std.algorithm.setops
Function Name | Description |
---|---|
cartesianProduct | Computes Cartesian product of two ranges. |
largestPartialIntersection | Copies out the values that occur most frequently in a range of ranges. |
largestPartialIntersectionWeighted | Copies out the values that occur most frequently (multiplied by per-value weights) in a range of ranges. |
nWayUnion | Computes the union of a set of sets implemented as a range of sorted ranges. |
setDifference | Lazily computes the set difference of two or more sorted ranges. |
setIntersection | Lazily computes the intersection of two or more sorted ranges. |
setSymmetricDifference | Lazily computes the symmetric set difference of two or more sorted ranges. |
Source: std/algorithm/setops.d
- auto
cartesianProduct
(R1, R2)(R1range1
, R2range2
)
if (!allSatisfy!(isForwardRange, R1, R2) || anySatisfy!(isInfinite, R1, R2));
autocartesianProduct
(RR...)(RRranges
)
if (ranges
.length >= 2 && allSatisfy!(isForwardRange, RR) && !anySatisfy!(isInfinite, RR));
autocartesianProduct
(R1, R2, RR...)(R1range1
, R2range2
, RRotherRanges
)
if (!allSatisfy!(isForwardRange, R1, R2, RR) || anySatisfy!(isInfinite, R1, R2, RR)); - Lazily computes the Cartesian product of two or more
ranges
. The product is a range of tuples of elements from each respective range.The conditions for the two-range case are as follows: If bothranges
are finite, then one must be (at least) a forward range and the other an input range. If one range is infinite and the other finite, then the finite range must be a forward range, and the infinite range can be an input range. If bothranges
are infinite, then both must be forwardranges
. When there are more than tworanges
, the above conditions apply to each adjacent pair ofranges
.Parameters:R1 range1
The first range R2 range2
The second range RR ranges
Two or more non-infinite forward ranges
RR otherRanges
Zero or more non-infinite forward ranges
Returns:A forward range of std.typecons.Tuple representing elements of the cartesian product of the givenranges
.Examples:import std.algorithm.searching : canFind; import std.range; import std.typecons : tuple; auto N = sequence!"n"(0); // the range of natural numbers auto N2 = cartesianProduct(N, N); // the range of all pairs of natural numbers // Various arbitrary number pairs can be found in the range in finite time. assert(canFind(N2, tuple(0, 0))); assert(canFind(N2, tuple(123, 321))); assert(canFind(N2, tuple(11, 35))); assert(canFind(N2, tuple(279, 172)));
Examples:import std.algorithm.searching : canFind; import std.typecons : tuple; auto B = [ 1, 2, 3 ]; auto C = [ 4, 5, 6 ]; auto BC = cartesianProduct(B, C); foreach (n; [[1, 4], [2, 4], [3, 4], [1, 5], [2, 5], [3, 5], [1, 6], [2, 6], [3, 6]]) { assert(canFind(BC, tuple(n[0], n[1]))); }
Examples:import std.algorithm.comparison : equal; import std.typecons : tuple; auto A = [ 1, 2, 3 ]; auto B = [ 'a', 'b', 'c' ]; auto C = [ "x", "y", "z" ]; auto ABC = cartesianProduct(A, B, C); assert(ABC.equal([ tuple(1, 'a', "x"), tuple(1, 'a', "y"), tuple(1, 'a', "z"), tuple(1, 'b', "x"), tuple(1, 'b', "y"), tuple(1, 'b', "z"), tuple(1, 'c', "x"), tuple(1, 'c', "y"), tuple(1, 'c', "z"), tuple(2, 'a', "x"), tuple(2, 'a', "y"), tuple(2, 'a', "z"), tuple(2, 'b', "x"), tuple(2, 'b', "y"), tuple(2, 'b', "z"), tuple(2, 'c', "x"), tuple(2, 'c', "y"), tuple(2, 'c', "z"), tuple(3, 'a', "x"), tuple(3, 'a', "y"), tuple(3, 'a', "z"), tuple(3, 'b', "x"), tuple(3, 'b', "y"), tuple(3, 'b', "z"), tuple(3, 'c', "x"), tuple(3, 'c', "y"), tuple(3, 'c', "z") ]));
- void
largestPartialIntersection
(alias less = "a < b", RangeOfRanges, Range)(RangeOfRangesror
, Rangetgt
, SortOutputsorted
= No.sortOutput); - Given a range of
sorted
forward rangesror
, copies totgt
the elements that are common to most ranges, along with their number of occurrences. All ranges inror
are assumed to besorted
by less. Only the most frequenttgt
.length elements are returned.Parameters:less The predicate the ranges are sorted
by.RangeOfRanges ror
A range of forward ranges sorted
by less.Range tgt
The target range to copy common elements to. SortOutput sorted
Whether the elements copied should be in sorted
order. The functionlargestPartialIntersection
is useful for e.g. searching an inverted index for the documents most likely to contain some terms of interest. The complexity of the search is Ο(n * log(tgt
.length)), where n is the sum of lengths of all input ranges. This approach is faster than keeping an associative array of the occurrences and then selecting its top items, and also requires less memory (largestPartialIntersection
builds its result directly intgt
and requires no extra memory).Warning: Because
largestPartialIntersection
does not allocate extra memory, it will leaveror
modified. Namely,largestPartialIntersection
assumes ownership ofror
and discretionarily swaps and advances elements of it. If you wantror
to preserve its contents after the call, you may want to pass a duplicate tolargestPartialIntersection
(and perhaps cache the duplicate in between calls).Examples:import std.typecons : tuple, Tuple; // Figure which number can be found in most arrays of the set of // arrays below. double[][] a = [ [ 1, 4, 7, 8 ], [ 1, 7 ], [ 1, 7, 8], [ 4 ], [ 7 ], ]; auto b = new Tuple!(double, uint)[1]; // it will modify the input range, hence we need to create a duplicate largestPartialIntersection(a.dup, b); // First member is the item, second is the occurrence count assert(b[0] == tuple(7.0, 4u)); // 7.0 occurs in 4 out of 5 inputs, more than any other number // If more of the top-frequent numbers are needed, just create a larger // tgt range auto c = new Tuple!(double, uint)[2]; largestPartialIntersection(a, c); assert(c[0] == tuple(1.0, 3u)); // 1.0 occurs in 3 inputs
- void
largestPartialIntersectionWeighted
(alias less = "a < b", RangeOfRanges, Range, WeightsAA)(RangeOfRangesror
, Rangetgt
, WeightsAAweights
, SortOutputsorted
= No.sortOutput); - Similar to largestPartialIntersection, but associates a weight with each distinct element in the intersection.Parameters:
less The predicate the ranges are sorted
by.RangeOfRanges ror
A range of forward ranges sorted
by less.Range tgt
The target range to copy common elements to. WeightsAA weights
An associative array mapping elements to weights
.SortOutput sorted
Whether the elements copied should be in sorted
order.Examples:import std.typecons : tuple, Tuple; // Figure which number can be found in most arrays of the set of // arrays below, with specific per-element weights double[][] a = [ [ 1, 4, 7, 8 ], [ 1, 7 ], [ 1, 7, 8], [ 4 ], [ 7 ], ]; auto b = new Tuple!(double, uint)[1]; double[double] weights = [ 1:1.2, 4:2.3, 7:1.1, 8:1.1 ]; largestPartialIntersectionWeighted(a, b, weights); // First member is the item, second is the occurrence count assert(b[0] == tuple(4.0, 2u)); // 4.0 occurs 2 times -> 4.6 (2 * 2.3) // 7.0 occurs 3 times -> 4.4 (3 * 1.1)
- struct
NWayUnion
(alias less, RangeOfRanges);
NWayUnion!(less, RangeOfRanges)nWayUnion
(alias less = "a < b", RangeOfRanges)(RangeOfRangesror
); - Computes the union of multiple sets. The input sets are passed as a range of ranges and each is assumed to be sorted by less. Computation is done lazily, one union element at a time. The complexity of one popFront operation is Ο(log(
ror
.length)). However, the length ofror
decreases as ranges in it are exhausted, so the complexity of a full pass throughNWayUnion
is dependent on the distribution of the lengths of ranges contained withinror
. If all ranges have the same length n (worst case scenario), the complexity of a full pass throughNWayUnion
is Ο(n *ror
.length * log(ror
.length)), i.e., log(ror
.length) times worse than just spanning all ranges in turn. The output comes sorted (unstably) by less.Parameters:less Predicate the given ranges are sorted by. RangeOfRanges ror
A range of ranges sorted by less to compute the union for. Returns:A range of the union of the ranges inror
.Warning: Because
NWayUnion
does not allocate extra memory, it will leaveror
modified. Namely,NWayUnion
assumes ownership ofror
and discretionarily swaps and advances elements of it. If you wantror
to preserve its contents after the call, you may want to pass a duplicate toNWayUnion
(and perhaps cache the duplicate in between calls).Examples:import std.algorithm.comparison : equal; double[][] a = [ [ 1, 4, 7, 8 ], [ 1, 7 ], [ 1, 7, 8], [ 4 ], [ 7 ], ]; auto witness = [ 1, 1, 1, 4, 4, 7, 7, 7, 7, 8, 8 ]; assert(equal(nWayUnion(a), witness));
- static bool
compFront
(.ElementType!RangeOfRangesa
, .ElementType!RangeOfRangesb
); - this(RangeOfRanges
ror
); - @property bool
empty
(); - @property ref auto
front
(); - void
popFront
();
- struct
SetDifference
(alias less = "a < b", R1, R2) if (isInputRange!R1 && isInputRange!R2);
SetDifference!(less, R1, R2)setDifference
(alias less = "a < b", R1, R2)(R1r1
, R2r2
); - Lazily computes the difference of
r1
andr2
. The two ranges are assumed to be sorted by less. The element types of the two ranges must have a common type.Parameters:less Predicate the given ranges are sorted by. R1 r1
The first range. R2 r2
The range to subtract from r1
.Returns:A range of the difference ofr1
andr2
.See Also:Examples:import std.algorithm.comparison : equal; import std.range.primitives : isForwardRange; int[] a = [ 1, 2, 4, 5, 7, 9 ]; int[] b = [ 0, 1, 2, 4, 7, 8 ]; assert(equal(setDifference(a, b), [5, 9][])); static assert(isForwardRange!(typeof(setDifference(a, b))));
- this(R1
r1
, R2r2
); - void
popFront
(); - @property ref auto
front
(); - @property typeof(this)
save
(); - @property bool
empty
();
- struct
SetIntersection
(alias less = "a < b", Rs...) if (Rs.length >= 2 && allSatisfy!(isInputRange, Rs) && !is(CommonType!(staticMap!(ElementType, Rs)) == void));
SetIntersection!(less, Rs)setIntersection
(alias less = "a < b", Rs...)(Rsranges
)
if (Rs.length >= 2 && allSatisfy!(isInputRange, Rs) && !is(CommonType!(staticMap!(ElementType, Rs)) == void)); - Lazily computes the intersection of two or more input
ranges
ranges
. Theranges
are assumed to be sorted by less. The element types of theranges
must have a common type.Parameters:less Predicate the given ranges
are sorted by.Rs ranges
The ranges
to compute the intersection for.Returns:A range containing the intersection of the givenranges
.Examples:import std.algorithm.comparison : equal; int[] a = [ 1, 2, 4, 5, 7, 9 ]; int[] b = [ 0, 1, 2, 4, 7, 8 ]; int[] c = [ 0, 1, 4, 5, 7, 8 ]; assert(equal(setIntersection(a, a), a)); assert(equal(setIntersection(a, b), [1, 2, 4, 7])); assert(equal(setIntersection(a, b, c), [1, 4, 7]));
- this(Rs
input
); - @property bool
empty
(); - void
popFront
(); - @property ElementType
front
(); - @property SetIntersection
save
();
- struct
SetSymmetricDifference
(alias less = "a < b", R1, R2) if (isInputRange!R1 && isInputRange!R2);
SetSymmetricDifference!(less, R1, R2)setSymmetricDifference
(alias less = "a < b", R1, R2)(R1r1
, R2r2
); - Lazily computes the symmetric difference of
r1
andr2
, i.e. the elements that are present in exactly one ofr1
andr2
. The two ranges are assumed to be sorted by less, and the output is also sorted by less. The element types of the two ranges must have a common type.If both arguments are ranges of L-values of the same type thenSetSymmetricDifference
will also be a range of L-values of that type.Parameters:less Predicate the given ranges are sorted by. R1 r1
The first range. R2 r2
The second range. Returns:A range of the symmetric difference betweenr1
andr2
.See Also:Examples:import std.algorithm.comparison : equal; import std.range.primitives : isForwardRange; int[] a = [ 1, 2, 4, 5, 7, 9 ]; int[] b = [ 0, 1, 2, 4, 7, 8 ]; assert(equal(setSymmetricDifference(a, b), [0, 5, 8, 9][])); static assert(isForwardRange!(typeof(setSymmetricDifference(a, b))));
- this(R1
r1
, R2r2
); - void
popFront
(); - @property ref auto
front
(); - @property typeof(this)
save
(); - ref auto
opSlice
(); - @property bool
empty
();