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platform_system_core/llkd/libllkd.cpp
Suren Baghdasaryan 2b92541e7f llkd: Disable in userdebug builds by default 
While llkd helps in discovering issues in apps which leave zombies, it
creates issues for dogfooders when apps are killed. Disable it by
default.

Bug: 202411543
Test: boot and check llkd not running
Test: `setprop ro.llk.enable true` enables llkd
Signed-off-by: Suren Baghdasaryan <surenb@google.com>
Change-Id: If93bf9e981eaa3921a9da5f3160db26c4fe17e66
2021-11-04 16:21:46 -07:00

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/*
* Copyright (C) 2018 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "llkd.h"
#include <ctype.h>
#include <dirent.h> // opendir() and readdir()
#include <errno.h>
#include <fcntl.h>
#include <pthread.h>
#include <pwd.h> // getpwuid()
#include <signal.h>
#include <stdint.h>
#include <string.h>
#include <sys/cdefs.h> // ___STRING, __predict_true() and _predict_false()
#include <sys/mman.h> // mlockall()
#include <sys/prctl.h>
#include <sys/stat.h> // lstat()
#include <sys/syscall.h> // __NR_getdents64
#include <sys/sysinfo.h> // get_nprocs_conf()
#include <sys/types.h>
#include <time.h>
#include <unistd.h>
#include <chrono>
#include <ios>
#include <sstream>
#include <string>
#include <unordered_map>
#include <unordered_set>
#include <vector>
#include <android-base/file.h>
#include <android-base/logging.h>
#include <android-base/parseint.h>
#include <android-base/properties.h>
#include <android-base/strings.h>
#include <cutils/android_get_control_file.h>
#include <log/log_main.h>
#define ARRAY_SIZE(x) (sizeof(x) / sizeof(*(x)))
#define TASK_COMM_LEN 16 // internal kernel, not uapi, from .../linux/include/linux/sched.h
using namespace std::chrono_literals;
using namespace std::chrono;
using namespace std::literals;
namespace {
constexpr pid_t kernelPid = 0;
constexpr pid_t initPid = 1;
constexpr pid_t kthreaddPid = 2;
constexpr char procdir[] = "/proc/";
// Configuration
milliseconds llkUpdate; // last check ms signature
milliseconds llkCycle; // ms to next thread check
bool llkEnable = LLK_ENABLE_DEFAULT; // llk daemon enabled
bool llkRunning = false; // thread is running
bool llkMlockall = LLK_MLOCKALL_DEFAULT; // run mlocked
bool llkTestWithKill = LLK_KILLTEST_DEFAULT; // issue test kills
milliseconds llkTimeoutMs = LLK_TIMEOUT_MS_DEFAULT; // default timeout
enum { // enum of state indexes
llkStateD, // Persistent 'D' state
llkStateZ, // Persistent 'Z' state
#ifdef __PTRACE_ENABLED__ // Extra privileged states
llkStateStack, // stack signature
#endif // End of extra privilege
llkNumStates, // Maxumum number of states
}; // state indexes
milliseconds llkStateTimeoutMs[llkNumStates]; // timeout override for each detection state
milliseconds llkCheckMs; // checking interval to inspect any
// persistent live-locked states
bool llkLowRam; // ro.config.low_ram
bool llkEnableSysrqT = LLK_ENABLE_SYSRQ_T_DEFAULT; // sysrq stack trace dump
bool khtEnable = LLK_ENABLE_DEFAULT; // [khungtaskd] panic
// [khungtaskd] should have a timeout beyond the granularity of llkTimeoutMs.
// Provides a wide angle of margin b/c khtTimeout is also its granularity.
seconds khtTimeout = duration_cast<seconds>(llkTimeoutMs * (1 + LLK_CHECKS_PER_TIMEOUT_DEFAULT) /
LLK_CHECKS_PER_TIMEOUT_DEFAULT);
#ifdef __PTRACE_ENABLED__
// list of stack symbols to search for persistence.
std::unordered_set<std::string> llkCheckStackSymbols;
#endif
// Ignorelist variables, initialized with comma separated lists of high false
// positive and/or dangerous references, e.g. without self restart, for pid,
// ppid, name and uid:
// list of pids, or tids or names to skip. kernel pid (0), init pid (1),
// [kthreadd] pid (2), ourselves, "init", "[kthreadd]", "lmkd", "llkd" or
// combinations of watchdogd in kernel and user space.
std::unordered_set<std::string> llkIgnorelistProcess;
// list of parent pids, comm or cmdline names to skip. default:
// kernel pid (0), [kthreadd] (2), or ourselves, enforced and implied
std::unordered_set<std::string> llkIgnorelistParent;
// list of parent and target processes to skip. default:
// adbd *and* [setsid]
std::unordered_map<std::string, std::unordered_set<std::string>> llkIgnorelistParentAndChild;
// list of uids, and uid names, to skip, default nothing
std::unordered_set<std::string> llkIgnorelistUid;
#ifdef __PTRACE_ENABLED__
// list of names to skip stack checking. "init", "lmkd", "llkd", "keystore",
// "keystore2", or "logd" (if not userdebug).
std::unordered_set<std::string> llkIgnorelistStack;
#endif
class dir {
public:
enum level { proc, task, numLevels };
private:
int fd;
size_t available_bytes;
dirent* next;
// each directory level picked to be just north of 4K in size
static constexpr size_t buffEntries = 15;
static dirent buff[numLevels][buffEntries];
bool fill(enum level index) {
if (index >= numLevels) return false;
if (available_bytes != 0) return true;
if (__predict_false(fd < 0)) return false;
// getdents64 has no libc wrapper
auto rc = TEMP_FAILURE_RETRY(syscall(__NR_getdents64, fd, buff[index], sizeof(buff[0]), 0));
if (rc <= 0) return false;
available_bytes = rc;
next = buff[index];
return true;
}
public:
dir() : fd(-1), available_bytes(0), next(nullptr) {}
explicit dir(const char* directory)
: fd(__predict_true(directory != nullptr)
? ::open(directory, O_CLOEXEC | O_DIRECTORY | O_RDONLY)
: -1),
available_bytes(0),
next(nullptr) {}
explicit dir(const std::string&& directory)
: fd(::open(directory.c_str(), O_CLOEXEC | O_DIRECTORY | O_RDONLY)),
available_bytes(0),
next(nullptr) {}
explicit dir(const std::string& directory)
: fd(::open(directory.c_str(), O_CLOEXEC | O_DIRECTORY | O_RDONLY)),
available_bytes(0),
next(nullptr) {}
// Don't need any copy or move constructors.
explicit dir(const dir& c) = delete;
explicit dir(dir& c) = delete;
explicit dir(dir&& c) = delete;
~dir() {
if (fd >= 0) {
::close(fd);
}
}
operator bool() const { return fd >= 0; }
void reset(void) {
if (fd >= 0) {
::close(fd);
fd = -1;
available_bytes = 0;
next = nullptr;
}
}
dir& reset(const char* directory) {
reset();
// available_bytes will _always_ be zero here as its value is
// intimately tied to fd < 0 or not.
fd = ::open(directory, O_CLOEXEC | O_DIRECTORY | O_RDONLY);
return *this;
}
void rewind(void) {
if (fd >= 0) {
::lseek(fd, off_t(0), SEEK_SET);
available_bytes = 0;
next = nullptr;
}
}
dirent* read(enum level index = proc, dirent* def = nullptr) {
if (!fill(index)) return def;
auto ret = next;
available_bytes -= next->d_reclen;
next = reinterpret_cast<dirent*>(reinterpret_cast<char*>(next) + next->d_reclen);
return ret;
}
} llkTopDirectory;
dirent dir::buff[dir::numLevels][dir::buffEntries];
// helper functions
bool llkIsMissingExeLink(pid_t tid) {
char c;
// CAP_SYS_PTRACE is required to prevent ret == -1, but ENOENT is signal
auto ret = ::readlink((procdir + std::to_string(tid) + "/exe").c_str(), &c, sizeof(c));
return (ret == -1) && (errno == ENOENT);
}
// Common routine where caller accepts empty content as error/passthrough.
// Reduces the churn of reporting read errors in the callers.
std::string ReadFile(std::string&& path) {
std::string content;
if (!android::base::ReadFileToString(path, &content)) {
PLOG(DEBUG) << "Read " << path << " failed";
content = "";
}
return content;
}
std::string llkProcGetName(pid_t tid, const char* node = "/cmdline") {
std::string content = ReadFile(procdir + std::to_string(tid) + node);
static constexpr char needles[] = " \t\r\n"; // including trailing nul
auto pos = content.find_first_of(needles, 0, sizeof(needles));
if (pos != std::string::npos) {
content.erase(pos);
}
return content;
}
uid_t llkProcGetUid(pid_t tid) {
// Get the process' uid. The following read from /status is admittedly
// racy, prone to corruption due to shape-changes. The consequences are
// not catastrophic as we sample a few times before taking action.
//
// If /loginuid worked on reliably, or on Android (all tasks report -1)...
// Android lmkd causes /cgroup to contain memory:/<dom>/uid_<uid>/pid_<pid>
// which is tighter, but also not reliable.
std::string content = ReadFile(procdir + std::to_string(tid) + "/status");
static constexpr char Uid[] = "\nUid:";
auto pos = content.find(Uid);
if (pos == std::string::npos) {
return -1;
}
pos += ::strlen(Uid);
while ((pos < content.size()) && ::isblank(content[pos])) {
++pos;
}
content.erase(0, pos);
for (pos = 0; (pos < content.size()) && ::isdigit(content[pos]); ++pos) {
;
}
// Content of form 'Uid: 0 0 0 0', newline is error
if ((pos >= content.size()) || !::isblank(content[pos])) {
return -1;
}
content.erase(pos);
uid_t ret;
if (!android::base::ParseUint(content, &ret, uid_t(0))) {
return -1;
}
return ret;
}
struct proc {
pid_t tid; // monitored thread id (in Z or D state).
nanoseconds schedUpdate; // /proc/<tid>/sched "se.avg.lastUpdateTime",
uint64_t nrSwitches; // /proc/<tid>/sched "nr_switches" for
// refined ABA problem detection, determine
// forward scheduling progress.
milliseconds update; // llkUpdate millisecond signature of last.
milliseconds count; // duration in state.
#ifdef __PTRACE_ENABLED__ // Privileged state checking
milliseconds count_stack; // duration where stack is stagnant.
#endif // End privilege
pid_t pid; // /proc/<pid> before iterating through
// /proc/<pid>/task/<tid> for threads.
pid_t ppid; // /proc/<tid>/stat field 4 parent pid.
uid_t uid; // /proc/<tid>/status Uid: field.
unsigned time; // sum of /proc/<tid>/stat field 14 utime &
// 15 stime for coarse ABA problem detection.
std::string cmdline; // cached /cmdline content
char state; // /proc/<tid>/stat field 3: Z or D
// (others we do not monitor: S, R, T or ?)
#ifdef __PTRACE_ENABLED__ // Privileged state checking
char stack; // index in llkCheckStackSymbols for matches
#endif // and with maximum index PROP_VALUE_MAX/2.
char comm[TASK_COMM_LEN + 3]; // space for adding '[' and ']'
bool exeMissingValid; // exeMissing has been cached
bool cmdlineValid; // cmdline has been cached
bool updated; // cleared before monitoring pass.
bool killed; // sent a kill to this thread, next panic...
bool frozen; // process is in frozen cgroup.
void setComm(const char* _comm) { strncpy(comm + 1, _comm, sizeof(comm) - 2); }
void setFrozen(bool _frozen) { frozen = _frozen; }
proc(pid_t tid, pid_t pid, pid_t ppid, const char* _comm, int time, char state, bool frozen)
: tid(tid),
schedUpdate(0),
nrSwitches(0),
update(llkUpdate),
count(0ms),
#ifdef __PTRACE_ENABLED__
count_stack(0ms),
#endif
pid(pid),
ppid(ppid),
uid(-1),
time(time),
state(state),
#ifdef __PTRACE_ENABLED__
stack(-1),
#endif
exeMissingValid(false),
cmdlineValid(false),
updated(true),
killed(!llkTestWithKill),
frozen(frozen) {
memset(comm, '\0', sizeof(comm));
setComm(_comm);
}
const char* getComm(void) {
if (comm[1] == '\0') { // comm Valid?
strncpy(comm + 1, llkProcGetName(tid, "/comm").c_str(), sizeof(comm) - 2);
}
if (!exeMissingValid) {
if (llkIsMissingExeLink(tid)) {
comm[0] = '[';
}
exeMissingValid = true;
}
size_t len = strlen(comm + 1);
if (__predict_true(len < (sizeof(comm) - 1))) {
if (comm[0] == '[') {
if ((comm[len] != ']') && __predict_true(len < (sizeof(comm) - 2))) {
comm[++len] = ']';
comm[++len] = '\0';
}
} else {
if (comm[len] == ']') {
comm[len] = '\0';
}
}
}
return &comm[comm[0] != '['];
}
const char* getCmdline(void) {
if (!cmdlineValid) {
cmdline = llkProcGetName(tid);
cmdlineValid = true;
}
return cmdline.c_str();
}
uid_t getUid(void) {
if (uid <= 0) { // Churn on root user, because most likely to setuid()
uid = llkProcGetUid(tid);
}
return uid;
}
bool isFrozen() { return frozen; }
void reset(void) { // reset cache, if we detected pid rollover
uid = -1;
state = '?';
#ifdef __PTRACE_ENABLED__
count_stack = 0ms;
stack = -1;
#endif
cmdline = "";
comm[0] = '\0';
exeMissingValid = false;
cmdlineValid = false;
}
};
std::unordered_map<pid_t, proc> tids;
// Check range and setup defaults, in order of propagation:
// llkTimeoutMs
// llkCheckMs
// ...
// KISS to keep it all self-contained, and called multiple times as parameters
// are interpreted so that defaults, llkCheckMs and llkCycle make sense.
void llkValidate() {
if (llkTimeoutMs == 0ms) {
llkTimeoutMs = LLK_TIMEOUT_MS_DEFAULT;
}
llkTimeoutMs = std::max(llkTimeoutMs, LLK_TIMEOUT_MS_MINIMUM);
if (llkCheckMs == 0ms) {
llkCheckMs = llkTimeoutMs / LLK_CHECKS_PER_TIMEOUT_DEFAULT;
}
llkCheckMs = std::min(llkCheckMs, llkTimeoutMs);
for (size_t state = 0; state < ARRAY_SIZE(llkStateTimeoutMs); ++state) {
if (llkStateTimeoutMs[state] == 0ms) {
llkStateTimeoutMs[state] = llkTimeoutMs;
}
llkStateTimeoutMs[state] =
std::min(std::max(llkStateTimeoutMs[state], LLK_TIMEOUT_MS_MINIMUM), llkTimeoutMs);
llkCheckMs = std::min(llkCheckMs, llkStateTimeoutMs[state]);
}
llkCheckMs = std::max(llkCheckMs, LLK_CHECK_MS_MINIMUM);
if (llkCycle == 0ms) {
llkCycle = llkCheckMs;
}
llkCycle = std::min(llkCycle, llkCheckMs);
}
milliseconds llkGetTimespecDiffMs(timespec* from, timespec* to) {
return duration_cast<milliseconds>(seconds(to->tv_sec - from->tv_sec)) +
duration_cast<milliseconds>(nanoseconds(to->tv_nsec - from->tv_nsec));
}
std::string llkProcGetName(pid_t tid, const char* comm, const char* cmdline) {
if ((cmdline != nullptr) && (*cmdline != '\0')) {
return cmdline;
}
if ((comm != nullptr) && (*comm != '\0')) {
return comm;
}
// UNLIKELY! Here because killed before we kill it?
// Assume change is afoot, do not call llkTidAlloc
// cmdline ?
std::string content = llkProcGetName(tid);
if (content.size() != 0) {
return content;
}
// Comm instead?
content = llkProcGetName(tid, "/comm");
if (llkIsMissingExeLink(tid) && (content.size() != 0)) {
return '[' + content + ']';
}
return content;
}
int llkKillOneProcess(pid_t pid, char state, pid_t tid, const char* tcomm = nullptr,
const char* tcmdline = nullptr, const char* pcomm = nullptr,
const char* pcmdline = nullptr) {
std::string forTid;
if (tid != pid) {
forTid = " for '" + llkProcGetName(tid, tcomm, tcmdline) + "' (" + std::to_string(tid) + ")";
}
LOG(INFO) << "Killing '" << llkProcGetName(pid, pcomm, pcmdline) << "' (" << pid
<< ") to check forward scheduling progress in " << state << " state" << forTid;
// CAP_KILL required
errno = 0;
auto r = ::kill(pid, SIGKILL);
if (r) {
PLOG(ERROR) << "kill(" << pid << ")=" << r << ' ';
}
return r;
}
// Kill one process
int llkKillOneProcess(pid_t pid, proc* tprocp) {
return llkKillOneProcess(pid, tprocp->state, tprocp->tid, tprocp->getComm(),
tprocp->getCmdline());
}
// Kill one process specified by kprocp
int llkKillOneProcess(proc* kprocp, proc* tprocp) {
if (kprocp == nullptr) {
return -2;
}
return llkKillOneProcess(kprocp->tid, tprocp->state, tprocp->tid, tprocp->getComm(),
tprocp->getCmdline(), kprocp->getComm(), kprocp->getCmdline());
}
// Acquire file descriptor from environment, or open and cache it.
// NB: cache is unnecessary in our current context, pedantically
// required to prevent leakage of file descriptors in the future.
int llkFileToWriteFd(const std::string& file) {
static std::unordered_map<std::string, int> cache;
auto search = cache.find(file);
if (search != cache.end()) return search->second;
auto fd = android_get_control_file(file.c_str());
if (fd >= 0) return fd;
fd = TEMP_FAILURE_RETRY(::open(file.c_str(), O_WRONLY | O_CLOEXEC));
if (fd >= 0) cache.emplace(std::make_pair(file, fd));
return fd;
}
// Wrap android::base::WriteStringToFile to use android_get_control_file.
bool llkWriteStringToFile(const std::string& string, const std::string& file) {
auto fd = llkFileToWriteFd(file);
if (fd < 0) return false;
return android::base::WriteStringToFd(string, fd);
}
bool llkWriteStringToFileConfirm(const std::string& string, const std::string& file) {
auto fd = llkFileToWriteFd(file);
auto ret = (fd < 0) ? false : android::base::WriteStringToFd(string, fd);
std::string content;
if (!android::base::ReadFileToString(file, &content)) return ret;
return android::base::Trim(content) == string;
}
void llkPanicKernel(bool dump, pid_t tid, const char* state, const std::string& message = "") {
if (!message.empty()) LOG(ERROR) << message;
auto sysrqTriggerFd = llkFileToWriteFd("/proc/sysrq-trigger");
if (sysrqTriggerFd < 0) {
// DYB
llkKillOneProcess(initPid, 'R', tid);
// The answer to life, the universe and everything
::exit(42);
// NOTREACHED
return;
}
// Wish could ::sync() here, if storage is locked up, we will not continue.
if (dump) {
// Show all locks that are held
android::base::WriteStringToFd("d", sysrqTriggerFd);
// Show all waiting tasks
android::base::WriteStringToFd("w", sysrqTriggerFd);
// This can trigger hardware watchdog, that is somewhat _ok_.
// But useless if pstore configured for <256KB, low ram devices ...
if (llkEnableSysrqT) {
android::base::WriteStringToFd("t", sysrqTriggerFd);
// Show all locks that are held (in case 't' overflows ramoops)
android::base::WriteStringToFd("d", sysrqTriggerFd);
// Show all waiting tasks (in case 't' overflows ramoops)
android::base::WriteStringToFd("w", sysrqTriggerFd);
}
::usleep(200000); // let everything settle
}
// SysRq message matches kernel format, and propagates through bootstat
// ultimately to the boot reason into panic,livelock,<state>.
llkWriteStringToFile(message + (message.empty() ? "" : "\n") +
"SysRq : Trigger a crash : 'livelock,"s + state + "'\n",
"/dev/kmsg");
// Because panic is such a serious thing to do, let us
// make sure that the tid being inspected still exists!
auto piddir = procdir + std::to_string(tid) + "/stat";
if (access(piddir.c_str(), F_OK) != 0) {
PLOG(WARNING) << piddir;
return;
}
android::base::WriteStringToFd("c", sysrqTriggerFd);
// NOTREACHED
// DYB
llkKillOneProcess(initPid, 'R', tid);
// I sat at my desk, stared into the garden and thought '42 will do'.
// I typed it out. End of story
::exit(42);
// NOTREACHED
}
void llkAlarmHandler(int) {
LOG(FATAL) << "alarm";
// NOTREACHED
llkPanicKernel(true, ::getpid(), "alarm");
}
milliseconds GetUintProperty(const std::string& key, milliseconds def) {
return milliseconds(android::base::GetUintProperty(key, static_cast<uint64_t>(def.count()),
static_cast<uint64_t>(def.max().count())));
}
seconds GetUintProperty(const std::string& key, seconds def) {
return seconds(android::base::GetUintProperty(key, static_cast<uint64_t>(def.count()),
static_cast<uint64_t>(def.max().count())));
}
proc* llkTidLookup(pid_t tid) {
auto search = tids.find(tid);
if (search == tids.end()) {
return nullptr;
}
return &search->second;
}
void llkTidRemove(pid_t tid) {
tids.erase(tid);
}
proc* llkTidAlloc(pid_t tid, pid_t pid, pid_t ppid, const char* comm, int time, char state,
bool frozen) {
auto it = tids.emplace(std::make_pair(tid, proc(tid, pid, ppid, comm, time, state, frozen)));
return &it.first->second;
}
std::string llkFormat(milliseconds ms) {
auto sec = duration_cast<seconds>(ms);
std::ostringstream s;
s << sec.count() << '.';
auto f = s.fill('0');
auto w = s.width(3);
s << std::right << (ms - sec).count();
s.width(w);
s.fill(f);
s << 's';
return s.str();
}
std::string llkFormat(seconds s) {
return std::to_string(s.count()) + 's';
}
std::string llkFormat(bool flag) {
return flag ? "true" : "false";
}
std::string llkFormat(const std::unordered_set<std::string>& ignorelist) {
std::string ret;
for (const auto& entry : ignorelist) {
if (!ret.empty()) ret += ",";
ret += entry;
}
return ret;
}
std::string llkFormat(
const std::unordered_map<std::string, std::unordered_set<std::string>>& ignorelist,
bool leading_comma = false) {
std::string ret;
for (const auto& entry : ignorelist) {
for (const auto& target : entry.second) {
if (leading_comma || !ret.empty()) ret += ",";
ret += entry.first + "&" + target;
}
}
return ret;
}
// This function parses the properties as a list, incorporating the supplied
// default. A leading comma separator means preserve the defaults and add
// entries (with an optional leading + sign), or removes entries with a leading
// - sign.
//
// We only officially support comma separators, but wetware being what they
// are will take some liberty and I do not believe they should be punished.
std::unordered_set<std::string> llkSplit(const std::string& prop, const std::string& def) {
auto s = android::base::GetProperty(prop, def);
constexpr char separators[] = ", \t:;";
if (!s.empty() && (s != def) && strchr(separators, s[0])) s = def + s;
std::unordered_set<std::string> result;
// Special case, allow boolean false to empty the list, otherwise expected
// source of input from android::base::GetProperty will supply the default
// value on empty content in the property.
if (s == "false") return result;
size_t base = 0;
while (s.size() > base) {
auto found = s.find_first_of(separators, base);
// Only emplace unique content, empty entries are not an option
if (found != base) {
switch (s[base]) {
case '-':
++base;
if (base >= s.size()) break;
if (base != found) {
auto have = result.find(s.substr(base, found - base));
if (have != result.end()) result.erase(have);
}
break;
case '+':
++base;
if (base >= s.size()) break;
if (base == found) break;
// FALLTHRU (for gcc, lint, pcc, etc; following for clang)
FALLTHROUGH_INTENDED;
default:
result.emplace(s.substr(base, found - base));
break;
}
}
if (found == s.npos) break;
base = found + 1;
}
return result;
}
bool llkSkipName(const std::string& name,
const std::unordered_set<std::string>& ignorelist = llkIgnorelistProcess) {
if (name.empty() || ignorelist.empty()) return false;
return ignorelist.find(name) != ignorelist.end();
}
bool llkSkipProc(proc* procp,
const std::unordered_set<std::string>& ignorelist = llkIgnorelistProcess) {
if (!procp) return false;
if (llkSkipName(std::to_string(procp->pid), ignorelist)) return true;
if (llkSkipName(procp->getComm(), ignorelist)) return true;
if (llkSkipName(procp->getCmdline(), ignorelist)) return true;
if (llkSkipName(android::base::Basename(procp->getCmdline()), ignorelist)) return true;
return false;
}
const std::unordered_set<std::string>& llkSkipName(
const std::string& name,
const std::unordered_map<std::string, std::unordered_set<std::string>>& ignorelist) {
static const std::unordered_set<std::string> empty;
if (name.empty() || ignorelist.empty()) return empty;
auto found = ignorelist.find(name);
if (found == ignorelist.end()) return empty;
return found->second;
}
bool llkSkipPproc(proc* pprocp, proc* procp,
const std::unordered_map<std::string, std::unordered_set<std::string>>&
ignorelist = llkIgnorelistParentAndChild) {
if (!pprocp || !procp || ignorelist.empty()) return false;
if (llkSkipProc(procp, llkSkipName(std::to_string(pprocp->pid), ignorelist))) return true;
if (llkSkipProc(procp, llkSkipName(pprocp->getComm(), ignorelist))) return true;
if (llkSkipProc(procp, llkSkipName(pprocp->getCmdline(), ignorelist))) return true;
return llkSkipProc(procp,
llkSkipName(android::base::Basename(pprocp->getCmdline()), ignorelist));
}
bool llkSkipPid(pid_t pid) {
return llkSkipName(std::to_string(pid), llkIgnorelistProcess);
}
bool llkSkipPpid(pid_t ppid) {
return llkSkipName(std::to_string(ppid), llkIgnorelistParent);
}
bool llkSkipUid(uid_t uid) {
// Match by number?
if (llkSkipName(std::to_string(uid), llkIgnorelistUid)) {
return true;
}
// Match by name?
auto pwd = ::getpwuid(uid);
return (pwd != nullptr) && __predict_true(pwd->pw_name != nullptr) &&
__predict_true(pwd->pw_name[0] != '\0') && llkSkipName(pwd->pw_name, llkIgnorelistUid);
}
bool getValidTidDir(dirent* dp, std::string* piddir) {
if (!::isdigit(dp->d_name[0])) {
return false;
}
// Corner case can not happen in reality b/c of above ::isdigit check
if (__predict_false(dp->d_type != DT_DIR)) {
if (__predict_false(dp->d_type == DT_UNKNOWN)) { // can't b/c procfs
struct stat st;
*piddir = procdir;
*piddir += dp->d_name;
return (lstat(piddir->c_str(), &st) == 0) && (st.st_mode & S_IFDIR);
}
return false;
}
*piddir = procdir;
*piddir += dp->d_name;
return true;
}
bool llkIsMonitorState(char state) {
return (state == 'Z') || (state == 'D');
}
// returns -1 if not found
long long getSchedValue(const std::string& schedString, const char* key) {
auto pos = schedString.find(key);
if (pos == std::string::npos) {
return -1;
}
pos = schedString.find(':', pos);
if (__predict_false(pos == std::string::npos)) {
return -1;
}
while ((++pos < schedString.size()) && ::isblank(schedString[pos])) {
;
}
long long ret;
if (!android::base::ParseInt(schedString.substr(pos), &ret, static_cast<long long>(0))) {
return -1;
}
return ret;
}
#ifdef __PTRACE_ENABLED__
bool llkCheckStack(proc* procp, const std::string& piddir) {
if (llkCheckStackSymbols.empty()) return false;
if (procp->state == 'Z') { // No brains for Zombies
procp->stack = -1;
procp->count_stack = 0ms;
return false;
}
// Don't check process that are known to block ptrace, save sepolicy noise.
if (llkSkipProc(procp, llkIgnorelistStack)) return false;
auto kernel_stack = ReadFile(piddir + "/stack");
if (kernel_stack.empty()) {
LOG(VERBOSE) << piddir << "/stack empty comm=" << procp->getComm()
<< " cmdline=" << procp->getCmdline();
return false;
}
// A scheduling incident that should not reset count_stack
if (kernel_stack.find(" cpu_worker_pools+0x") != std::string::npos) return false;
char idx = -1;
char match = -1;
std::string matched_stack_symbol = "<unknown>";
for (const auto& stack : llkCheckStackSymbols) {
if (++idx < 0) break;
if ((kernel_stack.find(" "s + stack + "+0x") != std::string::npos) ||
(kernel_stack.find(" "s + stack + ".cfi+0x") != std::string::npos)) {
match = idx;
matched_stack_symbol = stack;
break;
}
}
if (procp->stack != match) {
procp->stack = match;
procp->count_stack = 0ms;
return false;
}
if (match == char(-1)) return false;
procp->count_stack += llkCycle;
if (procp->count_stack < llkStateTimeoutMs[llkStateStack]) return false;
LOG(WARNING) << "Found " << matched_stack_symbol << " in stack for pid " << procp->pid;
return true;
}
#endif
// Primary ABA mitigation watching last time schedule activity happened
void llkCheckSchedUpdate(proc* procp, const std::string& piddir) {
// Audit finds /proc/<tid>/sched is just over 1K, and
// is rarely larger than 2K, even less on Android.
// For example, the "se.avg.lastUpdateTime" field we are
// interested in typically within the primary set in
// the first 1K.
//
// Proc entries can not be read >1K atomically via libbase,
// but if there are problems we assume at least a few
// samples of reads occur before we take any real action.
std::string schedString = ReadFile(piddir + "/sched");
if (schedString.empty()) {
// /schedstat is not as standardized, but in 3.1+
// Android devices, the third field is nr_switches
// from /sched:
schedString = ReadFile(piddir + "/schedstat");
if (schedString.empty()) {
return;
}
auto val = static_cast<unsigned long long>(-1);
if (((::sscanf(schedString.c_str(), "%*d %*d %llu", &val)) == 1) &&
(val != static_cast<unsigned long long>(-1)) && (val != 0) &&
(val != procp->nrSwitches)) {
procp->nrSwitches = val;
procp->count = 0ms;
procp->killed = !llkTestWithKill;
}
return;
}
auto val = getSchedValue(schedString, "\nse.avg.lastUpdateTime");
if (val == -1) {
val = getSchedValue(schedString, "\nse.svg.last_update_time");
}
if (val != -1) {
auto schedUpdate = nanoseconds(val);
if (schedUpdate != procp->schedUpdate) {
procp->schedUpdate = schedUpdate;
procp->count = 0ms;
procp->killed = !llkTestWithKill;
}
}
val = getSchedValue(schedString, "\nnr_switches");
if (val != -1) {
if (static_cast<uint64_t>(val) != procp->nrSwitches) {
procp->nrSwitches = val;
procp->count = 0ms;
procp->killed = !llkTestWithKill;
}
}
}
void llkLogConfig(void) {
LOG(INFO) << "ro.config.low_ram=" << llkFormat(llkLowRam) << "\n"
<< LLK_ENABLE_SYSRQ_T_PROPERTY "=" << llkFormat(llkEnableSysrqT) << "\n"
<< LLK_ENABLE_PROPERTY "=" << llkFormat(llkEnable) << "\n"
<< KHT_ENABLE_PROPERTY "=" << llkFormat(khtEnable) << "\n"
<< LLK_MLOCKALL_PROPERTY "=" << llkFormat(llkMlockall) << "\n"
<< LLK_KILLTEST_PROPERTY "=" << llkFormat(llkTestWithKill) << "\n"
<< KHT_TIMEOUT_PROPERTY "=" << llkFormat(khtTimeout) << "\n"
<< LLK_TIMEOUT_MS_PROPERTY "=" << llkFormat(llkTimeoutMs) << "\n"
<< LLK_D_TIMEOUT_MS_PROPERTY "=" << llkFormat(llkStateTimeoutMs[llkStateD]) << "\n"
<< LLK_Z_TIMEOUT_MS_PROPERTY "=" << llkFormat(llkStateTimeoutMs[llkStateZ]) << "\n"
#ifdef __PTRACE_ENABLED__
<< LLK_STACK_TIMEOUT_MS_PROPERTY "=" << llkFormat(llkStateTimeoutMs[llkStateStack])
<< "\n"
#endif
<< LLK_CHECK_MS_PROPERTY "=" << llkFormat(llkCheckMs) << "\n"
#ifdef __PTRACE_ENABLED__
<< LLK_CHECK_STACK_PROPERTY "=" << llkFormat(llkCheckStackSymbols) << "\n"
<< LLK_IGNORELIST_STACK_PROPERTY "=" << llkFormat(llkIgnorelistStack) << "\n"
#endif
<< LLK_IGNORELIST_PROCESS_PROPERTY "=" << llkFormat(llkIgnorelistProcess) << "\n"
<< LLK_IGNORELIST_PARENT_PROPERTY "=" << llkFormat(llkIgnorelistParent)
<< llkFormat(llkIgnorelistParentAndChild, true) << "\n"
<< LLK_IGNORELIST_UID_PROPERTY "=" << llkFormat(llkIgnorelistUid);
}
void* llkThread(void* obj) {
prctl(PR_SET_DUMPABLE, 0);
LOG(INFO) << "started";
std::string name = std::to_string(::gettid());
if (!llkSkipName(name)) {
llkIgnorelistProcess.emplace(name);
}
name = static_cast<const char*>(obj);
prctl(PR_SET_NAME, name.c_str());
if (__predict_false(!llkSkipName(name))) {
llkIgnorelistProcess.insert(name);
}
// No longer modifying llkIgnorelistProcess.
llkRunning = true;
llkLogConfig();
while (llkRunning) {
::usleep(duration_cast<microseconds>(llkCheck(true)).count());
}
// NOTREACHED
LOG(INFO) << "exiting";
return nullptr;
}
} // namespace
milliseconds llkCheck(bool checkRunning) {
if (!llkEnable || (checkRunning != llkRunning)) {
return milliseconds::max();
}
// Reset internal watchdog, which is a healthy engineering margin of
// double the maximum wait or cycle time for the mainloop that calls us.
//
// This alarm is effectively the live lock detection of llkd, as
// we understandably can not monitor ourselves otherwise.
::alarm(duration_cast<seconds>(llkTimeoutMs * 2 * android::base::HwTimeoutMultiplier())
.count());
// kernel jiffy precision fastest acquisition
static timespec last;
timespec now;
::clock_gettime(CLOCK_MONOTONIC_COARSE, &now);
auto ms = llkGetTimespecDiffMs(&last, &now);
if (ms < llkCycle) {
return llkCycle - ms;
}
last = now;
LOG(VERBOSE) << "opendir(\"" << procdir << "\")";
if (__predict_false(!llkTopDirectory)) {
// gid containing AID_READPROC required
llkTopDirectory.reset(procdir);
if (__predict_false(!llkTopDirectory)) {
// Most likely reason we could be here is a resource limit.
// Keep our processing down to a minimum, but not so low that
// we do not recover in a timely manner should the issue be
// transitory.
LOG(DEBUG) << "opendir(\"" << procdir << "\") failed";
return llkTimeoutMs;
}
}
for (auto& it : tids) {
it.second.updated = false;
}
auto prevUpdate = llkUpdate;
llkUpdate += ms;
ms -= llkCycle;
auto myPid = ::getpid();
auto myTid = ::gettid();
auto dump = true;
for (auto dp = llkTopDirectory.read(); dp != nullptr; dp = llkTopDirectory.read()) {
std::string piddir;
if (!getValidTidDir(dp, &piddir)) {
continue;
}
// Get the process tasks
std::string taskdir = piddir + "/task/";
int pid = -1;
LOG(VERBOSE) << "+opendir(\"" << taskdir << "\")";
dir taskDirectory(taskdir);
if (__predict_false(!taskDirectory)) {
LOG(DEBUG) << "+opendir(\"" << taskdir << "\") failed";
}
for (auto tp = taskDirectory.read(dir::task, dp); tp != nullptr;
tp = taskDirectory.read(dir::task)) {
if (!getValidTidDir(tp, &piddir)) {
continue;
}
// Get the process stat
std::string stat = ReadFile(piddir + "/stat");
if (stat.empty()) {
continue;
}
unsigned tid = -1;
char pdir[TASK_COMM_LEN + 1];
char state = '?';
unsigned ppid = -1;
unsigned utime = -1;
unsigned stime = -1;
int dummy;
pdir[0] = '\0';
// tid should not change value
auto match = ::sscanf(
stat.c_str(),
"%u (%" ___STRING(
TASK_COMM_LEN) "[^)]) %c %u %*d %*d %*d %*d %*d %*d %*d %*d %*d %u %u %d",
&tid, pdir, &state, &ppid, &utime, &stime, &dummy);
if (pid == -1) {
pid = tid;
}
LOG(VERBOSE) << "match " << match << ' ' << tid << " (" << pdir << ") " << state << ' '
<< ppid << " ... " << utime << ' ' << stime << ' ' << dummy;
if (match != 7) {
continue;
}
// Get the process cgroup
auto cgroup = ReadFile(piddir + "/cgroup");
auto frozen = cgroup.find(":freezer:/frozen") != std::string::npos;
auto procp = llkTidLookup(tid);
if (procp == nullptr) {
procp = llkTidAlloc(tid, pid, ppid, pdir, utime + stime, state, frozen);
} else {
// comm can change ...
procp->setComm(pdir);
// frozen can change, too...
procp->setFrozen(frozen);
procp->updated = true;
// pid/ppid/tid wrap?
if (((procp->update != prevUpdate) && (procp->update != llkUpdate)) ||
(procp->ppid != ppid) || (procp->pid != pid)) {
procp->reset();
} else if (procp->time != (utime + stime)) { // secondary ABA.
// watching utime+stime granularity jiffy
procp->state = '?';
}
procp->update = llkUpdate;
procp->pid = pid;
procp->ppid = ppid;
procp->time = utime + stime;
if (procp->state != state) {
procp->count = 0ms;
procp->killed = !llkTestWithKill;
procp->state = state;
} else {
procp->count += llkCycle;
}
}
// Filter checks in intuitive order of CPU cost to evaluate
// If tid unique continue, if ppid or pid unique break
if (pid == myPid) {
break;
}
#ifdef __PTRACE_ENABLED__
// if no stack monitoring, we can quickly exit here
if (!llkIsMonitorState(state) && llkCheckStackSymbols.empty()) {
continue;
}
#else
if (!llkIsMonitorState(state)) continue;
#endif
if ((tid == myTid) || llkSkipPid(tid)) {
continue;
}
if (procp->isFrozen()) {
break;
}
if (llkSkipPpid(ppid)) {
break;
}
auto process_comm = procp->getComm();
if (llkSkipName(process_comm)) {
continue;
}
if (llkSkipName(procp->getCmdline())) {
break;
}
if (llkSkipName(android::base::Basename(procp->getCmdline()))) {
break;
}
auto pprocp = llkTidLookup(ppid);
if (pprocp == nullptr) {
pprocp = llkTidAlloc(ppid, ppid, 0, "", 0, '?', false);
}
if (pprocp) {
if (llkSkipPproc(pprocp, procp)) break;
if (llkSkipProc(pprocp, llkIgnorelistParent)) break;
} else {
if (llkSkipName(std::to_string(ppid), llkIgnorelistParent)) break;
}
if ((llkIgnorelistUid.size() != 0) && llkSkipUid(procp->getUid())) {
continue;
}
// ABA mitigation watching last time schedule activity happened
llkCheckSchedUpdate(procp, piddir);
#ifdef __PTRACE_ENABLED__
auto stuck = llkCheckStack(procp, piddir);
if (llkIsMonitorState(state)) {
if (procp->count >= llkStateTimeoutMs[(state == 'Z') ? llkStateZ : llkStateD]) {
stuck = true;
} else if (procp->count != 0ms) {
LOG(VERBOSE) << state << ' ' << llkFormat(procp->count) << ' ' << ppid << "->"
<< pid << "->" << tid << ' ' << process_comm;
}
}
if (!stuck) continue;
#else
if (procp->count >= llkStateTimeoutMs[(state == 'Z') ? llkStateZ : llkStateD]) {
if (procp->count != 0ms) {
LOG(VERBOSE) << state << ' ' << llkFormat(procp->count) << ' ' << ppid << "->"
<< pid << "->" << tid << ' ' << process_comm;
}
continue;
}
#endif
// We have to kill it to determine difference between live lock
// and persistent state blocked on a resource. Is there something
// wrong with a process that has no forward scheduling progress in
// Z or D? Yes, generally means improper accounting in the
// process, but not always ...
//
// Whomever we hit with a test kill must accept the Android
// Aphorism that everything can be burned to the ground and
// must survive.
if (procp->killed == false) {
procp->killed = true;
// confirm: re-read uid before committing to a panic.
procp->uid = -1;
switch (state) {
case 'Z': // kill ppid to free up a Zombie
// Killing init will kernel panic without diagnostics
// so skip right to controlled kernel panic with
// diagnostics.
if (ppid == initPid) {
break;
}
LOG(WARNING) << "Z " << llkFormat(procp->count) << ' ' << ppid << "->"
<< pid << "->" << tid << ' ' << process_comm << " [kill]";
if ((llkKillOneProcess(pprocp, procp) >= 0) ||
(llkKillOneProcess(ppid, procp) >= 0)) {
continue;
}
break;
case 'D': // kill tid to free up an uninterruptible D
// If ABA is doing its job, we would not need or
// want the following. Test kill is a Hail Mary
// to make absolutely sure there is no forward
// scheduling progress. The cost when ABA is
// not working is we kill a process that likes to
// stay in 'D' state, instead of panicing the
// kernel (worse).
default:
LOG(WARNING) << state << ' ' << llkFormat(procp->count) << ' ' << pid
<< "->" << tid << ' ' << process_comm << " [kill]";
if ((llkKillOneProcess(llkTidLookup(pid), procp) >= 0) ||
(llkKillOneProcess(pid, state, tid) >= 0) ||
(llkKillOneProcess(procp, procp) >= 0) ||
(llkKillOneProcess(tid, state, tid) >= 0)) {
continue;
}
break;
}
}
// We are here because we have confirmed kernel live-lock
std::vector<std::string> threads;
auto taskdir = procdir + std::to_string(tid) + "/task/";
dir taskDirectory(taskdir);
for (auto tp = taskDirectory.read(); tp != nullptr; tp = taskDirectory.read()) {
std::string piddir;
if (getValidTidDir(tp, &piddir))
threads.push_back(android::base::Basename(piddir));
}
const auto message = state + " "s + llkFormat(procp->count) + " " +
std::to_string(ppid) + "->" + std::to_string(pid) + "->" +
std::to_string(tid) + " " + process_comm + " [panic]\n" +
" thread group: {" + android::base::Join(threads, ",") +
"}";
llkPanicKernel(dump, tid,
(state == 'Z') ? "zombie" : (state == 'D') ? "driver" : "sleeping",
message);
dump = false;
}
LOG(VERBOSE) << "+closedir()";
}
llkTopDirectory.rewind();
LOG(VERBOSE) << "closedir()";
// garbage collection of old process references
for (auto p = tids.begin(); p != tids.end();) {
if (!p->second.updated) {
IF_ALOG(LOG_VERBOSE, LOG_TAG) {
std::string ppidCmdline = llkProcGetName(p->second.ppid, nullptr, nullptr);
if (!ppidCmdline.empty()) ppidCmdline = "(" + ppidCmdline + ")";
std::string pidCmdline;
if (p->second.pid != p->second.tid) {
pidCmdline = llkProcGetName(p->second.pid, nullptr, p->second.getCmdline());
if (!pidCmdline.empty()) pidCmdline = "(" + pidCmdline + ")";
}
std::string tidCmdline =
llkProcGetName(p->second.tid, p->second.getComm(), p->second.getCmdline());
if (!tidCmdline.empty()) tidCmdline = "(" + tidCmdline + ")";
LOG(VERBOSE) << "thread " << p->second.ppid << ppidCmdline << "->" << p->second.pid
<< pidCmdline << "->" << p->second.tid << tidCmdline << " removed";
}
p = tids.erase(p);
} else {
++p;
}
}
if (__predict_false(tids.empty())) {
llkTopDirectory.reset();
}
llkCycle = llkCheckMs;
timespec end;
::clock_gettime(CLOCK_MONOTONIC_COARSE, &end);
auto milli = llkGetTimespecDiffMs(&now, &end);
LOG((milli > 10s) ? ERROR : (milli > 1s) ? WARNING : VERBOSE) << "sample " << llkFormat(milli);
// cap to minimum sleep for 1 second since last cycle
if (llkCycle < (ms + 1s)) {
return 1s;
}
return llkCycle - ms;
}
unsigned llkCheckMilliseconds() {
return duration_cast<milliseconds>(llkCheck()).count();
}
bool llkCheckEng(const std::string& property) {
return android::base::GetProperty(property, "eng") == "eng";
}
bool llkInit(const char* threadname) {
auto debuggable = android::base::GetBoolProperty("ro.debuggable", false);
llkLowRam = android::base::GetBoolProperty("ro.config.low_ram", false);
llkEnableSysrqT &= !llkLowRam;
if (debuggable) {
llkEnableSysrqT |= llkCheckEng(LLK_ENABLE_SYSRQ_T_PROPERTY);
if (!LLK_ENABLE_DEFAULT) {
khtEnable |= llkCheckEng(KHT_ENABLE_PROPERTY);
}
}
llkEnableSysrqT = android::base::GetBoolProperty(LLK_ENABLE_SYSRQ_T_PROPERTY, llkEnableSysrqT);
llkEnable = android::base::GetBoolProperty(LLK_ENABLE_PROPERTY, llkEnable);
if (llkEnable && !llkTopDirectory.reset(procdir)) {
// Most likely reason we could be here is llkd was started
// incorrectly without the readproc permissions. Keep our
// processing down to a minimum.
llkEnable = false;
}
khtEnable = android::base::GetBoolProperty(KHT_ENABLE_PROPERTY, khtEnable);
llkMlockall = android::base::GetBoolProperty(LLK_MLOCKALL_PROPERTY, llkMlockall);
llkTestWithKill = android::base::GetBoolProperty(LLK_KILLTEST_PROPERTY, llkTestWithKill);
// if LLK_TIMOUT_MS_PROPERTY was not set, we will use a set
// KHT_TIMEOUT_PROPERTY as co-operative guidance for the default value.
khtTimeout = GetUintProperty(KHT_TIMEOUT_PROPERTY, khtTimeout);
if (khtTimeout == 0s) {
khtTimeout = duration_cast<seconds>(llkTimeoutMs * (1 + LLK_CHECKS_PER_TIMEOUT_DEFAULT) /
LLK_CHECKS_PER_TIMEOUT_DEFAULT);
}
llkTimeoutMs =
khtTimeout * LLK_CHECKS_PER_TIMEOUT_DEFAULT / (1 + LLK_CHECKS_PER_TIMEOUT_DEFAULT);
llkTimeoutMs = GetUintProperty(LLK_TIMEOUT_MS_PROPERTY, llkTimeoutMs);
llkValidate(); // validate llkTimeoutMs, llkCheckMs and llkCycle
llkStateTimeoutMs[llkStateD] = GetUintProperty(LLK_D_TIMEOUT_MS_PROPERTY, llkTimeoutMs);
llkStateTimeoutMs[llkStateZ] = GetUintProperty(LLK_Z_TIMEOUT_MS_PROPERTY, llkTimeoutMs);
#ifdef __PTRACE_ENABLED__
llkStateTimeoutMs[llkStateStack] = GetUintProperty(LLK_STACK_TIMEOUT_MS_PROPERTY, llkTimeoutMs);
#endif
llkCheckMs = GetUintProperty(LLK_CHECK_MS_PROPERTY, llkCheckMs);
llkValidate(); // validate all (effectively minus llkTimeoutMs)
#ifdef __PTRACE_ENABLED__
if (debuggable) {
llkCheckStackSymbols = llkSplit(LLK_CHECK_STACK_PROPERTY, LLK_CHECK_STACK_DEFAULT);
}
std::string defaultIgnorelistStack(LLK_IGNORELIST_STACK_DEFAULT);
if (!debuggable) defaultIgnorelistStack += ",logd,/system/bin/logd";
llkIgnorelistStack = llkSplit(LLK_IGNORELIST_STACK_PROPERTY, defaultIgnorelistStack);
#endif
std::string defaultIgnorelistProcess(
std::to_string(kernelPid) + "," + std::to_string(initPid) + "," +
std::to_string(kthreaddPid) + "," + std::to_string(::getpid()) + "," +
std::to_string(::gettid()) + "," LLK_IGNORELIST_PROCESS_DEFAULT);
if (threadname) {
defaultIgnorelistProcess += ","s + threadname;
}
for (int cpu = 1; cpu < get_nprocs_conf(); ++cpu) {
defaultIgnorelistProcess += ",[watchdog/" + std::to_string(cpu) + "]";
}
llkIgnorelistProcess = llkSplit(LLK_IGNORELIST_PROCESS_PROPERTY, defaultIgnorelistProcess);
if (!llkSkipName("[khungtaskd]")) { // ALWAYS ignore as special
llkIgnorelistProcess.emplace("[khungtaskd]");
}
llkIgnorelistParent = llkSplit(LLK_IGNORELIST_PARENT_PROPERTY,
std::to_string(kernelPid) + "," + std::to_string(kthreaddPid) +
"," LLK_IGNORELIST_PARENT_DEFAULT);
// derive llkIgnorelistParentAndChild by moving entries with '&' from above
for (auto it = llkIgnorelistParent.begin(); it != llkIgnorelistParent.end();) {
auto pos = it->find('&');
if (pos == std::string::npos) {
++it;
continue;
}
auto parent = it->substr(0, pos);
auto child = it->substr(pos + 1);
it = llkIgnorelistParent.erase(it);
auto found = llkIgnorelistParentAndChild.find(parent);
if (found == llkIgnorelistParentAndChild.end()) {
llkIgnorelistParentAndChild.emplace(std::make_pair(
std::move(parent), std::unordered_set<std::string>({std::move(child)})));
} else {
found->second.emplace(std::move(child));
}
}
llkIgnorelistUid = llkSplit(LLK_IGNORELIST_UID_PROPERTY, LLK_IGNORELIST_UID_DEFAULT);
// internal watchdog
::signal(SIGALRM, llkAlarmHandler);
// kernel hung task configuration? Otherwise leave it as-is
if (khtEnable) {
// EUID must be AID_ROOT to write to /proc/sys/kernel/ nodes, there
// are no capability overrides. For security reasons we do not want
// to run as AID_ROOT. We may not be able to write them successfully,
// we will try, but the least we can do is read the values back to
// confirm expectations and report whether configured or not.
auto configured = llkWriteStringToFileConfirm(std::to_string(khtTimeout.count()),
"/proc/sys/kernel/hung_task_timeout_secs");
if (configured) {
llkWriteStringToFile("65535", "/proc/sys/kernel/hung_task_warnings");
llkWriteStringToFile("65535", "/proc/sys/kernel/hung_task_check_count");
configured = llkWriteStringToFileConfirm("1", "/proc/sys/kernel/hung_task_panic");
}
if (configured) {
LOG(INFO) << "[khungtaskd] configured";
} else {
LOG(WARNING) << "[khungtaskd] not configurable";
}
}
bool logConfig = true;
if (llkEnable) {
if (llkMlockall &&
// MCL_ONFAULT pins pages as they fault instead of loading
// everything immediately all at once. (Which would be bad,
// because as of this writing, we have a lot of mapped pages we
// never use.) Old kernels will see MCL_ONFAULT and fail with
// EINVAL; we ignore this failure.
//
// N.B. read the man page for mlockall. MCL_CURRENT | MCL_ONFAULT
// pins ⊆ MCL_CURRENT, converging to just MCL_CURRENT as we fault
// in pages.
// CAP_IPC_LOCK required
mlockall(MCL_CURRENT | MCL_FUTURE | MCL_ONFAULT) && (errno != EINVAL)) {
PLOG(WARNING) << "mlockall failed ";
}
if (threadname) {
pthread_attr_t attr;
if (!pthread_attr_init(&attr)) {
sched_param param;
memset(&param, 0, sizeof(param));
pthread_attr_setschedparam(&attr, &param);
pthread_attr_setschedpolicy(&attr, SCHED_BATCH);
if (!pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED)) {
pthread_t thread;
if (!pthread_create(&thread, &attr, llkThread, const_cast<char*>(threadname))) {
// wait a second for thread to start
for (auto retry = 50; retry && !llkRunning; --retry) {
::usleep(20000);
}
logConfig = !llkRunning; // printed in llkd context?
} else {
LOG(ERROR) << "failed to spawn llkd thread";
}
} else {
LOG(ERROR) << "failed to detach llkd thread";
}
pthread_attr_destroy(&attr);
} else {
LOG(ERROR) << "failed to allocate attibutes for llkd thread";
}
}
} else {
LOG(DEBUG) << "[khungtaskd] left unconfigured";
}
if (logConfig) {
llkLogConfig();
}
return llkEnable;
}
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