# Tag Info

## Hot answers tagged indices

20

Each and every value in the index array points at the same time for a position, a normal and a texture coordinate. They are only organized in groups of 3 because they are simply discribing the vertices of a triangle, so 3 vertices = 1 triangle, of course. const GLushort tigerBottomIndices[] = { 0,1,2, // #1 Triangle 3,0,4, // #2 Triangle 1,5,6, // #3 ...

15

Borrowing enumerate is fine and encouraged. However, it can be made a bit lazier by refusing to calculate the length of its argument: enumerate = zip [0..] (In fact, it's common to just use zip [0..] without naming it enumerate.) It's not clear to me why you think your second example should be costlier in either time or space. Remember: indexing is O(n), ...

9

Index-element tuples are quite a common thing to do in Haskell. Because zip stops when the first list stops, you can write them as enumerate x = zip [0..] x which is both more elegant and more efficient (as it doesn't compute length x up front). In fact I wouldn't even bother naming it, as zip [0..] is so short. This is definitely more efficient than ...

7

A fast method (when a is a large list) would be using a dict to map values in a to indices: >>> index_dict = dict((value, idx) for idx,value in enumerate(a)) >>> [index_dict[x] for x in b] [0, 2, 0] This will take linear time in the average case, compared to using a.index which would take quadratic time.

7

apply(mat, 1, which.max) #.....largest apply(mat, 1, which.min) #.....smallest t(apply(mat, 1, sort)[ 1:2, ]) # 2 smallest in each row t(apply(mat, 1, order)[ 1:2, ]) # indices of 2 smallest in each row Besides using decreasing=TRUE, you could also have used this for the two largest in a row: t(apply(mat, 1, order)[ 5:4, ])

7

As I mentioned in the comments, it's not practical to represent matrices using vector-of-vector for a few reasons: It is fiddly to set up; It is difficult to change; Cache locality is bad. Here is a very simple class I have created that will hold a 2D matrix in a single vector. This is pretty much how software like MATLAB does it... albeit a huge ...

7

Yes, it can be done, but it is a little tricky: # convert yourmulti-dim indices to flat indices flat_idx = np.ravel_multi_index((Px, Py), dims=a.shape) # extract the unique indices and their position unique_idx, idx_idx = np.unique(flat_idx, return_inverse=True) # Aggregate the repeated indices deltas = np.bincount(idx_idx, weights=x) # Sum them to your ...

6

You can omit columns from right to left when using an index, i.e. when you have an index on col_a, col_b you can use it in WHERE col_a = x but you can not use it in WHERE col_b = x. Imagine to have a telephone book that is sorted by the first names and then by the last names. At least in Europe and US first names have a much lower selectivity than last ...

6

Really you should be using a vector with an offset. Or even an array with an offset. The extra addition or subtraction isn't going to make any difference to the speed of execution of the program. If you want something with the exact same speed as a default C array, you can apply the offset to the array pointer: int* a = new int[10]; a = a + 5; a[-1] = 1; ...

6

GL_UNSIGNED_BYTE is OK for models which have at most 256 vertices - that's really not many. GL_UNSIGNED_SHORT, taking 2 bytes, would limit you to 65536 vertices - still that's kind of few. I'd say the most common variant is GL_UNSIGNED_INT, as even 2 bytes may not be enough for mid-poly and high-poly models.

6

Use Collections.shuffle: Integer[] numbers = { 1, 2, 3, 4, 5 }; Collections.shuffle(Arrays.asList(numbers)); See it working online: ideone It uses the Fisher-Yates shuffle internally. This is an efficient shuffling algorithm that won't give you duplicates. Related Java's Collections.shuffle is doing what? How to convert int[] to Integer[] in ...

6

This will do exactly that: inds = find(ismember(data, A)) the function ismember will find all elements in data that are in A. The second output of ismember could also be useful: >> [~, b] = ismember(data, A)) ans = 1 1 0 0 0 0 2 2 2 0 0 0 0 0 0 0 0 0 3 3 3 where the 1, 2 and 3 refer to the index into A.

6

The immediate issue You probably meant to use S[0:a] and S[a:len(S)] (slicing) rather than commas. A note about slicing... You don't have to specify the leading zero or the trailing len(S) there - they're implicit. So you could just use S[:a] and S[a:] to mean the same thing. Also note that S[0:a] + S[a:len(S)] is equivalent to S. You probably didn't ...

6

Python, Lua, and Ruby support negative subscripts. In Python, this feature was added as extended slicing in version 2.3. On p.264 of Sebesta's book (10th ed.) he claims Python does not support negative indexing on arrays. The original text was overhauled and republished as edition 6 in 2004, while Python 2.3 was released on July 29, 2003. I'm guessing ...

5

I should put the most selective column first According to Tom, column selectivity has no performance impact for queries that use all the columns in the index (it does affect Oracle's ability to compress the index). it is not the first thing, it is not the most important thing. sure, it is something to consider but it is relatively far down there ...

5

Using something like the following solves my problem: unsigned int indices[] = { 0, 256, 1, 257 }; I think it's safe to assume that the index is the x coordinate and that OpenGL is expecting that to be followed by y and z but we shouldn't increase by 3 ourselves, the server does it for us. And now that I think about it, glDrawElements has the word ...

5

Combine std::transform with a function object which calls std::find: #include <vector> #include <algorithm> #include <iostream> #include <iterator> struct find_functor { std::vector<int> &haystack; find_functor(std::vector<int> &haystack) : haystack(haystack) {} int operator()(int needle) { ...

5

Presuming we are working with smaller lists, this is as easy as: >>> a = [1, 2, 9, 3, 8] >>> b = [1, 9, 1] >>> [a.index(item) for item in b] [0, 2, 0] On larger lists, this will become quite expensive. (If there are duplicates, the first occurrence will always be the one referenced in the resulting list, if not set(b) <= ...

5

Only integers can be used as array or matrix indices. The default type for a matrix initialised like that is float. You can use a numpy.array not a numpy.matrix: In [2]: import numpy as np In [3]: x = np.array([1, 0, 2, 4, 3, 6, 5]) In [4]: x[x] Out[4]: array([0, 1, 2, 3, 4, 5, 6]) Or you can explicitly change your matrix to an integer type: In [5]: x ...

5

The answer is yes, VBO's are practical for large polygon rendering tasks. Immediate mode should not be used because it's part of the fixed function pipeline and the FFP is deprecated. But you should not recompute the landscape every frame and store it in the buffers again. There are some ways to handle such situations but you should avoid to update a VBO ...

5

You can use numpy.where with numpy.column_stack here. Example: >>> import numpy as np >>> a = np.array([[1, 0, 0], [0, 1, 0], [1, 1, 1]]) >>> np.column_stack(np.where(a==1)) array([[0, 0], [1, 1], [2, 0], [2, 1], [2, 2]])

4

GL_UNSIGNED_BYTE is 1 byte, GL_SHORT is 2 bytes. The only advantage of bytes is that they're smaller so they take less memory to store and less time to transfer to the graphics memory (assuming vertex arrays or VBOs). Beware that not all types are available for all uses: You can't have GL_UNSIGNED_BYTE vertices, for example.

4

to use where: import numpy as np np.random.seed(0) # Make a random masked array ar = np.ma.array(np.round(np.random.normal(50, 10, 20), 1), mask=np.random.binomial(1, .2, 20)).reshape((4,5)) # Sort the array from lowest to highest, with a flattened index sorted_ind = ar.argsort(axis=None) tmp = ar.flatten()[sorted_ind] print ...

4

Use an ArrayList to record the indices. This also eliminates the need for a count as the number of entries in the list is the number of occurrences. ArrayList<Integer> whitespaceLocations = new ArrayList<Integer>(); for(int i = 0; i < limit; ++i) { if(Character.isWhitespace(str.charAt(i))) { whitespaceLocations.add(i); } } ...

4

Since you have two dense matrices then the double for loop is the only option you have. You don't need a sparse matrix class at all since you only want to know the list of indices (i,j) for which a[i,j] != b[i,j]. In languages like R and Python the double for loop will perform poorly. I'd probably write this in native code for a double for loop and add the ...

4

1) If I want to select by username, and start date for a query.....will it use the index above OR do I need to specify an additional index? You have a complex condition, say, like this: username = 'blah-blah-blah' AND startdate > '01.01.2010' If your table's PK defined like: PRIMARY KEY (Username, Title, StartDate) Then index will be used for ...

4

Meh, pretty similar to the others, but it stops when it finds its target def find(M: Array[Array[Int]], W: Int): Option[(Int, Int, Int)] = { for { x <- M.indices.reverse y <- M(x).indices a = M(x)(y) if 0 < a && a <= W } return Some(x, y, a) None }

4

In GL_TRIANGLES mode, it needs 3 vertices for every triangle, thus it will pull 3 indices at a time (so, it will draw the two triangles with indices 1,2,3 and 4,5,6). Different figures apply if you have adjacency or draw a triangle strip, of course. Also, since you mentioned that you are importing an OBJ file, do note that there may be different indices on ...

4

Clearly a simple for-loop would be very much preferred here rather than any STL algorithm. But just as a proof of a concept one might adopt stl::equals and a lambda from C++11 here: std::equal(myVec.begin(), myVec.end(), markedToBeRead.begin(), [&](float item, int mark)->bool { if (mark) myResult.push_back(item); return true; }); ...

4

I mean, every time the player's position or camera rotation changed, you would have to recompute the vertex data No you don't. In your typical terrain renderer the data is subdivided into tiles. And usually those tiles subdivide again, and again to implement level of detail. What sets the tiles apart are the vertices they reference. So you'd have one ...

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