So the problem is that `test1`

is defined in terms of global variable `Global`a`

,
but the `a`

defined in the manipulate is created by a `DynamicModule`

and is thus local. This is what acl showed with his `Hold[a]`

example.

Maybe the easiest way to fix this is to use `With`

to insert `test1`

into the manipulate:

```
Clear[a, b, c]
test1 = {a, b, c};
With[{test1 = test1},
Manipulate[test1, {a, 0, 10, .1}, {b, 0, 10, .1}, {c, 0, 10, .1}]]
```

This way the `Manipulate`

never actually sees `test1`

, all it sees is `{a,b,c}`

which it then goes on to correctly localize. Although, this will run into problems if `a,b,c`

have been given a value before the `Manipulate`

is run - thus the `Clear[a,b,c]`

command.

I think that the *best practice* is to make all local variables completely explicit in the manipulate. So you should do something like

```
Clear[a, b, c, test1]
test1[a_, b_, c_] := {a, b, c};
Manipulate[test1[a, b, c], {a, 0, 10, .1}, {b, 0, 10, .1}, {c, 0, 10, .1}]
```

This avoids problems with the global vs local variables that you were having. It also makes it easier for you when you have to come back and read your own code again.

**Edit** to answer the question in the comments *"I really would like to understand why Evaluate does not work with the somewhat nested ListPlot?"*. IANLS (I am not Leonid Shifrin) and so I don't have a perfect Mathematica (non)standard evaluation sequence running in my brain, but I'll try to explain what's going on.

Ok, so unlike `Plot`

, `ListPlot`

does not need to localize any variables, so it does not have the `Attribute`

`HoldAll`

.

Let's define something similar to your example:

```
ClearAll[a, test]
test = {a, a + 1};
```

**The final example** you gave is like

```
Manipulate[Evaluate[ListPlot[test]], {a, 0, 1}]
```

By looking at the `Trace`

, you see that this first evaluates the first argument which is `ListPlot[test] ~> ListPlot[{a,a+1}]`

and since `a`

is not yet localized, it produces an empty list plot. To see this, simply run

```
ListPlot[{a, a + 1}]//InputForm
```

to get the empty graphics object

```
Graphics[{}, {AspectRatio -> GoldenRatio^(-1), Axes -> True, AxesOrigin -> {0, 0}, PlotRange -> {{0., 0.}, {0., 0.}}, PlotRangeClipping -> True, PlotRangePadding -> {Scaled[0.02], Scaled[0.02]}}]
```

As the symbolic values `a`

have been thrown out, they can not get localized by the `Manipulate`

and so not much else happens.

This could be fixed by still evaluating the first argument, but not calling `ListPlot`

until after `Manipulate`

has localized the variables. For example, both of the following work

```
Manipulate[Evaluate[listPlot[test]], {a, 0, 1}] /. listPlot -> ListPlot
Manipulate[Evaluate[Hold[ListPlot][test]], {a, 0, 1}] // ReleaseHold
```

The fact that `ListPlot`

throws away non-numeric values without even the slightest complaint, is probably a feature, but can lead to some annoyingly hard to track bugs (like the one this question pertains to). Maybe a more consistent (but less useful?) behaviour would be to return an unevaluated `ListPlot`

if the plot values are non-numeric... Or to at least issue a warning that some non-numeric points have been discarded.

**The penultimate example** you gave is (more?) interesting, it looks like

```
Manipulate[ListPlot[Evaluate[test]], {a, 0, 1}]
```

Now since `Manipulate`

has the attribute `HoldAll`

, the first thing it does is wrap the arguments in `Hold`

, so if you look at the `Trace`

, you'll see `Hold[ListPlot[Evaluate[test]]]`

being carried around. The `Evaluate`

**is not seen**, since as described in the Possible Issues section, *"Evaluate works only on the first level, directly inside a held function"*. This means that `test`

is not evaluated until after the variables have been localized and so they are taken to be the global `a`

and not the local (`DynamicModule`

) `a`

.

It's worth thinking about how the following variations work

```
ClearAll[a, test, f, g]
SetAttributes[g, HoldAll];
test = {a, a + 1};
Grid[{
{Manipulate[test, {a, 0, 1}], Manipulate[Evaluate[test], {a, 0, 1}]},
{Manipulate[f[test], {a, 0, 1}],
Manipulate[f[Evaluate[test]], {a, 0, 1}]},
{Manipulate[g[test], {a, 0, 1}],
Manipulate[g[Evaluate[test]], {a, 0, 1}]}
}]
```