| name | Diagnostics |
| description | Instructions for declaring, formatting, emitting, testing, and styling diagnostic messages (errors, warnings, notes) in the Carbon toolchain. |
Diagnostics in the Carbon Toolchain
The Carbon compiler features a highly-engineered, context-aware diagnostics
framework designed to deliver precise, readable, and highly targetable
diagnostic output (errors, warnings, notes). This document establishes strict
rules for declaring, formatting, emitting, testing, and styling compiler
diagnostics.
Architecture Overview
graph TD
Kind[kind.def Registry] -->|Registration| Enum[Kind Enum ID]
Enum -->|Build/Emit| Emitter[Emitter LocT]
Emitter -->|ConvertLoc| Loc[Converted Physical Loc]
Emitter -->|formatv serialization| Formatting[format_providers.h / Custom Types]
Emitter -->|Emit Messages| Consumer[Console / Sorting Consumer]
Consumer -->|stable sort| StdErr[Compiler Standard Error]
Diagnostics are handled via three decoupled core components:
- Registry: Globally enumerated kinds inside
kind.def.
- Emitters: Specialized formatting pipelines (parameterized on custom
phase location types
LocT like Token or LocId) that convert raw tokens
to standardized physical source locations (file, line, column, and text
snippet).
- Consumers: Pipelines that process, track, filter, and sort diagnostics.
The default
SortingConsumer buffers and stable-sorts diagnostics based on
their last_byte_offset matching compiler traversal order to ensure perfect
causal ordering.
1. Declaring and Registering Diagnostics
All diagnostic types must pass structural uniqueness and coverage verifications.
The Diagnostic Registry
Every diagnostic kind must be registered globally as an enum option under
kind.def:
CARBON_DIAGNOSTIC_KIND(RealLiteralTooLargeForUnsizedInt)
The Uniqueness Rule
To ensure optimal compile-time and analysis integrity, every diagnostic kind
declared in kind.def MUST be mapped to one and only one C++ macro
declaration (CARBON_DIAGNOSTIC or CARBON_DIAGNOSTIC_ON_SCOPE).
-
DO NOT duplicate diagnostic definitions across different locations.
-
The C++ representation of the diagnostic is a static/global constant of type
DiagnosticBase<Args...>.
-
Local Scope (Recommended): If the diagnostic is unique to a single
block/function body, declare it locally inside the function body
adjacent to its Emit trigger:
void ConvertFloatValueToInt(...) {
CARBON_DIAGNOSTIC(FloatNaNConvertedToInt, Error,
"cannot convert NaN to integer type {0}", SemIR::TypeId);
context.emitter().Emit(loc_id, FloatNaNConvertedToInt, dest_type_id);
}
-
File Scope: If the diagnostic is shared among multiple functions inside
the same file, declare it at file scope inside the anonymous namespace
of the .cpp file.
-
Global Scope: If a diagnostic (such as a shared helper note) is reused
across different physical files, define it in a shared header (e.g.
context/check helpers) and mark it extern where applicable, ensuring the
macro is only invoked once.
2. Formatting Diagnostic Arguments
Carbon diagnostics leverage LLVM's formatv engine. Parameters must be passed
using strongly-typed arguments to preserve translation capability.
String Lifetimes & Pitfalls
llvm::StringRef is DISALLOWED: Do not pass StringRef as a parameter
type to CARBON_DIAGNOSTIC due to unsafe lifetime and buffer-allocation
boundaries.
llvm::StringLiteral is DISALLOWED: Do not use literal types as
arguments as they prevent future diagnostic localization and translations.
- Use
std::string: If string formatting or custom allocations are
required, declare the parameter storage type as std::string.
Format Selectors (format_providers.h)
Use specialized formatting wrappers under
format_providers.h to
express clean inline options in format strings:
| Wrapper | Target Format Style | Example Usage | Output |
|---|
BoolAsSelect | {Index:true|false} | "{0:is signed|is unsigned}" | Maps bool to selection string. |
IntAsSelect | {Index:=Val:String|:Default} | "{0:=1:is|:are}" | Matches exact options. |
IntAsSelect (Plural) | {Index:s} | "{0} argument{0:s}" | Prints "s" if value != 1 (e.g., "1 argument", "3 arguments"). |
Custom Toolchain Type Mappings
Custom structures can define how they serialize inside diagnostics using the
DiagnosticType tag mapping to Diagnostics::TypeInfo<StorageType>:
- Identifiers & Names (declared in
check/diagnostic_helpers.h):
NameId: Formats raw identifier spelling, safely escaping keyword
conflicts under backticks automatically.
LibraryNameId: Formats custom library descriptors cleanly (e.g.
default library or library "foo").
- Sized Primitives:
TypedInt: Formats an APInt constant exactly, extracting target
signedness representation automatically from its bound type
representation.
- Type Formatter Hierarchy: When choosing parameter types to print
compiler type representations, follow this priority list:
TypeOfInstId (Preferred): Resolves the backing type of an
InstId, preserving programmatic aliasing, constraints, and source
spelling context. Enclosed under backticks automatically.
InstIdAsType: Converts an InstId for a type expression, printing
custom type layouts under backticks.
TypeId (Fallback): Canonical description of the type. Avoid when
possible because type canonicalization loses intermediate source
program spelling and aliasing metadata.
*AsRawType (e.g. InstIdAsRawType, TypeIdAsRawType): Formats
the type layout exactly like their counter-structures above, but
omits enclosing backticks (useful when inserting types inside larger
code snippets).
3. Fluent Emission Builders & RAII Scopes
Fluent Builder Pattern
For compound diagnostics requiring multiple sub-notes, carets, or custom code
overrides, use Build to chain actions fluently:
context.emitter()
.Build(second_node, ModifierRepeated, context.token_kind(second_node))
.Note(first_node, ModifierPrevious, context.token_kind(first_node))
.OverrideSnippet("custom snippet...")
.Emit();
[!SAFETY] Emitter builders are marked [[nodiscard]]. To prevent a developer
from creating a builder but failing to terminal-chain .Emit(), the builder
uses an rvalue overload Emit() && that triggers a compile-time
static_assert(false). You must save the builder to an lvalue or execute the
chain exactly as emitter.Build(...).Note(...).Emit().
RAII Context & Annotation Scopes
Manage large checking structures requiring blanket note context using RAII block
scopes:
-
ContextScope: Automatically converts any diagnostics emitted within its
scope into sub-notes under a high-level operation descriptor:
ContextScope context_scope(&context.emitter(), [&](ContextBuilder& builder) {
builder.Context(eval_loc, InCallToEvalFn);
});
-
AnnotationScope: RAII block scope that automatically attaches blanket note
annotations to all scoped diagnostics.
4. Diagnostics Wording Style Guide
Refer to the official
Diagnostic message style guide
for complete details.
To maintain message consistency and integrate cleanly with Clang diagnostics in
interoperable code, adhere strictly to these rules:
- Start with lowercase and omit periods: Start diagnostic messages with a
lowercase letter or quoted code, and do not end them with a period
(e.g.,
"cannot convert..." or "`self` declared...").
- Use backticks for quoted code: Enclose identifiers, code constructs, and
types inside standard backticks (e.g.,
"`{0}` is bad").
- Phrase as bullet points without articles: Phrase diagnostics as
descriptive bullet points or sentence fragments rather than full sentences.
Leave out standard articles (
a, an, the) unless necessary for logical
clarity. Semicolons can be used to separate fragments within a message.
- Describe the situation and language rule: Diagnostics should describe
the exact situation the toolchain observed. The language rule violated can
be mentioned if it wouldn't otherwise be clear:
- Situation-only:
"redeclaration of X" (implies that redeclaration is
not permitted).
- Rule-inclusion:
"`self` declared in invalid context; can only be declared in implicit parameter list".
- Wording Choice ("cannot" vs "allowed"): Explicitly avoid
"allowed",
"legal", "permitted", "valid", and related passive wording. You may
use "cannot" if needed, but try to use phrasing that does not require it:
- Correct:
"`export` in `impl` file" (Avoids "allowed")
- Incorrect:
"`export` is only allowed in API files"
- Correct:
"`extern library` specifies current library" (Avoids
"cannot")
- Incorrect:
"`extern library` cannot specify the current library"
- Developer Intent Hints: It is acceptable for a diagnostic to guess at
the developer's intent and provide a hint after explaining the situation
and the rule, but never as a substitute for that:
- Correct:
"cannot implicitly convert `i32` to `String`; add `as String` for explicit conversion"
- Incorrect:
"add `as String` to convert `i32` to `String`" (Lacks
the core violation message).
- Structure for Tooling API: Try to structure diagnostics such that
parameter inputs can be programmatically extracted without string parsing
(prefer strongly-typed parameters over format placeholders where possible).
5. Diagnostics Testing & Coverage Verification
Carbon strictly enforces testing coverage at build-time.
-
Tag Verification Requirement: Every diagnostic kind declared in
kind.def (which is not blacklisted in the UntestedKinds array under
coverage_test.cpp)
MUST be verified by at least one testcase file inside
toolchain/*/testdata/.
-
Stderr Checklist Matchers: The testcase split verifying the diagnostic
must catch it using standard CHECK matchers, explicitly tracking the
matching enum tag in standard error comments:
// CHECK:STDERR: fail_bounds.carbon:[[@LINE+1]]:15: error: cannot convert NaN to integer type `i32` [FloatNaNConvertedToInt]
let a: i32 = Convert(nan_val);
-
Build Enforcement: Failing to provide a diagnostic test check matcher
triggers a build compilation error on the target test
//toolchain/diagnostics:coverage_test.