Return type | Name and parameters |
---|---|
boolean
|
any(Closure closure)
Iterates over the contents of an iterable, and checks whether a predicate is valid for at least one element. |
Collection
|
asCollection()
Converts this Iterable to a Collection. |
List
|
asList()
Converts this Iterable to a List. |
List
|
collate(int size)
Collates this iterable into sub-lists of length size .
|
List
|
collate(int size, boolean keepRemainder)
Collates this iterable into sub-lists of length size .
|
List
|
collate(int size, int step)
Collates this iterable into sub-lists of length size stepping through the code step
elements for each subList.
|
List
|
collate(int size, int step, boolean keepRemainder)
Collates this iterable into sub-lists of length size stepping through the code step
elements for each sub-list.
|
Map
|
collectEntries()
A variant of collectEntries for Iterable objects using the identity closure as the transform. |
Map
|
collectEntries(Closure transform)
Iterates through this Iterable transforming each item using the transform closure
and returning a map of the resulting transformed entries.
|
Map
|
collectEntries(Map collector)
A variant of collectEntries for Iterables using the identity closure as the transform and a supplied map as the destination of transformed entries. |
Map
|
collectEntries(Map collector, Closure transform)
Iterates through this Iterable transforming each item using the closure as a transformer into a map entry, returning the supplied map with all of the transformed entries added to it. |
List
|
collectMany(Closure projection)
Projects each item from a source Iterable to a collection and concatenates (flattens) the resulting collections into a single list. |
Collection
|
collectMany(Collection collector, Closure projection)
Projects each item from a source collection to a result collection and concatenates (flattens) the resulting collections adding them into the collector .
|
List
|
collectNested(Closure transform)
Recursively iterates through this Iterable transforming each non-Collection value into a new value using the closure as a transformer. |
Collection
|
collectNested(Collection collector, Closure transform)
Recursively iterates through this Iterable transforming each non-Collection value into a new value using the transform closure.
|
List
|
combinations()
Adds GroovyCollections#combinations(Iterable) as a method on Iterables. |
List
|
combinations(Closure function)
Adds GroovyCollections#combinations(Iterable, Closure) as a method on collections. |
boolean
|
contains(Object item)
Returns true if this iterable contains the item. |
boolean
|
containsAll(Object[] items)
Returns true if this iterable contains all of the elements in the specified array. |
Number
|
count(Closure closure)
Counts the number of occurrences which satisfy the given closure from inside this Iterable. |
Number
|
count(Object value)
Counts the number of occurrences of the given value inside this Iterable. |
Map
|
countBy(Closure closure)
Sorts all collection members into groups determined by the supplied mapping closure and counts the group size. |
boolean
|
disjoint(Iterable right)
Returns true if the intersection of two iterables is empty.
|
Collection
|
drop(int num)
Drops the given number of elements from the head of this Iterable. |
Collection
|
dropRight(int num)
Drops the given number of elements from the tail of this Iterable. |
Collection
|
dropWhile(Closure condition)
Returns a suffix of this Iterable where elements are dropped from the front while the given closure evaluates to true. |
Iterable
|
each(Closure closure)
Iterates through an Iterable, passing each item to the given closure. |
void
|
eachCombination(Closure function)
Applies a function on each combination of the input lists. |
Iterator
|
eachPermutation(Closure closure)
Iterates over all permutations of a collection, running a closure for each iteration. |
Iterable
|
eachWithIndex(Closure closure)
Iterates through an iterable type, passing each item and the item's index (a counter starting at zero) to the given closure. |
boolean
|
every(Closure closure)
Used to determine if the given predicate closure is valid (i.e. |
Collection
|
findResults(Closure filteringTransform)
Iterates through the Iterable transforming items using the supplied closure and collecting any non-null results. |
Object
|
first()
Returns the first item from the Iterable. |
Collection
|
flatten()
Flatten an Iterable. |
Collection
|
flatten(Closure flattenUsing)
Flatten an Iterable. |
Object
|
getAt(int idx)
Support the subscript operator for an Iterable. |
Map
|
groupBy(Closure closure)
Sorts all Iterable members into groups determined by the supplied mapping closure. |
Map
|
groupBy(Object closures)
Sorts all Iterable members into (sub)groups determined by the supplied mapping closures. |
Map
|
groupBy(List closures)
Sorts all Iterable members into (sub)groups determined by the supplied mapping closures. |
Object
|
head()
Returns the first item from the Iterable. |
Map
|
indexed()
Zips an Iterable with indices in (index, value) order. |
Map
|
indexed(int offset)
Zips an Iterable with indices in (index, value) order. |
Collection
|
init()
Returns the items from the Iterable excluding the last item. |
Collection
|
intersect(Iterable right)
Create a Collection composed of the intersection of both iterables. |
String
|
join(String separator)
Concatenates the toString() representation of each
item in this Iterable, with the given String as a separator between each item.
|
Object
|
last()
Returns the last item from the Iterable. |
Object
|
max()
Adds max() method to Iterable objects. |
Object
|
max(Closure closure)
Selects the item in the iterable which when passed as a parameter to the supplied closure returns the maximum value. |
Object
|
max(Comparator comparator)
Selects the maximum value found in the Iterable using the given comparator. |
Object
|
min()
Adds min() method to Collection objects. |
Object
|
min(Closure closure)
Selects the item in the iterable which when passed as a parameter to the supplied closure returns the minimum value. |
Object
|
min(Comparator comparator)
Selects the minimum value found in the Iterable using the given comparator. |
Collection
|
minus(Iterable removeMe)
Create a new Collection composed of the elements of the first Iterable minus every occurrence of elements of the given Iterable. |
Collection
|
minus(Object removeMe)
Create a new Collection composed of the elements of the first Iterable minus every occurrence of the given element to remove. |
Collection
|
multiply(Number factor)
Create a Collection composed of the elements of this Iterable, repeated a certain number of times. |
Set
|
permutations()
Finds all permutations of an iterable. |
List
|
permutations(Closure function)
Finds all permutations of an iterable, applies a function to each permutation and collects the result into a list. |
Collection
|
plus(Iterable right)
Create a Collection as a union of two iterables. |
Collection
|
plus(Object right)
Create a collection as a union of an Iterable and an Object. |
int
|
size()
Provide the standard Groovy size() method for Iterable .
|
List
|
sort()
Sorts the Collection. |
List
|
sort(boolean mutate)
Sorts the Iterable. |
List
|
sort(boolean mutate, Closure closure)
Sorts this Iterable using the given Closure to determine the correct ordering. |
List
|
sort(boolean mutate, Comparator comparator)
Sorts the Iterable using the given Comparator. |
List
|
sort(Closure closure)
Sorts this Iterable using the given Closure to determine the correct ordering. |
Object
|
sum()
Sums the items in an Iterable. |
Object
|
sum(Closure closure)
Sums the result of apply a closure to each item of an Iterable. |
Object
|
sum(Object initialValue)
Sums the items in an Iterable, adding the result to some initial value. |
Object
|
sum(Object initialValue, Closure closure)
Sums the result of applying a closure to each item of an Iterable to some initial value. |
Collection
|
tail()
Returns the items from the Iterable excluding the first item. |
Collection
|
take(int num)
Returns the first num elements from the head of this Iterable.
|
Collection
|
takeRight(int num)
Returns the last num elements from the tail of this Iterable.
|
Collection
|
takeWhile(Closure condition)
Returns a Collection containing the longest prefix of the elements from this Iterable where each element passed to the given closure evaluates to true. |
List
|
toList()
Convert an Iterable to a List. |
Set
|
toSet()
Convert an Iterable to a Set. |
List
|
toSorted()
Sorts the Iterable. |
List
|
toSorted(Closure closure)
Sorts this Iterable using the given Closure to determine the correct ordering. |
List
|
toSorted(Comparator comparator)
Sorts the Iterable using the given Comparator. |
SpreadMap
|
toSpreadMap()
Creates a spreadable map from this iterable. |
Collection
|
toUnique()
Returns a Collection containing the items from the Iterable but with duplicates removed using the natural ordering of the items to determine uniqueness. |
Collection
|
toUnique(Closure condition)
Returns a Collection containing the items from the Iterable but with duplicates removed. |
Collection
|
toUnique(Comparator comparator)
Returns a Collection containing the items from the Iterable but with duplicates removed. |
List
|
withIndex()
Zips an Iterable with indices in (value, index) order. |
List
|
withIndex(int offset)
Zips an Iterable with indices in (value, index) order. |
Iterates over the contents of an iterable, and checks whether a predicate is valid for at least one element.
closure
- the closure predicate used for matchingConverts this Iterable to a Collection. Returns the original Iterable if it is already a Collection.
Example usage:
assert new HashSet().asCollection() instanceof Collection
Converts this Iterable to a List. Returns the original Iterable if it is already a List.
Example usage:
assert new HashSet().asList() instanceof List
Collates this iterable into sub-lists of length size
.
Example:
def list = [ 1, 2, 3, 4, 5, 6, 7 ] def coll = list.collate( 3 ) assert coll == [ [ 1, 2, 3 ], [ 4, 5, 6 ], [ 7 ] ]
size
- the length of each sub-list in the returned listCollates this iterable into sub-lists of length size
. Any remaining elements in
the iterable after the subdivision will be dropped if keepRemainder
is false.
Example:
def list = [ 1, 2, 3, 4, 5, 6, 7 ] def coll = list.collate( 3, false ) assert coll == [ [ 1, 2, 3 ], [ 4, 5, 6 ] ]
size
- the length of each sub-list in the returned listkeepRemainder
- if true, any remaining elements are returned as sub-lists. Otherwise they are discardedCollates this iterable into sub-lists of length size
stepping through the code step
elements for each subList.
Example:
def list = [ 1, 2, 3, 4 ] def coll = list.collate( 3, 1 ) assert coll == [ [ 1, 2, 3 ], [ 2, 3, 4 ], [ 3, 4 ], [ 4 ] ]
size
- the length of each sub-list in the returned liststep
- the number of elements to step through for each sub-listCollates this iterable into sub-lists of length size
stepping through the code step
elements for each sub-list. Any remaining elements in the iterable after the subdivision will be dropped if
keepRemainder
is false.
Example:
def list = [ 1, 2, 3, 4 ] assert list.collate( 2, 2, true ) == [ [ 1, 2 ], [ 3, 4 ] ] assert list.collate( 3, 1, true ) == [ [ 1, 2, 3 ], [ 2, 3, 4 ], [ 3, 4 ], [ 4 ] ] assert list.collate( 3, 1, false ) == [ [ 1, 2, 3 ], [ 2, 3, 4 ] ]
size
- the length of each sub-list in the returned liststep
- the number of elements to step through for each sub-listkeepRemainder
- if true, any remaining elements are returned as sub-lists. Otherwise they are discardedA variant of collectEntries for Iterable objects using the identity closure as the transform.
The source Iterable should contain a list of [key, value]
tuples or Map.Entry
objects.
def nums = [1, 10, 100, 1000] def tuples = nums.collect{ [it, it.toString().size()] } assert tuples == [[1, 1], [10, 2], [100, 3], [1000, 4]] def map = tuples.collectEntries() assert map == [1:1, 10:2, 100:3, 1000:4]
Iterates through this Iterable transforming each item using the transform
closure
and returning a map of the resulting transformed entries.
def letters = "abc" // collect letters with index using list style assert (0..2).collectEntries { index -> [index, letters[index]] } == [0:'a', 1:'b', 2:'c'] // collect letters with index using map style assert (0..2).collectEntries { index -> [(index): letters[index]] } == [0:'a', 1:'b', 2:'c']Note: When using the list-style of result, the behavior is '
def (key, value) = listResultFromClosure
'.
While we strongly discourage using a list of size other than 2, Groovy's normal semantics apply in this case;
throwing away elements after the second one and using null for the key or value for the case of a shortened list.
transform
- the closure used for transforming, which has an item from self as the parameter and
should return a Map.Entry, a Map or a two-element list containing the resulting key and valueA variant of collectEntries for Iterables using the identity closure as the transform and a supplied map as the destination of transformed entries.
collector
- the Map into which the transformed entries are putIterates through this Iterable transforming each item using the closure as a transformer into a map entry, returning the supplied map with all of the transformed entries added to it.
def letters = "abc" // collect letters with index assert (0..2).collectEntries( [:] ) { index -> [index, letters[index]] } == [0:'a', 1:'b', 2:'c'] assert (0..2).collectEntries( [4:'d'] ) { index -> [(index+1): letters[index]] } == [1:'a', 2:'b', 3:'c', 4:'d']Note: When using the list-style of result, the behavior is '
def (key, value) = listResultFromClosure
'.
While we strongly discourage using a list of size other than 2, Groovy's normal semantics apply in this case;
throwing away elements after the second one and using null for the key or value for the case of a shortened list.
If your collector Map doesn't support null keys or values, you might get a runtime error, e.g. NullPointerException or IllegalArgumentException.
collector
- the Map into which the transformed entries are puttransform
- the closure used for transforming, which has an item from self as the parameter and
should return a Map.Entry, a Map or a two-element list containing the resulting key and valueProjects each item from a source Iterable to a collection and concatenates (flattens) the resulting collections into a single list.
def nums = 1..10 def squaresAndCubesOfEvens = nums.collectMany{ it % 2 ? [] : [it**2, it**3] } assert squaresAndCubesOfEvens == [4, 8, 16, 64, 36, 216, 64, 512, 100, 1000] def animals = ['CAT', 'DOG', 'ELEPHANT'] as Set def smallAnimals = animals.collectMany{ it.size() > 3 ? [] : [it.toLowerCase()] } assert smallAnimals == ['cat', 'dog'] def orig = nums as Set def origPlusIncrements = orig.collectMany{ [it, it+1] } assert origPlusIncrements.size() == orig.size() * 2 assert origPlusIncrements.unique().size() == orig.size() + 1
projection
- a projecting Closure returning a collection of itemsProjects each item from a source collection to a result collection and concatenates (flattens) the resulting
collections adding them into the collector
.
def animals = ['CAT', 'DOG', 'ELEPHANT'] as Set def smallAnimals = animals.collectMany(['ant', 'bee']){ it.size() > 3 ? [] : [it.toLowerCase()] } assert smallAnimals == ['ant', 'bee', 'cat', 'dog'] def nums = 1..5 def origPlusIncrements = nums.collectMany([] as Set){ [it, it+1] } assert origPlusIncrements.size() == nums.size() + 1
collector
- an initial collection to add the projected items toprojection
- a projecting Closure returning a collection of itemsRecursively iterates through this Iterable transforming each non-Collection value into a new value using the closure as a transformer. Returns a potentially nested list of transformed values.
assert [2,[4,6],[8],[]] == [1,[2,3],[4],[]].collectNested { it * 2 }
transform
- the closure used to transform each item of the IterableRecursively iterates through this Iterable transforming each non-Collection value
into a new value using the transform
closure. Returns a potentially nested
collection of transformed values.
def x = [1,[2,3],[4],[]].collectNested(new Vector()) { it * 2 } assert x == [2,[4,6],[8],[]] assert x instanceof Vector
collector
- an initial Collection to which the transformed values are addedtransform
- the closure used to transform each element of the IterableAdds GroovyCollections#combinations(Iterable) as a method on Iterables.
Example usage:
assert [['a', 'b'],[1, 2, 3]].combinations() == [['a', 1], ['b', 1], ['a', 2], ['b', 2], ['a', 3], ['b', 3]]
Adds GroovyCollections#combinations(Iterable, Closure) as a method on collections.
Example usage:
assert [[2, 3],[4, 5, 6]].combinations {x,y -> x*y } == [8, 12, 10, 15, 12, 18]
function
- a closure to be called on each combinationReturns true if this iterable contains the item.
item
- an Object to be checked for containment in this iterableReturns true if this iterable contains all of the elements in the specified array.
items
- array to be checked for containment in this iterableCounts the number of occurrences which satisfy the given closure from inside this Iterable.
Example usage:
assert [2,4,2,1,3,5,2,4,3].count{ it % 2 == 0 } == 5
closure
- a closure conditionCounts the number of occurrences of the given value inside this Iterable.
Comparison is done using Groovy's == operator (using
compareTo(value) == 0
or equals(value)
).
Example usage:
assert [2,4,2,1,3,5,2,4,3].count(4) == 2
value
- the value being searched forSorts all collection members into groups determined by the supplied mapping closure and counts the group size. The closure should return the key that each item should be grouped by. The returned Map will have an entry for each distinct key returned from the closure, with each value being the frequency of items occurring for that group.
Example usage:
assert [0:2, 1:3] == [1,2,3,4,5].countBy { it % 2 }
closure
- a closure mapping items to the frequency keysReturns true
if the intersection of two iterables is empty.
assert [1,2,3].disjoint([3,4,5]) == false
assert [1,2].disjoint([3,4]) == true
right
- an Iterabletrue
if the intersection of two iterables
is empty, false
otherwise.Drops the given number of elements from the head of this Iterable.
def strings = [ 'a', 'b', 'c' ] assert strings.drop( 0 ) == [ 'a', 'b', 'c' ] assert strings.drop( 2 ) == [ 'c' ] assert strings.drop( 5 ) == [] class AbcIterable implements Iterable{ Iterator iterator() { "abc".iterator() } } def abc = new AbcIterable() assert abc.drop(0) == ['a', 'b', 'c'] assert abc.drop(1) == ['b', 'c'] assert abc.drop(3) == [] assert abc.drop(5) == []
num
- the number of elements to drop from this Iterablenum
elements,
or an empty list if it has less then num
elements.Drops the given number of elements from the tail of this Iterable.
def strings = [ 'a', 'b', 'c' ] assert strings.dropRight( 0 ) == [ 'a', 'b', 'c' ] assert strings.dropRight( 2 ) == [ 'a' ] assert strings.dropRight( 5 ) == [] class AbcIterable implements Iterable{ Iterator iterator() { "abc".iterator() } } def abc = new AbcIterable() assert abc.dropRight(0) == ['a', 'b', 'c'] assert abc.dropRight(1) == ['a', 'b'] assert abc.dropRight(3) == [] assert abc.dropRight(5) == []
num
- the number of elements to drop from this Iterablenum
elements,
or an empty list if it has less then num
elements.Returns a suffix of this Iterable where elements are dropped from the front while the given closure evaluates to true.
class HorseIterable implements Iterable{ Iterator iterator() { "horse".iterator() } } def horse = new HorseIterable() assert horse.dropWhile{ it < 'r' } == ['r', 's', 'e'] assert horse.dropWhile{ it <= 'r' } == ['s', 'e']
condition
- the closure that must evaluate to true to continue dropping elementsIterates through an Iterable, passing each item to the given closure.
closure
- the closure applied on each element foundApplies a function on each combination of the input lists.
Example usage:
[[2, 3],[4, 5, 6]].eachCombination { println "Found $it" }
function
- a closure to be called on each combinationIterates over all permutations of a collection, running a closure for each iteration.
Example usage:
def permutations = [] [1, 2, 3].eachPermutation{ permutations << it } assert permutations == [[1, 2, 3], [1, 3, 2], [2, 1, 3], [2, 3, 1], [3, 1, 2], [3, 2, 1]]
closure
- the closure to call for each permutationIterates through an iterable type, passing each item and the item's index (a counter starting at zero) to the given closure.
closure
- a Closure to operate on each itemUsed to determine if the given predicate closure is valid (i.e.&nsbp;returns
true
for all items in this iterable).
A simple example for a list:
def list = [3,4,5] def greaterThanTwo = list.every { it > 2 }
closure
- the closure predicate used for matchingIterates through the Iterable transforming items using the supplied closure and collecting any non-null results.
Example:
def list = [1,2,3] def result = list.findResults { it > 1 ? "Found $it" : null } assert result == ["Found 2", "Found 3"]
filteringTransform
- a Closure that should return either a non-null transformed value or null for items which should be discardedReturns the first item from the Iterable.
def set = [3, 4, 2] as LinkedHashSet assert set.first() == 3 // check original is unaltered assert set == [3, 4, 2] as SetThe first element returned by the Iterable's iterator is returned. If the Iterable doesn't guarantee a defined order it may appear like a random element is returned.
Flatten an Iterable. This Iterable and any nested arrays or collections have their contents (recursively) added to the new collection.
assert [1,2,3,4,5] == [1,[2,3],[[4]],[],5].flatten()
Flatten an Iterable. This Iterable and any nested arrays or collections have their contents (recursively) added to the new collection. For any non-Array, non-Collection object which represents some sort of collective type, the supplied closure should yield the contained items; otherwise, the closure should just return any element which corresponds to a leaf.
flattenUsing
- a closure to determine how to flatten non-Array, non-Collection elementsSupport the subscript operator for an Iterable. Typical usage:
// custom Iterable example: class MyIterable implements Iterable { Iterator iterator() { [1, 2, 3].iterator() } } def myIterable = new MyIterable() assert myIterable[1] == 2 // Set example: def set = [1,2,3] as LinkedHashSet assert set[1] == 2
idx
- an index value (-self.size() <= idx < self.size()) but using -ve index values will be inefficientSorts all Iterable members into groups determined by the supplied mapping closure. The closure should return the key that this item should be grouped by. The returned LinkedHashMap will have an entry for each distinct key returned from the closure, with each value being a list of items for that group.
Example usage:
assert [0:[2,4,6], 1:[1,3,5]] == [1,2,3,4,5,6].groupBy { it % 2 }
closure
- a closure mapping entries on keysSorts all Iterable members into (sub)groups determined by the supplied mapping closures. Each closure should return the key that this item should be grouped by. The returned LinkedHashMap will have an entry for each distinct 'key path' returned from the closures, with each value being a list of items for that 'group path'. Example usage:
def result = [1,2,3,4,5,6].groupBy({ it % 2 }, { it < 4 }) assert result == [1:[(true):[1, 3], (false):[5]], 0:[(true):[2], (false):[4, 6]]]Another example:
def sql = groovy.sql.Sql.newInstance(/* ... */) def data = sql.rows("SELECT * FROM a_table").groupBy({ it.column1 }, { it.column2 }, { it.column3 }) if (data.val1.val2.val3) { // there exists a record where: // a_table.column1 == val1 // a_table.column2 == val2, and // a_table.column3 == val3 } else { // there is no such record }If an empty array of closures is supplied the IDENTITY Closure will be used.
closures
- an array of closures, each mapping entries on keysSorts all Iterable members into (sub)groups determined by the supplied mapping closures. Each closure should return the key that this item should be grouped by. The returned LinkedHashMap will have an entry for each distinct 'key path' returned from the closures, with each value being a list of items for that 'group path'. Example usage:
def result = [1,2,3,4,5,6].groupBy([{ it % 2 }, { it < 4 }]) assert result == [1:[(true):[1, 3], (false):[5]], 0:[(true):[2], (false):[4, 6]]]Another example:
def sql = groovy.sql.Sql.newInstance(/* ... */) def data = sql.rows("SELECT * FROM a_table").groupBy([{ it.column1 }, { it.column2 }, { it.column3 }]) if (data.val1.val2.val3) { // there exists a record where: // a_table.column1 == val1 // a_table.column2 == val2, and // a_table.column3 == val3 } else { // there is no such record }If an empty list of closures is supplied the IDENTITY Closure will be used.
closures
- a list of closures, each mapping entries on keysReturns the first item from the Iterable.
def set = [3, 4, 2] as LinkedHashSet assert set.head() == 3 // check original is unaltered assert set == [3, 4, 2] as SetThe first element returned by the Iterable's iterator is returned. If the Iterable doesn't guarantee a defined order it may appear like a random element is returned.
Zips an Iterable with indices in (index, value) order.
Example usage:assert [0: "a", 1: "b"] == ["a", "b"].indexed() assert ["0: a", "1: b"] == ["a", "b"].indexed().collect { idx, str -> "$idx: $str" }
Zips an Iterable with indices in (index, value) order.
Example usage:assert [5: "a", 6: "b"] == ["a", "b"].indexed(5) assert ["1: a", "2: b"] == ["a", "b"].indexed(1).collect { idx, str -> "$idx: $str" }
offset
- an index to start fromReturns the items from the Iterable excluding the last item. Leaves the original Iterable unchanged.
def list = [3, 4, 2] assert list.init() == [3, 4] assert list == [3, 4, 2]
Create a Collection composed of the intersection of both iterables. Any elements that exist in both iterables are added to the resultant collection.
assert [4,5] == [1,2,3,4,5].intersect([4,5,6,7,8])
right
- an IterableConcatenates the toString()
representation of each
item in this Iterable, with the given String as a separator between each item.
assert "1, 2, 3" == [1,2,3].join(", ")
separator
- a String separatorReturns the last item from the Iterable.
def set = [3, 4, 2] as LinkedHashSet assert set.last() == 2 // check original unaltered assert set == [3, 4, 2] as SetThe first element returned by the Iterable's iterator is returned. If the Iterable doesn't guarantee a defined order it may appear like a random element is returned.
Adds max() method to Iterable objects.
assert 5 == [2,3,1,5,4].max()
Selects the item in the iterable which when passed as a parameter to the supplied closure returns the maximum value. A null return value represents the least possible return value, so any item for which the supplied closure returns null, won't be selected (unless all items return null). If more than one item has the maximum value, an arbitrary choice is made between the items having the maximum value.
If the closure has two parameters it is used like a traditional Comparator. I.e. it should compare its two parameters for order, returning a negative integer, zero, or a positive integer when the first parameter is less than, equal to, or greater than the second respectively. Otherwise, the Closure is assumed to take a single parameter and return a Comparable (typically an Integer) which is then used for further comparison.
assert "hello" == ["hello","hi","hey"].max { it.length() }
assert "hello" == ["hello","hi","hey"].max { a, b -> a.length() <=> b.length() }
def pets = ['dog', 'elephant', 'anaconda'] def longestName = pets.max{ it.size() } // one of 'elephant' or 'anaconda' assert longestName.size() == 8
closure
- a 1 or 2 arg Closure used to determine the correct orderingSelects the maximum value found in the Iterable using the given comparator.
assert "hello" == ["hello","hi","hey"].max( { a, b -> a.length() <=> b.length() } as Comparator )
comparator
- a ComparatorAdds min() method to Collection objects.
assert 2 == [4,2,5].min()
Selects the item in the iterable which when passed as a parameter to the supplied closure returns the minimum value. A null return value represents the least possible return value. If more than one item has the minimum value, an arbitrary choice is made between the items having the minimum value.
If the closure has two parameters it is used like a traditional Comparator. I.e. it should compare its two parameters for order, returning a negative integer, zero, or a positive integer when the first parameter is less than, equal to, or greater than the second respectively. Otherwise, the Closure is assumed to take a single parameter and return a Comparable (typically an Integer) which is then used for further comparison.
assert "hi" == ["hello","hi","hey"].min { it.length() }
def lastDigit = { a, b -> a % 10 <=> b % 10 } assert [19, 55, 91].min(lastDigit) == 91
def pets = ['dog', 'cat', 'anaconda'] def shortestName = pets.min{ it.size() } // one of 'dog' or 'cat' assert shortestName.size() == 3
closure
- a 1 or 2 arg Closure used to determine the correct orderingSelects the minimum value found in the Iterable using the given comparator.
assert "hi" == ["hello","hi","hey"].min( { a, b -> a.length() <=> b.length() } as Comparator )
comparator
- a ComparatorCreate a new Collection composed of the elements of the first Iterable minus every occurrence of elements of the given Iterable.
assert [1, "a", true, true, false, 5.3] - [true, 5.3] == [1, "a", false]
removeMe
- an Iterable of elements to removeCreate a new Collection composed of the elements of the first Iterable minus every occurrence of the given element to remove.
assert ["a", 5, 5, true] - 5 == ["a", true]
removeMe
- an element to remove from the IterableCreate a Collection composed of the elements of this Iterable, repeated a certain number of times. Note that for non-primitive elements, multiple references to the same instance will be added.
assert [1,2,3,1,2,3] == [1,2,3] * 2Note: if the Iterable happens to not support duplicates, e.g. a Set, then the method will effectively return a Collection with a single copy of the Iterable's items.
factor
- the number of times to appendFinds all permutations of an iterable.
Example usage:
def result = [1, 2, 3].permutations() assert result == [[3, 2, 1], [3, 1, 2], [1, 3, 2], [2, 3, 1], [2, 1, 3], [1, 2, 3]] as Set
Finds all permutations of an iterable, applies a function to each permutation and collects the result into a list.
Example usage:
Set result = [1, 2, 3].permutations { it.collect { v -> 2*v }} assert result == [[6, 4, 2], [6, 2, 4], [2, 6, 4], [4, 6, 2], [4, 2, 6], [2, 4, 6]] as Set
function
- the function to apply on each permutationCreate a Collection as a union of two iterables. If the left iterable is a Set, then the returned collection will be a Set otherwise a List. This operation will always create a new object for the result, while the operands remain unchanged.
assert [1,2,3,4] == [1,2] + [3,4]
right
- the right IterableCreate a collection as a union of an Iterable and an Object. If the iterable is a Set, then the returned collection will be a Set otherwise a List. This operation will always create a new object for the result, while the operands remain unchanged.
assert [1,2,3] == [1,2] + 3
right
- an object to add/appendProvide the standard Groovy size()
method for Iterable
.
def items = [1, 2, 3] def iterable = { [ hasNext:{ !items.isEmpty() }, next:{ items.pop() } ] as Iterator } as Iterable assert iterable.size() == 3
Sorts the Collection. Assumes that the collection items are comparable and uses their natural ordering to determine the resulting order. If the Collection is a List, it is sorted in place and returned. Otherwise, the elements are first placed into a new list which is then sorted and returned - leaving the original Collection unchanged.
assert [1,2,3] == [3,1,2].sort()
Sorts the Iterable. Assumes that the Iterable items are comparable and uses their natural ordering to determine the resulting order. If the Iterable is a List and mutate is true, it is sorted in place and returned. Otherwise, the elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
assert [1,2,3] == [3,1,2].sort()
def orig = [1, 3, 2] def sorted = orig.sort(false) assert orig == [1, 3, 2] assert sorted == [1, 2, 3]
mutate
- false will always cause a new list to be created, true will mutate lists in placeSorts this Iterable using the given Closure to determine the correct ordering. If the Iterable is a List and mutate is true, it is sorted in place and returned. Otherwise, the elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
If the closure has two parameters it is used like a traditional Comparator. I.e. it should compare its two parameters for order, returning a negative integer, zero, or a positive integer when the first parameter is less than, equal to, or greater than the second respectively. Otherwise, the Closure is assumed to take a single parameter and return a Comparable (typically an Integer) which is then used for further comparison.
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { it.length() }
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { a, b -> a.length() <=> b.length() }
def orig = ["hello","hi","Hey"] def sorted = orig.sort(false) { it.toUpperCase() } assert orig == ["hello","hi","Hey"] assert sorted == ["hello","Hey","hi"]
mutate
- false will always cause a new list to be created, true will mutate lists in placeclosure
- a 1 or 2 arg Closure used to determine the correct orderingSorts the Iterable using the given Comparator. If the Iterable is a List and mutate is true, it is sorted in place and returned. Otherwise, the elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort( { a, b -> a.length() <=> b.length() } as Comparator )
def orig = ["hello","hi","Hey"] def sorted = orig.sort(false, String.CASE_INSENSITIVE_ORDER) assert orig == ["hello","hi","Hey"] assert sorted == ["hello","Hey","hi"]
mutate
- false will always cause a new list to be created, true will mutate lists in placecomparator
- a Comparator used for the comparisonSorts this Iterable using the given Closure to determine the correct ordering. If the Iterable is a List, it is sorted in place and returned. Otherwise, the elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
If the Closure has two parameters it is used like a traditional Comparator. I.e. it should compare its two parameters for order, returning a negative integer, zero, or a positive integer when the first parameter is less than, equal to, or greater than the second respectively. Otherwise, the Closure is assumed to take a single parameter and return a Comparable (typically an Integer) which is then used for further comparison.
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { it.length() }
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { a, b -> a.length() <=> b.length() }
closure
- a 1 or 2 arg Closure used to determine the correct orderingSums the items in an Iterable. This is equivalent to invoking the "plus" method on all items in the Iterable.
assert 1+2+3+4 == [1,2,3,4].sum()
Sums the result of apply a closure to each item of an Iterable.
coll.sum(closure)
is equivalent to:
coll.collect(closure).sum()
.
assert 4+6+10+12 == [2,3,5,6].sum { it * 2 }
closure
- a single parameter closure that returns a numeric value.Sums the items in an Iterable, adding the result to some initial value.
assert 5+1+2+3+4 == [1,2,3,4].sum(5)
initialValue
- the items in the collection will be summed to this initial valueSums the result of applying a closure to each item of an Iterable to some initial value.
coll.sum(initVal, closure)
is equivalent to:
coll.collect(closure).sum(initVal)
.
assert 50+4+6+10+12 == [2,3,5,6].sum(50) { it * 2 }
closure
- a single parameter closure that returns a numeric value.initialValue
- the closure results will be summed to this initial valueReturns the items from the Iterable excluding the first item.
def list = [3, 4, 2] assert list.tail() == [4, 2] assert list == [3, 4, 2]
Returns the first num
elements from the head of this Iterable.
def strings = [ 'a', 'b', 'c' ] assert strings.take( 0 ) == [] assert strings.take( 2 ) == [ 'a', 'b' ] assert strings.take( 5 ) == [ 'a', 'b', 'c' ] class AbcIterable implements Iterable{ Iterator iterator() { "abc".iterator() } } def abc = new AbcIterable() assert abc.take(0) == [] assert abc.take(1) == ['a'] assert abc.take(3) == ['a', 'b', 'c'] assert abc.take(5) == ['a', 'b', 'c']
num
- the number of elements to take from this Iterablenum
elements from this Iterable,
or else all the elements from the Iterable if it has less then num
elements.Returns the last num
elements from the tail of this Iterable.
def strings = [ 'a', 'b', 'c' ] assert strings.takeRight( 0 ) == [] assert strings.takeRight( 2 ) == [ 'b', 'c' ] assert strings.takeRight( 5 ) == [ 'a', 'b', 'c' ] class AbcIterable implements Iterable{ Iterator iterator() { "abc".iterator() } } def abc = new AbcIterable() assert abc.takeRight(0) == [] assert abc.takeRight(1) == ['c'] assert abc.takeRight(3) == ['a', 'b', 'c'] assert abc.takeRight(5) == ['a', 'b', 'c']
num
- the number of elements to take from this Iterablenum
elements from this Iterable,
or else all the elements from the Iterable if it has less then num
elements.Returns a Collection containing the longest prefix of the elements from this Iterable where each element passed to the given closure evaluates to true.
class AbcIterable implements Iterable{ Iterator iterator() { "abc".iterator() } } def abc = new AbcIterable() assert abc.takeWhile{ it < 'b' } == ['a'] assert abc.takeWhile{ it <= 'b' } == ['a', 'b']
condition
- the closure that must evaluate to true to
continue taking elementsConvert an Iterable to a List. The Iterable's iterator will become exhausted of elements after making this conversion.
Example usage:
def x = [1,2,3] as HashSet assert x.class == HashSet assert x.toList() instanceof List
Convert an Iterable to a Set. Always returns a new Set even if the Iterable is already a Set.
Example usage:
def result = [1, 2, 2, 2, 3].toSet() assert result instanceof Set assert result == [1, 2, 3] as Set
Sorts the Iterable. Assumes that the Iterable elements are
comparable and uses a NumberAwareComparator to determine the resulting order.
NumberAwareComparator
has special treatment for numbers but otherwise uses the
natural ordering of the Iterable elements. The elements are first placed into a new list which
is then sorted and returned - leaving the original Iterable unchanged.
def orig = [1, 3, 2] def sorted = orig.toSorted() assert orig == [1, 3, 2] assert sorted == [1, 2, 3]
Sorts this Iterable using the given Closure to determine the correct ordering. The elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
If the Closure has two parameters it is used like a traditional Comparator. I.e. it should compare its two parameters for order, returning a negative integer, zero, or a positive integer when the first parameter is less than, equal to, or greater than the second respectively. Otherwise, the Closure is assumed to take a single parameter and return a Comparable (typically an Integer) which is then used for further comparison.
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { it.length() }
assert ["hi","hey","hello"] == ["hello","hi","hey"].sort { a, b -> a.length() <=> b.length() }
closure
- a 1 or 2 arg Closure used to determine the correct orderingSorts the Iterable using the given Comparator. The elements are first placed into a new list which is then sorted and returned - leaving the original Iterable unchanged.
def orig = ["hello","hi","Hey"] def sorted = orig.toSorted(String.CASE_INSENSITIVE_ORDER) assert orig == ["hello","hi","Hey"] assert sorted == ["hello","Hey","hi"]
comparator
- a Comparator used for the comparisonCreates a spreadable map from this iterable.
Returns a Collection containing the items from the Iterable but with duplicates removed using the natural ordering of the items to determine uniqueness.
String[] letters = ['c', 'a', 't', 's', 'a', 't', 'h', 'a', 't'] String[] expected = ['c', 'a', 't', 's', 'h'] assert letters.toUnique() == expected
Returns a Collection containing the items from the Iterable but with duplicates removed. The items in the Iterable are compared by the given Closure condition. For each duplicate, the first member which is returned from the Iterable is retained, but all other ones are removed.
If the closure takes a single parameter, each element from the Iterable will be passed to the closure. The closure should return a value used for comparison (either using Comparable#compareTo(java.lang.Object) or Object#equals(java.lang.Object)). If the closure takes two parameters, two items from the Iterable will be passed as arguments, and the closure should return an int value (with 0 indicating the items are not unique).
class Person { def fname, lname String toString() { return fname + " " + lname } } Person a = new Person(fname:"John", lname:"Taylor") Person b = new Person(fname:"Clark", lname:"Taylor") Person c = new Person(fname:"Tom", lname:"Cruz") Person d = new Person(fname:"Clark", lname:"Taylor") def list = [a, b, c, d] def list2 = list.toUnique{ p1, p2 -> p1.lname != p2.lname ? p1.lname <=> p2.lname : p1.fname <=> p2.fname } assert( list2 == [a, b, c] && list == [a, b, c, d] ) def list3 = list.toUnique{ it.toString() } assert( list3 == [a, b, c] && list == [a, b, c, d] )
condition
- a Closure used to determine unique itemsReturns a Collection containing the items from the Iterable but with duplicates removed. The items in the Iterable are compared by the given Comparator. For each duplicate, the first member which is returned from the Iterable is retained, but all other ones are removed.
class Person { def fname, lname String toString() { return fname + " " + lname } } class PersonComparator implements Comparator { int compare(Object o1, Object o2) { Person p1 = (Person) o1 Person p2 = (Person) o2 if (p1.lname != p2.lname) return p1.lname.compareTo(p2.lname) else return p1.fname.compareTo(p2.fname) } boolean equals(Object obj) { return this.equals(obj) } } Person a = new Person(fname:"John", lname:"Taylor") Person b = new Person(fname:"Clark", lname:"Taylor") Person c = new Person(fname:"Tom", lname:"Cruz") Person d = new Person(fname:"Clark", lname:"Taylor") def list = [a, b, c, d] List list2 = list.toUnique(new PersonComparator()) assert( list2 == list && list == [a, b, c] )
comparator
- a Comparator used to determine unique (equal) items
If null
, the Comparable natural ordering of the elements will be used.Zips an Iterable with indices in (value, index) order.
Example usage:assert [["a", 0], ["b", 1]] == ["a", "b"].withIndex() assert ["0: a", "1: b"] == ["a", "b"].withIndex().collect { str, idx -> "$idx: $str" }
Zips an Iterable with indices in (value, index) order.
Example usage:assert [["a", 5], ["b", 6]] == ["a", "b"].withIndex(5) assert ["1: a", "2: b"] == ["a", "b"].withIndex(1).collect { str, idx -> "$idx: $str" }
offset
- an index to start from