| // Copyright (c) 2014, 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/error/error.dart'; |
| import 'package:analyzer/src/error/analyzer_error_code.dart'; |
| |
| export 'package:analyzer/src/analysis_options/error/option_codes.dart'; |
| export 'package:analyzer/src/dart/error/hint_codes.dart'; |
| export 'package:analyzer/src/dart/error/lint_codes.dart'; |
| export 'package:analyzer/src/dart/error/todo_codes.dart'; |
| |
| // It is hard to visually separate each code's _doc comment_ from its published |
| // _documentation comment_ when each is written as an end-of-line comment. |
| // ignore_for_file: slash_for_doc_comments |
| |
| /** |
| * The error codes used for compile time errors. The convention for this class |
| * is for the name of the error code to indicate the problem that caused the |
| * error to be generated and for the error message to explain what is wrong and, |
| * when appropriate, how the problem can be corrected. |
| */ |
| class CompileTimeErrorCode extends AnalyzerErrorCode { |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a field that has the `abstract` |
| // modifier also has an initializer. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `f` is marked as |
| // `abstract` and has an initializer: |
| // |
| // ```dart |
| // abstract class C { |
| // abstract int [!f!] = 0; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `f` is marked as |
| // `abstract` and there's an initializer in the constructor: |
| // |
| // ```dart |
| // abstract class C { |
| // abstract int f; |
| // |
| // C() : [!f!] = 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field must be abstract, then remove the initializer: |
| // |
| // ```dart |
| // abstract class C { |
| // abstract int f; |
| // } |
| // ``` |
| // |
| // If the field isn't required to be abstract, then remove the keyword: |
| // |
| // ```dart |
| // abstract class C { |
| // int f = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode ABSTRACT_FIELD_CONSTRUCTOR_INITIALIZER = |
| CompileTimeErrorCode( |
| 'ABSTRACT_FIELD_INITIALIZER', |
| "Abstract fields can't have initializers.", |
| correction: "Try removing the field initializer or the 'abstract' keyword " |
| "from the field declaration.", |
| hasPublishedDocs: true, |
| uniqueName: 'ABSTRACT_FIELD_CONSTRUCTOR_INITIALIZER', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode ABSTRACT_FIELD_INITIALIZER = |
| CompileTimeErrorCode('ABSTRACT_FIELD_INITIALIZER', |
| "Abstract fields can't have initializers.", |
| correction: "Try removing the initializer or the 'abstract' keyword.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the display name for the kind of the found abstract member |
| * 1: the name of the member |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an inherited member is |
| // referenced using `super`, but there is no concrete implementation of the |
| // member in the superclass chain. Abstract members can't be invoked. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `B` doesn't inherit a |
| // concrete implementation of `a`: |
| // |
| // ```dart |
| // abstract class A { |
| // int get a; |
| // } |
| // class B extends A { |
| // int get a => super.[!a!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the invocation of the abstract member, possibly replacing it with an |
| // invocation of a concrete member. |
| // TODO(brianwilkerson) This either needs to be generalized (use 'member' |
| // rather than '{0}') or split into multiple codes. |
| static const CompileTimeErrorCode ABSTRACT_SUPER_MEMBER_REFERENCE = |
| CompileTimeErrorCode('ABSTRACT_SUPER_MEMBER_REFERENCE', |
| "The {0} '{1}' is always abstract in the supertype.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the ambiguous element |
| * 1: the name of the first library in which the type is found |
| * 2: the name of the second library in which the type is found |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when two or more export directives |
| // cause the same name to be exported from multiple libraries. |
| // |
| // #### Example |
| // |
| // Given a file named `a.dart` containing |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class C {} |
| // ``` |
| // |
| // And a file named `b.dart` containing |
| // |
| // ```dart |
| // %uri="lib/b.dart" |
| // class C {} |
| // ``` |
| // |
| // The following code produces this diagnostic because the name `C` is being |
| // exported from both `a.dart` and `b.dart`: |
| // |
| // ```dart |
| // export 'a.dart'; |
| // export [!'b.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If none of the names in one of the libraries needs to be exported, then |
| // remove the unnecessary export directives: |
| // |
| // ```dart |
| // export 'a.dart'; |
| // ``` |
| // |
| // If all of the export directives are needed, then hide the name in all |
| // except one of the directives: |
| // |
| // ```dart |
| // export 'a.dart'; |
| // export 'b.dart' hide C; |
| // ``` |
| static const CompileTimeErrorCode AMBIGUOUS_EXPORT = CompileTimeErrorCode( |
| 'AMBIGUOUS_EXPORT', |
| "The name '{0}' is defined in the libraries '{1}' and '{2}'.", |
| correction: "Try removing the export of one of the libraries, or " |
| "explicitly hiding the name in one of the export directives.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the member |
| * 1: the name of the first declaring extension |
| * 2: the name of the second declaring extension |
| */ |
| // #### Description |
| // |
| // When code refers to a member of an object (for example, `o.m()` or `o.m` or |
| // `o[i]`) where the static type of `o` doesn't declare the member (`m` or |
| // `[]`, for example), then the analyzer tries to find the member in an |
| // extension. For example, if the member is `m`, then the analyzer looks for |
| // extensions that declare a member named `m` and have an extended type that |
| // the static type of `o` can be assigned to. When there's more than one such |
| // extension in scope, the extension whose extended type is most specific is |
| // selected. |
| // |
| // The analyzer produces this diagnostic when none of the extensions has an |
| // extended type that's more specific than the extended types of all of the |
| // other extensions, making the reference to the member ambiguous. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there's no way to |
| // choose between the member in `E1` and the member in `E2`: |
| // |
| // ```dart |
| // extension E1 on String { |
| // int get charCount => 1; |
| // } |
| // |
| // extension E2 on String { |
| // int get charCount => 2; |
| // } |
| // |
| // void f(String s) { |
| // print(s.[!charCount!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you don't need both extensions, then you can delete or hide one of them. |
| // |
| // If you need both, then explicitly select the one you want to use by using |
| // an extension override: |
| // |
| // ```dart |
| // extension E1 on String { |
| // int get charCount => length; |
| // } |
| // |
| // extension E2 on String { |
| // int get charCount => length; |
| // } |
| // |
| // void f(String s) { |
| // print(E2(s).charCount); |
| // } |
| // ``` |
| static const CompileTimeErrorCode AMBIGUOUS_EXTENSION_MEMBER_ACCESS = |
| CompileTimeErrorCode( |
| 'AMBIGUOUS_EXTENSION_MEMBER_ACCESS', |
| "A member named '{0}' is defined in extensions {1}, and " |
| "none are more specific.", |
| correction: |
| "Try using an extension override to specify the extension " |
| "you want to be chosen.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the ambiguous type |
| * 1: the name of the first library that the type is found |
| * 2: the name of the second library that the type is found |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name is referenced that is |
| // declared in two or more imported libraries. |
| // |
| // #### Examples |
| // |
| // Given a library (`a.dart`) that defines a class (`C` in this example): |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class A {} |
| // class C {} |
| // ``` |
| // |
| // And a library (`b.dart`) that defines a different class with the same name: |
| // |
| // ```dart |
| // %uri="lib/b.dart" |
| // class B {} |
| // class C {} |
| // ``` |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // import 'a.dart'; |
| // import 'b.dart'; |
| // |
| // void f([!C!] c1, [!C!] c2) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If any of the libraries aren't needed, then remove the import directives |
| // for them: |
| // |
| // ```dart |
| // import 'a.dart'; |
| // |
| // void f(C c1, C c2) {} |
| // ``` |
| // |
| // If the name is still defined by more than one library, then add a `hide` |
| // clause to the import directives for all except one library: |
| // |
| // ```dart |
| // import 'a.dart' hide C; |
| // import 'b.dart'; |
| // |
| // void f(C c1, C c2) {} |
| // ``` |
| // |
| // If you must be able to reference more than one of these types, then add a |
| // prefix to each of the import directives, and qualify the references with |
| // the appropriate prefix: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // import 'b.dart' as b; |
| // |
| // void f(a.C c1, b.C c2) {} |
| // ``` |
| static const CompileTimeErrorCode AMBIGUOUS_IMPORT = CompileTimeErrorCode( |
| 'AMBIGUOUS_IMPORT', "The name '{0}' is defined in the libraries {1}.", |
| correction: "Try using 'as prefix' for one of the import directives, or " |
| "hiding the name from all but one of the imports.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // Because map and set literals use the same delimiters (`{` and `}`), the |
| // analyzer looks at the type arguments and the elements to determine which |
| // kind of literal you meant. When there are no type arguments, then the |
| // analyzer uses the types of the elements. If all of the elements are literal |
| // map entries and all of the spread operators are spreading a `Map` then it's |
| // a `Map`. If none of the elements are literal map entries and all of the |
| // spread operators are spreading an `Iterable`, then it's a `Set`. If neither |
| // of those is true then it's ambiguous. |
| // |
| // The analyzer produces this diagnostic when at least one element is a |
| // literal map entry or a spread operator spreading a `Map`, and at least one |
| // element is neither of these, making it impossible for the analyzer to |
| // determine whether you are writing a map literal or a set literal. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // union(Map<String, String> a, List<String> b, Map<String, String> c) => |
| // [!{...a, ...b, ...c}!]; |
| // ``` |
| // |
| // The list `b` can only be spread into a set, and the maps `a` and `c` can |
| // only be spread into a map, and the literal can't be both. |
| // |
| // #### Common fixes |
| // |
| // There are two common ways to fix this problem. The first is to remove all |
| // of the spread elements of one kind or another, so that the elements are |
| // consistent. In this case, that likely means removing the list and deciding |
| // what to do about the now unused parameter: |
| // |
| // ```dart |
| // union(Map<String, String> a, List<String> b, Map<String, String> c) => |
| // {...a, ...c}; |
| // ``` |
| // |
| // The second fix is to change the elements of one kind into elements that are |
| // consistent with the other elements. For example, you can add the elements |
| // of the list as keys that map to themselves: |
| // |
| // ```dart |
| // union(Map<String, String> a, List<String> b, Map<String, String> c) => |
| // {...a, for (String s in b) s: s, ...c}; |
| // ``` |
| static const CompileTimeErrorCode AMBIGUOUS_SET_OR_MAP_LITERAL_BOTH = |
| CompileTimeErrorCode( |
| 'AMBIGUOUS_SET_OR_MAP_LITERAL_BOTH', |
| "The literal can't be either a map or a set because it contains at " |
| "least one literal map entry or a spread operator spreading a " |
| "'Map', and at least one element which is neither of these.", |
| correction: |
| "Try removing or changing some of the elements so that all of " |
| "the elements are consistent.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // Because map and set literals use the same delimiters (`{` and `}`), the |
| // analyzer looks at the type arguments and the elements to determine which |
| // kind of literal you meant. When there are no type arguments and all of the |
| // elements are spread elements (which are allowed in both kinds of literals) |
| // then the analyzer uses the types of the expressions that are being spread. |
| // If all of the expressions have the type `Iterable`, then it's a set |
| // literal; if they all have the type `Map`, then it's a map literal. |
| // |
| // This diagnostic is produced when none of the expressions being spread have |
| // a type that allows the analyzer to decide whether you were writing a map |
| // literal or a set literal. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // union(a, b) => [!{...a, ...b}!]; |
| // ``` |
| // |
| // The problem occurs because there are no type arguments, and there is no |
| // information about the type of either `a` or `b`. |
| // |
| // #### Common fixes |
| // |
| // There are three common ways to fix this problem. The first is to add type |
| // arguments to the literal. For example, if the literal is intended to be a |
| // map literal, you might write something like this: |
| // |
| // ```dart |
| // union(a, b) => <String, String>{...a, ...b}; |
| // ``` |
| // |
| // The second fix is to add type information so that the expressions have |
| // either the type `Iterable` or the type `Map`. You can add an explicit cast |
| // or, in this case, add types to the declarations of the two parameters: |
| // |
| // ```dart |
| // union(List<int> a, List<int> b) => {...a, ...b}; |
| // ``` |
| // |
| // The third fix is to add context information. In this case, that means |
| // adding a return type to the function: |
| // |
| // ```dart |
| // Set<String> union(a, b) => {...a, ...b}; |
| // ``` |
| // |
| // In other cases, you might add a type somewhere else. For example, say the |
| // original code looks like this: |
| // |
| // ```dart |
| // union(a, b) { |
| // var x = [!{...a, ...b}!]; |
| // return x; |
| // } |
| // ``` |
| // |
| // You might add a type annotation on `x`, like this: |
| // |
| // ```dart |
| // union(a, b) { |
| // Map<String, String> x = {...a, ...b}; |
| // return x; |
| // } |
| // ``` |
| static const CompileTimeErrorCode AMBIGUOUS_SET_OR_MAP_LITERAL_EITHER = |
| CompileTimeErrorCode( |
| 'AMBIGUOUS_SET_OR_MAP_LITERAL_EITHER', |
| "This literal must be either a map or a set, but the elements don't " |
| "have enough information for type inference to work.", |
| correction: |
| "Try adding type arguments to the literal (one for sets, two " |
| "for maps).", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the actual argument type |
| * 1: the name of the expected type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the static type of an argument |
| // can't be assigned to the static type of the corresponding parameter. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because a `num` can't be |
| // assigned to a `String`: |
| // |
| // ```dart |
| // %language=2.9 |
| // String f(String x) => x; |
| // String g(num y) => f([!y!]); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If possible, rewrite the code so that the static type is assignable. In the |
| // example above you might be able to change the type of the parameter `y`: |
| // |
| // ```dart |
| // %language=2.9 |
| // String f(String x) => x; |
| // String g(String y) => f(y); |
| // ``` |
| // |
| // If that fix isn't possible, then add code to handle the case where the |
| // argument value isn't the required type. One approach is to coerce other |
| // types to the required type: |
| // |
| // ```dart |
| // %language=2.9 |
| // String f(String x) => x; |
| // String g(num y) => f(y.toString()); |
| // ``` |
| // |
| // Another approach is to add explicit type tests and fallback code: |
| // |
| // ```dart |
| // %language=2.9 |
| // String f(String x) => x; |
| // String g(num y) => f(y is String ? y : ''); |
| // ``` |
| // |
| // If you believe that the runtime type of the argument will always be the |
| // same as the static type of the parameter, and you're willing to risk having |
| // an exception thrown at runtime if you're wrong, then add an explicit cast: |
| // |
| // ```dart |
| // String f(String x) => x; |
| // String g(num y) => f(y as String); |
| // ``` |
| static const CompileTimeErrorCode ARGUMENT_TYPE_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'ARGUMENT_TYPE_NOT_ASSIGNABLE', |
| "The argument type '{0}' can't be assigned to the parameter type " |
| "'{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a redirecting constructor (a |
| // constructor that redirects to another constructor in the same class) has an |
| // assert in the initializer list. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the unnamed constructor |
| // is a redirecting constructor and also has an assert in the initializer |
| // list: |
| // |
| // ```dart |
| // class C { |
| // C(int x) : [!assert(x > 0)!], this.name(); |
| // C.name() {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the assert isn't needed, then remove it: |
| // |
| // ```dart |
| // class C { |
| // C(int x) : this.name(); |
| // C.name() {} |
| // } |
| // ``` |
| // |
| // If the assert is needed, then convert the constructor into a factory |
| // constructor: |
| // |
| // ```dart |
| // class C { |
| // factory C(int x) { |
| // assert(x > 0); |
| // return C.name(); |
| // } |
| // C.name() {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSERT_IN_REDIRECTING_CONSTRUCTOR = |
| CompileTimeErrorCode('ASSERT_IN_REDIRECTING_CONSTRUCTOR', |
| "A redirecting constructor can't have an 'assert' initializer.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds an assignment to a |
| // top-level variable, a static field, or a local variable that has the |
| // `const` modifier. The value of a compile-time constant can't be changed at |
| // runtime. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `c` is being assigned a |
| // value even though it has the `const` modifier: |
| // |
| // ```dart |
| // const c = 0; |
| // |
| // void f() { |
| // [!c!] = 1; |
| // print(c); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the variable must be assignable, then remove the `const` modifier: |
| // |
| // ```dart |
| // var c = 0; |
| // |
| // void f() { |
| // c = 1; |
| // print(c); |
| // } |
| // ``` |
| // |
| // If the constant shouldn't be changed, then either remove the assignment or |
| // use a local variable in place of references to the constant: |
| // |
| // ```dart |
| // const c = 0; |
| // |
| // void f() { |
| // var v = 1; |
| // print(v); |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_CONST = CompileTimeErrorCode( |
| 'ASSIGNMENT_TO_CONST', "Constant variables can't be assigned a value.", |
| correction: "Try removing the assignment, or " |
| "remove the modifier 'const' from the variable.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the final variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds an invocation of a |
| // setter, but there's no setter because the field with the same name was |
| // declared to be `final` or `const`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `v` is final: |
| // |
| // ```dart |
| // class C { |
| // final v = 0; |
| // } |
| // |
| // f(C c) { |
| // c.[!v!] = 1; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to be able to set the value of the field, then remove the |
| // modifier `final` from the field: |
| // |
| // ```dart |
| // class C { |
| // int v = 0; |
| // } |
| // |
| // f(C c) { |
| // c.v = 1; |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_FINAL = CompileTimeErrorCode( |
| 'ASSIGNMENT_TO_FINAL', |
| "'{0}' can't be used as a setter because it's final.", |
| correction: "Try finding a different setter, or making '{0}' non-final.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a local variable that was |
| // declared to be final is assigned after it was initialized. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is final, so it |
| // can't have a value assigned to it after it was initialized: |
| // |
| // ```dart |
| // void f() { |
| // final x = 0; |
| // [!x!] = 3; |
| // print(x); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the keyword `final`, and replace it with `var` if there's no type |
| // annotation: |
| // |
| // ```dart |
| // void f() { |
| // var x = 0; |
| // x = 3; |
| // print(x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_FINAL_LOCAL = |
| CompileTimeErrorCode('ASSIGNMENT_TO_FINAL_LOCAL', |
| "The final variable '{0}' can only be set once.", |
| correction: "Try making '{0}' non-final.", hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a reference to a setter is |
| // found; there is no setter defined for the type; but there is a getter |
| // defined with the same name. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there is no setter |
| // named `x` in `C`, but there is a getter named `x`: |
| // |
| // ```dart |
| // class C { |
| // int get x => 0; |
| // set y(int p) {} |
| // } |
| // |
| // void f(C c) { |
| // c.[!x!] = 1; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want to invoke an existing setter, then correct the name: |
| // |
| // ```dart |
| // class C { |
| // int get x => 0; |
| // set y(int p) {} |
| // } |
| // |
| // void f(C c) { |
| // c.y = 1; |
| // } |
| // ``` |
| // |
| // If you want to invoke the setter but it just doesn't exist yet, then |
| // declare it: |
| // |
| // ```dart |
| // class C { |
| // int get x => 0; |
| // set x(int p) {} |
| // set y(int p) {} |
| // } |
| // |
| // void f(C c) { |
| // c.x = 1; |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_FINAL_NO_SETTER = |
| CompileTimeErrorCode('ASSIGNMENT_TO_FINAL_NO_SETTER', |
| "There isn’t a setter named '{0}' in class '{1}'.", |
| correction: |
| "Try correcting the name to reference an existing setter, or " |
| "declare the setter.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name of a function appears |
| // on the left-hand side of an assignment expression. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the assignment to the |
| // function `f` is invalid: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // void g() { |
| // [!f!] = () {}; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the right-hand side should be assigned to something else, such as a |
| // local variable, then change the left-hand side: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // void g() { |
| // var x = () {}; |
| // print(x); |
| // } |
| // ``` |
| // |
| // If the intent is to change the implementation of the function, then define |
| // a function-valued variable instead of a function: |
| // |
| // ```dart |
| // void Function() f = () {}; |
| // |
| // void g() { |
| // f = () {}; |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_FUNCTION = |
| CompileTimeErrorCode( |
| 'ASSIGNMENT_TO_FUNCTION', "Functions can't be assigned a value.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the target of an assignment is a |
| // method. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` can't be assigned a |
| // value because it's a method: |
| // |
| // ```dart |
| // class C { |
| // void f() {} |
| // |
| // void g() { |
| // [!f!] = null; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rewrite the code so that there isn't an assignment to a method. |
| static const CompileTimeErrorCode ASSIGNMENT_TO_METHOD = CompileTimeErrorCode( |
| 'ASSIGNMENT_TO_METHOD', "Methods can't be assigned a value.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name of a type name appears |
| // on the left-hand side of an assignment expression. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the assignment to the |
| // class `C` is invalid: |
| // |
| // ```dart |
| // class C {} |
| // |
| // void f() { |
| // [!C!] = null; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the right-hand side should be assigned to something else, such as a |
| // local variable, then change the left-hand side: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // void g() { |
| // var c = null; |
| // print(c); |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASSIGNMENT_TO_TYPE = CompileTimeErrorCode( |
| 'ASSIGNMENT_TO_TYPE', "Types can't be assigned a value.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an async for-in loop is found in |
| // a function or method whose body isn't marked as being either `async` or |
| // `async*`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of `f` isn't |
| // marked as being either `async` or `async*`, but `f` contains an async |
| // for-in loop: |
| // |
| // ```dart |
| // void f(list) { |
| // await for (var e [!in!] list) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function should return a `Future`, then mark the body with `async`: |
| // |
| // ```dart |
| // Future<void> f(list) async { |
| // await for (var e in list) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| // |
| // If the function should return a `Stream` of values, then mark the body with |
| // `async*`: |
| // |
| // ```dart |
| // Stream<void> f(list) async* { |
| // await for (var e in list) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| // |
| // If the function should be synchronous, then remove the `await` before the |
| // loop: |
| // |
| // ```dart |
| // void f(list) { |
| // for (var e in list) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode ASYNC_FOR_IN_WRONG_CONTEXT = |
| CompileTimeErrorCode('ASYNC_FOR_IN_WRONG_CONTEXT', |
| "The async for-in loop can only be used in an async function.", |
| correction: |
| "Try marking the function body with either 'async' or 'async*', " |
| "or removing the 'await' before the for-in loop.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a local variable that has the |
| // `late` modifier uses an `await` expression in the initializer. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because an `await` expression |
| // is used in the initializer for `v`, a local variable that is marked `late`: |
| // |
| // ```dart |
| // Future<int> f() async { |
| // late var v = [!await!] 42; |
| // return v; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the initializer can be rewritten to not use `await`, then rewrite it: |
| // |
| // ```dart |
| // Future<int> f() async { |
| // late var v = 42; |
| // return v; |
| // } |
| // ``` |
| // |
| // If the initializer can't be rewritten, then remove the `late` modifier: |
| // |
| // ```dart |
| // Future<int> f() async { |
| // var v = await 42; |
| // return v; |
| // } |
| // ``` |
| static const CompileTimeErrorCode AWAIT_IN_LATE_LOCAL_VARIABLE_INITIALIZER = |
| CompileTimeErrorCode( |
| 'AWAIT_IN_LATE_LOCAL_VARIABLE_INITIALIZER', |
| "The 'await' expression can't be used in a 'late' local variable's " |
| "initializer.", |
| correction: |
| "Try removing the 'late' modifier, or rewriting the initializer " |
| "without using the 'await' expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 16.30 Await Expressions: It is a compile-time error if the function |
| * immediately enclosing _a_ is not declared asynchronous. (Where _a_ is the |
| * await expression.) |
| */ |
| static const CompileTimeErrorCode AWAIT_IN_WRONG_CONTEXT = |
| CompileTimeErrorCode('AWAIT_IN_WRONG_CONTEXT', |
| "The await expression can only be used in an async function.", |
| correction: |
| "Try marking the function body with either 'async' or 'async*'."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function has a |
| // return type that's [potentially non-nullable][] but would implicitly return |
| // `null` if control reached the end of the function. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the method `m` has an |
| // implicit return of `null` inserted at the end of the method, but the method |
| // is declared to not return `null`: |
| // |
| // ```dart |
| // class C { |
| // int [!m!](int t) { |
| // print(t); |
| // } |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the method `m` has an |
| // implicit return of `null` inserted at the end of the method, but because |
| // the class `C` can be instantiated with a non-nullable type argument, the |
| // method is effectively declared to not return `null`: |
| // |
| // ```dart |
| // class C<T> { |
| // T [!m!](T t) { |
| // print(t); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's a reasonable value that can be returned, then add a `return` |
| // statement at the end of the method: |
| // |
| // ```dart |
| // class C<T> { |
| // T m(T t) { |
| // print(t); |
| // return t; |
| // } |
| // } |
| // ``` |
| // |
| // If the method won't reach the implicit return, then add a `throw` at the |
| // end of the method: |
| // |
| // ```dart |
| // class C<T> { |
| // T m(T t) { |
| // print(t); |
| // throw ''; |
| // } |
| // } |
| // ``` |
| // |
| // If the method intentionally returns `null` at the end, then change the |
| // return type so that it's valid to return `null`: |
| // |
| // ```dart |
| // class C<T> { |
| // T? m(T t) { |
| // print(t); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode BODY_MIGHT_COMPLETE_NORMALLY = |
| CompileTimeErrorCode( |
| 'BODY_MIGHT_COMPLETE_NORMALLY', |
| "The body might complete normally, causing 'null' to be returned, " |
| "but the return type is a potentially non-nullable type.", |
| correction: |
| "Try adding either a return or a throw statement at the end.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a break in a case clause inside |
| // a switch statement has a label that is associated with another case clause. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the label `l` is |
| // associated with the case clause for `0`: |
| // |
| // ```dart |
| // void f(int i) { |
| // switch (i) { |
| // l: case 0: |
| // break; |
| // case 1: |
| // break [!l!]; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the intent is to transfer control to the statement after the switch, |
| // then remove the label from the break statement: |
| // |
| // ```dart |
| // void f(int i) { |
| // switch (i) { |
| // case 0: |
| // break; |
| // case 1: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If the intent is to transfer control to a different case block, then use |
| // `continue` rather than `break`: |
| // |
| // ```dart |
| // void f(int i) { |
| // switch (i) { |
| // l: case 0: |
| // break; |
| // case 1: |
| // continue l; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode BREAK_LABEL_ON_SWITCH_MEMBER = |
| CompileTimeErrorCode('BREAK_LABEL_ON_SWITCH_MEMBER', |
| "A break label resolves to the 'case' or 'default' statement.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name used in the declaration |
| // of a class, extension, mixin, typedef, type parameter, or import prefix is |
| // a built-in identifier. Built-in identifiers can’t be used to name any of |
| // these kinds of declarations. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `mixin` is a built-in |
| // identifier: |
| // |
| // ```dart |
| // extension [!mixin!] on int {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Choose a different name for the declaration. |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_EXTENSION_NAME = |
| CompileTimeErrorCode('BUILT_IN_IDENTIFIER_IN_DECLARATION', |
| "The built-in identifier '{0}' can't be used as an extension name.", |
| correction: "Try choosing a different name for the extension.", |
| hasPublishedDocs: true, |
| uniqueName: 'BUILT_IN_IDENTIFIER_AS_EXTENSION_NAME'); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_PREFIX_NAME = |
| CompileTimeErrorCode('BUILT_IN_IDENTIFIER_IN_DECLARATION', |
| "The built-in identifier '{0}' can't be used as a prefix name.", |
| correction: "Try choosing a different name for the prefix.", |
| hasPublishedDocs: true, |
| uniqueName: 'BUILT_IN_IDENTIFIER_AS_PREFIX_NAME'); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a built-in identifier is used |
| // where a type name is expected. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `import` can't be used |
| // as a type because it's a built-in identifier: |
| // |
| // ```dart |
| // [!import!]<int> x; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the built-in identifier with the name of a valid type: |
| // |
| // ```dart |
| // List<int> x; |
| // ``` |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_TYPE = |
| CompileTimeErrorCode('BUILT_IN_IDENTIFIER_AS_TYPE', |
| "The built-in identifier '{0}' can't be used as a type.", |
| correction: "Try correcting the name to match an existing type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_TYPE_NAME = |
| CompileTimeErrorCode('BUILT_IN_IDENTIFIER_IN_DECLARATION', |
| "The built-in identifier '{0}' can't be used as a type name.", |
| correction: "Try choosing a different name for the type.", |
| hasPublishedDocs: true, |
| uniqueName: 'BUILT_IN_IDENTIFIER_AS_TYPE_NAME'); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_TYPE_PARAMETER_NAME = |
| CompileTimeErrorCode( |
| 'BUILT_IN_IDENTIFIER_IN_DECLARATION', |
| "The built-in identifier '{0}' can't be used as a type parameter " |
| "name.", |
| correction: "Try choosing a different name for the type parameter.", |
| hasPublishedDocs: true, |
| uniqueName: 'BUILT_IN_IDENTIFIER_AS_TYPE_PARAMETER_NAME'); |
| |
| /** |
| * Parameters: |
| * 0: the built-in identifier that is being used |
| */ |
| static const CompileTimeErrorCode BUILT_IN_IDENTIFIER_AS_TYPEDEF_NAME = |
| CompileTimeErrorCode('BUILT_IN_IDENTIFIER_IN_DECLARATION', |
| "The built-in identifier '{0}' can't be used as a typedef name.", |
| correction: "Try choosing a different name for the typedef.", |
| hasPublishedDocs: true, |
| uniqueName: 'BUILT_IN_IDENTIFIER_AS_TYPEDEF_NAME'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the last statement in a `case` |
| // block isn't one of the required terminators: `break`, `continue`, |
| // `rethrow`, `return`, or `throw`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the `case` block ends |
| // with an assignment: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int x) { |
| // switch (x) { |
| // [!case!] 0: |
| // x += 2; |
| // default: |
| // x += 1; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add one of the required terminators: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int x) { |
| // switch (x) { |
| // case 0: |
| // x += 2; |
| // break; |
| // default: |
| // x += 1; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode CASE_BLOCK_NOT_TERMINATED = |
| CompileTimeErrorCode( |
| 'CASE_BLOCK_NOT_TERMINATED', |
| "The last statement of the 'case' should be 'break', 'continue', " |
| "'rethrow', 'return', or 'throw'.", |
| correction: "Try adding one of the required statements.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the this of the switch case expression |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of the expression |
| // following the keyword `case` has an implementation of the `==` operator |
| // other than the one in `Object`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the expression |
| // following the keyword `case` (`C(0)`) has the type `C`, and the class `C` |
| // overrides the `==` operator: |
| // |
| // ```dart |
| // class C { |
| // final int value; |
| // |
| // const C(this.value); |
| // |
| // bool operator ==(Object other) { |
| // return false; |
| // } |
| // } |
| // |
| // void f(C c) { |
| // switch (c) { |
| // case [!C(0)!]: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there isn't a strong reason not to do so, then rewrite the code to use |
| // an if-else structure: |
| // |
| // ```dart |
| // class C { |
| // final int value; |
| // |
| // const C(this.value); |
| // |
| // bool operator ==(Object other) { |
| // return false; |
| // } |
| // } |
| // |
| // void f(C c) { |
| // if (c == C(0)) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // If you can't rewrite the switch statement and the implementation of `==` |
| // isn't necessary, then remove it: |
| // |
| // ```dart |
| // class C { |
| // final int value; |
| // |
| // const C(this.value); |
| // } |
| // |
| // void f(C c) { |
| // switch (c) { |
| // case C(0): |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If you can't rewrite the switch statement and you can't remove the |
| // definition of `==`, then find some other value that can be used to control |
| // the switch: |
| // |
| // ```dart |
| // class C { |
| // final int value; |
| // |
| // const C(this.value); |
| // |
| // bool operator ==(Object other) { |
| // return false; |
| // } |
| // } |
| // |
| // void f(C c) { |
| // switch (c.value) { |
| // case 0: |
| // break; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode CASE_EXPRESSION_TYPE_IMPLEMENTS_EQUALS = |
| CompileTimeErrorCode( |
| 'CASE_EXPRESSION_TYPE_IMPLEMENTS_EQUALS', |
| "The switch case expression type '{0}' can't override the '==' " |
| "operator.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the case expression |
| * 1: the type of the switch expression |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression following `case` |
| // in a `switch` statement has a static type that isn't a subtype of the |
| // static type of the expression following `switch`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `1` is an `int`, which |
| // isn't a subtype of `String` (the type of `s`): |
| // |
| // ```dart |
| // void f(String s) { |
| // switch (s) { |
| // case [!1!]: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value of the `case` expression is wrong, then change the `case` |
| // expression so that it has the required type: |
| // |
| // ```dart |
| // void f(String s) { |
| // switch (s) { |
| // case '1': |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If the value of the `case` expression is correct, then change the `switch` |
| // expression to have the required type: |
| // |
| // ```dart |
| // void f(int s) { |
| // switch (s) { |
| // case 1: |
| // break; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| CASE_EXPRESSION_TYPE_IS_NOT_SWITCH_EXPRESSION_SUBTYPE = |
| CompileTimeErrorCode( |
| 'CASE_EXPRESSION_TYPE_IS_NOT_SWITCH_EXPRESSION_SUBTYPE', |
| "The switch case expression type '{0}' must be a subtype of the " |
| "switch expression type '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name following the `as` in a |
| // cast expression is defined to be something other than a type. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is a variable, not |
| // a type: |
| // |
| // ```dart |
| // num x = 0; |
| // int y = x as [!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the name with the name of a type: |
| // |
| // ```dart |
| // num x = 0; |
| // int y = x as int; |
| // ``` |
| static const CompileTimeErrorCode CAST_TO_NON_TYPE = CompileTimeErrorCode( |
| 'CAST_TO_NON_TYPE', |
| "The name '{0}' isn't a type, so it can't be used in an 'as' expression.", |
| correction: "Try changing the name to the name of an existing type, or " |
| "creating a type with the name '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the member |
| */ |
| static const CompileTimeErrorCode |
| CLASS_INSTANTIATION_ACCESS_TO_INSTANCE_MEMBER = CompileTimeErrorCode( |
| 'CLASS_INSTANTIATION_ACCESS_TO_MEMBER', |
| "The instance member '{0}' can't be accessed on a class " |
| "instantiation.", |
| correction: |
| "Try changing the member name to the name of a constructor.", |
| uniqueName: 'CLASS_INSTANTIATION_ACCESS_TO_INSTANCE_MEMBER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the member |
| */ |
| static const CompileTimeErrorCode |
| CLASS_INSTANTIATION_ACCESS_TO_STATIC_MEMBER = CompileTimeErrorCode( |
| 'CLASS_INSTANTIATION_ACCESS_TO_MEMBER', |
| "The static member '{0}' can't be accessed on a class instantiation.", |
| correction: "Try removing the type arguments from the class name, or " |
| "changing the member name to the name of a constructor.", |
| uniqueName: 'CLASS_INSTANTIATION_ACCESS_TO_STATIC_MEMBER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the member |
| */ |
| static const CompileTimeErrorCode |
| CLASS_INSTANTIATION_ACCESS_TO_UNKNOWN_MEMBER = CompileTimeErrorCode( |
| 'CLASS_INSTANTIATION_ACCESS_TO_MEMBER', |
| "The class '{0} doesn't have a constructor named '{1}.", |
| correction: "Try invoking a different constructor, or defining a " |
| "constructor named '{1}'.", |
| uniqueName: 'CLASS_INSTANTIATION_ACCESS_TO_UNKNOWN_MEMBER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the abstract method |
| * 1: the name of the enclosing class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a member of a concrete class is |
| // found that doesn't have a concrete implementation. Concrete classes aren't |
| // allowed to contain abstract members. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `m` is an abstract |
| // method but `C` isn't an abstract class: |
| // |
| // ```dart |
| // class C { |
| // [!void m();!] |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it's valid to create instances of the class, provide an implementation |
| // for the member: |
| // |
| // ```dart |
| // class C { |
| // void m() {} |
| // } |
| // ``` |
| // |
| // If it isn't valid to create instances of the class, mark the class as being |
| // abstract: |
| // |
| // ```dart |
| // abstract class C { |
| // void m(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONCRETE_CLASS_WITH_ABSTRACT_MEMBER = |
| CompileTimeErrorCode('CONCRETE_CLASS_WITH_ABSTRACT_MEMBER', |
| "'{0}' must have a method body because '{1}' isn't abstract.", |
| correction: "Try making '{1}' abstract, or adding a body to '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the constructor and field |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a named constructor and either a |
| // static method or static field have the same name. Both are accessed using |
| // the name of the class, so having the same name makes the reference |
| // ambiguous. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the static field `foo` |
| // and the named constructor `foo` have the same name: |
| // |
| // ```dart |
| // class C { |
| // C.[!foo!](); |
| // static int foo = 0; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the static method `foo` |
| // and the named constructor `foo` have the same name: |
| // |
| // ```dart |
| // class C { |
| // C.[!foo!](); |
| // static void foo() {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rename either the member or the constructor. |
| static const CompileTimeErrorCode CONFLICTING_CONSTRUCTOR_AND_STATIC_FIELD = |
| CompileTimeErrorCode( |
| 'CONFLICTING_CONSTRUCTOR_AND_STATIC_MEMBER', |
| "'{0}' can't be used to name both a constructor and a static field " |
| "in this class.", |
| correction: "Try renaming either the constructor or the field.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_CONSTRUCTOR_AND_STATIC_FIELD'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the constructor and getter |
| */ |
| static const CompileTimeErrorCode CONFLICTING_CONSTRUCTOR_AND_STATIC_GETTER = |
| CompileTimeErrorCode( |
| 'CONFLICTING_CONSTRUCTOR_AND_STATIC_MEMBER', |
| "'{0}' can't be used to name both a constructor and a static getter " |
| "in this class.", |
| correction: "Try renaming either the constructor or the getter.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_CONSTRUCTOR_AND_STATIC_GETTER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the constructor |
| */ |
| static const CompileTimeErrorCode CONFLICTING_CONSTRUCTOR_AND_STATIC_METHOD = |
| CompileTimeErrorCode( |
| 'CONFLICTING_CONSTRUCTOR_AND_STATIC_MEMBER', |
| "'{0}' can't be used to name both a constructor and a static method " |
| "in this class.", |
| correction: "Try renaming either the constructor or the method.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_CONSTRUCTOR_AND_STATIC_METHOD'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the constructor and setter |
| */ |
| static const CompileTimeErrorCode CONFLICTING_CONSTRUCTOR_AND_STATIC_SETTER = |
| CompileTimeErrorCode( |
| 'CONFLICTING_CONSTRUCTOR_AND_STATIC_MEMBER', |
| "'{0}' can't be used to name both a constructor and a static setter " |
| "in this class.", |
| correction: "Try renaming either the constructor or the setter.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_CONSTRUCTOR_AND_STATIC_SETTER'); |
| |
| /** |
| * 10.11 Class Member Conflicts: Let `C` be a class. It is a compile-time |
| * error if `C` declares a getter or a setter with basename `n`, and has a |
| * method named `n`. |
| * |
| * Parameters: |
| * 0: the name of the class defining the conflicting field |
| * 1: the name of the conflicting field |
| * 2: the name of the class defining the method with which the field conflicts |
| */ |
| static const CompileTimeErrorCode CONFLICTING_FIELD_AND_METHOD = |
| CompileTimeErrorCode( |
| 'CONFLICTING_FIELD_AND_METHOD', |
| "Class '{0}' can't define field '{1}' and have method '{2}.{1}' " |
| "with the same name.", |
| correction: "Try converting the getter to a method, or " |
| "renaming the field to a name that doesn't conflict."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type parameter |
| * 1: detail text explaining why the type could not be inferred |
| */ |
| static const CompileTimeErrorCode COULD_NOT_INFER = CompileTimeErrorCode( |
| 'COULD_NOT_INFER', "Couldn't infer type parameter '{0}'.{1}"); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class implementing the conflicting interface |
| * 1: the first conflicting type |
| * 2: the second conflicting type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class attempts to implement a |
| // generic interface multiple times, and the values of the type arguments |
| // aren't the same. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `C` is defined to |
| // implement both `I<int>` (because it extends `A`) and `I<String>` (because |
| // it implements`B`), but `int` and `String` aren't the same type: |
| // |
| // ```dart |
| // class I<T> {} |
| // class A implements I<int> {} |
| // class B implements I<String> {} |
| // class [!C!] extends A implements B {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rework the type hierarchy to avoid this situation. For example, you might |
| // make one or both of the inherited types generic so that `C` can specify the |
| // same type for both type arguments: |
| // |
| // ```dart |
| // class I<T> {} |
| // class A<S> implements I<S> {} |
| // class B implements I<String> {} |
| // class C extends A<String> implements B {} |
| // ``` |
| static const CompileTimeErrorCode CONFLICTING_GENERIC_INTERFACES = |
| CompileTimeErrorCode( |
| 'CONFLICTING_GENERIC_INTERFACES', |
| "The class '{0}' can't implement both '{1}' and '{2}' because the " |
| "type arguments are different.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 10.11 Class Member Conflicts: Let `C` be a class. It is a compile-time |
| * error if `C` declares a method named `n`, and has a getter or a setter |
| * with basename `n`. |
| * |
| * Parameters: |
| * 0: the name of the class defining the conflicting method |
| * 1: the name of the conflicting method |
| * 2: the name of the class defining the field with which the method conflicts |
| */ |
| static const CompileTimeErrorCode CONFLICTING_METHOD_AND_FIELD = |
| CompileTimeErrorCode( |
| 'CONFLICTING_METHOD_AND_FIELD', |
| "Class '{0}' can't define method '{1}' and have field '{2}.{1}' " |
| "with the same name.", |
| correction: "Try converting the method to a getter, or " |
| "renaming the method to a name that doesn't conflict."); |
| |
| /** |
| * 10.11 Class Member Conflicts: Let `C` be a class. It is a compile-time |
| * error if `C` declares a static member with basename `n`, and has an |
| * instance member with basename `n`. |
| * |
| * Parameters: |
| * 0: the name of the class defining the conflicting member |
| * 1: the name of the conflicting static member |
| * 2: the name of the class defining the field with which the method conflicts |
| */ |
| static const CompileTimeErrorCode CONFLICTING_STATIC_AND_INSTANCE = |
| CompileTimeErrorCode( |
| 'CONFLICTING_STATIC_AND_INSTANCE', |
| "Class '{0}' can't define static member '{1}' and have instance " |
| "member '{2}.{1}' with the same name.", |
| correction: |
| "Try renaming the member to a name that doesn't conflict."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class, mixin, or extension |
| // declaration declares a type parameter with the same name as the class, |
| // mixin, or extension that declares it. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type parameter `C` |
| // has the same name as the class `C` of which it's a part: |
| // |
| // ```dart |
| // class C<[!C!]> {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rename either the type parameter, or the class, mixin, or extension: |
| // |
| // ```dart |
| // class C<T> {} |
| // ``` |
| static const CompileTimeErrorCode CONFLICTING_TYPE_VARIABLE_AND_CLASS = |
| CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_CONTAINER', |
| "'{0}' can't be used to name both a type variable and the class in " |
| "which the type variable is defined.", |
| correction: "Try renaming either the type variable or the class.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_CLASS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| static const CompileTimeErrorCode CONFLICTING_TYPE_VARIABLE_AND_EXTENSION = |
| CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_CONTAINER', |
| "'{0}' can't be used to name both a type variable and the extension " |
| "in which the type variable is defined.", |
| correction: "Try renaming either the type variable or the extension.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_EXTENSION', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class, mixin, or extension |
| // declaration declares a type parameter with the same name as one of the |
| // members of the class, mixin, or extension that declares it. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type parameter `T` |
| // has the same name as the field `T`: |
| // |
| // ```dart |
| // class C<[!T!]> { |
| // int T = 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rename either the type parameter or the member with which it conflicts: |
| // |
| // ```dart |
| // class C<T> { |
| // int total = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONFLICTING_TYPE_VARIABLE_AND_MEMBER_CLASS = |
| CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER', |
| "'{0}' can't be used to name both a type variable and a member in " |
| "this class.", |
| correction: "Try renaming either the type variable or the member.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER_CLASS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| static const CompileTimeErrorCode CONFLICTING_TYPE_VARIABLE_AND_MEMBER_MIXIN = |
| CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER', |
| "'{0}' can't be used to name both a type variable and a member in " |
| "this mixin.", |
| correction: "Try renaming either the type variable or the member.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER_MIXIN', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| static const CompileTimeErrorCode |
| CONFLICTING_TYPE_VARIABLE_AND_MEMBER_EXTENSION = CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER', |
| "'{0}' can't be used to name both a type variable and a member in " |
| "this extension.", |
| correction: "Try renaming either the type variable or the member.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_MEMBER_EXTENSION', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type variable |
| */ |
| static const CompileTimeErrorCode CONFLICTING_TYPE_VARIABLE_AND_MIXIN = |
| CompileTimeErrorCode( |
| 'CONFLICTING_TYPE_VARIABLE_AND_CONTAINER', |
| "'{0}' can't be used to name both a type variable and the mixin in " |
| "which the type variable is defined.", |
| correction: "Try renaming either the type variable or the mixin.", |
| hasPublishedDocs: true, |
| uniqueName: 'CONFLICTING_TYPE_VARIABLE_AND_MIXIN', |
| ); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if evaluation of a constant |
| * object results in an uncaught exception being thrown. |
| */ |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_FIELD_TYPE_MISMATCH = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_FIELD_TYPE_MISMATCH', |
| "In a const constructor, a value of type '{0}' can't be assigned to the " |
| "field '{1}', which has type '{2}'.", |
| correction: "Try using a subtype, or removing the keyword 'const'.", |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the type of the runtime value of the argument |
| * 1: the static type of the parameter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the runtime type of a constant |
| // value can't be assigned to the static type of a constant constructor's |
| // parameter. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the runtime type of `i` |
| // is `int`, which can't be assigned to the static type of `s`: |
| // |
| // ```dart |
| // class C { |
| // final String s; |
| // |
| // const C(this.s); |
| // } |
| // |
| // const dynamic i = 0; |
| // |
| // void f() { |
| // const C([!i!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Pass a value of the correct type to the constructor: |
| // |
| // ```dart |
| // class C { |
| // final String s; |
| // |
| // const C(this.s); |
| // } |
| // |
| // const dynamic i = 0; |
| // |
| // void f() { |
| // const C('$i'); |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_PARAM_TYPE_MISMATCH = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_PARAM_TYPE_MISMATCH', |
| "A value of type '{0}' can't be assigned to a parameter of type " |
| "'{1}' in a const constructor.", |
| correction: "Try using a subtype, or removing the keyword 'const'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if evaluation of a constant |
| * object results in an uncaught exception being thrown. |
| */ |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_THROWS_EXCEPTION = |
| CompileTimeErrorCode('CONST_CONSTRUCTOR_THROWS_EXCEPTION', |
| "Const constructors can't throw exceptions.", |
| correction: "Try removing the throw statement, or " |
| "removing the keyword 'const'."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor has the keyword |
| // `const`, but a field in the class is initialized to a non-constant value. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field `s` is |
| // initialized to a non-constant value: |
| // |
| // ```dart |
| // class C { |
| // final String s = 3.toString(); |
| // [!const!] C(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field can be initialized to a constant value, then change the |
| // initializer to a constant expression: |
| // |
| // ```dart |
| // class C { |
| // final String s = '3'; |
| // const C(); |
| // } |
| // ``` |
| // |
| // If the field can't be initialized to a constant value, then remove the |
| // keyword `const` from the constructor: |
| // |
| // ```dart |
| // class C { |
| // final String s = 3.toString(); |
| // C(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| CONST_CONSTRUCTOR_WITH_FIELD_INITIALIZED_BY_NON_CONST = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_WITH_FIELD_INITIALIZED_BY_NON_CONST', |
| "Can't define the 'const' constructor because the field '{0}' is " |
| "initialized with a non-constant value.", |
| correction: "Try initializing the field to a constant value, or " |
| "removing the keyword 'const' from the constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.6.3 Constant Constructors: The superinitializer that appears, explicitly |
| * or implicitly, in the initializer list of a constant constructor must |
| * specify a constant constructor of the superclass of the immediately |
| * enclosing class or a compile-time error occurs. |
| * |
| * 12.1 Mixin Application: For each generative constructor named ... an |
| * implicitly declared constructor named ... is declared. If Sq is a |
| * generative const constructor, and M does not declare any fields, Cq is |
| * also a const constructor. |
| * |
| * Parameters: |
| * 0: the name of the instance field. |
| */ |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELD = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELD', |
| "This constructor can't be declared 'const' because a mixin adds the " |
| "instance field: {0}.", |
| correction: "Try removing the 'const' keyword or removing the 'with' " |
| "clause from the class declaration, or removing the field from " |
| "the mixin class.", |
| uniqueName: 'CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELD', |
| ); |
| |
| /** |
| * 7.6.3 Constant Constructors: The superinitializer that appears, explicitly |
| * or implicitly, in the initializer list of a constant constructor must |
| * specify a constant constructor of the superclass of the immediately |
| * enclosing class or a compile-time error occurs. |
| * |
| * 12.1 Mixin Application: For each generative constructor named ... an |
| * implicitly declared constructor named ... is declared. If Sq is a |
| * generative const constructor, and M does not declare any fields, Cq is |
| * also a const constructor. |
| * |
| * Parameters: |
| * 0: the names of the instance fields. |
| */ |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELDS = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELD', |
| "This constructor can't be declared 'const' because the mixins add " |
| "the instance fields: {0}.", |
| correction: "Try removing the 'const' keyword or removing the 'with' " |
| "clause from the class declaration, or removing the fields from " |
| "the mixin classes.", |
| uniqueName: 'CONST_CONSTRUCTOR_WITH_MIXIN_WITH_FIELDS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the superclass |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor that is marked as |
| // `const` invokes a constructor from its superclass that isn't marked as |
| // `const`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the `const` constructor |
| // in `B` invokes the constructor `nonConst` from the class `A`, and the |
| // superclass constructor isn't a `const` constructor: |
| // |
| // ```dart |
| // class A { |
| // const A(); |
| // A.nonConst(); |
| // } |
| // |
| // class B extends A { |
| // const B() : [!super.nonConst()!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it isn't essential to invoke the superclass constructor that is |
| // currently being invoked, then invoke a constant constructor from the |
| // superclass: |
| // |
| // ```dart |
| // class A { |
| // const A(); |
| // A.nonConst(); |
| // } |
| // |
| // class B extends A { |
| // const B() : super(); |
| // } |
| // ``` |
| // |
| // If it's essential that the current constructor be invoked and if you can |
| // modify it, then add `const` to the constructor in the superclass: |
| // |
| // ```dart |
| // class A { |
| // const A(); |
| // const A.nonConst(); |
| // } |
| // |
| // class B extends A { |
| // const B() : super.nonConst(); |
| // } |
| // ``` |
| // |
| // If it's essential that the current constructor be invoked and you can't |
| // modify it, then remove `const` from the constructor in the subclass: |
| // |
| // ```dart |
| // class A { |
| // const A(); |
| // A.nonConst(); |
| // } |
| // |
| // class B extends A { |
| // B() : super.nonConst(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_WITH_NON_CONST_SUPER = |
| CompileTimeErrorCode( |
| 'CONST_CONSTRUCTOR_WITH_NON_CONST_SUPER', |
| "A constant constructor can't call a non-constant super constructor " |
| "of '{0}'.", |
| correction: "Try calling a constant constructor in the superclass, " |
| "or removing the keyword 'const' from the constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor is marked as a |
| // const constructor, but the constructor is defined in a class that has at |
| // least one non-final instance field (either directly or by inheritance). |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the field `x` isn't |
| // final: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // const [!C!](this.x); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it's possible to mark all of the fields as final, then do so: |
| // |
| // ```dart |
| // class C { |
| // final int x; |
| // |
| // const C(this.x); |
| // } |
| // ``` |
| // |
| // If it isn't possible to mark all of the fields as final, then remove the |
| // keyword `const` from the constructor: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C(this.x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONST_CONSTRUCTOR_WITH_NON_FINAL_FIELD = |
| CompileTimeErrorCode('CONST_CONSTRUCTOR_WITH_NON_FINAL_FIELD', |
| "Can't define a const constructor for a class with non-final fields.", |
| correction: "Try making all of the fields final, or " |
| "removing the keyword 'const' from the constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class from a library that is |
| // imported using a deferred import is used to create a `const` object. |
| // Constants are evaluated at compile time, and classes from deferred |
| // libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because it attempts to create a |
| // `const` instance of a class from a deferred library: |
| // |
| // ```dart |
| // import 'dart:convert' deferred as convert; |
| // |
| // const json2 = [!convert.JsonCodec()!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the object isn't required to be a constant, then change the code so that |
| // a non-constant instance is created: |
| // |
| // ```dart |
| // import 'dart:convert' deferred as convert; |
| // |
| // final json2 = convert.JsonCodec(); |
| // ``` |
| // |
| // If the object must be a constant, then remove `deferred` from the import |
| // directive: |
| // |
| // ```dart |
| // import 'dart:convert' as convert; |
| // |
| // const json2 = convert.JsonCodec(); |
| // ``` |
| static const CompileTimeErrorCode CONST_DEFERRED_CLASS = CompileTimeErrorCode( |
| 'CONST_DEFERRED_CLASS', "Deferred classes can't be created with 'const'.", |
| correction: "Try using 'new' to create the instance, or " |
| "changing the import to not be deferred.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if evaluation of a constant |
| * object results in an uncaught exception being thrown. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_THROWS_EXCEPTION = |
| CompileTimeErrorCode('CONST_EVAL_THROWS_EXCEPTION', |
| "Evaluation of this constant expression throws an exception."); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if evaluation of a constant |
| * object results in an uncaught exception being thrown. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_THROWS_IDBZE = |
| CompileTimeErrorCode( |
| 'CONST_EVAL_THROWS_IDBZE', |
| "Evaluation of this constant expression throws an " |
| "IntegerDivisionByZeroException."); |
| |
| /** |
| * 16.12.2 Const: An expression of one of the forms !e, e1 && e2 or e1 || e2, |
| * where e, e1 and e2 are constant expressions that evaluate to a boolean |
| * value. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_BOOL = CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_BOOL', |
| "In constant expressions, operands of this operator must be of type " |
| "'bool'."); |
| |
| /** |
| * 16.12.2 Const: An expression of one of the forms !e, e1 && e2 or e1 || e2, |
| * where e, e1 and e2 are constant expressions that evaluate to a boolean |
| * value. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_BOOL_INT = |
| CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_BOOL_INT', |
| "In constant expressions, operands of this operator must be of type " |
| "'bool' or 'int'."); |
| |
| /** |
| * 16.12.2 Const: An expression of one of the forms e1 == e2 or e1 != e2 where |
| * e1 and e2 are constant expressions that evaluate to a numeric, string or |
| * boolean value or to null. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_BOOL_NUM_STRING = |
| CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_BOOL_NUM_STRING', |
| "In constant expressions, operands of this operator must be of type " |
| "'bool', 'num', 'String' or 'null'."); |
| |
| /** |
| * 16.12.2 Const: An expression of one of the forms ~e, e1 ^ e2, e1 & e2, |
| * e1 | e2, e1 >> e2 or e1 << e2, where e, e1 and e2 are constant expressions |
| * that evaluate to an integer value or to null. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_INT = CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_INT', |
| "In constant expressions, operands of this operator must be of type " |
| "'int'."); |
| |
| /** |
| * 16.12.2 Const: An expression of one of the forms e, e1 + e2, e1 - e2, e1 * |
| * e2, e1 / e2, e1 ~/ e2, e1 > e2, e1 < e2, e1 >= e2, e1 <= e2 or e1 % e2, |
| * where e, e1 and e2 are constant expressions that evaluate to a numeric |
| * value or to null. |
| */ |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_NUM = CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_NUM', |
| "In constant expressions, operands of this operator must be of type " |
| "'num'."); |
| |
| static const CompileTimeErrorCode CONST_EVAL_TYPE_TYPE = CompileTimeErrorCode( |
| 'CONST_EVAL_TYPE_TYPE', |
| "In constant expressions, operands of this operator must be of type " |
| "'Type'."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type of the initializer expression |
| * 1: the name of the type of the field |
| */ |
| static const CompileTimeErrorCode CONST_FIELD_INITIALIZER_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'FIELD_INITIALIZER_NOT_ASSIGNABLE', |
| "The initializer type '{0}' can't be assigned to the field type " |
| "'{1}' in a const constructor.", |
| correction: "Try using a subtype, or removing the 'const' keyword", |
| hasPublishedDocs: true, |
| uniqueName: 'CONST_FIELD_INITIALIZER_NOT_ASSIGNABLE', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a value that isn't statically |
| // known to be a constant is assigned to a variable that's declared to be a |
| // `const` variable. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` isn't declared to |
| // be `const`: |
| // |
| // ```dart |
| // var x = 0; |
| // const y = [!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value being assigned can be declared to be `const`, then change the |
| // declaration: |
| // |
| // ```dart |
| // const x = 0; |
| // const y = x; |
| // ``` |
| // |
| // If the value can't be declared to be `const`, then remove the `const` |
| // modifier from the variable, possibly using `final` in its place: |
| // |
| // ```dart |
| // var x = 0; |
| // final y = x; |
| // ``` |
| static const CompileTimeErrorCode CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE = |
| CompileTimeErrorCode('CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE', |
| "Const variables must be initialized with a constant value.", |
| correction: |
| "Try changing the initializer to be a constant expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a `const` variable is |
| // initialized using a `const` variable from a library that is imported using |
| // a deferred import. Constants are evaluated at compile time, and values from |
| // deferred libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the variable `pi` is |
| // being initialized using the constant `math.pi` from the library |
| // `dart:math`, and `dart:math` is imported as a deferred library: |
| // |
| // ```dart |
| // import 'dart:math' deferred as math; |
| // |
| // const pi = [!math.pi!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to reference the value of the constant from the imported |
| // library, then remove the keyword `deferred`: |
| // |
| // ```dart |
| // import 'dart:math' as math; |
| // |
| // const pi = math.pi; |
| // ``` |
| // |
| // If you don't need to reference the imported constant, then remove the |
| // reference: |
| // |
| // ```dart |
| // const pi = 3.14; |
| // ``` |
| static const CompileTimeErrorCode |
| CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'CONST_INITIALIZED_WITH_NON_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used to initialize " |
| "a 'const' variable.", |
| correction: |
| "Try initializing the variable without referencing members of " |
| "the deferred library, or changing the import to not be " |
| "deferred.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an instance field is marked as |
| // being const. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is an instance |
| // field: |
| // |
| // ```dart |
| // class C { |
| // [!const!] int f = 3; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field needs to be an instance field, then remove the keyword |
| // `const`, or replace it with `final`: |
| // |
| // ```dart |
| // class C { |
| // final int f = 3; |
| // } |
| // ``` |
| // |
| // If the field really should be a const field, then make it a static field: |
| // |
| // ```dart |
| // class C { |
| // static const int f = 3; |
| // } |
| // ``` |
| static const CompileTimeErrorCode CONST_INSTANCE_FIELD = CompileTimeErrorCode( |
| 'CONST_INSTANCE_FIELD', "Only static fields can be declared as const.", |
| correction: "Try declaring the field as final, or adding the keyword " |
| "'static'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the entry's key |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the class of object used as a |
| // key in a constant map literal implements the `==` operator. The |
| // implementation of constant maps uses the `==` operator, so any |
| // implementation other than the one inherited from `Object` requires |
| // executing arbitrary code at compile time, which isn't supported. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constant map |
| // contains a key whose type is `C`, and the class `C` overrides the |
| // implementation of `==`: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // |
| // bool operator ==(Object other) => true; |
| // } |
| // |
| // const map = {[!C()!] : 0}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you can remove the implementation of `==` from the class, then do so: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // } |
| // |
| // const map = {C() : 0}; |
| // ``` |
| // |
| // If you can't remove the implementation of `==` from the class, then make |
| // the map be non-constant: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // |
| // bool operator ==(Object other) => true; |
| // } |
| // |
| // final map = {C() : 0}; |
| // ``` |
| static const CompileTimeErrorCode |
| CONST_MAP_KEY_EXPRESSION_TYPE_IMPLEMENTS_EQUALS = CompileTimeErrorCode( |
| 'CONST_MAP_KEY_EXPRESSION_TYPE_IMPLEMENTS_EQUALS', |
| "The type of a key in a constant map can't override the '==' " |
| "operator, but the class '{0}' does.", |
| correction: "Try using a different value for the key, or " |
| "removing the keyword 'const' from the map.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the uninitialized final variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a variable that is declared to |
| // be a constant doesn't have an initializer. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `c` isn't initialized: |
| // |
| // ```dart |
| // const [!c!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add an initializer: |
| // |
| // ```dart |
| // const c = 'c'; |
| // ``` |
| static const CompileTimeErrorCode CONST_NOT_INITIALIZED = |
| CompileTimeErrorCode( |
| 'CONST_NOT_INITIALIZED', "The constant '{0}' must be initialized.", |
| correction: "Try adding an initialization to the declaration.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the element |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the class of object used as an |
| // element in a constant set literal implements the `==` operator. The |
| // implementation of constant sets uses the `==` operator, so any |
| // implementation other than the one inherited from `Object` requires |
| // executing arbitrary code at compile time, which isn't supported. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constant set |
| // contains an element whose type is `C`, and the class `C` overrides the |
| // implementation of `==`: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // |
| // bool operator ==(Object other) => true; |
| // } |
| // |
| // const set = {[!C()!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you can remove the implementation of `==` from the class, then do so: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // } |
| // |
| // const set = {C()}; |
| // ``` |
| // |
| // If you can't remove the implementation of `==` from the class, then make |
| // the set be non-constant: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // |
| // bool operator ==(Object other) => true; |
| // } |
| // |
| // final set = {C()}; |
| // ``` |
| static const CompileTimeErrorCode CONST_SET_ELEMENT_TYPE_IMPLEMENTS_EQUALS = |
| CompileTimeErrorCode( |
| 'CONST_SET_ELEMENT_TYPE_IMPLEMENTS_EQUALS', |
| "The type of an element in a constant set can't override the '==' " |
| "operator, but the type '{0}' does.", |
| correction: "Try using a different value for the element, or " |
| "removing the keyword 'const' from the set.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression of a spread |
| // operator in a constant list or set evaluates to something other than a list |
| // or a set. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the value of `list1` is |
| // `null`, which is neither a list nor a set: |
| // |
| // ```dart |
| // %language=2.9 |
| // const List<int> list1 = null; |
| // const List<int> list2 = [...[!list1!]]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the expression to something that evaluates to either a constant list |
| // or a constant set: |
| // |
| // ```dart |
| // %language=2.9 |
| // const List<int> list1 = []; |
| // const List<int> list2 = [...list1]; |
| // ``` |
| static const CompileTimeErrorCode CONST_SPREAD_EXPECTED_LIST_OR_SET = |
| CompileTimeErrorCode('CONST_SPREAD_EXPECTED_LIST_OR_SET', |
| "A list or a set is expected in this spread.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression of a spread |
| // operator in a constant map evaluates to something other than a map. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the value of `map1` is |
| // `null`, which isn't a map: |
| // |
| // ```dart |
| // %language=2.9 |
| // const Map<String, int> map1 = null; |
| // const Map<String, int> map2 = {...[!map1!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the expression to something that evaluates to a constant map: |
| // |
| // ```dart |
| // %language=2.9 |
| // const Map<String, int> map1 = {}; |
| // const Map<String, int> map2 = {...map1}; |
| // ``` |
| static const CompileTimeErrorCode CONST_SPREAD_EXPECTED_MAP = |
| CompileTimeErrorCode( |
| 'CONST_SPREAD_EXPECTED_MAP', "A map is expected in this spread.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the keyword `const` is used to |
| // invoke a constructor that isn't marked with `const`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the constructor in `A` |
| // isn't a const constructor: |
| // |
| // ```dart |
| // class A { |
| // A(); |
| // } |
| // |
| // A f() => [!const!] A(); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it's desirable and possible to make the class a constant class (by |
| // making all of the fields of the class, including inherited fields, final), |
| // then add the keyword `const` to the constructor: |
| // |
| // ```dart |
| // class A { |
| // const A(); |
| // } |
| // |
| // A f() => const A(); |
| // ``` |
| // |
| // Otherwise, remove the keyword `const`: |
| // |
| // ```dart |
| // class A { |
| // A(); |
| // } |
| // |
| // A f() => A(); |
| // ``` |
| static const CompileTimeErrorCode CONST_WITH_NON_CONST = CompileTimeErrorCode( |
| 'CONST_WITH_NON_CONST', |
| "The constructor being called isn't a const constructor.", |
| correction: "Try removing 'const' from the constructor invocation.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a const constructor is invoked |
| // with an argument that isn't a constant expression. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `i` isn't a constant: |
| // |
| // ```dart |
| // class C { |
| // final int i; |
| // const C(this.i); |
| // } |
| // C f(int i) => const C([!i!]); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Either make all of the arguments constant expressions, or remove the |
| // `const` keyword to use the non-constant form of the constructor: |
| // |
| // ```dart |
| // class C { |
| // final int i; |
| // const C(this.i); |
| // } |
| // C f(int i) => C(i); |
| // ``` |
| static const CompileTimeErrorCode CONST_WITH_NON_CONSTANT_ARGUMENT = |
| CompileTimeErrorCode('CONST_WITH_NON_CONSTANT_ARGUMENT', |
| "Arguments of a constant creation must be constant expressions.", |
| correction: "Try making the argument a valid constant, or " |
| "use 'new' to call the constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the non-type element |
| */ |
| static const CompileTimeErrorCode CONST_WITH_NON_TYPE = CompileTimeErrorCode( |
| 'CREATION_WITH_NON_TYPE', |
| "The name '{0}' isn't a class.", |
| correction: "Try correcting the name to match an existing class.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true, |
| uniqueName: 'CONST_WITH_NON_TYPE', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type parameter is used as a |
| // type argument in a `const` invocation of a constructor. This isn't allowed |
| // because the value of the type parameter (the actual type that will be used |
| // at runtime) can't be known at compile time. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type parameter `T` |
| // is being used as a type argument when creating a constant: |
| // |
| // ```dart |
| // class C<T> { |
| // const C(); |
| // } |
| // |
| // C<T> newC<T>() => const C<[!T!]>(); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type that will be used for the type parameter can be known at |
| // compile time, then remove the use of the type parameter: |
| // |
| // ```dart |
| // class C<T> { |
| // const C(); |
| // } |
| // |
| // C<int> newC() => const C<int>(); |
| // ``` |
| // |
| // If the type that will be used for the type parameter can't be known until |
| // runtime, then remove the keyword `const`: |
| // |
| // ```dart |
| // class C<T> { |
| // const C(); |
| // } |
| // |
| // C<T> newC<T>() => C<T>(); |
| // ``` |
| static const CompileTimeErrorCode CONST_WITH_TYPE_PARAMETERS = |
| CompileTimeErrorCode('CONST_WITH_TYPE_PARAMETERS', |
| "A constant creation can't use a type parameter as a type argument.", |
| correction: "Try replacing the type parameter with a different type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| CONST_WITH_TYPE_PARAMETERS_CONSTRUCTOR_TEAROFF = CompileTimeErrorCode( |
| 'CONST_WITH_TYPE_PARAMETERS', |
| "A constant constructor tearoff can't use a type parameter as a type " |
| "argument.", |
| correction: "Try replacing the type parameter with a different type.", |
| uniqueName: 'CONST_WITH_TYPE_PARAMETERS_CONSTRUCTOR_TEAROFF', |
| hasPublishedDocs: true); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if <i>T.id</i> is not the name of |
| * a constant constructor declared by the type <i>T</i>. |
| * |
| * Parameters: |
| * 0: the name of the type |
| * 1: the name of the requested constant constructor |
| */ |
| static const CompileTimeErrorCode CONST_WITH_UNDEFINED_CONSTRUCTOR = |
| CompileTimeErrorCode('CONST_WITH_UNDEFINED_CONSTRUCTOR', |
| "The class '{0}' doesn't have a constant constructor '{1}'.", |
| correction: "Try calling a different constructor."); |
| |
| /** |
| * 16.12.2 Const: It is a compile-time error if <i>T.id</i> is not the name of |
| * a constant constructor declared by the type <i>T</i>. |
| * |
| * Parameters: |
| * 0: the name of the type |
| */ |
| static const CompileTimeErrorCode CONST_WITH_UNDEFINED_CONSTRUCTOR_DEFAULT = |
| CompileTimeErrorCode('CONST_WITH_UNDEFINED_CONSTRUCTOR_DEFAULT', |
| "The class '{0}' doesn't have an unnamed constant constructor.", |
| correction: "Try calling a different constructor."); |
| |
| static const CompileTimeErrorCode CONTINUE_LABEL_ON_SWITCH = |
| CompileTimeErrorCode('CONTINUE_LABEL_ON_SWITCH', |
| "A continue label resolves to switch, must be loop or switch member"); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a use of the default |
| // constructor for the class `List` in code that has opted in to null safety. |
| // |
| // #### Example |
| // |
| // Assuming the following code is opted in to null safety, it produces this |
| // diagnostic because it uses the default `List` constructor: |
| // |
| // ```dart |
| // var l = [!List<int>!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If no initial size is provided, then convert the code to use a list |
| // literal: |
| // |
| // ```dart |
| // var l = <int>[]; |
| // ``` |
| // |
| // If an initial size needs to be provided and there is a single reasonable |
| // initial value for the elements, then use `List.filled`: |
| // |
| // ```dart |
| // var l = List.filled(3, 0); |
| // ``` |
| // |
| // If an initial size needs to be provided but each element needs to be |
| // computed, then use `List.generate`: |
| // |
| // ```dart |
| // var l = List.generate(3, (i) => i); |
| // ``` |
| static const CompileTimeErrorCode DEFAULT_LIST_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'DEFAULT_LIST_CONSTRUCTOR', |
| "The default 'List' constructor isn't available when null safety is " |
| "enabled.", |
| correction: "Try using a list literal, 'List.filled' or " |
| "'List.generate'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a factory constructor that |
| // redirects to another constructor specifies a default value for an optional |
| // parameter. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the factory constructor |
| // in `A` has a default value for the optional parameter `x`: |
| // |
| // ```dart |
| // class A { |
| // factory A([int [!x!] = 0]) = B; |
| // } |
| // |
| // class B implements A { |
| // B([int x = 1]) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the default value from the factory constructor: |
| // |
| // ```dart |
| // class A { |
| // factory A([int x]) = B; |
| // } |
| // |
| // class B implements A { |
| // B([int x = 1]) {} |
| // } |
| // ``` |
| // |
| // Note that this fix might change the value used when the optional parameter |
| // is omitted. If that happens, and if that change is a problem, then consider |
| // making the optional parameter a required parameter in the factory method: |
| // |
| // ```dart |
| // class A { |
| // factory A(int x) = B; |
| // } |
| // |
| // class B implements A { |
| // B([int x = 1]) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| DEFAULT_VALUE_IN_REDIRECTING_FACTORY_CONSTRUCTOR = CompileTimeErrorCode( |
| 'DEFAULT_VALUE_IN_REDIRECTING_FACTORY_CONSTRUCTOR', |
| "Default values aren't allowed in factory constructors that redirect " |
| "to another constructor.", |
| correction: "Try removing the default value.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| /* #### Description |
| // |
| // The analyzer produces this diagnostic when a named parameter has both the |
| // `required` modifier and a default value. If the parameter is required, then |
| // a value for the parameter is always provided at the call sites, so the |
| // default value can never be used. |
| // |
| // #### Examples |
| // |
| // The following code generates this diagnostic: |
| // |
| // ```dart |
| // void log({required String [!message!] = 'no message'}) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the parameter is really required, then remove the default value: |
| // |
| // ```dart |
| // void log({required String message}) {} |
| // ``` |
| // |
| // If the parameter isn't always required, then remove the `required` |
| // modifier: |
| // |
| // ```dart |
| // void log({String message = 'no message'}) {} |
| // ``` */ |
| static const CompileTimeErrorCode DEFAULT_VALUE_ON_REQUIRED_PARAMETER = |
| CompileTimeErrorCode('DEFAULT_VALUE_ON_REQUIRED_PARAMETER', |
| "Required named parameters can't have a default value.", |
| correction: "Try removing either the default value or the 'required' " |
| "modifier."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a library that is imported using |
| // a deferred import declares an extension that is visible in the importing |
| // library. Extension methods are resolved at compile time, and extensions |
| // from deferred libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // Given a file (`a.dart`) that defines a named extension: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class C {} |
| // |
| // extension E on String { |
| // int get size => length; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the named extension is |
| // visible to the library: |
| // |
| // ```dart |
| // import [!'a.dart'!] deferred as a; |
| // |
| // void f() { |
| // a.C(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the library must be imported as `deferred`, then either add a `show` |
| // clause listing the names being referenced or add a `hide` clause listing |
| // all of the named extensions. Adding a `show` clause would look like this: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a show C; |
| // |
| // void f() { |
| // a.C(); |
| // } |
| // ``` |
| // |
| // Adding a `hide` clause would look like this: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a hide E; |
| // |
| // void f() { |
| // a.C(); |
| // } |
| // ``` |
| // |
| // With the first fix, the benefit is that if new extensions are added to the |
| // imported library, then the extensions won't cause a diagnostic to be |
| // generated. |
| // |
| // If the library doesn't need to be imported as `deferred`, or if you need to |
| // make use of the extension method declared in it, then remove the keyword |
| // `deferred`: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // |
| // void f() { |
| // a.C(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode DEFERRED_IMPORT_OF_EXTENSION = |
| CompileTimeErrorCode('DEFERRED_IMPORT_OF_EXTENSION', |
| "Imports of deferred libraries must hide all extensions.", |
| correction: |
| "Try adding either a show combinator listing the names you need " |
| "to reference or a hide combinator listing all of the " |
| "extensions.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the variable that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when [definite assignment][] analysis |
| // shows that a local variable that's marked as `late` is read before being |
| // assigned. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` wasn't assigned a |
| // value before being read: |
| // |
| // ```dart |
| // void f(bool b) { |
| // late int x; |
| // print([!x!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Assign a value to the variable before reading from it: |
| // |
| // ```dart |
| // void f(bool b) { |
| // late int x; |
| // x = b ? 1 : 0; |
| // print(x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode DEFINITELY_UNASSIGNED_LATE_LOCAL_VARIABLE = |
| CompileTimeErrorCode( |
| 'DEFINITELY_UNASSIGNED_LATE_LOCAL_VARIABLE', |
| "The late local variable '{0}' is definitely unassigned at this " |
| "point.", |
| correction: |
| "Ensure that it is assigned on necessary execution paths.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class declares more than one |
| // unnamed constructor or when it declares more than one constructor with the |
| // same name. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there are two |
| // declarations for the unnamed constructor: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // |
| // [!C!](); |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because there are two |
| // declarations for the constructor named `m`: |
| // |
| // ```dart |
| // class C { |
| // C.m(); |
| // |
| // [!C.m!](); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there are multiple unnamed constructors and all of the constructors are |
| // needed, then give all of them, or all except one of them, a name: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // |
| // C.n(); |
| // } |
| // ``` |
| // |
| // If there are multiple unnamed constructors and all except one of them are |
| // unneeded, then remove the constructors that aren't needed: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // } |
| // ``` |
| // |
| // If there are multiple named constructors and all of the constructors are |
| // needed, then rename all except one of them: |
| // |
| // ```dart |
| // class C { |
| // C.m(); |
| // |
| // C.n(); |
| // } |
| // ``` |
| // |
| // If there are multiple named constructors and all except one of them are |
| // unneeded, then remove the constructorsthat aren't needed: |
| // |
| // ```dart |
| // class C { |
| // C.m(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode DUPLICATE_CONSTRUCTOR_DEFAULT = |
| CompileTimeErrorCode( |
| 'DUPLICATE_CONSTRUCTOR', |
| "The unnamed constructor is already defined.", |
| correction: "Try giving one of the constructors a name.", |
| hasPublishedDocs: true, |
| uniqueName: 'DUPLICATE_CONSTRUCTOR_DEFAULT', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the duplicate entity |
| */ |
| static const CompileTimeErrorCode DUPLICATE_CONSTRUCTOR_NAME = |
| CompileTimeErrorCode( |
| 'DUPLICATE_CONSTRUCTOR', |
| "The constructor with name '{0}' is already defined.", |
| correction: "Try renaming one of the constructors.", |
| hasPublishedDocs: true, |
| uniqueName: 'DUPLICATE_CONSTRUCTOR_NAME', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the duplicate entity |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name is declared, and there is |
| // a previous declaration with the same name in the same scope. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `x` is |
| // declared twice: |
| // |
| // ```dart |
| // int x = 0; |
| // int [!x!] = 1; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Choose a different name for one of the declarations. |
| // |
| // ```dart |
| // int x = 0; |
| // int y = 1; |
| // ``` |
| static const CompileTimeErrorCode DUPLICATE_DEFINITION = CompileTimeErrorCode( |
| 'DUPLICATE_DEFINITION', "The name '{0}' is already defined.", |
| correction: "Try renaming one of the declarations.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when there's more than one field |
| // formal parameter for the same field in a constructor's parameter list. It |
| // isn't useful to assign a value that will immediately be overwritten. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `this.f` appears twice |
| // in the parameter list: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f, this.[!f!]) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove one of the field formal parameters: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode DUPLICATE_FIELD_FORMAL_PARAMETER = |
| CompileTimeErrorCode( |
| 'DUPLICATE_FIELD_FORMAL_PARAMETER', |
| "The field '{0}' can't be initialized by multiple parameters in the " |
| "same constructor.", |
| correction: "Try removing one of the parameters, or " |
| "using different fields.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the parameter that was duplicated |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an invocation has two or more |
| // named arguments that have the same name. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there are two arguments |
| // with the name `a`: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(C c) { |
| // c.m(a: 0, [!a!]: 1); |
| // } |
| // |
| // class C { |
| // void m({int a, int b}) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If one of the arguments should have a different name, then change the name: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(C c) { |
| // c.m(a: 0, b: 1); |
| // } |
| // |
| // class C { |
| // void m({int a, int b}) {} |
| // } |
| // ``` |
| // |
| // If one of the arguments is wrong, then remove it: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(C c) { |
| // c.m(a: 1); |
| // } |
| // |
| // class C { |
| // void m({int a, int b}) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode DUPLICATE_NAMED_ARGUMENT = |
| CompileTimeErrorCode('DUPLICATE_NAMED_ARGUMENT', |
| "The argument for the named parameter '{0}' was already specified.", |
| correction: "Try removing one of the named arguments, or " |
| "correcting one of the names to reference a different named " |
| "parameter.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the URI of the duplicate part |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a single file is referenced in |
| // multiple part directives. |
| // |
| // #### Example |
| // |
| // Given a file named `part.dart` containing |
| // |
| // ```dart |
| // %uri="lib/part.dart" |
| // part of lib; |
| // ``` |
| // |
| // The following code produces this diagnostic because the file `part.dart` is |
| // included multiple times: |
| // |
| // ```dart |
| // library lib; |
| // |
| // part 'part.dart'; |
| // part [!'part.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove all except the first of the duplicated part directives: |
| // |
| // ```dart |
| // library lib; |
| // |
| // part 'part.dart'; |
| // ``` |
| static const CompileTimeErrorCode DUPLICATE_PART = CompileTimeErrorCode( |
| 'DUPLICATE_PART', |
| "The library already contains a part with the URI '{0}'.", |
| correction: |
| "Try removing all except one of the duplicated part directives.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode ENUM_CONSTANT_SAME_NAME_AS_ENCLOSING = |
| CompileTimeErrorCode('ENUM_CONSTANT_SAME_NAME_AS_ENCLOSING', |
| "The name of the enum constant can't be the same as the enum's name.", |
| correction: "Try renaming the constant."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when two elements in a constant set |
| // literal have the same value. The set can only contain each value once, |
| // which means that one of the values is unnecessary. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the string `'a'` is |
| // specified twice: |
| // |
| // ```dart |
| // const Set<String> set = {'a', [!'a'!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove one of the duplicate values: |
| // |
| // ```dart |
| // const Set<String> set = {'a'}; |
| // ``` |
| // |
| // Note that literal sets preserve the order of their elements, so the choice |
| // of which element to remove might affect the order in which elements are |
| // returned by an iterator. |
| static const CompileTimeErrorCode EQUAL_ELEMENTS_IN_CONST_SET = |
| CompileTimeErrorCode('EQUAL_ELEMENTS_IN_CONST_SET', |
| "Two elements in a constant set literal can't be equal.", |
| correction: "Change or remove the duplicate element.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a key in a constant map is the |
| // same as a previous key in the same map. If two keys are the same, then the |
| // second value would overwrite the first value, which makes having both pairs |
| // pointless. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the key `1` is used |
| // twice: |
| // |
| // ```dart |
| // const map = <int, String>{1: 'a', 2: 'b', [!1!]: 'c', 4: 'd'}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If both entries should be included in the map, then change one of the keys |
| // to be different: |
| // |
| // ```dart |
| // const map = <int, String>{1: 'a', 2: 'b', 3: 'c', 4: 'd'}; |
| // ``` |
| // |
| // If only one of the entries is needed, then remove the one that isn't |
| // needed: |
| // |
| // ```dart |
| // const map = <int, String>{1: 'a', 2: 'b', 4: 'd'}; |
| // ``` |
| // |
| // Note that literal maps preserve the order of their entries, so the choice |
| // of which entry to remove might affect the order in which keys and values |
| // are returned by an iterator. |
| static const CompileTimeErrorCode EQUAL_KEYS_IN_CONST_MAP = |
| CompileTimeErrorCode('EQUAL_KEYS_IN_CONST_MAP', |
| "Two keys in a constant map literal can't be equal.", |
| correction: "Change or remove the duplicate key.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the number of provided type arguments |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a list literal has more than one |
| // type argument. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the list literal has |
| // two type arguments when it can have at most one: |
| // |
| // ```dart |
| // var l = [!<int, int>!][]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove all except one of the type arguments: |
| // |
| // ```dart |
| // var l = <int>[]; |
| // ``` |
| static const CompileTimeErrorCode EXPECTED_ONE_LIST_TYPE_ARGUMENTS = |
| CompileTimeErrorCode('EXPECTED_ONE_LIST_TYPE_ARGUMENTS', |
| "List literals require one type argument or none, but {0} found.", |
| correction: "Try adjusting the number of type arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the number of provided type arguments |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a set literal has more than one |
| // type argument. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the set literal has |
| // three type arguments when it can have at most one: |
| // |
| // ```dart |
| // var s = [!<int, String, int>!]{0, 'a', 1}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove all except one of the type arguments: |
| // |
| // ```dart |
| // var s = <int>{0, 1}; |
| // ``` |
| static const CompileTimeErrorCode EXPECTED_ONE_SET_TYPE_ARGUMENTS = |
| CompileTimeErrorCode('EXPECTED_ONE_SET_TYPE_ARGUMENTS', |
| "Set literals require one type argument or none, but {0} were found.", |
| correction: "Try adjusting the number of type arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the number of provided type arguments |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a map literal has either one or |
| // more than two type arguments. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the map literal has |
| // three type arguments when it can have either two or zero: |
| // |
| // ```dart |
| // var m = [!<int, String, int>!]{}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove all except two of the type arguments: |
| // |
| // ```dart |
| // var m = <int, String>{}; |
| // ``` |
| static const CompileTimeErrorCode EXPECTED_TWO_MAP_TYPE_ARGUMENTS = |
| CompileTimeErrorCode('EXPECTED_TWO_MAP_TYPE_ARGUMENTS', |
| "Map literals require two type arguments or none, but {0} found.", |
| correction: "Try adjusting the number of type arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the uri pointing to a library |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds an export whose `dart:` |
| // URI references an internal library. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `_interceptors` is an |
| // internal library: |
| // |
| // ```dart |
| // export [!'dart:_interceptors'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the export directive. |
| static const CompileTimeErrorCode EXPORT_INTERNAL_LIBRARY = |
| CompileTimeErrorCode('EXPORT_INTERNAL_LIBRARY', |
| "The library '{0}' is internal and can't be exported.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of a symbol defined in a legacy library |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a library that was opted in to |
| // null safety exports another library, and the exported library is opted out |
| // of null safety. |
| // |
| // #### Example |
| // |
| // Given a library that is opted out of null safety: |
| // |
| // ```dart |
| // %uri="lib/optedOut.dart" |
| // // @dart = 2.8 |
| // String s; |
| // ``` |
| // |
| // The following code produces this diagnostic because it's exporting symbols |
| // from an opted-out library: |
| // |
| // ```dart |
| // export [!'optedOut.dart'!]; |
| // |
| // class C {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you're able to do so, migrate the exported library so that it doesn't |
| // need to opt out: |
| // |
| // ```dart |
| // String? s; |
| // ``` |
| // |
| // If you can't migrate the library, then remove the export: |
| // |
| // ```dart |
| // class C {} |
| // ``` |
| // |
| // If the exported library (the one that is opted out) itself exports an |
| // opted-in library, then it's valid for your library to indirectly export the |
| // symbols from the opted-in library. You can do so by adding a hide |
| // combinator to the export directive in your library that hides all of the |
| // names declared in the opted-out library. |
| static const CompileTimeErrorCode EXPORT_LEGACY_SYMBOL = CompileTimeErrorCode( |
| 'EXPORT_LEGACY_SYMBOL', |
| "The symbol '{0}' is defined in a legacy library, and can't be " |
| "re-exported from a library with null safety enabled.", |
| correction: "Try removing the export or migrating the legacy library.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the uri pointing to a non-library declaration |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an export directive references a |
| // part rather than a library. |
| // |
| // #### Example |
| // |
| // Given a file named `part.dart` containing |
| // |
| // ```dart |
| // %uri="lib/part.dart" |
| // part of lib; |
| // ``` |
| // |
| // The following code produces this diagnostic because the file `part.dart` is |
| // a part, and only libraries can be exported: |
| // |
| // ```dart |
| // library lib; |
| // |
| // export [!'part.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Either remove the export directive, or change the URI to be the URI of the |
| // library containing the part. |
| static const CompileTimeErrorCode EXPORT_OF_NON_LIBRARY = |
| CompileTimeErrorCode('EXPORT_OF_NON_LIBRARY', |
| "The exported library '{0}' can't have a part-of directive.", |
| correction: "Try exporting the library that the part is a part of.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the analyzer finds an |
| // expression, rather than a map entry, in what appears to be a map literal. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // var map = <String, int>{'a': 0, 'b': 1, [!'c'!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the expression is intended to compute either a key or a value in an |
| // entry, fix the issue by replacing the expression with the key or the value. |
| // For example: |
| // |
| // ```dart |
| // var map = <String, int>{'a': 0, 'b': 1, 'c': 2}; |
| // ``` |
| static const CompileTimeErrorCode EXPRESSION_IN_MAP = CompileTimeErrorCode( |
| 'EXPRESSION_IN_MAP', "Expressions can't be used in a map literal.", |
| correction: "Try removing the expression or converting it to be a map " |
| "entry.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type (class or mixin) is a |
| // subtype of a class from a library being imported using a deferred import. |
| // The supertypes of a type must be compiled at the same time as the type, and |
| // classes from deferred libraries aren't compiled until the library is |
| // loaded. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // Given a file (`a.dart`) that defines the class `A`: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class A {} |
| // ``` |
| // |
| // The following code produces this diagnostic because the superclass of `B` |
| // is declared in a deferred library: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // class B extends [!a.A!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to create a subtype of a type from the deferred library, then |
| // remove the `deferred` keyword: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // |
| // class B extends a.A {} |
| // ``` |
| static const CompileTimeErrorCode EXTENDS_DEFERRED_CLASS = |
| CompileTimeErrorCode( |
| 'SUBTYPE_OF_DEFERRED_CLASS', "Classes can't extend deferred classes.", |
| correction: "Try specifying a different superclass, or " |
| "removing the extends clause.", |
| hasPublishedDocs: true, |
| uniqueName: 'EXTENDS_DEFERRED_CLASS'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the disallowed type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when one of the restricted classes is |
| // used in either an `extends`, `implements`, `with`, or `on` clause. The |
| // classes `bool`, `double`, `FutureOr`, `int`, `Null`, `num`, and `String` |
| // are all restricted in this way, to allow for more efficient |
| // implementations. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `String` is used in an |
| // `extends` clause: |
| // |
| // ```dart |
| // class A extends [!String!] {} |
| // ``` |
| // |
| // The following code produces this diagnostic because `String` is used in an |
| // `implements` clause: |
| // |
| // ```dart |
| // class B implements [!String!] {} |
| // ``` |
| // |
| // The following code produces this diagnostic because `String` is used in a |
| // `with` clause: |
| // |
| // ```dart |
| // class C with [!String!] {} |
| // ``` |
| // |
| // The following code produces this diagnostic because `String` is used in an |
| // `on` clause: |
| // |
| // ```dart |
| // mixin M on [!String!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If a different type should be specified, then replace the type: |
| // |
| // ```dart |
| // class A extends Object {} |
| // ``` |
| // |
| // If there isn't a different type that would be appropriate, then remove the |
| // type, and possibly the whole clause: |
| // |
| // ```dart |
| // class B {} |
| // ``` |
| static const CompileTimeErrorCode EXTENDS_DISALLOWED_CLASS = |
| // TODO(scheglov) We might want to restore specific code with FrontEnd. |
| // https://github.com/dart-lang/sdk/issues/31821 |
| CompileTimeErrorCode( |
| 'SUBTYPE_OF_DISALLOWED_TYPE', |
| "Classes can't extend '{0}'.", |
| correction: "Try specifying a different superclass, or " |
| "removing the extends clause.", |
| hasPublishedDocs: true, |
| uniqueName: 'EXTENDS_DISALLOWED_CLASS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name in the extends clause |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an `extends` clause contains a |
| // name that is declared to be something other than a class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is declared to be a |
| // function: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // class C extends [!f!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want the class to extend a class other than `Object`, then replace |
| // the name in the `extends` clause with the name of that class: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // class C extends B {} |
| // |
| // class B {} |
| // ``` |
| // |
| // If you want the class to extend `Object`, then remove the `extends` clause: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // class C {} |
| // ``` |
| static const CompileTimeErrorCode EXTENDS_NON_CLASS = CompileTimeErrorCode( |
| 'EXTENDS_NON_CLASS', "Classes can only extend other classes.", |
| correction: |
| "Try specifying a different superclass, or removing the extends " |
| "clause.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type alias that expands to a |
| // type parameter is used in an `extends`, `implements`, `with`, or `on` |
| // clause. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type alias `T`, |
| // which expands to the type parameter `S`, is used in the `extends` clause of |
| // the class `C`: |
| // |
| // ```dart |
| // typedef T<S> = S; |
| // |
| // class C extends [!T!]<Object> {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use the value of the type argument directly: |
| // |
| // ```dart |
| // typedef T<S> = S; |
| // |
| // class C extends Object {} |
| // ``` |
| static const CompileTimeErrorCode |
| EXTENDS_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'SUPERTYPE_EXPANDS_TO_TYPE_PARAMETER', |
| "A type alias that expands to a type parameter can't be used as a " |
| "superclass.", |
| correction: |
| "Try specifying a different superclass, or removing the extends " |
| "clause.", |
| hasPublishedDocs: true, |
| uniqueName: 'EXTENDS_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the extension |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name of an extension is used |
| // in an expression other than in an extension override or to qualify an |
| // access to a static member of the extension. Because classes define a type, |
| // the name of a class can be used to refer to the instance of `Type` |
| // representing the type of the class. Extensions, on the other hand, don't |
| // define a type and can't be used as a type literal. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `E` is an extension: |
| // |
| // ```dart |
| // extension E on int { |
| // static String m() => ''; |
| // } |
| // |
| // var x = [!E!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the name of the extension with a name that can be referenced, such |
| // as a static member defined on the extension: |
| // |
| // ```dart |
| // extension E on int { |
| // static String m() => ''; |
| // } |
| // |
| // var x = E.m(); |
| // ``` |
| static const CompileTimeErrorCode EXTENSION_AS_EXPRESSION = |
| CompileTimeErrorCode('EXTENSION_AS_EXPRESSION', |
| "Extension '{0}' can't be used as an expression.", |
| correction: "Try replacing it with a valid expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the extension defining the conflicting member |
| * 1: the name of the conflicting static member |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension declaration |
| // contains both an instance member and a static member that have the same |
| // name. The instance member and the static member can't have the same name |
| // because it's unclear which member is being referenced by an unqualified use |
| // of the name within the body of the extension. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `a` is being |
| // used for two different members: |
| // |
| // ```dart |
| // extension E on Object { |
| // int get a => 0; |
| // static int [!a!]() => 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rename or remove one of the members: |
| // |
| // ```dart |
| // extension E on Object { |
| // int get a => 0; |
| // static int b() => 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTENSION_CONFLICTING_STATIC_AND_INSTANCE = |
| CompileTimeErrorCode( |
| 'EXTENSION_CONFLICTING_STATIC_AND_INSTANCE', |
| "Extension '{0}' can't define static member '{1}' and an instance " |
| "member with the same name.", |
| correction: |
| "Try renaming the member to a name that doesn't conflict.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension declaration |
| // declares a member with the same name as a member declared in the class |
| // `Object`. Such a member can never be used because the member in `Object` is |
| // always found first. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `toString` is defined |
| // by `Object`: |
| // |
| // ```dart |
| // extension E on String { |
| // String [!toString!]() => this; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the member or rename it so that the name doesn't conflict with the |
| // member in `Object`: |
| // |
| // ```dart |
| // extension E on String { |
| // String displayString() => this; |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTENSION_DECLARES_MEMBER_OF_OBJECT = |
| CompileTimeErrorCode( |
| 'EXTENSION_DECLARES_MEMBER_OF_OBJECT', |
| "Extensions can't declare members with the same name as a member " |
| "declared by 'Object'.", |
| correction: "Try specifying a different name for the member.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is the |
| // receiver of the invocation of a static member. Similar to static members in |
| // classes, the static members of an extension should be accessed using the |
| // name of the extension, not an extension override. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `m` is static: |
| // |
| // ```dart |
| // extension E on String { |
| // static void m() {} |
| // } |
| // |
| // void f() { |
| // E('').[!m!](); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the extension override with the name of the extension: |
| // |
| // ```dart |
| // extension E on String { |
| // static void m() {} |
| // } |
| // |
| // void f() { |
| // E.m(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTENSION_OVERRIDE_ACCESS_TO_STATIC_MEMBER = |
| CompileTimeErrorCode( |
| 'EXTENSION_OVERRIDE_ACCESS_TO_STATIC_MEMBER', |
| "An extension override can't be used to access a static member from " |
| "an extension.", |
| correction: "Try using just the name of the extension.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the argument |
| * 1: the extended type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the argument to an extension |
| // override isn't assignable to the type being extended by the extension. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `3` isn't a `String`: |
| // |
| // ```dart |
| // extension E on String { |
| // void method() {} |
| // } |
| // |
| // void f() { |
| // E([!3!]).method(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you're using the correct extension, then update the argument to have the |
| // correct type: |
| // |
| // ```dart |
| // extension E on String { |
| // void method() {} |
| // } |
| // |
| // void f() { |
| // E(3.toString()).method(); |
| // } |
| // ``` |
| // |
| // If there's a different extension that's valid for the type of the argument, |
| // then either replace the name of the extension or unwrap the argument so |
| // that the correct extension is found. |
| static const CompileTimeErrorCode EXTENSION_OVERRIDE_ARGUMENT_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'EXTENSION_OVERRIDE_ARGUMENT_NOT_ASSIGNABLE', |
| "The type of the argument to the extension override '{0}' " |
| "isn't assignable to the extended type '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is used as |
| // the receiver of a cascade expression. The value of a cascade expression |
| // `e..m` is the value of the receiver `e`, but extension overrides aren't |
| // expressions and don't have a value. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `E(3)` isn't an |
| // expression: |
| // |
| // ```dart |
| // extension E on int { |
| // void m() {} |
| // } |
| // f() { |
| // [!E!](3)..m(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use `.` rather than `..`: |
| // |
| // ```dart |
| // extension E on int { |
| // void m() {} |
| // } |
| // f() { |
| // E(3).m(); |
| // } |
| // ``` |
| // |
| // If there are multiple cascaded accesses, you'll need to duplicate the |
| // extension override for each one. |
| static const CompileTimeErrorCode EXTENSION_OVERRIDE_WITH_CASCADE = |
| CompileTimeErrorCode( |
| 'EXTENSION_OVERRIDE_WITH_CASCADE', |
| "Extension overrides have no value so they can't be used as the " |
| "receiver of a cascade expression.", |
| correction: "Try using '.' instead of '..'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is found |
| // that isn't being used to access one of the members of the extension. The |
| // extension override syntax doesn't have any runtime semantics; it only |
| // controls which member is selected at compile time. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `E(i)` isn't an |
| // expression: |
| // |
| // ```dart |
| // extension E on int { |
| // int get a => 0; |
| // } |
| // |
| // void f(int i) { |
| // print([!E(i)!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want to invoke one of the members of the extension, then add the |
| // invocation: |
| // |
| // ```dart |
| // extension E on int { |
| // int get a => 0; |
| // } |
| // |
| // void f(int i) { |
| // print(E(i).a); |
| // } |
| // ``` |
| // |
| // If you don't want to invoke a member, then unwrap the argument: |
| // |
| // ```dart |
| // extension E on int { |
| // int get a => 0; |
| // } |
| // |
| // void f(int i) { |
| // print(i); |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTENSION_OVERRIDE_WITHOUT_ACCESS = |
| CompileTimeErrorCode('EXTENSION_OVERRIDE_WITHOUT_ACCESS', |
| "An extension override can only be used to access instance members.", |
| correction: "Consider adding an access to an instance member.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode EXTERNAL_FIELD_CONSTRUCTOR_INITIALIZER = |
| CompileTimeErrorCode('EXTERNAL_FIELD_CONSTRUCTOR_INITIALIZER', |
| 'External fields cannot have initializers.', |
| correction: |
| "Try removing the field initializer or the 'external' keyword " |
| "from the field declaration."); |
| |
| static const CompileTimeErrorCode EXTERNAL_FIELD_INITIALIZER = |
| CompileTimeErrorCode('EXTERNAL_FIELD_INITIALIZER', |
| 'External fields cannot have initializers.', |
| correction: |
| "Try removing the initializer or the 'external' keyword."); |
| |
| static const CompileTimeErrorCode EXTERNAL_VARIABLE_INITIALIZER = |
| CompileTimeErrorCode('EXTERNAL_VARIABLE_INITIALIZER', |
| 'External variables cannot have initializers.', |
| correction: |
| "Try removing the initializer or the 'external' keyword."); |
| |
| /** |
| * Parameters: |
| * 0: the maximum number of positional arguments |
| * 1: the actual number of positional arguments given |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function invocation |
| // has more positional arguments than the method or function allows. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` defines 2 |
| // parameters but is invoked with 3 arguments: |
| // |
| // ```dart |
| // void f(int a, int b) {} |
| // void g() { |
| // f(1, 2, [!3!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the arguments that don't correspond to parameters: |
| // |
| // ```dart |
| // void f(int a, int b) {} |
| // void g() { |
| // f(1, 2); |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTRA_POSITIONAL_ARGUMENTS = |
| CompileTimeErrorCode('EXTRA_POSITIONAL_ARGUMENTS', |
| "Too many positional arguments: {0} expected, but {1} found.", |
| correction: "Try removing the extra arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the maximum number of positional arguments |
| * 1: the actual number of positional arguments given |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function invocation |
| // has more positional arguments than the method or function allows, but the |
| // method or function defines named parameters. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` defines 2 |
| // positional parameters but has a named parameter that could be used for the |
| // third argument: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int a, int b, {int c}) {} |
| // void g() { |
| // f(1, 2, [!3!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If some of the arguments should be values for named parameters, then add |
| // the names before the arguments: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int a, int b, {int c}) {} |
| // void g() { |
| // f(1, 2, c: 3); |
| // } |
| // ``` |
| // |
| // Otherwise, remove the arguments that don't correspond to positional |
| // parameters: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int a, int b, {int c}) {} |
| // void g() { |
| // f(1, 2); |
| // } |
| // ``` |
| static const CompileTimeErrorCode EXTRA_POSITIONAL_ARGUMENTS_COULD_BE_NAMED = |
| CompileTimeErrorCode('EXTRA_POSITIONAL_ARGUMENTS_COULD_BE_NAMED', |
| "Too many positional arguments: {0} expected, but {1} found.", |
| correction: "Try removing the extra positional arguments, " |
| "or specifying the name for named arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field being initialized multiple times |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the initializer list of a |
| // constructor initializes a field more than once. There is no value to allow |
| // both initializers because only the last value is preserved. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field `f` is being |
| // initialized twice: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C() : f = 0, [!f!] = 1; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove one of the initializers: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C() : f = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode FIELD_INITIALIZED_BY_MULTIPLE_INITIALIZERS = |
| CompileTimeErrorCode('FIELD_INITIALIZED_BY_MULTIPLE_INITIALIZERS', |
| "The field '{0}' can't be initialized twice in the same constructor.", |
| correction: "Try removing one of the initializations.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a final field is initialized in |
| // both the declaration of the field and in an initializer in a constructor. |
| // Final fields can only be assigned once, so it can't be initialized in both |
| // places. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `f` is : |
| // |
| // ```dart |
| // class C { |
| // final int f = 0; |
| // C() : [!f!] = 1; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the initialization doesn't depend on any values passed to the |
| // constructor, and if all of the constructors need to initialize the field to |
| // the same value, then remove the initializer from the constructor: |
| // |
| // ```dart |
| // class C { |
| // final int f = 0; |
| // C(); |
| // } |
| // ``` |
| // |
| // If the initialization depends on a value passed to the constructor, or if |
| // different constructors need to initialize the field differently, then |
| // remove the initializer in the field's declaration: |
| // |
| // ```dart |
| // class C { |
| // final int f; |
| // C() : f = 1; |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| FIELD_INITIALIZED_IN_INITIALIZER_AND_DECLARATION = CompileTimeErrorCode( |
| 'FIELD_INITIALIZED_IN_INITIALIZER_AND_DECLARATION', |
| "Fields can't be initialized in the constructor if they are final " |
| "and were already initialized at their declaration.", |
| correction: "Try removing one of the initializations.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a field is initialized in both |
| // the parameter list and in the initializer list of a constructor. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field `f` is |
| // initialized both by a field formal parameter and in the initializer list: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f) : [!f!] = 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field should be initialized by the parameter, then remove the |
| // initialization in the initializer list: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // } |
| // ``` |
| // |
| // If the field should be initialized in the initializer list and the |
| // parameter isn't needed, then remove the parameter: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C() : f = 0; |
| // } |
| // ``` |
| // |
| // If the field should be initialized in the initializer list and the |
| // parameter is needed, then make it a normal parameter: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(int g) : f = g * 2; |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| FIELD_INITIALIZED_IN_PARAMETER_AND_INITIALIZER = CompileTimeErrorCode( |
| 'FIELD_INITIALIZED_IN_PARAMETER_AND_INITIALIZER', |
| "Fields can't be initialized in both the parameter list and the " |
| "initializers.", |
| correction: "Try removing one of the initializations.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a factory constructor has a |
| // field formal parameter. Factory constructors can't assign values to fields |
| // because no instance is created; hence, there is no field to assign. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the factory constructor |
| // uses a field formal parameter: |
| // |
| // ```dart |
| // class C { |
| // int? f; |
| // |
| // factory C([!this.f!]) => throw 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the field formal parameter with a normal parameter: |
| // |
| // ```dart |
| // class C { |
| // int? f; |
| // |
| // factory C(int f) => throw 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode FIELD_INITIALIZER_FACTORY_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'FIELD_INITIALIZER_FACTORY_CONSTRUCTOR', |
| "Initializing formal parameters can't be used in factory " |
| "constructors.", |
| correction: "Try using a normal parameter.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type of the initializer expression |
| * 1: the name of the type of the field |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the initializer list of a |
| // constructor initializes a field to a value that isn't assignable to the |
| // field. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `0` has the type `int`, |
| // and an `int` can't be assigned to a field of type `String`: |
| // |
| // ```dart |
| // class C { |
| // String s; |
| // |
| // C() : s = [!0!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the field is correct, then change the value assigned to it |
| // so that the value has a valid type: |
| // |
| // ```dart |
| // class C { |
| // String s; |
| // |
| // C() : s = '0'; |
| // } |
| // ``` |
| // |
| // If the type of the value is correct, then change the type of the field to |
| // allow the assignment: |
| // |
| // ```dart |
| // class C { |
| // int s; |
| // |
| // C() : s = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode FIELD_INITIALIZER_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'FIELD_INITIALIZER_NOT_ASSIGNABLE', |
| "The initializer type '{0}' can't be assigned to the field type " |
| "'{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.6.1 Generative Constructors: It is a compile-time error if an |
| * initializing formal is used by a function other than a non-redirecting |
| * generative constructor. |
| */ |
| static const CompileTimeErrorCode FIELD_INITIALIZER_OUTSIDE_CONSTRUCTOR = |
| CompileTimeErrorCode('FIELD_INITIALIZER_OUTSIDE_CONSTRUCTOR', |
| "Initializing formal parameters can only be used in constructors.", |
| correction: "Try using a normal parameter."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a redirecting constructor |
| // initializes a field in the object. This isn't allowed because the instance |
| // that has the field hasn't been created at the point at which it should be |
| // initialized. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constructor |
| // `C.zero`, which redirects to the constructor `C`, has a field formal |
| // parameter that initializes the field `f`: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // |
| // C.zero([!this.f!]) : this(f); |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the constructor |
| // `C.zero`, which redirects to the constructor `C`, has an initializer that |
| // initializes the field `f`: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // |
| // C.zero() : [!f = 0!], this(1); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the initialization is done by a field formal parameter, then use a |
| // normal parameter: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // |
| // C.zero(int f) : this(f); |
| // } |
| // ``` |
| // |
| // If the initialization is done in an initializer, then remove the |
| // initializer: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // |
| // C.zero() : this(0); |
| // } |
| // ``` |
| static const CompileTimeErrorCode FIELD_INITIALIZER_REDIRECTING_CONSTRUCTOR = |
| CompileTimeErrorCode('FIELD_INITIALIZER_REDIRECTING_CONSTRUCTOR', |
| "The redirecting constructor can't have a field initializer.", |
| correction: |
| "Try initializing the field in the constructor being redirected " |
| "to.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type of the field formal parameter |
| * 1: the name of the type of the field |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of a field formal |
| // parameter isn't assignable to the type of the field being initialized. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field formal |
| // parameter has the type `String`, but the type of the field is `int`. The |
| // parameter must have a type that is a subtype of the field's type. |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C([!String this.f!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the field is incorrect, then change the type of the field to |
| // match the type of the parameter, and consider removing the type from the |
| // parameter: |
| // |
| // ```dart |
| // class C { |
| // String f; |
| // |
| // C(this.f); |
| // } |
| // ``` |
| // |
| // If the type of the parameter is incorrect, then remove the type of the |
| // parameter: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(this.f); |
| // } |
| // ``` |
| // |
| // If the types of both the field and the parameter are correct, then use an |
| // initializer rather than a field formal parameter to convert the parameter |
| // value into a value of the correct type: |
| // |
| // ```dart |
| // class C { |
| // int f; |
| // |
| // C(String s) : f = int.parse(s); |
| // } |
| // ``` |
| static const CompileTimeErrorCode FIELD_INITIALIZING_FORMAL_NOT_ASSIGNABLE = |
| CompileTimeErrorCode('FIELD_INITIALIZING_FORMAL_NOT_ASSIGNABLE', |
| "The parameter type '{0}' is incompatible with the field type '{1}'.", |
| correction: "Try changing or removing the parameter's type, or " |
| "changing the field's type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field in question |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a final field is initialized |
| // twice: once where it's declared and once by a constructor's parameter. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field `f` is |
| // initialized twice: |
| // |
| // ```dart |
| // class C { |
| // final int f = 0; |
| // |
| // C(this.[!f!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field should have the same value for all instances, then remove the |
| // initialization in the parameter list: |
| // |
| // ```dart |
| // class C { |
| // final int f = 0; |
| // |
| // C(); |
| // } |
| // ``` |
| // |
| // If the field can have different values in different instances, then remove |
| // the initialization in the declaration: |
| // |
| // ```dart |
| // class C { |
| // final int f; |
| // |
| // C(this.f); |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| FINAL_INITIALIZED_IN_DECLARATION_AND_CONSTRUCTOR = CompileTimeErrorCode( |
| 'FINAL_INITIALIZED_IN_DECLARATION_AND_CONSTRUCTOR', |
| "'{0}' is final and was given a value when it was declared, " |
| "so it can't be set to a new value.", |
| correction: "Try removing one of the initializations.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the uninitialized final variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a final field or variable isn't |
| // initialized. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` doesn't have an |
| // initializer: |
| // |
| // ```dart |
| // final [!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // For variables and static fields, you can add an initializer: |
| // |
| // ```dart |
| // final x = 0; |
| // ``` |
| // |
| // For instance fields, you can add an initializer as shown in the previous |
| // example, or you can initialize the field in every constructor. You can |
| // initialize the field by using a field formal parameter: |
| // |
| // ```dart |
| // class C { |
| // final int x; |
| // C(this.x); |
| // } |
| // ``` |
| // |
| // You can also initialize the field by using an initializer in the |
| // constructor: |
| // |
| // ```dart |
| // class C { |
| // final int x; |
| // C(int y) : x = y * 2; |
| // } |
| // ``` |
| static const CompileTimeErrorCode FINAL_NOT_INITIALIZED = |
| CompileTimeErrorCode('FINAL_NOT_INITIALIZED', |
| "The final variable '{0}' must be initialized.", |
| // TODO(brianwilkerson) Split this error code so that we can suggest |
| // initializing fields in constructors (FINAL_FIELD_NOT_INITIALIZED |
| // and FINAL_VARIABLE_NOT_INITIALIZED). |
| correction: "Try initializing the variable.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the uninitialized final variable |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class defines one or more |
| // final instance fields without initializers and has at least one constructor |
| // that doesn't initialize those fields. All final instance fields must be |
| // initialized when the instance is created, either by the field's initializer |
| // or by the constructor. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // class C { |
| // final String value; |
| // |
| // [!C!](); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value should be passed in to the constructor directly, then use a |
| // field formal parameter to initialize the field `value`: |
| // |
| // ```dart |
| // class C { |
| // final String value; |
| // |
| // C(this.value); |
| // } |
| // ``` |
| // |
| // If the value should be computed indirectly from a value provided by the |
| // caller, then add a parameter and include an initializer: |
| // |
| // ```dart |
| // class C { |
| // final String value; |
| // |
| // C(Object o) : value = o.toString(); |
| // } |
| // ``` |
| // |
| // If the value of the field doesn't depend on values that can be passed to |
| // the constructor, then add an initializer for the field as part of the field |
| // declaration: |
| // |
| // ```dart |
| // class C { |
| // final String value = ''; |
| // |
| // C(); |
| // } |
| // ``` |
| // |
| // If the value of the field doesn't depend on values that can be passed to |
| // the constructor but different constructors need to initialize it to |
| // different values, then add an initializer for the field in the initializer |
| // list: |
| // |
| // ```dart |
| // class C { |
| // final String value; |
| // |
| // C() : value = ''; |
| // |
| // C.named() : value = 'c'; |
| // } |
| // ``` |
| // |
| // However, if the value is the same for all instances, then consider using a |
| // static field instead of an instance field: |
| // |
| // ```dart |
| // class C { |
| // static const String value = ''; |
| // |
| // C(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode FINAL_NOT_INITIALIZED_CONSTRUCTOR_1 = |
| CompileTimeErrorCode( |
| 'FINAL_NOT_INITIALIZED_CONSTRUCTOR', |
| "All final variables must be initialized, but '{0}' isn't.", |
| correction: "Try adding an initializer for the field.", |
| hasPublishedDocs: true, |
| uniqueName: 'FINAL_NOT_INITIALIZED_CONSTRUCTOR_1', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the uninitialized final variable |
| * 1: the name of the uninitialized final variable |
| */ |
| static const CompileTimeErrorCode FINAL_NOT_INITIALIZED_CONSTRUCTOR_2 = |
| CompileTimeErrorCode( |
| 'FINAL_NOT_INITIALIZED_CONSTRUCTOR', |
| "All final variables must be initialized, but '{0}' and '{1}' " |
| "aren't.", |
| correction: "Try adding initializers for the fields.", |
| hasPublishedDocs: true, |
| uniqueName: 'FINAL_NOT_INITIALIZED_CONSTRUCTOR_2', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the uninitialized final variable |
| * 1: the name of the uninitialized final variable |
| * 2: the number of additional not initialized variables that aren't listed |
| */ |
| static const CompileTimeErrorCode FINAL_NOT_INITIALIZED_CONSTRUCTOR_3_PLUS = |
| CompileTimeErrorCode( |
| 'FINAL_NOT_INITIALIZED_CONSTRUCTOR', |
| "All final variables must be initialized, but '{0}', '{1}', and {2} " |
| "others aren't.", |
| correction: "Try adding initializers for the fields.", |
| hasPublishedDocs: true, |
| uniqueName: 'FINAL_NOT_INITIALIZED_CONSTRUCTOR_3', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the type of the iterable expression. |
| * 1: the sequence type -- Iterable for `for` or Stream for `await for`. |
| * 2: the loop variable type. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the `Iterable` or `Stream` in a |
| // for-in loop has an element type that can't be assigned to the loop |
| // variable. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `<String>[]` has an |
| // element type of `String`, and `String` can't be assigned to the type of `e` |
| // (`int`): |
| // |
| // ```dart |
| // void f() { |
| // for (int e in [!<String>[]!]) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the loop variable is correct, then update the type of the |
| // iterable: |
| // |
| // ```dart |
| // void f() { |
| // for (int e in <int>[]) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| // |
| // If the type of the iterable is correct, then update the type of the loop |
| // variable: |
| // |
| // ```dart |
| // void f() { |
| // for (String e in <String>[]) { |
| // print(e); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode FOR_IN_OF_INVALID_ELEMENT_TYPE = |
| CompileTimeErrorCode( |
| 'FOR_IN_OF_INVALID_ELEMENT_TYPE', |
| "The type '{0}' used in the 'for' loop must implement '{1}' with a " |
| "type argument that can be assigned to '{2}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the iterable expression. |
| * 1: the sequence type -- Iterable for `for` or Stream for `await for`. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression following `in` in |
| // a for-in loop has a type that isn't a subclass of `Iterable`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `m` is a `Map`, and |
| // `Map` isn't a subclass of `Iterable`: |
| // |
| // ```dart |
| // void f(Map<String, String> m) { |
| // for (String s in [!m!]) { |
| // print(s); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the expression with one that produces an iterable value: |
| // |
| // ```dart |
| // void f(Map<String, String> m) { |
| // for (String s in m.values) { |
| // print(s); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode FOR_IN_OF_INVALID_TYPE = |
| CompileTimeErrorCode('FOR_IN_OF_INVALID_TYPE', |
| "The type '{0}' used in the 'for' loop must implement {1}.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the loop variable declared in a |
| // for-in loop is declared to be a `const`. The variable can't be a `const` |
| // because the value can't be computed at compile time. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the loop variable `x` |
| // is declared to be a `const`: |
| // |
| // ```dart |
| // void f() { |
| // for ([!const!] x in [0, 1, 2]) { |
| // print(x); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's a type annotation, then remove the `const` modifier from the |
| // declaration. |
| // |
| // If there's no type, then replace the `const` modifier with `final`, `var`, |
| // or a type annotation: |
| // |
| // ```dart |
| // void f() { |
| // for (final x in [0, 1, 2]) { |
| // print(x); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode FOR_IN_WITH_CONST_VARIABLE = |
| CompileTimeErrorCode('FOR_IN_WITH_CONST_VARIABLE', |
| "A for-in loop variable can't be a 'const'.", |
| correction: "Try removing the 'const' modifier from the variable, or " |
| "use a different variable.", |
| hasPublishedDocs: true); |
| |
| /** |
| * It is a compile-time error if a generic function type is used as a bound |
| * for a formal type parameter of a class or a function. |
| */ |
| static const CompileTimeErrorCode GENERIC_FUNCTION_TYPE_CANNOT_BE_BOUND = |
| CompileTimeErrorCode('GENERIC_FUNCTION_TYPE_CANNOT_BE_BOUND', |
| "Generic function types can't be used as type parameter bounds", |
| correction: "Try making the free variable in the function type part " |
| "of the larger declaration signature"); |
| |
| /** |
| * It is a compile-time error if a generic function type is used as an actual |
| * type argument. |
| */ |
| static const CompileTimeErrorCode |
| GENERIC_FUNCTION_TYPE_CANNOT_BE_TYPE_ARGUMENT = CompileTimeErrorCode( |
| 'GENERIC_FUNCTION_TYPE_CANNOT_BE_TYPE_ARGUMENT', |
| "A generic function type can't be a type argument.", |
| correction: "Try removing type parameters from the generic function " |
| "type, or using 'dynamic' as the type argument here."); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| GENERIC_METHOD_TYPE_INSTANTIATION_ON_DYNAMIC = CompileTimeErrorCode( |
| 'GENERIC_METHOD_TYPE_INSTANTIATION_ON_DYNAMIC', |
| "A method tearoff on a target whose type is 'dynamic' can't have type " |
| "arguments.", |
| correction: |
| "Specify the type of the target, or remove the type arguments from the " |
| "method tearoff.", |
| ); |
| |
| /** |
| * 10.3 Setters: It is a compile-time error if a class has a setter named |
| * `v=` with argument type `T` and a getter named `v` with return type `S`, |
| * and `S` may not be assigned to `T`. |
| * |
| * Parameters: |
| * 0: the name of the getter |
| * 1: the type of the getter |
| * 2: the type of the setter |
| * 3: the name of the setter |
| */ |
| static const CompileTimeErrorCode GETTER_NOT_ASSIGNABLE_SETTER_TYPES = |
| CompileTimeErrorCode( |
| 'GETTER_NOT_ASSIGNABLE_SETTER_TYPES', |
| "The return type of getter '{0}' is '{1}' which isn't assignable " |
| "to the type '{2}' of its setter '{3}'.", |
| correction: "Try changing the types so that they are compatible."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the getter |
| * 1: the type of the getter |
| * 2: the type of the setter |
| * 3: the name of the setter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the return type of a getter |
| // isn't a subtype of the type of the parameter of a setter with the same |
| // name. |
| // |
| // The subtype relationship is a requirement whether the getter and setter are |
| // in the same class or whether one of them is in a superclass of the other. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the return type of the |
| // getter `x` is `num`, the parameter type of the setter `x` is `int`, and |
| // `num` isn't a subtype of `int`: |
| // |
| // ```dart |
| // class C { |
| // num get [!x!] => 0; |
| // |
| // set x(int y) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the getter is correct, then change the type of the setter: |
| // |
| // ```dart |
| // class C { |
| // num get x => 0; |
| // |
| // set x(num y) {} |
| // } |
| // ``` |
| // |
| // If the type of the setter is correct, then change the type of the getter: |
| // |
| // ```dart |
| // class C { |
| // int get x => 0; |
| // |
| // set x(int y) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode GETTER_NOT_SUBTYPE_SETTER_TYPES = |
| CompileTimeErrorCode( |
| 'GETTER_NOT_SUBTYPE_SETTER_TYPES', |
| "The return type of getter '{0}' is '{1}' which isn't a subtype " |
| "of the type '{2}' of its setter '{3}'.", |
| correction: "Try changing the types so that they are compatible.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode IF_ELEMENT_CONDITION_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'IF_ELEMENT_CONDITION_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as values in " |
| "an if condition inside a const collection literal.", |
| correction: "Try making the deferred import non-deferred."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a function has the |
| // `async*` modifier even though the return type of the function isn't either |
| // `Stream` or a supertype of `Stream`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the |
| // function `f` has the 'async*' modifier even though the return type `int` |
| // isn't a supertype of `Stream`: |
| // |
| // ```dart |
| // [!int!] f() async* {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function should be asynchronous, then change the return type to be |
| // either `Stream` or a supertype of `Stream`: |
| // |
| // ```dart |
| // Stream<int> f() async* {} |
| // ``` |
| // |
| // If the function should be synchronous, then remove the `async*` modifier: |
| // |
| // ```dart |
| // int f() => 0; |
| // ``` |
| static const CompileTimeErrorCode ILLEGAL_ASYNC_GENERATOR_RETURN_TYPE = |
| CompileTimeErrorCode( |
| 'ILLEGAL_ASYNC_GENERATOR_RETURN_TYPE', |
| "Functions marked 'async*' must have a return type that is a " |
| "supertype of 'Stream<T>' for some type 'T'.", |
| correction: "Try fixing the return type of the function, or " |
| "removing the modifier 'async*' from the function body.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a function has the |
| // `async` modifier even though the return type of the function isn't |
| // assignable to `Future`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the |
| // function `f` has the `async` modifier even though the return type isn't |
| // assignable to `Future`: |
| // |
| // ```dart |
| // [!int!] f() async { |
| // return 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function should be asynchronous, then change the return type to be |
| // assignable to `Future`: |
| // |
| // ```dart |
| // Future<int> f() async { |
| // return 0; |
| // } |
| // ``` |
| // |
| // If the function should be synchronous, then remove the `async` modifier: |
| // |
| // ```dart |
| // int f() => 0; |
| // ``` |
| static const CompileTimeErrorCode ILLEGAL_ASYNC_RETURN_TYPE = |
| CompileTimeErrorCode( |
| 'ILLEGAL_ASYNC_RETURN_TYPE', |
| "Functions marked 'async' must have a return type assignable to " |
| "'Future'.", |
| correction: "Try fixing the return type of the function, or " |
| "removing the modifier 'async' from the function body.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a function has the |
| // `sync*` modifier even though the return type of the function isn't either |
| // `Iterable` or a supertype of `Iterable`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the |
| // function `f` has the 'sync*' modifier even though the return type `int` |
| // isn't a supertype of `Iterable`: |
| // |
| // ```dart |
| // [!int!] f() sync* {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function should return an iterable, then change the return type to |
| // be either `Iterable` or a supertype of `Iterable`: |
| // |
| // ```dart |
| // Iterable<int> f() sync* {} |
| // ``` |
| // |
| // If the function should return a single value, then remove the `sync*` |
| // modifier: |
| // |
| // ```dart |
| // int f() => 0; |
| // ``` |
| static const CompileTimeErrorCode ILLEGAL_SYNC_GENERATOR_RETURN_TYPE = |
| CompileTimeErrorCode( |
| 'ILLEGAL_SYNC_GENERATOR_RETURN_TYPE', |
| "Functions marked 'sync*' must have a return type that is a " |
| "supertype of 'Iterable<T>' for some type 'T'.", |
| correction: "Try fixing the return type of the function, or " |
| "removing the modifier 'sync*' from the function body.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode IMPLEMENTS_DEFERRED_CLASS = |
| CompileTimeErrorCode('SUBTYPE_OF_DEFERRED_CLASS', |
| "Classes and mixins can't implement deferred classes.", |
| correction: "Try specifying a different interface, " |
| "removing the class from the list, or " |
| "changing the import to not be deferred.", |
| hasPublishedDocs: true, |
| uniqueName: 'IMPLEMENTS_DEFERRED_CLASS'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the disallowed type |
| */ |
| static const CompileTimeErrorCode IMPLEMENTS_DISALLOWED_CLASS = |
| CompileTimeErrorCode( |
| 'SUBTYPE_OF_DISALLOWED_TYPE', |
| "Classes and mixins can't implement '{0}'.", |
| correction: "Try specifying a different interface, or " |
| "remove the class from the list.", |
| hasPublishedDocs: true, |
| uniqueName: 'IMPLEMENTS_DISALLOWED_CLASS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the interface that was not found |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name used in the `implements` |
| // clause of a class or mixin declaration is defined to be something other |
| // than a class or mixin. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is a variable |
| // rather than a class or mixin: |
| // |
| // ```dart |
| // var x; |
| // class C implements [!x!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the name is the name of an existing class or mixin that's already being |
| // imported, then add a prefix to the import so that the local definition of |
| // the name doesn't shadow the imported name. |
| // |
| // If the name is the name of an existing class or mixin that isn't being |
| // imported, then add an import, with a prefix, for the library in which it’s |
| // declared. |
| // |
| // Otherwise, either replace the name in the `implements` clause with the name |
| // of an existing class or mixin, or remove the name from the `implements` |
| // clause. |
| static const CompileTimeErrorCode IMPLEMENTS_NON_CLASS = CompileTimeErrorCode( |
| 'IMPLEMENTS_NON_CLASS', |
| "Classes and mixins can only implement other classes and mixins.", |
| correction: |
| "Try specifying a class or mixin, or remove the name from the " |
| "list.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the interface that is implemented more than once |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a single class is specified more |
| // than once in an `implements` clause. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `A` is in the list |
| // twice: |
| // |
| // ```dart |
| // class A {} |
| // class B implements A, [!A!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove all except one occurrence of the class name: |
| // |
| // ```dart |
| // class A {} |
| // class B implements A {} |
| // ``` |
| static const CompileTimeErrorCode IMPLEMENTS_REPEATED = CompileTimeErrorCode( |
| 'IMPLEMENTS_REPEATED', "'{0}' can only be implemented once.", |
| correction: "Try removing all but one occurrence of the class name.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class that appears in both "extends" and "implements" |
| * clauses |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when one class is listed in both the |
| // `extends` and `implements` clauses of another class. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `A` is used |
| // in both the `extends` and `implements` clauses for the class `B`: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B extends A implements [!A!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want to inherit the implementation from the class, then remove the |
| // class from the `implements` clause: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B extends A {} |
| // ``` |
| // |
| // If you don't want to inherit the implementation from the class, then remove |
| // the `extends` clause: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B implements A {} |
| // ``` |
| static const CompileTimeErrorCode IMPLEMENTS_SUPER_CLASS = |
| CompileTimeErrorCode('IMPLEMENTS_SUPER_CLASS', |
| "'{0}' can't be used in both the 'extends' and 'implements' clauses.", |
| correction: "Try removing one of the occurrences.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| IMPLEMENTS_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'SUPERTYPE_EXPANDS_TO_TYPE_PARAMETER', |
| "A type alias that expands to a type parameter can't be implemented.", |
| correction: "Try specifying a class or mixin, or removing the list.", |
| hasPublishedDocs: true, |
| uniqueName: 'IMPLEMENTS_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the instance member |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a reference to an |
| // instance member in a constructor's initializer list. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `defaultX` is an |
| // instance member: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C() : x = [!defaultX!]; |
| // |
| // int get defaultX => 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the member can be made static, then do so: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C() : x = defaultX; |
| // |
| // static int get defaultX => 0; |
| // } |
| // ``` |
| // |
| // If not, then replace the reference in the initializer with a different |
| // expression that doesn't use an instance member: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C() : x = 0; |
| // |
| // int get defaultX => 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode IMPLICIT_THIS_REFERENCE_IN_INITIALIZER = |
| CompileTimeErrorCode('IMPLICIT_THIS_REFERENCE_IN_INITIALIZER', |
| "The instance member '{0}' can't be accessed in an initializer.", |
| correction: |
| 'Try replacing the reference to the instance member with a ' |
| 'different expression', |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the uri pointing to a library |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds an import whose `dart:` |
| // URI references an internal library. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `_interceptors` is an |
| // internal library: |
| // |
| // ```dart |
| // import [!'dart:_interceptors'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the import directive. |
| static const CompileTimeErrorCode IMPORT_INTERNAL_LIBRARY = |
| CompileTimeErrorCode('IMPORT_INTERNAL_LIBRARY', |
| "The library '{0}' is internal and can't be imported.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 14.1 Imports: It is a compile-time error if the specified URI of an |
| * immediate import does not refer to a library declaration. |
| * |
| * Parameters: |
| * 0: the uri pointing to a non-library declaration |
| */ |
| static const CompileTimeErrorCode IMPORT_OF_NON_LIBRARY = |
| CompileTimeErrorCode('IMPORT_OF_NON_LIBRARY', |
| "The imported library '{0}' can't have a part-of directive.", |
| correction: "Try importing the library that the part is a part of."); |
| |
| /** |
| * 13.9 Switch: It is a compile-time error if values of the expressions |
| * <i>e<sub>k</sub></i> are not instances of the same class <i>C</i>, for all |
| * <i>1 <= k <= n</i>. |
| * |
| * Parameters: |
| * 0: the expression source code that is the unexpected type |
| * 1: the name of the expected type |
| */ |
| static const CompileTimeErrorCode INCONSISTENT_CASE_EXPRESSION_TYPES = |
| CompileTimeErrorCode('INCONSISTENT_CASE_EXPRESSION_TYPES', |
| "Case expressions must have the same types, '{0}' isn't a '{1}'."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the instance member with inconsistent inheritance. |
| * 1: the list of all inherited signatures for this member. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class inherits two or more |
| // conflicting signatures for a member and doesn't provide an implementation |
| // that satisfies all the inherited signatures. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `C` is inheriting the |
| // declaration of `m` from `A`, and that implementation isn't consistent with |
| // the signature of `m` that's inherited from `B`: |
| // |
| // ```dart |
| // %language=2.9 |
| // class A { |
| // void m({int a}) {} |
| // } |
| // |
| // class B { |
| // void m({int b}) {} |
| // } |
| // |
| // class [!C!] extends A implements B { |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add an implementation of the method that satisfies all the inherited |
| // signatures: |
| // |
| // ```dart |
| // %language=2.9 |
| // class A { |
| // void m({int a}) {} |
| // } |
| // |
| // class B { |
| // void m({int b}) {} |
| // } |
| // |
| // class C extends A implements B { |
| // void m({int a, int b}) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode INCONSISTENT_INHERITANCE = |
| CompileTimeErrorCode('INCONSISTENT_INHERITANCE', |
| "Superinterfaces don't have a valid override for '{0}': {1}.", |
| correction: |
| "Try adding an explicit override that is consistent with all " |
| "of the inherited members.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 11.1.1 Inheritance and Overriding. Let `I` be the implicit interface of a |
| * class `C` declared in library `L`. `I` inherits all members of |
| * `inherited(I, L)` and `I` overrides `m'` if `m' ∈ overrides(I, L)`. It is |
| * a compile-time error if `m` is a method and `m'` is a getter, or if `m` |
| * is a getter and `m'` is a method. |
| * |
| * Parameters: |
| * 0: the name of the the instance member with inconsistent inheritance. |
| * 1: the name of the superinterface that declares the name as a getter. |
| * 2: the name of the superinterface that declares the name as a method. |
| */ |
| static const CompileTimeErrorCode INCONSISTENT_INHERITANCE_GETTER_AND_METHOD = |
| CompileTimeErrorCode( |
| 'INCONSISTENT_INHERITANCE_GETTER_AND_METHOD', |
| "'{0}' is inherited as a getter (from '{1}') and also a " |
| "method (from '{2}').", |
| correction: |
| "Try adjusting the supertypes of this class to remove the " |
| "inconsistency."); |
| |
| /** |
| * It is a compile-time error if a part file has a different language version |
| * override than its library. |
| * |
| * https://github.com/dart-lang/language/blob/master/accepted/ |
| * future-releases/language-versioning/feature-specification.md |
| * #individual-library-language-version-override |
| */ |
| static const CompileTimeErrorCode INCONSISTENT_LANGUAGE_VERSION_OVERRIDE = |
| CompileTimeErrorCode( |
| 'INCONSISTENT_LANGUAGE_VERSION_OVERRIDE', |
| "Parts must have exactly the same language version override as " |
| "the library."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the initializing formal that is not an instance variable in |
| * the immediately enclosing class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor initializes a |
| // field that isn't declared in the class containing the constructor. |
| // Constructors can't initialize fields that aren't declared and fields that |
| // are inherited from superclasses. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the initializer is |
| // initializing `x`, but `x` isn't a field in the class: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C() : [!x = 0!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If a different field should be initialized, then change the name to the |
| // name of the field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C() : y = 0; |
| // } |
| // ``` |
| // |
| // If the field must be declared, then add a declaration: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int x; |
| // int y; |
| // |
| // C() : x = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode INITIALIZER_FOR_NON_EXISTENT_FIELD = |
| CompileTimeErrorCode('INITIALIZER_FOR_NON_EXISTENT_FIELD', |
| "'{0}' isn't a field in the enclosing class.", |
| correction: "Try correcting the name to match an existing field, or " |
| "defining a field named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the initializing formal that is a static variable in the |
| * immediately enclosing class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a static field is initialized in |
| // a constructor using either a field formal parameter or an assignment in the |
| // initializer list. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the static field `a` is |
| // being initialized by the field formal parameter `this.a`: |
| // |
| // ```dart |
| // class C { |
| // static int? a; |
| // C([!this.a!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field should be an instance field, then remove the keyword `static`: |
| // |
| // ```dart |
| // class C { |
| // int? a; |
| // C(this.a); |
| // } |
| // ``` |
| // |
| // If you intended to initialize an instance field and typed the wrong name, |
| // then correct the name of the field being initialized: |
| // |
| // ```dart |
| // class C { |
| // static int? a; |
| // int? b; |
| // C(this.b); |
| // } |
| // ``` |
| // |
| // If you really want to initialize the static field, then move the |
| // initialization into the constructor body: |
| // |
| // ```dart |
| // class C { |
| // static int? a; |
| // C(int? c) { |
| // a = c; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode INITIALIZER_FOR_STATIC_FIELD = |
| CompileTimeErrorCode( |
| 'INITIALIZER_FOR_STATIC_FIELD', |
| "'{0}' is a static field in the enclosing class. Fields initialized " |
| "in a constructor can't be static.", |
| correction: "Try removing the initialization.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the initializing formal that is not an instance variable in |
| * the immediately enclosing class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a field formal parameter is |
| // found in a constructor in a class that doesn't declare the field being |
| // initialized. Constructors can't initialize fields that aren't declared and |
| // fields that are inherited from superclasses. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the field `x` isn't |
| // defined: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C([!this.x!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field name was wrong, then change it to the name of an existing |
| // field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C(this.y); |
| // } |
| // ``` |
| // |
| // If the field name is correct but hasn't yet been defined, then declare the |
| // field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int x; |
| // int y; |
| // |
| // C(this.x); |
| // } |
| // ``` |
| // |
| // If the parameter is needed but shouldn't initialize a field, then convert |
| // it to a normal parameter and use it: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C(int x) : y = x * 2; |
| // } |
| // ``` |
| // |
| // If the parameter isn't needed, then remove it: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int y; |
| // |
| // C(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode INITIALIZING_FORMAL_FOR_NON_EXISTENT_FIELD = |
| CompileTimeErrorCode('INITIALIZING_FORMAL_FOR_NON_EXISTENT_FIELD', |
| "'{0}' isn't a field in the enclosing class.", |
| correction: "Try correcting the name to match an existing field, or " |
| "defining a field named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the static member |
| * 1: the kind of the static member (field, getter, setter, or method) |
| * 2: the name of the defining class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an access operator is used to |
| // access a static member through an instance of the class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `zero` is a static |
| // field, but it’s being accessed as if it were an instance field: |
| // |
| // ```dart |
| // void f(C c) { |
| // c.[!zero!]; |
| // } |
| // |
| // class C { |
| // static int zero = 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use the class to access the static member: |
| // |
| // ```dart |
| // void f(C c) { |
| // C.zero; |
| // } |
| // |
| // class C { |
| // static int zero = 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode INSTANCE_ACCESS_TO_STATIC_MEMBER = |
| CompileTimeErrorCode('INSTANCE_ACCESS_TO_STATIC_MEMBER', |
| "Static {1} '{0}' can't be accessed through an instance.", |
| correction: "Try using the class '{2}' to access the {1}.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a factory constructor contains |
| // an unqualified reference to an instance member. In a generative |
| // constructor, the instance of the class is created and initialized before |
| // the body of the constructor is executed, so the instance can be bound to |
| // `this` and accessed just like it would be in an instance method. But, in a |
| // factory constructor, the instance isn't created before executing the body, |
| // so `this` can't be used to reference it. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` isn't in scope in |
| // the factory constructor: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // factory C() { |
| // return C._([!x!]); |
| // } |
| // C._(this.x); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rewrite the code so that it doesn't reference the instance member: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // factory C() { |
| // return C._(0); |
| // } |
| // C._(this.x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode INSTANCE_MEMBER_ACCESS_FROM_FACTORY = |
| CompileTimeErrorCode('INSTANCE_MEMBER_ACCESS_FROM_FACTORY', |
| "Instance members can't be accessed from a factory constructor.", |
| correction: "Try removing the reference to the instance member.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a static method contains an |
| // unqualified reference to an instance member. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the instance field `x` |
| // is being referenced in a static method: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int x; |
| // |
| // static int m() { |
| // return [!x!]; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the method must reference the instance member, then it can't be static, |
| // so remove the keyword: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int x; |
| // |
| // int m() { |
| // return x; |
| // } |
| // } |
| // ``` |
| // |
| // If the method can't be made an instance method, then add a parameter so |
| // that an instance of the class can be passed in: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // int x; |
| // |
| // static int m(C c) { |
| // return c.x; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode INSTANCE_MEMBER_ACCESS_FROM_STATIC = |
| CompileTimeErrorCode('INSTANCE_MEMBER_ACCESS_FROM_STATIC', |
| "Instance members can't be accessed from a static method.", |
| correction: "Try removing the reference to the instance member, or " |
| "removing the keyword 'static' from the method.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a constructor |
| // invocation and the constructor is declared in an abstract class. Even |
| // though you can't create an instance of an abstract class, abstract classes |
| // can declare constructors that can be invoked by subclasses. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `C` is an abstract |
| // class: |
| // |
| // ```dart |
| // abstract class C {} |
| // |
| // var c = new [!C!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's a concrete subclass of the abstract class that can be used, then |
| // create an instance of the concrete subclass. |
| static const CompileTimeErrorCode INSTANTIATE_ABSTRACT_CLASS = |
| CompileTimeErrorCode('INSTANTIATE_ABSTRACT_CLASS', |
| "Abstract classes can't be instantiated.", |
| correction: "Try creating an instance of a concrete subtype.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an enum is instantiated. It's |
| // invalid to create an instance of an enum by invoking a constructor; only |
| // the instances named in the declaration of the enum can exist. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the enum `E` is being |
| // instantiated: |
| // |
| // ```dart |
| // enum E {a} |
| // |
| // var e = [!E!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intend to use an instance of the enum, then reference one of the |
| // constants defined in the enum: |
| // |
| // ```dart |
| // enum E {a} |
| // |
| // var e = E.a; |
| // ``` |
| // |
| // If you intend to use an instance of a class, then use the name of that class in place of the name of the enum. |
| static const CompileTimeErrorCode INSTANTIATE_ENUM = CompileTimeErrorCode( |
| 'INSTANTIATE_ENUM', "Enums can't be instantiated.", |
| correction: "Try using one of the defined constants.", |
| hasPublishedDocs: true); |
| |
| /** |
| * It is a compile-time error for an instance creation `C<T1, .. Tk>(...)` or |
| * `C<T1, .. Tk>.name()` (where `k` may be zero, which means that the type |
| * argument list is absent) if `C` denotes a type alias that expands to a |
| * type variable. |
| */ |
| static const CompileTimeErrorCode |
| INSTANTIATE_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'INSTANTIATE_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER', |
| "Type aliases that expand to a type parameter can't be instantiated.", |
| correction: "Try replacing it with a class."); |
| |
| /** |
| * Parameters: |
| * 0: the lexeme of the integer |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an integer literal is being |
| // implicitly converted to a double, but can't be represented as a 64-bit |
| // double without overflow or loss of precision. Integer literals are |
| // implicitly converted to a double if the context requires the type `double`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the integer value |
| // `9223372036854775807` can't be represented exactly as a double: |
| // |
| // ```dart |
| // double x = [!9223372036854775807!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to use the exact value, then use the class `BigInt` to |
| // represent the value: |
| // |
| // ```dart |
| // var x = BigInt.parse('9223372036854775807'); |
| // ``` |
| // |
| // If you need to use a double, then change the value to one that can be |
| // represented exactly: |
| // |
| // ```dart |
| // double x = 9223372036854775808; |
| // ``` |
| static const CompileTimeErrorCode INTEGER_LITERAL_IMPRECISE_AS_DOUBLE = |
| CompileTimeErrorCode( |
| 'INTEGER_LITERAL_IMPRECISE_AS_DOUBLE', |
| "The integer literal is being used as a double, but can't be " |
| "represented as a 64-bit double without overflow or loss of " |
| "precision: '{0}'.", |
| correction: |
| "Try using the class 'BigInt', or switch to the closest valid " |
| "double: '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an integer literal has a value |
| // that is too large (positive) or too small (negative) to be represented in a |
| // 64-bit word. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the value can't be |
| // represented in 64 bits: |
| // |
| // ```dart |
| // var x = [!9223372036854775810!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to represent the current value, then wrap it in an instance of |
| // the class `BigInt`: |
| // |
| // ```dart |
| // var x = BigInt.parse('9223372036854775810'); |
| // ``` |
| static const CompileTimeErrorCode INTEGER_LITERAL_OUT_OF_RANGE = |
| CompileTimeErrorCode('INTEGER_LITERAL_OUT_OF_RANGE', |
| "The integer literal {0} can't be represented in 64 bits.", |
| correction: |
| "Try using the 'BigInt' class if you need an integer larger than " |
| "9,223,372,036,854,775,807 or less than " |
| "-9,223,372,036,854,775,808.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an annotation is found that is |
| // using something that is neither a variable marked as `const` or the |
| // invocation of a `const` constructor. |
| // |
| // Getters can't be used as annotations. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the variable `v` isn't |
| // a `const` variable: |
| // |
| // ```dart |
| // var v = 0; |
| // |
| // [!@v!] |
| // void f() { |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `f` isn't a variable: |
| // |
| // ```dart |
| // [!@f!] |
| // void f() { |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `f` isn't a |
| // constructor: |
| // |
| // ```dart |
| // [!@f()!] |
| // void f() { |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `g` is a getter: |
| // |
| // ```dart |
| // [!@g!] |
| // int get g => 0; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the annotation is referencing a variable that isn't a `const` |
| // constructor, add the keyword `const` to the variable's declaration: |
| // |
| // ```dart |
| // const v = 0; |
| // |
| // @v |
| // void f() { |
| // } |
| // ``` |
| // |
| // If the annotation isn't referencing a variable, then remove it: |
| // |
| // ```dart |
| // int v = 0; |
| // |
| // void f() { |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_ANNOTATION = CompileTimeErrorCode( |
| 'INVALID_ANNOTATION', |
| "Annotation must be either a const variable reference or const " |
| "constructor invocation.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode |
| INVALID_ANNOTATION_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'INVALID_ANNOTATION_CONSTANT_VALUE_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used in annotations.", |
| correction: "Try moving the constant from the deferred library," |
| " or removing 'deferred' from the import."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constant from a library that |
| // is imported using a deferred import is used as an annotation. Annotations |
| // are evaluated at compile time, and constants from deferred libraries aren't |
| // available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constant `pi` is |
| // being used as an annotation when the library `dart:math` is imported as |
| // `deferred`: |
| // |
| // ```dart |
| // import 'dart:math' deferred as math; |
| // |
| // @[!math.pi!] |
| // void f() {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to reference the constant as an annotation, then remove the |
| // keyword `deferred` from the import: |
| // |
| // ```dart |
| // import 'dart:math' as math; |
| // |
| // @math.pi |
| // void f() {} |
| // ``` |
| // |
| // If you can use a different constant as an annotation, then replace the |
| // annotation with a different constant: |
| // |
| // ```dart |
| // @deprecated |
| // void f() {} |
| // ``` |
| static const CompileTimeErrorCode INVALID_ANNOTATION_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'INVALID_ANNOTATION_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as " |
| "annotations.", |
| correction: "Try removing the annotation, or " |
| "changing the import to not be deferred.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the right hand side type |
| * 1: the name of the left hand side type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the static type of an expression |
| // that is assigned to a variable isn't assignable to the type of the |
| // variable. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the type of the |
| // initializer (`int`) isn't assignable to the type of the variable |
| // (`String`): |
| // |
| // ```dart |
| // int i = 0; |
| // String s = [!i!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value being assigned is always assignable at runtime, even though |
| // the static types don't reflect that, then add an explicit cast. |
| // |
| // Otherwise, change the value being assigned so that it has the expected |
| // type. In the previous example, this might look like: |
| // |
| // ```dart |
| // int i = 0; |
| // String s = i.toString(); |
| // ``` |
| // |
| // If you can’t change the value, then change the type of the variable to be |
| // compatible with the type of the value being assigned: |
| // |
| // ```dart |
| // int i = 0; |
| // int s = i; |
| // ``` |
| static const CompileTimeErrorCode INVALID_ASSIGNMENT = CompileTimeErrorCode( |
| 'INVALID_ASSIGNMENT', |
| "A value of type '{0}' can't be assigned to a variable of type " |
| "'{1}'.", |
| correction: "Try changing the type of the variable, or " |
| "casting the right-hand type to '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the function |
| * 1: the expected function type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_FUNCTION = CompileTimeErrorCode( |
| 'INVALID_CAST_FUNCTION', |
| "The function '{0}' has type '{1}' that isn't of expected type " |
| "'{2}'. This means its parameter or return type doesn't match what " |
| "is expected."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the torn-off function expression |
| * 1: the expected function type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_FUNCTION_EXPR = |
| CompileTimeErrorCode( |
| 'INVALID_CAST_FUNCTION_EXPR', |
| "The function expression type '{0}' isn't of type '{1}'. " |
| "This means its parameter or return type doesn't match what is " |
| "expected. Consider changing parameter type(s) or the returned " |
| "type(s)."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the literal |
| * 1: the expected type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_LITERAL = CompileTimeErrorCode( |
| 'INVALID_CAST_LITERAL', |
| "The literal '{0}' with type '{1}' isn't of expected type '{2}'."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the list literal |
| * 1: the expected type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_LITERAL_LIST = |
| CompileTimeErrorCode( |
| 'INVALID_CAST_LITERAL_LIST', |
| "The list literal type '{0}' isn't of expected type '{1}'. The " |
| "list's type can be changed with an explicit generic type " |
| "argument or by changing the element types."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the map literal |
| * 1: the expected type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_LITERAL_MAP = |
| CompileTimeErrorCode( |
| 'INVALID_CAST_LITERAL_MAP', |
| "The map literal type '{0}' isn't of expected type '{1}'. The maps's " |
| "type can be changed with an explicit generic type arguments or " |
| "by changing the key and value types."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the set literal |
| * 1: the expected type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_LITERAL_SET = |
| CompileTimeErrorCode( |
| 'INVALID_CAST_LITERAL_SET', |
| "The set literal type '{0}' isn't of expected type '{1}'. The set's " |
| "type can be changed with an explicit generic type argument or " |
| "by changing the element types."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the torn-off method |
| * 1: the expected function type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_METHOD = CompileTimeErrorCode( |
| 'INVALID_CAST_METHOD', |
| "The method tear-off '{0}' has type '{1}' that isn't of expected type " |
| "'{2}'. This means its parameter or return type doesn't match what " |
| "is expected."); |
| |
| /** |
| * Parameters: |
| * 0: the type of the instantiated object |
| * 1: the expected type |
| */ |
| static const CompileTimeErrorCode INVALID_CAST_NEW_EXPR = CompileTimeErrorCode( |
| 'INVALID_CAST_NEW_EXPR', |
| "The constructor returns type '{0}' that isn't of expected type '{1}'."); |
| |
| /** |
| * TODO(brianwilkerson) Remove this when we have decided on how to report |
| * errors in compile-time constants. Until then, this acts as a placeholder |
| * for more informative errors. |
| * |
| * See TODOs in ConstantVisitor |
| */ |
| static const CompileTimeErrorCode INVALID_CONSTANT = |
| CompileTimeErrorCode('INVALID_CONSTANT', "Invalid constant value."); |
| |
| /** |
| * 7.6 Constructors: It is a compile-time error if the name of a constructor |
| * is not a constructor name. |
| */ |
| static const CompileTimeErrorCode INVALID_CONSTRUCTOR_NAME = |
| CompileTimeErrorCode( |
| 'INVALID_CONSTRUCTOR_NAME', "Invalid constructor name."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override doesn't |
| // have exactly one argument. The argument is the expression used to compute |
| // the value of `this` within the extension method, so there must be one |
| // argument. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there are no arguments: |
| // |
| // ```dart |
| // extension E on String { |
| // String join(String other) => '$this $other'; |
| // } |
| // |
| // void f() { |
| // E[!()!].join('b'); |
| // } |
| // ``` |
| // |
| // And, the following code produces this diagnostic because there's more than |
| // one argument: |
| // |
| // ```dart |
| // extension E on String { |
| // String join(String other) => '$this $other'; |
| // } |
| // |
| // void f() { |
| // E[!('a', 'b')!].join('c'); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Provide one argument for the extension override: |
| // |
| // ```dart |
| // extension E on String { |
| // String join(String other) => '$this $other'; |
| // } |
| // |
| // void f() { |
| // E('a').join('b'); |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_EXTENSION_ARGUMENT_COUNT = |
| CompileTimeErrorCode( |
| 'INVALID_EXTENSION_ARGUMENT_COUNT', |
| "Extension overrides must have exactly one argument: " |
| "the value of 'this' in the extension method.", |
| correction: "Try specifying exactly one argument.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name of a factory |
| // constructor isn't the same as the name of the surrounding class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name of the factory |
| // constructor (`A`) isn't the same as the surrounding class (`C`): |
| // |
| // ```dart |
| // class A {} |
| // |
| // class C { |
| // factory [!A!]() => throw 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the factory returns an instance of the surrounding class, then rename |
| // the factory: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class C { |
| // factory C() => throw 0; |
| // } |
| // ``` |
| // |
| // If the factory returns an instance of a different class, then move the |
| // factory to that class: |
| // |
| // ```dart |
| // class A { |
| // factory A() => throw 0; |
| // } |
| // |
| // class C {} |
| // ``` |
| // |
| // If the factory returns an instance of a different class, but you can't |
| // modify that class or don't want to move the factory, then convert it to be |
| // a static method: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class C { |
| // static A a() => throw 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_FACTORY_NAME_NOT_A_CLASS = |
| CompileTimeErrorCode( |
| 'INVALID_FACTORY_NAME_NOT_A_CLASS', |
| "The name of a factory constructor must be the same as the name of " |
| "the immediately enclosing class.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the declared member that is not a valid override. |
| * 1: the name of the interface that declares the member. |
| * 2: the type of the declared member in the interface. |
| * 3. the name of the interface with the overridden member. |
| * 4. the type of the overridden member. |
| * |
| * These parameters must be kept in sync with those of |
| * [CompileTimeErrorCode.INVALID_OVERRIDE]. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when all of the following are true: |
| // |
| // - A class defines an abstract member. |
| // - There is a concrete implementation of that member in a superclass. |
| // - The concrete implementation isn't a valid implementation of the abstract |
| // method. |
| // |
| // The concrete implementation can be invalid because of incompatibilities in |
| // either the return type, the types of parameters, or the type variables. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the method `A.add` has |
| // a parameter of type `int`, and the overriding method `B.add` has a |
| // corresponding parameter of type `num`: |
| // |
| // ```dart |
| // class A { |
| // int add(int a) => a; |
| // } |
| // class [!B!] extends A { |
| // int add(num a); |
| // } |
| // ``` |
| // |
| // This is a problem because in an invocation of `B.add` like the following: |
| // |
| // ```dart |
| // void f(B b) { |
| // b.add(3.4); |
| // } |
| // ``` |
| // |
| // `B.add` is expecting to be able to take, for example, a `double`, but when |
| // the method `A.add` is executed (because it's the only concrete |
| // implementation of `add`), a runtime exception will be thrown because a |
| // `double` can't be assigned to a parameter of type `int`. |
| // |
| // #### Common fixes |
| // |
| // If the method in the subclass can conform to the implementation in the |
| // superclass, then change the declaration in the subclass (or remove it if |
| // it's the same): |
| // |
| // ```dart |
| // class A { |
| // int add(int a) => a; |
| // } |
| // class B extends A { |
| // int add(int a); |
| // } |
| // ``` |
| // |
| // If the method in the superclass can be generalized to be a valid |
| // implementation of the method in the subclass, then change the superclass |
| // method: |
| // |
| // ```dart |
| // class A { |
| // int add(num a) => a.floor(); |
| // } |
| // class B extends A { |
| // int add(num a); |
| // } |
| // ``` |
| // |
| // If neither the method in the superclass nor the method in the subclass can |
| // be changed, then provide a concrete implementation of the method in the |
| // subclass: |
| // |
| // ```dart |
| // class A { |
| // int add(int a) => a; |
| // } |
| // class B extends A { |
| // int add(num a) => a.floor(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_IMPLEMENTATION_OVERRIDE = |
| CompileTimeErrorCode( |
| 'INVALID_IMPLEMENTATION_OVERRIDE', |
| "'{1}.{0}' ('{2}') isn't a valid concrete implementation of " |
| "'{3}.{0}' ('{4}').", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a generic function type has a |
| // function-valued parameter that is written using the older inline function |
| // type syntax. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the parameter `f`, in |
| // the generic function type used to define `F`, uses the inline function |
| // type syntax: |
| // |
| // ```dart |
| // typedef F = int Function(int f[!(!]String s)); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use the generic function syntax for the parameter's type: |
| // |
| // ```dart |
| // typedef F = int Function(int Function(String)); |
| // ``` |
| static const CompileTimeErrorCode INVALID_INLINE_FUNCTION_TYPE = |
| CompileTimeErrorCode( |
| 'INVALID_INLINE_FUNCTION_TYPE', |
| "Inline function types can't be used for parameters in a generic " |
| "function type.", |
| correction: "Try using a generic function type " |
| "(returnType 'Function(' parameters ')').", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the invalid modifier |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a constructor is |
| // prefixed by one of the following modifiers: `async`, `async*`, or `sync*`. |
| // Constructor bodies must be synchronous. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the |
| // constructor for `C` is marked as being `async`: |
| // |
| // ```dart |
| // class C { |
| // C() [!async!] {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the constructor can be synchronous, then remove the modifier: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // } |
| // ``` |
| // |
| // If the constructor can't be synchronous, then use a static method to create |
| // the instance instead: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // static Future<C> c() async { |
| // return C(); |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_MODIFIER_ON_CONSTRUCTOR = |
| CompileTimeErrorCode('INVALID_MODIFIER_ON_CONSTRUCTOR', |
| "The modifier '{0}' can't be applied to the body of a constructor.", |
| correction: "Try removing the modifier.", hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the invalid modifier |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a setter is prefixed |
| // by one of the following modifiers: `async`, `async*`, or `sync*`. Setter |
| // bodies must be synchronous. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the setter |
| // `x` is marked as being `async`: |
| // |
| // ```dart |
| // class C { |
| // set x(int i) [!async!] {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the setter can be synchronous, then remove the modifier: |
| // |
| // ```dart |
| // class C { |
| // set x(int i) {} |
| // } |
| // ``` |
| // |
| // If the setter can't be synchronous, then use a method to set the value |
| // instead: |
| // |
| // ```dart |
| // class C { |
| // void x(int i) async {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_MODIFIER_ON_SETTER = |
| CompileTimeErrorCode('INVALID_MODIFIER_ON_SETTER', |
| "Setters can't use 'async', 'async*', or 'sync*'.", |
| correction: "Try removing the modifier.", hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the declared member that is not a valid override. |
| * 1: the name of the interface that declares the member. |
| * 2: the type of the declared member in the interface. |
| * 3. the name of the interface with the overridden member. |
| * 4. the type of the overridden member. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a member of a class is found |
| // that overrides a member from a supertype and the override isn't valid. An |
| // override is valid if all of these are true: |
| // * It allows all of the arguments allowed by the overridden member. |
| // * It doesn't require any arguments that aren't required by the overridden |
| // member. |
| // * The type of every parameter of the overridden member is assignable to the |
| // corresponding parameter of the override. |
| // * The return type of the override is assignable to the return type of the |
| // overridden member. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the type of the |
| // parameter `s` (`String`) isn't assignable to the type of the parameter `i` |
| // (`int`): |
| // |
| // ```dart |
| // class A { |
| // void m(int i) {} |
| // } |
| // |
| // class B extends A { |
| // void [!m!](String s) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the invalid method is intended to override the method from the |
| // superclass, then change it to conform: |
| // |
| // ```dart |
| // class A { |
| // void m(int i) {} |
| // } |
| // |
| // class B extends A { |
| // void m(int i) {} |
| // } |
| // ``` |
| // |
| // If it isn't intended to override the method from the superclass, then |
| // rename it: |
| // |
| // ```dart |
| // class A { |
| // void m(int i) {} |
| // } |
| // |
| // class B extends A { |
| // void m2(String s) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_OVERRIDE = CompileTimeErrorCode( |
| 'INVALID_OVERRIDE', |
| "'{1}.{0}' ('{2}') isn't a valid override of '{3}.{0}' ('{4}').", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when `this` is used outside of an |
| // instance method or a generative constructor. The reserved word `this` is |
| // only defined in the context of an instance method or a generative |
| // constructor. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `v` is a top-level |
| // variable: |
| // |
| // ```dart |
| // C f() => [!this!]; |
| // |
| // class C {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use a variable of the appropriate type in place of `this`, declaring it if |
| // necessary: |
| // |
| // ```dart |
| // C f(C c) => c; |
| // |
| // class C {} |
| // ``` |
| static const CompileTimeErrorCode INVALID_REFERENCE_TO_THIS = |
| CompileTimeErrorCode('INVALID_REFERENCE_TO_THIS', |
| "Invalid reference to 'this' expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the initializer list of a |
| // constructor contains an invocation of a constructor in the superclass, but |
| // the invocation isn't the last item in the initializer list. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the invocation of the |
| // superclass' constructor isn't the last item in the initializer list: |
| // |
| // ```dart |
| // class A { |
| // A(int x); |
| // } |
| // |
| // class B extends A { |
| // B(int x) : [!super!](x), assert(x >= 0); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Move the invocation of the superclass' constructor to the end of the |
| // initializer list: |
| // |
| // ```dart |
| // class A { |
| // A(int x); |
| // } |
| // |
| // class B extends A { |
| // B(int x) : assert(x >= 0), super(x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_SUPER_INVOCATION = |
| CompileTimeErrorCode('INVALID_SUPER_INVOCATION', |
| "The superclass call must be last in an initializer list: '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type parameter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type parameter is used as a |
| // type argument in a list, map, or set literal that is prefixed by `const`. |
| // This isn't allowed because the value of the type parameter (the actual type |
| // that will be used at runtime) can't be known at compile time. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type parameter `T` |
| // is being used as a type argument when creating a constant list: |
| // |
| // ```dart |
| // List<T> newList<T>() => const <[!T!]>[]; |
| // ``` |
| // |
| // The following code produces this diagnostic because the type parameter `T` |
| // is being used as a type argument when creating a constant map: |
| // |
| // ```dart |
| // Map<String, T> newSet<T>() => const <String, [!T!]>{}; |
| // ``` |
| // |
| // The following code produces this diagnostic because the type parameter `T` |
| // is being used as a type argument when creating a constant set: |
| // |
| // ```dart |
| // Set<T> newSet<T>() => const <[!T!]>{}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type that will be used for the type parameter can be known at |
| // compile time, then remove the type parameter: |
| // |
| // ```dart |
| // List<int> newList() => const <int>[]; |
| // ``` |
| // |
| // If the type that will be used for the type parameter can't be known until |
| // runtime, then remove the keyword `const`: |
| // |
| // ```dart |
| // List<T> newList<T>() => <T>[]; |
| // ``` |
| static const CompileTimeErrorCode INVALID_TYPE_ARGUMENT_IN_CONST_LIST = |
| CompileTimeErrorCode( |
| 'INVALID_TYPE_ARGUMENT_IN_CONST_LITERAL', |
| "Constant list literals can't include a type parameter as a type " |
| "argument, such as '{0}'.", |
| correction: "Try replacing the type parameter with a different type.", |
| hasPublishedDocs: true, |
| uniqueName: 'INVALID_TYPE_ARGUMENT_IN_CONST_LIST', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type parameter |
| */ |
| static const CompileTimeErrorCode INVALID_TYPE_ARGUMENT_IN_CONST_MAP = |
| CompileTimeErrorCode( |
| 'INVALID_TYPE_ARGUMENT_IN_CONST_LITERAL', |
| "Constant map literals can't include a type parameter as a type " |
| "argument, such as '{0}'.", |
| correction: "Try replacing the type parameter with a different type.", |
| hasPublishedDocs: true, |
| uniqueName: 'INVALID_TYPE_ARGUMENT_IN_CONST_MAP', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type parameter |
| */ |
| static const CompileTimeErrorCode INVALID_TYPE_ARGUMENT_IN_CONST_SET = |
| CompileTimeErrorCode( |
| 'INVALID_TYPE_ARGUMENT_IN_CONST_LITERAL', |
| "Constant set literals can't include a type parameter as a type " |
| "argument, such as '{0}'.", |
| correction: "Try replacing the type parameter with a different type.", |
| hasPublishedDocs: true, |
| uniqueName: 'INVALID_TYPE_ARGUMENT_IN_CONST_SET', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the URI that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a URI in a directive doesn't |
| // conform to the syntax of a valid URI. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `'#'` isn't a valid |
| // URI: |
| // |
| // ```dart |
| // import [!'#'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the invalid URI with a valid URI. |
| static const CompileTimeErrorCode INVALID_URI = CompileTimeErrorCode( |
| 'INVALID_URI', "Invalid URI syntax: '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * The 'covariant' keyword was found in an inappropriate location. |
| */ |
| static const CompileTimeErrorCode INVALID_USE_OF_COVARIANT = |
| CompileTimeErrorCode( |
| 'INVALID_USE_OF_COVARIANT', |
| "The 'covariant' keyword can only be used for parameters in instance " |
| "methods or before non-final instance fields.", |
| correction: "Try removing the 'covariant' keyword."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an expression whose value will |
| // always be `null` is dereferenced. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` will always be |
| // `null`: |
| // |
| // ```dart |
| // int f(Null x) { |
| // return [!x!].length; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value is allowed to be something other than `null`, then change the |
| // type of the expression: |
| // |
| // ```dart |
| // int f(String? x) { |
| // return x!.length; |
| // } |
| // ``` |
| static const CompileTimeErrorCode INVALID_USE_OF_NULL_VALUE = |
| CompileTimeErrorCode('INVALID_USE_OF_NULL_VALUE', |
| "An expression whose value is always 'null' can't be dereferenced.", |
| correction: "Try changing the type of the expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the extension |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is used to |
| // invoke a function but the extension doesn't declare a `call` method. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't define a `call` method: |
| // |
| // ```dart |
| // extension E on String {} |
| // |
| // void f() { |
| // [!E('')!](); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the extension is intended to define a `call` method, then declare it: |
| // |
| // ```dart |
| // extension E on String { |
| // int call() => 0; |
| // } |
| // |
| // void f() { |
| // E('')(); |
| // } |
| // ``` |
| // |
| // If the extended type defines a `call` method, then remove the extension |
| // override. |
| // |
| // If the `call` method isn't defined, then rewrite the code so that it |
| // doesn't invoke the `call` method. |
| static const CompileTimeErrorCode INVOCATION_OF_EXTENSION_WITHOUT_CALL = |
| CompileTimeErrorCode( |
| 'INVOCATION_OF_EXTENSION_WITHOUT_CALL', |
| "The extension '{0}' doesn't define a 'call' method so the override " |
| "can't be used in an invocation.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the identifier that is not a function type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a function invocation, |
| // but the name of the function being invoked is defined to be something other |
| // than a function. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `Binary` is the name of |
| // a function type, not a function: |
| // |
| // ```dart |
| // typedef Binary = int Function(int, int); |
| // |
| // int f() { |
| // return [!Binary!](1, 2); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the name with the name of a function. |
| static const CompileTimeErrorCode INVOCATION_OF_NON_FUNCTION = |
| CompileTimeErrorCode( |
| 'INVOCATION_OF_NON_FUNCTION', "'{0}' isn't a function.", |
| // TODO(brianwilkerson) Split this error code so that we can provide |
| // better error and correction messages. |
| correction: |
| "Try correcting the name to match an existing function, or " |
| "define a method or function named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a function invocation is found, |
| // but the name being referenced isn't the name of a function, or when the |
| // expression computing the function doesn't compute a function. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` isn't a function: |
| // |
| // ```dart |
| // int x = 0; |
| // |
| // int f() => x; |
| // |
| // var y = [!x!](); |
| // ``` |
| // |
| // The following code produces this diagnostic because `f()` doesn't return a |
| // function: |
| // |
| // ```dart |
| // int x = 0; |
| // |
| // int f() => x; |
| // |
| // var y = [!f()!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to invoke a function, then replace the code before the argument |
| // list with the name of a function or with an expression that computes a |
| // function: |
| // |
| // ```dart |
| // int x = 0; |
| // |
| // int f() => x; |
| // |
| // var y = f(); |
| // ``` |
| static const CompileTimeErrorCode INVOCATION_OF_NON_FUNCTION_EXPRESSION = |
| CompileTimeErrorCode( |
| 'INVOCATION_OF_NON_FUNCTION_EXPRESSION', |
| "The expression doesn't evaluate to a function, so it can't be " |
| "invoked.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the unresolvable label |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a `break` or `continue` |
| // statement references a label that is declared in a method or function |
| // containing the function in which the `break` or `continue` statement |
| // appears. The `break` and `continue` statements can't be used to transfer |
| // control outside the function that contains them. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the label `loop` is |
| // declared outside the local function `g`: |
| // |
| // ```dart |
| // void f() { |
| // loop: |
| // while (true) { |
| // void g() { |
| // break [!loop!]; |
| // } |
| // |
| // g(); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Try rewriting the code so that it isn't necessary to transfer control |
| // outside the local function, possibly by inlining the local function: |
| // |
| // ```dart |
| // void f() { |
| // loop: |
| // while (true) { |
| // break loop; |
| // } |
| // } |
| // ``` |
| // |
| // If that isn't possible, then try rewriting the local function so that a |
| // value returned by the function can be used to determine whether control is |
| // transferred: |
| // |
| // ```dart |
| // void f() { |
| // loop: |
| // while (true) { |
| // bool g() { |
| // return true; |
| // } |
| // |
| // if (g()) { |
| // break loop; |
| // } |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode LABEL_IN_OUTER_SCOPE = CompileTimeErrorCode( |
| 'LABEL_IN_OUTER_SCOPE', |
| "Can't reference label '{0}' declared in an outer method.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the unresolvable label |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a reference to a label |
| // that isn't defined in the scope of the `break` or `continue` statement that |
| // is referencing it. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the label `loop` isn't |
| // defined anywhere: |
| // |
| // ```dart |
| // void f() { |
| // for (int i = 0; i < 10; i++) { |
| // for (int j = 0; j < 10; j++) { |
| // break [!loop!]; |
| // } |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the label should be on the innermost enclosing `do`, `for`, `switch`, or |
| // `while` statement, then remove the label: |
| // |
| // ```dart |
| // void f() { |
| // for (int i = 0; i < 10; i++) { |
| // for (int j = 0; j < 10; j++) { |
| // break; |
| // } |
| // } |
| // } |
| // ``` |
| // |
| // If the label should be on some other statement, then add the label: |
| // |
| // ```dart |
| // void f() { |
| // loop: for (int i = 0; i < 10; i++) { |
| // for (int j = 0; j < 10; j++) { |
| // break loop; |
| // } |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode LABEL_UNDEFINED = CompileTimeErrorCode( |
| 'LABEL_UNDEFINED', "Can't reference an undefined label '{0}'.", |
| correction: "Try defining the label, or " |
| "correcting the name to match an existing label.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class that has at least one |
| // `const` constructor also has a field marked both `late` and `final`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `A` has a |
| // `const` constructor and the `final` field `f` is marked as `late`: |
| // |
| // ```dart |
| // class A { |
| // [!late!] final int f; |
| // |
| // const A(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field doesn't need to be marked `late`, then remove the `late` |
| // modifier from the field: |
| // |
| // ```dart |
| // class A { |
| // final int f = 0; |
| // |
| // const A(); |
| // } |
| // ``` |
| // |
| // If the field must be marked `late`, then remove the `const` modifier from |
| // the constructors: |
| // |
| // ```dart |
| // class A { |
| // late final int f; |
| // |
| // A(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode LATE_FINAL_FIELD_WITH_CONST_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'LATE_FINAL_FIELD_WITH_CONST_CONSTRUCTOR', |
| "Can't have a late final field in a class with a generative " |
| "const constructor.", |
| correction: "Try removing the 'late' modifier, or don't declare " |
| "'const' constructors.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the analyzer can prove that a |
| // local variable marked as both `late` and `final` was already assigned a |
| // value at the point where another assignment occurs. |
| // |
| // Because `final` variables can only be assigned once, subsequent assignments |
| // are guaranteed to fail, so they're flagged. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the `final` variable |
| // `v` is assigned a value in two places: |
| // |
| // ```dart |
| // int f() { |
| // late final int v; |
| // v = 0; |
| // [!v!] += 1; |
| // return v; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to be able to reassign the variable, then remove the `final` |
| // keyword: |
| // |
| // ```dart |
| // int f() { |
| // late int v; |
| // v = 0; |
| // v += 1; |
| // return v; |
| // } |
| // ``` |
| // |
| // If you don't need to reassign the variable, then remove all except the |
| // first of the assignments: |
| // |
| // ```dart |
| // int f() { |
| // late final int v; |
| // v = 0; |
| // return v; |
| // } |
| // ``` |
| static const CompileTimeErrorCode LATE_FINAL_LOCAL_ALREADY_ASSIGNED = |
| CompileTimeErrorCode('LATE_FINAL_LOCAL_ALREADY_ASSIGNED', |
| "The late final local variable is already assigned.", |
| correction: "Try removing the 'final' modifier, or don't reassign " |
| "the value.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the actual type of the list element |
| * 1: the expected type of the list element |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of an element in a list |
| // literal isn't assignable to the element type of the list. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `2.5` is a double, and |
| // the list can hold only integers: |
| // |
| // ```dart |
| // List<int> x = [1, [!2.5!], 3]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intended to add a different object to the list, then replace the |
| // element with an expression that computes the intended object: |
| // |
| // ```dart |
| // List<int> x = [1, 2, 3]; |
| // ``` |
| // |
| // If the object shouldn't be in the list, then remove the element: |
| // |
| // ```dart |
| // List<int> x = [1, 3]; |
| // ``` |
| // |
| // If the object being computed is correct, then widen the element type of the |
| // list to allow all of the different types of objects it needs to contain: |
| // |
| // ```dart |
| // List<num> x = [1, 2.5, 3]; |
| // ``` |
| static const CompileTimeErrorCode LIST_ELEMENT_TYPE_NOT_ASSIGNABLE = |
| CompileTimeErrorCode('LIST_ELEMENT_TYPE_NOT_ASSIGNABLE', |
| "The element type '{0}' can't be assigned to the list type '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the macro |
| * 1: the message |
| */ |
| static const CompileTimeErrorCode MACRO_EXECUTION_ERROR = |
| CompileTimeErrorCode( |
| 'MACRO_EXECUTION_ERROR', "Exception thrown by macro {0}: {1}"); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the first positional parameter |
| // of a function named `main` isn't a supertype of `List<String>`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `List<int>` isn't a |
| // supertype of `List<String>`: |
| // |
| // ```dart |
| // void main([!List<int>!] args) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function is an entry point, then change the type of the first |
| // positional parameter to be a supertype of `List<String>`: |
| // |
| // ```dart |
| // void main(List<String> args) {} |
| // ``` |
| // |
| // If the function isn't an entry point, then change the name of the function: |
| // |
| // ```dart |
| // void f(List<int> args) {} |
| // ``` |
| static const CompileTimeErrorCode MAIN_FIRST_POSITIONAL_PARAMETER_TYPE = |
| CompileTimeErrorCode( |
| 'MAIN_FIRST_POSITIONAL_PARAMETER_TYPE', |
| "The type of the first positional parameter of the 'main' function must be " |
| "a supertype of 'List<String>'.", |
| correction: "Try changing the type of the parameter.", |
| hasPublishedDocs: true, |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a function named `main` has one |
| // or more required named parameters. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the function named |
| // `main` has a required named parameter (`x`): |
| // |
| // ```dart |
| // void [!main!]({required int x}) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function is an entry point, then remove the `required` keyword: |
| // |
| // ```dart |
| // void main({int? x}) {} |
| // ``` |
| // |
| // If the function isn't an entry point, then change the name of the function: |
| // |
| // ```dart |
| // void f({required int x}) {} |
| // ``` |
| static const CompileTimeErrorCode MAIN_HAS_REQUIRED_NAMED_PARAMETERS = |
| CompileTimeErrorCode('MAIN_HAS_REQUIRED_NAMED_PARAMETERS', |
| "The function 'main' can't have any required named parameters.", |
| correction: |
| "Try using a different name for the function, or removing the " |
| "'required' modifier.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a function named `main` has more |
| // than two required positional parameters. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the function `main` has |
| // three required positional parameters: |
| // |
| // ```dart |
| // void [!main!](List<String> args, int x, int y) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the function is an entry point and the extra parameters aren't used, |
| // then remove them: |
| // |
| // ```dart |
| // void main(List<String> args, int x) {} |
| // ``` |
| // |
| // If the function is an entry point, but the extra parameters used are for |
| // when the function isn't being used as an entry point, then make the extra |
| // parameters optional: |
| // |
| // ```dart |
| // void main(List<String> args, int x, [int y = 0]) {} |
| // ``` |
| // |
| // If the function isn't an entry point, then change the name of the function: |
| // |
| // ```dart |
| // void f(List<String> args, int x, int y) {} |
| // ``` |
| static const CompileTimeErrorCode |
| MAIN_HAS_TOO_MANY_REQUIRED_POSITIONAL_PARAMETERS = CompileTimeErrorCode( |
| 'MAIN_HAS_TOO_MANY_REQUIRED_POSITIONAL_PARAMETERS', |
| "The function 'main' can't have more than two required positional " |
| "parameters.", |
| correction: |
| "Try using a different name for the function, or removing extra " |
| "parameters.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a library contains a declaration |
| // of the name `main` that isn't the declaration of a top-level function. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the name `main` is |
| // being used to declare a top-level variable: |
| // |
| // ```dart |
| // var [!main!] = 3; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Use a different name for the declaration: |
| // |
| // ```dart |
| // var mainIndex = 3; |
| // ``` |
| static const CompileTimeErrorCode MAIN_IS_NOT_FUNCTION = CompileTimeErrorCode( |
| 'MAIN_IS_NOT_FUNCTION', |
| "The declaration named 'main' must be a function.", |
| correction: "Try using a different name for this declaration.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a map entry (a key/value pair) |
| // is found in a set literal. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the literal has a map |
| // entry even though it's a set literal: |
| // |
| // ```dart |
| // const collection = <String>{[!'a' : 'b'!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intended for the collection to be a map, then change the code so |
| // that it is a map. In the previous example, you could do this by adding |
| // another type argument: |
| // |
| // ```dart |
| // const collection = <String, String>{'a' : 'b'}; |
| // ``` |
| // |
| // In other cases, you might need to change the explicit type from `Set` to |
| // `Map`. |
| // |
| // If you intended for the collection to be a set, then remove the map entry, |
| // possibly by replacing the colon with a comma if both values should be |
| // included in the set: |
| // |
| // ```dart |
| // const collection = <String>{'a', 'b'}; |
| // ``` |
| static const CompileTimeErrorCode MAP_ENTRY_NOT_IN_MAP = CompileTimeErrorCode( |
| 'MAP_ENTRY_NOT_IN_MAP', "Map entries can only be used in a map literal.", |
| correction: "Try converting the collection to a map or removing the map " |
| "entry.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the expression being used as a key |
| * 1: the type of keys declared for the map |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a key of a key-value pair in a |
| // map literal has a type that isn't assignable to the key type of the map. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `2` is an `int`, but |
| // the keys of the map are required to be `String`s: |
| // |
| // ```dart |
| // var m = <String, String>{[!2!] : 'a'}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the map is correct, then change the key to have the correct |
| // type: |
| // |
| // ```dart |
| // var m = <String, String>{'2' : 'a'}; |
| // ``` |
| // |
| // If the type of the key is correct, then change the key type of the map: |
| // |
| // ```dart |
| // var m = <int, String>{2 : 'a'}; |
| // ``` |
| static const CompileTimeErrorCode MAP_KEY_TYPE_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'MAP_KEY_TYPE_NOT_ASSIGNABLE', |
| "The element type '{0}' can't be assigned to the map key type " |
| "'{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the expression being used as a value |
| * 1: the type of values declared for the map |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a value of a key-value pair in a |
| // map literal has a type that isn't assignable to the the value type of the |
| // map. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `2` is an `int`, but/ |
| // the values of the map are required to be `String`s: |
| // |
| // ```dart |
| // var m = <String, String>{'a' : [!2!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the map is correct, then change the value to have the |
| // correct type: |
| // |
| // ```dart |
| // var m = <String, String>{'a' : '2'}; |
| // ``` |
| // |
| // If the type of the value is correct, then change the value type of the map: |
| // |
| // ```dart |
| // var m = <String, int>{'a' : 2}; |
| // ``` |
| static const CompileTimeErrorCode MAP_VALUE_TYPE_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'MAP_VALUE_TYPE_NOT_ASSIGNABLE', |
| "The element type '{0}' can't be assigned to the map value type " |
| "'{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 12.1 Constants: A constant expression is ... a constant list literal. |
| */ |
| static const CompileTimeErrorCode MISSING_CONST_IN_LIST_LITERAL = |
| CompileTimeErrorCode( |
| 'MISSING_CONST_IN_LIST_LITERAL', |
| "List literals must be prefixed with 'const' when used as a constant " |
| "expression.", |
| correction: "Try adding the keyword 'const' before the literal."); |
| |
| /** |
| * 12.1 Constants: A constant expression is ... a constant map literal. |
| */ |
| static const CompileTimeErrorCode MISSING_CONST_IN_MAP_LITERAL = |
| CompileTimeErrorCode( |
| 'MISSING_CONST_IN_MAP_LITERAL', |
| "Map literals must be prefixed with 'const' when used as a constant " |
| "expression.", |
| correction: "Try adding the keyword 'const' before the literal."); |
| |
| /** |
| * 12.1 Constants: A constant expression is ... a constant set literal. |
| */ |
| static const CompileTimeErrorCode MISSING_CONST_IN_SET_LITERAL = |
| CompileTimeErrorCode( |
| 'MISSING_CONST_IN_SET_LITERAL', |
| "Set literals must be prefixed with 'const' when used as a constant " |
| "expression.", |
| correction: "Try adding the keyword 'const' before the literal."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when either the Dart or Flutter SDK |
| // isn’t installed correctly, and, as a result, one of the `dart:` libraries |
| // can't be found. |
| // |
| // #### Common fixes |
| // |
| // Reinstall the Dart or Flutter SDK. |
| static const CompileTimeErrorCode MISSING_DART_LIBRARY = CompileTimeErrorCode( |
| 'MISSING_DART_LIBRARY', "Required library '{0}' is missing.", |
| correction: "Re-install the Dart or Flutter SDK.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an optional parameter, whether |
| // positional or named, has a [potentially non-nullable][] type and doesn't |
| // specify a default value. Optional parameters that have no explicit default |
| // value have an implicit default value of `null`. If the type of the |
| // parameter doesn't allow the parameter to have a value of `null`, then the |
| // implicit default value isn't valid. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` can't be `null`, |
| // and no non-`null` default value is specified: |
| // |
| // ```dart |
| // void f([int [!x!]]) {} |
| // ``` |
| // |
| // As does this: |
| // |
| // ```dart |
| // void g({int [!x!]}) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want to use `null` to indicate that no value was provided, then you |
| // need to make the type nullable: |
| // |
| // ```dart |
| // void f([int? x]) {} |
| // void g({int? x}) {} |
| // ``` |
| // |
| // If the parameter can't be null, then either provide a default value: |
| // |
| // ```dart |
| // void f([int x = 1]) {} |
| // void g({int x = 2}) {} |
| // ``` |
| // |
| // or make the parameter a required parameter: |
| // |
| // ```dart |
| // void f(int x) {} |
| // void g({required int x}) {} |
| // ``` |
| static const CompileTimeErrorCode MISSING_DEFAULT_VALUE_FOR_PARAMETER = |
| CompileTimeErrorCode( |
| 'MISSING_DEFAULT_VALUE_FOR_PARAMETER', |
| "The parameter '{0}' can't have a value of 'null' because of its " |
| "type, but the implicit default value is 'null'.", |
| correction: |
| "Try adding either an explicit non-'null' default value or the " |
| "'required' modifier.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the parameter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an invocation of a function is |
| // missing a required named parameter. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the invocation of `f` |
| // doesn't include a value for the required named parameter `end`: |
| // |
| // ```dart |
| // void f(int start, {required int end}) {} |
| // void g() { |
| // [!f!](3); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add a named argument corresponding to the missing required parameter: |
| // |
| // ```dart |
| // void f(int start, {required int end}) {} |
| // void g() { |
| // f(3, end: 5); |
| // } |
| // ``` |
| static const CompileTimeErrorCode MISSING_REQUIRED_ARGUMENT = |
| CompileTimeErrorCode( |
| 'MISSING_REQUIRED_ARGUMENT', |
| "The named parameter '{0}' is required, but there's no corresponding " |
| "argument.", |
| correction: "Try adding the required argument.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the super-invoked member |
| * 1: the display name of the type of the super-invoked member in the mixin |
| * 2: the display name of the type of the concrete member in the class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a mixin that invokes a method |
| // using `super` is used in a class where the concrete implementation of that |
| // method has a different signature than the signature defined for that method |
| // by the mixin's `on` type. The reason this is an error is because the |
| // invocation in the mixin might invoke the method in a way that's |
| // incompatible with the method that will actually be executed. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `C` uses the |
| // mixin `M`, the mixin `M` invokes `foo` using `super`, and the abstract |
| // version of `foo` declared in `I` (the mixin's `on` type) doesn't have the |
| // same signature as the concrete version of `foo` declared in `A`: |
| // |
| // ```dart |
| // class I { |
| // void foo([int? p]) {} |
| // } |
| // |
| // class A { |
| // void foo(int p) {} |
| // } |
| // |
| // abstract class B extends A implements I { |
| // @override |
| // void foo([int? p]); |
| // } |
| // |
| // mixin M on I { |
| // void bar() { |
| // super.foo(42); |
| // } |
| // } |
| // |
| // abstract class C extends B with [!M!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the class doesn't need to use the mixin, then remove it from the `with` |
| // clause: |
| // |
| // ```dart |
| // class I { |
| // void foo([int? p]) {} |
| // } |
| // |
| // class A { |
| // void foo(int? p) {} |
| // } |
| // |
| // abstract class B extends A implements I { |
| // @override |
| // void foo([int? p]); |
| // } |
| // |
| // mixin M on I { |
| // void bar() { |
| // super.foo(42); |
| // } |
| // } |
| // |
| // abstract class C extends B {} |
| // ``` |
| // |
| // If the class needs to use the mixin, then ensure that there's a concrete |
| // implementation of the method that conforms to the signature expected by the |
| // mixin: |
| // |
| // ```dart |
| // class I { |
| // void foo([int? p]) {} |
| // } |
| // |
| // class A { |
| // void foo(int? p) {} |
| // } |
| // |
| // abstract class B extends A implements I { |
| // @override |
| // void foo([int? p]) { |
| // super.foo(p); |
| // } |
| // } |
| // |
| // mixin M on I { |
| // void bar() { |
| // super.foo(42); |
| // } |
| // } |
| // |
| // abstract class C extends B with M {} |
| // ``` |
| static const CompileTimeErrorCode |
| MIXIN_APPLICATION_CONCRETE_SUPER_INVOKED_MEMBER_TYPE = |
| CompileTimeErrorCode( |
| 'MIXIN_APPLICATION_CONCRETE_SUPER_INVOKED_MEMBER_TYPE', |
| "The super-invoked member '{0}' has the type '{1}', and the concrete " |
| "member in the class has the type '{2}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the display name of the member without a concrete implementation |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a [mixin application][] contains |
| // an invocation of a member from its superclass, and there's no concrete |
| // member of that name in the mixin application's superclass. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the mixin `M` contains |
| // the invocation `super.m()`, and the class `A`, which is the superclass of |
| // the [mixin application][] `A+M`, doesn't define a concrete implementation |
| // of `m`: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // mixin M on A { |
| // void bar() { |
| // super.m(); |
| // } |
| // } |
| // |
| // abstract class B extends A with [!M!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intended to apply the mixin `M` to a different class, one that has a |
| // concrete implementation of `m`, then change the superclass of `B` to that |
| // class: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // mixin M on A { |
| // void bar() { |
| // super.m(); |
| // } |
| // } |
| // |
| // class C implements A { |
| // void m() {} |
| // } |
| // |
| // abstract class B extends C with M {} |
| // ``` |
| // |
| // If you need to make `B` a subclass of `A`, then add a concrete |
| // implementation of `m` in `A`: |
| // |
| // ```dart |
| // abstract class A { |
| // void m() {} |
| // } |
| // |
| // mixin M on A { |
| // void bar() { |
| // super.m(); |
| // } |
| // } |
| // |
| // abstract class B extends A with M {} |
| // ``` |
| static const CompileTimeErrorCode |
| MIXIN_APPLICATION_NO_CONCRETE_SUPER_INVOKED_MEMBER = CompileTimeErrorCode( |
| 'MIXIN_APPLICATION_NO_CONCRETE_SUPER_INVOKED_MEMBER', |
| "The class doesn't have a concrete implementation of the " |
| "super-invoked member '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the display name of the mixin |
| * 1: the display name of the superclass |
| * 2: the display name of the type that is not implemented |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a mixin that has a superclass |
| // constraint is used in a [mixin application][] with a superclass that |
| // doesn't implement the required constraint. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the mixin `M` requires |
| //that the class to which it's applied be a subclass of `A`, but `Object` |
| // isn't a subclass of `A`: |
| // |
| // ```dart |
| // class A {} |
| // |
| // mixin M on A {} |
| // |
| // class X = Object with [!M!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to use the mixin, then change the superclass to be either the |
| // same as or a subclass of the superclass constraint: |
| // |
| // ```dart |
| // class A {} |
| // |
| // mixin M on A {} |
| // |
| // class X = A with M; |
| // ``` |
| static const CompileTimeErrorCode |
| MIXIN_APPLICATION_NOT_IMPLEMENTED_INTERFACE = CompileTimeErrorCode( |
| 'MIXIN_APPLICATION_NOT_IMPLEMENTED_INTERFACE', |
| "'{0}' can't be mixed onto '{1}' because '{1}' doesn't implement " |
| "'{2}'.", |
| correction: "Try extending the class '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the mixin that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class is used as a mixin and |
| // the mixed-in class defines a constructor. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `A`, which |
| // defines a constructor, is being used as a mixin: |
| // |
| // ```dart |
| // class A { |
| // A(); |
| // } |
| // |
| // class B with [!A!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it's possible to convert the class to a mixin, then do so: |
| // |
| // ```dart |
| // mixin A { |
| // } |
| // |
| // class B with A {} |
| // ``` |
| // |
| // If the class can't be a mixin and it's possible to remove the constructor, |
| // then do so: |
| // |
| // ```dart |
| // class A { |
| // } |
| // |
| // class B with A {} |
| // ``` |
| // |
| // If the class can't be a mixin and you can't remove the constructor, then |
| // try extending or implementing the class rather than mixing it in: |
| // |
| // ```dart |
| // class A { |
| // A(); |
| // } |
| // |
| // class B extends A {} |
| // ``` |
| static const CompileTimeErrorCode MIXIN_CLASS_DECLARES_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'MIXIN_CLASS_DECLARES_CONSTRUCTOR', |
| "The class '{0}' can't be used as a mixin because it declares a " |
| "constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * The <i>mixinMember</i> production allows the same instance or static |
| * members that a class would allow, but no constructors (for now). |
| */ |
| static const CompileTimeErrorCode MIXIN_DECLARES_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'MIXIN_DECLARES_CONSTRUCTOR', "Mixins can't declare constructors."); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode MIXIN_DEFERRED_CLASS = CompileTimeErrorCode( |
| 'SUBTYPE_OF_DEFERRED_CLASS', "Classes can't mixin deferred classes.", |
| correction: "Try changing the import to not be deferred.", |
| hasPublishedDocs: true, |
| uniqueName: 'MIXIN_DEFERRED_CLASS'); |
| |
| static const CompileTimeErrorCode |
| MIXIN_INFERENCE_INCONSISTENT_MATCHING_CLASSES = CompileTimeErrorCode( |
| 'MIXIN_INFERENCE_INCONSISTENT_MATCHING_CLASSES', |
| "Type parameters couldn't be inferred for the mixin '{0}' because " |
| "the base class implements the mixin's supertype constraint " |
| "'{1}' in multiple conflicting ways"); |
| |
| static const CompileTimeErrorCode MIXIN_INFERENCE_NO_MATCHING_CLASS = |
| CompileTimeErrorCode( |
| 'MIXIN_INFERENCE_NO_MATCHING_CLASS', |
| "Type parameters couldn't be inferred for the mixin '{0}' because " |
| "the base class doesn't implement the mixin's supertype " |
| "constraint '{1}'"); |
| |
| static const CompileTimeErrorCode MIXIN_INFERENCE_NO_POSSIBLE_SUBSTITUTION = |
| CompileTimeErrorCode( |
| 'MIXIN_INFERENCE_NO_POSSIBLE_SUBSTITUTION', |
| "Type parameters couldn't be inferred for the mixin '{0}' because " |
| "no type parameter substitution could be found matching the " |
| "mixin's supertype constraints"); |
| |
| /** |
| * Parameters: |
| * 0: the name of the mixin that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class that extends a class |
| // other than `Object` is used as a mixin. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `B`, which |
| // extends `A`, is being used as a mixin by `C`: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B extends A {} |
| // |
| // class C with [!B!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the class being used as a mixin can be changed to extend `Object`, then |
| // change it: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B {} |
| // |
| // class C with B {} |
| // ``` |
| // |
| // If the class being used as a mixin can't be changed and the class that's |
| // using it extends `Object`, then extend the class being used as a mixin: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B extends A {} |
| // |
| // class C extends B {} |
| // ``` |
| // |
| // If the class doesn't extend `Object` or if you want to be able to mix in |
| // the behavior from `B` in other places, then create a real mixin: |
| // |
| // ```dart |
| // class A {} |
| // |
| // mixin M on A {} |
| // |
| // class B extends A with M {} |
| // |
| // class C extends A with M {} |
| // ``` |
| static const CompileTimeErrorCode MIXIN_INHERITS_FROM_NOT_OBJECT = |
| CompileTimeErrorCode( |
| 'MIXIN_INHERITS_FROM_NOT_OBJECT', |
| "The class '{0}' can't be used as a mixin because it extends a class " |
| "other than 'Object'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a mixin is instantiated. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the mixin `M` is being |
| // instantiated: |
| // |
| // ```dart |
| // mixin M {} |
| // |
| // var m = [!M!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intend to use an instance of a class, then use the name of that |
| // class in place of the name of the mixin. |
| static const CompileTimeErrorCode MIXIN_INSTANTIATE = CompileTimeErrorCode( |
| 'MIXIN_INSTANTIATE', "Mixins can't be instantiated.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the disallowed type |
| */ |
| static const CompileTimeErrorCode MIXIN_OF_DISALLOWED_CLASS = |
| CompileTimeErrorCode( |
| 'SUBTYPE_OF_DISALLOWED_TYPE', |
| "Classes can't mixin '{0}'.", |
| correction: "Try specifying a different class or mixin, or " |
| "remove the class or mixin from the list.", |
| hasPublishedDocs: true, |
| uniqueName: 'MIXIN_OF_DISALLOWED_CLASS', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name in a `with` clause is |
| // defined to be something other than a mixin or a class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `F` is defined to be a |
| // function type: |
| // |
| // ```dart |
| // typedef F = int Function(String); |
| // |
| // class C with [!F!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the invalid name from the list, possibly replacing it with the name |
| // of the intended mixin or class: |
| // |
| // ```dart |
| // typedef F = int Function(String); |
| // |
| // class C {} |
| // ``` |
| static const CompileTimeErrorCode MIXIN_OF_NON_CLASS = CompileTimeErrorCode( |
| 'MIXIN_OF_NON_CLASS', "Classes can only mix in mixins and classes.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| MIXIN_OF_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'SUPERTYPE_EXPANDS_TO_TYPE_PARAMETER', |
| "A type alias that expands to a type parameter can't be mixed in.", |
| hasPublishedDocs: true, |
| uniqueName: 'MIXIN_OF_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER'); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| MIXIN_ON_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'SUPERTYPE_EXPANDS_TO_TYPE_PARAMETER', |
| "A type alias that expands to a type parameter can't be used as a " |
| "superclass constraint.", |
| hasPublishedDocs: true, |
| uniqueName: 'MIXIN_ON_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER'); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| MIXIN_SUPER_CLASS_CONSTRAINT_DEFERRED_CLASS = CompileTimeErrorCode( |
| 'MIXIN_SUPER_CLASS_CONSTRAINT_DEFERRED_CLASS', |
| "Deferred classes can't be used as super-class constraints.", |
| correction: "Try changing the import to not be deferred."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the disallowed type |
| */ |
| static const CompileTimeErrorCode |
| MIXIN_SUPER_CLASS_CONSTRAINT_DISALLOWED_CLASS = CompileTimeErrorCode( |
| 'SUBTYPE_OF_DISALLOWED_TYPE', |
| "''{0}' can't be used as a superclass constraint.", |
| correction: "Try specifying a different super-class constraint, or " |
| "remove the 'on' clause.", |
| hasPublishedDocs: true, |
| uniqueName: 'MIXIN_SUPER_CLASS_CONSTRAINT_DISALLOWED_CLASS', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type following the `on` |
| // keyword in a mixin declaration is neither a class nor a mixin. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `F` is neither a class |
| // nor a mixin: |
| // |
| // ```dart |
| // typedef F = void Function(); |
| // |
| // mixin M on [!F!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type was intended to be a class but was mistyped, then replace the |
| // name. |
| // |
| // Otherwise, remove the type from the `on` clause. |
| static const CompileTimeErrorCode MIXIN_SUPER_CLASS_CONSTRAINT_NON_INTERFACE = |
| CompileTimeErrorCode('MIXIN_SUPER_CLASS_CONSTRAINT_NON_INTERFACE', |
| "Only classes and mixins can be used as superclass constraints.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 9.1 Mixin Application: It is a compile-time error if <i>S</i> does not |
| * denote a class available in the immediately enclosing scope. |
| */ |
| static const CompileTimeErrorCode MIXIN_WITH_NON_CLASS_SUPERCLASS = |
| CompileTimeErrorCode('MIXIN_WITH_NON_CLASS_SUPERCLASS', |
| "Mixin can only be applied to class."); |
| |
| /** |
| * Technically this is [IMPLEMENTS_SUPER_CLASS]. |
| * See https://github.com/dart-lang/sdk/issues/25765#issuecomment-307422593 |
| * |
| * Parameters: |
| * 0: the name of the class that appears in both "extends" and "with" clauses |
| */ |
| static const CompileTimeErrorCode MIXINS_SUPER_CLASS = CompileTimeErrorCode( |
| 'MIXINS_SUPER_CLASS', |
| "'{0}' can't be used in both 'extends' and 'with' clauses.", |
| correction: "Try removing one of the occurrences."); |
| |
| /** |
| * 7.6.1 Generative Constructors: A generative constructor may be redirecting, |
| * in which case its only action is to invoke another generative constructor. |
| */ |
| static const CompileTimeErrorCode |
| MULTIPLE_REDIRECTING_CONSTRUCTOR_INVOCATIONS = CompileTimeErrorCode( |
| 'MULTIPLE_REDIRECTING_CONSTRUCTOR_INVOCATIONS', |
| "Constructors can have at most one 'this' redirection.", |
| correction: "Try removing all but one of the redirections."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the initializer list of a |
| // constructor contains more than one invocation of a constructor from the |
| // superclass. The initializer list is required to have exactly one such call, |
| // which can either be explicit or implicit. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the initializer list |
| // for `B`’s constructor invokes both the constructor `one` and the |
| // constructor `two` from the superclass `A`: |
| // |
| // ```dart |
| // class A { |
| // int? x; |
| // String? s; |
| // A.one(this.x); |
| // A.two(this.s); |
| // } |
| // |
| // class B extends A { |
| // B() : super.one(0), [!super.two('')!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If one of the super constructors will initialize the instance fully, then |
| // remove the other: |
| // |
| // ```dart |
| // class A { |
| // int? x; |
| // String? s; |
| // A.one(this.x); |
| // A.two(this.s); |
| // } |
| // |
| // class B extends A { |
| // B() : super.one(0); |
| // } |
| // ``` |
| // |
| // If the initialization achieved by one of the super constructors can be |
| // performed in the body of the constructor, then remove its super invocation |
| // and perform the initialization in the body: |
| // |
| // ```dart |
| // class A { |
| // int? x; |
| // String? s; |
| // A.one(this.x); |
| // A.two(this.s); |
| // } |
| // |
| // class B extends A { |
| // B() : super.one(0) { |
| // s = ''; |
| // } |
| // } |
| // ``` |
| // |
| // If the initialization can only be performed in a constructor in the |
| // superclass, then either add a new constructor or modify one of the existing |
| // constructors so there's a constructor that allows all the required |
| // initialization to occur in a single call: |
| // |
| // ```dart |
| // class A { |
| // int? x; |
| // String? s; |
| // A.one(this.x); |
| // A.two(this.s); |
| // A.three(this.x, this.s); |
| // } |
| // |
| // class B extends A { |
| // B() : super.three(0, ''); |
| // } |
| // ``` |
| static const CompileTimeErrorCode MULTIPLE_SUPER_INITIALIZERS = |
| CompileTimeErrorCode('MULTIPLE_SUPER_INITIALIZERS', |
| "A constructor can have at most one 'super' initializer.", |
| correction: "Try removing all but one of the 'super' initializers.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the non-type element |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an instance creation using |
| // either `new` or `const` specifies a name that isn't defined as a class. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `f` is a function |
| // rather than a class: |
| // |
| // ```dart |
| // int f() => 0; |
| // |
| // void g() { |
| // new [!f!](); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If a class should be created, then replace the invalid name with the name |
| // of a valid class: |
| // |
| // ```dart |
| // int f() => 0; |
| // |
| // void g() { |
| // new Object(); |
| // } |
| // ``` |
| // |
| // If the name is the name of a function and you want that function to be |
| // invoked, then remove the `new` or `const` keyword: |
| // |
| // ```dart |
| // int f() => 0; |
| // |
| // void g() { |
| // f(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode NEW_WITH_NON_TYPE = CompileTimeErrorCode( |
| 'CREATION_WITH_NON_TYPE', |
| "The name '{0}' isn't a class.", |
| correction: "Try correcting the name to match an existing class.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true, |
| uniqueName: 'NEW_WITH_NON_TYPE', |
| ); |
| |
| /** |
| * 12.11.1 New: If <i>T</i> is a class or parameterized type accessible in the |
| * current scope then: |
| * 1. If <i>e</i> is of the form <i>new T.id(a<sub>1</sub>, …, |
| * a<sub>n</sub>, x<sub>n+1</sub>: a<sub>n+1</sub>, …, |
| * x<sub>n+k</sub>: a<sub>n+k</sub>)</i> it is a static warning if |
| * <i>T.id</i> is not the name of a constructor declared by the type |
| * <i>T</i>. |
| * If <i>e</i> of the form <i>new T(a<sub>1</sub>, …, a<sub>n</sub>, |
| * x<sub>n+1</sub>: a<sub>n+1</sub>, …, x<sub>n+k</sub>: |
| * a<sub>n+kM/sub>)</i> it is a static warning if the type <i>T</i> does not |
| * declare a constructor with the same name as the declaration of <i>T</i>. |
| */ |
| static const CompileTimeErrorCode NEW_WITH_UNDEFINED_CONSTRUCTOR = |
| CompileTimeErrorCode('NEW_WITH_UNDEFINED_CONSTRUCTOR', |
| "The class '{0}' doesn't have a constructor named '{1}'.", |
| correction: "Try invoking a different constructor, or " |
| "define a constructor named '{1}'."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class being instantiated |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an unnamed constructor is |
| // invoked on a class that defines named constructors but the class doesn’t |
| // have an unnamed constructor. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `A` doesn't define an |
| // unnamed constructor: |
| // |
| // ```dart |
| // class A { |
| // A.a(); |
| // } |
| // |
| // A f() => [!A!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If one of the named constructors does what you need, then use it: |
| // |
| // ```dart |
| // class A { |
| // A.a(); |
| // } |
| // |
| // A f() => A.a(); |
| // ``` |
| // |
| // If none of the named constructors does what you need, and you're able to |
| // add an unnamed constructor, then add the constructor: |
| // |
| // ```dart |
| // class A { |
| // A(); |
| // A.a(); |
| // } |
| // |
| // A f() => A(); |
| // ``` |
| static const CompileTimeErrorCode NEW_WITH_UNDEFINED_CONSTRUCTOR_DEFAULT = |
| CompileTimeErrorCode('NEW_WITH_UNDEFINED_CONSTRUCTOR_DEFAULT', |
| "The class '{0}' doesn't have an unnamed constructor.", |
| correction: |
| "Try using one of the named constructors defined in '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an annotation consists of a |
| // single identifier, but that identifier is the name of a class rather than a |
| // variable. To create an instance of the class, the identifier must be |
| // followed by an argument list. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `C` is a class, and a |
| // class can't be used as an annotation without invoking a `const` constructor |
| // from the class: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // } |
| // |
| // [!@C!] |
| // var x; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add the missing argument list: |
| // |
| // ```dart |
| // class C { |
| // const C(); |
| // } |
| // |
| // @C() |
| // var x; |
| // ``` |
| static const CompileTimeErrorCode NO_ANNOTATION_CONSTRUCTOR_ARGUMENTS = |
| CompileTimeErrorCode('NO_ANNOTATION_CONSTRUCTOR_ARGUMENTS', |
| "Annotation creation must have arguments.", |
| correction: "Try adding an empty argument list.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class where override error was detected |
| * 1: the list of candidate signatures which cannot be combined |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when there is a method declaration |
| // for which one or more types needs to be inferred, and those types can't be |
| // inferred because none of the overridden methods has a function type that is |
| // a supertype of all the other overridden methods, as specified by |
| // [override inference][]. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the method `m` declared |
| // in the class `C` is missing both the return type and the type of the |
| // parameter `a`, and neither of the missing types can be inferred for it: |
| // |
| // ```dart |
| // abstract class A { |
| // A m(String a); |
| // } |
| // |
| // abstract class B { |
| // B m(int a); |
| // } |
| // |
| // abstract class C implements A, B { |
| // [!m!](a); |
| // } |
| // ``` |
| // |
| // In this example, override inference can't be performed because the |
| // overridden methods are incompatible in these ways: |
| // - Neither parameter type (`String` and `int`) is a supertype of the other. |
| // - Neither return type is a subtype of the other. |
| // |
| // #### Common fixes |
| // |
| // If possible, add types to the method in the subclass that are consistent |
| // with the types from all the overridden methods: |
| // |
| // ```dart |
| // abstract class A { |
| // A m(String a); |
| // } |
| // |
| // abstract class B { |
| // B m(int a); |
| // } |
| // |
| // abstract class C implements A, B { |
| // C m(Object a); |
| // } |
| // ``` |
| static const CompileTimeErrorCode NO_COMBINED_SUPER_SIGNATURE = |
| CompileTimeErrorCode('NO_COMBINED_SUPER_SIGNATURE', |
| "Can't infer missing types in '{0}' from overridden methods: {1}.", |
| correction: "Try providing explicit types for this method's " |
| "parameters and return type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the superclass that does not define an implicitly invoked |
| * constructor |
| */ |
| static const CompileTimeErrorCode NO_DEFAULT_SUPER_CONSTRUCTOR_EXPLICIT = |
| CompileTimeErrorCode( |
| 'NO_DEFAULT_SUPER_CONSTRUCTOR', |
| "The superclass '{0}' doesn't have a zero argument constructor.", |
| correction: "Try declaring a zero argument constructor in '{0}', or " |
| "explicitly invoking a different constructor in '{0}'.", |
| uniqueName: 'NO_DEFAULT_SUPER_CONSTRUCTOR_EXPLICIT', |
| ); |
| |
| /** |
| * User friendly specialized error for [NON_GENERATIVE_CONSTRUCTOR]. This |
| * handles the case of `class E extends Exception` which will never work |
| * because [Exception] has no generative constructors. |
| * |
| * Parameters: |
| * 0: the name of the subclass |
| * 1: the name of the superclass |
| */ |
| static const CompileTimeErrorCode NO_GENERATIVE_CONSTRUCTORS_IN_SUPERCLASS = |
| CompileTimeErrorCode( |
| 'NO_GENERATIVE_CONSTRUCTOR_IN_SUPERCLASS', |
| "The class '{0}' cannot extend '{1}' because '{1}' only has factory " |
| "constructors (no generative constructors), and '{0}' has at " |
| "least one generative constructor.", |
| correction: "Try implementing the class instead, adding a generative " |
| "(not factory) constructor to the superclass {0}, or a factory " |
| "constructor to the subclass."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the superclass that does not define an implicitly invoked |
| * constructor |
| * 1: the name of the subclass that does not contain any explicit constructors |
| */ |
| static const CompileTimeErrorCode NO_DEFAULT_SUPER_CONSTRUCTOR_IMPLICIT = |
| CompileTimeErrorCode( |
| 'NO_DEFAULT_SUPER_CONSTRUCTOR', |
| "The superclass '{0}' doesn't have a zero argument constructor.", |
| correction: "Try declaring a zero argument constructor in '{0}', or " |
| "declaring a constructor in {1} that explicitly invokes a " |
| "constructor in '{0}'.", |
| uniqueName: 'NO_DEFAULT_SUPER_CONSTRUCTOR_IMPLICIT', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the first member |
| * 1: the name of the second member |
| * 2: the name of the third member |
| * 3: the name of the fourth member |
| * 4: the number of additional missing members that aren't listed |
| */ |
| static const CompileTimeErrorCode |
| NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_FIVE_PLUS = |
| CompileTimeErrorCode( |
| 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER', |
| "Missing concrete implementations of '{0}', '{1}', '{2}', '{3}', and " |
| "{4} more.", |
| correction: "Try implementing the missing methods, or make the class " |
| "abstract.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_FIVE_PLUS', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the first member |
| * 1: the name of the second member |
| * 2: the name of the third member |
| * 3: the name of the fourth member |
| */ |
| static const CompileTimeErrorCode |
| NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_FOUR = CompileTimeErrorCode( |
| 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER', |
| "Missing concrete implementations of '{0}', '{1}', '{2}', and '{3}'.", |
| correction: "Try implementing the missing methods, or make the class " |
| "abstract.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_FOUR', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the member |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a concrete class inherits one or |
| // more abstract members, and doesn't provide or inherit an implementation for |
| // at least one of those abstract members. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the class `B` doesn't |
| // have a concrete implementation of `m`: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // class [!B!] extends A {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the subclass can provide a concrete implementation for some or all of |
| // the abstract inherited members, then add the concrete implementations: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // class B extends A { |
| // void m() {} |
| // } |
| // ``` |
| // |
| // If there is a mixin that provides an implementation of the inherited |
| // methods, then apply the mixin to the subclass: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // class B extends A with M {} |
| // |
| // mixin M { |
| // void m() {} |
| // } |
| // ``` |
| // |
| // If the subclass can't provide a concrete implementation for all of the |
| // abstract inherited members, then mark the subclass as being abstract: |
| // |
| // ```dart |
| // abstract class A { |
| // void m(); |
| // } |
| // |
| // abstract class B extends A {} |
| // ``` |
| static const CompileTimeErrorCode |
| NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_ONE = CompileTimeErrorCode( |
| 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER', |
| "Missing concrete implementation of '{0}'.", |
| correction: "Try implementing the missing method, or make the class " |
| "abstract.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_ONE', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the first member |
| * 1: the name of the second member |
| * 2: the name of the third member |
| */ |
| static const CompileTimeErrorCode |
| NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_THREE = CompileTimeErrorCode( |
| 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER', |
| "Missing concrete implementations of '{0}', '{1}', and '{2}'.", |
| correction: "Try implementing the missing methods, or make the class " |
| "abstract.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_THREE', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the first member |
| * 1: the name of the second member |
| */ |
| static const CompileTimeErrorCode |
| NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_TWO = CompileTimeErrorCode( |
| 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER', |
| "Missing concrete implementations of '{0}' and '{1}'.", |
| correction: "Try implementing the missing methods, or make the class " |
| "abstract.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_ABSTRACT_CLASS_INHERITS_ABSTRACT_MEMBER_TWO', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a condition, such as an `if` or |
| // `while` loop, doesn't have the static type `bool`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` has the static type |
| // `int`: |
| // |
| // ```dart |
| // void f(int x) { |
| // if ([!x!]) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the condition so that it produces a Boolean value: |
| // |
| // ```dart |
| // void f(int x) { |
| // if (x == 0) { |
| // // ... |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_BOOL_CONDITION = CompileTimeErrorCode( |
| 'NON_BOOL_CONDITION', "Conditions must have a static type of 'bool'.", |
| correction: "Try changing the condition.", hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the first expression in an |
| // assert has a type other than `bool`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the type of `p` is |
| // `int`, but a `bool` is required: |
| // |
| // ```dart |
| // void f(int p) { |
| // assert([!p!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the expression so that it has the type `bool`: |
| // |
| // ```dart |
| // void f(int p) { |
| // assert(p > 0); |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_BOOL_EXPRESSION = CompileTimeErrorCode( |
| 'NON_BOOL_EXPRESSION', |
| "The expression in an assert must be of type 'bool'.", |
| correction: "Try changing the expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the operand of the unary |
| // negation operator (`!`) doesn't have the type `bool`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is an `int` when it |
| // must be a `bool`: |
| // |
| // ```dart |
| // int x = 0; |
| // bool y = ![!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the operand with an expression that has the type `bool`: |
| // |
| // ```dart |
| // int x = 0; |
| // bool y = !(x > 0); |
| // ``` |
| static const CompileTimeErrorCode NON_BOOL_NEGATION_EXPRESSION = |
| CompileTimeErrorCode('NON_BOOL_NEGATION_EXPRESSION', |
| "A negation operand must have a static type of 'bool'.", |
| correction: "Try changing the operand to the '!' operator.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the lexeme of the logical operator |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when one of the operands of either |
| // the `&&` or `||` operator doesn't have the type `bool`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `a` isn't a Boolean |
| // value: |
| // |
| // ```dart |
| // int a = 3; |
| // bool b = [!a!] || a > 1; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the operand to a Boolean value: |
| // |
| // ```dart |
| // int a = 3; |
| // bool b = a == 0 || a > 1; |
| // ``` |
| static const CompileTimeErrorCode NON_BOOL_OPERAND = CompileTimeErrorCode( |
| 'NON_BOOL_OPERAND', |
| "The operands of the operator '{0}' must be assignable to 'bool'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 13.2 Expression Statements: It is a compile-time error if a non-constant |
| * map literal that has no explicit type arguments appears in a place where a |
| * statement is expected. |
| */ |
| static const CompileTimeErrorCode NON_CONST_MAP_AS_EXPRESSION_STATEMENT = |
| CompileTimeErrorCode( |
| 'NON_CONST_MAP_AS_EXPRESSION_STATEMENT', |
| "A non-constant map or set literal without type arguments can't be " |
| "used as an expression statement."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an annotation is the invocation |
| // of an existing constructor even though the invoked constructor isn't a |
| // const constructor. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constructor for `C` |
| // isn't a const constructor: |
| // |
| // ```dart |
| // [!@C()!] |
| // void f() { |
| // } |
| // |
| // class C { |
| // C(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If it's valid for the class to have a const constructor, then create a |
| // const constructor that can be used for the annotation: |
| // |
| // ```dart |
| // @C() |
| // void f() { |
| // } |
| // |
| // class C { |
| // const C(); |
| // } |
| // ``` |
| // |
| // If it isn't valid for the class to have a const constructor, then either |
| // remove the annotation or use a different class for the annotation. |
| static const CompileTimeErrorCode NON_CONSTANT_ANNOTATION_CONSTRUCTOR = |
| CompileTimeErrorCode('NON_CONSTANT_ANNOTATION_CONSTRUCTOR', |
| "Annotation creation can only call a const constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression in a `case` |
| // clause isn't a constant expression. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `j` isn't a constant: |
| // |
| // ```dart |
| // void f(int i, int j) { |
| // switch (i) { |
| // case [!j!]: |
| // // ... |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Either make the expression a constant expression, or rewrite the `switch` |
| // statement as a sequence of `if` statements: |
| // |
| // ```dart |
| // void f(int i, int j) { |
| // if (i == j) { |
| // // ... |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_CASE_EXPRESSION = |
| CompileTimeErrorCode( |
| 'NON_CONSTANT_CASE_EXPRESSION', "Case expressions must be constant.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the expression in a case clause |
| // references a constant from a library that is imported using a deferred |
| // import. In order for switch statements to be compiled efficiently, the |
| // constants referenced in case clauses need to be available at compile time, |
| // and constants from deferred libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // Given a file (`a.dart`) that defines the constant `zero`: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // const zero = 0; |
| // ``` |
| // |
| // The following code produces this diagnostic because the library `a.dart` is |
| // imported using a `deferred` import, and the constant `a.zero`, declared in |
| // the imported library, is used in a case clause: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // void f(int x) { |
| // switch (x) { |
| // case [!a.zero!]: |
| // // ... |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to reference the constant from the imported library, then |
| // remove the `deferred` keyword: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // |
| // void f(int x) { |
| // switch (x) { |
| // case a.zero: |
| // // ... |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If you need to reference the constant from the imported library and also |
| // need the imported library to be deferred, then rewrite the switch statement |
| // as a sequence of `if` statements: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // void f(int x) { |
| // if (x == a.zero) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // If you don't need to reference the constant, then replace the case |
| // expression: |
| // |
| // ```dart |
| // void f(int x) { |
| // switch (x) { |
| // case 0: |
| // // ... |
| // break; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| NON_CONSTANT_CASE_EXPRESSION_FROM_DEFERRED_LIBRARY = CompileTimeErrorCode( |
| 'NON_CONSTANT_CASE_EXPRESSION_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as a case " |
| "expression.", |
| correction: |
| "Try re-writing the switch as a series of if statements, or " |
| "changing the import to not be deferred.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an optional parameter, either |
| // named or positional, has a default value that isn't a compile-time |
| // constant. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // %language=2.9 |
| // var defaultValue = 3; |
| // |
| // void f([int value = [!defaultValue!]]) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the default value can be converted to be a constant, then convert it: |
| // |
| // ```dart |
| // %language=2.9 |
| // const defaultValue = 3; |
| // |
| // void f([int value = defaultValue]) {} |
| // ``` |
| // |
| // If the default value needs to change over time, then apply the default |
| // value inside the function: |
| // |
| // ```dart |
| // %language=2.9 |
| // var defaultValue = 3; |
| // |
| // void f([int value]) { |
| // value ??= defaultValue; |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_DEFAULT_VALUE = |
| CompileTimeErrorCode('NON_CONSTANT_DEFAULT_VALUE', |
| "The default value of an optional parameter must be constant.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the default value of an optional |
| // parameter uses a constant from a library imported using a deferred import. |
| // Default values need to be available at compile time, and constants from |
| // deferred libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // Given a file (`a.dart`) that defines the constant `zero`: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // const zero = 0; |
| // ``` |
| // |
| // The following code produces this diagnostic because `zero` is declared in a |
| // library imported using a deferred import: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // void f({int x = [!a.zero!]}) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to reference the constant from the imported library, then |
| // remove the `deferred` keyword: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // |
| // void f({int x = a.zero}) {} |
| // ``` |
| // |
| // If you don't need to reference the constant, then replace the default |
| // value: |
| // |
| // ```dart |
| // void f({int x = 0}) {} |
| // ``` |
| static const CompileTimeErrorCode |
| NON_CONSTANT_DEFAULT_VALUE_FROM_DEFERRED_LIBRARY = CompileTimeErrorCode( |
| 'NON_CONSTANT_DEFAULT_VALUE_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as a default " |
| "parameter value.", |
| correction: |
| "Try leaving the default as null and initializing the parameter " |
| "inside the function body.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an element in a constant list |
| // literal isn't a constant value. The list literal can be constant either |
| // explicitly (because it's prefixed by the `const` keyword) or implicitly |
| // (because it appears in a [constant context][]). |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` isn't a constant, |
| // even though it appears in an implicitly constant list literal: |
| // |
| // ```dart |
| // var x = 2; |
| // var y = const <int>[0, 1, [!x!]]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the list needs to be a constant list, then convert the element to be a |
| // constant. In the example above, you might add the `const` keyword to the |
| // declaration of `x`: |
| // |
| // ```dart |
| // const x = 2; |
| // var y = const <int>[0, 1, x]; |
| // ``` |
| // |
| // If the expression can't be made a constant, then the list can't be a |
| // constant either, so you must change the code so that the list isn't a |
| // constant. In the example above this means removing the `const` keyword |
| // before the list literal: |
| // |
| // ```dart |
| // var x = 2; |
| // var y = <int>[0, 1, x]; |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_LIST_ELEMENT = |
| CompileTimeErrorCode('NON_CONSTANT_LIST_ELEMENT', |
| "The values in a const list literal must be constants.", |
| correction: "Try removing the keyword 'const' from the list literal.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a collection literal that is |
| // either explicitly (because it's prefixed by the `const` keyword) or |
| // implicitly (because it appears in a [constant context][]) a constant |
| // contains a value that is declared in a library that is imported using a |
| // deferred import. Constants are evaluated at compile time, and values from |
| // deferred libraries aren't available at compile time. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // Given a file (`a.dart`) that defines the constant `zero`: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // const zero = 0; |
| // ``` |
| // |
| // The following code produces this diagnostic because the constant list |
| // literal contains `a.zero`, which is imported using a `deferred` import: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // var l = const [[!a.zero!]]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the collection literal isn't required to be constant, then remove the |
| // `const` keyword: |
| // |
| // ```dart |
| // import 'a.dart' deferred as a; |
| // |
| // var l = [a.zero]; |
| // ``` |
| // |
| // If the collection is required to be constant and the imported constant must |
| // be referenced, then remove the keyword `deferred` from the import: |
| // |
| // ```dart |
| // import 'a.dart' as a; |
| // |
| // var l = const [a.zero]; |
| // ``` |
| // |
| // If you don't need to reference the constant, then replace it with a |
| // suitable value: |
| // |
| // ```dart |
| // var l = const [0]; |
| // ``` |
| static const CompileTimeErrorCode |
| NON_CONSTANT_LIST_ELEMENT_FROM_DEFERRED_LIBRARY = CompileTimeErrorCode( |
| 'COLLECTION_ELEMENT_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as values in " |
| "a 'const' list literal.", |
| correction: "Try removing the keyword 'const' from the list literal " |
| "or removing the keyword 'deferred' from the import.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_CONSTANT_LIST_ELEMENT_FROM_DEFERRED_LIBRARY'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an `if` element or a spread |
| // element in a constant map isn't a constant element. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because it's attempting to |
| // spread a non-constant map: |
| // |
| // ```dart |
| // var notConst = <int, int>{}; |
| // var map = const <int, int>{...[!notConst!]}; |
| // ``` |
| // |
| // Similarly, the following code produces this diagnostic because the |
| // condition in the `if` element isn't a constant expression: |
| // |
| // ```dart |
| // bool notConst = true; |
| // var map = const <int, int>{if ([!notConst!]) 1 : 2}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the map needs to be a constant map, then make the elements constants. |
| // In the spread example, you might do that by making the collection being |
| // spread a constant: |
| // |
| // ```dart |
| // const notConst = <int, int>{}; |
| // var map = const <int, int>{...notConst}; |
| // ``` |
| // |
| // If the map doesn't need to be a constant map, then remove the `const` |
| // keyword: |
| // |
| // ```dart |
| // bool notConst = true; |
| // var map = <int, int>{if (notConst) 1 : 2}; |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_MAP_ELEMENT = |
| CompileTimeErrorCode('NON_CONSTANT_MAP_ELEMENT', |
| "The elements in a const map literal must be constant.", |
| correction: "Try removing the keyword 'const' from the map literal.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a key in a constant map literal |
| // isn't a constant value. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic beause `a` isn't a constant: |
| // |
| // ```dart |
| // var a = 'a'; |
| // var m = const {[!a!]: 0}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the map needs to be a constant map, then make the key a constant: |
| // |
| // ```dart |
| // const a = 'a'; |
| // var m = const {a: 0}; |
| // ``` |
| // |
| // If the map doesn't need to be a constant map, then remove the `const` |
| // keyword: |
| // |
| // ```dart |
| // var a = 'a'; |
| // var m = {a: 0}; |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_MAP_KEY = CompileTimeErrorCode( |
| 'NON_CONSTANT_MAP_KEY', |
| "The keys in a const map literal must be constant.", |
| correction: "Try removing the keyword 'const' from the map literal.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode NON_CONSTANT_MAP_KEY_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'COLLECTION_ELEMENT_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as keys in a " |
| "'const' map literal.", |
| correction: |
| "Try removing the keyword 'const' from the map literal or removing " |
| "the keyword 'deferred' from the import.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_CONSTANT_MAP_KEY_FROM_DEFERRED_LIBRARY'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a value in a constant map |
| // literal isn't a constant value. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `a` isn't a constant: |
| // |
| // ```dart |
| // var a = 'a'; |
| // var m = const {0: [!a!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the map needs to be a constant map, then make the key a constant: |
| // |
| // ```dart |
| // const a = 'a'; |
| // var m = const {0: a}; |
| // ``` |
| // |
| // If the map doesn't need to be a constant map, then remove the `const` |
| // keyword: |
| // |
| // ```dart |
| // var a = 'a'; |
| // var m = {0: a}; |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_MAP_VALUE = |
| CompileTimeErrorCode('NON_CONSTANT_MAP_VALUE', |
| "The values in a const map literal must be constant.", |
| correction: "Try removing the keyword 'const' from the map literal.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| NON_CONSTANT_MAP_VALUE_FROM_DEFERRED_LIBRARY = CompileTimeErrorCode( |
| 'COLLECTION_ELEMENT_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as values in " |
| "a 'const' map literal.", |
| correction: |
| "Try removing the keyword 'const' from the map literal or removing " |
| "the keyword 'deferred' from the import.", |
| hasPublishedDocs: true, |
| uniqueName: 'NON_CONSTANT_MAP_VALUE_FROM_DEFERRED_LIBRARY'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constant set literal contains |
| // an element that isn't a compile-time constant. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `i` isn't a constant: |
| // |
| // ```dart |
| // var i = 0; |
| // |
| // var s = const {[!i!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the element can be changed to be a constant, then change it: |
| // |
| // ```dart |
| // const i = 0; |
| // |
| // var s = const {i}; |
| // ``` |
| // |
| // If the element can't be a constant, then remove the keyword `const`: |
| // |
| // ```dart |
| // var i = 0; |
| // |
| // var s = {i}; |
| // ``` |
| static const CompileTimeErrorCode NON_CONSTANT_SET_ELEMENT = |
| CompileTimeErrorCode('NON_CONSTANT_SET_ELEMENT', |
| "The values in a const set literal must be constants.", |
| correction: "Try removing the keyword 'const' from the set literal.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the non-generative constructor |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the initializer list of a |
| // constructor invokes a constructor from the superclass, and the invoked |
| // constructor is a factory constructor. Only a generative constructor can be |
| // invoked in the initializer list. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the invocation of the |
| // constructor `super.one()` is invoking a factory constructor: |
| // |
| // ```dart |
| // class A { |
| // factory A.one() = B; |
| // A.two(); |
| // } |
| // |
| // class B extends A { |
| // B() : [!super.one()!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the super invocation to invoke a generative constructor: |
| // |
| // ```dart |
| // class A { |
| // factory A.one() = B; |
| // A.two(); |
| // } |
| // |
| // class B extends A { |
| // B() : super.two(); |
| // } |
| // ``` |
| // |
| // If the generative constructor is the unnamed constructor, and if there are |
| // no arguments being passed to it, then you can remove the super invocation. |
| static const CompileTimeErrorCode NON_GENERATIVE_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'NON_GENERATIVE_CONSTRUCTOR', |
| "The generative constructor '{0}' is expected, but a factory was " |
| "found.", |
| correction: |
| "Try calling a different constructor of the superclass, or " |
| "making the called constructor not be a factory constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * An error code for when a class has no explicit constructor, and therefore |
| * a constructor is implicitly defined which uses a factory as a |
| * superinitializer. See [NON_GENERATIVE_CONSTRUCTOR]. |
| * |
| * Parameters: |
| * 0: the name of the superclass |
| * 1: the name of the current class |
| * 2: the implicitly called factory constructor of the superclass |
| */ |
| static const CompileTimeErrorCode NON_GENERATIVE_IMPLICIT_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'NON_GENERATIVE_IMPLICIT_CONSTRUCTOR', |
| "The unnamed constructor of superclass '{0}' (called by the default " |
| "constructor of '{1}') must be a generative constructor, " |
| "but factory found.", |
| correction: "Try adding an explicit constructor that has a different " |
| "superinitializer or changing the superclass constructor '{2}' " |
| "to not be a factory constructor."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the body of a factory |
| // constructor is marked with `async`, `async*`, or `sync*`. All constructors, |
| // including factory constructors, are required to return an instance of the |
| // class in which they're declared, not a `Future`, `Stream`, or `Iterator`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the body of the factory |
| // constructor is marked with `async`: |
| // |
| // ```dart |
| // class C { |
| // factory C() [!async!] { |
| // return C._(); |
| // } |
| // C._(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the member must be declared as a factory constructor, then remove the |
| // keyword appearing before the body: |
| // |
| // ```dart |
| // class C { |
| // factory C() { |
| // return C._(); |
| // } |
| // C._(); |
| // } |
| // ``` |
| // |
| // If the member must return something other than an instance of the enclosing |
| // class, then make the member a static method: |
| // |
| // ```dart |
| // class C { |
| // static Future<C> m() async { |
| // return C._(); |
| // } |
| // C._(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_SYNC_FACTORY = CompileTimeErrorCode( |
| 'NON_SYNC_FACTORY', |
| "Factory bodies can't use 'async', 'async*', or 'sync*'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name appearing where a type is expected |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an identifier that isn't a type |
| // is used as a type argument. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is a variable, not |
| // a type: |
| // |
| // ```dart |
| // var x = 0; |
| // List<[!x!]> xList = []; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the type argument to be a type: |
| // |
| // ```dart |
| // var x = 0; |
| // List<int> xList = []; |
| // ``` |
| static const CompileTimeErrorCode NON_TYPE_AS_TYPE_ARGUMENT = |
| CompileTimeErrorCode('NON_TYPE_AS_TYPE_ARGUMENT', |
| "The name '{0}' isn't a type so it can't be used as a type argument.", |
| correction: "Try correcting the name to an existing type, or " |
| "defining a type named '{0}'.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the non-type element |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the identifier following the |
| // `on` in a `catch` clause is defined to be something other than a type. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is a function, not |
| // a type: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f() { |
| // try { |
| // // ... |
| // } on [!f!] { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the name to the type of object that should be caught: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f() { |
| // try { |
| // // ... |
| // } on FormatException { |
| // // ... |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_TYPE_IN_CATCH_CLAUSE = |
| CompileTimeErrorCode( |
| 'NON_TYPE_IN_CATCH_CLAUSE', |
| "The name '{0}' isn't a type and can't be used in an on-catch " |
| "clause.", |
| correction: "Try correcting the name to match an existing class.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a declaration of the operator |
| // `[]=` has a return type other than `void`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the declaration of the |
| // operator `[]=` has a return type of `int`: |
| // |
| // ```dart |
| // class C { |
| // [!int!] operator []=(int index, int value) => 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the return type to `void`: |
| // |
| // ```dart |
| // class C { |
| // void operator []=(int index, int value) => 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_VOID_RETURN_FOR_OPERATOR = |
| CompileTimeErrorCode('NON_VOID_RETURN_FOR_OPERATOR', |
| "The return type of the operator []= must be 'void'.", |
| correction: "Try changing the return type to 'void'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a setter is defined with a |
| // return type other than `void`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the setter `p` has a |
| // return type of `int`: |
| // |
| // ```dart |
| // class C { |
| // [!int!] set p(int i) => 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the return type to `void` or omit the return type: |
| // |
| // ```dart |
| // class C { |
| // set p(int i) => 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode NON_VOID_RETURN_FOR_SETTER = |
| CompileTimeErrorCode('NON_VOID_RETURN_FOR_SETTER', |
| "The return type of the setter must be 'void' or absent.", |
| correction: "Try removing the return type, or " |
| "define a method rather than a setter.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name that is not a type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name is used as a type but |
| // declared to be something other than a type. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is a function: |
| // |
| // ```dart |
| // f() {} |
| // g([!f!] v) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the name with the name of a type. |
| static const CompileTimeErrorCode NOT_A_TYPE = CompileTimeErrorCode( |
| 'NOT_A_TYPE', "{0} isn't a type.", |
| correction: "Try correcting the name to match an existing type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the variable that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a local variable is referenced |
| // and has all these characteristics: |
| // - Has a type that's [potentially non-nullable][]. |
| // - Doesn't have an initializer. |
| // - Isn't marked as `late`. |
| // - The analyzer can't prove that the local variable will be assigned before |
| // the reference based on the specification of [definite assignment][]. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` can't have a value |
| // of `null`, but is referenced before a value was assigned to it: |
| // |
| // ```dart |
| // String f() { |
| // int x; |
| // return [!x!].toString(); |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the assignment to `x` |
| // might not be executed, so it might have a value of `null`: |
| // |
| // ```dart |
| // int g(bool b) { |
| // int x; |
| // if (b) { |
| // x = 1; |
| // } |
| // return [!x!] * 2; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the analyzer can't |
| // prove, based on definite assignment analysis, that `x` won't be referenced |
| // without having a value assigned to it: |
| // |
| // ```dart |
| // int h(bool b) { |
| // int x; |
| // if (b) { |
| // x = 1; |
| // } |
| // if (b) { |
| // return [!x!] * 2; |
| // } |
| // return 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If `null` is a valid value, then make the variable nullable: |
| // |
| // ```dart |
| // String f() { |
| // int? x; |
| // return x!.toString(); |
| // } |
| // ``` |
| // |
| // If `null` isn’t a valid value, and there's a reasonable default value, then |
| // add an initializer: |
| // |
| // ```dart |
| // int g(bool b) { |
| // int x = 2; |
| // if (b) { |
| // x = 1; |
| // } |
| // return x * 2; |
| // } |
| // ``` |
| // |
| // Otherwise, ensure that a value was assigned on every possible code path |
| // before the value is accessed: |
| // |
| // ```dart |
| // int g(bool b) { |
| // int x; |
| // if (b) { |
| // x = 1; |
| // } else { |
| // x = 2; |
| // } |
| // return x * 2; |
| // } |
| // ``` |
| // |
| // You can also mark the variable as `late`, which removes the diagnostic, but |
| // if the variable isn't assigned a value before it's accessed, then it |
| // results in an exception being thrown at runtime. This approach should only |
| // be used if you're sure that the variable will always be assigned, even |
| // though the analyzer can't prove it based on definite assignment analysis. |
| // |
| // ```dart |
| // int h(bool b) { |
| // late int x; |
| // if (b) { |
| // x = 1; |
| // } |
| // if (b) { |
| // return x * 2; |
| // } |
| // return 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| NOT_ASSIGNED_POTENTIALLY_NON_NULLABLE_LOCAL_VARIABLE = |
| CompileTimeErrorCode( |
| 'NOT_ASSIGNED_POTENTIALLY_NON_NULLABLE_LOCAL_VARIABLE', |
| "The non-nullable local variable '{0}' must be assigned before it " |
| "can be used.", |
| correction: "Try giving it an initializer expression, or ensure that " |
| "it's assigned on every execution path.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the operator that is not a binary operator. |
| */ |
| static const CompileTimeErrorCode NOT_BINARY_OPERATOR = CompileTimeErrorCode( |
| 'NOT_BINARY_OPERATOR', "'{0}' isn't a binary operator."); |
| |
| /** |
| * Parameters: |
| * 0: the expected number of required arguments |
| * 1: the actual number of positional arguments given |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function invocation |
| // has fewer positional arguments than the number of required positional |
| // parameters. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` declares two |
| // required parameters, but only one argument is provided: |
| // |
| // ```dart |
| // void f(int a, int b) {} |
| // void g() { |
| // f[!(0)!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add arguments corresponding to the remaining parameters: |
| // |
| // ```dart |
| // void f(int a, int b) {} |
| // void g() { |
| // f(0, 1); |
| // } |
| // ``` |
| static const CompileTimeErrorCode NOT_ENOUGH_POSITIONAL_ARGUMENTS = |
| CompileTimeErrorCode('NOT_ENOUGH_POSITIONAL_ARGUMENTS', |
| "{0} positional argument(s) expected, but {1} found.", |
| correction: "Try adding the missing arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field that is not initialized |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a field is declared and has all |
| // these characteristics: |
| // - Has a type that's [potentially non-nullable][] |
| // - Doesn't have an initializer |
| // - Isn't marked as `late` |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` is implicitly |
| // initialized to `null` when it isn't allowed to be `null`: |
| // |
| // ```dart |
| // class C { |
| // int [!x!]; |
| // } |
| // ``` |
| // |
| // Similarly, the following code produces this diagnostic because `x` is |
| // implicitly initialized to `null`, when it isn't allowed to be `null`, by |
| // one of the constructors, even though it's initialized by other |
| // constructors: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C(this.x); |
| // |
| // [!C!].n(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's a reasonable default value for the field that’s the same for all |
| // instances, then add an initializer expression: |
| // |
| // ```dart |
| // class C { |
| // int x = 0; |
| // } |
| // ``` |
| // |
| // If the value of the field should be provided when an instance is created, |
| // then add a constructor that sets the value of the field or update an |
| // existing constructor: |
| // |
| // ```dart |
| // class C { |
| // int x; |
| // |
| // C(this.x); |
| // } |
| // ``` |
| // |
| // You can also mark the field as `late`, which removes the diagnostic, but if |
| // the field isn't assigned a value before it's accessed, then it results in |
| // an exception being thrown at runtime. This approach should only be used if |
| // you're sure that the field will always be assigned before it's referenced. |
| // |
| // ```dart |
| // class C { |
| // late int x; |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| NOT_INITIALIZED_NON_NULLABLE_INSTANCE_FIELD = CompileTimeErrorCode( |
| 'NOT_INITIALIZED_NON_NULLABLE_INSTANCE_FIELD', |
| "Non-nullable instance field '{0}' must be initialized.", |
| correction: "Try adding an initializer expression, " |
| "or a generative constructor that initializes it, " |
| "or mark it 'late'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the field that is not initialized |
| */ |
| static const CompileTimeErrorCode |
| NOT_INITIALIZED_NON_NULLABLE_INSTANCE_FIELD_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'NOT_INITIALIZED_NON_NULLABLE_INSTANCE_FIELD', |
| "Non-nullable instance field '{0}' must be initialized.", |
| correction: "Try adding an initializer expression, " |
| "or add a field initializer in this constructor, " |
| "or mark it 'late'.", |
| hasPublishedDocs: true, |
| uniqueName: 'NOT_INITIALIZED_NON_NULLABLE_INSTANCE_FIELD_CONSTRUCTOR', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the variable that is invalid |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a static field or top-level |
| // variable has a type that's non-nullable and doesn't have an initializer. |
| // Fields and variables that don't have an initializer are normally |
| // initialized to `null`, but the type of the field or variable doesn't allow |
| // it to be set to `null`, so an explicit initializer must be provided. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the field `f` can't be |
| // initialized to `null`: |
| // |
| // ```dart |
| // class C { |
| // static int [!f!]; |
| // } |
| // ``` |
| // |
| // Similarly, the following code produces this diagnostic because the |
| // top-level variable `v` can't be initialized to `null`: |
| // |
| // ```dart |
| // int [!v!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the field or variable can't be initialized to `null`, then add an |
| // initializer that sets it to a non-null value: |
| // |
| // ```dart |
| // class C { |
| // static int f = 0; |
| // } |
| // ``` |
| // |
| // If the field or variable should be initialized to `null`, then change the |
| // type to be nullable: |
| // |
| // ```dart |
| // int? v; |
| // ``` |
| // |
| // If the field or variable can't be initialized in the declaration but will |
| // always be initialized before it's referenced, then mark it as being `late`: |
| // |
| // ```dart |
| // class C { |
| // static late int f; |
| // } |
| // ``` |
| static const CompileTimeErrorCode NOT_INITIALIZED_NON_NULLABLE_VARIABLE = |
| CompileTimeErrorCode('NOT_INITIALIZED_NON_NULLABLE_VARIABLE', |
| "The non-nullable variable '{0}' must be initialized.", |
| correction: "Try adding an initializer expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode NOT_INSTANTIATED_BOUND = |
| CompileTimeErrorCode('NOT_INSTANTIATED_BOUND', |
| 'Type parameter bound types must be instantiated.', |
| correction: 'Try adding type arguments to the type parameter bound.'); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode DISALLOWED_TYPE_INSTANTIATION_EXPRESSION = |
| CompileTimeErrorCode( |
| 'DISALLOWED_TYPE_INSTANTIATION_EXPRESSION', |
| 'Only a generic type, generic function, generic instance method, or ' |
| 'generic constructor can be type instantiated.', |
| correction: |
| 'Try instantiating the type(s) of a generic type, generic ' |
| 'function, generic instance method, or generic constructor.'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the static type of the |
| // expression of a spread element that appears in either a list literal or a |
| // set literal doesn't implement the type `Iterable`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic: |
| // |
| // ```dart |
| // var m = <String, int>{'a': 0, 'b': 1}; |
| // var s = <String>{...[!m!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // The most common fix is to replace the expression with one that produces an |
| // iterable object: |
| // |
| // ```dart |
| // var m = <String, int>{'a': 0, 'b': 1}; |
| // var s = <String>{...m.keys}; |
| // ``` |
| static const CompileTimeErrorCode NOT_ITERABLE_SPREAD = CompileTimeErrorCode( |
| 'NOT_ITERABLE_SPREAD', |
| "Spread elements in list or set literals must implement 'Iterable'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the static type of the |
| // expression of a spread element that appears in a map literal doesn't |
| // implement the type `Map`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `l` isn't a `Map`: |
| // |
| // ```dart |
| // var l = <String>['a', 'b']; |
| // var m = <int, String>{...[!l!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // The most common fix is to replace the expression with one that produces a |
| // map: |
| // |
| // ```dart |
| // var l = <String>['a', 'b']; |
| // var m = <int, String>{...l.asMap()}; |
| // ``` |
| static const CompileTimeErrorCode NOT_MAP_SPREAD = CompileTimeErrorCode( |
| 'NOT_MAP_SPREAD', "Spread elements in map literals must implement 'Map'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode NOT_NULL_AWARE_NULL_SPREAD = |
| CompileTimeErrorCode( |
| 'NOT_NULL_AWARE_NULL_SPREAD', |
| "The Null typed expression can't be used with a non-null-aware " |
| "spread."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class declaration uses an |
| // `extends` clause to specify a superclass, and the superclass is followed by |
| // a `?`. |
| // |
| // It isn't valid to specify a nullable superclass because doing so would have |
| // no meaning; it wouldn't change either the interface or implementation being |
| // inherited by the class containing the `extends` clause. |
| // |
| // Note, however, that it _is_ valid to use a nullable type as a type argument |
| // to the superclass, such as `class A extends B<C?> {}`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `A?` is a nullable |
| // type, and nullable types can't be used in an `extends` clause: |
| // |
| // ```dart |
| // class A {} |
| // class B extends [!A?!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the question mark from the type: |
| // |
| // ```dart |
| // class A {} |
| // class B extends A {} |
| // ``` |
| static const CompileTimeErrorCode NULLABLE_TYPE_IN_EXTENDS_CLAUSE = |
| CompileTimeErrorCode('NULLABLE_TYPE_IN_EXTENDS_CLAUSE', |
| "A class can't extend a nullable type.", |
| correction: "Try removing the question mark.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class or mixin declaration has |
| // an `implements` clause, and an interface is followed by a `?`. |
| // |
| // It isn't valid to specify a nullable interface because doing so would have |
| // no meaning; it wouldn't change the interface being inherited by the class |
| // containing the `implements` clause. |
| // |
| // Note, however, that it _is_ valid to use a nullable type as a type argument |
| // to the interface, such as `class A implements B<C?> {}`. |
| // |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `A?` is a nullable |
| // type, and nullable types can't be used in an `implements` clause: |
| // |
| // ```dart |
| // class A {} |
| // class B implements [!A?!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the question mark from the type: |
| // |
| // ```dart |
| // class A {} |
| // class B implements A {} |
| // ``` |
| static const CompileTimeErrorCode NULLABLE_TYPE_IN_IMPLEMENTS_CLAUSE = |
| CompileTimeErrorCode('NULLABLE_TYPE_IN_IMPLEMENTS_CLAUSE', |
| "A class or mixin can't implement a nullable type.", |
| correction: "Try removing the question mark.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a mixin declaration uses an `on` |
| // clause to specify a superclass constraint, and the class that's specified |
| // is followed by a `?`. |
| // |
| // It isn't valid to specify a nullable superclass constraint because doing so |
| // would have no meaning; it wouldn't change the interface being depended on |
| // by the mixin containing the `on` clause. |
| // |
| // Note, however, that it _is_ valid to use a nullable type as a type argument |
| // to the superclass constraint, such as `mixin A on B<C?> {}`. |
| // |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `A?` is a nullable type |
| // and nullable types can't be used in an `on` clause: |
| // |
| // ```dart |
| // class C {} |
| // mixin M on [!C?!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the question mark from the type: |
| // |
| // ```dart |
| // class C {} |
| // mixin M on C {} |
| // ``` |
| static const CompileTimeErrorCode NULLABLE_TYPE_IN_ON_CLAUSE = |
| CompileTimeErrorCode('NULLABLE_TYPE_IN_ON_CLAUSE', |
| "A mixin can't have a nullable type as a superclass constraint.", |
| correction: "Try removing the question mark.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class or mixin declaration has |
| // a `with` clause, and a mixin is followed by a `?`. |
| // |
| // It isn't valid to specify a nullable mixin because doing so would have no |
| // meaning; it wouldn't change either the interface or implementation being |
| // inherited by the class containing the `with` clause. |
| // |
| // Note, however, that it _is_ valid to use a nullable type as a type argument |
| // to the mixin, such as `class A with B<C?> {}`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `A?` is a nullable |
| // type, and nullable types can't be used in a `with` clause: |
| // |
| // ```dart |
| // mixin M {} |
| // class C with [!M?!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the question mark from the type: |
| // |
| // ```dart |
| // mixin M {} |
| // class C with M {} |
| // ``` |
| static const CompileTimeErrorCode NULLABLE_TYPE_IN_WITH_CLAUSE = |
| CompileTimeErrorCode('NULLABLE_TYPE_IN_WITH_CLAUSE', |
| "A class or mixin can't mix in a nullable type.", |
| correction: "Try removing the question mark.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.9 Superclasses: It is a compile-time error to specify an extends clause |
| * for class Object. |
| */ |
| static const CompileTimeErrorCode OBJECT_CANNOT_EXTEND_ANOTHER_CLASS = |
| CompileTimeErrorCode('OBJECT_CANNOT_EXTEND_ANOTHER_CLASS', |
| "The class 'Object' can't extend any other class."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the interface that is implemented more than once |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the same type is listed in the |
| // superclass constraints of a mixin multiple times. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `A` is included twice |
| // in the superclass constraints for `M`: |
| // |
| // ```dart |
| // mixin M on A, [!A!] { |
| // } |
| // |
| // class A {} |
| // class B {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If a different type should be included in the superclass constraints, then |
| // replace one of the occurrences with the other type: |
| // |
| // ```dart |
| // mixin M on A, B { |
| // } |
| // |
| // class A {} |
| // class B {} |
| // ``` |
| // |
| // If no other type was intended, then remove the repeated type name: |
| // |
| // ```dart |
| // mixin M on A { |
| // } |
| // |
| // class A {} |
| // class B {} |
| // ``` |
| static const CompileTimeErrorCode ON_REPEATED = CompileTimeErrorCode( |
| 'ON_REPEATED', |
| "The type '{0}' can be included in the superclass constraints only once.", |
| correction: "Try removing all except one occurrence of the type name.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when one or more of the parameters in |
| // an operator declaration are optional. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the parameter `other` |
| // is an optional parameter: |
| // |
| // ```dart |
| // class C { |
| // C operator +([[!C? other!]]) => this; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Make all of the parameters be required parameters: |
| // |
| // ```dart |
| // class C { |
| // C operator +(C other) => this; |
| // } |
| // ``` |
| static const CompileTimeErrorCode OPTIONAL_PARAMETER_IN_OPERATOR = |
| CompileTimeErrorCode('OPTIONAL_PARAMETER_IN_OPERATOR', |
| "Optional parameters aren't allowed when defining an operator.", |
| correction: "Try removing the optional parameters.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of expected library name |
| * 1: the non-matching actual library name from the "part of" declaration |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a library attempts to include a |
| // file as a part of itself when the other file is a part of a different |
| // library. |
| // |
| // #### Example |
| // |
| // Given a file named `part.dart` containing |
| // |
| // ```dart |
| // %uri="package:a/part.dart" |
| // part of 'library.dart'; |
| // ``` |
| // |
| // The following code, in any file other than `library.dart`, produces this |
| // diagnostic because it attempts to include `part.dart` as a part of itself |
| // when `part.dart` is a part of a different library: |
| // |
| // ```dart |
| // part [!'package:a/part.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the library should be using a different file as a part, then change the |
| // URI in the part directive to be the URI of the other file. |
| // |
| // If the part file should be a part of this library, then update the URI (or |
| // library name) in the part-of directive to be the URI (or name) of the |
| // correct library. |
| static const CompileTimeErrorCode PART_OF_DIFFERENT_LIBRARY = |
| CompileTimeErrorCode('PART_OF_DIFFERENT_LIBRARY', |
| "Expected this library to be part of '{0}', not '{1}'.", |
| correction: "Try including a different part, or changing the name of " |
| "the library in the part's part-of directive.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the uri pointing to a non-library declaration |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a part directive is found and |
| // the referenced file doesn't have a part-of directive. |
| // |
| // #### Examples |
| // |
| // Given a file (`a.dart`) containing: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class A {} |
| // ``` |
| // |
| // The following code produces this diagnostic because `a.dart` doesn't |
| // contain a part-of directive: |
| // |
| // ```dart |
| // part [!'a.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the referenced file is intended to be a part of another library, then |
| // add a part-of directive to the file: |
| // |
| // ```dart |
| // part of 'test.dart'; |
| // |
| // class A {} |
| // ``` |
| // |
| // If the referenced file is intended to be a library, then replace the part |
| // directive with an import directive: |
| // |
| // ```dart |
| // import 'a.dart'; |
| // ``` |
| static const CompileTimeErrorCode PART_OF_NON_PART = CompileTimeErrorCode( |
| 'PART_OF_NON_PART', |
| "The included part '{0}' must have a part-of directive.", |
| correction: "Try adding a part-of directive to '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the URI of the expected library |
| * 1: the non-matching actual library name from the "part of" declaration |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a library that doesn't have a |
| // `library` directive (and hence has no name) contains a `part` directive and |
| // the `part of` directive in the part file uses a name to specify the library |
| // that it's a part of. |
| // |
| // #### Example |
| // |
| // Given a part file named `part_file.dart` containing the following code: |
| // |
| // ```dart |
| // %uri="lib/part_file.dart" |
| // part of lib; |
| // ``` |
| // |
| // The following code produces this diagnostic because the library including |
| // the part file doesn't have a name even though the part file uses a name to |
| // specify which library it's a part of: |
| // |
| // ```dart |
| // part [!'part_file.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the `part of` directive in the part file to specify its library by |
| // URI: |
| // |
| // ```dart |
| // part of 'test.dart'; |
| // ``` |
| static const CompileTimeErrorCode PART_OF_UNNAMED_LIBRARY = |
| CompileTimeErrorCode( |
| 'PART_OF_UNNAMED_LIBRARY', |
| "The library is unnamed. A URI is expected, not a library name " |
| "'{0}', in the part-of directive.", |
| correction: |
| "Try changing the part-of directive to a URI, or try including a " |
| "different part.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the prefix |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name is used as both an import |
| // prefix and the name of a top-level declaration in the same library. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `f` is used as both an |
| // import prefix and the name of a function: |
| // |
| // ```dart |
| // import 'dart:math' as f; |
| // |
| // int [!f!]() => f.min(0, 1); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you want to use the name for the import prefix, then rename the |
| // top-level declaration: |
| // |
| // ```dart |
| // import 'dart:math' as f; |
| // |
| // int g() => f.min(0, 1); |
| // ``` |
| // |
| // If you want to use the name for the top-level declaration, then rename the |
| // import prefix: |
| // |
| // ```dart |
| // import 'dart:math' as math; |
| // |
| // int f() => math.min(0, 1); |
| // ``` |
| static const CompileTimeErrorCode PREFIX_COLLIDES_WITH_TOP_LEVEL_MEMBER = |
| CompileTimeErrorCode( |
| 'PREFIX_COLLIDES_WITH_TOP_LEVEL_MEMBER', |
| "The name '{0}' is already used as an import prefix and can't be " |
| "used to name a top-level element.", |
| correction: |
| "Try renaming either the top-level element or the prefix.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the prefix |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an import prefix is used by |
| // itself, without accessing any of the names declared in the libraries |
| // associated with the prefix. Prefixes aren't variables, and therefore can't |
| // be used as a value. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the prefix `math` is |
| // being used as if it were a variable: |
| // |
| // ```dart |
| // import 'dart:math' as math; |
| // |
| // void f() { |
| // print([!math!]); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the code is incomplete, then reference something in one of the libraries |
| // associated with the prefix: |
| // |
| // ```dart |
| // import 'dart:math' as math; |
| // |
| // void f() { |
| // print(math.pi); |
| // } |
| // ``` |
| // |
| // If the name is wrong, then correct the name. |
| static const CompileTimeErrorCode PREFIX_IDENTIFIER_NOT_FOLLOWED_BY_DOT = |
| CompileTimeErrorCode( |
| 'PREFIX_IDENTIFIER_NOT_FOLLOWED_BY_DOT', |
| "The name '{0}' refers to an import prefix, so it must be followed " |
| "by '.'.", |
| correction: |
| "Try correcting the name to refer to something other than a " |
| "prefix, or renaming the prefix.", |
| hasPublishedDocs: true); |
| |
| /** |
| * From the `Static Types` section of the spec: |
| * |
| * A type T is malformed if: |
| * - T has the form id or the form prefix.id, and in the enclosing lexical |
| * scope, the name id (respectively prefix.id) does not denote a type. |
| * |
| * In particular, this means that if an import prefix is shadowed by a local |
| * declaration, it is an error to try to use it as a prefix for a type name. |
| */ |
| static const CompileTimeErrorCode PREFIX_SHADOWED_BY_LOCAL_DECLARATION = |
| CompileTimeErrorCode( |
| 'PREFIX_SHADOWED_BY_LOCAL_DECLARATION', |
| "The prefix '{0}' can't be used here because it is shadowed by a " |
| "local declaration.", |
| correction: |
| "Try renaming either the prefix or the local declaration."); |
| |
| /** |
| * Parameters: |
| * 0: the private name that collides |
| * 1: the name of the first mixin |
| * 2: the name of the second mixin |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when two mixins that define the same |
| // private member are used together in a single class in a library other than |
| // the one that defines the mixins. |
| // |
| // #### Example |
| // |
| // Given a file named `a.dart` containing the following code: |
| // |
| // ```dart |
| // %uri="lib/a.dart" |
| // class A { |
| // void _foo() {} |
| // } |
| // |
| // class B { |
| // void _foo() {} |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the classes `A` and `B` |
| // both define the method `_foo`: |
| // |
| // ```dart |
| // import 'a.dart'; |
| // |
| // class C extends Object with A, [!B!] {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you don't need both of the mixins, then remove one of them from the |
| // `with` clause: |
| // |
| // ```dart |
| // import 'a.dart'; |
| // |
| // class C extends Object with A, [!B!] {} |
| // ``` |
| // |
| // If you need both of the mixins, then rename the conflicting member in one |
| // of the two mixins. |
| static const CompileTimeErrorCode PRIVATE_COLLISION_IN_MIXIN_APPLICATION = |
| CompileTimeErrorCode( |
| 'PRIVATE_COLLISION_IN_MIXIN_APPLICATION', |
| "The private name '{0}', defined by '{1}', " |
| "conflicts with the same name defined by '{2}'.", |
| correction: "Try removing '{1}' from the 'with' clause.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name of a named parameter |
| // starts with an underscore. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the named parameter |
| // `_x` starts with an underscore: |
| // |
| // ```dart |
| // class C { |
| // void m({int [!_x!] = 0}) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rename the parameter so that it doesn't start with an underscore: |
| // |
| // ```dart |
| // class C { |
| // void m({int x = 0}) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode PRIVATE_OPTIONAL_PARAMETER = |
| CompileTimeErrorCode('PRIVATE_OPTIONAL_PARAMETER', |
| "Named parameters can't start with an underscore.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode PRIVATE_SETTER = CompileTimeErrorCode( |
| 'PRIVATE_SETTER', |
| "The setter '{0}' is private and can't be accessed outside of the " |
| "library that declares it.", |
| correction: "Try making it public."); |
| |
| static const CompileTimeErrorCode READ_POTENTIALLY_UNASSIGNED_FINAL = |
| CompileTimeErrorCode( |
| 'READ_POTENTIALLY_UNASSIGNED_FINAL', |
| "The final variable '{0}' can't be read because it is potentially " |
| "unassigned at this point.", |
| correction: "Ensure that it is assigned on necessary execution paths.", |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the value of a compile-time |
| // constant is defined in terms of itself, either directly or indirectly, |
| // creating an infinite loop. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic twice because both of the |
| // constants are defined in terms of the other: |
| // |
| // ```dart |
| // const [!secondsPerHour!] = minutesPerHour * 60; |
| // const [!minutesPerHour!] = secondsPerHour / 60; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Break the cycle by finding an alternative way of defining at least one of |
| // the constants: |
| // |
| // ```dart |
| // const secondsPerHour = minutesPerHour * 60; |
| // const minutesPerHour = 60; |
| // ``` |
| static const CompileTimeErrorCode RECURSIVE_COMPILE_TIME_CONSTANT = |
| CompileTimeErrorCode('RECURSIVE_COMPILE_TIME_CONSTANT', |
| "The compile-time constant expression depends on itself.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| * |
| * TODO(scheglov) review this later, there are no explicit "it is a |
| * compile-time error" in specification. But it was added to the co19 and |
| * there is same error for factories. |
| * |
| * https://code.google.com/p/dart/issues/detail?id=954 |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor redirects to |
| // itself, either directly or indirectly, creating an infinite loop. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the generative |
| // constructors `C.a` and `C.b` each redirect to the other: |
| // |
| // ```dart |
| // class C { |
| // C.a() : [!this.b()!]; |
| // C.b() : [!this.a()!]; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the factory |
| // constructors `A` and `B` each redirect to the other: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = [!B!]; |
| // } |
| // class B implements A { |
| // factory B() = [!A!]; |
| // B.named(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // In the case of generative constructors, break the cycle by finding defining |
| // at least one of the constructors to not redirect to another constructor: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(); |
| // C.b(); |
| // } |
| // ``` |
| // |
| // In the case of factory constructors, break the cycle by defining at least |
| // one of the factory constructors to do one of the following: |
| // |
| // - Redirect to a generative constructor: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = B; |
| // } |
| // class B implements A { |
| // factory B() = B.named; |
| // B.named(); |
| // } |
| // ``` |
| // |
| // - Not redirect to another constructor: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = B; |
| // } |
| // class B implements A { |
| // factory B() { |
| // return B.named(); |
| // } |
| // |
| // B.named(); |
| // } |
| // ``` |
| // |
| // - Not be a factory constructor: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = B; |
| // } |
| // class B implements A { |
| // B(); |
| // B.named(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode RECURSIVE_CONSTRUCTOR_REDIRECT = |
| CompileTimeErrorCode( |
| 'RECURSIVE_CONSTRUCTOR_REDIRECT', |
| "Constructors can't redirect to themselves either directly or " |
| "indirectly.", |
| correction: 'Try changing one of the constructors in the loop to not ' |
| 'redirect.', |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode RECURSIVE_FACTORY_REDIRECT = |
| CompileTimeErrorCode( |
| 'RECURSIVE_CONSTRUCTOR_REDIRECT', |
| "Constructors can't redirect to themselves either directly or " |
| "indirectly.", |
| correction: 'Try changing one of the constructors in the loop to not ' |
| 'redirect.', |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_FACTORY_REDIRECT'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class that implements itself recursively |
| * 1: a string representation of the implements loop |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when there's a circularity in the |
| // type hierarchy. This happens when a type, either directly or indirectly, |
| // is declared to be a subtype of itself. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the class `A` is |
| // declared to be a subtype of `B`, and `B` is a subtype of `A`: |
| // |
| // ```dart |
| // class [!A!] extends B {} |
| // class B implements A {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the type hierarchy so that there's no circularity. |
| static const CompileTimeErrorCode RECURSIVE_INTERFACE_INHERITANCE = |
| CompileTimeErrorCode('RECURSIVE_INTERFACE_INHERITANCE', |
| "'{0}' can't be a superinterface of itself: {1}.", |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_INTERFACE_INHERITANCE'); |
| |
| /** |
| * 7.10 Superinterfaces: It is a compile-time error if the interface of a |
| * class <i>C</i> is a superinterface of itself. |
| * |
| * 8.1 Superinterfaces: It is a compile-time error if an interface is a |
| * superinterface of itself. |
| * |
| * 7.9 Superclasses: It is a compile-time error if a class <i>C</i> is a |
| * superclass of itself. |
| * |
| * Parameters: |
| * 0: the name of the class that implements itself recursively |
| */ |
| static const CompileTimeErrorCode RECURSIVE_INTERFACE_INHERITANCE_EXTENDS = |
| CompileTimeErrorCode( |
| 'RECURSIVE_INTERFACE_INHERITANCE', "'{0}' can't extend itself.", |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_INTERFACE_INHERITANCE_EXTENDS'); |
| |
| /** |
| * 7.10 Superinterfaces: It is a compile-time error if the interface of a |
| * class <i>C</i> is a superinterface of itself. |
| * |
| * 8.1 Superinterfaces: It is a compile-time error if an interface is a |
| * superinterface of itself. |
| * |
| * 7.9 Superclasses: It is a compile-time error if a class <i>C</i> is a |
| * superclass of itself. |
| * |
| * Parameters: |
| * 0: the name of the class that implements itself recursively |
| */ |
| static const CompileTimeErrorCode RECURSIVE_INTERFACE_INHERITANCE_IMPLEMENTS = |
| CompileTimeErrorCode( |
| 'RECURSIVE_INTERFACE_INHERITANCE', "'{0}' can't implement itself.", |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_INTERFACE_INHERITANCE_IMPLEMENTS'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the mixin that constraints itself recursively |
| */ |
| static const CompileTimeErrorCode RECURSIVE_INTERFACE_INHERITANCE_ON = |
| CompileTimeErrorCode('RECURSIVE_INTERFACE_INHERITANCE', |
| "'{0}' can't use itself as a superclass constraint.", |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_INTERFACE_INHERITANCE_ON'); |
| |
| /** |
| * 7.10 Superinterfaces: It is a compile-time error if the interface of a |
| * class <i>C</i> is a superinterface of itself. |
| * |
| * 8.1 Superinterfaces: It is a compile-time error if an interface is a |
| * superinterface of itself. |
| * |
| * 7.9 Superclasses: It is a compile-time error if a class <i>C</i> is a |
| * superclass of itself. |
| * |
| * Parameters: |
| * 0: the name of the class that implements itself recursively |
| */ |
| static const CompileTimeErrorCode RECURSIVE_INTERFACE_INHERITANCE_WITH = |
| CompileTimeErrorCode('RECURSIVE_INTERFACE_INHERITANCE', |
| "'{0}' can't use itself as a mixin.", |
| hasPublishedDocs: true, |
| uniqueName: 'RECURSIVE_INTERFACE_INHERITANCE_WITH'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a generative constructor |
| // redirects to a constructor that isn't defined. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constructor `C.a` |
| // redirects to the constructor `C.b`, but `C.b` isn't defined: |
| // |
| // ```dart |
| // class C { |
| // C.a() : [!this.b()!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the missing constructor must be called, then define it: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(); |
| // C.b(); |
| // } |
| // ``` |
| // |
| // If the missing constructor doesn't need to be called, then remove the |
| // redirect: |
| // |
| // ```dart |
| // class C { |
| // C.a(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode REDIRECT_GENERATIVE_TO_MISSING_CONSTRUCTOR = |
| CompileTimeErrorCode('REDIRECT_GENERATIVE_TO_MISSING_CONSTRUCTOR', |
| "The constructor '{0}' couldn't be found in '{1}'.", |
| correction: "Try redirecting to a different constructor, or " |
| "defining the constructor named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a generative constructor |
| // redirects to a factory constructor. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the generative |
| // constructor `C.a` redirects to the factory constructor `C.b`: |
| // |
| // ```dart |
| // class C { |
| // C.a() : [!this.b()!]; |
| // factory C.b() => C.a(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the generative constructor doesn't need to redirect to another |
| // constructor, then remove the redirect. |
| // |
| // ```dart |
| // class C { |
| // C.a(); |
| // factory C.b() => C.a(); |
| // } |
| // ``` |
| // |
| // If the generative constructor must redirect to another constructor, then |
| // make the other constructor be a generative (non-factory) constructor: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(); |
| // C.b(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| REDIRECT_GENERATIVE_TO_NON_GENERATIVE_CONSTRUCTOR = CompileTimeErrorCode( |
| 'REDIRECT_GENERATIVE_TO_NON_GENERATIVE_CONSTRUCTOR', |
| "Generative constructors can't redirect to a factory constructor.", |
| correction: "Try redirecting to a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * A factory constructor can't redirect to a non-generative constructor of an |
| * abstract class. |
| */ |
| static const CompileTimeErrorCode REDIRECT_TO_ABSTRACT_CLASS_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'REDIRECT_TO_ABSTRACT_CLASS_CONSTRUCTOR', |
| "The redirecting constructor '{0}' can't redirect to a constructor " |
| "of the abstract class '{1}'.", |
| correction: "Try redirecting to a constructor of a different class."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the redirected constructor |
| * 1: the name of the redirecting constructor |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a factory constructor attempts |
| // to redirect to another constructor, but the two have incompatible |
| // parameters. The parameters are compatible if all of the parameters of the |
| // redirecting constructor can be passed to the other constructor and if the |
| // other constructor doesn't require any parameters that aren't declared by |
| // the redirecting constructor. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the constructor for `A` |
| // doesn't declare a parameter that the constructor for `B` requires: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = [!B!]; |
| // } |
| // |
| // class B implements A { |
| // B(int x); |
| // B.zero(); |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the constructor for `A` |
| // declares a named parameter (`y`) that the constructor for `B` doesn't |
| // allow: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A(int x, {int y}) = [!B!]; |
| // } |
| // |
| // class B implements A { |
| // B(int x); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's a different constructor that is compatible with the redirecting |
| // constructor, then redirect to that constructor: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A() = B.zero; |
| // } |
| // |
| // class B implements A { |
| // B(int x); |
| // B.zero(); |
| // } |
| // ``` |
| // |
| // Otherwise, update the redirecting constructor to be compatible: |
| // |
| // ```dart |
| // abstract class A { |
| // factory A(int x) = B; |
| // } |
| // |
| // class B implements A { |
| // B(int x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode REDIRECT_TO_INVALID_FUNCTION_TYPE = |
| CompileTimeErrorCode( |
| 'REDIRECT_TO_INVALID_FUNCTION_TYPE', |
| "The redirected constructor '{0}' has incompatible parameters with " |
| "'{1}'.", |
| correction: "Try redirecting to a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the redirected constructor's return type |
| * 1: the name of the redirecting constructor's return type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a factory constructor redirects |
| // to a constructor whose return type isn't a subtype of the type that the |
| // factory constructor is declared to produce. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `A` isn't a subclass |
| // of `C`, which means that the value returned by the constructor `A()` |
| // couldn't be returned from the constructor `C()`: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B implements C {} |
| // |
| // class C { |
| // factory C() = [!A!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the factory constructor is redirecting to a constructor in the wrong |
| // class, then update the factory constructor to redirect to the correct |
| // constructor: |
| // |
| // ```dart |
| // class A {} |
| // |
| // class B implements C {} |
| // |
| // class C { |
| // factory C() = B; |
| // } |
| // ``` |
| // |
| // If the class defining the constructor being redirected to is the class that |
| // should be returned, then make it a subtype of the factory's return type: |
| // |
| // ```dart |
| // class A implements C {} |
| // |
| // class B implements C {} |
| // |
| // class C { |
| // factory C() = A; |
| // } |
| // ``` |
| static const CompileTimeErrorCode REDIRECT_TO_INVALID_RETURN_TYPE = |
| CompileTimeErrorCode( |
| 'REDIRECT_TO_INVALID_RETURN_TYPE', |
| "The return type '{0}' of the redirected constructor isn't " |
| "a subtype of '{1}'.", |
| correction: "Try redirecting to a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.6.2 Factories: It is a compile-time error if <i>k</i> is prefixed with |
| * the const modifier but <i>k'</i> is not a constant constructor. |
| */ |
| static const CompileTimeErrorCode REDIRECT_TO_MISSING_CONSTRUCTOR = |
| CompileTimeErrorCode('REDIRECT_TO_MISSING_CONSTRUCTOR', |
| "The constructor '{0}' couldn't be found in '{1}'.", |
| correction: "Try redirecting to a different constructor, or " |
| "define the constructor named '{0}'."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the non-type referenced in the redirect |
| */ |
| // #### Description |
| // |
| // One way to implement a factory constructor is to redirect to another |
| // constructor by referencing the name of the constructor. The analyzer |
| // produces this diagnostic when the redirect is to something other than a |
| // constructor. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is a function: |
| // |
| // ```dart |
| // C f() => throw 0; |
| // |
| // class C { |
| // factory C() = [!f!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the constructor isn't defined, then either define it or replace it with |
| // a constructor that is defined. |
| // |
| // If the constructor is defined but the class that defines it isn't visible, |
| // then you probably need to add an import. |
| // |
| // If you're trying to return the value returned by a function, then rewrite |
| // the constructor to return the value from the constructor's body: |
| // |
| // ```dart |
| // C f() => throw 0; |
| // |
| // class C { |
| // factory C() => f(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode REDIRECT_TO_NON_CLASS = |
| CompileTimeErrorCode( |
| 'REDIRECT_TO_NON_CLASS', |
| "The name '{0}' isn't a type and can't be used in a redirected " |
| "constructor.", |
| correction: "Try redirecting to a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor marked as `const` |
| // redirects to a constructor that isn't marked as `const`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constructor `C.a` |
| // is marked as `const` but redirects to the constructor `C.b`, which isn't: |
| // |
| // ```dart |
| // class C { |
| // const C.a() : this.[!b!](); |
| // C.b(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the non-constant constructor can be marked as `const`, then mark it as |
| // `const`: |
| // |
| // ```dart |
| // class C { |
| // const C.a() : this.b(); |
| // const C.b(); |
| // } |
| // ``` |
| // |
| // If the non-constant constructor can't be marked as `const`, then either |
| // remove the redirect or remove `const` from the redirecting constructor: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(); |
| // C.b(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode REDIRECT_TO_NON_CONST_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'REDIRECT_TO_NON_CONST_CONSTRUCTOR', |
| "A constant redirecting constructor can't redirect to a non-constant " |
| "constructor.", |
| correction: "Try redirecting to a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * It is a compile-time error for a redirecting factory constructor to have |
| * a body which is a type alias that expands to a type variable, or a body |
| * which is a parameterized type of the form `F<T1, .. Tk>`, where `F` is |
| * a type alias that expands to a type variable. |
| */ |
| static const CompileTimeErrorCode |
| REDIRECT_TO_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER = CompileTimeErrorCode( |
| 'REDIRECT_TO_TYPE_ALIAS_EXPANDS_TO_TYPE_PARAMETER', |
| "Redirecting constructor can't redirect to a type alias " |
| "that expands to a type parameter.", |
| correction: "Try replacing it with a class."); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a variable is referenced before |
| // it’s declared. In Dart, variables are visible everywhere in the block in |
| // which they are declared, but can only be referenced after they are |
| // declared. |
| // |
| // The analyzer also produces a context message that indicates where the |
| // declaration is located. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `i` is used before it |
| // is declared: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f() { |
| // print([!i!]); |
| // int i = 5; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intended to reference the local variable, move the declaration |
| // before the first reference: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f() { |
| // int i = 5; |
| // print(i); |
| // } |
| // ``` |
| // |
| // If you intended to reference a name from an outer scope, such as a |
| // parameter, instance field or top-level variable, then rename the local |
| // declaration so that it doesn't hide the outer variable. |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(int i) { |
| // print(i); |
| // int x = 5; |
| // print(x); |
| // } |
| // ``` |
| static const CompileTimeErrorCode REFERENCED_BEFORE_DECLARATION = |
| CompileTimeErrorCode('REFERENCED_BEFORE_DECLARATION', |
| "Local variable '{0}' can't be referenced before it is declared.", |
| correction: "Try moving the declaration to before the first use, or " |
| "renaming the local variable so that it doesn't hide a name from " |
| "an enclosing scope.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a `rethrow` statement is outside |
| // a `catch` clause. The `rethrow` statement is used to throw a caught |
| // exception again, but there's no caught exception outside of a `catch` |
| // clause. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the`rethrow` statement |
| // is outside of a `catch` clause: |
| // |
| // ```dart |
| // void f() { |
| // [!rethrow!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you're trying to rethrow an exception, then wrap the `rethrow` statement |
| // in a `catch` clause: |
| // |
| // ```dart |
| // void f() { |
| // try { |
| // // ... |
| // } catch (exception) { |
| // rethrow; |
| // } |
| // } |
| // ``` |
| // |
| // If you're trying to throw a new exception, then replace the `rethrow` |
| // statement with a `throw` expression: |
| // |
| // ```dart |
| // void f() { |
| // throw UnsupportedError('Not yet implemented'); |
| // } |
| // ``` |
| static const CompileTimeErrorCode RETHROW_OUTSIDE_CATCH = |
| CompileTimeErrorCode('RETHROW_OUTSIDE_CATCH', |
| "A rethrow must be inside of a catch clause.", |
| correction: |
| "Try moving the expression into a catch clause, or using a " |
| "'throw' expression.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a generative constructor |
| // contains a `return` statement that specifies a value to be returned. |
| // Generative constructors always return the object that was created, and |
| // therefore can't return a different object. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the `return` statement |
| // has an expression: |
| // |
| // ```dart |
| // class C { |
| // C() { |
| // return [!this!]; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the constructor should create a new instance, then remove either the |
| // `return` statement or the expression: |
| // |
| // ```dart |
| // class C { |
| // C(); |
| // } |
| // ``` |
| // |
| // If the constructor shouldn't create a new instance, then convert it to be a |
| // factory constructor: |
| // |
| // ```dart |
| // class C { |
| // factory C() { |
| // return _instance; |
| // } |
| // |
| // static C _instance = C._(); |
| // |
| // C._(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode RETURN_IN_GENERATIVE_CONSTRUCTOR = |
| CompileTimeErrorCode('RETURN_IN_GENERATIVE_CONSTRUCTOR', |
| "Constructors can't return values.", |
| correction: "Try removing the return statement or using a factory " |
| "constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a generator function (one whose |
| // body is marked with either `async*` or `sync*`) uses a `return` statement |
| // to return a value. In both cases, they should use `yield` instead of |
| // `return`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the method `f` is a |
| // generator and is using `return` to return a value: |
| // |
| // ```dart |
| // Iterable<int> f() sync* { |
| // [!return 3!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the method is intended to be a generator, then use `yield` to return a |
| // value: |
| // |
| // ```dart |
| // Iterable<int> f() sync* { |
| // yield 3; |
| // } |
| // ``` |
| // |
| // If the method isn't intended to be a generator, then remove the modifier |
| // from the body (or use `async` if you're returning a future): |
| // |
| // ```dart |
| // int f() { |
| // return 3; |
| // } |
| // ``` |
| static const CompileTimeErrorCode RETURN_IN_GENERATOR = CompileTimeErrorCode( |
| 'RETURN_IN_GENERATOR', |
| "Can't return a value from a generator function that uses the 'async*' " |
| "or 'sync*' modifier.", |
| // TODO(srawlins): Splitting this code into two cases, one for block- |
| // bodied, and one for expression-bodied, would improve each correction |
| // message. This split would have to be done in the parser. |
| correction: "Try replacing 'return' with 'yield', using a block function " |
| "body, or changing the method body modifier.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the return type as declared in the return statement |
| * 1: the expected return type as defined by the method |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the static type of a returned |
| // expression isn't assignable to the return type that the closure is required |
| // to have. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` is defined to be a |
| // function that returns a `String`, but the closure assigned to it returns an |
| // `int`: |
| // |
| // ```dart |
| // String Function(String) f = (s) => [!3!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the return type is correct, then replace the returned value with a value |
| // of the correct type, possibly by converting the existing value: |
| // |
| // ```dart |
| // String Function(String) f = (s) => 3.toString(); |
| // ``` |
| static const CompileTimeErrorCode RETURN_OF_INVALID_TYPE_FROM_CLOSURE = |
| CompileTimeErrorCode( |
| 'RETURN_OF_INVALID_TYPE_FROM_CLOSURE', |
| "The return type '{0}' isn't a '{1}', as required by the closure's " |
| "context.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the return type as declared in the return statement |
| * 1: the expected return type as defined by the enclosing class |
| * 2: the name of the constructor |
| */ |
| static const CompileTimeErrorCode RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR = |
| CompileTimeErrorCode( |
| 'RETURN_OF_INVALID_TYPE', |
| "A value of type '{0}' can't be returned from the constructor '{2}' " |
| "because it has a return type of '{1}'.", |
| hasPublishedDocs: true, |
| uniqueName: 'RETURN_OF_INVALID_TYPE_FROM_CONSTRUCTOR', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the return type as declared in the return statement |
| * 1: the expected return type as defined by the method |
| * 2: the name of the method |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function returns a |
| // value whose type isn't assignable to the declared return type. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` has a return type |
| // of `String` but is returning an `int`: |
| // |
| // ```dart |
| // String f() => [!3!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the return type is correct, then replace the value being returned with a |
| // value of the correct type, possibly by converting the existing value: |
| // |
| // ```dart |
| // String f() => 3.toString(); |
| // ``` |
| // |
| // If the value is correct, then change the return type to match: |
| // |
| // ```dart |
| // int f() => 3; |
| // ``` |
| static const CompileTimeErrorCode RETURN_OF_INVALID_TYPE_FROM_FUNCTION = |
| CompileTimeErrorCode( |
| 'RETURN_OF_INVALID_TYPE', |
| "A value of type '{0}' can't be returned from the function '{2}' because " |
| "it has a return type of '{1}'.", |
| hasPublishedDocs: true, |
| uniqueName: 'RETURN_OF_INVALID_TYPE_FROM_FUNCTION', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the return type as declared in the return statement |
| * 1: the expected return type as defined by the method |
| * 2: the name of the method |
| */ |
| static const CompileTimeErrorCode RETURN_OF_INVALID_TYPE_FROM_METHOD = |
| CompileTimeErrorCode( |
| 'RETURN_OF_INVALID_TYPE', |
| "A value of type '{0}' can't be returned from the method '{2}' because " |
| "it has a return type of '{1}'.", |
| hasPublishedDocs: true, |
| uniqueName: 'RETURN_OF_INVALID_TYPE_FROM_METHOD', |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds a `return` statement |
| // without an expression in a function that declares a return type. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the function `f` is |
| // expected to return an `int`, but no value is being returned: |
| // |
| // ```dart |
| // int f() { |
| // [!return!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add an expression that computes the value to be returned: |
| // |
| // ```dart |
| // int f() { |
| // return 0; |
| // } |
| // ``` |
| static const CompileTimeErrorCode RETURN_WITHOUT_VALUE = CompileTimeErrorCode( |
| 'RETURN_WITHOUT_VALUE', "The return value is missing after 'return'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode SET_ELEMENT_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'COLLECTION_ELEMENT_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be used as values in " |
| "a 'const' set literal.", |
| correction: |
| "Try removing the keyword 'const' from the set literal or removing " |
| "the keyword 'deferred' from the import.", |
| hasPublishedDocs: true, |
| uniqueName: 'SET_ELEMENT_FROM_DEFERRED_LIBRARY'); |
| |
| /** |
| * Parameters: |
| * 0: the actual type of the set element |
| * 1: the expected type of the set element |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an element in a set literal has |
| // a type that isn't assignable to the element type of the set. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type of the string |
| // literal `'0'` is `String`, which isn't assignable to `int`, the element |
| // type of the set: |
| // |
| // ```dart |
| // var s = <int>{[!'0'!]}; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the element type of the set literal is wrong, then change the element |
| // type of the set: |
| // |
| // ```dart |
| // var s = <String>{'0'}; |
| // ``` |
| // |
| // If the type of the element is wrong, then change the element: |
| // |
| // ```dart |
| // var s = <int>{'0'.length}; |
| // ``` |
| static const CompileTimeErrorCode SET_ELEMENT_TYPE_NOT_ASSIGNABLE = |
| CompileTimeErrorCode('SET_ELEMENT_TYPE_NOT_ASSIGNABLE', |
| "The element type '{0}' can't be assigned to the set type '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a prefix in a deferred import is |
| // also used as a prefix in other imports (whether deferred or not). The |
| // prefix in a deferred import can't be shared with other imports because the |
| // prefix is used to load the imported library. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the prefix `x` is used |
| // as the prefix for a deferred import and is also used for one other import: |
| // |
| // ```dart |
| // import 'dart:math' [!deferred!] as x; |
| // import 'dart:convert' as x; |
| // |
| // var y = x.json.encode(x.min(0, 1)); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you can use a different name for the deferred import, then do so: |
| // |
| // ```dart |
| // import 'dart:math' deferred as math; |
| // import 'dart:convert' as x; |
| // |
| // var y = x.json.encode(math.min(0, 1)); |
| // ``` |
| // |
| // If you can use a different name for the other imports, then do so: |
| // |
| // ```dart |
| // import 'dart:math' deferred as x; |
| // import 'dart:convert' as convert; |
| // |
| // var y = convert.json.encode(x.min(0, 1)); |
| // ``` |
| static const CompileTimeErrorCode SHARED_DEFERRED_PREFIX = |
| CompileTimeErrorCode( |
| 'SHARED_DEFERRED_PREFIX', |
| "The prefix of a deferred import can't be used in other import " |
| "directives.", |
| correction: "Try renaming one of the prefixes.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode SPREAD_EXPRESSION_FROM_DEFERRED_LIBRARY = |
| CompileTimeErrorCode( |
| 'SPREAD_EXPRESSION_FROM_DEFERRED_LIBRARY', |
| "Constant values from a deferred library can't be spread into a " |
| "const literal.", |
| correction: "Try making the deferred import non-deferred."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the instance member |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a class name is used to access |
| // an instance field. Instance fields don't exist on a class; they exist only |
| // on an instance of the class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `x` is an instance |
| // field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // static int a; |
| // |
| // int b; |
| // } |
| // |
| // int f() => C.[!b!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intend to access a static field, then change the name of the field |
| // to an existing static field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // static int a; |
| // |
| // int b; |
| // } |
| // |
| // int f() => C.a; |
| // ``` |
| // |
| // If you intend to access the instance field, then use an instance of the |
| // class to access the field: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // static int a; |
| // |
| // int b; |
| // } |
| // |
| // int f(C c) => c.b; |
| // ``` |
| static const CompileTimeErrorCode STATIC_ACCESS_TO_INSTANCE_MEMBER = |
| CompileTimeErrorCode('STATIC_ACCESS_TO_INSTANCE_MEMBER', |
| "Instance member '{0}' can't be accessed using static access.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a member declared inside an |
| // extension uses the `super` keyword . Extensions aren't classes and don't |
| // have superclasses, so the `super` keyword serves no purpose. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `super` can't be used |
| // in an extension: |
| // |
| // ```dart |
| // extension E on Object { |
| // String get displayString => [!super!].toString(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the `super` keyword : |
| // |
| // ```dart |
| // extension E on Object { |
| // String get displayString => toString(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode SUPER_IN_EXTENSION = CompileTimeErrorCode( |
| 'SUPER_IN_EXTENSION', |
| "The 'super' keyword can't be used in an extension because an " |
| "extension doesn't have a superclass.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the keyword `super` is used |
| // outside of a instance method. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `super` is used in a |
| // top-level function: |
| // |
| // ```dart |
| // void f() { |
| // [!super!].f(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Rewrite the code to not use `super`. |
| static const CompileTimeErrorCode SUPER_IN_INVALID_CONTEXT = |
| CompileTimeErrorCode( |
| 'SUPER_IN_INVALID_CONTEXT', "Invalid context for 'super' invocation.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a constructor that redirects to |
| // another constructor also attempts to invoke a constructor from the |
| // superclass. The superclass constructor will be invoked when the constructor |
| // that the redirecting constructor is redirected to is invoked. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the constructor `C.a` |
| // both redirects to `C.b` and invokes a constructor from the superclass: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(), [!super()!]; |
| // C.b(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the invocation of the `super` constructor: |
| // |
| // ```dart |
| // class C { |
| // C.a() : this.b(); |
| // C.b(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode SUPER_IN_REDIRECTING_CONSTRUCTOR = |
| CompileTimeErrorCode('SUPER_IN_REDIRECTING_CONSTRUCTOR', |
| "The redirecting constructor can't have a 'super' initializer.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.6.1 Generative Constructors: Let <i>k</i> be a generative constructor. It |
| * is a compile-time error if a generative constructor of class Object |
| * includes a superinitializer. |
| */ |
| static const CompileTimeErrorCode SUPER_INITIALIZER_IN_OBJECT = |
| CompileTimeErrorCode('SUPER_INITIALIZER_IN_OBJECT', |
| "The class 'Object' can't invoke a constructor from a superclass."); |
| |
| /** |
| * It is an error if any case of a switch statement except the last case (the |
| * default case if present) may complete normally. The previous syntactic |
| * restriction requiring the last statement of each case to be one of an |
| * enumerated list of statements (break, continue, return, throw, or rethrow) |
| * is removed. |
| */ |
| static const CompileTimeErrorCode SWITCH_CASE_COMPLETES_NORMALLY = |
| CompileTimeErrorCode('SWITCH_CASE_COMPLETES_NORMALLY', |
| "The 'case' should not complete normally.", |
| correction: "Try adding 'break', or 'return', etc."); |
| |
| /** |
| * Parameters: |
| * 0: the static type of the switch expression |
| * 1: the static type of the case expressions |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of the expression in a |
| // `switch` statement isn't assignable to the type of the expressions in the |
| // `case` clauses. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type of `s` |
| // (`String`) isn't assignable to the type of `0` (`int`): |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(String s) { |
| // switch ([!s!]) { |
| // case 0: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type of the `case` expressions is correct, then change the |
| // expression in the `switch` statement to have the correct type: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(String s) { |
| // switch (int.parse(s)) { |
| // case 0: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If the type of the `switch` expression is correct, then change the `case` |
| // expressions to have the correct type: |
| // |
| // ```dart |
| // %language=2.9 |
| // void f(String s) { |
| // switch (s) { |
| // case '0': |
| // break; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode SWITCH_EXPRESSION_NOT_ASSIGNABLE = |
| CompileTimeErrorCode( |
| 'SWITCH_EXPRESSION_NOT_ASSIGNABLE', |
| "Type '{0}' of the switch expression isn't assignable to " |
| "the type '{1}' of case expressions.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode |
| TEAROFF_OF_GENERATIVE_CONSTRUCTOR_OF_ABSTRACT_CLASS = |
| CompileTimeErrorCode( |
| 'TEAROFF_OF_GENERATIVE_CONSTRUCTOR_OF_ABSTRACT_CLASS', |
| "A generative constructor of an abstract class can't be torn off", |
| correction: "Try tearing off a constructor of a concrete class, or a " |
| "non-generative constructor."); |
| |
| /** |
| * Parameters: |
| * 0: the type that can't be thrown |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of the expression in a |
| // throw expression isn't assignable to `Object`. It isn't valid to throw |
| // `null`, so it isn't valid to use an expression that might evaluate to |
| // `null`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `s` might be `null`: |
| // |
| // ```dart |
| // void f(String? s) { |
| // throw [!s!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add an explicit null check to the expression: |
| // |
| // ```dart |
| // void f(String? s) { |
| // throw s!; |
| // } |
| // ``` |
| static const CompileTimeErrorCode THROW_OF_INVALID_TYPE = CompileTimeErrorCode( |
| 'THROW_OF_INVALID_TYPE', |
| "The type '{0}' of the thrown expression must be assignable to 'Object'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the element whose type could not be inferred. |
| * 1: The [TopLevelInferenceError]'s arguments that led to the cycle. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a top-level variable has no type |
| // annotation and the variable's initializer refers to the variable, either |
| // directly or indirectly. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the variables `x` and |
| // `y` are defined in terms of each other, and neither has an explicit type, |
| // so the type of the other can't be inferred: |
| // |
| // ```dart |
| // var x = y; |
| // var y = [!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the two variables don't need to refer to each other, then break the |
| // cycle: |
| // |
| // ```dart |
| // var x = 0; |
| // var y = x; |
| // ``` |
| // |
| // If the two variables need to refer to each other, then give at least one of |
| // them an explicit type: |
| // |
| // ```dart |
| // int x = y; |
| // var y = x; |
| // ``` |
| // |
| // Note, however, that while this code doesn't produce any diagnostics, it |
| // will produce a stack overflow at runtime unless at least one of the |
| // variables is assigned a value that doesn't depend on the other variables |
| // before any of the variables in the cycle are referenced. |
| static const CompileTimeErrorCode TOP_LEVEL_CYCLE = CompileTimeErrorCode( |
| 'TOP_LEVEL_CYCLE', |
| "The type of '{0}' can't be inferred because it depends on itself " |
| "through the cycle: {1}.", |
| correction: |
| "Try adding an explicit type to one or more of the variables in the " |
| "cycle in order to break the cycle.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a typedef refers to itself, |
| // either directly or indirectly. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `F` depends on itself |
| // indirectly through `G`: |
| // |
| // ```dart |
| // typedef [!F!] = void Function(G); |
| // typedef G = void Function(F); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change one or more of the typedefs in the cycle so that none of them refer |
| // to themselves: |
| // |
| // ```dart |
| // typedef F = void Function(G); |
| // typedef G = void Function(int); |
| // ``` |
| static const CompileTimeErrorCode TYPE_ALIAS_CANNOT_REFERENCE_ITSELF = |
| CompileTimeErrorCode( |
| 'TYPE_ALIAS_CANNOT_REFERENCE_ITSELF', |
| "Typedefs can't reference themselves directly or recursively via " |
| "another typedef.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type that is deferred and being used in a type |
| * annotation |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type annotation is in a |
| // variable declaration, or the type used in a cast (`as`) or type test (`is`) |
| // is a type declared in a library that is imported using a deferred import. |
| // These types are required to be available at compile time, but aren't. |
| // |
| // For more information, see the language tour's coverage of |
| // [deferred loading](https://dart.dev/guides/language/language-tour#lazily-loading-a-library). |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type of the |
| // parameter `f` is imported from a deferred library: |
| // |
| // ```dart |
| // import 'dart:io' deferred as io; |
| // |
| // void f([!io.File!] f) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you need to reference the imported type, then remove the `deferred` |
| // keyword: |
| // |
| // ```dart |
| // import 'dart:io' as io; |
| // |
| // void f(io.File f) {} |
| // ``` |
| // |
| // If the import is required to be deferred and there's another type that is |
| // appropriate, then use that type in place of the type from the deferred |
| // library. |
| static const CompileTimeErrorCode TYPE_ANNOTATION_DEFERRED_CLASS = |
| CompileTimeErrorCode( |
| 'TYPE_ANNOTATION_DEFERRED_CLASS', |
| "The deferred type '{0}' can't be used in a declaration, cast, or " |
| "type test.", |
| correction: "Try using a different type, or " |
| "changing the import to not be deferred.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type used in the instance creation that should be |
| * limited by the bound as specified in the class declaration |
| * 1: the name of the type parameter |
| * 2: the substituted bound of the type parameter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type argument isn't the same |
| // as or a subclass of the bounds of the corresponding type parameter. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `String` isn't a |
| // subclass of `num`: |
| // |
| // ```dart |
| // class A<E extends num> {} |
| // |
| // var a = A<[!String!]>(); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the type argument to be a subclass of the bounds: |
| // |
| // ```dart |
| // class A<E extends num> {} |
| // |
| // var a = A<int>(); |
| // ``` |
| static const CompileTimeErrorCode TYPE_ARGUMENT_NOT_MATCHING_BOUNDS = |
| CompileTimeErrorCode( |
| 'TYPE_ARGUMENT_NOT_MATCHING_BOUNDS', |
| "'{0}' doesn't conform to the bound '{2}' of the type parameter '{1}'.", |
| correction: "Try using a type that is or is a subclass of '{2}'.", |
| hasPublishedDocs: true, |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a static member references a |
| // type parameter that is declared for the class. Type parameters only have |
| // meaning for instances of the class. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the static method |
| // `hasType` has a reference to the type parameter `T`: |
| // |
| // ```dart |
| // class C<T> { |
| // static bool hasType(Object o) => o is [!T!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the member can be an instance member, then remove the keyword `static`: |
| // |
| // ```dart |
| // class C<T> { |
| // bool hasType(Object o) => o is T; |
| // } |
| // ``` |
| // |
| // If the member must be a static member, then make the member be generic: |
| // |
| // ```dart |
| // class C<T> { |
| // static bool hasType<S>(Object o) => o is S; |
| // } |
| // ``` |
| // |
| // Note, however, that there isn’t a relationship between `T` and `S`, so this |
| // second option changes the semantics from what was likely to be intended. |
| static const CompileTimeErrorCode TYPE_PARAMETER_REFERENCED_BY_STATIC = |
| CompileTimeErrorCode('TYPE_PARAMETER_REFERENCED_BY_STATIC', |
| "Static members can't reference type parameters of the class.", |
| correction: "Try removing the reference to the type parameter, or " |
| "making the member an instance member.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type parameter |
| * 1: the name of the bounding type |
| * |
| * See [CompileTimeErrorCode.TYPE_ARGUMENT_NOT_MATCHING_BOUNDS]. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the bound of a type parameter |
| // (the type following the `extends` keyword) is either directly or indirectly |
| // the type parameter itself. Stating that the type parameter must be the same |
| // as itself or a subtype of itself or a subtype of itself isn't helpful |
| // because it will always be the same as itself. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the bound of `T` is |
| // `T`: |
| // |
| // ```dart |
| // class C<[!T!] extends T> {} |
| // ``` |
| // |
| // The following code produces this diagnostic because the bound of `T1` is |
| // `T2`, and the bound of `T2` is `T1`, effectively making the bound of `T1` |
| // be `T1`: |
| // |
| // ```dart |
| // class C<[!T1!] extends T2, T2 extends T1> {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type parameter needs to be a subclass of some type, then replace the |
| // bound with the required type: |
| // |
| // ```dart |
| // class C<T extends num> {} |
| // ``` |
| // |
| // If the type parameter can be any type, then remove the `extends` clause: |
| // |
| // ```dart |
| // class C<T> {} |
| // ``` |
| static const CompileTimeErrorCode TYPE_PARAMETER_SUPERTYPE_OF_ITS_BOUND = |
| CompileTimeErrorCode('TYPE_PARAMETER_SUPERTYPE_OF_ITS_BOUND', |
| "'{0}' can't be a supertype of its upper bound.", |
| correction: |
| "Try using a type that is the same as or a subclass of '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the right-hand side of an `is` |
| // or `is!` test isn't a type. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the right-hand side is |
| // a parameter, not a type: |
| // |
| // ```dart |
| // typedef B = int Function(int); |
| // |
| // void f(Object a, B b) { |
| // if (a is [!b!]) { |
| // return; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you intended to use a type test, then replace the right-hand side with a |
| // type: |
| // |
| // ```dart |
| // typedef B = int Function(int); |
| // |
| // void f(Object a, B b) { |
| // if (a is B) { |
| // return; |
| // } |
| // } |
| // ``` |
| // |
| // If you intended to use a different kind of test, then change the test: |
| // |
| // ```dart |
| // typedef B = int Function(int); |
| // |
| // void f(Object a, B b) { |
| // if (a == b) { |
| // return; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode TYPE_TEST_WITH_NON_TYPE = |
| CompileTimeErrorCode( |
| 'TYPE_TEST_WITH_NON_TYPE', |
| "The name '{0}' isn't a type and can't be used in an 'is' " |
| "expression.", |
| correction: "Try correcting the name to match an existing type.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name following the `is` in a |
| // type test expression isn't defined. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `Srting` isn't |
| // defined: |
| // |
| // ```dart |
| // void f(Object o) { |
| // if (o is [!Srting!]) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Replace the name with the name of a type: |
| // |
| // ```dart |
| // void f(Object o) { |
| // if (o is String) { |
| // // ... |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode TYPE_TEST_WITH_UNDEFINED_NAME = |
| CompileTimeErrorCode( |
| 'TYPE_TEST_WITH_UNDEFINED_NAME', |
| "The name '{0}' isn't defined, so it can't be used in an 'is' " |
| "expression.", |
| correction: |
| "Try changing the name to the name of an existing type, or " |
| "creating a type with the name '{0}'.", |
| hasPublishedDocs: true); |
| |
| static const CompileTimeErrorCode UNCHECKED_INVOCATION_OF_NULLABLE_VALUE = |
| CompileTimeErrorCode('UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "The function can't be unconditionally invoked because it can be 'null'.", |
| correction: "Try adding a null check ('!').", |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_INVOCATION_OF_NULLABLE_VALUE'); |
| |
| static const CompileTimeErrorCode |
| UNCHECKED_METHOD_INVOCATION_OF_NULLABLE_VALUE = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "The method '{0}' can't be unconditionally invoked because the " |
| "receiver can be 'null'.", |
| correction: |
| "Try making the call conditional (using '?.') or adding a null " |
| "check to the target ('!').", |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_METHOD_INVOCATION_OF_NULLABLE_VALUE'); |
| |
| static const CompileTimeErrorCode |
| UNCHECKED_OPERATOR_INVOCATION_OF_NULLABLE_VALUE = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "The operator '{0}' can't be unconditionally invoked because the " |
| "receiver can be 'null'.", |
| correction: "Try adding a null check to the target ('!').", |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_OPERATOR_INVOCATION_OF_NULLABLE_VALUE'); |
| |
| static const CompileTimeErrorCode |
| UNCHECKED_PROPERTY_ACCESS_OF_NULLABLE_VALUE = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "The property '{0}' can't be unconditionally accessed because the " |
| "receiver can be 'null'.", |
| correction: |
| "Try making the access conditional (using '?.') or adding a null " |
| "check to the target ('!').", |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_PROPERTY_ACCESS_OF_NULLABLE_VALUE'); |
| |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an expression whose type is |
| // [potentially non-nullable][] is dereferenced without first verifying that |
| // the value isn't `null`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `s` can be `null` at |
| // the point where it's referenced: |
| // |
| // ```dart |
| // void f(String? s) { |
| // if (s.[!length!] > 3) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the value really can be `null`, then add a test to ensure that members |
| // are only accessed when the value isn't `null`: |
| // |
| // ```dart |
| // void f(String? s) { |
| // if (s != null && s.length > 3) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // If the expression is a variable and the value should never be `null`, then |
| // change the type of the variable to be non-nullable: |
| // |
| // ```dart |
| // void f(String s) { |
| // if (s.length > 3) { |
| // // ... |
| // } |
| // } |
| // ``` |
| // |
| // If you believe that the value of the expression should never be `null`, but |
| // you can't change the type of the variable, and you're willing to risk |
| // having an exception thrown at runtime if you're wrong, then you can assert |
| // that the value isn't null: |
| // |
| // ```dart |
| // void f(String? s) { |
| // if (s!.length > 3) { |
| // // ... |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| UNCHECKED_USE_OF_NULLABLE_VALUE_AS_CONDITION = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "A nullable expression can't be used as a condition.", |
| correction: |
| "Try checking that the value isn't 'null' before using it as a " |
| 'condition.', |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_USE_OF_NULLABLE_VALUE_AS_CONDITION'); |
| |
| static const CompileTimeErrorCode |
| UNCHECKED_USE_OF_NULLABLE_VALUE_AS_ITERATOR = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "A nullable expression can't be used as an iterator in a for-in " |
| 'loop.', |
| correction: |
| "Try checking that the value isn't 'null' before using it as an " |
| 'iterator.', |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_USE_OF_NULLABLE_VALUE_AS_ITERATOR'); |
| |
| static const CompileTimeErrorCode UNCHECKED_USE_OF_NULLABLE_VALUE_IN_SPREAD = |
| CompileTimeErrorCode('UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "A nullable expression can't be used in a spread.", |
| correction: |
| "Try checking that the value isn't 'null' before using it in a " |
| 'spread, or use a null-aware spread.', |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_USE_OF_NULLABLE_VALUE_IN_SPREAD'); |
| |
| static const CompileTimeErrorCode |
| UNCHECKED_USE_OF_NULLABLE_VALUE_IN_YIELD_EACH = CompileTimeErrorCode( |
| 'UNCHECKED_USE_OF_NULLABLE_VALUE', |
| "A nullable expression can't be used in a yield-each statement.", |
| correction: |
| "Try checking that the value isn't 'null' before using it in a " |
| 'yield-each statement.', |
| hasPublishedDocs: true, |
| uniqueName: 'UNCHECKED_USE_OF_NULLABLE_VALUE_IN_YIELD_EACH'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a name that isn't defined is |
| // used as an annotation. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `undefined` |
| // isn't defined: |
| // |
| // ```dart |
| // [!@undefined!] |
| // void f() {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the name is correct, but it isn’t declared yet, then declare the name as |
| // a constant value: |
| // |
| // ```dart |
| // const undefined = 'undefined'; |
| // |
| // @undefined |
| // void f() {} |
| // ``` |
| // |
| // If the name is wrong, replace the name with the name of a valid constant: |
| // |
| // ```dart |
| // @deprecated |
| // void f() {} |
| // ``` |
| // |
| // Otherwise, remove the annotation. |
| static const CompileTimeErrorCode UNDEFINED_ANNOTATION = CompileTimeErrorCode( |
| 'UNDEFINED_ANNOTATION', "Undefined name '{0}' used as an annotation.", |
| correction: "Try defining the name or importing it from another library.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the undefined class |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of a class but either isn't defined or isn't visible |
| // in the scope in which it's being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `Piont` isn't defined: |
| // |
| // ```dart |
| // class Point {} |
| // |
| // void f([!Piont!] p) {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // the name of a class that is defined. The example above can be corrected by |
| // fixing the spelling of the class: |
| // |
| // ```dart |
| // class Point {} |
| // |
| // void f(Point p) {} |
| // ``` |
| // |
| // If the class is defined but isn't visible, then you probably need to add an |
| // import. |
| static const CompileTimeErrorCode UNDEFINED_CLASS = CompileTimeErrorCode( |
| 'UNDEFINED_CLASS', "Undefined class '{0}'.", |
| correction: "Try changing the name to the name of an existing class, or " |
| "creating a class with the name '{0}'.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * Same as [CompileTimeErrorCode.UNDEFINED_CLASS], but to catch using |
| * "boolean" instead of "bool" in order to improve the correction message. |
| * |
| * Parameters: |
| * 0: the name of the undefined class |
| */ |
| static const CompileTimeErrorCode UNDEFINED_CLASS_BOOLEAN = |
| CompileTimeErrorCode('UNDEFINED_CLASS', "Undefined class '{0}'.", |
| correction: "Try using the type 'bool'.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true, |
| uniqueName: 'UNDEFINED_CLASS_BOOLEAN'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the superclass that does not define the invoked constructor |
| * 1: the name of the constructor being invoked |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a superclass constructor is |
| // invoked in the initializer list of a constructor, but the superclass |
| // doesn't define the constructor being invoked. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `A` doesn't have an |
| // unnamed constructor: |
| // |
| // ```dart |
| // class A { |
| // A.n(); |
| // } |
| // class B extends A { |
| // B() : [!super()!]; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `A` doesn't have a |
| // constructor named `m`: |
| // |
| // ```dart |
| // class A { |
| // A.n(); |
| // } |
| // class B extends A { |
| // B() : [!super.m()!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the superclass defines a constructor that should be invoked, then change |
| // the constructor being invoked: |
| // |
| // ```dart |
| // class A { |
| // A.n(); |
| // } |
| // class B extends A { |
| // B() : super.n(); |
| // } |
| // ``` |
| // |
| // If the superclass doesn't define an appropriate constructor, then define |
| // the constructor being invoked: |
| // |
| // ```dart |
| // class A { |
| // A.m(); |
| // A.n(); |
| // } |
| // class B extends A { |
| // B() : super.m(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_CONSTRUCTOR_IN_INITIALIZER = |
| CompileTimeErrorCode('UNDEFINED_CONSTRUCTOR_IN_INITIALIZER', |
| "The class '{0}' doesn't have a constructor named '{1}'.", |
| correction: "Try defining a constructor named '{1}' in '{0}', or " |
| "invoking a different constructor.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the superclass that does not define the invoked constructor |
| */ |
| static const CompileTimeErrorCode |
| UNDEFINED_CONSTRUCTOR_IN_INITIALIZER_DEFAULT = CompileTimeErrorCode( |
| 'UNDEFINED_CONSTRUCTOR_IN_INITIALIZER', |
| "The class '{0}' doesn't have an unnamed constructor.", |
| correction: "Try defining an unnamed constructor in '{0}', or " |
| "invoking a different constructor.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_CONSTRUCTOR_IN_INITIALIZER_DEFAULT', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the enumeration constant that is not defined |
| * 1: the name of the enumeration used to access the constant |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of an enum constant, and the name either isn't |
| // defined or isn't visible in the scope in which it's being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `E` doesn't define a |
| // constant named `c`: |
| // |
| // ```dart |
| // enum E {a, b} |
| // |
| // var e = E.[!c!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the constant should be defined, then add it to the declaration of the |
| // enum: |
| // |
| // ```dart |
| // enum E {a, b, c} |
| // |
| // var e = E.c; |
| // ``` |
| // |
| // If the constant shouldn't be defined, then change the name to the name of |
| // an existing constant: |
| // |
| // ```dart |
| // enum E {a, b} |
| // |
| // var e = E.b; |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_ENUM_CONSTANT = |
| CompileTimeErrorCode('UNDEFINED_ENUM_CONSTANT', |
| "There's no constant named '{0}' in '{1}'.", |
| correction: |
| "Try correcting the name to the name of an existing constant, or " |
| "defining a constant named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the getter that is undefined |
| * 1: the name of the extension that was explicitly specified |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is used to |
| // invoke a getter, but the getter isn't defined by the specified extension. |
| // The analyzer also produces this diagnostic when a static getter is |
| // referenced but isn't defined by the specified extension. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare an instance getter named `b`: |
| // |
| // ```dart |
| // extension E on String { |
| // String get a => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String get b => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').[!b!]; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare a static getter named `a`: |
| // |
| // ```dart |
| // extension E on String {} |
| // |
| // var x = E.[!a!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the name of the getter is incorrect, then change it to the name of an |
| // existing getter: |
| // |
| // ```dart |
| // extension E on String { |
| // String get a => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String get b => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').a; |
| // } |
| // ``` |
| // |
| // If the name of the getter is correct but the name of the extension is |
| // wrong, then change the name of the extension to the correct name: |
| // |
| // ```dart |
| // extension E on String { |
| // String get a => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String get b => 'b'; |
| // } |
| // |
| // void f() { |
| // F('c').b; |
| // } |
| // ``` |
| // |
| // If the name of the getter and extension are both correct, but the getter |
| // isn't defined, then define the getter: |
| // |
| // ```dart |
| // extension E on String { |
| // String get a => 'a'; |
| // String get b => 'z'; |
| // } |
| // |
| // extension F on String { |
| // String get b => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').b; |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_EXTENSION_GETTER = |
| CompileTimeErrorCode('UNDEFINED_EXTENSION_GETTER', |
| "The getter '{0}' isn't defined for the extension '{1}'.", |
| correction: |
| "Try correcting the name to the name of an existing getter, or " |
| "defining a getter named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method that is undefined |
| * 1: the name of the extension that was explicitly specified |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is used to |
| // invoke a method, but the method isn't defined by the specified extension. |
| // The analyzer also produces this diagnostic when a static method is |
| // referenced but isn't defined by the specified extension. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare an instance method named `b`: |
| // |
| // ```dart |
| // extension E on String { |
| // String a() => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String b() => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').[!b!](); |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare a static method named `a`: |
| // |
| // ```dart |
| // extension E on String {} |
| // |
| // var x = E.[!a!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the name of the method is incorrect, then change it to the name of an |
| // existing method: |
| // |
| // ```dart |
| // extension E on String { |
| // String a() => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String b() => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').a(); |
| // } |
| // ``` |
| // |
| // If the name of the method is correct, but the name of the extension is |
| // wrong, then change the name of the extension to the correct name: |
| // |
| // ```dart |
| // extension E on String { |
| // String a() => 'a'; |
| // } |
| // |
| // extension F on String { |
| // String b() => 'b'; |
| // } |
| // |
| // void f() { |
| // F('c').b(); |
| // } |
| // ``` |
| // |
| // If the name of the method and extension are both correct, but the method |
| // isn't defined, then define the method: |
| // |
| // ```dart |
| // extension E on String { |
| // String a() => 'a'; |
| // String b() => 'z'; |
| // } |
| // |
| // extension F on String { |
| // String b() => 'b'; |
| // } |
| // |
| // void f() { |
| // E('c').b(); |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_EXTENSION_METHOD = |
| CompileTimeErrorCode('UNDEFINED_EXTENSION_METHOD', |
| "The method '{0}' isn't defined for the extension '{1}'.", |
| correction: |
| "Try correcting the name to the name of an existing method, or " |
| "defining a method named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the operator that is undefined |
| * 1: the name of the extension that was explicitly specified |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an operator is invoked on a |
| // specific extension when that extension doesn't implement the operator. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't define the operator `*`: |
| // |
| // ```dart |
| // var x = E('') [!*!] 4; |
| // |
| // extension E on String {} |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the extension is expected to implement the operator, then add an |
| // implementation of the operator to the extension: |
| // |
| // ```dart |
| // var x = E('') * 4; |
| // |
| // extension E on String { |
| // int operator *(int multiplier) => length * multiplier; |
| // } |
| // ``` |
| // |
| // If the operator is defined by a different extension, then change the name |
| // of the extension to the name of the one that defines the operator. |
| // |
| // If the operator is defined on the argument of the extension override, then |
| // remove the extension override: |
| // |
| // ```dart |
| // var x = '' * 4; |
| // |
| // extension E on String {} |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_EXTENSION_OPERATOR = |
| CompileTimeErrorCode('UNDEFINED_EXTENSION_OPERATOR', |
| "The operator '{0}' isn't defined for the extension '{1}'.", |
| correction: "Try defining the operator '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the setter that is undefined |
| * 1: the name of the extension that was explicitly specified |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension override is used to |
| // invoke a setter, but the setter isn't defined by the specified extension. |
| // The analyzer also produces this diagnostic when a static setter is |
| // referenced but isn't defined by the specified extension. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare an instance setter named `b`: |
| // |
| // ```dart |
| // extension E on String { |
| // set a(String v) {} |
| // } |
| // |
| // extension F on String { |
| // set b(String v) {} |
| // } |
| // |
| // void f() { |
| // E('c').[!b!] = 'd'; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the extension `E` |
| // doesn't declare a static setter named `a`: |
| // |
| // ```dart |
| // extension E on String {} |
| // |
| // void f() { |
| // E.[!a!] = 3; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the name of the setter is incorrect, then change it to the name of an |
| // existing setter: |
| // |
| // ```dart |
| // extension E on String { |
| // set a(String v) {} |
| // } |
| // |
| // extension F on String { |
| // set b(String v) {} |
| // } |
| // |
| // void f() { |
| // E('c').a = 'd'; |
| // } |
| // ``` |
| // |
| // If the name of the setter is correct, but the name of the extension is |
| // wrong, then change the name of the extension to the correct name: |
| // |
| // ```dart |
| // extension E on String { |
| // set a(String v) {} |
| // } |
| // |
| // extension F on String { |
| // set b(String v) {} |
| // } |
| // |
| // void f() { |
| // F('c').b = 'd'; |
| // } |
| // ``` |
| // |
| // If the name of the setter and extension are both correct, but the setter |
| // isn't defined, then define the setter: |
| // |
| // ```dart |
| // extension E on String { |
| // set a(String v) {} |
| // set b(String v) {} |
| // } |
| // |
| // extension F on String { |
| // set b(String v) {} |
| // } |
| // |
| // void f() { |
| // E('c').b = 'd'; |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_EXTENSION_SETTER = |
| CompileTimeErrorCode('UNDEFINED_EXTENSION_SETTER', |
| "The setter '{0}' isn't defined for the extension '{1}'.", |
| correction: |
| "Try correcting the name to the name of an existing setter, or " |
| "defining a setter named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method that is undefined |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of a function but either isn't defined or isn't |
| // visible in the scope in which it's being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `emty` isn't |
| // defined: |
| // |
| // ```dart |
| // List<int> empty() => []; |
| // |
| // void main() { |
| // print([!emty!]()); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // the name of a function that is defined. The example above can be corrected |
| // by fixing the spelling of the function: |
| // |
| // ```dart |
| // List<int> empty() => []; |
| // |
| // void main() { |
| // print(empty()); |
| // } |
| // ``` |
| // |
| // If the function is defined but isn't visible, then you probably need to add |
| // an import or re-arrange your code to make the function visible. |
| static const CompileTimeErrorCode UNDEFINED_FUNCTION = CompileTimeErrorCode( |
| 'UNDEFINED_FUNCTION', "The function '{0}' isn't defined.", |
| correction: "Try importing the library that defines '{0}', " |
| "correcting the name to the name of an existing function, or " |
| "defining a function named '{0}'.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the getter |
| * 1: the name of the enclosing type where the getter is being looked for |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of a getter but either isn't defined or isn't |
| // visible in the scope in which it's being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `String` has no member |
| // named `len`: |
| // |
| // ```dart |
| // int f(String s) => s.[!len!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // the name of a getter that is defined. The example above can be corrected by |
| // fixing the spelling of the getter: |
| // |
| // ```dart |
| // int f(String s) => s.length; |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_GETTER = CompileTimeErrorCode( |
| 'UNDEFINED_GETTER', "The getter '{0}' isn't defined for the type '{1}'.", |
| correction: "Try importing the library that defines '{0}', " |
| "correcting the name to the name of an existing getter, or " |
| "defining a getter or field named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the getter |
| * 1: the name of the function type alias |
| */ |
| static const CompileTimeErrorCode UNDEFINED_GETTER_ON_FUNCTION_TYPE = |
| CompileTimeErrorCode('UNDEFINED_GETTER', |
| "The getter '{0}' isn't defined for the '{1}' function type.", |
| correction: "Try wrapping the function type alias in parentheses in " |
| "order to access '{0}' as an extension getter on 'Type'.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_GETTER_ON_FUNCTION_TYPE'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the identifier |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // either isn't defined or isn't visible in the scope in which it's being |
| // referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the name `rihgt` isn't |
| // defined: |
| // |
| // ```dart |
| // int min(int left, int right) => left <= [!rihgt!] ? left : right; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // an identifier that is defined. The example above can be corrected by |
| // fixing the spelling of the variable: |
| // |
| // ```dart |
| // int min(int left, int right) => left <= right ? left : right; |
| // ``` |
| // |
| // If the identifier is defined but isn't visible, then you probably need to |
| // add an import or re-arrange your code to make the identifier visible. |
| static const CompileTimeErrorCode UNDEFINED_IDENTIFIER = |
| CompileTimeErrorCode('UNDEFINED_IDENTIFIER', "Undefined name '{0}'.", |
| correction: "Try correcting the name to one that is defined, or " |
| "defining the name.", |
| hasPublishedDocs: true, |
| isUnresolvedIdentifier: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the name `await` is used in a |
| // method or function body without being declared, and the body isn't marked |
| // with the `async` keyword. The name `await` only introduces an await |
| // expression in an asynchronous function. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the name `await` is |
| // used in the body of `f` even though the body of `f` isn't marked with the |
| // `async` keyword: |
| // |
| // ```dart |
| // void f(p) { [!await!] p; } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add the keyword `async` to the function body: |
| // |
| // ```dart |
| // void f(p) async { await p; } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_IDENTIFIER_AWAIT = |
| CompileTimeErrorCode('UNDEFINED_IDENTIFIER_AWAIT', |
| "Undefined name 'await' in function body not marked with 'async'.", |
| correction: "Try correcting the name to one that is defined, " |
| "defining the name, or " |
| "adding 'async' to the enclosing function body.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method that is undefined |
| * 1: the resolved type name that the method lookup is happening on |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of a method but either isn't defined or isn't |
| // visible in the scope in which it's being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the identifier |
| // `removeMiddle` isn't defined: |
| // |
| // ```dart |
| // int f(List<int> l) => l.[!removeMiddle!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // the name of a method that is defined. The example above can be corrected by |
| // fixing the spelling of the method: |
| // |
| // ```dart |
| // int f(List<int> l) => l.removeLast(); |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_METHOD = CompileTimeErrorCode( |
| 'UNDEFINED_METHOD', "The method '{0}' isn't defined for the type '{1}'.", |
| correction: |
| "Try correcting the name to the name of an existing method, or " |
| "defining a method named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method |
| * 1: the name of the function type alias |
| */ |
| static const CompileTimeErrorCode UNDEFINED_METHOD_ON_FUNCTION_TYPE = |
| CompileTimeErrorCode('UNDEFINED_METHOD', |
| "The method '{0}' isn't defined for the '{1}' function type.", |
| correction: "Try wrapping the function type alias in parentheses in " |
| "order to access '{0}' as an extension method on 'Type'.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_METHOD_ON_FUNCTION_TYPE'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the requested named parameter |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function invocation |
| // has a named argument, but the method or function being invoked doesn't |
| // define a parameter with the same name. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `m` doesn't declare a |
| // named parameter named `a`: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // m({int b}) {} |
| // } |
| // |
| // void f(C c) { |
| // c.m([!a!]: 1); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the argument name is mistyped, then replace it with the correct name. |
| // The example above can be fixed by changing `a` to `b`: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // m({int b}) {} |
| // } |
| // |
| // void f(C c) { |
| // c.m(b: 1); |
| // } |
| // ``` |
| // |
| // If a subclass adds a parameter with the name in question, then cast the |
| // receiver to the subclass: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // m({int b}) {} |
| // } |
| // |
| // class D extends C { |
| // m({int a, int b}) {} |
| // } |
| // |
| // void f(C c) { |
| // (c as D).m(a: 1); |
| // } |
| // ``` |
| // |
| // If the parameter should be added to the function, then add it: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // m({int a, int b}) {} |
| // } |
| // |
| // void f(C c) { |
| // c.m(a: 1); |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_NAMED_PARAMETER = |
| CompileTimeErrorCode('UNDEFINED_NAMED_PARAMETER', |
| "The named parameter '{0}' isn't defined.", |
| correction: |
| "Try correcting the name to an existing named parameter's name, " |
| "or defining a named parameter with the name '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the operator |
| * 1: the name of the enclosing type where the operator is being looked for |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a user-definable operator is |
| // invoked on an object for which the operator isn't defined. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the class `C` doesn't |
| // define the operator `+`: |
| // |
| // ```dart |
| // class C {} |
| // |
| // C f(C c) => c [!+!] 2; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the operator should be defined for the class, then define it: |
| // |
| // ```dart |
| // class C { |
| // C operator +(int i) => this; |
| // } |
| // |
| // C f(C c) => c + 2; |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_OPERATOR = CompileTimeErrorCode( |
| 'UNDEFINED_OPERATOR', |
| "The operator '{0}' isn't defined for the type '{1}'.", |
| correction: "Try defining the operator '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a prefixed identifier is found |
| // where the prefix is valid, but the identifier isn't declared in any of the |
| // libraries imported using that prefix. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `dart:core` doesn't |
| // define anything named `a`: |
| // |
| // ```dart |
| // import 'dart:core' as p; |
| // |
| // void f() { |
| // p.[!a!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the library in which the name is declared isn't imported yet, add an |
| // import for the library. |
| // |
| // If the name is wrong, then change it to one of the names that's declared in |
| // the imported libraries. |
| static const CompileTimeErrorCode UNDEFINED_PREFIXED_NAME = |
| CompileTimeErrorCode( |
| 'UNDEFINED_PREFIXED_NAME', |
| "The name '{0}' is being referenced through the prefix '{1}', but it " |
| "isn't defined in any of the libraries imported using that " |
| "prefix.", |
| correction: "Try correcting the prefix or " |
| "importing the library that defines '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the setter |
| * 1: the name of the enclosing type where the setter is being looked for |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it encounters an identifier that |
| // appears to be the name of a setter but either isn't defined or isn't |
| // visible in the scope in which the identifier is being referenced. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because there isn't a setter |
| // named `z`: |
| // |
| // ```dart |
| // class C { |
| // int x = 0; |
| // void m(int y) { |
| // this.[!z!] = y; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the identifier isn't defined, then either define it or replace it with |
| // the name of a setter that is defined. The example above can be corrected by |
| // fixing the spelling of the setter: |
| // |
| // ```dart |
| // class C { |
| // int x = 0; |
| // void m(int y) { |
| // this.x = y; |
| // } |
| // } |
| // ``` |
| static const CompileTimeErrorCode UNDEFINED_SETTER = CompileTimeErrorCode( |
| 'UNDEFINED_SETTER', "The setter '{0}' isn't defined for the type '{1}'.", |
| correction: "Try importing the library that defines '{0}', " |
| "correcting the name to the name of an existing setter, or " |
| "defining a setter or field named '{0}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the setter |
| * 1: the name of the function type alias |
| */ |
| static const CompileTimeErrorCode UNDEFINED_SETTER_ON_FUNCTION_TYPE = |
| CompileTimeErrorCode('UNDEFINED_SETTER', |
| "The setter '{0}' isn't defined for the '{1}' function type.", |
| correction: "Try wrapping the function type alias in parentheses in " |
| "order to access '{0}' as an extension getter on 'Type'.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_SETTER_ON_FUNCTION_TYPE'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the getter |
| * 1: the name of the enclosing type where the getter is being looked for |
| */ |
| static const CompileTimeErrorCode UNDEFINED_SUPER_GETTER = |
| CompileTimeErrorCode( |
| 'UNDEFINED_SUPER_MEMBER', |
| "The getter '{0}' isn't defined in a superclass of '{1}'.", |
| correction: "Try correcting the name to the name of an existing getter, or " |
| "defining a getter or field named '{0}' in a superclass.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_SUPER_GETTER', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method that is undefined |
| * 1: the resolved type name that the method lookup is happening on |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an inherited member (method, |
| // getter, setter, or operator) is referenced using `super`, but there’s no |
| // member with that name in the superclass chain. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `Object` doesn't define |
| // a method named `n`: |
| // |
| // ```dart |
| // class C { |
| // void m() { |
| // super.[!n!](); |
| // } |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `Object` doesn't define |
| // a getter named `g`: |
| // |
| // ```dart |
| // class C { |
| // void m() { |
| // super.[!g!]; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the inherited member you intend to invoke has a different name, then |
| // make the name of the invoked member match the inherited member. |
| // |
| // If the member you intend to invoke is defined in the same class, then |
| // remove the `super.`. |
| // |
| // If the member isn’t defined, then either add the member to one of the |
| // superclasses or remove the invocation. |
| static const CompileTimeErrorCode UNDEFINED_SUPER_METHOD = |
| CompileTimeErrorCode( |
| 'UNDEFINED_SUPER_MEMBER', |
| "The method '{0}' isn't defined in a superclass of '{1}'.", |
| correction: "Try correcting the name to the name of an existing method, or " |
| "defining a method named '{0}' in a superclass.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_SUPER_METHOD', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the operator |
| * 1: the name of the enclosing type where the operator is being looked for |
| */ |
| static const CompileTimeErrorCode UNDEFINED_SUPER_OPERATOR = |
| CompileTimeErrorCode( |
| 'UNDEFINED_SUPER_MEMBER', |
| "The operator '{0}' isn't defined in a superclass of '{1}'.", |
| correction: "Try defining the operator '{0}' in a superclass.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_SUPER_OPERATOR', |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the setter |
| * 1: the name of the enclosing type where the setter is being looked for |
| */ |
| static const CompileTimeErrorCode UNDEFINED_SUPER_SETTER = |
| CompileTimeErrorCode( |
| 'UNDEFINED_SUPER_MEMBER', |
| "The setter '{0}' isn't defined in a superclass of '{1}'.", |
| correction: "Try correcting the name to the name of an existing setter, or " |
| "defining a setter or field named '{0}' in a superclass.", |
| hasPublishedDocs: true, |
| uniqueName: 'UNDEFINED_SUPER_SETTER', |
| ); |
| |
| /** |
| * This is a specialization of [INSTANCE_ACCESS_TO_STATIC_MEMBER] that is used |
| * when we are able to find the name defined in a supertype. It exists to |
| * provide a more informative error message. |
| * |
| * Parameters: |
| * 0: the name of the defining type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when code in one class references a |
| // static member in a superclass without prefixing the member's name with the |
| // name of the superclass. Static members can only be referenced without a |
| // prefix in the class in which they're declared. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the static field `x` is |
| // referenced in the getter `g` without prefixing it with the name of the |
| // defining class: |
| // |
| // ```dart |
| // class A { |
| // static int x = 3; |
| // } |
| // |
| // class B extends A { |
| // int get g => [!x!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Prefix the name of the static member with the name of the declaring class: |
| // |
| // ```dart |
| // class A { |
| // static int x = 3; |
| // } |
| // |
| // class B extends A { |
| // int get g => A.x; |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| UNQUALIFIED_REFERENCE_TO_NON_LOCAL_STATIC_MEMBER = CompileTimeErrorCode( |
| 'UNQUALIFIED_REFERENCE_TO_NON_LOCAL_STATIC_MEMBER', |
| "Static members from supertypes must be qualified by the name of the " |
| "defining type.", |
| correction: "Try adding '{0}.' before the name.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the defining type |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an undefined name is found, and |
| // the name is the same as a static member of the extended type or one of its |
| // superclasses. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `m` is a static member |
| // of the extended type `C`: |
| // |
| // ```dart |
| // class C { |
| // static void m() {} |
| // } |
| // |
| // extension E on C { |
| // void f() { |
| // [!m!](); |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If you're trying to reference a static member that's declared outside the |
| // extension, then add the name of the class or extension before the reference |
| // to the member: |
| // |
| // ```dart |
| // class C { |
| // static void m() {} |
| // } |
| // |
| // extension E on C { |
| // void f() { |
| // C.m(); |
| // } |
| // } |
| // ``` |
| // |
| // If you're referencing a member that isn't declared yet, add a declaration: |
| // |
| // ```dart |
| // class C { |
| // static void m() {} |
| // } |
| // |
| // extension E on C { |
| // void f() { |
| // m(); |
| // } |
| // |
| // void m() {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode |
| UNQUALIFIED_REFERENCE_TO_STATIC_MEMBER_OF_EXTENDED_TYPE = |
| CompileTimeErrorCode( |
| 'UNQUALIFIED_REFERENCE_TO_STATIC_MEMBER_OF_EXTENDED_TYPE', |
| "Static members from the extended type or one of its superclasses " |
| "must be qualified by the name of the defining type.", |
| correction: "Try adding '{0}.' before the name.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the URI pointing to a non-existent file |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an import, export, or part |
| // directive is found where the URI refers to a file that doesn't exist. |
| // |
| // #### Examples |
| // |
| // If the file `lib.dart` doesn't exist, the following code produces this |
| // diagnostic: |
| // |
| // ```dart |
| // import [!'lib.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the URI was mistyped or invalid, then correct the URI. |
| // |
| // If the URI is correct, then create the file. |
| static const CompileTimeErrorCode URI_DOES_NOT_EXIST = CompileTimeErrorCode( |
| 'URI_DOES_NOT_EXIST', "Target of URI doesn't exist: '{0}'.", |
| correction: "Try creating the file referenced by the URI, or " |
| "Try using a URI for a file that does exist.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the URI pointing to a non-existent file |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an import, export, or part |
| // directive is found where the URI refers to a file that doesn't exist and |
| // the name of the file ends with a pattern that's commonly produced by code |
| // generators, such as one of the following: |
| // - `.g.dart` |
| // - `.pb.dart` |
| // - `.pbenum.dart` |
| // - `.pbserver.dart` |
| // - `.pbjson.dart` |
| // - `.template.dart` |
| // |
| // #### Examples |
| // |
| // If the file `lib.g.dart` doesn't exist, the following code produces this |
| // diagnostic: |
| // |
| // ```dart |
| // import [!'lib.g.dart'!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the file is a generated file, then run the generator that generates the |
| // file. |
| // |
| // If the file isn't a generated file, then check the spelling of the URI or |
| // create the file. |
| static const CompileTimeErrorCode URI_HAS_NOT_BEEN_GENERATED = |
| CompileTimeErrorCode('URI_HAS_NOT_BEEN_GENERATED', |
| "Target of URI hasn't been generated: '{0}'.", |
| correction: "Try running the generator that will generate the file " |
| "referenced by the URI.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the string literal in an |
| // `import`, `export`, or `part` directive contains an interpolation. The |
| // resolution of the URIs in directives must happen before the declarations |
| // are compiled, so expressions can’t be evaluated while determining the |
| // values of the URIs. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the string in the |
| // `import` directive contains an interpolation: |
| // |
| // ```dart |
| // import [!'dart:$m'!]; |
| // |
| // const m = 'math'; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the interpolation from the URI: |
| // |
| // ```dart |
| // import 'dart:math'; |
| // |
| // var zero = min(0, 0); |
| // ``` |
| static const CompileTimeErrorCode URI_WITH_INTERPOLATION = |
| CompileTimeErrorCode( |
| 'URI_WITH_INTERPOLATION', "URIs can't use string interpolation.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when it finds an expression whose |
| // type is `void`, and the expression is used in a place where a value is |
| // expected, such as before a member access or on the right-hand side of an |
| // assignment. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `f` doesn't produce an |
| // object on which `toString` can be invoked: |
| // |
| // ```dart |
| // void f() {} |
| // |
| // void g() { |
| // [!f()!].toString(); |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Either rewrite the code so that the expression has a value or rewrite the |
| // code so that it doesn't depend on the value. |
| static const CompileTimeErrorCode USE_OF_VOID_RESULT = CompileTimeErrorCode( |
| 'USE_OF_VOID_RESULT', |
| "This expression has a type of 'void' so its value can't be used.", |
| correction: |
| "Try checking to see if you're using the correct API; there might " |
| "be a function or call that returns void you didn't expect. Also " |
| "check type parameters and variables which might also be void.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the object being assigned. |
| * 1: the type of the variable being assigned to |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the evaluation of a constant |
| // expression would result in a `CastException`. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the value of `x` is an |
| // `int`, which can't be assigned to `y` because an `int` isn't a `String`: |
| // |
| // ```dart |
| // %language=2.9 |
| // const Object x = 0; |
| // const String y = [!x!]; |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the declaration of the constant is correct, then change the value being |
| // assigned to be of the correct type: |
| // |
| // ```dart |
| // %language=2.9 |
| // const Object x = 0; |
| // const String y = '$x'; |
| // ``` |
| // |
| // If the assigned value is correct, then change the declaration to have the |
| // correct type: |
| // |
| // ```dart |
| // %language=2.9 |
| // const Object x = 0; |
| // const int y = x; |
| // ``` |
| static const CompileTimeErrorCode VARIABLE_TYPE_MISMATCH = |
| CompileTimeErrorCode( |
| 'VARIABLE_TYPE_MISMATCH', |
| "A value of type '{0}' can't be assigned to a const variable of type " |
| "'{1}'.", |
| correction: "Try using a subtype, or removing the 'const' keyword", |
| hasPublishedDocs: true); |
| |
| /** |
| * Let `C` be a generic class that declares a formal type parameter `X`, and |
| * assume that `T` is a direct superinterface of `C`. |
| * |
| * It is a compile-time error if `X` is explicitly defined as a covariant or |
| * 'in' type parameter and `X` occurs in a non-covariant position in `T`. |
| * It is a compile-time error if `X` is explicitly defined as a contravariant |
| * or 'out' type parameter and `X` occurs in a non-contravariant position in |
| * `T`. |
| * |
| * Parameters: |
| * 0: the name of the type parameter |
| * 1: the variance modifier defined for {0} |
| * 2: the variance position of the type parameter {0} in the |
| * superinterface {3} |
| * 3: the name of the superinterface |
| */ |
| static const CompileTimeErrorCode |
| WRONG_EXPLICIT_TYPE_PARAMETER_VARIANCE_IN_SUPERINTERFACE = |
| CompileTimeErrorCode( |
| 'WRONG_EXPLICIT_TYPE_PARAMETER_VARIANCE_IN_SUPERINTERFACE', |
| "'{0}' is an '{1}' type parameter and can't be used in an '{2}' position in '{3}'.", |
| correction: "Try using 'in' type parameters in 'in' positions and 'out' " |
| "type parameters in 'out' positions in the superinterface.", |
| ); |
| |
| /** |
| * Parameters: |
| * 0: the name of the declared operator |
| * 1: the number of parameters expected |
| * 2: the number of parameters found in the operator declaration |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a declaration of an operator has |
| // the wrong number of parameters. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the operator `+` must |
| // have a single parameter corresponding to the right operand: |
| // |
| // ```dart |
| // class C { |
| // int operator [!+!](a, b) => 0; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add or remove parameters to match the required number: |
| // |
| // ```dart |
| // class C { |
| // int operator +(a) => 0; |
| // } |
| // ``` |
| // TODO(brianwilkerson) It would be good to add a link to the spec or some |
| // other documentation that lists the number of parameters for each operator, |
| // but I don't know what to link to. |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_PARAMETERS_FOR_OPERATOR = |
| CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_PARAMETERS_FOR_OPERATOR', |
| "Operator '{0}' should declare exactly {1} parameters, but {2} " |
| "found.", |
| hasPublishedDocs: true); |
| |
| /** |
| * 7.1.1 Operators: It is a compile time error if the arity of the |
| * user-declared operator - is not 0 or 1. |
| * |
| * Parameters: |
| * 0: the number of parameters found in the operator declaration |
| */ |
| static const CompileTimeErrorCode |
| WRONG_NUMBER_OF_PARAMETERS_FOR_OPERATOR_MINUS = CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_PARAMETERS_FOR_OPERATOR', |
| "Operator '-' should declare 0 or 1 parameter, but {0} found.", |
| hasPublishedDocs: true, |
| uniqueName: 'WRONG_NUMBER_OF_PARAMETERS_FOR_OPERATOR_MINUS'); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a setter is found that doesn't |
| // declare exactly one required positional parameter. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the setter `s` declares |
| // two required parameters: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // set [!s!](int x, int y) {} |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because the setter `s` declares |
| // one optional parameter: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // set [!s!]([int x]) {} |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the declaration so that there's exactly one required positional |
| // parameter: |
| // |
| // ```dart |
| // %language=2.9 |
| // class C { |
| // set s(int x) {} |
| // } |
| // ``` |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_PARAMETERS_FOR_SETTER = |
| CompileTimeErrorCode('WRONG_NUMBER_OF_PARAMETERS_FOR_SETTER', |
| "Setters must declare exactly one required positional parameter.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the type being referenced (<i>G</i>) |
| * 1: the number of type parameters that were declared |
| * 2: the number of type arguments provided |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a type that has type parameters |
| // is used and type arguments are provided, but the number of type arguments |
| // isn't the same as the number of type parameters. |
| // |
| // The analyzer also produces this diagnostic when a constructor is invoked |
| // and the number of type arguments doesn't match the number of type |
| // parameters declared for the class. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because `C` has one type |
| // parameter but two type arguments are provided when it is used as a type |
| // annotation: |
| // |
| // ```dart |
| // class C<E> {} |
| // |
| // void f([!C<int, int>!] x) {} |
| // ``` |
| // |
| // The following code produces this diagnostic because `C` declares one type |
| // parameter, but two type arguments are provided when creating an instance: |
| // |
| // ```dart |
| // class C<E> {} |
| // |
| // var c = [!C<int, int>!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add or remove type arguments, as necessary, to match the number of type |
| // parameters defined for the type: |
| // |
| // ```dart |
| // class C<E> {} |
| // |
| // void f(C<int> x) {} |
| // ``` |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_TYPE_ARGUMENTS = |
| CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_TYPE_ARGUMENTS', |
| "The type '{0}' is declared with {1} type parameters, " |
| "but {2} type arguments were given.", |
| correction: |
| "Try adjusting the number of type arguments to match the number " |
| "of type parameters.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the number of type parameters that were declared |
| * 1: the number of type arguments provided |
| */ |
| static const CompileTimeErrorCode |
| WRONG_NUMBER_OF_TYPE_ARGUMENTS_ANONYMOUS_FUNCTION = CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_TYPE_ARGUMENTS_FUNCTION', |
| "This function is declared with {0} type parameters, " |
| "but {1} type arguments were given.", |
| correction: |
| "Try adjusting the number of type arguments to match the number " |
| "of type parameters.", |
| uniqueName: 'WRONG_NUMBER_OF_TYPE_ARGUMENTS_ANONYMOUS_FUNCTION'); |
| |
| /** |
| * Parameters: |
| * 0: the name of the class being instantiated |
| * 1: the name of the constructor being invoked |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when type arguments are provided |
| // after the name of a named constructor. Constructors can't declare type |
| // parameters, so invocations can only provide the type arguments associated |
| // with the class, and those type arguments are required to follow the name of |
| // the class rather than the name of the constructor. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the type parameters |
| // (`<String>`) follow the name of the constructor rather than the name of the |
| // class: |
| // |
| // ```dart |
| // class C<T> { |
| // C.named(); |
| // } |
| // C f() => C.named[!<String>!](); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type arguments are for the class' type parameters, then move the |
| // type arguments to follow the class name: |
| // |
| // ```dart |
| // class C<T> { |
| // C.named(); |
| // } |
| // C f() => C<String>.named(); |
| // ``` |
| // |
| // If the type arguments aren't for the class' type parameters, then remove |
| // them: |
| // |
| // ```dart |
| // class C<T> { |
| // C.named(); |
| // } |
| // C f() => C.named(); |
| // ``` |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_TYPE_ARGUMENTS_CONSTRUCTOR = |
| CompileTimeErrorCode('WRONG_NUMBER_OF_TYPE_ARGUMENTS_CONSTRUCTOR', |
| "The constructor '{0}.{1}' doesn't have type parameters.", |
| correction: "Try moving type arguments to after the type name.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the extension being referenced |
| * 1: the number of type parameters that were declared |
| * 2: the number of type arguments provided |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when an extension that has type |
| // parameters is used and type arguments are provided, but the number of type |
| // arguments isn't the same as the number of type parameters. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the extension `E` is |
| // declared to have a single type parameter (`T`), but the extension override |
| // has two type arguments: |
| // |
| // ```dart |
| // extension E<T> on List<T> { |
| // int get len => length; |
| // } |
| // |
| // void f(List<int> p) { |
| // E[!<int, String>!](p).len; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Change the type arguments so that there are the same number of type |
| // arguments as there are type parameters: |
| // |
| // ```dart |
| // extension E<T> on List<T> { |
| // int get len => length; |
| // } |
| // |
| // void f(List<int> p) { |
| // E<int>(p).len; |
| // } |
| // ``` |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_TYPE_ARGUMENTS_EXTENSION = |
| CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_TYPE_ARGUMENTS_EXTENSION', |
| "The extension '{0}' is declared with {1} type parameters, " |
| "but {2} type arguments were given.", |
| correction: "Try adjusting the number of type arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the name of the function being referenced |
| * 1: the number of type parameters that were declared |
| * 2: the number of type arguments provided |
| */ |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_TYPE_ARGUMENTS_FUNCTION = |
| CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_TYPE_ARGUMENTS_FUNCTION', |
| "The function '{0}' is declared with {1} type parameters, " |
| "but {2} type arguments were given.", |
| correction: |
| "Try adjusting the number of type arguments to match the number " |
| "of type parameters."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the method being referenced (<i>G</i>) |
| * 1: the number of type parameters that were declared |
| * 2: the number of type arguments provided |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a method or function is invoked |
| // with a different number of type arguments than the number of type |
| // parameters specified in its declaration. There must either be no type |
| // arguments or the number of arguments must match the number of parameters. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the invocation of the |
| // method `m` has two type arguments, but the declaration of `m` only has one |
| // type parameter: |
| // |
| // ```dart |
| // class C { |
| // int m<A>(A a) => 0; |
| // } |
| // |
| // int f(C c) => c.m[!<int, int>!](2); |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the type arguments are necessary, then make them match the number of |
| // type parameters by either adding or removing type arguments: |
| // |
| // ```dart |
| // class C { |
| // int m<A>(A a) => 0; |
| // } |
| // |
| // int f(C c) => c.m<int>(2); |
| // ``` |
| // |
| // If the type arguments aren't necessary, then remove them: |
| // |
| // ```dart |
| // class C { |
| // int m<A>(A a) => 0; |
| // } |
| // |
| // int f(C c) => c.m(2); |
| // ``` |
| static const CompileTimeErrorCode WRONG_NUMBER_OF_TYPE_ARGUMENTS_METHOD = |
| CompileTimeErrorCode( |
| 'WRONG_NUMBER_OF_TYPE_ARGUMENTS_METHOD', |
| "The method '{0}' is declared with {1} type parameters, but {2} type " |
| "arguments are given.", |
| correction: "Try adjusting the number of type arguments.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Let `C` be a generic class that declares a formal type parameter `X`, and |
| * assume that `T` is a direct superinterface of `C`. It is a compile-time |
| * error if `X` occurs contravariantly or invariantly in `T`. |
| */ |
| static const CompileTimeErrorCode |
| WRONG_TYPE_PARAMETER_VARIANCE_IN_SUPERINTERFACE = CompileTimeErrorCode( |
| 'WRONG_TYPE_PARAMETER_VARIANCE_IN_SUPERINTERFACE', |
| "'{0}' can't be used contravariantly or invariantly in '{1}'.", |
| correction: "Try not using class type parameters in types of formal " |
| "parameters of function types, nor in explicitly contravariant or " |
| "invariant superinterfaces.", |
| ); |
| |
| /** |
| * Let `C` be a generic class that declares a formal type parameter `X`. |
| * |
| * If `X` is explicitly contravariant then it is a compile-time error for |
| * `X` to occur in a non-contravariant position in a member signature in the |
| * body of `C`, except when `X` is in a contravariant position in the type |
| * annotation of a covariant formal parameter. |
| * |
| * If `X` is explicitly covariant then it is a compile-time error for |
| * `X` to occur in a non-covariant position in a member signature in the |
| * body of `C`, except when `X` is in a covariant position in the type |
| * annotation of a covariant formal parameter. |
| * |
| * Parameters: |
| * 0: the variance modifier defined for {0} |
| * 1: the name of the type parameter |
| * 2: the variance position that the type parameter {1} is in |
| */ |
| static const CompileTimeErrorCode WRONG_TYPE_PARAMETER_VARIANCE_POSITION = |
| CompileTimeErrorCode( |
| 'WRONG_TYPE_PARAMETER_VARIANCE_POSITION', |
| "The '{0}' type parameter '{1}' can't be used in an '{2}' position.", |
| correction: "Try removing the type parameter or change the explicit " |
| "variance modifier declaration for the type parameter to another one " |
| "of 'in', 'out', or 'inout'.", |
| ); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a `yield` or `yield*` statement |
| // appears in a function whose body isn't marked with one of the `async*` or |
| // `sync*` modifiers. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `yield` is being used |
| // in a function whose body doesn't have a modifier: |
| // |
| // ```dart |
| // Iterable<int> get digits { |
| // yield* [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `yield*` is being used |
| // in a function whose body has the `async` modifier rather than the `async*` |
| // modifier: |
| // |
| // ```dart |
| // Stream<int> get digits async { |
| // yield* [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Add a modifier, or change the existing modifier to be either `async*` or |
| // `sync*`: |
| // |
| // ```dart |
| // Iterable<int> get digits sync* { |
| // yield* [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]; |
| // } |
| // ``` |
| static const CompileTimeErrorCode YIELD_EACH_IN_NON_GENERATOR = |
| CompileTimeErrorCode( |
| 'YIELD_IN_NON_GENERATOR', |
| "Yield-each statements must be in a generator function " |
| "(one marked with either 'async*' or 'sync*').", |
| correction: |
| "Try adding 'async*' or 'sync*' to the enclosing function.", |
| hasPublishedDocs: true, |
| uniqueName: 'YIELD_EACH_IN_NON_GENERATOR'); |
| |
| /** |
| * ?? Yield: It is a compile-time error if a yield statement appears in a |
| * function that is not a generator function. |
| * |
| * No parameters. |
| */ |
| static const CompileTimeErrorCode YIELD_IN_NON_GENERATOR = |
| CompileTimeErrorCode( |
| 'YIELD_IN_NON_GENERATOR', |
| "Yield statements must be in a generator function " |
| "(one marked with either 'async*' or 'sync*').", |
| correction: |
| "Try adding 'async*' or 'sync*' to the enclosing function.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the type of the expression after `yield` |
| * 1: the return type of the function containing the `yield` |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the type of object produced by a |
| // `yield` expression doesn't match the type of objects that are to be |
| // returned from the `Iterable` or `Stream` types that are returned from a |
| // generator (a function or method marked with either `sync*` or `async*`). |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because the getter `zero` is |
| // declared to return an `Iterable` that returns integers, but the `yield` is |
| // returning a string from the iterable: |
| // |
| // ```dart |
| // Iterable<int> get zero sync* { |
| // yield [!'0'!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the return type of the function is correct, then fix the expression |
| // following the keyword `yield` to return the correct type: |
| // |
| // ```dart |
| // Iterable<int> get zero sync* { |
| // yield 0; |
| // } |
| // ``` |
| // |
| // If the expression following the `yield` is correct, then change the return |
| // type of the function to allow it: |
| // |
| // ```dart |
| // Iterable<String> get zero sync* { |
| // yield '0'; |
| // } |
| // ``` |
| static const CompileTimeErrorCode YIELD_OF_INVALID_TYPE = |
| CompileTimeErrorCode( |
| 'YIELD_OF_INVALID_TYPE', |
| "The type '{0}' implied by the 'yield' expression must be assignable " |
| "to '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Initialize a newly created error code to have the given [name]. The message |
| * associated with the error will be created from the given [message] |
| * template. The correction associated with the error will be created from the |
| * given [correction] template. |
| */ |
| const CompileTimeErrorCode( |
| String name, |
| String message, { |
| String? correction, |
| bool hasPublishedDocs = false, |
| bool isUnresolvedIdentifier = false, |
| String? uniqueName, |
| }) : super( |
| correction: correction, |
| hasPublishedDocs: hasPublishedDocs, |
| isUnresolvedIdentifier: isUnresolvedIdentifier, |
| message: message, |
| name: name, |
| uniqueName: 'CompileTimeErrorCode.${uniqueName ?? name}', |
| ); |
| |
| @override |
| ErrorSeverity get errorSeverity => ErrorType.COMPILE_TIME_ERROR.severity; |
| |
| @override |
| ErrorType get type => ErrorType.COMPILE_TIME_ERROR; |
| } |
| |
| /** |
| * This class has experimental Language-specific codes. |
| * |
| * Currently it only contains codes related to implicit dynamic. |
| */ |
| class LanguageCode extends ErrorCode { |
| /** |
| * This is appended to the end of an error message about implicit dynamic. |
| * |
| * The idea is to make sure the user is aware that this error message is the |
| * result of turning on a particular option, and they are free to turn it |
| * back off. |
| */ |
| static const String _implicitDynamicCorrection = |
| "Try adding an explicit type, or remove implicit-dynamic from your " |
| "analysis options file."; |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_FIELD = LanguageCode( |
| 'IMPLICIT_DYNAMIC_FIELD', "Missing field type for '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_FUNCTION = LanguageCode( |
| 'IMPLICIT_DYNAMIC_FUNCTION', |
| "Missing type arguments for generic function '{0}<{1}>'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_INVOKE = LanguageCode( |
| 'IMPLICIT_DYNAMIC_INVOKE', |
| "Missing type arguments for calling generic function type '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_LIST_LITERAL = LanguageCode( |
| 'IMPLICIT_DYNAMIC_LIST_LITERAL', |
| "Missing type argument for list literal.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_MAP_LITERAL = LanguageCode( |
| 'IMPLICIT_DYNAMIC_MAP_LITERAL', "Missing type arguments for map literal.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_METHOD = LanguageCode( |
| 'IMPLICIT_DYNAMIC_METHOD', |
| "Missing type arguments for generic method '{0}<{1}>'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_PARAMETER = LanguageCode( |
| 'IMPLICIT_DYNAMIC_PARAMETER', "Missing parameter type for '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_RETURN = LanguageCode( |
| 'IMPLICIT_DYNAMIC_RETURN', "Missing return type for '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_TYPE = LanguageCode( |
| 'IMPLICIT_DYNAMIC_TYPE', "Missing type arguments for generic type '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| static const LanguageCode IMPLICIT_DYNAMIC_VARIABLE = LanguageCode( |
| 'IMPLICIT_DYNAMIC_VARIABLE', "Missing variable type for '{0}'.", |
| correction: _implicitDynamicCorrection); |
| |
| @override |
| final ErrorType type = ErrorType.COMPILE_TIME_ERROR; |
| |
| /** |
| * Initialize a newly created language code to have the given [type] and |
| * [name]. |
| * |
| * The message associated with the code will be created from the given |
| * [message] template. The correction associated with the code will be |
| * created from the optional [correction] template. |
| */ |
| const LanguageCode(String name, String message, |
| {String? correction, bool hasPublishedDocs = false}) |
| : super( |
| correction: correction, |
| hasPublishedDocs: hasPublishedDocs, |
| message: message, |
| name: name, |
| uniqueName: 'LanguageCode.$name', |
| ); |
| |
| @override |
| ErrorSeverity get errorSeverity => type.severity; |
| } |
| |
| /** |
| * The error codes used for static warnings. The convention for this class is |
| * for the name of the error code to indicate the problem that caused the error |
| * to be generated and for the error message to explain what is wrong and, when |
| * appropriate, how the problem can be corrected. |
| */ |
| class StaticWarningCode extends AnalyzerErrorCode { |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic in two cases. |
| // |
| // The first is when the left operand of an `??` operator can't be `null`. |
| // The right operand is only evaluated if the left operand has the value |
| // `null`, and because the left operand can't be `null`, the right operand is |
| // never evaluated. |
| // |
| // The second is when the left-hand side of an assignment using the `??=` |
| // operator can't be `null`. The right-hand side is only evaluated if the |
| // left-hand side has the value `null`, and because the left-hand side can't |
| // be `null`, the right-hand side is never evaluated. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` can't be `null`: |
| // |
| // ```dart |
| // int f(int x) { |
| // return x ?? [!0!]; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `f` can't be `null`: |
| // |
| // ```dart |
| // class C { |
| // int f = -1; |
| // |
| // void m(int x) { |
| // f ??= [!x!]; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If the diagnostic is reported for an `??` operator, then remove the `??` |
| // operator and the right operand: |
| // |
| // ```dart |
| // int f(int x) { |
| // return x; |
| // } |
| // ``` |
| // |
| // If the diagnostic is reported for an assignment, and the assignment isn't |
| // needed, then remove the assignment: |
| // |
| // ```dart |
| // class C { |
| // int f = -1; |
| // |
| // void m(int x) { |
| // } |
| // } |
| // ``` |
| // |
| // If the assignment is needed, but should be based on a different condition, |
| // then rewrite the code to use `=` and the different condition: |
| // |
| // ```dart |
| // class C { |
| // int f = -1; |
| // |
| // void m(int x) { |
| // if (f < 0) { |
| // f = x; |
| // } |
| // } |
| // } |
| // ``` |
| static const StaticWarningCode DEAD_NULL_AWARE_EXPRESSION = StaticWarningCode( |
| 'DEAD_NULL_AWARE_EXPRESSION', |
| "The left operand can't be null, so the right operand is never executed.", |
| correction: "Try removing the operator and the right operand.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the null-aware operator that is invalid |
| * 1: the non-null-aware operator that can replace the invalid operator |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a null-aware operator (`?.`, |
| // `?..`, `?[`, `?..[`, or `...?`) is used on a receiver that's known to be |
| // non-nullable. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `s` can't be `null`: |
| // |
| // ```dart |
| // int? getLength(String s) { |
| // return s[!?.!]length; |
| // } |
| // ``` |
| // |
| // The following code produces this diagnostic because `a` can't be `null`: |
| // |
| // ```dart |
| // var a = []; |
| // var b = [[!...?!]a]; |
| // ``` |
| // |
| // The following code produces this diagnostic because `s?.length` can't |
| // return `null`: |
| // |
| // ```dart |
| // void f(String? s) { |
| // s?.length[!?.!]isEven; |
| // } |
| // ``` |
| // |
| // The reason `s?.length` can't return `null` is because the null-aware |
| // operator following `s` short-circuits the evaluation of both `length` and |
| // `isEven` if `s` is `null`. In other words, if `s` is `null`, then neither |
| // `length` nor `isEven` will be invoked, and if `s` is non-`null`, then |
| // `length` can't return a `null` value. Either way, `isEven` can't be invoked |
| // on a `null` value, so the null-aware operator is not necessary. See |
| // [Understanding null safety](/null-safety/understanding-null-safety#smarter-null-aware-methods) |
| // for more details. |
| // |
| // The following code produces this diagnostic because `s` can't be `null`. |
| // |
| // ```dart |
| // void f(Object? o) { |
| // var s = o as String; |
| // s[!?.!]length; |
| // } |
| // ``` |
| // |
| // The reason `s` can't be null, despite the fact that `o` can be `null`, is |
| // because of the cast to `String`, which is a non-nullable type. If `o` ever |
| // has the value `null`, the cast will fail and the invocation of `length` |
| // will not happen. |
| // |
| // #### Common fixes |
| // |
| // Replace the null-aware operator with a non-null-aware equivalent; for |
| // example, change `?.` to `.`: |
| // |
| // ```dart |
| // int getLength(String s) { |
| // return s.length; |
| // } |
| // ``` |
| // |
| // (Note that the return type was also changed to be non-nullable, which might |
| // not be appropriate in some cases.) |
| static const StaticWarningCode INVALID_NULL_AWARE_OPERATOR = |
| StaticWarningCode( |
| 'INVALID_NULL_AWARE_OPERATOR', |
| "The receiver can't be null, so the null-aware operator '{0}' is " |
| "unnecessary.", |
| correction: "Try replacing the operator '{0}' with '{1}'.", |
| hasPublishedDocs: true); |
| |
| /** |
| * Parameters: |
| * 0: the null-aware operator that is invalid |
| * 1: the non-null-aware operator that can replace the invalid operator |
| */ |
| static const StaticWarningCode |
| INVALID_NULL_AWARE_OPERATOR_AFTER_SHORT_CIRCUIT = StaticWarningCode( |
| 'INVALID_NULL_AWARE_OPERATOR', |
| "The receiver can't be null because of short-circuiting, so the " |
| "null-aware operator '{0}' can't be used.", |
| correction: "Try replacing the operator '{0}' with '{1}'.", |
| hasPublishedDocs: true, |
| uniqueName: 'INVALID_NULL_AWARE_OPERATOR_AFTER_SHORT_CIRCUIT', |
| ); |
| |
| /** |
| * 7.1 Instance Methods: It is a static warning if an instance method |
| * <i>m1</i> overrides an instance member <i>m2</i>, the signature of |
| * <i>m2</i> explicitly specifies a default value for a formal parameter |
| * <i>p</i> and the signature of <i>m1</i> specifies a different default value |
| * for <i>p</i>. |
| */ |
| static const StaticWarningCode |
| INVALID_OVERRIDE_DIFFERENT_DEFAULT_VALUES_NAMED = StaticWarningCode( |
| 'INVALID_OVERRIDE_DIFFERENT_DEFAULT_VALUES_NAMED', |
| "Parameters can't override default values, this method overrides " |
| "'{0}.{1}' where '{2}' has a different value.", |
| correction: "Try using the same default value in both methods."); |
| |
| /** |
| * 7.1 Instance Methods: It is a static warning if an instance method |
| * <i>m1</i> overrides an instance member <i>m2</i>, the signature of |
| * <i>m2</i> explicitly specifies a default value for a formal parameter |
| * <i>p</i> and the signature of <i>m1</i> specifies a different default value |
| * for <i>p</i>. |
| */ |
| static const StaticWarningCode |
| INVALID_OVERRIDE_DIFFERENT_DEFAULT_VALUES_POSITIONAL = StaticWarningCode( |
| 'INVALID_OVERRIDE_DIFFERENT_DEFAULT_VALUES_POSITIONAL', |
| "Parameters can't override default values, this method overrides " |
| "'{0}.{1}' where this positional parameter has a different " |
| "value.", |
| correction: "Try using the same default value in both methods."); |
| |
| /** |
| * Parameters: |
| * 0: the name of the constant that is missing |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when a `switch` statement for an enum |
| // doesn't include an option for one of the values in the enumeration. |
| // |
| // Note that `null` is always a possible value for an enum and therefore also |
| // must be handled. |
| // |
| // #### Examples |
| // |
| // The following code produces this diagnostic because the enum constant `e2` |
| // isn't handled: |
| // |
| // ```dart |
| // enum E { e1, e2 } |
| // |
| // void f(E e) { |
| // [!switch (e)!] { |
| // case E.e1: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // If there's special handling for the missing values, then add a `case` |
| // clause for each of the missing values: |
| // |
| // ```dart |
| // enum E { e1, e2 } |
| // |
| // void f(E e) { |
| // switch (e) { |
| // case E.e1: |
| // break; |
| // case E.e2: |
| // break; |
| // } |
| // } |
| // ``` |
| // |
| // If the missing values should be handled the same way, then add a `default` |
| // clause: |
| // |
| // ```dart |
| // enum E { e1, e2 } |
| // |
| // void f(E e) { |
| // switch (e) { |
| // case E.e1: |
| // break; |
| // default: |
| // break; |
| // } |
| // } |
| // ``` |
| // TODO(brianwilkerson) This documentation will need to be updated when NNBD |
| // ships. |
| static const StaticWarningCode MISSING_ENUM_CONSTANT_IN_SWITCH = |
| StaticWarningCode( |
| 'MISSING_ENUM_CONSTANT_IN_SWITCH', "Missing case clause for '{0}'.", |
| correction: "Try adding a case clause for the missing constant, or " |
| "adding a default clause.", |
| hasPublishedDocs: true); |
| |
| /** |
| * No parameters. |
| */ |
| // #### Description |
| // |
| // The analyzer produces this diagnostic when the operand of the `!` operator |
| // can't be `null`. |
| // |
| // #### Example |
| // |
| // The following code produces this diagnostic because `x` can't be `null`: |
| // |
| // ```dart |
| // int f(int x) { |
| // return x[!!!]; |
| // } |
| // ``` |
| // |
| // #### Common fixes |
| // |
| // Remove the null check operator (`!`): |
| // |
| // ```dart |
| // int f(int x) { |
| // return x; |
| // } |
| // ``` |
| static const StaticWarningCode UNNECESSARY_NON_NULL_ASSERTION = |
| StaticWarningCode('UNNECESSARY_NON_NULL_ASSERTION', |
| "The '!' will have no effect because the receiver can't be null.", |
| correction: "Try removing the '!' operator.", hasPublishedDocs: true); |
| |
| /** |
| * Initialize a newly created error code to have the given [name]. The message |
| * associated with the error will be created from the given [message] |
| * template. The correction associated with the error will be created from the |
| * given [correction] template. |
| */ |
| const StaticWarningCode( |
| String name, |
| String message, { |
| String? correction, |
| bool hasPublishedDocs = false, |
| bool isUnresolvedIdentifier = false, |
| String? uniqueName, |
| }) : super( |
| correction: correction, |
| hasPublishedDocs: hasPublishedDocs, |
| isUnresolvedIdentifier: isUnresolvedIdentifier, |
| message: message, |
| name: name, |
| uniqueName: 'StaticWarningCode.${uniqueName ?? name}', |
| ); |
| |
| @override |
| ErrorSeverity get errorSeverity => ErrorSeverity.WARNING; |
| |
| @override |
| ErrorType get type => ErrorType.STATIC_WARNING; |
| } |