Exemplo n.º 1
0
/* ------------------------------------------------------------------
 * Perform action corresponding to the first async event that
 * was logged.
 * ------------------------------------------------------------------
 */
void async_action(bool lnfetch_or_start)
{
	/* Double-check that we should be here: */
	assert(0 < num_deferred);

	switch(first_event)
	{
		case (outofband_event):
			/* This function can be invoked only by a op_*intrrpt* transfer table function. Those transfer table
			 * functions should be active only for a short duration between the occurrence of an outofband event
			 * and the handling of it at a logical boundary (next M-line). We dont expect to be running with
			 * those transfer table functions for more than one M-line. If "outofband" is set to 0, the call to
			 * "outofband_action" below will do nothing and we will end up running with the op_*intrrpt* transfer
			 * table functions indefinitely. In this case M-FOR loops are known to return incorrect results which
			 * might lead to application integrity issues. It is therefore considered safer to GTMASSERT as we
			 * will at least have the core for analysis.
			 */
			assertpro(0 != outofband);
			outofband_action(lnfetch_or_start);
			break;
		case (tt_write_error_event):
#			ifdef UNIX
			xfer_reset_if_setter(tt_write_error_event);
			iott_wrterr();
#			endif
			/* VMS tt error processing is done in op_*intrrpt */
			break;
		case (network_error_event):
			/* -------------------------------------------------------
			 * Network error not implemented here yet. Need to move
			 * from mdb_condition_handler after review.
			 * -------------------------------------------------------
			 */
		case (zstp_or_zbrk_event):
			/* -------------------------------------------------------
			 * ZStep/Zbreak events not implemented here yet. Need to
			 * move here after review.
			 * -------------------------------------------------------
			 */
		default:
			assertpro(FALSE);	/* see above assertpro() for comment as to why this is needed */
	}
}
Exemplo n.º 2
0
void op_zprint(mval *rtn, mval *start_label, int start_int_exp, mval *end_label, int end_int_exp)
/* contains label to be located or null string		*/
/* contains label offset or line number to reference	*/
/* contains routine to look in or null string		*/
/* NOTE: If only the first label is specified, the 	*/
/*	 parser makes the second label the duplicate	*/
/*	 of the first. (not so vice versa)		*/
{
	mval	print_line, null_str;
	mstr	*src1, *src2;
	uint4	stat1, stat2;
	rhdtyp	*rtn_vector;
	error_def(ERR_FILENOTFND);
	error_def(ERR_TXTSRCMAT);
	error_def(ERR_ZPRTLABNOTFND);
	error_def(ERR_ZLINKFILE);
	error_def(ERR_ZLMODULE);

	MV_FORCE_STR(start_label);
	MV_FORCE_STR(end_label);
	MV_FORCE_STR(rtn);
	if (NULL == (rtn_vector = find_rtn_hdr(&rtn->str)))
	{
		op_zlink(rtn, NULL);
		rtn_vector = find_rtn_hdr(&rtn->str);
		if (NULL == rtn_vector)
			rts_error(VARLSTCNT(8) ERR_ZLINKFILE, 2, rtn->str.len, rtn->str.addr,
					ERR_ZLMODULE, 2, mid_len(&zlink_mname), &zlink_mname.c[0]);
	}
	stat1 = get_src_line(rtn, start_label, start_int_exp, &src1);
	if (stat1 & LABELNOTFOUND)
		rts_error(VARLSTCNT(1) ERR_ZPRTLABNOTFND);
	if (stat1 & SRCNOTFND)
		rts_error(VARLSTCNT(4) ERR_FILENOTFND, 2, rtn_vector->src_full_name.len, rtn_vector->src_full_name.addr);
	if (stat1 & (SRCNOTAVAIL | AFTERLASTLINE))
		return;
	if (stat1 & (ZEROLINE | NEGATIVELINE))
	{
		null_str.mvtype = MV_STR;
		null_str.str.len = 0;
		stat1 = get_src_line(rtn, &null_str, 1, &src1);
		if (stat1 & AFTERLASTLINE)		/* the "null" file */
			return;
	}
	if (end_int_exp == 0 && (end_label->str.len == 0 || *end_label->str.addr == 0))
		stat2 = AFTERLASTLINE;
	else if ((stat2 = get_src_line(rtn, end_label, end_int_exp, &src2)) & LABELNOTFOUND)
		rts_error(VARLSTCNT(1) ERR_ZPRTLABNOTFND);
	if (stat2 & (ZEROLINE | NEGATIVELINE))
		return;
	if (stat2 & AFTERLASTLINE)
	{
		null_str.mvtype = MV_STR;
		null_str.str.len = 0;
		stat2 = get_src_line(rtn, &null_str, 1, &src2);
		/* number of lines less one for duplicated zero'th line and one due
		   to termination condition being <=
		*/
		assert((INTPTR_T)src2 > 0);
		src2 += rtn_vector->lnrtab_len - 2;
	}
	if (stat1 & CHECKSUMFAIL)
	{
		rts_error(VARLSTCNT(1) INFO_MSK(ERR_TXTSRCMAT));
		op_wteol(1);
	}
	print_line.mvtype = MV_STR;
	for ( ; src1 <= src2 ; src1++)
	{
		if (outofband)
			outofband_action(FALSE);
		print_line.str.addr = src1->addr;
		print_line.str.len = src1->len;
		op_write(&print_line);
		op_wteol(1);
	}
	return;
}
Exemplo n.º 3
0
boolean_t iosocket_wait(io_desc *iod, int4 timepar)
{
	struct 	timeval  	utimeout;
	ABS_TIME		cur_time, end_time;
	struct 	sockaddr_storage    	peer;           /* socket address + port */
	fd_set    		tcp_fd;
	d_socket_struct 	*dsocketptr;
	socket_struct   	*socketptr, *newsocketptr;
	socket_interrupt	*sockintr;
	char            	*errptr;
	int4            	errlen, ii, msec_timeout;
	int			rv, max_fd, len;
	GTM_SOCKLEN_TYPE	size;
	boolean_t		zint_restart;
	mv_stent		*mv_zintdev;
	int			retry_num;
	struct sockaddr		*peer_sa_ptr;
	char			port_buffer[NI_MAXSERV], ipaddr[SA_MAXLEN + 1];
	int			errcode;

	/* check for validity */
	assert(iod->type == gtmsocket);
	dsocketptr = (d_socket_struct *)iod->dev_sp;
	sockintr = &dsocketptr->sock_save_state;
	peer_sa_ptr = ((struct sockaddr *)(&peer));

	/* Check for restart */
	if (!dsocketptr->mupintr)
		/* Simple path, no worries*/
		zint_restart = FALSE;
	else
	{       /* We have a pending wait restart of some sort - check we aren't recursing on this device */
		if (sockwhich_invalid == sockintr->who_saved)
			GTMASSERT;	/* Interrupt should never have an invalid save state */
		if (dollar_zininterrupt)
			rts_error_csa(CSA_ARG(NULL) VARLSTCNT(1) ERR_ZINTRECURSEIO);
		if (sockwhich_wait != sockintr->who_saved)
			GTMASSERT;      /* ZINTRECURSEIO should have caught */
		DBGSOCK((stdout, "socwait: *#*#*#*#*#*#*#  Restarted interrupted wait\n"));
		mv_zintdev = io_find_mvstent(iod, FALSE);
		if (mv_zintdev)
		{
			if (sockintr->end_time_valid)
				/* Restore end_time for timeout */
				end_time = sockintr->end_time;

			/* Done with this mv_stent. Pop it off if we can, else mark it inactive. */
			if (mv_chain == mv_zintdev)
				POP_MV_STENT();         /* pop if top of stack */
			else
			{       /* else mark it unused */
				mv_zintdev->mv_st_cont.mvs_zintdev.buffer_valid = FALSE;
				mv_zintdev->mv_st_cont.mvs_zintdev.io_ptr = NULL;
			}
			zint_restart = TRUE;
			DBGSOCK((stdout, "socwait: mv_stent found - endtime: %d/%d\n", end_time.at_sec, end_time.at_usec));
		} else
			DBGSOCK((stdout, "socwait: no mv_stent found !!\n"));
		dsocketptr->mupintr = FALSE;
		sockintr->who_saved = sockwhich_invalid;
	}
	/* check for events */
	FD_ZERO(&tcp_fd);
	while (TRUE)
	{
		max_fd = 0;
		for (ii = 0; ii < dsocketptr->n_socket; ii++)
		{
			socketptr = dsocketptr->socket[ii];
			if ((socket_listening == socketptr->state) || (socket_connected == socketptr->state))
			{
				FD_SET(socketptr->sd, &tcp_fd);
				max_fd = MAX(max_fd, socketptr->sd);
			}
		}
		utimeout.tv_sec = timepar;
		utimeout.tv_usec = 0;
		msec_timeout = timeout2msec(timepar);
		sys_get_curr_time(&cur_time);
		if (!zint_restart || !sockintr->end_time_valid)
			add_int_to_abs_time(&cur_time, msec_timeout, &end_time);
		else
		{       /* end_time taken from restart data. Compute what msec_timeout should be so timeout timer
					   gets set correctly below.
			*/
			DBGSOCK((stdout, "socwait: Taking timeout end time from wait restart data\n"));
			cur_time = sub_abs_time(&end_time, &cur_time);
			if (0 > cur_time.at_sec)
			{
				msec_timeout = -1;
				utimeout.tv_sec = 0;
				utimeout.tv_usec = 0;
			} else
			{
				msec_timeout = (int4)(cur_time.at_sec * 1000 + cur_time.at_usec / 1000);
				utimeout.tv_sec = cur_time.at_sec;
				utimeout.tv_usec = (gtm_tv_usec_t)cur_time.at_usec;
			}
		}
		sockintr->end_time_valid = FALSE;
		for ( ; ; )
		{
			rv = select(max_fd + 1, (void *)&tcp_fd, (void *)0, (void *)0,
				    (timepar == NO_M_TIMEOUT ? (struct timeval *)0 : &utimeout));
			if (0 > rv && EINTR == errno)
			{
				if (0 != outofband)
				{
					DBGSOCK((stdout, "socwait: outofband interrupt received (%d) -- "
						 "queueing mv_stent for wait intr\n", outofband));
					PUSH_MV_STENT(MVST_ZINTDEV);
					mv_chain->mv_st_cont.mvs_zintdev.io_ptr = iod;
					mv_chain->mv_st_cont.mvs_zintdev.buffer_valid = FALSE;
					sockintr->who_saved = sockwhich_wait;
					sockintr->end_time = end_time;
					sockintr->end_time_valid = TRUE;
					dsocketptr->mupintr = TRUE;
					socketus_interruptus++;
					DBGSOCK((stdout, "socwait: mv_stent queued - endtime: %d/%d  interrupts: %d\n",
						 end_time.at_sec, end_time.at_usec, socketus_interruptus));
					outofband_action(FALSE);
					GTMASSERT;      /* Should *never* return from outofband_action */
					return FALSE;   /* For the compiler.. */
				}
				sys_get_curr_time(&cur_time);
				cur_time = sub_abs_time(&end_time, &cur_time);
				if (0 > cur_time.at_sec)
				{
					rv = 0;		/* time out */
					break;
				}
				utimeout.tv_sec = cur_time.at_sec;
				utimeout.tv_usec = (gtm_tv_usec_t)cur_time.at_usec;
			} else
				break;	/* either other error or done */
		}
		if (rv == 0)
		{
			iod->dollar.key[0] = '\0';
			return FALSE;
		} else  if (rv < 0)
		{
			errptr = (char *)STRERROR(errno);
			errlen = STRLEN(errptr);
			rts_error_csa(CSA_ARG(NULL) VARLSTCNT(6) ERR_SOCKWAIT, 0, ERR_TEXT, 2, errlen, errptr);
			return FALSE;
		}
		/* find out which socket is ready */
		for (ii = 0; ii < dsocketptr->n_socket; ii++)
		{
			socketptr = dsocketptr->socket[ii];
			if (0 != FD_ISSET(socketptr->sd, &tcp_fd))
				break;
		}
		assert(ii < dsocketptr->n_socket);
		if (socket_listening == socketptr->state)
		{
			if (gtm_max_sockets <= dsocketptr->n_socket)
			{
				rts_error_csa(CSA_ARG(NULL) VARLSTCNT(3) ERR_SOCKMAX, 1, gtm_max_sockets);
				return FALSE;
			}

			size = SIZEOF(struct sockaddr_storage);
			rv = tcp_routines.aa_accept(socketptr->sd, peer_sa_ptr, &size);
			if (-1 == rv)
			{
#				ifdef __hpux
				if (ENOBUFS == errno)
					continue;	/* On HP-UX, ENOBUFS may indicate a transient condition; retry */
#				endif
				errptr = (char *)STRERROR(errno);
				errlen = STRLEN(errptr);
				rts_error_csa(CSA_ARG(NULL) VARLSTCNT(6) ERR_SOCKACPT, 0, ERR_TEXT, 2, errlen, errptr);
				return FALSE;
			}
			SOCKET_DUP(socketptr, newsocketptr);
			newsocketptr->sd = rv;
			SOCKET_ADDR_COPY(newsocketptr->remote, peer_sa_ptr, size);
			/* translate internal address to numeric ip address */
			GETNAMEINFO(peer_sa_ptr, size, ipaddr, SA_MAXLEN, NULL, 0, NI_NUMERICHOST, errcode);
			if (0 != errcode)
			{
				SOCKET_FREE(newsocketptr);
				RTS_ERROR_ADDRINFO(NULL, ERR_GETNAMEINFO, errcode);
				return FALSE;
			}
			if (NULL != newsocketptr->remote.saddr_ip)
				free(newsocketptr->remote.saddr_ip);
			STRNDUP(ipaddr, SA_MAXLEN, newsocketptr->remote.saddr_ip);
			/* translate internal address to port number*/
			GETNAMEINFO(peer_sa_ptr, size, NULL, 0, port_buffer, NI_MAXSERV, NI_NUMERICSERV, errcode);
			if (0 != errcode)
			{
				SOCKET_FREE(newsocketptr);
				RTS_ERROR_ADDRINFO(NULL, ERR_GETNAMEINFO, errcode);
				return FALSE;
			}
			newsocketptr->remote.port = ATOI(port_buffer);
			newsocketptr->state = socket_connected;
			newsocketptr->passive = FALSE;
			newsocketptr->first_read = newsocketptr->first_write = TRUE;
			/* put the new-born socket to the list and create a handle for it */
			iosocket_handle(newsocketptr->handle, &newsocketptr->handle_len, TRUE, dsocketptr);
			dsocketptr->socket[dsocketptr->n_socket++] = newsocketptr;
			dsocketptr->current_socket = dsocketptr->n_socket - 1;
			len = SIZEOF(CONNECTED) - 1;
			memcpy(&iod->dollar.key[0], CONNECTED, len);
			iod->dollar.key[len++] = '|';
			memcpy(&iod->dollar.key[len], newsocketptr->handle, newsocketptr->handle_len);
			len += newsocketptr->handle_len;
			iod->dollar.key[len++] = '|';
			strncpy(&iod->dollar.key[len], newsocketptr->remote.saddr_ip, DD_BUFLEN - 1 - len);
			iod->dollar.key[DD_BUFLEN-1] = '\0';		/* In case we fill the buffer */
		} else
		{
			assert(socket_connected == socketptr->state);
			dsocketptr->current_socket = ii;
			len = SIZEOF(READ) - 1;
			memcpy(&iod->dollar.key[0], READ, len);
			iod->dollar.key[len++] = '|';
			memcpy(&iod->dollar.key[len], socketptr->handle, socketptr->handle_len);
			len += socketptr->handle_len;
			iod->dollar.key[len++] = '|';
			if (NULL != socketptr->remote.saddr_ip)
			{
				strncpy(&iod->dollar.key[len], socketptr->remote.saddr_ip, DD_BUFLEN - 1 - len);
				iod->dollar.key[DD_BUFLEN-1] = '\0';
			} else
				iod->dollar.key[len] = '\0';
		}
		break;
	}
Exemplo n.º 4
0
/*
 * -----------------------------------------------
 * Maintain in parallel with op_zalloc2
 * Arguments:
 *	timeout	- max. time to wait for locks before giving up
 *      laflag - passed to gvcmx* routines as "laflag" argument;
 *		 originally indicated the request was a Lock or
 *		 zAllocate request (hence the name "laflag"), but
 *		 now capable of holding more values signifying
 *		 additional information
 *
 * Return:
 *	1 - if not timeout specified
 *	if timeout specified:
 *		!= 0 - all the locks int the list obtained, or
 *		0 - blocked
 *	The return result is suited to be placed directly into
 *	the $T variable by the caller if timeout is specified.
 * -----------------------------------------------
 */
int	op_lock2(int4 timeout, unsigned char laflag)	/* timeout is in seconds */
{
	boolean_t	blocked, timer_on;
	signed char	gotit;
	unsigned short	locks_bckout, locks_done;
	int4		msec_timeout;	/* timeout in milliseconds */
	mlk_pvtblk	*pvt_ptr1, *pvt_ptr2, **prior;
	unsigned char	action;
	ABS_TIME	cur_time, end_time, remain_time;
	mv_stent	*mv_zintcmd;

	DCL_THREADGBL_ACCESS;

	SETUP_THREADGBL_ACCESS;
	gotit = -1;
	cm_action = laflag;
	out_of_time = FALSE;
	if (timeout < 0)
		timeout = 0;
	else if (TREF(tpnotacidtime) < timeout)
		TPNOTACID_CHECK(LOCKTIMESTR);
	if (!(timer_on = (NO_M_TIMEOUT != timeout)))	/* NOTE assignment */
		msec_timeout = NO_M_TIMEOUT;
	else
	{
		msec_timeout = timeout2msec(timeout);
		if (0 == msec_timeout)
		{
			out_of_time = TRUE;
			timer_on = FALSE;
		} else
		{
			mv_zintcmd = find_mvstent_cmd(ZINTCMD_LOCK, restart_pc, restart_ctxt, FALSE);
			if (mv_zintcmd)
			{
				remain_time = mv_zintcmd->mv_st_cont.mvs_zintcmd.end_or_remain;
				if (0 <= remain_time.at_sec)
					msec_timeout = (int4)(remain_time.at_sec * 1000 + remain_time.at_usec / 1000);
				else
					msec_timeout = 0;
				TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_pc_last
					= mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_pc_prior;
				TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_ctxt_last
					= mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_ctxt_prior;
				TAREF1(zintcmd_active, ZINTCMD_LOCK).count--;
				assert(0 <= TAREF1(zintcmd_active, ZINTCMD_LOCK).count);
				if (mv_chain == mv_zintcmd)
					POP_MV_STENT(); /* just pop if top of stack */
				else
				{       /* flag as not active */
					mv_zintcmd->mv_st_cont.mvs_zintcmd.command = ZINTCMD_NOOP;
					mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_pc_check = NULL;
				}
			}
			if (0 < msec_timeout)
			{
				sys_get_curr_time(&cur_time);
				add_int_to_abs_time(&cur_time, msec_timeout, &end_time);
				start_timer((TID)&timer_on, msec_timeout, wake_alarm, 0, NULL);
			} else
			{
				out_of_time = TRUE;
				timer_on = FALSE;
			}
		}
	}
	lckclr();
	for (blocked = FALSE;  !blocked;)
	{	/* if this is a request for a remote node */
		if (remlkreq)
		{
			if (gotit >= 0)
				gotit = gvcmx_resremlk(cm_action);
			else
				gotit = gvcmx_reqremlk(cm_action, msec_timeout);	/* REQIMMED if 2nd arg == 0 */
			if (!gotit)
			{	/* only REQIMMED returns false */
				blocked = TRUE;
				break;
			}
		}
		for (pvt_ptr1 = mlk_pvt_root, locks_done = 0;  locks_done < lks_this_cmd;  pvt_ptr1 = pvt_ptr1->next, locks_done++)
		{	/* Go thru the list of all locks to be obtained attempting to lock
			 * each one. If any lock could not be obtained, break out of the loop
			 */
			if (!mlk_lock(pvt_ptr1, 0, TRUE))
			{	/* If lock is obtained */
				pvt_ptr1->granted = TRUE;
				switch (laflag)
				{
				case CM_LOCKS:
					pvt_ptr1->level = 1;
					break;
				case INCREMENTAL:
					if (pvt_ptr1->level < 511) /* The same lock can not be incremented more than 511 times. */
						pvt_ptr1->level += pvt_ptr1->translev;
					else
						level_err(pvt_ptr1);
					break;
				default:
					GTMASSERT;
					break;
				}
			} else
			{
				blocked = TRUE;
				break;
			}
		}
		/* If we did not get blocked, we are all done */
		if (!blocked)
			break;
		/* We got blocked and need to keep retrying after some time interval */
		if (remlkreq)
			gvcmx_susremlk(cm_action);
		switch (cm_action)
		{
		case CM_LOCKS:
			action = LOCKED;
			break;
		case INCREMENTAL:
			action = INCREMENTAL;
			break;
		default:
			GTMASSERT;
			break;
		}
		for (pvt_ptr2 = mlk_pvt_root, locks_bckout = 0;  locks_bckout < locks_done;
			pvt_ptr2 = pvt_ptr2->next, locks_bckout++)
		{
			assert(pvt_ptr2->granted && (pvt_ptr2 != pvt_ptr1));
			mlk_bckout(pvt_ptr2, action);
		}
		if (dollar_tlevel && (CDB_STAGNATE <= t_tries))
		{	/* upper TPNOTACID_CHECK conditioned on no short timeout; this one rel_crits to avoid potential deadlock */
			assert(TREF(tpnotacidtime) >= timeout);
			TPNOTACID_CHECK(LOCKTIMESTR);
		}
		for (;;)
		{
			if (out_of_time || outofband)
			{	/* if time expired || control-c, tptimeout, or jobinterrupt encountered */
				if (outofband || !lk_check_own(pvt_ptr1))
				{	/* If CTL-C, check lock owner */
					if (pvt_ptr1->nodptr)		/* Get off pending list to be sent a wake */
						mlk_unpend(pvt_ptr1);
					/* Cancel all remote locks obtained so far */
					if (remlkreq)
					{
						gvcmx_canremlk();
						gvcmz_clrlkreq();
						remlkreq = FALSE;
					}
					if (outofband)
					{
						if (timer_on && !out_of_time)
						{
							cancel_timer((TID)&timer_on);
							timer_on = FALSE;
						}
						if (!out_of_time && (NO_M_TIMEOUT != timeout))
						{	/* get remain = end_time - cur_time */
							sys_get_curr_time(&cur_time);
							remain_time = sub_abs_time(&end_time, &cur_time);
							if (0 <= remain_time.at_sec)
								msec_timeout = (int4)(remain_time.at_sec * 1000
									+ remain_time.at_usec / 1000);
							else
								msec_timeout = 0;	/* treat as out_of_time */
							if (0 >= msec_timeout)
							{
								out_of_time = TRUE;
								timer_on = FALSE;	/* as if LOCK :0 */
								break;
							}
							PUSH_MV_STENT(MVST_ZINTCMD);
							mv_chain->mv_st_cont.mvs_zintcmd.end_or_remain = remain_time;
							mv_chain->mv_st_cont.mvs_zintcmd.restart_ctxt_check = restart_ctxt;
							mv_chain->mv_st_cont.mvs_zintcmd.restart_pc_check = restart_pc;
							/* save current information from zintcmd_active */
							mv_chain->mv_st_cont.mvs_zintcmd.restart_ctxt_prior
								= TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_ctxt_last;
							mv_chain->mv_st_cont.mvs_zintcmd.restart_pc_prior
								= TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_pc_last;
							TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_pc_last = restart_pc;
							TAREF1(zintcmd_active, ZINTCMD_LOCK).restart_ctxt_last = restart_ctxt;
							TAREF1(zintcmd_active, ZINTCMD_LOCK).count++;
							mv_chain->mv_st_cont.mvs_zintcmd.command = ZINTCMD_LOCK;
							outofband_action(FALSE);	/* no return */
						}
					}
					break;
				}
			}
			if (!mlk_lock(pvt_ptr1, 0, FALSE))
			{	/* If we got the lock, break out of timer loop */
				blocked = FALSE;
				if (pvt_ptr1 != mlk_pvt_root)
				{
					rel_quant();		/* attempt to get a full timeslice for maximum chance to get all */
					mlk_unlock(pvt_ptr1);
				}
				break;
			}
			if (pvt_ptr1->nodptr)
				lk_check_own(pvt_ptr1);		/* clear an abandoned owner */
			hiber_start_wait_any(LOCK_SELF_WAKE);
		}
		if (blocked && out_of_time)
			break;
	}
	if (remlkreq)
	{
		gvcmz_clrlkreq();
		remlkreq = FALSE;
	}
	if (NO_M_TIMEOUT != timeout)
	{	/* was timed or immediate */
		if (timer_on && !out_of_time)
			cancel_timer((TID)&timer_on);
		if (blocked)
		{
			for (prior = &mlk_pvt_root;  *prior;)
			{
				if (!(*prior)->granted)
				{	/* if entry was never granted, delete list entry */
					mlk_pvtblk_delete(prior);
				} else
					prior = &((*prior)->next);
			}
			mlk_stats.n_user_locks_fail++;
			return (FALSE);
		}
	}
	mlk_stats.n_user_locks_success++;
	return (TRUE);
}
Exemplo n.º 5
0
/*
 * -----------------------------------------------
 * Maintain in parallel with op_zalloc2
 * Arguments:
 *	timeout	- max. time to wait for locks before giving up
 *      laflag - passed to gvcmx* routines as "laflag" argument;
 *		 originally indicated the request was a Lock or
 *		 zAllocate request (hence the name "laflag"), but
 *		 now capable of holding more values signifying
 *		 additional information
 *
 * Return:
 *	1 - if not timeout specified
 *	if timeout specified:
 *		!= 0 - all the locks int the list obtained, or
 *		0 - blocked
 *	The return result is suited to be placed directly into
 *	the $T variable by the caller if timeout is specified.
 * -----------------------------------------------
 */
int	op_lock2(int4 timeout, unsigned char laflag)	/* timeout is in seconds */
{
	bool		blocked, timer_on;
	signed char	gotit;
	unsigned short	locks_bckout, locks_done;
	int4		msec_timeout;	/* timeout in milliseconds */
	mlk_pvtblk	*pvt_ptr1, *pvt_ptr2, **prior;
	unsigned char	action;

	gotit = -1;
	cm_action = laflag;
	timer_on = (NO_M_TIMEOUT != timeout);
	out_of_time = FALSE;
	if (!timer_on)
		msec_timeout = NO_M_TIMEOUT;
	else
	{
		msec_timeout = timeout2msec(timeout);
		if (0 == msec_timeout)
			out_of_time = TRUE;
		else
			start_timer((TID)&timer_on, msec_timeout, wake_alarm, 0, NULL);
	}
	lckclr();
	for (blocked = FALSE;  !blocked;)
	{
		/* if this is a request for a remote node */
		if (remlkreq)
		{
			if (gotit >= 0)
				gotit = gvcmx_resremlk(cm_action);
			else
				gotit = gvcmx_reqremlk(cm_action, timeout);

			if (!gotit)
			{
				/* only REQIMMED returns false */
				blocked = TRUE;
				break;
			}
		}
		for (pvt_ptr1 = mlk_pvt_root, locks_done = 0;  locks_done < lks_this_cmd;  pvt_ptr1 = pvt_ptr1->next, locks_done++)
		{	/* Go thru the list of all locks to be obtained attempting to lock
			 * each one. If any lock could not be obtained, break out of the loop */
			if (!mlk_lock(pvt_ptr1, 0, TRUE))
			{	/* If lock is obtained */
				pvt_ptr1->granted = TRUE;
				switch (laflag)
				{
				case CM_LOCKS:
					pvt_ptr1->level = 1;
					break;
				case INCREMENTAL:
					pvt_ptr1->level += pvt_ptr1->translev;
					break;
				default:
					GTMASSERT;
					break;
				}
			} else
			{
				blocked = TRUE;
				break;
			}
		}
		/* If we did not get blocked, we are all done */
		if (!blocked)
			break;
		/* We got blocked and need to keep retrying after some time interval */
		if (remlkreq)
			gvcmx_susremlk(cm_action);
		switch (cm_action)
		{
		case CM_LOCKS:
			action = LOCKED;
			break;
		case INCREMENTAL:
			action = INCREMENTAL;
			break;
		default:
			GTMASSERT;
			break;
		}
		for (pvt_ptr2 = mlk_pvt_root, locks_bckout = 0;  locks_bckout < locks_done;
			pvt_ptr2 = pvt_ptr2->next, locks_bckout++)
		{
			assert(pvt_ptr2->granted && (pvt_ptr2 != pvt_ptr1));
			mlk_bckout(pvt_ptr2, action);
		}
		if (dollar_tlevel && (CDB_STAGNATE <= t_tries))
		{
			mlk_unpend(pvt_ptr1);		/* Eliminated the dangling request block */
			if (timer_on)
				cancel_timer((TID)&timer_on);
			t_retry(cdb_sc_needlock);	/* release crit to prevent a deadlock */
		}
		for (;;)
		{
			if (out_of_time || outofband)
			{	/* if time expired  ||  control-c encountered */
				if (outofband || !lk_check_own(pvt_ptr1))
				{	/* If CTL-C, check lock owner */
					if (pvt_ptr1->nodptr)		/* Get off pending list to be sent a wake */
						mlk_unpend(pvt_ptr1);
					/* Cancel all remote locks obtained so far */
					if (remlkreq)
					{
						gvcmx_canremlk();
						gvcmz_clrlkreq();
						remlkreq = FALSE;
					}
					if (outofband)
					{
						cancel_timer((TID)&timer_on);
						outofband_action(FALSE);
					}
					break;
				}
			}
			if (!mlk_lock(pvt_ptr1, 0, FALSE))
			{	/* If we got the lock, break out of timer loop */
				blocked = FALSE;
				if (pvt_ptr1 != mlk_pvt_root)
				{
					rel_quant();		/* attempt to get a full timeslice for maximum chance to get all */
					mlk_unlock(pvt_ptr1);
				}
				break;
			}
			if (pvt_ptr1->nodptr)
				lk_check_own(pvt_ptr1);		/* clear an abandoned owner */
			hiber_start_wait_any(LOCK_SELF_WAKE);
		}
		if (blocked  &&  out_of_time)
			break;
	}
	if (remlkreq)
	{
		gvcmz_clrlkreq();
		remlkreq = FALSE;
	}
	if (timer_on)
	{
		cancel_timer((TID)&timer_on);
		if (blocked)
		{
			for (prior = &mlk_pvt_root;  *prior;)
			{
				if (!(*prior)->granted)
				{	/* if entry was never granted, delete list entry */
					mlk_pvtblk_delete(prior);
				} else
					prior = &((*prior)->next);
			}
			mlk_stats.n_user_locks_fail++;
			return (FALSE);
		}
	}
	mlk_stats.n_user_locks_success++;
	return (TRUE);
}
Exemplo n.º 6
0
void dm_read(mval *v)
{
	boolean_t	done;
	unsigned short	iosb[4];
	int		cl, index;
	uint4		max_width, save_modifiers, save_term_msk, status;
	read_iosb	stat_blk;
	io_desc		*io_ptr;
	t_cap		s_mode;
	d_tt_struct	*tt_ptr;
	DCL_THREADGBL_ACCESS;

	SETUP_THREADGBL_ACCESS;
	if (tt == io_curr_device.out->type)
		iott_flush(io_curr_device.out);
	if (!comline_base)
	{
		comline_base = malloc(MAX_RECALL * SIZEOF(mstr));
		memset(comline_base, 0, (MAX_RECALL * SIZEOF(mstr)));
	}
	io_ptr = io_curr_device.in;
	assert(tt == io_ptr->type);
	assert(dev_open == io_ptr->state);
	if (io_ptr->dollar.zeof)
		op_halt();
	if (outofband)
	{
		outofband_action(FALSE);
		assert(FALSE);
	}
	tt_ptr = (d_tt_struct *)io_ptr->dev_sp;
	max_width = (io_ptr->width > tt_ptr->in_buf_sz) ? io_ptr->width : tt_ptr->in_buf_sz;
	assert(stringpool.free >= stringpool.base);
	assert(stringpool.free <= stringpool.top);
	ENSURE_STP_FREE_SPACE(max_width);
	active_device = io_ptr;
	index = 0;
	/* the following section of code puts the terminal in "easy of use" mode */
	status = sys$qiow(EFN$C_ENF, tt_ptr->channel, IO$_SENSEMODE,
		&stat_blk, 0, 0, &s_mode, 12, 0, 0, 0, 0);
	if (SS$_NORMAL == status)
		status = stat_blk.status;
	if (SS$_NORMAL != status)
		rts_error(VARLSTCNT(1) status);
	if ((s_mode.ext_cap & TT2$M_PASTHRU) ||
		!(s_mode.ext_cap & TT2$M_EDITING) ||
		!(s_mode.term_char & TT$M_ESCAPE) ||
		!(s_mode.term_char & TT$M_TTSYNC))
	{
		s_mode.ext_cap &= (~TT2$M_PASTHRU);
		s_mode.ext_cap |= TT2$M_EDITING;
		s_mode.term_char |= (TT$M_ESCAPE | TT$M_TTSYNC);
		status = sys$qiow(EFN$C_ENF, tt_ptr->channel,
			IO$_SETMODE, &stat_blk, 0, 0, &s_mode, 12, 0, 0, 0, 0);
		if (SS$_NORMAL == status)
			status = stat_blk.status;
		if (SS$_NORMAL != status)
			/* The following error is probably going to cause the terminal state to get mucked up */
			rts_error(VARLSTCNT(1) status);
		/* the following flag is normally used by iott_rdone, iott_readfl and iott_use but dm_read resets it when done */
		tt_ptr->term_chars_twisted = TRUE;
	}
	save_modifiers = (unsigned)tt_ptr->item_list[0].addr;
	tt_ptr->item_list[0].addr = (unsigned)tt_ptr->item_list[0].addr | TRM$M_TM_NORECALL & (~TRM$M_TM_NOECHO);
	tt_ptr->item_list[1].addr = NO_M_TIMEOUT;			/* reset key click timeout */
	save_term_msk = ((io_termmask *)tt_ptr->item_list[2].addr)->mask[0];
	((io_termmask *)tt_ptr->item_list[2].addr)->mask[0] = TERM_MSK | (SHFT_MSK << CTRL_B) | (SHFT_MSK << CTRL_Z);
	tt_ptr->item_list[4].buf_len = (TREF(gtmprompt)).len;
	do
	{
		done = TRUE;
		assert(0 <= index && index <= MAX_RECALL + 1);
		cl = clmod(comline_index - index);
		if ((0 == index) || (MAX_RECALL + 1 == index))
			tt_ptr->item_list[5].buf_len	= 0;
		else
		{
			tt_ptr->item_list[5].buf_len	= comline_base[cl].len;
			tt_ptr->item_list[5].addr	= comline_base[cl].addr;
		}
		status = sys$qiow(EFN$C_ENF, tt_ptr->channel, tt_ptr->read_mask, &stat_blk, 0, 0,
			stringpool.free, tt_ptr->in_buf_sz, 0, 0, tt_ptr->item_list, 6 * SIZEOF(item_list_struct));
		if (outofband)
			break;
		if (SS$_NORMAL != status)
		{
			if (io_curr_device.in == io_std_device.in && io_curr_device.out == io_std_device.out)
			{
				if (prin_in_dev_failure)
					sys$exit(status);
				else
					prin_in_dev_failure = TRUE;
			}
			break;
		}
		if (stat_blk.term_length > ESC_LEN - 1)
		{
			stat_blk.term_length = ESC_LEN - 1;
			if (SS$_NORMAL == stat_blk.status)
				stat_blk.status = SS$_PARTESCAPE;
		}
		if (SS$_NORMAL != stat_blk.status)
		{
			if (ctrlu_occurred)
			{
				index = 0;
				done = FALSE;
				ctrlu_occurred = FALSE;
				iott_wtctrlu(stat_blk.char_ct + (TREF(gtmprompt)).len, io_ptr);
			} else
			{
				status = stat_blk.status;
				break;
			}
		} else
		{
			if ((CTRL_B == stat_blk.term_char) ||
				(stat_blk.term_length == tt_ptr->key_up_arrow.len &&
				!memcmp(tt_ptr->key_up_arrow.addr, stringpool.free + stat_blk.char_ct,
				tt_ptr->key_up_arrow.len)))
			{
				done = FALSE;
				if ((MAX_RECALL + 1 != index) && (comline_base[cl].len || !index))
					index++;
			} else
			{
				if (stat_blk.term_length == tt_ptr->key_down_arrow.len &&
					!memcmp(tt_ptr->key_down_arrow.addr, stringpool.free + stat_blk.char_ct,
					tt_ptr->key_down_arrow.len))
				{
					done = FALSE;
					if (index)
						--index;
				}
			}
			if (!done)
			{
				status = sys$qiow(EFN$C_ENF, tt_ptr->channel,
					IO$_WRITEVBLK, &iosb, NULL, 0,
					tt_ptr->erase_to_end_line.addr, tt_ptr->erase_to_end_line.len,
					0, CCRECALL, 0, 0);
			} else
			{
				if (stat_blk.char_ct > 0
					&& (('R' == *stringpool.free) || ('r' == *stringpool.free)) &&
					(TRUE == m_recall(stat_blk.char_ct, stringpool.free, &index, tt_ptr->channel)))
				{
					assert(-1 <= index && index <= MAX_RECALL);
					done = FALSE;
					flush_pio();
					status = sys$qiow(EFN$C_ENF, tt_ptr->channel,
						IO$_WRITEVBLK, &iosb, NULL, 0,
						0, 0, 0, CCPROMPT, 0, 0);
					if ((-1 == index) || (CTRL_Z == stat_blk.term_char))
						index = 0;
				}
			}
			if (!done)
			{
				if (SS$_NORMAL == status)
					status = iosb[0];
				if (SS$_NORMAL != status)
					break;
			} else
			{
				if (CTRL_Z == stat_blk.term_char)
					io_curr_device.in->dollar.zeof = TRUE;
			}
		}
	} while (!done);
	/* put the terminal back the way the user had it set up */
	tt_ptr->item_list[0].addr = save_modifiers;
	((io_termmask *)tt_ptr->item_list[2].addr)->mask[0] = save_term_msk;
	if (tt_ptr->term_chars_twisted)
	{
		s_mode.ext_cap &= (~TT2$M_PASTHRU & ~TT2$M_EDITING);
		s_mode.ext_cap |= (tt_ptr->ext_cap & (TT2$M_PASTHRU | TT2$M_EDITING));
		s_mode.term_char &= (~TT$M_ESCAPE);
		s_mode.term_char |= (tt_ptr->term_char & TT$M_ESCAPE);
		status = sys$qiow(EFN$C_ENF, tt_ptr->channel,
			IO$_SETMODE, iosb, 0, 0, &s_mode, 12, 0, 0, 0, 0);
		if (SS$_NORMAL == status)
			status = iosb[0];
		tt_ptr->term_chars_twisted = FALSE;
	}
	if (SS$_NORMAL != status)
		rts_error(VARLSTCNT(1) status);
	if (outofband)
	{
		/* outofband not going to help more than a error so it's checked 2nd */
		outofband_action(FALSE);
		assert(FALSE);
	}
	v->mvtype = MV_STR;
	v->str.len = stat_blk.char_ct;
	v->str.addr = stringpool.free;
	if (stat_blk.char_ct)
	{
		cl = clmod(comline_index - 1);
		if (stat_blk.char_ct != comline_base[cl].len || memcmp(comline_base[cl].addr, stringpool.free, stat_blk.char_ct))
		{
			comline_base[comline_index] = v->str;
			comline_index = clmod(comline_index + 1);
		}
		stringpool.free += stat_blk.char_ct;
	}
	assert(stringpool.free <= stringpool.top);
	if ((io_ptr->dollar.x += stat_blk.char_ct) > io_ptr->width && io_ptr->wrap)
	{
		/* dm_read doesn't maintain the other io status isv's,
		 but it does $x and $y so the user can find out where they wound up */
		io_ptr->dollar.y += io_ptr->dollar.x / io_ptr->width;
		if (io_ptr->length)
			io_ptr->dollar.y %= io_ptr->length;
		io_ptr->dollar.x %= io_ptr->width;
	}
	active_device = 0;
}
Exemplo n.º 7
0
short	iott_readfl (mval *v, int4 length, int4 timeout)	/* timeout in seconds */
{
	boolean_t	ret, nonzerotimeout, timed;
	uint4		mask;
	unsigned char	inchar, *temp;
#ifdef __MVS__
	unsigned char	asc_inchar;
#endif
	int		dx, msk_in, msk_num, outlen, rdlen, save_errno, selstat, status, width;
	int4		msec_timeout;			/* timeout in milliseconds */
	io_desc		*io_ptr;
	d_tt_struct	*tt_ptr;
	io_terminator	outofbands;
	io_termmask	mask_term;
	unsigned char	*zb_ptr, *zb_top;
	ABS_TIME	cur_time, end_time;
	fd_set		input_fd;
	struct timeval	input_timeval;
	struct timeval	save_input_timeval;

	error_def(ERR_CTRAP);
	error_def(ERR_IOEOF);
	error_def(ERR_NOPRINCIO);

	assert(stringpool.free >= stringpool.base);
	assert(stringpool.free <= stringpool.top);
	io_ptr = io_curr_device.in;
	tt_ptr = (d_tt_struct *)(io_ptr->dev_sp);
	assert(dev_open == io_ptr->state);
	iott_flush(io_curr_device.out);
	width = io_ptr->width;
	if (stringpool.free + length > stringpool.top)
		stp_gcol (length);
	outlen = 0;
	/* ---------------------------------------------------------
	 * zb_ptr is be used to fill-in the value of $zb as we go
	 * If we drop-out with error or otherwise permaturely,
	 * consider $zb to be null.
	 * ---------------------------------------------------------
	 */
	zb_ptr = io_ptr->dollar.zb;
	zb_top = zb_ptr + sizeof(io_ptr->dollar.zb) - 1;
	*zb_ptr = 0;
	io_ptr->esc_state = START;
	io_ptr->dollar.za = 0;
	io_ptr->dollar.zeof = FALSE;
	v->str.len = 0;
	dx = (int)io_ptr->dollar.x;
	ret = TRUE;
	temp = stringpool.free;
	mask = tt_ptr->term_ctrl;
	mask_term = tt_ptr->mask_term;
	if (mask & TRM_NOTYPEAHD)
		TCFLUSH(tt_ptr->fildes, TCIFLUSH, status);
	if (mask & TRM_READSYNC)
	{
		DOWRITERC(tt_ptr->fildes, &dc1, 1, status);
		if (0 != status)
		{
			io_ptr->dollar.za = 9;
			rts_error(VARLSTCNT(1) status);
		}
	}
	nonzerotimeout = FALSE;
	if (NO_M_TIMEOUT == timeout)
	{
		timed = FALSE;
		input_timeval.tv_sec = 100;
		msec_timeout = NO_M_TIMEOUT;
	} else
	{
		timed = TRUE;
		input_timeval.tv_sec = timeout;
		msec_timeout = timeout2msec(timeout);
		if (!msec_timeout)
			iott_mterm(io_ptr);
		else
		{
			nonzerotimeout = TRUE;
   			sys_get_curr_time(&cur_time);
			add_int_to_abs_time(&cur_time, msec_timeout, &end_time);
		}
	}
	input_timeval.tv_usec = 0;
	do
	{
		if (outofband)
		{
			outlen = 0;
			if (!msec_timeout)
				iott_rterm(io_ptr);
			outofband_action(FALSE);
			break;
		}
		errno = 0;
		FD_ZERO(&input_fd);
		FD_SET(tt_ptr->fildes, &input_fd);
		assert(0 != FD_ISSET(tt_ptr->fildes, &input_fd));
		/* the checks for EINTR below are valid and should not be converted to EINTR
		 * wrapper macros, since the select/read is not retried on EINTR.
		 */
		save_input_timeval = input_timeval;	/* take a copy and pass it because select() below might change it */
		selstat = select(tt_ptr->fildes + 1, (void *)&input_fd, (void *)NULL, (void *)NULL, &save_input_timeval);
		if (selstat < 0)
		{
			if (EINTR != errno)
				goto term_error;
		} else if (0 == selstat)
		{
			if (timed)
			{
				ret = FALSE;
				break;
			}
			continue;	/* select() timeout; keep going */
		} else if (0 < (rdlen = read(tt_ptr->fildes, &inchar, 1)))	/* This read is protected */
		{
			assert(0 != FD_ISSET(tt_ptr->fildes, &input_fd));
			/* --------------------------------------------------
			 * set prin_in_dev_failure to FALSE to indicate that
			 * input device is working now.
			 * --------------------------------------------------
			 */
			prin_in_dev_failure = FALSE;
			if (tt_ptr->canonical)
			{
				if (0 == inchar)
				{
					/* --------------------------------------
					 * This means that the device has hungup
					 * --------------------------------------
					 */
					io_ptr->dollar.zeof = TRUE;
					io_ptr->dollar.x = 0;
					io_ptr->dollar.za = 9;
					io_ptr->dollar.y++;
					if (io_ptr->error_handler.len > 0)
						rts_error(VARLSTCNT(1) ERR_IOEOF);
					break;
				} else
					io_ptr->dollar.zeof = FALSE;
			}
			if (mask & TRM_CONVERT)
				NATIVE_CVT2UPPER(inchar, inchar);
                        GETASCII(asc_inchar,inchar);
			if ((dx >= width) && io_ptr->wrap && !(mask & TRM_NOECHO))
			{
				DOWRITE(tt_ptr->fildes, NATIVE_TTEOL, strlen(NATIVE_TTEOL));
				dx = 0;
			}
			if ((' ' > INPUT_CHAR) && (tt_ptr->enbld_outofbands.mask & (1 << INPUT_CHAR)))
			{
				outlen = 0;
				io_ptr->dollar.za = 9;
				std_dev_outbndset(INPUT_CHAR);	/* it needs ASCII?	*/
				outofband = 0;
				if (!msec_timeout)
					iott_rterm(io_ptr);
				rts_error(VARLSTCNT(3) ERR_CTRAP, 1, ctrap_action_is);
				break;
			}
			if ((0 != (mask & TRM_ESCAPE))
			     && ((NATIVE_ESC == inchar) || (START != io_ptr->esc_state)))
			{
				if (zb_ptr >= zb_top)
				{	/* $zb overflow */
					io_ptr->dollar.za = 2;
					break;
				}
				*zb_ptr++ = inchar;
				iott_escape(zb_ptr - 1, zb_ptr, io_ptr);
				*(zb_ptr - 1) = INPUT_CHAR;     /* need to store ASCII value    */
				if (FINI == io_ptr->esc_state)
					break;
				if (BADESC == io_ptr->esc_state)
				{	/* Escape sequence failed parse */
					io_ptr->dollar.za = 2;
					break;
				}
				/* --------------------------------------------------------------------
				 * In escape sequence...do not process further, but get next character
				 * --------------------------------------------------------------------
				 */
			} else
			{	/* SIMPLIFY THIS! */
				msk_num = (uint4)INPUT_CHAR / NUM_BITS_IN_INT4;
				msk_in = (1 << ((uint4)INPUT_CHAR % NUM_BITS_IN_INT4));
				if (msk_in & mask_term.mask[msk_num])
				{
					*zb_ptr++ = INPUT_CHAR;
					break;
				}
				if (((int)inchar == tt_ptr->ttio_struct->c_cc[VERASE]) && !(mask & TRM_PASTHRU))
				{
					if ((0< outlen) && (0 < dx))
					{
						outlen--;
						dx--;
						*temp--;
						if (!(mask & TRM_NOECHO))
						{
							DOWRITERC(tt_ptr->fildes, eraser, sizeof(eraser), status);
							if (0 != status)
								goto term_error;
						}
					}
				} else
				{
					if (!(mask & TRM_NOECHO))
					{
						DOWRITERC(tt_ptr->fildes, &inchar, 1, status);
						if (0 != status)
							goto term_error;
					}
					*temp++ = inchar;
					outlen++;
					dx++;
				}
			}
		} else if (0 == rdlen)
		{
			if (0 < selstat)
			{	/* this should be the only possibility */
				io_ptr->dollar.zeof = TRUE;
				io_ptr->dollar.x = 0;
				io_ptr->dollar.za = 0;
				io_ptr->dollar.y++;
				if (io_curr_device.in == io_std_device.in)
				{
					if (!prin_in_dev_failure)
						prin_in_dev_failure = TRUE;
					else
					{
                                        	send_msg(VARLSTCNT(1) ERR_NOPRINCIO);
                                        	stop_image_no_core();
					}
                                }
				if (io_ptr->dollar.zeof)
				{
					io_ptr->dollar.za = 9;
					rts_error(VARLSTCNT(1) ERR_IOEOF);
				} else
				{
					io_ptr->dollar.zeof = TRUE;
					io_ptr->dollar.za = 0;
					if (0 < io_ptr->error_handler.len)
						rts_error(VARLSTCNT(1) ERR_IOEOF);
				}
				break;
			}
			if (0 == errno)
			{	/* eof */
				io_ptr->dollar.zeof = TRUE;
				io_ptr->dollar.x = 0;
				io_ptr->dollar.za = 0;
				io_ptr->dollar.y++;
				if (0 < io_ptr->error_handler.len)
					rts_error(VARLSTCNT(1) ERR_IOEOF);
				break;
			}
		} else if (EINTR != errno)	/* rdlen < 0 */
			goto term_error;
		if (nonzerotimeout)
		{
			sys_get_curr_time(&cur_time);
			cur_time = sub_abs_time(&end_time, &cur_time);
			if (0 > cur_time.at_sec)
			{
				ret = FALSE;
				break;
			}
			input_timeval.tv_sec = cur_time.at_sec;
			input_timeval.tv_usec = cur_time.at_usec;
		}
	} while (outlen < length);
	*zb_ptr++ = 0;
	if (!msec_timeout)
	{
		iott_rterm(io_ptr);
		if (0 == outlen)
			ret = FALSE;
	}
	if (mask & TRM_READSYNC)
	{
		DOWRITERC(tt_ptr->fildes, &dc3, 1, status);
		if (0 != status)
		{
			io_ptr->dollar.za = 9;
			rts_error(VARLSTCNT(1) status);
		}
	}
	if (outofband)
	{
		v->str.len = 0;
		io_ptr->dollar.za = 9;
		return(FALSE);
	}
	v->str.len = outlen;
	v->str.addr = (char *)stringpool.free;
	if (!(mask & TRM_NOECHO))
	{
		if ((io_ptr->dollar.x += v->str.len) >= io_ptr->width && io_ptr->wrap)
		{
			io_ptr->dollar.y += (io_ptr->dollar.x / io_ptr->width);
			if (io_ptr->length)
				io_ptr->dollar.y %= io_ptr->length;
			io_ptr->dollar.x %= io_ptr->width;
			if (0 == io_ptr->dollar.x)
				DOWRITE(tt_ptr->fildes, NATIVE_TTEOL, strlen(NATIVE_TTEOL));
		}
	}
	return ((short)ret);

term_error:
	save_errno = errno;
	io_ptr->dollar.za = 9;
	if (!msec_timeout)
		iott_rterm(io_ptr);
	rts_error(VARLSTCNT(1) save_errno);
	return FALSE;
}
Exemplo n.º 8
0
/*
 * ------------------------------------------
 * Hang the process for a specified time.
 *
 *	Goes to sleep for a positive value.
 *	Any caught signal will terminate the sleep
 *	following the execution of that signal's catching routine.
 *
 * 	The actual hang duration should be NO LESS than the specified
 * 	duration for specified durations greater than .001 seconds.
 * 	Certain applications depend on this assumption.
 *
 * Arguments:
 *	num - time to sleep
 *
 * Return:
 *	none
 * ------------------------------------------
 */
void op_hang(mval* num)
{
	int		ms;
	double		tmp;
	mv_stent	*mv_zintcmd;
	ABS_TIME	cur_time, end_time;
#	ifdef VMS
	uint4 		time[2];
	int4		efn_mask, status;
#	endif
	DCL_THREADGBL_ACCESS;

	SETUP_THREADGBL_ACCESS;
	ms = 0;
	MV_FORCE_NUM(num);
	if (num->mvtype & MV_INT)
	{
		if (0 < num->m[1])
		{
			assert(MV_BIAS >= 1000);	/* if formats change overflow may need attention */
			ms = num->m[1] * (1000 / MV_BIAS);
		}
	} else if (0 == num->sgn) 		/* if sign is not 0 it means num is negative */
	{
		tmp = mval2double(num) * (double)1000;
		ms = ((double)MAXPOSINT4 >= tmp) ? (int)tmp : (int)MAXPOSINT4;
	}
	if (ms)
	{
		if (TREF(tpnotacidtime) * 1000 < ms)
			TPNOTACID_CHECK(HANGSTR);
#		if defined(DEBUG) && defined(UNIX)
		if (WBTEST_ENABLED(WBTEST_DEFERRED_TIMERS) && (3 > gtm_white_box_test_case_count) && (123000 == ms))
		{
			DEFER_INTERRUPTS(INTRPT_NO_TIMER_EVENTS);
			DBGFPF((stderr, "OP_HANG: will sleep for 20 seconds\n"));
			LONG_SLEEP(20);
			DBGFPF((stderr, "OP_HANG: done sleeping\n"));
			ENABLE_INTERRUPTS(INTRPT_NO_TIMER_EVENTS);
			return;
		}
		if (WBTEST_ENABLED(WBTEST_BREAKMPC)&& (0 == gtm_white_box_test_case_count) && (999 == ms))
		{
			frame_pointer->old_frame_pointer->mpc = (unsigned char *)GTM64_ONLY(0xdeadbeef12345678)
				NON_GTM64_ONLY(0xdead1234);
			return;
		}
		if (WBTEST_ENABLED(WBTEST_UTIL_OUT_BUFFER_PROTECTION) && (0 == gtm_white_box_test_case_count) && (999 == ms))
		{	/* Upon seeing a .999s hang this white-box test launches a timer that pops with a period of
		 	 * UTIL_OUT_SYSLOG_INTERVAL and prints a long message via util_out_ptr.
			 */
			start_timer((TID)&util_out_syslog_dump, UTIL_OUT_SYSLOG_INTERVAL, util_out_syslog_dump, 0, NULL);
			return;
		}
#		endif
		sys_get_curr_time(&cur_time);
		mv_zintcmd = find_mvstent_cmd(ZINTCMD_HANG, restart_pc, restart_ctxt, FALSE);
		if (!mv_zintcmd)
			add_int_to_abs_time(&cur_time, ms, &end_time);
		else
		{
			end_time = mv_zintcmd->mv_st_cont.mvs_zintcmd.end_or_remain;
			cur_time = sub_abs_time(&end_time, &cur_time);	/* get remaing time to sleep */
			if (0 <= cur_time.at_sec)
				ms = (int4)(cur_time.at_sec * 1000 + cur_time.at_usec / 1000);
			else
				ms = 0;		/* all done */
			/* restore/pop previous zintcmd_active[ZINTCMD_HANG] hints */
			TAREF1(zintcmd_active, ZINTCMD_HANG).restart_pc_last = mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_pc_prior;
			TAREF1(zintcmd_active, ZINTCMD_HANG).restart_ctxt_last
				= mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_ctxt_prior;
			TAREF1(zintcmd_active, ZINTCMD_HANG).count--;
			assert(0 <= TAREF1(zintcmd_active, ZINTCMD_HANG).count);
			if (mv_chain == mv_zintcmd)
				POP_MV_STENT();	/* just pop if top of stack */
			else
			{	/* flag as not active */
				mv_zintcmd->mv_st_cont.mvs_zintcmd.command = ZINTCMD_NOOP;
				mv_zintcmd->mv_st_cont.mvs_zintcmd.restart_pc_check = NULL;
			}
			if (0 == ms)
				return;		/* done HANGing */
		}
#		ifdef UNIX
		if (ms < 10)
			SLEEP_USEC(ms * 1000, TRUE);	/* Finish the sleep if it is less than 10ms. */
		else
			hiber_start(ms);
#		elif defined(VMS)
		time[0] = -time_low_ms(ms);
		time[1] = -time_high_ms(ms) - 1;
		efn_mask = (1 << efn_outofband | 1 << efn_timer);
		if (SS$_NORMAL != (status = sys$setimr(efn_timer, &time, NULL, &time, 0)))
			rts_error_csa(CSA_ARG(NULL) VARLSTCNT(8) ERR_SYSCALL, 5, RTS_ERROR_LITERAL("$setimr"), CALLFROM, status);
		if (SS$_NORMAL != (status = sys$wflor(efn_outofband, efn_mask)))
			rts_error_csa(CSA_ARG(NULL) VARLSTCNT(8) ERR_SYSCALL, 5, RTS_ERROR_LITERAL("$wflor"), CALLFROM, status);
		if (outofband)
		{
			if (SS$_WASCLR == (status = sys$readef(efn_timer, &efn_mask)))
			{
				if (SS$_NORMAL != (status = sys$cantim(&time, 0)))
					rts_error_csa(CSA_ARG(NULL) VARLSTCNT(8) ERR_SYSCALL, 5, RTS_ERROR_LITERAL("$cantim"),
						CALLFROM, status);
			} else
				assertpro(SS$_WASSET == status);
		}
#		endif
	} else
		rel_quant();
	if (outofband)
	{
		PUSH_MV_STENT(MVST_ZINTCMD);
		mv_chain->mv_st_cont.mvs_zintcmd.end_or_remain = end_time;
		mv_chain->mv_st_cont.mvs_zintcmd.restart_ctxt_check = restart_ctxt;
		mv_chain->mv_st_cont.mvs_zintcmd.restart_pc_check = restart_pc;
		/* save current information from zintcmd_active */
		mv_chain->mv_st_cont.mvs_zintcmd.restart_ctxt_prior = TAREF1(zintcmd_active, ZINTCMD_HANG).restart_ctxt_last;
		mv_chain->mv_st_cont.mvs_zintcmd.restart_pc_prior = TAREF1(zintcmd_active, ZINTCMD_HANG).restart_pc_last;
		TAREF1(zintcmd_active, ZINTCMD_HANG).restart_pc_last = restart_pc;
		TAREF1(zintcmd_active, ZINTCMD_HANG).restart_ctxt_last = restart_ctxt;
		TAREF1(zintcmd_active, ZINTCMD_HANG).count++;
		mv_chain->mv_st_cont.mvs_zintcmd.command = ZINTCMD_HANG;
		outofband_action(FALSE);
	}
	return;
}
Exemplo n.º 9
0
bool io_open_try(io_log_name *naml, io_log_name *tl, mval *pp, int4 timeout, mval *mspace)
{
	char		buf1[MAX_TRANS_NAME_LEN];	/* buffer to hold translated name */
	char		dev_type[MAX_DEV_TYPE_LEN];
        int             n;
	mstr		tn;				/* translated name */
	uint4		stat;				/* status */
	int		p_offset;
	unsigned char	ch;
	ABS_TIME	cur_time, end_time;
	bool		out_of_time = FALSE;

	if (0 == naml->iod)
	{
		if (0 == tl->iod)
		{
			tl->iod = (io_desc *)malloc(SIZEOF(io_desc));
			memset((char*)tl->iod, 0, SIZEOF(io_desc));
			tl->iod->pair.in  = tl->iod;
			tl->iod->pair.out = tl->iod;
			tl->iod->trans_name = tl;
			p_offset = 0;
			while (iop_eol != *(pp->str.addr + p_offset))
			{
				if ((iop_tmpmbx == (ch = *(pp->str.addr + p_offset++))) || (iop_prmmbx == ch))
					tl->iod->type = mb;
				else  if (iop_nl == ch)
					tl->iod->type = nl;
				p_offset += ((IOP_VAR_SIZE == io_params_size[ch]) ?
					(unsigned char)*(pp->str.addr + p_offset) + 1 : io_params_size[ch]);
			}
			if (!tl->iod->type && mspace && mspace->str.len)
			{
				lower_to_upper(dev_type, mspace->str.addr, mspace->str.len);
				if (((SIZEOF("SOCKET") - 1) == mspace->str.len)
					&& (0 == memcmp(dev_type, LIT_AND_LEN("SOCKET"))))
					tl->iod->type = gtmsocket;
				else
					tl->iod->type = us;
			}
			if (!tl->iod->type)
			{
				tn.len = tl->len;
				tn.addr = &tl->dollar_io;
				tl->iod->type = io_type(&tn);
			}
		}
		naml->iod = tl->iod;
	}
	tl->iod->disp_ptr = &io_dev_dispatch[tl->iod->type];
	assert(0 != naml->iod);
	active_device = naml->iod;
	if (dev_never_opened == naml->iod->state)
	{
		naml->iod->wrap = DEFAULT_IOD_WRAP;
		naml->iod->width = DEFAULT_IOD_WIDTH;
		naml->iod->length = DEFAULT_IOD_LENGTH;
		naml->iod->write_filter = write_filter;
	}
	if (dev_open != naml->iod->state)
	{
		naml->iod->dollar.x = 0;
		naml->iod->dollar.y = 0;
		naml->iod->dollar.za = 0;
		naml->iod->dollar.zb[0] = 0;
		naml->iod->dollar.zeof = FALSE;
	}
	if (0 == timeout)
		stat = (naml->iod->disp_ptr->open)(naml, pp, -1, mspace, timeout);	/* ZY: add a parameter timeout */
	else  if (NO_M_TIMEOUT == timeout)
	{
		while (FALSE == (stat = (naml->iod->disp_ptr->open)(naml, pp, -1, mspace, timeout)))	/* ZY: add timeout */
		{
			hiber_start(1000);	/* 1 second */
			if (outofband)
				outofband_action(FALSE);
		}
	} else
	{
		sys_get_curr_time(&cur_time);
		add_int_to_abs_time(&cur_time, timeout * 1000, &end_time);
		while (FALSE == (stat = (naml->iod->disp_ptr->open)(naml, pp, -1, mspace, timeout))	/* ZY: add timeout */
			&& (!out_of_time))
		{
			hiber_start(1000);	/* 1 second */
			if (outofband)
				outofband_action(FALSE);
			sys_get_curr_time(&cur_time);
			if (abs_time_comp(&end_time, &cur_time) <= 0)
				out_of_time = TRUE;
		}
	}
	if (TRUE == stat)
	{
		naml->iod->state = dev_open;
		if (27 == naml->iod->trans_name->dollar_io[0])
		{
			tn.addr = &naml->iod->trans_name->dollar_io[4];
			n = naml->iod->trans_name->len - 4;
			if (n < 0)
				n = 0;
			tn.len = n;
			naml->iod->trans_name = get_log_name(&tn, INSERT);
			naml->iod->trans_name->iod = naml->iod;
		}
	}
	else
	{
		if (dev_open == naml->iod->state && (gtmsocket != naml->iod->type))
			naml->iod->state = dev_closed;
		else if ((gtmsocket == naml->iod->type) && naml->iod->newly_created)
		{
			assert(naml->iod->state != dev_open);
			iosocket_destroy(naml->iod);
		}
	}
	active_device = 0;
	if ((NO_M_TIMEOUT != timeout) && IS_MCODE_RUNNING)
		return (stat);
	return FALSE;
}
Exemplo n.º 10
0
void op_merge(void)
{
	boolean_t		found, check_for_null_subs, is_base_var;
	lv_val			*dst_lv;
	mval 			*mkey, *value, *subsc;
	int			org_glvn1_keysz, org_glvn2_keysz, delta2, dollardata_src, dollardata_dst, sbs_depth;
	unsigned char		*ptr, *ptr2;
	unsigned char  		buff[MAX_ZWR_KEY_SZ];
	unsigned char		nullcoll_src, nullcoll_dst;
	zshow_out		output;
	DCL_THREADGBL_ACCESS;

	SETUP_THREADGBL_ACCESS;
	assert(MAX_STRLEN >= MAX_ZWR_KEY_SZ);
	assert ((merge_args == (MARG1_LCL | MARG2_LCL)) ||
		(merge_args == (MARG1_LCL | MARG2_GBL)) ||
		(merge_args == (MARG1_GBL | MARG2_LCL)) ||
		(merge_args == (MARG1_GBL | MARG2_GBL)));
	assert(!lvzwrite_block || 0 == lvzwrite_block->curr_subsc);
	/* Need to protect value from stpgcol */
	PUSH_MV_STENT(MVST_MVAL);
	value = &mv_chain->mv_st_cont.mvs_mval;
	value->mvtype = 0; /* initialize mval in the M-stack in case stp_gcol gets called before value gets initialized below */
	if (MARG2_IS_GBL(merge_args))
	{	/* Need to protect mkey returned from gvcst_queryget from stpgcol */
		PUSH_MV_STENT(MVST_MVAL);
		mkey = &mv_chain->mv_st_cont.mvs_mval;
		mkey->mvtype = 0; /* initialize mval in M-stack in case stp_gcol gets called before mkey gets initialized below */
		gvname_env_restore(mglvnp->gblp[IND2]);
		/* now $DATA will be done for gvn2. op_gvdata input parameters are set in the form of some GBLREF */
		op_gvdata(value);
		dollardata_src = MV_FORCE_INT(value);
		if (0 == dollardata_src)
		{	/* nothing in source global */
			UNDO_ACTIVE_LV;
			POP_MV_STENT();	/* value */
			POP_MV_STENT(); /* mkey */
			if (MARG1_IS_GBL(merge_args))
				gvname_env_restore(mglvnp->gblp[IND1]);	 /* store destination as naked indicator in gv_currkey */
			merge_args = 0;	/* Must reset to zero to reuse the Global */
			return;
		}
		if (NULL == TREF(gv_mergekey2))
		{	/* We need to initialize gvn2 (right hand side). */
			GVKEY_INIT(TREF(gv_mergekey2), DBKEYSIZE(MAX_KEY_SZ));
		}
		org_glvn1_keysz = mglvnp->gblp[IND1]->s_gv_currkey->end + 1;
		org_glvn2_keysz = gv_currkey->end + 1;
		(TREF(gv_mergekey2))->end = gv_currkey->end;
		(TREF(gv_mergekey2))->prev = gv_currkey->prev;
		memcpy((TREF(gv_mergekey2))->base, gv_currkey->base, gv_currkey->end + 1);
		if (MARG1_IS_GBL(merge_args))
		{	/*==================== MERGE ^gvn1=^gvn2 =====================*/
			if (mglvnp->gblp[IND2]->s_gv_target->nct != mglvnp->gblp[IND1]->s_gv_target->nct)
				rts_error(VARLSTCNT(1) ERR_NCTCOLLDIFF);
			/* if self merge then NOOP*/
			if (!merge_desc_check()) /* will not proceed if one is descendant of another */
			{
				gvname_env_restore(mglvnp->gblp[IND1]);	 /* store destination as naked indicator in gv_currkey */
				POP_MV_STENT();	/* value */
				merge_args = 0;	/* Must reset to zero to reuse the Global */
				return;
			}
			nullcoll_src = mglvnp->gblp[IND2]->s_gv_cur_region->std_null_coll;
			nullcoll_dst = mglvnp->gblp[IND1]->s_gv_cur_region->std_null_coll;
			if (1 == dollardata_src || 11 == dollardata_src)
			{
				found = op_gvget(value);  /* value of ^glvn2 */
				if (found)
				{	/* SET ^gvn1=^gvn2 */
					gvname_env_restore(mglvnp->gblp[IND1]);
					op_gvput(value);
					/* Note: If ^gvn1's null_sub=ALLOWEXISTING and say ^gvn1("")=^gvn,
					 * this will give NULL_SUBC error
					 */
				}
			}
			check_for_null_subs = (NEVER != mglvnp->gblp[IND2]->s_gv_cur_region->null_subs) &&
				(ALWAYS != mglvnp->gblp[IND1]->s_gv_cur_region->null_subs);
			/* Traverse descendant of ^gvn2 and copy into ^gvn1 */
			for (; ;)
			{
				if (outofband)
				{
					gvname_env_restore(mglvnp->gblp[IND1]); /* naked indicator is restored into gv_currkey */
					outofband_action(FALSE);
				}
				/* Restore last key under ^gvn2 we worked */
				gvname_env_restore(mglvnp->gblp[IND2]);
				assert(0 == gv_currkey->base[gv_currkey->end - 1] && 0 == gv_currkey->base[gv_currkey->end]);
				/* following is an attempt to find immidiate right sibling */
				gv_currkey->base[gv_currkey->end] = 1;
				gv_currkey->base[gv_currkey->end + 1] = 0;
				gv_currkey->base[gv_currkey->end + 2] = 0;
				gv_currkey->end += 2;
				/* Do atomic $QUERY and $GET of current glvn2:
				 * mkey is a mstr which contains $QUERY result in database format (So no conversion necessary)
				 * value is a mstr which contains $GET result
				 */
				if (!op_gvqueryget(mkey, value))
					break;
				assert(MV_IS_STRING(mkey));
				if (mkey->str.len < org_glvn2_keysz)
					break;
				if (0 != *((unsigned char *)mkey->str.addr + (TREF(gv_mergekey2))->end - 1) ||
					memcmp(mkey->str.addr, (TREF(gv_mergekey2))->base, (TREF(gv_mergekey2))->end - 1))
					break; 					/* mkey is not under the sub-tree */
				delta2 = mkey->str.len - org_glvn2_keysz; 	/* length increase of source key */
				assert (0 < delta2);
				/* Save the new source key for next iteration */
				memcpy(mglvnp->gblp[IND2]->s_gv_currkey->base + org_glvn2_keysz - 2,
					mkey->str.addr + org_glvn2_keysz - 2, delta2 + 2);
				mglvnp->gblp[IND2]->s_gv_currkey->end = mkey->str.len - 1;
				/* Create the destination key for this iteration (under ^glvn1) */
				gvname_env_restore(mglvnp->gblp[IND1]);
				if (gv_cur_region->max_key_size < org_glvn1_keysz + delta2)
					ISSUE_GVSUBOFLOW_ERROR(gv_currkey);
				assert(gv_currkey->end == org_glvn1_keysz - 1);
				memcpy(gv_currkey->base + org_glvn1_keysz - 2,
					mkey->str.addr + org_glvn2_keysz - 2, delta2 + 2);
				gv_currkey->end = org_glvn1_keysz + delta2 - 1;
				if (nullcoll_src != nullcoll_dst)
				{
					if (0 == nullcoll_dst)
					{	/* Standard to GTM null subscript conversion*/
						STD2GTMNULLCOLL((unsigned char *)gv_currkey->base + org_glvn1_keysz - 1,
								delta2 - 1);
					} else
					{	/*  GTM to standard null subscript conversion */
						GTM2STDNULLCOLL((unsigned char *)gv_currkey->base + org_glvn1_keysz - 1,
								delta2 - 1);
					}
				}
				/* check null subscripts in destination key, note that we have already restored, destination global
				 * and curresponding region, key information
				 */
				if (check_for_null_subs)
				{
					ptr2 = gv_currkey->base + gv_currkey->end - 1;
					for (ptr = gv_currkey->base + org_glvn1_keysz - 2; ptr < ptr2; )
					{
						if (KEY_DELIMITER == *ptr++ && KEY_DELIMITER == *(ptr + 1) &&
							(0 == gv_cur_region->std_null_coll ? (STR_SUB_PREFIX == *ptr) :
							(SUBSCRIPT_STDCOL_NULL == *ptr)))
							/* Note: For sgnl_gvnulsubsc/rts_error
							 * 	 we do not restore proper naked indicator.
							 * The standard states that the effect of a MERGE command
							 * on the naked indicator is that the naked indicator will be changed
							 * as if a specific SET command would have been executed.
							 * The standard also states that the effect on the naked indicator
							 * will only take be visible after the MERGE command has completed.
							 * So, if there is an error during the execution of a MERGE command,
							 * the standard allows the naked indicator to reflect any intermediate
							 * state. This provision was made intentionally, otherwise it would
							 * have become nearly impossible to create a fully standard
							 * implementation. : From Ed de Moel : 2/1/2
							 */
							sgnl_gvnulsubsc();
					}
				}
				/* Now put value of ^glvn2 descendant into corresponding descendant under ^glvn1 */
				op_gvput(value);
			}
			gvname_env_restore(mglvnp->gblp[IND1]);	 /* store destination as naked indicator in gv_currkey */
		} else
		{	/*==================== MERGE lvn1=^gvn2 =====================*/
			assert(MARG1_IS_LCL(merge_args));
			assert(mglvnp->lclp[IND1]);
			/* Need to protect subsc created from global variable subscripts from stpgcol */
			PUSH_MV_STENT(MVST_MVAL);
			subsc = &mv_chain->mv_st_cont.mvs_mval;
			/* Restore ^gvn2 we will work */
			gvname_env_save(mglvnp->gblp[IND2]);
			if (1 == dollardata_src || 11 == dollardata_src)
			{	/* SET lvn1=^gvn2 */
				found = op_gvget(value);
				if (found)
					mglvnp->lclp[IND1]->v = *value;
			}
			for (; ;)
			{
				if (outofband)
				{
					gvname_env_restore(mglvnp->gblp[IND2]);	 /* naked indicator is restored into gv_currkey */
					outofband_action(FALSE);
				}
				assert(0 == gv_currkey->base[gv_currkey->end - 1] && 0 == gv_currkey->base[gv_currkey->end]);
				/* following is an attempt to find immidiate right sibling */
				gv_currkey->base[gv_currkey->end] = 1;
				gv_currkey->base[gv_currkey->end + 1] = 0;
				gv_currkey->base[gv_currkey->end + 2] = 0;
				gv_currkey->end += 2;
				/* Do $QUERY and $GET of current glvn2. Result will be in mkey and value respectively.
				 * mkey->str contains data as database format. So no conversion necessary
				 */
				if (!op_gvqueryget(mkey, value))
					break;
				if (mkey->str.len < (TREF(gv_mergekey2))->end + 1)
					break;
				ptr = (unsigned char *)mkey->str.addr +  (TREF(gv_mergekey2))->end - 1;
				if (0 != *ptr || memcmp(mkey->str.addr, (TREF(gv_mergekey2))->base, (TREF(gv_mergekey2))->end - 1))
					break;
				assert(MV_IS_STRING(mkey));
				delta2 = mkey->str.len - org_glvn2_keysz; /* length increase of key */
				assert (0 < delta2);
				/* Create next key for ^glvn2 */
				memcpy(gv_currkey->base + org_glvn2_keysz - 2, mkey->str.addr + org_glvn2_keysz - 2, delta2 + 2);
				gv_currkey->end = mkey->str.len - 1;
				/* Now add subscripts to create the entire key */
				dst_lv =  mglvnp->lclp[IND1];
				is_base_var = LV_IS_BASE_VAR(dst_lv);
				ptr = (unsigned char *)gv_currkey->base + org_glvn2_keysz - 1;
				assert(*ptr);
				do
				{
					LV_SBS_DEPTH(dst_lv, is_base_var, sbs_depth);
					if (MAX_LVSUBSCRIPTS <= sbs_depth)
						rts_error(VARLSTCNT(3) ERR_MERGEINCOMPL, 0, ERR_MAXNRSUBSCRIPTS);
					ptr2 = gvsub2str(ptr, buff, FALSE);
					subsc->mvtype = MV_STR;
					subsc->str.addr = (char *)buff;
					subsc->str.len = INTCAST(ptr2 - buff);
					s2pool(&subsc->str);
					dst_lv = op_putindx(VARLSTCNT(2) dst_lv, subsc);
					while (*ptr++);	/* skip to start of next subscript */
					is_base_var = FALSE;
				} while (*ptr);
				/* We created the key. Pre-process the node in case a container is being replaced,
				 * then assign the value directly. Note there is no need to worry about MV_ALIASCONT
				 * propagation since the source in this case is a global var.
				 */
				DECR_AC_REF(dst_lv, TRUE);
				dst_lv->v = *value;
			}
			gvname_env_restore(mglvnp->gblp[IND2]);	 /* naked indicator is restored into gv_currkey */
			POP_MV_STENT();     /* subsc */
		}
		POP_MV_STENT();     /* mkey */
	} else
	{	/* source is local */
		op_fndata(mglvnp->lclp[IND2], value);
		dollardata_src = MV_FORCE_INT(value);
		if (0 == dollardata_src)
		{
			UNDO_ACTIVE_LV;
			POP_MV_STENT();	/* value */
			if (MARG1_IS_GBL(merge_args))
				gvname_env_restore(mglvnp->gblp[IND1]);	 /* store destination as naked indicator in gv_currkey */
			merge_args = 0;	/* Must reset to zero to reuse the Global */
			return;
		}
		/* not memsetting output to 0 here can cause garbage value of output.out_var.lv.child which in turn can
		 * cause a premature return from lvzwr_var resulting in op_merge() returning without having done the merge.
		 */
		memset(&output, 0, SIZEOF(output));
		if (MARG1_IS_LCL(merge_args))
		{	/*==================== MERGE lvn1=lvn2 =====================*/
			assert(mglvnp->lclp[IND1]);
			/* if self merge then NOOP */
			if (!merge_desc_check()) /* will not proceed if one is descendant of another */
			{
				POP_MV_STENT();	/* value */
				merge_args = 0;	/* Must reset to zero to reuse the Global */
				return;
			}
			output.buff = (char *)buff;
			output.ptr = output.buff;
			output.out_var.lv.lvar = mglvnp->lclp[IND1];
			zwr_output = &output;
			lvzwr_init(zwr_patrn_mident, &mglvnp->lclp[IND2]->v);
			lvzwr_arg(ZWRITE_ASTERISK, 0, 0);
			lvzwr_var(mglvnp->lclp[IND2], 0);
			/* assert that destination got all data of the source and its descendants */
			DEBUG_ONLY(op_fndata(mglvnp->lclp[IND1], value));
			DEBUG_ONLY(dollardata_dst = MV_FORCE_INT(value));
			assert((dollardata_src & dollardata_dst) == dollardata_src);
		} else
		{	/*==================== MERGE ^gvn1=lvn2 =====================*/
			assert(MARG1_IS_GBL(merge_args) && MARG2_IS_LCL(merge_args));
			gvname_env_save(mglvnp->gblp[IND1]);
			output.buff = (char *)buff;
			output.ptr = output.buff;
			output.out_var.gv.end = gv_currkey->end;
			output.out_var.gv.prev = gv_currkey->prev;
			zwr_output = &output;
			lvzwr_init(zwr_patrn_mident, &mglvnp->lclp[IND2]->v);
			lvzwr_arg(ZWRITE_ASTERISK, 0, 0);
			lvzwr_var(mglvnp->lclp[IND2], 0);
			gvname_env_restore(mglvnp->gblp[IND1]);	 /* store destination as naked indicator in gv_currkey */
		}
	}
	POP_MV_STENT();	/* value */
	merge_args = 0;	/* Must reset to zero to reuse the Global */
}