// std.array
@property bool empty(T)(in T[] a) { return !a.length; }
@property ref T front(T)(T[] a) { return a[0]; }
void popFront(T)(ref T[] a) { a = a[1 .. $]; }
// std.typecons
struct Tuple(T...)
{
T field;
alias field this;
}
Tuple!T tuple(T...)(T args) { return typeof(return)(args); }
// std.range
template ElementType(R)
{
static if (is(typeof(R.init.front.init) T))
alias T ElementType;
else
alias void ElementType;
}
struct Repeat(T)
{
private T _value;
enum bool empty = false;
@property inout(T) front() inout { return _value; }
void popFront() {}
}
Repeat!T repeat(T)(T value) { return Repeat!T(value); }
struct Zip(R...)
{
//alias Tuple!(staticMap!(.ElementType, R)) ElementType;
static if (R.length == 3)
alias Tuple!(int, int, int) ElementType;
static if (R.length == 2)
alias Tuple!(int, int) ElementType;
R ranges;
this(R rs)
{
foreach (i, Unused; R)
{
ranges[i] = rs[i];
}
}
@property bool empty()
{
foreach (i, Unused; R)
{
if (ranges[i].empty)
return true;
}
return false;
}
@property ElementType front()
{
ElementType result;
return result;
}
void popFront()
{
foreach (i, Unused; R)
{
ranges[i].popFront();
}
}
ElementType opIndex(size_t n)
{
ElementType result;
return result;
}
}
auto zip(Rs...)(Rs ranges) { return Zip!Rs(ranges); }
// std.algorithm
template map(fun...)
{
auto map(Range)(Range r)
{
return MapResult!(fun, Range)(r);
}
}
private struct MapResult(alias fun, R)
{
R _input;
this(R input)
{
_input = input;
}
@property bool empty() { return _input.empty; }
@property auto ref front() { return fun(_input.front); }
void popFront() { _input.popFront(); }
}
auto cartesianProduct(R1, R2)(R1 range1, R2 range2)
{
return range2.map!((ElementType!R2 a) => zip(range1, repeat(a)));
}
auto cartesianProduct(R1, R2, RR...)(R1 range1, R2 range2, RR otherRanges)
{
return map!(a => tuple(a[0], a[1][0], a[1][1]))(
cartesianProduct(range1, cartesianProduct(range2, otherRanges))
);
}
// test
void main()
{
foreach (i, j, k; cartesianProduct([1], [1], [1])) {}
}