{-# LANGUAGE StandaloneDeriving #-} {-| A simple "Amount" is some quantity of money, shares, or anything else. It has a (possibly null) "Commodity" and a numeric quantity: @ $1 £-50 EUR 3.44 GOOG 500 1.5h 90 apples 0 @ It may also have an assigned unit price, which is another (unpriced) simple amount in a different commodity. If present, this is rendered like so: @ EUR 3 \@ $1.35 @ A "MixedAmount" is zero or more simple amounts, so can represent multiple commodities; this is the type most often used: @ 0 $50 + EUR 3 16h + $13.55 + AAPL 500 + 6 oranges @ When a mixed amount has been \"normalised\", it has no more than one amount in each commodity and no zero amounts; or it has just a single zero amount and no others. We can do two kinds of limited arithmetic with simple or mixed amounts: price-preserving (for amounts with the same prices) or price-ignoring (ignores and discards any prices). -} -- XXX due for review/rewrite module Hledger.Data.Amount ( -- * Amount nullamt, amountWithCommodity, canonicaliseAmountCommodity, setAmountPrecision, -- ** arithmetic costOfAmount, divideAmount, -- ** rendering showAmount, showAmountDebug, showAmountWithoutPrice, maxprecision, maxprecisionwithpoint, -- * MixedAmount nullmixedamt, missingamt, amounts, normaliseMixedAmount, canonicaliseMixedAmountCommodity, mixedAmountWithCommodity, setMixedAmountPrecision, -- ** arithmetic costOfMixedAmount, divideMixedAmount, isNegativeMixedAmount, isZeroMixedAmount, isReallyZeroMixedAmountCost, -- ** rendering showMixedAmount, showMixedAmountDebug, showMixedAmountOrZero, showMixedAmountOrZeroWithoutPrice, showMixedAmountWithoutPrice, showMixedAmountWithPrecision, -- * misc. tests_Hledger_Data_Amount ) where import Data.Char (isDigit) import Data.List import Data.Map (findWithDefault) import Test.HUnit import Text.Printf import qualified Data.Map as Map import Hledger.Data.Types import Hledger.Data.Commodity import Hledger.Utils deriving instance Show HistoricalPrice ------------------------------------------------------------------------------- -- Amount instance Show Amount where show = showAmount 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 negate a@Amount{quantity=q} = a{quantity=(-q)} (+) = similarAmountsOp (+) (-) = similarAmountsOp (-) (*) = similarAmountsOp (*) -- | The empty simple amount. nullamt :: Amount nullamt = Amount unknown 0 Nothing -- | Apply a binary arithmetic operator to two amounts, ignoring and -- discarding any assigned prices, and converting the first to the -- commodity of the second in a simplistic way (1-1 exchange rate). -- The highest precision of either amount is preserved in the result. similarAmountsOp :: (Double -> Double -> Double) -> Amount -> Amount -> Amount similarAmountsOp op a@(Amount Commodity{precision=ap} _ _) (Amount bc@Commodity{precision=bp} bq _) = Amount bc{precision=max ap bp} (quantity (amountWithCommodity bc a) `op` bq) Nothing -- | Convert an amount to the specified commodity, ignoring and discarding -- any assigned prices and assuming an exchange rate of 1. amountWithCommodity :: Commodity -> Amount -> Amount amountWithCommodity c (Amount _ q _) = Amount c q Nothing -- | Convert an amount to the commodity of its assigned price, if any. Notes: -- - price amounts must be MixedAmounts with exactly one component Amount (or there will be a runtime error) -- - price amounts should be positive, though this is not currently enforced costOfAmount :: Amount -> Amount costOfAmount a@(Amount _ q price) = case price of Nothing -> a Just (UnitPrice (Mixed [Amount pc pq Nothing])) -> Amount pc (pq*q) Nothing Just (TotalPrice (Mixed [Amount pc pq Nothing])) -> Amount pc (pq*signum q) Nothing _ -> error' "costOfAmount: Malformed price encountered, programmer error" -- | Divide an amount's quantity by a constant. divideAmount :: Amount -> Double -> Amount divideAmount a@Amount{quantity=q} d = a{quantity=q/d} -- | Is this amount negative ? The price is ignored. isNegativeAmount :: Amount -> Bool isNegativeAmount Amount{quantity=q} = q < 0 -- | Does this amount appear to be zero when displayed with its given precision ? isZeroAmount :: Amount -> Bool isZeroAmount = null . filter (`elem` "123456789") . showAmountWithoutPriceOrCommodity -- | 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 = null . filter (`elem` "123456789") . printf ("%."++show zeroprecision++"f") . quantity where zeroprecision = 8 -- | Get the string representation of an amount, based on its commodity's -- display settings except using the specified precision. showAmountWithPrecision :: Int -> Amount -> String showAmountWithPrecision p = showAmount . setAmountPrecision p -- | Set the display precision in the amount's commodity. setAmountPrecision :: Int -> Amount -> Amount setAmountPrecision p a@Amount{commodity=c} = a{commodity=c{precision=p}} -- | Get the unambiguous string representation of an amount, for debugging. showAmountDebug :: Amount -> String showAmountDebug (Amount c q pri) = printf "Amount {commodity = %s, quantity = %s, price = %s}" (show c) (show q) (maybe "" showPriceDebug pri) -- | Get the string representation of an amount, without any \@ price. showAmountWithoutPrice :: Amount -> String showAmountWithoutPrice a = showAmount a{price=Nothing} -- | Get the string representation of an amount, without any price or commodity symbol. showAmountWithoutPriceOrCommodity :: Amount -> String showAmountWithoutPriceOrCommodity a@Amount{commodity=c} = showAmount a{commodity=c{symbol=""}, price=Nothing} showPrice :: Price -> String showPrice (UnitPrice pa) = " @ " ++ showMixedAmount pa showPrice (TotalPrice pa) = " @@ " ++ showMixedAmount pa showPriceDebug :: Price -> String showPriceDebug (UnitPrice pa) = " @ " ++ showMixedAmountDebug pa showPriceDebug (TotalPrice pa) = " @@ " ++ showMixedAmountDebug pa -- | Get the string representation of an amount, based on its commodity's -- display settings. Amounts whose string representation would mean zero -- are rendered as just "0". showAmount :: Amount -> String showAmount (Amount (Commodity {symbol="AUTO"}) _ _) = "" -- can appear in an error message showAmount a@(Amount (Commodity {symbol=sym,side=side,spaced=spaced}) _ pri) = case side of L -> printf "%s%s%s%s" sym' space quantity' price R -> printf "%s%s%s%s" quantity' space sym' price where quantity = showamountquantity a displayingzero = null $ filter (`elem` "123456789") $ quantity (quantity',sym') | displayingzero = ("0","") | otherwise = (quantity,quoteCommoditySymbolIfNeeded sym) space = if (not (null sym') && spaced) then " " else "" price = maybe "" showPrice pri -- | Get the string representation of the number part of of an amount, -- using the display settings from its commodity. showamountquantity :: Amount -> String showamountquantity (Amount (Commodity {decimalpoint=d,precision=p,separator=s,separatorpositions=spos}) q _) = punctuatenumber d s spos $ qstr where -- isint n = fromIntegral (round n) == n qstr -- p == maxprecision && isint q = printf "%d" (round q::Integer) | p == maxprecisionwithpoint = printf "%f" q | p == maxprecision = chopdotzero $ printf "%f" q | otherwise = printf ("%."++show p++"f") q -- | Replace a number string's decimal point with the specified character, -- and add the specified digit group separators. punctuatenumber :: Char -> Char -> [Int] -> String -> String punctuatenumber dec sep grps str = sign ++ reverse (addseps sep (extend grps) (reverse int)) ++ frac'' where (sign,num) = break isDigit str (int,frac) = break (=='.') num frac' = dropWhile (=='.') frac frac'' | null frac' = "" | otherwise = dec:frac' extend [] = [] extend gs = init gs ++ repeat (last gs) addseps _ [] str = str addseps sep (g:gs) str | length str <= g = str | otherwise = let (s,rest) = splitAt g str in s ++ [sep] ++ addseps sep gs rest chopdotzero str = reverse $ case reverse str of '0':'.':s -> s s -> s -- | For rendering: a special precision value which means show all available digits. maxprecision :: Int maxprecision = 999998 -- | For rendering: a special precision value which forces display of a decimal point. maxprecisionwithpoint :: Int maxprecisionwithpoint = 999999 -- | Replace an amount's commodity with the canonicalised version from -- the provided commodity map. canonicaliseAmountCommodity :: Maybe (Map.Map String Commodity) -> Amount -> Amount canonicaliseAmountCommodity Nothing = id canonicaliseAmountCommodity (Just canonicalcommoditymap) = fixamount where -- like journalCanonicaliseAmounts fixamount a@Amount{commodity=c} = a{commodity=fixcommodity c} fixcommodity c@Commodity{symbol=s} = findWithDefault c s canonicalcommoditymap ------------------------------------------------------------------------------- -- MixedAmount instance Show MixedAmount where show = showMixedAmount instance Num MixedAmount where fromInteger i = Mixed [Amount (comm "") (fromInteger i) Nothing] negate (Mixed as) = Mixed $ map negate 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" -- | The empty mixed amount. nullmixedamt :: MixedAmount nullmixedamt = Mixed [] -- | A temporary value for parsed transactions which had no amount specified. missingamt :: MixedAmount missingamt = Mixed [Amount unknown{symbol="AUTO"} 0 Nothing] -- | Simplify a mixed amount by removing redundancy in its component amounts, -- as follows: -- -- 1. combine amounts which have the same commodity, discarding all but the first's price. -- -- 2. remove zero amounts -- -- 3. if there are no amounts at all, add a single zero amount normaliseMixedAmount :: MixedAmount -> MixedAmount normaliseMixedAmount (Mixed as) = Mixed as'' where as'' = if null nonzeros then [nullamt] else nonzeros (_,nonzeros) = partition (\a -> isReallyZeroAmount a && Mixed [a] /= missingamt) as' as' = map sumAmountsDiscardingAllButFirstPrice $ group $ sort as sort = sortBy (\a1 a2 -> compare (sym a1) (sym a2)) group = groupBy (\a1 a2 -> sym a1 == sym a2) sym = symbol . commodity sumAmountsDiscardingAllButFirstPrice [] = nullamt sumAmountsDiscardingAllButFirstPrice as = (sum as){price=price $ head as} -- | Get a mixed amount's component amounts. amounts :: MixedAmount -> [Amount] amounts (Mixed as) = as -- | Convert a mixed amount's component amounts to the commodity of their -- assigned price, if any. costOfMixedAmount :: MixedAmount -> MixedAmount costOfMixedAmount (Mixed as) = Mixed $ map costOfAmount as -- | Divide a mixed amount's quantities by a constant. divideMixedAmount :: MixedAmount -> Double -> MixedAmount divideMixedAmount (Mixed as) d = Mixed $ map (flip divideAmount d) as -- | Is this mixed amount negative, if it can be normalised to a single commodity ? isNegativeMixedAmount :: MixedAmount -> Maybe Bool isNegativeMixedAmount m = case as of [a] -> Just $ isNegativeAmount a _ -> Nothing where as = amounts $ normaliseMixedAmount m -- | Does this mixed amount appear to be zero when displayed with its given precision ? isZeroMixedAmount :: MixedAmount -> Bool isZeroMixedAmount = all isZeroAmount . amounts . normaliseMixedAmount -- | Is this mixed amount "really" zero ? See isReallyZeroAmount. isReallyZeroMixedAmount :: MixedAmount -> Bool isReallyZeroMixedAmount = all isReallyZeroAmount . amounts . normaliseMixedAmount -- | Is this mixed amount "really" zero, after converting to cost -- commodities where possible ? isReallyZeroMixedAmountCost :: MixedAmount -> Bool isReallyZeroMixedAmountCost = isReallyZeroMixedAmount . costOfMixedAmount -- -- | Convert a mixed amount to the specified commodity, assuming an exchange rate of 1. mixedAmountWithCommodity :: Commodity -> MixedAmount -> Amount mixedAmountWithCommodity c (Mixed as) = Amount c total Nothing where total = sum $ map (quantity . amountWithCommodity c) as -- -- | MixedAmount derived Eq instance in Types.hs doesn't know that we -- -- want $0 = EUR0 = 0. Yet we don't want to drag all this code over there. -- -- For now, use this when cross-commodity zero equality is important. -- 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 = vConcatRightAligned $ map show $ amounts $ normaliseMixedAmount m -- | Set the display precision in the amount's commodities. setMixedAmountPrecision :: Int -> MixedAmount -> MixedAmount setMixedAmountPrecision p (Mixed as) = Mixed $ map (setAmountPrecision p) as -- | Get the string representation of a mixed amount, showing each of its -- component amounts with the specified precision, ignoring their -- commoditys' display precision settings. NB a mixed amount can have an -- empty amounts list in which case it shows as \"\". showMixedAmountWithPrecision :: Int -> MixedAmount -> String showMixedAmountWithPrecision p m = vConcatRightAligned $ map (showAmountWithPrecision p) $ amounts $ normaliseMixedAmount m -- | Get an unambiguous string representation of a mixed amount for debugging. showMixedAmountDebug :: MixedAmount -> String showMixedAmountDebug m = printf "Mixed [%s]" as where as = intercalate "\n " $ map showAmountDebug $ amounts $ normaliseMixedAmount m -- | Get the string representation of a mixed amount, but without -- any \@ prices. showMixedAmountWithoutPrice :: MixedAmount -> String showMixedAmountWithoutPrice m = concat $ intersperse "\n" $ map showfixedwidth as where (Mixed as) = normaliseMixedAmount $ stripPrices m stripPrices (Mixed as) = Mixed $ map stripprice as where stripprice a = a{price=Nothing} width = maximum $ map (length . show) as showfixedwidth = printf (printf "%%%ds" width) . showAmountWithoutPrice -- | 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 | a == missingamt = "" | isZeroMixedAmount a = "0" | otherwise = showMixedAmount a -- | Get the string representation of a mixed amount, or a bare 0, -- without any \@ prices. showMixedAmountOrZeroWithoutPrice :: MixedAmount -> String showMixedAmountOrZeroWithoutPrice a | isZeroMixedAmount a = "0" | otherwise = showMixedAmountWithoutPrice a -- | Replace a mixed amount's commodity with the canonicalised version from -- the provided commodity map. canonicaliseMixedAmountCommodity :: Maybe (Map.Map String Commodity) -> MixedAmount -> MixedAmount canonicaliseMixedAmountCommodity canonicalcommoditymap (Mixed as) = Mixed $ map (canonicaliseAmountCommodity canonicalcommoditymap) as ------------------------------------------------------------------------------- -- misc tests_Hledger_Data_Amount = TestList [ -- Amount "costOfAmount" ~: do costOfAmount (euros 1) `is` euros 1 costOfAmount (euros 2){price=Just $ UnitPrice $ Mixed [dollars 2]} `is` dollars 4 costOfAmount (euros 1){price=Just $ TotalPrice $ Mixed [dollars 2]} `is` dollars 2 costOfAmount (euros (-1)){price=Just $ TotalPrice $ Mixed [dollars 2]} `is` dollars (-2) ,"isZeroAmount" ~: do assertBool "" $ isZeroAmount $ Amount unknown 0 Nothing assertBool "" $ isZeroAmount $ dollars 0 ,"negating amounts" ~: do let a = dollars 1 negate a `is` a{quantity=(-1)} let b = (dollars 1){price=Just $ UnitPrice $ Mixed [euros 2]} negate b `is` b{quantity=(-1)} ,"adding amounts" ~: do let a1 = dollars 1.23 let a2 = dollars (-1.23) let a3 = dollars (-1.23) (a1 + a2) `is` Amount (comm "$") 0 Nothing (a1 + a3) `is` Amount (comm "$") 0 Nothing (a2 + a3) `is` Amount (comm "$") (-2.46) Nothing (a3 + a3) `is` Amount (comm "$") (-2.46) Nothing sum [a1,a2,a3,-a3] `is` Amount (comm "$") 0 Nothing -- highest precision is preserved let ap1 = (dollars 1){commodity=dollar{precision=1}} ap3 = (dollars 1){commodity=dollar{precision=3}} (sum [ap1,ap3]) `is` ap3{quantity=2} (sum [ap3,ap1]) `is` ap3{quantity=2} -- adding different commodities assumes conversion rate 1 assertBool "" $ isZeroAmount (a1 - euros 1.23) ,"showAmount" ~: do showAmount (dollars 0 + pounds 0) `is` "0" -- MixedAmount ,"normaliseMixedAmount" ~: do normaliseMixedAmount (Mixed []) `is` Mixed [nullamt] assertBool "" $ isZeroMixedAmount $ normaliseMixedAmount (Mixed [Amount {commodity=dollar, quantity=10, price=Nothing} ,Amount {commodity=dollar, quantity=10, price=Just (TotalPrice (Mixed [Amount {commodity=euro, quantity=7, price=Nothing}]))} ,Amount {commodity=dollar, quantity=(-10), price=Nothing} ,Amount {commodity=dollar, quantity=(-10), price=Just (TotalPrice (Mixed [Amount {commodity=euro, quantity=7, price=Nothing}]))} ]) ,"adding mixed amounts" ~: do let dollar0 = dollar{precision=0} (sum $ map (Mixed . (\a -> [a])) [Amount dollar 1.25 Nothing, Amount dollar0 (-1) Nothing, Amount dollar (-0.25) Nothing]) `is` Mixed [Amount unknown 0 Nothing] ,"showMixedAmount" ~: do showMixedAmount (Mixed [dollars 1]) `is` "$1.00" showMixedAmount (Mixed [(dollars 1){price=Just $ UnitPrice $ Mixed [euros 2]}]) `is` "$1.00 @ €2.00" showMixedAmount (Mixed [dollars 0]) `is` "0" showMixedAmount (Mixed []) `is` "0" showMixedAmount missingamt `is` "" ,"showMixedAmountOrZero" ~: do showMixedAmountOrZero (Mixed [Amount dollar 0 Nothing]) `is` "0" showMixedAmountOrZero (Mixed []) `is` "0" showMixedAmountOrZero missingamt `is` "" ,"showMixedAmountWithoutPrice" ~: do let a = (dollars 1){price=Just $ UnitPrice $ Mixed [euros 2]} showMixedAmountWithoutPrice (Mixed [a]) `is` "$1.00" showMixedAmountWithoutPrice (Mixed [a, (-a)]) `is` "0" ]