How to check if the binary representation of an integer is a palindrome?

Question

如何检查整数的二进制表示是否是回文？

Answer 1

Hopefully correct:

_Bool is_palindrome(unsigned n)
{
    unsigned m = 0;

    for(unsigned tmp = n; tmp; tmp >>= 1)
        m = (m << 1) | (tmp & 1);

    return m == n;
}

Answer 2

Since you haven't specified a language in which to do it, here's some C code (not the most efficient implementation, but it should illustrate the point):

/* flip n */
unsigned int flip(unsigned int n)
{
    int i, newInt = 0;
    for (i=0; i<WORDSIZE; ++i)
    {
        newInt += (n & 0x0001);
        newInt <<= 1;
        n >>= 1;
    }
    return newInt;
}

bool isPalindrome(int n)
{
    int flipped = flip(n);
    /* shift to remove trailing zeroes */
    while (!(flipped & 0x0001))
        flipped >>= 1;
    return n == flipped;
}

EDIT fixed for your 10001 thing.

Answer 3

Create a 256 lines chart containing a char and it's bit reversed char. given a 4 byte integer, take the first char, look it on the chart, compare the answer to the last char of the integer. if they differ it is not palindrome, if the are the same repeat with the middle chars. if they differ it is not palindrome else it is.

Answer 4

Plenty of nice solutions here. Let me add one that is not the most efficient, but very readable, in my opinion:

/* Reverses the digits of num assuming the given base. */
uint64_t
reverse_base(uint64_t num, uint8_t base)
{
  uint64_t rev = num % base;

  for (; num /= base; rev = rev * base + num % base);

  return rev;
}

/* Tells whether num is palindrome in the given base. */
bool
is_palindrome_base(uint64_t num, uint8_t base)
{
  /* A palindrome is equal to its reverse. */
  return num == reverse_base(num, base);
}

/* Tells whether num is a binary palindrome. */ 
bool
is_palindrome_bin(uint64_t num) 
{
  /* A binary palindrome is a palindrome in base 2. */
  return is_palindrome_base(num, 2);
}

Answer 5

int palidrome (int num) 
{ 
  int rev = 0; 
  num = number; 
  while (num != 0)
  { 
    rev = (rev << 1) | (num & 1); num >> 1; 
  }

  if (rev = number) return 1; else return 0; 
}

Answer 6

The following should be adaptable to any unsigned type. (Bit operations on signed types tend to be fraught with problems.)

bool test_pal(unsigned n)
{
  unsigned t = 0;

  for(unsigned bit = 1; bit && bit <= n; bit <<= 1)
    t = (t << 1) | !!(n & bit);

  return t == n;
}

Answer 7

    public static bool IsPalindrome(int n) {
        for (int i = 0;  i < 16; i++) {
            if (((n >> i) & 1) != ((n >> (31 - i)) & 1)) {
                return false;
            }
        }
        return true;
    }

Answer 8

bool PaLInt (unsigned int i, unsigned int bits)
{
    unsigned int t = i;
    unsigned int x = 0;
    while(i)
    {
        x = x << bits;        
        x = x | (i & ((1<<bits) - 1));
        i = i >> bits;
    }
    return x == t;
}

1. Call PalInt(i,1) for binary pallindromes
2. Call PalInt(i,3) for Octal Palindromes
3. Call PalInt(i,4) for Hex Palindromes

Answer 9

In JAVA there is an easy way if you understand basic binary airthmetic, here is the code:

    public static void main(String []args){
        Integer num=73;
        String bin=getBinary(num);
        String revBin=reverse(bin);
        Integer revNum=getInteger(revBin);

        System.out.println("Is Palindrome: "+((num^revNum)==0));

     }

     static String getBinary(int c){
         return Integer.toBinaryString(c);
     }

     static Integer getInteger(String c){
         return Integer.parseInt(c,2);
     }

     static String reverse(String c){
         return new StringBuilder(c).reverse().toString();
     }

Answer 10

#include <iostream>
#include <math.h>
using namespace std;
int main()
{
    unsigned int n = 134217729;
    unsigned int bits = floor(log(n)/log(2)+1);
    cout<< "Number of bits:" << bits << endl;
    unsigned int i=0;
    bool isPal = true;
    while(i<(bits/2))
    {
        if(((n & (unsigned int)pow(2,bits-i-1)) && (n & (unsigned int)pow(2,i))) 
                                         ||    
        (!(n & (unsigned int)pow(2,bits-i-1)) && !(n & (unsigned int)pow(2,i))))
        {
            i++;
            continue;
        }
        else
        {
            cout<<"Not a palindrome" << endl;
            isPal = false;
            break;
        }
}

    if(isPal)
        cout<<"Number is binary palindrome" << endl;
}

Answer 11

The solution below works in python:

def CheckBinPal(b): b=str(bin(b)) if b[2:]==b[:1:-1]: return True else: return False

where b is the integer

Answer 12

If you're using Clang, you can make use of some __builtin s.

bool binaryPalindrome(const uint32_t n) {
  return n == __builtin_bitreverse32(n << __builtin_clz(n));
}

One thing to note is that __builtin_clz(0) is undefined so you'll need to check for zero. If you're compiling on ARM using Clang (next generation mac), then this makes use of the assembly instructions for reverse and clz ( compiler explorer ).

clz     w8, w0
lsl     w8, w0, w8
rbit    w8, w8
cmp     w8, w0
cset    w0, eq
ret

x86 has instructions for clz (sort of) but not reversing. Still, Clang will emit the fastest code possible for reversing on the target architecture.

Answer 13

Javascript Solution

function isPalindrome(num) {
  const binaryNum = num.toString(2);
  console.log(binaryNum)
  for(let i=0, j=binaryNum.length-1; i<=j; i++, j--) {
    if(binaryNum[i]!==binaryNum[j]) return false;
  }
  return true;
}

console.log(isPalindrome(0))

Answer 14

I always have a palindrome function that works with Strings, that returns true if it is, false otherwise, eg in Java. The only thing I need to do is something like:

int number = 245;
String test = Integer.toString(number, 2);
if(isPalindrome(test)){
   ...
}

Answer 15

I think the best approach is to start at the ends and work your way inward, ie compare the first bit and the last bit, the second bit and the second to last bit, etc, which will have O(N/2) where N is the size of the int. If at any point your pairs aren't the same, it isn't a palindrome.

bool IsPalindrome(int n) {
    bool palindrome = true;
    size_t len = sizeof(n) * 8;
    for (int i = 0; i < len / 2; i++) {
        bool left_bit = !!(n & (1 << len - i - 1));
        bool right_bit = !!(n & (1 << i));
        if (left_bit != right_bit) {
            palindrome = false; 
            break;
        }
    }
    return palindrome;
}

Answer 16

A generic version:

#include <iostream>
#include <limits>
using namespace std;

template <class T>
bool ispalindrome(T x) {
    size_t f = 0, l = (CHAR_BIT * sizeof x) - 1;
    // strip leading zeros
    while (!(x & (1 << l))) l--;
    for (; f != l; ++f, --l) {
        bool left = (x & (1 << f)) > 0; 
        bool right = (x & (1 << l)) > 0;
        //cout <<  left << '\n';
        //cout <<  right << '\n';
        if (left != right) break;
    }
    return f != l;
}       

int main() {
    cout << ispalindrome(17) << "\n";
}

Answer 17

Sometimes it's good to report a failure too;

There are lots of great answers here about the obvious way to do it, by analyzing in some form or other the bit pattern. I got to wondering, though, if there were any mathematical solutions? Are there properties of palendromic numbers that we might take advantage of?

So I played with the math a little bit, but the answer should really have been obvious from the start. It's trivial to prove that all binary palindromic numbers must be either odd or zero. That's about as far as I was able to get with it.

A little research showed no such approach for decimal palindromes, so it's either a very difficult problem or not solvable via a formal system. It might be interesting to prove the latter...

Answer 18

I know that this question has been posted 2 years ago, but I have a better solution which doesn't depend on the word size and all,

int temp = 0;
int i = num;
while (1)
{ // let's say num is the number which has to be checked
    if (i & 0x1)
    {
        temp = temp + 1;
    }
    i = i >> 1;
    if (i) {
        temp = temp << 1;
    }   
    else   
    {
        break;
    }
}   

return temp == num;