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Author SHA1 Message Date
Nathan Dwarshuis e6f97651e5 Merge branch 'use_subaccount' 2023-07-16 19:57:00 -04:00
Nathan Dwarshuis 2e0b591312 ADD errors for everything that needs them (ish) 2023-07-16 19:55:33 -04:00
Nathan Dwarshuis cafc066881 REF clean up useless types 2023-07-16 12:51:39 -04:00
Nathan Dwarshuis ad5e4a0748 REF use newtype for indices 2023-07-16 12:15:39 -04:00
Nathan Dwarshuis 901882b79f REF use newtypes for budget and tx desc 2023-07-16 00:39:03 -04:00
Nathan Dwarshuis 642ebb4727 REF use newtype for precision 2023-07-16 00:20:01 -04:00
Nathan Dwarshuis 81f09d1280 REF use newtypes for ids and commits 2023-07-16 00:10:49 -04:00
Nathan Dwarshuis cd89597b1f REF delete lots of dead code 2023-07-15 23:28:21 -04:00
Nathan Dwarshuis 8901fd6a64 FIX update bugs 2023-07-15 23:25:28 -04:00
Nathan Dwarshuis 223be34145 FIX mixed up account paths/keys 2023-07-15 14:14:23 -04:00
Nathan Dwarshuis 0e74ae41db FIX reversed account path 2023-07-13 23:43:10 -04:00
Nathan Dwarshuis 4c46f035f5 WIP use more robust update strategy 2023-07-13 23:31:27 -04:00
Nathan Dwarshuis c8f7689c7a ENH store account sign in db itself 2023-07-09 11:13:35 -04:00
Nathan Dwarshuis 9c93ad25af ENH break up input files to thread them 2023-07-09 00:16:57 -04:00
Nathan Dwarshuis bf1434542f ENH remove useless field 2023-07-08 19:05:34 -04:00
Nathan Dwarshuis 46decdc4de ENH use decimals to round 2023-07-08 00:52:40 -04:00
Nathan Dwarshuis c886c53f17 FIX readd export 2023-07-07 20:50:55 -04:00
Nathan Dwarshuis 90b88945c5 ENH clean up types again 2023-07-07 20:42:41 -04:00
Nathan Dwarshuis 00346ff8ee ENH clean up types a bit 2023-07-07 20:20:09 -04:00
Nathan Dwarshuis 2946a8f9e2 ADD priority flag to keep tx's sorted always 2023-07-07 00:20:18 -04:00
Nathan Dwarshuis 24bc9a239b FIX rounding errors 2023-07-06 00:05:16 -04:00
Nathan Dwarshuis dce3ff4166 ENH clean up (and hopefully fix) lots of balancing stuff 2023-07-05 22:30:24 -04:00
Nathan Dwarshuis d9709f565f FIX separate running totals by budget label 2023-07-04 10:35:11 -04:00
Nathan Dwarshuis 8c9dc1e970 REF rearrange stuff 2023-07-04 00:11:25 -04:00
Nathan Dwarshuis bae847d9f3 WIP balance transactions in two different ways 2023-07-03 20:27:52 -04:00
Nathan Dwarshuis d5761c75ed REF move commont stuff to common modules 2023-07-01 18:58:15 -04:00
Nathan Dwarshuis ebef4e0f6b WIP mostly unify history and budget transfer pipelines 2023-07-01 18:32:20 -04:00
Nathan Dwarshuis 5c1d2bce9d WIP unify budget and history pipelines 2023-07-01 13:12:50 -04:00
Nathan Dwarshuis 1ae670187a WIP unify history and budget pipelines 2023-06-30 23:54:39 -04:00
Nathan Dwarshuis cc0699eb4e WIP make budget and statement paths use same machinery 2023-06-29 21:32:14 -04:00
Nathan Dwarshuis d617fa52cc REF clean code 2023-06-26 19:04:37 -04:00
Nathan Dwarshuis f8669e5a15 WIP add code to actually insert updates in the db 2023-06-26 00:10:40 -04:00
Nathan Dwarshuis 7a44aeb5db WIP use newtypes to keep update balancer sane 2023-06-25 21:16:47 -04:00
Nathan Dwarshuis fc4da967be WIP read updates from database 2023-06-25 14:26:35 -04:00
Nathan Dwarshuis 05928087b2 WIP add logic for updating entries and summing read only entries 2023-06-24 17:32:43 -04:00
Nathan Dwarshuis 5697a071ab WIP add lots of stuff to cache deferred calculations 2023-06-22 23:27:14 -04:00
Nathan Dwarshuis 09e03ff675 ADD means to scale/flip the value of a transaction 2023-06-20 22:52:52 -04:00
Nathan Dwarshuis 4c88151610 ENH split partn 2023-06-19 13:21:20 -04:00
Nathan Dwarshuis 33678e3908 FIX yet another typo 2023-06-19 13:00:23 -04:00
Nathan Dwarshuis 352cc88eed FIX more typos 2023-06-19 12:44:14 -04:00
Nathan Dwarshuis 845899d073 FIX typo 2023-06-19 12:43:16 -04:00
Nathan Dwarshuis ec74e735d0 FIX more exports 2023-06-19 12:41:57 -04:00
Nathan Dwarshuis 024a57179d FIX half getter expiort 2023-06-19 12:39:56 -04:00
Nathan Dwarshuis f3d2c1655e FIX undefined error paths 2023-06-19 12:33:50 -04:00
Nathan Dwarshuis 03e75ce549 ADD linked credit entries 2023-06-19 12:14:18 -04:00
Nathan Dwarshuis c2525fb77c FIX balancing stuff 2023-06-18 00:14:06 -04:00
Nathan Dwarshuis 87e6dcff8f FIX typos 2023-06-17 20:57:24 -04:00
Nathan Dwarshuis 8d45614571 ADD defaults 2023-06-17 20:06:14 -04:00
Nathan Dwarshuis c18750d600 ADD comment and tags to txgetter 2023-06-17 00:16:01 -04:00
Nathan Dwarshuis 5858e2f8ce FIX typo 2023-06-16 23:46:09 -04:00
Nathan Dwarshuis a144b9fa3c ENH update dhall interface 2023-06-16 23:41:01 -04:00
Nathan Dwarshuis 4c0b192b9c FIX typo (clean compile) 2023-06-16 22:06:48 -04:00
Nathan Dwarshuis ad0975aba7 ENH use sane types to simplify tx balancing 2023-06-16 22:05:28 -04:00
Nathan Dwarshuis 6926003c46 ENH assault user's face with all errors at once 2023-06-13 20:32:12 -04:00
Nathan Dwarshuis efffda378a ADD calculations for running balances in statements 2023-06-13 20:12:29 -04:00
Nathan Dwarshuis 592c1550c0 FIX typo 2023-06-13 20:12:23 -04:00
Nathan Dwarshuis b2e4ee05e8 WIP allow running balances to be used in history 2023-06-12 00:27:34 -04:00
Nathan Dwarshuis 45df1af534 ENH export account tree type 2023-06-11 12:27:57 -04:00
Nathan Dwarshuis dcd260f6fd FIX update types 2023-06-10 21:38:13 -04:00
Nathan Dwarshuis 776a10ba11 ENH allow multiple entries on credit side of transaction statement getter 2023-06-10 21:30:30 -04:00
12 changed files with 2451 additions and 1612 deletions

View File

@ -2,13 +2,17 @@
module Main (main) where module Main (main) where
import Control.Concurrent
import Control.Monad.Except import Control.Monad.Except
import Control.Monad.IO.Rerunnable import Control.Monad.IO.Rerunnable
import Control.Monad.Logger import Control.Monad.Logger
import Control.Monad.Reader import Control.Monad.Reader
import Data.Bitraversable
-- import Data.Hashable
import qualified Data.Text.IO as TI import qualified Data.Text.IO as TI
import qualified Database.Esqueleto.Experimental as E
import Database.Persist.Monad import Database.Persist.Monad
import Dhall hiding (double, record) import qualified Dhall hiding (double, record)
import Internal.Budget import Internal.Budget
import Internal.Database import Internal.Database
import Internal.History import Internal.History
@ -17,6 +21,7 @@ import Internal.Utils
import Options.Applicative import Options.Applicative
import RIO import RIO
import RIO.FilePath import RIO.FilePath
-- import qualified RIO.Map as M
import qualified RIO.Text as T import qualified RIO.Text as T
main :: IO () main :: IO ()
@ -30,14 +35,26 @@ main = parse =<< execParser o
<> header "pwncash - your budget, your life" <> header "pwncash - your budget, your life"
) )
data Options = Options FilePath Mode type ConfigPath = FilePath
type BudgetPath = FilePath
type HistoryPath = FilePath
data Options = Options !ConfigPath !Mode
data Mode data Mode
= Reset = Reset
| DumpCurrencies | DumpCurrencies
| DumpAccounts | DumpAccounts
| DumpAccountKeys | DumpAccountKeys
| Sync | Sync !SyncOptions
data SyncOptions = SyncOptions
{ syncBudgets :: ![BudgetPath]
, syncHistories :: ![HistoryPath]
, syncThreads :: !Int
}
configFile :: Parser FilePath configFile :: Parser FilePath
configFile = configFile =
@ -104,6 +121,35 @@ sync =
<> short 'S' <> short 'S'
<> help "Sync config to database" <> help "Sync config to database"
) )
<*> syncOptions
syncOptions :: Parser SyncOptions
syncOptions =
SyncOptions
<$> many
( strOption
( long "budget"
<> short 'b'
<> metavar "BUDGET"
<> help "path to a budget config"
)
)
<*> many
( strOption
( long "history"
<> short 'H'
<> metavar "HISTORY"
<> help "path to a history config"
)
)
<*> option
auto
( long "threads"
<> short 't'
<> metavar "THREADS"
<> value 1
<> help "number of threads for syncing"
)
parse :: Options -> IO () parse :: Options -> IO ()
parse (Options c Reset) = do parse (Options c Reset) = do
@ -112,7 +158,8 @@ parse (Options c Reset) = do
parse (Options c DumpAccounts) = runDumpAccounts c parse (Options c DumpAccounts) = runDumpAccounts c
parse (Options c DumpAccountKeys) = runDumpAccountKeys c parse (Options c DumpAccountKeys) = runDumpAccountKeys c
parse (Options c DumpCurrencies) = runDumpCurrencies c parse (Options c DumpCurrencies) = runDumpCurrencies c
parse (Options c Sync) = runSync c parse (Options c (Sync SyncOptions {syncBudgets, syncHistories, syncThreads})) =
runSync syncThreads c syncBudgets syncHistories
runDumpCurrencies :: MonadUnliftIO m => FilePath -> m () runDumpCurrencies :: MonadUnliftIO m => FilePath -> m ()
runDumpCurrencies c = do runDumpCurrencies c = do
@ -150,50 +197,70 @@ runDumpAccountKeys c = do
ar <- accounts <$> readConfig c ar <- accounts <$> readConfig c
let ks = let ks =
paths2IDs $ paths2IDs $
fmap (double . fst) $ fmap (double . accountRFullpath . E.entityVal) $
concatMap (t3 . uncurry tree2Records) $ fst $
flattenAcntRoot ar indexAcntRoot ar
mapM_ (uncurry printPair) ks mapM_ (uncurry printPair) ks
where where
printPair i p = do printPair i p = do
liftIO $ putStrLn $ T.unpack $ T.concat [acntPath2Text p, ": ", i] liftIO $ putStrLn $ T.unpack $ T.concat [acntPath2Text p, ": ", unAcntID i]
t3 (_, _, x) = x
double x = (x, x) double x = (x, x)
runSync :: FilePath -> IO () runSync :: Int -> FilePath -> [FilePath] -> [FilePath] -> IO ()
runSync c = do runSync threads c bs hs = do
setNumCapabilities threads
-- putStrLn "reading config"
config <- readConfig c config <- readConfig c
let (hTs, hSs) = splitHistory $ statements config -- putStrLn "reading statements"
(bs', hs') <-
fmap (bimap concat concat . partitionEithers) $
pooledMapConcurrentlyN threads (bimapM readDhall readDhall) $
(Left <$> bs) ++ (Right <$> hs)
pool <- runNoLoggingT $ mkPool $ sqlConfig config pool <- runNoLoggingT $ mkPool $ sqlConfig config
putStrLn "doing other stuff"
setNumCapabilities 1
handle err $ do handle err $ do
-- _ <- askLoggerIO -- _ <- askLoggerIO
-- get the current DB state -- Get the current DB state.
(state, updates) <- runSqlQueryT pool $ do state <- runSqlQueryT pool $ do
runMigration migrateAll runMigration migrateAll
liftIOExceptT $ getDBState config liftIOExceptT $ readConfigState config bs' hs'
-- read desired statements from disk -- Read raw transactions according to state. If a transaction is already in
bSs <- -- the database, don't read it but record the commit so we can update it.
flip runReaderT state $ toIns <-
catMaybes <$> mapErrorsIO (readHistStmt root) hSs flip runReaderT state $ do
(CRUDOps hSs _ _ _) <- asks csHistStmts
hSs' <- mapErrorsIO (readHistStmt root) hSs
(CRUDOps hTs _ _ _) <- asks csHistTrans
hTs' <- liftIOExceptT $ mapErrors readHistTransfer hTs
(CRUDOps bTs _ _ _) <- asks csBudgets
bTs' <- liftIOExceptT $ mapErrors readBudget bTs
return $ concat $ hSs' ++ hTs' ++ bTs'
-- update the DB -- Update the DB.
runSqlQueryT pool $ withTransaction $ flip runReaderT state $ do runSqlQueryT pool $ withTransaction $ flip runReaderT state $ do
let hTransRes = mapErrors insertHistTransfer hTs -- NOTE this must come first (unless we defer foreign keys)
let bgtRes = mapErrors insertBudget $ budget config updateDBState
updateDBState updates -- TODO this will only work if foreign keys are deferred
res <- runExceptT $ do res <- runExceptT $ do
mapM_ (uncurry insertHistStmt) bSs (CRUDOps _ bRs bUs _) <- asks csBudgets
combineError hTransRes bgtRes $ \_ _ -> () (CRUDOps _ tRs tUs _) <- asks csHistTrans
(CRUDOps _ sRs sUs _) <- asks csHistStmts
let ebs = fmap ToUpdate (bUs ++ tUs ++ sUs) ++ fmap ToRead (bRs ++ tRs ++ sRs) ++ fmap ToInsert toIns
insertAll ebs
-- NOTE this rerunnable thing is a bit misleading; fromEither will throw
-- whatever error is encountered above in an IO context, but the first
-- thrown error should be caught despite possibly needing to be rerun
rerunnableIO $ fromEither res rerunnableIO $ fromEither res
where where
root = takeDirectory c root = takeDirectory c
err (InsertException es) = do err (AppException es) = do
liftIO $ mapM_ TI.putStrLn $ concatMap showError es liftIO $ mapM_ TI.putStrLn $ concatMap showError es
exitFailure exitFailure
-- showBalances
readConfig :: MonadUnliftIO m => FilePath -> m Config readConfig :: MonadUnliftIO m => FilePath -> m Config
readConfig confpath = liftIO $ unfix <$> Dhall.inputFile Dhall.auto confpath readConfig = fmap unfix . readDhall
readDhall :: Dhall.FromDhall a => MonadUnliftIO m => FilePath -> m a
readDhall confpath = liftIO $ Dhall.inputFile Dhall.auto confpath

View File

@ -75,7 +75,8 @@ library
ViewPatterns ViewPatterns
ghc-options: -Wall -Wcompat -Widentities -Wincomplete-record-updates -Wincomplete-uni-patterns -Wredundant-constraints -Wpartial-fields -Werror -O2 ghc-options: -Wall -Wcompat -Widentities -Wincomplete-record-updates -Wincomplete-uni-patterns -Wredundant-constraints -Wpartial-fields -Werror -O2
build-depends: build-depends:
base >=4.12 && <10 Decimal >=0.5.2
, base >=4.12 && <10
, cassava , cassava
, conduit >=1.3.4.2 , conduit >=1.3.4.2
, containers >=0.6.4.1 , containers >=0.6.4.1
@ -144,7 +145,8 @@ executable pwncash
ViewPatterns ViewPatterns
ghc-options: -Wall -Wcompat -Widentities -Wincomplete-record-updates -Wincomplete-uni-patterns -Wredundant-constraints -Wpartial-fields -Werror -O2 -threaded ghc-options: -Wall -Wcompat -Widentities -Wincomplete-record-updates -Wincomplete-uni-patterns -Wredundant-constraints -Wpartial-fields -Werror -O2 -threaded
build-depends: build-depends:
base >=4.12 && <10 Decimal >=0.5.2
, base >=4.12 && <10
, budget , budget
, cassava , cassava
, conduit >=1.3.4.2 , conduit >=1.3.4.2

View File

@ -278,8 +278,9 @@ let DatePat =
-} -}
< Cron : CronPat.Type | Mod : ModPat.Type > < Cron : CronPat.Type | Mod : ModPat.Type >
let TxOpts = let TxOpts_ =
{- Additional metadata to use when parsing a statement -} {- Additional metadata to use when parsing a statement -}
\(re : Type) ->
{ Type = { Type =
{ toDate : { toDate :
{- {-
@ -312,7 +313,7 @@ let TxOpts =
{- Format of the amount field. Must include three fields for the {- Format of the amount field. Must include three fields for the
sign, numerator, and denominator of the amount. sign, numerator, and denominator of the amount.
-} -}
Text re
} }
, default = , default =
{ toDate = "Date" { toDate = "Date"
@ -324,6 +325,8 @@ let TxOpts =
} }
} }
let TxOpts = TxOpts_ Text
let Field = let Field =
{- {-
General key-value type General key-value type
@ -402,9 +405,45 @@ let EntryNumGetter =
LookupN: lookup the value from a field LookupN: lookup the value from a field
ConstN: a constant value ConstN: a constant value
AmountN: the value of the 'Amount' column AmountN: the value of the 'Amount' column times a scaling factor
BalanceN: the amount required to make the target account reach a balance
PercentN: the amount required to make an account reach a given percentage
-} -}
< LookupN : Text | ConstN : Double | AmountN : Double > < LookupN : Text
| ConstN : Double
| AmountN : Double
| BalanceN : Double
| PercentN : Double
>
let LinkedNumGetter =
{-
Means to get a numeric value from another entry
-}
{ Type =
{ lngIndex :
{-
Index of the entry to link.
-}
Natural
, lngScale :
{-
Factor by which to multiply the value of the linked entry.
-}
Double
}
, default = { lngScale = 1.0, lngIndex = 0 }
}
let LinkedEntryNumGetter =
{-
Means to get a numeric value from a statement row or another entry getter.
Linked: a number referring to the entry on the 'from' side of the
transaction (with 0 being the primary entry)
Getter: a normal getter
-}
< Linked : LinkedNumGetter.Type | Getter : EntryNumGetter >
let EntryTextGetter = let EntryTextGetter =
{- {-
@ -443,7 +482,6 @@ let Entry =
-} -}
\(a : Type) -> \(a : Type) ->
\(v : Type) -> \(v : Type) ->
\(c : Type) ->
\(t : Type) -> \(t : Type) ->
{ eAcnt : { eAcnt :
{- {-
@ -455,11 +493,6 @@ let Entry =
Pertains to value for this entry. Pertains to value for this entry.
-} -}
v v
, eCurrency :
{-
Pertains to value for this entry.
-}
c
, eComment : , eComment :
{- {-
A short description of this entry (if none, use a blank string) A short description of this entry (if none, use a blank string)
@ -474,35 +507,107 @@ let Entry =
let EntryGetter = let EntryGetter =
{- {-
Means for getting an entry from a given row in a statement Means for getting an entry from a given row in a statement (debit side)
-}
\(n : Type) ->
{ Type = Entry EntryAcntGetter n TagID
, default = { eComment = "", eTags = [] : List TagID }
}
let FromEntryGetter =
{-
Means for getting an entry from a given row in a statement (debit side)
-}
EntryGetter EntryNumGetter
let ToEntryGetter =
{-
Means for getting an entry from a given row in a statement (credit side)
-}
EntryGetter LinkedEntryNumGetter
let TxHalfGetter =
{-
Means of transforming one row in a statement to either the credit or debit
half of a transaction
-}
\(e : Type) ->
{ Type =
{ thgAcnt :
{-
Account from which this transaction will be balanced. The value
of the transaction will be assigned to this account unless
other entries are specified (see below).
This account (and its associated entry) will be denoted
'primary'.
-}
EntryAcntGetter
, thgEntries :
{-
Means of getting additional entries from which this transaction
will be balanced. If this list is empty, the total value of the
transaction will be assigned to the value defined by 'tsgAcnt'.
Otherwise, the entries specified here will be added to this side
of this transaction, and their sum value will be subtracted from
the total value of the transaction and assigned to 'tsgAcnt'.
This is useful for situations where a particular transaction
denotes values that come from multiple subaccounts.
-}
List e
, thgComment :
{-
Comment for the primary entry
-}
Text
, thgTags :
{-
Tags for the primary entry
-}
List TagID
}
, default =
{ thgTags = [] : List TagID
, thgComment = ""
, thgEntries = [] : List e
}
}
let FromTxHalfGetter = TxHalfGetter FromEntryGetter.Type
let ToTxHalfGetter = TxHalfGetter ToEntryGetter.Type
let TxSubGetter =
{-
A means for transforming one row in a statement to a transaction
-} -}
{ Type = { Type =
Entry EntryAcntGetter (Optional EntryNumGetter) EntryCurGetter TagID { tsgValue : EntryNumGetter
, default = { eValue = None EntryNumGetter, eComment = "" } , tsgCurrency : EntryCurGetter
, tsgFrom : (TxHalfGetter FromEntryGetter.Type).Type
, tsgTo : (TxHalfGetter ToEntryGetter.Type).Type
}
, default = { tsgFrom = TxHalfGetter, tsgTo = TxHalfGetter }
} }
let TxGetter = let TxGetter =
{- {-
A means for transforming one row in a statement to a transaction A means for transforming one row in a statement to a transaction
Note that N-1 entries need to be specified to make a transaction, as the
Nth entry will be balanced with the others.
-} -}
{ tgEntries : { Type =
{- { tgFrom : (TxHalfGetter FromEntryGetter.Type).Type
A means of getting entries for this transaction (minimum 1) , tgTo : (TxHalfGetter ToEntryGetter.Type).Type
-} , tgScale : Double
List EntryGetter.Type , tgCurrency : EntryCurGetter
, tgCurrency : , tgOtherEntries : List TxSubGetter.Type
{- }
Currency against which entries in this transaction will be balanced , default =
-} { tgOtherEntries = [] : List TxSubGetter.Type
EntryCurGetter , tgFrom = TxHalfGetter
, tgAcnt : , tgTo = TxHalfGetter
{- , tgScale = 1.0
Account in which entries in this transaction will be balanced }
-}
EntryAcntGetter
} }
let StatementParser_ = let StatementParser_ =
@ -542,7 +647,7 @@ let StatementParser_ =
a transaction. If none, don't make a transaction (eg 'skip' a transaction. If none, don't make a transaction (eg 'skip'
this row in the statement). this row in the statement).
-} -}
Optional TxGetter Optional TxGetter.Type
, spTimes : , spTimes :
{- {-
Match at most this many rows; if none there is no limit Match at most this many rows; if none there is no limit
@ -559,7 +664,7 @@ let StatementParser_ =
, spVal = ValMatcher::{=} , spVal = ValMatcher::{=}
, spDesc = None Text , spDesc = None Text
, spOther = [] : List (FieldMatcher_ re) , spOther = [] : List (FieldMatcher_ re)
, spTx = None TxGetter , spTx = None TxGetter.Type
, spTimes = None Natural , spTimes = None Natural
, spPriority = +0 , spPriority = +0
} }
@ -577,7 +682,29 @@ let Amount =
-} -}
\(w : Type) -> \(w : Type) ->
\(v : Type) -> \(v : Type) ->
{ amtWhen : w, amtValue : v, amtDesc : Text } { Type =
{ amtWhen : w, amtValue : v, amtDesc : Text, amtPriority : Integer }
, default.amtPriority = +0
}
let TransferType =
{-
The type of a budget transfer.
BTFixed: Tranfer a fixed amount
BTPercent: Transfer a percent of the source account to destination
BTTarget: Transfer an amount such that the destination has a given target
value
-}
< TPercent | TBalance | TFixed >
let TransferValue =
{-
Means to determine the value of a budget transfer.
-}
{ Type = { tvVal : Double, tvType : TransferType }
, default.tvType = TransferType.TFixed
}
let Transfer = let Transfer =
{- {-
@ -590,14 +717,24 @@ let Transfer =
{ transFrom : a { transFrom : a
, transTo : a , transTo : a
, transCurrency : c , transCurrency : c
, transAmounts : List (Amount w v) , transAmounts : List (Amount w v).Type
}
let TaggedAcnt =
{-
An account with a tag
-}
{ Type = { taAcnt : AcntID, taTags : List TagID }
, default.taTags = [] : List TagID
} }
let HistTransfer = let HistTransfer =
{- {-
A manually specified historical transfer A manually specified historical transfer
-} -}
Transfer AcntID CurID DatePat Double Transfer TaggedAcnt.Type CurID DatePat TransferValue.Type
let TransferAmount = Amount DatePat TransferValue.Type
let Statement = let Statement =
{- {-
@ -634,44 +771,6 @@ let History =
-} -}
< HistTransfer : HistTransfer | HistStatement : Statement > < HistTransfer : HistTransfer | HistStatement : Statement >
let Exchange =
{-
A currency exchange.
-}
{ xFromCur :
{-
Starting currency of the exchange.
-}
CurID
, xToCur :
{-
Ending currency of the exchange.
-}
CurID
, xAcnt :
{-
account in which the exchange will be documented.
-}
AcntID
, xRate :
{-
The exchange rate between the currencies.
-}
Double
}
let BudgetCurrency =
{-
A 'currency' in the budget; either a fixed currency or an exchange
-}
< NoX : CurID | X : Exchange >
let TaggedAcnt =
{-
An account with a tag
-}
{ taAcnt : AcntID, taTags : List TagID }
let Allocation = let Allocation =
{- {-
How to allocate a given budget stream. This can be thought of as a Transfer How to allocate a given budget stream. This can be thought of as a Transfer
@ -679,12 +778,7 @@ let Allocation =
-} -}
\(w : Type) -> \(w : Type) ->
\(v : Type) -> \(v : Type) ->
{ alloTo : TaggedAcnt { alloTo : TaggedAcnt.Type, alloAmts : List (Amount w v).Type }
, alloAmts : List (Amount w v)
, alloCur :
{-TODO allow exchanges here-}
CurID
}
let PretaxValue = let PretaxValue =
{- {-
@ -779,6 +873,8 @@ let SingleAllocation =
-} -}
Allocation {} Allocation {}
let SingleAlloAmount = \(v : Type) -> Amount {} v
let MultiAllocation = let MultiAllocation =
{- {-
An allocation specialized to capturing multiple income streams within a given An allocation specialized to capturing multiple income streams within a given
@ -787,6 +883,8 @@ let MultiAllocation =
-} -}
Allocation Interval Allocation Interval
let MultiAlloAmount = \(v : Type) -> Amount Interval v
let HourlyPeriod = let HourlyPeriod =
{- {-
Definition for a pay period denominated in hours Definition for a pay period denominated in hours
@ -869,18 +967,20 @@ let Income =
This must be an income AcntID, and is the only place income This must be an income AcntID, and is the only place income
accounts may be specified in the entire budget. accounts may be specified in the entire budget.
-} -}
TaggedAcnt TaggedAcnt.Type
, incToBal : , incToBal :
{- {-
The account to which to send the remainder of the income stream The account to which to send the remainder of the income stream
(if any) after all allocations have been applied. (if any) after all allocations have been applied.
-} -}
TaggedAcnt TaggedAcnt.Type
, incPriority : Integer
} }
, default = , default =
{ incPretax = [] : List (SingleAllocation PretaxValue) { incPretax = [] : List (SingleAllocation PretaxValue)
, incTaxes = [] : List (SingleAllocation TaxValue) , incTaxes = [] : List (SingleAllocation TaxValue)
, incPosttaxx = [] : List (SingleAllocation PosttaxValue) , incPosttaxx = [] : List (SingleAllocation PosttaxValue)
, incPriority = +0
} }
} }
@ -937,17 +1037,6 @@ let TransferMatcher =
} }
} }
let BudgetTransferType =
{-
The type of a budget transfer.
BTFixed: Tranfer a fixed amount
BTPercent: Transfer a percent of the source account to destination
BTTarget: Transfer an amount such that the destination has a given target
value
-}
< BTPercent | BTTarget | BTFixed >
let ShadowTransfer = let ShadowTransfer =
{- {-
A transaction analogous to another transfer with given properties. A transaction analogous to another transfer with given properties.
@ -956,17 +1045,17 @@ let ShadowTransfer =
{- {-
Source of this transfer Source of this transfer
-} -}
TaggedAcnt TaggedAcnt.Type
, stTo : , stTo :
{- {-
Destination of this transfer. Destination of this transfer.
-} -}
TaggedAcnt TaggedAcnt.Type
, stCurrency : , stCurrency :
{- {-
Currency of this transfer. Currency of this transfer.
-} -}
BudgetCurrency CurID
, stDesc : , stDesc :
{- {-
Description of this transfer. Description of this transfer.
@ -980,7 +1069,7 @@ let ShadowTransfer =
specified in other fields of this type. specified in other fields of this type.
-} -}
TransferMatcher.Type TransferMatcher.Type
, stType : BudgetTransferType , stType : TransferType
, stRatio : , stRatio :
{- {-
Fixed multipler to translate value of matched transfer to this one. Fixed multipler to translate value of matched transfer to this one.
@ -988,17 +1077,11 @@ let ShadowTransfer =
Double Double
} }
let BudgetTransferValue =
{-
Means to determine the value of a budget transfer.
-}
{ btVal : Double, btType : BudgetTransferType }
let BudgetTransfer = let BudgetTransfer =
{- {-
A manually specified transaction for a budget A manually specified transaction for a budget
-} -}
Transfer TaggedAcnt BudgetCurrency DatePat BudgetTransferValue HistTransfer
let Budget = let Budget =
{- {-
@ -1040,6 +1123,7 @@ in { CurID
, CronPat , CronPat
, DatePat , DatePat
, TxOpts , TxOpts
, TxOpts_
, StatementParser , StatementParser
, StatementParser_ , StatementParser_
, ValMatcher , ValMatcher
@ -1048,10 +1132,13 @@ in { CurID
, FieldMatcher , FieldMatcher
, FieldMatcher_ , FieldMatcher_
, EntryNumGetter , EntryNumGetter
, LinkedEntryNumGetter
, LinkedNumGetter
, Field , Field
, FieldMap , FieldMap
, Entry , Entry
, EntryGetter , FromEntryGetter
, ToEntryGetter
, EntryTextGetter , EntryTextGetter
, EntryCurGetter , EntryCurGetter
, EntryAcntGetter , EntryAcntGetter
@ -1065,9 +1152,8 @@ in { CurID
, TransferMatcher , TransferMatcher
, ShadowTransfer , ShadowTransfer
, AcntSet , AcntSet
, BudgetCurrency
, Exchange
, TaggedAcnt , TaggedAcnt
, AccountTree
, Account , Account
, Placeholder , Placeholder
, PretaxValue , PretaxValue
@ -1076,13 +1162,20 @@ in { CurID
, TaxProgression , TaxProgression
, TaxMethod , TaxMethod
, TaxValue , TaxValue
, BudgetTransferValue , TransferValue
, BudgetTransferType , TransferType
, TxGetter , TxGetter
, TxSubGetter
, TxHalfGetter
, FromTxHalfGetter
, ToTxHalfGetter
, HistTransfer , HistTransfer
, SingleAllocation , SingleAllocation
, MultiAllocation , MultiAllocation
, HourlyPeriod , HourlyPeriod
, Period , Period
, PeriodType , PeriodType
, TransferAmount
, MultiAlloAmount
, SingleAlloAmount
} }

View File

@ -4,18 +4,10 @@ let List/map =
let T = ./Types.dhall let T = ./Types.dhall
let nullSplit = let nullEntry =
\(a : T.EntryAcntGetter) -> \(a : T.EntryAcntGetter) ->
\(c : T.EntryCurGetter) -> \(v : T.EntryNumGetter) ->
T.EntryGetter::{ eAcnt = a, eCurrency = c, eTags = [] : List T.TagID } T.FromEntryGetter::{ eAcnt = a, eValue = v }
let nullOpts = T.TxOpts::{=}
let nullVal = T.ValMatcher::{=}
let nullMatch = T.StatementParser::{=}
let nullCron = T.CronPat::{=}
let nullMod = let nullMod =
\(by : Natural) -> \(by : Natural) ->
@ -27,21 +19,22 @@ let cron1 =
\(m : Natural) -> \(m : Natural) ->
\(d : Natural) -> \(d : Natural) ->
T.DatePat.Cron T.DatePat.Cron
( nullCron T.CronPat::{
// { cpYear = Some (T.MDYPat.Single y) , cpYear = Some (T.MDYPat.Single y)
, cpMonth = Some (T.MDYPat.Single m) , cpMonth = Some (T.MDYPat.Single m)
, cpDay = Some (T.MDYPat.Single d) , cpDay = Some (T.MDYPat.Single d)
} }
)
let matchInf_ = nullMatch let matchInf_ = T.StatementParser::{=}
let matchInf = \(x : T.TxGetter) -> nullMatch // { spTx = Some x } let matchInf = \(x : T.TxGetter.Type) -> T.StatementParser::{ spTx = Some x }
let matchN_ = \(n : Natural) -> nullMatch // { spTimes = Some n } let matchN_ = \(n : Natural) -> T.StatementParser::{ spTimes = Some n }
let matchN = let matchN =
\(n : Natural) -> \(x : T.TxGetter) -> matchInf x // { spTimes = Some n } \(n : Natural) ->
\(x : T.TxGetter.Type) ->
matchInf x // { spTimes = Some n }
let match1_ = matchN_ 1 let match1_ = matchN_ 1
@ -86,46 +79,45 @@ let mRngYMD =
\(r : Natural) -> \(r : Natural) ->
T.DateMatcher.In { _1 = T.YMDMatcher.YMD (greg y m d), _2 = r } T.DateMatcher.In { _1 = T.YMDMatcher.YMD (greg y m d), _2 = r }
let PartSplit = { _1 : T.AcntID, _2 : Double, _3 : Text } let PartEntry = { _1 : T.AcntID, _2 : Double, _3 : Text }
let partN = let partNFrom =
\(c : T.EntryCurGetter) -> \(ss : List PartEntry) ->
\(a : T.EntryAcntGetter) -> let toEntry =
\(comment : Text) -> \(x : PartEntry) ->
\(ss : List PartSplit) -> T.FromEntryGetter::{
let toSplit = , eAcnt = T.EntryAcntGetter.ConstT x._1
\(x : PartSplit) -> , eValue = T.EntryNumGetter.ConstN x._2
nullSplit (T.EntryAcntGetter.ConstT x._1) c
// { eValue = Some (T.EntryNumGetter.ConstN x._2)
, eComment = x._3 , eComment = x._3
} }
in [ nullSplit a c // { eComment = comment } ] in List/map PartEntry T.FromEntryGetter.Type toEntry ss
# List/map PartSplit T.EntryGetter.Type toSplit ss
let part1 = let partNTo =
\(c : T.EntryCurGetter) -> \(ss : List PartEntry) ->
\(a : T.EntryAcntGetter) -> let toEntry =
\(comment : Text) -> \(x : PartEntry) ->
partN c a comment ([] : List PartSplit) T.ToEntryGetter::{
, eAcnt = T.EntryAcntGetter.ConstT x._1
, eValue =
T.LinkedEntryNumGetter.Getter (T.EntryNumGetter.ConstN x._2)
, eComment = x._3
}
let part1_ = in List/map PartEntry T.ToEntryGetter.Type toEntry ss
\(c : T.EntryCurGetter) ->
\(a : T.EntryAcntGetter) ->
partN c a "" ([] : List PartSplit)
let addDay = let addDay =
\(x : T.GregorianM) -> \(x : T.GregorianM) ->
\(d : Natural) -> \(d : Natural) ->
{ gYear = x.gmYear, gMonth = x.gmMonth, gDay = d } { gYear = x.gmYear, gMonth = x.gmMonth, gDay = d }
let mvP = nullVal // { vmSign = Some True } let mvP = T.ValMatcher::{ vmSign = Some True }
let mvN = nullVal // { vmSign = Some False } let mvN = T.ValMatcher::{ vmSign = Some False }
let mvNum = \(x : Natural) -> nullVal // { vmNum = Some x } let mvNum = \(x : Natural) -> T.ValMatcher::{ vmNum = Some x }
let mvDen = \(x : Natural) -> nullVal // { vmDen = Some x } let mvDen = \(x : Natural) -> T.ValMatcher::{ vmDen = Some x }
let mvNumP = \(x : Natural) -> mvP // { vmNum = Some x } let mvNumP = \(x : Natural) -> mvP // { vmNum = Some x }
@ -135,13 +127,7 @@ let mvDenP = \(x : Natural) -> mvP // { vmDen = Some x }
let mvDenN = \(x : Natural) -> mvN // { vmDen = Some x } let mvDenN = \(x : Natural) -> mvN // { vmDen = Some x }
in { nullSplit in { cron1
, nullMatch
, nullVal
, nullOpts
, nullCron
, nullMod
, cron1
, mY , mY
, mYM , mYM
, mYMD , mYMD
@ -156,9 +142,8 @@ in { nullSplit
, match1 , match1
, greg , greg
, gregM , gregM
, partN , partNFrom
, part1 , partNTo
, part1_
, addDay , addDay
, comma = 44 , comma = 44
, tab = 9 , tab = 9
@ -170,6 +155,8 @@ in { nullSplit
, mvDen , mvDen
, mvDenP , mvDenP
, mvDenN , mvDenN
, PartSplit , PartEntry
, nullEntry
, nullMod
} }
/\ T /\ T

View File

@ -1,9 +1,9 @@
module Internal.Budget (insertBudget) where module Internal.Budget (readBudget) where
import Control.Monad.Except import Control.Monad.Except
import Data.Decimal hiding (allocate)
import Data.Foldable import Data.Foldable
import Database.Persist.Monad import Data.Hashable
import Internal.Database
import Internal.Types.Main import Internal.Types.Main
import Internal.Utils import Internal.Utils
import RIO hiding (to) import RIO hiding (to)
@ -13,22 +13,8 @@ import qualified RIO.NonEmpty as NE
import qualified RIO.Text as T import qualified RIO.Text as T
import RIO.Time import RIO.Time
-- each budget (designated at the top level by a 'name') is processed in the readBudget :: (MonadAppError m, MonadFinance m) => Budget -> m [Tx CommitR]
-- following steps readBudget
-- 1. expand all transactions given the desired date range and date patterns for
-- each directive in the budget
-- 2. sort all transactions by date
-- 3. propagate all balances forward, and while doing so assign values to each
-- transaction (some of which depend on the 'current' balance of the
-- target account)
-- 4. assign shadow transactions
-- 5. insert all transactions
insertBudget
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
=> Budget
-> m ()
insertBudget
b@Budget b@Budget
{ bgtLabel { bgtLabel
, bgtIncomes , bgtIncomes
@ -39,15 +25,19 @@ insertBudget
, bgtPosttax , bgtPosttax
, bgtInterval , bgtInterval
} = } =
whenHash CTBudget b () $ \key -> do do
spanRes <- getSpan
case spanRes of
Nothing -> return []
Just budgetSpan -> do
(intAllos, _) <- combineError intAlloRes acntRes (,) (intAllos, _) <- combineError intAlloRes acntRes (,)
let res1 = mapErrors (insertIncome key bgtLabel intAllos bgtInterval) bgtIncomes let res1 = mapErrors (readIncome c bgtLabel intAllos budgetSpan) bgtIncomes
let res2 = expandTransfers key bgtLabel bgtInterval bgtTransfers let res2 = expandTransfers c bgtLabel budgetSpan bgtTransfers
txs <- combineError (concat <$> res1) res2 (++) txs <- combineError (concat <$> res1) res2 (++)
m <- askDBState kmCurrency shadow <- addShadowTransfers bgtShadowTransfers txs
shadow <- liftExcept $ addShadowTransfers m bgtShadowTransfers txs return $ txs ++ shadow
void $ mapErrors insertBudgetTx $ balanceTransfers $ txs ++ shadow
where where
c = CommitR (CommitHash $ hash b) CTBudget
acntRes = mapErrors isNotIncomeAcnt alloAcnts acntRes = mapErrors isNotIncomeAcnt alloAcnts
intAlloRes = combineError3 pre_ tax_ post_ (,,) intAlloRes = combineError3 pre_ tax_ post_ (,,)
pre_ = sortAllos bgtPretax pre_ = sortAllos bgtPretax
@ -58,73 +48,15 @@ insertBudget
(alloAcnt <$> bgtPretax) (alloAcnt <$> bgtPretax)
++ (alloAcnt <$> bgtTax) ++ (alloAcnt <$> bgtTax)
++ (alloAcnt <$> bgtPosttax) ++ (alloAcnt <$> bgtPosttax)
getSpan = do
globalSpan <- asks (unBSpan . csBudgetScope)
case bgtInterval of
Nothing -> return $ Just globalSpan
Just bi -> do
localSpan <- liftExcept $ resolveDaySpan bi
return $ intersectDaySpan globalSpan localSpan
balanceTransfers :: [UnbalancedTransfer] -> [BalancedTransfer] sortAllo :: MultiAllocation v -> AppExcept (DaySpanAllocation v)
balanceTransfers = snd . L.mapAccumR go M.empty . reverse . L.sortOn ftWhen
where
go bals f@FlatTransfer {ftFrom, ftTo, ftValue = UnbalancedValue {cvValue, cvType}} =
let balTo = M.findWithDefault 0 ftTo bals
x = amtToMove balTo cvType cvValue
bals' = mapAdd_ ftTo x $ mapAdd_ ftFrom (-x) bals
in (bals', f {ftValue = x})
-- TODO might need to query signs to make this intuitive; as it is this will
-- probably work, but for credit accounts I might need to supply a negative
-- target value
amtToMove _ BTFixed x = x
amtToMove bal BTPercent x = -(x / 100 * bal)
amtToMove bal BTTarget x = x - bal
-- TODO this seems too general for this module
mapAdd_ :: (Ord k, Num v) => k -> v -> M.Map k v -> M.Map k v
mapAdd_ k v = M.alter (maybe (Just v) (Just . (+ v))) k
insertBudgetTx
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m)
=> BalancedTransfer
-> m ()
insertBudgetTx FlatTransfer {ftFrom, ftTo, ftMeta, ftCur, ftValue, ftDesc, ftWhen} = do
((sFrom, sTo), exchange) <- entryPair 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 entry = do
sk <- insertEntry k entry
insert_ $ BudgetLabelR sk $ bmName ftMeta
entryPair
:: (MonadInsertError m, MonadFinance m)
=> TaggedAcnt
-> TaggedAcnt
-> BudgetCurrency
-> Rational
-> m (EntryPair, Maybe EntryPair)
entryPair 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 = entry curid from_ (-v)
let s2 = entry curid to_ v
combineError s1 s2 (,)
entry c TaggedAcnt {taAcnt, taTags} v =
resolveEntry $
Entry
{ eAcnt = taAcnt
, eValue = v
, eComment = ""
, eCurrency = c
, eTags = taTags
}
sortAllo :: MultiAllocation v -> InsertExcept (DaySpanAllocation v)
sortAllo a@Allocation {alloAmts = as} = do sortAllo a@Allocation {alloAmts = as} = do
bs <- foldSpan [] $ L.sortOn amtWhen as bs <- foldSpan [] $ L.sortOn amtWhen as
return $ a {alloAmts = reverse bs} return $ a {alloAmts = reverse bs}
@ -143,100 +75,107 @@ sortAllo a@Allocation {alloAmts = as} = do
-- TODO this will scan the interval allocations fully each time -- TODO this will scan the interval allocations fully each time
-- iteration which is a total waste, but the fix requires turning this -- iteration which is a total waste, but the fix requires turning this
-- loop into a fold which I don't feel like doing now :( -- loop into a fold which I don't feel like doing now :(
insertIncome readIncome
:: (MonadInsertError m, MonadFinance m) :: (MonadAppError m, MonadFinance m)
=> CommitRId => CommitR
-> T.Text -> BudgetName
-> IntAllocations -> IntAllocations
-> Maybe Interval -> DaySpan
-> Income -> Income
-> m [UnbalancedTransfer] -> m [Tx CommitR]
insertIncome readIncome
key key
name name
(intPre, intTax, intPost) (intPre, intTax, intPost)
localInterval ds
Income Income
{ incWhen { incWhen
, incCurrency , incCurrency
, incFrom , incFrom = TaggedAcnt {taAcnt = srcAcnt, taTags = srcTags}
, incPretax , incPretax
, incPosttax , incPosttax
, incTaxes , incTaxes
, incToBal , incToBal = TaggedAcnt {taAcnt = destAcnt, taTags = destTags}
, incGross , incGross
, incPayPeriod , incPayPeriod
, incPriority
} = } =
combineErrorM combineErrorM
(combineError incRes nonIncRes (,)) (combineError incRes nonIncRes (,))
(combineError precRes dayRes (,)) (combineError cpRes dayRes (,))
$ \_ (precision, days) -> do $ \_ (cp, days) -> do
let gross = roundPrecision precision incGross let gross = realFracToDecimalP (cpPrec cp) incGross
concat <$> foldDays (allocate precision gross) start days foldDays (allocate cp gross) start days
where where
incRes = isIncomeAcnt $ taAcnt incFrom srcAcnt' = AcntID srcAcnt
destAcnt' = AcntID destAcnt
incRes = isIncomeAcnt srcAcnt'
nonIncRes = nonIncRes =
mapErrors isNotIncomeAcnt $ mapErrors isNotIncomeAcnt $
taAcnt incToBal destAcnt'
: (alloAcnt <$> incPretax) : (alloAcnt <$> incPretax)
++ (alloAcnt <$> incTaxes) ++ (alloAcnt <$> incTaxes)
++ (alloAcnt <$> incPosttax) ++ (alloAcnt <$> incPosttax)
precRes = lookupCurrencyPrec incCurrency cpRes = lookupCurrency incCurrency
dayRes = askDays incWhen localInterval dayRes = liftExcept $ expandDatePat ds incWhen
start = fromGregorian' $ pStart incPayPeriod start = fromGregorian' $ pStart incPayPeriod
pType' = pType incPayPeriod pType' = pType incPayPeriod
meta = BudgetMeta key name
flatPre = concatMap flattenAllo incPretax flatPre = concatMap flattenAllo incPretax
flatTax = concatMap flattenAllo incTaxes flatTax = concatMap flattenAllo incTaxes
flatPost = concatMap flattenAllo incPosttax flatPost = concatMap flattenAllo incPosttax
sumAllos = sum . fmap faValue sumAllos = sum . fmap faValue
-- TODO ensure these are all the "correct" accounts entry0 a c ts = Entry {eAcnt = a, eValue = (), eComment = c, eTags = ts}
allocate precision gross prevDay day = do allocate cp gross prevDay day = do
scaler <- liftExcept $ periodScaler pType' prevDay day scaler <- liftExcept $ periodScaler pType' prevDay day
let precision = cpPrec cp
let (preDeductions, pre) = let (preDeductions, pre) =
allocatePre precision gross $ allocatePre precision gross $
flatPre ++ concatMap (selectAllos day) intPre flatPre ++ concatMap (selectAllos day) intPre
tax = let tax =
allocateTax precision gross preDeductions scaler $ allocateTax precision gross preDeductions scaler $
flatTax ++ concatMap (selectAllos day) intTax flatTax ++ concatMap (selectAllos day) intTax
aftertaxGross = gross - sumAllos (tax ++ pre) aftertaxGross = gross - sumAllos (tax ++ pre)
post = let post =
allocatePost precision aftertaxGross $ allocatePost precision aftertaxGross $
flatPost ++ concatMap (selectAllos day) intPost flatPost ++ concatMap (selectAllos day) intPost
balance = aftertaxGross - sumAllos post let src = entry0 srcAcnt' "gross income" (TagID <$> srcTags)
bal = let dest = entry0 destAcnt' "balance after deductions" (TagID <$> destTags)
FlatTransfer let allos = allo2Trans <$> (pre ++ tax ++ post)
{ ftMeta = meta let primary =
, ftWhen = day EntrySet
, ftFrom = incFrom { esTotalValue = gross
, ftCur = NoX incCurrency , esCurrency = cpID cp
, ftTo = incToBal , esFrom = HalfEntrySet {hesPrimary = src, hesOther = []}
, ftValue = UnbalancedValue BTFixed balance , esTo = HalfEntrySet {hesPrimary = dest, hesOther = allos}
, ftDesc = "balance after deductions" }
return $
Tx
{ txCommit = key
, txDate = day
, txPrimary = Left primary
, txOther = []
, txDescr = TxDesc ""
, txBudget = name
, txPriority = incPriority
} }
in if balance < 0
then throwError $ InsertException [IncomeError day name balance]
else return (bal : fmap (allo2Trans meta day incFrom) (pre ++ tax ++ post))
periodScaler periodScaler
:: PeriodType :: PeriodType
-> Day -> Day
-> Day -> Day
-> InsertExcept PeriodScaler -> AppExcept PeriodScaler
periodScaler pt prev cur = return scale periodScaler pt prev cur = return scale
where where
n = fromIntegral $ workingDays wds prev cur n = workingDays wds prev cur
wds = case pt of wds = case pt of
Hourly HourlyPeriod {hpWorkingDays} -> hpWorkingDays Hourly HourlyPeriod {hpWorkingDays} -> hpWorkingDays
Daily ds -> ds Daily ds -> ds
scale precision x = case pt of scale prec x = case pt of
Hourly HourlyPeriod {hpAnnualHours, hpDailyHours} -> Hourly HourlyPeriod {hpAnnualHours, hpDailyHours} ->
fromRational (rnd $ x / fromIntegral hpAnnualHours) realFracToDecimalP prec (x / fromIntegral hpAnnualHours)
* fromIntegral hpDailyHours * fromIntegral hpDailyHours
* n * fromIntegral n
Daily _ -> x * n / 365.25 Daily _ -> realFracToDecimalP prec (x * fromIntegral n / 365.25)
where
rnd = roundPrecision precision
-- ASSUME start < end -- ASSUME start < end
workingDays :: [Weekday] -> Day -> Day -> Natural workingDays :: [Weekday] -> Day -> Day -> Natural
@ -252,7 +191,7 @@ workingDays wds start end = fromIntegral $ daysFull + daysTail
-- ASSUME days is a sorted list -- ASSUME days is a sorted list
foldDays foldDays
:: MonadInsertError m :: MonadAppError m
=> (Day -> Day -> m a) => (Day -> Day -> m a)
-> Day -> Day
-> [Day] -> [Day]
@ -262,27 +201,27 @@ foldDays f start days = case NE.nonEmpty days of
Just ds Just ds
| any (start >) ds -> | any (start >) ds ->
throwError $ throwError $
InsertException [PeriodError start $ minimum ds] AppException [PeriodError start $ minimum ds]
| otherwise -> | otherwise ->
combineErrors $ combineErrors $
snd $ snd $
L.mapAccumL (\prevDay day -> (day, f prevDay day)) start days L.mapAccumL (\prevDay day -> (day, f prevDay day)) start days
isIncomeAcnt :: (MonadInsertError m, MonadFinance m) => AcntID -> m () isIncomeAcnt :: (MonadAppError m, MonadFinance m) => AcntID -> m ()
isIncomeAcnt = checkAcntType IncomeT isIncomeAcnt = checkAcntType IncomeT
isNotIncomeAcnt :: (MonadInsertError m, MonadFinance m) => AcntID -> m () isNotIncomeAcnt :: (MonadAppError m, MonadFinance m) => AcntID -> m ()
isNotIncomeAcnt = checkAcntTypes (AssetT :| [EquityT, ExpenseT, LiabilityT]) isNotIncomeAcnt = checkAcntTypes (AssetT :| [EquityT, ExpenseT, LiabilityT])
checkAcntType checkAcntType
:: (MonadInsertError m, MonadFinance m) :: (MonadAppError m, MonadFinance m)
=> AcntType => AcntType
-> AcntID -> AcntID
-> m () -> m ()
checkAcntType t = checkAcntTypes (t :| []) checkAcntType t = checkAcntTypes (t :| [])
checkAcntTypes checkAcntTypes
:: (MonadInsertError m, MonadFinance m) :: (MonadAppError m, MonadFinance m)
=> NE.NonEmpty AcntType => NE.NonEmpty AcntType
-> AcntID -> AcntID
-> m () -> m ()
@ -290,83 +229,70 @@ checkAcntTypes ts i = void $ go =<< lookupAccountType i
where where
go t go t
| t `L.elem` ts = return i | t `L.elem` ts = return i
| otherwise = throwError $ InsertException [AccountError i ts] | otherwise = throwError $ AppException [AccountTypeError i ts]
flattenAllo :: SingleAllocation v -> [FlatAllocation v] flattenAllo :: SingleAllocation v -> [FlatAllocation v]
flattenAllo Allocation {alloAmts, alloCur, alloTo} = fmap go alloAmts flattenAllo Allocation {alloAmts, alloTo} = fmap go alloAmts
where where
go Amount {amtValue, amtDesc} = go Amount {amtValue, amtDesc} =
FlatAllocation FlatAllocation
{ faCur = NoX alloCur { faTo = alloTo
, faTo = alloTo
, faValue = amtValue , faValue = amtValue
, faDesc = amtDesc , faDesc = amtDesc
} }
-- ASSUME allocations are sorted -- ASSUME allocations are sorted
selectAllos :: Day -> DaySpanAllocation v -> [FlatAllocation v] selectAllos :: Day -> DaySpanAllocation v -> [FlatAllocation v]
selectAllos day Allocation {alloAmts, alloCur, alloTo} = selectAllos day Allocation {alloAmts, alloTo} =
go <$> filter ((`inDaySpan` day) . amtWhen) alloAmts go <$> filter ((`inDaySpan` day) . amtWhen) alloAmts
where where
go Amount {amtValue, amtDesc} = go Amount {amtValue, amtDesc} =
FlatAllocation FlatAllocation
{ faCur = NoX alloCur { faTo = alloTo
, faTo = alloTo
, faValue = amtValue , faValue = amtValue
, faDesc = amtDesc , faDesc = amtDesc
} }
allo2Trans allo2Trans :: FlatAllocation Decimal -> Entry AcntID EntryLink TagID
:: BudgetMeta allo2Trans FlatAllocation {faValue, faTo = TaggedAcnt {taAcnt, taTags}, faDesc} =
-> Day Entry
-> TaggedAcnt { eValue = LinkValue (EntryFixed faValue)
-> FlatAllocation Rational , eComment = faDesc
-> UnbalancedTransfer , eAcnt = AcntID taAcnt
allo2Trans meta day from FlatAllocation {faValue, faTo, faDesc, faCur} = , eTags = TagID <$> taTags
FlatTransfer
{ ftMeta = meta
, ftWhen = day
, ftFrom = from
, ftCur = faCur
, ftTo = faTo
, ftValue = UnbalancedValue BTFixed faValue
, ftDesc = faDesc
} }
type PreDeductions = M.Map T.Text Decimal
allocatePre allocatePre
:: Natural :: Precision
-> Rational -> Decimal
-> [FlatAllocation PretaxValue] -> [FlatAllocation PretaxValue]
-> (M.Map T.Text Rational, [FlatAllocation Rational]) -> (PreDeductions, [FlatAllocation Decimal])
allocatePre precision gross = L.mapAccumR go M.empty allocatePre precision gross = L.mapAccumR go M.empty
where where
go m f@FlatAllocation {faValue} = go m f@FlatAllocation {faValue = PretaxValue {preCategory, preValue, prePercent}} =
let c = preCategory faValue let v =
p = preValue faValue if prePercent
v = then gross *. (preValue / 100)
if prePercent faValue else realFracToDecimalP precision preValue
then (roundPrecision 3 p / 100) * gross in (mapAdd_ preCategory v m, f {faValue = v})
else roundPrecision precision p
in (mapAdd_ c v m, f {faValue = v})
allocateTax allocateTax
:: Natural :: Precision
-> Rational -> Decimal
-> M.Map T.Text Rational -> PreDeductions
-> PeriodScaler -> PeriodScaler
-> [FlatAllocation TaxValue] -> [FlatAllocation TaxValue]
-> [FlatAllocation Rational] -> [FlatAllocation Decimal]
allocateTax precision gross preDeds f = fmap (fmap go) allocateTax precision gross preDeds f = fmap (fmap go)
where where
go TaxValue {tvCategories, tvMethod} = go TaxValue {tvCategories, tvMethod} =
let agi = gross - sum (mapMaybe (`M.lookup` preDeds) tvCategories) let agi = gross - sum (mapMaybe (`M.lookup` preDeds) tvCategories)
in case tvMethod of in case tvMethod of
TMPercent p -> TMPercent p -> agi *. p / 100
roundPrecision precision $
fromRational $
roundPrecision 3 p / 100 * agi
TMBracket TaxProgression {tpDeductible, tpBrackets} -> TMBracket TaxProgression {tpDeductible, tpBrackets} ->
let taxDed = roundPrecision precision $ f precision tpDeductible let taxDed = f precision tpDeductible
in foldBracket f precision (agi - taxDed) tpBrackets in foldBracket f precision (agi - taxDed) tpBrackets
-- | Compute effective tax percentage of a bracket -- | Compute effective tax percentage of a bracket
@ -380,174 +306,80 @@ allocateTax precision gross preDeds f = fmap (fmap go)
-- --
-- In reality, this can all be done with one loop, but it isn't clear these -- In reality, this can all be done with one loop, but it isn't clear these
-- three steps are implemented from this alone. -- three steps are implemented from this alone.
foldBracket :: PeriodScaler -> Natural -> Rational -> [TaxBracket] -> Rational foldBracket :: PeriodScaler -> Precision -> Decimal -> [TaxBracket] -> Decimal
foldBracket f precision agi bs = fst $ foldr go (0, agi) $ L.sortOn tbLowerLimit bs foldBracket f prec agi bs = fst $ foldr go (0, agi) $ L.sortOn tbLowerLimit bs
where where
go TaxBracket {tbLowerLimit, tbPercent} a@(acc, remain) = go TaxBracket {tbLowerLimit, tbPercent} a@(acc, remain) =
let l = roundPrecision precision $ f precision tbLowerLimit let l = f prec tbLowerLimit
p = roundPrecision 3 tbPercent / 100 in if remain >= l
in if remain >= l then (acc + p * (remain - l), l) else a then (acc + (remain - l) *. (tbPercent / 100), l)
else a
allocatePost allocatePost
:: Natural :: Precision
-> Rational -> Decimal
-> [FlatAllocation PosttaxValue] -> [FlatAllocation PosttaxValue]
-> [FlatAllocation Rational] -> [FlatAllocation Decimal]
allocatePost precision aftertax = fmap (fmap go) allocatePost prec aftertax = fmap (fmap go)
where where
go PosttaxValue {postValue, postPercent} = go PosttaxValue {postValue, postPercent}
let v = postValue | postPercent = aftertax *. (postValue / 100)
in if postPercent | otherwise = realFracToDecimalP prec postValue
then aftertax * roundPrecision 3 v / 100
else roundPrecision precision v
--------------------------------------------------------------------------------
-- Standalone Transfer
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 $ resolveDaySpan i
return $ filter (inDaySpan bounds . ftWhen) txs
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
}
withDates
:: (MonadSqlQuery m, MonadFinance m, MonadInsertError m)
=> DatePat
-> (Day -> m a)
-> m [a]
withDates dp f = do
bounds <- askDBState kmBudgetInterval
days <- liftExcept $ expandDatePat bounds dp
combineErrors $ fmap f days
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------
-- shadow transfers -- shadow transfers
-- TODO this is going to be O(n*m), which might be a problem? -- TODO this is going to be O(n*m), which might be a problem?
addShadowTransfers addShadowTransfers
:: CurrencyMap :: (MonadAppError m, MonadFinance m)
-> [ShadowTransfer] => [ShadowTransfer]
-> [UnbalancedTransfer] -> [Tx CommitR]
-> InsertExcept [UnbalancedTransfer] -> m [Tx CommitR]
addShadowTransfers cm ms txs = addShadowTransfers ms = mapErrors go
fmap catMaybes $ where
combineErrors $ go tx = do
fmap (uncurry (fromShadow cm)) $ es <- catMaybes <$> mapErrors (fromShadow tx) ms
[(t, m) | t <- txs, m <- ms] return $ tx {txOther = Right <$> es}
fromShadow fromShadow
:: CurrencyMap :: (MonadAppError m, MonadFinance m)
-> UnbalancedTransfer => Tx CommitR
-> ShadowTransfer -> ShadowTransfer
-> InsertExcept (Maybe UnbalancedTransfer) -> m (Maybe ShadowEntrySet)
fromShadow cm tx t@ShadowTransfer {stFrom, stTo, stDesc, stRatio, stCurrency, stType} = do fromShadow tx ShadowTransfer {stFrom, stTo, stDesc, stRatio, stCurrency, stMatch} =
res <- shadowMatches (stMatch t) tx combineErrorM curRes shaRes $ \cur sha -> do
v <- roundPrecisionCur (initialCurrency stCurrency) cm stRatio let es = entryPair stFrom stTo cur stDesc stRatio ()
return $ return $ if not sha then Nothing else Just es
if not res where
then Nothing curRes = lookupCurrencyKey (CurID stCurrency)
else shaRes = liftExcept $ shadowMatches stMatch tx
Just $
FlatTransfer
{ ftMeta = ftMeta tx
, ftWhen = ftWhen tx
, ftCur = stCurrency
, ftFrom = stFrom
, ftTo = stTo
, ftValue = UnbalancedValue stType $ v * cvValue (ftValue tx)
, ftDesc = stDesc
}
shadowMatches :: TransferMatcher -> UnbalancedTransfer -> InsertExcept Bool shadowMatches :: TransferMatcher -> Tx CommitR -> AppExcept Bool
shadowMatches TransferMatcher {tmFrom, tmTo, tmDate, tmVal} tx = do shadowMatches TransferMatcher {tmFrom, tmTo, tmDate, tmVal} Tx {txPrimary, txDate} = do
valRes <- valMatches tmVal $ cvValue $ ftValue tx -- NOTE this will only match against the primary entry set since those
-- are what are guaranteed to exist from a transfer
valRes <- case txPrimary of
Left es -> valMatches tmVal $ toRational $ esTotalValue es
Right _ -> return True
return $ return $
memberMaybe (taAcnt $ ftFrom tx) tmFrom memberMaybe fa tmFrom
&& memberMaybe (taAcnt $ ftTo tx) tmTo && memberMaybe ta tmTo
&& maybe True (`dateMatches` ftWhen tx) tmDate && maybe True (`dateMatches` txDate) tmDate
&& valRes && valRes
where where
fa = either getAcntFrom getAcntFrom txPrimary
ta = either getAcntTo getAcntTo txPrimary
getAcntFrom = getAcnt esFrom
getAcntTo = getAcnt esTo
getAcnt f = eAcnt . hesPrimary . f
memberMaybe x AcntSet {asList, asInclude} = memberMaybe x AcntSet {asList, asInclude} =
(if asInclude then id else not) $ x `elem` asList (if asInclude then id else not) $ x `elem` (AcntID <$> asList)
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------
-- random -- random
initialCurrency :: BudgetCurrency -> CurID
initialCurrency (NoX c) = c
initialCurrency (X Exchange {xFromCur = c}) = c
alloAcnt :: Allocation w v -> AcntID alloAcnt :: Allocation w v -> AcntID
alloAcnt = taAcnt . alloTo alloAcnt = AcntID . taAcnt . alloTo
data UnbalancedValue = UnbalancedValue
{ cvType :: !BudgetTransferType
, cvValue :: !Rational
}
deriving (Show)
type UnbalancedTransfer = FlatTransfer UnbalancedValue
type BalancedTransfer = FlatTransfer Rational
data FlatTransfer v = FlatTransfer
{ ftFrom :: !TaggedAcnt
, ftTo :: !TaggedAcnt
, ftValue :: !v
, ftWhen :: !Day
, ftDesc :: !T.Text
, ftMeta :: !BudgetMeta
, ftCur :: !BudgetCurrency
}
deriving (Show)
data BudgetMeta = BudgetMeta
{ bmCommit :: !CommitRId
, bmName :: !T.Text
}
deriving (Show)
type IntAllocations = type IntAllocations =
( [DaySpanAllocation PretaxValue] ( [DaySpanAllocation PretaxValue]
@ -557,14 +389,11 @@ type IntAllocations =
type DaySpanAllocation = Allocation DaySpan type DaySpanAllocation = Allocation DaySpan
type EntryPair = (KeyEntry, KeyEntry) type PeriodScaler = Precision -> Double -> Decimal
type PeriodScaler = Natural -> Double -> Double
data FlatAllocation v = FlatAllocation data FlatAllocation v = FlatAllocation
{ faValue :: !v { faValue :: !v
, faDesc :: !T.Text , faDesc :: !T.Text
, faTo :: !TaggedAcnt , faTo :: !TaggedAcnt
, faCur :: !BudgetCurrency
} }
deriving (Functor, Show) deriving (Functor, Show)

View File

@ -1,35 +1,38 @@
module Internal.Database module Internal.Database
( runDB ( runDB
, readConfigState
, nukeTables , nukeTables
, updateHashes
, updateDBState , updateDBState
, getDBState
, tree2Records , tree2Records
, flattenAcntRoot , flattenAcntRoot
, indexAcntRoot
, paths2IDs , paths2IDs
, mkPool , mkPool
, whenHash
, whenHash_
, insertEntry , insertEntry
, resolveEntry , readUpdates
, insertAll
, updateTx
) )
where where
import Conduit import Conduit
import Control.Monad.Except import Control.Monad.Except
import Control.Monad.Logger import Control.Monad.Logger
import Data.Decimal
import Data.Hashable import Data.Hashable
import Database.Esqueleto.Experimental ((==.), (^.)) import Database.Esqueleto.Experimental ((:&) (..), (==.), (?.), (^.))
import qualified Database.Esqueleto.Experimental as E import qualified Database.Esqueleto.Experimental as E
import Database.Esqueleto.Internal.Internal (SqlSelect) import Database.Esqueleto.Internal.Internal (SqlSelect)
import Database.Persist.Monad import Database.Persist.Monad
import Database.Persist.Sqlite hiding import Database.Persist.Sqlite hiding
( delete ( Statement
, delete
, deleteWhere , deleteWhere
, insert , insert
, insertKey , insertKey
, insert_ , insert_
, runMigration , runMigration
, update
, (==.) , (==.)
, (||.) , (||.)
) )
@ -37,10 +40,10 @@ import GHC.Err
import Internal.Types.Main import Internal.Types.Main
import Internal.Utils import Internal.Utils
import RIO hiding (LogFunc, isNothing, on, (^.)) import RIO hiding (LogFunc, isNothing, on, (^.))
import RIO.List ((\\))
import qualified RIO.List as L import qualified RIO.List as L
import qualified RIO.Map as M import qualified RIO.Map as M
import qualified RIO.NonEmpty as N import qualified RIO.NonEmpty as NE
import qualified RIO.Set as S
import qualified RIO.Text as T import qualified RIO.Text as T
runDB runDB
@ -103,85 +106,192 @@ nukeTables = do
-- toFullPath path name = T.unwords [unValue @T.Text path, "/", unValue @T.Text name] -- toFullPath path name = T.unwords [unValue @T.Text path, "/", unValue @T.Text name]
-- toBal = maybe "???" (fmtRational 2) . unValue -- toBal = maybe "???" (fmtRational 2) . unValue
hashConfig :: Config -> [Int] readConfigState
hashConfig :: (MonadAppError m, MonadSqlQuery m)
Config_ => Config
{ budget = bs -> [Budget]
, statements = ss -> [History]
} = (hash <$> bs) ++ (hash <$> ms) ++ (hash <$> ps) -> m ConfigState
readConfigState c bs hs = do
(acnts2Ins, acntsRem, acnts2Del) <- diff newAcnts
(pathsIns, _, pathsDel) <- diff newPaths
(curs2Ins, cursRem, curs2Del) <- diff newCurs
(tags2Ins, tagsRem, tags2Del) <- diff newTags
let amap = makeAcntMap $ acnts2Ins ++ (fst <$> acntsRem)
let cmap = currencyMap $ curs2Ins ++ (fst <$> cursRem)
let tmap = makeTagMap $ tags2Ins ++ (fst <$> tagsRem)
let fromMap f = S.fromList . fmap f . M.elems
let existing =
ExistingConfig (fromMap fst amap) (fromMap id tmap) (fromMap cpID cmap)
(curBgts, curHistTrs, curHistSts) <- readCurrentCommits
-- TODO refine this test to include the whole db (with data already mixed
-- in this algorithm)
let bsRes = BudgetSpan <$> resolveScope budgetInterval
let hsRes = HistorySpan <$> resolveScope statementInterval
combineErrorM bsRes hsRes $ \bscope hscope -> do
let dbempty = null $ curBgts ++ curHistTrs ++ curHistSts
(bChanged, hChanged) <- readScopeChanged dbempty bscope hscope
bgt <- makeTxCRUD existing bs curBgts bChanged
hTrans <- makeTxCRUD existing ts curHistTrs hChanged
hStmt <- makeTxCRUD existing ss curHistSts hChanged
return $
ConfigState
{ csCurrencies = CRUDOps curs2Ins () () curs2Del
, csTags = CRUDOps tags2Ins () () tags2Del
, csAccounts = CRUDOps acnts2Ins () () acnts2Del
, csPaths = CRUDOps pathsIns () () pathsDel
, csBudgets = bgt
, csHistTrans = hTrans
, csHistStmts = hStmt
, csAccountMap = amap
, csCurrencyMap = cmap
, csTagMap = tmap
, csBudgetScope = bscope
, csHistoryScope = hscope
}
where
(ts, ss) = splitHistory hs
diff new = setDiffWith (\a b -> E.entityKey a == b) new <$> readCurrentIds
(newAcnts, newPaths) = indexAcntRoot $ accounts c
newTags = tag2Record <$> tags c
newCurs = currency2Record <$> currencies c
resolveScope f = liftExcept $ resolveDaySpan $ f $ scope c
readScopeChanged
:: (MonadAppError m, MonadSqlQuery m)
=> Bool
-> BudgetSpan
-> HistorySpan
-> m (Bool, Bool)
readScopeChanged dbempty bscope hscope = do
rs <- dumpTbl
-- TODO these errors should only fire when someone messed with the DB
case rs of
[] -> if dbempty then return (True, True) else throwAppError $ DBError DBShouldBeEmpty
[r] -> do
let (ConfigStateR h b) = E.entityVal r
return (bscope /= b, hscope /= h)
_ -> throwAppError $ DBError DBMultiScope
makeTxCRUD
:: (MonadAppError m, MonadSqlQuery m, Hashable a)
=> ExistingConfig
-> [a]
-> [CommitHash]
-> Bool
-> m
( CRUDOps
[a]
[ReadEntry]
[Either TotalUpdateEntrySet FullUpdateEntrySet]
DeleteTxs
)
makeTxCRUD existing newThings curThings scopeChanged = do
let (toDelHashes, overlap, toIns) =
setDiffWith (\a b -> hash b == unCommitHash a) curThings newThings
-- Check the overlap for rows with accounts/tags/currencies that
-- won't exist on the next update. Those with invalid IDs will be set aside
-- to delete and reinsert (which may also fail) later
(noRetry, toInsRetry) <- readInvalidIds existing overlap
let (toDelAllHashes, toInsAll) = bimap (toDelHashes ++) (toIns ++) $ L.unzip toInsRetry
-- If we are inserting or deleting something or the scope changed, pull out
-- the remainder of the entries to update/read as we are (re)inserting other
-- stuff (this is necessary because a given transaction may depend on the
-- value of previous transactions, even if they are already in the DB).
(toRead, toUpdate) <- case (toInsAll, toDelAllHashes, scopeChanged) of
([], [], False) -> return ([], [])
_ -> readUpdates noRetry
toDelAll <- readTxIds toDelAllHashes
return $ CRUDOps toInsAll toRead toUpdate toDelAll
readTxIds :: MonadSqlQuery m => [CommitHash] -> m DeleteTxs
readTxIds cs = do
xs <- selectE $ do
(commits :& txs :& ess :& es :& ts) <-
E.from
$ E.table
`E.innerJoin` E.table
`E.on` (\(c :& t) -> c ^. CommitRId ==. t ^. TransactionRCommit)
`E.innerJoin` E.table
`E.on` (\(_ :& t :& es) -> t ^. TransactionRId ==. es ^. EntrySetRTransaction)
`E.innerJoin` E.table
`E.on` (\(_ :& _ :& es :& e) -> es ^. EntrySetRId ==. e ^. EntryREntryset)
`E.innerJoin` E.table
`E.on` (\(_ :& _ :& _ :& e :& t) -> e ^. EntryRId ==. t ^. TagRelationREntry)
E.where_ $ commits ^. CommitRHash `E.in_` E.valList cs
return
( txs ^. TransactionRId
, ess ^. EntrySetRId
, es ^. EntryRId
, ts ^. TagRelationRId
)
let (txs, ss, es, ts) = L.unzip4 xs
return $
DeleteTxs
{ dtTxs = go txs
, dtEntrySets = go ss
, dtEntries = go es
, dtTagRelations = E.unValue <$> ts
}
where
go :: Eq a => [E.Value a] -> [a]
go = fmap (E.unValue . NE.head) . NE.group
splitHistory :: [History] -> ([PairedTransfer], [Statement])
splitHistory = partitionEithers . fmap go
where where
(ms, ps) = partitionEithers $ fmap go ss
go (HistTransfer x) = Left x go (HistTransfer x) = Left x
go (HistStatement x) = Right x go (HistStatement x) = Right x
setDiff :: Eq a => [a] -> [a] -> ([a], [a]) makeTagMap :: [Entity TagR] -> TagMap
-- setDiff = setDiff' (==) makeTagMap = M.fromList . fmap (\e -> (tagRSymbol $ entityVal e, entityKey e))
setDiff as bs = (as \\ bs, bs \\ as)
-- setDiff' :: Eq a => (a -> b -> Bool) -> [a] -> [b] -> ([a], [b]) tag2Record :: Tag -> Entity TagR
-- setDiff' f = go [] tag2Record t@Tag {tagID, tagDesc} = Entity (toKey t) $ TagR (TagID tagID) tagDesc
-- where
-- go inA [] bs = (inA, bs)
-- go inA as [] = (as ++ inA, [])
-- go inA (a:as) bs = case inB a bs of
-- Just bs' -> go inA as bs'
-- Nothing -> go (a:inA) as bs
-- inB _ [] = Nothing
-- inB a (b:bs)
-- | f a b = Just bs
-- | otherwise = inB a bs
getDBHashes :: MonadSqlQuery m => m [Int]
getDBHashes = fmap (commitRHash . entityVal) <$> dumpTbl
nukeDBHash :: MonadSqlQuery m => Int -> m ()
nukeDBHash h = deleteE $ do
c <- E.from E.table
E.where_ (c ^. CommitRHash ==. E.val h)
nukeDBHashes :: MonadSqlQuery m => [Int] -> m ()
nukeDBHashes = mapM_ nukeDBHash
getConfigHashes :: MonadSqlQuery m => Config -> m ([Int], [Int])
getConfigHashes c = do
let ch = hashConfig c
dh <- getDBHashes
return $ setDiff dh ch
dumpTbl :: (MonadSqlQuery m, PersistEntity r) => m [Entity r]
dumpTbl = selectE $ E.from E.table
deleteAccount :: MonadSqlQuery m => Entity AccountR -> m ()
deleteAccount e = deleteE $ do
c <- E.from $ E.table @AccountR
E.where_ (c ^. AccountRId ==. E.val k)
where
k = entityKey e
deleteCurrency :: MonadSqlQuery m => Entity CurrencyR -> m ()
deleteCurrency e = deleteE $ do
c <- E.from $ E.table @CurrencyR
E.where_ (c ^. CurrencyRId ==. E.val k)
where
k = entityKey e
deleteTag :: MonadSqlQuery m => Entity TagR -> m ()
deleteTag e = deleteE $ do
c <- E.from $ E.table @TagR
E.where_ (c ^. TagRId ==. E.val k)
where
k = entityKey e
-- TODO slip-n-slide code...
insertFull
:: (PersistRecordBackend r SqlBackend, Typeable r, MonadSqlQuery m)
=> Entity r
-> m ()
insertFull (Entity k v) = insertKey k v
currency2Record :: Currency -> Entity CurrencyR currency2Record :: Currency -> Entity CurrencyR
currency2Record c@Currency {curSymbol, curFullname, curPrecision} = currency2Record c@Currency {curSymbol, curFullname, curPrecision} =
Entity (toKey c) $ CurrencyR curSymbol curFullname (fromIntegral curPrecision) Entity (toKey c) $ CurrencyR (CurID curSymbol) curFullname (fromIntegral curPrecision)
readCurrentIds :: PersistEntity a => MonadSqlQuery m => m [Key a]
readCurrentIds = fmap (E.unValue <$>) $ selectE $ do
rs <- E.from E.table
return (rs ^. E.persistIdField)
readCurrentCommits :: MonadSqlQuery m => m ([CommitHash], [CommitHash], [CommitHash])
readCurrentCommits = do
xs <- selectE $ do
rs <- E.from E.table
return (rs ^. CommitRHash, rs ^. CommitRType)
return $ foldr go ([], [], []) xs
where
go (x, t) (bs, ts, hs) =
let y = E.unValue x
in case E.unValue t of
CTBudget -> (y : bs, ts, hs)
CTHistoryTransfer -> (bs, y : ts, hs)
CTHistoryStatement -> (bs, ts, y : hs)
setDiffWith :: (a -> b -> Bool) -> [a] -> [b] -> ([a], [(a, b)], [b])
setDiffWith f = go [] []
where
go inA inBoth [] bs = (inA, inBoth, bs)
go inA inBoth as [] = (as ++ inA, inBoth, [])
go inA inBoth (a : as) bs =
let (res, bs') = findDelete (f a) bs
in case res of
Nothing -> go (a : inA) inBoth as bs
Just b -> go inA ((a, b) : inBoth) as bs'
findDelete :: (a -> Bool) -> [a] -> (Maybe a, [a])
findDelete f xs = case break f xs of
(ys, []) -> (Nothing, ys)
(ys, z : zs) -> (Just z, ys ++ zs)
dumpTbl :: (MonadSqlQuery m, PersistEntity r) => m [Entity r]
dumpTbl = selectE $ E.from E.table
currencyMap :: [Entity CurrencyR] -> CurrencyMap currencyMap :: [Entity CurrencyR] -> CurrencyMap
currencyMap = currencyMap =
@ -189,46 +299,43 @@ currencyMap =
. fmap . fmap
( \e -> ( \e ->
( currencyRSymbol $ entityVal e ( currencyRSymbol $ entityVal e
, (entityKey e, fromIntegral $ currencyRPrecision $ entityVal e) , CurrencyPrec (entityKey e) $ currencyRPrecision $ entityVal e
) )
) )
toKey :: (ToBackendKey SqlBackend b, Hashable a) => a -> Key b toKey :: (ToBackendKey SqlBackend b, Hashable a) => a -> Key b
toKey = toSqlKey . fromIntegral . hash toKey = toSqlKey . fromIntegral . hash
tree2Entity :: AcntType -> [T.Text] -> T.Text -> T.Text -> Entity AccountR makeAccountEntity :: AccountR -> Entity AccountR
tree2Entity t parents name des = makeAccountEntity a = Entity (toKey $ accountRFullpath a) a
Entity (toSqlKey $ fromIntegral h) $
AccountR name (toPath parents) des
where
p = AcntPath t (reverse (name : parents))
h = hash p
toPath = T.intercalate "/" . (atName t :) . reverse
tree2Records makeAccountR :: AcntType -> T.Text -> [T.Text] -> T.Text -> Bool -> AccountR
:: AcntType makeAccountR atype name parents des = AccountR name path des (accountSign atype)
-> AccountTree where
-> ([Entity AccountR], [AccountPathR], [(AcntPath, (AccountRId, AcntSign, AcntType))]) path = AcntPath atype (reverse $ name : parents)
tree2Records :: AcntType -> AccountTree -> ([Entity AccountR], [Entity AccountPathR])
tree2Records t = go [] tree2Records t = go []
where where
go ps (Placeholder d n cs) = go ps (Placeholder d n cs) =
let e = tree2Entity t (fmap snd ps) n d let (parentKeys, parentNames) = L.unzip ps
k = entityKey e a = acnt n parentNames d False
(as, aps, ms) = L.unzip3 $ fmap (go ((k, n) : ps)) cs k = entityKey a
a0 = acnt k n (fmap snd ps) d thesePaths = expand k parentKeys
paths = expand k $ fmap fst ps in bimap ((a :) . concat) ((thesePaths ++) . concat) $
in (a0 : concat as, paths ++ concat aps, concat ms) L.unzip $
go ((k, n) : ps) <$> cs
go ps (Account d n) = go ps (Account d n) =
let e = tree2Entity t (fmap snd ps) n d let (parentKeys, parentNames) = L.unzip ps
k = entityKey e a = acnt n parentNames d True
in ( [acnt k n (fmap snd ps) d] k = entityKey a
, expand k $ fmap fst ps in ([a], expand k parentKeys)
, [(AcntPath t $ reverse $ n : fmap snd ps, (k, sign, t))] expand h0 hs = (\(h, d) -> accountPathRecord h h0 d) <$> zip (h0 : hs) [0 ..]
) acnt n ps d = makeAccountEntity . makeAccountR t n ps d
toPath = T.intercalate "/" . (atName t :) . reverse
acnt k n ps = Entity k . AccountR n (toPath ps) accountPathRecord :: Key AccountR -> Key AccountR -> Int -> Entity AccountPathR
expand h0 hs = (\(h, d) -> AccountPathR h h0 d) <$> zip (h0 : hs) [0 ..] accountPathRecord p c d =
sign = accountSign t Entity (toKey (fromSqlKey p, fromSqlKey c)) $ AccountPathR p c d
paths2IDs :: [(AcntPath, a)] -> [(AcntID, a)] paths2IDs :: [(AcntPath, a)] -> [(AcntID, a)]
paths2IDs = paths2IDs =
@ -236,49 +343,25 @@ paths2IDs =
. first trimNames . first trimNames
. L.unzip . L.unzip
. L.sortOn fst . L.sortOn fst
. fmap (first pathList) . fmap (first (NE.reverse . acntPath2NonEmpty))
where
pathList (AcntPath t []) = atName t :| []
pathList (AcntPath t ns) = N.reverse $ atName t :| ns
-- none of these errors should fire assuming that input is sorted and unique -- none of these errors should fire assuming that input is sorted and unique
trimNames :: [N.NonEmpty T.Text] -> [AcntID] trimNames :: [NonEmpty T.Text] -> [AcntID]
trimNames = fmap (T.intercalate "_" . reverse) . trimAll 0 trimNames = fmap (AcntID . T.intercalate "_") . go []
where where
trimAll _ [] = [] go :: [T.Text] -> [NonEmpty T.Text] -> [[T.Text]]
trimAll i (y : ys) = case L.foldl' (matchPre i) (y, [], []) ys of go prev = concatMap (go' prev) . groupNonEmpty
(a, [], bs) -> reverse $ trim i a : bs go' prev (key, rest) = case rest of
(a, as, bs) -> reverse bs ++ trimAll (i + 1) (reverse $ a : as) (_ :| []) -> [key : prev]
matchPre i (y, ys, old) new = case (y !? i, new !? i) of ([] :| xs) ->
(Nothing, Just _) -> let next = key : prev
case ys of other = go next $ fmap (fromMaybe err . NE.nonEmpty) xs
[] -> (new, [], trim i y : old) in next : other
_ -> err "unsorted input" (x :| xs) -> go (key : prev) $ fmap (fromMaybe err . NE.nonEmpty) (x : xs)
(Just _, Nothing) -> err "unsorted input" err = error "account path list either not sorted or contains duplicates"
(Nothing, Nothing) -> err "duplicated inputs"
(Just a, Just b)
| a == b -> (new, y : ys, old)
| otherwise ->
let next = case ys of
[] -> [trim i y]
_ -> trimAll (i + 1) (reverse $ y : ys)
in (new, [], reverse next ++ old)
trim i = N.take (i + 1)
err msg = errorWithoutStackTrace $ "Import.Database.Ops.hs: " ++ msg
(!?) :: N.NonEmpty a -> Int -> Maybe a groupNonEmpty :: Ord a => [NonEmpty a] -> [(a, NonEmpty [a])]
xs !? n groupNonEmpty = fmap (second (NE.tail <$>)) . groupWith NE.head
| n < 0 = Nothing
-- Definition adapted from GHC.List
| otherwise =
foldr
( \x r k -> case k of
0 -> Just x
_ -> r (k - 1)
)
(const Nothing)
xs
n
flattenAcntRoot :: AccountRoot -> [(AcntType, AccountTree)] flattenAcntRoot :: AccountRoot -> [(AcntType, AccountTree)]
flattenAcntRoot AccountRoot_ {arIncome, arExpenses, arLiabilities, arAssets, arEquity} = flattenAcntRoot AccountRoot_ {arIncome, arExpenses, arLiabilities, arAssets, arEquity} =
@ -288,129 +371,372 @@ flattenAcntRoot AccountRoot_ {arIncome, arExpenses, arLiabilities, arAssets, arE
++ ((AssetT,) <$> arAssets) ++ ((AssetT,) <$> arAssets)
++ ((EquityT,) <$> arEquity) ++ ((EquityT,) <$> arEquity)
indexAcntRoot :: AccountRoot -> ([Entity AccountR], [AccountPathR], AccountMap) makeAcntMap :: [Entity AccountR] -> AccountMap
indexAcntRoot r = makeAcntMap =
( concat ars M.fromList
, concat aprs . paths2IDs
, M.fromList $ paths2IDs $ concat ms . fmap go
) . filter (accountRLeaf . snd)
. fmap (\e -> (E.entityKey e, E.entityVal e))
where where
(ars, aprs, ms) = L.unzip3 $ uncurry tree2Records <$> flattenAcntRoot r go (k, v) = let p = accountRFullpath v in (p, (k, apType p))
getDBState indexAcntRoot :: AccountRoot -> ([Entity AccountR], [Entity AccountPathR])
:: (MonadInsertError m, MonadSqlQuery m) indexAcntRoot = bimap concat concat . L.unzip . fmap (uncurry tree2Records) . flattenAcntRoot
=> Config
-> m (DBState, DBUpdates) updateCD
getDBState c = do :: ( MonadSqlQuery m
(del, new) <- getConfigHashes c , PersistRecordBackend a SqlBackend
combineError bi si $ \b s -> , PersistRecordBackend b SqlBackend
( DBState
{ kmCurrency = currencyMap cs
, kmAccount = am
, kmBudgetInterval = b
, kmStatementInterval = s
, kmTag = tagMap ts
, kmNewCommits = new
}
, DBUpdates
{ duOldCommits = del
, duNewTagIds = ts
, duNewAcntPaths = paths
, duNewAcntIds = acnts
, duNewCurrencyIds = cs
}
) )
=> CDOps (Entity a) (Key b)
-> m ()
updateCD (CRUDOps cs () () ds) = do
mapM_ deleteKeyE ds
insertEntityManyE cs
deleteTxs :: MonadSqlQuery m => DeleteTxs -> m ()
deleteTxs DeleteTxs {dtTxs, dtEntrySets, dtEntries, dtTagRelations} = do
mapM_ deleteKeyE dtTxs
mapM_ deleteKeyE dtEntrySets
mapM_ deleteKeyE dtEntries
mapM_ deleteKeyE dtTagRelations
updateDBState :: (MonadFinance m, MonadSqlQuery m) => m ()
updateDBState = do
updateCD =<< asks csCurrencies
updateCD =<< asks csAccounts
updateCD =<< asks csPaths
updateCD =<< asks csTags
deleteTxs =<< asks (coDelete . csBudgets)
deleteTxs =<< asks (coDelete . csHistTrans)
deleteTxs =<< asks (coDelete . csHistStmts)
b <- asks csBudgetScope
h <- asks csHistoryScope
repsertE (E.toSqlKey 1) $ ConfigStateR h b
readInvalidIds
:: MonadSqlQuery m
=> ExistingConfig
-> [(CommitHash, a)]
-> m ([CommitHash], [(CommitHash, a)])
readInvalidIds ExistingConfig {ecAccounts, ecCurrencies, ecTags} xs = do
rs <- selectE $ do
(commits :& _ :& entrysets :& entries :& tags) <-
E.from
$ E.table
`E.innerJoin` E.table
`E.on` (\(c :& t) -> c ^. CommitRId ==. t ^. TransactionRCommit)
`E.innerJoin` E.table
`E.on` (\(_ :& t :& es) -> t ^. TransactionRId ==. es ^. EntrySetRTransaction)
`E.innerJoin` E.table
`E.on` (\(_ :& _ :& es :& e) -> es ^. EntrySetRId ==. e ^. EntryREntryset)
`E.leftJoin` E.table
`E.on` (\(_ :& _ :& _ :& e :& r) -> E.just (e ^. EntryRId) ==. r ?. TagRelationREntry)
E.where_ $ commits ^. CommitRHash `E.in_` E.valList (fmap fst xs)
return
( commits ^. CommitRHash
, entrysets ^. EntrySetRCurrency
, entries ^. EntryRAccount
, tags ?. TagRelationRTag
)
-- TODO there are faster ways to do this; may/may not matter
let cs = go ecCurrencies $ fmap (\(i, E.Value c, _, _) -> (i, c)) rs
let as = go ecAccounts $ fmap (\(i, _, E.Value a, _) -> (i, a)) rs
let ts = go ecTags [(i, t) | (i, _, _, E.Value (Just t)) <- rs]
let valid = (cs `S.intersection` as) `S.intersection` ts
let (a0, _) = first (fst <$>) $ L.partition ((`S.member` valid) . fst) xs
return (a0, [])
where where
bi = liftExcept $ resolveDaySpan $ budgetInterval $ global c go existing =
si = liftExcept $ resolveDaySpan $ statementInterval $ global c S.fromList
(acnts, paths, am) = indexAcntRoot $ accounts c . fmap (E.unValue . fst)
cs = currency2Record <$> currencies c . L.filter (all (`S.member` existing) . snd)
ts = toRecord <$> tags c . groupKey id
toRecord t@Tag {tagID, tagDesc} = Entity (toKey t) $ TagR tagID tagDesc
tagMap = M.fromList . fmap (\e -> (tagRSymbol $ entityVal e, entityKey e))
updateHashes :: (MonadSqlQuery m) => DBUpdates -> m () readUpdates
updateHashes DBUpdates {duOldCommits} = nukeDBHashes duOldCommits :: (MonadAppError m, MonadSqlQuery m)
=> [CommitHash]
-> m ([ReadEntry], [Either TotalUpdateEntrySet FullUpdateEntrySet])
readUpdates hashes = do
xs <- selectE $ do
(commits :& txs :& entrysets :& entries :& currencies) <-
E.from
$ E.table @CommitR
`E.innerJoin` E.table @TransactionR
`E.on` (\(c :& t) -> c ^. CommitRId ==. t ^. TransactionRCommit)
`E.innerJoin` E.table @EntrySetR
`E.on` (\(_ :& t :& es) -> t ^. TransactionRId ==. es ^. EntrySetRTransaction)
`E.innerJoin` E.table @EntryR
`E.on` (\(_ :& _ :& es :& e) -> es ^. EntrySetRId ==. e ^. EntryREntryset)
`E.innerJoin` E.table @CurrencyR
`E.on` (\(_ :& _ :& es :& _ :& cur) -> es ^. EntrySetRCurrency ==. cur ^. CurrencyRId)
E.where_ $ commits ^. CommitRHash `E.in_` E.valList hashes
return
( entrysets ^. EntrySetRRebalance
,
(
( entrysets ^. EntrySetRId
, txs ^. TransactionRDate
, txs ^. TransactionRBudgetName
, txs ^. TransactionRPriority
,
( entrysets ^. EntrySetRCurrency
, currencies ^. CurrencyRPrecision
)
)
, entries
)
)
let (toUpdate, toRead) = L.partition (E.unValue . fst) xs
toUpdate' <- liftExcept $ mapErrors makeUES $ groupKey (\(i, _, _, _, _) -> i) (snd <$> toUpdate)
let toRead' = fmap (makeRE . snd) toRead
return (toRead', toUpdate')
where
makeUES ((_, day, name, pri, (curID, prec)), es) = do
let prec' = fromIntegral $ E.unValue prec
let cur = E.unValue curID
let res =
bimap NE.nonEmpty NE.nonEmpty $
NE.partition ((< 0) . entryRIndex . snd) $
NE.sortWith (entryRIndex . snd) $
fmap (\e -> (entityKey e, entityVal e)) es
case res of
(Just froms, Just tos) -> do
let tot = sum $ fmap (entryRValue . snd) froms
(from0, fromRO, fromUnkVec) <- splitFrom prec' $ NE.reverse froms
(from0', fromUnk, to0, toRO, toUnk) <- splitTo prec' from0 fromUnkVec tos
-- TODO WAP (wet ass programming)
return $ case from0' of
Left x ->
Left $
UpdateEntrySet
{ utDate = E.unValue day
, utCurrency = cur
, utFrom0 = x
, utTo0 = to0
, utFromRO = fromRO
, utToRO = toRO
, utFromUnk = fromUnk
, utToUnk = toUnk
, utTotalValue = realFracToDecimalP prec' tot
, utBudget = E.unValue name
, utPriority = E.unValue pri
}
Right x ->
Right $
UpdateEntrySet
{ utDate = E.unValue day
, utCurrency = cur
, utFrom0 = x
, utTo0 = to0
, utFromRO = fromRO
, utToRO = toRO
, utFromUnk = fromUnk
, utToUnk = toUnk
, utTotalValue = ()
, utBudget = E.unValue name
, utPriority = E.unValue pri
}
-- TODO this error is lame
_ -> throwAppError $ DBError $ DBUpdateUnbalanced
makeRE ((_, day, name, pri, (curID, prec)), entry) = do
let e = entityVal entry
in ReadEntry
{ reDate = E.unValue day
, reCurrency = E.unValue curID
, reAcnt = entryRAccount e
, reValue = realFracToDecimal (fromIntegral $ E.unValue prec) (entryRValue e)
, reBudget = E.unValue name
, rePriority = E.unValue pri
}
updateTags :: (MonadFinance m, MonadSqlQuery m) => DBUpdates -> m () splitFrom
updateTags DBUpdates {duNewTagIds} = do :: Precision
tags' <- selectE $ E.from $ E.table @TagR -> NonEmpty (EntryRId, EntryR)
let (toIns, toDel) = setDiff duNewTagIds tags' -> AppExcept (Either UEBlank (Either UE_RO UEUnk), [UE_RO], [UEUnk])
mapM_ deleteTag toDel splitFrom prec (f0 :| fs) = do
mapM_ insertFull toIns -- ASSUME entries are sorted by index
-- TODO combine errors here
let f0Res = readDeferredValue prec f0
let fsRes = mapErrors (splitDeferredValue prec) fs
combineErrorM f0Res fsRes $ \f0' fs' -> do
let (ro, unk) = partitionEithers fs'
-- let idxVec = V.fromList $ fmap (either (const Nothing) Just) fs'
return (f0', ro, unk)
updateAccounts :: (MonadFinance m, MonadSqlQuery m) => DBUpdates -> m () splitTo
updateAccounts DBUpdates {duNewAcntIds, duNewAcntPaths} = do :: Precision
acnts' <- dumpTbl -> Either UEBlank (Either UE_RO UEUnk)
let (toIns, toDel) = setDiff duNewAcntIds acnts' -> [UEUnk]
deleteWhere ([] :: [Filter AccountPathR]) -> NonEmpty (EntryRId, EntryR)
mapM_ deleteAccount toDel -> AppExcept
mapM_ insertFull toIns ( Either (UEBlank, [UELink]) (Either UE_RO (UEUnk, [UELink]))
mapM_ insert duNewAcntPaths , [(UEUnk, [UELink])]
, UEBlank
, [UE_RO]
, [UEUnk]
)
splitTo prec from0 fromUnk (t0 :| ts) = do
-- How to split the credit side of the database transaction in 1024 easy
-- steps:
--
-- 1. Split incoming entries (except primary) into those with links and not
let (unlinked, linked) = partitionEithers $ fmap splitLinked ts
updateCurrencies :: (MonadFinance m, MonadSqlQuery m) => DBUpdates -> m () -- 2. For unlinked entries, split into read-only and unknown entries
updateCurrencies DBUpdates {duNewCurrencyIds} = do let unlinkedRes = partitionEithers <$> mapErrors (splitDeferredValue prec) unlinked
curs' <- selectE $ E.from $ E.table @CurrencyR
let (toIns, toDel) = setDiff duNewCurrencyIds curs'
mapM_ deleteCurrency toDel
mapM_ insertFull toIns
updateDBState :: (MonadFinance m, MonadSqlQuery m) => DBUpdates -> m () -- 3. For linked entries, split into those that link to the primary debit
updateDBState u = do -- entry and not
updateHashes u let (linked0, linkedN) = second (groupKey id) $ L.partition ((== 0) . fst) linked
updateTags u
updateAccounts u
updateCurrencies u
deleteE :: (MonadSqlQuery m) => E.SqlQuery () -> m () -- 4. For linked entries that don't link to the primary debit entry, split
deleteE q = unsafeLiftSql "esqueleto-delete" (E.delete q) -- into those that link to an unknown debit entry or not. Those that
-- are not will be read-only and those that are will be collected with
-- their linked debit entry
let linkedRes = zipPaired prec fromUnk linkedN
-- 5. For entries linked to the primary debit entry, turn them into linked
-- entries (lazily only used when needed later)
let from0Res = mapErrors (makeLinkUnk . snd) linked0
combineErrorM3 from0Res linkedRes unlinkedRes $
-- 6. Depending on the type of primary debit entry we have, add linked
-- entries if it is either an unknown or a blank (to be solved) entry,
-- or turn the remaining linked entries to read-only and add to the other
-- read-only entries
\from0Links (fromUnk', toROLinkedN) (toROUnlinked, toUnk) -> do
let (from0', toROLinked0) = case from0 of
Left blnk -> (Left (blnk, from0Links), [])
Right (Left ro) -> (Right $ Left ro, makeRoUE prec . snd . snd <$> linked0)
Right (Right unk) -> (Right $ Right (unk, from0Links), [])
return (from0', fromUnk', primary, toROLinked0 ++ toROLinkedN ++ toROUnlinked, toUnk)
where
primary = uncurry makeUnkUE t0
splitLinked t@(_, e) = maybe (Left t) (Right . (,t)) $ entryRCachedLink e
-- | Match linked credit entries with unknown entries, returning a list of
-- matches and non-matching (read-only) credit entries. ASSUME both lists are
-- sorted according to index and 'fst' respectively. NOTE the output will NOT be
-- sorted.
zipPaired
:: Precision
-> [UEUnk]
-> [(EntryIndex, NonEmpty (EntryRId, EntryR))]
-> AppExcept ([(UEUnk, [UELink])], [UE_RO])
zipPaired prec = go ([], [])
where
nolinks = ((,[]) <$>)
go acc fs [] = return $ first (nolinks fs ++) acc
go (facc, tacc) fs ((ti, tls) : ts) = do
let (lesser, rest) = L.span ((< ti) . ueIndex) fs
links <- NE.toList <$> mapErrors makeLinkUnk tls
let (nextLink, fs') = case rest of
(r0 : rs)
| ueIndex r0 == ti -> (Just (r0, links), rs)
| otherwise -> (Nothing, rest)
_ -> (Nothing, rest)
let acc' = (nolinks lesser ++ facc, tacc)
let ros = NE.toList $ makeRoUE prec . snd <$> tls
let f = maybe (second (++ ros)) (\u -> first (u :)) nextLink
go (f acc') fs' ts
makeLinkUnk :: (EntryRId, EntryR) -> AppExcept UELink
makeLinkUnk (k, e) =
-- TODO error should state that scale must be present for a link in the db
maybe
(throwAppError $ DBError $ DBLinkError k DBLinkNoScale)
(return . makeUE k e . LinkScale)
$ fromRational <$> entryRCachedValue e
splitDeferredValue :: Precision -> (EntryRId, EntryR) -> AppExcept (Either UE_RO UEUnk)
splitDeferredValue prec p@(k, _) = do
res <- readDeferredValue prec p
case res of
Left _ -> throwAppError $ DBError $ DBLinkError k DBLinkNoValue
Right x -> return x
readDeferredValue :: Precision -> (EntryRId, EntryR) -> AppExcept (Either UEBlank (Either UE_RO UEUnk))
readDeferredValue prec (k, e) = case (entryRCachedValue e, entryRCachedType e) of
(Nothing, Just TFixed) -> return $ Right $ Left $ makeRoUE prec e
(Just v, Just TBalance) -> go $ fmap EVBalance $ makeUE k e $ realFracToDecimalP prec v
(Just v, Just TPercent) -> go $ fmap EVPercent $ makeUE k e $ fromRational v
(Nothing, Nothing) -> return $ Left $ makeUnkUE k e
(Just v, Nothing) -> err $ DBLinkInvalidValue v False
(Just v, Just TFixed) -> err $ DBLinkInvalidValue v True
(Nothing, Just TBalance) -> err $ DBLinkInvalidBalance
(Nothing, Just TPercent) -> err $ DBLinkInvalidPercent
where
go = return . Right . Right
err = throwAppError . DBError . DBLinkError k
makeUE :: i -> EntryR -> v -> UpdateEntry i v
makeUE k e v = UpdateEntry k (entryRAccount e) v (entryRIndex e)
makeRoUE :: Precision -> EntryR -> UpdateEntry () StaticValue
makeRoUE prec e = makeUE () e $ StaticValue (realFracToDecimalP prec $ entryRValue e)
makeUnkUE :: EntryRId -> EntryR -> UpdateEntry EntryRId ()
makeUnkUE k e = makeUE k e ()
insertAll
:: (MonadAppError m, MonadSqlQuery m, MonadFinance m)
=> [EntryCRU]
-> m ()
insertAll ebs = do
(toUpdate, toInsert) <- balanceTxs ebs
mapM_ updateTx toUpdate
forM_ (groupWith itxCommit toInsert) $
\(c, ts) -> do
ck <- insert c
mapM_ (insertTx ck) ts
insertTx :: MonadSqlQuery m => CommitRId -> InsertTx -> m ()
insertTx c InsertTx {itxDate, itxDescr, itxEntrySets, itxBudget, itxPriority} = do
k <- insert $ TransactionR c itxDate itxDescr itxBudget itxPriority
mapM_ (uncurry (insertEntrySet k)) $ zip [0 ..] (NE.toList itxEntrySets)
where
insertEntrySet tk i InsertEntrySet {iesCurrency, iesFromEntries, iesToEntries} = do
let fs = NE.toList iesFromEntries
let ts = NE.toList iesToEntries
let rebalance = any (isJust . ieCached) (fs ++ ts)
esk <- insert $ EntrySetR tk iesCurrency i rebalance
mapM_ (uncurry (go esk)) $ zip [0 ..] ts ++ zip (negate <$> [1 ..]) fs
go k i e = void $ insertEntry k i e
insertEntry :: MonadSqlQuery m => EntrySetRId -> EntryIndex -> InsertEntry -> m EntryRId
insertEntry
k
i
InsertEntry
{ ieEntry = Entry {eValue, eTags, eAcnt, eComment}
, ieCached
} =
do
ek <- insert $ EntryR k eAcnt eComment (toRational eValue) i cval ctype deflink
mapM_ (insert_ . TagRelationR ek) eTags
return ek
where
(cval, ctype, deflink) = case ieCached of
(Just (CachedLink x s)) -> (Just (toRational s), Nothing, Just x)
(Just (CachedBalance b)) -> (Just (toRational b), Just TBalance, Nothing)
(Just (CachedPercent p)) -> (Just (toRational p), Just TPercent, Nothing)
Nothing -> (Nothing, Just TFixed, Nothing)
updateTx :: MonadSqlQuery m => UEBalanced -> m ()
updateTx UpdateEntry {ueID, ueValue} = update ueID [EntryRValue =. v]
where
v = toRational $ unStaticValue ueValue
repsertE :: (MonadSqlQuery m, PersistRecordBackend r SqlBackend) => Key r -> r -> m ()
repsertE k r = unsafeLiftSql "esqueleto-repsert" (E.repsert k r)
selectE :: (MonadSqlQuery m, SqlSelect a r) => E.SqlQuery a -> m [r] selectE :: (MonadSqlQuery m, SqlSelect a r) => E.SqlQuery a -> m [r]
selectE q = unsafeLiftSql "esqueleto-select" (E.select q) selectE q = unsafeLiftSql "esqueleto-select" (E.select q)
whenHash deleteKeyE :: (MonadSqlQuery m, PersistRecordBackend a SqlBackend) => Key a -> m ()
:: (Hashable a, MonadFinance m, MonadSqlQuery m) deleteKeyE q = unsafeLiftSql "esqueleto-deleteKey" (E.deleteKey q)
=> 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_ insertEntityManyE :: (MonadSqlQuery m, PersistRecordBackend a SqlBackend) => [Entity a] -> m ()
:: (Hashable a, MonadFinance m) insertEntityManyE q = unsafeLiftSql "esqueleto-insertEntityMany" (E.insertEntityMany q)
=> 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
insertEntry :: MonadSqlQuery m => TransactionRId -> KeyEntry -> m EntryRId
insertEntry t Entry {eAcnt, eCurrency, eValue, eComment, eTags} = do
k <- insert $ EntryR t eCurrency eAcnt eComment eValue
mapM_ (insert_ . TagRelationR k) eTags
return k
resolveEntry :: (MonadInsertError m, MonadFinance m) => BalEntry -> m KeyEntry
resolveEntry 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
}

View File

@ -1,15 +1,16 @@
module Internal.History module Internal.History
( splitHistory ( readHistStmt
, insertHistTransfer , readHistTransfer
, readHistStmt , splitHistory
, insertHistStmt
) )
where where
import Control.Monad.Except import Control.Monad.Except
import Data.Csv import Data.Csv
import Database.Persist.Monad import Data.Decimal
import Internal.Database import Data.Foldable
import Data.Hashable
import GHC.Real
import Internal.Types.Main import Internal.Types.Main
import Internal.Utils import Internal.Utils
import RIO hiding (to) import RIO hiding (to)
@ -20,107 +21,55 @@ import qualified RIO.Map as M
import qualified RIO.Text as T import qualified RIO.Text as T
import RIO.Time import RIO.Time
import qualified RIO.Vector as V import qualified RIO.Vector as V
import Text.Regex.TDFA hiding (matchAll)
import Text.Regex.TDFA.Text
splitHistory :: [History] -> ([HistTransfer], [Statement]) -- NOTE keep statement and transfer readers separate because the former needs
-- the IO monad, and thus will throw IO errors rather than using the ExceptT
-- thingy
splitHistory :: [History] -> ([PairedTransfer], [Statement])
splitHistory = partitionEithers . fmap go splitHistory = partitionEithers . fmap go
where where
go (HistTransfer x) = Left x go (HistTransfer x) = Left x
go (HistStatement x) = Right x go (HistStatement x) = Right x
insertHistTransfer --------------------------------------------------------------------------------
:: (MonadInsertError m, MonadSqlQuery m, MonadFinance m) -- Transfers
=> HistTransfer
-> m () readHistTransfer
insertHistTransfer :: (MonadAppError m, MonadFinance m)
m@Transfer => PairedTransfer
{ transFrom = from -> m [Tx CommitR]
, transTo = to readHistTransfer ht = do
, transCurrency = u bounds <- asks (unHSpan . csHistoryScope)
, transAmounts = amts expandTransfer c historyName bounds ht
} = do where
whenHash CTManual m () $ \c -> do c = CommitR (CommitHash $ hash ht) CTHistoryTransfer
bounds <- askDBState kmStatementInterval
let precRes = lookupCurrencyPrec u --------------------------------------------------------------------------------
let go Amount {amtWhen, amtValue, amtDesc} = do -- Statements
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 readHistStmt
:: (MonadUnliftIO m, MonadFinance m) :: (MonadUnliftIO m, MonadFinance m)
=> FilePath => FilePath
-> Statement -> Statement
-> m (Maybe (CommitR, [KeyTx])) -> m [Tx CommitR]
readHistStmt root i = whenHash_ CTImport i $ do readHistStmt root i = do
bs <- readImport root i bs <- readImport root i
bounds <- askDBState kmStatementInterval bounds <- asks (unHSpan . csHistoryScope)
liftIOExceptT $ mapErrors resolveTx $ filter (inDaySpan bounds . txDate) bs return $ filter (inDaySpan bounds . txDate) $ fmap (\t -> t {txCommit = c}) bs
insertHistStmt :: (MonadSqlQuery m) => CommitR -> [KeyTx] -> m ()
insertHistStmt c ks = do
ck <- insert c
mapM_ (insertTx ck) ks
--------------------------------------------------------------------------------
-- 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 where
split a v = c = CommitR (CommitHash $ hash i) CTHistoryStatement
Entry
{ eAcnt = a
, eValue = v
, eComment = ""
, eCurrency = cur
, eTags = []
}
tx =
Tx
{ txDescr = desc
, txDate = day
, txEntries = [split from (-val), split to val]
}
resolveTx :: (MonadInsertError m, MonadFinance m) => BalTx -> m KeyTx
resolveTx t@Tx {txEntries = ss} =
fmap (\kss -> t {txEntries = kss}) $
combineErrors $
fmap resolveEntry ss
insertTx :: MonadSqlQuery m => CommitRId -> KeyTx -> m ()
insertTx c Tx {txDate = d, txDescr = e, txEntries = ss} = do
k <- insert $ TransactionR c d e
mapM_ (insertEntry k) ss
--------------------------------------------------------------------------------
-- Statements
-- TODO this probably won't scale well (pipes?) -- TODO this probably won't scale well (pipes?)
readImport :: (MonadUnliftIO m, MonadFinance m) => FilePath -> Statement -> m [BalTx] readImport :: (MonadUnliftIO m, MonadFinance m) => FilePath -> Statement -> m [Tx ()]
readImport root Statement {stmtTxOpts, stmtParsers, stmtSkipLines, stmtDelim, stmtPaths} = do readImport root Statement {stmtTxOpts, stmtParsers, stmtSkipLines, stmtDelim, stmtPaths} = do
let ores = compileOptions stmtTxOpts let ores = compileOptions stmtTxOpts
let cres = combineErrors $ compileMatch <$> stmtParsers let cres = combineErrors $ compileMatch <$> stmtParsers
(compiledOptions, compiledMatches) <- liftIOExcept $ combineError ores cres (,) (compiledOptions, compiledMatches) <- liftIOExcept $ combineError ores cres (,)
let readStmt = readImport_ stmtSkipLines stmtDelim compiledOptions let readStmt = readImport_ stmtSkipLines stmtDelim compiledOptions
records <- L.sort . concat <$> mapErrorsIO readStmt paths records <- L.sort . concat <$> mapErrorsIO readStmt paths
m <- askDBState kmCurrency fromEither =<< runExceptT (matchRecords compiledMatches records)
fromEither $
flip runReader m $
runExceptT $
matchRecords compiledMatches records
where where
paths = (root </>) <$> stmtPaths paths = (root </>) <$> stmtPaths
@ -133,9 +82,9 @@ readImport_
-> m [TxRecord] -> m [TxRecord]
readImport_ n delim tns p = do readImport_ n delim tns p = do
res <- tryIO $ BL.readFile p res <- tryIO $ BL.readFile p
bs <- fromEither $ first (InsertException . (: []) . InsertIOError . showT) res bs <- fromEither $ first (AppException . (: []) . StatementIOError . tshow) res
case decodeByNameWithP (parseTxRecord p tns) opts $ skip bs of case decodeByNameWithP (parseTxRecord p tns) opts $ skip bs of
Left m -> throwIO $ InsertException [ParseError $ T.pack m] Left m -> throwIO $ AppException [ParseError $ T.pack m]
Right (_, v) -> return $ catMaybes $ V.toList v Right (_, v) -> return $ catMaybes $ V.toList v
where where
opts = defaultDecodeOptions {decDelimiter = fromIntegral delim} opts = defaultDecodeOptions {decDelimiter = fromIntegral delim}
@ -149,18 +98,18 @@ parseTxRecord p TxOpts {toDate, toAmountFmt, toDesc, toAmount, toOther, toDateFm
if d == "" if d == ""
then return Nothing then return Nothing
else do else do
a <- parseRational toAmountFmt =<< r .: T.encodeUtf8 toAmount a <- parseDecimal toAmountFmt =<< r .: T.encodeUtf8 toAmount
e <- r .: T.encodeUtf8 toDesc e <- r .: T.encodeUtf8 toDesc
os <- M.fromList <$> mapM (\n -> (n,) <$> r .: T.encodeUtf8 n) toOther os <- M.fromList <$> mapM (\n -> (n,) <$> r .: T.encodeUtf8 n) toOther
d' <- parseTimeM True defaultTimeLocale (T.unpack toDateFmt) d d' <- parseTimeM True defaultTimeLocale (T.unpack toDateFmt) d
return $ Just $ TxRecord d' a e os p return $ Just $ TxRecord d' a e os p
matchRecords :: [MatchRe] -> [TxRecord] -> InsertExceptT CurrencyM [BalTx] matchRecords :: MonadFinance m => [MatchRe] -> [TxRecord] -> AppExceptT m [Tx ()]
matchRecords ms rs = do matchRecords ms rs = do
(matched, unmatched, notfound) <- matchAll (matchPriorities ms) rs (matched, unmatched, notfound) <- matchAll (matchPriorities ms) rs
case (matched, unmatched, notfound) of case (matched, unmatched, notfound) of
(ms_, [], []) -> liftInner $ combineErrors $ fmap balanceTx ms_ (ms_, [], []) -> return ms_
(_, us, ns) -> throwError $ InsertException [StatementError us ns] (_, us, ns) -> throwError $ AppException [StatementError us ns]
matchPriorities :: [MatchRe] -> [MatchGroup] matchPriorities :: [MatchRe] -> [MatchGroup]
matchPriorities = matchPriorities =
@ -214,9 +163,10 @@ zipperSlice f x = go
LT -> z LT -> z
zipperMatch zipperMatch
:: Unzipped MatchRe :: MonadFinance m
=> Unzipped MatchRe
-> TxRecord -> TxRecord
-> InsertExceptT CurrencyM (Zipped MatchRe, MatchRes RawTx) -> AppExceptT m (Zipped MatchRe, MatchRes (Tx ()))
zipperMatch (Unzipped bs cs as) x = go [] cs zipperMatch (Unzipped bs cs as) x = go [] cs
where where
go _ [] = return (Zipped bs $ cs ++ as, MatchFail) go _ [] = return (Zipped bs $ cs ++ as, MatchFail)
@ -230,9 +180,10 @@ zipperMatch (Unzipped bs cs as) x = go [] cs
in return (Zipped bs $ ps ++ ms' ++ as, skipOrPass) in return (Zipped bs $ ps ++ ms' ++ as, skipOrPass)
zipperMatch' zipperMatch'
:: Zipped MatchRe :: MonadFinance m
=> Zipped MatchRe
-> TxRecord -> TxRecord
-> InsertExceptT CurrencyM (Zipped MatchRe, MatchRes RawTx) -> AppExceptT m (Zipped MatchRe, MatchRes (Tx ()))
zipperMatch' z x = go z zipperMatch' z x = go z
where where
go (Zipped bs (a : as)) = do go (Zipped bs (a : as)) = do
@ -249,7 +200,11 @@ matchDec m = case spTimes m of
Just n -> Just $ m {spTimes = Just $ n - 1} Just n -> Just $ m {spTimes = Just $ n - 1}
Nothing -> Just m Nothing -> Just m
matchAll :: [MatchGroup] -> [TxRecord] -> InsertExceptT CurrencyM ([RawTx], [TxRecord], [MatchRe]) matchAll
:: MonadFinance m
=> [MatchGroup]
-> [TxRecord]
-> AppExceptT m ([Tx ()], [TxRecord], [MatchRe])
matchAll = go ([], []) matchAll = go ([], [])
where where
go (matched, unused) gs rs = case (gs, rs) of go (matched, unused) gs rs = case (gs, rs) of
@ -259,13 +214,21 @@ matchAll = go ([], [])
(ts, unmatched, us) <- matchGroup g rs (ts, unmatched, us) <- matchGroup g rs
go (ts ++ matched, us ++ unused) gs' unmatched go (ts ++ matched, us ++ unused) gs' unmatched
matchGroup :: MatchGroup -> [TxRecord] -> InsertExceptT CurrencyM ([RawTx], [TxRecord], [MatchRe]) matchGroup
:: MonadFinance m
=> MatchGroup
-> [TxRecord]
-> AppExceptT m ([Tx ()], [TxRecord], [MatchRe])
matchGroup MatchGroup {mgDate = ds, mgNoDate = ns} rs = do matchGroup MatchGroup {mgDate = ds, mgNoDate = ns} rs = do
(md, rest, ud) <- matchDates ds rs (md, rest, ud) <- matchDates ds rs
(mn, unmatched, un) <- matchNonDates ns rest (mn, unmatched, un) <- matchNonDates ns rest
return (md ++ mn, unmatched, filter ((/= Nothing) . spTimes) $ ud ++ un) return (md ++ mn, unmatched, filter ((/= Nothing) . spTimes) $ ud ++ un)
matchDates :: [MatchRe] -> [TxRecord] -> InsertExceptT CurrencyM ([RawTx], [TxRecord], [MatchRe]) matchDates
:: MonadFinance m
=> [MatchRe]
-> [TxRecord]
-> AppExceptT m ([Tx ()], [TxRecord], [MatchRe])
matchDates ms = go ([], [], initZipper ms) matchDates ms = go ([], [], initZipper ms)
where where
go (matched, unmatched, z) [] = go (matched, unmatched, z) [] =
@ -286,7 +249,11 @@ matchDates ms = go ([], [], initZipper ms)
go (m, u, z') rs go (m, u, z') rs
findDate m r = maybe EQ (`compareDate` trDate r) $ spDate m findDate m r = maybe EQ (`compareDate` trDate r) $ spDate m
matchNonDates :: [MatchRe] -> [TxRecord] -> InsertExceptT CurrencyM ([RawTx], [TxRecord], [MatchRe]) matchNonDates
:: MonadFinance m
=> [MatchRe]
-> [TxRecord]
-> AppExceptT m ([Tx ()], [TxRecord], [MatchRe])
matchNonDates ms = go ([], [], initZipper ms) matchNonDates ms = go ([], [], initZipper ms)
where where
go (matched, unmatched, z) [] = go (matched, unmatched, z) [] =
@ -303,26 +270,246 @@ matchNonDates ms = go ([], [], initZipper ms)
MatchFail -> (matched, r : unmatched) MatchFail -> (matched, r : unmatched)
in go (m, u, resetZipper z') rs in go (m, u, resetZipper z') rs
balanceTx :: RawTx -> InsertExcept BalTx matches :: MonadFinance m => MatchRe -> TxRecord -> AppExceptT m (MatchRes (Tx ()))
balanceTx t@Tx {txEntries = ss} = do matches
bs <- balanceEntries ss StatementParser {spTx, spOther, spVal, spDate, spDesc, spPriority}
return $ t {txEntries = bs} r@TxRecord {trDate, trAmount, trDesc, trOther} = do
res <- liftInner $
balanceEntries :: [RawEntry] -> InsertExcept [BalEntry] combineError3 val other desc $
balanceEntries ss = \x y z -> x && y && z && date
fmap concat if res
<$> mapM (uncurry bal) then maybe (return MatchSkip) convert spTx
$ groupByKey else return MatchFail
$ fmap (\s -> (eCurrency s, s)) ss
where where
haeValue s@Entry {eValue = Just v} = Right s {eValue = v} val = valMatches spVal $ toRational trAmount
haeValue s = Left s date = maybe True (`dateMatches` trDate) spDate
bal cur rss other = foldM (\a o -> (a &&) <$> otherMatches trOther o) True spOther
| length rss < 2 = throwError $ InsertException [BalanceError TooFewEntries cur rss] desc = maybe (return True) (matchMaybe (unTxDesc trDesc) . snd) spDesc
| otherwise = case partitionEithers $ fmap haeValue rss of convert tg = MatchPass <$> toTx (fromIntegral spPriority) tg r
([noVal], val) -> return $ noVal {eValue = foldr (\s x -> x - eValue s) 0 val} : val
([], val) -> return val
_ -> throwError $ InsertException [BalanceError NotOneBlank cur rss]
groupByKey :: Ord k => [(k, v)] -> [(k, [v])] toTx :: MonadFinance m => Int -> TxGetter -> TxRecord -> AppExceptT m (Tx ())
groupByKey = M.toList . M.fromListWith (++) . fmap (second (: [])) toTx
priority
TxGetter
{ tgFrom
, tgTo
, tgCurrency
, tgOtherEntries
, tgScale
}
r@TxRecord {trAmount, trDate, trDesc} = do
combineError curRes subRes $ \(cur, f, t) ss ->
Tx
{ txDate = trDate
, txDescr = trDesc
, txCommit = ()
, txPrimary =
Left $
EntrySet
{ esTotalValue = roundToP (cpPrec cur) trAmount *. tgScale
, esCurrency = cpID cur
, esFrom = f
, esTo = t
}
, txOther = Left <$> ss
, txBudget = historyName
, txPriority = priority
}
where
curRes = do
m <- asks csCurrencyMap
cur <- liftInner $ resolveCurrency m r tgCurrency
let prec = cpPrec cur
let fromRes = liftInner $ resolveHalfEntry resolveFromValue prec r () tgFrom
let toRes = liftInner $ resolveHalfEntry resolveToValue prec r () tgTo
combineError fromRes toRes (cur,,)
subRes = mapErrors (resolveSubGetter r) tgOtherEntries
resolveSubGetter
:: MonadFinance m
=> TxRecord
-> TxSubGetter
-> AppExceptT m SecondayEntrySet
resolveSubGetter r TxSubGetter {tsgFrom, tsgTo, tsgValue, tsgCurrency} = do
m <- asks csCurrencyMap
cur <- liftInner $ resolveCurrency m r tsgCurrency
let prec = cpPrec cur
let toRes = resolveHalfEntry resolveToValue prec r () tsgTo
let valRes = liftInner $ resolveValue prec r tsgValue
liftInner $ combineErrorM toRes valRes $ \t v -> do
f <- resolveHalfEntry resolveFromValue prec r v tsgFrom
return $
EntrySet
{ esTotalValue = ()
, esCurrency = cpID cur
, esFrom = f
, esTo = t
}
resolveHalfEntry
:: (Precision -> TxRecord -> n -> AppExcept v')
-> Precision
-> TxRecord
-> v
-> TxHalfGetter (EntryGetter n)
-> AppExcept (HalfEntrySet v v')
resolveHalfEntry f prec r v TxHalfGetter {thgAcnt, thgComment, thgTags, thgEntries} =
combineError acntRes esRes $ \a es ->
HalfEntrySet
{ hesPrimary =
Entry
{ eAcnt = a
, eValue = v
, eComment = thgComment
, eTags = thgTags
}
, hesOther = es
}
where
acntRes = resolveAcnt r thgAcnt
esRes = mapErrors (resolveEntry f prec r) thgEntries
otherMatches :: M.Map T.Text T.Text -> FieldMatcherRe -> AppExcept Bool
otherMatches dict m = case m of
Val (Field n mv) -> valMatches mv =<< (readRational =<< lookup_ MatchNumeric n)
Desc (Field n (_, md)) -> (`matchMaybe` md) =<< lookup_ MatchText n
where
lookup_ t n = lookupErr (MatchField t) n dict
resolveEntry
:: (Precision -> TxRecord -> n -> AppExcept v)
-> Precision
-> TxRecord
-> EntryGetter n
-> AppExcept (Entry AcntID v TagID)
resolveEntry f prec r s@Entry {eAcnt, eValue} =
combineError acntRes valRes $ \a v -> s {eAcnt = a, eValue = v}
where
acntRes = resolveAcnt r eAcnt
valRes = f prec r eValue
resolveFromValue :: Precision -> TxRecord -> EntryNumGetter -> AppExcept EntryValue
resolveFromValue = resolveValue
resolveToValue :: Precision -> TxRecord -> LinkedEntryNumGetter -> AppExcept EntryLink
resolveToValue _ _ (Linked l) = return $ LinkIndex l
resolveToValue prec r (Getter g) = LinkValue <$> resolveValue prec r g
resolveValue :: Precision -> TxRecord -> EntryNumGetter -> AppExcept EntryValue
resolveValue prec TxRecord {trOther, trAmount} s = case s of
(LookupN t) -> EntryFixed . go <$> (readDouble =<< lookupErr EntryValField t trOther)
(ConstN c) -> return $ EntryFixed $ go c
AmountN m -> return $ EntryFixed $ trAmount *. m
BalanceN x -> return $ EntryBalance $ go x
PercentN x -> return $ EntryPercent x
where
go = realFracToDecimalP prec
resolveAcnt :: TxRecord -> EntryAcnt -> AppExcept AcntID
resolveAcnt r e = AcntID <$> resolveEntryField AcntField r (unAcntID <$> e)
resolveCurrency :: CurrencyMap -> TxRecord -> EntryCur -> AppExcept CurrencyPrec
resolveCurrency m r c = do
i <- resolveEntryField CurField r (unCurID <$> c)
case M.lookup (CurID i) m of
Just k -> return k
Nothing -> throwError $ AppException [LookupError (DBKey CurField) i]
resolveEntryField :: EntryIDType -> TxRecord -> EntryTextGetter T.Text -> AppExcept T.Text
resolveEntryField t TxRecord {trOther = o} s = case s of
ConstT p -> return p
LookupT f -> lookup_ f o
MapT (Field f m) -> do
k <- lookup_ f o
lookup_ k m
Map2T (Field (f1, f2) m) -> do
(k1, k2) <- combineError (lookup_ f1 o) (lookup_ f2 o) (,)
lookup_ (k1, k2) m
where
lookup_ :: (Ord k, Show k) => k -> M.Map k v -> AppExcept v
lookup_ = lookupErr (EntryIDField t)
readDouble :: T.Text -> AppExcept Double
readDouble s = case readMaybe $ T.unpack s of
Just x -> return x
Nothing -> throwError $ AppException [ConversionError s True]
readRational :: T.Text -> AppExcept Rational
readRational s = case T.split (== '.') s of
[x] -> maybe err (return . fromInteger) $ readT x
[x, y] -> case (readT x, readT y) of
(Just x', Just y') ->
let p = 10 ^ T.length y
k = if x' >= 0 then 1 else -1
in return $ fromInteger x' + k * y' % p
_ -> err
_ -> err
where
readT = readMaybe . T.unpack
err = throwError $ AppException [ConversionError s False]
compileOptions :: TxOpts T.Text -> AppExcept TxOptsRe
compileOptions o@TxOpts {toAmountFmt = pat} = do
re <- compileRegex True pat
return $ o {toAmountFmt = re}
compileMatch :: StatementParser T.Text -> AppExcept MatchRe
compileMatch m@StatementParser {spDesc, spOther} = do
combineError dres ores $ \d os -> m {spDesc = d, spOther = os}
where
go = compileRegex False
dres = mapM go spDesc
ores = combineErrors $ fmap (mapM go) spOther
compileRegex :: Bool -> T.Text -> AppExcept (Text, Regex)
compileRegex groups pat = case res of
Right re -> return (pat, re)
Left _ -> throwError $ AppException [RegexError pat]
where
res =
compile
(blankCompOpt {newSyntax = True})
(blankExecOpt {captureGroups = groups})
pat
matchMaybe :: T.Text -> Regex -> AppExcept Bool
matchMaybe q re = case execute re q of
Right res -> return $ isJust res
Left _ -> throwError $ AppException [RegexError "this should not happen"]
matchGroupsMaybe :: T.Text -> Regex -> [T.Text]
matchGroupsMaybe q re = case regexec re q of
Right Nothing -> []
Right (Just (_, _, _, xs)) -> xs
-- this should never fail as regexec always returns Right
Left _ -> []
parseDecimal :: MonadFail m => (T.Text, Regex) -> T.Text -> m Decimal
parseDecimal (pat, re) s = case matchGroupsMaybe s re of
[sign, x, ""] -> Decimal 0 . uncurry (*) <$> readWhole sign x
[sign, x, y] -> do
d <- readT "decimal" y
let p = T.length y
(k, w) <- readWhole sign x
return $ Decimal (fromIntegral p) (k * (w * (10 ^ p) + d))
_ -> msg "malformed decimal"
where
readT what t = case readMaybe $ T.unpack t of
Just d -> return $ fromInteger d
_ -> msg $ T.unwords ["could not parse", what, singleQuote t]
msg :: MonadFail m => T.Text -> m a
msg m =
fail $
T.unpack $
T.unwords [m, "-", keyVals [("pattern", pat), ("query", s)]]
readSign x
| x == "-" = return (-1)
| x == "+" || x == "" = return 1
| otherwise = msg $ T.append "invalid sign: " x
readWhole sign x = do
w <- readT "whole number" x
k <- readSign sign
return (k, w)
historyName :: BudgetName
historyName = BudgetName "history"

View File

@ -7,9 +7,12 @@
-- | Types corresponding to the database model -- | Types corresponding to the database model
module Internal.Types.Database where module Internal.Types.Database where
import Data.Csv (FromField)
import Database.Persist.Sql hiding (Desc, In, Statement) import Database.Persist.Sql hiding (Desc, In, Statement)
import Database.Persist.TH import Database.Persist.TH
import Internal.Types.Dhall
import RIO import RIO
import qualified RIO.NonEmpty as NE
import qualified RIO.Text as T import qualified RIO.Text as T
import RIO.Time import RIO.Time
@ -17,51 +20,94 @@ share
[mkPersist sqlSettings, mkMigrate "migrateAll"] [mkPersist sqlSettings, mkMigrate "migrateAll"]
[persistLowerCase| [persistLowerCase|
CommitR sql=commits CommitR sql=commits
hash Int hash CommitHash
type ConfigType type ConfigType
deriving Show Eq UniqueCommitHash hash
deriving Show Eq Ord
ConfigStateR sql=config_state
historySpan HistorySpan
budgetSpan BudgetSpan
deriving Show
CurrencyR sql=currencies CurrencyR sql=currencies
symbol T.Text symbol CurID
fullname T.Text fullname T.Text
precision Int precision Precision
deriving Show Eq UniqueCurrencySymbol symbol
UniqueCurrencyFullname fullname
deriving Show Eq Ord
TagR sql=tags TagR sql=tags
symbol T.Text symbol TagID
fullname T.Text fullname T.Text
deriving Show Eq UniqueTagSymbol symbol
UniqueTagFullname fullname
deriving Show Eq Ord
AccountR sql=accounts AccountR sql=accounts
name T.Text name T.Text
fullpath T.Text fullpath AcntPath
desc T.Text desc T.Text
deriving Show Eq sign AcntSign
leaf Bool
UniqueAccountFullpath fullpath
deriving Show Eq Ord
AccountPathR sql=account_paths AccountPathR sql=account_paths
parent AccountRId OnDeleteCascade parent AccountRId
child AccountRId OnDeleteCascade child AccountRId
depth Int depth Int
deriving Show Eq deriving Show Eq Ord
TransactionR sql=transactions TransactionR sql=transactions
commit CommitRId OnDeleteCascade commit CommitRId
date Day date Day
description T.Text description TxDesc
budgetName BudgetName
priority Int
deriving Show Eq
EntrySetR sql=entry_sets
transaction TransactionRId
currency CurrencyRId
index EntrySetIndex
rebalance Bool
deriving Show Eq deriving Show Eq
EntryR sql=entries EntryR sql=entries
transaction TransactionRId OnDeleteCascade entryset EntrySetRId
currency CurrencyRId OnDeleteCascade account AccountRId
account AccountRId OnDeleteCascade
memo T.Text memo T.Text
value Rational value Rational
index EntryIndex
cachedValue (Maybe Rational)
cachedType (Maybe TransferType)
cachedLink (Maybe EntryIndex)
deriving Show Eq deriving Show Eq
TagRelationR sql=tag_relations TagRelationR sql=tag_relations
entry EntryRId OnDeleteCascade entry EntryRId
tag TagRId OnDeleteCascade tag TagRId
BudgetLabelR sql=budget_labels
entry EntryRId OnDeleteCascade
budgetName T.Text
deriving Show Eq deriving Show Eq
|] |]
data ConfigType = CTBudget | CTManual | CTImport newtype EntrySetIndex = EntrySetIndex {unEntrySetIndex :: Int}
deriving (Eq, Show, Read, Enum) deriving newtype (Show, Eq, Ord, Num, Real, Enum, Integral, PersistField, PersistFieldSql)
newtype EntryIndex = EntryIndex {unEntryIndex :: Int}
deriving newtype (Show, Eq, Ord, Num, Real, Enum, Integral, PersistField, PersistFieldSql)
newtype TxDesc = TxDesc {unTxDesc :: T.Text}
deriving newtype (Show, Eq, Ord, PersistField, PersistFieldSql, FromField)
newtype Precision = Precision {unPrecision :: Word8}
deriving newtype (Eq, Ord, Num, Show, Real, Enum, Integral, PersistField, PersistFieldSql)
type DaySpan = (Day, Int)
newtype CommitHash = CommitHash {unCommitHash :: Int}
deriving newtype (Show, Eq, Num, Ord, PersistField, PersistFieldSql)
newtype BudgetSpan = BudgetSpan {unBSpan :: DaySpan}
deriving newtype (Show, Eq, PersistField, PersistFieldSql)
newtype HistorySpan = HistorySpan {unHSpan :: DaySpan}
deriving newtype (Show, Eq, PersistField, PersistFieldSql)
data ConfigType = CTBudget | CTHistoryTransfer | CTHistoryStatement
deriving (Eq, Show, Read, Enum, Ord)
instance PersistFieldSql ConfigType where instance PersistFieldSql ConfigType where
sqlType _ = SqlString sqlType _ = SqlString
@ -69,7 +115,61 @@ instance PersistFieldSql ConfigType where
instance PersistField ConfigType where instance PersistField ConfigType where
toPersistValue = PersistText . T.pack . show toPersistValue = PersistText . T.pack . show
-- TODO these error messages *might* be good enough?
fromPersistValue (PersistText v) = fromPersistValue (PersistText v) =
maybe (Left $ "could not parse: " <> v) Right $ readMaybe $ T.unpack v maybe (Left $ "could not parse: " <> v) Right $ readMaybe $ T.unpack v
fromPersistValue _ = Left "wrong type" fromPersistValue _ = Left "not a string"
data AcntSign = Credit | Debit
deriving (Show, Eq, Ord)
instance PersistFieldSql AcntSign where
sqlType _ = SqlInt64
instance PersistField AcntSign where
toPersistValue Debit = PersistInt64 1
toPersistValue Credit = PersistInt64 (-1)
fromPersistValue (PersistInt64 1) = Right Debit
fromPersistValue (PersistInt64 (-1)) = Right Credit
fromPersistValue (PersistInt64 v) = Left $ "could not convert to account sign: " <> tshow v
fromPersistValue _ = Left "not an Int64"
data AcntType
= AssetT
| EquityT
| ExpenseT
| IncomeT
| LiabilityT
deriving (Show, Eq, Ord, Hashable, Generic, Read)
atName :: AcntType -> T.Text
atName AssetT = "asset"
atName EquityT = "equity"
atName ExpenseT = "expense"
atName IncomeT = "income"
atName LiabilityT = "liability"
data AcntPath = AcntPath
{ apType :: !AcntType
, apChildren :: ![T.Text]
}
deriving (Eq, Ord, Show, Hashable, Generic, Read)
acntPath2Text :: AcntPath -> T.Text
acntPath2Text = T.intercalate "/" . NE.toList . acntPath2NonEmpty
acntPath2NonEmpty :: AcntPath -> NonEmpty T.Text
acntPath2NonEmpty (AcntPath t cs) = atName t :| cs
instance PersistFieldSql AcntPath where
sqlType _ = SqlString
instance PersistField AcntPath where
toPersistValue = PersistText . acntPath2Text
fromPersistValue (PersistText v) = case T.split (== '/') v of
[] -> Left "path is empty"
(x : xs) -> case readMaybe $ T.unpack x of
Just t -> Right $ AcntPath t xs
_ -> Left "could not get account type"
fromPersistValue _ = Left "not a string"

View File

@ -19,9 +19,9 @@ import Language.Haskell.TH.Syntax (Lift)
import RIO import RIO
import qualified RIO.Map as M import qualified RIO.Map as M
import qualified RIO.Text as T import qualified RIO.Text as T
import RIO.Time
import Text.Regex.TDFA import Text.Regex.TDFA
-- TODO find a way to conventiently make TaggedAcnt use my newtypes
makeHaskellTypesWith makeHaskellTypesWith
(defaultGenerateOptions {generateToDhallInstance = False, generateFromDhallInstance = False}) (defaultGenerateOptions {generateToDhallInstance = False, generateFromDhallInstance = False})
[ MultipleConstructors "SqlConfig" "(./dhall/Types.dhall).SqlConfig" [ MultipleConstructors "SqlConfig" "(./dhall/Types.dhall).SqlConfig"
@ -33,13 +33,14 @@ makeHaskellTypesWith
, MultipleConstructors "YMDMatcher" "(./dhall/Types.dhall).YMDMatcher" , MultipleConstructors "YMDMatcher" "(./dhall/Types.dhall).YMDMatcher"
, MultipleConstructors "DateMatcher" "(./dhall/Types.dhall).DateMatcher" , MultipleConstructors "DateMatcher" "(./dhall/Types.dhall).DateMatcher"
, MultipleConstructors "EntryNumGetter" "(./dhall/Types.dhall).EntryNumGetter" , MultipleConstructors "EntryNumGetter" "(./dhall/Types.dhall).EntryNumGetter"
, MultipleConstructors "BudgetCurrency" "(./dhall/Types.dhall).BudgetCurrency" , MultipleConstructors "LinkedEntryNumGetter" "(./dhall/Types.dhall).LinkedEntryNumGetter"
, MultipleConstructors "BudgetTransferType" "(./dhall/Types.dhall).BudgetTransferType" , MultipleConstructors "TransferType" "(./dhall/Types.dhall).TransferType"
, MultipleConstructors "TaxMethod" "(./dhall/Types.dhall).TaxMethod" , MultipleConstructors "TaxMethod" "(./dhall/Types.dhall).TaxMethod"
, MultipleConstructors "PeriodType" "(./dhall/Types.dhall).PeriodType" , MultipleConstructors "PeriodType" "(./dhall/Types.dhall).PeriodType"
, SingleConstructor "LinkedNumGetter" "LinkedNumGetter" "(./dhall/Types.dhall).LinkedNumGetter.Type"
, SingleConstructor "Currency" "Currency" "(./dhall/Types.dhall).Currency" , SingleConstructor "Currency" "Currency" "(./dhall/Types.dhall).Currency"
, SingleConstructor "Tag" "Tag" "(./dhall/Types.dhall).Tag" , SingleConstructor "Tag" "Tag" "(./dhall/Types.dhall).Tag"
, SingleConstructor "TaggedAcnt" "TaggedAcnt" "(./dhall/Types.dhall).TaggedAcnt" , SingleConstructor "TaggedAcnt" "TaggedAcnt" "(./dhall/Types.dhall).TaggedAcnt.Type"
, SingleConstructor "Gregorian" "Gregorian" "(./dhall/Types.dhall).Gregorian" , SingleConstructor "Gregorian" "Gregorian" "(./dhall/Types.dhall).Gregorian"
, SingleConstructor "GregorianM" "GregorianM" "(./dhall/Types.dhall).GregorianM" , SingleConstructor "GregorianM" "GregorianM" "(./dhall/Types.dhall).GregorianM"
, SingleConstructor "Interval" "Interval" "(./dhall/Types.dhall).Interval" , SingleConstructor "Interval" "Interval" "(./dhall/Types.dhall).Interval"
@ -48,12 +49,17 @@ makeHaskellTypesWith
, SingleConstructor "ModPat" "ModPat" "(./dhall/Types.dhall).ModPat.Type" , SingleConstructor "ModPat" "ModPat" "(./dhall/Types.dhall).ModPat.Type"
, SingleConstructor "CronPat" "CronPat" "(./dhall/Types.dhall).CronPat.Type" , SingleConstructor "CronPat" "CronPat" "(./dhall/Types.dhall).CronPat.Type"
, SingleConstructor "ValMatcher" "ValMatcher" "(./dhall/Types.dhall).ValMatcher.Type" , SingleConstructor "ValMatcher" "ValMatcher" "(./dhall/Types.dhall).ValMatcher.Type"
, SingleConstructor "Amount" "Amount" "(./dhall/Types.dhall).Amount" , SingleConstructor
"Amount"
"Amount"
"\\(w : Type) -> \\(v : Type) -> ((./dhall/Types.dhall).Amount w v).Type"
, SingleConstructor
"TxOpts"
"TxOpts"
"\\(re : Type) -> ((./dhall/Types.dhall).TxOpts_ re).Type"
, SingleConstructor "AcntSet" "AcntSet" "(./dhall/Types.dhall).AcntSet.Type" , SingleConstructor "AcntSet" "AcntSet" "(./dhall/Types.dhall).AcntSet.Type"
, SingleConstructor "TransferMatcher" "TransferMatcher" "(./dhall/Types.dhall).TransferMatcher.Type" , SingleConstructor "TransferMatcher" "TransferMatcher" "(./dhall/Types.dhall).TransferMatcher.Type"
, SingleConstructor "ShadowTransfer" "ShadowTransfer" "(./dhall/Types.dhall).ShadowTransfer" , SingleConstructor "ShadowTransfer" "ShadowTransfer" "(./dhall/Types.dhall).ShadowTransfer"
, -- , SingleConstructor "Income" "Income" "(./dhall/Types.dhall).Income.Type"
SingleConstructor "Exchange" "Exchange" "(./dhall/Types.dhall).Exchange"
, SingleConstructor "Field" "Field" "(./dhall/Types.dhall).Field" , SingleConstructor "Field" "Field" "(./dhall/Types.dhall).Field"
, SingleConstructor "Entry" "Entry" "(./dhall/Types.dhall).Entry" , SingleConstructor "Entry" "Entry" "(./dhall/Types.dhall).Entry"
, SingleConstructor "PretaxValue" "PretaxValue" "(./dhall/Types.dhall).PretaxValue" , SingleConstructor "PretaxValue" "PretaxValue" "(./dhall/Types.dhall).PretaxValue"
@ -61,14 +67,9 @@ makeHaskellTypesWith
, SingleConstructor "TaxProgression" "TaxProgression" "(./dhall/Types.dhall).TaxProgression" , SingleConstructor "TaxProgression" "TaxProgression" "(./dhall/Types.dhall).TaxProgression"
, SingleConstructor "TaxValue" "TaxValue" "(./dhall/Types.dhall).TaxValue" , SingleConstructor "TaxValue" "TaxValue" "(./dhall/Types.dhall).TaxValue"
, SingleConstructor "PosttaxValue" "PosttaxValue" "(./dhall/Types.dhall).PosttaxValue" , SingleConstructor "PosttaxValue" "PosttaxValue" "(./dhall/Types.dhall).PosttaxValue"
, SingleConstructor "BudgetTransferValue" "BudgetTransferValue" "(./dhall/Types.dhall).BudgetTransferValue" , SingleConstructor "TransferValue" "TransferValue" "(./dhall/Types.dhall).TransferValue.Type"
, SingleConstructor "Period" "Period" "(./dhall/Types.dhall).Period" , SingleConstructor "Period" "Period" "(./dhall/Types.dhall).Period"
, SingleConstructor "HourlyPeriod" "HourlyPeriod" "(./dhall/Types.dhall).HourlyPeriod" , SingleConstructor "HourlyPeriod" "HourlyPeriod" "(./dhall/Types.dhall).HourlyPeriod"
-- , SingleConstructor "ToTx" "ToTx" "(./dhall/Types.dhall).ToTx"
-- , SingleConstructor "FieldMatcher" "FieldMatcher" "(./dhall/Types.dhall).FieldMatcher_"
-- , SingleConstructor "Match" "Match" "(./dhall/Types.dhall).Match_"
-- , SingleConstructor "Budget" "Budget" "(./dhall/Types.dhall).Budget"
-- SingleConstructor "Transfer" "Transfer" "(./dhall/Types.dhall).Transfer"
] ]
deriveProduct deriveProduct
@ -95,9 +96,9 @@ deriveProduct
, "DateMatcher" , "DateMatcher"
, "ValMatcher" , "ValMatcher"
, "YMDMatcher" , "YMDMatcher"
, "BudgetCurrency"
, "Exchange"
, "EntryNumGetter" , "EntryNumGetter"
, "LinkedNumGetter"
, "LinkedEntryNumGetter"
, "TemporalScope" , "TemporalScope"
, "SqlConfig" , "SqlConfig"
, "PretaxValue" , "PretaxValue"
@ -106,8 +107,8 @@ deriveProduct
, "TaxProgression" , "TaxProgression"
, "TaxMethod" , "TaxMethod"
, "PosttaxValue" , "PosttaxValue"
, "BudgetTransferValue" , "TransferValue"
, "BudgetTransferType" , "TransferType"
, "Period" , "Period"
, "PeriodType" , "PeriodType"
, "HourlyPeriod" , "HourlyPeriod"
@ -178,22 +179,24 @@ deriving instance Ord DatePat
deriving instance Hashable DatePat deriving instance Hashable DatePat
type BudgetTransfer = type PairedTransfer = Transfer TaggedAcnt CurID DatePat TransferValue
Transfer TaggedAcnt BudgetCurrency DatePat BudgetTransferValue
deriving instance Hashable BudgetTransfer deriving instance Hashable PairedTransfer
deriving instance Generic BudgetTransfer deriving instance Generic PairedTransfer
deriving instance FromDhall BudgetTransfer deriving instance FromDhall PairedTransfer
newtype BudgetName = BudgetName {unBudgetName :: T.Text}
deriving newtype (Show, Eq, Ord, Hashable, FromDhall, PersistField, PersistFieldSql)
data Budget = Budget data Budget = Budget
{ bgtLabel :: Text { bgtLabel :: BudgetName
, bgtIncomes :: [Income] , bgtIncomes :: [Income]
, bgtPretax :: [MultiAllocation PretaxValue] , bgtPretax :: [MultiAllocation PretaxValue]
, bgtTax :: [MultiAllocation TaxValue] , bgtTax :: [MultiAllocation TaxValue]
, bgtPosttax :: [MultiAllocation PosttaxValue] , bgtPosttax :: [MultiAllocation PosttaxValue]
, bgtTransfers :: [BudgetTransfer] , bgtTransfers :: [PairedTransfer]
, bgtShadowTransfers :: [ShadowTransfer] , bgtShadowTransfers :: [ShadowTransfer]
, bgtInterval :: !(Maybe Interval) , bgtInterval :: !(Maybe Interval)
} }
@ -212,15 +215,28 @@ deriving instance Hashable PosttaxValue
deriving instance Hashable Budget deriving instance Hashable Budget
deriving instance Hashable BudgetTransferValue deriving instance Hashable TransferValue
deriving instance Hashable BudgetTransferType deriving instance Hashable TransferType
deriving instance Read TransferType
instance PersistFieldSql TransferType where
sqlType _ = SqlString
instance PersistField TransferType where
toPersistValue = PersistText . T.pack . show
fromPersistValue (PersistText v) =
maybe (Left $ "could not parse: " <> v) Right $ readMaybe $ T.unpack v
fromPersistValue _ = Left "wrong type"
deriving instance Hashable TaggedAcnt deriving instance Hashable TaggedAcnt
deriving instance Ord TaggedAcnt deriving instance Ord TaggedAcnt
type CurID = T.Text newtype CurID = CurID {unCurID :: T.Text}
deriving newtype (Eq, Show, Ord, Hashable, FromDhall, PersistField, PersistFieldSql)
data Income = Income data Income = Income
{ incGross :: Double { incGross :: Double
@ -232,6 +248,7 @@ data Income = Income
, incFrom :: TaggedAcnt , incFrom :: TaggedAcnt
, incToBal :: TaggedAcnt , incToBal :: TaggedAcnt
, incPayPeriod :: !Period , incPayPeriod :: !Period
, incPriority :: !Int
} }
deriving instance Hashable HourlyPeriod deriving instance Hashable HourlyPeriod
@ -250,20 +267,13 @@ deriving instance (FromDhall v, FromDhall w) => FromDhall (Amount w v)
deriving instance (Hashable v, Hashable w) => Hashable (Amount w v) deriving instance (Hashable v, Hashable w) => Hashable (Amount w v)
-- deriving instance (Generic w, Generic v, FromDhall w, FromDhall v) => FromDhall (Amount w v)
deriving instance (Show w, Show v) => Show (Amount w v) deriving instance (Show w, Show v) => Show (Amount w v)
deriving instance (Eq w, Eq v) => Eq (Amount w v) deriving instance (Eq w, Eq v) => Eq (Amount w v)
deriving instance Hashable Exchange
deriving instance Hashable BudgetCurrency
data Allocation w v = Allocation data Allocation w v = Allocation
{ alloTo :: TaggedAcnt { alloTo :: TaggedAcnt
, alloAmts :: [Amount w v] , alloAmts :: [Amount w v]
, alloCur :: CurID
} }
deriving (Eq, Show, Generic, Hashable) deriving (Eq, Show, Generic, Hashable)
@ -340,6 +350,10 @@ instance Ord DateMatcher where
deriving instance Hashable EntryNumGetter deriving instance Hashable EntryNumGetter
deriving instance Hashable LinkedNumGetter
deriving instance Hashable LinkedEntryNumGetter
------------------------------------------------------------------------------- -------------------------------------------------------------------------------
-- top level type with fixed account tree to unroll the recursion in the dhall -- top level type with fixed account tree to unroll the recursion in the dhall
-- account tree type -- account tree type
@ -362,7 +376,7 @@ data AccountRoot_ a = AccountRoot_
, arIncome :: ![a] , arIncome :: ![a]
, arLiabilities :: ![a] , arLiabilities :: ![a]
} }
deriving (Generic) deriving (Generic, Hashable)
type AccountRootF = AccountRoot_ (Fix AccountTreeF) type AccountRootF = AccountRoot_ (Fix AccountTreeF)
@ -371,10 +385,8 @@ deriving instance FromDhall AccountRootF
type AccountRoot = AccountRoot_ AccountTree type AccountRoot = AccountRoot_ AccountTree
data Config_ a = Config_ data Config_ a = Config_
{ global :: !TemporalScope { scope :: !TemporalScope
, budget :: ![Budget]
, currencies :: ![Currency] , currencies :: ![Currency]
, statements :: ![History]
, accounts :: !a , accounts :: !a
, tags :: ![Tag] , tags :: ![Tag]
, sqlConfig :: !SqlConfig , sqlConfig :: !SqlConfig
@ -404,55 +416,44 @@ instance FromDhall a => FromDhall (Config_ a)
-- dhall type overrides (since dhall can't import types with parameters...yet) -- dhall type overrides (since dhall can't import types with parameters...yet)
-- TODO newtypes for these? -- TODO newtypes for these?
type AcntID = T.Text newtype AcntID = AcntID {unAcntID :: T.Text}
deriving newtype (Eq, Show, Ord, Hashable, FromDhall, PersistField, PersistFieldSql)
type TagID = T.Text newtype TagID = TagID {unTagID :: T.Text}
deriving newtype (Eq, Show, Ord, Hashable, FromDhall, PersistField, PersistFieldSql)
type HistTransfer = Transfer AcntID CurID DatePat Double
deriving instance Generic HistTransfer
deriving instance Hashable HistTransfer
deriving instance FromDhall HistTransfer
data History data History
= HistTransfer !HistTransfer = HistTransfer !PairedTransfer
| HistStatement !Statement | HistStatement !Statement
deriving (Eq, Generic, Hashable, FromDhall) deriving (Eq, Generic, Hashable, FromDhall)
type EntryGetter = Entry EntryAcnt (Maybe EntryNumGetter) EntryCur TagID type EntryGetter n = Entry EntryAcnt n TagID
instance FromDhall EntryGetter type FromEntryGetter = EntryGetter EntryNumGetter
deriving instance (Show a, Show c, Show v, Show t) => Show (Entry a v c t) type ToEntryGetter = EntryGetter LinkedEntryNumGetter
deriving instance Generic (Entry a v c t) instance FromDhall FromEntryGetter
deriving instance (Hashable a, Hashable v, Hashable c, Hashable t) => Hashable (Entry a v c t) instance FromDhall ToEntryGetter
deriving instance (Eq a, Eq v, Eq c, Eq t) => Eq (Entry a v c t) deriving instance (Show a, Show v, Show t) => Show (Entry a v t)
data Tx s = Tx deriving instance Generic (Entry a v t)
{ txDescr :: !T.Text
, txDate :: !Day
, txEntries :: ![s]
}
deriving (Generic)
type ExpTx = Tx EntryGetter deriving instance (Hashable a, Hashable v, Hashable t) => Hashable (Entry a v t)
instance FromDhall ExpTx deriving instance (Eq a, Eq v, Eq t) => Eq (Entry a v t)
data TxOpts re = TxOpts deriving instance Eq a => Eq (TxOpts a)
{ toDate :: !T.Text
, toAmount :: !T.Text deriving instance Generic (TxOpts a)
, toDesc :: !T.Text
, toOther :: ![T.Text] deriving instance Hashable a => Hashable (TxOpts a)
, toDateFmt :: !T.Text
, toAmountFmt :: !re deriving instance FromDhall a => FromDhall (TxOpts a)
}
deriving (Eq, Generic, Hashable, Show, FromDhall) deriving instance Show a => Show (TxOpts a)
data Statement = Statement data Statement = Statement
{ stmtPaths :: ![FilePath] { stmtPaths :: ![FilePath]
@ -461,7 +462,7 @@ data Statement = Statement
, stmtTxOpts :: !(TxOpts T.Text) , stmtTxOpts :: !(TxOpts T.Text)
, stmtSkipLines :: !Natural , stmtSkipLines :: !Natural
} }
deriving (Eq, Hashable, Generic, FromDhall) deriving (Eq, Hashable, Generic, FromDhall, Show)
-- | the value of a field in entry (text version) -- | the value of a field in entry (text version)
-- can either be a raw (constant) value, a lookup from the record, or a map -- can either be a raw (constant) value, a lookup from the record, or a map
@ -471,7 +472,7 @@ data EntryTextGetter t
| LookupT !T.Text | LookupT !T.Text
| MapT !(FieldMap T.Text t) | MapT !(FieldMap T.Text t)
| Map2T !(FieldMap (T.Text, T.Text) t) | Map2T !(FieldMap (T.Text, T.Text) t)
deriving (Eq, Generic, Hashable, Show, FromDhall) deriving (Eq, Generic, Hashable, Show, FromDhall, Functor)
type EntryCur = EntryTextGetter CurID type EntryCur = EntryTextGetter CurID
@ -503,10 +504,32 @@ data FieldMatcher re
deriving instance Show (FieldMatcher T.Text) deriving instance Show (FieldMatcher T.Text)
data TxHalfGetter e = TxHalfGetter
{ thgAcnt :: !EntryAcnt
, thgComment :: !T.Text
, thgTags :: ![TagID]
, thgEntries :: ![e]
}
deriving (Eq, Generic, Hashable, Show)
deriving instance FromDhall (TxHalfGetter FromEntryGetter)
deriving instance FromDhall (TxHalfGetter ToEntryGetter)
data TxSubGetter = TxSubGetter
{ tsgFrom :: !(TxHalfGetter FromEntryGetter)
, tsgTo :: !(TxHalfGetter ToEntryGetter)
, tsgValue :: !EntryNumGetter
, tsgCurrency :: !EntryCur
}
deriving (Eq, Generic, Hashable, Show, FromDhall)
data TxGetter = TxGetter data TxGetter = TxGetter
{ tgCurrency :: !EntryCur { tgFrom :: !(TxHalfGetter FromEntryGetter)
, tgAcnt :: !EntryAcnt , tgTo :: !(TxHalfGetter ToEntryGetter)
, tgEntries :: ![EntryGetter] , tgCurrency :: !EntryCur
, tgOtherEntries :: ![TxSubGetter]
, tgScale :: !Double
} }
deriving (Eq, Generic, Hashable, Show, FromDhall) deriving (Eq, Generic, Hashable, Show, FromDhall)

View File

@ -1,4 +1,3 @@
{-# LANGUAGE DeriveAnyClass #-}
{-# LANGUAGE DerivingVia #-} {-# LANGUAGE DerivingVia #-}
{-# LANGUAGE UndecidableInstances #-} {-# LANGUAGE UndecidableInstances #-}
@ -12,11 +11,11 @@ module Internal.Types.Main
where where
import Control.Monad.Except import Control.Monad.Except
import Data.Decimal
import Database.Persist.Sql hiding (Desc, In, Statement) import Database.Persist.Sql hiding (Desc, In, Statement)
import Dhall hiding (embed, maybe) import Dhall hiding (embed, maybe)
import Internal.Types.Database import Internal.Types.Database
import Internal.Types.Dhall import Internal.Types.Dhall
import Language.Haskell.TH.Syntax (Lift)
import RIO import RIO
import qualified RIO.Map as M import qualified RIO.Map as M
import qualified RIO.NonEmpty as NE import qualified RIO.NonEmpty as NE
@ -27,99 +26,139 @@ import Text.Regex.TDFA
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------
-- database cache types -- database cache types
data ConfigHashes = ConfigHashes type MonadFinance = MonadReader ConfigState
{ chIncome :: ![Int]
, chExpense :: ![Int] data DeleteTxs = DeleteTxs
, chManual :: ![Int] { dtTxs :: ![TransactionRId]
, chImport :: ![Int] , dtEntrySets :: ![EntrySetRId]
, dtEntries :: ![EntryRId]
, dtTagRelations :: ![TagRelationRId]
}
deriving (Show)
type CDOps c d = CRUDOps [c] () () [d]
-- TODO split the entry stuff from the account metadata stuff
data ConfigState = ConfigState
{ csCurrencies :: !(CDOps (Entity CurrencyR) CurrencyRId)
, csAccounts :: !(CDOps (Entity AccountR) AccountRId)
, csPaths :: !(CDOps (Entity AccountPathR) AccountPathRId)
, csTags :: !(CDOps (Entity TagR) TagRId)
, csBudgets :: !(CRUDOps [Budget] [ReadEntry] [Either TotalUpdateEntrySet FullUpdateEntrySet] DeleteTxs)
, csHistTrans :: !(CRUDOps [PairedTransfer] [ReadEntry] [Either TotalUpdateEntrySet FullUpdateEntrySet] DeleteTxs)
, csHistStmts :: !(CRUDOps [Statement] [ReadEntry] [Either TotalUpdateEntrySet FullUpdateEntrySet] DeleteTxs)
, csAccountMap :: !AccountMap
, csCurrencyMap :: !CurrencyMap
, csTagMap :: !TagMap
, csBudgetScope :: !BudgetSpan
, csHistoryScope :: !HistorySpan
}
deriving (Show)
data ExistingConfig = ExistingConfig
{ ecAccounts :: !(Set AccountRId)
, ecTags :: !(Set TagRId)
, ecCurrencies :: !(Set CurrencyRId)
} }
type AccountMap = M.Map AcntID (AccountRId, AcntSign, AcntType) type AccountMap = M.Map AcntID (AccountRId, AcntType)
type CurrencyMap = M.Map CurID (CurrencyRId, Natural) data CurrencyPrec = CurrencyPrec {cpID :: !CurrencyRId, cpPrec :: !Precision}
deriving (Show)
type CurrencyMap = M.Map CurID CurrencyPrec
type TagMap = M.Map TagID TagRId type TagMap = M.Map TagID TagRId
data DBState = DBState data CRUDOps c r u d = CRUDOps
{ kmCurrency :: !CurrencyMap { coCreate :: !c
, kmAccount :: !AccountMap , coRead :: !r
, kmTag :: !TagMap , coUpdate :: !u
, kmBudgetInterval :: !DaySpan , coDelete :: !d
, kmStatementInterval :: !DaySpan
, kmNewCommits :: ![Int]
} }
deriving (Show)
data DBUpdates = DBUpdates data CachedEntry
{ duOldCommits :: ![Int] = CachedLink EntryIndex LinkScale
, duNewTagIds :: ![Entity TagR] | CachedBalance Decimal
, duNewAcntPaths :: ![AccountPathR] | CachedPercent Double
, duNewAcntIds :: ![Entity AccountR]
, duNewCurrencyIds :: ![Entity CurrencyR] data ReadEntry = ReadEntry
{ reCurrency :: !CurrencyRId
, reAcnt :: !AccountRId
, reValue :: !Decimal
, reDate :: !Day
, rePriority :: !Int
, reBudget :: !BudgetName
} }
deriving (Show)
type CurrencyM = Reader CurrencyMap data UpdateEntry i v = UpdateEntry
{ ueID :: !i
, ueAcnt :: !AccountRId
, ueValue :: !v
, ueIndex :: !EntryIndex
}
deriving (Show)
type KeyEntry = Entry AccountRId Rational CurrencyRId TagRId deriving instance Functor (UpdateEntry i)
type KeyTx = Tx KeyEntry newtype LinkScale = LinkScale {unLinkScale :: Double}
deriving newtype (Num, Show, Eq, Ord, Real, Fractional)
type TreeR = Tree ([T.Text], AccountRId) newtype StaticValue = StaticValue {unStaticValue :: Decimal}
deriving newtype (Num, Show)
type MonadFinance = MonadReader DBState data EntryValueUnk = EVBalance Decimal | EVPercent Double deriving (Show)
askDBState :: MonadFinance m => (DBState -> a) -> m a type UEUnk = UpdateEntry EntryRId EntryValueUnk
askDBState = asks
type UELink = UpdateEntry EntryRId LinkScale
type UEBlank = UpdateEntry EntryRId ()
type UE_RO = UpdateEntry () StaticValue
type UEBalanced = UpdateEntry EntryRId StaticValue
data UpdateEntrySet f t = UpdateEntrySet
{ utFrom0 :: !f
, utTo0 :: !UEBlank
, utFromUnk :: ![(UEUnk, [UELink])]
, utToUnk :: ![UEUnk]
, utFromRO :: ![UE_RO]
, utToRO :: ![UE_RO]
, utCurrency :: !CurrencyRId
, utDate :: !Day
, utTotalValue :: !t
, utBudget :: !BudgetName
, utPriority :: !Int
}
deriving (Show)
type TotalUpdateEntrySet = UpdateEntrySet (UEBlank, [UELink]) Decimal
type FullUpdateEntrySet = UpdateEntrySet (Either UE_RO (UEUnk, [UELink])) ()
data EntryCRU
= ToUpdate (Either TotalUpdateEntrySet FullUpdateEntrySet)
| ToRead ReadEntry
| ToInsert (Tx CommitR)
------------------------------------------------------------------------------- -------------------------------------------------------------------------------
-- misc -- misc
data AcntType
= AssetT
| EquityT
| ExpenseT
| IncomeT
| LiabilityT
deriving (Show, Eq, Ord, Lift, Hashable, Generic, Read, FromDhall)
atName :: AcntType -> T.Text
atName AssetT = "asset"
atName EquityT = "equity"
atName ExpenseT = "expense"
atName IncomeT = "income"
atName LiabilityT = "liability"
data AcntPath = AcntPath
{ apType :: !AcntType
, apChildren :: ![T.Text]
}
deriving (Eq, Ord, Show, Lift, Hashable, Generic, Read, FromDhall)
data TxRecord = TxRecord data TxRecord = TxRecord
{ trDate :: !Day { trDate :: !Day
, trAmount :: !Rational , trAmount :: !Decimal
, trDesc :: !T.Text , trDesc :: !TxDesc
, trOther :: !(M.Map T.Text T.Text) , trOther :: !(M.Map T.Text T.Text)
, trFile :: !FilePath , trFile :: !FilePath
} }
deriving (Show, Eq, Ord) deriving (Show, Eq, Ord)
type DaySpan = (Day, Natural)
data Keyed a = Keyed
{ kKey :: !Int64
, kVal :: !a
}
deriving (Eq, Show, Functor)
data Tree a = Branch !a ![Tree a] | Leaf !a deriving (Show) data Tree a = Branch !a ![Tree a] | Leaf !a deriving (Show)
data AcntSign = Credit | Debit
deriving (Show)
sign2Int :: AcntSign -> Int
sign2Int Debit = 1
sign2Int Credit = 1
accountSign :: AcntType -> AcntSign accountSign :: AcntType -> AcntSign
accountSign AssetT = Debit accountSign AssetT = Debit
accountSign ExpenseT = Debit accountSign ExpenseT = Debit
@ -127,21 +166,81 @@ accountSign IncomeT = Credit
accountSign LiabilityT = Credit accountSign LiabilityT = Credit
accountSign EquityT = Credit accountSign EquityT = Credit
type RawEntry = Entry AcntID (Maybe Rational) CurID TagID data HalfEntrySet v0 vN = HalfEntrySet
{ hesPrimary :: !(Entry AcntID v0 TagID)
, hesOther :: ![Entry AcntID vN TagID]
}
deriving (Show)
type BalEntry = Entry AcntID Rational CurID TagID data EntrySet v0 vp0 vpN vtN = EntrySet
{ esTotalValue :: !v0
, esCurrency :: !CurrencyRId
, esFrom :: !(HalfEntrySet vp0 vpN)
, esTo :: !(HalfEntrySet () vtN)
}
deriving (Show)
type RawTx = Tx RawEntry type TotalEntrySet v0 vpN vtN = EntrySet v0 () vpN vtN
type BalTx = Tx BalEntry type FullEntrySet vp0 vpN vtN = EntrySet () vp0 vpN vtN
type PrimaryEntrySet = TotalEntrySet Decimal EntryValue EntryLink
type SecondayEntrySet = FullEntrySet EntryValue EntryValue EntryLink
type TransferEntrySet = SecondayEntrySet
type ShadowEntrySet = TotalEntrySet Double EntryValue EntryLink
data TxCommit = HistoryCommit CommitR | BudgetCommit CommitR T.Text
deriving (Eq, Ord, Show)
data Tx k = Tx
{ txDescr :: !TxDesc
, txDate :: !Day
, txPriority :: !Int
, txPrimary :: !(Either PrimaryEntrySet TransferEntrySet)
, txOther :: ![Either SecondayEntrySet ShadowEntrySet]
, txCommit :: !k
, txBudget :: !BudgetName
}
deriving (Generic, Show)
data InsertEntry = InsertEntry
{ ieCached :: !(Maybe CachedEntry)
, ieEntry :: !(Entry AccountRId Decimal TagRId)
}
data InsertEntrySet = InsertEntrySet
{ iesCurrency :: !CurrencyRId
, iesFromEntries :: !(NonEmpty InsertEntry)
, iesToEntries :: !(NonEmpty InsertEntry)
}
data InsertTx = InsertTx
{ itxDescr :: !TxDesc
, itxDate :: !Day
, itxPriority :: !Int
, itxEntrySets :: !(NonEmpty InsertEntrySet)
, itxCommit :: !CommitR
, itxBudget :: !BudgetName
}
deriving (Generic)
data EntryValue_ a = EntryValue_ TransferType a
deriving (Show, Functor, Foldable, Traversable)
data EntryValue = EntryFixed Decimal | EntryPercent Double | EntryBalance Decimal
deriving (Show, Eq, Ord)
data EntryLink = LinkValue EntryValue | LinkIndex LinkedNumGetter
deriving (Show)
data MatchRes a = MatchPass !a | MatchFail | MatchSkip data MatchRes a = MatchPass !a | MatchFail | MatchSkip
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------
-- exception types -- exception types
data BalanceType = TooFewEntries | NotOneBlank deriving (Show)
data MatchType = MatchNumeric | MatchText deriving (Show) data MatchType = MatchNumeric | MatchText deriving (Show)
data EntryIDType = AcntField | CurField | TagField deriving (Show) data EntryIDType = AcntField | CurField | TagField deriving (Show)
@ -153,48 +252,49 @@ data LookupSuberr
| DBKey !EntryIDType | DBKey !EntryIDType
deriving (Show) deriving (Show)
data AllocationSuberr
= NoAllocations
| ExceededTotal
| MissingBlank
| TooManyBlanks
deriving (Show)
data PatternSuberr = ZeroLength | ZeroRepeats deriving (Show) data PatternSuberr = ZeroLength | ZeroRepeats deriving (Show)
data InsertError data DBLinkSubError
= DBLinkNoScale
| DBLinkNoValue
| DBLinkInvalidValue !Rational !Bool
| DBLinkInvalidBalance
| DBLinkInvalidPercent
deriving (Show)
data DBSubError
= DBShouldBeEmpty
| DBMultiScope
| DBUpdateUnbalanced
| DBLinkError !EntryRId !DBLinkSubError
deriving (Show)
data AppError
= RegexError !T.Text = RegexError !T.Text
| MatchValPrecisionError !Natural !Natural | MatchValPrecisionError !Natural !Natural
| AccountError !AcntID !(NE.NonEmpty AcntType) | AccountTypeError !AcntID !(NE.NonEmpty AcntType)
| InsertIOError !T.Text | StatementIOError !T.Text
| ParseError !T.Text | ParseError !T.Text
| ConversionError !T.Text | ConversionError !T.Text !Bool
| LookupError !LookupSuberr !T.Text | LookupError !LookupSuberr !T.Text
| BalanceError !BalanceType !CurID ![RawEntry] | DatePatternError !Natural !Natural !(Maybe Natural) !PatternSuberr
| IncomeError !Day !T.Text !Rational
| PatternError !Natural !Natural !(Maybe Natural) !PatternSuberr
| DaySpanError !Gregorian !(Maybe Gregorian) | DaySpanError !Gregorian !(Maybe Gregorian)
| StatementError ![TxRecord] ![MatchRe] | StatementError ![TxRecord] ![MatchRe]
| PeriodError !Day !Day | PeriodError !Day !Day
| LinkError !EntryIndex !EntryIndex
| DBError !DBSubError
deriving (Show) deriving (Show)
newtype InsertException = InsertException [InsertError] newtype AppException = AppException [AppError]
deriving (Show, Semigroup) via [InsertError] deriving (Show, Semigroup) via [AppError]
instance Exception InsertException instance Exception AppException
type MonadInsertError = MonadError InsertException type MonadAppError = MonadError AppException
type InsertExceptT = ExceptT InsertException type AppExceptT = ExceptT AppException
type InsertExcept = InsertExceptT Identity type AppExcept = AppExceptT Identity
data XGregorian = XGregorian
{ xgYear :: !Int
, xgMonth :: !Int
, xgDay :: !Int
, xgDayOfWeek :: !Int
}
type MatchRe = StatementParser (T.Text, Regex) type MatchRe = StatementParser (T.Text, Regex)

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@ -87,6 +87,7 @@ dependencies:
- filepath - filepath
- mtl - mtl
- persistent-mtl >= 0.3.0.0 - persistent-mtl >= 0.3.0.0
- Decimal >= 0.5.2
library: library:
source-dirs: lib/ source-dirs: lib/