We consider a bit matrix (n x m) to be a regular array integers of size m containing n lines.
I have looked in Hacker's Delight and in other sources, the algorithms I found for this were rather specialized : square matrices of a size in powers of two, 8x8, 32x32, 64x64 (which is normal because the machine is built that way).
I thought of a more general algorithm (for arbitrary n and m) which is, in the worse case, of the expected complexity (I think), but for matrices containing mostly similar columns, or more zeros than ones, the algorithm seems a bit more interesting (in the extreme, it is linear if the matrix contains the same line over and over). It follows a sort of Binary Decision Diagram manipulation.
The output is not a transposed matrix but a compressed transposed matrix: a list of pairs (V,L) where L is an int_m that indicates the lines of the transposed matrix (by setting the bits of the corresponding position) that should contain the int_n V. The lines of the transposed matrix not appearing in any of the pairs are filled with 0.
For example, for the matrix
1010111 1111000 0001010
having the transposed
110 010 110 011 100 101 100
the algorithm outputs (010,0100000)(011,0001000)(100,0000101)(101,0000010)(110,1010000) and one reads the pair (100,0000101) as meaning "the value 100 is put in the 5th and the 7th line of the transposed matrix".
This is the algorithm (written in a pseudo-OCaml/C) and a picture of the progress of the algorithm on the above example.
We will run according to triples (index_of_current_line, V, L), which is of type
(int, int_n, int_m), where
int_n is the type of n-bit wide integers and
int is just a machine integer wide enough to hold n.
The function takes a list of these triples, the matrix, the number of lines and an accumulator for the output (list of pairs (int_m, int_n)) and returns, at some point, that accumulator.
list of (int_n, int_m) transpose(list of triple t, int_m[n] mat, int n, list of (int_n, int_m) acc)
The first call of the transpose function is
transpose([(0, 0, 2^m-1)], mat, n, ).
take "&", "|" "xor" to be the usual bit-wise operations
transpose(t, mat, n, acc) = match t with |  -> (* the list is empty, we're done *) return acc | (i, v, l)::tt -> let colIn = mat[i] & l in (* colIn contains the positions that were set in the parent's mask "l" and that are also set in the line "i" *) match colIn with |0 -> (* None of the positions are set in both, do not branch *) if (i<n) then (* not done with the matrix, simply move to next line *) transpose((i+1,v,l)::tt,mat,n,acc) else (* we reached the end of the matrix, we're at a leaf *) if (v>0) then transpose(tt,mat,n,(v,l)::acc) else (* We ignore the null values and continue *) transpose(tt,mat,n,acc) |_ -> (* colIn is non null, ie some of the positions set at the parent mask "l" are also set in this line. If ALL the positions are, we do not branch either. If only some of them are and some of them are not, we branch *) (* First, update v *) let vv = v | (2^(n-i-1)) in (* Then get the mask for the other branch *) let colOut = colIn xor l in, match colOut with | 0 -> (* All are in, none are out, no need to branch *) if (i<n) then transpose((i+1,vv,colIn)::tt,mat,n,acc) else (* we reached the end of the matrix, we're at a leaf *) transpose(tt,mat,n,(vv,colIn)::acc) | _ -> (* Some in, some out : now we branch *) if (i<n) then transpose((i+1,vv,colIn)::(i+1,v,colOut)::tt,mat,n,acc) else if (v>0) then transpose(tt,mat,n,(vv,colIn)::(v,colOut)::acc) else transpose(tt,mat,n,(vv,colIn)::acc)
Notice that if the matrix is more wide than it is high, it is even faster (if n = 3 and m = 64 for instance)
My questions are : Is this interesting and/or useful ? Am I reinventing the wheel ? Are "almost zero" matrices or "little differentiated-lines" matrices common enough for this to be interesting ?
PS: If anything doesn't seem clear, please do tell, I will rewrite whatever needs to be!