// Copyright 2020 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package utils import ( "math" "sync" "github.com/ethereum/go-ethereum/common/mclock" ) // ExpiredValue is a scalar value that is continuously expired (decreased // exponentially) based on the provided logarithmic expiration offset value. // // The formula for value calculation is: base*2^(exp-logOffset). In order to // simplify the calculation of ExpiredValue, its value is expressed in the form // of an exponent with a base of 2. // // Also here is a trick to reduce a lot of calculations. In theory, when a value X // decays over time and then a new value Y is added, the final result should be // X*2^(exp-logOffset)+Y. However it's very hard to represent in memory. // So the trick is using the idea of inflation instead of exponential decay. At this // moment the temporary value becomes: X*2^exp+Y*2^logOffset_1, apply the exponential // decay when we actually want to calculate the value. // // e.g. // t0: V = 100 // t1: add 30, inflationary value is: 100 + 30/0.3, 0.3 is the decay coefficient // t2: get value, decay coefficient is 0.2 now, final result is: 200*0.2 = 40 type ExpiredValue struct { Base, Exp uint64 // rlp encoding works by default } // ExpirationFactor is calculated from logOffset. 1 <= Factor < 2 and Factor*2^Exp // describes the multiplier applicable for additions and the divider for readouts. // If logOffset changes slowly then it saves some expensive operations to not calculate // them for each addition and readout but cache this intermediate form for some time. // It is also useful for structures where multiple values are expired with the same // Expirer. type ExpirationFactor struct { Exp uint64 Factor float64 } // ExpFactor calculates ExpirationFactor based on logOffset func ExpFactor(logOffset Fixed64) ExpirationFactor { return ExpirationFactor{Exp: logOffset.ToUint64(), Factor: logOffset.Fraction().Pow2()} } // Value calculates the expired value based on a floating point base and integer // power-of-2 exponent. This function should be used by multi-value expired structures. func (e ExpirationFactor) Value(base float64, exp uint64) float64 { return base / e.Factor * math.Pow(2, float64(int64(exp-e.Exp))) } // value calculates the value at the given moment. func (e ExpiredValue) Value(logOffset Fixed64) uint64 { offset := Uint64ToFixed64(e.Exp) - logOffset return uint64(float64(e.Base) * offset.Pow2()) } // add adds a signed value at the given moment func (e *ExpiredValue) Add(amount int64, logOffset Fixed64) int64 { integer, frac := logOffset.ToUint64(), logOffset.Fraction() factor := frac.Pow2() base := factor * float64(amount) if integer < e.Exp { base /= math.Pow(2, float64(e.Exp-integer)) } if integer > e.Exp { e.Base >>= (integer - e.Exp) e.Exp = integer } if base >= 0 || uint64(-base) <= e.Base { // The conversion from negative float64 to // uint64 is undefined in golang, and doesn't // work with ARMv8. More details at: // https://github.com/golang/go/issues/43047 if base >= 0 { e.Base += uint64(base) } else { e.Base -= uint64(-base) } return amount } net := int64(-float64(e.Base) / factor) e.Base = 0 return net } // addExp adds another ExpiredValue func (e *ExpiredValue) AddExp(a ExpiredValue) { if e.Exp > a.Exp { a.Base >>= (e.Exp - a.Exp) } if e.Exp < a.Exp { e.Base >>= (a.Exp - e.Exp) e.Exp = a.Exp } e.Base += a.Base } // subExp subtracts another ExpiredValue func (e *ExpiredValue) SubExp(a ExpiredValue) { if e.Exp > a.Exp { a.Base >>= (e.Exp - a.Exp) } if e.Exp < a.Exp { e.Base >>= (a.Exp - e.Exp) e.Exp = a.Exp } if e.Base > a.Base { e.Base -= a.Base } else { e.Base = 0 } } // IsZero returns true if the value is zero func (e *ExpiredValue) IsZero() bool { return e.Base == 0 } // LinearExpiredValue is very similar with the expiredValue which the value // will continuously expired. But the different part is it's expired linearly. type LinearExpiredValue struct { Offset uint64 // The latest time offset Val uint64 // The remaining value, can never be negative Rate mclock.AbsTime `rlp:"-"` // Expiration rate(by nanosecond), will ignored by RLP } // value calculates the value at the given moment. This function always has the // assumption that the given timestamp shouldn't less than the recorded one. func (e LinearExpiredValue) Value(now mclock.AbsTime) uint64 { offset := uint64(now / e.Rate) if e.Offset < offset { diff := offset - e.Offset if e.Val >= diff { e.Val -= diff } else { e.Val = 0 } } return e.Val } // add adds a signed value at the given moment. This function always has the // assumption that the given timestamp shouldn't less than the recorded one. func (e *LinearExpiredValue) Add(amount int64, now mclock.AbsTime) uint64 { offset := uint64(now / e.Rate) if e.Offset < offset { diff := offset - e.Offset if e.Val >= diff { e.Val -= diff } else { e.Val = 0 } e.Offset = offset } if amount < 0 && uint64(-amount) > e.Val { e.Val = 0 } else { e.Val = uint64(int64(e.Val) + amount) } return e.Val } // ValueExpirer controls value expiration rate type ValueExpirer interface { SetRate(now mclock.AbsTime, rate float64) SetLogOffset(now mclock.AbsTime, logOffset Fixed64) LogOffset(now mclock.AbsTime) Fixed64 } // Expirer changes logOffset with a linear rate which can be changed during operation. // It is not thread safe, if access by multiple goroutines is needed then it should be // encapsulated into a locked structure. // Note that if neither SetRate nor SetLogOffset are used during operation then LogOffset // is thread safe. type Expirer struct { lock sync.RWMutex logOffset Fixed64 rate float64 lastUpdate mclock.AbsTime } // SetRate changes the expiration rate which is the inverse of the time constant in // nanoseconds. func (e *Expirer) SetRate(now mclock.AbsTime, rate float64) { e.lock.Lock() defer e.lock.Unlock() dt := now - e.lastUpdate if dt > 0 { e.logOffset += Fixed64(logToFixedFactor * float64(dt) * e.rate) } e.lastUpdate = now e.rate = rate } // SetLogOffset sets logOffset instantly. func (e *Expirer) SetLogOffset(now mclock.AbsTime, logOffset Fixed64) { e.lock.Lock() defer e.lock.Unlock() e.lastUpdate = now e.logOffset = logOffset } // LogOffset returns the current logarithmic offset. func (e *Expirer) LogOffset(now mclock.AbsTime) Fixed64 { e.lock.RLock() defer e.lock.RUnlock() dt := now - e.lastUpdate if dt <= 0 { return e.logOffset } return e.logOffset + Fixed64(logToFixedFactor*float64(dt)*e.rate) } // fixedFactor is the fixed point multiplier factor used by Fixed64. const fixedFactor = 0x1000000 // Fixed64 implements 64-bit fixed point arithmetic functions. type Fixed64 int64 // Uint64ToFixed64 converts uint64 integer to Fixed64 format. func Uint64ToFixed64(f uint64) Fixed64 { return Fixed64(f * fixedFactor) } // float64ToFixed64 converts float64 to Fixed64 format. func Float64ToFixed64(f float64) Fixed64 { return Fixed64(f * fixedFactor) } // toUint64 converts Fixed64 format to uint64. func (f64 Fixed64) ToUint64() uint64 { return uint64(f64) / fixedFactor } // fraction returns the fractional part of a Fixed64 value. func (f64 Fixed64) Fraction() Fixed64 { return f64 % fixedFactor } var ( logToFixedFactor = float64(fixedFactor) / math.Log(2) fixedToLogFactor = math.Log(2) / float64(fixedFactor) ) // pow2Fixed returns the base 2 power of the fixed point value. func (f64 Fixed64) Pow2() float64 { return math.Exp(float64(f64) * fixedToLogFactor) }