streamly-core-0.3.0: src/Streamly/Data/Parser.hs
{-# LANGUAGE CPP #-}
-- |
-- Module : Streamly.Data.Parser
-- Copyright : (c) 2020 Composewell Technologies
-- License : BSD-3-Clause
-- Maintainer : streamly@composewell.com
-- Stability : pre-release
-- Portability : GHC
--
-- Parsers are more powerful but less general than 'Streamly.Data.Fold.Fold's:
--
-- * folds cannot fail but parsers can fail and backtrack.
-- * folds can be composed as a Tee but parsers cannot.
-- * folds can be converted to parsers.
--
-- Streamly parsers support all operations offered by popular Haskell parser
-- libraries. Unlike other parser libraries, (1) streamly parsers can operate
-- on any Haskell type as input - not just bytes, (2) natively support
-- streaming, (3) and are faster.
--
-- == High Performance by Static Parser Fusion
--
-- Like folds, parsers are designed to utilize stream fusion, compiling to
-- efficient low-level code comparable to the speed of C. Parsers are suitable
-- for high-performance parsing of streams.
--
-- Operations in this module are designed to be composed statically rather than
-- dynamically. They are inlined to enable static fusion. More importantly,
-- they are not designed to be used recursively. Recursive use will break
-- fusion and lead to quadratic performance slowdown. For dynamic and
-- recursive compositions use the continuation passing style (CPS) operations
-- from the "Streamly.Data.ParserK" module. 'Parser' and
-- 'Streamly.Data.ParserK.ParserK' types are interconvertible.
--
-- == How to parse a stream?
--
-- Parser combinators can be used to create a pipeline of parsers such
-- that the next parser consumes the result of the previous parser.
-- Such a composed pipeline of parsers can then be driven by one of many parser
-- drivers available in the Stream and Array modules.
--
-- Use Streamly.Data.Stream.'Streamly.Data.Stream.parse' or
-- Streamly.Data.Stream.'Streamly.Data.Stream.parseBreak' to run a parser on an
-- input stream and return the parsed result.
--
-- Use Streamly.Data.Stream.'Streamly.Data.Stream.parseMany' or
-- Streamly.Data.Stream.'Streamly.Data.Stream.parseIterate' to transform an
-- input data stream to an output stream of parsed data elements using a
-- parser.
--
-- == Parser vs ParserK
--
-- There are two functionally equivalent parsing modules,
-- "Streamly.Data.Parser" (this module) and "Streamly.Data.ParserK". The latter
-- is a CPS based wrapper over the former, and can be used for parsing in
-- general. "Streamly.Data.Parser" enables stream fusion and where possible it should be
-- preferred over "Streamly.Data.ParserK" for high performance stream parsing
-- use cases. However, there are a few cases where this module is not
-- suitable and ParserK should be used instead. As a thumb rule, when recursion
-- or heavy nesting is needed use ParserK.
--
-- === Parser: suitable for non-recursive static fusion
--
-- The 'Parser' type is suitable only for non-recursive static fusion. It could
-- be problematic for recursive definitions. To enable static fusion, parser
-- combinators use strict pattern matching on arguments of type Parser. This
-- leads to infinte loop when a parser is defined recursively, due to strict
-- evaluation of the recursive call. For example, the following implementation
-- loops infinitely because of the recursive use of parser @p@ in the @*>@
-- combinator:
--
-- >>> import Streamly.Data.Parser (Parser)
-- >>> import qualified Streamly.Data.Fold as Fold
-- >>> import qualified Streamly.Data.Parser as Parser
-- >>> import qualified Streamly.Data.Stream as Stream
-- >>> import Control.Applicative ((<|>))
--
-- >>> :{
-- >>> p, p1, p2 :: Monad m => Parser Char m String
-- >>> p1 = Parser.satisfy (== '(') *> p
-- >>> p2 = Parser.fromFold Fold.toList
-- >>> p = p1 <|> p2
-- >>> :}
--
-- Another limitation of Parser type quadratic performance slowdown when too
-- many nested compositions are used. Especially Applicative, Monad,
-- Alternative instances, and sequenced parsing operations (e.g. nested 'one',
-- and 'splitWith') exhibit quadratic slowdown (O(n^2) complexity) when
-- combined @n@ times, roughly 8 or less sequenced parsers usually work fine.
-- READ THE DOCS OF APPLICATIVE, MONAD AND ALTERNATIVE INSTANCES.
--
-- === ParserK: suitable for recursive definitions
--
-- ParserK is suitable for recursive definitions:
--
-- >>> import Streamly.Data.ParserK (ParserK)
-- >>> import Streamly.Data.StreamK (toParserK)
-- >>> import qualified Streamly.Data.StreamK as StreamK
--
-- >>> :{
-- >>> p, p1, p2 :: Monad m => ParserK Char m String
-- >>> p1 = toParserK (Parser.satisfy (== '(')) *> p
-- >>> p2 = toParserK (Parser.fromFold Fold.toList)
-- >>> p = p1 <|> p2
-- >>> :}
--
-- >>> StreamK.parse p $ StreamK.fromStream $ Stream.fromList "hello"
-- Right "hello"
--
-- For this reason Applicative, Alternative or Monad compositions with
-- recursion cannot be used with the 'Parser' type. Alternative type class based
-- operations like 'asum' and Alternative based generic parser combinators use
-- recursion. Similarly, Applicative type class based operations like
-- 'Prelude.sequence' use recursion. Custom implementations of many such
-- operations are provided in this module (e.g. 'some', 'many'), and those
-- should be used instead.
--
-- == Parsers Galore!
--
-- Streamly provides all the parsing functionality provided by popular parsing
-- libraries, and much more with higher performance.
-- This module provides most of the elementary parsers and parser combinators.
-- Additionally,
--
-- * all the folds from the "Streamly.Data.Fold" module can be converted to
-- parsers using 'fromFold'.
-- * "Streamly.Unicode.Parser" module provides Char stream parsers.
-- * all the combinators from the
-- <https://hackage.haskell.org/package/parser-combinators parser-combinators>
-- package can be used with streamly ParserK.
-- * See "Streamly.Internal.Data.Parser" for many more unreleased but useful APIs.
--
-- == Generic Parser Combinators
--
-- With 'Streamly.Data.ParserK.ParserK' you can use the 'Applicative' and
-- 'Control.Applicative.Alternative' type class based generic parser
-- combinators from the
-- <https://hackage.haskell.org/package/parser-combinators parser-combinators>
-- library or similar. However, if available, we recommend that you use the
-- equivalent functionality from this module where performance and streaming
-- behavior matters.
-- Firstly, the combinators in this module are faster due to stream fusion.
-- Secondly, these are streaming in nature as the results can be passed
-- directly to other stream consumers (folds or parsers). The Alternative type
-- class based parsers would end up buffering all the results in lists before
-- they can be consumed.
--
-- == Error Reporting
--
-- There are two types of parser drivers available, @parse@ and @parseBreak@
-- drivers do not track stream position, whereas @parsePos@ and @parseBreakPos@
-- drivers track and report stream position information with slightly more
-- performance overhead.
--
-- When an error occurs the stream position is reported, in case of byte streams
-- or unboxed array streams this is the byte position, in case of generic
-- element parsers or generic array parsers this is the element position in the
-- stream.
--
-- These parsers do not report a case specific error context (e.g. line number
-- or column). If you need line number or column information you can read the
-- stream again (if it is immutable) and this count the lines to translate the
-- reported byte position to line number and column. More elaborate support for
-- building arbitrary and custom error context information is planned to be
-- added in future.
--
-- == Monad Transformer Stack
--
-- 'MonadTrans' instance is not provided. If the 'Parser' type is the top most
-- layer (which should be the case almost always) you can just use 'fromEffect'
-- to execute the lower layer monad effects.
--
-- == Experimental APIs
--
-- Please refer to "Streamly.Internal.Data.Parser" for functions that have not
-- yet been released.
--
module Streamly.Data.Parser
(
-- * Setup
-- | To execute the code examples provided in this module in ghci, please
-- run the following commands first.
--
-- $setup
-- * Parser Type
Parser
, ParseError(..)
, ParseErrorPos(..)
-- -- * Downgrade to Fold
-- , toFold
-- * Elementary Parsers
-- ** From Folds
, fromFold
-- ** Without Input
-- , fromFoldMaybe
, fromPure
, fromEffect
, die
-- , dieM
, peek
, eof
-- ** Single Elements
-- All of these can be expressed in terms of either
, one
-- , oneEq
-- , oneNotEq
, oneOf
, noneOf
, satisfy
-- , maybe
-- , either
-- ** Sequences
, streamEqBy
, listEqBy
, listEq
-- * Transformations
-- Mapping on output
-- , rmapM
-- ** Map on input
, lmap
, lmapM
-- ** Map on output
, rmapM
-- ** Filtering
, filter
-- ** Look Ahead
, lookAhead
-- * Tokenizing Combinators
-- ** Tokenize by length
-- , takeBetween
, takeEQ
-- , takeGE
-- , takeP
-- ** Tokenize by predicate
-- , takeWhileP
, takeWhile
, takeWhile1
, dropWhile
-- , takeEndBy
-- , takeEndByEsc
-- , takeStartBy
, wordBy
-- ** Grouping
, groupBy
, groupByRolling
, groupByRollingEither
-- ** Framing
-- , wordFramedBy
, wordWithQuotes
-- , wordProcessQuotes
-- , wordKeepQuotes
-- -- * Alternative
-- , alt
-- * Splitting
, many
, some
, manyTill
-- * De-interleaving
, deintercalate
)
where
import Streamly.Internal.Data.Parser
import Prelude hiding (dropWhile, takeWhile, filter)
#include "DocTestDataParser.hs"