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I have written the below mentioned code. The code checks the first bit of every byte. If the first bit of every byte of is equal to 0, then it concatenates this value with the previous byte and stores it in a different variable var1. Here pos points to bytes of an integer. An integer in my implementation is uint64_t and can occupy upto 8 bytes.

uint64_t func(char* data)
{
    uint64_t var1 = 0; int i=0;
    while ((data[i] >> 7) == 0) 
    {
        variable = (variable << 7) | (data[i]);
        i++;
    }   
   return variable; 
}

Since I am repeatedly calling func() a trillion times for trillions of integers. Therefore it runs slow, is there a way by which I may optimize this code?

EDIT: Thanks to Joe Z..its indeed a form of uleb128 unpacking.

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3  
If you have a good optimizing compiler it will probably rewrite this to anyway. Tell it to optimize for speed on this module, if it's feeling generous it will probably also vectorize it for you. You can also use the "inline" keyword to inform the compiler that you will be calling it frequently and don't want call overhead. –  awiebe Jul 8 '13 at 8:32
    
@awiebe I am afraid..my compiler is not doing much. Even the trick suggested by ugoren seemed to have reduced 200 milliseconds. So, in case any optimization which you could suggested would really help me –  Rose Beck Jul 8 '13 at 8:36
1  
I too recommend the usage of the inline. But also don't forget to enable the usage of inline in the compiler settings, and to turn optimization to the max( for example in MSVC if you build as debug, it wont optimize for debug reasons ) –  akaltar Jul 8 '13 at 8:48
    
I'm curious if my function below actually helped much. I realize I did modify the data format slightly to standard uleb128. That does have advantages for faster decode, though, since you always know when you reach a byte what bits to shift it to, regardless of the other, earlier bytes. And, you can always defer masking until the end. –  Joe Z Jul 8 '13 at 9:10
    
Why does func not notify anyone how many bytes were used? This design requires inefficiency I think... –  Mooing Duck Jul 9 '13 at 19:10

6 Answers 6

up vote 15 down vote accepted

I have only tested this minimally; I am happy to fix glitches with it. With modern processors, you want to bias your code heavily toward easily predicted branches. And, if you can safely read the next 10 bytes of input, there's nothing to be saved by guarding their reads by conditional branches. That leads me to the following code:

// fast uleb128 decode
// assumes you can read all 10 bytes at *data safely.
// assumes standard uleb128 format, with LSB first, and 
// ... bit 7 indicating "more data in next byte"

uint64_t unpack( const uint8_t *const data )
{
    uint64_t value = ((data[0] & 0x7F   ) <<  0)
                   | ((data[1] & 0x7F   ) <<  7)
                   | ((data[2] & 0x7F   ) << 14)
                   | ((data[3] & 0x7F   ) << 21)
                   | ((data[4] & 0x7Full) << 28)
                   | ((data[5] & 0x7Full) << 35)
                   | ((data[6] & 0x7Full) << 42)
                   | ((data[7] & 0x7Full) << 49)
                   | ((data[8] & 0x7Full) << 56)
                   | ((data[9] & 0x7Full) << 63);

    if ((data[0] & 0x80) == 0) value &= 0x000000000000007Full; else
    if ((data[1] & 0x80) == 0) value &= 0x0000000000003FFFull; else
    if ((data[2] & 0x80) == 0) value &= 0x00000000001FFFFFull; else
    if ((data[3] & 0x80) == 0) value &= 0x000000000FFFFFFFull; else
    if ((data[4] & 0x80) == 0) value &= 0x00000007FFFFFFFFull; else
    if ((data[5] & 0x80) == 0) value &= 0x000003FFFFFFFFFFull; else
    if ((data[6] & 0x80) == 0) value &= 0x0001FFFFFFFFFFFFull; else
    if ((data[7] & 0x80) == 0) value &= 0x00FFFFFFFFFFFFFFull; else
    if ((data[8] & 0x80) == 0) value &= 0x7FFFFFFFFFFFFFFFull;

    return value;
}

The basic idea is that small values are common (and so most of the if-statements won't be reached), but assembling the 64-bit value that needs to be masked is something that can be efficiently pipelined. With a good branch predictor, I think the above code should work pretty well. You might also try removing the else keywords (without changing anything else) to see if that makes a difference. Branch predictors are subtle beasts, and the exact character of your data also matters. If nothing else, you should be able to see that the else keywords are optional from a logic standpoint, and are there only to guide the compiler's code generation and provide an avenue for optimizing the hardware's branch predictor behavior.

Ultimately, whether or not this approach is effective depends on the distribution of your dataset. If you try out this function, I would be interested to know how it turns out. This particular function focuses on standard uleb128, where the value gets sent LSB first, and bit 7 == 1 means that the data continues.

There are SIMD approaches, but none of them lend themselves readily to 7-bit data.

Also, if you can mark this inline in a header, then that may also help. It all depends on how many places this gets called from, and whether those places are in a different source file. In general, though, inlining when possible is highly recommended.

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5  
I never knew there's a Full number suffix... –  ugoren Jul 8 '13 at 9:48
5  
@ugoren: There isn't. 0x7Full == ((unsigned long long) 0x7F). –  orlp Jul 8 '13 at 12:32
    
You can even form 0xBull –  Mohammad Ali Baydoun Jul 9 '13 at 19:44

Your code is problematic

uint64_t func(const unsigned char* pos)
{
    uint64_t var1 = 0; int i=0;
    while ((pos[i] >> 7) == 0) 
    {
        var1 = (var1 << 7) | (pos[i]);
        i++;
    }
    return var1;    
}

First a minor thing: i should be unsigned.

Second: You don't assert that you don't read beyond the boundary of pos. E.g. if all values of your pos array are 0, then you will reach pos[size] where size is the size of the array, hence you invoke undefined behaviour. You should pass the size of your array to the function and check that i is smaller than this size.

Third: If pos[i] has most significant bit equal to zero for i=0,..,k with k>10, then previous work get's discarded (as you push the old value out of var1).

The third point actually helps us:

uint64_t func(const unsigned char* pos, size_t size)
{
    size_t i(0);
    while ( i < size && (pos[i] >> 7) == 0 )
    {
       ++i;
    }
    // At this point, i is either equal to size or
    // i is the index of the first pos value you don't want to use.
    // Therefore we want to use the values
    // pos[i-10], pos[i-9], ..., pos[i-1]
    // if i is less than 10, we obviously need to ignore some of the values
    const size_t start = (i >= 10) ? (i - 10) : 0;
    uint64_t var1 = 0;
    for ( size_t j(start); j < i; ++j )
    {
       var1 <<= 7;
       var1 += pos[j];
    }
    return var1; 
}

In conclusion: We separated logic and got rid of all discarded entries. The speed-up depends on the actual data you have. If lot's of entries are discarded then you save a lot of writes to var1 with this approach.

Another thing: Mostly, if one function is called massively, the best optimization you can do is call it less. Perhaps you can have come up with an additional condition that makes the call of this function useless.

Keep in mind that if you actually use 10 values, the first value ends up the be truncated.

64bit means that there are 9 values with their full 7 bits of information are represented, leaving exactly one bit left foe the tenth. You might want to switch to uint128_t.

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I just fixed a small issue with my code: As you're only shifting by 7 bits, not 8 bits, 9 items and one bit can be hold. I'm assuming CHAR_BIT == 8 here, bit that's the usual thing anyway. You might want to change that if you want to be truely platform independent. –  stefan Jul 8 '13 at 8:25
    
I don't see why i should be unsigned; there's nothing special about it, so the usual "good practice" would be to use int. (Of course, the usual idiomatic practice in C++ would be to use pointers.) –  James Kanze Jul 8 '13 at 8:45
    
@JamesKanze good practice would be unsigned since we only ever want to increase i. There's no reason ever to use a sign here. The idiomatic thing in C++ would be to be to use a container and iterate or give a start and end to mimic iterators. –  stefan Jul 8 '13 at 9:00
1  
@JamesKanze Can you please reference a (up-to-date) statement, i.e. a link to interview etc? I just don't see any reason to used signed integers for this. unsigned integers are better: no performance downside, but increase platform independence (you mentioned 16bit machines). Divisions may even be faster for unsigned types. int says "it might be negative as well". unsigned integers are born to be indices –  stefan Jul 8 '13 at 10:06
1  
@JamesKanze Well yes, you have to be careful with unsigned types, but you're only shifting the time you have to be careful. unsigned itself may be used for bit manipulations and modulo arithmetic, but not exclusively. Beeing an experienced C++ programmer myself, I only rarely use them for that purpose, i.e. I have only one such application. Most often I use them to express the intent of having representing natural number (e.g. index, size,...). I guess it's a matter of taste on which we disagree. –  stefan Jul 8 '13 at 10:24

A small optimization would be:

while ((pos[i] & 0x80) == 0) 

Bitwise and is generally faster than a shift. This of course depends on the platform, and it's also possible that the compiler will do this optimization itself.

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Apart from this...can you please suggest some other optimization...I am really in need of it –  Rose Beck Jul 8 '13 at 8:08
    
I would be shocked if any modern compiler didn't do this already. –  Mooing Duck Jul 9 '13 at 18:52
    
@MooingDuck I've checked with my machine with g++4.6 and it didn't substitute the instructions. Perhaps they are equivalently expensive? –  stefan Jul 10 '13 at 9:23
    
That would be my guess. The optimizer is smart enough to do this sort of thing if it were better –  Mooing Duck Jul 10 '13 at 16:44
    

Can you change the encoding?

Google came across the same problem, and Jeff Dean describes a really cool solution on slide 55 of his presentation:

The basic idea is that reading the first bit of several bytes is poorly supported on modern architectures. Instead, let's take 8 of these bits, and pack them as a single byte preceding the data. We then use the prefix byte to index into a 256-item lookup table, which holds masks describing how to extract numbers from the rest of the data.

I believe it's how protocol buffers are currently encoded.

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Can you change your encoding? As you've discovered, using a bit on each byte to indicate if there's another byte following really sucks for processing efficiency.

A better way to do it is to model UTF-8, which encodes the length of the full int into the first byte:

0xxxxxxx // one byte with 7 bits of data
10xxxxxx 10xxxxxx // two bytes with 12 bits of data
110xxxxx 10xxxxxx 10xxxxxx // three bytes with 16 bits of data
1110xxxx 10xxxxxx 10xxxxxx 10xxxxxx // four bytes with 22 bits of data
// etc.

But UTF-8 has special properties to make it easier to distinguish from ASCII. This bloats the data and you don't care about ASCII, so you'd modify it to look like this:

0xxxxxxx // one byte with 7 bits of data
10xxxxxx xxxxxxxx // two bytes with 14 bits of data.
110xxxxx xxxxxxxx xxxxxxxx // three bytes with 21 bits of data
1110xxxx xxxxxxxx xxxxxxxx xxxxxxxx // four bytes with 28 bits of data
// etc.

This has the same compression level as your method (up to 64 bits = 9 bytes), but is significantly easier for a CPU to process.

From this you can build a lookup table for the first byte which gives you a mask and length:

// byte_counts[255] contains the number of additional
// bytes if the first byte has a value of 255.
uint8_t const byte_counts[256]; // a global constant.

// byte_masks[255] contains a mask for the useful bits in
// the first byte, if the first byte has a value of 255.
uint8_t const byte_masks[256]; // a global constant.

And then to decode:

// the resulting value.
uint64_t v = 0;

// mask off the data bits in the first byte.
v = *data & byte_masks[*data];

// read in the rest.
switch(byte_counts[*data])
{
    case 3: v = v << 8 | *++data;
    case 2: v = v << 8 | *++data;
    case 1: v = v << 8 | *++data;
    case 0: return v;
    default:
        // If you're on VC++, this'll make it take one less branch.
        // Better make sure you've got all the valid inputs covered, though!
        __assume(0);
}

No matter the size of the integer, this hits only one branch point: the switch, which will likely be put into a jump table. You can potentially optimize it even further for ILP by not letting each case fall through.

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When I see v = v << 8 | *++data; I pause, and think "needs more parenthesis". I'm uncertain if the order of operations is correct there. –  Mooing Duck Jul 9 '13 at 19:18
    
It's equiv to (v << 8) | *++data. Correct, but perhaps it could use some parenthesis for readability. –  Cory Nelson Jul 9 '13 at 19:27

First, rather than shifting, you can do a bitwise test on the relevant bit. Second, you can use a pointer, rather than indexing (but the compiler should do this optimization itself. Thus:

uint64_t
readUnsignedVarLength( unsigned char const* pos )
{
    uint64_t results = 0;
    while ( (*pos & 0x80) == 0 ) {
        results = (results << 7) | *pos;
        ++ pos;
    }
    return results;
}

At least, this corresponds to what your code does. For variable length encoding of unsigned integers, it is incorrect, since 1) variable length encodings are little endian, and your code is big endian, and 2) your code doesn't or in the high order byte. Finally, the Wiki page suggests that you've got the test inversed. (I know this format mainly from BER encoding and Google protocol buffers, both of which set bit 7 to indicate that another byte will follow.

The routine I use is:

uint64_t
readUnsignedVarLen( unsigned char const* source )
{
    int shift = 0;
    uint64_t results = 0;
    uint8_t tmp = *source ++;
    while ( ( tmp & 0x80 ) != 0 ) {
        *value |= ( tmp & 0x7F ) << shift;
        shift += 7;
        tmp = *source ++;
    }
    return results | (tmp << shift);
}

For the rest, this wasn't written with performance in mind, but I doubt that you could do significantly better. An alternative solution would be to pick up all of the bytes first, then process them in reverse order:

uint64_t
readUnsignedVarLen( unsigned char const* source )
{
    unsigned char buffer[10];
    unsigned char* p = std::begin( buffer );
    while ( p != std::end( buffer ) && (*source & 0x80) != 0 ) {
        *p = *source & 0x7F;
        ++ p;
    }
    assert( p != std::end( buffer ) );
    *p = *source;
    ++ p;
    uint64_t results = 0;
    while ( p != std::begin( buffer ) ) {
        -- p;
        results = (results << 7) + *p;
    }
    return results;
}

The necessity of checking for buffer overrun will likely make this slightly slower, but on some architectures, shifting by a constant is significantly faster than shifting by a variable, so this could be faster on them.

Globally, however, don't expect miracles. The motivation for using variable length integers is to reduce data size, at a cost in runtime for decoding and encoding.

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