ExpressionStatement "ExpressionStatement" start:"CallExpression" start:"MemberExpression" start:"Identifier" start:"obj" } computed:"StringLiteral" start:"x" } } arguments:"NumericLiteral" start:"44347895_写ast处理代码的套路">写AST处理代码的套路接下来看看AST处理代码的骨架:
import generator from '@babel/generator';import traverse from '@babel/traverse';import { Node, isIdentifier, isMemberExpression, // ...} from '@babel/types';const ast = parser.parse(jsCode);traverse(ast, { // 在递归遍历子树之前,对是Identifier的节点进行修改 Identifier (path: NodePath<Identifier>) {...}});// 省略多个traversetraverse(ast, { // 是某种类型的节点,则调用对应的函数进行修改 NumericLiteral (path) {...}, StringLiteral (path) {...}});const { code } = generator(ast);
traverse
用dfs遍历AST,并在遍历前后提供钩子给我们,用于修改AST的节点。
我们需要知道关于节点的一些知识。所有的节点都是Node
,用IEDA点击Node
查看类型定义:
export type Node = Accessor | AnyTypeAnnotation | ArgumentPlaceholder | ArrayExpression | ArrayPattern | ArrayTypeAnnotation | ArrowFunctionExpression | AssignmentExpression | AssignmentPattern | AwaitExpression | BigIntLiteral | Binary | BinaryExpression | BindExpression | Block | BlockParent | BlockStatement | BooleanLiteral | BooleanLiteralTypeAnnotation | BooleanTypeAnnotation | BreakStatement | CallExpression | CatchClause | Class | ClassAccessorProperty | ClassBody | ClassDeclaration | ClassExpression | ClassImplements | ClassMethod | ClassPrivateMethod | ClassPrivateProperty | ClassProperty | CompletionStatement | Conditional | ConditionalExpression | ContinueStatement | DebuggerStatement | DecimalLiteral | Declaration | DeclareClass | DeclareExportAllDeclaration | DeclareExportDeclaration | DeclareFunction | DeclareInterface | DeclareModule | DeclareModuleExports | DeclareOpaqueType | DeclareTypeAlias | DeclareVariable | DeclaredPredicate | Decorator | Directive | DirectiveLiteral | DoExpression | DoWhileStatement | EmptyStatement | EmptyTypeAnnotation | EnumBody | EnumBooleanBody | EnumBooleanMember | EnumDeclaration | EnumDefaultedMember | EnumMember | EnumNumberBody | EnumNumberMember | EnumStringBody | EnumStringMember | EnumSymbolBody | ExistsTypeAnnotation | ExportAllDeclaration | ExportDeclaration | ExportDefaultDeclaration | ExportDefaultSpecifier | ExportNamedDeclaration | ExportNamespaceSpecifier | ExportSpecifier | Expression | ExpressionStatement | ExpressionWrapper | File | Flow | FlowBaseAnnotation | FlowDeclaration | FlowPredicate | FlowType | For | ForInStatement | ForOfStatement | ForStatement | ForXStatement | Function | FunctionDeclaration | FunctionExpression | FunctionParent | FunctionTypeAnnotation | FunctionTypeParam | GenericTypeAnnotation | Identifier | IfStatement | Immutable | Import | ImportAttribute | ImportDeclaration | ImportDefaultSpecifier | ImportNamespaceSpecifier | ImportSpecifier | IndexedAccessType | InferredPredicate | InterfaceDeclaration | InterfaceExtends | InterfaceTypeAnnotation | InterpreterDirective | IntersectionTypeAnnotation | JSX | JSXAttribute | JSXClosingElement | JSXClosingFragment | JSXElement | JSXEmptyExpression | JSXExpressionContainer | JSXFragment | JSXIdentifier | JSXMemberExpression | JSXNamespacedName | JSXOpeningElement | JSXOpeningFragment | JSXSpreadAttribute | JSXSpreadChild | JSXText | LVal | LabeledStatement | Literal | LogicalExpression | Loop | MemberExpression | MetaProperty | Method | Miscellaneous | MixedTypeAnnotation | ModuleDeclaration | ModuleExpression | ModuleSpecifier | NewExpression | Noop | NullLiteral | NullLiteralTypeAnnotation | NullableTypeAnnotation | NumberLiteral | NumberLiteralTypeAnnotation | NumberTypeAnnotation | NumericLiteral | ObjectExpression | ObjectMember | ObjectMethod | ObjectPattern | ObjectProperty | ObjectTypeAnnotation | ObjectTypeCallProperty | ObjectTypeIndexer | ObjectTypeInternalSlot | ObjectTypeProperty | ObjectTypeSpreadProperty | OpaqueType | OptionalCallExpression | OptionalIndexedAccessType | OptionalMemberExpression | ParenthesizedExpression | Pattern | PatternLike | PipelineBareFunction | PipelinePrimaryTopicReference | PipelineTopicExpression | Placeholder | Private | PrivateName | Program | Property | Pureish | QualifiedTypeIdentifier | RecordExpression | RegExpLiteral | RegexLiteral | RestElement | RestProperty | ReturnStatement | Scopable | SequenceExpression | SpreadElement | SpreadProperty | Standardized | Statement | StaticBlock | StringLiteral | StringLiteralTypeAnnotation | StringTypeAnnotation | Super | SwitchCase | SwitchStatement | SymbolTypeAnnotation | TSAnyKeyword | TSArrayType | TSAsExpression | TSBaseType | TSBigIntKeyword | TSBooleanKeyword | TSCallSignatureDeclaration | TSConditionalType | TSConstructSignatureDeclaration | TSConstructorType | TSDeclareFunction | TSDeclareMethod | TSEntityName | TSEnumDeclaration | TSEnumMember | TSExportAssignment | TSExpressionWithTypeArguments | TSExternalModuleReference | TSFunctionType | TSImportEqualsDeclaration | TSImportType | TSIndexSignature | TSIndexedAccessType | TSInferType | TSInstantiationExpression | TSInterfaceBody | TSInterfaceDeclaration | TSIntersectionType | TSIntrinsicKeyword | TSLiteralType | TSMappedType | TSMethodSignature | TSModuleBlock | TSModuleDeclaration | TSNamedTupleMember | TSNamespaceExportDeclaration | TSNeverKeyword | TSNonNullExpression | TSNullKeyword | TSNumberKeyword | TSObjectKeyword | TSOptionalType | TSParameterProperty | TSParenthesizedType | TSPropertySignature | TSQualifiedName | TSRestType | TSStringKeyword | TSSymbolKeyword | TSThisType | TSTupleType | TSType | TSTypeAliasDeclaration | TSTypeAnnotation | TSTypeAssertion | TSTypeElement | TSTypeLiteral | TSTypeOperator | TSTypeParameter | TSTypeParameterDeclaration | TSTypeParameterInstantiation | TSTypePredicate | TSTypeQuery | TSTypeReference | TSUndefinedKeyword | TSUnionType | TSUnknownKeyword | TSVoidKeyword | TaggedTemplateExpression | TemplateElement | TemplateLiteral | Terminatorless | ThisExpression | ThisTypeAnnotation | ThrowStatement | TopicReference | TryStatement | TupleExpression | TupleTypeAnnotation | TypeAlias | TypeAnnotation | TypeCastExpression | TypeParameter | TypeParameterDeclaration | TypeParameterInstantiation | TypeScript | TypeofTypeAnnotation | UnaryExpression | UnaryLike | UnionTypeAnnotation | UpdateExpression | UserWhitespacable | V8IntrinsicIdentifier | VariableDeclaration | VariableDeclarator | Variance | VoidTypeAnnotation | While | WhileStatement | WithStatement | YieldExpression;
Node
包含了MemberExpression
、Identifier
和StringLiteral
等。
对于NodePath
我们暂时不需要知道太多,只需要知道:
path.replaceInline(Nodes extends Node | readonly Node[])
(可以传Node[]
)、path.replaceWith(Node)
等方法可以替换当前节点。path.remove()
可以删除当前节点。path.node
可以获取NodePath
对应的节点。
我们写AST处理代码的流程一般是:
- 通过AST的相关属性来匹配特征,找到要修改的节点所对应的
NodePath
。这部分代码占了绝大部分。这一步需要大量使用”类型守卫“的技巧来保证我们的代码考虑到了各种边界条件。 - 调用
path.replaceInline
等方法来修改AST。 - 删除对修改后的AST无用的节点,如未用到的变量和函数声明。
这个工作最困难的地方在于,我们需要不停地观看 astexplorer 给出的AST,来调整代码。最后再强调一次为什么要用TS:
- Babel的官方文档语焉不详,TypeScript的类型提示结合IDE是更好的文档。
- 写类型守卫的过程是在倒逼自己去思考各种边界情况,写出更健壮的代码。
接下来给出几个有通用性的操作的demo,来迅速入门。
还原不直观的编码字符串或数值
对于数字,希望把0x14
等变成10进制;对于常量串,希望把'\u', '\x'
恢复成可见字符。参考链接6的代码处理得很不错。src/translate_literal.ts
:
import traverse from '@babel/traverse';import { stringLiteral, Node } from '@babel/types';export function translateLiteral (ast: Node) { traverse(ast, { NumericLiteral (path) { const node = path.node; // 直接去除node.extra即可 if (node.extra && /^0[obx]/i.test(node.extra.raw as string)) { node.extra = undefined; } }, StringLiteral (path) { const node = path.node; if (node.extra && /\\[ux]/gi.test(node.extra.raw as string)) { let nodeValue = ''; try { nodeValue = decodeURIComponent(escape(node.value)); } catch (error) { nodeValue = node.value; } path.replaceWith(stringLiteral(nodeValue)); path.node.extra = { 'raw': JSON.stringify(nodeValue), 'rawValue': nodeValue }; } } });}// 调用:translateLiteral(ast);
Babel实现变量重命名
我们设计了一个简单的变量重命名方案:先遍历一次AST,收集所有”可以重命名的“变量,再给出新名字(形如v1, v2, ...
),最后再遍历一次AST进行替换。
- 为了提供最大的灵活性,我们设计了一个
canReplace
函数,让调用者自己决定哪些变量是参与替换的。 - 我们设计了一个
renameMap
,允许调用者给出期望的变量重命名方案,提高可读性。
注意:对于全局变量与局部变量存在同名的情况,这段代码可能是有问题的。希望能基于作用域进行完善。
import traverse, { NodePath } from '@babel/traverse';import { Identifier, Node } from '@babel/types';// 对于全局变量与局部变量同名的情况,这段代码可能是有问题的export function renameVars ( ast: Node, canReplace: (name: string) => boolean = () => {return true;}, renameMap: {[key: string]: string} = {}) { const names = new Set<string>(); traverse(ast, { Identifier (path: NodePath<Identifier>) { const oldName = path.node.name; if (!canReplace(oldName)) return; names.add(oldName); } }); let i = 0; names.forEach((name) => { if (!Object.getOwnPropertyDescriptor(renameMap, name)) { renameMap[name] = `v${++i}`; } }); traverse(ast, { Identifier (path: NodePath<Identifier>) { const oldName = path.node.name; if (!canReplace(oldName)) return; path.node.name = renameMap[oldName]; } });}// 调用renameVars( ast, (name: string) => name.substring(0, 3) === '_0x', { enc: 'enc', _0x263396: 'i', _0x13adf6: 'out' });
Babel MemberExpression Array Notation转Dot Notation
前文提到,Dot Notation
和Array Notation
的computed
分别为false
和true
。因此代码会很简单。
import traverse, { NodePath } from '@babel/traverse';import { identifier, Node, MemberExpression } from '@babel/types';// console['log']() 变 console.log()// computed 属性如果为 false,是表示 . 来引用成员// computed 属性为 true,则是 [] 来引用成员export function memberExpComputedToFalse (ast: Node) { traverse(ast, { MemberExpression (path: NodePath<MemberExpression>) { // path.get('property')获取到的是一个NodePath类型 const propertyPath = path.get('property'); if (!propertyPath.isStringLiteral()) return; const val = propertyPath.node.value; path.node.computed = false; propertyPath.replaceWith(identifier(val)); } });}
引言
这个网站就是开源项目 javascript-obfuscator
(简称OB)的Web UI。它提供了一个Strings Transformations
选项用于隐藏常量串。据我所知,还没有给出Strings Transformations
解决方案的blog,因此可谓全网首创。我们勾选String Array, String Array Rotate, String Array Shuffle
这3个选项,观察一下生成的代码的特征:
(function(_0x1f23fa, _0x502274) { var _0x1841e6 = _0x546b, _0x54332a = _0x1f23fa(); while ([]) { try { var _0x37b83c = -parseInt(_0x1841e6(0x72)) / 0x1 + parseInt(_0x1841e6(0x73)) / 0x2 * (-parseInt(_0x1841e6(0x7c)) / 0x3) + parseInt(_0x1841e6(0x88)) / 0x4 * (parseInt(_0x1841e6(0x89)) / 0x5) + -parseInt(_0x1841e6(0x71)) / 0x6 + parseInt(_0x1841e6(0x6c)) / 0x7 * (-parseInt(_0x1841e6(0x85)) / 0x8) + -parseInt(_0x1841e6(0x82)) / 0x9 + -parseInt(_0x1841e6(0x7e)) / 0xa * (-parseInt(_0x1841e6(0x78)) / 0xb); if (_0x37b83c === _0x502274) break; else _0x54332a['push'](_0x54332a['shift']()); } catch (_0x258ebb) { _0x54332a['push'](_0x54332a['shift']()); } }}(_0x3ddf, 0x20d95));function _0x546b(_0x280dd3, _0x383a2d) { var _0x3ddf54 = _0x3ddf(); return _0x546b = function(_0x546b3f, _0x142ae2) { _0x546b3f = _0x546b3f - 0x6c; var _0x233a8a = _0x3ddf54[_0x546b3f]; return _0x233a8a; }, _0x546b(_0x280dd3, _0x383a2d);}function _0x3ddf() { var _0x45c37a = ['30037Sxrenc', 'error!', 'len\x20error', 'XmvLm', 'Orz..', '1159374JpqDju', '267734qPEpMO', '364750QkecUn', 'shrai', 'length', 'KUTlo', 'Vwtjq', '99juDGtv', 'FhQZn', 'charCodeAt', 'FdUfK', '3tSVDal', 'Ajnur', '874980MJshmD', 'KclRu', 'Fhqhk', 'charAt', '187074oiwMPp', 'PjAeQ', 'ewhZd', '328PNtXbI', 'congratulation!', 'DpUmp', '57576xxZPaZ', '65fmhmYN', 'ualDk', 'RHSOY', 'log']; _0x3ddf = function() { return _0x45c37a; }; return _0x3ddf();}
可知:
- 有一个自执行函数和两个函数。这3个函数会随机换位置,干扰你的分析。
- 有常量串数组的函数
_0x3ddf
,利用闭包来给出常量串数组,记为sl
。 _0x546b
函数仅仅相当于(idx) => sl[idx - 0x6c]
。- 自执行函数可以进行常量串数组的
shuffle
和rotate
。
再看常量串的获取方式:_0x583af1(0x74)
。因此我们的目标就是把这种函数调用恢复为常量串。开工!
首先,每个函数开头都有var _0x583af1 = _0x546b
这样的定义,因此我们需要识别实际上等于_0x546b
的变量。相关代码:
// 如果常量表不止1处,则此代码不正确 const stringLiteralFuncs = ['_0x546b']; // 收集与常量串隐藏有关的变量 traverse(ast, { VariableDeclarator (path) { const vaNode = path.node; if (!isIdentifier(vaNode.init) || !isIdentifier(vaNode.id)) return; if (stringLiteralFuncs.includes(vaNode.init.name)) { stringLiteralFuncs.push(vaNode.id.name); } } });
接下来需要拿到最终的常量串数组。暂时没找到优雅的方式,只能先用一个妥协方案:
- 因为常量串数组的最终形态是固定的,所以我们首先直接在浏览器控制台运行一下上面那段代码,再输入
_0x3ddf()
拿到常量串数组的最终形态,然后把它硬编码进代码里。 - 获取常量串的函数,我们设计为自行实现,即硬编码进代码里。
获取常量串的相关代码(直接展示了函数restoreStringLiteral
如何调用):
restoreStringLiteral(ast, (idx: number) => { return ['30037Sxrenc', 'error!', 'len\x20error', 'XmvLm', 'Orz..', '1159374JpqDju', '267734qPEpMO', '364750QkecUn', 'shrai', 'length', 'KUTlo', 'Vwtjq', '99juDGtv', 'FhQZn', 'charCodeAt', 'FdUfK', '3tSVDal', 'Ajnur', '874980MJshmD', 'KclRu', 'Fhqhk', 'charAt', '187074oiwMPp', 'PjAeQ', 'ewhZd', '328PNtXbI', 'congratulation!', 'DpUmp', '57576xxZPaZ', '65fmhmYN', 'ualDk', 'RHSOY', 'log'][idx - 108];});// 调用:getStringArr(idx)
最后,只需要path.replaceWith(stringLiteral(getStringArr(idx)))
完成节点的替换。
完整的相关代码:
function restoreStringLiteral (ast: Node, getStringArr: (idx: number) => string) { // 如果常量表不止1处,则此代码不正确 const stringLiteralFuncs = ['_0x546b']; // 收集与常量串隐藏有关的变量 traverse(ast, { VariableDeclarator (path) { const vaNode = path.node; if (!isIdentifier(vaNode.init) || !isIdentifier(vaNode.id)) return; if (stringLiteralFuncs.includes(vaNode.init.name)) { stringLiteralFuncs.push(vaNode.id.name); } } }); traverse(ast, { CallExpression (path) { const cNode = path.node; if (!isIdentifier(cNode.callee)) return; const varName = cNode.callee.name; if (!stringLiteralFuncs.includes(varName)) return; if (cNode.arguments.length !== 1 || !isNumericLiteral(cNode.arguments[0])) return; const idx = cNode.arguments[0].value; path.replaceWith(stringLiteral(getStringArr(idx))); } });}restoreStringLiteral(ast, (idx: number) => { return ['30037Sxrenc', 'error!', 'len\x20error', 'XmvLm', 'Orz..', '1159374JpqDju', '267734qPEpMO', '364750QkecUn', 'shrai', 'length', 'KUTlo', 'Vwtjq', '99juDGtv', 'FhQZn', 'charCodeAt', 'FdUfK', '3tSVDal', 'Ajnur', '874980MJshmD', 'KclRu', 'Fhqhk', 'charAt', '187074oiwMPp', 'PjAeQ', 'ewhZd', '328PNtXbI', 'congratulation!', 'DpUmp', '57576xxZPaZ', '65fmhmYN', 'ualDk', 'RHSOY', 'log'][idx - 108];});
TODO:找到一种避免硬编码的方式!
用Babel解析AST处理OB混淆JS代码(四):处理控制流平坦化
引言
控制流平坦化通过引入状态机与循环,破坏代码上下文之间的阅读连续性和代码块之间的关联性,将若干个分散的小整体整合成一个巨大的循环体。实现方式是将代码块之间的原有顺序关系打断,改为由一个分发器来控制代码块的跳转。特点:
- 无法还原成原来具体的函数。
- 无法使用以函数为单位的调试方法,大幅度增加调试难度。
- 降低代码运行效率,提高爬虫运行时执行JS的资源成本。
- 可根据JS运行时检测到的某些因素自由跳转到蜜罐或跳出代码执行。
所有教程都没有提及的是:控制流平坦化实际上至少有两种。第一种是语句级别的,用于打乱语序。第二种是表达式级别的,用于替换双目运算符、逻辑运算符和常量等。我们将尽力为 OB网站 提供的两种控制流平坦化提供解决方案。
去除基于switch语句的控制流平坦化:先来解析一个简单的demo
这个demo来自参考链接4。待解析文件src/inputs/hw.js
:
var arr = '3,0,1,2,4'.split(',');var x = 0;var cnt = 0;while (true) { switch (arr[cnt++]) { case '0': console.log('case 0'); x += 5; continue; case '1': console.log('case 1'); x += 4; continue; case '2': console.log('case 2'); x += 3; continue; case '3': console.log('case 3'); x += 2; continue; case '4': console.log('case 4'); x += 1; continue; } break;}
思路
- 获取
arr
运行时的值(是个定值)。 - 用Babel读取每一个
case
的body,具体取哪个case
用arr
确定。这里的body是Statement[]
。 - 把上面的所有body拼接起来,得所求,类型仍为
Statement[]
。调用path.replaceInline(Statement[])
来获取去除了控制流平坦化的代码。
src/hw.ts
的大多数代码都只是做第一步,因为考虑到源代码可能会变,希望有一定通用性。为了方便,也可以选择直接硬编码第一步的结果。因此代码的骨架如下:
const jsCode = getFile('src/inputs/hw.js');const ast = parser.parse(jsCode);const decodeWhileOpts = { WhileStatement (path: NodePath<WhileStatement>) { const { body } = path.node; const switchNode = (body as BlockStatement).body[0]; if (!isSwitchStatement(switchNode)) return; const { discriminant, cases } = switchNode; // 省略第一步的代码... const replaceBody = arrVal.reduce((replaceBody, index) => { const caseBody = cases[+index].consequent; if (isContinueStatement(caseBody[caseBody.length - 1])) { caseBody.pop(); } return replaceBody.concat(caseBody); }, [] as Statement[]); path.replaceInline(replaceBody); }};traverse(ast, decodeWhileOpts);const { code } = generator(ast);writeOutputToFile('hw_out.js', code);
这里偷懒了一下,直接用cases[+index]
来取具体的case
了,实际情况很可能要写额外的代码获取cases[index].test.value
。
完整代码看src/hw.ts
。注意:
- 我们在项目根目录用
npm run cff hw
来运行src/hw.ts
,所以读写文件要相对于项目根目录。
去除基于switch语句的控制流平坦化:更综合的demo
这个demo和上一个demo难度一样,但结合了常量串隐藏。准备以下程序:
function enc (inp) { var i = 0; i += -1; var out = ''; i += 1; for (;i < inp.length;++i) { var v = 0; if (i & 1) v = 0x33; else v = 0x31; out += String.fromCharCode(inp[i].charCodeAt() ^ v); } return out;}if (enc('flag{hans}') === 'W_PTJ[P]BN') console.log('pass');else console.log('try again');
在OB网站勾选Control Flow Flattening
,Control Flow Flattening Threshold
选择1,String Transformations
勾选String Array, String Array Rotate, String Array Shuffle
,String Array Threshold
选择1。得以下代码:
var _0x47f9f1 = _0x27c4;(function (_0x47124a, _0x19f73e) { var _0x3b6574 = _0x27c4, _0x2c307d = _0x47124a(); while ([]) { try { var _0x585cd6 = parseInt(_0x3b6574(0x95)) / 0x1 * (parseInt(_0x3b6574(0x8f)) / 0x2) + -parseInt(_0x3b6574(0x97)) / 0x3 * (parseInt(_0x3b6574(0x9d)) / 0x4) + -parseInt(_0x3b6574(0x89)) / 0x5 + -parseInt(_0x3b6574(0x98)) / 0x6 + -parseInt(_0x3b6574(0x8d)) / 0x7 * (-parseInt(_0x3b6574(0x94)) / 0x8) + parseInt(_0x3b6574(0x96)) / 0x9 * (parseInt(_0x3b6574(0xa1)) / 0xa) + parseInt(_0x3b6574(0x92)) / 0xb; if (_0x585cd6 === _0x19f73e) break; else _0x2c307d['push'](_0x2c307d['shift']()); } catch (_0x28b17f) { _0x2c307d['push'](_0x2c307d['shift']()); } }}(_0x379e, 0xdbab3));function _0x27c4 (_0x122105, _0x24f040) { var _0x379e52 = _0x379e(); return _0x27c4 = function (_0x27c4d4, _0x569919) { _0x27c4d4 = _0x27c4d4 - 0x89; var _0x5dfb85 = _0x379e52[_0x27c4d4]; return _0x5dfb85; }, _0x27c4(_0x122105, _0x24f040);}function _0x379e () { var _0x3ed6e2 = ['1914456NQDFwp', '1xRwaZJ', '36ZbcbZP', '3gJgrjU', '8162226GwaJpl', '3|4|2|0|5|1', 'split', 'charCodeAt', 'pass', '6278120IHpVNF', 'W_PTJ[P]BN', 'length', 'fromCharCode', '939280gOLaZV', '661835nuUXrL', 'dKifE', 'try\x20again', 'log', '7aEbwep', 'awvtQ', '2804302XtaWgC', 'rmnID', 'flag{hans}', '21393471OyFTzd', 'lXUhG']; _0x379e = function () { return _0x3ed6e2; }; return _0x379e();}function enc (_0x3bf54e) { var _0x55bea2 = _0x27c4, _0x550d17 = { 'dKifE': _0x55bea2(0x99), 'lXUhG': function (_0x7a78d6, _0x13ee42) { return _0x7a78d6 < _0x13ee42; }, 'rmnID': function (_0x28f0fb, _0x77896d) { return _0x28f0fb & _0x77896d; }, 'awvtQ': function (_0x26b565, _0x3ffc0b) { return _0x26b565 ^ _0x3ffc0b; } }, _0x31ce85 = _0x550d17[_0x55bea2(0x8a)][_0x55bea2(0x9a)]('|'), _0x1ffdde = 0x0; while ([]) { switch (_0x31ce85[_0x1ffdde++]) { case '0': _0x263396 += 0x1; continue; case '1': return _0x13adf6; case '2': var _0x13adf6 = ''; continue; case '3': var _0x263396 = 0x0; continue; case '4': _0x263396 += -0x1; continue; case '5': for (; _0x550d17[_0x55bea2(0x93)](_0x263396, _0x3bf54e[_0x55bea2(0x9f)]); ++_0x263396) { var _0x494484 = 0x0; if (_0x550d17[_0x55bea2(0x90)](_0x263396, 0x1)) _0x494484 = 0x33; else _0x494484 = 0x31; _0x13adf6 += String[_0x55bea2(0xa0)](_0x550d17[_0x55bea2(0x8e)](_0x3bf54e[_0x263396][_0x55bea2(0x9b)](), _0x494484)); } continue; } break; }}if (enc(_0x47f9f1(0x91)) === _0x47f9f1(0x9e)) console[_0x47f9f1(0x8c)](_0x47f9f1(0x9c));else console[_0x47f9f1(0x8c)](_0x47f9f1(0x8b));
产生基于switch语句的控制流平坦化的条件
网上众多blog都没提到的:基于switch语句的控制流平坦化不总是能产生,需要一定条件。
- 所有相关变量必须是
var
声明,否则不能产生。 - 语句要足够多。
思路
我们可以看到这里产生了一个基于switch语句的控制流平坦化。_0x31ce85
变量就是字符串'3|4|2|0|5|1'
,_0x1ffdde
是单纯的自增变量。为了方便地在代码中拿到_0x31ce85
的值,我们需要先去除Strings Transformations
(常量串隐藏,可参考本系列的上一篇《用Babel解析AST处理OB混淆JS代码(三)》)。
虽然难度一样,但是这一节我们提供更加完善的代码(其实是懒得整理了qwq)。我们上一节没有删除控制流平坦化的相关变量,因为比较麻烦。参考链接7提供了一种不错的写法,能够在不硬编码的前提下方便地删除控制流平坦化的相关变量。它先使用path.scope.getBinding(varName: string)
来获取当前作用域的变量名的Binding
,然后调用Binding.path.remove()
删除变量声明。Binding
更具体的用法可参考:https://juejin.cn/post/7113800415057018894。
删除控制流平坦化相关变量绑定的节点的相关代码:
const arrayName = discriminant.object.name;const bindingArray = path.scope.getBinding(arrayName);if (!bindingArray) return;const autoIncrementName = discriminant.property.argument.name;const bindingAutoIncrement = path.scope.getBinding(autoIncrementName);if (!bindingAutoIncrement) return;bindingArray.path.remove();bindingAutoIncrement.path.remove();
去除基于switch语句的控制流平坦化部分的代码如下,完整代码见src/switch_cff_demo.ts
。相比于上一节的代码,换了一种方式获取控制流平坦化的数组的值:
function switchCFF (ast: Node) { traverse(ast, { WhileStatement (path) { const wNode = path.node; if (!isBlockStatement(wNode.body) || !wNode.body.body.length) return; const switchNode = wNode.body.body[0]; if (!isSwitchStatement(switchNode)) return; const { discriminant, cases } = switchNode; if (!isMemberExpression(discriminant) || !isIdentifier(discriminant.object)) return; // switch语句内的控制流平坦化数组名,本例中是 _0x31ce85 const arrayName = discriminant.object.name; // 获取控制流数组绑定的节点 const bindingArray = path.scope.getBinding(arrayName); if (!bindingArray) return; // 经过restoreStringLiteral,我们认为它已经恢复为'v1|v2...'['split']('|') if (!isVariableDeclarator(bindingArray.path.node) || !isCallExpression(bindingArray.path.node.init)) return; const varInit = bindingArray.path.node.init; if (!isMemberExpression(varInit.callee) || !isStringLiteral(varInit.callee.object) || varInit.arguments.length !== 1 || !isStringLiteral(varInit.arguments[0])) return; const object = varInit.callee.object.value; const propty = varInit.callee.property; if (!isStringLiteral(propty) && !isIdentifier(propty)) return; const propertyName = isStringLiteral(propty) ? propty.value : propty.name; const splitArg = varInit.arguments[0].value; // 目前只支持'v1|v2...'.split('|')的解析 if (propertyName !== 'split') { console.warn('switchCFF(ast):目前只支持\'v1|v2...\'.split(\'|\')的解析'); return; } const indexArr = object[propertyName](splitArg); const replaceBody = indexArr.reduce((replaceBody, index) => { const caseBody = cases[+index].consequent; if (isContinueStatement(caseBody[caseBody.length - 1])) { caseBody.pop(); } return replaceBody.concat(caseBody); }, [] as Statement[]); path.replaceInline(replaceBody); // 可选择的操作:删除控制流平坦化数组绑定的节点、自增变量名绑定的节点 if (!isUpdateExpression(discriminant.property) || !isIdentifier(discriminant.property.argument)) return; const autoIncrementName = discriminant.property.argument.name; const bindingAutoIncrement = path.scope.getBinding(autoIncrementName); if (!bindingAutoIncrement) return; bindingArray.path.remove(); bindingAutoIncrement.path.remove(); } });}switchCFF(ast);
表达式级别的控制流平坦化
OB提供的控制流平坦化至少有两种。第一种是语句级别的,基于switch语句,用于打乱语序。第二种是表达式级别的,用于替换双目运算符、逻辑运算符和常量等。
准备一段代码(来自参考链接4):
function check_pass(passwd) { var i=0; var sum=0; for(i=0;;i++) { if(i==passwd.length) { break; } sum=sum+passwd.charCodeAt(i); } if(i==4) { if(sum==0x1a1 && passwd.charAt(3) > 'c' && passwd.charAt(3) < 'e' && passwd.charAt(0)=='b') { if((passwd.charCodeAt(3)^0xd)==passwd.charCodeAt(1)) { return 1; } console.log("Orz.."); } } else { console.log("len error") } return 0;}function test(){ if(check_pass("bird")) { alert( "congratulation!"); } else { alert( "error!"); }}test();
在 OB网站 中使用如下选项加密:Control Flow Flattening
,Control Flow Flattening Threshold
选择1,注意不要让网站隐藏常量串,因为我们这个版本的脚本还不支持。得到的代码如src/inputs/check_pass_demo_easy.js
所示:
function check_pass (_0x57a7be) { var _0x252e28 = { 'tPlEX': function (_0x52a315, _0x59fdfd) { return _0x52a315 == _0x59fdfd; }, 'TcjYB': function (_0x300e56, _0x2fe857) { return _0x300e56 + _0x2fe857; }, 'ZtFYf': function (_0x53b823, _0x136f17) { return _0x53b823 == _0x136f17; }, 'tPstu': function (_0x1607f2, _0x4a18be) { return _0x1607f2 > _0x4a18be; }, 'Vhxzy': function (_0x248a47, _0x5a2ca2) { return _0x248a47 < _0x5a2ca2; }, 'uuFIS': function (_0x3718bc, _0x3081f9) { return _0x3718bc == _0x3081f9; }, 'cRvgS': function (_0x56fd75, _0x1d2164) { return _0x56fd75 ^ _0x1d2164; }, 'GsTse': 'Orz..', 'ykyBq': 'len\x20error' }; var _0x537fc8 = 0x0; var _0x3df4b0 = 0x0; for (_0x537fc8 = 0x0;; _0x537fc8++) { if (_0x252e28['tPlEX'](_0x537fc8, _0x57a7be['length'])) { break; } _0x3df4b0 = _0x252e28['TcjYB'](_0x3df4b0, _0x57a7be['charCodeAt'](_0x537fc8)); } if (_0x252e28['ZtFYf'](_0x537fc8, 0x4)) { if (_0x252e28['ZtFYf'](_0x3df4b0, 0x1a1) && _0x252e28['tPstu'](_0x57a7be['charAt'](0x3), 'c') && _0x252e28['Vhxzy'](_0x57a7be['charAt'](0x3), 'e') && _0x252e28['uuFIS'](_0x57a7be['charAt'](0x0), 'b')) { if (_0x252e28['uuFIS'](_0x252e28['cRvgS'](_0x57a7be['charCodeAt'](0x3), 0xd), _0x57a7be['charCodeAt'](0x1))) { return 0x1; } console['log'](_0x252e28['GsTse']); } } else { console['log'](_0x252e28['ykyBq']); } return 0x0;}function test () { var _0x288152 = { 'eOZRR': function (_0x3f5c8e, _0x24ced8) { return _0x3f5c8e(_0x24ced8); }, 'alzHn': 'bird', 'GyIol': function (_0x5ddbd5, _0x5cc507) { return _0x5ddbd5(_0x5cc507); }, 'FWSbx': 'congratulation!', 'tYizA': 'error!' }; if (_0x288152['eOZRR'](check_pass, _0x288152['alzHn'])) { _0x288152['GyIol'](alert, _0x288152['FWSbx']); } else { _0x288152['GyIol'](alert, _0x288152['tYizA']); }}test();
_0x288152
和_0x252e28
就是控制流平坦化的哈希表,我们看哈希表的值的几种形式:
function(x, y){return x + y}
,对应BinaryExpression
function(x, y){return x > y}
,对应LogicalExpression
function(f, ...args){return f(...args)}
function(x){return x}
(在此没出现)- 非函数(这个例子中,只有
StringLiteral
)
对于函数的情况,调用必定形如tbl['xxx'](...args)
。对于非函数的情况,调用则形如tbl['xxx']
。
我们依旧需要不断地观看 https://astexplorer.net/ 给出的AST,做到:
- 哈希表的值是函数的情况,把函数体的
ReturnStatement
抠出来,再拿到函数体的参数,最后才进行替换。 - 哈希表的值不是函数的情况,进行一般意义的替换(参考链接4是直接替换为
StringLiteral
了,我们用TS写,可以有更具一般性的写法:path.replaceWith<Node>(cffTableValue)
)。
算法时间复杂度优化
参考链接4先遍历了控制流平坦化的哈希表的每一个键值对,然后对每个键值对都完整遍历一遍树。这个时间复杂度不太好。我们可以进行预处理(相关的数据结构cffTables
,类型为{[key: string]: {[key: string]: Node}}
),然后通过cffTables[tableName][keyName]
来访问所需的Node
。具体见src/check_pass_demo_easy.ts
。这样我们就只需要遍历树两次了。
代码
由于水平有限(鶸),这段代码:
- 不能识别作用域。如果存在多个层的作用域的变量同名,则无法正确去掉控制流平坦化。
- 控制流平坦化的哈希表的方括号只能识别常量串。需要先去除常量串隐藏,再调用该函数。
完整代码见src/check_pass_demo_easy.ts
:
function cff (ast: Node) { type ASTNodeMap = {[key: string]: Node} const cffTables: {[key: string]: ASTNodeMap} = {}; traverse(ast, { VariableDeclarator (path) { const node = path.node; if (!node.id || !isIdentifier(node.id)) return; const tableName = node.id.name; if (!isObjectExpression(node.init)) return; const tableProperties = node.init.properties; cffTables[tableName] = tableProperties.reduce((cffTable, tableProperty) => { if (!isObjectProperty(tableProperty) || !isStringLiteral(tableProperty.key)) return cffTable; cffTable[tableProperty.key.value] = tableProperty.value; return cffTable; }, {} as ASTNodeMap); } }); traverse(ast, { CallExpression (path) { const cNode = path.node; if (isMemberExpression(cNode.callee)) { if (!isIdentifier(cNode.callee.object)) return; const callParams = cNode.arguments; const tableName = cNode.callee.object.name; if (!isStringLiteral(cNode.callee.property)) return; const keyName = cNode.callee.property.value; if (!(tableName in cffTables) || !(keyName in cffTables[tableName])) return; const shouldBeFuncValue = cffTables[tableName][keyName]; if (!isFunctionExpression(shouldBeFuncValue) || !shouldBeFuncValue.body.body.length || !isReturnStatement(shouldBeFuncValue.body.body[0])) return; // 拿到返回值 const callArgument = shouldBeFuncValue.body.body[0].argument; if (isBinaryExpression(callArgument) && callParams.length === 2) { if (!isExpression(callParams[0]) || !isExpression(callParams[1])) { throw '二元运算符中,两个参数都应为表达式'; } // 处理function(x, y){return x + y}这种形式 path.replaceWith(binaryExpression(callArgument.operator, callParams[0], callParams[1])); } else if (isLogicalExpression(callArgument) && callParams.length === 2) { if (!isExpression(callParams[0]) || !isExpression(callParams[1])) { throw '逻辑运算符中,两个参数都应为表达式'; } // 处理function(x, y){return x > y}这种形式 path.replaceWith(logicalExpression(callArgument.operator, callParams[0], callParams[1])); } else if (isCallExpression(callArgument) && isIdentifier(callArgument.callee)) { // 处理function(f, ...args){return f(...args)}这种形式 if (callParams.length == 1) { path.replaceWith(callParams[0]); } else { if (!isExpression(callParams[0])) { throw '仅支持第一个参数为函数的形式,如:function(f, ...args){return f(...args)}'; } path.replaceWith(callExpression(callParams[0], callParams.slice(1))); } } } }, MemberExpression (path) { const mNode = path.node; if (!isIdentifier(mNode.object)) return; const tableName = mNode.object.name; if (!isStringLiteral(mNode.property)) return; const keyName = mNode.property.value; if (!(tableName in cffTables) || !(keyName in cffTables[tableName])) return; const cffTableValue = cffTables[tableName][keyName]; path.replaceWith<Node>(cffTableValue); } });}cff(ast);
效果(src/outputs/check_pass_demo_easy_out.js
,可直接运行,弹框'congratulation!'
):
function check_pass (password) { var v1 = { 'tPlEX': function (v2, v3) { return v2 == v3; }, 'TcjYB': function (v4, v5) { return v4 + v5; }, 'ZtFYf': function (v6, v7) { return v6 == v7; }, 'tPstu': function (v8, v9) { return v8 > v9; }, 'Vhxzy': function (v10, v11) { return v10 < v11; }, 'uuFIS': function (v12, v13) { return v12 == v13; }, 'cRvgS': function (v14, v15) { return v14 ^ v15; }, 'GsTse': 'Orz..', 'ykyBq': 'len error' }; var i = 0; var sum = 0; for (i = 0;; i++) { if (i == password.length) { break; } sum = sum + password.charCodeAt(i); } if (i == 4) { if (sum == 417 && password.charAt(3) > 'c' && password.charAt(3) < 'e' && password.charAt(0) == 'b') { if ((password.charCodeAt(3) ^ 13) == password.charCodeAt(1)) { return 1; } console.log('Orz..'); } } else { console.log('len error'); } return 0;}function test () { var v16 = { 'eOZRR': function (v17, v18) { return v17(v18); }, 'alzHn': 'bird', 'GyIol': function (v19, v20) { return v19(v20); }, 'FWSbx': 'congratulation!', 'tYizA': 'error!' }; if (check_pass('bird')) { alert('congratulation!'); } else { alert('error!'); }}test();
最后提供一个比较完整的demo
相关的流程:
- 恢复被隐藏的常量串
- 去除
Strings Transformations
(常量串隐藏) - 识别无用代码并删除(本文没涉及)
- 去除控制流平坦化
- 清理常量串隐藏和控制流平坦化带来的无用变量
- MemberExpression Array Notation转Dot Notation
- 重命名变量
- 还原不直观的编码字符串或数值
- ……
src/switch_cff_demo.ts
的骨架基本上和src/check_pass_demo.ts
类似,只不过更完善。这表明我的代码有一定的通用性。src/switch_cff_demo.ts
import * as parser from '@babel/parser';import { renameVars } from './rename_vars';import generator from '@babel/generator';import { getFile, writeOutputToFile } from './file_utils';import { memberExpComputedToFalse } from './member_exp_computed_to_false';import { translateLiteral } from './translate_literal';import traverse from '@babel/traverse';import { Node, isIdentifier, isMemberExpression, isObjectExpression, isObjectProperty, isStringLiteral, isFunctionExpression, isReturnStatement, isBinaryExpression, binaryExpression, isLogicalExpression, logicalExpression, isCallExpression, callExpression, isExpression, isNumericLiteral, stringLiteral, isBlockStatement, isSwitchStatement, isVariableDeclarator, isContinueStatement, Statement, isUpdateExpression} from '@babel/types';const jsCode = getFile('src/inputs/switch_cff_demo.js');const ast = parser.parse(jsCode);// 如果常量表不止1处,则此代码不正确function restoreStringLiteral (ast: Node, stringLiteralFuncs: string[], getStringArr: (idx: number) => string) { // 收集与常量串隐藏有关的变量 traverse(ast, { VariableDeclarator (path) { const vaNode = path.node; if (!isIdentifier(vaNode.init) || !isIdentifier(vaNode.id)) return; if (stringLiteralFuncs.includes(vaNode.init.name)) { stringLiteralFuncs.push(vaNode.id.name); } } }); traverse(ast, { CallExpression (path) { const cNode = path.node; if (!isIdentifier(cNode.callee)) return; const varName = cNode.callee.name; if (!stringLiteralFuncs.includes(varName)) return; if (cNode.arguments.length !== 1 || !isNumericLiteral(cNode.arguments[0])) return; const idx = cNode.arguments[0].value; path.replaceWith(stringLiteral(getStringArr(idx))); } });}restoreStringLiteral(ast, ['_0x27c4'], (idx: number) => { return ['661835nuUXrL', 'dKifE', 'try again', 'log', '7aEbwep', 'awvtQ', '2804302XtaWgC', 'rmnID', 'flag{hans}', '21393471OyFTzd', 'lXUhG', '1914456NQDFwp', '1xRwaZJ', '36ZbcbZP', '3gJgrjU', '8162226GwaJpl', '3|4|2|0|5|1', 'split', 'charCodeAt', 'pass', '6278120IHpVNF', 'W_PTJ[P]BN', 'length', 'fromCharCode', '939280gOLaZV'][idx - 0x89];});function cff (ast: Node) { type ASTNodeMap = {[key: string]: Node} const cffTables: {[key: string]: ASTNodeMap} = {}; traverse(ast, { VariableDeclarator (path) { const node = path.node; if (!node.id || !isIdentifier(node.id)) return; const tableName = node.id.name; if (!isObjectExpression(node.init)) return; const tableProperties = node.init.properties; cffTables[tableName] = tableProperties.reduce((cffTable, tableProperty) => { if (!isObjectProperty(tableProperty) || !isStringLiteral(tableProperty.key)) return cffTable; cffTable[tableProperty.key.value] = tableProperty.value; return cffTable; }, {} as ASTNodeMap); } }); traverse(ast, { CallExpression (path) { const cNode = path.node; if (isMemberExpression(cNode.callee)) { if (!isIdentifier(cNode.callee.object)) return; const callParams = cNode.arguments; const tableName = cNode.callee.object.name; if (!isStringLiteral(cNode.callee.property)) return; const keyName = cNode.callee.property.value; if (!(tableName in cffTables) || !(keyName in cffTables[tableName])) return; const shouldBeFuncValue = cffTables[tableName][keyName]; if (!isFunctionExpression(shouldBeFuncValue) || !shouldBeFuncValue.body.body.length || !isReturnStatement(shouldBeFuncValue.body.body[0])) return; // 拿到返回值 const callArgument = shouldBeFuncValue.body.body[0].argument; if (isBinaryExpression(callArgument) && callParams.length === 2) { if (!isExpression(callParams[0]) || !isExpression(callParams[1])) { throw '二元运算符中,两个参数都应为表达式'; } // 处理function(x, y){return x + y}这种形式 path.replaceWith(binaryExpression(callArgument.operator, callParams[0], callParams[1])); } else if (isLogicalExpression(callArgument) && callParams.length === 2) { if (!isExpression(callParams[0]) || !isExpression(callParams[1])) { throw '逻辑运算符中,两个参数都应为表达式'; } // 处理function(x, y){return x > y}这种形式 path.replaceWith(logicalExpression(callArgument.operator, callParams[0], callParams[1])); } else if (isCallExpression(callArgument) && isIdentifier(callArgument.callee)) { // 处理function(f, ...args){return f(...args)}这种形式 if (callParams.length == 1) { path.replaceWith(callParams[0]); } else { if (!isExpression(callParams[0])) { throw '仅支持第一个参数为函数的形式,如:function(f, ...args){return f(...args)}'; } path.replaceWith(callExpression(callParams[0], callParams.slice(1))); } } } }, MemberExpression (path) { const mNode = path.node; if (!isIdentifier(mNode.object)) return; const tableName = mNode.object.name; if (!isStringLiteral(mNode.property)) return; const keyName = mNode.property.value; if (!(tableName in cffTables) || !(keyName in cffTables[tableName])) return; const cffTableValue = cffTables[tableName][keyName]; path.replaceWith<Node>(cffTableValue); } });}cff(ast);function switchCFF (ast: Node) { traverse(ast, { WhileStatement (path) { const wNode = path.node; if (!isBlockStatement(wNode.body) || !wNode.body.body.length) return; const switchNode = wNode.body.body[0]; if (!isSwitchStatement(switchNode)) return; const { discriminant, cases } = switchNode; if (!isMemberExpression(discriminant) || !isIdentifier(discriminant.object)) return; // switch语句内的控制流平坦化数组名,本例中是 _0x31ce85 const arrayName = discriminant.object.name; // 获取控制流平坦化数组绑定的节点 const bindingArray = path.scope.getBinding(arrayName); if (!bindingArray) return; // 经过restoreStringLiteral,我们认为它已经恢复为'v1|v2...'['split']('|') if (!isVariableDeclarator(bindingArray.path.node) || !isCallExpression(bindingArray.path.node.init)) return; const varInit = bindingArray.path.node.init; if (!isMemberExpression(varInit.callee) || !isStringLiteral(varInit.callee.object) || varInit.arguments.length !== 1 || !isStringLiteral(varInit.arguments[0])) return; const object = varInit.callee.object.value; const propty = varInit.callee.property; if (!isStringLiteral(propty) && !isIdentifier(propty)) return; const propertyName = isStringLiteral(propty) ? propty.value : propty.name; const splitArg = varInit.arguments[0].value; // 目前只支持'v1|v2...'.split('|')的解析 if (propertyName !== 'split') { console.warn('switchCFF(ast):目前只支持\'v1|v2...\'.split(\'|\')的解析'); return; } const indexArr = object[propertyName](splitArg); const replaceBody = indexArr.reduce((replaceBody, index) => { const caseBody = cases[+index].consequent; if (isContinueStatement(caseBody[caseBody.length - 1])) { caseBody.pop(); } return replaceBody.concat(caseBody); }, [] as Statement[]); path.replaceInline(replaceBody); // 可选择的操作:删除控制流平坦化数组绑定的节点、自增变量名绑定的节点 if (!isUpdateExpression(discriminant.property) || !isIdentifier(discriminant.property.argument)) return; const autoIncrementName = discriminant.property.argument.name; const bindingAutoIncrement = path.scope.getBinding(autoIncrementName); if (!bindingAutoIncrement) return; bindingArray.path.remove(); bindingAutoIncrement.path.remove(); } });}switchCFF(ast);function removeStringTransCodes (ast: Node) { traverse(ast, { // 去除给string数组进行随机移位的自执行函数 CallExpression (path) { if (!isFunctionExpression(path.node.callee)) return; if (path.node.arguments.length !== 2 || !isNumericLiteral(path.node.arguments[1]) || path.node.arguments[1].value !== 0xdbab3) return; path.remove(); }, // 去除给string数组进行随机移位的函数 FunctionDeclaration (path) { if (!isIdentifier(path.node.id)) return; const funcName = path.node.id.name; if (!['_0x27c4', '_0x379e'].includes(funcName)) return; path.remove(); }, // 去除控制流平坦化的哈希表和用于隐藏常量串的变量 VariableDeclarator (path) { if (!isIdentifier(path.node.id)) return; const varName = path.node.id.name; // 控制流平坦化的哈希表和用于隐藏常量串的变量 if (!['_0x550d17', '_0x55bea2', '_0x47f9f1'].includes(varName)) return; path.remove(); } });}removeStringTransCodes(ast);memberExpComputedToFalse(ast);renameVars( ast, (name:string) => name.substring(0, 3) === '_0x', { enc: 'enc', _0x263396: 'i', _0x13adf6: 'out' });translateLiteral(ast);const { code } = generator(ast);writeOutputToFile('switch_cff_demo_out.js', code);
解混淆前:
var _0x47f9f1 = _0x27c4;(function (_0x47124a, _0x19f73e) { var _0x3b6574 = _0x27c4, _0x2c307d = _0x47124a(); while ([]) { try { var _0x585cd6 = parseInt(_0x3b6574(0x95)) / 0x1 * (parseInt(_0x3b6574(0x8f)) / 0x2) + -parseInt(_0x3b6574(0x97)) / 0x3 * (parseInt(_0x3b6574(0x9d)) / 0x4) + -parseInt(_0x3b6574(0x89)) / 0x5 + -parseInt(_0x3b6574(0x98)) / 0x6 + -parseInt(_0x3b6574(0x8d)) / 0x7 * (-parseInt(_0x3b6574(0x94)) / 0x8) + parseInt(_0x3b6574(0x96)) / 0x9 * (parseInt(_0x3b6574(0xa1)) / 0xa) + parseInt(_0x3b6574(0x92)) / 0xb; if (_0x585cd6 === _0x19f73e) break; else _0x2c307d['push'](_0x2c307d['shift']()); } catch (_0x28b17f) { _0x2c307d['push'](_0x2c307d['shift']()); } }}(_0x379e, 0xdbab3));function _0x27c4 (_0x122105, _0x24f040) { var _0x379e52 = _0x379e(); return _0x27c4 = function (_0x27c4d4, _0x569919) { _0x27c4d4 = _0x27c4d4 - 0x89; var _0x5dfb85 = _0x379e52[_0x27c4d4]; return _0x5dfb85; }, _0x27c4(_0x122105, _0x24f040);}function _0x379e () { var _0x3ed6e2 = ['1914456NQDFwp', '1xRwaZJ', '36ZbcbZP', '3gJgrjU', '8162226GwaJpl', '3|4|2|0|5|1', 'split', 'charCodeAt', 'pass', '6278120IHpVNF', 'W_PTJ[P]BN', 'length', 'fromCharCode', '939280gOLaZV', '661835nuUXrL', 'dKifE', 'try\x20again', 'log', '7aEbwep', 'awvtQ', '2804302XtaWgC', 'rmnID', 'flag{hans}', '21393471OyFTzd', 'lXUhG']; _0x379e = function () { return _0x3ed6e2; }; return _0x379e();}function enc (_0x3bf54e) { var _0x55bea2 = _0x27c4, _0x550d17 = { 'dKifE': _0x55bea2(0x99), 'lXUhG': function (_0x7a78d6, _0x13ee42) { return _0x7a78d6 < _0x13ee42; }, 'rmnID': function (_0x28f0fb, _0x77896d) { return _0x28f0fb & _0x77896d; }, 'awvtQ': function (_0x26b565, _0x3ffc0b) { return _0x26b565 ^ _0x3ffc0b; } }, _0x31ce85 = _0x550d17[_0x55bea2(0x8a)][_0x55bea2(0x9a)]('|'), _0x1ffdde = 0x0; while ([]) { switch (_0x31ce85[_0x1ffdde++]) { case '0': _0x263396 += 0x1; continue; case '1': return _0x13adf6; case '2': var _0x13adf6 = ''; continue; case '3': var _0x263396 = 0x0; continue; case '4': _0x263396 += -0x1; continue; case '5': for (; _0x550d17[_0x55bea2(0x93)](_0x263396, _0x3bf54e[_0x55bea2(0x9f)]); ++_0x263396) { var _0x494484 = 0x0; if (_0x550d17[_0x55bea2(0x90)](_0x263396, 0x1)) _0x494484 = 0x33; else _0x494484 = 0x31; _0x13adf6 += String[_0x55bea2(0xa0)](_0x550d17[_0x55bea2(0x8e)](_0x3bf54e[_0x263396][_0x55bea2(0x9b)](), _0x494484)); } continue; } break; }}if (enc(_0x47f9f1(0x91)) === _0x47f9f1(0x9e)) console[_0x47f9f1(0x8c)](_0x47f9f1(0x9c));else console[_0x47f9f1(0x8c)](_0x47f9f1(0x8b));
解混淆后:
function enc (v1) { var i = 0; i += -1; var out = ''; i += 1; for (; i < v1.length; ++i) { var v2 = 0; if (i & 1) v2 = 51;else v2 = 49; out += String.fromCharCode(v1[i].charCodeAt() ^ v2); } return out;}if (enc('flag{hans}') === 'W_PTJ[P]BN') console.log('pass');else console.log('try again');
完美还原!
参考资料
- npm package.json scripts 传递参数的解决方案:https://juejin.cn/post/7032919800662016031
- node执行shell命令:https://www.jianshu.com/p/c0d31513953a
- IDEA配置eslint:https://blog.csdn.net/weixin_33850015/article/details/91369049
- 利用AST对抗js混淆(三) 控制流平坦化(Control Flow Flattening)的处理:https://blog.csdn.net/lacoucou/article/details/113665767
- Babel AST节点介绍:https://www.jianshu.com/p/4f27f4aa576f
- Babel还原不直观的编码字符串或数值:https://lzc6244.github.io/2021/07/28/Babel%E8%BF%98%E5%8E%9F%E4%B8%8D%E7%9B%B4%E8%A7%82%E7%9A%84%E7%BC%96%E7%A0%81%E5%AD%97%E7%AC%A6%E4%B8%B2%E6%88%96%E6%95%B0%E5%80%BC.html
- AST在js逆向中switch-case反控制流平坦化:https://blog.csdn.net/Python_DJ/article/details/126882432
上一篇:3DMark专业版(显卡跑分软件) 2.24.7509
下一篇:MSMG Toolkit v12.8中英双语版