One slight interpretation change is you need to mark a loss as a `1`

and a win as a `0`

.

The first step is to find the edges of the losing runs, (`steps`

+ `edges`

). You then need to take the difference of the sizes of the steps and shove those values back into the original data. When you take a `cumsum`

of `toss2`

it gives you the current length of your losing streak. Your bet is then `2 ** cumsum(toss2)`

.

The `numpy`

version is faster than the `pandas`

version, but the factor depends on `N`

(~8 for `N=100`

and ~2 for `N > 10000`

).

# pandas

Using `pandas.Series`

:

```
import pandas as pd
toss = np.random.randint(0,2,100)
toss = pd.Series(toss)
steps = (toss.cumsum() * toss).diff() # mask out the cumsum where we won [0 1 2 3 0 0 4 5 6 ... ]
edges = steps < 0 # find where the cumsum steps down -> where we won
dsteps = steps[edges].diff() # find the length of each losing streak
dsteps[steps[edges].index[0]] = steps[edges][:1] # fix length of the first run which in now NaN
toss2 = toss.copy() # get a copy of the toss series
toss2[edges] = dsteps # insert the length of the losing streaks into the copy of the toss results
bets = 2 ** (toss2).cumsum() # compute the wagers
res = pd.DataFrame({'toss': toss,
'toss2': toss2,
'runs': toss2.cumsum(),
'next_bet': bets})
```

# numpy

This is the pure `numpy`

version (my native language is it were). There is a bit of fineagling to get the arrays to line up that `pandas`

does for you

```
toss = np.random.randint(0,2,100)
steps = np.diff(np.cumsum(toss) * toss)
edges = steps < 0
edges_shift = np.append(False, edges[:-1])
init_step = steps[edges][0]
toss2 = np.array(toss)
toss2[edges_shift] = np.append(init_step, np.diff(steps[edges]))
bets = 2 ** np.cumsum(toss2)
fmt_dict = {1:'l', 0:'w'}
for t, b in zip(toss, bets):
print fmt_dict[t] + '-> {0:d}'.format(b)
```

## pandas output

```
In [65]: res
Out[65]:
next_bet runs toss toss2
0 1 0 0 0
1 2 1 1 1
2 4 2 1 1
3 8 3 1 1
4 16 4 1 1
5 1 0 0 -4
6 1 0 0 0
7 2 1 1 1
8 4 2 1 1
9 1 0 0 -2
10 1 0 0 0
11 2 1 1 1
12 4 2 1 1
13 1 0 0 -2
14 1 0 0 0
15 2 1 1 1
16 1 0 0 -1
17 1 0 0 0
18 2 1 1 1
19 1 0 0 -1
20 1 0 0 0
21 1 0 0 0
22 2 1 1 1
23 1 0 0 -1
24 2 1 1 1
25 1 0 0 -1
26 1 0 0 0
27 1 0 0 0
28 2 1 1 1
29 4 2 1 1
30 1 0 0 -2
31 2 1 1 1
32 4 2 1 1
33 1 0 0 -2
34 1 0 0 0
35 1 0 0 0
36 1 0 0 0
37 2 1 1 1
38 4 2 1 1
39 1 0 0 -2
40 2 1 1 1
41 4 2 1 1
42 8 3 1 1
43 1 0 0 -3
44 1 0 0 0
45 1 0 0 0
46 1 0 0 0
47 2 1 1 1
48 1 0 0 -1
49 2 1 1 1
50 1 0 0 -1
51 1 0 0 0
52 1 0 0 0
53 1 0 0 0
54 1 0 0 0
55 2 1 1 1
56 1 0 0 -1
57 1 0 0 0
58 1 0 0 0
59 1 0 0 0
60 1 0 0 0
61 2 1 1 1
62 1 0 0 -1
63 2 1 1 1
64 4 2 1 1
65 8 3 1 1
66 16 4 1 1
67 32 5 1 1
68 1 0 0 -5
69 2 1 1 1
70 1 0 0 -1
71 2 1 1 1
72 4 2 1 1
73 1 0 0 -2
74 2 1 1 1
75 1 0 0 -1
76 1 0 0 0
77 2 1 1 1
78 4 2 1 1
79 1 0 0 -2
80 1 0 0 0
81 2 1 1 1
82 1 0 0 -1
83 1 0 0 0
84 1 0 0 0
85 1 0 0 0
86 2 1 1 1
87 4 2 1 1
88 8 3 1 1
89 16 4 1 1
90 32 5 1 1
91 64 6 1 1
92 1 0 0 -6
93 1 0 0 0
94 1 0 0 0
95 1 0 0 0
96 2 1 1 1
97 1 0 0 -1
98 1 0 0 0
99 1 0 0 0
```

## numpy output

(different seed than panadas results)

```
(result -> next bet):
w-> 1
l-> 2
w-> 1
w-> 1
l-> 2
w-> 1
l-> 2
w-> 1
l-> 2
l-> 4
w-> 1
l-> 2
w-> 1
l-> 2
l-> 4
w-> 1
w-> 1
w-> 1
l-> 2
l-> 4
l-> 8
w-> 1
l-> 2
l-> 4
w-> 1
l-> 2
l-> 4
w-> 1
w-> 1
l-> 2
w-> 1
w-> 1
w-> 1
w-> 1
l-> 2
l-> 4
w-> 1
w-> 1
l-> 2
l-> 4
l-> 8
w-> 1
w-> 1
l-> 2
l-> 4
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
l-> 2
w-> 1
l-> 2
w-> 1
l-> 2
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
l-> 2
l-> 4
l-> 8
l-> 16
w-> 1
l-> 2
l-> 4
w-> 1
w-> 1
w-> 1
w-> 1
l-> 2
w-> 1
w-> 1
l-> 2
w-> 1
w-> 1
w-> 1
l-> 2
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
w-> 1
l-> 2
l-> 4
l-> 8
w-> 1
w-> 1
l-> 2
l-> 4
l-> 8
w-> 1
l-> 2
l-> 4
w-> 1
l-> 2
```