## ----Rle-rollmean, eval=FALSE-------------------------------------------------
# rollmeanRle <- function (x, k)
# {
#     n <- length(x)
#     cumsum(c(Rle(sum(window(x, 1, k))), window(x, k + 1, n) - window(x, 1, n - k))) / k
# }

## ----Rle-rollvar, eval=FALSE--------------------------------------------------
# rollvarRle <- function(x, k)
# {
#     n <- length(x)
#     means <- rollmeanRle(x, k)
#     nextMean <- window(means, 2, n - k + 1)
#     cumsum(c(Rle(sum((window(x, 1, k) - means[1])^2)),
#     k * diff(means)^2 - (window(x, 1, n - k) - nextMean)^2 + (window(x, k + 1, n) - nextMean)^2)) / (k - 1)
# }

## ----Rle-rollcov, eval=FALSE--------------------------------------------------
# rollcovRle <- function(x, y, k)
# {
#     n <- length(x)
#     meanX <- rollmeanRle(x, k)
#     meanY <- rollmeanRle(y, k)
#     nextMeanX <- window(meanX, 2, n - k + 1)
#     nextMeanY <- window(meanY, 2, n - k + 1)
#     cumsum(c(Rle(sum((window(x, 1, k) - meanX[1]) * (window(y, 1, k) - meanY[1]))),
#     k * diff(meanX) * diff(meanY) - (window(x, 1, n - k) - nextMeanX) * (window(y, 1, n - k) - nextMeanY) + (window(x, k + 1, n) - nextMeanX) * (window(y, k + 1, n) - nextMeanY))) / (k - 1)
# }

## ----Rle-rollsd, eval=FALSE---------------------------------------------------
# rollsdRle <- function(x, k)
# {
#    sqrt(rollvarRle(x, k))
# }

## ----Rle-rollcor,eval=FALSE---------------------------------------------------
# rollcorRle <- function(x, y, k)
# {
#    rollcovRle(x, y, k) / (rollsdRle(x, k) * rollsdRle(y, k))
# }