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Eric 1d161d383e
Slot queue (#455) 
## Slot queue
Adds a slot queue, as per the [slot queue design](https://github.com/codex-storage/codex-research/blob/master/design/sales.md#slot-queue).

Any time storage is requested, all slots from that request are immediately added to the queue. Finished, Canclled, Failed requests remove all slots with that request id from the queue. SlotFreed events add a new slot to the queue and SlotFilled events remove the slot from the queue. This allows popping of a slot each time one is processed, making things much simpler.

When an entire request of slots is added to the queue, the slot indices are shuffled randomly to hopefully prevent nodes that pick up the same storage requested event from clashing on the first processed slot index. This allowed removal of assigning a random slot index in the SalePreparing state and it also ensured that all SalesAgents will have a slot index assigned to them at the start thus the removal of the optional slotIndex.

Remove slotId from SlotFreed event as it was not being used. RequestId and slotIndex were added to the SlotFreed event earlier and those are now being used

The slot queue invariant that prioritises queue items added to the queue relies on a scoring mechanism to sort them based on the [sort order in the design document](https://github.com/codex-storage/codex-research/blob/master/design/sales.md#sort-order).

When a storage request is handled by the sales module, a slot index was randomly assigned and then the slot was filled. Now, a random slot index is only assigned when adding an entire request to the slot queue. Additionally, the slot is checked that its state is `SlotState.Free` before continuing with the download process.

SlotQueue should always ensure the underlying AsyncHeapQueue has one less than the maximum items, ensuring the SlotQueue can always have space to add an additional item regardless if it’s full or not.

Constructing `SlotQueue.workers` in `SlotQueue.new` calls `newAsyncQueue` which causes side effects, so the construction call had to be moved to `SlotQueue.start`.

Prevent loading request from contract (network request) if there is an existing item in queue for that request.

Check availability before adding request to queue.

Add ability to query market contract for past events. When new availabilities are added, the `onReservationAdded` callback is triggered in which past `StorageRequested` events are queried, and those slots are added to the queue (filtered by availability on `push` and filtered by state in `SalePreparing`).

#### Request Workers
Limit the concurrent requests being processed in the queue by using a limited pool of workers (default = 3). Workers are in a data structure of type `AsyncQueue[SlotQueueWorker]`. This allows us to await a `popFirst` for available workers inside of the main SlotQueue event loop

Add an `onCleanUp` that stops the agents and removes them from the sales module agent list. `onCleanUp` is called from sales end states (eg ignored, cancelled, finished, failed, errored).

Add a `doneProcessing` future to `SlotQueueWorker` to be completed in the `OnProcessSlot` callback. Each `doneProcessing` future created is cancelled and awaited in `SlotQueue.stop` (thanks to `TrackableFuturees`), which forced `stop` to become async.
  - Cancel dispatched workers and the `onProcessSlot` callbacks, prevents zombie callbacks

#### Add TrackableFutures
Allow tracking of futures in a module so they can be cancelled at a later time. Useful for asyncSpawned futures, but works for any future.

### Sales module
The sales module needed to subscribe to request events to ensure that the request queue was managed correctly on each event. In the process of doing this, the sales agents were updated to avoid subscribing to events in each agent, and instead dispatch received events from the sales module to all created sales agents. This would prevent memory leaks on having too many eventemitters subscribed to.
  - prevent removal of agents from sales module while stopping, otherwise the agents seq len is modified while iterating

An additional sales agent state was added, `SalePreparing`, that handles all state machine setup, such as retrieving the request and subscribing to events that were previously in the `SaleDownloading` state.

Once agents have parked in an end state (eg ignored, cancelled, finished, failed, errored), they were not getting cleaned up and the sales module was keeping a handle on their reference. An `onCleanUp` callback was created to be called after the state machine enters an end state, which could prevent a memory leak if the number of requests coming in is high.

Move the SalesAgent callback raises pragmas from the Sales module to the proc definition in SalesAgent. This avoids having to catch `Exception`.
  - remove unneeded error handling as pragmas were moved

Move sales.subscriptions from an object containing named subscriptions to a `seq[Subscription]` directly on the sales object.

Sales tests: shut down repo after sales stop, to fix SIGABRT in CI

### Add async Promise API
  - modelled after JavaScript Promise API
  - alternative to `asyncSpawn` that allows handling of async calls in a synchronous context (including access to the synchronous closure) with less additional procs to be declared
  - Write less code, catch errors that would otherwise defect in asyncspawn, and execute a callback after completion
  - Add cancellation callbacks to utils/then, ensuring cancellations are handled properly

## Dependencies
- bump codex-contracts-eth to support slot queue (https://github.com/codex-storage/codex-contracts-eth/pull/61)
- bump nim-ethers to 0.5.0
- Bump nim-json-rpc submodule to 0bf2bcb

---------

Co-authored-by: Jaremy Creechley <creechley@gmail.com>
 		2023-07-25 12:50:30 +10:00
..
interactions Improving proc/func formatting consistency (#454) 2023-06-22 08:11:18 -07:00
Readme.md feat: collateral per slot (#390) 2023-04-14 11:04:17 +02:00
clock.nim Slot queue (#455) 2023-07-25 12:50:30 +10:00
config.nim feat: collateral per slot (#390) 2023-04-14 11:04:17 +02:00
deployment.nim feat: contract address management (#405) 2023-05-03 09:24:25 +02:00
interactions.nim Validator (#387) 2023-04-19 15:06:00 +02:00
market.nim Slot queue (#455) 2023-07-25 12:50:30 +10:00
marketplace.nim Slot queue (#455) 2023-07-25 12:50:30 +10:00
requests.nim Slot queue (#455) 2023-07-25 12:50:30 +10:00

Readme.md

Codex Contracts in Nim

Nim API for the Codex smart contracts.

Usage

For a global overview of the steps involved in starting and fulfilling a storage contract, see Codex Contracts.

Smart contract

Connecting to the smart contract on an Ethereum node:

import codex/contracts
import ethers

let address = # fill in address where the contract was deployed
let provider = JsonRpcProvider.new("ws://localhost:8545")
let marketplace = Marketplace.new(address, provider)

Setup client and host so that they can sign transactions; here we use the first two accounts on the Ethereum node:

let accounts = await provider.listAccounts()
let client = provider.getSigner(accounts[0])
let host = provider.getSigner(accounts[1])

Storage requests

Creating a request for storage:

let request : StorageRequest = (
  client:           # address of the client requesting storage
  duration:         # duration of the contract in seconds
  size:             # size in bytes
  contentHash:      # SHA256 hash of the content that's going to be stored
  proofProbability: # require a storage proof roughly once every N periods
  maxPrice:         # maximum price the client is willing to pay
  expiry:           # expiration time of the request (in unix time)
  nonce:            # random nonce to differentiate between similar requests
)

When a client wants to submit this request to the network, it needs to pay the maximum price to the smart contract in advance. The difference between the maximum price and the offered price will be reimbursed later.

Once the payment has been prepared, the client can submit the request to the network:

await storage
  .connect(client)
  .requestStorage(request)

Storage offers

Creating a storage offer:

let offer: StorageOffer = (
  host:       # address of the host that is offering storage
  requestId:  request.id,
  price:      # offered price (in number of tokens)
  expiry:     # expiration time of the offer (in unix time)
)

Hosts submits an offer:

await storage
  .connect(host)
  .offerStorage(offer)

Client selects an offer:

await storage
  .connect(client)
  .selectOffer(offer.id)

Starting and finishing a storage contract

The host whose offer got selected can start the storage contract once it received the data that needs to be stored:

await storage
  .connect(host)
  .startContract(offer.id)

Once the storage contract is finished, the host can release payment:

await storage
  .connect(host)
  .finishContract(id)

Storage proofs

Time is divided into periods, and each period a storage proof may be required from the host. The odds of requiring a storage proof are negotiated through the storage request. For more details about the timing of storage proofs, please refer to the design document.

At the start of each period of time, the host can check whether a storage proof is required:

let isProofRequired = await storage.isProofRequired(offer.id)

If a proof is required, the host can submit it before the end of the period:

await storage
  .connect(host)
  .submitProof(id, proof)

If a proof is not submitted, then a validator can mark a proof as missing:

await storage
  .connect(validator)
  .markProofAsMissing(id, period)