Matt,

It seems you missed my suggestion about basing the maximum block size on
the bitcoin days destroyed in transactions that are included in the block.
I think it has potential for both scaling as well as keeping up a constant
fee pressure. If tuned properly, it should both stop spamming and increase
block size maximum when there are a lot of real transactions waiting for
inclusion.

- Joel

This is a clever way to tie block size to fees.

I would just like to point out though that it still fundamentally is using
hard block size limits to enforce scarcity. Transactions with below market
fees will hang in limbo for days and fail, instead of failing immediately
by not propagating, or seeing degraded, long confirmation times followed by
eventual success.


Aaron Voisine
co-founder and CEO
breadwallet.com

Though I'm a fan of this class of techniques(*) and think using something
in this space is strictly superior to not, and I think it makes larger
sizes safer long term; I do not think it adequately obviates the need
for a hard upper limit for two reasons:

(1) for software engineering and operational reasons it is very
difficult to develop, test for, or provision for something without
knowing limits. There would in fact be hard limits on real deployments
but they'd be opaque to their operators and you could easily imagine
the network forking by surprise as hosts crossed those limits.

(2) At best this approach mitigates the collective action problem between
miners around fees; it does not correct the incentive alignment between
miners and everyone else (miners can afford huge node costs because they
have income; but the full-node-using-users that need to exist in plenty
to keep miners honest do not), or the centralization pressures (N miners
can reduce their storage/bandwidth/cpu costs N fold by centralizing).

A dynamic limit can be combined with a hard upper to at least be no
worse than a hard upper with respect to those two points.


Another related point which has been tendered before but seems to have
been ignored is that changing how the size limit is computed can help
better align incentives and thus reduce risk. E.g. a major cost to the
network is the UTXO impact of transactions, but since the limit is blind
to UTXO impact a miner would gain less income if substantially factoring
UTXO impact into its fee calculations; and without fee impact users have
little reason to optimize their UTXO behavior. This can be corrected
by augmenting the "size" used for limit calculations. An example would
be tx_size = MAX( real_size >> 1, real_size + 4*utxo_created_size -
3*utxo_consumed_size). The reason for the MAX is so that a block
which cleaned a bunch of big UTXO could not break software by being
super large, the utxo_consumed basically lets you credit your fees by
cleaning the utxo set; but since you get less credit than you cost the
pressure should be downward but not hugely so. The 1/2, 4, 3 I regard
as parameters which I don't have very strong opinions on which could be
set based on observations in the network today (e.g. adjusted so that a
normal cleaning transaction can hit the minimum size). One way to think
about this is that it makes it so that every output you create "prepays"
the transaction fees needed to spend it by shifting "space" from the
current block to a future block. The fact that the prepayment is not
perfectly efficient reduces the incentive for miners to create lots of
extra outputs when they have room left in their block in order to store
space to use later [an issue that is potentially less of a concern with a
dynamic size limit]. With the right parameters there would never be such
at thing as a dust output (one which costs more to spend than its worth).

(likewise the sigops limit should be counted correctly and turned into
size augmentation (ones that get run by the txn); which would greatly
simplify selection rules: maximize income within a single scalar limit)

(*) I believe my currently favored formulation of general dynamic control
idea is that each miner expresses in their coinbase a preferred size
between some minimum (e.g. 500k) and the miner's effective-maximum;
the actual block size can be up to the effective maximum even if the
preference is lower (you're not forced to make a lower block because you
stated you wished the limit were lower). There is a computed maximum
which is the 33-rd percentile of the last 2016 coinbase preferences
minus computed_max/52 (rounding up to 1) bytes-- or 500k if thats
larger. The effective maximum is X bytes more, where X on the range
[0, computed_maximum] e.g. the miner can double the size of their
block at most. If X > 0, then the miners must also reach a target
F(x/computed_maximum) times the bits-difficulty; with F(x) = x^2+1 ---
so the maximum penalty is 2, with a quadratic shape; for a given mempool
there will be some value that maximizes expected income. (obviously all
implemented with precise fixed point arithmetic). The percentile is
intended to give the preferences of the 33% least preferring miners a
veto on increases (unless a majority chooses to soft-fork them out). The
minus-comp_max/52 provides an incentive to slowly shrink the maximum
if its too large-- x/52 would halve the size in one year if miners
were doing the lowest difficulty mining. The parameters 500k/33rd,
-computed_max/52 bytes, and f(x) I have less strong opinions about;
and would love to hear reasoned arguments for particular parameters.

Sorry but I fail to see how a linear identity transform between block
size and difficulty would work.

The miner's reward for finding a block is the sum of subsidy and fees:

R = S + F

The probability that the miner will find a block over a time interval is
inversely proportional to the difficulty D:

P = K / D

where K is a constant that depends on the miner's hashrate. The expected
reward of the miner is:

E = P * R

Consider that the miner chooses a new difficulty:

D' = D(1 + x).

With a linear identity transform between block size and difficulty, the
miner will be allowed to collect fees from a block of size: S'=S(1+x)

In the best case, collected will be proportional to block size:

F' = F(1+x)

Thus we get:

E' = P' * R' = K/(D(1+x)) * (S + F(1+x))

E' = E - x/(1+x) * S * K / D

So with this linear identity transform, increasing block size never
increases the miners gain. As long as the subsidy exists, the best
strategy for miners is to reduce block size (i.e. to choose x<0).

Isn't that a step backwards, then? I see no reason for fee pressure to
exist at the moment. All it's doing is turning away users for no purpose:
mining isn't supported by fees, and the tiny fees we use right now seem to
be good enough to stop penny flooding.

Why not set the max size to be 20x the average size? Why 2x, given you just
pointed out that'd result in blocks shrinking rather than growing.

I like that idea.

Average is a better choice than median. The median is not well defined
on discrete sets, as shown in your example, and there is no need to be
robust to outliers, thanks to the max size.


------------------------------------------------------------------------------

I don't really believe that is possible. I'll argue why below. To be clear,
this is not an argument against increasing the block size, only against
using the assumption of size-independent propagation.

There are several significant improvements likely possible to various
aspects of block propagation, but I don't believe you can make any part
completely size-independent. Perhaps the remaining aspects result in terms
in the total time that vanish compared to the link latencies for 1 MB
blocks, but there will be some block sizes for which this is no longer the
case, and we need to know where that is the case.

* You can't assume that every transaction is pre-relayed and pre-validated.
This can happen due to non-uniform relay policies (different codebases, and
future things like size-limited mempools), double spend attempts, and
transactions generated before a block had time to propagate. You've
previously argued for a policy of not including too recent transactions,
but that requires a bound on network diameter, and if these late
transactions are profitable, it has exactly the same problem as making
larger blocks non-proportionally more economic for larger pools groups if
propagation time is size dependent).
* This results in extra bandwidth usage for efficient relay protocols,
and if discrepancy estimation mispredicts the size of IBLT or error
correction data needed, extra roundtrips.
* Signature validation for unrelayed transactions will be needed at block
relay time.
* Database lookups for the inputs of unrelayed transactions cannot be
cached in advance.

* Block validation with 100% known and pre-validated transactions is not
constant time, due to updates that need to be made to the UTXO set (and
future ideas like UTXO commitments would make this effect an order of
magnitude worse).

* More efficient relay protocols also have higher CPU cost for
encoding/decoding.

Again, none of this is a reason why the block size can't increase. If
availability of hardware with higher bandwidth, faster disk/ram access
times, and faster CPUs increases, we should be able to have larger blocks
with the same propagation profile as smaller blocks with earlier technology.

But we should know how technology scales with larger blocks, and I don't
believe we do, apart from microbenchmarks in laboratory conditions.
--
Pieter
A lot of people like this idea, or something like it. It is nice and
simple, which is really important for consensus-critical code.

With this rule in place, I believe there would be more "fee pressure"
(miners would be creating smaller blocks) today. I created a couple of
histograms of block sizes to infer what policy miners are ACTUALLY
following today with respect to block size:

Last 1,000 blocks:
http://bitcoincore.org/~gavin/sizes_last1000.html

Notice a big spike at 750K -- the default size for Bitcoin Core.
This graph might be misleading, because transaction volume or fees might
not be high enough over the last few days to fill blocks to whatever limit
miners are willing to mine.

So I graphed a time when (according to statoshi.info) there WERE a lot of
transactions waiting to be confirmed:
http://bitcoincore.org/~gavin/sizes_357511.html

That might also be misleading, because it is possible there were a lot of
transactions waiting to be confirmed because miners who choose to create
small blocks got lucky and found more blocks than normal. In fact, it
looks like that is what happened: more smaller-than-normal blocks were
found, and the memory pool backed up.

So: what if we had a dynamic maximum size limit based on recent history?

The average block size is about 400K, so a 1.5x rule would make the max
block size 600K; miners would definitely be squeezing out transactions /
putting pressure to increase transaction fees. Even a 2x rule (implying
800K max blocks) would, today, be squeezing out transactions / putting
pressure to increase fees.

Using a median size instead of an average means the size can increase or
decrease more quickly. For example, imagine the rule is "median of last
2016 blocks" and 49% of miners are producing 0-size blocks and 51% are
producing max-size blocks. The median is max-size, so the 51% have total
control over making blocks bigger. Swap the roles, and the median is
min-size.

Because of that, I think using an average is better-- it means the max size
will change (up or down) more slowly.

I also think 2016 blocks is too long, because transaction volumes change
quicker than that. An average over 144 blocks (last 24 hours) would be
better able to handle increased transaction volume around major holidays,
and would also be able to react more quickly if an economically irrational
attacker attempted to flood the network with fee-paying transactions.

So my straw-man proposal would be: max size 2x average size over last 144
blocks, calculated at every block.

There are a couple of other changes I'd pair with that consensus change:

+ Make the default mining policy for Bitcoin Core neutral-- have its target
block size be the average size, so miners that don't care will "go along
with the people who do care."

+ Use something like Greg's formula for size instead of bytes-on-the-wire,
to discourage bloating the UTXO set.


---------

When I've proposed (privately, to the other core committers) some dynamic
algorithm the objection has been "but that gives miners complete control
over the max block size."

I think that worry is unjustified right now-- certainly, until we have
size-independent new block propagation there is an incentive for miners to
keep their blocks small, and we see miners creating small blocks even when
there are fee-paying transactions waiting to be confirmed.

I don't even think it will be a problem if/when we do have size-independent
new block propagation, because I think the combination of the random timing
of block-finding plus a dynamic limit as described above will create a
healthy system.

If I'm wrong, then it seems to me the miners will have a very strong
incentive to, collectively, impose whatever rules are necessary (maybe a
soft-fork to put a hard cap on block size) to make the system healthy again.

to increase transaction fees

I'd just like to re-iterate that transactions getting "squeezed out"
(failure after a lengthy period of uncertainty) is a radical change from
the current behavior of the network. There are plenty of avenues to create
fee pressure without resorting to such a drastic change in how the network
works today.


Aaron Voisine
co-founder and CEO
breadwallet.com

My understanding, which is very likely wrong in one way or another, is
transaction size and block size are two slightly different things but
perhaps it's so negligible that block size is a fine stand-in for total
transaction throughput.

Potentially Doubling the block size everyday is frankly imprudent. The
logarithmic increases in difficulty, which were often closer to 10% or 20%
every 2016 blocks was and is plenty fast, potentially changing blocksize by
twice daily is the mentality I would expect from a startup with the move
fast break things motto.

Infrastructure takes time, not everyone wants to run a node on a virtual
amazon instance, provisioning additional hard drive and bandwidth can't
happen overnight and trying to plan when block size from one week to the
next is a total mystery would be extremely difficult.

Anyone who has spent time examining the mining difficulty increases and
trajectory knows future planning is very very hard, allowing block size to
double daily would make it impossible.

Perhaps a middle way would be 300% increase every 2016 blocks, that will
scale to 20mbs within a month or two

The problem is logarithmic increases seem slow until they seem fast. If the
network begins to grow and block size hits 20, then the next day 40, 80...
Small nodes could get swamped within a week or less.

As for your point about Christmas, Bitcoin is a global network, Christmas,
while widely celebrated, isn't the only holiday, and planning around
American buying habits seems short sighted and no different from developers
trying to choose what the right fee pressure is.
questions though.
scale by transactions confirmed instead? Anyone can write and relay a
transaction, and those are what we want to scale for, why not measure it
directly?
block...
a reasonable time period for planning on changes. Two weeks is plenty fast,
especially at a 50% rate increase, in a few months the block size could be
dramatically larger.
networks around Christmas?
block size will be dipping up and down. Also if something breaks trying to
fix it in a day seems problematic. The hard fork database size difference
error comes to mind. Finally daily 50% increases could quickly crowd out
smaller nodes if changes happen too quickly to adapt for.
there are fee-paying transactions around to pay them. What scenario are you
imagining where transaction volume increases by 50% a day for a sustained
period of time?