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8

It all boils down to type. What type would you like a dynamic accessor such as _<position> to have? In the general case, the only valid one would be Any. In a strongly-typed language such as Scala this is useless for most purposes. The good news is that the problem can be handled in a type-safe manner - see e.g. the HList-style tuple handling in ...


6

For tuples there is an productIterator method that gives you an opportunity to iterate over elements of tuple. But obviously each element of such iteration will be of type Any


4

I think this can be a solution for any type of matrix. #include <stdio.h> #define M 3 #define N 4 main(){ int a[M][N] = {{1, 2, 3, 4}, {5, 6, 7, 8}, {9,10,11,12}}; int i, j, t; for( t = 0; t<M+N; ++t) for( i=t, j=0; i>=0 ; --i, ++j) ...


3

I understand that it is clearly stated that Tuples are not iterable, but if ._1 works , shouldn't ._i work the same way ? Why should it? In one case you are calling the method _1 (which does exist), in the other case you are calling the method _i (which doesn't exist). Calling two different methods usually does not "work the same way", especially if one of ...


2

As @Bergi wrote if you manually maintain stack the solution is straightforward. const o = {x:0,c:[{x:1,c:[{x:2,c:[{x:3},{x:4,c:[{x:5}]},{x:6}]},{x:7},{x:8}]},{x:9}]} const traverse = g => { const dfs = (stack, head) => (head.c || []).concat(stack) const loop = (acc, stack) => { if (stack.length === 0) { return acc } ...


1

My question is how this calculated, and how we can say this Heuristic is Admissible and Consistent? Let's first start with definitions of what are admissible and consistent heuristics: An admissible heuristic never overestimates the cost of reaching the goal, i.e. the cost estimated to reach the goal is not greater than the cost of the shortest path from ...


1

You can divide the image into blocks and tile them along a third dimension using this great answer. You then loop over a random permutation of the third dimension indices: A = randn(12,12); m = 3; n = 6; T = permute(reshape(permute(reshape(A, size(A, 1), n, []), [2 1 3]), n, m, []), [2 1 3]); % each third-dim slice is an mxn block scan_order = randperm(size(...


1

Easy, let's make an example with small matrix (6x6) Im = rand(6,6); nblocks = 9; blocksize = 2; You will have blocks of size 2x2 (in total 3x3=9 blocks). Reshape the matrix into a 2 x 18 matrix. Im = reshape(Im, numel(Im)/blocksize, blocksize); Now generate a random permutation of indexes separated by the size of the block: idx = randperm(nblocks) * ...


1

You could provide an Iterator[U] where U is the least upper bound of the types T1 to Tn of the tuple. implicit class FancyTuple2[T1,T2,U](private val tuple: (T1 with U,T2 with U)) extends AnyVal { def iterator: Iterator[U] = Iterator(tuple._1, tuple._2) } You'd have to write (or generate) this for every arity that you need a tuple of.



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