05-25-15 - The Anti-Patent Patent Pool

The idea of the Anti-Patent Patent Pool is to destroy the system using the system.

The Anti-Patent Patent Pool is an independent patent licensing organization. (Hence APPP)

One option would be to just allow anyone to use those patents free of charge.

A more aggressive option would be a viral licensing model. (like the GPL, which has completely failed, so hey, maybe not). The idea of the viral licensing model is like this :

Anyone who owns no patents may use any patent in the APPP for free (if you currently own patents, you may donate them to the APPP).

If you wish to own patents, then you must pay a fee to license from the APPP. That fee is used to fund the APPP's activities, the most expensive being legal defense of its own patents, and legal attacks on other patents that it deems to be illegal or too broad.

(* = we'd have to be aggressive about going after companies that make a subsidiary to use APPP patents while still owning patents in the parent corporation)

The tipping point for the APPP would be to get a few patents that are important enough that major players need to either join the APPP (donate all their patents) or pay a large license.

The APPP provides a way for people who want their work to be free to ensure that it is free. In the current system this is hard to do without owning a patent, and owning a patent and enforcing it is hard to do without money.

The APPP pro-actively watches all patent submissions and objects to ones that cover prior art, are obvious and trivial, or excessively broad. It greatly reduces the issuance of junk patents, and fights ones that are mistakenly issued. (the APPP maintains a public list of patents that it believes to be junk, which it will help you fight if you choose to use the covered algorithms). (Obviously some of these activities have to be phased in over time as the APPP gets more money).

The APPP provides a way for small companies and individuals that cannot afford the lawyers to defend their work to be protected. When some evil behemoth tries to stop you from using algorithms that you believe you have a legal right to, rather than fight it yourself, you simply donate your work to the APPP and they fight for you.

Anyone who simply wants to ensure that they can use their own inventions could use the APPP.

Once the APPP has enough money, we would employ a staff of patent writers. They would take idea donations from the groundswell of developers, open-source coders, hobbyists. Describe your idea, the patent writer would make it all formal and go through the whole process. This would let us tap into where the ideas are really happening, all the millions of coders that don't have the time or money to pursue getting patents on their own.

In the current system, if you just want to keep your idea free, you have to constantly keep an eye on all patent submissions to make sure noone is slipping in and patenting it. It's ridiculous. Really the only safe thing to do is to go ahead and patent it yourself and then donate it to the APPP. (the problem is if you let them get the patent, even if it's bogus it may be expensive to fight, and what's worse is it creates a situation where your idea has a nasty asterisk on it - oh, there's this patent that covers this idea, but we believe that patent to be invalid so we claim this idea is still public domain. That's a nasty situation that will scare off lots of users.)

Some previous posts :

cbloom rants 02-10-09 - How to fight patents
cbloom rants 12-07-10 - Patents
cbloom rants 04-27-11 - Things we need
cbloom rants 05-19-11 - Nathan Myhrvold

Some notes :

1. I am not interested in debating whether patents are good or not. I am interested in providing a mechanism for those of us who hate patents to pursue our software and algorithm development in a reasonable way.

2. If you are thinking about the patent or not argument, I encourage you to think not of some ideal theoretical argument, but rather the realities of the situation. I see this on both sides of the fence; those who are pro-patent because it "protects inventors" but choose to ignore the reality of the ridiculous patent system, and those on the anti-patent side who believe patents are evil and they won't touch them, even though that may be the best way to keep free ideas free.

3. I believe part of the problem with the anti-patent movement is that we are all too fixated on details of our idealism. Everybody has slightly different ideas of how it should be, so the movement fractures and can't agree on a unified thrust. We need to compromise. We need to coordinate. We need to just settle on something that is a reasonable solution; perhaps not the ideal that you would want, but some change is better than no change. (of course the other part of the problem is we are mostly selfish and lazy)

4. Basically I think that something like the "defensive patent license" is a good idea as a way to make sure your own inventions stay free. It's the safest way (as opposed to not patenting), and in the long run it's the least work and maintenance. Instead of constantly fighting and keeping aware of attempts to patent your idea, you just patent it yourself, do the work up front and then know it's safe long term. But it doesn't go far enough. Once you have that patent you can use it as a wedge to open up more ideas that should be free. That patent is leverage, against all the other evil. That's where the APPP comes in. Just making your one idea free is not enough, because on the other side there is massive machinery that's constantly trying to patent every trivial idea they can think of.

5. What we need is for the APPP to get enough money so that it can be stuffing a deluge of trivial patents down the patent office's throat, to head off all the crap coming from "Intellectual Ventures" and its many brothers. We need to be getting at least as many patents as them and making them all free under the APPP.

Some links :

en.swpat.org - The Software Patents Wiki
Patent Absurdity � How software patents broke the system
Home defensivepatentlicense
FOSS Patents U.S. patent reform movement lacks strategic leadership, fails to leverage the Internet


05-21-15 - Software Patents are Fucking Awesome

Awesome. Spotted on encode.ru. It was inevitable I suppose :

"System and method for compressing data using asymmetric numeral systems with probability distributions"

By these tards :


Someone in the UK go over and punch them in the balls.

For those not aware of the background, ANS is probably the biggest invention in data compression in the last 20 years. Its inventor (Jarek Duda) has explicitly tried to publish it openly and make it patent-free, because he's awesome.

In the next 10 years I'm sure we will get patents for "using ANS with string-matching data compression", "using ANS with block mocomp data compression", "using ANS as a replacement for Huffman coding", "deferred summation with ANS", etc. etc. Lots of brilliant inventions like that. Really stimulating for innovation.

(as has happened over and over in data compression, and software in general in the past; hey let's take two obvious previously existing things; LZ string matching + Huffman = patent. LZ + hash table = patent. JPEG + arithmetic = patent. Mocomp + Huffman = patent. etc. etc.)

(often glossed over in the famous Stac-Microsoft suit story is the question of WHAT THE FUCK the LZS patent was supposed to be for? What was the invention there exactly? Doing LZ with a certain fixed bit encoding? Umm, yeah, like everyone does?)

Our patent system is working great. It obviously protects and motivates the real inventors, and doesn't just act as a way for the richest companies to lock in semi-monopolies of technologies they didn't even invent. Nope.

Recently at RAD we've made a few innovations related to ANS that are mostly in the vein of small improvements or clever usages, things that I wouldn't even imagine to patent, but of course that's wrong.

I've also noticed in general a lot of these vaporware companies in the UK. We saw one at RAD a few years ago that claimed to use "multi-dimensional curve interpolation for data compression" or some crackpot nonsense. There was another one that used alternate numeral systems (not ANS, but p-adic or some such) for god knows what. A few years ago there were lots of fractal-image-compression and other fractal-nonsense startups that did ... nothing. (this was before the VC "pivot" ; hey we have a bunch of fractal image patents, let's make a text messaging app)

They generally get some PhD's from Cambridge or whatever to be founders. They bring a bunch of "industry luminaries" on the board. They patent a bunch of nonsense. And then ...

... profit? There's a step missing where they actually ever make anything that works. But I guess sometimes they get bought for their vapor, or they manage to get a bullshit patent that's overly-general on something they didn't actually invent, and then they're golden.

I wonder if these places are getting college-backed "incubation" incentives? Pretty fucking gross up and down and all around. Everyone involved is scum.

(In general, universities getting patents and incubating startups is fucking disgusting. You take public funding and student's tuition, and you use that to lock up ideas for private profit. Fucking rotten, you scum.)

On a more practical note, if anyone knows the process for objecting to a patent in the UK, chime in.

Also, shame on us all for not doing more to fight the system. All our work should be going in the Anti-Patent Patent Pool.

Under the current first-to-file systems, apparently we are supposed to sit around all day reading every patent that's been filed to see if it covers something that we have already invented or is "well known" / public domain / prior art.

It's really a system that's designed around patents. It assumes that all inventions are patented. It doesn't really work well with a prior invention that's just not patented.

Which makes something like the APPP even more important. We need a way to patent all the free ideas just as a way to keep them legally free and not have to worry about all the fuckers who will rush in and try to patent our inventions as soon as we stop looking.

05-21-15 - LZ-Sub

LZ-Sub decoder :

delta_literal = get_sub_literal();

if ( delta_literal != 0 )
    *ptr++ = delta_literal + ptr[-lastOffset];
else // delta_literal == 0
    if ( ! get_offset_flag() )
        *ptr++ = ptr[-lastOffset];
    else if ( get_lastoffset_flag() )
        int lo_index = get_lo_index();
        lastOffset = last_offsets[lo_index];
        // do MTF or whatever using lo_index
        *ptr++ = ptr[-lastOffset];
        // extra 0 delta literal implied :
        *ptr++ = ptr[-lastOffset];
        lastOffset = get_offset();
        // put offset in last_offsets set
        *ptr++ = ptr[-lastOffset];
        *ptr++ = ptr[-lastOffset];
        // some automatic zero deltas follow for larger offsets
        if ( lastOffset > 128 )
            *ptr++ = ptr[-lastOffset];
            if ( lastOffset > 16384 )
                *ptr++ = ptr[-lastOffset];

    // each single zero is followed by a zero runlen
    //  (this is just a speed optimization)
    int zrl = get_zero_runlen();
        *ptr++ = ptr[-lastOffset];

This is basically LZMA. (sub literals instead of bitwise-LAM, but structurally the same) (also I've reversed the implied structure here; zero delta -> offset flag here, whereas in normal LZ you do offset flag -> zero delta)

This is what a modern LZ is. You're sending deltas from the prediction. The prediction is the source of the match. In the "match" range, the delta is zero.

The thing about modern LZ's (LZMA, etc.) is that the literals-after-match (LAMs) are very important too. These are the deltas after the zero run range. You can't really think of the match as just applying to the zero-run range. It applies until you send the next offset.

You can also of course do a simpler & more general variant :

Generalized-LZ-Sub decoder :

if ( get_offset_flag() )
    // also lastoffset LRU and so on not shown here
    lastOffset = get_offset();

delta_literal = get_sub_literal();

*ptr++ = delta_literal + ptr[-lastOffset];

Generalized-LZ-Sub just sends deltas from prediction. Matches are a bunch of zeros. I've removed the acceleration of sending zero's as a runlen for simplicity, but you could still do that.

The main difference is that you can send offsets anywhere, not just at certain spots where there are a bunch of zero deltas generated (aka "min match lengths").

This could be useful. For example when coding images/video/sound , there is often not an exact match that gives you a bunch of exact zero deltas, but there might be a very good match that gives you a bunch of small deltas. It would be worth sending that offset to get the small deltas, but normal LZ can't do it.

Generalized-LZ-Sub could also give you literal-before-match. That is, instead of sending the offset at the run of zero deltas, you could send it slightly *before* that, where the deltas are not zero but are small.

(when compressing text, "sub" should be replaced with some kind of smart lexicographical distance; for each character precompute a list of its most likely substitution character in order of probability.)

LZ is a bit like a BWT, but instead of the contexts being inferred by the prefix sort, you transmit them explicitly by sending offsets to prior strings. Weird.


05-16-15 - Threading Primitive - monitored semaphore

A monitored semaphore allows two-sided waiting :

The consumer side decs the semaphore, and waits on the count being positive.

The producer side incs the semaphore, and can wait on the count being a certain negative value (some number of waiting consumers).

Monitored semaphore solves a specific common problem :

In a worker thread system, you may need to wait on all work being done. This is hard to do in a race-free way using normal primitives. Typical ad-hoc solutions may miss work that is pushed during the wait-for-all-done phase. This is hard to enforce, ugly, and makes bugs. (it's particularly bad when work items may spawn new work items).

I've heard of many ad-hoc hacky ways of dealing with this. There's no need to muck around with that, because there's a simple and efficient way to just get it right.

The monitored semaphore also provides a race-free way to snapshot the state of the work system - how many work items are available, how many workers are sleeping. This allows you to wait on the joint condition - all workers are sleeping AND there is no work available. Any check of those two using separate primitives is likely a race.

The implementation is similar to the fastsemaphore I posted before.

"fastsemaphore" wraps some kind of underlying semaphore which actually provides the OS waits. The underlying semaphore is only used when the count goes negative. When count is positive, pops are done with simple atomic ops to avoid OS calls. eg. we only do an OS call when there's a possibility it will put our thread to sleep or wake a thread.

"fastsemaphore_monitored" uses the same kind atomic variable wrapping an underlying semaphore, but adds an eventcount for the waiter side to be triggered when enough workers are waiting. (see who ordered event count? )

Usage is like this :

To push a work item :

push item on your queue (MPMC FIFO or whatever)

To pop a work item :

pop item from queue

To flush all work :


NOTE : in my implementation, post & wait can be called from any thread, but wait_for_waiters must be called from only one thread. This assumes you either have a "main thread" that does that wait, or that you wrap that call with a mutex.

template <typename t_base_sem>
class fastsemaphore_monitored
    atomic<S32> m_state;
    eventcount m_waiters_ec;
    t_base_sem m_sem;

    enum { FSM_COUNT_SHIFT = 8 };
    enum { FSM_COUNT_MASK = 0xFFFFFF00UL };
    enum { FSM_WAIT_FOR_SHIFT = 0 };
    enum { FSM_WAIT_FOR_MASK = 0xFF };

    fastsemaphore_monitored(S32 count = 0)
    :   m_state(count<<FSM_COUNT_SHIFT)
        RL_ASSERT(count >= 0);



    inline S32 state_fetch_add_count(S32 inc)
        S32 prev = m_state($).fetch_add(inc<<FSM_COUNT_SHIFT,mo_acq_rel);
        S32 count = ( prev >> FSM_COUNT_SHIFT );
        RR_ASSERT( count < 0 || ( (U32)count < (FSM_COUNT_MAX-2) ) );
        return count;

    // warning : wait_for_waiters can only be called from one thread!
    void wait_for_waiters(S32 wait_for_count)
        RL_ASSERT( wait_for_count > 0 && wait_for_count < FSM_WAIT_FOR_MAX );
        S32 state = m_state($).load(mo_acquire);
            S32 cur_count = state >> FSM_COUNT_SHIFT;

            if ( (-cur_count) == wait_for_count )
                break; // got it
            S32 new_state = (cur_count<<FSM_COUNT_SHIFT) | (wait_for_count << FSM_WAIT_FOR_SHIFT);
            S32 ec = m_waiters_ec.prepare_wait();
            // double check and signal what we're waiting for :
            if ( ! m_state.compare_exchange_strong(state,new_state,mo_acq_rel) )
                continue; // retry ; state was reloaded
            state = m_state($).load(mo_acquire);
        // now turn off the mask :
            S32 new_state = state & FSM_COUNT_MASK;
            if ( state == new_state ) return;
            if ( m_state.compare_exchange_strong(state,new_state,mo_acq_rel) )
            // retry ; state was reloaded

    void post()
        if ( state_fetch_add_count(1) < 0 )

    void wait_no_spin()
        S32 prev_state = m_state($).fetch_add((-1)<<FSM_COUNT_SHIFT,mo_acq_rel);
        S32 prev_count = prev_state>>FSM_COUNT_SHIFT;
        if ( prev_count <= 0 )
            S32 waiters = (-prev_count) + 1;
            RR_ASSERT( waiters >= 1 );
            S32 wait_for = prev_state & FSM_WAIT_FOR_MASK;
            if ( waiters == wait_for )
                RR_ASSERT( wait_for >= 1 );
    void post(S32 n)
        RR_ASSERT( n > 0 );
        for(S32 i=0;i<n;i++)
    bool try_wait()
        // see if we can dec count before preparing the wait
        S32 state = m_state($).load(mo_acquire);
            if ( state < (1<<FSM_COUNT_SHIFT) ) return false;
            // dec count and leave the rest the same :
            //S32 new_state = ((c-1)<<FSM_COUNT_SHIFT) | (state & FSM_WAIT_FOR_MASK);
            S32 new_state = state - (1<<FSM_COUNT_SHIFT);
            RR_ASSERT( (new_state>>FSM_COUNT_SHIFT) >= 0 );
            if ( m_state($).compare_exchange_strong(state,new_state,mo_acq_rel) )
                return true;
            // state was reloaded
            // loop
            // backoff here optional
    S32 try_wait_all()
        // see if we can dec count before preparing the wait
        S32 state = m_state($).load(mo_acquire);
            S32 count = state >> FSM_COUNT_SHIFT;
            if ( count <= 0 ) return 0;
            // swap count to zero and leave the rest the same :
            S32 new_state = state & FSM_WAIT_FOR_MASK;
            if ( m_state($).compare_exchange_strong(state,new_state,mo_acq_rel) )
                return count;
            // state was reloaded
            // loop
            // backoff here optional
    void wait()
        int spin_count = rrGetSpinCount();
            if ( try_wait() ) 


05-16-15 - LZ literals after match

Some vague rambling about LAMs.

LAMs are weird.

LAM0 , the first literal after a match, has the strong exclusion property (assuming maximum match lengths). LAM0 is strictly != lolit. (lolit = literal at last offset).

LAM1, the next literal after end of match, has the exact opposite - VERY strong prediction of LAM1 == lolit. This prediction continues but weakens as you go to LAM2, LAM3, etc.

In Oodle LZNA (and in many other coders), I send a flag for (LAM == lolit) as a separate event. That means in the actual literal coding path you still have LAM1 != lolit. (the LAM == lolit flag should be context-coded using the distance from the end of the match).

In all cases, even though you know LAM != lolit, lolit is still a very strong predictor for LAM. Most likely LAM is *similar* to lolit.

LAM is both an exclude AND a predictor!

What similar means depends on the file type. In text it means something like vowels stay vowels, punctuation stays punctuation. lolit -> LAM is sort of like substituting one character change. In binary, it often means that they are numerically close. This means that the delta |LAM - lolit| is never zero, but is often small.

One of the interesting things about the delta is that it gives you a data-adaptive stride for a delta filter.

On some files, you can get huge compression wins by running the right delta filter. But the ideal delta distance is data-dependent (*). The sort of magic thing that works out is that the LZ match offsets will naturally pick up the structure & word sizes. In a file of 32-byte structs made of DWORDs, you'll get offsets of 4,8,12,32,etc. So you then take that offset and forming the LAM sub is just a way of doing a delta with that deduced stride. On DWORD or F32 data, you tend to get a lot of offset=4, so LAM tends to just be doing delta from the previous word (note of course this bytewise delta, not a proper dword delta).

(* = this is a huge thing that someone needs to work on; automatic detection of delta filters for arbitrary data; deltas could be byte,word,dword, other, from immediate neighbors or from struct/row strides, etc. In a compression world where we are fighting over 1% gains, this can be a 10-20% jump.)

Experimentally we have observed that LAMs are very rapidly changing. They benefit greatly from very quickly adapting models. They like geometric adaptation rates (more recent events are much more important). They cannot be modeled with large contexts (without very sophisticated handling of sparsity and fast adaptation), they need small contexts to get lots of events and statistical density. They seem to benefit greatly from modeling in groups (eg. bitwise or nibblewise or other), so that events on one symbol also affect other probabilities for faster group learning. Many of these observations are similar for post-BWT data. LAM sub literals does seem to behave like post-BWT data to some extent, and similar principles of modeling apply.

So, for example, just coding an 8-bit symbol using the 8-bit lolit as context is a no-go. In theory this would give you full modeling of the effects of lolit on the current symbol. In practice it dilutes your statistics way too much. (in theory you could do some kind of one-count boosts other counts thing (or a secondary coding table ala PPMZ SEE), but in practice that's a mess). Also as noted previously, if you have the full 8-bit context, then whether you code symbol raw or xor or sub is irrelevant, but if you do not have the full context then it does change things.

Related posts :

cbloom rants 08-20-10 - Deobfuscating LZMA
cbloom rants 09-14-10 - A small note on structured data
cbloom rants 03-10-13 - Two LZ Notes
cbloom rants 06-12-14 - Some LZMA Notes
cbloom rants 06-16-14 - Rep0 Exclusion in LZMA-like coders
cbloom rants 03-15-15 - LZ Literal Correlation Images


05-13-15 - Skewed Pareto Chart

It's hard to see just the decomp speed in the normal Pareto Chart. It gets squished down over at the far-right Y-intercept.

The obvious fix is just to magnify the right side. This is a linear scaling of the data; *1 on the far left, *10 on the far right :

The far-left is still proportional to the compression ratio, the far right is proportional to the decompression speed. The compressor lines are still speedups vs. memcpy, but the memcpy baseline is now sloped.

I'm not really sure how I feel about the warped chart vs unwarped.

The Pareto curves are in fact sigmoids (tanh's).

speedup = 1 / (1/compression_ratio + disk_speed / decompress_speed)

speedup = 1 / (1/compression_ratio + exp( log_disk_speed ) / decompress_speed)

(here they're warped sigmoids because of the magnification; the ones back here in the LZNA post are true sigmoids)

I believe (but have not proven) that a principle of the Pareto Frontier is that the maximum of all compressors should also be a sigmoid.

max_speedup(disk_speed) = MAX{c}( speedup[compressor c](disk_speed) );

One of the nice things about these charts is it makes it easy to see where some compressors are not as good as possible. If we fit a sigmoid over the top of all the curves :

We can easily see that LZHLW and LZNIB are not touching the curve. They're not as good as they should be in space/speed. Even thought nothing beats them at the moment (that I know of), they are algorithmically short of what's possible.

There are two things that constrain compressors from being better in a space/speed way. There's 1. what is our current best known algorithm. And then there's 2. what is possible given knowledge of all possible algorithms. #2 is the absolute limit and eventually it runs into a thermodynamic limit. In a certain amount of cpu time (cpu bit flips, which increase entropy), how much entropy can you take out of a a given data stream. You can't beat that limit no matter how good your algorithm is. So our goal in compression is always to just find improvements in the algorithms to edge closer to that eventual limit.

Anyway. I think I know how to fix them, and hopefully they'll be up at the gray line soon.


05-11-15 - ANS Minimal Flush

A detail for the record :

ANS (TANS or RANS) in the straightforward implementation writes a large minimum number of bytes.

To be concrete I'll consider a particular extremely bad case : 64-bit RANS with 32-bit renormalization.

The standard coder is :

initialize encoder (at end of stream) :

x = 1<<31

renormalize so x stays in the range x >= (1<<31) and x < (1<<63)

flush encoder (at the beginning of the stream) :

output all 8 bytes of x

decoder initializes by reading 8 bytes of x

decoder renormalizes via :

if ( x < (1<<31) )
  x <<= 32;  x |= get32(ptr); ptr += 4;

decoder terminates and can assert that x == 1<<31

this coder outputs a minimum of 8 bytes, which means it wastes up to 7 bytes on low-entropy data (assuming 1 byte minimum output and that the 1 byte required to byte-align output is not "waste").

In contrast, it's well known how to do minimal flush of arithmetic coders. When the arithmetic coder reaches the end, it has a "low" and "range" specifying an interval. "low" might be 64-bits, but you don't need to output them all, you only need to output enough such that the decoder will get something in the correct interval between "low" and "low+range".

Historically people often did arithmetic coder minimum flush assuming that the decoder would read zero-valued bytes after EOF. I no longer do that. I prefer to do a minimum flush such that decoder will get something in the correct interval no matter what byte follows EOF. This allows the decoder to just read past the end of your buffer with no extra work. (the arithmetic coder reads some # of bytes past EOF because it reads enough to fill "low" with bits, even though the top bits are all that are needed at the end of the stream).

The arithmetic coder minimum flush outputs a number of bytes proportional to log2(1/range) , which is the number of bits of information that are currently held pending in the arithmetic coder state, which is good. The excess is at most 1 byte.

So, to make ANS as clean as arithmetic coding we need a minimal flush. There are two sources of the waste in the normal ANS procedure outlined above.

One is the initial value of x (at the end of the stream). By setting x to (1<<31) , the low end of the renormalization interval, we have essentually filled it with bits it has to flush. (the pending bits in x is log2(x)). But those bits don't contain anything useful (except a value we can check at the end of decoding). One way to remove that waste is to stuff some other value in the initial state which contains bits you care about. Any value you initialize x with, you get back at the end of decoding, so then those bits aren't "wasted". But this can be annoying to find something useful to put in there, since you don't get that value out until the end of decoding.

The other source of waste is the final flush of x (at the beginning of the stream). This one is obvious - the # of pending bits stored in x at any time is log2(x). Clearly we should be flushing the final value of x in a # of bits proportional to log2(x).

So to do ANS minimal flush, here's one way :

initialize encoder (at end of stream) :

x = 0

renormalize so x stays in the range x < (1<<63)

flush encoder (at the beginning of the stream) :

output # of bytes with bits set in x, and those bytes

decoder initializes by reading variable # of bytes of x

decoder renormalizes via :

if ( x < (1<<31) )
  if ( ptr < ptrend )
    x <<= 32;  x |= get32(ptr); ptr += 4;

decoder terminates and can assert that x == 0

This ANS variant will output only 1 byte on very-low-entropy data.

There are now two phases of the coder. In the beginning of encoding (at the ending of the stream), x is allowed to be way below the renormalization range. During this phase, encoding just puts information into x, and the value of x grows. (note that x can actually stay 0 and never hold any bits if your consists of entirely the bottom symbol in RANS). Once x grows up into the renormalization interval, you enter the next phase where bits of x are pushed to the output to keep x in the renormalization interval. Decoding, in the first phase you read bytes from the stread to fill x with bits and keep it in the renormalization interval. Once the decoder read pointer hits the end, you switch to the second phase, and now x is allowed to shrink below the renormalization minimum and you can continue to decode the remaining information held in it.

This appears to add an extra branch to the decoder renormalization, but that can be removed by duplicating your decoder into "not near the end" and "near the end" variants.

The #sigbit output of x at the head is just the right thing and should always be done in all variants of ANS.

The checking ptr vs. ptrend and starting x = 0 is the variant that I call "minimal ANS".

Unfortunately "minimal ANS" doesn't play well with the ILP multi-state interleaved ANS. To do interleaved ANS like this you would need an EOF marker for each state. That's possible in theory (and could be done compactly in theory) but is a pain in the butt in practice.


05-09-15 - Oodle LZNA

Oodle 1.45 has a new compressor called LZNA. (LZ-nibbled-ANS)

LZNA is a high compression LZ (usually a bit more than 7z/LZMA) with better decode speed. Around 2.5X faster to decode than LZMA.

Anyone who needs LZMA-level compression and higher decode speeds should consider LZNA. Currently LZNA requires SSE2 to be fast, so it only runs full speed on modern platforms with x86 chips.

LZNA gets its speed from two primary changes. 1. It uses RANS instead of arithmetic coding. 2. It uses nibble-wise coding instead of bit-wise coding, so it can do 4x fewer coding operations in some cases. The magic sauce that makes these possible is Ryg's realization about mixing cumulative probability distributions . That lets you do the bitwise-style shift update of probabilities (keeping a power of two total), but on larger alphabets.

LZNA usually beats LZMA compression on binary, slightly worse on text. LZNA is closer to LZHAM decompress speeds.

Some results :


LZNA -z6 : 24,700,820 -> 9,154,248 =  2.965 bpb =  2.698 to 1
decode only      : 0.327 seconds, 43.75 b/kc, rate= 75.65 mb/s

LZMA : 24,700,820 -> 9,329,925 =  3.021 bpb =  2.647 to 1
decode           : 0.838 seconds, 58.67 clocks, rate= 29.47 M/s

LZHAM : 24,700,820 ->10,140,761 =  3.284 bpb =  2.435 to 1
decode           : 0.264 seconds, 18.44 clocks, rate= 93.74 M/s

(note on settings : LZHAM is run at BETTER because UBER is too slow. LZHAM BETTER is comparable to Oodle's -z6 ; UBER is similar to my -z7. LZMA is run at the best compression setting I can find; -m9 and lc=0,lp=2,pb=2 for binary data; with LZHAM I don't see a way to set the context bits. This is the new LZHAM 1.0, slightly different than my previous tests of LZHAM. All 64-bit, big dictionaries.).


LZNA -z6 : 58,788,904 ->12,933,907 =  1.760 bpb =  4.545 to 1
decode only      : 0.677 seconds, 50.22 b/kc, rate= 86.84 mb/s

LZMA : 58,788,904 ->13,525,659 =  1.840 bpb =  4.346 to 1
decode           : 1.384 seconds, 40.70 clocks, rate= 42.49 M/s

LZHAM : 58,788,904 ->15,594,877 =  2.122 bpb =  3.769 to 1
decode           : 0.582 seconds, 17.12 clocks, rate= 100.97 M/s

I'm not showing encode speeds because they're all running different amounts of threading. It would be complicated to show fairly. LZHAM is the most aggressively threaded, and also the slowest without threading.

My "game testset" total sizes, from most compression to least :

Oodle LZNA -z8 :            57,176,229
Oodle LZNA -z5 :            58,318,469

LZMA -mx9 d26:lc0:lp2:pb3 : 58,884,562
LZMA -mx9 :                 59,987,629

LZHAM -mx9 :                62,621,098

Oodle LZHLW -z6 :           68,199,739

zip -9 :                    88,436,013

raw :                       167,495,105

Here's the new Pareto chart for Oodle. See previous post on these charts

This is load+decomp speedup relative to memcpy : (lzt99)

The left-side Y-intercept is the compression ratio. The right-side Y-intercept is the decompression speed. In between you can see the zones where each compressor is the best tradeoff.

With LZMA and LZHAM : (changed colors)

lzt99 is bad for LZHAM, perhaps because it's heterogeneous and LZHAM assumes pretty stable data. (LZHAM usually beats LZHLW for compression ratio). Here's a different example :

load+decomp speedup relative to memcpy : (baby_robot_shell)

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