This is xnu-11215.1.10. See this file in:
#include <darwintest.h>
#include <darwintest_utils.h>
#include <sys/kern_memorystatus.h>
#include <kern/debug.h>
#include <mach-o/dyld.h>
#include <sys/stackshot.h>
#include <kdd.h>
#include <signal.h>
#include "test_utils.h"
#define RECURSIONS 25
#define FIRST_RECURSIVE_FRAME 3
T_GLOBAL_META(
T_META_NAMESPACE("xnu.stackshot.accuracy"),
T_META_RADAR_COMPONENT_NAME("xnu"),
T_META_RADAR_COMPONENT_VERSION("stackshot"),
T_META_OWNER("jonathan_w_adams"),
T_META_CHECK_LEAKS(false),
T_META_ASROOT(true),
XNU_T_META_SOC_SPECIFIC
);
void child_init(void);
void parent_helper_singleproc(int);
#define CHECK_FOR_FAULT_STATS (1 << 0)
#define WRITE_STACKSHOT_BUFFER_TO_TMP (1 << 1)
#define CHECK_FOR_KERNEL_THREADS (1 << 2)
int check_stackshot(void *, int);
/* used for WRITE_STACKSHOT_BUFFER_TO_TMP */
static char const *current_scenario_name;
static pid_t child_pid;
/* helpers */
static void __attribute__((noinline))
child_recurse(int r, int spin, void (^cb)(void))
{
if (r > 0) {
child_recurse(r - 1, spin, cb);
}
cb();
/* wait forever */
if (spin == 0) {
sleep(100000);
} else if (spin == 2) {
int v = 1;
/* ssh won't let the session die if we still have file handles open to its output. */
close(STDERR_FILENO);
close(STDOUT_FILENO);
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.wedge_thread", NULL, NULL, &v, sizeof(v)),
"wedged thread in the kernel");
} else {
while (1) {
__asm__ volatile("" : : : "memory");
}
}
}
T_HELPER_DECL(simple_child_process, "child process that will be frozen and others")
{
child_init();
}
T_HELPER_DECL(sid_child_process, "child process that setsid()s")
{
pid_t ppid = getppid();
T_ASSERT_POSIX_SUCCESS(setsid(), "session id set");
child_recurse(RECURSIONS, 2, ^{
kill(ppid, SIGUSR1);
});
T_ASSERT_FAIL("child_init returned!");
}
static void
kill_children(void)
{
kill(child_pid, SIGKILL);
}
static void *
take_stackshot(pid_t target_pid, uint64_t extra_flags, uint64_t since_timestamp)
{
void *stackshot_config;
int err, retries = 5;
uint64_t stackshot_flags = STACKSHOT_KCDATA_FORMAT |
STACKSHOT_THREAD_WAITINFO |
STACKSHOT_GET_DQ;
/* we should be able to verify delta stackshots */
if (since_timestamp != 0) {
stackshot_flags |= STACKSHOT_COLLECT_DELTA_SNAPSHOT;
}
stackshot_flags |= extra_flags;
stackshot_config = stackshot_config_create();
T_ASSERT_NOTNULL(stackshot_config, "allocate stackshot config");
err = stackshot_config_set_flags(stackshot_config, stackshot_flags);
T_ASSERT_EQ(err, 0, "set flags on stackshot config");
err = stackshot_config_set_pid(stackshot_config, target_pid);
T_ASSERT_EQ(err, 0, "set target pid on stackshot config");
if (since_timestamp != 0) {
err = stackshot_config_set_delta_timestamp(stackshot_config, since_timestamp);
T_ASSERT_EQ(err, 0, "set prev snapshot time on stackshot config");
}
while (retries > 0) {
err = stackshot_capture_with_config(stackshot_config);
if (err == 0) {
break;
} else if (err == EBUSY || err == ETIMEDOUT) {
T_LOG("stackshot capture returned %d (%s)\n", err, strerror(err));
if (retries == 0) {
T_ASSERT_FAIL("failed to take stackshot with error after retries: %d: %s\n", err, strerror(err));
}
retries--;
continue;
} else {
T_ASSERT_FAIL("failed to take stackshot with error: %d: %s\n", err, strerror(err));
}
}
return stackshot_config;
}
int
check_stackshot(void *stackshot_config, int flags)
{
void *buf;
uint32_t buflen, kcdata_type;
kcdata_iter_t iter;
NSError *nserror = nil;
pid_t target_pid;
int ret = 0;
uint64_t expected_return_addr = 0;
bool found_fault_stats = false;
struct stackshot_fault_stats fault_stats = {0};
buf = stackshot_config_get_stackshot_buffer(stackshot_config);
T_ASSERT_NOTNULL(buf, "stackshot buffer is not null");
buflen = stackshot_config_get_stackshot_size(stackshot_config);
T_ASSERT_GT(buflen, 0, "valid stackshot buffer length");
target_pid = ((struct stackshot_config*)stackshot_config)->sc_pid;
T_ASSERT_GT(target_pid, 0, "valid target_pid");
/* if need to write it to fs, do it now */
if (flags & WRITE_STACKSHOT_BUFFER_TO_TMP) {
char sspath[MAXPATHLEN];
strlcpy(sspath, current_scenario_name, sizeof(sspath));
strlcat(sspath, ".kcdata", sizeof(sspath));
T_QUIET; T_ASSERT_POSIX_ZERO(dt_resultfile(sspath, sizeof(sspath)),
"create result file path");
FILE *f = fopen(sspath, "w");
T_WITH_ERRNO; T_QUIET; T_ASSERT_NOTNULL(f,
"open stackshot output file");
size_t written = fwrite(buf, buflen, 1, f);
T_QUIET; T_ASSERT_POSIX_SUCCESS(written, "wrote stackshot to file");
fclose(f);
}
/* begin iterating */
iter = kcdata_iter(buf, buflen);
T_ASSERT_EQ(kcdata_iter_type(iter), KCDATA_BUFFER_BEGIN_STACKSHOT, "buffer is a stackshot");
/* time to iterate */
iter = kcdata_iter_next(iter);
KCDATA_ITER_FOREACH(iter) {
kcdata_type = kcdata_iter_type(iter);
NSNumber *parsedPid;
NSMutableDictionary *parsedContainer, *parsedThreads;
if ((flags & CHECK_FOR_FAULT_STATS) != 0 &&
kcdata_type == STACKSHOT_KCTYPE_STACKSHOT_FAULT_STATS) {
memcpy(&fault_stats, kcdata_iter_payload(iter), sizeof(fault_stats));
found_fault_stats = true;
}
if (kcdata_type != KCDATA_TYPE_CONTAINER_BEGIN) {
continue;
}
if (kcdata_iter_container_type(iter) != STACKSHOT_KCCONTAINER_TASK) {
continue;
}
parsedContainer = parseKCDataContainer(&iter, &nserror);
T_ASSERT_NOTNULL(parsedContainer, "parsedContainer is not null");
T_ASSERT_NULL(nserror, "no NSError occured while parsing the kcdata container");
/*
* given that we've targetted the pid, we can be sure that this
* ts_pid will be the pid we expect
*/
parsedPid = parsedContainer[@"task_snapshots"][@"task_snapshot"][@"ts_pid"];
T_ASSERT_EQ([parsedPid intValue], target_pid, "found correct pid");
/* start parsing the threads */
parsedThreads = parsedContainer[@"task_snapshots"][@"thread_snapshots"];
for (id th_key in parsedThreads) {
uint32_t frame_index = 0;
if ((flags & CHECK_FOR_KERNEL_THREADS) == 0) {
/* skip threads that don't have enough frames */
if ([parsedThreads[th_key][@"user_stack_frames"] count] < RECURSIONS) {
continue;
}
for (id frame in parsedThreads[th_key][@"user_stack_frames"]) {
if ((frame_index >= FIRST_RECURSIVE_FRAME) && (frame_index < (RECURSIONS - FIRST_RECURSIVE_FRAME))) {
if (expected_return_addr == 0ull) {
expected_return_addr = [frame[@"lr"] unsignedLongLongValue];
} else {
T_QUIET;
T_ASSERT_EQ(expected_return_addr, [frame[@"lr"] unsignedLongLongValue], "expected return address found");
}
}
frame_index ++;
}
} else {
T_ASSERT_NOTNULL(parsedThreads[th_key][@"kernel_stack_frames"],
"found kernel stack frames");
}
}
}
if (found_fault_stats) {
T_LOG("number of pages faulted in: %d", fault_stats.sfs_pages_faulted_in);
T_LOG("MATUs spent faulting: %lld", fault_stats.sfs_time_spent_faulting);
T_LOG("MATUS fault time limit: %lld", fault_stats.sfs_system_max_fault_time);
T_LOG("did we stop because of the limit?: %s", fault_stats.sfs_stopped_faulting ? "yes" : "no");
if (expected_return_addr != 0ull) {
T_ASSERT_GT(fault_stats.sfs_pages_faulted_in, 0, "faulted at least one page in");
T_LOG("NOTE: successfully faulted in the pages");
} else {
T_LOG("NOTE: We were not able to fault the stack's pages back in");
/* if we couldn't fault the pages back in, then at least verify that we tried */
T_ASSERT_GT(fault_stats.sfs_time_spent_faulting, 0ull, "spent time trying to fault");
}
} else if ((flags & CHECK_FOR_KERNEL_THREADS) == 0) {
T_ASSERT_NE(expected_return_addr, 0ull, "found child thread with recursions");
}
if (flags & CHECK_FOR_FAULT_STATS) {
T_ASSERT_EQ(found_fault_stats, true, "found fault stats");
}
return ret;
}
void
child_init(void)
{
#if !TARGET_OS_OSX
int freeze_state;
#endif /* !TARGET_OS_OSX */
pid_t pid = getpid();
char padding[16 * 1024];
__asm__ volatile(""::"r"(padding));
T_LOG("child pid: %d\n", pid);
#if !TARGET_OS_OSX
/* allow us to be frozen */
freeze_state = memorystatus_control(MEMORYSTATUS_CMD_GET_PROCESS_IS_FREEZABLE, pid, 0, NULL, 0);
if (freeze_state == 0) {
T_LOG("CHILD was found to be UNFREEZABLE, enabling freezing.");
memorystatus_control(MEMORYSTATUS_CMD_SET_PROCESS_IS_FREEZABLE, pid, 1, NULL, 0);
freeze_state = memorystatus_control(MEMORYSTATUS_CMD_GET_PROCESS_IS_FREEZABLE, pid, 0, NULL, 0);
T_ASSERT_EQ(freeze_state, 1, "successfully set freezeability");
}
#else
T_LOG("Cannot change freezeability as freezing is only available on embedded devices");
#endif /* !TARGET_OS_OSX */
/*
* recurse a bunch of times to generate predictable data in the stackshot,
* then send SIGUSR1 to the parent to let it know that we are done.
*/
child_recurse(RECURSIONS, 0, ^{
kill(getppid(), SIGUSR1);
});
T_ASSERT_FAIL("child_recurse returned, but it must not?");
}
void
parent_helper_singleproc(int spin)
{
dispatch_semaphore_t child_done_sema = dispatch_semaphore_create(0);
dispatch_queue_t dq = dispatch_queue_create("com.apple.stackshot_accuracy.basic_sp", NULL);
void *stackshot_config;
dispatch_async(dq, ^{
char padding[16 * 1024];
__asm__ volatile(""::"r"(padding));
child_recurse(RECURSIONS, spin, ^{
dispatch_semaphore_signal(child_done_sema);
});
});
dispatch_semaphore_wait(child_done_sema, DISPATCH_TIME_FOREVER);
T_LOG("done waiting for child");
/* take the stackshot and parse it */
stackshot_config = take_stackshot(getpid(), 0, 0);
/* check that the stackshot has the stack frames */
check_stackshot(stackshot_config, 0);
T_LOG("done!");
}
T_DECL(basic, "test that no-fault stackshot works correctly", T_META_TAG_VM_PREFERRED)
{
char path[PATH_MAX];
uint32_t path_size = sizeof(path);
char *args[] = { path, "-n", "simple_child_process", NULL };
dispatch_queue_t dq = dispatch_queue_create("com.apple.stackshot_accuracy.basic", NULL);
dispatch_semaphore_t child_done_sema = dispatch_semaphore_create(0);
dispatch_source_t child_sig_src;
void *stackshot_config;
current_scenario_name = __func__;
T_LOG("parent pid: %d\n", getpid());
T_QUIET; T_ASSERT_POSIX_ZERO(_NSGetExecutablePath(path, &path_size), "_NSGetExecutablePath");
/* check if we can run the child successfully */
#if !TARGET_OS_OSX
int freeze_state = memorystatus_control(MEMORYSTATUS_CMD_GET_PROCESS_IS_FREEZABLE, getpid(), 0, NULL, 0);
if (freeze_state == -1) {
T_SKIP("This device doesn't have CONFIG_FREEZE enabled.");
}
#endif
/* setup signal handling */
signal(SIGUSR1, SIG_IGN);
child_sig_src = dispatch_source_create(DISPATCH_SOURCE_TYPE_SIGNAL, SIGUSR1, 0, dq);
dispatch_source_set_event_handler(child_sig_src, ^{
dispatch_semaphore_signal(child_done_sema);
});
dispatch_activate(child_sig_src);
/* create the child process */
T_ASSERT_POSIX_SUCCESS(dt_launch_tool(&child_pid, args, false, NULL, NULL), "child launched");
T_ATEND(kill_children);
/* wait until the child has recursed enough */
dispatch_semaphore_wait(child_done_sema, dispatch_time(DISPATCH_TIME_NOW, 10 /*seconds*/ * 1000000000ULL));
T_LOG("child finished, parent executing");
/* take the stackshot and parse it */
stackshot_config = take_stackshot(child_pid, 0, 0);
/* check that the stackshot has the stack frames */
check_stackshot(stackshot_config, 0);
T_LOG("all done, killing child");
/* tell the child to quit */
T_ASSERT_POSIX_SUCCESS(kill(child_pid, SIGTERM), "killed child");
}
T_DECL(basic_singleproc, "test that no-fault stackshot works correctly in single process setting", T_META_TAG_VM_PREFERRED)
{
current_scenario_name = __func__;
parent_helper_singleproc(0);
}
T_DECL(basic_singleproc_spin, "test that no-fault stackshot works correctly in single process setting with spinning", T_META_TAG_VM_PREFERRED)
{
current_scenario_name = __func__;
parent_helper_singleproc(1);
}
T_DECL(fault, "test that faulting stackshots work correctly", T_META_TAG_VM_PREFERRED)
{
dispatch_queue_t dq = dispatch_queue_create("com.apple.stackshot_fault_accuracy", NULL);
dispatch_source_t child_sig_src;
dispatch_semaphore_t child_done_sema = dispatch_semaphore_create(0);
void *stackshot_config;
int oldftm, newval = 1, freeze_enabled, oldratio, newratio = 0;
size_t oldlen = sizeof(oldftm), fe_len = sizeof(freeze_enabled), ratiolen = sizeof(oldratio);
char path[PATH_MAX];
uint32_t path_size = sizeof(path);
char *args[] = { path, "-n", "simple_child_process", NULL };
current_scenario_name = __func__;
T_QUIET; T_ASSERT_POSIX_ZERO(_NSGetExecutablePath(path, &path_size), "_NSGetExecutablePath");
#if TARGET_OS_OSX
T_SKIP("freezing is not available on macOS");
#endif /* TARGET_OS_OSX */
/* Try checking if freezing is enabled at all */
if (sysctlbyname("vm.freeze_enabled", &freeze_enabled, &fe_len, NULL, 0) == -1) {
if (errno == ENOENT) {
T_SKIP("This device doesn't have CONFIG_FREEZE enabled.");
} else {
T_FAIL("failed to query vm.freeze_enabled, errno: %d", errno);
}
}
if (!freeze_enabled) {
T_SKIP("Freeze is not enabled, skipping test.");
}
/* signal handling */
signal(SIGUSR1, SIG_IGN);
child_sig_src = dispatch_source_create(DISPATCH_SOURCE_TYPE_SIGNAL, SIGUSR1, 0, dq);
dispatch_source_set_event_handler(child_sig_src, ^{
dispatch_semaphore_signal(child_done_sema);
});
dispatch_activate(child_sig_src);
T_ASSERT_POSIX_SUCCESS(dt_launch_tool(&child_pid, args, false, NULL, NULL), "child launched");
T_ATEND(kill_children);
dispatch_semaphore_wait(child_done_sema, DISPATCH_TIME_FOREVER);
/* keep processes in memory */
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.memorystatus_freeze_to_memory", &oldftm, &oldlen, &newval, sizeof(newval)),
"disabled freezing to disk");
/* set the ratio to zero */
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.memorystatus_freeze_private_shared_pages_ratio", &oldratio, &ratiolen, &newratio, sizeof(newratio)), "disabled private:shared ratio checking");
/* freeze the child */
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.memorystatus_freeze", NULL, 0, &child_pid, sizeof(child_pid)),
"froze child");
/* Sleep to allow the compressor to finish compressing the child */
sleep(5);
/* take the stackshot and parse it */
stackshot_config = take_stackshot(child_pid, STACKSHOT_ENABLE_BT_FAULTING | STACKSHOT_ENABLE_UUID_FAULTING, 0);
/* check that the stackshot has the stack frames */
check_stackshot(stackshot_config, CHECK_FOR_FAULT_STATS);
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.memorystatus_freeze_to_memory", NULL, 0, &oldftm, sizeof(oldftm)),
"reset freezing to disk");
/* reset the private:shared ratio */
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.memorystatus_freeze_private_shared_pages_ratio", NULL, 0, &oldratio, sizeof(oldratio)), "reset private:shared ratio");
T_LOG("all done, killing child");
/* tell the child to quit */
T_ASSERT_POSIX_SUCCESS(kill(child_pid, SIGTERM), "killed child");
}
T_DECL(fault_singleproc, "test that faulting stackshots work correctly in a single process setting", T_META_TAG_VM_PREFERRED)
{
dispatch_semaphore_t child_done_sema = dispatch_semaphore_create(0);
dispatch_queue_t dq = dispatch_queue_create("com.apple.stackshot_accuracy.fault_sp", NULL);
void *stackshot_config;
__block pthread_t child_thread;
char *child_stack;
size_t child_stacklen;
#if !TARGET_OS_OSX
T_SKIP("madvise(..., ..., MADV_PAGEOUT) is not available on embedded platforms");
#endif /* !TARGET_OS_OSX */
dispatch_async(dq, ^{
char padding[16 * 1024];
__asm__ volatile(""::"r"(padding));
child_recurse(RECURSIONS, 0, ^{
child_thread = pthread_self();
dispatch_semaphore_signal(child_done_sema);
});
});
dispatch_semaphore_wait(child_done_sema, DISPATCH_TIME_FOREVER);
T_LOG("done waiting for child");
child_stack = pthread_get_stackaddr_np(child_thread);
child_stacklen = pthread_get_stacksize_np(child_thread);
child_stack -= child_stacklen;
T_LOG("child stack: [0x%p - 0x%p]: 0x%zu bytes", (void *)child_stack,
(void *)(child_stack + child_stacklen), child_stacklen);
/* paging out the child */
T_ASSERT_POSIX_SUCCESS(madvise(child_stack, child_stacklen, MADV_PAGEOUT), "paged out via madvise(2) the child stack");
/* take the stackshot and parse it */
stackshot_config = take_stackshot(getpid(), STACKSHOT_ENABLE_BT_FAULTING | STACKSHOT_ENABLE_UUID_FAULTING, 0);
/* check that the stackshot has the stack frames */
check_stackshot(stackshot_config, CHECK_FOR_FAULT_STATS);
T_LOG("done!");
}
T_DECL(zombie, "test that threads wedged in the kernel can be stackshot'd", T_META_TAG_VM_PREFERRED)
{
dispatch_queue_t dq = dispatch_queue_create("com.apple.stackshot_accuracy.zombie", NULL);
dispatch_semaphore_t child_done_sema = dispatch_semaphore_create(0);
dispatch_source_t child_sig_src;
void *stackshot_config;
char path[PATH_MAX];
uint32_t path_size = sizeof(path);
char *args[] = { path, "-n", "sid_child_process", NULL };
current_scenario_name = __func__;
T_QUIET; T_ASSERT_POSIX_ZERO(_NSGetExecutablePath(path, &path_size), "_NSGetExecutablePath");
T_LOG("parent pid: %d\n", getpid());
/* setup signal handling */
signal(SIGUSR1, SIG_IGN);
child_sig_src = dispatch_source_create(DISPATCH_SOURCE_TYPE_SIGNAL, SIGUSR1, 0, dq);
dispatch_source_set_event_handler(child_sig_src, ^{
dispatch_semaphore_signal(child_done_sema);
});
dispatch_activate(child_sig_src);
/* create the child process */
T_ASSERT_POSIX_SUCCESS(dt_launch_tool(&child_pid, args, false, NULL, NULL), "child launched");
T_ATEND(kill_children);
/* wait until the child has recursed enough */
dispatch_semaphore_wait(child_done_sema, DISPATCH_TIME_FOREVER);
T_LOG("child finished, parent executing. invoking jetsam");
T_ASSERT_POSIX_SUCCESS(memorystatus_control(MEMORYSTATUS_CMD_TEST_JETSAM, child_pid, 0, 0, 0),
"jetsam'd the child");
/* Sleep to allow the target process to become zombified */
sleep(1);
/* take the stackshot and parse it */
stackshot_config = take_stackshot(child_pid, 0, 0);
/* check that the stackshot has the stack frames */
check_stackshot(stackshot_config, CHECK_FOR_KERNEL_THREADS);
T_LOG("all done, unwedging and killing child");
int v = 1;
T_ASSERT_POSIX_SUCCESS(sysctlbyname("kern.unwedge_thread", NULL, NULL, &v, sizeof(v)),
"unwedged child");
/* tell the child to quit */
T_ASSERT_POSIX_SUCCESS(kill(child_pid, SIGTERM), "killed child");
}