| # Copyright 1997, 1998, 1999 Free Software Foundation, Inc. |
| |
| # 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 2 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, write to the Free Software |
| # Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. |
| |
| # Please email any bugs, comments, and/or additions to this file to: |
| # bug-gdb@prep.ai.mit.edu |
| |
| if [target_info exists gdb,nosignals] { |
| verbose "Skipping signals.exp because of nosignals." |
| continue |
| } |
| |
| if $tracelevel then { |
| strace $tracelevel |
| } |
| |
| set prms_id 0 |
| set bug_id 0 |
| |
| set testfile signals |
| set srcfile ${testfile}.c |
| set binfile ${objdir}/${subdir}/${testfile} |
| if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable {debug}] != "" } { |
| gdb_suppress_entire_file "Testcase compile failed, so all tests in this file will automatically fail." |
| } |
| |
| # Create and source the file that provides information about the compiler |
| # used to compile the test case. |
| if [get_compiler_info ${binfile}] { |
| return -1; |
| } |
| |
| if {$hp_cc_compiler} { |
| set void 0 |
| } else { |
| set void void |
| } |
| |
| proc signal_tests_1 {} { |
| global gdb_prompt |
| if [runto_main] then { |
| gdb_test "next" "signal \\(SIGUSR1.*" \ |
| "next over signal (SIGALRM, handler)" |
| gdb_test "next" "alarm \\(.*" \ |
| "next over signal (SIGUSR1, handler)" |
| gdb_test "next" "\\+\\+count; /\\* first \\*/" \ |
| "next over alarm (1)" |
| # An alarm has been signaled, give the signal time to get delivered. |
| sleep 2 |
| |
| # i386 BSD currently fails the next test with a SIGTRAP. |
| setup_xfail "i*86-*-bsd*" |
| # But Dynix has a DECR_PC_AFTER_BREAK of zero, so the failure |
| # is shadowed by hitting the through_sigtramp_breakpoint. |
| clear_xfail "i*86-sequent-bsd*" |
| # Univel SVR4 i386 continues instead of stepping. |
| setup_xfail "i*86-univel-sysv4*" |
| # lynx fails with "next" acting like "continue" |
| setup_xfail "*-*-*lynx*" |
| # linux (aout versions) also fails with "next" acting like "continue" |
| # this is probably more dependant on the kernel version than on the |
| # object file format or utils. (sigh) |
| setup_xfail "i*86-pc-linuxaout-gnu" "i*86-pc-linuxoldld-gnu" |
| send_gdb "next\n" |
| gdb_expect { |
| -re "alarm .*$gdb_prompt $" { pass "next to 2nd alarm (1)" } |
| -re "Program received signal SIGTRAP.*first.*$gdb_prompt $" { |
| |
| # This can happen on machines that have a trace flag |
| # in their PS register. |
| # The trace flag in the PS register will be set due to |
| # the `next' command. |
| # Before calling the signal handler, the PS register |
| # is pushed along with the context on the user stack. |
| # When the signal handler has finished, it reenters the |
| # the kernel via a sigreturn syscall, which restores the |
| # PS register along with the context. |
| # If the kernel erroneously does not clear the trace flag |
| # in the pushed context, gdb will receive a SIGTRAP from |
| # the set trace flag in the restored context after the |
| # signal handler has finished. |
| |
| # I do not yet understand why the SIGTRAP does not occur |
| # after stepping the instruction at the restored PC on |
| # i386 BSDI 1.0 systems. |
| |
| # Note that the vax under Ultrix also exhibits |
| # this behaviour (it is uncovered by the `continue from |
| # a break in a signal handler' test below). |
| # With this test the failure is shadowed by hitting the |
| # through_sigtramp_breakpoint upon return from the signal |
| # handler. |
| |
| # SVR4 and Linux based i*86 systems exhibit this behaviour |
| # as well (it is uncovered by the `continue from a break |
| # in a signal handler' test below). |
| # As these systems use procfs, where we tell the kernel not |
| # to tell gdb about `pass' signals, and the trace flag is |
| # cleared by the kernel before entering the sigtramp |
| # routine, GDB will not notice the execution of the signal |
| # handler. |
| # Upon return from the signal handler, GDB will receive |
| # a SIGTRAP from the set trace flag in the restored context. |
| # The SIGTRAP marks the end of a (albeit long winded) |
| # single step for GDB, causing this test to pass. |
| |
| fail "next to 2nd alarm (1) (probably kernel bug)" |
| gdb_test "next" "alarm.*" "next to 2nd alarm (1)" |
| } |
| -re "Program exited with code.*$gdb_prompt $" { |
| |
| # This is apparently a bug in the UnixWare kernel (but |
| # has not been investigated beyond the |
| # resume/target_wait level, and has not been reported |
| # to Univel). If it steps when a signal is pending, |
| # it does a continue instead. I don't know whether |
| # there is a workaround. |
| |
| # Perhaps this problem exists on other SVR4 systems; |
| # but (a) we have no reason to think so, and (b) if we |
| # put a wrong xfail here, we never get an XPASS to let |
| # us know that it was incorrect (and then if such a |
| # configuration regresses we have no way of knowing). |
| # Solaris is not a relevant data point either way |
| # because it lacks single stepping. |
| |
| # fnf: I don't agree with the above philosophy. We |
| # can never be sure that any particular XFAIL is |
| # specified 100% correctly in that no systems with |
| # the bug are missed and all systems without the bug |
| # are excluded. If we include an XFAIL that isn't |
| # appropriate for a particular system, then when that |
| # system gets tested it will XPASS, and someone should |
| # investigate and fix the setup_xfail as appropriate, |
| # or more preferably, the actual bug. Each such case |
| # adds more data to narrowing down the scope of the |
| # problem and ultimately fixing it. |
| |
| setup_xfail "i*86-*-sysv4*" |
| fail "'next' behaved as 'continue (known SVR4 bug)'" |
| return 0 |
| } |
| -re ".*$gdb_prompt $" { fail "next to 2nd alarm (1)" } |
| timeout { fail "next to 2nd alarm (1); (timeout)" } |
| eof { fail "next to 2nd alarm (1); (eof)" } |
| } |
| |
| gdb_test "break handler" "Breakpoint \[0-9\]+ .*" |
| gdb_test "next" "\\+\\+count; /\\* second \\*/" \ |
| "next to 2nd ++count in signals_tests_1" |
| # An alarm has been signaled, give the signal time to get delivered. |
| sleep 2 |
| |
| set bash_bug 0 |
| send_gdb "next\n" |
| gdb_expect { |
| -re "Breakpoint.*handler.*$gdb_prompt $" { |
| pass "next to handler in signals_tests_1" |
| } |
| -re "Program received signal SIGEMT.*$gdb_prompt $" { |
| # Bash versions before 1.13.5 cause this behaviour |
| # by blocking SIGTRAP. |
| fail "next to handler in signals_tests_1 (known problem with bash versions before 1.13.5)" |
| set bash_bug 1 |
| gdb_test "signal 0" "Breakpoint.*handler.*" |
| } |
| -re ".*$gdb_prompt $" { fail "next to handler in signals_tests_1" } |
| timeout { fail "next to handler in signals_tests_1 (timeout)" } |
| eof { fail "next to handler in signals_tests_1 (eof)" } |
| } |
| |
| # This doesn't test that main is frame #2, just that main is frame |
| # #2, #3, or higher. At some point this should be fixed (but |
| # it quite possibly would introduce new FAILs on some systems). |
| setup_xfail "i*86-*-bsdi2.0" |
| gdb_test "backtrace 10" "#0.*handler.*#1.*#2.*main.*" \ |
| "backtrace in signals_tests_1" |
| |
| gdb_test "break func1" "Breakpoint \[0-9\]+ .*" |
| gdb_test "break func2" "Breakpoint \[0-9\]+ .*" |
| |
| # Vax Ultrix and i386 BSD currently fail the next test with |
| # a SIGTRAP, but with different symptoms. |
| setup_xfail "vax-*-ultrix*" |
| setup_xfail "i*86-*-bsd*" |
| setup_xfail "i*86-pc-linux-gnu*" |
| setup_xfail "i*86-*-solaris2*" |
| send_gdb "continue\n" |
| gdb_expect { |
| -re "Breakpoint.*func1.*$gdb_prompt $" { pass "continue to func1" } |
| -re "Program received signal SIGTRAP.*second.*$gdb_prompt $" { |
| |
| # See explanation for `next to 2nd alarm (1)' fail above. |
| # We did step into the signal handler, hit a breakpoint |
| # in the handler and continued from the breakpoint. |
| # The set trace flag in the restored context is causing |
| # the SIGTRAP, without stepping an instruction. |
| |
| fail "continue to func1 (probably kernel bug)" |
| gdb_test "continue" "Breakpoint.*func1.*" \ |
| "extra continue to func1" |
| } |
| -re "Program received signal SIGTRAP.*func1 ..;.*$gdb_prompt $" { |
| |
| # On the vax under Ultrix the set trace flag in the restored |
| # context is causing the SIGTRAP, but after stepping one |
| # instruction, as expected. |
| |
| fail "continue to func1 (probably kernel bug)" |
| gdb_test "continue" "Breakpoint.*func1.*" \ |
| "extra continue to func1" |
| } |
| -re ".*$gdb_prompt $" { fail "continue to func1" } |
| default { fail "continue to func1" } |
| } |
| |
| setup_xfail "*-*-irix*" |
| send_gdb "signal SIGUSR1\n" |
| gdb_expect { |
| -re "Breakpoint.*handler.*$gdb_prompt $" { pass "signal SIGUSR1" } |
| -re "Program received signal SIGUSR1.*$gdb_prompt $" { |
| # This is what irix4 and irix5 do. |
| # It would appear to be a kernel bug. |
| fail "signal SIGUSR1" |
| gdb_test "continue" "Breakpoint.*handler.*" "pass it SIGUSR1" |
| } |
| -re ".*$gdb_prompt $" { fail "signal SIGUSR1" } |
| default { fail "signal SIGUSR1" } |
| } |
| |
| # Will tend to wrongly require an extra continue. |
| |
| # The problem here is that the breakpoint at func1 will be |
| # inserted, and when the system finishes with the signal |
| # handler it will try to execute there. For GDB to try to |
| # remember that it was going to step over a breakpoint when a |
| # signal happened, distinguish this case from the case where |
| # func1 is called from the signal handler, etc., seems |
| # exceedingly difficult. So don't expect this to get fixed |
| # anytime soon. |
| |
| setup_xfail "*-*-*" |
| send_gdb "continue\n" |
| gdb_expect { |
| -re "Breakpoint.*func2.*$gdb_prompt $" { pass "continue to func2" } |
| -re "Breakpoint.*func1.*$gdb_prompt $" { |
| fail "continue to func2" |
| gdb_test "continue" "Breakpoint.*func2.*" \ |
| "extra continue to func2" |
| } |
| -re ".*$gdb_prompt $" { fail "continue to func2" } |
| default { fail "continue to func2" } |
| } |
| |
| sleep 2 |
| |
| # GDB yanks out the breakpoints to step over the breakpoint it |
| # stopped at, which means the breakpoint at handler is yanked. |
| # But if SOFTWARE_SINGLE_STEP_P, we won't get another chance to |
| # reinsert them (at least not with procfs, where we tell the kernel |
| # not to tell gdb about `pass' signals). So the fix would appear to |
| # be to just yank that one breakpoint when we step over it. |
| |
| setup_xfail "sparc*-*-*" |
| setup_xfail "rs6000-*-*" |
| setup_xfail "powerpc-*-*" |
| |
| # A faulty bash will not step the inferior into sigtramp on sun3. |
| if {$bash_bug} then { |
| setup_xfail "m68*-*-sunos4*" |
| } |
| |
| setup_xfail "i*86-pc-linux-gnu*" |
| setup_xfail "i*86-*-solaris2*" |
| gdb_test "continue" "Breakpoint.*handler.*" "continue to handler" |
| |
| # If the SOFTWARE_SINGLE_STEP_P failure happened, we have already |
| # exited. |
| # If we succeeded a continue will return from the handler to func2. |
| # GDB now has `forgotten' that it intended to step over the |
| # breakpoint at func2 and will stop at func2. |
| setup_xfail "*-*-*" |
| # The sun3 with a faulty bash will also be `forgetful' but it |
| # already got the spurious stop at func2 and this continue will work. |
| if {$bash_bug} then { |
| clear_xfail "m68*-*-sunos4*" |
| } |
| gdb_test "continue" "Program exited with code 010\\." \ |
| "continue to exit in signals_tests_1 " |
| } |
| } |
| |
| # On a few losing systems, ptrace (PT_CONTINUE) or ptrace (PT_STEP) |
| # causes pending signals to be cleared, which causes these tests to |
| # get nowhere fast. This is totally losing behavior (perhaps there |
| # are cases in which is it useful but the user needs more control, |
| # which they mostly have in GDB), but some people apparently think it |
| # is a feature. It is documented in the ptrace manpage on Motorola |
| # Delta Series sysV68 R3V7.1 and on HPUX 9.0. Even the non-HPUX PA |
| # OSes (BSD and OSF/1) seem to have figured they had to copy this |
| # braindamage. |
| |
| if {[ istarget "m68*-motorola-*" ] || [ istarget "hppa*-*-bsd*" ] || |
| [ istarget "hppa*-*-osf*" ]} then { |
| setup_xfail "*-*-*" |
| fail "ptrace loses on signals on this target" |
| return 0 |
| } |
| |
| # lynx2.2.2 doesn't lose signals, instead it screws up the stack pointer |
| # in some of these tests leading to massive problems. I've |
| # reported this to lynx, hopefully it'll be fixed in lynx2.3. |
| # Severe braindamage. |
| if [ istarget "*-*-*lynx*" ] then { |
| setup_xfail "*-*-*" |
| fail "kernel scroggs stack pointer in signal tests on this target" |
| return 0 |
| } |
| |
| gdb_exit |
| gdb_start |
| |
| # This will need to be updated as the exact list of signals changes, |
| # but I want to test that TARGET_SIGNAL_0, TARGET_SIGNAL_DEFAULT, and |
| # TARGET_SIGNAL_UNKNOWN are skipped. |
| proc test_handle_all_print {} { |
| global timeout |
| # Increase timeout and expect input buffer for large output from gdb. |
| # Allow blank or TAB as whitespace characters. |
| set oldtimeout $timeout |
| set timeout [expr "$timeout + 360"] |
| verbose "Timeout is now $timeout seconds" 2 |
| if { ![istarget "*-*-linux*"] |
| && ( [istarget "*-*-gnu*"] |
| || [istarget "*-*-mach*"] ) } { |
| gdb_test "handle all print" "Signal\[ \]+Stop\[ \]+Print\[ \]+Pass to program\[ \]+Description\r\nSIGHUP\[ \]+Yes\[ \]+Yes\[ \]+Yes\[ \]+Hangup.*SIG63\[ \]+Yes\[ \]+Yes\[ \]+Yes\[ \]+Real-time event 63.*EXC_BREAKPOINT\[ \]+Yes\[ \]+Yes\[ \]+Yes\[ \]+Breakpoint" |
| } else { |
| gdb_test "handle all print" "Signal\[ \]+Stop\[ \]+Print\[ \]+Pass to program\[ \]+Description\r\nSIGHUP\[ \]+Yes\[ \]+Yes\[ \]+Yes\[ \]+Hangup.*SIG63\[ \]+Yes\[ \]+Yes\[ \]+Yes\[ \]+Real-time event 63.*" |
| } |
| set timeout $oldtimeout |
| verbose "Timeout restored to $timeout seconds" 2 |
| } |
| test_handle_all_print |
| |
| gdb_exit |
| gdb_start |
| gdb_reinitialize_dir $srcdir/$subdir |
| gdb_load $binfile |
| signal_tests_1 |
| |
| # Force a resync, so we're looking at the right prompt. On SCO we |
| # were getting out of sync (I don't understand why). |
| send_gdb "p 1+1\n" |
| gdb_expect { |
| -re "= 2.*$gdb_prompt $" {} |
| -re ".*$gdb_prompt $" { perror "sync trouble in signals.exp" } |
| default { perror "sync trouble in signals.exp" } |
| } |
| |
| if [runto_main] then { |
| # Since count is a static variable outside main, runto_main |
| # is no guarantee that count will be 0 at this point. |
| gdb_test "set variable count = 0" "" |
| gdb_test "break handler if 0" "Breakpoint \[0-9\]+ .*" |
| gdb_test "set \$handler_breakpoint_number = \$bpnum" "" |
| |
| # Get to the point where a signal is waiting to be delivered |
| gdb_test "next" "signal \\(SIGUSR1.*" "next to signal in signals.exp" |
| gdb_test "next" "alarm \\(.*" "next to alarm #1 in signals.exp" |
| gdb_test "next" "\\+\\+count; /\\* first \\*/" \ |
| "next to ++count #1 in signals.exp" |
| # Give the signal time to get delivered |
| sleep 2 |
| |
| # Now call a function. When GDB tries to run the stack dummy, |
| # it will hit the breakpoint at handler. Provided it doesn't |
| # lose its cool, this is not a problem, it just has to note |
| # that the breakpoint condition is false and keep going. |
| |
| gdb_test "p func1 ()" "^p func1 \\(\\)\r\n.\[0-9\]* = $void" \ |
| "p func1 () #1 in signals.exp" |
| |
| # Make sure the count got incremented. |
| |
| # Haven't investigated this xfail |
| setup_xfail "rs6000-*-*" |
| setup_xfail "powerpc-*-*" |
| gdb_test "p count" "= 2" "p count #1 in signals.exp" |
| if { [istarget "rs6000-*-*"] || [istarget "powerpc-*-*"] } { return 0 } |
| |
| gdb_test "condition \$handler_breakpoint_number" "now unconditional\\." |
| gdb_test "next" "alarm \\(.*" "next to alarm #2 in signals.exp" |
| gdb_test "next" "\\+\\+count; /\\* second \\*/" \ |
| "next to ++count #2 in signals.exp" |
| sleep 2 |
| |
| # This time we stop when GDB tries to run the stack dummy. |
| # So it is OK that we do not print the return value from the function. |
| gdb_test "p func1 ()" \ |
| "Breakpoint \[0-9\]*, handler.* |
| The program being debugged stopped while in a function called from GDB.*" \ |
| "p func1 () #2 in signals.exp" |
| # But we should be able to backtrace... |
| # On alpha-*-osf2.0 this test works when run manually but sometime fails when |
| # run under dejagnu, making it very hard to debug the problem. Weird... |
| gdb_test "bt 10" "#0.*handler.*#1.*#2.*main.*" "bt in signals.exp" |
| # ...and continue... |
| gdb_test "continue" "Continuing\\." "continue in signals.exp" |
| # ...and then count should have been incremented |
| gdb_test "p count" "= 5" "p count #2 in signals.exp" |
| |
| |
| # Verify that "info signals" produces reasonable output. |
| # |
| send_gdb "info signals\n" |
| gdb_expect { |
| -re "SIGHUP.*SIGINT.*SIGQUIT.*SIGILL.*SIGTRAP.*SIGABRT.*SIGEMT.*SIGFPE.*SIGKILL.*SIGBUS.*SIGSEGV.*SIGSYS.*SIGPIPE.*SIGALRM.*SIGTERM.*SIGURG.*SIGSTOP.*SIGTSTP.*SIGCONT.*SIGCHLD.*SIGTTIN.*SIGTTOU.*SIGIO.*SIGXCPU.*SIGXFSZ.*SIGVTALRM.*SIGPROF.*SIGWINCH.*SIGLOST.*SIGUSR1.*SIGUSR2.*SIGPWR.*SIGPOLL.*SIGWIND.*SIGPHONE.*SIGWAITING.*SIGLWP.*SIGDANGER.*SIGGRANT.*SIGRETRACT.*SIGMSG.*SIGSOUND.*SIGSAK.*SIGPRIO.*SIG33.*SIG34.*SIG35.*SIG36.*SIG37.*SIG38.*SIG39.*SIG40.*SIG41.*SIG42.*SIG43.*SIG44.*SIG45.*SIG46.*SIG47.*SIG48.*SIG49.*SIG50.*SIG51.*SIG52.*SIG53.*SIG54.*SIG55.*SIG56.*SIG57.*SIG58.*SIG59.*SIG60.*SIG61.*SIG62.*SIG63.*Use the \"handle\" command to change these tables.*$gdb_prompt $"\ |
| {pass "info signals"} |
| -re "$gdb_prompt $"\ |
| {fail "info signals"} |
| timeout {fail "(timeout) info signals"} |
| } |
| |
| # Verify that "info signal" correctly handles an argument, be it a |
| # symbolic signal name, or an integer ID. |
| # |
| send_gdb "info signal SIGTRAP\n" |
| gdb_expect { |
| -re ".*SIGTRAP\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*No\[ \t\]*Trace/breakpoint trap.*$gdb_prompt $"\ |
| {pass "info signal SIGTRAP"} |
| -re "$gdb_prompt $"\ |
| {fail "info signal SIGTRAP"} |
| timeout {fail "(timeout) info signal SIGTRAP"} |
| } |
| |
| send_gdb "info signal 5\n" |
| gdb_expect { |
| -re ".*SIGTRAP\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*No\[ \t\]*Trace/breakpoint trap.*$gdb_prompt $"\ |
| {pass "info signal 5"} |
| -re "$gdb_prompt $"\ |
| {fail "info signal 5"} |
| timeout {fail "(timeout) info signal 5"} |
| } |
| |
| # Verify that "handle" with illegal arguments is gracefully, um, handled. |
| # |
| send_gdb "handle\n" |
| gdb_expect { |
| -re "Argument required .signal to handle.*$gdb_prompt $"\ |
| {pass "handle without arguments"} |
| -re "$gdb_prompt $"\ |
| {fail "handle without arguments"} |
| timeout {fail "(timeout) handle without arguments"} |
| } |
| |
| send_gdb "handle SIGFOO\n" |
| gdb_expect { |
| -re "Unrecognized or ambiguous flag word: \"SIGFOO\".*$gdb_prompt $"\ |
| {pass "handle with bogus SIG"} |
| -re "$gdb_prompt $"\ |
| {fail "handle with bogus SIG"} |
| timeout {fail "(timeout) handle with bogus SIG"} |
| } |
| |
| send_gdb "handle SIGHUP frump\n" |
| gdb_expect { |
| -re "Unrecognized or ambiguous flag word: \"frump\".*$gdb_prompt $"\ |
| {pass "handle SIG with bogus action"} |
| -re "$gdb_prompt $"\ |
| {fail "handle SIG with bogus action"} |
| timeout {fail "(timeout) handle SIG with bogus action"} |
| } |
| |
| # Verify that "handle" can take multiple actions per SIG, and that in |
| # the case of conflicting actions, that the rightmost action "wins". |
| # |
| send_gdb "handle SIGHUP print noprint\n" |
| gdb_expect { |
| -re ".*SIGHUP\[ \t\]*No\[ \t\]*No\[ \t\]*Yes\[ \t\]*Hangup.*$gdb_prompt $"\ |
| {pass "handle SIG with multiple conflicting actions"} |
| -re "$gdb_prompt $"\ |
| {fail "handle SIG with multiple conflicting actions"} |
| timeout {fail "(timeout) handle SIG with multiple conflicting actions"} |
| } |
| |
| # Exercise all the various actions. (We don't care what the outcome |
| # is, this is just to ensure that they all can be parsed.) |
| # |
| send_gdb "handle SIGHUP print noprint stop nostop ignore noignore pass nopass\n" |
| gdb_expect { |
| -re ".*Signal.*$gdb_prompt $"\ |
| {pass "handle SIG parses all legal actions"} |
| -re "$gdb_prompt $"\ |
| {fail "handle SIG parses all legal actions"} |
| timeout {fail "(timeout) handle SIG parses all legal actions"} |
| } |
| |
| # Verify that we can "handle" multiple signals at once, interspersed |
| # with actions. |
| # |
| send_gdb "handle SIG63 print SIGILL\n" |
| gdb_expect { |
| -re ".*SIGILL\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*Illegal instruction.*SIG63\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*Real-time event 63.*$gdb_prompt $"\ |
| {pass "handle multiple SIGs"} |
| -re "$gdb_prompt $"\ |
| {fail "handle multiple SIGs"} |
| timeout {fail "(timeout) handle multiple SIGs"} |
| } |
| |
| # Verify that "handle" can take a numeric argument for the signal ID, |
| # rather than a symbolic name. (This may not be portable; works for |
| # HP-UX.) |
| # |
| # Also note that this testpoint overrides SIGTRAP, which on HP-UX at |
| # least, is used to implement single-steps and breakpoints. Don't |
| # expect to run the inferior after this! |
| # |
| send_gdb "handle 5 nopass\n" |
| gdb_expect { |
| -re ".*SIGTRAP is used by the debugger.*Are you sure you want to change it.*y or n.*"\ |
| {send_gdb "y\n" |
| gdb_expect { |
| -re ".*SIGTRAP\[ \t\]*Yes\[ \t\]*Yes\[ \t\]*No\[ \t\]*Trace/breakpoint trap.*$gdb_prompt $"\ |
| {pass "override SIGTRAP (#5)"} |
| -re "$gdb_prompt $"\ |
| {fail "override SIGTRAP (#5)"} |
| timeout {fail "(timeout) override SIGTRAP (#5)"} |
| } |
| } |
| -re "$gdb_prompt $"\ |
| {fail "override SIGTRAP (#5)"} |
| timeout {fail "(timeout) override SIGTRAP (#5)"} |
| } |
| |
| # GDB doesn't seem to allow numeric signal IDs larger than 15. Verify |
| # that restriction. ??rehrauer: Not sure if this is a feature or a |
| # bug, actually. Why is the range 1-15? |
| # |
| send_gdb "handle 58\n" |
| gdb_expect { |
| -re "Only signals 1-15 are valid as numeric signals.*Use \"info signals\" for a list of symbolic signals.*$gdb_prompt $"\ |
| {pass "invalid signal number rejected"} |
| -re "$gdb_prompt $"\ |
| {fail "invalid signal number rejected"} |
| timeout {fail "(timeout) invalid signal number rejected"} |
| } |
| |
| # Verify that we can accept a signal ID range (number-number). |
| # ??rehrauer: This feature isn't documented on the quick-reference |
| # card. |
| # |
| send_gdb "handle 13-15\n" |
| gdb_expect { |
| -re ".*SIGPIPE.*SIGALRM.*SIGTERM.*$gdb_prompt $"\ |
| {pass "handle multiple SIGs via integer range"} |
| -re "$gdb_prompt $"\ |
| {fail "handle multiple SIGs via integer range"} |
| timeout {fail "(timeout) handle multiple SIGs via integer range"} |
| |
| } |
| |
| # Bizarrely enough, GDB also allows you to reverse the range |
| # stat, stop IDs. E.g., "3-1" and "1-3" mean the same thing. |
| # Probably this isn't documented, but the code anticipates it, |
| # so we'd best test it... |
| # |
| send_gdb "handle 15-13\n" |
| gdb_expect { |
| -re ".*SIGPIPE.*SIGALRM.*SIGTERM.*$gdb_prompt $"\ |
| {pass "handle multiple SIGs via integer range"} |
| -re "$gdb_prompt $"\ |
| {fail "handle multiple SIGs via integer range"} |
| timeout {fail "(timeout) handle multiple SIGs via integer range"} |
| |
| } |
| |
| # SIGINT is used by the debugger as well. Verify that we can change |
| # our minds about changing it. |
| # |
| send_gdb "handle SIGINT nopass\n" |
| gdb_expect { |
| -re ".*SIGINT is used by the debugger.*Are you sure you want to change it.*y or n.*"\ |
| {send_gdb "n\n" |
| # ??rehrauer: When you answer "n", the header for the signal info is |
| # printed, but not the actual handler settings. Probably a bug. |
| # |
| gdb_expect { |
| -re "Not confirmed, unchanged.*Signal.*$gdb_prompt $"\ |
| {pass "override SIGINT"} |
| -re "$gdb_prompt $"\ |
| {fail "override SIGINT"} |
| timeout {fail "(timeout) override SIGINT"} |
| } |
| } |
| -re "$gdb_prompt $"\ |
| {fail "override SIGINT"} |
| timeout {fail "(timeout) override SIGINT"} |
| } |
| |
| # Verify that GDB responds gracefully to the "signal" command with |
| # a missing argument. |
| # |
| send_gdb "signal\n" |
| gdb_expect { |
| -re "Argument required .signal number..*$gdb_prompt $"\ |
| {pass "signal without arguments disallowed"} |
| -re "$gdb_prompt $"\ |
| {fail "signal without arguments disallowed"} |
| timeout {fail "(timeout) signal without arguments disallowed"} |
| } |
| |
| # Verify that we can successfully send a signal other than 0 to |
| # the inferior. (This probably causes the inferior to run away. |
| # Be prepared to rerun to main for further testing.) |
| # |
| send_gdb "signal 5\n" |
| gdb_expect { |
| -re "Continuing with signal SIGTRAP.*$gdb_prompt $"\ |
| {pass "sent signal 5"} |
| -re "$gdb_prompt $"\ |
| {fail "sent signal 5"} |
| timeout {fail "(timeout) sent signal 5"} |
| } |
| |
| } |
| |
| return 0 |