Copyright | (c) Dong Han 2017-2019 |
---|---|

License | BSD |

Maintainer | winterland1989@gmail.com |

Stability | experimental |

Portability | non-portable |

Safe Haskell | None |

Language | Haskell2010 |

Textual numeric parsers.

## Synopsis

- uint :: forall a. (Integral a, Bounded a) => Parser a
- int :: forall a. (Integral a, Bounded a) => Parser a
- integer :: Parser Integer
- uint_ :: forall a. (Integral a, Bounded a) => Parser a
- int_ :: (Integral a, Bounded a) => Parser a
- digit :: Parser Int
- hex :: forall a. (Integral a, FiniteBits a) => Parser a
- hex' :: forall a. (Integral a, FiniteBits a) => Parser a
- hex_ :: (Integral a, Bits a) => Parser a
- rational :: Fractional a => Parser a
- float :: Parser Float
- double :: Parser Double
- scientific :: Parser Scientific
- scientifically :: (Scientific -> a) -> Parser a
- rational' :: Fractional a => Parser a
- float' :: Parser Float
- double' :: Parser Double
- scientific' :: Parser Scientific
- scientifically' :: (Scientific -> a) -> Parser a
- w2iHex :: Integral a => Word8 -> a
- w2iDec :: Integral a => Word8 -> a
- hexLoop :: forall a. (Integral a, Bits a) => a -> Bytes -> a
- decLoop :: Integral a => a -> Bytes -> a
- decLoopIntegerFast :: Bytes -> Integer

# Decimal

uint :: forall a. (Integral a, Bounded a) => Parser a Source #

Parse and decode an unsigned decimal number.

Will fail in case of overflow.

int :: forall a. (Integral a, Bounded a) => Parser a Source #

Parse a decimal number with an optional leading `'+'`

or `'-'`

sign
character.

This parser will fail if overflow happens.

uint_ :: forall a. (Integral a, Bounded a) => Parser a Source #

Same with `uint`

, but sliently cast in case of overflow.

int_ :: (Integral a, Bounded a) => Parser a Source #

Same with `int`

, but sliently cast if overflow happens.

# Hex

hex :: forall a. (Integral a, FiniteBits a) => Parser a Source #

Parse and decode an unsigned hex number, fail if input length is larger than (bit_size/4). The hex digits
`'a'`

through `'f'`

may be upper or lower case.

This parser does not accept a leading `"0x"`

string, and consider
sign bit part of the binary hex nibbles, e.g.

`>>>`

`parse' hex "FF" == Right (-1 :: Int8)`

`>>>`

`parse' hex "7F" == Right (127 :: Int8)`

`>>>`

`parse' hex "7Ft" == Right (127 :: Int8)`

`>>>`

`parse' hex "7FF" == Left ["Z.Data.Parser.Numeric.hex","hex numeric number overflow"]`

hex' :: forall a. (Integral a, FiniteBits a) => Parser a Source #

Same with `hex`

, but only take as many as (bit_size/4) bytes.

`>>>`

`parse' hex "FF" == Right (-1 :: Int8)`

`>>>`

`parse' hex "7F" == Right (127 :: Int8)`

`>>>`

`parse' hex "7Ft" == Right (127 :: Int8)`

`>>>`

`parse' hex "7FF" == Right (127 :: Int8)`

hex_ :: (Integral a, Bits a) => Parser a Source #

Same with `hex`

, but silently cast in case of overflow.

`>>>`

`parse' hex "FF" == Right (-1 :: Int8)`

`>>>`

`parse' hex "7F" == Right (127 :: Int8)`

`>>>`

`parse' hex "7Ft" == Right (127 :: Int8)`

`>>>`

`parse' hex "7FF" == Right (-1 :: Int8)`

# Fractional

rational :: Fractional a => Parser a Source #

Parse a rational number.

The syntax accepted by this parser is the same as for `double`

.

*Note*: this parser is not safe for use with inputs from untrusted
sources. An input with a suitably large exponent such as
`"1e1000000000"`

will cause a huge `Integer`

to be allocated,
resulting in what is effectively a denial-of-service attack.

In most cases, it is better to use `double`

or `scientific`

instead.

double :: Parser Double Source #

Parse a rational number and round to `Double`

.

This parser accepts an optional leading sign character, followed by
at least one decimal digit. The syntax similar to that accepted by
the `read`

function, with the exception that a trailing `'.'`

or
`'e'`

*not* followed by a number is not consumed.

Examples with behaviour identical to `read`

:

parse' double "3" == ("", Right 3.0) parse' double "3.1" == ("", Right 3.1) parse' double "3e4" == ("", Right 30000.0) parse' double "3.1e4" == ("", Right 31000.0)

parse' double ".3" == (".3", Left ParserError) parse' double "e3" == ("e3", Left ParserError)

Examples of differences from `read`

:

parse' double "3.foo" == (".foo", Right 3.0) parse' double "3e" == ("e", Right 3.0) parse' double "-3e" == ("e", Right -3.0)

This function does not accept string representations of "NaN" or "Infinity".

scientific :: Parser Scientific Source #

Parse a scientific number.

The syntax accepted by this parser is the same as for `double`

.

scientifically :: (Scientific -> a) -> Parser a Source #

Parse a scientific number and convert to result using a user supply function.

The syntax accepted by this parser is the same as for `double`

.

# Stricter fractional(rfc8259)

rational' :: Fractional a => Parser a Source #

Parse a rational number.

The syntax accepted by this parser is the same as for `double'`

.

*Note*: this parser is not safe for use with inputs from untrusted
sources. An input with a suitably large exponent such as
`"1e1000000000"`

will cause a huge `Integer`

to be allocated,
resulting in what is effectively a denial-of-service attack.

In most cases, it is better to use `double'`

or `scientific'`

instead.

double' :: Parser Double Source #

More strict number parsing(rfc8259).

`scientific`

support parse `2314.`

and `21321exyz`

without eating extra dot or `e`

via
backtrack, this is not allowed in some strict grammer such as JSON, so we make an
non-backtrack strict number parser separately using LL(1) lookahead. This parser also
agree with `read`

on extra dot or e handling:

parse' double "3.foo" == Left ParseError parse' double "3e" == Left ParseError

Leading zeros or `+`

sign is also not allowed:

parse' double "+3.14" == Left ParseError parse' double "0014" == Left ParseError

If you have a similar grammer, you can use this parser to save considerable time.

number = [ minus ] int [ frac ] [ exp ] decimal-point = %x2E ; . digit1-9 = %x31-39 ; 1-9 e = %x65 / %x45 ; e E exp = e [ minus / plus ] 1*DIGIT frac = decimal-point 1*DIGIT

This function does not accept string representations of "NaN" or "Infinity". reference: https://tools.ietf.org/html/rfc8259#section-6

scientific' :: Parser Scientific Source #

Parse a scientific number.

The syntax accepted by this parser is the same as for `double'`

.

scientifically' :: (Scientific -> a) -> Parser a Source #

Parse a scientific number and convert to result using a user supply function.

The syntax accepted by this parser is the same as for `double'`

.

# Misc

decode hex digits sequence within an array.

Decode digits sequence within an array.

This function may overflow if result can't fit into type.