refactored some old solutions

2014-12-04 16:50:52 -08:00 · 2014-12-04 16:50:52 -08:00 · a9d1671150
parent b8ab94b533
commit a9d1671150
10 changed files with 46 additions and 95 deletions
--- a/.gitignore
+++ b/.gitignore
@ -0,0 +1 @@
 .DS_Store
--- a/euler.rb
+++ b/euler.rb
@ -6,14 +6,18 @@ class Integer
  end
  def divisors
-    divisors = []
+    [].tap do |divisors|
-    (1..Math.sqrt(self).to_i).each do |num|
+      (1..Math.sqrt(self).to_i).each do |num|
-      if self % num == 0
+        if self % num == 0
-        divisors << num
+          divisors << num
-        divisors << self / num
+          divisors << self / num
        end
      end
    end
-    divisors
+  end
  def prime_factors
    self.prime_division.map(&:first)
  end
  def factorial
--- a/euler001.rb
+++ b/euler001.rb
@ -1,9 +1,7 @@
 def multiples_of_three_and_five_below(n)
-  multiples = []
+  (3..n-1).select { |i| (i % 3 == 0) || (i % 5 == 0) }
  (3..n-1).each do |i|
    multiples << i if ((i % 3 == 0) || (i % 5 == 0))
  end
  multiples
 end
-puts multiples_of_three_and_five_below(1000).inject(:+)
+def solution
  multiples_of_three_and_five_below(1000).inject(:+)
 end
--- a/euler002.rb
+++ b/euler002.rb
@ -1,30 +1,16 @@
-def fibonacci(n)
+def even_fibonacci_up_to(n)
-  fibTable = []
+  Enumerator.new do |y|
-  if (n == 0) or (n == 1)
+    a = 0
-    return 1
+    b = 1
-  else
+    loop do
-    if fibTable.at(n-1) == nil
+      temp = b
-      fibTable.insert(n-1, fibonacci(n-1))
+      b = a + b
-      fib1 = fibTable.at(n-1)
+      a = temp
-    else
+      y << b
      fib1 = fibTable.at(n-1)
    end
-    if fibTable.at(n-2) == nil
+  end.take_while { |i| i < n }.select { |i| i.even? }
      fibTable.insert(n-2, fibonacci(n-2))
      fib2 = fibTable.at(n-2)
    else
      fib2 = fibTable.at(n-2)
    end
    return fib1 + fib2
  end
 end
-sum = 0
+def solution
-for i in 1..32
+  even_fibonacci_up_to(4000000).inject(:+)
  fib = fibonacci(i)
  if (fib%2) == 0
    sum += fib
  end
 end
 puts sum
--- a/euler003.rb
+++ b/euler003.rb
@ -1,38 +1,5 @@
-def sieve(n) 
+require_relative 'euler'
-  eSieve = (2..n).to_a
+
-  i = 0
+def solution
-  pbar = ProgressBar.new("sieving", n)
+  600851475143.prime_factors.max
  while i < Math.sqrt(n)
    j = i + 1
    while (j < eSieve.length)
      if (eSieve[j] > (i ** 2)) and ((eSieve[j] % eSieve[i]) == 0)
        eSieve.delete_at j
        pbar.inc
      end
      j += 1
    end
    i += 1
    pbar.set(i + (n-eSieve.length))
  end
  pbar.finish
  eSieve
 end
 eSieve = sieve(600851475143)
 def isPrime(n)
  eSieve.contains(n)
 end
 puts isPrime(7)
 factors = []
 for i in 1..600851475143
  if (600851475143 % i) == 0
    if isPrime(600851475143 % i)
      factors << i
    end
  end
 end
--- a/euler004.rb
+++ b/euler004.rb
@ -1,13 +1,13 @@
 require_relative 'euler'
 def products_of_three_digits
-  products = []
+  [].tap do |products|
-  (100..999).each do |i|
+    (100..999).each do |i|
-    (100..999).each do |j|
+      (100..999).each do |j|
-      products << i*j
+        products << i*j
      end
    end
  end
  products
 end
 def solution
--- a/euler005.rb
+++ b/euler005.rb
@ -1,22 +1,17 @@
 require_relative 'euler'
 require 'prime'
 def factorization_of_integer_divisible_by_all_integers_up_to(n)
  {}.tap do |factorization|
    (2..n).map do |i|
-      Prime.prime_division(i).map do |factor|
+      Prime.prime_division(i).map do |prime, exponent|
-        factorization[factor.first] = factor.last if (!factorization.include?(factor.first) || (factor.last > factorization[factor.first]))
+        factorization[prime] = exponent if (!factorization.include?(prime) || (exponent > factorization[prime]))
      end
    end
  end
 end
 def factors_to_int(factorization)
-  [].tap do |result|
+  factorization.map { |prime, exponent| prime ** exponent }.inject(:*)
    factorization.each do |prime, exponent|
      result << prime ** exponent
    end
  end.inject(:*)
 end
 def solution
--- a/euler006.rb
+++ b/euler006.rb
@ -6,10 +6,6 @@ def square_sums(n)
  (1..n).map { |i| i ** 2 }.inject(:+)
 end
 def difference(n)
  sum_squared(n) - square_sums(n)
 end
 def solution
-  difference(100)
+  sum_squared(100) - square_sums(100)
 end
--- a/euler008.rb
+++ b/euler008.rb
@ -1,7 +1,7 @@
 require_relative 'euler'
 def largest_consecutive_product(n, adjacent)
-  n.to_digit_list.each_cons(adjacent).map { |x| x.inject(&:*) }.max
+  n.to_digit_list.each_cons(adjacent).map { |x| x.inject(:*) }.max
 end
 def solution
--- a/euler016.rb
+++ b/euler016.rb
@ -1 +1,5 @@
-puts (2**1000).to_s.split("").map(&:to_i).inject(:+)
+require_relative 'euler'
 def solution
  (2**1000).to_digit_list.inject(:+)
 end