The following code does not work as I expected:

a <- list(0, 1)
b <- list(0, 1)

# return a linear function with slope `a` and intercept `b`.
f <- function(a, b) function(x) a*x + b

# create a list of functions with different parameters.
fs <- mapply(f, a, b)

# test
# [1] 4  # expected zero!
# [1] 4

Can anyone tell me why?

NB: I've found a workaround, so I'm not looking for a different way to achieve the desired result. But I'm curious as to why this particular approach didn't work.


As of R 3.2.0, this now works as expected:

a <- list(0, 1)
b <- list(0, 1)
f <- function(a, b) function(x) a*x + b
fs <- mapply(f, a, b)

# test
# [1] 0 
# [1] 4
  • +1 for finding this weird behavior! I love these things :-) – Tommy Dec 9 '11 at 4:24
  • Might not be an *apply thing: fs <- list(); for(i in 1:2) fs[[i]] <- f(a[[i]], b[[i]]) does the same thing. – pete Dec 9 '11 at 8:38

[Update] My initial analysis was correct but the conclusions were wrong :) Let's get to the conclusions after the analysis.

Here's some code demonstrating the effects:

x <- lapply(1:3, function(x) sys.frame(sys.nframe()))
x[[1]] # An environment
x[[2]] # Another environment
x[[3]] # Yet nother environment
x[[1]]$x  # 3!!! (should be 1)
x[[2]]$x  # 3!!  (should be 2)
x[[3]]$x  # 3 as expected

# Accessing the variable within the function will "fix" the weird behavior:
x <- lapply(1:3, function(x) {x; sys.frame(sys.nframe())})
x[[1]]$x  # 1
x[[2]]$x  # 2
x[[3]]$x  # 3

So the work-around in your case:

f <- function(a, b) { a;b; function(x) a*x + b }

Btw, as @James notes there is a force function that makes accessing a variable more explicit:

f <- function(a, b) { force(a);force(b); function(x) a*x + b }


Well, as @mbq and @hadley noted, this is due to lazy evaluation. It' easier to show with a simple for-loop:

fs <- list(); for(i in 1:2) fs[[i]] <- f(a[[i]], b[[i]])

The function f's x argument will not get the value of a[[i]] (which is 0), but the whole expression and the environment where a and i exist. When you access x, it gets evaluated and therefore uses the i at the time of evaluation. If the for-loop has moved on since the call to f, you get the "wrong" result...

Initially I said that this was due to a bug in *apply, which it isn't. ...but since I hate to be wrong, I can point out that *apply DOES have a bug (or perhaps more of an inconsistency) in these cases:

lapply(11:12, function(x) sys.call())
#FUN(11:12[[1L]], ...)
#FUN(11:12[[2L]], ...)

lapply(11:12, function(x) function() x)[[1]]() # 12
lapply(11:12, function(x) function() x)[[2]]() # 12

As you see above, the lapply code says it calls the function with 11:12[[1L]]. If you evaluate that "later" you should still get the value 11 - but you actually get 12!

This is probably due to the fact that lapply is implemented in C code for performance reasons and cheat a bit, so the expression that it shows is not the expression that gets evaluated - ergo, a bug...


| improve this answer | |
  • See ?force for a similar example – James Dec 9 '11 at 11:34
  • 4
    It's not a bug. It's a consequence of lazy evaluation. – hadley Dec 9 '11 at 13:25

This is the result of lazy evaluation -- all arguments are passed down the call tree as promises to avoid unnecessary execution and remain in this suspended state till R is convinced that they are used.

In your code you just populate functions with a same promise to a and same promise to b; then they all got committed to a last pair of vales. As @Tommy already showed, the solution is to force commitment by "using" the value before the function gets defined.

| improve this answer | |

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.