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I have two dataframes; one is 48 rows long and looks like this:

name = Z31

     Est.Date   Site    Cultivar   Planting
1   24/07/2011  Birchip Axe           1
2   08/08/2011  Birchip Bolac         1
3   24/07/2011  Birchip Derrimut      1
4   12/08/2011  Birchip Eaglehawk     1
5   29/07/2011  Birchip Gregory       1
6   29/07/2011  Birchip Lincoln       1
7   23/07/2011  Birchip Mace          1
8   29/07/2011  Birchip Scout         1
9   17/09/2011  Birchip Axe           2
10  19/09/2011  Birchip Bolac         2

The other is > 23000 rows and contains output from a simulator. It looks like this:

name = pred

    Date        maxt    mint    Cultivar    Site    Planting    tt  cum_tt
1   5/05/2011   18       6.5    Axe        Birchip  1        12.25  0
2   6/05/2011   17.5     2.5    Axe        Birchip  1        10     0
3   7/05/2011   18       2.5    Axe        Birchip  1        10.25  0
4   8/05/2011   19.5       2    Axe        Birchip  1        10.75  0
5   9/05/2011   17       4.5    Axe        Birchip  1        10.75  0
6   10/05/2011  15.5    -0.5    Axe        Birchip  1        7.5    0
7   11/05/2011  14       5.5    Axe        Birchip  1        9.75   0
8   12/05/2011  19         8    Axe        Birchip  1        13.5   0
9   13/05/2011  18.5     7.5    Axe        Birchip  1        13     0
10  14/05/2011  16       3.5    Axe        Birchip  1        9.75   0

What I want to do is have the cum_tt column start to add the tt column of the current row to the cum_tt of the previous row (cumulative addition) ONLY if the date in the pred DF is equal to or greater than the Z31 est.Date. I have written the following for loop:

for (i in 1:nrow(Z31)){
  for (j in 1:nrow(pred)){
    if (Z31[i,]$Site == pred[j,]$Site & Z31[i,]$Cultivar == pred[j,]$Cultivar & Z31[i,]$Planting == pred[j,]$Planting &
        pred[j,]$Date >= Z31[i,]$Est.Date)
    {
      pred[j,]$cum_tt <- pred[j,]$tt + pred[j-1,]$cum_tt
    }
  }
}

This works but it is so slow it will take about an hour to run the entire set. I know loops are not R's strong point so can anyone assist me with vectorising this operation?

Thanks in advance.

UPDATE

Here's the output from dput(Z31):

structure(list(Est.Date = structure(c(15179, 15194, 15179, 15198, 15184, 15184, 15178, 15184, 15234, 15236, 15230, 15238, 15229, 15236, 15229, 15231, 15155, 15170, 15160, 15168, 15165, 15159, 15170, 15170, 15191, 15205, 15198, 15203, 15202, 15195, 15203, 15206, 15193, 15193, 15195, 15200, 15193, 15205, 15200, 15205, 15226, 15245, 15231, 15259, 15241, 15241, 15241, 15241), class = "Date"), Site = structure(c(1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L, 3L), .Label = c("Birchip", "Gatton", "Tarlee"), class = "factor"), Cultivar = structure(c(1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L, 1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L, 1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L, 1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L, 1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L, 1L, 2L, 3L, 4L, 5L, 6L, 7L, 8L), .Label = c("Axe", "Bolac", "Derrimut", "Eaglehawk", "Gregory", "Lincoln", "Mace", "Scout"), class = "factor"), Planting = c(1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 2L, 2L, 2L, 2L, 2L, 2L, 2L, 2L)), .Names = c("Est.Date", "Site", "Cultivar", "Planting"), row.names = c(NA, -48L), class = "data.frame")

Here's pred. Note there are some extra colums here. I've just included the relevant ones above for ease of reading.

structure(list(Date = structure(c(15099, 15100, 15101, 15102, 
15103, 15104, 15105, 15106, 15107, 15108, 15109, 15110, 15111, 
15112, 15113, 15114, 15115, 15116, 15117, 15118), class = "Date"), 
    flowering_das = c(0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L, 
    0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L, 0L), Zadok = c(9, 9, 
    9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 11, 11.032, 11.085, 
    11.157), stagename = structure(c(8L, 8L, 8L, 8L, 8L, 8L, 
    8L, 8L, 9L, 6L, 6L, 6L, 6L, 6L, 6L, 6L, 1L, 3L, 3L, 3L), .Label = c("emergence", 
    "end_grain_fill", "end_of_juvenil", "floral_initiat", "flowering", 
    "germination", "maturity", "out", "sowing", "start_grain_fi"
    ), class = "factor"), node_no = c(0, 0, 0, 0, 0, 0, 0, 0, 
    0, 0, 0, 0, 0, 0, 0, 0, 2, 2.032, 2.085, 2.157), maxt = c(18, 
    17.5, 18, 19.5, 17, 15.5, 14, 19, 18.5, 16, 16, 15, 16.5, 
    16.5, 20.5, 23, 25.5, 16.5, 16.5, 15), mint = c(6.5, 2.5, 
    2.5, 2, 4.5, -0.5, 5.5, 8, 7.5, 3.5, 6, 1, 5.5, 2, 7, 7, 
    9, 13.5, 11.5, 8.5), Cultivar = c("Axe", "Axe", "Axe", "Axe", 
    "Axe", "Axe", "Axe", "Axe", "Axe", "Axe", "Axe", "Axe", "Axe", 
    "Axe", "Axe", "Axe", "Axe", "Axe", "Axe", "Axe"), Site = c("Birchip", 
    "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", 
    "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", 
    "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", "Birchip", 
    "Birchip"), Planting = c("1", "1", "1", "1", "1", "1", "1", 
    "1", "1", "1", "1", "1", "1", "1", "1", "1", "1", "1", "1", 
    "1"), `NA` = c("Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", 
    "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out", "Birchip TOS1 Axe.out"
    ), tt = c(12.25, 10, 10.25, 10.75, 10.75, 7.5, 9.75, 13.5, 
    13, 9.75, 11, 8, 11, 9.25, 13.75, 15, 17.25, 15, 14, 11.75
    ), cum_tt = c(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 
    0, 0, 0, 0, 0)), .Names = c("Date", "flowering_das", "Zadok", 
"stagename", "node_no", "maxt", "mint", "Cultivar", "Site", "Planting", 
NA, "tt", "cum_tt"), row.names = c(NA, 20L), class = "data.frame")

UPDATE

Thanks everyone for your help. I'm still new to the vector way of doing things and I wasn't able to implement some of the more complex solutions in time. I've got some timing below for the way Subs suggested. It's fast enough now to do what I need. These number are in seconds for one iteration of Z over P.

my way: 59.77

Subs: 14.62

Subs using numeric date: 11.12

share|improve this question
    
Can you please update your question with the results of dput(Z31) and dput(pred)? I can't get your code to run as is after reading the text in... –  Chase Jun 6 '12 at 2:37
1  
FYI this also looks like data.table() and roll = TRUE would be faster. –  Chase Jun 6 '12 at 2:43
    
As above with regards to dput output. Had a look at data.table... that might be something to explore after lunch :) –  Justin Jun 6 '12 at 3:12
    
dput(head(pred,20)) should do the trick :) –  Chase Jun 6 '12 at 3:14
    
bonk of course... Here you go :) Off to eat now. –  Justin Jun 6 '12 at 3:27

3 Answers 3

up vote 5 down vote accepted

Sure that we can do this in a few seconds... my first answer on here so go gentle!

## first make sure we have dates in a suitable format for comparison
## by using strptime, creating the columns estdate_tidy and date_tidy
## in Z31 and pred respectively

Z31$estdate_tidy = strptime(as.character(Z31$Est.Date), "%d/%m/%Y")
pred$date_tidy = strptime(as.character(pred$Date), "%d/%m/%Y")

## now map the estdate_tidy column over to pred using the match command -
## Z31_m and pred_m are dummy variables that hopefully make this clear

Z31_m = paste(Z31$Site, Z31$Cultivar, Z31$Planting)
pred_m = paste(pred$Site, pred$Cultivar, pred$Planting)
pred$estdate_tidy = Z31$estdate_tidy[match(pred_m, Z31_m)]

## then define a ttfilter column that copies tt, except for being 0 when
## estdate_tidy is after date_tidy (think this is what you described)

pred$ttfilter = ifelse(pred$date_tidy >= pred$estdate_tidy, pred$tt, 0)

## finally use cumsum function to sum this new column up (looks like you
## wanted the answer in cum_tt so I've put it there)

pred$cum_tt = cumsum(pred$ttfilter)

Hope this helps :)

UPDATE (7 June):

The vectorised code to tackle the new specification - i.e. that the cumsum should be done separately for each set of conditions (Site/Cultivar/Planting) - is shown below:

Z31$Lookup=with(Z31,paste(Site,Cultivar,Planting,sep="~"))
Z31$LookupNum=match(Z31$Lookup,unique(Z31$Lookup))
pred$Lookup=with(pred,paste(Site,Cultivar,Planting,sep="~"))
pred$LookupNum=match(pred$Lookup,unique(pred$Lookup))

pred$Est.Date = Z31$Est.Date[match(pred$Lookup,Z31$Lookup)]
pred$ttValid = (pred$Date>=pred$Est.Date)
pred$ttFiltered = ifelse(pred$ttValid, pred$tt, 0)

### now fill in cumsum of ttFiltered separately for each LookupNum
pred$cum_tt_Z31 = as.vector(unlist(tapply(pred$ttFiltered,
                                          pred$LookupNum,cumsum)))

Runtime is 0.16 seconds on my machine, and the final pred$cum_tt_Z31 column matches exactly with the answer from the non-vectorised code :)

For completeness, it's worth noting that the final complicated tapply line above can be replaced by the following simpler approach with a short loop over the 48 possible cases:

pred$cum_tt_Z31 = rep(NA, nrow(pred))
for (lookup in unique(pred$Lookup)) {
    subs = which(pred$Lookup==lookup)
    pred$cum_tt_Z31[subs] = cumsum(pred$ttFiltered[subs])
}

The runtime only increases slightly to 0.25 seconds or so, because the loop here is very small and the work done inside the loop is vectorised.

Think we've cracked it! :)

Some quick observations on vectorisation (8 June):

The process of vectorising the steps of the process brought runtime down from close to an hour to 0.16 seconds in total. Even allowing for different machine speeds, this is a speedup by at least a factor of 10,000, which dwarfs the factors of 2-5 one might get from making minor tweaks but still retaining a loop structure.

The first key observation to make: in the solution, every line creates - without looping - an entire new vector with the same length as the columns in Z31 or pred. For neatness, I often find it useful to create these new vectors as new data frame columns, but obviously this is not strictly necessary.

Second observation: the required Est.Date column gets transferred correctly from Z31 to pred using a "paste'n'match" strategy. There are alternative approaches to this sort of task (e.g. using merge), but I take this route as it is completely failsafe and guarantees to preserve the order in pred (which is crucial). Essentially the paste operation just lets you match up several fields at once, because if the pasted strings match then all their constituent parts match. I use ~ as a separator (provided I know that symbol won't appear in any of the fields) to avoid the paste operation causing any ambiguity. If you use a space separator, then pasting together something like ("A B", "C", "D") would give the same result as pasting ("A", "B C", "D") - and we want to avoid any headaches!

Third observation: it's easy to vectorise logical operations such as seeing if one vector exceeds another (see pred$ttValid), or choosing one value or another based on the value of a vector (see pred$ttFiltered). In the current situation, these could be combined into one line, but I broke things down a little more as a demonstration.

Fourth observation: the final line that creates pred$cum_tt_Z31 essentially just does a cumsum operation across the rows corresponding to each separate value of pred$LookupNum, using tapply, which allows you to apply the same function over different groups of rows (here, we're grouping by pred$LookupNum). The definition of pred$LookupNum helps enormously here - it's a numeric index with a block of 1s, followed by a block of 2s, and so on. This means the final list of cumsum vectors that comes out of the tapply can simply be unlisted and put into a vector and is automatically in the right order. If you do a tapply and split by groups that aren't ordered like this, you normally need a couple of additional lines of code to match things back up again correctly (though it isn't tricky).

Final observation: if the final tapply is too scary, it's worth highlighting that a quick loop over a small number of cases (48 say) isn't always disastrous if the work within the loop is nicely vectorised. The "alternative method" at the end of the UPDATE section shows that the cumsum-on-groups step can also be achieved by pre-preparing an answer column (initially all NAs) and then going through the 48 subsets one by one and filling in the each block with the appropriate cumsum. As noted in the text, though, this single step is roughly half the speed as the clever tapply approach, and if more subsets were needed this would be considerably slower.

If anyone has any follow up questions on this kind of task, please don't hesitate to give me a shout.

share|improve this answer
    
Looks promising. match strategy with pasted vectors looks to be O(n) in time versus the O(n^2) loop strategy using separate accesses to dataframes. –  BondedDust Jun 6 '12 at 3:25
    
Looks like Est.Date is already in date format (original post didn't make it clear), so in my solution above Z31$estdate_tidy can be replaced by Z31$Est.Date (similarly for pred$date_tidy and pred$Date, if pred$Date is already in date rather than character format) :) –  Tim P Jun 6 '12 at 3:29
    
Thanks DWin - yes, expect the match strategy is optimal here. Should realise at least a 1000x speedup overall. –  Tim P Jun 6 '12 at 3:31
    
Wish I had sufficient points to contribute to the discussion below... but I expect looping is a terrible strategy here! Would be great to see some timing comparisons... –  Tim P Jun 6 '12 at 3:34
    
I did look briefly at merge but wasn't sure how to guarantee it correctly preserved order, which is essential here. My first few attempts seemed to mangle the order so I instead went for an approach guaranteed to work. What syntax for merge would work correctly here? Morally both approaches are one liners anyway (Z31_m and pred_m are defined separately just for clarity really). –  Tim P Jun 6 '12 at 4:11

a quick solution is to define a vector outside the loop as:

 temp_cumtt=c(rep(0,nrow(pred)))

and then use this:

if (Z31[i,2] == pred[j,5] & Z31[i,3] == pred[j,4] & Z31[i,4] == pred[j,6] & pred[j,1] >= Z31[i,1]){
   temp_cumtt[j]=pred[j,7] + pred[j-1,8]
}

instead of updating the data.frame column directly.

After you come out of the loop, you can update the column:

 pred$cum_tt = temp_cumtt  

The other thing is you have to be careful when using j-1 with index of j starting at 1. In your example it doesn't lead to that conditional-problem.

EDIT:

Now looking at your data-format, I have these suggestions.

1) Don't convert into Date class, instead keep it as a vector of values.

2) Sort the Z31 data_frame according to Date-vector: Z31=Z31[with(Z31, order(-Date)), ] (Note in descending order since you want to compare pred[,Date index]>=Z31[,Date index]

3) Use the 1st loop as pred. First take the Date of pred -> pred[i,1] and try to binary sort and find which index in Z31 it satisfies and from that index onwards go down the list. If Date condition satisfies then check for the rest of the conditions and fill the temp_cumtt[i] as before.

This should be blazing fast (since binary sort only on 48 rows of Z31 and you can compare the run time .with the other solution.

share|improve this answer
    
Thanks subs, that does improve execution speed, I'm down to about 15 secs per outside iteration, down from 60. I'm hopeing to be able to do this without loops at all though since they're so slow. Still, this is a big improvement. I'm not worried about the j-1 index since in the dataset I'm using the first row will never be true. –  Justin Jun 6 '12 at 3:21
    
loops are not inefficient. It depends on what you do inside them. The other way is to sort your Z31 data frame according to your Date and since the Date in pred is already sorted, you can check use an algorithm to start comparison from an index instead of going over all your Z rows * P rows –  Subs Jun 6 '12 at 3:31
    
Thanks again subs. I need to move on with what I'm doing so I wasn't able to implement the binary sort technique. You've helped me speed it up to an acceptable level though. Some timings in the question above. –  Justin Jun 6 '12 at 5:27

Let's make use of data.table, which should speed things up a whole lot.

Z31 <- data.table(Z31,key="Site,Cultivar,Planting")
pred <- data.table(pred)

## First, let's create an extra column in `pred` to see the corresponding date from `Z31` 
## Note 1: The JT is necessary since both sets have the same column names
## Note 2: I needed to use as.integer on Planting to make it work

pred[,Z31Est.Date:={JT=J(Site,Cultivar,as.integer(Planting)); Z31[JT,Est.Date][[4]]}]

## Now we can see for each row whether the date in `pred` is higher than or equal to that from `Z31`.

pred[,DateTrue:=Date>=Z31Est.Date]

## Finally, we only have to add up `pred[i,tt]` and `pred[i-1,cum_tt]` for each row where `DateTrue` equals `TRUE`.

for (i in 1:nrow(pred)) set(pred,i,13L,if(pred[i,DateTrue]) pred[i-1,cum_tt]+pred[i,tt] else(0))
share|improve this answer
    
A 'solution' that still contains for (i in 1:nrow(pred)) isn't really helpful - we already have a solution with full vectorisation. –  Tim P Jun 6 '12 at 19:56
    
The question was to speed up a loop, right? Well I think this speeds it up but I can't test whether it actually does. But indeed using a loop should be avoided. –  Dirk Jun 7 '12 at 9:28
    
I read the question as being... "I know loops are not R's strong point so can anyone assist me with vectorising this operation?" :) –  Tim P Jun 7 '12 at 10:45
    
@Dirk I can see what you were trying here. I suspect a shorter and simpler data.table solution is possible, though. Possibly even a one or two liner which should be faster than Tim's vectorisation using paste (which is usually the part that doesn't scale to 1e6, 1e7 or 1e9 rows). I'll come back to this one day. We could do with a 1e7 example to demonstrate the timings. –  Matt Dowle Jun 15 '12 at 17:56

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