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-rw-r--r-- | indra/llcommon/llcond.cpp | 111 | ||||
-rw-r--r-- | indra/llcommon/llcond.h | 168 |
2 files changed, 252 insertions, 27 deletions
diff --git a/indra/llcommon/llcond.cpp b/indra/llcommon/llcond.cpp new file mode 100644 index 0000000000..d5362a48fc --- /dev/null +++ b/indra/llcommon/llcond.cpp @@ -0,0 +1,111 @@ +/** + * @file llcond.cpp + * @author Nat Goodspeed + * @date 2019-07-17 + * @brief Implementation for llcond. + * + * $LicenseInfo:firstyear=2019&license=viewerlgpl$ + * Copyright (c) 2019, Linden Research, Inc. + * $/LicenseInfo$ + */ + +// Precompiled header +#include "linden_common.h" +// associated header +#include "llcond.h" +// STL headers +// std headers +// external library headers +// other Linden headers + +namespace // anonymous +{ + +// See comments in LLCond::convert(const LLDate&) below +std::time_t compute_lldate_epoch() +{ + LLDate lldate_epoch; + std::tm tm; + // It should be noted that calling LLDate::split() to write directly + // into a std::tm struct depends on S32 being a typedef for int in + // stdtypes.h: split() takes S32*, whereas tm fields are documented to + // be int. If you get compile errors here, somebody changed the + // definition of S32. You'll have to declare six S32 variables, + // split() into them, then assign them into the relevant tm fields. + if (! lldate_epoch.split(&tm.tm_year, &tm.tm_mon, &tm.tm_mday, + &tm.tm_hour, &tm.tm_min, &tm.tm_sec)) + { + // Theoretically split() could return false. In that case, we + // don't have valid data, so we can't compute offset, so skip the + // rest of this. + return 0; + } + + tm.tm_isdst = 0; + std::time_t lldate_epoch_time = std::mktime(&tm); + if (lldate_epoch_time == -1) + { + // Theoretically mktime() could return -1, meaning that the contents + // of the passed std::tm cannot be represented as a time_t. (Worrisome + // if LLDate's epoch happened to be exactly 1 tick before + // std::time_t's epoch...) + // In the error case, assume offset 0. + return 0; + } + + // But if we got this far, lldate_epoch_time is the time_t we want. + return lldate_epoch_time; +} + +} // anonymous namespace + +// convert LLDate to a chrono::time_point +std::chrono::system_clock::time_point LLCond::convert(const LLDate& lldate) +{ + // std::chrono::system_clock's epoch MAY be the Unix epoch, namely + // midnight UTC on 1970-01-01, in fact it probably is. But until C++20, + // system_clock does not guarantee that. Unfortunately time_t doesn't + // specify its epoch either, other than to note that it "almost always" is + // the Unix epoch (https://en.cppreference.com/w/cpp/chrono/c/time_t). + // LLDate, being based on apr_time_t, does guarantee 1970-01-01T00:00 UTC. + // http://apr.apache.org/docs/apr/1.5/group__apr__time.html#gadb4bde16055748190eae190c55aa02bb + + // The easy, efficient conversion would be + // std::chrono::system_clock::from_time_t(std::time_t(LLDate::secondsSinceEpoch())). + // But that assumes that both time_t and system_clock have the same epoch + // as LLDate -- an assumption that will work until it unexpectedly doesn't. + + // It would be more formally correct to break out the year, month, day, + // hour, minute, second (UTC) using LLDate::split() and recombine them + // into std::time_t using std::mktime(). However, both split() and + // mktime() have integer second granularity, whereas callers of + // wait_until() are very likely to be interested in sub-second precision. + // In that sense std::chrono::system_clock::from_time_t() is still + // preferred. + + // So use the split() / mktime() mechanism to determine the numeric value + // of the LLDate / apr_time_t epoch as expressed in time_t. (We assume + // that the epoch offset can be expressed as integer seconds, per split() + // and mktime(), which seems plausible.) + + // n.b. A function-static variable is initialized only once in a + // thread-safe way. + static std::time_t lldate_epoch_time = compute_lldate_epoch(); + + // LLDate::secondsSinceEpoch() gets us, of course, how long it has + // been since lldate_epoch_time. So adding lldate_epoch_time should + // give us the correct time_t representation of a given LLDate even if + // time_t's epoch differs from LLDate's. + // We don't have to worry about the relative epochs of time_t and + // system_clock because from_time_t() takes care of that! + return std::chrono::system_clock::from_time_t(lldate_epoch_time + + lldate.secondsSinceEpoch()); +} + +// convert F32Milliseconds to a chrono::duration +std::chrono::milliseconds LLCond::convert(F32Milliseconds) +{ + // extract the F32 milliseconds from F32Milliseconds, construct + // std::chrono::milliseconds from that value + return std::chrono::milliseconds(timeout_duration.value()); +} diff --git a/indra/llcommon/llcond.h b/indra/llcommon/llcond.h index adfeb27f82..5ed9f10123 100644 --- a/indra/llcommon/llcond.h +++ b/indra/llcommon/llcond.h @@ -14,6 +14,8 @@ #if ! defined(LL_LLCOND_H) #define LL_LLCOND_H +#include "llunits.h" +#include "lldate.h" #include <boost/fiber/condition_variable.hpp> #include <mutex> #include <chrono> @@ -37,9 +39,12 @@ template <typename DATA> class LLCond { +public: + typedef value_type DATA; + private: // This is the DATA controlled by the condition_variable. - DATA mData; + value_type mData; // condition_variable must be used in conjunction with a mutex. Use // boost::fibers::mutex instead of std::mutex because the latter blocks // the entire calling thread, whereas the former blocks only the current @@ -52,7 +57,7 @@ private: public: /// LLCond can be explicitly initialized with a specific value for mData if /// desired. - LLCond(DATA&& init=DATA()): + LLCond(value_type&& init=value_type()): mData(init) {} @@ -63,7 +68,7 @@ public: /// get() returns a const reference to the stored DATA. The only way to /// get a non-const reference -- to modify the stored DATA -- is via /// update_one() or update_all(). - const DATA& get() const { return mData; } + const value_type& get() const { return mData; } /** * Pass update_one() an invocable accepting non-const (DATA&). The @@ -122,7 +127,7 @@ public: // But what if they instead pass a predicate accepting non-const // (DATA&)? Such a predicate could modify mData, which would be Bad. // Forbid that. - while (! pred(const_cast<const DATA&>(mData))) + while (! pred(const_cast<const value_type&>(mData))) { mCond.wait(lk); } @@ -143,20 +148,30 @@ public: { std::unique_lock<boost::fibers::mutex> lk(mMutex); // see wait() for comments about this const_cast - while (! pred(const_cast<const DATA&>(mData))) + while (! pred(const_cast<const value_type&>(mData))) { if (boost::fibers::cv_status::timeout == mCond.wait_until(lk, timeout_time)) { // It's possible that wait_until() timed out AND the predicate // became true more or less simultaneously. Even though // wait_until() timed out, check the predicate one more time. - return pred(const_cast<const DATA&>(mData)); + return pred(const_cast<const value_type&>(mData)); } } return true; } /** + * This wait_until() overload accepts LLDate as the time_point. Its + * semantics are the same as the generic wait_until() method. + */ + template <typename Pred> + bool wait_until(const LLDate& timeout_time, Pred pred) + { + return wait_until(convert(timeout_time), pred); + } + + /** * Pass wait_for() a chrono::duration, indicating how long we're willing * to wait, and a predicate accepting (const DATA&), returning bool. The * predicate returns true when the condition for which it is waiting has @@ -178,6 +193,24 @@ public: // stick to it. return wait_until(std::chrono::steady_clock::now() + timeout_duration, pred); } + + /** + * This wait_for() overload accepts F32Milliseconds as the duration. Any + * duration unit defined in llunits.h is implicitly convertible to + * F32Milliseconds. The semantics of this method are the same as the + * generic wait_for() method. + */ + template <typename Pred> + bool wait_for(F32Milliseconds timeout_duration, Pred pred) + { + return wait_for(convert(timeout_duration), pred); + } + +protected: + // convert LLDate to a chrono::time_point + std::chrono::system_clock::time_point convert(const LLDate&); + // convert F32Milliseconds to a chrono::duration + std::chrono::milliseconds convert(F32Milliseconds); }; template <typename DATA> @@ -186,26 +219,32 @@ class LLScalarCond: public LLCond<DATA> using super = LLCond<DATA>; public: + using super::value_type; + using super::get; + using super::wait; + using super::wait_until; + using super::wait_for; + /// LLScalarCond can be explicitly initialized with a specific value for /// mData if desired. - LLCond(DATA&& init=DATA()): + LLCond(value_type&& init=value_type()): super(init) {} /// Pass set_one() a new value to which to update mData. set_one() will /// lock the mutex, update mData and then call notify_one() on the /// condition_variable. - void set_one(DATA&& value) + void set_one(value_type&& value) { - super::update_one([](DATA& data){ data = value; }); + super::update_one([](value_type& data){ data = value; }); } /// Pass set_all() a new value to which to update mData. set_all() will /// lock the mutex, update mData and then call notify_all() on the /// condition_variable. - void set_all(DATA&& value) + void set_all(value_type&& value) { - super::update_all([](DATA& data){ data = value; }); + super::update_all([](value_type& data){ data = value; }); } /** @@ -213,9 +252,9 @@ public: * mutex and, until the stored DATA equals that value, calls wait() on the * condition_variable. */ - void wait_equal(const DATA& value) + void wait_equal(const value_type& value) { - super::wait([&value](const DATA& data){ return (data == value); }); + super::wait([&value](const value_type& data){ return (data == value); }); } /** @@ -228,10 +267,19 @@ public: */ template <typename Clock, typename Duration> bool wait_until_equal(const std::chrono::time_point<Clock, Duration>& timeout_time, - const DATA& value) + const value_type& value) { return super::wait_until(timeout_time, - [&value](const DATA& data){ return (data == value); }); + [&value](const value_type& data){ return (data == value); }); + } + + /** + * This wait_until_equal() overload accepts LLDate as the time_point. Its + * semantics are the same as the generic wait_until_equal() method. + */ + bool wait_until_equal(const LLDate& timeout_time, const value_type& value) + { + return wait_until_equal(super::convert(timeout_time), value); } /** @@ -244,10 +292,21 @@ public: */ template <typename Rep, typename Period> bool wait_for_equal(const std::chrono::duration<Rep, Period>& timeout_duration, - const DATA& value) + const value_type& value) { return super::wait_for(timeout_duration, - [&value](const DATA& data){ return (data == value); }); + [&value](const value_type& data){ return (data == value); }); + } + + /** + * This wait_for_equal() overload accepts F32Milliseconds as the duration. + * Any duration unit defined in llunits.h is implicitly convertible to + * F32Milliseconds. The semantics of this method are the same as the + * generic wait_for_equal() method. + */ + bool wait_for_equal(F32Milliseconds timeout_duration, const value_type& value) + { + return wait_for_equal(super::convert(timeout_duration), value); } /** @@ -255,9 +314,9 @@ public: * locks the mutex and, until the stored DATA no longer equals that value, * calls wait() on the condition_variable. */ - void wait_unequal(const DATA& value) + void wait_unequal(const value_type& value) { - super::wait([&value](const DATA& data){ return (data != value); }); + super::wait([&value](const value_type& data){ return (data != value); }); } /** @@ -270,10 +329,19 @@ public: */ template <typename Clock, typename Duration> bool wait_until_unequal(const std::chrono::time_point<Clock, Duration>& timeout_time, - const DATA& value) + const value_type& value) { return super::wait_until(timeout_time, - [&value](const DATA& data){ return (data != value); }); + [&value](const value_type& data){ return (data != value); }); + } + + /** + * This wait_until_unequal() overload accepts LLDate as the time_point. + * Its semantics are the same as the generic wait_until_unequal() method. + */ + bool wait_until_unequal(const LLDate& timeout_time, const value_type& value) + { + return wait_until_unequal(super::convert(timeout_time), value); } /** @@ -286,22 +354,48 @@ public: */ template <typename Rep, typename Period> bool wait_for_unequal(const std::chrono::duration<Rep, Period>& timeout_duration, - const DATA& value) + const value_type& value) { return super::wait_for(timeout_duration, - [&value](const DATA& data){ return (data != value); }); + [&value](const value_type& data){ return (data != value); }); + } + + /** + * This wait_for_unequal() overload accepts F32Milliseconds as the duration. + * Any duration unit defined in llunits.h is implicitly convertible to + * F32Milliseconds. The semantics of this method are the same as the + * generic wait_for_unequal() method. + */ + bool wait_for_unequal(F32Milliseconds timeout_duration, const value_type& value) + { + return wait_for_unequal(super::convert(timeout_duration), value); } + +protected: + using super::convert; }; /// Using bool as LLScalarCond's DATA seems like a particularly useful case using LLBoolCond = LLScalarCond<bool>; -// LLOneShotCond -- init false, set (and wait for) true? Or full suite? +/// LLOneShotCond -- init false, set (and wait for) true class LLOneShotCond: public LLBoolCond { using super = LLBoolCond; public: + using super::value_type; + using super::get; + using super::wait; + using super::wait_until; + using super::wait_for; + using super::wait_equal; + using super::wait_until_equal; + using super::wait_for_equal; + using super::wait_unequal; + using super::wait_until_unequal; + using super::wait_for_unequal; + /// The bool stored in LLOneShotCond is initially false LLOneShotCond(): super(false) {} @@ -323,7 +417,7 @@ public: */ void wait() { - super::wait_equal(true); + super::wait_unequal(false); } /** @@ -336,7 +430,16 @@ public: template <typename Clock, typename Duration> bool wait_until(const std::chrono::time_point<Clock, Duration>& timeout_time) { - return super::wait_until_equal(timeout_time, true); + return super::wait_until_unequal(timeout_time, false); + } + + /** + * This wait_until() overload accepts LLDate as the time_point. + * Its semantics are the same as the generic wait_until() method. + */ + bool wait_until(const LLDate& timeout_time) + { + return wait_until(super::convert(timeout_time)); } /** @@ -349,7 +452,18 @@ public: template <typename Rep, typename Period> bool wait_for(const std::chrono::duration<Rep, Period>& timeout_duration) { - return super::wait_for_equal(timeout_duration, true); + return super::wait_for_unequal(timeout_duration, false); + } + + /** + * This wait_for() overload accepts F32Milliseconds as the duration. + * Any duration unit defined in llunits.h is implicitly convertible to + * F32Milliseconds. The semantics of this method are the same as the + * generic wait_for() method. + */ + bool wait_for(F32Milliseconds timeout_duration) + { + return wait_for(super::convert(timeout_duration)); } }; |