分享3个Jeb脚本(GotoClass、FastXposed、FastFrida)
2020-05-14 11:39:20 Author: bbs.pediy.com(查看原文) 阅读量:489 收藏
2020-05-14 11:39:20 Author: bbs.pediy.com(查看原文) 阅读量:489 收藏
【摘要】
战争的残酷属性不会因为我们的不足而有丝毫改变,仅以此文祭奠我们在第二届网鼎杯丢失的455高地。
【关键词】
汽车通讯协议、汽车ECU、ARM
一、455高地
Misc类目Teslaaaaa,3人攻破,分值455,全场失守阵地中分值最高的领地;若能拿下,仅凭一题就能在初赛中位列青龙组前50,更不用说160名的半决赛投名状了。
如图,我们觉得它可以归类为攻击汽车系统演化而来的逆向题。
上图中,提示使用的是CAN协议,协议参考标准为【ISO 15765-2】和【ISO 14229-1】
【点击打开图片】,应该注意到这是汽车ECU单元,芯片为嵌入式ARM;
如图,题目附件teslaaaaa.zip(参考附件)解压出来就一个CAN通讯记录文件
文件内容胜利如下,是CAN bus汽车通讯协议的标准通讯帧
date Thu Apr 2 10:37:15.950 am 2020 base hex timestamps absolute internal events logged // version 8.2.1 0.005921 CAN 1 Status:chip status error active 1.005921 CAN 1 Status:chip status error active 2.005922 CAN 1 Status:chip status error active 3.005922 CAN 1 Status:chip status error active 4.000621 1 7DF Tx d 8 02 3E 80 00 00 00 00 00 Length = 0 BitCount = 124 ID = 2015 // 1 OTP(01) Atom 7DF->7DF : SF Length: 02 [ 3E 80 ] 4.005922 CAN 1 Status:chip status error active 5.005922 CAN 1 Status:chip status error active 6.005923 CAN 1 Status:chip status error active 7.005923 CAN 1 Status:chip status error active 8.000537 1 7DF Tx d 8 02 3E 80 00 00 00 00 00 Length = 0 BitCount = 124 ID = 2015 // 1 OTP(02) Atom 7DF->7DF : SF Length: 02 [ 3E 80 ] 8.005923 CAN 1 Status:chip status error active 9.005924 CAN 1 Status:chip status error active 9.498709 1 7DF Tx d 8 02 10 02 AA AA AA AA AA Length = 0 BitCount = 116 ID = 2015 // 1 OTP(03) Atom 7DF->7DF : SF Length: 02 [ 10 02 ] 9.499693 1 7B0 Rx d 8 06 50 02 00 32 01 F4 00 Length = 235910 BitCount = 122 ID = 1968 ...略... 10.314499 1 730 Tx d 8 02 37 01 AA AA AA AA AA Length = 222259 BitCount = 114 ID = 1840 10.315695 1 7B0 Rx d 8 06 77 01 C6 B6 5E 10 00 Length = 225910 BitCount = 117 ID = 1968 10.318529 1 730 Tx d 8 04 31 01 DF FF AA AA AA Length = 226244 BitCount = 116 ID = 1840 10.319707 1 7B0 Rx d 8 03 7F 31 78 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 10.320695 1 7B0 Rx d 8 05 71 01 DF FF 00 00 00 Length = 233910 BitCount = 121 ID = 1968 10.322633 1 730 Tx d 8 04 31 01 FF 01 AA AA AA Length = 226244 BitCount = 116 ID = 1840 10.323695 1 7B0 Rx d 8 05 71 01 FF 01 00 00 00 Length = 233910 BitCount = 121 ID = 1968 10.325697 1 7DF Tx d 8 02 11 01 AA AA AA AA AA Length = 0 BitCount = 115 ID = 2015 // 1 OTP(04) Atom 7DF->7DF : SF Length: 02 [ 11 01 ] 10.326689 1 7B0 Rx d 8 03 7F 11 78 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 11.005924 CAN 1 Status:chip status error active 11.326752 1 7B0 Rx d 8 02 51 01 00 00 00 00 00 Length = 235910 BitCount = 122 ID = 1968 12.000742 1 7DF Tx d 8 02 3E 80 00 00 00 00 00 Length = 0 BitCount = 124 ID = 2015 // 1 OTP(05) Atom 7DF->7DF : SF Length: 02 [ 3E 80 ] 12.005925 CAN 1 Status:chip status error active 13.005925 CAN 1 Status:chip status error active 14.005925 CAN 1 Status:chip status error active 15.005926 CAN 1 Status:chip status error active 16.000532 1 7DF Tx d 8 02 3E 80 00 00 00 00 00 Length = 0 BitCount = 124 ID = 2015 // 1 OTP(06) Atom 7DF->7DF : SF Length: 02 [ 3E 80 ] 16.005926 CAN 1 Status:chip status error active
二、CAN协议的标准帧
在CAN协议的网络层,结点之间通讯的基本网络协议数据单元构为 N_PDU(Protoco Data Unit),
N_PDU由三部分构成,如图
N_PDU : N_AI,N_PCI,N_Data //The protocol data unit (N_PDU) N_AI : N_SA,N_TA,N_TAtype[,N_AE] //Address information (N_AI) N_PCI : //Protocol control information (N_PCI) N_Data : //Data Field (N_Data)
1、N_PDU结构,截图源自【ISO-15765-2-2004】
2、N_PCI结构,截图源自【ISO-15765-2-2004】
3、CAN的标准帧结构
(3.1)11字节的标准通讯帧
(A)CAN的标准帧固定为11个字节,我们依次定义为 Byte1,...,Byte11 (B)每个字节8位从高到低,依次定义位 ByteN.bit7,...,ByteN.bit0;其中N为1到11 (C)则CAN标准帧的基本格式为 Byte1.bit7,Byte1,bit6,x,x,Byte1.bit3~0 Byte2.bit7~0 //as CanID.10~3 Byte3.bit7~6,x,x,x,x,x // as CanID.2~0 Byte4~Byte11 // as N_PCI,N_Data 其中 Byte1.bit7=0 指示通讯帧为CAN标准帧 Byte1,bit6=0 指示通讯帧为数据帧,此时 N_PCI 部分才有效 Byte1.bit3~0 指示 N_PCI 和 N_Data 的长度 Byte2.bit7~0和Byte3.bit7~6 构成11位的报文ID N_PCI 的格式参考上面截图 N_Data 的的定义参考【ISO-14229-1】
(3.2)实例
如下 9.498709 1 7DF Tx d 8 02 10 02 AA AA AA AA AA Length = 0 BitCount = 116 ID = 2015 9.499693 1 7B0 Rx d 8 06 50 02 00 32 01 F4 00 Length = 235910 BitCount = 122 ID = 1968
说明: (A)其中的 ID = 2015 即 7DF就是11位的报文ID,所以有 Byte2=0x7DF>>3 = 0xFB Byte3=(0x7DF&7)<<5 = 0xE0 (B)即上述【7DF Tx d 8 02 10 02 AA AA AA AA AA】在CAN通讯线路上监控得到的CAN标准帧是 【08 FB E0 02 10 02 AA AA AA AA AA】 其中08指示 Byte1.bit7=0,Byte1,bit6=0,Byte1.bit3~0=8即N_PCI 和 N_Data的总长度, CAN标准数据帧的N_PCI 和 N_Data长度固定为8字节,有效字节由帧内指定,冗余字节收发双方自动截断丢弃。
(3.3)N_PCI 和 N_Data
如前面的N_PCI结构图
(A)N_PCI高四位 N_PCIType 指示了N_PCI的类型 0x0*为单帧SF 0x1*为多帧中的首 0x2*为多帧中的后续帧 0x3*为流控制 (B)如以下通讯对话 7DF Tx d 8 02 10 02 AA AA AA AA AA 7B0 Rx d 8 06 50 02 00 32 01 F4 00 表示给汽车ECU单元发送Tx单帧0x02&0xF0=0=SF,单帧中的有效内容为0x02&0x0F=2字节 10 02;后面的AA AA AA AA AA为多余被丢弃的数据 而接收Tx到来自汽车ECU单元反馈的单帧0x06&0xF0=0=SF,单帧中有效内容为0x06&0x0F=6字节 50 02 00 32 01 F4;后面的00为多余被丢弃的数据
三、Tester 与 汽车ECU的会话内容
每个单帧或多帧通讯的有效内容,就是通讯双方的真实对话,下面我们结合【ISO-14229-1-2013】解读日志记录了双方进行了什么类型的通讯对话。
1、通讯内容
(1)【7DF Tx d 8 02 3E 80 00 00 00 00 00】
说明:实现链路保持,即告诉作为服务端的汽车ECU,作为客户端的Tester还在线;若长时间没有告知,服务端就会关闭会话。
TesterPresent (0x3E) service 实际题目中的汽车ECU并不需要进行链路保持,这算是测试者Tester作为客户端有备无患的策略,甭管服务端是否需要链路保持,总不定时发送链路保持。 如果服务端有需要链路保持,其Tester端会收到服务端的链路保持正响应。如 【02 7E 80】
(2)【10 02】开启编程会话
这里通知ECU开启编程会话,得到了服务器的正响应【50 02】并返回了部分编程会话参数, 正响应都是请求的服务ID(这里SID=0x10)与0x40或运算为0x50;会话出错或拒绝的否定响应都是7F SID +错误代码等内容; 9.498709 1 7DF Tx d 8 02 10 02 AA AA AA AA AA Length = 0 BitCount = 116 ID = 2015 | |programmingSession enables all diagnostic services required to support the memory programming of a server. |DiagnosticSessionControl (10 hex) service:used to enable different diagnostic sessions in the server(s). 9.499693 1 7B0 Rx d 8 06 50 02 00 32 01 F4 00 Length = 235910 BitCount = 122 ID = 1968 | | | | | | | |P2*Server_max = 0x01F4*10ms = 5000ms | | |P2Server_max = 0x0032*1ms = 50ms | | | | | |sessionParameterRecord[] | |diagnosticSessionType |DiagnosticSessionControl Response Service Id
(3)【27 05】【07 06】安全校验
(3.1)因为是编程会话,可以刷写汽车上的ECU单元,安全等级较高,需要进行安全验证 安全验证的基本过程: (A) Tester 发送[27 05]请求安全验证,汽车ECU正响应返回 seed=0x11223344 (B) Tester 根据接收的seed=0x11223344,使用双方协定的安全算法函数algo_op,计算得到 key = algo_op(seed) (C) Tester 发送[27 06 key]给汽车ECU,若与汽车ECU使用algo_op计算的结果匹配,则通过验证,返回正响应【67 06】 (3.2)关于这个安全算法algo_op, (A)汽车厂商及其授权的合作商会知道; (B)第三者通过逆向汽车ECU可以知道,这种方法比较局限,只能都特定汽车ECU特定会话有效,且工作量较大; (C)第三者更多通过逆向汽车厂商的诊断设备来获取,这种方法简单,并可以获取汽车厂商所有支持的车系的所有ECU所有功能的校验算法; 9.740585 1 730 Tx d 8 02 27 05 AA AA AA AA AA Length = 222015 BitCount = 114 ID = 1840 9.741697 1 7B0 Rx d 8 06 67 05 11 22 33 44 00 Length = 223910 BitCount = 116 ID = 1968 如果这里Tester发送的key=EE DD CC BB AA不是使用与汽车ECU相同的algo_op计算的,汽车ECU将匹配失败,拒绝后续会话 9.782739 1 730 Tx d 8 06 27 06 EE DD CC BB AA Length = 226244 BitCount = 116 ID = 1840 9.783703 1 7B0 Rx d 8 02 67 06 00 00 00 00 00 Length = 235910 BitCount = 122 ID = 1968
(4)【31 01 FF 00 44 08 00 00 00 00 00 20 00】
Tester请求汽车ECU执行擦除eraseMemory过程,参数是,内存开始地址,和内存大小 其中44分别标记后面的地址和大小的字宽都是4字节,即要擦除 0x08000000 处 大小 0x00002000 的存储 9.788131 1 730 Tx d 8 10 0D 31 01 FF 00 44 08 Length = 232000 BitCount = 119 ID = 1840 9.788431 1 7B0 Rx d 8 30 08 00 00 00 00 00 00 Length = 239910 BitCount = 124 ID = 1968 9.788947 1 730 Tx d 8 21 00 00 00 00 00 20 00 Length = 244244 BitCount = 125 ID = 1840 9.789707 1 7B0 Rx d 8 05 71 01 FF 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 31 01 FF 00 44 08 00 00 00 00 00 20 00 | | | | | | | | | | | |routineControlOptionRecord[] // defined by the vehicle manufacturer. | | |routineIdentifier:=0xFF00 eraseMemory >> used to start the server's memory erase routine | |routineControlType RoutineControl Request SID := startRoutine |RoutineControl (0x31) service:used by the client to execute a defined sequence of steps and obtain any relevant results. 71 01 FF 00 00 |routineInfo //is vehicle manufacuter specific and provides a mechanism
(5)【34 00 44 08 00 00 00 00 00 20 00】
Tester请求下载数据RequestDownload,这个概念跟我们进行嵌入式开发时,最终需要把内容下载烧写到片上flash类似。 这里的44与上面的意思相同,指示后面参数字宽;下载数据到汽车ECU的0x08000000位置,数据大小为 0x00002000 这里的正响应告诉Tester,每次接收的数据大小最大可为 maxNumberOfBlockLength:=0x0102字节。 9.791765 1 730 Tx d 8 10 0B 34 00 44 08 00 00 Length = 236244 BitCount = 121 ID = 1840 9.792061 1 7B0 Rx d 8 30 08 00 00 00 00 00 00 Length = 239910 BitCount = 124 ID = 1968 9.792625 1 730 Tx d 8 21 00 00 00 20 00 AA AA Length = 234244 BitCount = 120 ID = 1840 9.793715 1 7B0 Rx d 8 04 74 20 01 02 00 00 00 Length = 233910 BitCount = 121 ID = 1968 34 00 44 08 00 00 00 00 00 20 00 | | | | | | | | | |memorySize:=0x00002000 | | | |memoryAddress:=0x08000000 is the starting address of the server memory where the data is to be written to | | |addressAndLengthFormatIdentifier | | |bit 7 - 4: Length (number of bytes) of the memorySize parameter | | |bit 3 - 0: Length (number of bytes) of the memoryAddress parameter | |dataFormatIdentifier:0x00 compressionMethod-encryptingMethod | |0x00 specifies that neither compressionMethod nor encryptingMethod is used |RequestDownload (34 hex) service:used by the client to initiate a data transfer from the client to the server (download) 74 20 01 02 | | | | | |maxNumberOfBlockLength:=0x0102 | |bit 3 - 0: reserved by document, to be set to '0'. | |bit 7 - 4: Length (number of bytes) of the maxNumberOfBlockLength parameter. | |lengthFormatIdentifier |RequestDownload Response SID
(6s)【36 xx data】
Tester 开始给汽车ECU传送刷写的数据,如上所提 maxNumberOfBlockLength为0x0102,除去[36 xx],有效的数据每次最多可以发送0x102-2=256个字节。 但Tester在这里每次只发送一半,有所保留,即0x80=128个字节; (A)其中【7F 36 78】是错误响应,错误代码为78,厂家自定义,这里没影响,因为最终有个肯定响应(B) (B)【76 xx】,表明汽车ECU已经正确接收这部分发送的数据并存储处理 (C) 其中 xx 为数据块编号,从1开始自动加1,一直到【36 40】,即总共成功发送了0x80*0x40=0x2000大小的数据,这些就是刷写到0x08000000地址的内容。 9.795696 1 730 Tx d 8 10 82 36 01 28 04 00 20 Length = 232244 BitCount = 119 ID = 1840 9.795987 1 7B0 Rx d 8 30 08 00 00 00 00 00 00 Length = 239910 BitCount = 124 ID = 1968 9.796548 1 730 Tx d 8 21 45 01 00 08 21 03 00 Length = 236244 BitCount = 121 ID = 1840 9.796790 1 730 Tx d 8 22 08 23 03 00 08 27 03 Length = 236244 BitCount = 121 ID = 1840 9.797030 1 730 Tx d 8 23 00 08 2B 03 00 08 2F Length = 234000 BitCount = 120 ID = 1840 9.797278 1 730 Tx d 8 24 03 00 08 00 00 00 00 Length = 242000 BitCount = 124 ID = 1840 9.797526 1 730 Tx d 8 25 00 00 00 00 00 00 00 Length = 242000 BitCount = 124 ID = 1840 9.797770 1 730 Tx d 8 26 00 00 00 00 00 33 03 Length = 238000 BitCount = 122 ID = 1840 9.798012 1 730 Tx d 8 27 00 08 35 03 00 08 00 Length = 236000 BitCount = 121 ID = 1840 9.798256 1 730 Tx d 8 28 00 00 00 37 03 00 08 Length = 238000 BitCount = 122 ID = 1840 9.798556 1 7B0 Rx d 8 30 08 00 00 00 00 00 00 Length = 239910 BitCount = 124 ID = 1968 9.799088 1 730 Tx d 8 29 39 03 00 08 5F 01 00 Length = 232259 BitCount = 119 ID = 1840 9.799329 1 730 Tx d 8 2A 08 5F 01 00 08 5F 01 Length = 234259 BitCount = 120 ID = 1840 9.799569 1 730 Tx d 8 2B 00 08 5F 01 00 08 5F Length = 234015 BitCount = 120 ID = 1840 9.799809 1 730 Tx d 8 2C 01 00 08 5F 01 00 08 Length = 234015 BitCount = 120 ID = 1840 9.800049 1 730 Tx d 8 2D 5F 01 00 08 5F 01 00 Length = 234015 BitCount = 120 ID = 1840 9.800291 1 730 Tx d 8 2E 08 5F 01 00 08 5F 01 Length = 236015 BitCount = 121 ID = 1840 9.800531 1 730 Tx d 8 2F 00 08 5F 01 00 08 5F Length = 234015 BitCount = 120 ID = 1840 9.800773 1 730 Tx d 8 20 01 00 08 5F 01 00 08 Length = 236015 BitCount = 121 ID = 1840 9.801077 1 7B0 Rx d 8 30 08 00 00 00 00 00 00 Length = 239910 BitCount = 124 ID = 1968 9.801509 1 730 Tx d 8 21 5F 01 00 08 5F 01 00 Length = 234244 BitCount = 120 ID = 1840 9.801745 1 730 Tx d 8 22 08 5F 01 00 08 AA AA Length = 230244 BitCount = 118 ID = 1840 |TransferData (36 hex) service 36 01 28 04 00 20 45 01 00 08 21 03 00 .. 08 5F 01 00 08 | | |transferRequestParameterRecord[] //For a download, the transferRequestParameterRecord include the data to be transferred | |blockSequenceCounter |TransferData (0x36) service 9.802687 1 7B0 Rx d 8 03 7F 36 78 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 9.802931 1 7B0 Rx d 8 02 76 01 00 00 00 00 00 Length = 235910 BitCount = 122 ID = 1968
(7)【37 01】下载完成,退出下载环节
10.314499 1 730 Tx d 8 02 37 01 AA AA AA AA AA Length = 222259 BitCount = 114 ID = 1840 | |RequestTransferExit (0x37) service 10.315695 1 7B0 Rx d 8 06 77 01 C6 B6 5E 10 00 Length = 225910 BitCount = 117 ID = 1968
(8)【31 01 DF FF】请求执行0xDFFF标志的过程,这里为厂家定义,估计是自校验或正式写入flash一类过程。
10.318529 1 730 Tx d 8 04 31 01 DF FF AA AA AA Length = 226244 BitCount = 116 ID = 1840 10.319707 1 7B0 Rx d 8 03 7F 31 78 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 10.320695 1 7B0 Rx d 8 05 71 01 DF FF 00 00 00 Length = 233910 BitCount = 121 ID = 1968 |startRoutine | 0xDFFF This range of values is reserved for vehicle manufacturer specific use
(9)【31 01 FF 01】请求执行0xFF01标志的过程,过程名称为checkProgrammingDependencies,检查编程相关项。
10.322633 1 730 Tx d 8 04 31 01 FF 01 AA AA AA Length = 226244 BitCount = 116 ID = 1840 10.323695 1 7B0 Rx d 8 05 71 01 FF 01 00 00 00 Length = 233910 BitCount = 121 ID = 1968 | 0xFF01 checkProgrammingDependencies
(10)【11 01】请求重启汽车ECU
10.325697 1 7DF Tx d 8 02 11 01 AA AA AA AA AA Length = 0 BitCount = 115 ID = 2015 // 1 OTP(04) Atom 7DF->7DF : SF Length: 02 [ 11 01 ] 10.326689 1 7B0 Rx d 8 03 7F 11 78 00 00 00 00 Length = 233910 BitCount = 121 ID = 1968 11.005924 CAN 1 Status:chip status error active 11.326752 1 7B0 Rx d 8 02 51 01 00 00 00 00 00 Length = 235910 BitCount = 122 ID = 1968 | ECUReset (0x11) service
2、我们整理下Tester与汽车ECU的通话的核心内容
(A)Tester请求编程会话 (B)Tester通过编程会话安全校验,得到许可 (C)Tester往汽车ECU的0x08000000写入了0x2000长的数据 (D)Tester请求重启汽车ECU
说明:我们前面知道,汽车的ECU为ARM,其中0x08000000地址一般作为第二BootLoader地址,即Tester让汽车ECU执行自己写入的内容。
四、代码数据提取与逆向
现在我们将注意力集中在Tester写入汽车ECU的0x08000000位置,大小为0x2000的代码数据内容上。
1、代码数据内容提取
我们通过编辑器正则替换,删除与下载数据【36 xx】无关的通讯帧,得到附件中的0x08000000_0x2000.binstr 其中每19行发送完一个大小为0x80的有效数据块
通过下述python代码,我们将0x08000000_0x2000.binstr提取出刷写的内容0x08000000_0x2000.bin(参考附件)
with open(r'.0x08000000_0x2000.binstr','rb') as fin:
fs = fin.read()
lns = fs.split('\n')
import re
fp = re.compile(r'(?sm)730 Tx d 8 10 82 36 (.. .. .. .. ..)')
dp = re.compile(r'(?sm)730 Tx d 8 2. (.. .. .. .. .. .. ..)')
hexstr = ''
for i in range(64):
sl = i*19
ff = [fp.match(lns[sl]).groups()[0][3:]]
for j in range(1,18):
ff.append(dp.match(lns[sl+j]).groups()[0])
ff.append(dp.match(lns[sl+18]).groups()[0][:-6])
hexstr+=' '.join(ff).replace(' ','').decode('hex')
with open(r'.\0x08000000_0x2000.bin','wb') as fout:
fout.write(hexstr)2、反编译
我们用IDA将0x08000000_0x2000.bin加载到0x08000000位置,使用小端ARM,通过快捷键【Alt+g】设置【T】值为1选择Thumb后,再对0x08000000处快捷键C反编译。如图
(2.1)起始函数Hi_start_8000000
(2.2) 由start函数到Hi_to_main_8001268函数
(2.3)由to_main函数进入主函数 Hi_main_8000138
(2.4)主函数main中获取flag的函数Hi_fetch_decrypt_flag_8000168
(A)获取flag的业务逻辑比较简单,对"flag{canoecr7-zd9h-1emi-or8m-f8vm2od81nfk}"简单运算
(B)fetch_flag函数伪码
(C)我们也可以通过unicorn简单模拟执行得到解密的flag
from unicorn import *
from unicorn.arm_const import *
import sark
import idc
segs = list(sark.segments())
elf_base = segs[0].ea
elf_size = segs[-1].ea+segs[-1].size
elf_size = 0x1000*((elf_size+0x0FFF)/0x1000)
stack_size = 4*1024*1024
mem_size = 4*1024*1024
mem_ptr = elf_base + elf_size + stack_size
all_size = elf_size + stack_size + mem_size
stack_init = elf_base + elf_size + stack_size/2
mu = Uc(UC_ARCH_ARM, UC_MODE_ARM)
mu.mem_map(elf_base, all_size)
print("Init Module: base:= {:06X} size:= {:04X}".format(elf_base,all_size))
for seg in segs:
segdata = idc.get_bytes(seg.ea,seg.size)
mu.mem_write(seg.ea, segdata)
print("Init Seg: base:= {:06X} size:= {:04X}".format(seg.ea,seg.size))
mu.reg_write(UC_ARM_REG_SP,stack_init)
mu.reg_write(UC_ARM_REG_R4, 0x80002C8)
mu.emu_start(0x08000180+1, 0x800028C)
mu.mem_read(0x080002C8,0x2c)
即【flag{3dad13db-cb48-495d-b023-3231d80f1713}】为我们鲜红的旗帜。
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