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How to get all definitions for a symbol associated with other symbols by TagSet, TagSetDelayed, UpSet or UpSetDelayed?

For example, if one has defined

area[square] ^= s^2
area[cube] ^= 6*s^2

how to obtain these definitions, not knowing the names square, cube but knowing only the name area?


I just have found that UpValues does not return definitions for MakeBoxes and N since they are stored in FormatValues and NValues correspondingly:

In[1]:= rotate /: MakeBoxes[expr_rotate, "StandardForm"] := x
UpValues[rotate]
FormatValues[rotate]

Out[2]= {}

Out[3]= {HoldPattern[MakeBoxes[expr_rotate, "StandardForm"]] :> x}

In[4]:= pi /: N[pi] = 3.14
UpValues[pi]
NValues[pi]

Out[4]= 3.14

Out[5]= {}

Out[6]= {HoldPattern[N[pi, {MachinePrecision, MachinePrecision}]] :> 
  3.14}

In this way instead of UpValues we should use a combination of UpValues, FormatValues and NValues.


When trying to output a list of FormatValues one can face problems with MakeBoxes since FormatValues gives definitions for MakeBoxes those are further processed by MakeBoxes on creating the output for the FrontEnd. This problem can be solved by switching FormatType temporarily to OutputForm or by converting these definitions to strings.

In[1]:= SetOptions[$Output,FormatType->OutputForm];
FormatValues[DialogNotebook]
Out[2]= {HoldPattern[MakeBoxes[BoxForm`apat$:HoldPattern[DialogNotebook[___]], BoxForm`fpat$_]] :> 

   BoxForm`BoxFormAutoLoad[MakeBoxes, BoxForm`apat$, BoxForm`fpat$, Typeset`CellNotebook`, 

    {{CellGroup, _}, {DocumentNotebook, _}, {PaletteNotebook, _}, {DialogNotebook, _}, {ExpressionCell, _}, {Text, _}, 

     {TextCell, _}, {Cell, HoldPattern[MakeExpression[_Cell, _]]}, {Notebook, HoldPattern[MakeExpression[_Notebook, _]]}}]}

In[1]:= ToString@FormatValues[DialogNotebook]
Out[1]= {HoldPattern[MakeBoxes[BoxForm`apat$:HoldPattern[DialogNotebook[___]], BoxForm`fpat$_]] :> BoxForm`BoxFormAutoLoad[MakeBoxes, BoxForm`apat$, BoxForm`fpat$, Typeset`CellNotebook`, {{CellGroup, _}, {DocumentNotebook, _}, {PaletteNotebook, _}, {DialogNotebook, _}, {ExpressionCell, _}, {Text, _}, {TextCell, _}, {Cell, HoldPattern[MakeExpression[_Cell, _]]}, {Notebook, HoldPattern[MakeExpression[_Notebook, _]]}}]}
share|improve this question
    
Is your recent edit a request for an updated answer, or posted only to help others finding this question? –  Mr.Wizard May 1 '11 at 7:37
    
@Mr.Wizard I think it would be better to make an updated answer with the complete solution. –  Alexey Popkov May 1 '11 at 7:42
    
@Mr.Wizard The problem is really tricky. See edited part of my question. Now I understand why the developers moved all definitions for MakeBoxes to scarcely documented FormatValues. :) –  Alexey Popkov May 1 '11 at 8:40
    
Nuts. Thought I had it. Out of time for now, but I'll try again later. –  Mr.Wizard May 1 '11 at 8:46
    
@Mr.Wizard From the other side, there are not so many cases when Mathematica generates error messages during printing/outputting of FormatValues: names = Names["*"]; If[(val = ToExpression[#, InputForm, FormatValues]) =!= {}, Quiet@Check[ToBoxes[val], Print["!!!!!", #]]] & /@ names;. –  Alexey Popkov May 1 '11 at 9:35

3 Answers 3

up vote 4 down vote accepted

Attempting to address Alexey's concerns with Howard's answer, I came up with this:

Cases[
   UpValues @@@ MakeExpression /@ Names["Global`*"],
   HoldPattern[_@_area :> _],
   {2}
]

In response to your updated requirements, here is the advanced version:

SetAttributes[otherValues, HoldFirst]

otherValues[sym_] :=
  With[{names = MakeExpression /@ Names["Global`*"]},
    Join[
      Cases[UpValues @@@ names, HoldPattern[_@_sym :> _], {2}],
      Cases[NValues @@@ names, HoldPattern[_@N[sym, ___] :> _], {2}],
      Select[Join @@ FormatValues @@@ names, ! FreeQ[#, HoldPattern@sym] &]
    ]
  ]
share|improve this answer
1  
I think this solution is quite elegant! –  Alexey Popkov May 1 '11 at 3:12
    
Both your and @Leonid's solutions evaluate area. One can avoid this by wrapping it with HoldPattern: HoldPattern[area][_]. After this the code becomes almost safe. The only exotic case when it becomes dangerous is when one define area[surprise] ^:= Unevaluated[Evaluate[Print["Surprise! :)"]]]. In this very special case both versions evaluate the definition. But I think we should not commonly care about such hacker's exotic. –  Alexey Popkov May 1 '11 at 3:30
    
@Alexey, when would area have a value? If I assign area[square] ^= s^2 and then area = 5, and afterward evaluate area[square] I get 5[square]. –  Mr.Wizard May 1 '11 at 3:34
1  
@Alexey, using your example, if evaluate this in a fresh kernel, I do not get the "!" printed: area[square] ^= s^2; area := (Print["!"]; area =.; area) Cases[UpValues @@@ MakeExpression /@ Names["Global`*"], HoldPattern[_@_area :> _], {2}] –  Mr.Wizard May 1 '11 at 3:48
1  
@Mr.Wizard Interesting! "!" is printed as the result of evaluation of area[square] ^= s^2;, not your code! area is evaluated although UpSet has attribute HoldFirst: area := (Print["!"]; area =.; area); Trace[area[square] ^:= s^2]. But why??? –  Alexey Popkov May 1 '11 at 4:12

The following version

Cases[
  Flatten@Map[
    ToExpression[#, InputForm, Function[sym, UpValues[sym], HoldAllComplete]] &,
    Names["Global`*"]],
  Verbatim[RuleDelayed][Verbatim[HoldPattern][_area], _]
]

will not evaluate symbols as well. It is similar in spirit to @Mr. Wizard's answer, but I prefer ToExpression to MakeExpression since the latter is tied to the FrontEnd and boxes ( at least conceptually) , while the former is a general-purpose command (although it is mentioned in the documentation that it will use rules for MakeExpression).

If you have an access to the full Mathematica session from the start, another solution would be to overload TagSet, TagSetDelayed, UpSet and UpSetDelayed so that they will record the symbol dependencies in some kind of hash. Here is an example for UpSet:

Unprotect[UpSet];
Module[{tried, upsetHash},
  upsetHash[_] = {};
  getUpsetHash[] := upsetHash;
  UpSet[f_[args___], rhs_] :=
    Block[{tried = True},
       AppendTo[upsetHash[f], 
          Select[HoldComplete[args], 
            Function[Null, Head[Unevaluated[#]] === Symbol, HoldAll]]];
       UpSet[f[args], rhs]] /; ! TrueQ[tried]
];
Protect[UpSet];

All assignments made with UpSet after this redefinition will be recorded. For example, after executing your example above, you can call

In[6]:= getUpsetHash[][area]

Out[6]= {HoldComplete[square], HoldComplete[cube]} 

This way you get your information much faster, especially if you want to make such inquiries frequently, and/or you have lots of packages loaded. You can also automate the process further, to switch to the standard definitions for assignments once you load the functionality of interest.

share|improve this answer
    
I don't understand your objection to MakeExpression, but I have learned to listen when you speak. Will you explain further? Also, why do you need Function[sym, UpValues[sym], HoldAllComplete]? –  Mr.Wizard Apr 30 '11 at 22:09
    
@Mr.Wizard The function is needed for wrapping the output of ToExpression without evaluating it. MakeExpression wraps its output in HoldComplete before evaluating it by default. BTW I think in this particular case HoldFirst attribute is quite sufficient. –  Alexey Popkov May 1 '11 at 3:04
1  
ToExpression just calls MakeExpression when the second argument is StandardForm or TraditionalForm: try On[MakeExpression]; ToExpression["1+1", StandardForm]. But for InputForm it does not since MakeExpression does not support InputForm as the second argument. For comparison, ToBoxes just always calls MakeBoxes. –  Alexey Popkov May 1 '11 at 3:10
1  
@Mr. Wizard This was not really an objection - I just mentioned that I prefer ToExpression. As for UpValues, you are probably right too, HoldAllComplete is an overkill (I just got used to this pattern in ToExpression for functions which don't hold their args - those would also need an Unevaluated inside the body) . My main point was the second part of my answer, for the first one I just displayed an alternative which seems more natural to me (but this is of course very subjective). So, in this particular case, you won't lose much by not listening to me :) –  Leonid Shifrin May 1 '11 at 14:39
1  
@Alexey It is an undocumented form, but I am sure you can rely on it. It is very unlikely that the support for it will be discontinued. Also, it is the only way (to my knowledge) to introduce a pure function with arbitrary number of variables which would be held (or carry other attributes). See this post of mine stackoverflow.com/questions/4867076/… for an example, and at the end of it I refer to the place where this form is mentioned. –  Leonid Shifrin May 1 '11 at 14:44

You can try an exhaustive search via

Select[UpValues /@ Cases[ToExpression[Names["*"]], _Symbol], ! FreeQ[#, area] &]

which in your example will yield

{{HoldPattern[area[cube]] :> 6 s^2}, {HoldPattern[area[square]] :> s^2}}
share|improve this answer
1  
This code is dangerous since each of the symbols in the $ContextPath is evaluated! There should be a way to do this without evaluation of symbols. The other problem is that this code will return also definitions having square on the r.h.s. or on the l.h.s but not in position of Head of the subexpression inside HoldPattern. But thank you anyway. –  Alexey Popkov Apr 30 '11 at 9:06

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