# Algorithm to find the most significant bit [duplicate]

A friend of mine was asked at an interview the following question: "Given a binary number, find the most significant bit". I immediately thought of the following solution but am not sure if it is correct.

Namely, divide the string into two parts and convert both parts into decimal. If the left-subarray is 0 in decimal then the do binary search in the right subarray, looking for 1.

That is my other question. Is the most significant bit, the left-most 1 in a binary number? Can you show me an example when a 0 is the most significant bit with an example and explanation.

## EDIT:

There seems to be a bit of confusion in the answers below so I am updating the question to make it more precise. The interviewer said "you have a website that you receive data from until the most significant bit indicates to stop transmitting data" How would you go about telling the program to stop the data transfer"

• Which side the MSB is on depends on whether your CPU architecture is Big-endian or Little-endian. Jun 10, 2013 at 15:53
• Many platforms for a CountLeadingZero opcode that does this very fast. This is useful for division and log base 2 math. Jun 10, 2013 at 15:53
• Example: the number 0. Also, you need to specify how negative numbers are represented.
– rici
Jun 10, 2013 at 15:54
• Most chipsets have some sort of instruction to do this. Jun 10, 2013 at 16:12
• Way too complicated. In Java you test whether the most significant bit is set with if(x < 0) …. That’s all. Nov 20, 2013 at 13:15

You could also use bit shifting. Pseudo-code:

number = gets
bitpos = 0
while number != 0
bitpos++             # increment the bit position
number = number >> 1 # shift the whole thing to the right once
end
puts bitpos

if the number is zero, bitpos is zero.

• You mean while number != 0? (I don't think pseudocode should follow C's idiosyncrasies.) Jun 10, 2013 at 16:09
• @svick 0 = false and non-zero as true predates C i believe Jun 10, 2013 at 16:11
• I don't understand this pseudocode.. Care to explain what lines 3, 5 and 6 represent? Jun 10, 2013 at 16:11
• hahaha guess it's not as universal as I thought then... @user2398832 #3: while number != 0, #5: shift the number to the right by 1 bit, #6: output bitpos Jun 10, 2013 at 16:12
• @user2398832: more clear now? Jun 10, 2013 at 16:20

Finding the most significant bit in a word (i.e. calculating log2 with rounding down) by using only C-like language instructions can be done by using a rather well-known method based on De Bruijn sequences. For example, for a 32-bit value

unsigned ulog2(uint32_t v)
{ /* Evaluates [log2 v] */
static const unsigned MUL_DE_BRUIJN_BIT[] =
{
0,  9,  1, 10, 13, 21,  2, 29, 11, 14, 16, 18, 22, 25,  3, 30,
8, 12, 20, 28, 15, 17, 24,  7, 19, 27, 23,  6, 26,  5,  4, 31
};

v |= v >> 1;
v |= v >> 2;
v |= v >> 4;
v |= v >> 8;
v |= v >> 16;

return MUL_DE_BRUIJN_BIT[(v * 0x07C4ACDDu) >> 27];
}

However, in practice more simple methods (like unrolled binary search) usually work just as well or better.

The edited question is really quite different, though not very clear. Who are "you"? The website or the programmer of the program that reads data from the website? If you're the website, you make the program stop by sending a value (but what, a byte, probably?) with its most-significant bit set. Just OR or ADD that bit in. If you're the programmer, you test the most-significant bit of the values you receive, and stop reading when it becomes set. For unsigned bytes, you could do the test like

bool stop = received_byte >= 128;
or
bool stop = received_byte & 128;

For signed bytes, you could use

bool stop = received_byte < 0;
or
bool stop = received_byte & 128;

If you're not reading bytes but, say, 32bit words, the 128 changes to (1 << 31).

This is one approach (not necessarily the most efficient, though, especially if your platform has a single-instruction solution to find-first-one or count-leading-zeros or something similar), assuming twos complement signed integers and a 32-bit integer width.

int mask = (int)(1U<<31); // signed integer with only bit 32 set
while (! n & mask)        // n is the int we're testing against
mask >>= 1;             // take advantage of sign fill on right shift of negative number

If you want the bit position of that first one, simply add a integer counter that starts at 31 and gets decremented on each loop iteration.

One downside to this is if n == 0, it's an infinite loop, so test for zero beforehand.

If you are interested in a C/C++ solution you can have a look at the book "Matters Computational" by Jörg Arndt where you have these functions defined in section "1.6.1 Isolating the highest one and finding its index":

static inline ulong highest_one_idx(ulong x)
// Return index of highest bit set.
// Return 0 if no bit is set.
{
#if defined  BITS_USE_ASM
return  asm_bsr(x);
#else  // BITS_USE_ASM

#if  BITS_PER_LONG == 64
#define MU0 0x5555555555555555UL  // MU0 == ((-1UL)/3UL) == ...01010101_2
#define MU1 0x3333333333333333UL  // MU1 == ((-1UL)/5UL)   == ...00110011_2
#define MU2 0x0f0f0f0f0f0f0f0fUL  // MU2 == ((-1UL)/17UL)  == ...00001111_2
#define MU3 0x00ff00ff00ff00ffUL  // MU3 == ((-1UL)/257UL)  == (8 ones)
#define MU4 0x0000ffff0000ffffUL  // MU4 == ((-1UL)/65537UL) == (16 ones)
#define MU5 0x00000000ffffffffUL  // MU5 == ((-1UL)/4294967297UL) == (32 ones)
#else
#define MU0 0x55555555UL  // MU0 == ((-1UL)/3UL) == ...01010101_2
#define MU1 0x33333333UL  // MU1 == ((-1UL)/5UL)   == ...00110011_2
#define MU2 0x0f0f0f0fUL  // MU2 == ((-1UL)/17UL)  == ...00001111_2
#define MU3 0x00ff00ffUL  // MU3 == ((-1UL)/257UL)  == (8 ones)
#define MU4 0x0000ffffUL  // MU4 == ((-1UL)/65537UL) == (16 ones)
#endif

ulong r = (ulong)ld_neq(x, x & MU0)
+ ((ulong)ld_neq(x, x & MU1) << 1)
+ ((ulong)ld_neq(x, x & MU2) << 2)
+ ((ulong)ld_neq(x, x & MU3) << 3)
+ ((ulong)ld_neq(x, x & MU4) << 4);
#if  BITS_PER_LONG > 32
r += ((ulong)ld_neq(x, x & MU5) << 5);
#endif
return r;

#undef MU0
#undef MU1
#undef MU2
#undef MU3
#undef MU4
#undef MU5
#endif
}

where asm_bsr is implemented depending on your processor architecture

// i386
static inline ulong asm_bsr(ulong x)
// Bit Scan Reverse: return index of highest one.
{
asm ("bsrl %0, %0" : "=r" (x) : "0" (x));
return x;
}

or

// AMD64
static inline ulong asm_bsr(ulong x)
// Bit Scan Reverse
{
asm ("bsrq %0, %0" : "=r" (x) : "0" (x));
return x;
}

Go here for the code: http://jjj.de/bitwizardry/bitwizardrypage.html

EDIT:

This is the definition in the source for function ld_neq:

static inline bool ld_neq(ulong x, ulong y)
// Return whether floor(log2(x))!=floor(log2(y))
{ return ( (x^y) > (x&y) ); }

I tihnk this is kind of a trick question. The most significant bit is always going to be a 1 :-). If interviewers like lateral thinking, that answer should be a winner!

• Even if the interpretation was correct (I believe it isn't), the answer is wrong. Jun 10, 2013 at 16:00
• does that mean that my solution is correct? It has O(lgn) complexity since I'm doing a binary search. Jun 10, 2013 at 16:01
• @Stochastically no it isn't, it's like saying that the most significant digit in zero can't be a 1 because there is no 1 in zero Jun 10, 2013 at 16:13
• @harold zero is obviously a special case. For non-zero numbers, the most significant digit of a binary number is going to be a 1. But if the interpretation of the question is the position of the most significant digit, then something like the answer of Denis is what's needed. Jun 10, 2013 at 16:21
• Of course, no argument there. I don't think either the OP or the interviewer intended for this to be the answer, but I thought it was funny and didn't downvote it. Jun 10, 2013 at 16:22

I don't know it this is too much tricky :)

I would convert the binary number to dec and then I would return the logaritm base 2 of the number directly (converted from float to int).

The solution is the (returned number + 1) bit starting from the right.

To your answer as far as I know its the left-most 1

• Your algorithm is subject to rounding errors. That's no good. If you don't do any rounding at all, it's entirely wrong as the position is always integer. Jun 10, 2013 at 16:02
• @JanDvorak its correct if you truncate instead of rounding, which a direct cast would do.... Jun 10, 2013 at 16:04
• @BobVale still not. Rounding errors will cause you to sometimes underestimate the result by one Jun 10, 2013 at 16:06
• I said "round". If the log-2 implementation decides (it well could) that log_2(8) is 2.9999999993, then this algorithm will claim the top bit of 8 is at the second position (bit 1) whereas it's on the third (bit 2) Jun 10, 2013 at 16:09
• @vivoconunxino umm... you have to be strict when telling the computer how to do something. Unless you can find an exact (up to less than 1 ulp) implementation of log_2 (hint: you won't), this algorithm can produce incorrect results. Jun 10, 2013 at 16:19