815 lines
26 KiB
Haskell
815 lines
26 KiB
Haskell
module Internal.Insert
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( insertBudget
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, splitHistory
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, insertHistTransfer
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, readHistStmt
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, insertHistStmt
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)
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where
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import Control.Monad.Except
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import Data.Hashable
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import Database.Persist.Monad
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import Internal.Statement
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import Internal.Types.Main
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import Internal.Utils
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import RIO hiding (to)
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import qualified RIO.List as L
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import qualified RIO.Map as M
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import qualified RIO.NonEmpty as NE
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import qualified RIO.Text as T
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import RIO.Time
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--------------------------------------------------------------------------------
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-- intervals
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expandDatePat :: Bounds -> DatePat -> InsertExcept [Day]
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expandDatePat b (Cron cp) = expandCronPat b cp
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expandDatePat i (Mod mp) = return $ expandModPat mp i
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expandModPat :: ModPat -> Bounds -> [Day]
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expandModPat ModPat {mpStart = s, mpBy = b, mpUnit = u, mpRepeats = r} bs =
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takeWhile (<= upper) $
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(`addFun` start) . (* b')
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<$> maybe id (take . fromIntegral) r [0 ..]
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where
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(lower, upper) = expandBounds bs
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start = maybe lower fromGregorian' s
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b' = fromIntegral b
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addFun = case u of
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Day -> addDays
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Week -> addDays . (* 7)
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Month -> addGregorianMonthsClip
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Year -> addGregorianYearsClip
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expandCronPat :: Bounds -> CronPat -> InsertExcept [Day]
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expandCronPat b CronPat {cpYear, cpMonth, cpDay, cpWeekly} =
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combineError3 yRes mRes dRes $ \ys ms ds ->
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filter validWeekday $
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mapMaybe (uncurry3 toDay) $
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takeWhile (\((y, _), m, d) -> (y, m, d) <= (yb1, mb1, db1)) $
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dropWhile (\((y, _), m, d) -> (y, m, d) < (yb0, mb0, db0)) $
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[(y, m, d) | y <- (\y -> (y, isLeapYear y)) <$> ys, m <- ms, d <- ds]
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where
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yRes = case cpYear of
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Nothing -> return [yb0 .. yb1]
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Just pat -> do
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ys <- expandMDYPat (fromIntegral yb0) (fromIntegral yb1) pat
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return $ dropWhile (< yb0) $ fromIntegral <$> ys
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mRes = expandMD 12 cpMonth
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dRes = expandMD 31 cpDay
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(s, e) = expandBounds b
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(yb0, mb0, db0) = toGregorian s
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(yb1, mb1, db1) = toGregorian $ addDays (-1) e
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expandMD lim =
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fmap (fromIntegral <$>)
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. maybe (return [1 .. lim]) (expandMDYPat 1 lim)
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expandW (OnDay x) = [fromEnum x]
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expandW (OnDays xs) = fromEnum <$> xs
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ws = maybe [] expandW cpWeekly
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validWeekday = if null ws then const True else \day -> dayToWeekday day `elem` ws
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toDay (y, leap) m d
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| m == 2 && (not leap && d > 28 || leap && d > 29) = Nothing
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| m `elem` [4, 6, 9, 11] && d > 30 = Nothing
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| otherwise = Just $ fromGregorian y m d
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expandMDYPat :: Natural -> Natural -> MDYPat -> InsertExcept [Natural]
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expandMDYPat lower upper (Single x) = return [x | lower <= x && x <= upper]
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expandMDYPat lower upper (Multi xs) = return $ dropWhile (<= lower) $ takeWhile (<= upper) xs
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expandMDYPat lower upper (After x) = return [max lower x .. upper]
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expandMDYPat lower upper (Before x) = return [lower .. min upper x]
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expandMDYPat lower upper (Between x y) = return [max lower x .. min upper y]
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expandMDYPat lower upper (Repeat RepeatPat {rpStart = s, rpBy = b, rpRepeats = r})
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| b < 1 = throwError $ InsertException [PatternError s b r ZeroLength]
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| otherwise = do
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k <- limit r
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return $ dropWhile (<= lower) $ takeWhile (<= k) [s + i * b | i <- [0 ..]]
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where
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limit Nothing = return upper
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limit (Just n)
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-- this guard not only produces the error for the user but also protects
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-- from an underflow below it
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| n < 1 = throwError $ InsertException [PatternError s b r ZeroRepeats]
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| otherwise = return $ min (s + b * (n - 1)) upper
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dayToWeekday :: Day -> Int
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dayToWeekday (ModifiedJulianDay d) = mod (fromIntegral d + 2) 7
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askDays
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:: (MonadFinance m, MonadInsertError m)
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=> DatePat
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-> Maybe Interval
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-> m [Day]
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askDays dp i = do
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globalBounds <- askDBState kmBudgetInterval
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case i of
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Just i' -> do
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localBounds <- liftExcept $ resolveBounds i'
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let bounds = intersectBounds globalBounds localBounds
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maybe (return []) expand bounds
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Nothing -> expand globalBounds
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where
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expand bs = liftExcept $ expandDatePat bs dp
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withDates
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:: (MonadSqlQuery m, MonadFinance m, MonadInsertError m)
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=> DatePat
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-> (Day -> m a)
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-> m [a]
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withDates dp f = do
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bounds <- askDBState kmBudgetInterval
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days <- liftExcept $ expandDatePat bounds dp
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combineErrors $ fmap f days
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foldDays
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:: MonadInsertError m
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=> (Day -> Day -> m a)
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-> Day
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-> [Day]
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-> m [a]
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foldDays f start days =
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combineErrors $
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snd $
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L.mapAccumL (\prevDay day -> (day, f prevDay day)) start days
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--------------------------------------------------------------------------------
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-- budget
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-- each budget (designated at the top level by a 'name') is processed in the
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-- following steps
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-- 1. expand all transactions given the desired date range and date patterns for
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-- each directive in the budget
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-- 2. sort all transactions by date
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-- 3. propagate all balances forward, and while doing so assign values to each
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-- transaction (some of which depend on the 'current' balance of the
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-- target account)
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-- 4. assign shadow transactions (TODO)
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-- 5. insert all transactions
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insertBudget
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:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
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=> Budget
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-> m ()
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insertBudget
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b@Budget
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{ bgtLabel
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, bgtIncomes
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, bgtTransfers
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, bgtShadowTransfers
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, bgtPretax
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, bgtTax
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, bgtPosttax
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, bgtInterval
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} =
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whenHash CTBudget b () $ \key -> do
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intAllos <- combineError3 pre_ tax_ post_ (,,)
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let res1 = mapErrors (insertIncome key bgtLabel intAllos bgtInterval) bgtIncomes
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let res2 = expandTransfers key bgtLabel bgtInterval bgtTransfers
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txs <- combineError (concat <$> res1) res2 (++)
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m <- askDBState kmCurrency
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shadow <- liftExcept $ addShadowTransfers m bgtShadowTransfers txs
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void $ mapErrors insertBudgetTx $ balanceTransfers $ txs ++ shadow
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where
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pre_ = sortAllos bgtPretax
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tax_ = sortAllos bgtTax
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post_ = sortAllos bgtPosttax
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sortAllos = liftExcept . combineErrors . fmap sortAllo
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type BoundAllocation = Allocation Bounds
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type IntAllocations =
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( [BoundAllocation PretaxValue]
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, [BoundAllocation TaxValue]
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, [BoundAllocation PosttaxValue]
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)
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-- TODO this should actually error if there is no ultimate end date?
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sortAllo :: MultiAllocation v -> InsertExcept (BoundAllocation v)
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sortAllo a@Allocation {alloAmts = as} = do
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bs <- foldBounds [] $ L.sortOn amtWhen as
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return $ a {alloAmts = reverse bs}
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where
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foldBounds acc [] = return acc
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foldBounds acc (x : xs) = do
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let start = amtWhen x
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res <- case xs of
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[] -> resolveBounds start
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(y : _) -> resolveBounds_ (intStart $ amtWhen y) start
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foldBounds (x {amtWhen = res} : acc) xs
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-- TODO this is going to be O(n*m), which might be a problem?
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addShadowTransfers
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:: CurrencyMap
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-> [ShadowTransfer]
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-> [UnbalancedTransfer]
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-> InsertExcept [UnbalancedTransfer]
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addShadowTransfers cm ms txs =
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fmap catMaybes $
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combineErrors $
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fmap (uncurry (fromShadow cm)) $
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[(t, m) | t <- txs, m <- ms]
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fromShadow
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:: CurrencyMap
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-> UnbalancedTransfer
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-> ShadowTransfer
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-> InsertExcept (Maybe UnbalancedTransfer)
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fromShadow cm tx t@ShadowTransfer {stFrom, stTo, stDesc, stRatio, stCurrency, stType} = do
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res <- shadowMatches (stMatch t) tx
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v <- roundPrecisionCur (initialCurrency stCurrency) cm stRatio
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return $
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if not res
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then Nothing
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else
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Just $
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FlatTransfer
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{ ftMeta = ftMeta tx
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, ftWhen = ftWhen tx
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, ftCur = stCurrency
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, ftFrom = stFrom
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, ftTo = stTo
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, ftValue = UnbalancedValue stType $ v * cvValue (ftValue tx)
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, ftDesc = stDesc
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}
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shadowMatches :: TransferMatcher -> UnbalancedTransfer -> InsertExcept Bool
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shadowMatches TransferMatcher {tmFrom, tmTo, tmDate, tmVal} tx = do
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valRes <- valMatches tmVal $ cvValue $ ftValue tx
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return $
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memberMaybe (taAcnt $ ftFrom tx) tmFrom
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&& memberMaybe (taAcnt $ ftTo tx) tmTo
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&& maybe True (`dateMatches` ftWhen tx) tmDate
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&& valRes
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where
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memberMaybe x AcntSet {asList, asInclude} =
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(if asInclude then id else not) $ x `elem` asList
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balanceTransfers :: [UnbalancedTransfer] -> [BalancedTransfer]
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balanceTransfers = snd . L.mapAccumR go M.empty . reverse . L.sortOn ftWhen
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where
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go bals f@FlatTransfer {ftFrom, ftTo, ftValue = UnbalancedValue {cvValue, cvType}} =
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let balTo = M.findWithDefault 0 ftTo bals
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x = amtToMove balTo cvType cvValue
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bals' = mapAdd_ ftTo x $ mapAdd_ ftFrom (-x) bals
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in (bals', f {ftValue = x})
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-- TODO might need to query signs to make this intuitive; as it is this will
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-- probably work, but for credit accounts I might need to supply a negative
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-- target value
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amtToMove _ BTFixed x = x
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amtToMove bal BTPercent x = -(x / 100 * bal)
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amtToMove bal BTTarget x = x - bal
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mapAdd_ :: (Ord k, Num v) => k -> v -> M.Map k v -> M.Map k v
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mapAdd_ k v = M.alter (maybe (Just v) (Just . (+ v))) k
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data BudgetMeta = BudgetMeta
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{ bmCommit :: !CommitRId
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, bmName :: !T.Text
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}
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deriving (Show)
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data FlatTransfer v = FlatTransfer
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{ ftFrom :: !TaggedAcnt
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, ftTo :: !TaggedAcnt
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, ftValue :: !v
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, ftWhen :: !Day
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, ftDesc :: !T.Text
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, ftMeta :: !BudgetMeta
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, ftCur :: !BudgetCurrency
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}
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deriving (Show)
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data UnbalancedValue = UnbalancedValue
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{ cvType :: !BudgetTransferType
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, cvValue :: !Rational
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}
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deriving (Show)
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type UnbalancedTransfer = FlatTransfer UnbalancedValue
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type BalancedTransfer = FlatTransfer Rational
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insertIncome
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:: (MonadInsertError m, MonadFinance m)
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=> CommitRId
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-> T.Text
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-> IntAllocations
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-> Maybe Interval
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-> Income
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-> m [UnbalancedTransfer]
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insertIncome
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key
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name
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(intPre, intTax, intPost)
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localInterval
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Income
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{ incWhen
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, incCurrency
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, incFrom
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, incPretax
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, incPosttax
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, incTaxes
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, incToBal
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, incGross
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, incPayPeriod
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} = do
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-- TODO check that the other accounts are not income somewhere here
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_ <- checkAcntType IncomeT $ taAcnt incFrom
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precision <- lookupCurrencyPrec incCurrency
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let gross = roundPrecision precision incGross
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-- TODO this will scan the interval allocations fully each time
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-- iteration which is a total waste, but the fix requires turning this
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-- loop into a fold which I don't feel like doing now :(
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days <- askDays incWhen localInterval
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res <- foldDays (allocate precision gross) start days
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return $ concat res
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where
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start = fromGregorian' $ pStart incPayPeriod
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pType' = pType incPayPeriod
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meta = BudgetMeta key name
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flatPre = concatMap flattenAllo incPretax
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flatTax = concatMap flattenAllo incTaxes
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flatPost = concatMap flattenAllo incPosttax
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sumAllos = sum . fmap faValue
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-- TODO ensure these are all the "correct" accounts
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allocate precision gross prevDay day = do
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scaler <- liftExcept $ periodScaler pType' prevDay day
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let (preDeductions, pre) =
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allocatePre precision gross $
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flatPre ++ concatMap (selectAllos day) intPre
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tax =
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allocateTax precision gross preDeductions scaler $
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flatTax ++ concatMap (selectAllos day) intTax
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aftertaxGross = gross - sumAllos (tax ++ pre)
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post =
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allocatePost precision aftertaxGross $
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flatPost ++ concatMap (selectAllos day) intPost
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balance = aftertaxGross - sumAllos post
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bal =
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FlatTransfer
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{ ftMeta = meta
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, ftWhen = day
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, ftFrom = incFrom
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, ftCur = NoX incCurrency
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, ftTo = incToBal
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, ftValue = UnbalancedValue BTFixed balance
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, ftDesc = "balance after deductions"
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}
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in if balance < 0
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then throwError $ InsertException [IncomeError day name balance]
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else return (bal : fmap (allo2Trans meta day incFrom) (pre ++ tax ++ post))
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type PeriodScaler = Natural -> Double -> Double
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-- TODO we probably don't need to check for 1/0 each time
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periodScaler
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:: PeriodType
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-> Day
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-> Day
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-> InsertExcept PeriodScaler
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periodScaler pt prev cur = do
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n <- workingDays wds prev cur
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return $ scale (fromIntegral n)
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where
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wds = case pt of
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Hourly HourlyPeriod {hpWorkingDays} -> hpWorkingDays
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Daily ds -> ds
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scale n precision x = case pt of
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Hourly HourlyPeriod {hpAnnualHours, hpDailyHours} ->
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fromRational (rnd $ x / fromIntegral hpAnnualHours)
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* fromIntegral hpDailyHours
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* n
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Daily _ -> x * n / 365.25
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where
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rnd = roundPrecision precision
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workingDays :: [Weekday] -> Day -> Day -> InsertExcept Natural
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workingDays wds start end
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| interval > 0 =
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let (nFull, nPart) = divMod interval 7
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daysFull = fromIntegral (length wds') * nFull
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daysTail = fromIntegral $ length $ takeWhile (< nPart) wds'
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in return $ fromIntegral $ daysFull + daysTail
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-- TODO make an error here that says something to the effect of "Period must be positive"
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| otherwise = throwError $ InsertException undefined
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where
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interval = diffDays end start
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startDay = dayOfWeek start
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wds' = L.sort $ (\x -> diff (fromWeekday x) startDay) <$> L.nub wds
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diff a b = fromIntegral $ mod (fromEnum a - fromEnum b) 7
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allocatePre
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:: Natural
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-> Rational
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-> [FlatAllocation PretaxValue]
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-> (M.Map T.Text Rational, [FlatAllocation Rational])
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allocatePre precision gross = L.mapAccumR go M.empty
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where
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go m f@FlatAllocation {faValue} =
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let c = preCategory faValue
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p = preValue faValue
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v =
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if prePercent faValue
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then (roundPrecision 3 p / 100) * gross
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else roundPrecision precision p
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in (mapAdd_ c v m, f {faValue = v})
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allo2Trans
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:: BudgetMeta
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-> Day
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-> TaggedAcnt
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-> FlatAllocation Rational
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-> UnbalancedTransfer
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allo2Trans meta day from FlatAllocation {faValue, faTo, faDesc, faCur} =
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FlatTransfer
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{ ftMeta = meta
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, ftWhen = day
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, ftFrom = from
|
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, ftCur = faCur
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, ftTo = faTo
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, ftValue = UnbalancedValue BTFixed faValue
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, ftDesc = faDesc
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}
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|
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allocateTax
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:: Natural
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-> Rational
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-> M.Map T.Text Rational
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-> PeriodScaler
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-> [FlatAllocation TaxValue]
|
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-> [FlatAllocation Rational]
|
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allocateTax precision gross preDeds f = fmap (fmap go)
|
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where
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go TaxValue {tvCategories, tvMethod} =
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let agi = gross - sum (mapMaybe (`M.lookup` preDeds) tvCategories)
|
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in case tvMethod of
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TMPercent p ->
|
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roundPrecision precision $
|
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fromRational $
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roundPrecision 3 p / 100 * agi
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TMBracket TaxProgression {tpDeductible, tpBrackets} ->
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let taxDed = roundPrecision precision $ f precision tpDeductible
|
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in foldBracket f precision (agi - taxDed) tpBrackets
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|
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allocatePost
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:: Natural
|
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-> Rational
|
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-> [FlatAllocation PosttaxValue]
|
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-> [FlatAllocation Rational]
|
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allocatePost precision aftertax = fmap (fmap go)
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where
|
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go PosttaxValue {postValue, postPercent} =
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let v = postValue
|
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in if postPercent
|
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then aftertax * roundPrecision 3 v / 100
|
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else roundPrecision precision v
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|
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-- | Compute effective tax percentage of a bracket
|
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-- The algorithm can be thought of in three phases:
|
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-- 1. Find the highest tax bracket by looping backward until the AGI is less
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-- than the bracket limit
|
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-- 2. Computing the tax in the top bracket by subtracting the AGI from the
|
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-- bracket limit and multiplying by the tax percentage.
|
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-- 3. Adding all lower brackets, which are just the limit of the bracket less
|
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-- the amount of the lower bracket times the percentage.
|
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--
|
|
-- In reality, this can all be done with one loop, but it isn't clear these
|
|
-- three steps are implemented from this alone.
|
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foldBracket :: PeriodScaler -> Natural -> Rational -> [TaxBracket] -> Rational
|
|
foldBracket f precision agi bs = fst $ foldr go (0, agi) $ L.sortOn tbLowerLimit bs
|
|
where
|
|
go TaxBracket {tbLowerLimit, tbPercent} a@(acc, remain) =
|
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let l = roundPrecision precision $ f precision tbLowerLimit
|
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p = roundPrecision 3 tbPercent / 100
|
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in if remain >= l then (acc + p * (remain - l), l) else a
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|
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data FlatAllocation v = FlatAllocation
|
|
{ faValue :: !v
|
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, faDesc :: !T.Text
|
|
, faTo :: !TaggedAcnt
|
|
, faCur :: !BudgetCurrency
|
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}
|
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deriving (Functor, Show)
|
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|
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flattenAllo :: SingleAllocation v -> [FlatAllocation v]
|
|
flattenAllo Allocation {alloAmts, alloCur, alloTo} = fmap go alloAmts
|
|
where
|
|
go Amount {amtValue, amtDesc} =
|
|
FlatAllocation
|
|
{ faCur = NoX alloCur
|
|
, faTo = alloTo
|
|
, faValue = amtValue
|
|
, faDesc = amtDesc
|
|
}
|
|
|
|
-- ASSUME allocations are sorted
|
|
selectAllos :: Day -> BoundAllocation v -> [FlatAllocation v]
|
|
selectAllos day Allocation {alloAmts, alloCur, alloTo} =
|
|
go <$> filter ((`inBounds` day) . amtWhen) alloAmts
|
|
where
|
|
go Amount {amtValue, amtDesc} =
|
|
FlatAllocation
|
|
{ faCur = NoX alloCur
|
|
, faTo = alloTo
|
|
, faValue = amtValue
|
|
, faDesc = amtDesc
|
|
}
|
|
|
|
expandTransfers
|
|
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
|
|
=> CommitRId
|
|
-> T.Text
|
|
-> Maybe Interval
|
|
-> [BudgetTransfer]
|
|
-> m [UnbalancedTransfer]
|
|
expandTransfers key name localInterval ts = do
|
|
txs <-
|
|
fmap (L.sortOn ftWhen . concat) $
|
|
combineErrors $
|
|
fmap (expandTransfer key name) ts
|
|
case localInterval of
|
|
Nothing -> return txs
|
|
Just i -> do
|
|
bounds <- liftExcept $ resolveBounds i
|
|
return $ filter (inBounds bounds . ftWhen) txs
|
|
|
|
initialCurrency :: BudgetCurrency -> CurID
|
|
initialCurrency (NoX c) = c
|
|
initialCurrency (X Exchange {xFromCur = c}) = c
|
|
|
|
expandTransfer
|
|
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
|
|
=> CommitRId
|
|
-> T.Text
|
|
-> BudgetTransfer
|
|
-> m [UnbalancedTransfer]
|
|
expandTransfer key name Transfer {transAmounts, transTo, transCurrency, transFrom} = do
|
|
precision <- lookupCurrencyPrec $ initialCurrency transCurrency
|
|
fmap concat $ combineErrors $ fmap (go precision) transAmounts
|
|
where
|
|
go
|
|
precision
|
|
Amount
|
|
{ amtWhen = pat
|
|
, amtValue = BudgetTransferValue {btVal = v, btType = y}
|
|
, amtDesc = desc
|
|
} =
|
|
withDates pat $ \day -> do
|
|
let meta = BudgetMeta {bmCommit = key, bmName = name}
|
|
return
|
|
FlatTransfer
|
|
{ ftMeta = meta
|
|
, ftWhen = day
|
|
, ftCur = transCurrency
|
|
, ftFrom = transFrom
|
|
, ftTo = transTo
|
|
, ftValue = UnbalancedValue y $ roundPrecision precision v
|
|
, ftDesc = desc
|
|
}
|
|
|
|
insertBudgetTx :: (MonadInsertError m, MonadSqlQuery m, MonadFinance m) => BalancedTransfer -> m ()
|
|
insertBudgetTx FlatTransfer {ftFrom, ftTo, ftMeta, ftCur, ftValue, ftDesc, ftWhen} = do
|
|
((sFrom, sTo), exchange) <- splitPair ftFrom ftTo ftCur ftValue
|
|
insertPair sFrom sTo
|
|
forM_ exchange $ uncurry insertPair
|
|
where
|
|
insertPair from to = do
|
|
k <- insert $ TransactionR (bmCommit ftMeta) ftWhen ftDesc
|
|
insertBudgetLabel k from
|
|
insertBudgetLabel k to
|
|
insertBudgetLabel k split = do
|
|
sk <- insertSplit k split
|
|
insert_ $ BudgetLabelR sk $ bmName ftMeta
|
|
|
|
type SplitPair = (KeySplit, KeySplit)
|
|
|
|
splitPair
|
|
:: (MonadInsertError m, MonadFinance m)
|
|
=> TaggedAcnt
|
|
-> TaggedAcnt
|
|
-> BudgetCurrency
|
|
-> Rational
|
|
-> m (SplitPair, Maybe SplitPair)
|
|
splitPair from to cur val = case cur of
|
|
NoX curid -> (,Nothing) <$> pair curid from to val
|
|
X Exchange {xFromCur, xToCur, xAcnt, xRate} -> do
|
|
let middle = TaggedAcnt xAcnt []
|
|
let res1 = pair xFromCur from middle val
|
|
let res2 = pair xToCur middle to (val * roundPrecision 3 xRate)
|
|
combineError res1 res2 $ \a b -> (a, Just b)
|
|
where
|
|
pair curid from_ to_ v = do
|
|
let s1 = split curid from_ (-v)
|
|
let s2 = split curid to_ v
|
|
combineError s1 s2 (,)
|
|
split c TaggedAcnt {taAcnt, taTags} v =
|
|
resolveSplit $
|
|
Entry
|
|
{ eAcnt = taAcnt
|
|
, eValue = v
|
|
, eComment = ""
|
|
, eCurrency = c
|
|
, eTags = taTags
|
|
}
|
|
|
|
checkAcntType
|
|
:: (MonadInsertError m, MonadFinance m)
|
|
=> AcntType
|
|
-> AcntID
|
|
-> m AcntID
|
|
checkAcntType t = checkAcntTypes (t :| [])
|
|
|
|
checkAcntTypes
|
|
:: (MonadInsertError m, MonadFinance m)
|
|
=> NE.NonEmpty AcntType
|
|
-> AcntID
|
|
-> m AcntID
|
|
checkAcntTypes ts i = go =<< lookupAccountType i
|
|
where
|
|
go t
|
|
| t `L.elem` ts = return i
|
|
| otherwise = throwError $ InsertException [AccountError i ts]
|
|
|
|
--------------------------------------------------------------------------------
|
|
-- statements
|
|
|
|
splitHistory :: [History] -> ([HistTransfer], [Statement])
|
|
splitHistory = partitionEithers . fmap go
|
|
where
|
|
go (HistTransfer x) = Left x
|
|
go (HistStatement x) = Right x
|
|
|
|
-- insertStatement
|
|
-- :: (MonadUnliftIO m, MonadSqlQuery m, MonadFinance m)
|
|
-- => History
|
|
-- -> m ()
|
|
-- insertStatement (HistTransfer m) = liftIOExceptT $ insertManual m
|
|
-- insertStatement (HistStatement i) = insertImport i
|
|
|
|
insertHistTransfer
|
|
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
|
|
=> HistTransfer
|
|
-> m ()
|
|
insertHistTransfer
|
|
m@Transfer
|
|
{ transFrom = from
|
|
, transTo = to
|
|
, transCurrency = u
|
|
, transAmounts = amts
|
|
} = do
|
|
whenHash CTManual m () $ \c -> do
|
|
bounds <- askDBState kmStatementInterval
|
|
let precRes = lookupCurrencyPrec u
|
|
let go Amount {amtWhen, amtValue, amtDesc} = do
|
|
let dayRes = liftExcept $ expandDatePat bounds amtWhen
|
|
(days, precision) <- combineError dayRes precRes (,)
|
|
let tx day = txPair day from to u (roundPrecision precision amtValue) amtDesc
|
|
keys <- combineErrors $ fmap tx days
|
|
mapM_ (insertTx c) keys
|
|
void $ combineErrors $ fmap go amts
|
|
|
|
readHistStmt :: (MonadUnliftIO m, MonadFinance m) => Statement -> m (Maybe (CommitR, [KeyTx]))
|
|
readHistStmt i = whenHash_ CTImport i $ do
|
|
bs <- readImport i
|
|
bounds <- askDBState kmStatementInterval
|
|
liftIOExceptT $ mapErrors resolveTx $ filter (inBounds bounds . txDate) bs
|
|
|
|
insertHistStmt :: (MonadSqlQuery m) => CommitR -> [KeyTx] -> m ()
|
|
insertHistStmt c ks = do
|
|
ck <- insert c
|
|
mapM_ (insertTx ck) ks
|
|
|
|
-- insertImport
|
|
-- :: (MonadUnliftIO m, MonadSqlQuery m, MonadFinance m)
|
|
-- => Statement
|
|
-- -> m ()
|
|
-- insertImport i = whenHash CTImport i () $ \c -> do
|
|
-- -- TODO this isn't efficient, the whole file will be read and maybe no
|
|
-- -- transactions will be desired
|
|
-- bs <- readImport i
|
|
-- bounds <- expandBounds <$> askDBState kmStatementInterval
|
|
-- keys <- liftIOExceptT $ mapErrors resolveTx $ filter (inBounds bounds . txDate) bs
|
|
-- mapM_ (insertTx c) keys
|
|
|
|
--------------------------------------------------------------------------------
|
|
-- low-level transaction stuff
|
|
|
|
-- TODO tags here?
|
|
txPair
|
|
:: (MonadInsertError m, MonadFinance m)
|
|
=> Day
|
|
-> AcntID
|
|
-> AcntID
|
|
-> CurID
|
|
-> Rational
|
|
-> T.Text
|
|
-> m KeyTx
|
|
txPair day from to cur val desc = resolveTx tx
|
|
where
|
|
split a v =
|
|
Entry
|
|
{ eAcnt = a
|
|
, eValue = v
|
|
, eComment = ""
|
|
, eCurrency = cur
|
|
, eTags = []
|
|
}
|
|
tx =
|
|
Tx
|
|
{ txDescr = desc
|
|
, txDate = day
|
|
, txSplits = [split from (-val), split to val]
|
|
}
|
|
|
|
resolveTx :: (MonadInsertError m, MonadFinance m) => BalTx -> m KeyTx
|
|
resolveTx t@Tx {txSplits = ss} =
|
|
fmap (\kss -> t {txSplits = kss}) $
|
|
combineErrors $
|
|
fmap resolveSplit ss
|
|
|
|
resolveSplit :: (MonadInsertError m, MonadFinance m) => BalSplit -> m KeySplit
|
|
resolveSplit s@Entry {eAcnt, eCurrency, eValue, eTags} = do
|
|
let aRes = lookupAccountKey eAcnt
|
|
let cRes = lookupCurrencyKey eCurrency
|
|
let sRes = lookupAccountSign eAcnt
|
|
let tagRes = combineErrors $ fmap lookupTag eTags
|
|
-- TODO correct sign here?
|
|
-- TODO lenses would be nice here
|
|
combineError (combineError3 aRes cRes sRes (,,)) tagRes $
|
|
\(aid, cid, sign) tags ->
|
|
s
|
|
{ eAcnt = aid
|
|
, eCurrency = cid
|
|
, eValue = eValue * fromIntegral (sign2Int sign)
|
|
, eTags = tags
|
|
}
|
|
|
|
insertTx :: MonadSqlQuery m => CommitRId -> KeyTx -> m ()
|
|
insertTx c Tx {txDate = d, txDescr = e, txSplits = ss} = do
|
|
k <- insert $ TransactionR c d e
|
|
mapM_ (insertSplit k) ss
|
|
|
|
insertSplit :: MonadSqlQuery m => TransactionRId -> KeySplit -> m SplitRId
|
|
insertSplit t Entry {eAcnt, eCurrency, eValue, eComment, eTags} = do
|
|
k <- insert $ SplitR t eCurrency eAcnt eComment eValue
|
|
mapM_ (insert_ . TagRelationR k) eTags
|
|
return k
|
|
|
|
lookupAccount :: (MonadInsertError m, MonadFinance m) => AcntID -> m (AccountRId, AcntSign, AcntType)
|
|
lookupAccount = lookupFinance AcntField kmAccount
|
|
|
|
lookupAccountKey :: (MonadInsertError m, MonadFinance m) => AcntID -> m AccountRId
|
|
lookupAccountKey = fmap fstOf3 . lookupAccount
|
|
|
|
lookupAccountSign :: (MonadInsertError m, MonadFinance m) => AcntID -> m AcntSign
|
|
lookupAccountSign = fmap sndOf3 . lookupAccount
|
|
|
|
lookupAccountType :: (MonadInsertError m, MonadFinance m) => AcntID -> m AcntType
|
|
lookupAccountType = fmap thdOf3 . lookupAccount
|
|
|
|
lookupCurrency :: (MonadInsertError m, MonadFinance m) => T.Text -> m (CurrencyRId, Natural)
|
|
lookupCurrency = lookupFinance CurField kmCurrency
|
|
|
|
lookupCurrencyKey :: (MonadInsertError m, MonadFinance m) => AcntID -> m CurrencyRId
|
|
lookupCurrencyKey = fmap fst . lookupCurrency
|
|
|
|
lookupCurrencyPrec :: (MonadInsertError m, MonadFinance m) => AcntID -> m Natural
|
|
lookupCurrencyPrec = fmap snd . lookupCurrency
|
|
|
|
lookupTag :: (MonadInsertError m, MonadFinance m) => TagID -> m TagRId
|
|
lookupTag = lookupFinance TagField kmTag
|
|
|
|
lookupFinance
|
|
:: (MonadInsertError m, MonadFinance m)
|
|
=> SplitIDType
|
|
-> (DBState -> M.Map T.Text a)
|
|
-> T.Text
|
|
-> m a
|
|
lookupFinance t f c = (liftExcept . lookupErr (DBKey t) c) =<< askDBState f
|
|
|
|
-- TODO this hashes twice (not that it really matters)
|
|
|
|
whenHash
|
|
:: (Hashable a, MonadFinance m, MonadSqlQuery m)
|
|
=> ConfigType
|
|
-> a
|
|
-> b
|
|
-> (CommitRId -> m b)
|
|
-> m b
|
|
whenHash t o def f = do
|
|
let h = hash o
|
|
hs <- askDBState kmNewCommits
|
|
if h `elem` hs then f =<< insert (CommitR h t) else return def
|
|
|
|
whenHash_
|
|
:: (Hashable a, MonadFinance m)
|
|
=> ConfigType
|
|
-> a
|
|
-> m b
|
|
-> m (Maybe (CommitR, b))
|
|
whenHash_ t o f = do
|
|
let h = hash o
|
|
let c = CommitR h t
|
|
hs <- askDBState kmNewCommits
|
|
if h `elem` hs then Just . (c,) <$> f else return Nothing
|