## Nim-Codex ## Copyright (c) 2022 Status Research & Development GmbH ## Licensed under either of ## * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE)) ## * MIT license ([LICENSE-MIT](LICENSE-MIT)) ## at your option. ## This file may not be copied, modified, or distributed except according to ## those terms. import pkg/upraises push: {.upraises: [].} import std/sequtils import std/sugar import pkg/chronos import pkg/libp2p/[multicodec, cid, multihash] import pkg/libp2p/protobuf/minprotobuf import ../logutils import ../manifest import ../merkletree import ../stores import ../blocktype as bt import ../utils import ../utils/asynciter import ../indexingstrategy import pkg/stew/byteutils import ./backend export backend logScope: topics = "codex erasure" type ## Encode a manifest into one that is erasure protected. ## ## The new manifest has K `blocks` that are encoded into ## additional M `parity` blocks. The resulting dataset ## is padded with empty blocks if it doesn't have a square ## shape. ## ## NOTE: The padding blocks could be excluded ## from transmission, but they aren't for now. ## ## The resulting dataset is logically divided into rows ## where a row is made up of B blocks. There are then, ## K + M = N rows in total, each of length B blocks. Rows ## are assumed to be of the same number of (B) blocks. ## ## The encoding is systematic and the rows can be ## read sequentially by any node without decoding. ## ## Decoding is possible with any K rows or partial K ## columns (with up to M blocks missing per column), ## or any combination there of. ## EncoderProvider* = proc(size, blocks, parity: int): EncoderBackend {.raises: [Defect], noSideEffect.} DecoderProvider* = proc(size, blocks, parity: int): DecoderBackend {.raises: [Defect], noSideEffect.} Erasure* = ref object encoderProvider*: EncoderProvider decoderProvider*: DecoderProvider store*: BlockStore EncodingParams = object ecK: Natural ecM: Natural rounded: Natural steps: Natural blocksCount: Natural strategy: StrategyType func indexToPos(steps, idx, step: int): int {.inline.} = ## Convert an index to a position in the encoded ## dataset ## `idx` - the index to convert ## `step` - the current step ## `pos` - the position in the encoded dataset ## (idx - step) div steps proc getPendingBlocks( self: Erasure, manifest: Manifest, indices: seq[int]): AsyncIter[(?!bt.Block, int)] = ## Get pending blocks iterator ## var # request blocks from the store pendingBlocks = indices.map( (i: int) => self.store.getBlock( BlockAddress.init(manifest.treeCid, i) ).map((r: ?!bt.Block) => (r, i)) # Get the data blocks (first K) ) proc isFinished(): bool = pendingBlocks.len == 0 proc genNext(): Future[(?!bt.Block, int)] {.async.} = let completedFut = await one(pendingBlocks) if (let i = pendingBlocks.find(completedFut); i >= 0): pendingBlocks.del(i) return await completedFut else: let (_, index) = await completedFut raise newException( CatchableError, "Future for block id not found, tree cid: " & $manifest.treeCid & ", index: " & $index) Iter.new(genNext, isFinished) proc prepareEncodingData( self: Erasure, manifest: Manifest, params: EncodingParams, step: Natural, data: ref seq[seq[byte]], cids: ref seq[Cid], emptyBlock: seq[byte]): Future[?!Natural] {.async.} = ## Prepare data for encoding ## let strategy = params.strategy.init( firstIndex = 0, lastIndex = params.rounded - 1, iterations = params.steps ) indices = toSeq(strategy.getIndices(step)) pendingBlocksIter = self.getPendingBlocks(manifest, indices.filterIt(it < manifest.blocksCount)) var resolved = 0 for fut in pendingBlocksIter: let (blkOrErr, idx) = await fut without blk =? blkOrErr, err: warn "Failed retreiving a block", treeCid = manifest.treeCid, idx, msg = err.msg continue let pos = indexToPos(params.steps, idx, step) shallowCopy(data[pos], if blk.isEmpty: emptyBlock else: blk.data) cids[idx] = blk.cid resolved.inc() for idx in indices.filterIt(it >= manifest.blocksCount): let pos = indexToPos(params.steps, idx, step) trace "Padding with empty block", idx shallowCopy(data[pos], emptyBlock) without emptyBlockCid =? emptyCid(manifest.version, manifest.hcodec, manifest.codec), err: return failure(err) cids[idx] = emptyBlockCid success(resolved.Natural) proc prepareDecodingData( self: Erasure, encoded: Manifest, step: Natural, data: ref seq[seq[byte]], parityData: ref seq[seq[byte]], cids: ref seq[Cid], emptyBlock: seq[byte]): Future[?!(Natural, Natural)] {.async.} = ## Prepare data for decoding ## `encoded` - the encoded manifest ## `step` - the current step ## `data` - the data to be prepared ## `parityData` - the parityData to be prepared ## `cids` - cids of prepared data ## `emptyBlock` - the empty block to be used for padding ## let strategy = encoded.protectedStrategy.init( firstIndex = 0, lastIndex = encoded.blocksCount - 1, iterations = encoded.steps ) indices = toSeq(strategy.getIndices(step)) pendingBlocksIter = self.getPendingBlocks(encoded, indices) var dataPieces = 0 parityPieces = 0 resolved = 0 for fut in pendingBlocksIter: # Continue to receive blocks until we have just enough for decoding # or no more blocks can arrive if resolved >= encoded.ecK: break let (blkOrErr, idx) = await fut without blk =? blkOrErr, err: trace "Failed retreiving a block", idx, treeCid = encoded.treeCid, msg = err.msg continue let pos = indexToPos(encoded.steps, idx, step) logScope: cid = blk.cid idx = idx pos = pos step = step empty = blk.isEmpty cids[idx] = blk.cid if idx >= encoded.rounded: trace "Retrieved parity block" shallowCopy(parityData[pos - encoded.ecK], if blk.isEmpty: emptyBlock else: blk.data) parityPieces.inc else: trace "Retrieved data block" shallowCopy(data[pos], if blk.isEmpty: emptyBlock else: blk.data) dataPieces.inc resolved.inc return success (dataPieces.Natural, parityPieces.Natural) proc init*( _: type EncodingParams, manifest: Manifest, ecK: Natural, ecM: Natural, strategy: StrategyType): ?!EncodingParams = if ecK > manifest.blocksCount: return failure( "Unable to encode manifest, not enough blocks, ecK = " & $ecK & ", blocksCount = " & $manifest.blocksCount) let rounded = roundUp(manifest.blocksCount, ecK) steps = divUp(manifest.blocksCount, ecK) blocksCount = rounded + (steps * ecM) success EncodingParams( ecK: ecK, ecM: ecM, rounded: rounded, steps: steps, blocksCount: blocksCount, strategy: strategy ) proc encodeData( self: Erasure, manifest: Manifest, params: EncodingParams ): Future[?!Manifest] {.async.} = ## Encode blocks pointed to by the protected manifest ## ## `manifest` - the manifest to encode ## logScope: steps = params.steps rounded_blocks = params.rounded blocks_count = params.blocksCount ecK = params.ecK ecM = params.ecM var cids = seq[Cid].new() encoder = self.encoderProvider(manifest.blockSize.int, params.ecK, params.ecM) emptyBlock = newSeq[byte](manifest.blockSize.int) cids[].setLen(params.blocksCount) try: for step in 0..= encoded.ecK: trace "Retrieved all the required data blocks" continue trace "Erasure decoding data" if ( let err = decoder.decode(data[], parityData[], recovered); err.isErr): trace "Unable to decode data!", err = $err.error return failure($err.error) for i in 0.. i < tree.leavesCount) if err =? (await self.store.putSomeProofs(tree, idxIter)).errorOption: return failure(err) let decoded = Manifest.new(encoded) return decoded.success proc start*(self: Erasure) {.async.} = return proc stop*(self: Erasure) {.async.} = return proc new*( T: type Erasure, store: BlockStore, encoderProvider: EncoderProvider, decoderProvider: DecoderProvider): Erasure = ## Create a new Erasure instance for encoding and decoding manifests Erasure( store: store, encoderProvider: encoderProvider, decoderProvider: decoderProvider)