djrtwo/casper_rewards.py

## casper_rewards.py
import argparse
import math
from copy import copy


def sqrt_of_total_deposits(deposits):
    return math.sqrt(deposits)


def reward_vote(deposit, reward_factor):
    return deposit * (1 + reward_factor)


def collective_reward(deposits, vote_fraction, reward_factor):
    return [
        deposit * (1 + vote_fraction * reward_factor / 2) / (1 + reward_factor)
        for deposit in deposits
    ]


def update_reward_factor(total_deposits, esf, base_interest_factor, base_penalty_factor):
    return base_interest_factor / sqrt_of_total_deposits(total_deposits) \
           + base_penalty_factor * esf


def calculate_annual_interest(initial_deposits, fraction_vote, base_interest_factor, base_penalty_factor):
    # 1/14.0 (blocks/second) * 86400 (seconds/day) * 365 (days/year) * 1/50 (epochs/block)
    epochs_per_year = (86400 * 365) / (14 * 50)
    reward_factor = 0
    deposits = copy(initial_deposits)
    for epoch in range(epochs_per_year):
        num_voted = int(len(deposits) * fraction_vote)
        deposits = collective_reward(deposits, fraction_vote, reward_factor)
        deposits = [reward_vote(deposit, reward_factor) for deposit in deposits[:num_voted]]
        reward_factor = update_reward_factor(
            sum(deposits),
            2,
            base_interest_factor,
            base_penalty_factor
        )

    initial_total = sum(initial_deposits)
    end_total = sum(deposits)
    issuance = end_total - initial_total
    interest = issuance / initial_total
    percent_gain = interest * 100

    print("interest_factor:\t%f" % base_interest_factor)
    print("initial:\t\t%s" % initial_total)
    print("end:\t\t\t%s" % end_total)
    print("issuance:\t\t%s" % issuance)
    print("interest:\t\t%.2f%%" % percent_gain)
    print("")

    return percent_gain


def calculate_validator_half_life(initial_deposits, fraction_offline, base_interest_factor, base_penalty_factor):
    split_index = int(len(initial_deposits) * (1 - fraction_offline))
    voting = initial_deposits[:split_index]
    offline = initial_deposits[split_index:]
    initial_offline_total = sum(offline)
    reward_factor = 0.0
    esf = 2
    epoch_count = 0
    while sum(offline) > 0.5 * initial_offline_total:
        fraction_voted = sum(voting) / float((sum(voting + offline)))
        voting = collective_reward(voting, fraction_voted, reward_factor)
        offline = collective_reward(offline, fraction_voted, reward_factor)
        voting = [reward_vote(deposit, reward_factor) for deposit in voting]

        if fraction_voted >= 2/3.0:
            esf = 2
        else:
            esf += 1

        reward_factor = update_reward_factor(
            sum(voting + offline),
            esf,
            base_interest_factor,
            base_penalty_factor
        )

        epoch_count += 1

    return epoch_count


def calculate_interest_factor(target_annual_interest, initial_deposits):
    interest_factor = 0.01
    while True:
        percent_gain = calculate_annual_interest(initial_deposits, 1.0, interest_factor, 0)
        if percent_gain > (target_annual_interest * 0.97) and percent_gain < (target_annual_interest * 1.03):
            return interest_factor

        if percent_gain > target_annual_interest:
            interest_factor = interest_factor * 0.9
        else:
            interest_factor = interest_factor * 1.1


def calculate_penalty_factor(target_day_half_life, initial_deposits,
                             interest_factor, fraction_offline):
    penalty_factor = 0.0005
    while True:
        epoch_half_life = calculate_validator_half_life(initial_deposits, fraction_offline,
                                                        interest_factor, penalty_factor)
        # 1/14.0 (blocks/second) * 86400 (seconds/day) * 1/50 (epochs/block)
        epochs_per_day = 86400 / (14.0 * 50)
        day_half_life = epoch_half_life / epochs_per_day
        print("penalty:\t%.6f" % penalty_factor)
        print("epochs:\t\t%s" % epoch_half_life)
        print("days:\t\t%.2f" % day_half_life)
        print("")

        if day_half_life > (target_day_half_life * 0.95) and day_half_life < (target_day_half_life * 1.05):
            return penalty_factor
        if day_half_life > target_day_half_life:
            penalty_factor = penalty_factor * 1.2
        else:
            penalty_factor = penalty_factor * 0.8


def main():
    parser = argparse.ArgumentParser(description='Run FFG reward script.')
    parser.add_argument(
        'target_interest', type=float,
        help='the target annual interest as a percent'
    )
    parser.add_argument(
        'target_half_life', type=int,
        help='the target half_life of inactive validators in days'
    )
    parser.add_argument(
        '--offline', type=float, default=0.5,
        help='the percentage of validators that go offline for penalty calculation'
    )
    parser.add_argument(
        '--total-deposits', type=float, default=10000000,
        help='the total initial deposits'
    )

    args = parser.parse_args()

    num_validators = 100
    deposit_size = args.total_deposits / num_validators
    initial_deposits = [deposit_size for i in range(num_validators)]  # target 10 million ether
    assert args.total_deposits == sum(initial_deposits)

    interest_factor = calculate_interest_factor(args.target_interest, initial_deposits)
    penalty_factor = calculate_penalty_factor(args.target_half_life, initial_deposits, interest_factor, args.offline)

    print("interest_factor:\t%f" % interest_factor)
    print("penalty_factor:\t\t%f" % penalty_factor)


if __name__ == '__main__':
    main()
	import argparse
	import math
	from copy import copy


	def sqrt_of_total_deposits(deposits):
	return math.sqrt(deposits)


	def reward_vote(deposit, reward_factor):
	return deposit * (1 + reward_factor)


	def collective_reward(deposits, vote_fraction, reward_factor):
	return [
	deposit * (1 + vote_fraction * reward_factor / 2) / (1 + reward_factor)
	for deposit in deposits
	]


	def update_reward_factor(total_deposits, esf, base_interest_factor, base_penalty_factor):
	return base_interest_factor / sqrt_of_total_deposits(total_deposits) \
	+ base_penalty_factor * esf


	def calculate_annual_interest(initial_deposits, fraction_vote, base_interest_factor, base_penalty_factor):
	# 1/14.0 (blocks/second) * 86400 (seconds/day) * 365 (days/year) * 1/50 (epochs/block)
	epochs_per_year = (86400 * 365) / (14 * 50)
	reward_factor = 0
	deposits = copy(initial_deposits)
	for epoch in range(epochs_per_year):
	num_voted = int(len(deposits) * fraction_vote)
	deposits = collective_reward(deposits, fraction_vote, reward_factor)
	deposits = [reward_vote(deposit, reward_factor) for deposit in deposits[:num_voted]]
	reward_factor = update_reward_factor(
	sum(deposits),
	2,
	base_interest_factor,
	base_penalty_factor
	)

	initial_total = sum(initial_deposits)
	end_total = sum(deposits)
	issuance = end_total - initial_total
	interest = issuance / initial_total
	percent_gain = interest * 100

	print("interest_factor:\t%f" % base_interest_factor)
	print("initial:\t\t%s" % initial_total)
	print("end:\t\t\t%s" % end_total)
	print("issuance:\t\t%s" % issuance)
	print("interest:\t\t%.2f%%" % percent_gain)
	print("")

	return percent_gain


	def calculate_validator_half_life(initial_deposits, fraction_offline, base_interest_factor, base_penalty_factor):
	split_index = int(len(initial_deposits) * (1 - fraction_offline))
	voting = initial_deposits[:split_index]
	offline = initial_deposits[split_index:]
	initial_offline_total = sum(offline)
	reward_factor = 0.0
	esf = 2
	epoch_count = 0
	while sum(offline) > 0.5 * initial_offline_total:
	fraction_voted = sum(voting) / float((sum(voting + offline)))
	voting = collective_reward(voting, fraction_voted, reward_factor)
	offline = collective_reward(offline, fraction_voted, reward_factor)
	voting = [reward_vote(deposit, reward_factor) for deposit in voting]

	if fraction_voted >= 2/3.0:
	esf = 2
	else:
	esf += 1

	reward_factor = update_reward_factor(
	sum(voting + offline),
	esf,
	base_interest_factor,
	base_penalty_factor
	)

	epoch_count += 1

	return epoch_count


	def calculate_interest_factor(target_annual_interest, initial_deposits):
	interest_factor = 0.01
	while True:
	percent_gain = calculate_annual_interest(initial_deposits, 1.0, interest_factor, 0)
	if percent_gain > (target_annual_interest * 0.97) and percent_gain < (target_annual_interest * 1.03):
	return interest_factor

	if percent_gain > target_annual_interest:
	interest_factor = interest_factor * 0.9
	else:
	interest_factor = interest_factor * 1.1


	def calculate_penalty_factor(target_day_half_life, initial_deposits,
	interest_factor, fraction_offline):
	penalty_factor = 0.0005
	while True:
	epoch_half_life = calculate_validator_half_life(initial_deposits, fraction_offline,
	interest_factor, penalty_factor)
	# 1/14.0 (blocks/second) * 86400 (seconds/day) * 1/50 (epochs/block)
	epochs_per_day = 86400 / (14.0 * 50)
	day_half_life = epoch_half_life / epochs_per_day
	print("penalty:\t%.6f" % penalty_factor)
	print("epochs:\t\t%s" % epoch_half_life)
	print("days:\t\t%.2f" % day_half_life)
	print("")

	if day_half_life > (target_day_half_life * 0.95) and day_half_life < (target_day_half_life * 1.05):
	return penalty_factor
	if day_half_life > target_day_half_life:
	penalty_factor = penalty_factor * 1.2
	else:
	penalty_factor = penalty_factor * 0.8


	def main():
	parser = argparse.ArgumentParser(description='Run FFG reward script.')
	parser.add_argument(
	'target_interest', type=float,
	help='the target annual interest as a percent'
	)
	parser.add_argument(
	'target_half_life', type=int,
	help='the target half_life of inactive validators in days'
	)
	parser.add_argument(
	'--offline', type=float, default=0.5,
	help='the percentage of validators that go offline for penalty calculation'
	)
	parser.add_argument(
	'--total-deposits', type=float, default=10000000,
	help='the total initial deposits'
	)

	args = parser.parse_args()

	num_validators = 100
	deposit_size = args.total_deposits / num_validators
	initial_deposits = [deposit_size for i in range(num_validators)] # target 10 million ether
	assert args.total_deposits == sum(initial_deposits)

	interest_factor = calculate_interest_factor(args.target_interest, initial_deposits)
	penalty_factor = calculate_penalty_factor(args.target_half_life, initial_deposits, interest_factor, args.offline)

	print("interest_factor:\t%f" % interest_factor)
	print("penalty_factor:\t\t%f" % penalty_factor)


	if __name__ == '__main__':
	main()