2018-02-19 00:19:59 +00:00
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BSIP: 0035
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Title: A Solution To Something-For-Nothing Issue
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Author: Abit More <https://github.com/abitmore>
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Status: Draft
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Type: Protocol
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Created: 2018-02-19
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Discussion: https://github.com/bitshares/bitshares-core/issues/132,
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https://github.com/bitshares/bitshares-core/issues/184
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Replaces: -
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Worker: To be done
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# Abstract
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Under some circumstances, when two orders get matched, due to rounding,
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one order may be paying something but receiving nothing,
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the other order may be paying nothing but receiving something.
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This is the so-called something-for-nothing issue.
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This looks clearly unfair.
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This BSIP proposes an overall mechanism to avoid something-for-nothing issue
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completely.
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This BSIP also sets a principle: something-for-nothing shouldn't happen when
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matching orders.
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# Motivation
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There are mechanisms in the system to try to avoid something-for-nothing issue,
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however, not all scenarios are well-handled, see [bitshares-core
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issue #184](https://github.com/bitshares/bitshares-core/issues/184) for example.
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# Rationale
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## Amounts, Prices and Rounding
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Amounts in the system are integers with per-asset fixed precisions.
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The minimum positive amount of an asset is called one Satoshi.
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Prices in the system are rational numbers, which are expressed as
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`base_amount / quote_amount` (precisions are omitted here).
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To calculate how much amount of asset B is equivalent to some amount of
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asset A, need to calculate `amount_of_a * a_to_b_price` which is
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`amount_of_a * b_amount_in_price / a_amount_in_price`. The accurate result
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of this formula is a rational number. To convert it to the final result which
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is an amount, which is an integer, may need to round.
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## Order Matching
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An order means someone is willing to give out some amount of asset X expecting
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to get some amount of asset Y. The ratio between the two assets is the price of
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the order. The price can be expressed as either `x_amount / y_amount` or
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`y_amount / x_amount`, when we know which amount in the price is of which asset,
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the two expressions are equivalent. The amount of asset X is known and fixed.
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In a market, E.G. the X:Y market, some people are selling X for Y, some people
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are selling Y for X (or say buying X with Y). Orders are classified by type
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(buy or sell), then ordered by price. For each type, the order offering the
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best price is on the top. So, in every market there may be a top buy order and
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a top sell order, name them highest bid and lowest ask, so there is
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a highest bid price (in terms of `asset X amount / asset Y amount`),
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and a lowest ask price (in terms of `asset X amount / asset Y amount` as well).
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When the highest bid price is higher or equal to the lowest ask price, the two
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top orders can be matched with each other.
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## The Match Price
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In a continuous trading market, orders are placed one by one, when comparing
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every two orders, it's deterministic that one order is placed earlier than the
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other.
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In BitShares, it doesn't mean that the transaction that contains the first
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order is signed before the transaction contains the second, but means that
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the first order is processed earlier than the second in the witness node that
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produced the block that contains the second order.
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When two orders get matched, the one placed earlier is maker, the other one
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is taker. Say, the maker provides an offer, the taker accept the offer.
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So, when calculating who will get how much, we use the maker order's price,
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aka maker price, as the match price.
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## The Need for Compromise
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When matching two orders, due to rounding, usually we're unable to completely
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satisfy both parties.
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Here is an example mentioned in the 4th comment of [bitshares-core
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issue #132](https://github.com/bitshares/bitshares-core/issues/132):
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Alice's order: Sell CORE at $3 / 8, balance 1000000 CORE
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Bob's order: Buy CORE at $19 / 50, balance $10
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Both assets have precision of 1, i.e. the order balances are
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1000000 CORE-satoshis and 10 USD-satoshis repectively.
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Alice is selling at $3/8 CORE = $0.375 / CORE and Bob is buying at
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$19 / 50 CORE = $0.38, so based on the price, Alice and Bob should match.
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Bob's $10 / $0.38 ~ 26.3. So 26.3 is the fewest CORE he is willing to accept
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(assuming that the meaning of "price" is "the least favorable exchange rate
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a party is willing to accept in trade"). Combined with the design restriction
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that satoshis are indivisible, in practice this means Bob will only accept 27
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or more CORE for his $10.
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But $10 / 27 gives a price smaller than $0.370 and $0.371, which is smaller
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than Alice's sale price of $0.375. So neither party can fill this offer.
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We need to come to a compromise.
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## The Possible Solutions
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There are some possible solutions listed in the 5th comment of [bitshares-core
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issue #132](https://github.com/bitshares/bitshares-core/issues/132):
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- (a) Fill someone at a less favorable exchange rate than the price they
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specified in their order. Downside: This violates the above definition of
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price; i.e. if a user enters a price intending the system to never sell below
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that price in any circumstance, the system will not always behave in a way
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which fulfills that user intent.
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- (b) Keep both orders on the books. Downside: This complicates the matching
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algorithm, as now Alice might be able to match an order behind Bob's order.
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Naive implementation would have potentially unbounded matching complexity;
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a more clever implementation might be possible but would require substantial
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design and testing effort.
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- (c) Cancel an order. This is complicated by the fact that an order such as
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a margin call cannot be cancelled. Downside: When there are margin calls
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happening, it seems perverse to delete a large order that's willing to fill
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them just because the lead margin call happens to fall in a narrow window
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which causes a rounding issue. Also, orders cancelled by this mechanism
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cannot be refunded. Otherwise an attacker who wants to consume
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a lot of memory on all nodes could create a large number of orders, then
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trigger this case to cancel them all, getting their investment in deferred
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cancellation fees back without paying the cancel op's per-order fee as
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intended.
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- (d) Require all orders to use the same denominator. Altcoin exchanges and
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many real-world markets like the stock market solve this problem by specifying
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one asset as the denominator asset, specifying a "tick" which is the smallest
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unit of price precision, and requiring all prices to conform.
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Downside: Complicates the implementation of flipped market UI, may require
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re-working part of market GUI, reduces user flexibility, new asset fields
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required to specify precision, if `n` assets exist then `O(n^2)` markets
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could exist and we need to figure out how to determine the precision
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requirement for all of them.
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## The Chosen Solution
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Current code actually implemented (a) in the first place: when matching two
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orders, if there is a rounding issue, the order with smaller volume will be
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filled at a less favorable price. It's the least bad compromise since it has
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the most efficiency (highest traded volume while not hard to implement) among
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the solutions.
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However, when filling a small order at a less favorable price, the receiving
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amount is often rounded down to zero, thus causes the something-for-nothing
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issue. Current code tried to solve the issue by cancelling the smaller order
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2018-02-19 20:35:00 +00:00
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when it would receive nothing, but only applied this rule in a few senarios
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(the processed parties won't be paying something for nothing):
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2018-02-19 00:19:59 +00:00
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* when matching two limit orders, processed the maker
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* when matching a limit order with a call order, processed the call order
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* when matching a settle order with a call order, processed the call order
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* when globally settling, processed the call order
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2018-02-19 20:35:00 +00:00
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Other senarios that need to be processed as well (these to-be-processed parties
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may be paying something for nothing in current system):
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* when matching two limit orders, process the taker
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2018-02-19 20:35:00 +00:00
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* when matching a limit order with a call order, process the limit order
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2018-02-19 00:19:59 +00:00
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* when matching a force settle order with a call order, process the settle order
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* when globally settling, process the settlement fund
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## The Improved Solution (This BSIP)
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The detailed rules proposes in this BSIP (new rules highlighted):
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* match in favor of taker, or say, match at maker price
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* round down receiving amounts when possible
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* when matching two limit orders, round down the receiving amounts in favor
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of bigger order, or say, try to fill the smaller order
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* **if the smaller order would get nothing after the round-down, cancel it**
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* when matching a limit order with a call order, in favor of call order,
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round down receiving collateral amount
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2018-02-20 18:16:48 +00:00
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* **if the call order is receiving the whole debt amount (so the short
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position will be closed) but paying nothing, let it pay 1 Satoshi
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(round up);**
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* **otherwise, if the limit order would get nothing after the round-down,
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cancel it (it's smaller, so safe to cancel)**
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2018-02-19 00:19:59 +00:00
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* when matching a settle order with a call order, in favor of call order,
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round down receiving collateral amount
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2018-02-20 18:16:48 +00:00
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* **if the call order is receiving the whole debt amount (so the short
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position will be closed) but paying nothing, let it pay 1 Satoshi
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(round up);**
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* **otherwise, if the settle order would be completely filled but would
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receive nothing, cancel it;**
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* **otherwise, it means both orders won't be completely filled, which may
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due to hitting `maximum_force_settlement_volume`, in this case, don't fill
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any one of the two orders, and stop matching for this asset at this block;**
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* **that said, only round up when the call order is completely filled, so
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won't trigger a black swan event, nor need to check for it.**
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* when globally settling, in favor of call order, round down receiving
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collateral amount
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* **when the asset is not a prediction market, if a call order would pay
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nothing, let it pay 1 Satoshi (round up).**
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Take the example mentioned in the 4th comment of [bitshares-core
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issue #132](https://github.com/bitshares/bitshares-core/issues/132):
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* Alice's order: Sell CORE at `$3 / 8 = $0.375`, balance `1000000 CORE`
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* Bob's order: Buy CORE at `$19 / 50 = $0.38`, balance `$10`
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Process:
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* If both orders are limit orders
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* If Alice's order is maker, use `$3 / 8` as match price;
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since Bob's order is smaller, round in favor of Alice's order,
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so Bob will get
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`round_down($10 * 8 CORE / $3) = round_down(26.67 CORE) = 26 CORE`,
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the effective price would be `$10 / 26 CORE = $0.3846`.
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* If Bob's order is maker, use `$19 / 50` as match price; since Bob's
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order is smaller, round in favor of Alice's order, so Bob will get
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`round_down($10 * 50 CORE / $19 = round_down(26.32 CORE) = 26 CORE`,
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the effective price would still be `$10 / 26 CORE = $0.3846`.
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* If Alice's order is a call order, always round in favor of it, we get
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same results.
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If we change the example to this:
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* Alice's order: Buy CORE at `3 CORE / $8 = 0.375`, balance `$1000000`
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* Bob's order: Sell CORE at `19 CORE / $50 = 0.38`, balance `10 CORE`
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Process:
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* If both orders are limit orders, we get same results as above
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* If Bob's order is a call order, we should always round in favor of it,
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however, it should have a debt amount which is an integer, for example
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`$27`, then Alice would get
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* `round_down(27 * 3 / 8) = round_down(10.125) = 10 CORE` as a maker, or
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* `round_down(27 * 19 / 50) = round_down(10.26) = 10 CORE` as a taker.
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# Specifications
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## When Matching Two Limit Orders
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In `match( const limit_order_object&, OrderType ... )` function of `database`
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class, after calculated `usd_receives` which is for the taker,
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check if it is zero.
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If the answer is `true`, skip filling and see the order is filled, return `1`,
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so the order will be cancelled later.
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## When Matching A Limit Order With A Call Order
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In `check_call_orders(...)` function of `database` class,
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after calculated `order_receives`, check if it is zero.
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If the answer is `true`,
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2018-02-20 18:16:48 +00:00
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* if `call_receives` is equal to `call_itr->debt`, set `order_receives` to `1`;
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2018-02-19 20:35:00 +00:00
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* otherwise, skip filling and cancel the limit order.
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2018-02-19 00:19:59 +00:00
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## When Matching A Settle Order With A Call Order
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In `match( const call_order_object&, ... )` function of `database` class,
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after calculated `call_pays`, check if it is zero.
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If the answer is `true`,
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* if `call_receives` is equal to `call_debt`, set `call_pays` to `1`;
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* otherwise, if `call_receives` is equal to `settle.balance`,
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call `cancel_order(...)` with parameter set to `settle`,
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then return a zero-amount collateral asset object;
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* otherwise, return a zero-amount collateral asset object directly.
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After returned, need to check the amount of returned asset at where calling the
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`match(...)` function, specifically, `clear_expired_orders()` function of
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`database` class. If the returned amount is `0`, break out of the `while` loop.
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2018-02-19 00:19:59 +00:00
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## When Globally Settling
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In `global_settle_asset(...)` function of `database` class, check each `pays`,
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once it's zero, and the asset is not a prediction market, let it be `1`.
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# Discussion
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There is an argument suggests when matching call orders, we should always
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round in favour of the call. If a settlement receives 0 collateral as a result,
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that's acceptable, because the settlement price is unknown at the time when
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settlement is requested, so no guarantee is violated (within the range of
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rounding errors). This should keep the collateral > 0 as long as there is
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outstanding debt. A counter-argument supports rounding up to 1 Satoshi since
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rounding down to zero may break the promise of "every smart coin is backed
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by something".
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There is an argument says breaking the `min_to_receive` limit is a no-go,
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because that's why it's called a "limit order". A counter-argument says
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slightly breaking the limit is the least bad compromise.
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# Summary for Shareholders
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[to be added if any]
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# Copyright
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This document is placed in the public domain.
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# See Also
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* https://github.com/bitshares/bitshares-core/issues/132
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* https://github.com/bitshares/bitshares-core/issues/184
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