The short answer to the OP's question regarding the result of the code is **No**. It just calculates the average over all the predictions returned by `cross_val_predict`

regardless of the fold an individual prediction belongs to. Hence, the warning **not** to, in general, use this method to score a model. But, for the long answer to the question posed in the OP's title, how to score a model using `cross_val_predict`

, read on.

As has been well demonstrated by @Omid, `cross_val_predict`

returns the out-of-sample predictions of each element of each fold generated by `KFold.split`

; this array of predictions is ordered by fold. On the other hand, `cross_val_score`

returns an array of scores for each fold; this array of scores is also ordered by fold. Under the hood, `cross_val_score`

just runs `cross_validate`

, but restricts scoring to just one scoring method and returns just the scores of the folds, and not all the rich minutia of `cross_validate`

. In order to calculate a (accuracy)score using `cross_val_prdeict`

, one needs to score over the folds the out-of-sample predictions as they are assigned to the folds returned by `KFold.split`

...

```
import numpy as np
from sklearn.datasets import make_regression
from sklearn.model_selection import KFold, cross_val_score, cross_val_predict
from sklearn.ensemble import RandomForestRegressor
from sklearn.metrics import mean_squared_error, make_scorer
q = np.arange(6)
kq = KFold(n_splits=3)
list(kq.split(q, q))
>>> [(array([2, 3, 4, 5]), array([0, 1])),
>>> (array([0, 1, 4, 5]), array([2, 3])),
>>> (array([0, 1, 2, 3]), array([4, 5]))]
```

In the code above, `KFold.split`

returns three tuples, one for each of the `n_splits`

. Each tuple holds two arrays each. Each array is a sequence of indexes into the data, the first for the in-sample (train) elements, the second for the out-of-sample (test) elements, a so-called **train / test** spilt.

For each fold, `cross_validate / cross_val_score`

fits a model to the in-sample elements then makes predictions over the corresponding out-of-sample elements and finally scores each model based on the predictions and the true values of the out-of-sample elements returning a score, one for each fold. On the other hand, `cross_val_predict`

also fits three models and makes predictions for over each fold, but it simply returns the out-of-sample predictions ordered by fold, i.e., (and with abuse of notation) `[0, 1| 2, 3| 4, 5]`

. Continuing, let's first score a model configuration using `cross_val_score`

...

```
X, y = make_regression(n_samples=100, n_features=4, n_informative=2,
random_state=42, shuffle=False)
rf = RandomForestRegressor(max_depth=2, random_state=0)
kf = KFold(n_splits=3)
scorer = make_scorer(mean_squared_error, squared=False)
scores = cross_val_score(rf, X, y, cv=kf, scoring=scorer, n_jobs=5)
print(scores)
print("Mean error using cv_score:", "{:0.5f}".format(scores.mean()))
>>> [25.50144578 28.08988198 12.04946325]
>>> Mean error using cv_score: 21.88026
```

We have found the estimated mean error for the model configuration specified above by averaging over the errors calculated for each fold. Next, let's see how we can score the same model configuration with `cross_val_predict`

...

```
rf_preds = cross_val_predict(rf, X, y, cv=kf, n_jobs=5)
print(rf_preds)
>>> [ 35.69694202 -15.59168309 -11.28825143 21.60466429 -31.96562568
>>> 38.77700627 -19.83164343 -24.38676228 -13.72695055 -1.78560192
>>> 34.89912527 -46.0089495 25.0016941 -14.07779504 -41.93602953
>>> -22.62378198 58.56391394 29.21820121 -1.80628501 -5.11926971
>>> -6.19392869 -42.01781879 -12.12197396 -28.29172172 27.51992864
>>> -44.06038966 -5.74855809 25.48187934 4.31608876 -14.08193166
>>> 31.95718759 54.93512694 -3.77541207 -31.71764816 -34.54156106
>>> 3.23757685 3.31396877 31.64161857 -21.82861194 35.5777048
>>> -27.43229009 35.07735314 -19.79404724 -7.14075063 0.34668447
>>> 25.33268394 -5.65974797 -40.72478199 -13.1132073 -32.31570859
>>> 1.20279636 -41.2647554 62.72557029 42.9298226 -30.25638425
>>> 27.23373331 -8.22833272 -23.86750856 -13.68328394 -33.20953592
>>> -29.49308561 -38.86304346 34.88313197 65.72332256 27.23373331
>>> -32.31570859 -20.33812998 -23.33472881 29.56201955 -17.57730738
>>> 11.00481711 25.0217706 -4.71655636 -5.22493376 37.46886883
>>> -39.41217135 -19.2260896 26.13223673 65.43519148 24.78781493
>>> 11.00481711 -39.98352882 64.40931468 -17.57730738 -37.53827746
>>> -33.5331878 -20.58164569 -31.36741304 28.4852275 -20.28666836
>>> 77.18589095 23.63780232 -17.57730738 75.09259284 29.62332547
>>> -39.41217135 -35.8903216 25.45938026 -18.33439858 -18.33439858]
```

`cross_val_predict`

has returned the 100 out-of-sample predictions ordered by fold. Now, let's mimic what `cross_validate`

does but using the `cross_val_predict`

result...

```
scores = np.array([mean_squared_error(y[x[1]], rf_preds[x[1]], squared=False)
for x in kf.split(X, y)])
print(scores)
print("Score using cv_rf_preds:", "{:0.5f}".format(np.array(scores).mean()))
>>> [25.50144578 28.08988198 12.04946325]
>>> Mean error using cv_rf_preds: 21.88026
```

What have we done? We grabbed the indexes of the out-of-sample elements for each fold, then used these to get the true and predicted values of each of these out-of-sample elements in each fold so each fold can be scored.

*The mean error estimates of the specified model configuration are the ***same**.

Essentially, `cross_val_predict`

can be seen as an intermediate step used in `cross_validate / cross_val_score`

. Because of design decisions in `scikit-learn`

necessary to support parallel fitting of models over the folds, `cross_validate`

does not return the out-of-sample predictions along with the fold scores. So, if we need both the out-of-sample predictions and the scores, and do not want to cross-validate the model twice (`cross_val_predict`

for the out-of-sample predictions then `cross_val_scores`

for the scores ), we can train with `cross_val_predict`

just once, and use its result decomposed over the fold indexes of `Kfold.split`

to calculate the fold scores.

By viewing `cross_val_predict`

as just an intermediate step in the `cross_validate`

process, it highlights the general admonition to **not** score the results of `cross_val_predict`

en masse. These results are useful for many other reasons, but to use them to score a model configuration, more work needs to be done.