hledger/Ledger/Amount.hs

211 lines
7.7 KiB
Haskell

{-|
An 'Amount' is some quantity of money, shares, or anything else.
A simple amount is a 'Commodity', quantity pair:
@
$1
£-50
EUR 3.44
GOOG 500
1.5h
90apples
0
@
A 'MixedAmount' is zero or more simple amounts:
@
$50, EUR 3, AAPL 500
16h, $13.55, oranges 6
@
Not implemented:
Commodities may be convertible or not. A mixed amount containing only
convertible commodities can be converted to a simple amount. Arithmetic
examples:
@
$1 - $5 = $-4
$1 + EUR 0.76 = $2
EUR0.76 + $1 = EUR 1.52
EUR0.76 - $1 = 0
($5, 2h) + $1 = ($6, 2h)
($50, EUR 3, AAPL 500) + ($13.55, oranges 6) = $67.51, AAPL 500, oranges 6
($50, EUR 3) * $-1 = $-53.96
($50, AAPL 500) * $-1 = error
@
-}
module Ledger.Amount
where
import qualified Data.Map as Map
import Ledger.Utils
import Ledger.Types
import Ledger.Commodity
instance Show Amount where show = showAmount
instance Show MixedAmount where show = showMixedAmount
instance Num Amount where
abs (Amount c q p) = Amount c (abs q) p
signum (Amount c q p) = Amount c (signum q) p
fromInteger i = Amount (comm "") (fromInteger i) Nothing
(+) = amountop (+)
(-) = amountop (-)
(*) = amountop (*)
instance Ord Amount where
compare (Amount ac aq ap) (Amount bc bq bp) = compare (ac,aq,ap) (bc,bq,bp)
instance Num MixedAmount where
fromInteger i = Mixed [Amount (comm "") (fromInteger i) Nothing]
negate (Mixed as) = Mixed $ map negateAmountPreservingPrice as
(+) (Mixed as) (Mixed bs) = normaliseMixedAmount $ Mixed $ as ++ bs
(*) = error "programming error, mixed amounts do not support multiplication"
abs = error "programming error, mixed amounts do not support abs"
signum = error "programming error, mixed amounts do not support signum"
instance Ord MixedAmount where
compare (Mixed as) (Mixed bs) = compare as bs
negateAmountPreservingPrice a = (-a){price=price a}
-- | Apply a binary arithmetic operator to two amounts - converting to the
-- second one's commodity, adopting the lowest precision, and discarding
-- any price information. (Using the second commodity is best since sum
-- and other folds start with a no-commodity amount.)
amountop :: (Double -> Double -> Double) -> Amount -> Amount -> Amount
amountop op a@(Amount ac aq ap) b@(Amount bc bq bp) =
Amount bc ((quantity $ convertAmountTo bc a) `op` bq) Nothing
-- | Convert an amount to the commodity of its saved price, if any.
costOfAmount :: Amount -> Amount
costOfAmount a@(Amount _ _ Nothing) = a
costOfAmount a@(Amount _ q (Just price))
| isZeroMixedAmount price = nullamt
| otherwise = Amount pc (pq*q) Nothing
where (Amount pc pq _) = head $ amounts price
-- | Convert an amount to the specified commodity using the appropriate
-- exchange rate (which is currently always 1).
convertAmountTo :: Commodity -> Amount -> Amount
convertAmountTo c2 (Amount c1 q p) = Amount c2 (q * conversionRate c1 c2) Nothing
-- | Get the string representation of an amount, based on its commodity's
-- display settings.
showAmount :: Amount -> String
showAmount a@(Amount (Commodity {symbol=sym,side=side,spaced=spaced}) q pri)
| sym=="AUTO" = "" -- can display one of these in an error message
| side==L = printf "%s%s%s%s" sym space quantity price
| side==R = printf "%s%s%s%s" quantity space sym price
where
space = if spaced then " " else ""
quantity = showAmount' a
price = case pri of (Just pamt) -> " @ " ++ showMixedAmount pamt
Nothing -> ""
-- | Get the string representation (of the number part of) of an amount
showAmount' :: Amount -> String
showAmount' (Amount (Commodity {comma=comma,precision=p}) q _) = quantity
where
quantity = commad $ printf ("%."++show p++"f") q
commad = if comma then punctuatethousands else id
-- | Add thousands-separating commas to a decimal number string
punctuatethousands :: String -> String
punctuatethousands s =
sign ++ (addcommas int) ++ frac
where
(sign,num) = break isDigit s
(int,frac) = break (=='.') num
addcommas = reverse . concat . intersperse "," . triples . reverse
triples [] = []
triples l = [take 3 l] ++ (triples $ drop 3 l)
-- | Does this amount appear to be zero when displayed with its given precision ?
isZeroAmount :: Amount -> Bool
isZeroAmount a = null $ filter (`elem` "123456789") $ showAmount a
-- | Is this amount "really" zero, regardless of the display precision ?
-- Since we are using floating point, for now just test to some high precision.
isReallyZeroAmount :: Amount -> Bool
isReallyZeroAmount a = null $ filter (`elem` "123456789") $ printf "%.10f" $ quantity a
-- | Access a mixed amount's components.
amounts :: MixedAmount -> [Amount]
amounts (Mixed as) = as
-- | Does this mixed amount appear to be zero - empty, or
-- containing only simple amounts which appear to be zero ?
isZeroMixedAmount :: MixedAmount -> Bool
isZeroMixedAmount = all isZeroAmount . amounts . normaliseMixedAmount
-- | Is this mixed amount "really" zero ? See isReallyZeroAmount.
isReallyZeroMixedAmount :: MixedAmount -> Bool
isReallyZeroMixedAmount = all isReallyZeroAmount . amounts . normaliseMixedAmount
-- | MixedAmount derives Eq in Types.hs, but that doesn't know that we
-- want $0 = EUR0 = 0. Yet we don't want to drag all this code in there.
-- When zero equality is important, use this, for now; should be used
-- everywhere.
mixedAmountEquals :: MixedAmount -> MixedAmount -> Bool
mixedAmountEquals a b = amounts a' == amounts b' || (isZeroMixedAmount a' && isZeroMixedAmount b')
where a' = normaliseMixedAmount a
b' = normaliseMixedAmount b
-- | Get the string representation of a mixed amount, showing each of
-- its component amounts. NB a mixed amount can have an empty amounts
-- list in which case it shows as \"\".
showMixedAmount :: MixedAmount -> String
showMixedAmount m = concat $ intersperse "\n" $ map showfixedwidth as
where
(Mixed as) = normaliseMixedAmount m
width = maximum $ map (length . show) $ as
showfixedwidth = printf (printf "%%%ds" width) . show
-- | Get the string representation of a mixed amount, and if it
-- appears to be all zero just show a bare 0, ledger-style.
showMixedAmountOrZero :: MixedAmount -> String
showMixedAmountOrZero a
| isZeroMixedAmount a = "0"
| otherwise = showMixedAmount a
-- | Simplify a mixed amount by combining any component amounts which have
-- the same commodity and the same price. Also removes redundant zero amounts
-- and adds a single zero amount if there are no amounts at all.
normaliseMixedAmount :: MixedAmount -> MixedAmount
normaliseMixedAmount (Mixed as) = Mixed as''
where
as'' = map sumAmountsPreservingPrice $ group $ sort as'
sort = sortBy cmpsymbolandprice
cmpsymbolandprice a1 a2 = compare (sym a1,price a1) (sym a2,price a2)
group = groupBy samesymbolandprice
samesymbolandprice a1 a2 = (sym a1 == sym a2) && (price a1 == price a2)
sym = symbol . commodity
as' | null nonzeros = [head $ zeros ++ [nullamt]]
| otherwise = nonzeros
(zeros,nonzeros) = partition isZeroAmount as
sumAmountsPreservingPrice [] = nullamt
sumAmountsPreservingPrice as = (sum as){price=price $ head as}
-- | Convert a mixed amount's component amounts to the commodity of their
-- saved price, if any.
costOfMixedAmount :: MixedAmount -> MixedAmount
costOfMixedAmount (Mixed as) = Mixed $ map costOfAmount as
-- | The empty simple amount.
nullamt :: Amount
nullamt = Amount unknown 0 Nothing
-- | The empty mixed amount.
nullmixedamt :: MixedAmount
nullmixedamt = Mixed []
-- | A temporary value for parsed transactions which had no amount specified.
missingamt :: MixedAmount
missingamt = Mixed [Amount (Commodity {symbol="AUTO",side=L,spaced=False,comma=False,precision=0}) 0 Nothing]