@CrisLuengo lol this had been my entire week trying to get our simulation software working on a linux cluster running Wine inside containers... Im reading forum posts about people getting games working to try and debug our bespoke sim packages, not ideal
Woo hoo! The Image Processing Toolbox team has just created a new product:Medical Imaging Toolbox™Shipped with the R2022b release a couple of months ago, this product provides apps, functions,... read more >>
Elapsed time is 0.780516 seconds. <- OP Elapsed time is 0.397369 seconds. <- you n1 Elapsed time is 0.305160 seconds. <- you implicit expansion (With bug fixed, `.*`)
There is another option: loop over the first two dimensions of the array. OP loops over the last dimension, which requires copying out slices, and iteratively update the output array. Looping the other way would be much more efficient I think. Avoids any intermediate arrays.
@AnderBiguri that's impossible, as the answer on there says. Way too many possibilities. So grab a random one instead. You'll not find the same combination twice anyway
but again, if there is only 1 possibile one among all the 250 (also note that its not 2 value, can be any amount of A's, and I assume OP wants the largerst subset), it can take millions of random samples to find that one
The cart-filling one, or however you want to call that, might actually work; where you have 10 sacks with different weights, the cart able to take X kg per trip, how to distribute the sacks over the trips in such a way that the least amount of trips needs to be taken
If they want all possible combinations adhering to the constraints, that's a problem. If they want one possible combination, that's fine (literally take A(1), B(1), or any random one). If they want the largest combination, try the knapsack
cv-pls Someone wanting to convert Python code to MATLAB. "I'm doing the conversion for practice." Yet they want us to convert the code... stackoverflow.com/q/74488598/7328782
These things are getting more hilarious by the minute.
>>> a = np.arange(10, dtype=np.uint8)
>>> (a + np.float64(1)).dtype
dtype('float64')
>>> (a + np.uint32(1)).dtype
dtype('uint8')
>>> (a + np.int32(1)).dtype
dtype('uint8')
I don't get that.
>>> (a + np.array([1], dtype=np.uint32)).dtype
dtype('uint32')
after spending all day writting latex code to split my images in groups and add them individual caption (images are generated stick together, otherwise I have >50) turns out that export fig has some bug in -preserve_resolution mode that adds/removes 1 pixels ometimes
#include<studio.h>
Void main (){
Printf("\n i need to know how I can do a model of okumora-Hata and cost hata with Matlab please")
}
