research/bitcoin_unlimited_style_siz...

# The purpose of this script is to create an evolutionary
# model to study the equilibrium effects of Bitcoin Unlimited-style
# "emergent consensus". Note that the model is not yet quite
# complete as it does not take into account the benefits of
# mining "sister blocks" that steal transaction fees, though it
# does give a rough idea of what equilibrium behavior
# among the various miner policy dimensions (block accept size,
# override depth, block creation size) looks like
import random

# Block reward
REWARD = 1000
# Call this function to get a tx with the right fee
TX_FEE_DISTRIBUTION = lambda: (10000 // random.randrange(5, 250)) * 0.01
# TX_FEE_DISTRIBUTION = lambda: 20
# Propagation time
PROPTIME_FACTOR = 1

# List of tuples:
# (default limit, n-block limit, acceptance depth, creation limit)
strategies = []
for i in range(4):
    for j in range(4):
        strategies.append([2 + i * 2, 100, 3, 10 + j * 4])

class Block():
    def __init__(self, parent, size, fees, miner):
        self.hash = random.randrange(10**20)
        self.parent = parent
        self.score = 1 if self.parent is None else parent.score + 1
        self.miner = miner
        self.size = size
        self.fees = fees

class Miner():
    def __init__(self, strategy, id):
        self.limit, self.big_limit, self.accept_depth, self.creation_limit = strategy
        self.chain = {}
        self.big_chain = {}
        self.head = None
        self.big_head = None
        self.id = id
        self.future = {}
        self.children = {}
        self.created = 0

    def process_history(self, time):
        deletes = []
        for t in self.future:
            if t <= time:
                for b in self.future[t]:
                    self.process_block(b)
                deletes.append(t)
        for t in deletes:
            del self.future[t]

    def add_block(self, block, time):
        self.process_history(time)
        if time + int(block.size * PROPTIME_FACTOR) not in self.future:
            self.future[time + int(block.size * PROPTIME_FACTOR)] = [block]
        else:
            self.future[time + int(block.size * PROPTIME_FACTOR)].append(block)

    def process_block(self, block):
        if block.size <= self.limit and (block.parent is None or block.parent.hash in self.chain):
            self.chain[block.hash] = block
            if block.score > (self.head.score if self.head else 0):
                self.head = block
        if block.size <= self.big_limit and (block.parent is None or block.parent.hash in self.big_chain):
            self.big_chain[block.hash] = block
            if block.score > (self.big_head.score if self.big_head else 0):
                self.big_head = block
            if block.score > (self.head.score if self.head else 0) + self.accept_depth:
                self.head = block
                self.chain[block.hash] = block
        if block.parent and block.parent.hash not in self.chain and block.parent.hash not in self.big_chain:
            if block.parent.hash not in self.children:
                self.children[block.parent.hash] = [block]
            else:
                self.children[block.parent.hash].append(block)
        if block.hash in self.children:
            for c in self.children[block.hash]:
                self.process_block(c)
            del self.children[block.hash]

    def create_block(self, backlog, time):
        self.process_history(time)
        fees = sum(backlog[:self.creation_limit])
        # print 'Creating block of size %d (fees %d, seq %d)' % (self.creation_limit, fees, self.head.score + 1 if self.head else 1)
        self.created += 1
        return Block(self.head, self.creation_limit, fees, self.id)


def simulate(strats):
    miners = [Miner(strat, i) for i, strat in enumerate(strats)]
    backlog = []
    for i in range(100000):
        if i % 10000 == 0:
            print 'Progress %d' % i
        backlog.append(TX_FEE_DISTRIBUTION())
        if random.random() < 0.01:
            backlog = sorted(backlog)[::-1]
            miner = random.choice(miners)
            b = miner.create_block(backlog, i)
            backlog = backlog[b.size:]
            for m in miners:
                m.add_block(b, i)
    rewards = [0] * len(miners)
    blocks = [0] * len(miners)
    h = miners[0].head
    sz = 0
    while h is not None:
        rewards[h.miner] += REWARD + h.fees
        blocks[h.miner] += 1
        h = h.parent
        sz += 1
    return rewards, blocks, [m.created for m in miners]

for r in range(200):
    tests = []
    for s in strategies:
        tests.append(s)
        tests.append((s[0] - 2, s[1], s[2], s[3]))
        tests.append((s[0] + 2, s[1], s[2], s[3]))
        tests.append((s[0], s[1], s[2] - 1, s[3]))
        tests.append((s[0], s[1], s[2] + 1, s[3]))
        tests.append((s[0], s[1], s[2], s[3] - 2))
        tests.append((s[0], s[1], s[2], s[3] + 2))
    NUM_TESTS = 7
    print 'Starting simulation'
    results, blks, created = simulate(tests)
    for i, s in enumerate(strategies):
        base = results[i * NUM_TESTS]
        if results[i * NUM_TESTS + 1] < base < results[i * NUM_TESTS + 2]:
            print 'Increasing base accept size beneficial at %r' % s
            s[0] += 2
        if results[i * NUM_TESTS + 1] > base > results[i * NUM_TESTS + 2] and s[0] > 2:
            print 'Decreasing base accept size beneficial at %r' % s
            s[0] -= 2
        if results[i * NUM_TESTS + 3] < base < results[i * NUM_TESTS + 4]:
            print 'Increasing override depth beneficial at %r' % s
            s[2] += 1
        if results[i * NUM_TESTS + 3] > base > results[i * NUM_TESTS + 4] and s[2] > 1:
            print 'Decreasing override depth beneficial at %r' % s
            s[2] -= 1
        if results[i * NUM_TESTS + 5] < base < results[i * NUM_TESTS + 6]:
            print 'Increasing creation size beneficial at %r' % s
            s[3] += 2
        if results[i * NUM_TESTS + 5] > base > results[i * NUM_TESTS + 6] and s[3] > 2:
            print 'Decreasing creation size beneficial at %r' % s
            s[3] -= 2
    for s in strategies:
        print s
    print 'Chain quality (per miner):', [(b * 100 / c) if c else 0 for b, c in zip(blks, created)]
    print 'Chain quality (total, non-perturbed miners only):', sum(blks[::NUM_TESTS]) * 1.0 / sum(created[::NUM_TESTS])
    if r % 20 == 0:
        print 'Control round'
        results, blks, created = simulate(strategies)
        print 'Chain quality (per miner):', [(b * 100 / c) if c else 0 for b, c in zip(blks, created)]
        print 'Chain quality (total):', sum(blks) * 1.0 / sum(created)
        
    
# results = simulate(strategies)
# for s, r in zip(strategies, results):
#     print s[0], s[3], r
Added BU evo model 2016-12-02 08:47:45 +00:00			`# The purpose of this script is to create an evolutionary`
			`# model to study the equilibrium effects of Bitcoin Unlimited-style`
			`# "emergent consensus". Note that the model is not yet quite`
			`# complete as it does not take into account the benefits of`
			`# mining "sister blocks" that steal transaction fees, though it`
			`# does give a rough idea of what equilibrium behavior`
			`# among the various miner policy dimensions (block accept size,`
			`# override depth, block creation size) looks like`
			`import random`

			`# Block reward`
			`REWARD = 1000`
			`# Call this function to get a tx with the right fee`
			`TX_FEE_DISTRIBUTION = lambda: (10000 // random.randrange(5, 250)) * 0.01`
			`# TX_FEE_DISTRIBUTION = lambda: 20`
			`# Propagation time`
			`PROPTIME_FACTOR = 1`

			`# List of tuples:`
			`# (default limit, n-block limit, acceptance depth, creation limit)`
			`strategies = []`
			`for i in range(4):`
			`for j in range(4):`
			`strategies.append([2 + i * 2, 100, 3, 10 + j * 4])`

			`class Block():`
			`def __init__(self, parent, size, fees, miner):`
			`self.hash = random.randrange(10**20)`
			`self.parent = parent`
			`self.score = 1 if self.parent is None else parent.score + 1`
			`self.miner = miner`
			`self.size = size`
			`self.fees = fees`

			`class Miner():`
			`def __init__(self, strategy, id):`
			`self.limit, self.big_limit, self.accept_depth, self.creation_limit = strategy`
			`self.chain = {}`
			`self.big_chain = {}`
			`self.head = None`
			`self.big_head = None`
			`self.id = id`
			`self.future = {}`
			`self.children = {}`
			`self.created = 0`

			`def process_history(self, time):`
			`deletes = []`
			`for t in self.future:`
			`if t <= time:`
			`for b in self.future[t]:`
			`self.process_block(b)`
			`deletes.append(t)`
			`for t in deletes:`
			`del self.future[t]`

			`def add_block(self, block, time):`
			`self.process_history(time)`
			`if time + int(block.size * PROPTIME_FACTOR) not in self.future:`
			`self.future[time + int(block.size * PROPTIME_FACTOR)] = [block]`
			`else:`
			`self.future[time + int(block.size * PROPTIME_FACTOR)].append(block)`

			`def process_block(self, block):`
			`if block.size <= self.limit and (block.parent is None or block.parent.hash in self.chain):`
			`self.chain[block.hash] = block`
			`if block.score > (self.head.score if self.head else 0):`
			`self.head = block`
			`if block.size <= self.big_limit and (block.parent is None or block.parent.hash in self.big_chain):`
			`self.big_chain[block.hash] = block`
			`if block.score > (self.big_head.score if self.big_head else 0):`
			`self.big_head = block`
			`if block.score > (self.head.score if self.head else 0) + self.accept_depth:`
			`self.head = block`
			`self.chain[block.hash] = block`
			`if block.parent and block.parent.hash not in self.chain and block.parent.hash not in self.big_chain:`
			`if block.parent.hash not in self.children:`
			`self.children[block.parent.hash] = [block]`
			`else:`
			`self.children[block.parent.hash].append(block)`
			`if block.hash in self.children:`
			`for c in self.children[block.hash]:`
			`self.process_block(c)`
			`del self.children[block.hash]`

			`def create_block(self, backlog, time):`
			`self.process_history(time)`
			`fees = sum(backlog[:self.creation_limit])`
			`# print 'Creating block of size %d (fees %d, seq %d)' % (self.creation_limit, fees, self.head.score + 1 if self.head else 1)`
			`self.created += 1`
			`return Block(self.head, self.creation_limit, fees, self.id)`


			`def simulate(strats):`
			`miners = [Miner(strat, i) for i, strat in enumerate(strats)]`
			`backlog = []`
			`for i in range(100000):`
			`if i % 10000 == 0:`
			`print 'Progress %d' % i`
			`backlog.append(TX_FEE_DISTRIBUTION())`
			`if random.random() < 0.01:`
			`backlog = sorted(backlog)[::-1]`
			`miner = random.choice(miners)`
			`b = miner.create_block(backlog, i)`
			`backlog = backlog[b.size:]`
			`for m in miners:`
			`m.add_block(b, i)`
			`rewards = [0] * len(miners)`
			`blocks = [0] * len(miners)`
			`h = miners[0].head`
			`sz = 0`
			`while h is not None:`
			`rewards[h.miner] += REWARD + h.fees`
			`blocks[h.miner] += 1`
			`h = h.parent`
			`sz += 1`
			`return rewards, blocks, [m.created for m in miners]`

			`for r in range(200):`
			`tests = []`
			`for s in strategies:`
			`tests.append(s)`
			`tests.append((s[0] - 2, s[1], s[2], s[3]))`
			`tests.append((s[0] + 2, s[1], s[2], s[3]))`
			`tests.append((s[0], s[1], s[2] - 1, s[3]))`
			`tests.append((s[0], s[1], s[2] + 1, s[3]))`
			`tests.append((s[0], s[1], s[2], s[3] - 2))`
			`tests.append((s[0], s[1], s[2], s[3] + 2))`
			`NUM_TESTS = 7`
			`print 'Starting simulation'`
			`results, blks, created = simulate(tests)`
			`for i, s in enumerate(strategies):`
			`base = results[i * NUM_TESTS]`
			`if results[i * NUM_TESTS + 1] < base < results[i * NUM_TESTS + 2]:`
			`print 'Increasing base accept size beneficial at %r' % s`
			`s[0] += 2`
			`if results[i * NUM_TESTS + 1] > base > results[i * NUM_TESTS + 2] and s[0] > 2:`
			`print 'Decreasing base accept size beneficial at %r' % s`
			`s[0] -= 2`
			`if results[i * NUM_TESTS + 3] < base < results[i * NUM_TESTS + 4]:`
			`print 'Increasing override depth beneficial at %r' % s`
			`s[2] += 1`
			`if results[i * NUM_TESTS + 3] > base > results[i * NUM_TESTS + 4] and s[2] > 1:`
			`print 'Decreasing override depth beneficial at %r' % s`
			`s[2] -= 1`
			`if results[i * NUM_TESTS + 5] < base < results[i * NUM_TESTS + 6]:`
			`print 'Increasing creation size beneficial at %r' % s`
			`s[3] += 2`
			`if results[i * NUM_TESTS + 5] > base > results[i * NUM_TESTS + 6] and s[3] > 2:`
			`print 'Decreasing creation size beneficial at %r' % s`
			`s[3] -= 2`
			`for s in strategies:`
			`print s`
			`print 'Chain quality (per miner):', [(b * 100 / c) if c else 0 for b, c in zip(blks, created)]`
			`print 'Chain quality (total, non-perturbed miners only):', sum(blks[::NUM_TESTS]) * 1.0 / sum(created[::NUM_TESTS])`
			`if r % 20 == 0:`
			`print 'Control round'`
			`results, blks, created = simulate(strategies)`
			`print 'Chain quality (per miner):', [(b * 100 / c) if c else 0 for b, c in zip(blks, created)]`
			`print 'Chain quality (total):', sum(blks) * 1.0 / sum(created)`



			`# results = simulate(strategies)`
			`# for s, r in zip(strategies, results):`
			`# print s[0], s[3], r`