This question pertains to creating "wide" tables similar to tables you could create using dcast from reshape2. I know this has been discussed many times before, but my question pertains to how to make the process more efficient. I have provided several examples below which might make the question seem lengthy, but most of it is just test code for benchmarking

Starting with a simple example,

> z <- data.table(col1=c(1,1,2,3,4), col2=c(10,10,20,20,30), 
                  col3=c(5,2,2.3,2.4,100), col4=c("a","a","b","c","a"))

> z
     col1 col2  col3 col4
1:    1   10   5.0    a      # col1 = 1, col2 = 10
2:    1   10   2.0    a      # col1 = 1, col2 = 10
3:    2   20   2.3    b
4:    3   20   2.4    c
5:    4   30 100.0    a

We need to create a "wide" table that will have the values of the col4 column as column names and the value of the sum(col3) for each combination of col1 and col2.

> ulist = unique(z$col4) # These will be the additional column names

# Create long table with sum
> z2 <- z[,list(sumcol=sum(col3)), by='col1,col2,col4']

# Pivot the long table
> z2 <- z2[,as.list((sumcol[match(ulist,col4)])), by=c("col1","col2")]

# Add column names
> setnames(z2[],c("col1","col2",ulist))

> z2
   col1 col2   a   b   c
1:    1   10   7  NA  NA  # a = 5.0 + 2.0 = 7 corresponding to col1=1, col2=10
2:    2   20  NA 2.3  NA
3:    3   20  NA  NA 2.4
4:    4   30 100  NA  NA

The issue I have is that while the above method is fine for smaller tables, it's virtually impossible to run them (unless you are fine with waiting x hours maybe) on very large tables.

This, I believe is likely related to the fact that the pivoted / wide table is of a much larger size than the original tables since each row in the wide table has n columns corresponding to the unique values of the pivot column no matter whether there is any value that corresponds to that cell (these are the NA values above). The size of the new table is therefore often 2x+ that of the original "long" table.

My original table has ~ 500 million rows, about 20 unique values. I have attempted to run the above using only 5 million rows and it takes forever in R (too long to wait for it to complete).

For benchmarking purposes, the example (using 5 million rows) - completes in about 1 minute using production rdbms systems running multithreaded. It completes in about 8 "seconds" using single core using KDB+/Q (http://www.kx.com). It might not be a fair comparison, but gives a sense that it is possible to do these operations much faster using alternative means. KDB+ doesn't have sparse rows, so it is allocating memory for all the cells and still much faster than anything else I have tried.

What I need however, is an R solution :) and so far, I haven't found an efficient way to perform similar operations.

If you have had experience and could reflect upon any alternative / more optimal solution, I'd be interested in knowing the same. A sample code is provided below. You can vary the value for n to simulate the results. The unique values for the pivot column (column c3) have been fixed at 25.

n = 100 # Increase this to benchmark

z <- data.table(c1=sample(1:10000,n,replace=T),

c3.unique <- 1:25

z <- z[,list(sumprice=sum(price)), by='c1,c2,c3'][,as.list((sumprice[match(c3.unique,c3)])), by='c1,c2']
setnames(z[], c("c1","c2",c3.unique))


  • Raj.
  • 1
    Can you include your KDB code you're benchmarking? Btw, @Arun is already working on a fast dcast in C. – Matt Dowle Sep 14 '13 at 14:55
  • 1
    @xbsd, yes as @MatthewDowle mentioned, I'm trying to implement dcast in C. I'll update the post with benchmarks once it's done. – Arun Sep 14 '13 at 18:12
  • 2
    @Arun -- File: t.csv.bz2 Code: R and Q Code R Time: 27.759 seconds, Q Time: 11.543 seconds. Should add -- these operations can be parallelized in Q using different methods. I have tried to do similar operations using R, generally with packages parallel, multicore, doMC, etc … and have also tried chunking data to sequentially process segments of the dataset in a map reduce fashion. These have almost "always" resulted in seg faults, unfortunately. The dataset sizes in these tests were ~ in the order of 35 GB+. – xbsd Sep 15 '13 at 18:04
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    @xbsd, Okay, I just benchmarked on the current C version of cast... Good news! Your data runs in 12 seconds on the C-version against your data.table code which runs in 40 seconds on my (slow) laptop. So, basically it seems like a 3.3x speedup (roughly). Hopefully, that'll turn out faster than the KDB approach. And hopefully, I'll be able to optimise it further... I'll try to wrap things up soon and commit and then post/update an answer. – Arun Sep 15 '13 at 18:36
  • 1
    @Arun ... wow, what can I say ! :) You're going to make a lot of people really happy (and the guys at Revolution R not as much ...) with that kind of performance. Let me know once you have it in svn. Would like to try it out against the original datasets. – xbsd Sep 15 '13 at 18:40

For n=1e6 the following takes about 10 seconds with plain dcast and about 4 seconds with dcast.data.table:


dcast(z[, sum(price), by = list(c1, c2, c3)], c1 + c2 ~ c3)

# or with 1.8.11
dcast.data.table(z, c1 + c2 ~ c3, fun = sum)
  • @Arun I don't understand your point 1 - why would it take any time to "convert" a data.table to a data.frame? – eddi Dec 4 '13 at 23:33
  • re point 2 - you're right, it's about 20% faster (so I edited that version instead) – eddi Dec 4 '13 at 23:36

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