Boolean implication operator. Useful for defining conditional properties:

prop_something x y  =  condition x y ==> something x y

Examples:

> prop_addMonotonic x y  =  y > 0 ==> x + y > x
> check prop_addMonotonic
+++ OK, passed 200 tests.

Allows building equality properties between functions.

prop_id_idempotent  =  id === id . id

> check $ id === (+0)
+++ OK, passed 200 tests.

> check $ id === id . id
+++ OK, passed 1 tests (exhausted).

> check $ id === (+1)
*** Failed! Falsifiable (after 1 tests):
0

Allows building equality properties between two-argument functions.

> holds 100 $ const ==== asTypeOf
True

> holds 100 $ (+) ==== flip (+)
True

> holds 100 $ (+) ==== (*)
False

And (&&) operator over one-argument properties.

Allows building conjuntions between one-argument properties:

> holds 100 $ id === (+0) &&& id === (id . id)
True

And (&&) operator over two-argument properties.

Allows building conjuntions between two-argument properties:

> holds 100 $ (+) ==== flip (+) &&&& (+) ==== (*)
False

And operator over three-argument properties.

Or (||) operator over one-argument properties.

Allows building disjunctions between one-argument properties:

> holds 100 $ id === (+0) ||| id === (id . id)
True

Or (||) operator over two-argument properties.

Allows building conjuntions between two-argument properties:

> holds 100 $ (+) ==== flip (+) |||| (+) ==== (*)
True

Is the given function idempotent? f (f x) == x

> check $ isIdempotent abs
+++ OK, passed 200 tests.

> check $ isIdempotent sort
+++ OK, passed 200 tests.

> check $ isIdempotent negate
*** Failed! Falsifiable (after 2 tests):
1

Is the given function an identity? f x == x

> check $ isIdentity (+0)
+++ OK, passed 200 tests.

> check $ isIdentity (sort :: [()]->[()])
+++ OK, passed 200 tests.

> check $ isIdentity (not . not)
+++ OK, passed 2 tests (exhausted).

Is the given function never an identity? f x /= x

> check $ neverIdentity not
+++ OK, passed 2 tests (exhausted).

> check $ neverIdentity negate
*** Failed! Falsifiable (after 1 tests):
0

Note: this is not the same as not being an identity.

Is a given operator commutative? x + y = y + x

> check $ isCommutative (+)
+++ OK, passed 200 tests.

> import Data.List
> check $ isCommutative (union :: [Int]->[Int]->[Int])
*** Failed! Falsifiable (after 4 tests):
[] [0,0]

Is a given operator associative? x + (y + z) = (x + y) + z

> check $ isAssociative (+)
+++ OK, passed 200 tests.

> check $ isAssociative (-)
*** Failed! Falsifiable (after 2 tests):
0 0 1

Does the first operator, left-distributes over the second?

This is an alias to isLeftDistributiveOver.

Does the first operator, left-distributes over the second? x * (y + z) = (x * y) + (x * z)

> check $ (*) `isLeftDistributiveOver` (+)
+++ OK, passed 200 tests.

> check $ (+) `isLeftDistributiveOver` (*)
*** Failed! Falsifiable (after 8 tests):
1 0 1

Does the first operator, right-distributes over the second? (y + z) * x = (y * x) + (z * x)

> check $ (*) `isRightDistributiveOver` (+)
+++ OK, passed 200 tests.

> check $ (+) `isRightDistributiveOver` (*)
*** Failed! Falsifiable (after 8 tests):
1 0 1

Are two operators flipped versions of each other?

> check $ ((<) `isFlipped` (>) :: Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check $ ((<=) `isFlipped` (>=) :: Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check $ ((<) `isFlipped` (>=) :: Int -> Int -> Bool)
*** Failed! Falsifiable (after 1 tests):
0 0

> check $ ((<=) `isFlipped` (>) :: Int -> Int -> Bool)
*** Failed! Falsifiable (after 1 tests):
0 0

Is a given relation transitive?

A relation is transitive when if a is related to b then b is related to c.

> check $ isTransitive ((==) :: Int->Int->Bool)
+++ OK, passed 200 tests.

> check $ isTransitive ((/=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 3 tests):
0 1 0

Is a given relation reflexive?

A relation is reflexive when an element is always related to itself.

> check $ isReflexive ((==) :: Int->Int->Bool)
+++ OK, passed 200 tests.

> check $ isReflexive ((/=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0

Is a given relation irreflexive?

A given relation is irreflexive or anti-reflexive when an element is _never_ related to itself.

This is not the negation of isReflexive.

> check $ isIrreflexive ((==) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0

> check $ isIrreflexive ((/=) :: Int->Int->Bool)
+++ OK, passed 200 tests.

Is a given relation symmetric?

A relation is symmetric when if a is related to b, then b is related to a.

> check $ isSymmetric (&&)
+++ OK, passed 4 tests (exhausted).

> check $ isSymmetric (==>)
*** Failed! Falsifiable (after 2 tests):
False True

This is a type-restricted version of isCommutative.

Is a given relation asymmetric?

Not to be confused with not isSymmetric and isAntisymmetric.

> check $ isAsymmetric ((<=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0 0

> check $ isAsymmetric ((<) :: Int->Int->Bool)
+++ OK, passed 200 tests.

Is a given relation antisymmetric?

Not to be confused with isAsymmetric. Not to be confused with the negation of isSymmetric.

> check $ isAntisymmetric ((<=) :: Int->Int->Bool)
+++ OK, passed 200 tests.

> check $ isAntisymmetric ((/=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 2 tests):
0 1

Is the given binary relation an equivalence?

In other words, is the given relation reflexive, symmetric and transitive?

> check (isEquivalence (==) :: Int -> Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check (isEquivalence (<=) :: Int -> Int -> Int -> Bool)
*** Failed! Falsifiable (after 3 tests):
0 1 0

Or, using Test.LeanCheck.Utils.TypeBinding:

> check $ isEquivalence (<=) -:> int
*** Failed! Falsifiable (after 3 tests):
0 1 0

Is the given binary relation a partial order?

In other words, is the given relation reflexive, antisymmetric and transitive?

> check $ isPartialOrder ((<) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0 0 0

> check $ isPartialOrder ((<=) :: Int->Int->Bool)
+++ OK, passed 200 tests.

> check $ isPartialOrder isSubsetOf
+++ OK, passed 200 tests.

Is the given binary relation a strict partial order?

In other words, is the given relation irreflexive, asymmetric and transitive?

> check $ isStrictPartialOrder ((<) :: Int->Int->Bool)
+++ OK, passed 200 tests.

> check $ isStrictPartialOrder ((<=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0 0 0

Is the given binary relation a total order?

> check $ isTotalOrder ((<) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0 0 0
> check $ isTotalOrder ((<=) :: Int->Int->Bool)
+++ OK, passed 200 tests.

Is the given binary relation a strict total order?

> check $ isStrictTotalOrder ((<=) :: Int->Int->Bool)
*** Failed! Falsifiable (after 1 tests):
0 0 0

> check $ isStrictTotalOrder ((<) :: Int->Int->Bool)
+++ OK, passed 200 tests.

Does the given compare function follow the required properties?

This is useful for testing custom Ord instances.

> check $ isComparison (compare :: Int->Int->Ordering)
+++ OK, passed 200 tests.

Equal under, a ternary operator with the same fixity as ==.

x =$ f $= y  =  f x == f y

> [1,2,3,4,5] =$ take 2 $= [1,2,4,8,16]
True

> [1,2,3,4,5] =$ take 3 $= [1,2,4,8,16]
False

> [1,2,3] =$ sort $= [3,2,1]
True

> 42 =$ (`mod` 10) $= 16842
True

> 42 =$ (`mod`  9) $= 16842
False

> 'a' =$ isLetter $= 'b'
True

> 'a' =$ isLetter $= '1'
False

See =$

Check if two lists are equal for n values. This operator has the same fixity of ==.

xs =| n |= ys  =  take n xs == take n ys

[1,2,3,4,5] =| 2 |= [1,2,4,8,16] -- > True
[1,2,3,4,5] =| 3 |= [1,2,4,8,16] -- > False

See =|

Is this Eq instance valid?

This is useful for testing your custom Eq instances against required properties.

In particular, this function tests that == is an equivalence and that /= is the negation of ==.

> check $ (okEq :: Int -> Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check $ (okEq :: Bool -> Bool -> Bool -> Bool)
+++ OK, passed 8 tests (exhausted).

Is this Ord instance valid?

This is useful for testing your custom Ord instances against required properties.

> check $ (okOrd :: Int -> Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check $ (okOrd :: Bool -> Bool -> Bool -> Bool)
+++ OK, passed 8 tests (exhausted).

Is this Eq and Ord instance valid and consistent?

This is useful for testing your custom Eq and Ord instances against required properties.

> check $ (okEqOrd :: Int -> Int -> Int -> Bool)
+++ OK, passed 200 tests.

> check $ (okEqOrd :: Bool -> Bool -> Bool -> Bool)
+++ OK, passed 8 tests (exhausted).

Is this Num instance valid?

This is useful for testing your custom Num instances against required properties.

> check (okNum :: Int -> Int -> Int -> Bool)
+++ OK, passed 200 tests.

Double is mostly valid, but not entirely valid:

> check (okNum :: Double -> Double -> Double -> Bool)
*** Failed! Falsifiable (after 6 tests):

1. 0 0.0 Infinity

Like okNum but restricted to zero and positives.

> check (okNumNonNegative :: Natural -> Natural -> Natural -> Bool)
+++ OK, passed 200 tests.

Deprecated: use isIdempotent.

Deprecated: use isIdentity.

Deprecated: use isNeverIdentity.

Deprecated: use isCommutative.

Deprecated: use isAssociative.

Deprecated: use isDistributiveOver.

Deprecated: use isFlipped.

Deprecated: use isTransitive.

Deprecated: use isReflexive.

Deprecated: use isIrreflexive.

Deprecated: use isSymmetric.

Deprecated: use isAsymmetric.

Deprecated: use isAntisymmetric.

Deprecated: use isEquivalence.

Deprecated: use isPartialOrder.

Deprecated: use isStrictPartialOrder.

Deprecated: use isTotalOrder.

Deprecated: use isStrictTotalOrder.

Deprecated: use isComparison.