I think implementation depends of your expectation. You can make pure functional implementation of machine state. You can also make pure functional implementation of transition table as function or module. And finally you can anything of it encapsulate in process using OTP behaviors or not.

Let start with symbols. It can be modeled as atoms and you can choose blank one. It can be atom `'0'`

. It can be some fancy name `blank`

. As you wish. We can define it as constant in `turing.hrl`

.

```
-define(BLANK, '0').
```

Let continue with tape. One elegant implementation is using well known zip structure. It will be 3-tuple `{LEFT, HEAD, RIGHT}`

.

```
-module(tape).
-include("turing.hrl").
-export([new/0, read/1, write/2, left/1, right/1, tape2list/1]).
new() -> {[], ?BLANK, []}.
read({_, HEAD, _}) -> HEAD.
write({LEFT, _, RIGHT}, HEAD) -> {LEFT, HEAD, RIGHT}.
left({LEFT, HEAD, []}) -> {[HEAD|LEFT], ?BLANK, []};
left({LEFT, HEAD, [HR|RIGHT]}) -> {[HEAD|LEFT], HR, RIGHT}.
right({[], HEAD, RIGHT}) -> {[], ?BLANK, [HEAD|RIGHT]};
right({[HL|LEFT], HEAD, RIGHT}) -> {LEFT, HL, [HEAD|RIGHT]}.
tape2list({LEFT, HEAD, RIGHT}) -> lists:reverse(LEFT, [[HEAD]|RIGHT]).
```

Now we can make machine implementation. Let expect table implemented as function `fun(STATE::any(), SYMBOL::any()) -> {NewSTATE::any(), NewSYMBOL::any(), 'left'|'right'}`

and state of machine in format {STATE, TAPE}. So transition can be modeled as function `next/2`

. Then we need function which determines if some state is accepting state `fun(STATE::any()) -> boolean()`

and then we can provide function for simulating machine as `go/3`

, `continue/3`

and extended versions `go/5`

and `continue/5`

with additional parameter for printing state of machine. Printing function can manage it's own state.

```
-module(turing_machine).
-export([next/2, continue/5, continue/3, go/3, go/5, print_with_tape/2]).
next({STATE, TAPE}, F) when is_function(F, 2) ->
{NewSTATE, NewSYMBOL, Dir} = F(STATE, tape:read(TAPE)),
{NewSTATE, tape:Dir(tape:write(TAPE, NewSYMBOL))}.
continue({S, _} = St, Transition, IsAccepting, Print, PS) when
is_function(Transition, 2), is_function(IsAccepting, 1), is_function(Print, 2) ->
case IsAccepting(S) of
true -> St;
false ->
NSt = next(St, Transition),
continue(NSt, Transition, IsAccepting, Print, Print(NSt, PS))
end.
print({S, T}, _) ->
io:format("State: ~p, Head: ~p~n", [S, tape:read(T)]).
print_with_tape({S, T}, _) ->
io:format("State: ~p, Tape: ~p~n", [S, tape:tape2list(T)]).
continue(St, Transition, IsAccepting) ->
continue(St, Transition, IsAccepting, fun print/2, ok).
go(IS, Transition, IsAccepting) ->
go(IS, Transition, IsAccepting, fun print/2, ok).
go(IS, Transition, IsAccepting, Print, PS) ->
continue({IS, tape:new()}, Transition, IsAccepting, Print, PS).
```

Then we can make *busy beaver* machine as function

```
BB = fun
('A', '0') -> {'B', '1', right};
('A', '1') -> {'C', '1', left};
('B', '0') -> {'A', '1', left};
('B', '1') -> {'B', '1', right};
('C', '0') -> {'B', '1', left};
('C', '1') -> {'HALT', '1', right}
end.
BBA = fun(S) -> S =:= 'HALT' end.
```

And than run:

```
> turing_machine:go('A', BB, BBA).
State: 'B', Head: '0'
State: 'A', Head: '1'
State: 'C', Head: '0'
State: 'B', Head: '0'
State: 'A', Head: '0'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '0'
State: 'A', Head: '1'
State: 'C', Head: '1'
State: 'HALT', Head: '1'
{'HALT',{['1'],'1',['1','1','1','1']}}
```

Or more fancy:

```
> turing_machine:go('A', BB, BBA, fun turing_machine:print_with_tape/2, ok).
State: 'B', Tape: [['0'],'1']
State: 'A', Tape: ['1',['1']]
State: 'C', Tape: ['1','1',['0']]
State: 'B', Tape: ['1','1','1',['0']]
State: 'A', Tape: ['1','1','1','1',['0']]
State: 'B', Tape: ['1','1','1',['1'],'1']
State: 'B', Tape: ['1','1',['1'],'1','1']
State: 'B', Tape: ['1',['1'],'1','1','1']
State: 'B', Tape: [['1'],'1','1','1','1']
State: 'B', Tape: [['0'],'1','1','1','1','1']
State: 'A', Tape: ['1',['1'],'1','1','1','1']
State: 'C', Tape: ['1','1',['1'],'1','1','1']
State: 'HALT', Tape: ['1',['1'],'1','1','1','1']
{'HALT',{['1'],'1',['1','1','1','1']}}
```

If you would prefer working with machines as modules you can define behavior `turing_machine`

by adding callbacks into `turing_machine.erl`

```
-callback init_st() -> St::any().
-callback transition(St::any(), Symb::any()) ->
{NewSt::any(), NewSymb::any(), left|right}.
-callback is_accepting(St::any()) -> boolean().
```

And also some additional exported functions

```
-export([go_mod/1, go_mod/3, continue_mod/2, continue_mod/4]).
```

And their implementations

```
go_mod(Mod) ->
go_mod(Mod, fun print/2, ok).
go_mod(Mod, Print, PS) ->
continue_mod(new_st(Mod:init_st()), Mod, Print, PS).
continue_mod(St, Mod) ->
continue_mod(St, Mod, fun print/2, ok).
continue_mod(St, Mod, Print, PS) ->
continue(St, fun Mod:transition/2, fun Mod:is_accepting/1, Print, PS).
```

And than *busy beaver* module

```
-module(busy_beaver).
-behaviour(turing_machine).
-include("turing.hrl").
-define(B, ?BLANK).
-define(P, '1').
-export([init_st/0, transition/2, is_accepting/1]).
init_st() -> 'A'.
transition('A', ?B) -> {'B', ?P, right};
transition('A', ?P) -> {'C', ?P, left};
transition('B', ?B) -> {'A', ?P, left};
transition('B', ?P) -> {'B', ?P, right};
transition('C', ?B) -> {'B', ?P, left};
transition('C', ?P) -> {'HALT', ?P, right}.
is_accepting(St) -> St =:= 'HALT'.
```

And then it can be used as

```
> turing_machine:go_mod(busy_beaver).
State: 'B', Head: '0'
State: 'A', Head: '1'
State: 'C', Head: '0'
State: 'B', Head: '0'
State: 'A', Head: '0'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '1'
State: 'B', Head: '0'
State: 'A', Head: '1'
State: 'C', Head: '1'
State: 'HALT', Head: '1'
{'HALT',{['1'],'1',['1','1','1','1']}}
```

Or even

```
> turing_machine:go_mod(busy_beaver, fun turing_machine:print_with_tape/2, ok).
State: 'B', Tape: [['0'],'1']
State: 'A', Tape: ['1',['1']]
State: 'C', Tape: ['1','1',['0']]
State: 'B', Tape: ['1','1','1',['0']]
State: 'A', Tape: ['1','1','1','1',['0']]
State: 'B', Tape: ['1','1','1',['1'],'1']
State: 'B', Tape: ['1','1',['1'],'1','1']
State: 'B', Tape: ['1',['1'],'1','1','1']
State: 'B', Tape: [['1'],'1','1','1','1']
State: 'B', Tape: [['0'],'1','1','1','1','1']
State: 'A', Tape: ['1',['1'],'1','1','1','1']
State: 'C', Tape: ['1','1',['1'],'1','1','1']
State: 'HALT', Tape: ['1',['1'],'1','1','1','1']
{'HALT',{['1'],'1',['1','1','1','1']}}
```

And then you can choose make it processes or OTP workers in one or other way.