Windows 7:过冲C std :: this_thread :: sleep_for

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我们的代码用C 11(VS2012 / Win 7-64bit)编写. C库提供了我们使用的sleep_for函数.我们观察到C sleep_for有时显示出大的过冲.换句话说,我们要求睡觉15分钟,但睡眠结果是例如100毫秒当系统负载很高时,我们会看到这一点.

我的第一反应是:“当然,如果系统上有很多负载而其他线程正在使用cpu,那么睡眠”需要更长的时间“.
然而,“有趣”的是,如果我们用Windows API“Sleep”调用替换sleep_for,那么我们就不会看到这种行为.我还看到了水下的sleep_for函数调用了Window API Sleep方法.

sleep_for的文档指出:

The function blocks the calling thread for at least the time that’s specified by Rel_time. This function does not throw any exceptions.

从技术上讲,功能正在发挥作用.但是我们没想到看到C sleep_for和常规Sleep(Ex)功能之间存在差异.

有人可以解释这种行为吗?

如果使用sleep_for vs SleepEx,还会执行相当多的额外代码.

例如,调用SleepEx(15)在调试模式下生成以下程序集(Visual Studio 2015):

; 9    :    SleepEx(15,false);

    mov esi,esp
    push    0
    push    15                  ; 0000000fH
    call    DWORD PTR __imp__SleepEx@8
    cmp esi,esp
    call    __RTC_CheckEsp

相比之下,这段代码

const std::chrono::milliseconds duration(15);
std::this_thread::sleep_for(duration);

生成以下内容

; 9    :    std::this_thread::sleep_for(std::chrono::milliseconds(15));

    mov DWORD PTR $T1[ebp],15          ; 0000000fH
    lea eax,DWORD PTR $T1[ebp]
    push    eax
    lea ecx,DWORD PTR $T2[ebp]
    call    duration
    push    eax
    call    sleep_for
    add esp,4

这呼吁:

duration PROC ; std::chrono::duration<__int64,std::ratio<1,1000> >::duration<__int64,1000> ><int,void>,COMDAT
; _this$= ecx

; 113  :        {   // construct from representation

    push    ebp
    mov ebp,esp
    sub esp,204                ; 000000ccH
    push    ebx
    push    esi
    push    edi
    push    ecx
    lea edi,DWORD PTR [ebp-204]
    mov ecx,51                 ; 00000033H
    mov eax,-858993460             ; ccccccccH
    rep stosd
    pop ecx
    mov DWORD PTR _this$[ebp],ecx

; 112  :            : _MyRep(static_cast<_Rep>(_Val))

    mov eax,DWORD PTR __Val$[ebp]
    mov eax,DWORD PTR [eax]
    cdq
    mov ecx,DWORD PTR _this$[ebp]
    mov DWORD PTR [ecx],eax
    mov DWORD PTR [ecx+4],edx

; 114  :        }

    mov eax,DWORD PTR _this$[ebp]
    pop edi
    pop esi
    pop ebx
    mov esp,ebp
    pop ebp
    ret 4
duration ENDP

并打电话给

sleep_for PROC ; std::this_thread::sleep_for<__int64,1000> >,COMDAT

    ; 151  :    {   // sleep for duration

        push    ebp
        mov ebp,esp
        sub esp,268                ; 0000010cH
        push    ebx
        push    esi
        push    edi
        lea edi,DWORD PTR [ebp-268]
        mov ecx,67                 ; 00000043H
        mov eax,-858993460             ; ccccccccH
        rep stosd
        mov eax,DWORD PTR ___security_cookie
        xor eax,ebp
        mov DWORD PTR __$ArrayPad$[ebp],eax

    ; 152  :    stdext::threads::xtime _Tgt = _To_xtime(_Rel_time);

        mov eax,DWORD PTR __Rel_time$[ebp]
        push    eax
        lea ecx,DWORD PTR $T1[ebp]
        push    ecx
        call    to_xtime
        add esp,8
        mov edx,DWORD PTR [eax]
        mov DWORD PTR $T2[ebp],edx
        mov ecx,DWORD PTR [eax+4]
        mov DWORD PTR $T2[ebp+4],ecx
        mov edx,DWORD PTR [eax+8]
        mov DWORD PTR $T2[ebp+8],edx
        mov eax,DWORD PTR [eax+12]
        mov DWORD PTR $T2[ebp+12],eax
        mov ecx,DWORD PTR $T2[ebp]
        mov DWORD PTR __Tgt$[ebp],DWORD PTR $T2[ebp+4]
        mov DWORD PTR __Tgt$[ebp+4],DWORD PTR $T2[ebp+8]
        mov DWORD PTR __Tgt$[ebp+8],DWORD PTR $T2[ebp+12]
        mov DWORD PTR __Tgt$[ebp+12],ecx

    ; 153  :    sleep_until(&_Tgt);

        lea eax,DWORD PTR __Tgt$[ebp]
        push    eax
        call    sleep_until
        add esp,4

    ; 154  :    }

        push    edx
        mov ecx,ebp
        push    eax
        lea edx,DWORD PTR $LN5@sleep_for
        call    @_RTC_CheckStackVars@8
        pop eax
        pop edx
        pop edi
        pop esi
        pop ebx
        mov ecx,DWORD PTR __$ArrayPad$[ebp]
        xor ecx,ebp
        call    @__security_check_cookie@4
        add esp,268                ; 0000010cH
        cmp ebp,esp
        call    __RTC_CheckEsp
        mov esp,ebp
        pop ebp
        ret 0
        npad    3
    $LN5@sleep_for:
        DD  1
        DD  $LN4@sleep_for
    $LN4@sleep_for:
        DD  -24                 ; ffffffe8H
        DD  16                  ; 00000010H
        DD  $LN3@sleep_for
    $LN3@sleep_for:
        DB  95                  ; 0000005fH
        DB  84                  ; 00000054H
        DB  103                 ; 00000067H
        DB  116                 ; 00000074H
        DB  0
    sleep_for ENDP

一些转换发生:

to_xtime PROC ; std::_To_xtime<__int64,COMDAT

; 758  :    {   // convert duration to xtime

    push    ebp
    mov ebp,348                ; 0000015cH
    push    ebx
    push    esi
    push    edi
    lea edi,DWORD PTR [ebp-348]
    mov ecx,87                 ; 00000057H
    mov eax,-858993460             ; ccccccccH
    rep stosd
    mov eax,DWORD PTR ___security_cookie
    xor eax,ebp
    mov DWORD PTR __$ArrayPad$[ebp],eax

; 759  :    xtime _Xt;
; 760  :    if (_Rel_time <= chrono::duration<_Rep,_Period>::zero())

    lea eax,DWORD PTR $T7[ebp]
    push    eax
    call    duration_zero ; std::chrono::duration<__int64,1000> >::zero
    add esp,4
    push    eax
    mov ecx,DWORD PTR __Rel_time$[ebp]
    push    ecx
    call    chronos_operator ; std::chrono::operator<=<__int64,1000>,__int64,1000> >
    add esp,8
    movzx   edx,al
    test    edx,edx
    je  SHORT $LN2@To_xtime

; 761  :        {   // negative or zero relative time,return zero
; 762  :        _Xt.sec = 0;

    xorps   xmm0,xmm0
    movlpd  QWORD PTR __Xt$[ebp],xmm0

; 763  :        _Xt.nsec = 0;

    mov DWORD PTR __Xt$[ebp+8],0

; 764  :        }
; 765  :    else

    jmp $LN3@To_xtime
$LN2@To_xtime:

; 766  :        {   // positive relative time,convert
; 767  :        chrono::nanoseconds _T0 =
; 768  :            chrono::system_clock::now().time_since_epoch();

    lea eax,DWORD PTR $T5[ebp]
    push    eax
    lea ecx,DWORD PTR $T6[ebp]
    push    ecx
    call    system_clock_now ; std::chrono::system_clock::now
    add esp,4
    mov ecx,eax
    call    time_since_ephoch ; std::chrono::time_point<std::chrono::system_clock,std::chrono::duration<__int64,10000000> > >::time_since_epoch
    push    eax
    lea ecx,DWORD PTR __T0$8[ebp]
    call    duration ; std::chrono::duration<__int64,1000000000> >::duration<__int64,1000000000> ><__int64,10000000>,void>

; 769  :        _T0 += _Rel_time;

    mov eax,DWORD PTR __Rel_time$[ebp]
    push    eax
    lea ecx,DWORD PTR $T4[ebp]
    call    duration_ratio ; std::chrono::duration<__int64,void>
    lea ecx,DWORD PTR $T4[ebp]
    push    ecx
    lea ecx,DWORD PTR __T0$8[ebp]
    call    duration_ratio ; std::chrono::duration<__int64,1000000000> >::operator+=

; 770  :        _Xt.sec = chrono::duration_cast<chrono::seconds>(_T0).count();

    lea eax,DWORD PTR __T0$8[ebp]
    push    eax
    lea ecx,DWORD PTR $T3[ebp]
    push    ecx
    call    duration_cast ; std::chrono::duration_cast<std::chrono::duration<__int64,1> >,1000000000> >
    add esp,8
    mov ecx,eax
    call    duration_count ; std::chrono::duration<__int64,1> >::count
    mov DWORD PTR __Xt$[ebp],eax
    mov DWORD PTR __Xt$[ebp+4],edx

; 771  :        _T0 -= chrono::seconds(_Xt.sec);

    lea eax,DWORD PTR __Xt$[ebp]
    push    eax
    lea ecx,DWORD PTR $T1[ebp]
    call    duration_ratio ; std::chrono::duration<__int64,1> >::duration<__int64,1> ><__int64,void>
    push    eax
    lea ecx,DWORD PTR $T2[ebp]
    call    duration_ratio ; std::chrono::duration<__int64,1>,DWORD PTR $T2[ebp]
    push    ecx
    lea ecx,1000000000> >::operator-=

; 772  :        _Xt.nsec = (long)_T0.count();

    lea ecx,1000000000> >::count
    mov DWORD PTR __Xt$[ebp+8],eax
$LN3@To_xtime:

; 773  :        }
; 774  :    return (_Xt);

    mov eax,DWORD PTR $T9[ebp]
    mov ecx,DWORD PTR __Xt$[ebp]
    mov DWORD PTR [eax],ecx
    mov edx,DWORD PTR __Xt$[ebp+4]
    mov DWORD PTR [eax+4],edx
    mov ecx,DWORD PTR __Xt$[ebp+8]
    mov DWORD PTR [eax+8],DWORD PTR __Xt$[ebp+12]
    mov DWORD PTR [eax+12],edx
    mov eax,DWORD PTR $T9[ebp]

; 775  :    }

    push    edx
    mov ecx,ebp
    push    eax
    lea edx,DWORD PTR $LN8@To_xtime
    call    @_RTC_CheckStackVars@8
    pop eax
    pop edx
    pop edi
    pop esi
    pop ebx
    mov ecx,DWORD PTR __$ArrayPad$[ebp]
    xor ecx,ebp
    call    @__security_check_cookie@4
    add esp,348                ; 0000015cH
    cmp ebp,esp
    call    __RTC_CheckEsp
    mov esp,ebp
    pop ebp
    ret 0
$LN8@To_xtime:
    DD  2
    DD  $LN7@To_xtime
$LN7@To_xtime:
    DD  -24                 ; ffffffe8H
    DD  16                  ; 00000010H
    DD  $LN5@To_xtime
    DD  -40                 ; ffffffd8H
    DD  8
    DD  $LN6@To_xtime
$LN6@To_xtime:
    DB  95                  ; 0000005fH
    DB  84                  ; 00000054H
    DB  48                  ; 00000030H
    DB  0
$LN5@To_xtime:
    DB  95                  ; 0000005fH
    DB  88                  ; 00000058H
    DB  116                 ; 00000074H
    DB  0
to_xtime ENDP

最终调用导入的函数,与SleepEx使用的函数相同.

sleep_until PROC    ; std::this_thread::sleep_until,COMDAT

; 131  :    {   // sleep until _Abs_time

    push    ebp
    mov ebp,192                ; 000000c0H
    push    ebx
    push    esi
    push    edi
    lea edi,DWORD PTR [ebp-192]
    mov ecx,48                 ; 00000030H
    mov eax,-858993460             ; ccccccccH
    rep stosd

; 132  :    _Thrd_sleep(_Abs_time);

    mov esi,esp
    mov eax,DWORD PTR __Abs_time$[ebp]
    push    eax
    call    DWORD PTR __imp___Thrd_sleep
    add esp,4
    cmp esi,esp
    call    __RTC_CheckEsp

; 133  :    }

    pop edi
    pop esi
    pop ebx
    add esp,192                ; 000000c0H
    cmp ebp,ebp
    pop ebp
    ret 0
sleep_until ENDP

您还应该注意,即使SleepEx可能无法根据MSDN文档https://msdn.microsoft.com/en-us/library/windows/desktop/ms686307(v=vs.85).aspx提供100%的确切结果

函数使线程放弃其时间片的剩余部分,并在基于dwMilliseconds值的时间间隔内变得不可用.系统时钟以恒定速率“滴答”.如果dwMilliseconds小于系统时钟的分辨率,则线程可能会睡眠时间少于指定的时间长度.如果dwMilliseconds大于一个tick但小于2,则等待可以是一到两个滴答之间的任何位置,依此类推.要提高休眠间隔的准确性,请调用timeGetDevCaps函数以确定支持的最小计时器分辨率,并调用timeBeginPeriod函数将计时器分辨率设置为最小值.调用timeBeginPeriod时要小心,因为频繁的调用会显着影响系统时钟,系统功耗和调度程序.如果你调用timeBeginPeriod,在应用程序的早期调用它一次,并确保在应用程序的最后调用timeEndPeriod函数.

原文链接:https://www.f2er.com/windows/364897.html

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