Review Verification Protocol
by @anderskev
Mandatory verification steps for all code reviews to reduce false positives. Load this skill before reporting ANY code review findings.
clawhub install review-verification-protocolπ About This Skill
name: review-verification-protocol description: Mandatory verification steps for all code reviews to reduce false positives. Load this skill before reporting ANY code review findings. user-invocable: false
Review Verification Protocol
This protocol MUST be followed before reporting any code review finding. Skipping these steps leads to false positives that waste developer time and erode trust in reviews.
Hard gates (sequenced)
Complete these in order before you add a finding. Skip a gate only when it clearly does not apply (e.g. skip the usages gate if the finding is not about dead code or βunusedβ).
1. Read scope β Pass: You name the exact file path(s) and the function, impl, or macro_rules! block you read in full (not only a diff hunk or partial snippet).
2. Usages (dead / unused) β Pass: You ran a repo-wide reference search (rg, IDE references, or equivalent) and either state zero matches for the symbol you call unused, or list each match and why it still supports the finding.
3. Surrounding behavior β Pass: You checked callers, trait impls, #[cfg], or error propagation that could make the pattern intentional; note one concrete checked location (path + rough location) or state βnone relevant after search.β
4. Edition and API β Pass: You opened the relevant Cargo.toml for the crate under review and either quote the [package] edition = "..." line or state the default edition applies and name the manifest path you checked.
5. Wrong vs style β Pass: In one sentence, you explain why the code is incorrect, unsound, or risky for this projectβnot merely a different valid style.
Pre-Report Verification Checklist
Before flagging ANY issue, verify:
Verification by Issue Type
"Unused Variable/Function"
Before flagging, you MUST:
1. Search for ALL references in the codebase (grep/find)
2. Check if it's pub and used by other crates in the workspace
3. Check if it's used via derive macros, trait implementations, or conditional compilation (#[cfg])
4. Verify it's not a trait method required by the trait definition
Common false positives:
#[cfg(test)] items only used in test buildsFrom/Into conversions"Missing Error Handling"
Before flagging, you MUST:
1. Check if the error is handled at a higher level (caller propagates with ?)
2. Check if the crate has a top-level error type that wraps this error
3. Verify the unwrap() isn't in test code or after a safety-ensuring check
Common false positives:
unwrap() in tests and examples (expected pattern)expect("reason") after validation (e.g., regex::Regex::new on a literal)? (the caller handles it)let _ = tx.send(...) β intentional when receiver may have dropped"Unnecessary Lifetime" / RPIT Capture (Edition 2024)
Before flagging, you MUST:
1. Check the project's Rust edition in Cargo.toml
2. In edition 2024, -> impl Trait captures ALL in-scope lifetimes by default
3. A lifetime that appears "unnecessary" may be implicitly captured β the code is correct
4. If the author uses + use<'a> syntax, this is precise capture control, not a mistake
Common false positives:
impl Trait β edition 2024 captures them implicitly+ use<'a, T> syntax β this is the new precise capturing syntax, not an error"Missing Unsafe Block" (Edition 2024)
Before flagging, you MUST:
1. Check if the code is inside an unsafe fn
2. In edition 2024, unsafe_op_in_unsafe_fn is deny-by-default β unsafe operations inside unsafe fn REQUIRE explicit unsafe {} blocks
3. This is edition-required behavior, not unnecessary verbosity
Common false positives:
unsafe {} blocks inside unsafe fn β REQUIRED in edition 2024, not redundantunsafe extern "C" {} β REQUIRED in edition 2024, not optional#[unsafe(no_mangle)] / #[unsafe(export_name)] β REQUIRED in edition 2024"Unnecessary Clone"
Before flagging, you MUST:
1. Confirm the clone is actually avoidable (borrow checker may require it)
2. Check if the value needs to be moved into a closure/thread/task
3. Verify the type isn't Copy (clone on Copy types is a no-op)
4. Check if the clone is in a hot path (test/setup code cloning is fine)
Common false positives:
Arc::clone(&arc) β this is the recommended explicit clone for Arctokio::spawn β required for 'static bound"Potential Race Condition"
Before flagging, you MUST:
1. Verify the data is actually shared across threads/tasks
2. Check if Mutex, RwLock, or atomic operations protect the access
3. Confirm the type doesn't already guarantee thread safety (e.g., Arc)
4. Check if the "race" is actually benign (e.g., logging, metrics)
Common false positives:
Arc> β already thread-safestd::sync::atomic operations β designed for concurrent access"Performance Issue"
Before flagging, you MUST: 1. Confirm the code runs frequently enough to matter 2. Verify the optimization would have measurable impact 3. Check if the compiler already optimizes this (iterator fusion, inlining)
Do NOT flag:
.collect() on small iteratorsSeverity Calibration
Critical (Block Merge)
ONLY use for:
unsafe code with unsound invariantsMajor (Should Fix)
Use for:
Minor (Consider Fixing)
Use for:
String parameters where &str would work#[must_use] on functions with important return valuesInformational (No Action Required)
Use for:
#[non_exhaustive]These are NOT review blockers.
Do NOT Flag At All
if let vs match for single variant)Valid Patterns (Do NOT Flag)
Rust
| Pattern | Why It's Valid |
|---------|----------------|
| unwrap() in tests | Standard test behavior β panics on unexpected errors |
| .clone() in test setup | Clarity over performance |
| use super::* in test modules | Standard pattern for accessing parent items |
| Box in binaries | Not every app needs custom error types |
| String fields in structs | Owned data is correct for struct fields |
| Arc::clone(&x) | Explicit Arc cloning is idiomatic and recommended |
| #[allow(clippy::...)] with reason | Intentional suppression is valid |
| #[expect(lint)] instead of #[allow] | Self-cleaning suppression (stable since 1.81) β warns when lint no longer triggers |
| unsafe {} inside unsafe fn | Required in edition 2024 (unsafe_op_in_unsafe_fn = deny) |
| unsafe extern "C" {} | Required in edition 2024 for extern blocks |
| #[unsafe(no_mangle)] | Required in edition 2024 for safety-relevant attributes |
| #[unsafe(export_name = "...")] | Required in edition 2024 for safety-relevant attributes |
| + use<'a, T> on impl Trait returns | Precise capture syntax for edition 2024 RPIT |
| r#gen as identifier | gen is reserved in edition 2024 |
| LazyLock / LazyCell | Standard library replacements for once_cell/lazy_static (stable since 1.80) |
| async fn in trait definitions | No longer needs async-trait crate (stable since 1.75) |
| #[diagnostic::on_unimplemented] | Custom trait error messages (stable since 1.78) |
Async/Tokio
| Pattern | Why It's Valid |
|---------|----------------|
| std::sync::Mutex for short critical sections | Tokio docs recommend this for non-async locks |
| tokio::spawn without join | Valid for background tasks with shutdown signaling |
| select! with default branch | Non-blocking check, intentional pattern |
| #[tokio::test] without multi_thread | Default single-thread is fine for most tests |
Testing
| Pattern | Why It's Valid |
|---------|----------------|
| expect() in tests | Acceptable for test setup/assertions |
| #[should_panic] with expected | Valid for testing panic behavior |
| Large test functions | Integration tests can be long |
| let _ = ... in test cleanup | Cleanup errors are often unactionable |
General
| Pattern | Why It's Valid |
|---------|----------------|
| todo!() in new code | Valid placeholder during development |
| #[allow(dead_code)] during development | Common during iteration |
| Multiple impl blocks for one type | Organized by trait or concern |
| Type aliases for complex types | Reduces boilerplate, improves readability |
Context-Sensitive Rules
Ownership
Flag unnecessary .clone() ONLY IF:
Send/'static boundsCopyError Handling
Flag missing error context ONLY IF:
? loses meaningful information about what operation failedUnsafe Code
Flag unsafe ONLY IF:
Edition 2024 unsafe changes β check Cargo.toml edition before flagging:
unsafe {} inside unsafe fn is required (not style) in edition 2024unsafe extern "C" {} is required in edition 2024 β bare extern "C" {} is a compile error#[unsafe(no_mangle)] and #[unsafe(export_name)] are required in edition 2024Edition-Aware Review
BEFORE flagging any edition-specific pattern, check Cargo.toml for the project's edition:
[package]
edition = "2024" # or "2021", "2018"
Edition 2024 changes that affect review findings:
| Change | Edition 2021 | Edition 2024 |
|--------|--------------|--------------|
| unsafe inside unsafe fn | Optional style | Required (unsafe_op_in_unsafe_fn = deny) |
| extern "C" {} | Valid | Must be unsafe extern "C" {} |
| #[no_mangle] | Valid | Must be #[unsafe(no_mangle)] |
| #[export_name] | Valid | Must be #[unsafe(export_name)] |
| -> impl Trait lifetime capture | Explicit only | Captures all in-scope lifetimes |
| gen as identifier | Valid | Reserved keyword (use r#gen) |
| ! type fallback | Falls back to () | Falls back to ! |
| if let temporaries | Dropped at end of block | Dropped earlier (end of if let) |
| Tail expression temporaries | Dropped after locals | Dropped before local variables |
| Box<[T]> iteration | Needs explicit .iter() | Has IntoIterator impl |
If edition is not specified, Rust defaults to edition 2015. Most modern projects use 2021 or later.
Cross-reference: The beagle-rust:rust-code-review and beagle-rust:rust-best-practices skills provide edition-specific code review guidance and idiomatic patterns.
Macro-Specific Verification
"Macro Hygiene Issue"
Before flagging, you MUST:
1. Verify the identifier actually leaks β types, modules, and functions are NOT hygienic in macro_rules!
2. Check if $crate is used correctly for exported macros (not crate or self)
3. Confirm ::core:: / ::alloc:: paths are needed (only for macros used in no_std contexts)
4. Check whether the macro is internal-only or #[macro_export]
Common false positives:
$crate not used in macros that are only pub(crate) β $crate is for cross-crate usage::std:: in macros for std-only crates β only flag if crate supports no_std"Procedural Macro Performance"
Before flagging, you MUST:
1. Verify the macro is actually in a proc-macro crate (check Cargo.toml for proc-macro = true)
2. Check if syn features are minimized (full syn with "full" feature vs selective features)
3. Confirm compile-time impact is meaningful (proc macros used across many files vs one-off)
"Wrong Fragment Type"
Before flagging, you MUST:
1. Verify the suggested fragment type actually works in that position
2. Check if :tt is intentionally used for flexibility (common in TT munching patterns)
3. Confirm :expr greediness issues actually manifest (test with the macro's actual call sites)
FFI-Specific Verification
"Missing repr(C)"
Before flagging, you MUST:
1. Confirm the type actually crosses the FFI boundary (passed to/from C code)
2. Check if the type is only used on the Rust side of the FFI wrapper
3. Verify there isn't a #[repr(transparent)] wrapper instead
Common false positives:
repr(C)repr(transparent) newtype wrappers β the wrapper handles layout*mut c_void) β no layout guarantee needed"FFI Safety"
Before flagging, you MUST:
1. Check if the unsafe FFI call has a SAFETY comment documenting invariants
2. Verify ownership transfer is actually ambiguous (check for Box::into_raw/Box::from_raw pairs)
3. Confirm CString lifetime issues are real (the CString must outlive the pointer passed to C)
4. Check if callback unwinding is actually possible (pure data functions can't panic across FFI)
Common false positives:
extern "C" fn callbacks that never panic β catch_unwind not needed*const c_char from CStr::as_ptr() held within the same scope β lifetime is fineunsafe β bindgen output is inherently unsafe-heavy by designConcurrency-Specific Verification
"Memory Ordering Too Weak"
Before flagging, you MUST:
1. Verify the atomic is actually shared between threads that need synchronization
2. Check if Relaxed is sufficient (counters, flags with no dependent data)
3. Confirm Acquire/Release vs SeqCst choice matters (most code doesn't need SeqCst)
Common false positives:
Relaxed on simple counters/metrics β no ordering needed for independent valuesRelaxed on boolean flags polled in a loop β the loop provides eventual visibilitySeqCst used "for safety" β not wrong, just potentially over-synchronizedBefore Submitting Review
Submission gate β Pass: Every finding uses [FILE:LINE] ISSUE_TITLE and includes the exact line (or minimal contiguous lines) that demonstrates the issue, so a reader can jump to the proof without trusting memory.
Final verification:
1. Re-read each finding and ask: "Did I verify this is actually an issue?"
2. For each finding, can you point to the specific line that proves the issue exists?
3. Would a Rust domain expert agree this is a problem, or is it a style preference?
4. Does fixing this provide real value, or is it busywork?
5. Format every finding as: [FILE:LINE] ISSUE_TITLE
6. For each finding, ask: "Does this fix existing code, or does it request entirely new code that didn't exist before?" If the latter, downgrade to Informational.
7. If this is a re-review: ONLY verify previous fixes. Do not introduce new findings.
If uncertain about any finding, either: