Is there a way to obtain desired index without using 'find'?
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Dmytro
el 1 de Oct. de 2012
Editada: Walter Roberson
el 12 de Nov. de 2017
Dear all,
Suppose there is some array
ar=[102 243 453 768 897 ...]
Is there any way to obtain indices of an element having value e.g. 243 without using find?
For each element I need to find its index, so the computational cost will be O(N^2), which is too much. One possibility is using sparse matrices, e.g.
smatr=sparse(ar,1,1:length(ar))
and then index can be retrieved simply as ind=smatr(243) and so on, reducing computational cost to O(N). However, the problem is that in my computations values of 'ar' might exceed maximum size of matrix. So is there any additional way to relate values of 'ar' to indices so the latter can be obtained in one operation?
Thanks,
Dima
9 comentarios
Matt J
el 2 de Oct. de 2012
Editada: Matt J
el 2 de Oct. de 2012
This routine greatly outperforms all other (in my calculations it was always almost independent of N, as well as faster, while all others linearly grow with N). So, I think, the problem is sorted. Thank you all for your answers, I am really glad I received help here and I greatly appreciate it!
Maybe, but just so you know, there are mex-driven versions of this available on the FEX
See also my 3rd Answer below for how to incorporate it.
Respuesta aceptada
Matt J
el 2 de Oct. de 2012
Editada: Matt J
el 2 de Oct. de 2012
Here's another approach that uses the find_idx function from the FEX
It seems to overcome the O(N) overhead of HISTC and is virtually independent of N in speed,
ar=[102 243 453 768 897 102];
[sar,i,j]=unique(ar);
ind=j(floor(find_idx(768,sar))), %search for 768 for example
Más respuestas (7)
Matt Fig
el 1 de Oct. de 2012
ar=[102 243 453 768 897 243 653 23];
KEY = 1:length(ar);
KEY(ar==243)
2 comentarios
Walter Roberson
el 1 de Oct. de 2012
Each of the == operations in your code will take N comparisons. Dmytro also wants to do this for each of the N elements, for a total of N*N = O(N^2) operations. Dmytro hopes to do it more efficiently.
Matt J
el 1 de Oct. de 2012
Editada: Matt J
el 1 de Oct. de 2012
Here's a modification of the sparse matrix approach that might ease the difficulty with maximum matrix sizes limits,
armax=max(ar);
armin=min(ar);
arc=ar-armin+1;
arcmax=armax-armin+1;
N=ceil(sqrt(arcmax));
[I,J]=ind2sub([N,N], arc);
smatr=sparse(I,J,1:length(arc),N,N);
Now, whenever you need to look up an index, e.g. 243, you would do
[i,j]=ind2sub([N,N],243-armin+1);
ind=smatr(i,j);
The difference is that now the matrix dimensions of smatr are roughly the square root of what they were in your approach. Even less, actually, since we offset the ar values by armin in its construction.
2 comentarios
Walter Roberson
el 1 de Oct. de 2012
2^96 cannot be handled as array indexes for MATLAB. The limit is 2^48 if I recall correctly. 2^96 exceeds 64 bit representation.
Matt J
el 1 de Oct. de 2012
Editada: Matt J
el 1 de Oct. de 2012
Here is an implementation of your O(log_2(N)) idea using HISTC
ar=[102 243 453 768 897 102];
[sar,i,j]=unique(ar);
[~,bin]=histc(768,sar); %search for 768 for example
ind=j(bin);
5 comentarios
Dima
el 2 de Oct. de 2012
Yes, I am sure, the code is
css=zeros(500,1); NN=1000*(1:500);
for cn=1:500
RM=unique(randi(NN,NN,1));
aaa=cputime;
for kn=1:10000, nn=randi(NN); [~,bb]=histc(nn,RM); end
css(cn)=cputime-aaa;
end
plot(NN,css,'o');
Walter Roberson
el 1 de Oct. de 2012
If each element is present only once, consider using the three-output form of unique()
5 comentarios
Matt Fig
el 1 de Oct. de 2012
I think it is not equivalent, because UNIQUE sorts first for ar of any real length (>1000). Time-wise this all adds up to more of it!
dipanka tanu sarmah
el 19 de Oct. de 2017
Editada: Walter Roberson
el 19 de Oct. de 2017
you can use the following function :
function posX = findPosition(x,y)
posX=[];
for i =1:length(x)
p=x-y;
isequal(p(i),0)
if ans==1
posX=[posX,i]
end
end
2 comentarios
Walter Roberson
el 19 de Oct. de 2017
That would print out the result of each isequal() . Better would be to use
function posX = findPosition(x,y)
posX=[];
for i = 1:length(x)
p = x - y;
if isequal(p(i),0)
posX=[posX,i]
end
end
Which optimizes to
function posX = findPosition(x,y)
posX=[];
p = x - y;
for i = 1:length(x)
if isequal(p(i),0)
posX=[posX,i]
end
end
But then that could be simplified further as
function posX = findPosition(x,y)
posX=[];
for i = 1:length(x)
if x(i) == y
posX=[posX,i]
end
end
However, this requires continually expanding posX, which could be expensive. Less expensive would be:
function posX = findPosition(x,y)
posX = 1 : length(x);
posX = posX( x == y );
On the other hand, this is an order N calculation anyhow, and since the indices have to be found for each entry in the array, using this repeatedly would still end up being O(N^2) which the poster was trying to avoid.
dipanka tanu sarmah
el 19 de Oct. de 2017
yeah. u are awesome. I didnt go thriugh the optimization part. thnk you
Walter Roberson
el 19 de Oct. de 2017
myMap = containers.Map( ar, 1:length(ar) )
This uses a hash structure. I am not sure which one it uses, so I do not know the creation time costs; certainly no less than O(N) as the 1:length(ar) is O(N). O(N*log(N)) I suspect.
Once hashed, each lookup is nominally constant time (I do not know if the hash structure it uses can have collisions that might need to be resolved.)
0 comentarios
Christian Troiani
el 12 de Nov. de 2017
Editada: Walter Roberson
el 12 de Nov. de 2017
for k = 1:length(ar)
if ar(k)==243 % Using your example of the 243 element
posX=k;
break
else
continue
end
end
0 comentarios
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