D-Modem/pjproject-2.11.1/third_party/BaseClasses/arithutil.cpp

//------------------------------------------------------------------------------
// File: ArithUtil.cpp
//
// Desc: DirectShow base classes - implements helper classes for building
//       multimedia filters.
//
// Copyright (c) 1992-2004 Microsoft Corporation.  All rights reserved.
//------------------------------------------------------------------------------

#include <pjmedia-videodev/config.h>

#if defined(PJMEDIA_VIDEO_DEV_HAS_DSHOW) && PJMEDIA_VIDEO_DEV_HAS_DSHOW != 0

#include <streams.h>

//
//  Declare function from largeint.h we need so that PPC can build
//

//
// Enlarged integer divide - 64-bits / 32-bits > 32-bits
//

#if !defined(_X86_) || !defined(_MSC_VER)

#define LLtoU64(x) (*(unsigned __int64*)(void*)(&(x)))

__inline
ULONG
WINAPI
EnlargedUnsignedDivide (
    IN ULARGE_INTEGER Dividend,
    IN ULONG Divisor,
    IN PULONG Remainder
    )
{
        // return remainder if necessary
        if (Remainder != NULL)
                *Remainder = (ULONG)(LLtoU64(Dividend) % Divisor);
        return (ULONG)(LLtoU64(Dividend) / Divisor);
}

#else
__inline
ULONG
WINAPI
EnlargedUnsignedDivide (
    IN ULARGE_INTEGER Dividend,
    IN ULONG Divisor,
    IN PULONG Remainder
    )
{
    ULONG ulResult;
    _asm {
        mov eax,Dividend.LowPart
        mov edx,Dividend.HighPart
        mov ecx,Remainder
        div Divisor
        or  ecx,ecx
        jz  short label
        mov [ecx],edx
label:
        mov ulResult,eax
    }
    return ulResult;
}
#endif


/*  Arithmetic functions to help with time format conversions
*/

#ifdef _M_ALPHA
// work around bug in version 12.00.8385 of the alpha compiler where
// UInt32x32To64 sign-extends its arguments (?)
#undef UInt32x32To64
#define UInt32x32To64(a, b) (((ULONGLONG)((ULONG)(a)) & 0xffffffff) * ((ULONGLONG)((ULONG)(b)) & 0xffffffff))
#endif

/*   Compute (a * b + d) / c */
LONGLONG WINAPI llMulDiv(LONGLONG a, LONGLONG b, LONGLONG c, LONGLONG d)
{
    /*  Compute the absolute values to avoid signed arithmetic problems */
    ULARGE_INTEGER ua, ub;
    DWORDLONG uc;

    ua.QuadPart = (DWORDLONG)(a >= 0 ? a : -a);
    ub.QuadPart = (DWORDLONG)(b >= 0 ? b : -b);
    uc          = (DWORDLONG)(c >= 0 ? c : -c);
    BOOL bSign = (a < 0) ^ (b < 0);

    /*  Do long multiplication */
    ULARGE_INTEGER p[2];
    p[0].QuadPart  = UInt32x32To64(ua.LowPart, ub.LowPart);

    /*  This next computation cannot overflow into p[1].HighPart because
        the max number we can compute here is:

                 (2 ** 32 - 1) * (2 ** 32 - 1) +  // ua.LowPart * ub.LowPart
    (2 ** 32) *  (2 ** 31) * (2 ** 32 - 1) * 2    // x.LowPart * y.HighPart * 2

    == 2 ** 96 - 2 ** 64 + (2 ** 64 - 2 ** 33 + 1)
    == 2 ** 96 - 2 ** 33 + 1
    < 2 ** 96
    */

    ULARGE_INTEGER x;
    x.QuadPart     = UInt32x32To64(ua.LowPart, ub.HighPart) +
                     UInt32x32To64(ua.HighPart, ub.LowPart) +
                     p[0].HighPart;
    p[0].HighPart  = x.LowPart;
    p[1].QuadPart  = UInt32x32To64(ua.HighPart, ub.HighPart) + x.HighPart;

    if (d != 0) {
        ULARGE_INTEGER ud[2];
        if (bSign) {
            ud[0].QuadPart = (DWORDLONG)(-d);
            if (d > 0) {
                /*  -d < 0 */
                ud[1].QuadPart = (DWORDLONG)(LONGLONG)-1;
            } else {
                ud[1].QuadPart = (DWORDLONG)0;
            }
        } else {
            ud[0].QuadPart = (DWORDLONG)d;
            if (d < 0) {
                ud[1].QuadPart = (DWORDLONG)(LONGLONG)-1;
            } else {
                ud[1].QuadPart = (DWORDLONG)0;
            }
        }
        /*  Now do extended addition */
        ULARGE_INTEGER uliTotal;

        /*  Add ls DWORDs */
        uliTotal.QuadPart  = (DWORDLONG)ud[0].LowPart + p[0].LowPart;
        p[0].LowPart       = uliTotal.LowPart;

        /*  Propagate carry */
        uliTotal.LowPart   = uliTotal.HighPart;
        uliTotal.HighPart  = 0;

        /*  Add 2nd most ls DWORDs */
        uliTotal.QuadPart += (DWORDLONG)ud[0].HighPart + p[0].HighPart;
        p[0].HighPart      = uliTotal.LowPart;

        /*  Propagate carry */
        uliTotal.LowPart   = uliTotal.HighPart;
        uliTotal.HighPart  = 0;

        /*  Add MS DWORDLONGs - no carry expected */
        p[1].QuadPart     += ud[1].QuadPart + uliTotal.QuadPart;

        /*  Now see if we got a sign change from the addition */
        if ((LONG)p[1].HighPart < 0) {
            bSign = !bSign;

            /*  Negate the current value (ugh!) */
            p[0].QuadPart  = ~p[0].QuadPart;
            p[1].QuadPart  = ~p[1].QuadPart;
            p[0].QuadPart += 1;
            p[1].QuadPart += (p[0].QuadPart == 0);
        }
    }

    /*  Now for the division */
    if (c < 0) {
        bSign = !bSign;
    }


    /*  This will catch c == 0 and overflow */
    if (uc <= p[1].QuadPart) {
        return bSign ? (LONGLONG)0x8000000000000000 :
                       (LONGLONG)0x7FFFFFFFFFFFFFFF;
    }

    DWORDLONG ullResult;

    /*  Do the division */
    /*  If the dividend is a DWORD_LONG use the compiler */
    if (p[1].QuadPart == 0) {
        ullResult = p[0].QuadPart / uc;
        return bSign ? -(LONGLONG)ullResult : (LONGLONG)ullResult;
    }

    /*  If the divisor is a DWORD then its simpler */
    ULARGE_INTEGER ulic;
    ulic.QuadPart = uc;
    if (ulic.HighPart == 0) {
        ULARGE_INTEGER uliDividend;
        ULARGE_INTEGER uliResult;
        DWORD dwDivisor = (DWORD)uc;
        // ASSERT(p[1].HighPart == 0 && p[1].LowPart < dwDivisor);
        uliDividend.HighPart = p[1].LowPart;
        uliDividend.LowPart = p[0].HighPart;
#ifndef USE_LARGEINT
        uliResult.HighPart = (DWORD)(uliDividend.QuadPart / dwDivisor);
        p[0].HighPart = (DWORD)(uliDividend.QuadPart % dwDivisor);
        uliResult.LowPart = 0;
        uliResult.QuadPart = p[0].QuadPart / dwDivisor + uliResult.QuadPart;
#else
        /*  NOTE - this routine will take exceptions if
            the result does not fit in a DWORD
        */
        if (uliDividend.QuadPart >= (DWORDLONG)dwDivisor) {
            uliResult.HighPart = EnlargedUnsignedDivide(
                                     uliDividend,
                                     dwDivisor,
                                     &p[0].HighPart);
        } else {
            uliResult.HighPart = 0;
        }
        uliResult.LowPart = EnlargedUnsignedDivide(
                                 p[0],
                                 dwDivisor,
                                 NULL);
#endif
        return bSign ? -(LONGLONG)uliResult.QuadPart :
                        (LONGLONG)uliResult.QuadPart;
    }


    ullResult = 0;

    /*  OK - do long division */
    for (int i = 0; i < 64; i++) {
        ullResult <<= 1;

        /*  Shift 128 bit p left 1 */
        p[1].QuadPart <<= 1;
        if ((p[0].HighPart & 0x80000000) != 0) {
            p[1].LowPart++;
        }
        p[0].QuadPart <<= 1;

        /*  Compare */
        if (uc <= p[1].QuadPart) {
            p[1].QuadPart -= uc;
            ullResult += 1;
        }
    }

    return bSign ? - (LONGLONG)ullResult : (LONGLONG)ullResult;
}

LONGLONG WINAPI Int64x32Div32(LONGLONG a, LONG b, LONG c, LONG d)
{
    ULARGE_INTEGER ua;
    DWORD ub;
    DWORD uc;

    /*  Compute the absolute values to avoid signed arithmetic problems */
    ua.QuadPart = (DWORDLONG)(a >= 0 ? a : -a);
    ub = (DWORD)(b >= 0 ? b : -b);
    uc = (DWORD)(c >= 0 ? c : -c);
    BOOL bSign = (a < 0) ^ (b < 0);

    /*  Do long multiplication */
    ULARGE_INTEGER p0;
    DWORD p1;
    p0.QuadPart  = UInt32x32To64(ua.LowPart, ub);

    if (ua.HighPart != 0) {
        ULARGE_INTEGER x;
        x.QuadPart     = UInt32x32To64(ua.HighPart, ub) + p0.HighPart;
        p0.HighPart  = x.LowPart;
        p1   = x.HighPart;
    } else {
        p1 = 0;
    }

    if (d != 0) {
        ULARGE_INTEGER ud0;
        DWORD ud1;

        if (bSign) {
            //
            //  Cast d to LONGLONG first otherwise -0x80000000 sign extends
            //  incorrectly
            //
            ud0.QuadPart = (DWORDLONG)(-(LONGLONG)d);
            if (d > 0) {
                /*  -d < 0 */
                ud1 = (DWORD)-1;
            } else {
                ud1 = (DWORD)0;
            }
        } else {
            ud0.QuadPart = (DWORDLONG)d;
            if (d < 0) {
                ud1 = (DWORD)-1;
            } else {
                ud1 = (DWORD)0;
            }
        }
        /*  Now do extended addition */
        ULARGE_INTEGER uliTotal;

        /*  Add ls DWORDs */
        uliTotal.QuadPart  = (DWORDLONG)ud0.LowPart + p0.LowPart;
        p0.LowPart       = uliTotal.LowPart;

        /*  Propagate carry */
        uliTotal.LowPart   = uliTotal.HighPart;
        uliTotal.HighPart  = 0;

        /*  Add 2nd most ls DWORDs */
        uliTotal.QuadPart += (DWORDLONG)ud0.HighPart + p0.HighPart;
        p0.HighPart      = uliTotal.LowPart;

        /*  Add MS DWORDLONGs - no carry expected */
        p1 += ud1 + uliTotal.HighPart;

        /*  Now see if we got a sign change from the addition */
        if ((LONG)p1 < 0) {
            bSign = !bSign;

            /*  Negate the current value (ugh!) */
            p0.QuadPart  = ~p0.QuadPart;
            p1 = ~p1;
            p0.QuadPart += 1;
            p1 += (p0.QuadPart == 0);
        }
    }

    /*  Now for the division */
    if (c < 0) {
        bSign = !bSign;
    }


    /*  This will catch c == 0 and overflow */
    if (uc <= p1) {
        return bSign ? (LONGLONG)0x8000000000000000 :
                       (LONGLONG)0x7FFFFFFFFFFFFFFF;
    }

    /*  Do the division */

    /*  If the divisor is a DWORD then its simpler */
    ULARGE_INTEGER uliDividend;
    ULARGE_INTEGER uliResult;
    DWORD dwDivisor = uc;
    uliDividend.HighPart = p1;
    uliDividend.LowPart = p0.HighPart;
    /*  NOTE - this routine will take exceptions if
        the result does not fit in a DWORD
    */
    if (uliDividend.QuadPart >= (DWORDLONG)dwDivisor) {
        uliResult.HighPart = EnlargedUnsignedDivide(
                                 uliDividend,
                                 dwDivisor,
                                 &p0.HighPart);
    } else {
        uliResult.HighPart = 0;
    }
    uliResult.LowPart = EnlargedUnsignedDivide(
                             p0,
                             dwDivisor,
                             NULL);
    return bSign ? -(LONGLONG)uliResult.QuadPart :
                    (LONGLONG)uliResult.QuadPart;
}

#endif /* PJMEDIA_VIDEO_DEV_HAS_DSHOW */
initial commit 2021-10-30 02:41:03 +08:00			`//------------------------------------------------------------------------------`
			`// File: ArithUtil.cpp`
			`//`
			`// Desc: DirectShow base classes - implements helper classes for building`
			`// multimedia filters.`
			`//`
			`// Copyright (c) 1992-2004 Microsoft Corporation. All rights reserved.`
			`//------------------------------------------------------------------------------`

			`#include <pjmedia-videodev/config.h>`

			`#if defined(PJMEDIA_VIDEO_DEV_HAS_DSHOW) && PJMEDIA_VIDEO_DEV_HAS_DSHOW != 0`

			`#include <streams.h>`

			`//`
			`// Declare function from largeint.h we need so that PPC can build`
			`//`

			`//`
			`// Enlarged integer divide - 64-bits / 32-bits > 32-bits`
			`//`

			`#if !defined(_X86_) \|\| !defined(_MSC_VER)`

			`#define LLtoU64(x) ((unsigned __int64)(void*)(&(x)))`

			`__inline`
			`ULONG`
			`WINAPI`
			`EnlargedUnsignedDivide (`
			`IN ULARGE_INTEGER Dividend,`
			`IN ULONG Divisor,`
			`IN PULONG Remainder`
			`)`
			`{`
			`// return remainder if necessary`
			`if (Remainder != NULL)`
			`*Remainder = (ULONG)(LLtoU64(Dividend) % Divisor);`
			`return (ULONG)(LLtoU64(Dividend) / Divisor);`
			`}`

			`#else`
			`__inline`
			`ULONG`
			`WINAPI`
			`EnlargedUnsignedDivide (`
			`IN ULARGE_INTEGER Dividend,`
			`IN ULONG Divisor,`
			`IN PULONG Remainder`
			`)`
			`{`
			`ULONG ulResult;`
			`_asm {`
			`mov eax,Dividend.LowPart`
			`mov edx,Dividend.HighPart`
			`mov ecx,Remainder`
			`div Divisor`
			`or ecx,ecx`
			`jz short label`
			`mov [ecx],edx`
			`label:`
			`mov ulResult,eax`
			`}`
			`return ulResult;`
			`}`
			`#endif`


			`/* Arithmetic functions to help with time format conversions`
			`*/`

			`#ifdef _M_ALPHA`
			`// work around bug in version 12.00.8385 of the alpha compiler where`
			`// UInt32x32To64 sign-extends its arguments (?)`
			`#undef UInt32x32To64`
			`#define UInt32x32To64(a, b) (((ULONGLONG)((ULONG)(a)) & 0xffffffff) * ((ULONGLONG)((ULONG)(b)) & 0xffffffff))`
			`#endif`

			`/* Compute (a * b + d) / c */`
			`LONGLONG WINAPI llMulDiv(LONGLONG a, LONGLONG b, LONGLONG c, LONGLONG d)`
			`{`
			`/* Compute the absolute values to avoid signed arithmetic problems */`
			`ULARGE_INTEGER ua, ub;`
			`DWORDLONG uc;`

			`ua.QuadPart = (DWORDLONG)(a >= 0 ? a : -a);`
			`ub.QuadPart = (DWORDLONG)(b >= 0 ? b : -b);`
			`uc = (DWORDLONG)(c >= 0 ? c : -c);`
			`BOOL bSign = (a < 0) ^ (b < 0);`

			`/* Do long multiplication */`
			`ULARGE_INTEGER p[2];`
			`p[0].QuadPart = UInt32x32To64(ua.LowPart, ub.LowPart);`

			`/* This next computation cannot overflow into p[1].HighPart because`
			`the max number we can compute here is:`

			`(2 ** 32 - 1) * (2 ** 32 - 1) + // ua.LowPart * ub.LowPart`
			`(2 ** 32) * (2 ** 31) * (2 ** 32 - 1) * 2 // x.LowPart * y.HighPart * 2`

			`== 2 96 - 2 64 + (2 64 - 2 33 + 1)`
			`== 2 96 - 2 33 + 1`
			`< 2 ** 96`
			`*/`

			`ULARGE_INTEGER x;`
			`x.QuadPart = UInt32x32To64(ua.LowPart, ub.HighPart) +`
			`UInt32x32To64(ua.HighPart, ub.LowPart) +`
			`p[0].HighPart;`
			`p[0].HighPart = x.LowPart;`
			`p[1].QuadPart = UInt32x32To64(ua.HighPart, ub.HighPart) + x.HighPart;`

			`if (d != 0) {`
			`ULARGE_INTEGER ud[2];`
			`if (bSign) {`
			`ud[0].QuadPart = (DWORDLONG)(-d);`
			`if (d > 0) {`
			`/* -d < 0 */`
			`ud[1].QuadPart = (DWORDLONG)(LONGLONG)-1;`
			`} else {`
			`ud[1].QuadPart = (DWORDLONG)0;`
			`}`
			`} else {`
			`ud[0].QuadPart = (DWORDLONG)d;`
			`if (d < 0) {`
			`ud[1].QuadPart = (DWORDLONG)(LONGLONG)-1;`
			`} else {`
			`ud[1].QuadPart = (DWORDLONG)0;`
			`}`
			`}`
			`/* Now do extended addition */`
			`ULARGE_INTEGER uliTotal;`

			`/* Add ls DWORDs */`
			`uliTotal.QuadPart = (DWORDLONG)ud[0].LowPart + p[0].LowPart;`
			`p[0].LowPart = uliTotal.LowPart;`

			`/* Propagate carry */`
			`uliTotal.LowPart = uliTotal.HighPart;`
			`uliTotal.HighPart = 0;`

			`/* Add 2nd most ls DWORDs */`
			`uliTotal.QuadPart += (DWORDLONG)ud[0].HighPart + p[0].HighPart;`
			`p[0].HighPart = uliTotal.LowPart;`

			`/* Propagate carry */`
			`uliTotal.LowPart = uliTotal.HighPart;`
			`uliTotal.HighPart = 0;`

			`/* Add MS DWORDLONGs - no carry expected */`
			`p[1].QuadPart += ud[1].QuadPart + uliTotal.QuadPart;`

			`/* Now see if we got a sign change from the addition */`
			`if ((LONG)p[1].HighPart < 0) {`
			`bSign = !bSign;`

			`/* Negate the current value (ugh!) */`
			`p[0].QuadPart = ~p[0].QuadPart;`
			`p[1].QuadPart = ~p[1].QuadPart;`
			`p[0].QuadPart += 1;`
			`p[1].QuadPart += (p[0].QuadPart == 0);`
			`}`
			`}`

			`/* Now for the division */`
			`if (c < 0) {`
			`bSign = !bSign;`
			`}`


			`/* This will catch c == 0 and overflow */`
			`if (uc <= p[1].QuadPart) {`
			`return bSign ? (LONGLONG)0x8000000000000000 :`
			`(LONGLONG)0x7FFFFFFFFFFFFFFF;`
			`}`

			`DWORDLONG ullResult;`

			`/* Do the division */`
			`/* If the dividend is a DWORD_LONG use the compiler */`
			`if (p[1].QuadPart == 0) {`
			`ullResult = p[0].QuadPart / uc;`
			`return bSign ? -(LONGLONG)ullResult : (LONGLONG)ullResult;`
			`}`

			`/* If the divisor is a DWORD then its simpler */`
			`ULARGE_INTEGER ulic;`
			`ulic.QuadPart = uc;`
			`if (ulic.HighPart == 0) {`
			`ULARGE_INTEGER uliDividend;`
			`ULARGE_INTEGER uliResult;`
			`DWORD dwDivisor = (DWORD)uc;`
			`// ASSERT(p[1].HighPart == 0 && p[1].LowPart < dwDivisor);`
			`uliDividend.HighPart = p[1].LowPart;`
			`uliDividend.LowPart = p[0].HighPart;`
			`#ifndef USE_LARGEINT`
			`uliResult.HighPart = (DWORD)(uliDividend.QuadPart / dwDivisor);`
			`p[0].HighPart = (DWORD)(uliDividend.QuadPart % dwDivisor);`
			`uliResult.LowPart = 0;`
			`uliResult.QuadPart = p[0].QuadPart / dwDivisor + uliResult.QuadPart;`
			`#else`
			`/* NOTE - this routine will take exceptions if`
			`the result does not fit in a DWORD`
			`*/`
			`if (uliDividend.QuadPart >= (DWORDLONG)dwDivisor) {`
			`uliResult.HighPart = EnlargedUnsignedDivide(`
			`uliDividend,`
			`dwDivisor,`
			`&p[0].HighPart);`
			`} else {`
			`uliResult.HighPart = 0;`
			`}`
			`uliResult.LowPart = EnlargedUnsignedDivide(`
			`p[0],`
			`dwDivisor,`
			`NULL);`
			`#endif`
			`return bSign ? -(LONGLONG)uliResult.QuadPart :`
			`(LONGLONG)uliResult.QuadPart;`
			`}`


			`ullResult = 0;`

			`/* OK - do long division */`
			`for (int i = 0; i < 64; i++) {`
			`ullResult <<= 1;`

			`/* Shift 128 bit p left 1 */`
			`p[1].QuadPart <<= 1;`
			`if ((p[0].HighPart & 0x80000000) != 0) {`
			`p[1].LowPart++;`
			`}`
			`p[0].QuadPart <<= 1;`

			`/* Compare */`
			`if (uc <= p[1].QuadPart) {`
			`p[1].QuadPart -= uc;`
			`ullResult += 1;`
			`}`
			`}`

			`return bSign ? - (LONGLONG)ullResult : (LONGLONG)ullResult;`
			`}`

			`LONGLONG WINAPI Int64x32Div32(LONGLONG a, LONG b, LONG c, LONG d)`
			`{`
			`ULARGE_INTEGER ua;`
			`DWORD ub;`
			`DWORD uc;`

			`/* Compute the absolute values to avoid signed arithmetic problems */`
			`ua.QuadPart = (DWORDLONG)(a >= 0 ? a : -a);`
			`ub = (DWORD)(b >= 0 ? b : -b);`
			`uc = (DWORD)(c >= 0 ? c : -c);`
			`BOOL bSign = (a < 0) ^ (b < 0);`

			`/* Do long multiplication */`
			`ULARGE_INTEGER p0;`
			`DWORD p1;`
			`p0.QuadPart = UInt32x32To64(ua.LowPart, ub);`

			`if (ua.HighPart != 0) {`
			`ULARGE_INTEGER x;`
			`x.QuadPart = UInt32x32To64(ua.HighPart, ub) + p0.HighPart;`
			`p0.HighPart = x.LowPart;`
			`p1 = x.HighPart;`
			`} else {`
			`p1 = 0;`
			`}`

			`if (d != 0) {`
			`ULARGE_INTEGER ud0;`
			`DWORD ud1;`

			`if (bSign) {`
			`//`
			`// Cast d to LONGLONG first otherwise -0x80000000 sign extends`
			`// incorrectly`
			`//`
			`ud0.QuadPart = (DWORDLONG)(-(LONGLONG)d);`
			`if (d > 0) {`
			`/* -d < 0 */`
			`ud1 = (DWORD)-1;`
			`} else {`
			`ud1 = (DWORD)0;`
			`}`
			`} else {`
			`ud0.QuadPart = (DWORDLONG)d;`
			`if (d < 0) {`
			`ud1 = (DWORD)-1;`
			`} else {`
			`ud1 = (DWORD)0;`
			`}`
			`}`
			`/* Now do extended addition */`
			`ULARGE_INTEGER uliTotal;`

			`/* Add ls DWORDs */`
			`uliTotal.QuadPart = (DWORDLONG)ud0.LowPart + p0.LowPart;`
			`p0.LowPart = uliTotal.LowPart;`

			`/* Propagate carry */`
			`uliTotal.LowPart = uliTotal.HighPart;`
			`uliTotal.HighPart = 0;`

			`/* Add 2nd most ls DWORDs */`
			`uliTotal.QuadPart += (DWORDLONG)ud0.HighPart + p0.HighPart;`
			`p0.HighPart = uliTotal.LowPart;`

			`/* Add MS DWORDLONGs - no carry expected */`
			`p1 += ud1 + uliTotal.HighPart;`

			`/* Now see if we got a sign change from the addition */`
			`if ((LONG)p1 < 0) {`
			`bSign = !bSign;`

			`/* Negate the current value (ugh!) */`
			`p0.QuadPart = ~p0.QuadPart;`
			`p1 = ~p1;`
			`p0.QuadPart += 1;`
			`p1 += (p0.QuadPart == 0);`
			`}`
			`}`

			`/* Now for the division */`
			`if (c < 0) {`
			`bSign = !bSign;`
			`}`


			`/* This will catch c == 0 and overflow */`
			`if (uc <= p1) {`
			`return bSign ? (LONGLONG)0x8000000000000000 :`
			`(LONGLONG)0x7FFFFFFFFFFFFFFF;`
			`}`

			`/* Do the division */`

			`/* If the divisor is a DWORD then its simpler */`
			`ULARGE_INTEGER uliDividend;`
			`ULARGE_INTEGER uliResult;`
			`DWORD dwDivisor = uc;`
			`uliDividend.HighPart = p1;`
			`uliDividend.LowPart = p0.HighPart;`
			`/* NOTE - this routine will take exceptions if`
			`the result does not fit in a DWORD`
			`*/`
			`if (uliDividend.QuadPart >= (DWORDLONG)dwDivisor) {`
			`uliResult.HighPart = EnlargedUnsignedDivide(`
			`uliDividend,`
			`dwDivisor,`
			`&p0.HighPart);`
			`} else {`
			`uliResult.HighPart = 0;`
			`}`
			`uliResult.LowPart = EnlargedUnsignedDivide(`
			`p0,`
			`dwDivisor,`
			`NULL);`
			`return bSign ? -(LONGLONG)uliResult.QuadPart :`
			`(LONGLONG)uliResult.QuadPart;`
			`}`

			`#endif /* PJMEDIA_VIDEO_DEV_HAS_DSHOW */`