gdb/testsuite/gdb.threads/access-mem-running-thread-exit.exp - binutils-gdb - Git at Google

 # Copyright (C) 2021-2022 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 <http://www.gnu.org/licenses/>.

 # Test that we can access memory while all the threads of the inferior
 # are running, and even if:
 #
 # - the leader thread exits
 # - the selected thread exits
 #
 # This test constantly spawns short lived threads to make sure that on
 # systems with debug APIs that require passing down a specific thread
 # to work with (e.g., GNU/Linux ptrace and /proc filesystem), GDB
 # copes with accessing memory just while the thread it is accessing
 # memory through exits.
 #
 # The test spawns two processes and alternates memory accesses between
 # them to force flushing per-process caches.  When the testcase was
 # originally written, the Linux backend would access inferior memory
 # via /proc/PID/mem, and kept one such file open, as a cache.
 # Alternating inferiors would force re-opening such file for a
 # different process, which would fail if GDB tried to open the file
 # for a thread that exited.  The test thus ensured those reopen/fail
 # code paths were exercised.  Nowadays, GDB keeps one /proc/PID/mem
 # file open per inferior.

 standard_testfile

 if {[build_executable "failed to prepare" $testfile $srcfile {debug pthreads}] == -1} {
     return -1
 }

 # The test proper.  NON_STOP indicates whether we're testing in
 # non-stop, or all-stop mode.

 proc test { non_stop } {
     global binfile
     global gdb_prompt
     global GDBFLAGS

     save_vars { GDBFLAGS } {
       append GDBFLAGS " -ex \"set non-stop $non_stop\""
       clean_restart ${binfile}
     }

     if ![runto_main] {
 	return -1
     }

     # If debugging with target remote, check whether the all-stop variant
     # of the RSP is being used.  If so, we can't run the background tests.
     if {!$non_stop
 	&& [target_info exists gdb_protocol]
 	&& ([target_info gdb_protocol] == "remote"
 	    || [target_info gdb_protocol] == "extended-remote")} {

 	gdb_test_multiple "maint show target-non-stop" "" {
 	    -wrap -re "(is|currently) on.*" {
 	    }
 	    -wrap -re "(is|currently) off.*" {
 		unsupported "can't issue commands while target is running"
 		return 0
 	    }
 	}
     }

     delete_breakpoints

     # Start the second inferior.
     with_test_prefix "second inferior" {
 	# With stub targets that do reload on run, if we let the new
 	# inferior share inferior 1's connection, runto_main would
 	# fail because GDB is already connected to something, like
 	# e.g. with --target_board=native-gdbserver:
 	#
 	#  (gdb) kill
 	#  ...
 	#  (gdb) target remote localhost:2348
 	#  Already connected to a remote target.  Disconnect? (y or n)
 	#
 	# Instead, start the inferior with no connection, and let
 	# gdb_load/runto_main spawn a new remote connection/gdbserver.
 	#
 	# OTOH, with extended-remote, we must let the new inferior
 	# reuse the current connection, so that runto_main below can
 	# issue the "run" command, and have the inferior run on the
 	# remote target.  If we forced no connection, then "run" would
 	# either fail if "set auto-connect-native-target" is on, like
 	# the native-extended-gdbserver board enforces, or it would
 	# run the inferior on the native target, which isn't what is
 	# being tested.
 	#
 	# Since it's reload_on_run targets that need special care, we
 	# default to reusing the connection on most targets.
 	if [target_info exists gdb,do_reload_on_run] {
 	    gdb_test "add-inferior -no-connection" "New inferior 2.*"
 	} else {
 	    gdb_test "add-inferior" "New inferior 2.*"
 	}
 	gdb_test "inferior 2" "Switching to inferior 2 .*"

 	gdb_load $binfile

 	if ![runto_main] {
 	    return -1
 	}
     }

     delete_breakpoints

     # These put too much noise in the logs.
     gdb_test_no_output "set print thread-events off"

     # Continue all threads of both processes.
     gdb_test_no_output "set schedule-multiple on"
     if {$non_stop == "off"} {
 	set cmd "continue &"
     } else {
 	set cmd "continue -a &"
     }
     gdb_test_multiple $cmd "continuing" {
 	-re "Continuing\.\r\n$gdb_prompt " {
 	    pass $gdb_test_name
 	}
     }

     # Like gdb_test, but:
     # - don't issue a pass on success.
     # - on failure, clear the ok variable in the calling context, and
     #   break it.
     proc my_gdb_test {cmd pattern message} {
 	upvar inf inf
 	upvar iter iter
 	if {[gdb_test -nopass \
 		 $cmd $pattern "access mem ($message, inf=$inf, iter=$iter)"] \
 		!= 0} {
 	    uplevel 1 {set ok 0}
 	    return -code break
 	}
     }

     # Hammer away for 5 seconds, alternating between inferiors.
     set ::done 0
     after 5000 { set ::done 1 }

     set inf 1
     set ok 1
     set iter 0
     while {!$::done && $ok} {
 	incr iter
 	verbose -log "xxxxx: iteration $iter"
 	gdb_test -nopass "info threads"

 	if {$inf == 1} {
 	    set inf 2
 	} else {
 	    set inf 1
 	}

 	my_gdb_test "inferior $inf" ".*" "inferior $inf"

 	my_gdb_test "print global_var = 555" " = 555" \
 	    "write to global_var"
 	my_gdb_test "print global_var" " = 555" \
 	    "print global_var after writing"
 	my_gdb_test "print global_var = 333" " = 333" \
 	    "write to global_var again"
 	my_gdb_test "print global_var" " = 333" \
 	    "print global_var after writing again"
     }

    if {$ok} {
        pass "access mem"
    }
 }

 foreach non_stop { "off" "on" } {
     set stop_mode [expr ($non_stop=="off")?"all-stop":"non-stop"]
     with_test_prefix "$stop_mode" {
 	test $non_stop
     }
 }
	# Copyright (C) 2021-2022 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 <http://www.gnu.org/licenses/>.

	# Test that we can access memory while all the threads of the inferior
	# are running, and even if:
	#
	# - the leader thread exits
	# - the selected thread exits
	#
	# This test constantly spawns short lived threads to make sure that on
	# systems with debug APIs that require passing down a specific thread
	# to work with (e.g., GNU/Linux ptrace and /proc filesystem), GDB
	# copes with accessing memory just while the thread it is accessing
	# memory through exits.
	#
	# The test spawns two processes and alternates memory accesses between
	# them to force flushing per-process caches. When the testcase was
	# originally written, the Linux backend would access inferior memory
	# via /proc/PID/mem, and kept one such file open, as a cache.
	# Alternating inferiors would force re-opening such file for a
	# different process, which would fail if GDB tried to open the file
	# for a thread that exited. The test thus ensured those reopen/fail
	# code paths were exercised. Nowadays, GDB keeps one /proc/PID/mem
	# file open per inferior.

	standard_testfile

	if {[build_executable "failed to prepare" $testfile $srcfile {debug pthreads}] == -1} {
	return -1
	}

	# The test proper. NON_STOP indicates whether we're testing in
	# non-stop, or all-stop mode.

	proc test { non_stop } {
	global binfile
	global gdb_prompt
	global GDBFLAGS

	save_vars { GDBFLAGS } {
	append GDBFLAGS " -ex \"set non-stop $non_stop\""
	clean_restart ${binfile}
	}

	if ![runto_main] {
	return -1
	}

	# If debugging with target remote, check whether the all-stop variant
	# of the RSP is being used. If so, we can't run the background tests.
	if {!$non_stop
	&& [target_info exists gdb_protocol]
	&& ([target_info gdb_protocol] == "remote"
	\|\| [target_info gdb_protocol] == "extended-remote")} {

	gdb_test_multiple "maint show target-non-stop" "" {
	-wrap -re "(is\|currently) on.*" {
	}
	-wrap -re "(is\|currently) off.*" {
	unsupported "can't issue commands while target is running"
	return 0
	}
	}
	}

	delete_breakpoints

	# Start the second inferior.
	with_test_prefix "second inferior" {
	# With stub targets that do reload on run, if we let the new
	# inferior share inferior 1's connection, runto_main would
	# fail because GDB is already connected to something, like
	# e.g. with --target_board=native-gdbserver:
	#
	# (gdb) kill
	# ...
	# (gdb) target remote localhost:2348
	# Already connected to a remote target. Disconnect? (y or n)
	#
	# Instead, start the inferior with no connection, and let
	# gdb_load/runto_main spawn a new remote connection/gdbserver.
	#
	# OTOH, with extended-remote, we must let the new inferior
	# reuse the current connection, so that runto_main below can
	# issue the "run" command, and have the inferior run on the
	# remote target. If we forced no connection, then "run" would
	# either fail if "set auto-connect-native-target" is on, like
	# the native-extended-gdbserver board enforces, or it would
	# run the inferior on the native target, which isn't what is
	# being tested.
	#
	# Since it's reload_on_run targets that need special care, we
	# default to reusing the connection on most targets.
	if [target_info exists gdb,do_reload_on_run] {
	gdb_test "add-inferior -no-connection" "New inferior 2.*"
	} else {
	gdb_test "add-inferior" "New inferior 2.*"
	}
	gdb_test "inferior 2" "Switching to inferior 2 .*"

	gdb_load $binfile

	if ![runto_main] {
	return -1
	}
	}

	delete_breakpoints

	# These put too much noise in the logs.
	gdb_test_no_output "set print thread-events off"

	# Continue all threads of both processes.
	gdb_test_no_output "set schedule-multiple on"
	if {$non_stop == "off"} {
	set cmd "continue &"
	} else {
	set cmd "continue -a &"
	}
	gdb_test_multiple $cmd "continuing" {
	-re "Continuing\.\r\n$gdb_prompt " {
	pass $gdb_test_name
	}
	}

	# Like gdb_test, but:
	# - don't issue a pass on success.
	# - on failure, clear the ok variable in the calling context, and
	# break it.
	proc my_gdb_test {cmd pattern message} {
	upvar inf inf
	upvar iter iter
	if {[gdb_test -nopass \
	$cmd $pattern "access mem ($message, inf=$inf, iter=$iter)"] \
	!= 0} {
	uplevel 1 {set ok 0}
	return -code break
	}
	}

	# Hammer away for 5 seconds, alternating between inferiors.
	set ::done 0
	after 5000 { set ::done 1 }

	set inf 1
	set ok 1
	set iter 0
	while {!$::done && $ok} {
	incr iter
	verbose -log "xxxxx: iteration $iter"
	gdb_test -nopass "info threads"

	if {$inf == 1} {
	set inf 2
	} else {
	set inf 1
	}

	my_gdb_test "inferior $inf" ".*" "inferior $inf"

	my_gdb_test "print global_var = 555" " = 555" \
	"write to global_var"
	my_gdb_test "print global_var" " = 555" \
	"print global_var after writing"
	my_gdb_test "print global_var = 333" " = 333" \
	"write to global_var again"
	my_gdb_test "print global_var" " = 333" \
	"print global_var after writing again"
	}

	if {$ok} {
	pass "access mem"
	}
	}

	foreach non_stop { "off" "on" } {
	set stop_mode [expr ($non_stop=="off")?"all-stop":"non-stop"]
	with_test_prefix "$stop_mode" {
	test $non_stop
	}
	}