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coral / android-core / 2ddb8df2ef22514f1bf91fe73b99877d19b2a964 / . / llkd / libllkd.cpp
blob: b26ad4df62b4a5976b10c6bf208d179b7ac9de41 [file] [log] [blame]
/*
* 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 <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
// Blacklist 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> llkBlacklistProcess;
// 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> llkBlacklistParent;
// list of parent and target processes to skip. default:
// adbd *and* [setsid]
std::unordered_map<std::string, std::unordered_set<std::string>> llkBlacklistParentAndChild;
// list of uids, and uid names, to skip, default nothing
std::unordered_set<std::string> llkBlacklistUid;
#ifdef __PTRACE_ENABLED__
// list of names to skip stack checking. "init", "lmkd", "llkd", "keystore" or
// "logd" (if not userdebug).
std::unordered_set<std::string> llkBlacklistStack;
#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...
void setComm(const char* _comm) { strncpy(comm + 1, _comm, sizeof(comm) - 2); }
proc(pid_t tid, pid_t pid, pid_t ppid, const char* _comm, int time, char state)
: 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) {
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;
}
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) {
auto it = tids.emplace(std::make_pair(tid, proc(tid, pid, ppid, comm, time, state)));
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>& blacklist) {
std::string ret;
for (const auto& entry : blacklist) {
if (!ret.empty()) ret += ",";
ret += entry;
}
return ret;
}
std::string llkFormat(
const std::unordered_map<std::string, std::unordered_set<std::string>>& blacklist,
bool leading_comma = false) {
std::string ret;
for (const auto& entry : blacklist) {
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>& blacklist = llkBlacklistProcess) {
if (name.empty() || blacklist.empty()) return false;
return blacklist.find(name) != blacklist.end();
}
bool llkSkipProc(proc* procp,
const std::unordered_set<std::string>& blacklist = llkBlacklistProcess) {
if (!procp) return false;
if (llkSkipName(std::to_string(procp->pid), blacklist)) return true;
if (llkSkipName(procp->getComm(), blacklist)) return true;
if (llkSkipName(procp->getCmdline(), blacklist)) return true;
if (llkSkipName(android::base::Basename(procp->getCmdline()), blacklist)) 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>>& blacklist) {
static const std::unordered_set<std::string> empty;
if (name.empty() || blacklist.empty()) return empty;
auto found = blacklist.find(name);
if (found == blacklist.end()) return empty;
return found->second;
}
bool llkSkipPproc(proc* pprocp, proc* procp,
const std::unordered_map<std::string, std::unordered_set<std::string>>&
blacklist = llkBlacklistParentAndChild) {
if (!pprocp || !procp || blacklist.empty()) return false;
if (llkSkipProc(procp, llkSkipName(std::to_string(pprocp->pid), blacklist))) return true;
if (llkSkipProc(procp, llkSkipName(pprocp->getComm(), blacklist))) return true;
if (llkSkipProc(procp, llkSkipName(pprocp->getCmdline(), blacklist))) return true;
return llkSkipProc(procp,
llkSkipName(android::base::Basename(pprocp->getCmdline()), blacklist));
}
bool llkSkipPid(pid_t pid) {
return llkSkipName(std::to_string(pid), llkBlacklistProcess);
}
bool llkSkipPpid(pid_t ppid) {
return llkSkipName(std::to_string(ppid), llkBlacklistParent);
}
bool llkSkipUid(uid_t uid) {
// Match by number?
if (llkSkipName(std::to_string(uid), llkBlacklistUid)) {
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, llkBlacklistUid);
}
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, llkBlacklistStack)) 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_BLACKLIST_STACK_PROPERTY "=" << llkFormat(llkBlacklistStack) << "\n"
#endif
<< LLK_BLACKLIST_PROCESS_PROPERTY "=" << llkFormat(llkBlacklistProcess) << "\n"
<< LLK_BLACKLIST_PARENT_PROPERTY "=" << llkFormat(llkBlacklistParent)
<< llkFormat(llkBlacklistParentAndChild, true) << "\n"
<< LLK_BLACKLIST_UID_PROPERTY "=" << llkFormat(llkBlacklistUid);
}
void* llkThread(void* obj) {
prctl(PR_SET_DUMPABLE, 0);
LOG(INFO) << "started";
std::string name = std::to_string(::gettid());
if (!llkSkipName(name)) {
llkBlacklistProcess.emplace(name);
}
name = static_cast<const char*>(obj);
prctl(PR_SET_NAME, name.c_str());
if (__predict_false(!llkSkipName(name))) {
llkBlacklistProcess.insert(name);
}
// No longer modifying llkBlacklistProcess.
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).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;
}
auto procp = llkTidLookup(tid);
if (procp == nullptr) {
procp = llkTidAlloc(tid, pid, ppid, pdir, utime + stime, state);
} else {
// comm can change ...
procp->setComm(pdir);
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 (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, '?');
}
if (pprocp) {
if (llkSkipPproc(pprocp, procp)) break;
if (llkSkipProc(pprocp, llkBlacklistParent)) break;
} else {
if (llkSkipName(std::to_string(ppid), llkBlacklistParent)) break;
}
if ((llkBlacklistUid.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
const auto message = state + " "s + llkFormat(procp->count) + " " +
std::to_string(ppid) + "->" + std::to_string(pid) + "->" +
std::to_string(tid) + " " + process_comm + " [panic]";
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) { // NB: default is currently true ...
llkEnable |= llkCheckEng(LLK_ENABLE_PROPERTY);
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 defaultBlacklistStack(LLK_BLACKLIST_STACK_DEFAULT);
if (!debuggable) defaultBlacklistStack += ",logd,/system/bin/logd";
llkBlacklistStack = llkSplit(LLK_BLACKLIST_STACK_PROPERTY, defaultBlacklistStack);
#endif
std::string defaultBlacklistProcess(
std::to_string(kernelPid) + "," + std::to_string(initPid) + "," +
std::to_string(kthreaddPid) + "," + std::to_string(::getpid()) + "," +
std::to_string(::gettid()) + "," LLK_BLACKLIST_PROCESS_DEFAULT);
if (threadname) {
defaultBlacklistProcess += ","s + threadname;
}
for (int cpu = 1; cpu < get_nprocs_conf(); ++cpu) {
defaultBlacklistProcess += ",[watchdog/" + std::to_string(cpu) + "]";
}
llkBlacklistProcess = llkSplit(LLK_BLACKLIST_PROCESS_PROPERTY, defaultBlacklistProcess);
if (!llkSkipName("[khungtaskd]")) { // ALWAYS ignore as special
llkBlacklistProcess.emplace("[khungtaskd]");
}
llkBlacklistParent = llkSplit(LLK_BLACKLIST_PARENT_PROPERTY,
std::to_string(kernelPid) + "," + std::to_string(kthreaddPid) +
"," LLK_BLACKLIST_PARENT_DEFAULT);
// derive llkBlacklistParentAndChild by moving entries with '&' from above
for (auto it = llkBlacklistParent.begin(); it != llkBlacklistParent.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 = llkBlacklistParent.erase(it);
auto found = llkBlacklistParentAndChild.find(parent);
if (found == llkBlacklistParentAndChild.end()) {
llkBlacklistParentAndChild.emplace(std::make_pair(
std::move(parent), std::unordered_set<std::string>({std::move(child)})));
} else {
found->second.emplace(std::move(child));
}
}
llkBlacklistUid = llkSplit(LLK_BLACKLIST_UID_PROPERTY, LLK_BLACKLIST_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;
}