Google Git
Sign in
dart / sdk.git / f860b70c98d03b454eb0ad2fba70e4e2c9641a6f / . / pkg / analyzer / lib / src / dart / constant / constant_verifier.dart
blob: 221872e1b733126b4f7f5b90b94fbd19f7408cbe [file] [log] [blame]
// Copyright (c) 2018, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
import 'package:analyzer/dart/analysis/declared_variables.dart';
import 'package:analyzer/dart/analysis/features.dart';
import 'package:analyzer/dart/ast/ast.dart';
import 'package:analyzer/dart/ast/token.dart';
import 'package:analyzer/dart/ast/visitor.dart';
import 'package:analyzer/dart/constant/value.dart';
import 'package:analyzer/dart/element/element.dart';
import 'package:analyzer/dart/element/type.dart';
import 'package:analyzer/dart/element/type_provider.dart';
import 'package:analyzer/diagnostic/diagnostic.dart';
import 'package:analyzer/error/error.dart';
import 'package:analyzer/error/listener.dart';
import 'package:analyzer/src/dart/ast/extensions.dart';
import 'package:analyzer/src/dart/ast/utilities.dart';
import 'package:analyzer/src/dart/constant/evaluation.dart';
import 'package:analyzer/src/dart/constant/potentially_constant.dart';
import 'package:analyzer/src/dart/constant/value.dart';
import 'package:analyzer/src/dart/element/element.dart';
import 'package:analyzer/src/dart/element/type_system.dart';
import 'package:analyzer/src/diagnostic/diagnostic_factory.dart';
import 'package:analyzer/src/error/codes.dart';
/// Instances of the class `ConstantVerifier` traverse an AST structure looking
/// for additional errors and warnings not covered by the parser and resolver.
/// In particular, it looks for errors and warnings related to constant
/// expressions.
class ConstantVerifier extends RecursiveAstVisitor<void> {
/// The error reporter by which errors will be reported.
final ErrorReporter _errorReporter;
/// The type operations.
final TypeSystemImpl _typeSystem;
/// The type provider used to access the known types.
final TypeProvider _typeProvider;
/// The set of variables declared using '-D' on the command line.
final DeclaredVariables declaredVariables;
/// The current library that is being analyzed.
final LibraryElementImpl _currentLibrary;
final ConstantEvaluationEngine _evaluationEngine;
final DiagnosticFactory _diagnosticFactory = DiagnosticFactory();
/// Initialize a newly created constant verifier.
ConstantVerifier(
ErrorReporter errorReporter,
LibraryElementImpl currentLibrary,
DeclaredVariables declaredVariables,
) : this._(
errorReporter,
currentLibrary,
currentLibrary.typeSystem,
currentLibrary.typeProvider,
declaredVariables,
);
ConstantVerifier._(
this._errorReporter,
this._currentLibrary,
this._typeSystem,
this._typeProvider,
this.declaredVariables,
) : _evaluationEngine = ConstantEvaluationEngine(declaredVariables,
_currentLibrary.featureSet.isEnabled(Feature.triple_shift));
bool get _isNonNullableByDefault => _currentLibrary.isNonNullableByDefault;
@override
void visitAnnotation(Annotation node) {
super.visitAnnotation(node);
// check annotation creation
var element = node.element;
if (element is ConstructorElement) {
// should be 'const' constructor
if (!element.isConst) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.NON_CONSTANT_ANNOTATION_CONSTRUCTOR, node);
return;
}
// should have arguments
var argumentList = node.arguments;
if (argumentList == null) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.NO_ANNOTATION_CONSTRUCTOR_ARGUMENTS, node);
return;
}
// arguments should be constants
_validateConstantArguments(argumentList);
}
}
@override
void visitConstructorDeclaration(ConstructorDeclaration node) {
var constKeyword = node.constKeyword;
if (constKeyword != null) {
_validateConstructorInitializers(node);
if (node.factoryKeyword == null) {
_validateFieldInitializers(
node.parent as ClassOrMixinDeclaration, constKeyword);
}
}
_validateDefaultValues(node.parameters);
super.visitConstructorDeclaration(node);
}
@override
void visitFunctionExpression(FunctionExpression node) {
super.visitFunctionExpression(node);
_validateDefaultValues(node.parameters);
}
@override
void visitInstanceCreationExpression(InstanceCreationExpression node) {
if (node.isConst) {
TypeName typeName = node.constructorName.type;
_checkForConstWithTypeParameters(typeName);
node.argumentList.accept(this);
// We need to evaluate the constant to see if any errors occur during its
// evaluation.
var constructor = node.constructorName.staticElement;
if (constructor != null) {
ConstantVisitor constantVisitor =
ConstantVisitor(_evaluationEngine, _currentLibrary, _errorReporter);
_evaluationEngine.evaluateConstructorCall(
_currentLibrary,
node,
node.argumentList.arguments,
constructor,
constantVisitor,
_errorReporter);
}
} else {
super.visitInstanceCreationExpression(node);
}
}
@override
void visitListLiteral(ListLiteral node) {
super.visitListLiteral(node);
if (node.isConst) {
var nodeType = node.staticType as InterfaceType;
DartType elementType = nodeType.typeArguments[0];
var verifier = _ConstLiteralVerifier(
this,
errorCode: CompileTimeErrorCode.NON_CONSTANT_LIST_ELEMENT,
listElementType: elementType,
);
for (CollectionElement element in node.elements) {
verifier.verify(element);
}
}
}
@override
void visitMethodDeclaration(MethodDeclaration node) {
super.visitMethodDeclaration(node);
_validateDefaultValues(node.parameters);
}
@override
void visitSetOrMapLiteral(SetOrMapLiteral node) {
super.visitSetOrMapLiteral(node);
if (node.isSet) {
if (node.isConst) {
var nodeType = node.staticType as InterfaceType;
var elementType = nodeType.typeArguments[0];
var config = _SetVerifierConfig(elementType: elementType);
var verifier = _ConstLiteralVerifier(
this,
errorCode: CompileTimeErrorCode.NON_CONSTANT_SET_ELEMENT,
setConfig: config,
);
for (CollectionElement element in node.elements) {
verifier.verify(element);
}
for (var duplicateEntry in config.duplicateElements.entries) {
_errorReporter.reportError(_diagnosticFactory.equalElementsInConstSet(
_errorReporter.source, duplicateEntry.key, duplicateEntry.value));
}
}
} else if (node.isMap) {
if (node.isConst) {
var nodeType = node.staticType as InterfaceType;
var keyType = nodeType.typeArguments[0];
var valueType = nodeType.typeArguments[1];
bool reportEqualKeys = true;
var config = _MapVerifierConfig(
keyType: keyType,
valueType: valueType,
);
var verifier = _ConstLiteralVerifier(
this,
errorCode: CompileTimeErrorCode.NON_CONSTANT_MAP_ELEMENT,
mapConfig: config,
);
for (CollectionElement entry in node.elements) {
verifier.verify(entry);
}
if (reportEqualKeys) {
for (var duplicateEntry in config.duplicateKeys.entries) {
_errorReporter.reportError(_diagnosticFactory.equalKeysInConstMap(
_errorReporter.source,
duplicateEntry.key,
duplicateEntry.value));
}
}
}
}
}
@override
void visitSwitchStatement(SwitchStatement node) {
if (_isNonNullableByDefault) {
_validateSwitchStatement_nullSafety(node);
} else {
_validateSwitchStatement_legacy(node);
}
super.visitSwitchStatement(node);
}
@override
void visitVariableDeclaration(VariableDeclaration node) {
super.visitVariableDeclaration(node);
var initializer = node.initializer;
if (initializer != null && (node.isConst || node.isFinal)) {
var element = node.declaredElement as VariableElementImpl;
var result = element.evaluationResult;
if (result == null) {
// Variables marked "const" should have had their values computed by
// ConstantValueComputer. Other variables will only have had their
// values computed if the value was needed (e.g. final variables in a
// class containing const constructors).
assert(!node.isConst);
return;
}
if (node.isConst) {
_reportErrors(result.errors,
CompileTimeErrorCode.CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE);
} else {
_reportErrors(result.errors, null);
}
_reportErrorIfFromDeferredLibrary(
initializer,
CompileTimeErrorCode
.CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY);
}
}
/// Verify that the given [type] does not reference any type parameters.
///
/// See [CompileTimeErrorCode.CONST_WITH_TYPE_PARAMETERS].
void _checkForConstWithTypeParameters(TypeAnnotation type) {
// something wrong with AST
if (type is! TypeName) {
return;
}
TypeName typeName = type;
Identifier name = typeName.name;
// should not be a type parameter
if (name.staticElement is TypeParameterElement) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_WITH_TYPE_PARAMETERS, name);
}
// check type arguments
var typeArguments = typeName.typeArguments;
if (typeArguments != null) {
for (TypeAnnotation argument in typeArguments.arguments) {
_checkForConstWithTypeParameters(argument);
}
}
}
/// @return `true` if given [Type] implements operator <i>==</i>, and it is
/// not <i>int</i> or <i>String</i>.
bool _implementsEqualsWhenNotAllowed(DartType? type) {
// ignore int or String
if (type == null || type.isDartCoreInt || type.isDartCoreString) {
return false;
} else if (type.isDartCoreDouble) {
return true;
}
// prepare ClassElement
if (type is InterfaceType) {
var element = type.element;
// lookup for ==
var method = element.lookUpConcreteMethod("==", _currentLibrary);
if (method == null ||
(method.enclosingElement as ClassElement).isDartCoreObject) {
return false;
}
// there is == that we don't like
return true;
}
return false;
}
/// Given some computed [Expression], this method generates the passed
/// [ErrorCode] on the node if its' value consists of information from a
/// deferred library.
///
/// @param expression the expression to be tested for a deferred library
/// reference
/// @param errorCode the error code to be used if the expression is or
/// consists of a reference to a deferred library
void _reportErrorIfFromDeferredLibrary(Expression expression,
ErrorCode errorCode,
[List<Object?>? arguments, List<DiagnosticMessage>? messages]) {
DeferredLibraryReferenceDetector referenceDetector =
DeferredLibraryReferenceDetector();
expression.accept(referenceDetector);
if (referenceDetector.result) {
_errorReporter.reportErrorForNode(
errorCode, expression, arguments, messages);
}
}
/// Report any errors in the given list. Except for special cases, use the
/// given error code rather than the one reported in the error.
///
/// @param errors the errors that need to be reported
/// @param errorCode the error code to be used
void _reportErrors(List<AnalysisError> errors, ErrorCode? errorCode) {
int length = errors.length;
for (int i = 0; i < length; i++) {
AnalysisError data = errors[i];
ErrorCode dataErrorCode = data.errorCode;
if (identical(dataErrorCode,
CompileTimeErrorCode.CONST_EVAL_THROWS_EXCEPTION) ||
identical(
dataErrorCode, CompileTimeErrorCode.CONST_EVAL_THROWS_IDBZE) ||
identical(dataErrorCode,
CompileTimeErrorCode.CONST_EVAL_TYPE_BOOL_NUM_STRING) ||
identical(dataErrorCode, CompileTimeErrorCode.CONST_EVAL_TYPE_BOOL) ||
identical(
dataErrorCode, CompileTimeErrorCode.CONST_EVAL_TYPE_BOOL_INT) ||
identical(dataErrorCode, CompileTimeErrorCode.CONST_EVAL_TYPE_INT) ||
identical(dataErrorCode, CompileTimeErrorCode.CONST_EVAL_TYPE_NUM) ||
identical(dataErrorCode,
CompileTimeErrorCode.RECURSIVE_COMPILE_TIME_CONSTANT) ||
identical(dataErrorCode,
CompileTimeErrorCode.CONST_CONSTRUCTOR_FIELD_TYPE_MISMATCH) ||
identical(dataErrorCode,
CompileTimeErrorCode.CONST_CONSTRUCTOR_PARAM_TYPE_MISMATCH) ||
identical(
dataErrorCode, CompileTimeErrorCode.VARIABLE_TYPE_MISMATCH)) {
_errorReporter.reportError(data);
} else if (errorCode != null) {
_errorReporter.reportError(
AnalysisError(data.source, data.offset, data.length, errorCode));
}
}
}
void _reportNotPotentialConstants(AstNode node) {
var notPotentiallyConstants = getNotPotentiallyConstants(
node,
isNonNullableByDefault: _isNonNullableByDefault,
);
if (notPotentiallyConstants.isEmpty) return;
for (var notConst in notPotentiallyConstants) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.INVALID_CONSTANT,
notConst,
);
}
}
/// Validates that all arguments in the [argumentList] are potentially
/// constant expressions.
void _reportNotPotentialConstantsArguments(ArgumentList argumentList) {
for (Expression argument in argumentList.arguments) {
_reportNotPotentialConstants(argument);
}
}
/// Check if the object [obj] matches the type [type] according to runtime
/// type checking rules.
bool _runtimeTypeMatch(DartObjectImpl obj, DartType type) {
return _evaluationEngine.runtimeTypeMatch(_currentLibrary, obj, type);
}
/// Validate that the given expression is a compile time constant. Return the
/// value of the compile time constant, or `null` if the expression is not a
/// compile time constant.
///
/// @param expression the expression to be validated
/// @param errorCode the error code to be used if the expression is not a
/// compile time constant
/// @return the value of the compile time constant
DartObjectImpl? _validate(Expression expression, ErrorCode errorCode) {
RecordingErrorListener errorListener = RecordingErrorListener();
ErrorReporter subErrorReporter = ErrorReporter(
errorListener,
_errorReporter.source,
isNonNullableByDefault: _currentLibrary.isNonNullableByDefault,
);
var result = expression.accept(
ConstantVisitor(_evaluationEngine, _currentLibrary, subErrorReporter));
_reportErrors(errorListener.errors, errorCode);
return result;
}
/// Validate that if the passed arguments are constant expressions.
///
/// @param argumentList the argument list to evaluate
void _validateConstantArguments(ArgumentList argumentList) {
for (Expression argument in argumentList.arguments) {
Expression realArgument =
argument is NamedExpression ? argument.expression : argument;
_validate(
realArgument, CompileTimeErrorCode.CONST_WITH_NON_CONSTANT_ARGUMENT);
if (realArgument is PrefixedIdentifier && realArgument.isDeferred) {
_reportErrorIfFromDeferredLibrary(
realArgument,
CompileTimeErrorCode
.INVALID_ANNOTATION_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY,
[realArgument]);
}
}
}
/// Validates that the expressions of the initializers of the given constant
/// [constructor] are all compile time constants.
void _validateConstructorInitializers(ConstructorDeclaration constructor) {
NodeList<ConstructorInitializer> initializers = constructor.initializers;
for (ConstructorInitializer initializer in initializers) {
if (initializer is AssertInitializer) {
_reportNotPotentialConstants(initializer.condition);
var message = initializer.message;
if (message != null) {
_reportNotPotentialConstants(message);
}
} else if (initializer is ConstructorFieldInitializer) {
_reportNotPotentialConstants(initializer.expression);
} else if (initializer is RedirectingConstructorInvocation) {
_reportNotPotentialConstantsArguments(initializer.argumentList);
} else if (initializer is SuperConstructorInvocation) {
_reportNotPotentialConstantsArguments(initializer.argumentList);
}
}
}
/// Validate that the default value associated with each of the parameters in
/// the given list is a compile time constant.
///
/// @param parameters the list of parameters to be validated
void _validateDefaultValues(FormalParameterList? parameters) {
if (parameters == null) {
return;
}
for (FormalParameter parameter in parameters.parameters) {
if (parameter is DefaultFormalParameter) {
var defaultValue = parameter.defaultValue;
DartObjectImpl? result;
if (defaultValue == null) {
result = DartObjectImpl(
_typeSystem,
_typeProvider.nullType,
NullState.NULL_STATE,
);
} else {
result = _validate(
defaultValue, CompileTimeErrorCode.NON_CONSTANT_DEFAULT_VALUE);
if (result != null) {
_reportErrorIfFromDeferredLibrary(
defaultValue,
CompileTimeErrorCode
.NON_CONSTANT_DEFAULT_VALUE_FROM_DEFERRED_LIBRARY);
}
}
VariableElementImpl element =
parameter.declaredElement as VariableElementImpl;
element.evaluationResult = EvaluationResultImpl(result);
}
}
}
/// Validates that the expressions of any field initializers in the class
/// declaration are all compile time constants. Since this is only required if
/// the class has a constant constructor, the error is reported at the
/// constructor site.
///
/// @param classDeclaration the class which should be validated
/// @param errorSite the site at which errors should be reported.
void _validateFieldInitializers(
ClassOrMixinDeclaration classDeclaration, Token constKeyword) {
NodeList<ClassMember> members = classDeclaration.members;
for (ClassMember member in members) {
if (member is FieldDeclaration && !member.isStatic) {
for (VariableDeclaration variableDeclaration
in member.fields.variables) {
var initializer = variableDeclaration.initializer;
if (initializer != null) {
// Ignore any errors produced during validation--if the constant
// can't be evaluated we'll just report a single error.
AnalysisErrorListener errorListener =
AnalysisErrorListener.NULL_LISTENER;
ErrorReporter subErrorReporter = ErrorReporter(
errorListener,
_errorReporter.source,
isNonNullableByDefault: _currentLibrary.isNonNullableByDefault,
);
var result = initializer.accept(ConstantVisitor(
_evaluationEngine, _currentLibrary, subErrorReporter));
if (result == null) {
_errorReporter.reportErrorForToken(
CompileTimeErrorCode
.CONST_CONSTRUCTOR_WITH_FIELD_INITIALIZED_BY_NON_CONST,
constKeyword,
[variableDeclaration.name.name]);
}
}
}
}
}
}
void _validateSwitchStatement_legacy(SwitchStatement node) {
// TODO(paulberry): to minimize error messages, it would be nice to
// compare all types with the most popular type rather than the first
// type.
bool foundError = false;
DartType? firstType;
for (var switchMember in node.members) {
if (switchMember is SwitchCase) {
Expression expression = switchMember.expression;
var expressionValue = _validate(
expression,
CompileTimeErrorCode.NON_CONSTANT_CASE_EXPRESSION,
);
if (expressionValue == null) {
continue;
}
_reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode
.NON_CONSTANT_CASE_EXPRESSION_FROM_DEFERRED_LIBRARY,
);
var expressionValueType = _typeSystem.toLegacyType(
expressionValue.type,
);
if (firstType == null) {
firstType = expressionValueType;
} else {
if (firstType != expressionValueType) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.INCONSISTENT_CASE_EXPRESSION_TYPES,
expression,
[expression.toSource(), firstType],
);
foundError = true;
}
}
}
}
if (foundError) {
return;
}
if (_implementsEqualsWhenNotAllowed(firstType)) {
_errorReporter.reportErrorForToken(
CompileTimeErrorCode.CASE_EXPRESSION_TYPE_IMPLEMENTS_EQUALS,
node.switchKeyword,
[firstType],
);
}
}
void _validateSwitchStatement_nullSafety(SwitchStatement node) {
var switchType = node.expression.typeOrThrow;
for (var switchMember in node.members) {
if (switchMember is SwitchCase) {
Expression expression = switchMember.expression;
var expressionValue = _validate(
expression,
CompileTimeErrorCode.NON_CONSTANT_CASE_EXPRESSION,
);
if (expressionValue == null) {
continue;
}
_reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode
.NON_CONSTANT_CASE_EXPRESSION_FROM_DEFERRED_LIBRARY,
);
var expressionType = expressionValue.type;
if (_implementsEqualsWhenNotAllowed(expressionType)) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode.CASE_EXPRESSION_TYPE_IMPLEMENTS_EQUALS,
expression,
[expressionType],
);
}
if (!_typeSystem.isSubtypeOf(expressionType, switchType)) {
_errorReporter.reportErrorForNode(
CompileTimeErrorCode
.CASE_EXPRESSION_TYPE_IS_NOT_SWITCH_EXPRESSION_SUBTYPE,
expression,
[expressionType, switchType],
);
}
}
}
}
}
class _ConstLiteralVerifier {
final ConstantVerifier verifier;
final ErrorCode errorCode;
final DartType? listElementType;
final _SetVerifierConfig? setConfig;
final _MapVerifierConfig? mapConfig;
_ConstLiteralVerifier(
this.verifier, {
required this.errorCode,
this.listElementType,
this.mapConfig,
this.setConfig,
});
bool verify(CollectionElement element) {
if (element is Expression) {
var value = verifier._validate(element, errorCode);
if (value == null) return false;
_validateExpressionFromDeferredLibrary(element);
final listElementType = this.listElementType;
if (listElementType != null) {
return _validateListExpression(listElementType, element, value);
}
final setConfig = this.setConfig;
if (setConfig != null) {
return _validateSetExpression(setConfig, element, value);
}
return true;
} else if (element is ForElement) {
verifier._errorReporter.reportErrorForNode(errorCode, element);
return false;
} else if (element is IfElement) {
var conditionValue = verifier._validate(element.condition, errorCode);
var conditionBool = conditionValue?.toBoolValue();
// The errors have already been reported.
if (conditionBool == null) return false;
verifier._reportErrorIfFromDeferredLibrary(element.condition,
CompileTimeErrorCode.IF_ELEMENT_CONDITION_FROM_DEFERRED_LIBRARY);
var thenValid = true;
var elseValid = true;
var thenElement = element.thenElement;
var elseElement = element.elseElement;
if (conditionBool) {
thenValid = verify(thenElement);
if (elseElement != null) {
elseValid = _reportNotPotentialConstants(elseElement);
}
} else {
thenValid = _reportNotPotentialConstants(thenElement);
if (elseElement != null) {
elseValid = verify(elseElement);
}
}
return thenValid && elseValid;
} else if (element is MapLiteralEntry) {
return _validateMapLiteralEntry(element);
} else if (element is SpreadElement) {
var value = verifier._validate(element.expression, errorCode);
if (value == null) return false;
verifier._reportErrorIfFromDeferredLibrary(element.expression,
CompileTimeErrorCode.SPREAD_EXPRESSION_FROM_DEFERRED_LIBRARY);
if (listElementType != null || setConfig != null) {
return _validateListOrSetSpread(element, value);
}
final mapConfig = this.mapConfig;
if (mapConfig != null) {
return _validateMapSpread(mapConfig, element, value);
}
return true;
}
throw UnsupportedError(
'Unhandled type of collection element: ${element.runtimeType}',
);
}
/// Return `true` if the [node] is a potential constant.
bool _reportNotPotentialConstants(AstNode node) {
var notPotentiallyConstants = getNotPotentiallyConstants(
node,
isNonNullableByDefault: verifier._isNonNullableByDefault,
);
if (notPotentiallyConstants.isEmpty) return true;
for (var notConst in notPotentiallyConstants) {
CompileTimeErrorCode errorCode;
if (listElementType != null) {
errorCode = CompileTimeErrorCode.NON_CONSTANT_LIST_ELEMENT;
} else if (mapConfig != null) {
errorCode = CompileTimeErrorCode.NON_CONSTANT_MAP_ELEMENT;
for (AstNode? parent = notConst;
parent != null;
parent = parent.parent) {
if (parent is MapLiteralEntry) {
if (parent.key == notConst) {
errorCode = CompileTimeErrorCode.NON_CONSTANT_MAP_KEY;
} else {
errorCode = CompileTimeErrorCode.NON_CONSTANT_MAP_VALUE;
}
break;
}
}
} else if (setConfig != null) {
errorCode = CompileTimeErrorCode.NON_CONSTANT_SET_ELEMENT;
} else {
throw UnimplementedError();
}
verifier._errorReporter.reportErrorForNode(errorCode, notConst);
}
return false;
}
void _validateExpressionFromDeferredLibrary(Expression expression) {
if (listElementType != null) {
verifier._reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode.NON_CONSTANT_LIST_ELEMENT_FROM_DEFERRED_LIBRARY,
);
} else if (setConfig != null) {
verifier._reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode.SET_ELEMENT_FROM_DEFERRED_LIBRARY,
);
}
}
bool _validateListExpression(
DartType listElementType, Expression expression, DartObjectImpl value) {
if (!verifier._runtimeTypeMatch(value, listElementType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.LIST_ELEMENT_TYPE_NOT_ASSIGNABLE,
expression,
[value.type, listElementType],
);
return false;
}
verifier._reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode.NON_CONSTANT_LIST_ELEMENT_FROM_DEFERRED_LIBRARY,
);
return true;
}
bool _validateListOrSetSpread(SpreadElement element, DartObjectImpl value) {
var listValue = value.toListValue();
var setValue = value.toSetValue();
var iterableValue = listValue ?? setValue;
if (iterableValue == null) {
if (value.isNull && element.isNullAware) {
return true;
}
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_SPREAD_EXPECTED_LIST_OR_SET,
element.expression,
);
return false;
}
if (listValue != null) {
var elementType = value.type.typeArguments[0];
if (verifier._implementsEqualsWhenNotAllowed(elementType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_SET_ELEMENT_TYPE_IMPLEMENTS_EQUALS,
element,
[elementType],
);
return false;
}
}
final setConfig = this.setConfig;
if (setConfig != null) {
for (var item in iterableValue) {
Expression expression = element.expression;
var existingValue = setConfig.uniqueValues[item];
if (existingValue != null) {
setConfig.duplicateElements[expression] = existingValue;
} else {
setConfig.uniqueValues[item] = expression;
}
}
}
return true;
}
bool _validateMapLiteralEntry(MapLiteralEntry entry) {
var config = mapConfig;
if (config == null) return false;
var keyExpression = entry.key;
var valueExpression = entry.value;
var keyValue = verifier._validate(
keyExpression,
CompileTimeErrorCode.NON_CONSTANT_MAP_KEY,
);
var valueValue = verifier._validate(
valueExpression,
CompileTimeErrorCode.NON_CONSTANT_MAP_VALUE,
);
if (keyValue != null) {
var keyType = keyValue.type;
if (!verifier._runtimeTypeMatch(keyValue, config.keyType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.MAP_KEY_TYPE_NOT_ASSIGNABLE,
keyExpression,
[keyType, config.keyType],
);
}
if (verifier._implementsEqualsWhenNotAllowed(keyType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_MAP_KEY_EXPRESSION_TYPE_IMPLEMENTS_EQUALS,
keyExpression,
[keyType],
);
}
verifier._reportErrorIfFromDeferredLibrary(
keyExpression,
CompileTimeErrorCode.NON_CONSTANT_MAP_KEY_FROM_DEFERRED_LIBRARY,
);
var existingKey = config.uniqueKeys[keyValue];
if (existingKey != null) {
config.duplicateKeys[keyExpression] = existingKey;
} else {
config.uniqueKeys[keyValue] = keyExpression;
}
}
if (valueValue != null) {
if (!verifier._runtimeTypeMatch(valueValue, config.valueType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.MAP_VALUE_TYPE_NOT_ASSIGNABLE,
valueExpression,
[valueValue.type, config.valueType],
);
}
verifier._reportErrorIfFromDeferredLibrary(
valueExpression,
CompileTimeErrorCode.NON_CONSTANT_MAP_VALUE_FROM_DEFERRED_LIBRARY,
);
}
return true;
}
bool _validateMapSpread(
_MapVerifierConfig config,
SpreadElement element,
DartObjectImpl value,
) {
if (value.isNull && element.isNullAware) {
return true;
}
var map = value.toMapValue();
if (map != null) {
// TODO(brianwilkerson) Figure out how to improve the error messages. They
// currently point to the whole spread expression, but the key and/or
// value being referenced might not be located there (if it's referenced
// through a const variable).
for (var keyValue in map.keys) {
var existingKey = config.uniqueKeys[keyValue];
if (existingKey != null) {
config.duplicateKeys[element.expression] = existingKey;
} else {
config.uniqueKeys[keyValue] = element.expression;
}
}
return true;
}
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_SPREAD_EXPECTED_MAP,
element.expression,
);
return false;
}
bool _validateSetExpression(
_SetVerifierConfig config,
Expression expression,
DartObjectImpl value,
) {
if (!verifier._runtimeTypeMatch(value, config.elementType)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.SET_ELEMENT_TYPE_NOT_ASSIGNABLE,
expression,
[value.type, config.elementType],
);
return false;
}
if (verifier._implementsEqualsWhenNotAllowed(value.type)) {
verifier._errorReporter.reportErrorForNode(
CompileTimeErrorCode.CONST_SET_ELEMENT_TYPE_IMPLEMENTS_EQUALS,
expression,
[value.type],
);
return false;
}
verifier._reportErrorIfFromDeferredLibrary(
expression,
CompileTimeErrorCode.SET_ELEMENT_FROM_DEFERRED_LIBRARY,
);
var existingValue = config.uniqueValues[value];
if (existingValue != null) {
config.duplicateElements[expression] = existingValue;
} else {
config.uniqueValues[value] = expression;
}
return true;
}
}
class _MapVerifierConfig {
final DartType keyType;
final DartType valueType;
final Map<DartObject, Expression> uniqueKeys = {};
final Map<Expression, Expression> duplicateKeys = {};
_MapVerifierConfig({
required this.keyType,
required this.valueType,
});
}
class _SetVerifierConfig {
final DartType elementType;
final Map<DartObject, Expression> uniqueValues = {};
final Map<Expression, Expression> duplicateElements = {};
_SetVerifierConfig({
required this.elementType,
});
}