{-|
A simple 'Amount' is some quantity of money, shares, or anything else.
It has a (possibly null) 'CommoditySymbol' and a numeric quantity:

@
  $1
  £-50
  EUR 3.44
  GOOG 500
  1.5h
  90 apples
  0
@

It may also have an assigned 'Price', representing this amount's per-unit
or total cost in a different commodity. If present, this is rendered like
so:

@
  EUR 2 \@ $1.50  (unit price)
  EUR 2 \@\@ $3   (total price)
@

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.

Limited arithmetic with simple and mixed amounts is supported, best used
with similar amounts since it mostly ignores assigned prices and commodity
exchange rates.

-}

{-# LANGUAGE StandaloneDeriving, RecordWildCards, OverloadedStrings #-}

module Hledger.Data.Amount (
  -- * Amount
  amount,
  nullamt,
  missingamt,
  num,
  usd,
  eur,
  gbp,
  per,
  hrs,
  at,
  (@@),
  amountWithCommodity,
  -- ** arithmetic
  costOfAmount,
  amountToCost,
  divideAmount,
  multiplyAmount,
  divideAmountAndPrice,
  multiplyAmountAndPrice,
  amountTotalPriceToUnitPrice,
  -- ** rendering
  amountstyle,
  styleAmount,
  styleAmountExceptPrecision,
  showAmount,
  cshowAmount,
  showAmountWithZeroCommodity,
  showAmountDebug,
  showAmountWithoutPrice,
  maxprecision,
  maxprecisionwithpoint,
  setAmountPrecision,
  withPrecision,
  setFullPrecision,
  setNaturalPrecision,
  setNaturalPrecisionUpTo,
  setAmountInternalPrecision,
  withInternalPrecision,
  setAmountDecimalPoint,
  withDecimalPoint,
  canonicaliseAmount,
  -- * MixedAmount
  nullmixedamt,
  missingmixedamt,
  mixed,
  amounts,
  filterMixedAmount,
  filterMixedAmountByCommodity,
  normaliseMixedAmountSquashPricesForDisplay,
  normaliseMixedAmount,
  -- ** arithmetic
  costOfMixedAmount,
  mixedAmountToCost,
  divideMixedAmount,
  multiplyMixedAmount,
  divideMixedAmountAndPrice,
  multiplyMixedAmountAndPrice,
  averageMixedAmounts,
  isNegativeAmount,
  isNegativeMixedAmount,
  isZeroAmount,
  isReallyZeroAmount,
  isZeroMixedAmount,
  isReallyZeroMixedAmount,
  isReallyZeroMixedAmountCost,
  mixedAmountTotalPriceToUnitPrice,
  -- ** rendering
  styleMixedAmount,
  showMixedAmount,
  showMixedAmountOneLine,
  showMixedAmountDebug,
  showMixedAmountWithoutPrice,
  showMixedAmountOneLineWithoutPrice,
  cshowMixedAmountWithoutPrice,
  cshowMixedAmountOneLineWithoutPrice,
  showMixedAmountWithZeroCommodity,
  showMixedAmountWithPrecision,
  setMixedAmountPrecision,
  canonicaliseMixedAmount,
  -- * misc.
  ltraceamount,
  tests_Amount
) where

import Data.Char (isDigit)
import Data.Decimal (roundTo, decimalPlaces, normalizeDecimal)
import Data.Function (on)
import Data.List
import qualified Data.Map as M
import Data.Map (findWithDefault)
import Data.Maybe
import qualified Data.Text as T
import Safe (maximumDef)
import Text.Printf

import Hledger.Data.Types
import Hledger.Data.Commodity
import Hledger.Utils


deriving instance Show MarketPrice


-------------------------------------------------------------------------------
-- Amount styles

-- | Default amount style
amountstyle = AmountStyle L False 0 (Just '.') Nothing


-------------------------------------------------------------------------------
-- Amount

instance Num Amount where
    abs a@Amount{aquantity=q}    = a{aquantity=abs q}
    signum a@Amount{aquantity=q} = a{aquantity=signum q}
    fromInteger i                = nullamt{aquantity=fromInteger i}
    negate a@Amount{aquantity=q} = a{aquantity= -q}
    (+)                          = similarAmountsOp (+)
    (-)                          = similarAmountsOp (-)
    (*)                          = similarAmountsOp (*)

-- | The empty simple amount.
amount, nullamt :: Amount
amount = Amount{acommodity="", aquantity=0, aprice=Nothing, astyle=amountstyle, aismultiplier=False}
nullamt = amount

-- | A temporary value for parsed transactions which had no amount specified.
missingamt :: Amount
missingamt = amount{acommodity="AUTO"}

-- Handy amount constructors for tests.
-- usd/eur/gbp round their argument to a whole number of pennies/cents.
num n = amount{acommodity="",  aquantity=n}
hrs n = amount{acommodity="h", aquantity=n,           astyle=amountstyle{asprecision=2, ascommodityside=R}}
usd n = amount{acommodity="$", aquantity=roundTo 2 n, astyle=amountstyle{asprecision=2}}
eur n = amount{acommodity="€", aquantity=roundTo 2 n, astyle=amountstyle{asprecision=2}}
gbp n = amount{acommodity="£", aquantity=roundTo 2 n, astyle=amountstyle{asprecision=2}}
per n = amount{acommodity="%", aquantity=n,           astyle=amountstyle{asprecision=1, ascommodityside=R, ascommodityspaced=True}}
amt `at` priceamt = amt{aprice=Just $ UnitPrice priceamt}
amt @@ priceamt = amt{aprice=Just $ TotalPrice priceamt}

-- | Apply a binary arithmetic operator to two amounts, which should
-- be in the same commodity if non-zero (warning, this is not checked).
-- A zero result keeps the commodity of the second amount.
-- The result's display style is that of the second amount, with
-- precision set to the highest of either amount.
-- Prices are ignored and discarded.
-- Remember: the caller is responsible for ensuring both amounts have the same commodity.
similarAmountsOp :: (Quantity -> Quantity -> Quantity) -> Amount -> Amount -> Amount
similarAmountsOp op Amount{acommodity=_,  aquantity=q1, astyle=AmountStyle{asprecision=p1}}
                    Amount{acommodity=c2, aquantity=q2, astyle=s2@AmountStyle{asprecision=p2}} =
   -- trace ("a1:"++showAmountDebug a1) $ trace ("a2:"++showAmountDebug a2) $ traceWith (("= :"++).showAmountDebug)
   amount{acommodity=c2, aquantity=q1 `op` q2, astyle=s2{asprecision=max p1 p2}}
  --  c1==c2 || q1==0 || q2==0 =
  --  otherwise = error "tried to do simple arithmetic with amounts in different commodities"

-- | Convert an amount to the specified commodity, ignoring and discarding
-- any assigned prices and assuming an exchange rate of 1.
amountWithCommodity :: CommoditySymbol -> Amount -> Amount
amountWithCommodity c a = a{acommodity=c, aprice=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) XXX
--
-- - price amounts should be positive, though this is not currently enforced
costOfAmount :: Amount -> Amount
costOfAmount a@Amount{aquantity=q, aprice=mp} =
    case mp of
      Nothing                                  -> a
      Just (UnitPrice  p@Amount{aquantity=pq}) -> p{aquantity=pq * q}
      Just (TotalPrice p@Amount{aquantity=pq}) -> p{aquantity=pq * signum q}

-- | Convert this amount to cost, and apply the appropriate amount style.
amountToCost :: M.Map CommoditySymbol AmountStyle -> Amount -> Amount
amountToCost styles = styleAmount styles . costOfAmount

-- | Replace an amount's TotalPrice, if it has one, with an equivalent UnitPrice.
-- Has no effect on amounts without one.
-- Also increases the unit price's display precision to show one extra decimal place,
-- to help keep transaction amounts balancing.
-- Does Decimal division, might be some rounding/irrational number issues.
amountTotalPriceToUnitPrice :: Amount -> Amount
amountTotalPriceToUnitPrice
  a@Amount{aquantity=q, aprice=Just (TotalPrice pa@Amount{aquantity=pq, astyle=ps@AmountStyle{asprecision=pp}})}
  = a{aprice = Just $ UnitPrice pa{aquantity=abs (pq/q), astyle=ps{asprecision=pp+1}}}
amountTotalPriceToUnitPrice a = a

-- | Divide an amount's quantity by a constant.
divideAmount :: Quantity -> Amount -> Amount
divideAmount n a@Amount{aquantity=q} = a{aquantity=q/n}

-- | Multiply an amount's quantity by a constant.
multiplyAmount :: Quantity -> Amount -> Amount
multiplyAmount n a@Amount{aquantity=q} = a{aquantity=q*n}

-- | Divide an amount's quantity (and its total price, if it has one) by a constant.
-- The total price will be kept positive regardless of the multiplier's sign.
divideAmountAndPrice :: Quantity -> Amount -> Amount
divideAmountAndPrice n a@Amount{aquantity=q,aprice=p} = a{aquantity=q/n, aprice=f <$> p}
  where
    f (TotalPrice a) = TotalPrice $ abs $ n `divideAmount` a
    f p = p

-- | Multiply an amount's quantity (and its total price, if it has one) by a constant.
-- The total price will be kept positive regardless of the multiplier's sign.
multiplyAmountAndPrice :: Quantity -> Amount -> Amount
multiplyAmountAndPrice n a@Amount{aquantity=q,aprice=p} = a{aquantity=q*n, aprice=f <$> p}
  where
    f (TotalPrice a) = TotalPrice $ abs $ n `multiplyAmount` a
    f p = p

-- | Is this amount negative ? The price is ignored.
isNegativeAmount :: Amount -> Bool
isNegativeAmount Amount{aquantity=q} = q < 0

digits = "123456789" :: String

-- | Does this amount appear to be zero when displayed with its given precision ?
isZeroAmount :: Amount -> Bool
isZeroAmount --  a==missingamt = False
  = not . any (`elem` digits) . showAmountWithoutPriceOrCommodity

-- | Is this amount "really" zero, regardless of the display precision ?
isReallyZeroAmount :: Amount -> Bool
isReallyZeroAmount Amount{aquantity=q} = q == 0

-- | 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 an amount's display precision, flipped.
withPrecision :: Amount -> Int -> Amount
withPrecision = flip setAmountPrecision

-- | Set an amount's display precision.
setAmountPrecision :: Int -> Amount -> Amount
setAmountPrecision p a@Amount{astyle=s} = a{astyle=s{asprecision=p}}

-- | Increase an amount's display precision, if needed, to enough
-- decimal places to show it exactly (showing all significant decimal
-- digits, excluding trailing zeros).
setFullPrecision :: Amount -> Amount
setFullPrecision a = setAmountPrecision p a
  where
    p                = max displayprecision normalprecision
    displayprecision = asprecision $ astyle a
    normalprecision  = fromIntegral $ decimalPlaces $ normalizeDecimal $ aquantity a

-- | Set an amount's display precision to just enough decimal places
-- to show it exactly (possibly less than the number specified by
-- the amount's display style).
setNaturalPrecision :: Amount -> Amount
setNaturalPrecision a = setAmountPrecision normalprecision a
  where
    normalprecision  = fromIntegral $ decimalPlaces $ normalizeDecimal $ aquantity a

-- | Set an amount's display precision to just enough decimal places
-- to show it exactly (possibly less than the number specified by the
-- amount's display style), but not more than the given maximum number
-- of decimal digits.
setNaturalPrecisionUpTo :: Int -> Amount -> Amount
setNaturalPrecisionUpTo n a = setAmountPrecision (min n normalprecision) a
  where
    normalprecision  = fromIntegral $ decimalPlaces $ normalizeDecimal $ aquantity a

-- | Get a string representation of an amount for debugging,
-- appropriate to the current debug level. 9 shows maximum detail.
showAmountDebug :: Amount -> String
showAmountDebug Amount{acommodity="AUTO"} = "(missing)"
showAmountDebug Amount{..} = printf "Amount {acommodity=%s, aquantity=%s, aprice=%s, astyle=%s}" (show acommodity) (show aquantity) (showAmountPriceDebug aprice) (show astyle)

-- | Get the string representation of an amount, without any \@ price.
showAmountWithoutPrice :: Amount -> String
showAmountWithoutPrice a = showAmount a{aprice=Nothing}

-- | Set an amount's internal precision, ie rounds the Decimal representing
-- the amount's quantity to some number of decimal places.
-- Rounding is done with Data.Decimal's default roundTo function:
-- "If the value ends in 5 then it is rounded to the nearest even value (Banker's Rounding)".
-- Does not change the amount's display precision.
-- Intended only for internal use, eg when comparing amounts in tests.
setAmountInternalPrecision :: Int -> Amount -> Amount
setAmountInternalPrecision p a@Amount{ aquantity=q, astyle=s } = a{
   astyle=s{asprecision=p}
  ,aquantity=roundTo (fromIntegral p) q
  }

-- | Set an amount's internal precision, flipped.
-- Intended only for internal use, eg when comparing amounts in tests.
withInternalPrecision :: Amount -> Int -> Amount
withInternalPrecision = flip setAmountInternalPrecision

-- | Set (or clear) an amount's display decimal point.
setAmountDecimalPoint :: Maybe Char -> Amount -> Amount
setAmountDecimalPoint mc a@Amount{ astyle=s } = a{ astyle=s{asdecimalpoint=mc} }

-- | Set (or clear) an amount's display decimal point, flipped.
withDecimalPoint :: Amount -> Maybe Char -> Amount
withDecimalPoint = flip setAmountDecimalPoint

-- | Colour version.
cshowAmountWithoutPrice :: Amount -> String
cshowAmountWithoutPrice a = cshowAmount a{aprice=Nothing}

-- | Get the string representation of an amount, without any price or commodity symbol.
showAmountWithoutPriceOrCommodity :: Amount -> String
showAmountWithoutPriceOrCommodity a = showAmount a{acommodity="", aprice=Nothing}

showAmountPrice :: Maybe AmountPrice -> String
showAmountPrice Nothing                = ""
showAmountPrice (Just (UnitPrice pa))  = " @ "  ++ showAmount pa
showAmountPrice (Just (TotalPrice pa)) = " @@ " ++ showAmount pa

showAmountPriceDebug :: Maybe AmountPrice -> String
showAmountPriceDebug Nothing                = ""
showAmountPriceDebug (Just (UnitPrice pa))  = " @ "  ++ showAmountDebug pa
showAmountPriceDebug (Just (TotalPrice pa)) = " @@ " ++ showAmountDebug pa

-- | Given a map of standard amount display styles, apply the appropriate one to this amount.
-- If there's no standard style for this amount's commodity, return the amount unchanged.
styleAmount :: M.Map CommoditySymbol AmountStyle -> Amount -> Amount
styleAmount styles a =
  case M.lookup (acommodity a) styles of
    Just s  -> a{astyle=s}
    Nothing -> a

-- | Like styleAmount, but keep the number of decimal places unchanged.
styleAmountExceptPrecision :: M.Map CommoditySymbol AmountStyle -> Amount -> Amount
styleAmountExceptPrecision styles a@Amount{astyle=AmountStyle{asprecision=origp}} =
  case M.lookup (acommodity a) styles of
    Just s  -> a{astyle=s{asprecision=origp}}
    Nothing -> a

-- | Get the string representation of an amount, based on its
-- commodity's display settings. String representations equivalent to
-- zero are converted to just \"0\". The special "missing" amount is
-- displayed as the empty string.
showAmount :: Amount -> String
showAmount = showAmountHelper False

-- | Colour version. For a negative amount, adds ANSI codes to change the colour,
-- currently to hard-coded red.
cshowAmount :: Amount -> String
cshowAmount a =
  (if isNegativeAmount a then color Dull Red else id) $
  showAmountHelper False a

showAmountHelper :: Bool -> Amount -> String
showAmountHelper _ Amount{acommodity="AUTO"} = ""
showAmountHelper showzerocommodity a@Amount{acommodity=c, aprice=mp, astyle=AmountStyle{..}} =
    case ascommodityside of
      L -> printf "%s%s%s%s" (T.unpack c') space quantity' price
      R -> printf "%s%s%s%s" quantity' space (T.unpack c') price
    where
      quantity = showamountquantity a
      displayingzero = not (any (`elem` digits) quantity)
      (quantity',c') | displayingzero && not showzerocommodity = ("0","")
                     | otherwise = (quantity, quoteCommoditySymbolIfNeeded c)
      space = if not (T.null c') && ascommodityspaced then " " else "" :: String
      price = showAmountPrice mp

-- | Like showAmount, but show a zero amount's commodity if it has one.
showAmountWithZeroCommodity :: Amount -> String
showAmountWithZeroCommodity = showAmountHelper True

-- | Get the string representation of the number part of of an amount,
-- using the display settings from its commodity.
showamountquantity :: Amount -> String
showamountquantity Amount{aquantity=q, astyle=AmountStyle{asprecision=p, asdecimalpoint=mdec, asdigitgroups=mgrps}} =
    punctuatenumber (fromMaybe '.' mdec) mgrps qstr
    where
      -- isint n = fromIntegral (round n) == n
      qstr -- p == maxprecision && isint q = printf "%d" (round q::Integer)
        | p == maxprecisionwithpoint = show q
        | p == maxprecision          = chopdotzero $ show q
        | otherwise                  = show $ roundTo (fromIntegral p) q

-- | Replace a number string's decimal mark with the specified
-- character, and add the specified digit group marks. The last digit
-- group will be repeated as needed.
punctuatenumber :: Char -> Maybe DigitGroupStyle -> String -> String
punctuatenumber dec mgrps s = sign ++ reverse (applyDigitGroupStyle mgrps (reverse int)) ++ frac''
    where
      (sign,num) = break isDigit s
      (int,frac) = break (=='.') num
      frac' = dropWhile (=='.') frac
      frac'' | null frac' = ""
             | otherwise  = dec:frac'

applyDigitGroupStyle :: Maybe DigitGroupStyle -> String -> String
applyDigitGroupStyle Nothing s = s
applyDigitGroupStyle (Just (DigitGroups c gs)) s = addseps (repeatLast gs) s
  where
    addseps [] s = s
    addseps (g:gs) s
      | length s <= g = s
      | otherwise     = let (part,rest) = splitAt g s
                        in part ++ [c] ++ addseps gs rest
    repeatLast [] = []
    repeatLast gs = init gs ++ repeat (last gs)

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

-- like journalCanonicaliseAmounts
-- | Canonicalise an amount's display style using the provided commodity style map.
canonicaliseAmount :: M.Map CommoditySymbol AmountStyle -> Amount -> Amount
canonicaliseAmount styles a@Amount{acommodity=c, astyle=s} = a{astyle=s'}
    where
      s' = findWithDefault s c styles

-------------------------------------------------------------------------------
-- MixedAmount

instance Num MixedAmount where
    fromInteger i = Mixed [fromInteger i]
    negate (Mixed as) = Mixed $ map negate as
    (+) (Mixed as) (Mixed bs) = normaliseMixedAmount $ Mixed $ as ++ bs
    (*)    = error' "error, mixed amounts do not support multiplication"
    abs    = error' "error, mixed amounts do not support abs"
    signum = error' "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.
missingmixedamt :: MixedAmount
missingmixedamt = Mixed [missingamt]

-- | Convert amounts in various commodities into a normalised MixedAmount.
mixed :: [Amount] -> MixedAmount
mixed = normaliseMixedAmount . Mixed

-- | Simplify a mixed amount's component amounts:
--
-- * amounts in the same commodity are combined unless they have different prices or total prices
--
-- * multiple zero amounts, all with the same non-null commodity, are replaced by just the last of them, preserving the commodity and amount style (all but the last zero amount are discarded)
--
-- * multiple zero amounts with multiple commodities, or no commodities, are replaced by one commodity-less zero amount
--
-- * an empty amount list is replaced by one commodity-less zero amount
--
-- * the special "missing" mixed amount remains unchanged
--
normaliseMixedAmount :: MixedAmount -> MixedAmount
normaliseMixedAmount = normaliseHelper False

normaliseHelper :: Bool -> MixedAmount -> MixedAmount
normaliseHelper squashprices (Mixed as)
  | missingamt `elem` as = missingmixedamt -- missingamt should always be alone, but detect it even if not
  | null nonzeros        = Mixed [newzero]
  | otherwise            = Mixed nonzeros
  where
    newzero = case filter (/= "") (map acommodity zeros) of
               _:_ -> last zeros
               _   -> nullamt
    (zeros, nonzeros) = partition isReallyZeroAmount $
                        map sumSimilarAmountsUsingFirstPrice $
                        groupBy groupfn $
                        sortBy sortfn
                        as
    sortfn  | squashprices = compare `on` acommodity
            | otherwise    = compare `on` \a -> (acommodity a, aprice a)
    groupfn | squashprices = (==) `on` acommodity
            | otherwise    = \a1 a2 -> acommodity a1 == acommodity a2 && combinableprices a1 a2

    combinableprices Amount{aprice=Nothing} Amount{aprice=Nothing} = True
    combinableprices Amount{aprice=Just (UnitPrice p1)} Amount{aprice=Just (UnitPrice p2)} = p1 == p2
    combinableprices _ _ = False

-- | Like normaliseMixedAmount, but combine each commodity's amounts
-- into just one by throwing away all prices except the first. This is
-- only used as a rendering helper, and could show a misleading price.
normaliseMixedAmountSquashPricesForDisplay :: MixedAmount -> MixedAmount
normaliseMixedAmountSquashPricesForDisplay = normaliseHelper True

-- | Sum same-commodity amounts in a lossy way, applying the first
-- price to the result and discarding any other prices. Only used as a
-- rendering helper.
sumSimilarAmountsUsingFirstPrice :: [Amount] -> Amount
sumSimilarAmountsUsingFirstPrice [] = nullamt
sumSimilarAmountsUsingFirstPrice as = (sumStrict as){aprice=aprice $ head as}

-- -- | Sum same-commodity amounts. If there were different prices, set
-- -- the price to a special marker indicating "various". Only used as a
-- -- rendering helper.
-- sumSimilarAmountsNotingPriceDifference :: [Amount] -> Amount
-- sumSimilarAmountsNotingPriceDifference [] = nullamt
-- sumSimilarAmountsNotingPriceDifference as = undefined

-- | Get a mixed amount's component amounts.
amounts :: MixedAmount -> [Amount]
amounts (Mixed as) = as

-- | Filter a mixed amount's component amounts by a predicate.
filterMixedAmount :: (Amount -> Bool) -> MixedAmount -> MixedAmount
filterMixedAmount p (Mixed as) = Mixed $ filter p as

-- | Return an unnormalised MixedAmount containing exactly one Amount
-- with the specified commodity and the quantity of that commodity
-- found in the original. NB if Amount's quantity is zero it will be
-- discarded next time the MixedAmount gets normalised.
filterMixedAmountByCommodity :: CommoditySymbol -> MixedAmount -> MixedAmount
filterMixedAmountByCommodity c (Mixed as) = Mixed as'
  where
    as' = case filter ((==c) . acommodity) as of
            []   -> [nullamt{acommodity=c}]
            as'' -> [sum as'']

-- | Apply a transform to a mixed amount's component 'Amount's.
mapMixedAmount :: (Amount -> Amount) -> MixedAmount -> MixedAmount
mapMixedAmount f (Mixed as) = Mixed $ map f 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

-- | Convert all component amounts to cost, and apply the appropriate amount styles.
mixedAmountToCost :: M.Map CommoditySymbol AmountStyle -> MixedAmount -> MixedAmount
mixedAmountToCost styles (Mixed as) = Mixed $ map (amountToCost styles) as

-- | Divide a mixed amount's quantities by a constant.
divideMixedAmount :: Quantity -> MixedAmount -> MixedAmount
divideMixedAmount n = mapMixedAmount (divideAmount n)

-- | Multiply a mixed amount's quantities by a constant.
multiplyMixedAmount :: Quantity -> MixedAmount -> MixedAmount
multiplyMixedAmount n = mapMixedAmount (multiplyAmount n)

-- | Divide a mixed amount's quantities (and total prices, if any) by a constant.
-- The total prices will be kept positive regardless of the multiplier's sign.
divideMixedAmountAndPrice :: Quantity -> MixedAmount -> MixedAmount
divideMixedAmountAndPrice n = mapMixedAmount (divideAmountAndPrice n)

-- | Multiply a mixed amount's quantities (and total prices, if any) by a constant.
-- The total prices will be kept positive regardless of the multiplier's sign.
multiplyMixedAmountAndPrice :: Quantity -> MixedAmount -> MixedAmount
multiplyMixedAmountAndPrice n = mapMixedAmount (multiplyAmountAndPrice n)

-- | Calculate the average of some mixed amounts.
averageMixedAmounts :: [MixedAmount] -> MixedAmount
averageMixedAmounts [] = 0
averageMixedAmounts as = fromIntegral (length as) `divideMixedAmount` sum 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 $ normaliseMixedAmountSquashPricesForDisplay m

-- | Does this mixed amount appear to be zero when displayed with its given precision ?
isZeroMixedAmount :: MixedAmount -> Bool
isZeroMixedAmount = all isZeroAmount . amounts . normaliseMixedAmountSquashPricesForDisplay

-- | Is this mixed amount "really" zero ? See isReallyZeroAmount.
isReallyZeroMixedAmount :: MixedAmount -> Bool
isReallyZeroMixedAmount = all isReallyZeroAmount . amounts . normaliseMixedAmountSquashPricesForDisplay

-- | Is this mixed amount "really" zero, after converting to cost
-- commodities where possible ?
isReallyZeroMixedAmountCost :: MixedAmount -> Bool
isReallyZeroMixedAmountCost = isReallyZeroMixedAmount . costOfMixedAmount

-- -- | 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' = normaliseMixedAmountSquashPricesForDisplay a
--           b' = normaliseMixedAmountSquashPricesForDisplay b

-- | Given a map of standard amount display styles, apply the appropriate ones to each individual amount.
styleMixedAmount :: M.Map CommoditySymbol AmountStyle -> MixedAmount -> MixedAmount
styleMixedAmount styles (Mixed as) = Mixed $ map (styleAmount styles) as

-- | Get the string representation of a mixed amount, after
-- normalising it to one amount per commodity. Assumes amounts have
-- no or similar prices, otherwise this can show misleading prices.
showMixedAmount :: MixedAmount -> String
showMixedAmount = showMixedAmountHelper False False

-- | Like showMixedAmount, but zero amounts are shown with their
-- commodity if they have one.
showMixedAmountWithZeroCommodity :: MixedAmount -> String
showMixedAmountWithZeroCommodity = showMixedAmountHelper True False

-- | Get the one-line string representation of a mixed amount.
showMixedAmountOneLine :: MixedAmount -> String
showMixedAmountOneLine = showMixedAmountHelper False True

showMixedAmountHelper :: Bool -> Bool -> MixedAmount -> String
showMixedAmountHelper showzerocommodity useoneline m =
  join $ map showamt $ amounts $ normaliseMixedAmountSquashPricesForDisplay m
  where
    join | useoneline = intercalate ", "
         | otherwise  = vConcatRightAligned
    showamt | showzerocommodity = showAmountWithZeroCommodity
            | otherwise         = showAmount

-- | Compact labelled trace of a mixed amount, for debugging.
ltraceamount :: String -> MixedAmount -> MixedAmount
ltraceamount s = traceWith (((s ++ ": ") ++).showMixedAmount)

-- | 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.
showMixedAmountWithPrecision :: Int -> MixedAmount -> String
showMixedAmountWithPrecision p m =
    vConcatRightAligned $ map (showAmountWithPrecision p) $ amounts $ normaliseMixedAmountSquashPricesForDisplay m

-- | Get an unambiguous string representation of a mixed amount for debugging.
showMixedAmountDebug :: MixedAmount -> String
showMixedAmountDebug m | m == missingmixedamt = "(missing)"
                       | otherwise       = printf "Mixed [%s]" as
    where as = intercalate "\n       " $ map showAmountDebug $ amounts m

-- TODO these and related fns are comically complicated:

-- | Get the string representation of a mixed amount, without showing any transaction prices.
showMixedAmountWithoutPrice :: MixedAmount -> String
showMixedAmountWithoutPrice m = intercalate "\n" $ map showamt as
  where
    Mixed as = normaliseMixedAmountSquashPricesForDisplay $ mixedAmountStripPrices m
    showamt = printf (printf "%%%ds" width) . showAmountWithoutPrice
      where
        width = maximumDef 0 $ map (length . showAmount) as

-- | Colour version of showMixedAmountWithoutPrice. Any individual Amount
-- which is negative is wrapped in ANSI codes to make it display in red.
cshowMixedAmountWithoutPrice :: MixedAmount -> String
cshowMixedAmountWithoutPrice m = intercalate "\n" $ map showamt as
  where
    Mixed as = normaliseMixedAmountSquashPricesForDisplay $ mixedAmountStripPrices m
    showamt a =
      (if isNegativeAmount a then color Dull Red else id) $
      printf (printf "%%%ds" width) $ showAmountWithoutPrice a
      where
        width = maximumDef 0 $ map (length . showAmount) as

mixedAmountStripPrices :: MixedAmount -> MixedAmount
mixedAmountStripPrices (Mixed as) = Mixed $ map (\a -> a{aprice=Nothing}) as

-- | Get the one-line string representation of a mixed amount, but without
-- any \@ prices.
showMixedAmountOneLineWithoutPrice :: MixedAmount -> String
showMixedAmountOneLineWithoutPrice m = intercalate ", " $ map showAmountWithoutPrice as
    where
      (Mixed as) = normaliseMixedAmountSquashPricesForDisplay $ stripPrices m
      stripPrices (Mixed as) = Mixed $ map stripprice as where stripprice a = a{aprice=Nothing}

-- | Colour version.
cshowMixedAmountOneLineWithoutPrice :: MixedAmount -> String
cshowMixedAmountOneLineWithoutPrice m = intercalate ", " $ map cshowAmountWithoutPrice as
    where
      (Mixed as) = normaliseMixedAmountSquashPricesForDisplay $ stripPrices m
      stripPrices (Mixed as) = Mixed $ map stripprice as where stripprice a = a{aprice=Nothing}

-- | Canonicalise a mixed amount's display styles using the provided commodity style map.
canonicaliseMixedAmount :: M.Map CommoditySymbol AmountStyle -> MixedAmount -> MixedAmount
canonicaliseMixedAmount styles (Mixed as) = Mixed $ map (canonicaliseAmount styles) as

-- | Replace each component amount's TotalPrice, if it has one, with an equivalent UnitPrice.
-- Has no effect on amounts without one.
-- Does Decimal division, might be some rounding/irrational number issues.
mixedAmountTotalPriceToUnitPrice :: MixedAmount -> MixedAmount
mixedAmountTotalPriceToUnitPrice (Mixed as) = Mixed $ map amountTotalPriceToUnitPrice as


-------------------------------------------------------------------------------
-- tests

tests_Amount = tests "Amount" [
   tests "Amount" [

     test "costOfAmount" $ do
       costOfAmount (eur 1) @?= eur 1
       costOfAmount (eur 2){aprice=Just $ UnitPrice $ usd 2} @?= usd 4
       costOfAmount (eur 1){aprice=Just $ TotalPrice $ usd 2} @?= usd 2
       costOfAmount (eur (-1)){aprice=Just $ TotalPrice $ usd 2} @?= usd (-2)

    ,test "isZeroAmount" $ do
       assertBool "" $ isZeroAmount amount
       assertBool "" $ isZeroAmount $ usd 0

    ,test "negating amounts" $ do
       negate (usd 1) @?= (usd 1){aquantity= -1}
       let b = (usd 1){aprice=Just $ UnitPrice $ eur 2} in negate b @?= b{aquantity= -1}

    ,test "adding amounts without prices" $ do
       (usd 1.23 + usd (-1.23)) @?= usd 0
       (usd 1.23 + usd (-1.23)) @?= usd 0
       (usd (-1.23) + usd (-1.23)) @?= usd (-2.46)
       sum [usd 1.23,usd (-1.23),usd (-1.23),-(usd (-1.23))] @?= usd 0
       -- highest precision is preserved
       asprecision (astyle $ sum [usd 1 `withPrecision` 1, usd 1 `withPrecision` 3]) @?= 3
       asprecision (astyle $ sum [usd 1 `withPrecision` 3, usd 1 `withPrecision` 1]) @?= 3
       -- adding different commodities assumes conversion rate 1
       assertBool "" $ isZeroAmount (usd 1.23 - eur 1.23)

    ,test "showAmount" $ do
      showAmount (usd 0 + gbp 0) @?= "0"

  ]

  ,tests "MixedAmount" [

     test "adding mixed amounts to zero, the commodity and amount style are preserved" $
      sum (map (Mixed . (:[]))
               [usd 1.25
               ,usd (-1) `withPrecision` 3
               ,usd (-0.25)
               ])
        @?= Mixed [usd 0 `withPrecision` 3]

    ,test "adding mixed amounts with total prices" $ do
      sum (map (Mixed . (:[]))
       [usd 1 @@ eur 1
       ,usd (-2) @@ eur 1
       ])
        @?= Mixed [usd 1 @@ eur 1
                   ,usd (-2) @@ eur 1
                   ]

    ,test "showMixedAmount" $ do
       showMixedAmount (Mixed [usd 1]) @?= "$1.00"
       showMixedAmount (Mixed [usd 1 `at` eur 2]) @?= "$1.00 @ €2.00"
       showMixedAmount (Mixed [usd 0]) @?= "0"
       showMixedAmount (Mixed []) @?= "0"
       showMixedAmount missingmixedamt @?= ""

    ,test "showMixedAmountWithoutPrice" $ do
      let a = usd 1 `at` eur 2
      showMixedAmountWithoutPrice (Mixed [a]) @?= "$1.00"
      showMixedAmountWithoutPrice (Mixed [a, -a]) @?= "0"

    ,tests "normaliseMixedAmount" [
       test "a missing amount overrides any other amounts" $
        normaliseMixedAmount (Mixed [usd 1, missingamt]) @?= missingmixedamt
      ,test "unpriced same-commodity amounts are combined" $
        normaliseMixedAmount (Mixed [usd 0, usd 2]) @?= Mixed [usd 2]
      ,test "amounts with same unit price are combined" $
        normaliseMixedAmount (Mixed [usd 1 `at` eur 1, usd 1 `at` eur 1]) @?= Mixed [usd 2 `at` eur 1]
      ,test "amounts with different unit prices are not combined" $
        normaliseMixedAmount (Mixed [usd 1 `at` eur 1, usd 1 `at` eur 2]) @?= Mixed [usd 1 `at` eur 1, usd 1 `at` eur 2]
      ,test "amounts with total prices are not combined" $
        normaliseMixedAmount (Mixed  [usd 1 @@ eur 1, usd 1 @@ eur 1]) @?= Mixed [usd 1 @@ eur 1, usd 1 @@ eur 1]
    ]

    ,test "normaliseMixedAmountSquashPricesForDisplay" $ do
       normaliseMixedAmountSquashPricesForDisplay (Mixed []) @?= Mixed [nullamt]
       assertBool "" $ isZeroMixedAmount $ normaliseMixedAmountSquashPricesForDisplay
        (Mixed [usd 10
               ,usd 10 @@ eur 7
               ,usd (-10)
               ,usd (-10) @@ eur 7
               ])

  ]

 ]