mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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581 lines
19 KiB
Go
581 lines
19 KiB
Go
package metamorphic
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import (
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"cmp"
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"fmt"
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"slices"
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"github.com/cockroachdb/pebble"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/testkeys"
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"github.com/stretchr/testify/require"
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)
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// objKey is a tuple of (objID, key). This struct is used primarily as a map
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// key for keyManager. Only writer objTags can occur here, i.e., dbTag and
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// batchTag, since this is used for tracking the keys in a writer.
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type objKey struct {
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id objID
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key []byte
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}
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// makeObjKey returns a new objKey given and id and key.
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func makeObjKey(id objID, key []byte) objKey {
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if id.tag() != dbTag && id.tag() != batchTag {
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panic("unexpected non-writer tag")
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}
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return objKey{id, key}
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}
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// String implements fmt.Stringer, returning a stable string representation of
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// the objKey. This string is used as map key.
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func (o objKey) String() string {
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return fmt.Sprintf("%s:%s", o.id, o.key)
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}
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type keyUpdate struct {
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deleted bool
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// metaTimestamp at which the write or delete op occurred.
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metaTimestamp int
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}
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// keyMeta is metadata associated with an (objID, key) pair, where objID is
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// a writer containing the key.
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type keyMeta struct {
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objKey
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// The number of Sets of the key in this writer.
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sets int
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// The number of Merges of the key in this writer.
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merges int
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// singleDel can be true only if sets <= 1 && merges == 0 and the
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// SingleDelete was added to this writer after the set.
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singleDel bool
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// The number of Deletes of the key in this writer.
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dels int
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// del can be true only if a Delete was added to this writer after the
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// Sets and Merges counted above.
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del bool
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// updateOps should always be ordered by non-decreasing metaTimestamp.
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// updateOps will not be updated if the key is range deleted. Therefore, it
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// is a best effort sequence of updates to the key. updateOps is used to
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// determine if an iterator created on the DB can read a certain key.
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updateOps []keyUpdate
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}
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func (m *keyMeta) clear() {
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m.sets = 0
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m.merges = 0
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m.singleDel = false
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m.del = false
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m.dels = 0
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m.updateOps = nil
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}
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// mergeInto merges this metadata this into the metadata for other.
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func (m *keyMeta) mergeInto(keyManager *keyManager, other *keyMeta) {
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if other.del && !m.del {
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// m's Sets and Merges are later.
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if m.sets > 0 || m.merges > 0 {
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other.del = false
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}
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} else {
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other.del = m.del
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}
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// Sets, merges, dels are additive.
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other.sets += m.sets
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other.merges += m.merges
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other.dels += m.dels
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// Single deletes are preserved. This is valid since we are also
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// maintaining a global invariant that SingleDelete will only be added for
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// a key that has no inflight Sets or Merges (Sets have made their way to
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// the DB), and no subsequent Sets or Merges will happen until the
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// SingleDelete makes its way to the DB.
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other.singleDel = other.singleDel || m.singleDel
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if other.singleDel {
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if other.sets > 1 || other.merges > 0 || other.dels > 0 {
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panic(fmt.Sprintf("invalid sets %d or merges %d or dels %d",
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other.sets, other.merges, other.dels))
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}
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}
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// Determine if the key is visible or not after the keyMetas are merged.
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// TODO(bananabrick): We currently only care about key updates which make it
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// to the DB, since we only use key updates to determine if an iterator
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// can read a key in the DB. We could extend the timestamp system to add
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// support for iterators created on batches.
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if other.del || other.singleDel {
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other.updateOps = append(
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other.updateOps, keyUpdate{true, keyManager.nextMetaTimestamp()},
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)
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} else {
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other.updateOps = append(
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other.updateOps, keyUpdate{false, keyManager.nextMetaTimestamp()},
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)
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}
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}
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// keyManager tracks the write operations performed on keys in the generation
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// phase of the metamorphic test. It makes the assumption that write
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// operations do not fail, since that can cause the keyManager state to be not
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// in-sync with the actual state of the writers. This assumption is needed to
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// correctly decide when it is safe to generate a SingleDelete. This
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// assumption is violated in a single place in the metamorphic test: ingestion
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// of multiple batches. We sidestep this issue in a narrow way in
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// generator.writerIngest by not ingesting multiple batches that contain
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// deletes or single deletes, since loss of those specific operations on a key
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// are what we cannot tolerate (doing SingleDelete on a key that has not been
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// written to because the Set was lost is harmless).
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type keyManager struct {
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comparer *base.Comparer
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// metaTimestamp is used to provide a ordering over certain operations like
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// iter creation, updates to keys. Keeping track of the timestamp allows us
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// to make determinations such as whether a key will be visible to an
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// iterator.
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metaTimestamp int
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// byObjKey tracks the state for each (writer, key) pair. It refers to the
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// same *keyMeta as in the byObj slices. Using a map allows for fast state
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// lookups when changing the state based on a writer operation on the key.
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byObjKey map[string]*keyMeta
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// List of keys per writer, and what has happened to it in that writer.
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// Will be transferred when needed.
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byObj map[objID][]*keyMeta
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// globalKeys represents all the keys that have been generated so far. Not
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// all these keys have been written to. globalKeys is sorted.
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globalKeys [][]byte
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// globalKeysMap contains the same keys as globalKeys. It ensures no
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// duplication, and contains the aggregate state of the key across all
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// writers, including inflight state that has not made its way to the DB
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// yet.The keyMeta.objKey is uninitialized.
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globalKeysMap map[string]*keyMeta
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// globalKeyPrefixes contains all the key prefixes (as defined by the
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// comparer's Split) generated so far. globalKeyPrefixes is sorted.
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globalKeyPrefixes [][]byte
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// globalKeyPrefixesMap contains the same keys as globalKeyPrefixes. It
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// ensures no duplication.
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globalKeyPrefixesMap map[string]struct{}
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// Using SingleDeletes imposes some constraints on the above state, and
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// causes some state transitions that help with generating complex but
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// correct sequences involving SingleDeletes.
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// - Generating a SingleDelete requires for that key: global.merges==0 &&
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// global.sets==1 && global.dels==0 && !global.singleDel && (db.sets==1
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// || writer.sets==1), where global represents the entry in
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// globalKeysMap[key] and db represents the entry in
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// byObjKey[makeObjKey(makeObjID(dbTag, 0), key)], and writer is the
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// entry in byObjKey[makeObjKey(writerID, key)].
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//
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// - We do not track state changes due to range deletes, so one should
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// think of these counts as upper bounds. Also we are not preventing
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// interactions caused by concurrently in-flight range deletes and
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// SingleDelete. This is acceptable since it does not cause
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// non-determinism.
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//
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// - When the SingleDelete is generated, it is recorded as
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// writer.singleDel=true and global.singleDel=true. No more write
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// operations are permitted on this key until db.singleDel transitions
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// to true.
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//
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// - When db.singleDel transitions to true, we are guaranteed that no
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// writer other than the DB has any writes for this key. We set
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// db.singleDel and global.singleDel to false and the corresponding sets
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// and merges counts in global and db also to 0. This allows this key to
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// fully participate again in write operations. This means we can
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// generate sequences of the form:
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// SET => SINGLEDEL => SET* => MERGE* => DEL
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// SET => SINGLEDEL => SET => SINGLEDEL, among others.
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//
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// - The above logic is insufficient to generate sequences of the form
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// SET => DEL => SET => SINGLEDEL
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// To do this we need to track Deletes. When db.del transitions to true,
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// we check if db.sets==global.sets && db.merges==global.merges &&
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// db.dels==global.dels. If true, there are no in-flight
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// sets/merges/deletes to this key. We then default initialize the
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// global and db entries since one can behave as if this key was never
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// written in this system. This enables the above sequence, among
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// others.
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}
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func (k *keyManager) nextMetaTimestamp() int {
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ret := k.metaTimestamp
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k.metaTimestamp++
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return ret
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}
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// newKeyManager returns a pointer to a new keyManager. Callers should
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// interact with this using addNewKey, eligible*Keys, update,
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// canTolerateApplyFailure methods only.
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func newKeyManager(numInstances int) *keyManager {
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m := &keyManager{
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comparer: testkeys.Comparer,
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byObjKey: make(map[string]*keyMeta),
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byObj: make(map[objID][]*keyMeta),
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globalKeysMap: make(map[string]*keyMeta),
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globalKeyPrefixesMap: make(map[string]struct{}),
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}
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for i := 1; i <= max(numInstances, 1); i++ {
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m.byObj[makeObjID(dbTag, uint32(i))] = []*keyMeta{}
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}
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return m
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}
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// addNewKey adds the given key to the key manager for global key tracking.
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// Returns false iff this is not a new key.
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func (k *keyManager) addNewKey(key []byte) bool {
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_, ok := k.globalKeysMap[string(key)]
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if ok {
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return false
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}
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keyString := string(key)
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insertSorted(k.comparer.Compare, &k.globalKeys, key)
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k.globalKeysMap[keyString] = &keyMeta{objKey: objKey{key: key}}
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prefixLen := k.comparer.Split(key)
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if _, ok := k.globalKeyPrefixesMap[keyString[:prefixLen]]; !ok {
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insertSorted(k.comparer.Compare, &k.globalKeyPrefixes, key[:prefixLen])
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k.globalKeyPrefixesMap[keyString[:prefixLen]] = struct{}{}
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}
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return true
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}
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// getOrInit returns the keyMeta for the (objID, key) pair, if it exists, else
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// allocates, initializes and returns a new value.
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func (k *keyManager) getOrInit(id objID, key []byte) *keyMeta {
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o := makeObjKey(id, key)
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m, ok := k.byObjKey[o.String()]
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if ok {
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return m
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}
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m = &keyMeta{objKey: makeObjKey(id, key)}
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// Initialize the key-to-meta index.
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k.byObjKey[o.String()] = m
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// Add to the id-to-metas slide.
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k.byObj[o.id] = append(k.byObj[o.id], m)
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return m
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}
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// contains returns true if the (objID, key) pair is tracked by the keyManager.
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func (k *keyManager) contains(id objID, key []byte) bool {
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_, ok := k.byObjKey[makeObjKey(id, key).String()]
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return ok
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}
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// mergeKeysInto merges all metadata for all keys associated with the "from" ID
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// with the metadata for keys associated with the "to" ID.
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func (k *keyManager) mergeKeysInto(from, to objID) {
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msFrom, ok := k.byObj[from]
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if !ok {
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msFrom = []*keyMeta{}
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k.byObj[from] = msFrom
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}
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msTo, ok := k.byObj[to]
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if !ok {
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msTo = []*keyMeta{}
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k.byObj[to] = msTo
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}
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// Sort to facilitate a merge.
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slices.SortFunc(msFrom, func(a, b *keyMeta) int {
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return cmp.Compare(a.String(), b.String())
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})
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slices.SortFunc(msTo, func(a, b *keyMeta) int {
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return cmp.Compare(a.String(), b.String())
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})
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var msNew []*keyMeta
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var iTo int
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for _, m := range msFrom {
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// Move cursor on mTo forward.
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for iTo < len(msTo) && string(msTo[iTo].key) < string(m.key) {
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msNew = append(msNew, msTo[iTo])
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iTo++
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}
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var mTo *keyMeta
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if iTo < len(msTo) && string(msTo[iTo].key) == string(m.key) {
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mTo = msTo[iTo]
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iTo++
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} else {
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mTo = &keyMeta{objKey: makeObjKey(to, m.key)}
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k.byObjKey[mTo.String()] = mTo
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}
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m.mergeInto(k, mTo)
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msNew = append(msNew, mTo)
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delete(k.byObjKey, m.String()) // Unlink "from".
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}
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// Add any remaining items from the "to" set.
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for iTo < len(msTo) {
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msNew = append(msNew, msTo[iTo])
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iTo++
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}
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k.byObj[to] = msNew // Update "to".
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delete(k.byObj, from) // Unlink "from".
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}
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func (k *keyManager) checkForDelOrSingleDelTransition(dbMeta *keyMeta, globalMeta *keyMeta) {
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if dbMeta.singleDel {
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if !globalMeta.singleDel {
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panic("inconsistency with globalMeta")
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}
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if dbMeta.del || globalMeta.del || dbMeta.dels > 0 || globalMeta.dels > 0 ||
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dbMeta.merges > 0 || globalMeta.merges > 0 || dbMeta.sets != 1 || globalMeta.sets != 1 {
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panic("inconsistency in metas when SingleDelete applied to DB")
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}
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dbMeta.clear()
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globalMeta.clear()
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return
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}
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if dbMeta.del && globalMeta.sets == dbMeta.sets && globalMeta.merges == dbMeta.merges &&
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globalMeta.dels == dbMeta.dels {
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if dbMeta.singleDel || globalMeta.singleDel {
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panic("Delete should not have happened given SingleDelete")
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}
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dbMeta.clear()
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globalMeta.clear()
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}
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}
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func (k *keyManager) checkForDelOrSingleDelTransitionInDB(dbID objID) {
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keys := k.byObj[dbID]
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for _, dbMeta := range keys {
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globalMeta := k.globalKeysMap[string(dbMeta.key)]
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k.checkForDelOrSingleDelTransition(dbMeta, globalMeta)
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}
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}
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// update updates the internal state of the keyManager according to the given
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// op.
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func (k *keyManager) update(o op) {
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switch s := o.(type) {
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case *setOp:
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meta := k.getOrInit(s.writerID, s.key)
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globalMeta := k.globalKeysMap[string(s.key)]
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meta.sets++ // Update the set count on this specific (id, key) pair.
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meta.del = false
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globalMeta.sets++
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meta.updateOps = append(meta.updateOps, keyUpdate{false, k.nextMetaTimestamp()})
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if meta.singleDel || globalMeta.singleDel {
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panic("setting a key that has in-flight SingleDelete")
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}
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case *mergeOp:
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meta := k.getOrInit(s.writerID, s.key)
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globalMeta := k.globalKeysMap[string(s.key)]
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meta.merges++
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meta.del = false
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globalMeta.merges++
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meta.updateOps = append(meta.updateOps, keyUpdate{false, k.nextMetaTimestamp()})
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if meta.singleDel || globalMeta.singleDel {
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panic("merging a key that has in-flight SingleDelete")
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}
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case *deleteOp:
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meta := k.getOrInit(s.writerID, s.key)
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globalMeta := k.globalKeysMap[string(s.key)]
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meta.del = true
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globalMeta.del = true
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meta.dels++
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globalMeta.dels++
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meta.updateOps = append(meta.updateOps, keyUpdate{true, k.nextMetaTimestamp()})
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if s.writerID.tag() == dbTag {
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k.checkForDelOrSingleDelTransition(meta, globalMeta)
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}
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case *singleDeleteOp:
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if !k.globalStateIndicatesEligibleForSingleDelete(s.key) {
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panic("key ineligible for SingleDelete")
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}
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meta := k.getOrInit(s.writerID, s.key)
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globalMeta := k.globalKeysMap[string(s.key)]
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meta.singleDel = true
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globalMeta.singleDel = true
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meta.updateOps = append(meta.updateOps, keyUpdate{true, k.nextMetaTimestamp()})
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if s.writerID.tag() == dbTag {
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k.checkForDelOrSingleDelTransition(meta, globalMeta)
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}
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case *ingestOp:
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// For each batch, merge all keys with the keys in the DB.
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for _, batchID := range s.batchIDs {
|
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k.mergeKeysInto(batchID, s.dbID)
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}
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k.checkForDelOrSingleDelTransitionInDB(s.dbID)
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case *applyOp:
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// Merge the keys from this writer into the parent writer.
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k.mergeKeysInto(s.batchID, s.writerID)
|
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if s.writerID.tag() == dbTag {
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k.checkForDelOrSingleDelTransitionInDB(s.writerID)
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}
|
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case *batchCommitOp:
|
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// Merge the keys from the batch with the keys from the DB.
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k.mergeKeysInto(s.batchID, s.dbID)
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k.checkForDelOrSingleDelTransitionInDB(s.dbID)
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}
|
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}
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|
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func (k *keyManager) eligibleReadKeys() (keys [][]byte) {
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return k.globalKeys
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}
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|
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// eligibleReadKeysInRange returns all eligible read keys within the range
|
|
// [start,end). The returned slice is owned by the keyManager and must not be
|
|
// retained.
|
|
func (k *keyManager) eligibleReadKeysInRange(kr pebble.KeyRange) (keys [][]byte) {
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s, _ := slices.BinarySearchFunc(k.globalKeys, kr.Start, k.comparer.Compare)
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e, _ := slices.BinarySearchFunc(k.globalKeys, kr.End, k.comparer.Compare)
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if s >= e {
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return nil
|
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}
|
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return k.globalKeys[s:e]
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}
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|
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func (k *keyManager) prefixes() (prefixes [][]byte) {
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return k.globalKeyPrefixes
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}
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|
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// prefixExists returns true if a key has been generated with the provided
|
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// prefix before.
|
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func (k *keyManager) prefixExists(prefix []byte) bool {
|
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_, exists := k.globalKeyPrefixesMap[string(prefix)]
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return exists
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}
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|
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func (k *keyManager) eligibleWriteKeys() (keys [][]byte) {
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// Creating and sorting this slice of keys is wasteful given that the
|
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// caller will pick one, but makes it simpler for unit testing.
|
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for _, v := range k.globalKeysMap {
|
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if v.singleDel {
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continue
|
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}
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keys = append(keys, v.key)
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}
|
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slices.SortFunc(keys, k.comparer.Compare)
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return keys
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}
|
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|
|
// eligibleSingleDeleteKeys returns a slice of keys that can be safely single
|
|
// deleted, given the writer id.
|
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func (k *keyManager) eligibleSingleDeleteKeys(id, dbID objID) (keys [][]byte) {
|
|
// Creating and sorting this slice of keys is wasteful given that the
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// caller will pick one, but makes it simpler for unit testing.
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addForObjID := func(id objID) {
|
|
for _, m := range k.byObj[id] {
|
|
if m.sets == 1 && k.globalStateIndicatesEligibleForSingleDelete(m.key) {
|
|
keys = append(keys, m.key)
|
|
}
|
|
}
|
|
}
|
|
addForObjID(id)
|
|
if id.tag() != dbTag {
|
|
addForObjID(dbID)
|
|
}
|
|
slices.SortFunc(keys, k.comparer.Compare)
|
|
return keys
|
|
}
|
|
|
|
func (k *keyManager) globalStateIndicatesEligibleForSingleDelete(key []byte) bool {
|
|
m := k.globalKeysMap[string(key)]
|
|
return m.merges == 0 && m.sets == 1 && m.dels == 0 && !m.singleDel
|
|
}
|
|
|
|
// canTolerateApplyFailure is called with a batch ID and returns true iff a
|
|
// failure to apply this batch to the DB can be tolerated.
|
|
func (k *keyManager) canTolerateApplyFailure(id objID) bool {
|
|
if id.tag() != batchTag {
|
|
panic("called with an objID that is not a batch")
|
|
}
|
|
ms, ok := k.byObj[id]
|
|
if !ok {
|
|
return true
|
|
}
|
|
for _, m := range ms {
|
|
if m.singleDel || m.del {
|
|
return false
|
|
}
|
|
}
|
|
return true
|
|
}
|
|
|
|
func opWrittenKeys(untypedOp op) [][]byte {
|
|
switch t := untypedOp.(type) {
|
|
case *applyOp:
|
|
case *batchCommitOp:
|
|
case *checkpointOp:
|
|
case *closeOp:
|
|
case *compactOp:
|
|
case *dbRestartOp:
|
|
case *deleteOp:
|
|
return [][]byte{t.key}
|
|
case *deleteRangeOp:
|
|
return [][]byte{t.start, t.end}
|
|
case *flushOp:
|
|
case *getOp:
|
|
case *ingestOp:
|
|
case *initOp:
|
|
case *iterFirstOp:
|
|
case *iterLastOp:
|
|
case *iterNextOp:
|
|
case *iterNextPrefixOp:
|
|
case *iterCanSingleDelOp:
|
|
case *iterPrevOp:
|
|
case *iterSeekGEOp:
|
|
case *iterSeekLTOp:
|
|
case *iterSeekPrefixGEOp:
|
|
case *iterSetBoundsOp:
|
|
case *iterSetOptionsOp:
|
|
case *mergeOp:
|
|
return [][]byte{t.key}
|
|
case *newBatchOp:
|
|
case *newIndexedBatchOp:
|
|
case *newIterOp:
|
|
case *newIterUsingCloneOp:
|
|
case *newSnapshotOp:
|
|
case *rangeKeyDeleteOp:
|
|
case *rangeKeySetOp:
|
|
case *rangeKeyUnsetOp:
|
|
case *setOp:
|
|
return [][]byte{t.key}
|
|
case *singleDeleteOp:
|
|
return [][]byte{t.key}
|
|
case *replicateOp:
|
|
return [][]byte{t.start, t.end}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func loadPrecedingKeys(t TestingT, ops []op, cfg *config, m *keyManager) {
|
|
for _, op := range ops {
|
|
// Pretend we're generating all the operation's keys as potential new
|
|
// key, so that we update the key manager's keys and prefix sets.
|
|
for _, k := range opWrittenKeys(op) {
|
|
m.addNewKey(k)
|
|
|
|
// If the key has a suffix, ratchet up the suffix distribution if
|
|
// necessary.
|
|
if s := m.comparer.Split(k); s < len(k) {
|
|
suffix, err := testkeys.ParseSuffix(k[s:])
|
|
require.NoError(t, err)
|
|
if uint64(suffix) > cfg.writeSuffixDist.Max() {
|
|
diff := int(uint64(suffix) - cfg.writeSuffixDist.Max())
|
|
cfg.writeSuffixDist.IncMax(diff)
|
|
}
|
|
}
|
|
}
|
|
|
|
// Update key tracking state.
|
|
m.update(op)
|
|
}
|
|
}
|
|
|
|
func insertSorted(cmp base.Compare, dst *[][]byte, k []byte) {
|
|
s := *dst
|
|
i, _ := slices.BinarySearchFunc(s, k, cmp)
|
|
*dst = slices.Insert(s, i, k)
|
|
}
|