# Copyright 2004-2021 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 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 . # The program sigstep.c creates a very simple backtrace containing one # signal handler and signal trampoline. A flag is set and then the # handler returns. This is repeated at infinitum. # This test runs the program up to the signal handler, and then # attempts to step/next out of the handler and back into main. if [target_info exists gdb,nosignals] { verbose "Skipping sigstep.exp because of nosignals." continue } standard_testfile if {[build_executable $testfile.exp $testfile $srcfile debug]} { untested "failed to compile" return -1 } set clear_done [gdb_get_line_number {done = 0}] set infinite_loop [gdb_get_line_number {while (!done)}] set other_handler_location [gdb_get_line_number "other handler location"] # Restart GDB, set a display showing $PC, and run to main. proc restart {} { global binfile clean_restart $binfile gdb_test "display/i \$pc" runto_main } # Pass all the alarms straight through (but verbosely) # gdb_test "handle SIGALRM print pass nostop" # gdb_test "handle SIGVTALRM print pass nostop" # gdb_test "handle SIGPROF print pass nostop" # Run to the signal handler, validate the backtrace. proc validate_backtrace {} { with_test_prefix "validate backtrace" { restart gdb_test "break handler" gdb_test "continue" ".* handler .*" "continue to stepi handler" gdb_test_sequence "bt" "backtrace for nexti" { "\[\r\n\]+.0 \[^\r\n\]* handler " "\[\r\n\]+.1 .signal handler called." "\[\r\n\]+.2 \[^\r\n\]* main " } } } validate_backtrace # Goes to handler using ENTER_CMD, runs IN_HANDLER while in the signal # hander, and then steps out of the signal handler using EXIT_CMD. proc advance { enter_cmd in_handler_prefix in_handler exit_cmd } { global gdb_prompt inferior_exited_re global clear_done other_handler_location set prefix "$enter_cmd to handler, $in_handler_prefix in handler, $exit_cmd from handler" with_test_prefix $prefix { restart # Get us into the handler if { $enter_cmd == "continue" } { gdb_test "break handler" } else { gdb_test "handle SIGALRM print pass stop" gdb_test "handle SIGVTALRM print pass stop" gdb_test "continue" "Program received signal.*" "continue to signal" } gdb_test "$enter_cmd" ".*handler .*" "$enter_cmd to handler" delete_breakpoints uplevel 1 $in_handler if { $exit_cmd == "continue" } { gdb_test "break $clear_done" ".*" "break clear done" } set test "leave handler" gdb_test_multiple "$exit_cmd" "${test}" { -re "Could not insert single-step breakpoint.*$gdb_prompt $" { setup_kfail gdb/8841 "sparc*-*-openbsd*" fail "$test (could not insert single-step breakpoint)" } -re "Cannot insert breakpoint.*Cannot access memory.*$gdb_prompt $" { setup_kfail gdb/8841 "nios2*-*-linux*" fail "$test (could not insert single-step breakpoint)" } -re "done = 1;.*${gdb_prompt} $" { send_gdb "$exit_cmd\n" exp_continue -continue_timer } -re "\} .. handler .*${gdb_prompt} $" { send_gdb "$exit_cmd\n" exp_continue -continue_timer } -re "$inferior_exited_re normally.*${gdb_prompt} $" { setup_kfail gdb/8744 powerpc-*-*bsd* fail "$test (program exited)" } -re "(while ..done|done = 0).*${gdb_prompt} $" { # After stepping out of a function /r signal-handler, GDB will # advance the inferior until it is at the first instruction of # a code-line. While typically things return to the middle of # the "while..." (and hence GDB advances the inferior to the # "return..." line) it is also possible for the return to land # on the first instruction of "while...". Accept both cases. pass "$test" } } } } # Map of PREFIX => "things to do within the signal handler", for the # advance tests. set in_handler_map { "nothing" { } "si+advance" { # Advance to the second location in handler. gdb_test "si" "handler.*" "si in handler" set test "advance in handler" gdb_test_multiple "advance $other_handler_location" $test { -re "Program received signal SIGTRAP.*$gdb_prompt $" { # On some versions of Linux (observed on # 3.16.4-200.fc20.x86_64), using PTRACE_SINGLESTEP+sig # to step into a signal handler, and then issuing # another PTRACE_SINGLESTEP within the handler ends up # with $eflags.TF mistakenly set, which results in # subsequent PTRACE_CONTINUEs trapping after each # insn. if {$enter_cmd != "continue"} { setup_xfail "i?86-*-linux*" gdb/17511 setup_xfail "x86_64-*-linux*" gdb/17511 } fail "$test (spurious SIGTRAP)" return } -re "other handler location.*$gdb_prompt $" { pass $test } } } } # Check that we can step/next/continue, etc. our way in and out of a # signal handler. Also test that we can step, and run to a breakpoint # within the handler. foreach enter_cmd { "stepi" "nexti" "step" "next" "continue" } { if { $enter_cmd != "continue" && ![can_single_step_to_signal_handler] } { continue } foreach exit_cmd { "step" "next" "continue" } { foreach {in_handler_prefix in_handler} $in_handler_map { advance $enter_cmd $in_handler_prefix $in_handler $exit_cmd } } } proc advancei { cmd } { global gdb_prompt inferior_exited_re with_test_prefix "$cmd from handleri" { restart # Get us into the handler. gdb_test "break handler" gdb_test "continue" ".* handler .*" "continue to handler" set program_exited 0 set test "leave handler" gdb_test_multiple "$cmd" "${test}" { -re "Cannot insert breakpoint 0.*${gdb_prompt} $" { # Some platforms use a special read-only page for signal # trampolines. We can't set a breakpoint there, and we # don't gracefully fall back to single-stepping. setup_kfail gdb/8841 "i?86-*-linux*" setup_kfail gdb/8841 "*-*-openbsd*" setup_kfail gdb/8841 "nios2-*-linux*" fail "$test (could not set breakpoint)" return } -re "Could not insert single-step breakpoint.*$gdb_prompt $" { setup_kfail gdb/8841 "sparc*-*-openbsd*" fail "$test (could not insert single-step breakpoint)" } -re "Breakpoint \[0-9\]*, handler .*${gdb_prompt} $" { fail "$test (hit breakpoint again)" } -re "done = 1;.*${gdb_prompt} $" { send_gdb "$cmd\n" exp_continue -continue_timer } -re "\} .. handler .*${gdb_prompt} $" { send_gdb "$cmd\n" exp_continue -continue_timer } -re "signal handler called.*${gdb_prompt} $" { pass "$test" } -re "main .*${gdb_prompt} $" { fail "$test (in main)" } -re "$inferior_exited_re normally.*${gdb_prompt} $" { fail "$test (program exited)" set program_exited 1 } -re "Make handler return now.*y or n. $" { send_gdb "y\n" exp_continue -continue_timer } } set test "leave signal trampoline" gdb_test_multiple "$cmd" "${test}" { -re "while .*${gdb_prompt} $" { pass "$test (in main)" } -re "signal handler called.*${gdb_prompt} $" { send_gdb "$cmd\n" exp_continue -continue_timer } -re "return .*${gdb_prompt} $" { fail "$test (stepped)" } -re "Make .*frame return now.*y or n. $" { send_gdb "y\n" exp_continue -continue_timer } -re "$inferior_exited_re normally.*${gdb_prompt} $" { kfail gdb/8744 "$test (program exited)" set program_exited 1 } -re "The program is not being run.*${gdb_prompt} $" { if { $program_exited } { # Previously kfailed with an exit pass "$test (the program is not being run)" } else { fail "$test (the program is not being run)" } } } } } # Check that we can step our way out of a signal handler, using # commands that first step out to the signal trampoline, and then out # to the mainline code. foreach cmd {"stepi" "nexti" "finish" "return"} { advancei $cmd } # Check that we can step/next our way into / over a signal handler. # There are at least the following cases: breakpoint @pc VS breakpoint # in handler VS step / next / continue. # Try stepping when there's a signal pending, and a breakpoint at the # handler. Should step into the signal handler. proc skip_to_handler { cmd } { global infinite_loop with_test_prefix "$cmd to handler" { restart # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" # Advance to the infinite loop. gdb_test "advance $infinite_loop" ".*" "advance to infinite loop" # Make the signal pending. sleep 1 # Insert the handler breakpoint. gdb_test "break handler" ".*" # Step into the handler. gdb_test "$cmd" " handler .*" "performing $cmd" } } foreach cmd {"step" "next" "continue"} { skip_to_handler $cmd } # Try stepping when there's a signal pending, and a breakpoint at the # handler's entry-point. Should step into the signal handler stopping # at the entry-point. # Some systems (e.x., GNU/Linux as of 2004-08-30), when delivering a # signal, resume the process at the first instruction of the signal # handler and not the first instruction of the signal trampoline. The # stack is constructed such that the signal handler still appears to # have been called by the trampoline code. This test checks that it # is possible to stop the inferior, even at that first instruction. proc skip_to_handler_entry { cmd } { global infinite_loop with_test_prefix "$cmd to handler entry" { restart # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" # Advance to the infinite loop. gdb_test "advance $infinite_loop" ".*" "advance to infinite loop" # Make the signal pending. sleep 1 # Insert / remove the handler breakpoint. gdb_test "break *handler" ".*" "break handler" gdb_test "$cmd" " handler .*" "performing $cmd" } } foreach cmd {"stepi" "nexti" "step" "next" "continue"} { skip_to_handler_entry $cmd } # Get the address of where a single-step should land. proc get_next_pc {test} { global gdb_prompt global hex set next "" gdb_test_multiple "x/2i \$pc" $test { -re "$hex .*:\[^\r\n\]+\r\n\[ \]+($hex).*\.\r\n$gdb_prompt $" { set next $expect_out(1,string) pass $test } } return $next } # Test that the command skipped over the handler. proc test_skip_handler {cmd} { if {$cmd == "stepi" || $cmd == "nexti"} { set next_pc [get_next_pc "get next PC"] gdb_test "$cmd" "dummy = 0.*" "performing $cmd" gdb_test "p /x \$pc" " = $next_pc" "advanced" } else { gdb_test "$cmd" "done = 0.*" "performing $cmd" } } # Try stepping when there's a signal pending but no breakpoints. # Should skip the handler advancing to the next line. proc skip_over_handler { cmd } { global infinite_loop global clear_done with_test_prefix "$cmd over handler" { restart # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" gdb_test "break $clear_done" ".*" "break clear done" # Advance to the infinite loop. gdb_test "advance $infinite_loop" ".*" "advance to infinite loop" # Make the signal pending. sleep 1 test_skip_handler $cmd } } foreach cmd {"stepi" "nexti" "step" "next" "continue"} { skip_over_handler $cmd } # Try stepping when there's a signal pending, a pre-existing # breakpoint at the current instruction, and a breakpoint in the # handler. Should advance to the signal handler. DISPLACED indicates # whether to try with or without displaced stepping (to exercise the # different techniques of stepping over the breakpoint at the current # instruction). proc breakpoint_to_handler { displaced cmd } { global infinite_loop with_test_prefix "displaced=$displaced: $cmd on breakpoint, to handler" { restart gdb_test_no_output "set displaced-stepping $displaced" # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" gdb_test "break $infinite_loop" ".*" "break infinite loop" gdb_test "break handler" ".*" # Continue to the infinite loop. gdb_test "continue" "while ..done.*" "continue to infinite loop" # Make the signal pending. sleep 1 gdb_test "$cmd" " handler .*" "performing $cmd" # Make sure we the displaced stepping scratch pad isn't in the # backtrace. gdb_test_sequence "bt" "backtrace" { "\[\r\n\]+.0 \[^\r\n\]* handler " "\[\r\n\]+.1 .signal handler called." "\[\r\n\]+.2 \[^\r\n\]* main " } } } foreach displaced {"off" "on"} { foreach cmd {"step" "next" "continue"} { breakpoint_to_handler $displaced $cmd } } # Try stepping when there's a signal pending, and a breakpoint at the # handler's entry instruction and a breakpoint at the current # instruction. Should step into the signal handler and breakpoint at # that entry instruction. # Some systems (e.x., GNU/Linux as of 2004-08-30), when delivering a # signal, resume the process at the first instruction of the signal # handler and not the first instruction of the signal trampoline. The # stack is constructed such that the signal handler still appears to # have been called by the trampoline code. This test checks that it # is possible to stop the inferior, even at that first instruction. # DISPLACED indicates whether to try with or without displaced # stepping (to exercise the different techniques of stepping over the # breakpoint at the current instruction). proc breakpoint_to_handler_entry { displaced cmd } { global infinite_loop with_test_prefix "displaced=$displaced: $cmd on breakpoint, to handler entry" { restart gdb_test_no_output "set displaced-stepping $displaced" # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" gdb_test "break $infinite_loop" ".*" "break infinite loop" gdb_test "break *handler" ".*" "break handler" # Continue to the infinite loop. gdb_test "continue" "while ..done.*" "continue to infinite loop" # Make the signal pending. sleep 1 gdb_test "$cmd" " handler .*" "performing $cmd" # Make sure we the displaced stepping scratch pad isn't in the # backtrace. gdb_test_sequence "bt" "backtrace" { "\[\r\n\]+.0 \[^\r\n\]* handler " "\[\r\n\]+.1 .signal handler called." "\[\r\n\]+.2 \[^\r\n\]* main " } } } foreach displaced {"off" "on"} { foreach cmd {"step" "next" "continue"} { breakpoint_to_handler_entry $displaced $cmd } } # Try stepping when there's a signal pending, and a pre-existing # breakpoint at the current instruction, and no breakpoint in the # handler. Should advance to the next line/instruction. DISPLACED # indicates whether to try with or without displaced stepping (to # exercise the different techniques of stepping over the breakpoint at # the current instruction). If SW_WATCH is true, set a software # watchpoint, which exercises stepping the breakpoint instruction # while delivering a signal at the same time. If NO_HANDLER, arrange # for the signal's handler be SIG_IGN, thus when the software # watchpoint is also set, testing stepping a breakpoint instruction # and immediately triggering the breakpoint (exercises # adjust_pc_after_break logic). proc breakpoint_over_handler { displaced cmd with_sw_watch no_handler } { global infinite_loop global clear_done set prefix "$cmd on breakpoint, skip handler" if { $with_sw_watch } { append prefix ", with sw-watchpoint" } if { $no_handler } { append prefix ", no handler" } with_test_prefix "displaced=$displaced: $prefix" { restart gdb_test_no_output "set displaced-stepping $displaced" # Use the real-time itimer, as otherwize the process never gets # enough time to expire the timer. gdb_test_no_output "set itimer = itimer_real" if {$no_handler} { gdb_test "print no_handler = 1" " = 1" \ "set no_handler" } gdb_test "break $infinite_loop" ".*" "break infinite loop" gdb_test "break $clear_done" ".*" "break clear done" # Continue to the infinite loop gdb_test "continue" "while ..done.*" "continue to infinite loop" # Make the signal pending sleep 1 if { $with_sw_watch } { # A watchpoint on a convenience variable is always a # software watchpoint. gdb_test "watch \$convenience" "Watchpoint .*: \\\$convenience" } if {$no_handler} { # With no handler, we need to set the global ourselves # manually. gdb_test "print done = 1" " = 1" "set done" } test_skip_handler $cmd } } foreach displaced {"off" "on"} { foreach cmd {"stepi" "nexti" "step" "next" "continue"} { foreach with_sw_watch {0 1} { foreach no_handler {0 1} { breakpoint_over_handler $displaced $cmd $with_sw_watch $no_handler } } } }