255 (number)

← 254 255 256 →
← 250 251 252 253 254 255 256 257 258 259 → List of numbers; Integers; ← 0 100 200 300 400 500 600 700 800 900 →
Cardinal	two hundred fifty-five
Ordinal	255th; (two hundred fifty-fifth)
Factorization	3 × 5 × 17
Greek numeral	ΣΝΕ´
Roman numeral	CCLV
Binary	111111112
Ternary	1001103
Senary	11036
Octal	3778
Duodecimal	19312
Hexadecimal	FF16

255 (two hundred [and] fifty-five) is the natural number following 254 and preceding 256.

In mathematics[edit]

Its factorization makes it a sphenic number.^[1] Since 255 = 2⁸ – 1, it is a Mersenne number^[2] (though not a pernicious one), and the fourth such number not to be a prime number. It is a perfect totient number, the smallest such number to be neither a power of three nor thrice a prime.

Since 255 is the product of the first three Fermat primes, the regular 255-gon is constructible.

In base 10, it is a self number.

255 is a repdigit in base 2 (11111111), in base 4 (3333), and in base 16 (FF).

$\left\{{9 \atop 2}\right\}=255.$

In computing[edit]

255 is a special number in some tasks having to do with computing. This is the maximum value representable by an eight-digit binary number, and therefore the maximum representable by an unsigned 8-bit byte (the most common size of byte, also called an octet), the smallest common variable size used in high level programming languages (bit being smaller, but rarely used for value storage). The range is 0 to 255, which is 256 total values.

255=2^{8}-1={\mbox{FF}}_{16}=11111111_{2}

For example, 255 is the maximum value of

components in the 24-bit RGB color model, since each color channel is allotted eight bits;
any dotted quad in an IPv4 address; and
the alpha blending scale in Delphi (255 being 100% visible and 0 being fully transparent).

The use of eight bits for storage in older video games has had the consequence of it appearing as a hard limit in many video games. For example, in the original The Legend of Zelda game, Link can carry a maximum of 255 rupees.^[3] It was often used for numbers where casual gameplay would not cause anyone to exceed the number. However, in most situations it is reachable given enough time. This can cause many other peculiarities to appear when the number wraps back to 0, such as the infamous "kill screen" seen after clearing level 255 of Pac-Man.^[4]

This number could be interpreted by a computer as −1 if a programmer is not careful about which 8-bit values are signed and unsigned, and the two's complement representation of −1 in a signed byte is equal to that of 255 in an unsigned byte.

References[edit]

^ Sloane, N. J. A. (ed.). "Sequence A007304 (Sphenic numbers: products of 3 distinct primes.)". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation.
^ "PDF" (PDF). American Mathematical Society. Retrieved 12 March 2015.
^ Hoovler, Evan. "The History of Annoying Side-Quests in Videogames Archived 2010-04-10 at the Wayback Machine." GameSpy. 2009-12-04.
^ Clewett, James. "255 and Pac-Man". Numberphile. 2007-17-11.

[1] Sloane, N. J. A. (ed.). "Sequence A007304 (Sphenic numbers: products of 3 distinct primes.)". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation.

[ams-2] "PDF" (PDF). American Mathematical Society. Retrieved 12 March 2015.

[3] Hoovler, Evan. "The History of Annoying Side-Quests in Videogames Archived 2010-04-10 at the Wayback Machine." GameSpy. 2009-12-04.

[4] Clewett, James. "255 and Pac-Man". Numberphile. 2007-17-11.

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