# Fibonacci One-Liner

I'm trying to solve questions from Project Euler in Ruby one-liners, and I'm curious if there's a more elegant solution for question two:

Each new term in the Fibonacci sequence is generated by adding the previous two terms. By starting with 1 and 2, the first 10 terms will be:

1, 2, 3, 5, 8, 13, 21, 34, 55, 89, ...

By considering the terms in the Fibonacci sequence whose values do not exceed four million, find the sum of the even-valued terms.

Here is my one line solution in Ruby:

(1..32).inject([0,1]) {|arr, i| (arr << arr[-1] + arr[-2] if arr[-1] + arr[-2] <= 4000000) || arr}.inject(0) {|total, i| total += i.even? ? i : 0}

My main concern here is that I'm using the range (1..32) only because I happen to know that that's all that's necessary until numbers in the Fibonacci sequence begin to exceed 4,000,000. I would prefer that this be built into the one-line somehow, but I haven't been able to figure it out.

Semi-colons are not allowed!

• I think it's subverting the spirit of your challenge a bit if the "one-liner" solutions include multiple blocks. I mean, you could do a Java one-liner the same way, if you didn't mind having a line that was 500 characters long and completely unreadable. Jun 20, 2011 at 23:07
• It's nothing to do with Ruby specifically, that's just the language I'm learning. It's just for fun.
– clem
Jun 20, 2011 at 23:16
• @aroth, Chaining blocks in Ruby is as natural as an assignment with multiple arithmetic operators. For a one-liner which bends the spirit of the rules more, see my solution: the semicolons are a dead givaway. Jun 21, 2011 at 0:26
• @Wayne - If chaining blocks in Ruby is always done by using a single line of code, then all I can say is ugh...I will never understand why seeming rational people take a practice that needlessly obfuscates code and make it "natural". Part of the design philosophy behind Ruby as a language was that it should be easy for a human to read and understand, and of your two example solutions the multi-line one is by far the most readable. Jun 21, 2011 at 0:40
• @aroth, I agree. I don't chain blocks on one line unless it's more readable. Sometimes it is, often it isn't. The one-liner in my example is because the OP asked for it, not because it's what I'd write. That said, writing one-liners is a valid exercise, like a musician playing musical scales. You wouldn't write one liners in production code, nor would you play musical scales in a concert. Jun 21, 2011 at 1:12

My favorite solution to this is to use a Hash, the values of which can be determined by an anonymous function:

fibonacci = Hash.new{ |h,k| h[k] = k < 2 ? k : h[k-1] + h[k-2] }

fibonacci[6]  # => 8
fibonacci[50] # => 12586269025

It's a "genuine" one-liner and very Ruby-ish.

• Very clever! But you're using a colon - isn't that twice as bad as using a semicolon? Aug 10, 2011 at 22:29
• Bravo! You get automagic memoization by using the hash to drive the function. This is elegance! Aug 20, 2012 at 2:24
• fibonacci[2299] # => stack level too deep (SystemStackError) Dec 14, 2013 at 21:14
• I'd like to highlight the performace difference between both approaches. Hash: codefibonacci = Hash.new{ |h,k| h[k] = k < 2 ? k : h[k-1] + h[k-2] } puts fibonacci[30] 832040 [Finished in 0.1s] code Lambda: code fibo = lambda { |x| (x<2) ? x : fibo.call(x-1) + fibo.call(x-2) } 832040 [Finished in 1.7s] code Sep 28, 2014 at 20:08
• Without a colon: fib = Hash.new { |fib, n| fib[n] = fib[n - 1] + fib[n - 2] }.merge!(0 => 0, 1 => 1) Nov 22, 2015 at 0:52

Using a Ruby 1.9 Enumerator:

fib = Enumerator.new do |yielder|
i = 0
j = 1
loop do
i, j = j, i + j
yielder.yield i
end
end

p fib.take_while { |n| n <= 4E6 }
# => [1, 1, 2 ... 1346269, 2178309, 3524578]

As one line:

p Enumerator.new { |yielder| i, j = 0, 1; loop {i, j = j, i + j; yielder.yield i} }.take_while { |n| n <= 4E6}
• A while ago I found out about the strange construct i=j+j=i. It's the same thing as i, j = j, i + j. Jan 29, 2013 at 19:43
• @Jonas, Did you mean j = i + i = j? It's an interesting construct! It's not one I'd like to use in production code, but a good one for thinking about how Ruby works. Thank you for pointing it out. Jan 29, 2013 at 20:12
• I wouldn't use it in production code either and me confusing them is a good indicator of why. Jan 30, 2013 at 12:28

# Ruby 1.8.7
f = lambda { |x| x < 2 ? x : f.call(x-1) + f.call(x-2) }
puts f.call(6)   #=> 8

# Ruby 1.9.2
f = ->(x){ x < 2 ? x : f[x-1] + f[x-2] }
puts f[6]        #=> 8
• fib = ->(n, i=0, j=1){(1..n).map{i=j+j=i}} Call it with fib[7] Jan 29, 2013 at 19:35
• I missed that the answer should be the n:th Fibonacci number and not the sequence itself. Here's another silly lambda for that fib = ->(n, i=0, j=1){n.times{i=j+j=i};i} Since i=j+j=i is such a quirky construct I don't think it deserves being an answer. Jan 30, 2013 at 12:36
• It's an offensive way to exploit operator precedence order. Try this is irb. i=0;j=1 then run i=j+j=i; puts "i:#{i}, j:#{j}" a couple of times. Oct 18, 2013 at 7:53
• i=j+j=i is evaluated from left to right. Starting point i=0;j=1. First i will be set to 1 + 0 since = precedes +. Now i=1;j=0. i will be set to 0 + 1. We arrive at i=1;j=1. i will be set to 1 + 1. i=2;j=1. i will be set to 1 + 2. i=3;j=2. i will be set to 2 + 3. i=5;j=3 and so on, thus producing the Fibonacci sequence. Oct 18, 2013 at 8:04
• @MikeH-R ...and the ;i is synonym for ; return i. Oct 18, 2013 at 11:30

My favorite is:

def fib(n)
(0..n).inject([1,0]) { |(a,b), _| [b, a+b] }[0]
end

(((1 + 5 ** 0.5) / 2) ** 35 / 5 ** 0.5 - 0.5).to_i / 2

(See this answer for an explanation.)

• I like this solution, but wouldn't you have to know the significance of why you are using 35? Given the Euler project questions, you really only know the number 4000000 and to sum the even numbers. Dec 23, 2012 at 3:59
• @pjammer: 35 can be replaced with (Math.log(4000000 * 5 ** 0.5, (1 + 5 ** 0.5) / 2) + 2).to_i, if you like. Jan 5, 2013 at 13:06

Here's a ruby 2.0 solution, without using inject/reduce which is not lazy:

(1..Float::INFINITY).
lazy.
with_object([0,1]).
map { |x, last| last[1] = last[0] + (last[0] = last[1]) }.
select { |x| x % 2 == 0 }.
take_while { |x| x < 4_000_000 }.
reduce(&:+)

I don't particularly like the fibonacci generator, because it doesn't include the initial 0. This solution also takes advantage of the first odd number being F3 (F1 in this sequence generator).

A cleaner (Fibonacci-wise) and correct (In Liber Abaci's definition) solution would be:

(1..Float::INFINITY).
lazy.
with_object([0,1]).
map { |x, last| last[1] = last[0] + (last[0] = last[1]);last[0] }.
select { |x| x % 2 == 0 }.
take_while { |x| x < 4_000_000 }.
reduce(&:+)

This solution includes a semi-colon, but I don't know if it counts when used this way :).

[Update]

Here's a proper Fibonacci generator (starting on 0) solution, with no semi-colon (btw, is this a javascript semi-colon wars thingy ?!?) :)

(1..Float::INFINITY).
lazy.
with_object([0,1]).
map { |x, last| last[0].tap { last[1] = last[0] + (last[0] = last[1]) } }.
select { |x| x % 2 == 0 }.
take_while { |x| x < 4_000_000 }.
reduce(&:+)

Building on Alex's Hash, this may make you go blind, but it's one line, no semicolons and eliminates the range dependency. the instance_eval trick is very useful for oneliners and golf, although it's horrible Ruby.

Hash.new{|h,k|h[k]=k<2?k:h[k-1]+h[k-2]}.update(sum: 0,1=>1).instance_eval {self[:sum]+= self[keys.last+1].even? ? self[keys.last] : 0 while values.last < 4E6 || puts(fetch :sum)}

Outputs: 4613732

I warned you it was horrible. I can't make it actually return the value without using a semicolon, sorry.

I realize this is an ancient question and has been classed as answered but no-one manages to solve the question in one block, none of them actually give the sum of the even valued terms in one line and in one block and with no semi colons (just noticed that waynes does solve with one line but I thought a one block solution might be nice in response to aroth). here is a solution that does:

(1..Float::INFINITY).inject([0,1,0]){|a| if a[0]+a[1] < 4000000 then [a[1],a[0]+a[1],(a[0]+a[1]).even? ? a[2] + (a[0]+a[1]) : a[2]] else break a[2] end }

for a slightly clearer version with one semi colon.

(1..Float::INFINITY).inject([0,1,0]){|a| sum=a[0]+a[1]; if sum < 4000000 then [a[1],sum,sum.even? ? a[2] + sum : a[2]] else break a[2] end }

I figure I'll explain it too, three pieces of information get carried forward in the array (as a at each iteration) the first fibonacci number, the second fibonacci number and the sum of the even terms. bearing this in mind I think this code is quite clear ruby.

it should be noted that this is basically the same as clems except in one block

• And afaik it seems to be efficient and memoises the information without storing too much of it (so both speed and memory efficient) Jun 25, 2013 at 12:36
• +1 for pointing out what the rest of missed: We were so focused on the fib. generator that we forgot to add that last bit that the OP asked for. Feb 14, 2016 at 12:57
puts (1..20).inject([0, 1]){|Fibonacci| Fibonacci << Fibonacci.last(2).inject(:+) }

This is the best solution I ever had used to print the Fibonacci series using inject keyword. Explanation: 1) .inject([0,1]) will hold the default value (0) first value of collection (1) element of the series. 2) At first Fibonacci object will have 0, 1 using Fibonacci.last(2) that will be passed through inject 3) .inject(:+) will add the 0+1 4) This will add 0+1 = 1 and then will be pushed to Fibonacci which on next iteration with outer inject([0,1]) will become inject(1,2) here 1 is the value after sum (0+1) and 2 is the next iteration value of collection. and so on till the end of collection

So the series will be like

0
1
1
2
3
5
8
13
21
34
55
89
144
233
377
610
987
1597
2584
4181
6765
10946

I can think of 4 ways for now to achieve the fibonacci goal!

1. Using a stabby lambda:
puts 'Fibonacci Sequence in a Line: ', ->(a=1, b=0) { 10.times.collect { (a, b = b, a + b)[0] } }.call

This evaluates 10 series. But if you want to get the user's number:

puts 'Fibonacci Sequence in a Line: ', ->(a=1, b=0) { gets.to_i.times.collect { (a, b = b, a + b)[0] } }.call
1. Using the tap method:
[0, 1].tap { |a| 10.times { a.push(a[-1] + a[-2]) } }
1. Using the reduce / inject method:
(1..10).reduce([0, 1]) { |a| a.push(a.last(2).sum) }

or

10.times.reduce([0, 1]) { |a| a.push(a.last(2).sum) }
1. Using the each_with_object or map.with_object method:
10.times.each_with_object([0, 1]) { |_, a| a.push(a.last(2).sum) }

Note: If you don't have Ruby 2.4+ you may not have the sum method. In that case, you can add the last two elements with ary[-2] + ary[-1] or ary.last(2).reduce(:+).

By considering the terms in the Fibonacci sequence whose values do not exceed four million, find the sum of the even-valued terms.

[0, 1].tap { |a| until (s = a.last(2).sum) > 4_000_000 do a.push(s) end }.select(&:even?).sum

Or (which is not that great):

[0, 1].tap { |a| loop while a.push(a.last(2).sum)[-1] < 4_000_000 }.tap(&:pop).select(&:even?).sum

Outputs: 4613732

Hope this helps!

Returns correct values up to Fib(70), beyond that just an approximation. But extremely fast:

(((Math.sqrt(5.0) + 1.0) / 2.0)**n / Math.sqrt(5.0) + 0.5).floor

(see https://en.wikipedia.org/wiki/Fibonacci_number#Computation_by_rounding for explanation)

With the new lazy in ruby 2.0, you can write like this.

puts (1..Float::INFINITY).lazy.map{|n| (0..n).inject([1,0]) {|(a,b), _| [b, a+b]}[0] }.take_while{|n| n < 4000000}.select{|x| x % 2 == 0}.reduce(:+)

As a summarizing solution for the answers above, with my humble additions:

32.
times.
lazy.
with_object([0, 1]).map { |_, fib| fib[1] = fib[0] + fib[0] = fib[1]; fib[0] }.
take_while(&:>.to_proc.curry(2)[4*10**6]).
select(&:even?).
inject(:+)

I don't really like how currying looks, but didn't want it to look similar to other answers. Alternative take_while just for the case:

take_while { |value| value < 4*10**6 }.

Here's a one line ruby solution to Euler prob #2

(0..4000000).take_while{|i| (0..i).reduce([1,0]){|(a,b), _| [b, a+b]}[0] <= 4000000 }.map{|i| (0..i).reduce([1,0]){|(a,b), _| [b, a+b]}[0] }.select{|i| i%2 == 0}.reduce(:+)

(0..4000000) .
take_while {|i| (0..i).reduce([1,0]){|(a,b), _| [b, a+b]}[0] <= 4000000} .
map {|i| (0..i).reduce([1,0]){|(a,b), _| [b, a+b]}[0]} .
select {|i| i%2 == 0} .
reduce(:+)

(1..32).inject([0, 1]) { |fib| fib << fib.last(2).inject(:+) }

Here is my one liner, with the @fib table being populated as we get the method returns..

@fib=[0,1];def fib num; return 0 if num < 0; @fib[num]||=fib(num-1)+fib(num-2);end

Simple and elegant is the best way, right?

a0 = 1; a1 = 1; 20.times {|i| b = a0 + a1; a0 = a1; a1 = b; puts b };

Output:

2
3
5
8
13
21
34
55
89
144
233
377
610
987
1597
2584
4181
6765
10946
17711
=> 20