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In [[arithmetic]], the '''greatest common divisor (gcd)''' of several [[integer]]s is the largest number that is a [[divisor]] of all of them.
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For example, the divisors of 60 are
The '''greatest common divisor''' (often abbreviated to '''gcd''', or '''g.c.d.''',
sometimes also called '''highest common factor''') of two or more [[natural number]]s
is the largest number which divides evenly both (or all) the numbers. Since 1 divides all numbers, and since a divisor of a number cannot be larger than that number, the greatest common divisor of some numbers is a number between 1 and the smallest of the numbers inclusive, and therefore can be determined (at least in principle) by testing finitely many numbers.


: 1, 2, 3, 4, 5, 6, 10, 12, 15, 20, 30, 60,
Numbers for which the greatest common divisor is 1 are called '''relatively prime'''.
If (for three or more numbers) any two of them are relatively prime, they are called '''pairwise relatively prime'''.


and the divisors of 72 are
The greatest common divisor of two numbers ''a'' and ''b''
usually is written as gcd(''a'',''b''), or, if no confusion is to be expected, simply as (''a'',''b'').


: 1, 2, 3, 4, 6, 8, 9, 12, 18, 24, 36, 72.
{{TOC|right}}


The '''common divisors''' of 60 and 72 are the numbers that appear in both lists:
== Finding the greatest common divisor ==


: 1, 2, 3, 4, 6, 12.
A theoretically important method to determine the greatest common divisor uses [[prime factorization]]:
Every prime factor of a common divisor must be a prime factor of all the numbers.
The greatest common divisor therefore is the product of all common prime factors
taken with the highest power common to all the numbers.
However, since prime factorization is not efficient,
this is at most practical for small numbers (or for numbers whose factorization is already known).
This product expression shows that the greatest common divisor can be characterized by the following property:
The gcd is a common divisor, and every common divisor divides it evenly.


The '''greatest common divisor''' of 60 and 72 is therefore 12.  One writes "gcd(60, 72) = 12.
Fortunately, the [[Euclidean algorithm]] provides an efficient means to calculate the greatest common divisor.
It also shows that the greatest common divisor can be expressed
as an integer linear combination of the numbers  (''a'',''b'') = ''ra'' + ''sb'' (with integers ''r'' and ''s'').
Since every such linear combination is divisible by all divisors common to
''a'' and ''b'', this, in turn, shows that it is the ''smallest'' positive linear combination,
and therefore (in the language of [[ring theory]])
the ideal generated by ''a'' and ''b'' is a principal ideal generated by (''a'',''b'').


The greatest common divisor is used in reducing fractions to lowest terms, thus:
== Examples ==


:<math>\frac{60}{72} = \frac{12 \times 5}{12 \times 6} = \frac{5}{6}.</math>
For instance,


== An algorithm involving prime factorizations ==
* (4,9) = 1, (4,6) = 2, and (4,12) = 4, because
:: the divisors of 4 for are '''1''',2,4; the divisors of 9 are '''1''',3,9; and the only common divisor and the gcd '''1''';
:: the divisors of 4 for are 1,'''2''',4; the divisors of 6 are 1,'''2''',3,6; the common divisors are 1 and '''2''', and the gcd is '''2''';
:: the divisors of 4 for are 1,2,'''4'''; the divisors of 12 are 1,2,3,'''4''',6,12; the common divisors are 1,2,'''4''', and the gcd is '''4'''.


One method of finding the greatest common divisor of two integers involves factoring both into [[prime number]]s:
* (72,108) = 36 because
:: the prime factorizations 72 = '''2''' • '''2''' • 2 • '''3''' • '''3''' and 108 = '''2''' • '''2''' • '''3''' • '''3''' • 3 have the common factors '''2''' • '''2''' • '''3''' • '''3''' = 36.


:<math> 60 = 2 \times 2 \times 3 \times 5,\,</math>
* 6, 10, and 15 are ''relatively prime'', but not ''pairwise'' relatively prime, because
==
:: gcd(6,10,15) = 1, but (6,10) = 2, (6,15) = 3, (10,15) = 5, as can be seen either
::: from the prime factorizations 6 = 2 3, 10 = 2 • 5, 15 = 3 • 5 in which no prime occurs in all three products, or
::: from the lists of divisors: 1,2,3,6 for 6, and 1,2,5,10 for 10, and 1,3,5,15 for 15.


:<math> 72 = 2 \times 2 \times 2 \times 3 \times 3.\,</math>
* 7, 9, and 10 are ''relatively prime'', but not ''pairwise'' relatively prime, because
:: gcd(4,9,10) = 1, but (4,10) = 2 even though two pairs are (4,9) = (9,10) = 1 are relatively prime.


Observe that the prime number 2 occurs twice in the factorization of 60, and three times in the factorization of 72.  One says that the ''multiplicity'' of that prime factor is 2 in the first case and 3 in the second.  For each prime factor, and sees which multiplicity is ''smaller'': the one in the factorization of 60 or the one in the factorization of 72:
* 7, 9, 10 are ''pairwise relatively prime'', and therefore also relatively prime
:: because (7,9) = (7,10) = (9,10) = (7,9,10) = 1.


: In the factorization of 60, the multiplicity of the prime factor 2 is 2.
''See also the [[/Tutorials|Tutorial]].''
: In the factorization of 72, the multiplicity of the prime factor 2 is 3.
: The smaller of those multiplicities is 2.


Next:
== Applications ==


: In the factorization of 60, the multiplicity of the prime factor 3 is 1.
In elementary arithmetic, the greatest common divisor is used to simplify expressions
: In the factorization of 72, the multiplicity of the prime factor 3 is 2.
by reducing the size of numbers involved,  
: The smaller of those multiplicities is 1.
e.g., given some fraction ''p''/''q'', then  ''p''/(''p'',''q'') / ''q''/(''p'',''q'') is its reduced representation.
For instance:
: The reduced form of 9/12 is 3/4 because (9,12) = 3.
Similarly, equations can be simplified:
: The quadratic equation 9''x''<sup>2</sup> + 12''x'' = 0 is equivalent to 3''x''<sup>2</sup> + 4''x'' = 0.
Moreover, the gcd can be used to calculate the [[least common multiple]]:
lcm(''a'',''b'') = ''ab''/gcd(''a'',''b''):
: lcm(9,12) = 9•12 / gcd(9,12) = 108/3 = 36


Next:
== Generalizations ==


: In the factorization of 60, the multiplicity of the prime factor 5 is 1.
The notion of [[divisibility]] can be generalized to the context of rings,
: In the factorization of 72, the multiplicity of the prime factor 5 is 0.
the idea of a greatest common divisor, however, is not always applicable.
: The smaller of those multiplicities is 0.
<br>
But in [[Euclidean rings]],
i.e., in rings for which there is an analogue to the Euclidean algorithm,
a greatest common divisor does exist.
An important example is the ring of [[polynomial]]s:
The greatest common divisor of two polynomials is a common factor of greatest degree.
In this case the gcd is only unique up to a constant factor.
<br>
More generally, a greatest common divisor can be defined for rings with unique prime factorization.


: All other prime numbers have multiplicity 0 in the factorization of both 60 and 72.
== Formulas ==
: The smaller of those two multiplicities (both 0) is 0.


Therefore
; Bounds :  <math> 1 \le \mathop{\rm gcd} (a,b) \le \min(a,b) </math>


: the multiplicity of 2 in the factorization of the gcd is 2;
; gcd and lcm : <math> \mathop{\rm gcd} (a,b) \mathop{\rm lcm} (a,b) = ab </math>
: the multiplicity of 3 in the factorization of the gcd is 1;
: the multiplicity of any other prime number in the factorization of the gcd is 0.


The gcd is therefore 2&nbsp;&times;&nbsp;2&nbsp;&times;&nbsp;3 = 12.
; prime factor representation : <math> a = \prod_{p\ \rm prime} p^{a(p)} \ \textrm{\ and\ }\ b = \prod_{p\ \rm prime} p^{b(p)} \ \Rightarrow \ \mathop{\rm gcd}(a,b) = \prod_{p\ \rm prime} p^{\min(a(p),b(p))} </math>[[Category:Suggestion Bot Tag]]
 
Here is another example: the problem is to find gcd(14280,&nbsp;1638).  We have
 
: 14280 = 2 &times; 2 &times; 2 &times; 3 &times; 5 &times; 7 &times; 17.
: 1638 = 2 &times; 3 &times; 3 &times; 7 &times; 13.
 
For the prime number 2, the multiplicities are 3 and 1; the smaller of those is 1.
 
For the prime number 3, the multiplicities are 1 and 2; the smaller of those is 1.
 
For the prime number 5, the multiplicities are 1 and 0; the smaller of those is 0.
 
And so on&mdash;for all larger prime numbers the multiplicity is 0.
 
Therefore gcd(14280,&nbsp;1638) = 2 &times; 3 = 6.
 
== An algorithm not involving prime numbers ==
 
When the prime factors of a number are large, the algorithm above may be inefficient.  [[Euclid's algorithm]] does not involve prime factorizations and runs fast in such cases.  It may be described as follows:
 
: (1) Replace the larger of the two numbers with the remainder on division of the larger by the smaller.
: (2) Repeat step (1) until one of the two numbers is 0.
: (3) The one that is not 0 is the gcd.

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The greatest common divisor (often abbreviated to gcd, or g.c.d., sometimes also called highest common factor) of two or more natural numbers is the largest number which divides evenly both (or all) the numbers. Since 1 divides all numbers, and since a divisor of a number cannot be larger than that number, the greatest common divisor of some numbers is a number between 1 and the smallest of the numbers inclusive, and therefore can be determined (at least in principle) by testing finitely many numbers.

Numbers for which the greatest common divisor is 1 are called relatively prime. If (for three or more numbers) any two of them are relatively prime, they are called pairwise relatively prime.

The greatest common divisor of two numbers a and b usually is written as gcd(a,b), or, if no confusion is to be expected, simply as (a,b).

Finding the greatest common divisor

A theoretically important method to determine the greatest common divisor uses prime factorization: Every prime factor of a common divisor must be a prime factor of all the numbers. The greatest common divisor therefore is the product of all common prime factors taken with the highest power common to all the numbers. However, since prime factorization is not efficient, this is at most practical for small numbers (or for numbers whose factorization is already known). This product expression shows that the greatest common divisor can be characterized by the following property: The gcd is a common divisor, and every common divisor divides it evenly.

Fortunately, the Euclidean algorithm provides an efficient means to calculate the greatest common divisor. It also shows that the greatest common divisor can be expressed as an integer linear combination of the numbers (a,b) = ra + sb (with integers r and s). Since every such linear combination is divisible by all divisors common to a and b, this, in turn, shows that it is the smallest positive linear combination, and therefore (in the language of ring theory) the ideal generated by a and b is a principal ideal generated by (a,b).

Examples

For instance,

  • (4,9) = 1, (4,6) = 2, and (4,12) = 4, because
the divisors of 4 for are 1,2,4; the divisors of 9 are 1,3,9; and the only common divisor and the gcd 1;
the divisors of 4 for are 1,2,4; the divisors of 6 are 1,2,3,6; the common divisors are 1 and 2, and the gcd is 2;
the divisors of 4 for are 1,2,4; the divisors of 12 are 1,2,3,4,6,12; the common divisors are 1,2,4, and the gcd is 4.
  • (72,108) = 36 because
the prime factorizations 72 = 22 • 2 • 33 and 108 = 2233 • 3 have the common factors 2233 = 36.
  • 6, 10, and 15 are relatively prime, but not pairwise relatively prime, because
gcd(6,10,15) = 1, but (6,10) = 2, (6,15) = 3, (10,15) = 5, as can be seen either
from the prime factorizations 6 = 2 • 3, 10 = 2 • 5, 15 = 3 • 5 in which no prime occurs in all three products, or
from the lists of divisors: 1,2,3,6 for 6, and 1,2,5,10 for 10, and 1,3,5,15 for 15.
  • 7, 9, and 10 are relatively prime, but not pairwise relatively prime, because
gcd(4,9,10) = 1, but (4,10) = 2 even though two pairs are (4,9) = (9,10) = 1 are relatively prime.
  • 7, 9, 10 are pairwise relatively prime, and therefore also relatively prime
because (7,9) = (7,10) = (9,10) = (7,9,10) = 1.

See also the Tutorial.

Applications

In elementary arithmetic, the greatest common divisor is used to simplify expressions by reducing the size of numbers involved, e.g., given some fraction p/q, then p/(p,q) / q/(p,q) is its reduced representation. For instance:

The reduced form of 9/12 is 3/4 because (9,12) = 3.

Similarly, equations can be simplified:

The quadratic equation 9x2 + 12x = 0 is equivalent to 3x2 + 4x = 0.

Moreover, the gcd can be used to calculate the least common multiple: lcm(a,b) = ab/gcd(a,b):

lcm(9,12) = 9•12 / gcd(9,12) = 108/3 = 36

Generalizations

The notion of divisibility can be generalized to the context of rings, the idea of a greatest common divisor, however, is not always applicable.
But in Euclidean rings, i.e., in rings for which there is an analogue to the Euclidean algorithm, a greatest common divisor does exist. An important example is the ring of polynomials: The greatest common divisor of two polynomials is a common factor of greatest degree. In this case the gcd is only unique up to a constant factor.
More generally, a greatest common divisor can be defined for rings with unique prime factorization.

Formulas

Bounds
gcd and lcm
prime factor representation