# shift bits vs multiply in PHP

I have the following code:

``````<?php
\$start = 1;

\$timestart = microtime(1);
for (\$i = 0; \$i < 1000000; \$i++) {
\$result1 = \$start * 4;
}
echo "\n";
echo microtime(1) - \$timestart;
echo "\n";

\$timestart = microtime(1);
for (\$i = 0; \$i < 1000000; \$i++) {
\$result2 = \$start << 2;
}
echo "\n";
echo microtime(1) - \$timestart;
echo "\n";
``````

This outputs:

``````0.14027094841003

0.12061500549316
``````

I found on the Internet a Google interview question (which I wanted to apply for a developer, but I realize I can't), and one of the questions asked what the fastest way was to multiply a number. My first thought was to use the `*` sign, so I tested it.

My question is, why is shifting bits faster than multiplication?

• Because multiply requires...a multiplication...which requires more time than a bitshift, because it is a more complicated operation?
– Dan
Nov 24, 2011 at 2:24
• @Dan - The question may have more to do with why bitshifting may or may not be equivalent to integer/float multiplication in PHP. Nov 24, 2011 at 2:26
• See en.wikipedia.org/wiki/Multiplication_algorithm#Electronic_usage stating that `To multiply two numbers with n digits using this method, one needs about n2 operations. More formally: using a natural size metric of number of digits, the time complexity of multiplying two n-digit numbers using long multiplication is Θ(n2).` Bit shifts are a single instruction. Nov 24, 2011 at 2:31
• Incidentally, there are more ways to perform multiplication than one might expect -- and different methods excel in different situations. Nov 24, 2011 at 2:31
• @drew010; A linear-time algorithm is available -- assuming you've got the RAM for some tables. Nov 24, 2011 at 2:32

Because bit shifting is something the computer does all the time in hardware, it's a no-brainer for the CPU. Multiplying arbitrary numbers is something more difficult, because it can't necessarily be done using simple bit shifting but requires actual work. Multiplying a small integer by 4 happens to be an operation that's identical to a left-shift by 2. But even if the compiler/runtime/CPU optimizes this operation down to a bit shift, some code first needs to recognize that it can be optimized this way, which is more work than a simple bit shift itself.

Either way, it's simply more work because the two operations do entirely different things, even if the outcome of certain operations is the same.

Because a bit shift is an operation that can be implemented directly in hardware, whereas hardware rarely has multiplication operations implemented directly. Multiplication by a power of two can be achieved with a few simple logic gates, whereas multiplication by arbitrary multiplicands requires at the very least several multiplications by powers of two plus an add-to-self operation stacked on top of each other (5 = 2 * 2 + 1). I don't know if the PHP language specifically implements a shift operation by using whatever low-level calls are available, but I would be surprised if it doesn't.

Source: years of experience + computer science education

• You might want to make it clear that you're talking about hardware efficiency versus ISA. Both x86 and ARM support multiplication instructions in hardware. That hardly counts as "rarely". I think you need to define what you mean by "directly". Nov 24, 2011 at 2:50
• I did not know that x86 and ARM support multiplication instructions in hardware. By "directly in hardware" I meant logic gates constructed in hardware, without any assembly code to assist. For example, addition and incrementation can be implemented using only hardware. I was taught that pure hardware multiplication could require thousands more gates than addition and is rarely implemented in anything but a supercomputer. Assembly routines can emulate hardware multiplication via repeated addition or other optimizations such as repeated bitshifts and addition-to-self.
– taz
Nov 24, 2011 at 3:22
• @taz: When you have a billion transistors in a chip, a few thousand for a multiplier isn't much, and the performance gain over shift-and-add is enough to justify it. Hard to find 32 or 64 bits CPUs that don't have multiply and divide built in. Jun 1, 2012 at 19:32
• @IraBaxter Thanks for the info. I suspect my instructor may have been a little behind the times.
– taz
Jun 1, 2012 at 19:40

On Intel sandybrigde CPUs it seems a shift with immediate costs about 1 clock cycle while a multiplication takes about 3-4 cycles. Apparently the whole program performance is affected by more factors than just the raw multiplication but it is enough of making a difference. Most compilers these days optimize multiplication by constants 2^n to shifts (compiler writers love to optimize your code :)) but maybe the PHP interpreter doesn't.

• This was a good answer. Now I'm curious if the PHP interpreter optimizes 2^n multiplies to shifts!
– aeu
Nov 18, 2015 at 17:59