_ERROR, string, args); } void error_stream (const string_file &stream) { error (("%s"), stream.c_str ()); } /* Emit a message and abort. */ static void ATTRIBUTE_NORETURN abort_with_message (const char *msg) { if (current_ui == NULL) fputs (msg, stderr); else fputs_unfiltered (msg, gdb_stderr); abort (); /* ARI: abort */ } /* Dump core trying to increase the core soft limit to hard limit first. */ void dump_core (void) { #ifdef HAVE_SETRLIMIT struct rlimit rlim = { (rlim_t) RLIM_INFINITY, (rlim_t) RLIM_INFINITY }; setrlimit (RLIMIT_CORE, &rlim); #endif /* HAVE_SETRLIMIT */ /* Ensure that the SIGABRT we're about to raise will immediately cause GDB to exit and dump core, we don't want to trigger GDB's printing of a backtrace to the console here. */ signal (SIGABRT, SIG_DFL); abort (); /* ARI: abort */ } /* Check whether GDB will be able to dump core using the dump_core function. Returns zero if GDB cannot or should not dump core. If LIMIT_KIND is LIMIT_CUR the user's soft limit will be respected. If LIMIT_KIND is LIMIT_MAX only the hard limit will be respected. */ int can_dump_core (enum resource_limit_kind limit_kind) { #ifdef HAVE_GETRLIMIT struct rlimit rlim; /* Be quiet and assume we can dump if an error is returned. */ if (getrlimit (RLIMIT_CORE, &rlim) != 0) return 1; switch (limit_kind) { case LIMIT_CUR: if (rlim.rlim_cur == 0) return 0; /* Fall through. */ case LIMIT_MAX: if (rlim.rlim_max == 0) return 0; } #endif /* HAVE_GETRLIMIT */ return 1; } /* Print a warning that we cannot dump core. */ void warn_cant_dump_core (const char *reason) { fprintf_unfiltered (gdb_stderr, _("%s\nUnable to dump core, use `ulimit -c" " unlimited' before executing GDB next time.\n"), reason); } /* Check whether GDB will be able to dump core using the dump_core function, and print a warning if we cannot. */ static int can_dump_core_warn (enum resource_limit_kind limit_kind, const char *reason) { int core_dump_allowed = can_dump_core (limit_kind); if (!core_dump_allowed) warn_cant_dump_core (reason); return core_dump_allowed; } /* Allow the user to configure the debugger behavior with respect to what to do when an internal problem is detected. */ const char internal_problem_ask[] = "ask"; const char internal_problem_yes[] = "yes"; const char internal_problem_no[] = "no"; static const char *const internal_problem_modes[] = { internal_problem_ask, internal_problem_yes, internal_problem_no, NULL }; /* Data structure used to control how the internal_vproblem function should behave. An instance of this structure is created for each problem type that GDB supports. */ struct internal_problem { /* The name of this problem type. This must not contain white space as this string is used to build command names. */ const char *name; /* When this is true then a user command is created (based on NAME) that allows the SHOULD_QUIT field to be modified, otherwise, SHOULD_QUIT can't be changed from its default value by the user. */ bool user_settable_should_quit; /* Reference a value from internal_problem_modes to indicate if GDB should quit when it hits a problem of this type. */ const char *should_quit; /* Like USER_SETTABLE_SHOULD_QUIT but for SHOULD_DUMP_CORE. */ bool user_settable_should_dump_core; /* Like SHOULD_QUIT, but whether GDB should dump core. */ const char *should_dump_core; /* Like USER_SETTABLE_SHOULD_QUIT but for SHOULD_PRINT_BACKTRACE. */ bool user_settable_should_print_backtrace; /* When this is true GDB will print a backtrace when a problem of this type is encountered. */ bool should_print_backtrace; }; /* Report a problem, internal to GDB, to the user. Once the problem has been reported, and assuming GDB didn't quit, the caller can either allow execution to resume or throw an error. */ static void ATTRIBUTE_PRINTF (4, 0) internal_vproblem (struct internal_problem *problem, const char *file, int line, const char *fmt, va_list ap) { static int dejavu; int quit_p; int dump_core_p; std::string reason; /* Don't allow infinite error/warning recursion. */ { static const char msg[] = "Recursive internal problem.\n"; switch (dejavu) { case 0: dejavu = 1; break; case 1: dejavu = 2; abort_with_message (msg); default: dejavu = 3; /* Newer GLIBC versions put the warn_unused_result attribute on write, but this is one of those rare cases where ignoring the return value is correct. Casting to (void) does not fix this problem. This is the solution suggested at http://gcc.gnu.org/bugzilla/show_bug.cgi?id=25509. */ if (write (STDERR_FILENO, msg, sizeof (msg)) != sizeof (msg)) abort (); /* ARI: abort */ exit (1); } } /* Create a string containing the full error/warning message. Need to call query with this full string, as otherwize the reason (error/warning) and question become separated. Format using a style similar to a compiler error message. Include extra detail so that the user knows that they are living on the edge. */ { std::string msg = string_vprintf (fmt, ap); reason = string_printf ("%s:%d: %s: %s\n" "A problem internal to GDB has been detected,\n" "further debugging may prove unreliable.", file, line, problem->name, msg.c_str ()); } /* Fall back to abort_with_message if gdb_stderr is not set up. */ if (current_ui == NULL) { fputs (reason.c_str (), stderr); abort_with_message ("\n"); } /* Try to get the message out and at the start of a new line. */ gdb::optional term_state; if (target_supports_terminal_ours ()) { term_state.emplace (); target_terminal::ours_for_output (); } if (filtered_printing_initialized ()) begin_line (); /* Emit the message unless query will emit it below. */ if (problem->should_quit != internal_problem_ask || !confirm || !filtered_printing_initialized () || problem->should_print_backtrace) fprintf_unfiltered (gdb_stderr, "%s\n", reason.c_str ()); if (problem->should_print_backtrace) gdb_internal_backtrace (); if (problem->should_quit == internal_problem_ask) { /* Default (yes/batch case) is to quit GDB. When in batch mode this lessens the likelihood of GDB going into an infinite loop. */ if (!confirm || !filtered_printing_initialized ()) quit_p = 1; else quit_p = query (_("%s\nQuit this debugging session? "), reason.c_str ()); } else if (problem->should_quit == internal_problem_yes) quit_p = 1; else if (problem->should_quit == internal_problem_no) quit_p = 0; else internal_error (__FILE__, __LINE__, _("bad switch")); fputs_unfiltered (_("\nThis is a bug, please report it."), gdb_stderr); if (REPORT_BUGS_TO[0]) fprintf_unfiltered (gdb_stderr, _(" For instructions, see:\n%s."), REPORT_BUGS_TO); fputs_unfiltered ("\n\n", gdb_stderr); if (problem->should_dump_core == internal_problem_ask) { if (!can_dump_core_warn (LIMIT_MAX, reason.c_str ())) dump_core_p = 0; else if (!filtered_printing_initialized ()) dump_core_p = 1; else { /* Default (yes/batch case) is to dump core. This leaves a GDB `dropping' so that it is easier to see that something went wrong in GDB. */ dump_core_p = query (_("%s\nCreate a core file of GDB? "), reason.c_str ()); } } else if (problem->should_dump_core == internal_problem_yes) dump_core_p = can_dump_core_warn (LIMIT_MAX, reason.c_str ()); else if (problem->should_dump_core == internal_problem_no) dump_core_p = 0; else internal_error (__FILE__, __LINE__, _("bad switch")); if (quit_p) { if (dump_core_p) dump_core (); else exit (1); } else { if (dump_core_p) { #ifdef HAVE_WORKING_FORK if (fork () == 0) dump_core (); #endif } } dejavu = 0; } static struct internal_problem internal_error_problem = { "internal-error", true, internal_problem_ask, true, internal_problem_ask, true, GDB_PRINT_INTERNAL_BACKTRACE_INIT_ON }; void internal_verror (const char *file, int line, const char *fmt, va_list ap) { internal_vproblem (&internal_error_problem, file, line, fmt, ap); throw_quit (_("Command aborted.")); } static struct internal_problem internal_warning_problem = { "internal-warning", true, internal_problem_ask, true, internal_problem_ask, true, false }; void internal_vwarning (const char *file, int line, const char *fmt, va_list ap) { internal_vproblem (&internal_warning_problem, file, line, fmt, ap); } static struct internal_problem demangler_warning_problem = { "demangler-warning", true, internal_problem_ask, false, internal_problem_no, false, false }; void demangler_vwarning (const char *file, int line, const char *fmt, va_list ap) { internal_vproblem (&demangler_warning_problem, file, line, fmt, ap); } void demangler_warning (const char *file, int line, const char *string, ...) { va_list ap; va_start (ap, string); demangler_vwarning (file, line, string, ap); va_end (ap); } /* When GDB reports an internal problem (error or warning) it gives the user the opportunity to quit GDB and/or create a core file of the current debug session. This function registers a few commands that make it possible to specify that GDB should always or never quit or create a core file, without asking. The commands look like: maint set PROBLEM-NAME quit ask|yes|no maint show PROBLEM-NAME quit maint set PROBLEM-NAME corefile ask|yes|no maint show PROBLEM-NAME corefile Where PROBLEM-NAME is currently "internal-error" or "internal-warning". */ static void add_internal_problem_command (struct internal_problem *problem) { struct cmd_list_element **set_cmd_list; struct cmd_list_element **show_cmd_list; set_cmd_list = XNEW (struct cmd_list_element *); show_cmd_list = XNEW (struct cmd_list_element *); *set_cmd_list = NULL; *show_cmd_list = NULL; /* The add_basic_prefix_cmd and add_show_prefix_cmd functions take ownership of the string passed in, which is why we don't need to free set_doc and show_doc in this function. */ const char *set_doc = xstrprintf (_("Configure what GDB does when %s is detected."), problem->name).release (); const char *show_doc = xstrprintf (_("Show what GDB does when %s is detected."), problem->name).release (); add_setshow_prefix_cmd (problem->name, class_maintenance, set_doc, show_doc, set_cmd_list, show_cmd_list, &maintenance_set_cmdlist, &maintenance_show_cmdlist); if (problem->user_settable_should_quit) { std::string set_quit_doc = string_printf (_("Set whether GDB should quit when an %s is " "detected."), problem->name); std::string show_quit_doc = string_printf (_("Show whether GDB will quit when an %s is " "detected."), problem->name); add_setshow_enum_cmd ("quit", class_maintenance, internal_problem_modes, &problem->should_quit, set_quit_doc.c_str (), show_quit_doc.c_str (), NULL, /* help_doc */ NULL, /* setfunc */ NULL, /* showfunc */ set_cmd_list, show_cmd_list); } if (problem->user_settable_should_dump_core) { std::string set_core_doc = string_printf (_("Set whether GDB should create a core file of " "GDB when %s is detected."), problem->name); std::string show_core_doc = string_printf (_("Show whether GDB will create a core file of " "GDB when %s is detected."), problem->name); add_setshow_enum_cmd ("corefile", class_maintenance, internal_problem_modes, &problem->should_dump_core, set_core_doc.c_str (), show_core_doc.c_str (), NULL, /* help_doc */ NULL, /* setfunc */ NULL, /* showfunc */ set_cmd_list, show_cmd_list); } if (problem->user_settable_should_print_backtrace) { std::string set_bt_doc = string_printf (_("Set whether GDB should print a backtrace of " "GDB when %s is detected."), problem->name); std::string show_bt_doc = string_printf (_("Show whether GDB will print a backtrace of " "GDB when %s is detected."), problem->name); add_setshow_boolean_cmd ("backtrace", class_maintenance, &problem->should_print_backtrace, set_bt_doc.c_str (), show_bt_doc.c_str (), NULL, /* help_doc */ gdb_internal_backtrace_set_cmd, NULL, /* showfunc */ set_cmd_list, show_cmd_list); } } /* Return a newly allocated string, containing the PREFIX followed by the system error message for errno (separated by a colon). */ static std::string perror_string (const char *prefix) { const char *err = safe_strerror (errno); return std::string (prefix) + ": " + err; } /* Print the system error message for errno, and also mention STRING as the file name for which the error was encountered. Use ERRCODE for the thrown exception. Then return to command level. */ void throw_perror_with_name (enum errors errcode, const char *string) { std::string combined = perror_string (string); /* I understand setting these is a matter of taste. Still, some people may clear errno but not know about bfd_error. Doing this here is not unreasonable. */ bfd_set_error (bfd_error_no_error); errno = 0; throw_error (errcode, _("%s."), combined.c_str ()); } /* See throw_perror_with_name, ERRCODE defaults here to GENERIC_ERROR. */ void perror_with_name (const char *string) { throw_perror_with_name (GENERIC_ERROR, string); } /* Same as perror_with_name except that it prints a warning instead of throwing an error. */ void perror_warning_with_name (const char *string) { std::string combined = perror_string (string); warning (_("%s"), combined.c_str ()); } /* Print the system error message for ERRCODE, and also mention STRING as the file name for which the error was encountered. */ void print_sys_errmsg (const char *string, int errcode) { const char *err = safe_strerror (errcode); /* We want anything which was printed on stdout to come out first, before this message. */ gdb_flush (gdb_stdout); fprintf_unfiltered (gdb_stderr, "%s: %s.\n", string, err); } /* Control C eventually causes this to be called, at a convenient time. */ void quit (void) { if (sync_quit_force_run) { sync_quit_force_run = 0; quit_force (NULL, 0); } #ifdef __MSDOS__ /* No steenking SIGINT will ever be coming our way when the program is resumed. Don't lie. */ throw_quit ("Quit"); #else if (job_control /* If there is no terminal switching for this target, then we can't possibly get screwed by the lack of job control. */ || !target_supports_terminal_ours ()) throw_quit ("Quit"); else throw_quit ("Quit (expect signal SIGINT when the program is resumed)"); #endif } /* See defs.h. */ void maybe_quit (void) { if (sync_quit_force_run) quit (); quit_handler (); } /* Called when a memory allocation fails, with the number of bytes of memory requested in SIZE. */ void malloc_failure (long size) { if (size > 0) { internal_error (__FILE__, __LINE__, _("virtual memory exhausted: can't allocate %ld bytes."), size); } else { internal_error (__FILE__, __LINE__, _("virtual memory exhausted.")); } } /* See common/errors.h. */ void flush_streams () { gdb_stdout->flush (); gdb_stderr->flush (); } /* My replacement for the read system call. Used like `read' but keeps going if `read' returns too soon. */ int myread (int desc, char *addr, int len) { int val; int orglen = len; while (len > 0) { val = read (desc, addr, len); if (val < 0) return val; if (val == 0) return orglen - len; len -= val; addr += val; } return orglen; } /* See utils.h. */ ULONGEST uinteger_pow (ULONGEST v1, LONGEST v2) { if (v2 < 0) { if (v1 == 0) error (_("Attempt to raise 0 to negative power.")); else return 0; } else { /* The Russian Peasant's Algorithm. */ ULONGEST v; v = 1; for (;;) { if (v2 & 1L) v *= v1; v2 >>= 1; if (v2 == 0) return v; v1 *= v1; } } } /* An RAII class that sets up to handle input and then tears down during destruction. */ class scoped_input_handler { public: scoped_input_handler () : m_quit_handler (&quit_handler, default_quit_handler), m_ui (NULL) { target_terminal::ours (); ui_register_input_event_handler (current_ui); if (current_ui->prompt_state == PROMPT_BLOCKED) m_ui = current_ui; } ~scoped_input_handler () { if (m_ui != NULL) ui_unregister_input_event_handler (m_ui); } DISABLE_COPY_AND_ASSIGN (scoped_input_handler); private: /* Save and restore the terminal state. */ target_terminal::scoped_restore_terminal_state m_term_state; /* Save and restore the quit handler. */ scoped_restore_tmpl m_quit_handler; /* The saved UI, if non-NULL. */ struct ui *m_ui; }; /* This function supports the query, nquery, and yquery functions. Ask user a y-or-n question and return 0 if answer is no, 1 if answer is yes, or default the answer to the specified default (for yquery or nquery). DEFCHAR may be 'y' or 'n' to provide a default answer, or '\0' for no default. CTLSTR is the control string and should end in "? ". It should not say how to answer, because we do that. ARGS are the arguments passed along with the CTLSTR argument to printf. */ static int ATTRIBUTE_PRINTF (1, 0) defaulted_query (const char *ctlstr, const char defchar, va_list args) { int retval; int def_value; char def_answer, not_def_answer; const char *y_string, *n_string; /* Set up according to which answer is the default. */ if (defchar == '\0') { def_value = 1; def_answer = 'Y'; not_def_answer = 'N'; y_string = "y"; n_string = "n"; } else if (defchar == 'y') { def_value = 1; def_answer = 'Y'; not_def_answer = 'N'; y_string = "[y]"; n_string = "n"; } else { def_value = 0; def_answer = 'N'; not_def_answer = 'Y'; y_string = "y"; n_string = "[n]"; } /* Automatically answer the default value if the user did not want prompts or the command was issued with the server prefix. */ if (!confirm || server_command) return def_value; /* If input isn't coming from the user directly, just say what question we're asking, and then answer the default automatically. This way, important error messages don't get lost when talking to GDB over a pipe. */ if (current_ui->instream != current_ui->stdin_stream || !input_interactive_p (current_ui) /* Restrict queries to the main UI. */ || current_ui != main_ui) { target_terminal::scoped_restore_terminal_state term_state; target_terminal::ours_for_output (); gdb_stdout->wrap_here (0); vfprintf_filtered (gdb_stdout, ctlstr, args); printf_filtered (_("(%s or %s) [answered %c; " "input not from terminal]\n"), y_string, n_string, def_answer); return def_value; } if (deprecated_query_hook) { target_terminal::scoped_restore_terminal_state term_state; return deprecated_query_hook (ctlstr, args); } /* Format the question outside of the loop, to avoid reusing args. */ std::string question = string_vprintf (ctlstr, args); std::string prompt = string_printf (_("%s%s(%s or %s) %s"), annotation_level > 1 ? "\n\032\032pre-query\n" : "", question.c_str (), y_string, n_string, annotation_level > 1 ? "\n\032\032query\n" : ""); /* Used to add duration we waited for user to respond to prompt_for_continue_wait_time. */ using namespace std::chrono; steady_clock::time_point prompt_started = steady_clock::now (); scoped_input_handler prepare_input; while (1) { char *response, answer; gdb_flush (gdb_stdout); response = gdb_readline_wrapper (prompt.c_str ()); if (response == NULL) /* C-d */ { printf_filtered ("EOF [assumed %c]\n", def_answer); retval = def_value; break; } answer = response[0]; xfree (response); if (answer >= 'a') answer -= 040; /* Check answer. For the non-default, the user must specify the non-default explicitly. */ if (answer == not_def_answer) { retval = !def_value; break; } /* Otherwise, if a default was specified, the user may either specify the required input or have it default by entering nothing. */ if (answer == def_answer || (defchar != '\0' && answer == '\0')) { retval = def_value; break; } /* Invalid entries are not defaulted and require another selection. */ printf_filtered (_("Please answer %s or %s.\n"), y_string, n_string); } /* Add time spend in this routine to prompt_for_continue_wait_time. */ prompt_for_continue_wait_time += steady_clock::now () - prompt_started; if (annotation_level > 1) printf_filtered (("\n\032\032post-query\n")); return retval; } /* Ask user a y-or-n question and return 0 if answer is no, 1 if answer is yes, or 0 if answer is defaulted. Takes three args which are given to printf to print the question. The first, a control string, should end in "? ". It should not say how to answer, because we do that. */ int nquery (const char *ctlstr, ...) { va_list args; int ret; va_start (args, ctlstr); ret = defaulted_query (ctlstr, 'n', args); va_end (args); return ret; } /* Ask user a y-or-n question and return 0 if answer is no, 1 if answer is yes, or 1 if answer is defaulted. Takes three args which are given to printf to print the question. The first, a control string, should end in "? ". It should not say how to answer, because we do that. */ int yquery (const char *ctlstr, ...) { va_list args; int ret; va_start (args, ctlstr); ret = defaulted_query (ctlstr, 'y', args); va_end (args); return ret; } /* Ask user a y-or-n question and return 1 iff answer is yes. Takes three args which are given to printf to print the question. The first, a control string, should end in "? ". It should not say how to answer, because we do that. */ int query (const char *ctlstr, ...) { va_list args; int ret; va_start (args, ctlstr); ret = defaulted_query (ctlstr, '\0', args); va_end (args); return ret; } /* A helper for parse_escape that converts a host character to a target character. C is the host character. If conversion is possible, then the target character is stored in *TARGET_C and the function returns 1. Otherwise, the function returns 0. */ static int host_char_to_target (struct gdbarch *gdbarch, int c, int *target_c) { char the_char = c; int result = 0; auto_obstack host_data; convert_between_encodings (target_charset (gdbarch), host_charset (), (gdb_byte *) &the_char, 1, 1, &host_data, translit_none); if (obstack_object_size (&host_data) == 1) { result = 1; *target_c = *(char *) obstack_base (&host_data); } return result; } /* Parse a C escape sequence. STRING_PTR points to a variable containing a pointer to the string to parse. That pointer should point to the character after the \. That pointer is updated past the characters we use. The value of the escape sequence is returned. A negative value means the sequence \ newline was seen, which is supposed to be equivalent to nothing at all. If \ is followed by a null character, we return a negative value and leave the string pointer pointing at the null character. If \ is followed by 000, we return 0 and leave the string pointer after the zeros. A value of 0 does not mean end of string. */ int parse_escape (struct gdbarch *gdbarch, const char **string_ptr) { int target_char = -2; /* Initialize to avoid GCC warnings. */ int c = *(*string_ptr)++; switch (c) { case '\n': return -2; case 0: (*string_ptr)--; return 0; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': { int i = fromhex (c); int count = 0; while (++count < 3) { c = (**string_ptr); if (ISDIGIT (c) && c != '8' && c != '9') { (*string_ptr)++; i *= 8; i += fromhex (c); } else { break; } } return i; } case 'a': c = '\a'; break; case 'b': c = '\b'; break; case 'f': c = '\f'; break; case 'n': c = '\n'; break; case 'r': c = '\r'; break; case 't': c = '\t'; break; case 'v': c = '\v'; break; default: break; } if (!host_char_to_target (gdbarch, c, &target_char)) error (_("The escape sequence `\\%c' is equivalent to plain `%c'," " which has no equivalent\nin the `%s' character set."), c, c, target_charset (gdbarch)); return target_char; } /* Number of lines per page or UINT_MAX if paging is disabled. */ static unsigned int lines_per_page; static void show_lines_per_page (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Number of lines gdb thinks are in a page is %s.\n"), value); } /* Number of chars per line or UINT_MAX if line folding is disabled. */ static unsigned int chars_per_line; static void show_chars_per_line (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Number of characters gdb thinks " "are in a line is %s.\n"), value); } /* Current count of lines printed on this page, chars on this line. */ static unsigned int lines_printed, chars_printed; /* True if pagination is disabled for just one command. */ static bool pagination_disabled_for_command; /* Buffer and start column of buffered text, for doing smarter word- wrapping. When someone calls wrap_here(), we start buffering output that comes through fputs_filtered(). If we see a newline, we just spit it out and forget about the wrap_here(). If we see another wrap_here(), we spit it out and remember the newer one. If we see the end of the line, we spit out a newline, the indent, and then the buffered output. */ static bool filter_initialized = false; /* Contains characters which are waiting to be output (they have already been counted in chars_printed). */ static std::string wrap_buffer; /* String to indent by if the wrap occurs. */ static int wrap_indent; /* Column number on the screen where wrap_buffer begins, or 0 if wrapping is not in effect. */ static int wrap_column; /* The style applied at the time that wrap_here was called. */ static ui_file_style wrap_style; /* Initialize the number of lines per page and chars per line. */ void init_page_info (void) { if (batch_flag) { lines_per_page = UINT_MAX; chars_per_line = UINT_MAX; } else #if defined(TUI) if (!tui_get_command_dimension (&chars_per_line, &lines_per_page)) #endif { int rows, cols; #if defined(__GO32__) rows = ScreenRows (); cols = ScreenCols (); lines_per_page = rows; chars_per_line = cols; #else /* Make sure Readline has initialized its terminal settings. */ rl_reset_terminal (NULL); /* Get the screen size from Readline. */ rl_get_screen_size (&rows, &cols); lines_per_page = rows; chars_per_line = cols; /* Readline should have fetched the termcap entry for us. Only try to use tgetnum function if rl_get_screen_size did not return a useful value. */ if (((rows <= 0) && (tgetnum ((char *) "li") < 0)) /* Also disable paging if inside Emacs. $EMACS was used before Emacs v25.1, $INSIDE_EMACS is used since then. */ || getenv ("EMACS") || getenv ("INSIDE_EMACS")) { /* The number of lines per page is not mentioned in the terminal description or EMACS environment variable is set. This probably means that paging is not useful, so disable paging. */ lines_per_page = UINT_MAX; } /* If the output is not a terminal, don't paginate it. */ if (!gdb_stdout->isatty ()) lines_per_page = UINT_MAX; #endif } /* We handle SIGWINCH ourselves. */ rl_catch_sigwinch = 0; set_screen_size (); set_width (); } /* Return nonzero if filtered printing is initialized. */ int filtered_printing_initialized (void) { return filter_initialized; } set_batch_flag_and_restore_page_info::set_batch_flag_and_restore_page_info () : m_save_lines_per_page (lines_per_page), m_save_chars_per_line (chars_per_line), m_save_batch_flag (batch_flag) { batch_flag = 1; init_page_info (); } set_batch_flag_and_restore_page_info::~set_batch_flag_and_restore_page_info () { batch_flag = m_save_batch_flag; chars_per_line = m_save_chars_per_line; lines_per_page = m_save_lines_per_page; set_screen_size (); set_width (); } /* Set the screen size based on LINES_PER_PAGE and CHARS_PER_LINE. */ static void set_screen_size (void) { int rows = lines_per_page; int cols = chars_per_line; /* If we get 0 or negative ROWS or COLS, treat as "infinite" size. A negative number can be seen here with the "set width/height" commands and either: - the user specified "unlimited", which maps to UINT_MAX, or - the user specified some number between INT_MAX and UINT_MAX. Cap "infinity" to approximately sqrt(INT_MAX) so that we don't overflow in rl_set_screen_size, which multiplies rows and columns to compute the number of characters on the screen. */ const int sqrt_int_max = INT_MAX >> (sizeof (int) * 8 / 2); if (rows <= 0 || rows > sqrt_int_max) { rows = sqrt_int_max; lines_per_page = UINT_MAX; } if (cols <= 0 || cols > sqrt_int_max) { cols = sqrt_int_max; chars_per_line = UINT_MAX; } /* Update Readline's idea of the terminal size. */ rl_set_screen_size (rows, cols); } /* Reinitialize WRAP_BUFFER. */ static void set_width (void) { if (chars_per_line == 0) init_page_info (); wrap_buffer.clear (); filter_initialized = true; } static void set_width_command (const char *args, int from_tty, struct cmd_list_element *c) { set_screen_size (); set_width (); } static void set_height_command (const char *args, int from_tty, struct cmd_list_element *c) { set_screen_size (); } /* See utils.h. */ void set_screen_width_and_height (int width, int height) { lines_per_page = height; chars_per_line = width; set_screen_size (); set_width (); } /* The currently applied style. */ static ui_file_style applied_style; /* Emit an ANSI style escape for STYLE. If STREAM is nullptr, emit to the wrap buffer; otherwise emit to STREAM. */ static void emit_style_escape (const ui_file_style &style, struct ui_file *stream = nullptr) { if (applied_style != style) { applied_style = style; if (stream == nullptr) wrap_buffer.append (style.to_ansi ()); else stream->puts (style.to_ansi ().c_str ()); } } /* Set the current output style. This will affect future uses of the _filtered output functions. */ static void set_output_style (struct ui_file *stream, const ui_file_style &style) { if (!stream->can_emit_style_escape ()) return; /* Note that we may not pass STREAM here, when we want to emit to the wrap buffer, not directly to STREAM. */ if (stream == gdb_stdout) stream = nullptr; emit_style_escape (style, stream); } /* See utils.h. */ void reset_terminal_style (struct ui_file *stream) { if (stream->can_emit_style_escape ()) { /* Force the setting, regardless of what we think the setting might already be. */ applied_style = ui_file_style (); wrap_buffer.append (applied_style.to_ansi ()); } } /* Wait, so the user can read what's on the screen. Prompt the user to continue by pressing RETURN. 'q' is also provided because telling users what to do in the prompt is more user-friendly than expecting them to think of Ctrl-C/SIGINT. */ static void prompt_for_continue (void) { char cont_prompt[120]; /* Used to add duration we waited for user to respond to prompt_for_continue_wait_time. */ using namespace std::chrono; steady_clock::time_point prompt_started = steady_clock::now (); bool disable_pagination = pagination_disabled_for_command; /* Clear the current styling. */ if (gdb_stdout->can_emit_style_escape ()) emit_style_escape (ui_file_style (), gdb_stdout); if (annotation_level > 1) printf_unfiltered (("\n\032\032pre-prompt-for-continue\n")); strcpy (cont_prompt, "--Type for more, q to quit, " "c to continue without paging--"); if (annotation_level > 1) strcat (cont_prompt, "\n\032\032prompt-for-continue\n"); /* We must do this *before* we call gdb_readline_wrapper, else it will eventually call us -- thinking that we're trying to print beyond the end of the screen. */ reinitialize_more_filter (); scoped_input_handler prepare_input; /* Call gdb_readline_wrapper, not readline, in order to keep an event loop running. */ gdb::unique_xmalloc_ptr ignore (gdb_readline_wrapper (cont_prompt)); /* Add time spend in this routine to prompt_for_continue_wait_time. */ prompt_for_continue_wait_time += steady_clock::now () - prompt_started; if (annotation_level > 1) printf_unfiltered (("\n\032\032post-prompt-for-continue\n")); if (ignore != NULL) { char *p = ignore.get (); while (*p == ' ' || *p == '\t') ++p; if (p[0] == 'q') /* Do not call quit here; there is no possibility of SIGINT. */ throw_quit ("Quit"); if (p[0] == 'c') disable_pagination = true; } /* Now we have to do this again, so that GDB will know that it doesn't need to save the ---Type --- line at the top of the screen. */ reinitialize_more_filter (); pagination_disabled_for_command = disable_pagination; dont_repeat (); /* Forget prev cmd -- CR won't repeat it. */ } /* Initialize timer to keep track of how long we waited for the user. */ void reset_prompt_for_continue_wait_time (void) { using namespace std::chrono; prompt_for_continue_wait_time = steady_clock::duration::zero (); } /* Fetch the cumulative time spent in prompt_for_continue. */ std::chrono::steady_clock::duration get_prompt_for_continue_wait_time () { return prompt_for_continue_wait_time; } /* Reinitialize filter; ie. tell it to reset to original values. */ void reinitialize_more_filter (void) { lines_printed = 0; chars_printed = 0; pagination_disabled_for_command = false; } /* Flush the wrap buffer to STREAM, if necessary. */ static void flush_wrap_buffer (struct ui_file *stream) { if (stream == gdb_stdout && !wrap_buffer.empty ()) { stream->puts (wrap_buffer.c_str ()); wrap_buffer.clear (); } } /* See utils.h. */ void gdb_flush (struct ui_file *stream) { flush_wrap_buffer (stream); stream->flush (); } /* See utils.h. */ int get_chars_per_line () { return chars_per_line; } /* See ui-file.h. */ void ui_file::wrap_here (int indent) { /* This should have been allocated, but be paranoid anyway. */ gdb_assert (filter_initialized); flush_wrap_buffer (this); if (chars_per_line == UINT_MAX) /* No line overflow checking. */ { wrap_column = 0; } else if (chars_printed >= chars_per_line) { puts_filtered ("\n"); if (indent != 0) puts_filtered (n_spaces (indent)); wrap_column = 0; } else { wrap_column = chars_printed; wrap_indent = indent; wrap_style = applied_style; } } /* Print input string to gdb_stdout, filtered, with wrap, arranging strings in columns of n chars. String can be right or left justified in the column. Never prints trailing spaces. String should never be longer than width. FIXME: this could be useful for the EXAMINE command, which currently doesn't tabulate very well. */ void puts_filtered_tabular (char *string, int width, int right) { int spaces = 0; int stringlen; char *spacebuf; gdb_assert (chars_per_line > 0); if (chars_per_line == UINT_MAX) { puts_filtered (string); puts_filtered ("\n"); return; } if (((chars_printed - 1) / width + 2) * width >= chars_per_line) puts_filtered ("\n"); if (width >= chars_per_line) width = chars_per_line - 1; stringlen = strlen (string); if (chars_printed > 0) spaces = width - (chars_printed - 1) % width - 1; if (right) spaces += width - stringlen; spacebuf = (char *) alloca (spaces + 1); spacebuf[spaces] = '\0'; while (spaces--) spacebuf[spaces] = ' '; puts_filtered (spacebuf); puts_filtered (string); } /* Ensure that whatever gets printed next, using the filtered output commands, starts at the beginning of the line. I.e. if there is any pending output for the current line, flush it and start a new line. Otherwise do nothing. */ void begin_line (void) { if (chars_printed > 0) { puts_filtered ("\n"); } } /* Like fputs but if FILTER is true, pause after every screenful. Regardless of FILTER can wrap at points other than the final character of a line. Unlike fputs, fputs_maybe_filtered does not return a value. It is OK for LINEBUFFER to be NULL, in which case just don't print anything. Note that a longjmp to top level may occur in this routine (only if FILTER is true) (since prompt_for_continue may do so) so this routine should not be called when cleanups are not in place. */ static void fputs_maybe_filtered (const char *linebuffer, struct ui_file *stream, int filter) { const char *lineptr; if (linebuffer == 0) return; /* Don't do any filtering if it is disabled. */ if (!stream->can_page () || stream != gdb_stdout || !pagination_enabled || pagination_disabled_for_command || batch_flag || (lines_per_page == UINT_MAX && chars_per_line == UINT_MAX) || top_level_interpreter () == NULL || top_level_interpreter ()->interp_ui_out ()->is_mi_like_p ()) { flush_wrap_buffer (stream); stream->puts (linebuffer); return; } auto buffer_clearer = make_scope_exit ([&] () { wrap_buffer.clear (); wrap_column = 0; wrap_indent = 0; }); /* Go through and output each character. Show line extension when this is necessary; prompt user for new page when this is necessary. */ lineptr = linebuffer; while (*lineptr) { /* Possible new page. Note that PAGINATION_DISABLED_FOR_COMMAND might be set during this loop, so we must continue to check it here. */ if (filter && (lines_printed >= lines_per_page - 1) && !pagination_disabled_for_command) prompt_for_continue (); while (*lineptr && *lineptr != '\n') { int skip_bytes; /* Print a single line. */ if (*lineptr == '\t') { wrap_buffer.push_back ('\t'); /* Shifting right by 3 produces the number of tab stops we have already passed, and then adding one and shifting left 3 advances to the next tab stop. */ chars_printed = ((chars_printed >> 3) + 1) << 3; lineptr++; } else if (*lineptr == '\033' && skip_ansi_escape (lineptr, &skip_bytes)) { wrap_buffer.append (lineptr, skip_bytes); /* Note that we don't consider this a character, so we don't increment chars_printed here. */ lineptr += skip_bytes; } else if (*lineptr == '\r') { wrap_buffer.push_back (*lineptr); chars_printed = 0; lineptr++; } else { wrap_buffer.push_back (*lineptr); chars_printed++; lineptr++; } if (chars_printed >= chars_per_line) { unsigned int save_chars = chars_printed; /* If we change the style, below, we'll want to reset it before continuing to print. If there is no wrap column, then we'll only reset the style if the pager prompt is given; and to avoid emitting style sequences in the middle of a run of text, we track this as well. */ ui_file_style save_style = applied_style; bool did_paginate = false; chars_printed = 0; lines_printed++; if (wrap_column) { /* We are about to insert a newline at an historic location in the WRAP_BUFFER. Before we do we want to restore the default style. To know if we actually need to insert an escape sequence we must restore the current applied style to how it was at the WRAP_COLUMN location. */ applied_style = wrap_style; if (stream->can_emit_style_escape ()) emit_style_escape (ui_file_style (), stream); /* If we aren't actually wrapping, don't output newline -- if chars_per_line is right, we probably just overflowed anyway; if it's wrong, let us keep going. */ /* XXX: The ideal thing would be to call 'stream->putc' here, but we can't because it currently calls 'fputc_unfiltered', which ends up calling us, which generates an infinite recursion. */ stream->puts ("\n"); } else flush_wrap_buffer (stream); /* Possible new page. Note that PAGINATION_DISABLED_FOR_COMMAND might be set during this loop, so we must continue to check it here. */ if (filter && lines_printed >= lines_per_page - 1 && !pagination_disabled_for_command) { prompt_for_continue (); did_paginate = true; } /* Now output indentation and wrapped string. */ if (wrap_column) { stream->puts (n_spaces (wrap_indent)); /* Having finished inserting the wrapping we should restore the style as it was at the WRAP_COLUMN. */ if (stream->can_emit_style_escape ()) emit_style_escape (wrap_style, stream); /* The WRAP_BUFFER will still contain content, and that content might set some alternative style. Restore APPLIED_STYLE as it was before we started wrapping, this reflects the current style for the last character in WRAP_BUFFER. */ applied_style = save_style; /* Note that this can set chars_printed > chars_per_line if we are printing a long string. */ chars_printed = wrap_indent + (save_chars - wrap_column); wrap_column = 0; /* And disable fancy wrap */ } else if (did_paginate && stream->can_emit_style_escape ()) emit_style_escape (save_style, stream); } } if (*lineptr == '\n') { chars_printed = 0; stream->wrap_here (0); /* Spit out chars, cancel further wraps. */ lines_printed++; /* XXX: The ideal thing would be to call 'stream->putc' here, but we can't because it currently calls 'fputc_unfiltered', which ends up calling us, which generates an infinite recursion. */ stream->puts ("\n"); lineptr++; } } buffer_clearer.release (); } void fputs_filtered (const char *linebuffer, struct ui_file *stream) { fputs_maybe_filtered (linebuffer, stream, 1); } void fputs_unfiltered (const char *linebuffer, struct ui_file *stream) { fputs_maybe_filtered (linebuffer, stream, 0); } /* See utils.h. */ void fputs_styled (const char *linebuffer, const ui_file_style &style, struct ui_file *stream) { set_output_style (stream, style); fputs_maybe_filtered (linebuffer, stream, 1); set_output_style (stream, ui_file_style ()); } /* See utils.h. */ void fputs_styled_unfiltered (const char *linebuffer, const ui_file_style &style, struct ui_file *stream) { set_output_style (stream, style); fputs_maybe_filtered (linebuffer, stream, 0); set_output_style (stream, ui_file_style ()); } /* See utils.h. */ void fputs_highlighted (const char *str, const compiled_regex &highlight, struct ui_file *stream) { regmatch_t pmatch; while (*str && highlight.exec (str, 1, &pmatch, 0) == 0) { size_t n_highlight = pmatch.rm_eo - pmatch.rm_so; /* Output the part before pmatch with current style. */ while (pmatch.rm_so > 0) { fputc_filtered (*str, stream); pmatch.rm_so--; str++; } /* Output pmatch with the highlight style. */ set_output_style (stream, highlight_style.style ()); while (n_highlight > 0) { fputc_filtered (*str, stream); n_highlight--; str++; } set_output_style (stream, ui_file_style ()); } /* Output the trailing part of STR not matching HIGHLIGHT. */ if (*str) fputs_filtered (str, stream); } int putchar_unfiltered (int c) { return fputc_unfiltered (c, gdb_stdout); } /* Write character C to gdb_stdout using GDB's paging mechanism and return C. May return nonlocally. */ int putchar_filtered (int c) { return fputc_filtered (c, gdb_stdout); } int fputc_unfiltered (int c, struct ui_file *stream) { char buf[2]; buf[0] = c; buf[1] = 0; fputs_unfiltered (buf, stream); return c; } int fputc_filtered (int c, struct ui_file *stream) { char buf[2]; buf[0] = c; buf[1] = 0; fputs_filtered (buf, stream); return c; } /* Print a variable number of ARGS using format FORMAT. If this information is going to put the amount written (since the last call to REINITIALIZE_MORE_FILTER or the last page break) over the page size, call prompt_for_continue to get the users permission to continue. Unlike fprintf, this function does not return a value. We implement three variants, vfprintf (takes a vararg list and stream), fprintf (takes a stream to write on), and printf (the usual). Note also that this may throw a quit (since prompt_for_continue may do so). */ static void vfprintf_maybe_filtered (struct ui_file *stream, const char *format, va_list args, bool filter) { ui_out_flags flags = disallow_ui_out_field; if (!filter) flags |= unfiltered_output; cli_ui_out (stream, flags).vmessage (applied_style, format, args); } void vfprintf_filtered (struct ui_file *stream, const char *format, va_list args) { vfprintf_maybe_filtered (stream, format, args, true); } void vfprintf_unfiltered (struct ui_file *stream, const char *format, va_list args) { if (debug_timestamp && stream == gdb_stdlog) { static bool needs_timestamp = true; /* Print timestamp if previous print ended with a \n. */ if (needs_timestamp) { using namespace std::chrono; steady_clock::time_point now = steady_clock::now (); seconds s = duration_cast (now.time_since_epoch ()); microseconds us = duration_cast (now.time_since_epoch () - s); std::string timestamp = string_printf ("%ld.%06ld ", (long) s.count (), (long) us.count ()); fputs_unfiltered (timestamp.c_str (), stream); } /* Print the message. */ string_file sfile; cli_ui_out (&sfile, 0).vmessage (ui_file_style (), format, args); const std::string &linebuffer = sfile.string (); fputs_unfiltered (linebuffer.c_str (), stream); size_t len = linebuffer.length (); needs_timestamp = (len > 0 && linebuffer[len - 1] == '\n'); } else vfprintf_maybe_filtered (stream, format, args, false); } void vprintf_filtered (const char *format, va_list args) { vfprintf_filtered (gdb_stdout, format, args); } void vprintf_unfiltered (const char *format, va_list args) { vfprintf_unfiltered (gdb_stdout, format, args); } void fprintf_filtered (struct ui_file *stream, const char *format, ...) { va_list args; va_start (args, format); vfprintf_filtered (stream, format, args); va_end (args); } void fprintf_unfiltered (struct ui_file *stream, const char *format, ...) { va_list args; va_start (args, format); vfprintf_unfiltered (stream, format, args); va_end (args); } /* See utils.h. */ void fprintf_styled (struct ui_file *stream, const ui_file_style &style, const char *format, ...) { va_list args; set_output_style (stream, style); va_start (args, format); vfprintf_filtered (stream, format, args); va_end (args); set_output_style (stream, ui_file_style ()); } /* See utils.h. */ void vfprintf_styled (struct ui_file *stream, const ui_file_style &style, const char *format, va_list args) { set_output_style (stream, style); vfprintf_filtered (stream, format, args); set_output_style (stream, ui_file_style ()); } /* See utils.h. */ void vfprintf_styled_no_gdbfmt (struct ui_file *stream, const ui_file_style &style, bool filter, const char *format, va_list args) { std::string str = string_vprintf (format, args); if (!str.empty ()) { set_output_style (stream, style); fputs_maybe_filtered (str.c_str (), stream, filter); set_output_style (stream, ui_file_style ()); } } void printf_filtered (const char *format, ...) { va_list args; va_start (args, format); vfprintf_filtered (gdb_stdout, format, args); va_end (args); } void printf_unfiltered (const char *format, ...) { va_list args; va_start (args, format); vfprintf_unfiltered (gdb_stdout, format, args); va_end (args); } /* Easy -- but watch out! This routine is *not* a replacement for puts()! puts() appends a newline. This one doesn't, and had better not! */ void puts_filtered (const char *string) { fputs_filtered (string, gdb_stdout); } void puts_unfiltered (const char *string) { fputs_unfiltered (string, gdb_stdout); } /* Return a pointer to N spaces and a null. The pointer is good until the next call to here. */ const char * n_spaces (int n) { char *t; static char *spaces = 0; static int max_spaces = -1; if (n > max_spaces) { xfree (spaces); spaces = (char *) xmalloc (n + 1); for (t = spaces + n; t != spaces;) *--t = ' '; spaces[n] = '\0'; max_spaces = n; } return spaces + max_spaces - n; } /* Print N spaces. */ void print_spaces_filtered (int n, struct ui_file *stream) { fputs_filtered (n_spaces (n), stream); } /* C++/ObjC demangler stuff. */ /* fprintf_symbol_filtered attempts to demangle NAME, a symbol in language LANG, using demangling args ARG_MODE, and print it filtered to STREAM. If the name is not mangled, or the language for the name is unknown, or demangling is off, the name is printed in its "raw" form. */ void fprintf_symbol_filtered (struct ui_file *stream, const char *name, enum language lang, int arg_mode) { if (name != NULL) { /* If user wants to see raw output, no problem. */ if (!demangle) { fputs_filtered (name, stream); } else { gdb::unique_xmalloc_ptr demangled = language_demangle (language_def (lang), name, arg_mode); fputs_filtered (demangled ? demangled.get () : name, stream); } } } /* True if CH is a character that can be part of a symbol name. I.e., either a number, a letter, or a '_'. */ static bool valid_identifier_name_char (int ch) { return (ISALNUM (ch) || ch == '_'); } /* Skip to end of token, or to END, whatever comes first. Input is assumed to be a C++ operator name. */ static const char * cp_skip_operator_token (const char *token, const char *end) { const char *p = token; while (p != end && !ISSPACE (*p) && *p != '(') { if (valid_identifier_name_char (*p)) { while (p != end && valid_identifier_name_char (*p)) p++; return p; } else { /* Note, ordered such that among ops that share a prefix, longer comes first. This is so that the loop below can bail on first match. */ static const char *ops[] = { "[", "]", "~", ",", "-=", "--", "->", "-", "+=", "++", "+", "*=", "*", "/=", "/", "%=", "%", "|=", "||", "|", "&=", "&&", "&", "^=", "^", "!=", "!", "<<=", "<=", "<<", "<", ">>=", ">=", ">>", ">", "==", "=", }; for (const char *op : ops) { size_t oplen = strlen (op); size_t lencmp = std::min (oplen, end - p); if (strncmp (p, op, lencmp) == 0) return p + lencmp; } /* Some unidentified character. Return it. */ return p + 1; } } return p; } /* Advance STRING1/STRING2 past whitespace. */ static void skip_ws (const char *&string1, const char *&string2, const char *end_str2) { while (ISSPACE (*string1)) string1++; while (string2 < end_str2 && ISSPACE (*string2)) string2++; } /* True if STRING points at the start of a C++ operator name. START is the start of the string that STRING points to, hence when reading backwards, we must not read any character before START. */ static bool cp_is_operator (const char *string, const char *start) { return ((string == start || !valid_identifier_name_char (string[-1])) && strncmp (string, CP_OPERATOR_STR, CP_OPERATOR_LEN) == 0 && !valid_identifier_name_char (string[CP_OPERATOR_LEN])); } /* If *NAME points at an ABI tag, skip it and return true. Otherwise leave *NAME unmodified and return false. (see GCC's abi_tag attribute), such names are demangled as e.g., "function[abi:cxx11]()". */ static bool skip_abi_tag (const char **name) { const char *p = *name; if (startswith (p, "[abi:")) { p += 5; while (valid_identifier_name_char (*p)) p++; if (*p == ']') { p++; *name = p; return true; } } return false; } /* If *NAME points at a template parameter list, skip it and return true. Otherwise do nothing and return false. */ static bool skip_template_parameter_list (const char **name) { const char *p = *name; if (*p == '<') { const char *template_param_list_end = find_toplevel_char (p + 1, '>'); if (template_param_list_end == NULL) return false; p = template_param_list_end + 1; /* Skip any whitespace that might occur after the closing of the parameter list, but only if it is the end of parameter list. */ const char *q = p; while (ISSPACE (*q)) ++q; if (*q == '>') p = q; *name = p; return true; } return false; } /* See utils.h. */ int strncmp_iw_with_mode (const char *string1, const char *string2, size_t string2_len, strncmp_iw_mode mode, enum language language, completion_match_for_lcd *match_for_lcd, bool ignore_template_params) { const char *string1_start = string1; const char *end_str2 = string2 + string2_len; bool skip_spaces = true; bool have_colon_op = (language == language_cplus || language == language_rust || language == language_fortran); while (1) { if (skip_spaces || ((ISSPACE (*string1) && !valid_identifier_name_char (*string2)) || (ISSPACE (*string2) && !valid_identifier_name_char (*string1)))) { skip_ws (string1, string2, end_str2); skip_spaces = false; } /* Skip [abi:cxx11] tags in the symbol name if the lookup name doesn't include them. E.g.: string1: function[abi:cxx1](int) string2: function string1: function[abi:cxx1](int) string2: function(int) string1: Struct[abi:cxx1]::function() string2: Struct::function() string1: function(Struct[abi:cxx1], int) string2: function(Struct, int) */ if (string2 == end_str2 || (*string2 != '[' && !valid_identifier_name_char (*string2))) { const char *abi_start = string1; /* There can be more than one tag. */ while (*string1 == '[' && skip_abi_tag (&string1)) ; if (match_for_lcd != NULL && abi_start != string1) match_for_lcd->mark_ignored_range (abi_start, string1); while (ISSPACE (*string1)) string1++; } /* Skip template parameters in STRING1 if STRING2 does not contain any. E.g.: Case 1: User is looking for all functions named "foo". string1: foo <...> (...) string2: foo Case 2: User is looking for all methods named "foo" in all template class instantiations. string1: Foo<...>::foo <...> (...) string2: Foo::foo (...) Case 3: User is looking for a specific overload of a template function or method. string1: foo<...> string2: foo(...) Case 4: User is looking for a specific overload of a specific template instantiation. string1: foo (...) string2: foo (...) Case 5: User is looking wild parameter match. string1: foo > > > (...) string2: foomark_ignored_range (template_start, string1); } } if (*string1 == '\0' || string2 == end_str2) break; /* Handle the :: operator. */ if (have_colon_op && string1[0] == ':' && string1[1] == ':') { if (*string2 != ':') return 1; string1++; string2++; if (string2 == end_str2) break; if (*string2 != ':') return 1; string1++; string2++; while (ISSPACE (*string1)) string1++; while (string2 < end_str2 && ISSPACE (*string2)) string2++; continue; } /* Handle C++ user-defined operators. */ else if (language == language_cplus && *string1 == 'o') { if (cp_is_operator (string1, string1_start)) { /* An operator name in STRING1. Check STRING2. */ size_t cmplen = std::min (CP_OPERATOR_LEN, end_str2 - string2); if (strncmp (string1, string2, cmplen) != 0) return 1; string1 += cmplen; string2 += cmplen; if (string2 != end_str2) { /* Check for "operatorX" in STRING2. */ if (valid_identifier_name_char (*string2)) return 1; skip_ws (string1, string2, end_str2); } /* Handle operator(). */ if (*string1 == '(') { if (string2 == end_str2) { if (mode == strncmp_iw_mode::NORMAL) return 0; else { /* Don't break for the regular return at the bottom, because "operator" should not match "operator()", since this open parentheses is not the parameter list start. */ return *string1 != '\0'; } } if (*string1 != *string2) return 1; string1++; string2++; } while (1) { skip_ws (string1, string2, end_str2); /* Skip to end of token, or to END, whatever comes first. */ const char *end_str1 = string1 + strlen (string1); const char *p1 = cp_skip_operator_token (string1, end_str1); const char *p2 = cp_skip_operator_token (string2, end_str2); cmplen = std::min (p1 - string1, p2 - string2); if (p2 == end_str2) { if (strncmp (string1, string2, cmplen) != 0) return 1; } else { if (p1 - string1 != p2 - string2) return 1; if (strncmp (string1, string2, cmplen) != 0) return 1; } string1 += cmplen; string2 += cmplen; if (*string1 == '\0' || string2 == end_str2) break; if (*string1 == '(' || *string2 == '(') break; /* If STRING1 or STRING2 starts with a template parameter list, break out of operator processing. */ skip_ws (string1, string2, end_str2); if (*string1 == '<' || *string2 == '<') break; } continue; } } if (case_sensitivity == case_sensitive_on && *string1 != *string2) break; if (case_sensitivity == case_sensitive_off && (TOLOWER ((unsigned char) *string1) != TOLOWER ((unsigned char) *string2))) break; /* If we see any non-whitespace, non-identifier-name character (any of "()<>*&" etc.), then skip spaces the next time around. */ if (!ISSPACE (*string1) && !valid_identifier_name_char (*string1)) skip_spaces = true; string1++; string2++; } if (string2 == end_str2) { if (mode == strncmp_iw_mode::NORMAL) { /* Strip abi tag markers from the matched symbol name. Usually the ABI marker will be found on function name (automatically added because the function returns an object marked with an ABI tag). However, it's also possible to see a marker in one of the function parameters, for example. string2 (lookup name): func symbol name: function(some_struct[abi:cxx11], int) and for completion LCD computation we want to say that the match was for: function(some_struct, int) */ if (match_for_lcd != NULL) { while ((string1 = strstr (string1, "[abi:")) != NULL) { const char *abi_start = string1; /* There can be more than one tag. */ while (skip_abi_tag (&string1) && *string1 == '[') ; if (abi_start != string1) match_for_lcd->mark_ignored_range (abi_start, string1); } } return 0; } else return (*string1 != '\0' && *string1 != '('); } else return 1; } #if GDB_SELF_TEST /* Unit tests for strncmp_iw_with_mode. */ #define CHECK_MATCH_LM(S1, S2, MODE, LANG, LCD) \ SELF_CHECK (strncmp_iw_with_mode ((S1), (S2), strlen ((S2)), \ strncmp_iw_mode::MODE, \ (LANG), (LCD)) == 0) #define CHECK_MATCH_LANG(S1, S2, MODE, LANG) \ CHECK_MATCH_LM ((S1), (S2), MODE, (LANG), nullptr) #define CHECK_MATCH(S1, S2, MODE) \ CHECK_MATCH_LANG ((S1), (S2), MODE, language_minimal) #define CHECK_NO_MATCH_LM(S1, S2, MODE, LANG, LCD) \ SELF_CHECK (strncmp_iw_with_mode ((S1), (S2), strlen ((S2)), \ strncmp_iw_mode::MODE, \ (LANG)) != 0) #define CHECK_NO_MATCH_LANG(S1, S2, MODE, LANG) \ CHECK_NO_MATCH_LM ((S1), (S2), MODE, (LANG), nullptr) #define CHECK_NO_MATCH(S1, S2, MODE) \ CHECK_NO_MATCH_LANG ((S1), (S2), MODE, language_minimal) static void check_scope_operator (enum language lang) { CHECK_MATCH_LANG ("::", "::", NORMAL, lang); CHECK_MATCH_LANG ("::foo", "::", NORMAL, lang); CHECK_MATCH_LANG ("::foo", "::foo", NORMAL, lang); CHECK_MATCH_LANG (" :: foo ", "::foo", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a ::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a\t::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a \t::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a\t ::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a:: b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a::\tb", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a:: \tb", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a::\t b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a :: b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a ::\tb", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a\t:: b", NORMAL, lang); CHECK_MATCH_LANG ("a::b", "a \t::\t b", NORMAL, lang); CHECK_MATCH_LANG ("a ::b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a\t::b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a \t::b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a\t ::b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a:: b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::\tb", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a:: \tb", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::\t b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a :: b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a ::\tb", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a\t:: b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a \t::\t b", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG (" a:: b:: c", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", " a:: b:: c", NORMAL, lang); CHECK_MATCH_LANG ("a ::b ::c", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", "a :: b:: c", NORMAL, lang); CHECK_MATCH_LANG ("\ta::\tb::\tc", "\ta::\tb::\tc", NORMAL, lang); CHECK_MATCH_LANG ("a\t::b\t::c\t", "a\t::b\t::c\t", NORMAL, lang); CHECK_MATCH_LANG (" \ta:: \tb:: \tc", " \ta:: \tb:: \tc", NORMAL, lang); CHECK_MATCH_LANG ("\t a::\t b::\t c", "\t a::\t b::\t c", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", "\ta::\tb::\tc", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", "a\t::b\t::c\t", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", " \ta:: \tb:: \tc", NORMAL, lang); CHECK_MATCH_LANG ("a::b::c", "\t a::\t b::\t c", NORMAL, lang); CHECK_MATCH_LANG ("\ta::\tb::\tc", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG ("a\t::b\t::c\t", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG (" \ta:: \tb:: \tc", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG ("\t a::\t b::\t c", "a::b::c", NORMAL, lang); CHECK_MATCH_LANG ("a :: b:: c\t", "\ta :: b\t:: c\t\t", NORMAL, lang); CHECK_MATCH_LANG (" a::\t \t b:: c\t", "\ta ::b:: c\t\t", NORMAL, lang); CHECK_MATCH_LANG ("a :: b :: \t\t\tc\t", "\t\t\t\ta :: \t\t\t b \t\t::c", NORMAL, lang); CHECK_MATCH_LANG ("a::b()", "a", NORMAL, lang); CHECK_MATCH_LANG ("a::b()", "a::", NORMAL, lang); CHECK_MATCH_LANG ("a::b()", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a)", "a", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a)", "a::", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a)", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b)", "a", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b)", "a::", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b)", "a::b", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b,c)", "a", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b,c)", "a::", NORMAL, lang); CHECK_MATCH_LANG ("a::b(a,b,c)", "a::b", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::", "::a", NORMAL, lang); CHECK_NO_MATCH_LANG ("::a", "::a()", NORMAL, lang); CHECK_NO_MATCH_LANG ("::", "::a", NORMAL, lang); CHECK_NO_MATCH_LANG ("a:::b", "a::b", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b()", "a::b(a)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b(a)", "a::b()", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b(a,b)", "a::b(a,a)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a()", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::()", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::b()", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a(a)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::(a)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::b()", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a(a,b)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::(a,b)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::b(a,b)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a(a,b,c)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::(a,b,c)", NORMAL, lang); CHECK_NO_MATCH_LANG ("a::b", "a::b(a,b,c)", NORMAL, lang); } /* Callback for strncmp_iw_with_mode unit tests. */ static void strncmp_iw_with_mode_tests () { /* Some of the following tests are nonsensical, but could be input by a deranged script (or user). */ /* strncmp_iw_mode::NORMAL: strcmp()-like but ignore any whitespace... */ CHECK_MATCH ("", "", NORMAL); CHECK_MATCH ("foo", "foo", NORMAL); CHECK_MATCH (" foo", "foo", NORMAL); CHECK_MATCH ("foo ", "foo", NORMAL); CHECK_MATCH (" foo ", "foo", NORMAL); CHECK_MATCH (" foo", "foo", NORMAL); CHECK_MATCH ("foo ", "foo", NORMAL); CHECK_MATCH (" foo ", "foo", NORMAL); CHECK_MATCH ("\tfoo", "foo", NORMAL); CHECK_MATCH ("foo\t", "foo", NORMAL); CHECK_MATCH ("\tfoo\t", "foo", NORMAL); CHECK_MATCH (" \tfoo \t", "foo", NORMAL); CHECK_MATCH ("\t foo\t ", "foo", NORMAL); CHECK_MATCH ("\t \t \t\t\t\t foo\t\t\t \t\t \t \t \t \t ", "foo", NORMAL); CHECK_MATCH ("foo", "\t \t \t\t\t\t foo\t\t\t \t\t \t \t \t \t ", NORMAL); CHECK_MATCH ("foo bar", "foo", NORMAL); CHECK_NO_MATCH ("foo", "bar", NORMAL); CHECK_NO_MATCH ("foo bar", "foobar", NORMAL); CHECK_NO_MATCH (" foo ", "bar", NORMAL); CHECK_NO_MATCH ("foo", " bar ", NORMAL); CHECK_NO_MATCH (" \t\t foo\t\t ", "\t \t \tbar\t", NORMAL); CHECK_NO_MATCH ("@!%&", "@!%&foo", NORMAL); /* ... and function parameters in STRING1. */ CHECK_MATCH ("foo()", "foo()", NORMAL); CHECK_MATCH ("foo ()", "foo()", NORMAL); CHECK_MATCH ("foo ()", "foo()", NORMAL); CHECK_MATCH ("foo\t()", "foo()", NORMAL); CHECK_MATCH ("foo\t ()", "foo()", NORMAL); CHECK_MATCH ("foo \t()", "foo()", NORMAL); CHECK_MATCH ("foo()", "foo ()", NORMAL); CHECK_MATCH ("foo()", "foo ()", NORMAL); CHECK_MATCH ("foo()", "foo\t()", NORMAL); CHECK_MATCH ("foo()", "foo\t ()", NORMAL); CHECK_MATCH ("foo()", "foo \t()", NORMAL); CHECK_MATCH ("foo()", "foo()", NORMAL); CHECK_MATCH ("foo ()", "foo ()", NORMAL); CHECK_MATCH ("foo ()", "foo ()", NORMAL); CHECK_MATCH ("foo\t()", "foo\t()", NORMAL); CHECK_MATCH ("foo\t ()", "foo\t ()", NORMAL); CHECK_MATCH ("foo \t()", "foo \t()", NORMAL); CHECK_MATCH ("foo(a)", "foo(a)", NORMAL); CHECK_MATCH ("foo( a)", "foo(a)", NORMAL); CHECK_MATCH ("foo(a )", "foo(a)", NORMAL); CHECK_MATCH ("foo(\ta)", "foo(a)", NORMAL); CHECK_MATCH ("foo(a\t)", "foo(a)", NORMAL); CHECK_MATCH ("foo(\t a)", "foo(a)", NORMAL); CHECK_MATCH ("foo( \ta)", "foo(a)", NORMAL); CHECK_MATCH ("foo(a\t )", "foo(a)", NORMAL); CHECK_MATCH ("foo(a \t)", "foo(a)", NORMAL); CHECK_MATCH ("foo( a )", "foo(a)", NORMAL); CHECK_MATCH ("foo(\ta\t)", "foo(a)", NORMAL); CHECK_MATCH ("foo(\t a\t )", "foo(a)", NORMAL); CHECK_MATCH ("foo( \ta \t)", "foo(a)", NORMAL); CHECK_MATCH ("foo(a)", "foo( a)", NORMAL); CHECK_MATCH ("foo(a)", "foo(a )", NORMAL); CHECK_MATCH ("foo(a)", "foo(\ta)", NORMAL); CHECK_MATCH ("foo(a)", "foo(a\t)", NORMAL); CHECK_MATCH ("foo(a)", "foo(\t a)", NORMAL); CHECK_MATCH ("foo(a)", "foo( \ta)", NORMAL); CHECK_MATCH ("foo(a)", "foo(a\t )", NORMAL); CHECK_MATCH ("foo(a)", "foo(a \t)", NORMAL); CHECK_MATCH ("foo(a)", "foo( a )", NORMAL); CHECK_MATCH ("foo(a)", "foo(\ta\t)", NORMAL); CHECK_MATCH ("foo(a)", "foo(\t a\t )", NORMAL); CHECK_MATCH ("foo(a)", "foo( \ta \t)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a ,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a\t,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a,\tb)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a\t,\tb)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a \t,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a\t ,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a,\tb)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a, \tb)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a,\t b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a ,b)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a\t,b)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a,\tb)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a\t,\tb)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a \t,b)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a\t ,b)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a,\tb)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a, \tb)", NORMAL); CHECK_MATCH ("foo(a,b)", "foo(a,\t b)", NORMAL); CHECK_MATCH ("foo(a,b,c,d)", "foo(a,b,c,d)", NORMAL); CHECK_MATCH (" foo ( a , b , c , d ) ", "foo(a,b,c,d)", NORMAL); CHECK_MATCH (" foo ( a , b , c , d ) ", "foo( a , b , c , d )", NORMAL); CHECK_MATCH ("foo &\t*(\ta b *\t\t&)", "foo", NORMAL); CHECK_MATCH ("foo &\t*(\ta b *\t\t&)", "foo&*(a b * &)", NORMAL); CHECK_MATCH ("foo(a) b", "foo(a)", NORMAL); CHECK_MATCH ("*foo(*a&)", "*foo", NORMAL); CHECK_MATCH ("*foo(*a&)", "*foo(*a&)", NORMAL); CHECK_MATCH ("*a&b#c/^d$foo(*a&)", "*a&b#c/^d$foo", NORMAL); CHECK_MATCH ("* foo", "*foo", NORMAL); CHECK_MATCH ("foo&", "foo", NORMAL); CHECK_MATCH ("foo*", "foo", NORMAL); CHECK_MATCH ("foo.", "foo", NORMAL); CHECK_MATCH ("foo->", "foo", NORMAL); CHECK_NO_MATCH ("foo", "foo(", NORMAL); CHECK_NO_MATCH ("foo", "foo()", NORMAL); CHECK_NO_MATCH ("foo", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo", "foo*", NORMAL); CHECK_NO_MATCH ("foo", "foo (*", NORMAL); CHECK_NO_MATCH ("foo*", "foo (*", NORMAL); CHECK_NO_MATCH ("foo *", "foo (*", NORMAL); CHECK_NO_MATCH ("foo&", "foo (*", NORMAL); CHECK_NO_MATCH ("foo &", "foo (*", NORMAL); CHECK_NO_MATCH ("foo &*", "foo (&)", NORMAL); CHECK_NO_MATCH ("foo & \t *\t", "foo (*", NORMAL); CHECK_NO_MATCH ("foo & \t *\t", "foo (*", NORMAL); CHECK_NO_MATCH ("foo(a*) b", "foo(a) b", NORMAL); CHECK_NO_MATCH ("foo[aqi:A](a)", "foo(b)", NORMAL); CHECK_NO_MATCH ("*foo", "foo", NORMAL); CHECK_NO_MATCH ("*foo", "foo*", NORMAL); CHECK_NO_MATCH ("*foo*", "*foo&", NORMAL); CHECK_NO_MATCH ("*foo*", "foo *", NORMAL); CHECK_NO_MATCH ("&foo", "foo", NORMAL); CHECK_NO_MATCH ("&foo", "foo&", NORMAL); CHECK_NO_MATCH ("foo&", "&foo", NORMAL); CHECK_NO_MATCH ("foo", "foo&", NORMAL); CHECK_NO_MATCH ("foo", "foo*", NORMAL); CHECK_NO_MATCH ("foo", "foo.", NORMAL); CHECK_NO_MATCH ("foo", "foo->", NORMAL); CHECK_NO_MATCH ("foo bar", "foo()", NORMAL); CHECK_NO_MATCH ("foo bar", "foo bar()", NORMAL); CHECK_NO_MATCH ("foo()", "foo(a)", NORMAL); CHECK_NO_MATCH ("*(*)&", "*(*)*", NORMAL); CHECK_NO_MATCH ("foo(a)", "foo()", NORMAL); CHECK_NO_MATCH ("foo(a)", "foo(b)", NORMAL); CHECK_NO_MATCH ("foo(a,b)", "foo(a,b,c)", NORMAL); CHECK_NO_MATCH ("foo(a\\b)", "foo()", NORMAL); CHECK_NO_MATCH ("foo bar(a b c d)", "foobar", NORMAL); CHECK_NO_MATCH ("foo bar(a b c d)", "foobar ( a b c \td\t)\t", NORMAL); /* Test scope operator. */ check_scope_operator (language_minimal); check_scope_operator (language_cplus); check_scope_operator (language_fortran); check_scope_operator (language_rust); /* Test C++ user-defined operators. */ CHECK_MATCH_LANG ("operator foo(int&)", "operator foo(int &)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo(int &)", "operator foo(int &)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo(int\t&)", "operator foo(int\t&)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo (int)", "operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo\t(int)", "operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo \t(int)", "operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo (int)", "operator foo \t(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo\t(int)", "operator foo \t(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("operator foo \t(int)", "operator foo \t(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo(int&)", "a::operator foo(int &)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a :: operator foo(int &)", "a::operator foo(int &)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a \t:: \toperator foo(int\t&)", "a::operator foo(int\t&)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo (int)", "a::operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo\t(int)", "a::operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo \t(int)", "a::operator foo(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo (int)", "a::operator foo \t(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo\t(int)", "a::operator foo \t(int)", NORMAL, language_cplus); CHECK_MATCH_LANG ("a::operator foo \t(int)", "a::operator foo \t(int)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("operator foo(int)", "operator foo(char)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("operator foo(int)", "operator foo(int *)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("operator foo(int)", "operator foo(int &)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("operator foo(int)", "operator foo(int, char *)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("operator foo(int)", "operator bar(int)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("a::operator b::foo(int)", "a::operator a::foo(char)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("a::operator foo(int)", "a::operator foo(int *)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("a::operator foo(int)", "a::operator foo(int &)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("a::operator foo(int)", "a::operator foo(int, char *)", NORMAL, language_cplus); CHECK_NO_MATCH_LANG ("a::operator foo(int)", "a::operator bar(int)", NORMAL, language_cplus); /* Skip "[abi:cxx11]" tags in the symbol name if the lookup name doesn't include them. These are not language-specific in strncmp_iw_with_mode. */ CHECK_MATCH ("foo[abi:a]", "foo", NORMAL); CHECK_MATCH ("foo[abi:a]()", "foo", NORMAL); CHECK_MATCH ("foo[abi:a](a)", "foo", NORMAL); CHECK_MATCH ("foo[abi:a](a&,b*)", "foo", NORMAL); CHECK_MATCH ("foo[abi:a](a,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo[abi:a](a,b) c", "foo(a,b) c", NORMAL); CHECK_MATCH ("foo[abi:a](a)", "foo(a)", NORMAL); CHECK_MATCH ("foo[abi:a](a,b)", "foo(a,b)", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[ abi:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[\tabi:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[ \tabi:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[\t abi:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[abi :a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[abi\t:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[abi \t:a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[abi\t :a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[ abi:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[\tabi:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[ \tabi:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[\t abi:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi :a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi\t:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi \t:a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi\t :a]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi:a ]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi:a\t]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi:a \t]", NORMAL); CHECK_MATCH ("foo[abi:a]", "foo[abi:a\t ]", NORMAL); CHECK_MATCH ("foo[abi:a,b]", "foo[abi:a,b]", NORMAL); CHECK_MATCH ("foo[abi:::]", "foo[abi:::]", NORMAL); CHECK_MATCH ("foo[abi : : : ]", "foo[abi:::]", NORMAL); CHECK_MATCH ("foo[abi:::]", "foo[abi : : : ]", NORMAL); CHECK_MATCH ("foo[ \t abi \t:\t: : \t]", "foo[ abi : \t ::]", NORMAL); CHECK_MATCH ("foo< bar< baz< quxi > > >(int)", "foo>>(int)", NORMAL); CHECK_MATCH ("\tfoo<\tbar<\tbaz\t<\tquxi\t>\t>\t>(int)", "foo>>(int)", NORMAL); CHECK_MATCH (" \tfoo \t< \tbar \t< \tbaz \t< \tquxi \t> \t> \t> \t( \tint \t)", "foo>>(int)", NORMAL); CHECK_MATCH ("foo>>(int)", "foo < bar < baz < quxi > > > (int)", NORMAL); CHECK_MATCH ("foo>>(int)", "\tfoo\t<\tbar\t<\tbaz\t<\tquxi\t>\t>\t>\t(int)", NORMAL); CHECK_MATCH ("foo>>(int)", " \tfoo \t< \tbar \t< \tbaz \t< \tquxi \t> \t> \t> \t( \tint \t)", NORMAL); CHECK_MATCH ("foo>::foo(quxi &)", "fo", NORMAL); CHECK_MATCH ("foo>::foo(quxi &)", "foo", NORMAL); CHECK_MATCH ("foo>::foo(quxi &)", "foo>::", NORMAL); CHECK_MATCH ("foo>::foo(quxi &)", "foo >::foo", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a][abi:b](bar[abi:c][abi:d])", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo(bar)", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a](bar)", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo(bar[abi:c])", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a](bar[abi:c])", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a][abi:b](bar)", NORMAL); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a][abi:b](bar[abi:c])", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo", NORMAL); CHECK_NO_MATCH("foo(char *, baz[abi:b])", "foo()", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz)", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz[abi:b])", NORMAL); CHECK_NO_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz[abi:A])", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz)", NORMAL); CHECK_NO_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz)", NORMAL); CHECK_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz[abi:b])", NORMAL); CHECK_NO_MATCH("foo(char *, baz[abi:b])", "foo(char*, baz[abi:B])", NORMAL); CHECK_NO_MATCH ("foo", "foo[", NORMAL); CHECK_NO_MATCH ("foo", "foo[]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ a]", NORMAL); CHECK_NO_MATCH ("foo", "foo[a ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ a ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[\ta]", NORMAL); CHECK_NO_MATCH ("foo", "foo[a \t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[a\t ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ \ta]", NORMAL); CHECK_NO_MATCH ("foo", "foo[\t a]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ \ta \t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[\t a\t ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ abi]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[\tabi]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi\t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[ \tabi]", NORMAL); CHECK_NO_MATCH ("foo", "foo[\t abi]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi \t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi\t ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi :]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi\t:]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi \t:]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi\t :]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi: ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:\t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi: \t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:\t ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi: a]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:\ta]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi: \ta]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:\t a]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:a ]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:a\t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:a \t]", NORMAL); CHECK_NO_MATCH ("foo", "foo[abi:a\t ]", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a)", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a) c", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a) .", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a) *", NORMAL); CHECK_NO_MATCH ("foo[abi:a]()", "foo(a) &", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b) c", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b) .", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b) *", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b) &", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b)c", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b).", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b)*", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b)", "foo(a,b)&", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a,b) d", "foo(a,b) c", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a)", "foo()", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a)", "foo(b)", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a)", "foo[abi:b](a)", NORMAL); CHECK_NO_MATCH ("foo[abi:a](a)", "foo[abi:a](b)", NORMAL); CHECK_NO_MATCH ("foo[abi:]", "foo[abi:a]", NORMAL); CHECK_NO_MATCH ("foo[abi:", "foo[abi:a]", NORMAL); CHECK_NO_MATCH ("foo[abi:]", "foo[abi:a", NORMAL); CHECK_NO_MATCH ("foo[abi:,]", "foo[abi:a]", NORMAL); CHECK_NO_MATCH ("foo[abi:a,b]", "foo[abi:a]", NORMAL); CHECK_NO_MATCH ("foo[abi::a]", "foo[abi:a]", NORMAL); CHECK_NO_MATCH ("foo[abi:,([a]", "foo[abi:a]", NORMAL); CHECK_MATCH ("foo a, b ], c )", "foo", NORMAL); CHECK_MATCH ("@!%&\\*", "@!%&\\*", NORMAL); CHECK_MATCH ("()", "()", NORMAL); CHECK_MATCH ("*(*)*", "*(*)*", NORMAL); CHECK_MATCH ("[]", "[]", NORMAL); CHECK_MATCH ("<>", "<>", NORMAL); /* strncmp_iw_with_mode::MATCH_PARAMS: the "strcmp_iw hack." */ CHECK_MATCH ("foo2", "foo", NORMAL); CHECK_NO_MATCH ("foo2", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "foo ", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "foo\t", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "foo \t", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "foo\t ", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "foo \t", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", " foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "\tfoo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", " \tfoo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2", "\t foo", MATCH_PARAMS); CHECK_NO_MATCH (" foo2", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("\tfoo2", "foo", MATCH_PARAMS); CHECK_NO_MATCH (" \tfoo2", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("\t foo2", "foo", MATCH_PARAMS); CHECK_NO_MATCH (" foo2 ", " foo ", MATCH_PARAMS); CHECK_NO_MATCH ("\tfoo2\t", "\tfoo\t", MATCH_PARAMS); CHECK_NO_MATCH (" \tfoo2 \t", " \tfoo \t", MATCH_PARAMS); CHECK_NO_MATCH ("\t foo2\t ", "\t foo\t ", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 ", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2\t", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 ", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 \t", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2\t ", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 (args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 (args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2\t(args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 \t(args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2\t (args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 ( args)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2(args )", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2(args\t)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 (args \t)", "foo", MATCH_PARAMS); CHECK_NO_MATCH ("foo2 (args\t )", "foo", MATCH_PARAMS); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo[abi:a][abi:b](bar[abi:c][abi:d])", MATCH_PARAMS); CHECK_MATCH ("foo[abi:a][abi:b](bar[abi:c][abi:d])", "foo", MATCH_PARAMS); /* strncmp_iw_with_mode also supports case insensitivity. */ { CHECK_NO_MATCH ("FoO", "foo", NORMAL); CHECK_NO_MATCH ("FoO", "foo", MATCH_PARAMS); scoped_restore restore_case = make_scoped_restore (&case_sensitivity); case_sensitivity = case_sensitive_off; CHECK_MATCH ("FoO", "foo", NORMAL); CHECK_MATCH ("FoO", "foo", MATCH_PARAMS); CHECK_MATCH ("foo", "FoO", NORMAL); CHECK_MATCH ("foo", "FoO", MATCH_PARAMS); CHECK_MATCH ("FoO[AbI:abC]()", "foo", NORMAL); CHECK_NO_MATCH ("FoO[AbI:abC]()", "foo", MATCH_PARAMS); CHECK_MATCH ("FoO2[AbI:abC]()", "foo", NORMAL); CHECK_NO_MATCH ("FoO2[AbI:abC]()", "foo", MATCH_PARAMS); CHECK_MATCH ("foo[abi:abc]()", "FoO[AbI:abC]()", NORMAL); CHECK_MATCH ("foo[abi:abc]()", "FoO[AbI:AbC]()", MATCH_PARAMS); CHECK_MATCH ("foo[abi:abc](xyz)", "FoO[AbI:abC](XyZ)", NORMAL); CHECK_MATCH ("foo[abi:abc](xyz)", "FoO[AbI:abC](XyZ)", MATCH_PARAMS); CHECK_MATCH ("foo[abi:abc][abi:def](xyz)", "FoO[AbI:abC](XyZ)", NORMAL); CHECK_MATCH ("foo[abi:abc][abi:def](xyz)", "FoO[AbI:abC](XyZ)", MATCH_PARAMS); CHECK_MATCH ("foo>(bar)", "FoO>(bAr)", NORMAL); CHECK_MATCH ("foo>(bar)", "FoO>(bAr)", MATCH_PARAMS); } } #undef MATCH #undef NO_MATCH #endif /* See utils.h. */ int strncmp_iw (const char *string1, const char *string2, size_t string2_len) { return strncmp_iw_with_mode (string1, string2, string2_len, strncmp_iw_mode::NORMAL, language_minimal); } /* See utils.h. */ int strcmp_iw (const char *string1, const char *string2) { return strncmp_iw_with_mode (string1, string2, strlen (string2), strncmp_iw_mode::MATCH_PARAMS, language_minimal); } /* This is like strcmp except that it ignores whitespace and treats '(' as the first non-NULL character in terms of ordering. Like strcmp (and unlike strcmp_iw), it returns negative if STRING1 < STRING2, 0 if STRING2 = STRING2, and positive if STRING1 > STRING2 according to that ordering. If a list is sorted according to this function and if you want to find names in the list that match some fixed NAME according to strcmp_iw(LIST_ELT, NAME), then the place to start looking is right where this function would put NAME. This function must be neutral to the CASE_SENSITIVITY setting as the user may choose it during later lookup. Therefore this function always sorts primarily case-insensitively and secondarily case-sensitively. Here are some examples of why using strcmp to sort is a bad idea: Whitespace example: Say your partial symtab contains: "foo", "goo". Then, if we try to do a search for "foo", strcmp will locate this after "foo" and before "goo". Then lookup_partial_symbol will start looking at strings beginning with "goo", and will never see the correct match of "foo". Parenthesis example: In practice, this is less like to be an issue, but I'll give it a shot. Let's assume that '$' is a legitimate character to occur in symbols. (Which may well even be the case on some systems.) Then say that the partial symbol table contains "foo$" and "foo(int)". strcmp will put them in this order, since '$' < '('. Now, if the user searches for "foo", then strcmp will sort "foo" before "foo$". Then lookup_partial_symbol will notice that strcmp_iw("foo$", "foo") is false, so it won't proceed to the actual match of "foo(int)" with "foo". */ int strcmp_iw_ordered (const char *string1, const char *string2) { const char *saved_string1 = string1, *saved_string2 = string2; enum case_sensitivity case_pass = case_sensitive_off; for (;;) { /* C1 and C2 are valid only if *string1 != '\0' && *string2 != '\0'. Provide stub characters if we are already at the end of one of the strings. */ char c1 = 'X', c2 = 'X'; while (*string1 != '\0' && *string2 != '\0') { while (ISSPACE (*string1)) string1++; while (ISSPACE (*string2)) string2++; switch (case_pass) { case case_sensitive_off: c1 = TOLOWER ((unsigned char) *string1); c2 = TOLOWER ((unsigned char) *string2); break; case case_sensitive_on: c1 = *string1; c2 = *string2; break; } if (c1 != c2) break; if (*string1 != '\0') { string1++; string2++; } } switch (*string1) { /* Characters are non-equal unless they're both '\0'; we want to make sure we get the comparison right according to our comparison in the cases where one of them is '\0' or '('. */ case '\0': if (*string2 == '\0') break; else return -1; case '(': if (*string2 == '\0') return 1; else return -1; default: if (*string2 == '\0' || *string2 == '(') return 1; else if (c1 > c2) return 1; else if (c1 < c2) return -1; /* PASSTHRU */ } if (case_pass == case_sensitive_on) return 0; /* Otherwise the strings were equal in case insensitive way, make a more fine grained comparison in a case sensitive way. */ case_pass = case_sensitive_on; string1 = saved_string1; string2 = saved_string2; } } /* See utils.h. */ bool streq (const char *lhs, const char *rhs) { return !strcmp (lhs, rhs); } /* ** subset_compare() ** Answer whether string_to_compare is a full or partial match to ** template_string. The partial match must be in sequence starting ** at index 0. */ int subset_compare (const char *string_to_compare, const char *template_string) { int match; if (template_string != NULL && string_to_compare != NULL && strlen (string_to_compare) <= strlen (template_string)) match = (startswith (template_string, string_to_compare)); else match = 0; return match; } static void show_debug_timestamp (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Timestamping debugging messages is %s.\n"), value); } /* See utils.h. */ CORE_ADDR address_significant (gdbarch *gdbarch, CORE_ADDR addr) { /* Clear insignificant bits of a target address and sign extend resulting address, avoiding shifts larger or equal than the width of a CORE_ADDR. The local variable ADDR_BIT stops the compiler reporting a shift overflow when it won't occur. Skip updating of target address if current target has not set gdbarch significant_addr_bit. */ int addr_bit = gdbarch_significant_addr_bit (gdbarch); if (addr_bit && (addr_bit < (sizeof (CORE_ADDR) * HOST_CHAR_BIT))) { CORE_ADDR sign = (CORE_ADDR) 1 << (addr_bit - 1); addr &= ((CORE_ADDR) 1 << addr_bit) - 1; addr = (addr ^ sign) - sign; } return addr; } const char * paddress (struct gdbarch *gdbarch, CORE_ADDR addr) { /* Truncate address to the size of a target address, avoiding shifts larger or equal than the width of a CORE_ADDR. The local variable ADDR_BIT stops the compiler reporting a shift overflow when it won't occur. */ /* NOTE: This assumes that the significant address information is kept in the least significant bits of ADDR - the upper bits were either zero or sign extended. Should gdbarch_address_to_pointer or some ADDRESS_TO_PRINTABLE() be used to do the conversion? */ int addr_bit = gdbarch_addr_bit (gdbarch); if (addr_bit < (sizeof (CORE_ADDR) * HOST_CHAR_BIT)) addr &= ((CORE_ADDR) 1 << addr_bit) - 1; return hex_string (addr); } /* This function is described in "defs.h". */ const char * print_core_address (struct gdbarch *gdbarch, CORE_ADDR address) { int addr_bit = gdbarch_addr_bit (gdbarch); if (addr_bit < (sizeof (CORE_ADDR) * HOST_CHAR_BIT)) address &= ((CORE_ADDR) 1 << addr_bit) - 1; /* FIXME: cagney/2002-05-03: Need local_address_string() function that returns the language localized string formatted to a width based on gdbarch_addr_bit. */ if (addr_bit <= 32) return hex_string_custom (address, 8); else return hex_string_custom (address, 16); } /* Convert a string back into a CORE_ADDR. */ CORE_ADDR string_to_core_addr (const char *my_string) { CORE_ADDR addr = 0; if (my_string[0] == '0' && TOLOWER (my_string[1]) == 'x') { /* Assume that it is in hex. */ int i; for (i = 2; my_string[i] != '\0'; i++) { if (ISDIGIT (my_string[i])) addr = (my_string[i] - '0') + (addr * 16); else if (ISXDIGIT (my_string[i])) addr = (TOLOWER (my_string[i]) - 'a' + 0xa) + (addr * 16); else error (_("invalid hex \"%s\""), my_string); } } else { /* Assume that it is in decimal. */ int i; for (i = 0; my_string[i] != '\0'; i++) { if (ISDIGIT (my_string[i])) addr = (my_string[i] - '0') + (addr * 10); else error (_("invalid decimal \"%s\""), my_string); } } return addr; } #if GDB_SELF_TEST static void gdb_realpath_check_trailer (const char *input, const char *trailer) { gdb::unique_xmalloc_ptr result = gdb_realpath (input); size_t len = strlen (result.get ()); size_t trail_len = strlen (trailer); SELF_CHECK (len >= trail_len && strcmp (result.get () + len - trail_len, trailer) == 0); } static void gdb_realpath_tests () { /* A file which contains a directory prefix. */ gdb_realpath_check_trailer ("./xfullpath.exp", "/xfullpath.exp"); /* A file which contains a directory prefix. */ gdb_realpath_check_trailer ("../../defs.h", "/defs.h"); /* A one-character filename. */ gdb_realpath_check_trailer ("./a", "/a"); /* A file in the root directory. */ gdb_realpath_check_trailer ("/root_file_which_should_exist", "/root_file_which_should_exist"); /* A file which does not have a directory prefix. */ gdb_realpath_check_trailer ("xfullpath.exp", "xfullpath.exp"); /* A one-char filename without any directory prefix. */ gdb_realpath_check_trailer ("a", "a"); /* An empty filename. */ gdb_realpath_check_trailer ("", ""); } /* Test the gdb_argv::as_array_view method. */ static void gdb_argv_as_array_view_test () { { gdb_argv argv; gdb::array_view view = argv.as_array_view (); SELF_CHECK (view.data () == nullptr); SELF_CHECK (view.size () == 0); } { gdb_argv argv ("une bonne 50"); gdb::array_view view = argv.as_array_view (); SELF_CHECK (view.size () == 3); SELF_CHECK (strcmp (view[0], "une") == 0); SELF_CHECK (strcmp (view[1], "bonne") == 0); SELF_CHECK (strcmp (view[2], "50") == 0); } } #endif /* GDB_SELF_TEST */ /* Simple, portable version of dirname that does not modify its argument. */ std::string ldirname (const char *filename) { std::string dirname; const char *base = lbasename (filename); while (base > filename && IS_DIR_SEPARATOR (base[-1])) --base; if (base == filename) return dirname; dirname = std::string (filename, base - filename); /* On DOS based file systems, convert "d:foo" to "d:.", so that we create "d:./bar" later instead of the (different) "d:/bar". */ if (base - filename == 2 && IS_ABSOLUTE_PATH (base) && !IS_DIR_SEPARATOR (filename[0])) dirname[base++ - filename] = '.'; return dirname; } /* Return ARGS parsed as a valid pid, or throw an error. */ int parse_pid_to_attach (const char *args) { unsigned long pid; char *dummy; if (!args) error_no_arg (_("process-id to attach")); dummy = (char *) args; pid = strtoul (args, &dummy, 0); /* Some targets don't set errno on errors, grrr! */ if ((pid == 0 && dummy == args) || dummy != &args[strlen (args)]) error (_("Illegal process-id: %s."), args); return pid; } /* Substitute all occurrences of string FROM by string TO in *STRINGP. *STRINGP must come from xrealloc-compatible allocator and it may be updated. FROM needs to be delimited by IS_DIR_SEPARATOR or DIRNAME_SEPARATOR (or be located at the start or end of *STRINGP. */ void substitute_path_component (char **stringp, const char *from, const char *to) { char *string = *stringp, *s; const size_t from_len = strlen (from); const size_t to_len = strlen (to); for (s = string;;) { s = strstr (s, from); if (s == NULL) break; if ((s == string || IS_DIR_SEPARATOR (s[-1]) || s[-1] == DIRNAME_SEPARATOR) && (s[from_len] == '\0' || IS_DIR_SEPARATOR (s[from_len]) || s[from_len] == DIRNAME_SEPARATOR)) { char *string_new; string_new = (char *) xrealloc (string, (strlen (string) + to_len + 1)); /* Relocate the current S pointer. */ s = s - string + string_new; string = string_new; /* Replace from by to. */ memmove (&s[to_len], &s[from_len], strlen (&s[from_len]) + 1); memcpy (s, to, to_len); s += to_len; } else s++; } *stringp = string; } #ifdef HAVE_WAITPID #ifdef SIGALRM /* SIGALRM handler for waitpid_with_timeout. */ static void sigalrm_handler (int signo) { /* Nothing to do. */ } #endif /* Wrapper to wait for child PID to die with TIMEOUT. TIMEOUT is the time to stop waiting in seconds. If TIMEOUT is zero, pass WNOHANG to waitpid. Returns PID if it was successfully waited for, otherwise -1. Timeouts are currently implemented with alarm and SIGALRM. If the host does not support them, this waits "forever". It would be odd though for a host to have waitpid and not SIGALRM. */ pid_t wait_to_die_with_timeout (pid_t pid, int *status, int timeout) { pid_t waitpid_result; gdb_assert (pid > 0); gdb_assert (timeout >= 0); if (timeout > 0) { #ifdef SIGALRM #if defined (HAVE_SIGACTION) && defined (SA_RESTART) struct sigaction sa, old_sa; sa.sa_handler = sigalrm_handler; sigemptyset (&sa.sa_mask); sa.sa_flags = 0; sigaction (SIGALRM, &sa, &old_sa); #else sighandler_t ofunc; ofunc = signal (SIGALRM, sigalrm_handler); #endif alarm (timeout); #endif waitpid_result = waitpid (pid, status, 0); #ifdef SIGALRM alarm (0); #if defined (HAVE_SIGACTION) && defined (SA_RESTART) sigaction (SIGALRM, &old_sa, NULL); #else signal (SIGALRM, ofunc); #endif #endif } else waitpid_result = waitpid (pid, status, WNOHANG); if (waitpid_result == pid) return pid; else return -1; } #endif /* HAVE_WAITPID */ /* Provide fnmatch compatible function for FNM_FILE_NAME matching of host files. Both FNM_FILE_NAME and FNM_NOESCAPE must be set in FLAGS. It handles correctly HAVE_DOS_BASED_FILE_SYSTEM and HAVE_CASE_INSENSITIVE_FILE_SYSTEM. */ int gdb_filename_fnmatch (const char *pattern, const char *string, int flags) { gdb_assert ((flags & FNM_FILE_NAME) != 0); /* It is unclear how '\' escaping vs. directory separator should coexist. */ gdb_assert ((flags & FNM_NOESCAPE) != 0); #ifdef HAVE_DOS_BASED_FILE_SYSTEM { char *pattern_slash, *string_slash; /* Replace '\' by '/' in both strings. */ pattern_slash = (char *) alloca (strlen (pattern) + 1); strcpy (pattern_slash, pattern); pattern = pattern_slash; for (; *pattern_slash != 0; pattern_slash++) if (IS_DIR_SEPARATOR (*pattern_slash)) *pattern_slash = '/'; string_slash = (char *) alloca (strlen (string) + 1); strcpy (string_slash, string); string = string_slash; for (; *string_slash != 0; string_slash++) if (IS_DIR_SEPARATOR (*string_slash)) *string_slash = '/'; } #endif /* HAVE_DOS_BASED_FILE_SYSTEM */ #ifdef HAVE_CASE_INSENSITIVE_FILE_SYSTEM flags |= FNM_CASEFOLD; #endif /* HAVE_CASE_INSENSITIVE_FILE_SYSTEM */ return fnmatch (pattern, string, flags); } /* Return the number of path elements in PATH. / = 1 /foo = 2 /foo/ = 2 foo/bar = 2 foo/ = 1 */ int count_path_elements (const char *path) { int count = 0; const char *p = path; if (HAS_DRIVE_SPEC (p)) { p = STRIP_DRIVE_SPEC (p); ++count; } while (*p != '\0') { if (IS_DIR_SEPARATOR (*p)) ++count; ++p; } /* Backup one if last character is /, unless it's the only one. */ if (p > path + 1 && IS_DIR_SEPARATOR (p[-1])) --count; /* Add one for the file name, if present. */ if (p > path && !IS_DIR_SEPARATOR (p[-1])) ++count; return count; } /* Remove N leading path elements from PATH. N must be non-negative. If PATH has more than N path elements then return NULL. If PATH has exactly N path elements then return "". See count_path_elements for a description of how we do the counting. */ const char * strip_leading_path_elements (const char *path, int n) { int i = 0; const char *p = path; gdb_assert (n >= 0); if (n == 0) return p; if (HAS_DRIVE_SPEC (p)) { p = STRIP_DRIVE_SPEC (p); ++i; } while (i < n) { while (*p != '\0' && !IS_DIR_SEPARATOR (*p)) ++p; if (*p == '\0') { if (i + 1 == n) return ""; return NULL; } ++p; ++i; } return p; } /* See utils.h. */ void copy_bitwise (gdb_byte *dest, ULONGEST dest_offset, const gdb_byte *source, ULONGEST source_offset, ULONGEST nbits, int bits_big_endian) { unsigned int buf, avail; if (nbits == 0) return; if (bits_big_endian) { /* Start from the end, then work backwards. */ dest_offset += nbits - 1; dest += dest_offset / 8; dest_offset = 7 - dest_offset % 8; source_offset += nbits - 1; source += source_offset / 8; source_offset = 7 - source_offset % 8; } else { dest += dest_offset / 8; dest_offset %= 8; source += source_offset / 8; source_offset %= 8; } /* Fill BUF with DEST_OFFSET bits from the destination and 8 - SOURCE_OFFSET bits from the source. */ buf = *(bits_big_endian ? source-- : source++) >> source_offset; buf <<= dest_offset; buf |= *dest & ((1 << dest_offset) - 1); /* NBITS: bits yet to be written; AVAIL: BUF's fill level. */ nbits += dest_offset; avail = dest_offset + 8 - source_offset; /* Flush 8 bits from BUF, if appropriate. */ if (nbits >= 8 && avail >= 8) { *(bits_big_endian ? dest-- : dest++) = buf; buf >>= 8; avail -= 8; nbits -= 8; } /* Copy the middle part. */ if (nbits >= 8) { size_t len = nbits / 8; /* Use a faster method for byte-aligned copies. */ if (avail == 0) { if (bits_big_endian) { dest -= len; source -= len; memcpy (dest + 1, source + 1, len); } else { memcpy (dest, source, len); dest += len; source += len; } } else { while (len--) { buf |= *(bits_big_endian ? source-- : source++) << avail; *(bits_big_endian ? dest-- : dest++) = buf; buf >>= 8; } } nbits %= 8; } /* Write the last byte. */ if (nbits) { if (avail < nbits) buf |= *source << avail; buf &= (1 << nbits) - 1; *dest = (*dest & (~0U << nbits)) | buf; } } void _initialize_utils (); void _initialize_utils () { add_setshow_uinteger_cmd ("width", class_support, &chars_per_line, _("\ Set number of characters where GDB should wrap lines of its output."), _("\ Show number of characters where GDB should wrap lines of its output."), _("\ This affects where GDB wraps its output to fit the screen width.\n\ Setting this to \"unlimited\" or zero prevents GDB from wrapping its output."), set_width_command, show_chars_per_line, &setlist, &showlist); add_setshow_uinteger_cmd ("height", class_support, &lines_per_page, _("\ Set number of lines in a page for GDB output pagination."), _("\ Show number of lines in a page for GDB output pagination."), _("\ This affects the number of lines after which GDB will pause\n\ its output and ask you whether to continue.\n\ Setting this to \"unlimited\" or zero causes GDB never pause during output."), set_height_command, show_lines_per_page, &setlist, &showlist); add_setshow_boolean_cmd ("pagination", class_support, &pagination_enabled, _("\ Set state of GDB output pagination."), _("\ Show state of GDB output pagination."), _("\ When pagination is ON, GDB pauses at end of each screenful of\n\ its output and asks you whether to continue.\n\ Turning pagination off is an alternative to \"set height unlimited\"."), NULL, show_pagination_enabled, &setlist, &showlist); add_setshow_boolean_cmd ("sevenbit-strings", class_support, &sevenbit_strings, _("\ Set printing of 8-bit characters in strings as \\nnn."), _("\ Show printing of 8-bit characters in strings as \\nnn."), NULL, NULL, show_sevenbit_strings, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("timestamp", class_maintenance, &debug_timestamp, _("\ Set timestamping of debugging messages."), _("\ Show timestamping of debugging messages."), _("\ When set, debugging messages will be marked with seconds and microseconds."), NULL, show_debug_timestamp, &setdebuglist, &showdebuglist); add_internal_problem_command (&internal_error_problem); add_internal_problem_command (&internal_warning_problem); add_internal_problem_command (&demangler_warning_problem); #if GDB_SELF_TEST selftests::register_test ("gdb_realpath", gdb_realpath_tests); selftests::register_test ("gdb_argv_array_view", gdb_argv_as_array_view_test); selftests::register_test ("strncmp_iw_with_mode", strncmp_iw_with_mode_tests); #endif }