remove dependence of TestGdbRemoteExitCode.py on parent directory source
As Pavel pointed out in a comment on llvm.org/pr30271, the VPATH I was using here to eliminate duplication of a .cpp file had a side effect of attempting to pull in a .o/.obj file from that same parent dir, where other tests can be running in parallel. This is no good. For now, I have removed the VPATH, which should address llvm.org/pr30271. I have also removed the XFAIL. llvm-svn: 280675
This commit is contained in:
parent
f245f56217
commit
7ed76d275f
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@ -1,7 +1,5 @@
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LEVEL = ../../../make
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VPATH = ..
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override CFLAGS_EXTRAS += -D__STDC_LIMIT_MACROS -D__STDC_FORMAT_MACROS
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ENABLE_THREADS := YES
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CXX_SOURCES := main.cpp
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@ -59,7 +59,6 @@ class TestGdbRemoteExitCode(GdbRemoteTestCaseBase):
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self.start_inferior()
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@llgs_test
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@expectedFailureAll(bugnumber="llvm.org/pr30271")
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def test_start_inferior_llgs(self):
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self.init_llgs_test()
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self.build()
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@ -119,7 +118,6 @@ class TestGdbRemoteExitCode(GdbRemoteTestCaseBase):
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self.inferior_exit_42()
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@llgs_test
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@expectedFailureAll(bugnumber="llvm.org/pr30271")
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def test_inferior_exit_42_llgs(self):
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self.init_llgs_test()
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self.build()
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@ -0,0 +1,391 @@
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#include <cstdlib>
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#include <cstring>
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#include <errno.h>
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#include <inttypes.h>
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#include <memory>
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#include <pthread.h>
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#include <setjmp.h>
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#include <signal.h>
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#include <stdint.h>
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#include <stdio.h>
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#include <string.h>
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#include <time.h>
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#include <unistd.h>
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#include <vector>
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#if defined(__APPLE__)
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__OSX_AVAILABLE_STARTING(__MAC_10_6, __IPHONE_3_2)
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int pthread_threadid_np(pthread_t,__uint64_t*);
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#elif defined(__linux__)
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#include <sys/syscall.h>
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#endif
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static const char *const RETVAL_PREFIX = "retval:";
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static const char *const SLEEP_PREFIX = "sleep:";
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static const char *const STDERR_PREFIX = "stderr:";
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static const char *const SET_MESSAGE_PREFIX = "set-message:";
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static const char *const PRINT_MESSAGE_COMMAND = "print-message:";
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static const char *const GET_DATA_ADDRESS_PREFIX = "get-data-address-hex:";
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static const char *const GET_STACK_ADDRESS_COMMAND = "get-stack-address-hex:";
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static const char *const GET_HEAP_ADDRESS_COMMAND = "get-heap-address-hex:";
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static const char *const GET_CODE_ADDRESS_PREFIX = "get-code-address-hex:";
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static const char *const CALL_FUNCTION_PREFIX = "call-function:";
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static const char *const THREAD_PREFIX = "thread:";
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static const char *const THREAD_COMMAND_NEW = "new";
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static const char *const THREAD_COMMAND_PRINT_IDS = "print-ids";
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static const char *const THREAD_COMMAND_SEGFAULT = "segfault";
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static bool g_print_thread_ids = false;
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static pthread_mutex_t g_print_mutex = PTHREAD_MUTEX_INITIALIZER;
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static bool g_threads_do_segfault = false;
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static pthread_mutex_t g_jump_buffer_mutex = PTHREAD_MUTEX_INITIALIZER;
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static jmp_buf g_jump_buffer;
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static bool g_is_segfaulting = false;
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static char g_message[256];
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static volatile char g_c1 = '0';
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static volatile char g_c2 = '1';
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static void
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print_thread_id ()
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{
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// Put in the right magic here for your platform to spit out the thread id (tid) that debugserver/lldb-gdbserver would see as a TID.
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// Otherwise, let the else clause print out the unsupported text so that the unit test knows to skip verifying thread ids.
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#if defined(__APPLE__)
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__uint64_t tid = 0;
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pthread_threadid_np(pthread_self(), &tid);
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printf ("%" PRIx64, tid);
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#elif defined (__linux__)
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// This is a call to gettid() via syscall.
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printf ("%" PRIx64, static_cast<uint64_t> (syscall (__NR_gettid)));
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#else
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printf("{no-tid-support}");
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#endif
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}
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static void
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signal_handler (int signo)
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{
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const char *signal_name = nullptr;
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switch (signo)
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{
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case SIGUSR1: signal_name = "SIGUSR1"; break;
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case SIGSEGV: signal_name = "SIGSEGV"; break;
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default: signal_name = nullptr;
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}
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// Print notice that we received the signal on a given thread.
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pthread_mutex_lock (&g_print_mutex);
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if (signal_name)
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printf ("received %s on thread id: ", signal_name);
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else
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printf ("received signo %d (%s) on thread id: ", signo, strsignal (signo));
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print_thread_id ();
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printf ("\n");
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pthread_mutex_unlock (&g_print_mutex);
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// Reset the signal handler if we're one of the expected signal handlers.
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switch (signo)
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{
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case SIGSEGV:
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if (g_is_segfaulting)
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{
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// Fix up the pointer we're writing to. This needs to happen if nothing intercepts the SIGSEGV
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// (i.e. if somebody runs this from the command line).
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longjmp(g_jump_buffer, 1);
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}
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break;
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case SIGUSR1:
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if (g_is_segfaulting)
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{
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// Fix up the pointer we're writing to. This is used to test gdb remote signal delivery.
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// A SIGSEGV will be raised when the thread is created, switched out for a SIGUSR1, and
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// then this code still needs to fix the seg fault.
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// (i.e. if somebody runs this from the command line).
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longjmp(g_jump_buffer, 1);
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}
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break;
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}
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// Reset the signal handler.
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sig_t sig_result = signal (signo, signal_handler);
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if (sig_result == SIG_ERR)
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{
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fprintf(stderr, "failed to set signal handler: errno=%d\n", errno);
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exit (1);
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}
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}
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static void
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swap_chars ()
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{
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g_c1 = '1';
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g_c2 = '0';
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g_c1 = '0';
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g_c2 = '1';
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}
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static void
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hello ()
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{
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pthread_mutex_lock (&g_print_mutex);
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printf ("hello, world\n");
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pthread_mutex_unlock (&g_print_mutex);
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}
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static void*
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thread_func (void *arg)
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{
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static pthread_mutex_t s_thread_index_mutex = PTHREAD_MUTEX_INITIALIZER;
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static int s_thread_index = 1;
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pthread_mutex_lock (&s_thread_index_mutex);
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const int this_thread_index = s_thread_index++;
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pthread_mutex_unlock (&s_thread_index_mutex);
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if (g_print_thread_ids)
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{
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pthread_mutex_lock (&g_print_mutex);
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printf ("thread %d id: ", this_thread_index);
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print_thread_id ();
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printf ("\n");
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pthread_mutex_unlock (&g_print_mutex);
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}
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if (g_threads_do_segfault)
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{
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// Sleep for a number of seconds based on the thread index.
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// TODO add ability to send commands to test exe so we can
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// handle timing more precisely. This is clunky. All we're
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// trying to do is add predictability as to the timing of
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// signal generation by created threads.
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int sleep_seconds = 2 * (this_thread_index - 1);
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while (sleep_seconds > 0)
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sleep_seconds = sleep(sleep_seconds);
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// Test creating a SEGV.
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pthread_mutex_lock (&g_jump_buffer_mutex);
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g_is_segfaulting = true;
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int *bad_p = nullptr;
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if (setjmp(g_jump_buffer) == 0)
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{
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// Force a seg fault signal on this thread.
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*bad_p = 0;
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}
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else
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{
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// Tell the system we're no longer seg faulting.
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// Used by the SIGUSR1 signal handler that we inject
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// in place of the SIGSEGV so it only tries to
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// recover from the SIGSEGV if this seg fault code
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// was in play.
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g_is_segfaulting = false;
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}
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pthread_mutex_unlock (&g_jump_buffer_mutex);
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pthread_mutex_lock (&g_print_mutex);
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printf ("thread ");
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print_thread_id ();
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printf (": past SIGSEGV\n");
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pthread_mutex_unlock (&g_print_mutex);
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}
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int sleep_seconds_remaining = 60;
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while (sleep_seconds_remaining > 0)
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{
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sleep_seconds_remaining = sleep (sleep_seconds_remaining);
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}
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return nullptr;
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}
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int main (int argc, char **argv)
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{
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lldb_enable_attach();
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std::vector<pthread_t> threads;
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std::unique_ptr<uint8_t[]> heap_array_up;
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int return_value = 0;
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// Set the signal handler.
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sig_t sig_result = signal (SIGALRM, signal_handler);
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if (sig_result == SIG_ERR)
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{
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fprintf(stderr, "failed to set SIGALRM signal handler: errno=%d\n", errno);
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exit (1);
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}
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sig_result = signal (SIGUSR1, signal_handler);
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if (sig_result == SIG_ERR)
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{
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fprintf(stderr, "failed to set SIGUSR1 handler: errno=%d\n", errno);
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exit (1);
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}
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sig_result = signal (SIGSEGV, signal_handler);
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if (sig_result == SIG_ERR)
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{
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fprintf(stderr, "failed to set SIGUSR1 handler: errno=%d\n", errno);
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exit (1);
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}
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// Process command line args.
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for (int i = 1; i < argc; ++i)
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{
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if (std::strstr (argv[i], STDERR_PREFIX))
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{
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// Treat remainder as text to go to stderr.
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fprintf (stderr, "%s\n", (argv[i] + strlen (STDERR_PREFIX)));
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}
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else if (std::strstr (argv[i], RETVAL_PREFIX))
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{
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// Treat as the return value for the program.
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return_value = std::atoi (argv[i] + strlen (RETVAL_PREFIX));
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}
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else if (std::strstr (argv[i], SLEEP_PREFIX))
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{
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// Treat as the amount of time to have this process sleep (in seconds).
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int sleep_seconds_remaining = std::atoi (argv[i] + strlen (SLEEP_PREFIX));
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// Loop around, sleeping until all sleep time is used up. Note that
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// signals will cause sleep to end early with the number of seconds remaining.
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for (int i = 0; sleep_seconds_remaining > 0; ++i)
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{
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sleep_seconds_remaining = sleep (sleep_seconds_remaining);
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// std::cout << "sleep result (call " << i << "): " << sleep_seconds_remaining << std::endl;
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}
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}
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else if (std::strstr (argv[i], SET_MESSAGE_PREFIX))
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{
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// Copy the contents after "set-message:" to the g_message buffer.
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// Used for reading inferior memory and verifying contents match expectations.
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strncpy (g_message, argv[i] + strlen (SET_MESSAGE_PREFIX), sizeof (g_message));
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// Ensure we're null terminated.
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g_message[sizeof (g_message) - 1] = '\0';
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}
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else if (std::strstr (argv[i], PRINT_MESSAGE_COMMAND))
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{
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pthread_mutex_lock (&g_print_mutex);
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printf ("message: %s\n", g_message);
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i], GET_DATA_ADDRESS_PREFIX))
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{
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volatile void *data_p = nullptr;
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if (std::strstr (argv[i] + strlen (GET_DATA_ADDRESS_PREFIX), "g_message"))
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data_p = &g_message[0];
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else if (std::strstr (argv[i] + strlen (GET_DATA_ADDRESS_PREFIX), "g_c1"))
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data_p = &g_c1;
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else if (std::strstr (argv[i] + strlen (GET_DATA_ADDRESS_PREFIX), "g_c2"))
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data_p = &g_c2;
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pthread_mutex_lock (&g_print_mutex);
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printf ("data address: %p\n", data_p);
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i], GET_HEAP_ADDRESS_COMMAND))
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{
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// Create a byte array if not already present.
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if (!heap_array_up)
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heap_array_up.reset (new uint8_t[32]);
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pthread_mutex_lock (&g_print_mutex);
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printf ("heap address: %p\n", heap_array_up.get ());
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i], GET_STACK_ADDRESS_COMMAND))
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{
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pthread_mutex_lock (&g_print_mutex);
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printf ("stack address: %p\n", &return_value);
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i], GET_CODE_ADDRESS_PREFIX))
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{
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void (*func_p)() = nullptr;
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if (std::strstr (argv[i] + strlen (GET_CODE_ADDRESS_PREFIX), "hello"))
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func_p = hello;
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else if (std::strstr (argv[i] + strlen (GET_CODE_ADDRESS_PREFIX), "swap_chars"))
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func_p = swap_chars;
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pthread_mutex_lock (&g_print_mutex);
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printf ("code address: %p\n", func_p);
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i], CALL_FUNCTION_PREFIX))
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{
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// Defaut to providing the address of main.
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if (std::strcmp (argv[i] + strlen (CALL_FUNCTION_PREFIX), "hello") == 0)
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hello();
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else if (std::strcmp (argv[i] + strlen (CALL_FUNCTION_PREFIX), "swap_chars") == 0)
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swap_chars();
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else
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{
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pthread_mutex_lock (&g_print_mutex);
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printf ("unknown function: %s\n", argv[i] + strlen (CALL_FUNCTION_PREFIX));
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pthread_mutex_unlock (&g_print_mutex);
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}
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}
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else if (std::strstr (argv[i], THREAD_PREFIX))
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{
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// Check if we're creating a new thread.
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if (std::strstr (argv[i] + strlen(THREAD_PREFIX), THREAD_COMMAND_NEW))
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{
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// Create a new thread.
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pthread_t new_thread;
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const int err = ::pthread_create (&new_thread, nullptr, thread_func, nullptr);
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if (err)
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{
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fprintf (stderr, "pthread_create() failed with error code %d\n", err);
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exit (err);
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}
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threads.push_back (new_thread);
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}
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else if (std::strstr (argv[i] + strlen(THREAD_PREFIX), THREAD_COMMAND_PRINT_IDS))
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{
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// Turn on thread id announcing.
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g_print_thread_ids = true;
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// And announce us.
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pthread_mutex_lock (&g_print_mutex);
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printf ("thread 0 id: ");
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print_thread_id ();
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printf ("\n");
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pthread_mutex_unlock (&g_print_mutex);
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}
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else if (std::strstr (argv[i] + strlen(THREAD_PREFIX), THREAD_COMMAND_SEGFAULT))
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{
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g_threads_do_segfault = true;
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}
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else
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{
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// At this point we don't do anything else with threads.
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// Later use thread index and send command to thread.
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}
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}
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else
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{
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// Treat the argument as text for stdout.
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printf("%s\n", argv[i]);
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}
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}
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// If we launched any threads, join them
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for (std::vector<pthread_t>::iterator it = threads.begin (); it != threads.end (); ++it)
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{
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void *thread_retval = nullptr;
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const int err = ::pthread_join (*it, &thread_retval);
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if (err != 0)
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fprintf (stderr, "pthread_join() failed with error code %d\n", err);
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}
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return return_value;
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}
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