For long lists a divide-and-conquer is typically faster. The idea is to compute the times-mod for the first and second halves, multiply that, and take the mod.

Here is an example. We'll use a list of 10^6 integers, all between 0 and 10^10.

```
SeedRandom[1111111];
len = 6;
max = 10;
list = RandomInteger[10^max, 10^len];
```

Multiplying and taking the modulus, for a slightly larger mod (I wanted to decrease the likelihood that the result was zero):

```
In[119]:= Timing[Mod[Times @@ list, 32327541]]
Out[119]= {1.360000, 8826597}
```

Here is a variant of the sort I described. Trial and error tuning indicated that lists of length 2^9 or so were best done nonrecursively, at least for numbers in the size range indicated above.

```
tmod2[ll_List, m_] := With[{len=Floor[Length[ll]/2]},
If[len<=256,
Mod[Times @@ ll, m],
Mod[tmod2[Take[ll,len],m] * tmod2[Drop[ll,len],m], m]]]
In[120]:= Timing[tmod2[list, 32327541]]
Out[120]= {0.310000, 8826597}
```

When I increase the list length to 10^7 and allow ints from 0 to 10^20, the first method takes 50 seconds and the second one takes 5 seconds. So clearly the scaling is working to our advantage.

For situations where an iteration interleaving two operations might be preferred to divide-and-conquer, one might use Fold as below.

```
tmod3[ll_List, m_] := Fold[Mod[#1*#2,m]&, First[ll], Rest[ll]]
```

While not competitive with tmod2 on long lists, this is faster than multiplying out everything prior to invoking Mod. For length 10^7 and max element 0f 10^20 it takes around 8 seconds to do what tmod2 did in 5.