Following a previous question I asked, I got an awesome answer.
Here is a quick summary:
I want to compute a multidimensional development index based on South Africa Data for several years. My list is composed of individual information for each year, so basically df1 is about year 1 and df2 about year2.
df1<-data.frame(var1=c(1, 1,1), var2=c(0,0,1), var3=c(1,1,0))
df2<-data.frame(var1=c(1, 0,1), var2=c(1,0,1), var3=c(0,1,0))
mylist <-list (df1,df2)
var1 could be the stance on religion of each person, var2 how she voted in last national election, etc. In my very simple case, I have the data for 3 different persons each year.
From there, I compute an index based on a number of variables (not all of them)
You can find here a very simplified working index function, with only 2 of 3 variables, named dimX and dimY:
myindex <- function(x, dimX, dimY){
econ_i<- ( x[dimX]+ x[dimY] )
return ( (1/length(econ_i))*sum(econ_i) )
}
myindex(df1, "var2", "var3")
and
myindex2 = function(x, d) {
myindex(x, d[1], d[2])
}
Then I have my dataframe of variables I want to use for my index. I am trying to compute the index for several sets of variables.
args <- data.frame(set1=c("var1", "var2"), set2=c("var2", "var3"), stringsAsFactors = F)
I'd like to have the result as follows : (a)list(set1 = list(df1, df2), set2 = (df1, df2))instead of (b) list(df1 = list(set1, set2), df2 = list(set1, set2)).
Case (a) represents a time series, meaning I have a list of results of my indexes each year for only one set of variables. Case (b) is the opposite where I have the index results of one year for every set of variables. Each individual result should be a unique numeric value. Hence, I am expecting to get a list of 2 sublists df1 and df2, each sublist containing 3 numeric values.
I've been adviced to do use that great command:
lapply(mylist, function(m) lapply(args, myindex2, x = m))
It's working great, but I get the result in the "wrong" format, namely the second one (b) I showed.
How could I get the results ordered per set (i.e. case (a) as time series) instead of per year?
Thanks a lot for your help!
PJ
EDIT: I've managed to find a solution that doesn't answer the question, but still allows me to get my data in desired order.
Namely, I'm transforming my list of lists to a matrix that I simply transpose.
This answer will be edited!
Currently, your function index() does this
myindex <- function(x, dimX, dimY){
econ_i<- ( x[dimX]+ x[dimY] )
return ( (1/length(econ_i))*sum(econ_i) )
}
Aren't you after this, however?
myindex <- function(x, dimX, dimY){
econ_i<- ( x[,dimX]+ x[,dimY] )
return ( (1/length(econ_i))*sum(econ_i) )
}
The way you have it right now, length(econ_i) always returns 1 because econ_i is a data.frame() and not a vector. The length of a data.frame() is always 1, while the length of a vector is the number of elements within it.
Kindly note that here is what the output looks like in R.
df1["var1"]
var1
1 1
2 1
3 1
returns a data.frame()
df1[,"var1"]
[1] 1 1 1
returns a vector.
I will adjust this post to answer your question when you respond. I think it's important to solve this part first.
If that may provide any help, from this article, here my actual index function:
RCI_a_3det <-function(x, econ1, econ2, econ3, perso1, perso2, perso3, civic1, civic2, civic3){
econ_i<- (1/3) *( x[econ1]+ x[econ2] + x[econ3])
perso_i<- (1/3)*( x[perso1] + x[perso2] + x[perso3])
civic_i<- (1/3)*(x[civic1] + x[civic2] + x[civic3])
daf <- data.frame(econ_i, perso_i, civic_i)
colnames(daf)<- c("econ_i", "perso_i", "civic_i")
df1 <- subset(daf, daf$econ_i !=1 & daf$perso_i !=1 & daf$civic_i!=1 )
sum_xik <- (df1$econ_i + df1$perso_i + df1$civic_i)
return ( 1/(3*nrow(df1)) * sum(sum_xik, na.rm=T))
}
Edit:
x is a list of all personal information, for every variable and for every year. It is pretty large.
I am using 9 variables to compute this index, but I actually have 30 such variables in my data, so I have set up a dataframe of sets of variables I could use to compute this index. This is the equivalent of my args df in the simple example. I am actually using 200 such combinations.
I have a very simple assignment for a project that requires processing a large amount of information; my professor's first words were "this will take a while to run" so I figured it'd be a good opportunity to spend that time i would be running my program making a super efficient one :P
Basically, I have a input file where each line is either a node or details. It might look something like:
#NODE1_length_17_2309482.2394832.2
val1 5 18
val2 6 21
val3 100 23
val4 9 6
#NODE2_length_1298_23948349.23984.2
val1 2 293
...
and so on. Basically, I want to know how I can efficiently use R to either output, line by line, something like:
NODE1_length_17 val1 18
NODE1_length_17 val2 21
...
So, as you can see, I would want to node name, the value, and the third column of the value line. I have implemented it using an ultra slow for loop that uses strsplit a whole bunch of times, and obviously this is not ideal. My current implementation looks like:
nodevals <- which(substring(data, 1, 1) == "#") # find lines with nodes
vallines <- which(substring(data, 1, 3) == "val")
out <- vector(mode="character", length=length(vallines))
for (i in vallines) {
line_ra <- strsplit(data[i], "\\s+")[[1]]
... and so on using a bunch of str splits and pastes to reformat
out[i] <- paste(node, val, value, sep="\t")
}
Does anybody know how I can optimize this using data frames or crafty vector manipulations?
EDIT: I'm implementing vecor wise splitting for everything, and so far I've found that the main thing I can't split correctly is the names of each node. I'm trying to do something like,
names <- data[max(nodes[nodelines < vallines])]
where nodes are the names of each line containing a node and vallines are the numbers of each line containing a val. The return vector should have the same number of elements as vallines. The goal is to find the maximum nodelines that is less than the line number of vallines for each vallines. Any thoughts?
I suggest using data.table package - it has very fast string split function tstrsplit.
library(data.table)
#read from file
data <- scan('data.txt', 'character', sep = '\n')
#create separate objects for nodes and values
dt <- data.table(data)
dt[, c('IsNode', 'NodeId') := list(IsNode <- substr(data, 1, 1) == '#', cumsum(IsNode))]
nodes <- dt[IsNode == TRUE, list(NodeId, data)]
values <- dt[IsNode == FALSE, list(data, NodeId)]
#split string and join back values and nodes
tmp <- values[, tstrsplit(data, '\\s+')]
values <- data.table(values[, list(NodeId)], tmp[, list(val = V1, value = V3)], key = 'NodeId')
res <- values[nodes]
I want to subtract each column from a column called df$Means in r. I want to do this as a function but Im not sure how to iterate through each of the columns- each iteration relies on one column being subtracted from df$Means and then there is a load of downstream code that uses the output. I have simplified the code for here as this is the bit that's giving me trouble. So far I have:
CopyNumberLoop <- function (i) {df$ZScore <- (df[3:5]-df$Means)/(df$sd)
}
apply(df[3:50], 2, CopyNumberLoop)
but Im not sure how to make sure that the operation is done on one column at a time. I don't think df[3:5] is correct?
I have been asked to produce a reproducible example so all the code I want is here:
df1 <- read.delim(file.choose(),header=TRUE)
#Take the control samples and average each row for three columns excluding the first two columns- add the per row means to the data frame
df$Means <- rowMeans(df[,30:32])
RowVar <- function(x) {rowSums((x - rowMeans(x))^2)/(dim(x)[2] - 1)}
df$sd=sqrt(RowVar(df[,c(30:32)]))
#Get a Z score by dividing the test sample count at each locus by the average for the control samples and divide everything by the st dev for controls at each locus.
{
df$ZScore <- (df[,35]-df$Means)/(df$sd)
######################################### QUARTILE FILTER ###########################################################
alpha=1.5
numberofControls = 3
UL = median(df$ZScore, na.rm = TRUE) + alpha*IQR(df$ZScore, na.rm = TRUE)
LL = median(df$ZScore, na.rm = TRUE) - alpha*IQR(df$ZScore, na.rm = TRUE)
#Copy the Z score if the score is > or < a certain number, i.e. LL or UL.
Zoutliers <- which(df$ZScore > UL | df$ZScore < LL)
df$Zoutliers <- ifelse(df$ZScore > UL |df$ZScore <LL ,1,-1)
tempout = ifelse(df$ZScore[Zoutliers] > UL,1,-1)
######################################### Three neighbour Isolation filter ##############################################################################
finalSeb=c()
for(i in 2:(length(Zoutliers)-1)){
j=Zoutliers[i]
if(sum(ifelse((j-1) == Zoutliers,1,0)) > 0 & tempout[i] == tempout[i-1] & sum(ifelse((j+1) == Zoutliers,1,0)) > 0 & tempout[i] == tempout[i+1]){
finalSeb = c(finalSeb,i)
}
}
finalset_row_number = Zoutliers[finalSeb]
#View(finalset_row_number)
p_seq = rep(0,nrow(df))
for(i in 1:length(finalset_row_number)){
p_seq[(finalset_row_number[i]-1):(finalset_row_number[i]+1)] = median(df$ZScore[(finalset_row_number[i]-1):(finalset_row_number[i]+1)])
}
nrow(as.data.frame(finalset_row_number))
}
For each column between 3 and 50 I'd like to generate a nrow(as.data.frame(finalset_row_number)) and keep it in another dataframe. Admittedly my code is a mess because I dont know how to create the function that will allow me to apply this to each column
Your code isn’t using the parameter i at all. In fact, i is the current column, so that’s what you should use:
result = apply(df[, 3 : 50], 2, function (col) col - df$Means)
Or you can subtract the means directly:
result = df[, 3 : 50] - df$Means
This will return a new matrix consisting of the columns 3–50 from df, subtracting df$Means from each in turn. Or, if you want to calculate Z scores as your code seems to do:
result = (df[, 3 : 50] - df$Means) / df$sd
It appeared that you wanted the Z-scores assigned back into the original dataframe as named columns. If you want to loop over columns, it would be just as economical to use lapply or sapply. The receiving function will accept each column in turn and match it to the first parameter. Any other arguments offered after the receiving function will get matched by name or position to any other symbol/names in the parameter list. You do not do any assignment to 'df' inside the function:
CopyNumberLoop <- function (col) { col-df$Means/(df$sd)
}
df[, paste0('ZScore' , 3:50)] <- # assignment done outside the loop
lapply(df[3:50], CopyNumberLoop) # result is a list
# but the `[.data.frame<-` method will accept a list.
Usign apply coerces to a matrix which may have undesirable effects in the column is not numeric (say factor or date-time). It's better to get into he habit of using lapply when working on ranges of columns in dataframes.
If you want to assign the result of this operation to a new dataframe, then the lapply(.) result would need to be wrapped in as.data.frame and then column names could be assigned. Same effort would need to be done to a result from apply(.).
I have three variables in a data frame and would like to swap the 4 columns around from
"dam" "piglet" "fdate" "ssire"
to
"piglet" "ssire" "dam" "tdate"
Is there any way I can do the swapping using R?
Any help would be very much appreciated.
Baz
dfrm <- dfrm[c("piglet", "ssire", "dam", "tdate")]
OR:
dfrm <- dfrm[ , c("piglet", "ssire", "dam", "tdate")]
d <- data.frame(a=1:3, b=11:13, c=21:23)
d
# a b c
#1 1 11 21
#2 2 12 22
#3 3 13 23
d2 <- d[,c("b", "c", "a")]
d2
# b c a
#1 11 21 1
#2 12 22 2
#3 13 23 3
or you can do same thing using index:
d3 <- d[,c(2, 3, 1)]
d3
# b c a
#1 11 21 1
#2 12 22 2
#3 13 23 3
To summarise the other posts, there are three ways of changing the column order, and two ways of specifying the indexing in each method.
Given a sample data frame
dfr <- data.frame(
dam = 1:5,
piglet = runif(5),
fdate = letters[1:5],
ssire = rnorm(5)
)
Kohske's answer: You can use standard matrix-like indexing using column numbers
dfr[, c(2, 4, 1, 3)]
or using column names
dfr[, c("piglet", "ssire", "dam", "fdate")]
DWin & Gavin's answer: Data frames allow you to omit the row argument when specifying the index.
dfr[c(2, 4, 1, 3)]
dfr[c("piglet", "ssire", "dam", "fdate")]
PaulHurleyuk's answer: You can also use subset.
subset(dfr, select = c(2, 4, 1, 3))
subset(dfr, select = c(c("piglet", "ssire", "dam", "fdate")))
You can use subset's 'select' argument;
#Assume df contains "dam" "piglet" "fdate" "ssire"
newdf<-subset(df, select=c("piglet", "ssire", "dam", "tdate"))
I noticed that this is almost an 8-year old question. But for people who are starting to learn R and might stumble upon this question, like I did, you can now use a much flexible select() function from dplyr package to accomplish the swapping operation as follows.
# Install and load the dplyr package
install.packages("dplyr")
library("dplyr")
# Override the existing data frame with the desired column order
df <- select(df, piglet, ssire, dam, tdate)
This approach has following advantages:
You will have to type less as the select() does not require variable names to be enclosed within quotes.
In case your data frame has more than 4 variables, you can utilize select helper functions such as starts_with(), ends_with(), etc. to select multiple columns without having to name each column and rearrange them with much ease.
Relevance Note: In response to some users (myself included) that would like to swap columns without having to specify every column, I wrote this answer up.
TL;DR: A one-liner for numerical indices is provided herein and a function for swapping exactly 2 nominal and numerical indices at the end, neither using imports, that will correctly swap any two columns in a data frame of any size is provided. A function that allows the reassignment of an arbitrary number of columns that may cause unavoidable superfluous swaps if not used carefully is also made available (read more & get functions in Summary section)
Preliminary Solution
Suppose you have some huge (or not) data frame, DF, and you only know the indices of the two columns you want to swap, say 1 < n < m < length(DF). (Also important is that your columns are not adjacent, i.e. |n-m| > 1 which is very likely to be the case in our "huge" data frame but not necessarily for smaller ones; work-arounds for all degenerate cases are provided at the end).
Because it is huge, there are a ton of columns and you don't want to have to specify every other column by hand, or it isn't huge and you're just lazy someone with fine taste in coding, either way, this one-liner will do the trick:
DF <- DF[ c( 1:(n-1), m, (n+1):(m-1), n, (m+1):length(DF) ) ]
Each piece works like this:
1:(n-1) # This keeps every column before column `n` in place
m # This places column `m` where column `n` was
(n+1):(m-1) # This keeps every column between the two in place
n # This places column `n` where column `m` was
(m+1):length(DF) # This keeps every column after column `m` in place
Generalizing for Degenerates
Because of how the : operator works, i.e. allowing "backwards-ranges" like this,
> 10:0
[1] 10 9 8 7 6 5 4 3 2 1 0
we have to be careful about our choices and placements of n and m, hence our previous restrictions. For instance, n < m doesn't lose us any generality (one of the columns has to be before the other one if they are different), however, it means we do need to be careful about which goes where in our line of code. We can make it so that we don't have to check this condition with the following modification:
DF <- DF[ c( 1:(min(n,m)-1), max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m), (max(n,m)+1):length(DF) ) ]
We have replaced every instance of n and m with min(n,m) and max(n,m) respectively, meaning that the correct ordering for our code will be preserved even in the case that m > n.
In the cases where min(n,m) == 1, max(n,m) == length(DF), both of those at the same time, and |n-m| == 1, we we will make some unreadable less aesthetic modifications involving if\else to forget about having to check if these are the case. Versions for where you know that one of these are the case, (i.e. you are always swapping some interior column with the first column, swapping some interior column with the last column, swapping the first and last columns, or swapping two adjacent columns), you can actually express these actions more succinctly because they usually just require omitting parts from our restricted case:
# Swapping not the last column with the first column
# We just got rid of 1:(min(n,m)-1) because it would be invalid and not what we meant
# since min(n,m) == 1
# Now we just stick the other column right at the front
DF <- DF[ c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m), (max(n,m)+1):length(DF) ) ]
# Also equivalent since we know min(n,m) == 1, for the leftover index i
DF <- DF[ c( i, 2:(i-1), 1, (i+1):length(DF) ) ]
# Swapping not the first column with the last column
# Similarly, we just got rid of (max(n,m)+1):length(DF) because it would also be invalid
# and not what we meant since max(n,m) == length(DF)
# Now we just stick the other column right at the end
DF <- DF[ c( 1:(min(n,m)-1), max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m) ) ]
# Also equivalent since we know max(n,m) == length(DF), for the leftover index, say i
DF <- DF[ c( 1:(i-1), length(DF), (i+1):(length(DF)-1), i ) ]
# Swapping the first column with the last column
DF <- DF[ c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m) ) ]
# Also equivalent (for if you don't actually know the length beforehand, as assumed
# elsewhere)
DF <- DF[ c( length(DF), 2:(length(DF)-1), 1 ) ]
# Swapping two interior adjacent columns
# Here we drop the explicit swap on either side of our middle column segment
# This is actually enough because then the middle segment becomes a backwards range
# because we know that `min(n,m) + 1 = max(n,m)`
# The range is just an ordering of the two adjacent indices from largest to smallest
DF <- DF[ c( 1:(min(n,m)-1), (min(n,m)+1):(max(n,m)-1), (max(n,m)+1):length(DF) )]
"But!", I hear you saying, "What if more than one of these cases occur simultaneously, like did in the third version in the block above!?". Right, coding up versions for each case is an enormous waste of time if one wants to be able to "swap columns" in the most general sense.
Swapping any Two Columns
It will be easiest to generalize our code to cover all of the cases at the same time, because they all employ essentially the same strategy. We will use if\else to keep our code a one-liner:
DF <- DF[ if (n==m) 1:length(DF) else c( (if (min(n,m)==1) c() else 1:(min(n,m)-1) ), (if (min(n,m)+1 == max(n,m)) (min(n,m)+1):(max(n,m)-1) else c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m))), (if (max(n,m)==length(DF)) c() else (max(n,m)+1):length(DF) ) ) ]
That's totally unreadable and probably pretty unfriendly to anyone who might try to understand or recreate your code (including yourself), so better to box it up in a function.
# A function that swaps the `n` column and `m` column in the data frame DF
swap <- function(DF, n, m)
{
return (DF[ if (n==m) 1:length(DF) else c( (if (min(n,m)==1) c() else 1:(min(n,m)-1) ), (if (min(n,m)+1 == max(n,m)) (min(n,m)+1):(max(n,m)-1) else c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m))), (if (max(n,m)==length(DF)) c() else (max(n,m)+1):length(DF) ) ) ])
}
A more robust version that can also swap on column names and has semi-explanatory comments:
# Returns data frame object with columns `n` and `m` swapped
# `n` and `m` can be column names, numerical indices, or a heterogeneous pair of both
swap <- function(DF, n, m)
{
# Of course, first, we want to make sure that n != m,
# because if they do, we don't need to do anything
if (n==m) return(DF)
# Next, if either n or m is a column name, we want to get its index
# We assume that if they aren't column names, they are indices (integers)
n <- if (class(n)=="character" & is.na(suppressWarnings(as.integer(n)))) which(colnames(DF)==n) else as.integer(n)
m <- if (class(m)=="character" & is.na(supressWarnings(as.integer(m)))) which(colnames(DF)==m) else as.integer(m)
# Make sure each index is actually valid
if (!(1<=n & n<=length(DF))) stop( "`n` represents invalid index!" )
if (!(1<=m & m<=length(DF))) stop( "`m` represents invalid index!" )
# Also, for readability, lets go ahead and set which column is earlier, and which is later
earlier <- min(n,m)
later <- max(n,m)
# This constructs the first third of the indices
# These are the columns that, if any, come before the earlier column you are swapping
firstThird <- if ( earlier==1 ) c() else 1:(earlier-1)
# This constructs the last third of the the indices
# These are the columns, if any, that come after the later column you are swapping
lastThird <- if ( later==length(DF) ) c() else (later+1):length(DF)
# This checks if the columns to be swapped are adjacent and then constructs the
# secondThird accordingly
if ( earlier+1 == later )
{
# Here; the second third is a list of the two columns ordered from later to earlier
secondThird <- (earlier+1):(later-1)
}
else
{
# Here; the second third is a list of
# the later column you want to swap
# the columns in between
# and then the earlier column you want to swap
secondThird <- c( later, (earlier+1):(later-1), earlier)
}
# Now we assemble our indices and return our permutation of DF
return (DF[ c( firstThird, secondThird, lastThird ) ])
}
And, for ease of repatriation with less of the spatial cost, a comment-less version that checks index validity and can handle column names, i.e. does everything in pretty close to the smallest space it can (yes, you could vectorize, using ifelse(...), the two checks that get performed, but then you'd have to unpack the vector back into n,m or change how the final line is written):
swap <- function(DF, n, m)
{
n <- if (class(n)=="character" & is.na(suppressWarnings(as.integer(n)))) which(colnames(DF)==n) else as.integer(n)
m <- if (class(m)=="character" & is.na(suppressWarnings(as.integer(m)))) which(colnames(DF)==m) else as.integer(m)
if (!(1<=n & n<=length(DF))) stop( "`n` represents invalid index!" )
if (!(1<=m & m<=length(DF))) stop( "`m` represents invalid index!" )
return (DF[ if (n==m) 1:length(DF) else c( (if (min(n,m)==1) c() else 1:(min(n,m)-1) ), (if (min(n,m)+1 == max(n,m)) (min(n,m)+1):(max(n,m)-1) else c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m))), (if (max(n,m)==length(DF)) c() else (max(n,m)+1):length(DF) ) ) ])
}
Permutations (or How to Do Specifically What the Question Asked and More!)
With our swap function in tow, we can try to actually do what the original question asked. The easiest way to do this, is to build a function that utilizes the really cool power that comes with a choice of heterogeneous arguments. Create a mapping:
mapping <- data.frame( "piglet" = 1, "ssire" = 2, "dam" = 3, "tdate" = 4)
In the case of the original question, these are all of the columns in our original data frame, but we will build a function where this doesn't have to be the case:
# A function that takes two data frames, one with actual data: DF, and the other with a
# rearrangement of the columns: R
# R must be structured so that colnames(R) is a subset of colnames(DF)
# Alternatively, R can be structured so that 1 <= as.integer(colnames(R)) <= length(DF)
# Further, 1 <= R$column <= length(DF), and length(R$column) == 1
# These structural requirements on R are not checked
# This is for brevity and because most likely R has been created specifically for use with
# this function
rearrange <- function(DF, R)
{
for (col in colnames(R))
{
DF <- swap(DF, col, R[col])
}
return (DF)
}
Wait, that's it? Yup. This will swap every column name to the appropriate placement. The power for such simplicity comes from swap taking heterogeneous arguments meaning we can specify the moving column name that we want to put somewhere, and so long as we only ever try to put one column in each position (which we should), once we put that column where it belongs, it won't move again. This means that even though it seems like later swaps could undo previous placements, the heterogeneous arguments make certain that won't happen, and so additionally, the order of the columns in our mapping also doesn't matter. This is a really nice quality because it means that we aren't kicking this whole "organizing the data" issue down the road too much. You only have to be able to determine which placement you want to send each column you want to move to.
Ok, ok, there is a catch. If you don't reassign the entire data frame when you do this, then you have superfluous swaps that occur, meaning that if you re-arrange over a subset of columns that isn't "closed", i.e. not every column name has an index that is represented in the rearrangement, then other columns that you didn't explicitly say to move may get moved to other places they don't exactly belong. This can be handled by creating your mapping very carefully, or simply using numerical indices mapping to other numerical indices. In the latter case, this doesn't solve the issue, but it makes more explicit what swaps are taking place and in what order so planning the rearrangement is more explicit and thus less likely to lead to problematic superfluous swaps.
Summary
You can use the swap function that we built to successfully swap exactly two columns or the rearrange function with a "rearrangement" data frame specifying where to send each column name you want to move. In the case of the rearrange function, if any of the placements chosen for each column name are not already occupied by one of the specified columns (i.e. not in colnames(R)), then superfluous swaps can and are very likely to occur (The only instance they won't is when every superfluous swap has a partner superfluous swap that undoes it before the end. This is, as stated, very unlikely to happen by accident, but the mapping can be structured to accomplish this outcome in practice).
swap <- function(DF, n, m)
{
n <- if (class(n)=="character" & is.na(suppressWarnings(as.integer(n)))) which(colnames(DF)==n) else as.integer(n)
m <- if (class(m)=="character" & is.na(suppressWarnings(as.integer(m)))) which(colnames(DF)==m) else as.integer(m)
if (!(1<=n & n<=length(DF))) stop( "`n` represents invalid index!" )
if (!(1<=m & m<=length(DF))) stop( "`m` represents invalid index!" )
return (DF[ if (n==m) 1:length(DF) else c( (if (min(n,m)==1) c() else 1:(min(n,m)-1) ), (if (min(n,m)+1 == max(n,m)) (min(n,m)+1):(max(n,m)-1) else c( max(n,m), (min(n,m)+1):(max(n,m)-1), min(n,m))), (if (max(n,m)==length(DF)) c() else (max(n,m)+1):length(DF) ) ) ])
}
rearrange <- function(DF, R)
{
for (col in colnames(R))
{
DF <- swap(DF, col, R[col])
}
return (DF)
}
I quickly wrote a function that takes a vector v and column indexes a and b which you want to swap.
swappy = function(v,a,b){ # where v is a dataframe, a and b are the columns indexes to swap
name = deparse(substitute(v))
helpy = v[,a]
v[,a] = v[,b]
v[,b] = helpy
name1 = colnames(v)[a]
name2 = colnames(v)[b]
colnames(v)[a] = name2
colnames(v)[b] = name1
assign(name,value = v , envir =.GlobalEnv)
}
I was using the function by Khôra Willis, which is helpful. But I encountered an error. I tried to make corrections. Here is R code that finally works. The arguments n and m could either be column names or column numbers in data frame DF.
require(tidyverse)
swap <- function(DF, n, m)
{
if (class(n)=="character") n <- which(colnames(DF)==n)
if (class(m)=="character") m <- which(colnames(DF)==m)
p <- NCOL(DF)
if (!(1<=n & n<=p)) stop("`n` represents invalid index!")
if (!(1<=m & m<=p)) stop("`m` represents invalid index!")
index <- 1:p
index[n] <- m; index[m] <- n
DF0 <- DF %>% select(all_of(index))
return(DF0)
}