在找sgmain相关资料时看到了这个贴子: https://bbs.pediy.com/thread-267741.htm 之后对大佬使用的trace工具很感兴趣,对反编译引擎也很感兴趣,不过底蕴不够,反编译引擎之类的也就将就用第三方,只能常试用frida的Stalker改了个类似的trace工具试了下效果也就有了这篇文章 用到的工具:ida/Ghidra/frida 看的是手淘6.5.82版本的sgmain,因为本身只是对trace工具的一次验证,所以不包含实际的算法分析过程,只谈测试过程中的感受 快速定位主要依赖的是Stalker,ida和Ghidra主要是用于静态分析 在静态分析上,我这种小菜鸡就不讨论两个反编译引擎的本质哪个优劣,就谈使用的感受。 先上对比,对于sgmain的doCommand方法 ida的效果: ghidra的效果: 源码大概是这样子的:
可以很明显看出ida对除法的优化更好一些,ghidra在除法这块就没有ida好,但是我个人更喜欢Ghidra的效果 这里说句题外话,关于除法,编译器对一个整数进行除法运算时往往会转换成乘一个魔数然后除2的多少次方这种,这个推导过程很复杂,本质上就是把除任意整数变成除2的N次方的数,但过程中存在很多边界问题导致比较复杂,不过如果当ida之类的返编译器在复杂需要手动推导时,网上有种方法可以算出大概的值,不过涉及到符号问题及取模问题,记得好像是有Sub类指令参与的可能就是取模,但没有细究,有兴趣的可以自己编译后对比看看。 一般像这种同时存在 乘法、位移0x3F/0x1f取符号位、ASR之类指令时,基本八九不离十就可能是除法
如上面的这种代码,就可以尝试用(1 << XX) / (magicNum - 1)这种方式来算出大概的除数,比如就上面的指令来说:
而且在patch后的及时效果上面感觉更好一些,特别是那些br reg,adrp ret之类的跳转识别效果会比ida好,用ida的时候那个JMPOUT很尴尬,即使你使用跳转patch了也不一定能有效f5,可能还得去除中间的一些混淆的乱码才可以 其次Ghidra也存在一个比较尴尬的问题,就像上面这个代码里面框起来的代码,那个0x2bb3c这个函数(ghidra会自动添加基址,默认是0x100000),在初次打开时,这个函数被识别为了空函数,而且无反回,这也就直接导致下面的那个0xe78c0所在的代码块被直接隐藏了,因为lStack76 != 0被直接视为了不可达分支,修改函数定义后代码也就立刻重新生成了上面的这个效果,修改是及时生效的,效果不错。 现在的一些间接跳转的混淆,不管他怎么变形,实际上很多时候都是常量表达式,而对于常量表达式的这种间接跳有很多种方式处理 比如0x2bb3c头部的这段代码:
代码看起来有点复杂,各种运算,还有间接地址访问,而且每个函数头部都有这种间接跳,且貌似每个表达式都不一样,但实际上这种处理起来也相当简单,分静态和动态两种情况。 动态的情况不用说,单步或trace来获取对应的跳转地址即可,对于Ghidra,也不需要特别处理,它会自动帮你把这些常量表达式计算出来,在进行反编译时会自动使用它计算出的结果进行代入。 比如下面的是Ghidra的汇编显示:
而如果你要说就用ida,不开启动态调试的情况下也简单,用ida的脚本使用unicorn进行模拟执行一下结果就跑出来了: 对于那种代码之间被各种跳转包围的间接跳,例如: ida中那种函数中间的间接跳
ghidra函数中部的间接跳:
处理方式其实差不多,不管是ida还是Ghidra它们即便是能算出来跳转地址,也会给你提示,比如上面的ida就提示地址是loc_2BD68,但是他们为了确宝流程尽可能准确,所以一般不会在返汇编窗口中进行常量化,这时候就需要进行手动patch。 如果是硬是要ida配合Unicorn,这时候也不是不可以,但是因为部分常量在其它代码块中,再加上里面经常混杂一些地址中常量的访问,在通用性上面可能会不太好,所以这种时候一般建议是用trace的数据,或依赖现有工具返汇编引擎的结果来参考进行Patch。 比如,在Ghidra中与上面的类似的代码块在反汇编引擎中一般会给你提示出来: 在汇编页面就是如下的这种:
可以看出,Ghidra已经通过自己的逻辑算出了常量地址,但是它并没有更新到返汇编结果中,patch后效果立马就出来了: 这种是间接跳,使用了全局变量进行跳转(大致含义就是全局变量0x270140这个地址中的内容+0xda计算出的结果就是call的地址),Ghidra这里识别为多种结果所以这种情况必需得上动态才能知道可能的结果了,不同流程可能结果会不一样 通过上面类似的反混淆操作后0x2bb3c这个函数大致的伪代码也就可以看了:
常见的混淆基本都是差不多的处理方式,再复杂的基本也离不开Trace了。
Stalker与ida的trace各有优缺点吧,ida的trace是依托于调试器的,所以调试器有的缺点他都有,一般配合DBG_Hooks脚本处理效果更好,我一般喜欢在定位范围缩小到一定程度后才会用它,再则是用它来追踪程序的退出流程返向推检测的代码,不过这里主要说Stalker使用的问题就不聊它了。 Stalker很早之前就存在了,不过貌似这个东西在arm64之后才用的比较多一些,在arm32里面需要处理跳转地址的问题,而我实际使用过程中发现,如果开启了call事件,基本必崩,所以所有事件都是false的情况下做的处理,简而言之就是只用了transform回调。 在使用过程中发现几点问题: 1.Stalker的模式给我的感觉是将每一个以b/ret之类的流程跳转指令作为块的分离点来处理的,transform入口处iterator.next()返回的是块的地址,所以在这里直接使用某一地址来判断是否为Trace跟踪的代码区间可能会存在问题,比如,我在尝试任意指令hook时不遍历整个iterator块而用addr.compare == 0作为判断就会永远无法到达,因为transform每次来时iterator.next()返回的只会是代码块的首地址 2.由于前面的原因,所以iterator.putCallout中的指令是没有b/ret之类跳转指令的,在arm32里面常见的adrp pc, #imm这类指令在这里没有看到,所以暂时不清楚这种情况会不会有其它变化。 3.instruction的regsRead和regsWritern里面是空的,碰到跳转或条件指令里里面会有值,但不包含常规寄存器,猜测可能是在性能优化上的有意为之,不过问题不大,无非就是在处理ldr x0,[x0]这类指令时打印寄存器值时需要注意一些。 除了这些外貌似也没什么太大的问题,整体执行速度还不错,就是代码量大时偶尔会挂掉,特别是在跟踪步入bl指令时。 然后依拖于Stalker封装了几个函数:
因为是随手测试的,所以没有专门去看sign的计算是哪一个,就随手测试了几个值,不需要的屏蔽掉了,也就有了下面的这个结果: sign计算的中间call都应该算是比较清析吧 中间的流程大概就是在0xbc708处bl 0xbe1ac,之后就是0xbc8e0处调用0xc709c,参数是1PaJH2i4Bu60DMq4zUogvFil9Bs=字符串,之后一连串的bl 0xc792c,之后会使用新的函数调用bl 0x2bb3c进行执行,之后还有
流程貌似还算比较清晰 然后在ghidra里面看了一下,不忍直视,来点片段享受一下吧 0xbc560
0xc709c
0xc792C
__int64 __fastcall sub_2DB50(JNIEnv
*
param_1,_int64 param_2,
int
param_3,
long
param_4){
unsigned
int
v12
=
0
;
long
ret
=
0
;
long
*
ptr
=
(
long
*
)malloc(
0x20
);
if
(ptr !
=
nullptr){
ptr[
0
]
=
0LL
;
ptr[
1
]
=
0LL
;
*
(_DWORD
*
)ptr
=
param_3
/
10000
;
v7
=
param_3
%
10000
/
100
;
*
((_DWORD
*
)ptr
+
1
)
=
v7;
*
((_DWORD
*
)ptr
+
2
)
=
param_3
%
100
;
ptr[
2
]
=
param_1;
ptr[
3
]
=
param_4;
ret
=
sub_2BB3C(param_3
/
10000
, v7, param_3
%
100
,
1u
, ptr, &v12);
}
free(ptr);
if
(ret
=
=
0
&& v12 !
=
0
){
/
/
throw Exception
sub_E78C0(param_1, v12,
0x20aa97
)
}
return
ret;
}
__int64 __fastcall sub_2DB50(JNIEnv
*
param_1,_int64 param_2,
int
param_3,
long
param_4){
unsigned
int
v12
=
0
;
long
ret
=
0
;
long
*
ptr
=
(
long
*
)malloc(
0x20
);
if
(ptr !
=
nullptr){
ptr[
0
]
=
0LL
;
ptr[
1
]
=
0LL
;
*
(_DWORD
*
)ptr
=
param_3
/
10000
;
v7
=
param_3
%
10000
/
100
;
*
((_DWORD
*
)ptr
+
1
)
=
v7;
*
((_DWORD
*
)ptr
+
2
)
=
param_3
%
100
;
ptr[
2
]
=
param_1;
ptr[
3
]
=
param_4;
ret
=
sub_2BB3C(param_3
/
10000
, v7, param_3
%
100
,
1u
, ptr, &v12);
}
free(ptr);
if
(ret
=
=
0
&& v12 !
=
0
){
/
/
throw Exception
sub_E78C0(param_1, v12,
0x20aa97
)
}
return
ret;
}
LOAD:
000000000002DBFC
A9
75
91
52
+
MOV W9,
LOAD:
000000000002DBFC
69
1B
AD
72
LOAD:
000000000002DC04
A9
7E
29
9B
SMULL X9, W21, W9
LOAD:
000000000002DC08
1F
7D
00
A9 STP XZR, XZR, [X8]
LOAD:
000000000002DC0C
E8
1B
40
F9 LDR X8, [SP,
LOAD:
000000000002DC10
2C
FD
7F
D3 LSR X12, X9,
LOAD:
000000000002DC14
29
FD
6C
93
ASR X9, X9,
LOAD:
000000000002DC18
20
01
0C
0B
ADD W0, W9, W12
LOAD:
000000000002DC1C
0A
E2
84
52
MOV W10,
LOAD:
000000000002DC20
EB A3
90
52
MOV W11,
LOAD:
000000000002DC24
00
01
00
B9
STR
W0, [X8]
LOAD:
000000000002DC28
6B
3D
AA
72
MOVK W11,
LOAD:
000000000002DC2C
0A
D4
0A
1B
MSUB W10, W0, W10, W21
LOAD:
000000000002DC30
E8
1B
40
F9 LDR X8, [SP,
LOAD:
000000000002DC34
4A
7D
2B
9B
SMULL X10, W10, W11
LOAD:
000000000002DC38
A9
7E
2B
9B
SMULL X9, W21, W11
LOAD:
000000000002DC3C
4B
FD
7F
D3 LSR X11, X10,
LOAD:
000000000002DC40
4A
FD
65
93
ASR X10, X10,
LOAD:
000000000002DC44
41
01
0B
0B
ADD W1, W10, W11
LOAD:
000000000002DC48
01
05
00
B9
STR
W1, [X8,
LOAD:
000000000002DC4C
2A
FD
7F
D3 LSR X10, X9,
LOAD:
000000000002DC50
28
FD
65
93
ASR X8, X9,
LOAD:
000000000002DC54
E9
1B
40
F9 LDR X9, [SP,
LOAD:
000000000002DC58
08
01
0A
0B
ADD W8, W8, W10
LOAD:
000000000002DC5C
8A
0C
80
52
MOV W10,
LOAD:
000000000002DC60
02
D5
0A
1B
MSUB W2, W8, W10, W21
LOAD:
000000000002DC64
22
09
00
B9
STR
W2, [X9,
LOAD:
000000000002DBFC
A9
75
91
52
+
MOV W9,
LOAD:
000000000002DBFC
69
1B
AD
72
LOAD:
000000000002DC04
A9
7E
29
9B
SMULL X9, W21, W9
LOAD:
000000000002DC08
1F
7D
00
A9 STP XZR, XZR, [X8]
LOAD:
000000000002DC0C
E8
1B
40
F9 LDR X8, [SP,
LOAD:
000000000002DC10
2C
FD
7F
D3 LSR X12, X9,
LOAD:
000000000002DC14
29
FD
6C
93
ASR X9, X9,
LOAD:
000000000002DC18
20
01
0C
0B
ADD W0, W9, W12
LOAD:
000000000002DC1C
0A
E2
84
52
MOV W10,
LOAD:
000000000002DC20
EB A3
90
52
MOV W11,
LOAD:
000000000002DC24
00
01
00
B9
STR
W0, [X8]
LOAD:
000000000002DC28
6B
3D
AA
72
MOVK W11,
LOAD:
000000000002DC2C
0A
D4
0A
1B
MSUB W10, W0, W10, W21
LOAD:
000000000002DC30
E8
1B
40
F9 LDR X8, [SP,
LOAD:
000000000002DC34
4A
7D
2B
9B
SMULL X10, W10, W11
LOAD:
000000000002DC38
A9
7E
2B
9B
SMULL X9, W21, W11
LOAD:
000000000002DC3C
4B
FD
7F
D3 LSR X11, X10,
LOAD:
000000000002DC40
4A
FD
65
93
ASR X10, X10,
LOAD:
000000000002DC44
41
01
0B
0B
ADD W1, W10, W11
LOAD:
000000000002DC48
01
05
00
B9
STR
W1, [X8,
LOAD:
000000000002DC4C
2A
FD
7F
D3 LSR X10, X9,
LOAD:
000000000002DC50
28
FD
65
93
ASR X8, X9,
LOAD:
000000000002DC54
E9
1B
40
F9 LDR X9, [SP,
LOAD:
000000000002DC58
08
01
0A
0B
ADD W8, W8, W10
LOAD:
000000000002DC5C
8A
0C
80
52
MOV W10,
LOAD:
000000000002DC60
02
D5
0A
1B
MSUB W2, W8, W10, W21
LOAD:
000000000002DC64
22
09
00
B9
STR
W2, [X9,
>>> (
1
<<
0x2c
)
/
(
0x68db8bad
-
1
)
10000.000002510205
>>> (
1
<<
0x25
)
/
(
0x51eb85ef
-
1
)
99.99998491839733
>>> (
1
<<
0x2c
)
/
(
0x68db8bad
-
1
)
10000.000002510205
>>> (
1
<<
0x25
)
/
(
0x51eb85ef
-
1
)
99.99998491839733
LOAD:
000000000002BB3C
SUB SP, SP,
LOAD:
000000000002BB40
STP X28, X27, [SP,
LOAD:
000000000002BB44
STP X26, X25, [SP,
LOAD:
000000000002BB48
STP X24, X23, [SP,
LOAD:
000000000002BB4C
STP X22, X21, [SP,
LOAD:
000000000002BB50
STP X20, X19, [SP,
LOAD:
000000000002BB54
STP X29, X30, [SP,
LOAD:
000000000002BB58
ADD X29, SP,
LOAD:
000000000002BB5C
MRS X26,
LOAD:
000000000002BB60
MOV W23, W1
LOAD:
000000000002BB64
MOV W24, W0
LOAD:
000000000002BB68
MOV W10,
LOAD:
000000000002BB6C
MOV W12,
LOAD:
000000000002BB70
LDR X14, [X26,
LOAD:
000000000002BB74
MUL W15, W24, W10
LOAD:
000000000002BB78
MUL W12, W23, W12
LOAD:
000000000002BB7C
MOV W22, W2
LOAD:
000000000002BB80
MOV W13,
LOAD:
000000000002BB84
ADD W10, W15, W12
LOAD:
000000000002BB88
MOV W8,
LOAD:
000000000002BB8C
SUB X9, X29,
LOAD:
000000000002BB90
MOVK W13,
LOAD:
000000000002BB94
ADD W10, W10, W22
LOAD:
000000000002BB98
MOV X21, X4
LOAD:
000000000002BB9C
ADD W13, W10, W13
LOAD:
000000000002BBA0
STUR X14, [X29,
LOAD:
000000000002BBA4
STUR W8, [X29,
LOAD:
000000000002BBA8
ADR X27, loc_2BBAC
LOAD:
000000000002BBAC
LOAD:
000000000002BBAC
loc_2BBAC ; DATA XREF: sub_2BB3C
+
6C
↑o
LOAD:
000000000002BBAC
LDRSW X4,
=
0xFFFFFE62
LOAD:
000000000002BBB0
MOV X20,
LOAD:
000000000002BBB4
EOR X4, X4, X20
LOAD:
000000000002BBB8
ADD X4, X4,
LOAD:
000000000002BBBC
MVN X4, X4
LOAD:
000000000002BBC0
LDRSW X10, [X9]
LOAD:
000000000002BBC4
EOR X4, X4, X10
LOAD:
000000000002BBC8
ADD X27, X27, X4
LOAD:
000000000002BBCC
MOV X8,
LOAD:
000000000002BBD0
BR X27
LOAD:
000000000002BB3C
SUB SP, SP,
LOAD:
000000000002BB40
STP X28, X27, [SP,
LOAD:
000000000002BB44
STP X26, X25, [SP,
LOAD:
000000000002BB48
STP X24, X23, [SP,
LOAD:
000000000002BB4C
STP X22, X21, [SP,
LOAD:
000000000002BB50
STP X20, X19, [SP,
LOAD:
000000000002BB54
STP X29, X30, [SP,
LOAD:
000000000002BB58
ADD X29, SP,
LOAD:
000000000002BB5C
MRS X26,
LOAD:
000000000002BB60
MOV W23, W1
LOAD:
000000000002BB64
MOV W24, W0
LOAD:
000000000002BB68
MOV W10,
LOAD:
000000000002BB6C
MOV W12,
LOAD:
000000000002BB70
LDR X14, [X26,
LOAD:
000000000002BB74
MUL W15, W24, W10
LOAD:
000000000002BB78
MUL W12, W23, W12
LOAD:
000000000002BB7C
MOV W22, W2
LOAD:
000000000002BB80
MOV W13,
LOAD:
000000000002BB84
ADD W10, W15, W12
LOAD:
000000000002BB88
MOV W8,
LOAD:
000000000002BB8C
SUB X9, X29,
LOAD:
000000000002BB90
MOVK W13,
LOAD:
000000000002BB94
ADD W10, W10, W22
LOAD:
000000000002BB98
MOV X21, X4
LOAD:
000000000002BB9C
ADD W13, W10, W13
LOAD:
000000000002BBA0
STUR X14, [X29,
LOAD:
000000000002BBA4
STUR W8, [X29,
LOAD:
000000000002BBA8
ADR X27, loc_2BBAC
LOAD:
000000000002BBAC
LOAD:
000000000002BBAC
loc_2BBAC ; DATA XREF: sub_2BB3C
+
6C
↑o
LOAD:
000000000002BBAC
LDRSW X4,
=
0xFFFFFE62
LOAD:
000000000002BBB0
MOV X20,
LOAD:
000000000002BBB4
EOR X4, X4, X20
LOAD:
000000000002BBB8
ADD X4, X4,
LOAD:
000000000002BBBC
MVN X4, X4
LOAD:
000000000002BBC0
LDRSW X10, [X9]
LOAD:
000000000002BBC4
EOR X4, X4, X10
LOAD:
000000000002BBC8
ADD X27, X27, X4
LOAD:
000000000002BBCC
MOV X8,
LOAD:
000000000002BBD0
BR X27
LAB_0013dd1c XREF[
1
]:
0013dd00
(j)
0013dd1c
e8
03
00
90
adrp x8,
0x1b9000
0013dd20
08
01
11
91
add x8,x8,
0013dd24
08
09
40
f9 ldr x8,[x8,
0013dd28
08
71
02
91
add x8,x8,
0013dd2c
00
01
1f
d6 br x8
=
>LAB_0013dd30
LAB_0013dd1c XREF[
1
]:
0013dd00
(j)
0013dd1c
e8
03
00
90
adrp x8,
0x1b9000
0013dd20
08
01
11
91
add x8,x8,
0013dd24
08
09
40
f9 ldr x8,[x8,
0013dd28
08
71
02
91
add x8,x8,
0013dd2c
00
01
1f
d6 br x8
=
>LAB_0013dd30
LOAD:
000000000002BD58
loc_2BD58 ; DATA XREF: sub_2BB3C
+
3B0
↓o
LOAD:
000000000002BD58
; LOAD:off_16FC38↓o
LOAD:
000000000002BD58
E9
23
0A
A9 STP X9, X8, [SP,
LOAD:
000000000002BD5C
88
36
40
F9 LDR X8, [X20,
LOAD:
000000000002BD60
FF
0F
00
F9
STR
XZR, [SP,
LOAD:
000000000002BD64
08
2D
00
91
ADD X8, X8,
LOAD:
000000000002BD68
LOAD:
000000000002BD68
loc_2BD68 ; DATA XREF: sub_2BB3C
+
220
↑o
LOAD:
000000000002BD68
; LOAD:off_16FC28↓o
LOAD:
000000000002BD68
03
00
00
14
B loc_2BD74 ; loc_2BD74 ; Keypatch modified this
from
:
LOAD:
000000000002BD68
; BR X8
LOAD:
000000000002BD58
loc_2BD58 ; DATA XREF: sub_2BB3C
+
3B0
↓o
LOAD:
000000000002BD58
; LOAD:off_16FC38↓o
LOAD:
000000000002BD58
E9
23
0A
A9 STP X9, X8, [SP,
LOAD:
000000000002BD5C
88
36
40
F9 LDR X8, [X20,
LOAD:
000000000002BD60
FF
0F
00
F9
STR
XZR, [SP,
LOAD:
000000000002BD64
08
2D
00
91
ADD X8, X8,
LOAD:
000000000002BD68
LOAD:
000000000002BD68
loc_2BD68 ; DATA XREF: sub_2BB3C
+
220
↑o
LOAD:
000000000002BD68
; LOAD:off_16FC28↓o
LOAD:
000000000002BD68
03
00
00
14
B loc_2BD74 ; loc_2BD74 ; Keypatch modified this
from
:
LOAD:
000000000002BD68
; BR X8
LAB_0013dd1c XREF[
1
]:
0013dd00
(j)
0013dd1c
e8
03
00
90
adrp x8,
0x1b9000
0013dd20
08
01
11
91
add x8,x8,
0013dd24
08
09
40
f9 ldr x8,[x8,
0013dd28
08
71
02
91
add x8,x8,
0013dd2c
00
01
1f
d6 br x8
=
>LAB_0013dd30
LAB_0013dd1c XREF[
1
]:
0013dd00
(j)
0013dd1c
e8
03
00
90
adrp x8,
0x1b9000
0013dd20
08
01
11
91
add x8,x8,
0013dd24
08
09
40
f9 ldr x8,[x8,
0013dd28
08
71
02
91
add x8,x8,
0013dd2c
00
01
1f
d6 br x8
=
>LAB_0013dd30
LAB_00134638 XREF[
1
]:
00134604
(j)
00134638
69
22
40
a9 ldp x9,x8,[x19]
0013463c
a8
03
18
f8 stur x8,[x29,
00134640
08
7d
40
92
and
x8,x8,
00134644
a9 a7
38
a9 stp x9,x9,[x29,
00134648
a8 c3
17
b8 stur w8,[x29,
0013464c
e9
07
00
b4 cbz x9,LAB_00134748
00134650
c8
07
00
34
cbz w8,LAB_00134748
00134654
f6
09
00
90
adrp x22,
0x270000
00134658
d6
82
01
91
add x22,x22,
0013465c
c8
4a
40
f9 ldr x8,[x22,
00134660
08
ad
01
91
add x8,x8,
00134664
00
01
1f
d6 br x8
=
>LAB_00134668
LAB_00134638 XREF[
1
]:
00134604
(j)
00134638
69
22
40
a9 ldp x9,x8,[x19]
0013463c
a8
03
18
f8 stur x8,[x29,
00134640
08
7d
40
92
and
x8,x8,
00134644
a9 a7
38
a9 stp x9,x9,[x29,
00134648
a8 c3
17
b8 stur w8,[x29,
0013464c
e9
07
00
b4 cbz x9,LAB_00134748
00134650
c8
07
00
34
cbz w8,LAB_00134748
00134654
f6
09
00
90
adrp x22,
0x270000
00134658
d6
82
01
91
add x22,x22,
0013465c
c8
4a
40
f9 ldr x8,[x22,
00134660
08
ad
01
91
add x8,x8,
00134664
00
01
1f
d6 br x8
=
>LAB_00134668
typedef struct _StData{
void
*
*
ppParamSt;
int
sz;
}StData;
typedef struct _StParam1{
int
param;
int
unknow;
StData
*
pSD;
}StParam1;
typedef struct _StParam2{
int
unknow;
int
param;
long
flag;
StData
*
pSD;
}StParam2;
typedef struct _StParam3{
long
unknow;
int
param;
int
unknow;
long
encryFuncAddr;
}StParam3;
long
FUN_0012bb3c(
int
param_1,
int
param_2,
int
param_3,
int
param_4,
long
*
param_5,
int
*
param_6)
{
int
iVar1;
long
lVar2;
StParam3
*
pSVar3;
long
local_1a8;
StParam1
*
pSStack416;
long
lStack408;
StParam2
*
pSStack400;
long
lStack392;
int
local_17c;
long
local_178;
int
local_7c;
long
*
plStack120;
int
*
piStack112;
long
local_68;
StData
*
*
pplVar1;
local_7c
=
1
;
plStack120
=
param_5;
piStack112
=
param_6;
local_178
=
FUN_00168480(param_1
*
10000
+
param_2
*
100
+
param_3
+
88000000
,
param_4,
0
, &plStack120, &local_7c);
if
(local_7c !
=
0
) {
pplVar1
=
(
long
*
*
)
0x279af0
;
/
/
全局变量非常量
if
(param_4 !
=
0
) {
pplVar1
=
(
long
*
*
)&DAT_00279ae8;
/
/
全局变量非常量
}
iVar1
=
(
*
pplVar1)
-
>sz;
if
(iVar1 <
1
){
local_17c
=
0x26b0
;
}
else
{
for
(local_1a8
=
0
; local_1a8 < iVar1; local_1a8
+
+
){
pSStack416
=
(StParam1
*
)(
*
pplVar1)
-
>ppParamSt[local_1a8];
if
(pSStack416
-
>param
=
=
param_1){
goto LAB_JMP1;
}
}
pSStack416
=
0
;
LAB_JMP1:
if
(pSStack416
=
=
0
){
local_17c
=
0x26b0
;
}
else
{
iVar1
=
pSStack416
-
>pSD
-
>sz;
if
(iVar1 <
1
){
local_17c
=
0x26b1
;
}
else
{
for
(lStack408
=
0
; lStack408 < iVar1; lStack408
+
+
){
pSStack400
=
(StParam2
*
)pSStack416
-
>pSD
-
>ppParamSt[lStack408];
if
(pSStack400
-
>param
=
=
param_2){
goto LAB_JMP2;
}
}
pSStack400
=
0
;
LAB_JMP2:
if
(pSStack400
=
=
0
){
local_17c
=
0x26b1
;
}
else
{
iVar1
=
pSStack400
-
>pSD
-
>sz;
if
(iVar1 >
0
){
for
(lStack392
=
0
; lStack392 < iVar1; lStack392
+
+
){
pSVar3
=
(StParam3
*
)pSStack400
-
>pSD
-
>ppParamSt[lStack392];
if
(pSVar3 !
=
0
&& pSVar3
-
>param
=
=
param_3){
local_178
=
(
*
(func
*
)(pSStack400
-
>flag ^ pSVar3
-
>encryFuncAddr))(param_5, param_6);
return
local_178;
}
}
}
local_17c
=
0x26b2
;
}
}
}
}
if
(param_6 !
=
(
int
*
)
0x0
) {
*
param_6
=
local_17c
+
(param_2
*
100
+
param_1
*
10000
+
param_3)
*
10000
;
}
local_178
=
0
;
}
return
local_178;
}
typedef struct _StData{
void
*
*
ppParamSt;
int
sz;
}StData;
typedef struct _StParam1{
int
param;
int
unknow;
StData
*
pSD;
}StParam1;
typedef struct _StParam2{
int
unknow;
int
param;
long
flag;
StData
*
pSD;
}StParam2;
typedef struct _StParam3{
long
unknow;
int
param;
int
unknow;
long
encryFuncAddr;
}StParam3;
long
FUN_0012bb3c(
int
param_1,
int
param_2,
int
param_3,
int
param_4,
long
*
param_5,
int
*
param_6)
{
int
iVar1;
long
lVar2;
StParam3
*
pSVar3;
long
local_1a8;
StParam1
*
pSStack416;
long
lStack408;
StParam2
*
pSStack400;
long
lStack392;
int
local_17c;
long
local_178;
int
local_7c;
long
*
plStack120;
int
*
piStack112;
long
local_68;
StData
*
*
pplVar1;
local_7c
=
1
;
plStack120
=
param_5;
piStack112
=
param_6;
local_178
=
FUN_00168480(param_1
*
10000
+
param_2
*
100
+
param_3
+
88000000
,
param_4,
0
, &plStack120, &local_7c);
if
(local_7c !
=
0
) {
pplVar1
=
(
long
*
*
)
0x279af0
;
/
/
全局变量非常量
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