4

I need to generate lower triangle matrix indices (row and columns pairs). The current implementation is inefficient (memory wise) specially when symmetric matrix gets big (more than 50K rows). Is there a better way?

rows <- 2e+01
id <- which(lower.tri(matrix(, rows, rows)) == TRUE, arr.ind=T)
head(id)

#      row col
# [1,]   2   1
# [2,]   3   1
# [3,]   4   1
# [4,]   5   1
# [5,]   6   1
# [6,]   7   1

3 Answers 3

6

Here's another approach:

z <- sequence(rows)
cbind(
  row = unlist(lapply(2:rows, function(x) x:rows), use.names = FALSE),
  col = rep(z[-length(z)], times = rev(tail(z, -1))-1))

Benchmarks with larger data:

library(microbenchmark)

rows <- 1000
m <- matrix(, rows, rows)

## Your current approach
fun1 <- function() which(lower.tri(m) == TRUE, arr.ind=TRUE)

## An improvement of your current approach
fun2 <- function() which(lower.tri(m), arr.ind = TRUE)

## The approach shared in this answer
fun3 <- function() {
  z <- sequence(rows)
  cbind(
    row = unlist(lapply(2:rows, function(x) x:rows), use.names = FALSE),
    col = rep(z[-length(z)], times = rev(tail(z, -1))-1))
}

## Sven's answer
fun4 <- function() {
  row <- rev(abs(sequence(seq.int(rows - 1)) - rows) + 1)
  col <- rep.int(seq.int(rows - 1), rev(seq.int(rows - 1)))
  cbind(row, col)
}

microbenchmark(fun1(), fun2(), fun3(), fun4())
# Unit: milliseconds
#    expr       min        lq   median       uq       max neval
#  fun1() 77.813577 85.343356 90.60689 95.71648 130.40059   100
#  fun2() 73.812204 82.103600 85.87555 90.59235 138.66547   100
#  fun3()  9.016237  9.382506 10.63291 13.20085  55.42137   100
#  fun4() 20.591863 24.999702 28.82232 31.90663  65.05169   100
1
  • 1
    When I have rows <- 1e+05 then lapply requires lots of memory to build the list, i.e. of order O(n^2). Is there a way to rewrite fun3() so it can be called iteratively in a loop to return subsets of the index pairs, lets say 10K pairs a time? Jan 3, 2014 at 22:39
2

Your approach is so slow because multiple matrices have to be created. You create the first matrix using matrix. The function lower.tri creates 3 matrices internally. The comparison of the result with TRUE creates a fifth matrix. By the way: The comparison with TRUE is unnecessary.

The following approach does not create any matrix, but calculates the indices:

rows <- 2e+01 # number of rows and columns (20)

x <- rev(abs(sequence(seq.int(rows - 1)) - rows) + 1)
y <- rep.int(seq.int(rows - 1), rev(seq.int(rows - 1)))

idx <- cbind(x, y)

(If you want a slightly faster approach, you can assign the result of seq.int(rows - 1) to a variable instead of using this command three times.)

Compare with original solution:

id <- which(lower.tri(matrix(, rows, rows)) == TRUE, arr.ind=T)

all(id == idx)
# TRUE
0

Here's a simplified and faster version of the fun3 method from the accepted answer (rep.int is faster than rep, 1:rows is faster than sequence(rows), (rows-1):1 was slightly faster than rev(z[-rows]), and use.names=F is not needed):

rows=5
z=1:rows
cbind(unlist(lapply(z[-1],function(x)x:rows)),rep(z[-rows],(rows-1):1))

Or if you don't save the sequence in a variable, then the code becomes a bit slower but easier to understand:

cbind(unlist(lapply(2:rows,function(x)x:rows)),rep(1:(rows-1),(rows-1):1))

1:n is faster than sequence(n) and seq.int(n):

> n=1e6;microbenchmark(sequence(n),1:n,seq(n),seq.int(n))
Unit: nanoseconds
          expr    min        lq       mean    median        uq     max neval
   sequence(n) 420147 1397684.5 1295462.89 1428241.5 1466248.0 2016984   100
           1:n    129     160.0     561.22     242.5     617.0    4028   100
        seq(n)   3596    4045.5    7538.04    5081.5   11194.5   23921   100
    seq.int(n)    235     289.5    1001.95     502.5    1737.0    5265   100

rep.int is faster than rep:

> z1=1:100;z2=100:1;microbenchmark(times=1000,rep.int(z1,z2),rep(z1,z2))
Unit: microseconds
            expr    min     lq     mean median      uq    max neval
 rep.int(z1, z2) 28.058 28.351 28.76671 28.490 28.9725 69.061  1000
     rep(z1, z2) 29.553 29.849 30.29978 29.963 30.4945 85.321  1000

This is an easy but slow way to generate the indexes of the lower triangle:

combn(rows,2)

This procedural method is also slow:

o=matrix(,(rows^2-rows)/2,2)
n=1;for(i in 1:(rows-1))for(j in(i+1):rows){o[n,]=c(j,i);n=n+1}
o

But the Rcpp version of the procedural method is much faster:

Rcpp::cppFunction('NumericMatrix pairij_cpp(int n){
  NumericMatrix out(n*(n-1)/2,2);
  int row=0;
  for(int i=1;i<=n-1;i++)for(int j=i+1;j<=n;j++){out(row,0)=j;out(row++,1)=i;}
  return out;
}')

This shows the median time in ms for each number of rows:

     10    100   1000
0.01682 0.2700  24.32 fun1
0.01623 0.2380  20.01 fun2
0.02830 0.1717   5.69 fun3
0.01456 0.1440   9.75 fun4
0.01506 0.1440   5.31 fun3_simplified
0.01436 0.1622   7.35 fun3_simplified_no_variable
0.05219 2.9143 296.11 comb
0.05249 4.9847 520.86 procedural_matrix
0.06642 6.5620 682.25 procedural_vector
0.00360 0.0461   2.80 pairij_cpp(rows)

Benchmark code:

Rcpp::cppFunction('NumericMatrix pairij_cpp(int n){
  NumericMatrix out(n*(n-1)/2,2);
  int row=0;
  for(int i=1;i<=n-1;i++)for(int j=i+1;j<=n;j++){out(row,0)=j;out(row++,1)=i;}
  return out;
}')

size=c(10,100,1000)
r=sapply(size,function(rows){
  m=matrix(,rows,rows)
  b=microbenchmark(times=100,
    fun1={which(lower.tri(m)==T,arr.ind=T)},
    fun2={which(lower.tri(m),arr.ind=T)},
    fun3={z=sequence(rows);cbind(row=unlist(lapply(2:rows,function(x)x:rows),use.names=F),col=rep(z[-length(z)],times=rev(tail(z,-1))-1))},
    fun4={row=rev(abs(sequence(seq.int(rows-1))-rows)+1);col=rep.int(seq.int(rows-1),rev(seq.int(rows-1)));cbind(row,col)},
    fun3_simplified={z=1:rows;cbind(unlist(lapply(z[-1],function(x)x:rows)),rep.int(z[-rows],(rows-1):1))},
    fun3_simplified_no_variable={cbind(unlist(lapply(2:rows,function(x)x:rows)),rep.int(1:(rows-1),(rows-1):1))},
    comb={c=t(combn(rows,2));c[,2:1]},
    procedural_matrix={o=matrix(,(rows^2-rows)/2,2);n=1;for(i in 1:(rows-1))for(j in(i+1):rows){o[n,]=c(j,i);n=n+1};o},
    procedural_vector={o=integer(rows^2-rows);n=1;for(i in 1:(rows-1))for(j in(i+1):rows){o[n]=j;o[n+1]=i;n=n+2};matrix(o,,2,T)},
    pairij_cpp(rows)
  )
  a=aggregate(b$time,list(b$expr),median)
  setNames(a[,2]/1e6,a[,1])
})

r2=apply(r,2,function(x)formatC(x,max(0,3-ceiling(log10(min(x,na.rm=T)))),format="f"))
r3=apply(rbind(size,r2),2,function(x)formatC(x,max(nchar(x)),format="s"))
writeLines(apply(cbind(r3,c("",rownames(r))),1,paste,collapse=" "))

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