Safe Haskell | None |
---|---|

Language | Haskell2010 |

- data Many xs = Many (Seq Any)
- class IsMany t xs a where
- fromMany' :: IsMany Tagged xs a => Many xs -> a
- toMany' :: IsMany Tagged xs a => a -> Many xs
- nil :: Many '[]
- single :: x -> Many '[x]
- prefix :: x -> Many xs -> Many (x ': xs)
- (./) :: x -> Many xs -> Many (x ': xs)
- postfix :: Many xs -> y -> Many (Append xs '[y])
- postfix' :: forall xs y n. MaybeUniqueMemberAt n y xs => Many xs -> y -> Many (SnocUnique xs y)
- (\.) :: Many xs -> y -> Many (Append xs '[y])
- append :: Many xs -> Many ys -> Many (Append xs ys)
- append' :: CanAppendUnique xs ys => Many xs -> Many ys -> Many (AppendUnique xs ys)
- (/./) :: Many xs -> Many ys -> Many (Append xs ys)
- viewf :: Many (x ': xs) -> (x, Many xs)
- viewb :: Many (x ': xs) -> (Many (Init (x ': xs)), Last (x ': xs))
- front :: Many (x ': xs) -> x
- back :: Many (x ': xs) -> Last (x ': xs)
- aft :: Many (x ': xs) -> Many xs
- fore :: Many (x ': xs) -> Many (Init (x ': xs))
- fetch :: forall x xs. UniqueMember x xs => Many xs -> x
- fetchL :: forall l xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> x
- fetchN :: forall n x xs proxy. MemberAt n x xs => proxy n -> Many xs -> x
- replace :: forall x xs. UniqueMember x xs => Many xs -> x -> Many xs
- replace' :: forall x y xs proxy. UniqueMember x xs => proxy x -> Many xs -> y -> Many (Replace x y xs)
- replaceL :: forall l xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> x -> Many xs
- replaceL' :: forall l y xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> y -> Many (Replace x y xs)
- replaceN :: forall n x y xs proxy. MemberAt n x xs => proxy n -> Many xs -> y -> Many xs
- replaceN' :: forall n x y xs proxy. MemberAt n x xs => proxy n -> Many xs -> y -> Many (ReplaceIndex n y xs)
- type Select smaller larger = AFoldable (CollectorAny (CaseSelect smaller larger) larger) (Maybe (Int, WrappedAny))
- select :: forall smaller larger. Select smaller larger => Many larger -> Many smaller
- selectL :: forall ls smaller larger proxy. (Select smaller larger, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller
- type SelectN ns smaller larger = (AFoldable (CollectorAnyN (CaseSelectN ns smaller) 0 larger) (Maybe (Int, WrappedAny)), smaller ~ KindsAtIndices ns larger, IsDistinct ns)
- selectN :: forall ns smaller larger proxy. SelectN ns smaller larger => proxy ns -> Many larger -> Many smaller
- type Amend smaller larger = (AFoldable (CollectorAny (CaseAmend larger) smaller) (Int, WrappedAny), IsDistinct smaller)
- amend :: forall smaller larger. Amend smaller larger => Many larger -> Many smaller -> Many larger
- type Amend' smaller smaller' larger zipped = (AFoldable (CollectorAny (CaseAmend' larger) zipped) (Int, WrappedAny), IsDistinct smaller, zipped ~ Zip smaller smaller')
- amend' :: forall smaller smaller' larger proxy zipped. Amend' smaller smaller' larger zipped => proxy smaller -> Many larger -> Many smaller' -> Many (Replaces smaller smaller' larger)
- amendL :: forall ls smaller larger proxy. (Amend smaller larger, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller -> Many larger
- amendL' :: forall ls smaller smaller' larger proxy zipped. (Amend' smaller smaller' larger zipped, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller' -> Many (Replaces smaller smaller' larger)
- type AmendN ns smaller larger = (AFoldable (CollectorAnyN (CaseAmendN ns larger) 0 smaller) (Int, WrappedAny), smaller ~ KindsAtIndices ns larger, IsDistinct ns)
- amendN :: forall ns smaller larger proxy. AmendN ns smaller larger => proxy ns -> Many larger -> Many smaller -> Many larger
- type AmendN' ns smaller smaller' larger zipped = (AFoldable (CollectorAnyN (CaseAmendN' ns larger) 0 zipped) (Int, WrappedAny), smaller ~ KindsAtIndices ns larger, IsDistinct ns, zipped ~ Zip smaller smaller')
- amendN' :: forall ns smaller smaller' larger proxy zipped. AmendN' ns smaller smaller' larger zipped => proxy ns -> Many larger -> Many smaller' -> Many (ReplacesIndex ns smaller' larger)
- forMany :: (t ~ Collector c xs, AFoldable t r, Case c xs r) => c xs r -> Many xs -> t r
- collect :: (t ~ Collector c xs, AFoldable t r, Case c xs r) => Many xs -> c xs r -> t r
- forManyN :: (t ~ CollectorN c n xs, AFoldable t r, Case (c n) xs r) => c n xs r -> Many xs -> t r
- collectN :: (t ~ CollectorN c n xs, AFoldable t r, Case (c n) xs r) => Many xs -> c n xs r -> t r

`Many`

type

A Many is an anonymous product type (also know as polymorphic record), with no limit on the number of fields.

The following functions are available can be used to manipulate unique fields

- getter/setter for single field:
`fetch`

and`replace`

- getter/setter for multiple fields:
`select`

and`amend`

- folds:
`forMany`

or`collect`

These functions are type specified. This means labels are not required because the types themselves can be used to access the 'Many. It is a compile error to use those functions for duplicate fields.

For duplicate fields, Nat-indexed versions of the functions are available:

- getter/setter for single field:
`fetchN`

and`replaceN`

- getter/setter for multiple fields:
`selectN`

and`amendN`

- folds:
`forManyN`

or`collectN`

Encoding: The record is encoded as (Offset, Map Int Any). This encoding should reasonabily efficient for any number of fields.

The map Key is index + offset of the type in the typelist.
The Offset is used to allow efficient cons `prefix`

.

Key = Index of type in typelist + Offset

The constructor will guarantee the correct number and types of the elements. The constructor is only exported in the Data.Diverse.Many.Internal module

Eq (Many_ xs) => Eq (Many xs) Source # | Two |

Ord (Many_ xs) => Ord (Many xs) Source # | Two |

Read (Many_ xs) => Read (Many xs) Source # | read "5 . |

Show (Many_ xs) => Show (Many xs) Source # | show (5 :: Int) |

Generic (Many ((:) Type x xs)) Source # | A |

Generic (Many ([] Type)) Source # | |

Semigroup (Many ([] Type)) Source # | |

Monoid (Many ([] Type)) Source # | |

(NFData x, NFData (Many xs)) => NFData (Many ((:) * x xs)) Source # | |

NFData (Many ([] Type)) Source # | |

type Rep (Many ((:) Type x xs)) Source # | |

type Rep (Many ([] Type)) Source # | |

# Isomorphism

class IsMany t xs a where Source #

This instance allows converting to and from Many There are instances for converting tuples of up to size 15.

IsMany * (Tagged [Type]) ([] Type) () Source # | These instances add about 7 seconds to the compile time! |

IsMany * (Tagged [Type]) ((:) Type a ([] Type)) a Source # | This single field instance is the reason for |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ([] Type))) (a, b) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ([] Type)))) (a, b, c) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ([] Type))))) (a, b, c, d) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ([] Type)))))) (a, b, c, d, e) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ([] Type))))))) (a, b, c, d, e, f) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ([] Type)))))))) (a, b, c, d, e, f, g) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ([] Type))))))))) (a, b, c, d, e, f, g, h) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ([] Type)))))))))) (a, b, c, d, e, f, g, h, i) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ([] Type))))))))))) (a, b, c, d, e, f, g, h, i, j) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ((:) Type k ([] Type)))))))))))) (a, b, c, d, e, f, g, h, i, j, k) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ((:) Type k ((:) Type l ([] Type))))))))))))) (a, b, c, d, e, f, g, h, i, j, k, l) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ((:) Type k ((:) Type l ((:) Type m ([] Type)))))))))))))) (a, b, c, d, e, f, g, h, i, j, k, l, m) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ((:) Type k ((:) Type l ((:) Type m ((:) Type n ([] Type))))))))))))))) (a, b, c, d, e, f, g, h, i, j, k, l, m, n) Source # | |

IsMany * (Tagged [Type]) ((:) Type a ((:) Type b ((:) Type c ((:) Type d ((:) Type e ((:) Type f ((:) Type g ((:) Type h ((:) Type i ((:) Type j ((:) Type k ((:) Type l ((:) Type m ((:) Type n ((:) Type o ([] Type)))))))))))))))) (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) Source # | |

fromMany' :: IsMany Tagged xs a => Many xs -> a Source #

Converts from a Many to a value (eg a tuple), via a Tagged wrapper

# Construction

prefix :: x -> Many xs -> Many (x ': xs) infixr 5 Source #

Add an element to the left of a Many.
Not named `cons`

to avoid conflict with `cons`

postfix :: Many xs -> y -> Many (Append xs '[y]) infixl 5 Source #

Add an element to the right of a Many
Not named `snoc`

to avoid conflict with `snoc`

postfix' :: forall xs y n. MaybeUniqueMemberAt n y xs => Many xs -> y -> Many (SnocUnique xs y) infixl 5 Source #

Add an element to the right of a Many iff the field doesn't already exist.

append' :: CanAppendUnique xs ys => Many xs -> Many ys -> Many (AppendUnique xs ys) infixr 5 Source #

Appends the unique fields fields from the right Many using `postfix'`

# Simple queries

viewf :: Many (x ': xs) -> (x, Many xs) Source #

Split a non-empty Many into the first element, then the rest of the Many.
Analogous to `viewl`

viewb :: Many (x ': xs) -> (Many (Init (x ': xs)), Last (x ': xs)) Source #

Split a non-empty Many into initial part of Many, and the last element.
Analogous to `viewr`

front :: Many (x ': xs) -> x Source #

Extract the first element of a Many, which guaranteed to be non-empty.
Analogous to `head`

aft :: Many (x ': xs) -> Many xs Source #

Extract the elements after the front of a Many, which guaranteed to be non-empty.
Analogous to `tail`

# Single field

## Getter for single field

fetch :: forall x xs. UniqueMember x xs => Many xs -> x Source #

fetchL :: forall l xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> x Source #

## Setter for single field

replace' :: forall x y xs proxy. UniqueMember x xs => proxy x -> Many xs -> y -> Many (Replace x y xs) Source #

replaceL :: forall l xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> x -> Many xs Source #

Setter by unique label. Set the field with label `l`

.

let y = (5 :: Int)`./`

False`./`

Tagged @Foo 'X'`./`

Tagged @"Hello" (6 :: Int)`./`

`nil`

`replaceL`

@Foo Proxy y (Tagged @Foo 'Y') `shouldBe` (5 :: Int)`./`

False`./`

Tagged @Foo 'Y'`./`

Tagged @"Hello" (6 :: Int)`./`

`nil`

`replaceL`

@"Hello" Proxy y (Tagged @"Hello" 7) `shouldBe` (5 :: Int)`./`

False`./`

Tagged @Foo 'X'`./`

Tagged @"Hello" (7 :: Int)`./`

`nil`

replaceL' :: forall l y xs x proxy. (UniqueLabelMember l xs, x ~ KindAtLabel l xs) => proxy l -> Many xs -> y -> Many (Replace x y xs) Source #

Polymorphic setter by unique type. Set the field with type `x`

, and replace with type `y`

let y = (5 :: Int)`./`

False`./`

Tagged @Foo 'X'`./`

Tagged @"Hello" (6 :: Int)`./`

`nil`

replaceL' @Foo Proxy y (Tagged @Bar 'Y')`shouldBe`

(5 :: Int)`./`

False`./`

Tagged`Bar`

Hello (6 :: Int)`Y`

`./`

Tagged`./`

`nil`

replaceL' @"Hello" Proxy y (Tagged @"Hello" False) `shouldBe` (5 :: Int)`./`

False`./`

Tagged @Foo 'X'`./`

Tagged @"Hello" False`./`

`nil`

replaceN' :: forall n x y xs proxy. MemberAt n x xs => proxy n -> Many xs -> y -> Many (ReplaceIndex n y xs) Source #

Polymorphic version of `replaceN`

# Multiple fields

## Getter for multiple fields

type Select smaller larger = AFoldable (CollectorAny (CaseSelect smaller larger) larger) (Maybe (Int, WrappedAny)) Source #

A friendlier type constraint synomyn for `select`

select :: forall smaller larger. Select smaller larger => Many larger -> Many smaller Source #

Construct a `Many`

with a smaller number of fields than the original.
Analogous to `fetch`

getter but for multiple fields.

This can also be used to reorder fields in the original `Many`

.

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

`select`

@'[Bool, Char] x `shouldBe` False`./`

'X'`./`

`nil`

selectL :: forall ls smaller larger proxy. (Select smaller larger, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller Source #

A variation of `select`

which selects by labels

let x = False`./`

Tagged @"Hi" (5 :: Int)`./`

Tagged @Foo False`./`

Tagged @Bar 'X'`./`

Tagged @"Bye"`O`

`./`

`nil`

`selectL`

@'[Foo, Bar] Proxy x `shouldBe` Tagged @Foo False`./`

Tagged @Bar 'X'`./`

`nil`

`selectL`

@'["Hi", "Bye"] Proxy x `shouldBe` Tagged @"Hi" (5 :: Int)`./`

Tagged @"Bye" 'O'`./`

`nil`

type SelectN ns smaller larger = (AFoldable (CollectorAnyN (CaseSelectN ns smaller) 0 larger) (Maybe (Int, WrappedAny)), smaller ~ KindsAtIndices ns larger, IsDistinct ns) Source #

A friendlier type constraint synomyn for `selectN`

selectN :: forall ns smaller larger proxy. SelectN ns smaller larger => proxy ns -> Many larger -> Many smaller Source #

A variation of `select`

which uses a Nat list `n`

to specify how to reorder the fields, where

indices[branch_idx] = tree_idx@

This variation allows `smaller`

or `larger`

to contain indistinct since
the mapping is specified by `indicies`

.

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

`selectN`

(Proxy @'[5, 4, 0]) x `shouldBe` Just 'A'`./`

(6 :: Int)`./`

(5 ::Int)`./`

`nil`

## Setter for multiple fields

type Amend smaller larger = (AFoldable (CollectorAny (CaseAmend larger) smaller) (Int, WrappedAny), IsDistinct smaller) Source #

A friendlier type constraint synomyn for `amend`

amend :: forall smaller larger. Amend smaller larger => Many larger -> Many smaller -> Many larger Source #

type Amend' smaller smaller' larger zipped = (AFoldable (CollectorAny (CaseAmend' larger) zipped) (Int, WrappedAny), IsDistinct smaller, zipped ~ Zip smaller smaller') Source #

A friendlier type constraint synomyn for `amend'`

amend' :: forall smaller smaller' larger proxy zipped. Amend' smaller smaller' larger zipped => proxy smaller -> Many larger -> Many smaller' -> Many (Replaces smaller smaller' larger) Source #

amendL :: forall ls smaller larger proxy. (Amend smaller larger, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller -> Many larger Source #

A variation of `amend`

which amends via labels.

let x = False .Tagged @"Hi" (5 :: Int) .Tagged @Foo False .Tagged @Bar 'X' .Tagged @"Bye" 'O' ./`nil`

`amendL`

@'[Foo, Bar] Proxy x (Tagged @Foo True .Tagged @Bar 'Y' .nil)`shouldBe`

False .Tagged @"Hi" (5 :: Int) .Tagged @Foo True .Tagged @Bar 'Y' .Tagged @"Bye" 'O' ./`nil`

`amendL`

@'["Hi", "Bye"] Proxy x (Tagged @"Hi" (6 :: Int) .Tagged @"Bye" 'P' .nil)`shouldBe`

False .Tagged @"Hi" (6 :: Int) .Tagged @Foo False .Tagged @Bar 'X' .Tagged @"Bye" 'P' ./`nil`

amendL' :: forall ls smaller smaller' larger proxy zipped. (Amend' smaller smaller' larger zipped, smaller ~ KindsAtLabels ls larger, IsDistinct ls, UniqueLabels ls larger) => proxy ls -> Many larger -> Many smaller' -> Many (Replaces smaller smaller' larger) Source #

A variation of `amend`

which amends via labels.

let x = False`./`

Tagged @"Hi" (5 :: Int)`./`

Tagged @Foo False`./`

Tagged @Bar`X`

`./`

Tagged @"Bye" 'O'`./`

`nil`

`amendL'`

@'[Foo, Bar] Proxy x ('Y'`./`

True`./`

`ni`

l) `shouldBe` False`./`

Tagged @"Hi" (5 :: Int)`./`

'Y'`./`

True`./`

Tagged @"Bye" 'O'`./`

`nil`

`amendL'`

@'["Hi", "Bye"] Proxy x (True`./`

Tagged @"Changed" True`./`

`nil`

) `shouldBe` False`./`

True`./`

Tagged @Foo False`./`

Tagged @Bar 'X'`./`

Tagged @"Changed" True`./`

`nil`

type AmendN ns smaller larger = (AFoldable (CollectorAnyN (CaseAmendN ns larger) 0 smaller) (Int, WrappedAny), smaller ~ KindsAtIndices ns larger, IsDistinct ns) Source #

A friendlier type constraint synomyn for `amendN`

amendN :: forall ns smaller larger proxy. AmendN ns smaller larger => proxy ns -> Many larger -> Many smaller -> Many larger Source #

A variation of `amend`

which uses a Nat list `n`

to specify how to reorder the fields, where

indices[branch_idx] = tree_idx@

This variation allows `smaller`

or `larger`

to contain indistinct since
the mapping is specified by `indicies`

.

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

`amendN`

(Proxy @'[5, 4, 0]) x (Just 'B'`./`

(8 :: Int)`./`

(4 ::Int)`./`

`nil`

) `shouldBe` (4 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(8 :: Int)`./`

Just 'B'`./`

`nil`

type AmendN' ns smaller smaller' larger zipped = (AFoldable (CollectorAnyN (CaseAmendN' ns larger) 0 zipped) (Int, WrappedAny), smaller ~ KindsAtIndices ns larger, IsDistinct ns, zipped ~ Zip smaller smaller') Source #

A friendlier type constraint synomyn for `amendN`

amendN' :: forall ns smaller smaller' larger proxy zipped. AmendN' ns smaller smaller' larger zipped => proxy ns -> Many larger -> Many smaller' -> Many (ReplacesIndex ns smaller' larger) Source #

A polymorphic variation of `amendN`

# Destruction

## By type

forMany :: (t ~ Collector c xs, AFoldable t r, Case c xs r) => c xs r -> Many xs -> t r Source #

Folds any `Many`

, even with indistinct types.
Given **distinct** handlers for the fields in `Many`

, create `AFoldable`

of the results of running the handlers over the fields in `Many`

.

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

y = show @Int`./`

show @Char`./`

show @(Maybe Char)`./`

show @Bool`./`

`nil`

`afoldr`

(:) [] (`forMany`

(`cases`

y) x) `shouldBe` ["5", "False", "'X'", "Just 'O'", "6", "Just 'A'"]

## By Nat index offset

forManyN :: (t ~ CollectorN c n xs, AFoldable t r, Case (c n) xs r) => c n xs r -> Many xs -> t r Source #

Folds any `Many`

, even with indistinct types.
Given **index** handlers for the fields in `Many`

, create `AFoldable`

of the results of running the handlers over the fields in `Many`

.

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

y = show @Int`./`

show @Bool`./`

show @Char`./`

show @(Maybe Char)`./`

show @Int`./`

show @(Maybe Char)`./`

`nil`

`afoldr`

(:) [] (`forManyN`

(`casesN`

y) x) `shouldBe` ["5", "False", "'X'", "Just 'O'", "6", "Just 'A'"]

collectN :: (t ~ CollectorN c n xs, AFoldable t r, Case (c n) xs r) => Many xs -> c n xs r -> t r Source #

This is `flip `

`forManyN`

let x = (5 :: Int)`./`

False`./`

'X'`./`

Just 'O'`./`

(6 :: Int)`./`

Just 'A'`./`

`nil`

y = show @Int`./`

show @Bool`./`

show @Char`./`

show @(Maybe Char)`./`

show @Int`./`

show @(Maybe Char)`./`

`nil`

`afoldr`

(:) [] (`collectN`

x (`casesN`

y)) `shouldBe` ["5", "False", "'X'", "Just 'O'", "6", "Just 'A'"]