# What does 'x << ~y' represent in JavaScript?

What does 'x << ~y' represent in JavaScript?

I understand that the bitwise `SHIFT` operation does this:

`x << y AS x * 2y`

And a tilde `~` operator does:

``````~x AS -(x+1)
``````

So, I assume the following:

`5 << ~3 AS 5 * 2-4 or 5 * Math.pow(2, -4)`

It should result in `0.3125`.

But, when I run `5 << ~3` it results in `1342177280`.

What is a step-by-step explanation? How and why does this combination of operations result in `1342177280` instead of `0.3125`?

(This question is similar to Stack Overflow question What are bitwise operators? about the bitwise `SHIFT` operator.)

• How could a bit shift operation give a fractional result like 0.3125? Dec 18 '15 at 7:59
• after `!--` and `<<~` what is next? I'm supposed to post "What does the `^<<!~` operator do?" Dec 18 '15 at 12:00
• @Zaibis `!~--this[](...[this[\$]],_=>..._)`
– azz
Dec 18 '15 at 13:20
• @Zaibis you could probably just interchange left-shift with right-shift and ask this question again. You might get 20 up-votes. Dec 18 '15 at 14:21
• @JonnyHenly: Changing left and right shift... but.... that would be .... `>>~`It looks like a guy..... what could he be doing.... I feel like I have the duty to ask SO "What does the Guy operator do?" x'D Dec 18 '15 at 14:32

`x << -n` is equal to `x << (32 - n)`
`~3 == -4` so
`5 << ~3` === `5 << (32 - 4)` === `5 << 28` which is `1,342,177,280`

to be accurate X << -n is not the same as X << (32 - n) ... in fact it's both simpler and more complicated ... the valid range of a bit shift operator is 0 to 31 ... the RHS in a bit shift operator is first converted to an unsigned 32 bit integer, then masked with 31 (hex 1f) (binary `11111`)

``````                   3 = 00000000000000000000000000000011
~3 = 11111111111111111111111111111100
--------------------------------
~3 & 0x1f  00000000000000000000000000011100 = 28
``````

when the magnitude is less than 32, it's exactly the same as what I posted above though

Bit operations work with 32 bit integers. Negative bit shifts are meaningless so are wrapped into positive 32 bit integers

How the << operator works

The rhs is converted to an unsigned 32bit integer - like explained here ToUInt32

ToUint32 basically takes a number and returns the number modulo 2^32

• How do you get the reference that `-n` is equal to `(32 - n)`? I am not doubting the fact that this is the answer. But, I am just curious since I couldn't find one.
– choz
Dec 18 '15 at 8:07
• @choz That actually goes all the way back to computer architecture. This is because most computer instructions set used 5 bits for storing the shift amount (at least for MIPS). Specially these bits are un-signed binary. Dec 18 '15 at 8:14
• It's not 32-n. It's using just the least siginficant 5 bits, that is `n & 31` (see cited reference about operator <<, 12.8.3.11 subpoint 11). If n is negative, then `32+n` == `n & 31` Dec 18 '15 at 8:16
• @choz ... `-n modulo X` = `X - n` when `abs(n) <= X` ... it's an over simplification on my part Dec 18 '15 at 8:16
• If +3 is (binary) ....0011 then the two's complement if this is ....1101 not ....1100 where the ellipses extend the most significant bit as far left as needed. OOPS!!! this comment is superfluous or incorrect or both, but I can't delete it, sorry Dec 22 '15 at 22:43

The `~` operator flips the bits of the item, while `<<` is a bitwise left shift. Here is what is happening in binary step-by-step. Note that the most left bit being 1 signified a negative number, this format is twos compliment:

``````3         // (00000000000000000000000000000011 => +3 in decimal)
// ~ flips the bits
~3        // (11111111111111111111111111111100 => -4 in decimal)
// The number 5 (..00101) shifted by left by -4 (-4 unsigned -> 28)
5         // (00000000000000000000000000000101 => +5 in decimal)
5 << -4   // (01010000000000000000000000000000 => +1342177280 in decimal)
``````

In the last line the bits are shifted and "rotated" to the other side, leading to a large positive number. In fact shifting by a negative number is similar to a bitwise rotation (overflowed bits are rotated to the other side), where shifting by positive numbers do not have such behaviour. The draw back is that the non-rotated bits are disregarded. Essentially meaning that `5 << -4` is the same as doing `5 << (32 - 4)`, that rather the rotation is actually a large shift.

The reasoning for this is because bit shifts are only a 5 bit unsigned integer. So the binary number in twos compliment`-4 (11100)` unsigned would be `28`.

• @JaromandaX Ah your right, it's binary 5 shifted by -4. Give me one second, this explains by it seems I'm off by 1. Dec 18 '15 at 6:39
• Thanks for your answer spencer. I am using online binary converter that `00000111111111111111111111111111` is `0x07FFFFFF` which resulted as `134217727`. Am I doing something wrong here?
– choz
Dec 18 '15 at 6:39
• @choz That was a mess-up on my part, I read the last expression in a wrong order and got a very close number by chance. I've updated my answer. Dec 18 '15 at 6:42
• maybe add a disclaimer or FYI that javascript converts the number from a 64bit double precision floating point to a 32bit integer, does the bit manipulations, then converts back. Good answer though, now that it's fixed. Dec 18 '15 at 6:47
• @SpencerWieczorek I am wondering since `5 << -4` is right shifting the binary of `5` for 4 times, correct? Doesn't it mean it should be like an equal of `5 >> 4` then? I am kinda confused in shifting this bs.. :(
– choz
Dec 18 '15 at 7:33

Your analysis is correct, except that you should not interpret ~3 (11100) (the bit-complement of 3 (00011)) as -4 , but as an unsigned (that is non-negative) 5-bit integer, namely 28 = 16 + 8 + 4 (11100).

This is explained in the ECMAScript standard (NB in most modern machines, positive and negative integers are represented in memory using two's complement representation):

12.8.3 The Left Shift Operator ( << )

NOTE Performs a bitwise left shift operation on the left operand by the amount specified by the right operand.

12.8.3.1 Runtime Semantics: Evaluation

1. Let lref be the result of evaluating ShiftExpression.
2. Let lval be GetValue(lref).
3. ReturnIfAbrupt(lval).
4. Let rref be the result of evaluating AdditiveExpression.
5. Let rval be GetValue(rref).
6. ReturnIfAbrupt(rval).
7. Let lnum be ToInt32(lval).
8. ReturnIfAbrupt(lnum).
9. Let rnum be ToUint32(rval).
10. ReturnIfAbrupt(rnum).
11. Let shiftCount be the result of masking out all but the least significant 5 bits of rnum, that is, compute rnum & 0x1F.
12. Return the result of left shifting lnum by shiftCount bits. The result is a signed 32-bit integer.

`~x` will reverse the bit representation of your x value (32 bits signed value with two's complement).

`x << y` is the left shift operator (here left). Your mathematical interpretation is correct :)

You can read more about bitwise operations over here: bitwise operators in Javascript

`5 << ~3` gives the same result as `5 << -4`, you are right.

Important thing: shifting x << y really results into x * 2y, but it is not a direct usage, it is just a useful side-effect.
Moreover, if you have a negative `y`, it doesn't work in the same way.

• How is that supposed to work with negative value btw? I am sorry I don't really understand about bit representation of anything.
– choz
Dec 18 '15 at 6:10
• , if you have a negative y, it doesn't work in the same way so you don't actually have an answer to the actual question Dec 18 '15 at 6:30