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[94.112.227.180]) by smtp.gmail.com with ESMTPSA id ot17-20020a170906ccd100b00a235b01886dsm3340123ejb.10.2023.12.20.01.40.07 (version=TLS1_3 cipher=TLS_AES_128_GCM_SHA256 bits=128/128); Wed, 20 Dec 2023 01:40:07 -0800 (PST) Message-ID: <7ff2cd49-6374-6f7c-53eb-db07bf724a1e@redhat.com> Date: Wed, 20 Dec 2023 10:40:06 +0100 MIME-Version: 1.0 User-Agent: Mozilla/5.0 (X11; Linux x86_64; rv:102.0) Gecko/20100101 Thunderbird/102.15.1 Subject: Re: [PATCH v4] gdb/testsuite: add test for backtracing for threaded inferiors from a corefile To: gdb-patches@sourceware.org Cc: Andrew Burgess , Luis Machado , Guinevere Larsen References: <20231204173316.4175260-2-blarsen@redhat.com> From: Guinevere Larsen In-Reply-To: <20231204173316.4175260-2-blarsen@redhat.com> X-Mimecast-Spam-Score: 0 X-Mimecast-Originator: redhat.com Content-Language: en-US Content-Type: text/plain; charset=UTF-8; format=flowed Content-Transfer-Encoding: 7bit X-Spam-Status: No, score=-10.7 required=5.0 tests=BAYES_00,DKIMWL_WL_HIGH,DKIM_SIGNED,DKIM_VALID,DKIM_VALID_AU,DKIM_VALID_EF,GIT_PATCH_0,KAM_SHORT,NICE_REPLY_A,RCVD_IN_BARRACUDACENTRAL,RCVD_IN_DNSWL_NONE,RCVD_IN_MSPIKE_H4,RCVD_IN_MSPIKE_WL,SPF_HELO_NONE,SPF_NONE,TXREP,T_SCC_BODY_TEXT_LINE autolearn=ham autolearn_force=no version=3.4.6 X-Spam-Checker-Version: SpamAssassin 3.4.6 (2021-04-09) on server2.sourceware.org List-Id: Ping! -- Cheers, Guinevere Larsen She/Her/Hers On 04/12/2023 18:33, Guinevere Larsen wrote: > This patch is based on an out-of-tree patch that fedora has been > carrying for a while. It tests if GDB is able to properly unwind a > threaded program in the following situations: > * regular threads > * in a signal handler > * in a signal handler executing on an alternate stack > > And the final frame can either be in a syscall or in an infinite loop. > > The test works by running the inferior until a crash to generate a > corefile, or until right before the crash. Then applies a backtrace to > all threads to see if any frame can't be identified, and the order of > the threads in GDB. Finally, it goes thread by thread and tries to > collect a large part of the backtrace, to confirm that everything is > being unwound correctly. > > Co-Authored-By: Andrew Burgess > Reviewed-By: Luis Machado > > --- > > Changes for v4: > * Luis mentioned that my strategy for starting the inferior didn't work > with native-extended testing. Changed to use runto_main instead > * Improved comments in the exp file based on Andrew's comments > * Minor cleanups with regards to TCL usage > --- > gdb/testsuite/gdb.threads/threadcrash.c | 443 ++++++++++++++++++++++ > gdb/testsuite/gdb.threads/threadcrash.exp | 233 ++++++++++++ > 2 files changed, 676 insertions(+) > create mode 100644 gdb/testsuite/gdb.threads/threadcrash.c > create mode 100644 gdb/testsuite/gdb.threads/threadcrash.exp > > diff --git a/gdb/testsuite/gdb.threads/threadcrash.c b/gdb/testsuite/gdb.threads/threadcrash.c > new file mode 100644 > index 00000000000..e476ae7b07d > --- /dev/null > +++ b/gdb/testsuite/gdb.threads/threadcrash.c > @@ -0,0 +1,443 @@ > +/* This testcase is part of GDB, the GNU debugger. > + > + Copyright 2023 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 . */ > + > +#include > +#include > +#include > +#include > +#include > + > +/* The delay that the main thread gives once all the worker threads have > + reached the barrier before the main thread enters the function on which > + GDB will have placed a breakpoint. */ > + > +#define MAIN_THREAD_DELAY 2 > + > +/* The maximum time we allow this test program to run for before an alarm > + signal is sent and everything will exit. */ > +#define WATCHDOG_ALARM_TIME 600 > + > +/* Aliases for the signals used within this script. Each signal > + corresponds to an action (from the FINAL_ACTION enum) that the signal > + handler will perform. */ > + > +#define SPIN_SIGNAL SIGUSR1 > +#define SYSCALL_SIGNAL SIGUSR2 > + > +/* Describe the final action that a thread should perform. */ > + > +enum final_action > + { > + /* Thread should spin in an infinite loop. */ > + SPIN = 0, > + > + /* Thread should block in a syscall. */ > + SYSCALL, > + > + /* This is just a marker to allow for looping over the enum. */ > + LAST_ACTION > + }; > + > +/* Where should the thread perform this action? */ > + > +enum exec_location > + { > + /* Just a normal thread, on a normal stack. */ > + NORMAL = 0, > + > + /* In a signal handler, but use the normal stack. */ > + SIGNAL_HANDLER, > + > + /* In a signal handler using an alternative stack. */ > + SIGNAL_ALT_STACK, > + > + /* This is just a marker to allow for looping over the enum. */ > + LAST_LOCACTION > + }; > + > +/* A descriptor for a single thread job. We create a new thread for each > + job_description. */ > + > +struct job_description > +{ > + /* What action should this thread perform. */ > + enum final_action action; > + > + /* Where should the thread perform the action. */ > + enum exec_location location; > + > + /* The actual thread handle, so we can join with the thread. */ > + pthread_t thread; > +}; > + > +/* A pthread barrier, used to (try) and synchronise the threads. */ > +pthread_barrier_t global_barrier; > + > +/* Return a list of jobs, and place the length of the list in *COUNT. */ > + > +struct job_description * > +get_job_list (int *count) > +{ > + /* The number of jobs. */ > + int num = LAST_ACTION * LAST_LOCACTION; > + > + /* The uninitialised array of jobs. */ > + struct job_description *list > + = malloc (num * sizeof (struct job_description)); > + assert (list != NULL); > + > + /* Fill the array with all possible jobs. */ > + for (int i = 0; i < (int) LAST_ACTION; ++i) > + for (int j = 0; j < (int) LAST_LOCACTION; ++j) > + { > + int idx = (i * LAST_LOCACTION) + j; > + list[idx].action = (enum final_action) i; > + list[idx].location = (enum exec_location) j; > + } > + > + /* Return the array of jobs. */ > + *count = num; > + return list; > +} > + > +/* This function should never be called. If it is then an assertion will > + trigger. */ > + > +void > +assert_not_reached (void) > +{ > + assert (0); > +} > + > +/* The function for a SPIN action. Just spins in a loop. The LOCATION > + argument exists so GDB can identify the expected context for this > + function. */ > + > +void > +do_spin_task (enum exec_location location) > +{ > + (void) location; > + > + /* Let everyone know that we're about to perform our action. */ > + int res = pthread_barrier_wait (&global_barrier); > + assert (res == PTHREAD_BARRIER_SERIAL_THREAD || res == 0); > + > + while (1) > + { > + /* Nothing. */ > + } > +} > + > +/* The function for a SYSCALL action. Just spins in a loop. The LOCATION > + argument exists so GDB can identify the expected context for this > + function. */ > + > +void > +do_syscall_task (enum exec_location location) > +{ > + (void) location; > + > + /* Let everyone know that we're about to perform our action. */ > + int res = pthread_barrier_wait (&global_barrier); > + assert (res == PTHREAD_BARRIER_SERIAL_THREAD || res == 0); > + > + sleep (600); > +} > + > +/* Return the required size for a sigaltstack. We start with a single > + page, but do check against the system defined minimums. We don't run > + much on the alternative stacks, so we don't need a huge one. */ > + > +size_t > +get_stack_size (void) > +{ > + size_t size = getpagesize (); /* Arbitrary starting size. */ > + if (size < SIGSTKSZ) > + size = SIGSTKSZ; > + if (size < MINSIGSTKSZ) > + size = MINSIGSTKSZ; > + return size; > +} > + > +/* A descriptor for an alternative stack. */ > + > +struct stack_descriptor > +{ > + /* The base address of the alternative stack. This is the address that > + must be freed to release the memory used by this stack. */ > + void *base; > + > + /* The size of this alternative stack. Tracked just so we can query this > + from GDB. */ > + size_t size; > +}; > + > +/* Install an alternative signal stack. Return a descriptor for the newly > + allocated alternative stack. */ > + > +struct stack_descriptor > +setup_alt_stack (void) > +{ > + size_t stack_size = get_stack_size (); > + > + void *stack_area = malloc (stack_size); > + > + stack_t stk; > + stk.ss_sp = stack_area; > + stk.ss_flags = 0; > + stk.ss_size = stack_size; > + > + int res = sigaltstack (&stk, NULL); > + assert (res == 0); > + > + struct stack_descriptor desc; > + desc.base = stack_area; > + desc.size = stack_size; > + > + return desc; > +} > + > +/* Return true (non-zero) if we are currently on the alternative stack, > + otherwise, return false (zero). */ > + > +int > +on_alt_stack_p (void) > +{ > + stack_t stk; > + int res = sigaltstack (NULL, &stk); > + assert (res == 0); > + > + return (stk.ss_flags & SS_ONSTACK) != 0; > +} > + > +/* The signal handler function. All signals call here, so we use SIGNO > + (the signal that was delivered) to decide what action to perform. This > + function might, or might not, have been called on an alternative signal > + stack. */ > + > +void > +signal_handler (int signo) > +{ > + enum exec_location location > + = on_alt_stack_p () ? SIGNAL_ALT_STACK : SIGNAL_HANDLER; > + > + switch (signo) > + { > + case SPIN_SIGNAL: > + do_spin_task (location); > + break; > + > + case SYSCALL_SIGNAL: > + do_syscall_task (location); > + break; > + > + default: > + assert_not_reached (); > + } > +} > + > +/* The thread worker function. ARG is a job_description pointer which > + describes what this thread is expected to do. This function always > + returns a NULL pointer. */ > + > +void * > +thread_function (void *arg) > +{ > + struct job_description *job = (struct job_description *) arg; > + struct stack_descriptor desc = { NULL, 0 }; > + int sa_flags = 0; > + > + switch (job->location) > + { > + case NORMAL: > + /* This thread performs the worker action on the current thread, > + select the correct worker function based on the requested > + action. */ > + switch (job->action) > + { > + case SPIN: > + do_spin_task (NORMAL); > + break; > + > + case SYSCALL: > + do_syscall_task (NORMAL); > + break; > + > + default: > + assert_not_reached (); > + } > + break; > + > + case SIGNAL_ALT_STACK: > + /* This thread is to perform its action in a signal handler on the > + alternative stack. Install the alternative stack now, and then > + fall through to the normal signal handler location code. */ > + desc = setup_alt_stack (); > + assert (desc.base != NULL); > + assert (desc.size > 0); > + sa_flags = SA_ONSTACK; > + > + /* Fall through. */ > + case SIGNAL_HANDLER: > + { > + /* This thread is to perform its action in a signal handler. We > + might have just installed an alternative signal stack. */ > + int signo, res; > + > + /* Select the correct signal number so that the signal handler will > + perform the required action. */ > + switch (job->action) > + { > + case SPIN: > + signo = SPIN_SIGNAL; > + break; > + > + case SYSCALL: > + signo = SYSCALL_SIGNAL; > + break; > + > + default: > + assert_not_reached (); > + } > + > + /* Now setup the signal handler. */ > + struct sigaction sa; > + sa.sa_handler = signal_handler; > + sigfillset (&sa.sa_mask); > + sa.sa_flags = sa_flags; > + res = sigaction (signo, &sa, NULL); > + assert (res == 0); > + > + /* Send the signal to this thread. */ > + res = pthread_kill (job->thread, signo); > + assert (res == 0); > + } > + break; > + > + default: > + assert_not_reached (); > + }; > + > + /* Free the alt-stack if we allocated one, if not DESC.BASE will be > + NULL so this call is fine. */ > + free (desc.base); > + > + /* Thread complete. */ > + return NULL; > +} > + > +void > +start_job (struct job_description *job) > +{ > + int res; > + > + res = pthread_create (&job->thread, NULL, thread_function, job); > + assert (res == 0); > +} > + > +/* Join with the thread for JOB. This will block until the thread for JOB > + has finished. */ > + > +void > +finalise_job (struct job_description *job) > +{ > + int res; > + void *retval; > + > + res = pthread_join (job->thread, &retval); > + assert (res == 0); > + assert (retval == NULL); > +} > + > +/* Function that GDB can place a breakpoint on. */ > + > +void > +breakpt (void) > +{ > + /* Nothing. */ > +} > + > +/* Function that triggers a crash, if the user has setup their environment > + correctly this will dump a core file, which GDB can then examine. */ > + > +void > +crash_function (void) > +{ > + volatile int *p = 0; > + volatile int n = *p; > + (void) n; > +} > + > +/* Entry point. */ > + > +int > +main () > +{ > + int job_count, res; > + struct job_description *jobs = get_job_list (&job_count); > + > + /* This test is going to park some threads inside infinite loops. Just > + in case this program is left running, install an alarm that will cause > + everything to exit. */ > + alarm (WATCHDOG_ALARM_TIME); > + > + /* We want each worker thread (of which there are JOB_COUNT) plus the > + main thread (hence + 1) to wait at the barrier. */ > + res = pthread_barrier_init (&global_barrier, NULL, job_count + 1); > + assert (res == 0); > + > + /* Start all the jobs. */ > + for (int i = 0; i < job_count; ++i) > + start_job (&jobs[i]); > + > + /* Notify all the worker threads that we're waiting for them. */ > + res = pthread_barrier_wait (&global_barrier); > + assert (res == PTHREAD_BARRIER_SERIAL_THREAD || res == 0); > + > + /* All we know at this point is that all the worker threads have reached > + the barrier, which is just before they perform their action. But we > + really want them to start their action. > + > + There's really no way we can be 100% certain that the worker threads > + have started their action, all we can do is wait for a short while and > + hope that the machine we're running on is not too slow. */ > + sleep (MAIN_THREAD_DELAY); > + > + /* A function that GDB can place a breakpoint on. By the time we get > + here we are as sure as we can be that all of the worker threads have > + started and are in their worker action (spinning, or syscall). */ > + breakpt (); > + > + /* If GDB is not attached then this function will cause a crash, which > + can be used to dump a core file, which GDB can then analyse. */ > + crash_function (); > + > + /* Due to the crash we never expect to get here. Plus the worker actions > + never terminate. But for completeness, here's where we join with all > + the worker threads. */ > + for (int i = 0; i < job_count; ++i) > + finalise_job (&jobs[i]); > + > + /* Cleanup the barrier. */ > + res = pthread_barrier_destroy (&global_barrier); > + assert (res == 0); > + > + /* And clean up the jobs list. */ > + free (jobs); > + > + return 0; > +} > diff --git a/gdb/testsuite/gdb.threads/threadcrash.exp b/gdb/testsuite/gdb.threads/threadcrash.exp > new file mode 100644 > index 00000000000..996e020d1e8 > --- /dev/null > +++ b/gdb/testsuite/gdb.threads/threadcrash.exp > @@ -0,0 +1,233 @@ > +# This testcase is part of GDB, the GNU debugger. > + > +# Copyright 2023 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 . > + > +# This test case looks at GDB's ability to get correct backtraces for a > +# crashed inferior, recreating it from a live inferior, a corefile and > +# a gcore. > + > + > +# Check that the inferior has 7 threads, and return the number of threads (7). > +# We return the thread count so that, even if there is some error in the test, > +# the final log doesn't get flooded with failures. > + > +proc test_thread_count {} { > + set thread_count 0 > + > + gdb_test_multiple "info threads" "getting thread count" -lbl { > + -re "Thread" { > + incr thread_count > + exp_continue > + } > + -re "$::gdb_prompt " { > + gdb_assert {$thread_count == 7} > + } > + } > + > + return $thread_count > +} > + > +# Use 'thread apply all backtrace' to check if all expected threads > +# are present, and stopped in the expected locations. Set the global > +# TEST_LIST to be the a list of regexps expected to match all the > +# threads. We generate it now so that the list is in the order that > +# GDB sees the threads. > + > +proc thread_apply_all {} { > + global test_list > + > + set test_list { } > + > + set unwind_fail false > + > + gdb_test_multiple "thread apply all backtrace" \ > + "Get thread information" -lbl { > + -re "#\[0-9\]+\\\?\\\?\[^\n\]*" { > + set unwind_fail true > + exp_continue > + } > + -re "\[^\n\]*syscall_task .location=SIGNAL_ALT_STACK\[^\n\]*" { > + lappend test_list [multi_line ".*sleep.*" \ > + ".*do_syscall_task .location=SIGNAL_ALT_STACK.*" \ > + ".*signal_handler.*" \ > + ".*signal handler called.*" \ > + ".*pthread_kill.*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*syscall_task .location=SIGNAL_HANDLER\[^\n\]*" { > + lappend test_list [multi_line ".*sleep.*" \ > + ".*do_syscall_task .location=SIGNAL_HANDLER.*" \ > + ".*signal_handler.*" \ > + ".*signal handler called.*" \ > + ".*pthread_kill.*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*syscall_task .location=NORMAL\[^\n\]*" { > + lappend test_list [multi_line ".*sleep.*" \ > + ".*do_syscall_task .location=NORMAL.*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*spin_task .location=SIGNAL_ALT_STACK\[^\n\]*" { > + lappend test_list [multi_line ".*do_spin_task .location=SIGNAL_ALT_STACK.*" \ > + ".*signal_handler.*" \ > + ".*signal handler called.*" \ > + ".*pthread_kill.*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*spin_task .location=SIGNAL_HANDLER\[^\n\]*" { > + lappend test_list [multi_line ".*do_spin_task .location=SIGNAL_HANDLER.*" \ > + ".*signal_handler.*" \ > + ".*signal handler called.*" \ > + ".*pthread_kill.*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*spin_task .location=NORMAL\[^\n\]*" { > + lappend test_list [multi_line ".*do_spin_task .location=NORMAL..*" \ > + ".*thread_function.*"] > + exp_continue > + } > + -re "\[^\n\]*main\[^\n\]*" { > + lappend test_list ".*main.*" > + exp_continue > + } > + -re "$::gdb_prompt " { > + pass $gdb_test_name > + } > + } > + > + gdb_assert {$unwind_fail == false} > +} > + > +# Perform all the tests we're interested in. They are: > +# * test if we have 7 threads > +# * Creating the list of backtraces for all threads seen > +# * testing if GDB recreated the full backtrace we expect for all threads > + > +proc do_full_test {} { > + global test_list > + set thread_count [test_thread_count] > + > + thread_apply_all > + > + gdb_assert {$thread_count == [llength $test_list]} > + > + for {set i 0} {$i < $thread_count } {incr i} { > + set thread_num [expr [llength $test_list] - $i] > + > + gdb_test "thread apply $thread_num backtrace" [lindex $test_list $i] > + } > +} > + > +# Do all preparation steps for running the corefile tests, then > +# call do_full_test to actually run the tests. > + > +proc_with_prefix test_live_inferior {} { > + gdb_test "handle SIGUSR1 nostop print pass" \ > + ".*SIGUSR1.*No.*Yes.*Yes.*User defined signal 1" \ > + "setup SIGUSR1" > + gdb_test "handle SIGUSR2 nostop print pass" \ > + ".*SIGUSR2.*No.*Yes.*Yes.*User defined signal 2" \ > + "setup SIGUSR2" > + > + if {![runto_main]} { > + return > + } > + > + gdb_breakpoint "breakpt" > + gdb_continue_to_breakpoint "running to breakpoint" ".*" > + > + do_full_test > +} > + > +# Do all preparation steps for running the corefile tests, then > +# call do_full_test to actually run the tests. > + > +proc_with_prefix test_corefile {} { > + set corefile [core_find $::binfile] > + if { $corefile == "" } { > + untested "couldn't generate corefile" > + return > + } > + set corefile [gdb_remote_download host $corefile] > + > + gdb_test "core-file $corefile" \ > + "" \ > + "loading_corefile" \ > + "A program is being debugged already\\\. Kill it\\\? \\\(y or n\\\) " \ > + "y" > + > + do_full_test > +} > + > +# Do all preparation steps for running the gcore tests, then > +# call do_full_test to actually run the tests. > + > +proc_with_prefix test_gcore {} { > + > + clean_restart "$::binfile" > + > + gdb_test "handle SIGUSR1 nostop print pass" \ > + ".*SIGUSR1.*No.*Yes.*Yes.*User defined signal 1" \ > + "setup SIGUSR1" > + gdb_test "handle SIGUSR2 nostop print pass" \ > + ".*SIGUSR2.*No.*Yes.*Yes.*User defined signal 2" \ > + "setup SIGUSR2" > + > + if {![runto_main]} { > + return -1 > + } > + gdb_test "continue" ".*Segmentation fault.*" "continue to crash" > + > + set gcore_name "${::binfile}.gcore" > + set gcore_supported [gdb_gcore_cmd "$gcore_name" "saving gcore"] > + > + if {!$gcore_supported} { > + unsupported "couldn't generate gcore file" > + return > + } > + > + set corefile [gdb_remote_download host $gcore_name] > + > + gdb_test "core-file $corefile" \ > + "" \ > + "loading_corefile" \ > + "A program is being debugged already\\\. Kill it\\\? \\\(y or n\\\) " \ > + "y" > + > + do_full_test > +} > + > +standard_testfile > + > +if [prepare_for_testing "failed to prepare" $testfile $srcfile \ > + {debug pthreads}] { > + return -1 > +} > + > +clean_restart ${binfile} > + > +gdb_test_no_output "set backtrace limit unlimited" > + > +test_live_inferior > + > +test_corefile > + > +test_gcore