用汇编的眼光看C++(之类继承)11
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继承是类的一个基本属性,可是在类的继承过程中,函数是怎么初始化?怎么析构的呢?我们不妨看看下面这样的一段代码?
- class employee
- {
- public:
- employee() { printf("employee()!\n");}
- ~employee() { printf("~employee()!\n");}
- };
- class manager : public employee
- {
- public:
- manager() { printf("manager()!\n");}
- ~manager() { printf("~maneger()!\n");}
- };
看到上面的代码,相信大家也明白了,我们定义了这样一个类。基类是empoyee,继承类是manager。我们看到manager是一种特殊的employee,那么在内存构建和析构的时候函数又是怎么安排的呢?
- 74: manager m;
- 00401268 lea ecx,[ebp-4]
- 0040126B call @ILT+60(manager::manager) (00401041)
- 75: }
- 00401270 lea ecx,[ebp-4]
- 00401273 call @ILT+0(manager::~manager) (00401005)
- 00401278 pop edi
- 00401279 pop esi
- 0040127A pop ebx
- 0040127B add esp,44h
- 0040127E cmp ebp,esp
- 00401280 call __chkesp (00408760)
- 00401285 mov esp,ebp
- 00401287 pop ebp
我们发现manager的构造和析构其实也简单。构造函数其实就是在变量出现的时候进行构造。那什么时候析构呢?也就在函数快结束的时候进行析构。下面我们可以进一步讨论在manager的构造和析构究竟是怎么做的?
- 65: class manager : public employee
- 66: {
- 67: public:
- 68: manager() { printf("manager()!\n");}
- 004012A0 push ebp
- 004012A1 mov ebp,esp
- 004012A3 sub esp,44h
- 004012A6 push ebx
- 004012A7 push esi
- 004012A8 push edi
- 004012A9 push ecx
- 004012AA lea edi,[ebp-44h]
- 004012AD mov ecx,11h
- 004012B2 mov eax,0CCCCCCCCh
- 004012B7 rep stos dword ptr [edi]
- 004012B9 pop ecx
- 004012BA mov dword ptr [ebp-4],ecx
- 004012BD mov ecx,dword ptr [ebp-4]
- 004012C0 call @ILT+40(employee::employee) (0040102d)
- 004012C5 push offset string "manager()!\n" (00431020)
- 004012CA call printf (004086e0)
- 004012CF add esp,4
- 004012D2 mov eax,dword ptr [ebp-4]
- 004012D5 pop edi
- 004012D6 pop esi
- 004012D7 pop ebx
- 004012D8 add esp,44h
- 004012DB cmp ebp,esp
- 004012DD call __chkesp (00408760)
- 004012E2 mov esp,ebp
- 004012E4 pop ebp
- 004012E5 ret
我们发现,manager的构造里面添加了employee的缺省构造函数,那么析构函数呢?
- 69: ~manager() { printf("~maneger()!\n");}
- 00401350 push ebp
- 00401351 mov ebp,esp
- 00401353 sub esp,44h
- 00401356 push ebx
- 00401357 push esi
- 00401358 push edi
- 00401359 push ecx
- 0040135A lea edi,[ebp-44h]
- 0040135D mov ecx,11h
- 00401362 mov eax,0CCCCCCCCh
- 00401367 rep stos dword ptr [edi]
- 00401369 pop ecx
- 0040136A mov dword ptr [ebp-4],ecx
- 0040136D push offset string "~maneger()!\n" (00431040)
- 00401372 call printf (004086e0)
- 00401377 add esp,4
- 0040137A mov ecx,dword ptr [ebp-4]
- 0040137D call @ILT+5(employee::~employee) (0040100a)
- 00401382 pop edi
- 00401383 pop esi
- 00401384 pop ebx
- 00401385 add esp,44h
- 00401388 cmp ebp,esp
- 0040138A call __chkesp (00408760)
- 0040138F mov esp,ebp
- 00401391 pop ebp
- 00401392 ret
我们发现,manager构造的时候employee率先构造,然后打印manager;析构的时候,恰恰相反,manager首先析构自己,然后在再调用employee的析构函数,上面的汇编代码证明了一切。