Here is a hack which may enable your code to be fast, but I don't guarantee it to always work correctly:

```
ClearAll[withFastCoefficient];
SetAttributes[withFastCoefficient, HoldFirst];
withFastCoefficient[code_] :=
Block[{Binomial},
Binomial[x_, y_] := 10 /; ! FreeQ[Stack[_][[-6]], Coefficient];
code]
```

Using it, we get:

```
In[58]:= withFastCoefficient[Coefficient[expr,x,234]]//Timing
Out[58]= {0.172,3116518719381876183528738595379210}
```

The idea is that, `Coefficient`

is using `Binomial`

internally to estimate the number of terms, and then expands (calls `Expand`

) if the number of terms is less than `1000`

, which you can check by using `Trace[..., TraceInternal->True]`

. And when it does not expand, it computes lots of sums of large coefficient lists dominated by zeros, and this is apparently slower than expanding, for a range of expressions. What I do is to fool `Binomial`

into returning a small number (`10`

), but I also tried to make it such that it will only affect the `Binomial`

called internally by `Coefficient`

:

```
In[67]:= withFastCoefficient[f[Binomial[7,4]]Coefficient[expr,x,234]]
Out[67]= 3116518719381876183528738595379210 f[35]
```

I can not however guarantee that there are no examples where `Binomial`

somewhere else in the code will be computed incorrectly.

**EDIT**

Of course, a safer alternative that always exists is to redefine `Coefficient`

using the Villegas - Gayley trick, expanding an expression inside it and calling it again:

```
Unprotect[Coefficient];
Module[{inCoefficient},
Coefficient[expr_, args__] :=
Block[{inCoefficient = True},
Coefficient[Expand[expr], args]] /; ! TrueQ[inCoefficient]
];
Protect[Coefficient];
```

**EDIT 2**

My first suggestion had an advantage that we defined a macro which modified the properties of functions locally, but disadvantage that it was unsafe. My second suggestion is safer but modifies `Coefficient`

globally, so it will *always* expand until we remove that definition. We can have the best of both worlds with the help of `Internal`InheritedBlock`

, which creates a local copy of a given function. Here is the code:

```
ClearAll[withExpandingCoefficient];
SetAttributes[withExpandingCoefficient, HoldFirst];
withExpandingCoefficient[code_] :=
Module[{inCoefficient},
Internal`InheritedBlock[{Coefficient},
Unprotect[Coefficient];
Coefficient[expr_, args__] :=
Block[{inCoefficient = True},
Coefficient[Expand[expr], args]] /; ! TrueQ[inCoefficient];
Protect[Coefficient];
code
]
];
```

The usage is similar to the first case:

```
In[92]:= withExpandingCoefficient[Coefficient[expr,x,234]]//Timing
Out[92]= {0.156,3116518719381876183528738595379210}
```

The main `Coefficient`

function remains unaffected however:

```
In[93]:= DownValues[Coefficient]
Out[93]= {}
```

`Coefficient`

's algorithm trades off speed for space, to be able to work on expressions with an extremely long expanded form? BTW your computer is 4.5 times faster than mine. – Szabolcs Nov 23 '11 at 14:33`Coefficient`

is far more memory efficient on`(1 + x)^50000`

. Is there anything reasonable I can do to make a generalized function that calls`Coefficient`

faster? Is there some kind of semi-expanded form, or`Method`

option that that would give me a balance between these options? – Mr.Wizard Nov 23 '11 at 14:53