There is a natural sequence indexing, but no so easy to calculate.

Let look for A_n for n>0, since A_0 = 1.

Indexing is done in 2 steps.

## Part 1:

Group sequences by places where A_n = max(A_0 .. A_n-1) + 1. Call these places *steps*.

- On steps are consecutive numbers (2,3,4,5,...).
- On non-step places we can put numbers from 1 to number of steps with index less than k.

Each group can be represent as binary string where 1 is step and 0 non-step. E.g. 001001010 means group with 112aa3b4c, a<=2, b<=3, c<=4. Because, groups are indexed with binary number there is natural indexing of groups. From 0 to 2^length - 1. Lets call value of group binary representation *group order*.

## Part 2:

Index sequences inside a group. Since groups define step positions, only numbers on non-step positions are variable, and they are variable in defined ranges. With that it is easy to index sequence of given group inside that group, with lexicographical order of variable places.

It is easy to calculate number of sequences in one group. It is number of form 1^i_1 * 2^i_2 * 3^i_3 * ....

## Combining:

This gives a 2 part key: `<Steps, Group>`

this then needs to be mapped to the integers. To do that we have to find how many sequences are in groups that have order less than some value. For that, lets first find how many sequences are in groups of given length. That can be computed passing through all groups and summing number of sequences or similar with recurrence. Let T(l, n) be number of sequences of length l (A_0 is omitted ) where maximal value of first element can be n+1. Than holds:

```
T(l,n) = n*T(l-1,n) + T(l-1,n+1)
T(1,n) = n
```

Because `l + n <= sequence length + 1`

there are ~`sequence_length^2/2`

T(l,n) values, which can be easily calculated.

Next is to calculate number of sequences in groups of order less or equal than given value. That can be done with summing of T(l,n) values. E.g. number of sequences in groups with order <= 1001010 binary, is equal to

```
T(7,1) + # for 1000000
2^2 * T(4,2) + # for 001000
2^2 * 3 * T(2,3) # for 010
```

## Optimizations:

This will give a mapping but the direct implementation for combining the key parts is `>O(1)`

at best. On the other hand, the `Steps`

portion of the key is small and by computing the range of `Groups`

for each `Steps`

value, a lookup table can reduce this to `O(1)`

.

I'm not 100% sure about upper formula, but it should be something like it.

With these remarks and recurrence it is possible to make functions sequence -> index and index -> sequence. But not so trivial :-)