weexteam/weex_devtools_android

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Method formatHeadersAsJSON has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

  private static JSONObject formatHeadersAsJSON(InspectorHeaders headers) {
    JSONObject json = new JSONObject();
    for (int i = 0; i < headers.headerCount(); i++) {
      String name = headers.headerName(i);
      String value = headers.headerValue(i);

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method findFragmentForViewInFragmentManager has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

  @Nullable
  private static Object findFragmentForViewInFragmentManager(
      FragmentCompat compat,
      Object fragmentManager,
      View view) {

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method convertViewPropertyNameToCSSName has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

  private String convertViewPropertyNameToCSSName(String getterName) {
    // Split string by uppercase characters. Thankfully since
    // this is the android source we don't have to worry about
    // internationalization funk.

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method Slider has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

    public  void Slider(){

        for(final View caseView : mCaseListIndexView){
            if (((WXTextView)caseView).getText().toString().equals("TC_Slider")){
                Log.e(TAG, "TC_Slider find");

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Function 0 has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

/***/ function(module, exports, __webpack_require__) {

    ;__weex_define__("@weex-component/89d20f2b69944aec95a233f12eadd0e7", [], function(__weex_require__, __weex_exports__, __weex_module__){


Severity: Minor
Found in playground/app/src/main/assets/showcase/dropdown/dropdown-demo.js - About 25 mins to fix

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method buildDispatchTable has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

  private static Map<String, MethodDispatchHelper> buildDispatchTable(
      ObjectMapper objectMapper,
      Iterable<ChromeDevtoolsDomain> domainHandlers) {
    Util.throwIfNull(objectMapper);
    HashMap<String, MethodDispatchHelper> methods = new HashMap<String, MethodDispatchHelper>();

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method getValue has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

    public static <T> T getValue(Map<String, Object> data, String key, T defValue) {
        if (key != null) {
            if (data.get(key) != null) {
                try {
                    return (T) data.get(key);

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Method syncCall has a Cognitive Complexity of 6 (exceeds 5 allowed). Consider refactoring.
Open

    @ChromeDevtoolsMethod
    public SyncCallResponse syncCall(JsonRpcPeer peer, JSONObject params) {
        WXLogUtils.e("WxDebug-new >>>> syncCall=" + params);
        SyncCallResponse response = new SyncCallResponse();
        int syncId = params.optInt("syncId");

Cognitive Complexity

Cognitive Complexity is a measure of how difficult a unit of code is to intuitively understand. Unlike Cyclomatic Complexity, which determines how difficult your code will be to test, Cognitive Complexity tells you how difficult your code will be to read and comprehend.

A method's cognitive complexity is based on a few simple rules:

  • Code is not considered more complex when it uses shorthand that the language provides for collapsing multiple statements into one
  • Code is considered more complex for each "break in the linear flow of the code"
  • Code is considered more complex when "flow breaking structures are nested"

Further reading

Unnecessary semicolon.
Open

    ;

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Unnecessary semicolon.
Open

    ;

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Unnecessary semicolon.
Open

    ;__weex_define__("@weex-component/wxc-hn", [], function(__weex_require__, __weex_exports__, __weex_module__){

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Unnecessary semicolon.
Open

    ;__weex_define__("@weex-component/wxc-panel", [], function(__weex_require__, __weex_exports__, __weex_module__){

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Expected an assignment or function call and instead saw an expression.
Open

                    cb && cb();

Disallow Unused Expressions (no-unused-expressions)

An unused expression which has no effect on the state of the program indicates a logic error.

For example, n + 1; is not a syntax error, but it might be a typing mistake where a programmer meant an assignment statement n += 1; instead.

Rule Details

This rule aims to eliminate unused expressions which have no effect on the state of the program.

This rule does not apply to function calls or constructor calls with the new operator, because they could have side effects on the state of the program.

var i = 0;
function increment() { i += 1; }
increment(); // return value is unused, but i changed as a side effect

var nThings = 0;
function Thing() { nThings += 1; }
new Thing(); // constructed object is unused, but nThings changed as a side effect

This rule does not apply to directives (which are in the form of literal string expressions such as "use strict"; at the beginning of a script, module, or function).

Sequence expressions (those using a comma, such as a = 1, b = 2) are always considered unused unless their return value is assigned or used in a condition evaluation, or a function call is made with the sequence expression value.

Options

This rule, in its default state, does not require any arguments. If you would like to enable one or more of the following you may pass an object with the options set as follows:

  • allowShortCircuit set to true will allow you to use short circuit evaluations in your expressions (Default: false).
  • allowTernary set to true will enable you to use ternary operators in your expressions similarly to short circuit evaluations (Default: false).
  • allowTaggedTemplates set to true will enable you to use tagged template literals in your expressions (Default: false).

These options allow unused expressions only if all of the code paths either directly change the state (for example, assignment statement) or could have side effects (for example, function call).

Examples of incorrect code for the default { "allowShortCircuit": false, "allowTernary": false } options:

/*eslint no-unused-expressions: "error"*/

0

if(0) 0

{0}

f(0), {}

a && b()

a, b()

c = a, b;

a() && function namedFunctionInExpressionContext () {f();}

(function anIncompleteIIFE () {});

injectGlobal`body{ color: red; }`

Note that one or more string expression statements (with or without semi-colons) will only be considered as unused if they are not in the beginning of a script, module, or function (alone and uninterrupted by other statements). Otherwise, they will be treated as part of a "directive prologue", a section potentially usable by JavaScript engines. This includes "strict mode" directives.

"use strict";
"use asm"
"use stricter";
"use babel"
"any other strings like this in the prologue";

Examples of correct code for the default { "allowShortCircuit": false, "allowTernary": false } options:

/*eslint no-unused-expressions: "error"*/

{} // In this context, this is a block statement, not an object literal

{myLabel: someVar} // In this context, this is a block statement with a label and expression, not an object literal

function namedFunctionDeclaration () {}

(function aGenuineIIFE () {}());

f()

a = 0

new C

delete a.b

void a

allowShortCircuit

Examples of incorrect code for the { "allowShortCircuit": true } option:

/*eslint no-unused-expressions: ["error", { "allowShortCircuit": true }]*/

a || b

Examples of correct code for the { "allowShortCircuit": true } option:

/*eslint no-unused-expressions: ["error", { "allowShortCircuit": true }]*/

a && b()
a() || (b = c)

allowTernary

Examples of incorrect code for the { "allowTernary": true } option:

/*eslint no-unused-expressions: ["error", { "allowTernary": true }]*/

a ? b : 0
a ? b : c()

Examples of correct code for the { "allowTernary": true } option:

/*eslint no-unused-expressions: ["error", { "allowTernary": true }]*/

a ? b() : c()
a ? (b = c) : d()

allowShortCircuit and allowTernary

Examples of correct code for the { "allowShortCircuit": true, "allowTernary": true } options:

/*eslint no-unused-expressions: ["error", { "allowShortCircuit": true, "allowTernary": true }]*/

a ? b() || (c = d) : e()

allowTaggedTemplates

Examples of incorrect code for the { "allowTaggedTemplates": true } option:

/*eslint no-unused-expressions: ["error", { "allowTaggedTemplates": true }]*/

`some untagged template string`;

Examples of correct code for the { "allowTaggedTemplates": true } option:

/*eslint no-unused-expressions: ["error", { "allowTaggedTemplates": true }]*/

tag`some tagged template string`;

Source: http://eslint.org/docs/rules/

Unnecessary semicolon.
Open

    ;__weex_define__("@weex-component/wxc-countdown", [], function(__weex_require__, __weex_exports__, __weex_module__){

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Move the invocation into the parens that contain the function.
Open

/******/ (function(modules) { // webpackBootstrap

Require IIFEs to be Wrapped (wrap-iife)

You can immediately invoke function expressions, but not function declarations. A common technique to create an immediately-invoked function expression (IIFE) is to wrap a function declaration in parentheses. The opening parentheses causes the contained function to be parsed as an expression, rather than a declaration.

// function expression could be unwrapped
var x = function () { return { y: 1 };}();

// function declaration must be wrapped
function () { /* side effects */ }(); // SyntaxError

Rule Details

This rule requires all immediately-invoked function expressions to be wrapped in parentheses.

Options

This rule has two options, a string option and an object option.

String option:

  • "outside" enforces always wrapping the call expression. The default is "outside".
  • "inside" enforces always wrapping the function expression.
  • "any" enforces always wrapping, but allows either style.

Object option:

  • "functionPrototypeMethods": true additionally enforces wrapping function expressions invoked using .call and .apply. The default is false.

outside

Examples of incorrect code for the default "outside" option:

/*eslint wrap-iife: ["error", "outside"]*/

var x = function () { return { y: 1 };}(); // unwrapped
var x = (function () { return { y: 1 };})(); // wrapped function expression

Examples of correct code for the default "outside" option:

/*eslint wrap-iife: ["error", "outside"]*/

var x = (function () { return { y: 1 };}()); // wrapped call expression

inside

Examples of incorrect code for the "inside" option:

/*eslint wrap-iife: ["error", "inside"]*/

var x = function () { return { y: 1 };}(); // unwrapped
var x = (function () { return { y: 1 };}()); // wrapped call expression

Examples of correct code for the "inside" option:

/*eslint wrap-iife: ["error", "inside"]*/

var x = (function () { return { y: 1 };})(); // wrapped function expression

any

Examples of incorrect code for the "any" option:

/*eslint wrap-iife: ["error", "any"]*/

var x = function () { return { y: 1 };}(); // unwrapped

Examples of correct code for the "any" option:

/*eslint wrap-iife: ["error", "any"]*/

var x = (function () { return { y: 1 };}()); // wrapped call expression
var x = (function () { return { y: 1 };})(); // wrapped function expression

functionPrototypeMethods

Examples of incorrect code for this rule with the "inside", { "functionPrototypeMethods": true } options:

/* eslint wrap-iife: [2, "inside", { functionPrototypeMethods: true }] */

var x = function(){ foo(); }()
var x = (function(){ foo(); }())
var x = function(){ foo(); }.call(bar)
var x = (function(){ foo(); }.call(bar))

Examples of correct code for this rule with the "inside", { "functionPrototypeMethods": true } options:

/* eslint wrap-iife: [2, "inside", { functionPrototypeMethods: true }] */

var x = (function(){ foo(); })()
var x = (function(){ foo(); }).call(bar)

Source: http://eslint.org/docs/rules/

Unnecessary semicolon.
Open

    ;__weex_define__("@weex-component/index", [], function(__weex_require__, __weex_exports__, __weex_module__){

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Missing radix parameter.
Open

                this.time.M = String(parseInt(remain / 60));

Require Radix Parameter (radix)

When using the parseInt() function it is common to omit the second argument, the radix, and let the function try to determine from the first argument what type of number it is. By default, parseInt() will autodetect decimal and hexadecimal (via 0x prefix). Prior to ECMAScript 5, parseInt() also autodetected octal literals, which caused problems because many developers assumed a leading 0 would be ignored.

This confusion led to the suggestion that you always use the radix parameter to parseInt() to eliminate unintended consequences. So instead of doing this:

var num = parseInt("071");      // 57

Do this:

var num = parseInt("071", 10);  // 71

ECMAScript 5 changed the behavior of parseInt() so that it no longer autodetects octal literals and instead treats them as decimal literals. However, the differences between hexadecimal and decimal interpretation of the first parameter causes many developers to continue using the radix parameter to ensure the string is interpreted in the intended way.

On the other hand, if the code is targeting only ES5-compliant environments passing the radix 10 may be redundant. In such a case you might want to disallow using such a radix.

Rule Details

This rule is aimed at preventing the unintended conversion of a string to a number of a different base than intended or at preventing the redundant 10 radix if targeting modern environments only.

Options

There are two options for this rule:

  • "always" enforces providing a radix (default)
  • "as-needed" disallows providing the 10 radix

always

Examples of incorrect code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071");

var num = parseInt(someValue);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071", 10);

var num = parseInt("071", 8);

var num = parseFloat(someValue);

as-needed

Examples of incorrect code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071", 10);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071");

var num = parseInt("071", 8);

var num = parseFloat(someValue);

When Not To Use It

If you don't want to enforce either presence or omission of the 10 radix value you can turn this rule off.

Further Reading

Unnecessary semicolon.
Open

    ;

disallow unnecessary semicolons (no-extra-semi)

Typing mistakes and misunderstandings about where semicolons are required can lead to semicolons that are unnecessary. While not technically an error, extra semicolons can cause confusion when reading code.

Rule Details

This rule disallows unnecessary semicolons.

Examples of incorrect code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;;

function foo() {
    // code
};

Examples of correct code for this rule:

/*eslint no-extra-semi: "error"*/

var x = 5;

var foo = function() {
    // code
};

When Not To Use It

If you intentionally use extra semicolons then you can disable this rule.

Related Rules

Missing radix parameter.
Open

                this.time.m = String(parseInt((remain - parseInt(this.time.H) * 3600) / 60));

Require Radix Parameter (radix)

When using the parseInt() function it is common to omit the second argument, the radix, and let the function try to determine from the first argument what type of number it is. By default, parseInt() will autodetect decimal and hexadecimal (via 0x prefix). Prior to ECMAScript 5, parseInt() also autodetected octal literals, which caused problems because many developers assumed a leading 0 would be ignored.

This confusion led to the suggestion that you always use the radix parameter to parseInt() to eliminate unintended consequences. So instead of doing this:

var num = parseInt("071");      // 57

Do this:

var num = parseInt("071", 10);  // 71

ECMAScript 5 changed the behavior of parseInt() so that it no longer autodetects octal literals and instead treats them as decimal literals. However, the differences between hexadecimal and decimal interpretation of the first parameter causes many developers to continue using the radix parameter to ensure the string is interpreted in the intended way.

On the other hand, if the code is targeting only ES5-compliant environments passing the radix 10 may be redundant. In such a case you might want to disallow using such a radix.

Rule Details

This rule is aimed at preventing the unintended conversion of a string to a number of a different base than intended or at preventing the redundant 10 radix if targeting modern environments only.

Options

There are two options for this rule:

  • "always" enforces providing a radix (default)
  • "as-needed" disallows providing the 10 radix

always

Examples of incorrect code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071");

var num = parseInt(someValue);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071", 10);

var num = parseInt("071", 8);

var num = parseFloat(someValue);

as-needed

Examples of incorrect code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071", 10);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071");

var num = parseInt("071", 8);

var num = parseFloat(someValue);

When Not To Use It

If you don't want to enforce either presence or omission of the 10 radix value you can turn this rule off.

Further Reading

Missing radix parameter.
Open

                this.time.s = String(remain - parseInt(this.time.M) * 60);

Require Radix Parameter (radix)

When using the parseInt() function it is common to omit the second argument, the radix, and let the function try to determine from the first argument what type of number it is. By default, parseInt() will autodetect decimal and hexadecimal (via 0x prefix). Prior to ECMAScript 5, parseInt() also autodetected octal literals, which caused problems because many developers assumed a leading 0 would be ignored.

This confusion led to the suggestion that you always use the radix parameter to parseInt() to eliminate unintended consequences. So instead of doing this:

var num = parseInt("071");      // 57

Do this:

var num = parseInt("071", 10);  // 71

ECMAScript 5 changed the behavior of parseInt() so that it no longer autodetects octal literals and instead treats them as decimal literals. However, the differences between hexadecimal and decimal interpretation of the first parameter causes many developers to continue using the radix parameter to ensure the string is interpreted in the intended way.

On the other hand, if the code is targeting only ES5-compliant environments passing the radix 10 may be redundant. In such a case you might want to disallow using such a radix.

Rule Details

This rule is aimed at preventing the unintended conversion of a string to a number of a different base than intended or at preventing the redundant 10 radix if targeting modern environments only.

Options

There are two options for this rule:

  • "always" enforces providing a radix (default)
  • "as-needed" disallows providing the 10 radix

always

Examples of incorrect code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071");

var num = parseInt(someValue);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the default "always" option:

/*eslint radix: "error"*/

var num = parseInt("071", 10);

var num = parseInt("071", 8);

var num = parseFloat(someValue);

as-needed

Examples of incorrect code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071", 10);

var num = parseInt("071", "abc");

var num = parseInt();

Examples of correct code for the "as-needed" option:

/*eslint radix: ["error", "as-needed"]*/

var num = parseInt("071");

var num = parseInt("071", 8);

var num = parseFloat(someValue);

When Not To Use It

If you don't want to enforce either presence or omission of the 10 radix value you can turn this rule off.

Further Reading

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