# Mathematica Module Not Returning Value

I am new to Mathematica, and using a Module to perform a procedure, then return a value. However, Mathematica seems to be evaluating and returning symbolic values instead of the numerical value I want.

Questions I have are: When don't you use semicolons? And when do you use Return[value] instead of just writing "value"?

``````DumpVar[x_] := Print[ToString[HoldForm[x]], ":", x];
SetAttributes[DumpVar, {Listable, HoldAll}]

width = 1;
interval = width/2;

panelCoeff = 2;
lightAngle = Pi/3;

(*Panel and light equations*)

panel[x_] = Abs[panelCoeff x];(*panelCoeff ((x)^2);*)

light[x_] = Tan[lightAngle]*x;

getAngleAttack[offset_] :=
Module[{bounce1x, l1a, lightSlope, panelSlope},
light[x_] = light'[x] (x - offset) + panel[interval];
DumpVar[offset];

lightSlope = N[light'[offset]];
u1S = light'[offset];
u1[x_] = (u1S (x - offset)) + panel[interval];

bounce1x =
x /. N[NSolve[u1[x] == panel[x] && x < interval && x > -interval,
x]];

u1r[x_] = panel'[bounce1x] (x - bounce1x) + panel[bounce1x];

If[Length[bounce1x] > 0,
bounce1x = bounce1x[[1]];,
bounce1x = offset;
]

If[bounce1x > -interval && bounce1x < interval,

lightSlope = N[u1'[bounce1x]];

If[x <= 0,
panelSlope := N[panelCoeff],
panelSlope := -N[panelCoeff]];

DumpVar[lightSlope];
DumpVar[panelSlope];
l1a =
N[ArcTan[(lightSlope -
panelSlope)/(1 + (panelSlope lightSlope))]];

DumpVar[l1a];

l1a
Return[l1a]
]

Return[l1a];
];

myint = getAngleAttack[0];
(*myint = N[f[10]];*)
DumpVar[myint];

Plot[{panel[x], light[x]}, {x, -.6, .6}]

myint = getAngleAttack[.5];
DumpVar[myint];
``````

My goal is to be able to graph and integrate this function.

-
I have to work through this, but be careful in how you name your variables. It's not obvious what you mean by `light[x_] = light'[x] (x - offset) + panel[interval]` –  Mike Bantegui Nov 15 '11 at 16:50
@yoda: There's a few other issues too. Further down in the module is a bunch of problems. I'll post an answer with some notes. –  Mike Bantegui Nov 15 '11 at 16:56
Fantastic! Thank you. :-) –  Geekgirl Nov 15 '11 at 17:08
I've added some additional notes to further simplify/explain some points. –  rcollyer Nov 15 '11 at 18:02

In the middle of your block you have:

``````If[Length[bounce1x] > 0,
bounce1x = bounce1x[[1]];,
bounce1x = offset;
]
``````

The format of `If` is as follows: `If[Condition, ValueIfTrue, ValueIfFalse]`

So `If[True, 3, 2]` returns 3, and `If[False, 3, 2]` returns 2. Your semicolons here are unnecessary, but you do need one at the end of the if statement:

``````If[Length[bounce1x] > 0,
bounce1x = bounce1x[[1]],
bounce1x = offset
];
``````

Otherwise, Mathematica will interpret that as multiplication of that statement times whatever the next one to show up will be. In this case, you're returning `null` from that `If` statement, and it's being multiplied by the return value of the next `If` statement that comes up.

For `Module` the syntax is: `Module[{localvars}, ReturnValue]`

Which means whatever is the last statement that shows up without a semicolon is the ReturnValue. So for example the following module:

``````Module[{y},
y = x * x;
If[x < 0, -y, +y]
]
``````

will return -y when x < 0, and +y otherwise. The one exception this is when `Return` shows up. Just like in most languages, you can return early from a function by using `Return`:

``````Module[{y},
y = x * x;
If[x < 0,
Return[-y],
Return[+y]];
(* We never reach this point to return null *)
];
``````

With respect to your `Module`, I think this may be what you're trying to accomplish:

``````getAngleAttack[offset_] :=
Module[{bounce1x, l1a, lightSlope, panelSlope},
light[x_] = light'[x] (x - offset) + panel[interval];
DumpVar[offset];

lightSlope = N[light'[offset]];
u1S = light'[offset];
u1[x_] = (u1S (x - offset)) + panel[interval];

bounce1x =
x /. N[NSolve[u1[x] == panel[x] && x < interval && x > -interval,
x]];

u1r[x_] = panel'[bounce1x] (x - bounce1x) + panel[bounce1x];

If[Length[bounce1x] > 0,
bounce1x = bounce1x[[1]],
bounce1x = offset];

If[bounce1x > -interval && bounce1x < interval,

lightSlope = N[u1'[bounce1x]];

If[x <= 0,
panelSlope := N[panelCoeff],
panelSlope := -N[panelCoeff]];

DumpVar[lightSlope];
DumpVar[panelSlope];

l1a = N[
ArcTan[(lightSlope - panelSlope)/(1 + (panelSlope lightSlope))]];

DumpVar[l1a];
Return[l1a]
];
l1a]
``````

Another thing you should watch out for is any variables you use inside of a `Module`. If you run the following piece of code, you'll get `4, -113/5, 32` as the output values:

``````d = 4 (* d was 4 *)
Module[{a, b, c},
a = 3;
b = 2;
c = 5;
d = 32; (* Uh oh! I just overwrite whatever d was *)
a^2 + b / c - d]
d (* d is now 32 *)
``````

To avoid this, define any variables you're using as local variables within the start of the `Module`: `Module[{a, b, c, d}, ...]`

-
Thanks! I was having trouble figuring out that syntax, especially coming from programming languages where semicolons are in EVERY line. :-) –  Geekgirl Nov 15 '11 at 17:10
The semicolons here are necessary if you want to do something but NOT return a value. The semantics of semicolons in Mathematica are to suppress the return value of a statement, and instead return `null`. So in a sense, you do need semicolons on almost every line. –  Mike Bantegui Nov 15 '11 at 17:13
@Geekgirl Perhaps now is a good time to tell that ';' is actually -just like everything else in Mathematica- a function. In this case the function `CompoundExpression`,with `a;b` being equivalent to `CompoundExpression[a,b]` and `a;b;` equivalent to `CompoundExpression[a,b,Null]` –  Sjoerd C. de Vries Nov 15 '11 at 17:48
@SjoerdC.deVries, beat me to it. I wrote a more lengthy answer that included that. –  rcollyer Nov 15 '11 at 18:03

I'd like to add a couple of things to Mike's excellent answer.

First, semi-colons are way of building compound expressions, and as Mike pointed out, they suppress the output of the immediately preceding statement. But, they're most useful in allowing you to chain multiple expressions together where only a single expression is expected, like in the body of a `Module`, as you're doing. However, they're useful for simpler things like this contrived example

``````a = 5;
b = (Print[a]; a - 3)
``````

Note the parentheses; `;` has a lower precedence than `=`, so

``````b = Print[a]; a - 3
``````

would set b to the return value of `Print` which is `Null`.

To incorporate what Sjoerd was saying in his comment, the expression

``````b = (Print[a]; a - 3)
``````

is interpreted as

``````Set[b, CompoundExpression[ Print[a], a - 3] ]
``````

while the second, incorrect, form is interpreted as

``````CompoundExpression[ Set[b, Print[a]], a - 3]
``````

If you want to see what form an expression takes, use `FullForm[Hold[ expression ]]` which reveals the internal form of an expression. You need to use `Hold` when you don't want anything to be executed prior to examining its form, as would be the case with `Set`.

Second, when using an `If` expression to `Set` a variable to different values, it can be pulled out of the `If` statement, as follows

`````` bounce1x = If[Length[bounce1x] > 0, bounce1x[[1]], offset];
``````

Since `If` will return either `bounce1x[[1]]` or `offset`. This can greatly simplify your expressions. This also works with `SetDelayed` (`:=`), like for `panelSlope`

``````panelSlope := If[x <= 0, N[panelCoeff], -N[panelCoeff]];
``````

However, I wouldn't use `SetDelayed` here as you don't need to recalculate `panelSlope` every time you use it. Also, you can simplify that a little by using `UnitStep`,

``````panelSlope = (1 - 2 UnitStep[x]) N[panelCoeff];
``````

or, even

``````panelSlope = If[x<=0, 1, -1] N[panelCoeff];
``````

(`Sign` wouldn't be appropriate here, as it will return zero when its parameter is 0.)

Lastly, there's a bug in your code with regards to `l1a`. Your `Module` returns it, but if the `bounce1x > -interval && bounce1x < interval` condition is not met, the `If` statement where it is set is not entered. So, it will return something of the form `l1a\$###` where `###` are numbers. Also, I'd get rid of the `Return[ l1a ]` in that `If` statement entirely, as it is not necessary, `l1a` is set within the `If` statement.

-
@Sjoerd, sorry, I'm not as familiar with the "o" before "e" rules as I am with the "i" before "e" rules. :) –  rcollyer Nov 15 '11 at 19:10
No problemo, amigo –  Sjoerd C. de Vries Nov 15 '11 at 19:25
Thank you so much for such a helpful and thorough answer! It's exactly the information I was lacking. :-) –  Geekgirl Nov 16 '11 at 3:12
@Geekgirl, you're welcome. –  rcollyer Nov 16 '11 at 3:16