// Copyright (c) 2013, 2014 Conformal Systems LLC. // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package btcutil import ( "errors" "math" "strconv" ) // AmountUnit describes a method of converting an Amount to something // other than the base unit of a bitcoin. The value of the AmountUnit // is the exponent component of the decadic multiple to convert from // an amount in bitcoin to an amount counted in units. type AmountUnit int // These constants define various units used when describing a bitcoin // monetary amount. const ( AmountMegaBTC AmountUnit = 6 AmountKiloBTC AmountUnit = 3 AmountBTC AmountUnit = 0 AmountMilliBTC AmountUnit = -3 AmountMicroBTC AmountUnit = -6 AmountSatoshi AmountUnit = -8 ) // String returns the unit as a string. For recognized units, the SI // prefix is used, or "Satoshi" for the base unit. For all unrecognized // units, "1eN BTC" is returned, where N is the AmountUnit. func (u AmountUnit) String() string { switch u { case AmountMegaBTC: return "MBTC" case AmountKiloBTC: return "kBTC" case AmountBTC: return "BTC" case AmountMilliBTC: return "mBTC" case AmountMicroBTC: return "μBTC" case AmountSatoshi: return "Satoshi" default: return "1e" + strconv.FormatInt(int64(u), 10) + " BTC" } } // Amount represents the base bitcoin monetary unit (colloquially referred // to as a `Satoshi'). A single Amount is equal to 1e-8 of a bitcoin. type Amount int64 // round converts a floating point number, which may or may not be representable // as an integer, to the Amount integer type by rounding to the nearest integer. // This is performed by adding or subtracting 0.5 depending on the sign, and // relying on integer truncation to round the value to the nearest Amount. func round(f float64) Amount { if f < 0 { return Amount(f - 0.5) } return Amount(f + 0.5) } // NewAmount creates an Amount from a floating point value representing // some value in bitcoin. NewAmount errors if f is NaN or +-Infinity, but // does not check that the amount is within the total amount of bitcoin // producable as f may not refer to an amount at a single moment in time. func NewAmount(f float64) (Amount, error) { // The amount is only considered invalid if it cannot be represented // as an integer type. This may happen if f is NaN or +-Infinity. switch { case math.IsNaN(f): fallthrough case math.IsInf(f, 1): fallthrough case math.IsInf(f, -1): return 0, errors.New("invalid bitcoin amount") } return round(f * SatoshiPerBitcoin), nil } // ToUnit converts a monetary amount counted in bitcoin base units to a // floating point value representing an amount of bitcoin. func (a Amount) ToUnit(u AmountUnit) float64 { return float64(a) / math.Pow10(int(u+8)) } // ToBTC is the equivalent of calling ToUnit with AmountBTC. func (a Amount) ToBTC() float64 { return a.ToUnit(AmountBTC) } // Format formats a monetary amount counted in bitcoin base units as a // string for a given unit. The conversion will succeed for any unit, // however, known units will be formated with an appended label describing // the units with SI notation, or "Satoshi" for the base unit. func (a Amount) Format(u AmountUnit) string { units := " " + u.String() return strconv.FormatFloat(a.ToUnit(u), 'f', -int(u+8), 64) + units } // String is the equivalent of calling Format with AmountBTC. func (a Amount) String() string { return a.Format(AmountBTC) } // MulF64 multiplies an Amount by a floating point value. While this is not // an operation that must typically be done by a full node or wallet, it is // useful for services that build on top of bitcoin (for example, calculating // a fee by multiplying by a percentage). func (a Amount) MulF64(f float64) Amount { return round(float64(a) * f) }