package regexp2 import ( "sync" "sync/atomic" "time" ) // fasttime holds a time value (ticks since clock initialization) type fasttime int64 // fastclock provides a fast clock implementation. // // A background goroutine periodically stores the current time // into an atomic variable. // // A deadline can be quickly checked for expiration by comparing // its value to the clock stored in the atomic variable. // // The goroutine automatically stops once clockEnd is reached. // (clockEnd covers the largest deadline seen so far + some // extra time). This ensures that if regexp2 with timeouts // stops being used we will stop background work. type fastclock struct { // current and clockEnd can be read via atomic loads. // Reads and writes of other fields require mu to be held. mu sync.Mutex start time.Time // Time corresponding to fasttime(0) current atomicTime // Current time (approximate) clockEnd atomicTime // When clock updater is supposed to stop (>= any existing deadline) running bool // Is a clock updater running? } var fast fastclock // reached returns true if current time is at or past t. func (t fasttime) reached() bool { return fast.current.read() >= t } // makeDeadline returns a time that is approximately time.Now().Add(d) func makeDeadline(d time.Duration) fasttime { // Increase the deadline since the clock we are reading may be // just about to tick forwards. end := fast.current.read() + durationToTicks(d+clockPeriod) // Start or extend clock if necessary. if end > fast.clockEnd.read() { extendClock(end) } return end } // extendClock ensures that clock is live and will run until at least end. func extendClock(end fasttime) { fast.mu.Lock() defer fast.mu.Unlock() if fast.start.IsZero() { fast.start = time.Now() } // Extend the running time to cover end as well as a bit of slop. if shutdown := end + durationToTicks(time.Second); shutdown > fast.clockEnd.read() { fast.clockEnd.write(shutdown) } // Start clock if necessary if !fast.running { fast.running = true go runClock() } } func durationToTicks(d time.Duration) fasttime { // Downscale nanoseconds to approximately a millisecond so that we can avoid // overflow even if the caller passes in math.MaxInt64. return fasttime(d) >> 20 } // clockPeriod is the approximate interval between updates of approximateClock. const clockPeriod = 100 * time.Millisecond func runClock() { fast.mu.Lock() defer fast.mu.Unlock() for fast.current.read() <= fast.clockEnd.read() { // Unlock while sleeping. fast.mu.Unlock() time.Sleep(clockPeriod) fast.mu.Lock() newTime := durationToTicks(time.Since(fast.start)) fast.current.write(newTime) } fast.running = false } type atomicTime struct{ v int64 } // Should change to atomic.Int64 when we can use go 1.19 func (t *atomicTime) read() fasttime { return fasttime(atomic.LoadInt64(&t.v)) } func (t *atomicTime) write(v fasttime) { atomic.StoreInt64(&t.v, int64(v)) }