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lbrycrd/src/scheduler.cpp
Pieter Wuille 9d7032e4f0 Switch all RNG code to the built-in PRNG. 
It includes the following policy changes:
* All GetRand* functions seed the stack pointer and rdrand result
  (in addition to the performance counter)
* The periodic entropy added by the idle scheduler now seeds stack pointer,
  rdrand and perfmon data (once every 10 minutes) in addition to
  just a sleep timing.
* The entropy added when calling GetStrongRandBytes no longer includes
  the once-per-10-minutes perfmon data on windows (it is moved to the
  idle scheduler instead, where latency matters less).

Other changes:
* OpenSSL is no longer seeded directly anywhere. Instead, any generated
  randomness through our own RNG is fed back to OpenSSL (after an
  additional hashing step to prevent leaking our RNG state).
* Seeding that was previously done directly in RandAddSeedSleep is now
  moved to SeedSleep(), which is indirectly invoked through ProcRand
  from RandAddSeedSleep.
* Seeding that was previously done directly in GetStrongRandBytes()
  is now moved to SeedSlow(), which is indirectly invoked through
  ProcRand from GetStrongRandBytes().
2019-01-16 16:34:56 -08:00

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// Copyright (c) 2015-2018 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <scheduler.h>
#include <random.h>
#include <reverselock.h>
#include <assert.h>
#include <utility>
CScheduler::CScheduler() : nThreadsServicingQueue(0), stopRequested(false), stopWhenEmpty(false)
{
}
CScheduler::~CScheduler()
{
assert(nThreadsServicingQueue == 0);
}
#if BOOST_VERSION < 105000
static boost::system_time toPosixTime(const boost::chrono::system_clock::time_point& t)
{
// Creating the posix_time using from_time_t loses sub-second precision. So rather than exporting the time_point to time_t,
// start with a posix_time at the epoch (0) and add the milliseconds that have passed since then.
return boost::posix_time::from_time_t(0) + boost::posix_time::milliseconds(boost::chrono::duration_cast<boost::chrono::milliseconds>(t.time_since_epoch()).count());
}
#endif
void CScheduler::serviceQueue()
{
boost::unique_lock<boost::mutex> lock(newTaskMutex);
++nThreadsServicingQueue;
// newTaskMutex is locked throughout this loop EXCEPT
// when the thread is waiting or when the user's function
// is called.
while (!shouldStop()) {
try {
if (!shouldStop() && taskQueue.empty()) {
reverse_lock<boost::unique_lock<boost::mutex> > rlock(lock);
// Use this chance to get more entropy
RandAddSeedSleep();
}
while (!shouldStop() && taskQueue.empty()) {
// Wait until there is something to do.
newTaskScheduled.wait(lock);
}
// Wait until either there is a new task, or until
// the time of the first item on the queue:
// wait_until needs boost 1.50 or later; older versions have timed_wait:
#if BOOST_VERSION < 105000
while (!shouldStop() && !taskQueue.empty() &&
newTaskScheduled.timed_wait(lock, toPosixTime(taskQueue.begin()->first))) {
// Keep waiting until timeout
}
#else
// Some boost versions have a conflicting overload of wait_until that returns void.
// Explicitly use a template here to avoid hitting that overload.
while (!shouldStop() && !taskQueue.empty()) {
boost::chrono::system_clock::time_point timeToWaitFor = taskQueue.begin()->first;
if (newTaskScheduled.wait_until<>(lock, timeToWaitFor) == boost::cv_status::timeout)
break; // Exit loop after timeout, it means we reached the time of the event
}
#endif
// If there are multiple threads, the queue can empty while we're waiting (another
// thread may service the task we were waiting on).
if (shouldStop() || taskQueue.empty())
continue;
Function f = taskQueue.begin()->second;
taskQueue.erase(taskQueue.begin());
{
// Unlock before calling f, so it can reschedule itself or another task
// without deadlocking:
reverse_lock<boost::unique_lock<boost::mutex> > rlock(lock);
f();
}
} catch (...) {
--nThreadsServicingQueue;
throw;
}
}
--nThreadsServicingQueue;
newTaskScheduled.notify_one();
}
void CScheduler::stop(bool drain)
{
{
boost::unique_lock<boost::mutex> lock(newTaskMutex);
if (drain)
stopWhenEmpty = true;
else
stopRequested = true;
}
newTaskScheduled.notify_all();
}
void CScheduler::schedule(CScheduler::Function f, boost::chrono::system_clock::time_point t)
{
{
boost::unique_lock<boost::mutex> lock(newTaskMutex);
taskQueue.insert(std::make_pair(t, f));
}
newTaskScheduled.notify_one();
}
void CScheduler::scheduleFromNow(CScheduler::Function f, int64_t deltaMilliSeconds)
{
schedule(f, boost::chrono::system_clock::now() + boost::chrono::milliseconds(deltaMilliSeconds));
}
static void Repeat(CScheduler* s, CScheduler::Function f, int64_t deltaMilliSeconds)
{
f();
s->scheduleFromNow(std::bind(&Repeat, s, f, deltaMilliSeconds), deltaMilliSeconds);
}
void CScheduler::scheduleEvery(CScheduler::Function f, int64_t deltaMilliSeconds)
{
scheduleFromNow(std::bind(&Repeat, this, f, deltaMilliSeconds), deltaMilliSeconds);
}
size_t CScheduler::getQueueInfo(boost::chrono::system_clock::time_point &first,
boost::chrono::system_clock::time_point &last) const
{
boost::unique_lock<boost::mutex> lock(newTaskMutex);
size_t result = taskQueue.size();
if (!taskQueue.empty()) {
first = taskQueue.begin()->first;
last = taskQueue.rbegin()->first;
}
return result;
}
bool CScheduler::AreThreadsServicingQueue() const {
boost::unique_lock<boost::mutex> lock(newTaskMutex);
return nThreadsServicingQueue;
}
void SingleThreadedSchedulerClient::MaybeScheduleProcessQueue() {
{
LOCK(m_cs_callbacks_pending);
// Try to avoid scheduling too many copies here, but if we
// accidentally have two ProcessQueue's scheduled at once its
// not a big deal.
if (m_are_callbacks_running) return;
if (m_callbacks_pending.empty()) return;
}
m_pscheduler->schedule(std::bind(&SingleThreadedSchedulerClient::ProcessQueue, this));
}
void SingleThreadedSchedulerClient::ProcessQueue() {
std::function<void ()> callback;
{
LOCK(m_cs_callbacks_pending);
if (m_are_callbacks_running) return;
if (m_callbacks_pending.empty()) return;
m_are_callbacks_running = true;
callback = std::move(m_callbacks_pending.front());
m_callbacks_pending.pop_front();
}
// RAII the setting of fCallbacksRunning and calling MaybeScheduleProcessQueue
// to ensure both happen safely even if callback() throws.
struct RAIICallbacksRunning {
SingleThreadedSchedulerClient* instance;
explicit RAIICallbacksRunning(SingleThreadedSchedulerClient* _instance) : instance(_instance) {}
~RAIICallbacksRunning() {
{
LOCK(instance->m_cs_callbacks_pending);
instance->m_are_callbacks_running = false;
}
instance->MaybeScheduleProcessQueue();
}
} raiicallbacksrunning(this);
callback();
}
void SingleThreadedSchedulerClient::AddToProcessQueue(std::function<void ()> func) {
assert(m_pscheduler);
{
LOCK(m_cs_callbacks_pending);
m_callbacks_pending.emplace_back(std::move(func));
}
MaybeScheduleProcessQueue();
}
void SingleThreadedSchedulerClient::EmptyQueue() {
assert(!m_pscheduler->AreThreadsServicingQueue());
bool should_continue = true;
while (should_continue) {
ProcessQueue();
LOCK(m_cs_callbacks_pending);
should_continue = !m_callbacks_pending.empty();
}
}
size_t SingleThreadedSchedulerClient::CallbacksPending() {
LOCK(m_cs_callbacks_pending);
return m_callbacks_pending.size();
}
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