name	audit-linearizability
description	Analyze the cache for linearizability violations across all public methods
context	fork
agent	auditor
disable-model-invocation	true

Analyze the cache for linearizability violations. For each public method below, identify its LINEARIZATION POINT — the single atomic step at which the operation appears to take effect.

Methods to analyze:

Single-key operations:

get(key), getIfPresent(key)
put(key, value), putIfAbsent(key, value)
remove(key), remove(key, value)
replace(key, value), replace(key, oldValue, newValue)
computeIfAbsent(key, function), compute(key, function), merge(key, value, function)

Bulk / aggregate operations:

getAll(keys) / getAllPresent(keys)
putAll(map)
invalidateAll(keys) / invalidateAll()
size(), containsKey(key), containsValue(value)

Note: Bulk operations are typically NOT linearizable as a unit. State whether each provides any atomicity beyond per-element linearizability.

For each method:

State the linearization point (e.g., "CAS on CHM bin at line X").
If conditional, enumerate all cases.
Construct a 2-thread scenario confirming the linearization point.

Then attempt to construct violations: 4. Can two threads observe operations in an inconsistent order?

put(k, v1) / put(k, v2) / get(k): Can C see v2 then v1?
computeIfAbsent(k, f): Can f execute twice concurrently?
remove(k) / get(k): Can get return a value after remove linearized?

Is size() linearizable or documented as an estimate? Bounds on error?
For async cache variants: is the linearization point the future insertion or completion? Can get() return an already-replaced future?

For each candidate violation:

Provide the full interleaving
Show the sequential history it violates
Verify the interleaving is JMM-legal

Do not analyze internal consistency, only external observability.

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name	audit-linearizability
description	Analyze the cache for linearizability violations across all public methods
context	fork
agent	auditor
disable-model-invocation	true

Analyze the cache for linearizability violations. For each public method below, identify its LINEARIZATION POINT — the single atomic step at which the operation appears to take effect.

Methods to analyze:

Single-key operations:

get(key), getIfPresent(key)
put(key, value), putIfAbsent(key, value)
remove(key), remove(key, value)
replace(key, value), replace(key, oldValue, newValue)
computeIfAbsent(key, function), compute(key, function), merge(key, value, function)

Bulk / aggregate operations:

getAll(keys) / getAllPresent(keys)
putAll(map)
invalidateAll(keys) / invalidateAll()
size(), containsKey(key), containsValue(value)

Note: Bulk operations are typically NOT linearizable as a unit. State whether each provides any atomicity beyond per-element linearizability.

For each method:

State the linearization point (e.g., "CAS on CHM bin at line X").
If conditional, enumerate all cases.
Construct a 2-thread scenario confirming the linearization point.

Then attempt to construct violations: 4. Can two threads observe operations in an inconsistent order?

put(k, v1) / put(k, v2) / get(k): Can C see v2 then v1?
computeIfAbsent(k, f): Can f execute twice concurrently?
remove(k) / get(k): Can get return a value after remove linearized?

Is size() linearizable or documented as an estimate? Bounds on error?
For async cache variants: is the linearization point the future insertion or completion? Can get() return an already-replaced future?

For each candidate violation:

Provide the full interleaving
Show the sequential history it violates
Verify the interleaving is JMM-legal

Do not analyze internal consistency, only external observability.