Aristo db kvt maintenance update (#1952)
* Update KVT layers abstraction details: modelled after Aristo layers * Simplified KVT database iterators (removed item counters) why: Not needed for production functions * Simplify KVT merge function `layersCc()` * Simplified Aristo database iterators (removed item counters) why: Not needed for production functions * Update failure condition for hash labels compiler `hashify()` why: Node need not be rejected as long as links are on the schedule. In that case, `redo[]` is to become `wff.base[]` at a later stage. * Update merging layers and label update functions why: + Merging a stack of layers with `layersCc()` could be simplified + Merging layers will optimise the reverse `kMap[]` table maps `pAmk: label->{vid, ..}` by deleting empty mappings `label->{}` where they are redundant. + Updated `layersPutLabel()` for optimising `pAmk[]` tables
This commit is contained in:
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dded8643d9
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@ -92,7 +92,7 @@ proc checkBE*[T: RdbBackendRef|MemBackendRef|VoidBackendRef](
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let vids = IntervalSetRef[VertexID,uint64].init()
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discard vids.merge Interval[VertexID,uint64].new(VertexID(1),high(VertexID))
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for (_,vid,vtx) in T.walkVtxBE db:
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for (vid,vtx) in T.walkVtxBE db:
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if not vtx.isValid:
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return err((vid,CheckBeVtxInvalid))
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let rc = db.getKeyBE vid
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@ -114,7 +114,7 @@ proc checkBE*[T: RdbBackendRef|MemBackendRef|VoidBackendRef](
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if vtx.ePfx.len == 0:
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return err((vid,CheckBeVtxExtPfxMissing))
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for (_,vid,key) in T.walkKeyBE db:
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for (vid,key) in T.walkKeyBE db:
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if not key.isvalid:
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return err((vid,CheckBeKeyInvalid))
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let vtx = db.getVtxBE(vid).valueOr:
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@ -483,12 +483,22 @@ proc ppBe[T](be: T; db: AristoDbRef; root: VertexID; indent: int): string =
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result = "<" & $be.kind & ">"
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result &= pfx & "vGen" & pfx1 & "[" &
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be.getIdgFn().get(otherwise = EmptyVidSeq).mapIt(it.ppVid).join(",") & "]"
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result &= pfx & "sTab" & pfx1 & "{" & be.walkVtx.toSeq.mapIt(
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$(1+it[0]) & "(" & it[1].ppVid & "," & it[2].ppVtx(db,it[1]) & ")"
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).join(pfx2) & "}"
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result &= pfx & "kMap" & pfx1 & "{" & be.walkKey.toSeq.mapIt(
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$(1+it[0]) & "(" & it[1].ppVid & "," & it[2].ppKey(db,root) & ")"
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).join(pfx2) & "}"
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block:
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result &= pfx & "sTab" & pfx1 & "{"
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var n = 0
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for (vid,vtx) in be.walkVtx:
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if 0 < n: result &= pfx2
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n.inc
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result &= $n & "(" & vid.ppVid & "," & vtx.ppVtx(db,vid) & ")"
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result &= "}"
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block:
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result &= pfx & "kMap" & pfx1 & "{"
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var n = 0
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for (vid,key) in be.walkKey:
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if 0 < n: result &= pfx2
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n.inc
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result &= $n & "(" & vid.ppVid & "," & key.ppKey(db,root) & ")"
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result &= "}"
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proc ppLayer(
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layer: LayerRef;
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@ -802,7 +812,24 @@ proc pp*(
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): string =
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result = db.layersCc.pp(db, indent=indent) & indent.toPfx
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if 0 < db.stack.len:
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result &= " level=" & $db.stack.len & indent.toPfx
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result &= " level=" & $db.stack.len
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when false: # or true:
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let layers = @[db.top] & db.stack.reversed
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var lStr = ""
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for n,w in layers:
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let
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m = layers.len - n - 1
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l = db.layersCc m
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a = w.delta.kMap.values.toSeq.filterIt(not it.isValid).len
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b = w.delta.pAmk.values.toSeq.filterIt(not it.isValid).len
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c = l.delta.kMap.values.toSeq.filterIt(not it.isValid).len
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d = l.delta.pAmk.values.toSeq.filterIt(not it.isValid).len
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result &= " (" & $(w.delta.kMap.len - a) & "," & $a
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result &= ";" & $(w.delta.pAmk.len - b) & "," & $b & ")"
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lStr &= " " & $m & "=(" & $(l.delta.kMap.len - c) & "," & $c
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lStr &= ";" & $(l.delta.pAmk.len - d) & "," & $d & ")"
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result &= " --" & lStr
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result &= indent.toPfx
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if backendOk:
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result &= db.backend.pp(db)
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elif filterOk:
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@ -112,7 +112,6 @@ type
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HashifyNodeUnresolved
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HashifyRootHashMismatch
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HashifyRootNodeUnresolved
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HashifyLoop
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# Cache checker `checkCache()`
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CheckStkKeyStrayZeroEntry
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@ -119,7 +119,8 @@ type
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vGen*: seq[VertexID] ## Unique vertex ID generator
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dirty*: bool ## Needs to be hashified if `true`
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LayerRef* = ref object
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LayerRef* = ref LayerObj
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LayerObj* = object
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## Hexary trie database layer structures. Any layer holds the full
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## change relative to the backend.
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delta*: LayerDelta ## Most structural tables held as deltas
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@ -377,7 +377,7 @@ proc hashify*(
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wff.pool[vid] = val
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# Add the child vertices to `redo[]` for the schedule `base[]` list.
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for w in error:
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if w notin wff.base:
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if w notin wff.base and w notin redo:
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if db.layersGetVtx(w).isErr:
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# Ooops, should have been marked for update
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return err((w,HashifyNodeUnresolved))
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@ -311,7 +311,7 @@ proc memoryBackend*(qidLayout: QidLayoutRef): BackendRef =
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iterator walkVtx*(
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be: MemBackendRef;
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): tuple[n: int, vid: VertexID, vtx: VertexRef] =
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): tuple[vid: VertexID, vtx: VertexRef] =
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## Iteration over the vertex sub-table.
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for n,vid in be.sTab.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
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let data = be.sTab.getOrDefault(vid, EmptyBlob)
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@ -320,20 +320,20 @@ iterator walkVtx*(
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if rc.isErr:
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debug logTxt "walkVtxFn() skip", n, vid, error=rc.error
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else:
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yield (n, vid, rc.value)
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yield (vid, rc.value)
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iterator walkKey*(
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be: MemBackendRef;
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): tuple[n: int, vid: VertexID, key: HashKey] =
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): tuple[vid: VertexID, key: HashKey] =
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## Iteration over the Markle hash sub-table.
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for n,vid in be.kMap.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
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for vid in be.kMap.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
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let key = be.kMap.getOrVoid vid
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if key.isValid:
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yield (n, vid, key)
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yield (vid, key)
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iterator walkFil*(
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be: MemBackendRef;
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): tuple[n: int, qid: QueueID, filter: FilterRef] =
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): tuple[qid: QueueID, filter: FilterRef] =
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## Iteration over the vertex sub-table.
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if not be.noFq:
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for n,qid in be.rFil.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.QueueID):
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@ -341,45 +341,38 @@ iterator walkFil*(
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if 0 < data.len:
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let rc = data.deblobify FilterRef
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if rc.isErr:
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debug logTxt "walkFilFn() skip", n,qid, error=rc.error
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debug logTxt "walkFilFn() skip", n, qid, error=rc.error
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else:
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yield (n, qid, rc.value)
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yield (qid, rc.value)
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iterator walk*(
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be: MemBackendRef;
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): tuple[n: int, pfx: StorageType, xid: uint64, data: Blob] =
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): tuple[pfx: StorageType, xid: uint64, data: Blob] =
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## Walk over all key-value pairs of the database.
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##
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## Non-decodable entries are stepped over while the counter `n` of the
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## yield record is still incremented.
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var n = 0
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if be.vGen.isSome:
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yield(0, AdmPfx, AdmTabIdIdg.uint64, be.vGen.unsafeGet.blobify)
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n.inc
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yield(AdmPfx, AdmTabIdIdg.uint64, be.vGen.unsafeGet.blobify)
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if not be.noFq:
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if be.vFqs.isSome:
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yield(0, AdmPfx, AdmTabIdFqs.uint64, be.vFqs.unsafeGet.blobify)
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n.inc
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yield(AdmPfx, AdmTabIdFqs.uint64, be.vFqs.unsafeGet.blobify)
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for vid in be.sTab.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
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let data = be.sTab.getOrDefault(vid, EmptyBlob)
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if 0 < data.len:
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yield (n, VtxPfx, vid.uint64, data)
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n.inc
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yield (VtxPfx, vid.uint64, data)
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for (_,vid,key) in be.walkKey:
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yield (n, KeyPfx, vid.uint64, @key)
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n.inc
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for (vid,key) in be.walkKey:
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yield (KeyPfx, vid.uint64, @key)
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if not be.noFq:
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for lid in be.rFil.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.QueueID):
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let data = be.rFil.getOrDefault(lid, EmptyBlob)
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if 0 < data.len:
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yield (n, FilPfx, lid.uint64, data)
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n.inc
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yield (FilPfx, lid.uint64, data)
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# ------------------------------------------------------------------------------
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# End
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@ -368,7 +368,7 @@ proc rocksDbBackend*(
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iterator walk*(
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be: RdbBackendRef;
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): tuple[n: int, pfx: StorageType, xid: uint64, data: Blob] =
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): tuple[pfx: StorageType, xid: uint64, data: Blob] =
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## Walk over all key-value pairs of the database.
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##
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## Non-decodable entries are stepped over while the counter `n` of the
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@ -390,31 +390,31 @@ iterator walk*(
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iterator walkVtx*(
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be: RdbBackendRef;
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): tuple[n: int, vid: VertexID, vtx: VertexRef] =
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): tuple[vid: VertexID, vtx: VertexRef] =
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## Variant of `walk()` iteration over the vertex sub-table.
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for (n, xid, data) in be.rdb.walk VtxPfx:
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for (xid, data) in be.rdb.walk VtxPfx:
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let rc = data.deblobify VertexRef
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if rc.isOk:
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yield (n, VertexID(xid), rc.value)
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yield (VertexID(xid), rc.value)
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iterator walkKey*(
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be: RdbBackendRef;
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): tuple[n: int, vid: VertexID, key: HashKey] =
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): tuple[vid: VertexID, key: HashKey] =
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## Variant of `walk()` iteration over the Markle hash sub-table.
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for (n, xid, data) in be.rdb.walk KeyPfx:
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for (xid, data) in be.rdb.walk KeyPfx:
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let lid = HashKey.fromBytes(data).valueOr:
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continue
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yield (n, VertexID(xid), lid)
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yield (VertexID(xid), lid)
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iterator walkFil*(
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be: RdbBackendRef;
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): tuple[n: int, qid: QueueID, filter: FilterRef] =
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): tuple[qid: QueueID, filter: FilterRef] =
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## Variant of `walk()` iteration over the filter sub-table.
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if not be.noFq:
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for (n, xid, data) in be.rdb.walk FilPfx:
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for (xid, data) in be.rdb.walk FilPfx:
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let rc = data.deblobify FilterRef
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if rc.isOk:
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yield (n, QueueID(xid), rc.value)
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yield (QueueID(xid), rc.value)
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# ------------------------------------------------------------------------------
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# End
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@ -45,16 +45,14 @@ func valBlob(vData: cstring, vLen: csize_t): Blob =
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iterator walk*(
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rdb: RdbInst;
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): tuple[n: int, pfx: StorageType, xid: uint64, data: Blob] =
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): tuple[pfx: StorageType, xid: uint64, data: Blob] =
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## Walk over all key-value pairs of the database.
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##
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## Non-decodable entries are stepped over while the counter `n` of the
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## yield record is still incremented.
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## Non-decodable entries are stepped over and ignored.
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let rit = rdb.store.db.rocksdb_create_iterator(rdb.store.readOptions)
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defer: rit.rocksdb_iter_destroy()
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rit.rocksdb_iter_seek_to_first()
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var count = 0
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while rit.rocksdb_iter_valid() != 0:
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var kLen: csize_t
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@ -72,23 +70,21 @@ iterator walk*(
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let val = vData.valBlob(vLen)
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if 0 < val.len:
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yield (count, pfx.StorageType, xid, val)
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yield (pfx.StorageType, xid, val)
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# Update Iterator (might overwrite kData/vdata)
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rit.rocksdb_iter_next()
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count.inc
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# End while
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iterator walk*(
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rdb: RdbInst;
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pfx: StorageType;
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): tuple[n: int, xid: uint64, data: Blob] =
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): tuple[xid: uint64, data: Blob] =
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## Walk over key-value pairs of the table referted to by the argument `pfx`
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## whic must be different from `Oops` and `AdmPfx`.
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##
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## Non-decodable entries are stepped over while the counter `n` of the
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## yield record is still incremented.
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## Non-decodable entries are stepped over and ignored.
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##
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block walkBody:
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if pfx in {Oops, AdmPfx}:
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@ -99,7 +95,6 @@ iterator walk*(
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defer: rit.rocksdb_iter_destroy()
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var
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count = 0
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kLen: csize_t
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kData: cstring
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@ -139,14 +134,13 @@ iterator walk*(
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let val = vData.valBlob(vLen)
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if 0 < val.len:
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yield (count, xid, val)
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yield (xid, val)
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# Update Iterator
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rit.rocksdb_iter_next()
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if rit.rocksdb_iter_valid() == 0:
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break walkBody
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count.inc
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# End while
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# ------------------------------------------------------------------------------
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@ -25,18 +25,22 @@ func dup(sTab: Table[VertexID,VertexRef]): Table[VertexID,VertexRef] =
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for (k,v) in sTab.pairs:
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result[k] = v.dup
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func dup(delta: LayerDelta): LayerDelta =
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result = LayerDelta(
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sTab: delta.sTab.dup, # explicit dup for ref values
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kMap: delta.kMap,
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pAmk: delta.pAmk)
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func stackGetLebalOrVoid(db: AristoDbRef; lbl: HashLabel): HashSet[VertexID] =
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func getLebalOrVoid(stack: seq[LayerRef]; lbl: HashLabel): HashSet[VertexID] =
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# Helper: get next set of vertex IDs from stack.
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for w in db.stack.reversed:
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for w in stack.reversed:
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w.delta.pAmk.withValue(lbl,value):
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return value[]
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proc recalcLebal(layer: var LayerObj) =
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## Calculate reverse `kMap[]` for final (aka zero) layer
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layer.delta.pAmk.clear
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for (vid,lbl) in layer.delta.kMap.pairs:
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if lbl.isValid:
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layer.delta.pAmk.withValue(lbl, value):
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value[].incl vid
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do:
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layer.delta.pAmk[lbl] = @[vid].toHashSet
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# ------------------------------------------------------------------------------
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# Public getters: lazy value lookup for read only versions
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# ------------------------------------------------------------------------------
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@ -58,15 +62,24 @@ func dirty*(db: AristoDbRef): bool =
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# ------------------------------------------------------------------------------
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func nLayersVtx*(db: AristoDbRef): int =
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## Number of vertex entries on the cache layers
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## Number of vertex ID/vertex entries on the cache layers. This is an upper
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## bound for the number of effective vertex ID mappings held on the cache
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## layers as there might be duplicate entries for the same vertex ID on
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## different layers.
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db.stack.mapIt(it.delta.sTab.len).foldl(a + b, db.top.delta.sTab.len)
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func nLayersLabel*(db: AristoDbRef): int =
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## Number of key/label entries on the cache layers
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## Number of vertex ID/label entries on the cache layers. This is an upper
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## bound for the number of effective vertex ID mappingss held on the cache
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## layers as there might be duplicate entries for the same vertex ID on
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## different layers.
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db.stack.mapIt(it.delta.kMap.len).foldl(a + b, db.top.delta.kMap.len)
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func nLayersLebal*(db: AristoDbRef): int =
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## Number of key/label reverse lookup entries on the cache layers
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## Number of label/vertex IDs reverse lookup entries on the cache layers.
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## This is an upper bound for the number of effective label mappingss held
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## on the cache layers as there might be duplicate entries for the same label
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## on different layers.
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db.stack.mapIt(it.delta.pAmk.len).foldl(a + b, db.top.delta.pAmk.len)
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# ------------------------------------------------------------------------------
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@ -170,17 +183,25 @@ proc layersPutLabel*(db: AristoDbRef; vid: VertexID; lbl: HashLabel) =
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# Clear previous value on reverse table if it has changed
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if blb.isValid and blb != lbl:
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var vidsLen = -1
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db.top.delta.pAmk.withValue(blb, value):
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value[].excl vid
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vidsLen = value[].len
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do: # provide empty lookup
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db.top.delta.pAmk[blb] = db.stackGetLebalOrVoid(blb) - @[vid].toHashSet
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let vids = db.stack.getLebalOrVoid(blb)
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if vids.isValid and vid in vids:
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# This entry supersedes non-emtpty changed ones from lower levels
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db.top.delta.pAmk[blb] = vids - @[vid].toHashSet
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if vidsLen == 0 and not db.stack.getLebalOrVoid(blb).isValid:
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# There is no non-emtpty entry on lower levels, so ledete this one
|
||||
db.top.delta.pAmk.del blb
|
||||
|
||||
# Add updated value on reverse table if non-zero
|
||||
if lbl.isValid:
|
||||
db.top.delta.pAmk.withValue(lbl, value):
|
||||
value[].incl vid
|
||||
do: # else if not found: need to merge with value set from lower layer
|
||||
db.top.delta.pAmk[lbl] = db.stackGetLebalOrVoid(lbl) + @[vid].toHashSet
|
||||
db.top.delta.pAmk[lbl] = db.stack.getLebalOrVoid(lbl) + @[vid].toHashSet
|
||||
|
||||
|
||||
proc layersResLabel*(db: AristoDbRef; vid: VertexID) =
|
||||
|
@ -192,48 +213,53 @@ proc layersResLabel*(db: AristoDbRef; vid: VertexID) =
|
|||
# Public functions
|
||||
# ------------------------------------------------------------------------------
|
||||
|
||||
proc layersMergeOnto*(src: LayerRef; trg: LayerRef): LayerRef {.discardable.} =
|
||||
proc layersMergeOnto*(src: LayerRef; trg: var LayerObj; stack: seq[LayerRef]) =
|
||||
## Merges the argument `src` into the argument `trg` and returns `trg`. For
|
||||
## the result layer, the `txUid` value set to `0`.
|
||||
##
|
||||
trg.final = src.final
|
||||
trg.txUid = 0
|
||||
|
||||
for (vid,vtx) in src.delta.sTab.pairs:
|
||||
trg.delta.sTab[vid] = vtx
|
||||
|
||||
for (vid,lbl) in src.delta.kMap.pairs:
|
||||
trg.delta.kMap[vid] = lbl
|
||||
|
||||
for (lbl,vids) in src.delta.pAmk.pairs:
|
||||
trg.delta.pAmk.withValue(lbl, value):
|
||||
value[] = value[] + vids
|
||||
do:
|
||||
trg.delta.pAmk[lbl] = vids
|
||||
|
||||
trg
|
||||
if stack.len == 0:
|
||||
# Re-calculate `pAmk[]`
|
||||
trg.recalcLebal()
|
||||
else:
|
||||
# Merge reverse `kMap[]` layers. Empty label image sets are ignored unless
|
||||
# they supersede non-empty values on the argument `stack[]`.
|
||||
for (lbl,vids) in src.delta.pAmk.pairs:
|
||||
if 0 < vids.len or stack.getLebalOrVoid(lbl).isValid:
|
||||
trg.delta.pAmk[lbl] = vids
|
||||
|
||||
|
||||
proc layersCc*(db: AristoDbRef; level = high(int)): LayerRef =
|
||||
func layersCc*(db: AristoDbRef; level = high(int)): LayerRef =
|
||||
## Provide a collapsed copy of layers up to a particular transaction level.
|
||||
## If the `level` argument is too large, the maximum transaction level is
|
||||
## returned. For the result layer, the `txUid` value set to `0`.
|
||||
let level = min(level, db.stack.len)
|
||||
##
|
||||
let layers = if db.stack.len <= level: db.stack & @[db.top]
|
||||
else: db.stack[0 .. level]
|
||||
|
||||
result = LayerRef(final: db.top.final) # Pre-merged/final values
|
||||
# Set up initial layer (bottom layer)
|
||||
result = LayerRef(
|
||||
final: layers[^1].final, # Pre-merged/final values
|
||||
delta: LayerDelta(
|
||||
sTab: layers[0].delta.sTab.dup, # explicit dup for ref values
|
||||
kMap: layers[0].delta.kMap))
|
||||
|
||||
# Merge stack into its bottom layer
|
||||
if level <= 0 and db.stack.len == 0:
|
||||
result.delta = db.top.delta.dup # Explicit dup for ref values
|
||||
else:
|
||||
# now: 0 < level <= db.stack.len
|
||||
result.delta = db.stack[0].delta.dup # Explicit dup for ref values
|
||||
# Consecutively merge other layers on top
|
||||
for n in 1 ..< layers.len:
|
||||
for (vid,vtx) in layers[n].delta.sTab.pairs:
|
||||
result.delta.sTab[vid] = vtx
|
||||
for (vid,lbl) in layers[n].delta.kMap.pairs:
|
||||
result.delta.kMap[vid] = lbl
|
||||
|
||||
# Merge stack: structural vertex table and hash key mapping
|
||||
for w in db.stack.reversed:
|
||||
w.layersMergeOnto result
|
||||
|
||||
# Merge top layer
|
||||
db.top.layersMergeOnto result
|
||||
# Re-calculate `pAmk[]`
|
||||
result[].recalcLebal()
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public iterators
|
||||
|
|
|
@ -14,6 +14,7 @@
|
|||
{.push raises: [].}
|
||||
|
||||
import
|
||||
std/tables,
|
||||
results,
|
||||
"."/[aristo_desc, aristo_filter, aristo_get, aristo_layers, aristo_hashify]
|
||||
|
||||
|
@ -248,12 +249,23 @@ proc commit*(
|
|||
discard db.hashify().valueOr:
|
||||
return err(error[1])
|
||||
|
||||
# Replace the top two layers by its merged version
|
||||
let merged = db.top.layersMergeOnto db.stack[^1]
|
||||
# Pop layer from stack and merge database top layer onto it
|
||||
let merged = block:
|
||||
if db.top.delta.sTab.len == 0 and
|
||||
db.top.delta.kMap.len == 0 and
|
||||
db.top.delta.pAmk.len == 0:
|
||||
# Avoid `layersMergeOnto()`
|
||||
db.top.delta.shallowCopy db.stack[^1].delta
|
||||
db.stack.setLen(db.stack.len-1)
|
||||
db.top
|
||||
else:
|
||||
let layer = db.stack[^1]
|
||||
db.stack.setLen(db.stack.len-1)
|
||||
db.top.layersMergeOnto(layer[], db.stack)
|
||||
layer
|
||||
|
||||
# Install `merged` layer
|
||||
# Install `merged` stack top layer and update stack
|
||||
db.top = merged
|
||||
db.stack.setLen(db.stack.len-1)
|
||||
db.txRef = tx.parent
|
||||
if 0 < db.stack.len:
|
||||
db.txRef.txUid = db.getTxUid
|
||||
|
|
|
@ -28,27 +28,27 @@ export
|
|||
iterator walkVtxBe*[T: MemBackendRef|VoidBackendRef](
|
||||
_: type T;
|
||||
db: AristoDbRef;
|
||||
): tuple[n: int, vid: VertexID, vtx: VertexRef] =
|
||||
): tuple[vid: VertexID, vtx: VertexRef] =
|
||||
## Iterate over filtered memory backend or backend-less vertices. This
|
||||
## function depends on the particular backend type name which must match
|
||||
## the backend descriptor.
|
||||
for (n,vid,vtx) in walkVtxBeImpl[T](db):
|
||||
yield (n,vid,vtx)
|
||||
for (vid,vtx) in walkVtxBeImpl[T](db):
|
||||
yield (vid,vtx)
|
||||
|
||||
iterator walkKeyBe*[T: MemBackendRef|VoidBackendRef](
|
||||
_: type T;
|
||||
db: AristoDbRef;
|
||||
): tuple[n: int, vid: VertexID, key: HashKey] =
|
||||
): tuple[vid: VertexID, key: HashKey] =
|
||||
## Similar to `walkVtxBe()` but for keys.
|
||||
for (n,vid,key) in walkKeyBeImpl[T](db):
|
||||
yield (n,vid,key)
|
||||
for (vid,key) in walkKeyBeImpl[T](db):
|
||||
yield (vid,key)
|
||||
|
||||
iterator walkFilBe*[T: MemBackendRef|VoidBackendRef](
|
||||
be: T;
|
||||
): tuple[n: int, qid: QueueID, filter: FilterRef] =
|
||||
): tuple[qid: QueueID, filter: FilterRef] =
|
||||
## Iterate over backend filters.
|
||||
for (n,qid,filter) in walkFilBeImpl[T](be):
|
||||
yield (n,qid,filter)
|
||||
for (qid,filter) in walkFilBeImpl[T](be):
|
||||
yield (qid,filter)
|
||||
|
||||
iterator walkFifoBe*[T: MemBackendRef|VoidBackendRef](
|
||||
be: T;
|
||||
|
|
|
@ -34,26 +34,26 @@ export
|
|||
iterator walkVtxBe*(
|
||||
T: type RdbBackendRef;
|
||||
db: AristoDbRef;
|
||||
): tuple[n: int, vid: VertexID, vtx: VertexRef] =
|
||||
): tuple[vid: VertexID, vtx: VertexRef] =
|
||||
## Iterate over filtered RocksDB backend vertices. This function depends on
|
||||
## the particular backend type name which must match the backend descriptor.
|
||||
for (n,vid,vtx) in walkVtxBeImpl[T](db):
|
||||
yield (n,vid,vtx)
|
||||
for (vid,vtx) in walkVtxBeImpl[T](db):
|
||||
yield (vid,vtx)
|
||||
|
||||
iterator walkKeyBe*(
|
||||
T: type RdbBackendRef;
|
||||
db: AristoDbRef;
|
||||
): tuple[n: int, vid: VertexID, key: HashKey] =
|
||||
): tuple[vid: VertexID, key: HashKey] =
|
||||
## Similar to `walkVtxBe()` but for keys.
|
||||
for (n,vid,key) in walkKeyBeImpl[T](db):
|
||||
yield (n,vid,key)
|
||||
for (vid,key) in walkKeyBeImpl[T](db):
|
||||
yield (vid,key)
|
||||
|
||||
iterator walkFilBe*(
|
||||
be: RdbBackendRef;
|
||||
): tuple[n: int, qid: QueueID, filter: FilterRef] =
|
||||
): tuple[qid: QueueID, filter: FilterRef] =
|
||||
## Iterate over backend filters.
|
||||
for (n,qid,filter) in be.walkFilBeImpl:
|
||||
yield (n,qid,filter)
|
||||
for (qid,filter) in be.walkFilBeImpl:
|
||||
yield (qid,filter)
|
||||
|
||||
iterator walkFifoBe*(
|
||||
be: RdbBackendRef;
|
||||
|
|
|
@ -12,7 +12,7 @@
|
|||
import
|
||||
std/[sequtils, sets, tables],
|
||||
results,
|
||||
".."/[aristo_desc, aristo_get, aristo_layers, aristo_init, aristo_utils]
|
||||
".."/[aristo_desc, aristo_get, aristo_init, aristo_layers, aristo_utils]
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public generic iterators
|
||||
|
@ -20,10 +20,8 @@ import
|
|||
|
||||
iterator walkVtxBeImpl*[T](
|
||||
db: AristoDbRef; # Database with optional backend filter
|
||||
): tuple[n: int, vid: VertexID, vtx: VertexRef] =
|
||||
): tuple[vid: VertexID, vtx: VertexRef] =
|
||||
## Generic iterator
|
||||
var n = 0
|
||||
|
||||
when T is VoidBackendRef:
|
||||
let filter = if db.roFilter.isNil: FilterRef() else: db.roFilter
|
||||
|
||||
|
@ -34,30 +32,25 @@ iterator walkVtxBeImpl*[T](
|
|||
if not db.roFilter.isNil:
|
||||
filter.sTab = db.roFilter.sTab # copy table
|
||||
|
||||
for (_,vid,vtx) in db.backend.T.walkVtx:
|
||||
for (vid,vtx) in db.backend.T.walkVtx:
|
||||
if filter.sTab.hasKey vid:
|
||||
let fVtx = filter.sTab.getOrVoid vid
|
||||
if fVtx.isValid:
|
||||
yield (n,vid,fVtx)
|
||||
n.inc
|
||||
yield (vid,fVtx)
|
||||
filter.sTab.del vid
|
||||
else:
|
||||
yield (n,vid,vtx)
|
||||
n.inc
|
||||
yield (vid,vtx)
|
||||
|
||||
for vid in filter.sTab.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
|
||||
let vtx = filter.sTab.getOrVoid vid
|
||||
if vtx.isValid:
|
||||
yield (n,vid,vtx)
|
||||
n.inc
|
||||
yield (vid,vtx)
|
||||
|
||||
|
||||
iterator walkKeyBeImpl*[T](
|
||||
db: AristoDbRef; # Database with optional backend filter
|
||||
): tuple[n: int, vid: VertexID, key: HashKey] =
|
||||
): tuple[vid: VertexID, key: HashKey] =
|
||||
## Generic iterator
|
||||
var n = 0
|
||||
|
||||
when T is VoidBackendRef:
|
||||
let filter = if db.roFilter.isNil: FilterRef() else: db.roFilter
|
||||
|
||||
|
@ -68,33 +61,30 @@ iterator walkKeyBeImpl*[T](
|
|||
if not db.roFilter.isNil:
|
||||
filter.kMap = db.roFilter.kMap # copy table
|
||||
|
||||
for (_,vid,key) in db.backend.T.walkKey:
|
||||
for (vid,key) in db.backend.T.walkKey:
|
||||
if filter.kMap.hasKey vid:
|
||||
let fKey = filter.kMap.getOrVoid vid
|
||||
if fKey.isValid:
|
||||
yield (n,vid,fKey)
|
||||
n.inc
|
||||
yield (vid,fKey)
|
||||
filter.kMap.del vid
|
||||
else:
|
||||
yield (n,vid,key)
|
||||
n.inc
|
||||
yield (vid,key)
|
||||
|
||||
for vid in filter.kMap.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
|
||||
let key = filter.kMap.getOrVoid vid
|
||||
if key.isValid:
|
||||
yield (n,vid,key)
|
||||
n.inc
|
||||
yield (vid,key)
|
||||
|
||||
|
||||
iterator walkFilBeImpl*[T](
|
||||
be: T; # Backend descriptor
|
||||
): tuple[n: int, qid: QueueID, filter: FilterRef] =
|
||||
): tuple[qid: QueueID, filter: FilterRef] =
|
||||
## Generic filter iterator
|
||||
when T isnot VoidBackendRef:
|
||||
mixin walkFil
|
||||
|
||||
for (n,qid,filter) in be.walkFil:
|
||||
yield (n,qid,filter)
|
||||
for (qid,filter) in be.walkFil:
|
||||
yield (qid,filter)
|
||||
|
||||
|
||||
iterator walkFifoBeImpl*[T](
|
||||
|
|
|
@ -121,19 +121,24 @@ proc ppBe[T](be: T; db: KvtDbRef; indent: int): string =
|
|||
pfx1 = indent.toPfx(1)
|
||||
pfx2 = indent.toPfx(2)
|
||||
pfx3 = indent.toPfx(3)
|
||||
data = be.walk.toSeq.mapIt(
|
||||
$(1+it[0]) & "(" & it[1].ppKey(db) & "," & it[2].ppValue & ")"
|
||||
).join(pfx3)
|
||||
spc = if 0 < data.len: pfx2 else: " "
|
||||
var
|
||||
data = ""
|
||||
n = 0
|
||||
for (key,val) in be.walk:
|
||||
if 0 < n: data &= pfx3
|
||||
n.inc
|
||||
data &= $n & "(" & key.ppKey(db) & "," & val.ppValue & ")"
|
||||
var
|
||||
spc = if 0 < n: pfx2 else: " "
|
||||
"<" & $be.kind & ">" & pfx1 & "tab" & spc & "{" & data & "}"
|
||||
|
||||
proc ppLayer(layer: LayerRef; db: KvtDbRef; indent = 4): string =
|
||||
let
|
||||
tLen = layer.dTab.len
|
||||
tLen = layer.delta.sTab.len
|
||||
info = "tab(" & $tLen & ")"
|
||||
pfx1 = indent.toPfx(1)
|
||||
pfx2 = if 0 < tLen: indent.toPfx(2) else: " "
|
||||
"<layer>" & pfx1 & info & pfx2 & layer.dTab.ppTab(db,indent+2)
|
||||
"<layer>" & pfx1 & info & pfx2 & layer.delta.sTab.ppTab(db,indent+2)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public functions
|
||||
|
|
|
@ -27,7 +27,7 @@
|
|||
{.push raises: [].}
|
||||
|
||||
import
|
||||
std/[algorithm, sequtils, tables],
|
||||
std/tables,
|
||||
chronicles,
|
||||
eth/common,
|
||||
results,
|
||||
|
@ -140,14 +140,13 @@ proc memoryBackend*: BackendRef =
|
|||
|
||||
iterator walk*(
|
||||
be: MemBackendRef;
|
||||
): tuple[n: int, key: Blob, data: Blob] =
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Walk over all key-value pairs of the database.
|
||||
for n,key in be.tab.keys.toSeq.sorted:
|
||||
let data = be.tab.getOrVoid key
|
||||
if data.len == 0:
|
||||
debug logTxt "walk() skip empty", n, key
|
||||
for (key,data) in be.tab.pairs:
|
||||
if data.isValid:
|
||||
yield (key, data)
|
||||
else:
|
||||
yield (n, key, data)
|
||||
debug logTxt "walk() skip empty", key
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -169,13 +169,11 @@ proc rocksDbBackend*(
|
|||
|
||||
iterator walk*(
|
||||
be: RdbBackendRef;
|
||||
): tuple[n: int, key: Blob, data: Blob] =
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Walk over all key-value pairs of the database.
|
||||
##
|
||||
var n = 0
|
||||
for (k,v) in be.rdb.walk:
|
||||
yield (n, k,v)
|
||||
n.inc
|
||||
yield (k,v)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -11,10 +11,58 @@
|
|||
{.push raises: [].}
|
||||
|
||||
import
|
||||
std/tables,
|
||||
std/[algorithm, sequtils, sets, tables],
|
||||
eth/common,
|
||||
results,
|
||||
./kvt_desc
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public getters/helpers
|
||||
# ------------------------------------------------------------------------------
|
||||
|
||||
func nLayersKeys*(db: KvtDbRef): int =
|
||||
## Maximum number of ley/value entries on the cache layers. This is an upper
|
||||
## bound for the number of effective key/value mappings held on the cache
|
||||
## layers as there might be duplicate entries for the same key on different
|
||||
## layers.
|
||||
db.stack.mapIt(it.delta.sTab.len).foldl(a + b, db.top.delta.sTab.len)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public functions: get function
|
||||
# ------------------------------------------------------------------------------
|
||||
|
||||
proc layersHasKey*(db: KvtDbRef; key: openArray[byte]): bool =
|
||||
## Return `true` id the argument key is cached.
|
||||
##
|
||||
if db.top.delta.sTab.hasKey @key:
|
||||
return true
|
||||
|
||||
for w in db.stack.reversed:
|
||||
if w.delta.sTab.hasKey @key:
|
||||
return true
|
||||
|
||||
|
||||
proc layersGet*(db: KvtDbRef; key: openArray[byte]): Result[Blob,void] =
|
||||
## Find an item on the cache layers. An `ok()` result might contain an
|
||||
## empty value if it is stored on the cache that way.
|
||||
##
|
||||
if db.top.delta.sTab.hasKey @key:
|
||||
return ok(db.top.delta.sTab.getOrVoid @key)
|
||||
|
||||
for w in db.stack.reversed:
|
||||
if w.delta.sTab.hasKey @key:
|
||||
return ok(w.delta.sTab.getOrVoid @key)
|
||||
|
||||
err()
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public functions: put function
|
||||
# ------------------------------------------------------------------------------
|
||||
|
||||
proc layersPut*(db: KvtDbRef; key: openArray[byte]; data: openArray[byte]) =
|
||||
## Store a (potentally empty) value on the top layer
|
||||
db.top.delta.sTab[@key] = @data
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public functions
|
||||
# ------------------------------------------------------------------------------
|
||||
|
@ -23,23 +71,49 @@ proc layersCc*(db: KvtDbRef; level = high(int)): LayerRef =
|
|||
## Provide a collapsed copy of layers up to a particular transaction level.
|
||||
## If the `level` argument is too large, the maximum transaction level is
|
||||
## returned. For the result layer, the `txUid` value set to `0`.
|
||||
let level = min(level, db.stack.len)
|
||||
let layers = if db.stack.len <= level: db.stack & @[db.top]
|
||||
else: db.stack[0 .. level]
|
||||
|
||||
# Merge stack into its bottom layer
|
||||
if level <= 0 and db.stack.len == 0:
|
||||
result = LayerRef(delta: LayerDelta(sTab: db.top.delta.sTab))
|
||||
else:
|
||||
# now: 0 < level <= db.stack.len
|
||||
result = LayerRef(delta: LayerDelta(sTab: db.stack[0].delta.sTab))
|
||||
# Set up initial layer (bottom layer)
|
||||
result = LayerRef(delta: LayerDelta(sTab: layers[0].delta.sTab))
|
||||
|
||||
for n in 1 ..< level:
|
||||
for (key,val) in db.stack[n].delta.sTab.pairs:
|
||||
result.delta.sTab[key] = val
|
||||
# Consecutively merge other layers on top
|
||||
for n in 1 ..< layers.len:
|
||||
for (key,val) in layers[n].delta.sTab.pairs:
|
||||
result.delta.sTab[key] = val
|
||||
|
||||
# Merge top layer if needed
|
||||
if level == db.stack.len:
|
||||
for (key,val) in db.top.delta.sTab.pairs:
|
||||
result.delta.sTab[key] = val
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public iterators
|
||||
# ------------------------------------------------------------------------------
|
||||
|
||||
iterator layersWalk*(
|
||||
db: KvtDbRef;
|
||||
seen: var HashSet[Blob];
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Walk over all key-value pairs on the cache layers. Note that
|
||||
## entries are unsorted.
|
||||
##
|
||||
## The argument `seen` collects a set of all visited vertex IDs including
|
||||
## the one with a zero vertex which are othewise skipped by the iterator.
|
||||
## The `seen` argument must not be modified while the iterator is active.
|
||||
##
|
||||
for (key,val) in db.top.delta.sTab.pairs:
|
||||
yield (key,val)
|
||||
seen.incl key
|
||||
|
||||
for w in db.stack.reversed:
|
||||
for (key,val) in w.delta.sTab.pairs:
|
||||
if key notin seen:
|
||||
yield (key,val)
|
||||
seen.incl key
|
||||
|
||||
iterator layersWalk*(
|
||||
db: KvtDbRef;
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Variant of `layersWalk()`.
|
||||
var seen: HashSet[Blob]
|
||||
for (key,val) in db.layersWalk seen:
|
||||
yield (key,val)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -14,11 +14,10 @@
|
|||
{.push raises: [].}
|
||||
|
||||
import
|
||||
std/algorithm,
|
||||
eth/common,
|
||||
results,
|
||||
./kvt_desc/desc_backend,
|
||||
./kvt_desc
|
||||
"."/[kvt_desc, kvt_layers]
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Private helpers
|
||||
|
@ -52,7 +51,7 @@ proc put*(
|
|||
if data.len == 0:
|
||||
return err(DataInvalid)
|
||||
|
||||
db.top.delta.sTab[@key] = @data
|
||||
db.layersPut(key, data)
|
||||
ok()
|
||||
|
||||
|
||||
|
@ -65,22 +64,7 @@ proc del*(
|
|||
if key.len == 0:
|
||||
return err(KeyInvalid)
|
||||
|
||||
block haveKey:
|
||||
for w in db.stack.reversed:
|
||||
if w.delta.sTab.hasKey @key:
|
||||
break haveKey
|
||||
|
||||
# Do this one last as it is the most expensive lookup
|
||||
let rc = db.getBE key
|
||||
if rc.isOk:
|
||||
break haveKey
|
||||
if rc.error != GetNotFound:
|
||||
return err(rc.error)
|
||||
|
||||
db.top.delta.sTab.del @key # No such key anywhere => delete now
|
||||
return ok()
|
||||
|
||||
db.top.delta.sTab[@key] = EmptyBlob # Mark for deletion
|
||||
db.layersPut(key, EmptyBlob)
|
||||
ok()
|
||||
|
||||
# ------------
|
||||
|
@ -95,18 +79,10 @@ proc get*(
|
|||
if key.len == 0:
|
||||
return err(KeyInvalid)
|
||||
|
||||
block:
|
||||
let data = db.top.delta.sTab.getOrVoid @key
|
||||
if data.isValid:
|
||||
return ok(data)
|
||||
let data = db.layersGet(key).valueOr:
|
||||
return db.getBE key
|
||||
|
||||
block:
|
||||
for w in db.stack.reversed:
|
||||
let data = w.delta.sTab.getOrVoid @key
|
||||
if data.isValid:
|
||||
return ok(data)
|
||||
|
||||
db.getBE key
|
||||
return ok(data)
|
||||
|
||||
|
||||
proc hasKey*(
|
||||
|
@ -119,13 +95,9 @@ proc hasKey*(
|
|||
if key.len == 0:
|
||||
return err(KeyInvalid)
|
||||
|
||||
if db.top.delta.sTab.hasKey @key:
|
||||
if db.layersHasKey @key:
|
||||
return ok(true)
|
||||
|
||||
for w in db.stack.reversed:
|
||||
if w.delta.sTab.haskey @key:
|
||||
return ok(true)
|
||||
|
||||
let rc = db.getBE key
|
||||
if rc.isOk:
|
||||
return ok(true)
|
||||
|
|
|
@ -28,10 +28,10 @@ export
|
|||
iterator walkPairs*[T: MemBackendRef|VoidBackendRef](
|
||||
_: type T;
|
||||
db: KvtDbRef;
|
||||
): tuple[n: int; key: Blob, data: Blob] =
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Iterate over backend filters.
|
||||
for (n, vid,vtx) in walkPairsImpl[T](db):
|
||||
yield (n, vid,vtx)
|
||||
for (key,data) in walkPairsImpl[T](db):
|
||||
yield (key,data)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -34,10 +34,10 @@ export
|
|||
iterator walkPairs*(
|
||||
T: type RdbBackendRef;
|
||||
db: KvtDbRef;
|
||||
): tuple[n: int, key: Blob, data: Blob] =
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Iterate over backend filters.
|
||||
for (n, vid,vtx) in walkPairsImpl[T](db):
|
||||
yield (n, vid,vtx)
|
||||
for (key,data) in walkPairsImpl[T](db):
|
||||
yield (key,data)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -9,9 +9,9 @@
|
|||
# distributed except according to those terms.
|
||||
|
||||
import
|
||||
std/[algorithm, sets, tables],
|
||||
std/[sets, tables],
|
||||
eth/common,
|
||||
".."/[kvt_desc, kvt_init]
|
||||
".."/[kvt_desc, kvt_init, kvt_layers]
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# Public generic iterators
|
||||
|
@ -19,33 +19,20 @@ import
|
|||
|
||||
iterator walkPairsImpl*[T](
|
||||
db: KvtDbRef; # Database with top layer & backend filter
|
||||
): tuple[n: int, key: Blob, data: Blob] =
|
||||
): tuple[key: Blob, data: Blob] =
|
||||
## Walk over all `(VertexID,VertexRef)` in the database. Note that entries
|
||||
## are unsorted.
|
||||
|
||||
var
|
||||
seen: HashSet[Blob]
|
||||
i = 0
|
||||
for (key,data) in db.top.delta.sTab.pairs:
|
||||
var seen: HashSet[Blob]
|
||||
for (key,data) in db.layersWalk seen:
|
||||
if data.isValid:
|
||||
yield (i,key,data)
|
||||
i.inc
|
||||
seen.incl key
|
||||
|
||||
for w in db.stack.reversed:
|
||||
for (key,data) in w.delta.sTab.pairs:
|
||||
if key notin seen:
|
||||
if data.isValid:
|
||||
yield (i,key,data)
|
||||
i.inc
|
||||
seen.incl key
|
||||
yield (key,data)
|
||||
|
||||
when T isnot VoidBackendRef:
|
||||
mixin walk
|
||||
|
||||
for (n,key,data) in db.backend.T.walk:
|
||||
for (_,key,data) in db.backend.T.walk:
|
||||
if key notin seen and data.isValid:
|
||||
yield (n+i,key,data)
|
||||
yield (key,data)
|
||||
|
||||
# ------------------------------------------------------------------------------
|
||||
# End
|
||||
|
|
|
@ -102,8 +102,8 @@ proc verify(
|
|||
## ..
|
||||
|
||||
let
|
||||
beSTab = be.walkVtx.toSeq.mapIt((it[1],it[2])).toTable
|
||||
beKMap = be.walkKey.toSeq.mapIt((it[1],it[2])).toTable
|
||||
beSTab = be.walkVtx.toSeq.mapIt((it[0],it[1])).toTable
|
||||
beKMap = be.walkKey.toSeq.mapIt((it[0],it[1])).toTable
|
||||
|
||||
for vid in beSTab.keys.toSeq.mapIt(it.uint64).sorted.mapIt(it.VertexID):
|
||||
let
|
||||
|
@ -154,7 +154,7 @@ proc verifyFiltersImpl[T](
|
|||
): bool =
|
||||
## Compare stored filters against registered ones
|
||||
var n = 0
|
||||
for (_,fid,filter) in be.walkFilBe:
|
||||
for (fid,filter) in be.walkFilBe:
|
||||
let
|
||||
filterHash = filter.hash
|
||||
registered = tab.getOrDefault(fid, BlindHash)
|
||||
|
|
Loading…
Reference in New Issue