dataframe-1.0.0.0: src/DataFrame/Lazy/Internal/DataFrame.hs
{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE GADTs #-}
{-# LANGUAGE NumericUnderscores #-}
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE ScopedTypeVariables #-}
module DataFrame.Lazy.Internal.DataFrame where
import qualified Data.Text as T
import qualified DataFrame.Internal.Column as C
import qualified DataFrame.Internal.DataFrame as D
import qualified DataFrame.Internal.Expression as E
import DataFrame.Internal.Schema (Schema)
import DataFrame.Lazy.Internal.Executor (
ExecutorConfig (..),
defaultExecutorConfig,
execute,
)
import DataFrame.Lazy.Internal.LogicalPlan (
DataSource (..),
LogicalPlan (..),
SortOrder (..),
)
import qualified DataFrame.Lazy.Internal.Optimizer as Opt
import DataFrame.Operations.Join (JoinType)
{- | A lazy query that has not been executed yet.
The query is represented as a 'LogicalPlan' tree; execution is deferred
until 'runDataFrame' is called.
-}
data LazyDataFrame = LazyDataFrame
{ plan :: LogicalPlan
, batchSize :: Int
}
instance Show LazyDataFrame where
show ldf =
"LazyDataFrame { batchSize = "
<> (show (batchSize ldf) <> (", plan = " <> (show (plan ldf) <> " }")))
-- ---------------------------------------------------------------------------
-- Entry point
-- ---------------------------------------------------------------------------
{- | Execute the lazy query: optimise the logical plan, then stream-execute
the resulting physical plan, returning a fully-materialised 'D.DataFrame'.
-}
runDataFrame :: LazyDataFrame -> IO D.DataFrame
runDataFrame ldf = do
let physPlan = Opt.optimize (batchSize ldf) (plan ldf)
execute physPlan defaultExecutorConfig{defaultBatchSize = batchSize ldf}
-- ---------------------------------------------------------------------------
-- Builders that construct the logical plan tree
-- ---------------------------------------------------------------------------
-- | Lift an already-loaded eager 'D.DataFrame' into the lazy plan.
fromDataFrame :: D.DataFrame -> LazyDataFrame
fromDataFrame df = LazyDataFrame{plan = SourceDF df, batchSize = 1_000_000}
-- | Scan a CSV file with the default comma separator.
scanCsv :: Schema -> T.Text -> LazyDataFrame
scanCsv schema path =
LazyDataFrame
{ plan = Scan (CsvSource (T.unpack path) ',') schema
, batchSize = 1_000_000
}
-- | Scan a character-separated file.
scanSeparated :: Char -> Schema -> T.Text -> LazyDataFrame
scanSeparated sep schema path =
LazyDataFrame
{ plan = Scan (CsvSource (T.unpack path) sep) schema
, batchSize = 1_000_000
}
-- | Scan a Parquet file, directory of files, or glob pattern.
scanParquet :: Schema -> T.Text -> LazyDataFrame
scanParquet schema path =
LazyDataFrame
{ plan = Scan (ParquetSource (T.unpack path)) schema
, batchSize = 1_000_000
}
-- | Add a computed column (or overwrite an existing one).
derive ::
(C.Columnable a) => T.Text -> E.Expr a -> LazyDataFrame -> LazyDataFrame
derive name expr ldf =
ldf{plan = Derive name (E.UExpr expr) (plan ldf)}
-- | Retain only the listed columns.
select :: [T.Text] -> LazyDataFrame -> LazyDataFrame
select cols ldf = ldf{plan = Project cols (plan ldf)}
-- | Keep rows that satisfy the predicate.
filter :: E.Expr Bool -> LazyDataFrame -> LazyDataFrame
filter cond ldf = ldf{plan = Filter cond (plan ldf)}
-- | Join two lazy queries on the given key columns.
join ::
JoinType ->
-- | Left join key column name
T.Text ->
-- | Right join key column name
T.Text ->
-- | Left sub-query
LazyDataFrame ->
-- | Right sub-query
LazyDataFrame ->
LazyDataFrame
join jt leftKey rightKey left right =
LazyDataFrame
{ plan = Join jt leftKey rightKey (plan left) (plan right)
, batchSize = batchSize left
}
{- | Group by a set of columns and compute aggregate expressions.
Each aggregate expression should use an 'Agg' node (e.g. @sumOf@, @meanOf@).
-}
groupBy ::
-- | Group-by key columns
[T.Text] ->
-- | @[(outputName, aggregateExpr)]@
[(T.Text, E.UExpr)] ->
LazyDataFrame ->
LazyDataFrame
groupBy keys aggs ldf = ldf{plan = Aggregate keys aggs (plan ldf)}
-- | Sort the result by the given @(column, direction)@ pairs.
sortBy :: [(T.Text, SortOrder)] -> LazyDataFrame -> LazyDataFrame
sortBy cols ldf = ldf{plan = Sort cols (plan ldf)}
-- | Retain at most @n@ rows.
take :: Int -> LazyDataFrame -> LazyDataFrame
take n ldf = ldf{plan = Limit n (plan ldf)}