コード例 #1
0
int main(void)
{
	unsigned long i,j,k;
	float **a,**aa,*ax,*b,*x;

	a=matrix(1,NP,1,MP);
	aa=matrix(1,NP,1,NP);
	ax=vector(1,NP);
	b=vector(1,NP);
	x=vector(1,NP);
	for (i=1;i<=M1;i++) for (j=1;j<=NP;j++) a[j][i]=10.0*j+i;
	/* Lower band */
	for (i=1;i<=NP;i++) a[i][M1+1]=i;
	/* Diagonal */
	for (i=1;i<=M2;i++) for (j=1;j<=NP;j++) a[j][M1+1+i]=0.1*j+i;
	/* Upper band */
	for (i=1;i<=NP;i++) {
		for (j=1;j<=NP;j++) {
			k=i-M1-1;
			if (j>=LMAX(1,1+k) && j<=LMIN(M1+M2+1+k,NP))
			aa[i][j]=a[i][j-k];
			else aa[i][j]=0.0;
		}
	}
	for (i=1;i<=NP;i++) x[i]=i/10.0;
	banmul(a,NP,M1,M2,x,b);
	for (i=1;i<=NP;i++) {
		for (ax[i]=0.0,j=1;j<=NP;j++) ax[i] += aa[i][j]*x[j];
	}
	printf("\tReference vector\tbanmul vector\n");
	for (i=1;i<=NP;i++) printf("\t%12.4f\t%12.4f\n",ax[i],b[i]);
	free_vector(x,1,NP);
	free_vector(b,1,NP);
	free_vector(ax,1,NP);
	free_matrix(aa,1,NP,1,NP);
	free_matrix(a,1,NP,1,MP);
	return 0;
}
コード例 #2
0
ファイル: xrdp_pcsc.c プロジェクト: 340211173/xrdp
PCSC_API LONG
SCardGetStatusChange(SCARDCONTEXT hContext, DWORD dwTimeout,
                     LPSCARD_READERSTATE rgReaderStates, DWORD cReaders)
{
    char *msg;
    const char *rname;
    int bytes;
    int code;
    int index;
    int offset;
    int str_len;
    int status;
    int dwCurrentState;
    int dwEventState;
    int cbAtr;
    char atr[36];

    LLOGLN(10, ("SCardGetStatusChange:"));
    LLOGLN(10, ("  dwTimeout %d cReaders %d", (int)dwTimeout, (int)cReaders));
    if (g_sck == -1)
    {
        LLOGLN(0, ("SCardGetStatusChange: error, not connected"));
        return SCARD_F_INTERNAL_ERROR;
    }
    msg = (char *) malloc(8192);
    SET_UINT32(msg, 0, hContext);
    SET_UINT32(msg, 4, dwTimeout);
    SET_UINT32(msg, 8, cReaders);
    offset = 12;
    for (index = 0; index < cReaders; index++)
    {
        rgReaderStates[index].dwCurrentState &= ~2;
        rgReaderStates[index].dwEventState &= ~2;
        rname = rgReaderStates[index].szReader;
        if (strcmp(rname, "\\\\?PnP?\\Notification") == 0)
        {
            LLOGLN(10, ("  \\\\?PnP?\\Notification present"));
            dwCurrentState = 0;
            dwEventState = 0;
            cbAtr = 0;
            memset(atr, 0, 36);
        }
        else
        {
            dwCurrentState = rgReaderStates[index].dwCurrentState;
            dwEventState = rgReaderStates[index].dwEventState;
            cbAtr = rgReaderStates[index].cbAtr;
            memset(atr, 0, 36);
            memcpy(atr, rgReaderStates[index].rgbAtr, 33);
        }
        str_len = strlen(rname);
        str_len = LMIN(str_len, 99);
        memset(msg + offset, 0, 100);
        memcpy(msg + offset, rname, str_len);
        LLOGLN(10, ("  in szReader       %s", rname));
        offset += 100;
        LLOGLN(10, ("  in dwCurrentState 0x%8.8x", dwCurrentState));
        SET_UINT32(msg, offset, dwCurrentState);
        offset += 4;
        LLOGLN(10, ("  in dwEventState   0x%8.8x", dwEventState));
        SET_UINT32(msg, offset, dwEventState);
        offset += 4;
        LLOGLN(10, ("  in cbAtr          %d", cbAtr));
        SET_UINT32(msg, offset, cbAtr);
        offset += 4;
        memcpy(msg + offset, atr, 36);
        offset += 36;
    }
    if (send_message(SCARD_GET_STATUS_CHANGE, msg, offset) != 0)
    {
        LLOGLN(0, ("SCardGetStatusChange: error, send_message"));
        free(msg);
        return SCARD_F_INTERNAL_ERROR;
    }
    bytes = 8192;
    code = SCARD_GET_STATUS_CHANGE;
    if (get_message(&code, msg, &bytes) != 0)
    {
        LLOGLN(0, ("SCardGetStatusChange: error, get_message"));
        free(msg);
        return SCARD_F_INTERNAL_ERROR;
    }
    if (code != SCARD_GET_STATUS_CHANGE)
    {
        LLOGLN(0, ("SCardGetStatusChange: error, bad code"));
        free(msg);
        return SCARD_F_INTERNAL_ERROR;
    }
    cReaders = GET_UINT32(msg, 0);
    offset = 4;
    LLOGLN(10, ("SCardGetStatusChange: got back cReaders %d", (int)cReaders));
    for (index = 0; index < cReaders; index++)
    {
        rname = rgReaderStates[index].szReader;
#if 1
        if (strcmp(rname, "\\\\?PnP?\\Notification") == 0)
        {
            LLOGLN(10, ("  out szReader       %s", rgReaderStates[index].szReader));
            dwCurrentState = GET_UINT32(msg, offset);
            rgReaderStates[index].dwCurrentState = dwCurrentState;
            offset += 4;
            LLOGLN(10, ("  out dwCurrentState 0x%8.8x", dwCurrentState));
            // disable PnP for now
            dwEventState = 4; // GET_UINT32(msg, offset);
            rgReaderStates[index].dwEventState = dwEventState;
            offset += 4;
            LLOGLN(10, ("  out dwEventState   0x%8.8x", dwEventState));
            cbAtr = GET_UINT32(msg, offset);
            rgReaderStates[index].cbAtr = cbAtr;
            offset += 4;
            LLOGLN(10, ("  out cbAtr          %d", cbAtr));
            memcpy(rgReaderStates[index].rgbAtr, msg + offset, 33);
            offset += 36;
        }
        else
#endif
        {
            LLOGLN(10, ("  out szReader       %s", rgReaderStates[index].szReader));
            dwCurrentState = GET_UINT32(msg, offset);
            rgReaderStates[index].dwCurrentState = dwCurrentState;
            offset += 4;
            LLOGLN(10, ("  out dwCurrentState 0x%8.8x", dwCurrentState));
            dwEventState = GET_UINT32(msg, offset);
            rgReaderStates[index].dwEventState = dwEventState;
            offset += 4;
            LLOGLN(10, ("  out dwEventState   0x%8.8x", dwEventState));
            cbAtr = GET_UINT32(msg, offset);
            rgReaderStates[index].cbAtr = cbAtr;
            offset += 4;
            LLOGLN(10, ("  out cbAtr          %d", cbAtr));
            memcpy(rgReaderStates[index].rgbAtr, msg + offset, 33);
            offset += 36;
        }
    }
    status = GET_UINT32(msg, offset);
    offset += 4;
    free(msg);
    return status;
}
コード例 #3
0
/* we have 3 differents structures to update:
 * the first is the real representation of the datatype
 * the second is the internal representation using extents
 * the last is the representation used for send operations
 * If the count is ZERO we dont have to add the pdtAdd datatype. But we have to
 * be sure that the pdtBase datatype is correctly initialized with all fields
 * set to ZERO if it's a empty datatype.
 */
int32_t opal_datatype_add( opal_datatype_t* pdtBase, const opal_datatype_t* pdtAdd,
                           uint32_t count, OPAL_PTRDIFF_TYPE disp, OPAL_PTRDIFF_TYPE extent )
{
    uint32_t newLength, place_needed = 0, i;
    short localFlags = 0;  /* no specific options yet */
    dt_elem_desc_t *pLast, *pLoop = NULL;
    OPAL_PTRDIFF_TYPE lb, ub, true_lb, true_ub, epsilon, old_true_ub;

    /* the extent should always be positive. So a negative
     * value here have a special meaning ie. default extent as
     * computed by ub - lb
     */
    if( extent == -1 ) extent = (pdtAdd->ub - pdtAdd->lb);

    /* Deal with the special markers (OPAL_DATATYPE_LB and OPAL_DATATYPE_UB) */
    if( OPAL_DATATYPE_LB == pdtAdd->id ) {
        pdtBase->bdt_used |= (((uint32_t)1) << OPAL_DATATYPE_LB);
        if( pdtBase->flags & OPAL_DATATYPE_FLAG_USER_LB ) {
            pdtBase->lb = LMIN( pdtBase->lb, disp );
        } else {
            pdtBase->lb = disp;
            pdtBase->flags |= OPAL_DATATYPE_FLAG_USER_LB;
        }
        if( (pdtBase->ub - pdtBase->lb) != (OPAL_PTRDIFF_TYPE)pdtBase->size ) {
            pdtBase->flags &= ~OPAL_DATATYPE_FLAG_NO_GAPS;
        }
        return OPAL_SUCCESS; /* Just ignore the OPAL_DATATYPE_LOOP and OPAL_DATATYPE_END_LOOP */
    } else if( OPAL_DATATYPE_UB == pdtAdd->id ) {
        pdtBase->bdt_used |= (((uint32_t)1) << OPAL_DATATYPE_UB);
        if( pdtBase->flags & OPAL_DATATYPE_FLAG_USER_UB ) {
            pdtBase->ub = LMAX( pdtBase->ub, disp );
        } else {
            pdtBase->ub = disp;
            pdtBase->flags |= OPAL_DATATYPE_FLAG_USER_UB;
        }
        if( (pdtBase->ub - pdtBase->lb) != (OPAL_PTRDIFF_TYPE)pdtBase->size ) {
            pdtBase->flags &= ~OPAL_DATATYPE_FLAG_NO_GAPS;
        }
        return OPAL_SUCCESS; /* Just ignore the OPAL_DATATYPE_LOOP and OPAL_DATATYPE_END_LOOP */
    }

    /* Compute the number of entries we need in the datatype description */
    OPAL_DATATYPE_COMPUTE_REQUIRED_ENTRIES( pdtAdd, count, extent, place_needed );

    /*
     * Compute the lower and upper bound of the datatype. We do it in 2 steps.
     * First compute the lb and ub of the new datatype taking in account the
     * count. Then update the lb value depending on the user markers and
     * update the global lb and ub.
     */
    OPAL_DATATYPE_LB_UB_CONT( count, disp, pdtAdd->lb, pdtAdd->ub, extent, lb, ub );

    /* Compute the true_lb and true_ub for the datatype to be added, taking
     * in account the number of repetions. These values do not include the
     * potential gaps at the begining and at the end of the datatype.
     */
    true_lb = lb - (pdtAdd->lb - pdtAdd->true_lb);
    true_ub = ub - (pdtAdd->ub - pdtAdd->true_ub);
    if( true_lb > true_ub ) {
        old_true_ub = true_lb;
        true_lb = true_ub;
        true_ub = old_true_ub;
    }

#if 0
    /* Avoid claiming overlap as much as possible. */
    if( !(pdtBase->flags & OPAL_DATATYPE_FLAG_OVERLAP) ) {
        if( ((disp + true_lb) >= pdtBase->true_ub) ||
                ((disp + true_ub) <= pdtBase->true_lb) ) {
        } else {
            /* potential overlap */
        }
    }
#endif

    /* The lower bound should be inherited from the parent if and only
     * if the USER has explicitly set it. The result lb is the MIN between
     * the all lb + disp if and only if all or nobody flags's contain the LB.
     */
    if( (pdtAdd->flags ^ pdtBase->flags) & OPAL_DATATYPE_FLAG_USER_LB ) {
        if( pdtBase->flags & OPAL_DATATYPE_FLAG_USER_LB ) {
            lb = pdtBase->lb;  /* base type has a user provided lb */
        }
        pdtBase->flags |= OPAL_DATATYPE_FLAG_USER_LB;
    } else {
        /* both of them have the LB flag or both of them dont have it */
        lb = LMIN( pdtBase->lb, lb );
    }

    /* the same apply for the upper bound except for the case where
     * either of them has the flag UB, in which case we should
     * compute the UB including the natural alignement of the data.
     */
    if( (pdtBase->flags ^ pdtAdd->flags) & OPAL_DATATYPE_FLAG_USER_UB ) {
        if( pdtBase->flags & OPAL_DATATYPE_FLAG_USER_UB ) {
            ub = pdtBase->ub;
        }
        pdtBase->flags |= OPAL_DATATYPE_FLAG_USER_UB;
    } else {
        /* both of them have the UB flag or both of them dont have it */
        /* we should compute the extent depending on the alignement */
        ub = LMAX( pdtBase->ub, ub );
    }
    /* While the true_lb and true_ub have to be ordered to have the true_lb lower
     * than the true_ub, the ub and lb do not have to be ordered. They should be
     * as the user define them.
     */
    pdtBase->lb = lb;
    pdtBase->ub = ub;

    /* compute the new memory alignement */
    pdtBase->align = IMAX( pdtBase->align, pdtAdd->align );

    /* Now that we have the new ub and the alignment we should update the ub to match
     * the new alignement. We have to add an epsilon that is the least nonnegative
     * increment needed to roung the extent to the next multiple of the alignment.
     * This rule apply only if there is user specified upper bound as stated in the
     * MPI standard MPI 1.2 page 71.
     */
    if( !(pdtBase->flags & OPAL_DATATYPE_FLAG_USER_UB) ) {
        epsilon = (pdtBase->ub - pdtBase->lb) % pdtBase->align;
        if( 0 != epsilon ) {
            pdtBase->ub += (pdtBase->align - epsilon);
        }
    }
    /* now we know it contain some data */
    pdtBase->flags |= OPAL_DATATYPE_FLAG_DATA;

    /*
     * the count == 0 is LEGAL only for MPI_UB and MPI_LB. Therefore we support it
     * here in the upper part of this function. As an extension, the count set to
     * zero can be used to reset the alignment of the data, but not for changing
     * the true_lb and true_ub.
     */
    if( (0 == count) || (0 == pdtAdd->size) ) {
        return OPAL_SUCCESS;
    }

    /* Now, once we know everything is fine and there are some bytes in
     * the data-type we can update the size, true_lb and true_ub.
     */
    pdtBase->size += count * pdtAdd->size;
    if( 0 == pdtBase->nbElems ) old_true_ub = disp;
    else                        old_true_ub = pdtBase->true_ub;
    if( 0 != pdtBase->size ) {
        pdtBase->true_lb = LMIN( true_lb, pdtBase->true_lb );
        pdtBase->true_ub = LMAX( true_ub, pdtBase->true_ub );
    } else {
        pdtBase->true_lb = true_lb;
        pdtBase->true_ub = true_ub;
    }

    pdtBase->bdt_used |= pdtAdd->bdt_used;
    newLength = pdtBase->desc.used + place_needed;
    if( newLength > pdtBase->desc.length ) {
        newLength = ((newLength / DT_INCREASE_STACK) + 1 ) * DT_INCREASE_STACK;
        pdtBase->desc.desc   = (dt_elem_desc_t*)realloc( pdtBase->desc.desc,
                               sizeof(dt_elem_desc_t) * newLength );
        pdtBase->desc.length = newLength;
    }
    pLast = &(pdtBase->desc.desc[pdtBase->desc.used]);
    /* The condition to be able to use the optimized path here is to be in presence
     * of an predefined contiguous datatype. This part is unable to handle any
     * predefined non contiguous datatypes (like MPI_SHORT_INT).
     */
    if( (pdtAdd->flags & (OPAL_DATATYPE_FLAG_PREDEFINED | OPAL_DATATYPE_FLAG_DATA)) == (OPAL_DATATYPE_FLAG_PREDEFINED | OPAL_DATATYPE_FLAG_DATA) ) {
        pdtBase->btypes[pdtAdd->id] += count;
        if( (extent != (OPAL_PTRDIFF_TYPE)pdtAdd->size) && (count > 1) ) {  /* gaps around the datatype */
            localFlags = pdtAdd->flags & ~(OPAL_DATATYPE_FLAG_COMMITED | OPAL_DATATYPE_FLAG_CONTIGUOUS | OPAL_DATATYPE_FLAG_NO_GAPS);
            CREATE_LOOP_START( pLast, count, 2, extent, localFlags );
            pLast++;
            pLast->elem.common.type  = pdtAdd->id;
            pLast->elem.count        = 1;
            pLast->elem.disp         = disp;
            pLast->elem.extent       = pdtAdd->size;
            pLast->elem.common.flags = localFlags | OPAL_DATATYPE_FLAG_CONTIGUOUS;
            pLast++;
            CREATE_LOOP_END( pLast, 2, disp, pdtAdd->size, localFlags );
            pdtBase->desc.used += 3;
            pdtBase->btypes[OPAL_DATATYPE_LOOP]     = 1;
            pdtBase->btypes[OPAL_DATATYPE_END_LOOP] = 1;
        } else {
            pLast->elem.common.type = pdtAdd->id;
            pLast->elem.count       = count;
            pLast->elem.disp        = disp;
            pLast->elem.extent      = extent;
            pdtBase->desc.used++;
            pLast->elem.common.flags  = pdtAdd->flags & ~(OPAL_DATATYPE_FLAG_COMMITED);
        }
    } else {
        /* keep trace of the total number of basic datatypes in the datatype definition */
        pdtBase->btypes[OPAL_DATATYPE_LOOP]     += pdtAdd->btypes[OPAL_DATATYPE_LOOP];
        pdtBase->btypes[OPAL_DATATYPE_END_LOOP] += pdtAdd->btypes[OPAL_DATATYPE_END_LOOP];
        pdtBase->btypes[OPAL_DATATYPE_LB]       |= pdtAdd->btypes[OPAL_DATATYPE_LB];
        pdtBase->btypes[OPAL_DATATYPE_UB]       |= pdtAdd->btypes[OPAL_DATATYPE_UB];
        for( i = 4; i < OPAL_DATATYPE_MAX_PREDEFINED; i++ )
            if( pdtAdd->btypes[i] != 0 ) pdtBase->btypes[i] += (count * pdtAdd->btypes[i]);

        if( (1 == pdtAdd->desc.used) && (extent == (pdtAdd->ub - pdtAdd->lb)) &&
                (extent == pdtAdd->desc.desc[0].elem.extent) ) {
            pLast->elem        = pdtAdd->desc.desc[0].elem;
            pLast->elem.count *= count;
            pLast->elem.disp  += disp;
            pdtBase->desc.used++;
        } else {
            /* if the extent of the datatype is the same as the extent of the loop
             * description of the datatype then we simply have to update the main loop.
             */
            if( count != 1 ) {
                pLoop = pLast;
                CREATE_LOOP_START( pLast, count, pdtAdd->desc.used + 1, extent,
                                   (pdtAdd->flags & ~(OPAL_DATATYPE_FLAG_COMMITED)) );
                pdtBase->btypes[OPAL_DATATYPE_LOOP] += 2;
                pdtBase->desc.used += 2;
                pLast++;
            }

            for( i = 0; i < pdtAdd->desc.used; i++ ) {
                pLast->elem               = pdtAdd->desc.desc[i].elem;
                if( OPAL_DATATYPE_FLAG_DATA & pLast->elem.common.flags )
                    pLast->elem.disp += disp;
                else if( OPAL_DATATYPE_END_LOOP == pLast->elem.common.type ) {
                    pLast->end_loop.first_elem_disp += disp;
                }
                pLast++;
            }
            pdtBase->desc.used += pdtAdd->desc.used;
            if( pLoop != NULL ) {
                int index = GET_FIRST_NON_LOOP( pLoop );
                assert( pLoop[index].elem.common.flags & OPAL_DATATYPE_FLAG_DATA );
                CREATE_LOOP_END( pLast, pdtAdd->desc.used + 1, pLoop[index].elem.disp,
                                 pdtAdd->size, pLoop->loop.common.flags );
            }
        }
        /* should I add some space until the extent of this datatype ? */
    }

    /* Is the data still contiguous ?
     * The only way for the data to be contiguous is to have the true extent
     * equal to his size. In other words to avoid having internal gaps between
     * elements. If any of the data are overlapping then this method will not work.
     */
    localFlags = pdtBase->flags & pdtAdd->flags;
    UNSET_CONTIGUOUS_FLAG(pdtBase->flags);
    if( (localFlags & OPAL_DATATYPE_FLAG_CONTIGUOUS)             /* both type were contiguous */
            && ((disp + pdtAdd->true_lb) == old_true_ub)  /* and there is no gap between them */
            && ( ((OPAL_PTRDIFF_TYPE)pdtAdd->size == extent)      /* the size and the extent of the
                                                       * added type have to match */
                 || (count < 2)) ) {                      /* if the count is bigger than 2 */
        SET_CONTIGUOUS_FLAG(pdtBase->flags);
        if( (OPAL_PTRDIFF_TYPE)pdtBase->size == (pdtBase->ub - pdtBase->lb) )
            SET_NO_GAP_FLAG(pdtBase->flags);
    }

    /* If the NO_GAP flag is set the contiguous have to be set too */
    if( pdtBase->flags & OPAL_DATATYPE_FLAG_NO_GAPS ) {
        assert( pdtBase->flags & OPAL_DATATYPE_FLAG_CONTIGUOUS );
    }
    pdtBase->nbElems += (count * pdtAdd->nbElems);

    return OPAL_SUCCESS;
}
コード例 #4
0
ファイル: dt_add.c プロジェクト: meghnave/SpherePacking
/* we have 3 differents structures to update:
 * the first is the real representation of the datatype
 * the second is the internal representation using extents
 * the last is the representation used for send operations
 * If the count is ZERO we dont have to add the pdtAdd datatype. But we have to
 * be sure that the pdtBase datatype is correctly initialized with all fields
 * set to ZERO if it's a empty datatype.
 */
int32_t ompi_ddt_add( ompi_datatype_t* pdtBase, const ompi_datatype_t* pdtAdd,
                      uint32_t count, ptrdiff_t disp, ptrdiff_t extent )
{
    uint32_t newLength, place_needed = 0, i;
    short localFlags = 0;  /* no specific options yet */
    dt_elem_desc_t *pLast, *pLoop = NULL;
    ptrdiff_t lb, ub, true_lb, true_ub, epsilon, old_true_ub;

    /* the extent should always be positive. So a negative
     * value here have a special meaning ie. default extent as
     * computed by ub - lb
     */
    if( extent == -1 ) extent = (pdtAdd->ub - pdtAdd->lb);

    if( pdtAdd->flags & DT_FLAG_PREDEFINED ) { /* add a basic datatype */
        /* handle special cases for DT_LB and DT_UB */
        if( pdtAdd == ompi_ddt_basicDatatypes[DT_LB] ) {
            pdtBase->bdt_used |= (((uint64_t)1) << DT_LB);
            if( pdtBase->flags & DT_FLAG_USER_LB ) {
                pdtBase->lb = LMIN( pdtBase->lb, disp );
            } else {
                pdtBase->lb = disp;
                pdtBase->flags |= DT_FLAG_USER_LB;
            }
            if( (pdtBase->ub - pdtBase->lb) != (ptrdiff_t)pdtBase->size ) {
                pdtBase->flags &= ~DT_FLAG_NO_GAPS;
            }
            return OMPI_SUCCESS;
        } else if( pdtAdd == ompi_ddt_basicDatatypes[DT_UB] ) {
            pdtBase->bdt_used |= (((uint64_t)1) << DT_UB);
            if( pdtBase->flags & DT_FLAG_USER_UB ) {
                pdtBase->ub = LMAX( pdtBase->ub, disp );
            } else {
                pdtBase->ub = disp;
                pdtBase->flags |= DT_FLAG_USER_UB;
            }
            if( (pdtBase->ub - pdtBase->lb) != (ptrdiff_t)pdtBase->size ) {
                pdtBase->flags &= ~DT_FLAG_NO_GAPS;
            }
            return OMPI_SUCCESS;
        }
        place_needed = (extent == (ptrdiff_t)pdtAdd->size ? 1 : 3);
    } else {
        place_needed = pdtAdd->desc.used;
        if( count != 1 ) place_needed += 2;  /* for the loop markers */
    }

    /*
     * Compute the lower and upper bound of the datatype. We do it in 2 steps.
     * First compute the lb and ub of the new datatype taking in account the
     * count. Then update the lb value depending on the user markers and
     * update the global lb and ub.
     */
    OMPI_DDT_LB_UB_CONT( count, disp, pdtAdd->lb, pdtAdd->ub, extent, lb, ub );
    /* The true_lb and true_ub take in account the gaps at the begining and the
     * end of the datatype independing on the number of repetitions of the datatype.
     */
    true_lb = lb - (pdtAdd->lb - pdtAdd->true_lb);
    true_ub = ub - (pdtAdd->ub - pdtAdd->true_ub);
    if( true_lb > true_ub ) {
        old_true_ub = true_lb;
        true_lb = true_ub;
        true_ub = old_true_ub;
    }

    /* the lower bound should be inherited from the parent if and only
     * if the USER has explicitly set it. The result lb is the MIN between
     * the all lb + disp if and only if all or nobody flags's contain the LB.
     */
    if( (pdtAdd->flags ^ pdtBase->flags) & DT_FLAG_USER_LB ) {
        if( pdtBase->flags & DT_FLAG_USER_LB ) {
            lb = pdtBase->lb;  /* base type has a user provided lb */
        }
        pdtBase->flags |= DT_FLAG_USER_LB;
    } else {
        /* both of them have the LB flag or both of them dont have it */
        lb = LMIN( pdtBase->lb, lb );
    }

    /* the same apply for the upper bound except for the case where
     * either of them has the flag UB, in which case we should
     * compute the UB including the natural alignement of the data.
     */
    if( (pdtBase->flags ^ pdtAdd->flags) & DT_FLAG_USER_UB ) {
        if( pdtBase->flags & DT_FLAG_USER_UB ) {
            ub = pdtBase->ub;
        }
        pdtBase->flags |= DT_FLAG_USER_UB;
    } else {
        /* both of them have the UB flag or both of them dont have it */
        /* we should compute the extent depending on the alignement */
        ub = LMAX( pdtBase->ub, ub );
    }
    /* While the true_lb and true_ub have to be ordered to have the true_lb lower
     * than the true_ub, the ub and lb does not have to be ordered. They should be
     * as the user define them.
     */
    pdtBase->lb = lb;
    pdtBase->ub = ub;

    if( 0 == pdtBase->nbElems ) old_true_ub = disp;
    else                        old_true_ub = pdtBase->true_ub;
    pdtBase->true_lb = LMIN( true_lb, pdtBase->true_lb );
    pdtBase->true_ub = LMAX( true_ub, pdtBase->true_ub );

    /* compute the new memory alignement */
    pdtBase->align = IMAX( pdtBase->align, pdtAdd->align );
    pdtBase->size += count * pdtAdd->size;

    /* Now that we have the new ub and the alignment we should update the ub to match
     * the new alignement. We have to add an epsilon that is the least nonnegative increment
     * needed to roung the extent to the next multiple of the alignment. This rule
     * apply only if there is user specified upper bound as stated in the MPI
     * standard MPI 1.2 page 71.
     */
    if( !(pdtBase->flags & DT_FLAG_USER_UB) ) {
        epsilon = (pdtBase->ub - pdtBase->lb) % pdtBase->align;
        if( 0 != epsilon ) {
            pdtBase->ub += (pdtBase->align - epsilon);
        }
    }

    /*
     * the count == 0 is LEGAL only for MPI_UB and MPI_LB. I accept it just as a nice way to set
     * the soft UB for a data (without using a real UB marker). This approach can be used to
     * create the subarray and darray datatype. However from the MPI level this function
     * should never be called directly with a count set to 0.
     * Adding a data-type with a size zero is legal but does not have to go through all the
     * stuff below.
     */
    if( (0 == count) || (0 == pdtAdd->size) ) {
        return OMPI_SUCCESS;
    }

    pdtBase->bdt_used |= pdtAdd->bdt_used;
    newLength = pdtBase->desc.used + place_needed;
    if( newLength > pdtBase->desc.length ) {
        newLength = ((newLength / DT_INCREASE_STACK) + 1 ) * DT_INCREASE_STACK;
        pdtBase->desc.desc   = (dt_elem_desc_t*)realloc( pdtBase->desc.desc,
                                                         sizeof(dt_elem_desc_t) * newLength );
        pdtBase->desc.length = newLength;
    }
    pLast = &(pdtBase->desc.desc[pdtBase->desc.used]);
    /* The condition to be able to use the optimized path here is to be in presence
     * of an predefined contiguous datatype. This part is unable to handle any
     * predefined non contiguous datatypes (like MPI_SHORT_INT).
     */
    if( (pdtAdd->flags & (DT_FLAG_PREDEFINED | DT_FLAG_DATA)) == (DT_FLAG_PREDEFINED | DT_FLAG_DATA) ) {
        pdtBase->btypes[pdtAdd->id] += count;
        if( (extent != (ptrdiff_t)pdtAdd->size) && (count > 1) ) {  /* gaps around the datatype */
            localFlags = pdtAdd->flags & ~(DT_FLAG_COMMITED | DT_FLAG_CONTIGUOUS | DT_FLAG_NO_GAPS);
            CREATE_LOOP_START( pLast, count, 2, extent, localFlags );
            pLast++;
            pLast->elem.common.type  = pdtAdd->id;
            pLast->elem.count        = 1;
            pLast->elem.disp         = disp;
            pLast->elem.extent       = pdtAdd->size;
            pLast->elem.common.flags = localFlags | DT_FLAG_CONTIGUOUS;
            pLast++;
            CREATE_LOOP_END( pLast, 2, disp, pdtAdd->size, localFlags );
            pdtBase->desc.used += 3;
            pdtBase->btypes[DT_LOOP]     = 1;
            pdtBase->btypes[DT_END_LOOP] = 1;
        } else {
            pLast->elem.common.type = pdtAdd->id;
            pLast->elem.count       = count;
            pLast->elem.disp        = disp;
            pLast->elem.extent      = extent;
            pdtBase->desc.used++;
            pLast->elem.common.flags  = pdtAdd->flags & ~(DT_FLAG_COMMITED);
        }
    } else {
        /* keep trace of the total number of basic datatypes in the datatype definition */
        pdtBase->btypes[DT_LOOP]     += pdtAdd->btypes[DT_LOOP];
        pdtBase->btypes[DT_END_LOOP] += pdtAdd->btypes[DT_END_LOOP];
        pdtBase->btypes[DT_LB]       |= pdtAdd->btypes[DT_LB];
        pdtBase->btypes[DT_UB]       |= pdtAdd->btypes[DT_UB];
        for( i = 4; i < DT_MAX_PREDEFINED; i++ )
            if( pdtAdd->btypes[i] != 0 ) pdtBase->btypes[i] += (count * pdtAdd->btypes[i]);

        if( (1 == pdtAdd->desc.used) && (extent == (pdtAdd->ub - pdtAdd->lb)) &&
            (extent == pdtAdd->desc.desc[0].elem.extent) ){
            pLast->elem        = pdtAdd->desc.desc[0].elem;
            pLast->elem.count *= count;
            pLast->elem.disp  += disp;
            pdtBase->desc.used++;
        } else {
            /* if the extent of the datatype is the same as the extent of the loop
             * description of the datatype then we simply have to update the main loop.
             */
            if( count != 1 ) {
                pLoop = pLast;
                CREATE_LOOP_START( pLast, count, pdtAdd->desc.used + 1, extent,
                                   (pdtAdd->flags & ~(DT_FLAG_COMMITED)) );
                pdtBase->btypes[DT_LOOP] += 2;
                pdtBase->desc.used += 2;
                pLast++;
            }

            for( i = 0; i < pdtAdd->desc.used; i++ ) {
                pLast->elem               = pdtAdd->desc.desc[i].elem;
                if( DT_FLAG_DATA & pLast->elem.common.flags )
                    pLast->elem.disp += disp;
                else if( DT_END_LOOP == pLast->elem.common.type ) {
                    pLast->end_loop.first_elem_disp += disp;
                }
                pLast++;
            }
            pdtBase->desc.used += pdtAdd->desc.used;
            if( pLoop != NULL ) {
                int index = GET_FIRST_NON_LOOP( pLoop );
                assert( pLoop[index].elem.common.flags & DT_FLAG_DATA );
                CREATE_LOOP_END( pLast, pdtAdd->desc.used + 1, pLoop[index].elem.disp,
                                 pdtAdd->size, pLoop->loop.common.flags );
            }
        }
        /* should I add some space until the extent of this datatype ? */
    }

    /* Is the data still contiguous ?
     * The only way for the data to be contiguous is to have the true extent
     * equal to his size. In other words to avoid having internal gaps between
     * elements. If any of the data are overlapping then this method will not work.
     */
    localFlags = pdtBase->flags & pdtAdd->flags;
    UNSET_CONTIGUOUS_FLAG(pdtBase->flags);
    if( disp != old_true_ub ) { /* is there a gap between the 2 datatypes ? */
        if( disp < old_true_ub ) pdtBase->flags |= DT_FLAG_OVERLAP;
    } else {
        if( (localFlags & DT_FLAG_CONTIGUOUS)        /* both have to be contiguous */
            && ( ((ptrdiff_t)pdtAdd->size == extent) /* the size and the extent of the
                                                      * added type have to match */
                 || (count < 2)) ) {                 /* if the count is bigger than 2 */
            SET_CONTIGUOUS_FLAG(pdtBase->flags);
            if( (ptrdiff_t)pdtBase->size == (pdtBase->ub - pdtBase->lb) )
                SET_NO_GAP_FLAG(pdtBase->flags);
        }
    }
    /* If the NO_GAP flag is set the contiguous have to be set too */
    if( pdtBase->flags & DT_FLAG_NO_GAPS ) {
        assert( pdtBase->flags & DT_FLAG_CONTIGUOUS );
    }
    pdtBase->nbElems += (count * pdtAdd->nbElems);

    return OMPI_SUCCESS;
}