Safe Haskell | Safe-Inferred |
---|---|
Language | Haskell2010 |
This module implements a view of a VersionRange
as a finite
list of separated version intervals and provides the Boolean
algebra operations union, intersection, and complement.
It interprets the caret operator ^>=x.y
as simply ==x.y.*
.
Until Cabal < 3.6
, this module was called Distribution.Types.VersionInterval.
The current module Distribution.Types.VersionInterval (refurbished since
Cabal >= 3.6
) makes some effort to preserve the caret operator,
but so far does not expose the Boolean algebra structure.
Synopsis
- data VersionIntervals
- toVersionIntervals :: VersionRange -> VersionIntervals
- fromVersionIntervals :: VersionIntervals -> VersionRange
- withinIntervals :: Version -> VersionIntervals -> Bool
- versionIntervals :: VersionIntervals -> [VersionInterval]
- mkVersionIntervals :: [VersionInterval] -> VersionIntervals
- unionVersionIntervals :: VersionIntervals -> VersionIntervals -> VersionIntervals
- intersectVersionIntervals :: VersionIntervals -> VersionIntervals -> VersionIntervals
- invertVersionIntervals :: VersionIntervals -> VersionIntervals
- relaxLastInterval :: VersionIntervals -> VersionIntervals
- relaxHeadInterval :: VersionIntervals -> VersionIntervals
- asVersionIntervals :: VersionRange -> [VersionInterval]
- type VersionInterval = (LowerBound, UpperBound)
- data LowerBound = LowerBound Version !Bound
- data UpperBound
- data Bound
Version intervals
data VersionIntervals Source #
A complementary representation of a VersionRange
,
using an increasing sequence of separated (i.e., non-overlapping, non-touching)
non-empty intervals.
The represented range is the union of these intervals, meaning
that the empty sequence denotes the empty range.
As ranges form a Boolean algebra, we can compute union, intersection, and complement. These operations are all linear in the size of the input, thanks to the ordered representation.
The interval-sequence representation gives a canonical representation
for the semantics of VersionRange
s. This makes it easier to check things
like whether a version range is empty, covers all versions, or requires a
certain minimum or maximum version. It also makes it easy to check equality (just ==
)
or containment. It also makes it easier to identify 'simple' version
predicates for translation into foreign packaging systems that do not
support complex version range expressions.
Instances
Show VersionIntervals Source # | |
Defined in Distribution.Types.VersionInterval.Legacy showsPrec :: Int -> VersionIntervals -> ShowS # show :: VersionIntervals -> String # showList :: [VersionIntervals] -> ShowS # | |
Eq VersionIntervals Source # | |
Defined in Distribution.Types.VersionInterval.Legacy (==) :: VersionIntervals -> VersionIntervals -> Bool # (/=) :: VersionIntervals -> VersionIntervals -> Bool # |
toVersionIntervals :: VersionRange -> VersionIntervals Source #
Convert a VersionRange
to a sequence of version intervals.
fromVersionIntervals :: VersionIntervals -> VersionRange Source #
Convert a VersionIntervals
value back into a VersionRange
expression
representing the version intervals.
withinIntervals :: Version -> VersionIntervals -> Bool Source #
Test if a version falls within the version intervals.
It exists mostly for completeness and testing. It satisfies the following properties:
withinIntervals v (toVersionIntervals vr) = withinRange v vr withinIntervals v ivs = withinRange v (fromVersionIntervals ivs)
versionIntervals :: VersionIntervals -> [VersionInterval] Source #
Inspect the list of version intervals.
mkVersionIntervals :: [VersionInterval] -> VersionIntervals Source #
Directly construct a VersionIntervals
from a list of intervals.
unionVersionIntervals :: VersionIntervals -> VersionIntervals -> VersionIntervals Source #
Union two interval sequences, fusing intervals where necessary. Computed \( O(n+m) \) time, resulting in sequence of length \( ≤ n+m \).
intersectVersionIntervals :: VersionIntervals -> VersionIntervals -> VersionIntervals Source #
The intersection \( is \cap is' \) of two interval sequences \( is \) and \( is' \) of lengths \( n \) and \( m \), resp., satisfies the specification \( is ∩ is' = \{ i ∩ i' \mid i ∈ is, i' ∈ is' \} \). Thanks to the ordered representation of intervals it can be computed in \( O(n+m) \) (rather than the naive \( O(nm) \).
The length of \( is \cap is' \) is \( ≤ \min(n,m) \).
invertVersionIntervals :: VersionIntervals -> VersionIntervals Source #
Compute the complement. \( O(n) \).
relaxLastInterval :: VersionIntervals -> VersionIntervals Source #
Remove the last upper bound, enlarging the range. But empty ranges stay empty. \( O(n) \).
relaxHeadInterval :: VersionIntervals -> VersionIntervals Source #
Remove the first lower bound (i.e, make it \( [0 \). Empty ranges stay empty. \( O(1) \).
Version intervals view
asVersionIntervals :: VersionRange -> [VersionInterval] Source #
View a VersionRange
as a sequence of separated intervals.
This provides a canonical view of the semantics of a VersionRange
as
opposed to the syntax of the expression used to define it. For the syntactic
view use foldVersionRange
.
Canonical means that two semantically equal ranges translate to the same
[
, thus its VersionInterval
]Eq
instance can decide semantical equality
of ranges.
In the returned sequence, each interval is non-empty.
The sequence is in increasing order and the intervals are separated, i.e., they
neither overlap nor touch. Therefore only the first and last interval can be
unbounded. The sequence can be empty if the range is empty
(e.g. a range expression like > 2 && < 1
).
Other checks are trivial to implement using this view. For example:
isNoVersion vr | [] <- asVersionIntervals vr = True | otherwise = False
isSpecificVersion vr | [(LowerBound v InclusiveBound ,UpperBound v' InclusiveBound)] <- asVersionIntervals vr , v == v' = Just v | otherwise = Nothing
type VersionInterval = (LowerBound, UpperBound) Source #
Version intervals with exclusive or inclusive bounds, in all combinations:
- \( (lb,ub) \) meaning \( lb < \_ < ub \).
- \( (lb,ub] \) meaning \( lb < \_ ≤ ub \).
- \( [lb,ub) \) meaning \( lb ≤ \_ < ub \).
- \( [lb,ub] \) meaning \( lb ≤ \_ < ub \).
The upper bound can also be missing, meaning "\( ..,∞) \)".
data LowerBound Source #
LowerBound Version !Bound | Either exclusive |
Instances
Show LowerBound Source # | |
Defined in Distribution.Types.VersionInterval.Legacy showsPrec :: Int -> LowerBound -> ShowS # show :: LowerBound -> String # showList :: [LowerBound] -> ShowS # | |
Eq LowerBound Source # | |
Defined in Distribution.Types.VersionInterval.Legacy (==) :: LowerBound -> LowerBound -> Bool # (/=) :: LowerBound -> LowerBound -> Bool # | |
Ord LowerBound Source # |
|
Defined in Distribution.Types.VersionInterval.Legacy compare :: LowerBound -> LowerBound -> Ordering # (<) :: LowerBound -> LowerBound -> Bool # (<=) :: LowerBound -> LowerBound -> Bool # (>) :: LowerBound -> LowerBound -> Bool # (>=) :: LowerBound -> LowerBound -> Bool # max :: LowerBound -> LowerBound -> LowerBound # min :: LowerBound -> LowerBound -> LowerBound # |
data UpperBound Source #
NoUpperBound | ..,∞) |
UpperBound Version !Bound | Either exclusive |
Instances
Show UpperBound Source # | |
Defined in Distribution.Types.VersionInterval.Legacy showsPrec :: Int -> UpperBound -> ShowS # show :: UpperBound -> String # showList :: [UpperBound] -> ShowS # | |
Eq UpperBound Source # | |
Defined in Distribution.Types.VersionInterval.Legacy (==) :: UpperBound -> UpperBound -> Bool # (/=) :: UpperBound -> UpperBound -> Bool # | |
Ord UpperBound Source # |
|
Defined in Distribution.Types.VersionInterval.Legacy compare :: UpperBound -> UpperBound -> Ordering # (<) :: UpperBound -> UpperBound -> Bool # (<=) :: UpperBound -> UpperBound -> Bool # (>) :: UpperBound -> UpperBound -> Bool # (>=) :: UpperBound -> UpperBound -> Bool # max :: UpperBound -> UpperBound -> UpperBound # min :: UpperBound -> UpperBound -> UpperBound # |
ExclusiveBound |
|
InclusiveBound |
|