# Conditionnal Data Manipulation in Mathematica

I am trying to prepare the best tools for efficient Data Analysis in Mathematica. I have a approximately 300 Columns & 100 000 Rows.

What would be the best tricks to :

"Remove", "Extract" or simply "Consider" parts of the data structure, for plotting for e.g.

One of the trickiest examples I could think of is :

Given a data structure,

Extract Column 1 to 3, 6 to 9 as well as the last One for every lines where the value in Column 2 is equal to x and the value in column 8 is different than y

I also welcome any general advice on data manipulation.

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Oh boy! I might get stoned here, but the best advice I can give you to do all of the above operations on numerical data structures is to use MATLAB :D –  r.m. May 25 '11 at 20:19
And I am so glad I walked away from Matlab ! Mathematica`s interface is heaven to me ;) –  500 May 25 '11 at 20:23
I didn't really mean to suggest that you switch to MATLAB when your question is in mma :) –  r.m. May 25 '11 at 20:35
@yoda We really need a sarcasm symbol, just like the question mark and the quote symbol. I really thought you meant it seriously. –  Sjoerd C. de Vries May 25 '11 at 20:49
@Sjoerd: I usually reserve ‽ for when you ask me how to index a matrix, but instead I give you a roast rabbit. –  r.m. May 25 '11 at 20:54

For a generic manipulation of data in a table with named columns, I refer you to this solution of mine, for a similar question. For any particular case, it might be easier to write a function for `Select` manually. However, for many columns, and many different queries, chances to mess up indexes are high. Here is the modified solution from the mentioned post, which provides a more friendly syntax:

``````Clear[getIds];
getIds[table : {colNames_List, rows__List}] := {rows}[[All, 1]];

ClearAll[select, where];
SetAttributes[where, HoldAll];
select[cnames_List, from[table : {colNames_List, rows__List}], where[condition_]] :=
With[{selF = Apply[Function, Hold[condition] /. colRules]},
Select[{rows}, selF @@ # &][[All, cnames /. indexRules]]]];
``````

What happens here is that the function used in `Select` gets generated automatically from your specifications. For example (using @Yoda's example):

``````rows = Array[#1 #2 &, {5, 15}];
``````

We need to define the column names (must be strings or symbols without values):

``````In[425]:=
colnames = "c" <> ToString[#] & /@ Range[15]

Out[425]= {"c1", "c2", "c3", "c4", "c5", "c6", "c7", "c8", "c9", "c10", "c11", "c12",
"c13", "c14", "c15"}
``````

(in practice, usually names are more descriptive, of course). Here is the table then:

``````table = Prepend[rows, colnames];
``````

Here is the select statement you need (I picked `x = 4` and `y=2`):

``````select[{"c1", "c2", "c3", "c6", "c7", "c8", "c9", "c15"}, from[table],
where["c2" == 4 && "c8" != 2]]

{{2, 4, 6, 12, 14, 16, 18, 30}}
``````

Now, for a single query, this may look like a complicated way to do this. But you can do many different queries, such as

``````In[468]:= select[{"c1", "c2", "c3"}, from[table], where[EvenQ["c2"] && "c10" > 10]]

Out[468]= {{2, 4, 6}, {3, 6, 9}, {4, 8, 12}, {5, 10, 15}}
``````

and similar.

Of course, if there are specific correlations in your data, you might find a particular special-purpose algorithm which will be faster. The function above can be extended in many ways, to simplify common queries (include "all", etc), or to auto-compile the generated pure function (if possible).

EDIT

On a philosophical note, I am sure that many Mathematica users (myself included) found themselves from time to time writing similar code again and again. The fact that Mathematica has a concise syntax makes it often very easy to write for any particular case. However, as long as one works in some specific domain (like, for example, data manipulations in a table), the cost of repeating yourself will be high for many operations. What my example illustrates in a very simple setting is a one possible way out - create a Domain-Specific Language (DSL). For that, one generally needs to define a syntax/grammar for it, and write a compiler from it to Mathematica (to generate Mathematica code automatically). Now, the example above is a very primitive realization of this idea, but my point is that Mathematica is generally very well suited for DSL creation, which I think is a very powerful technique.

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Thank You very much Leonid ! –  500 May 25 '11 at 21:33
@Leonid, your solution seems to handle strings columns header. In general, would you recommend to keep the header made out of strings in data-structure ? Also I must admit, I am struggling a bit to use your code, but I am still working through it to try figure out what I am doing wrong. If I fail, I will try to formulate the problem in the best way to ask for your help. Thanks again ! –  500 May 30 '11 at 15:00
@500 In the particular case of table data manipulation, I'd suggest to keep the headers simply because they are more descriptive and you have fewer chances of getting the column indexes wrong - and my solution is supposed to automate the translation to index numbers. As to my code, let me know which parts may cause the confusion, and I will post better explanations. One thing that may be instructive is to look at the generated pure function for `Select` - you can do it for example with the debug utility `ShowIt` that I described in the recent question on debugging. –  Leonid Shifrin May 30 '11 at 15:05
@500 Another good reason to keep the headers is that they provide a level of indirection and make your solution more robust: should you wish to change the order of the columns in a table at some later time (for example by inserting some new column type into your table, or deleting an existing one, or simply exchanging columns), and the queries made with header names will remain valid, while all your functions with explicit indexes are likely to become garbage. The true SQL queries operate with column names rather than numeric indexes for the same reason. –  Leonid Shifrin May 30 '11 at 15:10
@Leonid, would you mind throwing an eye on this Notebook, where you will see what happen as I try to use your code. I think I am really missing something stupid, please pardon me if it is the case. Thank You again for your help : laeh500.com/LAEH/For_Leonid.html –  500 May 30 '11 at 19:54
``````data = RandomInteger[{1, 20}, {40, 20}]

x = 5;
y = 8;
Select[data, (#[[2]] == x && #[[8]] != y &)][[All, {1, 2, 3, 6, 7, 8, 9, -1}]]

==> {{5, 5, 1, 4, 18, 6, 3, 5}, {10, 5, 15, 3, 15, 14, 2, 5}, {18, 5, 6, 7, 7, 19, 14, 6}}
``````

Some useful commands to get pieces of matrices and list are `Span` (;;), `Drop`, `Take`, `Select`, `Cases` and more. See tutorial/GettingAndSettingPiecesOfMatrices and guide/PartsOfMatrices,

`Part` ([[...]]) in combination with `;;` can be quite powerful. a[[All, 1;;-1;;2]], for instance, means take all rows and all odd columns (-1 having the usual meaning of counting from the end).

`Select` can be used to pick elements from a list (and remember a matrix is a list of lists), based on a logical function. It's twin brother is `Cases` which does selection based on a pattern. The function I used here is a 'pure' function, where # refers to the argument on which this function is applied (the elements of the list in this case). Since the elements are lists themselves (the rows of the matrix) I can refer to the columns by using the `Part` ([[..]]) function.

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@Sjoerd: I think the two points are disjoint.. I think @500 meant 1. How to pick columns out and 2. find elements in 2nd column & 8th column.. yada yada. In anycase, it's a simple modification from your solution above. –  r.m. May 25 '11 at 20:45
@yoda I didn't think so. The two requirements read as a single sentence and I interpreted them as two requirements that need to be fulfilled together. Why did you remove your answer? The Range part was something I didn't have and might come in handy when you want to select more than the few columns necessary here. –  Sjoerd C. de Vries May 25 '11 at 20:48
@Sjoerd: You're right; I guess I misread the requirements. –  r.m. May 25 '11 at 20:49
Single Sentence it was, my apologies for not being clear. –  500 May 25 '11 at 20:49
@500 @yoda 'Single Sentence it was' that's yoda talk ;-) –  Sjoerd C. de Vries May 25 '11 at 20:54

To pull out columns (or rows) you can do it by part indexing

``````data = Array[#1 #2 &, {5, 15}];
data[[All, Flatten@{Range@3, Range @@ {6, 9}, -1}]]

MatrixForm@%
``````

The last line is just to view it pretty.

As Sjoerd mentioned in his comment (and in the explanation in his answer), indexing a single range can be easily done with the `Span` (`;;`) command. If you are joining multiple disjoint ranges, using `Flatten` to combine the separate ranges created with `Range` is easier than entering them by hand.

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Perhaps it should be remarked that Range is useful here because we have several disjunct ranges that you combined using Flatten. Otherwise Span (;;) could have been used. –  Sjoerd C. de Vries May 25 '11 at 21:17
@Sjoerd: Yes, that is correct. Will edit to add that. –  r.m. May 25 '11 at 21:19

Extract Column 1 to 3, 6 to 9 as well as the last One for every lines where the value in Column 2 is equal to x and the value in column 8 is different than y

as meaning that we want:

• elements 1-3 and 6-9 from each row

AND

• the last element from rows wherein `[[2]] == x && [[8]] != y`.

This is what I hacked together:

``````a = RandomInteger[5, {20, 10}];          (*define the array*)
x = 4; y = 0;                            (*define the test values*)

Join @@ Range @@@ {1 ;; 3, 6 ;; 9};      (*define the column ranges*)

#2 == x && #8 != y & @@@ a;              (*test the rows*)

Append[%%, #] & /@ % /. {True -> -1, False :> Sequence[]};  (*complete the ranges according to the test*)

MapThread[Part, {a, %}] // TableForm     (*extract and display*)
``````
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