# Tag Info

2

Partially unrolling your loop will certainly help: mat = zeros(L,M*N); for ii=1:M*N mat(:,ii) = randperm(K,L); end mat = reshape(mat.', [M N L]); But I think the main issue is that you're using randperm with large K and small L. I'm not sure how randperm is implemented on newer versions of MATLAB (which you seem to have), but if it's anything ...

2

A rejection approach may be faster, depending on the values of L and K. The idea is to generate all entries with randi without regard to repetition, detect third-dim-lines which have repetitions, and generate those again, until no repetitions exist. It's easier to work with the first two dimensions collapsed into one, and reshape at the end. Of course, ...

0

This should execute quicker: s = repmat(L, [M*N 1]); P = arrayfun(@(x)(randperm(K, x)), s, 'UniformOutput', false); Q = cell2mat(P); mat = reshape(Q, [M N L]); NOTE: The randperm I have only accepts one parameter, so I couldn't try your code, this approach works for me with the anonymous function @(x)(randperm(x)) in arrayfun.

0

I tried to successively increase the the size of the int-arrays (size of the loop) and it seems the vectorization kicks in if the big-ints are >= 14 words. But I still don't see why there is this threshold in the front-end. I still think the front-end should always vectorise and the back-end should decide how to lower vectors, because it has the information ...

0

If you are okay with finding the column numbers with their corresponding row numbers in a different vector, as suggested by Luis, you may use this too - %// Main portion haystack_t = haystack'; num1 = strfind(num2str(haystack_t(:))',num2str(needle(:))'); col = rem(num1,size(haystack,2)); ind = floor(num1/size(haystack,2))+1; %// We need to remove indices ...

0

If you can accept the result in a different format (more suited to vectorization): [m n] = size(haystack); haystackLin = haystack.'; haystackLin = haystackLin(:).'; %// linearize haystack row-wise ind = strfind(haystackLin,needle); %// find matches [jj ii] = ind2sub([n m],ind); %// convert to row and column valid = jj<=n-numel(needle)+1; %// remove false ...

0

It is possible to concatenate the entire haystack variable and then find the needle in it as follows: totalWhiteSpaces=isspace(haystack); %finds white space locations totalWhiteSpaces=sum(totalWhiteSpaces(1,:),2); %Assumes that "haystack" has equal number %of characters (including whitespaces) in each row. ...

0

If you don't want to use for loop, you co do as follows: result = cellfun(@(row) strfind(row, needle), num2cell(haystack, 2), 'UniformOutput', 0);

0

Initialization - N = 3; rho_g = linspace(1e-3,1,N); phi_g = linspace(0,2*pi,N); n = 1:3; tau = [1 2.*ones(1,length(n)-1)]; Nested loops form (Copy from your code and shown here for comparison only) - for ii = 1:length(rho_g) for jj = 1:length(phi_g) % Coordinates rho_o = rho_g(ii); phi_o = phi_g(jj); % factors ...

0

In order to give a self-contained answer, I'll copy the original initialization N = 3; rho_g = linspace(1e-3,1,N); phi_g = linspace(0,2*pi,N); n = 1:3; tau = [1 2.*ones(1,length(n)-1)]; and generate some missing data (k(3) and rho_s and phi_s in the dimension of n) rho_s = rand(size(n)); phi_s = rand(size(n)); k(3) = rand(1); then you can compute the ...

1

The standard llvm toolchain provided by XCode5 doesn't seem to support getting debug info from the optimizer. However, if you roll your own llvm and use that, you should be able to pass flags as mishr suggested above. Here's the workflow I used: 1. Using homebrew, install llvm brew tap homebrew/versions brew install llvm33 --with-clang --with-asan This ...

1

You could try to vectorize this code, which might be possible with some bsxfun or so, but it would be hard to understand code, and it is the question if it would run any faster, since your code already uses vector math in the inner loop (even though your vectors only have length 3). The resulting code would become very difficult to read, so you or your ...

3

For a true lookup table, the result should be the length of the query and also deal with replication in the query. The approaches using match(...) are the only ones that do this: query4 <- c("jack","sam", "dan","sam","jack") dt[match(query4,dt\$name),]\$age # [1] 20 28 13 28 20 This is because match(LHS,RHS) returns an integer vector of length(LHS) which ...

2

There are a lot of ways to do this, but I'll throw out one that I find useful. match(). @jlhoward's answer goes into more detail and explains why my previous == examples were wrong. > match(query1, dt\$name) #these give us the index of the *first* matching value [1] 1 4 > match(query2, dt\$name) [1] 3 > dt\$age[match(query1, dt\$name)] [1] 20 13 > ...

3

You want %in%, it returns of logical vector that is used to subset the data frame dt[dt\$name %in% query3,"age"]

0

I have no idea of what you intended to ask with your question, and it seemed extremely vague (It may be my ignorance, probably). Nevertheless, It's definitely not good to have a function with 99999 inputs. I would suggest you to create a class for your "Black76Model" and give for every instance of it these inputs, and implement methods to do things with ...

0

If memory is not an issue, you can concat all matrices along a third dim; and then indexing is very easy: %// Example data A = {[1 2;5 6], [3 4; 6 7]; [3 4; 6 7], [9 8; 5 6]}; ii = 2; jj = 1; %// Compute the result B A2 = cat(3,A{:}); %// concat along third dim B = reshape(A2(ii,jj,:),size(A{1})); %// index A2 and reshape

1

The easy to use cellfun one-liner would be: ii = 2; jj = 1; A = {[1 2;5 6], [3 4; 6 7]; [3 4; 6 7], [9 8; 5 6]}; B = cell2mat( cellfun( @(x) x(ii,jj), A, 'uni', 0) ) gives: B = 5 6 6 5 Advantage over Divakar's Solution: it works also for inconsistent matrix sizes in A. And if you want to avoid also the outer loop, another fancy ...

3

CELL2MAT gets all the data from a cell array that consists of numeric data only, into a numeric array. So, that helped us here. For your original problem, try this - celldim_i = 10; celldim_j = 10; block_size_i = 5; block_size_j = 20; search_i = i; %// Edit to your i search_j = j; %// Edit to your j A_mat = cell2mat(A); out = ...

0

Found this in the document "A Guide to Vectorization with IntelĀ® C++ Compilers" To allow comparisons of vectorized with unvectorized code, vectorization may be disabled with the switch /Qvec- (Windows*) or -no-vec (Linux* or Mac OS* X). Lots of additional good information on the Intel® Composer XE Suite page.

0

As Dennis noted, this is a lot of code, cutting it down to the minimum that's slow given by the profiler will help. I'm not sure if my code is equivalent to yours, can you try it and profile it? The 'trick' to Matlab vectorization is using .* and .^, which operate element-by-element instead of having to use loops. ...

3

I'll skip the first loop, because I'm not sure how it's intended to work (->comment) and explain vectorisation for the second loop: C1=0; for j=1:m C1=C1+(L(j)*(w(j).^2)); end What does the code do? squaring each element of w multiplying the result with the corresponding element in L get the sum of the result. To find the right operations, you ...

0

So apparently I had 3 other different problems in the data source that I think could have stucked the routine Divakar proposed. Anyway I thought it was being too slow so I started thinking to another solution and came up with a super quick vectorized one. Given that the observations I wanted to modify fall in a determined known interval of time the ...

1

Sensible version - for count = 1:numel(time) dtime = diff([0 ;time]); ind1 = find(dtime<0,1,'last')-1; time(ind1) = time(ind1)-1; end Faster-but-crazier version - dtime = diff([0 ;time]); for count = 1:numel(time) ind1 = find(dtime<0,1,'last')-1; time(ind1) = time(ind1)-1; dtime(ind1+1) = 0; dtime(ind1) = dtime(ind1)-1; ...

0

tricky way without using explicit fors.. clc close all clear all Paragraph=lower(fileread('Temp1.txt')); AlphabetFlag=Paragraph>=97 & Paragraph<=122; % finding alphabets DelimFlag=find(AlphabetFlag==0); % considering non-alphabets delimiters WordLength=[DelimFlag(1), diff(DelimFlag)]; Paragraph(DelimFlag)=[]; % setting delimiters to white ...

3

The problem with your code is that you use the matrix division operation / when you intend (I think) to do an element by element division - ./ . This is a subtle but very very important distinction. If you have two vectors, X and Y, you could take their dot product with s = 0; for ii = 1:numel(X) s = s + X(ii) * Y(ii); end After this, the sum of the ...

1

Here are two options: This one uses the somewhat discouraged <<- operator: lapply(1:nr, function(i) out[i, sample.int(nc, rs[i], prob = p)] <<- 1) This one uses more traditional indexing: out[do.call('rbind',sapply(1:nr, function(i) cbind(i,sample.int(nc, rs[i], prob = p))))] <- 1 I suppose you could also use Vectorize to do an implicit ...

2

Similar to Julian's answer: sapply( split(incdf, 1:nrow(incdf)), function(x) do.call(myfun, c(unname(x), bdays=50, fdays=100)) ) Here I don't use apply because apply will coerce the whole row to the same type, which may not be desirable. Note we need to unname(x) because your df doesn't have the same column names as args to your function.

1

First, when you call apply all values are coerced to strings, so you need to convert tdate before using it. Otherwise you're trying to add days to a string: tdate <- as.Date(tdate) fdays <- tdate+fdays bdays <- tdate-bdays Second, you call apply(inc, 1, myfun). Note that in that case you're passing a single parameter to myfun (the whole row), and ...

2

For this type of function it is indeed possible. Define your function so that it works with all rows at the same time: G = @(x) x(1:2:end,:) | x(2:2:end,:) and then: y = G(x); Example: let x = 1 1 0 1 0 0 0 0 0 0 1 1 0 0 0 1 0 1 0 1 1 1 1 1 1 ...

0

Use a(1,z(:,2)) = mat2cell(z(:,1), ones(1,size(z,1)), 1); For example, with z = [1 2 3 4]; this results in a = [] [1] [] [3]

0

You might find it useful to look at examples of how SIMD can be applied to some common algorithms. At Games Developer Conference 2011, there was an Intel talk called "Hotspots, FLOPS, and uOps: To-the-Metal CPU Optimization" that attempts to demonstrate SIMD for algorithms common in games. The talk refers to some Intel sample code that shows how AVX can be ...

0

I'd use sub2ind and pass the indices as both x and y parameters: A = zeros(4) V=[2 4] idx = sub2ind(size(a), b,b) % idx = [6, 16] A(idx) = 1 % A = % 0 0 0 0 % 0 1 0 0 % 0 0 0 0 % 0 0 0 1

2

The meshgrid/where/indexing solution is already extremely fast. I made it about 65 % faster. This is not too much, but I explain it anyway, step by step: It was easiest for me to approach this problem with all 3D vectors in the grid being columns in one large 2D 3 x M array. meshgrid is the right tool for creating all the combinations (note that numpy ...

2

Thanks to @Bill, I was able to get this to work. Very fast now. Perhaps could be done better, especially with the two masks to get rid of the two conditions that I originally had for loops for. from __future__ import division import numpy as np N = 100 n = 12 r = np.sqrt(2) x, y, z = np.meshgrid(*[np.arange(-N, N+1)]*3) ind = ...

1

CountVectorizer and TfIdfVectorizer allow you to specify the vocabulary to be used. Pass them as the keyword argument vocabulary to the constructor. Quote from the docs: vocabulary: Mapping or iterable, optional Either a Mapping (e.g., a dict) where keys are terms and values are indices in the feature matrix, or an iterable over terms. If not ...

0

I see @LuisMendo arrived at mostly the same solution quicker than I did, but an alternative to using ismember is to use more of what unique gives you: threshold = 20; [vals, ~, ix] = unique(a); % capture the values and their indices counts = histc(a(:), vals); % count the occurrences of each value vals(counts<threshold) = 0; % zero the values that ...

1

I think this does what you want: threshold_length = 20; replace_value = 0; u = unique(a); %// values of a h = histc(a(:), u); %// count for each value r = u(h<threshold_length); %// values to be removed a(ismember(a,r)) = replace_value; %// remove those values

1

You can use this approach: set.seed(42) df <- data.frame(measurement = rnorm(1000)) res <- sapply(seq(nrow(df)), function(x) quantile(df[seq(x), "measurement"], c(.01, .99))) It creates a matrix with nrow(df) columns and 2 rows, one row for the 1st percentile and one row for the 99th percentile. You can add this information to you data frame df ...

0

What you see in dcl_literal l16, 0x00000001, 0x00000001, 0x00000001, 0x00000001 ... seems to be LLVM assembler. It's an output of compiler front-end yet to be processed by back end & translated into machine code. As it's not the final version, than, in my opinion, there is no measure to determine how optimal this code is. As suggestion - such LLVM ...

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