Not a trivial problem because data is misaligned. Performance depends on what is a *long* sequence. Take the example of a *square* problem : a *lot of*, *long*, regular and zeros sequences (`n_iter==n_reg==lag_mean`

):

```
import numpy as np
n_iter = 1000
n_reg = 1000
regular_sequence = np.arange(n_reg, dtype=np.int)
lag_mean = n_reg # mean length of zeros sequence
lag_sd = lag_mean/10 # standard deviation of zeros sequence length
lag_seq=np.int64(np.random.normal(lag_mean,lag_sd,n_iter)) # Sequence of lags lengths
```

First your solution :

```
def seq_hybrid():
seqs = [np.concatenate((np.zeros(x, dtype=np.int), regular_sequence)) for x in lag_seq]
seq = np.concatenate(seqs)
return seq
```

Then a pure numpy one :

```
def seq_numpy():
seq=np.zeros(lag_seq.sum()+n_iter*n_reg,dtype=int)
cs=np.cumsum(lag_seq+n_reg)-n_reg
indexes=np.add.outer(cs,np.arange(n_reg))
seq[indexes]=regular_sequence
return seq
```

A for loop solution :

```
def seq_python():
seq=np.empty(lag_seq.sum()+n_iter*n_reg,dtype=int)
i=0
for lag in lag_seq:
for k in range(lag):
seq[i]=0
i+=1
for k in range(n_reg):
seq[i]=regular_sequence[k]
i+=1
return seq
```

And a just in time compilation with numba :

```
from numba import jit
seq_numba=jit(seq_python)
```

Tests now :

```
In [96]: %timeit seq_hybrid()
10 loops, best of 3: 38.5 ms per loop
In [97]: %timeit seq_numpy()
10 loops, best of 3: 34.4 ms per loop
In [98]: %timeit seq_python()
1 loops, best of 3: 1.56 s per loop
In [99]: %timeit seq_numba()
100 loops, best of 3: 12.9 ms per loop
```

Your hybrid solution is quite as speed as a pure numpy one in this case because
the performance depend essentially of the inner loop. And yours (zeros and concatenate) is a numpy one. Predictably , python solution is slower with a traditional about **40x** factor. But numpy is not optimal here, because it uses fancy indexing, necessary with misaligned data . In this case numba can help you : minimal operations are done at C level, for a **120x** factor gain this time compared to the python solution.

For other values of `n_iter,n_reg`

the factor gains compared to the python solution are:

```
n_iter= 1000, n_reg= 1000 : seq_numba 124, seq_hybrid 49, seq_numpy 44.
n_iter= 10, n_reg= 100000 : seq_numba 123, seq_hybrid 104, seq_numpy 49.
n_iter= 100000, n_reg= 10 : seq_numba 127, seq_hybrid 1, seq_numpy 42.
```

`regular_sequence`

into carefully-chosen random places in this array?`N(10, 1)`

? The chances of that ever occuring are astronomically small, but if those parameters are not fixed, you may run into this problem. Is it an option to simply sample from a uniform distribution over some range?`regular_sequence`

s. So, there will be another line of code which will replace any negative value of`lag_seq`

with 0.