nimbus-eth1/nimbus/sync/snap/worker/db/hexary_range.nim

# nimbus-eth1
# Copyright (c) 2021 Status Research & Development GmbH
# Licensed under either of
#  * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or
#    http://www.apache.org/licenses/LICENSE-2.0)
#  * MIT license ([LICENSE-MIT](LICENSE-MIT) or
#    http://opensource.org/licenses/MIT)
# at your option. This file may not be copied, modified, or distributed
# except according to those terms.

import
  std/[sequtils, sets, tables],
  chronicles,
  eth/[common, p2p, rlp, trie/nibbles],
  stew/[byteutils, interval_set],
  ../../range_desc,
  "."/[hexary_desc, hexary_error, hexary_nearby, hexary_paths]

{.push raises: [Defect].}

type
  RangeLeaf* = object
    key*: NodeKey ## Leaf node path
    data*: Blob   ## Leaf node data

  RangeProof* = object
    leafs*: seq[RangeLeaf]
    proof*: seq[Blob]

# ------------------------------------------------------------------------------
# Private helpers
# ------------------------------------------------------------------------------

proc convertTo(key: RepairKey; T: type NodeKey): T =
  ## Might be lossy, check before use (if at all, unless debugging)
  (addr result.ByteArray32[0]).copyMem(unsafeAddr key.ByteArray33[1], 32)

# ------------------------------------------------------------------------------
# Private functions
# ------------------------------------------------------------------------------

template collectLeafs(
    iv: NodeTagRange;                # Proofed range of leaf paths
    rootKey: NodeKey|RepairKey;      # State root
    db: HexaryGetFn|HexaryTreeDbRef; # Database abstraction
    nLeafs: int;                     # Implies maximal data size
      ): auto =
  ## Collect trie database leafs prototype. This directive is provided as
  ## `template` for avoiding varying exceprion annotations.
  var rc: Result[seq[RangeLeaf],HexaryError]

  block body:
    var
      nodeTag = iv.minPt
      prevTag: NodeTag
      rls: seq[RangeLeaf]

    # Fill at most `nLeafs` leaf nodes from interval range
    while rls.len < nLeafs and nodeTag <= iv.maxPt:
      # The following logic might be sub-optimal. A strict version of the
      # `next()` function that stops with an error at dangling links could
      # be faster if the leaf nodes are not too far apart on the hexary trie.
      var
        xPath = block:
          let rx = nodeTag.hexaryPath(rootKey,db).hexaryNearbyRight(db)
          if rx.isErr:
            rc = typeof(rc).err(rx.error)
            break body
          rx.value
        rightKey = xPath.getPartialPath.convertTo(NodeKey)
        rightTag = rightKey.to(NodeTag)

      # Prevents from semi-endless looping
      if rightTag <= prevTag and 0 < rls.len:
        # Oops, should have been tackeled by `hexaryNearbyRight()`
        rc = typeof(rc).err(FailedNextNode)
        break body # stop here

      rls.add RangeLeaf(
        key:  rightKey,
        data: xPath.leafData)

      prevTag = nodeTag
      nodeTag = rightTag + 1.u256

    rc = typeof(rc).ok(rls)
    # End body

  rc


template updateProof(
    baseTag: NodeTag;                # Left boundary
    leafList: seq[RangeLeaf];        # Set of collected leafs
    rootKey: NodeKey|RepairKey;      # State root
    db: HexaryGetFn|HexaryTreeDbRef; # Database abstraction
      ): auto =
  ## Update leafs list by adding proof nodes. This directive is provided as
  ## `template` for avoiding varying exceprion annotations.
  var proof = baseTag.hexaryPath(rootKey, db)
        .path
        .mapIt(it.node)
        .filterIt(it.kind != Leaf)
        .mapIt(it.convertTo(Blob))
        .toHashSet
  if 0 < leafList.len:
    proof.incl leafList[^1].key.to(NodeTag).hexaryPath(rootKey, db)
        .path
         .mapIt(it.node)
        .filterIt(it.kind != Leaf)
        .mapIt(it.convertTo(Blob))
        .toHashSet

  RangeProof(
    leafs: leafList,
    proof: proof.toSeq)

# ------------------------------------------------------------------------------
# Public functions
# ------------------------------------------------------------------------------

proc hexaryRangeLeafsProof*(
    iv: NodeTagRange;                # Proofed range of leaf paths
    rootKey: NodeKey;                # State root
    db: HexaryGetFn;                 # Database abstraction
    nLeafs = high(int);              # Implies maximal data size
      ): Result[RangeProof,HexaryError]
      {.gcsafe, raises: [Defect,RlpError]} =
  ## ...
  let rc = iv.collectLeafs(rootKey, db, nLeafs)
  if rc.isErr:
    err(rc.error)
  else:
    ok(iv.minPt.updateProof(rc.value, rootKey, db))

proc hexaryRangeLeafsProof*(
    baseTag: NodeTag;                # Left boundary
    leafList: seq[RangeLeaf];        # Set of already collected leafs
    rootKey: NodeKey;                # State root
    db: HexaryGetFn;                 # Database abstraction
      ): RangeProof
      {.gcsafe, raises: [Defect,RlpError]} =
  ## ...
  baseTag.updateProof(leafList, rootKey, db)


proc hexaryRangeLeafsProof*(
    iv: NodeTagRange;                # Proofed range of leaf paths
    rootKey: NodeKey;                # State root
    db: HexaryTreeDbRef;             # Database abstraction
    nLeafs = high(int);              # Implies maximal data size
      ): Result[RangeProof,HexaryError]
      {.gcsafe, raises: [Defect,KeyError]} =
  ## ...
  let rc = iv.collectLeafs(rootKey, db, nLeafs)
  if rc.isErr:
    err(rc.error)
  else:
    ok(iv.minPt.updateProof(rc.value, rootKey, db))

proc hexaryRangeLeafsProof*(
    baseTag: NodeTag;                # Left boundary
    leafList: seq[RangeLeaf];        # Set of already collected leafs
    rootKey: NodeKey;                # State root
    db: HexaryTreeDbRef;             # Database abstraction
      ): RangeProof
      {.gcsafe, raises: [Defect,KeyError]} =
  ## ...
  baseTag.updateProof(leafList, rootKey, db)

# ------------------------------------------------------------------------------
# End
# ------------------------------------------------------------------------------
Snap sync interval range extractor (#1449) * Update comments and test noise * Fix boundary proofs why: Where neither used in production, nor unit tested. For production, other methods apply to test leaf range integrity directly based of the proof nodes. * Added `hexary_range()`: interval range + proof extractor details: + Will be used for `snap/1` protocol handler + Unit tests added (also for testing left boundary proof) todo: Need to verify completeness of proof nodes * Reduce some nim 1.6 compiler noise * Stop unit test gossip for ci tests 2023-01-30 17:50:58 +00:00			`# nimbus-eth1`
			`# Copyright (c) 2021 Status Research & Development GmbH`
			`# Licensed under either of`
			`# * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or`
			`# http://www.apache.org/licenses/LICENSE-2.0)`
			`# * MIT license ([LICENSE-MIT](LICENSE-MIT) or`
			`# http://opensource.org/licenses/MIT)`
			`# at your option. This file may not be copied, modified, or distributed`
			`# except according to those terms.`

			`import`
			`std/[sequtils, sets, tables],`
			`chronicles,`
			`eth/[common, p2p, rlp, trie/nibbles],`
			`stew/[byteutils, interval_set],`
			`../../range_desc,`
			`"."/[hexary_desc, hexary_error, hexary_nearby, hexary_paths]`

			`{.push raises: [Defect].}`

			`type`
			`RangeLeaf* = object`
			`key*: NodeKey ## Leaf node path`
			`data*: Blob ## Leaf node data`

			`RangeProof* = object`
			`leafs*: seq[RangeLeaf]`
			`proof*: seq[Blob]`

			`# ------------------------------------------------------------------------------`
			`# Private helpers`
			`# ------------------------------------------------------------------------------`

			`proc convertTo(key: RepairKey; T: type NodeKey): T =`
			`## Might be lossy, check before use (if at all, unless debugging)`
			`(addr result.ByteArray32[0]).copyMem(unsafeAddr key.ByteArray33[1], 32)`

			`# ------------------------------------------------------------------------------`
			`# Private functions`
			`# ------------------------------------------------------------------------------`

			`template collectLeafs(`
			`iv: NodeTagRange; # Proofed range of leaf paths`
			`rootKey: NodeKey\|RepairKey; # State root`
			`db: HexaryGetFn\|HexaryTreeDbRef; # Database abstraction`
			`nLeafs: int; # Implies maximal data size`
			`): auto =`
			`## Collect trie database leafs prototype. This directive is provided as`
			## `template` for avoiding varying exceprion annotations.
			`var rc: Result[seq[RangeLeaf],HexaryError]`

			`block body:`
			`var`
			`nodeTag = iv.minPt`
			`prevTag: NodeTag`
			`rls: seq[RangeLeaf]`

			# Fill at most `nLeafs` leaf nodes from interval range
			`while rls.len < nLeafs and nodeTag <= iv.maxPt:`
			`# The following logic might be sub-optimal. A strict version of the`
			# `next()` function that stops with an error at dangling links could
			`# be faster if the leaf nodes are not too far apart on the hexary trie.`
			`var`
			`xPath = block:`
			`let rx = nodeTag.hexaryPath(rootKey,db).hexaryNearbyRight(db)`
			`if rx.isErr:`
			`rc = typeof(rc).err(rx.error)`
			`break body`
			`rx.value`
			`rightKey = xPath.getPartialPath.convertTo(NodeKey)`
			`rightTag = rightKey.to(NodeTag)`

			`# Prevents from semi-endless looping`
			`if rightTag <= prevTag and 0 < rls.len:`
			# Oops, should have been tackeled by `hexaryNearbyRight()`
			`rc = typeof(rc).err(FailedNextNode)`
			`break body # stop here`

			`rls.add RangeLeaf(`
			`key: rightKey,`
			`data: xPath.leafData)`

			`prevTag = nodeTag`
			`nodeTag = rightTag + 1.u256`

			`rc = typeof(rc).ok(rls)`
			`# End body`

			`rc`


			`template updateProof(`
			`baseTag: NodeTag; # Left boundary`
			`leafList: seq[RangeLeaf]; # Set of collected leafs`
			`rootKey: NodeKey\|RepairKey; # State root`
			`db: HexaryGetFn\|HexaryTreeDbRef; # Database abstraction`
			`): auto =`
			`## Update leafs list by adding proof nodes. This directive is provided as`
			## `template` for avoiding varying exceprion annotations.
			`var proof = baseTag.hexaryPath(rootKey, db)`
			`.path`
			`.mapIt(it.node)`
			`.filterIt(it.kind != Leaf)`
			`.mapIt(it.convertTo(Blob))`
			`.toHashSet`
			`if 0 < leafList.len:`
			`proof.incl leafList[^1].key.to(NodeTag).hexaryPath(rootKey, db)`
			`.path`
			`.mapIt(it.node)`
			`.filterIt(it.kind != Leaf)`
			`.mapIt(it.convertTo(Blob))`
			`.toHashSet`

			`RangeProof(`
			`leafs: leafList,`
			`proof: proof.toSeq)`

			`# ------------------------------------------------------------------------------`
			`# Public functions`
			`# ------------------------------------------------------------------------------`

			`proc hexaryRangeLeafsProof*(`
			`iv: NodeTagRange; # Proofed range of leaf paths`
			`rootKey: NodeKey; # State root`
			`db: HexaryGetFn; # Database abstraction`
			`nLeafs = high(int); # Implies maximal data size`
			`): Result[RangeProof,HexaryError]`
			`{.gcsafe, raises: [Defect,RlpError]} =`
			`## ...`
			`let rc = iv.collectLeafs(rootKey, db, nLeafs)`
			`if rc.isErr:`
			`err(rc.error)`
			`else:`
			`ok(iv.minPt.updateProof(rc.value, rootKey, db))`

			`proc hexaryRangeLeafsProof*(`
			`baseTag: NodeTag; # Left boundary`
			`leafList: seq[RangeLeaf]; # Set of already collected leafs`
			`rootKey: NodeKey; # State root`
			`db: HexaryGetFn; # Database abstraction`
			`): RangeProof`
			`{.gcsafe, raises: [Defect,RlpError]} =`
			`## ...`
			`baseTag.updateProof(leafList, rootKey, db)`


			`proc hexaryRangeLeafsProof*(`
			`iv: NodeTagRange; # Proofed range of leaf paths`
			`rootKey: NodeKey; # State root`
			`db: HexaryTreeDbRef; # Database abstraction`
			`nLeafs = high(int); # Implies maximal data size`
			`): Result[RangeProof,HexaryError]`
			`{.gcsafe, raises: [Defect,KeyError]} =`
			`## ...`
			`let rc = iv.collectLeafs(rootKey, db, nLeafs)`
			`if rc.isErr:`
			`err(rc.error)`
			`else:`
			`ok(iv.minPt.updateProof(rc.value, rootKey, db))`

			`proc hexaryRangeLeafsProof*(`
			`baseTag: NodeTag; # Left boundary`
			`leafList: seq[RangeLeaf]; # Set of already collected leafs`
			`rootKey: NodeKey; # State root`
			`db: HexaryTreeDbRef; # Database abstraction`
			`): RangeProof`
			`{.gcsafe, raises: [Defect,KeyError]} =`
			`## ...`
			`baseTag.updateProof(leafList, rootKey, db)`

			`# ------------------------------------------------------------------------------`
			`# End`
			`# ------------------------------------------------------------------------------`