# Function for multi-level Harshad Number in R

## The challenge:

The German geek podcast Fanboys asked their audience in their latest episode 135 to check which of the episode numbers for upcoming shows will be a 2-level Harshad Number.

A Harshad Number in a given number base, is an integer that is divisible by the sum of its digits when written in that base.

A 2-level Harshad Number, according to the Fanboys interpretation, shall be a number which divisible by the sum of its digits, and the resulting ratio itself shall be a Harshad Number.

## Solution (ugly, to be refined):

I tried to solve this task in R with following code adding a function "two.step.harshed.number(start, end)" with following code:

``````# Function to calculate the two-leveled Harshed Numbers for given integer number intervall

two.step.harshed.number = function(start, end)
{
# Function to calculate a digit sum
digitsum = function (x) {sum(as.numeric(unlist(strsplit(as.character(x), split="")))) }

# Function returning a numbers value if integer, otherwise NA
checkinteger = function (x) {
if (x%%1==0) {
return (x)
}
else {
return(NA)
}
}

# Setup data frame with rows of numbers from start value to end value
db = data.frame(number=start:end)

# 1st level run
# Calculate the digit sum of those numbers
db\$digitsum1 = sapply(db\$number, FUN=digitsum)
# Calculate the ratio of number and it's digit sum and keep only if it's an integer
db\$ratio1 = db\$number / db\$digitsum1
db\$ratio1 = sapply(db\$ratio1, FUN=checkinteger)
db = na.omit(db)

# 2st level run
# Calculate the digit sum of the previous (integer) ratio
db\$digitsum2 = sapply(db\$ratio1, FUN=digitsum)
# Calculate the ratio of the previous ratio and it's digit sum and keep only if it's an integer
db\$ratio2 = db\$ratio1 / db\$digitsum2
db\$ratio2 = sapply(db\$ratio2, FUN=checkinteger)
db = na.omit(db)

# Return remaining number, which proved to be two-leveled Harshed Numbers
return(db\$number)
}
``````

The solution for the challenge (next episodes up to number 200) when using the function:

two.step.harshed.number(136, 200)

is a series of three numbers, which appear correct to me:

162 180 200

## Question:

I am aware this is a beginners code. I'd like to create another function which generalizes the task to n-steps. I.e. function "n.step.harshed.number(steps, start, end)". Any ideas to accomplish this and make the code more efficient?

-
Have you read all the papers linked on the wiki page? –  Carl Witthoft Sep 7 '13 at 15:08
@CarlWitthoft Yes, I did read and tried to understand those papers. As far as I understand them, they do not really cover the approach I have chosen and are more focussed on the numbers theory. My question is more related to seek for experienced R coders suggestions to make the code more efficient and generalize it. –  user2030503 Sep 7 '13 at 15:43

In the meantime I made some progress in simplifying and generalizing the Harshad function:

``````# Function to calculate the n-leveled Harshad Numbers for given integer number intervall
multi.step.harshed.number = function(numlevels, start, end)
{
digitsum = function(x) sum(floor(x / 10^(0:(nchar(x) - 1))) %% 10)
checkinteger = function (x) {
ifelse (x == as.integer(x), return (x), return(NA))
}
db = data.frame(start:end)
for (i in 1:numlevels) {
db[, (2*i)] = sapply(db[, (2*i)-1], FUN=digitsum)
db[, (2*i)+1] = db[, (2*i)-1] / db[, (2*i)]
db[, (2*i)+1] = sapply(db[, (2*i)+1], FUN=checkinteger)
db = na.omit(db)
if (nrow(db) == 0) break
}
return(db[,1])
}
``````

EDIT: 2nd version - maybe following code is a bit more elegant and less busy:

``````multi.step.harshed.number = function(numlevels, start, end) {
is.integer= function(x) ifelse (x== as.integer(x), return (x), return(NA))
digitsum = function(x) sum(floor(x/10^(0:(nchar(x)-1))) %% 10)
digitsumratio= function(x) ifelse(is.integer(x/digitsum(x)), x/digitsum(x), NA)
multi.digitsumratio= function(iter, x) {
for (i in 1:iter) x= digitsumratio(x)
return (ifelse(is.na(x), FALSE, TRUE))
}
sequence=start:end
idx=sapply(sequence, FUN=function (x) multi.digitsumratio(numlevels, x))
sequence[idx]
}
``````

EDIT: 3rd version - same as 2nd but just faster due to use of parallel package:

``````multi.step.harshed.number = function(numlevels, start, end) {
library(parallel)
processors= detectCores()
cl= makeCluster(processors)
is.integer= function(x) ifelse (x== as.integer(x), return (x), return(NA))
digitsum = function(x) sum(floor(x/10^(0:(nchar(x)-1))) %% 10)
digitsumratio= function(x) ifelse(is.integer(x/digitsum(x)), x/digitsum(x), NA)
multi.digitsumratio= function(iter, x) {
for (i in 1:iter) x= digitsumratio(x)
return (ifelse(is.na(x), FALSE, TRUE))
}
sequence=start:end
idx=parSapply(cl=cl,X=sequence, FUN=function (x) multi.digitsumratio(numlevels, x))
sequence[idx]
}
``````

Trying: `multi.step.harshed.number(42, 100, 10000)` returns:

`````` [1]   100   108   120   162   180   200   210   216   240   243   270   300   324   360   378   400   405   420   432   450
[21]   480   486   500   540   600   630   648   700   720   756   800   810   840   864   900   972  1000  1080  1200  1296
[41]  1458  1620  1800  1944  2000  2100  2160  2400  2430  2700  2916  3000  3240  3402  3600  3780  4000  4050  4200  4320
[61]  4374  4500  4800  4860  5000  5400  5832  6000  6300  6480  6804  7000  7200  7290  7560  8000  8100  8400  8640  8748
[81]  9000  9720 10000
``````
-