I have a set of 2000 trained random regression trees (from scikit learn's Random Forest Regressor with n_estimators=1). Training the trees in parallel (50 cores) on a large dataset (~100000*700000 = 70GB @ 8-bit) using multiprocessing and shared memory works like a charm. Note, I am not using RF's inbuilt multicore support since I am doing feature selection beforehand.

The problem: when testing a large matrix (~20000*700000) in parallel I always run out of memory (I have access to a server with 500 GB of RAM).

My strategy is to have the test matrix in memory and share it among all processes. According to a statement by one of the developers the memory requirement for testing is 2*n_jobs*sizeof(X), and in my case another factor of *4 is relevant, since the 8bit matrix entries are upcast to float32 internally in RF.

By numbers, I think for testing I need:
14GB to hold the test matrix in memory + 50(=n_jobs)*20000(n_samples)*700(=n_features)*4(upcasting to float)*2 bytes = 14 gb + 5.6 gb = ~21GB of memory.

Yet it always blows up to several hundreds of GB. What am I missing here? (I am on the newest version of scikit-learn, so the old memory issues should be ironed out)

An observation:
Running on one core only memory usage for testing fluctuates between 30 and 100 GB (as measured by free)

My code:

#helper functions
def initializeRFtest(*args):
    global df_test, pt_test #initialize test data and test labels as globals in shared memory
    df_test, pt_test = args

def star_testTree(model_featidx):
    return predTree(*model_featidx)

#end of helper functions

def RFtest(models, df_test, pt_test, features_idx, no_trees):
    #test trees in parallel
    ncores = 50
    p = Pool(ncores, initializer=initializeRFtest, initargs=(df_test, pt_test))
    args = itertools.izip(models, features_idx)
    out_list = p.map(star_testTree, args)
    return out_list

def predTree(model, feat_idx):
    #get all indices of samples that meet feature subset requirement
    nan_rows = np.unique(np.where(df_test.iloc[:,feat_idx] == settings.nan_enc)[0])
    all_rows = np.arange(df_test.shape[0])
    rows = all_rows[np.invert(np.in1d(all_rows, nan_rows))]    #discard rows with missing values in the given features

    pred = model.predict(df_test.iloc[rows,feat_idx])
    return predicted

#main program
out = RFtest(models, df_test, pt_test, features_idx, no_trees)

Edit: another observation: When chunking the test data the program runs smoothly with much reduced memory usage. This is what I used to make the program run.
Code snippet for the updated predTree function:

def predTree(model, feat_idx):
    # get all indices of samples that meet feature subset requirement
    nan_rows = np.unique(np.where(test_df.iloc[:,feat_idx] == settings.nan_enc)[0])
    all_rows = np.arange(test_df.shape[0])
    rows = all_rows[np.invert(np.in1d(all_rows, nan_rows))]    #discard rows with missing values in the given features

    # predict height per valid sample
    chunksize = 500
    n_chunks = np.int(math.ceil(np.float(rows.shape[0])/chunksize))

    pred = []
    for i in range(n_chunks):
        if n_chunks == 1:
            pred_chunked = model.predict(test_df.iloc[rows[i*chunksize:], feat_idx])
        if i == n_chunks-1:
            pred_chunked = model.predict(test_df.iloc[rows[i*chunksize:], feat_idx])
            pred_chunked = model.predict(test_df.iloc[rows[i*chunksize:(i+1)*chunksize], feat_idx])
        print pred_chunked.shape
    pred = np.concatenate(pred)

    # populate matrix
    predicted = np.empty(test_df.shape[0])
    predicted[rows] = pred
    return predicted
  • How much memory do your 2000 trained random regression trees take? Are they being copied for each of the 50 cores? Mar 8 '17 at 3:40
  • @BrianO'Donnell do you mean the size of the model? I don't have access to the model anymore, but it was definitely manageable in size.
    – Dahlai
    Mar 12 '17 at 5:58
  • Yes, the size of the model. Mar 12 '17 at 21:20
  • Sadly, I can't look up the exact size anymore, but it was in the MB's, if I'm not completely mistaken
    – Dahlai
    Mar 16 '17 at 17:37

I am not sure if the memory issue is not related to usage of itertools.izip in args = itertools.izip(models, features_idx) which may trigger creation of copies of the iterator along with its arguments across all threads. Have you tried just using zip?

Another hypothesis might be inefficient garbage collection - not triggered when you need it. I would check if running gc.collect() just before model.predict in predTree does not help.

There is also a 3rd potential reason (probably the most credible). Let me cite Python FAQ on How does Python manage memory?:

In current releases of CPython, each new assignment to x inside the loop will release the previously allocated resource.

In your chunked function you do precisely that - repetitively assign to pred_chunked.


Might be too late but i think i know why this happened, it's a guess though.

Random forest uses different subsets of the same data to train different trees. After the training is complete the subset can be discarded. Depending on how the subset is created each subset could take more memory. Meaning depending on how many trees are trained in parallel you would have more such subsets in memory at the same time leading to your memory problem.

I did the following experiment:

Created a random dataframe (a big one so it would show up in htop) -

df = pd.DataFrame(np.random.randint(0,100,size=(3000000, 4)), columns=list('ABCD'))

Checked htop and found python is taking 1% memory. Now I want to sample the df to a subset of the data. Im using sample as the random is important for both random forest and the memory usage.

a = df.sample(frac=0.7)  # 0.7 is the default for sklearn random forest if im not mistaken

Now the memory is on 1.7% usage! So yay?

Any way this might be the reason, really depends on the implementation in sklean.

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