# Using numpy.vstack in numba

So I have been trying to optimize some code that calculates a statistical error metric from some array data. The metric is called the Continuous Rank Probability Score (CRPS).

I have been using Numba to try to speed up the double for loop required in this calculation, but I have been having an issue with the `numpy.vstack` function. From what I understand from the docs here, the `vstack()` function should be supported, but when I run the following code I get an error.

``````def crps_hersbach_numba(obs, fcst_ens, remove_neg=False, remove_zero=False):
"""Calculate the the continuous ranked probability score (CRPS) as per equation 25-27 in
Hersbach et al. (2000)

Parameters
----------
obs: 1D ndarry
Array of observations for each start date
fcst_ens: 2D ndarray
Array of ensemble forecast of dimension n x M, where n = number of start dates and
M = number of ensemble members.

remove_neg: bool
If True, when a negative value is found at the i-th position in the observed OR ensemble
array, the i-th value of the observed AND ensemble array are removed before the
computation.

remove_zero: bool
If true, when a zero value is found at the i-th position in the observed OR ensemble
array, the i-th value of the observed AND ensemble array are removed before the
computation.

Returns
-------
dict
Dictionary contains a number of *experimental* outputs including:
- ["crps"] 1D ndarray of crps values per n start dates.
- ["crpsMean1"] arithmetic mean of crps values.
- ["crpsMean2"] mean crps using eqn. 28 in Hersbach (2000).

Notes
-----
**NaN and inf treatment:** If any value in obs or fcst_ens is NaN or inf, then the
corresponding row in both fcst_ens (for all ensemble members) and in obs will be deleted.

References
----------
- Hersbach, H. (2000) Decomposition of the Continuous Ranked Porbability Score
for Ensemble Prediction Systems, Weather and Forecasting, 15, 559-570.
"""
# Treating the Data
obs, fcst_ens = treat_data(obs, fcst_ens, remove_neg=remove_neg, remove_zero=remove_zero)

# Set parameters
n = fcst_ens.shape  # number of forecast start dates
m = fcst_ens.shape  # number of ensemble members

# Create vector of pi's
p = np.linspace(0, m, m + 1)
pi = p / m

crps_numba = np.zeros(n)

@njit
def calculate_crps():
# Loop fcst start times
for i in prange(n):

# Initialise vectors for storing output
a = np.zeros(m - 1)
b = np.zeros(m - 1)

# Verifying analysis (or obs)
xa = obs[i]

# Ensemble fcst CDF
x = np.sort(fcst_ens[i, :])

# Deal with 0 < i < m [So, will loop 50 times for m = 51]
for j in prange(m - 1):

# Rule 1
if xa > x[j + 1]:
a[j] = x[j + 1] - x[j]
b[j] = 0

# Rule 2
if x[j] < xa < x[j + 1]:
a[j] = xa - x[j]
b[j] = x[j + 1] - xa

# Rule 3
if xa < x[j]:
a[j] = 0
b[j] = x[j + 1] - x[j]

# Deal with outliers for i = 0, and i = m,
# else a & b are 0 for non-outliers
if xa < x:
a1 = 0
b1 = x - xa
else:
a1 = 0
b1 = 0

# Upper outlier (rem m-1 is for last member m, but python is 0-based indexing)
if xa > x[m - 1]:
am = xa - x[m - 1]
bm = 0
else:
am = 0
bm = 0

# Combine full a & b vectors including outlier
a = np.concatenate((np.array(), a, np.array([am])))
# a = np.insert(a, 0, a1)
# a = np.append(a, am)
a = np.concatenate((np.array(), a, np.array([bm])))
# b = np.insert(b, 0, b1)
# b = np.append(b, bm)

# Populate a_mat and b_mat
if i == 0:
a_mat = a
b_mat = b
else:
a_mat = np.vstack((a_mat, a))
b_mat = np.vstack((b_mat, b))

# Calc crps for individual start times
crps_numba[i] = ((a * pi ** 2) + (b * (1 - pi) ** 2)).sum()

return crps_numba, a_mat, b_mat

crps, a_mat, b_mat = calculate_crps()
print(crps)
# Calc mean crps as simple mean across crps[i]
crps_mean_method1 = np.mean(crps)

# Calc mean crps across all start times from eqn. 28 in Hersbach (2000)
abar = np.mean(a_mat, 0)
bbar = np.mean(b_mat, 0)
crps_mean_method2 = ((abar * pi ** 2) + (bbar * (1 - pi) ** 2)).sum()

# Output array as a dictionary
output = {'crps': crps, 'crpsMean1': crps_mean_method1,
'crpsMean2': crps_mean_method2}

return output
``````

The error I get is this:

``````Cannot unify array(float64, 1d, C) and array(float64, 2d, C) for 'a_mat', defined at *path

File "test.py", line 86:
def calculate_crps():
<source elided>
if i == 0:
a_mat = a
^

 During: typing of assignment at *path

File "test.py", line 89:
def calculate_crps():
<source elided>
else:
a_mat = np.vstack((a_mat, a))
^

This is not usually a problem with Numba itself but instead often caused by
the use of unsupported features or an issue in resolving types.
``````

I just wanted to know where I am going wrong. It seems as though the `vstack` function should work but maybe I am missing something.

• If performance is of any concern, avoid the np.concatenate and np.vstack (preallocate arrays and fill them afterwards). Even for quite small (n,m) most of the runtime is spend in uneccessary memory allocations and copys. (Each concatenation is equivivalent in allocating a new array and copying all the content into it) Aug 9, 2018 at 14:45

I just wanted to know where I am going wrong. It seems as though the `vstack` function should work but maybe I am missing something.

TL;DR: It's not `vstack` that is the problem. The problem is that you have code-paths that try to assign different types of arrays to the same variable (which throws that unification exception).

The problem lies here:

``````# Populate a_mat and b_mat
if i == 0:
a_mat = a
b_mat = b
else:
a_mat = np.vstack((a_mat, a))
b_mat = np.vstack((b_mat, b))
``````

In the first code-path you assign a 1d c-contigous float64 array to `a_mat` and `b_mat` and in the `else` it's a 2d c-contiguous float64 array. These types are not compatible and thus numba throws an error. It's sometimes tricky that numba code doesn't work like Python code, where it doesn't matter what types you have when you assign something to a variable. However in recent releases the numba exception messages got a lot better so if you know what the exception hints at you can normally quickly find out what's the problem.

### Longer Explanation

The problem is that numba infers the types of your variables implicitly. For example:

``````from numba import njit

@njit
def func(arr):
a = arr
return a
``````

Here I haven't typed the function so I need to run it once:

``````>>> import numpy as np
>>> func(np.zeros(5))
array([0., 0., 0., 0., 0.])
``````

Then you can inspect the types:

``````>>> func.inspect_types()
``````
``````func (array(float64, 1d, C),)
--------------------------------------------------------------------------------
# File: <ipython-input-4-02470248b065>
# --- LINE 3 ---
# label 0

@njit

# --- LINE 4 ---

def func(arr):

# --- LINE 5 ---
#   arr = arg(0, name=arr)  :: array(float64, 1d, C)
#   a = arr  :: array(float64, 1d, C)
#   del arr

a = arr

# --- LINE 6 ---
#   \$0.3 = cast(value=a)  :: array(float64, 1d, C)
#   del a
#   return \$0.3

return a
``````

As you can see the variable `a` is typed for an input of type `array(float64, 1d, C)` as `array(float64, 1d, C)`.

Now, let's use `np.vstack` instead:

``````from numba import njit
import numpy as np

@njit
def func(arr):
a = np.vstack((arr, arr))
return a
``````

And the mandatory first call to compile it:

``````>>> func(np.zeros(5))
array([[0., 0., 0., 0., 0.],
[0., 0., 0., 0., 0.]])
``````

Then inspect the types again:

``````func (array(float64, 1d, C),)
--------------------------------------------------------------------------------
# File: <ipython-input-11-f0214d5181c6>
# --- LINE 4 ---
# label 0

@njit

# --- LINE 5 ---

def func(arr):

# --- LINE 6 ---
#   arr = arg(0, name=arr)  :: array(float64, 1d, C)
#   \$0.1 = global(np: <module 'numpy'>)  :: Module(<module 'numpy'>)
#   \$0.2 = getattr(value=\$0.1, attr=vstack)  :: Function(<function vstack at 0x000001DB7082A400>)
#   del \$0.1
#   \$0.5 = build_tuple(items=[Var(arr, <ipython-input-11-f0214d5181c6> (6)), Var(arr, <ipython-input-11-f0214d5181c6> (6))])  :: tuple(array(float64, 1d, C) x 2)
#   del arr
#   \$0.6 = call \$0.2(\$0.5, func=\$0.2, args=[Var(\$0.5, <ipython-input-11-f0214d5181c6> (6))], kws=(), vararg=None)  :: (tuple(array(float64, 1d, C) x 2),) -> array(float64, 2d, C)
#   del \$0.5
#   del \$0.2
#   a = \$0.6  :: array(float64, 2d, C)
#   del \$0.6

a = np.vstack((arr, arr))

# --- LINE 7 ---
#   \$0.8 = cast(value=a)  :: array(float64, 2d, C)
#   del a
#   return \$0.8

return a
``````

This time `a` is typed as `array(float64, 2d, C)` for an input of `array(float64, 1d, C)`.

You may have asked yourself why I'm talking about that. Let's see what happens if you try to conditionally assign to `a`:

``````from numba import njit
import numpy as np

@njit
def func(arr, condition):
if condition:
a = np.vstack((arr, arr))
else:
a = arr
return a
``````

If you now run the code:

``````>>> func(np.zeros(5), True)
``````
``````TypingError: Failed at nopython (nopython frontend)
Cannot unify array(float64, 2d, C) and array(float64, 1d, C) for 'a', defined at <ipython-input-16-f4bd9a4f377a> (7)

File "<ipython-input-16-f4bd9a4f377a>", line 7:
def func(arr, condition):
<source elided>
if condition:
a = np.vstack((arr, arr))
^

 During: typing of assignment at <ipython-input-16-f4bd9a4f377a> (9)

File "<ipython-input-16-f4bd9a4f377a>", line 9:
def func(arr, condition):
<source elided>
else:
a = arr
^
``````

That's exactly the problem you have and it's because variables need to have one and only one type in numba for a fixed set of input types. And because the dtype, the rank (number of dimensions), and the contiguous property are all part of the type you cannot assign arrays with different dimensions to the same variable.

Note that you could expand the dimensions to make it works and squeeze the unnecessary dimensions again from the result (probably not very nice but it should solve the problem with minimal amount of "changes":

``````from numba import njit
import numpy as np

@njit
def func(arr, condition):
if condition:
a = np.vstack((arr, arr))
else:
a = np.expand_dims(arr, 0)
return a

>>> func(np.zeros(5), False)
array([[0., 0., 0., 0., 0.]])  # <-- 2d array!
>>> func(np.zeros(5), True)
array([[0., 0., 0., 0., 0.],
[0., 0., 0., 0., 0.]])
``````