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list:={ Plus[1,1], Times[2,3] }

When looking at list, I get


I want to keep them unevaluated (as above) so that list returns

{ Plus[1,1], Times[2,3] }

Later I want to evaluate the functions in list sequence to get


The number of unevaluated functions in list is not known beforehand. Besides Plus, user defined functions like f[x_] may be stored in list

I hope the example is clear.

What is the best way to do this?

share|improve this question
up vote 10 down vote accepted

The best way is to store them in Hold, not List, like so:

In[255]:= f[x_] := x^2;
lh = Hold[Plus[1, 1], Times[2, 3], f[2]]

Out[256]= Hold[1 + 1, 2 3, f[2]]

In this way, you have full control over them. At some point, you may call ReleaseHold to evaluate them:

In[258]:= ReleaseHold@lh

Out[258]= Sequence[2, 6, 4]

If you want the results in a list rather than Sequence, you may use just List@@lh instead. If you need to evaluate a specific one, simply use Part to extract it:

In[261]:= lh[[2]]

Out[261]= 6

If you insist on your construction, here is a way:

In[263]:= l:={Plus[1,1],Times[2,3],f[2]};

Out[264]= Hold[{1+1,2 3,f[2]}]


In case you have some functions/symbols with UpValues which can evaluate even inside Hold, you may want to use HoldComplete in place of Hold.


As pointed by @Mr.Wizard in another answer, sometimes you may find it more convenient to have Hold wrapped around individual items in your sequence. My comment here is that the usefulness of both forms is amplified once we realize that it is very easy to transform one into another and back. The following function will split the sequence inside Hold into a list of held items:

splitHeldSequence[Hold[seq___], f_: Hold] := List @@ Map[f, Hold[seq]]

for example,

In[274]:= splitHeldSequence[Hold[1 + 1, 2 + 2]]

Out[274]= {Hold[1 + 1], Hold[2 + 2]}

grouping them back into a single Hold is even easier - just Apply Join:

In[275]:= Join @@ {Hold[1 + 1], Hold[2 + 2]}

Out[275]= Hold[1 + 1, 2 + 2]

The two different forms are useful in diferrent circumstances. You can easily use things such as Union, Select, Cases on a list of held items without thinking much about evaluation. Once finished, you can combine them back into a single Hold, for example, to feed as unevaluated sequence of arguments to some function.


Per request of @ndroock1, here is a specific example. The setup:

l = {1, 1, 1, 2, 4, 8, 3, 9, 27} 
S[n_] := Module[{}, l[[n]] = l[[n]] + 1; l] 
Z[n_] := Module[{}, l[[n]] = 0; l]

placing functions in Hold:

In[43]:= held = Hold[Z[1], S[1]]

Out[43]= Hold[Z[1], S[1]]

Here is how the exec function may look:

exec[n_] := MapAt[Evaluate, held, n]


In[46]:= {exec[1], exec[2]}

Out[46]= {Hold[{0, 1, 1, 2, 4, 8, 3, 9, 27}, S[1]],  Hold[Z[1], {1, 1, 1, 2, 4, 8, 3, 9, 27}]}

Note that the original variable held remains unchanged, since we operate on the copy. Note also that the original setup contains mutable state (l), which is not very idiomatic in Mathematica. In particular, the order of evaluations matter:

In[61]:= Reverse[{exec[2], exec[1]}]

Out[61]= {Hold[{0, 1, 1, 2, 4, 8, 3, 9, 27}, S[1]],  Hold[Z[1], {2, 1, 1, 2, 4, 8, 3, 9, 27}]}

Whether or not this is desired depends on the specific needs, I just wanted to point this out. Also, while the exec above is implemented according to the requested spec, it implicitly depends on a global variable l, which I consider a bad practice.

An alternative way to store functions suggested by @Mr.Wizard can be achieved e.g. like

In[63]:= listOfHeld = splitHeldSequence[held]

Out[63]= {Hold[Z1], Hold[S1]}

and here

In[64]:= execAlt[n_] := MapAt[ReleaseHold, listOfHeld, n]

In[70]:= l = {1, 1, 1, 2, 4, 8, 3, 9, 27} ;
{execAlt[1], execAlt[2]}

Out[71]= {{{0, 1, 1, 2, 4, 8, 3, 9, 27}, Hold[S[1]]}, {Hold[Z[1]], {1, 1, 1, 2, 4, 8, 3, 9, 27}}}

The same comments about mutability and dependence on a global variable go here as well. This last form is also more suited to query the function type:

getType[n_, lh_] := lh[[n]] /. {Hold[_Z] :> zType, Hold[_S] :> sType, _ :> unknownType}

for example:

In[172]:= getType[#, listOfHeld] & /@ {1, 2}

Out[172]= {zType, sType}
share|improve this answer
@Leonid z[n_]:= – nilo de roock Jun 8 '11 at 8:03
The idea is: l = {1, 1, 1, 2, 4, 8, 3, 9, 27} S[n_] := Module[{}, l[[n]] = l[[n]] + 1; l] Z[n_] := Module[{}, l[[n]] = 0; l] Then I want to store {Z[1],S[1]} in a list, unevaluated. A function exec[n_]:='Execute function at position n in list'. I still don't get this to work using Hold. – nilo de roock Jun 8 '11 at 8:09
@ndroock1 - Please see my edit. If possible, I'd rethink the design, to build from immutable lists. – Leonid Shifrin Jun 8 '11 at 8:41
Edit 3 does it. Thank you very much. ( I will use it to emulate Cutland's URM ( unlimited register machine ), a concept similar to the Turing Machine. ) – nilo de roock Jun 8 '11 at 10:43
@ndroock1 Well, great then! Thanks also for the accept. – Leonid Shifrin Jun 8 '11 at 10:44

The first thing that spings to mind is to not use List but rather use something like this:

 SetAttributes[lst, HoldAll];
 heldL=lst[Plus[1, 1], Times[2, 3]]

There will surely be lots of more erudite suggestions though!

share|improve this answer

You can also use Hold on every element that you want held:

a = {Hold[2 + 2], Hold[2*3]}

You can use HoldForm on either the elements or the list, if you want the appearance of the list without Hold visible:

b = {HoldForm[2 + 2], HoldForm[2*3]}

c = HoldForm@{2 + 2, 2*3}
   {2 + 2, 2 * 3}

And you can recover the evaluated form with ReleaseHold:

a // ReleaseHold
b // ReleaseHold
c // ReleaseHold

Out[8]= {4, 6}

Out[9]= {4, 6}

Out[10]= {4, 6}

The form Hold[2+2, 2*3] or that of a and b above are good because you can easily add terms with e.g. Append. For b type is it logically:

Append[b, HoldForm[8/4]]

For Hold[2+2, 2*3]:

Hold[2+2, 2*3] ~Join~ Hold[8/4]
share|improve this answer

Another way:

lh = Function[u, Hold@u, {HoldAll, Listable}];
k = lh@{2 + 2, Sin[Pi]}
->{Hold[2 + 2], Hold[Sin[\[Pi]]]}
-> 4
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