# Nimbus # Copyright (c) 2023-2024 Status Research & Development GmbH # Licensed and distributed under either of # * MIT license (license terms in the root directory or at # https://opensource.org/licenses/MIT). # * Apache v2 license (license terms in the root directory or at # https://www.apache.org/licenses/LICENSE-2.0). # at your option. This file may not be copied, modified, or distributed # except according to those terms. {.push raises:[].} import pkg/[chronicles, chronos], pkg/eth/[common, p2p], pkg/stew/[interval_set, sorted_set], ../../common, ./worker/[blocks_staged, headers_staged, headers_unproc, start_stop, update], ./worker_desc # ------------------------------------------------------------------------------ # Private functions # ------------------------------------------------------------------------------ proc headersToFetchOk(buddy: BeaconBuddyRef): bool = 0 < buddy.ctx.headersUnprocTotal() and buddy.ctrl.running and not buddy.ctx.poolMode proc bodiesToFetchOk(buddy: BeaconBuddyRef): bool = buddy.ctx.blocksStagedFetchOk() and buddy.ctrl.running and not buddy.ctx.poolMode proc napUnlessSomethingToFetch( buddy: BeaconBuddyRef; ): Future[bool] {.async: (raises: []).} = ## When idle, save cpu cycles waiting for something to do. if buddy.ctx.pool.blockImportOk or # currently importing blocks buddy.ctx.hibernate or # not activated yet? not (buddy.headersToFetchOk() or # something on TODO list buddy.bodiesToFetchOk()): try: await sleepAsync workerIdleWaitInterval except CancelledError: buddy.ctrl.zombie = true return true else: return false # ------------------------------------------------------------------------------ # Public start/stop and admin functions # ------------------------------------------------------------------------------ proc setup*(ctx: BeaconCtxRef; info: static[string]): bool = ## Global set up ctx.setupRpcMagic info # Load initial state from database if there is any ctx.setupDatabase info # Debugging stuff, might be an empty template ctx.setupTicker() true proc release*(ctx: BeaconCtxRef; info: static[string]) = ## Global clean up ctx.destroyRpcMagic() ctx.destroyTicker() proc start*(buddy: BeaconBuddyRef; info: static[string]): bool = ## Initialise worker peer let peer = buddy.peer if runsThisManyPeersOnly <= buddy.ctx.pool.nBuddies: if not buddy.ctx.hibernate: debug info & ": peers limit reached", peer return false if not buddy.startBuddy(): if not buddy.ctx.hibernate: debug info & ": failed", peer return false if not buddy.ctx.hibernate: debug info & ": new peer", peer true proc stop*(buddy: BeaconBuddyRef; info: static[string]) = ## Clean up this peer if not buddy.ctx.hibernate: debug info & ": release peer", peer=buddy.peer, ctrl=buddy.ctrl.state, nLaps=buddy.only.nMultiLoop, lastIdleGap=buddy.only.multiRunIdle.toStr buddy.stopBuddy() # ------------------------------------------------------------------------------ # Public functions # ------------------------------------------------------------------------------ proc runDaemon*( ctx: BeaconCtxRef; info: static[string]; ) {.async: (raises: []).} = ## Global background job that will be re-started as long as the variable ## `ctx.daemon` is set `true`. If that job was stopped due to re-setting ## `ctx.daemon` to `false`, it will be restarted next after it was reset ## as `true` not before there is some activity on the `runPool()`, ## `runSingle()`, or `runMulti()` functions. ## ## On a fresh start, the flag `ctx.daemon` will not be set `true` before the ## first usable request from the CL (via RPC) stumbles in. ## # Check for a possible header layout and body request changes ctx.updateSyncState info if ctx.hibernate: return # Execute staged block records. if ctx.blocksStagedCanImportOk(): block: # Set advisory flag telling that a slow/long running process will take # place. So there might be some peers active. If they are waiting for # a message reply, this will most probably time out as all processing # power is usurped by the import task here. ctx.pool.blockImportOk = true defer: ctx.pool.blockImportOk = false # Import from staged queue. while await ctx.blocksStagedImport(info): if not ctx.daemon: # Implied by external sync shutdown? return # At the end of the cycle, leave time to trigger refill headers/blocks try: await sleepAsync daemonWaitInterval except CancelledError: discard proc runPool*( buddy: BeaconBuddyRef; last: bool; laps: int; info: static[string]; ): bool = ## Once started, the function `runPool()` is called for all worker peers in ## sequence as long as this function returns `false`. There will be no other ## `runPeer()` functions activated while `runPool()` is active. ## ## This procedure is started if the global flag `buddy.ctx.poolMode` is set ## `true` (default is `false`.) The flag will be automatically reset before ## the loop starts. Re-setting it again results in repeating the loop. The ## argument `laps` (starting with `0`) indicated the currend lap of the ## repeated loops. ## ## The argument `last` is set `true` if the last entry is reached. ## ## Note that this function does not run in `async` mode. ## buddy.ctx.headersStagedReorg info true # stop proc runPeer*( buddy: BeaconBuddyRef; info: static[string]; ) {.async: (raises: []).} = ## This peer worker method is repeatedly invoked (exactly one per peer) while ## the `buddy.ctrl.poolMode` flag is set `false`. ## if 0 < buddy.only.nMultiLoop: # statistics/debugging buddy.only.multiRunIdle = Moment.now() - buddy.only.stoppedMultiRun buddy.only.nMultiLoop.inc # statistics/debugging # Update consensus header target when needed. It comes with a finalised # header hash where we need to complete the block number. await buddy.headerStagedUpdateTarget info if not await buddy.napUnlessSomethingToFetch(): # # Layout of a triple of linked header chains (see `README.md`) # :: # 0 C D H # | <--- [0,C] --> | <----- (C,D) -----> | <-- [D,H] ---> | # o----------------o---------------------o----------------o---> # | <-- linked --> | <-- unprocessed --> | <-- linked --> | # # This function is run concurrently for fetching the next batch of # headers and stashing them on the database. Each concurrently running # actor works as follows: # # * Get a range of block numbers from the `unprocessed` range `(C,D)`. # * Fetch headers for this range (as much as one can get). # * Stash then on the database. # * Rinse and repeat. # # The block numbers range concurrently taken from `(C,D)` are chosen # from the upper range. So exactly one of the actors has a range # `[whatever,D-1]` adjacent to `[D,H]`. Call this actor the lead actor. # # For the lead actor, headers can be downloaded all by the hashes as # the parent hash for the header with block number `D` is known. All # other non-lead actors will download headers by the block number only # and stage it to be re-ordered and stashed on the database when ready. # # Once the lead actor stashes the dowloaded headers, the other staged # headers will also be stashed on the database until there is a gap or # the stashed haeders are exhausted. # # Due to the nature of the `async` logic, the current lead actor will # stay lead when fetching the next range of block numbers. # while buddy.headersToFetchOk(): # * Get unprocessed range from pool # * Fetch headers for this range (as much as one can get) # * Verify that a block is contiguous, chained by parent hash, etc. # * Stash this range on the staged queue on the pool if await buddy.headersStagedCollect info: # * Save updated state and headers # * Decrease the dangling left boundary `D` of the trusted range `[D,H]` discard buddy.ctx.headersStagedProcess info # Fetch bodies and combine them with headers to blocks to be staged. These # staged blocks are then excuted by the daemon process (no `peer` needed.) while buddy.bodiesToFetchOk(): discard await buddy.blocksStagedCollect info # Note that it is important **not** to leave this function to be # re-invoked by the scheduler unless necessary. While the time gap # until restarting is typically a few millisecs, there are always # outliers which well exceed several seconds. This seems to let # remote peers run into timeouts. buddy.only.stoppedMultiRun = Moment.now() # statistics/debugging # ------------------------------------------------------------------------------ # End # ------------------------------------------------------------------------------