freebsd-nq/tests/sys/kern/ptrace_test.c
Andrew Turner 6713be3159 Add NT_ARM_ADDR_MASK
This can be used by debuggers to find which bits in a virtual address
should be masked off to get a canonical address. This is currently used
by the Pointer Authentication Code support to get its mask. It could also
be used if we support Top Byte Ignore for the same purpose.

Reviewed by:	kib
Sponsored by:	The FreeBSD Foundation
Differential Revision: https://reviews.freebsd.org/D34302
2022-02-22 17:10:35 +00:00

4399 lines
120 KiB
C

/*-
* Copyright (c) 2015 John Baldwin <jhb@FreeBSD.org>
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <sys/cpuset.h>
#include <sys/elf.h>
#include <sys/event.h>
#include <sys/file.h>
#include <sys/time.h>
#include <sys/procctl.h>
#include <sys/procdesc.h>
#define _WANT_MIPS_REGNUM
#include <sys/ptrace.h>
#include <sys/procfs.h>
#include <sys/queue.h>
#include <sys/runq.h>
#include <sys/syscall.h>
#include <sys/sysctl.h>
#include <sys/user.h>
#include <sys/wait.h>
#include <errno.h>
#include <machine/cpufunc.h>
#include <pthread.h>
#include <sched.h>
#include <semaphore.h>
#include <signal.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <atf-c.h>
/*
* Architectures with a user-visible breakpoint().
*/
#if defined(__aarch64__) || defined(__amd64__) || defined(__arm__) || \
defined(__i386__) || defined(__mips__) || defined(__riscv) || \
defined(__sparc64__)
#define HAVE_BREAKPOINT
#endif
/*
* Adjust PC to skip over a breakpoint when stopped for a breakpoint trap.
*/
#ifdef HAVE_BREAKPOINT
#if defined(__aarch64__)
#define SKIP_BREAK(reg) ((reg)->elr += 4)
#elif defined(__amd64__) || defined(__i386__)
#define SKIP_BREAK(reg)
#elif defined(__arm__)
#define SKIP_BREAK(reg) ((reg)->r_pc += 4)
#elif defined(__mips__)
#define SKIP_BREAK(reg) ((reg)->r_regs[PC] += 4)
#elif defined(__riscv)
#define SKIP_BREAK(reg) ((reg)->sepc += 4)
#elif defined(__sparc64__)
#define SKIP_BREAK(reg) do { \
(reg)->r_tpc = (reg)->r_tnpc + 4; \
(reg)->r_tnpc += 8; \
} while (0)
#endif
#endif
/*
* A variant of ATF_REQUIRE that is suitable for use in child
* processes. This only works if the parent process is tripped up by
* the early exit and fails some requirement itself.
*/
#define CHILD_REQUIRE(exp) do { \
if (!(exp)) \
child_fail_require(__FILE__, __LINE__, \
#exp " not met\n"); \
} while (0)
#define CHILD_REQUIRE_EQ(actual, expected) do { \
__typeof__(expected) _e = expected; \
__typeof__(actual) _a = actual; \
if (_e != _a) \
child_fail_require(__FILE__, __LINE__, #actual \
" (%jd) == " #expected " (%jd) not met\n", \
(intmax_t)_a, (intmax_t)_e); \
} while (0)
static __dead2 void
child_fail_require(const char *file, int line, const char *fmt, ...)
{
va_list ap;
char buf[1024];
/* Use write() not fprintf() to avoid possible duplicate output. */
snprintf(buf, sizeof(buf), "%s:%d: ", file, line);
write(STDERR_FILENO, buf, strlen(buf));
va_start(ap, fmt);
vsnprintf(buf, sizeof(buf), fmt, ap);
write(STDERR_FILENO, buf, strlen(buf));
va_end(ap);
_exit(32);
}
#define REQUIRE_EQ(actual, expected) do { \
__typeof__(expected) _e = expected; \
__typeof__(actual) _a = actual; \
ATF_REQUIRE_MSG(_e == _a, #actual " (%jd) == " \
#expected " (%jd) not met", (intmax_t)_a, (intmax_t)_e); \
} while (0)
static void
trace_me(void)
{
/* Attach the parent process as a tracer of this process. */
CHILD_REQUIRE(ptrace(PT_TRACE_ME, 0, NULL, 0) != -1);
/* Trigger a stop. */
raise(SIGSTOP);
}
static void
attach_child(pid_t pid)
{
pid_t wpid;
int status;
REQUIRE_EQ(ptrace(PT_ATTACH, pid, NULL, 0), 0);
wpid = waitpid(pid, &status, 0);
REQUIRE_EQ(wpid, pid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
}
static void
wait_for_zombie(pid_t pid)
{
/*
* Wait for a process to exit. This is kind of gross, but
* there is not a better way.
*
* Prior to r325719, the kern.proc.pid.<pid> sysctl failed
* with ESRCH. After that change, a valid struct kinfo_proc
* is returned for zombies with ki_stat set to SZOMB.
*/
for (;;) {
struct kinfo_proc kp;
size_t len;
int mib[4];
mib[0] = CTL_KERN;
mib[1] = KERN_PROC;
mib[2] = KERN_PROC_PID;
mib[3] = pid;
len = sizeof(kp);
if (sysctl(mib, nitems(mib), &kp, &len, NULL, 0) == -1) {
REQUIRE_EQ(errno, ESRCH);
break;
}
if (kp.ki_stat == SZOMB)
break;
usleep(5000);
}
}
/*
* Verify that a parent debugger process "sees" the exit of a debugged
* process exactly once when attached via PT_TRACE_ME.
*/
ATF_TC_WITHOUT_HEAD(ptrace__parent_wait_after_trace_me);
ATF_TC_BODY(ptrace__parent_wait_after_trace_me, tc)
{
pid_t child, wpid;
int status;
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
/* Child process. */
trace_me();
_exit(1);
}
/* Parent process. */
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/* The second wait() should report the exit status. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
/* The child should no longer exist. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a parent debugger process "sees" the exit of a debugged
* process exactly once when attached via PT_ATTACH.
*/
ATF_TC_WITHOUT_HEAD(ptrace__parent_wait_after_attach);
ATF_TC_BODY(ptrace__parent_wait_after_attach, tc)
{
pid_t child, wpid;
int cpipe[2], status;
char c;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
/* Child process. */
close(cpipe[0]);
/* Wait for the parent to attach. */
CHILD_REQUIRE_EQ(0, read(cpipe[1], &c, sizeof(c)));
_exit(1);
}
close(cpipe[1]);
/* Parent process. */
/* Attach to the child process. */
attach_child(child);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/* Signal the child to exit. */
close(cpipe[0]);
/* The second wait() should report the exit status. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
/* The child should no longer exist. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a parent process "sees" the exit of a debugged process only
* after the debugger has seen it.
*/
ATF_TC_WITHOUT_HEAD(ptrace__parent_sees_exit_after_child_debugger);
ATF_TC_BODY(ptrace__parent_sees_exit_after_child_debugger, tc)
{
pid_t child, debugger, wpid;
int cpipe[2], dpipe[2], status;
char c;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
/* Child process. */
close(cpipe[0]);
/* Wait for parent to be ready. */
CHILD_REQUIRE_EQ(read(cpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
_exit(1);
}
close(cpipe[1]);
REQUIRE_EQ(pipe(dpipe), 0);
ATF_REQUIRE((debugger = fork()) != -1);
if (debugger == 0) {
/* Debugger process. */
close(dpipe[0]);
CHILD_REQUIRE(ptrace(PT_ATTACH, child, NULL, 0) != -1);
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFSTOPPED(status));
CHILD_REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
CHILD_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/* Signal parent that debugger is attached. */
CHILD_REQUIRE_EQ(write(dpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
/* Wait for parent's failed wait. */
CHILD_REQUIRE_EQ(read(dpipe[1], &c, sizeof(c)), 0);
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFEXITED(status));
CHILD_REQUIRE_EQ(WEXITSTATUS(status), 1);
_exit(0);
}
close(dpipe[1]);
/* Parent process. */
/* Wait for the debugger to attach to the child. */
REQUIRE_EQ(read(dpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
/* Release the child. */
REQUIRE_EQ(write(cpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
REQUIRE_EQ(read(cpipe[0], &c, sizeof(c)), 0);
close(cpipe[0]);
wait_for_zombie(child);
/*
* This wait should return a pid of 0 to indicate no status to
* report. The parent should see the child as non-exited
* until the debugger sees the exit.
*/
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, 0);
/* Signal the debugger to wait for the child. */
close(dpipe[0]);
/* Wait for the debugger. */
wpid = waitpid(debugger, &status, 0);
REQUIRE_EQ(wpid, debugger);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
/* The child process should now be ready. */
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
}
/*
* Verify that a parent process "sees" the exit of a debugged process
* only after a non-direct-child debugger has seen it. In particular,
* various wait() calls in the parent must avoid failing with ESRCH by
* checking the parent's orphan list for the debugee.
*/
ATF_TC_WITHOUT_HEAD(ptrace__parent_sees_exit_after_unrelated_debugger);
ATF_TC_BODY(ptrace__parent_sees_exit_after_unrelated_debugger, tc)
{
pid_t child, debugger, fpid, wpid;
int cpipe[2], dpipe[2], status;
char c;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
/* Child process. */
close(cpipe[0]);
/* Wait for parent to be ready. */
CHILD_REQUIRE_EQ(read(cpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
_exit(1);
}
close(cpipe[1]);
REQUIRE_EQ(pipe(dpipe), 0);
ATF_REQUIRE((debugger = fork()) != -1);
if (debugger == 0) {
/* Debugger parent. */
/*
* Fork again and drop the debugger parent so that the
* debugger is not a child of the main parent.
*/
CHILD_REQUIRE((fpid = fork()) != -1);
if (fpid != 0)
_exit(2);
/* Debugger process. */
close(dpipe[0]);
CHILD_REQUIRE(ptrace(PT_ATTACH, child, NULL, 0) != -1);
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFSTOPPED(status));
CHILD_REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
CHILD_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/* Signal parent that debugger is attached. */
CHILD_REQUIRE_EQ(write(dpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
/* Wait for parent's failed wait. */
CHILD_REQUIRE_EQ(read(dpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFEXITED(status));
CHILD_REQUIRE_EQ(WEXITSTATUS(status), 1);
_exit(0);
}
close(dpipe[1]);
/* Parent process. */
/* Wait for the debugger parent process to exit. */
wpid = waitpid(debugger, &status, 0);
REQUIRE_EQ(wpid, debugger);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
/* A WNOHANG wait here should see the non-exited child. */
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, 0);
/* Wait for the debugger to attach to the child. */
REQUIRE_EQ(read(dpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
/* Release the child. */
REQUIRE_EQ(write(cpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
REQUIRE_EQ(read(cpipe[0], &c, sizeof(c)), 0);
close(cpipe[0]);
wait_for_zombie(child);
/*
* This wait should return a pid of 0 to indicate no status to
* report. The parent should see the child as non-exited
* until the debugger sees the exit.
*/
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, 0);
/* Signal the debugger to wait for the child. */
REQUIRE_EQ(write(dpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
/* Wait for the debugger. */
REQUIRE_EQ(read(dpipe[0], &c, sizeof(c)), 0);
close(dpipe[0]);
/* The child process should now be ready. */
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
}
/*
* Make sure that we can collect the exit status of an orphaned process.
*/
ATF_TC_WITHOUT_HEAD(ptrace__parent_exits_before_child);
ATF_TC_BODY(ptrace__parent_exits_before_child, tc)
{
ssize_t n;
int cpipe1[2], cpipe2[2], gcpipe[2], status;
pid_t child, gchild;
REQUIRE_EQ(pipe(cpipe1), 0);
REQUIRE_EQ(pipe(cpipe2), 0);
REQUIRE_EQ(pipe(gcpipe), 0);
REQUIRE_EQ(procctl(P_PID, getpid(), PROC_REAP_ACQUIRE, NULL), 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
CHILD_REQUIRE((gchild = fork()) != -1);
if (gchild == 0) {
status = 1;
do {
n = read(gcpipe[0], &status, sizeof(status));
} while (n == -1 && errno == EINTR);
_exit(status);
}
CHILD_REQUIRE_EQ(write(cpipe1[1], &gchild, sizeof(gchild)),
(ssize_t)sizeof(gchild));
CHILD_REQUIRE_EQ(read(cpipe2[0], &status, sizeof(status)),
(ssize_t)sizeof(status));
_exit(status);
}
REQUIRE_EQ(read(cpipe1[0], &gchild, sizeof(gchild)),
(ssize_t)sizeof(gchild));
REQUIRE_EQ(ptrace(PT_ATTACH, gchild, NULL, 0), 0);
status = 0;
REQUIRE_EQ(write(cpipe2[1], &status, sizeof(status)),
(ssize_t)sizeof(status));
REQUIRE_EQ(waitpid(child, &status, 0), child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
status = 0;
REQUIRE_EQ(write(gcpipe[1], &status, sizeof(status)),
(ssize_t)sizeof(status));
REQUIRE_EQ(waitpid(gchild, &status, 0), gchild);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(ptrace(PT_DETACH, gchild, (caddr_t)1, 0), 0);
REQUIRE_EQ(waitpid(gchild, &status, 0), gchild);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
REQUIRE_EQ(close(cpipe1[0]), 0);
REQUIRE_EQ(close(cpipe1[1]), 0);
REQUIRE_EQ(close(cpipe2[0]), 0);
REQUIRE_EQ(close(cpipe2[1]), 0);
REQUIRE_EQ(close(gcpipe[0]), 0);
REQUIRE_EQ(close(gcpipe[1]), 0);
}
/*
* The parent process should always act the same regardless of how the
* debugger is attached to it.
*/
static __dead2 void
follow_fork_parent(bool use_vfork)
{
pid_t fpid, wpid;
int status;
if (use_vfork)
CHILD_REQUIRE((fpid = vfork()) != -1);
else
CHILD_REQUIRE((fpid = fork()) != -1);
if (fpid == 0)
/* Child */
_exit(2);
wpid = waitpid(fpid, &status, 0);
CHILD_REQUIRE_EQ(wpid, fpid);
CHILD_REQUIRE(WIFEXITED(status));
CHILD_REQUIRE_EQ(WEXITSTATUS(status), 2);
_exit(1);
}
/*
* Helper routine for follow fork tests. This waits for two stops
* that report both "sides" of a fork. It returns the pid of the new
* child process.
*/
static pid_t
handle_fork_events(pid_t parent, struct ptrace_lwpinfo *ppl)
{
struct ptrace_lwpinfo pl;
bool fork_reported[2];
pid_t child, wpid;
int i, status;
fork_reported[0] = false;
fork_reported[1] = false;
child = -1;
/*
* Each process should report a fork event. The parent should
* report a PL_FLAG_FORKED event, and the child should report
* a PL_FLAG_CHILD event.
*/
for (i = 0; i < 2; i++) {
wpid = wait(&status);
ATF_REQUIRE(wpid > 0);
ATF_REQUIRE(WIFSTOPPED(status));
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & (PL_FLAG_FORKED | PL_FLAG_CHILD)) !=
0);
ATF_REQUIRE((pl.pl_flags & (PL_FLAG_FORKED | PL_FLAG_CHILD)) !=
(PL_FLAG_FORKED | PL_FLAG_CHILD));
if (pl.pl_flags & PL_FLAG_CHILD) {
ATF_REQUIRE(wpid != parent);
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(!fork_reported[1]);
if (child == -1)
child = wpid;
else
REQUIRE_EQ(child, wpid);
if (ppl != NULL)
ppl[1] = pl;
fork_reported[1] = true;
} else {
REQUIRE_EQ(wpid, parent);
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(!fork_reported[0]);
if (child == -1)
child = pl.pl_child_pid;
else
REQUIRE_EQ(child, pl.pl_child_pid);
if (ppl != NULL)
ppl[0] = pl;
fork_reported[0] = true;
}
}
return (child);
}
/*
* Verify that a new child process is stopped after a followed fork and
* that the traced parent sees the exit of the child after the debugger
* when both processes remain attached to the debugger.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_both_attached);
ATF_TC_BODY(ptrace__follow_fork_both_attached, tc)
{
pid_t children[2], fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(false);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The child can't exit until the grandchild reports status, so the
* grandchild should report its exit first to the debugger.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a new child process is stopped after a followed fork
* and that the traced parent sees the exit of the child when the new
* child process is detached after it reports its fork.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_child_detached);
ATF_TC_BODY(ptrace__follow_fork_child_detached, tc)
{
pid_t children[2], fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(false);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_DETACH, children[1], (caddr_t)1, 0) != -1);
/*
* Should not see any status from the grandchild now, only the
* child.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a new child process is stopped after a followed fork
* and that the traced parent sees the exit of the child when the
* traced parent is detached after the fork.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_parent_detached);
ATF_TC_BODY(ptrace__follow_fork_parent_detached, tc)
{
pid_t children[2], fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(false);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_DETACH, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The child can't exit until the grandchild reports status, so the
* grandchild should report its exit first to the debugger.
*
* Even though the child process is detached, it is still a
* child of the debugger, so it will still report it's exit
* after the grandchild.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void
attach_fork_parent(int cpipe[2])
{
pid_t fpid;
close(cpipe[0]);
/* Double-fork to disassociate from the debugger. */
CHILD_REQUIRE((fpid = fork()) != -1);
if (fpid != 0)
_exit(3);
/* Send the pid of the disassociated child to the debugger. */
fpid = getpid();
CHILD_REQUIRE_EQ(write(cpipe[1], &fpid, sizeof(fpid)),
(ssize_t)sizeof(fpid));
/* Wait for the debugger to attach. */
CHILD_REQUIRE_EQ(read(cpipe[1], &fpid, sizeof(fpid)), 0);
}
/*
* Verify that a new child process is stopped after a followed fork and
* that the traced parent sees the exit of the child after the debugger
* when both processes remain attached to the debugger. In this test
* the parent that forks is not a direct child of the debugger.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_both_attached_unrelated_debugger);
ATF_TC_BODY(ptrace__follow_fork_both_attached_unrelated_debugger, tc)
{
pid_t children[2], fpid, wpid;
int cpipe[2], status;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
attach_fork_parent(cpipe);
follow_fork_parent(false);
}
/* Parent process. */
close(cpipe[1]);
/* Wait for the direct child to exit. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 3);
/* Read the pid of the fork parent. */
REQUIRE_EQ(read(cpipe[0], &children[0], sizeof(children[0])),
(ssize_t)sizeof(children[0]));
/* Attach to the fork parent. */
attach_child(children[0]);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the fork parent ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Signal the fork parent to continue. */
close(cpipe[0]);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The fork parent can't exit until the child reports status,
* so the child should report its exit first to the debugger.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a new child process is stopped after a followed fork
* and that the traced parent sees the exit of the child when the new
* child process is detached after it reports its fork. In this test
* the parent that forks is not a direct child of the debugger.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_child_detached_unrelated_debugger);
ATF_TC_BODY(ptrace__follow_fork_child_detached_unrelated_debugger, tc)
{
pid_t children[2], fpid, wpid;
int cpipe[2], status;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
attach_fork_parent(cpipe);
follow_fork_parent(false);
}
/* Parent process. */
close(cpipe[1]);
/* Wait for the direct child to exit. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 3);
/* Read the pid of the fork parent. */
REQUIRE_EQ(read(cpipe[0], &children[0], sizeof(children[0])),
(ssize_t)sizeof(children[0]));
/* Attach to the fork parent. */
attach_child(children[0]);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the fork parent ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Signal the fork parent to continue. */
close(cpipe[0]);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_DETACH, children[1], (caddr_t)1, 0) != -1);
/*
* Should not see any status from the child now, only the fork
* parent.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a new child process is stopped after a followed fork
* and that the traced parent sees the exit of the child when the
* traced parent is detached after the fork. In this test the parent
* that forks is not a direct child of the debugger.
*/
ATF_TC_WITHOUT_HEAD(ptrace__follow_fork_parent_detached_unrelated_debugger);
ATF_TC_BODY(ptrace__follow_fork_parent_detached_unrelated_debugger, tc)
{
pid_t children[2], fpid, wpid;
int cpipe[2], status;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
attach_fork_parent(cpipe);
follow_fork_parent(false);
}
/* Parent process. */
close(cpipe[1]);
/* Wait for the direct child to exit. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 3);
/* Read the pid of the fork parent. */
REQUIRE_EQ(read(cpipe[0], &children[0], sizeof(children[0])),
(ssize_t)sizeof(children[0]));
/* Attach to the fork parent. */
attach_child(children[0]);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the fork parent ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Signal the fork parent to continue. */
close(cpipe[0]);
children[1] = handle_fork_events(children[0], NULL);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE(ptrace(PT_DETACH, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* Should not see any status from the fork parent now, only
* the child.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a child process does not see an unrelated debugger as its
* parent but sees its original parent process.
*/
ATF_TC_WITHOUT_HEAD(ptrace__getppid);
ATF_TC_BODY(ptrace__getppid, tc)
{
pid_t child, debugger, ppid, wpid;
int cpipe[2], dpipe[2], status;
char c;
REQUIRE_EQ(pipe(cpipe), 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
/* Child process. */
close(cpipe[0]);
/* Wait for parent to be ready. */
CHILD_REQUIRE_EQ(read(cpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
/* Report the parent PID to the parent. */
ppid = getppid();
CHILD_REQUIRE_EQ(write(cpipe[1], &ppid, sizeof(ppid)),
(ssize_t)sizeof(ppid));
_exit(1);
}
close(cpipe[1]);
REQUIRE_EQ(pipe(dpipe), 0);
ATF_REQUIRE((debugger = fork()) != -1);
if (debugger == 0) {
/* Debugger process. */
close(dpipe[0]);
CHILD_REQUIRE(ptrace(PT_ATTACH, child, NULL, 0) != -1);
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFSTOPPED(status));
CHILD_REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
CHILD_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/* Signal parent that debugger is attached. */
CHILD_REQUIRE_EQ(write(dpipe[1], &c, sizeof(c)),
(ssize_t)sizeof(c));
/* Wait for traced child to exit. */
wpid = waitpid(child, &status, 0);
CHILD_REQUIRE_EQ(wpid, child);
CHILD_REQUIRE(WIFEXITED(status));
CHILD_REQUIRE_EQ(WEXITSTATUS(status), 1);
_exit(0);
}
close(dpipe[1]);
/* Parent process. */
/* Wait for the debugger to attach to the child. */
REQUIRE_EQ(read(dpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
/* Release the child. */
REQUIRE_EQ(write(cpipe[0], &c, sizeof(c)), (ssize_t)sizeof(c));
/* Read the parent PID from the child. */
REQUIRE_EQ(read(cpipe[0], &ppid, sizeof(ppid)), (ssize_t)sizeof(ppid));
close(cpipe[0]);
REQUIRE_EQ(ppid, getpid());
/* Wait for the debugger. */
wpid = waitpid(debugger, &status, 0);
REQUIRE_EQ(wpid, debugger);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
/* The child process should now be ready. */
wpid = waitpid(child, &status, WNOHANG);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
}
/*
* Verify that pl_syscall_code in struct ptrace_lwpinfo for a new
* child process created via fork() reports the correct value.
*/
ATF_TC_WITHOUT_HEAD(ptrace__new_child_pl_syscall_code_fork);
ATF_TC_BODY(ptrace__new_child_pl_syscall_code_fork, tc)
{
struct ptrace_lwpinfo pl[2];
pid_t children[2], fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(false);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Wait for both halves of the fork event to get reported. */
children[1] = handle_fork_events(children[0], pl);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE((pl[0].pl_flags & PL_FLAG_SCX) != 0);
ATF_REQUIRE((pl[1].pl_flags & PL_FLAG_SCX) != 0);
REQUIRE_EQ(pl[0].pl_syscall_code, (unsigned)SYS_fork);
REQUIRE_EQ(pl[0].pl_syscall_code, pl[1].pl_syscall_code);
REQUIRE_EQ(pl[0].pl_syscall_narg, pl[1].pl_syscall_narg);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The child can't exit until the grandchild reports status, so the
* grandchild should report its exit first to the debugger.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that pl_syscall_code in struct ptrace_lwpinfo for a new
* child process created via vfork() reports the correct value.
*/
ATF_TC_WITHOUT_HEAD(ptrace__new_child_pl_syscall_code_vfork);
ATF_TC_BODY(ptrace__new_child_pl_syscall_code_vfork, tc)
{
struct ptrace_lwpinfo pl[2];
pid_t children[2], fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(true);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, children[0], NULL, 1) != -1);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Wait for both halves of the fork event to get reported. */
children[1] = handle_fork_events(children[0], pl);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE((pl[0].pl_flags & PL_FLAG_SCX) != 0);
ATF_REQUIRE((pl[1].pl_flags & PL_FLAG_SCX) != 0);
REQUIRE_EQ(pl[0].pl_syscall_code, (unsigned)SYS_vfork);
REQUIRE_EQ(pl[0].pl_syscall_code, pl[1].pl_syscall_code);
REQUIRE_EQ(pl[0].pl_syscall_narg, pl[1].pl_syscall_narg);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The child can't exit until the grandchild reports status, so the
* grandchild should report its exit first to the debugger.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
simple_thread(void *arg __unused)
{
pthread_exit(NULL);
}
static __dead2 void
simple_thread_main(void)
{
pthread_t thread;
CHILD_REQUIRE_EQ(pthread_create(&thread, NULL, simple_thread, NULL), 0);
CHILD_REQUIRE_EQ(pthread_join(thread, NULL), 0);
exit(1);
}
/*
* Verify that pl_syscall_code in struct ptrace_lwpinfo for a new
* thread reports the correct value.
*/
ATF_TC_WITHOUT_HEAD(ptrace__new_child_pl_syscall_code_thread);
ATF_TC_BODY(ptrace__new_child_pl_syscall_code_thread, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
lwpid_t mainlwp;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
simple_thread_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
mainlwp = pl.pl_lwpid;
/*
* Continue the child ignoring the SIGSTOP and tracing all
* system call exits.
*/
ATF_REQUIRE(ptrace(PT_TO_SCX, fpid, (caddr_t)1, 0) != -1);
/*
* Wait for the new thread to arrive. pthread_create() might
* invoke any number of system calls. For now we just wait
* for the new thread to arrive and make sure it reports a
* valid system call code. If ptrace grows thread event
* reporting then this test can be made more precise.
*/
for (;;) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & PL_FLAG_SCX) != 0);
ATF_REQUIRE(pl.pl_syscall_code != 0);
if (pl.pl_lwpid != mainlwp)
/* New thread seen. */
break;
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
}
/* Wait for the child to exit. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
for (;;) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFEXITED(status))
break;
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
}
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that the expected LWP events are reported for a child thread.
*/
ATF_TC_WITHOUT_HEAD(ptrace__lwp_events);
ATF_TC_BODY(ptrace__lwp_events, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
lwpid_t lwps[2];
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
simple_thread_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
lwps[0] = pl.pl_lwpid;
REQUIRE_EQ(ptrace(PT_LWP_EVENTS, wpid, NULL, 1), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The first event should be for the child thread's birth. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_BORN | PL_FLAG_SCX)),
(PL_FLAG_BORN | PL_FLAG_SCX));
ATF_REQUIRE(pl.pl_lwpid != lwps[0]);
lwps[1] = pl.pl_lwpid;
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next event should be for the child thread's death. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_EXITED | PL_FLAG_SCE)),
(PL_FLAG_EXITED | PL_FLAG_SCE));
REQUIRE_EQ(pl.pl_lwpid, lwps[1]);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
exec_thread(void *arg __unused)
{
execl("/usr/bin/true", "true", NULL);
exit(127);
}
static __dead2 void
exec_thread_main(void)
{
pthread_t thread;
CHILD_REQUIRE_EQ(pthread_create(&thread, NULL, exec_thread, NULL), 0);
for (;;)
sleep(60);
exit(1);
}
/*
* Verify that the expected LWP events are reported for a multithreaded
* process that calls execve(2).
*/
ATF_TC_WITHOUT_HEAD(ptrace__lwp_events_exec);
ATF_TC_BODY(ptrace__lwp_events_exec, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
lwpid_t lwps[2];
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exec_thread_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
lwps[0] = pl.pl_lwpid;
REQUIRE_EQ(ptrace(PT_LWP_EVENTS, wpid, NULL, 1), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The first event should be for the child thread's birth. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_BORN | PL_FLAG_SCX)),
(PL_FLAG_BORN | PL_FLAG_SCX));
ATF_REQUIRE(pl.pl_lwpid != lwps[0]);
lwps[1] = pl.pl_lwpid;
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next event should be for the main thread's death due to
* single threading from execve().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_EXITED | PL_FLAG_SCE)),
(PL_FLAG_EXITED));
REQUIRE_EQ(pl.pl_lwpid, lwps[0]);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next event should be for the child process's exec. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_EXEC | PL_FLAG_SCX)),
(PL_FLAG_EXEC | PL_FLAG_SCX));
REQUIRE_EQ(pl.pl_lwpid, lwps[1]);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void
handler(int sig __unused)
{
}
static void
signal_main(void)
{
signal(SIGINFO, handler);
raise(SIGINFO);
exit(0);
}
/*
* Verify that the expected ptrace event is reported for a signal.
*/
ATF_TC_WITHOUT_HEAD(ptrace__siginfo);
ATF_TC_BODY(ptrace__siginfo, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
signal_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next event should be for the SIGINFO. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGINFO);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_event, PL_EVENT_SIGNAL);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_code, SI_LWP);
REQUIRE_EQ(pl.pl_siginfo.si_pid, wpid);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that the expected ptrace events are reported for PTRACE_EXEC.
*/
ATF_TC_WITHOUT_HEAD(ptrace__ptrace_exec_disable);
ATF_TC_BODY(ptrace__ptrace_exec_disable, tc)
{
pid_t fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exec_thread(NULL);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
events = 0;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Should get one event at exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
ATF_TC_WITHOUT_HEAD(ptrace__ptrace_exec_enable);
ATF_TC_BODY(ptrace__ptrace_exec_enable, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exec_thread(NULL);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
events = PTRACE_EXEC;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next event should be for the child process's exec. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_EXEC | PL_FLAG_SCX)),
(PL_FLAG_EXEC | PL_FLAG_SCX));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
ATF_TC_WITHOUT_HEAD(ptrace__event_mask);
ATF_TC_BODY(ptrace__event_mask, tc)
{
pid_t fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exit(0);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* PT_FOLLOW_FORK should toggle the state of PTRACE_FORK. */
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, fpid, NULL, 1) != -1);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
ATF_REQUIRE(events & PTRACE_FORK);
ATF_REQUIRE(ptrace(PT_FOLLOW_FORK, fpid, NULL, 0) != -1);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
ATF_REQUIRE(!(events & PTRACE_FORK));
/* PT_LWP_EVENTS should toggle the state of PTRACE_LWP. */
ATF_REQUIRE(ptrace(PT_LWP_EVENTS, fpid, NULL, 1) != -1);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
ATF_REQUIRE(events & PTRACE_LWP);
ATF_REQUIRE(ptrace(PT_LWP_EVENTS, fpid, NULL, 0) != -1);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
ATF_REQUIRE(!(events & PTRACE_LWP));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Should get one event at exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that the expected ptrace events are reported for PTRACE_VFORK.
*/
ATF_TC_WITHOUT_HEAD(ptrace__ptrace_vfork);
ATF_TC_BODY(ptrace__ptrace_vfork, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(true);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
events |= PTRACE_VFORK;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0) != -1);
/* The next event should report the end of the vfork. */
wpid = wait(&status);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & PL_FLAG_VFORK_DONE) != 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0) != -1);
wpid = wait(&status);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
ATF_TC_WITHOUT_HEAD(ptrace__ptrace_vfork_follow);
ATF_TC_BODY(ptrace__ptrace_vfork_follow, tc)
{
struct ptrace_lwpinfo pl[2];
pid_t children[2], fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
follow_fork_parent(true);
}
/* Parent process. */
children[0] = fpid;
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(children[0], &status, 0);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, children[0], (caddr_t)&events,
sizeof(events)) == 0);
events |= PTRACE_FORK | PTRACE_VFORK;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, children[0], (caddr_t)&events,
sizeof(events)) == 0);
/* Continue the child ignoring the SIGSTOP. */
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
/* Wait for both halves of the fork event to get reported. */
children[1] = handle_fork_events(children[0], pl);
ATF_REQUIRE(children[1] > 0);
ATF_REQUIRE((pl[0].pl_flags & PL_FLAG_VFORKED) != 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[1], (caddr_t)1, 0) != -1);
/*
* The child can't exit until the grandchild reports status, so the
* grandchild should report its exit first to the debugger.
*/
wpid = waitpid(children[1], &status, 0);
REQUIRE_EQ(wpid, children[1]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
/*
* The child should report it's vfork() completion before it
* exits.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl[0], sizeof(pl[0])) !=
-1);
ATF_REQUIRE((pl[0].pl_flags & PL_FLAG_VFORK_DONE) != 0);
ATF_REQUIRE(ptrace(PT_CONTINUE, children[0], (caddr_t)1, 0) != -1);
wpid = wait(&status);
REQUIRE_EQ(wpid, children[0]);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#ifdef HAVE_BREAKPOINT
/*
* Verify that no more events are reported after PT_KILL except for the
* process exit when stopped due to a breakpoint trap.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_KILL_breakpoint);
ATF_TC_BODY(ptrace__PT_KILL_breakpoint, tc)
{
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
breakpoint();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report hitting the breakpoint. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
/* Kill the child process. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#endif /* HAVE_BREAKPOINT */
/*
* Verify that no more events are reported after PT_KILL except for the
* process exit when stopped inside of a system call.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_KILL_system_call);
ATF_TC_BODY(ptrace__PT_KILL_system_call, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a system call entry for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Kill the child process. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that no more events are reported after PT_KILL except for the
* process exit when killing a multithreaded process.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_KILL_threads);
ATF_TC_BODY(ptrace__PT_KILL_threads, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
lwpid_t main_lwp;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
simple_thread_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
main_lwp = pl.pl_lwpid;
REQUIRE_EQ(ptrace(PT_LWP_EVENTS, wpid, NULL, 1), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The first event should be for the child thread's birth. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_BORN | PL_FLAG_SCX)),
(PL_FLAG_BORN | PL_FLAG_SCX));
ATF_REQUIRE(pl.pl_lwpid != main_lwp);
/* Kill the child process. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
mask_usr1_thread(void *arg)
{
pthread_barrier_t *pbarrier;
sigset_t sigmask;
pbarrier = (pthread_barrier_t*)arg;
sigemptyset(&sigmask);
sigaddset(&sigmask, SIGUSR1);
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_BLOCK, &sigmask, NULL), 0);
/* Sync up with other thread after sigmask updated. */
pthread_barrier_wait(pbarrier);
for (;;)
sleep(60);
return (NULL);
}
/*
* Verify that the SIGKILL from PT_KILL takes priority over other signals
* and prevents spurious stops due to those other signals.
*/
ATF_TC(ptrace__PT_KILL_competing_signal);
ATF_TC_HEAD(ptrace__PT_KILL_competing_signal, tc)
{
atf_tc_set_md_var(tc, "require.user", "root");
}
ATF_TC_BODY(ptrace__PT_KILL_competing_signal, tc)
{
pid_t fpid, wpid;
int status;
cpuset_t setmask;
pthread_t t;
pthread_barrier_t barrier;
struct sched_param sched_param;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
/* Bind to one CPU so only one thread at a time will run. */
CPU_ZERO(&setmask);
CPU_SET(0, &setmask);
cpusetid_t setid;
CHILD_REQUIRE_EQ(cpuset(&setid), 0);
CHILD_REQUIRE(cpuset_setaffinity(CPU_LEVEL_CPUSET,
CPU_WHICH_CPUSET, setid, sizeof(setmask), &setmask) == 0);
CHILD_REQUIRE_EQ(pthread_barrier_init(&barrier, NULL, 2), 0);
CHILD_REQUIRE(pthread_create(&t, NULL, mask_usr1_thread,
(void*)&barrier) == 0);
/*
* Give the main thread higher priority. The test always
* assumes that, if both threads are able to run, the main
* thread runs first.
*/
sched_param.sched_priority =
(sched_get_priority_max(SCHED_FIFO) +
sched_get_priority_min(SCHED_FIFO)) / 2;
CHILD_REQUIRE(pthread_setschedparam(pthread_self(),
SCHED_FIFO, &sched_param) == 0);
sched_param.sched_priority -= RQ_PPQ;
CHILD_REQUIRE(pthread_setschedparam(t, SCHED_FIFO,
&sched_param) == 0);
sigset_t sigmask;
sigemptyset(&sigmask);
sigaddset(&sigmask, SIGUSR2);
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_BLOCK, &sigmask, NULL), 0);
/* Sync up with other thread after sigmask updated. */
pthread_barrier_wait(&barrier);
trace_me();
for (;;)
sleep(60);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Send a signal that only the second thread can handle. */
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
/* The second wait() should report the SIGUSR2. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
/* Send a signal that only the first thread can handle. */
REQUIRE_EQ(kill(fpid, SIGUSR1), 0);
/* Replace the SIGUSR2 with a kill. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL (not the SIGUSR signal). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that the SIGKILL from PT_KILL takes priority over other stop events
* and prevents spurious stops caused by those events.
*/
ATF_TC(ptrace__PT_KILL_competing_stop);
ATF_TC_HEAD(ptrace__PT_KILL_competing_stop, tc)
{
atf_tc_set_md_var(tc, "require.user", "root");
}
ATF_TC_BODY(ptrace__PT_KILL_competing_stop, tc)
{
pid_t fpid, wpid;
int status;
cpuset_t setmask;
pthread_t t;
pthread_barrier_t barrier;
lwpid_t main_lwp;
struct ptrace_lwpinfo pl;
struct sched_param sched_param;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
/* Bind to one CPU so only one thread at a time will run. */
CPU_ZERO(&setmask);
CPU_SET(0, &setmask);
cpusetid_t setid;
CHILD_REQUIRE_EQ(cpuset(&setid), 0);
CHILD_REQUIRE(cpuset_setaffinity(CPU_LEVEL_CPUSET,
CPU_WHICH_CPUSET, setid, sizeof(setmask), &setmask) == 0);
CHILD_REQUIRE_EQ(pthread_barrier_init(&barrier, NULL, 2), 0);
CHILD_REQUIRE(pthread_create(&t, NULL, mask_usr1_thread,
(void*)&barrier) == 0);
/*
* Give the main thread higher priority. The test always
* assumes that, if both threads are able to run, the main
* thread runs first.
*/
sched_param.sched_priority =
(sched_get_priority_max(SCHED_FIFO) +
sched_get_priority_min(SCHED_FIFO)) / 2;
CHILD_REQUIRE(pthread_setschedparam(pthread_self(),
SCHED_FIFO, &sched_param) == 0);
sched_param.sched_priority -= RQ_PPQ;
CHILD_REQUIRE(pthread_setschedparam(t, SCHED_FIFO,
&sched_param) == 0);
sigset_t sigmask;
sigemptyset(&sigmask);
sigaddset(&sigmask, SIGUSR2);
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_BLOCK, &sigmask, NULL), 0);
/* Sync up with other thread after sigmask updated. */
pthread_barrier_wait(&barrier);
/* Sync up with the test before doing the getpid(). */
raise(SIGSTOP);
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
main_lwp = pl.pl_lwpid;
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/*
* Continue until child is done with setup, which is indicated with
* SIGSTOP. Ignore system calls in the meantime.
*/
for (;;) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
if (WSTOPSIG(status) == SIGTRAP) {
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & (PL_FLAG_SCE | PL_FLAG_SCX));
} else {
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
break;
}
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
}
/* Proceed, allowing main thread to hit syscall entry for getpid(). */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_lwpid, main_lwp);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Prevent the main thread from hitting its syscall exit for now. */
REQUIRE_EQ(ptrace(PT_SUSPEND, main_lwp, 0, 0), 0);
/*
* Proceed, allowing second thread to hit syscall exit for
* pthread_barrier_wait().
*/
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_lwpid != main_lwp);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
/* Send a signal that only the second thread can handle. */
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The next wait() should report the SIGUSR2. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
/* Allow the main thread to try to finish its system call. */
REQUIRE_EQ(ptrace(PT_RESUME, main_lwp, 0, 0), 0);
/*
* At this point, the main thread is in the middle of a system call and
* has been resumed. The second thread has taken a SIGUSR2 which will
* be replaced with a SIGKILL below. The main thread will get to run
* first. It should notice the kill request (even though the signal
* replacement occurred in the other thread) and exit accordingly. It
* should not stop for the system call exit event.
*/
/* Replace the SIGUSR2 with a kill. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL (not a syscall exit). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void
sigusr1_handler(int sig)
{
CHILD_REQUIRE_EQ(sig, SIGUSR1);
_exit(2);
}
/*
* Verify that even if the signal queue is full for a child process,
* a PT_KILL will kill the process.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_KILL_with_signal_full_sigqueue);
ATF_TC_BODY(ptrace__PT_KILL_with_signal_full_sigqueue, tc)
{
pid_t fpid, wpid;
int status;
int max_pending_per_proc;
size_t len;
int i;
ATF_REQUIRE(signal(SIGUSR1, sigusr1_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
len = sizeof(max_pending_per_proc);
ATF_REQUIRE(sysctlbyname("kern.sigqueue.max_pending_per_proc",
&max_pending_per_proc, &len, NULL, 0) == 0);
/* Fill the signal queue. */
for (i = 0; i < max_pending_per_proc; ++i)
REQUIRE_EQ(kill(fpid, SIGUSR1), 0);
/* Kill the child process. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that when stopped at a system call entry, a signal can be
* requested with PT_CONTINUE which will be delivered once the system
* call is complete.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_system_call_entry);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_system_call_entry, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE(signal(SIGUSR1, sigusr1_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a system call entry for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Continue the child process with a signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
for (;;) {
/*
* The last wait() should report exit 2, i.e., a normal _exit
* from the signal handler. In the meantime, catch and proceed
* past any syscall stops.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP) {
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & (PL_FLAG_SCE | PL_FLAG_SCX));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
} else {
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
break;
}
}
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void
sigusr1_counting_handler(int sig)
{
static int counter = 0;
CHILD_REQUIRE_EQ(sig, SIGUSR1);
counter++;
if (counter == 2)
_exit(2);
}
/*
* Verify that, when continuing from a stop at system call entry and exit,
* a signal can be requested from both stops, and both will be delivered when
* the system call is complete.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_system_call_entry_and_exit);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_system_call_entry_and_exit, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE(signal(SIGUSR1, sigusr1_counting_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a system call entry for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Continue the child process with a signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The third wait() should report a system call exit for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
/* Continue the child process with a signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
for (;;) {
/*
* The last wait() should report exit 2, i.e., a normal _exit
* from the signal handler. In the meantime, catch and proceed
* past any syscall stops.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP) {
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & (PL_FLAG_SCE | PL_FLAG_SCX));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
} else {
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
break;
}
}
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that even if the signal queue is full for a child process,
* a PT_CONTINUE with a signal will not result in loss of that signal.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_full_sigqueue);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_full_sigqueue, tc)
{
pid_t fpid, wpid;
int status;
int max_pending_per_proc;
size_t len;
int i;
ATF_REQUIRE(signal(SIGUSR2, handler) != SIG_ERR);
ATF_REQUIRE(signal(SIGUSR1, sigusr1_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
len = sizeof(max_pending_per_proc);
ATF_REQUIRE(sysctlbyname("kern.sigqueue.max_pending_per_proc",
&max_pending_per_proc, &len, NULL, 0) == 0);
/* Fill the signal queue. */
for (i = 0; i < max_pending_per_proc; ++i)
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
/* Continue with signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
for (;;) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFSTOPPED(status)) {
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
} else {
/*
* The last wait() should report normal _exit from the
* SIGUSR1 handler.
*/
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
break;
}
}
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static sem_t sigusr1_sem;
static int got_usr1;
static void
sigusr1_sempost_handler(int sig __unused)
{
got_usr1++;
CHILD_REQUIRE_EQ(sem_post(&sigusr1_sem), 0);
}
/*
* Verify that even if the signal queue is full for a child process,
* and the signal is masked, a PT_CONTINUE with a signal will not
* result in loss of that signal.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_masked_full_sigqueue);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_masked_full_sigqueue, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status, err;
int max_pending_per_proc;
size_t len;
int i;
sigset_t sigmask;
ATF_REQUIRE(signal(SIGUSR2, handler) != SIG_ERR);
REQUIRE_EQ(sem_init(&sigusr1_sem, 0, 0), 0);
ATF_REQUIRE(signal(SIGUSR1, sigusr1_sempost_handler) != SIG_ERR);
got_usr1 = 0;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
CHILD_REQUIRE_EQ(sigemptyset(&sigmask), 0);
CHILD_REQUIRE_EQ(sigaddset(&sigmask, SIGUSR1), 0);
CHILD_REQUIRE_EQ(sigprocmask(SIG_BLOCK, &sigmask, NULL), 0);
trace_me();
CHILD_REQUIRE_EQ(got_usr1, 0);
/* Allow the pending SIGUSR1 in now. */
CHILD_REQUIRE_EQ(sigprocmask(SIG_UNBLOCK, &sigmask, NULL), 0);
/* Wait to receive the SIGUSR1. */
do {
err = sem_wait(&sigusr1_sem);
CHILD_REQUIRE(err == 0 || errno == EINTR);
} while (err != 0 && errno == EINTR);
CHILD_REQUIRE_EQ(got_usr1, 1);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
len = sizeof(max_pending_per_proc);
ATF_REQUIRE(sysctlbyname("kern.sigqueue.max_pending_per_proc",
&max_pending_per_proc, &len, NULL, 0) == 0);
/* Fill the signal queue. */
for (i = 0; i < max_pending_per_proc; ++i)
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
/* Continue with signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* Collect and ignore all of the SIGUSR2. */
for (i = 0; i < max_pending_per_proc; ++i) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
}
/* Now our PT_CONTINUE'd SIGUSR1 should cause a stop after unmask. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR1);
ATF_REQUIRE(ptrace(PT_LWPINFO, fpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGUSR1);
/* Continue the child, ignoring the SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last wait() should report exit after receiving SIGUSR1. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that, after stopping due to a signal, that signal can be
* replaced with another signal.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_change_sig);
ATF_TC_BODY(ptrace__PT_CONTINUE_change_sig, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
sleep(20);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Send a signal without ptrace. */
REQUIRE_EQ(kill(fpid, SIGINT), 0);
/* The second wait() should report a SIGINT was received. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGINT);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGINT);
/* Continue the child process with a different signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGTERM), 0);
/*
* The last wait() should report having died due to the new
* signal, SIGTERM.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGTERM);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a signal can be passed through to the child even when there
* was no true signal originally. Such cases arise when a SIGTRAP is
* invented for e.g, system call stops.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_sigtrap_system_call_entry);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_sigtrap_system_call_entry, tc)
{
struct ptrace_lwpinfo pl;
struct rlimit rl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
/* SIGTRAP expected to cause exit on syscall entry. */
rl.rlim_cur = rl.rlim_max = 0;
REQUIRE_EQ(setrlimit(RLIMIT_CORE, &rl), 0);
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a system call entry for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Continue the child process with a SIGTRAP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGTRAP), 0);
for (;;) {
/*
* The last wait() should report exit due to SIGTRAP. In the
* meantime, catch and proceed past any syscall stops.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP) {
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & (PL_FLAG_SCE | PL_FLAG_SCX));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
} else {
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGTRAP);
break;
}
}
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* A mixed bag PT_CONTINUE with signal test.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_mix);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_mix, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE(signal(SIGUSR1, sigusr1_counting_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
getpid();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP and tracing system calls. */
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a system call entry for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
/* Continue with the first SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The next wait() should report a system call exit for getpid(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
/* Send an ABRT without ptrace. */
REQUIRE_EQ(kill(fpid, SIGABRT), 0);
/* Continue normally. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next wait() should report the SIGABRT. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGABRT);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGABRT);
/* Continue, replacing the SIGABRT with another SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
for (;;) {
/*
* The last wait() should report exit 2, i.e., a normal _exit
* from the signal handler. In the meantime, catch and proceed
* past any syscall stops.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
if (WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP) {
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & (PL_FLAG_SCE | PL_FLAG_SCX));
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
} else {
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 2);
break;
}
}
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify a signal delivered by ptrace is noticed by kevent(2).
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_kqueue);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_kqueue, tc)
{
pid_t fpid, wpid;
int status, kq, nevents;
struct kevent kev;
ATF_REQUIRE(signal(SIGUSR1, SIG_IGN) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
CHILD_REQUIRE((kq = kqueue()) > 0);
EV_SET(&kev, SIGUSR1, EVFILT_SIGNAL, EV_ADD, 0, 0, 0);
CHILD_REQUIRE_EQ(kevent(kq, &kev, 1, NULL, 0, NULL), 0);
trace_me();
for (;;) {
nevents = kevent(kq, NULL, 0, &kev, 1, NULL);
if (nevents == -1 && errno == EINTR)
continue;
CHILD_REQUIRE(nevents > 0);
CHILD_REQUIRE_EQ(kev.filter, EVFILT_SIGNAL);
CHILD_REQUIRE_EQ(kev.ident, (uintptr_t)SIGUSR1);
break;
}
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue with the SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/*
* The last wait() should report normal exit with code 1.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
signal_thread(void *arg)
{
int err;
sigset_t sigmask;
pthread_barrier_t *pbarrier = (pthread_barrier_t*)arg;
/* Wait for this thread to receive a SIGUSR1. */
do {
err = sem_wait(&sigusr1_sem);
CHILD_REQUIRE(err == 0 || errno == EINTR);
} while (err != 0 && errno == EINTR);
/* Free our companion thread from the barrier. */
pthread_barrier_wait(pbarrier);
/*
* Swap ignore duties; the next SIGUSR1 should go to the
* other thread.
*/
CHILD_REQUIRE_EQ(sigemptyset(&sigmask), 0);
CHILD_REQUIRE_EQ(sigaddset(&sigmask, SIGUSR1), 0);
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_BLOCK, &sigmask, NULL), 0);
/* Sync up threads after swapping signal masks. */
pthread_barrier_wait(pbarrier);
/* Wait until our companion has received its SIGUSR1. */
pthread_barrier_wait(pbarrier);
return (NULL);
}
/*
* Verify that a traced process with blocked signal received the
* signal from kill() once unmasked.
*/
ATF_TC_WITHOUT_HEAD(ptrace__killed_with_sigmask);
ATF_TC_BODY(ptrace__killed_with_sigmask, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status, err;
sigset_t sigmask;
REQUIRE_EQ(sem_init(&sigusr1_sem, 0, 0), 0);
ATF_REQUIRE(signal(SIGUSR1, sigusr1_sempost_handler) != SIG_ERR);
got_usr1 = 0;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
CHILD_REQUIRE_EQ(sigemptyset(&sigmask), 0);
CHILD_REQUIRE_EQ(sigaddset(&sigmask, SIGUSR1), 0);
CHILD_REQUIRE_EQ(sigprocmask(SIG_BLOCK, &sigmask, NULL), 0);
trace_me();
CHILD_REQUIRE_EQ(got_usr1, 0);
/* Allow the pending SIGUSR1 in now. */
CHILD_REQUIRE_EQ(sigprocmask(SIG_UNBLOCK, &sigmask, NULL), 0);
/* Wait to receive a SIGUSR1. */
do {
err = sem_wait(&sigusr1_sem);
CHILD_REQUIRE(err == 0 || errno == EINTR);
} while (err != 0 && errno == EINTR);
CHILD_REQUIRE_EQ(got_usr1, 1);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, fpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGSTOP);
/* Send blocked SIGUSR1 which should cause a stop. */
REQUIRE_EQ(kill(fpid, SIGUSR1), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next wait() should report the kill(SIGUSR1) was received. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR1);
ATF_REQUIRE(ptrace(PT_LWPINFO, fpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGUSR1);
/* Continue the child, allowing in the SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The last wait() should report normal exit with code 1. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that a traced process with blocked signal received the
* signal from PT_CONTINUE once unmasked.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_sigmask);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_sigmask, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status, err;
sigset_t sigmask;
REQUIRE_EQ(sem_init(&sigusr1_sem, 0, 0), 0);
ATF_REQUIRE(signal(SIGUSR1, sigusr1_sempost_handler) != SIG_ERR);
got_usr1 = 0;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
CHILD_REQUIRE_EQ(sigemptyset(&sigmask), 0);
CHILD_REQUIRE_EQ(sigaddset(&sigmask, SIGUSR1), 0);
CHILD_REQUIRE_EQ(sigprocmask(SIG_BLOCK, &sigmask, NULL), 0);
trace_me();
CHILD_REQUIRE_EQ(got_usr1, 0);
/* Allow the pending SIGUSR1 in now. */
CHILD_REQUIRE_EQ(sigprocmask(SIG_UNBLOCK, &sigmask, NULL), 0);
/* Wait to receive a SIGUSR1. */
do {
err = sem_wait(&sigusr1_sem);
CHILD_REQUIRE(err == 0 || errno == EINTR);
} while (err != 0 && errno == EINTR);
CHILD_REQUIRE_EQ(got_usr1, 1);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, fpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGSTOP);
/* Continue the child replacing SIGSTOP with SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The next wait() should report the SIGUSR1 was received. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR1);
ATF_REQUIRE(ptrace(PT_LWPINFO, fpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGUSR1);
/* Continue the child, ignoring the SIGUSR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last wait() should report normal exit with code 1. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that if ptrace stops due to a signal but continues with
* a different signal that the new signal is routed to a thread
* that can accept it, and that the thread is awakened by the signal
* in a timely manner.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_with_signal_thread_sigmask);
ATF_TC_BODY(ptrace__PT_CONTINUE_with_signal_thread_sigmask, tc)
{
pid_t fpid, wpid;
int status, err;
pthread_t t;
sigset_t sigmask;
pthread_barrier_t barrier;
REQUIRE_EQ(pthread_barrier_init(&barrier, NULL, 2), 0);
REQUIRE_EQ(sem_init(&sigusr1_sem, 0, 0), 0);
ATF_REQUIRE(signal(SIGUSR1, sigusr1_sempost_handler) != SIG_ERR);
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
CHILD_REQUIRE_EQ(pthread_create(&t, NULL, signal_thread,
(void *)&barrier), 0);
/* The other thread should receive the first SIGUSR1. */
CHILD_REQUIRE_EQ(sigemptyset(&sigmask), 0);
CHILD_REQUIRE_EQ(sigaddset(&sigmask, SIGUSR1), 0);
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_BLOCK, &sigmask, NULL), 0);
trace_me();
/* Wait until other thread has received its SIGUSR1. */
pthread_barrier_wait(&barrier);
/*
* Swap ignore duties; the next SIGUSR1 should go to this
* thread.
*/
CHILD_REQUIRE_EQ(pthread_sigmask(SIG_UNBLOCK, &sigmask, NULL),
0);
/* Sync up threads after swapping signal masks. */
pthread_barrier_wait(&barrier);
/*
* Sync up with test code; we're ready for the next SIGUSR1
* now.
*/
raise(SIGSTOP);
/* Wait for this thread to receive a SIGUSR1. */
do {
err = sem_wait(&sigusr1_sem);
CHILD_REQUIRE(err == 0 || errno == EINTR);
} while (err != 0 && errno == EINTR);
/* Free the other thread from the barrier. */
pthread_barrier_wait(&barrier);
CHILD_REQUIRE_EQ(pthread_join(t, NULL), 0);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* Send a signal without ptrace that either thread will accept (USR2,
* in this case).
*/
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
/* The second wait() should report a SIGUSR2 was received. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
/* Continue the child, changing the signal to USR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The next wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
REQUIRE_EQ(kill(fpid, SIGUSR2), 0);
/* The next wait() should report a SIGUSR2 was received. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGUSR2);
/* Continue the child, changing the signal to USR1. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, SIGUSR1), 0);
/* The last wait() should report normal exit with code 1. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that PT_GETREGSET returns registers and PT_SETREGSET updates them.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_REGSET);
ATF_TC_BODY(ptrace__PT_REGSET, tc)
{
#if defined(__aarch64__)
struct arm64_addr_mask addr_mask;
#endif
struct prstatus prstatus;
struct iovec vec;
pid_t child, wpid;
int status;
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
trace_me();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Check the size is returned when vec.iov_base is NULL */
vec.iov_base = NULL;
vec.iov_len = 0;
ATF_REQUIRE(ptrace(PT_GETREGSET, wpid, (caddr_t)&vec, NT_PRSTATUS) !=
-1);
ATF_REQUIRE(vec.iov_len == sizeof(prstatus));
ATF_REQUIRE(vec.iov_base == NULL);
/* Read the registers. */
memset(&prstatus, 0, sizeof(prstatus));
vec.iov_base = &prstatus;
ATF_REQUIRE(ptrace(PT_GETREGSET, wpid, (caddr_t)&vec, NT_PRSTATUS) !=
-1);
ATF_REQUIRE(vec.iov_len == sizeof(prstatus));
ATF_REQUIRE(vec.iov_base == &prstatus);
ATF_REQUIRE(prstatus.pr_statussz == sizeof(prstatus));
/* Write the registers back. */
ATF_REQUIRE(ptrace(PT_SETREGSET, wpid, (caddr_t)&vec, NT_PRSTATUS) !=
-1);
#if defined(__aarch64__)
vec.iov_base = &addr_mask;
vec.iov_len = sizeof(addr_mask);
ATF_REQUIRE(ptrace(PT_GETREGSET, wpid, (caddr_t)&vec,
NT_ARM_ADDR_MASK) != -1);
REQUIRE_EQ(addr_mask.code, addr_mask.data);
ATF_REQUIRE(addr_mask.code == 0 ||
addr_mask.code == 0xff7f000000000000UL);
#endif
REQUIRE_EQ(ptrace(PT_CONTINUE, child, (caddr_t)1, 0), 0);
/* The second wait() should report the exit status. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
/* The child should no longer exist. */
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
raise_sigstop_thread(void *arg __unused)
{
raise(SIGSTOP);
return NULL;
}
static void *
sleep_thread(void *arg __unused)
{
sleep(60);
return NULL;
}
static void
terminate_with_pending_sigstop(bool sigstop_from_main_thread)
{
pid_t fpid, wpid;
int status, i;
cpuset_t setmask;
cpusetid_t setid;
pthread_t t;
/*
* Become the reaper for this process tree. We need to be able to check
* that both child and grandchild have died.
*/
REQUIRE_EQ(procctl(P_PID, getpid(), PROC_REAP_ACQUIRE, NULL), 0);
fpid = fork();
ATF_REQUIRE(fpid >= 0);
if (fpid == 0) {
fpid = fork();
CHILD_REQUIRE(fpid >= 0);
if (fpid == 0) {
trace_me();
/* Pin to CPU 0 to serialize thread execution. */
CPU_ZERO(&setmask);
CPU_SET(0, &setmask);
CHILD_REQUIRE_EQ(cpuset(&setid), 0);
CHILD_REQUIRE(cpuset_setaffinity(CPU_LEVEL_CPUSET,
CPU_WHICH_CPUSET, setid,
sizeof(setmask), &setmask) == 0);
if (sigstop_from_main_thread) {
/*
* We expect the SIGKILL sent when our parent
* dies to be delivered to the new thread.
* Raise the SIGSTOP in this thread so the
* threads compete.
*/
CHILD_REQUIRE(pthread_create(&t, NULL,
sleep_thread, NULL) == 0);
raise(SIGSTOP);
} else {
/*
* We expect the SIGKILL to be delivered to
* this thread. After creating the new thread,
* just get off the CPU so the other thread can
* raise the SIGSTOP.
*/
CHILD_REQUIRE(pthread_create(&t, NULL,
raise_sigstop_thread, NULL) == 0);
sleep(60);
}
exit(0);
}
/* First stop is trace_me() immediately after fork. */
wpid = waitpid(fpid, &status, 0);
CHILD_REQUIRE_EQ(wpid, fpid);
CHILD_REQUIRE(WIFSTOPPED(status));
CHILD_REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
CHILD_REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Second stop is from the raise(SIGSTOP). */
wpid = waitpid(fpid, &status, 0);
CHILD_REQUIRE_EQ(wpid, fpid);
CHILD_REQUIRE(WIFSTOPPED(status));
CHILD_REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/*
* Terminate tracing process without detaching. Our child
* should be killed.
*/
exit(0);
}
/*
* We should get a normal exit from our immediate child and a SIGKILL
* exit from our grandchild. The latter case is the interesting one.
* Our grandchild should not have stopped due to the SIGSTOP that was
* left dangling when its parent died.
*/
for (i = 0; i < 2; ++i) {
wpid = wait(&status);
if (wpid == fpid) {
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
} else {
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
}
}
}
/*
* These two tests ensure that if the tracing process exits without detaching
* just after the child received a SIGSTOP, the child is cleanly killed and
* doesn't go to sleep due to the SIGSTOP. The parent's death will send a
* SIGKILL to the child. If the SIGKILL and the SIGSTOP are handled by
* different threads, the SIGKILL must win. There are two variants of this
* test, designed to catch the case where the SIGKILL is delivered to the
* younger thread (the first test) and the case where the SIGKILL is delivered
* to the older thread (the second test). This behavior has changed in the
* past, so make no assumption.
*/
ATF_TC(ptrace__parent_terminate_with_pending_sigstop1);
ATF_TC_HEAD(ptrace__parent_terminate_with_pending_sigstop1, tc)
{
atf_tc_set_md_var(tc, "require.user", "root");
}
ATF_TC_BODY(ptrace__parent_terminate_with_pending_sigstop1, tc)
{
terminate_with_pending_sigstop(true);
}
ATF_TC(ptrace__parent_terminate_with_pending_sigstop2);
ATF_TC_HEAD(ptrace__parent_terminate_with_pending_sigstop2, tc)
{
atf_tc_set_md_var(tc, "require.user", "root");
}
ATF_TC_BODY(ptrace__parent_terminate_with_pending_sigstop2, tc)
{
terminate_with_pending_sigstop(false);
}
/*
* Verify that after ptrace() discards a SIGKILL signal, the event mask
* is not modified.
*/
ATF_TC_WITHOUT_HEAD(ptrace__event_mask_sigkill_discard);
ATF_TC_BODY(ptrace__event_mask_sigkill_discard, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status, event_mask, new_event_mask;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
raise(SIGSTOP);
exit(0);
}
/* The first wait() should report the stop from trace_me(). */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Set several unobtrusive event bits. */
event_mask = PTRACE_EXEC | PTRACE_FORK | PTRACE_LWP;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, wpid, (caddr_t)&event_mask,
sizeof(event_mask)) == 0);
/* Send a SIGKILL without using ptrace. */
REQUIRE_EQ(kill(fpid, SIGKILL), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next stop should be due to the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGKILL);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGKILL);
/* Continue the child ignoring the SIGKILL. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Check the current event mask. It should not have changed. */
new_event_mask = 0;
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, wpid, (caddr_t)&new_event_mask,
sizeof(new_event_mask)) == 0);
REQUIRE_EQ(event_mask, new_event_mask);
/* Continue the child to let it exit. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
static void *
flock_thread(void *arg)
{
int fd;
fd = *(int *)arg;
(void)flock(fd, LOCK_EX);
(void)flock(fd, LOCK_UN);
return (NULL);
}
/*
* Verify that PT_ATTACH will suspend threads sleeping in an SBDRY section.
* We rely on the fact that the lockf implementation sets SBDRY before blocking
* on a lock. This is a regression test for r318191.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_ATTACH_with_SBDRY_thread);
ATF_TC_BODY(ptrace__PT_ATTACH_with_SBDRY_thread, tc)
{
pthread_barrier_t barrier;
pthread_barrierattr_t battr;
char tmpfile[64];
pid_t child, wpid;
int error, fd, i, status;
REQUIRE_EQ(pthread_barrierattr_init(&battr), 0);
ATF_REQUIRE(pthread_barrierattr_setpshared(&battr,
PTHREAD_PROCESS_SHARED) == 0);
REQUIRE_EQ(pthread_barrier_init(&barrier, &battr, 2), 0);
(void)snprintf(tmpfile, sizeof(tmpfile), "./ptrace.XXXXXX");
fd = mkstemp(tmpfile);
ATF_REQUIRE(fd >= 0);
ATF_REQUIRE((child = fork()) != -1);
if (child == 0) {
pthread_t t[2];
int cfd;
error = pthread_barrier_wait(&barrier);
if (error != 0 && error != PTHREAD_BARRIER_SERIAL_THREAD)
_exit(1);
cfd = open(tmpfile, O_RDONLY);
if (cfd < 0)
_exit(1);
/*
* We want at least two threads blocked on the file lock since
* the SIGSTOP from PT_ATTACH may kick one of them out of
* sleep.
*/
if (pthread_create(&t[0], NULL, flock_thread, &cfd) != 0)
_exit(1);
if (pthread_create(&t[1], NULL, flock_thread, &cfd) != 0)
_exit(1);
if (pthread_join(t[0], NULL) != 0)
_exit(1);
if (pthread_join(t[1], NULL) != 0)
_exit(1);
_exit(0);
}
REQUIRE_EQ(flock(fd, LOCK_EX), 0);
error = pthread_barrier_wait(&barrier);
ATF_REQUIRE(error == 0 || error == PTHREAD_BARRIER_SERIAL_THREAD);
/*
* Give the child some time to block. Is there a better way to do this?
*/
sleep(1);
/*
* Attach and give the child 3 seconds to stop.
*/
REQUIRE_EQ(ptrace(PT_ATTACH, child, NULL, 0), 0);
for (i = 0; i < 3; i++) {
wpid = waitpid(child, &status, WNOHANG);
if (wpid == child && WIFSTOPPED(status) &&
WSTOPSIG(status) == SIGSTOP)
break;
sleep(1);
}
ATF_REQUIRE_MSG(i < 3, "failed to stop child process after PT_ATTACH");
REQUIRE_EQ(ptrace(PT_DETACH, child, NULL, 0), 0);
REQUIRE_EQ(flock(fd, LOCK_UN), 0);
REQUIRE_EQ(unlink(tmpfile), 0);
REQUIRE_EQ(close(fd), 0);
}
static void
sigusr1_step_handler(int sig)
{
CHILD_REQUIRE_EQ(sig, SIGUSR1);
raise(SIGABRT);
}
/*
* Verify that PT_STEP with a signal invokes the signal before
* stepping the next instruction (and that the next instruction is
* stepped correctly).
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_STEP_with_signal);
ATF_TC_BODY(ptrace__PT_STEP_with_signal, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
signal(SIGUSR1, sigusr1_step_handler);
raise(SIGABRT);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next stop should report the SIGABRT in the child body. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGABRT);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGABRT);
/* Step the child process inserting SIGUSR1. */
REQUIRE_EQ(ptrace(PT_STEP, fpid, (caddr_t)1, SIGUSR1), 0);
/* The next stop should report the SIGABRT in the signal handler. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGABRT);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGABRT);
/* Continue the child process discarding the signal. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next stop should report a trace trap from PT_STEP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGTRAP);
REQUIRE_EQ(pl.pl_siginfo.si_code, TRAP_TRACE);
/* Continue the child to let it exit. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#ifdef HAVE_BREAKPOINT
/*
* Verify that a SIGTRAP event with the TRAP_BRKPT code is reported
* for a breakpoint trap.
*/
ATF_TC_WITHOUT_HEAD(ptrace__breakpoint_siginfo);
ATF_TC_BODY(ptrace__breakpoint_siginfo, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
breakpoint();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report hitting the breakpoint. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & PL_FLAG_SI) != 0);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGTRAP);
REQUIRE_EQ(pl.pl_siginfo.si_code, TRAP_BRKPT);
/* Kill the child process. */
REQUIRE_EQ(ptrace(PT_KILL, fpid, 0, 0), 0);
/* The last wait() should report the SIGKILL. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSIGNALED(status));
REQUIRE_EQ(WTERMSIG(status), SIGKILL);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#endif /* HAVE_BREAKPOINT */
/*
* Verify that a SIGTRAP event with the TRAP_TRACE code is reported
* for a single-step trap from PT_STEP.
*/
ATF_TC_WITHOUT_HEAD(ptrace__step_siginfo);
ATF_TC_BODY(ptrace__step_siginfo, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Step the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_STEP, fpid, (caddr_t)1, 0), 0);
/* The second wait() should report a single-step trap. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & PL_FLAG_SI) != 0);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGTRAP);
REQUIRE_EQ(pl.pl_siginfo.si_code, TRAP_TRACE);
/* Continue the child process. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#if defined(HAVE_BREAKPOINT) && defined(SKIP_BREAK)
static void *
continue_thread(void *arg __unused)
{
breakpoint();
return (NULL);
}
static __dead2 void
continue_thread_main(void)
{
pthread_t threads[2];
CHILD_REQUIRE(pthread_create(&threads[0], NULL, continue_thread,
NULL) == 0);
CHILD_REQUIRE(pthread_create(&threads[1], NULL, continue_thread,
NULL) == 0);
CHILD_REQUIRE_EQ(pthread_join(threads[0], NULL), 0);
CHILD_REQUIRE_EQ(pthread_join(threads[1], NULL), 0);
exit(1);
}
/*
* Ensure that PT_CONTINUE clears the status of the thread that
* triggered the stop even if a different thread's LWP was passed to
* PT_CONTINUE.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_CONTINUE_different_thread);
ATF_TC_BODY(ptrace__PT_CONTINUE_different_thread, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
lwpid_t lwps[2];
bool hit_break[2];
struct reg reg;
int i, j, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
continue_thread_main();
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
REQUIRE_EQ(ptrace(PT_LWP_EVENTS, wpid, NULL, 1), 0);
/* Continue the child ignoring the SIGSTOP. */
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* One of the new threads should report it's birth. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_BORN | PL_FLAG_SCX)),
(PL_FLAG_BORN | PL_FLAG_SCX));
lwps[0] = pl.pl_lwpid;
/*
* Suspend this thread to ensure both threads are alive before
* hitting the breakpoint.
*/
ATF_REQUIRE(ptrace(PT_SUSPEND, lwps[0], NULL, 0) != -1);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* Second thread should report it's birth. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
REQUIRE_EQ((pl.pl_flags & (PL_FLAG_BORN | PL_FLAG_SCX)),
(PL_FLAG_BORN | PL_FLAG_SCX));
ATF_REQUIRE(pl.pl_lwpid != lwps[0]);
lwps[1] = pl.pl_lwpid;
/* Resume both threads waiting for breakpoint events. */
hit_break[0] = hit_break[1] = false;
ATF_REQUIRE(ptrace(PT_RESUME, lwps[0], NULL, 0) != -1);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* One thread should report a breakpoint. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE((pl.pl_flags & PL_FLAG_SI) != 0);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGTRAP);
REQUIRE_EQ(pl.pl_siginfo.si_code, TRAP_BRKPT);
if (pl.pl_lwpid == lwps[0])
i = 0;
else
i = 1;
hit_break[i] = true;
ATF_REQUIRE(ptrace(PT_GETREGS, pl.pl_lwpid, (caddr_t)&reg, 0) != -1);
SKIP_BREAK(&reg);
ATF_REQUIRE(ptrace(PT_SETREGS, pl.pl_lwpid, (caddr_t)&reg, 0) != -1);
/*
* Resume both threads but pass the other thread's LWPID to
* PT_CONTINUE.
*/
REQUIRE_EQ(ptrace(PT_CONTINUE, lwps[i ^ 1], (caddr_t)1, 0), 0);
/*
* Will now get two thread exit events and one more breakpoint
* event.
*/
for (j = 0; j < 3; j++) {
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl,
sizeof(pl)) != -1);
if (pl.pl_lwpid == lwps[0])
i = 0;
else
i = 1;
ATF_REQUIRE_MSG(lwps[i] != 0, "event for exited thread");
if (pl.pl_flags & PL_FLAG_EXITED) {
ATF_REQUIRE_MSG(hit_break[i],
"exited thread did not report breakpoint");
lwps[i] = 0;
} else {
ATF_REQUIRE((pl.pl_flags & PL_FLAG_SI) != 0);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGTRAP);
REQUIRE_EQ(pl.pl_siginfo.si_code, TRAP_BRKPT);
ATF_REQUIRE_MSG(!hit_break[i],
"double breakpoint event");
hit_break[i] = true;
ATF_REQUIRE(ptrace(PT_GETREGS, pl.pl_lwpid, (caddr_t)&reg,
0) != -1);
SKIP_BREAK(&reg);
ATF_REQUIRE(ptrace(PT_SETREGS, pl.pl_lwpid, (caddr_t)&reg,
0) != -1);
}
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
}
/* Both threads should have exited. */
REQUIRE_EQ(lwps[0], 0);
REQUIRE_EQ(lwps[1], 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
#endif
/*
* Verify that PT_LWPINFO doesn't return stale siginfo.
*/
ATF_TC_WITHOUT_HEAD(ptrace__PT_LWPINFO_stale_siginfo);
ATF_TC_BODY(ptrace__PT_LWPINFO_stale_siginfo, tc)
{
struct ptrace_lwpinfo pl;
pid_t fpid, wpid;
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
raise(SIGABRT);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The next stop should report the SIGABRT in the child body. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGABRT);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SI);
REQUIRE_EQ(pl.pl_siginfo.si_signo, SIGABRT);
/*
* Continue the process ignoring the signal, but enabling
* syscall traps.
*/
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should report a system call entry from
* exit(). PL_FLAGS_SI should not be set.
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
REQUIRE_EQ((pl.pl_flags & PL_FLAG_SI), 0);
/* Disable syscall tracing and continue the child to let it exit. */
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
events &= ~PTRACE_SYSCALL;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* A simple test of PT_GET_SC_ARGS and PT_GET_SC_RET.
*/
ATF_TC_WITHOUT_HEAD(ptrace__syscall_args);
ATF_TC_BODY(ptrace__syscall_args, tc)
{
struct ptrace_lwpinfo pl;
struct ptrace_sc_ret psr;
pid_t fpid, wpid;
register_t args[2];
int events, status;
ATF_REQUIRE((fpid = fork()) != -1);
if (fpid == 0) {
trace_me();
kill(getpid(), 0);
/* Close a fd that should not exist. */
close(12345);
exit(1);
}
/* The first wait() should report the stop from SIGSTOP. */
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/*
* Continue the process ignoring the signal, but enabling
* syscall traps.
*/
REQUIRE_EQ(ptrace(PT_SYSCALL, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall entry from getpid().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_getpid);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall exit from getpid().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_getpid);
ATF_REQUIRE(ptrace(PT_GET_SC_RET, wpid, (caddr_t)&psr,
sizeof(psr)) != -1);
REQUIRE_EQ(psr.sr_error, 0);
REQUIRE_EQ(psr.sr_retval[0], wpid);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall entry from kill().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_kill);
REQUIRE_EQ(pl.pl_syscall_narg, 2u);
ATF_REQUIRE(ptrace(PT_GET_SC_ARGS, wpid, (caddr_t)args,
sizeof(args)) != -1);
REQUIRE_EQ(args[0], wpid);
REQUIRE_EQ(args[1], 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall exit from kill().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_kill);
ATF_REQUIRE(ptrace(PT_GET_SC_RET, wpid, (caddr_t)&psr,
sizeof(psr)) != -1);
REQUIRE_EQ(psr.sr_error, 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall entry from close().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCE);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_close);
REQUIRE_EQ(pl.pl_syscall_narg, 1u);
ATF_REQUIRE(ptrace(PT_GET_SC_ARGS, wpid, (caddr_t)args,
sizeof(args)) != -1);
REQUIRE_EQ(args[0], 12345);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/*
* The next stop should be the syscall exit from close().
*/
wpid = waitpid(fpid, &status, 0);
REQUIRE_EQ(wpid, fpid);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGTRAP);
ATF_REQUIRE(ptrace(PT_LWPINFO, wpid, (caddr_t)&pl, sizeof(pl)) != -1);
ATF_REQUIRE(pl.pl_flags & PL_FLAG_SCX);
REQUIRE_EQ(pl.pl_syscall_code, (unsigned)SYS_close);
ATF_REQUIRE(ptrace(PT_GET_SC_RET, wpid, (caddr_t)&psr,
sizeof(psr)) != -1);
REQUIRE_EQ(psr.sr_error, EBADF);
/* Disable syscall tracing and continue the child to let it exit. */
ATF_REQUIRE(ptrace(PT_GET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
events &= ~PTRACE_SYSCALL;
ATF_REQUIRE(ptrace(PT_SET_EVENT_MASK, fpid, (caddr_t)&events,
sizeof(events)) == 0);
REQUIRE_EQ(ptrace(PT_CONTINUE, fpid, (caddr_t)1, 0), 0);
/* The last event should be for the child process's exit. */
wpid = waitpid(fpid, &status, 0);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 1);
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Verify that when the process is traced that it isn't reparent
* to the init process when we close all process descriptors.
*/
ATF_TC(ptrace__proc_reparent);
ATF_TC_HEAD(ptrace__proc_reparent, tc)
{
atf_tc_set_md_var(tc, "timeout", "2");
}
ATF_TC_BODY(ptrace__proc_reparent, tc)
{
pid_t traced, debuger, wpid;
int pd, status;
traced = pdfork(&pd, 0);
ATF_REQUIRE(traced >= 0);
if (traced == 0) {
raise(SIGSTOP);
exit(0);
}
ATF_REQUIRE(pd >= 0);
debuger = fork();
ATF_REQUIRE(debuger >= 0);
if (debuger == 0) {
/* The traced process is reparented to debuger. */
REQUIRE_EQ(ptrace(PT_ATTACH, traced, 0, 0), 0);
wpid = waitpid(traced, &status, 0);
REQUIRE_EQ(wpid, traced);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
REQUIRE_EQ(close(pd), 0);
REQUIRE_EQ(ptrace(PT_DETACH, traced, (caddr_t)1, 0), 0);
/* We closed pd so we should not have any child. */
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
exit(0);
}
REQUIRE_EQ(close(pd), 0);
wpid = waitpid(debuger, &status, 0);
REQUIRE_EQ(wpid, debuger);
REQUIRE_EQ(WEXITSTATUS(status), 0);
/* Check if we still have any child. */
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
}
/*
* Ensure that traced processes created with pdfork(2) are visible to
* waitid(P_ALL).
*/
ATF_TC_WITHOUT_HEAD(ptrace__procdesc_wait_child);
ATF_TC_BODY(ptrace__procdesc_wait_child, tc)
{
pid_t child, wpid;
int pd, status;
child = pdfork(&pd, 0);
ATF_REQUIRE(child >= 0);
if (child == 0) {
trace_me();
(void)raise(SIGSTOP);
exit(0);
}
wpid = waitpid(child, &status, 0);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
wpid = wait(&status);
REQUIRE_EQ(wpid, child);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
ATF_REQUIRE(ptrace(PT_CONTINUE, child, (caddr_t)1, 0) != -1);
/*
* If process was created by pdfork, the return code have to
* be collected through process descriptor.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
ATF_REQUIRE(close(pd) != -1);
}
/*
* Ensure that traced processes created with pdfork(2) are not visible
* after returning to parent - waitid(P_ALL).
*/
ATF_TC_WITHOUT_HEAD(ptrace__procdesc_reparent_wait_child);
ATF_TC_BODY(ptrace__procdesc_reparent_wait_child, tc)
{
pid_t traced, debuger, wpid;
int pd, status;
traced = pdfork(&pd, 0);
ATF_REQUIRE(traced >= 0);
if (traced == 0) {
raise(SIGSTOP);
exit(0);
}
ATF_REQUIRE(pd >= 0);
/* Wait until the child process has stopped before fork()ing again. */
REQUIRE_EQ(traced, waitpid(traced, &status, WSTOPPED));
debuger = fork();
ATF_REQUIRE(debuger >= 0);
if (debuger == 0) {
/* The traced process is reparented to debuger. */
REQUIRE_EQ(ptrace(PT_ATTACH, traced, 0, 0), 0);
wpid = waitpid(traced, &status, 0);
REQUIRE_EQ(wpid, traced);
ATF_REQUIRE(WIFSTOPPED(status));
REQUIRE_EQ(WSTOPSIG(status), SIGSTOP);
/* Allow process to die. */
REQUIRE_EQ(ptrace(PT_CONTINUE, traced, (caddr_t)1, 0), 0);
wpid = waitpid(traced, &status, 0);
REQUIRE_EQ(wpid, traced);
ATF_REQUIRE(WIFEXITED(status));
REQUIRE_EQ(WEXITSTATUS(status), 0);
/* Reparent back to the orginal process. */
REQUIRE_EQ(close(pd), 0);
exit(0);
}
wpid = waitpid(debuger, &status, 0);
REQUIRE_EQ(wpid, debuger);
REQUIRE_EQ(WEXITSTATUS(status), 0);
/*
* We have a child but it has a process descriptori
* so we should not be able to collect it process.
*/
wpid = wait(&status);
REQUIRE_EQ(wpid, -1);
REQUIRE_EQ(errno, ECHILD);
REQUIRE_EQ(close(pd), 0);
}
ATF_TP_ADD_TCS(tp)
{
ATF_TP_ADD_TC(tp, ptrace__parent_wait_after_trace_me);
ATF_TP_ADD_TC(tp, ptrace__parent_wait_after_attach);
ATF_TP_ADD_TC(tp, ptrace__parent_sees_exit_after_child_debugger);
ATF_TP_ADD_TC(tp, ptrace__parent_sees_exit_after_unrelated_debugger);
ATF_TP_ADD_TC(tp, ptrace__parent_exits_before_child);
ATF_TP_ADD_TC(tp, ptrace__follow_fork_both_attached);
ATF_TP_ADD_TC(tp, ptrace__follow_fork_child_detached);
ATF_TP_ADD_TC(tp, ptrace__follow_fork_parent_detached);
ATF_TP_ADD_TC(tp, ptrace__follow_fork_both_attached_unrelated_debugger);
ATF_TP_ADD_TC(tp,
ptrace__follow_fork_child_detached_unrelated_debugger);
ATF_TP_ADD_TC(tp,
ptrace__follow_fork_parent_detached_unrelated_debugger);
ATF_TP_ADD_TC(tp, ptrace__getppid);
ATF_TP_ADD_TC(tp, ptrace__new_child_pl_syscall_code_fork);
ATF_TP_ADD_TC(tp, ptrace__new_child_pl_syscall_code_vfork);
ATF_TP_ADD_TC(tp, ptrace__new_child_pl_syscall_code_thread);
ATF_TP_ADD_TC(tp, ptrace__lwp_events);
ATF_TP_ADD_TC(tp, ptrace__lwp_events_exec);
ATF_TP_ADD_TC(tp, ptrace__siginfo);
ATF_TP_ADD_TC(tp, ptrace__ptrace_exec_disable);
ATF_TP_ADD_TC(tp, ptrace__ptrace_exec_enable);
ATF_TP_ADD_TC(tp, ptrace__event_mask);
ATF_TP_ADD_TC(tp, ptrace__ptrace_vfork);
ATF_TP_ADD_TC(tp, ptrace__ptrace_vfork_follow);
#ifdef HAVE_BREAKPOINT
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_breakpoint);
#endif
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_system_call);
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_threads);
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_competing_signal);
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_competing_stop);
ATF_TP_ADD_TC(tp, ptrace__PT_KILL_with_signal_full_sigqueue);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_system_call_entry);
ATF_TP_ADD_TC(tp,
ptrace__PT_CONTINUE_with_signal_system_call_entry_and_exit);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_full_sigqueue);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_masked_full_sigqueue);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_change_sig);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_sigtrap_system_call_entry);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_mix);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_kqueue);
ATF_TP_ADD_TC(tp, ptrace__killed_with_sigmask);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_sigmask);
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_with_signal_thread_sigmask);
ATF_TP_ADD_TC(tp, ptrace__PT_REGSET);
ATF_TP_ADD_TC(tp, ptrace__parent_terminate_with_pending_sigstop1);
ATF_TP_ADD_TC(tp, ptrace__parent_terminate_with_pending_sigstop2);
ATF_TP_ADD_TC(tp, ptrace__event_mask_sigkill_discard);
ATF_TP_ADD_TC(tp, ptrace__PT_ATTACH_with_SBDRY_thread);
ATF_TP_ADD_TC(tp, ptrace__PT_STEP_with_signal);
#ifdef HAVE_BREAKPOINT
ATF_TP_ADD_TC(tp, ptrace__breakpoint_siginfo);
#endif
ATF_TP_ADD_TC(tp, ptrace__step_siginfo);
#if defined(HAVE_BREAKPOINT) && defined(SKIP_BREAK)
ATF_TP_ADD_TC(tp, ptrace__PT_CONTINUE_different_thread);
#endif
ATF_TP_ADD_TC(tp, ptrace__PT_LWPINFO_stale_siginfo);
ATF_TP_ADD_TC(tp, ptrace__syscall_args);
ATF_TP_ADD_TC(tp, ptrace__proc_reparent);
ATF_TP_ADD_TC(tp, ptrace__procdesc_wait_child);
ATF_TP_ADD_TC(tp, ptrace__procdesc_reparent_wait_child);
return (atf_no_error());
}