# Create large random boolean matrix with numpy

I am trying to create a huge `boolean` matrix which is randomly filled with `True` and `False` with a given probability `p`. At first I used this code:

``````N = 30000
p = 0.1
np.random.choice(a=[False, True], size=(N, N), p=[p, 1-p])
``````

But sadly it does not seem to terminate for this big `N`. So I tried to split it up into the generation of the single rows by doing this:

``````N = 30000
p = 0.1
for i in range (N):
mask[i] = np.random.choice(a=[False, True], size=N, p=[p, 1-p])
if (i % 100 == 0):
print(i)
``````

Now, there happens something strange (at least on my device): The first ~1100 rows are very fastly generated - but after it, the code becomes horribly slow. Why is this happening? What do I miss here? Are there better ways to create a big matrix which has `True` entries with probability `p` and `False` entries with probability `1-p`?

Edit: As many of you assumed that the RAM will be a problem: As the device which will run the code has almost 500GB RAM, this won't be a problem.

• Failed to understand that part - `does not seem to terminate for this big N`. Clarifications on it? Commented Apr 20, 2017 at 19:53
• Why a boolean-array but not setting the dtype? And check iif your memory is enough. Otherwise trashing will slow down every approach. Commented Apr 20, 2017 at 19:53
• once memory exhausted, it slows down machine? Commented Apr 20, 2017 at 19:53
• @Serge But why? I mean: I am creating the NxN array in line 3 - so there is no reason why the memory should get exhausted. Furthermore, the memory is really no problem, as there is plenty in the machine - roughly 0.5 TB. Commented Apr 20, 2017 at 19:54
• @FlashTek: Your OS won't actually commit RAM to that allocation until you write to it. Commented Apr 20, 2017 at 19:59

The problem is your RAM, the values are being stored in memory as it's being created. I just created this matrix using this command:

`np.random.choice(a=[False, True], size=(N, N), p=[p, 1-p])`

I used an `AWS i3` instance with 64GB of RAM and 8 cores. To create this matrix, `htop` shows that it takes up ~20GB of RAM. Here is a benchmark in case you care:

``````time np.random.choice(a=[False, True], size=(N, N), p=[p, 1-p])

CPU times: user 18.3 s, sys: 3.4 s, total: 21.7 s
Wall time: 21.7 s

for i in range(N):
mask[i] = np.random.choice(a=[False, True], size=N, p=[p, 1-p])
if (i % 100 == 0):
print(i)

CPU times: user 20.9 s, sys: 1.55 s, total: 22.5 s
Wall time: 22.5 s
``````

Note that the mask method only takes up ~9GB of RAM at it's peak.

Edit: The first method flushes the RAM after the process is done where as the function method retains all of it.

So I tried to split it up into the generation of the single rows by doing this:

The way that `np.random.choice` works is by first generating a `float64` in `[0, 1)` for every cell of your data, and then converting that into an index in your array using `np.search_sorted`. This intermediate representation is 8 times larger than the boolean array!

Since your data is boolean, you can get a factor of two speedup with

``````np.random.rand(N, N) > p
``````

Which naturally, you could use inside your looping solution

It seems like `np.random.choice` could do with some buffering here - you might want to file an issue against numpy.

Another option would be to try and generate `float32`s instead of `float64`s. I'm not sure if numpy can do that right now, but you could request the feature.

• Okay, interesting - the solution with`np.random.rand(N, N) > p` was my first idea which I discarded as I thought that the direct numpy call would be faster. Commented Apr 21, 2017 at 5:42
• @FlashTek: Problem is that `np.random.choice` has to do more work, since it's has to handle cases with more than two outcomes. Definitely scope for a special case when the number of choices is two
– Eric
Commented Apr 21, 2017 at 8:57
• Alright. But do you know why this kind of slowdown happens in my first post? Commented Apr 22, 2017 at 14:53
• Which kind of slowdown? The reason your second attempt is faster is because you're not allocating all the floats at once, and they're much bigger than your final result.
– Eric
Commented Apr 22, 2017 at 16:56
• No, I mean the slowdown in the second attempt which happens ~ after row 1100 has been generated - as described above. Commented Jun 18, 2017 at 8:55

Really surprised no one has mentioned this solution yet..

This line

``````np.random.choice(a=[False, True], size=(N, N), p=[p, 1-p])
``````

runs NXN Bernoulli Trials. (In your case, 900M of them!) A Bernoulli trial is just a random experiment with two possible outcomes, with probabilities p and 1-p.

The sum of N Bernoulli trials, each with probability p, can be modeled by the Binomial distribution.

We can leverage this fact to randomly simulate the total count of True elements. With NumPy,

``````import numpy as np

N = 30000
p = 0.1

# Build a random number generator
rng = np.random.default_rng(123)

# Randomly determine the total number of True values
Ntrue = rng.binomial(n=N*N, p=p, size=1)[0]  # 90016776
``````

Now we can randomly determine the position of each True element by randomly choosing row and col indices without replacement.

``````# Randomly determine true position
position_ids = rng.choice(a=N*N, size=Ntrue, replace=False)
positions = np.unravel_index(position_ids, shape=(N,N))
``````

And now we can populate a compressed sparse row (CSR) matrix.

``````from scipy import sparse

# Build a compressed sparse row matrix with the constructor:
# csr_matrix((data, (row_ind, col_ind)), [shape=(M, N)])
result = sparse.csr_matrix((np.ones(shape=Ntrue), positions), shape=(N,N))
``````

Notice this solution avoids storing and computing 900M boolean values.

Funny enough, I wrote about a nearly identical problem before stumbling upon this question.

With equal distribution:

``````mask = np.random.randint(2, size=(N, N), dtype=bool)
``````

np.random.randint

• I arrived from a web search looking for exactly this. Commented Feb 4 at 12:50

Another possibility could be to generate it in a batch (i.e. compute many sub-arrays and stack them together at the very end). But, consider not to update one array (`mask`) in a `for` loop as OP is doing. This would force the whole array to load in main memory during every indexing update.

Instead for example: to get `30000x30000`, have 9000 `100x100` separate arrays, update each of this `100x100` array accordingly in a `for` loop and finally stack these 9000 arrays together in a giant array. This would definitely need not more than 4GB of RAM and would be very fast as well.

Minimal Example:

``````In [9]: a
Out[9]:
array([[0, 1],
[2, 3]])

In [10]: np.hstack([np.vstack([a]*5)]*5)
Out[10]:
array([[0, 1, 0, 1, 0, 1, 0, 1, 0, 1],
[2, 3, 2, 3, 2, 3, 2, 3, 2, 3],
[0, 1, 0, 1, 0, 1, 0, 1, 0, 1],
[2, 3, 2, 3, 2, 3, 2, 3, 2, 3],
[0, 1, 0, 1, 0, 1, 0, 1, 0, 1],
[2, 3, 2, 3, 2, 3, 2, 3, 2, 3],
[0, 1, 0, 1, 0, 1, 0, 1, 0, 1],
[2, 3, 2, 3, 2, 3, 2, 3, 2, 3],
[0, 1, 0, 1, 0, 1, 0, 1, 0, 1],
[2, 3, 2, 3, 2, 3, 2, 3, 2, 3]])

In [11]: np.hstack([np.vstack([a]*5)]*5).shape
Out[11]: (10, 10)
``````

You can use random number generator for this like:

## random_bools= rng.integers(0,1,(4,3),endpoint= True).astype('bool')

It will give you random boolean array of size (4,3) which you can choose according to your need.