hledger/hledger-lib/Hledger/Data/Account.hs

272 lines
10 KiB
Haskell

{-# LANGUAGE RecordWildCards, OverloadedStrings #-}
{-|
An 'Account' has a name, a list of subaccounts, an optional parent
account, and subaccounting-excluding and -including balances.
-}
module Hledger.Data.Account
where
import Data.List
import Data.List.Extra (groupSort, groupOn)
import Data.Maybe
import Data.Ord
import qualified Data.Map as M
import Data.Text (pack,unpack)
import Safe (headMay, lookupJustDef)
import Text.Printf
import Hledger.Data.AccountName
import Hledger.Data.Amount
import Hledger.Data.Posting()
import Hledger.Data.Types
import Hledger.Utils
-- deriving instance Show Account
instance Show Account where
show Account{..} = printf "Account %s (boring:%s, postings:%d, ebalance:%s, ibalance:%s)"
(pack $ regexReplace ":" "_" $ unpack aname) -- hide : so pretty-show doesn't break line
(if aboring then "y" else "n" :: String)
anumpostings
(showMixedAmount aebalance)
(showMixedAmount aibalance)
instance Eq Account where
(==) a b = aname a == aname b -- quick equality test for speed
-- and
-- [ aname a == aname b
-- -- , aparent a == aparent b -- avoid infinite recursion
-- , asubs a == asubs b
-- , aebalance a == aebalance b
-- , aibalance a == aibalance b
-- ]
nullacct = Account
{ aname = ""
, adeclarationinfo = Nothing
, asubs = []
, aparent = Nothing
, aboring = False
, anumpostings = 0
, aebalance = nullmixedamt
, aibalance = nullmixedamt
}
-- | Derive 1. an account tree and 2. each account's total exclusive
-- and inclusive changes from a list of postings.
-- This is the core of the balance command (and of *ledger).
-- The accounts are returned as a list in flattened tree order,
-- and also reference each other as a tree.
-- (The first account is the root of the tree.)
accountsFromPostings :: [Posting] -> [Account]
accountsFromPostings ps =
let
grouped = groupSort [(paccount p,pamount p) | p <- ps]
counted = [(aname, length amts) | (aname, amts) <- grouped]
summed = [(aname, sumStrict amts) | (aname, amts) <- grouped] -- always non-empty
acctstree = accountTree "root" $ map fst summed
acctswithnumps = mapAccounts setnumps acctstree where setnumps a = a{anumpostings=fromMaybe 0 $ lookup (aname a) counted}
acctswithebals = mapAccounts setebalance acctswithnumps where setebalance a = a{aebalance=lookupJustDef nullmixedamt (aname a) summed}
acctswithibals = sumAccounts acctswithebals
acctswithparents = tieAccountParents acctswithibals
acctsflattened = flattenAccounts acctswithparents
in
acctsflattened
-- | Convert a list of account names to a tree of Account objects,
-- with just the account names filled in.
-- A single root account with the given name is added.
accountTree :: AccountName -> [AccountName] -> Account
accountTree rootname as = nullacct{aname=rootname, asubs=map (uncurry accountTree') $ M.assocs m }
where
T m = treeFromPaths $ map expandAccountName as :: FastTree AccountName
accountTree' a (T m) =
nullacct{
aname=a
,asubs=map (uncurry accountTree') $ M.assocs m
}
-- | Tie the knot so all subaccounts' parents are set correctly.
tieAccountParents :: Account -> Account
tieAccountParents = tie Nothing
where
tie parent a@Account{..} = a'
where
a' = a{aparent=parent, asubs=map (tie (Just a')) asubs}
-- | Get this account's parent accounts, from the nearest up to the root.
parentAccounts :: Account -> [Account]
parentAccounts Account{aparent=Nothing} = []
parentAccounts Account{aparent=Just a} = a:parentAccounts a
-- | List the accounts at each level of the account tree.
accountsLevels :: Account -> [[Account]]
accountsLevels = takeWhile (not . null) . iterate (concatMap asubs) . (:[])
-- | Map a (non-tree-structure-modifying) function over this and sub accounts.
mapAccounts :: (Account -> Account) -> Account -> Account
mapAccounts f a = f a{asubs = map (mapAccounts f) $ asubs a}
-- | Is the predicate true on any of this account or its subaccounts ?
anyAccounts :: (Account -> Bool) -> Account -> Bool
anyAccounts p a
| p a = True
| otherwise = any (anyAccounts p) $ asubs a
-- | Add subaccount-inclusive balances to an account tree.
sumAccounts :: Account -> Account
sumAccounts a
| null $ asubs a = a{aibalance=aebalance a}
| otherwise = a{aibalance=ibal, asubs=subs}
where
subs = map sumAccounts $ asubs a
ibal = sum $ aebalance a : map aibalance subs
-- | Remove all subaccounts below a certain depth.
clipAccounts :: Int -> Account -> Account
clipAccounts 0 a = a{asubs=[]}
clipAccounts d a = a{asubs=subs}
where
subs = map (clipAccounts (d-1)) $ asubs a
-- | Remove subaccounts below the specified depth, aggregating their balance at the depth limit
-- (accounts at the depth limit will have any sub-balances merged into their exclusive balance).
clipAccountsAndAggregate :: Int -> [Account] -> [Account]
clipAccountsAndAggregate d as = combined
where
clipped = [a{aname=clipOrEllipsifyAccountName d $ aname a} | a <- as]
combined = [a{aebalance=sum (map aebalance same)}
| same@(a:_) <- groupOn aname clipped]
{-
test cases, assuming d=1:
assets:cash 1 1
assets:checking 1 1
->
as: [assets:cash 1 1, assets:checking 1 1]
clipped: [assets 1 1, assets 1 1]
combined: [assets 2 2]
assets 0 2
assets:cash 1 1
assets:checking 1 1
->
as: [assets 0 2, assets:cash 1 1, assets:checking 1 1]
clipped: [assets 0 2, assets 1 1, assets 1 1]
combined: [assets 2 2]
assets 0 2
assets:bank 1 2
assets:bank:checking 1 1
->
as: [assets 0 2, assets:bank 1 2, assets:bank:checking 1 1]
clipped: [assets 0 2, assets 1 2, assets 1 1]
combined: [assets 2 2]
-}
-- | Remove all leaf accounts and subtrees matching a predicate.
pruneAccounts :: (Account -> Bool) -> Account -> Maybe Account
pruneAccounts p = headMay . prune
where
prune a
| null prunedsubs = if p a then [] else [a']
| otherwise = [a']
where
prunedsubs = concatMap prune $ asubs a
a' = a{asubs=prunedsubs}
-- | Flatten an account tree into a list, which is sometimes
-- convenient. Note since accounts link to their parents/subs, the
-- tree's structure remains intact and can still be used. It's a tree/list!
flattenAccounts :: Account -> [Account]
flattenAccounts a = squish a []
where squish a as = a : Prelude.foldr squish as (asubs a)
-- | Filter an account tree (to a list).
filterAccounts :: (Account -> Bool) -> Account -> [Account]
filterAccounts p a
| p a = a : concatMap (filterAccounts p) (asubs a)
| otherwise = concatMap (filterAccounts p) (asubs a)
-- | Sort each group of siblings in an account tree by inclusive amount,
-- so that the accounts with largest normal balances are listed first.
-- The provided normal balance sign determines whether normal balances
-- are negative or positive, affecting the sort order. Ie,
-- if balances are normally negative, then the most negative balances
-- sort first, and vice versa.
sortAccountTreeByAmount :: NormalSign -> Account -> Account
sortAccountTreeByAmount normalsign a
| null $ asubs a = a
| otherwise = a{asubs=
sortBy (maybeflip $ comparing (normaliseMixedAmountSquashPricesForDisplay . aibalance)) $
map (sortAccountTreeByAmount normalsign) $ asubs a}
where
maybeflip | normalsign==NormallyNegative = id
| otherwise = flip
-- | Add extra info for this account derived from the Journal's
-- account directives, if any (comment, tags, declaration order..).
accountSetDeclarationInfo :: Journal -> Account -> Account
accountSetDeclarationInfo j a@Account{..} =
a{ adeclarationinfo=lookup aname $ jdeclaredaccounts j }
-- | Sort account names by the order in which they were declared in
-- the journal, at each level of the account tree (ie within each
-- group of siblings). Undeclared accounts are sorted last and
-- alphabetically.
-- This is hledger's default sort for reports organised by account.
-- The account list is converted to a tree temporarily, adding any
-- missing parents; these can be kept (suitable for a tree-mode report)
-- or removed (suitable for a flat-mode report).
--
sortAccountNamesByDeclaration :: Journal -> Bool -> [AccountName] -> [AccountName]
sortAccountNamesByDeclaration j keepparents as =
(if keepparents then id else filter (`elem` as)) $ -- maybe discard missing parents that were added
map aname $ -- keep just the names
drop 1 $ -- drop the root node that was added
flattenAccounts $ -- convert to an account list
sortAccountTreeByDeclaration $ -- sort by declaration order (and name)
mapAccounts (accountSetDeclarationInfo j) $ -- add declaration order info
accountTree "root" -- convert to an account tree
as
-- | Sort each group of siblings in an account tree by declaration order, then account name.
-- So each group will contain first the declared accounts,
-- in the same order as their account directives were parsed,
-- and then the undeclared accounts, sorted by account name.
sortAccountTreeByDeclaration :: Account -> Account
sortAccountTreeByDeclaration a
| null $ asubs a = a
| otherwise = a{asubs=
sortOn accountDeclarationOrderAndName $
map sortAccountTreeByDeclaration $ asubs a
}
accountDeclarationOrderAndName :: Account -> (Int, AccountName)
accountDeclarationOrderAndName a = (adeclarationorder', aname a)
where
adeclarationorder' = maybe maxBound adideclarationorder $ adeclarationinfo a
-- | Search an account list by name.
lookupAccount :: AccountName -> [Account] -> Maybe Account
lookupAccount a = find ((==a).aname)
-- debug helpers
printAccounts :: Account -> IO ()
printAccounts = putStrLn . showAccounts
showAccounts = unlines . map showAccountDebug . flattenAccounts
showAccountsBoringFlag = unlines . map (show . aboring) . flattenAccounts
showAccountDebug a = printf "%-25s %4s %4s %s"
(aname a)
(showMixedAmount $ aebalance a)
(showMixedAmount $ aibalance a)
(if aboring a then "b" else " " :: String)