I can never remember the number. I need a memory rule.

48unsigned: 2³²1 = 4·1024³1; signed: 2³¹ .. +2³¹1, because the signbit is the highest bit. Just learn 2⁰=1 to 2¹⁰=1024 and combine. 1024=1k, 1024²=1M, 1024³=1G – comonad Mar 28 '11 at 20:01

31I generally remember that every 3 bits is about a decimal digit. This gets me to the right order of magnitude: 32 bits is 10 digits. – Barmar Oct 2 '13 at 15:11

8@JoachimSauer it can certainly help debugging if you learn to at least recognize these kinds of numbers. – Dunaril Nov 13 '13 at 16:38

72"if a disk becomes full, deleting all mbytes will archive" (2 letters, 1 letter, 4 letters, 7 letters, 4 letters, 8 letters, 3 letters, 6 letters, 4 letters, 7 letters) – UltraCommit Mar 11 '14 at 14:30

8A case, when the int32 is not enough: bbc.com/news/worldasia30288542 – ingaham Dec 4 '14 at 20:14
With Groovy on the path:
groovy e " println Integer.MAX_VALUE "
(Groovy is extremely useful for quick reference, within a Java context.)
2147483647
Here's what you need to remember:
 It's 2 billion.
 The next three triplets are increasing like so: 100s, 400s, 600s
 The first and the last triplet need 3 added to them so they get rounded up to 50 (eg 147 + 3 = 150 & 647 + 3 = 650)
 The second triplet needs 3 subtracted from it to round it down to 80 (eg 483  3 = 480)
Hence 2, 147, 483, 647
I made a couple genius methods in C# that you can take advantage of in your production environment:
public static int GetIntMaxValueGenius1()
{
int n = 0;
while (++n > 0) { }
return n;
}
public static int GetIntMaxValueGenius2()
{
int n = 0;
try
{
while (true)
n = checked(n + 1);
}
catch { }
return n;
}

1I was thinking of some kind of method that would guess trillions of random integers, and return the highest one. – Slothario Jan 9 '19 at 21:55
Just remember that it's the eighth Mersenne prime.
If that's too hard, it's also the third of only four known double Mersenne primes.
Edit per comment request:
The EuclidEuler theorem states that every even perfect number has the form 2^(n − 1) (2^n − 1), where 2^n − 1 is a prime number. The prime numbers of the form 2^n − 1 are known as Mersenne primes, and require n itself to be prime.
We know that the length of an INT32 is of course 32 bits. Given the generally accepted understanding of 2's complement, a signed INT32 is 32 bits  1 bit.
To find the magnitude of a binary number with a given number of bits we generally raise 2 to the power n, minus 1, where n is equal to the number of bits.
Thus the magnitude calculation is 2^(32  1)  1 = 2^31  1. 31 is prime and as outlined above, prime numbers of this form are Mersenne primes. We can prove it is the eight of such simply by counting them. For further details, please ask Euler, or maybe Bernoulli (to whom he wrote about them).

Any Reference you could link to...? (Directly, without having to google/wikipediaze...) – chivracq Aug 29 '18 at 3:40
This is how I remember...
In hex, a digit represents four bits, so 4 * 8 = 32, so the max signed 32 bit int is:
0xFFFFFFFF >> 1 # => 2147483647

This would probably work. I wish the guy that downvoted you would give you an explanation. – Joe Plante Aug 15 '13 at 17:41

3@JoePlante The question asker was asking for a way that he, as a human, could memorize the number (as in, its decimal digits). I don't know about you, but parsing hexadecimal and then bit shifting isn't an intuitive operation on my mental hardware. If you're going to take this approach, you might as well just calculate 2^311. – Mark Amery Aug 27 '13 at 19:56

The question I was answering was "What is the maximum value for a int32?" I do see your point @MarkAmery, but remembering to type this line into an interpreter or into a print statement is actually how I remember the numbers. It also works as a general pattern for other sizes. Thank you for the support @JoePlante! – Sean Vikoren Aug 28 '13 at 22:57

No problem. After 16 bits, I simply stopped memorizing because you can always look it up. 0xFFFFFFFF >> 1 I feel is correct in a lot of cases because if you need to go to 64 bits, 0xFFFFFFFFFFFFFFFF >> 1 also works. 0xFFFF >> 1 and 0xFF >> 1 also works. I'm not sure if this works in languages with signed values or not, but still I feel it's viable – Joe Plante Sep 1 '13 at 14:20
To never forget the maximum value of any type:
If it has 32 bits, the largest possible value would be the 32 bits with the number 1:
The result would be 4294967295 in decimal:
But, as there is also the representation of negative numbers, divide 4294967295 by 2 and get 2147483647.
Therefore, a 32bit integer is capable of representing 2147483647 to 2147483647

You can, you know, just get 2^31 (which is indeed also how it is stored in ram one bit for positive/negative flag and 31 bits for the number), which will automatically be the half. And subtract one for the number zero (in your case you get 2147483647.5, not 2147483647 as you don't account for that). – Ave May 6 '17 at 9:46
It is very easy to remember. In hexadecimal one digit is 4 bits. So for unsigned int write 0x
and 8 f
s (0xffffffff
) into a Python or Ruby shell to get the value in base 10. If you need the signed value, just remember that the highest bit is used as the sign. So you have to leave that out. You only need to remember that the number where the lower 3 bits are 1 and the 4th bit is 0 equals 7, so write 0x7fffffff
into a Python or Ruby shell. You could also write 0x100000000  1
and 0x80000000  1
, if that is more easy to you to remember.
You will find in binary the maximum value of an Int32 is 1111111111111111111111111111111 but in ten based you will find it is 2147483647 or 2^311 or Int32.MaxValue
Using Java 9's REPL, jshell:
$ jshell
 Welcome to JShell  Version 9Debian
jshell> System.out.println(Integer.MAX_VALUE)
2147483647
In C use INT32_MAX
after #include <stdint.h>
.
In C++ use INT32_MAX
after #include <cstdint>
.
Or INT_MAX
for platformspecific size or UINT32_MAX
or UINT_MAX
for unsigned int
. See http://www.cplusplus.com/reference/cstdint/ and http://www.cplusplus.com/reference/climits/.
Or sizeof(int)
.
In general you could do a simple operation which reflects the very nature of a Int32, fill all the available bits with 1's  That is something which you can hold easily in your memory. It works basically the same way in most languages, but i'm going with Python for the example:
max = 0
bits = [1] * 31 # Generate a "bit array" filled with 1's
for bit in bits:
max = (max << 1)  bit
# max is now 2147483647
For unsigned Int32's, make it 32 instead of 31 1's.
But since there are posted a few more adventurous approaches, i began to think of formulas, just for the fun of it...
Formula 1 (Numbers are concatenated if no operator is given)
 a = 4
 b = 8
 ba/a
 ab1
 ab
 abab
 ab1
Python quickcheck
a = 4
b = 8
ab = int('%d%d' % (a, b))
ba = int('%d%d' % (b, a))
'%d%d%d%d%d' % (ba/a, ab1, ab, abab, ab1)
# gives '2147483647'
Formula 2
 x = 48
 x/23
 x1
 x
 x*3/4
 x1
Python quickcheck
x = 48
'%d%d%d%d%d' % (x/23, x1, x, x*3/4, x1)
# gives '2147483647'
"If a huge integer isn't recalled, you recall this mnemonic."
Now count the letters in each word.
max_signed_32_bit_num = 1 << 31  1; // alternatively ~(1 << 31)
A compiler should optimize it anyway.
I prefer 1 << 31  1
over
0x7fffffff
because you don't need count f
s
unsigned( pow( 2, 31 ) )  1
because you don't need <math.h>

You can use underscores to improve the readability of some languages. Java and Swift support this from what I know, perhaps others.
0x7FFF_FFFF
– Alexander  Reinstate Monica Mar 18 '17 at 17:18
It's 2^{31} − 1 (32 bits, one is used for sign).
If you want an approximate value, use 2^{10} = 1024 ≈ 10^{3}, so 2^{31} ≈ 2*10^{9}. If you want to compute an exact value by hand, use exponentiation by squaring to get to 2^{32} = 2^{(25)} and divide by two. You only need to square five times to get 2^{32}:
2*2 = 4
4*4 = 16
16*16 = 256
256*256 = 25*25*100 + 2*250*6 + 36 = 62500 + 3000 + 36 = 65536
65536*65536 =65000*65000 + 2*65000*536 + 536*536 =
4225000000 + 130000*536 + (250000 + 3600 + 36*36) =
4225000000 + 69680000 + 250000 + 3600 + 1296 =
4294967296
dividing this by two and subtracting one gives you 2,147,483,647. If you don't need all digits, but only want say, the first three significant digits, the computations on each squaring step are very easy.