How does Duff's device work?

I've read the article on Wikipedia on the Duff's device, and I don't get it. I am really interested, but I've read the explanation there a couple of times and I still don't get it how the Duff's device works.

What would a more detailed explanation be?

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There are some good explanations elsewhere, but let me give it a try. (This is a lot easier on a whiteboard!) Here's the Wikipedia example with some notations.

Let's say you're copying 20 bytes. The flow control of the program for the first pass is:

int count;                        // Set to 20
{
int n = (count + 7) / 8;      // n is now 3.  (The "while" is going
//              to be run three times.)

switch (count % 8) {          // The remainder is 4 (20 modulo 8) so

case 0:                       // [skipped]
do {                 // [skipped]
*to = *from++;   // [skipped]
case 7:      *to = *from++;   // [skipped]
case 6:      *to = *from++;   // [skipped]
case 5:      *to = *from++;   // [skipped]
case 4:      *to = *from++;   // Start here.  Copy 1 byte  (total 1)
case 3:      *to = *from++;   // Copy 1 byte (total 2)
case 2:      *to = *from++;   // Copy 1 byte (total 3)
case 1:      *to = *from++;   // Copy 1 byte (total 4)
} while (--n > 0);     // N = 3 Reduce N by 1, then jump up
//       to the "do" if it's still
}                             //        greater than 0 (and it is)
}


Now, start the second pass, we run just the indicated code:

int count;                        //
{
int n = (count + 7) / 8;      //
//

switch (count % 8) {          //
//

case 0:                       //
do {                 // The while jumps to here.
*to = *from++;   // Copy 1 byte (total 5)
case 7:      *to = *from++;   // Copy 1 byte (total 6)
case 6:      *to = *from++;   // Copy 1 byte (total 7)
case 5:      *to = *from++;   // Copy 1 byte (total 8)
case 4:      *to = *from++;   // Copy 1 byte (total 9)
case 3:      *to = *from++;   // Copy 1 byte (total 10)
case 2:      *to = *from++;   // Copy 1 byte (total 11)
case 1:      *to = *from++;   // Copy 1 byte (total 12)
} while (--n > 0);     // N = 2 Reduce N by 1, then jump up
//       to the "do" if it's still
}                             //       greater than 0 (and it is)
}


Now, start the third pass:

int count;                        //
{
int n = (count + 7) / 8;      //
//

switch (count % 8) {          //
//

case 0:                       //
do {                 // The while jumps to here.
*to = *from++;   // Copy 1 byte (total 13)
case 7:      *to = *from++;   // Copy 1 byte (total 14)
case 6:      *to = *from++;   // Copy 1 byte (total 15)
case 5:      *to = *from++;   // Copy 1 byte (total 16)
case 4:      *to = *from++;   // Copy 1 byte (total 17)
case 3:      *to = *from++;   // Copy 1 byte (total 18)
case 2:      *to = *from++;   // Copy 1 byte (total 19)
case 1:      *to = *from++;   // Copy 1 byte (total 20)
} while (--n > 0);     // N = 1  Reduce N by 1, then jump up
//       to the "do" if it's still
}                             //       greater than 0 (and it's not, so bail)
}                                 // continue here...


20 bytes are now copied.

Note: The original Duff's Device (shown above) copied to an I/O device at the to address. Thus, it wasn't necessary to increment the pointer *to. When copying between two memory buffers you'd need to use *to++.

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Thanks for the comments explaining the syntax; +1! –  Pops Jun 1 '10 at 16:56
This answer is far more useful than the accepted one. It's a real shame that accepted trumps vote count. –  Dan Dec 31 '14 at 15:21

The explanation in Dr. Dobb's Journal is the best that I found on the topic.

This being my AHA moment:

for (i = 0; i < len; ++i) {
HAL_IO_PORT = *pSource++;
}


becomes:

int n = len / 8;
for (i = 0; i < n; ++i) {
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
HAL_IO_PORT = *pSource++;
}


:) becomes:

int n = (len + 8 - 1) / 8;
switch (len % 8) {
case 0: do { HAL_IO_PORT = *pSource++;
case 7: HAL_IO_PORT = *pSource++;
case 6: HAL_IO_PORT = *pSource++;
case 5: HAL_IO_PORT = *pSource++;
case 4: HAL_IO_PORT = *pSource++;
case 3: HAL_IO_PORT = *pSource++;
case 2: HAL_IO_PORT = *pSource++;
case 1: HAL_IO_PORT = *pSource++;
} while (--n > 0);
}

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good post (plus I have to find one good answer from you to upvote ;) 2 down, 13 to go: stackoverflow.com/questions/359727#486543 ). Enjoy the nice answer badge. –  VonC Feb 6 '09 at 7:40
+1 because downvoting someone because you don't understand C syntax is unfair –  Dancrumb Aug 28 '10 at 18:20
The crucial fact here, and which made Duff's device incomprehensible to me for the longest time, is that by a quirk of C, after the first time it reaches the while, it jumps back and executes all the statements. Thus even if len%8 was 4, it will execute the case 4, case 2, case 2, and case 1, and then jump back and execute all the cases from the next loop onwards. This is the part that needs explaining, the way the loop and the switch statement "interact". –  ShreevatsaR Jan 24 '12 at 12:24
The Dr. Dobbs article is good however aside from the link the answer does not add anything. See Rob Kennedy's answer below which actually provides an important point about the remainder of the transfer size being handled first followed by zero or more transfer blocks of 8 bytes. In my opinion that is the key to understanding this code. –  Richard Chambers Apr 20 '13 at 23:03
Am I missing something, or in the second code snippet len % 8 bytes will not be copied? –  newbie Mar 30 '14 at 21:54

There are two key things to Duff's device. First, which I suspect is the easier part to understand, the loop is unrolled. This trades larger code size for more speed by avoiding some of the overhead involved in checking whether the loop is finished and jumping back to the top of the loop. The CPU can run faster when it's executing straight-line code instead of jumping.

The second aspect is the switch statement. It allows the code to jump into the middle of the loop the first time through. The surprising part to most people is that such a thing is allowed. Well, it's allowed. Execution starts at the calculated case label, and then it falls through to each successive assignment statement, just like any other switch statement. After the last case label, execution reaches the bottom of the loop, at which point it jumps back to the top. The top of the loop is inside the switch statement, so the switch is not re-evaluated anymore.

The original loop is unwound eight times, so the number of iterations is divided by eight. If the number of bytes to be copied isn't a multiple of eight, then there are some bytes left over. Most algorithms that copy blocks of bytes at a time will handle the remainder bytes at the end, but Duff's device handles them at the beginning. The function calculates count % 8 for the switch statement to figure what the remainder will be, jumps to the case label for that many bytes, and copies them. Then the loop continues to copy groups of eight bytes.

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This made sense to me. +1 –  Almo Feb 23 '12 at 16:35
This explanation makes more sense. the key for me to understand that the remainder is copied first then the rest in blocks of 8 bytes which is unusual since as mentioned most of the time, you would copy in blocks of 8 bytes and then copy the remainder. doing the remainder first is the key to understanding this algorithm. –  Richard Chambers Apr 20 '13 at 22:55
+1 for mentioning the crazy placement/nesting of switch / while loop. Impossible to imagine coming from a language like Java... –  Parobay Feb 3 '14 at 7:06

The point of duffs device is to reduce the number of comparisons done in a tight memcpy implementation.

Suppose you want to copy 'count' bytes from a to b, the straight forward approach is to do the following:

  do {
*a = *b++;
} while (--count > 0);


How many times do you need to compare count to see if it's a above 0? 'count' times.

Now, the duff device uses a nasty unintentional side effect of a switch case which allows you to reduce the number of comparisons needed to count / 8.

Now suppose you want to copy 20 bytes using duffs device, how many comparisons would you need? Only 3, since you copy eight bytes at a time except the last first one where you copy just 4.

UPDATED: You don't have to do 8 comparisons/case-in-switch statements, but it's reasonable a trade-off between function size and speed.

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Note that duff's device is not limited to 8 duplications in the switch statement. –  strager Feb 5 '09 at 1:29
why can't you just use instead of --count, count = count-8? and use a second loop to deal with the remainder? –  hhafez Feb 5 '09 at 1:36
Hhafez, you can use a second loop to deal with the remainder. But now you've twice as much code to accomplish the same thing with no speed increase. –  Rob Kennedy Feb 5 '09 at 1:39
Johan, you have it backward. The remaining 4 bytes are copied on the first iteration of the loop, not the last. –  Rob Kennedy Feb 5 '09 at 1:40
@Rob: Edited to correct that. –  Lawrence Dol Feb 5 '09 at 5:00

When I read it for the first time, I autoformatted it to this

void dsend(char* to, char* from, count) {
int n = (count + 7) / 8;
switch (count % 8) {
case 0: do {
*to = *from++;
case 7: *to = *from++;
case 6: *to = *from++;
case 5: *to = *from++;
case 4: *to = *from++;
case 3: *to = *from++;
case 2: *to = *from++;
case 1: *to = *from++;
} while (--n > 0);
}
}


and I had no idea what was happening.

Maybe not when this question was asked, but now Wikipedia has a very good explanation

The device is valid, legal C by virtue of two attributes in C:

• Relaxed specification of the switch statement in the language's definition. At the time of the device's invention this was the first edition of The C Programming Language which requires only that the controlled statement of the switch be a syntactically valid (compound) statement within which case labels can appear prefixing any sub-statement. In conjunction with the fact that, in the absence of a break statement, the flow of control will fall-through from a statement controlled by one case label to that controlled by the next, this means that the code specifies a succession of count copies from sequential source addresses to the memory-mapped output port.
• The ability to legally jump into the middle of a loop in C.
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Though I'm not 100% sure what you're asking for, here goes...

The issue that Duff's device addresses is one of loop unwinding (as you'll no doubt have seen on the Wiki link you posted). What this basically equates to is an optimisation of run-time efficiency, over memory footprint. Duff's device deals with serial copying, rather than just any old problem, but is a classic example of how optimisations can be made by reducing the number of times that a comparison needs to be done in a loop.

As an alternative example, which may make it easier to understand, imagine you have an array of items you wish to loop over, and add 1 to them each time... ordinarily, you might use a for loop, and loop around 100 times. This seems fairly logical and, it is... however, an optimisation can be made by unwinding the loop (obviously not too far... or you may as well just not use the loop).

So a regular for loop:

for(int i = 0; i < 100; i++)
{
myArray[i] += 1;
}


becomes

for(int i = 0; i < 100; i+10)
{
myArray[i] += 1;
myArray[i+1] += 1;
myArray[i+2] += 1;
myArray[i+3] += 1;
myArray[i+4] += 1;
myArray[i+5] += 1;
myArray[i+6] += 1;
myArray[i+7] += 1;
myArray[i+8] += 1;
myArray[i+9] += 1;
}


What Duff's device does is implement this idea, in C, but (as you saw on the Wiki) with serial copies. What you're seeing above, with the unwound example, is 10 comparisons compared to 100 in the original - this amounts to a minor, but possibly significant, optimisation.

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You're missing the key part. It's not just about loop unwinding. The switch statement jumps into the middle of the loop. That's what makes the device look so confusing. Your loop above always performs a multiple of 10 copies, but Duff's performs any number. –  Rob Kennedy Feb 5 '09 at 1:37
That's true - but I was attempting to simplify the description for the OP. Perhaps I didn't clear that up enough! :) –  James Burgess Feb 5 '09 at 8:20

1: Duffs device is a particular implimentation of loop unrolling. What is loop unrolling?
If you have an operation to perform N times in a loop you can trade program size for speed by executing the loop N/n times and then in the loop inlining (unrolling) the loop code n times e.g. replacing:

for (int i=0; i<N; i++) {
// [The loop code...]
}


with

for (int i=0; i<N/n; i++) {
// [The loop code...]
// [The loop code...]
// [The loop code...]
...
// [The loop code...] // n times!
}


Which works great if N % n == 0 - no need for Duff! If that is not true then you have to handle the remainder - which is a pain.

2: How does Duffs device differ from this standard loop unrolling?
Duffs device is just a clever way of dealing with the remainder loop cycles when N % n != 0. The whole do / while executes N / n number of times as per standard loop unrolling (because the case 0 applies). On the last run through the loop (the 'N/n+1'th time) the case kicks in and we jump to the N % n case and run the loop code the 'remainder' number of times.

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I got interest in Duffs device this following this question: stackoverflow.com/questions/17192246/switch-case-weird-scoping so thought Id have a go at clarifing Duff - not sure if it is any improvement on existing answers... –  Ricibob Jun 20 '13 at 8:15